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-rw-r--r--Documentation/feature-removal-schedule.txt8
-rw-r--r--Documentation/networking/00-INDEX3
-rw-r--r--Documentation/networking/sk98lin.txt568
-rw-r--r--drivers/net/Kconfig89
-rw-r--r--drivers/net/Makefile1
-rw-r--r--drivers/net/sk98lin/Makefile87
-rw-r--r--drivers/net/sk98lin/h/lm80.h179
-rw-r--r--drivers/net/sk98lin/h/skaddr.h285
-rw-r--r--drivers/net/sk98lin/h/skcsum.h213
-rw-r--r--drivers/net/sk98lin/h/skdebug.h74
-rw-r--r--drivers/net/sk98lin/h/skdrv1st.h188
-rw-r--r--drivers/net/sk98lin/h/skdrv2nd.h447
-rw-r--r--drivers/net/sk98lin/h/skerror.h55
-rw-r--r--drivers/net/sk98lin/h/skgedrv.h51
-rw-r--r--drivers/net/sk98lin/h/skgehw.h2126
-rw-r--r--drivers/net/sk98lin/h/skgehwt.h48
-rw-r--r--drivers/net/sk98lin/h/skgei2c.h210
-rw-r--r--drivers/net/sk98lin/h/skgeinit.h797
-rw-r--r--drivers/net/sk98lin/h/skgepnm2.h334
-rw-r--r--drivers/net/sk98lin/h/skgepnmi.h962
-rw-r--r--drivers/net/sk98lin/h/skgesirq.h110
-rw-r--r--drivers/net/sk98lin/h/ski2c.h174
-rw-r--r--drivers/net/sk98lin/h/skqueue.h94
-rw-r--r--drivers/net/sk98lin/h/skrlmt.h438
-rw-r--r--drivers/net/sk98lin/h/sktimer.h63
-rw-r--r--drivers/net/sk98lin/h/sktypes.h69
-rw-r--r--drivers/net/sk98lin/h/skversion.h38
-rw-r--r--drivers/net/sk98lin/h/skvpd.h248
-rw-r--r--drivers/net/sk98lin/h/xmac_ii.h1579
-rw-r--r--drivers/net/sk98lin/skaddr.c1788
-rw-r--r--drivers/net/sk98lin/skdim.c742
-rw-r--r--drivers/net/sk98lin/skethtool.c627
-rw-r--r--drivers/net/sk98lin/skge.c5219
-rw-r--r--drivers/net/sk98lin/skgehwt.c171
-rw-r--r--drivers/net/sk98lin/skgeinit.c2005
-rw-r--r--drivers/net/sk98lin/skgemib.c1075
-rw-r--r--drivers/net/sk98lin/skgepnmi.c8210
-rw-r--r--drivers/net/sk98lin/skgesirq.c2229
-rw-r--r--drivers/net/sk98lin/ski2c.c1296
-rw-r--r--drivers/net/sk98lin/sklm80.c141
-rw-r--r--drivers/net/sk98lin/skqueue.c179
-rw-r--r--drivers/net/sk98lin/skrlmt.c3257
-rw-r--r--drivers/net/sk98lin/sktimer.c250
-rw-r--r--drivers/net/sk98lin/skvpd.c1091
-rw-r--r--drivers/net/sk98lin/skxmac2.c4160
45 files changed, 41977 insertions, 1 deletions
diff --git a/Documentation/feature-removal-schedule.txt b/Documentation/feature-removal-schedule.txt
index b9a3fdc1cc5a..00928d2ecfb2 100644
--- a/Documentation/feature-removal-schedule.txt
+++ b/Documentation/feature-removal-schedule.txt
@@ -298,3 +298,11 @@ Why: All mthca hardware also supports MSI-X, which provides
298Who: Roland Dreier <rolandd@cisco.com> 298Who: Roland Dreier <rolandd@cisco.com>
299 299
300--------------------------- 300---------------------------
301
302What: sk98lin network driver
303When: Feburary 2008
304Why: In kernel tree version of driver is unmaintained. Sk98lin driver
305 replaced by the skge driver.
306Who: Stephen Hemminger <shemminger@linux-foundation.org>
307
308---------------------------
diff --git a/Documentation/networking/00-INDEX b/Documentation/networking/00-INDEX
index d63f480afb74..153d84d281e6 100644
--- a/Documentation/networking/00-INDEX
+++ b/Documentation/networking/00-INDEX
@@ -96,6 +96,9 @@ routing.txt
96 - the new routing mechanism 96 - the new routing mechanism
97shaper.txt 97shaper.txt
98 - info on the module that can shape/limit transmitted traffic. 98 - info on the module that can shape/limit transmitted traffic.
99sk98lin.txt
100 - Marvell Yukon Chipset / SysKonnect SK-98xx compliant Gigabit
101 Ethernet Adapter family driver info
99skfp.txt 102skfp.txt
100 - SysKonnect FDDI (SK-5xxx, Compaq Netelligent) driver info. 103 - SysKonnect FDDI (SK-5xxx, Compaq Netelligent) driver info.
101smc9.txt 104smc9.txt
diff --git a/Documentation/networking/sk98lin.txt b/Documentation/networking/sk98lin.txt
new file mode 100644
index 000000000000..8590a954df1d
--- /dev/null
+++ b/Documentation/networking/sk98lin.txt
@@ -0,0 +1,568 @@
1(C)Copyright 1999-2004 Marvell(R).
2All rights reserved
3===========================================================================
4
5sk98lin.txt created 13-Feb-2004
6
7Readme File for sk98lin v6.23
8Marvell Yukon/SysKonnect SK-98xx Gigabit Ethernet Adapter family driver for LINUX
9
10This file contains
11 1 Overview
12 2 Required Files
13 3 Installation
14 3.1 Driver Installation
15 3.2 Inclusion of adapter at system start
16 4 Driver Parameters
17 4.1 Per-Port Parameters
18 4.2 Adapter Parameters
19 5 Large Frame Support
20 6 VLAN and Link Aggregation Support (IEEE 802.1, 802.1q, 802.3ad)
21 7 Troubleshooting
22
23===========================================================================
24
25
261 Overview
27===========
28
29The sk98lin driver supports the Marvell Yukon and SysKonnect
30SK-98xx/SK-95xx compliant Gigabit Ethernet Adapter on Linux. It has
31been tested with Linux on Intel/x86 machines.
32***
33
34
352 Required Files
36=================
37
38The linux kernel source.
39No additional files required.
40***
41
42
433 Installation
44===============
45
46It is recommended to download the latest version of the driver from the
47SysKonnect web site www.syskonnect.com. If you have downloaded the latest
48driver, the Linux kernel has to be patched before the driver can be
49installed. For details on how to patch a Linux kernel, refer to the
50patch.txt file.
51
523.1 Driver Installation
53------------------------
54
55The following steps describe the actions that are required to install
56the driver and to start it manually. These steps should be carried
57out for the initial driver setup. Once confirmed to be ok, they can
58be included in the system start.
59
60NOTE 1: To perform the following tasks you need 'root' access.
61
62NOTE 2: In case of problems, please read the section "Troubleshooting"
63 below.
64
65The driver can either be integrated into the kernel or it can be compiled
66as a module. Select the appropriate option during the kernel
67configuration.
68
69Compile/use the driver as a module
70----------------------------------
71To compile the driver, go to the directory /usr/src/linux and
72execute the command "make menuconfig" or "make xconfig" and proceed as
73follows:
74
75To integrate the driver permanently into the kernel, proceed as follows:
76
771. Select the menu "Network device support" and then "Ethernet(1000Mbit)"
782. Mark "Marvell Yukon Chipset / SysKonnect SK-98xx family support"
79 with (*)
803. Build a new kernel when the configuration of the above options is
81 finished.
824. Install the new kernel.
835. Reboot your system.
84
85To use the driver as a module, proceed as follows:
86
871. Enable 'loadable module support' in the kernel.
882. For automatic driver start, enable the 'Kernel module loader'.
893. Select the menu "Network device support" and then "Ethernet(1000Mbit)"
904. Mark "Marvell Yukon Chipset / SysKonnect SK-98xx family support"
91 with (M)
925. Execute the command "make modules".
936. Execute the command "make modules_install".
94 The appropriate modules will be installed.
957. Reboot your system.
96
97
98Load the module manually
99------------------------
100To load the module manually, proceed as follows:
101
1021. Enter "modprobe sk98lin".
1032. If a Marvell Yukon or SysKonnect SK-98xx adapter is installed in
104 your computer and you have a /proc file system, execute the command:
105 "ls /proc/net/sk98lin/"
106 This should produce an output containing a line with the following
107 format:
108 eth0 eth1 ...
109 which indicates that your adapter has been found and initialized.
110
111 NOTE 1: If you have more than one Marvell Yukon or SysKonnect SK-98xx
112 adapter installed, the adapters will be listed as 'eth0',
113 'eth1', 'eth2', etc.
114 For each adapter, repeat steps 3 and 4 below.
115
116 NOTE 2: If you have other Ethernet adapters installed, your Marvell
117 Yukon or SysKonnect SK-98xx adapter will be mapped to the
118 next available number, e.g. 'eth1'. The mapping is executed
119 automatically.
120 The module installation message (displayed either in a system
121 log file or on the console) prints a line for each adapter
122 found containing the corresponding 'ethX'.
123
1243. Select an IP address and assign it to the respective adapter by
125 entering:
126 ifconfig eth0 <ip-address>
127 With this command, the adapter is connected to the Ethernet.
128
129 SK-98xx Gigabit Ethernet Server Adapters: The yellow LED on the adapter
130 is now active, the link status LED of the primary port is active and
131 the link status LED of the secondary port (on dual port adapters) is
132 blinking (if the ports are connected to a switch or hub).
133 SK-98xx V2.0 Gigabit Ethernet Adapters: The link status LED is active.
134 In addition, you will receive a status message on the console stating
135 "ethX: network connection up using port Y" and showing the selected
136 connection parameters (x stands for the ethernet device number
137 (0,1,2, etc), y stands for the port name (A or B)).
138
139 NOTE: If you are in doubt about IP addresses, ask your network
140 administrator for assistance.
141
1424. Your adapter should now be fully operational.
143 Use 'ping <otherstation>' to verify the connection to other computers
144 on your network.
1455. To check the adapter configuration view /proc/net/sk98lin/[devicename].
146 For example by executing:
147 "cat /proc/net/sk98lin/eth0"
148
149Unload the module
150-----------------
151To stop and unload the driver modules, proceed as follows:
152
1531. Execute the command "ifconfig eth0 down".
1542. Execute the command "rmmod sk98lin".
155
1563.2 Inclusion of adapter at system start
157-----------------------------------------
158
159Since a large number of different Linux distributions are
160available, we are unable to describe a general installation procedure
161for the driver module.
162Because the driver is now integrated in the kernel, installation should
163be easy, using the standard mechanism of your distribution.
164Refer to the distribution's manual for installation of ethernet adapters.
165
166***
167
1684 Driver Parameters
169====================
170
171Parameters can be set at the command line after the module has been
172loaded with the command 'modprobe'.
173In some distributions, the configuration tools are able to pass parameters
174to the driver module.
175
176If you use the kernel module loader, you can set driver parameters
177in the file /etc/modprobe.conf (or /etc/modules.conf in 2.4 or earlier).
178To set the driver parameters in this file, proceed as follows:
179
1801. Insert a line of the form :
181 options sk98lin ...
182 For "...", the same syntax is required as described for the command
183 line parameters of modprobe below.
1842. To activate the new parameters, either reboot your computer
185 or
186 unload and reload the driver.
187 The syntax of the driver parameters is:
188
189 modprobe sk98lin parameter=value1[,value2[,value3...]]
190
191 where value1 refers to the first adapter, value2 to the second etc.
192
193NOTE: All parameters are case sensitive. Write them exactly as shown
194 below.
195
196Example:
197Suppose you have two adapters. You want to set auto-negotiation
198on the first adapter to ON and on the second adapter to OFF.
199You also want to set DuplexCapabilities on the first adapter
200to FULL, and on the second adapter to HALF.
201Then, you must enter:
202
203 modprobe sk98lin AutoNeg_A=On,Off DupCap_A=Full,Half
204
205NOTE: The number of adapters that can be configured this way is
206 limited in the driver (file skge.c, constant SK_MAX_CARD_PARAM).
207 The current limit is 16. If you happen to install
208 more adapters, adjust this and recompile.
209
210
2114.1 Per-Port Parameters
212------------------------
213
214These settings are available for each port on the adapter.
215In the following description, '?' stands for the port for
216which you set the parameter (A or B).
217
218Speed
219-----
220Parameter: Speed_?
221Values: 10, 100, 1000, Auto
222Default: Auto
223
224This parameter is used to set the speed capabilities. It is only valid
225for the SK-98xx V2.0 copper adapters.
226Usually, the speed is negotiated between the two ports during link
227establishment. If this fails, a port can be forced to a specific setting
228with this parameter.
229
230Auto-Negotiation
231----------------
232Parameter: AutoNeg_?
233Values: On, Off, Sense
234Default: On
235
236The "Sense"-mode automatically detects whether the link partner supports
237auto-negotiation or not.
238
239Duplex Capabilities
240-------------------
241Parameter: DupCap_?
242Values: Half, Full, Both
243Default: Both
244
245This parameters is only relevant if auto-negotiation for this port is
246not set to "Sense". If auto-negotiation is set to "On", all three values
247are possible. If it is set to "Off", only "Full" and "Half" are allowed.
248This parameter is useful if your link partner does not support all
249possible combinations.
250
251Flow Control
252------------
253Parameter: FlowCtrl_?
254Values: Sym, SymOrRem, LocSend, None
255Default: SymOrRem
256
257This parameter can be used to set the flow control capabilities the
258port reports during auto-negotiation. It can be set for each port
259individually.
260Possible modes:
261 -- Sym = Symmetric: both link partners are allowed to send
262 PAUSE frames
263 -- SymOrRem = SymmetricOrRemote: both or only remote partner
264 are allowed to send PAUSE frames
265 -- LocSend = LocalSend: only local link partner is allowed
266 to send PAUSE frames
267 -- None = no link partner is allowed to send PAUSE frames
268
269NOTE: This parameter is ignored if auto-negotiation is set to "Off".
270
271Role in Master-Slave-Negotiation (1000Base-T only)
272--------------------------------------------------
273Parameter: Role_?
274Values: Auto, Master, Slave
275Default: Auto
276
277This parameter is only valid for the SK-9821 and SK-9822 adapters.
278For two 1000Base-T ports to communicate, one must take the role of the
279master (providing timing information), while the other must be the
280slave. Usually, this is negotiated between the two ports during link
281establishment. If this fails, a port can be forced to a specific setting
282with this parameter.
283
284
2854.2 Adapter Parameters
286-----------------------
287
288Connection Type (SK-98xx V2.0 copper adapters only)
289---------------
290Parameter: ConType
291Values: Auto, 100FD, 100HD, 10FD, 10HD
292Default: Auto
293
294The parameter 'ConType' is a combination of all five per-port parameters
295within one single parameter. This simplifies the configuration of both ports
296of an adapter card! The different values of this variable reflect the most
297meaningful combinations of port parameters.
298
299The following table shows the values of 'ConType' and the corresponding
300combinations of the per-port parameters:
301
302 ConType | DupCap AutoNeg FlowCtrl Role Speed
303 ----------+------------------------------------------------------
304 Auto | Both On SymOrRem Auto Auto
305 100FD | Full Off None Auto (ignored) 100
306 100HD | Half Off None Auto (ignored) 100
307 10FD | Full Off None Auto (ignored) 10
308 10HD | Half Off None Auto (ignored) 10
309
310Stating any other port parameter together with this 'ConType' variable
311will result in a merged configuration of those settings. This due to
312the fact, that the per-port parameters (e.g. Speed_? ) have a higher
313priority than the combined variable 'ConType'.
314
315NOTE: This parameter is always used on both ports of the adapter card.
316
317Interrupt Moderation
318--------------------
319Parameter: Moderation
320Values: None, Static, Dynamic
321Default: None
322
323Interrupt moderation is employed to limit the maximum number of interrupts
324the driver has to serve. That is, one or more interrupts (which indicate any
325transmit or receive packet to be processed) are queued until the driver
326processes them. When queued interrupts are to be served, is determined by the
327'IntsPerSec' parameter, which is explained later below.
328
329Possible modes:
330
331 -- None - No interrupt moderation is applied on the adapter card.
332 Therefore, each transmit or receive interrupt is served immediately
333 as soon as it appears on the interrupt line of the adapter card.
334
335 -- Static - Interrupt moderation is applied on the adapter card.
336 All transmit and receive interrupts are queued until a complete
337 moderation interval ends. If such a moderation interval ends, all
338 queued interrupts are processed in one big bunch without any delay.
339 The term 'static' reflects the fact, that interrupt moderation is
340 always enabled, regardless how much network load is currently
341 passing via a particular interface. In addition, the duration of
342 the moderation interval has a fixed length that never changes while
343 the driver is operational.
344
345 -- Dynamic - Interrupt moderation might be applied on the adapter card,
346 depending on the load of the system. If the driver detects that the
347 system load is too high, the driver tries to shield the system against
348 too much network load by enabling interrupt moderation. If - at a later
349 time - the CPU utilization decreases again (or if the network load is
350 negligible) the interrupt moderation will automatically be disabled.
351
352Interrupt moderation should be used when the driver has to handle one or more
353interfaces with a high network load, which - as a consequence - leads also to a
354high CPU utilization. When moderation is applied in such high network load
355situations, CPU load might be reduced by 20-30%.
356
357NOTE: The drawback of using interrupt moderation is an increase of the round-
358trip-time (RTT), due to the queueing and serving of interrupts at dedicated
359moderation times.
360
361Interrupts per second
362---------------------
363Parameter: IntsPerSec
364Values: 30...40000 (interrupts per second)
365Default: 2000
366
367This parameter is only used if either static or dynamic interrupt moderation
368is used on a network adapter card. Using this parameter if no moderation is
369applied will lead to no action performed.
370
371This parameter determines the length of any interrupt moderation interval.
372Assuming that static interrupt moderation is to be used, an 'IntsPerSec'
373parameter value of 2000 will lead to an interrupt moderation interval of
374500 microseconds.
375
376NOTE: The duration of the moderation interval is to be chosen with care.
377At first glance, selecting a very long duration (e.g. only 100 interrupts per
378second) seems to be meaningful, but the increase of packet-processing delay
379is tremendous. On the other hand, selecting a very short moderation time might
380compensate the use of any moderation being applied.
381
382
383Preferred Port
384--------------
385Parameter: PrefPort
386Values: A, B
387Default: A
388
389This is used to force the preferred port to A or B (on dual-port network
390adapters). The preferred port is the one that is used if both are detected
391as fully functional.
392
393RLMT Mode (Redundant Link Management Technology)
394------------------------------------------------
395Parameter: RlmtMode
396Values: CheckLinkState,CheckLocalPort, CheckSeg, DualNet
397Default: CheckLinkState
398
399RLMT monitors the status of the port. If the link of the active port
400fails, RLMT switches immediately to the standby link. The virtual link is
401maintained as long as at least one 'physical' link is up.
402
403Possible modes:
404
405 -- CheckLinkState - Check link state only: RLMT uses the link state
406 reported by the adapter hardware for each individual port to
407 determine whether a port can be used for all network traffic or
408 not.
409
410 -- CheckLocalPort - In this mode, RLMT monitors the network path
411 between the two ports of an adapter by regularly exchanging packets
412 between them. This mode requires a network configuration in which
413 the two ports are able to "see" each other (i.e. there must not be
414 any router between the ports).
415
416 -- CheckSeg - Check local port and segmentation: This mode supports the
417 same functions as the CheckLocalPort mode and additionally checks
418 network segmentation between the ports. Therefore, this mode is only
419 to be used if Gigabit Ethernet switches are installed on the network
420 that have been configured to use the Spanning Tree protocol.
421
422 -- DualNet - In this mode, ports A and B are used as separate devices.
423 If you have a dual port adapter, port A will be configured as eth0
424 and port B as eth1. Both ports can be used independently with
425 distinct IP addresses. The preferred port setting is not used.
426 RLMT is turned off.
427
428NOTE: RLMT modes CLP and CLPSS are designed to operate in configurations
429 where a network path between the ports on one adapter exists.
430 Moreover, they are not designed to work where adapters are connected
431 back-to-back.
432***
433
434
4355 Large Frame Support
436======================
437
438The driver supports large frames (also called jumbo frames). Using large
439frames can result in an improved throughput if transferring large amounts
440of data.
441To enable large frames, set the MTU (maximum transfer unit) of the
442interface to the desired value (up to 9000), execute the following
443command:
444 ifconfig eth0 mtu 9000
445This will only work if you have two adapters connected back-to-back
446or if you use a switch that supports large frames. When using a switch,
447it should be configured to allow large frames and auto-negotiation should
448be set to OFF. The setting must be configured on all adapters that can be
449reached by the large frames. If one adapter is not set to receive large
450frames, it will simply drop them.
451
452You can switch back to the standard ethernet frame size by executing the
453following command:
454 ifconfig eth0 mtu 1500
455
456To permanently configure this setting, add a script with the 'ifconfig'
457line to the system startup sequence (named something like "S99sk98lin"
458in /etc/rc.d/rc2.d).
459***
460
461
4626 VLAN and Link Aggregation Support (IEEE 802.1, 802.1q, 802.3ad)
463==================================================================
464
465The Marvell Yukon/SysKonnect Linux drivers are able to support VLAN and
466Link Aggregation according to IEEE standards 802.1, 802.1q, and 802.3ad.
467These features are only available after installation of open source
468modules available on the Internet:
469For VLAN go to: http://www.candelatech.com/~greear/vlan.html
470For Link Aggregation go to: http://www.st.rim.or.jp/~yumo
471
472NOTE: SysKonnect GmbH does not offer any support for these open source
473 modules and does not take the responsibility for any kind of
474 failures or problems arising in connection with these modules.
475
476NOTE: Configuring Link Aggregation on a SysKonnect dual link adapter may
477 cause problems when unloading the driver.
478
479
4807 Troubleshooting
481==================
482
483If any problems occur during the installation process, check the
484following list:
485
486
487Problem: The SK-98xx adapter cannot be found by the driver.
488Solution: In /proc/pci search for the following entry:
489 'Ethernet controller: SysKonnect SK-98xx ...'
490 If this entry exists, the SK-98xx or SK-98xx V2.0 adapter has
491 been found by the system and should be operational.
492 If this entry does not exist or if the file '/proc/pci' is not
493 found, there may be a hardware problem or the PCI support may
494 not be enabled in your kernel.
495 The adapter can be checked using the diagnostics program which
496 is available on the SysKonnect web site:
497 www.syskonnect.com
498
499 Some COMPAQ machines have problems dealing with PCI under Linux.
500 This problem is described in the 'PCI howto' document
501 (included in some distributions or available from the
502 web, e.g. at 'www.linux.org').
503
504
505Problem: Programs such as 'ifconfig' or 'route' cannot be found or the
506 error message 'Operation not permitted' is displayed.
507Reason: You are not logged in as user 'root'.
508Solution: Logout and login as 'root' or change to 'root' via 'su'.
509
510
511Problem: Upon use of the command 'ping <address>' the message
512 "ping: sendto: Network is unreachable" is displayed.
513Reason: Your route is not set correctly.
514Solution: If you are using RedHat, you probably forgot to set up the
515 route in the 'network configuration'.
516 Check the existing routes with the 'route' command and check
517 if an entry for 'eth0' exists, and if so, if it is set correctly.
518
519
520Problem: The driver can be started, the adapter is connected to the
521 network, but you cannot receive or transmit any packets;
522 e.g. 'ping' does not work.
523Reason: There is an incorrect route in your routing table.
524Solution: Check the routing table with the command 'route' and read the
525 manual help pages dealing with routes (enter 'man route').
526
527NOTE: Although the 2.2.x kernel versions generate the routing entry
528 automatically, problems of this kind may occur here as well. We've
529 come across a situation in which the driver started correctly at
530 system start, but after the driver has been removed and reloaded,
531 the route of the adapter's network pointed to the 'dummy0'device
532 and had to be corrected manually.
533
534
535Problem: Your computer should act as a router between multiple
536 IP subnetworks (using multiple adapters), but computers in
537 other subnetworks cannot be reached.
538Reason: Either the router's kernel is not configured for IP forwarding
539 or the routing table and gateway configuration of at least one
540 computer is not working.
541
542Problem: Upon driver start, the following error message is displayed:
543 "eth0: -- ERROR --
544 Class: internal Software error
545 Nr: 0xcc
546 Msg: SkGeInitPort() cannot init running ports"
547Reason: You are using a driver compiled for single processor machines
548 on a multiprocessor machine with SMP (Symmetric MultiProcessor)
549 kernel.
550Solution: Configure your kernel appropriately and recompile the kernel or
551 the modules.
552
553
554
555If your problem is not listed here, please contact SysKonnect's technical
556support for help (linux@syskonnect.de).
557When contacting our technical support, please ensure that the following
558information is available:
559- System Manufacturer and HW Informations (CPU, Memory... )
560- PCI-Boards in your system
561- Distribution
562- Kernel version
563- Driver version
564***
565
566
567
568***End of Readme File***
diff --git a/drivers/net/Kconfig b/drivers/net/Kconfig
index 5b9e17bf1749..c5519250efd9 100644
--- a/drivers/net/Kconfig
+++ b/drivers/net/Kconfig
@@ -2177,7 +2177,7 @@ config SKGE
2177 with better performance and more complete ethtool support. 2177 with better performance and more complete ethtool support.
2178 2178
2179 It does not support the link failover and network management 2179 It does not support the link failover and network management
2180 features available in the hardware. 2180 features that "portable" vendor supplied sk98lin driver does.
2181 2181
2182 This driver supports adapters based on the original Yukon chipset: 2182 This driver supports adapters based on the original Yukon chipset:
2183 Marvell 88E8001, Belkin F5D5005, CNet GigaCard, DLink DGE-530T, 2183 Marvell 88E8001, Belkin F5D5005, CNet GigaCard, DLink DGE-530T,
@@ -2215,6 +2215,93 @@ config SKY2_DEBUG
2215 2215
2216 If unsure, say N. 2216 If unsure, say N.
2217 2217
2218config SK98LIN
2219 tristate "Marvell Yukon Chipset / SysKonnect SK-98xx Support (DEPRECATED)"
2220 depends on PCI
2221 ---help---
2222 Say Y here if you have a Marvell Yukon or SysKonnect SK-98xx/SK-95xx
2223 compliant Gigabit Ethernet Adapter.
2224
2225 This driver supports the original Yukon chipset. This driver is
2226 deprecated and will be removed from the kernel in the near future,
2227 it has been replaced by the skge driver. skge is cleaner and
2228 seems to work better.
2229
2230 This driver does not support the newer Yukon2 chipset. A separate
2231 driver, sky2, is provided to support Yukon2-based adapters.
2232
2233 The following adapters are supported by this driver:
2234 - 3Com 3C940 Gigabit LOM Ethernet Adapter
2235 - 3Com 3C941 Gigabit LOM Ethernet Adapter
2236 - Allied Telesyn AT-2970LX Gigabit Ethernet Adapter
2237 - Allied Telesyn AT-2970LX/2SC Gigabit Ethernet Adapter
2238 - Allied Telesyn AT-2970SX Gigabit Ethernet Adapter
2239 - Allied Telesyn AT-2970SX/2SC Gigabit Ethernet Adapter
2240 - Allied Telesyn AT-2970TX Gigabit Ethernet Adapter
2241 - Allied Telesyn AT-2970TX/2TX Gigabit Ethernet Adapter
2242 - Allied Telesyn AT-2971SX Gigabit Ethernet Adapter
2243 - Allied Telesyn AT-2971T Gigabit Ethernet Adapter
2244 - Belkin Gigabit Desktop Card 10/100/1000Base-T Adapter, Copper RJ-45
2245 - EG1032 v2 Instant Gigabit Network Adapter
2246 - EG1064 v2 Instant Gigabit Network Adapter
2247 - Marvell 88E8001 Gigabit LOM Ethernet Adapter (Abit)
2248 - Marvell 88E8001 Gigabit LOM Ethernet Adapter (Albatron)
2249 - Marvell 88E8001 Gigabit LOM Ethernet Adapter (Asus)
2250 - Marvell 88E8001 Gigabit LOM Ethernet Adapter (ECS)
2251 - Marvell 88E8001 Gigabit LOM Ethernet Adapter (Epox)
2252 - Marvell 88E8001 Gigabit LOM Ethernet Adapter (Foxconn)
2253 - Marvell 88E8001 Gigabit LOM Ethernet Adapter (Gigabyte)
2254 - Marvell 88E8001 Gigabit LOM Ethernet Adapter (Iwill)
2255 - Marvell 88E8050 Gigabit LOM Ethernet Adapter (Intel)
2256 - Marvell RDK-8001 Adapter
2257 - Marvell RDK-8002 Adapter
2258 - Marvell RDK-8003 Adapter
2259 - Marvell RDK-8004 Adapter
2260 - Marvell RDK-8006 Adapter
2261 - Marvell RDK-8007 Adapter
2262 - Marvell RDK-8008 Adapter
2263 - Marvell RDK-8009 Adapter
2264 - Marvell RDK-8010 Adapter
2265 - Marvell RDK-8011 Adapter
2266 - Marvell RDK-8012 Adapter
2267 - Marvell RDK-8052 Adapter
2268 - Marvell Yukon Gigabit Ethernet 10/100/1000Base-T Adapter (32 bit)
2269 - Marvell Yukon Gigabit Ethernet 10/100/1000Base-T Adapter (64 bit)
2270 - N-Way PCI-Bus Giga-Card 1000/100/10Mbps(L)
2271 - SK-9521 10/100/1000Base-T Adapter
2272 - SK-9521 V2.0 10/100/1000Base-T Adapter
2273 - SK-9821 Gigabit Ethernet Server Adapter (SK-NET GE-T)
2274 - SK-9821 V2.0 Gigabit Ethernet 10/100/1000Base-T Adapter
2275 - SK-9822 Gigabit Ethernet Server Adapter (SK-NET GE-T dual link)
2276 - SK-9841 Gigabit Ethernet Server Adapter (SK-NET GE-LX)
2277 - SK-9841 V2.0 Gigabit Ethernet 1000Base-LX Adapter
2278 - SK-9842 Gigabit Ethernet Server Adapter (SK-NET GE-LX dual link)
2279 - SK-9843 Gigabit Ethernet Server Adapter (SK-NET GE-SX)
2280 - SK-9843 V2.0 Gigabit Ethernet 1000Base-SX Adapter
2281 - SK-9844 Gigabit Ethernet Server Adapter (SK-NET GE-SX dual link)
2282 - SK-9851 V2.0 Gigabit Ethernet 1000Base-SX Adapter
2283 - SK-9861 Gigabit Ethernet Server Adapter (SK-NET GE-SX Volition)
2284 - SK-9861 V2.0 Gigabit Ethernet 1000Base-SX Adapter
2285 - SK-9862 Gigabit Ethernet Server Adapter (SK-NET GE-SX Volition dual link)
2286 - SK-9871 Gigabit Ethernet Server Adapter (SK-NET GE-ZX)
2287 - SK-9871 V2.0 Gigabit Ethernet 1000Base-ZX Adapter
2288 - SK-9872 Gigabit Ethernet Server Adapter (SK-NET GE-ZX dual link)
2289 - SMC EZ Card 1000 (SMC9452TXV.2)
2290
2291 The adapters support Jumbo Frames.
2292 The dual link adapters support link-failover and dual port features.
2293 Both Marvell Yukon and SysKonnect SK-98xx/SK-95xx adapters support
2294 the scatter-gather functionality with sendfile(). Please refer to
2295 <file:Documentation/networking/sk98lin.txt> for more information about
2296 optional driver parameters.
2297 Questions concerning this driver may be addressed to:
2298 <linux@syskonnect.de>
2299
2300 If you want to compile this driver as a module ( = code which can be
2301 inserted in and removed from the running kernel whenever you want),
2302 say M here and read <file:Documentation/kbuild/modules.txt>. The module will
2303 be called sk98lin. This is recommended.
2304
2218config VIA_VELOCITY 2305config VIA_VELOCITY
2219 tristate "VIA Velocity support" 2306 tristate "VIA Velocity support"
2220 depends on PCI 2307 depends on PCI
diff --git a/drivers/net/Makefile b/drivers/net/Makefile
index e684212fd8e2..9c928a845841 100644
--- a/drivers/net/Makefile
+++ b/drivers/net/Makefile
@@ -66,6 +66,7 @@ ps3_gelic-objs += ps3_gelic_net.o
66obj-$(CONFIG_TC35815) += tc35815.o 66obj-$(CONFIG_TC35815) += tc35815.o
67obj-$(CONFIG_SKGE) += skge.o 67obj-$(CONFIG_SKGE) += skge.o
68obj-$(CONFIG_SKY2) += sky2.o 68obj-$(CONFIG_SKY2) += sky2.o
69obj-$(CONFIG_SK98LIN) += sk98lin/
69obj-$(CONFIG_SKFP) += skfp/ 70obj-$(CONFIG_SKFP) += skfp/
70obj-$(CONFIG_VIA_RHINE) += via-rhine.o 71obj-$(CONFIG_VIA_RHINE) += via-rhine.o
71obj-$(CONFIG_VIA_VELOCITY) += via-velocity.o 72obj-$(CONFIG_VIA_VELOCITY) += via-velocity.o
diff --git a/drivers/net/sk98lin/Makefile b/drivers/net/sk98lin/Makefile
new file mode 100644
index 000000000000..afd900d5d730
--- /dev/null
+++ b/drivers/net/sk98lin/Makefile
@@ -0,0 +1,87 @@
1#
2# Makefile for the SysKonnect SK-98xx device driver.
3#
4
5
6#
7# Standalone driver params
8# SKPARAM += -DSK_KERNEL_24
9# SKPARAM += -DSK_KERNEL_24_26
10# SKPARAM += -DSK_KERNEL_26
11# SKPARAM += -DSK_KERNEL_22_24
12
13obj-$(CONFIG_SK98LIN) += sk98lin.o
14sk98lin-objs := \
15 skge.o \
16 skethtool.o \
17 skdim.o \
18 skaddr.o \
19 skgehwt.o \
20 skgeinit.o \
21 skgepnmi.o \
22 skgesirq.o \
23 ski2c.o \
24 sklm80.o \
25 skqueue.o \
26 skrlmt.o \
27 sktimer.o \
28 skvpd.o \
29 skxmac2.o
30
31# DBGDEF = \
32# -DDEBUG
33
34ifdef DEBUG
35DBGDEF += \
36-DSK_DEBUG_CHKMOD=0x00000000L \
37-DSK_DEBUG_CHKCAT=0x00000000L
38endif
39
40
41# **** possible debug modules for SK_DEBUG_CHKMOD *****************
42# SK_DBGMOD_MERR 0x00000001L /* general module error indication */
43# SK_DBGMOD_HWM 0x00000002L /* Hardware init module */
44# SK_DBGMOD_RLMT 0x00000004L /* RLMT module */
45# SK_DBGMOD_VPD 0x00000008L /* VPD module */
46# SK_DBGMOD_I2C 0x00000010L /* I2C module */
47# SK_DBGMOD_PNMI 0x00000020L /* PNMI module */
48# SK_DBGMOD_CSUM 0x00000040L /* CSUM module */
49# SK_DBGMOD_ADDR 0x00000080L /* ADDR module */
50# SK_DBGMOD_DRV 0x00010000L /* DRV module */
51
52# **** possible debug categories for SK_DEBUG_CHKCAT **************
53# *** common modules ***
54# SK_DBGCAT_INIT 0x00000001L module/driver initialization
55# SK_DBGCAT_CTRL 0x00000002L controlling: add/rmv MCA/MAC and other controls (IOCTL)
56# SK_DBGCAT_ERR 0x00000004L error handling paths
57# SK_DBGCAT_TX 0x00000008L transmit path
58# SK_DBGCAT_RX 0x00000010L receive path
59# SK_DBGCAT_IRQ 0x00000020L general IRQ handling
60# SK_DBGCAT_QUEUE 0x00000040L any queue management
61# SK_DBGCAT_DUMP 0x00000080L large data output e.g. hex dump
62# SK_DBGCAT_FATAL 0x00000100L large data output e.g. hex dump
63
64# *** driver (file skge.c) ***
65# SK_DBGCAT_DRV_ENTRY 0x00010000 entry points
66# SK_DBGCAT_DRV_??? 0x00020000 not used
67# SK_DBGCAT_DRV_MCA 0x00040000 multicast
68# SK_DBGCAT_DRV_TX_PROGRESS 0x00080000 tx path
69# SK_DBGCAT_DRV_RX_PROGRESS 0x00100000 rx path
70# SK_DBGCAT_DRV_PROGRESS 0x00200000 general runtime
71# SK_DBGCAT_DRV_??? 0x00400000 not used
72# SK_DBGCAT_DRV_PROM 0x00800000 promiscuous mode
73# SK_DBGCAT_DRV_TX_FRAME 0x01000000 display tx frames
74# SK_DBGCAT_DRV_ERROR 0x02000000 error conditions
75# SK_DBGCAT_DRV_INT_SRC 0x04000000 interrupts sources
76# SK_DBGCAT_DRV_EVENT 0x08000000 driver events
77
78EXTRA_CFLAGS += -Idrivers/net/sk98lin -DSK_DIAG_SUPPORT -DGENESIS -DYUKON $(DBGDEF) $(SKPARAM)
79
80clean:
81 rm -f core *.o *.a *.s
82
83
84
85
86
87
diff --git a/drivers/net/sk98lin/h/lm80.h b/drivers/net/sk98lin/h/lm80.h
new file mode 100644
index 000000000000..4e2dbbf78000
--- /dev/null
+++ b/drivers/net/sk98lin/h/lm80.h
@@ -0,0 +1,179 @@
1/******************************************************************************
2 *
3 * Name: lm80.h
4 * Project: Gigabit Ethernet Adapters, Common Modules
5 * Version: $Revision: 1.6 $
6 * Date: $Date: 2003/05/13 17:26:52 $
7 * Purpose: Contains all defines for the LM80 Chip
8 * (National Semiconductor).
9 *
10 ******************************************************************************/
11
12/******************************************************************************
13 *
14 * (C)Copyright 1998-2002 SysKonnect.
15 * (C)Copyright 2002-2003 Marvell.
16 *
17 * This program is free software; you can redistribute it and/or modify
18 * it under the terms of the GNU General Public License as published by
19 * the Free Software Foundation; either version 2 of the License, or
20 * (at your option) any later version.
21 *
22 * The information in this file is provided "AS IS" without warranty.
23 *
24 ******************************************************************************/
25
26#ifndef __INC_LM80_H
27#define __INC_LM80_H
28
29#ifdef __cplusplus
30extern "C" {
31#endif /* __cplusplus */
32
33/* defines ********************************************************************/
34
35/*
36 * LM80 register definition
37 *
38 * All registers are 8 bit wide
39 */
40#define LM80_CFG 0x00 /* Configuration Register */
41#define LM80_ISRC_1 0x01 /* Interrupt Status Register 1 */
42#define LM80_ISRC_2 0x02 /* Interrupt Status Register 2 */
43#define LM80_IMSK_1 0x03 /* Interrupt Mask Register 1 */
44#define LM80_IMSK_2 0x04 /* Interrupt Mask Register 2 */
45#define LM80_FAN_CTRL 0x05 /* Fan Devisor/RST#/OS# Register */
46#define LM80_TEMP_CTRL 0x06 /* OS# Config, Temp Res. Reg */
47 /* 0x07 - 0x1f reserved */
48 /* current values */
49#define LM80_VT0_IN 0x20 /* current Voltage 0 value */
50#define LM80_VT1_IN 0x21 /* current Voltage 1 value */
51#define LM80_VT2_IN 0x22 /* current Voltage 2 value */
52#define LM80_VT3_IN 0x23 /* current Voltage 3 value */
53#define LM80_VT4_IN 0x24 /* current Voltage 4 value */
54#define LM80_VT5_IN 0x25 /* current Voltage 5 value */
55#define LM80_VT6_IN 0x26 /* current Voltage 6 value */
56#define LM80_TEMP_IN 0x27 /* current Temperature value */
57#define LM80_FAN1_IN 0x28 /* current Fan 1 count */
58#define LM80_FAN2_IN 0x29 /* current Fan 2 count */
59 /* limit values */
60#define LM80_VT0_HIGH_LIM 0x2a /* high limit val for Voltage 0 */
61#define LM80_VT0_LOW_LIM 0x2b /* low limit val for Voltage 0 */
62#define LM80_VT1_HIGH_LIM 0x2c /* high limit val for Voltage 1 */
63#define LM80_VT1_LOW_LIM 0x2d /* low limit val for Voltage 1 */
64#define LM80_VT2_HIGH_LIM 0x2e /* high limit val for Voltage 2 */
65#define LM80_VT2_LOW_LIM 0x2f /* low limit val for Voltage 2 */
66#define LM80_VT3_HIGH_LIM 0x30 /* high limit val for Voltage 3 */
67#define LM80_VT3_LOW_LIM 0x31 /* low limit val for Voltage 3 */
68#define LM80_VT4_HIGH_LIM 0x32 /* high limit val for Voltage 4 */
69#define LM80_VT4_LOW_LIM 0x33 /* low limit val for Voltage 4 */
70#define LM80_VT5_HIGH_LIM 0x34 /* high limit val for Voltage 5 */
71#define LM80_VT5_LOW_LIM 0x35 /* low limit val for Voltage 5 */
72#define LM80_VT6_HIGH_LIM 0x36 /* high limit val for Voltage 6 */
73#define LM80_VT6_LOW_LIM 0x37 /* low limit val for Voltage 6 */
74#define LM80_THOT_LIM_UP 0x38 /* hot temperature limit (high) */
75#define LM80_THOT_LIM_LO 0x39 /* hot temperature limit (low) */
76#define LM80_TOS_LIM_UP 0x3a /* OS temperature limit (high) */
77#define LM80_TOS_LIM_LO 0x3b /* OS temperature limit (low) */
78#define LM80_FAN1_COUNT_LIM 0x3c /* Fan 1 count limit (high) */
79#define LM80_FAN2_COUNT_LIM 0x3d /* Fan 2 count limit (low) */
80 /* 0x3e - 0x3f reserved */
81
82/*
83 * LM80 bit definitions
84 */
85
86/* LM80_CFG Configuration Register */
87#define LM80_CFG_START (1<<0) /* start monitoring operation */
88#define LM80_CFG_INT_ENA (1<<1) /* enables the INT# Interrupt output */
89#define LM80_CFG_INT_POL (1<<2) /* INT# pol: 0 act low, 1 act high */
90#define LM80_CFG_INT_CLR (1<<3) /* disables INT#/RST_OUT#/OS# outputs */
91#define LM80_CFG_RESET (1<<4) /* signals a reset */
92#define LM80_CFG_CHASS_CLR (1<<5) /* clears Chassis Intrusion (CI) pin */
93#define LM80_CFG_GPO (1<<6) /* drives the GPO# pin */
94#define LM80_CFG_INIT (1<<7) /* restore power on defaults */
95
96/* LM80_ISRC_1 Interrupt Status Register 1 */
97/* LM80_IMSK_1 Interrupt Mask Register 1 */
98#define LM80_IS_VT0 (1<<0) /* limit exceeded for Voltage 0 */
99#define LM80_IS_VT1 (1<<1) /* limit exceeded for Voltage 1 */
100#define LM80_IS_VT2 (1<<2) /* limit exceeded for Voltage 2 */
101#define LM80_IS_VT3 (1<<3) /* limit exceeded for Voltage 3 */
102#define LM80_IS_VT4 (1<<4) /* limit exceeded for Voltage 4 */
103#define LM80_IS_VT5 (1<<5) /* limit exceeded for Voltage 5 */
104#define LM80_IS_VT6 (1<<6) /* limit exceeded for Voltage 6 */
105#define LM80_IS_INT_IN (1<<7) /* state of INT_IN# */
106
107/* LM80_ISRC_2 Interrupt Status Register 2 */
108/* LM80_IMSK_2 Interrupt Mask Register 2 */
109#define LM80_IS_TEMP (1<<0) /* HOT temperature limit exceeded */
110#define LM80_IS_BTI (1<<1) /* state of BTI# pin */
111#define LM80_IS_FAN1 (1<<2) /* count limit exceeded for Fan 1 */
112#define LM80_IS_FAN2 (1<<3) /* count limit exceeded for Fan 2 */
113#define LM80_IS_CI (1<<4) /* Chassis Intrusion occured */
114#define LM80_IS_OS (1<<5) /* OS temperature limit exceeded */
115 /* bit 6 and 7 are reserved in LM80_ISRC_2 */
116#define LM80_IS_HT_IRQ_MD (1<<6) /* Hot temperature interrupt mode */
117#define LM80_IS_OT_IRQ_MD (1<<7) /* OS temperature interrupt mode */
118
119/* LM80_FAN_CTRL Fan Devisor/RST#/OS# Register */
120#define LM80_FAN1_MD_SEL (1<<0) /* Fan 1 mode select */
121#define LM80_FAN2_MD_SEL (1<<1) /* Fan 2 mode select */
122#define LM80_FAN1_PRM_CTL (3<<2) /* Fan 1 speed control */
123#define LM80_FAN2_PRM_CTL (3<<4) /* Fan 2 speed control */
124#define LM80_FAN_OS_ENA (1<<6) /* enable OS mode on RST_OUT#/OS# pins*/
125#define LM80_FAN_RST_ENA (1<<7) /* sets RST_OUT#/OS# pins in RST mode */
126
127/* LM80_TEMP_CTRL OS# Config, Temp Res. Reg */
128#define LM80_TEMP_OS_STAT (1<<0) /* mirrors the state of RST_OUT#/OS# */
129#define LM80_TEMP_OS_POL (1<<1) /* select OS# polarity */
130#define LM80_TEMP_OS_MODE (1<<2) /* selects Interrupt mode */
131#define LM80_TEMP_RES (1<<3) /* selects 9 or 11 bit temp resulution*/
132#define LM80_TEMP_LSB (0xf<<4)/* 4 LSBs of 11 bit temp data */
133#define LM80_TEMP_LSB_9 (1<<7) /* LSB of 9 bit temperature data */
134
135 /* 0x07 - 0x1f reserved */
136/* LM80_VT0_IN current Voltage 0 value */
137/* LM80_VT1_IN current Voltage 1 value */
138/* LM80_VT2_IN current Voltage 2 value */
139/* LM80_VT3_IN current Voltage 3 value */
140/* LM80_VT4_IN current Voltage 4 value */
141/* LM80_VT5_IN current Voltage 5 value */
142/* LM80_VT6_IN current Voltage 6 value */
143/* LM80_TEMP_IN current temperature value */
144/* LM80_FAN1_IN current Fan 1 count */
145/* LM80_FAN2_IN current Fan 2 count */
146/* LM80_VT0_HIGH_LIM high limit val for Voltage 0 */
147/* LM80_VT0_LOW_LIM low limit val for Voltage 0 */
148/* LM80_VT1_HIGH_LIM high limit val for Voltage 1 */
149/* LM80_VT1_LOW_LIM low limit val for Voltage 1 */
150/* LM80_VT2_HIGH_LIM high limit val for Voltage 2 */
151/* LM80_VT2_LOW_LIM low limit val for Voltage 2 */
152/* LM80_VT3_HIGH_LIM high limit val for Voltage 3 */
153/* LM80_VT3_LOW_LIM low limit val for Voltage 3 */
154/* LM80_VT4_HIGH_LIM high limit val for Voltage 4 */
155/* LM80_VT4_LOW_LIM low limit val for Voltage 4 */
156/* LM80_VT5_HIGH_LIM high limit val for Voltage 5 */
157/* LM80_VT5_LOW_LIM low limit val for Voltage 5 */
158/* LM80_VT6_HIGH_LIM high limit val for Voltage 6 */
159/* LM80_VT6_LOW_LIM low limit val for Voltage 6 */
160/* LM80_THOT_LIM_UP hot temperature limit (high) */
161/* LM80_THOT_LIM_LO hot temperature limit (low) */
162/* LM80_TOS_LIM_UP OS temperature limit (high) */
163/* LM80_TOS_LIM_LO OS temperature limit (low) */
164/* LM80_FAN1_COUNT_LIM Fan 1 count limit (high) */
165/* LM80_FAN2_COUNT_LIM Fan 2 count limit (low) */
166 /* 0x3e - 0x3f reserved */
167
168#define LM80_ADDR 0x28 /* LM80 default addr */
169
170/* typedefs *******************************************************************/
171
172
173/* function prototypes ********************************************************/
174
175#ifdef __cplusplus
176}
177#endif /* __cplusplus */
178
179#endif /* __INC_LM80_H */
diff --git a/drivers/net/sk98lin/h/skaddr.h b/drivers/net/sk98lin/h/skaddr.h
new file mode 100644
index 000000000000..423ad063d09b
--- /dev/null
+++ b/drivers/net/sk98lin/h/skaddr.h
@@ -0,0 +1,285 @@
1/******************************************************************************
2 *
3 * Name: skaddr.h
4 * Project: Gigabit Ethernet Adapters, ADDR-Modul
5 * Version: $Revision: 1.29 $
6 * Date: $Date: 2003/05/13 16:57:24 $
7 * Purpose: Header file for Address Management (MC, UC, Prom).
8 *
9 ******************************************************************************/
10
11/******************************************************************************
12 *
13 * (C)Copyright 1998-2002 SysKonnect GmbH.
14 * (C)Copyright 2002-2003 Marvell.
15 *
16 * This program is free software; you can redistribute it and/or modify
17 * it under the terms of the GNU General Public License as published by
18 * the Free Software Foundation; either version 2 of the License, or
19 * (at your option) any later version.
20 *
21 * The information in this file is provided "AS IS" without warranty.
22 *
23 ******************************************************************************/
24
25/******************************************************************************
26 *
27 * Description:
28 *
29 * This module is intended to manage multicast addresses and promiscuous mode
30 * on GEnesis adapters.
31 *
32 * Include File Hierarchy:
33 *
34 * "skdrv1st.h"
35 * ...
36 * "sktypes.h"
37 * "skqueue.h"
38 * "skaddr.h"
39 * ...
40 * "skdrv2nd.h"
41 *
42 ******************************************************************************/
43
44#ifndef __INC_SKADDR_H
45#define __INC_SKADDR_H
46
47#ifdef __cplusplus
48extern "C" {
49#endif /* cplusplus */
50
51/* defines ********************************************************************/
52
53#define SK_MAC_ADDR_LEN 6 /* Length of MAC address. */
54#define SK_MAX_ADDRS 14 /* #Addrs for exact match. */
55
56/* ----- Common return values ----- */
57
58#define SK_ADDR_SUCCESS 0 /* Function returned successfully. */
59#define SK_ADDR_ILLEGAL_PORT 100 /* Port number too high. */
60#define SK_ADDR_TOO_EARLY 101 /* Function called too early. */
61
62/* ----- Clear/Add flag bits ----- */
63
64#define SK_ADDR_PERMANENT 1 /* RLMT Address */
65
66/* ----- Additional Clear flag bits ----- */
67
68#define SK_MC_SW_ONLY 2 /* Do not update HW when clearing. */
69
70/* ----- Override flag bits ----- */
71
72#define SK_ADDR_LOGICAL_ADDRESS 0
73#define SK_ADDR_VIRTUAL_ADDRESS (SK_ADDR_LOGICAL_ADDRESS) /* old */
74#define SK_ADDR_PHYSICAL_ADDRESS 1
75#define SK_ADDR_CLEAR_LOGICAL 2
76#define SK_ADDR_SET_LOGICAL 4
77
78/* ----- Override return values ----- */
79
80#define SK_ADDR_OVERRIDE_SUCCESS (SK_ADDR_SUCCESS)
81#define SK_ADDR_DUPLICATE_ADDRESS 1
82#define SK_ADDR_MULTICAST_ADDRESS 2
83
84/* ----- Partitioning of excact match table ----- */
85
86#define SK_ADDR_EXACT_MATCHES 16 /* #Exact match entries. */
87
88#define SK_ADDR_FIRST_MATCH_RLMT 1
89#define SK_ADDR_LAST_MATCH_RLMT 2
90#define SK_ADDR_FIRST_MATCH_DRV 3
91#define SK_ADDR_LAST_MATCH_DRV (SK_ADDR_EXACT_MATCHES - 1)
92
93/* ----- SkAddrMcAdd/SkAddrMcUpdate return values ----- */
94
95#define SK_MC_FILTERING_EXACT 0 /* Exact filtering. */
96#define SK_MC_FILTERING_INEXACT 1 /* Inexact filtering. */
97
98/* ----- Additional SkAddrMcAdd return values ----- */
99
100#define SK_MC_ILLEGAL_ADDRESS 2 /* Illegal address. */
101#define SK_MC_ILLEGAL_PORT 3 /* Illegal port (not the active one). */
102#define SK_MC_RLMT_OVERFLOW 4 /* Too many RLMT mc addresses. */
103
104/* Promiscuous mode bits ----- */
105
106#define SK_PROM_MODE_NONE 0 /* Normal receive. */
107#define SK_PROM_MODE_LLC 1 /* Receive all LLC frames. */
108#define SK_PROM_MODE_ALL_MC 2 /* Receive all multicast frames. */
109/* #define SK_PROM_MODE_NON_LLC 4 */ /* Receive all non-LLC frames. */
110
111/* Macros */
112
113#ifdef OLD_STUFF
114#ifndef SK_ADDR_EQUAL
115/*
116 * "&" instead of "&&" allows better optimization on IA-64.
117 * The replacement is safe here, as all bytes exist.
118 */
119#ifndef SK_ADDR_DWORD_COMPARE
120#define SK_ADDR_EQUAL(A1,A2) ( \
121 (((SK_U8 *)(A1))[5] == ((SK_U8 *)(A2))[5]) & \
122 (((SK_U8 *)(A1))[4] == ((SK_U8 *)(A2))[4]) & \
123 (((SK_U8 *)(A1))[3] == ((SK_U8 *)(A2))[3]) & \
124 (((SK_U8 *)(A1))[2] == ((SK_U8 *)(A2))[2]) & \
125 (((SK_U8 *)(A1))[1] == ((SK_U8 *)(A2))[1]) & \
126 (((SK_U8 *)(A1))[0] == ((SK_U8 *)(A2))[0]))
127#else /* SK_ADDR_DWORD_COMPARE */
128#define SK_ADDR_EQUAL(A1,A2) ( \
129 (*(SK_U32 *)&(((SK_U8 *)(A1))[2]) == *(SK_U32 *)&(((SK_U8 *)(A2))[2])) & \
130 (*(SK_U32 *)&(((SK_U8 *)(A1))[0]) == *(SK_U32 *)&(((SK_U8 *)(A2))[0])))
131#endif /* SK_ADDR_DWORD_COMPARE */
132#endif /* SK_ADDR_EQUAL */
133#endif /* 0 */
134
135#ifndef SK_ADDR_EQUAL
136#ifndef SK_ADDR_DWORD_COMPARE
137#define SK_ADDR_EQUAL(A1,A2) ( \
138 (((SK_U8 SK_FAR *)(A1))[5] == ((SK_U8 SK_FAR *)(A2))[5]) & \
139 (((SK_U8 SK_FAR *)(A1))[4] == ((SK_U8 SK_FAR *)(A2))[4]) & \
140 (((SK_U8 SK_FAR *)(A1))[3] == ((SK_U8 SK_FAR *)(A2))[3]) & \
141 (((SK_U8 SK_FAR *)(A1))[2] == ((SK_U8 SK_FAR *)(A2))[2]) & \
142 (((SK_U8 SK_FAR *)(A1))[1] == ((SK_U8 SK_FAR *)(A2))[1]) & \
143 (((SK_U8 SK_FAR *)(A1))[0] == ((SK_U8 SK_FAR *)(A2))[0]))
144#else /* SK_ADDR_DWORD_COMPARE */
145#define SK_ADDR_EQUAL(A1,A2) ( \
146 (*(SK_U16 SK_FAR *)&(((SK_U8 SK_FAR *)(A1))[4]) == \
147 *(SK_U16 SK_FAR *)&(((SK_U8 SK_FAR *)(A2))[4])) && \
148 (*(SK_U32 SK_FAR *)&(((SK_U8 SK_FAR *)(A1))[0]) == \
149 *(SK_U32 SK_FAR *)&(((SK_U8 SK_FAR *)(A2))[0])))
150#endif /* SK_ADDR_DWORD_COMPARE */
151#endif /* SK_ADDR_EQUAL */
152
153/* typedefs *******************************************************************/
154
155typedef struct s_MacAddr {
156 SK_U8 a[SK_MAC_ADDR_LEN];
157} SK_MAC_ADDR;
158
159
160/* SK_FILTER is used to ensure alignment of the filter. */
161typedef union s_InexactFilter {
162 SK_U8 Bytes[8];
163 SK_U64 Val; /* Dummy entry for alignment only. */
164} SK_FILTER64;
165
166
167typedef struct s_AddrNet SK_ADDR_NET;
168
169
170typedef struct s_AddrPort {
171
172/* ----- Public part (read-only) ----- */
173
174 SK_MAC_ADDR CurrentMacAddress; /* Current physical MAC Address. */
175 SK_MAC_ADDR PermanentMacAddress; /* Permanent physical MAC Address. */
176 int PromMode; /* Promiscuous Mode. */
177
178/* ----- Private part ----- */
179
180 SK_MAC_ADDR PreviousMacAddress; /* Prev. phys. MAC Address. */
181 SK_BOOL CurrentMacAddressSet; /* CurrentMacAddress is set. */
182 SK_U8 Align01;
183
184 SK_U32 FirstExactMatchRlmt;
185 SK_U32 NextExactMatchRlmt;
186 SK_U32 FirstExactMatchDrv;
187 SK_U32 NextExactMatchDrv;
188 SK_MAC_ADDR Exact[SK_ADDR_EXACT_MATCHES];
189 SK_FILTER64 InexactFilter; /* For 64-bit hash register. */
190 SK_FILTER64 InexactRlmtFilter; /* For 64-bit hash register. */
191 SK_FILTER64 InexactDrvFilter; /* For 64-bit hash register. */
192} SK_ADDR_PORT;
193
194
195struct s_AddrNet {
196/* ----- Public part (read-only) ----- */
197
198 SK_MAC_ADDR CurrentMacAddress; /* Logical MAC Address. */
199 SK_MAC_ADDR PermanentMacAddress; /* Logical MAC Address. */
200
201/* ----- Private part ----- */
202
203 SK_U32 ActivePort; /* View of module ADDR. */
204 SK_BOOL CurrentMacAddressSet; /* CurrentMacAddress is set. */
205 SK_U8 Align01;
206 SK_U16 Align02;
207};
208
209
210typedef struct s_Addr {
211
212/* ----- Public part (read-only) ----- */
213
214 SK_ADDR_NET Net[SK_MAX_NETS];
215 SK_ADDR_PORT Port[SK_MAX_MACS];
216
217/* ----- Private part ----- */
218} SK_ADDR;
219
220/* function prototypes ********************************************************/
221
222#ifndef SK_KR_PROTO
223
224/* Functions provided by SkAddr */
225
226/* ANSI/C++ compliant function prototypes */
227
228extern int SkAddrInit(
229 SK_AC *pAC,
230 SK_IOC IoC,
231 int Level);
232
233extern int SkAddrMcClear(
234 SK_AC *pAC,
235 SK_IOC IoC,
236 SK_U32 PortNumber,
237 int Flags);
238
239extern int SkAddrMcAdd(
240 SK_AC *pAC,
241 SK_IOC IoC,
242 SK_U32 PortNumber,
243 SK_MAC_ADDR *pMc,
244 int Flags);
245
246extern int SkAddrMcUpdate(
247 SK_AC *pAC,
248 SK_IOC IoC,
249 SK_U32 PortNumber);
250
251extern int SkAddrOverride(
252 SK_AC *pAC,
253 SK_IOC IoC,
254 SK_U32 PortNumber,
255 SK_MAC_ADDR SK_FAR *pNewAddr,
256 int Flags);
257
258extern int SkAddrPromiscuousChange(
259 SK_AC *pAC,
260 SK_IOC IoC,
261 SK_U32 PortNumber,
262 int NewPromMode);
263
264#ifndef SK_SLIM
265extern int SkAddrSwap(
266 SK_AC *pAC,
267 SK_IOC IoC,
268 SK_U32 FromPortNumber,
269 SK_U32 ToPortNumber);
270#endif
271
272#else /* defined(SK_KR_PROTO)) */
273
274/* Non-ANSI/C++ compliant function prototypes */
275
276#error KR-style prototypes are not yet provided.
277
278#endif /* defined(SK_KR_PROTO)) */
279
280
281#ifdef __cplusplus
282}
283#endif /* __cplusplus */
284
285#endif /* __INC_SKADDR_H */
diff --git a/drivers/net/sk98lin/h/skcsum.h b/drivers/net/sk98lin/h/skcsum.h
new file mode 100644
index 000000000000..6e256bd9a28c
--- /dev/null
+++ b/drivers/net/sk98lin/h/skcsum.h
@@ -0,0 +1,213 @@
1/******************************************************************************
2 *
3 * Name: skcsum.h
4 * Project: GEnesis - SysKonnect SK-NET Gigabit Ethernet (SK-98xx)
5 * Version: $Revision: 1.10 $
6 * Date: $Date: 2003/08/20 13:59:57 $
7 * Purpose: Store/verify Internet checksum in send/receive packets.
8 *
9 ******************************************************************************/
10
11/******************************************************************************
12 *
13 * (C)Copyright 1998-2001 SysKonnect GmbH.
14 *
15 * This program is free software; you can redistribute it and/or modify
16 * it under the terms of the GNU General Public License as published by
17 * the Free Software Foundation; either version 2 of the License, or
18 * (at your option) any later version.
19 *
20 * The information in this file is provided "AS IS" without warranty.
21 *
22 ******************************************************************************/
23
24/******************************************************************************
25 *
26 * Description:
27 *
28 * Public header file for the "GEnesis" common module "CSUM".
29 *
30 * "GEnesis" is an abbreviation of "Gigabit Ethernet Network System in Silicon"
31 * and is the code name of this SysKonnect project.
32 *
33 * Compilation Options:
34 *
35 * SK_USE_CSUM - Define if CSUM is to be used. Otherwise, CSUM will be an
36 * empty module.
37 *
38 * SKCS_OVERWRITE_PROTO - Define to overwrite the default protocol id
39 * definitions. In this case, all SKCS_PROTO_xxx definitions must be made
40 * external.
41 *
42 * SKCS_OVERWRITE_STATUS - Define to overwrite the default return status
43 * definitions. In this case, all SKCS_STATUS_xxx definitions must be made
44 * external.
45 *
46 * Include File Hierarchy:
47 *
48 * "h/skcsum.h"
49 * "h/sktypes.h"
50 * "h/skqueue.h"
51 *
52 ******************************************************************************/
53
54#ifndef __INC_SKCSUM_H
55#define __INC_SKCSUM_H
56
57#include "h/sktypes.h"
58#include "h/skqueue.h"
59
60/* defines ********************************************************************/
61
62/*
63 * Define the default bit flags for 'SKCS_PACKET_INFO.ProtocolFlags' if no user
64 * overwrite.
65 */
66#ifndef SKCS_OVERWRITE_PROTO /* User overwrite? */
67#define SKCS_PROTO_IP 0x1 /* IP (Internet Protocol version 4) */
68#define SKCS_PROTO_TCP 0x2 /* TCP (Transmission Control Protocol) */
69#define SKCS_PROTO_UDP 0x4 /* UDP (User Datagram Protocol) */
70
71/* Indices for protocol statistics. */
72#define SKCS_PROTO_STATS_IP 0
73#define SKCS_PROTO_STATS_UDP 1
74#define SKCS_PROTO_STATS_TCP 2
75#define SKCS_NUM_PROTOCOLS 3 /* Number of supported protocols. */
76#endif /* !SKCS_OVERWRITE_PROTO */
77
78/*
79 * Define the default SKCS_STATUS type and values if no user overwrite.
80 *
81 * SKCS_STATUS_UNKNOWN_IP_VERSION - Not an IP v4 frame.
82 * SKCS_STATUS_IP_CSUM_ERROR - IP checksum error.
83 * SKCS_STATUS_IP_CSUM_ERROR_TCP - IP checksum error in TCP frame.
84 * SKCS_STATUS_IP_CSUM_ERROR_UDP - IP checksum error in UDP frame
85 * SKCS_STATUS_IP_FRAGMENT - IP fragment (IP checksum ok).
86 * SKCS_STATUS_IP_CSUM_OK - IP checksum ok (not a TCP or UDP frame).
87 * SKCS_STATUS_TCP_CSUM_ERROR - TCP checksum error (IP checksum ok).
88 * SKCS_STATUS_UDP_CSUM_ERROR - UDP checksum error (IP checksum ok).
89 * SKCS_STATUS_TCP_CSUM_OK - IP and TCP checksum ok.
90 * SKCS_STATUS_UDP_CSUM_OK - IP and UDP checksum ok.
91 * SKCS_STATUS_IP_CSUM_OK_NO_UDP - IP checksum OK and no UDP checksum.
92 */
93#ifndef SKCS_OVERWRITE_STATUS /* User overwrite? */
94#define SKCS_STATUS int /* Define status type. */
95
96#define SKCS_STATUS_UNKNOWN_IP_VERSION 1
97#define SKCS_STATUS_IP_CSUM_ERROR 2
98#define SKCS_STATUS_IP_FRAGMENT 3
99#define SKCS_STATUS_IP_CSUM_OK 4
100#define SKCS_STATUS_TCP_CSUM_ERROR 5
101#define SKCS_STATUS_UDP_CSUM_ERROR 6
102#define SKCS_STATUS_TCP_CSUM_OK 7
103#define SKCS_STATUS_UDP_CSUM_OK 8
104/* needed for Microsoft */
105#define SKCS_STATUS_IP_CSUM_ERROR_UDP 9
106#define SKCS_STATUS_IP_CSUM_ERROR_TCP 10
107/* UDP checksum may be omitted */
108#define SKCS_STATUS_IP_CSUM_OK_NO_UDP 11
109#endif /* !SKCS_OVERWRITE_STATUS */
110
111/* Clear protocol statistics event. */
112#define SK_CSUM_EVENT_CLEAR_PROTO_STATS 1
113
114/*
115 * Add two values in one's complement.
116 *
117 * Note: One of the two input values may be "longer" than 16-bit, but then the
118 * resulting sum may be 17 bits long. In this case, add zero to the result using
119 * SKCS_OC_ADD() again.
120 *
121 * Result = Value1 + Value2
122 */
123#define SKCS_OC_ADD(Result, Value1, Value2) { \
124 unsigned long Sum; \
125 \
126 Sum = (unsigned long) (Value1) + (unsigned long) (Value2); \
127 /* Add-in any carry. */ \
128 (Result) = (Sum & 0xffff) + (Sum >> 16); \
129}
130
131/*
132 * Subtract two values in one's complement.
133 *
134 * Result = Value1 - Value2
135 */
136#define SKCS_OC_SUB(Result, Value1, Value2) \
137 SKCS_OC_ADD((Result), (Value1), ~(Value2) & 0xffff)
138
139/* typedefs *******************************************************************/
140
141/*
142 * SKCS_PROTO_STATS - The CSUM protocol statistics structure.
143 *
144 * There is one instance of this structure for each protocol supported.
145 */
146typedef struct s_CsProtocolStatistics {
147 SK_U64 RxOkCts; /* Receive checksum ok. */
148 SK_U64 RxUnableCts; /* Unable to verify receive checksum. */
149 SK_U64 RxErrCts; /* Receive checksum error. */
150 SK_U64 TxOkCts; /* Transmit checksum ok. */
151 SK_U64 TxUnableCts; /* Unable to calculate checksum in hw. */
152} SKCS_PROTO_STATS;
153
154/*
155 * s_Csum - The CSUM module context structure.
156 */
157typedef struct s_Csum {
158 /* Enabled receive SK_PROTO_XXX bit flags. */
159 unsigned ReceiveFlags[SK_MAX_NETS];
160#ifdef TX_CSUM
161 unsigned TransmitFlags[SK_MAX_NETS];
162#endif /* TX_CSUM */
163
164 /* The protocol statistics structure; one per supported protocol. */
165 SKCS_PROTO_STATS ProtoStats[SK_MAX_NETS][SKCS_NUM_PROTOCOLS];
166} SK_CSUM;
167
168/*
169 * SKCS_PACKET_INFO - The packet information structure.
170 */
171typedef struct s_CsPacketInfo {
172 /* Bit field specifiying the desired/found protocols. */
173 unsigned ProtocolFlags;
174
175 /* Length of complete IP header, including any option fields. */
176 unsigned IpHeaderLength;
177
178 /* IP header checksum. */
179 unsigned IpHeaderChecksum;
180
181 /* TCP/UDP pseudo header checksum. */
182 unsigned PseudoHeaderChecksum;
183} SKCS_PACKET_INFO;
184
185/* function prototypes ********************************************************/
186
187#ifndef SK_CS_CALCULATE_CHECKSUM
188extern unsigned SkCsCalculateChecksum(
189 void *pData,
190 unsigned Length);
191#endif /* SK_CS_CALCULATE_CHECKSUM */
192
193extern int SkCsEvent(
194 SK_AC *pAc,
195 SK_IOC Ioc,
196 SK_U32 Event,
197 SK_EVPARA Param);
198
199extern SKCS_STATUS SkCsGetReceiveInfo(
200 SK_AC *pAc,
201 void *pIpHeader,
202 unsigned Checksum1,
203 unsigned Checksum2,
204 int NetNumber);
205
206extern void SkCsSetReceiveFlags(
207 SK_AC *pAc,
208 unsigned ReceiveFlags,
209 unsigned *pChecksum1Offset,
210 unsigned *pChecksum2Offset,
211 int NetNumber);
212
213#endif /* __INC_SKCSUM_H */
diff --git a/drivers/net/sk98lin/h/skdebug.h b/drivers/net/sk98lin/h/skdebug.h
new file mode 100644
index 000000000000..3cba171d74b2
--- /dev/null
+++ b/drivers/net/sk98lin/h/skdebug.h
@@ -0,0 +1,74 @@
1/******************************************************************************
2 *
3 * Name: skdebug.h
4 * Project: Gigabit Ethernet Adapters, Common Modules
5 * Version: $Revision: 1.14 $
6 * Date: $Date: 2003/05/13 17:26:00 $
7 * Purpose: SK specific DEBUG support
8 *
9 ******************************************************************************/
10
11/******************************************************************************
12 *
13 * (C)Copyright 1998-2002 SysKonnect.
14 * (C)Copyright 2002-2003 Marvell.
15 *
16 * This program is free software; you can redistribute it and/or modify
17 * it under the terms of the GNU General Public License as published by
18 * the Free Software Foundation; either version 2 of the License, or
19 * (at your option) any later version.
20 *
21 * The information in this file is provided "AS IS" without warranty.
22 *
23 ******************************************************************************/
24
25#ifndef __INC_SKDEBUG_H
26#define __INC_SKDEBUG_H
27
28#ifdef DEBUG
29#ifndef SK_DBG_MSG
30#define SK_DBG_MSG(pAC,comp,cat,arg) \
31 if ( ((comp) & SK_DBG_CHKMOD(pAC)) && \
32 ((cat) & SK_DBG_CHKCAT(pAC)) ) { \
33 SK_DBG_PRINTF arg ; \
34 }
35#endif
36#else
37#define SK_DBG_MSG(pAC,comp,lev,arg)
38#endif
39
40/* PLS NOTE:
41 * =========
42 * Due to any restrictions of kernel printf routines do not use other
43 * format identifiers as: %x %d %c %s .
44 * Never use any combined format identifiers such as: %lx %ld in your
45 * printf - argument (arg) because some OS specific kernel printfs may
46 * only support some basic identifiers.
47 */
48
49/* Debug modules */
50
51#define SK_DBGMOD_MERR 0x00000001L /* general module error indication */
52#define SK_DBGMOD_HWM 0x00000002L /* Hardware init module */
53#define SK_DBGMOD_RLMT 0x00000004L /* RLMT module */
54#define SK_DBGMOD_VPD 0x00000008L /* VPD module */
55#define SK_DBGMOD_I2C 0x00000010L /* I2C module */
56#define SK_DBGMOD_PNMI 0x00000020L /* PNMI module */
57#define SK_DBGMOD_CSUM 0x00000040L /* CSUM module */
58#define SK_DBGMOD_ADDR 0x00000080L /* ADDR module */
59#define SK_DBGMOD_PECP 0x00000100L /* PECP module */
60#define SK_DBGMOD_POWM 0x00000200L /* Power Management module */
61
62/* Debug events */
63
64#define SK_DBGCAT_INIT 0x00000001L /* module/driver initialization */
65#define SK_DBGCAT_CTRL 0x00000002L /* controlling devices */
66#define SK_DBGCAT_ERR 0x00000004L /* error handling paths */
67#define SK_DBGCAT_TX 0x00000008L /* transmit path */
68#define SK_DBGCAT_RX 0x00000010L /* receive path */
69#define SK_DBGCAT_IRQ 0x00000020L /* general IRQ handling */
70#define SK_DBGCAT_QUEUE 0x00000040L /* any queue management */
71#define SK_DBGCAT_DUMP 0x00000080L /* large data output e.g. hex dump */
72#define SK_DBGCAT_FATAL 0x00000100L /* fatal error */
73
74#endif /* __INC_SKDEBUG_H */
diff --git a/drivers/net/sk98lin/h/skdrv1st.h b/drivers/net/sk98lin/h/skdrv1st.h
new file mode 100644
index 000000000000..91b8d4f45904
--- /dev/null
+++ b/drivers/net/sk98lin/h/skdrv1st.h
@@ -0,0 +1,188 @@
1/******************************************************************************
2 *
3 * Name: skdrv1st.h
4 * Project: GEnesis, PCI Gigabit Ethernet Adapter
5 * Version: $Revision: 1.4 $
6 * Date: $Date: 2003/11/12 14:28:14 $
7 * Purpose: First header file for driver and all other modules
8 *
9 ******************************************************************************/
10
11/******************************************************************************
12 *
13 * (C)Copyright 1998-2002 SysKonnect GmbH.
14 * (C)Copyright 2002-2003 Marvell.
15 *
16 * This program is free software; you can redistribute it and/or modify
17 * it under the terms of the GNU General Public License as published by
18 * the Free Software Foundation; either version 2 of the License, or
19 * (at your option) any later version.
20 *
21 * The information in this file is provided "AS IS" without warranty.
22 *
23 ******************************************************************************/
24
25/******************************************************************************
26 *
27 * Description:
28 *
29 * This is the first include file of the driver, which includes all
30 * neccessary system header files and some of the GEnesis header files.
31 * It also defines some basic items.
32 *
33 * Include File Hierarchy:
34 *
35 * see skge.c
36 *
37 ******************************************************************************/
38
39#ifndef __INC_SKDRV1ST_H
40#define __INC_SKDRV1ST_H
41
42typedef struct s_AC SK_AC;
43
44/* Set card versions */
45#define SK_FAR
46
47/* override some default functions with optimized linux functions */
48
49#define SK_PNMI_STORE_U16(p,v) memcpy((char*)(p),(char*)&(v),2)
50#define SK_PNMI_STORE_U32(p,v) memcpy((char*)(p),(char*)&(v),4)
51#define SK_PNMI_STORE_U64(p,v) memcpy((char*)(p),(char*)&(v),8)
52#define SK_PNMI_READ_U16(p,v) memcpy((char*)&(v),(char*)(p),2)
53#define SK_PNMI_READ_U32(p,v) memcpy((char*)&(v),(char*)(p),4)
54#define SK_PNMI_READ_U64(p,v) memcpy((char*)&(v),(char*)(p),8)
55
56#define SK_ADDR_EQUAL(a1,a2) (!memcmp(a1,a2,6))
57
58#include <linux/types.h>
59#include <linux/kernel.h>
60#include <linux/string.h>
61#include <linux/errno.h>
62#include <linux/ioport.h>
63#include <linux/slab.h>
64#include <linux/interrupt.h>
65#include <linux/pci.h>
66#include <linux/bitops.h>
67#include <asm/byteorder.h>
68#include <asm/io.h>
69#include <asm/irq.h>
70#include <linux/netdevice.h>
71#include <linux/etherdevice.h>
72#include <linux/skbuff.h>
73
74#include <linux/init.h>
75#include <asm/uaccess.h>
76#include <net/checksum.h>
77
78#define SK_CS_CALCULATE_CHECKSUM
79#ifndef CONFIG_X86_64
80#define SkCsCalculateChecksum(p,l) ((~ip_compute_csum(p, l)) & 0xffff)
81#else
82#define SkCsCalculateChecksum(p,l) ((~ip_fast_csum(p, l)) & 0xffff)
83#endif
84
85#include "h/sktypes.h"
86#include "h/skerror.h"
87#include "h/skdebug.h"
88#include "h/lm80.h"
89#include "h/xmac_ii.h"
90
91#ifdef __LITTLE_ENDIAN
92#define SK_LITTLE_ENDIAN
93#else
94#define SK_BIG_ENDIAN
95#endif
96
97#define SK_NET_DEVICE net_device
98
99
100/* we use gethrtime(), return unit: nanoseconds */
101#define SK_TICKS_PER_SEC 100
102
103#define SK_MEM_MAPPED_IO
104
105// #define SK_RLMT_SLOW_LOOKAHEAD
106
107#define SK_MAX_MACS 2
108#define SK_MAX_NETS 2
109
110#define SK_IOC char __iomem *
111
112typedef struct s_DrvRlmtMbuf SK_MBUF;
113
114#define SK_CONST64 INT64_C
115#define SK_CONSTU64 UINT64_C
116
117#define SK_MEMCPY(dest,src,size) memcpy(dest,src,size)
118#define SK_MEMCMP(s1,s2,size) memcmp(s1,s2,size)
119#define SK_MEMSET(dest,val,size) memset(dest,val,size)
120#define SK_STRLEN(pStr) strlen((char*)(pStr))
121#define SK_STRNCPY(pDest,pSrc,size) strncpy((char*)(pDest),(char*)(pSrc),size)
122#define SK_STRCMP(pStr1,pStr2) strcmp((char*)(pStr1),(char*)(pStr2))
123
124/* macros to access the adapter */
125#define SK_OUT8(b,a,v) writeb((v), ((b)+(a)))
126#define SK_OUT16(b,a,v) writew((v), ((b)+(a)))
127#define SK_OUT32(b,a,v) writel((v), ((b)+(a)))
128#define SK_IN8(b,a,pv) (*(pv) = readb((b)+(a)))
129#define SK_IN16(b,a,pv) (*(pv) = readw((b)+(a)))
130#define SK_IN32(b,a,pv) (*(pv) = readl((b)+(a)))
131
132#define int8_t char
133#define int16_t short
134#define int32_t long
135#define int64_t long long
136#define uint8_t u_char
137#define uint16_t u_short
138#define uint32_t u_long
139#define uint64_t unsigned long long
140#define t_scalar_t int
141#define t_uscalar_t unsigned int
142#define uintptr_t unsigned long
143
144#define __CONCAT__(A,B) A##B
145
146#define INT32_C(a) __CONCAT__(a,L)
147#define INT64_C(a) __CONCAT__(a,LL)
148#define UINT32_C(a) __CONCAT__(a,UL)
149#define UINT64_C(a) __CONCAT__(a,ULL)
150
151#ifdef DEBUG
152#define SK_DBG_PRINTF printk
153#ifndef SK_DEBUG_CHKMOD
154#define SK_DEBUG_CHKMOD 0
155#endif
156#ifndef SK_DEBUG_CHKCAT
157#define SK_DEBUG_CHKCAT 0
158#endif
159/* those come from the makefile */
160#define SK_DBG_CHKMOD(pAC) (SK_DEBUG_CHKMOD)
161#define SK_DBG_CHKCAT(pAC) (SK_DEBUG_CHKCAT)
162
163extern void SkDbgPrintf(const char *format,...);
164
165#define SK_DBGMOD_DRV 0x00010000
166
167/**** possible driver debug categories ********************************/
168#define SK_DBGCAT_DRV_ENTRY 0x00010000
169#define SK_DBGCAT_DRV_SAP 0x00020000
170#define SK_DBGCAT_DRV_MCA 0x00040000
171#define SK_DBGCAT_DRV_TX_PROGRESS 0x00080000
172#define SK_DBGCAT_DRV_RX_PROGRESS 0x00100000
173#define SK_DBGCAT_DRV_PROGRESS 0x00200000
174#define SK_DBGCAT_DRV_MSG 0x00400000
175#define SK_DBGCAT_DRV_PROM 0x00800000
176#define SK_DBGCAT_DRV_TX_FRAME 0x01000000
177#define SK_DBGCAT_DRV_ERROR 0x02000000
178#define SK_DBGCAT_DRV_INT_SRC 0x04000000
179#define SK_DBGCAT_DRV_EVENT 0x08000000
180
181#endif
182
183#define SK_ERR_LOG SkErrorLog
184
185extern void SkErrorLog(SK_AC*, int, int, char*);
186
187#endif
188
diff --git a/drivers/net/sk98lin/h/skdrv2nd.h b/drivers/net/sk98lin/h/skdrv2nd.h
new file mode 100644
index 000000000000..3fa67171e832
--- /dev/null
+++ b/drivers/net/sk98lin/h/skdrv2nd.h
@@ -0,0 +1,447 @@
1/******************************************************************************
2 *
3 * Name: skdrv2nd.h
4 * Project: GEnesis, PCI Gigabit Ethernet Adapter
5 * Version: $Revision: 1.10 $
6 * Date: $Date: 2003/12/11 16:04:45 $
7 * Purpose: Second header file for driver and all other modules
8 *
9 ******************************************************************************/
10
11/******************************************************************************
12 *
13 * (C)Copyright 1998-2002 SysKonnect GmbH.
14 * (C)Copyright 2002-2003 Marvell.
15 *
16 * This program is free software; you can redistribute it and/or modify
17 * it under the terms of the GNU General Public License as published by
18 * the Free Software Foundation; either version 2 of the License, or
19 * (at your option) any later version.
20 *
21 * The information in this file is provided "AS IS" without warranty.
22 *
23 ******************************************************************************/
24
25/******************************************************************************
26 *
27 * Description:
28 *
29 * This is the second include file of the driver, which includes all other
30 * neccessary files and defines all structures and constants used by the
31 * driver and the common modules.
32 *
33 * Include File Hierarchy:
34 *
35 * see skge.c
36 *
37 ******************************************************************************/
38
39#ifndef __INC_SKDRV2ND_H
40#define __INC_SKDRV2ND_H
41
42#include "h/skqueue.h"
43#include "h/skgehwt.h"
44#include "h/sktimer.h"
45#include "h/ski2c.h"
46#include "h/skgepnmi.h"
47#include "h/skvpd.h"
48#include "h/skgehw.h"
49#include "h/skgeinit.h"
50#include "h/skaddr.h"
51#include "h/skgesirq.h"
52#include "h/skcsum.h"
53#include "h/skrlmt.h"
54#include "h/skgedrv.h"
55
56
57extern SK_MBUF *SkDrvAllocRlmtMbuf(SK_AC*, SK_IOC, unsigned);
58extern void SkDrvFreeRlmtMbuf(SK_AC*, SK_IOC, SK_MBUF*);
59extern SK_U64 SkOsGetTime(SK_AC*);
60extern int SkPciReadCfgDWord(SK_AC*, int, SK_U32*);
61extern int SkPciReadCfgWord(SK_AC*, int, SK_U16*);
62extern int SkPciReadCfgByte(SK_AC*, int, SK_U8*);
63extern int SkPciWriteCfgWord(SK_AC*, int, SK_U16);
64extern int SkPciWriteCfgByte(SK_AC*, int, SK_U8);
65extern int SkDrvEvent(SK_AC*, SK_IOC IoC, SK_U32, SK_EVPARA);
66
67#ifdef SK_DIAG_SUPPORT
68extern int SkDrvEnterDiagMode(SK_AC *pAc);
69extern int SkDrvLeaveDiagMode(SK_AC *pAc);
70#endif
71
72struct s_DrvRlmtMbuf {
73 SK_MBUF *pNext; /* Pointer to next RLMT Mbuf. */
74 SK_U8 *pData; /* Data buffer (virtually contig.). */
75 unsigned Size; /* Data buffer size. */
76 unsigned Length; /* Length of packet (<= Size). */
77 SK_U32 PortIdx; /* Receiving/transmitting port. */
78#ifdef SK_RLMT_MBUF_PRIVATE
79 SK_RLMT_MBUF Rlmt; /* Private part for RLMT. */
80#endif /* SK_RLMT_MBUF_PRIVATE */
81 struct sk_buff *pOs; /* Pointer to message block */
82};
83
84
85/*
86 * Time macros
87 */
88#if SK_TICKS_PER_SEC == 100
89#define SK_PNMI_HUNDREDS_SEC(t) (t)
90#else
91#define SK_PNMI_HUNDREDS_SEC(t) ((((unsigned long)t) * 100) / \
92 (SK_TICKS_PER_SEC))
93#endif
94
95/*
96 * New SkOsGetTime
97 */
98#define SkOsGetTimeCurrent(pAC, pUsec) {\
99 struct timeval t;\
100 do_gettimeofday(&t);\
101 *pUsec = ((((t.tv_sec) * 1000000L)+t.tv_usec)/10000);\
102}
103
104
105/*
106 * ioctl definitions
107 */
108#define SK_IOCTL_BASE (SIOCDEVPRIVATE)
109#define SK_IOCTL_GETMIB (SK_IOCTL_BASE + 0)
110#define SK_IOCTL_SETMIB (SK_IOCTL_BASE + 1)
111#define SK_IOCTL_PRESETMIB (SK_IOCTL_BASE + 2)
112#define SK_IOCTL_GEN (SK_IOCTL_BASE + 3)
113#define SK_IOCTL_DIAG (SK_IOCTL_BASE + 4)
114
115typedef struct s_IOCTL SK_GE_IOCTL;
116
117struct s_IOCTL {
118 char __user * pData;
119 unsigned int Len;
120};
121
122
123/*
124 * define sizes of descriptor rings in bytes
125 */
126
127#define TX_RING_SIZE (8*1024)
128#define RX_RING_SIZE (24*1024)
129
130/*
131 * Buffer size for ethernet packets
132 */
133#define ETH_BUF_SIZE 1540
134#define ETH_MAX_MTU 1514
135#define ETH_MIN_MTU 60
136#define ETH_MULTICAST_BIT 0x01
137#define SK_JUMBO_MTU 9000
138
139/*
140 * transmit priority selects the queue: LOW=asynchron, HIGH=synchron
141 */
142#define TX_PRIO_LOW 0
143#define TX_PRIO_HIGH 1
144
145/*
146 * alignment of rx/tx descriptors
147 */
148#define DESCR_ALIGN 64
149
150/*
151 * definitions for pnmi. TODO
152 */
153#define SK_DRIVER_RESET(pAC, IoC) 0
154#define SK_DRIVER_SENDEVENT(pAC, IoC) 0
155#define SK_DRIVER_SELFTEST(pAC, IoC) 0
156/* For get mtu you must add an own function */
157#define SK_DRIVER_GET_MTU(pAc,IoC,i) 0
158#define SK_DRIVER_SET_MTU(pAc,IoC,i,v) 0
159#define SK_DRIVER_PRESET_MTU(pAc,IoC,i,v) 0
160
161/*
162** Interim definition of SK_DRV_TIMER placed in this file until
163** common modules have been finalized
164*/
165#define SK_DRV_TIMER 11
166#define SK_DRV_MODERATION_TIMER 1
167#define SK_DRV_MODERATION_TIMER_LENGTH 1000000 /* 1 second */
168#define SK_DRV_RX_CLEANUP_TIMER 2
169#define SK_DRV_RX_CLEANUP_TIMER_LENGTH 1000000 /* 100 millisecs */
170
171/*
172** Definitions regarding transmitting frames
173** any calculating any checksum.
174*/
175#define C_LEN_ETHERMAC_HEADER_DEST_ADDR 6
176#define C_LEN_ETHERMAC_HEADER_SRC_ADDR 6
177#define C_LEN_ETHERMAC_HEADER_LENTYPE 2
178#define C_LEN_ETHERMAC_HEADER ( (C_LEN_ETHERMAC_HEADER_DEST_ADDR) + \
179 (C_LEN_ETHERMAC_HEADER_SRC_ADDR) + \
180 (C_LEN_ETHERMAC_HEADER_LENTYPE) )
181
182#define C_LEN_ETHERMTU_MINSIZE 46
183#define C_LEN_ETHERMTU_MAXSIZE_STD 1500
184#define C_LEN_ETHERMTU_MAXSIZE_JUMBO 9000
185
186#define C_LEN_ETHERNET_MINSIZE ( (C_LEN_ETHERMAC_HEADER) + \
187 (C_LEN_ETHERMTU_MINSIZE) )
188
189#define C_OFFSET_IPHEADER C_LEN_ETHERMAC_HEADER
190#define C_OFFSET_IPHEADER_IPPROTO 9
191#define C_OFFSET_TCPHEADER_TCPCS 16
192#define C_OFFSET_UDPHEADER_UDPCS 6
193
194#define C_OFFSET_IPPROTO ( (C_LEN_ETHERMAC_HEADER) + \
195 (C_OFFSET_IPHEADER_IPPROTO) )
196
197#define C_PROTO_ID_UDP 17 /* refer to RFC 790 or Stevens' */
198#define C_PROTO_ID_TCP 6 /* TCP/IP illustrated for details */
199
200/* TX and RX descriptors *****************************************************/
201
202typedef struct s_RxD RXD; /* the receive descriptor */
203
204struct s_RxD {
205 volatile SK_U32 RBControl; /* Receive Buffer Control */
206 SK_U32 VNextRxd; /* Next receive descriptor,low dword */
207 SK_U32 VDataLow; /* Receive buffer Addr, low dword */
208 SK_U32 VDataHigh; /* Receive buffer Addr, high dword */
209 SK_U32 FrameStat; /* Receive Frame Status word */
210 SK_U32 TimeStamp; /* Time stamp from XMAC */
211 SK_U32 TcpSums; /* TCP Sum 2 / TCP Sum 1 */
212 SK_U32 TcpSumStarts; /* TCP Sum Start 2 / TCP Sum Start 1 */
213 RXD *pNextRxd; /* Pointer to next Rxd */
214 struct sk_buff *pMBuf; /* Pointer to Linux' socket buffer */
215};
216
217typedef struct s_TxD TXD; /* the transmit descriptor */
218
219struct s_TxD {
220 volatile SK_U32 TBControl; /* Transmit Buffer Control */
221 SK_U32 VNextTxd; /* Next transmit descriptor,low dword */
222 SK_U32 VDataLow; /* Transmit Buffer Addr, low dword */
223 SK_U32 VDataHigh; /* Transmit Buffer Addr, high dword */
224 SK_U32 FrameStat; /* Transmit Frame Status Word */
225 SK_U32 TcpSumOfs; /* Reserved / TCP Sum Offset */
226 SK_U16 TcpSumSt; /* TCP Sum Start */
227 SK_U16 TcpSumWr; /* TCP Sum Write */
228 SK_U32 TcpReserved; /* not used */
229 TXD *pNextTxd; /* Pointer to next Txd */
230 struct sk_buff *pMBuf; /* Pointer to Linux' socket buffer */
231};
232
233/* Used interrupt bits in the interrupts source register *********************/
234
235#define DRIVER_IRQS ((IS_IRQ_SW) | \
236 (IS_R1_F) |(IS_R2_F) | \
237 (IS_XS1_F) |(IS_XA1_F) | \
238 (IS_XS2_F) |(IS_XA2_F))
239
240#define SPECIAL_IRQS ((IS_HW_ERR) |(IS_I2C_READY) | \
241 (IS_EXT_REG) |(IS_TIMINT) | \
242 (IS_PA_TO_RX1) |(IS_PA_TO_RX2) | \
243 (IS_PA_TO_TX1) |(IS_PA_TO_TX2) | \
244 (IS_MAC1) |(IS_LNK_SYNC_M1)| \
245 (IS_MAC2) |(IS_LNK_SYNC_M2)| \
246 (IS_R1_C) |(IS_R2_C) | \
247 (IS_XS1_C) |(IS_XA1_C) | \
248 (IS_XS2_C) |(IS_XA2_C))
249
250#define IRQ_MASK ((IS_IRQ_SW) | \
251 (IS_R1_B) |(IS_R1_F) |(IS_R2_B) |(IS_R2_F) | \
252 (IS_XS1_B) |(IS_XS1_F) |(IS_XA1_B)|(IS_XA1_F)| \
253 (IS_XS2_B) |(IS_XS2_F) |(IS_XA2_B)|(IS_XA2_F)| \
254 (IS_HW_ERR) |(IS_I2C_READY)| \
255 (IS_EXT_REG) |(IS_TIMINT) | \
256 (IS_PA_TO_RX1) |(IS_PA_TO_RX2)| \
257 (IS_PA_TO_TX1) |(IS_PA_TO_TX2)| \
258 (IS_MAC1) |(IS_MAC2) | \
259 (IS_R1_C) |(IS_R2_C) | \
260 (IS_XS1_C) |(IS_XA1_C) | \
261 (IS_XS2_C) |(IS_XA2_C))
262
263#define IRQ_HWE_MASK (IS_ERR_MSK) /* enable all HW irqs */
264
265typedef struct s_DevNet DEV_NET;
266
267struct s_DevNet {
268 int PortNr;
269 int NetNr;
270 SK_AC *pAC;
271};
272
273typedef struct s_TxPort TX_PORT;
274
275struct s_TxPort {
276 /* the transmit descriptor rings */
277 caddr_t pTxDescrRing; /* descriptor area memory */
278 SK_U64 VTxDescrRing; /* descr. area bus virt. addr. */
279 TXD *pTxdRingHead; /* Head of Tx rings */
280 TXD *pTxdRingTail; /* Tail of Tx rings */
281 TXD *pTxdRingPrev; /* descriptor sent previously */
282 int TxdRingFree; /* # of free entrys */
283 spinlock_t TxDesRingLock; /* serialize descriptor accesses */
284 SK_IOC HwAddr; /* bmu registers address */
285 int PortIndex; /* index number of port (0 or 1) */
286};
287
288typedef struct s_RxPort RX_PORT;
289
290struct s_RxPort {
291 /* the receive descriptor rings */
292 caddr_t pRxDescrRing; /* descriptor area memory */
293 SK_U64 VRxDescrRing; /* descr. area bus virt. addr. */
294 RXD *pRxdRingHead; /* Head of Rx rings */
295 RXD *pRxdRingTail; /* Tail of Rx rings */
296 RXD *pRxdRingPrev; /* descriptor given to BMU previously */
297 int RxdRingFree; /* # of free entrys */
298 int RxCsum; /* use receive checksum hardware */
299 spinlock_t RxDesRingLock; /* serialize descriptor accesses */
300 int RxFillLimit; /* limit for buffers in ring */
301 SK_IOC HwAddr; /* bmu registers address */
302 int PortIndex; /* index number of port (0 or 1) */
303};
304
305/* Definitions needed for interrupt moderation *******************************/
306
307#define IRQ_EOF_AS_TX ((IS_XA1_F) | (IS_XA2_F))
308#define IRQ_EOF_SY_TX ((IS_XS1_F) | (IS_XS2_F))
309#define IRQ_MASK_TX_ONLY ((IRQ_EOF_AS_TX)| (IRQ_EOF_SY_TX))
310#define IRQ_MASK_RX_ONLY ((IS_R1_F) | (IS_R2_F))
311#define IRQ_MASK_SP_ONLY (SPECIAL_IRQS)
312#define IRQ_MASK_TX_RX ((IRQ_MASK_TX_ONLY)| (IRQ_MASK_RX_ONLY))
313#define IRQ_MASK_SP_RX ((SPECIAL_IRQS) | (IRQ_MASK_RX_ONLY))
314#define IRQ_MASK_SP_TX ((SPECIAL_IRQS) | (IRQ_MASK_TX_ONLY))
315#define IRQ_MASK_RX_TX_SP ((SPECIAL_IRQS) | (IRQ_MASK_TX_RX))
316
317#define C_INT_MOD_NONE 1
318#define C_INT_MOD_STATIC 2
319#define C_INT_MOD_DYNAMIC 4
320
321#define C_CLK_FREQ_GENESIS 53215000 /* shorter: 53.125 MHz */
322#define C_CLK_FREQ_YUKON 78215000 /* shorter: 78.125 MHz */
323
324#define C_INTS_PER_SEC_DEFAULT 2000
325#define C_INT_MOD_ENABLE_PERCENTAGE 50 /* if higher 50% enable */
326#define C_INT_MOD_DISABLE_PERCENTAGE 50 /* if lower 50% disable */
327#define C_INT_MOD_IPS_LOWER_RANGE 30
328#define C_INT_MOD_IPS_UPPER_RANGE 40000
329
330
331typedef struct s_DynIrqModInfo DIM_INFO;
332struct s_DynIrqModInfo {
333 unsigned long PrevTimeVal;
334 unsigned int PrevSysLoad;
335 unsigned int PrevUsedTime;
336 unsigned int PrevTotalTime;
337 int PrevUsedDescrRatio;
338 int NbrProcessedDescr;
339 SK_U64 PrevPort0RxIntrCts;
340 SK_U64 PrevPort1RxIntrCts;
341 SK_U64 PrevPort0TxIntrCts;
342 SK_U64 PrevPort1TxIntrCts;
343 SK_BOOL ModJustEnabled; /* Moderation just enabled yes/no */
344
345 int MaxModIntsPerSec; /* Moderation Threshold */
346 int MaxModIntsPerSecUpperLimit; /* Upper limit for DIM */
347 int MaxModIntsPerSecLowerLimit; /* Lower limit for DIM */
348
349 long MaskIrqModeration; /* ModIrqType (eg. 'TxRx') */
350 SK_BOOL DisplayStats; /* Stats yes/no */
351 SK_BOOL AutoSizing; /* Resize DIM-timer on/off */
352 int IntModTypeSelect; /* EnableIntMod (eg. 'dynamic') */
353
354 SK_TIMER ModTimer; /* just some timer */
355};
356
357typedef struct s_PerStrm PER_STRM;
358
359#define SK_ALLOC_IRQ 0x00000001
360
361#ifdef SK_DIAG_SUPPORT
362#define DIAG_ACTIVE 1
363#define DIAG_NOTACTIVE 0
364#endif
365
366/****************************************************************************
367 * Per board structure / Adapter Context structure:
368 * Allocated within attach(9e) and freed within detach(9e).
369 * Contains all 'per device' necessary handles, flags, locks etc.:
370 */
371struct s_AC {
372 SK_GEINIT GIni; /* GE init struct */
373 SK_PNMI Pnmi; /* PNMI data struct */
374 SK_VPD vpd; /* vpd data struct */
375 SK_QUEUE Event; /* Event queue */
376 SK_HWT Hwt; /* Hardware Timer control struct */
377 SK_TIMCTRL Tim; /* Software Timer control struct */
378 SK_I2C I2c; /* I2C relevant data structure */
379 SK_ADDR Addr; /* for Address module */
380 SK_CSUM Csum; /* for checksum module */
381 SK_RLMT Rlmt; /* for rlmt module */
382 spinlock_t SlowPathLock; /* Normal IRQ lock */
383 struct timer_list BlinkTimer; /* for LED blinking */
384 int LedsOn;
385 SK_PNMI_STRUCT_DATA PnmiStruct; /* structure to get all Pnmi-Data */
386 int RlmtMode; /* link check mode to set */
387 int RlmtNets; /* Number of nets */
388
389 SK_IOC IoBase; /* register set of adapter */
390 int BoardLevel; /* level of active hw init (0-2) */
391
392 SK_U32 AllocFlag; /* flag allocation of resources */
393 struct pci_dev *PciDev; /* for access to pci config space */
394 struct SK_NET_DEVICE *dev[2]; /* pointer to device struct */
395
396 int RxBufSize; /* length of receive buffers */
397 struct net_device_stats stats; /* linux 'netstat -i' statistics */
398 int Index; /* internal board index number */
399
400 /* adapter RAM sizes for queues of active port */
401 int RxQueueSize; /* memory used for receive queue */
402 int TxSQueueSize; /* memory used for sync. tx queue */
403 int TxAQueueSize; /* memory used for async. tx queue */
404
405 int PromiscCount; /* promiscuous mode counter */
406 int AllMultiCount; /* allmulticast mode counter */
407 int MulticCount; /* number of different MC */
408 /* addresses for this board */
409 /* (may be more than HW can)*/
410
411 int HWRevision; /* Hardware revision */
412 int ActivePort; /* the active XMAC port */
413 int MaxPorts; /* number of activated ports */
414 int TxDescrPerRing; /* # of descriptors per tx ring */
415 int RxDescrPerRing; /* # of descriptors per rx ring */
416
417 caddr_t pDescrMem; /* Pointer to the descriptor area */
418 dma_addr_t pDescrMemDMA; /* PCI DMA address of area */
419
420 /* the port structures with descriptor rings */
421 TX_PORT TxPort[SK_MAX_MACS][2];
422 RX_PORT RxPort[SK_MAX_MACS];
423
424 SK_BOOL CheckQueue; /* check event queue soon */
425 SK_TIMER DrvCleanupTimer;/* to check for pending descriptors */
426 DIM_INFO DynIrqModInfo; /* all data related to DIM */
427
428 /* Only for tests */
429 int PortDown;
430 int ChipsetType; /* Chipset family type
431 * 0 == Genesis family support
432 * 1 == Yukon family support
433 */
434#ifdef SK_DIAG_SUPPORT
435 SK_U32 DiagModeActive; /* is diag active? */
436 SK_BOOL DiagFlowCtrl; /* for control purposes */
437 SK_PNMI_STRUCT_DATA PnmiBackup; /* backup structure for all Pnmi-Data */
438 SK_BOOL WasIfUp[SK_MAX_MACS]; /* for OpenClose while
439 * DIAG is busy with NIC
440 */
441#endif
442
443};
444
445
446#endif /* __INC_SKDRV2ND_H */
447
diff --git a/drivers/net/sk98lin/h/skerror.h b/drivers/net/sk98lin/h/skerror.h
new file mode 100644
index 000000000000..da062f766238
--- /dev/null
+++ b/drivers/net/sk98lin/h/skerror.h
@@ -0,0 +1,55 @@
1/******************************************************************************
2 *
3 * Name: skerror.h
4 * Project: Gigabit Ethernet Adapters, Common Modules
5 * Version: $Revision: 1.7 $
6 * Date: $Date: 2003/05/13 17:25:13 $
7 * Purpose: SK specific Error log support
8 *
9 ******************************************************************************/
10
11/******************************************************************************
12 *
13 * (C)Copyright 1998-2002 SysKonnect.
14 * (C)Copyright 2002-2003 Marvell.
15 *
16 * This program is free software; you can redistribute it and/or modify
17 * it under the terms of the GNU General Public License as published by
18 * the Free Software Foundation; either version 2 of the License, or
19 * (at your option) any later version.
20 *
21 * The information in this file is provided "AS IS" without warranty.
22 *
23 ******************************************************************************/
24
25#ifndef _INC_SKERROR_H_
26#define _INC_SKERROR_H_
27
28/*
29 * Define Error Classes
30 */
31#define SK_ERRCL_OTHER (0) /* Other error */
32#define SK_ERRCL_CONFIG (1L<<0) /* Configuration error */
33#define SK_ERRCL_INIT (1L<<1) /* Initialization error */
34#define SK_ERRCL_NORES (1L<<2) /* Out of Resources error */
35#define SK_ERRCL_SW (1L<<3) /* Internal Software error */
36#define SK_ERRCL_HW (1L<<4) /* Hardware Failure */
37#define SK_ERRCL_COMM (1L<<5) /* Communication error */
38
39
40/*
41 * Define Error Code Bases
42 */
43#define SK_ERRBASE_RLMT 100 /* Base Error number for RLMT */
44#define SK_ERRBASE_HWINIT 200 /* Base Error number for HWInit */
45#define SK_ERRBASE_VPD 300 /* Base Error number for VPD */
46#define SK_ERRBASE_PNMI 400 /* Base Error number for PNMI */
47#define SK_ERRBASE_CSUM 500 /* Base Error number for Checksum */
48#define SK_ERRBASE_SIRQ 600 /* Base Error number for Special IRQ */
49#define SK_ERRBASE_I2C 700 /* Base Error number for I2C module */
50#define SK_ERRBASE_QUEUE 800 /* Base Error number for Scheduler */
51#define SK_ERRBASE_ADDR 900 /* Base Error number for Address module */
52#define SK_ERRBASE_PECP 1000 /* Base Error number for PECP */
53#define SK_ERRBASE_DRV 1100 /* Base Error number for Driver */
54
55#endif /* _INC_SKERROR_H_ */
diff --git a/drivers/net/sk98lin/h/skgedrv.h b/drivers/net/sk98lin/h/skgedrv.h
new file mode 100644
index 000000000000..44fd4c3de818
--- /dev/null
+++ b/drivers/net/sk98lin/h/skgedrv.h
@@ -0,0 +1,51 @@
1/******************************************************************************
2 *
3 * Name: skgedrv.h
4 * Project: Gigabit Ethernet Adapters, Common Modules
5 * Version: $Revision: 1.10 $
6 * Date: $Date: 2003/07/04 12:25:01 $
7 * Purpose: Interface with the driver
8 *
9 ******************************************************************************/
10
11/******************************************************************************
12 *
13 * (C)Copyright 1998-2002 SysKonnect.
14 * (C)Copyright 2002-2003 Marvell.
15 *
16 * This program is free software; you can redistribute it and/or modify
17 * it under the terms of the GNU General Public License as published by
18 * the Free Software Foundation; either version 2 of the License, or
19 * (at your option) any later version.
20 *
21 * The information in this file is provided "AS IS" without warranty.
22 *
23 ******************************************************************************/
24
25#ifndef __INC_SKGEDRV_H_
26#define __INC_SKGEDRV_H_
27
28/* defines ********************************************************************/
29
30/*
31 * Define the driver events.
32 * Usually the events are defined by the destination module.
33 * In case of the driver we put the definition of the events here.
34 */
35#define SK_DRV_PORT_RESET 1 /* The port needs to be reset */
36#define SK_DRV_NET_UP 2 /* The net is operational */
37#define SK_DRV_NET_DOWN 3 /* The net is down */
38#define SK_DRV_SWITCH_SOFT 4 /* Ports switch with both links connected */
39#define SK_DRV_SWITCH_HARD 5 /* Port switch due to link failure */
40#define SK_DRV_RLMT_SEND 6 /* Send a RLMT packet */
41#define SK_DRV_ADAP_FAIL 7 /* The whole adapter fails */
42#define SK_DRV_PORT_FAIL 8 /* One port fails */
43#define SK_DRV_SWITCH_INTERN 9 /* Port switch by the driver itself */
44#define SK_DRV_POWER_DOWN 10 /* Power down mode */
45#define SK_DRV_TIMER 11 /* Timer for free use */
46#ifdef SK_NO_RLMT
47#define SK_DRV_LINK_UP 12 /* Link Up event for driver */
48#define SK_DRV_LINK_DOWN 13 /* Link Down event for driver */
49#endif
50#define SK_DRV_DOWNSHIFT_DET 14 /* Downshift 4-Pair / 2-Pair (YUKON only) */
51#endif /* __INC_SKGEDRV_H_ */
diff --git a/drivers/net/sk98lin/h/skgehw.h b/drivers/net/sk98lin/h/skgehw.h
new file mode 100644
index 000000000000..f6282b7956db
--- /dev/null
+++ b/drivers/net/sk98lin/h/skgehw.h
@@ -0,0 +1,2126 @@
1/******************************************************************************
2 *
3 * Name: skgehw.h
4 * Project: Gigabit Ethernet Adapters, Common Modules
5 * Version: $Revision: 1.56 $
6 * Date: $Date: 2003/09/23 09:01:00 $
7 * Purpose: Defines and Macros for the Gigabit Ethernet Adapter Product Family
8 *
9 ******************************************************************************/
10
11/******************************************************************************
12 *
13 * (C)Copyright 1998-2002 SysKonnect.
14 * (C)Copyright 2002-2003 Marvell.
15 *
16 * This program is free software; you can redistribute it and/or modify
17 * it under the terms of the GNU General Public License as published by
18 * the Free Software Foundation; either version 2 of the License, or
19 * (at your option) any later version.
20 *
21 * The information in this file is provided "AS IS" without warranty.
22 *
23 ******************************************************************************/
24
25#ifndef __INC_SKGEHW_H
26#define __INC_SKGEHW_H
27
28#ifdef __cplusplus
29extern "C" {
30#endif /* __cplusplus */
31
32/* defines ********************************************************************/
33
34#define BIT_31 (1UL << 31)
35#define BIT_30 (1L << 30)
36#define BIT_29 (1L << 29)
37#define BIT_28 (1L << 28)
38#define BIT_27 (1L << 27)
39#define BIT_26 (1L << 26)
40#define BIT_25 (1L << 25)
41#define BIT_24 (1L << 24)
42#define BIT_23 (1L << 23)
43#define BIT_22 (1L << 22)
44#define BIT_21 (1L << 21)
45#define BIT_20 (1L << 20)
46#define BIT_19 (1L << 19)
47#define BIT_18 (1L << 18)
48#define BIT_17 (1L << 17)
49#define BIT_16 (1L << 16)
50#define BIT_15 (1L << 15)
51#define BIT_14 (1L << 14)
52#define BIT_13 (1L << 13)
53#define BIT_12 (1L << 12)
54#define BIT_11 (1L << 11)
55#define BIT_10 (1L << 10)
56#define BIT_9 (1L << 9)
57#define BIT_8 (1L << 8)
58#define BIT_7 (1L << 7)
59#define BIT_6 (1L << 6)
60#define BIT_5 (1L << 5)
61#define BIT_4 (1L << 4)
62#define BIT_3 (1L << 3)
63#define BIT_2 (1L << 2)
64#define BIT_1 (1L << 1)
65#define BIT_0 1L
66
67#define BIT_15S (1U << 15)
68#define BIT_14S (1 << 14)
69#define BIT_13S (1 << 13)
70#define BIT_12S (1 << 12)
71#define BIT_11S (1 << 11)
72#define BIT_10S (1 << 10)
73#define BIT_9S (1 << 9)
74#define BIT_8S (1 << 8)
75#define BIT_7S (1 << 7)
76#define BIT_6S (1 << 6)
77#define BIT_5S (1 << 5)
78#define BIT_4S (1 << 4)
79#define BIT_3S (1 << 3)
80#define BIT_2S (1 << 2)
81#define BIT_1S (1 << 1)
82#define BIT_0S 1
83
84#define SHIFT31(x) ((x) << 31)
85#define SHIFT30(x) ((x) << 30)
86#define SHIFT29(x) ((x) << 29)
87#define SHIFT28(x) ((x) << 28)
88#define SHIFT27(x) ((x) << 27)
89#define SHIFT26(x) ((x) << 26)
90#define SHIFT25(x) ((x) << 25)
91#define SHIFT24(x) ((x) << 24)
92#define SHIFT23(x) ((x) << 23)
93#define SHIFT22(x) ((x) << 22)
94#define SHIFT21(x) ((x) << 21)
95#define SHIFT20(x) ((x) << 20)
96#define SHIFT19(x) ((x) << 19)
97#define SHIFT18(x) ((x) << 18)
98#define SHIFT17(x) ((x) << 17)
99#define SHIFT16(x) ((x) << 16)
100#define SHIFT15(x) ((x) << 15)
101#define SHIFT14(x) ((x) << 14)
102#define SHIFT13(x) ((x) << 13)
103#define SHIFT12(x) ((x) << 12)
104#define SHIFT11(x) ((x) << 11)
105#define SHIFT10(x) ((x) << 10)
106#define SHIFT9(x) ((x) << 9)
107#define SHIFT8(x) ((x) << 8)
108#define SHIFT7(x) ((x) << 7)
109#define SHIFT6(x) ((x) << 6)
110#define SHIFT5(x) ((x) << 5)
111#define SHIFT4(x) ((x) << 4)
112#define SHIFT3(x) ((x) << 3)
113#define SHIFT2(x) ((x) << 2)
114#define SHIFT1(x) ((x) << 1)
115#define SHIFT0(x) ((x) << 0)
116
117/*
118 * Configuration Space header
119 * Since this module is used for different OS', those may be
120 * duplicate on some of them (e.g. Linux). But to keep the
121 * common source, we have to live with this...
122 */
123#define PCI_VENDOR_ID 0x00 /* 16 bit Vendor ID */
124#define PCI_DEVICE_ID 0x02 /* 16 bit Device ID */
125#define PCI_COMMAND 0x04 /* 16 bit Command */
126#define PCI_STATUS 0x06 /* 16 bit Status */
127#define PCI_REV_ID 0x08 /* 8 bit Revision ID */
128#define PCI_CLASS_CODE 0x09 /* 24 bit Class Code */
129#define PCI_CACHE_LSZ 0x0c /* 8 bit Cache Line Size */
130#define PCI_LAT_TIM 0x0d /* 8 bit Latency Timer */
131#define PCI_HEADER_T 0x0e /* 8 bit Header Type */
132#define PCI_BIST 0x0f /* 8 bit Built-in selftest */
133#define PCI_BASE_1ST 0x10 /* 32 bit 1st Base address */
134#define PCI_BASE_2ND 0x14 /* 32 bit 2nd Base address */
135 /* Byte 0x18..0x2b: reserved */
136#define PCI_SUB_VID 0x2c /* 16 bit Subsystem Vendor ID */
137#define PCI_SUB_ID 0x2e /* 16 bit Subsystem ID */
138#define PCI_BASE_ROM 0x30 /* 32 bit Expansion ROM Base Address */
139#define PCI_CAP_PTR 0x34 /* 8 bit Capabilities Ptr */
140 /* Byte 0x35..0x3b: reserved */
141#define PCI_IRQ_LINE 0x3c /* 8 bit Interrupt Line */
142#define PCI_IRQ_PIN 0x3d /* 8 bit Interrupt Pin */
143#define PCI_MIN_GNT 0x3e /* 8 bit Min_Gnt */
144#define PCI_MAX_LAT 0x3f /* 8 bit Max_Lat */
145 /* Device Dependent Region */
146#define PCI_OUR_REG_1 0x40 /* 32 bit Our Register 1 */
147#define PCI_OUR_REG_2 0x44 /* 32 bit Our Register 2 */
148 /* Power Management Region */
149#define PCI_PM_CAP_ID 0x48 /* 8 bit Power Management Cap. ID */
150#define PCI_PM_NITEM 0x49 /* 8 bit Next Item Ptr */
151#define PCI_PM_CAP_REG 0x4a /* 16 bit Power Management Capabilities */
152#define PCI_PM_CTL_STS 0x4c /* 16 bit Power Manag. Control/Status */
153 /* Byte 0x4e: reserved */
154#define PCI_PM_DAT_REG 0x4f /* 8 bit Power Manag. Data Register */
155 /* VPD Region */
156#define PCI_VPD_CAP_ID 0x50 /* 8 bit VPD Cap. ID */
157#define PCI_VPD_NITEM 0x51 /* 8 bit Next Item Ptr */
158#define PCI_VPD_ADR_REG 0x52 /* 16 bit VPD Address Register */
159#define PCI_VPD_DAT_REG 0x54 /* 32 bit VPD Data Register */
160 /* Byte 0x58..0x59: reserved */
161#define PCI_SER_LD_CTRL 0x5a /* 16 bit SEEPROM Loader Ctrl (YUKON only) */
162 /* Byte 0x5c..0xff: reserved */
163
164/*
165 * I2C Address (PCI Config)
166 *
167 * Note: The temperature and voltage sensors are relocated on a different
168 * I2C bus.
169 */
170#define I2C_ADDR_VPD 0xa0 /* I2C address for the VPD EEPROM */
171
172/*
173 * Define Bits and Values of the registers
174 */
175/* PCI_COMMAND 16 bit Command */
176 /* Bit 15..11: reserved */
177#define PCI_INT_DIS BIT_10S /* Interrupt INTx# disable (PCI 2.3) */
178#define PCI_FBTEN BIT_9S /* Fast Back-To-Back enable */
179#define PCI_SERREN BIT_8S /* SERR enable */
180#define PCI_ADSTEP BIT_7S /* Address Stepping */
181#define PCI_PERREN BIT_6S /* Parity Report Response enable */
182#define PCI_VGA_SNOOP BIT_5S /* VGA palette snoop */
183#define PCI_MWIEN BIT_4S /* Memory write an inv cycl ena */
184#define PCI_SCYCEN BIT_3S /* Special Cycle enable */
185#define PCI_BMEN BIT_2S /* Bus Master enable */
186#define PCI_MEMEN BIT_1S /* Memory Space Access enable */
187#define PCI_IOEN BIT_0S /* I/O Space Access enable */
188
189#define PCI_COMMAND_VAL (PCI_FBTEN | PCI_SERREN | PCI_PERREN | PCI_MWIEN |\
190 PCI_BMEN | PCI_MEMEN | PCI_IOEN)
191
192/* PCI_STATUS 16 bit Status */
193#define PCI_PERR BIT_15S /* Parity Error */
194#define PCI_SERR BIT_14S /* Signaled SERR */
195#define PCI_RMABORT BIT_13S /* Received Master Abort */
196#define PCI_RTABORT BIT_12S /* Received Target Abort */
197 /* Bit 11: reserved */
198#define PCI_DEVSEL (3<<9) /* Bit 10.. 9: DEVSEL Timing */
199#define PCI_DEV_FAST (0<<9) /* fast */
200#define PCI_DEV_MEDIUM (1<<9) /* medium */
201#define PCI_DEV_SLOW (2<<9) /* slow */
202#define PCI_DATAPERR BIT_8S /* DATA Parity error detected */
203#define PCI_FB2BCAP BIT_7S /* Fast Back-to-Back Capability */
204#define PCI_UDF BIT_6S /* User Defined Features */
205#define PCI_66MHZCAP BIT_5S /* 66 MHz PCI bus clock capable */
206#define PCI_NEWCAP BIT_4S /* New cap. list implemented */
207#define PCI_INT_STAT BIT_3S /* Interrupt INTx# Status (PCI 2.3) */
208 /* Bit 2.. 0: reserved */
209
210#define PCI_ERRBITS (PCI_PERR | PCI_SERR | PCI_RMABORT | PCI_RTABORT |\
211 PCI_DATAPERR)
212
213/* PCI_CLASS_CODE 24 bit Class Code */
214/* Byte 2: Base Class (02) */
215/* Byte 1: SubClass (00) */
216/* Byte 0: Programming Interface (00) */
217
218/* PCI_CACHE_LSZ 8 bit Cache Line Size */
219/* Possible values: 0,2,4,8,16,32,64,128 */
220
221/* PCI_HEADER_T 8 bit Header Type */
222#define PCI_HD_MF_DEV BIT_7S /* 0= single, 1= multi-func dev */
223#define PCI_HD_TYPE 0x7f /* Bit 6..0: Header Layout 0= normal */
224
225/* PCI_BIST 8 bit Built-in selftest */
226/* Built-in Self test not supported (optional) */
227
228/* PCI_BASE_1ST 32 bit 1st Base address */
229#define PCI_MEMSIZE 0x4000L /* use 16 kB Memory Base */
230#define PCI_MEMBASE_MSK 0xffffc000L /* Bit 31..14: Memory Base Address */
231#define PCI_MEMSIZE_MSK 0x00003ff0L /* Bit 13.. 4: Memory Size Req. */
232#define PCI_PREFEN BIT_3 /* Prefetchable */
233#define PCI_MEM_TYP (3L<<2) /* Bit 2.. 1: Memory Type */
234#define PCI_MEM32BIT (0L<<1) /* Base addr anywhere in 32 Bit range */
235#define PCI_MEM1M (1L<<1) /* Base addr below 1 MegaByte */
236#define PCI_MEM64BIT (2L<<1) /* Base addr anywhere in 64 Bit range */
237#define PCI_MEMSPACE BIT_0 /* Memory Space Indicator */
238
239/* PCI_BASE_2ND 32 bit 2nd Base address */
240#define PCI_IOBASE 0xffffff00L /* Bit 31.. 8: I/O Base address */
241#define PCI_IOSIZE 0x000000fcL /* Bit 7.. 2: I/O Size Requirements */
242 /* Bit 1: reserved */
243#define PCI_IOSPACE BIT_0 /* I/O Space Indicator */
244
245/* PCI_BASE_ROM 32 bit Expansion ROM Base Address */
246#define PCI_ROMBASE_MSK 0xfffe0000L /* Bit 31..17: ROM Base address */
247#define PCI_ROMBASE_SIZ (0x1cL<<14) /* Bit 16..14: Treat as Base or Size */
248#define PCI_ROMSIZE (0x38L<<11) /* Bit 13..11: ROM Size Requirements */
249 /* Bit 10.. 1: reserved */
250#define PCI_ROMEN BIT_0 /* Address Decode enable */
251
252/* Device Dependent Region */
253/* PCI_OUR_REG_1 32 bit Our Register 1 */
254 /* Bit 31..29: reserved */
255#define PCI_PHY_COMA BIT_28 /* Set PHY to Coma Mode (YUKON only) */
256#define PCI_TEST_CAL BIT_27 /* Test PCI buffer calib. (YUKON only) */
257#define PCI_EN_CAL BIT_26 /* Enable PCI buffer calib. (YUKON only) */
258#define PCI_VIO BIT_25 /* PCI I/O Voltage, 0 = 3.3V, 1 = 5V */
259#define PCI_DIS_BOOT BIT_24 /* Disable BOOT via ROM */
260#define PCI_EN_IO BIT_23 /* Mapping to I/O space */
261#define PCI_EN_FPROM BIT_22 /* Enable FLASH mapping to memory */
262 /* 1 = Map Flash to memory */
263 /* 0 = Disable addr. dec */
264#define PCI_PAGESIZE (3L<<20) /* Bit 21..20: FLASH Page Size */
265#define PCI_PAGE_16 (0L<<20) /* 16 k pages */
266#define PCI_PAGE_32K (1L<<20) /* 32 k pages */
267#define PCI_PAGE_64K (2L<<20) /* 64 k pages */
268#define PCI_PAGE_128K (3L<<20) /* 128 k pages */
269 /* Bit 19: reserved */
270#define PCI_PAGEREG (7L<<16) /* Bit 18..16: Page Register */
271#define PCI_NOTAR BIT_15 /* No turnaround cycle */
272#define PCI_FORCE_BE BIT_14 /* Assert all BEs on MR */
273#define PCI_DIS_MRL BIT_13 /* Disable Mem Read Line */
274#define PCI_DIS_MRM BIT_12 /* Disable Mem Read Multiple */
275#define PCI_DIS_MWI BIT_11 /* Disable Mem Write & Invalidate */
276#define PCI_DISC_CLS BIT_10 /* Disc: cacheLsz bound */
277#define PCI_BURST_DIS BIT_9 /* Burst Disable */
278#define PCI_DIS_PCI_CLK BIT_8 /* Disable PCI clock driving */
279#define PCI_SKEW_DAS (0xfL<<4) /* Bit 7.. 4: Skew Ctrl, DAS Ext */
280#define PCI_SKEW_BASE 0xfL /* Bit 3.. 0: Skew Ctrl, Base */
281
282
283/* PCI_OUR_REG_2 32 bit Our Register 2 */
284#define PCI_VPD_WR_THR (0xffL<<24) /* Bit 31..24: VPD Write Threshold */
285#define PCI_DEV_SEL (0x7fL<<17) /* Bit 23..17: EEPROM Device Select */
286#define PCI_VPD_ROM_SZ (7L<<14) /* Bit 16..14: VPD ROM Size */
287 /* Bit 13..12: reserved */
288#define PCI_PATCH_DIR (0xfL<<8) /* Bit 11.. 8: Ext Patches dir 3..0 */
289#define PCI_PATCH_DIR_3 BIT_11
290#define PCI_PATCH_DIR_2 BIT_10
291#define PCI_PATCH_DIR_1 BIT_9
292#define PCI_PATCH_DIR_0 BIT_8
293#define PCI_EXT_PATCHS (0xfL<<4) /* Bit 7.. 4: Extended Patches 3..0 */
294#define PCI_EXT_PATCH_3 BIT_7
295#define PCI_EXT_PATCH_2 BIT_6
296#define PCI_EXT_PATCH_1 BIT_5
297#define PCI_EXT_PATCH_0 BIT_4
298#define PCI_EN_DUMMY_RD BIT_3 /* Enable Dummy Read */
299#define PCI_REV_DESC BIT_2 /* Reverse Desc. Bytes */
300 /* Bit 1: reserved */
301#define PCI_USEDATA64 BIT_0 /* Use 64Bit Data bus ext */
302
303
304/* Power Management Region */
305/* PCI_PM_CAP_REG 16 bit Power Management Capabilities */
306#define PCI_PME_SUP_MSK (0x1f<<11) /* Bit 15..11: PM Event Support Mask */
307#define PCI_PME_D3C_SUP BIT_15S /* PME from D3cold Support (if Vaux) */
308#define PCI_PME_D3H_SUP BIT_14S /* PME from D3hot Support */
309#define PCI_PME_D2_SUP BIT_13S /* PME from D2 Support */
310#define PCI_PME_D1_SUP BIT_12S /* PME from D1 Support */
311#define PCI_PME_D0_SUP BIT_11S /* PME from D0 Support */
312#define PCI_PM_D2_SUP BIT_10S /* D2 Support in 33 MHz mode */
313#define PCI_PM_D1_SUP BIT_9S /* D1 Support */
314 /* Bit 8.. 6: reserved */
315#define PCI_PM_DSI BIT_5S /* Device Specific Initialization */
316#define PCI_PM_APS BIT_4S /* Auxialiary Power Source */
317#define PCI_PME_CLOCK BIT_3S /* PM Event Clock */
318#define PCI_PM_VER_MSK 7 /* Bit 2.. 0: PM PCI Spec. version */
319
320/* PCI_PM_CTL_STS 16 bit Power Management Control/Status */
321#define PCI_PME_STATUS BIT_15S /* PME Status (YUKON only) */
322#define PCI_PM_DAT_SCL (3<<13) /* Bit 14..13: Data Reg. scaling factor */
323#define PCI_PM_DAT_SEL (0xf<<9) /* Bit 12.. 9: PM data selector field */
324#define PCI_PME_EN BIT_8S /* Enable PME# generation (YUKON only) */
325 /* Bit 7.. 2: reserved */
326#define PCI_PM_STATE_MSK 3 /* Bit 1.. 0: Power Management State */
327
328#define PCI_PM_STATE_D0 0 /* D0: Operational (default) */
329#define PCI_PM_STATE_D1 1 /* D1: (YUKON only) */
330#define PCI_PM_STATE_D2 2 /* D2: (YUKON only) */
331#define PCI_PM_STATE_D3 3 /* D3: HOT, Power Down and Reset */
332
333/* VPD Region */
334/* PCI_VPD_ADR_REG 16 bit VPD Address Register */
335#define PCI_VPD_FLAG BIT_15S /* starts VPD rd/wr cycle */
336#define PCI_VPD_ADR_MSK 0x7fffL /* Bit 14.. 0: VPD address mask */
337
338/* Control Register File (Address Map) */
339
340/*
341 * Bank 0
342 */
343#define B0_RAP 0x0000 /* 8 bit Register Address Port */
344 /* 0x0001 - 0x0003: reserved */
345#define B0_CTST 0x0004 /* 16 bit Control/Status register */
346#define B0_LED 0x0006 /* 8 Bit LED register */
347#define B0_POWER_CTRL 0x0007 /* 8 Bit Power Control reg (YUKON only) */
348#define B0_ISRC 0x0008 /* 32 bit Interrupt Source Register */
349#define B0_IMSK 0x000c /* 32 bit Interrupt Mask Register */
350#define B0_HWE_ISRC 0x0010 /* 32 bit HW Error Interrupt Src Reg */
351#define B0_HWE_IMSK 0x0014 /* 32 bit HW Error Interrupt Mask Reg */
352#define B0_SP_ISRC 0x0018 /* 32 bit Special Interrupt Source Reg */
353 /* 0x001c: reserved */
354
355/* B0 XMAC 1 registers (GENESIS only) */
356#define B0_XM1_IMSK 0x0020 /* 16 bit r/w XMAC 1 Interrupt Mask Register*/
357 /* 0x0022 - 0x0027: reserved */
358#define B0_XM1_ISRC 0x0028 /* 16 bit ro XMAC 1 Interrupt Status Reg */
359 /* 0x002a - 0x002f: reserved */
360#define B0_XM1_PHY_ADDR 0x0030 /* 16 bit r/w XMAC 1 PHY Address Register */
361 /* 0x0032 - 0x0033: reserved */
362#define B0_XM1_PHY_DATA 0x0034 /* 16 bit r/w XMAC 1 PHY Data Register */
363 /* 0x0036 - 0x003f: reserved */
364
365/* B0 XMAC 2 registers (GENESIS only) */
366#define B0_XM2_IMSK 0x0040 /* 16 bit r/w XMAC 2 Interrupt Mask Register*/
367 /* 0x0042 - 0x0047: reserved */
368#define B0_XM2_ISRC 0x0048 /* 16 bit ro XMAC 2 Interrupt Status Reg */
369 /* 0x004a - 0x004f: reserved */
370#define B0_XM2_PHY_ADDR 0x0050 /* 16 bit r/w XMAC 2 PHY Address Register */
371 /* 0x0052 - 0x0053: reserved */
372#define B0_XM2_PHY_DATA 0x0054 /* 16 bit r/w XMAC 2 PHY Data Register */
373 /* 0x0056 - 0x005f: reserved */
374
375/* BMU Control Status Registers */
376#define B0_R1_CSR 0x0060 /* 32 bit BMU Ctrl/Stat Rx Queue 1 */
377#define B0_R2_CSR 0x0064 /* 32 bit BMU Ctrl/Stat Rx Queue 2 */
378#define B0_XS1_CSR 0x0068 /* 32 bit BMU Ctrl/Stat Sync Tx Queue 1 */
379#define B0_XA1_CSR 0x006c /* 32 bit BMU Ctrl/Stat Async Tx Queue 1*/
380#define B0_XS2_CSR 0x0070 /* 32 bit BMU Ctrl/Stat Sync Tx Queue 2 */
381#define B0_XA2_CSR 0x0074 /* 32 bit BMU Ctrl/Stat Async Tx Queue 2*/
382 /* 0x0078 - 0x007f: reserved */
383
384/*
385 * Bank 1
386 * - completely empty (this is the RAP Block window)
387 * Note: if RAP = 1 this page is reserved
388 */
389
390/*
391 * Bank 2
392 */
393/* NA reg = 48 bit Network Address Register, 3x16 or 8x8 bit readable */
394#define B2_MAC_1 0x0100 /* NA reg MAC Address 1 */
395 /* 0x0106 - 0x0107: reserved */
396#define B2_MAC_2 0x0108 /* NA reg MAC Address 2 */
397 /* 0x010e - 0x010f: reserved */
398#define B2_MAC_3 0x0110 /* NA reg MAC Address 3 */
399 /* 0x0116 - 0x0117: reserved */
400#define B2_CONN_TYP 0x0118 /* 8 bit Connector type */
401#define B2_PMD_TYP 0x0119 /* 8 bit PMD type */
402#define B2_MAC_CFG 0x011a /* 8 bit MAC Configuration / Chip Revision */
403#define B2_CHIP_ID 0x011b /* 8 bit Chip Identification Number */
404 /* Eprom registers are currently of no use */
405#define B2_E_0 0x011c /* 8 bit EPROM Byte 0 (ext. SRAM size */
406#define B2_E_1 0x011d /* 8 bit EPROM Byte 1 (PHY type) */
407#define B2_E_2 0x011e /* 8 bit EPROM Byte 2 */
408#define B2_E_3 0x011f /* 8 bit EPROM Byte 3 */
409#define B2_FAR 0x0120 /* 32 bit Flash-Prom Addr Reg/Cnt */
410#define B2_FDP 0x0124 /* 8 bit Flash-Prom Data Port */
411 /* 0x0125 - 0x0127: reserved */
412#define B2_LD_CTRL 0x0128 /* 8 bit EPROM loader control register */
413#define B2_LD_TEST 0x0129 /* 8 bit EPROM loader test register */
414 /* 0x012a - 0x012f: reserved */
415#define B2_TI_INI 0x0130 /* 32 bit Timer Init Value */
416#define B2_TI_VAL 0x0134 /* 32 bit Timer Value */
417#define B2_TI_CTRL 0x0138 /* 8 bit Timer Control */
418#define B2_TI_TEST 0x0139 /* 8 Bit Timer Test */
419 /* 0x013a - 0x013f: reserved */
420#define B2_IRQM_INI 0x0140 /* 32 bit IRQ Moderation Timer Init Reg.*/
421#define B2_IRQM_VAL 0x0144 /* 32 bit IRQ Moderation Timer Value */
422#define B2_IRQM_CTRL 0x0148 /* 8 bit IRQ Moderation Timer Control */
423#define B2_IRQM_TEST 0x0149 /* 8 bit IRQ Moderation Timer Test */
424#define B2_IRQM_MSK 0x014c /* 32 bit IRQ Moderation Mask */
425#define B2_IRQM_HWE_MSK 0x0150 /* 32 bit IRQ Moderation HW Error Mask */
426 /* 0x0154 - 0x0157: reserved */
427#define B2_TST_CTRL1 0x0158 /* 8 bit Test Control Register 1 */
428#define B2_TST_CTRL2 0x0159 /* 8 bit Test Control Register 2 */
429 /* 0x015a - 0x015b: reserved */
430#define B2_GP_IO 0x015c /* 32 bit General Purpose I/O Register */
431#define B2_I2C_CTRL 0x0160 /* 32 bit I2C HW Control Register */
432#define B2_I2C_DATA 0x0164 /* 32 bit I2C HW Data Register */
433#define B2_I2C_IRQ 0x0168 /* 32 bit I2C HW IRQ Register */
434#define B2_I2C_SW 0x016c /* 32 bit I2C SW Port Register */
435
436/* Blink Source Counter (GENESIS only) */
437#define B2_BSC_INI 0x0170 /* 32 bit Blink Source Counter Init Val */
438#define B2_BSC_VAL 0x0174 /* 32 bit Blink Source Counter Value */
439#define B2_BSC_CTRL 0x0178 /* 8 bit Blink Source Counter Control */
440#define B2_BSC_STAT 0x0179 /* 8 bit Blink Source Counter Status */
441#define B2_BSC_TST 0x017a /* 16 bit Blink Source Counter Test Reg */
442 /* 0x017c - 0x017f: reserved */
443
444/*
445 * Bank 3
446 */
447/* RAM Random Registers */
448#define B3_RAM_ADDR 0x0180 /* 32 bit RAM Address, to read or write */
449#define B3_RAM_DATA_LO 0x0184 /* 32 bit RAM Data Word (low dWord) */
450#define B3_RAM_DATA_HI 0x0188 /* 32 bit RAM Data Word (high dWord) */
451 /* 0x018c - 0x018f: reserved */
452
453/* RAM Interface Registers */
454/*
455 * The HW-Spec. calls this registers Timeout Value 0..11. But this names are
456 * not usable in SW. Please notice these are NOT real timeouts, these are
457 * the number of qWords transferred continuously.
458 */
459#define B3_RI_WTO_R1 0x0190 /* 8 bit WR Timeout Queue R1 (TO0) */
460#define B3_RI_WTO_XA1 0x0191 /* 8 bit WR Timeout Queue XA1 (TO1) */
461#define B3_RI_WTO_XS1 0x0192 /* 8 bit WR Timeout Queue XS1 (TO2) */
462#define B3_RI_RTO_R1 0x0193 /* 8 bit RD Timeout Queue R1 (TO3) */
463#define B3_RI_RTO_XA1 0x0194 /* 8 bit RD Timeout Queue XA1 (TO4) */
464#define B3_RI_RTO_XS1 0x0195 /* 8 bit RD Timeout Queue XS1 (TO5) */
465#define B3_RI_WTO_R2 0x0196 /* 8 bit WR Timeout Queue R2 (TO6) */
466#define B3_RI_WTO_XA2 0x0197 /* 8 bit WR Timeout Queue XA2 (TO7) */
467#define B3_RI_WTO_XS2 0x0198 /* 8 bit WR Timeout Queue XS2 (TO8) */
468#define B3_RI_RTO_R2 0x0199 /* 8 bit RD Timeout Queue R2 (TO9) */
469#define B3_RI_RTO_XA2 0x019a /* 8 bit RD Timeout Queue XA2 (TO10)*/
470#define B3_RI_RTO_XS2 0x019b /* 8 bit RD Timeout Queue XS2 (TO11)*/
471#define B3_RI_TO_VAL 0x019c /* 8 bit Current Timeout Count Val */
472 /* 0x019d - 0x019f: reserved */
473#define B3_RI_CTRL 0x01a0 /* 16 bit RAM Interface Control Register */
474#define B3_RI_TEST 0x01a2 /* 8 bit RAM Interface Test Register */
475 /* 0x01a3 - 0x01af: reserved */
476
477/* MAC Arbiter Registers (GENESIS only) */
478/* these are the no. of qWord transferred continuously and NOT real timeouts */
479#define B3_MA_TOINI_RX1 0x01b0 /* 8 bit Timeout Init Val Rx Path MAC 1 */
480#define B3_MA_TOINI_RX2 0x01b1 /* 8 bit Timeout Init Val Rx Path MAC 2 */
481#define B3_MA_TOINI_TX1 0x01b2 /* 8 bit Timeout Init Val Tx Path MAC 1 */
482#define B3_MA_TOINI_TX2 0x01b3 /* 8 bit Timeout Init Val Tx Path MAC 2 */
483#define B3_MA_TOVAL_RX1 0x01b4 /* 8 bit Timeout Value Rx Path MAC 1 */
484#define B3_MA_TOVAL_RX2 0x01b5 /* 8 bit Timeout Value Rx Path MAC 1 */
485#define B3_MA_TOVAL_TX1 0x01b6 /* 8 bit Timeout Value Tx Path MAC 2 */
486#define B3_MA_TOVAL_TX2 0x01b7 /* 8 bit Timeout Value Tx Path MAC 2 */
487#define B3_MA_TO_CTRL 0x01b8 /* 16 bit MAC Arbiter Timeout Ctrl Reg */
488#define B3_MA_TO_TEST 0x01ba /* 16 bit MAC Arbiter Timeout Test Reg */
489 /* 0x01bc - 0x01bf: reserved */
490#define B3_MA_RCINI_RX1 0x01c0 /* 8 bit Recovery Init Val Rx Path MAC 1 */
491#define B3_MA_RCINI_RX2 0x01c1 /* 8 bit Recovery Init Val Rx Path MAC 2 */
492#define B3_MA_RCINI_TX1 0x01c2 /* 8 bit Recovery Init Val Tx Path MAC 1 */
493#define B3_MA_RCINI_TX2 0x01c3 /* 8 bit Recovery Init Val Tx Path MAC 2 */
494#define B3_MA_RCVAL_RX1 0x01c4 /* 8 bit Recovery Value Rx Path MAC 1 */
495#define B3_MA_RCVAL_RX2 0x01c5 /* 8 bit Recovery Value Rx Path MAC 1 */
496#define B3_MA_RCVAL_TX1 0x01c6 /* 8 bit Recovery Value Tx Path MAC 2 */
497#define B3_MA_RCVAL_TX2 0x01c7 /* 8 bit Recovery Value Tx Path MAC 2 */
498#define B3_MA_RC_CTRL 0x01c8 /* 16 bit MAC Arbiter Recovery Ctrl Reg */
499#define B3_MA_RC_TEST 0x01ca /* 16 bit MAC Arbiter Recovery Test Reg */
500 /* 0x01cc - 0x01cf: reserved */
501
502/* Packet Arbiter Registers (GENESIS only) */
503/* these are real timeouts */
504#define B3_PA_TOINI_RX1 0x01d0 /* 16 bit Timeout Init Val Rx Path MAC 1 */
505 /* 0x01d2 - 0x01d3: reserved */
506#define B3_PA_TOINI_RX2 0x01d4 /* 16 bit Timeout Init Val Rx Path MAC 2 */
507 /* 0x01d6 - 0x01d7: reserved */
508#define B3_PA_TOINI_TX1 0x01d8 /* 16 bit Timeout Init Val Tx Path MAC 1 */
509 /* 0x01da - 0x01db: reserved */
510#define B3_PA_TOINI_TX2 0x01dc /* 16 bit Timeout Init Val Tx Path MAC 2 */
511 /* 0x01de - 0x01df: reserved */
512#define B3_PA_TOVAL_RX1 0x01e0 /* 16 bit Timeout Val Rx Path MAC 1 */
513 /* 0x01e2 - 0x01e3: reserved */
514#define B3_PA_TOVAL_RX2 0x01e4 /* 16 bit Timeout Val Rx Path MAC 2 */
515 /* 0x01e6 - 0x01e7: reserved */
516#define B3_PA_TOVAL_TX1 0x01e8 /* 16 bit Timeout Val Tx Path MAC 1 */
517 /* 0x01ea - 0x01eb: reserved */
518#define B3_PA_TOVAL_TX2 0x01ec /* 16 bit Timeout Val Tx Path MAC 2 */
519 /* 0x01ee - 0x01ef: reserved */
520#define B3_PA_CTRL 0x01f0 /* 16 bit Packet Arbiter Ctrl Register */
521#define B3_PA_TEST 0x01f2 /* 16 bit Packet Arbiter Test Register */
522 /* 0x01f4 - 0x01ff: reserved */
523
524/*
525 * Bank 4 - 5
526 */
527/* Transmit Arbiter Registers MAC 1 and 2, use MR_ADDR() to access */
528#define TXA_ITI_INI 0x0200 /* 32 bit Tx Arb Interval Timer Init Val*/
529#define TXA_ITI_VAL 0x0204 /* 32 bit Tx Arb Interval Timer Value */
530#define TXA_LIM_INI 0x0208 /* 32 bit Tx Arb Limit Counter Init Val */
531#define TXA_LIM_VAL 0x020c /* 32 bit Tx Arb Limit Counter Value */
532#define TXA_CTRL 0x0210 /* 8 bit Tx Arbiter Control Register */
533#define TXA_TEST 0x0211 /* 8 bit Tx Arbiter Test Register */
534#define TXA_STAT 0x0212 /* 8 bit Tx Arbiter Status Register */
535 /* 0x0213 - 0x027f: reserved */
536 /* 0x0280 - 0x0292: MAC 2 */
537 /* 0x0213 - 0x027f: reserved */
538
539/*
540 * Bank 6
541 */
542/* External registers (GENESIS only) */
543#define B6_EXT_REG 0x0300
544
545/*
546 * Bank 7
547 */
548/* This is a copy of the Configuration register file (lower half) */
549#define B7_CFG_SPC 0x0380
550
551/*
552 * Bank 8 - 15
553 */
554/* Receive and Transmit Queue Registers, use Q_ADDR() to access */
555#define B8_Q_REGS 0x0400
556
557/* Queue Register Offsets, use Q_ADDR() to access */
558#define Q_D 0x00 /* 8*32 bit Current Descriptor */
559#define Q_DA_L 0x20 /* 32 bit Current Descriptor Address Low dWord */
560#define Q_DA_H 0x24 /* 32 bit Current Descriptor Address High dWord */
561#define Q_AC_L 0x28 /* 32 bit Current Address Counter Low dWord */
562#define Q_AC_H 0x2c /* 32 bit Current Address Counter High dWord */
563#define Q_BC 0x30 /* 32 bit Current Byte Counter */
564#define Q_CSR 0x34 /* 32 bit BMU Control/Status Register */
565#define Q_F 0x38 /* 32 bit Flag Register */
566#define Q_T1 0x3c /* 32 bit Test Register 1 */
567#define Q_T1_TR 0x3c /* 8 bit Test Register 1 Transfer SM */
568#define Q_T1_WR 0x3d /* 8 bit Test Register 1 Write Descriptor SM */
569#define Q_T1_RD 0x3e /* 8 bit Test Register 1 Read Descriptor SM */
570#define Q_T1_SV 0x3f /* 8 bit Test Register 1 Supervisor SM */
571#define Q_T2 0x40 /* 32 bit Test Register 2 */
572#define Q_T3 0x44 /* 32 bit Test Register 3 */
573 /* 0x48 - 0x7f: reserved */
574
575/*
576 * Bank 16 - 23
577 */
578/* RAM Buffer Registers */
579#define B16_RAM_REGS 0x0800
580
581/* RAM Buffer Register Offsets, use RB_ADDR() to access */
582#define RB_START 0x00 /* 32 bit RAM Buffer Start Address */
583#define RB_END 0x04 /* 32 bit RAM Buffer End Address */
584#define RB_WP 0x08 /* 32 bit RAM Buffer Write Pointer */
585#define RB_RP 0x0c /* 32 bit RAM Buffer Read Pointer */
586#define RB_RX_UTPP 0x10 /* 32 bit Rx Upper Threshold, Pause Pack */
587#define RB_RX_LTPP 0x14 /* 32 bit Rx Lower Threshold, Pause Pack */
588#define RB_RX_UTHP 0x18 /* 32 bit Rx Upper Threshold, High Prio */
589#define RB_RX_LTHP 0x1c /* 32 bit Rx Lower Threshold, High Prio */
590 /* 0x10 - 0x1f: reserved at Tx RAM Buffer Registers */
591#define RB_PC 0x20 /* 32 bit RAM Buffer Packet Counter */
592#define RB_LEV 0x24 /* 32 bit RAM Buffer Level Register */
593#define RB_CTRL 0x28 /* 8 bit RAM Buffer Control Register */
594#define RB_TST1 0x29 /* 8 bit RAM Buffer Test Register 1 */
595#define RB_TST2 0x2A /* 8 bit RAM Buffer Test Register 2 */
596 /* 0x2c - 0x7f: reserved */
597
598/*
599 * Bank 24
600 */
601/*
602 * Receive MAC FIFO, Receive LED, and Link_Sync regs (GENESIS only)
603 * use MR_ADDR() to access
604 */
605#define RX_MFF_EA 0x0c00 /* 32 bit Receive MAC FIFO End Address */
606#define RX_MFF_WP 0x0c04 /* 32 bit Receive MAC FIFO Write Pointer */
607 /* 0x0c08 - 0x0c0b: reserved */
608#define RX_MFF_RP 0x0c0c /* 32 bit Receive MAC FIFO Read Pointer */
609#define RX_MFF_PC 0x0c10 /* 32 bit Receive MAC FIFO Packet Cnt */
610#define RX_MFF_LEV 0x0c14 /* 32 bit Receive MAC FIFO Level */
611#define RX_MFF_CTRL1 0x0c18 /* 16 bit Receive MAC FIFO Control Reg 1*/
612#define RX_MFF_STAT_TO 0x0c1a /* 8 bit Receive MAC Status Timeout */
613#define RX_MFF_TIST_TO 0x0c1b /* 8 bit Receive MAC Time Stamp Timeout */
614#define RX_MFF_CTRL2 0x0c1c /* 8 bit Receive MAC FIFO Control Reg 2*/
615#define RX_MFF_TST1 0x0c1d /* 8 bit Receive MAC FIFO Test Reg 1 */
616#define RX_MFF_TST2 0x0c1e /* 8 bit Receive MAC FIFO Test Reg 2 */
617 /* 0x0c1f: reserved */
618#define RX_LED_INI 0x0c20 /* 32 bit Receive LED Cnt Init Value */
619#define RX_LED_VAL 0x0c24 /* 32 bit Receive LED Cnt Current Value */
620#define RX_LED_CTRL 0x0c28 /* 8 bit Receive LED Cnt Control Reg */
621#define RX_LED_TST 0x0c29 /* 8 bit Receive LED Cnt Test Register */
622 /* 0x0c2a - 0x0c2f: reserved */
623#define LNK_SYNC_INI 0x0c30 /* 32 bit Link Sync Cnt Init Value */
624#define LNK_SYNC_VAL 0x0c34 /* 32 bit Link Sync Cnt Current Value */
625#define LNK_SYNC_CTRL 0x0c38 /* 8 bit Link Sync Cnt Control Register */
626#define LNK_SYNC_TST 0x0c39 /* 8 bit Link Sync Cnt Test Register */
627 /* 0x0c3a - 0x0c3b: reserved */
628#define LNK_LED_REG 0x0c3c /* 8 bit Link LED Register */
629 /* 0x0c3d - 0x0c3f: reserved */
630
631/* Receive GMAC FIFO (YUKON only), use MR_ADDR() to access */
632#define RX_GMF_EA 0x0c40 /* 32 bit Rx GMAC FIFO End Address */
633#define RX_GMF_AF_THR 0x0c44 /* 32 bit Rx GMAC FIFO Almost Full Thresh. */
634#define RX_GMF_CTRL_T 0x0c48 /* 32 bit Rx GMAC FIFO Control/Test */
635#define RX_GMF_FL_MSK 0x0c4c /* 32 bit Rx GMAC FIFO Flush Mask */
636#define RX_GMF_FL_THR 0x0c50 /* 32 bit Rx GMAC FIFO Flush Threshold */
637 /* 0x0c54 - 0x0c5f: reserved */
638#define RX_GMF_WP 0x0c60 /* 32 bit Rx GMAC FIFO Write Pointer */
639 /* 0x0c64 - 0x0c67: reserved */
640#define RX_GMF_WLEV 0x0c68 /* 32 bit Rx GMAC FIFO Write Level */
641 /* 0x0c6c - 0x0c6f: reserved */
642#define RX_GMF_RP 0x0c70 /* 32 bit Rx GMAC FIFO Read Pointer */
643 /* 0x0c74 - 0x0c77: reserved */
644#define RX_GMF_RLEV 0x0c78 /* 32 bit Rx GMAC FIFO Read Level */
645 /* 0x0c7c - 0x0c7f: reserved */
646
647/*
648 * Bank 25
649 */
650 /* 0x0c80 - 0x0cbf: MAC 2 */
651 /* 0x0cc0 - 0x0cff: reserved */
652
653/*
654 * Bank 26
655 */
656/*
657 * Transmit MAC FIFO and Transmit LED Registers (GENESIS only),
658 * use MR_ADDR() to access
659 */
660#define TX_MFF_EA 0x0d00 /* 32 bit Transmit MAC FIFO End Address */
661#define TX_MFF_WP 0x0d04 /* 32 bit Transmit MAC FIFO WR Pointer */
662#define TX_MFF_WSP 0x0d08 /* 32 bit Transmit MAC FIFO WR Shadow Ptr */
663#define TX_MFF_RP 0x0d0c /* 32 bit Transmit MAC FIFO RD Pointer */
664#define TX_MFF_PC 0x0d10 /* 32 bit Transmit MAC FIFO Packet Cnt */
665#define TX_MFF_LEV 0x0d14 /* 32 bit Transmit MAC FIFO Level */
666#define TX_MFF_CTRL1 0x0d18 /* 16 bit Transmit MAC FIFO Ctrl Reg 1 */
667#define TX_MFF_WAF 0x0d1a /* 8 bit Transmit MAC Wait after flush */
668 /* 0x0c1b: reserved */
669#define TX_MFF_CTRL2 0x0d1c /* 8 bit Transmit MAC FIFO Ctrl Reg 2 */
670#define TX_MFF_TST1 0x0d1d /* 8 bit Transmit MAC FIFO Test Reg 1 */
671#define TX_MFF_TST2 0x0d1e /* 8 bit Transmit MAC FIFO Test Reg 2 */
672 /* 0x0d1f: reserved */
673#define TX_LED_INI 0x0d20 /* 32 bit Transmit LED Cnt Init Value */
674#define TX_LED_VAL 0x0d24 /* 32 bit Transmit LED Cnt Current Val */
675#define TX_LED_CTRL 0x0d28 /* 8 bit Transmit LED Cnt Control Reg */
676#define TX_LED_TST 0x0d29 /* 8 bit Transmit LED Cnt Test Reg */
677 /* 0x0d2a - 0x0d3f: reserved */
678
679/* Transmit GMAC FIFO (YUKON only), use MR_ADDR() to access */
680#define TX_GMF_EA 0x0d40 /* 32 bit Tx GMAC FIFO End Address */
681#define TX_GMF_AE_THR 0x0d44 /* 32 bit Tx GMAC FIFO Almost Empty Thresh.*/
682#define TX_GMF_CTRL_T 0x0d48 /* 32 bit Tx GMAC FIFO Control/Test */
683 /* 0x0d4c - 0x0d5f: reserved */
684#define TX_GMF_WP 0x0d60 /* 32 bit Tx GMAC FIFO Write Pointer */
685#define TX_GMF_WSP 0x0d64 /* 32 bit Tx GMAC FIFO Write Shadow Ptr. */
686#define TX_GMF_WLEV 0x0d68 /* 32 bit Tx GMAC FIFO Write Level */
687 /* 0x0d6c - 0x0d6f: reserved */
688#define TX_GMF_RP 0x0d70 /* 32 bit Tx GMAC FIFO Read Pointer */
689#define TX_GMF_RSTP 0x0d74 /* 32 bit Tx GMAC FIFO Restart Pointer */
690#define TX_GMF_RLEV 0x0d78 /* 32 bit Tx GMAC FIFO Read Level */
691 /* 0x0d7c - 0x0d7f: reserved */
692
693/*
694 * Bank 27
695 */
696 /* 0x0d80 - 0x0dbf: MAC 2 */
697 /* 0x0daa - 0x0dff: reserved */
698
699/*
700 * Bank 28
701 */
702/* Descriptor Poll Timer Registers */
703#define B28_DPT_INI 0x0e00 /* 24 bit Descriptor Poll Timer Init Val */
704#define B28_DPT_VAL 0x0e04 /* 24 bit Descriptor Poll Timer Curr Val */
705#define B28_DPT_CTRL 0x0e08 /* 8 bit Descriptor Poll Timer Ctrl Reg */
706 /* 0x0e09: reserved */
707#define B28_DPT_TST 0x0e0a /* 8 bit Descriptor Poll Timer Test Reg */
708 /* 0x0e0b: reserved */
709
710/* Time Stamp Timer Registers (YUKON only) */
711 /* 0x0e10: reserved */
712#define GMAC_TI_ST_VAL 0x0e14 /* 32 bit Time Stamp Timer Curr Val */
713#define GMAC_TI_ST_CTRL 0x0e18 /* 8 bit Time Stamp Timer Ctrl Reg */
714 /* 0x0e19: reserved */
715#define GMAC_TI_ST_TST 0x0e1a /* 8 bit Time Stamp Timer Test Reg */
716 /* 0x0e1b - 0x0e7f: reserved */
717
718/*
719 * Bank 29
720 */
721 /* 0x0e80 - 0x0efc: reserved */
722
723/*
724 * Bank 30
725 */
726/* GMAC and GPHY Control Registers (YUKON only) */
727#define GMAC_CTRL 0x0f00 /* 32 bit GMAC Control Reg */
728#define GPHY_CTRL 0x0f04 /* 32 bit GPHY Control Reg */
729#define GMAC_IRQ_SRC 0x0f08 /* 8 bit GMAC Interrupt Source Reg */
730 /* 0x0f09 - 0x0f0b: reserved */
731#define GMAC_IRQ_MSK 0x0f0c /* 8 bit GMAC Interrupt Mask Reg */
732 /* 0x0f0d - 0x0f0f: reserved */
733#define GMAC_LINK_CTRL 0x0f10 /* 16 bit Link Control Reg */
734 /* 0x0f14 - 0x0f1f: reserved */
735
736/* Wake-up Frame Pattern Match Control Registers (YUKON only) */
737
738#define WOL_REG_OFFS 0x20 /* HW-Bug: Address is + 0x20 against spec. */
739
740#define WOL_CTRL_STAT 0x0f20 /* 16 bit WOL Control/Status Reg */
741#define WOL_MATCH_CTL 0x0f22 /* 8 bit WOL Match Control Reg */
742#define WOL_MATCH_RES 0x0f23 /* 8 bit WOL Match Result Reg */
743#define WOL_MAC_ADDR_LO 0x0f24 /* 32 bit WOL MAC Address Low */
744#define WOL_MAC_ADDR_HI 0x0f28 /* 16 bit WOL MAC Address High */
745#define WOL_PATT_RPTR 0x0f2c /* 8 bit WOL Pattern Read Ptr */
746
747/* use this macro to access above registers */
748#define WOL_REG(Reg) ((Reg) + (pAC->GIni.GIWolOffs))
749
750
751/* WOL Pattern Length Registers (YUKON only) */
752
753#define WOL_PATT_LEN_LO 0x0f30 /* 32 bit WOL Pattern Length 3..0 */
754#define WOL_PATT_LEN_HI 0x0f34 /* 24 bit WOL Pattern Length 6..4 */
755
756/* WOL Pattern Counter Registers (YUKON only) */
757
758#define WOL_PATT_CNT_0 0x0f38 /* 32 bit WOL Pattern Counter 3..0 */
759#define WOL_PATT_CNT_4 0x0f3c /* 24 bit WOL Pattern Counter 6..4 */
760 /* 0x0f40 - 0x0f7f: reserved */
761
762/*
763 * Bank 31
764 */
765/* 0x0f80 - 0x0fff: reserved */
766
767/*
768 * Bank 32 - 33
769 */
770#define WOL_PATT_RAM_1 0x1000 /* WOL Pattern RAM Link 1 */
771
772/*
773 * Bank 0x22 - 0x3f
774 */
775/* 0x1100 - 0x1fff: reserved */
776
777/*
778 * Bank 0x40 - 0x4f
779 */
780#define BASE_XMAC_1 0x2000 /* XMAC 1 registers */
781
782/*
783 * Bank 0x50 - 0x5f
784 */
785
786#define BASE_GMAC_1 0x2800 /* GMAC 1 registers */
787
788/*
789 * Bank 0x60 - 0x6f
790 */
791#define BASE_XMAC_2 0x3000 /* XMAC 2 registers */
792
793/*
794 * Bank 0x70 - 0x7f
795 */
796#define BASE_GMAC_2 0x3800 /* GMAC 2 registers */
797
798/*
799 * Control Register Bit Definitions:
800 */
801/* B0_RAP 8 bit Register Address Port */
802 /* Bit 7: reserved */
803#define RAP_RAP 0x3f /* Bit 6..0: 0 = block 0,..,6f = block 6f */
804
805/* B0_CTST 16 bit Control/Status register */
806 /* Bit 15..14: reserved */
807#define CS_CLK_RUN_HOT BIT_13S /* CLK_RUN hot m. (YUKON-Lite only) */
808#define CS_CLK_RUN_RST BIT_12S /* CLK_RUN reset (YUKON-Lite only) */
809#define CS_CLK_RUN_ENA BIT_11S /* CLK_RUN enable (YUKON-Lite only) */
810#define CS_VAUX_AVAIL BIT_10S /* VAUX available (YUKON only) */
811#define CS_BUS_CLOCK BIT_9S /* Bus Clock 0/1 = 33/66 MHz */
812#define CS_BUS_SLOT_SZ BIT_8S /* Slot Size 0/1 = 32/64 bit slot */
813#define CS_ST_SW_IRQ BIT_7S /* Set IRQ SW Request */
814#define CS_CL_SW_IRQ BIT_6S /* Clear IRQ SW Request */
815#define CS_STOP_DONE BIT_5S /* Stop Master is finished */
816#define CS_STOP_MAST BIT_4S /* Command Bit to stop the master */
817#define CS_MRST_CLR BIT_3S /* Clear Master reset */
818#define CS_MRST_SET BIT_2S /* Set Master reset */
819#define CS_RST_CLR BIT_1S /* Clear Software reset */
820#define CS_RST_SET BIT_0S /* Set Software reset */
821
822/* B0_LED 8 Bit LED register */
823 /* Bit 7.. 2: reserved */
824#define LED_STAT_ON BIT_1S /* Status LED on */
825#define LED_STAT_OFF BIT_0S /* Status LED off */
826
827/* B0_POWER_CTRL 8 Bit Power Control reg (YUKON only) */
828#define PC_VAUX_ENA BIT_7 /* Switch VAUX Enable */
829#define PC_VAUX_DIS BIT_6 /* Switch VAUX Disable */
830#define PC_VCC_ENA BIT_5 /* Switch VCC Enable */
831#define PC_VCC_DIS BIT_4 /* Switch VCC Disable */
832#define PC_VAUX_ON BIT_3 /* Switch VAUX On */
833#define PC_VAUX_OFF BIT_2 /* Switch VAUX Off */
834#define PC_VCC_ON BIT_1 /* Switch VCC On */
835#define PC_VCC_OFF BIT_0 /* Switch VCC Off */
836
837/* B0_ISRC 32 bit Interrupt Source Register */
838/* B0_IMSK 32 bit Interrupt Mask Register */
839/* B0_SP_ISRC 32 bit Special Interrupt Source Reg */
840/* B2_IRQM_MSK 32 bit IRQ Moderation Mask */
841#define IS_ALL_MSK 0xbfffffffUL /* All Interrupt bits */
842#define IS_HW_ERR BIT_31 /* Interrupt HW Error */
843 /* Bit 30: reserved */
844#define IS_PA_TO_RX1 BIT_29 /* Packet Arb Timeout Rx1 */
845#define IS_PA_TO_RX2 BIT_28 /* Packet Arb Timeout Rx2 */
846#define IS_PA_TO_TX1 BIT_27 /* Packet Arb Timeout Tx1 */
847#define IS_PA_TO_TX2 BIT_26 /* Packet Arb Timeout Tx2 */
848#define IS_I2C_READY BIT_25 /* IRQ on end of I2C Tx */
849#define IS_IRQ_SW BIT_24 /* SW forced IRQ */
850#define IS_EXT_REG BIT_23 /* IRQ from LM80 or PHY (GENESIS only) */
851 /* IRQ from PHY (YUKON only) */
852#define IS_TIMINT BIT_22 /* IRQ from Timer */
853#define IS_MAC1 BIT_21 /* IRQ from MAC 1 */
854#define IS_LNK_SYNC_M1 BIT_20 /* Link Sync Cnt wrap MAC 1 */
855#define IS_MAC2 BIT_19 /* IRQ from MAC 2 */
856#define IS_LNK_SYNC_M2 BIT_18 /* Link Sync Cnt wrap MAC 2 */
857/* Receive Queue 1 */
858#define IS_R1_B BIT_17 /* Q_R1 End of Buffer */
859#define IS_R1_F BIT_16 /* Q_R1 End of Frame */
860#define IS_R1_C BIT_15 /* Q_R1 Encoding Error */
861/* Receive Queue 2 */
862#define IS_R2_B BIT_14 /* Q_R2 End of Buffer */
863#define IS_R2_F BIT_13 /* Q_R2 End of Frame */
864#define IS_R2_C BIT_12 /* Q_R2 Encoding Error */
865/* Synchronous Transmit Queue 1 */
866#define IS_XS1_B BIT_11 /* Q_XS1 End of Buffer */
867#define IS_XS1_F BIT_10 /* Q_XS1 End of Frame */
868#define IS_XS1_C BIT_9 /* Q_XS1 Encoding Error */
869/* Asynchronous Transmit Queue 1 */
870#define IS_XA1_B BIT_8 /* Q_XA1 End of Buffer */
871#define IS_XA1_F BIT_7 /* Q_XA1 End of Frame */
872#define IS_XA1_C BIT_6 /* Q_XA1 Encoding Error */
873/* Synchronous Transmit Queue 2 */
874#define IS_XS2_B BIT_5 /* Q_XS2 End of Buffer */
875#define IS_XS2_F BIT_4 /* Q_XS2 End of Frame */
876#define IS_XS2_C BIT_3 /* Q_XS2 Encoding Error */
877/* Asynchronous Transmit Queue 2 */
878#define IS_XA2_B BIT_2 /* Q_XA2 End of Buffer */
879#define IS_XA2_F BIT_1 /* Q_XA2 End of Frame */
880#define IS_XA2_C BIT_0 /* Q_XA2 Encoding Error */
881
882
883/* B0_HWE_ISRC 32 bit HW Error Interrupt Src Reg */
884/* B0_HWE_IMSK 32 bit HW Error Interrupt Mask Reg */
885/* B2_IRQM_HWE_MSK 32 bit IRQ Moderation HW Error Mask */
886#define IS_ERR_MSK 0x00000fffL /* All Error bits */
887 /* Bit 31..14: reserved */
888#define IS_IRQ_TIST_OV BIT_13 /* Time Stamp Timer Overflow (YUKON only) */
889#define IS_IRQ_SENSOR BIT_12 /* IRQ from Sensor (YUKON only) */
890#define IS_IRQ_MST_ERR BIT_11 /* IRQ master error detected */
891#define IS_IRQ_STAT BIT_10 /* IRQ status exception */
892#define IS_NO_STAT_M1 BIT_9 /* No Rx Status from MAC 1 */
893#define IS_NO_STAT_M2 BIT_8 /* No Rx Status from MAC 2 */
894#define IS_NO_TIST_M1 BIT_7 /* No Time Stamp from MAC 1 */
895#define IS_NO_TIST_M2 BIT_6 /* No Time Stamp from MAC 2 */
896#define IS_RAM_RD_PAR BIT_5 /* RAM Read Parity Error */
897#define IS_RAM_WR_PAR BIT_4 /* RAM Write Parity Error */
898#define IS_M1_PAR_ERR BIT_3 /* MAC 1 Parity Error */
899#define IS_M2_PAR_ERR BIT_2 /* MAC 2 Parity Error */
900#define IS_R1_PAR_ERR BIT_1 /* Queue R1 Parity Error */
901#define IS_R2_PAR_ERR BIT_0 /* Queue R2 Parity Error */
902
903/* B2_CONN_TYP 8 bit Connector type */
904/* B2_PMD_TYP 8 bit PMD type */
905/* Values of connector and PMD type comply to SysKonnect internal std */
906
907/* B2_MAC_CFG 8 bit MAC Configuration / Chip Revision */
908#define CFG_CHIP_R_MSK (0xf<<4) /* Bit 7.. 4: Chip Revision */
909 /* Bit 3.. 2: reserved */
910#define CFG_DIS_M2_CLK BIT_1S /* Disable Clock for 2nd MAC */
911#define CFG_SNG_MAC BIT_0S /* MAC Config: 0=2 MACs / 1=1 MAC*/
912
913/* B2_CHIP_ID 8 bit Chip Identification Number */
914#define CHIP_ID_GENESIS 0x0a /* Chip ID for GENESIS */
915#define CHIP_ID_YUKON 0xb0 /* Chip ID for YUKON */
916#define CHIP_ID_YUKON_LITE 0xb1 /* Chip ID for YUKON-Lite (Rev. A1-A3) */
917#define CHIP_ID_YUKON_LP 0xb2 /* Chip ID for YUKON-LP */
918
919#define CHIP_REV_YU_LITE_A1 3 /* Chip Rev. for YUKON-Lite A1,A2 */
920#define CHIP_REV_YU_LITE_A3 7 /* Chip Rev. for YUKON-Lite A3 */
921
922/* B2_FAR 32 bit Flash-Prom Addr Reg/Cnt */
923#define FAR_ADDR 0x1ffffL /* Bit 16.. 0: FPROM Address mask */
924
925/* B2_LD_CTRL 8 bit EPROM loader control register */
926/* Bits are currently reserved */
927
928/* B2_LD_TEST 8 bit EPROM loader test register */
929 /* Bit 7.. 4: reserved */
930#define LD_T_ON BIT_3S /* Loader Test mode on */
931#define LD_T_OFF BIT_2S /* Loader Test mode off */
932#define LD_T_STEP BIT_1S /* Decrement FPROM addr. Counter */
933#define LD_START BIT_0S /* Start loading FPROM */
934
935/*
936 * Timer Section
937 */
938/* B2_TI_CTRL 8 bit Timer control */
939/* B2_IRQM_CTRL 8 bit IRQ Moderation Timer Control */
940 /* Bit 7.. 3: reserved */
941#define TIM_START BIT_2S /* Start Timer */
942#define TIM_STOP BIT_1S /* Stop Timer */
943#define TIM_CLR_IRQ BIT_0S /* Clear Timer IRQ (!IRQM) */
944
945/* B2_TI_TEST 8 Bit Timer Test */
946/* B2_IRQM_TEST 8 bit IRQ Moderation Timer Test */
947/* B28_DPT_TST 8 bit Descriptor Poll Timer Test Reg */
948 /* Bit 7.. 3: reserved */
949#define TIM_T_ON BIT_2S /* Test mode on */
950#define TIM_T_OFF BIT_1S /* Test mode off */
951#define TIM_T_STEP BIT_0S /* Test step */
952
953/* B28_DPT_INI 32 bit Descriptor Poll Timer Init Val */
954/* B28_DPT_VAL 32 bit Descriptor Poll Timer Curr Val */
955 /* Bit 31..24: reserved */
956#define DPT_MSK 0x00ffffffL /* Bit 23.. 0: Desc Poll Timer Bits */
957
958/* B28_DPT_CTRL 8 bit Descriptor Poll Timer Ctrl Reg */
959 /* Bit 7.. 2: reserved */
960#define DPT_START BIT_1S /* Start Descriptor Poll Timer */
961#define DPT_STOP BIT_0S /* Stop Descriptor Poll Timer */
962
963/* B2_E_3 8 bit lower 4 bits used for HW self test result */
964#define B2_E3_RES_MASK 0x0f
965
966/* B2_TST_CTRL1 8 bit Test Control Register 1 */
967#define TST_FRC_DPERR_MR BIT_7S /* force DATAPERR on MST RD */
968#define TST_FRC_DPERR_MW BIT_6S /* force DATAPERR on MST WR */
969#define TST_FRC_DPERR_TR BIT_5S /* force DATAPERR on TRG RD */
970#define TST_FRC_DPERR_TW BIT_4S /* force DATAPERR on TRG WR */
971#define TST_FRC_APERR_M BIT_3S /* force ADDRPERR on MST */
972#define TST_FRC_APERR_T BIT_2S /* force ADDRPERR on TRG */
973#define TST_CFG_WRITE_ON BIT_1S /* Enable Config Reg WR */
974#define TST_CFG_WRITE_OFF BIT_0S /* Disable Config Reg WR */
975
976/* B2_TST_CTRL2 8 bit Test Control Register 2 */
977 /* Bit 7.. 4: reserved */
978 /* force the following error on the next master read/write */
979#define TST_FRC_DPERR_MR64 BIT_3S /* DataPERR RD 64 */
980#define TST_FRC_DPERR_MW64 BIT_2S /* DataPERR WR 64 */
981#define TST_FRC_APERR_1M64 BIT_1S /* AddrPERR on 1. phase */
982#define TST_FRC_APERR_2M64 BIT_0S /* AddrPERR on 2. phase */
983
984/* B2_GP_IO 32 bit General Purpose I/O Register */
985 /* Bit 31..26: reserved */
986#define GP_DIR_9 BIT_25 /* IO_9 direct, 0=In/1=Out */
987#define GP_DIR_8 BIT_24 /* IO_8 direct, 0=In/1=Out */
988#define GP_DIR_7 BIT_23 /* IO_7 direct, 0=In/1=Out */
989#define GP_DIR_6 BIT_22 /* IO_6 direct, 0=In/1=Out */
990#define GP_DIR_5 BIT_21 /* IO_5 direct, 0=In/1=Out */
991#define GP_DIR_4 BIT_20 /* IO_4 direct, 0=In/1=Out */
992#define GP_DIR_3 BIT_19 /* IO_3 direct, 0=In/1=Out */
993#define GP_DIR_2 BIT_18 /* IO_2 direct, 0=In/1=Out */
994#define GP_DIR_1 BIT_17 /* IO_1 direct, 0=In/1=Out */
995#define GP_DIR_0 BIT_16 /* IO_0 direct, 0=In/1=Out */
996 /* Bit 15..10: reserved */
997#define GP_IO_9 BIT_9 /* IO_9 pin */
998#define GP_IO_8 BIT_8 /* IO_8 pin */
999#define GP_IO_7 BIT_7 /* IO_7 pin */
1000#define GP_IO_6 BIT_6 /* IO_6 pin */
1001#define GP_IO_5 BIT_5 /* IO_5 pin */
1002#define GP_IO_4 BIT_4 /* IO_4 pin */
1003#define GP_IO_3 BIT_3 /* IO_3 pin */
1004#define GP_IO_2 BIT_2 /* IO_2 pin */
1005#define GP_IO_1 BIT_1 /* IO_1 pin */
1006#define GP_IO_0 BIT_0 /* IO_0 pin */
1007
1008/* B2_I2C_CTRL 32 bit I2C HW Control Register */
1009#define I2C_FLAG BIT_31 /* Start read/write if WR */
1010#define I2C_ADDR (0x7fffL<<16) /* Bit 30..16: Addr to be RD/WR */
1011#define I2C_DEV_SEL (0x7fL<<9) /* Bit 15.. 9: I2C Device Select */
1012 /* Bit 8.. 5: reserved */
1013#define I2C_BURST_LEN BIT_4 /* Burst Len, 1/4 bytes */
1014#define I2C_DEV_SIZE (7<<1) /* Bit 3.. 1: I2C Device Size */
1015#define I2C_025K_DEV (0<<1) /* 0: 256 Bytes or smal. */
1016#define I2C_05K_DEV (1<<1) /* 1: 512 Bytes */
1017#define I2C_1K_DEV (2<<1) /* 2: 1024 Bytes */
1018#define I2C_2K_DEV (3<<1) /* 3: 2048 Bytes */
1019#define I2C_4K_DEV (4<<1) /* 4: 4096 Bytes */
1020#define I2C_8K_DEV (5<<1) /* 5: 8192 Bytes */
1021#define I2C_16K_DEV (6<<1) /* 6: 16384 Bytes */
1022#define I2C_32K_DEV (7<<1) /* 7: 32768 Bytes */
1023#define I2C_STOP BIT_0 /* Interrupt I2C transfer */
1024
1025/* B2_I2C_IRQ 32 bit I2C HW IRQ Register */
1026 /* Bit 31.. 1 reserved */
1027#define I2C_CLR_IRQ BIT_0 /* Clear I2C IRQ */
1028
1029/* B2_I2C_SW 32 bit (8 bit access) I2C HW SW Port Register */
1030 /* Bit 7.. 3: reserved */
1031#define I2C_DATA_DIR BIT_2S /* direction of I2C_DATA */
1032#define I2C_DATA BIT_1S /* I2C Data Port */
1033#define I2C_CLK BIT_0S /* I2C Clock Port */
1034
1035/*
1036 * I2C Address
1037 */
1038#define I2C_SENS_ADDR LM80_ADDR /* I2C Sensor Address, (Volt and Temp)*/
1039
1040
1041/* B2_BSC_CTRL 8 bit Blink Source Counter Control */
1042 /* Bit 7.. 2: reserved */
1043#define BSC_START BIT_1S /* Start Blink Source Counter */
1044#define BSC_STOP BIT_0S /* Stop Blink Source Counter */
1045
1046/* B2_BSC_STAT 8 bit Blink Source Counter Status */
1047 /* Bit 7.. 1: reserved */
1048#define BSC_SRC BIT_0S /* Blink Source, 0=Off / 1=On */
1049
1050/* B2_BSC_TST 16 bit Blink Source Counter Test Reg */
1051#define BSC_T_ON BIT_2S /* Test mode on */
1052#define BSC_T_OFF BIT_1S /* Test mode off */
1053#define BSC_T_STEP BIT_0S /* Test step */
1054
1055
1056/* B3_RAM_ADDR 32 bit RAM Address, to read or write */
1057 /* Bit 31..19: reserved */
1058#define RAM_ADR_RAN 0x0007ffffL /* Bit 18.. 0: RAM Address Range */
1059
1060/* RAM Interface Registers */
1061/* B3_RI_CTRL 16 bit RAM Iface Control Register */
1062 /* Bit 15..10: reserved */
1063#define RI_CLR_RD_PERR BIT_9S /* Clear IRQ RAM Read Parity Err */
1064#define RI_CLR_WR_PERR BIT_8S /* Clear IRQ RAM Write Parity Err*/
1065 /* Bit 7.. 2: reserved */
1066#define RI_RST_CLR BIT_1S /* Clear RAM Interface Reset */
1067#define RI_RST_SET BIT_0S /* Set RAM Interface Reset */
1068
1069/* B3_RI_TEST 8 bit RAM Iface Test Register */
1070 /* Bit 15.. 4: reserved */
1071#define RI_T_EV BIT_3S /* Timeout Event occured */
1072#define RI_T_ON BIT_2S /* Timeout Timer Test On */
1073#define RI_T_OFF BIT_1S /* Timeout Timer Test Off */
1074#define RI_T_STEP BIT_0S /* Timeout Timer Step */
1075
1076/* MAC Arbiter Registers */
1077/* B3_MA_TO_CTRL 16 bit MAC Arbiter Timeout Ctrl Reg */
1078 /* Bit 15.. 4: reserved */
1079#define MA_FOE_ON BIT_3S /* XMAC Fast Output Enable ON */
1080#define MA_FOE_OFF BIT_2S /* XMAC Fast Output Enable OFF */
1081#define MA_RST_CLR BIT_1S /* Clear MAC Arbiter Reset */
1082#define MA_RST_SET BIT_0S /* Set MAC Arbiter Reset */
1083
1084/* B3_MA_RC_CTRL 16 bit MAC Arbiter Recovery Ctrl Reg */
1085 /* Bit 15.. 8: reserved */
1086#define MA_ENA_REC_TX2 BIT_7S /* Enable Recovery Timer TX2 */
1087#define MA_DIS_REC_TX2 BIT_6S /* Disable Recovery Timer TX2 */
1088#define MA_ENA_REC_TX1 BIT_5S /* Enable Recovery Timer TX1 */
1089#define MA_DIS_REC_TX1 BIT_4S /* Disable Recovery Timer TX1 */
1090#define MA_ENA_REC_RX2 BIT_3S /* Enable Recovery Timer RX2 */
1091#define MA_DIS_REC_RX2 BIT_2S /* Disable Recovery Timer RX2 */
1092#define MA_ENA_REC_RX1 BIT_1S /* Enable Recovery Timer RX1 */
1093#define MA_DIS_REC_RX1 BIT_0S /* Disable Recovery Timer RX1 */
1094
1095/* Packet Arbiter Registers */
1096/* B3_PA_CTRL 16 bit Packet Arbiter Ctrl Register */
1097 /* Bit 15..14: reserved */
1098#define PA_CLR_TO_TX2 BIT_13S /* Clear IRQ Packet Timeout TX2 */
1099#define PA_CLR_TO_TX1 BIT_12S /* Clear IRQ Packet Timeout TX1 */
1100#define PA_CLR_TO_RX2 BIT_11S /* Clear IRQ Packet Timeout RX2 */
1101#define PA_CLR_TO_RX1 BIT_10S /* Clear IRQ Packet Timeout RX1 */
1102#define PA_ENA_TO_TX2 BIT_9S /* Enable Timeout Timer TX2 */
1103#define PA_DIS_TO_TX2 BIT_8S /* Disable Timeout Timer TX2 */
1104#define PA_ENA_TO_TX1 BIT_7S /* Enable Timeout Timer TX1 */
1105#define PA_DIS_TO_TX1 BIT_6S /* Disable Timeout Timer TX1 */
1106#define PA_ENA_TO_RX2 BIT_5S /* Enable Timeout Timer RX2 */
1107#define PA_DIS_TO_RX2 BIT_4S /* Disable Timeout Timer RX2 */
1108#define PA_ENA_TO_RX1 BIT_3S /* Enable Timeout Timer RX1 */
1109#define PA_DIS_TO_RX1 BIT_2S /* Disable Timeout Timer RX1 */
1110#define PA_RST_CLR BIT_1S /* Clear MAC Arbiter Reset */
1111#define PA_RST_SET BIT_0S /* Set MAC Arbiter Reset */
1112
1113#define PA_ENA_TO_ALL (PA_ENA_TO_RX1 | PA_ENA_TO_RX2 |\
1114 PA_ENA_TO_TX1 | PA_ENA_TO_TX2)
1115
1116/* Rx/Tx Path related Arbiter Test Registers */
1117/* B3_MA_TO_TEST 16 bit MAC Arbiter Timeout Test Reg */
1118/* B3_MA_RC_TEST 16 bit MAC Arbiter Recovery Test Reg */
1119/* B3_PA_TEST 16 bit Packet Arbiter Test Register */
1120/* Bit 15, 11, 7, and 3 are reserved in B3_PA_TEST */
1121#define TX2_T_EV BIT_15S /* TX2 Timeout/Recv Event occured */
1122#define TX2_T_ON BIT_14S /* TX2 Timeout/Recv Timer Test On */
1123#define TX2_T_OFF BIT_13S /* TX2 Timeout/Recv Timer Tst Off */
1124#define TX2_T_STEP BIT_12S /* TX2 Timeout/Recv Timer Step */
1125#define TX1_T_EV BIT_11S /* TX1 Timeout/Recv Event occured */
1126#define TX1_T_ON BIT_10S /* TX1 Timeout/Recv Timer Test On */
1127#define TX1_T_OFF BIT_9S /* TX1 Timeout/Recv Timer Tst Off */
1128#define TX1_T_STEP BIT_8S /* TX1 Timeout/Recv Timer Step */
1129#define RX2_T_EV BIT_7S /* RX2 Timeout/Recv Event occured */
1130#define RX2_T_ON BIT_6S /* RX2 Timeout/Recv Timer Test On */
1131#define RX2_T_OFF BIT_5S /* RX2 Timeout/Recv Timer Tst Off */
1132#define RX2_T_STEP BIT_4S /* RX2 Timeout/Recv Timer Step */
1133#define RX1_T_EV BIT_3S /* RX1 Timeout/Recv Event occured */
1134#define RX1_T_ON BIT_2S /* RX1 Timeout/Recv Timer Test On */
1135#define RX1_T_OFF BIT_1S /* RX1 Timeout/Recv Timer Tst Off */
1136#define RX1_T_STEP BIT_0S /* RX1 Timeout/Recv Timer Step */
1137
1138
1139/* Transmit Arbiter Registers MAC 1 and 2, use MR_ADDR() to access */
1140/* TXA_ITI_INI 32 bit Tx Arb Interval Timer Init Val */
1141/* TXA_ITI_VAL 32 bit Tx Arb Interval Timer Value */
1142/* TXA_LIM_INI 32 bit Tx Arb Limit Counter Init Val */
1143/* TXA_LIM_VAL 32 bit Tx Arb Limit Counter Value */
1144 /* Bit 31..24: reserved */
1145#define TXA_MAX_VAL 0x00ffffffUL/* Bit 23.. 0: Max TXA Timer/Cnt Val */
1146
1147/* TXA_CTRL 8 bit Tx Arbiter Control Register */
1148#define TXA_ENA_FSYNC BIT_7S /* Enable force of sync Tx queue */
1149#define TXA_DIS_FSYNC BIT_6S /* Disable force of sync Tx queue */
1150#define TXA_ENA_ALLOC BIT_5S /* Enable alloc of free bandwidth */
1151#define TXA_DIS_ALLOC BIT_4S /* Disable alloc of free bandwidth */
1152#define TXA_START_RC BIT_3S /* Start sync Rate Control */
1153#define TXA_STOP_RC BIT_2S /* Stop sync Rate Control */
1154#define TXA_ENA_ARB BIT_1S /* Enable Tx Arbiter */
1155#define TXA_DIS_ARB BIT_0S /* Disable Tx Arbiter */
1156
1157/* TXA_TEST 8 bit Tx Arbiter Test Register */
1158 /* Bit 7.. 6: reserved */
1159#define TXA_INT_T_ON BIT_5S /* Tx Arb Interval Timer Test On */
1160#define TXA_INT_T_OFF BIT_4S /* Tx Arb Interval Timer Test Off */
1161#define TXA_INT_T_STEP BIT_3S /* Tx Arb Interval Timer Step */
1162#define TXA_LIM_T_ON BIT_2S /* Tx Arb Limit Timer Test On */
1163#define TXA_LIM_T_OFF BIT_1S /* Tx Arb Limit Timer Test Off */
1164#define TXA_LIM_T_STEP BIT_0S /* Tx Arb Limit Timer Step */
1165
1166/* TXA_STAT 8 bit Tx Arbiter Status Register */
1167 /* Bit 7.. 1: reserved */
1168#define TXA_PRIO_XS BIT_0S /* sync queue has prio to send */
1169
1170/* Q_BC 32 bit Current Byte Counter */
1171 /* Bit 31..16: reserved */
1172#define BC_MAX 0xffff /* Bit 15.. 0: Byte counter */
1173
1174/* BMU Control Status Registers */
1175/* B0_R1_CSR 32 bit BMU Ctrl/Stat Rx Queue 1 */
1176/* B0_R2_CSR 32 bit BMU Ctrl/Stat Rx Queue 2 */
1177/* B0_XA1_CSR 32 bit BMU Ctrl/Stat Sync Tx Queue 1 */
1178/* B0_XS1_CSR 32 bit BMU Ctrl/Stat Async Tx Queue 1 */
1179/* B0_XA2_CSR 32 bit BMU Ctrl/Stat Sync Tx Queue 2 */
1180/* B0_XS2_CSR 32 bit BMU Ctrl/Stat Async Tx Queue 2 */
1181/* Q_CSR 32 bit BMU Control/Status Register */
1182 /* Bit 31..25: reserved */
1183#define CSR_SV_IDLE BIT_24 /* BMU SM Idle */
1184 /* Bit 23..22: reserved */
1185#define CSR_DESC_CLR BIT_21 /* Clear Reset for Descr */
1186#define CSR_DESC_SET BIT_20 /* Set Reset for Descr */
1187#define CSR_FIFO_CLR BIT_19 /* Clear Reset for FIFO */
1188#define CSR_FIFO_SET BIT_18 /* Set Reset for FIFO */
1189#define CSR_HPI_RUN BIT_17 /* Release HPI SM */
1190#define CSR_HPI_RST BIT_16 /* Reset HPI SM to Idle */
1191#define CSR_SV_RUN BIT_15 /* Release Supervisor SM */
1192#define CSR_SV_RST BIT_14 /* Reset Supervisor SM */
1193#define CSR_DREAD_RUN BIT_13 /* Release Descr Read SM */
1194#define CSR_DREAD_RST BIT_12 /* Reset Descr Read SM */
1195#define CSR_DWRITE_RUN BIT_11 /* Release Descr Write SM */
1196#define CSR_DWRITE_RST BIT_10 /* Reset Descr Write SM */
1197#define CSR_TRANS_RUN BIT_9 /* Release Transfer SM */
1198#define CSR_TRANS_RST BIT_8 /* Reset Transfer SM */
1199#define CSR_ENA_POL BIT_7 /* Enable Descr Polling */
1200#define CSR_DIS_POL BIT_6 /* Disable Descr Polling */
1201#define CSR_STOP BIT_5 /* Stop Rx/Tx Queue */
1202#define CSR_START BIT_4 /* Start Rx/Tx Queue */
1203#define CSR_IRQ_CL_P BIT_3 /* (Rx) Clear Parity IRQ */
1204#define CSR_IRQ_CL_B BIT_2 /* Clear EOB IRQ */
1205#define CSR_IRQ_CL_F BIT_1 /* Clear EOF IRQ */
1206#define CSR_IRQ_CL_C BIT_0 /* Clear ERR IRQ */
1207
1208#define CSR_SET_RESET (CSR_DESC_SET | CSR_FIFO_SET | CSR_HPI_RST |\
1209 CSR_SV_RST | CSR_DREAD_RST | CSR_DWRITE_RST |\
1210 CSR_TRANS_RST)
1211#define CSR_CLR_RESET (CSR_DESC_CLR | CSR_FIFO_CLR | CSR_HPI_RUN |\
1212 CSR_SV_RUN | CSR_DREAD_RUN | CSR_DWRITE_RUN |\
1213 CSR_TRANS_RUN)
1214
1215/* Q_F 32 bit Flag Register */
1216 /* Bit 31..28: reserved */
1217#define F_ALM_FULL BIT_27 /* Rx FIFO: almost full */
1218#define F_EMPTY BIT_27 /* Tx FIFO: empty flag */
1219#define F_FIFO_EOF BIT_26 /* Tag (EOF Flag) bit in FIFO */
1220#define F_WM_REACHED BIT_25 /* Watermark reached */
1221 /* reserved */
1222#define F_FIFO_LEVEL (0x1fL<<16) /* Bit 23..16: # of Qwords in FIFO */
1223 /* Bit 15..11: reserved */
1224#define F_WATER_MARK 0x0007ffL /* Bit 10.. 0: Watermark */
1225
1226/* Q_T1 32 bit Test Register 1 */
1227/* Holds four State Machine control Bytes */
1228#define SM_CTRL_SV_MSK (0xffL<<24) /* Bit 31..24: Control Supervisor SM */
1229#define SM_CTRL_RD_MSK (0xffL<<16) /* Bit 23..16: Control Read Desc SM */
1230#define SM_CTRL_WR_MSK (0xffL<<8) /* Bit 15.. 8: Control Write Desc SM */
1231#define SM_CTRL_TR_MSK 0xffL /* Bit 7.. 0: Control Transfer SM */
1232
1233/* Q_T1_TR 8 bit Test Register 1 Transfer SM */
1234/* Q_T1_WR 8 bit Test Register 1 Write Descriptor SM */
1235/* Q_T1_RD 8 bit Test Register 1 Read Descriptor SM */
1236/* Q_T1_SV 8 bit Test Register 1 Supervisor SM */
1237
1238/* The control status byte of each machine looks like ... */
1239#define SM_STATE 0xf0 /* Bit 7.. 4: State which shall be loaded */
1240#define SM_LOAD BIT_3S /* Load the SM with SM_STATE */
1241#define SM_TEST_ON BIT_2S /* Switch on SM Test Mode */
1242#define SM_TEST_OFF BIT_1S /* Go off the Test Mode */
1243#define SM_STEP BIT_0S /* Step the State Machine */
1244/* The encoding of the states is not supported by the Diagnostics Tool */
1245
1246/* Q_T2 32 bit Test Register 2 */
1247 /* Bit 31.. 8: reserved */
1248#define T2_AC_T_ON BIT_7 /* Address Counter Test Mode on */
1249#define T2_AC_T_OFF BIT_6 /* Address Counter Test Mode off */
1250#define T2_BC_T_ON BIT_5 /* Byte Counter Test Mode on */
1251#define T2_BC_T_OFF BIT_4 /* Byte Counter Test Mode off */
1252#define T2_STEP04 BIT_3 /* Inc AC/Dec BC by 4 */
1253#define T2_STEP03 BIT_2 /* Inc AC/Dec BC by 3 */
1254#define T2_STEP02 BIT_1 /* Inc AC/Dec BC by 2 */
1255#define T2_STEP01 BIT_0 /* Inc AC/Dec BC by 1 */
1256
1257/* Q_T3 32 bit Test Register 3 */
1258 /* Bit 31.. 7: reserved */
1259#define T3_MUX_MSK (7<<4) /* Bit 6.. 4: Mux Position */
1260 /* Bit 3: reserved */
1261#define T3_VRAM_MSK 7 /* Bit 2.. 0: Virtual RAM Buffer Address */
1262
1263/* RAM Buffer Register Offsets, use RB_ADDR(Queue, Offs) to access */
1264/* RB_START 32 bit RAM Buffer Start Address */
1265/* RB_END 32 bit RAM Buffer End Address */
1266/* RB_WP 32 bit RAM Buffer Write Pointer */
1267/* RB_RP 32 bit RAM Buffer Read Pointer */
1268/* RB_RX_UTPP 32 bit Rx Upper Threshold, Pause Pack */
1269/* RB_RX_LTPP 32 bit Rx Lower Threshold, Pause Pack */
1270/* RB_RX_UTHP 32 bit Rx Upper Threshold, High Prio */
1271/* RB_RX_LTHP 32 bit Rx Lower Threshold, High Prio */
1272/* RB_PC 32 bit RAM Buffer Packet Counter */
1273/* RB_LEV 32 bit RAM Buffer Level Register */
1274 /* Bit 31..19: reserved */
1275#define RB_MSK 0x0007ffff /* Bit 18.. 0: RAM Buffer Pointer Bits */
1276
1277/* RB_TST2 8 bit RAM Buffer Test Register 2 */
1278 /* Bit 7.. 4: reserved */
1279#define RB_PC_DEC BIT_3S /* Packet Counter Decrem */
1280#define RB_PC_T_ON BIT_2S /* Packet Counter Test On */
1281#define RB_PC_T_OFF BIT_1S /* Packet Counter Tst Off */
1282#define RB_PC_INC BIT_0S /* Packet Counter Increm */
1283
1284/* RB_TST1 8 bit RAM Buffer Test Register 1 */
1285 /* Bit 7: reserved */
1286#define RB_WP_T_ON BIT_6S /* Write Pointer Test On */
1287#define RB_WP_T_OFF BIT_5S /* Write Pointer Test Off */
1288#define RB_WP_INC BIT_4S /* Write Pointer Increm */
1289 /* Bit 3: reserved */
1290#define RB_RP_T_ON BIT_2S /* Read Pointer Test On */
1291#define RB_RP_T_OFF BIT_1S /* Read Pointer Test Off */
1292#define RB_RP_DEC BIT_0S /* Read Pointer Decrement */
1293
1294/* RB_CTRL 8 bit RAM Buffer Control Register */
1295 /* Bit 7.. 6: reserved */
1296#define RB_ENA_STFWD BIT_5S /* Enable Store & Forward */
1297#define RB_DIS_STFWD BIT_4S /* Disable Store & Forward */
1298#define RB_ENA_OP_MD BIT_3S /* Enable Operation Mode */
1299#define RB_DIS_OP_MD BIT_2S /* Disable Operation Mode */
1300#define RB_RST_CLR BIT_1S /* Clear RAM Buf STM Reset */
1301#define RB_RST_SET BIT_0S /* Set RAM Buf STM Reset */
1302
1303
1304/* Receive and Transmit MAC FIFO Registers (GENESIS only) */
1305
1306/* RX_MFF_EA 32 bit Receive MAC FIFO End Address */
1307/* RX_MFF_WP 32 bit Receive MAC FIFO Write Pointer */
1308/* RX_MFF_RP 32 bit Receive MAC FIFO Read Pointer */
1309/* RX_MFF_PC 32 bit Receive MAC FIFO Packet Counter */
1310/* RX_MFF_LEV 32 bit Receive MAC FIFO Level */
1311/* TX_MFF_EA 32 bit Transmit MAC FIFO End Address */
1312/* TX_MFF_WP 32 bit Transmit MAC FIFO Write Pointer */
1313/* TX_MFF_WSP 32 bit Transmit MAC FIFO WR Shadow Pointer */
1314/* TX_MFF_RP 32 bit Transmit MAC FIFO Read Pointer */
1315/* TX_MFF_PC 32 bit Transmit MAC FIFO Packet Cnt */
1316/* TX_MFF_LEV 32 bit Transmit MAC FIFO Level */
1317 /* Bit 31.. 6: reserved */
1318#define MFF_MSK 0x007fL /* Bit 5.. 0: MAC FIFO Address/Ptr Bits */
1319
1320/* RX_MFF_CTRL1 16 bit Receive MAC FIFO Control Reg 1 */
1321 /* Bit 15..14: reserved */
1322#define MFF_ENA_RDY_PAT BIT_13S /* Enable Ready Patch */
1323#define MFF_DIS_RDY_PAT BIT_12S /* Disable Ready Patch */
1324#define MFF_ENA_TIM_PAT BIT_11S /* Enable Timing Patch */
1325#define MFF_DIS_TIM_PAT BIT_10S /* Disable Timing Patch */
1326#define MFF_ENA_ALM_FUL BIT_9S /* Enable AlmostFull Sign */
1327#define MFF_DIS_ALM_FUL BIT_8S /* Disable AlmostFull Sign */
1328#define MFF_ENA_PAUSE BIT_7S /* Enable Pause Signaling */
1329#define MFF_DIS_PAUSE BIT_6S /* Disable Pause Signaling */
1330#define MFF_ENA_FLUSH BIT_5S /* Enable Frame Flushing */
1331#define MFF_DIS_FLUSH BIT_4S /* Disable Frame Flushing */
1332#define MFF_ENA_TIST BIT_3S /* Enable Time Stamp Gener */
1333#define MFF_DIS_TIST BIT_2S /* Disable Time Stamp Gener */
1334#define MFF_CLR_INTIST BIT_1S /* Clear IRQ No Time Stamp */
1335#define MFF_CLR_INSTAT BIT_0S /* Clear IRQ No Status */
1336
1337#define MFF_RX_CTRL_DEF MFF_ENA_TIM_PAT
1338
1339/* TX_MFF_CTRL1 16 bit Transmit MAC FIFO Control Reg 1 */
1340#define MFF_CLR_PERR BIT_15S /* Clear Parity Error IRQ */
1341 /* Bit 14: reserved */
1342#define MFF_ENA_PKT_REC BIT_13S /* Enable Packet Recovery */
1343#define MFF_DIS_PKT_REC BIT_12S /* Disable Packet Recovery */
1344/* MFF_ENA_TIM_PAT (see RX_MFF_CTRL1) Bit 11: Enable Timing Patch */
1345/* MFF_DIS_TIM_PAT (see RX_MFF_CTRL1) Bit 10: Disable Timing Patch */
1346/* MFF_ENA_ALM_FUL (see RX_MFF_CTRL1) Bit 9: Enable Almost Full Sign */
1347/* MFF_DIS_ALM_FUL (see RX_MFF_CTRL1) Bit 8: Disable Almost Full Sign */
1348#define MFF_ENA_W4E BIT_7S /* Enable Wait for Empty */
1349#define MFF_DIS_W4E BIT_6S /* Disable Wait for Empty */
1350/* MFF_ENA_FLUSH (see RX_MFF_CTRL1) Bit 5: Enable Frame Flushing */
1351/* MFF_DIS_FLUSH (see RX_MFF_CTRL1) Bit 4: Disable Frame Flushing */
1352#define MFF_ENA_LOOPB BIT_3S /* Enable Loopback */
1353#define MFF_DIS_LOOPB BIT_2S /* Disable Loopback */
1354#define MFF_CLR_MAC_RST BIT_1S /* Clear XMAC Reset */
1355#define MFF_SET_MAC_RST BIT_0S /* Set XMAC Reset */
1356
1357#define MFF_TX_CTRL_DEF (MFF_ENA_PKT_REC | MFF_ENA_TIM_PAT | MFF_ENA_FLUSH)
1358
1359/* RX_MFF_TST2 8 bit Receive MAC FIFO Test Register 2 */
1360/* TX_MFF_TST2 8 bit Transmit MAC FIFO Test Register 2 */
1361 /* Bit 7: reserved */
1362#define MFF_WSP_T_ON BIT_6S /* Tx: Write Shadow Ptr TestOn */
1363#define MFF_WSP_T_OFF BIT_5S /* Tx: Write Shadow Ptr TstOff */
1364#define MFF_WSP_INC BIT_4S /* Tx: Write Shadow Ptr Increment */
1365#define MFF_PC_DEC BIT_3S /* Packet Counter Decrement */
1366#define MFF_PC_T_ON BIT_2S /* Packet Counter Test On */
1367#define MFF_PC_T_OFF BIT_1S /* Packet Counter Test Off */
1368#define MFF_PC_INC BIT_0S /* Packet Counter Increment */
1369
1370/* RX_MFF_TST1 8 bit Receive MAC FIFO Test Register 1 */
1371/* TX_MFF_TST1 8 bit Transmit MAC FIFO Test Register 1 */
1372 /* Bit 7: reserved */
1373#define MFF_WP_T_ON BIT_6S /* Write Pointer Test On */
1374#define MFF_WP_T_OFF BIT_5S /* Write Pointer Test Off */
1375#define MFF_WP_INC BIT_4S /* Write Pointer Increm */
1376 /* Bit 3: reserved */
1377#define MFF_RP_T_ON BIT_2S /* Read Pointer Test On */
1378#define MFF_RP_T_OFF BIT_1S /* Read Pointer Test Off */
1379#define MFF_RP_DEC BIT_0S /* Read Pointer Decrement */
1380
1381/* RX_MFF_CTRL2 8 bit Receive MAC FIFO Control Reg 2 */
1382/* TX_MFF_CTRL2 8 bit Transmit MAC FIFO Control Reg 2 */
1383 /* Bit 7..4: reserved */
1384#define MFF_ENA_OP_MD BIT_3S /* Enable Operation Mode */
1385#define MFF_DIS_OP_MD BIT_2S /* Disable Operation Mode */
1386#define MFF_RST_CLR BIT_1S /* Clear MAC FIFO Reset */
1387#define MFF_RST_SET BIT_0S /* Set MAC FIFO Reset */
1388
1389
1390/* Link LED Counter Registers (GENESIS only) */
1391
1392/* RX_LED_CTRL 8 bit Receive LED Cnt Control Reg */
1393/* TX_LED_CTRL 8 bit Transmit LED Cnt Control Reg */
1394/* LNK_SYNC_CTRL 8 bit Link Sync Cnt Control Register */
1395 /* Bit 7.. 3: reserved */
1396#define LED_START BIT_2S /* Start Timer */
1397#define LED_STOP BIT_1S /* Stop Timer */
1398#define LED_STATE BIT_0S /* Rx/Tx: LED State, 1=LED on */
1399#define LED_CLR_IRQ BIT_0S /* Lnk: Clear Link IRQ */
1400
1401/* RX_LED_TST 8 bit Receive LED Cnt Test Register */
1402/* TX_LED_TST 8 bit Transmit LED Cnt Test Register */
1403/* LNK_SYNC_TST 8 bit Link Sync Cnt Test Register */
1404 /* Bit 7.. 3: reserved */
1405#define LED_T_ON BIT_2S /* LED Counter Test mode On */
1406#define LED_T_OFF BIT_1S /* LED Counter Test mode Off */
1407#define LED_T_STEP BIT_0S /* LED Counter Step */
1408
1409/* LNK_LED_REG 8 bit Link LED Register */
1410 /* Bit 7.. 6: reserved */
1411#define LED_BLK_ON BIT_5S /* Link LED Blinking On */
1412#define LED_BLK_OFF BIT_4S /* Link LED Blinking Off */
1413#define LED_SYNC_ON BIT_3S /* Use Sync Wire to switch LED */
1414#define LED_SYNC_OFF BIT_2S /* Disable Sync Wire Input */
1415#define LED_ON BIT_1S /* switch LED on */
1416#define LED_OFF BIT_0S /* switch LED off */
1417
1418/* Receive and Transmit GMAC FIFO Registers (YUKON only) */
1419
1420/* RX_GMF_EA 32 bit Rx GMAC FIFO End Address */
1421/* RX_GMF_AF_THR 32 bit Rx GMAC FIFO Almost Full Thresh. */
1422/* RX_GMF_WP 32 bit Rx GMAC FIFO Write Pointer */
1423/* RX_GMF_WLEV 32 bit Rx GMAC FIFO Write Level */
1424/* RX_GMF_RP 32 bit Rx GMAC FIFO Read Pointer */
1425/* RX_GMF_RLEV 32 bit Rx GMAC FIFO Read Level */
1426/* TX_GMF_EA 32 bit Tx GMAC FIFO End Address */
1427/* TX_GMF_AE_THR 32 bit Tx GMAC FIFO Almost Empty Thresh.*/
1428/* TX_GMF_WP 32 bit Tx GMAC FIFO Write Pointer */
1429/* TX_GMF_WSP 32 bit Tx GMAC FIFO Write Shadow Ptr. */
1430/* TX_GMF_WLEV 32 bit Tx GMAC FIFO Write Level */
1431/* TX_GMF_RP 32 bit Tx GMAC FIFO Read Pointer */
1432/* TX_GMF_RSTP 32 bit Tx GMAC FIFO Restart Pointer */
1433/* TX_GMF_RLEV 32 bit Tx GMAC FIFO Read Level */
1434
1435/* RX_GMF_CTRL_T 32 bit Rx GMAC FIFO Control/Test */
1436 /* Bits 31..15: reserved */
1437#define GMF_WP_TST_ON BIT_14 /* Write Pointer Test On */
1438#define GMF_WP_TST_OFF BIT_13 /* Write Pointer Test Off */
1439#define GMF_WP_STEP BIT_12 /* Write Pointer Step/Increment */
1440 /* Bit 11: reserved */
1441#define GMF_RP_TST_ON BIT_10 /* Read Pointer Test On */
1442#define GMF_RP_TST_OFF BIT_9 /* Read Pointer Test Off */
1443#define GMF_RP_STEP BIT_8 /* Read Pointer Step/Increment */
1444#define GMF_RX_F_FL_ON BIT_7 /* Rx FIFO Flush Mode On */
1445#define GMF_RX_F_FL_OFF BIT_6 /* Rx FIFO Flush Mode Off */
1446#define GMF_CLI_RX_FO BIT_5 /* Clear IRQ Rx FIFO Overrun */
1447#define GMF_CLI_RX_FC BIT_4 /* Clear IRQ Rx Frame Complete */
1448#define GMF_OPER_ON BIT_3 /* Operational Mode On */
1449#define GMF_OPER_OFF BIT_2 /* Operational Mode Off */
1450#define GMF_RST_CLR BIT_1 /* Clear GMAC FIFO Reset */
1451#define GMF_RST_SET BIT_0 /* Set GMAC FIFO Reset */
1452
1453/* TX_GMF_CTRL_T 32 bit Tx GMAC FIFO Control/Test */
1454 /* Bits 31..19: reserved */
1455#define GMF_WSP_TST_ON BIT_18 /* Write Shadow Pointer Test On */
1456#define GMF_WSP_TST_OFF BIT_17 /* Write Shadow Pointer Test Off */
1457#define GMF_WSP_STEP BIT_16 /* Write Shadow Pointer Step/Increment */
1458 /* Bits 15..7: same as for RX_GMF_CTRL_T */
1459#define GMF_CLI_TX_FU BIT_6 /* Clear IRQ Tx FIFO Underrun */
1460#define GMF_CLI_TX_FC BIT_5 /* Clear IRQ Tx Frame Complete */
1461#define GMF_CLI_TX_PE BIT_4 /* Clear IRQ Tx Parity Error */
1462 /* Bits 3..0: same as for RX_GMF_CTRL_T */
1463
1464#define GMF_RX_CTRL_DEF (GMF_OPER_ON | GMF_RX_F_FL_ON)
1465#define GMF_TX_CTRL_DEF GMF_OPER_ON
1466
1467#define RX_GMF_FL_THR_DEF 0x0a /* Rx GMAC FIFO Flush Threshold default */
1468
1469/* GMAC_TI_ST_CTRL 8 bit Time Stamp Timer Ctrl Reg (YUKON only) */
1470 /* Bit 7.. 3: reserved */
1471#define GMT_ST_START BIT_2S /* Start Time Stamp Timer */
1472#define GMT_ST_STOP BIT_1S /* Stop Time Stamp Timer */
1473#define GMT_ST_CLR_IRQ BIT_0S /* Clear Time Stamp Timer IRQ */
1474
1475/* GMAC_CTRL 32 bit GMAC Control Reg (YUKON only) */
1476 /* Bits 31.. 8: reserved */
1477#define GMC_H_BURST_ON BIT_7 /* Half Duplex Burst Mode On */
1478#define GMC_H_BURST_OFF BIT_6 /* Half Duplex Burst Mode Off */
1479#define GMC_F_LOOPB_ON BIT_5 /* FIFO Loopback On */
1480#define GMC_F_LOOPB_OFF BIT_4 /* FIFO Loopback Off */
1481#define GMC_PAUSE_ON BIT_3 /* Pause On */
1482#define GMC_PAUSE_OFF BIT_2 /* Pause Off */
1483#define GMC_RST_CLR BIT_1 /* Clear GMAC Reset */
1484#define GMC_RST_SET BIT_0 /* Set GMAC Reset */
1485
1486/* GPHY_CTRL 32 bit GPHY Control Reg (YUKON only) */
1487 /* Bits 31..29: reserved */
1488#define GPC_SEL_BDT BIT_28 /* Select Bi-Dir. Transfer for MDC/MDIO */
1489#define GPC_INT_POL_HI BIT_27 /* IRQ Polarity is Active HIGH */
1490#define GPC_75_OHM BIT_26 /* Use 75 Ohm Termination instead of 50 */
1491#define GPC_DIS_FC BIT_25 /* Disable Automatic Fiber/Copper Detection */
1492#define GPC_DIS_SLEEP BIT_24 /* Disable Energy Detect */
1493#define GPC_HWCFG_M_3 BIT_23 /* HWCFG_MODE[3] */
1494#define GPC_HWCFG_M_2 BIT_22 /* HWCFG_MODE[2] */
1495#define GPC_HWCFG_M_1 BIT_21 /* HWCFG_MODE[1] */
1496#define GPC_HWCFG_M_0 BIT_20 /* HWCFG_MODE[0] */
1497#define GPC_ANEG_0 BIT_19 /* ANEG[0] */
1498#define GPC_ENA_XC BIT_18 /* Enable MDI crossover */
1499#define GPC_DIS_125 BIT_17 /* Disable 125 MHz clock */
1500#define GPC_ANEG_3 BIT_16 /* ANEG[3] */
1501#define GPC_ANEG_2 BIT_15 /* ANEG[2] */
1502#define GPC_ANEG_1 BIT_14 /* ANEG[1] */
1503#define GPC_ENA_PAUSE BIT_13 /* Enable Pause (SYM_OR_REM) */
1504#define GPC_PHYADDR_4 BIT_12 /* Bit 4 of Phy Addr */
1505#define GPC_PHYADDR_3 BIT_11 /* Bit 3 of Phy Addr */
1506#define GPC_PHYADDR_2 BIT_10 /* Bit 2 of Phy Addr */
1507#define GPC_PHYADDR_1 BIT_9 /* Bit 1 of Phy Addr */
1508#define GPC_PHYADDR_0 BIT_8 /* Bit 0 of Phy Addr */
1509 /* Bits 7..2: reserved */
1510#define GPC_RST_CLR BIT_1 /* Clear GPHY Reset */
1511#define GPC_RST_SET BIT_0 /* Set GPHY Reset */
1512
1513#define GPC_HWCFG_GMII_COP (GPC_HWCFG_M_3 | GPC_HWCFG_M_2 | \
1514 GPC_HWCFG_M_1 | GPC_HWCFG_M_0)
1515
1516#define GPC_HWCFG_GMII_FIB ( GPC_HWCFG_M_2 | \
1517 GPC_HWCFG_M_1 | GPC_HWCFG_M_0)
1518
1519#define GPC_ANEG_ADV_ALL_M (GPC_ANEG_3 | GPC_ANEG_2 | \
1520 GPC_ANEG_1 | GPC_ANEG_0)
1521
1522/* forced speed and duplex mode (don't mix with other ANEG bits) */
1523#define GPC_FRC10MBIT_HALF 0
1524#define GPC_FRC10MBIT_FULL GPC_ANEG_0
1525#define GPC_FRC100MBIT_HALF GPC_ANEG_1
1526#define GPC_FRC100MBIT_FULL (GPC_ANEG_0 | GPC_ANEG_1)
1527
1528/* auto-negotiation with limited advertised speeds */
1529/* mix only with master/slave settings (for copper) */
1530#define GPC_ADV_1000_HALF GPC_ANEG_2
1531#define GPC_ADV_1000_FULL GPC_ANEG_3
1532#define GPC_ADV_ALL (GPC_ANEG_2 | GPC_ANEG_3)
1533
1534/* master/slave settings */
1535/* only for copper with 1000 Mbps */
1536#define GPC_FORCE_MASTER 0
1537#define GPC_FORCE_SLAVE GPC_ANEG_0
1538#define GPC_PREF_MASTER GPC_ANEG_1
1539#define GPC_PREF_SLAVE (GPC_ANEG_1 | GPC_ANEG_0)
1540
1541/* GMAC_IRQ_SRC 8 bit GMAC Interrupt Source Reg (YUKON only) */
1542/* GMAC_IRQ_MSK 8 bit GMAC Interrupt Mask Reg (YUKON only) */
1543#define GM_IS_TX_CO_OV BIT_5 /* Transmit Counter Overflow IRQ */
1544#define GM_IS_RX_CO_OV BIT_4 /* Receive Counter Overflow IRQ */
1545#define GM_IS_TX_FF_UR BIT_3 /* Transmit FIFO Underrun */
1546#define GM_IS_TX_COMPL BIT_2 /* Frame Transmission Complete */
1547#define GM_IS_RX_FF_OR BIT_1 /* Receive FIFO Overrun */
1548#define GM_IS_RX_COMPL BIT_0 /* Frame Reception Complete */
1549
1550#define GMAC_DEF_MSK (GM_IS_TX_CO_OV | GM_IS_RX_CO_OV | \
1551 GM_IS_TX_FF_UR)
1552
1553/* GMAC_LINK_CTRL 16 bit GMAC Link Control Reg (YUKON only) */
1554 /* Bits 15.. 2: reserved */
1555#define GMLC_RST_CLR BIT_1S /* Clear GMAC Link Reset */
1556#define GMLC_RST_SET BIT_0S /* Set GMAC Link Reset */
1557
1558
1559/* WOL_CTRL_STAT 16 bit WOL Control/Status Reg */
1560#define WOL_CTL_LINK_CHG_OCC BIT_15S
1561#define WOL_CTL_MAGIC_PKT_OCC BIT_14S
1562#define WOL_CTL_PATTERN_OCC BIT_13S
1563
1564#define WOL_CTL_CLEAR_RESULT BIT_12S
1565
1566#define WOL_CTL_ENA_PME_ON_LINK_CHG BIT_11S
1567#define WOL_CTL_DIS_PME_ON_LINK_CHG BIT_10S
1568#define WOL_CTL_ENA_PME_ON_MAGIC_PKT BIT_9S
1569#define WOL_CTL_DIS_PME_ON_MAGIC_PKT BIT_8S
1570#define WOL_CTL_ENA_PME_ON_PATTERN BIT_7S
1571#define WOL_CTL_DIS_PME_ON_PATTERN BIT_6S
1572
1573#define WOL_CTL_ENA_LINK_CHG_UNIT BIT_5S
1574#define WOL_CTL_DIS_LINK_CHG_UNIT BIT_4S
1575#define WOL_CTL_ENA_MAGIC_PKT_UNIT BIT_3S
1576#define WOL_CTL_DIS_MAGIC_PKT_UNIT BIT_2S
1577#define WOL_CTL_ENA_PATTERN_UNIT BIT_1S
1578#define WOL_CTL_DIS_PATTERN_UNIT BIT_0S
1579
1580#define WOL_CTL_DEFAULT \
1581 (WOL_CTL_DIS_PME_ON_LINK_CHG | \
1582 WOL_CTL_DIS_PME_ON_PATTERN | \
1583 WOL_CTL_DIS_PME_ON_MAGIC_PKT | \
1584 WOL_CTL_DIS_LINK_CHG_UNIT | \
1585 WOL_CTL_DIS_PATTERN_UNIT | \
1586 WOL_CTL_DIS_MAGIC_PKT_UNIT)
1587
1588/* WOL_MATCH_CTL 8 bit WOL Match Control Reg */
1589#define WOL_CTL_PATT_ENA(x) (BIT_0 << (x))
1590
1591#define SK_NUM_WOL_PATTERN 7
1592#define SK_PATTERN_PER_WORD 4
1593#define SK_BITMASK_PATTERN 7
1594#define SK_POW_PATTERN_LENGTH 128
1595
1596#define WOL_LENGTH_MSK 0x7f
1597#define WOL_LENGTH_SHIFT 8
1598
1599
1600/* Receive and Transmit Descriptors ******************************************/
1601
1602/* Transmit Descriptor struct */
1603typedef struct s_HwTxd {
1604 SK_U32 volatile TxCtrl; /* Transmit Buffer Control Field */
1605 SK_U32 TxNext; /* Physical Address Pointer to the next TxD */
1606 SK_U32 TxAdrLo; /* Physical Tx Buffer Address lower dword */
1607 SK_U32 TxAdrHi; /* Physical Tx Buffer Address upper dword */
1608 SK_U32 TxStat; /* Transmit Frame Status Word */
1609#ifndef SK_USE_REV_DESC
1610 SK_U16 TxTcpOffs; /* TCP Checksum Calculation Start Value */
1611 SK_U16 TxRes1; /* 16 bit reserved field */
1612 SK_U16 TxTcpWp; /* TCP Checksum Write Position */
1613 SK_U16 TxTcpSp; /* TCP Checksum Calculation Start Position */
1614#else /* SK_USE_REV_DESC */
1615 SK_U16 TxRes1; /* 16 bit reserved field */
1616 SK_U16 TxTcpOffs; /* TCP Checksum Calculation Start Value */
1617 SK_U16 TxTcpSp; /* TCP Checksum Calculation Start Position */
1618 SK_U16 TxTcpWp; /* TCP Checksum Write Position */
1619#endif /* SK_USE_REV_DESC */
1620 SK_U32 TxRes2; /* 32 bit reserved field */
1621} SK_HWTXD;
1622
1623/* Receive Descriptor struct */
1624typedef struct s_HwRxd {
1625 SK_U32 volatile RxCtrl; /* Receive Buffer Control Field */
1626 SK_U32 RxNext; /* Physical Address Pointer to the next RxD */
1627 SK_U32 RxAdrLo; /* Physical Rx Buffer Address lower dword */
1628 SK_U32 RxAdrHi; /* Physical Rx Buffer Address upper dword */
1629 SK_U32 RxStat; /* Receive Frame Status Word */
1630 SK_U32 RxTiSt; /* Receive Time Stamp (from XMAC on GENESIS) */
1631#ifndef SK_USE_REV_DESC
1632 SK_U16 RxTcpSum1; /* TCP Checksum 1 */
1633 SK_U16 RxTcpSum2; /* TCP Checksum 2 */
1634 SK_U16 RxTcpSp1; /* TCP Checksum Calculation Start Position 1 */
1635 SK_U16 RxTcpSp2; /* TCP Checksum Calculation Start Position 2 */
1636#else /* SK_USE_REV_DESC */
1637 SK_U16 RxTcpSum2; /* TCP Checksum 2 */
1638 SK_U16 RxTcpSum1; /* TCP Checksum 1 */
1639 SK_U16 RxTcpSp2; /* TCP Checksum Calculation Start Position 2 */
1640 SK_U16 RxTcpSp1; /* TCP Checksum Calculation Start Position 1 */
1641#endif /* SK_USE_REV_DESC */
1642} SK_HWRXD;
1643
1644/*
1645 * Drivers which use the reverse descriptor feature (PCI_OUR_REG_2)
1646 * should set the define SK_USE_REV_DESC.
1647 * Structures are 'normaly' not endianess dependent. But in
1648 * this case the SK_U16 fields are bound to bit positions inside the
1649 * descriptor. RxTcpSum1 e.g. must start at bit 0 within the 6.th DWord.
1650 * The bit positions inside a DWord are of course endianess dependent and
1651 * swaps if the DWord is swapped by the hardware.
1652 */
1653
1654
1655/* Descriptor Bit Definition */
1656/* TxCtrl Transmit Buffer Control Field */
1657/* RxCtrl Receive Buffer Control Field */
1658#define BMU_OWN BIT_31 /* OWN bit: 0=host/1=BMU */
1659#define BMU_STF BIT_30 /* Start of Frame */
1660#define BMU_EOF BIT_29 /* End of Frame */
1661#define BMU_IRQ_EOB BIT_28 /* Req "End of Buffer" IRQ */
1662#define BMU_IRQ_EOF BIT_27 /* Req "End of Frame" IRQ */
1663/* TxCtrl specific bits */
1664#define BMU_STFWD BIT_26 /* (Tx) Store & Forward Frame */
1665#define BMU_NO_FCS BIT_25 /* (Tx) Disable MAC FCS (CRC) generation */
1666#define BMU_SW BIT_24 /* (Tx) 1 bit res. for SW use */
1667/* RxCtrl specific bits */
1668#define BMU_DEV_0 BIT_26 /* (Rx) Transfer data to Dev0 */
1669#define BMU_STAT_VAL BIT_25 /* (Rx) Rx Status Valid */
1670#define BMU_TIST_VAL BIT_24 /* (Rx) Rx TimeStamp Valid */
1671 /* Bit 23..16: BMU Check Opcodes */
1672#define BMU_CHECK (0x55L<<16) /* Default BMU check */
1673#define BMU_TCP_CHECK (0x56L<<16) /* Descr with TCP ext */
1674#define BMU_UDP_CHECK (0x57L<<16) /* Descr with UDP ext (YUKON only) */
1675#define BMU_BBC 0xffffL /* Bit 15.. 0: Buffer Byte Counter */
1676
1677/* TxStat Transmit Frame Status Word */
1678/* RxStat Receive Frame Status Word */
1679/*
1680 *Note: TxStat is reserved for ASIC loopback mode only
1681 *
1682 * The Bits of the Status words are defined in xmac_ii.h
1683 * (see XMR_FS bits)
1684 */
1685
1686/* macros ********************************************************************/
1687
1688/* Receive and Transmit Queues */
1689#define Q_R1 0x0000 /* Receive Queue 1 */
1690#define Q_R2 0x0080 /* Receive Queue 2 */
1691#define Q_XS1 0x0200 /* Synchronous Transmit Queue 1 */
1692#define Q_XA1 0x0280 /* Asynchronous Transmit Queue 1 */
1693#define Q_XS2 0x0300 /* Synchronous Transmit Queue 2 */
1694#define Q_XA2 0x0380 /* Asynchronous Transmit Queue 2 */
1695
1696/*
1697 * Macro Q_ADDR()
1698 *
1699 * Use this macro to access the Receive and Transmit Queue Registers.
1700 *
1701 * para:
1702 * Queue Queue to access.
1703 * Values: Q_R1, Q_R2, Q_XS1, Q_XA1, Q_XS2, and Q_XA2
1704 * Offs Queue register offset.
1705 * Values: Q_D, Q_DA_L ... Q_T2, Q_T3
1706 *
1707 * usage SK_IN32(pAC, Q_ADDR(Q_R2, Q_BC), pVal)
1708 */
1709#define Q_ADDR(Queue, Offs) (B8_Q_REGS + (Queue) + (Offs))
1710
1711/*
1712 * Macro RB_ADDR()
1713 *
1714 * Use this macro to access the RAM Buffer Registers.
1715 *
1716 * para:
1717 * Queue Queue to access.
1718 * Values: Q_R1, Q_R2, Q_XS1, Q_XA1, Q_XS2, and Q_XA2
1719 * Offs Queue register offset.
1720 * Values: RB_START, RB_END ... RB_LEV, RB_CTRL
1721 *
1722 * usage SK_IN32(pAC, RB_ADDR(Q_R2, RB_RP), pVal)
1723 */
1724#define RB_ADDR(Queue, Offs) (B16_RAM_REGS + (Queue) + (Offs))
1725
1726
1727/* MAC Related Registers */
1728#define MAC_1 0 /* belongs to the port near the slot */
1729#define MAC_2 1 /* belongs to the port far away from the slot */
1730
1731/*
1732 * Macro MR_ADDR()
1733 *
1734 * Use this macro to access a MAC Related Registers inside the ASIC.
1735 *
1736 * para:
1737 * Mac MAC to access.
1738 * Values: MAC_1, MAC_2
1739 * Offs MAC register offset.
1740 * Values: RX_MFF_EA, RX_MFF_WP ... LNK_LED_REG,
1741 * TX_MFF_EA, TX_MFF_WP ... TX_LED_TST
1742 *
1743 * usage SK_IN32(pAC, MR_ADDR(MAC_1, TX_MFF_EA), pVal)
1744 */
1745#define MR_ADDR(Mac, Offs) (((Mac) << 7) + (Offs))
1746
1747#ifdef SK_LITTLE_ENDIAN
1748#define XM_WORD_LO 0
1749#define XM_WORD_HI 1
1750#else /* !SK_LITTLE_ENDIAN */
1751#define XM_WORD_LO 1
1752#define XM_WORD_HI 0
1753#endif /* !SK_LITTLE_ENDIAN */
1754
1755
1756/*
1757 * macros to access the XMAC (GENESIS only)
1758 *
1759 * XM_IN16(), to read a 16 bit register (e.g. XM_MMU_CMD)
1760 * XM_OUT16(), to write a 16 bit register (e.g. XM_MMU_CMD)
1761 * XM_IN32(), to read a 32 bit register (e.g. XM_TX_EV_CNT)
1762 * XM_OUT32(), to write a 32 bit register (e.g. XM_TX_EV_CNT)
1763 * XM_INADDR(), to read a network address register (e.g. XM_SRC_CHK)
1764 * XM_OUTADDR(), to write a network address register (e.g. XM_SRC_CHK)
1765 * XM_INHASH(), to read the XM_HSM_CHK register
1766 * XM_OUTHASH() to write the XM_HSM_CHK register
1767 *
1768 * para:
1769 * Mac XMAC to access values: MAC_1 or MAC_2
1770 * IoC I/O context needed for SK I/O macros
1771 * Reg XMAC Register to read or write
1772 * (p)Val Value or pointer to the value which should be read or written
1773 *
1774 * usage: XM_OUT16(IoC, MAC_1, XM_MMU_CMD, Value);
1775 */
1776
1777#define XMA(Mac, Reg) \
1778 ((BASE_XMAC_1 + (Mac) * (BASE_XMAC_2 - BASE_XMAC_1)) | ((Reg) << 1))
1779
1780#define XM_IN16(IoC, Mac, Reg, pVal) \
1781 SK_IN16((IoC), XMA((Mac), (Reg)), (pVal))
1782
1783#define XM_OUT16(IoC, Mac, Reg, Val) \
1784 SK_OUT16((IoC), XMA((Mac), (Reg)), (Val))
1785
1786#define XM_IN32(IoC, Mac, Reg, pVal) { \
1787 SK_IN16((IoC), XMA((Mac), (Reg)), \
1788 (SK_U16 SK_FAR*)&((SK_U16 SK_FAR*)(pVal))[XM_WORD_LO]); \
1789 SK_IN16((IoC), XMA((Mac), (Reg+2)), \
1790 (SK_U16 SK_FAR*)&((SK_U16 SK_FAR*)(pVal))[XM_WORD_HI]); \
1791}
1792
1793#define XM_OUT32(IoC, Mac, Reg, Val) { \
1794 SK_OUT16((IoC), XMA((Mac), (Reg)), (SK_U16)((Val) & 0xffffL)); \
1795 SK_OUT16((IoC), XMA((Mac), (Reg+2)), (SK_U16)(((Val) >> 16) & 0xffffL));\
1796}
1797
1798/* Remember: we are always writing to / reading from LITTLE ENDIAN memory */
1799
1800#define XM_INADDR(IoC, Mac, Reg, pVal) { \
1801 SK_U16 Word; \
1802 SK_U8 *pByte; \
1803 pByte = (SK_U8 *)&((SK_U8 *)(pVal))[0]; \
1804 SK_IN16((IoC), XMA((Mac), (Reg)), &Word); \
1805 pByte[0] = (SK_U8)(Word & 0x00ff); \
1806 pByte[1] = (SK_U8)((Word >> 8) & 0x00ff); \
1807 SK_IN16((IoC), XMA((Mac), (Reg+2)), &Word); \
1808 pByte[2] = (SK_U8)(Word & 0x00ff); \
1809 pByte[3] = (SK_U8)((Word >> 8) & 0x00ff); \
1810 SK_IN16((IoC), XMA((Mac), (Reg+4)), &Word); \
1811 pByte[4] = (SK_U8)(Word & 0x00ff); \
1812 pByte[5] = (SK_U8)((Word >> 8) & 0x00ff); \
1813}
1814
1815#define XM_OUTADDR(IoC, Mac, Reg, pVal) { \
1816 SK_U8 SK_FAR *pByte; \
1817 pByte = (SK_U8 SK_FAR *)&((SK_U8 SK_FAR *)(pVal))[0]; \
1818 SK_OUT16((IoC), XMA((Mac), (Reg)), (SK_U16) \
1819 (((SK_U16)(pByte[0]) & 0x00ff) | \
1820 (((SK_U16)(pByte[1]) << 8) & 0xff00))); \
1821 SK_OUT16((IoC), XMA((Mac), (Reg+2)), (SK_U16) \
1822 (((SK_U16)(pByte[2]) & 0x00ff) | \
1823 (((SK_U16)(pByte[3]) << 8) & 0xff00))); \
1824 SK_OUT16((IoC), XMA((Mac), (Reg+4)), (SK_U16) \
1825 (((SK_U16)(pByte[4]) & 0x00ff) | \
1826 (((SK_U16)(pByte[5]) << 8) & 0xff00))); \
1827}
1828
1829#define XM_INHASH(IoC, Mac, Reg, pVal) { \
1830 SK_U16 Word; \
1831 SK_U8 SK_FAR *pByte; \
1832 pByte = (SK_U8 SK_FAR *)&((SK_U8 SK_FAR *)(pVal))[0]; \
1833 SK_IN16((IoC), XMA((Mac), (Reg)), &Word); \
1834 pByte[0] = (SK_U8)(Word & 0x00ff); \
1835 pByte[1] = (SK_U8)((Word >> 8) & 0x00ff); \
1836 SK_IN16((IoC), XMA((Mac), (Reg+2)), &Word); \
1837 pByte[2] = (SK_U8)(Word & 0x00ff); \
1838 pByte[3] = (SK_U8)((Word >> 8) & 0x00ff); \
1839 SK_IN16((IoC), XMA((Mac), (Reg+4)), &Word); \
1840 pByte[4] = (SK_U8)(Word & 0x00ff); \
1841 pByte[5] = (SK_U8)((Word >> 8) & 0x00ff); \
1842 SK_IN16((IoC), XMA((Mac), (Reg+6)), &Word); \
1843 pByte[6] = (SK_U8)(Word & 0x00ff); \
1844 pByte[7] = (SK_U8)((Word >> 8) & 0x00ff); \
1845}
1846
1847#define XM_OUTHASH(IoC, Mac, Reg, pVal) { \
1848 SK_U8 SK_FAR *pByte; \
1849 pByte = (SK_U8 SK_FAR *)&((SK_U8 SK_FAR *)(pVal))[0]; \
1850 SK_OUT16((IoC), XMA((Mac), (Reg)), (SK_U16) \
1851 (((SK_U16)(pByte[0]) & 0x00ff)| \
1852 (((SK_U16)(pByte[1]) << 8) & 0xff00))); \
1853 SK_OUT16((IoC), XMA((Mac), (Reg+2)), (SK_U16) \
1854 (((SK_U16)(pByte[2]) & 0x00ff)| \
1855 (((SK_U16)(pByte[3]) << 8) & 0xff00))); \
1856 SK_OUT16((IoC), XMA((Mac), (Reg+4)), (SK_U16) \
1857 (((SK_U16)(pByte[4]) & 0x00ff)| \
1858 (((SK_U16)(pByte[5]) << 8) & 0xff00))); \
1859 SK_OUT16((IoC), XMA((Mac), (Reg+6)), (SK_U16) \
1860 (((SK_U16)(pByte[6]) & 0x00ff)| \
1861 (((SK_U16)(pByte[7]) << 8) & 0xff00))); \
1862}
1863
1864/*
1865 * macros to access the GMAC (YUKON only)
1866 *
1867 * GM_IN16(), to read a 16 bit register (e.g. GM_GP_STAT)
1868 * GM_OUT16(), to write a 16 bit register (e.g. GM_GP_CTRL)
1869 * GM_IN32(), to read a 32 bit register (e.g. GM_)
1870 * GM_OUT32(), to write a 32 bit register (e.g. GM_)
1871 * GM_INADDR(), to read a network address register (e.g. GM_SRC_ADDR_1L)
1872 * GM_OUTADDR(), to write a network address register (e.g. GM_SRC_ADDR_2L)
1873 * GM_INHASH(), to read the GM_MC_ADDR_H1 register
1874 * GM_OUTHASH() to write the GM_MC_ADDR_H1 register
1875 *
1876 * para:
1877 * Mac GMAC to access values: MAC_1 or MAC_2
1878 * IoC I/O context needed for SK I/O macros
1879 * Reg GMAC Register to read or write
1880 * (p)Val Value or pointer to the value which should be read or written
1881 *
1882 * usage: GM_OUT16(IoC, MAC_1, GM_GP_CTRL, Value);
1883 */
1884
1885#define GMA(Mac, Reg) \
1886 ((BASE_GMAC_1 + (Mac) * (BASE_GMAC_2 - BASE_GMAC_1)) | (Reg))
1887
1888#define GM_IN16(IoC, Mac, Reg, pVal) \
1889 SK_IN16((IoC), GMA((Mac), (Reg)), (pVal))
1890
1891#define GM_OUT16(IoC, Mac, Reg, Val) \
1892 SK_OUT16((IoC), GMA((Mac), (Reg)), (Val))
1893
1894#define GM_IN32(IoC, Mac, Reg, pVal) { \
1895 SK_IN16((IoC), GMA((Mac), (Reg)), \
1896 (SK_U16 SK_FAR*)&((SK_U16 SK_FAR*)(pVal))[XM_WORD_LO]); \
1897 SK_IN16((IoC), GMA((Mac), (Reg+4)), \
1898 (SK_U16 SK_FAR*)&((SK_U16 SK_FAR*)(pVal))[XM_WORD_HI]); \
1899}
1900
1901#define GM_OUT32(IoC, Mac, Reg, Val) { \
1902 SK_OUT16((IoC), GMA((Mac), (Reg)), (SK_U16)((Val) & 0xffffL)); \
1903 SK_OUT16((IoC), GMA((Mac), (Reg+4)), (SK_U16)(((Val) >> 16) & 0xffffL));\
1904}
1905
1906#define GM_INADDR(IoC, Mac, Reg, pVal) { \
1907 SK_U16 Word; \
1908 SK_U8 *pByte; \
1909 pByte = (SK_U8 *)&((SK_U8 *)(pVal))[0]; \
1910 SK_IN16((IoC), GMA((Mac), (Reg)), &Word); \
1911 pByte[0] = (SK_U8)(Word & 0x00ff); \
1912 pByte[1] = (SK_U8)((Word >> 8) & 0x00ff); \
1913 SK_IN16((IoC), GMA((Mac), (Reg+4)), &Word); \
1914 pByte[2] = (SK_U8)(Word & 0x00ff); \
1915 pByte[3] = (SK_U8)((Word >> 8) & 0x00ff); \
1916 SK_IN16((IoC), GMA((Mac), (Reg+8)), &Word); \
1917 pByte[4] = (SK_U8)(Word & 0x00ff); \
1918 pByte[5] = (SK_U8)((Word >> 8) & 0x00ff); \
1919}
1920
1921#define GM_OUTADDR(IoC, Mac, Reg, pVal) { \
1922 SK_U8 SK_FAR *pByte; \
1923 pByte = (SK_U8 SK_FAR *)&((SK_U8 SK_FAR *)(pVal))[0]; \
1924 SK_OUT16((IoC), GMA((Mac), (Reg)), (SK_U16) \
1925 (((SK_U16)(pByte[0]) & 0x00ff) | \
1926 (((SK_U16)(pByte[1]) << 8) & 0xff00))); \
1927 SK_OUT16((IoC), GMA((Mac), (Reg+4)), (SK_U16) \
1928 (((SK_U16)(pByte[2]) & 0x00ff) | \
1929 (((SK_U16)(pByte[3]) << 8) & 0xff00))); \
1930 SK_OUT16((IoC), GMA((Mac), (Reg+8)), (SK_U16) \
1931 (((SK_U16)(pByte[4]) & 0x00ff) | \
1932 (((SK_U16)(pByte[5]) << 8) & 0xff00))); \
1933}
1934
1935#define GM_INHASH(IoC, Mac, Reg, pVal) { \
1936 SK_U16 Word; \
1937 SK_U8 *pByte; \
1938 pByte = (SK_U8 *)&((SK_U8 *)(pVal))[0]; \
1939 SK_IN16((IoC), GMA((Mac), (Reg)), &Word); \
1940 pByte[0] = (SK_U8)(Word & 0x00ff); \
1941 pByte[1] = (SK_U8)((Word >> 8) & 0x00ff); \
1942 SK_IN16((IoC), GMA((Mac), (Reg+4)), &Word); \
1943 pByte[2] = (SK_U8)(Word & 0x00ff); \
1944 pByte[3] = (SK_U8)((Word >> 8) & 0x00ff); \
1945 SK_IN16((IoC), GMA((Mac), (Reg+8)), &Word); \
1946 pByte[4] = (SK_U8)(Word & 0x00ff); \
1947 pByte[5] = (SK_U8)((Word >> 8) & 0x00ff); \
1948 SK_IN16((IoC), GMA((Mac), (Reg+12)), &Word); \
1949 pByte[6] = (SK_U8)(Word & 0x00ff); \
1950 pByte[7] = (SK_U8)((Word >> 8) & 0x00ff); \
1951}
1952
1953#define GM_OUTHASH(IoC, Mac, Reg, pVal) { \
1954 SK_U8 *pByte; \
1955 pByte = (SK_U8 *)&((SK_U8 *)(pVal))[0]; \
1956 SK_OUT16((IoC), GMA((Mac), (Reg)), (SK_U16) \
1957 (((SK_U16)(pByte[0]) & 0x00ff)| \
1958 (((SK_U16)(pByte[1]) << 8) & 0xff00))); \
1959 SK_OUT16((IoC), GMA((Mac), (Reg+4)), (SK_U16) \
1960 (((SK_U16)(pByte[2]) & 0x00ff)| \
1961 (((SK_U16)(pByte[3]) << 8) & 0xff00))); \
1962 SK_OUT16((IoC), GMA((Mac), (Reg+8)), (SK_U16) \
1963 (((SK_U16)(pByte[4]) & 0x00ff)| \
1964 (((SK_U16)(pByte[5]) << 8) & 0xff00))); \
1965 SK_OUT16((IoC), GMA((Mac), (Reg+12)), (SK_U16) \
1966 (((SK_U16)(pByte[6]) & 0x00ff)| \
1967 (((SK_U16)(pByte[7]) << 8) & 0xff00))); \
1968}
1969
1970/*
1971 * Different MAC Types
1972 */
1973#define SK_MAC_XMAC 0 /* Xaqti XMAC II */
1974#define SK_MAC_GMAC 1 /* Marvell GMAC */
1975
1976/*
1977 * Different PHY Types
1978 */
1979#define SK_PHY_XMAC 0 /* integrated in XMAC II */
1980#define SK_PHY_BCOM 1 /* Broadcom BCM5400 */
1981#define SK_PHY_LONE 2 /* Level One LXT1000 */
1982#define SK_PHY_NAT 3 /* National DP83891 */
1983#define SK_PHY_MARV_COPPER 4 /* Marvell 88E1011S */
1984#define SK_PHY_MARV_FIBER 5 /* Marvell 88E1011S working on fiber */
1985
1986/*
1987 * PHY addresses (bits 12..8 of PHY address reg)
1988 */
1989#define PHY_ADDR_XMAC (0<<8)
1990#define PHY_ADDR_BCOM (1<<8)
1991#define PHY_ADDR_LONE (3<<8)
1992#define PHY_ADDR_NAT (0<<8)
1993
1994/* GPHY address (bits 15..11 of SMI control reg) */
1995#define PHY_ADDR_MARV 0
1996
1997/*
1998 * macros to access the PHY
1999 *
2000 * PHY_READ() read a 16 bit value from the PHY
2001 * PHY_WRITE() write a 16 bit value to the PHY
2002 *
2003 * para:
2004 * IoC I/O context needed for SK I/O macros
2005 * pPort Pointer to port struct for PhyAddr
2006 * Mac XMAC to access values: MAC_1 or MAC_2
2007 * PhyReg PHY Register to read or write
2008 * (p)Val Value or pointer to the value which should be read or
2009 * written.
2010 *
2011 * usage: PHY_READ(IoC, pPort, MAC_1, PHY_CTRL, Value);
2012 * Warning: a PHY_READ on an uninitialized PHY (PHY still in reset) never
2013 * comes back. This is checked in DEBUG mode.
2014 */
2015#ifndef DEBUG
2016#define PHY_READ(IoC, pPort, Mac, PhyReg, pVal) { \
2017 SK_U16 Mmu; \
2018 \
2019 XM_OUT16((IoC), (Mac), XM_PHY_ADDR, (PhyReg) | (pPort)->PhyAddr); \
2020 XM_IN16((IoC), (Mac), XM_PHY_DATA, (pVal)); \
2021 if ((pPort)->PhyType != SK_PHY_XMAC) { \
2022 do { \
2023 XM_IN16((IoC), (Mac), XM_MMU_CMD, &Mmu); \
2024 } while ((Mmu & XM_MMU_PHY_RDY) == 0); \
2025 XM_IN16((IoC), (Mac), XM_PHY_DATA, (pVal)); \
2026 } \
2027}
2028#else
2029#define PHY_READ(IoC, pPort, Mac, PhyReg, pVal) { \
2030 SK_U16 Mmu; \
2031 int __i = 0; \
2032 \
2033 XM_OUT16((IoC), (Mac), XM_PHY_ADDR, (PhyReg) | (pPort)->PhyAddr); \
2034 XM_IN16((IoC), (Mac), XM_PHY_DATA, (pVal)); \
2035 if ((pPort)->PhyType != SK_PHY_XMAC) { \
2036 do { \
2037 XM_IN16((IoC), (Mac), XM_MMU_CMD, &Mmu); \
2038 __i++; \
2039 if (__i > 100000) { \
2040 SK_DBG_PRINTF("*****************************\n"); \
2041 SK_DBG_PRINTF("PHY_READ on uninitialized PHY\n"); \
2042 SK_DBG_PRINTF("*****************************\n"); \
2043 break; \
2044 } \
2045 } while ((Mmu & XM_MMU_PHY_RDY) == 0); \
2046 XM_IN16((IoC), (Mac), XM_PHY_DATA, (pVal)); \
2047 } \
2048}
2049#endif /* DEBUG */
2050
2051#define PHY_WRITE(IoC, pPort, Mac, PhyReg, Val) { \
2052 SK_U16 Mmu; \
2053 \
2054 if ((pPort)->PhyType != SK_PHY_XMAC) { \
2055 do { \
2056 XM_IN16((IoC), (Mac), XM_MMU_CMD, &Mmu); \
2057 } while ((Mmu & XM_MMU_PHY_BUSY) != 0); \
2058 } \
2059 XM_OUT16((IoC), (Mac), XM_PHY_ADDR, (PhyReg) | (pPort)->PhyAddr); \
2060 XM_OUT16((IoC), (Mac), XM_PHY_DATA, (Val)); \
2061 if ((pPort)->PhyType != SK_PHY_XMAC) { \
2062 do { \
2063 XM_IN16((IoC), (Mac), XM_MMU_CMD, &Mmu); \
2064 } while ((Mmu & XM_MMU_PHY_BUSY) != 0); \
2065 } \
2066}
2067
2068/*
2069 * Macro PCI_C()
2070 *
2071 * Use this macro to access PCI config register from the I/O space.
2072 *
2073 * para:
2074 * Addr PCI configuration register to access.
2075 * Values: PCI_VENDOR_ID ... PCI_VPD_ADR_REG,
2076 *
2077 * usage SK_IN16(pAC, PCI_C(PCI_VENDOR_ID), pVal);
2078 */
2079#define PCI_C(Addr) (B7_CFG_SPC + (Addr)) /* PCI Config Space */
2080
2081/*
2082 * Macro SK_HW_ADDR(Base, Addr)
2083 *
2084 * Calculates the effective HW address
2085 *
2086 * para:
2087 * Base I/O or memory base address
2088 * Addr Address offset
2089 *
2090 * usage: May be used in SK_INxx and SK_OUTxx macros
2091 * #define SK_IN8(pAC, Addr, pVal) ...\
2092 * *pVal = (SK_U8)inp(SK_HW_ADDR(pAC->Hw.Iop, Addr)))
2093 */
2094#ifdef SK_MEM_MAPPED_IO
2095#define SK_HW_ADDR(Base, Addr) ((Base) + (Addr))
2096#else /* SK_MEM_MAPPED_IO */
2097#define SK_HW_ADDR(Base, Addr) \
2098 ((Base) + (((Addr) & 0x7f) | (((Addr) >> 7 > 0) ? 0x80 : 0)))
2099#endif /* SK_MEM_MAPPED_IO */
2100
2101#define SZ_LONG (sizeof(SK_U32))
2102
2103/*
2104 * Macro SK_HWAC_LINK_LED()
2105 *
2106 * Use this macro to set the link LED mode.
2107 * para:
2108 * pAC Pointer to adapter context struct
2109 * IoC I/O context needed for SK I/O macros
2110 * Port Port number
2111 * Mode Mode to set for this LED
2112 */
2113#define SK_HWAC_LINK_LED(pAC, IoC, Port, Mode) \
2114 SK_OUT8(IoC, MR_ADDR(Port, LNK_LED_REG), Mode);
2115
2116
2117/* typedefs *******************************************************************/
2118
2119
2120/* function prototypes ********************************************************/
2121
2122#ifdef __cplusplus
2123}
2124#endif /* __cplusplus */
2125
2126#endif /* __INC_SKGEHW_H */
diff --git a/drivers/net/sk98lin/h/skgehwt.h b/drivers/net/sk98lin/h/skgehwt.h
new file mode 100644
index 000000000000..e6b0016a695c
--- /dev/null
+++ b/drivers/net/sk98lin/h/skgehwt.h
@@ -0,0 +1,48 @@
1/******************************************************************************
2 *
3 * Name: skhwt.h
4 * Project: Gigabit Ethernet Adapters, Event Scheduler Module
5 * Version: $Revision: 1.7 $
6 * Date: $Date: 2003/09/16 12:55:08 $
7 * Purpose: Defines for the hardware timer functions
8 *
9 ******************************************************************************/
10
11/******************************************************************************
12 *
13 * (C)Copyright 1998-2002 SysKonnect GmbH.
14 * (C)Copyright 2002-2003 Marvell.
15 *
16 * This program is free software; you can redistribute it and/or modify
17 * it under the terms of the GNU General Public License as published by
18 * the Free Software Foundation; either version 2 of the License, or
19 * (at your option) any later version.
20 *
21 * The information in this file is provided "AS IS" without warranty.
22 *
23 ******************************************************************************/
24
25/*
26 * SKGEHWT.H contains all defines and types for the timer functions
27 */
28
29#ifndef _SKGEHWT_H_
30#define _SKGEHWT_H_
31
32/*
33 * SK Hardware Timer
34 * - needed wherever the HWT module is used
35 * - use in Adapters context name pAC->Hwt
36 */
37typedef struct s_Hwt {
38 SK_U32 TStart; /* HWT start */
39 SK_U32 TStop; /* HWT stop */
40 int TActive; /* HWT: flag : active/inactive */
41} SK_HWT;
42
43extern void SkHwtInit(SK_AC *pAC, SK_IOC Ioc);
44extern void SkHwtStart(SK_AC *pAC, SK_IOC Ioc, SK_U32 Time);
45extern void SkHwtStop(SK_AC *pAC, SK_IOC Ioc);
46extern SK_U32 SkHwtRead(SK_AC *pAC, SK_IOC Ioc);
47extern void SkHwtIsr(SK_AC *pAC, SK_IOC Ioc);
48#endif /* _SKGEHWT_H_ */
diff --git a/drivers/net/sk98lin/h/skgei2c.h b/drivers/net/sk98lin/h/skgei2c.h
new file mode 100644
index 000000000000..d9b6f6d8dfe2
--- /dev/null
+++ b/drivers/net/sk98lin/h/skgei2c.h
@@ -0,0 +1,210 @@
1/******************************************************************************
2 *
3 * Name: skgei2c.h
4 * Project: Gigabit Ethernet Adapters, TWSI-Module
5 * Version: $Revision: 1.25 $
6 * Date: $Date: 2003/10/20 09:06:05 $
7 * Purpose: Special defines for TWSI
8 *
9 ******************************************************************************/
10
11/******************************************************************************
12 *
13 * (C)Copyright 1998-2002 SysKonnect.
14 * (C)Copyright 2002-2003 Marvell.
15 *
16 * This program is free software; you can redistribute it and/or modify
17 * it under the terms of the GNU General Public License as published by
18 * the Free Software Foundation; either version 2 of the License, or
19 * (at your option) any later version.
20 *
21 * The information in this file is provided "AS IS" without warranty.
22 *
23 ******************************************************************************/
24
25/*
26 * SKGEI2C.H contains all SK-98xx specific defines for the TWSI handling
27 */
28
29#ifndef _INC_SKGEI2C_H_
30#define _INC_SKGEI2C_H_
31
32/*
33 * Macros to access the B2_I2C_CTRL
34 */
35#define SK_I2C_CTL(IoC, flag, dev, dev_size, reg, burst) \
36 SK_OUT32(IoC, B2_I2C_CTRL,\
37 (flag ? 0x80000000UL : 0x0L) | \
38 (((SK_U32)reg << 16) & I2C_ADDR) | \
39 (((SK_U32)dev << 9) & I2C_DEV_SEL) | \
40 (dev_size & I2C_DEV_SIZE) | \
41 ((burst << 4) & I2C_BURST_LEN))
42
43#define SK_I2C_STOP(IoC) { \
44 SK_U32 I2cCtrl; \
45 SK_IN32(IoC, B2_I2C_CTRL, &I2cCtrl); \
46 SK_OUT32(IoC, B2_I2C_CTRL, I2cCtrl | I2C_STOP); \
47}
48
49#define SK_I2C_GET_CTL(IoC, pI2cCtrl) SK_IN32(IoC, B2_I2C_CTRL, pI2cCtrl)
50
51/*
52 * Macros to access the TWSI SW Registers
53 */
54#define SK_I2C_SET_BIT(IoC, SetBits) { \
55 SK_U8 OrgBits; \
56 SK_IN8(IoC, B2_I2C_SW, &OrgBits); \
57 SK_OUT8(IoC, B2_I2C_SW, OrgBits | (SK_U8)(SetBits)); \
58}
59
60#define SK_I2C_CLR_BIT(IoC, ClrBits) { \
61 SK_U8 OrgBits; \
62 SK_IN8(IoC, B2_I2C_SW, &OrgBits); \
63 SK_OUT8(IoC, B2_I2C_SW, OrgBits & ~((SK_U8)(ClrBits))); \
64}
65
66#define SK_I2C_GET_SW(IoC, pI2cSw) SK_IN8(IoC, B2_I2C_SW, pI2cSw)
67
68/*
69 * define the possible sensor states
70 */
71#define SK_SEN_IDLE 0 /* Idle: sensor not read */
72#define SK_SEN_VALUE 1 /* Value Read cycle */
73#define SK_SEN_VALEXT 2 /* Extended Value Read cycle */
74
75/*
76 * Conversion factor to convert read Voltage sensor to milli Volt
77 * Conversion factor to convert read Temperature sensor to 10th degree Celsius
78 */
79#define SK_LM80_VT_LSB 22 /* 22mV LSB resolution */
80#define SK_LM80_TEMP_LSB 10 /* 1 degree LSB resolution */
81#define SK_LM80_TEMPEXT_LSB 5 /* 0.5 degree LSB resolution for ext. val. */
82
83/*
84 * formula: counter = (22500*60)/(rpm * divisor * pulses/2)
85 * assuming: 6500rpm, 4 pulses, divisor 1
86 */
87#define SK_LM80_FAN_FAKTOR ((22500L*60)/(1*2))
88
89/*
90 * Define sensor management data
91 * Maximum is reached on Genesis copper dual port and Yukon-64
92 * Board specific maximum is in pAC->I2c.MaxSens
93 */
94#define SK_MAX_SENSORS 8 /* maximal no. of installed sensors */
95#define SK_MIN_SENSORS 5 /* minimal no. of installed sensors */
96
97/*
98 * To watch the state machine (SM) use the timer in two ways
99 * instead of one as hitherto
100 */
101#define SK_TIMER_WATCH_SM 0 /* Watch the SM to finish in a spec. time */
102#define SK_TIMER_NEW_GAUGING 1 /* Start a new gauging when timer expires */
103
104/*
105 * Defines for the individual thresholds
106 */
107
108/* Temperature sensor */
109#define SK_SEN_TEMP_HIGH_ERR 800 /* Temperature High Err Threshold */
110#define SK_SEN_TEMP_HIGH_WARN 700 /* Temperature High Warn Threshold */
111#define SK_SEN_TEMP_LOW_WARN 100 /* Temperature Low Warn Threshold */
112#define SK_SEN_TEMP_LOW_ERR 0 /* Temperature Low Err Threshold */
113
114/* VCC which should be 5 V */
115#define SK_SEN_PCI_5V_HIGH_ERR 5588 /* Voltage PCI High Err Threshold */
116#define SK_SEN_PCI_5V_HIGH_WARN 5346 /* Voltage PCI High Warn Threshold */
117#define SK_SEN_PCI_5V_LOW_WARN 4664 /* Voltage PCI Low Warn Threshold */
118#define SK_SEN_PCI_5V_LOW_ERR 4422 /* Voltage PCI Low Err Threshold */
119
120/*
121 * VIO may be 5 V or 3.3 V. Initialization takes two parts:
122 * 1. Initialize lowest lower limit and highest higher limit.
123 * 2. After the first value is read correct the upper or the lower limit to
124 * the appropriate C constant.
125 *
126 * Warning limits are +-5% of the exepected voltage.
127 * Error limits are +-10% of the expected voltage.
128 */
129
130/* Bug fix AF: 16.Aug.2001: Correct the init base of LM80 sensor */
131
132#define SK_SEN_PCI_IO_5V_HIGH_ERR 5566 /* + 10% V PCI-IO High Err Threshold */
133#define SK_SEN_PCI_IO_5V_HIGH_WARN 5324 /* + 5% V PCI-IO High Warn Threshold */
134 /* 5000 mVolt */
135#define SK_SEN_PCI_IO_5V_LOW_WARN 4686 /* - 5% V PCI-IO Low Warn Threshold */
136#define SK_SEN_PCI_IO_5V_LOW_ERR 4444 /* - 10% V PCI-IO Low Err Threshold */
137
138#define SK_SEN_PCI_IO_RANGE_LIMITER 4000 /* 4000 mV range delimiter */
139
140/* correction values for the second pass */
141#define SK_SEN_PCI_IO_3V3_HIGH_ERR 3850 /* + 15% V PCI-IO High Err Threshold */
142#define SK_SEN_PCI_IO_3V3_HIGH_WARN 3674 /* + 10% V PCI-IO High Warn Threshold */
143 /* 3300 mVolt */
144#define SK_SEN_PCI_IO_3V3_LOW_WARN 2926 /* - 10% V PCI-IO Low Warn Threshold */
145#define SK_SEN_PCI_IO_3V3_LOW_ERR 2772 /* - 15% V PCI-IO Low Err Threshold */
146
147/*
148 * VDD voltage
149 */
150#define SK_SEN_VDD_HIGH_ERR 3630 /* Voltage ASIC High Err Threshold */
151#define SK_SEN_VDD_HIGH_WARN 3476 /* Voltage ASIC High Warn Threshold */
152#define SK_SEN_VDD_LOW_WARN 3146 /* Voltage ASIC Low Warn Threshold */
153#define SK_SEN_VDD_LOW_ERR 2970 /* Voltage ASIC Low Err Threshold */
154
155/*
156 * PHY PLL 3V3 voltage
157 */
158#define SK_SEN_PLL_3V3_HIGH_ERR 3630 /* Voltage PMA High Err Threshold */
159#define SK_SEN_PLL_3V3_HIGH_WARN 3476 /* Voltage PMA High Warn Threshold */
160#define SK_SEN_PLL_3V3_LOW_WARN 3146 /* Voltage PMA Low Warn Threshold */
161#define SK_SEN_PLL_3V3_LOW_ERR 2970 /* Voltage PMA Low Err Threshold */
162
163/*
164 * VAUX (YUKON only)
165 */
166#define SK_SEN_VAUX_3V3_HIGH_ERR 3630 /* Voltage VAUX High Err Threshold */
167#define SK_SEN_VAUX_3V3_HIGH_WARN 3476 /* Voltage VAUX High Warn Threshold */
168#define SK_SEN_VAUX_3V3_LOW_WARN 3146 /* Voltage VAUX Low Warn Threshold */
169#define SK_SEN_VAUX_3V3_LOW_ERR 2970 /* Voltage VAUX Low Err Threshold */
170#define SK_SEN_VAUX_0V_WARN_ERR 0 /* if VAUX not present */
171#define SK_SEN_VAUX_RANGE_LIMITER 1000 /* 1000 mV range delimiter */
172
173/*
174 * PHY 2V5 voltage
175 */
176#define SK_SEN_PHY_2V5_HIGH_ERR 2750 /* Voltage PHY High Err Threshold */
177#define SK_SEN_PHY_2V5_HIGH_WARN 2640 /* Voltage PHY High Warn Threshold */
178#define SK_SEN_PHY_2V5_LOW_WARN 2376 /* Voltage PHY Low Warn Threshold */
179#define SK_SEN_PHY_2V5_LOW_ERR 2222 /* Voltage PHY Low Err Threshold */
180
181/*
182 * ASIC Core 1V5 voltage (YUKON only)
183 */
184#define SK_SEN_CORE_1V5_HIGH_ERR 1650 /* Voltage ASIC Core High Err Threshold */
185#define SK_SEN_CORE_1V5_HIGH_WARN 1575 /* Voltage ASIC Core High Warn Threshold */
186#define SK_SEN_CORE_1V5_LOW_WARN 1425 /* Voltage ASIC Core Low Warn Threshold */
187#define SK_SEN_CORE_1V5_LOW_ERR 1350 /* Voltage ASIC Core Low Err Threshold */
188
189/*
190 * FAN 1 speed
191 */
192/* assuming: 6500rpm +-15%, 4 pulses,
193 * warning at: 80 %
194 * error at: 70 %
195 * no upper limit
196 */
197#define SK_SEN_FAN_HIGH_ERR 20000 /* FAN Speed High Err Threshold */
198#define SK_SEN_FAN_HIGH_WARN 20000 /* FAN Speed High Warn Threshold */
199#define SK_SEN_FAN_LOW_WARN 5200 /* FAN Speed Low Warn Threshold */
200#define SK_SEN_FAN_LOW_ERR 4550 /* FAN Speed Low Err Threshold */
201
202/*
203 * Some Voltages need dynamic thresholds
204 */
205#define SK_SEN_DYN_INIT_NONE 0 /* No dynamic init of thresholds */
206#define SK_SEN_DYN_INIT_PCI_IO 10 /* Init PCI-IO with new thresholds */
207#define SK_SEN_DYN_INIT_VAUX 11 /* Init VAUX with new thresholds */
208
209extern int SkLm80ReadSensor(SK_AC *pAC, SK_IOC IoC, SK_SENSOR *pSen);
210#endif /* n_INC_SKGEI2C_H */
diff --git a/drivers/net/sk98lin/h/skgeinit.h b/drivers/net/sk98lin/h/skgeinit.h
new file mode 100644
index 000000000000..143e635ec24d
--- /dev/null
+++ b/drivers/net/sk98lin/h/skgeinit.h
@@ -0,0 +1,797 @@
1/******************************************************************************
2 *
3 * Name: skgeinit.h
4 * Project: Gigabit Ethernet Adapters, Common Modules
5 * Version: $Revision: 1.83 $
6 * Date: $Date: 2003/09/16 14:07:37 $
7 * Purpose: Structures and prototypes for the GE Init Module
8 *
9 ******************************************************************************/
10
11/******************************************************************************
12 *
13 * (C)Copyright 1998-2002 SysKonnect.
14 * (C)Copyright 2002-2003 Marvell.
15 *
16 * This program is free software; you can redistribute it and/or modify
17 * it under the terms of the GNU General Public License as published by
18 * the Free Software Foundation; either version 2 of the License, or
19 * (at your option) any later version.
20 *
21 * The information in this file is provided "AS IS" without warranty.
22 *
23 ******************************************************************************/
24
25#ifndef __INC_SKGEINIT_H_
26#define __INC_SKGEINIT_H_
27
28#ifdef __cplusplus
29extern "C" {
30#endif /* __cplusplus */
31
32/* defines ********************************************************************/
33
34#define SK_TEST_VAL 0x11335577UL
35
36/* modifying Link LED behaviour (used with SkGeLinkLED()) */
37#define SK_LNK_OFF LED_OFF
38#define SK_LNK_ON (LED_ON | LED_BLK_OFF | LED_SYNC_OFF)
39#define SK_LNK_BLINK (LED_ON | LED_BLK_ON | LED_SYNC_ON)
40#define SK_LNK_PERM (LED_ON | LED_BLK_OFF | LED_SYNC_ON)
41#define SK_LNK_TST (LED_ON | LED_BLK_ON | LED_SYNC_OFF)
42
43/* parameter 'Mode' when calling SK_HWAC_LINK_LED() */
44#define SK_LED_OFF LED_OFF
45#define SK_LED_ACTIVE (LED_ON | LED_BLK_OFF | LED_SYNC_OFF)
46#define SK_LED_STANDBY (LED_ON | LED_BLK_ON | LED_SYNC_OFF)
47
48/* addressing LED Registers in SkGeXmitLED() */
49#define XMIT_LED_INI 0
50#define XMIT_LED_CNT (RX_LED_VAL - RX_LED_INI)
51#define XMIT_LED_CTRL (RX_LED_CTRL- RX_LED_INI)
52#define XMIT_LED_TST (RX_LED_TST - RX_LED_INI)
53
54/* parameter 'Mode' when calling SkGeXmitLED() */
55#define SK_LED_DIS 0
56#define SK_LED_ENA 1
57#define SK_LED_TST 2
58
59/* Counter and Timer constants, for a host clock of 62.5 MHz */
60#define SK_XMIT_DUR 0x002faf08UL /* 50 ms */
61#define SK_BLK_DUR 0x01dcd650UL /* 500 ms */
62
63#define SK_DPOLL_DEF 0x00ee6b28UL /* 250 ms at 62.5 MHz */
64
65#define SK_DPOLL_MAX 0x00ffffffUL /* 268 ms at 62.5 MHz */
66 /* 215 ms at 78.12 MHz */
67
68#define SK_FACT_62 100 /* is given in percent */
69#define SK_FACT_53 85 /* on GENESIS: 53.12 MHz */
70#define SK_FACT_78 125 /* on YUKON: 78.12 MHz */
71
72/* Timeout values */
73#define SK_MAC_TO_53 72 /* MAC arbiter timeout */
74#define SK_PKT_TO_53 0x2000 /* Packet arbiter timeout */
75#define SK_PKT_TO_MAX 0xffff /* Maximum value */
76#define SK_RI_TO_53 36 /* RAM interface timeout */
77
78#define SK_PHY_ACC_TO 600000 /* PHY access timeout */
79
80/* RAM Buffer High Pause Threshold values */
81#define SK_RB_ULPP ( 8 * 1024) /* Upper Level in kB/8 */
82#define SK_RB_LLPP_S (10 * 1024) /* Lower Level for small Queues */
83#define SK_RB_LLPP_B (16 * 1024) /* Lower Level for big Queues */
84
85#ifndef SK_BMU_RX_WM
86#define SK_BMU_RX_WM 0x600 /* BMU Rx Watermark */
87#endif
88#ifndef SK_BMU_TX_WM
89#define SK_BMU_TX_WM 0x600 /* BMU Tx Watermark */
90#endif
91
92/* XMAC II Rx High Watermark */
93#define SK_XM_RX_HI_WM 0x05aa /* 1450 */
94
95/* XMAC II Tx Threshold */
96#define SK_XM_THR_REDL 0x01fb /* .. for redundant link usage */
97#define SK_XM_THR_SL 0x01fb /* .. for single link adapters */
98#define SK_XM_THR_MULL 0x01fb /* .. for multiple link usage */
99#define SK_XM_THR_JUMBO 0x03fc /* .. for jumbo frame usage */
100
101/* values for GIPortUsage */
102#define SK_RED_LINK 1 /* redundant link usage */
103#define SK_MUL_LINK 2 /* multiple link usage */
104#define SK_JUMBO_LINK 3 /* driver uses jumbo frames */
105
106/* Minimum RAM Buffer Rx Queue Size */
107#define SK_MIN_RXQ_SIZE 16 /* 16 kB */
108
109/* Minimum RAM Buffer Tx Queue Size */
110#define SK_MIN_TXQ_SIZE 16 /* 16 kB */
111
112/* Queue Size units */
113#define QZ_UNITS 0x7
114#define QZ_STEP 8
115
116/* Percentage of queue size from whole memory */
117/* 80 % for receive */
118#define RAM_QUOTA_RX 80L
119/* 0% for sync transfer */
120#define RAM_QUOTA_SYNC 0L
121/* the rest (20%) is taken for async transfer */
122
123/* Get the rounded queue size in Bytes in 8k steps */
124#define ROUND_QUEUE_SIZE(SizeInBytes) \
125 ((((unsigned long) (SizeInBytes) + (QZ_STEP*1024L)-1) / 1024) & \
126 ~(QZ_STEP-1))
127
128/* Get the rounded queue size in KBytes in 8k steps */
129#define ROUND_QUEUE_SIZE_KB(Kilobytes) \
130 ROUND_QUEUE_SIZE((Kilobytes) * 1024L)
131
132/* Types of RAM Buffer Queues */
133#define SK_RX_SRAM_Q 1 /* small receive queue */
134#define SK_RX_BRAM_Q 2 /* big receive queue */
135#define SK_TX_RAM_Q 3 /* small or big transmit queue */
136
137/* parameter 'Dir' when calling SkGeStopPort() */
138#define SK_STOP_TX 1 /* Stops the transmit path, resets the XMAC */
139#define SK_STOP_RX 2 /* Stops the receive path */
140#define SK_STOP_ALL 3 /* Stops Rx and Tx path, resets the XMAC */
141
142/* parameter 'RstMode' when calling SkGeStopPort() */
143#define SK_SOFT_RST 1 /* perform a software reset */
144#define SK_HARD_RST 2 /* perform a hardware reset */
145
146/* Init Levels */
147#define SK_INIT_DATA 0 /* Init level 0: init data structures */
148#define SK_INIT_IO 1 /* Init level 1: init with IOs */
149#define SK_INIT_RUN 2 /* Init level 2: init for run time */
150
151/* Link Mode Parameter */
152#define SK_LMODE_HALF 1 /* Half Duplex Mode */
153#define SK_LMODE_FULL 2 /* Full Duplex Mode */
154#define SK_LMODE_AUTOHALF 3 /* AutoHalf Duplex Mode */
155#define SK_LMODE_AUTOFULL 4 /* AutoFull Duplex Mode */
156#define SK_LMODE_AUTOBOTH 5 /* AutoBoth Duplex Mode */
157#define SK_LMODE_AUTOSENSE 6 /* configured mode auto sensing */
158#define SK_LMODE_INDETERMINATED 7 /* indeterminated */
159
160/* Auto-negotiation timeout in 100ms granularity */
161#define SK_AND_MAX_TO 6 /* Wait 600 msec before link comes up */
162
163/* Auto-negotiation error codes */
164#define SK_AND_OK 0 /* no error */
165#define SK_AND_OTHER 1 /* other error than below */
166#define SK_AND_DUP_CAP 2 /* Duplex capabilities error */
167
168
169/* Link Speed Capabilities */
170#define SK_LSPEED_CAP_AUTO (1<<0) /* Automatic resolution */
171#define SK_LSPEED_CAP_10MBPS (1<<1) /* 10 Mbps */
172#define SK_LSPEED_CAP_100MBPS (1<<2) /* 100 Mbps */
173#define SK_LSPEED_CAP_1000MBPS (1<<3) /* 1000 Mbps */
174#define SK_LSPEED_CAP_INDETERMINATED (1<<4) /* indeterminated */
175
176/* Link Speed Parameter */
177#define SK_LSPEED_AUTO 1 /* Automatic resolution */
178#define SK_LSPEED_10MBPS 2 /* 10 Mbps */
179#define SK_LSPEED_100MBPS 3 /* 100 Mbps */
180#define SK_LSPEED_1000MBPS 4 /* 1000 Mbps */
181#define SK_LSPEED_INDETERMINATED 5 /* indeterminated */
182
183/* Link Speed Current State */
184#define SK_LSPEED_STAT_UNKNOWN 1
185#define SK_LSPEED_STAT_10MBPS 2
186#define SK_LSPEED_STAT_100MBPS 3
187#define SK_LSPEED_STAT_1000MBPS 4
188#define SK_LSPEED_STAT_INDETERMINATED 5
189
190
191/* Link Capability Parameter */
192#define SK_LMODE_CAP_HALF (1<<0) /* Half Duplex Mode */
193#define SK_LMODE_CAP_FULL (1<<1) /* Full Duplex Mode */
194#define SK_LMODE_CAP_AUTOHALF (1<<2) /* AutoHalf Duplex Mode */
195#define SK_LMODE_CAP_AUTOFULL (1<<3) /* AutoFull Duplex Mode */
196#define SK_LMODE_CAP_INDETERMINATED (1<<4) /* indeterminated */
197
198/* Link Mode Current State */
199#define SK_LMODE_STAT_UNKNOWN 1 /* Unknown Duplex Mode */
200#define SK_LMODE_STAT_HALF 2 /* Half Duplex Mode */
201#define SK_LMODE_STAT_FULL 3 /* Full Duplex Mode */
202#define SK_LMODE_STAT_AUTOHALF 4 /* Half Duplex Mode obtained by Auto-Neg */
203#define SK_LMODE_STAT_AUTOFULL 5 /* Full Duplex Mode obtained by Auto-Neg */
204#define SK_LMODE_STAT_INDETERMINATED 6 /* indeterminated */
205
206/* Flow Control Mode Parameter (and capabilities) */
207#define SK_FLOW_MODE_NONE 1 /* No Flow-Control */
208#define SK_FLOW_MODE_LOC_SEND 2 /* Local station sends PAUSE */
209#define SK_FLOW_MODE_SYMMETRIC 3 /* Both stations may send PAUSE */
210#define SK_FLOW_MODE_SYM_OR_REM 4 /* Both stations may send PAUSE or
211 * just the remote station may send PAUSE
212 */
213#define SK_FLOW_MODE_INDETERMINATED 5 /* indeterminated */
214
215/* Flow Control Status Parameter */
216#define SK_FLOW_STAT_NONE 1 /* No Flow Control */
217#define SK_FLOW_STAT_REM_SEND 2 /* Remote Station sends PAUSE */
218#define SK_FLOW_STAT_LOC_SEND 3 /* Local station sends PAUSE */
219#define SK_FLOW_STAT_SYMMETRIC 4 /* Both station may send PAUSE */
220#define SK_FLOW_STAT_INDETERMINATED 5 /* indeterminated */
221
222/* Master/Slave Mode Capabilities */
223#define SK_MS_CAP_AUTO (1<<0) /* Automatic resolution */
224#define SK_MS_CAP_MASTER (1<<1) /* This station is master */
225#define SK_MS_CAP_SLAVE (1<<2) /* This station is slave */
226#define SK_MS_CAP_INDETERMINATED (1<<3) /* indeterminated */
227
228/* Set Master/Slave Mode Parameter (and capabilities) */
229#define SK_MS_MODE_AUTO 1 /* Automatic resolution */
230#define SK_MS_MODE_MASTER 2 /* This station is master */
231#define SK_MS_MODE_SLAVE 3 /* This station is slave */
232#define SK_MS_MODE_INDETERMINATED 4 /* indeterminated */
233
234/* Master/Slave Status Parameter */
235#define SK_MS_STAT_UNSET 1 /* The M/S status is not set */
236#define SK_MS_STAT_MASTER 2 /* This station is master */
237#define SK_MS_STAT_SLAVE 3 /* This station is slave */
238#define SK_MS_STAT_FAULT 4 /* M/S resolution failed */
239#define SK_MS_STAT_INDETERMINATED 5 /* indeterminated */
240
241/* parameter 'Mode' when calling SkXmSetRxCmd() */
242#define SK_STRIP_FCS_ON (1<<0) /* Enable FCS stripping of Rx frames */
243#define SK_STRIP_FCS_OFF (1<<1) /* Disable FCS stripping of Rx frames */
244#define SK_STRIP_PAD_ON (1<<2) /* Enable pad byte stripping of Rx fr */
245#define SK_STRIP_PAD_OFF (1<<3) /* Disable pad byte stripping of Rx fr */
246#define SK_LENERR_OK_ON (1<<4) /* Don't chk fr for in range len error */
247#define SK_LENERR_OK_OFF (1<<5) /* Check frames for in range len error */
248#define SK_BIG_PK_OK_ON (1<<6) /* Don't set Rx Error bit for big frames */
249#define SK_BIG_PK_OK_OFF (1<<7) /* Set Rx Error bit for big frames */
250#define SK_SELF_RX_ON (1<<8) /* Enable Rx of own packets */
251#define SK_SELF_RX_OFF (1<<9) /* Disable Rx of own packets */
252
253/* parameter 'Para' when calling SkMacSetRxTxEn() */
254#define SK_MAC_LOOPB_ON (1<<0) /* Enable MAC Loopback Mode */
255#define SK_MAC_LOOPB_OFF (1<<1) /* Disable MAC Loopback Mode */
256#define SK_PHY_LOOPB_ON (1<<2) /* Enable PHY Loopback Mode */
257#define SK_PHY_LOOPB_OFF (1<<3) /* Disable PHY Loopback Mode */
258#define SK_PHY_FULLD_ON (1<<4) /* Enable GMII Full Duplex */
259#define SK_PHY_FULLD_OFF (1<<5) /* Disable GMII Full Duplex */
260
261/* States of PState */
262#define SK_PRT_RESET 0 /* the port is reset */
263#define SK_PRT_STOP 1 /* the port is stopped (similar to SW reset) */
264#define SK_PRT_INIT 2 /* the port is initialized */
265#define SK_PRT_RUN 3 /* the port has an active link */
266
267/* PHY power down modes */
268#define PHY_PM_OPERATIONAL_MODE 0 /* PHY operational mode */
269#define PHY_PM_DEEP_SLEEP 1 /* coma mode --> minimal power */
270#define PHY_PM_IEEE_POWER_DOWN 2 /* IEEE 22.2.4.1.5 compl. power down */
271#define PHY_PM_ENERGY_DETECT 3 /* energy detect */
272#define PHY_PM_ENERGY_DETECT_PLUS 4 /* energy detect plus */
273
274/* Default receive frame limit for Workaround of XMAC Errata */
275#define SK_DEF_RX_WA_LIM SK_CONSTU64(100)
276
277/* values for GILedBlinkCtrl (LED Blink Control) */
278#define SK_ACT_LED_BLINK (1<<0) /* Active LED blinking */
279#define SK_DUP_LED_NORMAL (1<<1) /* Duplex LED normal */
280#define SK_LED_LINK100_ON (1<<2) /* Link 100M LED on */
281
282/* Link Partner Status */
283#define SK_LIPA_UNKNOWN 0 /* Link partner is in unknown state */
284#define SK_LIPA_MANUAL 1 /* Link partner is in detected manual state */
285#define SK_LIPA_AUTO 2 /* Link partner is in auto-negotiation state */
286
287/* Maximum Restarts before restart is ignored (3Com WA) */
288#define SK_MAX_LRESTART 3 /* Max. 3 times the link is restarted */
289
290/* Max. Auto-neg. timeouts before link detection in sense mode is reset */
291#define SK_MAX_ANEG_TO 10 /* Max. 10 times the sense mode is reset */
292
293/* structures *****************************************************************/
294
295/*
296 * MAC specific functions
297 */
298typedef struct s_GeMacFunc {
299 int (*pFnMacUpdateStats)(SK_AC *pAC, SK_IOC IoC, unsigned int Port);
300 int (*pFnMacStatistic)(SK_AC *pAC, SK_IOC IoC, unsigned int Port,
301 SK_U16 StatAddr, SK_U32 SK_FAR *pVal);
302 int (*pFnMacResetCounter)(SK_AC *pAC, SK_IOC IoC, unsigned int Port);
303 int (*pFnMacOverflow)(SK_AC *pAC, SK_IOC IoC, unsigned int Port,
304 SK_U16 IStatus, SK_U64 SK_FAR *pVal);
305} SK_GEMACFUNC;
306
307/*
308 * Port Structure
309 */
310typedef struct s_GePort {
311#ifndef SK_DIAG
312 SK_TIMER PWaTimer; /* Workaround Timer */
313 SK_TIMER HalfDupChkTimer;
314#endif /* SK_DIAG */
315 SK_U32 PPrevShorts; /* Previous Short Counter checking */
316 SK_U32 PPrevFcs; /* Previous FCS Error Counter checking */
317 SK_U64 PPrevRx; /* Previous RxOk Counter checking */
318 SK_U64 PRxLim; /* Previous RxOk Counter checking */
319 SK_U64 LastOctets; /* For half duplex hang check */
320 int PLinkResCt; /* Link Restart Counter */
321 int PAutoNegTimeOut;/* Auto-negotiation timeout current value */
322 int PAutoNegTOCt; /* Auto-negotiation Timeout Counter */
323 int PRxQSize; /* Port Rx Queue Size in kB */
324 int PXSQSize; /* Port Synchronous Transmit Queue Size in kB */
325 int PXAQSize; /* Port Asynchronous Transmit Queue Size in kB */
326 SK_U32 PRxQRamStart; /* Receive Queue RAM Buffer Start Address */
327 SK_U32 PRxQRamEnd; /* Receive Queue RAM Buffer End Address */
328 SK_U32 PXsQRamStart; /* Sync Tx Queue RAM Buffer Start Address */
329 SK_U32 PXsQRamEnd; /* Sync Tx Queue RAM Buffer End Address */
330 SK_U32 PXaQRamStart; /* Async Tx Queue RAM Buffer Start Address */
331 SK_U32 PXaQRamEnd; /* Async Tx Queue RAM Buffer End Address */
332 SK_U32 PRxOverCnt; /* Receive Overflow Counter */
333 int PRxQOff; /* Rx Queue Address Offset */
334 int PXsQOff; /* Synchronous Tx Queue Address Offset */
335 int PXaQOff; /* Asynchronous Tx Queue Address Offset */
336 int PhyType; /* PHY used on this port */
337 int PState; /* Port status (reset, stop, init, run) */
338 SK_U16 PhyId1; /* PHY Id1 on this port */
339 SK_U16 PhyAddr; /* MDIO/MDC PHY address */
340 SK_U16 PIsave; /* Saved Interrupt status word */
341 SK_U16 PSsave; /* Saved PHY status word */
342 SK_U16 PGmANegAdv; /* Saved GPhy AutoNegAdvertisment register */
343 SK_BOOL PHWLinkUp; /* The hardware Link is up (wiring) */
344 SK_BOOL PLinkBroken; /* Is Link broken ? */
345 SK_BOOL PCheckPar; /* Do we check for parity errors ? */
346 SK_BOOL HalfDupTimerActive;
347 SK_U8 PLinkCap; /* Link Capabilities */
348 SK_U8 PLinkModeConf; /* Link Mode configured */
349 SK_U8 PLinkMode; /* Link Mode currently used */
350 SK_U8 PLinkModeStatus;/* Link Mode Status */
351 SK_U8 PLinkSpeedCap; /* Link Speed Capabilities(10/100/1000 Mbps) */
352 SK_U8 PLinkSpeed; /* configured Link Speed (10/100/1000 Mbps) */
353 SK_U8 PLinkSpeedUsed; /* current Link Speed (10/100/1000 Mbps) */
354 SK_U8 PFlowCtrlCap; /* Flow Control Capabilities */
355 SK_U8 PFlowCtrlMode; /* Flow Control Mode */
356 SK_U8 PFlowCtrlStatus;/* Flow Control Status */
357 SK_U8 PMSCap; /* Master/Slave Capabilities */
358 SK_U8 PMSMode; /* Master/Slave Mode */
359 SK_U8 PMSStatus; /* Master/Slave Status */
360 SK_BOOL PAutoNegFail; /* Auto-negotiation fail flag */
361 SK_U8 PLipaAutoNeg; /* Auto-negotiation possible with Link Partner */
362 SK_U8 PCableLen; /* Cable Length */
363 SK_U8 PMdiPairLen[4]; /* MDI[0..3] Pair Length */
364 SK_U8 PMdiPairSts[4]; /* MDI[0..3] Pair Diagnostic Status */
365 SK_U8 PPhyPowerState; /* PHY current power state */
366 int PMacColThres; /* MAC Collision Threshold */
367 int PMacJamLen; /* MAC Jam length */
368 int PMacJamIpgVal; /* MAC Jam IPG */
369 int PMacJamIpgData; /* MAC IPG Jam to Data */
370 int PMacIpgData; /* MAC Data IPG */
371 SK_BOOL PMacLimit4; /* reset collision counter and backoff algorithm */
372} SK_GEPORT;
373
374/*
375 * Gigabit Ethernet Initialization Struct
376 * (has to be included in the adapter context)
377 */
378typedef struct s_GeInit {
379 int GIChipId; /* Chip Identification Number */
380 int GIChipRev; /* Chip Revision Number */
381 SK_U8 GIPciHwRev; /* PCI HW Revision Number */
382 SK_BOOL GIGenesis; /* Genesis adapter ? */
383 SK_BOOL GIYukon; /* YUKON-A1/Bx chip */
384 SK_BOOL GIYukonLite; /* YUKON-Lite chip */
385 SK_BOOL GICopperType; /* Copper Type adapter ? */
386 SK_BOOL GIPciSlot64; /* 64-bit PCI Slot */
387 SK_BOOL GIPciClock66; /* 66 MHz PCI Clock */
388 SK_BOOL GIVauxAvail; /* VAUX available (YUKON) */
389 SK_BOOL GIYukon32Bit; /* 32-Bit YUKON adapter */
390 SK_U16 GILedBlinkCtrl; /* LED Blink Control */
391 int GIMacsFound; /* Number of MACs found on this adapter */
392 int GIMacType; /* MAC Type used on this adapter */
393 int GIHstClkFact; /* Host Clock Factor (62.5 / HstClk * 100) */
394 int GIPortUsage; /* Driver Port Usage */
395 int GILevel; /* Initialization Level completed */
396 int GIRamSize; /* The RAM size of the adapter in kB */
397 int GIWolOffs; /* WOL Register Offset (HW-Bug in Rev. A) */
398 SK_U32 GIRamOffs; /* RAM Address Offset for addr calculation */
399 SK_U32 GIPollTimerVal; /* Descr. Poll Timer Init Val (HstClk ticks) */
400 SK_U32 GIValIrqMask; /* Value for Interrupt Mask */
401 SK_U32 GITimeStampCnt; /* Time Stamp High Counter (YUKON only) */
402 SK_GEPORT GP[SK_MAX_MACS];/* Port Dependent Information */
403 SK_GEMACFUNC GIFunc; /* MAC depedent functions */
404} SK_GEINIT;
405
406/*
407 * Error numbers and messages for skxmac2.c and skgeinit.c
408 */
409#define SKERR_HWI_E001 (SK_ERRBASE_HWINIT)
410#define SKERR_HWI_E001MSG "SkXmClrExactAddr() has got illegal parameters"
411#define SKERR_HWI_E002 (SKERR_HWI_E001+1)
412#define SKERR_HWI_E002MSG "SkGeInit(): Level 1 call missing"
413#define SKERR_HWI_E003 (SKERR_HWI_E002+1)
414#define SKERR_HWI_E003MSG "SkGeInit() called with illegal init Level"
415#define SKERR_HWI_E004 (SKERR_HWI_E003+1)
416#define SKERR_HWI_E004MSG "SkGeInitPort(): Queue Size illegal configured"
417#define SKERR_HWI_E005 (SKERR_HWI_E004+1)
418#define SKERR_HWI_E005MSG "SkGeInitPort(): cannot init running ports"
419#define SKERR_HWI_E006 (SKERR_HWI_E005+1)
420#define SKERR_HWI_E006MSG "SkGeMacInit(): PState does not match HW state"
421#define SKERR_HWI_E007 (SKERR_HWI_E006+1)
422#define SKERR_HWI_E007MSG "SkXmInitDupMd() called with invalid Dup Mode"
423#define SKERR_HWI_E008 (SKERR_HWI_E007+1)
424#define SKERR_HWI_E008MSG "SkXmSetRxCmd() called with invalid Mode"
425#define SKERR_HWI_E009 (SKERR_HWI_E008+1)
426#define SKERR_HWI_E009MSG "SkGeCfgSync() called although PXSQSize zero"
427#define SKERR_HWI_E010 (SKERR_HWI_E009+1)
428#define SKERR_HWI_E010MSG "SkGeCfgSync() called with invalid parameters"
429#define SKERR_HWI_E011 (SKERR_HWI_E010+1)
430#define SKERR_HWI_E011MSG "SkGeInitPort(): Receive Queue Size too small"
431#define SKERR_HWI_E012 (SKERR_HWI_E011+1)
432#define SKERR_HWI_E012MSG "SkGeInitPort(): invalid Queue Size specified"
433#define SKERR_HWI_E013 (SKERR_HWI_E012+1)
434#define SKERR_HWI_E013MSG "SkGeInitPort(): cfg changed for running queue"
435#define SKERR_HWI_E014 (SKERR_HWI_E013+1)
436#define SKERR_HWI_E014MSG "SkGeInitPort(): unknown GIPortUsage specified"
437#define SKERR_HWI_E015 (SKERR_HWI_E014+1)
438#define SKERR_HWI_E015MSG "Illegal Link mode parameter"
439#define SKERR_HWI_E016 (SKERR_HWI_E015+1)
440#define SKERR_HWI_E016MSG "Illegal Flow control mode parameter"
441#define SKERR_HWI_E017 (SKERR_HWI_E016+1)
442#define SKERR_HWI_E017MSG "Illegal value specified for GIPollTimerVal"
443#define SKERR_HWI_E018 (SKERR_HWI_E017+1)
444#define SKERR_HWI_E018MSG "FATAL: SkGeStopPort() does not terminate (Tx)"
445#define SKERR_HWI_E019 (SKERR_HWI_E018+1)
446#define SKERR_HWI_E019MSG "Illegal Speed parameter"
447#define SKERR_HWI_E020 (SKERR_HWI_E019+1)
448#define SKERR_HWI_E020MSG "Illegal Master/Slave parameter"
449#define SKERR_HWI_E021 (SKERR_HWI_E020+1)
450#define SKERR_HWI_E021MSG "MacUpdateStats(): cannot update statistic counter"
451#define SKERR_HWI_E022 (SKERR_HWI_E021+1)
452#define SKERR_HWI_E022MSG "MacStatistic(): illegal statistic base address"
453#define SKERR_HWI_E023 (SKERR_HWI_E022+1)
454#define SKERR_HWI_E023MSG "SkGeInitPort(): Transmit Queue Size too small"
455#define SKERR_HWI_E024 (SKERR_HWI_E023+1)
456#define SKERR_HWI_E024MSG "FATAL: SkGeStopPort() does not terminate (Rx)"
457#define SKERR_HWI_E025 (SKERR_HWI_E024+1)
458#define SKERR_HWI_E025MSG ""
459
460/* function prototypes ********************************************************/
461
462#ifndef SK_KR_PROTO
463
464/*
465 * public functions in skgeinit.c
466 */
467extern void SkGePollTxD(
468 SK_AC *pAC,
469 SK_IOC IoC,
470 int Port,
471 SK_BOOL PollTxD);
472
473extern void SkGeYellowLED(
474 SK_AC *pAC,
475 SK_IOC IoC,
476 int State);
477
478extern int SkGeCfgSync(
479 SK_AC *pAC,
480 SK_IOC IoC,
481 int Port,
482 SK_U32 IntTime,
483 SK_U32 LimCount,
484 int SyncMode);
485
486extern void SkGeLoadLnkSyncCnt(
487 SK_AC *pAC,
488 SK_IOC IoC,
489 int Port,
490 SK_U32 CntVal);
491
492extern void SkGeStopPort(
493 SK_AC *pAC,
494 SK_IOC IoC,
495 int Port,
496 int Dir,
497 int RstMode);
498
499extern int SkGeInit(
500 SK_AC *pAC,
501 SK_IOC IoC,
502 int Level);
503
504extern void SkGeDeInit(
505 SK_AC *pAC,
506 SK_IOC IoC);
507
508extern int SkGeInitPort(
509 SK_AC *pAC,
510 SK_IOC IoC,
511 int Port);
512
513extern void SkGeXmitLED(
514 SK_AC *pAC,
515 SK_IOC IoC,
516 int Led,
517 int Mode);
518
519extern int SkGeInitAssignRamToQueues(
520 SK_AC *pAC,
521 int ActivePort,
522 SK_BOOL DualNet);
523
524/*
525 * public functions in skxmac2.c
526 */
527extern void SkMacRxTxDisable(
528 SK_AC *pAC,
529 SK_IOC IoC,
530 int Port);
531
532extern void SkMacSoftRst(
533 SK_AC *pAC,
534 SK_IOC IoC,
535 int Port);
536
537extern void SkMacHardRst(
538 SK_AC *pAC,
539 SK_IOC IoC,
540 int Port);
541
542extern void SkXmInitMac(
543 SK_AC *pAC,
544 SK_IOC IoC,
545 int Port);
546
547extern void SkGmInitMac(
548 SK_AC *pAC,
549 SK_IOC IoC,
550 int Port);
551
552extern void SkMacInitPhy(
553 SK_AC *pAC,
554 SK_IOC IoC,
555 int Port,
556 SK_BOOL DoLoop);
557
558extern void SkMacIrqDisable(
559 SK_AC *pAC,
560 SK_IOC IoC,
561 int Port);
562
563extern void SkMacFlushTxFifo(
564 SK_AC *pAC,
565 SK_IOC IoC,
566 int Port);
567
568extern void SkMacIrq(
569 SK_AC *pAC,
570 SK_IOC IoC,
571 int Port);
572
573extern int SkMacAutoNegDone(
574 SK_AC *pAC,
575 SK_IOC IoC,
576 int Port);
577
578extern void SkMacAutoNegLipaPhy(
579 SK_AC *pAC,
580 SK_IOC IoC,
581 int Port,
582 SK_U16 IStatus);
583
584extern int SkMacRxTxEnable(
585 SK_AC *pAC,
586 SK_IOC IoC,
587 int Port);
588
589extern void SkMacPromiscMode(
590 SK_AC *pAC,
591 SK_IOC IoC,
592 int Port,
593 SK_BOOL Enable);
594
595extern void SkMacHashing(
596 SK_AC *pAC,
597 SK_IOC IoC,
598 int Port,
599 SK_BOOL Enable);
600
601extern void SkXmPhyRead(
602 SK_AC *pAC,
603 SK_IOC IoC,
604 int Port,
605 int Addr,
606 SK_U16 SK_FAR *pVal);
607
608extern void SkXmPhyWrite(
609 SK_AC *pAC,
610 SK_IOC IoC,
611 int Port,
612 int Addr,
613 SK_U16 Val);
614
615extern void SkGmPhyRead(
616 SK_AC *pAC,
617 SK_IOC IoC,
618 int Port,
619 int Addr,
620 SK_U16 SK_FAR *pVal);
621
622extern void SkGmPhyWrite(
623 SK_AC *pAC,
624 SK_IOC IoC,
625 int Port,
626 int Addr,
627 SK_U16 Val);
628
629extern void SkXmClrExactAddr(
630 SK_AC *pAC,
631 SK_IOC IoC,
632 int Port,
633 int StartNum,
634 int StopNum);
635
636extern void SkXmAutoNegLipaXmac(
637 SK_AC *pAC,
638 SK_IOC IoC,
639 int Port,
640 SK_U16 IStatus);
641
642extern int SkXmUpdateStats(
643 SK_AC *pAC,
644 SK_IOC IoC,
645 unsigned int Port);
646
647extern int SkGmUpdateStats(
648 SK_AC *pAC,
649 SK_IOC IoC,
650 unsigned int Port);
651
652extern int SkXmMacStatistic(
653 SK_AC *pAC,
654 SK_IOC IoC,
655 unsigned int Port,
656 SK_U16 StatAddr,
657 SK_U32 SK_FAR *pVal);
658
659extern int SkGmMacStatistic(
660 SK_AC *pAC,
661 SK_IOC IoC,
662 unsigned int Port,
663 SK_U16 StatAddr,
664 SK_U32 SK_FAR *pVal);
665
666extern int SkXmResetCounter(
667 SK_AC *pAC,
668 SK_IOC IoC,
669 unsigned int Port);
670
671extern int SkGmResetCounter(
672 SK_AC *pAC,
673 SK_IOC IoC,
674 unsigned int Port);
675
676extern int SkXmOverflowStatus(
677 SK_AC *pAC,
678 SK_IOC IoC,
679 unsigned int Port,
680 SK_U16 IStatus,
681 SK_U64 SK_FAR *pStatus);
682
683extern int SkGmOverflowStatus(
684 SK_AC *pAC,
685 SK_IOC IoC,
686 unsigned int Port,
687 SK_U16 MacStatus,
688 SK_U64 SK_FAR *pStatus);
689
690extern int SkGmCableDiagStatus(
691 SK_AC *pAC,
692 SK_IOC IoC,
693 int Port,
694 SK_BOOL StartTest);
695
696#ifdef SK_DIAG
697extern void SkGePhyRead(
698 SK_AC *pAC,
699 SK_IOC IoC,
700 int Port,
701 int Addr,
702 SK_U16 *pVal);
703
704extern void SkGePhyWrite(
705 SK_AC *pAC,
706 SK_IOC IoC,
707 int Port,
708 int Addr,
709 SK_U16 Val);
710
711extern void SkMacSetRxCmd(
712 SK_AC *pAC,
713 SK_IOC IoC,
714 int Port,
715 int Mode);
716extern void SkMacCrcGener(
717 SK_AC *pAC,
718 SK_IOC IoC,
719 int Port,
720 SK_BOOL Enable);
721extern void SkMacTimeStamp(
722 SK_AC *pAC,
723 SK_IOC IoC,
724 int Port,
725 SK_BOOL Enable);
726extern void SkXmSendCont(
727 SK_AC *pAC,
728 SK_IOC IoC,
729 int Port,
730 SK_BOOL Enable);
731#endif /* SK_DIAG */
732
733#else /* SK_KR_PROTO */
734
735/*
736 * public functions in skgeinit.c
737 */
738extern void SkGePollTxD();
739extern void SkGeYellowLED();
740extern int SkGeCfgSync();
741extern void SkGeLoadLnkSyncCnt();
742extern void SkGeStopPort();
743extern int SkGeInit();
744extern void SkGeDeInit();
745extern int SkGeInitPort();
746extern void SkGeXmitLED();
747extern int SkGeInitAssignRamToQueues();
748
749/*
750 * public functions in skxmac2.c
751 */
752extern void SkMacRxTxDisable();
753extern void SkMacSoftRst();
754extern void SkMacHardRst();
755extern void SkMacInitPhy();
756extern int SkMacRxTxEnable();
757extern void SkMacPromiscMode();
758extern void SkMacHashing();
759extern void SkMacIrqDisable();
760extern void SkMacFlushTxFifo();
761extern void SkMacIrq();
762extern int SkMacAutoNegDone();
763extern void SkMacAutoNegLipaPhy();
764extern void SkXmInitMac();
765extern void SkXmPhyRead();
766extern void SkXmPhyWrite();
767extern void SkGmInitMac();
768extern void SkGmPhyRead();
769extern void SkGmPhyWrite();
770extern void SkXmClrExactAddr();
771extern void SkXmAutoNegLipaXmac();
772extern int SkXmUpdateStats();
773extern int SkGmUpdateStats();
774extern int SkXmMacStatistic();
775extern int SkGmMacStatistic();
776extern int SkXmResetCounter();
777extern int SkGmResetCounter();
778extern int SkXmOverflowStatus();
779extern int SkGmOverflowStatus();
780extern int SkGmCableDiagStatus();
781
782#ifdef SK_DIAG
783extern void SkGePhyRead();
784extern void SkGePhyWrite();
785extern void SkMacSetRxCmd();
786extern void SkMacCrcGener();
787extern void SkMacTimeStamp();
788extern void SkXmSendCont();
789#endif /* SK_DIAG */
790
791#endif /* SK_KR_PROTO */
792
793#ifdef __cplusplus
794}
795#endif /* __cplusplus */
796
797#endif /* __INC_SKGEINIT_H_ */
diff --git a/drivers/net/sk98lin/h/skgepnm2.h b/drivers/net/sk98lin/h/skgepnm2.h
new file mode 100644
index 000000000000..ddd304f1a48b
--- /dev/null
+++ b/drivers/net/sk98lin/h/skgepnm2.h
@@ -0,0 +1,334 @@
1/*****************************************************************************
2 *
3 * Name: skgepnm2.h
4 * Project: GEnesis, PCI Gigabit Ethernet Adapter
5 * Version: $Revision: 1.36 $
6 * Date: $Date: 2003/05/23 12:45:13 $
7 * Purpose: Defines for Private Network Management Interface
8 *
9 ****************************************************************************/
10
11/******************************************************************************
12 *
13 * (C)Copyright 1998-2002 SysKonnect GmbH.
14 * (C)Copyright 2002-2003 Marvell.
15 *
16 * This program is free software; you can redistribute it and/or modify
17 * it under the terms of the GNU General Public License as published by
18 * the Free Software Foundation; either version 2 of the License, or
19 * (at your option) any later version.
20 *
21 * The information in this file is provided "AS IS" without warranty.
22 *
23 ******************************************************************************/
24
25#ifndef _SKGEPNM2_H_
26#define _SKGEPNM2_H_
27
28/*
29 * General definitions
30 */
31#define SK_PNMI_CHIPSET_XMAC 1 /* XMAC11800FP */
32#define SK_PNMI_CHIPSET_YUKON 2 /* YUKON */
33
34#define SK_PNMI_BUS_PCI 1 /* PCI bus*/
35
36/*
37 * Actions
38 */
39#define SK_PNMI_ACT_IDLE 1
40#define SK_PNMI_ACT_RESET 2
41#define SK_PNMI_ACT_SELFTEST 3
42#define SK_PNMI_ACT_RESETCNT 4
43
44/*
45 * VPD releated defines
46 */
47
48#define SK_PNMI_VPD_RW 1
49#define SK_PNMI_VPD_RO 2
50
51#define SK_PNMI_VPD_OK 0
52#define SK_PNMI_VPD_NOTFOUND 1
53#define SK_PNMI_VPD_CUT 2
54#define SK_PNMI_VPD_TIMEOUT 3
55#define SK_PNMI_VPD_FULL 4
56#define SK_PNMI_VPD_NOWRITE 5
57#define SK_PNMI_VPD_FATAL 6
58
59#define SK_PNMI_VPD_IGNORE 0
60#define SK_PNMI_VPD_CREATE 1
61#define SK_PNMI_VPD_DELETE 2
62
63
64/*
65 * RLMT related defines
66 */
67#define SK_PNMI_DEF_RLMT_CHG_THRES 240 /* 4 changes per minute */
68
69
70/*
71 * VCT internal status values
72 */
73#define SK_PNMI_VCT_PENDING 32
74#define SK_PNMI_VCT_TEST_DONE 64
75#define SK_PNMI_VCT_LINK 128
76
77/*
78 * Internal table definitions
79 */
80#define SK_PNMI_GET 0
81#define SK_PNMI_PRESET 1
82#define SK_PNMI_SET 2
83
84#define SK_PNMI_RO 0
85#define SK_PNMI_RW 1
86#define SK_PNMI_WO 2
87
88typedef struct s_OidTabEntry {
89 SK_U32 Id;
90 SK_U32 InstanceNo;
91 unsigned int StructSize;
92 unsigned int Offset;
93 int Access;
94 int (* Func)(SK_AC *pAc, SK_IOC pIo, int action,
95 SK_U32 Id, char* pBuf, unsigned int* pLen,
96 SK_U32 Instance, unsigned int TableIndex,
97 SK_U32 NetNumber);
98 SK_U16 Param;
99} SK_PNMI_TAB_ENTRY;
100
101
102/*
103 * Trap lengths
104 */
105#define SK_PNMI_TRAP_SIMPLE_LEN 17
106#define SK_PNMI_TRAP_SENSOR_LEN_BASE 46
107#define SK_PNMI_TRAP_RLMT_CHANGE_LEN 23
108#define SK_PNMI_TRAP_RLMT_PORT_LEN 23
109
110/*
111 * Number of MAC types supported
112 */
113#define SK_PNMI_MAC_TYPES (SK_MAC_GMAC + 1)
114
115/*
116 * MAC statistic data list (overall set for MAC types used)
117 */
118enum SK_MACSTATS {
119 SK_PNMI_HTX = 0,
120 SK_PNMI_HTX_OCTET,
121 SK_PNMI_HTX_OCTETHIGH = SK_PNMI_HTX_OCTET,
122 SK_PNMI_HTX_OCTETLOW,
123 SK_PNMI_HTX_BROADCAST,
124 SK_PNMI_HTX_MULTICAST,
125 SK_PNMI_HTX_UNICAST,
126 SK_PNMI_HTX_BURST,
127 SK_PNMI_HTX_PMACC,
128 SK_PNMI_HTX_MACC,
129 SK_PNMI_HTX_COL,
130 SK_PNMI_HTX_SINGLE_COL,
131 SK_PNMI_HTX_MULTI_COL,
132 SK_PNMI_HTX_EXCESS_COL,
133 SK_PNMI_HTX_LATE_COL,
134 SK_PNMI_HTX_DEFFERAL,
135 SK_PNMI_HTX_EXCESS_DEF,
136 SK_PNMI_HTX_UNDERRUN,
137 SK_PNMI_HTX_CARRIER,
138 SK_PNMI_HTX_UTILUNDER,
139 SK_PNMI_HTX_UTILOVER,
140 SK_PNMI_HTX_64,
141 SK_PNMI_HTX_127,
142 SK_PNMI_HTX_255,
143 SK_PNMI_HTX_511,
144 SK_PNMI_HTX_1023,
145 SK_PNMI_HTX_MAX,
146 SK_PNMI_HTX_LONGFRAMES,
147 SK_PNMI_HTX_SYNC,
148 SK_PNMI_HTX_SYNC_OCTET,
149 SK_PNMI_HTX_RESERVED,
150
151 SK_PNMI_HRX,
152 SK_PNMI_HRX_OCTET,
153 SK_PNMI_HRX_OCTETHIGH = SK_PNMI_HRX_OCTET,
154 SK_PNMI_HRX_OCTETLOW,
155 SK_PNMI_HRX_BADOCTET,
156 SK_PNMI_HRX_BADOCTETHIGH = SK_PNMI_HRX_BADOCTET,
157 SK_PNMI_HRX_BADOCTETLOW,
158 SK_PNMI_HRX_BROADCAST,
159 SK_PNMI_HRX_MULTICAST,
160 SK_PNMI_HRX_UNICAST,
161 SK_PNMI_HRX_PMACC,
162 SK_PNMI_HRX_MACC,
163 SK_PNMI_HRX_PMACC_ERR,
164 SK_PNMI_HRX_MACC_UNKWN,
165 SK_PNMI_HRX_BURST,
166 SK_PNMI_HRX_MISSED,
167 SK_PNMI_HRX_FRAMING,
168 SK_PNMI_HRX_UNDERSIZE,
169 SK_PNMI_HRX_OVERFLOW,
170 SK_PNMI_HRX_JABBER,
171 SK_PNMI_HRX_CARRIER,
172 SK_PNMI_HRX_IRLENGTH,
173 SK_PNMI_HRX_SYMBOL,
174 SK_PNMI_HRX_SHORTS,
175 SK_PNMI_HRX_RUNT,
176 SK_PNMI_HRX_TOO_LONG,
177 SK_PNMI_HRX_FCS,
178 SK_PNMI_HRX_CEXT,
179 SK_PNMI_HRX_UTILUNDER,
180 SK_PNMI_HRX_UTILOVER,
181 SK_PNMI_HRX_64,
182 SK_PNMI_HRX_127,
183 SK_PNMI_HRX_255,
184 SK_PNMI_HRX_511,
185 SK_PNMI_HRX_1023,
186 SK_PNMI_HRX_MAX,
187 SK_PNMI_HRX_LONGFRAMES,
188
189 SK_PNMI_HRX_RESERVED,
190
191 SK_PNMI_MAX_IDX /* NOTE: Ensure SK_PNMI_CNT_NO is set to this value */
192};
193
194/*
195 * MAC specific data
196 */
197typedef struct s_PnmiStatAddr {
198 SK_U16 Reg; /* MAC register containing the value */
199 SK_BOOL GetOffset; /* TRUE: Offset managed by PNMI (call GetStatVal())*/
200} SK_PNMI_STATADDR;
201
202
203/*
204 * SK_PNMI_STRUCT_DATA copy offset evaluation macros
205 */
206#define SK_PNMI_OFF(e) ((SK_U32)(SK_UPTR)&(((SK_PNMI_STRUCT_DATA *)0)->e))
207#define SK_PNMI_MAI_OFF(e) ((SK_U32)(SK_UPTR)&(((SK_PNMI_STRUCT_DATA *)0)->e))
208#define SK_PNMI_VPD_OFF(e) ((SK_U32)(SK_UPTR)&(((SK_PNMI_VPD *)0)->e))
209#define SK_PNMI_SEN_OFF(e) ((SK_U32)(SK_UPTR)&(((SK_PNMI_SENSOR *)0)->e))
210#define SK_PNMI_CHK_OFF(e) ((SK_U32)(SK_UPTR)&(((SK_PNMI_CHECKSUM *)0)->e))
211#define SK_PNMI_STA_OFF(e) ((SK_U32)(SK_UPTR)&(((SK_PNMI_STAT *)0)->e))
212#define SK_PNMI_CNF_OFF(e) ((SK_U32)(SK_UPTR)&(((SK_PNMI_CONF *)0)->e))
213#define SK_PNMI_RLM_OFF(e) ((SK_U32)(SK_UPTR)&(((SK_PNMI_RLMT *)0)->e))
214#define SK_PNMI_MON_OFF(e) ((SK_U32)(SK_UPTR)&(((SK_PNMI_RLMT_MONITOR *)0)->e))
215#define SK_PNMI_TRP_OFF(e) ((SK_U32)(SK_UPTR)&(((SK_PNMI_TRAP *)0)->e))
216
217#define SK_PNMI_SET_STAT(b,s,o) {SK_U32 Val32; char *pVal; \
218 Val32 = (s); \
219 pVal = (char *)(b) + ((SK_U32)(SK_UPTR) \
220 &(((SK_PNMI_STRUCT_DATA *)0)-> \
221 ReturnStatus.ErrorStatus)); \
222 SK_PNMI_STORE_U32(pVal, Val32); \
223 Val32 = (o); \
224 pVal = (char *)(b) + ((SK_U32)(SK_UPTR) \
225 &(((SK_PNMI_STRUCT_DATA *)0)-> \
226 ReturnStatus.ErrorOffset)); \
227 SK_PNMI_STORE_U32(pVal, Val32);}
228
229/*
230 * Time macros
231 */
232#ifndef SK_PNMI_HUNDREDS_SEC
233#if SK_TICKS_PER_SEC == 100
234#define SK_PNMI_HUNDREDS_SEC(t) (t)
235#else
236#define SK_PNMI_HUNDREDS_SEC(t) (((t) * 100) / (SK_TICKS_PER_SEC))
237#endif /* !SK_TICKS_PER_SEC */
238#endif /* !SK_PNMI_HUNDREDS_SEC */
239
240/*
241 * Macros to work around alignment problems
242 */
243#ifndef SK_PNMI_STORE_U16
244#define SK_PNMI_STORE_U16(p,v) {*(char *)(p) = *((char *)&(v)); \
245 *((char *)(p) + 1) = \
246 *(((char *)&(v)) + 1);}
247#endif
248
249#ifndef SK_PNMI_STORE_U32
250#define SK_PNMI_STORE_U32(p,v) {*(char *)(p) = *((char *)&(v)); \
251 *((char *)(p) + 1) = \
252 *(((char *)&(v)) + 1); \
253 *((char *)(p) + 2) = \
254 *(((char *)&(v)) + 2); \
255 *((char *)(p) + 3) = \
256 *(((char *)&(v)) + 3);}
257#endif
258
259#ifndef SK_PNMI_STORE_U64
260#define SK_PNMI_STORE_U64(p,v) {*(char *)(p) = *((char *)&(v)); \
261 *((char *)(p) + 1) = \
262 *(((char *)&(v)) + 1); \
263 *((char *)(p) + 2) = \
264 *(((char *)&(v)) + 2); \
265 *((char *)(p) + 3) = \
266 *(((char *)&(v)) + 3); \
267 *((char *)(p) + 4) = \
268 *(((char *)&(v)) + 4); \
269 *((char *)(p) + 5) = \
270 *(((char *)&(v)) + 5); \
271 *((char *)(p) + 6) = \
272 *(((char *)&(v)) + 6); \
273 *((char *)(p) + 7) = \
274 *(((char *)&(v)) + 7);}
275#endif
276
277#ifndef SK_PNMI_READ_U16
278#define SK_PNMI_READ_U16(p,v) {*((char *)&(v)) = *(char *)(p); \
279 *(((char *)&(v)) + 1) = \
280 *((char *)(p) + 1);}
281#endif
282
283#ifndef SK_PNMI_READ_U32
284#define SK_PNMI_READ_U32(p,v) {*((char *)&(v)) = *(char *)(p); \
285 *(((char *)&(v)) + 1) = \
286 *((char *)(p) + 1); \
287 *(((char *)&(v)) + 2) = \
288 *((char *)(p) + 2); \
289 *(((char *)&(v)) + 3) = \
290 *((char *)(p) + 3);}
291#endif
292
293#ifndef SK_PNMI_READ_U64
294#define SK_PNMI_READ_U64(p,v) {*((char *)&(v)) = *(char *)(p); \
295 *(((char *)&(v)) + 1) = \
296 *((char *)(p) + 1); \
297 *(((char *)&(v)) + 2) = \
298 *((char *)(p) + 2); \
299 *(((char *)&(v)) + 3) = \
300 *((char *)(p) + 3); \
301 *(((char *)&(v)) + 4) = \
302 *((char *)(p) + 4); \
303 *(((char *)&(v)) + 5) = \
304 *((char *)(p) + 5); \
305 *(((char *)&(v)) + 6) = \
306 *((char *)(p) + 6); \
307 *(((char *)&(v)) + 7) = \
308 *((char *)(p) + 7);}
309#endif
310
311/*
312 * Macros for Debug
313 */
314#ifdef DEBUG
315
316#define SK_PNMI_CHECKFLAGS(vSt) {if (pAC->Pnmi.MacUpdatedFlag > 0 || \
317 pAC->Pnmi.RlmtUpdatedFlag > 0 || \
318 pAC->Pnmi.SirqUpdatedFlag > 0) { \
319 SK_DBG_MSG(pAC, \
320 SK_DBGMOD_PNMI, \
321 SK_DBGCAT_CTRL, \
322 ("PNMI: ERR: %s MacUFlag=%d, RlmtUFlag=%d, SirqUFlag=%d\n", \
323 vSt, \
324 pAC->Pnmi.MacUpdatedFlag, \
325 pAC->Pnmi.RlmtUpdatedFlag, \
326 pAC->Pnmi.SirqUpdatedFlag))}}
327
328#else /* !DEBUG */
329
330#define SK_PNMI_CHECKFLAGS(vSt) /* Nothing */
331
332#endif /* !DEBUG */
333
334#endif /* _SKGEPNM2_H_ */
diff --git a/drivers/net/sk98lin/h/skgepnmi.h b/drivers/net/sk98lin/h/skgepnmi.h
new file mode 100644
index 000000000000..1ed214ccb253
--- /dev/null
+++ b/drivers/net/sk98lin/h/skgepnmi.h
@@ -0,0 +1,962 @@
1/*****************************************************************************
2 *
3 * Name: skgepnmi.h
4 * Project: GEnesis, PCI Gigabit Ethernet Adapter
5 * Version: $Revision: 1.62 $
6 * Date: $Date: 2003/08/15 12:31:52 $
7 * Purpose: Defines for Private Network Management Interface
8 *
9 ****************************************************************************/
10
11/******************************************************************************
12 *
13 * (C)Copyright 1998-2002 SysKonnect GmbH.
14 * (C)Copyright 2002-2003 Marvell.
15 *
16 * This program is free software; you can redistribute it and/or modify
17 * it under the terms of the GNU General Public License as published by
18 * the Free Software Foundation; either version 2 of the License, or
19 * (at your option) any later version.
20 *
21 * The information in this file is provided "AS IS" without warranty.
22 *
23 ******************************************************************************/
24
25#ifndef _SKGEPNMI_H_
26#define _SKGEPNMI_H_
27
28/*
29 * Include dependencies
30 */
31#include "h/sktypes.h"
32#include "h/skerror.h"
33#include "h/sktimer.h"
34#include "h/ski2c.h"
35#include "h/skaddr.h"
36#include "h/skrlmt.h"
37#include "h/skvpd.h"
38
39/*
40 * Management Database Version
41 */
42#define SK_PNMI_MDB_VERSION 0x00030001 /* 3.1 */
43
44
45/*
46 * Event definitions
47 */
48#define SK_PNMI_EVT_SIRQ_OVERFLOW 1 /* Counter overflow */
49#define SK_PNMI_EVT_SEN_WAR_LOW 2 /* Lower war thres exceeded */
50#define SK_PNMI_EVT_SEN_WAR_UPP 3 /* Upper war thres exceeded */
51#define SK_PNMI_EVT_SEN_ERR_LOW 4 /* Lower err thres exceeded */
52#define SK_PNMI_EVT_SEN_ERR_UPP 5 /* Upper err thres exceeded */
53#define SK_PNMI_EVT_CHG_EST_TIMER 6 /* Timer event for RLMT Chg */
54#define SK_PNMI_EVT_UTILIZATION_TIMER 7 /* Timer event for Utiliza. */
55#define SK_PNMI_EVT_CLEAR_COUNTER 8 /* Clear statistic counters */
56#define SK_PNMI_EVT_XMAC_RESET 9 /* XMAC will be reset */
57
58#define SK_PNMI_EVT_RLMT_PORT_UP 10 /* Port came logically up */
59#define SK_PNMI_EVT_RLMT_PORT_DOWN 11 /* Port went logically down */
60#define SK_PNMI_EVT_RLMT_SEGMENTATION 13 /* Two SP root bridges found */
61#define SK_PNMI_EVT_RLMT_ACTIVE_DOWN 14 /* Port went logically down */
62#define SK_PNMI_EVT_RLMT_ACTIVE_UP 15 /* Port came logically up */
63#define SK_PNMI_EVT_RLMT_SET_NETS 16 /* 1. Parameter is number of nets
64 1 = single net; 2 = dual net */
65#define SK_PNMI_EVT_VCT_RESET 17 /* VCT port reset timer event started with SET. */
66
67
68/*
69 * Return values
70 */
71#define SK_PNMI_ERR_OK 0
72#define SK_PNMI_ERR_GENERAL 1
73#define SK_PNMI_ERR_TOO_SHORT 2
74#define SK_PNMI_ERR_BAD_VALUE 3
75#define SK_PNMI_ERR_READ_ONLY 4
76#define SK_PNMI_ERR_UNKNOWN_OID 5
77#define SK_PNMI_ERR_UNKNOWN_INST 6
78#define SK_PNMI_ERR_UNKNOWN_NET 7
79#define SK_PNMI_ERR_NOT_SUPPORTED 10
80
81
82/*
83 * Return values of driver reset function SK_DRIVER_RESET() and
84 * driver event function SK_DRIVER_EVENT()
85 */
86#define SK_PNMI_ERR_OK 0
87#define SK_PNMI_ERR_FAIL 1
88
89
90/*
91 * Return values of driver test function SK_DRIVER_SELFTEST()
92 */
93#define SK_PNMI_TST_UNKNOWN (1 << 0)
94#define SK_PNMI_TST_TRANCEIVER (1 << 1)
95#define SK_PNMI_TST_ASIC (1 << 2)
96#define SK_PNMI_TST_SENSOR (1 << 3)
97#define SK_PNMI_TST_POWERMGMT (1 << 4)
98#define SK_PNMI_TST_PCI (1 << 5)
99#define SK_PNMI_TST_MAC (1 << 6)
100
101
102/*
103 * RLMT specific definitions
104 */
105#define SK_PNMI_RLMT_STATUS_STANDBY 1
106#define SK_PNMI_RLMT_STATUS_ACTIVE 2
107#define SK_PNMI_RLMT_STATUS_ERROR 3
108
109#define SK_PNMI_RLMT_LSTAT_PHY_DOWN 1
110#define SK_PNMI_RLMT_LSTAT_AUTONEG 2
111#define SK_PNMI_RLMT_LSTAT_LOG_DOWN 3
112#define SK_PNMI_RLMT_LSTAT_LOG_UP 4
113#define SK_PNMI_RLMT_LSTAT_INDETERMINATED 5
114
115#define SK_PNMI_RLMT_MODE_CHK_LINK (SK_RLMT_CHECK_LINK)
116#define SK_PNMI_RLMT_MODE_CHK_RX (SK_RLMT_CHECK_LOC_LINK)
117#define SK_PNMI_RLMT_MODE_CHK_SPT (SK_RLMT_CHECK_SEG)
118/* #define SK_PNMI_RLMT_MODE_CHK_EX */
119
120/*
121 * OID definition
122 */
123#ifndef _NDIS_ /* Check, whether NDIS already included OIDs */
124
125#define OID_GEN_XMIT_OK 0x00020101
126#define OID_GEN_RCV_OK 0x00020102
127#define OID_GEN_XMIT_ERROR 0x00020103
128#define OID_GEN_RCV_ERROR 0x00020104
129#define OID_GEN_RCV_NO_BUFFER 0x00020105
130
131/* #define OID_GEN_DIRECTED_BYTES_XMIT 0x00020201 */
132#define OID_GEN_DIRECTED_FRAMES_XMIT 0x00020202
133/* #define OID_GEN_MULTICAST_BYTES_XMIT 0x00020203 */
134#define OID_GEN_MULTICAST_FRAMES_XMIT 0x00020204
135/* #define OID_GEN_BROADCAST_BYTES_XMIT 0x00020205 */
136#define OID_GEN_BROADCAST_FRAMES_XMIT 0x00020206
137/* #define OID_GEN_DIRECTED_BYTES_RCV 0x00020207 */
138#define OID_GEN_DIRECTED_FRAMES_RCV 0x00020208
139/* #define OID_GEN_MULTICAST_BYTES_RCV 0x00020209 */
140#define OID_GEN_MULTICAST_FRAMES_RCV 0x0002020A
141/* #define OID_GEN_BROADCAST_BYTES_RCV 0x0002020B */
142#define OID_GEN_BROADCAST_FRAMES_RCV 0x0002020C
143#define OID_GEN_RCV_CRC_ERROR 0x0002020D
144#define OID_GEN_TRANSMIT_QUEUE_LENGTH 0x0002020E
145
146#define OID_802_3_PERMANENT_ADDRESS 0x01010101
147#define OID_802_3_CURRENT_ADDRESS 0x01010102
148/* #define OID_802_3_MULTICAST_LIST 0x01010103 */
149/* #define OID_802_3_MAXIMUM_LIST_SIZE 0x01010104 */
150/* #define OID_802_3_MAC_OPTIONS 0x01010105 */
151
152#define OID_802_3_RCV_ERROR_ALIGNMENT 0x01020101
153#define OID_802_3_XMIT_ONE_COLLISION 0x01020102
154#define OID_802_3_XMIT_MORE_COLLISIONS 0x01020103
155#define OID_802_3_XMIT_DEFERRED 0x01020201
156#define OID_802_3_XMIT_MAX_COLLISIONS 0x01020202
157#define OID_802_3_RCV_OVERRUN 0x01020203
158#define OID_802_3_XMIT_UNDERRUN 0x01020204
159#define OID_802_3_XMIT_TIMES_CRS_LOST 0x01020206
160#define OID_802_3_XMIT_LATE_COLLISIONS 0x01020207
161
162/*
163 * PnP and PM OIDs
164 */
165#ifdef SK_POWER_MGMT
166#define OID_PNP_CAPABILITIES 0xFD010100
167#define OID_PNP_SET_POWER 0xFD010101
168#define OID_PNP_QUERY_POWER 0xFD010102
169#define OID_PNP_ADD_WAKE_UP_PATTERN 0xFD010103
170#define OID_PNP_REMOVE_WAKE_UP_PATTERN 0xFD010104
171#define OID_PNP_ENABLE_WAKE_UP 0xFD010106
172#endif /* SK_POWER_MGMT */
173
174#endif /* _NDIS_ */
175
176#define OID_SKGE_MDB_VERSION 0xFF010100
177#define OID_SKGE_SUPPORTED_LIST 0xFF010101
178#define OID_SKGE_VPD_FREE_BYTES 0xFF010102
179#define OID_SKGE_VPD_ENTRIES_LIST 0xFF010103
180#define OID_SKGE_VPD_ENTRIES_NUMBER 0xFF010104
181#define OID_SKGE_VPD_KEY 0xFF010105
182#define OID_SKGE_VPD_VALUE 0xFF010106
183#define OID_SKGE_VPD_ACCESS 0xFF010107
184#define OID_SKGE_VPD_ACTION 0xFF010108
185
186#define OID_SKGE_PORT_NUMBER 0xFF010110
187#define OID_SKGE_DEVICE_TYPE 0xFF010111
188#define OID_SKGE_DRIVER_DESCR 0xFF010112
189#define OID_SKGE_DRIVER_VERSION 0xFF010113
190#define OID_SKGE_HW_DESCR 0xFF010114
191#define OID_SKGE_HW_VERSION 0xFF010115
192#define OID_SKGE_CHIPSET 0xFF010116
193#define OID_SKGE_ACTION 0xFF010117
194#define OID_SKGE_RESULT 0xFF010118
195#define OID_SKGE_BUS_TYPE 0xFF010119
196#define OID_SKGE_BUS_SPEED 0xFF01011A
197#define OID_SKGE_BUS_WIDTH 0xFF01011B
198/* 0xFF01011C unused */
199#define OID_SKGE_DIAG_ACTION 0xFF01011D
200#define OID_SKGE_DIAG_RESULT 0xFF01011E
201#define OID_SKGE_MTU 0xFF01011F
202#define OID_SKGE_PHYS_CUR_ADDR 0xFF010120
203#define OID_SKGE_PHYS_FAC_ADDR 0xFF010121
204#define OID_SKGE_PMD 0xFF010122
205#define OID_SKGE_CONNECTOR 0xFF010123
206#define OID_SKGE_LINK_CAP 0xFF010124
207#define OID_SKGE_LINK_MODE 0xFF010125
208#define OID_SKGE_LINK_MODE_STATUS 0xFF010126
209#define OID_SKGE_LINK_STATUS 0xFF010127
210#define OID_SKGE_FLOWCTRL_CAP 0xFF010128
211#define OID_SKGE_FLOWCTRL_MODE 0xFF010129
212#define OID_SKGE_FLOWCTRL_STATUS 0xFF01012A
213#define OID_SKGE_PHY_OPERATION_CAP 0xFF01012B
214#define OID_SKGE_PHY_OPERATION_MODE 0xFF01012C
215#define OID_SKGE_PHY_OPERATION_STATUS 0xFF01012D
216#define OID_SKGE_MULTICAST_LIST 0xFF01012E
217#define OID_SKGE_CURRENT_PACKET_FILTER 0xFF01012F
218
219#define OID_SKGE_TRAP 0xFF010130
220#define OID_SKGE_TRAP_NUMBER 0xFF010131
221
222#define OID_SKGE_RLMT_MODE 0xFF010140
223#define OID_SKGE_RLMT_PORT_NUMBER 0xFF010141
224#define OID_SKGE_RLMT_PORT_ACTIVE 0xFF010142
225#define OID_SKGE_RLMT_PORT_PREFERRED 0xFF010143
226#define OID_SKGE_INTERMEDIATE_SUPPORT 0xFF010160
227
228#define OID_SKGE_SPEED_CAP 0xFF010170
229#define OID_SKGE_SPEED_MODE 0xFF010171
230#define OID_SKGE_SPEED_STATUS 0xFF010172
231
232#define OID_SKGE_BOARDLEVEL 0xFF010180
233
234#define OID_SKGE_SENSOR_NUMBER 0xFF020100
235#define OID_SKGE_SENSOR_INDEX 0xFF020101
236#define OID_SKGE_SENSOR_DESCR 0xFF020102
237#define OID_SKGE_SENSOR_TYPE 0xFF020103
238#define OID_SKGE_SENSOR_VALUE 0xFF020104
239#define OID_SKGE_SENSOR_WAR_THRES_LOW 0xFF020105
240#define OID_SKGE_SENSOR_WAR_THRES_UPP 0xFF020106
241#define OID_SKGE_SENSOR_ERR_THRES_LOW 0xFF020107
242#define OID_SKGE_SENSOR_ERR_THRES_UPP 0xFF020108
243#define OID_SKGE_SENSOR_STATUS 0xFF020109
244#define OID_SKGE_SENSOR_WAR_CTS 0xFF02010A
245#define OID_SKGE_SENSOR_ERR_CTS 0xFF02010B
246#define OID_SKGE_SENSOR_WAR_TIME 0xFF02010C
247#define OID_SKGE_SENSOR_ERR_TIME 0xFF02010D
248
249#define OID_SKGE_CHKSM_NUMBER 0xFF020110
250#define OID_SKGE_CHKSM_RX_OK_CTS 0xFF020111
251#define OID_SKGE_CHKSM_RX_UNABLE_CTS 0xFF020112
252#define OID_SKGE_CHKSM_RX_ERR_CTS 0xFF020113
253#define OID_SKGE_CHKSM_TX_OK_CTS 0xFF020114
254#define OID_SKGE_CHKSM_TX_UNABLE_CTS 0xFF020115
255
256#define OID_SKGE_STAT_TX 0xFF020120
257#define OID_SKGE_STAT_TX_OCTETS 0xFF020121
258#define OID_SKGE_STAT_TX_BROADCAST 0xFF020122
259#define OID_SKGE_STAT_TX_MULTICAST 0xFF020123
260#define OID_SKGE_STAT_TX_UNICAST 0xFF020124
261#define OID_SKGE_STAT_TX_LONGFRAMES 0xFF020125
262#define OID_SKGE_STAT_TX_BURST 0xFF020126
263#define OID_SKGE_STAT_TX_PFLOWC 0xFF020127
264#define OID_SKGE_STAT_TX_FLOWC 0xFF020128
265#define OID_SKGE_STAT_TX_SINGLE_COL 0xFF020129
266#define OID_SKGE_STAT_TX_MULTI_COL 0xFF02012A
267#define OID_SKGE_STAT_TX_EXCESS_COL 0xFF02012B
268#define OID_SKGE_STAT_TX_LATE_COL 0xFF02012C
269#define OID_SKGE_STAT_TX_DEFFERAL 0xFF02012D
270#define OID_SKGE_STAT_TX_EXCESS_DEF 0xFF02012E
271#define OID_SKGE_STAT_TX_UNDERRUN 0xFF02012F
272#define OID_SKGE_STAT_TX_CARRIER 0xFF020130
273/* #define OID_SKGE_STAT_TX_UTIL 0xFF020131 */
274#define OID_SKGE_STAT_TX_64 0xFF020132
275#define OID_SKGE_STAT_TX_127 0xFF020133
276#define OID_SKGE_STAT_TX_255 0xFF020134
277#define OID_SKGE_STAT_TX_511 0xFF020135
278#define OID_SKGE_STAT_TX_1023 0xFF020136
279#define OID_SKGE_STAT_TX_MAX 0xFF020137
280#define OID_SKGE_STAT_TX_SYNC 0xFF020138
281#define OID_SKGE_STAT_TX_SYNC_OCTETS 0xFF020139
282#define OID_SKGE_STAT_RX 0xFF02013A
283#define OID_SKGE_STAT_RX_OCTETS 0xFF02013B
284#define OID_SKGE_STAT_RX_BROADCAST 0xFF02013C
285#define OID_SKGE_STAT_RX_MULTICAST 0xFF02013D
286#define OID_SKGE_STAT_RX_UNICAST 0xFF02013E
287#define OID_SKGE_STAT_RX_PFLOWC 0xFF02013F
288#define OID_SKGE_STAT_RX_FLOWC 0xFF020140
289#define OID_SKGE_STAT_RX_PFLOWC_ERR 0xFF020141
290#define OID_SKGE_STAT_RX_FLOWC_UNKWN 0xFF020142
291#define OID_SKGE_STAT_RX_BURST 0xFF020143
292#define OID_SKGE_STAT_RX_MISSED 0xFF020144
293#define OID_SKGE_STAT_RX_FRAMING 0xFF020145
294#define OID_SKGE_STAT_RX_OVERFLOW 0xFF020146
295#define OID_SKGE_STAT_RX_JABBER 0xFF020147
296#define OID_SKGE_STAT_RX_CARRIER 0xFF020148
297#define OID_SKGE_STAT_RX_IR_LENGTH 0xFF020149
298#define OID_SKGE_STAT_RX_SYMBOL 0xFF02014A
299#define OID_SKGE_STAT_RX_SHORTS 0xFF02014B
300#define OID_SKGE_STAT_RX_RUNT 0xFF02014C
301#define OID_SKGE_STAT_RX_CEXT 0xFF02014D
302#define OID_SKGE_STAT_RX_TOO_LONG 0xFF02014E
303#define OID_SKGE_STAT_RX_FCS 0xFF02014F
304/* #define OID_SKGE_STAT_RX_UTIL 0xFF020150 */
305#define OID_SKGE_STAT_RX_64 0xFF020151
306#define OID_SKGE_STAT_RX_127 0xFF020152
307#define OID_SKGE_STAT_RX_255 0xFF020153
308#define OID_SKGE_STAT_RX_511 0xFF020154
309#define OID_SKGE_STAT_RX_1023 0xFF020155
310#define OID_SKGE_STAT_RX_MAX 0xFF020156
311#define OID_SKGE_STAT_RX_LONGFRAMES 0xFF020157
312
313#define OID_SKGE_RLMT_CHANGE_CTS 0xFF020160
314#define OID_SKGE_RLMT_CHANGE_TIME 0xFF020161
315#define OID_SKGE_RLMT_CHANGE_ESTIM 0xFF020162
316#define OID_SKGE_RLMT_CHANGE_THRES 0xFF020163
317
318#define OID_SKGE_RLMT_PORT_INDEX 0xFF020164
319#define OID_SKGE_RLMT_STATUS 0xFF020165
320#define OID_SKGE_RLMT_TX_HELLO_CTS 0xFF020166
321#define OID_SKGE_RLMT_RX_HELLO_CTS 0xFF020167
322#define OID_SKGE_RLMT_TX_SP_REQ_CTS 0xFF020168
323#define OID_SKGE_RLMT_RX_SP_CTS 0xFF020169
324
325#define OID_SKGE_RLMT_MONITOR_NUMBER 0xFF010150
326#define OID_SKGE_RLMT_MONITOR_INDEX 0xFF010151
327#define OID_SKGE_RLMT_MONITOR_ADDR 0xFF010152
328#define OID_SKGE_RLMT_MONITOR_ERRS 0xFF010153
329#define OID_SKGE_RLMT_MONITOR_TIMESTAMP 0xFF010154
330#define OID_SKGE_RLMT_MONITOR_ADMIN 0xFF010155
331
332#define OID_SKGE_TX_SW_QUEUE_LEN 0xFF020170
333#define OID_SKGE_TX_SW_QUEUE_MAX 0xFF020171
334#define OID_SKGE_TX_RETRY 0xFF020172
335#define OID_SKGE_RX_INTR_CTS 0xFF020173
336#define OID_SKGE_TX_INTR_CTS 0xFF020174
337#define OID_SKGE_RX_NO_BUF_CTS 0xFF020175
338#define OID_SKGE_TX_NO_BUF_CTS 0xFF020176
339#define OID_SKGE_TX_USED_DESCR_NO 0xFF020177
340#define OID_SKGE_RX_DELIVERED_CTS 0xFF020178
341#define OID_SKGE_RX_OCTETS_DELIV_CTS 0xFF020179
342#define OID_SKGE_RX_HW_ERROR_CTS 0xFF02017A
343#define OID_SKGE_TX_HW_ERROR_CTS 0xFF02017B
344#define OID_SKGE_IN_ERRORS_CTS 0xFF02017C
345#define OID_SKGE_OUT_ERROR_CTS 0xFF02017D
346#define OID_SKGE_ERR_RECOVERY_CTS 0xFF02017E
347#define OID_SKGE_SYSUPTIME 0xFF02017F
348
349#define OID_SKGE_ALL_DATA 0xFF020190
350
351/* Defines for VCT. */
352#define OID_SKGE_VCT_GET 0xFF020200
353#define OID_SKGE_VCT_SET 0xFF020201
354#define OID_SKGE_VCT_STATUS 0xFF020202
355
356#ifdef SK_DIAG_SUPPORT
357/* Defines for driver DIAG mode. */
358#define OID_SKGE_DIAG_MODE 0xFF020204
359#endif /* SK_DIAG_SUPPORT */
360
361/* New OIDs */
362#define OID_SKGE_DRIVER_RELDATE 0xFF020210
363#define OID_SKGE_DRIVER_FILENAME 0xFF020211
364#define OID_SKGE_CHIPID 0xFF020212
365#define OID_SKGE_RAMSIZE 0xFF020213
366#define OID_SKGE_VAUXAVAIL 0xFF020214
367#define OID_SKGE_PHY_TYPE 0xFF020215
368#define OID_SKGE_PHY_LP_MODE 0xFF020216
369
370/* VCT struct to store a backup copy of VCT data after a port reset. */
371typedef struct s_PnmiVct {
372 SK_U8 VctStatus;
373 SK_U8 PCableLen;
374 SK_U32 PMdiPairLen[4];
375 SK_U8 PMdiPairSts[4];
376} SK_PNMI_VCT;
377
378
379/* VCT status values (to be given to CPA via OID_SKGE_VCT_STATUS). */
380#define SK_PNMI_VCT_NONE 0
381#define SK_PNMI_VCT_OLD_VCT_DATA 1
382#define SK_PNMI_VCT_NEW_VCT_DATA 2
383#define SK_PNMI_VCT_OLD_DSP_DATA 4
384#define SK_PNMI_VCT_NEW_DSP_DATA 8
385#define SK_PNMI_VCT_RUNNING 16
386
387
388/* VCT cable test status. */
389#define SK_PNMI_VCT_NORMAL_CABLE 0
390#define SK_PNMI_VCT_SHORT_CABLE 1
391#define SK_PNMI_VCT_OPEN_CABLE 2
392#define SK_PNMI_VCT_TEST_FAIL 3
393#define SK_PNMI_VCT_IMPEDANCE_MISMATCH 4
394
395#define OID_SKGE_TRAP_SEN_WAR_LOW 500
396#define OID_SKGE_TRAP_SEN_WAR_UPP 501
397#define OID_SKGE_TRAP_SEN_ERR_LOW 502
398#define OID_SKGE_TRAP_SEN_ERR_UPP 503
399#define OID_SKGE_TRAP_RLMT_CHANGE_THRES 520
400#define OID_SKGE_TRAP_RLMT_CHANGE_PORT 521
401#define OID_SKGE_TRAP_RLMT_PORT_DOWN 522
402#define OID_SKGE_TRAP_RLMT_PORT_UP 523
403#define OID_SKGE_TRAP_RLMT_SEGMENTATION 524
404
405#ifdef SK_DIAG_SUPPORT
406/* Defines for driver DIAG mode. */
407#define SK_DIAG_ATTACHED 2
408#define SK_DIAG_RUNNING 1
409#define SK_DIAG_IDLE 0
410#endif /* SK_DIAG_SUPPORT */
411
412/*
413 * Generic PNMI IOCTL subcommand definitions.
414 */
415#define SK_GET_SINGLE_VAR 1
416#define SK_SET_SINGLE_VAR 2
417#define SK_PRESET_SINGLE_VAR 3
418#define SK_GET_FULL_MIB 4
419#define SK_SET_FULL_MIB 5
420#define SK_PRESET_FULL_MIB 6
421
422
423/*
424 * Define error numbers and messages for syslog
425 */
426#define SK_PNMI_ERR001 (SK_ERRBASE_PNMI + 1)
427#define SK_PNMI_ERR001MSG "SkPnmiGetStruct: Unknown OID"
428#define SK_PNMI_ERR002 (SK_ERRBASE_PNMI + 2)
429#define SK_PNMI_ERR002MSG "SkPnmiGetStruct: Cannot read VPD keys"
430#define SK_PNMI_ERR003 (SK_ERRBASE_PNMI + 3)
431#define SK_PNMI_ERR003MSG "OidStruct: Called with wrong OID"
432#define SK_PNMI_ERR004 (SK_ERRBASE_PNMI + 4)
433#define SK_PNMI_ERR004MSG "OidStruct: Called with wrong action"
434#define SK_PNMI_ERR005 (SK_ERRBASE_PNMI + 5)
435#define SK_PNMI_ERR005MSG "Perform: Cannot reset driver"
436#define SK_PNMI_ERR006 (SK_ERRBASE_PNMI + 6)
437#define SK_PNMI_ERR006MSG "Perform: Unknown OID action command"
438#define SK_PNMI_ERR007 (SK_ERRBASE_PNMI + 7)
439#define SK_PNMI_ERR007MSG "General: Driver description not initialized"
440#define SK_PNMI_ERR008 (SK_ERRBASE_PNMI + 8)
441#define SK_PNMI_ERR008MSG "Addr: Tried to get unknown OID"
442#define SK_PNMI_ERR009 (SK_ERRBASE_PNMI + 9)
443#define SK_PNMI_ERR009MSG "Addr: Unknown OID"
444#define SK_PNMI_ERR010 (SK_ERRBASE_PNMI + 10)
445#define SK_PNMI_ERR010MSG "CsumStat: Unknown OID"
446#define SK_PNMI_ERR011 (SK_ERRBASE_PNMI + 11)
447#define SK_PNMI_ERR011MSG "SensorStat: Sensor descr string too long"
448#define SK_PNMI_ERR012 (SK_ERRBASE_PNMI + 12)
449#define SK_PNMI_ERR012MSG "SensorStat: Unknown OID"
450#define SK_PNMI_ERR013 (SK_ERRBASE_PNMI + 13)
451#define SK_PNMI_ERR013MSG ""
452#define SK_PNMI_ERR014 (SK_ERRBASE_PNMI + 14)
453#define SK_PNMI_ERR014MSG "Vpd: Cannot read VPD keys"
454#define SK_PNMI_ERR015 (SK_ERRBASE_PNMI + 15)
455#define SK_PNMI_ERR015MSG "Vpd: Internal array for VPD keys to small"
456#define SK_PNMI_ERR016 (SK_ERRBASE_PNMI + 16)
457#define SK_PNMI_ERR016MSG "Vpd: Key string too long"
458#define SK_PNMI_ERR017 (SK_ERRBASE_PNMI + 17)
459#define SK_PNMI_ERR017MSG "Vpd: Invalid VPD status pointer"
460#define SK_PNMI_ERR018 (SK_ERRBASE_PNMI + 18)
461#define SK_PNMI_ERR018MSG "Vpd: VPD data not valid"
462#define SK_PNMI_ERR019 (SK_ERRBASE_PNMI + 19)
463#define SK_PNMI_ERR019MSG "Vpd: VPD entries list string too long"
464#define SK_PNMI_ERR021 (SK_ERRBASE_PNMI + 21)
465#define SK_PNMI_ERR021MSG "Vpd: VPD data string too long"
466#define SK_PNMI_ERR022 (SK_ERRBASE_PNMI + 22)
467#define SK_PNMI_ERR022MSG "Vpd: VPD data string too long should be errored before"
468#define SK_PNMI_ERR023 (SK_ERRBASE_PNMI + 23)
469#define SK_PNMI_ERR023MSG "Vpd: Unknown OID in get action"
470#define SK_PNMI_ERR024 (SK_ERRBASE_PNMI + 24)
471#define SK_PNMI_ERR024MSG "Vpd: Unknown OID in preset/set action"
472#define SK_PNMI_ERR025 (SK_ERRBASE_PNMI + 25)
473#define SK_PNMI_ERR025MSG "Vpd: Cannot write VPD after modify entry"
474#define SK_PNMI_ERR026 (SK_ERRBASE_PNMI + 26)
475#define SK_PNMI_ERR026MSG "Vpd: Cannot update VPD"
476#define SK_PNMI_ERR027 (SK_ERRBASE_PNMI + 27)
477#define SK_PNMI_ERR027MSG "Vpd: Cannot delete VPD entry"
478#define SK_PNMI_ERR028 (SK_ERRBASE_PNMI + 28)
479#define SK_PNMI_ERR028MSG "Vpd: Cannot update VPD after delete entry"
480#define SK_PNMI_ERR029 (SK_ERRBASE_PNMI + 29)
481#define SK_PNMI_ERR029MSG "General: Driver description string too long"
482#define SK_PNMI_ERR030 (SK_ERRBASE_PNMI + 30)
483#define SK_PNMI_ERR030MSG "General: Driver version not initialized"
484#define SK_PNMI_ERR031 (SK_ERRBASE_PNMI + 31)
485#define SK_PNMI_ERR031MSG "General: Driver version string too long"
486#define SK_PNMI_ERR032 (SK_ERRBASE_PNMI + 32)
487#define SK_PNMI_ERR032MSG "General: Cannot read VPD Name for HW descr"
488#define SK_PNMI_ERR033 (SK_ERRBASE_PNMI + 33)
489#define SK_PNMI_ERR033MSG "General: HW description string too long"
490#define SK_PNMI_ERR034 (SK_ERRBASE_PNMI + 34)
491#define SK_PNMI_ERR034MSG "General: Unknown OID"
492#define SK_PNMI_ERR035 (SK_ERRBASE_PNMI + 35)
493#define SK_PNMI_ERR035MSG "Rlmt: Unknown OID"
494#define SK_PNMI_ERR036 (SK_ERRBASE_PNMI + 36)
495#define SK_PNMI_ERR036MSG ""
496#define SK_PNMI_ERR037 (SK_ERRBASE_PNMI + 37)
497#define SK_PNMI_ERR037MSG "Rlmt: SK_RLMT_MODE_CHANGE event return not 0"
498#define SK_PNMI_ERR038 (SK_ERRBASE_PNMI + 38)
499#define SK_PNMI_ERR038MSG "Rlmt: SK_RLMT_PREFPORT_CHANGE event return not 0"
500#define SK_PNMI_ERR039 (SK_ERRBASE_PNMI + 39)
501#define SK_PNMI_ERR039MSG "RlmtStat: Unknown OID"
502#define SK_PNMI_ERR040 (SK_ERRBASE_PNMI + 40)
503#define SK_PNMI_ERR040MSG "PowerManagement: Unknown OID"
504#define SK_PNMI_ERR041 (SK_ERRBASE_PNMI + 41)
505#define SK_PNMI_ERR041MSG "MacPrivateConf: Unknown OID"
506#define SK_PNMI_ERR042 (SK_ERRBASE_PNMI + 42)
507#define SK_PNMI_ERR042MSG "MacPrivateConf: SK_HWEV_SET_ROLE returned not 0"
508#define SK_PNMI_ERR043 (SK_ERRBASE_PNMI + 43)
509#define SK_PNMI_ERR043MSG "MacPrivateConf: SK_HWEV_SET_LMODE returned not 0"
510#define SK_PNMI_ERR044 (SK_ERRBASE_PNMI + 44)
511#define SK_PNMI_ERR044MSG "MacPrivateConf: SK_HWEV_SET_FLOWMODE returned not 0"
512#define SK_PNMI_ERR045 (SK_ERRBASE_PNMI + 45)
513#define SK_PNMI_ERR045MSG "MacPrivateConf: SK_HWEV_SET_SPEED returned not 0"
514#define SK_PNMI_ERR046 (SK_ERRBASE_PNMI + 46)
515#define SK_PNMI_ERR046MSG "Monitor: Unknown OID"
516#define SK_PNMI_ERR047 (SK_ERRBASE_PNMI + 47)
517#define SK_PNMI_ERR047MSG "SirqUpdate: Event function returns not 0"
518#define SK_PNMI_ERR048 (SK_ERRBASE_PNMI + 48)
519#define SK_PNMI_ERR048MSG "RlmtUpdate: Event function returns not 0"
520#define SK_PNMI_ERR049 (SK_ERRBASE_PNMI + 49)
521#define SK_PNMI_ERR049MSG "SkPnmiInit: Invalid size of 'CounterOffset' struct!!"
522#define SK_PNMI_ERR050 (SK_ERRBASE_PNMI + 50)
523#define SK_PNMI_ERR050MSG "SkPnmiInit: Invalid size of 'StatAddr' table!!"
524#define SK_PNMI_ERR051 (SK_ERRBASE_PNMI + 51)
525#define SK_PNMI_ERR051MSG "SkPnmiEvent: Port switch suspicious"
526#define SK_PNMI_ERR052 (SK_ERRBASE_PNMI + 52)
527#define SK_PNMI_ERR052MSG ""
528#define SK_PNMI_ERR053 (SK_ERRBASE_PNMI + 53)
529#define SK_PNMI_ERR053MSG "General: Driver release date not initialized"
530#define SK_PNMI_ERR054 (SK_ERRBASE_PNMI + 54)
531#define SK_PNMI_ERR054MSG "General: Driver release date string too long"
532#define SK_PNMI_ERR055 (SK_ERRBASE_PNMI + 55)
533#define SK_PNMI_ERR055MSG "General: Driver file name not initialized"
534#define SK_PNMI_ERR056 (SK_ERRBASE_PNMI + 56)
535#define SK_PNMI_ERR056MSG "General: Driver file name string too long"
536
537/*
538 * Management counter macros called by the driver
539 */
540#define SK_PNMI_SET_DRIVER_DESCR(pAC,v) ((pAC)->Pnmi.pDriverDescription = \
541 (char *)(v))
542
543#define SK_PNMI_SET_DRIVER_VER(pAC,v) ((pAC)->Pnmi.pDriverVersion = \
544 (char *)(v))
545
546#define SK_PNMI_SET_DRIVER_RELDATE(pAC,v) ((pAC)->Pnmi.pDriverReleaseDate = \
547 (char *)(v))
548
549#define SK_PNMI_SET_DRIVER_FILENAME(pAC,v) ((pAC)->Pnmi.pDriverFileName = \
550 (char *)(v))
551
552#define SK_PNMI_CNT_TX_QUEUE_LEN(pAC,v,p) \
553 { \
554 (pAC)->Pnmi.Port[p].TxSwQueueLen = (SK_U64)(v); \
555 if ((pAC)->Pnmi.Port[p].TxSwQueueLen > (pAC)->Pnmi.Port[p].TxSwQueueMax) { \
556 (pAC)->Pnmi.Port[p].TxSwQueueMax = (pAC)->Pnmi.Port[p].TxSwQueueLen; \
557 } \
558 }
559#define SK_PNMI_CNT_TX_RETRY(pAC,p) (((pAC)->Pnmi.Port[p].TxRetryCts)++)
560#define SK_PNMI_CNT_RX_INTR(pAC,p) (((pAC)->Pnmi.Port[p].RxIntrCts)++)
561#define SK_PNMI_CNT_TX_INTR(pAC,p) (((pAC)->Pnmi.Port[p].TxIntrCts)++)
562#define SK_PNMI_CNT_NO_RX_BUF(pAC,p) (((pAC)->Pnmi.Port[p].RxNoBufCts)++)
563#define SK_PNMI_CNT_NO_TX_BUF(pAC,p) (((pAC)->Pnmi.Port[p].TxNoBufCts)++)
564#define SK_PNMI_CNT_USED_TX_DESCR(pAC,v,p) \
565 ((pAC)->Pnmi.Port[p].TxUsedDescrNo=(SK_U64)(v));
566#define SK_PNMI_CNT_RX_OCTETS_DELIVERED(pAC,v,p) \
567 { \
568 ((pAC)->Pnmi.Port[p].RxDeliveredCts)++; \
569 (pAC)->Pnmi.Port[p].RxOctetsDeliveredCts += (SK_U64)(v); \
570 }
571#define SK_PNMI_CNT_ERR_RECOVERY(pAC,p) (((pAC)->Pnmi.Port[p].ErrRecoveryCts)++);
572
573#define SK_PNMI_CNT_SYNC_OCTETS(pAC,p,v) \
574 { \
575 if ((p) < SK_MAX_MACS) { \
576 ((pAC)->Pnmi.Port[p].StatSyncCts)++; \
577 (pAC)->Pnmi.Port[p].StatSyncOctetsCts += (SK_U64)(v); \
578 } \
579 }
580
581#define SK_PNMI_CNT_RX_LONGFRAMES(pAC,p) \
582 { \
583 if ((p) < SK_MAX_MACS) { \
584 ((pAC)->Pnmi.Port[p].StatRxLongFrameCts++); \
585 } \
586 }
587
588#define SK_PNMI_CNT_RX_FRAMETOOLONG(pAC,p) \
589 { \
590 if ((p) < SK_MAX_MACS) { \
591 ((pAC)->Pnmi.Port[p].StatRxFrameTooLongCts++); \
592 } \
593 }
594
595#define SK_PNMI_CNT_RX_PMACC_ERR(pAC,p) \
596 { \
597 if ((p) < SK_MAX_MACS) { \
598 ((pAC)->Pnmi.Port[p].StatRxPMaccErr++); \
599 } \
600 }
601
602/*
603 * Conversion Macros
604 */
605#define SK_PNMI_PORT_INST2LOG(i) ((unsigned int)(i) - 1)
606#define SK_PNMI_PORT_LOG2INST(l) ((unsigned int)(l) + 1)
607#define SK_PNMI_PORT_PHYS2LOG(p) ((unsigned int)(p) + 1)
608#define SK_PNMI_PORT_LOG2PHYS(pAC,l) ((unsigned int)(l) - 1)
609#define SK_PNMI_PORT_PHYS2INST(pAC,p) \
610 (pAC->Pnmi.DualNetActiveFlag ? 2 : ((unsigned int)(p) + 2))
611#define SK_PNMI_PORT_INST2PHYS(pAC,i) ((unsigned int)(i) - 2)
612
613/*
614 * Structure definition for SkPnmiGetStruct and SkPnmiSetStruct
615 */
616#define SK_PNMI_VPD_KEY_SIZE 5
617#define SK_PNMI_VPD_BUFSIZE (VPD_SIZE)
618#define SK_PNMI_VPD_ENTRIES (VPD_SIZE / 4)
619#define SK_PNMI_VPD_DATALEN 128 /* Number of data bytes */
620
621#define SK_PNMI_MULTICAST_LISTLEN 64
622#define SK_PNMI_SENSOR_ENTRIES (SK_MAX_SENSORS)
623#define SK_PNMI_CHECKSUM_ENTRIES 3
624#define SK_PNMI_MAC_ENTRIES (SK_MAX_MACS + 1)
625#define SK_PNMI_MONITOR_ENTRIES 20
626#define SK_PNMI_TRAP_ENTRIES 10
627#define SK_PNMI_TRAPLEN 128
628#define SK_PNMI_STRINGLEN1 80
629#define SK_PNMI_STRINGLEN2 25
630#define SK_PNMI_TRAP_QUEUE_LEN 512
631
632typedef struct s_PnmiVpd {
633 char VpdKey[SK_PNMI_VPD_KEY_SIZE];
634 char VpdValue[SK_PNMI_VPD_DATALEN];
635 SK_U8 VpdAccess;
636 SK_U8 VpdAction;
637} SK_PNMI_VPD;
638
639typedef struct s_PnmiSensor {
640 SK_U8 SensorIndex;
641 char SensorDescr[SK_PNMI_STRINGLEN2];
642 SK_U8 SensorType;
643 SK_U32 SensorValue;
644 SK_U32 SensorWarningThresholdLow;
645 SK_U32 SensorWarningThresholdHigh;
646 SK_U32 SensorErrorThresholdLow;
647 SK_U32 SensorErrorThresholdHigh;
648 SK_U8 SensorStatus;
649 SK_U64 SensorWarningCts;
650 SK_U64 SensorErrorCts;
651 SK_U64 SensorWarningTimestamp;
652 SK_U64 SensorErrorTimestamp;
653} SK_PNMI_SENSOR;
654
655typedef struct s_PnmiChecksum {
656 SK_U64 ChecksumRxOkCts;
657 SK_U64 ChecksumRxUnableCts;
658 SK_U64 ChecksumRxErrCts;
659 SK_U64 ChecksumTxOkCts;
660 SK_U64 ChecksumTxUnableCts;
661} SK_PNMI_CHECKSUM;
662
663typedef struct s_PnmiStat {
664 SK_U64 StatTxOkCts;
665 SK_U64 StatTxOctetsOkCts;
666 SK_U64 StatTxBroadcastOkCts;
667 SK_U64 StatTxMulticastOkCts;
668 SK_U64 StatTxUnicastOkCts;
669 SK_U64 StatTxLongFramesCts;
670 SK_U64 StatTxBurstCts;
671 SK_U64 StatTxPauseMacCtrlCts;
672 SK_U64 StatTxMacCtrlCts;
673 SK_U64 StatTxSingleCollisionCts;
674 SK_U64 StatTxMultipleCollisionCts;
675 SK_U64 StatTxExcessiveCollisionCts;
676 SK_U64 StatTxLateCollisionCts;
677 SK_U64 StatTxDeferralCts;
678 SK_U64 StatTxExcessiveDeferralCts;
679 SK_U64 StatTxFifoUnderrunCts;
680 SK_U64 StatTxCarrierCts;
681 SK_U64 Dummy1; /* StatTxUtilization */
682 SK_U64 StatTx64Cts;
683 SK_U64 StatTx127Cts;
684 SK_U64 StatTx255Cts;
685 SK_U64 StatTx511Cts;
686 SK_U64 StatTx1023Cts;
687 SK_U64 StatTxMaxCts;
688 SK_U64 StatTxSyncCts;
689 SK_U64 StatTxSyncOctetsCts;
690 SK_U64 StatRxOkCts;
691 SK_U64 StatRxOctetsOkCts;
692 SK_U64 StatRxBroadcastOkCts;
693 SK_U64 StatRxMulticastOkCts;
694 SK_U64 StatRxUnicastOkCts;
695 SK_U64 StatRxLongFramesCts;
696 SK_U64 StatRxPauseMacCtrlCts;
697 SK_U64 StatRxMacCtrlCts;
698 SK_U64 StatRxPauseMacCtrlErrorCts;
699 SK_U64 StatRxMacCtrlUnknownCts;
700 SK_U64 StatRxBurstCts;
701 SK_U64 StatRxMissedCts;
702 SK_U64 StatRxFramingCts;
703 SK_U64 StatRxFifoOverflowCts;
704 SK_U64 StatRxJabberCts;
705 SK_U64 StatRxCarrierCts;
706 SK_U64 StatRxIRLengthCts;
707 SK_U64 StatRxSymbolCts;
708 SK_U64 StatRxShortsCts;
709 SK_U64 StatRxRuntCts;
710 SK_U64 StatRxCextCts;
711 SK_U64 StatRxTooLongCts;
712 SK_U64 StatRxFcsCts;
713 SK_U64 Dummy2; /* StatRxUtilization */
714 SK_U64 StatRx64Cts;
715 SK_U64 StatRx127Cts;
716 SK_U64 StatRx255Cts;
717 SK_U64 StatRx511Cts;
718 SK_U64 StatRx1023Cts;
719 SK_U64 StatRxMaxCts;
720} SK_PNMI_STAT;
721
722typedef struct s_PnmiConf {
723 char ConfMacCurrentAddr[6];
724 char ConfMacFactoryAddr[6];
725 SK_U8 ConfPMD;
726 SK_U8 ConfConnector;
727 SK_U32 ConfPhyType;
728 SK_U32 ConfPhyMode;
729 SK_U8 ConfLinkCapability;
730 SK_U8 ConfLinkMode;
731 SK_U8 ConfLinkModeStatus;
732 SK_U8 ConfLinkStatus;
733 SK_U8 ConfFlowCtrlCapability;
734 SK_U8 ConfFlowCtrlMode;
735 SK_U8 ConfFlowCtrlStatus;
736 SK_U8 ConfPhyOperationCapability;
737 SK_U8 ConfPhyOperationMode;
738 SK_U8 ConfPhyOperationStatus;
739 SK_U8 ConfSpeedCapability;
740 SK_U8 ConfSpeedMode;
741 SK_U8 ConfSpeedStatus;
742} SK_PNMI_CONF;
743
744typedef struct s_PnmiRlmt {
745 SK_U32 RlmtIndex;
746 SK_U32 RlmtStatus;
747 SK_U64 RlmtTxHelloCts;
748 SK_U64 RlmtRxHelloCts;
749 SK_U64 RlmtTxSpHelloReqCts;
750 SK_U64 RlmtRxSpHelloCts;
751} SK_PNMI_RLMT;
752
753typedef struct s_PnmiRlmtMonitor {
754 SK_U32 RlmtMonitorIndex;
755 char RlmtMonitorAddr[6];
756 SK_U64 RlmtMonitorErrorCts;
757 SK_U64 RlmtMonitorTimestamp;
758 SK_U8 RlmtMonitorAdmin;
759} SK_PNMI_RLMT_MONITOR;
760
761typedef struct s_PnmiRequestStatus {
762 SK_U32 ErrorStatus;
763 SK_U32 ErrorOffset;
764} SK_PNMI_REQUEST_STATUS;
765
766typedef struct s_PnmiStrucData {
767 SK_U32 MgmtDBVersion;
768 SK_PNMI_REQUEST_STATUS ReturnStatus;
769 SK_U32 VpdFreeBytes;
770 char VpdEntriesList[SK_PNMI_VPD_ENTRIES * SK_PNMI_VPD_KEY_SIZE];
771 SK_U32 VpdEntriesNumber;
772 SK_PNMI_VPD Vpd[SK_PNMI_VPD_ENTRIES];
773 SK_U32 PortNumber;
774 SK_U32 DeviceType;
775 char DriverDescr[SK_PNMI_STRINGLEN1];
776 char DriverVersion[SK_PNMI_STRINGLEN2];
777 char DriverReleaseDate[SK_PNMI_STRINGLEN1];
778 char DriverFileName[SK_PNMI_STRINGLEN1];
779 char HwDescr[SK_PNMI_STRINGLEN1];
780 char HwVersion[SK_PNMI_STRINGLEN2];
781 SK_U16 Chipset;
782 SK_U32 ChipId;
783 SK_U8 VauxAvail;
784 SK_U32 RamSize;
785 SK_U32 MtuSize;
786 SK_U32 Action;
787 SK_U32 TestResult;
788 SK_U8 BusType;
789 SK_U8 BusSpeed;
790 SK_U8 BusWidth;
791 SK_U8 SensorNumber;
792 SK_PNMI_SENSOR Sensor[SK_PNMI_SENSOR_ENTRIES];
793 SK_U8 ChecksumNumber;
794 SK_PNMI_CHECKSUM Checksum[SK_PNMI_CHECKSUM_ENTRIES];
795 SK_PNMI_STAT Stat[SK_PNMI_MAC_ENTRIES];
796 SK_PNMI_CONF Conf[SK_PNMI_MAC_ENTRIES];
797 SK_U8 RlmtMode;
798 SK_U32 RlmtPortNumber;
799 SK_U8 RlmtPortActive;
800 SK_U8 RlmtPortPreferred;
801 SK_U64 RlmtChangeCts;
802 SK_U64 RlmtChangeTime;
803 SK_U64 RlmtChangeEstimate;
804 SK_U64 RlmtChangeThreshold;
805 SK_PNMI_RLMT Rlmt[SK_MAX_MACS];
806 SK_U32 RlmtMonitorNumber;
807 SK_PNMI_RLMT_MONITOR RlmtMonitor[SK_PNMI_MONITOR_ENTRIES];
808 SK_U32 TrapNumber;
809 SK_U8 Trap[SK_PNMI_TRAP_QUEUE_LEN];
810 SK_U64 TxSwQueueLen;
811 SK_U64 TxSwQueueMax;
812 SK_U64 TxRetryCts;
813 SK_U64 RxIntrCts;
814 SK_U64 TxIntrCts;
815 SK_U64 RxNoBufCts;
816 SK_U64 TxNoBufCts;
817 SK_U64 TxUsedDescrNo;
818 SK_U64 RxDeliveredCts;
819 SK_U64 RxOctetsDeliveredCts;
820 SK_U64 RxHwErrorsCts;
821 SK_U64 TxHwErrorsCts;
822 SK_U64 InErrorsCts;
823 SK_U64 OutErrorsCts;
824 SK_U64 ErrRecoveryCts;
825 SK_U64 SysUpTime;
826} SK_PNMI_STRUCT_DATA;
827
828#define SK_PNMI_STRUCT_SIZE (sizeof(SK_PNMI_STRUCT_DATA))
829#define SK_PNMI_MIN_STRUCT_SIZE ((unsigned int)(SK_UPTR)\
830 &(((SK_PNMI_STRUCT_DATA *)0)->VpdFreeBytes))
831 /*
832 * ReturnStatus field
833 * must be located
834 * before VpdFreeBytes
835 */
836
837/*
838 * Various definitions
839 */
840#define SK_PNMI_MAX_PROTOS 3
841
842#define SK_PNMI_CNT_NO 66 /* Must have the value of the enum
843 * SK_PNMI_MAX_IDX. Define SK_PNMI_CHECK
844 * for check while init phase 1
845 */
846
847/*
848 * Estimate data structure
849 */
850typedef struct s_PnmiEstimate {
851 unsigned int EstValueIndex;
852 SK_U64 EstValue[7];
853 SK_U64 Estimate;
854 SK_TIMER EstTimer;
855} SK_PNMI_ESTIMATE;
856
857
858/*
859 * VCT timer data structure
860 */
861typedef struct s_VctTimer {
862 SK_TIMER VctTimer;
863} SK_PNMI_VCT_TIMER;
864
865
866/*
867 * PNMI specific adapter context structure
868 */
869typedef struct s_PnmiPort {
870 SK_U64 StatSyncCts;
871 SK_U64 StatSyncOctetsCts;
872 SK_U64 StatRxLongFrameCts;
873 SK_U64 StatRxFrameTooLongCts;
874 SK_U64 StatRxPMaccErr;
875 SK_U64 TxSwQueueLen;
876 SK_U64 TxSwQueueMax;
877 SK_U64 TxRetryCts;
878 SK_U64 RxIntrCts;
879 SK_U64 TxIntrCts;
880 SK_U64 RxNoBufCts;
881 SK_U64 TxNoBufCts;
882 SK_U64 TxUsedDescrNo;
883 SK_U64 RxDeliveredCts;
884 SK_U64 RxOctetsDeliveredCts;
885 SK_U64 RxHwErrorsCts;
886 SK_U64 TxHwErrorsCts;
887 SK_U64 InErrorsCts;
888 SK_U64 OutErrorsCts;
889 SK_U64 ErrRecoveryCts;
890 SK_U64 RxShortZeroMark;
891 SK_U64 CounterOffset[SK_PNMI_CNT_NO];
892 SK_U32 CounterHigh[SK_PNMI_CNT_NO];
893 SK_BOOL ActiveFlag;
894 SK_U8 Align[3];
895} SK_PNMI_PORT;
896
897
898typedef struct s_PnmiData {
899 SK_PNMI_PORT Port [SK_MAX_MACS];
900 SK_PNMI_PORT BufPort [SK_MAX_MACS]; /* 2002-09-13 pweber */
901 SK_U64 VirtualCounterOffset[SK_PNMI_CNT_NO];
902 SK_U32 TestResult;
903 char HwVersion[10];
904 SK_U16 Align01;
905
906 char *pDriverDescription;
907 char *pDriverVersion;
908 char *pDriverReleaseDate;
909 char *pDriverFileName;
910
911 int MacUpdatedFlag;
912 int RlmtUpdatedFlag;
913 int SirqUpdatedFlag;
914
915 SK_U64 RlmtChangeCts;
916 SK_U64 RlmtChangeTime;
917 SK_PNMI_ESTIMATE RlmtChangeEstimate;
918 SK_U64 RlmtChangeThreshold;
919
920 SK_U64 StartUpTime;
921 SK_U32 DeviceType;
922 char PciBusSpeed;
923 char PciBusWidth;
924 char Chipset;
925 char PMD;
926 char Connector;
927 SK_BOOL DualNetActiveFlag;
928 SK_U16 Align02;
929
930 char TrapBuf[SK_PNMI_TRAP_QUEUE_LEN];
931 unsigned int TrapBufFree;
932 unsigned int TrapQueueBeg;
933 unsigned int TrapQueueEnd;
934 unsigned int TrapBufPad;
935 unsigned int TrapUnique;
936 SK_U8 VctStatus[SK_MAX_MACS];
937 SK_PNMI_VCT VctBackup[SK_MAX_MACS];
938 SK_PNMI_VCT_TIMER VctTimeout[SK_MAX_MACS];
939#ifdef SK_DIAG_SUPPORT
940 SK_U32 DiagAttached;
941#endif /* SK_DIAG_SUPPORT */
942} SK_PNMI;
943
944
945/*
946 * Function prototypes
947 */
948extern int SkPnmiInit(SK_AC *pAC, SK_IOC IoC, int Level);
949extern int SkPnmiSetVar(SK_AC *pAC, SK_IOC IoC, SK_U32 Id, void* pBuf,
950 unsigned int *pLen, SK_U32 Instance, SK_U32 NetIndex);
951extern int SkPnmiGetStruct(SK_AC *pAC, SK_IOC IoC, void* pBuf,
952 unsigned int *pLen, SK_U32 NetIndex);
953extern int SkPnmiPreSetStruct(SK_AC *pAC, SK_IOC IoC, void* pBuf,
954 unsigned int *pLen, SK_U32 NetIndex);
955extern int SkPnmiSetStruct(SK_AC *pAC, SK_IOC IoC, void* pBuf,
956 unsigned int *pLen, SK_U32 NetIndex);
957extern int SkPnmiEvent(SK_AC *pAC, SK_IOC IoC, SK_U32 Event,
958 SK_EVPARA Param);
959extern int SkPnmiGenIoctl(SK_AC *pAC, SK_IOC IoC, void * pBuf,
960 unsigned int * pLen, SK_U32 NetIndex);
961
962#endif
diff --git a/drivers/net/sk98lin/h/skgesirq.h b/drivers/net/sk98lin/h/skgesirq.h
new file mode 100644
index 000000000000..3eec6274e413
--- /dev/null
+++ b/drivers/net/sk98lin/h/skgesirq.h
@@ -0,0 +1,110 @@
1/******************************************************************************
2 *
3 * Name: skgesirq.h
4 * Project: Gigabit Ethernet Adapters, Common Modules
5 * Version: $Revision: 1.30 $
6 * Date: $Date: 2003/07/04 12:34:13 $
7 * Purpose: SK specific Gigabit Ethernet special IRQ functions
8 *
9 ******************************************************************************/
10
11/******************************************************************************
12 *
13 * (C)Copyright 1998-2002 SysKonnect.
14 * (C)Copyright 2002-2003 Marvell.
15 *
16 * This program is free software; you can redistribute it and/or modify
17 * it under the terms of the GNU General Public License as published by
18 * the Free Software Foundation; either version 2 of the License, or
19 * (at your option) any later version.
20 *
21 * The information in this file is provided "AS IS" without warranty.
22 *
23 ******************************************************************************/
24
25#ifndef _INC_SKGESIRQ_H_
26#define _INC_SKGESIRQ_H_
27
28/* Define return codes of SkGePortCheckUp and CheckShort */
29#define SK_HW_PS_NONE 0 /* No action needed */
30#define SK_HW_PS_RESTART 1 /* Restart needed */
31#define SK_HW_PS_LINK 2 /* Link Up actions needed */
32
33/*
34 * Define the Event the special IRQ/INI module can handle
35 */
36#define SK_HWEV_WATIM 1 /* Timeout for WA Errata #2 XMAC */
37#define SK_HWEV_PORT_START 2 /* Port Start Event by RLMT */
38#define SK_HWEV_PORT_STOP 3 /* Port Stop Event by RLMT */
39#define SK_HWEV_CLEAR_STAT 4 /* Clear Statistics by PNMI */
40#define SK_HWEV_UPDATE_STAT 5 /* Update Statistics by PNMI */
41#define SK_HWEV_SET_LMODE 6 /* Set Link Mode by PNMI */
42#define SK_HWEV_SET_FLOWMODE 7 /* Set Flow Control Mode by PNMI */
43#define SK_HWEV_SET_ROLE 8 /* Set Master/Slave (Role) by PNMI */
44#define SK_HWEV_SET_SPEED 9 /* Set Link Speed by PNMI */
45#define SK_HWEV_HALFDUP_CHK 10 /* Half Duplex Hangup Workaround */
46
47#define SK_WA_ACT_TIME (5000000UL) /* 5 sec */
48#define SK_WA_INA_TIME (100000UL) /* 100 msec */
49
50#define SK_HALFDUP_CHK_TIME (10000UL) /* 10 msec */
51
52/*
53 * Define the error numbers and messages
54 */
55#define SKERR_SIRQ_E001 (SK_ERRBASE_SIRQ+0)
56#define SKERR_SIRQ_E001MSG "Unknown event"
57#define SKERR_SIRQ_E002 (SKERR_SIRQ_E001+1)
58#define SKERR_SIRQ_E002MSG "Packet timeout RX1"
59#define SKERR_SIRQ_E003 (SKERR_SIRQ_E002+1)
60#define SKERR_SIRQ_E003MSG "Packet timeout RX2"
61#define SKERR_SIRQ_E004 (SKERR_SIRQ_E003+1)
62#define SKERR_SIRQ_E004MSG "MAC 1 not correctly initialized"
63#define SKERR_SIRQ_E005 (SKERR_SIRQ_E004+1)
64#define SKERR_SIRQ_E005MSG "MAC 2 not correctly initialized"
65#define SKERR_SIRQ_E006 (SKERR_SIRQ_E005+1)
66#define SKERR_SIRQ_E006MSG "CHECK failure R1"
67#define SKERR_SIRQ_E007 (SKERR_SIRQ_E006+1)
68#define SKERR_SIRQ_E007MSG "CHECK failure R2"
69#define SKERR_SIRQ_E008 (SKERR_SIRQ_E007+1)
70#define SKERR_SIRQ_E008MSG "CHECK failure XS1"
71#define SKERR_SIRQ_E009 (SKERR_SIRQ_E008+1)
72#define SKERR_SIRQ_E009MSG "CHECK failure XA1"
73#define SKERR_SIRQ_E010 (SKERR_SIRQ_E009+1)
74#define SKERR_SIRQ_E010MSG "CHECK failure XS2"
75#define SKERR_SIRQ_E011 (SKERR_SIRQ_E010+1)
76#define SKERR_SIRQ_E011MSG "CHECK failure XA2"
77#define SKERR_SIRQ_E012 (SKERR_SIRQ_E011+1)
78#define SKERR_SIRQ_E012MSG "unexpected IRQ Master error"
79#define SKERR_SIRQ_E013 (SKERR_SIRQ_E012+1)
80#define SKERR_SIRQ_E013MSG "unexpected IRQ Status error"
81#define SKERR_SIRQ_E014 (SKERR_SIRQ_E013+1)
82#define SKERR_SIRQ_E014MSG "Parity error on RAM (read)"
83#define SKERR_SIRQ_E015 (SKERR_SIRQ_E014+1)
84#define SKERR_SIRQ_E015MSG "Parity error on RAM (write)"
85#define SKERR_SIRQ_E016 (SKERR_SIRQ_E015+1)
86#define SKERR_SIRQ_E016MSG "Parity error MAC 1"
87#define SKERR_SIRQ_E017 (SKERR_SIRQ_E016+1)
88#define SKERR_SIRQ_E017MSG "Parity error MAC 2"
89#define SKERR_SIRQ_E018 (SKERR_SIRQ_E017+1)
90#define SKERR_SIRQ_E018MSG "Parity error RX 1"
91#define SKERR_SIRQ_E019 (SKERR_SIRQ_E018+1)
92#define SKERR_SIRQ_E019MSG "Parity error RX 2"
93#define SKERR_SIRQ_E020 (SKERR_SIRQ_E019+1)
94#define SKERR_SIRQ_E020MSG "MAC transmit FIFO underrun"
95#define SKERR_SIRQ_E021 (SKERR_SIRQ_E020+1)
96#define SKERR_SIRQ_E021MSG "Spurious TWSI interrupt"
97#define SKERR_SIRQ_E022 (SKERR_SIRQ_E021+1)
98#define SKERR_SIRQ_E022MSG "Cable pair swap error"
99#define SKERR_SIRQ_E023 (SKERR_SIRQ_E022+1)
100#define SKERR_SIRQ_E023MSG "Auto-negotiation error"
101#define SKERR_SIRQ_E024 (SKERR_SIRQ_E023+1)
102#define SKERR_SIRQ_E024MSG "FIFO overflow error"
103#define SKERR_SIRQ_E025 (SKERR_SIRQ_E024+1)
104#define SKERR_SIRQ_E025MSG "2 Pair Downshift detected"
105
106extern void SkGeSirqIsr(SK_AC *pAC, SK_IOC IoC, SK_U32 Istatus);
107extern int SkGeSirqEvent(SK_AC *pAC, SK_IOC IoC, SK_U32 Event, SK_EVPARA Para);
108extern void SkHWLinkDown(SK_AC *pAC, SK_IOC IoC, int Port);
109
110#endif /* _INC_SKGESIRQ_H_ */
diff --git a/drivers/net/sk98lin/h/ski2c.h b/drivers/net/sk98lin/h/ski2c.h
new file mode 100644
index 000000000000..6a63f4a15de6
--- /dev/null
+++ b/drivers/net/sk98lin/h/ski2c.h
@@ -0,0 +1,174 @@
1/******************************************************************************
2 *
3 * Name: ski2c.h
4 * Project: Gigabit Ethernet Adapters, TWSI-Module
5 * Version: $Revision: 1.35 $
6 * Date: $Date: 2003/10/20 09:06:30 $
7 * Purpose: Defines to access Voltage and Temperature Sensor
8 *
9 ******************************************************************************/
10
11/******************************************************************************
12 *
13 * (C)Copyright 1998-2002 SysKonnect.
14 * (C)Copyright 2002-2003 Marvell.
15 *
16 * This program is free software; you can redistribute it and/or modify
17 * it under the terms of the GNU General Public License as published by
18 * the Free Software Foundation; either version 2 of the License, or
19 * (at your option) any later version.
20 *
21 * The information in this file is provided "AS IS" without warranty.
22 *
23 ******************************************************************************/
24
25/*
26 * SKI2C.H contains all I2C specific defines
27 */
28
29#ifndef _SKI2C_H_
30#define _SKI2C_H_
31
32typedef struct s_Sensor SK_SENSOR;
33
34#include "h/skgei2c.h"
35
36/*
37 * Define the I2C events.
38 */
39#define SK_I2CEV_IRQ 1 /* IRQ happened Event */
40#define SK_I2CEV_TIM 2 /* Timeout event */
41#define SK_I2CEV_CLEAR 3 /* Clear MIB Values */
42
43/*
44 * Define READ and WRITE Constants.
45 */
46#define I2C_READ 0
47#define I2C_WRITE 1
48#define I2C_BURST 1
49#define I2C_SINGLE 0
50
51#define SKERR_I2C_E001 (SK_ERRBASE_I2C+0)
52#define SKERR_I2C_E001MSG "Sensor index unknown"
53#define SKERR_I2C_E002 (SKERR_I2C_E001+1)
54#define SKERR_I2C_E002MSG "TWSI: transfer does not complete"
55#define SKERR_I2C_E003 (SKERR_I2C_E002+1)
56#define SKERR_I2C_E003MSG "LM80: NAK on device send"
57#define SKERR_I2C_E004 (SKERR_I2C_E003+1)
58#define SKERR_I2C_E004MSG "LM80: NAK on register send"
59#define SKERR_I2C_E005 (SKERR_I2C_E004+1)
60#define SKERR_I2C_E005MSG "LM80: NAK on device (2) send"
61#define SKERR_I2C_E006 (SKERR_I2C_E005+1)
62#define SKERR_I2C_E006MSG "Unknown event"
63#define SKERR_I2C_E007 (SKERR_I2C_E006+1)
64#define SKERR_I2C_E007MSG "LM80 read out of state"
65#define SKERR_I2C_E008 (SKERR_I2C_E007+1)
66#define SKERR_I2C_E008MSG "Unexpected sensor read completed"
67#define SKERR_I2C_E009 (SKERR_I2C_E008+1)
68#define SKERR_I2C_E009MSG "WARNING: temperature sensor out of range"
69#define SKERR_I2C_E010 (SKERR_I2C_E009+1)
70#define SKERR_I2C_E010MSG "WARNING: voltage sensor out of range"
71#define SKERR_I2C_E011 (SKERR_I2C_E010+1)
72#define SKERR_I2C_E011MSG "ERROR: temperature sensor out of range"
73#define SKERR_I2C_E012 (SKERR_I2C_E011+1)
74#define SKERR_I2C_E012MSG "ERROR: voltage sensor out of range"
75#define SKERR_I2C_E013 (SKERR_I2C_E012+1)
76#define SKERR_I2C_E013MSG "ERROR: couldn't init sensor"
77#define SKERR_I2C_E014 (SKERR_I2C_E013+1)
78#define SKERR_I2C_E014MSG "WARNING: fan sensor out of range"
79#define SKERR_I2C_E015 (SKERR_I2C_E014+1)
80#define SKERR_I2C_E015MSG "ERROR: fan sensor out of range"
81#define SKERR_I2C_E016 (SKERR_I2C_E015+1)
82#define SKERR_I2C_E016MSG "TWSI: active transfer does not complete"
83
84/*
85 * Define Timeout values
86 */
87#define SK_I2C_TIM_LONG 2000000L /* 2 seconds */
88#define SK_I2C_TIM_SHORT 100000L /* 100 milliseconds */
89#define SK_I2C_TIM_WATCH 1000000L /* 1 second */
90
91/*
92 * Define trap and error log hold times
93 */
94#ifndef SK_SEN_ERR_TR_HOLD
95#define SK_SEN_ERR_TR_HOLD (4*SK_TICKS_PER_SEC)
96#endif
97#ifndef SK_SEN_ERR_LOG_HOLD
98#define SK_SEN_ERR_LOG_HOLD (60*SK_TICKS_PER_SEC)
99#endif
100#ifndef SK_SEN_WARN_TR_HOLD
101#define SK_SEN_WARN_TR_HOLD (15*SK_TICKS_PER_SEC)
102#endif
103#ifndef SK_SEN_WARN_LOG_HOLD
104#define SK_SEN_WARN_LOG_HOLD (15*60*SK_TICKS_PER_SEC)
105#endif
106
107/*
108 * Defines for SenType
109 */
110#define SK_SEN_UNKNOWN 0
111#define SK_SEN_TEMP 1
112#define SK_SEN_VOLT 2
113#define SK_SEN_FAN 3
114
115/*
116 * Define for the SenErrorFlag
117 */
118#define SK_SEN_ERR_NOT_PRESENT 0 /* Error Flag: Sensor not present */
119#define SK_SEN_ERR_OK 1 /* Error Flag: O.K. */
120#define SK_SEN_ERR_WARN 2 /* Error Flag: Warning */
121#define SK_SEN_ERR_ERR 3 /* Error Flag: Error */
122#define SK_SEN_ERR_FAULTY 4 /* Error Flag: Faulty */
123
124/*
125 * Define the Sensor struct
126 */
127struct s_Sensor {
128 char *SenDesc; /* Description */
129 int SenType; /* Voltage or Temperature */
130 SK_I32 SenValue; /* Current value of the sensor */
131 SK_I32 SenThreErrHigh; /* High error Threshhold of this sensor */
132 SK_I32 SenThreWarnHigh; /* High warning Threshhold of this sensor */
133 SK_I32 SenThreErrLow; /* Lower error Threshold of the sensor */
134 SK_I32 SenThreWarnLow; /* Lower warning Threshold of the sensor */
135 int SenErrFlag; /* Sensor indicated an error */
136 SK_BOOL SenInit; /* Is sensor initialized ? */
137 SK_U64 SenErrCts; /* Error trap counter */
138 SK_U64 SenWarnCts; /* Warning trap counter */
139 SK_U64 SenBegErrTS; /* Begin error timestamp */
140 SK_U64 SenBegWarnTS; /* Begin warning timestamp */
141 SK_U64 SenLastErrTrapTS; /* Last error trap timestamp */
142 SK_U64 SenLastErrLogTS; /* Last error log timestamp */
143 SK_U64 SenLastWarnTrapTS; /* Last warning trap timestamp */
144 SK_U64 SenLastWarnLogTS; /* Last warning log timestamp */
145 int SenState; /* Sensor State (see HW specific include) */
146 int (*SenRead)(SK_AC *pAC, SK_IOC IoC, struct s_Sensor *pSen);
147 /* Sensors read function */
148 SK_U16 SenReg; /* Register Address for this sensor */
149 SK_U8 SenDev; /* Device Selection for this sensor */
150};
151
152typedef struct s_I2c {
153 SK_SENSOR SenTable[SK_MAX_SENSORS]; /* Sensor Table */
154 int CurrSens; /* Which sensor is currently queried */
155 int MaxSens; /* Max. number of sensors */
156 int TimerMode; /* Use the timer also to watch the state machine */
157 int InitLevel; /* Initialized Level */
158#ifndef SK_DIAG
159 int DummyReads; /* Number of non-checked dummy reads */
160 SK_TIMER SenTimer; /* Sensors timer */
161#endif /* !SK_DIAG */
162} SK_I2C;
163
164extern int SkI2cInit(SK_AC *pAC, SK_IOC IoC, int Level);
165#ifdef SK_DIAG
166extern SK_U32 SkI2cRead(SK_AC *pAC, SK_IOC IoC, int Dev, int Size, int Reg,
167 int Burst);
168#else /* !SK_DIAG */
169extern int SkI2cEvent(SK_AC *pAC, SK_IOC IoC, SK_U32 Event, SK_EVPARA Para);
170extern void SkI2cWaitIrq(SK_AC *pAC, SK_IOC IoC);
171extern void SkI2cIsr(SK_AC *pAC, SK_IOC IoC);
172#endif /* !SK_DIAG */
173#endif /* n_SKI2C_H */
174
diff --git a/drivers/net/sk98lin/h/skqueue.h b/drivers/net/sk98lin/h/skqueue.h
new file mode 100644
index 000000000000..2ec40d4fdf60
--- /dev/null
+++ b/drivers/net/sk98lin/h/skqueue.h
@@ -0,0 +1,94 @@
1/******************************************************************************
2 *
3 * Name: skqueue.h
4 * Project: Gigabit Ethernet Adapters, Event Scheduler Module
5 * Version: $Revision: 1.16 $
6 * Date: $Date: 2003/09/16 12:50:32 $
7 * Purpose: Defines for the Event queue
8 *
9 ******************************************************************************/
10
11/******************************************************************************
12 *
13 * (C)Copyright 1998-2002 SysKonnect GmbH.
14 * (C)Copyright 2002-2003 Marvell.
15 *
16 * This program is free software; you can redistribute it and/or modify
17 * it under the terms of the GNU General Public License as published by
18 * the Free Software Foundation; either version 2 of the License, or
19 * (at your option) any later version.
20 *
21 * The information in this file is provided "AS IS" without warranty.
22 *
23 ******************************************************************************/
24
25/*
26 * SKQUEUE.H contains all defines and types for the event queue
27 */
28
29#ifndef _SKQUEUE_H_
30#define _SKQUEUE_H_
31
32
33/*
34 * define the event classes to be served
35 */
36#define SKGE_DRV 1 /* Driver Event Class */
37#define SKGE_RLMT 2 /* RLMT Event Class */
38#define SKGE_I2C 3 /* I2C Event Class */
39#define SKGE_PNMI 4 /* PNMI Event Class */
40#define SKGE_CSUM 5 /* Checksum Event Class */
41#define SKGE_HWAC 6 /* Hardware Access Event Class */
42
43#define SKGE_SWT 9 /* Software Timer Event Class */
44#define SKGE_LACP 10 /* LACP Aggregation Event Class */
45#define SKGE_RSF 11 /* RSF Aggregation Event Class */
46#define SKGE_MARKER 12 /* MARKER Aggregation Event Class */
47#define SKGE_FD 13 /* FD Distributor Event Class */
48
49/*
50 * define event queue as circular buffer
51 */
52#define SK_MAX_EVENT 64
53
54/*
55 * Parameter union for the Para stuff
56 */
57typedef union u_EvPara {
58 void *pParaPtr; /* Parameter Pointer */
59 SK_U64 Para64; /* Parameter 64bit version */
60 SK_U32 Para32[2]; /* Parameter Array of 32bit parameters */
61} SK_EVPARA;
62
63/*
64 * Event Queue
65 * skqueue.c
66 * events are class/value pairs
67 * class is addressee, e.g. RLMT, PNMI etc.
68 * value is command, e.g. line state change, ring op change etc.
69 */
70typedef struct s_EventElem {
71 SK_U32 Class; /* Event class */
72 SK_U32 Event; /* Event value */
73 SK_EVPARA Para; /* Event parameter */
74} SK_EVENTELEM;
75
76typedef struct s_Queue {
77 SK_EVENTELEM EvQueue[SK_MAX_EVENT];
78 SK_EVENTELEM *EvPut;
79 SK_EVENTELEM *EvGet;
80} SK_QUEUE;
81
82extern void SkEventInit(SK_AC *pAC, SK_IOC Ioc, int Level);
83extern void SkEventQueue(SK_AC *pAC, SK_U32 Class, SK_U32 Event,
84 SK_EVPARA Para);
85extern int SkEventDispatcher(SK_AC *pAC, SK_IOC Ioc);
86
87
88/* Define Error Numbers and messages */
89#define SKERR_Q_E001 (SK_ERRBASE_QUEUE+0)
90#define SKERR_Q_E001MSG "Event queue overflow"
91#define SKERR_Q_E002 (SKERR_Q_E001+1)
92#define SKERR_Q_E002MSG "Undefined event class"
93#endif /* _SKQUEUE_H_ */
94
diff --git a/drivers/net/sk98lin/h/skrlmt.h b/drivers/net/sk98lin/h/skrlmt.h
new file mode 100644
index 000000000000..ca75dfdcf2d6
--- /dev/null
+++ b/drivers/net/sk98lin/h/skrlmt.h
@@ -0,0 +1,438 @@
1/******************************************************************************
2 *
3 * Name: skrlmt.h
4 * Project: GEnesis, PCI Gigabit Ethernet Adapter
5 * Version: $Revision: 1.37 $
6 * Date: $Date: 2003/04/15 09:43:43 $
7 * Purpose: Header file for Redundant Link ManagemenT.
8 *
9 ******************************************************************************/
10
11/******************************************************************************
12 *
13 * (C)Copyright 1998-2002 SysKonnect GmbH.
14 * (C)Copyright 2002-2003 Marvell.
15 *
16 * This program is free software; you can redistribute it and/or modify
17 * it under the terms of the GNU General Public License as published by
18 * the Free Software Foundation; either version 2 of the License, or
19 * (at your option) any later version.
20 *
21 * The information in this file is provided "AS IS" without warranty.
22 *
23 ******************************************************************************/
24
25/******************************************************************************
26 *
27 * Description:
28 *
29 * This is the header file for Redundant Link ManagemenT.
30 *
31 * Include File Hierarchy:
32 *
33 * "skdrv1st.h"
34 * ...
35 * "sktypes.h"
36 * "skqueue.h"
37 * "skaddr.h"
38 * "skrlmt.h"
39 * ...
40 * "skdrv2nd.h"
41 *
42 ******************************************************************************/
43
44#ifndef __INC_SKRLMT_H
45#define __INC_SKRLMT_H
46
47#ifdef __cplusplus
48extern "C" {
49#endif /* cplusplus */
50
51/* defines ********************************************************************/
52
53#define SK_RLMT_NET_DOWN_TEMP 1 /* NET_DOWN due to last port down. */
54#define SK_RLMT_NET_DOWN_FINAL 2 /* NET_DOWN due to RLMT_STOP. */
55
56/* ----- Default queue sizes - must be multiples of 8 KB ----- */
57
58/* Less than 8 KB free in RX queue => pause frames. */
59#define SK_RLMT_STANDBY_QRXSIZE 128 /* Size of rx standby queue in KB. */
60#define SK_RLMT_STANDBY_QXASIZE 32 /* Size of async standby queue in KB. */
61#define SK_RLMT_STANDBY_QXSSIZE 0 /* Size of sync standby queue in KB. */
62
63#define SK_RLMT_MAX_TX_BUF_SIZE 60 /* Maximum RLMT transmit size. */
64
65/* ----- PORT states ----- */
66
67#define SK_RLMT_PS_INIT 0 /* Port state: Init. */
68#define SK_RLMT_PS_LINK_DOWN 1 /* Port state: Link down. */
69#define SK_RLMT_PS_DOWN 2 /* Port state: Port down. */
70#define SK_RLMT_PS_GOING_UP 3 /* Port state: Going up. */
71#define SK_RLMT_PS_UP 4 /* Port state: Up. */
72
73/* ----- RLMT states ----- */
74
75#define SK_RLMT_RS_INIT 0 /* RLMT state: Init. */
76#define SK_RLMT_RS_NET_DOWN 1 /* RLMT state: Net down. */
77#define SK_RLMT_RS_NET_UP 2 /* RLMT state: Net up. */
78
79/* ----- PORT events ----- */
80
81#define SK_RLMT_LINK_UP 1001 /* Link came up. */
82#define SK_RLMT_LINK_DOWN 1002 /* Link went down. */
83#define SK_RLMT_PORT_ADDR 1003 /* Port address changed. */
84
85/* ----- RLMT events ----- */
86
87#define SK_RLMT_START 2001 /* Start RLMT. */
88#define SK_RLMT_STOP 2002 /* Stop RLMT. */
89#define SK_RLMT_PACKET_RECEIVED 2003 /* Packet was received for RLMT. */
90#define SK_RLMT_STATS_CLEAR 2004 /* Clear statistics. */
91#define SK_RLMT_STATS_UPDATE 2005 /* Update statistics. */
92#define SK_RLMT_PREFPORT_CHANGE 2006 /* Change preferred port. */
93#define SK_RLMT_MODE_CHANGE 2007 /* New RlmtMode. */
94#define SK_RLMT_SET_NETS 2008 /* Number of Nets (1 or 2). */
95
96/* ----- RLMT mode bits ----- */
97
98/*
99 * CAUTION: These defines are private to RLMT.
100 * Please use the RLMT mode defines below.
101 */
102
103#define SK_RLMT_CHECK_LINK 1 /* Check Link. */
104#define SK_RLMT_CHECK_LOC_LINK 2 /* Check other link on same adapter. */
105#define SK_RLMT_CHECK_SEG 4 /* Check segmentation. */
106
107#ifndef RLMT_CHECK_REMOTE
108#define SK_RLMT_CHECK_OTHERS SK_RLMT_CHECK_LOC_LINK
109#else /* RLMT_CHECK_REMOTE */
110#define SK_RLMT_CHECK_REM_LINK 8 /* Check link(s) on other adapter(s). */
111#define SK_RLMT_MAX_REMOTE_PORTS_CHECKED 3
112#define SK_RLMT_CHECK_OTHERS \
113 (SK_RLMT_CHECK_LOC_LINK | SK_RLMT_CHECK_REM_LINK)
114#endif /* RLMT_CHECK_REMOTE */
115
116#ifndef SK_RLMT_ENABLE_TRANSPARENT
117#define SK_RLMT_TRANSPARENT 0 /* RLMT transparent - inactive. */
118#else /* SK_RLMT_ENABLE_TRANSPARENT */
119#define SK_RLMT_TRANSPARENT 128 /* RLMT transparent. */
120#endif /* SK_RLMT_ENABLE_TRANSPARENT */
121
122/* ----- RLMT modes ----- */
123
124/* Check Link State. */
125#define SK_RLMT_MODE_CLS (SK_RLMT_CHECK_LINK)
126
127/* Check Local Ports: check other links on the same adapter. */
128#define SK_RLMT_MODE_CLP (SK_RLMT_CHECK_LINK | SK_RLMT_CHECK_LOC_LINK)
129
130/* Check Local Ports and Segmentation Status. */
131#define SK_RLMT_MODE_CLPSS \
132 (SK_RLMT_CHECK_LINK | SK_RLMT_CHECK_LOC_LINK | SK_RLMT_CHECK_SEG)
133
134#ifdef RLMT_CHECK_REMOTE
135/* Check Local and Remote Ports: check links (local or remote). */
136 Name of define TBD!
137#define SK_RLMT_MODE_CRP \
138 (SK_RLMT_CHECK_LINK | SK_RLMT_CHECK_LOC_LINK | SK_RLMT_CHECK_REM_LINK)
139
140/* Check Local and Remote Ports and Segmentation Status. */
141 Name of define TBD!
142#define SK_RLMT_MODE_CRPSS \
143 (SK_RLMT_CHECK_LINK | SK_RLMT_CHECK_LOC_LINK | \
144 SK_RLMT_CHECK_REM_LINK | SK_RLMT_CHECK_SEG)
145#endif /* RLMT_CHECK_REMOTE */
146
147/* ----- RLMT lookahead result bits ----- */
148
149#define SK_RLMT_RX_RLMT 1 /* Give packet to RLMT. */
150#define SK_RLMT_RX_PROTOCOL 2 /* Give packet to protocol. */
151
152/* Macros */
153
154#if 0
155SK_AC *pAC /* adapter context */
156SK_U32 PortNum /* receiving port */
157unsigned PktLen /* received packet's length */
158SK_BOOL IsBc /* Flag: packet is broadcast */
159unsigned *pOffset /* offs. of bytes to present to SK_RLMT_LOOKAHEAD */
160unsigned *pNumBytes /* #Bytes to present to SK_RLMT_LOOKAHEAD */
161#endif /* 0 */
162
163#define SK_RLMT_PRE_LOOKAHEAD(pAC,PortNum,PktLen,IsBc,pOffset,pNumBytes) { \
164 SK_AC *_pAC; \
165 SK_U32 _PortNum; \
166 _pAC = (pAC); \
167 _PortNum = (SK_U32)(PortNum); \
168 /* _pAC->Rlmt.Port[_PortNum].PacketsRx++; */ \
169 _pAC->Rlmt.Port[_PortNum].PacketsPerTimeSlot++; \
170 if (_pAC->Rlmt.RlmtOff) { \
171 *(pNumBytes) = 0; \
172 } \
173 else {\
174 if ((_pAC->Rlmt.Port[_PortNum].Net->RlmtMode & SK_RLMT_TRANSPARENT) != 0) { \
175 *(pNumBytes) = 0; \
176 } \
177 else if (IsBc) { \
178 if (_pAC->Rlmt.Port[_PortNum].Net->RlmtMode != SK_RLMT_MODE_CLS) { \
179 *(pNumBytes) = 6; \
180 *(pOffset) = 6; \
181 } \
182 else { \
183 *(pNumBytes) = 0; \
184 } \
185 } \
186 else { \
187 if ((PktLen) > SK_RLMT_MAX_TX_BUF_SIZE) { \
188 /* _pAC->Rlmt.Port[_PortNum].DataPacketsPerTimeSlot++; */ \
189 *(pNumBytes) = 0; \
190 } \
191 else { \
192 *(pNumBytes) = 6; \
193 *(pOffset) = 0; \
194 } \
195 } \
196 } \
197}
198
199#if 0
200SK_AC *pAC /* adapter context */
201SK_U32 PortNum /* receiving port */
202SK_U8 *pLaPacket, /* received packet's data (points to pOffset) */
203SK_BOOL IsBc /* Flag: packet is broadcast */
204SK_BOOL IsMc /* Flag: packet is multicast */
205unsigned *pForRlmt /* Result: bits SK_RLMT_RX_RLMT, SK_RLMT_RX_PROTOCOL */
206SK_RLMT_LOOKAHEAD() expects *pNumBytes from
207packet offset *pOffset (s.a.) at *pLaPacket.
208
209If you use SK_RLMT_LOOKAHEAD in a path where you already know if the packet is
210BC, MC, or UC, you should use constants for IsBc and IsMc, so that your compiler
211can trash unneeded parts of the if construction.
212#endif /* 0 */
213
214#define SK_RLMT_LOOKAHEAD(pAC,PortNum,pLaPacket,IsBc,IsMc,pForRlmt) { \
215 SK_AC *_pAC; \
216 SK_U32 _PortNum; \
217 SK_U8 *_pLaPacket; \
218 _pAC = (pAC); \
219 _PortNum = (SK_U32)(PortNum); \
220 _pLaPacket = (SK_U8 *)(pLaPacket); \
221 if (IsBc) {\
222 if (!SK_ADDR_EQUAL(_pLaPacket, _pAC->Addr.Net[_pAC->Rlmt.Port[ \
223 _PortNum].Net->NetNumber].CurrentMacAddress.a)) { \
224 _pAC->Rlmt.Port[_PortNum].BcTimeStamp = SkOsGetTime(_pAC); \
225 _pAC->Rlmt.CheckSwitch = SK_TRUE; \
226 } \
227 /* _pAC->Rlmt.Port[_PortNum].DataPacketsPerTimeSlot++; */ \
228 *(pForRlmt) = SK_RLMT_RX_PROTOCOL; \
229 } \
230 else if (IsMc) { \
231 if (SK_ADDR_EQUAL(_pLaPacket, BridgeMcAddr.a)) { \
232 _pAC->Rlmt.Port[_PortNum].BpduPacketsPerTimeSlot++; \
233 if (_pAC->Rlmt.Port[_PortNum].Net->RlmtMode & SK_RLMT_CHECK_SEG) { \
234 *(pForRlmt) = SK_RLMT_RX_RLMT | SK_RLMT_RX_PROTOCOL; \
235 } \
236 else { \
237 *(pForRlmt) = SK_RLMT_RX_PROTOCOL; \
238 } \
239 } \
240 else if (SK_ADDR_EQUAL(_pLaPacket, SkRlmtMcAddr.a)) { \
241 *(pForRlmt) = SK_RLMT_RX_RLMT; \
242 } \
243 else { \
244 /* _pAC->Rlmt.Port[_PortNum].DataPacketsPerTimeSlot++; */ \
245 *(pForRlmt) = SK_RLMT_RX_PROTOCOL; \
246 } \
247 } \
248 else { \
249 if (SK_ADDR_EQUAL( \
250 _pLaPacket, \
251 _pAC->Addr.Port[_PortNum].CurrentMacAddress.a)) { \
252 *(pForRlmt) = SK_RLMT_RX_RLMT; \
253 } \
254 else { \
255 /* _pAC->Rlmt.Port[_PortNum].DataPacketsPerTimeSlot++; */ \
256 *(pForRlmt) = SK_RLMT_RX_PROTOCOL; \
257 } \
258 } \
259}
260
261#ifdef SK_RLMT_FAST_LOOKAHEAD
262Error: SK_RLMT_FAST_LOOKAHEAD no longer used. Use new macros for lookahead.
263#endif /* SK_RLMT_FAST_LOOKAHEAD */
264#ifdef SK_RLMT_SLOW_LOOKAHEAD
265Error: SK_RLMT_SLOW_LOOKAHEAD no longer used. Use new macros for lookahead.
266#endif /* SK_RLMT_SLOW_LOOKAHEAD */
267
268/* typedefs *******************************************************************/
269
270#ifdef SK_RLMT_MBUF_PRIVATE
271typedef struct s_RlmtMbuf {
272 some content
273} SK_RLMT_MBUF;
274#endif /* SK_RLMT_MBUF_PRIVATE */
275
276
277#ifdef SK_LA_INFO
278typedef struct s_Rlmt_PacketInfo {
279 unsigned PacketLength; /* Length of packet. */
280 unsigned PacketType; /* Directed/Multicast/Broadcast. */
281} SK_RLMT_PINFO;
282#endif /* SK_LA_INFO */
283
284
285typedef struct s_RootId {
286 SK_U8 Id[8]; /* Root Bridge Id. */
287} SK_RLMT_ROOT_ID;
288
289
290typedef struct s_port {
291 SK_MAC_ADDR CheckAddr;
292 SK_BOOL SuspectTx;
293} SK_PORT_CHECK;
294
295
296typedef struct s_RlmtNet SK_RLMT_NET;
297
298
299typedef struct s_RlmtPort {
300
301/* ----- Public part (read-only) ----- */
302
303 SK_U8 PortState; /* Current state of this port. */
304
305 /* For PNMI */
306 SK_BOOL LinkDown;
307 SK_BOOL PortDown;
308 SK_U8 Align01;
309
310 SK_U32 PortNumber; /* Number of port on adapter. */
311 SK_RLMT_NET * Net; /* Net port belongs to. */
312
313 SK_U64 TxHelloCts;
314 SK_U64 RxHelloCts;
315 SK_U64 TxSpHelloReqCts;
316 SK_U64 RxSpHelloCts;
317
318/* ----- Private part ----- */
319
320/* SK_U64 PacketsRx; */ /* Total packets received. */
321 SK_U32 PacketsPerTimeSlot; /* Packets rxed between TOs. */
322/* SK_U32 DataPacketsPerTimeSlot; */ /* Data packets ... */
323 SK_U32 BpduPacketsPerTimeSlot; /* BPDU packets rxed in TS. */
324 SK_U64 BcTimeStamp; /* Time of last BC receive. */
325 SK_U64 GuTimeStamp; /* Time of entering GOING_UP. */
326
327 SK_TIMER UpTimer; /* Timer struct Link/Port up. */
328 SK_TIMER DownRxTimer; /* Timer struct down rx. */
329 SK_TIMER DownTxTimer; /* Timer struct down tx. */
330
331 SK_U32 CheckingState; /* Checking State. */
332
333 SK_ADDR_PORT * AddrPort;
334
335 SK_U8 Random[4]; /* Random value. */
336 unsigned PortsChecked; /* #ports checked. */
337 unsigned PortsSuspect; /* #ports checked that are s. */
338 SK_PORT_CHECK PortCheck[1];
339/* SK_PORT_CHECK PortCheck[SK_MAX_MACS - 1]; */
340
341 SK_BOOL PortStarted; /* Port is started. */
342 SK_BOOL PortNoRx; /* NoRx for >= 1 time slot. */
343 SK_BOOL RootIdSet;
344 SK_RLMT_ROOT_ID Root; /* Root Bridge Id. */
345} SK_RLMT_PORT;
346
347
348struct s_RlmtNet {
349
350/* ----- Public part (read-only) ----- */
351
352 SK_U32 NetNumber; /* Number of net. */
353
354 SK_RLMT_PORT * Port[SK_MAX_MACS]; /* Ports that belong to this net. */
355 SK_U32 NumPorts; /* Number of ports. */
356 SK_U32 PrefPort; /* Preferred port. */
357
358 /* For PNMI */
359
360 SK_U32 ChgBcPrio; /* Change Priority of last broadcast received */
361 SK_U32 RlmtMode; /* Check ... */
362 SK_U32 ActivePort; /* Active port. */
363 SK_U32 Preference; /* 0xFFFFFFFF: Automatic. */
364
365 SK_U8 RlmtState; /* Current RLMT state. */
366
367/* ----- Private part ----- */
368 SK_BOOL RootIdSet;
369 SK_U16 Align01;
370
371 int LinksUp; /* #Links up. */
372 int PortsUp; /* #Ports up. */
373 SK_U32 TimeoutValue; /* RLMT timeout value. */
374
375 SK_U32 CheckingState; /* Checking State. */
376 SK_RLMT_ROOT_ID Root; /* Root Bridge Id. */
377
378 SK_TIMER LocTimer; /* Timer struct. */
379 SK_TIMER SegTimer; /* Timer struct. */
380};
381
382
383typedef struct s_Rlmt {
384
385/* ----- Public part (read-only) ----- */
386
387 SK_U32 NumNets; /* Number of nets. */
388 SK_U32 NetsStarted; /* Number of nets started. */
389 SK_RLMT_NET Net[SK_MAX_NETS]; /* Array of available nets. */
390 SK_RLMT_PORT Port[SK_MAX_MACS]; /* Array of available ports. */
391
392/* ----- Private part ----- */
393 SK_BOOL CheckSwitch;
394 SK_BOOL RlmtOff; /* set to zero if the Mac addresses
395 are equal or the second one
396 is zero */
397 SK_U16 Align01;
398
399} SK_RLMT;
400
401
402extern SK_MAC_ADDR BridgeMcAddr;
403extern SK_MAC_ADDR SkRlmtMcAddr;
404
405/* function prototypes ********************************************************/
406
407
408#ifndef SK_KR_PROTO
409
410/* Functions provided by SkRlmt */
411
412/* ANSI/C++ compliant function prototypes */
413
414extern void SkRlmtInit(
415 SK_AC *pAC,
416 SK_IOC IoC,
417 int Level);
418
419extern int SkRlmtEvent(
420 SK_AC *pAC,
421 SK_IOC IoC,
422 SK_U32 Event,
423 SK_EVPARA Para);
424
425#else /* defined(SK_KR_PROTO) */
426
427/* Non-ANSI/C++ compliant function prototypes */
428
429#error KR-style function prototypes are not yet provided.
430
431#endif /* defined(SK_KR_PROTO)) */
432
433
434#ifdef __cplusplus
435}
436#endif /* __cplusplus */
437
438#endif /* __INC_SKRLMT_H */
diff --git a/drivers/net/sk98lin/h/sktimer.h b/drivers/net/sk98lin/h/sktimer.h
new file mode 100644
index 000000000000..04e6d7c1ec33
--- /dev/null
+++ b/drivers/net/sk98lin/h/sktimer.h
@@ -0,0 +1,63 @@
1/******************************************************************************
2 *
3 * Name: sktimer.h
4 * Project: Gigabit Ethernet Adapters, Event Scheduler Module
5 * Version: $Revision: 1.11 $
6 * Date: $Date: 2003/09/16 12:58:18 $
7 * Purpose: Defines for the timer functions
8 *
9 ******************************************************************************/
10
11/******************************************************************************
12 *
13 * (C)Copyright 1998-2002 SysKonnect GmbH.
14 * (C)Copyright 2002-2003 Marvell.
15 *
16 * This program is free software; you can redistribute it and/or modify
17 * it under the terms of the GNU General Public License as published by
18 * the Free Software Foundation; either version 2 of the License, or
19 * (at your option) any later version.
20 *
21 * The information in this file is provided "AS IS" without warranty.
22 *
23 ******************************************************************************/
24
25/*
26 * SKTIMER.H contains all defines and types for the timer functions
27 */
28
29#ifndef _SKTIMER_H_
30#define _SKTIMER_H_
31
32#include "h/skqueue.h"
33
34/*
35 * SK timer
36 * - needed wherever a timer is used. Put this in your data structure
37 * wherever you want.
38 */
39typedef struct s_Timer SK_TIMER;
40
41struct s_Timer {
42 SK_TIMER *TmNext; /* linked list */
43 SK_U32 TmClass; /* Timer Event class */
44 SK_U32 TmEvent; /* Timer Event value */
45 SK_EVPARA TmPara; /* Timer Event parameter */
46 SK_U32 TmDelta; /* delta time */
47 int TmActive; /* flag: active/inactive */
48};
49
50/*
51 * Timer control struct.
52 * - use in Adapters context name pAC->Tim
53 */
54typedef struct s_TimCtrl {
55 SK_TIMER *StQueue; /* Head of Timer queue */
56} SK_TIMCTRL;
57
58extern void SkTimerInit(SK_AC *pAC, SK_IOC Ioc, int Level);
59extern void SkTimerStop(SK_AC *pAC, SK_IOC Ioc, SK_TIMER *pTimer);
60extern void SkTimerStart(SK_AC *pAC, SK_IOC Ioc, SK_TIMER *pTimer,
61 SK_U32 Time, SK_U32 Class, SK_U32 Event, SK_EVPARA Para);
62extern void SkTimerDone(SK_AC *pAC, SK_IOC Ioc);
63#endif /* _SKTIMER_H_ */
diff --git a/drivers/net/sk98lin/h/sktypes.h b/drivers/net/sk98lin/h/sktypes.h
new file mode 100644
index 000000000000..40edc96e1055
--- /dev/null
+++ b/drivers/net/sk98lin/h/sktypes.h
@@ -0,0 +1,69 @@
1/******************************************************************************
2 *
3 * Name: sktypes.h
4 * Project: GEnesis, PCI Gigabit Ethernet Adapter
5 * Version: $Revision: 1.2 $
6 * Date: $Date: 2003/10/07 08:16:51 $
7 * Purpose: Define data types for Linux
8 *
9 ******************************************************************************/
10
11/******************************************************************************
12 *
13 * (C)Copyright 1998-2002 SysKonnect GmbH.
14 * (C)Copyright 2002-2003 Marvell.
15 *
16 * This program is free software; you can redistribute it and/or modify
17 * it under the terms of the GNU General Public License as published by
18 * the Free Software Foundation; either version 2 of the License, or
19 * (at your option) any later version.
20 *
21 * The information in this file is provided "AS IS" without warranty.
22 *
23 ******************************************************************************/
24
25/******************************************************************************
26 *
27 * Description:
28 *
29 * In this file, all data types that are needed by the common modules
30 * are mapped to Linux data types.
31 *
32 *
33 * Include File Hierarchy:
34 *
35 *
36 ******************************************************************************/
37
38#ifndef __INC_SKTYPES_H
39#define __INC_SKTYPES_H
40
41
42/* defines *******************************************************************/
43
44/*
45 * Data types with a specific size. 'I' = signed, 'U' = unsigned.
46 */
47#define SK_I8 s8
48#define SK_U8 u8
49#define SK_I16 s16
50#define SK_U16 u16
51#define SK_I32 s32
52#define SK_U32 u32
53#define SK_I64 s64
54#define SK_U64 u64
55
56#define SK_UPTR ulong /* casting pointer <-> integral */
57
58/*
59* Boolean type.
60*/
61#define SK_BOOL SK_U8
62#define SK_FALSE 0
63#define SK_TRUE (!SK_FALSE)
64
65/* typedefs *******************************************************************/
66
67/* function prototypes ********************************************************/
68
69#endif /* __INC_SKTYPES_H */
diff --git a/drivers/net/sk98lin/h/skversion.h b/drivers/net/sk98lin/h/skversion.h
new file mode 100644
index 000000000000..a1a7294828e5
--- /dev/null
+++ b/drivers/net/sk98lin/h/skversion.h
@@ -0,0 +1,38 @@
1/******************************************************************************
2 *
3 * Name: version.h
4 * Project: GEnesis, PCI Gigabit Ethernet Adapter
5 * Version: $Revision: 1.5 $
6 * Date: $Date: 2003/10/07 08:16:51 $
7 * Purpose: SK specific Error log support
8 *
9 ******************************************************************************/
10
11/******************************************************************************
12 *
13 * (C)Copyright 1998-2002 SysKonnect GmbH.
14 * (C)Copyright 2002-2003 Marvell.
15 *
16 * This program is free software; you can redistribute it and/or modify
17 * it under the terms of the GNU General Public License as published by
18 * the Free Software Foundation; either version 2 of the License, or
19 * (at your option) any later version.
20 *
21 * The information in this file is provided "AS IS" without warranty.
22 *
23 ******************************************************************************/
24
25#ifdef lint
26static const char SysKonnectFileId[] = "@(#) (C) SysKonnect GmbH.";
27static const char SysKonnectBuildNumber[] =
28 "@(#)SK-BUILD: 6.23 PL: 01";
29#endif /* !defined(lint) */
30
31#define BOOT_STRING "sk98lin: Network Device Driver v6.23\n" \
32 "(C)Copyright 1999-2004 Marvell(R)."
33
34#define VER_STRING "6.23"
35#define DRIVER_FILE_NAME "sk98lin"
36#define DRIVER_REL_DATE "Feb-13-2004"
37
38
diff --git a/drivers/net/sk98lin/h/skvpd.h b/drivers/net/sk98lin/h/skvpd.h
new file mode 100644
index 000000000000..fdd9e48e8040
--- /dev/null
+++ b/drivers/net/sk98lin/h/skvpd.h
@@ -0,0 +1,248 @@
1/******************************************************************************
2 *
3 * Name: skvpd.h
4 * Project: GEnesis, PCI Gigabit Ethernet Adapter
5 * Version: $Revision: 1.15 $
6 * Date: $Date: 2003/01/13 10:39:38 $
7 * Purpose: Defines and Macros for VPD handling
8 *
9 ******************************************************************************/
10
11/******************************************************************************
12 *
13 * (C)Copyright 1998-2003 SysKonnect GmbH.
14 *
15 * This program is free software; you can redistribute it and/or modify
16 * it under the terms of the GNU General Public License as published by
17 * the Free Software Foundation; either version 2 of the License, or
18 * (at your option) any later version.
19 *
20 * The information in this file is provided "AS IS" without warranty.
21 *
22 ******************************************************************************/
23
24/*
25 * skvpd.h contains Diagnostic specific defines for VPD handling
26 */
27
28#ifndef __INC_SKVPD_H_
29#define __INC_SKVPD_H_
30
31/*
32 * Define Resource Type Identifiers and VPD keywords
33 */
34#define RES_ID 0x82 /* Resource Type ID String (Product Name) */
35#define RES_VPD_R 0x90 /* start of VPD read only area */
36#define RES_VPD_W 0x91 /* start of VPD read/write area */
37#define RES_END 0x78 /* Resource Type End Tag */
38
39#ifndef VPD_NAME
40#define VPD_NAME "Name" /* Product Name, VPD name of RES_ID */
41#endif /* VPD_NAME */
42#define VPD_PN "PN" /* Adapter Part Number */
43#define VPD_EC "EC" /* Adapter Engineering Level */
44#define VPD_MN "MN" /* Manufacture ID */
45#define VPD_SN "SN" /* Serial Number */
46#define VPD_CP "CP" /* Extended Capability */
47#define VPD_RV "RV" /* Checksum and Reserved */
48#define VPD_YA "YA" /* Asset Tag Identifier */
49#define VPD_VL "VL" /* First Error Log Message (SK specific) */
50#define VPD_VF "VF" /* Second Error Log Message (SK specific) */
51#define VPD_RW "RW" /* Remaining Read / Write Area */
52
53/* 'type' values for vpd_setup_para() */
54#define VPD_RO_KEY 1 /* RO keys are "PN", "EC", "MN", "SN", "RV" */
55#define VPD_RW_KEY 2 /* RW keys are "Yx", "Vx", and "RW" */
56
57/* 'op' values for vpd_setup_para() */
58#define ADD_KEY 1 /* add the key at the pos "RV" or "RW" */
59#define OWR_KEY 2 /* overwrite key if already exists */
60
61/*
62 * Define READ and WRITE Constants.
63 */
64
65#define VPD_DEV_ID_GENESIS 0x4300
66
67#define VPD_SIZE_YUKON 256
68#define VPD_SIZE_GENESIS 512
69#define VPD_SIZE 512
70#define VPD_READ 0x0000
71#define VPD_WRITE 0x8000
72
73#define VPD_STOP(pAC,IoC) VPD_OUT16(pAC,IoC,PCI_VPD_ADR_REG,VPD_WRITE)
74
75#define VPD_GET_RES_LEN(p) ((unsigned int) \
76 (* (SK_U8 *)&(p)[1]) |\
77 ((* (SK_U8 *)&(p)[2]) << 8))
78#define VPD_GET_VPD_LEN(p) ((unsigned int)(* (SK_U8 *)&(p)[2]))
79#define VPD_GET_VAL(p) ((char *)&(p)[3])
80
81#define VPD_MAX_LEN 50
82
83/* VPD status */
84 /* bit 7..1 reserved */
85#define VPD_VALID (1<<0) /* VPD data buffer, vpd_free_ro, */
86 /* and vpd_free_rw valid */
87
88/*
89 * VPD structs
90 */
91typedef struct s_vpd_status {
92 unsigned short Align01; /* Alignment */
93 unsigned short vpd_status; /* VPD status, description see above */
94 int vpd_free_ro; /* unused bytes in read only area */
95 int vpd_free_rw; /* bytes available in read/write area */
96} SK_VPD_STATUS;
97
98typedef struct s_vpd {
99 SK_VPD_STATUS v; /* VPD status structure */
100 char vpd_buf[VPD_SIZE]; /* VPD buffer */
101 int rom_size; /* VPD ROM Size from PCI_OUR_REG_2 */
102 int vpd_size; /* saved VPD-size */
103} SK_VPD;
104
105typedef struct s_vpd_para {
106 unsigned int p_len; /* parameter length */
107 char *p_val; /* points to the value */
108} SK_VPD_PARA;
109
110/*
111 * structure of Large Resource Type Identifiers
112 */
113
114/* was removed because of alignment problems */
115
116/*
117 * structure of VPD keywords
118 */
119typedef struct s_vpd_key {
120 char p_key[2]; /* 2 bytes ID string */
121 unsigned char p_len; /* 1 byte length */
122 char p_val; /* start of the value string */
123} SK_VPD_KEY;
124
125
126/*
127 * System specific VPD macros
128 */
129#ifndef SKDIAG
130#ifndef VPD_DO_IO
131#define VPD_OUT8(pAC,IoC,Addr,Val) (void)SkPciWriteCfgByte(pAC,Addr,Val)
132#define VPD_OUT16(pAC,IoC,Addr,Val) (void)SkPciWriteCfgWord(pAC,Addr,Val)
133#define VPD_IN8(pAC,IoC,Addr,pVal) (void)SkPciReadCfgByte(pAC,Addr,pVal)
134#define VPD_IN16(pAC,IoC,Addr,pVal) (void)SkPciReadCfgWord(pAC,Addr,pVal)
135#define VPD_IN32(pAC,IoC,Addr,pVal) (void)SkPciReadCfgDWord(pAC,Addr,pVal)
136#else /* VPD_DO_IO */
137#define VPD_OUT8(pAC,IoC,Addr,Val) SK_OUT8(IoC,PCI_C(Addr),Val)
138#define VPD_OUT16(pAC,IoC,Addr,Val) SK_OUT16(IoC,PCI_C(Addr),Val)
139#define VPD_IN8(pAC,IoC,Addr,pVal) SK_IN8(IoC,PCI_C(Addr),pVal)
140#define VPD_IN16(pAC,IoC,Addr,pVal) SK_IN16(IoC,PCI_C(Addr),pVal)
141#define VPD_IN32(pAC,IoC,Addr,pVal) SK_IN32(IoC,PCI_C(Addr),pVal)
142#endif /* VPD_DO_IO */
143#else /* SKDIAG */
144#define VPD_OUT8(pAC,Ioc,Addr,Val) { \
145 if ((pAC)->DgT.DgUseCfgCycle) \
146 SkPciWriteCfgByte(pAC,Addr,Val); \
147 else \
148 SK_OUT8(pAC,PCI_C(Addr),Val); \
149 }
150#define VPD_OUT16(pAC,Ioc,Addr,Val) { \
151 if ((pAC)->DgT.DgUseCfgCycle) \
152 SkPciWriteCfgWord(pAC,Addr,Val); \
153 else \
154 SK_OUT16(pAC,PCI_C(Addr),Val); \
155 }
156#define VPD_IN8(pAC,Ioc,Addr,pVal) { \
157 if ((pAC)->DgT.DgUseCfgCycle) \
158 SkPciReadCfgByte(pAC,Addr,pVal); \
159 else \
160 SK_IN8(pAC,PCI_C(Addr),pVal); \
161 }
162#define VPD_IN16(pAC,Ioc,Addr,pVal) { \
163 if ((pAC)->DgT.DgUseCfgCycle) \
164 SkPciReadCfgWord(pAC,Addr,pVal); \
165 else \
166 SK_IN16(pAC,PCI_C(Addr),pVal); \
167 }
168#define VPD_IN32(pAC,Ioc,Addr,pVal) { \
169 if ((pAC)->DgT.DgUseCfgCycle) \
170 SkPciReadCfgDWord(pAC,Addr,pVal); \
171 else \
172 SK_IN32(pAC,PCI_C(Addr),pVal); \
173 }
174#endif /* nSKDIAG */
175
176/* function prototypes ********************************************************/
177
178#ifndef SK_KR_PROTO
179#ifdef SKDIAG
180extern SK_U32 VpdReadDWord(
181 SK_AC *pAC,
182 SK_IOC IoC,
183 int addr);
184#endif /* SKDIAG */
185
186extern SK_VPD_STATUS *VpdStat(
187 SK_AC *pAC,
188 SK_IOC IoC);
189
190extern int VpdKeys(
191 SK_AC *pAC,
192 SK_IOC IoC,
193 char *buf,
194 int *len,
195 int *elements);
196
197extern int VpdRead(
198 SK_AC *pAC,
199 SK_IOC IoC,
200 const char *key,
201 char *buf,
202 int *len);
203
204extern SK_BOOL VpdMayWrite(
205 char *key);
206
207extern int VpdWrite(
208 SK_AC *pAC,
209 SK_IOC IoC,
210 const char *key,
211 const char *buf);
212
213extern int VpdDelete(
214 SK_AC *pAC,
215 SK_IOC IoC,
216 char *key);
217
218extern int VpdUpdate(
219 SK_AC *pAC,
220 SK_IOC IoC);
221
222#ifdef SKDIAG
223extern int VpdReadBlock(
224 SK_AC *pAC,
225 SK_IOC IoC,
226 char *buf,
227 int addr,
228 int len);
229
230extern int VpdWriteBlock(
231 SK_AC *pAC,
232 SK_IOC IoC,
233 char *buf,
234 int addr,
235 int len);
236#endif /* SKDIAG */
237#else /* SK_KR_PROTO */
238extern SK_U32 VpdReadDWord();
239extern SK_VPD_STATUS *VpdStat();
240extern int VpdKeys();
241extern int VpdRead();
242extern SK_BOOL VpdMayWrite();
243extern int VpdWrite();
244extern int VpdDelete();
245extern int VpdUpdate();
246#endif /* SK_KR_PROTO */
247
248#endif /* __INC_SKVPD_H_ */
diff --git a/drivers/net/sk98lin/h/xmac_ii.h b/drivers/net/sk98lin/h/xmac_ii.h
new file mode 100644
index 000000000000..7f8e6d0084c7
--- /dev/null
+++ b/drivers/net/sk98lin/h/xmac_ii.h
@@ -0,0 +1,1579 @@
1/******************************************************************************
2 *
3 * Name: xmac_ii.h
4 * Project: Gigabit Ethernet Adapters, Common Modules
5 * Version: $Revision: 1.52 $
6 * Date: $Date: 2003/10/02 16:35:50 $
7 * Purpose: Defines and Macros for Gigabit Ethernet Controller
8 *
9 ******************************************************************************/
10
11/******************************************************************************
12 *
13 * (C)Copyright 1998-2002 SysKonnect.
14 * (C)Copyright 2002-2003 Marvell.
15 *
16 * This program is free software; you can redistribute it and/or modify
17 * it under the terms of the GNU General Public License as published by
18 * the Free Software Foundation; either version 2 of the License, or
19 * (at your option) any later version.
20 *
21 * The information in this file is provided "AS IS" without warranty.
22 *
23 ******************************************************************************/
24
25#ifndef __INC_XMAC_H
26#define __INC_XMAC_H
27
28#ifdef __cplusplus
29extern "C" {
30#endif /* __cplusplus */
31
32/* defines ********************************************************************/
33
34/*
35 * XMAC II registers
36 *
37 * The XMAC registers are 16 or 32 bits wide.
38 * The XMACs host processor interface is set to 16 bit mode,
39 * therefore ALL registers will be addressed with 16 bit accesses.
40 *
41 * The following macros are provided to access the XMAC registers
42 * XM_IN16(), XM_OUT16, XM_IN32(), XM_OUT32(), XM_INADR(), XM_OUTADR(),
43 * XM_INHASH(), and XM_OUTHASH().
44 * The macros are defined in SkGeHw.h.
45 *
46 * Note: NA reg = Network Address e.g DA, SA etc.
47 *
48 */
49#define XM_MMU_CMD 0x0000 /* 16 bit r/w MMU Command Register */
50 /* 0x0004: reserved */
51#define XM_POFF 0x0008 /* 32 bit r/w Packet Offset Register */
52#define XM_BURST 0x000c /* 32 bit r/w Burst Register for half duplex*/
53#define XM_1L_VLAN_TAG 0x0010 /* 16 bit r/w One Level VLAN Tag ID */
54#define XM_2L_VLAN_TAG 0x0014 /* 16 bit r/w Two Level VLAN Tag ID */
55 /* 0x0018 - 0x001e: reserved */
56#define XM_TX_CMD 0x0020 /* 16 bit r/w Transmit Command Register */
57#define XM_TX_RT_LIM 0x0024 /* 16 bit r/w Transmit Retry Limit Register */
58#define XM_TX_STIME 0x0028 /* 16 bit r/w Transmit Slottime Register */
59#define XM_TX_IPG 0x002c /* 16 bit r/w Transmit Inter Packet Gap */
60#define XM_RX_CMD 0x0030 /* 16 bit r/w Receive Command Register */
61#define XM_PHY_ADDR 0x0034 /* 16 bit r/w PHY Address Register */
62#define XM_PHY_DATA 0x0038 /* 16 bit r/w PHY Data Register */
63 /* 0x003c: reserved */
64#define XM_GP_PORT 0x0040 /* 32 bit r/w General Purpose Port Register */
65#define XM_IMSK 0x0044 /* 16 bit r/w Interrupt Mask Register */
66#define XM_ISRC 0x0048 /* 16 bit r/o Interrupt Status Register */
67#define XM_HW_CFG 0x004c /* 16 bit r/w Hardware Config Register */
68 /* 0x0050 - 0x005e: reserved */
69#define XM_TX_LO_WM 0x0060 /* 16 bit r/w Tx FIFO Low Water Mark */
70#define XM_TX_HI_WM 0x0062 /* 16 bit r/w Tx FIFO High Water Mark */
71#define XM_TX_THR 0x0064 /* 16 bit r/w Tx Request Threshold */
72#define XM_HT_THR 0x0066 /* 16 bit r/w Host Request Threshold */
73#define XM_PAUSE_DA 0x0068 /* NA reg r/w Pause Destination Address */
74 /* 0x006e: reserved */
75#define XM_CTL_PARA 0x0070 /* 32 bit r/w Control Parameter Register */
76#define XM_MAC_OPCODE 0x0074 /* 16 bit r/w Opcode for MAC control frames */
77#define XM_MAC_PTIME 0x0076 /* 16 bit r/w Pause time for MAC ctrl frames*/
78#define XM_TX_STAT 0x0078 /* 32 bit r/o Tx Status LIFO Register */
79
80 /* 0x0080 - 0x00fc: 16 NA reg r/w Exact Match Address Registers */
81 /* use the XM_EXM() macro to address */
82#define XM_EXM_START 0x0080 /* r/w Start Address of the EXM Regs */
83
84 /*
85 * XM_EXM(Reg)
86 *
87 * returns the XMAC address offset of specified Exact Match Addr Reg
88 *
89 * para: Reg EXM register to addr (0 .. 15)
90 *
91 * usage: XM_INADDR(IoC, MAC_1, XM_EXM(i), &val[i]);
92 */
93#define XM_EXM(Reg) (XM_EXM_START + ((Reg) << 3))
94
95#define XM_SRC_CHK 0x0100 /* NA reg r/w Source Check Address Register */
96#define XM_SA 0x0108 /* NA reg r/w Station Address Register */
97#define XM_HSM 0x0110 /* 64 bit r/w Hash Match Address Registers */
98#define XM_RX_LO_WM 0x0118 /* 16 bit r/w Receive Low Water Mark */
99#define XM_RX_HI_WM 0x011a /* 16 bit r/w Receive High Water Mark */
100#define XM_RX_THR 0x011c /* 32 bit r/w Receive Request Threshold */
101#define XM_DEV_ID 0x0120 /* 32 bit r/o Device ID Register */
102#define XM_MODE 0x0124 /* 32 bit r/w Mode Register */
103#define XM_LSA 0x0128 /* NA reg r/o Last Source Register */
104 /* 0x012e: reserved */
105#define XM_TS_READ 0x0130 /* 32 bit r/o Time Stamp Read Register */
106#define XM_TS_LOAD 0x0134 /* 32 bit r/o Time Stamp Load Value */
107 /* 0x0138 - 0x01fe: reserved */
108#define XM_STAT_CMD 0x0200 /* 16 bit r/w Statistics Command Register */
109#define XM_RX_CNT_EV 0x0204 /* 32 bit r/o Rx Counter Event Register */
110#define XM_TX_CNT_EV 0x0208 /* 32 bit r/o Tx Counter Event Register */
111#define XM_RX_EV_MSK 0x020c /* 32 bit r/w Rx Counter Event Mask */
112#define XM_TX_EV_MSK 0x0210 /* 32 bit r/w Tx Counter Event Mask */
113 /* 0x0204 - 0x027e: reserved */
114#define XM_TXF_OK 0x0280 /* 32 bit r/o Frames Transmitted OK Conuter */
115#define XM_TXO_OK_HI 0x0284 /* 32 bit r/o Octets Transmitted OK High Cnt*/
116#define XM_TXO_OK_LO 0x0288 /* 32 bit r/o Octets Transmitted OK Low Cnt */
117#define XM_TXF_BC_OK 0x028c /* 32 bit r/o Broadcast Frames Xmitted OK */
118#define XM_TXF_MC_OK 0x0290 /* 32 bit r/o Multicast Frames Xmitted OK */
119#define XM_TXF_UC_OK 0x0294 /* 32 bit r/o Unicast Frames Xmitted OK */
120#define XM_TXF_LONG 0x0298 /* 32 bit r/o Tx Long Frame Counter */
121#define XM_TXE_BURST 0x029c /* 32 bit r/o Tx Burst Event Counter */
122#define XM_TXF_MPAUSE 0x02a0 /* 32 bit r/o Tx Pause MAC Ctrl Frame Cnt */
123#define XM_TXF_MCTRL 0x02a4 /* 32 bit r/o Tx MAC Ctrl Frame Counter */
124#define XM_TXF_SNG_COL 0x02a8 /* 32 bit r/o Tx Single Collision Counter */
125#define XM_TXF_MUL_COL 0x02ac /* 32 bit r/o Tx Multiple Collision Counter */
126#define XM_TXF_ABO_COL 0x02b0 /* 32 bit r/o Tx aborted due to Exces. Col. */
127#define XM_TXF_LAT_COL 0x02b4 /* 32 bit r/o Tx Late Collision Counter */
128#define XM_TXF_DEF 0x02b8 /* 32 bit r/o Tx Deferred Frame Counter */
129#define XM_TXF_EX_DEF 0x02bc /* 32 bit r/o Tx Excessive Deferall Counter */
130#define XM_TXE_FIFO_UR 0x02c0 /* 32 bit r/o Tx FIFO Underrun Event Cnt */
131#define XM_TXE_CS_ERR 0x02c4 /* 32 bit r/o Tx Carrier Sense Error Cnt */
132#define XM_TXP_UTIL 0x02c8 /* 32 bit r/o Tx Utilization in % */
133 /* 0x02cc - 0x02ce: reserved */
134#define XM_TXF_64B 0x02d0 /* 32 bit r/o 64 Byte Tx Frame Counter */
135#define XM_TXF_127B 0x02d4 /* 32 bit r/o 65-127 Byte Tx Frame Counter */
136#define XM_TXF_255B 0x02d8 /* 32 bit r/o 128-255 Byte Tx Frame Counter */
137#define XM_TXF_511B 0x02dc /* 32 bit r/o 256-511 Byte Tx Frame Counter */
138#define XM_TXF_1023B 0x02e0 /* 32 bit r/o 512-1023 Byte Tx Frame Counter*/
139#define XM_TXF_MAX_SZ 0x02e4 /* 32 bit r/o 1024-MaxSize Byte Tx Frame Cnt*/
140 /* 0x02e8 - 0x02fe: reserved */
141#define XM_RXF_OK 0x0300 /* 32 bit r/o Frames Received OK */
142#define XM_RXO_OK_HI 0x0304 /* 32 bit r/o Octets Received OK High Cnt */
143#define XM_RXO_OK_LO 0x0308 /* 32 bit r/o Octets Received OK Low Counter*/
144#define XM_RXF_BC_OK 0x030c /* 32 bit r/o Broadcast Frames Received OK */
145#define XM_RXF_MC_OK 0x0310 /* 32 bit r/o Multicast Frames Received OK */
146#define XM_RXF_UC_OK 0x0314 /* 32 bit r/o Unicast Frames Received OK */
147#define XM_RXF_MPAUSE 0x0318 /* 32 bit r/o Rx Pause MAC Ctrl Frame Cnt */
148#define XM_RXF_MCTRL 0x031c /* 32 bit r/o Rx MAC Ctrl Frame Counter */
149#define XM_RXF_INV_MP 0x0320 /* 32 bit r/o Rx invalid Pause Frame Cnt */
150#define XM_RXF_INV_MOC 0x0324 /* 32 bit r/o Rx Frames with inv. MAC Opcode*/
151#define XM_RXE_BURST 0x0328 /* 32 bit r/o Rx Burst Event Counter */
152#define XM_RXE_FMISS 0x032c /* 32 bit r/o Rx Missed Frames Event Cnt */
153#define XM_RXF_FRA_ERR 0x0330 /* 32 bit r/o Rx Framing Error Counter */
154#define XM_RXE_FIFO_OV 0x0334 /* 32 bit r/o Rx FIFO overflow Event Cnt */
155#define XM_RXF_JAB_PKT 0x0338 /* 32 bit r/o Rx Jabber Packet Frame Cnt */
156#define XM_RXE_CAR_ERR 0x033c /* 32 bit r/o Rx Carrier Event Error Cnt */
157#define XM_RXF_LEN_ERR 0x0340 /* 32 bit r/o Rx in Range Length Error */
158#define XM_RXE_SYM_ERR 0x0344 /* 32 bit r/o Rx Symbol Error Counter */
159#define XM_RXE_SHT_ERR 0x0348 /* 32 bit r/o Rx Short Event Error Cnt */
160#define XM_RXE_RUNT 0x034c /* 32 bit r/o Rx Runt Event Counter */
161#define XM_RXF_LNG_ERR 0x0350 /* 32 bit r/o Rx Frame too Long Error Cnt */
162#define XM_RXF_FCS_ERR 0x0354 /* 32 bit r/o Rx Frame Check Seq. Error Cnt */
163 /* 0x0358 - 0x035a: reserved */
164#define XM_RXF_CEX_ERR 0x035c /* 32 bit r/o Rx Carrier Ext Error Frame Cnt*/
165#define XM_RXP_UTIL 0x0360 /* 32 bit r/o Rx Utilization in % */
166 /* 0x0364 - 0x0366: reserved */
167#define XM_RXF_64B 0x0368 /* 32 bit r/o 64 Byte Rx Frame Counter */
168#define XM_RXF_127B 0x036c /* 32 bit r/o 65-127 Byte Rx Frame Counter */
169#define XM_RXF_255B 0x0370 /* 32 bit r/o 128-255 Byte Rx Frame Counter */
170#define XM_RXF_511B 0x0374 /* 32 bit r/o 256-511 Byte Rx Frame Counter */
171#define XM_RXF_1023B 0x0378 /* 32 bit r/o 512-1023 Byte Rx Frame Counter*/
172#define XM_RXF_MAX_SZ 0x037c /* 32 bit r/o 1024-MaxSize Byte Rx Frame Cnt*/
173 /* 0x02e8 - 0x02fe: reserved */
174
175
176/*----------------------------------------------------------------------------*/
177/*
178 * XMAC Bit Definitions
179 *
180 * If the bit access behaviour differs from the register access behaviour
181 * (r/w, r/o) this is documented after the bit number.
182 * The following bit access behaviours are used:
183 * (sc) self clearing
184 * (ro) read only
185 */
186
187/* XM_MMU_CMD 16 bit r/w MMU Command Register */
188 /* Bit 15..13: reserved */
189#define XM_MMU_PHY_RDY (1<<12) /* Bit 12: PHY Read Ready */
190#define XM_MMU_PHY_BUSY (1<<11) /* Bit 11: PHY Busy */
191#define XM_MMU_IGN_PF (1<<10) /* Bit 10: Ignore Pause Frame */
192#define XM_MMU_MAC_LB (1<<9) /* Bit 9: Enable MAC Loopback */
193 /* Bit 8: reserved */
194#define XM_MMU_FRC_COL (1<<7) /* Bit 7: Force Collision */
195#define XM_MMU_SIM_COL (1<<6) /* Bit 6: Simulate Collision */
196#define XM_MMU_NO_PRE (1<<5) /* Bit 5: No MDIO Preamble */
197#define XM_MMU_GMII_FD (1<<4) /* Bit 4: GMII uses Full Duplex */
198#define XM_MMU_RAT_CTRL (1<<3) /* Bit 3: Enable Rate Control */
199#define XM_MMU_GMII_LOOP (1<<2) /* Bit 2: PHY is in Loopback Mode */
200#define XM_MMU_ENA_RX (1<<1) /* Bit 1: Enable Receiver */
201#define XM_MMU_ENA_TX (1<<0) /* Bit 0: Enable Transmitter */
202
203
204/* XM_TX_CMD 16 bit r/w Transmit Command Register */
205 /* Bit 15..7: reserved */
206#define XM_TX_BK2BK (1<<6) /* Bit 6: Ignor Carrier Sense (Tx Bk2Bk)*/
207#define XM_TX_ENC_BYP (1<<5) /* Bit 5: Set Encoder in Bypass Mode */
208#define XM_TX_SAM_LINE (1<<4) /* Bit 4: (sc) Start utilization calculation */
209#define XM_TX_NO_GIG_MD (1<<3) /* Bit 3: Disable Carrier Extension */
210#define XM_TX_NO_PRE (1<<2) /* Bit 2: Disable Preamble Generation */
211#define XM_TX_NO_CRC (1<<1) /* Bit 1: Disable CRC Generation */
212#define XM_TX_AUTO_PAD (1<<0) /* Bit 0: Enable Automatic Padding */
213
214
215/* XM_TX_RT_LIM 16 bit r/w Transmit Retry Limit Register */
216 /* Bit 15..5: reserved */
217#define XM_RT_LIM_MSK 0x1f /* Bit 4..0: Tx Retry Limit */
218
219
220/* XM_TX_STIME 16 bit r/w Transmit Slottime Register */
221 /* Bit 15..7: reserved */
222#define XM_STIME_MSK 0x7f /* Bit 6..0: Tx Slottime bits */
223
224
225/* XM_TX_IPG 16 bit r/w Transmit Inter Packet Gap */
226 /* Bit 15..8: reserved */
227#define XM_IPG_MSK 0xff /* Bit 7..0: IPG value bits */
228
229
230/* XM_RX_CMD 16 bit r/w Receive Command Register */
231 /* Bit 15..9: reserved */
232#define XM_RX_LENERR_OK (1<<8) /* Bit 8 don't set Rx Err bit for */
233 /* inrange error packets */
234#define XM_RX_BIG_PK_OK (1<<7) /* Bit 7 don't set Rx Err bit for */
235 /* jumbo packets */
236#define XM_RX_IPG_CAP (1<<6) /* Bit 6 repl. type field with IPG */
237#define XM_RX_TP_MD (1<<5) /* Bit 5: Enable transparent Mode */
238#define XM_RX_STRIP_FCS (1<<4) /* Bit 4: Enable FCS Stripping */
239#define XM_RX_SELF_RX (1<<3) /* Bit 3: Enable Rx of own packets */
240#define XM_RX_SAM_LINE (1<<2) /* Bit 2: (sc) Start utilization calculation */
241#define XM_RX_STRIP_PAD (1<<1) /* Bit 1: Strip pad bytes of Rx frames */
242#define XM_RX_DIS_CEXT (1<<0) /* Bit 0: Disable carrier ext. check */
243
244
245/* XM_PHY_ADDR 16 bit r/w PHY Address Register */
246 /* Bit 15..5: reserved */
247#define XM_PHY_ADDR_SZ 0x1f /* Bit 4..0: PHY Address bits */
248
249
250/* XM_GP_PORT 32 bit r/w General Purpose Port Register */
251 /* Bit 31..7: reserved */
252#define XM_GP_ANIP (1L<<6) /* Bit 6: (ro) Auto-Neg. in progress */
253#define XM_GP_FRC_INT (1L<<5) /* Bit 5: (sc) Force Interrupt */
254 /* Bit 4: reserved */
255#define XM_GP_RES_MAC (1L<<3) /* Bit 3: (sc) Reset MAC and FIFOs */
256#define XM_GP_RES_STAT (1L<<2) /* Bit 2: (sc) Reset the statistics module */
257 /* Bit 1: reserved */
258#define XM_GP_INP_ASS (1L<<0) /* Bit 0: (ro) GP Input Pin asserted */
259
260
261/* XM_IMSK 16 bit r/w Interrupt Mask Register */
262/* XM_ISRC 16 bit r/o Interrupt Status Register */
263 /* Bit 15: reserved */
264#define XM_IS_LNK_AE (1<<14) /* Bit 14: Link Asynchronous Event */
265#define XM_IS_TX_ABORT (1<<13) /* Bit 13: Transmit Abort, late Col. etc */
266#define XM_IS_FRC_INT (1<<12) /* Bit 12: Force INT bit set in GP */
267#define XM_IS_INP_ASS (1<<11) /* Bit 11: Input Asserted, GP bit 0 set */
268#define XM_IS_LIPA_RC (1<<10) /* Bit 10: Link Partner requests config */
269#define XM_IS_RX_PAGE (1<<9) /* Bit 9: Page Received */
270#define XM_IS_TX_PAGE (1<<8) /* Bit 8: Next Page Loaded for Transmit */
271#define XM_IS_AND (1<<7) /* Bit 7: Auto-Negotiation Done */
272#define XM_IS_TSC_OV (1<<6) /* Bit 6: Time Stamp Counter Overflow */
273#define XM_IS_RXC_OV (1<<5) /* Bit 5: Rx Counter Event Overflow */
274#define XM_IS_TXC_OV (1<<4) /* Bit 4: Tx Counter Event Overflow */
275#define XM_IS_RXF_OV (1<<3) /* Bit 3: Receive FIFO Overflow */
276#define XM_IS_TXF_UR (1<<2) /* Bit 2: Transmit FIFO Underrun */
277#define XM_IS_TX_COMP (1<<1) /* Bit 1: Frame Tx Complete */
278#define XM_IS_RX_COMP (1<<0) /* Bit 0: Frame Rx Complete */
279
280#define XM_DEF_MSK (~(XM_IS_INP_ASS | XM_IS_LIPA_RC | XM_IS_RX_PAGE |\
281 XM_IS_AND | XM_IS_RXC_OV | XM_IS_TXC_OV | XM_IS_TXF_UR))
282
283
284/* XM_HW_CFG 16 bit r/w Hardware Config Register */
285 /* Bit 15.. 4: reserved */
286#define XM_HW_GEN_EOP (1<<3) /* Bit 3: generate End of Packet pulse */
287#define XM_HW_COM4SIG (1<<2) /* Bit 2: use Comma Detect for Sig. Det.*/
288 /* Bit 1: reserved */
289#define XM_HW_GMII_MD (1<<0) /* Bit 0: GMII Interface selected */
290
291
292/* XM_TX_LO_WM 16 bit r/w Tx FIFO Low Water Mark */
293/* XM_TX_HI_WM 16 bit r/w Tx FIFO High Water Mark */
294 /* Bit 15..10 reserved */
295#define XM_TX_WM_MSK 0x01ff /* Bit 9.. 0 Tx FIFO Watermark bits */
296
297/* XM_TX_THR 16 bit r/w Tx Request Threshold */
298/* XM_HT_THR 16 bit r/w Host Request Threshold */
299/* XM_RX_THR 16 bit r/w Rx Request Threshold */
300 /* Bit 15..11 reserved */
301#define XM_THR_MSK 0x03ff /* Bit 10.. 0 Rx/Tx Request Threshold bits */
302
303
304/* XM_TX_STAT 32 bit r/o Tx Status LIFO Register */
305#define XM_ST_VALID (1UL<<31) /* Bit 31: Status Valid */
306#define XM_ST_BYTE_CNT (0x3fffL<<17) /* Bit 30..17: Tx frame Length */
307#define XM_ST_RETRY_CNT (0x1fL<<12) /* Bit 16..12: Retry Count */
308#define XM_ST_EX_COL (1L<<11) /* Bit 11: Excessive Collisions */
309#define XM_ST_EX_DEF (1L<<10) /* Bit 10: Excessive Deferral */
310#define XM_ST_BURST (1L<<9) /* Bit 9: p. xmitted in burst md*/
311#define XM_ST_DEFER (1L<<8) /* Bit 8: packet was defered */
312#define XM_ST_BC (1L<<7) /* Bit 7: Broadcast packet */
313#define XM_ST_MC (1L<<6) /* Bit 6: Multicast packet */
314#define XM_ST_UC (1L<<5) /* Bit 5: Unicast packet */
315#define XM_ST_TX_UR (1L<<4) /* Bit 4: FIFO Underrun occured */
316#define XM_ST_CS_ERR (1L<<3) /* Bit 3: Carrier Sense Error */
317#define XM_ST_LAT_COL (1L<<2) /* Bit 2: Late Collision Error */
318#define XM_ST_MUL_COL (1L<<1) /* Bit 1: Multiple Collisions */
319#define XM_ST_SGN_COL (1L<<0) /* Bit 0: Single Collision */
320
321/* XM_RX_LO_WM 16 bit r/w Receive Low Water Mark */
322/* XM_RX_HI_WM 16 bit r/w Receive High Water Mark */
323 /* Bit 15..11: reserved */
324#define XM_RX_WM_MSK 0x03ff /* Bit 11.. 0: Rx FIFO Watermark bits */
325
326
327/* XM_DEV_ID 32 bit r/o Device ID Register */
328#define XM_DEV_OUI (0x00ffffffUL<<8) /* Bit 31..8: Device OUI */
329#define XM_DEV_REV (0x07L << 5) /* Bit 7..5: Chip Rev Num */
330
331
332/* XM_MODE 32 bit r/w Mode Register */
333 /* Bit 31..27: reserved */
334#define XM_MD_ENA_REJ (1L<<26) /* Bit 26: Enable Frame Reject */
335#define XM_MD_SPOE_E (1L<<25) /* Bit 25: Send Pause on Edge */
336 /* extern generated */
337#define XM_MD_TX_REP (1L<<24) /* Bit 24: Transmit Repeater Mode */
338#define XM_MD_SPOFF_I (1L<<23) /* Bit 23: Send Pause on FIFO full */
339 /* intern generated */
340#define XM_MD_LE_STW (1L<<22) /* Bit 22: Rx Stat Word in Little Endian */
341#define XM_MD_TX_CONT (1L<<21) /* Bit 21: Send Continuous */
342#define XM_MD_TX_PAUSE (1L<<20) /* Bit 20: (sc) Send Pause Frame */
343#define XM_MD_ATS (1L<<19) /* Bit 19: Append Time Stamp */
344#define XM_MD_SPOL_I (1L<<18) /* Bit 18: Send Pause on Low */
345 /* intern generated */
346#define XM_MD_SPOH_I (1L<<17) /* Bit 17: Send Pause on High */
347 /* intern generated */
348#define XM_MD_CAP (1L<<16) /* Bit 16: Check Address Pair */
349#define XM_MD_ENA_HASH (1L<<15) /* Bit 15: Enable Hashing */
350#define XM_MD_CSA (1L<<14) /* Bit 14: Check Station Address */
351#define XM_MD_CAA (1L<<13) /* Bit 13: Check Address Array */
352#define XM_MD_RX_MCTRL (1L<<12) /* Bit 12: Rx MAC Control Frame */
353#define XM_MD_RX_RUNT (1L<<11) /* Bit 11: Rx Runt Frames */
354#define XM_MD_RX_IRLE (1L<<10) /* Bit 10: Rx in Range Len Err Frame */
355#define XM_MD_RX_LONG (1L<<9) /* Bit 9: Rx Long Frame */
356#define XM_MD_RX_CRCE (1L<<8) /* Bit 8: Rx CRC Error Frame */
357#define XM_MD_RX_ERR (1L<<7) /* Bit 7: Rx Error Frame */
358#define XM_MD_DIS_UC (1L<<6) /* Bit 6: Disable Rx Unicast */
359#define XM_MD_DIS_MC (1L<<5) /* Bit 5: Disable Rx Multicast */
360#define XM_MD_DIS_BC (1L<<4) /* Bit 4: Disable Rx Broadcast */
361#define XM_MD_ENA_PROM (1L<<3) /* Bit 3: Enable Promiscuous */
362#define XM_MD_ENA_BE (1L<<2) /* Bit 2: Enable Big Endian */
363#define XM_MD_FTF (1L<<1) /* Bit 1: (sc) Flush Tx FIFO */
364#define XM_MD_FRF (1L<<0) /* Bit 0: (sc) Flush Rx FIFO */
365
366#define XM_PAUSE_MODE (XM_MD_SPOE_E | XM_MD_SPOL_I | XM_MD_SPOH_I)
367#define XM_DEF_MODE (XM_MD_RX_RUNT | XM_MD_RX_IRLE | XM_MD_RX_LONG |\
368 XM_MD_RX_CRCE | XM_MD_RX_ERR | XM_MD_CSA | XM_MD_CAA)
369
370/* XM_STAT_CMD 16 bit r/w Statistics Command Register */
371 /* Bit 16..6: reserved */
372#define XM_SC_SNP_RXC (1<<5) /* Bit 5: (sc) Snap Rx Counters */
373#define XM_SC_SNP_TXC (1<<4) /* Bit 4: (sc) Snap Tx Counters */
374#define XM_SC_CP_RXC (1<<3) /* Bit 3: Copy Rx Counters Continuously */
375#define XM_SC_CP_TXC (1<<2) /* Bit 2: Copy Tx Counters Continuously */
376#define XM_SC_CLR_RXC (1<<1) /* Bit 1: (sc) Clear Rx Counters */
377#define XM_SC_CLR_TXC (1<<0) /* Bit 0: (sc) Clear Tx Counters */
378
379
380/* XM_RX_CNT_EV 32 bit r/o Rx Counter Event Register */
381/* XM_RX_EV_MSK 32 bit r/w Rx Counter Event Mask */
382#define XMR_MAX_SZ_OV (1UL<<31) /* Bit 31: 1024-MaxSize Rx Cnt Ov*/
383#define XMR_1023B_OV (1L<<30) /* Bit 30: 512-1023Byte Rx Cnt Ov*/
384#define XMR_511B_OV (1L<<29) /* Bit 29: 256-511 Byte Rx Cnt Ov*/
385#define XMR_255B_OV (1L<<28) /* Bit 28: 128-255 Byte Rx Cnt Ov*/
386#define XMR_127B_OV (1L<<27) /* Bit 27: 65-127 Byte Rx Cnt Ov */
387#define XMR_64B_OV (1L<<26) /* Bit 26: 64 Byte Rx Cnt Ov */
388#define XMR_UTIL_OV (1L<<25) /* Bit 25: Rx Util Cnt Overflow */
389#define XMR_UTIL_UR (1L<<24) /* Bit 24: Rx Util Cnt Underrun */
390#define XMR_CEX_ERR_OV (1L<<23) /* Bit 23: CEXT Err Cnt Ov */
391 /* Bit 22: reserved */
392#define XMR_FCS_ERR_OV (1L<<21) /* Bit 21: Rx FCS Error Cnt Ov */
393#define XMR_LNG_ERR_OV (1L<<20) /* Bit 20: Rx too Long Err Cnt Ov*/
394#define XMR_RUNT_OV (1L<<19) /* Bit 19: Runt Event Cnt Ov */
395#define XMR_SHT_ERR_OV (1L<<18) /* Bit 18: Rx Short Ev Err Cnt Ov*/
396#define XMR_SYM_ERR_OV (1L<<17) /* Bit 17: Rx Sym Err Cnt Ov */
397 /* Bit 16: reserved */
398#define XMR_CAR_ERR_OV (1L<<15) /* Bit 15: Rx Carr Ev Err Cnt Ov */
399#define XMR_JAB_PKT_OV (1L<<14) /* Bit 14: Rx Jabb Packet Cnt Ov */
400#define XMR_FIFO_OV (1L<<13) /* Bit 13: Rx FIFO Ov Ev Cnt Ov */
401#define XMR_FRA_ERR_OV (1L<<12) /* Bit 12: Rx Framing Err Cnt Ov */
402#define XMR_FMISS_OV (1L<<11) /* Bit 11: Rx Missed Ev Cnt Ov */
403#define XMR_BURST (1L<<10) /* Bit 10: Rx Burst Event Cnt Ov */
404#define XMR_INV_MOC (1L<<9) /* Bit 9: Rx with inv. MAC OC Ov*/
405#define XMR_INV_MP (1L<<8) /* Bit 8: Rx inv Pause Frame Ov */
406#define XMR_MCTRL_OV (1L<<7) /* Bit 7: Rx MAC Ctrl-F Cnt Ov */
407#define XMR_MPAUSE_OV (1L<<6) /* Bit 6: Rx Pause MAC Ctrl-F Ov*/
408#define XMR_UC_OK_OV (1L<<5) /* Bit 5: Rx Unicast Frame CntOv*/
409#define XMR_MC_OK_OV (1L<<4) /* Bit 4: Rx Multicast Cnt Ov */
410#define XMR_BC_OK_OV (1L<<3) /* Bit 3: Rx Broadcast Cnt Ov */
411#define XMR_OK_LO_OV (1L<<2) /* Bit 2: Octets Rx OK Low CntOv*/
412#define XMR_OK_HI_OV (1L<<1) /* Bit 1: Octets Rx OK Hi Cnt Ov*/
413#define XMR_OK_OV (1L<<0) /* Bit 0: Frames Received Ok Ov */
414
415#define XMR_DEF_MSK (XMR_OK_LO_OV | XMR_OK_HI_OV)
416
417/* XM_TX_CNT_EV 32 bit r/o Tx Counter Event Register */
418/* XM_TX_EV_MSK 32 bit r/w Tx Counter Event Mask */
419 /* Bit 31..26: reserved */
420#define XMT_MAX_SZ_OV (1L<<25) /* Bit 25: 1024-MaxSize Tx Cnt Ov*/
421#define XMT_1023B_OV (1L<<24) /* Bit 24: 512-1023Byte Tx Cnt Ov*/
422#define XMT_511B_OV (1L<<23) /* Bit 23: 256-511 Byte Tx Cnt Ov*/
423#define XMT_255B_OV (1L<<22) /* Bit 22: 128-255 Byte Tx Cnt Ov*/
424#define XMT_127B_OV (1L<<21) /* Bit 21: 65-127 Byte Tx Cnt Ov */
425#define XMT_64B_OV (1L<<20) /* Bit 20: 64 Byte Tx Cnt Ov */
426#define XMT_UTIL_OV (1L<<19) /* Bit 19: Tx Util Cnt Overflow */
427#define XMT_UTIL_UR (1L<<18) /* Bit 18: Tx Util Cnt Underrun */
428#define XMT_CS_ERR_OV (1L<<17) /* Bit 17: Tx Carr Sen Err Cnt Ov*/
429#define XMT_FIFO_UR_OV (1L<<16) /* Bit 16: Tx FIFO Ur Ev Cnt Ov */
430#define XMT_EX_DEF_OV (1L<<15) /* Bit 15: Tx Ex Deferall Cnt Ov */
431#define XMT_DEF (1L<<14) /* Bit 14: Tx Deferred Cnt Ov */
432#define XMT_LAT_COL_OV (1L<<13) /* Bit 13: Tx Late Col Cnt Ov */
433#define XMT_ABO_COL_OV (1L<<12) /* Bit 12: Tx abo dueto Ex Col Ov*/
434#define XMT_MUL_COL_OV (1L<<11) /* Bit 11: Tx Mult Col Cnt Ov */
435#define XMT_SNG_COL (1L<<10) /* Bit 10: Tx Single Col Cnt Ov */
436#define XMT_MCTRL_OV (1L<<9) /* Bit 9: Tx MAC Ctrl Counter Ov*/
437#define XMT_MPAUSE (1L<<8) /* Bit 8: Tx Pause MAC Ctrl-F Ov*/
438#define XMT_BURST (1L<<7) /* Bit 7: Tx Burst Event Cnt Ov */
439#define XMT_LONG (1L<<6) /* Bit 6: Tx Long Frame Cnt Ov */
440#define XMT_UC_OK_OV (1L<<5) /* Bit 5: Tx Unicast Cnt Ov */
441#define XMT_MC_OK_OV (1L<<4) /* Bit 4: Tx Multicast Cnt Ov */
442#define XMT_BC_OK_OV (1L<<3) /* Bit 3: Tx Broadcast Cnt Ov */
443#define XMT_OK_LO_OV (1L<<2) /* Bit 2: Octets Tx OK Low CntOv*/
444#define XMT_OK_HI_OV (1L<<1) /* Bit 1: Octets Tx OK Hi Cnt Ov*/
445#define XMT_OK_OV (1L<<0) /* Bit 0: Frames Tx Ok Ov */
446
447#define XMT_DEF_MSK (XMT_OK_LO_OV | XMT_OK_HI_OV)
448
449/*
450 * Receive Frame Status Encoding
451 */
452#define XMR_FS_LEN (0x3fffUL<<18) /* Bit 31..18: Rx Frame Length */
453#define XMR_FS_2L_VLAN (1L<<17) /* Bit 17: tagged wh 2Lev VLAN ID*/
454#define XMR_FS_1L_VLAN (1L<<16) /* Bit 16: tagged wh 1Lev VLAN ID*/
455#define XMR_FS_BC (1L<<15) /* Bit 15: Broadcast Frame */
456#define XMR_FS_MC (1L<<14) /* Bit 14: Multicast Frame */
457#define XMR_FS_UC (1L<<13) /* Bit 13: Unicast Frame */
458 /* Bit 12: reserved */
459#define XMR_FS_BURST (1L<<11) /* Bit 11: Burst Mode */
460#define XMR_FS_CEX_ERR (1L<<10) /* Bit 10: Carrier Ext. Error */
461#define XMR_FS_802_3 (1L<<9) /* Bit 9: 802.3 Frame */
462#define XMR_FS_COL_ERR (1L<<8) /* Bit 8: Collision Error */
463#define XMR_FS_CAR_ERR (1L<<7) /* Bit 7: Carrier Event Error */
464#define XMR_FS_LEN_ERR (1L<<6) /* Bit 6: In-Range Length Error */
465#define XMR_FS_FRA_ERR (1L<<5) /* Bit 5: Framing Error */
466#define XMR_FS_RUNT (1L<<4) /* Bit 4: Runt Frame */
467#define XMR_FS_LNG_ERR (1L<<3) /* Bit 3: Giant (Jumbo) Frame */
468#define XMR_FS_FCS_ERR (1L<<2) /* Bit 2: Frame Check Sequ Err */
469#define XMR_FS_ERR (1L<<1) /* Bit 1: Frame Error */
470#define XMR_FS_MCTRL (1L<<0) /* Bit 0: MAC Control Packet */
471
472/*
473 * XMR_FS_ERR will be set if
474 * XMR_FS_FCS_ERR, XMR_FS_LNG_ERR, XMR_FS_RUNT,
475 * XMR_FS_FRA_ERR, XMR_FS_LEN_ERR, or XMR_FS_CEX_ERR
476 * is set. XMR_FS_LNG_ERR and XMR_FS_LEN_ERR will issue
477 * XMR_FS_ERR unless the corresponding bit in the Receive Command
478 * Register is set.
479 */
480#define XMR_FS_ANY_ERR XMR_FS_ERR
481
482/*----------------------------------------------------------------------------*/
483/*
484 * XMAC-PHY Registers, indirect addressed over the XMAC
485 */
486#define PHY_XMAC_CTRL 0x00 /* 16 bit r/w PHY Control Register */
487#define PHY_XMAC_STAT 0x01 /* 16 bit r/w PHY Status Register */
488#define PHY_XMAC_ID0 0x02 /* 16 bit r/o PHY ID0 Register */
489#define PHY_XMAC_ID1 0x03 /* 16 bit r/o PHY ID1 Register */
490#define PHY_XMAC_AUNE_ADV 0x04 /* 16 bit r/w Auto-Neg. Advertisement */
491#define PHY_XMAC_AUNE_LP 0x05 /* 16 bit r/o Link Partner Abi Reg */
492#define PHY_XMAC_AUNE_EXP 0x06 /* 16 bit r/o Auto-Neg. Expansion Reg */
493#define PHY_XMAC_NEPG 0x07 /* 16 bit r/w Next Page Register */
494#define PHY_XMAC_NEPG_LP 0x08 /* 16 bit r/o Next Page Link Partner */
495 /* 0x09 - 0x0e: reserved */
496#define PHY_XMAC_EXT_STAT 0x0f /* 16 bit r/o Ext Status Register */
497#define PHY_XMAC_RES_ABI 0x10 /* 16 bit r/o PHY Resolved Ability */
498
499/*----------------------------------------------------------------------------*/
500/*
501 * Broadcom-PHY Registers, indirect addressed over XMAC
502 */
503#define PHY_BCOM_CTRL 0x00 /* 16 bit r/w PHY Control Register */
504#define PHY_BCOM_STAT 0x01 /* 16 bit r/o PHY Status Register */
505#define PHY_BCOM_ID0 0x02 /* 16 bit r/o PHY ID0 Register */
506#define PHY_BCOM_ID1 0x03 /* 16 bit r/o PHY ID1 Register */
507#define PHY_BCOM_AUNE_ADV 0x04 /* 16 bit r/w Auto-Neg. Advertisement */
508#define PHY_BCOM_AUNE_LP 0x05 /* 16 bit r/o Link Part Ability Reg */
509#define PHY_BCOM_AUNE_EXP 0x06 /* 16 bit r/o Auto-Neg. Expansion Reg */
510#define PHY_BCOM_NEPG 0x07 /* 16 bit r/w Next Page Register */
511#define PHY_BCOM_NEPG_LP 0x08 /* 16 bit r/o Next Page Link Partner */
512 /* Broadcom-specific registers */
513#define PHY_BCOM_1000T_CTRL 0x09 /* 16 bit r/w 1000Base-T Ctrl Reg */
514#define PHY_BCOM_1000T_STAT 0x0a /* 16 bit r/o 1000Base-T Status Reg */
515 /* 0x0b - 0x0e: reserved */
516#define PHY_BCOM_EXT_STAT 0x0f /* 16 bit r/o Extended Status Reg */
517#define PHY_BCOM_P_EXT_CTRL 0x10 /* 16 bit r/w PHY Extended Ctrl Reg */
518#define PHY_BCOM_P_EXT_STAT 0x11 /* 16 bit r/o PHY Extended Stat Reg */
519#define PHY_BCOM_RE_CTR 0x12 /* 16 bit r/w Receive Error Counter */
520#define PHY_BCOM_FC_CTR 0x13 /* 16 bit r/w False Carrier Sense Cnt */
521#define PHY_BCOM_RNO_CTR 0x14 /* 16 bit r/w Receiver NOT_OK Cnt */
522 /* 0x15 - 0x17: reserved */
523#define PHY_BCOM_AUX_CTRL 0x18 /* 16 bit r/w Auxiliary Control Reg */
524#define PHY_BCOM_AUX_STAT 0x19 /* 16 bit r/o Auxiliary Stat Summary */
525#define PHY_BCOM_INT_STAT 0x1a /* 16 bit r/o Interrupt Status Reg */
526#define PHY_BCOM_INT_MASK 0x1b /* 16 bit r/w Interrupt Mask Reg */
527 /* 0x1c: reserved */
528 /* 0x1d - 0x1f: test registers */
529
530/*----------------------------------------------------------------------------*/
531/*
532 * Marvel-PHY Registers, indirect addressed over GMAC
533 */
534#define PHY_MARV_CTRL 0x00 /* 16 bit r/w PHY Control Register */
535#define PHY_MARV_STAT 0x01 /* 16 bit r/o PHY Status Register */
536#define PHY_MARV_ID0 0x02 /* 16 bit r/o PHY ID0 Register */
537#define PHY_MARV_ID1 0x03 /* 16 bit r/o PHY ID1 Register */
538#define PHY_MARV_AUNE_ADV 0x04 /* 16 bit r/w Auto-Neg. Advertisement */
539#define PHY_MARV_AUNE_LP 0x05 /* 16 bit r/o Link Part Ability Reg */
540#define PHY_MARV_AUNE_EXP 0x06 /* 16 bit r/o Auto-Neg. Expansion Reg */
541#define PHY_MARV_NEPG 0x07 /* 16 bit r/w Next Page Register */
542#define PHY_MARV_NEPG_LP 0x08 /* 16 bit r/o Next Page Link Partner */
543 /* Marvel-specific registers */
544#define PHY_MARV_1000T_CTRL 0x09 /* 16 bit r/w 1000Base-T Ctrl Reg */
545#define PHY_MARV_1000T_STAT 0x0a /* 16 bit r/o 1000Base-T Status Reg */
546 /* 0x0b - 0x0e: reserved */
547#define PHY_MARV_EXT_STAT 0x0f /* 16 bit r/o Extended Status Reg */
548#define PHY_MARV_PHY_CTRL 0x10 /* 16 bit r/w PHY Specific Ctrl Reg */
549#define PHY_MARV_PHY_STAT 0x11 /* 16 bit r/o PHY Specific Stat Reg */
550#define PHY_MARV_INT_MASK 0x12 /* 16 bit r/w Interrupt Mask Reg */
551#define PHY_MARV_INT_STAT 0x13 /* 16 bit r/o Interrupt Status Reg */
552#define PHY_MARV_EXT_CTRL 0x14 /* 16 bit r/w Ext. PHY Specific Ctrl */
553#define PHY_MARV_RXE_CNT 0x15 /* 16 bit r/w Receive Error Counter */
554#define PHY_MARV_EXT_ADR 0x16 /* 16 bit r/w Ext. Ad. for Cable Diag. */
555 /* 0x17: reserved */
556#define PHY_MARV_LED_CTRL 0x18 /* 16 bit r/w LED Control Reg */
557#define PHY_MARV_LED_OVER 0x19 /* 16 bit r/w Manual LED Override Reg */
558#define PHY_MARV_EXT_CTRL_2 0x1a /* 16 bit r/w Ext. PHY Specific Ctrl 2 */
559#define PHY_MARV_EXT_P_STAT 0x1b /* 16 bit r/w Ext. PHY Spec. Stat Reg */
560#define PHY_MARV_CABLE_DIAG 0x1c /* 16 bit r/o Cable Diagnostic Reg */
561 /* 0x1d - 0x1f: reserved */
562
563/*----------------------------------------------------------------------------*/
564/*
565 * Level One-PHY Registers, indirect addressed over XMAC
566 */
567#define PHY_LONE_CTRL 0x00 /* 16 bit r/w PHY Control Register */
568#define PHY_LONE_STAT 0x01 /* 16 bit r/o PHY Status Register */
569#define PHY_LONE_ID0 0x02 /* 16 bit r/o PHY ID0 Register */
570#define PHY_LONE_ID1 0x03 /* 16 bit r/o PHY ID1 Register */
571#define PHY_LONE_AUNE_ADV 0x04 /* 16 bit r/w Auto-Neg. Advertisement */
572#define PHY_LONE_AUNE_LP 0x05 /* 16 bit r/o Link Part Ability Reg */
573#define PHY_LONE_AUNE_EXP 0x06 /* 16 bit r/o Auto-Neg. Expansion Reg */
574#define PHY_LONE_NEPG 0x07 /* 16 bit r/w Next Page Register */
575#define PHY_LONE_NEPG_LP 0x08 /* 16 bit r/o Next Page Link Partner */
576 /* Level One-specific registers */
577#define PHY_LONE_1000T_CTRL 0x09 /* 16 bit r/w 1000Base-T Control Reg*/
578#define PHY_LONE_1000T_STAT 0x0a /* 16 bit r/o 1000Base-T Status Reg */
579 /* 0x0b -0x0e: reserved */
580#define PHY_LONE_EXT_STAT 0x0f /* 16 bit r/o Extended Status Reg */
581#define PHY_LONE_PORT_CFG 0x10 /* 16 bit r/w Port Configuration Reg*/
582#define PHY_LONE_Q_STAT 0x11 /* 16 bit r/o Quick Status Reg */
583#define PHY_LONE_INT_ENAB 0x12 /* 16 bit r/w Interrupt Enable Reg */
584#define PHY_LONE_INT_STAT 0x13 /* 16 bit r/o Interrupt Status Reg */
585#define PHY_LONE_LED_CFG 0x14 /* 16 bit r/w LED Configuration Reg */
586#define PHY_LONE_PORT_CTRL 0x15 /* 16 bit r/w Port Control Reg */
587#define PHY_LONE_CIM 0x16 /* 16 bit r/o CIM Reg */
588 /* 0x17 -0x1c: reserved */
589
590/*----------------------------------------------------------------------------*/
591/*
592 * National-PHY Registers, indirect addressed over XMAC
593 */
594#define PHY_NAT_CTRL 0x00 /* 16 bit r/w PHY Control Register */
595#define PHY_NAT_STAT 0x01 /* 16 bit r/w PHY Status Register */
596#define PHY_NAT_ID0 0x02 /* 16 bit r/o PHY ID0 Register */
597#define PHY_NAT_ID1 0x03 /* 16 bit r/o PHY ID1 Register */
598#define PHY_NAT_AUNE_ADV 0x04 /* 16 bit r/w Auto-Neg. Advertisement */
599#define PHY_NAT_AUNE_LP 0x05 /* 16 bit r/o Link Partner Ability Reg */
600#define PHY_NAT_AUNE_EXP 0x06 /* 16 bit r/o Auto-Neg. Expansion Reg */
601#define PHY_NAT_NEPG 0x07 /* 16 bit r/w Next Page Register */
602#define PHY_NAT_NEPG_LP 0x08 /* 16 bit r/o Next Page Link Partner Reg */
603 /* National-specific registers */
604#define PHY_NAT_1000T_CTRL 0x09 /* 16 bit r/w 1000Base-T Control Reg */
605#define PHY_NAT_1000T_STAT 0x0a /* 16 bit r/o 1000Base-T Status Reg */
606 /* 0x0b -0x0e: reserved */
607#define PHY_NAT_EXT_STAT 0x0f /* 16 bit r/o Extended Status Register */
608#define PHY_NAT_EXT_CTRL1 0x10 /* 16 bit r/o Extended Control Reg1 */
609#define PHY_NAT_Q_STAT1 0x11 /* 16 bit r/o Quick Status Reg1 */
610#define PHY_NAT_10B_OP 0x12 /* 16 bit r/o 10Base-T Operations Reg */
611#define PHY_NAT_EXT_CTRL2 0x13 /* 16 bit r/o Extended Control Reg1 */
612#define PHY_NAT_Q_STAT2 0x14 /* 16 bit r/o Quick Status Reg2 */
613 /* 0x15 -0x18: reserved */
614#define PHY_NAT_PHY_ADDR 0x19 /* 16 bit r/o PHY Address Register */
615
616
617/*----------------------------------------------------------------------------*/
618
619/*
620 * PHY bit definitions
621 * Bits defined as PHY_X_..., PHY_B_..., PHY_L_... or PHY_N_... are
622 * XMAC/Broadcom/LevelOne/National/Marvell-specific.
623 * All other are general.
624 */
625
626/***** PHY_XMAC_CTRL 16 bit r/w PHY Control Register *****/
627/***** PHY_BCOM_CTRL 16 bit r/w PHY Control Register *****/
628/***** PHY_MARV_CTRL 16 bit r/w PHY Status Register *****/
629/***** PHY_LONE_CTRL 16 bit r/w PHY Control Register *****/
630#define PHY_CT_RESET (1<<15) /* Bit 15: (sc) clear all PHY related regs */
631#define PHY_CT_LOOP (1<<14) /* Bit 14: enable Loopback over PHY */
632#define PHY_CT_SPS_LSB (1<<13) /* Bit 13: (BC,L1) Speed select, lower bit */
633#define PHY_CT_ANE (1<<12) /* Bit 12: Auto-Negotiation Enabled */
634#define PHY_CT_PDOWN (1<<11) /* Bit 11: (BC,L1) Power Down Mode */
635#define PHY_CT_ISOL (1<<10) /* Bit 10: (BC,L1) Isolate Mode */
636#define PHY_CT_RE_CFG (1<<9) /* Bit 9: (sc) Restart Auto-Negotiation */
637#define PHY_CT_DUP_MD (1<<8) /* Bit 8: Duplex Mode */
638#define PHY_CT_COL_TST (1<<7) /* Bit 7: (BC,L1) Collision Test enabled */
639#define PHY_CT_SPS_MSB (1<<6) /* Bit 6: (BC,L1) Speed select, upper bit */
640 /* Bit 5..0: reserved */
641
642#define PHY_CT_SP1000 PHY_CT_SPS_MSB /* enable speed of 1000 Mbps */
643#define PHY_CT_SP100 PHY_CT_SPS_LSB /* enable speed of 100 Mbps */
644#define PHY_CT_SP10 (0) /* enable speed of 10 Mbps */
645
646
647/***** PHY_XMAC_STAT 16 bit r/w PHY Status Register *****/
648/***** PHY_BCOM_STAT 16 bit r/w PHY Status Register *****/
649/***** PHY_MARV_STAT 16 bit r/w PHY Status Register *****/
650/***** PHY_LONE_STAT 16 bit r/w PHY Status Register *****/
651 /* Bit 15..9: reserved */
652 /* (BC/L1) 100/10 Mbps cap bits ignored*/
653#define PHY_ST_EXT_ST (1<<8) /* Bit 8: Extended Status Present */
654 /* Bit 7: reserved */
655#define PHY_ST_PRE_SUP (1<<6) /* Bit 6: (BC/L1) preamble suppression */
656#define PHY_ST_AN_OVER (1<<5) /* Bit 5: Auto-Negotiation Over */
657#define PHY_ST_REM_FLT (1<<4) /* Bit 4: Remote Fault Condition Occured */
658#define PHY_ST_AN_CAP (1<<3) /* Bit 3: Auto-Negotiation Capability */
659#define PHY_ST_LSYNC (1<<2) /* Bit 2: Link Synchronized */
660#define PHY_ST_JAB_DET (1<<1) /* Bit 1: (BC/L1) Jabber Detected */
661#define PHY_ST_EXT_REG (1<<0) /* Bit 0: Extended Register available */
662
663
664/***** PHY_XMAC_ID1 16 bit r/o PHY ID1 Register */
665/***** PHY_BCOM_ID1 16 bit r/o PHY ID1 Register */
666/***** PHY_MARV_ID1 16 bit r/o PHY ID1 Register */
667/***** PHY_LONE_ID1 16 bit r/o PHY ID1 Register */
668#define PHY_I1_OUI_MSK (0x3f<<10) /* Bit 15..10: Organization Unique ID */
669#define PHY_I1_MOD_NUM (0x3f<<4) /* Bit 9.. 4: Model Number */
670#define PHY_I1_REV_MSK 0x0f /* Bit 3.. 0: Revision Number */
671
672/* different Broadcom PHY Ids */
673#define PHY_BCOM_ID1_A1 0x6041
674#define PHY_BCOM_ID1_B2 0x6043
675#define PHY_BCOM_ID1_C0 0x6044
676#define PHY_BCOM_ID1_C5 0x6047
677
678
679/***** PHY_XMAC_AUNE_ADV 16 bit r/w Auto-Negotiation Advertisement *****/
680/***** PHY_XMAC_AUNE_LP 16 bit r/o Link Partner Ability Reg *****/
681#define PHY_AN_NXT_PG (1<<15) /* Bit 15: Request Next Page */
682#define PHY_X_AN_ACK (1<<14) /* Bit 14: (ro) Acknowledge Received */
683#define PHY_X_AN_RFB (3<<12) /* Bit 13..12: Remote Fault Bits */
684 /* Bit 11.. 9: reserved */
685#define PHY_X_AN_PAUSE (3<<7) /* Bit 8.. 7: Pause Bits */
686#define PHY_X_AN_HD (1<<6) /* Bit 6: Half Duplex */
687#define PHY_X_AN_FD (1<<5) /* Bit 5: Full Duplex */
688 /* Bit 4.. 0: reserved */
689
690/***** PHY_BCOM_AUNE_ADV 16 bit r/w Auto-Negotiation Advertisement *****/
691/***** PHY_BCOM_AUNE_LP 16 bit r/o Link Partner Ability Reg *****/
692/* PHY_AN_NXT_PG (see XMAC) Bit 15: Request Next Page */
693 /* Bit 14: reserved */
694#define PHY_B_AN_RF (1<<13) /* Bit 13: Remote Fault */
695 /* Bit 12: reserved */
696#define PHY_B_AN_ASP (1<<11) /* Bit 11: Asymmetric Pause */
697#define PHY_B_AN_PC (1<<10) /* Bit 10: Pause Capable */
698 /* Bit 9..5: 100/10 BT cap bits ingnored */
699#define PHY_B_AN_SEL 0x1f /* Bit 4..0: Selector Field, 00001=Ethernet*/
700
701/***** PHY_LONE_AUNE_ADV 16 bit r/w Auto-Negotiation Advertisement *****/
702/***** PHY_LONE_AUNE_LP 16 bit r/o Link Partner Ability Reg *****/
703/* PHY_AN_NXT_PG (see XMAC) Bit 15: Request Next Page */
704 /* Bit 14: reserved */
705#define PHY_L_AN_RF (1<<13) /* Bit 13: Remote Fault */
706 /* Bit 12: reserved */
707#define PHY_L_AN_ASP (1<<11) /* Bit 11: Asymmetric Pause */
708#define PHY_L_AN_PC (1<<10) /* Bit 10: Pause Capable */
709 /* Bit 9..5: 100/10 BT cap bits ingnored */
710#define PHY_L_AN_SEL 0x1f /* Bit 4..0: Selector Field, 00001=Ethernet*/
711
712/***** PHY_NAT_AUNE_ADV 16 bit r/w Auto-Negotiation Advertisement *****/
713/***** PHY_NAT_AUNE_LP 16 bit r/o Link Partner Ability Reg *****/
714/* PHY_AN_NXT_PG (see XMAC) Bit 15: Request Next Page */
715 /* Bit 14: reserved */
716#define PHY_N_AN_RF (1<<13) /* Bit 13: Remote Fault */
717 /* Bit 12: reserved */
718#define PHY_N_AN_100F (1<<11) /* Bit 11: 100Base-T2 FD Support */
719#define PHY_N_AN_100H (1<<10) /* Bit 10: 100Base-T2 HD Support */
720 /* Bit 9..5: 100/10 BT cap bits ingnored */
721#define PHY_N_AN_SEL 0x1f /* Bit 4..0: Selector Field, 00001=Ethernet*/
722
723/* field type definition for PHY_x_AN_SEL */
724#define PHY_SEL_TYPE 0x01 /* 00001 = Ethernet */
725
726/***** PHY_XMAC_AUNE_EXP 16 bit r/o Auto-Negotiation Expansion Reg *****/
727 /* Bit 15..4: reserved */
728#define PHY_ANE_LP_NP (1<<3) /* Bit 3: Link Partner can Next Page */
729#define PHY_ANE_LOC_NP (1<<2) /* Bit 2: Local PHY can Next Page */
730#define PHY_ANE_RX_PG (1<<1) /* Bit 1: Page Received */
731 /* Bit 0: reserved */
732
733/***** PHY_BCOM_AUNE_EXP 16 bit r/o Auto-Negotiation Expansion Reg *****/
734/***** PHY_LONE_AUNE_EXP 16 bit r/o Auto-Negotiation Expansion Reg *****/
735/***** PHY_MARV_AUNE_EXP 16 bit r/o Auto-Negotiation Expansion Reg *****/
736 /* Bit 15..5: reserved */
737#define PHY_ANE_PAR_DF (1<<4) /* Bit 4: Parallel Detection Fault */
738/* PHY_ANE_LP_NP (see XMAC) Bit 3: Link Partner can Next Page */
739/* PHY_ANE_LOC_NP (see XMAC) Bit 2: Local PHY can Next Page */
740/* PHY_ANE_RX_PG (see XMAC) Bit 1: Page Received */
741#define PHY_ANE_LP_CAP (1<<0) /* Bit 0: Link Partner Auto-Neg. Cap. */
742
743/***** PHY_XMAC_NEPG 16 bit r/w Next Page Register *****/
744/***** PHY_BCOM_NEPG 16 bit r/w Next Page Register *****/
745/***** PHY_LONE_NEPG 16 bit r/w Next Page Register *****/
746/***** PHY_XMAC_NEPG_LP 16 bit r/o Next Page Link Partner *****/
747/***** PHY_BCOM_NEPG_LP 16 bit r/o Next Page Link Partner *****/
748/***** PHY_LONE_NEPG_LP 16 bit r/o Next Page Link Partner *****/
749#define PHY_NP_MORE (1<<15) /* Bit 15: More, Next Pages to follow */
750#define PHY_NP_ACK1 (1<<14) /* Bit 14: (ro) Ack1, for receiving a message */
751#define PHY_NP_MSG_VAL (1<<13) /* Bit 13: Message Page valid */
752#define PHY_NP_ACK2 (1<<12) /* Bit 12: Ack2, comply with msg content */
753#define PHY_NP_TOG (1<<11) /* Bit 11: Toggle Bit, ensure sync */
754#define PHY_NP_MSG 0x07ff /* Bit 10..0: Message from/to Link Partner */
755
756/*
757 * XMAC-Specific
758 */
759/***** PHY_XMAC_EXT_STAT 16 bit r/w Extended Status Register *****/
760#define PHY_X_EX_FD (1<<15) /* Bit 15: Device Supports Full Duplex */
761#define PHY_X_EX_HD (1<<14) /* Bit 14: Device Supports Half Duplex */
762 /* Bit 13..0: reserved */
763
764/***** PHY_XMAC_RES_ABI 16 bit r/o PHY Resolved Ability *****/
765 /* Bit 15..9: reserved */
766#define PHY_X_RS_PAUSE (3<<7) /* Bit 8..7: selected Pause Mode */
767#define PHY_X_RS_HD (1<<6) /* Bit 6: Half Duplex Mode selected */
768#define PHY_X_RS_FD (1<<5) /* Bit 5: Full Duplex Mode selected */
769#define PHY_X_RS_ABLMIS (1<<4) /* Bit 4: duplex or pause cap mismatch */
770#define PHY_X_RS_PAUMIS (1<<3) /* Bit 3: pause capability mismatch */
771 /* Bit 2..0: reserved */
772/*
773 * Remote Fault Bits (PHY_X_AN_RFB) encoding
774 */
775#define X_RFB_OK (0<<12) /* Bit 13..12 No errors, Link OK */
776#define X_RFB_LF (1<<12) /* Bit 13..12 Link Failure */
777#define X_RFB_OFF (2<<12) /* Bit 13..12 Offline */
778#define X_RFB_AN_ERR (3<<12) /* Bit 13..12 Auto-Negotiation Error */
779
780/*
781 * Pause Bits (PHY_X_AN_PAUSE and PHY_X_RS_PAUSE) encoding
782 */
783#define PHY_X_P_NO_PAUSE (0<<7) /* Bit 8..7: no Pause Mode */
784#define PHY_X_P_SYM_MD (1<<7) /* Bit 8..7: symmetric Pause Mode */
785#define PHY_X_P_ASYM_MD (2<<7) /* Bit 8..7: asymmetric Pause Mode */
786#define PHY_X_P_BOTH_MD (3<<7) /* Bit 8..7: both Pause Mode */
787
788
789/*
790 * Broadcom-Specific
791 */
792/***** PHY_BCOM_1000T_CTRL 16 bit r/w 1000Base-T Control Reg *****/
793#define PHY_B_1000C_TEST (7<<13) /* Bit 15..13: Test Modes */
794#define PHY_B_1000C_MSE (1<<12) /* Bit 12: Master/Slave Enable */
795#define PHY_B_1000C_MSC (1<<11) /* Bit 11: M/S Configuration */
796#define PHY_B_1000C_RD (1<<10) /* Bit 10: Repeater/DTE */
797#define PHY_B_1000C_AFD (1<<9) /* Bit 9: Advertise Full Duplex */
798#define PHY_B_1000C_AHD (1<<8) /* Bit 8: Advertise Half Duplex */
799 /* Bit 7..0: reserved */
800
801/***** PHY_BCOM_1000T_STAT 16 bit r/o 1000Base-T Status Reg *****/
802/***** PHY_MARV_1000T_STAT 16 bit r/o 1000Base-T Status Reg *****/
803#define PHY_B_1000S_MSF (1<<15) /* Bit 15: Master/Slave Fault */
804#define PHY_B_1000S_MSR (1<<14) /* Bit 14: Master/Slave Result */
805#define PHY_B_1000S_LRS (1<<13) /* Bit 13: Local Receiver Status */
806#define PHY_B_1000S_RRS (1<<12) /* Bit 12: Remote Receiver Status */
807#define PHY_B_1000S_LP_FD (1<<11) /* Bit 11: Link Partner can FD */
808#define PHY_B_1000S_LP_HD (1<<10) /* Bit 10: Link Partner can HD */
809 /* Bit 9..8: reserved */
810#define PHY_B_1000S_IEC 0xff /* Bit 7..0: Idle Error Count */
811
812/***** PHY_BCOM_EXT_STAT 16 bit r/o Extended Status Register *****/
813#define PHY_B_ES_X_FD_CAP (1<<15) /* Bit 15: 1000Base-X FD capable */
814#define PHY_B_ES_X_HD_CAP (1<<14) /* Bit 14: 1000Base-X HD capable */
815#define PHY_B_ES_T_FD_CAP (1<<13) /* Bit 13: 1000Base-T FD capable */
816#define PHY_B_ES_T_HD_CAP (1<<12) /* Bit 12: 1000Base-T HD capable */
817 /* Bit 11..0: reserved */
818
819/***** PHY_BCOM_P_EXT_CTRL 16 bit r/w PHY Extended Control Reg *****/
820#define PHY_B_PEC_MAC_PHY (1<<15) /* Bit 15: 10BIT/GMI-Interface */
821#define PHY_B_PEC_DIS_CROSS (1<<14) /* Bit 14: Disable MDI Crossover */
822#define PHY_B_PEC_TX_DIS (1<<13) /* Bit 13: Tx output Disabled */
823#define PHY_B_PEC_INT_DIS (1<<12) /* Bit 12: Interrupts Disabled */
824#define PHY_B_PEC_F_INT (1<<11) /* Bit 11: Force Interrupt */
825#define PHY_B_PEC_BY_45 (1<<10) /* Bit 10: Bypass 4B5B-Decoder */
826#define PHY_B_PEC_BY_SCR (1<<9) /* Bit 9: Bypass Scrambler */
827#define PHY_B_PEC_BY_MLT3 (1<<8) /* Bit 8: Bypass MLT3 Encoder */
828#define PHY_B_PEC_BY_RXA (1<<7) /* Bit 7: Bypass Rx Alignm. */
829#define PHY_B_PEC_RES_SCR (1<<6) /* Bit 6: Reset Scrambler */
830#define PHY_B_PEC_EN_LTR (1<<5) /* Bit 5: Ena LED Traffic Mode */
831#define PHY_B_PEC_LED_ON (1<<4) /* Bit 4: Force LED's on */
832#define PHY_B_PEC_LED_OFF (1<<3) /* Bit 3: Force LED's off */
833#define PHY_B_PEC_EX_IPG (1<<2) /* Bit 2: Extend Tx IPG Mode */
834#define PHY_B_PEC_3_LED (1<<1) /* Bit 1: Three Link LED mode */
835#define PHY_B_PEC_HIGH_LA (1<<0) /* Bit 0: GMII FIFO Elasticy */
836
837/***** PHY_BCOM_P_EXT_STAT 16 bit r/o PHY Extended Status Reg *****/
838 /* Bit 15..14: reserved */
839#define PHY_B_PES_CROSS_STAT (1<<13) /* Bit 13: MDI Crossover Status */
840#define PHY_B_PES_INT_STAT (1<<12) /* Bit 12: Interrupt Status */
841#define PHY_B_PES_RRS (1<<11) /* Bit 11: Remote Receiver Stat. */
842#define PHY_B_PES_LRS (1<<10) /* Bit 10: Local Receiver Stat. */
843#define PHY_B_PES_LOCKED (1<<9) /* Bit 9: Locked */
844#define PHY_B_PES_LS (1<<8) /* Bit 8: Link Status */
845#define PHY_B_PES_RF (1<<7) /* Bit 7: Remote Fault */
846#define PHY_B_PES_CE_ER (1<<6) /* Bit 6: Carrier Ext Error */
847#define PHY_B_PES_BAD_SSD (1<<5) /* Bit 5: Bad SSD */
848#define PHY_B_PES_BAD_ESD (1<<4) /* Bit 4: Bad ESD */
849#define PHY_B_PES_RX_ER (1<<3) /* Bit 3: Receive Error */
850#define PHY_B_PES_TX_ER (1<<2) /* Bit 2: Transmit Error */
851#define PHY_B_PES_LOCK_ER (1<<1) /* Bit 1: Lock Error */
852#define PHY_B_PES_MLT3_ER (1<<0) /* Bit 0: MLT3 code Error */
853
854/***** PHY_BCOM_FC_CTR 16 bit r/w False Carrier Counter *****/
855 /* Bit 15..8: reserved */
856#define PHY_B_FC_CTR 0xff /* Bit 7..0: False Carrier Counter */
857
858/***** PHY_BCOM_RNO_CTR 16 bit r/w Receive NOT_OK Counter *****/
859#define PHY_B_RC_LOC_MSK 0xff00 /* Bit 15..8: Local Rx NOT_OK cnt */
860#define PHY_B_RC_REM_MSK 0x00ff /* Bit 7..0: Remote Rx NOT_OK cnt */
861
862/***** PHY_BCOM_AUX_CTRL 16 bit r/w Auxiliary Control Reg *****/
863#define PHY_B_AC_L_SQE (1<<15) /* Bit 15: Low Squelch */
864#define PHY_B_AC_LONG_PACK (1<<14) /* Bit 14: Rx Long Packets */
865#define PHY_B_AC_ER_CTRL (3<<12) /* Bit 13..12: Edgerate Control */
866 /* Bit 11: reserved */
867#define PHY_B_AC_TX_TST (1<<10) /* Bit 10: Tx test bit, always 1 */
868 /* Bit 9.. 8: reserved */
869#define PHY_B_AC_DIS_PRF (1<<7) /* Bit 7: dis part resp filter */
870 /* Bit 6: reserved */
871#define PHY_B_AC_DIS_PM (1<<5) /* Bit 5: dis power management */
872 /* Bit 4: reserved */
873#define PHY_B_AC_DIAG (1<<3) /* Bit 3: Diagnostic Mode */
874 /* Bit 2.. 0: reserved */
875
876/***** PHY_BCOM_AUX_STAT 16 bit r/o Auxiliary Status Reg *****/
877#define PHY_B_AS_AN_C (1<<15) /* Bit 15: AutoNeg complete */
878#define PHY_B_AS_AN_CA (1<<14) /* Bit 14: AN Complete Ack */
879#define PHY_B_AS_ANACK_D (1<<13) /* Bit 13: AN Ack Detect */
880#define PHY_B_AS_ANAB_D (1<<12) /* Bit 12: AN Ability Detect */
881#define PHY_B_AS_NPW (1<<11) /* Bit 11: AN Next Page Wait */
882#define PHY_B_AS_AN_RES_MSK (7<<8) /* Bit 10..8: AN HDC */
883#define PHY_B_AS_PDF (1<<7) /* Bit 7: Parallel Detect. Fault */
884#define PHY_B_AS_RF (1<<6) /* Bit 6: Remote Fault */
885#define PHY_B_AS_ANP_R (1<<5) /* Bit 5: AN Page Received */
886#define PHY_B_AS_LP_ANAB (1<<4) /* Bit 4: LP AN Ability */
887#define PHY_B_AS_LP_NPAB (1<<3) /* Bit 3: LP Next Page Ability */
888#define PHY_B_AS_LS (1<<2) /* Bit 2: Link Status */
889#define PHY_B_AS_PRR (1<<1) /* Bit 1: Pause Resolution-Rx */
890#define PHY_B_AS_PRT (1<<0) /* Bit 0: Pause Resolution-Tx */
891
892#define PHY_B_AS_PAUSE_MSK (PHY_B_AS_PRR | PHY_B_AS_PRT)
893
894/***** PHY_BCOM_INT_STAT 16 bit r/o Interrupt Status Reg *****/
895/***** PHY_BCOM_INT_MASK 16 bit r/w Interrupt Mask Reg *****/
896 /* Bit 15: reserved */
897#define PHY_B_IS_PSE (1<<14) /* Bit 14: Pair Swap Error */
898#define PHY_B_IS_MDXI_SC (1<<13) /* Bit 13: MDIX Status Change */
899#define PHY_B_IS_HCT (1<<12) /* Bit 12: counter above 32k */
900#define PHY_B_IS_LCT (1<<11) /* Bit 11: counter above 128 */
901#define PHY_B_IS_AN_PR (1<<10) /* Bit 10: Page Received */
902#define PHY_B_IS_NO_HDCL (1<<9) /* Bit 9: No HCD Link */
903#define PHY_B_IS_NO_HDC (1<<8) /* Bit 8: No HCD */
904#define PHY_B_IS_NEG_USHDC (1<<7) /* Bit 7: Negotiated Unsup. HCD */
905#define PHY_B_IS_SCR_S_ER (1<<6) /* Bit 6: Scrambler Sync Error */
906#define PHY_B_IS_RRS_CHANGE (1<<5) /* Bit 5: Remote Rx Stat Change */
907#define PHY_B_IS_LRS_CHANGE (1<<4) /* Bit 4: Local Rx Stat Change */
908#define PHY_B_IS_DUP_CHANGE (1<<3) /* Bit 3: Duplex Mode Change */
909#define PHY_B_IS_LSP_CHANGE (1<<2) /* Bit 2: Link Speed Change */
910#define PHY_B_IS_LST_CHANGE (1<<1) /* Bit 1: Link Status Changed */
911#define PHY_B_IS_CRC_ER (1<<0) /* Bit 0: CRC Error */
912
913#define PHY_B_DEF_MSK (~(PHY_B_IS_AN_PR | PHY_B_IS_LST_CHANGE))
914
915/* Pause Bits (PHY_B_AN_ASP and PHY_B_AN_PC) encoding */
916#define PHY_B_P_NO_PAUSE (0<<10) /* Bit 11..10: no Pause Mode */
917#define PHY_B_P_SYM_MD (1<<10) /* Bit 11..10: symmetric Pause Mode */
918#define PHY_B_P_ASYM_MD (2<<10) /* Bit 11..10: asymmetric Pause Mode */
919#define PHY_B_P_BOTH_MD (3<<10) /* Bit 11..10: both Pause Mode */
920
921/*
922 * Resolved Duplex mode and Capabilities (Aux Status Summary Reg)
923 */
924#define PHY_B_RES_1000FD (7<<8) /* Bit 10..8: 1000Base-T Full Dup. */
925#define PHY_B_RES_1000HD (6<<8) /* Bit 10..8: 1000Base-T Half Dup. */
926/* others: 100/10: invalid for us */
927
928/*
929 * Level One-Specific
930 */
931/***** PHY_LONE_1000T_CTRL 16 bit r/w 1000Base-T Control Reg *****/
932#define PHY_L_1000C_TEST (7<<13) /* Bit 15..13: Test Modes */
933#define PHY_L_1000C_MSE (1<<12) /* Bit 12: Master/Slave Enable */
934#define PHY_L_1000C_MSC (1<<11) /* Bit 11: M/S Configuration */
935#define PHY_L_1000C_RD (1<<10) /* Bit 10: Repeater/DTE */
936#define PHY_L_1000C_AFD (1<<9) /* Bit 9: Advertise Full Duplex */
937#define PHY_L_1000C_AHD (1<<8) /* Bit 8: Advertise Half Duplex */
938 /* Bit 7..0: reserved */
939
940/***** PHY_LONE_1000T_STAT 16 bit r/o 1000Base-T Status Reg *****/
941#define PHY_L_1000S_MSF (1<<15) /* Bit 15: Master/Slave Fault */
942#define PHY_L_1000S_MSR (1<<14) /* Bit 14: Master/Slave Result */
943#define PHY_L_1000S_LRS (1<<13) /* Bit 13: Local Receiver Status */
944#define PHY_L_1000S_RRS (1<<12) /* Bit 12: Remote Receiver Status */
945#define PHY_L_1000S_LP_FD (1<<11) /* Bit 11: Link Partner can FD */
946#define PHY_L_1000S_LP_HD (1<<10) /* Bit 10: Link Partner can HD */
947 /* Bit 9..8: reserved */
948#define PHY_B_1000S_IEC 0xff /* Bit 7..0: Idle Error Count */
949
950/***** PHY_LONE_EXT_STAT 16 bit r/o Extended Status Register *****/
951#define PHY_L_ES_X_FD_CAP (1<<15) /* Bit 15: 1000Base-X FD capable */
952#define PHY_L_ES_X_HD_CAP (1<<14) /* Bit 14: 1000Base-X HD capable */
953#define PHY_L_ES_T_FD_CAP (1<<13) /* Bit 13: 1000Base-T FD capable */
954#define PHY_L_ES_T_HD_CAP (1<<12) /* Bit 12: 1000Base-T HD capable */
955 /* Bit 11..0: reserved */
956
957/***** PHY_LONE_PORT_CFG 16 bit r/w Port Configuration Reg *****/
958#define PHY_L_PC_REP_MODE (1<<15) /* Bit 15: Repeater Mode */
959 /* Bit 14: reserved */
960#define PHY_L_PC_TX_DIS (1<<13) /* Bit 13: Tx output Disabled */
961#define PHY_L_PC_BY_SCR (1<<12) /* Bit 12: Bypass Scrambler */
962#define PHY_L_PC_BY_45 (1<<11) /* Bit 11: Bypass 4B5B-Decoder */
963#define PHY_L_PC_JAB_DIS (1<<10) /* Bit 10: Jabber Disabled */
964#define PHY_L_PC_SQE (1<<9) /* Bit 9: Enable Heartbeat */
965#define PHY_L_PC_TP_LOOP (1<<8) /* Bit 8: TP Loopback */
966#define PHY_L_PC_SSS (1<<7) /* Bit 7: Smart Speed Selection */
967#define PHY_L_PC_FIFO_SIZE (1<<6) /* Bit 6: FIFO Size */
968#define PHY_L_PC_PRE_EN (1<<5) /* Bit 5: Preamble Enable */
969#define PHY_L_PC_CIM (1<<4) /* Bit 4: Carrier Integrity Mon */
970#define PHY_L_PC_10_SER (1<<3) /* Bit 3: Use Serial Output */
971#define PHY_L_PC_ANISOL (1<<2) /* Bit 2: Unisolate Port */
972#define PHY_L_PC_TEN_BIT (1<<1) /* Bit 1: 10bit iface mode on */
973#define PHY_L_PC_ALTCLOCK (1<<0) /* Bit 0: (ro) ALTCLOCK Mode on */
974
975/***** PHY_LONE_Q_STAT 16 bit r/o Quick Status Reg *****/
976#define PHY_L_QS_D_RATE (3<<14) /* Bit 15..14: Data Rate */
977#define PHY_L_QS_TX_STAT (1<<13) /* Bit 13: Transmitting */
978#define PHY_L_QS_RX_STAT (1<<12) /* Bit 12: Receiving */
979#define PHY_L_QS_COL_STAT (1<<11) /* Bit 11: Collision */
980#define PHY_L_QS_L_STAT (1<<10) /* Bit 10: Link is up */
981#define PHY_L_QS_DUP_MOD (1<<9) /* Bit 9: Full/Half Duplex */
982#define PHY_L_QS_AN (1<<8) /* Bit 8: AutoNeg is On */
983#define PHY_L_QS_AN_C (1<<7) /* Bit 7: AN is Complete */
984#define PHY_L_QS_LLE (7<<4) /* Bit 6: Line Length Estim. */
985#define PHY_L_QS_PAUSE (1<<3) /* Bit 3: LP advertised Pause */
986#define PHY_L_QS_AS_PAUSE (1<<2) /* Bit 2: LP adv. asym. Pause */
987#define PHY_L_QS_ISOLATE (1<<1) /* Bit 1: CIM Isolated */
988#define PHY_L_QS_EVENT (1<<0) /* Bit 0: Event has occurred */
989
990/***** PHY_LONE_INT_ENAB 16 bit r/w Interrupt Enable Reg *****/
991/***** PHY_LONE_INT_STAT 16 bit r/o Interrupt Status Reg *****/
992 /* Bit 15..14: reserved */
993#define PHY_L_IS_AN_F (1<<13) /* Bit 13: Auto-Negotiation fault */
994 /* Bit 12: not described */
995#define PHY_L_IS_CROSS (1<<11) /* Bit 11: Crossover used */
996#define PHY_L_IS_POL (1<<10) /* Bit 10: Polarity correct. used */
997#define PHY_L_IS_SS (1<<9) /* Bit 9: Smart Speed Downgrade */
998#define PHY_L_IS_CFULL (1<<8) /* Bit 8: Counter Full */
999#define PHY_L_IS_AN_C (1<<7) /* Bit 7: AutoNeg Complete */
1000#define PHY_L_IS_SPEED (1<<6) /* Bit 6: Speed Changed */
1001#define PHY_L_IS_DUP (1<<5) /* Bit 5: Duplex Changed */
1002#define PHY_L_IS_LS (1<<4) /* Bit 4: Link Status Changed */
1003#define PHY_L_IS_ISOL (1<<3) /* Bit 3: Isolate Occured */
1004#define PHY_L_IS_MDINT (1<<2) /* Bit 2: (ro) STAT: MII Int Pending */
1005#define PHY_L_IS_INTEN (1<<1) /* Bit 1: ENAB: Enable IRQs */
1006#define PHY_L_IS_FORCE (1<<0) /* Bit 0: ENAB: Force Interrupt */
1007
1008/* int. mask */
1009#define PHY_L_DEF_MSK (PHY_L_IS_LS | PHY_L_IS_ISOL | PHY_L_IS_INTEN)
1010
1011/***** PHY_LONE_LED_CFG 16 bit r/w LED Configuration Reg *****/
1012#define PHY_L_LC_LEDC (3<<14) /* Bit 15..14: Col/Blink/On/Off */
1013#define PHY_L_LC_LEDR (3<<12) /* Bit 13..12: Rx/Blink/On/Off */
1014#define PHY_L_LC_LEDT (3<<10) /* Bit 11..10: Tx/Blink/On/Off */
1015#define PHY_L_LC_LEDG (3<<8) /* Bit 9..8: Giga/Blink/On/Off */
1016#define PHY_L_LC_LEDS (3<<6) /* Bit 7..6: 10-100/Blink/On/Off */
1017#define PHY_L_LC_LEDL (3<<4) /* Bit 5..4: Link/Blink/On/Off */
1018#define PHY_L_LC_LEDF (3<<2) /* Bit 3..2: Duplex/Blink/On/Off */
1019#define PHY_L_LC_PSTRECH (1<<1) /* Bit 1: Strech LED Pulses */
1020#define PHY_L_LC_FREQ (1<<0) /* Bit 0: 30/100 ms */
1021
1022/***** PHY_LONE_PORT_CTRL 16 bit r/w Port Control Reg *****/
1023#define PHY_L_PC_TX_TCLK (1<<15) /* Bit 15: Enable TX_TCLK */
1024 /* Bit 14: reserved */
1025#define PHY_L_PC_ALT_NP (1<<13) /* Bit 14: Alternate Next Page */
1026#define PHY_L_PC_GMII_ALT (1<<12) /* Bit 13: Alternate GMII driver */
1027 /* Bit 11: reserved */
1028#define PHY_L_PC_TEN_CRS (1<<10) /* Bit 10: Extend CRS*/
1029 /* Bit 9..0: not described */
1030
1031/***** PHY_LONE_CIM 16 bit r/o CIM Reg *****/
1032#define PHY_L_CIM_ISOL (255<<8)/* Bit 15..8: Isolate Count */
1033#define PHY_L_CIM_FALSE_CAR (255<<0)/* Bit 7..0: False Carrier Count */
1034
1035
1036/*
1037 * Pause Bits (PHY_L_AN_ASP and PHY_L_AN_PC) encoding
1038 */
1039#define PHY_L_P_NO_PAUSE (0<<10) /* Bit 11..10: no Pause Mode */
1040#define PHY_L_P_SYM_MD (1<<10) /* Bit 11..10: symmetric Pause Mode */
1041#define PHY_L_P_ASYM_MD (2<<10) /* Bit 11..10: asymmetric Pause Mode */
1042#define PHY_L_P_BOTH_MD (3<<10) /* Bit 11..10: both Pause Mode */
1043
1044
1045/*
1046 * National-Specific
1047 */
1048/***** PHY_NAT_1000T_CTRL 16 bit r/w 1000Base-T Control Reg *****/
1049#define PHY_N_1000C_TEST (7<<13) /* Bit 15..13: Test Modes */
1050#define PHY_N_1000C_MSE (1<<12) /* Bit 12: Master/Slave Enable */
1051#define PHY_N_1000C_MSC (1<<11) /* Bit 11: M/S Configuration */
1052#define PHY_N_1000C_RD (1<<10) /* Bit 10: Repeater/DTE */
1053#define PHY_N_1000C_AFD (1<<9) /* Bit 9: Advertise Full Duplex */
1054#define PHY_N_1000C_AHD (1<<8) /* Bit 8: Advertise Half Duplex */
1055#define PHY_N_1000C_APC (1<<7) /* Bit 7: Asymmetric Pause Cap. */
1056 /* Bit 6..0: reserved */
1057
1058/***** PHY_NAT_1000T_STAT 16 bit r/o 1000Base-T Status Reg *****/
1059#define PHY_N_1000S_MSF (1<<15) /* Bit 15: Master/Slave Fault */
1060#define PHY_N_1000S_MSR (1<<14) /* Bit 14: Master/Slave Result */
1061#define PHY_N_1000S_LRS (1<<13) /* Bit 13: Local Receiver Status */
1062#define PHY_N_1000S_RRS (1<<12) /* Bit 12: Remote Receiver Status*/
1063#define PHY_N_1000S_LP_FD (1<<11) /* Bit 11: Link Partner can FD */
1064#define PHY_N_1000S_LP_HD (1<<10) /* Bit 10: Link Partner can HD */
1065#define PHY_N_1000C_LP_APC (1<<9) /* Bit 9: LP Asym. Pause Cap. */
1066 /* Bit 8: reserved */
1067#define PHY_N_1000S_IEC 0xff /* Bit 7..0: Idle Error Count */
1068
1069/***** PHY_NAT_EXT_STAT 16 bit r/o Extended Status Register *****/
1070#define PHY_N_ES_X_FD_CAP (1<<15) /* Bit 15: 1000Base-X FD capable */
1071#define PHY_N_ES_X_HD_CAP (1<<14) /* Bit 14: 1000Base-X HD capable */
1072#define PHY_N_ES_T_FD_CAP (1<<13) /* Bit 13: 1000Base-T FD capable */
1073#define PHY_N_ES_T_HD_CAP (1<<12) /* Bit 12: 1000Base-T HD capable */
1074 /* Bit 11..0: reserved */
1075
1076/* todo: those are still missing */
1077/***** PHY_NAT_EXT_CTRL1 16 bit r/o Extended Control Reg1 *****/
1078/***** PHY_NAT_Q_STAT1 16 bit r/o Quick Status Reg1 *****/
1079/***** PHY_NAT_10B_OP 16 bit r/o 10Base-T Operations Reg *****/
1080/***** PHY_NAT_EXT_CTRL2 16 bit r/o Extended Control Reg1 *****/
1081/***** PHY_NAT_Q_STAT2 16 bit r/o Quick Status Reg2 *****/
1082/***** PHY_NAT_PHY_ADDR 16 bit r/o PHY Address Register *****/
1083
1084/*
1085 * Marvell-Specific
1086 */
1087/***** PHY_MARV_AUNE_ADV 16 bit r/w Auto-Negotiation Advertisement *****/
1088/***** PHY_MARV_AUNE_LP 16 bit r/w Link Part Ability Reg *****/
1089#define PHY_M_AN_NXT_PG BIT_15 /* Request Next Page */
1090#define PHY_M_AN_ACK BIT_14 /* (ro) Acknowledge Received */
1091#define PHY_M_AN_RF BIT_13 /* Remote Fault */
1092 /* Bit 12: reserved */
1093#define PHY_M_AN_ASP BIT_11 /* Asymmetric Pause */
1094#define PHY_M_AN_PC BIT_10 /* MAC Pause implemented */
1095#define PHY_M_AN_100_FD BIT_8 /* Advertise 100Base-TX Full Duplex */
1096#define PHY_M_AN_100_HD BIT_7 /* Advertise 100Base-TX Half Duplex */
1097#define PHY_M_AN_10_FD BIT_6 /* Advertise 10Base-TX Full Duplex */
1098#define PHY_M_AN_10_HD BIT_5 /* Advertise 10Base-TX Half Duplex */
1099
1100/* special defines for FIBER (88E1011S only) */
1101#define PHY_M_AN_ASP_X BIT_8 /* Asymmetric Pause */
1102#define PHY_M_AN_PC_X BIT_7 /* MAC Pause implemented */
1103#define PHY_M_AN_1000X_AHD BIT_6 /* Advertise 10000Base-X Half Duplex */
1104#define PHY_M_AN_1000X_AFD BIT_5 /* Advertise 10000Base-X Full Duplex */
1105
1106/* Pause Bits (PHY_M_AN_ASP_X and PHY_M_AN_PC_X) encoding */
1107#define PHY_M_P_NO_PAUSE_X (0<<7) /* Bit 8.. 7: no Pause Mode */
1108#define PHY_M_P_SYM_MD_X (1<<7) /* Bit 8.. 7: symmetric Pause Mode */
1109#define PHY_M_P_ASYM_MD_X (2<<7) /* Bit 8.. 7: asymmetric Pause Mode */
1110#define PHY_M_P_BOTH_MD_X (3<<7) /* Bit 8.. 7: both Pause Mode */
1111
1112/***** PHY_MARV_1000T_CTRL 16 bit r/w 1000Base-T Control Reg *****/
1113#define PHY_M_1000C_TEST (7<<13) /* Bit 15..13: Test Modes */
1114#define PHY_M_1000C_MSE (1<<12) /* Bit 12: Manual Master/Slave Enable */
1115#define PHY_M_1000C_MSC (1<<11) /* Bit 11: M/S Configuration (1=Master) */
1116#define PHY_M_1000C_MPD (1<<10) /* Bit 10: Multi-Port Device */
1117#define PHY_M_1000C_AFD (1<<9) /* Bit 9: Advertise Full Duplex */
1118#define PHY_M_1000C_AHD (1<<8) /* Bit 8: Advertise Half Duplex */
1119 /* Bit 7..0: reserved */
1120
1121/***** PHY_MARV_PHY_CTRL 16 bit r/w PHY Specific Ctrl Reg *****/
1122#define PHY_M_PC_TX_FFD_MSK (3<<14) /* Bit 15..14: Tx FIFO Depth Mask */
1123#define PHY_M_PC_RX_FFD_MSK (3<<12) /* Bit 13..12: Rx FIFO Depth Mask */
1124#define PHY_M_PC_ASS_CRS_TX (1<<11) /* Bit 11: Assert CRS on Transmit */
1125#define PHY_M_PC_FL_GOOD (1<<10) /* Bit 10: Force Link Good */
1126#define PHY_M_PC_EN_DET_MSK (3<<8) /* Bit 9.. 8: Energy Detect Mask */
1127#define PHY_M_PC_ENA_EXT_D (1<<7) /* Bit 7: Enable Ext. Distance (10BT) */
1128#define PHY_M_PC_MDIX_MSK (3<<5) /* Bit 6.. 5: MDI/MDIX Config. Mask */
1129#define PHY_M_PC_DIS_125CLK (1<<4) /* Bit 4: Disable 125 CLK */
1130#define PHY_M_PC_MAC_POW_UP (1<<3) /* Bit 3: MAC Power up */
1131#define PHY_M_PC_SQE_T_ENA (1<<2) /* Bit 2: SQE Test Enabled */
1132#define PHY_M_PC_POL_R_DIS (1<<1) /* Bit 1: Polarity Reversal Disabled */
1133#define PHY_M_PC_DIS_JABBER (1<<0) /* Bit 0: Disable Jabber */
1134
1135#define PHY_M_PC_EN_DET SHIFT8(2) /* Energy Detect (Mode 1) */
1136#define PHY_M_PC_EN_DET_PLUS SHIFT8(3) /* Energy Detect Plus (Mode 2) */
1137
1138#define PHY_M_PC_MDI_XMODE(x) SHIFT5(x)
1139#define PHY_M_PC_MAN_MDI 0 /* 00 = Manual MDI configuration */
1140#define PHY_M_PC_MAN_MDIX 1 /* 01 = Manual MDIX configuration */
1141#define PHY_M_PC_ENA_AUTO 3 /* 11 = Enable Automatic Crossover */
1142
1143/***** PHY_MARV_PHY_STAT 16 bit r/o PHY Specific Status Reg *****/
1144#define PHY_M_PS_SPEED_MSK (3<<14) /* Bit 15..14: Speed Mask */
1145#define PHY_M_PS_SPEED_1000 (1<<15) /* 10 = 1000 Mbps */
1146#define PHY_M_PS_SPEED_100 (1<<14) /* 01 = 100 Mbps */
1147#define PHY_M_PS_SPEED_10 0 /* 00 = 10 Mbps */
1148#define PHY_M_PS_FULL_DUP (1<<13) /* Bit 13: Full Duplex */
1149#define PHY_M_PS_PAGE_REC (1<<12) /* Bit 12: Page Received */
1150#define PHY_M_PS_SPDUP_RES (1<<11) /* Bit 11: Speed & Duplex Resolved */
1151#define PHY_M_PS_LINK_UP (1<<10) /* Bit 10: Link Up */
1152#define PHY_M_PS_CABLE_MSK (3<<7) /* Bit 9.. 7: Cable Length Mask */
1153#define PHY_M_PS_MDI_X_STAT (1<<6) /* Bit 6: MDI Crossover Stat (1=MDIX) */
1154#define PHY_M_PS_DOWNS_STAT (1<<5) /* Bit 5: Downshift Status (1=downsh.) */
1155#define PHY_M_PS_ENDET_STAT (1<<4) /* Bit 4: Energy Detect Status (1=act) */
1156#define PHY_M_PS_TX_P_EN (1<<3) /* Bit 3: Tx Pause Enabled */
1157#define PHY_M_PS_RX_P_EN (1<<2) /* Bit 2: Rx Pause Enabled */
1158#define PHY_M_PS_POL_REV (1<<1) /* Bit 1: Polarity Reversed */
1159#define PHY_M_PC_JABBER (1<<0) /* Bit 0: Jabber */
1160
1161#define PHY_M_PS_PAUSE_MSK (PHY_M_PS_TX_P_EN | PHY_M_PS_RX_P_EN)
1162
1163/***** PHY_MARV_INT_MASK 16 bit r/w Interrupt Mask Reg *****/
1164/***** PHY_MARV_INT_STAT 16 bit r/o Interrupt Status Reg *****/
1165#define PHY_M_IS_AN_ERROR (1<<15) /* Bit 15: Auto-Negotiation Error */
1166#define PHY_M_IS_LSP_CHANGE (1<<14) /* Bit 14: Link Speed Changed */
1167#define PHY_M_IS_DUP_CHANGE (1<<13) /* Bit 13: Duplex Mode Changed */
1168#define PHY_M_IS_AN_PR (1<<12) /* Bit 12: Page Received */
1169#define PHY_M_IS_AN_COMPL (1<<11) /* Bit 11: Auto-Negotiation Completed */
1170#define PHY_M_IS_LST_CHANGE (1<<10) /* Bit 10: Link Status Changed */
1171#define PHY_M_IS_SYMB_ERROR (1<<9) /* Bit 9: Symbol Error */
1172#define PHY_M_IS_FALSE_CARR (1<<8) /* Bit 8: False Carrier */
1173#define PHY_M_IS_FIFO_ERROR (1<<7) /* Bit 7: FIFO Overflow/Underrun Error */
1174#define PHY_M_IS_MDI_CHANGE (1<<6) /* Bit 6: MDI Crossover Changed */
1175#define PHY_M_IS_DOWNSH_DET (1<<5) /* Bit 5: Downshift Detected */
1176#define PHY_M_IS_END_CHANGE (1<<4) /* Bit 4: Energy Detect Changed */
1177 /* Bit 3..2: reserved */
1178#define PHY_M_IS_POL_CHANGE (1<<1) /* Bit 1: Polarity Changed */
1179#define PHY_M_IS_JABBER (1<<0) /* Bit 0: Jabber */
1180
1181#define PHY_M_DEF_MSK (PHY_M_IS_AN_ERROR | PHY_M_IS_AN_PR | \
1182 PHY_M_IS_LST_CHANGE | PHY_M_IS_FIFO_ERROR)
1183
1184/***** PHY_MARV_EXT_CTRL 16 bit r/w Ext. PHY Specific Ctrl *****/
1185#define PHY_M_EC_M_DSC_MSK (3<<10) /* Bit 11..10: Master downshift counter */
1186#define PHY_M_EC_S_DSC_MSK (3<<8) /* Bit 9.. 8: Slave downshift counter */
1187#define PHY_M_EC_MAC_S_MSK (7<<4) /* Bit 6.. 4: Def. MAC interface speed */
1188#define PHY_M_EC_FIB_AN_ENA (1<<3) /* Bit 3: Fiber Auto-Neg. Enable */
1189
1190#define PHY_M_EC_M_DSC(x) SHIFT10(x) /* 00=1x; 01=2x; 10=3x; 11=4x */
1191#define PHY_M_EC_S_DSC(x) SHIFT8(x) /* 00=dis; 01=1x; 10=2x; 11=3x */
1192#define PHY_M_EC_MAC_S(x) SHIFT4(x) /* 01X=0; 110=2.5; 111=25 (MHz) */
1193
1194#define MAC_TX_CLK_0_MHZ 2
1195#define MAC_TX_CLK_2_5_MHZ 6
1196#define MAC_TX_CLK_25_MHZ 7
1197
1198/***** PHY_MARV_LED_CTRL 16 bit r/w LED Control Reg *****/
1199#define PHY_M_LEDC_DIS_LED (1<<15) /* Bit 15: Disable LED */
1200#define PHY_M_LEDC_PULS_MSK (7<<12) /* Bit 14..12: Pulse Stretch Mask */
1201#define PHY_M_LEDC_F_INT (1<<11) /* Bit 11: Force Interrupt */
1202#define PHY_M_LEDC_BL_R_MSK (7<<8) /* Bit 10.. 8: Blink Rate Mask */
1203 /* Bit 7.. 5: reserved */
1204#define PHY_M_LEDC_LINK_MSK (3<<3) /* Bit 4.. 3: Link Control Mask */
1205#define PHY_M_LEDC_DP_CTRL (1<<2) /* Bit 2: Duplex Control */
1206#define PHY_M_LEDC_RX_CTRL (1<<1) /* Bit 1: Rx activity / Link */
1207#define PHY_M_LEDC_TX_CTRL (1<<0) /* Bit 0: Tx activity / Link */
1208
1209#define PHY_M_LED_PULS_DUR(x) SHIFT12(x) /* Pulse Stretch Duration */
1210
1211#define PULS_NO_STR 0 /* no pulse stretching */
1212#define PULS_21MS 1 /* 21 ms to 42 ms */
1213#define PULS_42MS 2 /* 42 ms to 84 ms */
1214#define PULS_84MS 3 /* 84 ms to 170 ms */
1215#define PULS_170MS 4 /* 170 ms to 340 ms */
1216#define PULS_340MS 5 /* 340 ms to 670 ms */
1217#define PULS_670MS 6 /* 670 ms to 1.3 s */
1218#define PULS_1300MS 7 /* 1.3 s to 2.7 s */
1219
1220#define PHY_M_LED_BLINK_RT(x) SHIFT8(x) /* Blink Rate */
1221
1222#define BLINK_42MS 0 /* 42 ms */
1223#define BLINK_84MS 1 /* 84 ms */
1224#define BLINK_170MS 2 /* 170 ms */
1225#define BLINK_340MS 3 /* 340 ms */
1226#define BLINK_670MS 4 /* 670 ms */
1227 /* values 5 - 7: reserved */
1228
1229/***** PHY_MARV_LED_OVER 16 bit r/w Manual LED Override Reg *****/
1230#define PHY_M_LED_MO_DUP(x) SHIFT10(x) /* Bit 11..10: Duplex */
1231#define PHY_M_LED_MO_10(x) SHIFT8(x) /* Bit 9.. 8: Link 10 */
1232#define PHY_M_LED_MO_100(x) SHIFT6(x) /* Bit 7.. 6: Link 100 */
1233#define PHY_M_LED_MO_1000(x) SHIFT4(x) /* Bit 5.. 4: Link 1000 */
1234#define PHY_M_LED_MO_RX(x) SHIFT2(x) /* Bit 3.. 2: Rx */
1235#define PHY_M_LED_MO_TX(x) SHIFT0(x) /* Bit 1.. 0: Tx */
1236
1237#define MO_LED_NORM 0
1238#define MO_LED_BLINK 1
1239#define MO_LED_OFF 2
1240#define MO_LED_ON 3
1241
1242/***** PHY_MARV_EXT_CTRL_2 16 bit r/w Ext. PHY Specific Ctrl 2 *****/
1243 /* Bit 15.. 7: reserved */
1244#define PHY_M_EC2_FI_IMPED (1<<6) /* Bit 6: Fiber Input Impedance */
1245#define PHY_M_EC2_FO_IMPED (1<<5) /* Bit 5: Fiber Output Impedance */
1246#define PHY_M_EC2_FO_M_CLK (1<<4) /* Bit 4: Fiber Mode Clock Enable */
1247#define PHY_M_EC2_FO_BOOST (1<<3) /* Bit 3: Fiber Output Boost */
1248#define PHY_M_EC2_FO_AM_MSK 7 /* Bit 2.. 0: Fiber Output Amplitude */
1249
1250/***** PHY_MARV_EXT_P_STAT 16 bit r/w Ext. PHY Specific Status *****/
1251#define PHY_M_FC_AUTO_SEL (1<<15) /* Bit 15: Fiber/Copper Auto Sel. dis. */
1252#define PHY_M_FC_AN_REG_ACC (1<<14) /* Bit 14: Fiber/Copper Autoneg. reg acc */
1253#define PHY_M_FC_RESULUTION (1<<13) /* Bit 13: Fiber/Copper Resulution */
1254#define PHY_M_SER_IF_AN_BP (1<<12) /* Bit 12: Ser IF autoneg. bypass enable */
1255#define PHY_M_SER_IF_BP_ST (1<<11) /* Bit 11: Ser IF autoneg. bypass status */
1256#define PHY_M_IRQ_POLARITY (1<<10) /* Bit 10: IRQ polarity */
1257 /* Bit 9..4: reserved */
1258#define PHY_M_UNDOC1 (1<< 7) /* undocumented bit !! */
1259#define PHY_M_MODE_MASK (0xf<<0)/* Bit 3..0: copy of HWCFG MODE[3:0] */
1260
1261
1262/***** PHY_MARV_CABLE_DIAG 16 bit r/o Cable Diagnostic Reg *****/
1263#define PHY_M_CABD_ENA_TEST (1<<15) /* Bit 15: Enable Test */
1264#define PHY_M_CABD_STAT_MSK (3<<13) /* Bit 14..13: Status */
1265 /* Bit 12.. 8: reserved */
1266#define PHY_M_CABD_DIST_MSK 0xff /* Bit 7.. 0: Distance */
1267
1268/* values for Cable Diagnostic Status (11=fail; 00=OK; 10=open; 01=short) */
1269#define CABD_STAT_NORMAL 0
1270#define CABD_STAT_SHORT 1
1271#define CABD_STAT_OPEN 2
1272#define CABD_STAT_FAIL 3
1273
1274
1275/*
1276 * GMAC registers
1277 *
1278 * The GMAC registers are 16 or 32 bits wide.
1279 * The GMACs host processor interface is 16 bits wide,
1280 * therefore ALL registers will be addressed with 16 bit accesses.
1281 *
1282 * The following macros are provided to access the GMAC registers
1283 * GM_IN16(), GM_OUT16, GM_IN32(), GM_OUT32(), GM_INADR(), GM_OUTADR(),
1284 * GM_INHASH(), and GM_OUTHASH().
1285 * The macros are defined in SkGeHw.h.
1286 *
1287 * Note: NA reg = Network Address e.g DA, SA etc.
1288 *
1289 */
1290
1291/* Port Registers */
1292#define GM_GP_STAT 0x0000 /* 16 bit r/o General Purpose Status */
1293#define GM_GP_CTRL 0x0004 /* 16 bit r/w General Purpose Control */
1294#define GM_TX_CTRL 0x0008 /* 16 bit r/w Transmit Control Reg. */
1295#define GM_RX_CTRL 0x000c /* 16 bit r/w Receive Control Reg. */
1296#define GM_TX_FLOW_CTRL 0x0010 /* 16 bit r/w Transmit Flow-Control */
1297#define GM_TX_PARAM 0x0014 /* 16 bit r/w Transmit Parameter Reg. */
1298#define GM_SERIAL_MODE 0x0018 /* 16 bit r/w Serial Mode Register */
1299
1300/* Source Address Registers */
1301#define GM_SRC_ADDR_1L 0x001c /* 16 bit r/w Source Address 1 (low) */
1302#define GM_SRC_ADDR_1M 0x0020 /* 16 bit r/w Source Address 1 (middle) */
1303#define GM_SRC_ADDR_1H 0x0024 /* 16 bit r/w Source Address 1 (high) */
1304#define GM_SRC_ADDR_2L 0x0028 /* 16 bit r/w Source Address 2 (low) */
1305#define GM_SRC_ADDR_2M 0x002c /* 16 bit r/w Source Address 2 (middle) */
1306#define GM_SRC_ADDR_2H 0x0030 /* 16 bit r/w Source Address 2 (high) */
1307
1308/* Multicast Address Hash Registers */
1309#define GM_MC_ADDR_H1 0x0034 /* 16 bit r/w Multicast Address Hash 1 */
1310#define GM_MC_ADDR_H2 0x0038 /* 16 bit r/w Multicast Address Hash 2 */
1311#define GM_MC_ADDR_H3 0x003c /* 16 bit r/w Multicast Address Hash 3 */
1312#define GM_MC_ADDR_H4 0x0040 /* 16 bit r/w Multicast Address Hash 4 */
1313
1314/* Interrupt Source Registers */
1315#define GM_TX_IRQ_SRC 0x0044 /* 16 bit r/o Tx Overflow IRQ Source */
1316#define GM_RX_IRQ_SRC 0x0048 /* 16 bit r/o Rx Overflow IRQ Source */
1317#define GM_TR_IRQ_SRC 0x004c /* 16 bit r/o Tx/Rx Over. IRQ Source */
1318
1319/* Interrupt Mask Registers */
1320#define GM_TX_IRQ_MSK 0x0050 /* 16 bit r/w Tx Overflow IRQ Mask */
1321#define GM_RX_IRQ_MSK 0x0054 /* 16 bit r/w Rx Overflow IRQ Mask */
1322#define GM_TR_IRQ_MSK 0x0058 /* 16 bit r/w Tx/Rx Over. IRQ Mask */
1323
1324/* Serial Management Interface (SMI) Registers */
1325#define GM_SMI_CTRL 0x0080 /* 16 bit r/w SMI Control Register */
1326#define GM_SMI_DATA 0x0084 /* 16 bit r/w SMI Data Register */
1327#define GM_PHY_ADDR 0x0088 /* 16 bit r/w GPHY Address Register */
1328
1329/* MIB Counters */
1330#define GM_MIB_CNT_BASE 0x0100 /* Base Address of MIB Counters */
1331#define GM_MIB_CNT_SIZE 44 /* Number of MIB Counters */
1332
1333/*
1334 * MIB Counters base address definitions (low word) -
1335 * use offset 4 for access to high word (32 bit r/o)
1336 */
1337#define GM_RXF_UC_OK \
1338 (GM_MIB_CNT_BASE + 0) /* Unicast Frames Received OK */
1339#define GM_RXF_BC_OK \
1340 (GM_MIB_CNT_BASE + 8) /* Broadcast Frames Received OK */
1341#define GM_RXF_MPAUSE \
1342 (GM_MIB_CNT_BASE + 16) /* Pause MAC Ctrl Frames Received */
1343#define GM_RXF_MC_OK \
1344 (GM_MIB_CNT_BASE + 24) /* Multicast Frames Received OK */
1345#define GM_RXF_FCS_ERR \
1346 (GM_MIB_CNT_BASE + 32) /* Rx Frame Check Seq. Error */
1347 /* GM_MIB_CNT_BASE + 40: reserved */
1348#define GM_RXO_OK_LO \
1349 (GM_MIB_CNT_BASE + 48) /* Octets Received OK Low */
1350#define GM_RXO_OK_HI \
1351 (GM_MIB_CNT_BASE + 56) /* Octets Received OK High */
1352#define GM_RXO_ERR_LO \
1353 (GM_MIB_CNT_BASE + 64) /* Octets Received Invalid Low */
1354#define GM_RXO_ERR_HI \
1355 (GM_MIB_CNT_BASE + 72) /* Octets Received Invalid High */
1356#define GM_RXF_SHT \
1357 (GM_MIB_CNT_BASE + 80) /* Frames <64 Byte Received OK */
1358#define GM_RXE_FRAG \
1359 (GM_MIB_CNT_BASE + 88) /* Frames <64 Byte Received with FCS Err */
1360#define GM_RXF_64B \
1361 (GM_MIB_CNT_BASE + 96) /* 64 Byte Rx Frame */
1362#define GM_RXF_127B \
1363 (GM_MIB_CNT_BASE + 104) /* 65-127 Byte Rx Frame */
1364#define GM_RXF_255B \
1365 (GM_MIB_CNT_BASE + 112) /* 128-255 Byte Rx Frame */
1366#define GM_RXF_511B \
1367 (GM_MIB_CNT_BASE + 120) /* 256-511 Byte Rx Frame */
1368#define GM_RXF_1023B \
1369 (GM_MIB_CNT_BASE + 128) /* 512-1023 Byte Rx Frame */
1370#define GM_RXF_1518B \
1371 (GM_MIB_CNT_BASE + 136) /* 1024-1518 Byte Rx Frame */
1372#define GM_RXF_MAX_SZ \
1373 (GM_MIB_CNT_BASE + 144) /* 1519-MaxSize Byte Rx Frame */
1374#define GM_RXF_LNG_ERR \
1375 (GM_MIB_CNT_BASE + 152) /* Rx Frame too Long Error */
1376#define GM_RXF_JAB_PKT \
1377 (GM_MIB_CNT_BASE + 160) /* Rx Jabber Packet Frame */
1378 /* GM_MIB_CNT_BASE + 168: reserved */
1379#define GM_RXE_FIFO_OV \
1380 (GM_MIB_CNT_BASE + 176) /* Rx FIFO overflow Event */
1381 /* GM_MIB_CNT_BASE + 184: reserved */
1382#define GM_TXF_UC_OK \
1383 (GM_MIB_CNT_BASE + 192) /* Unicast Frames Xmitted OK */
1384#define GM_TXF_BC_OK \
1385 (GM_MIB_CNT_BASE + 200) /* Broadcast Frames Xmitted OK */
1386#define GM_TXF_MPAUSE \
1387 (GM_MIB_CNT_BASE + 208) /* Pause MAC Ctrl Frames Xmitted */
1388#define GM_TXF_MC_OK \
1389 (GM_MIB_CNT_BASE + 216) /* Multicast Frames Xmitted OK */
1390#define GM_TXO_OK_LO \
1391 (GM_MIB_CNT_BASE + 224) /* Octets Transmitted OK Low */
1392#define GM_TXO_OK_HI \
1393 (GM_MIB_CNT_BASE + 232) /* Octets Transmitted OK High */
1394#define GM_TXF_64B \
1395 (GM_MIB_CNT_BASE + 240) /* 64 Byte Tx Frame */
1396#define GM_TXF_127B \
1397 (GM_MIB_CNT_BASE + 248) /* 65-127 Byte Tx Frame */
1398#define GM_TXF_255B \
1399 (GM_MIB_CNT_BASE + 256) /* 128-255 Byte Tx Frame */
1400#define GM_TXF_511B \
1401 (GM_MIB_CNT_BASE + 264) /* 256-511 Byte Tx Frame */
1402#define GM_TXF_1023B \
1403 (GM_MIB_CNT_BASE + 272) /* 512-1023 Byte Tx Frame */
1404#define GM_TXF_1518B \
1405 (GM_MIB_CNT_BASE + 280) /* 1024-1518 Byte Tx Frame */
1406#define GM_TXF_MAX_SZ \
1407 (GM_MIB_CNT_BASE + 288) /* 1519-MaxSize Byte Tx Frame */
1408 /* GM_MIB_CNT_BASE + 296: reserved */
1409#define GM_TXF_COL \
1410 (GM_MIB_CNT_BASE + 304) /* Tx Collision */
1411#define GM_TXF_LAT_COL \
1412 (GM_MIB_CNT_BASE + 312) /* Tx Late Collision */
1413#define GM_TXF_ABO_COL \
1414 (GM_MIB_CNT_BASE + 320) /* Tx aborted due to Exces. Col. */
1415#define GM_TXF_MUL_COL \
1416 (GM_MIB_CNT_BASE + 328) /* Tx Multiple Collision */
1417#define GM_TXF_SNG_COL \
1418 (GM_MIB_CNT_BASE + 336) /* Tx Single Collision */
1419#define GM_TXE_FIFO_UR \
1420 (GM_MIB_CNT_BASE + 344) /* Tx FIFO Underrun Event */
1421
1422/*----------------------------------------------------------------------------*/
1423/*
1424 * GMAC Bit Definitions
1425 *
1426 * If the bit access behaviour differs from the register access behaviour
1427 * (r/w, r/o) this is documented after the bit number.
1428 * The following bit access behaviours are used:
1429 * (sc) self clearing
1430 * (r/o) read only
1431 */
1432
1433/* GM_GP_STAT 16 bit r/o General Purpose Status Register */
1434#define GM_GPSR_SPEED (1<<15) /* Bit 15: Port Speed (1 = 100 Mbps) */
1435#define GM_GPSR_DUPLEX (1<<14) /* Bit 14: Duplex Mode (1 = Full) */
1436#define GM_GPSR_FC_TX_DIS (1<<13) /* Bit 13: Tx Flow-Control Mode Disabled */
1437#define GM_GPSR_LINK_UP (1<<12) /* Bit 12: Link Up Status */
1438#define GM_GPSR_PAUSE (1<<11) /* Bit 11: Pause State */
1439#define GM_GPSR_TX_ACTIVE (1<<10) /* Bit 10: Tx in Progress */
1440#define GM_GPSR_EXC_COL (1<<9) /* Bit 9: Excessive Collisions Occured */
1441#define GM_GPSR_LAT_COL (1<<8) /* Bit 8: Late Collisions Occured */
1442 /* Bit 7..6: reserved */
1443#define GM_GPSR_PHY_ST_CH (1<<5) /* Bit 5: PHY Status Change */
1444#define GM_GPSR_GIG_SPEED (1<<4) /* Bit 4: Gigabit Speed (1 = 1000 Mbps) */
1445#define GM_GPSR_PART_MODE (1<<3) /* Bit 3: Partition mode */
1446#define GM_GPSR_FC_RX_DIS (1<<2) /* Bit 2: Rx Flow-Control Mode Disabled */
1447#define GM_GPSR_PROM_EN (1<<1) /* Bit 1: Promiscuous Mode Enabled */
1448 /* Bit 0: reserved */
1449
1450/* GM_GP_CTRL 16 bit r/w General Purpose Control Register */
1451 /* Bit 15: reserved */
1452#define GM_GPCR_PROM_ENA (1<<14) /* Bit 14: Enable Promiscuous Mode */
1453#define GM_GPCR_FC_TX_DIS (1<<13) /* Bit 13: Disable Tx Flow-Control Mode */
1454#define GM_GPCR_TX_ENA (1<<12) /* Bit 12: Enable Transmit */
1455#define GM_GPCR_RX_ENA (1<<11) /* Bit 11: Enable Receive */
1456#define GM_GPCR_BURST_ENA (1<<10) /* Bit 10: Enable Burst Mode */
1457#define GM_GPCR_LOOP_ENA (1<<9) /* Bit 9: Enable MAC Loopback Mode */
1458#define GM_GPCR_PART_ENA (1<<8) /* Bit 8: Enable Partition Mode */
1459#define GM_GPCR_GIGS_ENA (1<<7) /* Bit 7: Gigabit Speed (1000 Mbps) */
1460#define GM_GPCR_FL_PASS (1<<6) /* Bit 6: Force Link Pass */
1461#define GM_GPCR_DUP_FULL (1<<5) /* Bit 5: Full Duplex Mode */
1462#define GM_GPCR_FC_RX_DIS (1<<4) /* Bit 4: Disable Rx Flow-Control Mode */
1463#define GM_GPCR_SPEED_100 (1<<3) /* Bit 3: Port Speed 100 Mbps */
1464#define GM_GPCR_AU_DUP_DIS (1<<2) /* Bit 2: Disable Auto-Update Duplex */
1465#define GM_GPCR_AU_FCT_DIS (1<<1) /* Bit 1: Disable Auto-Update Flow-C. */
1466#define GM_GPCR_AU_SPD_DIS (1<<0) /* Bit 0: Disable Auto-Update Speed */
1467
1468#define GM_GPCR_SPEED_1000 (GM_GPCR_GIGS_ENA | GM_GPCR_SPEED_100)
1469#define GM_GPCR_AU_ALL_DIS (GM_GPCR_AU_DUP_DIS | GM_GPCR_AU_FCT_DIS |\
1470 GM_GPCR_AU_SPD_DIS)
1471
1472/* GM_TX_CTRL 16 bit r/w Transmit Control Register */
1473#define GM_TXCR_FORCE_JAM (1<<15) /* Bit 15: Force Jam / Flow-Control */
1474#define GM_TXCR_CRC_DIS (1<<14) /* Bit 14: Disable insertion of CRC */
1475#define GM_TXCR_PAD_DIS (1<<13) /* Bit 13: Disable padding of packets */
1476#define GM_TXCR_COL_THR_MSK (7<<10) /* Bit 12..10: Collision Threshold */
1477
1478#define TX_COL_THR(x) (SHIFT10(x) & GM_TXCR_COL_THR_MSK)
1479
1480#define TX_COL_DEF 0x04
1481
1482/* GM_RX_CTRL 16 bit r/w Receive Control Register */
1483#define GM_RXCR_UCF_ENA (1<<15) /* Bit 15: Enable Unicast filtering */
1484#define GM_RXCR_MCF_ENA (1<<14) /* Bit 14: Enable Multicast filtering */
1485#define GM_RXCR_CRC_DIS (1<<13) /* Bit 13: Remove 4-byte CRC */
1486#define GM_RXCR_PASS_FC (1<<12) /* Bit 12: Pass FC packets to FIFO */
1487
1488/* GM_TX_PARAM 16 bit r/w Transmit Parameter Register */
1489#define GM_TXPA_JAMLEN_MSK (0x03<<14) /* Bit 15..14: Jam Length */
1490#define GM_TXPA_JAMIPG_MSK (0x1f<<9) /* Bit 13..9: Jam IPG */
1491#define GM_TXPA_JAMDAT_MSK (0x1f<<4) /* Bit 8..4: IPG Jam to Data */
1492 /* Bit 3..0: reserved */
1493
1494#define TX_JAM_LEN_VAL(x) (SHIFT14(x) & GM_TXPA_JAMLEN_MSK)
1495#define TX_JAM_IPG_VAL(x) (SHIFT9(x) & GM_TXPA_JAMIPG_MSK)
1496#define TX_IPG_JAM_DATA(x) (SHIFT4(x) & GM_TXPA_JAMDAT_MSK)
1497
1498#define TX_JAM_LEN_DEF 0x03
1499#define TX_JAM_IPG_DEF 0x0b
1500#define TX_IPG_JAM_DEF 0x1c
1501
1502/* GM_SERIAL_MODE 16 bit r/w Serial Mode Register */
1503#define GM_SMOD_DATABL_MSK (0x1f<<11) /* Bit 15..11: Data Blinder (r/o) */
1504#define GM_SMOD_LIMIT_4 (1<<10) /* Bit 10: 4 consecutive Tx trials */
1505#define GM_SMOD_VLAN_ENA (1<<9) /* Bit 9: Enable VLAN (Max. Frame Len) */
1506#define GM_SMOD_JUMBO_ENA (1<<8) /* Bit 8: Enable Jumbo (Max. Frame Len) */
1507 /* Bit 7..5: reserved */
1508#define GM_SMOD_IPG_MSK 0x1f /* Bit 4..0: Inter-Packet Gap (IPG) */
1509
1510#define DATA_BLIND_VAL(x) (SHIFT11(x) & GM_SMOD_DATABL_MSK)
1511#define DATA_BLIND_DEF 0x04
1512
1513#define IPG_DATA_VAL(x) (x & GM_SMOD_IPG_MSK)
1514#define IPG_DATA_DEF 0x1e
1515
1516/* GM_SMI_CTRL 16 bit r/w SMI Control Register */
1517#define GM_SMI_CT_PHY_A_MSK (0x1f<<11) /* Bit 15..11: PHY Device Address */
1518#define GM_SMI_CT_REG_A_MSK (0x1f<<6) /* Bit 10.. 6: PHY Register Address */
1519#define GM_SMI_CT_OP_RD (1<<5) /* Bit 5: OpCode Read (0=Write)*/
1520#define GM_SMI_CT_RD_VAL (1<<4) /* Bit 4: Read Valid (Read completed) */
1521#define GM_SMI_CT_BUSY (1<<3) /* Bit 3: Busy (Operation in progress) */
1522 /* Bit 2..0: reserved */
1523
1524#define GM_SMI_CT_PHY_AD(x) (SHIFT11(x) & GM_SMI_CT_PHY_A_MSK)
1525#define GM_SMI_CT_REG_AD(x) (SHIFT6(x) & GM_SMI_CT_REG_A_MSK)
1526
1527 /* GM_PHY_ADDR 16 bit r/w GPHY Address Register */
1528 /* Bit 15..6: reserved */
1529#define GM_PAR_MIB_CLR (1<<5) /* Bit 5: Set MIB Clear Counter Mode */
1530#define GM_PAR_MIB_TST (1<<4) /* Bit 4: MIB Load Counter (Test Mode) */
1531 /* Bit 3..0: reserved */
1532
1533/* Receive Frame Status Encoding */
1534#define GMR_FS_LEN (0xffffUL<<16) /* Bit 31..16: Rx Frame Length */
1535 /* Bit 15..14: reserved */
1536#define GMR_FS_VLAN (1L<<13) /* Bit 13: VLAN Packet */
1537#define GMR_FS_JABBER (1L<<12) /* Bit 12: Jabber Packet */
1538#define GMR_FS_UN_SIZE (1L<<11) /* Bit 11: Undersize Packet */
1539#define GMR_FS_MC (1L<<10) /* Bit 10: Multicast Packet */
1540#define GMR_FS_BC (1L<<9) /* Bit 9: Broadcast Packet */
1541#define GMR_FS_RX_OK (1L<<8) /* Bit 8: Receive OK (Good Packet) */
1542#define GMR_FS_GOOD_FC (1L<<7) /* Bit 7: Good Flow-Control Packet */
1543#define GMR_FS_BAD_FC (1L<<6) /* Bit 6: Bad Flow-Control Packet */
1544#define GMR_FS_MII_ERR (1L<<5) /* Bit 5: MII Error */
1545#define GMR_FS_LONG_ERR (1L<<4) /* Bit 4: Too Long Packet */
1546#define GMR_FS_FRAGMENT (1L<<3) /* Bit 3: Fragment */
1547 /* Bit 2: reserved */
1548#define GMR_FS_CRC_ERR (1L<<1) /* Bit 1: CRC Error */
1549#define GMR_FS_RX_FF_OV (1L<<0) /* Bit 0: Rx FIFO Overflow */
1550
1551/*
1552 * GMR_FS_ANY_ERR (analogous to XMR_FS_ANY_ERR)
1553 */
1554#define GMR_FS_ANY_ERR (GMR_FS_CRC_ERR | \
1555 GMR_FS_LONG_ERR | \
1556 GMR_FS_MII_ERR | \
1557 GMR_FS_BAD_FC | \
1558 GMR_FS_GOOD_FC | \
1559 GMR_FS_JABBER)
1560
1561/* Rx GMAC FIFO Flush Mask (default) */
1562#define RX_FF_FL_DEF_MSK (GMR_FS_CRC_ERR | \
1563 GMR_FS_RX_FF_OV | \
1564 GMR_FS_MII_ERR | \
1565 GMR_FS_BAD_FC | \
1566 GMR_FS_GOOD_FC | \
1567 GMR_FS_UN_SIZE | \
1568 GMR_FS_JABBER)
1569
1570/* typedefs *******************************************************************/
1571
1572
1573/* function prototypes ********************************************************/
1574
1575#ifdef __cplusplus
1576}
1577#endif /* __cplusplus */
1578
1579#endif /* __INC_XMAC_H */
diff --git a/drivers/net/sk98lin/skaddr.c b/drivers/net/sk98lin/skaddr.c
new file mode 100644
index 000000000000..6e6c56aa6d6f
--- /dev/null
+++ b/drivers/net/sk98lin/skaddr.c
@@ -0,0 +1,1788 @@
1/******************************************************************************
2 *
3 * Name: skaddr.c
4 * Project: Gigabit Ethernet Adapters, ADDR-Module
5 * Version: $Revision: 1.52 $
6 * Date: $Date: 2003/06/02 13:46:15 $
7 * Purpose: Manage Addresses (Multicast and Unicast) and Promiscuous Mode.
8 *
9 ******************************************************************************/
10
11/******************************************************************************
12 *
13 * (C)Copyright 1998-2002 SysKonnect GmbH.
14 * (C)Copyright 2002-2003 Marvell.
15 *
16 * This program is free software; you can redistribute it and/or modify
17 * it under the terms of the GNU General Public License as published by
18 * the Free Software Foundation; either version 2 of the License, or
19 * (at your option) any later version.
20 *
21 * The information in this file is provided "AS IS" without warranty.
22 *
23 ******************************************************************************/
24
25/******************************************************************************
26 *
27 * Description:
28 *
29 * This module is intended to manage multicast addresses, address override,
30 * and promiscuous mode on GEnesis and Yukon adapters.
31 *
32 * Address Layout:
33 * port address: physical MAC address
34 * 1st exact match: logical MAC address (GEnesis only)
35 * 2nd exact match: RLMT multicast (GEnesis only)
36 * exact match 3-13: OS-specific multicasts (GEnesis only)
37 *
38 * Include File Hierarchy:
39 *
40 * "skdrv1st.h"
41 * "skdrv2nd.h"
42 *
43 ******************************************************************************/
44
45#if (defined(DEBUG) || ((!defined(LINT)) && (!defined(SK_SLIM))))
46static const char SysKonnectFileId[] =
47 "@(#) $Id: skaddr.c,v 1.52 2003/06/02 13:46:15 tschilli Exp $ (C) Marvell.";
48#endif /* DEBUG ||!LINT || !SK_SLIM */
49
50#define __SKADDR_C
51
52#ifdef __cplusplus
53extern "C" {
54#endif /* cplusplus */
55
56#include "h/skdrv1st.h"
57#include "h/skdrv2nd.h"
58
59/* defines ********************************************************************/
60
61
62#define XMAC_POLY 0xEDB88320UL /* CRC32-Poly - XMAC: Little Endian */
63#define GMAC_POLY 0x04C11DB7L /* CRC16-Poly - GMAC: Little Endian */
64#define HASH_BITS 6 /* #bits in hash */
65#define SK_MC_BIT 0x01
66
67/* Error numbers and messages. */
68
69#define SKERR_ADDR_E001 (SK_ERRBASE_ADDR + 0)
70#define SKERR_ADDR_E001MSG "Bad Flags."
71#define SKERR_ADDR_E002 (SKERR_ADDR_E001 + 1)
72#define SKERR_ADDR_E002MSG "New Error."
73
74/* typedefs *******************************************************************/
75
76/* None. */
77
78/* global variables ***********************************************************/
79
80/* 64-bit hash values with all bits set. */
81
82static const SK_U16 OnesHash[4] = {0xFFFF, 0xFFFF, 0xFFFF, 0xFFFF};
83
84/* local variables ************************************************************/
85
86#ifdef DEBUG
87static int Next0[SK_MAX_MACS] = {0};
88#endif /* DEBUG */
89
90static int SkAddrGmacMcAdd(SK_AC *pAC, SK_IOC IoC, SK_U32 PortNumber,
91 SK_MAC_ADDR *pMc, int Flags);
92static int SkAddrGmacMcClear(SK_AC *pAC, SK_IOC IoC, SK_U32 PortNumber,
93 int Flags);
94static int SkAddrGmacMcUpdate(SK_AC *pAC, SK_IOC IoC, SK_U32 PortNumber);
95static int SkAddrGmacPromiscuousChange(SK_AC *pAC, SK_IOC IoC,
96 SK_U32 PortNumber, int NewPromMode);
97static int SkAddrXmacMcAdd(SK_AC *pAC, SK_IOC IoC, SK_U32 PortNumber,
98 SK_MAC_ADDR *pMc, int Flags);
99static int SkAddrXmacMcClear(SK_AC *pAC, SK_IOC IoC, SK_U32 PortNumber,
100 int Flags);
101static int SkAddrXmacMcUpdate(SK_AC *pAC, SK_IOC IoC, SK_U32 PortNumber);
102static int SkAddrXmacPromiscuousChange(SK_AC *pAC, SK_IOC IoC,
103 SK_U32 PortNumber, int NewPromMode);
104
105/* functions ******************************************************************/
106
107/******************************************************************************
108 *
109 * SkAddrInit - initialize data, set state to init
110 *
111 * Description:
112 *
113 * SK_INIT_DATA
114 * ============
115 *
116 * This routine clears the multicast tables and resets promiscuous mode.
117 * Some entries are reserved for the "logical MAC address", the
118 * SK-RLMT multicast address, and the BPDU multicast address.
119 *
120 *
121 * SK_INIT_IO
122 * ==========
123 *
124 * All permanent MAC addresses are read from EPROM.
125 * If the current MAC addresses are not already set in software,
126 * they are set to the values of the permanent addresses.
127 * The current addresses are written to the corresponding MAC.
128 *
129 *
130 * SK_INIT_RUN
131 * ===========
132 *
133 * Nothing.
134 *
135 * Context:
136 * init, pageable
137 *
138 * Returns:
139 * SK_ADDR_SUCCESS
140 */
141int SkAddrInit(
142SK_AC *pAC, /* the adapter context */
143SK_IOC IoC, /* I/O context */
144int Level) /* initialization level */
145{
146 int j;
147 SK_U32 i;
148 SK_U8 *InAddr;
149 SK_U16 *OutAddr;
150 SK_ADDR_PORT *pAPort;
151
152 switch (Level) {
153 case SK_INIT_DATA:
154 SK_MEMSET((char *) &pAC->Addr, (SK_U8) 0,
155 (SK_U16) sizeof(SK_ADDR));
156
157 for (i = 0; i < SK_MAX_MACS; i++) {
158 pAPort = &pAC->Addr.Port[i];
159 pAPort->PromMode = SK_PROM_MODE_NONE;
160
161 pAPort->FirstExactMatchRlmt = SK_ADDR_FIRST_MATCH_RLMT;
162 pAPort->FirstExactMatchDrv = SK_ADDR_FIRST_MATCH_DRV;
163 pAPort->NextExactMatchRlmt = SK_ADDR_FIRST_MATCH_RLMT;
164 pAPort->NextExactMatchDrv = SK_ADDR_FIRST_MATCH_DRV;
165 }
166#ifdef xDEBUG
167 for (i = 0; i < SK_MAX_MACS; i++) {
168 if (pAC->Addr.Port[i].NextExactMatchRlmt <
169 SK_ADDR_FIRST_MATCH_RLMT) {
170 Next0[i] |= 4;
171 }
172 }
173#endif /* DEBUG */
174 /* pAC->Addr.InitDone = SK_INIT_DATA; */
175 break;
176
177 case SK_INIT_IO:
178#ifndef SK_NO_RLMT
179 for (i = 0; i < SK_MAX_NETS; i++) {
180 pAC->Addr.Net[i].ActivePort = pAC->Rlmt.Net[i].ActivePort;
181 }
182#endif /* !SK_NO_RLMT */
183#ifdef xDEBUG
184 for (i = 0; i < SK_MAX_MACS; i++) {
185 if (pAC->Addr.Port[i].NextExactMatchRlmt <
186 SK_ADDR_FIRST_MATCH_RLMT) {
187 Next0[i] |= 8;
188 }
189 }
190#endif /* DEBUG */
191
192 /* Read permanent logical MAC address from Control Register File. */
193 for (j = 0; j < SK_MAC_ADDR_LEN; j++) {
194 InAddr = (SK_U8 *) &pAC->Addr.Net[0].PermanentMacAddress.a[j];
195 SK_IN8(IoC, B2_MAC_1 + j, InAddr);
196 }
197
198 if (!pAC->Addr.Net[0].CurrentMacAddressSet) {
199 /* Set the current logical MAC address to the permanent one. */
200 pAC->Addr.Net[0].CurrentMacAddress =
201 pAC->Addr.Net[0].PermanentMacAddress;
202 pAC->Addr.Net[0].CurrentMacAddressSet = SK_TRUE;
203 }
204
205 /* Set the current logical MAC address. */
206 pAC->Addr.Port[pAC->Addr.Net[0].ActivePort].Exact[0] =
207 pAC->Addr.Net[0].CurrentMacAddress;
208#if SK_MAX_NETS > 1
209 /* Set logical MAC address for net 2 to (log | 3). */
210 if (!pAC->Addr.Net[1].CurrentMacAddressSet) {
211 pAC->Addr.Net[1].PermanentMacAddress =
212 pAC->Addr.Net[0].PermanentMacAddress;
213 pAC->Addr.Net[1].PermanentMacAddress.a[5] |= 3;
214 /* Set the current logical MAC address to the permanent one. */
215 pAC->Addr.Net[1].CurrentMacAddress =
216 pAC->Addr.Net[1].PermanentMacAddress;
217 pAC->Addr.Net[1].CurrentMacAddressSet = SK_TRUE;
218 }
219#endif /* SK_MAX_NETS > 1 */
220
221#ifdef DEBUG
222 for (i = 0; i < (SK_U32) pAC->GIni.GIMacsFound; i++) {
223 SK_DBG_MSG(pAC, SK_DBGMOD_ADDR, SK_DBGCAT_INIT,
224 ("Permanent MAC Address (Net%d): %02X %02X %02X %02X %02X %02X\n",
225 i,
226 pAC->Addr.Net[i].PermanentMacAddress.a[0],
227 pAC->Addr.Net[i].PermanentMacAddress.a[1],
228 pAC->Addr.Net[i].PermanentMacAddress.a[2],
229 pAC->Addr.Net[i].PermanentMacAddress.a[3],
230 pAC->Addr.Net[i].PermanentMacAddress.a[4],
231 pAC->Addr.Net[i].PermanentMacAddress.a[5]))
232
233 SK_DBG_MSG(pAC, SK_DBGMOD_ADDR, SK_DBGCAT_INIT,
234 ("Logical MAC Address (Net%d): %02X %02X %02X %02X %02X %02X\n",
235 i,
236 pAC->Addr.Net[i].CurrentMacAddress.a[0],
237 pAC->Addr.Net[i].CurrentMacAddress.a[1],
238 pAC->Addr.Net[i].CurrentMacAddress.a[2],
239 pAC->Addr.Net[i].CurrentMacAddress.a[3],
240 pAC->Addr.Net[i].CurrentMacAddress.a[4],
241 pAC->Addr.Net[i].CurrentMacAddress.a[5]))
242 }
243#endif /* DEBUG */
244
245 for (i = 0; i < (SK_U32) pAC->GIni.GIMacsFound; i++) {
246 pAPort = &pAC->Addr.Port[i];
247
248 /* Read permanent port addresses from Control Register File. */
249 for (j = 0; j < SK_MAC_ADDR_LEN; j++) {
250 InAddr = (SK_U8 *) &pAPort->PermanentMacAddress.a[j];
251 SK_IN8(IoC, B2_MAC_2 + 8 * i + j, InAddr);
252 }
253
254 if (!pAPort->CurrentMacAddressSet) {
255 /*
256 * Set the current and previous physical MAC address
257 * of this port to its permanent MAC address.
258 */
259 pAPort->CurrentMacAddress = pAPort->PermanentMacAddress;
260 pAPort->PreviousMacAddress = pAPort->PermanentMacAddress;
261 pAPort->CurrentMacAddressSet = SK_TRUE;
262 }
263
264 /* Set port's current physical MAC address. */
265 OutAddr = (SK_U16 *) &pAPort->CurrentMacAddress.a[0];
266#ifdef GENESIS
267 if (pAC->GIni.GIGenesis) {
268 XM_OUTADDR(IoC, i, XM_SA, OutAddr);
269 }
270#endif /* GENESIS */
271#ifdef YUKON
272 if (!pAC->GIni.GIGenesis) {
273 GM_OUTADDR(IoC, i, GM_SRC_ADDR_1L, OutAddr);
274 }
275#endif /* YUKON */
276#ifdef DEBUG
277 SK_DBG_MSG(pAC, SK_DBGMOD_ADDR, SK_DBGCAT_INIT,
278 ("SkAddrInit: Permanent Physical MAC Address: %02X %02X %02X %02X %02X %02X\n",
279 pAPort->PermanentMacAddress.a[0],
280 pAPort->PermanentMacAddress.a[1],
281 pAPort->PermanentMacAddress.a[2],
282 pAPort->PermanentMacAddress.a[3],
283 pAPort->PermanentMacAddress.a[4],
284 pAPort->PermanentMacAddress.a[5]))
285
286 SK_DBG_MSG(pAC, SK_DBGMOD_ADDR, SK_DBGCAT_INIT,
287 ("SkAddrInit: Physical MAC Address: %02X %02X %02X %02X %02X %02X\n",
288 pAPort->CurrentMacAddress.a[0],
289 pAPort->CurrentMacAddress.a[1],
290 pAPort->CurrentMacAddress.a[2],
291 pAPort->CurrentMacAddress.a[3],
292 pAPort->CurrentMacAddress.a[4],
293 pAPort->CurrentMacAddress.a[5]))
294#endif /* DEBUG */
295 }
296 /* pAC->Addr.InitDone = SK_INIT_IO; */
297 break;
298
299 case SK_INIT_RUN:
300#ifdef xDEBUG
301 for (i = 0; i < SK_MAX_MACS; i++) {
302 if (pAC->Addr.Port[i].NextExactMatchRlmt <
303 SK_ADDR_FIRST_MATCH_RLMT) {
304 Next0[i] |= 16;
305 }
306 }
307#endif /* DEBUG */
308
309 /* pAC->Addr.InitDone = SK_INIT_RUN; */
310 break;
311
312 default: /* error */
313 break;
314 }
315
316 return (SK_ADDR_SUCCESS);
317
318} /* SkAddrInit */
319
320#ifndef SK_SLIM
321
322/******************************************************************************
323 *
324 * SkAddrMcClear - clear the multicast table
325 *
326 * Description:
327 * This routine clears the multicast table.
328 *
329 * If not suppressed by Flag SK_MC_SW_ONLY, the hardware is updated
330 * immediately.
331 *
332 * It calls either SkAddrXmacMcClear or SkAddrGmacMcClear, according
333 * to the adapter in use. The real work is done there.
334 *
335 * Context:
336 * runtime, pageable
337 * may be called starting with SK_INIT_DATA with flag SK_MC_SW_ONLY
338 * may be called after SK_INIT_IO without limitation
339 *
340 * Returns:
341 * SK_ADDR_SUCCESS
342 * SK_ADDR_ILLEGAL_PORT
343 */
344int SkAddrMcClear(
345SK_AC *pAC, /* adapter context */
346SK_IOC IoC, /* I/O context */
347SK_U32 PortNumber, /* Index of affected port */
348int Flags) /* permanent/non-perm, sw-only */
349{
350 int ReturnCode;
351
352 if (PortNumber >= (SK_U32) pAC->GIni.GIMacsFound) {
353 return (SK_ADDR_ILLEGAL_PORT);
354 }
355
356 if (pAC->GIni.GIGenesis) {
357 ReturnCode = SkAddrXmacMcClear(pAC, IoC, PortNumber, Flags);
358 }
359 else {
360 ReturnCode = SkAddrGmacMcClear(pAC, IoC, PortNumber, Flags);
361 }
362
363 return (ReturnCode);
364
365} /* SkAddrMcClear */
366
367#endif /* !SK_SLIM */
368
369#ifndef SK_SLIM
370
371/******************************************************************************
372 *
373 * SkAddrXmacMcClear - clear the multicast table
374 *
375 * Description:
376 * This routine clears the multicast table
377 * (either entry 2 or entries 3-16 and InexactFilter) of the given port.
378 * If not suppressed by Flag SK_MC_SW_ONLY, the hardware is updated
379 * immediately.
380 *
381 * Context:
382 * runtime, pageable
383 * may be called starting with SK_INIT_DATA with flag SK_MC_SW_ONLY
384 * may be called after SK_INIT_IO without limitation
385 *
386 * Returns:
387 * SK_ADDR_SUCCESS
388 * SK_ADDR_ILLEGAL_PORT
389 */
390static int SkAddrXmacMcClear(
391SK_AC *pAC, /* adapter context */
392SK_IOC IoC, /* I/O context */
393SK_U32 PortNumber, /* Index of affected port */
394int Flags) /* permanent/non-perm, sw-only */
395{
396 int i;
397
398 if (Flags & SK_ADDR_PERMANENT) { /* permanent => RLMT */
399
400 /* Clear RLMT multicast addresses. */
401 pAC->Addr.Port[PortNumber].NextExactMatchRlmt = SK_ADDR_FIRST_MATCH_RLMT;
402 }
403 else { /* not permanent => DRV */
404
405 /* Clear InexactFilter */
406 for (i = 0; i < 8; i++) {
407 pAC->Addr.Port[PortNumber].InexactFilter.Bytes[i] = 0;
408 }
409
410 /* Clear DRV multicast addresses. */
411
412 pAC->Addr.Port[PortNumber].NextExactMatchDrv = SK_ADDR_FIRST_MATCH_DRV;
413 }
414
415 if (!(Flags & SK_MC_SW_ONLY)) {
416 (void) SkAddrXmacMcUpdate(pAC, IoC, PortNumber);
417 }
418
419 return (SK_ADDR_SUCCESS);
420
421} /* SkAddrXmacMcClear */
422
423#endif /* !SK_SLIM */
424
425#ifndef SK_SLIM
426
427/******************************************************************************
428 *
429 * SkAddrGmacMcClear - clear the multicast table
430 *
431 * Description:
432 * This routine clears the multicast hashing table (InexactFilter)
433 * (either the RLMT or the driver bits) of the given port.
434 *
435 * If not suppressed by Flag SK_MC_SW_ONLY, the hardware is updated
436 * immediately.
437 *
438 * Context:
439 * runtime, pageable
440 * may be called starting with SK_INIT_DATA with flag SK_MC_SW_ONLY
441 * may be called after SK_INIT_IO without limitation
442 *
443 * Returns:
444 * SK_ADDR_SUCCESS
445 * SK_ADDR_ILLEGAL_PORT
446 */
447static int SkAddrGmacMcClear(
448SK_AC *pAC, /* adapter context */
449SK_IOC IoC, /* I/O context */
450SK_U32 PortNumber, /* Index of affected port */
451int Flags) /* permanent/non-perm, sw-only */
452{
453 int i;
454
455#ifdef DEBUG
456 SK_DBG_MSG(pAC, SK_DBGMOD_ADDR, SK_DBGCAT_CTRL,
457 ("GMAC InexactFilter (not cleared): %02X %02X %02X %02X %02X %02X %02X %02X\n",
458 pAC->Addr.Port[PortNumber].InexactFilter.Bytes[0],
459 pAC->Addr.Port[PortNumber].InexactFilter.Bytes[1],
460 pAC->Addr.Port[PortNumber].InexactFilter.Bytes[2],
461 pAC->Addr.Port[PortNumber].InexactFilter.Bytes[3],
462 pAC->Addr.Port[PortNumber].InexactFilter.Bytes[4],
463 pAC->Addr.Port[PortNumber].InexactFilter.Bytes[5],
464 pAC->Addr.Port[PortNumber].InexactFilter.Bytes[6],
465 pAC->Addr.Port[PortNumber].InexactFilter.Bytes[7]))
466#endif /* DEBUG */
467
468 /* Clear InexactFilter */
469 for (i = 0; i < 8; i++) {
470 pAC->Addr.Port[PortNumber].InexactFilter.Bytes[i] = 0;
471 }
472
473 if (Flags & SK_ADDR_PERMANENT) { /* permanent => RLMT */
474
475 /* Copy DRV bits to InexactFilter. */
476 for (i = 0; i < 8; i++) {
477 pAC->Addr.Port[PortNumber].InexactFilter.Bytes[i] |=
478 pAC->Addr.Port[PortNumber].InexactDrvFilter.Bytes[i];
479
480 /* Clear InexactRlmtFilter. */
481 pAC->Addr.Port[PortNumber].InexactRlmtFilter.Bytes[i] = 0;
482
483 }
484 }
485 else { /* not permanent => DRV */
486
487 /* Copy RLMT bits to InexactFilter. */
488 for (i = 0; i < 8; i++) {
489 pAC->Addr.Port[PortNumber].InexactFilter.Bytes[i] |=
490 pAC->Addr.Port[PortNumber].InexactRlmtFilter.Bytes[i];
491
492 /* Clear InexactDrvFilter. */
493 pAC->Addr.Port[PortNumber].InexactDrvFilter.Bytes[i] = 0;
494 }
495 }
496
497#ifdef DEBUG
498 SK_DBG_MSG(pAC, SK_DBGMOD_ADDR, SK_DBGCAT_CTRL,
499 ("GMAC InexactFilter (cleared): %02X %02X %02X %02X %02X %02X %02X %02X\n",
500 pAC->Addr.Port[PortNumber].InexactFilter.Bytes[0],
501 pAC->Addr.Port[PortNumber].InexactFilter.Bytes[1],
502 pAC->Addr.Port[PortNumber].InexactFilter.Bytes[2],
503 pAC->Addr.Port[PortNumber].InexactFilter.Bytes[3],
504 pAC->Addr.Port[PortNumber].InexactFilter.Bytes[4],
505 pAC->Addr.Port[PortNumber].InexactFilter.Bytes[5],
506 pAC->Addr.Port[PortNumber].InexactFilter.Bytes[6],
507 pAC->Addr.Port[PortNumber].InexactFilter.Bytes[7]))
508#endif /* DEBUG */
509
510 if (!(Flags & SK_MC_SW_ONLY)) {
511 (void) SkAddrGmacMcUpdate(pAC, IoC, PortNumber);
512 }
513
514 return (SK_ADDR_SUCCESS);
515
516} /* SkAddrGmacMcClear */
517
518#ifndef SK_ADDR_CHEAT
519
520/******************************************************************************
521 *
522 * SkXmacMcHash - hash multicast address
523 *
524 * Description:
525 * This routine computes the hash value for a multicast address.
526 * A CRC32 algorithm is used.
527 *
528 * Notes:
529 * The code was adapted from the XaQti data sheet.
530 *
531 * Context:
532 * runtime, pageable
533 *
534 * Returns:
535 * Hash value of multicast address.
536 */
537static SK_U32 SkXmacMcHash(
538unsigned char *pMc) /* Multicast address */
539{
540 SK_U32 Idx;
541 SK_U32 Bit;
542 SK_U32 Data;
543 SK_U32 Crc;
544
545 Crc = 0xFFFFFFFFUL;
546 for (Idx = 0; Idx < SK_MAC_ADDR_LEN; Idx++) {
547 Data = *pMc++;
548 for (Bit = 0; Bit < 8; Bit++, Data >>= 1) {
549 Crc = (Crc >> 1) ^ (((Crc ^ Data) & 1) ? XMAC_POLY : 0);
550 }
551 }
552
553 return (Crc & ((1 << HASH_BITS) - 1));
554
555} /* SkXmacMcHash */
556
557
558/******************************************************************************
559 *
560 * SkGmacMcHash - hash multicast address
561 *
562 * Description:
563 * This routine computes the hash value for a multicast address.
564 * A CRC16 algorithm is used.
565 *
566 * Notes:
567 *
568 *
569 * Context:
570 * runtime, pageable
571 *
572 * Returns:
573 * Hash value of multicast address.
574 */
575static SK_U32 SkGmacMcHash(
576unsigned char *pMc) /* Multicast address */
577{
578 SK_U32 Data;
579 SK_U32 TmpData;
580 SK_U32 Crc;
581 int Byte;
582 int Bit;
583
584 Crc = 0xFFFFFFFFUL;
585 for (Byte = 0; Byte < 6; Byte++) {
586 /* Get next byte. */
587 Data = (SK_U32) pMc[Byte];
588
589 /* Change bit order in byte. */
590 TmpData = Data;
591 for (Bit = 0; Bit < 8; Bit++) {
592 if (TmpData & 1L) {
593 Data |= 1L << (7 - Bit);
594 }
595 else {
596 Data &= ~(1L << (7 - Bit));
597 }
598 TmpData >>= 1;
599 }
600
601 Crc ^= (Data << 24);
602 for (Bit = 0; Bit < 8; Bit++) {
603 if (Crc & 0x80000000) {
604 Crc = (Crc << 1) ^ GMAC_POLY;
605 }
606 else {
607 Crc <<= 1;
608 }
609 }
610 }
611
612 return (Crc & ((1 << HASH_BITS) - 1));
613
614} /* SkGmacMcHash */
615
616#endif /* !SK_ADDR_CHEAT */
617
618/******************************************************************************
619 *
620 * SkAddrMcAdd - add a multicast address to a port
621 *
622 * Description:
623 * This routine enables reception for a given address on the given port.
624 *
625 * It calls either SkAddrXmacMcAdd or SkAddrGmacMcAdd, according to the
626 * adapter in use. The real work is done there.
627 *
628 * Notes:
629 * The return code is only valid for SK_PROM_MODE_NONE.
630 *
631 * Context:
632 * runtime, pageable
633 * may be called after SK_INIT_DATA
634 *
635 * Returns:
636 * SK_MC_FILTERING_EXACT
637 * SK_MC_FILTERING_INEXACT
638 * SK_MC_ILLEGAL_ADDRESS
639 * SK_MC_ILLEGAL_PORT
640 * SK_MC_RLMT_OVERFLOW
641 */
642int SkAddrMcAdd(
643SK_AC *pAC, /* adapter context */
644SK_IOC IoC, /* I/O context */
645SK_U32 PortNumber, /* Port Number */
646SK_MAC_ADDR *pMc, /* multicast address to be added */
647int Flags) /* permanent/non-permanent */
648{
649 int ReturnCode;
650
651 if (PortNumber >= (SK_U32) pAC->GIni.GIMacsFound) {
652 return (SK_ADDR_ILLEGAL_PORT);
653 }
654
655 if (pAC->GIni.GIGenesis) {
656 ReturnCode = SkAddrXmacMcAdd(pAC, IoC, PortNumber, pMc, Flags);
657 }
658 else {
659 ReturnCode = SkAddrGmacMcAdd(pAC, IoC, PortNumber, pMc, Flags);
660 }
661
662 return (ReturnCode);
663
664} /* SkAddrMcAdd */
665
666
667/******************************************************************************
668 *
669 * SkAddrXmacMcAdd - add a multicast address to a port
670 *
671 * Description:
672 * This routine enables reception for a given address on the given port.
673 *
674 * Notes:
675 * The return code is only valid for SK_PROM_MODE_NONE.
676 *
677 * The multicast bit is only checked if there are no free exact match
678 * entries.
679 *
680 * Context:
681 * runtime, pageable
682 * may be called after SK_INIT_DATA
683 *
684 * Returns:
685 * SK_MC_FILTERING_EXACT
686 * SK_MC_FILTERING_INEXACT
687 * SK_MC_ILLEGAL_ADDRESS
688 * SK_MC_RLMT_OVERFLOW
689 */
690static int SkAddrXmacMcAdd(
691SK_AC *pAC, /* adapter context */
692SK_IOC IoC, /* I/O context */
693SK_U32 PortNumber, /* Port Number */
694SK_MAC_ADDR *pMc, /* multicast address to be added */
695int Flags) /* permanent/non-permanent */
696{
697 int i;
698 SK_U8 Inexact;
699#ifndef SK_ADDR_CHEAT
700 SK_U32 HashBit;
701#endif /* !defined(SK_ADDR_CHEAT) */
702
703 if (Flags & SK_ADDR_PERMANENT) { /* permanent => RLMT */
704#ifdef xDEBUG
705 if (pAC->Addr.Port[PortNumber].NextExactMatchRlmt <
706 SK_ADDR_FIRST_MATCH_RLMT) {
707 Next0[PortNumber] |= 1;
708 return (SK_MC_RLMT_OVERFLOW);
709 }
710#endif /* DEBUG */
711
712 if (pAC->Addr.Port[PortNumber].NextExactMatchRlmt >
713 SK_ADDR_LAST_MATCH_RLMT) {
714 return (SK_MC_RLMT_OVERFLOW);
715 }
716
717 /* Set a RLMT multicast address. */
718
719 pAC->Addr.Port[PortNumber].Exact[
720 pAC->Addr.Port[PortNumber].NextExactMatchRlmt++] = *pMc;
721
722 return (SK_MC_FILTERING_EXACT);
723 }
724
725#ifdef xDEBUG
726 if (pAC->Addr.Port[PortNumber].NextExactMatchDrv <
727 SK_ADDR_FIRST_MATCH_DRV) {
728 Next0[PortNumber] |= 2;
729 return (SK_MC_RLMT_OVERFLOW);
730 }
731#endif /* DEBUG */
732
733 if (pAC->Addr.Port[PortNumber].NextExactMatchDrv <= SK_ADDR_LAST_MATCH_DRV) {
734
735 /* Set exact match entry. */
736 pAC->Addr.Port[PortNumber].Exact[
737 pAC->Addr.Port[PortNumber].NextExactMatchDrv++] = *pMc;
738
739 /* Clear InexactFilter */
740 for (i = 0; i < 8; i++) {
741 pAC->Addr.Port[PortNumber].InexactFilter.Bytes[i] = 0;
742 }
743 }
744 else {
745 if (!(pMc->a[0] & SK_MC_BIT)) {
746 /* Hashing only possible with multicast addresses */
747 return (SK_MC_ILLEGAL_ADDRESS);
748 }
749#ifndef SK_ADDR_CHEAT
750 /* Compute hash value of address. */
751 HashBit = 63 - SkXmacMcHash(&pMc->a[0]);
752
753 /* Add bit to InexactFilter. */
754 pAC->Addr.Port[PortNumber].InexactFilter.Bytes[HashBit / 8] |=
755 1 << (HashBit % 8);
756#else /* SK_ADDR_CHEAT */
757 /* Set all bits in InexactFilter. */
758 for (i = 0; i < 8; i++) {
759 pAC->Addr.Port[PortNumber].InexactFilter.Bytes[i] = 0xFF;
760 }
761#endif /* SK_ADDR_CHEAT */
762 }
763
764 for (Inexact = 0, i = 0; i < 8; i++) {
765 Inexact |= pAC->Addr.Port[PortNumber].InexactFilter.Bytes[i];
766 }
767
768 if (Inexact == 0 && pAC->Addr.Port[PortNumber].PromMode == 0) {
769 return (SK_MC_FILTERING_EXACT);
770 }
771 else {
772 return (SK_MC_FILTERING_INEXACT);
773 }
774
775} /* SkAddrXmacMcAdd */
776
777
778/******************************************************************************
779 *
780 * SkAddrGmacMcAdd - add a multicast address to a port
781 *
782 * Description:
783 * This routine enables reception for a given address on the given port.
784 *
785 * Notes:
786 * The return code is only valid for SK_PROM_MODE_NONE.
787 *
788 * Context:
789 * runtime, pageable
790 * may be called after SK_INIT_DATA
791 *
792 * Returns:
793 * SK_MC_FILTERING_INEXACT
794 * SK_MC_ILLEGAL_ADDRESS
795 */
796static int SkAddrGmacMcAdd(
797SK_AC *pAC, /* adapter context */
798SK_IOC IoC, /* I/O context */
799SK_U32 PortNumber, /* Port Number */
800SK_MAC_ADDR *pMc, /* multicast address to be added */
801int Flags) /* permanent/non-permanent */
802{
803 int i;
804#ifndef SK_ADDR_CHEAT
805 SK_U32 HashBit;
806#endif /* !defined(SK_ADDR_CHEAT) */
807
808 if (!(pMc->a[0] & SK_MC_BIT)) {
809 /* Hashing only possible with multicast addresses */
810 return (SK_MC_ILLEGAL_ADDRESS);
811 }
812
813#ifndef SK_ADDR_CHEAT
814
815 /* Compute hash value of address. */
816 HashBit = SkGmacMcHash(&pMc->a[0]);
817
818 if (Flags & SK_ADDR_PERMANENT) { /* permanent => RLMT */
819
820 /* Add bit to InexactRlmtFilter. */
821 pAC->Addr.Port[PortNumber].InexactRlmtFilter.Bytes[HashBit / 8] |=
822 1 << (HashBit % 8);
823
824 /* Copy bit to InexactFilter. */
825 for (i = 0; i < 8; i++) {
826 pAC->Addr.Port[PortNumber].InexactFilter.Bytes[i] |=
827 pAC->Addr.Port[PortNumber].InexactRlmtFilter.Bytes[i];
828 }
829#ifdef DEBUG
830 SK_DBG_MSG(pAC, SK_DBGMOD_ADDR, SK_DBGCAT_CTRL,
831 ("GMAC InexactRlmtFilter: %02X %02X %02X %02X %02X %02X %02X %02X\n",
832 pAC->Addr.Port[PortNumber].InexactRlmtFilter.Bytes[0],
833 pAC->Addr.Port[PortNumber].InexactRlmtFilter.Bytes[1],
834 pAC->Addr.Port[PortNumber].InexactRlmtFilter.Bytes[2],
835 pAC->Addr.Port[PortNumber].InexactRlmtFilter.Bytes[3],
836 pAC->Addr.Port[PortNumber].InexactRlmtFilter.Bytes[4],
837 pAC->Addr.Port[PortNumber].InexactRlmtFilter.Bytes[5],
838 pAC->Addr.Port[PortNumber].InexactRlmtFilter.Bytes[6],
839 pAC->Addr.Port[PortNumber].InexactRlmtFilter.Bytes[7]))
840#endif /* DEBUG */
841 }
842 else { /* not permanent => DRV */
843
844 /* Add bit to InexactDrvFilter. */
845 pAC->Addr.Port[PortNumber].InexactDrvFilter.Bytes[HashBit / 8] |=
846 1 << (HashBit % 8);
847
848 /* Copy bit to InexactFilter. */
849 for (i = 0; i < 8; i++) {
850 pAC->Addr.Port[PortNumber].InexactFilter.Bytes[i] |=
851 pAC->Addr.Port[PortNumber].InexactDrvFilter.Bytes[i];
852 }
853#ifdef DEBUG
854 SK_DBG_MSG(pAC, SK_DBGMOD_ADDR, SK_DBGCAT_CTRL,
855 ("GMAC InexactDrvFilter: %02X %02X %02X %02X %02X %02X %02X %02X\n",
856 pAC->Addr.Port[PortNumber].InexactDrvFilter.Bytes[0],
857 pAC->Addr.Port[PortNumber].InexactDrvFilter.Bytes[1],
858 pAC->Addr.Port[PortNumber].InexactDrvFilter.Bytes[2],
859 pAC->Addr.Port[PortNumber].InexactDrvFilter.Bytes[3],
860 pAC->Addr.Port[PortNumber].InexactDrvFilter.Bytes[4],
861 pAC->Addr.Port[PortNumber].InexactDrvFilter.Bytes[5],
862 pAC->Addr.Port[PortNumber].InexactDrvFilter.Bytes[6],
863 pAC->Addr.Port[PortNumber].InexactDrvFilter.Bytes[7]))
864#endif /* DEBUG */
865 }
866
867#else /* SK_ADDR_CHEAT */
868
869 /* Set all bits in InexactFilter. */
870 for (i = 0; i < 8; i++) {
871 pAC->Addr.Port[PortNumber].InexactFilter.Bytes[i] = 0xFF;
872 }
873#endif /* SK_ADDR_CHEAT */
874
875 return (SK_MC_FILTERING_INEXACT);
876
877} /* SkAddrGmacMcAdd */
878
879#endif /* !SK_SLIM */
880
881/******************************************************************************
882 *
883 * SkAddrMcUpdate - update the HW MC address table and set the MAC address
884 *
885 * Description:
886 * This routine enables reception of the addresses contained in a local
887 * table for a given port.
888 * It also programs the port's current physical MAC address.
889 *
890 * It calls either SkAddrXmacMcUpdate or SkAddrGmacMcUpdate, according
891 * to the adapter in use. The real work is done there.
892 *
893 * Notes:
894 * The return code is only valid for SK_PROM_MODE_NONE.
895 *
896 * Context:
897 * runtime, pageable
898 * may be called after SK_INIT_IO
899 *
900 * Returns:
901 * SK_MC_FILTERING_EXACT
902 * SK_MC_FILTERING_INEXACT
903 * SK_ADDR_ILLEGAL_PORT
904 */
905int SkAddrMcUpdate(
906SK_AC *pAC, /* adapter context */
907SK_IOC IoC, /* I/O context */
908SK_U32 PortNumber) /* Port Number */
909{
910 int ReturnCode = 0;
911#if (!defined(SK_SLIM) || defined(DEBUG))
912 if (PortNumber >= (SK_U32) pAC->GIni.GIMacsFound) {
913 return (SK_ADDR_ILLEGAL_PORT);
914 }
915#endif /* !SK_SLIM || DEBUG */
916
917#ifdef GENESIS
918 if (pAC->GIni.GIGenesis) {
919 ReturnCode = SkAddrXmacMcUpdate(pAC, IoC, PortNumber);
920 }
921#endif /* GENESIS */
922#ifdef YUKON
923 if (!pAC->GIni.GIGenesis) {
924 ReturnCode = SkAddrGmacMcUpdate(pAC, IoC, PortNumber);
925 }
926#endif /* YUKON */
927 return (ReturnCode);
928
929} /* SkAddrMcUpdate */
930
931
932#ifdef GENESIS
933
934/******************************************************************************
935 *
936 * SkAddrXmacMcUpdate - update the HW MC address table and set the MAC address
937 *
938 * Description:
939 * This routine enables reception of the addresses contained in a local
940 * table for a given port.
941 * It also programs the port's current physical MAC address.
942 *
943 * Notes:
944 * The return code is only valid for SK_PROM_MODE_NONE.
945 *
946 * Context:
947 * runtime, pageable
948 * may be called after SK_INIT_IO
949 *
950 * Returns:
951 * SK_MC_FILTERING_EXACT
952 * SK_MC_FILTERING_INEXACT
953 * SK_ADDR_ILLEGAL_PORT
954 */
955static int SkAddrXmacMcUpdate(
956SK_AC *pAC, /* adapter context */
957SK_IOC IoC, /* I/O context */
958SK_U32 PortNumber) /* Port Number */
959{
960 SK_U32 i;
961 SK_U8 Inexact;
962 SK_U16 *OutAddr;
963 SK_ADDR_PORT *pAPort;
964
965 SK_DBG_MSG(pAC,SK_DBGMOD_ADDR, SK_DBGCAT_CTRL,
966 ("SkAddrXmacMcUpdate on Port %u.\n", PortNumber))
967
968 pAPort = &pAC->Addr.Port[PortNumber];
969
970#ifdef DEBUG
971 SK_DBG_MSG(pAC,SK_DBGMOD_ADDR, SK_DBGCAT_CTRL,
972 ("Next0 on Port %d: %d\n", PortNumber, Next0[PortNumber]))
973#endif /* DEBUG */
974
975 /* Start with 0 to also program the logical MAC address. */
976 for (i = 0; i < pAPort->NextExactMatchRlmt; i++) {
977 /* Set exact match address i on XMAC */
978 OutAddr = (SK_U16 *) &pAPort->Exact[i].a[0];
979 XM_OUTADDR(IoC, PortNumber, XM_EXM(i), OutAddr);
980 }
981
982 /* Clear other permanent exact match addresses on XMAC */
983 if (pAPort->NextExactMatchRlmt <= SK_ADDR_LAST_MATCH_RLMT) {
984
985 SkXmClrExactAddr(pAC, IoC, PortNumber, pAPort->NextExactMatchRlmt,
986 SK_ADDR_LAST_MATCH_RLMT);
987 }
988
989 for (i = pAPort->FirstExactMatchDrv; i < pAPort->NextExactMatchDrv; i++) {
990 OutAddr = (SK_U16 *) &pAPort->Exact[i].a[0];
991 XM_OUTADDR(IoC, PortNumber, XM_EXM(i), OutAddr);
992 }
993
994 /* Clear other non-permanent exact match addresses on XMAC */
995 if (pAPort->NextExactMatchDrv <= SK_ADDR_LAST_MATCH_DRV) {
996
997 SkXmClrExactAddr(pAC, IoC, PortNumber, pAPort->NextExactMatchDrv,
998 SK_ADDR_LAST_MATCH_DRV);
999 }
1000
1001 for (Inexact = 0, i = 0; i < 8; i++) {
1002 Inexact |= pAPort->InexactFilter.Bytes[i];
1003 }
1004
1005 if (pAPort->PromMode & SK_PROM_MODE_ALL_MC) {
1006
1007 /* Set all bits in 64-bit hash register. */
1008 XM_OUTHASH(IoC, PortNumber, XM_HSM, &OnesHash);
1009
1010 /* Enable Hashing */
1011 SkMacHashing(pAC, IoC, (int) PortNumber, SK_TRUE);
1012 }
1013 else if (Inexact != 0) {
1014
1015 /* Set 64-bit hash register to InexactFilter. */
1016 XM_OUTHASH(IoC, PortNumber, XM_HSM, &pAPort->InexactFilter.Bytes[0]);
1017
1018 /* Enable Hashing */
1019 SkMacHashing(pAC, IoC, (int) PortNumber, SK_TRUE);
1020 }
1021 else {
1022 /* Disable Hashing */
1023 SkMacHashing(pAC, IoC, (int) PortNumber, SK_FALSE);
1024 }
1025
1026 if (pAPort->PromMode != SK_PROM_MODE_NONE) {
1027 (void) SkAddrXmacPromiscuousChange(pAC, IoC, PortNumber, pAPort->PromMode);
1028 }
1029
1030 /* Set port's current physical MAC address. */
1031 OutAddr = (SK_U16 *) &pAPort->CurrentMacAddress.a[0];
1032
1033 XM_OUTADDR(IoC, PortNumber, XM_SA, OutAddr);
1034
1035#ifdef xDEBUG
1036 for (i = 0; i < pAPort->NextExactMatchRlmt; i++) {
1037 SK_U8 InAddr8[6];
1038 SK_U16 *InAddr;
1039
1040 /* Get exact match address i from port PortNumber. */
1041 InAddr = (SK_U16 *) &InAddr8[0];
1042
1043 XM_INADDR(IoC, PortNumber, XM_EXM(i), InAddr);
1044
1045 SK_DBG_MSG(pAC,SK_DBGMOD_ADDR, SK_DBGCAT_CTRL,
1046 ("SkAddrXmacMcUpdate: MC address %d on Port %u: ",
1047 "%02x %02x %02x %02x %02x %02x -- %02x %02x %02x %02x %02x %02x\n",
1048 i,
1049 PortNumber,
1050 InAddr8[0],
1051 InAddr8[1],
1052 InAddr8[2],
1053 InAddr8[3],
1054 InAddr8[4],
1055 InAddr8[5],
1056 pAPort->Exact[i].a[0],
1057 pAPort->Exact[i].a[1],
1058 pAPort->Exact[i].a[2],
1059 pAPort->Exact[i].a[3],
1060 pAPort->Exact[i].a[4],
1061 pAPort->Exact[i].a[5]))
1062 }
1063#endif /* DEBUG */
1064
1065 /* Determine return value. */
1066 if (Inexact == 0 && pAPort->PromMode == 0) {
1067 return (SK_MC_FILTERING_EXACT);
1068 }
1069 else {
1070 return (SK_MC_FILTERING_INEXACT);
1071 }
1072
1073} /* SkAddrXmacMcUpdate */
1074
1075#endif /* GENESIS */
1076
1077#ifdef YUKON
1078
1079/******************************************************************************
1080 *
1081 * SkAddrGmacMcUpdate - update the HW MC address table and set the MAC address
1082 *
1083 * Description:
1084 * This routine enables reception of the addresses contained in a local
1085 * table for a given port.
1086 * It also programs the port's current physical MAC address.
1087 *
1088 * Notes:
1089 * The return code is only valid for SK_PROM_MODE_NONE.
1090 *
1091 * Context:
1092 * runtime, pageable
1093 * may be called after SK_INIT_IO
1094 *
1095 * Returns:
1096 * SK_MC_FILTERING_EXACT
1097 * SK_MC_FILTERING_INEXACT
1098 * SK_ADDR_ILLEGAL_PORT
1099 */
1100static int SkAddrGmacMcUpdate(
1101SK_AC *pAC, /* adapter context */
1102SK_IOC IoC, /* I/O context */
1103SK_U32 PortNumber) /* Port Number */
1104{
1105#ifndef SK_SLIM
1106 SK_U32 i;
1107 SK_U8 Inexact;
1108#endif /* not SK_SLIM */
1109 SK_U16 *OutAddr;
1110 SK_ADDR_PORT *pAPort;
1111
1112 SK_DBG_MSG(pAC,SK_DBGMOD_ADDR, SK_DBGCAT_CTRL,
1113 ("SkAddrGmacMcUpdate on Port %u.\n", PortNumber))
1114
1115 pAPort = &pAC->Addr.Port[PortNumber];
1116
1117#ifdef DEBUG
1118 SK_DBG_MSG(pAC,SK_DBGMOD_ADDR, SK_DBGCAT_CTRL,
1119 ("Next0 on Port %d: %d\n", PortNumber, Next0[PortNumber]))
1120#endif /* DEBUG */
1121
1122#ifndef SK_SLIM
1123 for (Inexact = 0, i = 0; i < 8; i++) {
1124 Inexact |= pAPort->InexactFilter.Bytes[i];
1125 }
1126
1127 /* Set 64-bit hash register to InexactFilter. */
1128 GM_OUTHASH(IoC, PortNumber, GM_MC_ADDR_H1,
1129 &pAPort->InexactFilter.Bytes[0]);
1130
1131 if (pAPort->PromMode & SK_PROM_MODE_ALL_MC) {
1132
1133 /* Set all bits in 64-bit hash register. */
1134 GM_OUTHASH(IoC, PortNumber, GM_MC_ADDR_H1, &OnesHash);
1135
1136 /* Enable Hashing */
1137 SkMacHashing(pAC, IoC, (int) PortNumber, SK_TRUE);
1138 }
1139 else {
1140 /* Enable Hashing. */
1141 SkMacHashing(pAC, IoC, (int) PortNumber, SK_TRUE);
1142 }
1143
1144 if (pAPort->PromMode != SK_PROM_MODE_NONE) {
1145 (void) SkAddrGmacPromiscuousChange(pAC, IoC, PortNumber, pAPort->PromMode);
1146 }
1147#else /* SK_SLIM */
1148
1149 /* Set all bits in 64-bit hash register. */
1150 GM_OUTHASH(IoC, PortNumber, GM_MC_ADDR_H1, &OnesHash);
1151
1152 /* Enable Hashing */
1153 SkMacHashing(pAC, IoC, (int) PortNumber, SK_TRUE);
1154
1155 (void) SkAddrGmacPromiscuousChange(pAC, IoC, PortNumber, pAPort->PromMode);
1156
1157#endif /* SK_SLIM */
1158
1159 /* Set port's current physical MAC address. */
1160 OutAddr = (SK_U16 *) &pAPort->CurrentMacAddress.a[0];
1161 GM_OUTADDR(IoC, PortNumber, GM_SRC_ADDR_1L, OutAddr);
1162
1163 /* Set port's current logical MAC address. */
1164 OutAddr = (SK_U16 *) &pAPort->Exact[0].a[0];
1165 GM_OUTADDR(IoC, PortNumber, GM_SRC_ADDR_2L, OutAddr);
1166
1167#ifdef DEBUG
1168 SK_DBG_MSG(pAC, SK_DBGMOD_ADDR, SK_DBGCAT_CTRL,
1169 ("SkAddrGmacMcUpdate: Permanent Physical MAC Address: %02X %02X %02X %02X %02X %02X\n",
1170 pAPort->Exact[0].a[0],
1171 pAPort->Exact[0].a[1],
1172 pAPort->Exact[0].a[2],
1173 pAPort->Exact[0].a[3],
1174 pAPort->Exact[0].a[4],
1175 pAPort->Exact[0].a[5]))
1176
1177 SK_DBG_MSG(pAC, SK_DBGMOD_ADDR, SK_DBGCAT_CTRL,
1178 ("SkAddrGmacMcUpdate: Physical MAC Address: %02X %02X %02X %02X %02X %02X\n",
1179 pAPort->CurrentMacAddress.a[0],
1180 pAPort->CurrentMacAddress.a[1],
1181 pAPort->CurrentMacAddress.a[2],
1182 pAPort->CurrentMacAddress.a[3],
1183 pAPort->CurrentMacAddress.a[4],
1184 pAPort->CurrentMacAddress.a[5]))
1185#endif /* DEBUG */
1186
1187#ifndef SK_SLIM
1188 /* Determine return value. */
1189 if (Inexact == 0 && pAPort->PromMode == 0) {
1190 return (SK_MC_FILTERING_EXACT);
1191 }
1192 else {
1193 return (SK_MC_FILTERING_INEXACT);
1194 }
1195#else /* SK_SLIM */
1196 return (SK_MC_FILTERING_INEXACT);
1197#endif /* SK_SLIM */
1198
1199} /* SkAddrGmacMcUpdate */
1200
1201#endif /* YUKON */
1202
1203#ifndef SK_NO_MAO
1204
1205/******************************************************************************
1206 *
1207 * SkAddrOverride - override a port's MAC address
1208 *
1209 * Description:
1210 * This routine overrides the MAC address of one port.
1211 *
1212 * Context:
1213 * runtime, pageable
1214 * may be called after SK_INIT_IO
1215 *
1216 * Returns:
1217 * SK_ADDR_SUCCESS if successful.
1218 * SK_ADDR_DUPLICATE_ADDRESS if duplicate MAC address.
1219 * SK_ADDR_MULTICAST_ADDRESS if multicast or broadcast address.
1220 * SK_ADDR_TOO_EARLY if SK_INIT_IO was not executed before.
1221 */
1222int SkAddrOverride(
1223SK_AC *pAC, /* adapter context */
1224SK_IOC IoC, /* I/O context */
1225SK_U32 PortNumber, /* Port Number */
1226SK_MAC_ADDR SK_FAR *pNewAddr, /* new MAC address */
1227int Flags) /* logical/physical MAC address */
1228{
1229#ifndef SK_NO_RLMT
1230 SK_EVPARA Para;
1231#endif /* !SK_NO_RLMT */
1232 SK_U32 NetNumber;
1233 SK_U32 i;
1234 SK_U16 SK_FAR *OutAddr;
1235
1236#ifndef SK_NO_RLMT
1237 NetNumber = pAC->Rlmt.Port[PortNumber].Net->NetNumber;
1238#else
1239 NetNumber = 0;
1240#endif /* SK_NO_RLMT */
1241#if (!defined(SK_SLIM) || defined(DEBUG))
1242 if (PortNumber >= (SK_U32) pAC->GIni.GIMacsFound) {
1243 return (SK_ADDR_ILLEGAL_PORT);
1244 }
1245#endif /* !SK_SLIM || DEBUG */
1246 if (pNewAddr != NULL && (pNewAddr->a[0] & SK_MC_BIT) != 0) {
1247 return (SK_ADDR_MULTICAST_ADDRESS);
1248 }
1249
1250 if (!pAC->Addr.Net[NetNumber].CurrentMacAddressSet) {
1251 return (SK_ADDR_TOO_EARLY);
1252 }
1253
1254 if (Flags & SK_ADDR_SET_LOGICAL) { /* Activate logical MAC address. */
1255 /* Parameter *pNewAddr is ignored. */
1256 for (i = 0; i < (SK_U32) pAC->GIni.GIMacsFound; i++) {
1257 if (!pAC->Addr.Port[i].CurrentMacAddressSet) {
1258 return (SK_ADDR_TOO_EARLY);
1259 }
1260 }
1261#ifndef SK_NO_RLMT
1262 /* Set PortNumber to number of net's active port. */
1263 PortNumber = pAC->Rlmt.Net[NetNumber].
1264 Port[pAC->Addr.Net[NetNumber].ActivePort]->PortNumber;
1265#endif /* !SK_NO_RLMT */
1266 pAC->Addr.Port[PortNumber].Exact[0] =
1267 pAC->Addr.Net[NetNumber].CurrentMacAddress;
1268
1269 /* Write address to first exact match entry of active port. */
1270 (void) SkAddrMcUpdate(pAC, IoC, PortNumber);
1271 }
1272 else if (Flags & SK_ADDR_CLEAR_LOGICAL) {
1273 /* Deactivate logical MAC address. */
1274 /* Parameter *pNewAddr is ignored. */
1275 for (i = 0; i < (SK_U32) pAC->GIni.GIMacsFound; i++) {
1276 if (!pAC->Addr.Port[i].CurrentMacAddressSet) {
1277 return (SK_ADDR_TOO_EARLY);
1278 }
1279 }
1280#ifndef SK_NO_RLMT
1281 /* Set PortNumber to number of net's active port. */
1282 PortNumber = pAC->Rlmt.Net[NetNumber].
1283 Port[pAC->Addr.Net[NetNumber].ActivePort]->PortNumber;
1284#endif /* !SK_NO_RLMT */
1285 for (i = 0; i < SK_MAC_ADDR_LEN; i++ ) {
1286 pAC->Addr.Port[PortNumber].Exact[0].a[i] = 0;
1287 }
1288
1289 /* Write address to first exact match entry of active port. */
1290 (void) SkAddrMcUpdate(pAC, IoC, PortNumber);
1291 }
1292 else if (Flags & SK_ADDR_PHYSICAL_ADDRESS) { /* Physical MAC address. */
1293 if (SK_ADDR_EQUAL(pNewAddr->a,
1294 pAC->Addr.Net[NetNumber].CurrentMacAddress.a)) {
1295 return (SK_ADDR_DUPLICATE_ADDRESS);
1296 }
1297
1298 for (i = 0; i < (SK_U32) pAC->GIni.GIMacsFound; i++) {
1299 if (!pAC->Addr.Port[i].CurrentMacAddressSet) {
1300 return (SK_ADDR_TOO_EARLY);
1301 }
1302
1303 if (SK_ADDR_EQUAL(pNewAddr->a,
1304 pAC->Addr.Port[i].CurrentMacAddress.a)) {
1305 if (i == PortNumber) {
1306 return (SK_ADDR_SUCCESS);
1307 }
1308 else {
1309 return (SK_ADDR_DUPLICATE_ADDRESS);
1310 }
1311 }
1312 }
1313
1314 pAC->Addr.Port[PortNumber].PreviousMacAddress =
1315 pAC->Addr.Port[PortNumber].CurrentMacAddress;
1316 pAC->Addr.Port[PortNumber].CurrentMacAddress = *pNewAddr;
1317
1318 /* Change port's physical MAC address. */
1319 OutAddr = (SK_U16 SK_FAR *) pNewAddr;
1320#ifdef GENESIS
1321 if (pAC->GIni.GIGenesis) {
1322 XM_OUTADDR(IoC, PortNumber, XM_SA, OutAddr);
1323 }
1324#endif /* GENESIS */
1325#ifdef YUKON
1326 if (!pAC->GIni.GIGenesis) {
1327 GM_OUTADDR(IoC, PortNumber, GM_SRC_ADDR_1L, OutAddr);
1328 }
1329#endif /* YUKON */
1330
1331#ifndef SK_NO_RLMT
1332 /* Report address change to RLMT. */
1333 Para.Para32[0] = PortNumber;
1334 Para.Para32[0] = -1;
1335 SkEventQueue(pAC, SKGE_RLMT, SK_RLMT_PORT_ADDR, Para);
1336#endif /* !SK_NO_RLMT */
1337 }
1338 else { /* Logical MAC address. */
1339 if (SK_ADDR_EQUAL(pNewAddr->a,
1340 pAC->Addr.Net[NetNumber].CurrentMacAddress.a)) {
1341 return (SK_ADDR_SUCCESS);
1342 }
1343
1344 for (i = 0; i < (SK_U32) pAC->GIni.GIMacsFound; i++) {
1345 if (!pAC->Addr.Port[i].CurrentMacAddressSet) {
1346 return (SK_ADDR_TOO_EARLY);
1347 }
1348
1349 if (SK_ADDR_EQUAL(pNewAddr->a,
1350 pAC->Addr.Port[i].CurrentMacAddress.a)) {
1351 return (SK_ADDR_DUPLICATE_ADDRESS);
1352 }
1353 }
1354
1355 /*
1356 * In case that the physical and the logical MAC addresses are equal
1357 * we must also change the physical MAC address here.
1358 * In this case we have an adapter which initially was programmed with
1359 * two identical MAC addresses.
1360 */
1361 if (SK_ADDR_EQUAL(pAC->Addr.Port[PortNumber].CurrentMacAddress.a,
1362 pAC->Addr.Port[PortNumber].Exact[0].a)) {
1363
1364 pAC->Addr.Port[PortNumber].PreviousMacAddress =
1365 pAC->Addr.Port[PortNumber].CurrentMacAddress;
1366 pAC->Addr.Port[PortNumber].CurrentMacAddress = *pNewAddr;
1367
1368#ifndef SK_NO_RLMT
1369 /* Report address change to RLMT. */
1370 Para.Para32[0] = PortNumber;
1371 Para.Para32[0] = -1;
1372 SkEventQueue(pAC, SKGE_RLMT, SK_RLMT_PORT_ADDR, Para);
1373#endif /* !SK_NO_RLMT */
1374 }
1375
1376#ifndef SK_NO_RLMT
1377 /* Set PortNumber to number of net's active port. */
1378 PortNumber = pAC->Rlmt.Net[NetNumber].
1379 Port[pAC->Addr.Net[NetNumber].ActivePort]->PortNumber;
1380#endif /* !SK_NO_RLMT */
1381 pAC->Addr.Net[NetNumber].CurrentMacAddress = *pNewAddr;
1382 pAC->Addr.Port[PortNumber].Exact[0] = *pNewAddr;
1383#ifdef DEBUG
1384 SK_DBG_MSG(pAC,SK_DBGMOD_ADDR, SK_DBGCAT_CTRL,
1385 ("SkAddrOverride: Permanent MAC Address: %02X %02X %02X %02X %02X %02X\n",
1386 pAC->Addr.Net[NetNumber].PermanentMacAddress.a[0],
1387 pAC->Addr.Net[NetNumber].PermanentMacAddress.a[1],
1388 pAC->Addr.Net[NetNumber].PermanentMacAddress.a[2],
1389 pAC->Addr.Net[NetNumber].PermanentMacAddress.a[3],
1390 pAC->Addr.Net[NetNumber].PermanentMacAddress.a[4],
1391 pAC->Addr.Net[NetNumber].PermanentMacAddress.a[5]))
1392
1393 SK_DBG_MSG(pAC,SK_DBGMOD_ADDR, SK_DBGCAT_CTRL,
1394 ("SkAddrOverride: New logical MAC Address: %02X %02X %02X %02X %02X %02X\n",
1395 pAC->Addr.Net[NetNumber].CurrentMacAddress.a[0],
1396 pAC->Addr.Net[NetNumber].CurrentMacAddress.a[1],
1397 pAC->Addr.Net[NetNumber].CurrentMacAddress.a[2],
1398 pAC->Addr.Net[NetNumber].CurrentMacAddress.a[3],
1399 pAC->Addr.Net[NetNumber].CurrentMacAddress.a[4],
1400 pAC->Addr.Net[NetNumber].CurrentMacAddress.a[5]))
1401#endif /* DEBUG */
1402
1403 /* Write address to first exact match entry of active port. */
1404 (void) SkAddrMcUpdate(pAC, IoC, PortNumber);
1405 }
1406
1407 return (SK_ADDR_SUCCESS);
1408
1409} /* SkAddrOverride */
1410
1411
1412#endif /* SK_NO_MAO */
1413
1414/******************************************************************************
1415 *
1416 * SkAddrPromiscuousChange - set promiscuous mode for given port
1417 *
1418 * Description:
1419 * This routine manages promiscuous mode:
1420 * - none
1421 * - all LLC frames
1422 * - all MC frames
1423 *
1424 * It calls either SkAddrXmacPromiscuousChange or
1425 * SkAddrGmacPromiscuousChange, according to the adapter in use.
1426 * The real work is done there.
1427 *
1428 * Context:
1429 * runtime, pageable
1430 * may be called after SK_INIT_IO
1431 *
1432 * Returns:
1433 * SK_ADDR_SUCCESS
1434 * SK_ADDR_ILLEGAL_PORT
1435 */
1436int SkAddrPromiscuousChange(
1437SK_AC *pAC, /* adapter context */
1438SK_IOC IoC, /* I/O context */
1439SK_U32 PortNumber, /* port whose promiscuous mode changes */
1440int NewPromMode) /* new promiscuous mode */
1441{
1442 int ReturnCode = 0;
1443#if (!defined(SK_SLIM) || defined(DEBUG))
1444 if (PortNumber >= (SK_U32) pAC->GIni.GIMacsFound) {
1445 return (SK_ADDR_ILLEGAL_PORT);
1446 }
1447#endif /* !SK_SLIM || DEBUG */
1448
1449#ifdef GENESIS
1450 if (pAC->GIni.GIGenesis) {
1451 ReturnCode =
1452 SkAddrXmacPromiscuousChange(pAC, IoC, PortNumber, NewPromMode);
1453 }
1454#endif /* GENESIS */
1455#ifdef YUKON
1456 if (!pAC->GIni.GIGenesis) {
1457 ReturnCode =
1458 SkAddrGmacPromiscuousChange(pAC, IoC, PortNumber, NewPromMode);
1459 }
1460#endif /* YUKON */
1461
1462 return (ReturnCode);
1463
1464} /* SkAddrPromiscuousChange */
1465
1466#ifdef GENESIS
1467
1468/******************************************************************************
1469 *
1470 * SkAddrXmacPromiscuousChange - set promiscuous mode for given port
1471 *
1472 * Description:
1473 * This routine manages promiscuous mode:
1474 * - none
1475 * - all LLC frames
1476 * - all MC frames
1477 *
1478 * Context:
1479 * runtime, pageable
1480 * may be called after SK_INIT_IO
1481 *
1482 * Returns:
1483 * SK_ADDR_SUCCESS
1484 * SK_ADDR_ILLEGAL_PORT
1485 */
1486static int SkAddrXmacPromiscuousChange(
1487SK_AC *pAC, /* adapter context */
1488SK_IOC IoC, /* I/O context */
1489SK_U32 PortNumber, /* port whose promiscuous mode changes */
1490int NewPromMode) /* new promiscuous mode */
1491{
1492 int i;
1493 SK_BOOL InexactModeBit;
1494 SK_U8 Inexact;
1495 SK_U8 HwInexact;
1496 SK_FILTER64 HwInexactFilter;
1497 SK_U16 LoMode; /* Lower 16 bits of XMAC Mode Register. */
1498 int CurPromMode = SK_PROM_MODE_NONE;
1499
1500 /* Read CurPromMode from Hardware. */
1501 XM_IN16(IoC, PortNumber, XM_MODE, &LoMode);
1502
1503 if ((LoMode & XM_MD_ENA_PROM) != 0) {
1504 /* Promiscuous mode! */
1505 CurPromMode |= SK_PROM_MODE_LLC;
1506 }
1507
1508 for (Inexact = 0xFF, i = 0; i < 8; i++) {
1509 Inexact &= pAC->Addr.Port[PortNumber].InexactFilter.Bytes[i];
1510 }
1511 if (Inexact == 0xFF) {
1512 CurPromMode |= (pAC->Addr.Port[PortNumber].PromMode & SK_PROM_MODE_ALL_MC);
1513 }
1514 else {
1515 /* Get InexactModeBit (bit XM_MD_ENA_HASH in mode register) */
1516 XM_IN16(IoC, PortNumber, XM_MODE, &LoMode);
1517
1518 InexactModeBit = (LoMode & XM_MD_ENA_HASH) != 0;
1519
1520 /* Read 64-bit hash register from XMAC */
1521 XM_INHASH(IoC, PortNumber, XM_HSM, &HwInexactFilter.Bytes[0]);
1522
1523 for (HwInexact = 0xFF, i = 0; i < 8; i++) {
1524 HwInexact &= HwInexactFilter.Bytes[i];
1525 }
1526
1527 if (InexactModeBit && (HwInexact == 0xFF)) {
1528 CurPromMode |= SK_PROM_MODE_ALL_MC;
1529 }
1530 }
1531
1532 pAC->Addr.Port[PortNumber].PromMode = NewPromMode;
1533
1534 if (NewPromMode == CurPromMode) {
1535 return (SK_ADDR_SUCCESS);
1536 }
1537
1538 if ((NewPromMode & SK_PROM_MODE_ALL_MC) &&
1539 !(CurPromMode & SK_PROM_MODE_ALL_MC)) { /* All MC. */
1540
1541 /* Set all bits in 64-bit hash register. */
1542 XM_OUTHASH(IoC, PortNumber, XM_HSM, &OnesHash);
1543
1544 /* Enable Hashing */
1545 SkMacHashing(pAC, IoC, (int) PortNumber, SK_TRUE);
1546 }
1547 else if ((CurPromMode & SK_PROM_MODE_ALL_MC) &&
1548 !(NewPromMode & SK_PROM_MODE_ALL_MC)) { /* Norm MC. */
1549 for (Inexact = 0, i = 0; i < 8; i++) {
1550 Inexact |= pAC->Addr.Port[PortNumber].InexactFilter.Bytes[i];
1551 }
1552 if (Inexact == 0) {
1553 /* Disable Hashing */
1554 SkMacHashing(pAC, IoC, (int) PortNumber, SK_FALSE);
1555 }
1556 else {
1557 /* Set 64-bit hash register to InexactFilter. */
1558 XM_OUTHASH(IoC, PortNumber, XM_HSM,
1559 &pAC->Addr.Port[PortNumber].InexactFilter.Bytes[0]);
1560
1561 /* Enable Hashing */
1562 SkMacHashing(pAC, IoC, (int) PortNumber, SK_TRUE);
1563 }
1564 }
1565
1566 if ((NewPromMode & SK_PROM_MODE_LLC) &&
1567 !(CurPromMode & SK_PROM_MODE_LLC)) { /* Prom. LLC */
1568 /* Set the MAC in Promiscuous Mode */
1569 SkMacPromiscMode(pAC, IoC, (int) PortNumber, SK_TRUE);
1570 }
1571 else if ((CurPromMode & SK_PROM_MODE_LLC) &&
1572 !(NewPromMode & SK_PROM_MODE_LLC)) { /* Norm. LLC. */
1573 /* Clear Promiscuous Mode */
1574 SkMacPromiscMode(pAC, IoC, (int) PortNumber, SK_FALSE);
1575 }
1576
1577 return (SK_ADDR_SUCCESS);
1578
1579} /* SkAddrXmacPromiscuousChange */
1580
1581#endif /* GENESIS */
1582
1583#ifdef YUKON
1584
1585/******************************************************************************
1586 *
1587 * SkAddrGmacPromiscuousChange - set promiscuous mode for given port
1588 *
1589 * Description:
1590 * This routine manages promiscuous mode:
1591 * - none
1592 * - all LLC frames
1593 * - all MC frames
1594 *
1595 * Context:
1596 * runtime, pageable
1597 * may be called after SK_INIT_IO
1598 *
1599 * Returns:
1600 * SK_ADDR_SUCCESS
1601 * SK_ADDR_ILLEGAL_PORT
1602 */
1603static int SkAddrGmacPromiscuousChange(
1604SK_AC *pAC, /* adapter context */
1605SK_IOC IoC, /* I/O context */
1606SK_U32 PortNumber, /* port whose promiscuous mode changes */
1607int NewPromMode) /* new promiscuous mode */
1608{
1609 SK_U16 ReceiveControl; /* GMAC Receive Control Register */
1610 int CurPromMode = SK_PROM_MODE_NONE;
1611
1612 /* Read CurPromMode from Hardware. */
1613 GM_IN16(IoC, PortNumber, GM_RX_CTRL, &ReceiveControl);
1614
1615 if ((ReceiveControl & (GM_RXCR_UCF_ENA | GM_RXCR_MCF_ENA)) == 0) {
1616 /* Promiscuous mode! */
1617 CurPromMode |= SK_PROM_MODE_LLC;
1618 }
1619
1620 if ((ReceiveControl & GM_RXCR_MCF_ENA) == 0) {
1621 /* All Multicast mode! */
1622 CurPromMode |= (pAC->Addr.Port[PortNumber].PromMode & SK_PROM_MODE_ALL_MC);
1623 }
1624
1625 pAC->Addr.Port[PortNumber].PromMode = NewPromMode;
1626
1627 if (NewPromMode == CurPromMode) {
1628 return (SK_ADDR_SUCCESS);
1629 }
1630
1631 if ((NewPromMode & SK_PROM_MODE_ALL_MC) &&
1632 !(CurPromMode & SK_PROM_MODE_ALL_MC)) { /* All MC */
1633
1634 /* Set all bits in 64-bit hash register. */
1635 GM_OUTHASH(IoC, PortNumber, GM_MC_ADDR_H1, &OnesHash);
1636
1637 /* Enable Hashing */
1638 SkMacHashing(pAC, IoC, (int) PortNumber, SK_TRUE);
1639 }
1640
1641 if ((CurPromMode & SK_PROM_MODE_ALL_MC) &&
1642 !(NewPromMode & SK_PROM_MODE_ALL_MC)) { /* Norm. MC */
1643
1644 /* Set 64-bit hash register to InexactFilter. */
1645 GM_OUTHASH(IoC, PortNumber, GM_MC_ADDR_H1,
1646 &pAC->Addr.Port[PortNumber].InexactFilter.Bytes[0]);
1647
1648 /* Enable Hashing. */
1649 SkMacHashing(pAC, IoC, (int) PortNumber, SK_TRUE);
1650 }
1651
1652 if ((NewPromMode & SK_PROM_MODE_LLC) &&
1653 !(CurPromMode & SK_PROM_MODE_LLC)) { /* Prom. LLC */
1654
1655 /* Set the MAC to Promiscuous Mode. */
1656 SkMacPromiscMode(pAC, IoC, (int) PortNumber, SK_TRUE);
1657 }
1658 else if ((CurPromMode & SK_PROM_MODE_LLC) &&
1659 !(NewPromMode & SK_PROM_MODE_LLC)) { /* Norm. LLC */
1660
1661 /* Clear Promiscuous Mode. */
1662 SkMacPromiscMode(pAC, IoC, (int) PortNumber, SK_FALSE);
1663 }
1664
1665 return (SK_ADDR_SUCCESS);
1666
1667} /* SkAddrGmacPromiscuousChange */
1668
1669#endif /* YUKON */
1670
1671#ifndef SK_SLIM
1672
1673/******************************************************************************
1674 *
1675 * SkAddrSwap - swap address info
1676 *
1677 * Description:
1678 * This routine swaps address info of two ports.
1679 *
1680 * Context:
1681 * runtime, pageable
1682 * may be called after SK_INIT_IO
1683 *
1684 * Returns:
1685 * SK_ADDR_SUCCESS
1686 * SK_ADDR_ILLEGAL_PORT
1687 */
1688int SkAddrSwap(
1689SK_AC *pAC, /* adapter context */
1690SK_IOC IoC, /* I/O context */
1691SK_U32 FromPortNumber, /* Port1 Index */
1692SK_U32 ToPortNumber) /* Port2 Index */
1693{
1694 int i;
1695 SK_U8 Byte;
1696 SK_MAC_ADDR MacAddr;
1697 SK_U32 DWord;
1698
1699 if (FromPortNumber >= (SK_U32) pAC->GIni.GIMacsFound) {
1700 return (SK_ADDR_ILLEGAL_PORT);
1701 }
1702
1703 if (ToPortNumber >= (SK_U32) pAC->GIni.GIMacsFound) {
1704 return (SK_ADDR_ILLEGAL_PORT);
1705 }
1706
1707 if (pAC->Rlmt.Port[FromPortNumber].Net != pAC->Rlmt.Port[ToPortNumber].Net) {
1708 return (SK_ADDR_ILLEGAL_PORT);
1709 }
1710
1711 /*
1712 * Swap:
1713 * - Exact Match Entries (GEnesis and Yukon)
1714 * Yukon uses first entry for the logical MAC
1715 * address (stored in the second GMAC register).
1716 * - FirstExactMatchRlmt (GEnesis only)
1717 * - NextExactMatchRlmt (GEnesis only)
1718 * - FirstExactMatchDrv (GEnesis only)
1719 * - NextExactMatchDrv (GEnesis only)
1720 * - 64-bit filter (InexactFilter)
1721 * - Promiscuous Mode
1722 * of ports.
1723 */
1724
1725 for (i = 0; i < SK_ADDR_EXACT_MATCHES; i++) {
1726 MacAddr = pAC->Addr.Port[FromPortNumber].Exact[i];
1727 pAC->Addr.Port[FromPortNumber].Exact[i] =
1728 pAC->Addr.Port[ToPortNumber].Exact[i];
1729 pAC->Addr.Port[ToPortNumber].Exact[i] = MacAddr;
1730 }
1731
1732 for (i = 0; i < 8; i++) {
1733 Byte = pAC->Addr.Port[FromPortNumber].InexactFilter.Bytes[i];
1734 pAC->Addr.Port[FromPortNumber].InexactFilter.Bytes[i] =
1735 pAC->Addr.Port[ToPortNumber].InexactFilter.Bytes[i];
1736 pAC->Addr.Port[ToPortNumber].InexactFilter.Bytes[i] = Byte;
1737 }
1738
1739 i = pAC->Addr.Port[FromPortNumber].PromMode;
1740 pAC->Addr.Port[FromPortNumber].PromMode = pAC->Addr.Port[ToPortNumber].PromMode;
1741 pAC->Addr.Port[ToPortNumber].PromMode = i;
1742
1743 if (pAC->GIni.GIGenesis) {
1744 DWord = pAC->Addr.Port[FromPortNumber].FirstExactMatchRlmt;
1745 pAC->Addr.Port[FromPortNumber].FirstExactMatchRlmt =
1746 pAC->Addr.Port[ToPortNumber].FirstExactMatchRlmt;
1747 pAC->Addr.Port[ToPortNumber].FirstExactMatchRlmt = DWord;
1748
1749 DWord = pAC->Addr.Port[FromPortNumber].NextExactMatchRlmt;
1750 pAC->Addr.Port[FromPortNumber].NextExactMatchRlmt =
1751 pAC->Addr.Port[ToPortNumber].NextExactMatchRlmt;
1752 pAC->Addr.Port[ToPortNumber].NextExactMatchRlmt = DWord;
1753
1754 DWord = pAC->Addr.Port[FromPortNumber].FirstExactMatchDrv;
1755 pAC->Addr.Port[FromPortNumber].FirstExactMatchDrv =
1756 pAC->Addr.Port[ToPortNumber].FirstExactMatchDrv;
1757 pAC->Addr.Port[ToPortNumber].FirstExactMatchDrv = DWord;
1758
1759 DWord = pAC->Addr.Port[FromPortNumber].NextExactMatchDrv;
1760 pAC->Addr.Port[FromPortNumber].NextExactMatchDrv =
1761 pAC->Addr.Port[ToPortNumber].NextExactMatchDrv;
1762 pAC->Addr.Port[ToPortNumber].NextExactMatchDrv = DWord;
1763 }
1764
1765 /* CAUTION: Solution works if only ports of one adapter are in use. */
1766 for (i = 0; (SK_U32) i < pAC->Rlmt.Net[pAC->Rlmt.Port[ToPortNumber].
1767 Net->NetNumber].NumPorts; i++) {
1768 if (pAC->Rlmt.Net[pAC->Rlmt.Port[ToPortNumber].Net->NetNumber].
1769 Port[i]->PortNumber == ToPortNumber) {
1770 pAC->Addr.Net[pAC->Rlmt.Port[ToPortNumber].Net->NetNumber].
1771 ActivePort = i;
1772 /* 20001207 RA: Was "ToPortNumber;". */
1773 }
1774 }
1775
1776 (void) SkAddrMcUpdate(pAC, IoC, FromPortNumber);
1777 (void) SkAddrMcUpdate(pAC, IoC, ToPortNumber);
1778
1779 return (SK_ADDR_SUCCESS);
1780
1781} /* SkAddrSwap */
1782
1783#endif /* !SK_SLIM */
1784
1785#ifdef __cplusplus
1786}
1787#endif /* __cplusplus */
1788
diff --git a/drivers/net/sk98lin/skdim.c b/drivers/net/sk98lin/skdim.c
new file mode 100644
index 000000000000..37ce03fb8de3
--- /dev/null
+++ b/drivers/net/sk98lin/skdim.c
@@ -0,0 +1,742 @@
1/******************************************************************************
2 *
3 * Name: skdim.c
4 * Project: GEnesis, PCI Gigabit Ethernet Adapter
5 * Version: $Revision: 1.5 $
6 * Date: $Date: 2003/11/28 12:55:40 $
7 * Purpose: All functions to maintain interrupt moderation
8 *
9 ******************************************************************************/
10
11/******************************************************************************
12 *
13 * (C)Copyright 1998-2002 SysKonnect GmbH.
14 * (C)Copyright 2002-2003 Marvell.
15 *
16 * This program is free software; you can redistribute it and/or modify
17 * it under the terms of the GNU General Public License as published by
18 * the Free Software Foundation; either version 2 of the License, or
19 * (at your option) any later version.
20 *
21 * The information in this file is provided "AS IS" without warranty.
22 *
23 ******************************************************************************/
24
25/******************************************************************************
26 *
27 * Description:
28 *
29 * This module is intended to manage the dynamic interrupt moderation on both
30 * GEnesis and Yukon adapters.
31 *
32 * Include File Hierarchy:
33 *
34 * "skdrv1st.h"
35 * "skdrv2nd.h"
36 *
37 ******************************************************************************/
38
39#ifndef lint
40static const char SysKonnectFileId[] =
41 "@(#) $Id: skdim.c,v 1.5 2003/11/28 12:55:40 rroesler Exp $ (C) SysKonnect.";
42#endif
43
44#define __SKADDR_C
45
46#ifdef __cplusplus
47#error C++ is not yet supported.
48extern "C" {
49#endif
50
51/*******************************************************************************
52**
53** Includes
54**
55*******************************************************************************/
56
57#ifndef __INC_SKDRV1ST_H
58#include "h/skdrv1st.h"
59#endif
60
61#ifndef __INC_SKDRV2ND_H
62#include "h/skdrv2nd.h"
63#endif
64
65#include <linux/kernel_stat.h>
66
67/*******************************************************************************
68**
69** Defines
70**
71*******************************************************************************/
72
73/*******************************************************************************
74**
75** Typedefs
76**
77*******************************************************************************/
78
79/*******************************************************************************
80**
81** Local function prototypes
82**
83*******************************************************************************/
84
85static unsigned int GetCurrentSystemLoad(SK_AC *pAC);
86static SK_U64 GetIsrCalls(SK_AC *pAC);
87static SK_BOOL IsIntModEnabled(SK_AC *pAC);
88static void SetCurrIntCtr(SK_AC *pAC);
89static void EnableIntMod(SK_AC *pAC);
90static void DisableIntMod(SK_AC *pAC);
91static void ResizeDimTimerDuration(SK_AC *pAC);
92static void DisplaySelectedModerationType(SK_AC *pAC);
93static void DisplaySelectedModerationMask(SK_AC *pAC);
94static void DisplayDescrRatio(SK_AC *pAC);
95
96/*******************************************************************************
97**
98** Global variables
99**
100*******************************************************************************/
101
102/*******************************************************************************
103**
104** Local variables
105**
106*******************************************************************************/
107
108/*******************************************************************************
109**
110** Global functions
111**
112*******************************************************************************/
113
114/*******************************************************************************
115** Function : SkDimModerate
116** Description : Called in every ISR to check if moderation is to be applied
117** or not for the current number of interrupts
118** Programmer : Ralph Roesler
119** Last Modified: 22-mar-03
120** Returns : void (!)
121** Notes : -
122*******************************************************************************/
123
124void
125SkDimModerate(SK_AC *pAC) {
126 unsigned int CurrSysLoad = 0; /* expressed in percent */
127 unsigned int LoadIncrease = 0; /* expressed in percent */
128 SK_U64 ThresholdInts = 0;
129 SK_U64 IsrCallsPerSec = 0;
130
131#define M_DIMINFO pAC->DynIrqModInfo
132
133 if (!IsIntModEnabled(pAC)) {
134 if (M_DIMINFO.IntModTypeSelect == C_INT_MOD_DYNAMIC) {
135 CurrSysLoad = GetCurrentSystemLoad(pAC);
136 if (CurrSysLoad > 75) {
137 /*
138 ** More than 75% total system load! Enable the moderation
139 ** to shield the system against too many interrupts.
140 */
141 EnableIntMod(pAC);
142 } else if (CurrSysLoad > M_DIMINFO.PrevSysLoad) {
143 LoadIncrease = (CurrSysLoad - M_DIMINFO.PrevSysLoad);
144 if (LoadIncrease > ((M_DIMINFO.PrevSysLoad *
145 C_INT_MOD_ENABLE_PERCENTAGE) / 100)) {
146 if (CurrSysLoad > 10) {
147 /*
148 ** More than 50% increase with respect to the
149 ** previous load of the system. Most likely this
150 ** is due to our ISR-proc...
151 */
152 EnableIntMod(pAC);
153 }
154 }
155 } else {
156 /*
157 ** Neither too much system load at all nor too much increase
158 ** with respect to the previous system load. Hence, we can leave
159 ** the ISR-handling like it is without enabling moderation.
160 */
161 }
162 M_DIMINFO.PrevSysLoad = CurrSysLoad;
163 }
164 } else {
165 if (M_DIMINFO.IntModTypeSelect == C_INT_MOD_DYNAMIC) {
166 ThresholdInts = ((M_DIMINFO.MaxModIntsPerSec *
167 C_INT_MOD_DISABLE_PERCENTAGE) / 100);
168 IsrCallsPerSec = GetIsrCalls(pAC);
169 if (IsrCallsPerSec <= ThresholdInts) {
170 /*
171 ** The number of interrupts within the last second is
172 ** lower than the disable_percentage of the desried
173 ** maxrate. Therefore we can disable the moderation.
174 */
175 DisableIntMod(pAC);
176 M_DIMINFO.MaxModIntsPerSec =
177 (M_DIMINFO.MaxModIntsPerSecUpperLimit +
178 M_DIMINFO.MaxModIntsPerSecLowerLimit) / 2;
179 } else {
180 /*
181 ** The number of interrupts per sec is the same as expected.
182 ** Evalulate the descriptor-ratio. If it has changed, a resize
183 ** in the moderation timer might be useful
184 */
185 if (M_DIMINFO.AutoSizing) {
186 ResizeDimTimerDuration(pAC);
187 }
188 }
189 }
190 }
191
192 /*
193 ** Some information to the log...
194 */
195 if (M_DIMINFO.DisplayStats) {
196 DisplaySelectedModerationType(pAC);
197 DisplaySelectedModerationMask(pAC);
198 DisplayDescrRatio(pAC);
199 }
200
201 M_DIMINFO.NbrProcessedDescr = 0;
202 SetCurrIntCtr(pAC);
203}
204
205/*******************************************************************************
206** Function : SkDimStartModerationTimer
207** Description : Starts the audit-timer for the dynamic interrupt moderation
208** Programmer : Ralph Roesler
209** Last Modified: 22-mar-03
210** Returns : void (!)
211** Notes : -
212*******************************************************************************/
213
214void
215SkDimStartModerationTimer(SK_AC *pAC) {
216 SK_EVPARA EventParam; /* Event struct for timer event */
217
218 SK_MEMSET((char *) &EventParam, 0, sizeof(EventParam));
219 EventParam.Para32[0] = SK_DRV_MODERATION_TIMER;
220 SkTimerStart(pAC, pAC->IoBase, &pAC->DynIrqModInfo.ModTimer,
221 SK_DRV_MODERATION_TIMER_LENGTH,
222 SKGE_DRV, SK_DRV_TIMER, EventParam);
223}
224
225/*******************************************************************************
226** Function : SkDimEnableModerationIfNeeded
227** Description : Either enables or disables moderation
228** Programmer : Ralph Roesler
229** Last Modified: 22-mar-03
230** Returns : void (!)
231** Notes : This function is called when a particular adapter is opened
232** There is no Disable function, because when all interrupts
233** might be disable, the moderation timer has no meaning at all
234******************************************************************************/
235
236void
237SkDimEnableModerationIfNeeded(SK_AC *pAC) {
238
239 if (M_DIMINFO.IntModTypeSelect == C_INT_MOD_STATIC) {
240 EnableIntMod(pAC); /* notification print in this function */
241 } else if (M_DIMINFO.IntModTypeSelect == C_INT_MOD_DYNAMIC) {
242 SkDimStartModerationTimer(pAC);
243 if (M_DIMINFO.DisplayStats) {
244 printk("Dynamic moderation has been enabled\n");
245 }
246 } else {
247 if (M_DIMINFO.DisplayStats) {
248 printk("No moderation has been enabled\n");
249 }
250 }
251}
252
253/*******************************************************************************
254** Function : SkDimDisplayModerationSettings
255** Description : Displays the current settings regarding interrupt moderation
256** Programmer : Ralph Roesler
257** Last Modified: 22-mar-03
258** Returns : void (!)
259** Notes : -
260*******************************************************************************/
261
262void
263SkDimDisplayModerationSettings(SK_AC *pAC) {
264 DisplaySelectedModerationType(pAC);
265 DisplaySelectedModerationMask(pAC);
266}
267
268/*******************************************************************************
269**
270** Local functions
271**
272*******************************************************************************/
273
274/*******************************************************************************
275** Function : GetCurrentSystemLoad
276** Description : Retrieves the current system load of the system. This load
277** is evaluated for all processors within the system.
278** Programmer : Ralph Roesler
279** Last Modified: 22-mar-03
280** Returns : unsigned int: load expressed in percentage
281** Notes : The possible range being returned is from 0 up to 100.
282** Whereas 0 means 'no load at all' and 100 'system fully loaded'
283** It is impossible to determine what actually causes the system
284** to be in 100%, but maybe that is due to too much interrupts.
285*******************************************************************************/
286
287static unsigned int
288GetCurrentSystemLoad(SK_AC *pAC) {
289 unsigned long jif = jiffies;
290 unsigned int UserTime = 0;
291 unsigned int SystemTime = 0;
292 unsigned int NiceTime = 0;
293 unsigned int IdleTime = 0;
294 unsigned int TotalTime = 0;
295 unsigned int UsedTime = 0;
296 unsigned int SystemLoad = 0;
297
298 /* unsigned int NbrCpu = 0; */
299
300 /*
301 ** The following lines have been commented out, because
302 ** from kernel 2.5.44 onwards, the kernel-owned structure
303 **
304 ** struct kernel_stat kstat
305 **
306 ** is not marked as an exported symbol in the file
307 **
308 ** kernel/ksyms.c
309 **
310 ** As a consequence, using this driver as KLM is not possible
311 ** and any access of the structure kernel_stat via the
312 ** dedicated macros kstat_cpu(i).cpustat.xxx is to be avoided.
313 **
314 ** The kstat-information might be added again in future
315 ** versions of the 2.5.xx kernel, but for the time being,
316 ** number of interrupts will serve as indication how much
317 ** load we currently have...
318 **
319 ** for (NbrCpu = 0; NbrCpu < num_online_cpus(); NbrCpu++) {
320 ** UserTime = UserTime + kstat_cpu(NbrCpu).cpustat.user;
321 ** NiceTime = NiceTime + kstat_cpu(NbrCpu).cpustat.nice;
322 ** SystemTime = SystemTime + kstat_cpu(NbrCpu).cpustat.system;
323 ** }
324 */
325 SK_U64 ThresholdInts = 0;
326 SK_U64 IsrCallsPerSec = 0;
327
328 ThresholdInts = ((M_DIMINFO.MaxModIntsPerSec *
329 C_INT_MOD_ENABLE_PERCENTAGE) + 100);
330 IsrCallsPerSec = GetIsrCalls(pAC);
331 if (IsrCallsPerSec >= ThresholdInts) {
332 /*
333 ** We do not know how much the real CPU-load is!
334 ** Return 80% as a default in order to activate DIM
335 */
336 SystemLoad = 80;
337 return (SystemLoad);
338 }
339
340 UsedTime = UserTime + NiceTime + SystemTime;
341
342 IdleTime = jif * num_online_cpus() - UsedTime;
343 TotalTime = UsedTime + IdleTime;
344
345 SystemLoad = ( 100 * (UsedTime - M_DIMINFO.PrevUsedTime) ) /
346 (TotalTime - M_DIMINFO.PrevTotalTime);
347
348 if (M_DIMINFO.DisplayStats) {
349 printk("Current system load is: %u\n", SystemLoad);
350 }
351
352 M_DIMINFO.PrevTotalTime = TotalTime;
353 M_DIMINFO.PrevUsedTime = UsedTime;
354
355 return (SystemLoad);
356}
357
358/*******************************************************************************
359** Function : GetIsrCalls
360** Description : Depending on the selected moderation mask, this function will
361** return the number of interrupts handled in the previous time-
362** frame. This evaluated number is based on the current number
363** of interrupts stored in PNMI-context and the previous stored
364** interrupts.
365** Programmer : Ralph Roesler
366** Last Modified: 23-mar-03
367** Returns : int: the number of interrupts being executed in the last
368** timeframe
369** Notes : It makes only sense to call this function, when dynamic
370** interrupt moderation is applied
371*******************************************************************************/
372
373static SK_U64
374GetIsrCalls(SK_AC *pAC) {
375 SK_U64 RxPort0IntDiff = 0;
376 SK_U64 RxPort1IntDiff = 0;
377 SK_U64 TxPort0IntDiff = 0;
378 SK_U64 TxPort1IntDiff = 0;
379
380 if (pAC->DynIrqModInfo.MaskIrqModeration == IRQ_MASK_TX_ONLY) {
381 if (pAC->GIni.GIMacsFound == 2) {
382 TxPort1IntDiff = pAC->Pnmi.Port[1].TxIntrCts -
383 pAC->DynIrqModInfo.PrevPort1TxIntrCts;
384 }
385 TxPort0IntDiff = pAC->Pnmi.Port[0].TxIntrCts -
386 pAC->DynIrqModInfo.PrevPort0TxIntrCts;
387 } else if (pAC->DynIrqModInfo.MaskIrqModeration == IRQ_MASK_RX_ONLY) {
388 if (pAC->GIni.GIMacsFound == 2) {
389 RxPort1IntDiff = pAC->Pnmi.Port[1].RxIntrCts -
390 pAC->DynIrqModInfo.PrevPort1RxIntrCts;
391 }
392 RxPort0IntDiff = pAC->Pnmi.Port[0].RxIntrCts -
393 pAC->DynIrqModInfo.PrevPort0RxIntrCts;
394 } else {
395 if (pAC->GIni.GIMacsFound == 2) {
396 RxPort1IntDiff = pAC->Pnmi.Port[1].RxIntrCts -
397 pAC->DynIrqModInfo.PrevPort1RxIntrCts;
398 TxPort1IntDiff = pAC->Pnmi.Port[1].TxIntrCts -
399 pAC->DynIrqModInfo.PrevPort1TxIntrCts;
400 }
401 RxPort0IntDiff = pAC->Pnmi.Port[0].RxIntrCts -
402 pAC->DynIrqModInfo.PrevPort0RxIntrCts;
403 TxPort0IntDiff = pAC->Pnmi.Port[0].TxIntrCts -
404 pAC->DynIrqModInfo.PrevPort0TxIntrCts;
405 }
406
407 return (RxPort0IntDiff + RxPort1IntDiff + TxPort0IntDiff + TxPort1IntDiff);
408}
409
410/*******************************************************************************
411** Function : GetRxCalls
412** Description : This function will return the number of times a receive inter-
413** rupt was processed. This is needed to evaluate any resizing
414** factor.
415** Programmer : Ralph Roesler
416** Last Modified: 23-mar-03
417** Returns : SK_U64: the number of RX-ints being processed
418** Notes : It makes only sense to call this function, when dynamic
419** interrupt moderation is applied
420*******************************************************************************/
421
422static SK_U64
423GetRxCalls(SK_AC *pAC) {
424 SK_U64 RxPort0IntDiff = 0;
425 SK_U64 RxPort1IntDiff = 0;
426
427 if (pAC->GIni.GIMacsFound == 2) {
428 RxPort1IntDiff = pAC->Pnmi.Port[1].RxIntrCts -
429 pAC->DynIrqModInfo.PrevPort1RxIntrCts;
430 }
431 RxPort0IntDiff = pAC->Pnmi.Port[0].RxIntrCts -
432 pAC->DynIrqModInfo.PrevPort0RxIntrCts;
433
434 return (RxPort0IntDiff + RxPort1IntDiff);
435}
436
437/*******************************************************************************
438** Function : SetCurrIntCtr
439** Description : Will store the current number orf occured interrupts in the
440** adapter context. This is needed to evaluated the number of
441** interrupts within a current timeframe.
442** Programmer : Ralph Roesler
443** Last Modified: 23-mar-03
444** Returns : void (!)
445** Notes : -
446*******************************************************************************/
447
448static void
449SetCurrIntCtr(SK_AC *pAC) {
450 if (pAC->GIni.GIMacsFound == 2) {
451 pAC->DynIrqModInfo.PrevPort1RxIntrCts = pAC->Pnmi.Port[1].RxIntrCts;
452 pAC->DynIrqModInfo.PrevPort1TxIntrCts = pAC->Pnmi.Port[1].TxIntrCts;
453 }
454 pAC->DynIrqModInfo.PrevPort0RxIntrCts = pAC->Pnmi.Port[0].RxIntrCts;
455 pAC->DynIrqModInfo.PrevPort0TxIntrCts = pAC->Pnmi.Port[0].TxIntrCts;
456}
457
458/*******************************************************************************
459** Function : IsIntModEnabled()
460** Description : Retrieves the current value of the interrupts moderation
461** command register. Its content determines whether any
462** moderation is running or not.
463** Programmer : Ralph Roesler
464** Last Modified: 23-mar-03
465** Returns : SK_TRUE : if mod timer running
466** SK_FALSE : if no moderation is being performed
467** Notes : -
468*******************************************************************************/
469
470static SK_BOOL
471IsIntModEnabled(SK_AC *pAC) {
472 unsigned long CtrCmd;
473
474 SK_IN32(pAC->IoBase, B2_IRQM_CTRL, &CtrCmd);
475 if ((CtrCmd & TIM_START) == TIM_START) {
476 return SK_TRUE;
477 } else {
478 return SK_FALSE;
479 }
480}
481
482/*******************************************************************************
483** Function : EnableIntMod()
484** Description : Enables the interrupt moderation using the values stored in
485** in the pAC->DynIntMod data structure
486** Programmer : Ralph Roesler
487** Last Modified: 22-mar-03
488** Returns : -
489** Notes : -
490*******************************************************************************/
491
492static void
493EnableIntMod(SK_AC *pAC) {
494 unsigned long ModBase;
495
496 if (pAC->GIni.GIChipId == CHIP_ID_GENESIS) {
497 ModBase = C_CLK_FREQ_GENESIS / pAC->DynIrqModInfo.MaxModIntsPerSec;
498 } else {
499 ModBase = C_CLK_FREQ_YUKON / pAC->DynIrqModInfo.MaxModIntsPerSec;
500 }
501
502 SK_OUT32(pAC->IoBase, B2_IRQM_INI, ModBase);
503 SK_OUT32(pAC->IoBase, B2_IRQM_MSK, pAC->DynIrqModInfo.MaskIrqModeration);
504 SK_OUT32(pAC->IoBase, B2_IRQM_CTRL, TIM_START);
505 if (M_DIMINFO.DisplayStats) {
506 printk("Enabled interrupt moderation (%i ints/sec)\n",
507 M_DIMINFO.MaxModIntsPerSec);
508 }
509}
510
511/*******************************************************************************
512** Function : DisableIntMod()
513** Description : Disables the interrupt moderation independent of what inter-
514** rupts are running or not
515** Programmer : Ralph Roesler
516** Last Modified: 23-mar-03
517** Returns : -
518** Notes : -
519*******************************************************************************/
520
521static void
522DisableIntMod(SK_AC *pAC) {
523
524 SK_OUT32(pAC->IoBase, B2_IRQM_CTRL, TIM_STOP);
525 if (M_DIMINFO.DisplayStats) {
526 printk("Disabled interrupt moderation\n");
527 }
528}
529
530/*******************************************************************************
531** Function : ResizeDimTimerDuration();
532** Description : Checks the current used descriptor ratio and resizes the
533** duration timer (longer/smaller) if possible.
534** Programmer : Ralph Roesler
535** Last Modified: 23-mar-03
536** Returns : -
537** Notes : There are both maximum and minimum timer duration value.
538** This function assumes that interrupt moderation is already
539** enabled!
540*******************************************************************************/
541
542static void
543ResizeDimTimerDuration(SK_AC *pAC) {
544 SK_BOOL IncreaseTimerDuration;
545 int TotalMaxNbrDescr;
546 int UsedDescrRatio;
547 int RatioDiffAbs;
548 int RatioDiffRel;
549 int NewMaxModIntsPerSec;
550 int ModAdjValue;
551 long ModBase;
552
553 /*
554 ** Check first if we are allowed to perform any modification
555 */
556 if (IsIntModEnabled(pAC)) {
557 if (M_DIMINFO.IntModTypeSelect != C_INT_MOD_DYNAMIC) {
558 return;
559 } else {
560 if (M_DIMINFO.ModJustEnabled) {
561 M_DIMINFO.ModJustEnabled = SK_FALSE;
562 return;
563 }
564 }
565 }
566
567 /*
568 ** If we got until here, we have to evaluate the amount of the
569 ** descriptor ratio change...
570 */
571 TotalMaxNbrDescr = pAC->RxDescrPerRing * GetRxCalls(pAC);
572 UsedDescrRatio = (M_DIMINFO.NbrProcessedDescr * 100) / TotalMaxNbrDescr;
573
574 if (UsedDescrRatio > M_DIMINFO.PrevUsedDescrRatio) {
575 RatioDiffAbs = (UsedDescrRatio - M_DIMINFO.PrevUsedDescrRatio);
576 RatioDiffRel = (RatioDiffAbs * 100) / UsedDescrRatio;
577 M_DIMINFO.PrevUsedDescrRatio = UsedDescrRatio;
578 IncreaseTimerDuration = SK_FALSE; /* in other words: DECREASE */
579 } else if (UsedDescrRatio < M_DIMINFO.PrevUsedDescrRatio) {
580 RatioDiffAbs = (M_DIMINFO.PrevUsedDescrRatio - UsedDescrRatio);
581 RatioDiffRel = (RatioDiffAbs * 100) / M_DIMINFO.PrevUsedDescrRatio;
582 M_DIMINFO.PrevUsedDescrRatio = UsedDescrRatio;
583 IncreaseTimerDuration = SK_TRUE; /* in other words: INCREASE */
584 } else {
585 RatioDiffAbs = (M_DIMINFO.PrevUsedDescrRatio - UsedDescrRatio);
586 RatioDiffRel = (RatioDiffAbs * 100) / M_DIMINFO.PrevUsedDescrRatio;
587 M_DIMINFO.PrevUsedDescrRatio = UsedDescrRatio;
588 IncreaseTimerDuration = SK_TRUE; /* in other words: INCREASE */
589 }
590
591 /*
592 ** Now we can determine the change in percent
593 */
594 if ((RatioDiffRel >= 0) && (RatioDiffRel <= 5) ) {
595 ModAdjValue = 1; /* 1% change - maybe some other value in future */
596 } else if ((RatioDiffRel > 5) && (RatioDiffRel <= 10) ) {
597 ModAdjValue = 1; /* 1% change - maybe some other value in future */
598 } else if ((RatioDiffRel > 10) && (RatioDiffRel <= 15) ) {
599 ModAdjValue = 1; /* 1% change - maybe some other value in future */
600 } else {
601 ModAdjValue = 1; /* 1% change - maybe some other value in future */
602 }
603
604 if (IncreaseTimerDuration) {
605 NewMaxModIntsPerSec = M_DIMINFO.MaxModIntsPerSec +
606 (M_DIMINFO.MaxModIntsPerSec * ModAdjValue) / 100;
607 } else {
608 NewMaxModIntsPerSec = M_DIMINFO.MaxModIntsPerSec -
609 (M_DIMINFO.MaxModIntsPerSec * ModAdjValue) / 100;
610 }
611
612 /*
613 ** Check if we exceed boundaries...
614 */
615 if ( (NewMaxModIntsPerSec > M_DIMINFO.MaxModIntsPerSecUpperLimit) ||
616 (NewMaxModIntsPerSec < M_DIMINFO.MaxModIntsPerSecLowerLimit)) {
617 if (M_DIMINFO.DisplayStats) {
618 printk("Cannot change ModTim from %i to %i ints/sec\n",
619 M_DIMINFO.MaxModIntsPerSec, NewMaxModIntsPerSec);
620 }
621 return;
622 } else {
623 if (M_DIMINFO.DisplayStats) {
624 printk("Resized ModTim from %i to %i ints/sec\n",
625 M_DIMINFO.MaxModIntsPerSec, NewMaxModIntsPerSec);
626 }
627 }
628
629 M_DIMINFO.MaxModIntsPerSec = NewMaxModIntsPerSec;
630
631 if (pAC->GIni.GIChipId == CHIP_ID_GENESIS) {
632 ModBase = C_CLK_FREQ_GENESIS / pAC->DynIrqModInfo.MaxModIntsPerSec;
633 } else {
634 ModBase = C_CLK_FREQ_YUKON / pAC->DynIrqModInfo.MaxModIntsPerSec;
635 }
636
637 /*
638 ** We do not need to touch any other registers
639 */
640 SK_OUT32(pAC->IoBase, B2_IRQM_INI, ModBase);
641}
642
643/*******************************************************************************
644** Function : DisplaySelectedModerationType()
645** Description : Displays what type of moderation we have
646** Programmer : Ralph Roesler
647** Last Modified: 23-mar-03
648** Returns : void!
649** Notes : -
650*******************************************************************************/
651
652static void
653DisplaySelectedModerationType(SK_AC *pAC) {
654
655 if (pAC->DynIrqModInfo.DisplayStats) {
656 if (pAC->DynIrqModInfo.IntModTypeSelect == C_INT_MOD_STATIC) {
657 printk("Static int moderation runs with %i INTS/sec\n",
658 pAC->DynIrqModInfo.MaxModIntsPerSec);
659 } else if (pAC->DynIrqModInfo.IntModTypeSelect == C_INT_MOD_DYNAMIC) {
660 if (IsIntModEnabled(pAC)) {
661 printk("Dynamic int moderation runs with %i INTS/sec\n",
662 pAC->DynIrqModInfo.MaxModIntsPerSec);
663 } else {
664 printk("Dynamic int moderation currently not applied\n");
665 }
666 } else {
667 printk("No interrupt moderation selected!\n");
668 }
669 }
670}
671
672/*******************************************************************************
673** Function : DisplaySelectedModerationMask()
674** Description : Displays what interrupts are moderated
675** Programmer : Ralph Roesler
676** Last Modified: 23-mar-03
677** Returns : void!
678** Notes : -
679*******************************************************************************/
680
681static void
682DisplaySelectedModerationMask(SK_AC *pAC) {
683
684 if (pAC->DynIrqModInfo.DisplayStats) {
685 if (pAC->DynIrqModInfo.IntModTypeSelect != C_INT_MOD_NONE) {
686 switch (pAC->DynIrqModInfo.MaskIrqModeration) {
687 case IRQ_MASK_TX_ONLY:
688 printk("Only Tx-interrupts are moderated\n");
689 break;
690 case IRQ_MASK_RX_ONLY:
691 printk("Only Rx-interrupts are moderated\n");
692 break;
693 case IRQ_MASK_SP_ONLY:
694 printk("Only special-interrupts are moderated\n");
695 break;
696 case IRQ_MASK_TX_RX:
697 printk("Tx- and Rx-interrupts are moderated\n");
698 break;
699 case IRQ_MASK_SP_RX:
700 printk("Special- and Rx-interrupts are moderated\n");
701 break;
702 case IRQ_MASK_SP_TX:
703 printk("Special- and Tx-interrupts are moderated\n");
704 break;
705 case IRQ_MASK_RX_TX_SP:
706 printk("All Rx-, Tx and special-interrupts are moderated\n");
707 break;
708 default:
709 printk("Don't know what is moderated\n");
710 break;
711 }
712 } else {
713 printk("No specific interrupts masked for moderation\n");
714 }
715 }
716}
717
718/*******************************************************************************
719** Function : DisplayDescrRatio
720** Description : Like the name states...
721** Programmer : Ralph Roesler
722** Last Modified: 23-mar-03
723** Returns : void!
724** Notes : -
725*******************************************************************************/
726
727static void
728DisplayDescrRatio(SK_AC *pAC) {
729 int TotalMaxNbrDescr = 0;
730
731 if (pAC->DynIrqModInfo.DisplayStats) {
732 TotalMaxNbrDescr = pAC->RxDescrPerRing * GetRxCalls(pAC);
733 printk("Ratio descriptors: %i/%i\n",
734 M_DIMINFO.NbrProcessedDescr, TotalMaxNbrDescr);
735 }
736}
737
738/*******************************************************************************
739**
740** End of file
741**
742*******************************************************************************/
diff --git a/drivers/net/sk98lin/skethtool.c b/drivers/net/sk98lin/skethtool.c
new file mode 100644
index 000000000000..5a6da8950faa
--- /dev/null
+++ b/drivers/net/sk98lin/skethtool.c
@@ -0,0 +1,627 @@
1/******************************************************************************
2 *
3 * Name: skethtool.c
4 * Project: GEnesis, PCI Gigabit Ethernet Adapter
5 * Version: $Revision: 1.7 $
6 * Date: $Date: 2004/09/29 13:32:07 $
7 * Purpose: All functions regarding ethtool handling
8 *
9 ******************************************************************************/
10
11/******************************************************************************
12 *
13 * (C)Copyright 1998-2002 SysKonnect GmbH.
14 * (C)Copyright 2002-2004 Marvell.
15 *
16 * Driver for Marvell Yukon/2 chipset and SysKonnect Gigabit Ethernet
17 * Server Adapters.
18 *
19 * Author: Ralph Roesler (rroesler@syskonnect.de)
20 * Mirko Lindner (mlindner@syskonnect.de)
21 *
22 * Address all question to: linux@syskonnect.de
23 *
24 * The technical manual for the adapters is available from SysKonnect's
25 * web pages: www.syskonnect.com
26 *
27 * This program is free software; you can redistribute it and/or modify
28 * it under the terms of the GNU General Public License as published by
29 * the Free Software Foundation; either version 2 of the License, or
30 * (at your option) any later version.
31 *
32 * The information in this file is provided "AS IS" without warranty.
33 *
34 *****************************************************************************/
35
36#include "h/skdrv1st.h"
37#include "h/skdrv2nd.h"
38#include "h/skversion.h"
39
40#include <linux/ethtool.h>
41#include <linux/timer.h>
42#include <linux/delay.h>
43
44/******************************************************************************
45 *
46 * Defines
47 *
48 *****************************************************************************/
49
50#define SUPP_COPPER_ALL (SUPPORTED_10baseT_Half | SUPPORTED_10baseT_Full | \
51 SUPPORTED_100baseT_Half | SUPPORTED_100baseT_Full | \
52 SUPPORTED_1000baseT_Half| SUPPORTED_1000baseT_Full| \
53 SUPPORTED_TP)
54
55#define ADV_COPPER_ALL (ADVERTISED_10baseT_Half | ADVERTISED_10baseT_Full | \
56 ADVERTISED_100baseT_Half | ADVERTISED_100baseT_Full | \
57 ADVERTISED_1000baseT_Half| ADVERTISED_1000baseT_Full| \
58 ADVERTISED_TP)
59
60#define SUPP_FIBRE_ALL (SUPPORTED_1000baseT_Full | \
61 SUPPORTED_FIBRE | \
62 SUPPORTED_Autoneg)
63
64#define ADV_FIBRE_ALL (ADVERTISED_1000baseT_Full | \
65 ADVERTISED_FIBRE | \
66 ADVERTISED_Autoneg)
67
68
69/******************************************************************************
70 *
71 * Local Functions
72 *
73 *****************************************************************************/
74
75/*****************************************************************************
76 *
77 * getSettings - retrieves the current settings of the selected adapter
78 *
79 * Description:
80 * The current configuration of the selected adapter is returned.
81 * This configuration involves a)speed, b)duplex and c)autoneg plus
82 * a number of other variables.
83 *
84 * Returns: always 0
85 *
86 */
87static int getSettings(struct net_device *dev, struct ethtool_cmd *ecmd)
88{
89 const DEV_NET *pNet = netdev_priv(dev);
90 int port = pNet->PortNr;
91 const SK_AC *pAC = pNet->pAC;
92 const SK_GEPORT *pPort = &pAC->GIni.GP[port];
93
94 static int DuplexAutoNegConfMap[9][3]= {
95 { -1 , -1 , -1 },
96 { 0 , -1 , -1 },
97 { SK_LMODE_HALF , DUPLEX_HALF, AUTONEG_DISABLE },
98 { SK_LMODE_FULL , DUPLEX_FULL, AUTONEG_DISABLE },
99 { SK_LMODE_AUTOHALF , DUPLEX_HALF, AUTONEG_ENABLE },
100 { SK_LMODE_AUTOFULL , DUPLEX_FULL, AUTONEG_ENABLE },
101 { SK_LMODE_AUTOBOTH , DUPLEX_FULL, AUTONEG_ENABLE },
102 { SK_LMODE_AUTOSENSE , -1 , -1 },
103 { SK_LMODE_INDETERMINATED, -1 , -1 }
104 };
105 static int SpeedConfMap[6][2] = {
106 { 0 , -1 },
107 { SK_LSPEED_AUTO , -1 },
108 { SK_LSPEED_10MBPS , SPEED_10 },
109 { SK_LSPEED_100MBPS , SPEED_100 },
110 { SK_LSPEED_1000MBPS , SPEED_1000 },
111 { SK_LSPEED_INDETERMINATED, -1 }
112 };
113 static int AdvSpeedMap[6][2] = {
114 { 0 , -1 },
115 { SK_LSPEED_AUTO , -1 },
116 { SK_LSPEED_10MBPS , ADVERTISED_10baseT_Half | ADVERTISED_10baseT_Full },
117 { SK_LSPEED_100MBPS , ADVERTISED_100baseT_Half | ADVERTISED_100baseT_Full },
118 { SK_LSPEED_1000MBPS , ADVERTISED_1000baseT_Half | ADVERTISED_1000baseT_Full},
119 { SK_LSPEED_INDETERMINATED, -1 }
120 };
121
122 ecmd->phy_address = port;
123 ecmd->speed = SpeedConfMap[pPort->PLinkSpeedUsed][1];
124 ecmd->duplex = DuplexAutoNegConfMap[pPort->PLinkModeStatus][1];
125 ecmd->autoneg = DuplexAutoNegConfMap[pPort->PLinkModeStatus][2];
126 ecmd->transceiver = XCVR_INTERNAL;
127
128 if (pAC->GIni.GICopperType) {
129 ecmd->port = PORT_TP;
130 ecmd->supported = (SUPP_COPPER_ALL|SUPPORTED_Autoneg);
131 if (pAC->GIni.GIGenesis) {
132 ecmd->supported &= ~(SUPPORTED_10baseT_Half);
133 ecmd->supported &= ~(SUPPORTED_10baseT_Full);
134 ecmd->supported &= ~(SUPPORTED_100baseT_Half);
135 ecmd->supported &= ~(SUPPORTED_100baseT_Full);
136 } else {
137 if (pAC->GIni.GIChipId == CHIP_ID_YUKON) {
138 ecmd->supported &= ~(SUPPORTED_1000baseT_Half);
139 }
140#ifdef CHIP_ID_YUKON_FE
141 if (pAC->GIni.GIChipId == CHIP_ID_YUKON_FE) {
142 ecmd->supported &= ~(SUPPORTED_1000baseT_Half);
143 ecmd->supported &= ~(SUPPORTED_1000baseT_Full);
144 }
145#endif
146 }
147 if (pAC->GIni.GP[0].PLinkSpeed != SK_LSPEED_AUTO) {
148 ecmd->advertising = AdvSpeedMap[pPort->PLinkSpeed][1];
149 if (pAC->GIni.GIChipId == CHIP_ID_YUKON) {
150 ecmd->advertising &= ~(SUPPORTED_1000baseT_Half);
151 }
152 } else {
153 ecmd->advertising = ecmd->supported;
154 }
155
156 if (ecmd->autoneg == AUTONEG_ENABLE)
157 ecmd->advertising |= ADVERTISED_Autoneg;
158 } else {
159 ecmd->port = PORT_FIBRE;
160 ecmd->supported = SUPP_FIBRE_ALL;
161 ecmd->advertising = ADV_FIBRE_ALL;
162 }
163 return 0;
164}
165
166/*
167 * MIB infrastructure uses instance value starting at 1
168 * based on board and port.
169 */
170static inline u32 pnmiInstance(const DEV_NET *pNet)
171{
172 return 1 + (pNet->pAC->RlmtNets == 2) + pNet->PortNr;
173}
174
175/*****************************************************************************
176 *
177 * setSettings - configures the settings of a selected adapter
178 *
179 * Description:
180 * Possible settings that may be altered are a)speed, b)duplex or
181 * c)autonegotiation.
182 *
183 * Returns:
184 * 0: everything fine, no error
185 * <0: the return value is the error code of the failure
186 */
187static int setSettings(struct net_device *dev, struct ethtool_cmd *ecmd)
188{
189 DEV_NET *pNet = netdev_priv(dev);
190 SK_AC *pAC = pNet->pAC;
191 u32 instance;
192 char buf[4];
193 int len = 1;
194
195 if (ecmd->speed != SPEED_10 && ecmd->speed != SPEED_100
196 && ecmd->speed != SPEED_1000)
197 return -EINVAL;
198
199 if (ecmd->duplex != DUPLEX_HALF && ecmd->duplex != DUPLEX_FULL)
200 return -EINVAL;
201
202 if (ecmd->autoneg != AUTONEG_DISABLE && ecmd->autoneg != AUTONEG_ENABLE)
203 return -EINVAL;
204
205 if (ecmd->autoneg == AUTONEG_DISABLE)
206 *buf = (ecmd->duplex == DUPLEX_FULL)
207 ? SK_LMODE_FULL : SK_LMODE_HALF;
208 else
209 *buf = (ecmd->duplex == DUPLEX_FULL)
210 ? SK_LMODE_AUTOFULL : SK_LMODE_AUTOHALF;
211
212 instance = pnmiInstance(pNet);
213 if (SkPnmiSetVar(pAC, pAC->IoBase, OID_SKGE_LINK_MODE,
214 &buf, &len, instance, pNet->NetNr) != SK_PNMI_ERR_OK)
215 return -EINVAL;
216
217 switch(ecmd->speed) {
218 case SPEED_1000:
219 *buf = SK_LSPEED_1000MBPS;
220 break;
221 case SPEED_100:
222 *buf = SK_LSPEED_100MBPS;
223 break;
224 case SPEED_10:
225 *buf = SK_LSPEED_10MBPS;
226 }
227
228 if (SkPnmiSetVar(pAC, pAC->IoBase, OID_SKGE_SPEED_MODE,
229 &buf, &len, instance, pNet->NetNr) != SK_PNMI_ERR_OK)
230 return -EINVAL;
231
232 return 0;
233}
234
235/*****************************************************************************
236 *
237 * getDriverInfo - returns generic driver and adapter information
238 *
239 * Description:
240 * Generic driver information is returned via this function, such as
241 * the name of the driver, its version and and firmware version.
242 * In addition to this, the location of the selected adapter is
243 * returned as a bus info string (e.g. '01:05.0').
244 *
245 * Returns: N/A
246 *
247 */
248static void getDriverInfo(struct net_device *dev, struct ethtool_drvinfo *info)
249{
250 const DEV_NET *pNet = netdev_priv(dev);
251 const SK_AC *pAC = pNet->pAC;
252 char vers[32];
253
254 snprintf(vers, sizeof(vers)-1, VER_STRING "(v%d.%d)",
255 (pAC->GIni.GIPciHwRev >> 4) & 0xf, pAC->GIni.GIPciHwRev & 0xf);
256
257 strlcpy(info->driver, DRIVER_FILE_NAME, sizeof(info->driver));
258 strcpy(info->version, vers);
259 strcpy(info->fw_version, "N/A");
260 strlcpy(info->bus_info, pci_name(pAC->PciDev), ETHTOOL_BUSINFO_LEN);
261}
262
263/*
264 * Ethtool statistics support.
265 */
266static const char StringsStats[][ETH_GSTRING_LEN] = {
267 "rx_packets", "tx_packets",
268 "rx_bytes", "tx_bytes",
269 "rx_errors", "tx_errors",
270 "rx_dropped", "tx_dropped",
271 "multicasts", "collisions",
272 "rx_length_errors", "rx_buffer_overflow_errors",
273 "rx_crc_errors", "rx_frame_errors",
274 "rx_too_short_errors", "rx_too_long_errors",
275 "rx_carrier_extension_errors", "rx_symbol_errors",
276 "rx_llc_mac_size_errors", "rx_carrier_errors",
277 "rx_jabber_errors", "rx_missed_errors",
278 "tx_abort_collision_errors", "tx_carrier_errors",
279 "tx_buffer_underrun_errors", "tx_heartbeat_errors",
280 "tx_window_errors",
281};
282
283static int getStatsCount(struct net_device *dev)
284{
285 return ARRAY_SIZE(StringsStats);
286}
287
288static void getStrings(struct net_device *dev, u32 stringset, u8 *data)
289{
290 switch(stringset) {
291 case ETH_SS_STATS:
292 memcpy(data, *StringsStats, sizeof(StringsStats));
293 break;
294 }
295}
296
297static void getEthtoolStats(struct net_device *dev,
298 struct ethtool_stats *stats, u64 *data)
299{
300 const DEV_NET *pNet = netdev_priv(dev);
301 const SK_AC *pAC = pNet->pAC;
302 const SK_PNMI_STRUCT_DATA *pPnmiStruct = &pAC->PnmiStruct;
303
304 *data++ = pPnmiStruct->Stat[0].StatRxOkCts;
305 *data++ = pPnmiStruct->Stat[0].StatTxOkCts;
306 *data++ = pPnmiStruct->Stat[0].StatRxOctetsOkCts;
307 *data++ = pPnmiStruct->Stat[0].StatTxOctetsOkCts;
308 *data++ = pPnmiStruct->InErrorsCts;
309 *data++ = pPnmiStruct->Stat[0].StatTxSingleCollisionCts;
310 *data++ = pPnmiStruct->RxNoBufCts;
311 *data++ = pPnmiStruct->TxNoBufCts;
312 *data++ = pPnmiStruct->Stat[0].StatRxMulticastOkCts;
313 *data++ = pPnmiStruct->Stat[0].StatTxSingleCollisionCts;
314 *data++ = pPnmiStruct->Stat[0].StatRxRuntCts;
315 *data++ = pPnmiStruct->Stat[0].StatRxFifoOverflowCts;
316 *data++ = pPnmiStruct->Stat[0].StatRxFcsCts;
317 *data++ = pPnmiStruct->Stat[0].StatRxFramingCts;
318 *data++ = pPnmiStruct->Stat[0].StatRxShortsCts;
319 *data++ = pPnmiStruct->Stat[0].StatRxTooLongCts;
320 *data++ = pPnmiStruct->Stat[0].StatRxCextCts;
321 *data++ = pPnmiStruct->Stat[0].StatRxSymbolCts;
322 *data++ = pPnmiStruct->Stat[0].StatRxIRLengthCts;
323 *data++ = pPnmiStruct->Stat[0].StatRxCarrierCts;
324 *data++ = pPnmiStruct->Stat[0].StatRxJabberCts;
325 *data++ = pPnmiStruct->Stat[0].StatRxMissedCts;
326 *data++ = pAC->stats.tx_aborted_errors;
327 *data++ = pPnmiStruct->Stat[0].StatTxCarrierCts;
328 *data++ = pPnmiStruct->Stat[0].StatTxFifoUnderrunCts;
329 *data++ = pPnmiStruct->Stat[0].StatTxCarrierCts;
330 *data++ = pAC->stats.tx_window_errors;
331}
332
333
334/*****************************************************************************
335 *
336 * toggleLeds - Changes the LED state of an adapter
337 *
338 * Description:
339 * This function changes the current state of all LEDs of an adapter so
340 * that it can be located by a user.
341 *
342 * Returns: N/A
343 *
344 */
345static void toggleLeds(DEV_NET *pNet, int on)
346{
347 SK_AC *pAC = pNet->pAC;
348 int port = pNet->PortNr;
349 void __iomem *io = pAC->IoBase;
350
351 if (pAC->GIni.GIGenesis) {
352 SK_OUT8(io, MR_ADDR(port,LNK_LED_REG),
353 on ? SK_LNK_ON : SK_LNK_OFF);
354 SkGeYellowLED(pAC, io,
355 on ? (LED_ON >> 1) : (LED_OFF >> 1));
356 SkGeXmitLED(pAC, io, MR_ADDR(port,RX_LED_INI),
357 on ? SK_LED_TST : SK_LED_DIS);
358
359 if (pAC->GIni.GP[port].PhyType == SK_PHY_BCOM)
360 SkXmPhyWrite(pAC, io, port, PHY_BCOM_P_EXT_CTRL,
361 on ? PHY_B_PEC_LED_ON : PHY_B_PEC_LED_OFF);
362 else if (pAC->GIni.GP[port].PhyType == SK_PHY_LONE)
363 SkXmPhyWrite(pAC, io, port, PHY_LONE_LED_CFG,
364 on ? 0x0800 : PHY_L_LC_LEDT);
365 else
366 SkGeXmitLED(pAC, io, MR_ADDR(port,TX_LED_INI),
367 on ? SK_LED_TST : SK_LED_DIS);
368 } else {
369 const u16 YukLedOn = (PHY_M_LED_MO_DUP(MO_LED_ON) |
370 PHY_M_LED_MO_10(MO_LED_ON) |
371 PHY_M_LED_MO_100(MO_LED_ON) |
372 PHY_M_LED_MO_1000(MO_LED_ON) |
373 PHY_M_LED_MO_RX(MO_LED_ON));
374 const u16 YukLedOff = (PHY_M_LED_MO_DUP(MO_LED_OFF) |
375 PHY_M_LED_MO_10(MO_LED_OFF) |
376 PHY_M_LED_MO_100(MO_LED_OFF) |
377 PHY_M_LED_MO_1000(MO_LED_OFF) |
378 PHY_M_LED_MO_RX(MO_LED_OFF));
379
380
381 SkGmPhyWrite(pAC,io,port,PHY_MARV_LED_CTRL,0);
382 SkGmPhyWrite(pAC,io,port,PHY_MARV_LED_OVER,
383 on ? YukLedOn : YukLedOff);
384 }
385}
386
387/*****************************************************************************
388 *
389 * skGeBlinkTimer - Changes the LED state of an adapter
390 *
391 * Description:
392 * This function changes the current state of all LEDs of an adapter so
393 * that it can be located by a user. If the requested time interval for
394 * this test has elapsed, this function cleans up everything that was
395 * temporarily setup during the locate NIC test. This involves of course
396 * also closing or opening any adapter so that the initial board state
397 * is recovered.
398 *
399 * Returns: N/A
400 *
401 */
402void SkGeBlinkTimer(unsigned long data)
403{
404 struct net_device *dev = (struct net_device *) data;
405 DEV_NET *pNet = netdev_priv(dev);
406 SK_AC *pAC = pNet->pAC;
407
408 toggleLeds(pNet, pAC->LedsOn);
409
410 pAC->LedsOn = !pAC->LedsOn;
411 mod_timer(&pAC->BlinkTimer, jiffies + HZ/4);
412}
413
414/*****************************************************************************
415 *
416 * locateDevice - start the locate NIC feature of the elected adapter
417 *
418 * Description:
419 * This function is used if the user want to locate a particular NIC.
420 * All LEDs are regularly switched on and off, so the NIC can easily
421 * be identified.
422 *
423 * Returns:
424 * ==0: everything fine, no error, locateNIC test was started
425 * !=0: one locateNIC test runs already
426 *
427 */
428static int locateDevice(struct net_device *dev, u32 data)
429{
430 DEV_NET *pNet = netdev_priv(dev);
431 SK_AC *pAC = pNet->pAC;
432
433 if(!data || data > (u32)(MAX_SCHEDULE_TIMEOUT / HZ))
434 data = (u32)(MAX_SCHEDULE_TIMEOUT / HZ);
435
436 /* start blinking */
437 pAC->LedsOn = 0;
438 mod_timer(&pAC->BlinkTimer, jiffies);
439 msleep_interruptible(data * 1000);
440 del_timer_sync(&pAC->BlinkTimer);
441 toggleLeds(pNet, 0);
442
443 return 0;
444}
445
446/*****************************************************************************
447 *
448 * getPauseParams - retrieves the pause parameters
449 *
450 * Description:
451 * All current pause parameters of a selected adapter are placed
452 * in the passed ethtool_pauseparam structure and are returned.
453 *
454 * Returns: N/A
455 *
456 */
457static void getPauseParams(struct net_device *dev, struct ethtool_pauseparam *epause)
458{
459 DEV_NET *pNet = netdev_priv(dev);
460 SK_AC *pAC = pNet->pAC;
461 SK_GEPORT *pPort = &pAC->GIni.GP[pNet->PortNr];
462
463 epause->rx_pause = (pPort->PFlowCtrlMode == SK_FLOW_MODE_SYMMETRIC) ||
464 (pPort->PFlowCtrlMode == SK_FLOW_MODE_SYM_OR_REM);
465
466 epause->tx_pause = epause->rx_pause || (pPort->PFlowCtrlMode == SK_FLOW_MODE_LOC_SEND);
467 epause->autoneg = epause->rx_pause || epause->tx_pause;
468}
469
470/*****************************************************************************
471 *
472 * setPauseParams - configures the pause parameters of an adapter
473 *
474 * Description:
475 * This function sets the Rx or Tx pause parameters
476 *
477 * Returns:
478 * ==0: everything fine, no error
479 * !=0: the return value is the error code of the failure
480 */
481static int setPauseParams(struct net_device *dev , struct ethtool_pauseparam *epause)
482{
483 DEV_NET *pNet = netdev_priv(dev);
484 SK_AC *pAC = pNet->pAC;
485 SK_GEPORT *pPort = &pAC->GIni.GP[pNet->PortNr];
486 u32 instance = pnmiInstance(pNet);
487 struct ethtool_pauseparam old;
488 u8 oldspeed = pPort->PLinkSpeedUsed;
489 char buf[4];
490 int len = 1;
491 int ret;
492
493 /*
494 ** we have to determine the current settings to see if
495 ** the operator requested any modification of the flow
496 ** control parameters...
497 */
498 getPauseParams(dev, &old);
499
500 /*
501 ** perform modifications regarding the changes
502 ** requested by the operator
503 */
504 if (epause->autoneg != old.autoneg)
505 *buf = epause->autoneg ? SK_FLOW_MODE_NONE : SK_FLOW_MODE_SYMMETRIC;
506 else {
507 if (epause->rx_pause && epause->tx_pause)
508 *buf = SK_FLOW_MODE_SYMMETRIC;
509 else if (epause->rx_pause && !epause->tx_pause)
510 *buf = SK_FLOW_MODE_SYM_OR_REM;
511 else if (!epause->rx_pause && epause->tx_pause)
512 *buf = SK_FLOW_MODE_LOC_SEND;
513 else
514 *buf = SK_FLOW_MODE_NONE;
515 }
516
517 ret = SkPnmiSetVar(pAC, pAC->IoBase, OID_SKGE_FLOWCTRL_MODE,
518 &buf, &len, instance, pNet->NetNr);
519
520 if (ret != SK_PNMI_ERR_OK) {
521 SK_DBG_MSG(NULL, SK_DBGMOD_DRV, SK_DBGCAT_CTRL,
522 ("ethtool (sk98lin): error changing rx/tx pause (%i)\n", ret));
523 goto err;
524 }
525
526 /*
527 ** It may be that autoneg has been disabled! Therefore
528 ** set the speed to the previously used value...
529 */
530 if (!epause->autoneg) {
531 len = 1;
532 ret = SkPnmiSetVar(pAC, pAC->IoBase, OID_SKGE_SPEED_MODE,
533 &oldspeed, &len, instance, pNet->NetNr);
534 if (ret != SK_PNMI_ERR_OK)
535 SK_DBG_MSG(NULL, SK_DBGMOD_DRV, SK_DBGCAT_CTRL,
536 ("ethtool (sk98lin): error setting speed (%i)\n", ret));
537 }
538 err:
539 return ret ? -EIO : 0;
540}
541
542/* Only Yukon supports checksum offload. */
543static int setScatterGather(struct net_device *dev, u32 data)
544{
545 DEV_NET *pNet = netdev_priv(dev);
546 SK_AC *pAC = pNet->pAC;
547
548 if (pAC->GIni.GIChipId == CHIP_ID_GENESIS)
549 return -EOPNOTSUPP;
550 return ethtool_op_set_sg(dev, data);
551}
552
553static int setTxCsum(struct net_device *dev, u32 data)
554{
555 DEV_NET *pNet = netdev_priv(dev);
556 SK_AC *pAC = pNet->pAC;
557
558 if (pAC->GIni.GIChipId == CHIP_ID_GENESIS)
559 return -EOPNOTSUPP;
560
561 return ethtool_op_set_tx_csum(dev, data);
562}
563
564static u32 getRxCsum(struct net_device *dev)
565{
566 DEV_NET *pNet = netdev_priv(dev);
567 SK_AC *pAC = pNet->pAC;
568
569 return pAC->RxPort[pNet->PortNr].RxCsum;
570}
571
572static int setRxCsum(struct net_device *dev, u32 data)
573{
574 DEV_NET *pNet = netdev_priv(dev);
575 SK_AC *pAC = pNet->pAC;
576
577 if (pAC->GIni.GIChipId == CHIP_ID_GENESIS)
578 return -EOPNOTSUPP;
579
580 pAC->RxPort[pNet->PortNr].RxCsum = data != 0;
581 return 0;
582}
583
584static int getRegsLen(struct net_device *dev)
585{
586 return 0x4000;
587}
588
589/*
590 * Returns copy of whole control register region
591 * Note: skip RAM address register because accessing it will
592 * cause bus hangs!
593 */
594static void getRegs(struct net_device *dev, struct ethtool_regs *regs,
595 void *p)
596{
597 DEV_NET *pNet = netdev_priv(dev);
598 const void __iomem *io = pNet->pAC->IoBase;
599
600 regs->version = 1;
601 memset(p, 0, regs->len);
602 memcpy_fromio(p, io, B3_RAM_ADDR);
603
604 memcpy_fromio(p + B3_RI_WTO_R1, io + B3_RI_WTO_R1,
605 regs->len - B3_RI_WTO_R1);
606}
607
608const struct ethtool_ops SkGeEthtoolOps = {
609 .get_settings = getSettings,
610 .set_settings = setSettings,
611 .get_drvinfo = getDriverInfo,
612 .get_strings = getStrings,
613 .get_stats_count = getStatsCount,
614 .get_ethtool_stats = getEthtoolStats,
615 .phys_id = locateDevice,
616 .get_pauseparam = getPauseParams,
617 .set_pauseparam = setPauseParams,
618 .get_link = ethtool_op_get_link,
619 .get_sg = ethtool_op_get_sg,
620 .set_sg = setScatterGather,
621 .get_tx_csum = ethtool_op_get_tx_csum,
622 .set_tx_csum = setTxCsum,
623 .get_rx_csum = getRxCsum,
624 .set_rx_csum = setRxCsum,
625 .get_regs = getRegs,
626 .get_regs_len = getRegsLen,
627};
diff --git a/drivers/net/sk98lin/skge.c b/drivers/net/sk98lin/skge.c
new file mode 100644
index 000000000000..7dc9c9ebf5e7
--- /dev/null
+++ b/drivers/net/sk98lin/skge.c
@@ -0,0 +1,5219 @@
1/******************************************************************************
2 *
3 * Name: skge.c
4 * Project: GEnesis, PCI Gigabit Ethernet Adapter
5 * Version: $Revision: 1.45 $
6 * Date: $Date: 2004/02/12 14:41:02 $
7 * Purpose: The main driver source module
8 *
9 ******************************************************************************/
10
11/******************************************************************************
12 *
13 * (C)Copyright 1998-2002 SysKonnect GmbH.
14 * (C)Copyright 2002-2003 Marvell.
15 *
16 * Driver for Marvell Yukon chipset and SysKonnect Gigabit Ethernet
17 * Server Adapters.
18 *
19 * Created 10-Feb-1999, based on Linux' acenic.c, 3c59x.c and
20 * SysKonnects GEnesis Solaris driver
21 * Author: Christoph Goos (cgoos@syskonnect.de)
22 * Mirko Lindner (mlindner@syskonnect.de)
23 *
24 * Address all question to: linux@syskonnect.de
25 *
26 * The technical manual for the adapters is available from SysKonnect's
27 * web pages: www.syskonnect.com
28 * Goto "Support" and search Knowledge Base for "manual".
29 *
30 * This program is free software; you can redistribute it and/or modify
31 * it under the terms of the GNU General Public License as published by
32 * the Free Software Foundation; either version 2 of the License, or
33 * (at your option) any later version.
34 *
35 * The information in this file is provided "AS IS" without warranty.
36 *
37 ******************************************************************************/
38
39/******************************************************************************
40 *
41 * Possible compiler options (#define xxx / -Dxxx):
42 *
43 * debugging can be enable by changing SK_DEBUG_CHKMOD and
44 * SK_DEBUG_CHKCAT in makefile (described there).
45 *
46 ******************************************************************************/
47
48/******************************************************************************
49 *
50 * Description:
51 *
52 * This is the main module of the Linux GE driver.
53 *
54 * All source files except skge.c, skdrv1st.h, skdrv2nd.h and sktypes.h
55 * are part of SysKonnect's COMMON MODULES for the SK-98xx adapters.
56 * Those are used for drivers on multiple OS', so some thing may seem
57 * unnecessary complicated on Linux. Please do not try to 'clean up'
58 * them without VERY good reasons, because this will make it more
59 * difficult to keep the Linux driver in synchronisation with the
60 * other versions.
61 *
62 * Include file hierarchy:
63 *
64 * <linux/module.h>
65 *
66 * "h/skdrv1st.h"
67 * <linux/types.h>
68 * <linux/kernel.h>
69 * <linux/string.h>
70 * <linux/errno.h>
71 * <linux/ioport.h>
72 * <linux/slab.h>
73 * <linux/interrupt.h>
74 * <linux/pci.h>
75 * <linux/bitops.h>
76 * <asm/byteorder.h>
77 * <asm/io.h>
78 * <linux/netdevice.h>
79 * <linux/etherdevice.h>
80 * <linux/skbuff.h>
81 * those three depending on kernel version used:
82 * <linux/bios32.h>
83 * <linux/init.h>
84 * <asm/uaccess.h>
85 * <net/checksum.h>
86 *
87 * "h/skerror.h"
88 * "h/skdebug.h"
89 * "h/sktypes.h"
90 * "h/lm80.h"
91 * "h/xmac_ii.h"
92 *
93 * "h/skdrv2nd.h"
94 * "h/skqueue.h"
95 * "h/skgehwt.h"
96 * "h/sktimer.h"
97 * "h/ski2c.h"
98 * "h/skgepnmi.h"
99 * "h/skvpd.h"
100 * "h/skgehw.h"
101 * "h/skgeinit.h"
102 * "h/skaddr.h"
103 * "h/skgesirq.h"
104 * "h/skrlmt.h"
105 *
106 ******************************************************************************/
107
108#include "h/skversion.h"
109
110#include <linux/in.h>
111#include <linux/module.h>
112#include <linux/moduleparam.h>
113#include <linux/init.h>
114#include <linux/dma-mapping.h>
115#include <linux/ip.h>
116#include <linux/mii.h>
117#include <linux/mm.h>
118
119#include "h/skdrv1st.h"
120#include "h/skdrv2nd.h"
121
122/*******************************************************************************
123 *
124 * Defines
125 *
126 ******************************************************************************/
127
128/* for debuging on x86 only */
129/* #define BREAKPOINT() asm(" int $3"); */
130
131/* use the transmit hw checksum driver functionality */
132#define USE_SK_TX_CHECKSUM
133
134/* use the receive hw checksum driver functionality */
135#define USE_SK_RX_CHECKSUM
136
137/* use the scatter-gather functionality with sendfile() */
138#define SK_ZEROCOPY
139
140/* use of a transmit complete interrupt */
141#define USE_TX_COMPLETE
142
143/*
144 * threshold for copying small receive frames
145 * set to 0 to avoid copying, set to 9001 to copy all frames
146 */
147#define SK_COPY_THRESHOLD 50
148
149/* number of adapters that can be configured via command line params */
150#define SK_MAX_CARD_PARAM 16
151
152
153
154/*
155 * use those defines for a compile-in version of the driver instead
156 * of command line parameters
157 */
158// #define LINK_SPEED_A {"Auto", }
159// #define LINK_SPEED_B {"Auto", }
160// #define AUTO_NEG_A {"Sense", }
161// #define AUTO_NEG_B {"Sense", }
162// #define DUP_CAP_A {"Both", }
163// #define DUP_CAP_B {"Both", }
164// #define FLOW_CTRL_A {"SymOrRem", }
165// #define FLOW_CTRL_B {"SymOrRem", }
166// #define ROLE_A {"Auto", }
167// #define ROLE_B {"Auto", }
168// #define PREF_PORT {"A", }
169// #define CON_TYPE {"Auto", }
170// #define RLMT_MODE {"CheckLinkState", }
171
172#define DEV_KFREE_SKB(skb) dev_kfree_skb(skb)
173#define DEV_KFREE_SKB_IRQ(skb) dev_kfree_skb_irq(skb)
174#define DEV_KFREE_SKB_ANY(skb) dev_kfree_skb_any(skb)
175
176
177/* Set blink mode*/
178#define OEM_CONFIG_VALUE ( SK_ACT_LED_BLINK | \
179 SK_DUP_LED_NORMAL | \
180 SK_LED_LINK100_ON)
181
182
183/* Isr return value */
184#define SkIsrRetVar irqreturn_t
185#define SkIsrRetNone IRQ_NONE
186#define SkIsrRetHandled IRQ_HANDLED
187
188
189/*******************************************************************************
190 *
191 * Local Function Prototypes
192 *
193 ******************************************************************************/
194
195static void FreeResources(struct SK_NET_DEVICE *dev);
196static int SkGeBoardInit(struct SK_NET_DEVICE *dev, SK_AC *pAC);
197static SK_BOOL BoardAllocMem(SK_AC *pAC);
198static void BoardFreeMem(SK_AC *pAC);
199static void BoardInitMem(SK_AC *pAC);
200static void SetupRing(SK_AC*, void*, uintptr_t, RXD**, RXD**, RXD**, int*, SK_BOOL);
201static SkIsrRetVar SkGeIsr(int irq, void *dev_id);
202static SkIsrRetVar SkGeIsrOnePort(int irq, void *dev_id);
203static int SkGeOpen(struct SK_NET_DEVICE *dev);
204static int SkGeClose(struct SK_NET_DEVICE *dev);
205static int SkGeXmit(struct sk_buff *skb, struct SK_NET_DEVICE *dev);
206static int SkGeSetMacAddr(struct SK_NET_DEVICE *dev, void *p);
207static void SkGeSetRxMode(struct SK_NET_DEVICE *dev);
208static struct net_device_stats *SkGeStats(struct SK_NET_DEVICE *dev);
209static int SkGeIoctl(struct SK_NET_DEVICE *dev, struct ifreq *rq, int cmd);
210static void GetConfiguration(SK_AC*);
211static int XmitFrame(SK_AC*, TX_PORT*, struct sk_buff*);
212static void FreeTxDescriptors(SK_AC*pAC, TX_PORT*);
213static void FillRxRing(SK_AC*, RX_PORT*);
214static SK_BOOL FillRxDescriptor(SK_AC*, RX_PORT*);
215static void ReceiveIrq(SK_AC*, RX_PORT*, SK_BOOL);
216static void ClearAndStartRx(SK_AC*, int);
217static void ClearTxIrq(SK_AC*, int, int);
218static void ClearRxRing(SK_AC*, RX_PORT*);
219static void ClearTxRing(SK_AC*, TX_PORT*);
220static int SkGeChangeMtu(struct SK_NET_DEVICE *dev, int new_mtu);
221static void PortReInitBmu(SK_AC*, int);
222static int SkGeIocMib(DEV_NET*, unsigned int, int);
223static int SkGeInitPCI(SK_AC *pAC);
224static void StartDrvCleanupTimer(SK_AC *pAC);
225static void StopDrvCleanupTimer(SK_AC *pAC);
226static int XmitFrameSG(SK_AC*, TX_PORT*, struct sk_buff*);
227
228#ifdef SK_DIAG_SUPPORT
229static SK_U32 ParseDeviceNbrFromSlotName(const char *SlotName);
230static int SkDrvInitAdapter(SK_AC *pAC, int devNbr);
231static int SkDrvDeInitAdapter(SK_AC *pAC, int devNbr);
232#endif
233
234/*******************************************************************************
235 *
236 * Extern Function Prototypes
237 *
238 ******************************************************************************/
239extern void SkDimEnableModerationIfNeeded(SK_AC *pAC);
240extern void SkDimDisplayModerationSettings(SK_AC *pAC);
241extern void SkDimStartModerationTimer(SK_AC *pAC);
242extern void SkDimModerate(SK_AC *pAC);
243extern void SkGeBlinkTimer(unsigned long data);
244
245#ifdef DEBUG
246static void DumpMsg(struct sk_buff*, char*);
247static void DumpData(char*, int);
248static void DumpLong(char*, int);
249#endif
250
251/* global variables *********************************************************/
252static SK_BOOL DoPrintInterfaceChange = SK_TRUE;
253extern const struct ethtool_ops SkGeEthtoolOps;
254
255/* local variables **********************************************************/
256static uintptr_t TxQueueAddr[SK_MAX_MACS][2] = {{0x680, 0x600},{0x780, 0x700}};
257static uintptr_t RxQueueAddr[SK_MAX_MACS] = {0x400, 0x480};
258
259/*****************************************************************************
260 *
261 * SkPciWriteCfgDWord - write a 32 bit value to pci config space
262 *
263 * Description:
264 * This routine writes a 32 bit value to the pci configuration
265 * space.
266 *
267 * Returns:
268 * 0 - indicate everything worked ok.
269 * != 0 - error indication
270 */
271static inline int SkPciWriteCfgDWord(
272SK_AC *pAC, /* Adapter Control structure pointer */
273int PciAddr, /* PCI register address */
274SK_U32 Val) /* pointer to store the read value */
275{
276 pci_write_config_dword(pAC->PciDev, PciAddr, Val);
277 return(0);
278} /* SkPciWriteCfgDWord */
279
280/*****************************************************************************
281 *
282 * SkGeInitPCI - Init the PCI resources
283 *
284 * Description:
285 * This function initialize the PCI resources and IO
286 *
287 * Returns:
288 * 0 - indicate everything worked ok.
289 * != 0 - error indication
290 */
291static __devinit int SkGeInitPCI(SK_AC *pAC)
292{
293 struct SK_NET_DEVICE *dev = pAC->dev[0];
294 struct pci_dev *pdev = pAC->PciDev;
295 int retval;
296
297 dev->mem_start = pci_resource_start (pdev, 0);
298 pci_set_master(pdev);
299
300 retval = pci_request_regions(pdev, "sk98lin");
301 if (retval)
302 goto out;
303
304#ifdef SK_BIG_ENDIAN
305 /*
306 * On big endian machines, we use the adapter's aibility of
307 * reading the descriptors as big endian.
308 */
309 {
310 SK_U32 our2;
311 SkPciReadCfgDWord(pAC, PCI_OUR_REG_2, &our2);
312 our2 |= PCI_REV_DESC;
313 SkPciWriteCfgDWord(pAC, PCI_OUR_REG_2, our2);
314 }
315#endif
316
317 /*
318 * Remap the regs into kernel space.
319 */
320 pAC->IoBase = ioremap_nocache(dev->mem_start, 0x4000);
321 if (!pAC->IoBase) {
322 retval = -EIO;
323 goto out_release;
324 }
325
326 return 0;
327
328 out_release:
329 pci_release_regions(pdev);
330 out:
331 return retval;
332}
333
334
335/*****************************************************************************
336 *
337 * FreeResources - release resources allocated for adapter
338 *
339 * Description:
340 * This function releases the IRQ, unmaps the IO and
341 * frees the desriptor ring.
342 *
343 * Returns: N/A
344 *
345 */
346static void FreeResources(struct SK_NET_DEVICE *dev)
347{
348SK_U32 AllocFlag;
349DEV_NET *pNet;
350SK_AC *pAC;
351
352 pNet = netdev_priv(dev);
353 pAC = pNet->pAC;
354 AllocFlag = pAC->AllocFlag;
355 if (pAC->PciDev) {
356 pci_release_regions(pAC->PciDev);
357 }
358 if (AllocFlag & SK_ALLOC_IRQ) {
359 free_irq(dev->irq, dev);
360 }
361 if (pAC->IoBase) {
362 iounmap(pAC->IoBase);
363 }
364 if (pAC->pDescrMem) {
365 BoardFreeMem(pAC);
366 }
367
368} /* FreeResources */
369
370MODULE_AUTHOR("Mirko Lindner <mlindner@syskonnect.de>");
371MODULE_DESCRIPTION("SysKonnect SK-NET Gigabit Ethernet SK-98xx driver");
372MODULE_LICENSE("GPL");
373
374#ifdef LINK_SPEED_A
375static char *Speed_A[SK_MAX_CARD_PARAM] = LINK_SPEED;
376#else
377static char *Speed_A[SK_MAX_CARD_PARAM] = {"", };
378#endif
379
380#ifdef LINK_SPEED_B
381static char *Speed_B[SK_MAX_CARD_PARAM] = LINK_SPEED;
382#else
383static char *Speed_B[SK_MAX_CARD_PARAM] = {"", };
384#endif
385
386#ifdef AUTO_NEG_A
387static char *AutoNeg_A[SK_MAX_CARD_PARAM] = AUTO_NEG_A;
388#else
389static char *AutoNeg_A[SK_MAX_CARD_PARAM] = {"", };
390#endif
391
392#ifdef DUP_CAP_A
393static char *DupCap_A[SK_MAX_CARD_PARAM] = DUP_CAP_A;
394#else
395static char *DupCap_A[SK_MAX_CARD_PARAM] = {"", };
396#endif
397
398#ifdef FLOW_CTRL_A
399static char *FlowCtrl_A[SK_MAX_CARD_PARAM] = FLOW_CTRL_A;
400#else
401static char *FlowCtrl_A[SK_MAX_CARD_PARAM] = {"", };
402#endif
403
404#ifdef ROLE_A
405static char *Role_A[SK_MAX_CARD_PARAM] = ROLE_A;
406#else
407static char *Role_A[SK_MAX_CARD_PARAM] = {"", };
408#endif
409
410#ifdef AUTO_NEG_B
411static char *AutoNeg_B[SK_MAX_CARD_PARAM] = AUTO_NEG_B;
412#else
413static char *AutoNeg_B[SK_MAX_CARD_PARAM] = {"", };
414#endif
415
416#ifdef DUP_CAP_B
417static char *DupCap_B[SK_MAX_CARD_PARAM] = DUP_CAP_B;
418#else
419static char *DupCap_B[SK_MAX_CARD_PARAM] = {"", };
420#endif
421
422#ifdef FLOW_CTRL_B
423static char *FlowCtrl_B[SK_MAX_CARD_PARAM] = FLOW_CTRL_B;
424#else
425static char *FlowCtrl_B[SK_MAX_CARD_PARAM] = {"", };
426#endif
427
428#ifdef ROLE_B
429static char *Role_B[SK_MAX_CARD_PARAM] = ROLE_B;
430#else
431static char *Role_B[SK_MAX_CARD_PARAM] = {"", };
432#endif
433
434#ifdef CON_TYPE
435static char *ConType[SK_MAX_CARD_PARAM] = CON_TYPE;
436#else
437static char *ConType[SK_MAX_CARD_PARAM] = {"", };
438#endif
439
440#ifdef PREF_PORT
441static char *PrefPort[SK_MAX_CARD_PARAM] = PREF_PORT;
442#else
443static char *PrefPort[SK_MAX_CARD_PARAM] = {"", };
444#endif
445
446#ifdef RLMT_MODE
447static char *RlmtMode[SK_MAX_CARD_PARAM] = RLMT_MODE;
448#else
449static char *RlmtMode[SK_MAX_CARD_PARAM] = {"", };
450#endif
451
452static int IntsPerSec[SK_MAX_CARD_PARAM];
453static char *Moderation[SK_MAX_CARD_PARAM];
454static char *ModerationMask[SK_MAX_CARD_PARAM];
455static char *AutoSizing[SK_MAX_CARD_PARAM];
456static char *Stats[SK_MAX_CARD_PARAM];
457
458module_param_array(Speed_A, charp, NULL, 0);
459module_param_array(Speed_B, charp, NULL, 0);
460module_param_array(AutoNeg_A, charp, NULL, 0);
461module_param_array(AutoNeg_B, charp, NULL, 0);
462module_param_array(DupCap_A, charp, NULL, 0);
463module_param_array(DupCap_B, charp, NULL, 0);
464module_param_array(FlowCtrl_A, charp, NULL, 0);
465module_param_array(FlowCtrl_B, charp, NULL, 0);
466module_param_array(Role_A, charp, NULL, 0);
467module_param_array(Role_B, charp, NULL, 0);
468module_param_array(ConType, charp, NULL, 0);
469module_param_array(PrefPort, charp, NULL, 0);
470module_param_array(RlmtMode, charp, NULL, 0);
471/* used for interrupt moderation */
472module_param_array(IntsPerSec, int, NULL, 0);
473module_param_array(Moderation, charp, NULL, 0);
474module_param_array(Stats, charp, NULL, 0);
475module_param_array(ModerationMask, charp, NULL, 0);
476module_param_array(AutoSizing, charp, NULL, 0);
477
478/*****************************************************************************
479 *
480 * SkGeBoardInit - do level 0 and 1 initialization
481 *
482 * Description:
483 * This function prepares the board hardware for running. The desriptor
484 * ring is set up, the IRQ is allocated and the configuration settings
485 * are examined.
486 *
487 * Returns:
488 * 0, if everything is ok
489 * !=0, on error
490 */
491static int __devinit SkGeBoardInit(struct SK_NET_DEVICE *dev, SK_AC *pAC)
492{
493short i;
494unsigned long Flags;
495char *DescrString = "sk98lin: Driver for Linux"; /* this is given to PNMI */
496char *VerStr = VER_STRING;
497int Ret; /* return code of request_irq */
498SK_BOOL DualNet;
499
500 SK_DBG_MSG(NULL, SK_DBGMOD_DRV, SK_DBGCAT_DRV_ENTRY,
501 ("IoBase: %08lX\n", (unsigned long)pAC->IoBase));
502 for (i=0; i<SK_MAX_MACS; i++) {
503 pAC->TxPort[i][0].HwAddr = pAC->IoBase + TxQueueAddr[i][0];
504 pAC->TxPort[i][0].PortIndex = i;
505 pAC->RxPort[i].HwAddr = pAC->IoBase + RxQueueAddr[i];
506 pAC->RxPort[i].PortIndex = i;
507 }
508
509 /* Initialize the mutexes */
510 for (i=0; i<SK_MAX_MACS; i++) {
511 spin_lock_init(&pAC->TxPort[i][0].TxDesRingLock);
512 spin_lock_init(&pAC->RxPort[i].RxDesRingLock);
513 }
514 spin_lock_init(&pAC->SlowPathLock);
515
516 /* setup phy_id blink timer */
517 pAC->BlinkTimer.function = SkGeBlinkTimer;
518 pAC->BlinkTimer.data = (unsigned long) dev;
519 init_timer(&pAC->BlinkTimer);
520
521 /* level 0 init common modules here */
522
523 spin_lock_irqsave(&pAC->SlowPathLock, Flags);
524 /* Does a RESET on board ...*/
525 if (SkGeInit(pAC, pAC->IoBase, SK_INIT_DATA) != 0) {
526 printk("HWInit (0) failed.\n");
527 spin_unlock_irqrestore(&pAC->SlowPathLock, Flags);
528 return -EIO;
529 }
530 SkI2cInit( pAC, pAC->IoBase, SK_INIT_DATA);
531 SkEventInit(pAC, pAC->IoBase, SK_INIT_DATA);
532 SkPnmiInit( pAC, pAC->IoBase, SK_INIT_DATA);
533 SkAddrInit( pAC, pAC->IoBase, SK_INIT_DATA);
534 SkRlmtInit( pAC, pAC->IoBase, SK_INIT_DATA);
535 SkTimerInit(pAC, pAC->IoBase, SK_INIT_DATA);
536
537 pAC->BoardLevel = SK_INIT_DATA;
538 pAC->RxBufSize = ETH_BUF_SIZE;
539
540 SK_PNMI_SET_DRIVER_DESCR(pAC, DescrString);
541 SK_PNMI_SET_DRIVER_VER(pAC, VerStr);
542
543 spin_unlock_irqrestore(&pAC->SlowPathLock, Flags);
544
545 /* level 1 init common modules here (HW init) */
546 spin_lock_irqsave(&pAC->SlowPathLock, Flags);
547 if (SkGeInit(pAC, pAC->IoBase, SK_INIT_IO) != 0) {
548 printk("sk98lin: HWInit (1) failed.\n");
549 spin_unlock_irqrestore(&pAC->SlowPathLock, Flags);
550 return -EIO;
551 }
552 SkI2cInit( pAC, pAC->IoBase, SK_INIT_IO);
553 SkEventInit(pAC, pAC->IoBase, SK_INIT_IO);
554 SkPnmiInit( pAC, pAC->IoBase, SK_INIT_IO);
555 SkAddrInit( pAC, pAC->IoBase, SK_INIT_IO);
556 SkRlmtInit( pAC, pAC->IoBase, SK_INIT_IO);
557 SkTimerInit(pAC, pAC->IoBase, SK_INIT_IO);
558
559 /* Set chipset type support */
560 pAC->ChipsetType = 0;
561 if ((pAC->GIni.GIChipId == CHIP_ID_YUKON) ||
562 (pAC->GIni.GIChipId == CHIP_ID_YUKON_LITE)) {
563 pAC->ChipsetType = 1;
564 }
565
566 GetConfiguration(pAC);
567 if (pAC->RlmtNets == 2) {
568 pAC->GIni.GIPortUsage = SK_MUL_LINK;
569 }
570
571 pAC->BoardLevel = SK_INIT_IO;
572 spin_unlock_irqrestore(&pAC->SlowPathLock, Flags);
573
574 if (pAC->GIni.GIMacsFound == 2) {
575 Ret = request_irq(dev->irq, SkGeIsr, IRQF_SHARED, "sk98lin", dev);
576 } else if (pAC->GIni.GIMacsFound == 1) {
577 Ret = request_irq(dev->irq, SkGeIsrOnePort, IRQF_SHARED,
578 "sk98lin", dev);
579 } else {
580 printk(KERN_WARNING "sk98lin: Illegal number of ports: %d\n",
581 pAC->GIni.GIMacsFound);
582 return -EIO;
583 }
584
585 if (Ret) {
586 printk(KERN_WARNING "sk98lin: Requested IRQ %d is busy.\n",
587 dev->irq);
588 return Ret;
589 }
590 pAC->AllocFlag |= SK_ALLOC_IRQ;
591
592 /* Alloc memory for this board (Mem for RxD/TxD) : */
593 if(!BoardAllocMem(pAC)) {
594 printk("No memory for descriptor rings.\n");
595 return -ENOMEM;
596 }
597
598 BoardInitMem(pAC);
599 /* tschilling: New common function with minimum size check. */
600 DualNet = SK_FALSE;
601 if (pAC->RlmtNets == 2) {
602 DualNet = SK_TRUE;
603 }
604
605 if (SkGeInitAssignRamToQueues(
606 pAC,
607 pAC->ActivePort,
608 DualNet)) {
609 BoardFreeMem(pAC);
610 printk("sk98lin: SkGeInitAssignRamToQueues failed.\n");
611 return -EIO;
612 }
613
614 return (0);
615} /* SkGeBoardInit */
616
617
618/*****************************************************************************
619 *
620 * BoardAllocMem - allocate the memory for the descriptor rings
621 *
622 * Description:
623 * This function allocates the memory for all descriptor rings.
624 * Each ring is aligned for the desriptor alignment and no ring
625 * has a 4 GByte boundary in it (because the upper 32 bit must
626 * be constant for all descriptiors in one rings).
627 *
628 * Returns:
629 * SK_TRUE, if all memory could be allocated
630 * SK_FALSE, if not
631 */
632static __devinit SK_BOOL BoardAllocMem(SK_AC *pAC)
633{
634caddr_t pDescrMem; /* pointer to descriptor memory area */
635size_t AllocLength; /* length of complete descriptor area */
636int i; /* loop counter */
637unsigned long BusAddr;
638
639
640 /* rings plus one for alignment (do not cross 4 GB boundary) */
641 /* RX_RING_SIZE is assumed bigger than TX_RING_SIZE */
642#if (BITS_PER_LONG == 32)
643 AllocLength = (RX_RING_SIZE + TX_RING_SIZE) * pAC->GIni.GIMacsFound + 8;
644#else
645 AllocLength = (RX_RING_SIZE + TX_RING_SIZE) * pAC->GIni.GIMacsFound
646 + RX_RING_SIZE + 8;
647#endif
648
649 pDescrMem = pci_alloc_consistent(pAC->PciDev, AllocLength,
650 &pAC->pDescrMemDMA);
651
652 if (pDescrMem == NULL) {
653 return (SK_FALSE);
654 }
655 pAC->pDescrMem = pDescrMem;
656 BusAddr = (unsigned long) pAC->pDescrMemDMA;
657
658 /* Descriptors need 8 byte alignment, and this is ensured
659 * by pci_alloc_consistent.
660 */
661 for (i=0; i<pAC->GIni.GIMacsFound; i++) {
662 SK_DBG_MSG(NULL, SK_DBGMOD_DRV, SK_DBGCAT_DRV_TX_PROGRESS,
663 ("TX%d/A: pDescrMem: %lX, PhysDescrMem: %lX\n",
664 i, (unsigned long) pDescrMem,
665 BusAddr));
666 pAC->TxPort[i][0].pTxDescrRing = pDescrMem;
667 pAC->TxPort[i][0].VTxDescrRing = BusAddr;
668 pDescrMem += TX_RING_SIZE;
669 BusAddr += TX_RING_SIZE;
670
671 SK_DBG_MSG(NULL, SK_DBGMOD_DRV, SK_DBGCAT_DRV_TX_PROGRESS,
672 ("RX%d: pDescrMem: %lX, PhysDescrMem: %lX\n",
673 i, (unsigned long) pDescrMem,
674 (unsigned long)BusAddr));
675 pAC->RxPort[i].pRxDescrRing = pDescrMem;
676 pAC->RxPort[i].VRxDescrRing = BusAddr;
677 pDescrMem += RX_RING_SIZE;
678 BusAddr += RX_RING_SIZE;
679 } /* for */
680
681 return (SK_TRUE);
682} /* BoardAllocMem */
683
684
685/****************************************************************************
686 *
687 * BoardFreeMem - reverse of BoardAllocMem
688 *
689 * Description:
690 * Free all memory allocated in BoardAllocMem: adapter context,
691 * descriptor rings, locks.
692 *
693 * Returns: N/A
694 */
695static void BoardFreeMem(
696SK_AC *pAC)
697{
698size_t AllocLength; /* length of complete descriptor area */
699
700 SK_DBG_MSG(NULL, SK_DBGMOD_DRV, SK_DBGCAT_DRV_ENTRY,
701 ("BoardFreeMem\n"));
702#if (BITS_PER_LONG == 32)
703 AllocLength = (RX_RING_SIZE + TX_RING_SIZE) * pAC->GIni.GIMacsFound + 8;
704#else
705 AllocLength = (RX_RING_SIZE + TX_RING_SIZE) * pAC->GIni.GIMacsFound
706 + RX_RING_SIZE + 8;
707#endif
708
709 pci_free_consistent(pAC->PciDev, AllocLength,
710 pAC->pDescrMem, pAC->pDescrMemDMA);
711 pAC->pDescrMem = NULL;
712} /* BoardFreeMem */
713
714
715/*****************************************************************************
716 *
717 * BoardInitMem - initiate the descriptor rings
718 *
719 * Description:
720 * This function sets the descriptor rings up in memory.
721 * The adapter is initialized with the descriptor start addresses.
722 *
723 * Returns: N/A
724 */
725static __devinit void BoardInitMem(SK_AC *pAC)
726{
727int i; /* loop counter */
728int RxDescrSize; /* the size of a rx descriptor rounded up to alignment*/
729int TxDescrSize; /* the size of a tx descriptor rounded up to alignment*/
730
731 SK_DBG_MSG(NULL, SK_DBGMOD_DRV, SK_DBGCAT_DRV_ENTRY,
732 ("BoardInitMem\n"));
733
734 RxDescrSize = (((sizeof(RXD) - 1) / DESCR_ALIGN) + 1) * DESCR_ALIGN;
735 pAC->RxDescrPerRing = RX_RING_SIZE / RxDescrSize;
736 TxDescrSize = (((sizeof(TXD) - 1) / DESCR_ALIGN) + 1) * DESCR_ALIGN;
737 pAC->TxDescrPerRing = TX_RING_SIZE / RxDescrSize;
738
739 for (i=0; i<pAC->GIni.GIMacsFound; i++) {
740 SetupRing(
741 pAC,
742 pAC->TxPort[i][0].pTxDescrRing,
743 pAC->TxPort[i][0].VTxDescrRing,
744 (RXD**)&pAC->TxPort[i][0].pTxdRingHead,
745 (RXD**)&pAC->TxPort[i][0].pTxdRingTail,
746 (RXD**)&pAC->TxPort[i][0].pTxdRingPrev,
747 &pAC->TxPort[i][0].TxdRingFree,
748 SK_TRUE);
749 SetupRing(
750 pAC,
751 pAC->RxPort[i].pRxDescrRing,
752 pAC->RxPort[i].VRxDescrRing,
753 &pAC->RxPort[i].pRxdRingHead,
754 &pAC->RxPort[i].pRxdRingTail,
755 &pAC->RxPort[i].pRxdRingPrev,
756 &pAC->RxPort[i].RxdRingFree,
757 SK_FALSE);
758 }
759} /* BoardInitMem */
760
761
762/*****************************************************************************
763 *
764 * SetupRing - create one descriptor ring
765 *
766 * Description:
767 * This function creates one descriptor ring in the given memory area.
768 * The head, tail and number of free descriptors in the ring are set.
769 *
770 * Returns:
771 * none
772 */
773static void SetupRing(
774SK_AC *pAC,
775void *pMemArea, /* a pointer to the memory area for the ring */
776uintptr_t VMemArea, /* the virtual bus address of the memory area */
777RXD **ppRingHead, /* address where the head should be written */
778RXD **ppRingTail, /* address where the tail should be written */
779RXD **ppRingPrev, /* address where the tail should be written */
780int *pRingFree, /* address where the # of free descr. goes */
781SK_BOOL IsTx) /* flag: is this a tx ring */
782{
783int i; /* loop counter */
784int DescrSize; /* the size of a descriptor rounded up to alignment*/
785int DescrNum; /* number of descriptors per ring */
786RXD *pDescr; /* pointer to a descriptor (receive or transmit) */
787RXD *pNextDescr; /* pointer to the next descriptor */
788RXD *pPrevDescr; /* pointer to the previous descriptor */
789uintptr_t VNextDescr; /* the virtual bus address of the next descriptor */
790
791 if (IsTx == SK_TRUE) {
792 DescrSize = (((sizeof(TXD) - 1) / DESCR_ALIGN) + 1) *
793 DESCR_ALIGN;
794 DescrNum = TX_RING_SIZE / DescrSize;
795 } else {
796 DescrSize = (((sizeof(RXD) - 1) / DESCR_ALIGN) + 1) *
797 DESCR_ALIGN;
798 DescrNum = RX_RING_SIZE / DescrSize;
799 }
800
801 SK_DBG_MSG(NULL, SK_DBGMOD_DRV, SK_DBGCAT_DRV_TX_PROGRESS,
802 ("Descriptor size: %d Descriptor Number: %d\n",
803 DescrSize,DescrNum));
804
805 pDescr = (RXD*) pMemArea;
806 pPrevDescr = NULL;
807 pNextDescr = (RXD*) (((char*)pDescr) + DescrSize);
808 VNextDescr = VMemArea + DescrSize;
809 for(i=0; i<DescrNum; i++) {
810 /* set the pointers right */
811 pDescr->VNextRxd = VNextDescr & 0xffffffffULL;
812 pDescr->pNextRxd = pNextDescr;
813 if (!IsTx) pDescr->TcpSumStarts = ETH_HLEN << 16 | ETH_HLEN;
814
815 /* advance one step */
816 pPrevDescr = pDescr;
817 pDescr = pNextDescr;
818 pNextDescr = (RXD*) (((char*)pDescr) + DescrSize);
819 VNextDescr += DescrSize;
820 }
821 pPrevDescr->pNextRxd = (RXD*) pMemArea;
822 pPrevDescr->VNextRxd = VMemArea;
823 pDescr = (RXD*) pMemArea;
824 *ppRingHead = (RXD*) pMemArea;
825 *ppRingTail = *ppRingHead;
826 *ppRingPrev = pPrevDescr;
827 *pRingFree = DescrNum;
828} /* SetupRing */
829
830
831/*****************************************************************************
832 *
833 * PortReInitBmu - re-initiate the descriptor rings for one port
834 *
835 * Description:
836 * This function reinitializes the descriptor rings of one port
837 * in memory. The port must be stopped before.
838 * The HW is initialized with the descriptor start addresses.
839 *
840 * Returns:
841 * none
842 */
843static void PortReInitBmu(
844SK_AC *pAC, /* pointer to adapter context */
845int PortIndex) /* index of the port for which to re-init */
846{
847 SK_DBG_MSG(NULL, SK_DBGMOD_DRV, SK_DBGCAT_DRV_ENTRY,
848 ("PortReInitBmu "));
849
850 /* set address of first descriptor of ring in BMU */
851 SK_OUT32(pAC->IoBase, TxQueueAddr[PortIndex][TX_PRIO_LOW]+ Q_DA_L,
852 (uint32_t)(((caddr_t)
853 (pAC->TxPort[PortIndex][TX_PRIO_LOW].pTxdRingHead) -
854 pAC->TxPort[PortIndex][TX_PRIO_LOW].pTxDescrRing +
855 pAC->TxPort[PortIndex][TX_PRIO_LOW].VTxDescrRing) &
856 0xFFFFFFFF));
857 SK_OUT32(pAC->IoBase, TxQueueAddr[PortIndex][TX_PRIO_LOW]+ Q_DA_H,
858 (uint32_t)(((caddr_t)
859 (pAC->TxPort[PortIndex][TX_PRIO_LOW].pTxdRingHead) -
860 pAC->TxPort[PortIndex][TX_PRIO_LOW].pTxDescrRing +
861 pAC->TxPort[PortIndex][TX_PRIO_LOW].VTxDescrRing) >> 32));
862 SK_OUT32(pAC->IoBase, RxQueueAddr[PortIndex]+Q_DA_L,
863 (uint32_t)(((caddr_t)(pAC->RxPort[PortIndex].pRxdRingHead) -
864 pAC->RxPort[PortIndex].pRxDescrRing +
865 pAC->RxPort[PortIndex].VRxDescrRing) & 0xFFFFFFFF));
866 SK_OUT32(pAC->IoBase, RxQueueAddr[PortIndex]+Q_DA_H,
867 (uint32_t)(((caddr_t)(pAC->RxPort[PortIndex].pRxdRingHead) -
868 pAC->RxPort[PortIndex].pRxDescrRing +
869 pAC->RxPort[PortIndex].VRxDescrRing) >> 32));
870} /* PortReInitBmu */
871
872
873/****************************************************************************
874 *
875 * SkGeIsr - handle adapter interrupts
876 *
877 * Description:
878 * The interrupt routine is called when the network adapter
879 * generates an interrupt. It may also be called if another device
880 * shares this interrupt vector with the driver.
881 *
882 * Returns: N/A
883 *
884 */
885static SkIsrRetVar SkGeIsr(int irq, void *dev_id)
886{
887struct SK_NET_DEVICE *dev = (struct SK_NET_DEVICE *)dev_id;
888DEV_NET *pNet;
889SK_AC *pAC;
890SK_U32 IntSrc; /* interrupts source register contents */
891
892 pNet = netdev_priv(dev);
893 pAC = pNet->pAC;
894
895 /*
896 * Check and process if its our interrupt
897 */
898 SK_IN32(pAC->IoBase, B0_SP_ISRC, &IntSrc);
899 if (IntSrc == 0) {
900 return SkIsrRetNone;
901 }
902
903 while (((IntSrc & IRQ_MASK) & ~SPECIAL_IRQS) != 0) {
904#if 0 /* software irq currently not used */
905 if (IntSrc & IS_IRQ_SW) {
906 SK_DBG_MSG(NULL, SK_DBGMOD_DRV,
907 SK_DBGCAT_DRV_INT_SRC,
908 ("Software IRQ\n"));
909 }
910#endif
911 if (IntSrc & IS_R1_F) {
912 SK_DBG_MSG(NULL, SK_DBGMOD_DRV,
913 SK_DBGCAT_DRV_INT_SRC,
914 ("EOF RX1 IRQ\n"));
915 ReceiveIrq(pAC, &pAC->RxPort[0], SK_TRUE);
916 SK_PNMI_CNT_RX_INTR(pAC, 0);
917 }
918 if (IntSrc & IS_R2_F) {
919 SK_DBG_MSG(NULL, SK_DBGMOD_DRV,
920 SK_DBGCAT_DRV_INT_SRC,
921 ("EOF RX2 IRQ\n"));
922 ReceiveIrq(pAC, &pAC->RxPort[1], SK_TRUE);
923 SK_PNMI_CNT_RX_INTR(pAC, 1);
924 }
925#ifdef USE_TX_COMPLETE /* only if tx complete interrupt used */
926 if (IntSrc & IS_XA1_F) {
927 SK_DBG_MSG(NULL, SK_DBGMOD_DRV,
928 SK_DBGCAT_DRV_INT_SRC,
929 ("EOF AS TX1 IRQ\n"));
930 SK_PNMI_CNT_TX_INTR(pAC, 0);
931 spin_lock(&pAC->TxPort[0][TX_PRIO_LOW].TxDesRingLock);
932 FreeTxDescriptors(pAC, &pAC->TxPort[0][TX_PRIO_LOW]);
933 spin_unlock(&pAC->TxPort[0][TX_PRIO_LOW].TxDesRingLock);
934 }
935 if (IntSrc & IS_XA2_F) {
936 SK_DBG_MSG(NULL, SK_DBGMOD_DRV,
937 SK_DBGCAT_DRV_INT_SRC,
938 ("EOF AS TX2 IRQ\n"));
939 SK_PNMI_CNT_TX_INTR(pAC, 1);
940 spin_lock(&pAC->TxPort[1][TX_PRIO_LOW].TxDesRingLock);
941 FreeTxDescriptors(pAC, &pAC->TxPort[1][TX_PRIO_LOW]);
942 spin_unlock(&pAC->TxPort[1][TX_PRIO_LOW].TxDesRingLock);
943 }
944#if 0 /* only if sync. queues used */
945 if (IntSrc & IS_XS1_F) {
946 SK_DBG_MSG(NULL, SK_DBGMOD_DRV,
947 SK_DBGCAT_DRV_INT_SRC,
948 ("EOF SY TX1 IRQ\n"));
949 SK_PNMI_CNT_TX_INTR(pAC, 1);
950 spin_lock(&pAC->TxPort[0][TX_PRIO_HIGH].TxDesRingLock);
951 FreeTxDescriptors(pAC, 0, TX_PRIO_HIGH);
952 spin_unlock(&pAC->TxPort[0][TX_PRIO_HIGH].TxDesRingLock);
953 ClearTxIrq(pAC, 0, TX_PRIO_HIGH);
954 }
955 if (IntSrc & IS_XS2_F) {
956 SK_DBG_MSG(NULL, SK_DBGMOD_DRV,
957 SK_DBGCAT_DRV_INT_SRC,
958 ("EOF SY TX2 IRQ\n"));
959 SK_PNMI_CNT_TX_INTR(pAC, 1);
960 spin_lock(&pAC->TxPort[1][TX_PRIO_HIGH].TxDesRingLock);
961 FreeTxDescriptors(pAC, 1, TX_PRIO_HIGH);
962 spin_unlock(&pAC->TxPort[1][TX_PRIO_HIGH].TxDesRingLock);
963 ClearTxIrq(pAC, 1, TX_PRIO_HIGH);
964 }
965#endif
966#endif
967
968 /* do all IO at once */
969 if (IntSrc & IS_R1_F)
970 ClearAndStartRx(pAC, 0);
971 if (IntSrc & IS_R2_F)
972 ClearAndStartRx(pAC, 1);
973#ifdef USE_TX_COMPLETE /* only if tx complete interrupt used */
974 if (IntSrc & IS_XA1_F)
975 ClearTxIrq(pAC, 0, TX_PRIO_LOW);
976 if (IntSrc & IS_XA2_F)
977 ClearTxIrq(pAC, 1, TX_PRIO_LOW);
978#endif
979 SK_IN32(pAC->IoBase, B0_ISRC, &IntSrc);
980 } /* while (IntSrc & IRQ_MASK != 0) */
981
982 IntSrc &= pAC->GIni.GIValIrqMask;
983 if ((IntSrc & SPECIAL_IRQS) || pAC->CheckQueue) {
984 SK_DBG_MSG(NULL, SK_DBGMOD_DRV, SK_DBGCAT_DRV_INT_SRC,
985 ("SPECIAL IRQ DP-Cards => %x\n", IntSrc));
986 pAC->CheckQueue = SK_FALSE;
987 spin_lock(&pAC->SlowPathLock);
988 if (IntSrc & SPECIAL_IRQS)
989 SkGeSirqIsr(pAC, pAC->IoBase, IntSrc);
990
991 SkEventDispatcher(pAC, pAC->IoBase);
992 spin_unlock(&pAC->SlowPathLock);
993 }
994 /*
995 * do it all again is case we cleared an interrupt that
996 * came in after handling the ring (OUTs may be delayed
997 * in hardware buffers, but are through after IN)
998 *
999 * rroesler: has been commented out and shifted to
1000 * SkGeDrvEvent(), because it is timer
1001 * guarded now
1002 *
1003 ReceiveIrq(pAC, &pAC->RxPort[0], SK_TRUE);
1004 ReceiveIrq(pAC, &pAC->RxPort[1], SK_TRUE);
1005 */
1006
1007 if (pAC->CheckQueue) {
1008 pAC->CheckQueue = SK_FALSE;
1009 spin_lock(&pAC->SlowPathLock);
1010 SkEventDispatcher(pAC, pAC->IoBase);
1011 spin_unlock(&pAC->SlowPathLock);
1012 }
1013
1014 /* IRQ is processed - Enable IRQs again*/
1015 SK_OUT32(pAC->IoBase, B0_IMSK, pAC->GIni.GIValIrqMask);
1016
1017 return SkIsrRetHandled;
1018} /* SkGeIsr */
1019
1020
1021/****************************************************************************
1022 *
1023 * SkGeIsrOnePort - handle adapter interrupts for single port adapter
1024 *
1025 * Description:
1026 * The interrupt routine is called when the network adapter
1027 * generates an interrupt. It may also be called if another device
1028 * shares this interrupt vector with the driver.
1029 * This is the same as above, but handles only one port.
1030 *
1031 * Returns: N/A
1032 *
1033 */
1034static SkIsrRetVar SkGeIsrOnePort(int irq, void *dev_id)
1035{
1036struct SK_NET_DEVICE *dev = (struct SK_NET_DEVICE *)dev_id;
1037DEV_NET *pNet;
1038SK_AC *pAC;
1039SK_U32 IntSrc; /* interrupts source register contents */
1040
1041 pNet = netdev_priv(dev);
1042 pAC = pNet->pAC;
1043
1044 /*
1045 * Check and process if its our interrupt
1046 */
1047 SK_IN32(pAC->IoBase, B0_SP_ISRC, &IntSrc);
1048 if (IntSrc == 0) {
1049 return SkIsrRetNone;
1050 }
1051
1052 while (((IntSrc & IRQ_MASK) & ~SPECIAL_IRQS) != 0) {
1053#if 0 /* software irq currently not used */
1054 if (IntSrc & IS_IRQ_SW) {
1055 SK_DBG_MSG(NULL, SK_DBGMOD_DRV,
1056 SK_DBGCAT_DRV_INT_SRC,
1057 ("Software IRQ\n"));
1058 }
1059#endif
1060 if (IntSrc & IS_R1_F) {
1061 SK_DBG_MSG(NULL, SK_DBGMOD_DRV,
1062 SK_DBGCAT_DRV_INT_SRC,
1063 ("EOF RX1 IRQ\n"));
1064 ReceiveIrq(pAC, &pAC->RxPort[0], SK_TRUE);
1065 SK_PNMI_CNT_RX_INTR(pAC, 0);
1066 }
1067#ifdef USE_TX_COMPLETE /* only if tx complete interrupt used */
1068 if (IntSrc & IS_XA1_F) {
1069 SK_DBG_MSG(NULL, SK_DBGMOD_DRV,
1070 SK_DBGCAT_DRV_INT_SRC,
1071 ("EOF AS TX1 IRQ\n"));
1072 SK_PNMI_CNT_TX_INTR(pAC, 0);
1073 spin_lock(&pAC->TxPort[0][TX_PRIO_LOW].TxDesRingLock);
1074 FreeTxDescriptors(pAC, &pAC->TxPort[0][TX_PRIO_LOW]);
1075 spin_unlock(&pAC->TxPort[0][TX_PRIO_LOW].TxDesRingLock);
1076 }
1077#if 0 /* only if sync. queues used */
1078 if (IntSrc & IS_XS1_F) {
1079 SK_DBG_MSG(NULL, SK_DBGMOD_DRV,
1080 SK_DBGCAT_DRV_INT_SRC,
1081 ("EOF SY TX1 IRQ\n"));
1082 SK_PNMI_CNT_TX_INTR(pAC, 0);
1083 spin_lock(&pAC->TxPort[0][TX_PRIO_HIGH].TxDesRingLock);
1084 FreeTxDescriptors(pAC, 0, TX_PRIO_HIGH);
1085 spin_unlock(&pAC->TxPort[0][TX_PRIO_HIGH].TxDesRingLock);
1086 ClearTxIrq(pAC, 0, TX_PRIO_HIGH);
1087 }
1088#endif
1089#endif
1090
1091 /* do all IO at once */
1092 if (IntSrc & IS_R1_F)
1093 ClearAndStartRx(pAC, 0);
1094#ifdef USE_TX_COMPLETE /* only if tx complete interrupt used */
1095 if (IntSrc & IS_XA1_F)
1096 ClearTxIrq(pAC, 0, TX_PRIO_LOW);
1097#endif
1098 SK_IN32(pAC->IoBase, B0_ISRC, &IntSrc);
1099 } /* while (IntSrc & IRQ_MASK != 0) */
1100
1101 IntSrc &= pAC->GIni.GIValIrqMask;
1102 if ((IntSrc & SPECIAL_IRQS) || pAC->CheckQueue) {
1103 SK_DBG_MSG(NULL, SK_DBGMOD_DRV, SK_DBGCAT_DRV_INT_SRC,
1104 ("SPECIAL IRQ SP-Cards => %x\n", IntSrc));
1105 pAC->CheckQueue = SK_FALSE;
1106 spin_lock(&pAC->SlowPathLock);
1107 if (IntSrc & SPECIAL_IRQS)
1108 SkGeSirqIsr(pAC, pAC->IoBase, IntSrc);
1109
1110 SkEventDispatcher(pAC, pAC->IoBase);
1111 spin_unlock(&pAC->SlowPathLock);
1112 }
1113 /*
1114 * do it all again is case we cleared an interrupt that
1115 * came in after handling the ring (OUTs may be delayed
1116 * in hardware buffers, but are through after IN)
1117 *
1118 * rroesler: has been commented out and shifted to
1119 * SkGeDrvEvent(), because it is timer
1120 * guarded now
1121 *
1122 ReceiveIrq(pAC, &pAC->RxPort[0], SK_TRUE);
1123 */
1124
1125 /* IRQ is processed - Enable IRQs again*/
1126 SK_OUT32(pAC->IoBase, B0_IMSK, pAC->GIni.GIValIrqMask);
1127
1128 return SkIsrRetHandled;
1129} /* SkGeIsrOnePort */
1130
1131#ifdef CONFIG_NET_POLL_CONTROLLER
1132/****************************************************************************
1133 *
1134 * SkGePollController - polling receive, for netconsole
1135 *
1136 * Description:
1137 * Polling receive - used by netconsole and other diagnostic tools
1138 * to allow network i/o with interrupts disabled.
1139 *
1140 * Returns: N/A
1141 */
1142static void SkGePollController(struct net_device *dev)
1143{
1144 disable_irq(dev->irq);
1145 SkGeIsr(dev->irq, dev);
1146 enable_irq(dev->irq);
1147}
1148#endif
1149
1150/****************************************************************************
1151 *
1152 * SkGeOpen - handle start of initialized adapter
1153 *
1154 * Description:
1155 * This function starts the initialized adapter.
1156 * The board level variable is set and the adapter is
1157 * brought to full functionality.
1158 * The device flags are set for operation.
1159 * Do all necessary level 2 initialization, enable interrupts and
1160 * give start command to RLMT.
1161 *
1162 * Returns:
1163 * 0 on success
1164 * != 0 on error
1165 */
1166static int SkGeOpen(
1167struct SK_NET_DEVICE *dev)
1168{
1169 DEV_NET *pNet;
1170 SK_AC *pAC;
1171 unsigned long Flags; /* for spin lock */
1172 int i;
1173 SK_EVPARA EvPara; /* an event parameter union */
1174
1175 pNet = netdev_priv(dev);
1176 pAC = pNet->pAC;
1177
1178 SK_DBG_MSG(NULL, SK_DBGMOD_DRV, SK_DBGCAT_DRV_ENTRY,
1179 ("SkGeOpen: pAC=0x%lX:\n", (unsigned long)pAC));
1180
1181#ifdef SK_DIAG_SUPPORT
1182 if (pAC->DiagModeActive == DIAG_ACTIVE) {
1183 if (pAC->Pnmi.DiagAttached == SK_DIAG_RUNNING) {
1184 return (-1); /* still in use by diag; deny actions */
1185 }
1186 }
1187#endif
1188
1189 /* Set blink mode */
1190 if ((pAC->PciDev->vendor == 0x1186) || (pAC->PciDev->vendor == 0x11ab ))
1191 pAC->GIni.GILedBlinkCtrl = OEM_CONFIG_VALUE;
1192
1193 if (pAC->BoardLevel == SK_INIT_DATA) {
1194 /* level 1 init common modules here */
1195 if (SkGeInit(pAC, pAC->IoBase, SK_INIT_IO) != 0) {
1196 printk("%s: HWInit (1) failed.\n", pAC->dev[pNet->PortNr]->name);
1197 return (-1);
1198 }
1199 SkI2cInit (pAC, pAC->IoBase, SK_INIT_IO);
1200 SkEventInit (pAC, pAC->IoBase, SK_INIT_IO);
1201 SkPnmiInit (pAC, pAC->IoBase, SK_INIT_IO);
1202 SkAddrInit (pAC, pAC->IoBase, SK_INIT_IO);
1203 SkRlmtInit (pAC, pAC->IoBase, SK_INIT_IO);
1204 SkTimerInit (pAC, pAC->IoBase, SK_INIT_IO);
1205 pAC->BoardLevel = SK_INIT_IO;
1206 }
1207
1208 if (pAC->BoardLevel != SK_INIT_RUN) {
1209 /* tschilling: Level 2 init modules here, check return value. */
1210 if (SkGeInit(pAC, pAC->IoBase, SK_INIT_RUN) != 0) {
1211 printk("%s: HWInit (2) failed.\n", pAC->dev[pNet->PortNr]->name);
1212 return (-1);
1213 }
1214 SkI2cInit (pAC, pAC->IoBase, SK_INIT_RUN);
1215 SkEventInit (pAC, pAC->IoBase, SK_INIT_RUN);
1216 SkPnmiInit (pAC, pAC->IoBase, SK_INIT_RUN);
1217 SkAddrInit (pAC, pAC->IoBase, SK_INIT_RUN);
1218 SkRlmtInit (pAC, pAC->IoBase, SK_INIT_RUN);
1219 SkTimerInit (pAC, pAC->IoBase, SK_INIT_RUN);
1220 pAC->BoardLevel = SK_INIT_RUN;
1221 }
1222
1223 for (i=0; i<pAC->GIni.GIMacsFound; i++) {
1224 /* Enable transmit descriptor polling. */
1225 SkGePollTxD(pAC, pAC->IoBase, i, SK_TRUE);
1226 FillRxRing(pAC, &pAC->RxPort[i]);
1227 }
1228 SkGeYellowLED(pAC, pAC->IoBase, 1);
1229
1230 StartDrvCleanupTimer(pAC);
1231 SkDimEnableModerationIfNeeded(pAC);
1232 SkDimDisplayModerationSettings(pAC);
1233
1234 pAC->GIni.GIValIrqMask &= IRQ_MASK;
1235
1236 /* enable Interrupts */
1237 SK_OUT32(pAC->IoBase, B0_IMSK, pAC->GIni.GIValIrqMask);
1238 SK_OUT32(pAC->IoBase, B0_HWE_IMSK, IRQ_HWE_MASK);
1239
1240 spin_lock_irqsave(&pAC->SlowPathLock, Flags);
1241
1242 if ((pAC->RlmtMode != 0) && (pAC->MaxPorts == 0)) {
1243 EvPara.Para32[0] = pAC->RlmtNets;
1244 EvPara.Para32[1] = -1;
1245 SkEventQueue(pAC, SKGE_RLMT, SK_RLMT_SET_NETS,
1246 EvPara);
1247 EvPara.Para32[0] = pAC->RlmtMode;
1248 EvPara.Para32[1] = 0;
1249 SkEventQueue(pAC, SKGE_RLMT, SK_RLMT_MODE_CHANGE,
1250 EvPara);
1251 }
1252
1253 EvPara.Para32[0] = pNet->NetNr;
1254 EvPara.Para32[1] = -1;
1255 SkEventQueue(pAC, SKGE_RLMT, SK_RLMT_START, EvPara);
1256 SkEventDispatcher(pAC, pAC->IoBase);
1257 spin_unlock_irqrestore(&pAC->SlowPathLock, Flags);
1258
1259 pAC->MaxPorts++;
1260
1261
1262 SK_DBG_MSG(NULL, SK_DBGMOD_DRV, SK_DBGCAT_DRV_ENTRY,
1263 ("SkGeOpen suceeded\n"));
1264
1265 return (0);
1266} /* SkGeOpen */
1267
1268
1269/****************************************************************************
1270 *
1271 * SkGeClose - Stop initialized adapter
1272 *
1273 * Description:
1274 * Close initialized adapter.
1275 *
1276 * Returns:
1277 * 0 - on success
1278 * error code - on error
1279 */
1280static int SkGeClose(
1281struct SK_NET_DEVICE *dev)
1282{
1283 DEV_NET *pNet;
1284 DEV_NET *newPtrNet;
1285 SK_AC *pAC;
1286
1287 unsigned long Flags; /* for spin lock */
1288 int i;
1289 int PortIdx;
1290 SK_EVPARA EvPara;
1291
1292 SK_DBG_MSG(NULL, SK_DBGMOD_DRV, SK_DBGCAT_DRV_ENTRY,
1293 ("SkGeClose: pAC=0x%lX ", (unsigned long)pAC));
1294
1295 pNet = netdev_priv(dev);
1296 pAC = pNet->pAC;
1297
1298#ifdef SK_DIAG_SUPPORT
1299 if (pAC->DiagModeActive == DIAG_ACTIVE) {
1300 if (pAC->DiagFlowCtrl == SK_FALSE) {
1301 /*
1302 ** notify that the interface which has been closed
1303 ** by operator interaction must not be started up
1304 ** again when the DIAG has finished.
1305 */
1306 newPtrNet = netdev_priv(pAC->dev[0]);
1307 if (newPtrNet == pNet) {
1308 pAC->WasIfUp[0] = SK_FALSE;
1309 } else {
1310 pAC->WasIfUp[1] = SK_FALSE;
1311 }
1312 return 0; /* return to system everything is fine... */
1313 } else {
1314 pAC->DiagFlowCtrl = SK_FALSE;
1315 }
1316 }
1317#endif
1318
1319 netif_stop_queue(dev);
1320
1321 if (pAC->RlmtNets == 1)
1322 PortIdx = pAC->ActivePort;
1323 else
1324 PortIdx = pNet->NetNr;
1325
1326 StopDrvCleanupTimer(pAC);
1327
1328 /*
1329 * Clear multicast table, promiscuous mode ....
1330 */
1331 SkAddrMcClear(pAC, pAC->IoBase, PortIdx, 0);
1332 SkAddrPromiscuousChange(pAC, pAC->IoBase, PortIdx,
1333 SK_PROM_MODE_NONE);
1334
1335 if (pAC->MaxPorts == 1) {
1336 spin_lock_irqsave(&pAC->SlowPathLock, Flags);
1337 /* disable interrupts */
1338 SK_OUT32(pAC->IoBase, B0_IMSK, 0);
1339 EvPara.Para32[0] = pNet->NetNr;
1340 EvPara.Para32[1] = -1;
1341 SkEventQueue(pAC, SKGE_RLMT, SK_RLMT_STOP, EvPara);
1342 SkEventDispatcher(pAC, pAC->IoBase);
1343 SK_OUT32(pAC->IoBase, B0_IMSK, 0);
1344 /* stop the hardware */
1345 SkGeDeInit(pAC, pAC->IoBase);
1346 pAC->BoardLevel = SK_INIT_DATA;
1347 spin_unlock_irqrestore(&pAC->SlowPathLock, Flags);
1348 } else {
1349
1350 spin_lock_irqsave(&pAC->SlowPathLock, Flags);
1351 EvPara.Para32[0] = pNet->NetNr;
1352 EvPara.Para32[1] = -1;
1353 SkEventQueue(pAC, SKGE_RLMT, SK_RLMT_STOP, EvPara);
1354 SkPnmiEvent(pAC, pAC->IoBase, SK_PNMI_EVT_XMAC_RESET, EvPara);
1355 SkEventDispatcher(pAC, pAC->IoBase);
1356 spin_unlock_irqrestore(&pAC->SlowPathLock, Flags);
1357
1358 /* Stop port */
1359 spin_lock_irqsave(&pAC->TxPort[pNet->PortNr]
1360 [TX_PRIO_LOW].TxDesRingLock, Flags);
1361 SkGeStopPort(pAC, pAC->IoBase, pNet->PortNr,
1362 SK_STOP_ALL, SK_HARD_RST);
1363 spin_unlock_irqrestore(&pAC->TxPort[pNet->PortNr]
1364 [TX_PRIO_LOW].TxDesRingLock, Flags);
1365 }
1366
1367 if (pAC->RlmtNets == 1) {
1368 /* clear all descriptor rings */
1369 for (i=0; i<pAC->GIni.GIMacsFound; i++) {
1370 ReceiveIrq(pAC, &pAC->RxPort[i], SK_TRUE);
1371 ClearRxRing(pAC, &pAC->RxPort[i]);
1372 ClearTxRing(pAC, &pAC->TxPort[i][TX_PRIO_LOW]);
1373 }
1374 } else {
1375 /* clear port descriptor rings */
1376 ReceiveIrq(pAC, &pAC->RxPort[pNet->PortNr], SK_TRUE);
1377 ClearRxRing(pAC, &pAC->RxPort[pNet->PortNr]);
1378 ClearTxRing(pAC, &pAC->TxPort[pNet->PortNr][TX_PRIO_LOW]);
1379 }
1380
1381 SK_DBG_MSG(NULL, SK_DBGMOD_DRV, SK_DBGCAT_DRV_ENTRY,
1382 ("SkGeClose: done "));
1383
1384 SK_MEMSET(&(pAC->PnmiBackup), 0, sizeof(SK_PNMI_STRUCT_DATA));
1385 SK_MEMCPY(&(pAC->PnmiBackup), &(pAC->PnmiStruct),
1386 sizeof(SK_PNMI_STRUCT_DATA));
1387
1388 pAC->MaxPorts--;
1389
1390 return (0);
1391} /* SkGeClose */
1392
1393
1394/*****************************************************************************
1395 *
1396 * SkGeXmit - Linux frame transmit function
1397 *
1398 * Description:
1399 * The system calls this function to send frames onto the wire.
1400 * It puts the frame in the tx descriptor ring. If the ring is
1401 * full then, the 'tbusy' flag is set.
1402 *
1403 * Returns:
1404 * 0, if everything is ok
1405 * !=0, on error
1406 * WARNING: returning 1 in 'tbusy' case caused system crashes (double
1407 * allocated skb's) !!!
1408 */
1409static int SkGeXmit(struct sk_buff *skb, struct SK_NET_DEVICE *dev)
1410{
1411DEV_NET *pNet;
1412SK_AC *pAC;
1413int Rc; /* return code of XmitFrame */
1414
1415 pNet = netdev_priv(dev);
1416 pAC = pNet->pAC;
1417
1418 if ((!skb_shinfo(skb)->nr_frags) ||
1419 (pAC->GIni.GIChipId == CHIP_ID_GENESIS)) {
1420 /* Don't activate scatter-gather and hardware checksum */
1421
1422 if (pAC->RlmtNets == 2)
1423 Rc = XmitFrame(
1424 pAC,
1425 &pAC->TxPort[pNet->PortNr][TX_PRIO_LOW],
1426 skb);
1427 else
1428 Rc = XmitFrame(
1429 pAC,
1430 &pAC->TxPort[pAC->ActivePort][TX_PRIO_LOW],
1431 skb);
1432 } else {
1433 /* scatter-gather and hardware TCP checksumming anabled*/
1434 if (pAC->RlmtNets == 2)
1435 Rc = XmitFrameSG(
1436 pAC,
1437 &pAC->TxPort[pNet->PortNr][TX_PRIO_LOW],
1438 skb);
1439 else
1440 Rc = XmitFrameSG(
1441 pAC,
1442 &pAC->TxPort[pAC->ActivePort][TX_PRIO_LOW],
1443 skb);
1444 }
1445
1446 /* Transmitter out of resources? */
1447 if (Rc <= 0) {
1448 netif_stop_queue(dev);
1449 }
1450
1451 /* If not taken, give buffer ownership back to the
1452 * queueing layer.
1453 */
1454 if (Rc < 0)
1455 return (1);
1456
1457 dev->trans_start = jiffies;
1458 return (0);
1459} /* SkGeXmit */
1460
1461
1462/*****************************************************************************
1463 *
1464 * XmitFrame - fill one socket buffer into the transmit ring
1465 *
1466 * Description:
1467 * This function puts a message into the transmit descriptor ring
1468 * if there is a descriptors left.
1469 * Linux skb's consist of only one continuous buffer.
1470 * The first step locks the ring. It is held locked
1471 * all time to avoid problems with SWITCH_../PORT_RESET.
1472 * Then the descriptoris allocated.
1473 * The second part is linking the buffer to the descriptor.
1474 * At the very last, the Control field of the descriptor
1475 * is made valid for the BMU and a start TX command is given
1476 * if necessary.
1477 *
1478 * Returns:
1479 * > 0 - on succes: the number of bytes in the message
1480 * = 0 - on resource shortage: this frame sent or dropped, now
1481 * the ring is full ( -> set tbusy)
1482 * < 0 - on failure: other problems ( -> return failure to upper layers)
1483 */
1484static int XmitFrame(
1485SK_AC *pAC, /* pointer to adapter context */
1486TX_PORT *pTxPort, /* pointer to struct of port to send to */
1487struct sk_buff *pMessage) /* pointer to send-message */
1488{
1489 TXD *pTxd; /* the rxd to fill */
1490 TXD *pOldTxd;
1491 unsigned long Flags;
1492 SK_U64 PhysAddr;
1493 int BytesSend = pMessage->len;
1494
1495 SK_DBG_MSG(NULL, SK_DBGMOD_DRV, SK_DBGCAT_DRV_TX_PROGRESS, ("X"));
1496
1497 spin_lock_irqsave(&pTxPort->TxDesRingLock, Flags);
1498#ifndef USE_TX_COMPLETE
1499 FreeTxDescriptors(pAC, pTxPort);
1500#endif
1501 if (pTxPort->TxdRingFree == 0) {
1502 /*
1503 ** no enough free descriptors in ring at the moment.
1504 ** Maybe free'ing some old one help?
1505 */
1506 FreeTxDescriptors(pAC, pTxPort);
1507 if (pTxPort->TxdRingFree == 0) {
1508 spin_unlock_irqrestore(&pTxPort->TxDesRingLock, Flags);
1509 SK_PNMI_CNT_NO_TX_BUF(pAC, pTxPort->PortIndex);
1510 SK_DBG_MSG(NULL, SK_DBGMOD_DRV,
1511 SK_DBGCAT_DRV_TX_PROGRESS,
1512 ("XmitFrame failed\n"));
1513 /*
1514 ** the desired message can not be sent
1515 ** Because tbusy seems to be set, the message
1516 ** should not be freed here. It will be used
1517 ** by the scheduler of the ethernet handler
1518 */
1519 return (-1);
1520 }
1521 }
1522
1523 /*
1524 ** If the passed socket buffer is of smaller MTU-size than 60,
1525 ** copy everything into new buffer and fill all bytes between
1526 ** the original packet end and the new packet end of 60 with 0x00.
1527 ** This is to resolve faulty padding by the HW with 0xaa bytes.
1528 */
1529 if (BytesSend < C_LEN_ETHERNET_MINSIZE) {
1530 if (skb_padto(pMessage, C_LEN_ETHERNET_MINSIZE)) {
1531 spin_unlock_irqrestore(&pTxPort->TxDesRingLock, Flags);
1532 return 0;
1533 }
1534 pMessage->len = C_LEN_ETHERNET_MINSIZE;
1535 }
1536
1537 /*
1538 ** advance head counter behind descriptor needed for this frame,
1539 ** so that needed descriptor is reserved from that on. The next
1540 ** action will be to add the passed buffer to the TX-descriptor
1541 */
1542 pTxd = pTxPort->pTxdRingHead;
1543 pTxPort->pTxdRingHead = pTxd->pNextTxd;
1544 pTxPort->TxdRingFree--;
1545
1546#ifdef SK_DUMP_TX
1547 DumpMsg(pMessage, "XmitFrame");
1548#endif
1549
1550 /*
1551 ** First step is to map the data to be sent via the adapter onto
1552 ** the DMA memory. Kernel 2.2 uses virt_to_bus(), but kernels 2.4
1553 ** and 2.6 need to use pci_map_page() for that mapping.
1554 */
1555 PhysAddr = (SK_U64) pci_map_page(pAC->PciDev,
1556 virt_to_page(pMessage->data),
1557 ((unsigned long) pMessage->data & ~PAGE_MASK),
1558 pMessage->len,
1559 PCI_DMA_TODEVICE);
1560 pTxd->VDataLow = (SK_U32) (PhysAddr & 0xffffffff);
1561 pTxd->VDataHigh = (SK_U32) (PhysAddr >> 32);
1562 pTxd->pMBuf = pMessage;
1563
1564 if (pMessage->ip_summed == CHECKSUM_PARTIAL) {
1565 u16 hdrlen = skb_transport_offset(pMessage);
1566 u16 offset = hdrlen + pMessage->csum_offset;
1567
1568 if ((ipip_hdr(pMessage)->protocol == IPPROTO_UDP) &&
1569 (pAC->GIni.GIChipRev == 0) &&
1570 (pAC->GIni.GIChipId == CHIP_ID_YUKON)) {
1571 pTxd->TBControl = BMU_TCP_CHECK;
1572 } else {
1573 pTxd->TBControl = BMU_UDP_CHECK;
1574 }
1575
1576 pTxd->TcpSumOfs = 0;
1577 pTxd->TcpSumSt = hdrlen;
1578 pTxd->TcpSumWr = offset;
1579
1580 pTxd->TBControl |= BMU_OWN | BMU_STF |
1581 BMU_SW | BMU_EOF |
1582#ifdef USE_TX_COMPLETE
1583 BMU_IRQ_EOF |
1584#endif
1585 pMessage->len;
1586 } else {
1587 pTxd->TBControl = BMU_OWN | BMU_STF | BMU_CHECK |
1588 BMU_SW | BMU_EOF |
1589#ifdef USE_TX_COMPLETE
1590 BMU_IRQ_EOF |
1591#endif
1592 pMessage->len;
1593 }
1594
1595 /*
1596 ** If previous descriptor already done, give TX start cmd
1597 */
1598 pOldTxd = xchg(&pTxPort->pTxdRingPrev, pTxd);
1599 if ((pOldTxd->TBControl & BMU_OWN) == 0) {
1600 SK_OUT8(pTxPort->HwAddr, Q_CSR, CSR_START);
1601 }
1602
1603 /*
1604 ** after releasing the lock, the skb may immediately be free'd
1605 */
1606 spin_unlock_irqrestore(&pTxPort->TxDesRingLock, Flags);
1607 if (pTxPort->TxdRingFree != 0) {
1608 return (BytesSend);
1609 } else {
1610 return (0);
1611 }
1612
1613} /* XmitFrame */
1614
1615/*****************************************************************************
1616 *
1617 * XmitFrameSG - fill one socket buffer into the transmit ring
1618 * (use SG and TCP/UDP hardware checksumming)
1619 *
1620 * Description:
1621 * This function puts a message into the transmit descriptor ring
1622 * if there is a descriptors left.
1623 *
1624 * Returns:
1625 * > 0 - on succes: the number of bytes in the message
1626 * = 0 - on resource shortage: this frame sent or dropped, now
1627 * the ring is full ( -> set tbusy)
1628 * < 0 - on failure: other problems ( -> return failure to upper layers)
1629 */
1630static int XmitFrameSG(
1631SK_AC *pAC, /* pointer to adapter context */
1632TX_PORT *pTxPort, /* pointer to struct of port to send to */
1633struct sk_buff *pMessage) /* pointer to send-message */
1634{
1635
1636 TXD *pTxd;
1637 TXD *pTxdFst;
1638 TXD *pTxdLst;
1639 int CurrFrag;
1640 int BytesSend;
1641 skb_frag_t *sk_frag;
1642 SK_U64 PhysAddr;
1643 unsigned long Flags;
1644 SK_U32 Control;
1645
1646 spin_lock_irqsave(&pTxPort->TxDesRingLock, Flags);
1647#ifndef USE_TX_COMPLETE
1648 FreeTxDescriptors(pAC, pTxPort);
1649#endif
1650 if ((skb_shinfo(pMessage)->nr_frags +1) > pTxPort->TxdRingFree) {
1651 FreeTxDescriptors(pAC, pTxPort);
1652 if ((skb_shinfo(pMessage)->nr_frags + 1) > pTxPort->TxdRingFree) {
1653 spin_unlock_irqrestore(&pTxPort->TxDesRingLock, Flags);
1654 SK_PNMI_CNT_NO_TX_BUF(pAC, pTxPort->PortIndex);
1655 SK_DBG_MSG(NULL, SK_DBGMOD_DRV,
1656 SK_DBGCAT_DRV_TX_PROGRESS,
1657 ("XmitFrameSG failed - Ring full\n"));
1658 /* this message can not be sent now */
1659 return(-1);
1660 }
1661 }
1662
1663 pTxd = pTxPort->pTxdRingHead;
1664 pTxdFst = pTxd;
1665 pTxdLst = pTxd;
1666 BytesSend = 0;
1667
1668 /*
1669 ** Map the first fragment (header) into the DMA-space
1670 */
1671 PhysAddr = (SK_U64) pci_map_page(pAC->PciDev,
1672 virt_to_page(pMessage->data),
1673 ((unsigned long) pMessage->data & ~PAGE_MASK),
1674 skb_headlen(pMessage),
1675 PCI_DMA_TODEVICE);
1676
1677 pTxd->VDataLow = (SK_U32) (PhysAddr & 0xffffffff);
1678 pTxd->VDataHigh = (SK_U32) (PhysAddr >> 32);
1679
1680 /*
1681 ** Does the HW need to evaluate checksum for TCP or UDP packets?
1682 */
1683 if (pMessage->ip_summed == CHECKSUM_PARTIAL) {
1684 u16 hdrlen = skb_transport_offset(pMessage);
1685 u16 offset = hdrlen + pMessage->csum_offset;
1686
1687 Control = BMU_STFWD;
1688
1689 /*
1690 ** We have to use the opcode for tcp here, because the
1691 ** opcode for udp is not working in the hardware yet
1692 ** (Revision 2.0)
1693 */
1694 if ((ipip_hdr(pMessage)->protocol == IPPROTO_UDP) &&
1695 (pAC->GIni.GIChipRev == 0) &&
1696 (pAC->GIni.GIChipId == CHIP_ID_YUKON)) {
1697 Control |= BMU_TCP_CHECK;
1698 } else {
1699 Control |= BMU_UDP_CHECK;
1700 }
1701
1702 pTxd->TcpSumOfs = 0;
1703 pTxd->TcpSumSt = hdrlen;
1704 pTxd->TcpSumWr = offset;
1705 } else
1706 Control = BMU_CHECK | BMU_SW;
1707
1708 pTxd->TBControl = BMU_STF | Control | skb_headlen(pMessage);
1709
1710 pTxd = pTxd->pNextTxd;
1711 pTxPort->TxdRingFree--;
1712 BytesSend += skb_headlen(pMessage);
1713
1714 /*
1715 ** Browse over all SG fragments and map each of them into the DMA space
1716 */
1717 for (CurrFrag = 0; CurrFrag < skb_shinfo(pMessage)->nr_frags; CurrFrag++) {
1718 sk_frag = &skb_shinfo(pMessage)->frags[CurrFrag];
1719 /*
1720 ** we already have the proper value in entry
1721 */
1722 PhysAddr = (SK_U64) pci_map_page(pAC->PciDev,
1723 sk_frag->page,
1724 sk_frag->page_offset,
1725 sk_frag->size,
1726 PCI_DMA_TODEVICE);
1727
1728 pTxd->VDataLow = (SK_U32) (PhysAddr & 0xffffffff);
1729 pTxd->VDataHigh = (SK_U32) (PhysAddr >> 32);
1730 pTxd->pMBuf = pMessage;
1731
1732 pTxd->TBControl = Control | BMU_OWN | sk_frag->size;
1733
1734 /*
1735 ** Do we have the last fragment?
1736 */
1737 if( (CurrFrag+1) == skb_shinfo(pMessage)->nr_frags ) {
1738#ifdef USE_TX_COMPLETE
1739 pTxd->TBControl |= BMU_EOF | BMU_IRQ_EOF;
1740#else
1741 pTxd->TBControl |= BMU_EOF;
1742#endif
1743 pTxdFst->TBControl |= BMU_OWN | BMU_SW;
1744 }
1745 pTxdLst = pTxd;
1746 pTxd = pTxd->pNextTxd;
1747 pTxPort->TxdRingFree--;
1748 BytesSend += sk_frag->size;
1749 }
1750
1751 /*
1752 ** If previous descriptor already done, give TX start cmd
1753 */
1754 if ((pTxPort->pTxdRingPrev->TBControl & BMU_OWN) == 0) {
1755 SK_OUT8(pTxPort->HwAddr, Q_CSR, CSR_START);
1756 }
1757
1758 pTxPort->pTxdRingPrev = pTxdLst;
1759 pTxPort->pTxdRingHead = pTxd;
1760
1761 spin_unlock_irqrestore(&pTxPort->TxDesRingLock, Flags);
1762
1763 if (pTxPort->TxdRingFree > 0) {
1764 return (BytesSend);
1765 } else {
1766 return (0);
1767 }
1768}
1769
1770/*****************************************************************************
1771 *
1772 * FreeTxDescriptors - release descriptors from the descriptor ring
1773 *
1774 * Description:
1775 * This function releases descriptors from a transmit ring if they
1776 * have been sent by the BMU.
1777 * If a descriptors is sent, it can be freed and the message can
1778 * be freed, too.
1779 * The SOFTWARE controllable bit is used to prevent running around a
1780 * completely free ring for ever. If this bit is no set in the
1781 * frame (by XmitFrame), this frame has never been sent or is
1782 * already freed.
1783 * The Tx descriptor ring lock must be held while calling this function !!!
1784 *
1785 * Returns:
1786 * none
1787 */
1788static void FreeTxDescriptors(
1789SK_AC *pAC, /* pointer to the adapter context */
1790TX_PORT *pTxPort) /* pointer to destination port structure */
1791{
1792TXD *pTxd; /* pointer to the checked descriptor */
1793TXD *pNewTail; /* pointer to 'end' of the ring */
1794SK_U32 Control; /* TBControl field of descriptor */
1795SK_U64 PhysAddr; /* address of DMA mapping */
1796
1797 pNewTail = pTxPort->pTxdRingTail;
1798 pTxd = pNewTail;
1799 /*
1800 ** loop forever; exits if BMU_SW bit not set in start frame
1801 ** or BMU_OWN bit set in any frame
1802 */
1803 while (1) {
1804 Control = pTxd->TBControl;
1805 if ((Control & BMU_SW) == 0) {
1806 /*
1807 ** software controllable bit is set in first
1808 ** fragment when given to BMU. Not set means that
1809 ** this fragment was never sent or is already
1810 ** freed ( -> ring completely free now).
1811 */
1812 pTxPort->pTxdRingTail = pTxd;
1813 netif_wake_queue(pAC->dev[pTxPort->PortIndex]);
1814 return;
1815 }
1816 if (Control & BMU_OWN) {
1817 pTxPort->pTxdRingTail = pTxd;
1818 if (pTxPort->TxdRingFree > 0) {
1819 netif_wake_queue(pAC->dev[pTxPort->PortIndex]);
1820 }
1821 return;
1822 }
1823
1824 /*
1825 ** release the DMA mapping, because until not unmapped
1826 ** this buffer is considered being under control of the
1827 ** adapter card!
1828 */
1829 PhysAddr = ((SK_U64) pTxd->VDataHigh) << (SK_U64) 32;
1830 PhysAddr |= (SK_U64) pTxd->VDataLow;
1831 pci_unmap_page(pAC->PciDev, PhysAddr,
1832 pTxd->pMBuf->len,
1833 PCI_DMA_TODEVICE);
1834
1835 if (Control & BMU_EOF)
1836 DEV_KFREE_SKB_ANY(pTxd->pMBuf); /* free message */
1837
1838 pTxPort->TxdRingFree++;
1839 pTxd->TBControl &= ~BMU_SW;
1840 pTxd = pTxd->pNextTxd; /* point behind fragment with EOF */
1841 } /* while(forever) */
1842} /* FreeTxDescriptors */
1843
1844/*****************************************************************************
1845 *
1846 * FillRxRing - fill the receive ring with valid descriptors
1847 *
1848 * Description:
1849 * This function fills the receive ring descriptors with data
1850 * segments and makes them valid for the BMU.
1851 * The active ring is filled completely, if possible.
1852 * The non-active ring is filled only partial to save memory.
1853 *
1854 * Description of rx ring structure:
1855 * head - points to the descriptor which will be used next by the BMU
1856 * tail - points to the next descriptor to give to the BMU
1857 *
1858 * Returns: N/A
1859 */
1860static void FillRxRing(
1861SK_AC *pAC, /* pointer to the adapter context */
1862RX_PORT *pRxPort) /* ptr to port struct for which the ring
1863 should be filled */
1864{
1865unsigned long Flags;
1866
1867 spin_lock_irqsave(&pRxPort->RxDesRingLock, Flags);
1868 while (pRxPort->RxdRingFree > pRxPort->RxFillLimit) {
1869 if(!FillRxDescriptor(pAC, pRxPort))
1870 break;
1871 }
1872 spin_unlock_irqrestore(&pRxPort->RxDesRingLock, Flags);
1873} /* FillRxRing */
1874
1875
1876/*****************************************************************************
1877 *
1878 * FillRxDescriptor - fill one buffer into the receive ring
1879 *
1880 * Description:
1881 * The function allocates a new receive buffer and
1882 * puts it into the next descriptor.
1883 *
1884 * Returns:
1885 * SK_TRUE - a buffer was added to the ring
1886 * SK_FALSE - a buffer could not be added
1887 */
1888static SK_BOOL FillRxDescriptor(
1889SK_AC *pAC, /* pointer to the adapter context struct */
1890RX_PORT *pRxPort) /* ptr to port struct of ring to fill */
1891{
1892struct sk_buff *pMsgBlock; /* pointer to a new message block */
1893RXD *pRxd; /* the rxd to fill */
1894SK_U16 Length; /* data fragment length */
1895SK_U64 PhysAddr; /* physical address of a rx buffer */
1896
1897 pMsgBlock = alloc_skb(pAC->RxBufSize, GFP_ATOMIC);
1898 if (pMsgBlock == NULL) {
1899 SK_DBG_MSG(NULL, SK_DBGMOD_DRV,
1900 SK_DBGCAT_DRV_ENTRY,
1901 ("%s: Allocation of rx buffer failed !\n",
1902 pAC->dev[pRxPort->PortIndex]->name));
1903 SK_PNMI_CNT_NO_RX_BUF(pAC, pRxPort->PortIndex);
1904 return(SK_FALSE);
1905 }
1906 skb_reserve(pMsgBlock, 2); /* to align IP frames */
1907 /* skb allocated ok, so add buffer */
1908 pRxd = pRxPort->pRxdRingTail;
1909 pRxPort->pRxdRingTail = pRxd->pNextRxd;
1910 pRxPort->RxdRingFree--;
1911 Length = pAC->RxBufSize;
1912 PhysAddr = (SK_U64) pci_map_page(pAC->PciDev,
1913 virt_to_page(pMsgBlock->data),
1914 ((unsigned long) pMsgBlock->data &
1915 ~PAGE_MASK),
1916 pAC->RxBufSize - 2,
1917 PCI_DMA_FROMDEVICE);
1918
1919 pRxd->VDataLow = (SK_U32) (PhysAddr & 0xffffffff);
1920 pRxd->VDataHigh = (SK_U32) (PhysAddr >> 32);
1921 pRxd->pMBuf = pMsgBlock;
1922 pRxd->RBControl = BMU_OWN |
1923 BMU_STF |
1924 BMU_IRQ_EOF |
1925 BMU_TCP_CHECK |
1926 Length;
1927 return (SK_TRUE);
1928
1929} /* FillRxDescriptor */
1930
1931
1932/*****************************************************************************
1933 *
1934 * ReQueueRxBuffer - fill one buffer back into the receive ring
1935 *
1936 * Description:
1937 * Fill a given buffer back into the rx ring. The buffer
1938 * has been previously allocated and aligned, and its phys.
1939 * address calculated, so this is no more necessary.
1940 *
1941 * Returns: N/A
1942 */
1943static void ReQueueRxBuffer(
1944SK_AC *pAC, /* pointer to the adapter context struct */
1945RX_PORT *pRxPort, /* ptr to port struct of ring to fill */
1946struct sk_buff *pMsg, /* pointer to the buffer */
1947SK_U32 PhysHigh, /* phys address high dword */
1948SK_U32 PhysLow) /* phys address low dword */
1949{
1950RXD *pRxd; /* the rxd to fill */
1951SK_U16 Length; /* data fragment length */
1952
1953 pRxd = pRxPort->pRxdRingTail;
1954 pRxPort->pRxdRingTail = pRxd->pNextRxd;
1955 pRxPort->RxdRingFree--;
1956 Length = pAC->RxBufSize;
1957
1958 pRxd->VDataLow = PhysLow;
1959 pRxd->VDataHigh = PhysHigh;
1960 pRxd->pMBuf = pMsg;
1961 pRxd->RBControl = BMU_OWN |
1962 BMU_STF |
1963 BMU_IRQ_EOF |
1964 BMU_TCP_CHECK |
1965 Length;
1966 return;
1967} /* ReQueueRxBuffer */
1968
1969/*****************************************************************************
1970 *
1971 * ReceiveIrq - handle a receive IRQ
1972 *
1973 * Description:
1974 * This function is called when a receive IRQ is set.
1975 * It walks the receive descriptor ring and sends up all
1976 * frames that are complete.
1977 *
1978 * Returns: N/A
1979 */
1980static void ReceiveIrq(
1981 SK_AC *pAC, /* pointer to adapter context */
1982 RX_PORT *pRxPort, /* pointer to receive port struct */
1983 SK_BOOL SlowPathLock) /* indicates if SlowPathLock is needed */
1984{
1985RXD *pRxd; /* pointer to receive descriptors */
1986SK_U32 Control; /* control field of descriptor */
1987struct sk_buff *pMsg; /* pointer to message holding frame */
1988struct sk_buff *pNewMsg; /* pointer to a new message for copying frame */
1989int FrameLength; /* total length of received frame */
1990SK_MBUF *pRlmtMbuf; /* ptr to a buffer for giving a frame to rlmt */
1991SK_EVPARA EvPara; /* an event parameter union */
1992unsigned long Flags; /* for spin lock */
1993int PortIndex = pRxPort->PortIndex;
1994unsigned int Offset;
1995unsigned int NumBytes;
1996unsigned int ForRlmt;
1997SK_BOOL IsBc;
1998SK_BOOL IsMc;
1999SK_BOOL IsBadFrame; /* Bad frame */
2000
2001SK_U32 FrameStat;
2002SK_U64 PhysAddr;
2003
2004rx_start:
2005 /* do forever; exit if BMU_OWN found */
2006 for ( pRxd = pRxPort->pRxdRingHead ;
2007 pRxPort->RxdRingFree < pAC->RxDescrPerRing ;
2008 pRxd = pRxd->pNextRxd,
2009 pRxPort->pRxdRingHead = pRxd,
2010 pRxPort->RxdRingFree ++) {
2011
2012 /*
2013 * For a better understanding of this loop
2014 * Go through every descriptor beginning at the head
2015 * Please note: the ring might be completely received so the OWN bit
2016 * set is not a good crirteria to leave that loop.
2017 * Therefore the RingFree counter is used.
2018 * On entry of this loop pRxd is a pointer to the Rxd that needs
2019 * to be checked next.
2020 */
2021
2022 Control = pRxd->RBControl;
2023
2024 /* check if this descriptor is ready */
2025 if ((Control & BMU_OWN) != 0) {
2026 /* this descriptor is not yet ready */
2027 /* This is the usual end of the loop */
2028 /* We don't need to start the ring again */
2029 FillRxRing(pAC, pRxPort);
2030 return;
2031 }
2032 pAC->DynIrqModInfo.NbrProcessedDescr++;
2033
2034 /* get length of frame and check it */
2035 FrameLength = Control & BMU_BBC;
2036 if (FrameLength > pAC->RxBufSize) {
2037 goto rx_failed;
2038 }
2039
2040 /* check for STF and EOF */
2041 if ((Control & (BMU_STF | BMU_EOF)) != (BMU_STF | BMU_EOF)) {
2042 goto rx_failed;
2043 }
2044
2045 /* here we have a complete frame in the ring */
2046 pMsg = pRxd->pMBuf;
2047
2048 FrameStat = pRxd->FrameStat;
2049
2050 /* check for frame length mismatch */
2051#define XMR_FS_LEN_SHIFT 18
2052#define GMR_FS_LEN_SHIFT 16
2053 if (pAC->GIni.GIChipId == CHIP_ID_GENESIS) {
2054 if (FrameLength != (SK_U32) (FrameStat >> XMR_FS_LEN_SHIFT)) {
2055 SK_DBG_MSG(NULL, SK_DBGMOD_DRV,
2056 SK_DBGCAT_DRV_RX_PROGRESS,
2057 ("skge: Frame length mismatch (%u/%u).\n",
2058 FrameLength,
2059 (SK_U32) (FrameStat >> XMR_FS_LEN_SHIFT)));
2060 goto rx_failed;
2061 }
2062 }
2063 else {
2064 if (FrameLength != (SK_U32) (FrameStat >> GMR_FS_LEN_SHIFT)) {
2065 SK_DBG_MSG(NULL, SK_DBGMOD_DRV,
2066 SK_DBGCAT_DRV_RX_PROGRESS,
2067 ("skge: Frame length mismatch (%u/%u).\n",
2068 FrameLength,
2069 (SK_U32) (FrameStat >> XMR_FS_LEN_SHIFT)));
2070 goto rx_failed;
2071 }
2072 }
2073
2074 /* Set Rx Status */
2075 if (pAC->GIni.GIChipId == CHIP_ID_GENESIS) {
2076 IsBc = (FrameStat & XMR_FS_BC) != 0;
2077 IsMc = (FrameStat & XMR_FS_MC) != 0;
2078 IsBadFrame = (FrameStat &
2079 (XMR_FS_ANY_ERR | XMR_FS_2L_VLAN)) != 0;
2080 } else {
2081 IsBc = (FrameStat & GMR_FS_BC) != 0;
2082 IsMc = (FrameStat & GMR_FS_MC) != 0;
2083 IsBadFrame = (((FrameStat & GMR_FS_ANY_ERR) != 0) ||
2084 ((FrameStat & GMR_FS_RX_OK) == 0));
2085 }
2086
2087 SK_DBG_MSG(NULL, SK_DBGMOD_DRV, 0,
2088 ("Received frame of length %d on port %d\n",
2089 FrameLength, PortIndex));
2090 SK_DBG_MSG(NULL, SK_DBGMOD_DRV, 0,
2091 ("Number of free rx descriptors: %d\n",
2092 pRxPort->RxdRingFree));
2093/* DumpMsg(pMsg, "Rx"); */
2094
2095 if ((Control & BMU_STAT_VAL) != BMU_STAT_VAL || (IsBadFrame)) {
2096#if 0
2097 (FrameStat & (XMR_FS_ANY_ERR | XMR_FS_2L_VLAN)) != 0) {
2098#endif
2099 /* there is a receive error in this frame */
2100 SK_DBG_MSG(NULL, SK_DBGMOD_DRV,
2101 SK_DBGCAT_DRV_RX_PROGRESS,
2102 ("skge: Error in received frame, dropped!\n"
2103 "Control: %x\nRxStat: %x\n",
2104 Control, FrameStat));
2105
2106 ReQueueRxBuffer(pAC, pRxPort, pMsg,
2107 pRxd->VDataHigh, pRxd->VDataLow);
2108
2109 continue;
2110 }
2111
2112 /*
2113 * if short frame then copy data to reduce memory waste
2114 */
2115 if ((FrameLength < SK_COPY_THRESHOLD) &&
2116 ((pNewMsg = alloc_skb(FrameLength+2, GFP_ATOMIC)) != NULL)) {
2117 /*
2118 * Short frame detected and allocation successfull
2119 */
2120 /* use new skb and copy data */
2121 skb_reserve(pNewMsg, 2);
2122 skb_put(pNewMsg, FrameLength);
2123 PhysAddr = ((SK_U64) pRxd->VDataHigh) << (SK_U64)32;
2124 PhysAddr |= (SK_U64) pRxd->VDataLow;
2125
2126 pci_dma_sync_single_for_cpu(pAC->PciDev,
2127 (dma_addr_t) PhysAddr,
2128 FrameLength,
2129 PCI_DMA_FROMDEVICE);
2130 skb_copy_to_linear_data(pNewMsg, pMsg, FrameLength);
2131
2132 pci_dma_sync_single_for_device(pAC->PciDev,
2133 (dma_addr_t) PhysAddr,
2134 FrameLength,
2135 PCI_DMA_FROMDEVICE);
2136 ReQueueRxBuffer(pAC, pRxPort, pMsg,
2137 pRxd->VDataHigh, pRxd->VDataLow);
2138
2139 pMsg = pNewMsg;
2140
2141 }
2142 else {
2143 /*
2144 * if large frame, or SKB allocation failed, pass
2145 * the SKB directly to the networking
2146 */
2147
2148 PhysAddr = ((SK_U64) pRxd->VDataHigh) << (SK_U64)32;
2149 PhysAddr |= (SK_U64) pRxd->VDataLow;
2150
2151 /* release the DMA mapping */
2152 pci_unmap_single(pAC->PciDev,
2153 PhysAddr,
2154 pAC->RxBufSize - 2,
2155 PCI_DMA_FROMDEVICE);
2156
2157 /* set length in message */
2158 skb_put(pMsg, FrameLength);
2159 } /* frame > SK_COPY_TRESHOLD */
2160
2161#ifdef USE_SK_RX_CHECKSUM
2162 pMsg->csum = pRxd->TcpSums & 0xffff;
2163 pMsg->ip_summed = CHECKSUM_COMPLETE;
2164#else
2165 pMsg->ip_summed = CHECKSUM_NONE;
2166#endif
2167
2168 SK_DBG_MSG(NULL, SK_DBGMOD_DRV, 1,("V"));
2169 ForRlmt = SK_RLMT_RX_PROTOCOL;
2170#if 0
2171 IsBc = (FrameStat & XMR_FS_BC)==XMR_FS_BC;
2172#endif
2173 SK_RLMT_PRE_LOOKAHEAD(pAC, PortIndex, FrameLength,
2174 IsBc, &Offset, &NumBytes);
2175 if (NumBytes != 0) {
2176#if 0
2177 IsMc = (FrameStat & XMR_FS_MC)==XMR_FS_MC;
2178#endif
2179 SK_RLMT_LOOKAHEAD(pAC, PortIndex,
2180 &pMsg->data[Offset],
2181 IsBc, IsMc, &ForRlmt);
2182 }
2183 if (ForRlmt == SK_RLMT_RX_PROTOCOL) {
2184 SK_DBG_MSG(NULL, SK_DBGMOD_DRV, 1,("W"));
2185 /* send up only frames from active port */
2186 if ((PortIndex == pAC->ActivePort) ||
2187 (pAC->RlmtNets == 2)) {
2188 /* frame for upper layer */
2189 SK_DBG_MSG(NULL, SK_DBGMOD_DRV, 1,("U"));
2190#ifdef xDEBUG
2191 DumpMsg(pMsg, "Rx");
2192#endif
2193 SK_PNMI_CNT_RX_OCTETS_DELIVERED(pAC,
2194 FrameLength, pRxPort->PortIndex);
2195
2196 pMsg->protocol = eth_type_trans(pMsg,
2197 pAC->dev[pRxPort->PortIndex]);
2198 netif_rx(pMsg);
2199 pAC->dev[pRxPort->PortIndex]->last_rx = jiffies;
2200 }
2201 else {
2202 /* drop frame */
2203 SK_DBG_MSG(NULL, SK_DBGMOD_DRV,
2204 SK_DBGCAT_DRV_RX_PROGRESS,
2205 ("D"));
2206 DEV_KFREE_SKB(pMsg);
2207 }
2208
2209 } /* if not for rlmt */
2210 else {
2211 /* packet for rlmt */
2212 SK_DBG_MSG(NULL, SK_DBGMOD_DRV,
2213 SK_DBGCAT_DRV_RX_PROGRESS, ("R"));
2214 pRlmtMbuf = SkDrvAllocRlmtMbuf(pAC,
2215 pAC->IoBase, FrameLength);
2216 if (pRlmtMbuf != NULL) {
2217 pRlmtMbuf->pNext = NULL;
2218 pRlmtMbuf->Length = FrameLength;
2219 pRlmtMbuf->PortIdx = PortIndex;
2220 EvPara.pParaPtr = pRlmtMbuf;
2221 memcpy((char*)(pRlmtMbuf->pData),
2222 (char*)(pMsg->data),
2223 FrameLength);
2224
2225 /* SlowPathLock needed? */
2226 if (SlowPathLock == SK_TRUE) {
2227 spin_lock_irqsave(&pAC->SlowPathLock, Flags);
2228 SkEventQueue(pAC, SKGE_RLMT,
2229 SK_RLMT_PACKET_RECEIVED,
2230 EvPara);
2231 pAC->CheckQueue = SK_TRUE;
2232 spin_unlock_irqrestore(&pAC->SlowPathLock, Flags);
2233 } else {
2234 SkEventQueue(pAC, SKGE_RLMT,
2235 SK_RLMT_PACKET_RECEIVED,
2236 EvPara);
2237 pAC->CheckQueue = SK_TRUE;
2238 }
2239
2240 SK_DBG_MSG(NULL, SK_DBGMOD_DRV,
2241 SK_DBGCAT_DRV_RX_PROGRESS,
2242 ("Q"));
2243 }
2244 if ((pAC->dev[pRxPort->PortIndex]->flags &
2245 (IFF_PROMISC | IFF_ALLMULTI)) != 0 ||
2246 (ForRlmt & SK_RLMT_RX_PROTOCOL) ==
2247 SK_RLMT_RX_PROTOCOL) {
2248 pMsg->protocol = eth_type_trans(pMsg,
2249 pAC->dev[pRxPort->PortIndex]);
2250 netif_rx(pMsg);
2251 pAC->dev[pRxPort->PortIndex]->last_rx = jiffies;
2252 }
2253 else {
2254 DEV_KFREE_SKB(pMsg);
2255 }
2256
2257 } /* if packet for rlmt */
2258 } /* for ... scanning the RXD ring */
2259
2260 /* RXD ring is empty -> fill and restart */
2261 FillRxRing(pAC, pRxPort);
2262 /* do not start if called from Close */
2263 if (pAC->BoardLevel > SK_INIT_DATA) {
2264 ClearAndStartRx(pAC, PortIndex);
2265 }
2266 return;
2267
2268rx_failed:
2269 /* remove error frame */
2270 SK_DBG_MSG(NULL, SK_DBGMOD_DRV, SK_DBGCAT_DRV_ERROR,
2271 ("Schrottdescriptor, length: 0x%x\n", FrameLength));
2272
2273 /* release the DMA mapping */
2274
2275 PhysAddr = ((SK_U64) pRxd->VDataHigh) << (SK_U64)32;
2276 PhysAddr |= (SK_U64) pRxd->VDataLow;
2277 pci_unmap_page(pAC->PciDev,
2278 PhysAddr,
2279 pAC->RxBufSize - 2,
2280 PCI_DMA_FROMDEVICE);
2281 DEV_KFREE_SKB_IRQ(pRxd->pMBuf);
2282 pRxd->pMBuf = NULL;
2283 pRxPort->RxdRingFree++;
2284 pRxPort->pRxdRingHead = pRxd->pNextRxd;
2285 goto rx_start;
2286
2287} /* ReceiveIrq */
2288
2289
2290/*****************************************************************************
2291 *
2292 * ClearAndStartRx - give a start receive command to BMU, clear IRQ
2293 *
2294 * Description:
2295 * This function sends a start command and a clear interrupt
2296 * command for one receive queue to the BMU.
2297 *
2298 * Returns: N/A
2299 * none
2300 */
2301static void ClearAndStartRx(
2302SK_AC *pAC, /* pointer to the adapter context */
2303int PortIndex) /* index of the receive port (XMAC) */
2304{
2305 SK_OUT8(pAC->IoBase,
2306 RxQueueAddr[PortIndex]+Q_CSR,
2307 CSR_START | CSR_IRQ_CL_F);
2308} /* ClearAndStartRx */
2309
2310
2311/*****************************************************************************
2312 *
2313 * ClearTxIrq - give a clear transmit IRQ command to BMU
2314 *
2315 * Description:
2316 * This function sends a clear tx IRQ command for one
2317 * transmit queue to the BMU.
2318 *
2319 * Returns: N/A
2320 */
2321static void ClearTxIrq(
2322SK_AC *pAC, /* pointer to the adapter context */
2323int PortIndex, /* index of the transmit port (XMAC) */
2324int Prio) /* priority or normal queue */
2325{
2326 SK_OUT8(pAC->IoBase,
2327 TxQueueAddr[PortIndex][Prio]+Q_CSR,
2328 CSR_IRQ_CL_F);
2329} /* ClearTxIrq */
2330
2331
2332/*****************************************************************************
2333 *
2334 * ClearRxRing - remove all buffers from the receive ring
2335 *
2336 * Description:
2337 * This function removes all receive buffers from the ring.
2338 * The receive BMU must be stopped before calling this function.
2339 *
2340 * Returns: N/A
2341 */
2342static void ClearRxRing(
2343SK_AC *pAC, /* pointer to adapter context */
2344RX_PORT *pRxPort) /* pointer to rx port struct */
2345{
2346RXD *pRxd; /* pointer to the current descriptor */
2347unsigned long Flags;
2348SK_U64 PhysAddr;
2349
2350 if (pRxPort->RxdRingFree == pAC->RxDescrPerRing) {
2351 return;
2352 }
2353 spin_lock_irqsave(&pRxPort->RxDesRingLock, Flags);
2354 pRxd = pRxPort->pRxdRingHead;
2355 do {
2356 if (pRxd->pMBuf != NULL) {
2357
2358 PhysAddr = ((SK_U64) pRxd->VDataHigh) << (SK_U64)32;
2359 PhysAddr |= (SK_U64) pRxd->VDataLow;
2360 pci_unmap_page(pAC->PciDev,
2361 PhysAddr,
2362 pAC->RxBufSize - 2,
2363 PCI_DMA_FROMDEVICE);
2364 DEV_KFREE_SKB(pRxd->pMBuf);
2365 pRxd->pMBuf = NULL;
2366 }
2367 pRxd->RBControl &= BMU_OWN;
2368 pRxd = pRxd->pNextRxd;
2369 pRxPort->RxdRingFree++;
2370 } while (pRxd != pRxPort->pRxdRingTail);
2371 pRxPort->pRxdRingTail = pRxPort->pRxdRingHead;
2372 spin_unlock_irqrestore(&pRxPort->RxDesRingLock, Flags);
2373} /* ClearRxRing */
2374
2375/*****************************************************************************
2376 *
2377 * ClearTxRing - remove all buffers from the transmit ring
2378 *
2379 * Description:
2380 * This function removes all transmit buffers from the ring.
2381 * The transmit BMU must be stopped before calling this function
2382 * and transmitting at the upper level must be disabled.
2383 * The BMU own bit of all descriptors is cleared, the rest is
2384 * done by calling FreeTxDescriptors.
2385 *
2386 * Returns: N/A
2387 */
2388static void ClearTxRing(
2389SK_AC *pAC, /* pointer to adapter context */
2390TX_PORT *pTxPort) /* pointer to tx prt struct */
2391{
2392TXD *pTxd; /* pointer to the current descriptor */
2393int i;
2394unsigned long Flags;
2395
2396 spin_lock_irqsave(&pTxPort->TxDesRingLock, Flags);
2397 pTxd = pTxPort->pTxdRingHead;
2398 for (i=0; i<pAC->TxDescrPerRing; i++) {
2399 pTxd->TBControl &= ~BMU_OWN;
2400 pTxd = pTxd->pNextTxd;
2401 }
2402 FreeTxDescriptors(pAC, pTxPort);
2403 spin_unlock_irqrestore(&pTxPort->TxDesRingLock, Flags);
2404} /* ClearTxRing */
2405
2406/*****************************************************************************
2407 *
2408 * SkGeSetMacAddr - Set the hardware MAC address
2409 *
2410 * Description:
2411 * This function sets the MAC address used by the adapter.
2412 *
2413 * Returns:
2414 * 0, if everything is ok
2415 * !=0, on error
2416 */
2417static int SkGeSetMacAddr(struct SK_NET_DEVICE *dev, void *p)
2418{
2419
2420DEV_NET *pNet = netdev_priv(dev);
2421SK_AC *pAC = pNet->pAC;
2422
2423struct sockaddr *addr = p;
2424unsigned long Flags;
2425
2426 SK_DBG_MSG(NULL, SK_DBGMOD_DRV, SK_DBGCAT_DRV_ENTRY,
2427 ("SkGeSetMacAddr starts now...\n"));
2428 if(netif_running(dev))
2429 return -EBUSY;
2430
2431 memcpy(dev->dev_addr, addr->sa_data,dev->addr_len);
2432
2433 spin_lock_irqsave(&pAC->SlowPathLock, Flags);
2434
2435 if (pAC->RlmtNets == 2)
2436 SkAddrOverride(pAC, pAC->IoBase, pNet->NetNr,
2437 (SK_MAC_ADDR*)dev->dev_addr, SK_ADDR_VIRTUAL_ADDRESS);
2438 else
2439 SkAddrOverride(pAC, pAC->IoBase, pAC->ActivePort,
2440 (SK_MAC_ADDR*)dev->dev_addr, SK_ADDR_VIRTUAL_ADDRESS);
2441
2442
2443
2444 spin_unlock_irqrestore(&pAC->SlowPathLock, Flags);
2445 return 0;
2446} /* SkGeSetMacAddr */
2447
2448
2449/*****************************************************************************
2450 *
2451 * SkGeSetRxMode - set receive mode
2452 *
2453 * Description:
2454 * This function sets the receive mode of an adapter. The adapter
2455 * supports promiscuous mode, allmulticast mode and a number of
2456 * multicast addresses. If more multicast addresses the available
2457 * are selected, a hash function in the hardware is used.
2458 *
2459 * Returns:
2460 * 0, if everything is ok
2461 * !=0, on error
2462 */
2463static void SkGeSetRxMode(struct SK_NET_DEVICE *dev)
2464{
2465
2466DEV_NET *pNet;
2467SK_AC *pAC;
2468
2469struct dev_mc_list *pMcList;
2470int i;
2471int PortIdx;
2472unsigned long Flags;
2473
2474 SK_DBG_MSG(NULL, SK_DBGMOD_DRV, SK_DBGCAT_DRV_ENTRY,
2475 ("SkGeSetRxMode starts now... "));
2476
2477 pNet = netdev_priv(dev);
2478 pAC = pNet->pAC;
2479 if (pAC->RlmtNets == 1)
2480 PortIdx = pAC->ActivePort;
2481 else
2482 PortIdx = pNet->NetNr;
2483
2484 spin_lock_irqsave(&pAC->SlowPathLock, Flags);
2485 if (dev->flags & IFF_PROMISC) {
2486 SK_DBG_MSG(NULL, SK_DBGMOD_DRV, SK_DBGCAT_DRV_ENTRY,
2487 ("PROMISCUOUS mode\n"));
2488 SkAddrPromiscuousChange(pAC, pAC->IoBase, PortIdx,
2489 SK_PROM_MODE_LLC);
2490 } else if (dev->flags & IFF_ALLMULTI) {
2491 SK_DBG_MSG(NULL, SK_DBGMOD_DRV, SK_DBGCAT_DRV_ENTRY,
2492 ("ALLMULTI mode\n"));
2493 SkAddrPromiscuousChange(pAC, pAC->IoBase, PortIdx,
2494 SK_PROM_MODE_ALL_MC);
2495 } else {
2496 SkAddrPromiscuousChange(pAC, pAC->IoBase, PortIdx,
2497 SK_PROM_MODE_NONE);
2498 SkAddrMcClear(pAC, pAC->IoBase, PortIdx, 0);
2499
2500 SK_DBG_MSG(NULL, SK_DBGMOD_DRV, SK_DBGCAT_DRV_ENTRY,
2501 ("Number of MC entries: %d ", dev->mc_count));
2502
2503 pMcList = dev->mc_list;
2504 for (i=0; i<dev->mc_count; i++, pMcList = pMcList->next) {
2505 SkAddrMcAdd(pAC, pAC->IoBase, PortIdx,
2506 (SK_MAC_ADDR*)pMcList->dmi_addr, 0);
2507 SK_DBG_MSG(NULL, SK_DBGMOD_DRV, SK_DBGCAT_DRV_MCA,
2508 ("%02x:%02x:%02x:%02x:%02x:%02x\n",
2509 pMcList->dmi_addr[0],
2510 pMcList->dmi_addr[1],
2511 pMcList->dmi_addr[2],
2512 pMcList->dmi_addr[3],
2513 pMcList->dmi_addr[4],
2514 pMcList->dmi_addr[5]));
2515 }
2516 SkAddrMcUpdate(pAC, pAC->IoBase, PortIdx);
2517 }
2518 spin_unlock_irqrestore(&pAC->SlowPathLock, Flags);
2519
2520 return;
2521} /* SkGeSetRxMode */
2522
2523
2524/*****************************************************************************
2525 *
2526 * SkGeChangeMtu - set the MTU to another value
2527 *
2528 * Description:
2529 * This function sets is called whenever the MTU size is changed
2530 * (ifconfig mtu xxx dev ethX). If the MTU is bigger than standard
2531 * ethernet MTU size, long frame support is activated.
2532 *
2533 * Returns:
2534 * 0, if everything is ok
2535 * !=0, on error
2536 */
2537static int SkGeChangeMtu(struct SK_NET_DEVICE *dev, int NewMtu)
2538{
2539DEV_NET *pNet;
2540struct net_device *pOtherDev;
2541SK_AC *pAC;
2542unsigned long Flags;
2543int i;
2544SK_EVPARA EvPara;
2545
2546 SK_DBG_MSG(NULL, SK_DBGMOD_DRV, SK_DBGCAT_DRV_ENTRY,
2547 ("SkGeChangeMtu starts now...\n"));
2548
2549 pNet = netdev_priv(dev);
2550 pAC = pNet->pAC;
2551
2552 if ((NewMtu < 68) || (NewMtu > SK_JUMBO_MTU)) {
2553 return -EINVAL;
2554 }
2555
2556 if(pAC->BoardLevel != SK_INIT_RUN) {
2557 return -EINVAL;
2558 }
2559
2560#ifdef SK_DIAG_SUPPORT
2561 if (pAC->DiagModeActive == DIAG_ACTIVE) {
2562 if (pAC->DiagFlowCtrl == SK_FALSE) {
2563 return -1; /* still in use, deny any actions of MTU */
2564 } else {
2565 pAC->DiagFlowCtrl = SK_FALSE;
2566 }
2567 }
2568#endif
2569
2570 pOtherDev = pAC->dev[1 - pNet->NetNr];
2571
2572 if ( netif_running(pOtherDev) && (pOtherDev->mtu > 1500)
2573 && (NewMtu <= 1500))
2574 return 0;
2575
2576 pAC->RxBufSize = NewMtu + 32;
2577 dev->mtu = NewMtu;
2578
2579 SK_DBG_MSG(NULL, SK_DBGMOD_DRV, SK_DBGCAT_DRV_ENTRY,
2580 ("New MTU: %d\n", NewMtu));
2581
2582 /*
2583 ** Prevent any reconfiguration while changing the MTU
2584 ** by disabling any interrupts
2585 */
2586 SK_OUT32(pAC->IoBase, B0_IMSK, 0);
2587 spin_lock_irqsave(&pAC->SlowPathLock, Flags);
2588
2589 /*
2590 ** Notify RLMT that any ports are to be stopped
2591 */
2592 EvPara.Para32[0] = 0;
2593 EvPara.Para32[1] = -1;
2594 if ((pAC->GIni.GIMacsFound == 2 ) && (pAC->RlmtNets == 2)) {
2595 SkEventQueue(pAC, SKGE_RLMT, SK_RLMT_STOP, EvPara);
2596 EvPara.Para32[0] = 1;
2597 SkEventQueue(pAC, SKGE_RLMT, SK_RLMT_STOP, EvPara);
2598 } else {
2599 SkEventQueue(pAC, SKGE_RLMT, SK_RLMT_STOP, EvPara);
2600 }
2601
2602 /*
2603 ** After calling the SkEventDispatcher(), RLMT is aware about
2604 ** the stopped ports -> configuration can take place!
2605 */
2606 SkEventDispatcher(pAC, pAC->IoBase);
2607
2608 for (i=0; i<pAC->GIni.GIMacsFound; i++) {
2609 spin_lock(&pAC->TxPort[i][TX_PRIO_LOW].TxDesRingLock);
2610 netif_stop_queue(pAC->dev[i]);
2611
2612 }
2613
2614 /*
2615 ** Depending on the desired MTU size change, a different number of
2616 ** RX buffers need to be allocated
2617 */
2618 if (NewMtu > 1500) {
2619 /*
2620 ** Use less rx buffers
2621 */
2622 for (i=0; i<pAC->GIni.GIMacsFound; i++) {
2623 if ((pAC->GIni.GIMacsFound == 2 ) && (pAC->RlmtNets == 2)) {
2624 pAC->RxPort[i].RxFillLimit = pAC->RxDescrPerRing -
2625 (pAC->RxDescrPerRing / 4);
2626 } else {
2627 if (i == pAC->ActivePort) {
2628 pAC->RxPort[i].RxFillLimit = pAC->RxDescrPerRing -
2629 (pAC->RxDescrPerRing / 4);
2630 } else {
2631 pAC->RxPort[i].RxFillLimit = pAC->RxDescrPerRing -
2632 (pAC->RxDescrPerRing / 10);
2633 }
2634 }
2635 }
2636 } else {
2637 /*
2638 ** Use the normal amount of rx buffers
2639 */
2640 for (i=0; i<pAC->GIni.GIMacsFound; i++) {
2641 if ((pAC->GIni.GIMacsFound == 2 ) && (pAC->RlmtNets == 2)) {
2642 pAC->RxPort[i].RxFillLimit = 1;
2643 } else {
2644 if (i == pAC->ActivePort) {
2645 pAC->RxPort[i].RxFillLimit = 1;
2646 } else {
2647 pAC->RxPort[i].RxFillLimit = pAC->RxDescrPerRing -
2648 (pAC->RxDescrPerRing / 4);
2649 }
2650 }
2651 }
2652 }
2653
2654 SkGeDeInit(pAC, pAC->IoBase);
2655
2656 /*
2657 ** enable/disable hardware support for long frames
2658 */
2659 if (NewMtu > 1500) {
2660// pAC->JumboActivated = SK_TRUE; /* is never set back !!! */
2661 pAC->GIni.GIPortUsage = SK_JUMBO_LINK;
2662 } else {
2663 if ((pAC->GIni.GIMacsFound == 2 ) && (pAC->RlmtNets == 2)) {
2664 pAC->GIni.GIPortUsage = SK_MUL_LINK;
2665 } else {
2666 pAC->GIni.GIPortUsage = SK_RED_LINK;
2667 }
2668 }
2669
2670 SkGeInit( pAC, pAC->IoBase, SK_INIT_IO);
2671 SkI2cInit( pAC, pAC->IoBase, SK_INIT_IO);
2672 SkEventInit(pAC, pAC->IoBase, SK_INIT_IO);
2673 SkPnmiInit( pAC, pAC->IoBase, SK_INIT_IO);
2674 SkAddrInit( pAC, pAC->IoBase, SK_INIT_IO);
2675 SkRlmtInit( pAC, pAC->IoBase, SK_INIT_IO);
2676 SkTimerInit(pAC, pAC->IoBase, SK_INIT_IO);
2677
2678 /*
2679 ** tschilling:
2680 ** Speed and others are set back to default in level 1 init!
2681 */
2682 GetConfiguration(pAC);
2683
2684 SkGeInit( pAC, pAC->IoBase, SK_INIT_RUN);
2685 SkI2cInit( pAC, pAC->IoBase, SK_INIT_RUN);
2686 SkEventInit(pAC, pAC->IoBase, SK_INIT_RUN);
2687 SkPnmiInit( pAC, pAC->IoBase, SK_INIT_RUN);
2688 SkAddrInit( pAC, pAC->IoBase, SK_INIT_RUN);
2689 SkRlmtInit( pAC, pAC->IoBase, SK_INIT_RUN);
2690 SkTimerInit(pAC, pAC->IoBase, SK_INIT_RUN);
2691
2692 /*
2693 ** clear and reinit the rx rings here
2694 */
2695 for (i=0; i<pAC->GIni.GIMacsFound; i++) {
2696 ReceiveIrq(pAC, &pAC->RxPort[i], SK_TRUE);
2697 ClearRxRing(pAC, &pAC->RxPort[i]);
2698 FillRxRing(pAC, &pAC->RxPort[i]);
2699
2700 /*
2701 ** Enable transmit descriptor polling
2702 */
2703 SkGePollTxD(pAC, pAC->IoBase, i, SK_TRUE);
2704 FillRxRing(pAC, &pAC->RxPort[i]);
2705 };
2706
2707 SkGeYellowLED(pAC, pAC->IoBase, 1);
2708 SkDimEnableModerationIfNeeded(pAC);
2709 SkDimDisplayModerationSettings(pAC);
2710
2711 netif_start_queue(pAC->dev[pNet->PortNr]);
2712 for (i=pAC->GIni.GIMacsFound-1; i>=0; i--) {
2713 spin_unlock(&pAC->TxPort[i][TX_PRIO_LOW].TxDesRingLock);
2714 }
2715
2716 /*
2717 ** Enable Interrupts again
2718 */
2719 SK_OUT32(pAC->IoBase, B0_IMSK, pAC->GIni.GIValIrqMask);
2720 SK_OUT32(pAC->IoBase, B0_HWE_IMSK, IRQ_HWE_MASK);
2721
2722 SkEventQueue(pAC, SKGE_RLMT, SK_RLMT_START, EvPara);
2723 SkEventDispatcher(pAC, pAC->IoBase);
2724
2725 /*
2726 ** Notify RLMT about the changing and restarting one (or more) ports
2727 */
2728 if ((pAC->GIni.GIMacsFound == 2 ) && (pAC->RlmtNets == 2)) {
2729 EvPara.Para32[0] = pAC->RlmtNets;
2730 EvPara.Para32[1] = -1;
2731 SkEventQueue(pAC, SKGE_RLMT, SK_RLMT_SET_NETS, EvPara);
2732 EvPara.Para32[0] = pNet->PortNr;
2733 EvPara.Para32[1] = -1;
2734 SkEventQueue(pAC, SKGE_RLMT, SK_RLMT_START, EvPara);
2735
2736 if (netif_running(pOtherDev)) {
2737 DEV_NET *pOtherNet = netdev_priv(pOtherDev);
2738 EvPara.Para32[0] = pOtherNet->PortNr;
2739 SkEventQueue(pAC, SKGE_RLMT, SK_RLMT_START, EvPara);
2740 }
2741 } else {
2742 SkEventQueue(pAC, SKGE_RLMT, SK_RLMT_START, EvPara);
2743 }
2744
2745 SkEventDispatcher(pAC, pAC->IoBase);
2746 spin_unlock_irqrestore(&pAC->SlowPathLock, Flags);
2747
2748 /*
2749 ** While testing this driver with latest kernel 2.5 (2.5.70), it
2750 ** seems as if upper layers have a problem to handle a successful
2751 ** return value of '0'. If such a zero is returned, the complete
2752 ** system hangs for several minutes (!), which is in acceptable.
2753 **
2754 ** Currently it is not clear, what the exact reason for this problem
2755 ** is. The implemented workaround for 2.5 is to return the desired
2756 ** new MTU size if all needed changes for the new MTU size where
2757 ** performed. In kernels 2.2 and 2.4, a zero value is returned,
2758 ** which indicates the successful change of the mtu-size.
2759 */
2760 return NewMtu;
2761
2762} /* SkGeChangeMtu */
2763
2764
2765/*****************************************************************************
2766 *
2767 * SkGeStats - return ethernet device statistics
2768 *
2769 * Description:
2770 * This function return statistic data about the ethernet device
2771 * to the operating system.
2772 *
2773 * Returns:
2774 * pointer to the statistic structure.
2775 */
2776static struct net_device_stats *SkGeStats(struct SK_NET_DEVICE *dev)
2777{
2778DEV_NET *pNet = netdev_priv(dev);
2779SK_AC *pAC = pNet->pAC;
2780SK_PNMI_STRUCT_DATA *pPnmiStruct; /* structure for all Pnmi-Data */
2781SK_PNMI_STAT *pPnmiStat; /* pointer to virtual XMAC stat. data */
2782SK_PNMI_CONF *pPnmiConf; /* pointer to virtual link config. */
2783unsigned int Size; /* size of pnmi struct */
2784unsigned long Flags; /* for spin lock */
2785
2786 SK_DBG_MSG(NULL, SK_DBGMOD_DRV, SK_DBGCAT_DRV_ENTRY,
2787 ("SkGeStats starts now...\n"));
2788 pPnmiStruct = &pAC->PnmiStruct;
2789
2790#ifdef SK_DIAG_SUPPORT
2791 if ((pAC->DiagModeActive == DIAG_NOTACTIVE) &&
2792 (pAC->BoardLevel == SK_INIT_RUN)) {
2793#endif
2794 SK_MEMSET(pPnmiStruct, 0, sizeof(SK_PNMI_STRUCT_DATA));
2795 spin_lock_irqsave(&pAC->SlowPathLock, Flags);
2796 Size = SK_PNMI_STRUCT_SIZE;
2797 SkPnmiGetStruct(pAC, pAC->IoBase, pPnmiStruct, &Size, pNet->NetNr);
2798 spin_unlock_irqrestore(&pAC->SlowPathLock, Flags);
2799#ifdef SK_DIAG_SUPPORT
2800 }
2801#endif
2802
2803 pPnmiStat = &pPnmiStruct->Stat[0];
2804 pPnmiConf = &pPnmiStruct->Conf[0];
2805
2806 pAC->stats.rx_packets = (SK_U32) pPnmiStruct->RxDeliveredCts & 0xFFFFFFFF;
2807 pAC->stats.tx_packets = (SK_U32) pPnmiStat->StatTxOkCts & 0xFFFFFFFF;
2808 pAC->stats.rx_bytes = (SK_U32) pPnmiStruct->RxOctetsDeliveredCts;
2809 pAC->stats.tx_bytes = (SK_U32) pPnmiStat->StatTxOctetsOkCts;
2810
2811 if (dev->mtu <= 1500) {
2812 pAC->stats.rx_errors = (SK_U32) pPnmiStruct->InErrorsCts & 0xFFFFFFFF;
2813 } else {
2814 pAC->stats.rx_errors = (SK_U32) ((pPnmiStruct->InErrorsCts -
2815 pPnmiStat->StatRxTooLongCts) & 0xFFFFFFFF);
2816 }
2817
2818
2819 if (pAC->GIni.GP[0].PhyType == SK_PHY_XMAC && pAC->HWRevision < 12)
2820 pAC->stats.rx_errors = pAC->stats.rx_errors - pPnmiStat->StatRxShortsCts;
2821
2822 pAC->stats.tx_errors = (SK_U32) pPnmiStat->StatTxSingleCollisionCts & 0xFFFFFFFF;
2823 pAC->stats.rx_dropped = (SK_U32) pPnmiStruct->RxNoBufCts & 0xFFFFFFFF;
2824 pAC->stats.tx_dropped = (SK_U32) pPnmiStruct->TxNoBufCts & 0xFFFFFFFF;
2825 pAC->stats.multicast = (SK_U32) pPnmiStat->StatRxMulticastOkCts & 0xFFFFFFFF;
2826 pAC->stats.collisions = (SK_U32) pPnmiStat->StatTxSingleCollisionCts & 0xFFFFFFFF;
2827
2828 /* detailed rx_errors: */
2829 pAC->stats.rx_length_errors = (SK_U32) pPnmiStat->StatRxRuntCts & 0xFFFFFFFF;
2830 pAC->stats.rx_over_errors = (SK_U32) pPnmiStat->StatRxFifoOverflowCts & 0xFFFFFFFF;
2831 pAC->stats.rx_crc_errors = (SK_U32) pPnmiStat->StatRxFcsCts & 0xFFFFFFFF;
2832 pAC->stats.rx_frame_errors = (SK_U32) pPnmiStat->StatRxFramingCts & 0xFFFFFFFF;
2833 pAC->stats.rx_fifo_errors = (SK_U32) pPnmiStat->StatRxFifoOverflowCts & 0xFFFFFFFF;
2834 pAC->stats.rx_missed_errors = (SK_U32) pPnmiStat->StatRxMissedCts & 0xFFFFFFFF;
2835
2836 /* detailed tx_errors */
2837 pAC->stats.tx_aborted_errors = (SK_U32) 0;
2838 pAC->stats.tx_carrier_errors = (SK_U32) pPnmiStat->StatTxCarrierCts & 0xFFFFFFFF;
2839 pAC->stats.tx_fifo_errors = (SK_U32) pPnmiStat->StatTxFifoUnderrunCts & 0xFFFFFFFF;
2840 pAC->stats.tx_heartbeat_errors = (SK_U32) pPnmiStat->StatTxCarrierCts & 0xFFFFFFFF;
2841 pAC->stats.tx_window_errors = (SK_U32) 0;
2842
2843 return(&pAC->stats);
2844} /* SkGeStats */
2845
2846/*
2847 * Basic MII register access
2848 */
2849static int SkGeMiiIoctl(struct net_device *dev,
2850 struct mii_ioctl_data *data, int cmd)
2851{
2852 DEV_NET *pNet = netdev_priv(dev);
2853 SK_AC *pAC = pNet->pAC;
2854 SK_IOC IoC = pAC->IoBase;
2855 int Port = pNet->PortNr;
2856 SK_GEPORT *pPrt = &pAC->GIni.GP[Port];
2857 unsigned long Flags;
2858 int err = 0;
2859 int reg = data->reg_num & 0x1f;
2860 SK_U16 val = data->val_in;
2861
2862 if (!netif_running(dev))
2863 return -ENODEV; /* Phy still in reset */
2864
2865 spin_lock_irqsave(&pAC->SlowPathLock, Flags);
2866 switch(cmd) {
2867 case SIOCGMIIPHY:
2868 data->phy_id = pPrt->PhyAddr;
2869
2870 /* fallthru */
2871 case SIOCGMIIREG:
2872 if (pAC->GIni.GIGenesis)
2873 SkXmPhyRead(pAC, IoC, Port, reg, &val);
2874 else
2875 SkGmPhyRead(pAC, IoC, Port, reg, &val);
2876
2877 data->val_out = val;
2878 break;
2879
2880 case SIOCSMIIREG:
2881 if (!capable(CAP_NET_ADMIN))
2882 err = -EPERM;
2883
2884 else if (pAC->GIni.GIGenesis)
2885 SkXmPhyWrite(pAC, IoC, Port, reg, val);
2886 else
2887 SkGmPhyWrite(pAC, IoC, Port, reg, val);
2888 break;
2889 default:
2890 err = -EOPNOTSUPP;
2891 }
2892 spin_unlock_irqrestore(&pAC->SlowPathLock, Flags);
2893 return err;
2894}
2895
2896
2897/*****************************************************************************
2898 *
2899 * SkGeIoctl - IO-control function
2900 *
2901 * Description:
2902 * This function is called if an ioctl is issued on the device.
2903 * There are three subfunction for reading, writing and test-writing
2904 * the private MIB data structure (useful for SysKonnect-internal tools).
2905 *
2906 * Returns:
2907 * 0, if everything is ok
2908 * !=0, on error
2909 */
2910static int SkGeIoctl(struct SK_NET_DEVICE *dev, struct ifreq *rq, int cmd)
2911{
2912DEV_NET *pNet;
2913SK_AC *pAC;
2914void *pMemBuf;
2915struct pci_dev *pdev = NULL;
2916SK_GE_IOCTL Ioctl;
2917unsigned int Err = 0;
2918int Size = 0;
2919int Ret = 0;
2920unsigned int Length = 0;
2921int HeaderLength = sizeof(SK_U32) + sizeof(SK_U32);
2922
2923 SK_DBG_MSG(NULL, SK_DBGMOD_DRV, SK_DBGCAT_DRV_ENTRY,
2924 ("SkGeIoctl starts now...\n"));
2925
2926 pNet = netdev_priv(dev);
2927 pAC = pNet->pAC;
2928
2929 if (cmd == SIOCGMIIPHY || cmd == SIOCSMIIREG || cmd == SIOCGMIIREG)
2930 return SkGeMiiIoctl(dev, if_mii(rq), cmd);
2931
2932 if(copy_from_user(&Ioctl, rq->ifr_data, sizeof(SK_GE_IOCTL))) {
2933 return -EFAULT;
2934 }
2935
2936 switch(cmd) {
2937 case SK_IOCTL_SETMIB:
2938 case SK_IOCTL_PRESETMIB:
2939 if (!capable(CAP_NET_ADMIN)) return -EPERM;
2940 case SK_IOCTL_GETMIB:
2941 if(copy_from_user(&pAC->PnmiStruct, Ioctl.pData,
2942 Ioctl.Len<sizeof(pAC->PnmiStruct)?
2943 Ioctl.Len : sizeof(pAC->PnmiStruct))) {
2944 return -EFAULT;
2945 }
2946 Size = SkGeIocMib(pNet, Ioctl.Len, cmd);
2947 if(copy_to_user(Ioctl.pData, &pAC->PnmiStruct,
2948 Ioctl.Len<Size? Ioctl.Len : Size)) {
2949 return -EFAULT;
2950 }
2951 Ioctl.Len = Size;
2952 if(copy_to_user(rq->ifr_data, &Ioctl, sizeof(SK_GE_IOCTL))) {
2953 return -EFAULT;
2954 }
2955 break;
2956 case SK_IOCTL_GEN:
2957 if (Ioctl.Len < (sizeof(pAC->PnmiStruct) + HeaderLength)) {
2958 Length = Ioctl.Len;
2959 } else {
2960 Length = sizeof(pAC->PnmiStruct) + HeaderLength;
2961 }
2962 if (NULL == (pMemBuf = kmalloc(Length, GFP_KERNEL))) {
2963 return -ENOMEM;
2964 }
2965 if(copy_from_user(pMemBuf, Ioctl.pData, Length)) {
2966 Err = -EFAULT;
2967 goto fault_gen;
2968 }
2969 if ((Ret = SkPnmiGenIoctl(pAC, pAC->IoBase, pMemBuf, &Length, 0)) < 0) {
2970 Err = -EFAULT;
2971 goto fault_gen;
2972 }
2973 if(copy_to_user(Ioctl.pData, pMemBuf, Length) ) {
2974 Err = -EFAULT;
2975 goto fault_gen;
2976 }
2977 Ioctl.Len = Length;
2978 if(copy_to_user(rq->ifr_data, &Ioctl, sizeof(SK_GE_IOCTL))) {
2979 Err = -EFAULT;
2980 goto fault_gen;
2981 }
2982fault_gen:
2983 kfree(pMemBuf); /* cleanup everything */
2984 break;
2985#ifdef SK_DIAG_SUPPORT
2986 case SK_IOCTL_DIAG:
2987 if (!capable(CAP_NET_ADMIN)) return -EPERM;
2988 if (Ioctl.Len < (sizeof(pAC->PnmiStruct) + HeaderLength)) {
2989 Length = Ioctl.Len;
2990 } else {
2991 Length = sizeof(pAC->PnmiStruct) + HeaderLength;
2992 }
2993 if (NULL == (pMemBuf = kmalloc(Length, GFP_KERNEL))) {
2994 return -ENOMEM;
2995 }
2996 if(copy_from_user(pMemBuf, Ioctl.pData, Length)) {
2997 Err = -EFAULT;
2998 goto fault_diag;
2999 }
3000 pdev = pAC->PciDev;
3001 Length = 3 * sizeof(SK_U32); /* Error, Bus and Device */
3002 /*
3003 ** While coding this new IOCTL interface, only a few lines of code
3004 ** are to to be added. Therefore no dedicated function has been
3005 ** added. If more functionality is added, a separate function
3006 ** should be used...
3007 */
3008 * ((SK_U32 *)pMemBuf) = 0;
3009 * ((SK_U32 *)pMemBuf + 1) = pdev->bus->number;
3010 * ((SK_U32 *)pMemBuf + 2) = ParseDeviceNbrFromSlotName(pci_name(pdev));
3011 if(copy_to_user(Ioctl.pData, pMemBuf, Length) ) {
3012 Err = -EFAULT;
3013 goto fault_diag;
3014 }
3015 Ioctl.Len = Length;
3016 if(copy_to_user(rq->ifr_data, &Ioctl, sizeof(SK_GE_IOCTL))) {
3017 Err = -EFAULT;
3018 goto fault_diag;
3019 }
3020fault_diag:
3021 kfree(pMemBuf); /* cleanup everything */
3022 break;
3023#endif
3024 default:
3025 Err = -EOPNOTSUPP;
3026 }
3027
3028 return(Err);
3029
3030} /* SkGeIoctl */
3031
3032
3033/*****************************************************************************
3034 *
3035 * SkGeIocMib - handle a GetMib, SetMib- or PresetMib-ioctl message
3036 *
3037 * Description:
3038 * This function reads/writes the MIB data using PNMI (Private Network
3039 * Management Interface).
3040 * The destination for the data must be provided with the
3041 * ioctl call and is given to the driver in the form of
3042 * a user space address.
3043 * Copying from the user-provided data area into kernel messages
3044 * and back is done by copy_from_user and copy_to_user calls in
3045 * SkGeIoctl.
3046 *
3047 * Returns:
3048 * returned size from PNMI call
3049 */
3050static int SkGeIocMib(
3051DEV_NET *pNet, /* pointer to the adapter context */
3052unsigned int Size, /* length of ioctl data */
3053int mode) /* flag for set/preset */
3054{
3055unsigned long Flags; /* for spin lock */
3056SK_AC *pAC;
3057
3058 SK_DBG_MSG(NULL, SK_DBGMOD_DRV, SK_DBGCAT_DRV_ENTRY,
3059 ("SkGeIocMib starts now...\n"));
3060 pAC = pNet->pAC;
3061 /* access MIB */
3062 spin_lock_irqsave(&pAC->SlowPathLock, Flags);
3063 switch(mode) {
3064 case SK_IOCTL_GETMIB:
3065 SkPnmiGetStruct(pAC, pAC->IoBase, &pAC->PnmiStruct, &Size,
3066 pNet->NetNr);
3067 break;
3068 case SK_IOCTL_PRESETMIB:
3069 SkPnmiPreSetStruct(pAC, pAC->IoBase, &pAC->PnmiStruct, &Size,
3070 pNet->NetNr);
3071 break;
3072 case SK_IOCTL_SETMIB:
3073 SkPnmiSetStruct(pAC, pAC->IoBase, &pAC->PnmiStruct, &Size,
3074 pNet->NetNr);
3075 break;
3076 default:
3077 break;
3078 }
3079 spin_unlock_irqrestore(&pAC->SlowPathLock, Flags);
3080 SK_DBG_MSG(NULL, SK_DBGMOD_DRV, SK_DBGCAT_DRV_ENTRY,
3081 ("MIB data access succeeded\n"));
3082 return (Size);
3083} /* SkGeIocMib */
3084
3085
3086/*****************************************************************************
3087 *
3088 * GetConfiguration - read configuration information
3089 *
3090 * Description:
3091 * This function reads per-adapter configuration information from
3092 * the options provided on the command line.
3093 *
3094 * Returns:
3095 * none
3096 */
3097static void GetConfiguration(
3098SK_AC *pAC) /* pointer to the adapter context structure */
3099{
3100SK_I32 Port; /* preferred port */
3101SK_BOOL AutoSet;
3102SK_BOOL DupSet;
3103int LinkSpeed = SK_LSPEED_AUTO; /* Link speed */
3104int AutoNeg = 1; /* autoneg off (0) or on (1) */
3105int DuplexCap = 0; /* 0=both,1=full,2=half */
3106int FlowCtrl = SK_FLOW_MODE_SYM_OR_REM; /* FlowControl */
3107int MSMode = SK_MS_MODE_AUTO; /* master/slave mode */
3108
3109SK_BOOL IsConTypeDefined = SK_TRUE;
3110SK_BOOL IsLinkSpeedDefined = SK_TRUE;
3111SK_BOOL IsFlowCtrlDefined = SK_TRUE;
3112SK_BOOL IsRoleDefined = SK_TRUE;
3113SK_BOOL IsModeDefined = SK_TRUE;
3114/*
3115 * The two parameters AutoNeg. and DuplexCap. map to one configuration
3116 * parameter. The mapping is described by this table:
3117 * DuplexCap -> | both | full | half |
3118 * AutoNeg | | | |
3119 * -----------------------------------------------------------------
3120 * Off | illegal | Full | Half |
3121 * -----------------------------------------------------------------
3122 * On | AutoBoth | AutoFull | AutoHalf |
3123 * -----------------------------------------------------------------
3124 * Sense | AutoSense | AutoSense | AutoSense |
3125 */
3126int Capabilities[3][3] =
3127 { { -1, SK_LMODE_FULL , SK_LMODE_HALF },
3128 {SK_LMODE_AUTOBOTH , SK_LMODE_AUTOFULL , SK_LMODE_AUTOHALF },
3129 {SK_LMODE_AUTOSENSE, SK_LMODE_AUTOSENSE, SK_LMODE_AUTOSENSE} };
3130
3131#define DC_BOTH 0
3132#define DC_FULL 1
3133#define DC_HALF 2
3134#define AN_OFF 0
3135#define AN_ON 1
3136#define AN_SENS 2
3137#define M_CurrPort pAC->GIni.GP[Port]
3138
3139
3140 /*
3141 ** Set the default values first for both ports!
3142 */
3143 for (Port = 0; Port < SK_MAX_MACS; Port++) {
3144 M_CurrPort.PLinkModeConf = Capabilities[AN_ON][DC_BOTH];
3145 M_CurrPort.PFlowCtrlMode = SK_FLOW_MODE_SYM_OR_REM;
3146 M_CurrPort.PMSMode = SK_MS_MODE_AUTO;
3147 M_CurrPort.PLinkSpeed = SK_LSPEED_AUTO;
3148 }
3149
3150 /*
3151 ** Check merged parameter ConType. If it has not been used,
3152 ** verify any other parameter (e.g. AutoNeg) and use default values.
3153 **
3154 ** Stating both ConType and other lowlevel link parameters is also
3155 ** possible. If this is the case, the passed ConType-parameter is
3156 ** overwritten by the lowlevel link parameter.
3157 **
3158 ** The following settings are used for a merged ConType-parameter:
3159 **
3160 ** ConType DupCap AutoNeg FlowCtrl Role Speed
3161 ** ------- ------ ------- -------- ---------- -----
3162 ** Auto Both On SymOrRem Auto Auto
3163 ** 100FD Full Off None <ignored> 100
3164 ** 100HD Half Off None <ignored> 100
3165 ** 10FD Full Off None <ignored> 10
3166 ** 10HD Half Off None <ignored> 10
3167 **
3168 ** This ConType parameter is used for all ports of the adapter!
3169 */
3170 if ( (ConType != NULL) &&
3171 (pAC->Index < SK_MAX_CARD_PARAM) &&
3172 (ConType[pAC->Index] != NULL) ) {
3173
3174 /* Check chipset family */
3175 if ((!pAC->ChipsetType) &&
3176 (strcmp(ConType[pAC->Index],"Auto")!=0) &&
3177 (strcmp(ConType[pAC->Index],"")!=0)) {
3178 /* Set the speed parameter back */
3179 printk("sk98lin: Illegal value \"%s\" "
3180 "for ConType."
3181 " Using Auto.\n",
3182 ConType[pAC->Index]);
3183
3184 sprintf(ConType[pAC->Index], "Auto");
3185 }
3186
3187 if (strcmp(ConType[pAC->Index],"")==0) {
3188 IsConTypeDefined = SK_FALSE; /* No ConType defined */
3189 } else if (strcmp(ConType[pAC->Index],"Auto")==0) {
3190 for (Port = 0; Port < SK_MAX_MACS; Port++) {
3191 M_CurrPort.PLinkModeConf = Capabilities[AN_ON][DC_BOTH];
3192 M_CurrPort.PFlowCtrlMode = SK_FLOW_MODE_SYM_OR_REM;
3193 M_CurrPort.PMSMode = SK_MS_MODE_AUTO;
3194 M_CurrPort.PLinkSpeed = SK_LSPEED_AUTO;
3195 }
3196 } else if (strcmp(ConType[pAC->Index],"100FD")==0) {
3197 for (Port = 0; Port < SK_MAX_MACS; Port++) {
3198 M_CurrPort.PLinkModeConf = Capabilities[AN_OFF][DC_FULL];
3199 M_CurrPort.PFlowCtrlMode = SK_FLOW_MODE_NONE;
3200 M_CurrPort.PMSMode = SK_MS_MODE_AUTO;
3201 M_CurrPort.PLinkSpeed = SK_LSPEED_100MBPS;
3202 }
3203 } else if (strcmp(ConType[pAC->Index],"100HD")==0) {
3204 for (Port = 0; Port < SK_MAX_MACS; Port++) {
3205 M_CurrPort.PLinkModeConf = Capabilities[AN_OFF][DC_HALF];
3206 M_CurrPort.PFlowCtrlMode = SK_FLOW_MODE_NONE;
3207 M_CurrPort.PMSMode = SK_MS_MODE_AUTO;
3208 M_CurrPort.PLinkSpeed = SK_LSPEED_100MBPS;
3209 }
3210 } else if (strcmp(ConType[pAC->Index],"10FD")==0) {
3211 for (Port = 0; Port < SK_MAX_MACS; Port++) {
3212 M_CurrPort.PLinkModeConf = Capabilities[AN_OFF][DC_FULL];
3213 M_CurrPort.PFlowCtrlMode = SK_FLOW_MODE_NONE;
3214 M_CurrPort.PMSMode = SK_MS_MODE_AUTO;
3215 M_CurrPort.PLinkSpeed = SK_LSPEED_10MBPS;
3216 }
3217 } else if (strcmp(ConType[pAC->Index],"10HD")==0) {
3218 for (Port = 0; Port < SK_MAX_MACS; Port++) {
3219 M_CurrPort.PLinkModeConf = Capabilities[AN_OFF][DC_HALF];
3220 M_CurrPort.PFlowCtrlMode = SK_FLOW_MODE_NONE;
3221 M_CurrPort.PMSMode = SK_MS_MODE_AUTO;
3222 M_CurrPort.PLinkSpeed = SK_LSPEED_10MBPS;
3223 }
3224 } else {
3225 printk("sk98lin: Illegal value \"%s\" for ConType\n",
3226 ConType[pAC->Index]);
3227 IsConTypeDefined = SK_FALSE; /* Wrong ConType defined */
3228 }
3229 } else {
3230 IsConTypeDefined = SK_FALSE; /* No ConType defined */
3231 }
3232
3233 /*
3234 ** Parse any parameter settings for port A:
3235 ** a) any LinkSpeed stated?
3236 */
3237 if (Speed_A != NULL && pAC->Index<SK_MAX_CARD_PARAM &&
3238 Speed_A[pAC->Index] != NULL) {
3239 if (strcmp(Speed_A[pAC->Index],"")==0) {
3240 IsLinkSpeedDefined = SK_FALSE;
3241 } else if (strcmp(Speed_A[pAC->Index],"Auto")==0) {
3242 LinkSpeed = SK_LSPEED_AUTO;
3243 } else if (strcmp(Speed_A[pAC->Index],"10")==0) {
3244 LinkSpeed = SK_LSPEED_10MBPS;
3245 } else if (strcmp(Speed_A[pAC->Index],"100")==0) {
3246 LinkSpeed = SK_LSPEED_100MBPS;
3247 } else if (strcmp(Speed_A[pAC->Index],"1000")==0) {
3248 LinkSpeed = SK_LSPEED_1000MBPS;
3249 } else {
3250 printk("sk98lin: Illegal value \"%s\" for Speed_A\n",
3251 Speed_A[pAC->Index]);
3252 IsLinkSpeedDefined = SK_FALSE;
3253 }
3254 } else {
3255 IsLinkSpeedDefined = SK_FALSE;
3256 }
3257
3258 /*
3259 ** Check speed parameter:
3260 ** Only copper type adapter and GE V2 cards
3261 */
3262 if (((!pAC->ChipsetType) || (pAC->GIni.GICopperType != SK_TRUE)) &&
3263 ((LinkSpeed != SK_LSPEED_AUTO) &&
3264 (LinkSpeed != SK_LSPEED_1000MBPS))) {
3265 printk("sk98lin: Illegal value for Speed_A. "
3266 "Not a copper card or GE V2 card\n Using "
3267 "speed 1000\n");
3268 LinkSpeed = SK_LSPEED_1000MBPS;
3269 }
3270
3271 /*
3272 ** Decide whether to set new config value if somethig valid has
3273 ** been received.
3274 */
3275 if (IsLinkSpeedDefined) {
3276 pAC->GIni.GP[0].PLinkSpeed = LinkSpeed;
3277 }
3278
3279 /*
3280 ** b) Any Autonegotiation and DuplexCapabilities set?
3281 ** Please note that both belong together...
3282 */
3283 AutoNeg = AN_ON; /* tschilling: Default: Autonegotiation on! */
3284 AutoSet = SK_FALSE;
3285 if (AutoNeg_A != NULL && pAC->Index<SK_MAX_CARD_PARAM &&
3286 AutoNeg_A[pAC->Index] != NULL) {
3287 AutoSet = SK_TRUE;
3288 if (strcmp(AutoNeg_A[pAC->Index],"")==0) {
3289 AutoSet = SK_FALSE;
3290 } else if (strcmp(AutoNeg_A[pAC->Index],"On")==0) {
3291 AutoNeg = AN_ON;
3292 } else if (strcmp(AutoNeg_A[pAC->Index],"Off")==0) {
3293 AutoNeg = AN_OFF;
3294 } else if (strcmp(AutoNeg_A[pAC->Index],"Sense")==0) {
3295 AutoNeg = AN_SENS;
3296 } else {
3297 printk("sk98lin: Illegal value \"%s\" for AutoNeg_A\n",
3298 AutoNeg_A[pAC->Index]);
3299 }
3300 }
3301
3302 DuplexCap = DC_BOTH;
3303 DupSet = SK_FALSE;
3304 if (DupCap_A != NULL && pAC->Index<SK_MAX_CARD_PARAM &&
3305 DupCap_A[pAC->Index] != NULL) {
3306 DupSet = SK_TRUE;
3307 if (strcmp(DupCap_A[pAC->Index],"")==0) {
3308 DupSet = SK_FALSE;
3309 } else if (strcmp(DupCap_A[pAC->Index],"Both")==0) {
3310 DuplexCap = DC_BOTH;
3311 } else if (strcmp(DupCap_A[pAC->Index],"Full")==0) {
3312 DuplexCap = DC_FULL;
3313 } else if (strcmp(DupCap_A[pAC->Index],"Half")==0) {
3314 DuplexCap = DC_HALF;
3315 } else {
3316 printk("sk98lin: Illegal value \"%s\" for DupCap_A\n",
3317 DupCap_A[pAC->Index]);
3318 }
3319 }
3320
3321 /*
3322 ** Check for illegal combinations
3323 */
3324 if ((LinkSpeed == SK_LSPEED_1000MBPS) &&
3325 ((DuplexCap == SK_LMODE_STAT_AUTOHALF) ||
3326 (DuplexCap == SK_LMODE_STAT_HALF)) &&
3327 (pAC->ChipsetType)) {
3328 printk("sk98lin: Half Duplex not possible with Gigabit speed!\n"
3329 " Using Full Duplex.\n");
3330 DuplexCap = DC_FULL;
3331 }
3332
3333 if ( AutoSet && AutoNeg==AN_SENS && DupSet) {
3334 printk("sk98lin, Port A: DuplexCapabilities"
3335 " ignored using Sense mode\n");
3336 }
3337
3338 if (AutoSet && AutoNeg==AN_OFF && DupSet && DuplexCap==DC_BOTH){
3339 printk("sk98lin: Port A: Illegal combination"
3340 " of values AutoNeg. and DuplexCap.\n Using "
3341 "Full Duplex\n");
3342 DuplexCap = DC_FULL;
3343 }
3344
3345 if (AutoSet && AutoNeg==AN_OFF && !DupSet) {
3346 DuplexCap = DC_FULL;
3347 }
3348
3349 if (!AutoSet && DupSet) {
3350 printk("sk98lin: Port A: Duplex setting not"
3351 " possible in\n default AutoNegotiation mode"
3352 " (Sense).\n Using AutoNegotiation On\n");
3353 AutoNeg = AN_ON;
3354 }
3355
3356 /*
3357 ** set the desired mode
3358 */
3359 if (AutoSet || DupSet) {
3360 pAC->GIni.GP[0].PLinkModeConf = Capabilities[AutoNeg][DuplexCap];
3361 }
3362
3363 /*
3364 ** c) Any Flowcontrol-parameter set?
3365 */
3366 if (FlowCtrl_A != NULL && pAC->Index<SK_MAX_CARD_PARAM &&
3367 FlowCtrl_A[pAC->Index] != NULL) {
3368 if (strcmp(FlowCtrl_A[pAC->Index],"") == 0) {
3369 IsFlowCtrlDefined = SK_FALSE;
3370 } else if (strcmp(FlowCtrl_A[pAC->Index],"SymOrRem") == 0) {
3371 FlowCtrl = SK_FLOW_MODE_SYM_OR_REM;
3372 } else if (strcmp(FlowCtrl_A[pAC->Index],"Sym")==0) {
3373 FlowCtrl = SK_FLOW_MODE_SYMMETRIC;
3374 } else if (strcmp(FlowCtrl_A[pAC->Index],"LocSend")==0) {
3375 FlowCtrl = SK_FLOW_MODE_LOC_SEND;
3376 } else if (strcmp(FlowCtrl_A[pAC->Index],"None")==0) {
3377 FlowCtrl = SK_FLOW_MODE_NONE;
3378 } else {
3379 printk("sk98lin: Illegal value \"%s\" for FlowCtrl_A\n",
3380 FlowCtrl_A[pAC->Index]);
3381 IsFlowCtrlDefined = SK_FALSE;
3382 }
3383 } else {
3384 IsFlowCtrlDefined = SK_FALSE;
3385 }
3386
3387 if (IsFlowCtrlDefined) {
3388 if ((AutoNeg == AN_OFF) && (FlowCtrl != SK_FLOW_MODE_NONE)) {
3389 printk("sk98lin: Port A: FlowControl"
3390 " impossible without AutoNegotiation,"
3391 " disabled\n");
3392 FlowCtrl = SK_FLOW_MODE_NONE;
3393 }
3394 pAC->GIni.GP[0].PFlowCtrlMode = FlowCtrl;
3395 }
3396
3397 /*
3398 ** d) What is with the RoleParameter?
3399 */
3400 if (Role_A != NULL && pAC->Index<SK_MAX_CARD_PARAM &&
3401 Role_A[pAC->Index] != NULL) {
3402 if (strcmp(Role_A[pAC->Index],"")==0) {
3403 IsRoleDefined = SK_FALSE;
3404 } else if (strcmp(Role_A[pAC->Index],"Auto")==0) {
3405 MSMode = SK_MS_MODE_AUTO;
3406 } else if (strcmp(Role_A[pAC->Index],"Master")==0) {
3407 MSMode = SK_MS_MODE_MASTER;
3408 } else if (strcmp(Role_A[pAC->Index],"Slave")==0) {
3409 MSMode = SK_MS_MODE_SLAVE;
3410 } else {
3411 printk("sk98lin: Illegal value \"%s\" for Role_A\n",
3412 Role_A[pAC->Index]);
3413 IsRoleDefined = SK_FALSE;
3414 }
3415 } else {
3416 IsRoleDefined = SK_FALSE;
3417 }
3418
3419 if (IsRoleDefined == SK_TRUE) {
3420 pAC->GIni.GP[0].PMSMode = MSMode;
3421 }
3422
3423
3424
3425 /*
3426 ** Parse any parameter settings for port B:
3427 ** a) any LinkSpeed stated?
3428 */
3429 IsConTypeDefined = SK_TRUE;
3430 IsLinkSpeedDefined = SK_TRUE;
3431 IsFlowCtrlDefined = SK_TRUE;
3432 IsModeDefined = SK_TRUE;
3433
3434 if (Speed_B != NULL && pAC->Index<SK_MAX_CARD_PARAM &&
3435 Speed_B[pAC->Index] != NULL) {
3436 if (strcmp(Speed_B[pAC->Index],"")==0) {
3437 IsLinkSpeedDefined = SK_FALSE;
3438 } else if (strcmp(Speed_B[pAC->Index],"Auto")==0) {
3439 LinkSpeed = SK_LSPEED_AUTO;
3440 } else if (strcmp(Speed_B[pAC->Index],"10")==0) {
3441 LinkSpeed = SK_LSPEED_10MBPS;
3442 } else if (strcmp(Speed_B[pAC->Index],"100")==0) {
3443 LinkSpeed = SK_LSPEED_100MBPS;
3444 } else if (strcmp(Speed_B[pAC->Index],"1000")==0) {
3445 LinkSpeed = SK_LSPEED_1000MBPS;
3446 } else {
3447 printk("sk98lin: Illegal value \"%s\" for Speed_B\n",
3448 Speed_B[pAC->Index]);
3449 IsLinkSpeedDefined = SK_FALSE;
3450 }
3451 } else {
3452 IsLinkSpeedDefined = SK_FALSE;
3453 }
3454
3455 /*
3456 ** Check speed parameter:
3457 ** Only copper type adapter and GE V2 cards
3458 */
3459 if (((!pAC->ChipsetType) || (pAC->GIni.GICopperType != SK_TRUE)) &&
3460 ((LinkSpeed != SK_LSPEED_AUTO) &&
3461 (LinkSpeed != SK_LSPEED_1000MBPS))) {
3462 printk("sk98lin: Illegal value for Speed_B. "
3463 "Not a copper card or GE V2 card\n Using "
3464 "speed 1000\n");
3465 LinkSpeed = SK_LSPEED_1000MBPS;
3466 }
3467
3468 /*
3469 ** Decide whether to set new config value if somethig valid has
3470 ** been received.
3471 */
3472 if (IsLinkSpeedDefined) {
3473 pAC->GIni.GP[1].PLinkSpeed = LinkSpeed;
3474 }
3475
3476 /*
3477 ** b) Any Autonegotiation and DuplexCapabilities set?
3478 ** Please note that both belong together...
3479 */
3480 AutoNeg = AN_SENS; /* default: do auto Sense */
3481 AutoSet = SK_FALSE;
3482 if (AutoNeg_B != NULL && pAC->Index<SK_MAX_CARD_PARAM &&
3483 AutoNeg_B[pAC->Index] != NULL) {
3484 AutoSet = SK_TRUE;
3485 if (strcmp(AutoNeg_B[pAC->Index],"")==0) {
3486 AutoSet = SK_FALSE;
3487 } else if (strcmp(AutoNeg_B[pAC->Index],"On")==0) {
3488 AutoNeg = AN_ON;
3489 } else if (strcmp(AutoNeg_B[pAC->Index],"Off")==0) {
3490 AutoNeg = AN_OFF;
3491 } else if (strcmp(AutoNeg_B[pAC->Index],"Sense")==0) {
3492 AutoNeg = AN_SENS;
3493 } else {
3494 printk("sk98lin: Illegal value \"%s\" for AutoNeg_B\n",
3495 AutoNeg_B[pAC->Index]);
3496 }
3497 }
3498
3499 DuplexCap = DC_BOTH;
3500 DupSet = SK_FALSE;
3501 if (DupCap_B != NULL && pAC->Index<SK_MAX_CARD_PARAM &&
3502 DupCap_B[pAC->Index] != NULL) {
3503 DupSet = SK_TRUE;
3504 if (strcmp(DupCap_B[pAC->Index],"")==0) {
3505 DupSet = SK_FALSE;
3506 } else if (strcmp(DupCap_B[pAC->Index],"Both")==0) {
3507 DuplexCap = DC_BOTH;
3508 } else if (strcmp(DupCap_B[pAC->Index],"Full")==0) {
3509 DuplexCap = DC_FULL;
3510 } else if (strcmp(DupCap_B[pAC->Index],"Half")==0) {
3511 DuplexCap = DC_HALF;
3512 } else {
3513 printk("sk98lin: Illegal value \"%s\" for DupCap_B\n",
3514 DupCap_B[pAC->Index]);
3515 }
3516 }
3517
3518
3519 /*
3520 ** Check for illegal combinations
3521 */
3522 if ((LinkSpeed == SK_LSPEED_1000MBPS) &&
3523 ((DuplexCap == SK_LMODE_STAT_AUTOHALF) ||
3524 (DuplexCap == SK_LMODE_STAT_HALF)) &&
3525 (pAC->ChipsetType)) {
3526 printk("sk98lin: Half Duplex not possible with Gigabit speed!\n"
3527 " Using Full Duplex.\n");
3528 DuplexCap = DC_FULL;
3529 }
3530
3531 if (AutoSet && AutoNeg==AN_SENS && DupSet) {
3532 printk("sk98lin, Port B: DuplexCapabilities"
3533 " ignored using Sense mode\n");
3534 }
3535
3536 if (AutoSet && AutoNeg==AN_OFF && DupSet && DuplexCap==DC_BOTH){
3537 printk("sk98lin: Port B: Illegal combination"
3538 " of values AutoNeg. and DuplexCap.\n Using "
3539 "Full Duplex\n");
3540 DuplexCap = DC_FULL;
3541 }
3542
3543 if (AutoSet && AutoNeg==AN_OFF && !DupSet) {
3544 DuplexCap = DC_FULL;
3545 }
3546
3547 if (!AutoSet && DupSet) {
3548 printk("sk98lin: Port B: Duplex setting not"
3549 " possible in\n default AutoNegotiation mode"
3550 " (Sense).\n Using AutoNegotiation On\n");
3551 AutoNeg = AN_ON;
3552 }
3553
3554 /*
3555 ** set the desired mode
3556 */
3557 if (AutoSet || DupSet) {
3558 pAC->GIni.GP[1].PLinkModeConf = Capabilities[AutoNeg][DuplexCap];
3559 }
3560
3561 /*
3562 ** c) Any FlowCtrl parameter set?
3563 */
3564 if (FlowCtrl_B != NULL && pAC->Index<SK_MAX_CARD_PARAM &&
3565 FlowCtrl_B[pAC->Index] != NULL) {
3566 if (strcmp(FlowCtrl_B[pAC->Index],"") == 0) {
3567 IsFlowCtrlDefined = SK_FALSE;
3568 } else if (strcmp(FlowCtrl_B[pAC->Index],"SymOrRem") == 0) {
3569 FlowCtrl = SK_FLOW_MODE_SYM_OR_REM;
3570 } else if (strcmp(FlowCtrl_B[pAC->Index],"Sym")==0) {
3571 FlowCtrl = SK_FLOW_MODE_SYMMETRIC;
3572 } else if (strcmp(FlowCtrl_B[pAC->Index],"LocSend")==0) {
3573 FlowCtrl = SK_FLOW_MODE_LOC_SEND;
3574 } else if (strcmp(FlowCtrl_B[pAC->Index],"None")==0) {
3575 FlowCtrl = SK_FLOW_MODE_NONE;
3576 } else {
3577 printk("sk98lin: Illegal value \"%s\" for FlowCtrl_B\n",
3578 FlowCtrl_B[pAC->Index]);
3579 IsFlowCtrlDefined = SK_FALSE;
3580 }
3581 } else {
3582 IsFlowCtrlDefined = SK_FALSE;
3583 }
3584
3585 if (IsFlowCtrlDefined) {
3586 if ((AutoNeg == AN_OFF) && (FlowCtrl != SK_FLOW_MODE_NONE)) {
3587 printk("sk98lin: Port B: FlowControl"
3588 " impossible without AutoNegotiation,"
3589 " disabled\n");
3590 FlowCtrl = SK_FLOW_MODE_NONE;
3591 }
3592 pAC->GIni.GP[1].PFlowCtrlMode = FlowCtrl;
3593 }
3594
3595 /*
3596 ** d) What is the RoleParameter?
3597 */
3598 if (Role_B != NULL && pAC->Index<SK_MAX_CARD_PARAM &&
3599 Role_B[pAC->Index] != NULL) {
3600 if (strcmp(Role_B[pAC->Index],"")==0) {
3601 IsRoleDefined = SK_FALSE;
3602 } else if (strcmp(Role_B[pAC->Index],"Auto")==0) {
3603 MSMode = SK_MS_MODE_AUTO;
3604 } else if (strcmp(Role_B[pAC->Index],"Master")==0) {
3605 MSMode = SK_MS_MODE_MASTER;
3606 } else if (strcmp(Role_B[pAC->Index],"Slave")==0) {
3607 MSMode = SK_MS_MODE_SLAVE;
3608 } else {
3609 printk("sk98lin: Illegal value \"%s\" for Role_B\n",
3610 Role_B[pAC->Index]);
3611 IsRoleDefined = SK_FALSE;
3612 }
3613 } else {
3614 IsRoleDefined = SK_FALSE;
3615 }
3616
3617 if (IsRoleDefined) {
3618 pAC->GIni.GP[1].PMSMode = MSMode;
3619 }
3620
3621 /*
3622 ** Evaluate settings for both ports
3623 */
3624 pAC->ActivePort = 0;
3625 if (PrefPort != NULL && pAC->Index<SK_MAX_CARD_PARAM &&
3626 PrefPort[pAC->Index] != NULL) {
3627 if (strcmp(PrefPort[pAC->Index],"") == 0) { /* Auto */
3628 pAC->ActivePort = 0;
3629 pAC->Rlmt.Net[0].Preference = -1; /* auto */
3630 pAC->Rlmt.Net[0].PrefPort = 0;
3631 } else if (strcmp(PrefPort[pAC->Index],"A") == 0) {
3632 /*
3633 ** do not set ActivePort here, thus a port
3634 ** switch is issued after net up.
3635 */
3636 Port = 0;
3637 pAC->Rlmt.Net[0].Preference = Port;
3638 pAC->Rlmt.Net[0].PrefPort = Port;
3639 } else if (strcmp(PrefPort[pAC->Index],"B") == 0) {
3640 /*
3641 ** do not set ActivePort here, thus a port
3642 ** switch is issued after net up.
3643 */
3644 if (pAC->GIni.GIMacsFound == 1) {
3645 printk("sk98lin: Illegal value \"B\" for PrefPort.\n"
3646 " Port B not available on single port adapters.\n");
3647
3648 pAC->ActivePort = 0;
3649 pAC->Rlmt.Net[0].Preference = -1; /* auto */
3650 pAC->Rlmt.Net[0].PrefPort = 0;
3651 } else {
3652 Port = 1;
3653 pAC->Rlmt.Net[0].Preference = Port;
3654 pAC->Rlmt.Net[0].PrefPort = Port;
3655 }
3656 } else {
3657 printk("sk98lin: Illegal value \"%s\" for PrefPort\n",
3658 PrefPort[pAC->Index]);
3659 }
3660 }
3661
3662 pAC->RlmtNets = 1;
3663
3664 if (RlmtMode != NULL && pAC->Index<SK_MAX_CARD_PARAM &&
3665 RlmtMode[pAC->Index] != NULL) {
3666 if (strcmp(RlmtMode[pAC->Index], "") == 0) {
3667 pAC->RlmtMode = 0;
3668 } else if (strcmp(RlmtMode[pAC->Index], "CheckLinkState") == 0) {
3669 pAC->RlmtMode = SK_RLMT_CHECK_LINK;
3670 } else if (strcmp(RlmtMode[pAC->Index], "CheckLocalPort") == 0) {
3671 pAC->RlmtMode = SK_RLMT_CHECK_LINK |
3672 SK_RLMT_CHECK_LOC_LINK;
3673 } else if (strcmp(RlmtMode[pAC->Index], "CheckSeg") == 0) {
3674 pAC->RlmtMode = SK_RLMT_CHECK_LINK |
3675 SK_RLMT_CHECK_LOC_LINK |
3676 SK_RLMT_CHECK_SEG;
3677 } else if ((strcmp(RlmtMode[pAC->Index], "DualNet") == 0) &&
3678 (pAC->GIni.GIMacsFound == 2)) {
3679 pAC->RlmtMode = SK_RLMT_CHECK_LINK;
3680 pAC->RlmtNets = 2;
3681 } else {
3682 printk("sk98lin: Illegal value \"%s\" for"
3683 " RlmtMode, using default\n",
3684 RlmtMode[pAC->Index]);
3685 pAC->RlmtMode = 0;
3686 }
3687 } else {
3688 pAC->RlmtMode = 0;
3689 }
3690
3691 /*
3692 ** Check the interrupt moderation parameters
3693 */
3694 if (Moderation[pAC->Index] != NULL) {
3695 if (strcmp(Moderation[pAC->Index], "") == 0) {
3696 pAC->DynIrqModInfo.IntModTypeSelect = C_INT_MOD_NONE;
3697 } else if (strcmp(Moderation[pAC->Index], "Static") == 0) {
3698 pAC->DynIrqModInfo.IntModTypeSelect = C_INT_MOD_STATIC;
3699 } else if (strcmp(Moderation[pAC->Index], "Dynamic") == 0) {
3700 pAC->DynIrqModInfo.IntModTypeSelect = C_INT_MOD_DYNAMIC;
3701 } else if (strcmp(Moderation[pAC->Index], "None") == 0) {
3702 pAC->DynIrqModInfo.IntModTypeSelect = C_INT_MOD_NONE;
3703 } else {
3704 printk("sk98lin: Illegal value \"%s\" for Moderation.\n"
3705 " Disable interrupt moderation.\n",
3706 Moderation[pAC->Index]);
3707 pAC->DynIrqModInfo.IntModTypeSelect = C_INT_MOD_NONE;
3708 }
3709 } else {
3710 pAC->DynIrqModInfo.IntModTypeSelect = C_INT_MOD_NONE;
3711 }
3712
3713 if (Stats[pAC->Index] != NULL) {
3714 if (strcmp(Stats[pAC->Index], "Yes") == 0) {
3715 pAC->DynIrqModInfo.DisplayStats = SK_TRUE;
3716 } else {
3717 pAC->DynIrqModInfo.DisplayStats = SK_FALSE;
3718 }
3719 } else {
3720 pAC->DynIrqModInfo.DisplayStats = SK_FALSE;
3721 }
3722
3723 if (ModerationMask[pAC->Index] != NULL) {
3724 if (strcmp(ModerationMask[pAC->Index], "Rx") == 0) {
3725 pAC->DynIrqModInfo.MaskIrqModeration = IRQ_MASK_RX_ONLY;
3726 } else if (strcmp(ModerationMask[pAC->Index], "Tx") == 0) {
3727 pAC->DynIrqModInfo.MaskIrqModeration = IRQ_MASK_TX_ONLY;
3728 } else if (strcmp(ModerationMask[pAC->Index], "Sp") == 0) {
3729 pAC->DynIrqModInfo.MaskIrqModeration = IRQ_MASK_SP_ONLY;
3730 } else if (strcmp(ModerationMask[pAC->Index], "RxSp") == 0) {
3731 pAC->DynIrqModInfo.MaskIrqModeration = IRQ_MASK_SP_RX;
3732 } else if (strcmp(ModerationMask[pAC->Index], "SpRx") == 0) {
3733 pAC->DynIrqModInfo.MaskIrqModeration = IRQ_MASK_SP_RX;
3734 } else if (strcmp(ModerationMask[pAC->Index], "RxTx") == 0) {
3735 pAC->DynIrqModInfo.MaskIrqModeration = IRQ_MASK_TX_RX;
3736 } else if (strcmp(ModerationMask[pAC->Index], "TxRx") == 0) {
3737 pAC->DynIrqModInfo.MaskIrqModeration = IRQ_MASK_TX_RX;
3738 } else if (strcmp(ModerationMask[pAC->Index], "TxSp") == 0) {
3739 pAC->DynIrqModInfo.MaskIrqModeration = IRQ_MASK_SP_TX;
3740 } else if (strcmp(ModerationMask[pAC->Index], "SpTx") == 0) {
3741 pAC->DynIrqModInfo.MaskIrqModeration = IRQ_MASK_SP_TX;
3742 } else if (strcmp(ModerationMask[pAC->Index], "RxTxSp") == 0) {
3743 pAC->DynIrqModInfo.MaskIrqModeration = IRQ_MASK_RX_TX_SP;
3744 } else if (strcmp(ModerationMask[pAC->Index], "RxSpTx") == 0) {
3745 pAC->DynIrqModInfo.MaskIrqModeration = IRQ_MASK_RX_TX_SP;
3746 } else if (strcmp(ModerationMask[pAC->Index], "TxRxSp") == 0) {
3747 pAC->DynIrqModInfo.MaskIrqModeration = IRQ_MASK_RX_TX_SP;
3748 } else if (strcmp(ModerationMask[pAC->Index], "TxSpRx") == 0) {
3749 pAC->DynIrqModInfo.MaskIrqModeration = IRQ_MASK_RX_TX_SP;
3750 } else if (strcmp(ModerationMask[pAC->Index], "SpTxRx") == 0) {
3751 pAC->DynIrqModInfo.MaskIrqModeration = IRQ_MASK_RX_TX_SP;
3752 } else if (strcmp(ModerationMask[pAC->Index], "SpRxTx") == 0) {
3753 pAC->DynIrqModInfo.MaskIrqModeration = IRQ_MASK_RX_TX_SP;
3754 } else { /* some rubbish */
3755 pAC->DynIrqModInfo.MaskIrqModeration = IRQ_MASK_RX_ONLY;
3756 }
3757 } else { /* operator has stated nothing */
3758 pAC->DynIrqModInfo.MaskIrqModeration = IRQ_MASK_TX_RX;
3759 }
3760
3761 if (AutoSizing[pAC->Index] != NULL) {
3762 if (strcmp(AutoSizing[pAC->Index], "On") == 0) {
3763 pAC->DynIrqModInfo.AutoSizing = SK_FALSE;
3764 } else {
3765 pAC->DynIrqModInfo.AutoSizing = SK_FALSE;
3766 }
3767 } else { /* operator has stated nothing */
3768 pAC->DynIrqModInfo.AutoSizing = SK_FALSE;
3769 }
3770
3771 if (IntsPerSec[pAC->Index] != 0) {
3772 if ((IntsPerSec[pAC->Index]< C_INT_MOD_IPS_LOWER_RANGE) ||
3773 (IntsPerSec[pAC->Index] > C_INT_MOD_IPS_UPPER_RANGE)) {
3774 printk("sk98lin: Illegal value \"%d\" for IntsPerSec. (Range: %d - %d)\n"
3775 " Using default value of %i.\n",
3776 IntsPerSec[pAC->Index],
3777 C_INT_MOD_IPS_LOWER_RANGE,
3778 C_INT_MOD_IPS_UPPER_RANGE,
3779 C_INTS_PER_SEC_DEFAULT);
3780 pAC->DynIrqModInfo.MaxModIntsPerSec = C_INTS_PER_SEC_DEFAULT;
3781 } else {
3782 pAC->DynIrqModInfo.MaxModIntsPerSec = IntsPerSec[pAC->Index];
3783 }
3784 } else {
3785 pAC->DynIrqModInfo.MaxModIntsPerSec = C_INTS_PER_SEC_DEFAULT;
3786 }
3787
3788 /*
3789 ** Evaluate upper and lower moderation threshold
3790 */
3791 pAC->DynIrqModInfo.MaxModIntsPerSecUpperLimit =
3792 pAC->DynIrqModInfo.MaxModIntsPerSec +
3793 (pAC->DynIrqModInfo.MaxModIntsPerSec / 2);
3794
3795 pAC->DynIrqModInfo.MaxModIntsPerSecLowerLimit =
3796 pAC->DynIrqModInfo.MaxModIntsPerSec -
3797 (pAC->DynIrqModInfo.MaxModIntsPerSec / 2);
3798
3799 pAC->DynIrqModInfo.PrevTimeVal = jiffies; /* initial value */
3800
3801
3802} /* GetConfiguration */
3803
3804
3805/*****************************************************************************
3806 *
3807 * ProductStr - return a adapter identification string from vpd
3808 *
3809 * Description:
3810 * This function reads the product name string from the vpd area
3811 * and puts it the field pAC->DeviceString.
3812 *
3813 * Returns: N/A
3814 */
3815static inline int ProductStr(
3816 SK_AC *pAC, /* pointer to adapter context */
3817 char *DeviceStr, /* result string */
3818 int StrLen /* length of the string */
3819)
3820{
3821char Keyword[] = VPD_NAME; /* vpd productname identifier */
3822int ReturnCode; /* return code from vpd_read */
3823unsigned long Flags;
3824
3825 spin_lock_irqsave(&pAC->SlowPathLock, Flags);
3826 ReturnCode = VpdRead(pAC, pAC->IoBase, Keyword, DeviceStr, &StrLen);
3827 spin_unlock_irqrestore(&pAC->SlowPathLock, Flags);
3828
3829 return ReturnCode;
3830} /* ProductStr */
3831
3832/*****************************************************************************
3833 *
3834 * StartDrvCleanupTimer - Start timer to check for descriptors which
3835 * might be placed in descriptor ring, but
3836 * havent been handled up to now
3837 *
3838 * Description:
3839 * This function requests a HW-timer fo the Yukon card. The actions to
3840 * perform when this timer expires, are located in the SkDrvEvent().
3841 *
3842 * Returns: N/A
3843 */
3844static void
3845StartDrvCleanupTimer(SK_AC *pAC) {
3846 SK_EVPARA EventParam; /* Event struct for timer event */
3847
3848 SK_MEMSET((char *) &EventParam, 0, sizeof(EventParam));
3849 EventParam.Para32[0] = SK_DRV_RX_CLEANUP_TIMER;
3850 SkTimerStart(pAC, pAC->IoBase, &pAC->DrvCleanupTimer,
3851 SK_DRV_RX_CLEANUP_TIMER_LENGTH,
3852 SKGE_DRV, SK_DRV_TIMER, EventParam);
3853}
3854
3855/*****************************************************************************
3856 *
3857 * StopDrvCleanupTimer - Stop timer to check for descriptors
3858 *
3859 * Description:
3860 * This function requests a HW-timer fo the Yukon card. The actions to
3861 * perform when this timer expires, are located in the SkDrvEvent().
3862 *
3863 * Returns: N/A
3864 */
3865static void
3866StopDrvCleanupTimer(SK_AC *pAC) {
3867 SkTimerStop(pAC, pAC->IoBase, &pAC->DrvCleanupTimer);
3868 SK_MEMSET((char *) &pAC->DrvCleanupTimer, 0, sizeof(SK_TIMER));
3869}
3870
3871/****************************************************************************/
3872/* functions for common modules *********************************************/
3873/****************************************************************************/
3874
3875
3876/*****************************************************************************
3877 *
3878 * SkDrvAllocRlmtMbuf - allocate an RLMT mbuf
3879 *
3880 * Description:
3881 * This routine returns an RLMT mbuf or NULL. The RLMT Mbuf structure
3882 * is embedded into a socket buff data area.
3883 *
3884 * Context:
3885 * runtime
3886 *
3887 * Returns:
3888 * NULL or pointer to Mbuf.
3889 */
3890SK_MBUF *SkDrvAllocRlmtMbuf(
3891SK_AC *pAC, /* pointer to adapter context */
3892SK_IOC IoC, /* the IO-context */
3893unsigned BufferSize) /* size of the requested buffer */
3894{
3895SK_MBUF *pRlmtMbuf; /* pointer to a new rlmt-mbuf structure */
3896struct sk_buff *pMsgBlock; /* pointer to a new message block */
3897
3898 pMsgBlock = alloc_skb(BufferSize + sizeof(SK_MBUF), GFP_ATOMIC);
3899 if (pMsgBlock == NULL) {
3900 return (NULL);
3901 }
3902 pRlmtMbuf = (SK_MBUF*) pMsgBlock->data;
3903 skb_reserve(pMsgBlock, sizeof(SK_MBUF));
3904 pRlmtMbuf->pNext = NULL;
3905 pRlmtMbuf->pOs = pMsgBlock;
3906 pRlmtMbuf->pData = pMsgBlock->data; /* Data buffer. */
3907 pRlmtMbuf->Size = BufferSize; /* Data buffer size. */
3908 pRlmtMbuf->Length = 0; /* Length of packet (<= Size). */
3909 return (pRlmtMbuf);
3910
3911} /* SkDrvAllocRlmtMbuf */
3912
3913
3914/*****************************************************************************
3915 *
3916 * SkDrvFreeRlmtMbuf - free an RLMT mbuf
3917 *
3918 * Description:
3919 * This routine frees one or more RLMT mbuf(s).
3920 *
3921 * Context:
3922 * runtime
3923 *
3924 * Returns:
3925 * Nothing
3926 */
3927void SkDrvFreeRlmtMbuf(
3928SK_AC *pAC, /* pointer to adapter context */
3929SK_IOC IoC, /* the IO-context */
3930SK_MBUF *pMbuf) /* size of the requested buffer */
3931{
3932SK_MBUF *pFreeMbuf;
3933SK_MBUF *pNextMbuf;
3934
3935 pFreeMbuf = pMbuf;
3936 do {
3937 pNextMbuf = pFreeMbuf->pNext;
3938 DEV_KFREE_SKB_ANY(pFreeMbuf->pOs);
3939 pFreeMbuf = pNextMbuf;
3940 } while ( pFreeMbuf != NULL );
3941} /* SkDrvFreeRlmtMbuf */
3942
3943
3944/*****************************************************************************
3945 *
3946 * SkOsGetTime - provide a time value
3947 *
3948 * Description:
3949 * This routine provides a time value. The unit is 1/HZ (defined by Linux).
3950 * It is not used for absolute time, but only for time differences.
3951 *
3952 *
3953 * Returns:
3954 * Time value
3955 */
3956SK_U64 SkOsGetTime(SK_AC *pAC)
3957{
3958 SK_U64 PrivateJiffies;
3959 SkOsGetTimeCurrent(pAC, &PrivateJiffies);
3960 return PrivateJiffies;
3961} /* SkOsGetTime */
3962
3963
3964/*****************************************************************************
3965 *
3966 * SkPciReadCfgDWord - read a 32 bit value from pci config space
3967 *
3968 * Description:
3969 * This routine reads a 32 bit value from the pci configuration
3970 * space.
3971 *
3972 * Returns:
3973 * 0 - indicate everything worked ok.
3974 * != 0 - error indication
3975 */
3976int SkPciReadCfgDWord(
3977SK_AC *pAC, /* Adapter Control structure pointer */
3978int PciAddr, /* PCI register address */
3979SK_U32 *pVal) /* pointer to store the read value */
3980{
3981 pci_read_config_dword(pAC->PciDev, PciAddr, pVal);
3982 return(0);
3983} /* SkPciReadCfgDWord */
3984
3985
3986/*****************************************************************************
3987 *
3988 * SkPciReadCfgWord - read a 16 bit value from pci config space
3989 *
3990 * Description:
3991 * This routine reads a 16 bit value from the pci configuration
3992 * space.
3993 *
3994 * Returns:
3995 * 0 - indicate everything worked ok.
3996 * != 0 - error indication
3997 */
3998int SkPciReadCfgWord(
3999SK_AC *pAC, /* Adapter Control structure pointer */
4000int PciAddr, /* PCI register address */
4001SK_U16 *pVal) /* pointer to store the read value */
4002{
4003 pci_read_config_word(pAC->PciDev, PciAddr, pVal);
4004 return(0);
4005} /* SkPciReadCfgWord */
4006
4007
4008/*****************************************************************************
4009 *
4010 * SkPciReadCfgByte - read a 8 bit value from pci config space
4011 *
4012 * Description:
4013 * This routine reads a 8 bit value from the pci configuration
4014 * space.
4015 *
4016 * Returns:
4017 * 0 - indicate everything worked ok.
4018 * != 0 - error indication
4019 */
4020int SkPciReadCfgByte(
4021SK_AC *pAC, /* Adapter Control structure pointer */
4022int PciAddr, /* PCI register address */
4023SK_U8 *pVal) /* pointer to store the read value */
4024{
4025 pci_read_config_byte(pAC->PciDev, PciAddr, pVal);
4026 return(0);
4027} /* SkPciReadCfgByte */
4028
4029
4030/*****************************************************************************
4031 *
4032 * SkPciWriteCfgWord - write a 16 bit value to pci config space
4033 *
4034 * Description:
4035 * This routine writes a 16 bit value to the pci configuration
4036 * space. The flag PciConfigUp indicates whether the config space
4037 * is accesible or must be set up first.
4038 *
4039 * Returns:
4040 * 0 - indicate everything worked ok.
4041 * != 0 - error indication
4042 */
4043int SkPciWriteCfgWord(
4044SK_AC *pAC, /* Adapter Control structure pointer */
4045int PciAddr, /* PCI register address */
4046SK_U16 Val) /* pointer to store the read value */
4047{
4048 pci_write_config_word(pAC->PciDev, PciAddr, Val);
4049 return(0);
4050} /* SkPciWriteCfgWord */
4051
4052
4053/*****************************************************************************
4054 *
4055 * SkPciWriteCfgWord - write a 8 bit value to pci config space
4056 *
4057 * Description:
4058 * This routine writes a 8 bit value to the pci configuration
4059 * space. The flag PciConfigUp indicates whether the config space
4060 * is accesible or must be set up first.
4061 *
4062 * Returns:
4063 * 0 - indicate everything worked ok.
4064 * != 0 - error indication
4065 */
4066int SkPciWriteCfgByte(
4067SK_AC *pAC, /* Adapter Control structure pointer */
4068int PciAddr, /* PCI register address */
4069SK_U8 Val) /* pointer to store the read value */
4070{
4071 pci_write_config_byte(pAC->PciDev, PciAddr, Val);
4072 return(0);
4073} /* SkPciWriteCfgByte */
4074
4075
4076/*****************************************************************************
4077 *
4078 * SkDrvEvent - handle driver events
4079 *
4080 * Description:
4081 * This function handles events from all modules directed to the driver
4082 *
4083 * Context:
4084 * Is called under protection of slow path lock.
4085 *
4086 * Returns:
4087 * 0 if everything ok
4088 * < 0 on error
4089 *
4090 */
4091int SkDrvEvent(
4092SK_AC *pAC, /* pointer to adapter context */
4093SK_IOC IoC, /* io-context */
4094SK_U32 Event, /* event-id */
4095SK_EVPARA Param) /* event-parameter */
4096{
4097SK_MBUF *pRlmtMbuf; /* pointer to a rlmt-mbuf structure */
4098struct sk_buff *pMsg; /* pointer to a message block */
4099int FromPort; /* the port from which we switch away */
4100int ToPort; /* the port we switch to */
4101SK_EVPARA NewPara; /* parameter for further events */
4102int Stat;
4103unsigned long Flags;
4104SK_BOOL DualNet;
4105
4106 switch (Event) {
4107 case SK_DRV_ADAP_FAIL:
4108 SK_DBG_MSG(NULL, SK_DBGMOD_DRV, SK_DBGCAT_DRV_EVENT,
4109 ("ADAPTER FAIL EVENT\n"));
4110 printk("%s: Adapter failed.\n", pAC->dev[0]->name);
4111 /* disable interrupts */
4112 SK_OUT32(pAC->IoBase, B0_IMSK, 0);
4113 /* cgoos */
4114 break;
4115 case SK_DRV_PORT_FAIL:
4116 FromPort = Param.Para32[0];
4117 SK_DBG_MSG(NULL, SK_DBGMOD_DRV, SK_DBGCAT_DRV_EVENT,
4118 ("PORT FAIL EVENT, Port: %d\n", FromPort));
4119 if (FromPort == 0) {
4120 printk("%s: Port A failed.\n", pAC->dev[0]->name);
4121 } else {
4122 printk("%s: Port B failed.\n", pAC->dev[1]->name);
4123 }
4124 /* cgoos */
4125 break;
4126 case SK_DRV_PORT_RESET: /* SK_U32 PortIdx */
4127 /* action list 4 */
4128 FromPort = Param.Para32[0];
4129 SK_DBG_MSG(NULL, SK_DBGMOD_DRV, SK_DBGCAT_DRV_EVENT,
4130 ("PORT RESET EVENT, Port: %d ", FromPort));
4131 NewPara.Para64 = FromPort;
4132 SkPnmiEvent(pAC, IoC, SK_PNMI_EVT_XMAC_RESET, NewPara);
4133 spin_lock_irqsave(
4134 &pAC->TxPort[FromPort][TX_PRIO_LOW].TxDesRingLock,
4135 Flags);
4136
4137 SkGeStopPort(pAC, IoC, FromPort, SK_STOP_ALL, SK_HARD_RST);
4138 netif_carrier_off(pAC->dev[Param.Para32[0]]);
4139 spin_unlock_irqrestore(
4140 &pAC->TxPort[FromPort][TX_PRIO_LOW].TxDesRingLock,
4141 Flags);
4142
4143 /* clear rx ring from received frames */
4144 ReceiveIrq(pAC, &pAC->RxPort[FromPort], SK_FALSE);
4145
4146 ClearTxRing(pAC, &pAC->TxPort[FromPort][TX_PRIO_LOW]);
4147 spin_lock_irqsave(
4148 &pAC->TxPort[FromPort][TX_PRIO_LOW].TxDesRingLock,
4149 Flags);
4150
4151 /* tschilling: Handling of return value inserted. */
4152 if (SkGeInitPort(pAC, IoC, FromPort)) {
4153 if (FromPort == 0) {
4154 printk("%s: SkGeInitPort A failed.\n", pAC->dev[0]->name);
4155 } else {
4156 printk("%s: SkGeInitPort B failed.\n", pAC->dev[1]->name);
4157 }
4158 }
4159 SkAddrMcUpdate(pAC,IoC, FromPort);
4160 PortReInitBmu(pAC, FromPort);
4161 SkGePollTxD(pAC, IoC, FromPort, SK_TRUE);
4162 ClearAndStartRx(pAC, FromPort);
4163 spin_unlock_irqrestore(
4164 &pAC->TxPort[FromPort][TX_PRIO_LOW].TxDesRingLock,
4165 Flags);
4166 break;
4167 case SK_DRV_NET_UP: /* SK_U32 PortIdx */
4168 { struct net_device *dev = pAC->dev[Param.Para32[0]];
4169 /* action list 5 */
4170 FromPort = Param.Para32[0];
4171 SK_DBG_MSG(NULL, SK_DBGMOD_DRV, SK_DBGCAT_DRV_EVENT,
4172 ("NET UP EVENT, Port: %d ", Param.Para32[0]));
4173 /* Mac update */
4174 SkAddrMcUpdate(pAC,IoC, FromPort);
4175
4176 if (DoPrintInterfaceChange) {
4177 printk("%s: network connection up using"
4178 " port %c\n", pAC->dev[Param.Para32[0]]->name, 'A'+Param.Para32[0]);
4179
4180 /* tschilling: Values changed according to LinkSpeedUsed. */
4181 Stat = pAC->GIni.GP[FromPort].PLinkSpeedUsed;
4182 if (Stat == SK_LSPEED_STAT_10MBPS) {
4183 printk(" speed: 10\n");
4184 } else if (Stat == SK_LSPEED_STAT_100MBPS) {
4185 printk(" speed: 100\n");
4186 } else if (Stat == SK_LSPEED_STAT_1000MBPS) {
4187 printk(" speed: 1000\n");
4188 } else {
4189 printk(" speed: unknown\n");
4190 }
4191
4192
4193 Stat = pAC->GIni.GP[FromPort].PLinkModeStatus;
4194 if (Stat == SK_LMODE_STAT_AUTOHALF ||
4195 Stat == SK_LMODE_STAT_AUTOFULL) {
4196 printk(" autonegotiation: yes\n");
4197 }
4198 else {
4199 printk(" autonegotiation: no\n");
4200 }
4201 if (Stat == SK_LMODE_STAT_AUTOHALF ||
4202 Stat == SK_LMODE_STAT_HALF) {
4203 printk(" duplex mode: half\n");
4204 }
4205 else {
4206 printk(" duplex mode: full\n");
4207 }
4208 Stat = pAC->GIni.GP[FromPort].PFlowCtrlStatus;
4209 if (Stat == SK_FLOW_STAT_REM_SEND ) {
4210 printk(" flowctrl: remote send\n");
4211 }
4212 else if (Stat == SK_FLOW_STAT_LOC_SEND ){
4213 printk(" flowctrl: local send\n");
4214 }
4215 else if (Stat == SK_FLOW_STAT_SYMMETRIC ){
4216 printk(" flowctrl: symmetric\n");
4217 }
4218 else {
4219 printk(" flowctrl: none\n");
4220 }
4221
4222 /* tschilling: Check against CopperType now. */
4223 if ((pAC->GIni.GICopperType == SK_TRUE) &&
4224 (pAC->GIni.GP[FromPort].PLinkSpeedUsed ==
4225 SK_LSPEED_STAT_1000MBPS)) {
4226 Stat = pAC->GIni.GP[FromPort].PMSStatus;
4227 if (Stat == SK_MS_STAT_MASTER ) {
4228 printk(" role: master\n");
4229 }
4230 else if (Stat == SK_MS_STAT_SLAVE ) {
4231 printk(" role: slave\n");
4232 }
4233 else {
4234 printk(" role: ???\n");
4235 }
4236 }
4237
4238 /*
4239 Display dim (dynamic interrupt moderation)
4240 informations
4241 */
4242 if (pAC->DynIrqModInfo.IntModTypeSelect == C_INT_MOD_STATIC)
4243 printk(" irq moderation: static (%d ints/sec)\n",
4244 pAC->DynIrqModInfo.MaxModIntsPerSec);
4245 else if (pAC->DynIrqModInfo.IntModTypeSelect == C_INT_MOD_DYNAMIC)
4246 printk(" irq moderation: dynamic (%d ints/sec)\n",
4247 pAC->DynIrqModInfo.MaxModIntsPerSec);
4248 else
4249 printk(" irq moderation: disabled\n");
4250
4251
4252 printk(" scatter-gather: %s\n",
4253 (dev->features & NETIF_F_SG) ? "enabled" : "disabled");
4254 printk(" tx-checksum: %s\n",
4255 (dev->features & NETIF_F_IP_CSUM) ? "enabled" : "disabled");
4256 printk(" rx-checksum: %s\n",
4257 pAC->RxPort[Param.Para32[0]].RxCsum ? "enabled" : "disabled");
4258
4259 } else {
4260 DoPrintInterfaceChange = SK_TRUE;
4261 }
4262
4263 if ((Param.Para32[0] != pAC->ActivePort) &&
4264 (pAC->RlmtNets == 1)) {
4265 NewPara.Para32[0] = pAC->ActivePort;
4266 NewPara.Para32[1] = Param.Para32[0];
4267 SkEventQueue(pAC, SKGE_DRV, SK_DRV_SWITCH_INTERN,
4268 NewPara);
4269 }
4270
4271 /* Inform the world that link protocol is up. */
4272 netif_carrier_on(dev);
4273 break;
4274 }
4275 case SK_DRV_NET_DOWN: /* SK_U32 Reason */
4276 /* action list 7 */
4277 SK_DBG_MSG(NULL, SK_DBGMOD_DRV, SK_DBGCAT_DRV_EVENT,
4278 ("NET DOWN EVENT "));
4279 if (DoPrintInterfaceChange) {
4280 printk("%s: network connection down\n",
4281 pAC->dev[Param.Para32[1]]->name);
4282 } else {
4283 DoPrintInterfaceChange = SK_TRUE;
4284 }
4285 netif_carrier_off(pAC->dev[Param.Para32[1]]);
4286 break;
4287 case SK_DRV_SWITCH_HARD: /* SK_U32 FromPortIdx SK_U32 ToPortIdx */
4288 SK_DBG_MSG(NULL, SK_DBGMOD_DRV, SK_DBGCAT_DRV_EVENT,
4289 ("PORT SWITCH HARD "));
4290 case SK_DRV_SWITCH_SOFT: /* SK_U32 FromPortIdx SK_U32 ToPortIdx */
4291 /* action list 6 */
4292 printk("%s: switching to port %c\n", pAC->dev[0]->name,
4293 'A'+Param.Para32[1]);
4294 case SK_DRV_SWITCH_INTERN: /* SK_U32 FromPortIdx SK_U32 ToPortIdx */
4295 FromPort = Param.Para32[0];
4296 ToPort = Param.Para32[1];
4297 SK_DBG_MSG(NULL, SK_DBGMOD_DRV, SK_DBGCAT_DRV_EVENT,
4298 ("PORT SWITCH EVENT, From: %d To: %d (Pref %d) ",
4299 FromPort, ToPort, pAC->Rlmt.Net[0].PrefPort));
4300 NewPara.Para64 = FromPort;
4301 SkPnmiEvent(pAC, IoC, SK_PNMI_EVT_XMAC_RESET, NewPara);
4302 NewPara.Para64 = ToPort;
4303 SkPnmiEvent(pAC, IoC, SK_PNMI_EVT_XMAC_RESET, NewPara);
4304 spin_lock_irqsave(
4305 &pAC->TxPort[FromPort][TX_PRIO_LOW].TxDesRingLock,
4306 Flags);
4307 spin_lock(&pAC->TxPort[ToPort][TX_PRIO_LOW].TxDesRingLock);
4308 SkGeStopPort(pAC, IoC, FromPort, SK_STOP_ALL, SK_SOFT_RST);
4309 SkGeStopPort(pAC, IoC, ToPort, SK_STOP_ALL, SK_SOFT_RST);
4310 spin_unlock(&pAC->TxPort[ToPort][TX_PRIO_LOW].TxDesRingLock);
4311 spin_unlock_irqrestore(
4312 &pAC->TxPort[FromPort][TX_PRIO_LOW].TxDesRingLock,
4313 Flags);
4314
4315 ReceiveIrq(pAC, &pAC->RxPort[FromPort], SK_FALSE); /* clears rx ring */
4316 ReceiveIrq(pAC, &pAC->RxPort[ToPort], SK_FALSE); /* clears rx ring */
4317
4318 ClearTxRing(pAC, &pAC->TxPort[FromPort][TX_PRIO_LOW]);
4319 ClearTxRing(pAC, &pAC->TxPort[ToPort][TX_PRIO_LOW]);
4320 spin_lock_irqsave(
4321 &pAC->TxPort[FromPort][TX_PRIO_LOW].TxDesRingLock,
4322 Flags);
4323 spin_lock(&pAC->TxPort[ToPort][TX_PRIO_LOW].TxDesRingLock);
4324 pAC->ActivePort = ToPort;
4325#if 0
4326 SetQueueSizes(pAC);
4327#else
4328 /* tschilling: New common function with minimum size check. */
4329 DualNet = SK_FALSE;
4330 if (pAC->RlmtNets == 2) {
4331 DualNet = SK_TRUE;
4332 }
4333
4334 if (SkGeInitAssignRamToQueues(
4335 pAC,
4336 pAC->ActivePort,
4337 DualNet)) {
4338 spin_unlock(&pAC->TxPort[ToPort][TX_PRIO_LOW].TxDesRingLock);
4339 spin_unlock_irqrestore(
4340 &pAC->TxPort[FromPort][TX_PRIO_LOW].TxDesRingLock,
4341 Flags);
4342 printk("SkGeInitAssignRamToQueues failed.\n");
4343 break;
4344 }
4345#endif
4346 /* tschilling: Handling of return values inserted. */
4347 if (SkGeInitPort(pAC, IoC, FromPort) ||
4348 SkGeInitPort(pAC, IoC, ToPort)) {
4349 printk("%s: SkGeInitPort failed.\n", pAC->dev[0]->name);
4350 }
4351 if (Event == SK_DRV_SWITCH_SOFT) {
4352 SkMacRxTxEnable(pAC, IoC, FromPort);
4353 }
4354 SkMacRxTxEnable(pAC, IoC, ToPort);
4355 SkAddrSwap(pAC, IoC, FromPort, ToPort);
4356 SkAddrMcUpdate(pAC, IoC, FromPort);
4357 SkAddrMcUpdate(pAC, IoC, ToPort);
4358 PortReInitBmu(pAC, FromPort);
4359 PortReInitBmu(pAC, ToPort);
4360 SkGePollTxD(pAC, IoC, FromPort, SK_TRUE);
4361 SkGePollTxD(pAC, IoC, ToPort, SK_TRUE);
4362 ClearAndStartRx(pAC, FromPort);
4363 ClearAndStartRx(pAC, ToPort);
4364 spin_unlock(&pAC->TxPort[ToPort][TX_PRIO_LOW].TxDesRingLock);
4365 spin_unlock_irqrestore(
4366 &pAC->TxPort[FromPort][TX_PRIO_LOW].TxDesRingLock,
4367 Flags);
4368 break;
4369 case SK_DRV_RLMT_SEND: /* SK_MBUF *pMb */
4370 SK_DBG_MSG(NULL, SK_DBGMOD_DRV, SK_DBGCAT_DRV_EVENT,
4371 ("RLS "));
4372 pRlmtMbuf = (SK_MBUF*) Param.pParaPtr;
4373 pMsg = (struct sk_buff*) pRlmtMbuf->pOs;
4374 skb_put(pMsg, pRlmtMbuf->Length);
4375 if (XmitFrame(pAC, &pAC->TxPort[pRlmtMbuf->PortIdx][TX_PRIO_LOW],
4376 pMsg) < 0)
4377
4378 DEV_KFREE_SKB_ANY(pMsg);
4379 break;
4380 case SK_DRV_TIMER:
4381 if (Param.Para32[0] == SK_DRV_MODERATION_TIMER) {
4382 /*
4383 ** expiration of the moderation timer implies that
4384 ** dynamic moderation is to be applied
4385 */
4386 SkDimStartModerationTimer(pAC);
4387 SkDimModerate(pAC);
4388 if (pAC->DynIrqModInfo.DisplayStats) {
4389 SkDimDisplayModerationSettings(pAC);
4390 }
4391 } else if (Param.Para32[0] == SK_DRV_RX_CLEANUP_TIMER) {
4392 /*
4393 ** check if we need to check for descriptors which
4394 ** haven't been handled the last millisecs
4395 */
4396 StartDrvCleanupTimer(pAC);
4397 if (pAC->GIni.GIMacsFound == 2) {
4398 ReceiveIrq(pAC, &pAC->RxPort[1], SK_FALSE);
4399 }
4400 ReceiveIrq(pAC, &pAC->RxPort[0], SK_FALSE);
4401 } else {
4402 printk("Expiration of unknown timer\n");
4403 }
4404 break;
4405 default:
4406 break;
4407 }
4408 SK_DBG_MSG(NULL, SK_DBGMOD_DRV, SK_DBGCAT_DRV_EVENT,
4409 ("END EVENT "));
4410
4411 return (0);
4412} /* SkDrvEvent */
4413
4414
4415/*****************************************************************************
4416 *
4417 * SkErrorLog - log errors
4418 *
4419 * Description:
4420 * This function logs errors to the system buffer and to the console
4421 *
4422 * Returns:
4423 * 0 if everything ok
4424 * < 0 on error
4425 *
4426 */
4427void SkErrorLog(
4428SK_AC *pAC,
4429int ErrClass,
4430int ErrNum,
4431char *pErrorMsg)
4432{
4433char ClassStr[80];
4434
4435 switch (ErrClass) {
4436 case SK_ERRCL_OTHER:
4437 strcpy(ClassStr, "Other error");
4438 break;
4439 case SK_ERRCL_CONFIG:
4440 strcpy(ClassStr, "Configuration error");
4441 break;
4442 case SK_ERRCL_INIT:
4443 strcpy(ClassStr, "Initialization error");
4444 break;
4445 case SK_ERRCL_NORES:
4446 strcpy(ClassStr, "Out of resources error");
4447 break;
4448 case SK_ERRCL_SW:
4449 strcpy(ClassStr, "internal Software error");
4450 break;
4451 case SK_ERRCL_HW:
4452 strcpy(ClassStr, "Hardware failure");
4453 break;
4454 case SK_ERRCL_COMM:
4455 strcpy(ClassStr, "Communication error");
4456 break;
4457 }
4458 printk(KERN_INFO "%s: -- ERROR --\n Class: %s\n"
4459 " Nr: 0x%x\n Msg: %s\n", pAC->dev[0]->name,
4460 ClassStr, ErrNum, pErrorMsg);
4461
4462} /* SkErrorLog */
4463
4464#ifdef SK_DIAG_SUPPORT
4465
4466/*****************************************************************************
4467 *
4468 * SkDrvEnterDiagMode - handles DIAG attach request
4469 *
4470 * Description:
4471 * Notify the kernel to NOT access the card any longer due to DIAG
4472 * Deinitialize the Card
4473 *
4474 * Returns:
4475 * int
4476 */
4477int SkDrvEnterDiagMode(
4478SK_AC *pAc) /* pointer to adapter context */
4479{
4480 DEV_NET *pNet = netdev_priv(pAc->dev[0]);
4481 SK_AC *pAC = pNet->pAC;
4482
4483 SK_MEMCPY(&(pAc->PnmiBackup), &(pAc->PnmiStruct),
4484 sizeof(SK_PNMI_STRUCT_DATA));
4485
4486 pAC->DiagModeActive = DIAG_ACTIVE;
4487 if (pAC->BoardLevel > SK_INIT_DATA) {
4488 if (netif_running(pAC->dev[0])) {
4489 pAC->WasIfUp[0] = SK_TRUE;
4490 pAC->DiagFlowCtrl = SK_TRUE; /* for SkGeClose */
4491 DoPrintInterfaceChange = SK_FALSE;
4492 SkDrvDeInitAdapter(pAC, 0); /* performs SkGeClose */
4493 } else {
4494 pAC->WasIfUp[0] = SK_FALSE;
4495 }
4496 if (pNet != netdev_priv(pAC->dev[1])) {
4497 pNet = netdev_priv(pAC->dev[1]);
4498 if (netif_running(pAC->dev[1])) {
4499 pAC->WasIfUp[1] = SK_TRUE;
4500 pAC->DiagFlowCtrl = SK_TRUE; /* for SkGeClose */
4501 DoPrintInterfaceChange = SK_FALSE;
4502 SkDrvDeInitAdapter(pAC, 1); /* do SkGeClose */
4503 } else {
4504 pAC->WasIfUp[1] = SK_FALSE;
4505 }
4506 }
4507 pAC->BoardLevel = SK_INIT_DATA;
4508 }
4509 return(0);
4510}
4511
4512/*****************************************************************************
4513 *
4514 * SkDrvLeaveDiagMode - handles DIAG detach request
4515 *
4516 * Description:
4517 * Notify the kernel to may access the card again after use by DIAG
4518 * Initialize the Card
4519 *
4520 * Returns:
4521 * int
4522 */
4523int SkDrvLeaveDiagMode(
4524SK_AC *pAc) /* pointer to adapter control context */
4525{
4526 SK_MEMCPY(&(pAc->PnmiStruct), &(pAc->PnmiBackup),
4527 sizeof(SK_PNMI_STRUCT_DATA));
4528 pAc->DiagModeActive = DIAG_NOTACTIVE;
4529 pAc->Pnmi.DiagAttached = SK_DIAG_IDLE;
4530 if (pAc->WasIfUp[0] == SK_TRUE) {
4531 pAc->DiagFlowCtrl = SK_TRUE; /* for SkGeClose */
4532 DoPrintInterfaceChange = SK_FALSE;
4533 SkDrvInitAdapter(pAc, 0); /* first device */
4534 }
4535 if (pAc->WasIfUp[1] == SK_TRUE) {
4536 pAc->DiagFlowCtrl = SK_TRUE; /* for SkGeClose */
4537 DoPrintInterfaceChange = SK_FALSE;
4538 SkDrvInitAdapter(pAc, 1); /* second device */
4539 }
4540 return(0);
4541}
4542
4543/*****************************************************************************
4544 *
4545 * ParseDeviceNbrFromSlotName - Evaluate PCI device number
4546 *
4547 * Description:
4548 * This function parses the PCI slot name information string and will
4549 * retrieve the devcie number out of it. The slot_name maintianed by
4550 * linux is in the form of '02:0a.0', whereas the first two characters
4551 * represent the bus number in hex (in the sample above this is
4552 * pci bus 0x02) and the next two characters the device number (0x0a).
4553 *
4554 * Returns:
4555 * SK_U32: The device number from the PCI slot name
4556 */
4557
4558static SK_U32 ParseDeviceNbrFromSlotName(
4559const char *SlotName) /* pointer to pci slot name eg. '02:0a.0' */
4560{
4561 char *CurrCharPos = (char *) SlotName;
4562 int FirstNibble = -1;
4563 int SecondNibble = -1;
4564 SK_U32 Result = 0;
4565
4566 while (*CurrCharPos != '\0') {
4567 if (*CurrCharPos == ':') {
4568 while (*CurrCharPos != '.') {
4569 CurrCharPos++;
4570 if ( (*CurrCharPos >= '0') &&
4571 (*CurrCharPos <= '9')) {
4572 if (FirstNibble == -1) {
4573 /* dec. value for '0' */
4574 FirstNibble = *CurrCharPos - 48;
4575 } else {
4576 SecondNibble = *CurrCharPos - 48;
4577 }
4578 } else if ( (*CurrCharPos >= 'a') &&
4579 (*CurrCharPos <= 'f') ) {
4580 if (FirstNibble == -1) {
4581 FirstNibble = *CurrCharPos - 87;
4582 } else {
4583 SecondNibble = *CurrCharPos - 87;
4584 }
4585 } else {
4586 Result = 0;
4587 }
4588 }
4589
4590 Result = FirstNibble;
4591 Result = Result << 4; /* first nibble is higher one */
4592 Result = Result | SecondNibble;
4593 }
4594 CurrCharPos++; /* next character */
4595 }
4596 return (Result);
4597}
4598
4599/****************************************************************************
4600 *
4601 * SkDrvDeInitAdapter - deinitialize adapter (this function is only
4602 * called if Diag attaches to that card)
4603 *
4604 * Description:
4605 * Close initialized adapter.
4606 *
4607 * Returns:
4608 * 0 - on success
4609 * error code - on error
4610 */
4611static int SkDrvDeInitAdapter(
4612SK_AC *pAC, /* pointer to adapter context */
4613int devNbr) /* what device is to be handled */
4614{
4615 struct SK_NET_DEVICE *dev;
4616
4617 dev = pAC->dev[devNbr];
4618
4619 /* On Linux 2.6 the network driver does NOT mess with reference
4620 ** counts. The driver MUST be able to be unloaded at any time
4621 ** due to the possibility of hotplug.
4622 */
4623 if (SkGeClose(dev) != 0) {
4624 return (-1);
4625 }
4626 return (0);
4627
4628} /* SkDrvDeInitAdapter() */
4629
4630/****************************************************************************
4631 *
4632 * SkDrvInitAdapter - Initialize adapter (this function is only
4633 * called if Diag deattaches from that card)
4634 *
4635 * Description:
4636 * Close initialized adapter.
4637 *
4638 * Returns:
4639 * 0 - on success
4640 * error code - on error
4641 */
4642static int SkDrvInitAdapter(
4643SK_AC *pAC, /* pointer to adapter context */
4644int devNbr) /* what device is to be handled */
4645{
4646 struct SK_NET_DEVICE *dev;
4647
4648 dev = pAC->dev[devNbr];
4649
4650 if (SkGeOpen(dev) != 0) {
4651 return (-1);
4652 }
4653
4654 /*
4655 ** Use correct MTU size and indicate to kernel TX queue can be started
4656 */
4657 if (SkGeChangeMtu(dev, dev->mtu) != 0) {
4658 return (-1);
4659 }
4660 return (0);
4661
4662} /* SkDrvInitAdapter */
4663
4664#endif
4665
4666#ifdef DEBUG
4667/****************************************************************************/
4668/* "debug only" section *****************************************************/
4669/****************************************************************************/
4670
4671
4672/*****************************************************************************
4673 *
4674 * DumpMsg - print a frame
4675 *
4676 * Description:
4677 * This function prints frames to the system logfile/to the console.
4678 *
4679 * Returns: N/A
4680 *
4681 */
4682static void DumpMsg(struct sk_buff *skb, char *str)
4683{
4684 int msglen;
4685
4686 if (skb == NULL) {
4687 printk("DumpMsg(): NULL-Message\n");
4688 return;
4689 }
4690
4691 if (skb->data == NULL) {
4692 printk("DumpMsg(): Message empty\n");
4693 return;
4694 }
4695
4696 msglen = skb->len;
4697 if (msglen > 64)
4698 msglen = 64;
4699
4700 printk("--- Begin of message from %s , len %d (from %d) ----\n", str, msglen, skb->len);
4701
4702 DumpData((char *)skb->data, msglen);
4703
4704 printk("------- End of message ---------\n");
4705} /* DumpMsg */
4706
4707
4708
4709/*****************************************************************************
4710 *
4711 * DumpData - print a data area
4712 *
4713 * Description:
4714 * This function prints a area of data to the system logfile/to the
4715 * console.
4716 *
4717 * Returns: N/A
4718 *
4719 */
4720static void DumpData(char *p, int size)
4721{
4722register int i;
4723int haddr, addr;
4724char hex_buffer[180];
4725char asc_buffer[180];
4726char HEXCHAR[] = "0123456789ABCDEF";
4727
4728 addr = 0;
4729 haddr = 0;
4730 hex_buffer[0] = 0;
4731 asc_buffer[0] = 0;
4732 for (i=0; i < size; ) {
4733 if (*p >= '0' && *p <='z')
4734 asc_buffer[addr] = *p;
4735 else
4736 asc_buffer[addr] = '.';
4737 addr++;
4738 asc_buffer[addr] = 0;
4739 hex_buffer[haddr] = HEXCHAR[(*p & 0xf0) >> 4];
4740 haddr++;
4741 hex_buffer[haddr] = HEXCHAR[*p & 0x0f];
4742 haddr++;
4743 hex_buffer[haddr] = ' ';
4744 haddr++;
4745 hex_buffer[haddr] = 0;
4746 p++;
4747 i++;
4748 if (i%16 == 0) {
4749 printk("%s %s\n", hex_buffer, asc_buffer);
4750 addr = 0;
4751 haddr = 0;
4752 }
4753 }
4754} /* DumpData */
4755
4756
4757/*****************************************************************************
4758 *
4759 * DumpLong - print a data area as long values
4760 *
4761 * Description:
4762 * This function prints a area of data to the system logfile/to the
4763 * console.
4764 *
4765 * Returns: N/A
4766 *
4767 */
4768static void DumpLong(char *pc, int size)
4769{
4770register int i;
4771int haddr, addr;
4772char hex_buffer[180];
4773char asc_buffer[180];
4774char HEXCHAR[] = "0123456789ABCDEF";
4775long *p;
4776int l;
4777
4778 addr = 0;
4779 haddr = 0;
4780 hex_buffer[0] = 0;
4781 asc_buffer[0] = 0;
4782 p = (long*) pc;
4783 for (i=0; i < size; ) {
4784 l = (long) *p;
4785 hex_buffer[haddr] = HEXCHAR[(l >> 28) & 0xf];
4786 haddr++;
4787 hex_buffer[haddr] = HEXCHAR[(l >> 24) & 0xf];
4788 haddr++;
4789 hex_buffer[haddr] = HEXCHAR[(l >> 20) & 0xf];
4790 haddr++;
4791 hex_buffer[haddr] = HEXCHAR[(l >> 16) & 0xf];
4792 haddr++;
4793 hex_buffer[haddr] = HEXCHAR[(l >> 12) & 0xf];
4794 haddr++;
4795 hex_buffer[haddr] = HEXCHAR[(l >> 8) & 0xf];
4796 haddr++;
4797 hex_buffer[haddr] = HEXCHAR[(l >> 4) & 0xf];
4798 haddr++;
4799 hex_buffer[haddr] = HEXCHAR[l & 0x0f];
4800 haddr++;
4801 hex_buffer[haddr] = ' ';
4802 haddr++;
4803 hex_buffer[haddr] = 0;
4804 p++;
4805 i++;
4806 if (i%8 == 0) {
4807 printk("%4x %s\n", (i-8)*4, hex_buffer);
4808 haddr = 0;
4809 }
4810 }
4811 printk("------------------------\n");
4812} /* DumpLong */
4813
4814#endif
4815
4816static int __devinit skge_probe_one(struct pci_dev *pdev,
4817 const struct pci_device_id *ent)
4818{
4819 SK_AC *pAC;
4820 DEV_NET *pNet = NULL;
4821 struct net_device *dev = NULL;
4822 static int boards_found = 0;
4823 int error = -ENODEV;
4824 int using_dac = 0;
4825 char DeviceStr[80];
4826
4827 if (pci_enable_device(pdev))
4828 goto out;
4829
4830 /* Configure DMA attributes. */
4831 if (sizeof(dma_addr_t) > sizeof(u32) &&
4832 !(error = pci_set_dma_mask(pdev, DMA_64BIT_MASK))) {
4833 using_dac = 1;
4834 error = pci_set_consistent_dma_mask(pdev, DMA_64BIT_MASK);
4835 if (error < 0) {
4836 printk(KERN_ERR "sk98lin %s unable to obtain 64 bit DMA "
4837 "for consistent allocations\n", pci_name(pdev));
4838 goto out_disable_device;
4839 }
4840 } else {
4841 error = pci_set_dma_mask(pdev, DMA_32BIT_MASK);
4842 if (error) {
4843 printk(KERN_ERR "sk98lin %s no usable DMA configuration\n",
4844 pci_name(pdev));
4845 goto out_disable_device;
4846 }
4847 }
4848
4849 error = -ENOMEM;
4850 dev = alloc_etherdev(sizeof(DEV_NET));
4851 if (!dev) {
4852 printk(KERN_ERR "sk98lin: unable to allocate etherdev "
4853 "structure!\n");
4854 goto out_disable_device;
4855 }
4856
4857 pNet = netdev_priv(dev);
4858 pNet->pAC = kzalloc(sizeof(SK_AC), GFP_KERNEL);
4859 if (!pNet->pAC) {
4860 printk(KERN_ERR "sk98lin: unable to allocate adapter "
4861 "structure!\n");
4862 goto out_free_netdev;
4863 }
4864
4865 pAC = pNet->pAC;
4866 pAC->PciDev = pdev;
4867
4868 pAC->dev[0] = dev;
4869 pAC->dev[1] = dev;
4870 pAC->CheckQueue = SK_FALSE;
4871
4872 dev->irq = pdev->irq;
4873
4874 error = SkGeInitPCI(pAC);
4875 if (error) {
4876 printk(KERN_ERR "sk98lin: PCI setup failed: %i\n", error);
4877 goto out_free_netdev;
4878 }
4879
4880 SET_MODULE_OWNER(dev);
4881 dev->open = &SkGeOpen;
4882 dev->stop = &SkGeClose;
4883 dev->hard_start_xmit = &SkGeXmit;
4884 dev->get_stats = &SkGeStats;
4885 dev->set_multicast_list = &SkGeSetRxMode;
4886 dev->set_mac_address = &SkGeSetMacAddr;
4887 dev->do_ioctl = &SkGeIoctl;
4888 dev->change_mtu = &SkGeChangeMtu;
4889#ifdef CONFIG_NET_POLL_CONTROLLER
4890 dev->poll_controller = &SkGePollController;
4891#endif
4892 SET_NETDEV_DEV(dev, &pdev->dev);
4893 SET_ETHTOOL_OPS(dev, &SkGeEthtoolOps);
4894
4895 /* Use only if yukon hardware */
4896 if (pAC->ChipsetType) {
4897#ifdef USE_SK_TX_CHECKSUM
4898 dev->features |= NETIF_F_IP_CSUM;
4899#endif
4900#ifdef SK_ZEROCOPY
4901 dev->features |= NETIF_F_SG;
4902#endif
4903#ifdef USE_SK_RX_CHECKSUM
4904 pAC->RxPort[0].RxCsum = 1;
4905#endif
4906 }
4907
4908 if (using_dac)
4909 dev->features |= NETIF_F_HIGHDMA;
4910
4911 pAC->Index = boards_found++;
4912
4913 error = SkGeBoardInit(dev, pAC);
4914 if (error)
4915 goto out_free_netdev;
4916
4917 /* Read Adapter name from VPD */
4918 if (ProductStr(pAC, DeviceStr, sizeof(DeviceStr)) != 0) {
4919 error = -EIO;
4920 printk(KERN_ERR "sk98lin: Could not read VPD data.\n");
4921 goto out_free_resources;
4922 }
4923
4924 /* Register net device */
4925 error = register_netdev(dev);
4926 if (error) {
4927 printk(KERN_ERR "sk98lin: Could not register device.\n");
4928 goto out_free_resources;
4929 }
4930
4931 /* Print adapter specific string from vpd */
4932 printk("%s: %s\n", dev->name, DeviceStr);
4933
4934 /* Print configuration settings */
4935 printk(" PrefPort:%c RlmtMode:%s\n",
4936 'A' + pAC->Rlmt.Net[0].Port[pAC->Rlmt.Net[0].PrefPort]->PortNumber,
4937 (pAC->RlmtMode==0) ? "Check Link State" :
4938 ((pAC->RlmtMode==1) ? "Check Link State" :
4939 ((pAC->RlmtMode==3) ? "Check Local Port" :
4940 ((pAC->RlmtMode==7) ? "Check Segmentation" :
4941 ((pAC->RlmtMode==17) ? "Dual Check Link State" :"Error")))));
4942
4943 SkGeYellowLED(pAC, pAC->IoBase, 1);
4944
4945 memcpy(&dev->dev_addr, &pAC->Addr.Net[0].CurrentMacAddress, 6);
4946 memcpy(dev->perm_addr, dev->dev_addr, dev->addr_len);
4947
4948 pNet->PortNr = 0;
4949 pNet->NetNr = 0;
4950
4951 boards_found++;
4952
4953 pci_set_drvdata(pdev, dev);
4954
4955 /* More then one port found */
4956 if ((pAC->GIni.GIMacsFound == 2 ) && (pAC->RlmtNets == 2)) {
4957 dev = alloc_etherdev(sizeof(DEV_NET));
4958 if (!dev) {
4959 printk(KERN_ERR "sk98lin: unable to allocate etherdev "
4960 "structure!\n");
4961 goto single_port;
4962 }
4963
4964 pNet = netdev_priv(dev);
4965 pNet->PortNr = 1;
4966 pNet->NetNr = 1;
4967 pNet->pAC = pAC;
4968
4969 dev->open = &SkGeOpen;
4970 dev->stop = &SkGeClose;
4971 dev->hard_start_xmit = &SkGeXmit;
4972 dev->get_stats = &SkGeStats;
4973 dev->set_multicast_list = &SkGeSetRxMode;
4974 dev->set_mac_address = &SkGeSetMacAddr;
4975 dev->do_ioctl = &SkGeIoctl;
4976 dev->change_mtu = &SkGeChangeMtu;
4977 SET_NETDEV_DEV(dev, &pdev->dev);
4978 SET_ETHTOOL_OPS(dev, &SkGeEthtoolOps);
4979
4980 if (pAC->ChipsetType) {
4981#ifdef USE_SK_TX_CHECKSUM
4982 dev->features |= NETIF_F_IP_CSUM;
4983#endif
4984#ifdef SK_ZEROCOPY
4985 dev->features |= NETIF_F_SG;
4986#endif
4987#ifdef USE_SK_RX_CHECKSUM
4988 pAC->RxPort[1].RxCsum = 1;
4989#endif
4990 }
4991
4992 if (using_dac)
4993 dev->features |= NETIF_F_HIGHDMA;
4994
4995 error = register_netdev(dev);
4996 if (error) {
4997 printk(KERN_ERR "sk98lin: Could not register device"
4998 " for second port. (%d)\n", error);
4999 free_netdev(dev);
5000 goto single_port;
5001 }
5002
5003 pAC->dev[1] = dev;
5004 memcpy(&dev->dev_addr,
5005 &pAC->Addr.Net[1].CurrentMacAddress, 6);
5006 memcpy(dev->perm_addr, dev->dev_addr, dev->addr_len);
5007
5008 printk("%s: %s\n", dev->name, DeviceStr);
5009 printk(" PrefPort:B RlmtMode:Dual Check Link State\n");
5010 }
5011
5012single_port:
5013
5014 /* Save the hardware revision */
5015 pAC->HWRevision = (((pAC->GIni.GIPciHwRev >> 4) & 0x0F)*10) +
5016 (pAC->GIni.GIPciHwRev & 0x0F);
5017
5018 /* Set driver globals */
5019 pAC->Pnmi.pDriverFileName = DRIVER_FILE_NAME;
5020 pAC->Pnmi.pDriverReleaseDate = DRIVER_REL_DATE;
5021
5022 memset(&pAC->PnmiBackup, 0, sizeof(SK_PNMI_STRUCT_DATA));
5023 memcpy(&pAC->PnmiBackup, &pAC->PnmiStruct, sizeof(SK_PNMI_STRUCT_DATA));
5024
5025 return 0;
5026
5027 out_free_resources:
5028 FreeResources(dev);
5029 out_free_netdev:
5030 free_netdev(dev);
5031 out_disable_device:
5032 pci_disable_device(pdev);
5033 out:
5034 return error;
5035}
5036
5037static void __devexit skge_remove_one(struct pci_dev *pdev)
5038{
5039 struct net_device *dev = pci_get_drvdata(pdev);
5040 DEV_NET *pNet = netdev_priv(dev);
5041 SK_AC *pAC = pNet->pAC;
5042 struct net_device *otherdev = pAC->dev[1];
5043
5044 unregister_netdev(dev);
5045
5046 SkGeYellowLED(pAC, pAC->IoBase, 0);
5047
5048 if (pAC->BoardLevel == SK_INIT_RUN) {
5049 SK_EVPARA EvPara;
5050 unsigned long Flags;
5051
5052 /* board is still alive */
5053 spin_lock_irqsave(&pAC->SlowPathLock, Flags);
5054 EvPara.Para32[0] = 0;
5055 EvPara.Para32[1] = -1;
5056 SkEventQueue(pAC, SKGE_RLMT, SK_RLMT_STOP, EvPara);
5057 EvPara.Para32[0] = 1;
5058 EvPara.Para32[1] = -1;
5059 SkEventQueue(pAC, SKGE_RLMT, SK_RLMT_STOP, EvPara);
5060 SkEventDispatcher(pAC, pAC->IoBase);
5061 /* disable interrupts */
5062 SK_OUT32(pAC->IoBase, B0_IMSK, 0);
5063 SkGeDeInit(pAC, pAC->IoBase);
5064 spin_unlock_irqrestore(&pAC->SlowPathLock, Flags);
5065 pAC->BoardLevel = SK_INIT_DATA;
5066 /* We do NOT check here, if IRQ was pending, of course*/
5067 }
5068
5069 if (pAC->BoardLevel == SK_INIT_IO) {
5070 /* board is still alive */
5071 SkGeDeInit(pAC, pAC->IoBase);
5072 pAC->BoardLevel = SK_INIT_DATA;
5073 }
5074
5075 FreeResources(dev);
5076 free_netdev(dev);
5077 if (otherdev != dev)
5078 free_netdev(otherdev);
5079 kfree(pAC);
5080}
5081
5082#ifdef CONFIG_PM
5083static int skge_suspend(struct pci_dev *pdev, pm_message_t state)
5084{
5085 struct net_device *dev = pci_get_drvdata(pdev);
5086 DEV_NET *pNet = netdev_priv(dev);
5087 SK_AC *pAC = pNet->pAC;
5088 struct net_device *otherdev = pAC->dev[1];
5089
5090 if (netif_running(dev)) {
5091 netif_carrier_off(dev);
5092 DoPrintInterfaceChange = SK_FALSE;
5093 SkDrvDeInitAdapter(pAC, 0); /* performs SkGeClose */
5094 netif_device_detach(dev);
5095 }
5096 if (otherdev != dev) {
5097 if (netif_running(otherdev)) {
5098 netif_carrier_off(otherdev);
5099 DoPrintInterfaceChange = SK_FALSE;
5100 SkDrvDeInitAdapter(pAC, 1); /* performs SkGeClose */
5101 netif_device_detach(otherdev);
5102 }
5103 }
5104
5105 pci_save_state(pdev);
5106 pci_enable_wake(pdev, pci_choose_state(pdev, state), 0);
5107 if (pAC->AllocFlag & SK_ALLOC_IRQ) {
5108 free_irq(dev->irq, dev);
5109 }
5110 pci_disable_device(pdev);
5111 pci_set_power_state(pdev, pci_choose_state(pdev, state));
5112
5113 return 0;
5114}
5115
5116static int skge_resume(struct pci_dev *pdev)
5117{
5118 struct net_device *dev = pci_get_drvdata(pdev);
5119 DEV_NET *pNet = netdev_priv(dev);
5120 SK_AC *pAC = pNet->pAC;
5121 struct net_device *otherdev = pAC->dev[1];
5122 int ret;
5123
5124 pci_set_power_state(pdev, PCI_D0);
5125 pci_restore_state(pdev);
5126 ret = pci_enable_device(pdev);
5127 if (ret) {
5128 printk(KERN_WARNING "sk98lin: unable to enable device %s "
5129 "in resume\n", dev->name);
5130 goto err_out;
5131 }
5132 pci_set_master(pdev);
5133 if (pAC->GIni.GIMacsFound == 2)
5134 ret = request_irq(dev->irq, SkGeIsr, IRQF_SHARED, "sk98lin", dev);
5135 else
5136 ret = request_irq(dev->irq, SkGeIsrOnePort, IRQF_SHARED, "sk98lin", dev);
5137 if (ret) {
5138 printk(KERN_WARNING "sk98lin: unable to acquire IRQ %d\n", dev->irq);
5139 ret = -EBUSY;
5140 goto err_out_disable_pdev;
5141 }
5142
5143 netif_device_attach(dev);
5144 if (netif_running(dev)) {
5145 DoPrintInterfaceChange = SK_FALSE;
5146 SkDrvInitAdapter(pAC, 0); /* first device */
5147 }
5148 if (otherdev != dev) {
5149 netif_device_attach(otherdev);
5150 if (netif_running(otherdev)) {
5151 DoPrintInterfaceChange = SK_FALSE;
5152 SkDrvInitAdapter(pAC, 1); /* second device */
5153 }
5154 }
5155
5156 return 0;
5157
5158err_out_disable_pdev:
5159 pci_disable_device(pdev);
5160err_out:
5161 pAC->AllocFlag &= ~SK_ALLOC_IRQ;
5162 dev->irq = 0;
5163 return ret;
5164}
5165#else
5166#define skge_suspend NULL
5167#define skge_resume NULL
5168#endif
5169
5170static struct pci_device_id skge_pci_tbl[] = {
5171#ifdef SK98LIN_ALL_DEVICES
5172 { PCI_VENDOR_ID_3COM, 0x1700, PCI_ANY_ID, PCI_ANY_ID, 0, 0, 0 },
5173 { PCI_VENDOR_ID_3COM, 0x80eb, PCI_ANY_ID, PCI_ANY_ID, 0, 0, 0 },
5174#endif
5175#ifdef GENESIS
5176 /* Generic SysKonnect SK-98xx Gigabit Ethernet Server Adapter */
5177 { PCI_VENDOR_ID_SYSKONNECT, 0x4300, PCI_ANY_ID, PCI_ANY_ID, 0, 0, 0 },
5178#endif
5179 /* Generic SysKonnect SK-98xx V2.0 Gigabit Ethernet Adapter */
5180 { PCI_VENDOR_ID_SYSKONNECT, 0x4320, PCI_ANY_ID, PCI_ANY_ID, 0, 0, 0 },
5181#ifdef SK98LIN_ALL_DEVICES
5182/* DLink card does not have valid VPD so this driver gags
5183 * { PCI_VENDOR_ID_DLINK, 0x4c00, PCI_ANY_ID, PCI_ANY_ID, 0, 0, 0 },
5184 */
5185 { PCI_VENDOR_ID_MARVELL, 0x4320, PCI_ANY_ID, PCI_ANY_ID, 0, 0, 0 },
5186 { PCI_VENDOR_ID_MARVELL, 0x5005, PCI_ANY_ID, PCI_ANY_ID, 0, 0, 0 },
5187 { PCI_VENDOR_ID_CNET, 0x434e, PCI_ANY_ID, PCI_ANY_ID, 0, 0, 0 },
5188 { PCI_VENDOR_ID_LINKSYS, 0x1032, PCI_ANY_ID, 0x0015, },
5189 { PCI_VENDOR_ID_LINKSYS, 0x1064, PCI_ANY_ID, PCI_ANY_ID, 0, 0, 0 },
5190#endif
5191 { 0 }
5192};
5193
5194MODULE_DEVICE_TABLE(pci, skge_pci_tbl);
5195
5196static struct pci_driver skge_driver = {
5197 .name = "sk98lin",
5198 .id_table = skge_pci_tbl,
5199 .probe = skge_probe_one,
5200 .remove = __devexit_p(skge_remove_one),
5201 .suspend = skge_suspend,
5202 .resume = skge_resume,
5203};
5204
5205static int __init skge_init(void)
5206{
5207 printk(KERN_NOTICE "sk98lin: driver has been replaced by the skge driver"
5208 " and is scheduled for removal\n");
5209
5210 return pci_register_driver(&skge_driver);
5211}
5212
5213static void __exit skge_exit(void)
5214{
5215 pci_unregister_driver(&skge_driver);
5216}
5217
5218module_init(skge_init);
5219module_exit(skge_exit);
diff --git a/drivers/net/sk98lin/skgehwt.c b/drivers/net/sk98lin/skgehwt.c
new file mode 100644
index 000000000000..db670993c2df
--- /dev/null
+++ b/drivers/net/sk98lin/skgehwt.c
@@ -0,0 +1,171 @@
1/******************************************************************************
2 *
3 * Name: skgehwt.c
4 * Project: Gigabit Ethernet Adapters, Event Scheduler Module
5 * Version: $Revision: 1.15 $
6 * Date: $Date: 2003/09/16 13:41:23 $
7 * Purpose: Hardware Timer
8 *
9 ******************************************************************************/
10
11/******************************************************************************
12 *
13 * (C)Copyright 1998-2002 SysKonnect GmbH.
14 * (C)Copyright 2002-2003 Marvell.
15 *
16 * This program is free software; you can redistribute it and/or modify
17 * it under the terms of the GNU General Public License as published by
18 * the Free Software Foundation; either version 2 of the License, or
19 * (at your option) any later version.
20 *
21 * The information in this file is provided "AS IS" without warranty.
22 *
23 ******************************************************************************/
24
25/*
26 * Event queue and dispatcher
27 */
28#if (defined(DEBUG) || ((!defined(LINT)) && (!defined(SK_SLIM))))
29static const char SysKonnectFileId[] =
30 "@(#) $Id: skgehwt.c,v 1.15 2003/09/16 13:41:23 rschmidt Exp $ (C) Marvell.";
31#endif
32
33#include "h/skdrv1st.h" /* Driver Specific Definitions */
34#include "h/skdrv2nd.h" /* Adapter Control- and Driver specific Def. */
35
36#ifdef __C2MAN__
37/*
38 * Hardware Timer function queue management.
39 */
40intro()
41{}
42#endif
43
44/*
45 * Prototypes of local functions.
46 */
47#define SK_HWT_MAX (65000)
48
49/* correction factor */
50#define SK_HWT_FAC (1000 * (SK_U32)pAC->GIni.GIHstClkFact / 100)
51
52/*
53 * Initialize hardware timer.
54 *
55 * Must be called during init level 1.
56 */
57void SkHwtInit(
58SK_AC *pAC, /* Adapters context */
59SK_IOC Ioc) /* IoContext */
60{
61 pAC->Hwt.TStart = 0 ;
62 pAC->Hwt.TStop = 0 ;
63 pAC->Hwt.TActive = SK_FALSE;
64
65 SkHwtStop(pAC, Ioc);
66}
67
68/*
69 *
70 * Start hardware timer (clock ticks are 16us).
71 *
72 */
73void SkHwtStart(
74SK_AC *pAC, /* Adapters context */
75SK_IOC Ioc, /* IoContext */
76SK_U32 Time) /* Time in units of 16us to load the timer with. */
77{
78 SK_U32 Cnt;
79
80 if (Time > SK_HWT_MAX)
81 Time = SK_HWT_MAX;
82
83 pAC->Hwt.TStart = Time;
84 pAC->Hwt.TStop = 0L;
85
86 Cnt = Time;
87
88 /*
89 * if time < 16 us
90 * time = 16 us
91 */
92 if (!Cnt) {
93 Cnt++;
94 }
95
96 SK_OUT32(Ioc, B2_TI_INI, Cnt * SK_HWT_FAC);
97
98 SK_OUT16(Ioc, B2_TI_CTRL, TIM_START); /* Start timer. */
99
100 pAC->Hwt.TActive = SK_TRUE;
101}
102
103/*
104 * Stop hardware timer.
105 * and clear the timer IRQ
106 */
107void SkHwtStop(
108SK_AC *pAC, /* Adapters context */
109SK_IOC Ioc) /* IoContext */
110{
111 SK_OUT16(Ioc, B2_TI_CTRL, TIM_STOP);
112
113 SK_OUT16(Ioc, B2_TI_CTRL, TIM_CLR_IRQ);
114
115 pAC->Hwt.TActive = SK_FALSE;
116}
117
118
119/*
120 * Stop hardware timer and read time elapsed since last start.
121 *
122 * returns
123 * The elapsed time since last start in units of 16us.
124 *
125 */
126SK_U32 SkHwtRead(
127SK_AC *pAC, /* Adapters context */
128SK_IOC Ioc) /* IoContext */
129{
130 SK_U32 TRead;
131 SK_U32 IStatus;
132
133 if (pAC->Hwt.TActive) {
134
135 SkHwtStop(pAC, Ioc);
136
137 SK_IN32(Ioc, B2_TI_VAL, &TRead);
138 TRead /= SK_HWT_FAC;
139
140 SK_IN32(Ioc, B0_ISRC, &IStatus);
141
142 /* Check if timer expired (or wraped around) */
143 if ((TRead > pAC->Hwt.TStart) || (IStatus & IS_TIMINT)) {
144
145 SkHwtStop(pAC, Ioc);
146
147 pAC->Hwt.TStop = pAC->Hwt.TStart;
148 }
149 else {
150
151 pAC->Hwt.TStop = pAC->Hwt.TStart - TRead;
152 }
153 }
154 return(pAC->Hwt.TStop);
155}
156
157/*
158 * interrupt source= timer
159 */
160void SkHwtIsr(
161SK_AC *pAC, /* Adapters context */
162SK_IOC Ioc) /* IoContext */
163{
164 SkHwtStop(pAC, Ioc);
165
166 pAC->Hwt.TStop = pAC->Hwt.TStart;
167
168 SkTimerDone(pAC, Ioc);
169}
170
171/* End of file */
diff --git a/drivers/net/sk98lin/skgeinit.c b/drivers/net/sk98lin/skgeinit.c
new file mode 100644
index 000000000000..67f1d6a5c15d
--- /dev/null
+++ b/drivers/net/sk98lin/skgeinit.c
@@ -0,0 +1,2005 @@
1/******************************************************************************
2 *
3 * Name: skgeinit.c
4 * Project: Gigabit Ethernet Adapters, Common Modules
5 * Version: $Revision: 1.97 $
6 * Date: $Date: 2003/10/02 16:45:31 $
7 * Purpose: Contains functions to initialize the adapter
8 *
9 ******************************************************************************/
10
11/******************************************************************************
12 *
13 * (C)Copyright 1998-2002 SysKonnect.
14 * (C)Copyright 2002-2003 Marvell.
15 *
16 * This program is free software; you can redistribute it and/or modify
17 * it under the terms of the GNU General Public License as published by
18 * the Free Software Foundation; either version 2 of the License, or
19 * (at your option) any later version.
20 *
21 * The information in this file is provided "AS IS" without warranty.
22 *
23 ******************************************************************************/
24
25#include "h/skdrv1st.h"
26#include "h/skdrv2nd.h"
27
28/* global variables ***********************************************************/
29
30/* local variables ************************************************************/
31
32#if (defined(DEBUG) || ((!defined(LINT)) && (!defined(SK_SLIM))))
33static const char SysKonnectFileId[] =
34 "@(#) $Id: skgeinit.c,v 1.97 2003/10/02 16:45:31 rschmidt Exp $ (C) Marvell.";
35#endif
36
37struct s_QOffTab {
38 int RxQOff; /* Receive Queue Address Offset */
39 int XsQOff; /* Sync Tx Queue Address Offset */
40 int XaQOff; /* Async Tx Queue Address Offset */
41};
42static struct s_QOffTab QOffTab[] = {
43 {Q_R1, Q_XS1, Q_XA1}, {Q_R2, Q_XS2, Q_XA2}
44};
45
46struct s_Config {
47 char ScanString[8];
48 SK_U32 Value;
49};
50
51static struct s_Config OemConfig = {
52 {'O','E','M','_','C','o','n','f'},
53#ifdef SK_OEM_CONFIG
54 OEM_CONFIG_VALUE,
55#else
56 0,
57#endif
58};
59
60/******************************************************************************
61 *
62 * SkGePollTxD() - Enable / Disable Descriptor Polling of TxD Rings
63 *
64 * Description:
65 * Enable or disable the descriptor polling of the transmit descriptor
66 * ring(s) (TxD) for port 'Port'.
67 * The new configuration is *not* saved over any SkGeStopPort() and
68 * SkGeInitPort() calls.
69 *
70 * Returns:
71 * nothing
72 */
73void SkGePollTxD(
74SK_AC *pAC, /* adapter context */
75SK_IOC IoC, /* IO context */
76int Port, /* Port Index (MAC_1 + n) */
77SK_BOOL PollTxD) /* SK_TRUE (enable pol.), SK_FALSE (disable pol.) */
78{
79 SK_GEPORT *pPrt;
80 SK_U32 DWord;
81
82 pPrt = &pAC->GIni.GP[Port];
83
84 DWord = (SK_U32)(PollTxD ? CSR_ENA_POL : CSR_DIS_POL);
85
86 if (pPrt->PXSQSize != 0) {
87 SK_OUT32(IoC, Q_ADDR(pPrt->PXsQOff, Q_CSR), DWord);
88 }
89
90 if (pPrt->PXAQSize != 0) {
91 SK_OUT32(IoC, Q_ADDR(pPrt->PXaQOff, Q_CSR), DWord);
92 }
93} /* SkGePollTxD */
94
95
96/******************************************************************************
97 *
98 * SkGeYellowLED() - Switch the yellow LED on or off.
99 *
100 * Description:
101 * Switch the yellow LED on or off.
102 *
103 * Note:
104 * This function may be called any time after SkGeInit(Level 1).
105 *
106 * Returns:
107 * nothing
108 */
109void SkGeYellowLED(
110SK_AC *pAC, /* adapter context */
111SK_IOC IoC, /* IO context */
112int State) /* yellow LED state, 0 = OFF, 0 != ON */
113{
114 if (State == 0) {
115 /* Switch yellow LED OFF */
116 SK_OUT8(IoC, B0_LED, LED_STAT_OFF);
117 }
118 else {
119 /* Switch yellow LED ON */
120 SK_OUT8(IoC, B0_LED, LED_STAT_ON);
121 }
122} /* SkGeYellowLED */
123
124
125#if (!defined(SK_SLIM) || defined(GENESIS))
126/******************************************************************************
127 *
128 * SkGeXmitLED() - Modify the Operational Mode of a transmission LED.
129 *
130 * Description:
131 * The Rx or Tx LED which is specified by 'Led' will be
132 * enabled, disabled or switched on in test mode.
133 *
134 * Note:
135 * 'Led' must contain the address offset of the LEDs INI register.
136 *
137 * Usage:
138 * SkGeXmitLED(pAC, IoC, MR_ADDR(Port, TX_LED_INI), SK_LED_ENA);
139 *
140 * Returns:
141 * nothing
142 */
143void SkGeXmitLED(
144SK_AC *pAC, /* adapter context */
145SK_IOC IoC, /* IO context */
146int Led, /* offset to the LED Init Value register */
147int Mode) /* Mode may be SK_LED_DIS, SK_LED_ENA, SK_LED_TST */
148{
149 SK_U32 LedIni;
150
151 switch (Mode) {
152 case SK_LED_ENA:
153 LedIni = SK_XMIT_DUR * (SK_U32)pAC->GIni.GIHstClkFact / 100;
154 SK_OUT32(IoC, Led + XMIT_LED_INI, LedIni);
155 SK_OUT8(IoC, Led + XMIT_LED_CTRL, LED_START);
156 break;
157 case SK_LED_TST:
158 SK_OUT8(IoC, Led + XMIT_LED_TST, LED_T_ON);
159 SK_OUT32(IoC, Led + XMIT_LED_CNT, 100);
160 SK_OUT8(IoC, Led + XMIT_LED_CTRL, LED_START);
161 break;
162 case SK_LED_DIS:
163 default:
164 /*
165 * Do NOT stop the LED Timer here. The LED might be
166 * in on state. But it needs to go off.
167 */
168 SK_OUT32(IoC, Led + XMIT_LED_CNT, 0);
169 SK_OUT8(IoC, Led + XMIT_LED_TST, LED_T_OFF);
170 break;
171 }
172
173 /*
174 * 1000BT: The Transmit LED is driven by the PHY.
175 * But the default LED configuration is used for
176 * Level One and Broadcom PHYs.
177 * (Broadcom: It may be that PHY_B_PEC_EN_LTR has to be set.)
178 * (In this case it has to be added here. But we will see. XXX)
179 */
180} /* SkGeXmitLED */
181#endif /* !SK_SLIM || GENESIS */
182
183
184/******************************************************************************
185 *
186 * DoCalcAddr() - Calculates the start and the end address of a queue.
187 *
188 * Description:
189 * This function calculates the start and the end address of a queue.
190 * Afterwards the 'StartVal' is incremented to the next start position.
191 * If the port is already initialized the calculated values
192 * will be checked against the configured values and an
193 * error will be returned, if they are not equal.
194 * If the port is not initialized the values will be written to
195 * *StartAdr and *EndAddr.
196 *
197 * Returns:
198 * 0: success
199 * 1: configuration error
200 */
201static int DoCalcAddr(
202SK_AC *pAC, /* adapter context */
203SK_GEPORT SK_FAR *pPrt, /* port index */
204int QuSize, /* size of the queue to configure in kB */
205SK_U32 SK_FAR *StartVal, /* start value for address calculation */
206SK_U32 SK_FAR *QuStartAddr,/* start addr to calculate */
207SK_U32 SK_FAR *QuEndAddr) /* end address to calculate */
208{
209 SK_U32 EndVal;
210 SK_U32 NextStart;
211 int Rtv;
212
213 Rtv = 0;
214 if (QuSize == 0) {
215 EndVal = *StartVal;
216 NextStart = EndVal;
217 }
218 else {
219 EndVal = *StartVal + ((SK_U32)QuSize * 1024) - 1;
220 NextStart = EndVal + 1;
221 }
222
223 if (pPrt->PState >= SK_PRT_INIT) {
224 if (*StartVal != *QuStartAddr || EndVal != *QuEndAddr) {
225 Rtv = 1;
226 }
227 }
228 else {
229 *QuStartAddr = *StartVal;
230 *QuEndAddr = EndVal;
231 }
232
233 *StartVal = NextStart;
234 return(Rtv);
235} /* DoCalcAddr */
236
237/******************************************************************************
238 *
239 * SkGeInitAssignRamToQueues() - allocate default queue sizes
240 *
241 * Description:
242 * This function assigns the memory to the different queues and ports.
243 * When DualNet is set to SK_TRUE all ports get the same amount of memory.
244 * Otherwise the first port gets most of the memory and all the
245 * other ports just the required minimum.
246 * This function can only be called when pAC->GIni.GIRamSize and
247 * pAC->GIni.GIMacsFound have been initialized, usually this happens
248 * at init level 1
249 *
250 * Returns:
251 * 0 - ok
252 * 1 - invalid input values
253 * 2 - not enough memory
254 */
255
256int SkGeInitAssignRamToQueues(
257SK_AC *pAC, /* Adapter context */
258int ActivePort, /* Active Port in RLMT mode */
259SK_BOOL DualNet) /* adapter context */
260{
261 int i;
262 int UsedKilobytes; /* memory already assigned */
263 int ActivePortKilobytes; /* memory available for active port */
264 SK_GEPORT *pGePort;
265
266 UsedKilobytes = 0;
267
268 if (ActivePort >= pAC->GIni.GIMacsFound) {
269 SK_DBG_MSG(pAC, SK_DBGMOD_HWM, SK_DBGCAT_INIT,
270 ("SkGeInitAssignRamToQueues: ActivePort (%d) invalid\n",
271 ActivePort));
272 return(1);
273 }
274 if (((pAC->GIni.GIMacsFound * (SK_MIN_RXQ_SIZE + SK_MIN_TXQ_SIZE)) +
275 ((RAM_QUOTA_SYNC == 0) ? 0 : SK_MIN_TXQ_SIZE)) > pAC->GIni.GIRamSize) {
276 SK_DBG_MSG(pAC, SK_DBGMOD_HWM, SK_DBGCAT_INIT,
277 ("SkGeInitAssignRamToQueues: Not enough memory (%d)\n",
278 pAC->GIni.GIRamSize));
279 return(2);
280 }
281
282 if (DualNet) {
283 /* every port gets the same amount of memory */
284 ActivePortKilobytes = pAC->GIni.GIRamSize / pAC->GIni.GIMacsFound;
285 for (i = 0; i < pAC->GIni.GIMacsFound; i++) {
286
287 pGePort = &pAC->GIni.GP[i];
288
289 /* take away the minimum memory for active queues */
290 ActivePortKilobytes -= (SK_MIN_RXQ_SIZE + SK_MIN_TXQ_SIZE);
291
292 /* receive queue gets the minimum + 80% of the rest */
293 pGePort->PRxQSize = (int) (ROUND_QUEUE_SIZE_KB((
294 ActivePortKilobytes * (unsigned long) RAM_QUOTA_RX) / 100))
295 + SK_MIN_RXQ_SIZE;
296
297 ActivePortKilobytes -= (pGePort->PRxQSize - SK_MIN_RXQ_SIZE);
298
299 /* synchronous transmit queue */
300 pGePort->PXSQSize = 0;
301
302 /* asynchronous transmit queue */
303 pGePort->PXAQSize = (int) ROUND_QUEUE_SIZE_KB(ActivePortKilobytes +
304 SK_MIN_TXQ_SIZE);
305 }
306 }
307 else {
308 /* Rlmt Mode or single link adapter */
309
310 /* Set standby queue size defaults for all standby ports */
311 for (i = 0; i < pAC->GIni.GIMacsFound; i++) {
312
313 if (i != ActivePort) {
314 pGePort = &pAC->GIni.GP[i];
315
316 pGePort->PRxQSize = SK_MIN_RXQ_SIZE;
317 pGePort->PXAQSize = SK_MIN_TXQ_SIZE;
318 pGePort->PXSQSize = 0;
319
320 /* Count used RAM */
321 UsedKilobytes += pGePort->PRxQSize + pGePort->PXAQSize;
322 }
323 }
324 /* what's left? */
325 ActivePortKilobytes = pAC->GIni.GIRamSize - UsedKilobytes;
326
327 /* assign it to the active port */
328 /* first take away the minimum memory */
329 ActivePortKilobytes -= (SK_MIN_RXQ_SIZE + SK_MIN_TXQ_SIZE);
330 pGePort = &pAC->GIni.GP[ActivePort];
331
332 /* receive queue get's the minimum + 80% of the rest */
333 pGePort->PRxQSize = (int) (ROUND_QUEUE_SIZE_KB((ActivePortKilobytes *
334 (unsigned long) RAM_QUOTA_RX) / 100)) + SK_MIN_RXQ_SIZE;
335
336 ActivePortKilobytes -= (pGePort->PRxQSize - SK_MIN_RXQ_SIZE);
337
338 /* synchronous transmit queue */
339 pGePort->PXSQSize = 0;
340
341 /* asynchronous transmit queue */
342 pGePort->PXAQSize = (int) ROUND_QUEUE_SIZE_KB(ActivePortKilobytes) +
343 SK_MIN_TXQ_SIZE;
344 }
345#ifdef VCPU
346 VCPUprintf(0, "PRxQSize=%u, PXSQSize=%u, PXAQSize=%u\n",
347 pGePort->PRxQSize, pGePort->PXSQSize, pGePort->PXAQSize);
348#endif /* VCPU */
349
350 return(0);
351} /* SkGeInitAssignRamToQueues */
352
353/******************************************************************************
354 *
355 * SkGeCheckQSize() - Checks the Adapters Queue Size Configuration
356 *
357 * Description:
358 * This function verifies the Queue Size Configuration specified
359 * in the variables PRxQSize, PXSQSize, and PXAQSize of all
360 * used ports.
361 * This requirements must be fullfilled to have a valid configuration:
362 * - The size of all queues must not exceed GIRamSize.
363 * - The queue sizes must be specified in units of 8 kB.
364 * - The size of Rx queues of available ports must not be
365 * smaller than 16 kB.
366 * - The size of at least one Tx queue (synch. or asynch.)
367 * of available ports must not be smaller than 16 kB
368 * when Jumbo Frames are used.
369 * - The RAM start and end addresses must not be changed
370 * for ports which are already initialized.
371 * Furthermore SkGeCheckQSize() defines the Start and End Addresses
372 * of all ports and stores them into the HWAC port structure.
373 *
374 * Returns:
375 * 0: Queue Size Configuration valid
376 * 1: Queue Size Configuration invalid
377 */
378static int SkGeCheckQSize(
379SK_AC *pAC, /* adapter context */
380int Port) /* port index */
381{
382 SK_GEPORT *pPrt;
383 int i;
384 int Rtv;
385 int Rtv2;
386 SK_U32 StartAddr;
387#ifndef SK_SLIM
388 int UsedMem; /* total memory used (max. found ports) */
389#endif
390
391 Rtv = 0;
392
393#ifndef SK_SLIM
394
395 UsedMem = 0;
396 for (i = 0; i < pAC->GIni.GIMacsFound; i++) {
397 pPrt = &pAC->GIni.GP[i];
398
399 if ((pPrt->PRxQSize & QZ_UNITS) != 0 ||
400 (pPrt->PXSQSize & QZ_UNITS) != 0 ||
401 (pPrt->PXAQSize & QZ_UNITS) != 0) {
402
403 SK_ERR_LOG(pAC, SK_ERRCL_SW, SKERR_HWI_E012, SKERR_HWI_E012MSG);
404 return(1);
405 }
406
407 if (i == Port && pPrt->PRxQSize < SK_MIN_RXQ_SIZE) {
408 SK_ERR_LOG(pAC, SK_ERRCL_SW, SKERR_HWI_E011, SKERR_HWI_E011MSG);
409 return(1);
410 }
411
412 /*
413 * the size of at least one Tx queue (synch. or asynch.) has to be > 0.
414 * if Jumbo Frames are used, this size has to be >= 16 kB.
415 */
416 if ((i == Port && pPrt->PXSQSize == 0 && pPrt->PXAQSize == 0) ||
417 (pAC->GIni.GIPortUsage == SK_JUMBO_LINK &&
418 ((pPrt->PXSQSize > 0 && pPrt->PXSQSize < SK_MIN_TXQ_SIZE) ||
419 (pPrt->PXAQSize > 0 && pPrt->PXAQSize < SK_MIN_TXQ_SIZE)))) {
420 SK_ERR_LOG(pAC, SK_ERRCL_SW, SKERR_HWI_E023, SKERR_HWI_E023MSG);
421 return(1);
422 }
423
424 UsedMem += pPrt->PRxQSize + pPrt->PXSQSize + pPrt->PXAQSize;
425 }
426
427 if (UsedMem > pAC->GIni.GIRamSize) {
428 SK_ERR_LOG(pAC, SK_ERRCL_SW, SKERR_HWI_E012, SKERR_HWI_E012MSG);
429 return(1);
430 }
431#endif /* !SK_SLIM */
432
433 /* Now start address calculation */
434 StartAddr = pAC->GIni.GIRamOffs;
435 for (i = 0; i < pAC->GIni.GIMacsFound; i++) {
436 pPrt = &pAC->GIni.GP[i];
437
438 /* Calculate/Check values for the receive queue */
439 Rtv2 = DoCalcAddr(pAC, pPrt, pPrt->PRxQSize, &StartAddr,
440 &pPrt->PRxQRamStart, &pPrt->PRxQRamEnd);
441 Rtv |= Rtv2;
442
443 /* Calculate/Check values for the synchronous Tx queue */
444 Rtv2 = DoCalcAddr(pAC, pPrt, pPrt->PXSQSize, &StartAddr,
445 &pPrt->PXsQRamStart, &pPrt->PXsQRamEnd);
446 Rtv |= Rtv2;
447
448 /* Calculate/Check values for the asynchronous Tx queue */
449 Rtv2 = DoCalcAddr(pAC, pPrt, pPrt->PXAQSize, &StartAddr,
450 &pPrt->PXaQRamStart, &pPrt->PXaQRamEnd);
451 Rtv |= Rtv2;
452
453 if (Rtv) {
454 SK_ERR_LOG(pAC, SK_ERRCL_SW, SKERR_HWI_E013, SKERR_HWI_E013MSG);
455 return(1);
456 }
457 }
458
459 return(0);
460} /* SkGeCheckQSize */
461
462
463#ifdef GENESIS
464/******************************************************************************
465 *
466 * SkGeInitMacArb() - Initialize the MAC Arbiter
467 *
468 * Description:
469 * This function initializes the MAC Arbiter.
470 * It must not be called if there is still an
471 * initialized or active port.
472 *
473 * Returns:
474 * nothing
475 */
476static void SkGeInitMacArb(
477SK_AC *pAC, /* adapter context */
478SK_IOC IoC) /* IO context */
479{
480 /* release local reset */
481 SK_OUT16(IoC, B3_MA_TO_CTRL, MA_RST_CLR);
482
483 /* configure timeout values */
484 SK_OUT8(IoC, B3_MA_TOINI_RX1, SK_MAC_TO_53);
485 SK_OUT8(IoC, B3_MA_TOINI_RX2, SK_MAC_TO_53);
486 SK_OUT8(IoC, B3_MA_TOINI_TX1, SK_MAC_TO_53);
487 SK_OUT8(IoC, B3_MA_TOINI_TX2, SK_MAC_TO_53);
488
489 SK_OUT8(IoC, B3_MA_RCINI_RX1, 0);
490 SK_OUT8(IoC, B3_MA_RCINI_RX2, 0);
491 SK_OUT8(IoC, B3_MA_RCINI_TX1, 0);
492 SK_OUT8(IoC, B3_MA_RCINI_TX2, 0);
493
494 /* recovery values are needed for XMAC II Rev. B2 only */
495 /* Fast Output Enable Mode was intended to use with Rev. B2, but now? */
496
497 /*
498 * There is no start or enable button to push, therefore
499 * the MAC arbiter is configured and enabled now.
500 */
501} /* SkGeInitMacArb */
502
503
504/******************************************************************************
505 *
506 * SkGeInitPktArb() - Initialize the Packet Arbiter
507 *
508 * Description:
509 * This function initializes the Packet Arbiter.
510 * It must not be called if there is still an
511 * initialized or active port.
512 *
513 * Returns:
514 * nothing
515 */
516static void SkGeInitPktArb(
517SK_AC *pAC, /* adapter context */
518SK_IOC IoC) /* IO context */
519{
520 /* release local reset */
521 SK_OUT16(IoC, B3_PA_CTRL, PA_RST_CLR);
522
523 /* configure timeout values */
524 SK_OUT16(IoC, B3_PA_TOINI_RX1, SK_PKT_TO_MAX);
525 SK_OUT16(IoC, B3_PA_TOINI_RX2, SK_PKT_TO_MAX);
526 SK_OUT16(IoC, B3_PA_TOINI_TX1, SK_PKT_TO_MAX);
527 SK_OUT16(IoC, B3_PA_TOINI_TX2, SK_PKT_TO_MAX);
528
529 /*
530 * enable timeout timers if jumbo frames not used
531 * NOTE: the packet arbiter timeout interrupt is needed for
532 * half duplex hangup workaround
533 */
534 if (pAC->GIni.GIPortUsage != SK_JUMBO_LINK) {
535 if (pAC->GIni.GIMacsFound == 1) {
536 SK_OUT16(IoC, B3_PA_CTRL, PA_ENA_TO_TX1);
537 }
538 else {
539 SK_OUT16(IoC, B3_PA_CTRL, PA_ENA_TO_TX1 | PA_ENA_TO_TX2);
540 }
541 }
542} /* SkGeInitPktArb */
543#endif /* GENESIS */
544
545
546/******************************************************************************
547 *
548 * SkGeInitMacFifo() - Initialize the MAC FIFOs
549 *
550 * Description:
551 * Initialize all MAC FIFOs of the specified port
552 *
553 * Returns:
554 * nothing
555 */
556static void SkGeInitMacFifo(
557SK_AC *pAC, /* adapter context */
558SK_IOC IoC, /* IO context */
559int Port) /* Port Index (MAC_1 + n) */
560{
561 SK_U16 Word;
562#ifdef VCPU
563 SK_U32 DWord;
564#endif /* VCPU */
565 /*
566 * For each FIFO:
567 * - release local reset
568 * - use default value for MAC FIFO size
569 * - setup defaults for the control register
570 * - enable the FIFO
571 */
572
573#ifdef GENESIS
574 if (pAC->GIni.GIGenesis) {
575 /* Configure Rx MAC FIFO */
576 SK_OUT8(IoC, MR_ADDR(Port, RX_MFF_CTRL2), MFF_RST_CLR);
577 SK_OUT16(IoC, MR_ADDR(Port, RX_MFF_CTRL1), MFF_RX_CTRL_DEF);
578 SK_OUT8(IoC, MR_ADDR(Port, RX_MFF_CTRL2), MFF_ENA_OP_MD);
579
580 /* Configure Tx MAC FIFO */
581 SK_OUT8(IoC, MR_ADDR(Port, TX_MFF_CTRL2), MFF_RST_CLR);
582 SK_OUT16(IoC, MR_ADDR(Port, TX_MFF_CTRL1), MFF_TX_CTRL_DEF);
583 SK_OUT8(IoC, MR_ADDR(Port, TX_MFF_CTRL2), MFF_ENA_OP_MD);
584
585 /* Enable frame flushing if jumbo frames used */
586 if (pAC->GIni.GIPortUsage == SK_JUMBO_LINK) {
587 SK_OUT16(IoC, MR_ADDR(Port, RX_MFF_CTRL1), MFF_ENA_FLUSH);
588 }
589 }
590#endif /* GENESIS */
591
592#ifdef YUKON
593 if (pAC->GIni.GIYukon) {
594 /* set Rx GMAC FIFO Flush Mask */
595 SK_OUT16(IoC, MR_ADDR(Port, RX_GMF_FL_MSK), (SK_U16)RX_FF_FL_DEF_MSK);
596
597 Word = (SK_U16)GMF_RX_CTRL_DEF;
598
599 /* disable Rx GMAC FIFO Flush for YUKON-Lite Rev. A0 only */
600 if (pAC->GIni.GIYukonLite && pAC->GIni.GIChipId == CHIP_ID_YUKON) {
601
602 Word &= ~GMF_RX_F_FL_ON;
603 }
604
605 /* Configure Rx MAC FIFO */
606 SK_OUT8(IoC, MR_ADDR(Port, RX_GMF_CTRL_T), (SK_U8)GMF_RST_CLR);
607 SK_OUT16(IoC, MR_ADDR(Port, RX_GMF_CTRL_T), Word);
608
609 /* set Rx GMAC FIFO Flush Threshold (default: 0x0a -> 56 bytes) */
610 SK_OUT16(IoC, MR_ADDR(Port, RX_GMF_FL_THR), RX_GMF_FL_THR_DEF);
611
612 /* Configure Tx MAC FIFO */
613 SK_OUT8(IoC, MR_ADDR(Port, TX_GMF_CTRL_T), (SK_U8)GMF_RST_CLR);
614 SK_OUT16(IoC, MR_ADDR(Port, TX_GMF_CTRL_T), (SK_U16)GMF_TX_CTRL_DEF);
615
616#ifdef VCPU
617 SK_IN32(IoC, MR_ADDR(Port, RX_GMF_AF_THR), &DWord);
618 SK_IN32(IoC, MR_ADDR(Port, TX_GMF_AE_THR), &DWord);
619#endif /* VCPU */
620
621 /* set Tx GMAC FIFO Almost Empty Threshold */
622/* SK_OUT32(IoC, MR_ADDR(Port, TX_GMF_AE_THR), 0); */
623 }
624#endif /* YUKON */
625
626} /* SkGeInitMacFifo */
627
628#ifdef SK_LNK_SYNC_CNT
629/******************************************************************************
630 *
631 * SkGeLoadLnkSyncCnt() - Load the Link Sync Counter and starts counting
632 *
633 * Description:
634 * This function starts the Link Sync Counter of the specified
635 * port and enables the generation of an Link Sync IRQ.
636 * The Link Sync Counter may be used to detect an active link,
637 * if autonegotiation is not used.
638 *
639 * Note:
640 * o To ensure receiving the Link Sync Event the LinkSyncCounter
641 * should be initialized BEFORE clearing the XMAC's reset!
642 * o Enable IS_LNK_SYNC_M1 and IS_LNK_SYNC_M2 after calling this
643 * function.
644 *
645 * Returns:
646 * nothing
647 */
648void SkGeLoadLnkSyncCnt(
649SK_AC *pAC, /* adapter context */
650SK_IOC IoC, /* IO context */
651int Port, /* Port Index (MAC_1 + n) */
652SK_U32 CntVal) /* Counter value */
653{
654 SK_U32 OrgIMsk;
655 SK_U32 NewIMsk;
656 SK_U32 ISrc;
657 SK_BOOL IrqPend;
658
659 /* stop counter */
660 SK_OUT8(IoC, MR_ADDR(Port, LNK_SYNC_CTRL), LED_STOP);
661
662 /*
663 * ASIC problem:
664 * Each time starting the Link Sync Counter an IRQ is generated
665 * by the adapter. See problem report entry from 21.07.98
666 *
667 * Workaround: Disable Link Sync IRQ and clear the unexpeced IRQ
668 * if no IRQ is already pending.
669 */
670 IrqPend = SK_FALSE;
671 SK_IN32(IoC, B0_ISRC, &ISrc);
672 SK_IN32(IoC, B0_IMSK, &OrgIMsk);
673 if (Port == MAC_1) {
674 NewIMsk = OrgIMsk & ~IS_LNK_SYNC_M1;
675 if ((ISrc & IS_LNK_SYNC_M1) != 0) {
676 IrqPend = SK_TRUE;
677 }
678 }
679 else {
680 NewIMsk = OrgIMsk & ~IS_LNK_SYNC_M2;
681 if ((ISrc & IS_LNK_SYNC_M2) != 0) {
682 IrqPend = SK_TRUE;
683 }
684 }
685 if (!IrqPend) {
686 SK_OUT32(IoC, B0_IMSK, NewIMsk);
687 }
688
689 /* load counter */
690 SK_OUT32(IoC, MR_ADDR(Port, LNK_SYNC_INI), CntVal);
691
692 /* start counter */
693 SK_OUT8(IoC, MR_ADDR(Port, LNK_SYNC_CTRL), LED_START);
694
695 if (!IrqPend) {
696 /* clear the unexpected IRQ, and restore the interrupt mask */
697 SK_OUT8(IoC, MR_ADDR(Port, LNK_SYNC_CTRL), LED_CLR_IRQ);
698 SK_OUT32(IoC, B0_IMSK, OrgIMsk);
699 }
700} /* SkGeLoadLnkSyncCnt*/
701#endif /* SK_LNK_SYNC_CNT */
702
703#if defined(SK_DIAG) || defined(SK_CFG_SYNC)
704/******************************************************************************
705 *
706 * SkGeCfgSync() - Configure synchronous bandwidth for this port.
707 *
708 * Description:
709 * This function may be used to configure synchronous bandwidth
710 * to the specified port. This may be done any time after
711 * initializing the port. The configuration values are NOT saved
712 * in the HWAC port structure and will be overwritten any
713 * time when stopping and starting the port.
714 * Any values for the synchronous configuration will be ignored
715 * if the size of the synchronous queue is zero!
716 *
717 * The default configuration for the synchronous service is
718 * TXA_ENA_FSYNC. This means if the size of
719 * the synchronous queue is unequal zero but no specific
720 * synchronous bandwidth is configured, the synchronous queue
721 * will always have the 'unlimited' transmit priority!
722 *
723 * This mode will be restored if the synchronous bandwidth is
724 * deallocated ('IntTime' = 0 and 'LimCount' = 0).
725 *
726 * Returns:
727 * 0: success
728 * 1: parameter configuration error
729 * 2: try to configure quality of service although no
730 * synchronous queue is configured
731 */
732int SkGeCfgSync(
733SK_AC *pAC, /* adapter context */
734SK_IOC IoC, /* IO context */
735int Port, /* Port Index (MAC_1 + n) */
736SK_U32 IntTime, /* Interval Timer Value in units of 8ns */
737SK_U32 LimCount, /* Number of bytes to transfer during IntTime */
738int SyncMode) /* Sync Mode: TXA_ENA_ALLOC | TXA_DIS_ALLOC | 0 */
739{
740 int Rtv;
741
742 Rtv = 0;
743
744 /* check the parameters */
745 if (LimCount > IntTime ||
746 (LimCount == 0 && IntTime != 0) ||
747 (LimCount != 0 && IntTime == 0)) {
748
749 SK_ERR_LOG(pAC, SK_ERRCL_SW, SKERR_HWI_E010, SKERR_HWI_E010MSG);
750 return(1);
751 }
752
753 if (pAC->GIni.GP[Port].PXSQSize == 0) {
754 SK_ERR_LOG(pAC, SK_ERRCL_SW, SKERR_HWI_E009, SKERR_HWI_E009MSG);
755 return(2);
756 }
757
758 /* calculate register values */
759 IntTime = (IntTime / 2) * pAC->GIni.GIHstClkFact / 100;
760 LimCount = LimCount / 8;
761
762 if (IntTime > TXA_MAX_VAL || LimCount > TXA_MAX_VAL) {
763 SK_ERR_LOG(pAC, SK_ERRCL_SW, SKERR_HWI_E010, SKERR_HWI_E010MSG);
764 return(1);
765 }
766
767 /*
768 * - Enable 'Force Sync' to ensure the synchronous queue
769 * has the priority while configuring the new values.
770 * - Also 'disable alloc' to ensure the settings complies
771 * to the SyncMode parameter.
772 * - Disable 'Rate Control' to configure the new values.
773 * - write IntTime and LimCount
774 * - start 'Rate Control' and disable 'Force Sync'
775 * if Interval Timer or Limit Counter not zero.
776 */
777 SK_OUT8(IoC, MR_ADDR(Port, TXA_CTRL),
778 TXA_ENA_FSYNC | TXA_DIS_ALLOC | TXA_STOP_RC);
779
780 SK_OUT32(IoC, MR_ADDR(Port, TXA_ITI_INI), IntTime);
781 SK_OUT32(IoC, MR_ADDR(Port, TXA_LIM_INI), LimCount);
782
783 SK_OUT8(IoC, MR_ADDR(Port, TXA_CTRL),
784 (SK_U8)(SyncMode & (TXA_ENA_ALLOC | TXA_DIS_ALLOC)));
785
786 if (IntTime != 0 || LimCount != 0) {
787 SK_OUT8(IoC, MR_ADDR(Port, TXA_CTRL), TXA_DIS_FSYNC | TXA_START_RC);
788 }
789
790 return(0);
791} /* SkGeCfgSync */
792#endif /* SK_DIAG || SK_CFG_SYNC*/
793
794
795/******************************************************************************
796 *
797 * DoInitRamQueue() - Initialize the RAM Buffer Address of a single Queue
798 *
799 * Desccription:
800 * If the queue is used, enable and initialize it.
801 * Make sure the queue is still reset, if it is not used.
802 *
803 * Returns:
804 * nothing
805 */
806static void DoInitRamQueue(
807SK_AC *pAC, /* adapter context */
808SK_IOC IoC, /* IO context */
809int QuIoOffs, /* Queue IO Address Offset */
810SK_U32 QuStartAddr, /* Queue Start Address */
811SK_U32 QuEndAddr, /* Queue End Address */
812int QuType) /* Queue Type (SK_RX_SRAM_Q|SK_RX_BRAM_Q|SK_TX_RAM_Q) */
813{
814 SK_U32 RxUpThresVal;
815 SK_U32 RxLoThresVal;
816
817 if (QuStartAddr != QuEndAddr) {
818 /* calculate thresholds, assume we have a big Rx queue */
819 RxUpThresVal = (QuEndAddr + 1 - QuStartAddr - SK_RB_ULPP) / 8;
820 RxLoThresVal = (QuEndAddr + 1 - QuStartAddr - SK_RB_LLPP_B)/8;
821
822 /* build HW address format */
823 QuStartAddr = QuStartAddr / 8;
824 QuEndAddr = QuEndAddr / 8;
825
826 /* release local reset */
827 SK_OUT8(IoC, RB_ADDR(QuIoOffs, RB_CTRL), RB_RST_CLR);
828
829 /* configure addresses */
830 SK_OUT32(IoC, RB_ADDR(QuIoOffs, RB_START), QuStartAddr);
831 SK_OUT32(IoC, RB_ADDR(QuIoOffs, RB_END), QuEndAddr);
832 SK_OUT32(IoC, RB_ADDR(QuIoOffs, RB_WP), QuStartAddr);
833 SK_OUT32(IoC, RB_ADDR(QuIoOffs, RB_RP), QuStartAddr);
834
835 switch (QuType) {
836 case SK_RX_SRAM_Q:
837 /* configure threshold for small Rx Queue */
838 RxLoThresVal += (SK_RB_LLPP_B - SK_RB_LLPP_S) / 8;
839
840 /* continue with SK_RX_BRAM_Q */
841 case SK_RX_BRAM_Q:
842 /* write threshold for Rx Queue */
843
844 SK_OUT32(IoC, RB_ADDR(QuIoOffs, RB_RX_UTPP), RxUpThresVal);
845 SK_OUT32(IoC, RB_ADDR(QuIoOffs, RB_RX_LTPP), RxLoThresVal);
846
847 /* the high priority threshold not used */
848 break;
849 case SK_TX_RAM_Q:
850 /*
851 * Do NOT use Store & Forward under normal operation due to
852 * performance optimization (GENESIS only).
853 * But if Jumbo Frames are configured (XMAC Tx FIFO is only 4 kB)
854 * or YUKON is used ((GMAC Tx FIFO is only 1 kB)
855 * we NEED Store & Forward of the RAM buffer.
856 */
857 if (pAC->GIni.GIPortUsage == SK_JUMBO_LINK ||
858 pAC->GIni.GIYukon) {
859 /* enable Store & Forward Mode for the Tx Side */
860 SK_OUT8(IoC, RB_ADDR(QuIoOffs, RB_CTRL), RB_ENA_STFWD);
861 }
862 break;
863 }
864
865 /* set queue operational */
866 SK_OUT8(IoC, RB_ADDR(QuIoOffs, RB_CTRL), RB_ENA_OP_MD);
867 }
868 else {
869 /* ensure the queue is still disabled */
870 SK_OUT8(IoC, RB_ADDR(QuIoOffs, RB_CTRL), RB_RST_SET);
871 }
872} /* DoInitRamQueue */
873
874
875/******************************************************************************
876 *
877 * SkGeInitRamBufs() - Initialize the RAM Buffer Queues
878 *
879 * Description:
880 * Initialize all RAM Buffer Queues of the specified port
881 *
882 * Returns:
883 * nothing
884 */
885static void SkGeInitRamBufs(
886SK_AC *pAC, /* adapter context */
887SK_IOC IoC, /* IO context */
888int Port) /* Port Index (MAC_1 + n) */
889{
890 SK_GEPORT *pPrt;
891 int RxQType;
892
893 pPrt = &pAC->GIni.GP[Port];
894
895 if (pPrt->PRxQSize == SK_MIN_RXQ_SIZE) {
896 RxQType = SK_RX_SRAM_Q; /* small Rx Queue */
897 }
898 else {
899 RxQType = SK_RX_BRAM_Q; /* big Rx Queue */
900 }
901
902 DoInitRamQueue(pAC, IoC, pPrt->PRxQOff, pPrt->PRxQRamStart,
903 pPrt->PRxQRamEnd, RxQType);
904
905 DoInitRamQueue(pAC, IoC, pPrt->PXsQOff, pPrt->PXsQRamStart,
906 pPrt->PXsQRamEnd, SK_TX_RAM_Q);
907
908 DoInitRamQueue(pAC, IoC, pPrt->PXaQOff, pPrt->PXaQRamStart,
909 pPrt->PXaQRamEnd, SK_TX_RAM_Q);
910
911} /* SkGeInitRamBufs */
912
913
914/******************************************************************************
915 *
916 * SkGeInitRamIface() - Initialize the RAM Interface
917 *
918 * Description:
919 * This function initializes the Adapters RAM Interface.
920 *
921 * Note:
922 * This function is used in the diagnostics.
923 *
924 * Returns:
925 * nothing
926 */
927static void SkGeInitRamIface(
928SK_AC *pAC, /* adapter context */
929SK_IOC IoC) /* IO context */
930{
931 /* release local reset */
932 SK_OUT16(IoC, B3_RI_CTRL, RI_RST_CLR);
933
934 /* configure timeout values */
935 SK_OUT8(IoC, B3_RI_WTO_R1, SK_RI_TO_53);
936 SK_OUT8(IoC, B3_RI_WTO_XA1, SK_RI_TO_53);
937 SK_OUT8(IoC, B3_RI_WTO_XS1, SK_RI_TO_53);
938 SK_OUT8(IoC, B3_RI_RTO_R1, SK_RI_TO_53);
939 SK_OUT8(IoC, B3_RI_RTO_XA1, SK_RI_TO_53);
940 SK_OUT8(IoC, B3_RI_RTO_XS1, SK_RI_TO_53);
941 SK_OUT8(IoC, B3_RI_WTO_R2, SK_RI_TO_53);
942 SK_OUT8(IoC, B3_RI_WTO_XA2, SK_RI_TO_53);
943 SK_OUT8(IoC, B3_RI_WTO_XS2, SK_RI_TO_53);
944 SK_OUT8(IoC, B3_RI_RTO_R2, SK_RI_TO_53);
945 SK_OUT8(IoC, B3_RI_RTO_XA2, SK_RI_TO_53);
946 SK_OUT8(IoC, B3_RI_RTO_XS2, SK_RI_TO_53);
947
948} /* SkGeInitRamIface */
949
950
951/******************************************************************************
952 *
953 * SkGeInitBmu() - Initialize the BMU state machines
954 *
955 * Description:
956 * Initialize all BMU state machines of the specified port
957 *
958 * Returns:
959 * nothing
960 */
961static void SkGeInitBmu(
962SK_AC *pAC, /* adapter context */
963SK_IOC IoC, /* IO context */
964int Port) /* Port Index (MAC_1 + n) */
965{
966 SK_GEPORT *pPrt;
967 SK_U32 RxWm;
968 SK_U32 TxWm;
969
970 pPrt = &pAC->GIni.GP[Port];
971
972 RxWm = SK_BMU_RX_WM;
973 TxWm = SK_BMU_TX_WM;
974
975 if (!pAC->GIni.GIPciSlot64 && !pAC->GIni.GIPciClock66) {
976 /* for better performance */
977 RxWm /= 2;
978 TxWm /= 2;
979 }
980
981 /* Rx Queue: Release all local resets and set the watermark */
982 SK_OUT32(IoC, Q_ADDR(pPrt->PRxQOff, Q_CSR), CSR_CLR_RESET);
983 SK_OUT32(IoC, Q_ADDR(pPrt->PRxQOff, Q_F), RxWm);
984
985 /*
986 * Tx Queue: Release all local resets if the queue is used !
987 * set watermark
988 */
989 if (pPrt->PXSQSize != 0) {
990 SK_OUT32(IoC, Q_ADDR(pPrt->PXsQOff, Q_CSR), CSR_CLR_RESET);
991 SK_OUT32(IoC, Q_ADDR(pPrt->PXsQOff, Q_F), TxWm);
992 }
993
994 if (pPrt->PXAQSize != 0) {
995 SK_OUT32(IoC, Q_ADDR(pPrt->PXaQOff, Q_CSR), CSR_CLR_RESET);
996 SK_OUT32(IoC, Q_ADDR(pPrt->PXaQOff, Q_F), TxWm);
997 }
998 /*
999 * Do NOT enable the descriptor poll timers here, because
1000 * the descriptor addresses are not specified yet.
1001 */
1002} /* SkGeInitBmu */
1003
1004
1005/******************************************************************************
1006 *
1007 * TestStopBit() - Test the stop bit of the queue
1008 *
1009 * Description:
1010 * Stopping a queue is not as simple as it seems to be.
1011 * If descriptor polling is enabled, it may happen
1012 * that RX/TX stop is done and SV idle is NOT set.
1013 * In this case we have to issue another stop command.
1014 *
1015 * Returns:
1016 * The queues control status register
1017 */
1018static SK_U32 TestStopBit(
1019SK_AC *pAC, /* Adapter Context */
1020SK_IOC IoC, /* IO Context */
1021int QuIoOffs) /* Queue IO Address Offset */
1022{
1023 SK_U32 QuCsr; /* CSR contents */
1024
1025 SK_IN32(IoC, Q_ADDR(QuIoOffs, Q_CSR), &QuCsr);
1026
1027 if ((QuCsr & (CSR_STOP | CSR_SV_IDLE)) == 0) {
1028 /* Stop Descriptor overridden by start command */
1029 SK_OUT32(IoC, Q_ADDR(QuIoOffs, Q_CSR), CSR_STOP);
1030
1031 SK_IN32(IoC, Q_ADDR(QuIoOffs, Q_CSR), &QuCsr);
1032 }
1033
1034 return(QuCsr);
1035} /* TestStopBit */
1036
1037
1038/******************************************************************************
1039 *
1040 * SkGeStopPort() - Stop the Rx/Tx activity of the port 'Port'.
1041 *
1042 * Description:
1043 * After calling this function the descriptor rings and Rx and Tx
1044 * queues of this port may be reconfigured.
1045 *
1046 * It is possible to stop the receive and transmit path separate or
1047 * both together.
1048 *
1049 * Dir = SK_STOP_TX Stops the transmit path only and resets the MAC.
1050 * The receive queue is still active and
1051 * the pending Rx frames may be still transferred
1052 * into the RxD.
1053 * SK_STOP_RX Stop the receive path. The tansmit path
1054 * has to be stopped once before.
1055 * SK_STOP_ALL SK_STOP_TX + SK_STOP_RX
1056 *
1057 * RstMode = SK_SOFT_RST Resets the MAC. The PHY is still alive.
1058 * SK_HARD_RST Resets the MAC and the PHY.
1059 *
1060 * Example:
1061 * 1) A Link Down event was signaled for a port. Therefore the activity
1062 * of this port should be stopped and a hardware reset should be issued
1063 * to enable the workaround of XMAC Errata #2. But the received frames
1064 * should not be discarded.
1065 * ...
1066 * SkGeStopPort(pAC, IoC, Port, SK_STOP_TX, SK_HARD_RST);
1067 * (transfer all pending Rx frames)
1068 * SkGeStopPort(pAC, IoC, Port, SK_STOP_RX, SK_HARD_RST);
1069 * ...
1070 *
1071 * 2) An event was issued which request the driver to switch
1072 * the 'virtual active' link to an other already active port
1073 * as soon as possible. The frames in the receive queue of this
1074 * port may be lost. But the PHY must not be reset during this
1075 * event.
1076 * ...
1077 * SkGeStopPort(pAC, IoC, Port, SK_STOP_ALL, SK_SOFT_RST);
1078 * ...
1079 *
1080 * Extended Description:
1081 * If SK_STOP_TX is set,
1082 * o disable the MAC's receive and transmitter to prevent
1083 * from sending incomplete frames
1084 * o stop the port's transmit queues before terminating the
1085 * BMUs to prevent from performing incomplete PCI cycles
1086 * on the PCI bus
1087 * - The network Rx and Tx activity and PCI Tx transfer is
1088 * disabled now.
1089 * o reset the MAC depending on the RstMode
1090 * o Stop Interval Timer and Limit Counter of Tx Arbiter,
1091 * also disable Force Sync bit and Enable Alloc bit.
1092 * o perform a local reset of the port's Tx path
1093 * - reset the PCI FIFO of the async Tx queue
1094 * - reset the PCI FIFO of the sync Tx queue
1095 * - reset the RAM Buffer async Tx queue
1096 * - reset the RAM Buffer sync Tx queue
1097 * - reset the MAC Tx FIFO
1098 * o switch Link and Tx LED off, stop the LED counters
1099 *
1100 * If SK_STOP_RX is set,
1101 * o stop the port's receive queue
1102 * - The path data transfer activity is fully stopped now.
1103 * o perform a local reset of the port's Rx path
1104 * - reset the PCI FIFO of the Rx queue
1105 * - reset the RAM Buffer receive queue
1106 * - reset the MAC Rx FIFO
1107 * o switch Rx LED off, stop the LED counter
1108 *
1109 * If all ports are stopped,
1110 * o reset the RAM Interface.
1111 *
1112 * Notes:
1113 * o This function may be called during the driver states RESET_PORT and
1114 * SWITCH_PORT.
1115 */
1116void SkGeStopPort(
1117SK_AC *pAC, /* adapter context */
1118SK_IOC IoC, /* I/O context */
1119int Port, /* port to stop (MAC_1 + n) */
1120int Dir, /* Direction to Stop (SK_STOP_RX, SK_STOP_TX, SK_STOP_ALL) */
1121int RstMode)/* Reset Mode (SK_SOFT_RST, SK_HARD_RST) */
1122{
1123#ifndef SK_DIAG
1124 SK_EVPARA Para;
1125#endif /* !SK_DIAG */
1126 SK_GEPORT *pPrt;
1127 SK_U32 DWord;
1128 SK_U32 XsCsr;
1129 SK_U32 XaCsr;
1130 SK_U64 ToutStart;
1131 int i;
1132 int ToutCnt;
1133
1134 pPrt = &pAC->GIni.GP[Port];
1135
1136 if ((Dir & SK_STOP_TX) != 0) {
1137 /* disable receiver and transmitter */
1138 SkMacRxTxDisable(pAC, IoC, Port);
1139
1140 /* stop both transmit queues */
1141 /*
1142 * If the BMU is in the reset state CSR_STOP will terminate
1143 * immediately.
1144 */
1145 SK_OUT32(IoC, Q_ADDR(pPrt->PXsQOff, Q_CSR), CSR_STOP);
1146 SK_OUT32(IoC, Q_ADDR(pPrt->PXaQOff, Q_CSR), CSR_STOP);
1147
1148 ToutStart = SkOsGetTime(pAC);
1149 ToutCnt = 0;
1150 do {
1151 /*
1152 * Clear packet arbiter timeout to make sure
1153 * this loop will terminate.
1154 */
1155 SK_OUT16(IoC, B3_PA_CTRL, (SK_U16)((Port == MAC_1) ?
1156 PA_CLR_TO_TX1 : PA_CLR_TO_TX2));
1157
1158 /*
1159 * If the transfer stucks at the MAC the STOP command will not
1160 * terminate if we don't flush the XMAC's transmit FIFO !
1161 */
1162 SkMacFlushTxFifo(pAC, IoC, Port);
1163
1164 XsCsr = TestStopBit(pAC, IoC, pPrt->PXsQOff);
1165 XaCsr = TestStopBit(pAC, IoC, pPrt->PXaQOff);
1166
1167 if (SkOsGetTime(pAC) - ToutStart > (SK_TICKS_PER_SEC / 18)) {
1168 /*
1169 * Timeout of 1/18 second reached.
1170 * This needs to be checked at 1/18 sec only.
1171 */
1172 ToutCnt++;
1173 if (ToutCnt > 1) {
1174 /* Might be a problem when the driver event handler
1175 * calls StopPort again. XXX.
1176 */
1177
1178 /* Fatal Error, Loop aborted */
1179 SK_ERR_LOG(pAC, SK_ERRCL_HW, SKERR_HWI_E018,
1180 SKERR_HWI_E018MSG);
1181#ifndef SK_DIAG
1182 Para.Para64 = Port;
1183 SkEventQueue(pAC, SKGE_DRV, SK_DRV_PORT_FAIL, Para);
1184#endif /* !SK_DIAG */
1185 return;
1186 }
1187 /*
1188 * Cache incoherency workaround: Assume a start command
1189 * has been lost while sending the frame.
1190 */
1191 ToutStart = SkOsGetTime(pAC);
1192
1193 if ((XsCsr & CSR_STOP) != 0) {
1194 SK_OUT32(IoC, Q_ADDR(pPrt->PXsQOff, Q_CSR), CSR_START);
1195 }
1196 if ((XaCsr & CSR_STOP) != 0) {
1197 SK_OUT32(IoC, Q_ADDR(pPrt->PXaQOff, Q_CSR), CSR_START);
1198 }
1199 }
1200
1201 /*
1202 * Because of the ASIC problem report entry from 21.08.1998 it is
1203 * required to wait until CSR_STOP is reset and CSR_SV_IDLE is set.
1204 */
1205 } while ((XsCsr & (CSR_STOP | CSR_SV_IDLE)) != CSR_SV_IDLE ||
1206 (XaCsr & (CSR_STOP | CSR_SV_IDLE)) != CSR_SV_IDLE);
1207
1208 /* Reset the MAC depending on the RstMode */
1209 if (RstMode == SK_SOFT_RST) {
1210 SkMacSoftRst(pAC, IoC, Port);
1211 }
1212 else {
1213 SkMacHardRst(pAC, IoC, Port);
1214 }
1215
1216 /* Disable Force Sync bit and Enable Alloc bit */
1217 SK_OUT8(IoC, MR_ADDR(Port, TXA_CTRL),
1218 TXA_DIS_FSYNC | TXA_DIS_ALLOC | TXA_STOP_RC);
1219
1220 /* Stop Interval Timer and Limit Counter of Tx Arbiter */
1221 SK_OUT32(IoC, MR_ADDR(Port, TXA_ITI_INI), 0L);
1222 SK_OUT32(IoC, MR_ADDR(Port, TXA_LIM_INI), 0L);
1223
1224 /* Perform a local reset of the port's Tx path */
1225
1226 /* Reset the PCI FIFO of the async Tx queue */
1227 SK_OUT32(IoC, Q_ADDR(pPrt->PXaQOff, Q_CSR), CSR_SET_RESET);
1228 /* Reset the PCI FIFO of the sync Tx queue */
1229 SK_OUT32(IoC, Q_ADDR(pPrt->PXsQOff, Q_CSR), CSR_SET_RESET);
1230 /* Reset the RAM Buffer async Tx queue */
1231 SK_OUT8(IoC, RB_ADDR(pPrt->PXaQOff, RB_CTRL), RB_RST_SET);
1232 /* Reset the RAM Buffer sync Tx queue */
1233 SK_OUT8(IoC, RB_ADDR(pPrt->PXsQOff, RB_CTRL), RB_RST_SET);
1234
1235 /* Reset Tx MAC FIFO */
1236#ifdef GENESIS
1237 if (pAC->GIni.GIGenesis) {
1238 /* Note: MFF_RST_SET does NOT reset the XMAC ! */
1239 SK_OUT8(IoC, MR_ADDR(Port, TX_MFF_CTRL2), MFF_RST_SET);
1240
1241 /* switch Link and Tx LED off, stop the LED counters */
1242 /* Link LED is switched off by the RLMT and the Diag itself */
1243 SkGeXmitLED(pAC, IoC, MR_ADDR(Port, TX_LED_INI), SK_LED_DIS);
1244 }
1245#endif /* GENESIS */
1246
1247#ifdef YUKON
1248 if (pAC->GIni.GIYukon) {
1249 /* Reset TX MAC FIFO */
1250 SK_OUT8(IoC, MR_ADDR(Port, TX_GMF_CTRL_T), (SK_U8)GMF_RST_SET);
1251 }
1252#endif /* YUKON */
1253 }
1254
1255 if ((Dir & SK_STOP_RX) != 0) {
1256 /*
1257 * The RX Stop Command will not terminate if no buffers
1258 * are queued in the RxD ring. But it will always reach
1259 * the Idle state. Therefore we can use this feature to
1260 * stop the transfer of received packets.
1261 */
1262 /* stop the port's receive queue */
1263 SK_OUT32(IoC, Q_ADDR(pPrt->PRxQOff, Q_CSR), CSR_STOP);
1264
1265 i = 100;
1266 do {
1267 /*
1268 * Clear packet arbiter timeout to make sure
1269 * this loop will terminate
1270 */
1271 SK_OUT16(IoC, B3_PA_CTRL, (SK_U16)((Port == MAC_1) ?
1272 PA_CLR_TO_RX1 : PA_CLR_TO_RX2));
1273
1274 DWord = TestStopBit(pAC, IoC, pPrt->PRxQOff);
1275
1276 /* timeout if i==0 (bug fix for #10748) */
1277 if (--i == 0) {
1278 SK_ERR_LOG(pAC, SK_ERRCL_HW, SKERR_HWI_E024,
1279 SKERR_HWI_E024MSG);
1280 break;
1281 }
1282 /*
1283 * because of the ASIC problem report entry from 21.08.98
1284 * it is required to wait until CSR_STOP is reset and
1285 * CSR_SV_IDLE is set.
1286 */
1287 } while ((DWord & (CSR_STOP | CSR_SV_IDLE)) != CSR_SV_IDLE);
1288
1289 /* The path data transfer activity is fully stopped now */
1290
1291 /* Perform a local reset of the port's Rx path */
1292
1293 /* Reset the PCI FIFO of the Rx queue */
1294 SK_OUT32(IoC, Q_ADDR(pPrt->PRxQOff, Q_CSR), CSR_SET_RESET);
1295 /* Reset the RAM Buffer receive queue */
1296 SK_OUT8(IoC, RB_ADDR(pPrt->PRxQOff, RB_CTRL), RB_RST_SET);
1297
1298 /* Reset Rx MAC FIFO */
1299#ifdef GENESIS
1300 if (pAC->GIni.GIGenesis) {
1301
1302 SK_OUT8(IoC, MR_ADDR(Port, RX_MFF_CTRL2), MFF_RST_SET);
1303
1304 /* switch Rx LED off, stop the LED counter */
1305 SkGeXmitLED(pAC, IoC, MR_ADDR(Port, RX_LED_INI), SK_LED_DIS);
1306 }
1307#endif /* GENESIS */
1308
1309#ifdef YUKON
1310 if (pAC->GIni.GIYukon) {
1311 /* Reset Rx MAC FIFO */
1312 SK_OUT8(IoC, MR_ADDR(Port, RX_GMF_CTRL_T), (SK_U8)GMF_RST_SET);
1313 }
1314#endif /* YUKON */
1315 }
1316} /* SkGeStopPort */
1317
1318
1319/******************************************************************************
1320 *
1321 * SkGeInit0() - Level 0 Initialization
1322 *
1323 * Description:
1324 * - Initialize the BMU address offsets
1325 *
1326 * Returns:
1327 * nothing
1328 */
1329static void SkGeInit0(
1330SK_AC *pAC, /* adapter context */
1331SK_IOC IoC) /* IO context */
1332{
1333 int i;
1334 SK_GEPORT *pPrt;
1335
1336 for (i = 0; i < SK_MAX_MACS; i++) {
1337 pPrt = &pAC->GIni.GP[i];
1338
1339 pPrt->PState = SK_PRT_RESET;
1340 pPrt->PRxQOff = QOffTab[i].RxQOff;
1341 pPrt->PXsQOff = QOffTab[i].XsQOff;
1342 pPrt->PXaQOff = QOffTab[i].XaQOff;
1343 pPrt->PCheckPar = SK_FALSE;
1344 pPrt->PIsave = 0;
1345 pPrt->PPrevShorts = 0;
1346 pPrt->PLinkResCt = 0;
1347 pPrt->PAutoNegTOCt = 0;
1348 pPrt->PPrevRx = 0;
1349 pPrt->PPrevFcs = 0;
1350 pPrt->PRxLim = SK_DEF_RX_WA_LIM;
1351 pPrt->PLinkMode = (SK_U8)SK_LMODE_AUTOFULL;
1352 pPrt->PLinkSpeedCap = (SK_U8)SK_LSPEED_CAP_1000MBPS;
1353 pPrt->PLinkSpeed = (SK_U8)SK_LSPEED_1000MBPS;
1354 pPrt->PLinkSpeedUsed = (SK_U8)SK_LSPEED_STAT_UNKNOWN;
1355 pPrt->PLinkModeConf = (SK_U8)SK_LMODE_AUTOSENSE;
1356 pPrt->PFlowCtrlMode = (SK_U8)SK_FLOW_MODE_SYM_OR_REM;
1357 pPrt->PLinkCap = (SK_U8)(SK_LMODE_CAP_HALF | SK_LMODE_CAP_FULL |
1358 SK_LMODE_CAP_AUTOHALF | SK_LMODE_CAP_AUTOFULL);
1359 pPrt->PLinkModeStatus = (SK_U8)SK_LMODE_STAT_UNKNOWN;
1360 pPrt->PFlowCtrlCap = (SK_U8)SK_FLOW_MODE_SYM_OR_REM;
1361 pPrt->PFlowCtrlStatus = (SK_U8)SK_FLOW_STAT_NONE;
1362 pPrt->PMSCap = 0;
1363 pPrt->PMSMode = (SK_U8)SK_MS_MODE_AUTO;
1364 pPrt->PMSStatus = (SK_U8)SK_MS_STAT_UNSET;
1365 pPrt->PLipaAutoNeg = (SK_U8)SK_LIPA_UNKNOWN;
1366 pPrt->PAutoNegFail = SK_FALSE;
1367 pPrt->PHWLinkUp = SK_FALSE;
1368 pPrt->PLinkBroken = SK_TRUE; /* See WA code */
1369 pPrt->PPhyPowerState = PHY_PM_OPERATIONAL_MODE;
1370 pPrt->PMacColThres = TX_COL_DEF;
1371 pPrt->PMacJamLen = TX_JAM_LEN_DEF;
1372 pPrt->PMacJamIpgVal = TX_JAM_IPG_DEF;
1373 pPrt->PMacJamIpgData = TX_IPG_JAM_DEF;
1374 pPrt->PMacIpgData = IPG_DATA_DEF;
1375 pPrt->PMacLimit4 = SK_FALSE;
1376 }
1377
1378 pAC->GIni.GIPortUsage = SK_RED_LINK;
1379 pAC->GIni.GILedBlinkCtrl = (SK_U16)OemConfig.Value;
1380 pAC->GIni.GIValIrqMask = IS_ALL_MSK;
1381
1382} /* SkGeInit0*/
1383
1384
1385/******************************************************************************
1386 *
1387 * SkGeInit1() - Level 1 Initialization
1388 *
1389 * Description:
1390 * o Do a software reset.
1391 * o Clear all reset bits.
1392 * o Verify that the detected hardware is present.
1393 * Return an error if not.
1394 * o Get the hardware configuration
1395 * + Read the number of MACs/Ports.
1396 * + Read the RAM size.
1397 * + Read the PCI Revision Id.
1398 * + Find out the adapters host clock speed
1399 * + Read and check the PHY type
1400 *
1401 * Returns:
1402 * 0: success
1403 * 5: Unexpected PHY type detected
1404 * 6: HW self test failed
1405 */
1406static int SkGeInit1(
1407SK_AC *pAC, /* adapter context */
1408SK_IOC IoC) /* IO context */
1409{
1410 SK_U8 Byte;
1411 SK_U16 Word;
1412 SK_U16 CtrlStat;
1413 SK_U32 DWord;
1414 int RetVal;
1415 int i;
1416
1417 RetVal = 0;
1418
1419 /* save CLK_RUN bits (YUKON-Lite) */
1420 SK_IN16(IoC, B0_CTST, &CtrlStat);
1421
1422 /* do the SW-reset */
1423 SK_OUT8(IoC, B0_CTST, CS_RST_SET);
1424
1425 /* release the SW-reset */
1426 SK_OUT8(IoC, B0_CTST, CS_RST_CLR);
1427
1428 /* reset all error bits in the PCI STATUS register */
1429 /*
1430 * Note: PCI Cfg cycles cannot be used, because they are not
1431 * available on some platforms after 'boot time'.
1432 */
1433 SK_IN16(IoC, PCI_C(PCI_STATUS), &Word);
1434
1435 SK_OUT8(IoC, B2_TST_CTRL1, TST_CFG_WRITE_ON);
1436 SK_OUT16(IoC, PCI_C(PCI_STATUS), (SK_U16)(Word | PCI_ERRBITS));
1437 SK_OUT8(IoC, B2_TST_CTRL1, TST_CFG_WRITE_OFF);
1438
1439 /* release Master Reset */
1440 SK_OUT8(IoC, B0_CTST, CS_MRST_CLR);
1441
1442#ifdef CLK_RUN
1443 CtrlStat |= CS_CLK_RUN_ENA;
1444#endif /* CLK_RUN */
1445
1446 /* restore CLK_RUN bits */
1447 SK_OUT16(IoC, B0_CTST, (SK_U16)(CtrlStat &
1448 (CS_CLK_RUN_HOT | CS_CLK_RUN_RST | CS_CLK_RUN_ENA)));
1449
1450 /* read Chip Identification Number */
1451 SK_IN8(IoC, B2_CHIP_ID, &Byte);
1452 pAC->GIni.GIChipId = Byte;
1453
1454 /* read number of MACs */
1455 SK_IN8(IoC, B2_MAC_CFG, &Byte);
1456 pAC->GIni.GIMacsFound = (Byte & CFG_SNG_MAC) ? 1 : 2;
1457
1458 /* get Chip Revision Number */
1459 pAC->GIni.GIChipRev = (SK_U8)((Byte & CFG_CHIP_R_MSK) >> 4);
1460
1461 /* get diff. PCI parameters */
1462 SK_IN16(IoC, B0_CTST, &CtrlStat);
1463
1464 /* read the adapters RAM size */
1465 SK_IN8(IoC, B2_E_0, &Byte);
1466
1467 pAC->GIni.GIGenesis = SK_FALSE;
1468 pAC->GIni.GIYukon = SK_FALSE;
1469 pAC->GIni.GIYukonLite = SK_FALSE;
1470
1471#ifdef GENESIS
1472 if (pAC->GIni.GIChipId == CHIP_ID_GENESIS) {
1473
1474 pAC->GIni.GIGenesis = SK_TRUE;
1475
1476 if (Byte == (SK_U8)3) {
1477 /* special case: 4 x 64k x 36, offset = 0x80000 */
1478 pAC->GIni.GIRamSize = 1024;
1479 pAC->GIni.GIRamOffs = (SK_U32)512 * 1024;
1480 }
1481 else {
1482 pAC->GIni.GIRamSize = (int)Byte * 512;
1483 pAC->GIni.GIRamOffs = 0;
1484 }
1485 /* all GE adapters work with 53.125 MHz host clock */
1486 pAC->GIni.GIHstClkFact = SK_FACT_53;
1487
1488 /* set Descr. Poll Timer Init Value to 250 ms */
1489 pAC->GIni.GIPollTimerVal =
1490 SK_DPOLL_DEF * (SK_U32)pAC->GIni.GIHstClkFact / 100;
1491 }
1492#endif /* GENESIS */
1493
1494#ifdef YUKON
1495 if (pAC->GIni.GIChipId != CHIP_ID_GENESIS) {
1496
1497 pAC->GIni.GIYukon = SK_TRUE;
1498
1499 pAC->GIni.GIRamSize = (Byte == (SK_U8)0) ? 128 : (int)Byte * 4;
1500
1501 pAC->GIni.GIRamOffs = 0;
1502
1503 /* WA for chip Rev. A */
1504 pAC->GIni.GIWolOffs = (pAC->GIni.GIChipId == CHIP_ID_YUKON &&
1505 pAC->GIni.GIChipRev == 0) ? WOL_REG_OFFS : 0;
1506
1507 /* get PM Capabilities of PCI config space */
1508 SK_IN16(IoC, PCI_C(PCI_PM_CAP_REG), &Word);
1509
1510 /* check if VAUX is available */
1511 if (((CtrlStat & CS_VAUX_AVAIL) != 0) &&
1512 /* check also if PME from D3cold is set */
1513 ((Word & PCI_PME_D3C_SUP) != 0)) {
1514 /* set entry in GE init struct */
1515 pAC->GIni.GIVauxAvail = SK_TRUE;
1516 }
1517
1518 if (pAC->GIni.GIChipId == CHIP_ID_YUKON_LITE) {
1519 /* this is Rev. A1 */
1520 pAC->GIni.GIYukonLite = SK_TRUE;
1521 }
1522 else {
1523 /* save Flash-Address Register */
1524 SK_IN32(IoC, B2_FAR, &DWord);
1525
1526 /* test Flash-Address Register */
1527 SK_OUT8(IoC, B2_FAR + 3, 0xff);
1528 SK_IN8(IoC, B2_FAR + 3, &Byte);
1529
1530 if (Byte != 0) {
1531 /* this is Rev. A0 */
1532 pAC->GIni.GIYukonLite = SK_TRUE;
1533
1534 /* restore Flash-Address Register */
1535 SK_OUT32(IoC, B2_FAR, DWord);
1536 }
1537 }
1538
1539 /* switch power to VCC (WA for VAUX problem) */
1540 SK_OUT8(IoC, B0_POWER_CTRL, (SK_U8)(PC_VAUX_ENA | PC_VCC_ENA |
1541 PC_VAUX_OFF | PC_VCC_ON));
1542
1543 /* read the Interrupt source */
1544 SK_IN32(IoC, B0_ISRC, &DWord);
1545
1546 if ((DWord & IS_HW_ERR) != 0) {
1547 /* read the HW Error Interrupt source */
1548 SK_IN32(IoC, B0_HWE_ISRC, &DWord);
1549
1550 if ((DWord & IS_IRQ_SENSOR) != 0) {
1551 /* disable HW Error IRQ */
1552 pAC->GIni.GIValIrqMask &= ~IS_HW_ERR;
1553 }
1554 }
1555
1556 for (i = 0; i < pAC->GIni.GIMacsFound; i++) {
1557 /* set GMAC Link Control reset */
1558 SK_OUT16(IoC, MR_ADDR(i, GMAC_LINK_CTRL), GMLC_RST_SET);
1559
1560 /* clear GMAC Link Control reset */
1561 SK_OUT16(IoC, MR_ADDR(i, GMAC_LINK_CTRL), GMLC_RST_CLR);
1562 }
1563 /* all YU chips work with 78.125 MHz host clock */
1564 pAC->GIni.GIHstClkFact = SK_FACT_78;
1565
1566 pAC->GIni.GIPollTimerVal = SK_DPOLL_MAX; /* 215 ms */
1567 }
1568#endif /* YUKON */
1569
1570 /* check if 64-bit PCI Slot is present */
1571 pAC->GIni.GIPciSlot64 = (SK_BOOL)((CtrlStat & CS_BUS_SLOT_SZ) != 0);
1572
1573 /* check if 66 MHz PCI Clock is active */
1574 pAC->GIni.GIPciClock66 = (SK_BOOL)((CtrlStat & CS_BUS_CLOCK) != 0);
1575
1576 /* read PCI HW Revision Id. */
1577 SK_IN8(IoC, PCI_C(PCI_REV_ID), &Byte);
1578 pAC->GIni.GIPciHwRev = Byte;
1579
1580 /* read the PMD type */
1581 SK_IN8(IoC, B2_PMD_TYP, &Byte);
1582 pAC->GIni.GICopperType = (SK_U8)(Byte == 'T');
1583
1584 /* read the PHY type */
1585 SK_IN8(IoC, B2_E_1, &Byte);
1586
1587 Byte &= 0x0f; /* the PHY type is stored in the lower nibble */
1588 for (i = 0; i < pAC->GIni.GIMacsFound; i++) {
1589
1590#ifdef GENESIS
1591 if (pAC->GIni.GIGenesis) {
1592 switch (Byte) {
1593 case SK_PHY_XMAC:
1594 pAC->GIni.GP[i].PhyAddr = PHY_ADDR_XMAC;
1595 break;
1596 case SK_PHY_BCOM:
1597 pAC->GIni.GP[i].PhyAddr = PHY_ADDR_BCOM;
1598 pAC->GIni.GP[i].PMSCap = (SK_U8)(SK_MS_CAP_AUTO |
1599 SK_MS_CAP_MASTER | SK_MS_CAP_SLAVE);
1600 break;
1601#ifdef OTHER_PHY
1602 case SK_PHY_LONE:
1603 pAC->GIni.GP[i].PhyAddr = PHY_ADDR_LONE;
1604 break;
1605 case SK_PHY_NAT:
1606 pAC->GIni.GP[i].PhyAddr = PHY_ADDR_NAT;
1607 break;
1608#endif /* OTHER_PHY */
1609 default:
1610 /* ERROR: unexpected PHY type detected */
1611 RetVal = 5;
1612 break;
1613 }
1614 }
1615#endif /* GENESIS */
1616
1617#ifdef YUKON
1618 if (pAC->GIni.GIYukon) {
1619
1620 if (Byte < (SK_U8)SK_PHY_MARV_COPPER) {
1621 /* if this field is not initialized */
1622 Byte = (SK_U8)SK_PHY_MARV_COPPER;
1623
1624 pAC->GIni.GICopperType = SK_TRUE;
1625 }
1626
1627 pAC->GIni.GP[i].PhyAddr = PHY_ADDR_MARV;
1628
1629 if (pAC->GIni.GICopperType) {
1630
1631 pAC->GIni.GP[i].PLinkSpeedCap = (SK_U8)(SK_LSPEED_CAP_AUTO |
1632 SK_LSPEED_CAP_10MBPS | SK_LSPEED_CAP_100MBPS |
1633 SK_LSPEED_CAP_1000MBPS);
1634
1635 pAC->GIni.GP[i].PLinkSpeed = (SK_U8)SK_LSPEED_AUTO;
1636
1637 pAC->GIni.GP[i].PMSCap = (SK_U8)(SK_MS_CAP_AUTO |
1638 SK_MS_CAP_MASTER | SK_MS_CAP_SLAVE);
1639 }
1640 else {
1641 Byte = (SK_U8)SK_PHY_MARV_FIBER;
1642 }
1643 }
1644#endif /* YUKON */
1645
1646 pAC->GIni.GP[i].PhyType = (int)Byte;
1647
1648 SK_DBG_MSG(pAC, SK_DBGMOD_HWM, SK_DBGCAT_INIT,
1649 ("PHY type: %d PHY addr: %04x\n", Byte,
1650 pAC->GIni.GP[i].PhyAddr));
1651 }
1652
1653 /* get MAC Type & set function pointers dependent on */
1654#ifdef GENESIS
1655 if (pAC->GIni.GIGenesis) {
1656
1657 pAC->GIni.GIMacType = SK_MAC_XMAC;
1658
1659 pAC->GIni.GIFunc.pFnMacUpdateStats = SkXmUpdateStats;
1660 pAC->GIni.GIFunc.pFnMacStatistic = SkXmMacStatistic;
1661 pAC->GIni.GIFunc.pFnMacResetCounter = SkXmResetCounter;
1662 pAC->GIni.GIFunc.pFnMacOverflow = SkXmOverflowStatus;
1663 }
1664#endif /* GENESIS */
1665
1666#ifdef YUKON
1667 if (pAC->GIni.GIYukon) {
1668
1669 pAC->GIni.GIMacType = SK_MAC_GMAC;
1670
1671 pAC->GIni.GIFunc.pFnMacUpdateStats = SkGmUpdateStats;
1672 pAC->GIni.GIFunc.pFnMacStatistic = SkGmMacStatistic;
1673 pAC->GIni.GIFunc.pFnMacResetCounter = SkGmResetCounter;
1674 pAC->GIni.GIFunc.pFnMacOverflow = SkGmOverflowStatus;
1675
1676#ifdef SPECIAL_HANDLING
1677 if (pAC->GIni.GIChipId == CHIP_ID_YUKON) {
1678 /* check HW self test result */
1679 SK_IN8(IoC, B2_E_3, &Byte);
1680 if (Byte & B2_E3_RES_MASK) {
1681 RetVal = 6;
1682 }
1683 }
1684#endif
1685 }
1686#endif /* YUKON */
1687
1688 return(RetVal);
1689} /* SkGeInit1 */
1690
1691
1692/******************************************************************************
1693 *
1694 * SkGeInit2() - Level 2 Initialization
1695 *
1696 * Description:
1697 * - start the Blink Source Counter
1698 * - start the Descriptor Poll Timer
1699 * - configure the MAC-Arbiter
1700 * - configure the Packet-Arbiter
1701 * - enable the Tx Arbiters
1702 * - enable the RAM Interface Arbiter
1703 *
1704 * Returns:
1705 * nothing
1706 */
1707static void SkGeInit2(
1708SK_AC *pAC, /* adapter context */
1709SK_IOC IoC) /* IO context */
1710{
1711#ifdef GENESIS
1712 SK_U32 DWord;
1713#endif /* GENESIS */
1714 int i;
1715
1716 /* start the Descriptor Poll Timer */
1717 if (pAC->GIni.GIPollTimerVal != 0) {
1718 if (pAC->GIni.GIPollTimerVal > SK_DPOLL_MAX) {
1719 pAC->GIni.GIPollTimerVal = SK_DPOLL_MAX;
1720
1721 SK_ERR_LOG(pAC, SK_ERRCL_SW, SKERR_HWI_E017, SKERR_HWI_E017MSG);
1722 }
1723 SK_OUT32(IoC, B28_DPT_INI, pAC->GIni.GIPollTimerVal);
1724 SK_OUT8(IoC, B28_DPT_CTRL, DPT_START);
1725 }
1726
1727#ifdef GENESIS
1728 if (pAC->GIni.GIGenesis) {
1729 /* start the Blink Source Counter */
1730 DWord = SK_BLK_DUR * (SK_U32)pAC->GIni.GIHstClkFact / 100;
1731
1732 SK_OUT32(IoC, B2_BSC_INI, DWord);
1733 SK_OUT8(IoC, B2_BSC_CTRL, BSC_START);
1734
1735 /*
1736 * Configure the MAC Arbiter and the Packet Arbiter.
1737 * They will be started once and never be stopped.
1738 */
1739 SkGeInitMacArb(pAC, IoC);
1740
1741 SkGeInitPktArb(pAC, IoC);
1742 }
1743#endif /* GENESIS */
1744
1745#ifdef YUKON
1746 if (pAC->GIni.GIYukon) {
1747 /* start Time Stamp Timer */
1748 SK_OUT8(IoC, GMAC_TI_ST_CTRL, (SK_U8)GMT_ST_START);
1749 }
1750#endif /* YUKON */
1751
1752 /* enable the Tx Arbiters */
1753 for (i = 0; i < pAC->GIni.GIMacsFound; i++) {
1754 SK_OUT8(IoC, MR_ADDR(i, TXA_CTRL), TXA_ENA_ARB);
1755 }
1756
1757 /* enable the RAM Interface Arbiter */
1758 SkGeInitRamIface(pAC, IoC);
1759
1760} /* SkGeInit2 */
1761
1762/******************************************************************************
1763 *
1764 * SkGeInit() - Initialize the GE Adapter with the specified level.
1765 *
1766 * Description:
1767 * Level 0: Initialize the Module structures.
1768 * Level 1: Generic Hardware Initialization. The IOP/MemBase pointer has
1769 * to be set before calling this level.
1770 *
1771 * o Do a software reset.
1772 * o Clear all reset bits.
1773 * o Verify that the detected hardware is present.
1774 * Return an error if not.
1775 * o Get the hardware configuration
1776 * + Set GIMacsFound with the number of MACs.
1777 * + Store the RAM size in GIRamSize.
1778 * + Save the PCI Revision ID in GIPciHwRev.
1779 * o return an error
1780 * if Number of MACs > SK_MAX_MACS
1781 *
1782 * After returning from Level 0 the adapter
1783 * may be accessed with IO operations.
1784 *
1785 * Level 2: start the Blink Source Counter
1786 *
1787 * Returns:
1788 * 0: success
1789 * 1: Number of MACs exceeds SK_MAX_MACS (after level 1)
1790 * 2: Adapter not present or not accessible
1791 * 3: Illegal initialization level
1792 * 4: Initialization Level 1 Call missing
1793 * 5: Unexpected PHY type detected
1794 * 6: HW self test failed
1795 */
1796int SkGeInit(
1797SK_AC *pAC, /* adapter context */
1798SK_IOC IoC, /* IO context */
1799int Level) /* initialization level */
1800{
1801 int RetVal; /* return value */
1802 SK_U32 DWord;
1803
1804 RetVal = 0;
1805 SK_DBG_MSG(pAC, SK_DBGMOD_HWM, SK_DBGCAT_INIT,
1806 ("SkGeInit(Level %d)\n", Level));
1807
1808 switch (Level) {
1809 case SK_INIT_DATA:
1810 /* Initialization Level 0 */
1811 SkGeInit0(pAC, IoC);
1812 pAC->GIni.GILevel = SK_INIT_DATA;
1813 break;
1814
1815 case SK_INIT_IO:
1816 /* Initialization Level 1 */
1817 RetVal = SkGeInit1(pAC, IoC);
1818 if (RetVal != 0) {
1819 break;
1820 }
1821
1822 /* check if the adapter seems to be accessible */
1823 SK_OUT32(IoC, B2_IRQM_INI, SK_TEST_VAL);
1824 SK_IN32(IoC, B2_IRQM_INI, &DWord);
1825 SK_OUT32(IoC, B2_IRQM_INI, 0L);
1826
1827 if (DWord != SK_TEST_VAL) {
1828 RetVal = 2;
1829 break;
1830 }
1831
1832 /* check if the number of GIMacsFound matches SK_MAX_MACS */
1833 if (pAC->GIni.GIMacsFound > SK_MAX_MACS) {
1834 RetVal = 1;
1835 break;
1836 }
1837
1838 /* Level 1 successfully passed */
1839 pAC->GIni.GILevel = SK_INIT_IO;
1840 break;
1841
1842 case SK_INIT_RUN:
1843 /* Initialization Level 2 */
1844 if (pAC->GIni.GILevel != SK_INIT_IO) {
1845#ifndef SK_DIAG
1846 SK_ERR_LOG(pAC, SK_ERRCL_SW, SKERR_HWI_E002, SKERR_HWI_E002MSG);
1847#endif /* !SK_DIAG */
1848 RetVal = 4;
1849 break;
1850 }
1851 SkGeInit2(pAC, IoC);
1852
1853 /* Level 2 successfully passed */
1854 pAC->GIni.GILevel = SK_INIT_RUN;
1855 break;
1856
1857 default:
1858 SK_ERR_LOG(pAC, SK_ERRCL_SW, SKERR_HWI_E003, SKERR_HWI_E003MSG);
1859 RetVal = 3;
1860 break;
1861 }
1862
1863 return(RetVal);
1864} /* SkGeInit */
1865
1866
1867/******************************************************************************
1868 *
1869 * SkGeDeInit() - Deinitialize the adapter
1870 *
1871 * Description:
1872 * All ports of the adapter will be stopped if not already done.
1873 * Do a software reset and switch off all LEDs.
1874 *
1875 * Returns:
1876 * nothing
1877 */
1878void SkGeDeInit(
1879SK_AC *pAC, /* adapter context */
1880SK_IOC IoC) /* IO context */
1881{
1882 int i;
1883 SK_U16 Word;
1884
1885#if (!defined(SK_SLIM) && !defined(VCPU))
1886 /* ensure I2C is ready */
1887 SkI2cWaitIrq(pAC, IoC);
1888#endif
1889
1890 /* stop all current transfer activity */
1891 for (i = 0; i < pAC->GIni.GIMacsFound; i++) {
1892 if (pAC->GIni.GP[i].PState != SK_PRT_STOP &&
1893 pAC->GIni.GP[i].PState != SK_PRT_RESET) {
1894
1895 SkGeStopPort(pAC, IoC, i, SK_STOP_ALL, SK_HARD_RST);
1896 }
1897 }
1898
1899 /* Reset all bits in the PCI STATUS register */
1900 /*
1901 * Note: PCI Cfg cycles cannot be used, because they are not
1902 * available on some platforms after 'boot time'.
1903 */
1904 SK_IN16(IoC, PCI_C(PCI_STATUS), &Word);
1905
1906 SK_OUT8(IoC, B2_TST_CTRL1, TST_CFG_WRITE_ON);
1907 SK_OUT16(IoC, PCI_C(PCI_STATUS), (SK_U16)(Word | PCI_ERRBITS));
1908 SK_OUT8(IoC, B2_TST_CTRL1, TST_CFG_WRITE_OFF);
1909
1910 /* do the reset, all LEDs are switched off now */
1911 SK_OUT8(IoC, B0_CTST, CS_RST_SET);
1912
1913 pAC->GIni.GILevel = SK_INIT_DATA;
1914} /* SkGeDeInit */
1915
1916
1917/******************************************************************************
1918 *
1919 * SkGeInitPort() Initialize the specified port.
1920 *
1921 * Description:
1922 * PRxQSize, PXSQSize, and PXAQSize has to be
1923 * configured for the specified port before calling this function.
1924 * The descriptor rings has to be initialized too.
1925 *
1926 * o (Re)configure queues of the specified port.
1927 * o configure the MAC of the specified port.
1928 * o put ASIC and MAC(s) in operational mode.
1929 * o initialize Rx/Tx and Sync LED
1930 * o initialize RAM Buffers and MAC FIFOs
1931 *
1932 * The port is ready to connect when returning.
1933 *
1934 * Note:
1935 * The MAC's Rx and Tx state machine is still disabled when returning.
1936 *
1937 * Returns:
1938 * 0: success
1939 * 1: Queue size initialization error. The configured values
1940 * for PRxQSize, PXSQSize, or PXAQSize are invalid for one
1941 * or more queues. The specified port was NOT initialized.
1942 * An error log entry was generated.
1943 * 2: The port has to be stopped before it can be initialized again.
1944 */
1945int SkGeInitPort(
1946SK_AC *pAC, /* adapter context */
1947SK_IOC IoC, /* IO context */
1948int Port) /* Port to configure */
1949{
1950 SK_GEPORT *pPrt;
1951
1952 pPrt = &pAC->GIni.GP[Port];
1953
1954 if (SkGeCheckQSize(pAC, Port) != 0) {
1955 SK_ERR_LOG(pAC, SK_ERRCL_SW, SKERR_HWI_E004, SKERR_HWI_E004MSG);
1956 return(1);
1957 }
1958
1959 if (pPrt->PState == SK_PRT_INIT || pPrt->PState == SK_PRT_RUN) {
1960 SK_ERR_LOG(pAC, SK_ERRCL_SW, SKERR_HWI_E005, SKERR_HWI_E005MSG);
1961 return(2);
1962 }
1963
1964 /* configuration ok, initialize the Port now */
1965
1966#ifdef GENESIS
1967 if (pAC->GIni.GIGenesis) {
1968 /* initialize Rx, Tx and Link LED */
1969 /*
1970 * If 1000BT Phy needs LED initialization than swap
1971 * LED and XMAC initialization order
1972 */
1973 SkGeXmitLED(pAC, IoC, MR_ADDR(Port, TX_LED_INI), SK_LED_ENA);
1974 SkGeXmitLED(pAC, IoC, MR_ADDR(Port, RX_LED_INI), SK_LED_ENA);
1975 /* The Link LED is initialized by RLMT or Diagnostics itself */
1976
1977 SkXmInitMac(pAC, IoC, Port);
1978 }
1979#endif /* GENESIS */
1980
1981#ifdef YUKON
1982 if (pAC->GIni.GIYukon) {
1983
1984 SkGmInitMac(pAC, IoC, Port);
1985 }
1986#endif /* YUKON */
1987
1988 /* do NOT initialize the Link Sync Counter */
1989
1990 SkGeInitMacFifo(pAC, IoC, Port);
1991
1992 SkGeInitRamBufs(pAC, IoC, Port);
1993
1994 if (pPrt->PXSQSize != 0) {
1995 /* enable Force Sync bit if synchronous queue available */
1996 SK_OUT8(IoC, MR_ADDR(Port, TXA_CTRL), TXA_ENA_FSYNC);
1997 }
1998
1999 SkGeInitBmu(pAC, IoC, Port);
2000
2001 /* mark port as initialized */
2002 pPrt->PState = SK_PRT_INIT;
2003
2004 return(0);
2005} /* SkGeInitPort */
diff --git a/drivers/net/sk98lin/skgemib.c b/drivers/net/sk98lin/skgemib.c
new file mode 100644
index 000000000000..0a6f67a7a395
--- /dev/null
+++ b/drivers/net/sk98lin/skgemib.c
@@ -0,0 +1,1075 @@
1/*****************************************************************************
2 *
3 * Name: skgemib.c
4 * Project: GEnesis, PCI Gigabit Ethernet Adapter
5 * Version: $Revision: 1.11 $
6 * Date: $Date: 2003/09/15 13:38:12 $
7 * Purpose: Private Network Management Interface Management Database
8 *
9 ****************************************************************************/
10
11/******************************************************************************
12 *
13 * (C)Copyright 1998-2002 SysKonnect GmbH.
14 * (C)Copyright 2002-2003 Marvell.
15 *
16 * This program is free software; you can redistribute it and/or modify
17 * it under the terms of the GNU General Public License as published by
18 * the Free Software Foundation; either version 2 of the License, or
19 * (at your option) any later version.
20 *
21 * The information in this file is provided "AS IS" without warranty.
22 *
23 ******************************************************************************/
24
25/*
26 * PRIVATE OID handler function prototypes
27 */
28PNMI_STATIC int Addr(SK_AC *pAC, SK_IOC IoC, int action,
29 SK_U32 Id, char *pBuf, unsigned int *pLen, SK_U32 Instance,
30 unsigned int TableIndex, SK_U32 NetIndex);
31PNMI_STATIC int CsumStat(SK_AC *pAC, SK_IOC IoC, int action, SK_U32 Id,
32 char *pBuf, unsigned int *pLen, SK_U32 Instance,
33 unsigned int TableIndex, SK_U32 NetIndex);
34PNMI_STATIC int General(SK_AC *pAC, SK_IOC IoC, int action, SK_U32 Id,
35 char *pBuf, unsigned int *pLen, SK_U32 Instance,
36 unsigned int TableIndex, SK_U32 NetIndex);
37PNMI_STATIC int Mac8023Stat(SK_AC *pAC, SK_IOC IoC, int action, SK_U32 Id,
38 char *pBuf, unsigned int *pLen, SK_U32 Instance,
39 unsigned int TableIndex, SK_U32 NetIndex);
40PNMI_STATIC int MacPrivateConf(SK_AC *pAC, SK_IOC IoC, int action, SK_U32 Id,
41 char *pBuf, unsigned int *pLen, SK_U32 Instance,
42 unsigned int TableIndex, SK_U32 NetIndex);
43PNMI_STATIC int MacPrivateStat(SK_AC *pAC, SK_IOC IoC, int action, SK_U32 Id,
44 char *pBuf, unsigned int *pLen, SK_U32 Instance,
45 unsigned int TableIndex, SK_U32 NetIndex);
46PNMI_STATIC int Monitor(SK_AC *pAC, SK_IOC IoC, int action,
47 SK_U32 Id, char *pBuf, unsigned int *pLen, SK_U32 Instance,
48 unsigned int TableIndex, SK_U32 NetIndex);
49PNMI_STATIC int OidStruct(SK_AC *pAC, SK_IOC IoC, int action, SK_U32 Id,
50 char *pBuf, unsigned int *pLen, SK_U32 Instance,
51 unsigned int TableIndex, SK_U32 NetIndex);
52PNMI_STATIC int Perform(SK_AC *pAC, SK_IOC IoC, int action, SK_U32 Id,
53 char *pBuf, unsigned int* pLen, SK_U32 Instance,
54 unsigned int TableIndex, SK_U32 NetIndex);
55PNMI_STATIC int Rlmt(SK_AC *pAC, SK_IOC IoC, int action, SK_U32 Id,
56 char *pBuf, unsigned int *pLen, SK_U32 Instance,
57 unsigned int TableIndex, SK_U32 NetIndex);
58PNMI_STATIC int RlmtStat(SK_AC *pAC, SK_IOC IoC, int action, SK_U32 Id,
59 char *pBuf, unsigned int *pLen, SK_U32 Instance,
60 unsigned int TableIndex, SK_U32 NetIndex);
61PNMI_STATIC int SensorStat(SK_AC *pAC, SK_IOC IoC, int action, SK_U32 Id,
62 char *pBuf, unsigned int *pLen, SK_U32 Instance,
63 unsigned int TableIndex, SK_U32 NetIndex);
64PNMI_STATIC int Vpd(SK_AC *pAC, SK_IOC IoC, int action, SK_U32 Id,
65 char *pBuf, unsigned int *pLen, SK_U32 Instance,
66 unsigned int TableIndex, SK_U32 NetIndex);
67PNMI_STATIC int Vct(SK_AC *pAC, SK_IOC IoC, int action, SK_U32 Id,
68 char *pBuf, unsigned int *pLen, SK_U32 Instance,
69 unsigned int TableIndex, SK_U32 NetIndex);
70
71#ifdef SK_POWER_MGMT
72PNMI_STATIC int PowerManagement(SK_AC *pAC, SK_IOC IoC, int action, SK_U32 Id,
73 char *pBuf, unsigned int *pLen, SK_U32 Instance,
74 unsigned int TableIndex, SK_U32 NetIndex);
75#endif /* SK_POWER_MGMT */
76
77#ifdef SK_DIAG_SUPPORT
78PNMI_STATIC int DiagActions(SK_AC *pAC, SK_IOC IoC, int action, SK_U32 Id,
79 char *pBuf, unsigned int *pLen, SK_U32 Instance,
80 unsigned int TableIndex, SK_U32 NetIndex);
81#endif /* SK_DIAG_SUPPORT */
82
83
84/* defines *******************************************************************/
85#define ID_TABLE_SIZE (sizeof(IdTable)/sizeof(IdTable[0]))
86
87
88/* global variables **********************************************************/
89
90/*
91 * Table to correlate OID with handler function and index to
92 * hardware register stored in StatAddress if applicable.
93 */
94PNMI_STATIC const SK_PNMI_TAB_ENTRY IdTable[] = {
95 {OID_GEN_XMIT_OK,
96 0,
97 0,
98 0,
99 SK_PNMI_RO, Mac8023Stat, SK_PNMI_HTX},
100 {OID_GEN_RCV_OK,
101 0,
102 0,
103 0,
104 SK_PNMI_RO, Mac8023Stat, SK_PNMI_HRX},
105 {OID_GEN_XMIT_ERROR,
106 0,
107 0,
108 0,
109 SK_PNMI_RO, General, 0},
110 {OID_GEN_RCV_ERROR,
111 0,
112 0,
113 0,
114 SK_PNMI_RO, General, 0},
115 {OID_GEN_RCV_NO_BUFFER,
116 0,
117 0,
118 0,
119 SK_PNMI_RO, General, 0},
120 {OID_GEN_DIRECTED_FRAMES_XMIT,
121 0,
122 0,
123 0,
124 SK_PNMI_RO, Mac8023Stat, SK_PNMI_HTX_UNICAST},
125 {OID_GEN_MULTICAST_FRAMES_XMIT,
126 0,
127 0,
128 0,
129 SK_PNMI_RO, Mac8023Stat, SK_PNMI_HTX_MULTICAST},
130 {OID_GEN_BROADCAST_FRAMES_XMIT,
131 0,
132 0,
133 0,
134 SK_PNMI_RO, Mac8023Stat, SK_PNMI_HTX_BROADCAST},
135 {OID_GEN_DIRECTED_FRAMES_RCV,
136 0,
137 0,
138 0,
139 SK_PNMI_RO, Mac8023Stat, SK_PNMI_HRX_UNICAST},
140 {OID_GEN_MULTICAST_FRAMES_RCV,
141 0,
142 0,
143 0,
144 SK_PNMI_RO, Mac8023Stat, SK_PNMI_HRX_MULTICAST},
145 {OID_GEN_BROADCAST_FRAMES_RCV,
146 0,
147 0,
148 0,
149 SK_PNMI_RO, Mac8023Stat, SK_PNMI_HRX_BROADCAST},
150 {OID_GEN_RCV_CRC_ERROR,
151 0,
152 0,
153 0,
154 SK_PNMI_RO, Mac8023Stat, SK_PNMI_HRX_FCS},
155 {OID_GEN_TRANSMIT_QUEUE_LENGTH,
156 0,
157 0,
158 0,
159 SK_PNMI_RO, General, 0},
160 {OID_802_3_PERMANENT_ADDRESS,
161 0,
162 0,
163 0,
164 SK_PNMI_RO, Mac8023Stat, 0},
165 {OID_802_3_CURRENT_ADDRESS,
166 0,
167 0,
168 0,
169 SK_PNMI_RO, Mac8023Stat, 0},
170 {OID_802_3_RCV_ERROR_ALIGNMENT,
171 0,
172 0,
173 0,
174 SK_PNMI_RO, Mac8023Stat, SK_PNMI_HRX_FRAMING},
175 {OID_802_3_XMIT_ONE_COLLISION,
176 0,
177 0,
178 0,
179 SK_PNMI_RO, Mac8023Stat, SK_PNMI_HTX_SINGLE_COL},
180 {OID_802_3_XMIT_MORE_COLLISIONS,
181 0,
182 0,
183 0,
184 SK_PNMI_RO, Mac8023Stat, SK_PNMI_HTX_MULTI_COL},
185 {OID_802_3_XMIT_DEFERRED,
186 0,
187 0,
188 0,
189 SK_PNMI_RO, Mac8023Stat, SK_PNMI_HTX_DEFFERAL},
190 {OID_802_3_XMIT_MAX_COLLISIONS,
191 0,
192 0,
193 0,
194 SK_PNMI_RO, Mac8023Stat, SK_PNMI_HTX_EXCESS_COL},
195 {OID_802_3_RCV_OVERRUN,
196 0,
197 0,
198 0,
199 SK_PNMI_RO, Mac8023Stat, SK_PNMI_HRX_OVERFLOW},
200 {OID_802_3_XMIT_UNDERRUN,
201 0,
202 0,
203 0,
204 SK_PNMI_RO, Mac8023Stat, SK_PNMI_HTX_UNDERRUN},
205 {OID_802_3_XMIT_TIMES_CRS_LOST,
206 0,
207 0,
208 0,
209 SK_PNMI_RO, Mac8023Stat, SK_PNMI_HTX_CARRIER},
210 {OID_802_3_XMIT_LATE_COLLISIONS,
211 0,
212 0,
213 0,
214 SK_PNMI_RO, Mac8023Stat, SK_PNMI_HTX_LATE_COL},
215#ifdef SK_POWER_MGMT
216 {OID_PNP_CAPABILITIES,
217 0,
218 0,
219 0,
220 SK_PNMI_RO, PowerManagement, 0},
221 {OID_PNP_SET_POWER,
222 0,
223 0,
224 0,
225 SK_PNMI_WO, PowerManagement, 0},
226 {OID_PNP_QUERY_POWER,
227 0,
228 0,
229 0,
230 SK_PNMI_RO, PowerManagement, 0},
231 {OID_PNP_ADD_WAKE_UP_PATTERN,
232 0,
233 0,
234 0,
235 SK_PNMI_WO, PowerManagement, 0},
236 {OID_PNP_REMOVE_WAKE_UP_PATTERN,
237 0,
238 0,
239 0,
240 SK_PNMI_WO, PowerManagement, 0},
241 {OID_PNP_ENABLE_WAKE_UP,
242 0,
243 0,
244 0,
245 SK_PNMI_RW, PowerManagement, 0},
246#endif /* SK_POWER_MGMT */
247#ifdef SK_DIAG_SUPPORT
248 {OID_SKGE_DIAG_MODE,
249 0,
250 0,
251 0,
252 SK_PNMI_RW, DiagActions, 0},
253#endif /* SK_DIAG_SUPPORT */
254 {OID_SKGE_MDB_VERSION,
255 1,
256 0,
257 SK_PNMI_MAI_OFF(MgmtDBVersion),
258 SK_PNMI_RO, General, 0},
259 {OID_SKGE_SUPPORTED_LIST,
260 0,
261 0,
262 0,
263 SK_PNMI_RO, General, 0},
264 {OID_SKGE_ALL_DATA,
265 0,
266 0,
267 0,
268 SK_PNMI_RW, OidStruct, 0},
269 {OID_SKGE_VPD_FREE_BYTES,
270 1,
271 0,
272 SK_PNMI_MAI_OFF(VpdFreeBytes),
273 SK_PNMI_RO, Vpd, 0},
274 {OID_SKGE_VPD_ENTRIES_LIST,
275 1,
276 0,
277 SK_PNMI_MAI_OFF(VpdEntriesList),
278 SK_PNMI_RO, Vpd, 0},
279 {OID_SKGE_VPD_ENTRIES_NUMBER,
280 1,
281 0,
282 SK_PNMI_MAI_OFF(VpdEntriesNumber),
283 SK_PNMI_RO, Vpd, 0},
284 {OID_SKGE_VPD_KEY,
285 SK_PNMI_VPD_ENTRIES,
286 sizeof(SK_PNMI_VPD),
287 SK_PNMI_OFF(Vpd) + SK_PNMI_VPD_OFF(VpdKey),
288 SK_PNMI_RO, Vpd, 0},
289 {OID_SKGE_VPD_VALUE,
290 SK_PNMI_VPD_ENTRIES,
291 sizeof(SK_PNMI_VPD),
292 SK_PNMI_OFF(Vpd) + SK_PNMI_VPD_OFF(VpdValue),
293 SK_PNMI_RO, Vpd, 0},
294 {OID_SKGE_VPD_ACCESS,
295 SK_PNMI_VPD_ENTRIES,
296 sizeof(SK_PNMI_VPD),
297 SK_PNMI_OFF(Vpd) + SK_PNMI_VPD_OFF(VpdAccess),
298 SK_PNMI_RO, Vpd, 0},
299 {OID_SKGE_VPD_ACTION,
300 SK_PNMI_VPD_ENTRIES,
301 sizeof(SK_PNMI_VPD),
302 SK_PNMI_OFF(Vpd) + SK_PNMI_VPD_OFF(VpdAction),
303 SK_PNMI_RW, Vpd, 0},
304 {OID_SKGE_PORT_NUMBER,
305 1,
306 0,
307 SK_PNMI_MAI_OFF(PortNumber),
308 SK_PNMI_RO, General, 0},
309 {OID_SKGE_DEVICE_TYPE,
310 1,
311 0,
312 SK_PNMI_MAI_OFF(DeviceType),
313 SK_PNMI_RO, General, 0},
314 {OID_SKGE_DRIVER_DESCR,
315 1,
316 0,
317 SK_PNMI_MAI_OFF(DriverDescr),
318 SK_PNMI_RO, General, 0},
319 {OID_SKGE_DRIVER_VERSION,
320 1,
321 0,
322 SK_PNMI_MAI_OFF(DriverVersion),
323 SK_PNMI_RO, General, 0},
324 {OID_SKGE_DRIVER_RELDATE,
325 1,
326 0,
327 SK_PNMI_MAI_OFF(DriverReleaseDate),
328 SK_PNMI_RO, General, 0},
329 {OID_SKGE_DRIVER_FILENAME,
330 1,
331 0,
332 SK_PNMI_MAI_OFF(DriverFileName),
333 SK_PNMI_RO, General, 0},
334 {OID_SKGE_HW_DESCR,
335 1,
336 0,
337 SK_PNMI_MAI_OFF(HwDescr),
338 SK_PNMI_RO, General, 0},
339 {OID_SKGE_HW_VERSION,
340 1,
341 0,
342 SK_PNMI_MAI_OFF(HwVersion),
343 SK_PNMI_RO, General, 0},
344 {OID_SKGE_CHIPSET,
345 1,
346 0,
347 SK_PNMI_MAI_OFF(Chipset),
348 SK_PNMI_RO, General, 0},
349 {OID_SKGE_CHIPID,
350 1,
351 0,
352 SK_PNMI_MAI_OFF(ChipId),
353 SK_PNMI_RO, General, 0},
354 {OID_SKGE_RAMSIZE,
355 1,
356 0,
357 SK_PNMI_MAI_OFF(RamSize),
358 SK_PNMI_RO, General, 0},
359 {OID_SKGE_VAUXAVAIL,
360 1,
361 0,
362 SK_PNMI_MAI_OFF(VauxAvail),
363 SK_PNMI_RO, General, 0},
364 {OID_SKGE_ACTION,
365 1,
366 0,
367 SK_PNMI_MAI_OFF(Action),
368 SK_PNMI_RW, Perform, 0},
369 {OID_SKGE_RESULT,
370 1,
371 0,
372 SK_PNMI_MAI_OFF(TestResult),
373 SK_PNMI_RO, General, 0},
374 {OID_SKGE_BUS_TYPE,
375 1,
376 0,
377 SK_PNMI_MAI_OFF(BusType),
378 SK_PNMI_RO, General, 0},
379 {OID_SKGE_BUS_SPEED,
380 1,
381 0,
382 SK_PNMI_MAI_OFF(BusSpeed),
383 SK_PNMI_RO, General, 0},
384 {OID_SKGE_BUS_WIDTH,
385 1,
386 0,
387 SK_PNMI_MAI_OFF(BusWidth),
388 SK_PNMI_RO, General, 0},
389 {OID_SKGE_TX_SW_QUEUE_LEN,
390 1,
391 0,
392 SK_PNMI_MAI_OFF(TxSwQueueLen),
393 SK_PNMI_RO, General, 0},
394 {OID_SKGE_TX_SW_QUEUE_MAX,
395 1,
396 0,
397 SK_PNMI_MAI_OFF(TxSwQueueMax),
398 SK_PNMI_RO, General, 0},
399 {OID_SKGE_TX_RETRY,
400 1,
401 0,
402 SK_PNMI_MAI_OFF(TxRetryCts),
403 SK_PNMI_RO, General, 0},
404 {OID_SKGE_RX_INTR_CTS,
405 1,
406 0,
407 SK_PNMI_MAI_OFF(RxIntrCts),
408 SK_PNMI_RO, General, 0},
409 {OID_SKGE_TX_INTR_CTS,
410 1,
411 0,
412 SK_PNMI_MAI_OFF(TxIntrCts),
413 SK_PNMI_RO, General, 0},
414 {OID_SKGE_RX_NO_BUF_CTS,
415 1,
416 0,
417 SK_PNMI_MAI_OFF(RxNoBufCts),
418 SK_PNMI_RO, General, 0},
419 {OID_SKGE_TX_NO_BUF_CTS,
420 1,
421 0,
422 SK_PNMI_MAI_OFF(TxNoBufCts),
423 SK_PNMI_RO, General, 0},
424 {OID_SKGE_TX_USED_DESCR_NO,
425 1,
426 0,
427 SK_PNMI_MAI_OFF(TxUsedDescrNo),
428 SK_PNMI_RO, General, 0},
429 {OID_SKGE_RX_DELIVERED_CTS,
430 1,
431 0,
432 SK_PNMI_MAI_OFF(RxDeliveredCts),
433 SK_PNMI_RO, General, 0},
434 {OID_SKGE_RX_OCTETS_DELIV_CTS,
435 1,
436 0,
437 SK_PNMI_MAI_OFF(RxOctetsDeliveredCts),
438 SK_PNMI_RO, General, 0},
439 {OID_SKGE_RX_HW_ERROR_CTS,
440 1,
441 0,
442 SK_PNMI_MAI_OFF(RxHwErrorsCts),
443 SK_PNMI_RO, General, 0},
444 {OID_SKGE_TX_HW_ERROR_CTS,
445 1,
446 0,
447 SK_PNMI_MAI_OFF(TxHwErrorsCts),
448 SK_PNMI_RO, General, 0},
449 {OID_SKGE_IN_ERRORS_CTS,
450 1,
451 0,
452 SK_PNMI_MAI_OFF(InErrorsCts),
453 SK_PNMI_RO, General, 0},
454 {OID_SKGE_OUT_ERROR_CTS,
455 1,
456 0,
457 SK_PNMI_MAI_OFF(OutErrorsCts),
458 SK_PNMI_RO, General, 0},
459 {OID_SKGE_ERR_RECOVERY_CTS,
460 1,
461 0,
462 SK_PNMI_MAI_OFF(ErrRecoveryCts),
463 SK_PNMI_RO, General, 0},
464 {OID_SKGE_SYSUPTIME,
465 1,
466 0,
467 SK_PNMI_MAI_OFF(SysUpTime),
468 SK_PNMI_RO, General, 0},
469 {OID_SKGE_SENSOR_NUMBER,
470 1,
471 0,
472 SK_PNMI_MAI_OFF(SensorNumber),
473 SK_PNMI_RO, General, 0},
474 {OID_SKGE_SENSOR_INDEX,
475 SK_PNMI_SENSOR_ENTRIES,
476 sizeof(SK_PNMI_SENSOR),
477 SK_PNMI_OFF(Sensor) + SK_PNMI_SEN_OFF(SensorIndex),
478 SK_PNMI_RO, SensorStat, 0},
479 {OID_SKGE_SENSOR_DESCR,
480 SK_PNMI_SENSOR_ENTRIES,
481 sizeof(SK_PNMI_SENSOR),
482 SK_PNMI_OFF(Sensor) + SK_PNMI_SEN_OFF(SensorDescr),
483 SK_PNMI_RO, SensorStat, 0},
484 {OID_SKGE_SENSOR_TYPE,
485 SK_PNMI_SENSOR_ENTRIES,
486 sizeof(SK_PNMI_SENSOR),
487 SK_PNMI_OFF(Sensor) + SK_PNMI_SEN_OFF(SensorType),
488 SK_PNMI_RO, SensorStat, 0},
489 {OID_SKGE_SENSOR_VALUE,
490 SK_PNMI_SENSOR_ENTRIES,
491 sizeof(SK_PNMI_SENSOR),
492 SK_PNMI_OFF(Sensor) + SK_PNMI_SEN_OFF(SensorValue),
493 SK_PNMI_RO, SensorStat, 0},
494 {OID_SKGE_SENSOR_WAR_THRES_LOW,
495 SK_PNMI_SENSOR_ENTRIES,
496 sizeof(SK_PNMI_SENSOR),
497 SK_PNMI_OFF(Sensor) + SK_PNMI_SEN_OFF(SensorWarningThresholdLow),
498 SK_PNMI_RO, SensorStat, 0},
499 {OID_SKGE_SENSOR_WAR_THRES_UPP,
500 SK_PNMI_SENSOR_ENTRIES,
501 sizeof(SK_PNMI_SENSOR),
502 SK_PNMI_OFF(Sensor) + SK_PNMI_SEN_OFF(SensorWarningThresholdHigh),
503 SK_PNMI_RO, SensorStat, 0},
504 {OID_SKGE_SENSOR_ERR_THRES_LOW,
505 SK_PNMI_SENSOR_ENTRIES,
506 sizeof(SK_PNMI_SENSOR),
507 SK_PNMI_OFF(Sensor) + SK_PNMI_SEN_OFF(SensorErrorThresholdLow),
508 SK_PNMI_RO, SensorStat, 0},
509 {OID_SKGE_SENSOR_ERR_THRES_UPP,
510 SK_PNMI_SENSOR_ENTRIES,
511 sizeof(SK_PNMI_SENSOR),
512 SK_PNMI_OFF(Sensor) + SK_PNMI_SEN_OFF(SensorErrorThresholdHigh),
513 SK_PNMI_RO, SensorStat, 0},
514 {OID_SKGE_SENSOR_STATUS,
515 SK_PNMI_SENSOR_ENTRIES,
516 sizeof(SK_PNMI_SENSOR),
517 SK_PNMI_OFF(Sensor) + SK_PNMI_SEN_OFF(SensorStatus),
518 SK_PNMI_RO, SensorStat, 0},
519 {OID_SKGE_SENSOR_WAR_CTS,
520 SK_PNMI_SENSOR_ENTRIES,
521 sizeof(SK_PNMI_SENSOR),
522 SK_PNMI_OFF(Sensor) + SK_PNMI_SEN_OFF(SensorWarningCts),
523 SK_PNMI_RO, SensorStat, 0},
524 {OID_SKGE_SENSOR_ERR_CTS,
525 SK_PNMI_SENSOR_ENTRIES,
526 sizeof(SK_PNMI_SENSOR),
527 SK_PNMI_OFF(Sensor) + SK_PNMI_SEN_OFF(SensorErrorCts),
528 SK_PNMI_RO, SensorStat, 0},
529 {OID_SKGE_SENSOR_WAR_TIME,
530 SK_PNMI_SENSOR_ENTRIES,
531 sizeof(SK_PNMI_SENSOR),
532 SK_PNMI_OFF(Sensor) + SK_PNMI_SEN_OFF(SensorWarningTimestamp),
533 SK_PNMI_RO, SensorStat, 0},
534 {OID_SKGE_SENSOR_ERR_TIME,
535 SK_PNMI_SENSOR_ENTRIES,
536 sizeof(SK_PNMI_SENSOR),
537 SK_PNMI_OFF(Sensor) + SK_PNMI_SEN_OFF(SensorErrorTimestamp),
538 SK_PNMI_RO, SensorStat, 0},
539 {OID_SKGE_CHKSM_NUMBER,
540 1,
541 0,
542 SK_PNMI_MAI_OFF(ChecksumNumber),
543 SK_PNMI_RO, General, 0},
544 {OID_SKGE_CHKSM_RX_OK_CTS,
545 SKCS_NUM_PROTOCOLS,
546 sizeof(SK_PNMI_CHECKSUM),
547 SK_PNMI_OFF(Checksum) + SK_PNMI_CHK_OFF(ChecksumRxOkCts),
548 SK_PNMI_RO, CsumStat, 0},
549 {OID_SKGE_CHKSM_RX_UNABLE_CTS,
550 SKCS_NUM_PROTOCOLS,
551 sizeof(SK_PNMI_CHECKSUM),
552 SK_PNMI_OFF(Checksum) + SK_PNMI_CHK_OFF(ChecksumRxUnableCts),
553 SK_PNMI_RO, CsumStat, 0},
554 {OID_SKGE_CHKSM_RX_ERR_CTS,
555 SKCS_NUM_PROTOCOLS,
556 sizeof(SK_PNMI_CHECKSUM),
557 SK_PNMI_OFF(Checksum) + SK_PNMI_CHK_OFF(ChecksumRxErrCts),
558 SK_PNMI_RO, CsumStat, 0},
559 {OID_SKGE_CHKSM_TX_OK_CTS,
560 SKCS_NUM_PROTOCOLS,
561 sizeof(SK_PNMI_CHECKSUM),
562 SK_PNMI_OFF(Checksum) + SK_PNMI_CHK_OFF(ChecksumTxOkCts),
563 SK_PNMI_RO, CsumStat, 0},
564 {OID_SKGE_CHKSM_TX_UNABLE_CTS,
565 SKCS_NUM_PROTOCOLS,
566 sizeof(SK_PNMI_CHECKSUM),
567 SK_PNMI_OFF(Checksum) + SK_PNMI_CHK_OFF(ChecksumTxUnableCts),
568 SK_PNMI_RO, CsumStat, 0},
569 {OID_SKGE_STAT_TX,
570 SK_PNMI_MAC_ENTRIES,
571 sizeof(SK_PNMI_STAT),
572 SK_PNMI_OFF(Stat) + SK_PNMI_STA_OFF(StatTxOkCts),
573 SK_PNMI_RO, MacPrivateStat, SK_PNMI_HTX},
574 {OID_SKGE_STAT_TX_OCTETS,
575 SK_PNMI_MAC_ENTRIES,
576 sizeof(SK_PNMI_STAT),
577 SK_PNMI_OFF(Stat) + SK_PNMI_STA_OFF(StatTxOctetsOkCts),
578 SK_PNMI_RO, MacPrivateStat, SK_PNMI_HTX_OCTET},
579 {OID_SKGE_STAT_TX_BROADCAST,
580 SK_PNMI_MAC_ENTRIES,
581 sizeof(SK_PNMI_STAT),
582 SK_PNMI_OFF(Stat) + SK_PNMI_STA_OFF(StatTxBroadcastOkCts),
583 SK_PNMI_RO, MacPrivateStat, SK_PNMI_HTX_BROADCAST},
584 {OID_SKGE_STAT_TX_MULTICAST,
585 SK_PNMI_MAC_ENTRIES,
586 sizeof(SK_PNMI_STAT),
587 SK_PNMI_OFF(Stat) + SK_PNMI_STA_OFF(StatTxMulticastOkCts),
588 SK_PNMI_RO, MacPrivateStat, SK_PNMI_HTX_MULTICAST},
589 {OID_SKGE_STAT_TX_UNICAST,
590 SK_PNMI_MAC_ENTRIES,
591 sizeof(SK_PNMI_STAT),
592 SK_PNMI_OFF(Stat) + SK_PNMI_STA_OFF(StatTxUnicastOkCts),
593 SK_PNMI_RO, MacPrivateStat, SK_PNMI_HTX_UNICAST},
594 {OID_SKGE_STAT_TX_LONGFRAMES,
595 SK_PNMI_MAC_ENTRIES,
596 sizeof(SK_PNMI_STAT),
597 SK_PNMI_OFF(Stat) + SK_PNMI_STA_OFF(StatTxLongFramesCts),
598 SK_PNMI_RO, MacPrivateStat, SK_PNMI_HTX_LONGFRAMES},
599 {OID_SKGE_STAT_TX_BURST,
600 SK_PNMI_MAC_ENTRIES,
601 sizeof(SK_PNMI_STAT),
602 SK_PNMI_OFF(Stat) + SK_PNMI_STA_OFF(StatTxBurstCts),
603 SK_PNMI_RO, MacPrivateStat, SK_PNMI_HTX_BURST},
604 {OID_SKGE_STAT_TX_PFLOWC,
605 SK_PNMI_MAC_ENTRIES,
606 sizeof(SK_PNMI_STAT),
607 SK_PNMI_OFF(Stat) + SK_PNMI_STA_OFF(StatTxPauseMacCtrlCts),
608 SK_PNMI_RO, MacPrivateStat, SK_PNMI_HTX_PMACC},
609 {OID_SKGE_STAT_TX_FLOWC,
610 SK_PNMI_MAC_ENTRIES,
611 sizeof(SK_PNMI_STAT),
612 SK_PNMI_OFF(Stat) + SK_PNMI_STA_OFF(StatTxMacCtrlCts),
613 SK_PNMI_RO, MacPrivateStat, SK_PNMI_HTX_MACC},
614 {OID_SKGE_STAT_TX_SINGLE_COL,
615 SK_PNMI_MAC_ENTRIES,
616 sizeof(SK_PNMI_STAT),
617 SK_PNMI_OFF(Stat) + SK_PNMI_STA_OFF(StatTxSingleCollisionCts),
618 SK_PNMI_RO, MacPrivateStat, SK_PNMI_HTX_SINGLE_COL},
619 {OID_SKGE_STAT_TX_MULTI_COL,
620 SK_PNMI_MAC_ENTRIES,
621 sizeof(SK_PNMI_STAT),
622 SK_PNMI_OFF(Stat) + SK_PNMI_STA_OFF(StatTxMultipleCollisionCts),
623 SK_PNMI_RO, MacPrivateStat, SK_PNMI_HTX_MULTI_COL},
624 {OID_SKGE_STAT_TX_EXCESS_COL,
625 SK_PNMI_MAC_ENTRIES,
626 sizeof(SK_PNMI_STAT),
627 SK_PNMI_OFF(Stat) + SK_PNMI_STA_OFF(StatTxExcessiveCollisionCts),
628 SK_PNMI_RO, MacPrivateStat, SK_PNMI_HTX_EXCESS_COL},
629 {OID_SKGE_STAT_TX_LATE_COL,
630 SK_PNMI_MAC_ENTRIES,
631 sizeof(SK_PNMI_STAT),
632 SK_PNMI_OFF(Stat) + SK_PNMI_STA_OFF(StatTxLateCollisionCts),
633 SK_PNMI_RO, MacPrivateStat, SK_PNMI_HTX_LATE_COL},
634 {OID_SKGE_STAT_TX_DEFFERAL,
635 SK_PNMI_MAC_ENTRIES,
636 sizeof(SK_PNMI_STAT),
637 SK_PNMI_OFF(Stat) + SK_PNMI_STA_OFF(StatTxDeferralCts),
638 SK_PNMI_RO, MacPrivateStat, SK_PNMI_HTX_DEFFERAL},
639 {OID_SKGE_STAT_TX_EXCESS_DEF,
640 SK_PNMI_MAC_ENTRIES,
641 sizeof(SK_PNMI_STAT),
642 SK_PNMI_OFF(Stat) + SK_PNMI_STA_OFF(StatTxExcessiveDeferralCts),
643 SK_PNMI_RO, MacPrivateStat, SK_PNMI_HTX_EXCESS_DEF},
644 {OID_SKGE_STAT_TX_UNDERRUN,
645 SK_PNMI_MAC_ENTRIES,
646 sizeof(SK_PNMI_STAT),
647 SK_PNMI_OFF(Stat) + SK_PNMI_STA_OFF(StatTxFifoUnderrunCts),
648 SK_PNMI_RO, MacPrivateStat, SK_PNMI_HTX_UNDERRUN},
649 {OID_SKGE_STAT_TX_CARRIER,
650 SK_PNMI_MAC_ENTRIES,
651 sizeof(SK_PNMI_STAT),
652 SK_PNMI_OFF(Stat) + SK_PNMI_STA_OFF(StatTxCarrierCts),
653 SK_PNMI_RO, MacPrivateStat, SK_PNMI_HTX_CARRIER},
654/* {OID_SKGE_STAT_TX_UTIL,
655 SK_PNMI_MAC_ENTRIES,
656 sizeof(SK_PNMI_STAT),
657 SK_PNMI_OFF(Stat) + SK_PNMI_STA_OFF(StatTxUtilization),
658 SK_PNMI_RO, MacPrivateStat, (SK_U16)(-1)}, */
659 {OID_SKGE_STAT_TX_64,
660 SK_PNMI_MAC_ENTRIES,
661 sizeof(SK_PNMI_STAT),
662 SK_PNMI_OFF(Stat) + SK_PNMI_STA_OFF(StatTx64Cts),
663 SK_PNMI_RO, MacPrivateStat, SK_PNMI_HTX_64},
664 {OID_SKGE_STAT_TX_127,
665 SK_PNMI_MAC_ENTRIES,
666 sizeof(SK_PNMI_STAT),
667 SK_PNMI_OFF(Stat) + SK_PNMI_STA_OFF(StatTx127Cts),
668 SK_PNMI_RO, MacPrivateStat, SK_PNMI_HTX_127},
669 {OID_SKGE_STAT_TX_255,
670 SK_PNMI_MAC_ENTRIES,
671 sizeof(SK_PNMI_STAT),
672 SK_PNMI_OFF(Stat) + SK_PNMI_STA_OFF(StatTx255Cts),
673 SK_PNMI_RO, MacPrivateStat, SK_PNMI_HTX_255},
674 {OID_SKGE_STAT_TX_511,
675 SK_PNMI_MAC_ENTRIES,
676 sizeof(SK_PNMI_STAT),
677 SK_PNMI_OFF(Stat) + SK_PNMI_STA_OFF(StatTx511Cts),
678 SK_PNMI_RO, MacPrivateStat, SK_PNMI_HTX_511},
679 {OID_SKGE_STAT_TX_1023,
680 SK_PNMI_MAC_ENTRIES,
681 sizeof(SK_PNMI_STAT),
682 SK_PNMI_OFF(Stat) + SK_PNMI_STA_OFF(StatTx1023Cts),
683 SK_PNMI_RO, MacPrivateStat, SK_PNMI_HTX_1023},
684 {OID_SKGE_STAT_TX_MAX,
685 SK_PNMI_MAC_ENTRIES,
686 sizeof(SK_PNMI_STAT),
687 SK_PNMI_OFF(Stat) + SK_PNMI_STA_OFF(StatTxMaxCts),
688 SK_PNMI_RO, MacPrivateStat, SK_PNMI_HTX_MAX},
689 {OID_SKGE_STAT_TX_SYNC,
690 SK_PNMI_MAC_ENTRIES,
691 sizeof(SK_PNMI_STAT),
692 SK_PNMI_OFF(Stat) + SK_PNMI_STA_OFF(StatTxSyncCts),
693 SK_PNMI_RO, MacPrivateStat, SK_PNMI_HTX_SYNC},
694 {OID_SKGE_STAT_TX_SYNC_OCTETS,
695 SK_PNMI_MAC_ENTRIES,
696 sizeof(SK_PNMI_STAT),
697 SK_PNMI_OFF(Stat) + SK_PNMI_STA_OFF(StatTxSyncOctetsCts),
698 SK_PNMI_RO, MacPrivateStat, SK_PNMI_HTX_SYNC_OCTET},
699 {OID_SKGE_STAT_RX,
700 SK_PNMI_MAC_ENTRIES,
701 sizeof(SK_PNMI_STAT),
702 SK_PNMI_OFF(Stat) + SK_PNMI_STA_OFF(StatRxOkCts),
703 SK_PNMI_RO, MacPrivateStat, SK_PNMI_HRX},
704 {OID_SKGE_STAT_RX_OCTETS,
705 SK_PNMI_MAC_ENTRIES,
706 sizeof(SK_PNMI_STAT),
707 SK_PNMI_OFF(Stat) + SK_PNMI_STA_OFF(StatRxOctetsOkCts),
708 SK_PNMI_RO, MacPrivateStat, SK_PNMI_HRX_OCTET},
709 {OID_SKGE_STAT_RX_BROADCAST,
710 SK_PNMI_MAC_ENTRIES,
711 sizeof(SK_PNMI_STAT),
712 SK_PNMI_OFF(Stat) + SK_PNMI_STA_OFF(StatRxBroadcastOkCts),
713 SK_PNMI_RO, MacPrivateStat, SK_PNMI_HRX_BROADCAST},
714 {OID_SKGE_STAT_RX_MULTICAST,
715 SK_PNMI_MAC_ENTRIES,
716 sizeof(SK_PNMI_STAT),
717 SK_PNMI_OFF(Stat) + SK_PNMI_STA_OFF(StatRxMulticastOkCts),
718 SK_PNMI_RO, MacPrivateStat, SK_PNMI_HRX_MULTICAST},
719 {OID_SKGE_STAT_RX_UNICAST,
720 SK_PNMI_MAC_ENTRIES,
721 sizeof(SK_PNMI_STAT),
722 SK_PNMI_OFF(Stat) + SK_PNMI_STA_OFF(StatRxUnicastOkCts),
723 SK_PNMI_RO, MacPrivateStat, SK_PNMI_HRX_UNICAST},
724 {OID_SKGE_STAT_RX_LONGFRAMES,
725 SK_PNMI_MAC_ENTRIES,
726 sizeof(SK_PNMI_STAT),
727 SK_PNMI_OFF(Stat) + SK_PNMI_STA_OFF(StatRxLongFramesCts),
728 SK_PNMI_RO, MacPrivateStat, SK_PNMI_HRX_LONGFRAMES},
729 {OID_SKGE_STAT_RX_PFLOWC,
730 SK_PNMI_MAC_ENTRIES,
731 sizeof(SK_PNMI_STAT),
732 SK_PNMI_OFF(Stat) + SK_PNMI_STA_OFF(StatRxPauseMacCtrlCts),
733 SK_PNMI_RO, MacPrivateStat, SK_PNMI_HRX_PMACC},
734 {OID_SKGE_STAT_RX_FLOWC,
735 SK_PNMI_MAC_ENTRIES,
736 sizeof(SK_PNMI_STAT),
737 SK_PNMI_OFF(Stat) + SK_PNMI_STA_OFF(StatRxMacCtrlCts),
738 SK_PNMI_RO, MacPrivateStat, SK_PNMI_HRX_MACC},
739 {OID_SKGE_STAT_RX_PFLOWC_ERR,
740 SK_PNMI_MAC_ENTRIES,
741 sizeof(SK_PNMI_STAT),
742 SK_PNMI_OFF(Stat) + SK_PNMI_STA_OFF(StatRxPauseMacCtrlErrorCts),
743 SK_PNMI_RO, MacPrivateStat, SK_PNMI_HRX_PMACC_ERR},
744 {OID_SKGE_STAT_RX_FLOWC_UNKWN,
745 SK_PNMI_MAC_ENTRIES,
746 sizeof(SK_PNMI_STAT),
747 SK_PNMI_OFF(Stat) + SK_PNMI_STA_OFF(StatRxMacCtrlUnknownCts),
748 SK_PNMI_RO, MacPrivateStat, SK_PNMI_HRX_MACC_UNKWN},
749 {OID_SKGE_STAT_RX_BURST,
750 SK_PNMI_MAC_ENTRIES,
751 sizeof(SK_PNMI_STAT),
752 SK_PNMI_OFF(Stat) + SK_PNMI_STA_OFF(StatRxBurstCts),
753 SK_PNMI_RO, MacPrivateStat, SK_PNMI_HRX_BURST},
754 {OID_SKGE_STAT_RX_MISSED,
755 SK_PNMI_MAC_ENTRIES,
756 sizeof(SK_PNMI_STAT),
757 SK_PNMI_OFF(Stat) + SK_PNMI_STA_OFF(StatRxMissedCts),
758 SK_PNMI_RO, MacPrivateStat, SK_PNMI_HRX_MISSED},
759 {OID_SKGE_STAT_RX_FRAMING,
760 SK_PNMI_MAC_ENTRIES,
761 sizeof(SK_PNMI_STAT),
762 SK_PNMI_OFF(Stat) + SK_PNMI_STA_OFF(StatRxFramingCts),
763 SK_PNMI_RO, MacPrivateStat, SK_PNMI_HRX_FRAMING},
764 {OID_SKGE_STAT_RX_OVERFLOW,
765 SK_PNMI_MAC_ENTRIES,
766 sizeof(SK_PNMI_STAT),
767 SK_PNMI_OFF(Stat) + SK_PNMI_STA_OFF(StatRxFifoOverflowCts),
768 SK_PNMI_RO, MacPrivateStat, SK_PNMI_HRX_OVERFLOW},
769 {OID_SKGE_STAT_RX_JABBER,
770 SK_PNMI_MAC_ENTRIES,
771 sizeof(SK_PNMI_STAT),
772 SK_PNMI_OFF(Stat) + SK_PNMI_STA_OFF(StatRxJabberCts),
773 SK_PNMI_RO, MacPrivateStat, SK_PNMI_HRX_JABBER},
774 {OID_SKGE_STAT_RX_CARRIER,
775 SK_PNMI_MAC_ENTRIES,
776 sizeof(SK_PNMI_STAT),
777 SK_PNMI_OFF(Stat) + SK_PNMI_STA_OFF(StatRxCarrierCts),
778 SK_PNMI_RO, MacPrivateStat, SK_PNMI_HRX_CARRIER},
779 {OID_SKGE_STAT_RX_IR_LENGTH,
780 SK_PNMI_MAC_ENTRIES,
781 sizeof(SK_PNMI_STAT),
782 SK_PNMI_OFF(Stat) + SK_PNMI_STA_OFF(StatRxIRLengthCts),
783 SK_PNMI_RO, MacPrivateStat, SK_PNMI_HRX_IRLENGTH},
784 {OID_SKGE_STAT_RX_SYMBOL,
785 SK_PNMI_MAC_ENTRIES,
786 sizeof(SK_PNMI_STAT),
787 SK_PNMI_OFF(Stat) + SK_PNMI_STA_OFF(StatRxSymbolCts),
788 SK_PNMI_RO, MacPrivateStat, SK_PNMI_HRX_SYMBOL},
789 {OID_SKGE_STAT_RX_SHORTS,
790 SK_PNMI_MAC_ENTRIES,
791 sizeof(SK_PNMI_STAT),
792 SK_PNMI_OFF(Stat) + SK_PNMI_STA_OFF(StatRxShortsCts),
793 SK_PNMI_RO, MacPrivateStat, SK_PNMI_HRX_SHORTS},
794 {OID_SKGE_STAT_RX_RUNT,
795 SK_PNMI_MAC_ENTRIES,
796 sizeof(SK_PNMI_STAT),
797 SK_PNMI_OFF(Stat) + SK_PNMI_STA_OFF(StatRxRuntCts),
798 SK_PNMI_RO, MacPrivateStat, SK_PNMI_HRX_RUNT},
799 {OID_SKGE_STAT_RX_CEXT,
800 SK_PNMI_MAC_ENTRIES,
801 sizeof(SK_PNMI_STAT),
802 SK_PNMI_OFF(Stat) + SK_PNMI_STA_OFF(StatRxCextCts),
803 SK_PNMI_RO, MacPrivateStat, SK_PNMI_HRX_CEXT},
804 {OID_SKGE_STAT_RX_TOO_LONG,
805 SK_PNMI_MAC_ENTRIES,
806 sizeof(SK_PNMI_STAT),
807 SK_PNMI_OFF(Stat) + SK_PNMI_STA_OFF(StatRxTooLongCts),
808 SK_PNMI_RO, MacPrivateStat, SK_PNMI_HRX_TOO_LONG},
809 {OID_SKGE_STAT_RX_FCS,
810 SK_PNMI_MAC_ENTRIES,
811 sizeof(SK_PNMI_STAT),
812 SK_PNMI_OFF(Stat) + SK_PNMI_STA_OFF(StatRxFcsCts),
813 SK_PNMI_RO, MacPrivateStat, SK_PNMI_HRX_FCS},
814/* {OID_SKGE_STAT_RX_UTIL,
815 SK_PNMI_MAC_ENTRIES,
816 sizeof(SK_PNMI_STAT),
817 SK_PNMI_OFF(Stat) + SK_PNMI_STA_OFF(StatRxUtilization),
818 SK_PNMI_RO, MacPrivateStat, (SK_U16)(-1)}, */
819 {OID_SKGE_STAT_RX_64,
820 SK_PNMI_MAC_ENTRIES,
821 sizeof(SK_PNMI_STAT),
822 SK_PNMI_OFF(Stat) + SK_PNMI_STA_OFF(StatRx64Cts),
823 SK_PNMI_RO, MacPrivateStat, SK_PNMI_HRX_64},
824 {OID_SKGE_STAT_RX_127,
825 SK_PNMI_MAC_ENTRIES,
826 sizeof(SK_PNMI_STAT),
827 SK_PNMI_OFF(Stat) + SK_PNMI_STA_OFF(StatRx127Cts),
828 SK_PNMI_RO, MacPrivateStat, SK_PNMI_HRX_127},
829 {OID_SKGE_STAT_RX_255,
830 SK_PNMI_MAC_ENTRIES,
831 sizeof(SK_PNMI_STAT),
832 SK_PNMI_OFF(Stat) + SK_PNMI_STA_OFF(StatRx255Cts),
833 SK_PNMI_RO, MacPrivateStat, SK_PNMI_HRX_255},
834 {OID_SKGE_STAT_RX_511,
835 SK_PNMI_MAC_ENTRIES,
836 sizeof(SK_PNMI_STAT),
837 SK_PNMI_OFF(Stat) + SK_PNMI_STA_OFF(StatRx511Cts),
838 SK_PNMI_RO, MacPrivateStat, SK_PNMI_HRX_511},
839 {OID_SKGE_STAT_RX_1023,
840 SK_PNMI_MAC_ENTRIES,
841 sizeof(SK_PNMI_STAT),
842 SK_PNMI_OFF(Stat) + SK_PNMI_STA_OFF(StatRx1023Cts),
843 SK_PNMI_RO, MacPrivateStat, SK_PNMI_HRX_1023},
844 {OID_SKGE_STAT_RX_MAX,
845 SK_PNMI_MAC_ENTRIES,
846 sizeof(SK_PNMI_STAT),
847 SK_PNMI_OFF(Stat) + SK_PNMI_STA_OFF(StatRxMaxCts),
848 SK_PNMI_RO, MacPrivateStat, SK_PNMI_HRX_MAX},
849 {OID_SKGE_PHYS_CUR_ADDR,
850 SK_PNMI_MAC_ENTRIES,
851 sizeof(SK_PNMI_CONF),
852 SK_PNMI_OFF(Conf) + SK_PNMI_CNF_OFF(ConfMacCurrentAddr),
853 SK_PNMI_RW, Addr, 0},
854 {OID_SKGE_PHYS_FAC_ADDR,
855 SK_PNMI_MAC_ENTRIES,
856 sizeof(SK_PNMI_CONF),
857 SK_PNMI_OFF(Conf) + SK_PNMI_CNF_OFF(ConfMacFactoryAddr),
858 SK_PNMI_RO, Addr, 0},
859 {OID_SKGE_PMD,
860 SK_PNMI_MAC_ENTRIES,
861 sizeof(SK_PNMI_CONF),
862 SK_PNMI_OFF(Conf) + SK_PNMI_CNF_OFF(ConfPMD),
863 SK_PNMI_RO, MacPrivateConf, 0},
864 {OID_SKGE_CONNECTOR,
865 SK_PNMI_MAC_ENTRIES,
866 sizeof(SK_PNMI_CONF),
867 SK_PNMI_OFF(Conf) + SK_PNMI_CNF_OFF(ConfConnector),
868 SK_PNMI_RO, MacPrivateConf, 0},
869 {OID_SKGE_PHY_TYPE,
870 SK_PNMI_MAC_ENTRIES,
871 sizeof(SK_PNMI_CONF),
872 SK_PNMI_OFF(Conf) + SK_PNMI_CNF_OFF(ConfPhyType),
873 SK_PNMI_RO, MacPrivateConf, 0},
874 {OID_SKGE_LINK_CAP,
875 SK_PNMI_MAC_ENTRIES,
876 sizeof(SK_PNMI_CONF),
877 SK_PNMI_OFF(Conf) + SK_PNMI_CNF_OFF(ConfLinkCapability),
878 SK_PNMI_RO, MacPrivateConf, 0},
879 {OID_SKGE_LINK_MODE,
880 SK_PNMI_MAC_ENTRIES,
881 sizeof(SK_PNMI_CONF),
882 SK_PNMI_OFF(Conf) + SK_PNMI_CNF_OFF(ConfLinkMode),
883 SK_PNMI_RW, MacPrivateConf, 0},
884 {OID_SKGE_LINK_MODE_STATUS,
885 SK_PNMI_MAC_ENTRIES,
886 sizeof(SK_PNMI_CONF),
887 SK_PNMI_OFF(Conf) + SK_PNMI_CNF_OFF(ConfLinkModeStatus),
888 SK_PNMI_RO, MacPrivateConf, 0},
889 {OID_SKGE_LINK_STATUS,
890 SK_PNMI_MAC_ENTRIES,
891 sizeof(SK_PNMI_CONF),
892 SK_PNMI_OFF(Conf) + SK_PNMI_CNF_OFF(ConfLinkStatus),
893 SK_PNMI_RO, MacPrivateConf, 0},
894 {OID_SKGE_FLOWCTRL_CAP,
895 SK_PNMI_MAC_ENTRIES,
896 sizeof(SK_PNMI_CONF),
897 SK_PNMI_OFF(Conf) + SK_PNMI_CNF_OFF(ConfFlowCtrlCapability),
898 SK_PNMI_RO, MacPrivateConf, 0},
899 {OID_SKGE_FLOWCTRL_MODE,
900 SK_PNMI_MAC_ENTRIES,
901 sizeof(SK_PNMI_CONF),
902 SK_PNMI_OFF(Conf) + SK_PNMI_CNF_OFF(ConfFlowCtrlMode),
903 SK_PNMI_RW, MacPrivateConf, 0},
904 {OID_SKGE_FLOWCTRL_STATUS,
905 SK_PNMI_MAC_ENTRIES,
906 sizeof(SK_PNMI_CONF),
907 SK_PNMI_OFF(Conf) + SK_PNMI_CNF_OFF(ConfFlowCtrlStatus),
908 SK_PNMI_RO, MacPrivateConf, 0},
909 {OID_SKGE_PHY_OPERATION_CAP,
910 SK_PNMI_MAC_ENTRIES,
911 sizeof(SK_PNMI_CONF),
912 SK_PNMI_OFF(Conf) + SK_PNMI_CNF_OFF(ConfPhyOperationCapability),
913 SK_PNMI_RO, MacPrivateConf, 0},
914 {OID_SKGE_PHY_OPERATION_MODE,
915 SK_PNMI_MAC_ENTRIES,
916 sizeof(SK_PNMI_CONF),
917 SK_PNMI_OFF(Conf) + SK_PNMI_CNF_OFF(ConfPhyOperationMode),
918 SK_PNMI_RW, MacPrivateConf, 0},
919 {OID_SKGE_PHY_OPERATION_STATUS,
920 SK_PNMI_MAC_ENTRIES,
921 sizeof(SK_PNMI_CONF),
922 SK_PNMI_OFF(Conf) + SK_PNMI_CNF_OFF(ConfPhyOperationStatus),
923 SK_PNMI_RO, MacPrivateConf, 0},
924 {OID_SKGE_SPEED_CAP,
925 SK_PNMI_MAC_ENTRIES,
926 sizeof(SK_PNMI_CONF),
927 SK_PNMI_OFF(Conf) + SK_PNMI_CNF_OFF(ConfSpeedCapability),
928 SK_PNMI_RO, MacPrivateConf, 0},
929 {OID_SKGE_SPEED_MODE,
930 SK_PNMI_MAC_ENTRIES,
931 sizeof(SK_PNMI_CONF),
932 SK_PNMI_OFF(Conf) + SK_PNMI_CNF_OFF(ConfSpeedMode),
933 SK_PNMI_RW, MacPrivateConf, 0},
934 {OID_SKGE_SPEED_STATUS,
935 SK_PNMI_MAC_ENTRIES,
936 sizeof(SK_PNMI_CONF),
937 SK_PNMI_OFF(Conf) + SK_PNMI_CNF_OFF(ConfSpeedStatus),
938 SK_PNMI_RO, MacPrivateConf, 0},
939 {OID_SKGE_TRAP,
940 1,
941 0,
942 SK_PNMI_MAI_OFF(Trap),
943 SK_PNMI_RO, General, 0},
944 {OID_SKGE_TRAP_NUMBER,
945 1,
946 0,
947 SK_PNMI_MAI_OFF(TrapNumber),
948 SK_PNMI_RO, General, 0},
949 {OID_SKGE_RLMT_MODE,
950 1,
951 0,
952 SK_PNMI_MAI_OFF(RlmtMode),
953 SK_PNMI_RW, Rlmt, 0},
954 {OID_SKGE_RLMT_PORT_NUMBER,
955 1,
956 0,
957 SK_PNMI_MAI_OFF(RlmtPortNumber),
958 SK_PNMI_RO, Rlmt, 0},
959 {OID_SKGE_RLMT_PORT_ACTIVE,
960 1,
961 0,
962 SK_PNMI_MAI_OFF(RlmtPortActive),
963 SK_PNMI_RO, Rlmt, 0},
964 {OID_SKGE_RLMT_PORT_PREFERRED,
965 1,
966 0,
967 SK_PNMI_MAI_OFF(RlmtPortPreferred),
968 SK_PNMI_RW, Rlmt, 0},
969 {OID_SKGE_RLMT_CHANGE_CTS,
970 1,
971 0,
972 SK_PNMI_MAI_OFF(RlmtChangeCts),
973 SK_PNMI_RO, Rlmt, 0},
974 {OID_SKGE_RLMT_CHANGE_TIME,
975 1,
976 0,
977 SK_PNMI_MAI_OFF(RlmtChangeTime),
978 SK_PNMI_RO, Rlmt, 0},
979 {OID_SKGE_RLMT_CHANGE_ESTIM,
980 1,
981 0,
982 SK_PNMI_MAI_OFF(RlmtChangeEstimate),
983 SK_PNMI_RO, Rlmt, 0},
984 {OID_SKGE_RLMT_CHANGE_THRES,
985 1,
986 0,
987 SK_PNMI_MAI_OFF(RlmtChangeThreshold),
988 SK_PNMI_RW, Rlmt, 0},
989 {OID_SKGE_RLMT_PORT_INDEX,
990 SK_PNMI_MAC_ENTRIES,
991 sizeof(SK_PNMI_RLMT),
992 SK_PNMI_OFF(Rlmt) + SK_PNMI_RLM_OFF(RlmtIndex),
993 SK_PNMI_RO, RlmtStat, 0},
994 {OID_SKGE_RLMT_STATUS,
995 SK_PNMI_MAC_ENTRIES,
996 sizeof(SK_PNMI_RLMT),
997 SK_PNMI_OFF(Rlmt) + SK_PNMI_RLM_OFF(RlmtStatus),
998 SK_PNMI_RO, RlmtStat, 0},
999 {OID_SKGE_RLMT_TX_HELLO_CTS,
1000 SK_PNMI_MAC_ENTRIES,
1001 sizeof(SK_PNMI_RLMT),
1002 SK_PNMI_OFF(Rlmt) + SK_PNMI_RLM_OFF(RlmtTxHelloCts),
1003 SK_PNMI_RO, RlmtStat, 0},
1004 {OID_SKGE_RLMT_RX_HELLO_CTS,
1005 SK_PNMI_MAC_ENTRIES,
1006 sizeof(SK_PNMI_RLMT),
1007 SK_PNMI_OFF(Rlmt) + SK_PNMI_RLM_OFF(RlmtRxHelloCts),
1008 SK_PNMI_RO, RlmtStat, 0},
1009 {OID_SKGE_RLMT_TX_SP_REQ_CTS,
1010 SK_PNMI_MAC_ENTRIES,
1011 sizeof(SK_PNMI_RLMT),
1012 SK_PNMI_OFF(Rlmt) + SK_PNMI_RLM_OFF(RlmtTxSpHelloReqCts),
1013 SK_PNMI_RO, RlmtStat, 0},
1014 {OID_SKGE_RLMT_RX_SP_CTS,
1015 SK_PNMI_MAC_ENTRIES,
1016 sizeof(SK_PNMI_RLMT),
1017 SK_PNMI_OFF(Rlmt) + SK_PNMI_RLM_OFF(RlmtRxSpHelloCts),
1018 SK_PNMI_RO, RlmtStat, 0},
1019 {OID_SKGE_RLMT_MONITOR_NUMBER,
1020 1,
1021 0,
1022 SK_PNMI_MAI_OFF(RlmtMonitorNumber),
1023 SK_PNMI_RO, General, 0},
1024 {OID_SKGE_RLMT_MONITOR_INDEX,
1025 SK_PNMI_MONITOR_ENTRIES,
1026 sizeof(SK_PNMI_RLMT_MONITOR),
1027 SK_PNMI_OFF(RlmtMonitor) + SK_PNMI_MON_OFF(RlmtMonitorIndex),
1028 SK_PNMI_RO, Monitor, 0},
1029 {OID_SKGE_RLMT_MONITOR_ADDR,
1030 SK_PNMI_MONITOR_ENTRIES,
1031 sizeof(SK_PNMI_RLMT_MONITOR),
1032 SK_PNMI_OFF(RlmtMonitor) + SK_PNMI_MON_OFF(RlmtMonitorAddr),
1033 SK_PNMI_RO, Monitor, 0},
1034 {OID_SKGE_RLMT_MONITOR_ERRS,
1035 SK_PNMI_MONITOR_ENTRIES,
1036 sizeof(SK_PNMI_RLMT_MONITOR),
1037 SK_PNMI_OFF(RlmtMonitor) + SK_PNMI_MON_OFF(RlmtMonitorErrorCts),
1038 SK_PNMI_RO, Monitor, 0},
1039 {OID_SKGE_RLMT_MONITOR_TIMESTAMP,
1040 SK_PNMI_MONITOR_ENTRIES,
1041 sizeof(SK_PNMI_RLMT_MONITOR),
1042 SK_PNMI_OFF(RlmtMonitor) + SK_PNMI_MON_OFF(RlmtMonitorTimestamp),
1043 SK_PNMI_RO, Monitor, 0},
1044 {OID_SKGE_RLMT_MONITOR_ADMIN,
1045 SK_PNMI_MONITOR_ENTRIES,
1046 sizeof(SK_PNMI_RLMT_MONITOR),
1047 SK_PNMI_OFF(RlmtMonitor) + SK_PNMI_MON_OFF(RlmtMonitorAdmin),
1048 SK_PNMI_RW, Monitor, 0},
1049 {OID_SKGE_MTU,
1050 1,
1051 0,
1052 SK_PNMI_MAI_OFF(MtuSize),
1053 SK_PNMI_RW, MacPrivateConf, 0},
1054 {OID_SKGE_VCT_GET,
1055 0,
1056 0,
1057 0,
1058 SK_PNMI_RO, Vct, 0},
1059 {OID_SKGE_VCT_SET,
1060 0,
1061 0,
1062 0,
1063 SK_PNMI_WO, Vct, 0},
1064 {OID_SKGE_VCT_STATUS,
1065 0,
1066 0,
1067 0,
1068 SK_PNMI_RO, Vct, 0},
1069 {OID_SKGE_BOARDLEVEL,
1070 0,
1071 0,
1072 0,
1073 SK_PNMI_RO, General, 0},
1074};
1075
diff --git a/drivers/net/sk98lin/skgepnmi.c b/drivers/net/sk98lin/skgepnmi.c
new file mode 100644
index 000000000000..b36dd9ac6b29
--- /dev/null
+++ b/drivers/net/sk98lin/skgepnmi.c
@@ -0,0 +1,8210 @@
1/*****************************************************************************
2 *
3 * Name: skgepnmi.c
4 * Project: GEnesis, PCI Gigabit Ethernet Adapter
5 * Version: $Revision: 1.111 $
6 * Date: $Date: 2003/09/15 13:35:35 $
7 * Purpose: Private Network Management Interface
8 *
9 ****************************************************************************/
10
11/******************************************************************************
12 *
13 * (C)Copyright 1998-2002 SysKonnect GmbH.
14 * (C)Copyright 2002-2003 Marvell.
15 *
16 * This program is free software; you can redistribute it and/or modify
17 * it under the terms of the GNU General Public License as published by
18 * the Free Software Foundation; either version 2 of the License, or
19 * (at your option) any later version.
20 *
21 * The information in this file is provided "AS IS" without warranty.
22 *
23 ******************************************************************************/
24
25
26#ifndef _lint
27static const char SysKonnectFileId[] =
28 "@(#) $Id: skgepnmi.c,v 1.111 2003/09/15 13:35:35 tschilli Exp $ (C) Marvell.";
29#endif /* !_lint */
30
31#include "h/skdrv1st.h"
32#include "h/sktypes.h"
33#include "h/xmac_ii.h"
34#include "h/skdebug.h"
35#include "h/skqueue.h"
36#include "h/skgepnmi.h"
37#include "h/skgesirq.h"
38#include "h/skcsum.h"
39#include "h/skvpd.h"
40#include "h/skgehw.h"
41#include "h/skgeinit.h"
42#include "h/skdrv2nd.h"
43#include "h/skgepnm2.h"
44#ifdef SK_POWER_MGMT
45#include "h/skgepmgt.h"
46#endif
47/* defines *******************************************************************/
48
49#ifndef DEBUG
50#define PNMI_STATIC static
51#else /* DEBUG */
52#define PNMI_STATIC
53#endif /* DEBUG */
54
55/*
56 * Public Function prototypes
57 */
58int SkPnmiInit(SK_AC *pAC, SK_IOC IoC, int level);
59int SkPnmiSetVar(SK_AC *pAC, SK_IOC IoC, SK_U32 Id, void *pBuf,
60 unsigned int *pLen, SK_U32 Instance, SK_U32 NetIndex);
61int SkPnmiGetStruct(SK_AC *pAC, SK_IOC IoC, void *pBuf,
62 unsigned int *pLen, SK_U32 NetIndex);
63int SkPnmiPreSetStruct(SK_AC *pAC, SK_IOC IoC, void *pBuf,
64 unsigned int *pLen, SK_U32 NetIndex);
65int SkPnmiSetStruct(SK_AC *pAC, SK_IOC IoC, void *pBuf,
66 unsigned int *pLen, SK_U32 NetIndex);
67int SkPnmiEvent(SK_AC *pAC, SK_IOC IoC, SK_U32 Event, SK_EVPARA Param);
68int SkPnmiGenIoctl(SK_AC *pAC, SK_IOC IoC, void * pBuf,
69 unsigned int * pLen, SK_U32 NetIndex);
70
71
72/*
73 * Private Function prototypes
74 */
75
76PNMI_STATIC SK_U8 CalculateLinkModeStatus(SK_AC *pAC, SK_IOC IoC, unsigned int
77 PhysPortIndex);
78PNMI_STATIC SK_U8 CalculateLinkStatus(SK_AC *pAC, SK_IOC IoC, unsigned int
79 PhysPortIndex);
80PNMI_STATIC void CopyMac(char *pDst, SK_MAC_ADDR *pMac);
81PNMI_STATIC void CopyTrapQueue(SK_AC *pAC, char *pDstBuf);
82PNMI_STATIC SK_U64 GetPhysStatVal(SK_AC *pAC, SK_IOC IoC,
83 unsigned int PhysPortIndex, unsigned int StatIndex);
84PNMI_STATIC SK_U64 GetStatVal(SK_AC *pAC, SK_IOC IoC, unsigned int LogPortIndex,
85 unsigned int StatIndex, SK_U32 NetIndex);
86PNMI_STATIC char* GetTrapEntry(SK_AC *pAC, SK_U32 TrapId, unsigned int Size);
87PNMI_STATIC void GetTrapQueueLen(SK_AC *pAC, unsigned int *pLen,
88 unsigned int *pEntries);
89PNMI_STATIC int GetVpdKeyArr(SK_AC *pAC, SK_IOC IoC, char *pKeyArr,
90 unsigned int KeyArrLen, unsigned int *pKeyNo);
91PNMI_STATIC int LookupId(SK_U32 Id);
92PNMI_STATIC int MacUpdate(SK_AC *pAC, SK_IOC IoC, unsigned int FirstMac,
93 unsigned int LastMac);
94PNMI_STATIC int PnmiStruct(SK_AC *pAC, SK_IOC IoC, int Action, char *pBuf,
95 unsigned int *pLen, SK_U32 NetIndex);
96PNMI_STATIC int PnmiVar(SK_AC *pAC, SK_IOC IoC, int Action, SK_U32 Id,
97 char *pBuf, unsigned int *pLen, SK_U32 Instance, SK_U32 NetIndex);
98PNMI_STATIC void QueueRlmtNewMacTrap(SK_AC *pAC, unsigned int ActiveMac);
99PNMI_STATIC void QueueRlmtPortTrap(SK_AC *pAC, SK_U32 TrapId,
100 unsigned int PortIndex);
101PNMI_STATIC void QueueSensorTrap(SK_AC *pAC, SK_U32 TrapId,
102 unsigned int SensorIndex);
103PNMI_STATIC void QueueSimpleTrap(SK_AC *pAC, SK_U32 TrapId);
104PNMI_STATIC void ResetCounter(SK_AC *pAC, SK_IOC IoC, SK_U32 NetIndex);
105PNMI_STATIC int RlmtUpdate(SK_AC *pAC, SK_IOC IoC, SK_U32 NetIndex);
106PNMI_STATIC int SirqUpdate(SK_AC *pAC, SK_IOC IoC);
107PNMI_STATIC void VirtualConf(SK_AC *pAC, SK_IOC IoC, SK_U32 Id, char *pBuf);
108PNMI_STATIC int Vct(SK_AC *pAC, SK_IOC IoC, int Action, SK_U32 Id, char *pBuf,
109 unsigned int *pLen, SK_U32 Instance, unsigned int TableIndex, SK_U32 NetIndex);
110PNMI_STATIC void CheckVctStatus(SK_AC *, SK_IOC, char *, SK_U32, SK_U32);
111
112/*
113 * Table to correlate OID with handler function and index to
114 * hardware register stored in StatAddress if applicable.
115 */
116#include "skgemib.c"
117
118/* global variables **********************************************************/
119
120/*
121 * Overflow status register bit table and corresponding counter
122 * dependent on MAC type - the number relates to the size of overflow
123 * mask returned by the pFnMacOverflow function
124 */
125PNMI_STATIC const SK_U16 StatOvrflwBit[][SK_PNMI_MAC_TYPES] = {
126/* Bit0 */ { SK_PNMI_HTX, SK_PNMI_HTX_UNICAST},
127/* Bit1 */ { SK_PNMI_HTX_OCTETHIGH, SK_PNMI_HTX_BROADCAST},
128/* Bit2 */ { SK_PNMI_HTX_OCTETLOW, SK_PNMI_HTX_PMACC},
129/* Bit3 */ { SK_PNMI_HTX_BROADCAST, SK_PNMI_HTX_MULTICAST},
130/* Bit4 */ { SK_PNMI_HTX_MULTICAST, SK_PNMI_HTX_OCTETLOW},
131/* Bit5 */ { SK_PNMI_HTX_UNICAST, SK_PNMI_HTX_OCTETHIGH},
132/* Bit6 */ { SK_PNMI_HTX_LONGFRAMES, SK_PNMI_HTX_64},
133/* Bit7 */ { SK_PNMI_HTX_BURST, SK_PNMI_HTX_127},
134/* Bit8 */ { SK_PNMI_HTX_PMACC, SK_PNMI_HTX_255},
135/* Bit9 */ { SK_PNMI_HTX_MACC, SK_PNMI_HTX_511},
136/* Bit10 */ { SK_PNMI_HTX_SINGLE_COL, SK_PNMI_HTX_1023},
137/* Bit11 */ { SK_PNMI_HTX_MULTI_COL, SK_PNMI_HTX_MAX},
138/* Bit12 */ { SK_PNMI_HTX_EXCESS_COL, SK_PNMI_HTX_LONGFRAMES},
139/* Bit13 */ { SK_PNMI_HTX_LATE_COL, SK_PNMI_HTX_RESERVED},
140/* Bit14 */ { SK_PNMI_HTX_DEFFERAL, SK_PNMI_HTX_COL},
141/* Bit15 */ { SK_PNMI_HTX_EXCESS_DEF, SK_PNMI_HTX_LATE_COL},
142/* Bit16 */ { SK_PNMI_HTX_UNDERRUN, SK_PNMI_HTX_EXCESS_COL},
143/* Bit17 */ { SK_PNMI_HTX_CARRIER, SK_PNMI_HTX_MULTI_COL},
144/* Bit18 */ { SK_PNMI_HTX_UTILUNDER, SK_PNMI_HTX_SINGLE_COL},
145/* Bit19 */ { SK_PNMI_HTX_UTILOVER, SK_PNMI_HTX_UNDERRUN},
146/* Bit20 */ { SK_PNMI_HTX_64, SK_PNMI_HTX_RESERVED},
147/* Bit21 */ { SK_PNMI_HTX_127, SK_PNMI_HTX_RESERVED},
148/* Bit22 */ { SK_PNMI_HTX_255, SK_PNMI_HTX_RESERVED},
149/* Bit23 */ { SK_PNMI_HTX_511, SK_PNMI_HTX_RESERVED},
150/* Bit24 */ { SK_PNMI_HTX_1023, SK_PNMI_HTX_RESERVED},
151/* Bit25 */ { SK_PNMI_HTX_MAX, SK_PNMI_HTX_RESERVED},
152/* Bit26 */ { SK_PNMI_HTX_RESERVED, SK_PNMI_HTX_RESERVED},
153/* Bit27 */ { SK_PNMI_HTX_RESERVED, SK_PNMI_HTX_RESERVED},
154/* Bit28 */ { SK_PNMI_HTX_RESERVED, SK_PNMI_HTX_RESERVED},
155/* Bit29 */ { SK_PNMI_HTX_RESERVED, SK_PNMI_HTX_RESERVED},
156/* Bit30 */ { SK_PNMI_HTX_RESERVED, SK_PNMI_HTX_RESERVED},
157/* Bit31 */ { SK_PNMI_HTX_RESERVED, SK_PNMI_HTX_RESERVED},
158/* Bit32 */ { SK_PNMI_HRX, SK_PNMI_HRX_UNICAST},
159/* Bit33 */ { SK_PNMI_HRX_OCTETHIGH, SK_PNMI_HRX_BROADCAST},
160/* Bit34 */ { SK_PNMI_HRX_OCTETLOW, SK_PNMI_HRX_PMACC},
161/* Bit35 */ { SK_PNMI_HRX_BROADCAST, SK_PNMI_HRX_MULTICAST},
162/* Bit36 */ { SK_PNMI_HRX_MULTICAST, SK_PNMI_HRX_FCS},
163/* Bit37 */ { SK_PNMI_HRX_UNICAST, SK_PNMI_HRX_RESERVED},
164/* Bit38 */ { SK_PNMI_HRX_PMACC, SK_PNMI_HRX_OCTETLOW},
165/* Bit39 */ { SK_PNMI_HRX_MACC, SK_PNMI_HRX_OCTETHIGH},
166/* Bit40 */ { SK_PNMI_HRX_PMACC_ERR, SK_PNMI_HRX_BADOCTETLOW},
167/* Bit41 */ { SK_PNMI_HRX_MACC_UNKWN, SK_PNMI_HRX_BADOCTETHIGH},
168/* Bit42 */ { SK_PNMI_HRX_BURST, SK_PNMI_HRX_UNDERSIZE},
169/* Bit43 */ { SK_PNMI_HRX_MISSED, SK_PNMI_HRX_RUNT},
170/* Bit44 */ { SK_PNMI_HRX_FRAMING, SK_PNMI_HRX_64},
171/* Bit45 */ { SK_PNMI_HRX_OVERFLOW, SK_PNMI_HRX_127},
172/* Bit46 */ { SK_PNMI_HRX_JABBER, SK_PNMI_HRX_255},
173/* Bit47 */ { SK_PNMI_HRX_CARRIER, SK_PNMI_HRX_511},
174/* Bit48 */ { SK_PNMI_HRX_IRLENGTH, SK_PNMI_HRX_1023},
175/* Bit49 */ { SK_PNMI_HRX_SYMBOL, SK_PNMI_HRX_MAX},
176/* Bit50 */ { SK_PNMI_HRX_SHORTS, SK_PNMI_HRX_LONGFRAMES},
177/* Bit51 */ { SK_PNMI_HRX_RUNT, SK_PNMI_HRX_TOO_LONG},
178/* Bit52 */ { SK_PNMI_HRX_TOO_LONG, SK_PNMI_HRX_JABBER},
179/* Bit53 */ { SK_PNMI_HRX_FCS, SK_PNMI_HRX_RESERVED},
180/* Bit54 */ { SK_PNMI_HRX_RESERVED, SK_PNMI_HRX_OVERFLOW},
181/* Bit55 */ { SK_PNMI_HRX_CEXT, SK_PNMI_HRX_RESERVED},
182/* Bit56 */ { SK_PNMI_HRX_UTILUNDER, SK_PNMI_HRX_RESERVED},
183/* Bit57 */ { SK_PNMI_HRX_UTILOVER, SK_PNMI_HRX_RESERVED},
184/* Bit58 */ { SK_PNMI_HRX_64, SK_PNMI_HRX_RESERVED},
185/* Bit59 */ { SK_PNMI_HRX_127, SK_PNMI_HRX_RESERVED},
186/* Bit60 */ { SK_PNMI_HRX_255, SK_PNMI_HRX_RESERVED},
187/* Bit61 */ { SK_PNMI_HRX_511, SK_PNMI_HRX_RESERVED},
188/* Bit62 */ { SK_PNMI_HRX_1023, SK_PNMI_HRX_RESERVED},
189/* Bit63 */ { SK_PNMI_HRX_MAX, SK_PNMI_HRX_RESERVED}
190};
191
192/*
193 * Table for hardware register saving on resets and port switches
194 */
195PNMI_STATIC const SK_PNMI_STATADDR StatAddr[SK_PNMI_MAX_IDX][SK_PNMI_MAC_TYPES] = {
196 /* SK_PNMI_HTX */
197 {{XM_TXF_OK, SK_TRUE}, {0, SK_FALSE}},
198 /* SK_PNMI_HTX_OCTETHIGH */
199 {{XM_TXO_OK_HI, SK_TRUE}, {GM_TXO_OK_HI, SK_TRUE}},
200 /* SK_PNMI_HTX_OCTETLOW */
201 {{XM_TXO_OK_LO, SK_FALSE}, {GM_TXO_OK_LO, SK_FALSE}},
202 /* SK_PNMI_HTX_BROADCAST */
203 {{XM_TXF_BC_OK, SK_TRUE}, {GM_TXF_BC_OK, SK_TRUE}},
204 /* SK_PNMI_HTX_MULTICAST */
205 {{XM_TXF_MC_OK, SK_TRUE}, {GM_TXF_MC_OK, SK_TRUE}},
206 /* SK_PNMI_HTX_UNICAST */
207 {{XM_TXF_UC_OK, SK_TRUE}, {GM_TXF_UC_OK, SK_TRUE}},
208 /* SK_PNMI_HTX_BURST */
209 {{XM_TXE_BURST, SK_TRUE}, {0, SK_FALSE}},
210 /* SK_PNMI_HTX_PMACC */
211 {{XM_TXF_MPAUSE, SK_TRUE}, {GM_TXF_MPAUSE, SK_TRUE}},
212 /* SK_PNMI_HTX_MACC */
213 {{XM_TXF_MCTRL, SK_TRUE}, {0, SK_FALSE}},
214 /* SK_PNMI_HTX_COL */
215 {{0, SK_FALSE}, {GM_TXF_COL, SK_TRUE}},
216 /* SK_PNMI_HTX_SINGLE_COL */
217 {{XM_TXF_SNG_COL, SK_TRUE}, {GM_TXF_SNG_COL, SK_TRUE}},
218 /* SK_PNMI_HTX_MULTI_COL */
219 {{XM_TXF_MUL_COL, SK_TRUE}, {GM_TXF_MUL_COL, SK_TRUE}},
220 /* SK_PNMI_HTX_EXCESS_COL */
221 {{XM_TXF_ABO_COL, SK_TRUE}, {GM_TXF_ABO_COL, SK_TRUE}},
222 /* SK_PNMI_HTX_LATE_COL */
223 {{XM_TXF_LAT_COL, SK_TRUE}, {GM_TXF_LAT_COL, SK_TRUE}},
224 /* SK_PNMI_HTX_DEFFERAL */
225 {{XM_TXF_DEF, SK_TRUE}, {0, SK_FALSE}},
226 /* SK_PNMI_HTX_EXCESS_DEF */
227 {{XM_TXF_EX_DEF, SK_TRUE}, {0, SK_FALSE}},
228 /* SK_PNMI_HTX_UNDERRUN */
229 {{XM_TXE_FIFO_UR, SK_TRUE}, {GM_TXE_FIFO_UR, SK_TRUE}},
230 /* SK_PNMI_HTX_CARRIER */
231 {{XM_TXE_CS_ERR, SK_TRUE}, {0, SK_FALSE}},
232 /* SK_PNMI_HTX_UTILUNDER */
233 {{0, SK_FALSE}, {0, SK_FALSE}},
234 /* SK_PNMI_HTX_UTILOVER */
235 {{0, SK_FALSE}, {0, SK_FALSE}},
236 /* SK_PNMI_HTX_64 */
237 {{XM_TXF_64B, SK_TRUE}, {GM_TXF_64B, SK_TRUE}},
238 /* SK_PNMI_HTX_127 */
239 {{XM_TXF_127B, SK_TRUE}, {GM_TXF_127B, SK_TRUE}},
240 /* SK_PNMI_HTX_255 */
241 {{XM_TXF_255B, SK_TRUE}, {GM_TXF_255B, SK_TRUE}},
242 /* SK_PNMI_HTX_511 */
243 {{XM_TXF_511B, SK_TRUE}, {GM_TXF_511B, SK_TRUE}},
244 /* SK_PNMI_HTX_1023 */
245 {{XM_TXF_1023B, SK_TRUE}, {GM_TXF_1023B, SK_TRUE}},
246 /* SK_PNMI_HTX_MAX */
247 {{XM_TXF_MAX_SZ, SK_TRUE}, {GM_TXF_1518B, SK_TRUE}},
248 /* SK_PNMI_HTX_LONGFRAMES */
249 {{XM_TXF_LONG, SK_TRUE}, {GM_TXF_MAX_SZ, SK_TRUE}},
250 /* SK_PNMI_HTX_SYNC */
251 {{0, SK_FALSE}, {0, SK_FALSE}},
252 /* SK_PNMI_HTX_SYNC_OCTET */
253 {{0, SK_FALSE}, {0, SK_FALSE}},
254 /* SK_PNMI_HTX_RESERVED */
255 {{0, SK_FALSE}, {0, SK_FALSE}},
256 /* SK_PNMI_HRX */
257 {{XM_RXF_OK, SK_TRUE}, {0, SK_FALSE}},
258 /* SK_PNMI_HRX_OCTETHIGH */
259 {{XM_RXO_OK_HI, SK_TRUE}, {GM_RXO_OK_HI, SK_TRUE}},
260 /* SK_PNMI_HRX_OCTETLOW */
261 {{XM_RXO_OK_LO, SK_FALSE}, {GM_RXO_OK_LO, SK_FALSE}},
262 /* SK_PNMI_HRX_BADOCTETHIGH */
263 {{0, SK_FALSE}, {GM_RXO_ERR_HI, SK_TRUE}},
264 /* SK_PNMI_HRX_BADOCTETLOW */
265 {{0, SK_FALSE}, {GM_RXO_ERR_LO, SK_TRUE}},
266 /* SK_PNMI_HRX_BROADCAST */
267 {{XM_RXF_BC_OK, SK_TRUE}, {GM_RXF_BC_OK, SK_TRUE}},
268 /* SK_PNMI_HRX_MULTICAST */
269 {{XM_RXF_MC_OK, SK_TRUE}, {GM_RXF_MC_OK, SK_TRUE}},
270 /* SK_PNMI_HRX_UNICAST */
271 {{XM_RXF_UC_OK, SK_TRUE}, {GM_RXF_UC_OK, SK_TRUE}},
272 /* SK_PNMI_HRX_PMACC */
273 {{XM_RXF_MPAUSE, SK_TRUE}, {GM_RXF_MPAUSE, SK_TRUE}},
274 /* SK_PNMI_HRX_MACC */
275 {{XM_RXF_MCTRL, SK_TRUE}, {0, SK_FALSE}},
276 /* SK_PNMI_HRX_PMACC_ERR */
277 {{XM_RXF_INV_MP, SK_TRUE}, {0, SK_FALSE}},
278 /* SK_PNMI_HRX_MACC_UNKWN */
279 {{XM_RXF_INV_MOC, SK_TRUE}, {0, SK_FALSE}},
280 /* SK_PNMI_HRX_BURST */
281 {{XM_RXE_BURST, SK_TRUE}, {0, SK_FALSE}},
282 /* SK_PNMI_HRX_MISSED */
283 {{XM_RXE_FMISS, SK_TRUE}, {0, SK_FALSE}},
284 /* SK_PNMI_HRX_FRAMING */
285 {{XM_RXF_FRA_ERR, SK_TRUE}, {0, SK_FALSE}},
286 /* SK_PNMI_HRX_UNDERSIZE */
287 {{0, SK_FALSE}, {GM_RXF_SHT, SK_TRUE}},
288 /* SK_PNMI_HRX_OVERFLOW */
289 {{XM_RXE_FIFO_OV, SK_TRUE}, {GM_RXE_FIFO_OV, SK_TRUE}},
290 /* SK_PNMI_HRX_JABBER */
291 {{XM_RXF_JAB_PKT, SK_TRUE}, {GM_RXF_JAB_PKT, SK_TRUE}},
292 /* SK_PNMI_HRX_CARRIER */
293 {{XM_RXE_CAR_ERR, SK_TRUE}, {0, SK_FALSE}},
294 /* SK_PNMI_HRX_IRLENGTH */
295 {{XM_RXF_LEN_ERR, SK_TRUE}, {0, SK_FALSE}},
296 /* SK_PNMI_HRX_SYMBOL */
297 {{XM_RXE_SYM_ERR, SK_TRUE}, {0, SK_FALSE}},
298 /* SK_PNMI_HRX_SHORTS */
299 {{XM_RXE_SHT_ERR, SK_TRUE}, {0, SK_FALSE}},
300 /* SK_PNMI_HRX_RUNT */
301 {{XM_RXE_RUNT, SK_TRUE}, {GM_RXE_FRAG, SK_TRUE}},
302 /* SK_PNMI_HRX_TOO_LONG */
303 {{XM_RXF_LNG_ERR, SK_TRUE}, {GM_RXF_LNG_ERR, SK_TRUE}},
304 /* SK_PNMI_HRX_FCS */
305 {{XM_RXF_FCS_ERR, SK_TRUE}, {GM_RXF_FCS_ERR, SK_TRUE}},
306 /* SK_PNMI_HRX_CEXT */
307 {{XM_RXF_CEX_ERR, SK_TRUE}, {0, SK_FALSE}},
308 /* SK_PNMI_HRX_UTILUNDER */
309 {{0, SK_FALSE}, {0, SK_FALSE}},
310 /* SK_PNMI_HRX_UTILOVER */
311 {{0, SK_FALSE}, {0, SK_FALSE}},
312 /* SK_PNMI_HRX_64 */
313 {{XM_RXF_64B, SK_TRUE}, {GM_RXF_64B, SK_TRUE}},
314 /* SK_PNMI_HRX_127 */
315 {{XM_RXF_127B, SK_TRUE}, {GM_RXF_127B, SK_TRUE}},
316 /* SK_PNMI_HRX_255 */
317 {{XM_RXF_255B, SK_TRUE}, {GM_RXF_255B, SK_TRUE}},
318 /* SK_PNMI_HRX_511 */
319 {{XM_RXF_511B, SK_TRUE}, {GM_RXF_511B, SK_TRUE}},
320 /* SK_PNMI_HRX_1023 */
321 {{XM_RXF_1023B, SK_TRUE}, {GM_RXF_1023B, SK_TRUE}},
322 /* SK_PNMI_HRX_MAX */
323 {{XM_RXF_MAX_SZ, SK_TRUE}, {GM_RXF_1518B, SK_TRUE}},
324 /* SK_PNMI_HRX_LONGFRAMES */
325 {{0, SK_FALSE}, {GM_RXF_MAX_SZ, SK_TRUE}},
326 /* SK_PNMI_HRX_RESERVED */
327 {{0, SK_FALSE}, {0, SK_FALSE}}
328};
329
330
331/*****************************************************************************
332 *
333 * Public functions
334 *
335 */
336
337/*****************************************************************************
338 *
339 * SkPnmiInit - Init function of PNMI
340 *
341 * Description:
342 * SK_INIT_DATA: Initialises the data structures
343 * SK_INIT_IO: Resets the XMAC statistics, determines the device and
344 * connector type.
345 * SK_INIT_RUN: Starts a timer event for port switch per hour
346 * calculation.
347 *
348 * Returns:
349 * Always 0
350 */
351int SkPnmiInit(
352SK_AC *pAC, /* Pointer to adapter context */
353SK_IOC IoC, /* IO context handle */
354int Level) /* Initialization level */
355{
356 unsigned int PortMax; /* Number of ports */
357 unsigned int PortIndex; /* Current port index in loop */
358 SK_U16 Val16; /* Multiple purpose 16 bit variable */
359 SK_U8 Val8; /* Mulitple purpose 8 bit variable */
360 SK_EVPARA EventParam; /* Event struct for timer event */
361 SK_PNMI_VCT *pVctBackupData;
362
363
364 SK_DBG_MSG(pAC, SK_DBGMOD_PNMI, SK_DBGCAT_CTRL,
365 ("PNMI: SkPnmiInit: Called, level=%d\n", Level));
366
367 switch (Level) {
368
369 case SK_INIT_DATA:
370 SK_MEMSET((char *)&pAC->Pnmi, 0, sizeof(pAC->Pnmi));
371 pAC->Pnmi.TrapBufFree = SK_PNMI_TRAP_QUEUE_LEN;
372 pAC->Pnmi.StartUpTime = SK_PNMI_HUNDREDS_SEC(SkOsGetTime(pAC));
373 pAC->Pnmi.RlmtChangeThreshold = SK_PNMI_DEF_RLMT_CHG_THRES;
374 for (PortIndex = 0; PortIndex < SK_MAX_MACS; PortIndex ++) {
375
376 pAC->Pnmi.Port[PortIndex].ActiveFlag = SK_FALSE;
377 pAC->Pnmi.DualNetActiveFlag = SK_FALSE;
378 }
379
380#ifdef SK_PNMI_CHECK
381 if (SK_PNMI_MAX_IDX != SK_PNMI_CNT_NO) {
382
383 SK_ERR_LOG(pAC, SK_ERRCL_SW, SK_PNMI_ERR049, SK_PNMI_ERR049MSG);
384
385 SK_DBG_MSG(pAC, SK_DBGMOD_PNMI, SK_DBGCAT_INIT | SK_DBGCAT_FATAL,
386 ("CounterOffset struct size (%d) differs from"
387 "SK_PNMI_MAX_IDX (%d)\n",
388 SK_PNMI_CNT_NO, SK_PNMI_MAX_IDX));
389 }
390
391 if (SK_PNMI_MAX_IDX !=
392 (sizeof(StatAddr) / (sizeof(SK_PNMI_STATADDR) * SK_PNMI_MAC_TYPES))) {
393
394 SK_ERR_LOG(pAC, SK_ERRCL_SW, SK_PNMI_ERR050, SK_PNMI_ERR050MSG);
395
396 SK_DBG_MSG(pAC, SK_DBGMOD_PNMI, SK_DBGCAT_INIT | SK_DBGCAT_FATAL,
397 ("StatAddr table size (%d) differs from "
398 "SK_PNMI_MAX_IDX (%d)\n",
399 (sizeof(StatAddr) /
400 (sizeof(SK_PNMI_STATADDR) * SK_PNMI_MAC_TYPES)),
401 SK_PNMI_MAX_IDX));
402 }
403#endif /* SK_PNMI_CHECK */
404 break;
405
406 case SK_INIT_IO:
407 /*
408 * Reset MAC counters
409 */
410 PortMax = pAC->GIni.GIMacsFound;
411
412 for (PortIndex = 0; PortIndex < PortMax; PortIndex ++) {
413
414 pAC->GIni.GIFunc.pFnMacResetCounter(pAC, IoC, PortIndex);
415 }
416
417 /* Initialize DSP variables for Vct() to 0xff => Never written! */
418 for (PortIndex = 0; PortIndex < PortMax; PortIndex ++) {
419 pAC->GIni.GP[PortIndex].PCableLen = 0xff;
420 pVctBackupData = &pAC->Pnmi.VctBackup[PortIndex];
421 pVctBackupData->PCableLen = 0xff;
422 }
423
424 /*
425 * Get pci bus speed
426 */
427 SK_IN16(IoC, B0_CTST, &Val16);
428 if ((Val16 & CS_BUS_CLOCK) == 0) {
429
430 pAC->Pnmi.PciBusSpeed = 33;
431 }
432 else {
433 pAC->Pnmi.PciBusSpeed = 66;
434 }
435
436 /*
437 * Get pci bus width
438 */
439 SK_IN16(IoC, B0_CTST, &Val16);
440 if ((Val16 & CS_BUS_SLOT_SZ) == 0) {
441
442 pAC->Pnmi.PciBusWidth = 32;
443 }
444 else {
445 pAC->Pnmi.PciBusWidth = 64;
446 }
447
448 /*
449 * Get chipset
450 */
451 switch (pAC->GIni.GIChipId) {
452 case CHIP_ID_GENESIS:
453 pAC->Pnmi.Chipset = SK_PNMI_CHIPSET_XMAC;
454 break;
455
456 case CHIP_ID_YUKON:
457 pAC->Pnmi.Chipset = SK_PNMI_CHIPSET_YUKON;
458 break;
459
460 default:
461 break;
462 }
463
464 /*
465 * Get PMD and DeviceType
466 */
467 SK_IN8(IoC, B2_PMD_TYP, &Val8);
468 switch (Val8) {
469 case 'S':
470 pAC->Pnmi.PMD = 3;
471 if (pAC->GIni.GIMacsFound > 1) {
472
473 pAC->Pnmi.DeviceType = 0x00020002;
474 }
475 else {
476 pAC->Pnmi.DeviceType = 0x00020001;
477 }
478 break;
479
480 case 'L':
481 pAC->Pnmi.PMD = 2;
482 if (pAC->GIni.GIMacsFound > 1) {
483
484 pAC->Pnmi.DeviceType = 0x00020004;
485 }
486 else {
487 pAC->Pnmi.DeviceType = 0x00020003;
488 }
489 break;
490
491 case 'C':
492 pAC->Pnmi.PMD = 4;
493 if (pAC->GIni.GIMacsFound > 1) {
494
495 pAC->Pnmi.DeviceType = 0x00020006;
496 }
497 else {
498 pAC->Pnmi.DeviceType = 0x00020005;
499 }
500 break;
501
502 case 'T':
503 pAC->Pnmi.PMD = 5;
504 if (pAC->GIni.GIMacsFound > 1) {
505
506 pAC->Pnmi.DeviceType = 0x00020008;
507 }
508 else {
509 pAC->Pnmi.DeviceType = 0x00020007;
510 }
511 break;
512
513 default :
514 pAC->Pnmi.PMD = 1;
515 pAC->Pnmi.DeviceType = 0;
516 break;
517 }
518
519 /*
520 * Get connector
521 */
522 SK_IN8(IoC, B2_CONN_TYP, &Val8);
523 switch (Val8) {
524 case 'C':
525 pAC->Pnmi.Connector = 2;
526 break;
527
528 case 'D':
529 pAC->Pnmi.Connector = 3;
530 break;
531
532 case 'F':
533 pAC->Pnmi.Connector = 4;
534 break;
535
536 case 'J':
537 pAC->Pnmi.Connector = 5;
538 break;
539
540 case 'V':
541 pAC->Pnmi.Connector = 6;
542 break;
543
544 default:
545 pAC->Pnmi.Connector = 1;
546 break;
547 }
548 break;
549
550 case SK_INIT_RUN:
551 /*
552 * Start timer for RLMT change counter
553 */
554 SK_MEMSET((char *)&EventParam, 0, sizeof(EventParam));
555 SkTimerStart(pAC, IoC, &pAC->Pnmi.RlmtChangeEstimate.EstTimer,
556 28125000, SKGE_PNMI, SK_PNMI_EVT_CHG_EST_TIMER,
557 EventParam);
558 break;
559
560 default:
561 break; /* Nothing todo */
562 }
563
564 return (0);
565}
566
567/*****************************************************************************
568 *
569 * SkPnmiGetVar - Retrieves the value of a single OID
570 *
571 * Description:
572 * Calls a general sub-function for all this stuff. If the instance
573 * -1 is passed, the values of all instances are returned in an
574 * array of values.
575 *
576 * Returns:
577 * SK_PNMI_ERR_OK The request was successfully performed
578 * SK_PNMI_ERR_GENERAL A general severe internal error occured
579 * SK_PNMI_ERR_TOO_SHORT The passed buffer is too short to take
580 * the data.
581 * SK_PNMI_ERR_UNKNOWN_OID The requested OID is unknown
582 * SK_PNMI_ERR_UNKNOWN_INST The requested instance of the OID doesn't
583 * exist (e.g. port instance 3 on a two port
584 * adapter.
585 */
586static int SkPnmiGetVar(
587SK_AC *pAC, /* Pointer to adapter context */
588SK_IOC IoC, /* IO context handle */
589SK_U32 Id, /* Object ID that is to be processed */
590void *pBuf, /* Buffer to which the management data will be copied */
591unsigned int *pLen, /* On call: buffer length. On return: used buffer */
592SK_U32 Instance, /* Instance (1..n) that is to be queried or -1 */
593SK_U32 NetIndex) /* NetIndex (0..n), in single net mode always zero */
594{
595 SK_DBG_MSG(pAC, SK_DBGMOD_PNMI, SK_DBGCAT_CTRL,
596 ("PNMI: SkPnmiGetVar: Called, Id=0x%x, BufLen=%d, Instance=%d, NetIndex=%d\n",
597 Id, *pLen, Instance, NetIndex));
598
599 return (PnmiVar(pAC, IoC, SK_PNMI_GET, Id, (char *)pBuf, pLen,
600 Instance, NetIndex));
601}
602
603/*****************************************************************************
604 *
605 * SkPnmiPreSetVar - Presets the value of a single OID
606 *
607 * Description:
608 * Calls a general sub-function for all this stuff. The preset does
609 * the same as a set, but returns just before finally setting the
610 * new value. This is useful to check if a set might be successfull.
611 * If the instance -1 is passed, an array of values is supposed and
612 * all instances of the OID will be set.
613 *
614 * Returns:
615 * SK_PNMI_ERR_OK The request was successfully performed.
616 * SK_PNMI_ERR_GENERAL A general severe internal error occured.
617 * SK_PNMI_ERR_TOO_SHORT The passed buffer is too short to contain
618 * the correct data (e.g. a 32bit value is
619 * needed, but a 16 bit value was passed).
620 * SK_PNMI_ERR_BAD_VALUE The passed value is not in the valid
621 * value range.
622 * SK_PNMI_ERR_READ_ONLY The OID is read-only and cannot be set.
623 * SK_PNMI_ERR_UNKNOWN_OID The requested OID is unknown.
624 * SK_PNMI_ERR_UNKNOWN_INST The requested instance of the OID doesn't
625 * exist (e.g. port instance 3 on a two port
626 * adapter.
627 */
628static int SkPnmiPreSetVar(
629SK_AC *pAC, /* Pointer to adapter context */
630SK_IOC IoC, /* IO context handle */
631SK_U32 Id, /* Object ID that is to be processed */
632void *pBuf, /* Buffer to which the management data will be copied */
633unsigned int *pLen, /* Total length of management data */
634SK_U32 Instance, /* Instance (1..n) that is to be set or -1 */
635SK_U32 NetIndex) /* NetIndex (0..n), in single net mode always zero */
636{
637 SK_DBG_MSG(pAC, SK_DBGMOD_PNMI, SK_DBGCAT_CTRL,
638 ("PNMI: SkPnmiPreSetVar: Called, Id=0x%x, BufLen=%d, Instance=%d, NetIndex=%d\n",
639 Id, *pLen, Instance, NetIndex));
640
641
642 return (PnmiVar(pAC, IoC, SK_PNMI_PRESET, Id, (char *)pBuf, pLen,
643 Instance, NetIndex));
644}
645
646/*****************************************************************************
647 *
648 * SkPnmiSetVar - Sets the value of a single OID
649 *
650 * Description:
651 * Calls a general sub-function for all this stuff. The preset does
652 * the same as a set, but returns just before finally setting the
653 * new value. This is useful to check if a set might be successfull.
654 * If the instance -1 is passed, an array of values is supposed and
655 * all instances of the OID will be set.
656 *
657 * Returns:
658 * SK_PNMI_ERR_OK The request was successfully performed.
659 * SK_PNMI_ERR_GENERAL A general severe internal error occured.
660 * SK_PNMI_ERR_TOO_SHORT The passed buffer is too short to contain
661 * the correct data (e.g. a 32bit value is
662 * needed, but a 16 bit value was passed).
663 * SK_PNMI_ERR_BAD_VALUE The passed value is not in the valid
664 * value range.
665 * SK_PNMI_ERR_READ_ONLY The OID is read-only and cannot be set.
666 * SK_PNMI_ERR_UNKNOWN_OID The requested OID is unknown.
667 * SK_PNMI_ERR_UNKNOWN_INST The requested instance of the OID doesn't
668 * exist (e.g. port instance 3 on a two port
669 * adapter.
670 */
671int SkPnmiSetVar(
672SK_AC *pAC, /* Pointer to adapter context */
673SK_IOC IoC, /* IO context handle */
674SK_U32 Id, /* Object ID that is to be processed */
675void *pBuf, /* Buffer to which the management data will be copied */
676unsigned int *pLen, /* Total length of management data */
677SK_U32 Instance, /* Instance (1..n) that is to be set or -1 */
678SK_U32 NetIndex) /* NetIndex (0..n), in single net mode always zero */
679{
680 SK_DBG_MSG(pAC, SK_DBGMOD_PNMI, SK_DBGCAT_CTRL,
681 ("PNMI: SkPnmiSetVar: Called, Id=0x%x, BufLen=%d, Instance=%d, NetIndex=%d\n",
682 Id, *pLen, Instance, NetIndex));
683
684 return (PnmiVar(pAC, IoC, SK_PNMI_SET, Id, (char *)pBuf, pLen,
685 Instance, NetIndex));
686}
687
688/*****************************************************************************
689 *
690 * SkPnmiGetStruct - Retrieves the management database in SK_PNMI_STRUCT_DATA
691 *
692 * Description:
693 * Runs through the IdTable, queries the single OIDs and stores the
694 * returned data into the management database structure
695 * SK_PNMI_STRUCT_DATA. The offset of the OID in the structure
696 * is stored in the IdTable. The return value of the function will also
697 * be stored in SK_PNMI_STRUCT_DATA if the passed buffer has the
698 * minimum size of SK_PNMI_MIN_STRUCT_SIZE.
699 *
700 * Returns:
701 * SK_PNMI_ERR_OK The request was successfully performed
702 * SK_PNMI_ERR_GENERAL A general severe internal error occured
703 * SK_PNMI_ERR_TOO_SHORT The passed buffer is too short to take
704 * the data.
705 * SK_PNMI_ERR_UNKNOWN_NET The requested NetIndex doesn't exist
706 */
707int SkPnmiGetStruct(
708SK_AC *pAC, /* Pointer to adapter context */
709SK_IOC IoC, /* IO context handle */
710void *pBuf, /* Buffer to which the management data will be copied. */
711unsigned int *pLen, /* Length of buffer */
712SK_U32 NetIndex) /* NetIndex (0..n), in single net mode always zero */
713{
714 int Ret;
715 unsigned int TableIndex;
716 unsigned int DstOffset;
717 unsigned int InstanceNo;
718 unsigned int InstanceCnt;
719 SK_U32 Instance;
720 unsigned int TmpLen;
721 char KeyArr[SK_PNMI_VPD_ENTRIES][SK_PNMI_VPD_KEY_SIZE];
722
723
724 SK_DBG_MSG(pAC, SK_DBGMOD_PNMI, SK_DBGCAT_CTRL,
725 ("PNMI: SkPnmiGetStruct: Called, BufLen=%d, NetIndex=%d\n",
726 *pLen, NetIndex));
727
728 if (*pLen < SK_PNMI_STRUCT_SIZE) {
729
730 if (*pLen >= SK_PNMI_MIN_STRUCT_SIZE) {
731
732 SK_PNMI_SET_STAT(pBuf, SK_PNMI_ERR_TOO_SHORT,
733 (SK_U32)(-1));
734 }
735
736 *pLen = SK_PNMI_STRUCT_SIZE;
737 return (SK_PNMI_ERR_TOO_SHORT);
738 }
739
740 /*
741 * Check NetIndex
742 */
743 if (NetIndex >= pAC->Rlmt.NumNets) {
744 return (SK_PNMI_ERR_UNKNOWN_NET);
745 }
746
747 /* Update statistic */
748 SK_PNMI_CHECKFLAGS("SkPnmiGetStruct: On call");
749
750 if ((Ret = MacUpdate(pAC, IoC, 0, pAC->GIni.GIMacsFound - 1)) !=
751 SK_PNMI_ERR_OK) {
752
753 SK_PNMI_SET_STAT(pBuf, Ret, (SK_U32)(-1));
754 *pLen = SK_PNMI_MIN_STRUCT_SIZE;
755 return (Ret);
756 }
757
758 if ((Ret = RlmtUpdate(pAC, IoC, NetIndex)) != SK_PNMI_ERR_OK) {
759
760 SK_PNMI_SET_STAT(pBuf, Ret, (SK_U32)(-1));
761 *pLen = SK_PNMI_MIN_STRUCT_SIZE;
762 return (Ret);
763 }
764
765 if ((Ret = SirqUpdate(pAC, IoC)) != SK_PNMI_ERR_OK) {
766
767 SK_PNMI_SET_STAT(pBuf, Ret, (SK_U32)(-1));
768 *pLen = SK_PNMI_MIN_STRUCT_SIZE;
769 return (Ret);
770 }
771
772 /*
773 * Increment semaphores to indicate that an update was
774 * already done
775 */
776 pAC->Pnmi.MacUpdatedFlag ++;
777 pAC->Pnmi.RlmtUpdatedFlag ++;
778 pAC->Pnmi.SirqUpdatedFlag ++;
779
780 /* Get vpd keys for instance calculation */
781 Ret = GetVpdKeyArr(pAC, IoC, &KeyArr[0][0], sizeof(KeyArr), &TmpLen);
782 if (Ret != SK_PNMI_ERR_OK) {
783
784 pAC->Pnmi.MacUpdatedFlag --;
785 pAC->Pnmi.RlmtUpdatedFlag --;
786 pAC->Pnmi.SirqUpdatedFlag --;
787
788 SK_PNMI_CHECKFLAGS("SkPnmiGetStruct: On return");
789 SK_PNMI_SET_STAT(pBuf, Ret, (SK_U32)(-1));
790 *pLen = SK_PNMI_MIN_STRUCT_SIZE;
791 return (SK_PNMI_ERR_GENERAL);
792 }
793
794 /* Retrieve values */
795 SK_MEMSET((char *)pBuf, 0, SK_PNMI_STRUCT_SIZE);
796 for (TableIndex = 0; TableIndex < ID_TABLE_SIZE; TableIndex ++) {
797
798 InstanceNo = IdTable[TableIndex].InstanceNo;
799 for (InstanceCnt = 1; InstanceCnt <= InstanceNo;
800 InstanceCnt ++) {
801
802 DstOffset = IdTable[TableIndex].Offset +
803 (InstanceCnt - 1) *
804 IdTable[TableIndex].StructSize;
805
806 /*
807 * For the VPD the instance is not an index number
808 * but the key itself. Determin with the instance
809 * counter the VPD key to be used.
810 */
811 if (IdTable[TableIndex].Id == OID_SKGE_VPD_KEY ||
812 IdTable[TableIndex].Id == OID_SKGE_VPD_VALUE ||
813 IdTable[TableIndex].Id == OID_SKGE_VPD_ACCESS ||
814 IdTable[TableIndex].Id == OID_SKGE_VPD_ACTION) {
815
816 SK_STRNCPY((char *)&Instance, KeyArr[InstanceCnt - 1], 4);
817 }
818 else {
819 Instance = (SK_U32)InstanceCnt;
820 }
821
822 TmpLen = *pLen - DstOffset;
823 Ret = IdTable[TableIndex].Func(pAC, IoC, SK_PNMI_GET,
824 IdTable[TableIndex].Id, (char *)pBuf +
825 DstOffset, &TmpLen, Instance, TableIndex, NetIndex);
826
827 /*
828 * An unknown instance error means that we reached
829 * the last instance of that variable. Proceed with
830 * the next OID in the table and ignore the return
831 * code.
832 */
833 if (Ret == SK_PNMI_ERR_UNKNOWN_INST) {
834
835 break;
836 }
837
838 if (Ret != SK_PNMI_ERR_OK) {
839
840 pAC->Pnmi.MacUpdatedFlag --;
841 pAC->Pnmi.RlmtUpdatedFlag --;
842 pAC->Pnmi.SirqUpdatedFlag --;
843
844 SK_PNMI_CHECKFLAGS("SkPnmiGetStruct: On return");
845 SK_PNMI_SET_STAT(pBuf, Ret, DstOffset);
846 *pLen = SK_PNMI_MIN_STRUCT_SIZE;
847 return (Ret);
848 }
849 }
850 }
851
852 pAC->Pnmi.MacUpdatedFlag --;
853 pAC->Pnmi.RlmtUpdatedFlag --;
854 pAC->Pnmi.SirqUpdatedFlag --;
855
856 *pLen = SK_PNMI_STRUCT_SIZE;
857 SK_PNMI_CHECKFLAGS("SkPnmiGetStruct: On return");
858 SK_PNMI_SET_STAT(pBuf, SK_PNMI_ERR_OK, (SK_U32)(-1));
859 return (SK_PNMI_ERR_OK);
860}
861
862/*****************************************************************************
863 *
864 * SkPnmiPreSetStruct - Presets the management database in SK_PNMI_STRUCT_DATA
865 *
866 * Description:
867 * Calls a general sub-function for all this set stuff. The preset does
868 * the same as a set, but returns just before finally setting the
869 * new value. This is useful to check if a set might be successfull.
870 * The sub-function runs through the IdTable, checks which OIDs are able
871 * to set, and calls the handler function of the OID to perform the
872 * preset. The return value of the function will also be stored in
873 * SK_PNMI_STRUCT_DATA if the passed buffer has the minimum size of
874 * SK_PNMI_MIN_STRUCT_SIZE.
875 *
876 * Returns:
877 * SK_PNMI_ERR_OK The request was successfully performed.
878 * SK_PNMI_ERR_GENERAL A general severe internal error occured.
879 * SK_PNMI_ERR_TOO_SHORT The passed buffer is too short to contain
880 * the correct data (e.g. a 32bit value is
881 * needed, but a 16 bit value was passed).
882 * SK_PNMI_ERR_BAD_VALUE The passed value is not in the valid
883 * value range.
884 */
885int SkPnmiPreSetStruct(
886SK_AC *pAC, /* Pointer to adapter context */
887SK_IOC IoC, /* IO context handle */
888void *pBuf, /* Buffer which contains the data to be set */
889unsigned int *pLen, /* Length of buffer */
890SK_U32 NetIndex) /* NetIndex (0..n), in single net mode always zero */
891{
892 SK_DBG_MSG(pAC, SK_DBGMOD_PNMI, SK_DBGCAT_CTRL,
893 ("PNMI: SkPnmiPreSetStruct: Called, BufLen=%d, NetIndex=%d\n",
894 *pLen, NetIndex));
895
896 return (PnmiStruct(pAC, IoC, SK_PNMI_PRESET, (char *)pBuf,
897 pLen, NetIndex));
898}
899
900/*****************************************************************************
901 *
902 * SkPnmiSetStruct - Sets the management database in SK_PNMI_STRUCT_DATA
903 *
904 * Description:
905 * Calls a general sub-function for all this set stuff. The return value
906 * of the function will also be stored in SK_PNMI_STRUCT_DATA if the
907 * passed buffer has the minimum size of SK_PNMI_MIN_STRUCT_SIZE.
908 * The sub-function runs through the IdTable, checks which OIDs are able
909 * to set, and calls the handler function of the OID to perform the
910 * set. The return value of the function will also be stored in
911 * SK_PNMI_STRUCT_DATA if the passed buffer has the minimum size of
912 * SK_PNMI_MIN_STRUCT_SIZE.
913 *
914 * Returns:
915 * SK_PNMI_ERR_OK The request was successfully performed.
916 * SK_PNMI_ERR_GENERAL A general severe internal error occured.
917 * SK_PNMI_ERR_TOO_SHORT The passed buffer is too short to contain
918 * the correct data (e.g. a 32bit value is
919 * needed, but a 16 bit value was passed).
920 * SK_PNMI_ERR_BAD_VALUE The passed value is not in the valid
921 * value range.
922 */
923int SkPnmiSetStruct(
924SK_AC *pAC, /* Pointer to adapter context */
925SK_IOC IoC, /* IO context handle */
926void *pBuf, /* Buffer which contains the data to be set */
927unsigned int *pLen, /* Length of buffer */
928SK_U32 NetIndex) /* NetIndex (0..n), in single net mode always zero */
929{
930 SK_DBG_MSG(pAC, SK_DBGMOD_PNMI, SK_DBGCAT_CTRL,
931 ("PNMI: SkPnmiSetStruct: Called, BufLen=%d, NetIndex=%d\n",
932 *pLen, NetIndex));
933
934 return (PnmiStruct(pAC, IoC, SK_PNMI_SET, (char *)pBuf,
935 pLen, NetIndex));
936}
937
938/*****************************************************************************
939 *
940 * SkPnmiEvent - Event handler
941 *
942 * Description:
943 * Handles the following events:
944 * SK_PNMI_EVT_SIRQ_OVERFLOW When a hardware counter overflows an
945 * interrupt will be generated which is
946 * first handled by SIRQ which generates a
947 * this event. The event increments the
948 * upper 32 bit of the 64 bit counter.
949 * SK_PNMI_EVT_SEN_XXX The event is generated by the I2C module
950 * when a sensor reports a warning or
951 * error. The event will store a trap
952 * message in the trap buffer.
953 * SK_PNMI_EVT_CHG_EST_TIMER The timer event was initiated by this
954 * module and is used to calculate the
955 * port switches per hour.
956 * SK_PNMI_EVT_CLEAR_COUNTER The event clears all counters and
957 * timestamps.
958 * SK_PNMI_EVT_XMAC_RESET The event is generated by the driver
959 * before a hard reset of the XMAC is
960 * performed. All counters will be saved
961 * and added to the hardware counter
962 * values after reset to grant continuous
963 * counter values.
964 * SK_PNMI_EVT_RLMT_PORT_UP Generated by RLMT to notify that a port
965 * went logically up. A trap message will
966 * be stored to the trap buffer.
967 * SK_PNMI_EVT_RLMT_PORT_DOWN Generated by RLMT to notify that a port
968 * went logically down. A trap message will
969 * be stored to the trap buffer.
970 * SK_PNMI_EVT_RLMT_SEGMENTATION Generated by RLMT to notify that two
971 * spanning tree root bridges were
972 * detected. A trap message will be stored
973 * to the trap buffer.
974 * SK_PNMI_EVT_RLMT_ACTIVE_DOWN Notifies PNMI that an active port went
975 * down. PNMI will not further add the
976 * statistic values to the virtual port.
977 * SK_PNMI_EVT_RLMT_ACTIVE_UP Notifies PNMI that a port went up and
978 * is now an active port. PNMI will now
979 * add the statistic data of this port to
980 * the virtual port.
981 * SK_PNMI_EVT_RLMT_SET_NETS Notifies PNMI about the net mode. The first parameter
982 * contains the number of nets. 1 means single net, 2 means
983 * dual net. The second parameter is -1
984 *
985 * Returns:
986 * Always 0
987 */
988int SkPnmiEvent(
989SK_AC *pAC, /* Pointer to adapter context */
990SK_IOC IoC, /* IO context handle */
991SK_U32 Event, /* Event-Id */
992SK_EVPARA Param) /* Event dependent parameter */
993{
994 unsigned int PhysPortIndex;
995 unsigned int MaxNetNumber;
996 int CounterIndex;
997 int Ret;
998 SK_U16 MacStatus;
999 SK_U64 OverflowStatus;
1000 SK_U64 Mask;
1001 int MacType;
1002 SK_U64 Value;
1003 SK_U32 Val32;
1004 SK_U16 Register;
1005 SK_EVPARA EventParam;
1006 SK_U64 NewestValue;
1007 SK_U64 OldestValue;
1008 SK_U64 Delta;
1009 SK_PNMI_ESTIMATE *pEst;
1010 SK_U32 NetIndex;
1011 SK_GEPORT *pPrt;
1012 SK_PNMI_VCT *pVctBackupData;
1013 SK_U32 RetCode;
1014 int i;
1015 SK_U32 CableLength;
1016
1017
1018#ifdef DEBUG
1019 if (Event != SK_PNMI_EVT_XMAC_RESET) {
1020
1021 SK_DBG_MSG(pAC, SK_DBGMOD_PNMI, SK_DBGCAT_CTRL,
1022 ("PNMI: SkPnmiEvent: Called, Event=0x%x, Param=0x%x\n",
1023 (unsigned int)Event, (unsigned int)Param.Para64));
1024 }
1025#endif /* DEBUG */
1026 SK_PNMI_CHECKFLAGS("SkPnmiEvent: On call");
1027
1028 MacType = pAC->GIni.GIMacType;
1029
1030 switch (Event) {
1031
1032 case SK_PNMI_EVT_SIRQ_OVERFLOW:
1033 PhysPortIndex = (int)Param.Para32[0];
1034 MacStatus = (SK_U16)Param.Para32[1];
1035#ifdef DEBUG
1036 if (PhysPortIndex >= SK_MAX_MACS) {
1037
1038 SK_DBG_MSG(pAC, SK_DBGMOD_PNMI, SK_DBGCAT_CTRL,
1039 ("PNMI: ERR: SkPnmiEvent: SK_PNMI_EVT_SIRQ_OVERFLOW parameter"
1040 " wrong, PhysPortIndex=0x%x\n",
1041 PhysPortIndex));
1042 return (0);
1043 }
1044#endif /* DEBUG */
1045 OverflowStatus = 0;
1046
1047 /*
1048 * Check which source caused an overflow interrupt.
1049 */
1050 if ((pAC->GIni.GIFunc.pFnMacOverflow(pAC, IoC, PhysPortIndex,
1051 MacStatus, &OverflowStatus) != 0) ||
1052 (OverflowStatus == 0)) {
1053
1054 SK_PNMI_CHECKFLAGS("SkPnmiEvent: On return");
1055 return (0);
1056 }
1057
1058 /*
1059 * Check the overflow status register and increment
1060 * the upper dword of corresponding counter.
1061 */
1062 for (CounterIndex = 0; CounterIndex < sizeof(Mask) * 8;
1063 CounterIndex ++) {
1064
1065 Mask = (SK_U64)1 << CounterIndex;
1066 if ((OverflowStatus & Mask) == 0) {
1067
1068 continue;
1069 }
1070
1071 switch (StatOvrflwBit[CounterIndex][MacType]) {
1072
1073 case SK_PNMI_HTX_UTILUNDER:
1074 case SK_PNMI_HTX_UTILOVER:
1075 if (MacType == SK_MAC_XMAC) {
1076 XM_IN16(IoC, PhysPortIndex, XM_TX_CMD, &Register);
1077 Register |= XM_TX_SAM_LINE;
1078 XM_OUT16(IoC, PhysPortIndex, XM_TX_CMD, Register);
1079 }
1080 break;
1081
1082 case SK_PNMI_HRX_UTILUNDER:
1083 case SK_PNMI_HRX_UTILOVER:
1084 if (MacType == SK_MAC_XMAC) {
1085 XM_IN16(IoC, PhysPortIndex, XM_RX_CMD, &Register);
1086 Register |= XM_RX_SAM_LINE;
1087 XM_OUT16(IoC, PhysPortIndex, XM_RX_CMD, Register);
1088 }
1089 break;
1090
1091 case SK_PNMI_HTX_OCTETHIGH:
1092 case SK_PNMI_HTX_OCTETLOW:
1093 case SK_PNMI_HTX_RESERVED:
1094 case SK_PNMI_HRX_OCTETHIGH:
1095 case SK_PNMI_HRX_OCTETLOW:
1096 case SK_PNMI_HRX_IRLENGTH:
1097 case SK_PNMI_HRX_RESERVED:
1098
1099 /*
1100 * the following counters aren't be handled (id > 63)
1101 */
1102 case SK_PNMI_HTX_SYNC:
1103 case SK_PNMI_HTX_SYNC_OCTET:
1104 break;
1105
1106 case SK_PNMI_HRX_LONGFRAMES:
1107 if (MacType == SK_MAC_GMAC) {
1108 pAC->Pnmi.Port[PhysPortIndex].
1109 CounterHigh[CounterIndex] ++;
1110 }
1111 break;
1112
1113 default:
1114 pAC->Pnmi.Port[PhysPortIndex].
1115 CounterHigh[CounterIndex] ++;
1116 }
1117 }
1118 break;
1119
1120 case SK_PNMI_EVT_SEN_WAR_LOW:
1121#ifdef DEBUG
1122 if ((unsigned int)Param.Para64 >= (unsigned int)pAC->I2c.MaxSens) {
1123
1124 SK_DBG_MSG(pAC, SK_DBGMOD_PNMI, SK_DBGCAT_CTRL,
1125 ("PNMI: ERR: SkPnmiEvent: SK_PNMI_EVT_SEN_WAR_LOW parameter wrong, SensorIndex=%d\n",
1126 (unsigned int)Param.Para64));
1127 return (0);
1128 }
1129#endif /* DEBUG */
1130
1131 /*
1132 * Store a trap message in the trap buffer and generate
1133 * an event for user space applications with the
1134 * SK_DRIVER_SENDEVENT macro.
1135 */
1136 QueueSensorTrap(pAC, OID_SKGE_TRAP_SEN_WAR_LOW,
1137 (unsigned int)Param.Para64);
1138 (void)SK_DRIVER_SENDEVENT(pAC, IoC);
1139 break;
1140
1141 case SK_PNMI_EVT_SEN_WAR_UPP:
1142#ifdef DEBUG
1143 if ((unsigned int)Param.Para64 >= (unsigned int)pAC->I2c.MaxSens) {
1144
1145 SK_DBG_MSG(pAC, SK_DBGMOD_PNMI, SK_DBGCAT_CTRL,
1146 ("PNMI: ERR: SkPnmiEvent: SK_PNMI_EVT_SEN_WAR_UPP parameter wrong, SensorIndex=%d\n",
1147 (unsigned int)Param.Para64));
1148 return (0);
1149 }
1150#endif /* DEBUG */
1151
1152 /*
1153 * Store a trap message in the trap buffer and generate
1154 * an event for user space applications with the
1155 * SK_DRIVER_SENDEVENT macro.
1156 */
1157 QueueSensorTrap(pAC, OID_SKGE_TRAP_SEN_WAR_UPP,
1158 (unsigned int)Param.Para64);
1159 (void)SK_DRIVER_SENDEVENT(pAC, IoC);
1160 break;
1161
1162 case SK_PNMI_EVT_SEN_ERR_LOW:
1163#ifdef DEBUG
1164 if ((unsigned int)Param.Para64 >= (unsigned int)pAC->I2c.MaxSens) {
1165
1166 SK_DBG_MSG(pAC, SK_DBGMOD_PNMI, SK_DBGCAT_CTRL,
1167 ("PNMI: ERR: SkPnmiEvent: SK_PNMI_EVT_SEN_ERR_LOW parameter wrong, SensorIndex=%d\n",
1168 (unsigned int)Param.Para64));
1169 return (0);
1170 }
1171#endif /* DEBUG */
1172
1173 /*
1174 * Store a trap message in the trap buffer and generate
1175 * an event for user space applications with the
1176 * SK_DRIVER_SENDEVENT macro.
1177 */
1178 QueueSensorTrap(pAC, OID_SKGE_TRAP_SEN_ERR_LOW,
1179 (unsigned int)Param.Para64);
1180 (void)SK_DRIVER_SENDEVENT(pAC, IoC);
1181 break;
1182
1183 case SK_PNMI_EVT_SEN_ERR_UPP:
1184#ifdef DEBUG
1185 if ((unsigned int)Param.Para64 >= (unsigned int)pAC->I2c.MaxSens) {
1186
1187 SK_DBG_MSG(pAC, SK_DBGMOD_PNMI, SK_DBGCAT_CTRL,
1188 ("PNMI: ERR: SkPnmiEvent: SK_PNMI_EVT_SEN_ERR_UPP parameter wrong, SensorIndex=%d\n",
1189 (unsigned int)Param.Para64));
1190 return (0);
1191 }
1192#endif /* DEBUG */
1193
1194 /*
1195 * Store a trap message in the trap buffer and generate
1196 * an event for user space applications with the
1197 * SK_DRIVER_SENDEVENT macro.
1198 */
1199 QueueSensorTrap(pAC, OID_SKGE_TRAP_SEN_ERR_UPP,
1200 (unsigned int)Param.Para64);
1201 (void)SK_DRIVER_SENDEVENT(pAC, IoC);
1202 break;
1203
1204 case SK_PNMI_EVT_CHG_EST_TIMER:
1205 /*
1206 * Calculate port switch average on a per hour basis
1207 * Time interval for check : 28125 ms
1208 * Number of values for average : 8
1209 *
1210 * Be careful in changing these values, on change check
1211 * - typedef of SK_PNMI_ESTIMATE (Size of EstValue
1212 * array one less than value number)
1213 * - Timer initialization SkTimerStart() in SkPnmiInit
1214 * - Delta value below must be multiplicated with
1215 * power of 2
1216 *
1217 */
1218 pEst = &pAC->Pnmi.RlmtChangeEstimate;
1219 CounterIndex = pEst->EstValueIndex + 1;
1220 if (CounterIndex == 7) {
1221
1222 CounterIndex = 0;
1223 }
1224 pEst->EstValueIndex = CounterIndex;
1225
1226 NewestValue = pAC->Pnmi.RlmtChangeCts;
1227 OldestValue = pEst->EstValue[CounterIndex];
1228 pEst->EstValue[CounterIndex] = NewestValue;
1229
1230 /*
1231 * Calculate average. Delta stores the number of
1232 * port switches per 28125 * 8 = 225000 ms
1233 */
1234 if (NewestValue >= OldestValue) {
1235
1236 Delta = NewestValue - OldestValue;
1237 }
1238 else {
1239 /* Overflow situation */
1240 Delta = (SK_U64)(0 - OldestValue) + NewestValue;
1241 }
1242
1243 /*
1244 * Extrapolate delta to port switches per hour.
1245 * Estimate = Delta * (3600000 / 225000)
1246 * = Delta * 16
1247 * = Delta << 4
1248 */
1249 pAC->Pnmi.RlmtChangeEstimate.Estimate = Delta << 4;
1250
1251 /*
1252 * Check if threshold is exceeded. If the threshold is
1253 * permanently exceeded every 28125 ms an event will be
1254 * generated to remind the user of this condition.
1255 */
1256 if ((pAC->Pnmi.RlmtChangeThreshold != 0) &&
1257 (pAC->Pnmi.RlmtChangeEstimate.Estimate >=
1258 pAC->Pnmi.RlmtChangeThreshold)) {
1259
1260 QueueSimpleTrap(pAC, OID_SKGE_TRAP_RLMT_CHANGE_THRES);
1261 (void)SK_DRIVER_SENDEVENT(pAC, IoC);
1262 }
1263
1264 SK_MEMSET((char *)&EventParam, 0, sizeof(EventParam));
1265 SkTimerStart(pAC, IoC, &pAC->Pnmi.RlmtChangeEstimate.EstTimer,
1266 28125000, SKGE_PNMI, SK_PNMI_EVT_CHG_EST_TIMER,
1267 EventParam);
1268 break;
1269
1270 case SK_PNMI_EVT_CLEAR_COUNTER:
1271 /*
1272 * Param.Para32[0] contains the NetIndex (0 ..1).
1273 * Param.Para32[1] is reserved, contains -1.
1274 */
1275 NetIndex = (SK_U32)Param.Para32[0];
1276
1277#ifdef DEBUG
1278 if (NetIndex >= pAC->Rlmt.NumNets) {
1279
1280 SK_DBG_MSG(pAC, SK_DBGMOD_PNMI, SK_DBGCAT_CTRL,
1281 ("PNMI: ERR: SkPnmiEvent: SK_PNMI_EVT_CLEAR_COUNTER parameter wrong, NetIndex=%d\n",
1282 NetIndex));
1283
1284 return (0);
1285 }
1286#endif /* DEBUG */
1287
1288 /*
1289 * Set all counters and timestamps to zero.
1290 * The according NetIndex is required as a
1291 * parameter of the event.
1292 */
1293 ResetCounter(pAC, IoC, NetIndex);
1294 break;
1295
1296 case SK_PNMI_EVT_XMAC_RESET:
1297 /*
1298 * To grant continuous counter values store the current
1299 * XMAC statistic values to the entries 1..n of the
1300 * CounterOffset array. XMAC Errata #2
1301 */
1302#ifdef DEBUG
1303 if ((unsigned int)Param.Para64 >= SK_MAX_MACS) {
1304
1305 SK_DBG_MSG(pAC, SK_DBGMOD_PNMI, SK_DBGCAT_CTRL,
1306 ("PNMI: ERR: SkPnmiEvent: SK_PNMI_EVT_XMAC_RESET parameter wrong, PhysPortIndex=%d\n",
1307 (unsigned int)Param.Para64));
1308 return (0);
1309 }
1310#endif
1311 PhysPortIndex = (unsigned int)Param.Para64;
1312
1313 /*
1314 * Update XMAC statistic to get fresh values
1315 */
1316 Ret = MacUpdate(pAC, IoC, 0, pAC->GIni.GIMacsFound - 1);
1317 if (Ret != SK_PNMI_ERR_OK) {
1318
1319 SK_PNMI_CHECKFLAGS("SkPnmiEvent: On return");
1320 return (0);
1321 }
1322 /*
1323 * Increment semaphore to indicate that an update was
1324 * already done
1325 */
1326 pAC->Pnmi.MacUpdatedFlag ++;
1327
1328 for (CounterIndex = 0; CounterIndex < SK_PNMI_MAX_IDX;
1329 CounterIndex ++) {
1330
1331 if (!StatAddr[CounterIndex][MacType].GetOffset) {
1332
1333 continue;
1334 }
1335
1336 pAC->Pnmi.Port[PhysPortIndex].CounterOffset[CounterIndex] =
1337 GetPhysStatVal(pAC, IoC, PhysPortIndex, CounterIndex);
1338
1339 pAC->Pnmi.Port[PhysPortIndex].CounterHigh[CounterIndex] = 0;
1340 }
1341
1342 pAC->Pnmi.MacUpdatedFlag --;
1343 break;
1344
1345 case SK_PNMI_EVT_RLMT_PORT_UP:
1346 PhysPortIndex = (unsigned int)Param.Para32[0];
1347#ifdef DEBUG
1348 if (PhysPortIndex >= SK_MAX_MACS) {
1349
1350 SK_DBG_MSG(pAC, SK_DBGMOD_PNMI, SK_DBGCAT_CTRL,
1351 ("PNMI: ERR: SkPnmiEvent: SK_PNMI_EVT_RLMT_PORT_UP parameter"
1352 " wrong, PhysPortIndex=%d\n", PhysPortIndex));
1353
1354 return (0);
1355 }
1356#endif /* DEBUG */
1357
1358 /*
1359 * Store a trap message in the trap buffer and generate an event for
1360 * user space applications with the SK_DRIVER_SENDEVENT macro.
1361 */
1362 QueueRlmtPortTrap(pAC, OID_SKGE_TRAP_RLMT_PORT_UP, PhysPortIndex);
1363 (void)SK_DRIVER_SENDEVENT(pAC, IoC);
1364
1365 /* Bugfix for XMAC errata (#10620)*/
1366 if (MacType == SK_MAC_XMAC) {
1367 /* Add incremental difference to offset (#10620)*/
1368 (void)pAC->GIni.GIFunc.pFnMacStatistic(pAC, IoC, PhysPortIndex,
1369 XM_RXE_SHT_ERR, &Val32);
1370
1371 Value = (((SK_U64)pAC->Pnmi.Port[PhysPortIndex].
1372 CounterHigh[SK_PNMI_HRX_SHORTS] << 32) | (SK_U64)Val32);
1373 pAC->Pnmi.Port[PhysPortIndex].CounterOffset[SK_PNMI_HRX_SHORTS] +=
1374 Value - pAC->Pnmi.Port[PhysPortIndex].RxShortZeroMark;
1375 }
1376
1377 /* Tell VctStatus() that a link was up meanwhile. */
1378 pAC->Pnmi.VctStatus[PhysPortIndex] |= SK_PNMI_VCT_LINK;
1379 break;
1380
1381 case SK_PNMI_EVT_RLMT_PORT_DOWN:
1382 PhysPortIndex = (unsigned int)Param.Para32[0];
1383
1384#ifdef DEBUG
1385 if (PhysPortIndex >= SK_MAX_MACS) {
1386
1387 SK_DBG_MSG(pAC, SK_DBGMOD_PNMI, SK_DBGCAT_CTRL,
1388 ("PNMI: ERR: SkPnmiEvent: SK_PNMI_EVT_RLMT_PORT_DOWN parameter"
1389 " wrong, PhysPortIndex=%d\n", PhysPortIndex));
1390
1391 return (0);
1392 }
1393#endif /* DEBUG */
1394
1395 /*
1396 * Store a trap message in the trap buffer and generate an event for
1397 * user space applications with the SK_DRIVER_SENDEVENT macro.
1398 */
1399 QueueRlmtPortTrap(pAC, OID_SKGE_TRAP_RLMT_PORT_DOWN, PhysPortIndex);
1400 (void)SK_DRIVER_SENDEVENT(pAC, IoC);
1401
1402 /* Bugfix #10620 - get zero level for incremental difference */
1403 if (MacType == SK_MAC_XMAC) {
1404
1405 (void)pAC->GIni.GIFunc.pFnMacStatistic(pAC, IoC, PhysPortIndex,
1406 XM_RXE_SHT_ERR, &Val32);
1407
1408 pAC->Pnmi.Port[PhysPortIndex].RxShortZeroMark =
1409 (((SK_U64)pAC->Pnmi.Port[PhysPortIndex].
1410 CounterHigh[SK_PNMI_HRX_SHORTS] << 32) | (SK_U64)Val32);
1411 }
1412 break;
1413
1414 case SK_PNMI_EVT_RLMT_ACTIVE_DOWN:
1415 PhysPortIndex = (unsigned int)Param.Para32[0];
1416 NetIndex = (SK_U32)Param.Para32[1];
1417
1418#ifdef DEBUG
1419 if (PhysPortIndex >= SK_MAX_MACS) {
1420
1421 SK_DBG_MSG(pAC, SK_DBGMOD_PNMI, SK_DBGCAT_CTRL,
1422 ("PNMI: ERR: SkPnmiEvent: SK_PNMI_EVT_RLMT_ACTIVE_DOWN parameter too high, PhysPort=%d\n",
1423 PhysPortIndex));
1424 }
1425
1426 if (NetIndex >= pAC->Rlmt.NumNets) {
1427
1428 SK_DBG_MSG(pAC, SK_DBGMOD_PNMI, SK_DBGCAT_CTRL,
1429 ("PNMI: ERR: SkPnmiEvent: SK_PNMI_EVT_RLMT_ACTIVE_DOWN parameter too high, NetIndex=%d\n",
1430 NetIndex));
1431 }
1432#endif /* DEBUG */
1433
1434 /*
1435 * For now, ignore event if NetIndex != 0.
1436 */
1437 if (Param.Para32[1] != 0) {
1438
1439 return (0);
1440 }
1441
1442 /*
1443 * Nothing to do if port is already inactive
1444 */
1445 if (!pAC->Pnmi.Port[PhysPortIndex].ActiveFlag) {
1446
1447 return (0);
1448 }
1449
1450 /*
1451 * Update statistic counters to calculate new offset for the virtual
1452 * port and increment semaphore to indicate that an update was already
1453 * done.
1454 */
1455 if (MacUpdate(pAC, IoC, 0, pAC->GIni.GIMacsFound - 1) !=
1456 SK_PNMI_ERR_OK) {
1457
1458 SK_PNMI_CHECKFLAGS("SkPnmiEvent: On return");
1459 return (0);
1460 }
1461 pAC->Pnmi.MacUpdatedFlag ++;
1462
1463 /*
1464 * Calculate new counter offset for virtual port to grant continous
1465 * counting on port switches. The virtual port consists of all currently
1466 * active ports. The port down event indicates that a port is removed
1467 * from the virtual port. Therefore add the counter value of the removed
1468 * port to the CounterOffset for the virtual port to grant the same
1469 * counter value.
1470 */
1471 for (CounterIndex = 0; CounterIndex < SK_PNMI_MAX_IDX;
1472 CounterIndex ++) {
1473
1474 if (!StatAddr[CounterIndex][MacType].GetOffset) {
1475
1476 continue;
1477 }
1478
1479 Value = GetPhysStatVal(pAC, IoC, PhysPortIndex, CounterIndex);
1480
1481 pAC->Pnmi.VirtualCounterOffset[CounterIndex] += Value;
1482 }
1483
1484 /*
1485 * Set port to inactive
1486 */
1487 pAC->Pnmi.Port[PhysPortIndex].ActiveFlag = SK_FALSE;
1488
1489 pAC->Pnmi.MacUpdatedFlag --;
1490 break;
1491
1492 case SK_PNMI_EVT_RLMT_ACTIVE_UP:
1493 PhysPortIndex = (unsigned int)Param.Para32[0];
1494 NetIndex = (SK_U32)Param.Para32[1];
1495
1496#ifdef DEBUG
1497 if (PhysPortIndex >= SK_MAX_MACS) {
1498
1499 SK_DBG_MSG(pAC, SK_DBGMOD_PNMI, SK_DBGCAT_CTRL,
1500 ("PNMI: ERR: SkPnmiEvent: SK_PNMI_EVT_RLMT_ACTIVE_UP parameter too high, PhysPort=%d\n",
1501 PhysPortIndex));
1502 }
1503
1504 if (NetIndex >= pAC->Rlmt.NumNets) {
1505
1506 SK_DBG_MSG(pAC, SK_DBGMOD_PNMI, SK_DBGCAT_CTRL,
1507 ("PNMI: ERR: SkPnmiEvent: SK_PNMI_EVT_RLMT_ACTIVE_UP parameter too high, NetIndex=%d\n",
1508 NetIndex));
1509 }
1510#endif /* DEBUG */
1511
1512 /*
1513 * For now, ignore event if NetIndex != 0.
1514 */
1515 if (Param.Para32[1] != 0) {
1516
1517 return (0);
1518 }
1519
1520 /*
1521 * Nothing to do if port is already active
1522 */
1523 if (pAC->Pnmi.Port[PhysPortIndex].ActiveFlag) {
1524
1525 return (0);
1526 }
1527
1528 /*
1529 * Statistic maintenance
1530 */
1531 pAC->Pnmi.RlmtChangeCts ++;
1532 pAC->Pnmi.RlmtChangeTime = SK_PNMI_HUNDREDS_SEC(SkOsGetTime(pAC));
1533
1534 /*
1535 * Store a trap message in the trap buffer and generate an event for
1536 * user space applications with the SK_DRIVER_SENDEVENT macro.
1537 */
1538 QueueRlmtNewMacTrap(pAC, PhysPortIndex);
1539 (void)SK_DRIVER_SENDEVENT(pAC, IoC);
1540
1541 /*
1542 * Update statistic counters to calculate new offset for the virtual
1543 * port and increment semaphore to indicate that an update was
1544 * already done.
1545 */
1546 if (MacUpdate(pAC, IoC, 0, pAC->GIni.GIMacsFound - 1) !=
1547 SK_PNMI_ERR_OK) {
1548
1549 SK_PNMI_CHECKFLAGS("SkPnmiEvent: On return");
1550 return (0);
1551 }
1552 pAC->Pnmi.MacUpdatedFlag ++;
1553
1554 /*
1555 * Calculate new counter offset for virtual port to grant continous
1556 * counting on port switches. A new port is added to the virtual port.
1557 * Therefore substract the counter value of the new port from the
1558 * CounterOffset for the virtual port to grant the same value.
1559 */
1560 for (CounterIndex = 0; CounterIndex < SK_PNMI_MAX_IDX;
1561 CounterIndex ++) {
1562
1563 if (!StatAddr[CounterIndex][MacType].GetOffset) {
1564
1565 continue;
1566 }
1567
1568 Value = GetPhysStatVal(pAC, IoC, PhysPortIndex, CounterIndex);
1569
1570 pAC->Pnmi.VirtualCounterOffset[CounterIndex] -= Value;
1571 }
1572
1573 /* Set port to active */
1574 pAC->Pnmi.Port[PhysPortIndex].ActiveFlag = SK_TRUE;
1575
1576 pAC->Pnmi.MacUpdatedFlag --;
1577 break;
1578
1579 case SK_PNMI_EVT_RLMT_SEGMENTATION:
1580 /*
1581 * Para.Para32[0] contains the NetIndex.
1582 */
1583
1584 /*
1585 * Store a trap message in the trap buffer and generate an event for
1586 * user space applications with the SK_DRIVER_SENDEVENT macro.
1587 */
1588 QueueSimpleTrap(pAC, OID_SKGE_TRAP_RLMT_SEGMENTATION);
1589 (void)SK_DRIVER_SENDEVENT(pAC, IoC);
1590 break;
1591
1592 case SK_PNMI_EVT_RLMT_SET_NETS:
1593 /*
1594 * Param.Para32[0] contains the number of Nets.
1595 * Param.Para32[1] is reserved, contains -1.
1596 */
1597 /*
1598 * Check number of nets
1599 */
1600 MaxNetNumber = pAC->GIni.GIMacsFound;
1601 if (((unsigned int)Param.Para32[0] < 1)
1602 || ((unsigned int)Param.Para32[0] > MaxNetNumber)) {
1603 return (SK_PNMI_ERR_UNKNOWN_NET);
1604 }
1605
1606 if ((unsigned int)Param.Para32[0] == 1) { /* single net mode */
1607 pAC->Pnmi.DualNetActiveFlag = SK_FALSE;
1608 }
1609 else { /* dual net mode */
1610 pAC->Pnmi.DualNetActiveFlag = SK_TRUE;
1611 }
1612 break;
1613
1614 case SK_PNMI_EVT_VCT_RESET:
1615 PhysPortIndex = Param.Para32[0];
1616 pPrt = &pAC->GIni.GP[PhysPortIndex];
1617 pVctBackupData = &pAC->Pnmi.VctBackup[PhysPortIndex];
1618
1619 if (pAC->Pnmi.VctStatus[PhysPortIndex] & SK_PNMI_VCT_PENDING) {
1620 RetCode = SkGmCableDiagStatus(pAC, IoC, PhysPortIndex, SK_FALSE);
1621 if (RetCode == 2) {
1622 /*
1623 * VCT test is still running.
1624 * Start VCT timer counter again.
1625 */
1626 SK_MEMSET((char *) &Param, 0, sizeof(Param));
1627 Param.Para32[0] = PhysPortIndex;
1628 Param.Para32[1] = -1;
1629 SkTimerStart(pAC, IoC,
1630 &pAC->Pnmi.VctTimeout[PhysPortIndex].VctTimer,
1631 4000000, SKGE_PNMI, SK_PNMI_EVT_VCT_RESET, Param);
1632 break;
1633 }
1634 pAC->Pnmi.VctStatus[PhysPortIndex] &= ~SK_PNMI_VCT_PENDING;
1635 pAC->Pnmi.VctStatus[PhysPortIndex] |=
1636 (SK_PNMI_VCT_NEW_VCT_DATA | SK_PNMI_VCT_TEST_DONE);
1637
1638 /* Copy results for later use to PNMI struct. */
1639 for (i = 0; i < 4; i++) {
1640 if (pPrt->PMdiPairSts[i] == SK_PNMI_VCT_NORMAL_CABLE) {
1641 if ((pPrt->PMdiPairLen[i] > 35) &&
1642 (pPrt->PMdiPairLen[i] < 0xff)) {
1643 pPrt->PMdiPairSts[i] = SK_PNMI_VCT_IMPEDANCE_MISMATCH;
1644 }
1645 }
1646 if ((pPrt->PMdiPairLen[i] > 35) &&
1647 (pPrt->PMdiPairLen[i] != 0xff)) {
1648 CableLength = 1000 *
1649 (((175 * pPrt->PMdiPairLen[i]) / 210) - 28);
1650 }
1651 else {
1652 CableLength = 0;
1653 }
1654 pVctBackupData->PMdiPairLen[i] = CableLength;
1655 pVctBackupData->PMdiPairSts[i] = pPrt->PMdiPairSts[i];
1656 }
1657
1658 Param.Para32[0] = PhysPortIndex;
1659 Param.Para32[1] = -1;
1660 SkEventQueue(pAC, SKGE_DRV, SK_DRV_PORT_RESET, Param);
1661 SkEventDispatcher(pAC, IoC);
1662 }
1663
1664 break;
1665
1666 default:
1667 break;
1668 }
1669
1670 SK_PNMI_CHECKFLAGS("SkPnmiEvent: On return");
1671 return (0);
1672}
1673
1674
1675/******************************************************************************
1676 *
1677 * Private functions
1678 *
1679 */
1680
1681/*****************************************************************************
1682 *
1683 * PnmiVar - Gets, presets, and sets single OIDs
1684 *
1685 * Description:
1686 * Looks up the requested OID, calls the corresponding handler
1687 * function, and passes the parameters with the get, preset, or
1688 * set command. The function is called by SkGePnmiGetVar,
1689 * SkGePnmiPreSetVar, or SkGePnmiSetVar.
1690 *
1691 * Returns:
1692 * SK_PNMI_ERR_XXX. For details have a look at the description of the
1693 * calling functions.
1694 * SK_PNMI_ERR_UNKNOWN_NET The requested NetIndex doesn't exist
1695 */
1696PNMI_STATIC int PnmiVar(
1697SK_AC *pAC, /* Pointer to adapter context */
1698SK_IOC IoC, /* IO context handle */
1699int Action, /* GET/PRESET/SET action */
1700SK_U32 Id, /* Object ID that is to be processed */
1701char *pBuf, /* Buffer used for the management data transfer */
1702unsigned int *pLen, /* Total length of pBuf management data */
1703SK_U32 Instance, /* Instance (1..n) that is to be set or -1 */
1704SK_U32 NetIndex) /* NetIndex (0..n), in single net mode always zero */
1705{
1706 unsigned int TableIndex;
1707 int Ret;
1708
1709
1710 if ((TableIndex = LookupId(Id)) == (unsigned int)(-1)) {
1711
1712 *pLen = 0;
1713 return (SK_PNMI_ERR_UNKNOWN_OID);
1714 }
1715
1716 /* Check NetIndex */
1717 if (NetIndex >= pAC->Rlmt.NumNets) {
1718 return (SK_PNMI_ERR_UNKNOWN_NET);
1719 }
1720
1721 SK_PNMI_CHECKFLAGS("PnmiVar: On call");
1722
1723 Ret = IdTable[TableIndex].Func(pAC, IoC, Action, Id, pBuf, pLen,
1724 Instance, TableIndex, NetIndex);
1725
1726 SK_PNMI_CHECKFLAGS("PnmiVar: On return");
1727
1728 return (Ret);
1729}
1730
1731/*****************************************************************************
1732 *
1733 * PnmiStruct - Presets and Sets data in structure SK_PNMI_STRUCT_DATA
1734 *
1735 * Description:
1736 * The return value of the function will also be stored in
1737 * SK_PNMI_STRUCT_DATA if the passed buffer has the minimum size of
1738 * SK_PNMI_MIN_STRUCT_SIZE. The sub-function runs through the IdTable,
1739 * checks which OIDs are able to set, and calls the handler function of
1740 * the OID to perform the set. The return value of the function will
1741 * also be stored in SK_PNMI_STRUCT_DATA if the passed buffer has the
1742 * minimum size of SK_PNMI_MIN_STRUCT_SIZE. The function is called
1743 * by SkGePnmiPreSetStruct and SkGePnmiSetStruct.
1744 *
1745 * Returns:
1746 * SK_PNMI_ERR_XXX. The codes are described in the calling functions.
1747 * SK_PNMI_ERR_UNKNOWN_NET The requested NetIndex doesn't exist
1748 */
1749PNMI_STATIC int PnmiStruct(
1750SK_AC *pAC, /* Pointer to adapter context */
1751SK_IOC IoC, /* IO context handle */
1752int Action, /* PRESET/SET action to be performed */
1753char *pBuf, /* Buffer used for the management data transfer */
1754unsigned int *pLen, /* Length of pBuf management data buffer */
1755SK_U32 NetIndex) /* NetIndex (0..n), in single net mode always zero */
1756{
1757 int Ret;
1758 unsigned int TableIndex;
1759 unsigned int DstOffset;
1760 unsigned int Len;
1761 unsigned int InstanceNo;
1762 unsigned int InstanceCnt;
1763 SK_U32 Instance;
1764 SK_U32 Id;
1765
1766
1767 /* Check if the passed buffer has the right size */
1768 if (*pLen < SK_PNMI_STRUCT_SIZE) {
1769
1770 /* Check if we can return the error within the buffer */
1771 if (*pLen >= SK_PNMI_MIN_STRUCT_SIZE) {
1772
1773 SK_PNMI_SET_STAT(pBuf, SK_PNMI_ERR_TOO_SHORT,
1774 (SK_U32)(-1));
1775 }
1776
1777 *pLen = SK_PNMI_STRUCT_SIZE;
1778 return (SK_PNMI_ERR_TOO_SHORT);
1779 }
1780
1781 /* Check NetIndex */
1782 if (NetIndex >= pAC->Rlmt.NumNets) {
1783 return (SK_PNMI_ERR_UNKNOWN_NET);
1784 }
1785
1786 SK_PNMI_CHECKFLAGS("PnmiStruct: On call");
1787
1788 /*
1789 * Update the values of RLMT and SIRQ and increment semaphores to
1790 * indicate that an update was already done.
1791 */
1792 if ((Ret = RlmtUpdate(pAC, IoC, NetIndex)) != SK_PNMI_ERR_OK) {
1793
1794 SK_PNMI_SET_STAT(pBuf, Ret, (SK_U32)(-1));
1795 *pLen = SK_PNMI_MIN_STRUCT_SIZE;
1796 return (Ret);
1797 }
1798
1799 if ((Ret = SirqUpdate(pAC, IoC)) != SK_PNMI_ERR_OK) {
1800
1801 SK_PNMI_SET_STAT(pBuf, Ret, (SK_U32)(-1));
1802 *pLen = SK_PNMI_MIN_STRUCT_SIZE;
1803 return (Ret);
1804 }
1805
1806 pAC->Pnmi.RlmtUpdatedFlag ++;
1807 pAC->Pnmi.SirqUpdatedFlag ++;
1808
1809 /* Preset/Set values */
1810 for (TableIndex = 0; TableIndex < ID_TABLE_SIZE; TableIndex ++) {
1811
1812 if ((IdTable[TableIndex].Access != SK_PNMI_RW) &&
1813 (IdTable[TableIndex].Access != SK_PNMI_WO)) {
1814
1815 continue;
1816 }
1817
1818 InstanceNo = IdTable[TableIndex].InstanceNo;
1819 Id = IdTable[TableIndex].Id;
1820
1821 for (InstanceCnt = 1; InstanceCnt <= InstanceNo;
1822 InstanceCnt ++) {
1823
1824 DstOffset = IdTable[TableIndex].Offset +
1825 (InstanceCnt - 1) *
1826 IdTable[TableIndex].StructSize;
1827
1828 /*
1829 * Because VPD multiple instance variables are
1830 * not setable we do not need to evaluate VPD
1831 * instances. Have a look to VPD instance
1832 * calculation in SkPnmiGetStruct().
1833 */
1834 Instance = (SK_U32)InstanceCnt;
1835
1836 /*
1837 * Evaluate needed buffer length
1838 */
1839 Len = 0;
1840 Ret = IdTable[TableIndex].Func(pAC, IoC,
1841 SK_PNMI_GET, IdTable[TableIndex].Id,
1842 NULL, &Len, Instance, TableIndex, NetIndex);
1843
1844 if (Ret == SK_PNMI_ERR_UNKNOWN_INST) {
1845
1846 break;
1847 }
1848 if (Ret != SK_PNMI_ERR_TOO_SHORT) {
1849
1850 pAC->Pnmi.RlmtUpdatedFlag --;
1851 pAC->Pnmi.SirqUpdatedFlag --;
1852
1853 SK_PNMI_CHECKFLAGS("PnmiStruct: On return");
1854 SK_PNMI_SET_STAT(pBuf,
1855 SK_PNMI_ERR_GENERAL, DstOffset);
1856 *pLen = SK_PNMI_MIN_STRUCT_SIZE;
1857 return (SK_PNMI_ERR_GENERAL);
1858 }
1859 if (Id == OID_SKGE_VPD_ACTION) {
1860
1861 switch (*(pBuf + DstOffset)) {
1862
1863 case SK_PNMI_VPD_CREATE:
1864 Len = 3 + *(pBuf + DstOffset + 3);
1865 break;
1866
1867 case SK_PNMI_VPD_DELETE:
1868 Len = 3;
1869 break;
1870
1871 default:
1872 Len = 1;
1873 break;
1874 }
1875 }
1876
1877 /* Call the OID handler function */
1878 Ret = IdTable[TableIndex].Func(pAC, IoC, Action,
1879 IdTable[TableIndex].Id, pBuf + DstOffset,
1880 &Len, Instance, TableIndex, NetIndex);
1881
1882 if (Ret != SK_PNMI_ERR_OK) {
1883
1884 pAC->Pnmi.RlmtUpdatedFlag --;
1885 pAC->Pnmi.SirqUpdatedFlag --;
1886
1887 SK_PNMI_CHECKFLAGS("PnmiStruct: On return");
1888 SK_PNMI_SET_STAT(pBuf, SK_PNMI_ERR_BAD_VALUE,
1889 DstOffset);
1890 *pLen = SK_PNMI_MIN_STRUCT_SIZE;
1891 return (SK_PNMI_ERR_BAD_VALUE);
1892 }
1893 }
1894 }
1895
1896 pAC->Pnmi.RlmtUpdatedFlag --;
1897 pAC->Pnmi.SirqUpdatedFlag --;
1898
1899 SK_PNMI_CHECKFLAGS("PnmiStruct: On return");
1900 SK_PNMI_SET_STAT(pBuf, SK_PNMI_ERR_OK, (SK_U32)(-1));
1901 return (SK_PNMI_ERR_OK);
1902}
1903
1904/*****************************************************************************
1905 *
1906 * LookupId - Lookup an OID in the IdTable
1907 *
1908 * Description:
1909 * Scans the IdTable to find the table entry of an OID.
1910 *
1911 * Returns:
1912 * The table index or -1 if not found.
1913 */
1914PNMI_STATIC int LookupId(
1915SK_U32 Id) /* Object identifier to be searched */
1916{
1917 int i;
1918
1919 for (i = 0; i < ID_TABLE_SIZE; i++) {
1920
1921 if (IdTable[i].Id == Id) {
1922
1923 return i;
1924 }
1925 }
1926
1927 return (-1);
1928}
1929
1930/*****************************************************************************
1931 *
1932 * OidStruct - Handler of OID_SKGE_ALL_DATA
1933 *
1934 * Description:
1935 * This OID performs a Get/Preset/SetStruct call and returns all data
1936 * in a SK_PNMI_STRUCT_DATA structure.
1937 *
1938 * Returns:
1939 * SK_PNMI_ERR_OK The request was successfully performed.
1940 * SK_PNMI_ERR_GENERAL A general severe internal error occured.
1941 * SK_PNMI_ERR_TOO_SHORT The passed buffer is too short to contain
1942 * the correct data (e.g. a 32bit value is
1943 * needed, but a 16 bit value was passed).
1944 * SK_PNMI_ERR_BAD_VALUE The passed value is not in the valid
1945 * value range.
1946 * SK_PNMI_ERR_READ_ONLY The OID is read-only and cannot be set.
1947 * SK_PNMI_ERR_UNKNOWN_INST The requested instance of the OID doesn't
1948 * exist (e.g. port instance 3 on a two port
1949 * adapter.
1950 */
1951PNMI_STATIC int OidStruct(
1952SK_AC *pAC, /* Pointer to adapter context */
1953SK_IOC IoC, /* IO context handle */
1954int Action, /* GET/PRESET/SET action */
1955SK_U32 Id, /* Object ID that is to be processed */
1956char *pBuf, /* Buffer used for the management data transfer */
1957unsigned int *pLen, /* On call: pBuf buffer length. On return: used buffer */
1958SK_U32 Instance, /* Instance (1..n) that is to be queried or -1 */
1959unsigned int TableIndex, /* Index to the Id table */
1960SK_U32 NetIndex) /* NetIndex (0..n), in single net mode always zero */
1961{
1962 if (Id != OID_SKGE_ALL_DATA) {
1963
1964 SK_ERR_LOG(pAC, SK_ERRCL_SW, SK_PNMI_ERR003,
1965 SK_PNMI_ERR003MSG);
1966
1967 *pLen = 0;
1968 return (SK_PNMI_ERR_GENERAL);
1969 }
1970
1971 /*
1972 * Check instance. We only handle single instance variables
1973 */
1974 if (Instance != (SK_U32)(-1) && Instance != 1) {
1975
1976 *pLen = 0;
1977 return (SK_PNMI_ERR_UNKNOWN_INST);
1978 }
1979
1980 switch (Action) {
1981
1982 case SK_PNMI_GET:
1983 return (SkPnmiGetStruct(pAC, IoC, pBuf, pLen, NetIndex));
1984
1985 case SK_PNMI_PRESET:
1986 return (SkPnmiPreSetStruct(pAC, IoC, pBuf, pLen, NetIndex));
1987
1988 case SK_PNMI_SET:
1989 return (SkPnmiSetStruct(pAC, IoC, pBuf, pLen, NetIndex));
1990 }
1991
1992 SK_ERR_LOG(pAC, SK_ERRCL_SW, SK_PNMI_ERR004, SK_PNMI_ERR004MSG);
1993
1994 *pLen = 0;
1995 return (SK_PNMI_ERR_GENERAL);
1996}
1997
1998/*****************************************************************************
1999 *
2000 * Perform - OID handler of OID_SKGE_ACTION
2001 *
2002 * Description:
2003 * None.
2004 *
2005 * Returns:
2006 * SK_PNMI_ERR_OK The request was successfully performed.
2007 * SK_PNMI_ERR_GENERAL A general severe internal error occured.
2008 * SK_PNMI_ERR_TOO_SHORT The passed buffer is too short to contain
2009 * the correct data (e.g. a 32bit value is
2010 * needed, but a 16 bit value was passed).
2011 * SK_PNMI_ERR_BAD_VALUE The passed value is not in the valid
2012 * value range.
2013 * SK_PNMI_ERR_READ_ONLY The OID is read-only and cannot be set.
2014 * SK_PNMI_ERR_UNKNOWN_INST The requested instance of the OID doesn't
2015 * exist (e.g. port instance 3 on a two port
2016 * adapter.
2017 */
2018PNMI_STATIC int Perform(
2019SK_AC *pAC, /* Pointer to adapter context */
2020SK_IOC IoC, /* IO context handle */
2021int Action, /* GET/PRESET/SET action */
2022SK_U32 Id, /* Object ID that is to be processed */
2023char *pBuf, /* Buffer used for the management data transfer */
2024unsigned int *pLen, /* On call: pBuf buffer length. On return: used buffer */
2025SK_U32 Instance, /* Instance (1..n) that is to be queried or -1 */
2026unsigned int TableIndex, /* Index to the Id table */
2027SK_U32 NetIndex) /* NetIndex (0..n), in single net mode always zero */
2028{
2029 int Ret;
2030 SK_U32 ActionOp;
2031
2032
2033 /*
2034 * Check instance. We only handle single instance variables
2035 */
2036 if (Instance != (SK_U32)(-1) && Instance != 1) {
2037
2038 *pLen = 0;
2039 return (SK_PNMI_ERR_UNKNOWN_INST);
2040 }
2041
2042 if (*pLen < sizeof(SK_U32)) {
2043
2044 *pLen = sizeof(SK_U32);
2045 return (SK_PNMI_ERR_TOO_SHORT);
2046 }
2047
2048 /* Check if a get should be performed */
2049 if (Action == SK_PNMI_GET) {
2050
2051 /* A get is easy. We always return the same value */
2052 ActionOp = (SK_U32)SK_PNMI_ACT_IDLE;
2053 SK_PNMI_STORE_U32(pBuf, ActionOp);
2054 *pLen = sizeof(SK_U32);
2055
2056 return (SK_PNMI_ERR_OK);
2057 }
2058
2059 /* Continue with PRESET/SET action */
2060 if (*pLen > sizeof(SK_U32)) {
2061
2062 return (SK_PNMI_ERR_BAD_VALUE);
2063 }
2064
2065 /* Check if the command is a known one */
2066 SK_PNMI_READ_U32(pBuf, ActionOp);
2067 if (*pLen > sizeof(SK_U32) ||
2068 (ActionOp != SK_PNMI_ACT_IDLE &&
2069 ActionOp != SK_PNMI_ACT_RESET &&
2070 ActionOp != SK_PNMI_ACT_SELFTEST &&
2071 ActionOp != SK_PNMI_ACT_RESETCNT)) {
2072
2073 *pLen = 0;
2074 return (SK_PNMI_ERR_BAD_VALUE);
2075 }
2076
2077 /* A preset ends here */
2078 if (Action == SK_PNMI_PRESET) {
2079
2080 return (SK_PNMI_ERR_OK);
2081 }
2082
2083 switch (ActionOp) {
2084
2085 case SK_PNMI_ACT_IDLE:
2086 /* Nothing to do */
2087 break;
2088
2089 case SK_PNMI_ACT_RESET:
2090 /*
2091 * Perform a driver reset or something that comes near
2092 * to this.
2093 */
2094 Ret = SK_DRIVER_RESET(pAC, IoC);
2095 if (Ret != 0) {
2096
2097 SK_ERR_LOG(pAC, SK_ERRCL_SW, SK_PNMI_ERR005,
2098 SK_PNMI_ERR005MSG);
2099
2100 return (SK_PNMI_ERR_GENERAL);
2101 }
2102 break;
2103
2104 case SK_PNMI_ACT_SELFTEST:
2105 /*
2106 * Perform a driver selftest or something similar to this.
2107 * Currently this feature is not used and will probably
2108 * implemented in another way.
2109 */
2110 Ret = SK_DRIVER_SELFTEST(pAC, IoC);
2111 pAC->Pnmi.TestResult = Ret;
2112 break;
2113
2114 case SK_PNMI_ACT_RESETCNT:
2115 /* Set all counters and timestamps to zero */
2116 ResetCounter(pAC, IoC, NetIndex);
2117 break;
2118
2119 default:
2120 SK_ERR_LOG(pAC, SK_ERRCL_SW, SK_PNMI_ERR006,
2121 SK_PNMI_ERR006MSG);
2122
2123 return (SK_PNMI_ERR_GENERAL);
2124 }
2125
2126 return (SK_PNMI_ERR_OK);
2127}
2128
2129/*****************************************************************************
2130 *
2131 * Mac8023Stat - OID handler of OID_GEN_XXX and OID_802_3_XXX
2132 *
2133 * Description:
2134 * Retrieves the statistic values of the virtual port (logical
2135 * index 0). Only special OIDs of NDIS are handled which consist
2136 * of a 32 bit instead of a 64 bit value. The OIDs are public
2137 * because perhaps some other platform can use them too.
2138 *
2139 * Returns:
2140 * SK_PNMI_ERR_OK The request was successfully performed.
2141 * SK_PNMI_ERR_GENERAL A general severe internal error occured.
2142 * SK_PNMI_ERR_TOO_SHORT The passed buffer is too short to contain
2143 * the correct data (e.g. a 32bit value is
2144 * needed, but a 16 bit value was passed).
2145 * SK_PNMI_ERR_UNKNOWN_INST The requested instance of the OID doesn't
2146 * exist (e.g. port instance 3 on a two port
2147 * adapter.
2148 */
2149PNMI_STATIC int Mac8023Stat(
2150SK_AC *pAC, /* Pointer to adapter context */
2151SK_IOC IoC, /* IO context handle */
2152int Action, /* GET/PRESET/SET action */
2153SK_U32 Id, /* Object ID that is to be processed */
2154char *pBuf, /* Buffer used for the management data transfer */
2155unsigned int *pLen, /* On call: pBuf buffer length. On return: used buffer */
2156SK_U32 Instance, /* Instance (1..n) that is to be queried or -1 */
2157unsigned int TableIndex, /* Index to the Id table */
2158SK_U32 NetIndex) /* NetIndex (0..n), in single net mode always zero */
2159{
2160 int Ret;
2161 SK_U64 StatVal;
2162 SK_U32 StatVal32;
2163 SK_BOOL Is64BitReq = SK_FALSE;
2164
2165 /*
2166 * Only the active Mac is returned
2167 */
2168 if (Instance != (SK_U32)(-1) && Instance != 1) {
2169
2170 *pLen = 0;
2171 return (SK_PNMI_ERR_UNKNOWN_INST);
2172 }
2173
2174 /*
2175 * Check action type
2176 */
2177 if (Action != SK_PNMI_GET) {
2178
2179 *pLen = 0;
2180 return (SK_PNMI_ERR_READ_ONLY);
2181 }
2182
2183 /* Check length */
2184 switch (Id) {
2185
2186 case OID_802_3_PERMANENT_ADDRESS:
2187 case OID_802_3_CURRENT_ADDRESS:
2188 if (*pLen < sizeof(SK_MAC_ADDR)) {
2189
2190 *pLen = sizeof(SK_MAC_ADDR);
2191 return (SK_PNMI_ERR_TOO_SHORT);
2192 }
2193 break;
2194
2195 default:
2196#ifndef SK_NDIS_64BIT_CTR
2197 if (*pLen < sizeof(SK_U32)) {
2198 *pLen = sizeof(SK_U32);
2199 return (SK_PNMI_ERR_TOO_SHORT);
2200 }
2201
2202#else /* SK_NDIS_64BIT_CTR */
2203
2204 /* for compatibility, at least 32bit are required for OID */
2205 if (*pLen < sizeof(SK_U32)) {
2206 /*
2207 * but indicate handling for 64bit values,
2208 * if insufficient space is provided
2209 */
2210 *pLen = sizeof(SK_U64);
2211 return (SK_PNMI_ERR_TOO_SHORT);
2212 }
2213
2214 Is64BitReq = (*pLen < sizeof(SK_U64)) ? SK_FALSE : SK_TRUE;
2215#endif /* SK_NDIS_64BIT_CTR */
2216 break;
2217 }
2218
2219 /*
2220 * Update all statistics, because we retrieve virtual MAC, which
2221 * consists of multiple physical statistics and increment semaphore
2222 * to indicate that an update was already done.
2223 */
2224 Ret = MacUpdate(pAC, IoC, 0, pAC->GIni.GIMacsFound - 1);
2225 if ( Ret != SK_PNMI_ERR_OK) {
2226
2227 *pLen = 0;
2228 return (Ret);
2229 }
2230 pAC->Pnmi.MacUpdatedFlag ++;
2231
2232 /*
2233 * Get value (MAC Index 0 identifies the virtual MAC)
2234 */
2235 switch (Id) {
2236
2237 case OID_802_3_PERMANENT_ADDRESS:
2238 CopyMac(pBuf, &pAC->Addr.Net[NetIndex].PermanentMacAddress);
2239 *pLen = sizeof(SK_MAC_ADDR);
2240 break;
2241
2242 case OID_802_3_CURRENT_ADDRESS:
2243 CopyMac(pBuf, &pAC->Addr.Net[NetIndex].CurrentMacAddress);
2244 *pLen = sizeof(SK_MAC_ADDR);
2245 break;
2246
2247 default:
2248 StatVal = GetStatVal(pAC, IoC, 0, IdTable[TableIndex].Param, NetIndex);
2249
2250 /* by default 32bit values are evaluated */
2251 if (!Is64BitReq) {
2252 StatVal32 = (SK_U32)StatVal;
2253 SK_PNMI_STORE_U32(pBuf, StatVal32);
2254 *pLen = sizeof(SK_U32);
2255 }
2256 else {
2257 SK_PNMI_STORE_U64(pBuf, StatVal);
2258 *pLen = sizeof(SK_U64);
2259 }
2260 break;
2261 }
2262
2263 pAC->Pnmi.MacUpdatedFlag --;
2264
2265 return (SK_PNMI_ERR_OK);
2266}
2267
2268/*****************************************************************************
2269 *
2270 * MacPrivateStat - OID handler function of OID_SKGE_STAT_XXX
2271 *
2272 * Description:
2273 * Retrieves the MAC statistic data.
2274 *
2275 * Returns:
2276 * SK_PNMI_ERR_OK The request was successfully performed.
2277 * SK_PNMI_ERR_GENERAL A general severe internal error occured.
2278 * SK_PNMI_ERR_TOO_SHORT The passed buffer is too short to contain
2279 * the correct data (e.g. a 32bit value is
2280 * needed, but a 16 bit value was passed).
2281 * SK_PNMI_ERR_UNKNOWN_INST The requested instance of the OID doesn't
2282 * exist (e.g. port instance 3 on a two port
2283 * adapter.
2284 */
2285PNMI_STATIC int MacPrivateStat(
2286SK_AC *pAC, /* Pointer to adapter context */
2287SK_IOC IoC, /* IO context handle */
2288int Action, /* GET/PRESET/SET action */
2289SK_U32 Id, /* Object ID that is to be processed */
2290char *pBuf, /* Buffer used for the management data transfer */
2291unsigned int *pLen, /* On call: pBuf buffer length. On return: used buffer */
2292SK_U32 Instance, /* Instance (1..n) that is to be queried or -1 */
2293unsigned int TableIndex, /* Index to the Id table */
2294SK_U32 NetIndex) /* NetIndex (0..n), in single net mode always zero */
2295{
2296 unsigned int LogPortMax;
2297 unsigned int LogPortIndex;
2298 unsigned int PhysPortMax;
2299 unsigned int Limit;
2300 unsigned int Offset;
2301 int MacType;
2302 int Ret;
2303 SK_U64 StatVal;
2304
2305
2306
2307 /* Calculate instance if wished. MAC index 0 is the virtual MAC */
2308 PhysPortMax = pAC->GIni.GIMacsFound;
2309 LogPortMax = SK_PNMI_PORT_PHYS2LOG(PhysPortMax);
2310
2311 MacType = pAC->GIni.GIMacType;
2312
2313 if (pAC->Pnmi.DualNetActiveFlag == SK_TRUE) { /* Dual net mode */
2314 LogPortMax--;
2315 }
2316
2317 if ((Instance != (SK_U32)(-1))) { /* Only one specific instance is queried */
2318 /* Check instance range */
2319 if ((Instance < 1) || (Instance > LogPortMax)) {
2320
2321 *pLen = 0;
2322 return (SK_PNMI_ERR_UNKNOWN_INST);
2323 }
2324 LogPortIndex = SK_PNMI_PORT_INST2LOG(Instance);
2325 Limit = LogPortIndex + 1;
2326 }
2327
2328 else { /* Instance == (SK_U32)(-1), get all Instances of that OID */
2329
2330 LogPortIndex = 0;
2331 Limit = LogPortMax;
2332 }
2333
2334 /* Check action */
2335 if (Action != SK_PNMI_GET) {
2336
2337 *pLen = 0;
2338 return (SK_PNMI_ERR_READ_ONLY);
2339 }
2340
2341 /* Check length */
2342 if (*pLen < (Limit - LogPortIndex) * sizeof(SK_U64)) {
2343
2344 *pLen = (Limit - LogPortIndex) * sizeof(SK_U64);
2345 return (SK_PNMI_ERR_TOO_SHORT);
2346 }
2347
2348 /*
2349 * Update MAC statistic and increment semaphore to indicate that
2350 * an update was already done.
2351 */
2352 Ret = MacUpdate(pAC, IoC, 0, pAC->GIni.GIMacsFound - 1);
2353 if (Ret != SK_PNMI_ERR_OK) {
2354
2355 *pLen = 0;
2356 return (Ret);
2357 }
2358 pAC->Pnmi.MacUpdatedFlag ++;
2359
2360 /* Get value */
2361 Offset = 0;
2362 for (; LogPortIndex < Limit; LogPortIndex ++) {
2363
2364 switch (Id) {
2365
2366/* XXX not yet implemented due to XMAC problems
2367 case OID_SKGE_STAT_TX_UTIL:
2368 return (SK_PNMI_ERR_GENERAL);
2369*/
2370/* XXX not yet implemented due to XMAC problems
2371 case OID_SKGE_STAT_RX_UTIL:
2372 return (SK_PNMI_ERR_GENERAL);
2373*/
2374 case OID_SKGE_STAT_RX:
2375 if (MacType == SK_MAC_GMAC) {
2376 StatVal =
2377 GetStatVal(pAC, IoC, LogPortIndex,
2378 SK_PNMI_HRX_BROADCAST, NetIndex) +
2379 GetStatVal(pAC, IoC, LogPortIndex,
2380 SK_PNMI_HRX_MULTICAST, NetIndex) +
2381 GetStatVal(pAC, IoC, LogPortIndex,
2382 SK_PNMI_HRX_UNICAST, NetIndex) +
2383 GetStatVal(pAC, IoC, LogPortIndex,
2384 SK_PNMI_HRX_UNDERSIZE, NetIndex);
2385 }
2386 else {
2387 StatVal = GetStatVal(pAC, IoC, LogPortIndex,
2388 IdTable[TableIndex].Param, NetIndex);
2389 }
2390 break;
2391
2392 case OID_SKGE_STAT_TX:
2393 if (MacType == SK_MAC_GMAC) {
2394 StatVal =
2395 GetStatVal(pAC, IoC, LogPortIndex,
2396 SK_PNMI_HTX_BROADCAST, NetIndex) +
2397 GetStatVal(pAC, IoC, LogPortIndex,
2398 SK_PNMI_HTX_MULTICAST, NetIndex) +
2399 GetStatVal(pAC, IoC, LogPortIndex,
2400 SK_PNMI_HTX_UNICAST, NetIndex);
2401 }
2402 else {
2403 StatVal = GetStatVal(pAC, IoC, LogPortIndex,
2404 IdTable[TableIndex].Param, NetIndex);
2405 }
2406 break;
2407
2408 default:
2409 StatVal = GetStatVal(pAC, IoC, LogPortIndex,
2410 IdTable[TableIndex].Param, NetIndex);
2411 }
2412 SK_PNMI_STORE_U64(pBuf + Offset, StatVal);
2413
2414 Offset += sizeof(SK_U64);
2415 }
2416 *pLen = Offset;
2417
2418 pAC->Pnmi.MacUpdatedFlag --;
2419
2420 return (SK_PNMI_ERR_OK);
2421}
2422
2423/*****************************************************************************
2424 *
2425 * Addr - OID handler function of OID_SKGE_PHYS_CUR_ADDR and _FAC_ADDR
2426 *
2427 * Description:
2428 * Get/Presets/Sets the current and factory MAC address. The MAC
2429 * address of the virtual port, which is reported to the OS, may
2430 * not be changed, but the physical ones. A set to the virtual port
2431 * will be ignored. No error should be reported because otherwise
2432 * a multiple instance set (-1) would always fail.
2433 *
2434 * Returns:
2435 * SK_PNMI_ERR_OK The request was successfully performed.
2436 * SK_PNMI_ERR_GENERAL A general severe internal error occured.
2437 * SK_PNMI_ERR_TOO_SHORT The passed buffer is too short to contain
2438 * the correct data (e.g. a 32bit value is
2439 * needed, but a 16 bit value was passed).
2440 * SK_PNMI_ERR_BAD_VALUE The passed value is not in the valid
2441 * value range.
2442 * SK_PNMI_ERR_READ_ONLY The OID is read-only and cannot be set.
2443 * SK_PNMI_ERR_UNKNOWN_INST The requested instance of the OID doesn't
2444 * exist (e.g. port instance 3 on a two port
2445 * adapter.
2446 */
2447PNMI_STATIC int Addr(
2448SK_AC *pAC, /* Pointer to adapter context */
2449SK_IOC IoC, /* IO context handle */
2450int Action, /* GET/PRESET/SET action */
2451SK_U32 Id, /* Object ID that is to be processed */
2452char *pBuf, /* Buffer used for the management data transfer */
2453unsigned int *pLen, /* On call: pBuf buffer length. On return: used buffer */
2454SK_U32 Instance, /* Instance (1..n) that is to be queried or -1 */
2455unsigned int TableIndex, /* Index to the Id table */
2456SK_U32 NetIndex) /* NetIndex (0..n), in single net mode always zero */
2457{
2458 int Ret;
2459 unsigned int LogPortMax;
2460 unsigned int PhysPortMax;
2461 unsigned int LogPortIndex;
2462 unsigned int PhysPortIndex;
2463 unsigned int Limit;
2464 unsigned int Offset = 0;
2465
2466 /*
2467 * Calculate instance if wished. MAC index 0 is the virtual
2468 * MAC.
2469 */
2470 PhysPortMax = pAC->GIni.GIMacsFound;
2471 LogPortMax = SK_PNMI_PORT_PHYS2LOG(PhysPortMax);
2472
2473 if (pAC->Pnmi.DualNetActiveFlag == SK_TRUE) { /* Dual net mode */
2474 LogPortMax--;
2475 }
2476
2477 if ((Instance != (SK_U32)(-1))) { /* Only one specific instance is queried */
2478 /* Check instance range */
2479 if ((Instance < 1) || (Instance > LogPortMax)) {
2480
2481 *pLen = 0;
2482 return (SK_PNMI_ERR_UNKNOWN_INST);
2483 }
2484 LogPortIndex = SK_PNMI_PORT_INST2LOG(Instance);
2485 Limit = LogPortIndex + 1;
2486 }
2487 else { /* Instance == (SK_U32)(-1), get all Instances of that OID */
2488
2489 LogPortIndex = 0;
2490 Limit = LogPortMax;
2491 }
2492
2493 /*
2494 * Perform Action
2495 */
2496 if (Action == SK_PNMI_GET) {
2497
2498 /* Check length */
2499 if (*pLen < (Limit - LogPortIndex) * 6) {
2500
2501 *pLen = (Limit - LogPortIndex) * 6;
2502 return (SK_PNMI_ERR_TOO_SHORT);
2503 }
2504
2505 /*
2506 * Get value
2507 */
2508 for (; LogPortIndex < Limit; LogPortIndex ++) {
2509
2510 switch (Id) {
2511
2512 case OID_SKGE_PHYS_CUR_ADDR:
2513 if (LogPortIndex == 0) {
2514 CopyMac(pBuf + Offset, &pAC->Addr.Net[NetIndex].CurrentMacAddress);
2515 }
2516 else {
2517 PhysPortIndex = SK_PNMI_PORT_LOG2PHYS(pAC, LogPortIndex);
2518
2519 CopyMac(pBuf + Offset,
2520 &pAC->Addr.Port[PhysPortIndex].CurrentMacAddress);
2521 }
2522 Offset += 6;
2523 break;
2524
2525 case OID_SKGE_PHYS_FAC_ADDR:
2526 if (LogPortIndex == 0) {
2527 CopyMac(pBuf + Offset,
2528 &pAC->Addr.Net[NetIndex].PermanentMacAddress);
2529 }
2530 else {
2531 PhysPortIndex = SK_PNMI_PORT_LOG2PHYS(
2532 pAC, LogPortIndex);
2533
2534 CopyMac(pBuf + Offset,
2535 &pAC->Addr.Port[PhysPortIndex].PermanentMacAddress);
2536 }
2537 Offset += 6;
2538 break;
2539
2540 default:
2541 SK_ERR_LOG(pAC, SK_ERRCL_SW, SK_PNMI_ERR008,
2542 SK_PNMI_ERR008MSG);
2543
2544 *pLen = 0;
2545 return (SK_PNMI_ERR_GENERAL);
2546 }
2547 }
2548
2549 *pLen = Offset;
2550 }
2551 else {
2552 /*
2553 * The logical MAC address may not be changed only
2554 * the physical ones
2555 */
2556 if (Id == OID_SKGE_PHYS_FAC_ADDR) {
2557
2558 *pLen = 0;
2559 return (SK_PNMI_ERR_READ_ONLY);
2560 }
2561
2562 /*
2563 * Only the current address may be changed
2564 */
2565 if (Id != OID_SKGE_PHYS_CUR_ADDR) {
2566
2567 SK_ERR_LOG(pAC, SK_ERRCL_SW, SK_PNMI_ERR009,
2568 SK_PNMI_ERR009MSG);
2569
2570 *pLen = 0;
2571 return (SK_PNMI_ERR_GENERAL);
2572 }
2573
2574 /* Check length */
2575 if (*pLen < (Limit - LogPortIndex) * 6) {
2576
2577 *pLen = (Limit - LogPortIndex) * 6;
2578 return (SK_PNMI_ERR_TOO_SHORT);
2579 }
2580 if (*pLen > (Limit - LogPortIndex) * 6) {
2581
2582 *pLen = 0;
2583 return (SK_PNMI_ERR_BAD_VALUE);
2584 }
2585
2586 /*
2587 * Check Action
2588 */
2589 if (Action == SK_PNMI_PRESET) {
2590
2591 *pLen = 0;
2592 return (SK_PNMI_ERR_OK);
2593 }
2594
2595 /*
2596 * Set OID_SKGE_MAC_CUR_ADDR
2597 */
2598 for (; LogPortIndex < Limit; LogPortIndex ++, Offset += 6) {
2599
2600 /*
2601 * A set to virtual port and set of broadcast
2602 * address will be ignored
2603 */
2604 if (LogPortIndex == 0 || SK_MEMCMP(pBuf + Offset,
2605 "\xff\xff\xff\xff\xff\xff", 6) == 0) {
2606
2607 continue;
2608 }
2609
2610 PhysPortIndex = SK_PNMI_PORT_LOG2PHYS(pAC,
2611 LogPortIndex);
2612
2613 Ret = SkAddrOverride(pAC, IoC, PhysPortIndex,
2614 (SK_MAC_ADDR *)(pBuf + Offset),
2615 (LogPortIndex == 0 ? SK_ADDR_VIRTUAL_ADDRESS :
2616 SK_ADDR_PHYSICAL_ADDRESS));
2617 if (Ret != SK_ADDR_OVERRIDE_SUCCESS) {
2618
2619 return (SK_PNMI_ERR_GENERAL);
2620 }
2621 }
2622 *pLen = Offset;
2623 }
2624
2625 return (SK_PNMI_ERR_OK);
2626}
2627
2628/*****************************************************************************
2629 *
2630 * CsumStat - OID handler function of OID_SKGE_CHKSM_XXX
2631 *
2632 * Description:
2633 * Retrieves the statistic values of the CSUM module. The CSUM data
2634 * structure must be available in the SK_AC even if the CSUM module
2635 * is not included, because PNMI reads the statistic data from the
2636 * CSUM part of SK_AC directly.
2637 *
2638 * Returns:
2639 * SK_PNMI_ERR_OK The request was successfully performed.
2640 * SK_PNMI_ERR_GENERAL A general severe internal error occured.
2641 * SK_PNMI_ERR_TOO_SHORT The passed buffer is too short to contain
2642 * the correct data (e.g. a 32bit value is
2643 * needed, but a 16 bit value was passed).
2644 * SK_PNMI_ERR_UNKNOWN_INST The requested instance of the OID doesn't
2645 * exist (e.g. port instance 3 on a two port
2646 * adapter.
2647 */
2648PNMI_STATIC int CsumStat(
2649SK_AC *pAC, /* Pointer to adapter context */
2650SK_IOC IoC, /* IO context handle */
2651int Action, /* GET/PRESET/SET action */
2652SK_U32 Id, /* Object ID that is to be processed */
2653char *pBuf, /* Buffer used for the management data transfer */
2654unsigned int *pLen, /* On call: pBuf buffer length. On return: used buffer */
2655SK_U32 Instance, /* Instance (1..n) that is to be queried or -1 */
2656unsigned int TableIndex, /* Index to the Id table */
2657SK_U32 NetIndex) /* NetIndex (0..n), in single net mode always zero */
2658{
2659 unsigned int Index;
2660 unsigned int Limit;
2661 unsigned int Offset = 0;
2662 SK_U64 StatVal;
2663
2664
2665 /*
2666 * Calculate instance if wished
2667 */
2668 if (Instance != (SK_U32)(-1)) {
2669
2670 if ((Instance < 1) || (Instance > SKCS_NUM_PROTOCOLS)) {
2671
2672 *pLen = 0;
2673 return (SK_PNMI_ERR_UNKNOWN_INST);
2674 }
2675 Index = (unsigned int)Instance - 1;
2676 Limit = Index + 1;
2677 }
2678 else {
2679 Index = 0;
2680 Limit = SKCS_NUM_PROTOCOLS;
2681 }
2682
2683 /*
2684 * Check action
2685 */
2686 if (Action != SK_PNMI_GET) {
2687
2688 *pLen = 0;
2689 return (SK_PNMI_ERR_READ_ONLY);
2690 }
2691
2692 /* Check length */
2693 if (*pLen < (Limit - Index) * sizeof(SK_U64)) {
2694
2695 *pLen = (Limit - Index) * sizeof(SK_U64);
2696 return (SK_PNMI_ERR_TOO_SHORT);
2697 }
2698
2699 /*
2700 * Get value
2701 */
2702 for (; Index < Limit; Index ++) {
2703
2704 switch (Id) {
2705
2706 case OID_SKGE_CHKSM_RX_OK_CTS:
2707 StatVal = pAC->Csum.ProtoStats[NetIndex][Index].RxOkCts;
2708 break;
2709
2710 case OID_SKGE_CHKSM_RX_UNABLE_CTS:
2711 StatVal = pAC->Csum.ProtoStats[NetIndex][Index].RxUnableCts;
2712 break;
2713
2714 case OID_SKGE_CHKSM_RX_ERR_CTS:
2715 StatVal = pAC->Csum.ProtoStats[NetIndex][Index].RxErrCts;
2716 break;
2717
2718 case OID_SKGE_CHKSM_TX_OK_CTS:
2719 StatVal = pAC->Csum.ProtoStats[NetIndex][Index].TxOkCts;
2720 break;
2721
2722 case OID_SKGE_CHKSM_TX_UNABLE_CTS:
2723 StatVal = pAC->Csum.ProtoStats[NetIndex][Index].TxUnableCts;
2724 break;
2725
2726 default:
2727 SK_ERR_LOG(pAC, SK_ERRCL_SW, SK_PNMI_ERR010,
2728 SK_PNMI_ERR010MSG);
2729
2730 *pLen = 0;
2731 return (SK_PNMI_ERR_GENERAL);
2732 }
2733
2734 SK_PNMI_STORE_U64(pBuf + Offset, StatVal);
2735 Offset += sizeof(SK_U64);
2736 }
2737
2738 /*
2739 * Store used buffer space
2740 */
2741 *pLen = Offset;
2742
2743 return (SK_PNMI_ERR_OK);
2744}
2745
2746/*****************************************************************************
2747 *
2748 * SensorStat - OID handler function of OID_SKGE_SENSOR_XXX
2749 *
2750 * Description:
2751 * Retrieves the statistic values of the I2C module, which handles
2752 * the temperature and voltage sensors.
2753 *
2754 * Returns:
2755 * SK_PNMI_ERR_OK The request was successfully performed.
2756 * SK_PNMI_ERR_GENERAL A general severe internal error occured.
2757 * SK_PNMI_ERR_TOO_SHORT The passed buffer is too short to contain
2758 * the correct data (e.g. a 32bit value is
2759 * needed, but a 16 bit value was passed).
2760 * SK_PNMI_ERR_UNKNOWN_INST The requested instance of the OID doesn't
2761 * exist (e.g. port instance 3 on a two port
2762 * adapter.
2763 */
2764PNMI_STATIC int SensorStat(
2765SK_AC *pAC, /* Pointer to adapter context */
2766SK_IOC IoC, /* IO context handle */
2767int Action, /* GET/PRESET/SET action */
2768SK_U32 Id, /* Object ID that is to be processed */
2769char *pBuf, /* Buffer used for the management data transfer */
2770unsigned int *pLen, /* On call: pBuf buffer length. On return: used buffer */
2771SK_U32 Instance, /* Instance (1..n) that is to be queried or -1 */
2772unsigned int TableIndex, /* Index to the Id table */
2773SK_U32 NetIndex) /* NetIndex (0..n), in single net mode always zero */
2774{
2775 unsigned int i;
2776 unsigned int Index;
2777 unsigned int Limit;
2778 unsigned int Offset;
2779 unsigned int Len;
2780 SK_U32 Val32;
2781 SK_U64 Val64;
2782
2783
2784 /*
2785 * Calculate instance if wished
2786 */
2787 if ((Instance != (SK_U32)(-1))) {
2788
2789 if ((Instance < 1) || (Instance > (SK_U32)pAC->I2c.MaxSens)) {
2790
2791 *pLen = 0;
2792 return (SK_PNMI_ERR_UNKNOWN_INST);
2793 }
2794
2795 Index = (unsigned int)Instance -1;
2796 Limit = (unsigned int)Instance;
2797 }
2798 else {
2799 Index = 0;
2800 Limit = (unsigned int) pAC->I2c.MaxSens;
2801 }
2802
2803 /*
2804 * Check action
2805 */
2806 if (Action != SK_PNMI_GET) {
2807
2808 *pLen = 0;
2809 return (SK_PNMI_ERR_READ_ONLY);
2810 }
2811
2812 /* Check length */
2813 switch (Id) {
2814
2815 case OID_SKGE_SENSOR_VALUE:
2816 case OID_SKGE_SENSOR_WAR_THRES_LOW:
2817 case OID_SKGE_SENSOR_WAR_THRES_UPP:
2818 case OID_SKGE_SENSOR_ERR_THRES_LOW:
2819 case OID_SKGE_SENSOR_ERR_THRES_UPP:
2820 if (*pLen < (Limit - Index) * sizeof(SK_U32)) {
2821
2822 *pLen = (Limit - Index) * sizeof(SK_U32);
2823 return (SK_PNMI_ERR_TOO_SHORT);
2824 }
2825 break;
2826
2827 case OID_SKGE_SENSOR_DESCR:
2828 for (Offset = 0, i = Index; i < Limit; i ++) {
2829
2830 Len = (unsigned int)
2831 SK_STRLEN(pAC->I2c.SenTable[i].SenDesc) + 1;
2832 if (Len >= SK_PNMI_STRINGLEN2) {
2833
2834 SK_ERR_LOG(pAC, SK_ERRCL_SW, SK_PNMI_ERR011,
2835 SK_PNMI_ERR011MSG);
2836
2837 *pLen = 0;
2838 return (SK_PNMI_ERR_GENERAL);
2839 }
2840 Offset += Len;
2841 }
2842 if (*pLen < Offset) {
2843
2844 *pLen = Offset;
2845 return (SK_PNMI_ERR_TOO_SHORT);
2846 }
2847 break;
2848
2849 case OID_SKGE_SENSOR_INDEX:
2850 case OID_SKGE_SENSOR_TYPE:
2851 case OID_SKGE_SENSOR_STATUS:
2852 if (*pLen < Limit - Index) {
2853
2854 *pLen = Limit - Index;
2855 return (SK_PNMI_ERR_TOO_SHORT);
2856 }
2857 break;
2858
2859 case OID_SKGE_SENSOR_WAR_CTS:
2860 case OID_SKGE_SENSOR_WAR_TIME:
2861 case OID_SKGE_SENSOR_ERR_CTS:
2862 case OID_SKGE_SENSOR_ERR_TIME:
2863 if (*pLen < (Limit - Index) * sizeof(SK_U64)) {
2864
2865 *pLen = (Limit - Index) * sizeof(SK_U64);
2866 return (SK_PNMI_ERR_TOO_SHORT);
2867 }
2868 break;
2869
2870 default:
2871 SK_ERR_LOG(pAC, SK_ERRCL_SW, SK_PNMI_ERR012,
2872 SK_PNMI_ERR012MSG);
2873
2874 *pLen = 0;
2875 return (SK_PNMI_ERR_GENERAL);
2876
2877 }
2878
2879 /*
2880 * Get value
2881 */
2882 for (Offset = 0; Index < Limit; Index ++) {
2883
2884 switch (Id) {
2885
2886 case OID_SKGE_SENSOR_INDEX:
2887 *(pBuf + Offset) = (char)Index;
2888 Offset += sizeof(char);
2889 break;
2890
2891 case OID_SKGE_SENSOR_DESCR:
2892 Len = SK_STRLEN(pAC->I2c.SenTable[Index].SenDesc);
2893 SK_MEMCPY(pBuf + Offset + 1,
2894 pAC->I2c.SenTable[Index].SenDesc, Len);
2895 *(pBuf + Offset) = (char)Len;
2896 Offset += Len + 1;
2897 break;
2898
2899 case OID_SKGE_SENSOR_TYPE:
2900 *(pBuf + Offset) =
2901 (char)pAC->I2c.SenTable[Index].SenType;
2902 Offset += sizeof(char);
2903 break;
2904
2905 case OID_SKGE_SENSOR_VALUE:
2906 Val32 = (SK_U32)pAC->I2c.SenTable[Index].SenValue;
2907 SK_PNMI_STORE_U32(pBuf + Offset, Val32);
2908 Offset += sizeof(SK_U32);
2909 break;
2910
2911 case OID_SKGE_SENSOR_WAR_THRES_LOW:
2912 Val32 = (SK_U32)pAC->I2c.SenTable[Index].
2913 SenThreWarnLow;
2914 SK_PNMI_STORE_U32(pBuf + Offset, Val32);
2915 Offset += sizeof(SK_U32);
2916 break;
2917
2918 case OID_SKGE_SENSOR_WAR_THRES_UPP:
2919 Val32 = (SK_U32)pAC->I2c.SenTable[Index].
2920 SenThreWarnHigh;
2921 SK_PNMI_STORE_U32(pBuf + Offset, Val32);
2922 Offset += sizeof(SK_U32);
2923 break;
2924
2925 case OID_SKGE_SENSOR_ERR_THRES_LOW:
2926 Val32 = (SK_U32)pAC->I2c.SenTable[Index].
2927 SenThreErrLow;
2928 SK_PNMI_STORE_U32(pBuf + Offset, Val32);
2929 Offset += sizeof(SK_U32);
2930 break;
2931
2932 case OID_SKGE_SENSOR_ERR_THRES_UPP:
2933 Val32 = pAC->I2c.SenTable[Index].SenThreErrHigh;
2934 SK_PNMI_STORE_U32(pBuf + Offset, Val32);
2935 Offset += sizeof(SK_U32);
2936 break;
2937
2938 case OID_SKGE_SENSOR_STATUS:
2939 *(pBuf + Offset) =
2940 (char)pAC->I2c.SenTable[Index].SenErrFlag;
2941 Offset += sizeof(char);
2942 break;
2943
2944 case OID_SKGE_SENSOR_WAR_CTS:
2945 Val64 = pAC->I2c.SenTable[Index].SenWarnCts;
2946 SK_PNMI_STORE_U64(pBuf + Offset, Val64);
2947 Offset += sizeof(SK_U64);
2948 break;
2949
2950 case OID_SKGE_SENSOR_ERR_CTS:
2951 Val64 = pAC->I2c.SenTable[Index].SenErrCts;
2952 SK_PNMI_STORE_U64(pBuf + Offset, Val64);
2953 Offset += sizeof(SK_U64);
2954 break;
2955
2956 case OID_SKGE_SENSOR_WAR_TIME:
2957 Val64 = SK_PNMI_HUNDREDS_SEC(pAC->I2c.SenTable[Index].
2958 SenBegWarnTS);
2959 SK_PNMI_STORE_U64(pBuf + Offset, Val64);
2960 Offset += sizeof(SK_U64);
2961 break;
2962
2963 case OID_SKGE_SENSOR_ERR_TIME:
2964 Val64 = SK_PNMI_HUNDREDS_SEC(pAC->I2c.SenTable[Index].
2965 SenBegErrTS);
2966 SK_PNMI_STORE_U64(pBuf + Offset, Val64);
2967 Offset += sizeof(SK_U64);
2968 break;
2969
2970 default:
2971 SK_DBG_MSG(pAC, SK_DBGMOD_PNMI, SK_DBGCAT_ERR,
2972 ("SensorStat: Unknown OID should be handled before"));
2973
2974 return (SK_PNMI_ERR_GENERAL);
2975 }
2976 }
2977
2978 /*
2979 * Store used buffer space
2980 */
2981 *pLen = Offset;
2982
2983 return (SK_PNMI_ERR_OK);
2984}
2985
2986/*****************************************************************************
2987 *
2988 * Vpd - OID handler function of OID_SKGE_VPD_XXX
2989 *
2990 * Description:
2991 * Get/preset/set of VPD data. As instance the name of a VPD key
2992 * can be passed. The Instance parameter is a SK_U32 and can be
2993 * used as a string buffer for the VPD key, because their maximum
2994 * length is 4 byte.
2995 *
2996 * Returns:
2997 * SK_PNMI_ERR_OK The request was successfully performed.
2998 * SK_PNMI_ERR_GENERAL A general severe internal error occured.
2999 * SK_PNMI_ERR_TOO_SHORT The passed buffer is too short to contain
3000 * the correct data (e.g. a 32bit value is
3001 * needed, but a 16 bit value was passed).
3002 * SK_PNMI_ERR_BAD_VALUE The passed value is not in the valid
3003 * value range.
3004 * SK_PNMI_ERR_READ_ONLY The OID is read-only and cannot be set.
3005 * SK_PNMI_ERR_UNKNOWN_INST The requested instance of the OID doesn't
3006 * exist (e.g. port instance 3 on a two port
3007 * adapter.
3008 */
3009PNMI_STATIC int Vpd(
3010SK_AC *pAC, /* Pointer to adapter context */
3011SK_IOC IoC, /* IO context handle */
3012int Action, /* GET/PRESET/SET action */
3013SK_U32 Id, /* Object ID that is to be processed */
3014char *pBuf, /* Buffer used for the management data transfer */
3015unsigned int *pLen, /* On call: pBuf buffer length. On return: used buffer */
3016SK_U32 Instance, /* Instance (1..n) that is to be queried or -1 */
3017unsigned int TableIndex, /* Index to the Id table */
3018SK_U32 NetIndex) /* NetIndex (0..n), in single net mode always zero */
3019{
3020 SK_VPD_STATUS *pVpdStatus;
3021 unsigned int BufLen;
3022 char Buf[256];
3023 char KeyArr[SK_PNMI_VPD_ENTRIES][SK_PNMI_VPD_KEY_SIZE];
3024 char KeyStr[SK_PNMI_VPD_KEY_SIZE];
3025 unsigned int KeyNo;
3026 unsigned int Offset;
3027 unsigned int Index;
3028 unsigned int FirstIndex;
3029 unsigned int LastIndex;
3030 unsigned int Len;
3031 int Ret;
3032 SK_U32 Val32;
3033
3034 /*
3035 * Get array of all currently stored VPD keys
3036 */
3037 Ret = GetVpdKeyArr(pAC, IoC, &KeyArr[0][0], sizeof(KeyArr), &KeyNo);
3038 if (Ret != SK_PNMI_ERR_OK) {
3039 *pLen = 0;
3040 return (Ret);
3041 }
3042
3043 /*
3044 * If instance is not -1, try to find the requested VPD key for
3045 * the multiple instance variables. The other OIDs as for example
3046 * OID VPD_ACTION are single instance variables and must be
3047 * handled separatly.
3048 */
3049 FirstIndex = 0;
3050 LastIndex = KeyNo;
3051
3052 if ((Instance != (SK_U32)(-1))) {
3053
3054 if (Id == OID_SKGE_VPD_KEY || Id == OID_SKGE_VPD_VALUE ||
3055 Id == OID_SKGE_VPD_ACCESS) {
3056
3057 SK_STRNCPY(KeyStr, (char *)&Instance, 4);
3058 KeyStr[4] = 0;
3059
3060 for (Index = 0; Index < KeyNo; Index ++) {
3061
3062 if (SK_STRCMP(KeyStr, KeyArr[Index]) == 0) {
3063 FirstIndex = Index;
3064 LastIndex = Index+1;
3065 break;
3066 }
3067 }
3068 if (Index == KeyNo) {
3069
3070 *pLen = 0;
3071 return (SK_PNMI_ERR_UNKNOWN_INST);
3072 }
3073 }
3074 else if (Instance != 1) {
3075
3076 *pLen = 0;
3077 return (SK_PNMI_ERR_UNKNOWN_INST);
3078 }
3079 }
3080
3081 /*
3082 * Get value, if a query should be performed
3083 */
3084 if (Action == SK_PNMI_GET) {
3085
3086 switch (Id) {
3087
3088 case OID_SKGE_VPD_FREE_BYTES:
3089 /* Check length of buffer */
3090 if (*pLen < sizeof(SK_U32)) {
3091
3092 *pLen = sizeof(SK_U32);
3093 return (SK_PNMI_ERR_TOO_SHORT);
3094 }
3095 /* Get number of free bytes */
3096 pVpdStatus = VpdStat(pAC, IoC);
3097 if (pVpdStatus == NULL) {
3098
3099 SK_ERR_LOG(pAC, SK_ERRCL_SW, SK_PNMI_ERR017,
3100 SK_PNMI_ERR017MSG);
3101
3102 *pLen = 0;
3103 return (SK_PNMI_ERR_GENERAL);
3104 }
3105 if ((pVpdStatus->vpd_status & VPD_VALID) == 0) {
3106
3107 SK_ERR_LOG(pAC, SK_ERRCL_SW, SK_PNMI_ERR018,
3108 SK_PNMI_ERR018MSG);
3109
3110 *pLen = 0;
3111 return (SK_PNMI_ERR_GENERAL);
3112 }
3113
3114 Val32 = (SK_U32)pVpdStatus->vpd_free_rw;
3115 SK_PNMI_STORE_U32(pBuf, Val32);
3116 *pLen = sizeof(SK_U32);
3117 break;
3118
3119 case OID_SKGE_VPD_ENTRIES_LIST:
3120 /* Check length */
3121 for (Len = 0, Index = 0; Index < KeyNo; Index ++) {
3122
3123 Len += SK_STRLEN(KeyArr[Index]) + 1;
3124 }
3125 if (*pLen < Len) {
3126
3127 *pLen = Len;
3128 return (SK_PNMI_ERR_TOO_SHORT);
3129 }
3130
3131 /* Get value */
3132 *(pBuf) = (char)Len - 1;
3133 for (Offset = 1, Index = 0; Index < KeyNo; Index ++) {
3134
3135 Len = SK_STRLEN(KeyArr[Index]);
3136 SK_MEMCPY(pBuf + Offset, KeyArr[Index], Len);
3137
3138 Offset += Len;
3139
3140 if (Index < KeyNo - 1) {
3141
3142 *(pBuf + Offset) = ' ';
3143 Offset ++;
3144 }
3145 }
3146 *pLen = Offset;
3147 break;
3148
3149 case OID_SKGE_VPD_ENTRIES_NUMBER:
3150 /* Check length */
3151 if (*pLen < sizeof(SK_U32)) {
3152
3153 *pLen = sizeof(SK_U32);
3154 return (SK_PNMI_ERR_TOO_SHORT);
3155 }
3156
3157 Val32 = (SK_U32)KeyNo;
3158 SK_PNMI_STORE_U32(pBuf, Val32);
3159 *pLen = sizeof(SK_U32);
3160 break;
3161
3162 case OID_SKGE_VPD_KEY:
3163 /* Check buffer length, if it is large enough */
3164 for (Len = 0, Index = FirstIndex;
3165 Index < LastIndex; Index ++) {
3166
3167 Len += SK_STRLEN(KeyArr[Index]) + 1;
3168 }
3169 if (*pLen < Len) {
3170
3171 *pLen = Len;
3172 return (SK_PNMI_ERR_TOO_SHORT);
3173 }
3174
3175 /*
3176 * Get the key to an intermediate buffer, because
3177 * we have to prepend a length byte.
3178 */
3179 for (Offset = 0, Index = FirstIndex;
3180 Index < LastIndex; Index ++) {
3181
3182 Len = SK_STRLEN(KeyArr[Index]);
3183
3184 *(pBuf + Offset) = (char)Len;
3185 SK_MEMCPY(pBuf + Offset + 1, KeyArr[Index],
3186 Len);
3187 Offset += Len + 1;
3188 }
3189 *pLen = Offset;
3190 break;
3191
3192 case OID_SKGE_VPD_VALUE:
3193 /* Check the buffer length if it is large enough */
3194 for (Offset = 0, Index = FirstIndex;
3195 Index < LastIndex; Index ++) {
3196
3197 BufLen = 256;
3198 if (VpdRead(pAC, IoC, KeyArr[Index], Buf,
3199 (int *)&BufLen) > 0 ||
3200 BufLen >= SK_PNMI_VPD_DATALEN) {
3201
3202 SK_ERR_LOG(pAC, SK_ERRCL_SW,
3203 SK_PNMI_ERR021,
3204 SK_PNMI_ERR021MSG);
3205
3206 return (SK_PNMI_ERR_GENERAL);
3207 }
3208 Offset += BufLen + 1;
3209 }
3210 if (*pLen < Offset) {
3211
3212 *pLen = Offset;
3213 return (SK_PNMI_ERR_TOO_SHORT);
3214 }
3215
3216 /*
3217 * Get the value to an intermediate buffer, because
3218 * we have to prepend a length byte.
3219 */
3220 for (Offset = 0, Index = FirstIndex;
3221 Index < LastIndex; Index ++) {
3222
3223 BufLen = 256;
3224 if (VpdRead(pAC, IoC, KeyArr[Index], Buf,
3225 (int *)&BufLen) > 0 ||
3226 BufLen >= SK_PNMI_VPD_DATALEN) {
3227
3228 SK_ERR_LOG(pAC, SK_ERRCL_SW,
3229 SK_PNMI_ERR022,
3230 SK_PNMI_ERR022MSG);
3231
3232 *pLen = 0;
3233 return (SK_PNMI_ERR_GENERAL);
3234 }
3235
3236 *(pBuf + Offset) = (char)BufLen;
3237 SK_MEMCPY(pBuf + Offset + 1, Buf, BufLen);
3238 Offset += BufLen + 1;
3239 }
3240 *pLen = Offset;
3241 break;
3242
3243 case OID_SKGE_VPD_ACCESS:
3244 if (*pLen < LastIndex - FirstIndex) {
3245
3246 *pLen = LastIndex - FirstIndex;
3247 return (SK_PNMI_ERR_TOO_SHORT);
3248 }
3249
3250 for (Offset = 0, Index = FirstIndex;
3251 Index < LastIndex; Index ++) {
3252
3253 if (VpdMayWrite(KeyArr[Index])) {
3254
3255 *(pBuf + Offset) = SK_PNMI_VPD_RW;
3256 }
3257 else {
3258 *(pBuf + Offset) = SK_PNMI_VPD_RO;
3259 }
3260 Offset ++;
3261 }
3262 *pLen = Offset;
3263 break;
3264
3265 case OID_SKGE_VPD_ACTION:
3266 Offset = LastIndex - FirstIndex;
3267 if (*pLen < Offset) {
3268
3269 *pLen = Offset;
3270 return (SK_PNMI_ERR_TOO_SHORT);
3271 }
3272 SK_MEMSET(pBuf, 0, Offset);
3273 *pLen = Offset;
3274 break;
3275
3276 default:
3277 SK_ERR_LOG(pAC, SK_ERRCL_SW, SK_PNMI_ERR023,
3278 SK_PNMI_ERR023MSG);
3279
3280 *pLen = 0;
3281 return (SK_PNMI_ERR_GENERAL);
3282 }
3283 }
3284 else {
3285 /* The only OID which can be set is VPD_ACTION */
3286 if (Id != OID_SKGE_VPD_ACTION) {
3287
3288 if (Id == OID_SKGE_VPD_FREE_BYTES ||
3289 Id == OID_SKGE_VPD_ENTRIES_LIST ||
3290 Id == OID_SKGE_VPD_ENTRIES_NUMBER ||
3291 Id == OID_SKGE_VPD_KEY ||
3292 Id == OID_SKGE_VPD_VALUE ||
3293 Id == OID_SKGE_VPD_ACCESS) {
3294
3295 *pLen = 0;
3296 return (SK_PNMI_ERR_READ_ONLY);
3297 }
3298
3299 SK_ERR_LOG(pAC, SK_ERRCL_SW, SK_PNMI_ERR024,
3300 SK_PNMI_ERR024MSG);
3301
3302 *pLen = 0;
3303 return (SK_PNMI_ERR_GENERAL);
3304 }
3305
3306 /*
3307 * From this point we handle VPD_ACTION. Check the buffer
3308 * length. It should at least have the size of one byte.
3309 */
3310 if (*pLen < 1) {
3311
3312 *pLen = 1;
3313 return (SK_PNMI_ERR_TOO_SHORT);
3314 }
3315
3316 /*
3317 * The first byte contains the VPD action type we should
3318 * perform.
3319 */
3320 switch (*pBuf) {
3321
3322 case SK_PNMI_VPD_IGNORE:
3323 /* Nothing to do */
3324 break;
3325
3326 case SK_PNMI_VPD_CREATE:
3327 /*
3328 * We have to create a new VPD entry or we modify
3329 * an existing one. Check first the buffer length.
3330 */
3331 if (*pLen < 4) {
3332
3333 *pLen = 4;
3334 return (SK_PNMI_ERR_TOO_SHORT);
3335 }
3336 KeyStr[0] = pBuf[1];
3337 KeyStr[1] = pBuf[2];
3338 KeyStr[2] = 0;
3339
3340 /*
3341 * Is the entry writable or does it belong to the
3342 * read-only area?
3343 */
3344 if (!VpdMayWrite(KeyStr)) {
3345
3346 *pLen = 0;
3347 return (SK_PNMI_ERR_BAD_VALUE);
3348 }
3349
3350 Offset = (int)pBuf[3] & 0xFF;
3351
3352 SK_MEMCPY(Buf, pBuf + 4, Offset);
3353 Buf[Offset] = 0;
3354
3355 /* A preset ends here */
3356 if (Action == SK_PNMI_PRESET) {
3357
3358 return (SK_PNMI_ERR_OK);
3359 }
3360
3361 /* Write the new entry or modify an existing one */
3362 Ret = VpdWrite(pAC, IoC, KeyStr, Buf);
3363 if (Ret == SK_PNMI_VPD_NOWRITE ) {
3364
3365 *pLen = 0;
3366 return (SK_PNMI_ERR_BAD_VALUE);
3367 }
3368 else if (Ret != SK_PNMI_VPD_OK) {
3369
3370 SK_ERR_LOG(pAC, SK_ERRCL_SW, SK_PNMI_ERR025,
3371 SK_PNMI_ERR025MSG);
3372
3373 *pLen = 0;
3374 return (SK_PNMI_ERR_GENERAL);
3375 }
3376
3377 /*
3378 * Perform an update of the VPD data. This is
3379 * not mandantory, but just to be sure.
3380 */
3381 Ret = VpdUpdate(pAC, IoC);
3382 if (Ret != SK_PNMI_VPD_OK) {
3383
3384 SK_ERR_LOG(pAC, SK_ERRCL_SW, SK_PNMI_ERR026,
3385 SK_PNMI_ERR026MSG);
3386
3387 *pLen = 0;
3388 return (SK_PNMI_ERR_GENERAL);
3389 }
3390 break;
3391
3392 case SK_PNMI_VPD_DELETE:
3393 /* Check if the buffer size is plausible */
3394 if (*pLen < 3) {
3395
3396 *pLen = 3;
3397 return (SK_PNMI_ERR_TOO_SHORT);
3398 }
3399 if (*pLen > 3) {
3400
3401 *pLen = 0;
3402 return (SK_PNMI_ERR_BAD_VALUE);
3403 }
3404 KeyStr[0] = pBuf[1];
3405 KeyStr[1] = pBuf[2];
3406 KeyStr[2] = 0;
3407
3408 /* Find the passed key in the array */
3409 for (Index = 0; Index < KeyNo; Index ++) {
3410
3411 if (SK_STRCMP(KeyStr, KeyArr[Index]) == 0) {
3412
3413 break;
3414 }
3415 }
3416 /*
3417 * If we cannot find the key it is wrong, so we
3418 * return an appropriate error value.
3419 */
3420 if (Index == KeyNo) {
3421
3422 *pLen = 0;
3423 return (SK_PNMI_ERR_BAD_VALUE);
3424 }
3425
3426 if (Action == SK_PNMI_PRESET) {
3427
3428 return (SK_PNMI_ERR_OK);
3429 }
3430
3431 /* Ok, you wanted it and you will get it */
3432 Ret = VpdDelete(pAC, IoC, KeyStr);
3433 if (Ret != SK_PNMI_VPD_OK) {
3434
3435 SK_ERR_LOG(pAC, SK_ERRCL_SW, SK_PNMI_ERR027,
3436 SK_PNMI_ERR027MSG);
3437
3438 *pLen = 0;
3439 return (SK_PNMI_ERR_GENERAL);
3440 }
3441
3442 /*
3443 * Perform an update of the VPD data. This is
3444 * not mandantory, but just to be sure.
3445 */
3446 Ret = VpdUpdate(pAC, IoC);
3447 if (Ret != SK_PNMI_VPD_OK) {
3448
3449 SK_ERR_LOG(pAC, SK_ERRCL_SW, SK_PNMI_ERR028,
3450 SK_PNMI_ERR028MSG);
3451
3452 *pLen = 0;
3453 return (SK_PNMI_ERR_GENERAL);
3454 }
3455 break;
3456
3457 default:
3458 *pLen = 0;
3459 return (SK_PNMI_ERR_BAD_VALUE);
3460 }
3461 }
3462
3463 return (SK_PNMI_ERR_OK);
3464}
3465
3466/*****************************************************************************
3467 *
3468 * General - OID handler function of various single instance OIDs
3469 *
3470 * Description:
3471 * The code is simple. No description necessary.
3472 *
3473 * Returns:
3474 * SK_PNMI_ERR_OK The request was successfully performed.
3475 * SK_PNMI_ERR_GENERAL A general severe internal error occured.
3476 * SK_PNMI_ERR_TOO_SHORT The passed buffer is too short to contain
3477 * the correct data (e.g. a 32bit value is
3478 * needed, but a 16 bit value was passed).
3479 * SK_PNMI_ERR_UNKNOWN_INST The requested instance of the OID doesn't
3480 * exist (e.g. port instance 3 on a two port
3481 * adapter.
3482 */
3483PNMI_STATIC int General(
3484SK_AC *pAC, /* Pointer to adapter context */
3485SK_IOC IoC, /* IO context handle */
3486int Action, /* GET/PRESET/SET action */
3487SK_U32 Id, /* Object ID that is to be processed */
3488char *pBuf, /* Buffer used for the management data transfer */
3489unsigned int *pLen, /* On call: buffer length. On return: used buffer */
3490SK_U32 Instance, /* Instance (1..n) that is to be queried or -1 */
3491unsigned int TableIndex, /* Index to the Id table */
3492SK_U32 NetIndex) /* NetIndex (0..n), in single net mode always zero */
3493{
3494 int Ret;
3495 unsigned int Index;
3496 unsigned int Len;
3497 unsigned int Offset;
3498 unsigned int Val;
3499 SK_U8 Val8;
3500 SK_U16 Val16;
3501 SK_U32 Val32;
3502 SK_U64 Val64;
3503 SK_U64 Val64RxHwErrs = 0;
3504 SK_U64 Val64TxHwErrs = 0;
3505 SK_BOOL Is64BitReq = SK_FALSE;
3506 char Buf[256];
3507 int MacType;
3508
3509 /*
3510 * Check instance. We only handle single instance variables.
3511 */
3512 if (Instance != (SK_U32)(-1) && Instance != 1) {
3513
3514 *pLen = 0;
3515 return (SK_PNMI_ERR_UNKNOWN_INST);
3516 }
3517
3518 /*
3519 * Check action. We only allow get requests.
3520 */
3521 if (Action != SK_PNMI_GET) {
3522
3523 *pLen = 0;
3524 return (SK_PNMI_ERR_READ_ONLY);
3525 }
3526
3527 MacType = pAC->GIni.GIMacType;
3528
3529 /*
3530 * Check length for the various supported OIDs
3531 */
3532 switch (Id) {
3533
3534 case OID_GEN_XMIT_ERROR:
3535 case OID_GEN_RCV_ERROR:
3536 case OID_GEN_RCV_NO_BUFFER:
3537#ifndef SK_NDIS_64BIT_CTR
3538 if (*pLen < sizeof(SK_U32)) {
3539 *pLen = sizeof(SK_U32);
3540 return (SK_PNMI_ERR_TOO_SHORT);
3541 }
3542
3543#else /* SK_NDIS_64BIT_CTR */
3544
3545 /*
3546 * for compatibility, at least 32bit are required for oid
3547 */
3548 if (*pLen < sizeof(SK_U32)) {
3549 /*
3550 * but indicate handling for 64bit values,
3551 * if insufficient space is provided
3552 */
3553 *pLen = sizeof(SK_U64);
3554 return (SK_PNMI_ERR_TOO_SHORT);
3555 }
3556
3557 Is64BitReq = (*pLen < sizeof(SK_U64)) ? SK_FALSE : SK_TRUE;
3558#endif /* SK_NDIS_64BIT_CTR */
3559 break;
3560
3561 case OID_SKGE_PORT_NUMBER:
3562 case OID_SKGE_DEVICE_TYPE:
3563 case OID_SKGE_RESULT:
3564 case OID_SKGE_RLMT_MONITOR_NUMBER:
3565 case OID_GEN_TRANSMIT_QUEUE_LENGTH:
3566 case OID_SKGE_TRAP_NUMBER:
3567 case OID_SKGE_MDB_VERSION:
3568 case OID_SKGE_BOARDLEVEL:
3569 case OID_SKGE_CHIPID:
3570 case OID_SKGE_RAMSIZE:
3571 if (*pLen < sizeof(SK_U32)) {
3572
3573 *pLen = sizeof(SK_U32);
3574 return (SK_PNMI_ERR_TOO_SHORT);
3575 }
3576 break;
3577
3578 case OID_SKGE_CHIPSET:
3579 if (*pLen < sizeof(SK_U16)) {
3580
3581 *pLen = sizeof(SK_U16);
3582 return (SK_PNMI_ERR_TOO_SHORT);
3583 }
3584 break;
3585
3586 case OID_SKGE_BUS_TYPE:
3587 case OID_SKGE_BUS_SPEED:
3588 case OID_SKGE_BUS_WIDTH:
3589 case OID_SKGE_SENSOR_NUMBER:
3590 case OID_SKGE_CHKSM_NUMBER:
3591 case OID_SKGE_VAUXAVAIL:
3592 if (*pLen < sizeof(SK_U8)) {
3593
3594 *pLen = sizeof(SK_U8);
3595 return (SK_PNMI_ERR_TOO_SHORT);
3596 }
3597 break;
3598
3599 case OID_SKGE_TX_SW_QUEUE_LEN:
3600 case OID_SKGE_TX_SW_QUEUE_MAX:
3601 case OID_SKGE_TX_RETRY:
3602 case OID_SKGE_RX_INTR_CTS:
3603 case OID_SKGE_TX_INTR_CTS:
3604 case OID_SKGE_RX_NO_BUF_CTS:
3605 case OID_SKGE_TX_NO_BUF_CTS:
3606 case OID_SKGE_TX_USED_DESCR_NO:
3607 case OID_SKGE_RX_DELIVERED_CTS:
3608 case OID_SKGE_RX_OCTETS_DELIV_CTS:
3609 case OID_SKGE_RX_HW_ERROR_CTS:
3610 case OID_SKGE_TX_HW_ERROR_CTS:
3611 case OID_SKGE_IN_ERRORS_CTS:
3612 case OID_SKGE_OUT_ERROR_CTS:
3613 case OID_SKGE_ERR_RECOVERY_CTS:
3614 case OID_SKGE_SYSUPTIME:
3615 if (*pLen < sizeof(SK_U64)) {
3616
3617 *pLen = sizeof(SK_U64);
3618 return (SK_PNMI_ERR_TOO_SHORT);
3619 }
3620 break;
3621
3622 default:
3623 /* Checked later */
3624 break;
3625 }
3626
3627 /* Update statistic */
3628 if (Id == OID_SKGE_RX_HW_ERROR_CTS ||
3629 Id == OID_SKGE_TX_HW_ERROR_CTS ||
3630 Id == OID_SKGE_IN_ERRORS_CTS ||
3631 Id == OID_SKGE_OUT_ERROR_CTS ||
3632 Id == OID_GEN_XMIT_ERROR ||
3633 Id == OID_GEN_RCV_ERROR) {
3634
3635 /* Force the XMAC to update its statistic counters and
3636 * Increment semaphore to indicate that an update was
3637 * already done.
3638 */
3639 Ret = MacUpdate(pAC, IoC, 0, pAC->GIni.GIMacsFound - 1);
3640 if (Ret != SK_PNMI_ERR_OK) {
3641
3642 *pLen = 0;
3643 return (Ret);
3644 }
3645 pAC->Pnmi.MacUpdatedFlag ++;
3646
3647 /*
3648 * Some OIDs consist of multiple hardware counters. Those
3649 * values which are contained in all of them will be added
3650 * now.
3651 */
3652 switch (Id) {
3653
3654 case OID_SKGE_RX_HW_ERROR_CTS:
3655 case OID_SKGE_IN_ERRORS_CTS:
3656 case OID_GEN_RCV_ERROR:
3657 Val64RxHwErrs =
3658 GetStatVal(pAC, IoC, 0, SK_PNMI_HRX_MISSED, NetIndex) +
3659 GetStatVal(pAC, IoC, 0, SK_PNMI_HRX_FRAMING, NetIndex) +
3660 GetStatVal(pAC, IoC, 0, SK_PNMI_HRX_OVERFLOW, NetIndex) +
3661 GetStatVal(pAC, IoC, 0, SK_PNMI_HRX_JABBER, NetIndex) +
3662 GetStatVal(pAC, IoC, 0, SK_PNMI_HRX_CARRIER, NetIndex) +
3663 GetStatVal(pAC, IoC, 0, SK_PNMI_HRX_IRLENGTH, NetIndex) +
3664 GetStatVal(pAC, IoC, 0, SK_PNMI_HRX_SYMBOL, NetIndex) +
3665 GetStatVal(pAC, IoC, 0, SK_PNMI_HRX_SHORTS, NetIndex) +
3666 GetStatVal(pAC, IoC, 0, SK_PNMI_HRX_RUNT, NetIndex) +
3667 GetStatVal(pAC, IoC, 0, SK_PNMI_HRX_TOO_LONG, NetIndex) +
3668 GetStatVal(pAC, IoC, 0, SK_PNMI_HRX_FCS, NetIndex) +
3669 GetStatVal(pAC, IoC, 0, SK_PNMI_HRX_CEXT, NetIndex);
3670 break;
3671
3672 case OID_SKGE_TX_HW_ERROR_CTS:
3673 case OID_SKGE_OUT_ERROR_CTS:
3674 case OID_GEN_XMIT_ERROR:
3675 Val64TxHwErrs =
3676 GetStatVal(pAC, IoC, 0, SK_PNMI_HTX_EXCESS_COL, NetIndex) +
3677 GetStatVal(pAC, IoC, 0, SK_PNMI_HTX_LATE_COL, NetIndex) +
3678 GetStatVal(pAC, IoC, 0, SK_PNMI_HTX_UNDERRUN, NetIndex) +
3679 GetStatVal(pAC, IoC, 0, SK_PNMI_HTX_CARRIER, NetIndex);
3680 break;
3681 }
3682 }
3683
3684 /*
3685 * Retrieve value
3686 */
3687 switch (Id) {
3688
3689 case OID_SKGE_SUPPORTED_LIST:
3690 Len = ID_TABLE_SIZE * sizeof(SK_U32);
3691 if (*pLen < Len) {
3692
3693 *pLen = Len;
3694 return (SK_PNMI_ERR_TOO_SHORT);
3695 }
3696 for (Offset = 0, Index = 0; Offset < Len;
3697 Offset += sizeof(SK_U32), Index ++) {
3698
3699 Val32 = (SK_U32)IdTable[Index].Id;
3700 SK_PNMI_STORE_U32(pBuf + Offset, Val32);
3701 }
3702 *pLen = Len;
3703 break;
3704
3705 case OID_SKGE_BOARDLEVEL:
3706 Val32 = (SK_U32)pAC->GIni.GILevel;
3707 SK_PNMI_STORE_U32(pBuf, Val32);
3708 *pLen = sizeof(SK_U32);
3709 break;
3710
3711 case OID_SKGE_PORT_NUMBER:
3712 Val32 = (SK_U32)pAC->GIni.GIMacsFound;
3713 SK_PNMI_STORE_U32(pBuf, Val32);
3714 *pLen = sizeof(SK_U32);
3715 break;
3716
3717 case OID_SKGE_DEVICE_TYPE:
3718 Val32 = (SK_U32)pAC->Pnmi.DeviceType;
3719 SK_PNMI_STORE_U32(pBuf, Val32);
3720 *pLen = sizeof(SK_U32);
3721 break;
3722
3723 case OID_SKGE_DRIVER_DESCR:
3724 if (pAC->Pnmi.pDriverDescription == NULL) {
3725
3726 SK_ERR_LOG(pAC, SK_ERRCL_SW, SK_PNMI_ERR007,
3727 SK_PNMI_ERR007MSG);
3728
3729 *pLen = 0;
3730 return (SK_PNMI_ERR_GENERAL);
3731 }
3732
3733 Len = SK_STRLEN(pAC->Pnmi.pDriverDescription) + 1;
3734 if (Len > SK_PNMI_STRINGLEN1) {
3735
3736 SK_ERR_LOG(pAC, SK_ERRCL_SW, SK_PNMI_ERR029,
3737 SK_PNMI_ERR029MSG);
3738
3739 *pLen = 0;
3740 return (SK_PNMI_ERR_GENERAL);
3741 }
3742
3743 if (*pLen < Len) {
3744
3745 *pLen = Len;
3746 return (SK_PNMI_ERR_TOO_SHORT);
3747 }
3748 *pBuf = (char)(Len - 1);
3749 SK_MEMCPY(pBuf + 1, pAC->Pnmi.pDriverDescription, Len - 1);
3750 *pLen = Len;
3751 break;
3752
3753 case OID_SKGE_DRIVER_VERSION:
3754 if (pAC->Pnmi.pDriverVersion == NULL) {
3755
3756 SK_ERR_LOG(pAC, SK_ERRCL_SW, SK_PNMI_ERR030,
3757 SK_PNMI_ERR030MSG);
3758
3759 *pLen = 0;
3760 return (SK_PNMI_ERR_GENERAL);
3761 }
3762
3763 Len = SK_STRLEN(pAC->Pnmi.pDriverVersion) + 1;
3764 if (Len > SK_PNMI_STRINGLEN1) {
3765
3766 SK_ERR_LOG(pAC, SK_ERRCL_SW, SK_PNMI_ERR031,
3767 SK_PNMI_ERR031MSG);
3768
3769 *pLen = 0;
3770 return (SK_PNMI_ERR_GENERAL);
3771 }
3772
3773 if (*pLen < Len) {
3774
3775 *pLen = Len;
3776 return (SK_PNMI_ERR_TOO_SHORT);
3777 }
3778 *pBuf = (char)(Len - 1);
3779 SK_MEMCPY(pBuf + 1, pAC->Pnmi.pDriverVersion, Len - 1);
3780 *pLen = Len;
3781 break;
3782
3783 case OID_SKGE_DRIVER_RELDATE:
3784 if (pAC->Pnmi.pDriverReleaseDate == NULL) {
3785
3786 SK_ERR_LOG(pAC, SK_ERRCL_SW, SK_PNMI_ERR030,
3787 SK_PNMI_ERR053MSG);
3788
3789 *pLen = 0;
3790 return (SK_PNMI_ERR_GENERAL);
3791 }
3792
3793 Len = SK_STRLEN(pAC->Pnmi.pDriverReleaseDate) + 1;
3794 if (Len > SK_PNMI_STRINGLEN1) {
3795
3796 SK_ERR_LOG(pAC, SK_ERRCL_SW, SK_PNMI_ERR031,
3797 SK_PNMI_ERR054MSG);
3798
3799 *pLen = 0;
3800 return (SK_PNMI_ERR_GENERAL);
3801 }
3802
3803 if (*pLen < Len) {
3804
3805 *pLen = Len;
3806 return (SK_PNMI_ERR_TOO_SHORT);
3807 }
3808 *pBuf = (char)(Len - 1);
3809 SK_MEMCPY(pBuf + 1, pAC->Pnmi.pDriverReleaseDate, Len - 1);
3810 *pLen = Len;
3811 break;
3812
3813 case OID_SKGE_DRIVER_FILENAME:
3814 if (pAC->Pnmi.pDriverFileName == NULL) {
3815
3816 SK_ERR_LOG(pAC, SK_ERRCL_SW, SK_PNMI_ERR030,
3817 SK_PNMI_ERR055MSG);
3818
3819 *pLen = 0;
3820 return (SK_PNMI_ERR_GENERAL);
3821 }
3822
3823 Len = SK_STRLEN(pAC->Pnmi.pDriverFileName) + 1;
3824 if (Len > SK_PNMI_STRINGLEN1) {
3825
3826 SK_ERR_LOG(pAC, SK_ERRCL_SW, SK_PNMI_ERR031,
3827 SK_PNMI_ERR056MSG);
3828
3829 *pLen = 0;
3830 return (SK_PNMI_ERR_GENERAL);
3831 }
3832
3833 if (*pLen < Len) {
3834
3835 *pLen = Len;
3836 return (SK_PNMI_ERR_TOO_SHORT);
3837 }
3838 *pBuf = (char)(Len - 1);
3839 SK_MEMCPY(pBuf + 1, pAC->Pnmi.pDriverFileName, Len - 1);
3840 *pLen = Len;
3841 break;
3842
3843 case OID_SKGE_HW_DESCR:
3844 /*
3845 * The hardware description is located in the VPD. This
3846 * query may move to the initialisation routine. But
3847 * the VPD data is cached and therefore a call here
3848 * will not make much difference.
3849 */
3850 Len = 256;
3851 if (VpdRead(pAC, IoC, VPD_NAME, Buf, (int *)&Len) > 0) {
3852
3853 SK_ERR_LOG(pAC, SK_ERRCL_SW, SK_PNMI_ERR032,
3854 SK_PNMI_ERR032MSG);
3855
3856 *pLen = 0;
3857 return (SK_PNMI_ERR_GENERAL);
3858 }
3859 Len ++;
3860 if (Len > SK_PNMI_STRINGLEN1) {
3861
3862 SK_ERR_LOG(pAC, SK_ERRCL_SW, SK_PNMI_ERR033,
3863 SK_PNMI_ERR033MSG);
3864
3865 *pLen = 0;
3866 return (SK_PNMI_ERR_GENERAL);
3867 }
3868 if (*pLen < Len) {
3869
3870 *pLen = Len;
3871 return (SK_PNMI_ERR_TOO_SHORT);
3872 }
3873 *pBuf = (char)(Len - 1);
3874 SK_MEMCPY(pBuf + 1, Buf, Len - 1);
3875 *pLen = Len;
3876 break;
3877
3878 case OID_SKGE_HW_VERSION:
3879 /* Oh, I love to do some string manipulation */
3880 if (*pLen < 5) {
3881
3882 *pLen = 5;
3883 return (SK_PNMI_ERR_TOO_SHORT);
3884 }
3885 Val8 = (SK_U8)pAC->GIni.GIPciHwRev;
3886 pBuf[0] = 4;
3887 pBuf[1] = 'v';
3888 pBuf[2] = (char)(0x30 | ((Val8 >> 4) & 0x0F));
3889 pBuf[3] = '.';
3890 pBuf[4] = (char)(0x30 | (Val8 & 0x0F));
3891 *pLen = 5;
3892 break;
3893
3894 case OID_SKGE_CHIPSET:
3895 Val16 = pAC->Pnmi.Chipset;
3896 SK_PNMI_STORE_U16(pBuf, Val16);
3897 *pLen = sizeof(SK_U16);
3898 break;
3899
3900 case OID_SKGE_CHIPID:
3901 Val32 = pAC->GIni.GIChipId;
3902 SK_PNMI_STORE_U32(pBuf, Val32);
3903 *pLen = sizeof(SK_U32);
3904 break;
3905
3906 case OID_SKGE_RAMSIZE:
3907 Val32 = pAC->GIni.GIRamSize;
3908 SK_PNMI_STORE_U32(pBuf, Val32);
3909 *pLen = sizeof(SK_U32);
3910 break;
3911
3912 case OID_SKGE_VAUXAVAIL:
3913 *pBuf = (char) pAC->GIni.GIVauxAvail;
3914 *pLen = sizeof(char);
3915 break;
3916
3917 case OID_SKGE_BUS_TYPE:
3918 *pBuf = (char) SK_PNMI_BUS_PCI;
3919 *pLen = sizeof(char);
3920 break;
3921
3922 case OID_SKGE_BUS_SPEED:
3923 *pBuf = pAC->Pnmi.PciBusSpeed;
3924 *pLen = sizeof(char);
3925 break;
3926
3927 case OID_SKGE_BUS_WIDTH:
3928 *pBuf = pAC->Pnmi.PciBusWidth;
3929 *pLen = sizeof(char);
3930 break;
3931
3932 case OID_SKGE_RESULT:
3933 Val32 = pAC->Pnmi.TestResult;
3934 SK_PNMI_STORE_U32(pBuf, Val32);
3935 *pLen = sizeof(SK_U32);
3936 break;
3937
3938 case OID_SKGE_SENSOR_NUMBER:
3939 *pBuf = (char)pAC->I2c.MaxSens;
3940 *pLen = sizeof(char);
3941 break;
3942
3943 case OID_SKGE_CHKSM_NUMBER:
3944 *pBuf = SKCS_NUM_PROTOCOLS;
3945 *pLen = sizeof(char);
3946 break;
3947
3948 case OID_SKGE_TRAP_NUMBER:
3949 GetTrapQueueLen(pAC, &Len, &Val);
3950 Val32 = (SK_U32)Val;
3951 SK_PNMI_STORE_U32(pBuf, Val32);
3952 *pLen = sizeof(SK_U32);
3953 break;
3954
3955 case OID_SKGE_TRAP:
3956 GetTrapQueueLen(pAC, &Len, &Val);
3957 if (*pLen < Len) {
3958
3959 *pLen = Len;
3960 return (SK_PNMI_ERR_TOO_SHORT);
3961 }
3962 CopyTrapQueue(pAC, pBuf);
3963 *pLen = Len;
3964 break;
3965
3966 case OID_SKGE_RLMT_MONITOR_NUMBER:
3967/* XXX Not yet implemented by RLMT therefore we return zero elements */
3968 Val32 = 0;
3969 SK_PNMI_STORE_U32(pBuf, Val32);
3970 *pLen = sizeof(SK_U32);
3971 break;
3972
3973 case OID_SKGE_TX_SW_QUEUE_LEN:
3974 /* 2002-09-17 pweber: For XMAC, use the frozen SW counters (BufPort) */
3975 if (MacType == SK_MAC_XMAC) {
3976 /* Dual net mode */
3977 if (pAC->Pnmi.DualNetActiveFlag == SK_TRUE) {
3978 Val64 = pAC->Pnmi.BufPort[NetIndex].TxSwQueueLen;
3979 }
3980 /* Single net mode */
3981 else {
3982 Val64 = pAC->Pnmi.BufPort[0].TxSwQueueLen +
3983 pAC->Pnmi.BufPort[1].TxSwQueueLen;
3984 }
3985 }
3986 else {
3987 /* Dual net mode */
3988 if (pAC->Pnmi.DualNetActiveFlag == SK_TRUE) {
3989 Val64 = pAC->Pnmi.Port[NetIndex].TxSwQueueLen;
3990 }
3991 /* Single net mode */
3992 else {
3993 Val64 = pAC->Pnmi.Port[0].TxSwQueueLen +
3994 pAC->Pnmi.Port[1].TxSwQueueLen;
3995 }
3996 }
3997 SK_PNMI_STORE_U64(pBuf, Val64);
3998 *pLen = sizeof(SK_U64);
3999 break;
4000
4001
4002 case OID_SKGE_TX_SW_QUEUE_MAX:
4003 /* 2002-09-17 pweber: For XMAC, use the frozen SW counters (BufPort) */
4004 if (MacType == SK_MAC_XMAC) {
4005 /* Dual net mode */
4006 if (pAC->Pnmi.DualNetActiveFlag == SK_TRUE) {
4007 Val64 = pAC->Pnmi.BufPort[NetIndex].TxSwQueueMax;
4008 }
4009 /* Single net mode */
4010 else {
4011 Val64 = pAC->Pnmi.BufPort[0].TxSwQueueMax +
4012 pAC->Pnmi.BufPort[1].TxSwQueueMax;
4013 }
4014 }
4015 else {
4016 /* Dual net mode */
4017 if (pAC->Pnmi.DualNetActiveFlag == SK_TRUE) {
4018 Val64 = pAC->Pnmi.Port[NetIndex].TxSwQueueMax;
4019 }
4020 /* Single net mode */
4021 else {
4022 Val64 = pAC->Pnmi.Port[0].TxSwQueueMax +
4023 pAC->Pnmi.Port[1].TxSwQueueMax;
4024 }
4025 }
4026 SK_PNMI_STORE_U64(pBuf, Val64);
4027 *pLen = sizeof(SK_U64);
4028 break;
4029
4030 case OID_SKGE_TX_RETRY:
4031 /* 2002-09-17 pweber: For XMAC, use the frozen SW counters (BufPort) */
4032 if (MacType == SK_MAC_XMAC) {
4033 /* Dual net mode */
4034 if (pAC->Pnmi.DualNetActiveFlag == SK_TRUE) {
4035 Val64 = pAC->Pnmi.BufPort[NetIndex].TxRetryCts;
4036 }
4037 /* Single net mode */
4038 else {
4039 Val64 = pAC->Pnmi.BufPort[0].TxRetryCts +
4040 pAC->Pnmi.BufPort[1].TxRetryCts;
4041 }
4042 }
4043 else {
4044 /* Dual net mode */
4045 if (pAC->Pnmi.DualNetActiveFlag == SK_TRUE) {
4046 Val64 = pAC->Pnmi.Port[NetIndex].TxRetryCts;
4047 }
4048 /* Single net mode */
4049 else {
4050 Val64 = pAC->Pnmi.Port[0].TxRetryCts +
4051 pAC->Pnmi.Port[1].TxRetryCts;
4052 }
4053 }
4054 SK_PNMI_STORE_U64(pBuf, Val64);
4055 *pLen = sizeof(SK_U64);
4056 break;
4057
4058 case OID_SKGE_RX_INTR_CTS:
4059 /* 2002-09-17 pweber: For XMAC, use the frozen SW counters (BufPort) */
4060 if (MacType == SK_MAC_XMAC) {
4061 /* Dual net mode */
4062 if (pAC->Pnmi.DualNetActiveFlag == SK_TRUE) {
4063 Val64 = pAC->Pnmi.BufPort[NetIndex].RxIntrCts;
4064 }
4065 /* Single net mode */
4066 else {
4067 Val64 = pAC->Pnmi.BufPort[0].RxIntrCts +
4068 pAC->Pnmi.BufPort[1].RxIntrCts;
4069 }
4070 }
4071 else {
4072 /* Dual net mode */
4073 if (pAC->Pnmi.DualNetActiveFlag == SK_TRUE) {
4074 Val64 = pAC->Pnmi.Port[NetIndex].RxIntrCts;
4075 }
4076 /* Single net mode */
4077 else {
4078 Val64 = pAC->Pnmi.Port[0].RxIntrCts +
4079 pAC->Pnmi.Port[1].RxIntrCts;
4080 }
4081 }
4082 SK_PNMI_STORE_U64(pBuf, Val64);
4083 *pLen = sizeof(SK_U64);
4084 break;
4085
4086 case OID_SKGE_TX_INTR_CTS:
4087 /* 2002-09-17 pweber: For XMAC, use the frozen SW counters (BufPort) */
4088 if (MacType == SK_MAC_XMAC) {
4089 /* Dual net mode */
4090 if (pAC->Pnmi.DualNetActiveFlag == SK_TRUE) {
4091 Val64 = pAC->Pnmi.BufPort[NetIndex].TxIntrCts;
4092 }
4093 /* Single net mode */
4094 else {
4095 Val64 = pAC->Pnmi.BufPort[0].TxIntrCts +
4096 pAC->Pnmi.BufPort[1].TxIntrCts;
4097 }
4098 }
4099 else {
4100 /* Dual net mode */
4101 if (pAC->Pnmi.DualNetActiveFlag == SK_TRUE) {
4102 Val64 = pAC->Pnmi.Port[NetIndex].TxIntrCts;
4103 }
4104 /* Single net mode */
4105 else {
4106 Val64 = pAC->Pnmi.Port[0].TxIntrCts +
4107 pAC->Pnmi.Port[1].TxIntrCts;
4108 }
4109 }
4110 SK_PNMI_STORE_U64(pBuf, Val64);
4111 *pLen = sizeof(SK_U64);
4112 break;
4113
4114 case OID_SKGE_RX_NO_BUF_CTS:
4115 /* 2002-09-17 pweber: For XMAC, use the frozen SW counters (BufPort) */
4116 if (MacType == SK_MAC_XMAC) {
4117 /* Dual net mode */
4118 if (pAC->Pnmi.DualNetActiveFlag == SK_TRUE) {
4119 Val64 = pAC->Pnmi.BufPort[NetIndex].RxNoBufCts;
4120 }
4121 /* Single net mode */
4122 else {
4123 Val64 = pAC->Pnmi.BufPort[0].RxNoBufCts +
4124 pAC->Pnmi.BufPort[1].RxNoBufCts;
4125 }
4126 }
4127 else {
4128 /* Dual net mode */
4129 if (pAC->Pnmi.DualNetActiveFlag == SK_TRUE) {
4130 Val64 = pAC->Pnmi.Port[NetIndex].RxNoBufCts;
4131 }
4132 /* Single net mode */
4133 else {
4134 Val64 = pAC->Pnmi.Port[0].RxNoBufCts +
4135 pAC->Pnmi.Port[1].RxNoBufCts;
4136 }
4137 }
4138 SK_PNMI_STORE_U64(pBuf, Val64);
4139 *pLen = sizeof(SK_U64);
4140 break;
4141
4142 case OID_SKGE_TX_NO_BUF_CTS:
4143 /* 2002-09-17 pweber: For XMAC, use the frozen SW counters (BufPort) */
4144 if (MacType == SK_MAC_XMAC) {
4145 /* Dual net mode */
4146 if (pAC->Pnmi.DualNetActiveFlag == SK_TRUE) {
4147 Val64 = pAC->Pnmi.BufPort[NetIndex].TxNoBufCts;
4148 }
4149 /* Single net mode */
4150 else {
4151 Val64 = pAC->Pnmi.BufPort[0].TxNoBufCts +
4152 pAC->Pnmi.BufPort[1].TxNoBufCts;
4153 }
4154 }
4155 else {
4156 /* Dual net mode */
4157 if (pAC->Pnmi.DualNetActiveFlag == SK_TRUE) {
4158 Val64 = pAC->Pnmi.Port[NetIndex].TxNoBufCts;
4159 }
4160 /* Single net mode */
4161 else {
4162 Val64 = pAC->Pnmi.Port[0].TxNoBufCts +
4163 pAC->Pnmi.Port[1].TxNoBufCts;
4164 }
4165 }
4166 SK_PNMI_STORE_U64(pBuf, Val64);
4167 *pLen = sizeof(SK_U64);
4168 break;
4169
4170 case OID_SKGE_TX_USED_DESCR_NO:
4171 /* 2002-09-17 pweber: For XMAC, use the frozen SW counters (BufPort) */
4172 if (MacType == SK_MAC_XMAC) {
4173 /* Dual net mode */
4174 if (pAC->Pnmi.DualNetActiveFlag == SK_TRUE) {
4175 Val64 = pAC->Pnmi.BufPort[NetIndex].TxUsedDescrNo;
4176 }
4177 /* Single net mode */
4178 else {
4179 Val64 = pAC->Pnmi.BufPort[0].TxUsedDescrNo +
4180 pAC->Pnmi.BufPort[1].TxUsedDescrNo;
4181 }
4182 }
4183 else {
4184 /* Dual net mode */
4185 if (pAC->Pnmi.DualNetActiveFlag == SK_TRUE) {
4186 Val64 = pAC->Pnmi.Port[NetIndex].TxUsedDescrNo;
4187 }
4188 /* Single net mode */
4189 else {
4190 Val64 = pAC->Pnmi.Port[0].TxUsedDescrNo +
4191 pAC->Pnmi.Port[1].TxUsedDescrNo;
4192 }
4193 }
4194 SK_PNMI_STORE_U64(pBuf, Val64);
4195 *pLen = sizeof(SK_U64);
4196 break;
4197
4198 case OID_SKGE_RX_DELIVERED_CTS:
4199 /* 2002-09-17 pweber: For XMAC, use the frozen SW counters (BufPort) */
4200 if (MacType == SK_MAC_XMAC) {
4201 /* Dual net mode */
4202 if (pAC->Pnmi.DualNetActiveFlag == SK_TRUE) {
4203 Val64 = pAC->Pnmi.BufPort[NetIndex].RxDeliveredCts;
4204 }
4205 /* Single net mode */
4206 else {
4207 Val64 = pAC->Pnmi.BufPort[0].RxDeliveredCts +
4208 pAC->Pnmi.BufPort[1].RxDeliveredCts;
4209 }
4210 }
4211 else {
4212 /* Dual net mode */
4213 if (pAC->Pnmi.DualNetActiveFlag == SK_TRUE) {
4214 Val64 = pAC->Pnmi.Port[NetIndex].RxDeliveredCts;
4215 }
4216 /* Single net mode */
4217 else {
4218 Val64 = pAC->Pnmi.Port[0].RxDeliveredCts +
4219 pAC->Pnmi.Port[1].RxDeliveredCts;
4220 }
4221 }
4222 SK_PNMI_STORE_U64(pBuf, Val64);
4223 *pLen = sizeof(SK_U64);
4224 break;
4225
4226 case OID_SKGE_RX_OCTETS_DELIV_CTS:
4227 /* 2002-09-17 pweber: For XMAC, use the frozen SW counters (BufPort) */
4228 if (MacType == SK_MAC_XMAC) {
4229 /* Dual net mode */
4230 if (pAC->Pnmi.DualNetActiveFlag == SK_TRUE) {
4231 Val64 = pAC->Pnmi.BufPort[NetIndex].RxOctetsDeliveredCts;
4232 }
4233 /* Single net mode */
4234 else {
4235 Val64 = pAC->Pnmi.BufPort[0].RxOctetsDeliveredCts +
4236 pAC->Pnmi.BufPort[1].RxOctetsDeliveredCts;
4237 }
4238 }
4239 else {
4240 /* Dual net mode */
4241 if (pAC->Pnmi.DualNetActiveFlag == SK_TRUE) {
4242 Val64 = pAC->Pnmi.Port[NetIndex].RxOctetsDeliveredCts;
4243 }
4244 /* Single net mode */
4245 else {
4246 Val64 = pAC->Pnmi.Port[0].RxOctetsDeliveredCts +
4247 pAC->Pnmi.Port[1].RxOctetsDeliveredCts;
4248 }
4249 }
4250 SK_PNMI_STORE_U64(pBuf, Val64);
4251 *pLen = sizeof(SK_U64);
4252 break;
4253
4254 case OID_SKGE_RX_HW_ERROR_CTS:
4255 SK_PNMI_STORE_U64(pBuf, Val64RxHwErrs);
4256 *pLen = sizeof(SK_U64);
4257 break;
4258
4259 case OID_SKGE_TX_HW_ERROR_CTS:
4260 SK_PNMI_STORE_U64(pBuf, Val64TxHwErrs);
4261 *pLen = sizeof(SK_U64);
4262 break;
4263
4264 case OID_SKGE_IN_ERRORS_CTS:
4265 /* 2002-09-17 pweber: For XMAC, use the frozen SW counters (BufPort) */
4266 if (MacType == SK_MAC_XMAC) {
4267 /* Dual net mode */
4268 if (pAC->Pnmi.DualNetActiveFlag == SK_TRUE) {
4269 Val64 = Val64RxHwErrs + pAC->Pnmi.BufPort[NetIndex].RxNoBufCts;
4270 }
4271 /* Single net mode */
4272 else {
4273 Val64 = Val64RxHwErrs +
4274 pAC->Pnmi.BufPort[0].RxNoBufCts +
4275 pAC->Pnmi.BufPort[1].RxNoBufCts;
4276 }
4277 }
4278 else {
4279 /* Dual net mode */
4280 if (pAC->Pnmi.DualNetActiveFlag == SK_TRUE) {
4281 Val64 = Val64RxHwErrs + pAC->Pnmi.Port[NetIndex].RxNoBufCts;
4282 }
4283 /* Single net mode */
4284 else {
4285 Val64 = Val64RxHwErrs +
4286 pAC->Pnmi.Port[0].RxNoBufCts +
4287 pAC->Pnmi.Port[1].RxNoBufCts;
4288 }
4289 }
4290 SK_PNMI_STORE_U64(pBuf, Val64);
4291 *pLen = sizeof(SK_U64);
4292 break;
4293
4294 case OID_SKGE_OUT_ERROR_CTS:
4295 /* 2002-09-17 pweber: For XMAC, use the frozen SW counters (BufPort) */
4296 if (MacType == SK_MAC_XMAC) {
4297 /* Dual net mode */
4298 if (pAC->Pnmi.DualNetActiveFlag == SK_TRUE) {
4299 Val64 = Val64TxHwErrs + pAC->Pnmi.BufPort[NetIndex].TxNoBufCts;
4300 }
4301 /* Single net mode */
4302 else {
4303 Val64 = Val64TxHwErrs +
4304 pAC->Pnmi.BufPort[0].TxNoBufCts +
4305 pAC->Pnmi.BufPort[1].TxNoBufCts;
4306 }
4307 }
4308 else {
4309 /* Dual net mode */
4310 if (pAC->Pnmi.DualNetActiveFlag == SK_TRUE) {
4311 Val64 = Val64TxHwErrs + pAC->Pnmi.Port[NetIndex].TxNoBufCts;
4312 }
4313 /* Single net mode */
4314 else {
4315 Val64 = Val64TxHwErrs +
4316 pAC->Pnmi.Port[0].TxNoBufCts +
4317 pAC->Pnmi.Port[1].TxNoBufCts;
4318 }
4319 }
4320 SK_PNMI_STORE_U64(pBuf, Val64);
4321 *pLen = sizeof(SK_U64);
4322 break;
4323
4324 case OID_SKGE_ERR_RECOVERY_CTS:
4325 /* 2002-09-17 pweber: For XMAC, use the frozen SW counters (BufPort) */
4326 if (MacType == SK_MAC_XMAC) {
4327 /* Dual net mode */
4328 if (pAC->Pnmi.DualNetActiveFlag == SK_TRUE) {
4329 Val64 = pAC->Pnmi.BufPort[NetIndex].ErrRecoveryCts;
4330 }
4331 /* Single net mode */
4332 else {
4333 Val64 = pAC->Pnmi.BufPort[0].ErrRecoveryCts +
4334 pAC->Pnmi.BufPort[1].ErrRecoveryCts;
4335 }
4336 }
4337 else {
4338 /* Dual net mode */
4339 if (pAC->Pnmi.DualNetActiveFlag == SK_TRUE) {
4340 Val64 = pAC->Pnmi.Port[NetIndex].ErrRecoveryCts;
4341 }
4342 /* Single net mode */
4343 else {
4344 Val64 = pAC->Pnmi.Port[0].ErrRecoveryCts +
4345 pAC->Pnmi.Port[1].ErrRecoveryCts;
4346 }
4347 }
4348 SK_PNMI_STORE_U64(pBuf, Val64);
4349 *pLen = sizeof(SK_U64);
4350 break;
4351
4352 case OID_SKGE_SYSUPTIME:
4353 Val64 = SK_PNMI_HUNDREDS_SEC(SkOsGetTime(pAC));
4354 Val64 -= pAC->Pnmi.StartUpTime;
4355 SK_PNMI_STORE_U64(pBuf, Val64);
4356 *pLen = sizeof(SK_U64);
4357 break;
4358
4359 case OID_SKGE_MDB_VERSION:
4360 Val32 = SK_PNMI_MDB_VERSION;
4361 SK_PNMI_STORE_U32(pBuf, Val32);
4362 *pLen = sizeof(SK_U32);
4363 break;
4364
4365 case OID_GEN_RCV_ERROR:
4366 /* 2002-09-17 pweber: For XMAC, use the frozen SW counters (BufPort) */
4367 if (MacType == SK_MAC_XMAC) {
4368 Val64 = Val64RxHwErrs + pAC->Pnmi.BufPort[NetIndex].RxNoBufCts;
4369 }
4370 else {
4371 Val64 = Val64RxHwErrs + pAC->Pnmi.Port[NetIndex].RxNoBufCts;
4372 }
4373
4374 /*
4375 * by default 32bit values are evaluated
4376 */
4377 if (!Is64BitReq) {
4378 Val32 = (SK_U32)Val64;
4379 SK_PNMI_STORE_U32(pBuf, Val32);
4380 *pLen = sizeof(SK_U32);
4381 }
4382 else {
4383 SK_PNMI_STORE_U64(pBuf, Val64);
4384 *pLen = sizeof(SK_U64);
4385 }
4386 break;
4387
4388 case OID_GEN_XMIT_ERROR:
4389 /* 2002-09-17 pweber: For XMAC, use the frozen SW counters (BufPort) */
4390 if (MacType == SK_MAC_XMAC) {
4391 Val64 = Val64TxHwErrs + pAC->Pnmi.BufPort[NetIndex].TxNoBufCts;
4392 }
4393 else {
4394 Val64 = Val64TxHwErrs + pAC->Pnmi.Port[NetIndex].TxNoBufCts;
4395 }
4396
4397 /*
4398 * by default 32bit values are evaluated
4399 */
4400 if (!Is64BitReq) {
4401 Val32 = (SK_U32)Val64;
4402 SK_PNMI_STORE_U32(pBuf, Val32);
4403 *pLen = sizeof(SK_U32);
4404 }
4405 else {
4406 SK_PNMI_STORE_U64(pBuf, Val64);
4407 *pLen = sizeof(SK_U64);
4408 }
4409 break;
4410
4411 case OID_GEN_RCV_NO_BUFFER:
4412 /* 2002-09-17 pweber: For XMAC, use the frozen SW counters (BufPort) */
4413 if (MacType == SK_MAC_XMAC) {
4414 Val64 = pAC->Pnmi.BufPort[NetIndex].RxNoBufCts;
4415 }
4416 else {
4417 Val64 = pAC->Pnmi.Port[NetIndex].RxNoBufCts;
4418 }
4419
4420 /*
4421 * by default 32bit values are evaluated
4422 */
4423 if (!Is64BitReq) {
4424 Val32 = (SK_U32)Val64;
4425 SK_PNMI_STORE_U32(pBuf, Val32);
4426 *pLen = sizeof(SK_U32);
4427 }
4428 else {
4429 SK_PNMI_STORE_U64(pBuf, Val64);
4430 *pLen = sizeof(SK_U64);
4431 }
4432 break;
4433
4434 case OID_GEN_TRANSMIT_QUEUE_LENGTH:
4435 Val32 = (SK_U32)pAC->Pnmi.Port[NetIndex].TxSwQueueLen;
4436 SK_PNMI_STORE_U32(pBuf, Val32);
4437 *pLen = sizeof(SK_U32);
4438 break;
4439
4440 default:
4441 SK_ERR_LOG(pAC, SK_ERRCL_SW, SK_PNMI_ERR034,
4442 SK_PNMI_ERR034MSG);
4443
4444 *pLen = 0;
4445 return (SK_PNMI_ERR_GENERAL);
4446 }
4447
4448 if (Id == OID_SKGE_RX_HW_ERROR_CTS ||
4449 Id == OID_SKGE_TX_HW_ERROR_CTS ||
4450 Id == OID_SKGE_IN_ERRORS_CTS ||
4451 Id == OID_SKGE_OUT_ERROR_CTS ||
4452 Id == OID_GEN_XMIT_ERROR ||
4453 Id == OID_GEN_RCV_ERROR) {
4454
4455 pAC->Pnmi.MacUpdatedFlag --;
4456 }
4457
4458 return (SK_PNMI_ERR_OK);
4459}
4460
4461/*****************************************************************************
4462 *
4463 * Rlmt - OID handler function of OID_SKGE_RLMT_XXX single instance.
4464 *
4465 * Description:
4466 * Get/Presets/Sets the RLMT OIDs.
4467 *
4468 * Returns:
4469 * SK_PNMI_ERR_OK The request was successfully performed.
4470 * SK_PNMI_ERR_GENERAL A general severe internal error occured.
4471 * SK_PNMI_ERR_TOO_SHORT The passed buffer is too short to contain
4472 * the correct data (e.g. a 32bit value is
4473 * needed, but a 16 bit value was passed).
4474 * SK_PNMI_ERR_BAD_VALUE The passed value is not in the valid
4475 * value range.
4476 * SK_PNMI_ERR_READ_ONLY The OID is read-only and cannot be set.
4477 * SK_PNMI_ERR_UNKNOWN_INST The requested instance of the OID doesn't
4478 * exist (e.g. port instance 3 on a two port
4479 * adapter.
4480 */
4481PNMI_STATIC int Rlmt(
4482SK_AC *pAC, /* Pointer to adapter context */
4483SK_IOC IoC, /* IO context handle */
4484int Action, /* GET/PRESET/SET action */
4485SK_U32 Id, /* Object ID that is to be processed */
4486char *pBuf, /* Buffer used for the management data transfer */
4487unsigned int *pLen, /* On call: pBuf buffer length. On return: used buffer */
4488SK_U32 Instance, /* Instance (1..n) that is to be queried or -1 */
4489unsigned int TableIndex, /* Index to the Id table */
4490SK_U32 NetIndex) /* NetIndex (0..n), in single net mode always zero */
4491{
4492 int Ret;
4493 unsigned int PhysPortIndex;
4494 unsigned int PhysPortMax;
4495 SK_EVPARA EventParam;
4496 SK_U32 Val32;
4497 SK_U64 Val64;
4498
4499
4500 /*
4501 * Check instance. Only single instance OIDs are allowed here.
4502 */
4503 if (Instance != (SK_U32)(-1) && Instance != 1) {
4504
4505 *pLen = 0;
4506 return (SK_PNMI_ERR_UNKNOWN_INST);
4507 }
4508
4509 /*
4510 * Perform the requested action.
4511 */
4512 if (Action == SK_PNMI_GET) {
4513
4514 /*
4515 * Check if the buffer length is large enough.
4516 */
4517
4518 switch (Id) {
4519
4520 case OID_SKGE_RLMT_MODE:
4521 case OID_SKGE_RLMT_PORT_ACTIVE:
4522 case OID_SKGE_RLMT_PORT_PREFERRED:
4523 if (*pLen < sizeof(SK_U8)) {
4524
4525 *pLen = sizeof(SK_U8);
4526 return (SK_PNMI_ERR_TOO_SHORT);
4527 }
4528 break;
4529
4530 case OID_SKGE_RLMT_PORT_NUMBER:
4531 if (*pLen < sizeof(SK_U32)) {
4532
4533 *pLen = sizeof(SK_U32);
4534 return (SK_PNMI_ERR_TOO_SHORT);
4535 }
4536 break;
4537
4538 case OID_SKGE_RLMT_CHANGE_CTS:
4539 case OID_SKGE_RLMT_CHANGE_TIME:
4540 case OID_SKGE_RLMT_CHANGE_ESTIM:
4541 case OID_SKGE_RLMT_CHANGE_THRES:
4542 if (*pLen < sizeof(SK_U64)) {
4543
4544 *pLen = sizeof(SK_U64);
4545 return (SK_PNMI_ERR_TOO_SHORT);
4546 }
4547 break;
4548
4549 default:
4550 SK_ERR_LOG(pAC, SK_ERRCL_SW, SK_PNMI_ERR035,
4551 SK_PNMI_ERR035MSG);
4552
4553 *pLen = 0;
4554 return (SK_PNMI_ERR_GENERAL);
4555 }
4556
4557 /*
4558 * Update RLMT statistic and increment semaphores to indicate
4559 * that an update was already done. Maybe RLMT will hold its
4560 * statistic always up to date some time. Then we can
4561 * remove this type of call.
4562 */
4563 if ((Ret = RlmtUpdate(pAC, IoC, NetIndex)) != SK_PNMI_ERR_OK) {
4564
4565 *pLen = 0;
4566 return (Ret);
4567 }
4568 pAC->Pnmi.RlmtUpdatedFlag ++;
4569
4570 /*
4571 * Retrieve Value
4572 */
4573 switch (Id) {
4574
4575 case OID_SKGE_RLMT_MODE:
4576 *pBuf = (char)pAC->Rlmt.Net[0].RlmtMode;
4577 *pLen = sizeof(char);
4578 break;
4579
4580 case OID_SKGE_RLMT_PORT_NUMBER:
4581 Val32 = (SK_U32)pAC->GIni.GIMacsFound;
4582 SK_PNMI_STORE_U32(pBuf, Val32);
4583 *pLen = sizeof(SK_U32);
4584 break;
4585
4586 case OID_SKGE_RLMT_PORT_ACTIVE:
4587 *pBuf = 0;
4588 /*
4589 * If multiple ports may become active this OID
4590 * doesn't make sense any more. A new variable in
4591 * the port structure should be created. However,
4592 * for this variable the first active port is
4593 * returned.
4594 */
4595 PhysPortMax = pAC->GIni.GIMacsFound;
4596
4597 for (PhysPortIndex = 0; PhysPortIndex < PhysPortMax;
4598 PhysPortIndex ++) {
4599
4600 if (pAC->Pnmi.Port[PhysPortIndex].ActiveFlag) {
4601
4602 *pBuf = (char)SK_PNMI_PORT_PHYS2LOG(PhysPortIndex);
4603 break;
4604 }
4605 }
4606 *pLen = sizeof(char);
4607 break;
4608
4609 case OID_SKGE_RLMT_PORT_PREFERRED:
4610 *pBuf = (char)SK_PNMI_PORT_PHYS2LOG(pAC->Rlmt.Net[NetIndex].Preference);
4611 *pLen = sizeof(char);
4612 break;
4613
4614 case OID_SKGE_RLMT_CHANGE_CTS:
4615 Val64 = pAC->Pnmi.RlmtChangeCts;
4616 SK_PNMI_STORE_U64(pBuf, Val64);
4617 *pLen = sizeof(SK_U64);
4618 break;
4619
4620 case OID_SKGE_RLMT_CHANGE_TIME:
4621 Val64 = pAC->Pnmi.RlmtChangeTime;
4622 SK_PNMI_STORE_U64(pBuf, Val64);
4623 *pLen = sizeof(SK_U64);
4624 break;
4625
4626 case OID_SKGE_RLMT_CHANGE_ESTIM:
4627 Val64 = pAC->Pnmi.RlmtChangeEstimate.Estimate;
4628 SK_PNMI_STORE_U64(pBuf, Val64);
4629 *pLen = sizeof(SK_U64);
4630 break;
4631
4632 case OID_SKGE_RLMT_CHANGE_THRES:
4633 Val64 = pAC->Pnmi.RlmtChangeThreshold;
4634 SK_PNMI_STORE_U64(pBuf, Val64);
4635 *pLen = sizeof(SK_U64);
4636 break;
4637
4638 default:
4639 SK_DBG_MSG(pAC, SK_DBGMOD_PNMI, SK_DBGCAT_ERR,
4640 ("Rlmt: Unknown OID should be handled before"));
4641
4642 pAC->Pnmi.RlmtUpdatedFlag --;
4643 *pLen = 0;
4644 return (SK_PNMI_ERR_GENERAL);
4645 }
4646
4647 pAC->Pnmi.RlmtUpdatedFlag --;
4648 }
4649 else {
4650 /* Perform a preset or set */
4651 switch (Id) {
4652
4653 case OID_SKGE_RLMT_MODE:
4654 /* Check if the buffer length is plausible */
4655 if (*pLen < sizeof(char)) {
4656
4657 *pLen = sizeof(char);
4658 return (SK_PNMI_ERR_TOO_SHORT);
4659 }
4660 /* Check if the value range is correct */
4661 if (*pLen != sizeof(char) ||
4662 (*pBuf & SK_PNMI_RLMT_MODE_CHK_LINK) == 0 ||
4663 *(SK_U8 *)pBuf > 15) {
4664
4665 *pLen = 0;
4666 return (SK_PNMI_ERR_BAD_VALUE);
4667 }
4668 /* The preset ends here */
4669 if (Action == SK_PNMI_PRESET) {
4670
4671 *pLen = 0;
4672 return (SK_PNMI_ERR_OK);
4673 }
4674 /* Send an event to RLMT to change the mode */
4675 SK_MEMSET((char *)&EventParam, 0, sizeof(EventParam));
4676 EventParam.Para32[0] |= (SK_U32)(*pBuf);
4677 EventParam.Para32[1] = 0;
4678 if (SkRlmtEvent(pAC, IoC, SK_RLMT_MODE_CHANGE,
4679 EventParam) > 0) {
4680
4681 SK_ERR_LOG(pAC, SK_ERRCL_SW, SK_PNMI_ERR037,
4682 SK_PNMI_ERR037MSG);
4683
4684 *pLen = 0;
4685 return (SK_PNMI_ERR_GENERAL);
4686 }
4687 break;
4688
4689 case OID_SKGE_RLMT_PORT_PREFERRED:
4690 /* Check if the buffer length is plausible */
4691 if (*pLen < sizeof(char)) {
4692
4693 *pLen = sizeof(char);
4694 return (SK_PNMI_ERR_TOO_SHORT);
4695 }
4696 /* Check if the value range is correct */
4697 if (*pLen != sizeof(char) || *(SK_U8 *)pBuf >
4698 (SK_U8)pAC->GIni.GIMacsFound) {
4699
4700 *pLen = 0;
4701 return (SK_PNMI_ERR_BAD_VALUE);
4702 }
4703 /* The preset ends here */
4704 if (Action == SK_PNMI_PRESET) {
4705
4706 *pLen = 0;
4707 return (SK_PNMI_ERR_OK);
4708 }
4709
4710 /*
4711 * Send an event to RLMT change the preferred port.
4712 * A param of -1 means automatic mode. RLMT will
4713 * make the decision which is the preferred port.
4714 */
4715 SK_MEMSET((char *)&EventParam, 0, sizeof(EventParam));
4716 EventParam.Para32[0] = (SK_U32)(*pBuf) - 1;
4717 EventParam.Para32[1] = NetIndex;
4718 if (SkRlmtEvent(pAC, IoC, SK_RLMT_PREFPORT_CHANGE,
4719 EventParam) > 0) {
4720
4721 SK_ERR_LOG(pAC, SK_ERRCL_SW, SK_PNMI_ERR038,
4722 SK_PNMI_ERR038MSG);
4723
4724 *pLen = 0;
4725 return (SK_PNMI_ERR_GENERAL);
4726 }
4727 break;
4728
4729 case OID_SKGE_RLMT_CHANGE_THRES:
4730 /* Check if the buffer length is plausible */
4731 if (*pLen < sizeof(SK_U64)) {
4732
4733 *pLen = sizeof(SK_U64);
4734 return (SK_PNMI_ERR_TOO_SHORT);
4735 }
4736 /*
4737 * There are not many restrictions to the
4738 * value range.
4739 */
4740 if (*pLen != sizeof(SK_U64)) {
4741
4742 *pLen = 0;
4743 return (SK_PNMI_ERR_BAD_VALUE);
4744 }
4745 /* A preset ends here */
4746 if (Action == SK_PNMI_PRESET) {
4747
4748 *pLen = 0;
4749 return (SK_PNMI_ERR_OK);
4750 }
4751 /*
4752 * Store the new threshold, which will be taken
4753 * on the next timer event.
4754 */
4755 SK_PNMI_READ_U64(pBuf, Val64);
4756 pAC->Pnmi.RlmtChangeThreshold = Val64;
4757 break;
4758
4759 default:
4760 /* The other OIDs are not be able for set */
4761 *pLen = 0;
4762 return (SK_PNMI_ERR_READ_ONLY);
4763 }
4764 }
4765
4766 return (SK_PNMI_ERR_OK);
4767}
4768
4769/*****************************************************************************
4770 *
4771 * RlmtStat - OID handler function of OID_SKGE_RLMT_XXX multiple instance.
4772 *
4773 * Description:
4774 * Performs get requests on multiple instance variables.
4775 *
4776 * Returns:
4777 * SK_PNMI_ERR_OK The request was successfully performed.
4778 * SK_PNMI_ERR_GENERAL A general severe internal error occured.
4779 * SK_PNMI_ERR_TOO_SHORT The passed buffer is too short to contain
4780 * the correct data (e.g. a 32bit value is
4781 * needed, but a 16 bit value was passed).
4782 * SK_PNMI_ERR_UNKNOWN_INST The requested instance of the OID doesn't
4783 * exist (e.g. port instance 3 on a two port
4784 * adapter.
4785 */
4786PNMI_STATIC int RlmtStat(
4787SK_AC *pAC, /* Pointer to adapter context */
4788SK_IOC IoC, /* IO context handle */
4789int Action, /* GET/PRESET/SET action */
4790SK_U32 Id, /* Object ID that is to be processed */
4791char *pBuf, /* Buffer used for the management data transfer */
4792unsigned int *pLen, /* On call: pBuf buffer length. On return: used buffer */
4793SK_U32 Instance, /* Instance (1..n) that is to be queried or -1 */
4794unsigned int TableIndex, /* Index to the Id table */
4795SK_U32 NetIndex) /* NetIndex (0..n), in single net mode always zero */
4796{
4797 unsigned int PhysPortMax;
4798 unsigned int PhysPortIndex;
4799 unsigned int Limit;
4800 unsigned int Offset;
4801 int Ret;
4802 SK_U32 Val32;
4803 SK_U64 Val64;
4804
4805 /*
4806 * Calculate the port indexes from the instance.
4807 */
4808 PhysPortMax = pAC->GIni.GIMacsFound;
4809
4810 if ((Instance != (SK_U32)(-1))) {
4811 /* Check instance range */
4812 if ((Instance < 1) || (Instance > PhysPortMax)) {
4813
4814 *pLen = 0;
4815 return (SK_PNMI_ERR_UNKNOWN_INST);
4816 }
4817
4818 /* Single net mode */
4819 PhysPortIndex = Instance - 1;
4820
4821 /* Dual net mode */
4822 if (pAC->Pnmi.DualNetActiveFlag == SK_TRUE) {
4823 PhysPortIndex = NetIndex;
4824 }
4825
4826 /* Both net modes */
4827 Limit = PhysPortIndex + 1;
4828 }
4829 else {
4830 /* Single net mode */
4831 PhysPortIndex = 0;
4832 Limit = PhysPortMax;
4833
4834 /* Dual net mode */
4835 if (pAC->Pnmi.DualNetActiveFlag == SK_TRUE) {
4836 PhysPortIndex = NetIndex;
4837 Limit = PhysPortIndex + 1;
4838 }
4839 }
4840
4841 /*
4842 * Currently only get requests are allowed.
4843 */
4844 if (Action != SK_PNMI_GET) {
4845
4846 *pLen = 0;
4847 return (SK_PNMI_ERR_READ_ONLY);
4848 }
4849
4850 /*
4851 * Check if the buffer length is large enough.
4852 */
4853 switch (Id) {
4854
4855 case OID_SKGE_RLMT_PORT_INDEX:
4856 case OID_SKGE_RLMT_STATUS:
4857 if (*pLen < (Limit - PhysPortIndex) * sizeof(SK_U32)) {
4858
4859 *pLen = (Limit - PhysPortIndex) * sizeof(SK_U32);
4860 return (SK_PNMI_ERR_TOO_SHORT);
4861 }
4862 break;
4863
4864 case OID_SKGE_RLMT_TX_HELLO_CTS:
4865 case OID_SKGE_RLMT_RX_HELLO_CTS:
4866 case OID_SKGE_RLMT_TX_SP_REQ_CTS:
4867 case OID_SKGE_RLMT_RX_SP_CTS:
4868 if (*pLen < (Limit - PhysPortIndex) * sizeof(SK_U64)) {
4869
4870 *pLen = (Limit - PhysPortIndex) * sizeof(SK_U64);
4871 return (SK_PNMI_ERR_TOO_SHORT);
4872 }
4873 break;
4874
4875 default:
4876 SK_ERR_LOG(pAC, SK_ERRCL_SW, SK_PNMI_ERR039,
4877 SK_PNMI_ERR039MSG);
4878
4879 *pLen = 0;
4880 return (SK_PNMI_ERR_GENERAL);
4881
4882 }
4883
4884 /*
4885 * Update statistic and increment semaphores to indicate that
4886 * an update was already done.
4887 */
4888 if ((Ret = RlmtUpdate(pAC, IoC, NetIndex)) != SK_PNMI_ERR_OK) {
4889
4890 *pLen = 0;
4891 return (Ret);
4892 }
4893 pAC->Pnmi.RlmtUpdatedFlag ++;
4894
4895 /*
4896 * Get value
4897 */
4898 Offset = 0;
4899 for (; PhysPortIndex < Limit; PhysPortIndex ++) {
4900
4901 switch (Id) {
4902
4903 case OID_SKGE_RLMT_PORT_INDEX:
4904 Val32 = PhysPortIndex;
4905 SK_PNMI_STORE_U32(pBuf + Offset, Val32);
4906 Offset += sizeof(SK_U32);
4907 break;
4908
4909 case OID_SKGE_RLMT_STATUS:
4910 if (pAC->Rlmt.Port[PhysPortIndex].PortState ==
4911 SK_RLMT_PS_INIT ||
4912 pAC->Rlmt.Port[PhysPortIndex].PortState ==
4913 SK_RLMT_PS_DOWN) {
4914
4915 Val32 = SK_PNMI_RLMT_STATUS_ERROR;
4916 }
4917 else if (pAC->Pnmi.Port[PhysPortIndex].ActiveFlag) {
4918
4919 Val32 = SK_PNMI_RLMT_STATUS_ACTIVE;
4920 }
4921 else {
4922 Val32 = SK_PNMI_RLMT_STATUS_STANDBY;
4923 }
4924 SK_PNMI_STORE_U32(pBuf + Offset, Val32);
4925 Offset += sizeof(SK_U32);
4926 break;
4927
4928 case OID_SKGE_RLMT_TX_HELLO_CTS:
4929 Val64 = pAC->Rlmt.Port[PhysPortIndex].TxHelloCts;
4930 SK_PNMI_STORE_U64(pBuf + Offset, Val64);
4931 Offset += sizeof(SK_U64);
4932 break;
4933
4934 case OID_SKGE_RLMT_RX_HELLO_CTS:
4935 Val64 = pAC->Rlmt.Port[PhysPortIndex].RxHelloCts;
4936 SK_PNMI_STORE_U64(pBuf + Offset, Val64);
4937 Offset += sizeof(SK_U64);
4938 break;
4939
4940 case OID_SKGE_RLMT_TX_SP_REQ_CTS:
4941 Val64 = pAC->Rlmt.Port[PhysPortIndex].TxSpHelloReqCts;
4942 SK_PNMI_STORE_U64(pBuf + Offset, Val64);
4943 Offset += sizeof(SK_U64);
4944 break;
4945
4946 case OID_SKGE_RLMT_RX_SP_CTS:
4947 Val64 = pAC->Rlmt.Port[PhysPortIndex].RxSpHelloCts;
4948 SK_PNMI_STORE_U64(pBuf + Offset, Val64);
4949 Offset += sizeof(SK_U64);
4950 break;
4951
4952 default:
4953 SK_DBG_MSG(pAC, SK_DBGMOD_PNMI, SK_DBGCAT_ERR,
4954 ("RlmtStat: Unknown OID should be errored before"));
4955
4956 pAC->Pnmi.RlmtUpdatedFlag --;
4957 *pLen = 0;
4958 return (SK_PNMI_ERR_GENERAL);
4959 }
4960 }
4961 *pLen = Offset;
4962
4963 pAC->Pnmi.RlmtUpdatedFlag --;
4964
4965 return (SK_PNMI_ERR_OK);
4966}
4967
4968/*****************************************************************************
4969 *
4970 * MacPrivateConf - OID handler function of OIDs concerning the configuration
4971 *
4972 * Description:
4973 * Get/Presets/Sets the OIDs concerning the configuration.
4974 *
4975 * Returns:
4976 * SK_PNMI_ERR_OK The request was successfully performed.
4977 * SK_PNMI_ERR_GENERAL A general severe internal error occured.
4978 * SK_PNMI_ERR_TOO_SHORT The passed buffer is too short to contain
4979 * the correct data (e.g. a 32bit value is
4980 * needed, but a 16 bit value was passed).
4981 * SK_PNMI_ERR_BAD_VALUE The passed value is not in the valid
4982 * value range.
4983 * SK_PNMI_ERR_READ_ONLY The OID is read-only and cannot be set.
4984 * SK_PNMI_ERR_UNKNOWN_INST The requested instance of the OID doesn't
4985 * exist (e.g. port instance 3 on a two port
4986 * adapter.
4987 */
4988PNMI_STATIC int MacPrivateConf(
4989SK_AC *pAC, /* Pointer to adapter context */
4990SK_IOC IoC, /* IO context handle */
4991int Action, /* GET/PRESET/SET action */
4992SK_U32 Id, /* Object ID that is to be processed */
4993char *pBuf, /* Buffer used for the management data transfer */
4994unsigned int *pLen, /* On call: pBuf buffer length. On return: used buffer */
4995SK_U32 Instance, /* Instance (1..n) that is to be queried or -1 */
4996unsigned int TableIndex, /* Index to the Id table */
4997SK_U32 NetIndex) /* NetIndex (0..n), in single net mode always zero */
4998{
4999 unsigned int PhysPortMax;
5000 unsigned int PhysPortIndex;
5001 unsigned int LogPortMax;
5002 unsigned int LogPortIndex;
5003 unsigned int Limit;
5004 unsigned int Offset;
5005 char Val8;
5006 char *pBufPtr;
5007 int Ret;
5008 SK_EVPARA EventParam;
5009 SK_U32 Val32;
5010
5011 /*
5012 * Calculate instance if wished. MAC index 0 is the virtual MAC.
5013 */
5014 PhysPortMax = pAC->GIni.GIMacsFound;
5015 LogPortMax = SK_PNMI_PORT_PHYS2LOG(PhysPortMax);
5016
5017 if (pAC->Pnmi.DualNetActiveFlag == SK_TRUE) { /* Dual net mode */
5018 LogPortMax--;
5019 }
5020
5021 if ((Instance != (SK_U32)(-1))) { /* Only one specific instance is queried */
5022 /* Check instance range */
5023 if ((Instance < 1) || (Instance > LogPortMax)) {
5024
5025 *pLen = 0;
5026 return (SK_PNMI_ERR_UNKNOWN_INST);
5027 }
5028 LogPortIndex = SK_PNMI_PORT_INST2LOG(Instance);
5029 Limit = LogPortIndex + 1;
5030 }
5031
5032 else { /* Instance == (SK_U32)(-1), get all Instances of that OID */
5033
5034 LogPortIndex = 0;
5035 Limit = LogPortMax;
5036 }
5037
5038 /*
5039 * Perform action
5040 */
5041 if (Action == SK_PNMI_GET) {
5042
5043 /* Check length */
5044 switch (Id) {
5045
5046 case OID_SKGE_PMD:
5047 case OID_SKGE_CONNECTOR:
5048 case OID_SKGE_LINK_CAP:
5049 case OID_SKGE_LINK_MODE:
5050 case OID_SKGE_LINK_MODE_STATUS:
5051 case OID_SKGE_LINK_STATUS:
5052 case OID_SKGE_FLOWCTRL_CAP:
5053 case OID_SKGE_FLOWCTRL_MODE:
5054 case OID_SKGE_FLOWCTRL_STATUS:
5055 case OID_SKGE_PHY_OPERATION_CAP:
5056 case OID_SKGE_PHY_OPERATION_MODE:
5057 case OID_SKGE_PHY_OPERATION_STATUS:
5058 case OID_SKGE_SPEED_CAP:
5059 case OID_SKGE_SPEED_MODE:
5060 case OID_SKGE_SPEED_STATUS:
5061 if (*pLen < (Limit - LogPortIndex) * sizeof(SK_U8)) {
5062
5063 *pLen = (Limit - LogPortIndex) * sizeof(SK_U8);
5064 return (SK_PNMI_ERR_TOO_SHORT);
5065 }
5066 break;
5067
5068 case OID_SKGE_MTU:
5069 case OID_SKGE_PHY_TYPE:
5070 if (*pLen < (Limit - LogPortIndex) * sizeof(SK_U32)) {
5071
5072 *pLen = (Limit - LogPortIndex) * sizeof(SK_U32);
5073 return (SK_PNMI_ERR_TOO_SHORT);
5074 }
5075 break;
5076
5077 default:
5078 SK_ERR_LOG(pAC, SK_ERRCL_SW, SK_PNMI_ERR041,
5079 SK_PNMI_ERR041MSG);
5080 *pLen = 0;
5081 return (SK_PNMI_ERR_GENERAL);
5082 }
5083
5084 /*
5085 * Update statistic and increment semaphore to indicate
5086 * that an update was already done.
5087 */
5088 if ((Ret = SirqUpdate(pAC, IoC)) != SK_PNMI_ERR_OK) {
5089
5090 *pLen = 0;
5091 return (Ret);
5092 }
5093 pAC->Pnmi.SirqUpdatedFlag ++;
5094
5095 /*
5096 * Get value
5097 */
5098 Offset = 0;
5099 for (; LogPortIndex < Limit; LogPortIndex ++) {
5100
5101 pBufPtr = pBuf + Offset;
5102
5103 switch (Id) {
5104
5105 case OID_SKGE_PMD:
5106 *pBufPtr = pAC->Pnmi.PMD;
5107 Offset += sizeof(char);
5108 break;
5109
5110 case OID_SKGE_CONNECTOR:
5111 *pBufPtr = pAC->Pnmi.Connector;
5112 Offset += sizeof(char);
5113 break;
5114
5115 case OID_SKGE_PHY_TYPE:
5116 if (!pAC->Pnmi.DualNetActiveFlag) { /* SingleNetMode */
5117 if (LogPortIndex == 0) {
5118 continue;
5119 }
5120 else {
5121 /* Get value for physical ports */
5122 PhysPortIndex = SK_PNMI_PORT_LOG2PHYS(
5123 pAC, LogPortIndex);
5124 Val32 = pAC->GIni.GP[PhysPortIndex].PhyType;
5125 SK_PNMI_STORE_U32(pBufPtr, Val32);
5126 }
5127 }
5128 else { /* DualNetMode */
5129
5130 Val32 = pAC->GIni.GP[NetIndex].PhyType;
5131 SK_PNMI_STORE_U32(pBufPtr, Val32);
5132 }
5133 Offset += sizeof(SK_U32);
5134 break;
5135
5136 case OID_SKGE_LINK_CAP:
5137 if (!pAC->Pnmi.DualNetActiveFlag) { /* SingleNetMode */
5138 if (LogPortIndex == 0) {
5139 /* Get value for virtual port */
5140 VirtualConf(pAC, IoC, Id, pBufPtr);
5141 }
5142 else {
5143 /* Get value for physical ports */
5144 PhysPortIndex = SK_PNMI_PORT_LOG2PHYS(
5145 pAC, LogPortIndex);
5146
5147 *pBufPtr = pAC->GIni.GP[PhysPortIndex].PLinkCap;
5148 }
5149 }
5150 else { /* DualNetMode */
5151
5152 *pBufPtr = pAC->GIni.GP[NetIndex].PLinkCap;
5153 }
5154 Offset += sizeof(char);
5155 break;
5156
5157 case OID_SKGE_LINK_MODE:
5158 if (!pAC->Pnmi.DualNetActiveFlag) { /* SingleNetMode */
5159 if (LogPortIndex == 0) {
5160 /* Get value for virtual port */
5161 VirtualConf(pAC, IoC, Id, pBufPtr);
5162 }
5163 else {
5164 /* Get value for physical ports */
5165 PhysPortIndex = SK_PNMI_PORT_LOG2PHYS(
5166 pAC, LogPortIndex);
5167
5168 *pBufPtr = pAC->GIni.GP[PhysPortIndex].PLinkModeConf;
5169 }
5170 }
5171 else { /* DualNetMode */
5172
5173 *pBufPtr = pAC->GIni.GP[NetIndex].PLinkModeConf;
5174 }
5175 Offset += sizeof(char);
5176 break;
5177
5178 case OID_SKGE_LINK_MODE_STATUS:
5179 if (!pAC->Pnmi.DualNetActiveFlag) { /* SingleNetMode */
5180 if (LogPortIndex == 0) {
5181 /* Get value for virtual port */
5182 VirtualConf(pAC, IoC, Id, pBufPtr);
5183 }
5184 else {
5185 /* Get value for physical port */
5186 PhysPortIndex = SK_PNMI_PORT_LOG2PHYS(
5187 pAC, LogPortIndex);
5188
5189 *pBufPtr =
5190 CalculateLinkModeStatus(pAC, IoC, PhysPortIndex);
5191 }
5192 }
5193 else { /* DualNetMode */
5194
5195 *pBufPtr = CalculateLinkModeStatus(pAC, IoC, NetIndex);
5196 }
5197 Offset += sizeof(char);
5198 break;
5199
5200 case OID_SKGE_LINK_STATUS:
5201 if (!pAC->Pnmi.DualNetActiveFlag) { /* SingleNetMode */
5202 if (LogPortIndex == 0) {
5203 /* Get value for virtual port */
5204 VirtualConf(pAC, IoC, Id, pBufPtr);
5205 }
5206 else {
5207 /* Get value for physical ports */
5208 PhysPortIndex = SK_PNMI_PORT_LOG2PHYS(
5209 pAC, LogPortIndex);
5210
5211 *pBufPtr = CalculateLinkStatus(pAC, IoC, PhysPortIndex);
5212 }
5213 }
5214 else { /* DualNetMode */
5215
5216 *pBufPtr = CalculateLinkStatus(pAC, IoC, NetIndex);
5217 }
5218 Offset += sizeof(char);
5219 break;
5220
5221 case OID_SKGE_FLOWCTRL_CAP:
5222 if (!pAC->Pnmi.DualNetActiveFlag) { /* SingleNetMode */
5223 if (LogPortIndex == 0) {
5224 /* Get value for virtual port */
5225 VirtualConf(pAC, IoC, Id, pBufPtr);
5226 }
5227 else {
5228 /* Get value for physical ports */
5229 PhysPortIndex = SK_PNMI_PORT_LOG2PHYS(
5230 pAC, LogPortIndex);
5231
5232 *pBufPtr = pAC->GIni.GP[PhysPortIndex].PFlowCtrlCap;
5233 }
5234 }
5235 else { /* DualNetMode */
5236
5237 *pBufPtr = pAC->GIni.GP[NetIndex].PFlowCtrlCap;
5238 }
5239 Offset += sizeof(char);
5240 break;
5241
5242 case OID_SKGE_FLOWCTRL_MODE:
5243 if (!pAC->Pnmi.DualNetActiveFlag) { /* SingleNetMode */
5244 if (LogPortIndex == 0) {
5245 /* Get value for virtual port */
5246 VirtualConf(pAC, IoC, Id, pBufPtr);
5247 }
5248 else {
5249 /* Get value for physical port */
5250 PhysPortIndex = SK_PNMI_PORT_LOG2PHYS(
5251 pAC, LogPortIndex);
5252
5253 *pBufPtr = pAC->GIni.GP[PhysPortIndex].PFlowCtrlMode;
5254 }
5255 }
5256 else { /* DualNetMode */
5257
5258 *pBufPtr = pAC->GIni.GP[NetIndex].PFlowCtrlMode;
5259 }
5260 Offset += sizeof(char);
5261 break;
5262
5263 case OID_SKGE_FLOWCTRL_STATUS:
5264 if (!pAC->Pnmi.DualNetActiveFlag) { /* SingleNetMode */
5265 if (LogPortIndex == 0) {
5266 /* Get value for virtual port */
5267 VirtualConf(pAC, IoC, Id, pBufPtr);
5268 }
5269 else {
5270 /* Get value for physical port */
5271 PhysPortIndex = SK_PNMI_PORT_LOG2PHYS(
5272 pAC, LogPortIndex);
5273
5274 *pBufPtr = pAC->GIni.GP[PhysPortIndex].PFlowCtrlStatus;
5275 }
5276 }
5277 else { /* DualNetMode */
5278
5279 *pBufPtr = pAC->GIni.GP[NetIndex].PFlowCtrlStatus;
5280 }
5281 Offset += sizeof(char);
5282 break;
5283
5284 case OID_SKGE_PHY_OPERATION_CAP:
5285 if (!pAC->Pnmi.DualNetActiveFlag) { /* SingleNetMode */
5286 if (LogPortIndex == 0) {
5287 /* Get value for virtual port */
5288 VirtualConf(pAC, IoC, Id, pBufPtr);
5289 }
5290 else {
5291 /* Get value for physical ports */
5292 PhysPortIndex = SK_PNMI_PORT_LOG2PHYS(
5293 pAC, LogPortIndex);
5294
5295 *pBufPtr = pAC->GIni.GP[PhysPortIndex].PMSCap;
5296 }
5297 }
5298 else { /* DualNetMode */
5299
5300 *pBufPtr = pAC->GIni.GP[NetIndex].PMSCap;
5301 }
5302 Offset += sizeof(char);
5303 break;
5304
5305 case OID_SKGE_PHY_OPERATION_MODE:
5306 if (!pAC->Pnmi.DualNetActiveFlag) { /* SingleNetMode */
5307 if (LogPortIndex == 0) {
5308 /* Get value for virtual port */
5309 VirtualConf(pAC, IoC, Id, pBufPtr);
5310 }
5311 else {
5312 /* Get value for physical port */
5313 PhysPortIndex = SK_PNMI_PORT_LOG2PHYS(
5314 pAC, LogPortIndex);
5315
5316 *pBufPtr = pAC->GIni.GP[PhysPortIndex].PMSMode;
5317 }
5318 }
5319 else { /* DualNetMode */
5320
5321 *pBufPtr = pAC->GIni.GP[NetIndex].PMSMode;
5322 }
5323 Offset += sizeof(char);
5324 break;
5325
5326 case OID_SKGE_PHY_OPERATION_STATUS:
5327 if (!pAC->Pnmi.DualNetActiveFlag) { /* SingleNetMode */
5328 if (LogPortIndex == 0) {
5329 /* Get value for virtual port */
5330 VirtualConf(pAC, IoC, Id, pBufPtr);
5331 }
5332 else {
5333 /* Get value for physical port */
5334 PhysPortIndex = SK_PNMI_PORT_LOG2PHYS(
5335 pAC, LogPortIndex);
5336
5337 *pBufPtr = pAC->GIni.GP[PhysPortIndex].PMSStatus;
5338 }
5339 }
5340 else {
5341
5342 *pBufPtr = pAC->GIni.GP[NetIndex].PMSStatus;
5343 }
5344 Offset += sizeof(char);
5345 break;
5346
5347 case OID_SKGE_SPEED_CAP:
5348 if (!pAC->Pnmi.DualNetActiveFlag) { /* SingleNetMode */
5349 if (LogPortIndex == 0) {
5350 /* Get value for virtual port */
5351 VirtualConf(pAC, IoC, Id, pBufPtr);
5352 }
5353 else {
5354 /* Get value for physical ports */
5355 PhysPortIndex = SK_PNMI_PORT_LOG2PHYS(
5356 pAC, LogPortIndex);
5357
5358 *pBufPtr = pAC->GIni.GP[PhysPortIndex].PLinkSpeedCap;
5359 }
5360 }
5361 else { /* DualNetMode */
5362
5363 *pBufPtr = pAC->GIni.GP[NetIndex].PLinkSpeedCap;
5364 }
5365 Offset += sizeof(char);
5366 break;
5367
5368 case OID_SKGE_SPEED_MODE:
5369 if (!pAC->Pnmi.DualNetActiveFlag) { /* SingleNetMode */
5370 if (LogPortIndex == 0) {
5371 /* Get value for virtual port */
5372 VirtualConf(pAC, IoC, Id, pBufPtr);
5373 }
5374 else {
5375 /* Get value for physical port */
5376 PhysPortIndex = SK_PNMI_PORT_LOG2PHYS(
5377 pAC, LogPortIndex);
5378
5379 *pBufPtr = pAC->GIni.GP[PhysPortIndex].PLinkSpeed;
5380 }
5381 }
5382 else { /* DualNetMode */
5383
5384 *pBufPtr = pAC->GIni.GP[NetIndex].PLinkSpeed;
5385 }
5386 Offset += sizeof(char);
5387 break;
5388
5389 case OID_SKGE_SPEED_STATUS:
5390 if (!pAC->Pnmi.DualNetActiveFlag) { /* SingleNetMode */
5391 if (LogPortIndex == 0) {
5392 /* Get value for virtual port */
5393 VirtualConf(pAC, IoC, Id, pBufPtr);
5394 }
5395 else {
5396 /* Get value for physical port */
5397 PhysPortIndex = SK_PNMI_PORT_LOG2PHYS(
5398 pAC, LogPortIndex);
5399
5400 *pBufPtr = pAC->GIni.GP[PhysPortIndex].PLinkSpeedUsed;
5401 }
5402 }
5403 else { /* DualNetMode */
5404
5405 *pBufPtr = pAC->GIni.GP[NetIndex].PLinkSpeedUsed;
5406 }
5407 Offset += sizeof(char);
5408 break;
5409
5410 case OID_SKGE_MTU:
5411 Val32 = SK_DRIVER_GET_MTU(pAC, IoC, NetIndex);
5412 SK_PNMI_STORE_U32(pBufPtr, Val32);
5413 Offset += sizeof(SK_U32);
5414 break;
5415
5416 default:
5417 SK_DBG_MSG(pAC, SK_DBGMOD_PNMI, SK_DBGCAT_ERR,
5418 ("MacPrivateConf: Unknown OID should be handled before"));
5419
5420 pAC->Pnmi.SirqUpdatedFlag --;
5421 return (SK_PNMI_ERR_GENERAL);
5422 }
5423 }
5424 *pLen = Offset;
5425 pAC->Pnmi.SirqUpdatedFlag --;
5426
5427 return (SK_PNMI_ERR_OK);
5428 }
5429
5430 /*
5431 * From here SET or PRESET action. Check if the passed
5432 * buffer length is plausible.
5433 */
5434 switch (Id) {
5435
5436 case OID_SKGE_LINK_MODE:
5437 case OID_SKGE_FLOWCTRL_MODE:
5438 case OID_SKGE_PHY_OPERATION_MODE:
5439 case OID_SKGE_SPEED_MODE:
5440 if (*pLen < Limit - LogPortIndex) {
5441
5442 *pLen = Limit - LogPortIndex;
5443 return (SK_PNMI_ERR_TOO_SHORT);
5444 }
5445 if (*pLen != Limit - LogPortIndex) {
5446
5447 *pLen = 0;
5448 return (SK_PNMI_ERR_BAD_VALUE);
5449 }
5450 break;
5451
5452 case OID_SKGE_MTU:
5453 if (*pLen < sizeof(SK_U32)) {
5454
5455 *pLen = sizeof(SK_U32);
5456 return (SK_PNMI_ERR_TOO_SHORT);
5457 }
5458 if (*pLen != sizeof(SK_U32)) {
5459
5460 *pLen = 0;
5461 return (SK_PNMI_ERR_BAD_VALUE);
5462 }
5463 break;
5464
5465 default:
5466 *pLen = 0;
5467 return (SK_PNMI_ERR_READ_ONLY);
5468 }
5469
5470 /*
5471 * Perform preset or set
5472 */
5473 Offset = 0;
5474 for (; LogPortIndex < Limit; LogPortIndex ++) {
5475
5476 switch (Id) {
5477
5478 case OID_SKGE_LINK_MODE:
5479 /* Check the value range */
5480 Val8 = *(pBuf + Offset);
5481 if (Val8 == 0) {
5482
5483 Offset += sizeof(char);
5484 break;
5485 }
5486 if (Val8 < SK_LMODE_HALF ||
5487 (LogPortIndex != 0 && Val8 > SK_LMODE_AUTOSENSE) ||
5488 (LogPortIndex == 0 && Val8 > SK_LMODE_INDETERMINATED)) {
5489
5490 *pLen = 0;
5491 return (SK_PNMI_ERR_BAD_VALUE);
5492 }
5493
5494 /* The preset ends here */
5495 if (Action == SK_PNMI_PRESET) {
5496
5497 return (SK_PNMI_ERR_OK);
5498 }
5499
5500 if (LogPortIndex == 0) {
5501
5502 /*
5503 * The virtual port consists of all currently
5504 * active ports. Find them and send an event
5505 * with the new link mode to SIRQ.
5506 */
5507 for (PhysPortIndex = 0;
5508 PhysPortIndex < PhysPortMax;
5509 PhysPortIndex ++) {
5510
5511 if (!pAC->Pnmi.Port[PhysPortIndex].
5512 ActiveFlag) {
5513
5514 continue;
5515 }
5516
5517 EventParam.Para32[0] = PhysPortIndex;
5518 EventParam.Para32[1] = (SK_U32)Val8;
5519 if (SkGeSirqEvent(pAC, IoC,
5520 SK_HWEV_SET_LMODE,
5521 EventParam) > 0) {
5522
5523 SK_ERR_LOG(pAC, SK_ERRCL_SW,
5524 SK_PNMI_ERR043,
5525 SK_PNMI_ERR043MSG);
5526
5527 *pLen = 0;
5528 return (SK_PNMI_ERR_GENERAL);
5529 }
5530 }
5531 }
5532 else {
5533 /*
5534 * Send an event with the new link mode to
5535 * the SIRQ module.
5536 */
5537 EventParam.Para32[0] = SK_PNMI_PORT_LOG2PHYS(
5538 pAC, LogPortIndex);
5539 EventParam.Para32[1] = (SK_U32)Val8;
5540 if (SkGeSirqEvent(pAC, IoC, SK_HWEV_SET_LMODE,
5541 EventParam) > 0) {
5542
5543 SK_ERR_LOG(pAC, SK_ERRCL_SW,
5544 SK_PNMI_ERR043,
5545 SK_PNMI_ERR043MSG);
5546
5547 *pLen = 0;
5548 return (SK_PNMI_ERR_GENERAL);
5549 }
5550 }
5551 Offset += sizeof(char);
5552 break;
5553
5554 case OID_SKGE_FLOWCTRL_MODE:
5555 /* Check the value range */
5556 Val8 = *(pBuf + Offset);
5557 if (Val8 == 0) {
5558
5559 Offset += sizeof(char);
5560 break;
5561 }
5562 if (Val8 < SK_FLOW_MODE_NONE ||
5563 (LogPortIndex != 0 && Val8 > SK_FLOW_MODE_SYM_OR_REM) ||
5564 (LogPortIndex == 0 && Val8 > SK_FLOW_MODE_INDETERMINATED)) {
5565
5566 *pLen = 0;
5567 return (SK_PNMI_ERR_BAD_VALUE);
5568 }
5569
5570 /* The preset ends here */
5571 if (Action == SK_PNMI_PRESET) {
5572
5573 return (SK_PNMI_ERR_OK);
5574 }
5575
5576 if (LogPortIndex == 0) {
5577
5578 /*
5579 * The virtual port consists of all currently
5580 * active ports. Find them and send an event
5581 * with the new flow control mode to SIRQ.
5582 */
5583 for (PhysPortIndex = 0;
5584 PhysPortIndex < PhysPortMax;
5585 PhysPortIndex ++) {
5586
5587 if (!pAC->Pnmi.Port[PhysPortIndex].
5588 ActiveFlag) {
5589
5590 continue;
5591 }
5592
5593 EventParam.Para32[0] = PhysPortIndex;
5594 EventParam.Para32[1] = (SK_U32)Val8;
5595 if (SkGeSirqEvent(pAC, IoC,
5596 SK_HWEV_SET_FLOWMODE,
5597 EventParam) > 0) {
5598
5599 SK_ERR_LOG(pAC, SK_ERRCL_SW,
5600 SK_PNMI_ERR044,
5601 SK_PNMI_ERR044MSG);
5602
5603 *pLen = 0;
5604 return (SK_PNMI_ERR_GENERAL);
5605 }
5606 }
5607 }
5608 else {
5609 /*
5610 * Send an event with the new flow control
5611 * mode to the SIRQ module.
5612 */
5613 EventParam.Para32[0] = SK_PNMI_PORT_LOG2PHYS(
5614 pAC, LogPortIndex);
5615 EventParam.Para32[1] = (SK_U32)Val8;
5616 if (SkGeSirqEvent(pAC, IoC,
5617 SK_HWEV_SET_FLOWMODE, EventParam)
5618 > 0) {
5619
5620 SK_ERR_LOG(pAC, SK_ERRCL_SW,
5621 SK_PNMI_ERR044,
5622 SK_PNMI_ERR044MSG);
5623
5624 *pLen = 0;
5625 return (SK_PNMI_ERR_GENERAL);
5626 }
5627 }
5628 Offset += sizeof(char);
5629 break;
5630
5631 case OID_SKGE_PHY_OPERATION_MODE :
5632 /* Check the value range */
5633 Val8 = *(pBuf + Offset);
5634 if (Val8 == 0) {
5635 /* mode of this port remains unchanged */
5636 Offset += sizeof(char);
5637 break;
5638 }
5639 if (Val8 < SK_MS_MODE_AUTO ||
5640 (LogPortIndex != 0 && Val8 > SK_MS_MODE_SLAVE) ||
5641 (LogPortIndex == 0 && Val8 > SK_MS_MODE_INDETERMINATED)) {
5642
5643 *pLen = 0;
5644 return (SK_PNMI_ERR_BAD_VALUE);
5645 }
5646
5647 /* The preset ends here */
5648 if (Action == SK_PNMI_PRESET) {
5649
5650 return (SK_PNMI_ERR_OK);
5651 }
5652
5653 if (LogPortIndex == 0) {
5654
5655 /*
5656 * The virtual port consists of all currently
5657 * active ports. Find them and send an event
5658 * with new master/slave (role) mode to SIRQ.
5659 */
5660 for (PhysPortIndex = 0;
5661 PhysPortIndex < PhysPortMax;
5662 PhysPortIndex ++) {
5663
5664 if (!pAC->Pnmi.Port[PhysPortIndex].
5665 ActiveFlag) {
5666
5667 continue;
5668 }
5669
5670 EventParam.Para32[0] = PhysPortIndex;
5671 EventParam.Para32[1] = (SK_U32)Val8;
5672 if (SkGeSirqEvent(pAC, IoC,
5673 SK_HWEV_SET_ROLE,
5674 EventParam) > 0) {
5675
5676 SK_ERR_LOG(pAC, SK_ERRCL_SW,
5677 SK_PNMI_ERR042,
5678 SK_PNMI_ERR042MSG);
5679
5680 *pLen = 0;
5681 return (SK_PNMI_ERR_GENERAL);
5682 }
5683 }
5684 }
5685 else {
5686 /*
5687 * Send an event with the new master/slave
5688 * (role) mode to the SIRQ module.
5689 */
5690 EventParam.Para32[0] = SK_PNMI_PORT_LOG2PHYS(
5691 pAC, LogPortIndex);
5692 EventParam.Para32[1] = (SK_U32)Val8;
5693 if (SkGeSirqEvent(pAC, IoC,
5694 SK_HWEV_SET_ROLE, EventParam) > 0) {
5695
5696 SK_ERR_LOG(pAC, SK_ERRCL_SW,
5697 SK_PNMI_ERR042,
5698 SK_PNMI_ERR042MSG);
5699
5700 *pLen = 0;
5701 return (SK_PNMI_ERR_GENERAL);
5702 }
5703 }
5704
5705 Offset += sizeof(char);
5706 break;
5707
5708 case OID_SKGE_SPEED_MODE:
5709 /* Check the value range */
5710 Val8 = *(pBuf + Offset);
5711 if (Val8 == 0) {
5712
5713 Offset += sizeof(char);
5714 break;
5715 }
5716 if (Val8 < (SK_LSPEED_AUTO) ||
5717 (LogPortIndex != 0 && Val8 > (SK_LSPEED_1000MBPS)) ||
5718 (LogPortIndex == 0 && Val8 > (SK_LSPEED_INDETERMINATED))) {
5719
5720 *pLen = 0;
5721 return (SK_PNMI_ERR_BAD_VALUE);
5722 }
5723
5724 /* The preset ends here */
5725 if (Action == SK_PNMI_PRESET) {
5726
5727 return (SK_PNMI_ERR_OK);
5728 }
5729
5730 if (LogPortIndex == 0) {
5731
5732 /*
5733 * The virtual port consists of all currently
5734 * active ports. Find them and send an event
5735 * with the new flow control mode to SIRQ.
5736 */
5737 for (PhysPortIndex = 0;
5738 PhysPortIndex < PhysPortMax;
5739 PhysPortIndex ++) {
5740
5741 if (!pAC->Pnmi.Port[PhysPortIndex].ActiveFlag) {
5742
5743 continue;
5744 }
5745
5746 EventParam.Para32[0] = PhysPortIndex;
5747 EventParam.Para32[1] = (SK_U32)Val8;
5748 if (SkGeSirqEvent(pAC, IoC,
5749 SK_HWEV_SET_SPEED,
5750 EventParam) > 0) {
5751
5752 SK_ERR_LOG(pAC, SK_ERRCL_SW,
5753 SK_PNMI_ERR045,
5754 SK_PNMI_ERR045MSG);
5755
5756 *pLen = 0;
5757 return (SK_PNMI_ERR_GENERAL);
5758 }
5759 }
5760 }
5761 else {
5762 /*
5763 * Send an event with the new flow control
5764 * mode to the SIRQ module.
5765 */
5766 EventParam.Para32[0] = SK_PNMI_PORT_LOG2PHYS(
5767 pAC, LogPortIndex);
5768 EventParam.Para32[1] = (SK_U32)Val8;
5769 if (SkGeSirqEvent(pAC, IoC,
5770 SK_HWEV_SET_SPEED,
5771 EventParam) > 0) {
5772
5773 SK_ERR_LOG(pAC, SK_ERRCL_SW,
5774 SK_PNMI_ERR045,
5775 SK_PNMI_ERR045MSG);
5776
5777 *pLen = 0;
5778 return (SK_PNMI_ERR_GENERAL);
5779 }
5780 }
5781 Offset += sizeof(char);
5782 break;
5783
5784 case OID_SKGE_MTU :
5785 /* Check the value range */
5786 Val32 = *(SK_U32*)(pBuf + Offset);
5787 if (Val32 == 0) {
5788 /* mtu of this port remains unchanged */
5789 Offset += sizeof(SK_U32);
5790 break;
5791 }
5792 if (SK_DRIVER_PRESET_MTU(pAC, IoC, NetIndex, Val32) != 0) {
5793 *pLen = 0;
5794 return (SK_PNMI_ERR_BAD_VALUE);
5795 }
5796
5797 /* The preset ends here */
5798 if (Action == SK_PNMI_PRESET) {
5799 return (SK_PNMI_ERR_OK);
5800 }
5801
5802 if (SK_DRIVER_SET_MTU(pAC, IoC, NetIndex, Val32) != 0) {
5803 return (SK_PNMI_ERR_GENERAL);
5804 }
5805
5806 Offset += sizeof(SK_U32);
5807 break;
5808
5809 default:
5810 SK_DBG_MSG(pAC, SK_DBGMOD_PNMI, SK_DBGCAT_ERR,
5811 ("MacPrivateConf: Unknown OID should be handled before set"));
5812
5813 *pLen = 0;
5814 return (SK_PNMI_ERR_GENERAL);
5815 }
5816 }
5817
5818 return (SK_PNMI_ERR_OK);
5819}
5820
5821/*****************************************************************************
5822 *
5823 * Monitor - OID handler function for RLMT_MONITOR_XXX
5824 *
5825 * Description:
5826 * Because RLMT currently does not support the monitoring of
5827 * remote adapter cards, we return always an empty table.
5828 *
5829 * Returns:
5830 * SK_PNMI_ERR_OK The request was successfully performed.
5831 * SK_PNMI_ERR_GENERAL A general severe internal error occured.
5832 * SK_PNMI_ERR_TOO_SHORT The passed buffer is too short to contain
5833 * the correct data (e.g. a 32bit value is
5834 * needed, but a 16 bit value was passed).
5835 * SK_PNMI_ERR_BAD_VALUE The passed value is not in the valid
5836 * value range.
5837 * SK_PNMI_ERR_READ_ONLY The OID is read-only and cannot be set.
5838 * SK_PNMI_ERR_UNKNOWN_INST The requested instance of the OID doesn't
5839 * exist (e.g. port instance 3 on a two port
5840 * adapter.
5841 */
5842PNMI_STATIC int Monitor(
5843SK_AC *pAC, /* Pointer to adapter context */
5844SK_IOC IoC, /* IO context handle */
5845int Action, /* GET/PRESET/SET action */
5846SK_U32 Id, /* Object ID that is to be processed */
5847char *pBuf, /* Buffer used for the management data transfer */
5848unsigned int *pLen, /* On call: pBuf buffer length. On return: used buffer */
5849SK_U32 Instance, /* Instance (1..n) that is to be queried or -1 */
5850unsigned int TableIndex, /* Index to the Id table */
5851SK_U32 NetIndex) /* NetIndex (0..n), in single net mode always zero */
5852{
5853 unsigned int Index;
5854 unsigned int Limit;
5855 unsigned int Offset;
5856 unsigned int Entries;
5857
5858
5859 /*
5860 * Calculate instance if wished.
5861 */
5862 /* XXX Not yet implemented. Return always an empty table. */
5863 Entries = 0;
5864
5865 if ((Instance != (SK_U32)(-1))) {
5866
5867 if ((Instance < 1) || (Instance > Entries)) {
5868
5869 *pLen = 0;
5870 return (SK_PNMI_ERR_UNKNOWN_INST);
5871 }
5872
5873 Index = (unsigned int)Instance - 1;
5874 Limit = (unsigned int)Instance;
5875 }
5876 else {
5877 Index = 0;
5878 Limit = Entries;
5879 }
5880
5881 /*
5882 * Get/Set value
5883 */
5884 if (Action == SK_PNMI_GET) {
5885
5886 for (Offset=0; Index < Limit; Index ++) {
5887
5888 switch (Id) {
5889
5890 case OID_SKGE_RLMT_MONITOR_INDEX:
5891 case OID_SKGE_RLMT_MONITOR_ADDR:
5892 case OID_SKGE_RLMT_MONITOR_ERRS:
5893 case OID_SKGE_RLMT_MONITOR_TIMESTAMP:
5894 case OID_SKGE_RLMT_MONITOR_ADMIN:
5895 break;
5896
5897 default:
5898 SK_ERR_LOG(pAC, SK_ERRCL_SW, SK_PNMI_ERR046,
5899 SK_PNMI_ERR046MSG);
5900
5901 *pLen = 0;
5902 return (SK_PNMI_ERR_GENERAL);
5903 }
5904 }
5905 *pLen = Offset;
5906 }
5907 else {
5908 /* Only MONITOR_ADMIN can be set */
5909 if (Id != OID_SKGE_RLMT_MONITOR_ADMIN) {
5910
5911 *pLen = 0;
5912 return (SK_PNMI_ERR_READ_ONLY);
5913 }
5914
5915 /* Check if the length is plausible */
5916 if (*pLen < (Limit - Index)) {
5917
5918 return (SK_PNMI_ERR_TOO_SHORT);
5919 }
5920 /* Okay, we have a wide value range */
5921 if (*pLen != (Limit - Index)) {
5922
5923 *pLen = 0;
5924 return (SK_PNMI_ERR_BAD_VALUE);
5925 }
5926/*
5927 for (Offset=0; Index < Limit; Index ++) {
5928 }
5929*/
5930/*
5931 * XXX Not yet implemented. Return always BAD_VALUE, because the table
5932 * is empty.
5933 */
5934 *pLen = 0;
5935 return (SK_PNMI_ERR_BAD_VALUE);
5936 }
5937
5938 return (SK_PNMI_ERR_OK);
5939}
5940
5941/*****************************************************************************
5942 *
5943 * VirtualConf - Calculates the values of configuration OIDs for virtual port
5944 *
5945 * Description:
5946 * We handle here the get of the configuration group OIDs, which are
5947 * a little bit complicated. The virtual port consists of all currently
5948 * active physical ports. If multiple ports are active and configured
5949 * differently we get in some trouble to return a single value. So we
5950 * get the value of the first active port and compare it with that of
5951 * the other active ports. If they are not the same, we return a value
5952 * that indicates that the state is indeterminated.
5953 *
5954 * Returns:
5955 * Nothing
5956 */
5957PNMI_STATIC void VirtualConf(
5958SK_AC *pAC, /* Pointer to adapter context */
5959SK_IOC IoC, /* IO context handle */
5960SK_U32 Id, /* Object ID that is to be processed */
5961char *pBuf) /* Buffer used for the management data transfer */
5962{
5963 unsigned int PhysPortMax;
5964 unsigned int PhysPortIndex;
5965 SK_U8 Val8;
5966 SK_U32 Val32;
5967 SK_BOOL PortActiveFlag;
5968 SK_GEPORT *pPrt;
5969
5970 *pBuf = 0;
5971 PortActiveFlag = SK_FALSE;
5972 PhysPortMax = pAC->GIni.GIMacsFound;
5973
5974 for (PhysPortIndex = 0; PhysPortIndex < PhysPortMax;
5975 PhysPortIndex ++) {
5976
5977 pPrt = &pAC->GIni.GP[PhysPortIndex];
5978
5979 /* Check if the physical port is active */
5980 if (!pAC->Pnmi.Port[PhysPortIndex].ActiveFlag) {
5981
5982 continue;
5983 }
5984
5985 PortActiveFlag = SK_TRUE;
5986
5987 switch (Id) {
5988
5989 case OID_SKGE_PHY_TYPE:
5990 /* Check if it is the first active port */
5991 if (*pBuf == 0) {
5992 Val32 = pPrt->PhyType;
5993 SK_PNMI_STORE_U32(pBuf, Val32);
5994 continue;
5995 }
5996
5997 case OID_SKGE_LINK_CAP:
5998
5999 /*
6000 * Different capabilities should not happen, but
6001 * in the case of the cases OR them all together.
6002 * From a curious point of view the virtual port
6003 * is capable of all found capabilities.
6004 */
6005 *pBuf |= pPrt->PLinkCap;
6006 break;
6007
6008 case OID_SKGE_LINK_MODE:
6009 /* Check if it is the first active port */
6010 if (*pBuf == 0) {
6011
6012 *pBuf = pPrt->PLinkModeConf;
6013 continue;
6014 }
6015
6016 /*
6017 * If we find an active port with a different link
6018 * mode than the first one we return a value that
6019 * indicates that the link mode is indeterminated.
6020 */
6021 if (*pBuf != pPrt->PLinkModeConf) {
6022
6023 *pBuf = SK_LMODE_INDETERMINATED;
6024 }
6025 break;
6026
6027 case OID_SKGE_LINK_MODE_STATUS:
6028 /* Get the link mode of the physical port */
6029 Val8 = CalculateLinkModeStatus(pAC, IoC, PhysPortIndex);
6030
6031 /* Check if it is the first active port */
6032 if (*pBuf == 0) {
6033
6034 *pBuf = Val8;
6035 continue;
6036 }
6037
6038 /*
6039 * If we find an active port with a different link
6040 * mode status than the first one we return a value
6041 * that indicates that the link mode status is
6042 * indeterminated.
6043 */
6044 if (*pBuf != Val8) {
6045
6046 *pBuf = SK_LMODE_STAT_INDETERMINATED;
6047 }
6048 break;
6049
6050 case OID_SKGE_LINK_STATUS:
6051 /* Get the link status of the physical port */
6052 Val8 = CalculateLinkStatus(pAC, IoC, PhysPortIndex);
6053
6054 /* Check if it is the first active port */
6055 if (*pBuf == 0) {
6056
6057 *pBuf = Val8;
6058 continue;
6059 }
6060
6061 /*
6062 * If we find an active port with a different link
6063 * status than the first one, we return a value
6064 * that indicates that the link status is
6065 * indeterminated.
6066 */
6067 if (*pBuf != Val8) {
6068
6069 *pBuf = SK_PNMI_RLMT_LSTAT_INDETERMINATED;
6070 }
6071 break;
6072
6073 case OID_SKGE_FLOWCTRL_CAP:
6074 /* Check if it is the first active port */
6075 if (*pBuf == 0) {
6076
6077 *pBuf = pPrt->PFlowCtrlCap;
6078 continue;
6079 }
6080
6081 /*
6082 * From a curious point of view the virtual port
6083 * is capable of all found capabilities.
6084 */
6085 *pBuf |= pPrt->PFlowCtrlCap;
6086 break;
6087
6088 case OID_SKGE_FLOWCTRL_MODE:
6089 /* Check if it is the first active port */
6090 if (*pBuf == 0) {
6091
6092 *pBuf = pPrt->PFlowCtrlMode;
6093 continue;
6094 }
6095
6096 /*
6097 * If we find an active port with a different flow
6098 * control mode than the first one, we return a value
6099 * that indicates that the mode is indeterminated.
6100 */
6101 if (*pBuf != pPrt->PFlowCtrlMode) {
6102
6103 *pBuf = SK_FLOW_MODE_INDETERMINATED;
6104 }
6105 break;
6106
6107 case OID_SKGE_FLOWCTRL_STATUS:
6108 /* Check if it is the first active port */
6109 if (*pBuf == 0) {
6110
6111 *pBuf = pPrt->PFlowCtrlStatus;
6112 continue;
6113 }
6114
6115 /*
6116 * If we find an active port with a different flow
6117 * control status than the first one, we return a
6118 * value that indicates that the status is
6119 * indeterminated.
6120 */
6121 if (*pBuf != pPrt->PFlowCtrlStatus) {
6122
6123 *pBuf = SK_FLOW_STAT_INDETERMINATED;
6124 }
6125 break;
6126
6127 case OID_SKGE_PHY_OPERATION_CAP:
6128 /* Check if it is the first active port */
6129 if (*pBuf == 0) {
6130
6131 *pBuf = pPrt->PMSCap;
6132 continue;
6133 }
6134
6135 /*
6136 * From a curious point of view the virtual port
6137 * is capable of all found capabilities.
6138 */
6139 *pBuf |= pPrt->PMSCap;
6140 break;
6141
6142 case OID_SKGE_PHY_OPERATION_MODE:
6143 /* Check if it is the first active port */
6144 if (*pBuf == 0) {
6145
6146 *pBuf = pPrt->PMSMode;
6147 continue;
6148 }
6149
6150 /*
6151 * If we find an active port with a different master/
6152 * slave mode than the first one, we return a value
6153 * that indicates that the mode is indeterminated.
6154 */
6155 if (*pBuf != pPrt->PMSMode) {
6156
6157 *pBuf = SK_MS_MODE_INDETERMINATED;
6158 }
6159 break;
6160
6161 case OID_SKGE_PHY_OPERATION_STATUS:
6162 /* Check if it is the first active port */
6163 if (*pBuf == 0) {
6164
6165 *pBuf = pPrt->PMSStatus;
6166 continue;
6167 }
6168
6169 /*
6170 * If we find an active port with a different master/
6171 * slave status than the first one, we return a
6172 * value that indicates that the status is
6173 * indeterminated.
6174 */
6175 if (*pBuf != pPrt->PMSStatus) {
6176
6177 *pBuf = SK_MS_STAT_INDETERMINATED;
6178 }
6179 break;
6180
6181 case OID_SKGE_SPEED_MODE:
6182 /* Check if it is the first active port */
6183 if (*pBuf == 0) {
6184
6185 *pBuf = pPrt->PLinkSpeed;
6186 continue;
6187 }
6188
6189 /*
6190 * If we find an active port with a different flow
6191 * control mode than the first one, we return a value
6192 * that indicates that the mode is indeterminated.
6193 */
6194 if (*pBuf != pPrt->PLinkSpeed) {
6195
6196 *pBuf = SK_LSPEED_INDETERMINATED;
6197 }
6198 break;
6199
6200 case OID_SKGE_SPEED_STATUS:
6201 /* Check if it is the first active port */
6202 if (*pBuf == 0) {
6203
6204 *pBuf = pPrt->PLinkSpeedUsed;
6205 continue;
6206 }
6207
6208 /*
6209 * If we find an active port with a different flow
6210 * control status than the first one, we return a
6211 * value that indicates that the status is
6212 * indeterminated.
6213 */
6214 if (*pBuf != pPrt->PLinkSpeedUsed) {
6215
6216 *pBuf = SK_LSPEED_STAT_INDETERMINATED;
6217 }
6218 break;
6219 }
6220 }
6221
6222 /*
6223 * If no port is active return an indeterminated answer
6224 */
6225 if (!PortActiveFlag) {
6226
6227 switch (Id) {
6228
6229 case OID_SKGE_LINK_CAP:
6230 *pBuf = SK_LMODE_CAP_INDETERMINATED;
6231 break;
6232
6233 case OID_SKGE_LINK_MODE:
6234 *pBuf = SK_LMODE_INDETERMINATED;
6235 break;
6236
6237 case OID_SKGE_LINK_MODE_STATUS:
6238 *pBuf = SK_LMODE_STAT_INDETERMINATED;
6239 break;
6240
6241 case OID_SKGE_LINK_STATUS:
6242 *pBuf = SK_PNMI_RLMT_LSTAT_INDETERMINATED;
6243 break;
6244
6245 case OID_SKGE_FLOWCTRL_CAP:
6246 case OID_SKGE_FLOWCTRL_MODE:
6247 *pBuf = SK_FLOW_MODE_INDETERMINATED;
6248 break;
6249
6250 case OID_SKGE_FLOWCTRL_STATUS:
6251 *pBuf = SK_FLOW_STAT_INDETERMINATED;
6252 break;
6253
6254 case OID_SKGE_PHY_OPERATION_CAP:
6255 *pBuf = SK_MS_CAP_INDETERMINATED;
6256 break;
6257
6258 case OID_SKGE_PHY_OPERATION_MODE:
6259 *pBuf = SK_MS_MODE_INDETERMINATED;
6260 break;
6261
6262 case OID_SKGE_PHY_OPERATION_STATUS:
6263 *pBuf = SK_MS_STAT_INDETERMINATED;
6264 break;
6265 case OID_SKGE_SPEED_CAP:
6266 *pBuf = SK_LSPEED_CAP_INDETERMINATED;
6267 break;
6268
6269 case OID_SKGE_SPEED_MODE:
6270 *pBuf = SK_LSPEED_INDETERMINATED;
6271 break;
6272
6273 case OID_SKGE_SPEED_STATUS:
6274 *pBuf = SK_LSPEED_STAT_INDETERMINATED;
6275 break;
6276 }
6277 }
6278}
6279
6280/*****************************************************************************
6281 *
6282 * CalculateLinkStatus - Determins the link status of a physical port
6283 *
6284 * Description:
6285 * Determins the link status the following way:
6286 * LSTAT_PHY_DOWN: Link is down
6287 * LSTAT_AUTONEG: Auto-negotiation failed
6288 * LSTAT_LOG_DOWN: Link is up but RLMT did not yet put the port
6289 * logically up.
6290 * LSTAT_LOG_UP: RLMT marked the port as up
6291 *
6292 * Returns:
6293 * Link status of physical port
6294 */
6295PNMI_STATIC SK_U8 CalculateLinkStatus(
6296SK_AC *pAC, /* Pointer to adapter context */
6297SK_IOC IoC, /* IO context handle */
6298unsigned int PhysPortIndex) /* Physical port index */
6299{
6300 SK_U8 Result;
6301
6302 if (!pAC->GIni.GP[PhysPortIndex].PHWLinkUp) {
6303
6304 Result = SK_PNMI_RLMT_LSTAT_PHY_DOWN;
6305 }
6306 else if (pAC->GIni.GP[PhysPortIndex].PAutoNegFail > 0) {
6307
6308 Result = SK_PNMI_RLMT_LSTAT_AUTONEG;
6309 }
6310 else if (!pAC->Rlmt.Port[PhysPortIndex].PortDown) {
6311
6312 Result = SK_PNMI_RLMT_LSTAT_LOG_UP;
6313 }
6314 else {
6315 Result = SK_PNMI_RLMT_LSTAT_LOG_DOWN;
6316 }
6317
6318 return (Result);
6319}
6320
6321/*****************************************************************************
6322 *
6323 * CalculateLinkModeStatus - Determins the link mode status of a phys. port
6324 *
6325 * Description:
6326 * The COMMON module only tells us if the mode is half or full duplex.
6327 * But in the decade of auto sensing it is useful for the user to
6328 * know if the mode was negotiated or forced. Therefore we have a
6329 * look to the mode, which was last used by the negotiation process.
6330 *
6331 * Returns:
6332 * The link mode status
6333 */
6334PNMI_STATIC SK_U8 CalculateLinkModeStatus(
6335SK_AC *pAC, /* Pointer to adapter context */
6336SK_IOC IoC, /* IO context handle */
6337unsigned int PhysPortIndex) /* Physical port index */
6338{
6339 SK_U8 Result;
6340
6341 /* Get the current mode, which can be full or half duplex */
6342 Result = pAC->GIni.GP[PhysPortIndex].PLinkModeStatus;
6343
6344 /* Check if no valid mode could be found (link is down) */
6345 if (Result < SK_LMODE_STAT_HALF) {
6346
6347 Result = SK_LMODE_STAT_UNKNOWN;
6348 }
6349 else if (pAC->GIni.GP[PhysPortIndex].PLinkMode >= SK_LMODE_AUTOHALF) {
6350
6351 /*
6352 * Auto-negotiation was used to bring up the link. Change
6353 * the already found duplex status that it indicates
6354 * auto-negotiation was involved.
6355 */
6356 if (Result == SK_LMODE_STAT_HALF) {
6357
6358 Result = SK_LMODE_STAT_AUTOHALF;
6359 }
6360 else if (Result == SK_LMODE_STAT_FULL) {
6361
6362 Result = SK_LMODE_STAT_AUTOFULL;
6363 }
6364 }
6365
6366 return (Result);
6367}
6368
6369/*****************************************************************************
6370 *
6371 * GetVpdKeyArr - Obtain an array of VPD keys
6372 *
6373 * Description:
6374 * Read the VPD keys and build an array of VPD keys, which are
6375 * easy to access.
6376 *
6377 * Returns:
6378 * SK_PNMI_ERR_OK Task successfully performed.
6379 * SK_PNMI_ERR_GENERAL Something went wrong.
6380 */
6381PNMI_STATIC int GetVpdKeyArr(
6382SK_AC *pAC, /* Pointer to adapter context */
6383SK_IOC IoC, /* IO context handle */
6384char *pKeyArr, /* Ptr KeyArray */
6385unsigned int KeyArrLen, /* Length of array in bytes */
6386unsigned int *pKeyNo) /* Number of keys */
6387{
6388 unsigned int BufKeysLen = SK_PNMI_VPD_BUFSIZE;
6389 char BufKeys[SK_PNMI_VPD_BUFSIZE];
6390 unsigned int StartOffset;
6391 unsigned int Offset;
6392 int Index;
6393 int Ret;
6394
6395
6396 SK_MEMSET(pKeyArr, 0, KeyArrLen);
6397
6398 /*
6399 * Get VPD key list
6400 */
6401 Ret = VpdKeys(pAC, IoC, (char *)&BufKeys, (int *)&BufKeysLen,
6402 (int *)pKeyNo);
6403 if (Ret > 0) {
6404
6405 SK_ERR_LOG(pAC, SK_ERRCL_SW, SK_PNMI_ERR014,
6406 SK_PNMI_ERR014MSG);
6407
6408 return (SK_PNMI_ERR_GENERAL);
6409 }
6410 /* If no keys are available return now */
6411 if (*pKeyNo == 0 || BufKeysLen == 0) {
6412
6413 return (SK_PNMI_ERR_OK);
6414 }
6415 /*
6416 * If the key list is too long for us trunc it and give a
6417 * errorlog notification. This case should not happen because
6418 * the maximum number of keys is limited due to RAM limitations
6419 */
6420 if (*pKeyNo > SK_PNMI_VPD_ENTRIES) {
6421
6422 SK_ERR_LOG(pAC, SK_ERRCL_SW, SK_PNMI_ERR015,
6423 SK_PNMI_ERR015MSG);
6424
6425 *pKeyNo = SK_PNMI_VPD_ENTRIES;
6426 }
6427
6428 /*
6429 * Now build an array of fixed string length size and copy
6430 * the keys together.
6431 */
6432 for (Index = 0, StartOffset = 0, Offset = 0; Offset < BufKeysLen;
6433 Offset ++) {
6434
6435 if (BufKeys[Offset] != 0) {
6436
6437 continue;
6438 }
6439
6440 if (Offset - StartOffset > SK_PNMI_VPD_KEY_SIZE) {
6441
6442 SK_ERR_LOG(pAC, SK_ERRCL_SW, SK_PNMI_ERR016,
6443 SK_PNMI_ERR016MSG);
6444 return (SK_PNMI_ERR_GENERAL);
6445 }
6446
6447 SK_STRNCPY(pKeyArr + Index * SK_PNMI_VPD_KEY_SIZE,
6448 &BufKeys[StartOffset], SK_PNMI_VPD_KEY_SIZE);
6449
6450 Index ++;
6451 StartOffset = Offset + 1;
6452 }
6453
6454 /* Last key not zero terminated? Get it anyway */
6455 if (StartOffset < Offset) {
6456
6457 SK_STRNCPY(pKeyArr + Index * SK_PNMI_VPD_KEY_SIZE,
6458 &BufKeys[StartOffset], SK_PNMI_VPD_KEY_SIZE);
6459 }
6460
6461 return (SK_PNMI_ERR_OK);
6462}
6463
6464/*****************************************************************************
6465 *
6466 * SirqUpdate - Let the SIRQ update its internal values
6467 *
6468 * Description:
6469 * Just to be sure that the SIRQ module holds its internal data
6470 * structures up to date, we send an update event before we make
6471 * any access.
6472 *
6473 * Returns:
6474 * SK_PNMI_ERR_OK Task successfully performed.
6475 * SK_PNMI_ERR_GENERAL Something went wrong.
6476 */
6477PNMI_STATIC int SirqUpdate(
6478SK_AC *pAC, /* Pointer to adapter context */
6479SK_IOC IoC) /* IO context handle */
6480{
6481 SK_EVPARA EventParam;
6482
6483
6484 /* Was the module already updated during the current PNMI call? */
6485 if (pAC->Pnmi.SirqUpdatedFlag > 0) {
6486
6487 return (SK_PNMI_ERR_OK);
6488 }
6489
6490 /* Send an synchronuous update event to the module */
6491 SK_MEMSET((char *)&EventParam, 0, sizeof(EventParam));
6492 if (SkGeSirqEvent(pAC, IoC, SK_HWEV_UPDATE_STAT, EventParam) > 0) {
6493
6494 SK_ERR_LOG(pAC, SK_ERRCL_SW, SK_PNMI_ERR047,
6495 SK_PNMI_ERR047MSG);
6496
6497 return (SK_PNMI_ERR_GENERAL);
6498 }
6499
6500 return (SK_PNMI_ERR_OK);
6501}
6502
6503/*****************************************************************************
6504 *
6505 * RlmtUpdate - Let the RLMT update its internal values
6506 *
6507 * Description:
6508 * Just to be sure that the RLMT module holds its internal data
6509 * structures up to date, we send an update event before we make
6510 * any access.
6511 *
6512 * Returns:
6513 * SK_PNMI_ERR_OK Task successfully performed.
6514 * SK_PNMI_ERR_GENERAL Something went wrong.
6515 */
6516PNMI_STATIC int RlmtUpdate(
6517SK_AC *pAC, /* Pointer to adapter context */
6518SK_IOC IoC, /* IO context handle */
6519SK_U32 NetIndex) /* NetIndex (0..n), in single net mode allways zero */
6520{
6521 SK_EVPARA EventParam;
6522
6523
6524 /* Was the module already updated during the current PNMI call? */
6525 if (pAC->Pnmi.RlmtUpdatedFlag > 0) {
6526
6527 return (SK_PNMI_ERR_OK);
6528 }
6529
6530 /* Send an synchronuous update event to the module */
6531 SK_MEMSET((char *)&EventParam, 0, sizeof(EventParam));
6532 EventParam.Para32[0] = NetIndex;
6533 EventParam.Para32[1] = (SK_U32)-1;
6534 if (SkRlmtEvent(pAC, IoC, SK_RLMT_STATS_UPDATE, EventParam) > 0) {
6535
6536 SK_ERR_LOG(pAC, SK_ERRCL_SW, SK_PNMI_ERR048,
6537 SK_PNMI_ERR048MSG);
6538
6539 return (SK_PNMI_ERR_GENERAL);
6540 }
6541
6542 return (SK_PNMI_ERR_OK);
6543}
6544
6545/*****************************************************************************
6546 *
6547 * MacUpdate - Force the XMAC to output the current statistic
6548 *
6549 * Description:
6550 * The XMAC holds its statistic internally. To obtain the current
6551 * values we must send a command so that the statistic data will
6552 * be written to a predefined memory area on the adapter.
6553 *
6554 * Returns:
6555 * SK_PNMI_ERR_OK Task successfully performed.
6556 * SK_PNMI_ERR_GENERAL Something went wrong.
6557 */
6558PNMI_STATIC int MacUpdate(
6559SK_AC *pAC, /* Pointer to adapter context */
6560SK_IOC IoC, /* IO context handle */
6561unsigned int FirstMac, /* Index of the first Mac to be updated */
6562unsigned int LastMac) /* Index of the last Mac to be updated */
6563{
6564 unsigned int MacIndex;
6565
6566 /*
6567 * Were the statistics already updated during the
6568 * current PNMI call?
6569 */
6570 if (pAC->Pnmi.MacUpdatedFlag > 0) {
6571
6572 return (SK_PNMI_ERR_OK);
6573 }
6574
6575 /* Send an update command to all MACs specified */
6576 for (MacIndex = FirstMac; MacIndex <= LastMac; MacIndex ++) {
6577
6578 /*
6579 * 2002-09-13 pweber: Freeze the current SW counters.
6580 * (That should be done as close as
6581 * possible to the update of the
6582 * HW counters)
6583 */
6584 if (pAC->GIni.GIMacType == SK_MAC_XMAC) {
6585 pAC->Pnmi.BufPort[MacIndex] = pAC->Pnmi.Port[MacIndex];
6586 }
6587
6588 /* 2002-09-13 pweber: Update the HW counter */
6589 if (pAC->GIni.GIFunc.pFnMacUpdateStats(pAC, IoC, MacIndex) != 0) {
6590
6591 return (SK_PNMI_ERR_GENERAL);
6592 }
6593 }
6594
6595 return (SK_PNMI_ERR_OK);
6596}
6597
6598/*****************************************************************************
6599 *
6600 * GetStatVal - Retrieve an XMAC statistic counter
6601 *
6602 * Description:
6603 * Retrieves the statistic counter of a virtual or physical port. The
6604 * virtual port is identified by the index 0. It consists of all
6605 * currently active ports. To obtain the counter value for this port
6606 * we must add the statistic counter of all active ports. To grant
6607 * continuous counter values for the virtual port even when port
6608 * switches occur we must additionally add a delta value, which was
6609 * calculated during a SK_PNMI_EVT_RLMT_ACTIVE_UP event.
6610 *
6611 * Returns:
6612 * Requested statistic value
6613 */
6614PNMI_STATIC SK_U64 GetStatVal(
6615SK_AC *pAC, /* Pointer to adapter context */
6616SK_IOC IoC, /* IO context handle */
6617unsigned int LogPortIndex, /* Index of the logical Port to be processed */
6618unsigned int StatIndex, /* Index to statistic value */
6619SK_U32 NetIndex) /* NetIndex (0..n), in single net mode allways zero */
6620{
6621 unsigned int PhysPortIndex;
6622 unsigned int PhysPortMax;
6623 SK_U64 Val = 0;
6624
6625
6626 if (pAC->Pnmi.DualNetActiveFlag == SK_TRUE) { /* Dual net mode */
6627
6628 PhysPortIndex = NetIndex;
6629
6630 Val = GetPhysStatVal(pAC, IoC, PhysPortIndex, StatIndex);
6631 }
6632 else { /* Single Net mode */
6633
6634 if (LogPortIndex == 0) {
6635
6636 PhysPortMax = pAC->GIni.GIMacsFound;
6637
6638 /* Add counter of all active ports */
6639 for (PhysPortIndex = 0; PhysPortIndex < PhysPortMax;
6640 PhysPortIndex ++) {
6641
6642 if (pAC->Pnmi.Port[PhysPortIndex].ActiveFlag) {
6643
6644 Val += GetPhysStatVal(pAC, IoC, PhysPortIndex, StatIndex);
6645 }
6646 }
6647
6648 /* Correct value because of port switches */
6649 Val += pAC->Pnmi.VirtualCounterOffset[StatIndex];
6650 }
6651 else {
6652 /* Get counter value of physical port */
6653 PhysPortIndex = SK_PNMI_PORT_LOG2PHYS(pAC, LogPortIndex);
6654
6655 Val = GetPhysStatVal(pAC, IoC, PhysPortIndex, StatIndex);
6656 }
6657 }
6658 return (Val);
6659}
6660
6661/*****************************************************************************
6662 *
6663 * GetPhysStatVal - Get counter value for physical port
6664 *
6665 * Description:
6666 * Builds a 64bit counter value. Except for the octet counters
6667 * the lower 32bit are counted in hardware and the upper 32bit
6668 * in software by monitoring counter overflow interrupts in the
6669 * event handler. To grant continous counter values during XMAC
6670 * resets (caused by a workaround) we must add a delta value.
6671 * The delta was calculated in the event handler when a
6672 * SK_PNMI_EVT_XMAC_RESET was received.
6673 *
6674 * Returns:
6675 * Counter value
6676 */
6677PNMI_STATIC SK_U64 GetPhysStatVal(
6678SK_AC *pAC, /* Pointer to adapter context */
6679SK_IOC IoC, /* IO context handle */
6680unsigned int PhysPortIndex, /* Index of the logical Port to be processed */
6681unsigned int StatIndex) /* Index to statistic value */
6682{
6683 SK_U64 Val = 0;
6684 SK_U32 LowVal = 0;
6685 SK_U32 HighVal = 0;
6686 SK_U16 Word;
6687 int MacType;
6688 unsigned int HelpIndex;
6689 SK_GEPORT *pPrt;
6690
6691 SK_PNMI_PORT *pPnmiPrt;
6692 SK_GEMACFUNC *pFnMac;
6693
6694 pPrt = &pAC->GIni.GP[PhysPortIndex];
6695
6696 MacType = pAC->GIni.GIMacType;
6697
6698 /* 2002-09-17 pweber: For XMAC, use the frozen SW counters (BufPort) */
6699 if (MacType == SK_MAC_XMAC) {
6700 pPnmiPrt = &pAC->Pnmi.BufPort[PhysPortIndex];
6701 }
6702 else {
6703 pPnmiPrt = &pAC->Pnmi.Port[PhysPortIndex];
6704 }
6705
6706 pFnMac = &pAC->GIni.GIFunc;
6707
6708 switch (StatIndex) {
6709 case SK_PNMI_HTX:
6710 if (MacType == SK_MAC_GMAC) {
6711 (void)pFnMac->pFnMacStatistic(pAC, IoC, PhysPortIndex,
6712 StatAddr[SK_PNMI_HTX_BROADCAST][MacType].Reg,
6713 &LowVal);
6714 (void)pFnMac->pFnMacStatistic(pAC, IoC, PhysPortIndex,
6715 StatAddr[SK_PNMI_HTX_MULTICAST][MacType].Reg,
6716 &HighVal);
6717 LowVal += HighVal;
6718 (void)pFnMac->pFnMacStatistic(pAC, IoC, PhysPortIndex,
6719 StatAddr[SK_PNMI_HTX_UNICAST][MacType].Reg,
6720 &HighVal);
6721 LowVal += HighVal;
6722 }
6723 else {
6724 (void)pFnMac->pFnMacStatistic(pAC, IoC, PhysPortIndex,
6725 StatAddr[StatIndex][MacType].Reg,
6726 &LowVal);
6727 }
6728 HighVal = pPnmiPrt->CounterHigh[StatIndex];
6729 break;
6730
6731 case SK_PNMI_HRX:
6732 if (MacType == SK_MAC_GMAC) {
6733 (void)pFnMac->pFnMacStatistic(pAC, IoC, PhysPortIndex,
6734 StatAddr[SK_PNMI_HRX_BROADCAST][MacType].Reg,
6735 &LowVal);
6736 (void)pFnMac->pFnMacStatistic(pAC, IoC, PhysPortIndex,
6737 StatAddr[SK_PNMI_HRX_MULTICAST][MacType].Reg,
6738 &HighVal);
6739 LowVal += HighVal;
6740 (void)pFnMac->pFnMacStatistic(pAC, IoC, PhysPortIndex,
6741 StatAddr[SK_PNMI_HRX_UNICAST][MacType].Reg,
6742 &HighVal);
6743 LowVal += HighVal;
6744 }
6745 else {
6746 (void)pFnMac->pFnMacStatistic(pAC, IoC, PhysPortIndex,
6747 StatAddr[StatIndex][MacType].Reg,
6748 &LowVal);
6749 }
6750 HighVal = pPnmiPrt->CounterHigh[StatIndex];
6751 break;
6752
6753 case SK_PNMI_HTX_OCTET:
6754 case SK_PNMI_HRX_OCTET:
6755 (void)pFnMac->pFnMacStatistic(pAC, IoC, PhysPortIndex,
6756 StatAddr[StatIndex][MacType].Reg,
6757 &HighVal);
6758 (void)pFnMac->pFnMacStatistic(pAC, IoC, PhysPortIndex,
6759 StatAddr[StatIndex + 1][MacType].Reg,
6760 &LowVal);
6761 break;
6762
6763 case SK_PNMI_HTX_BURST:
6764 case SK_PNMI_HTX_EXCESS_DEF:
6765 case SK_PNMI_HTX_CARRIER:
6766 /* Not supported by GMAC */
6767 if (MacType == SK_MAC_GMAC) {
6768 return (Val);
6769 }
6770
6771 (void)pFnMac->pFnMacStatistic(pAC, IoC, PhysPortIndex,
6772 StatAddr[StatIndex][MacType].Reg,
6773 &LowVal);
6774 HighVal = pPnmiPrt->CounterHigh[StatIndex];
6775 break;
6776
6777 case SK_PNMI_HTX_MACC:
6778 /* GMAC only supports PAUSE MAC control frames */
6779 if (MacType == SK_MAC_GMAC) {
6780 HelpIndex = SK_PNMI_HTX_PMACC;
6781 }
6782 else {
6783 HelpIndex = StatIndex;
6784 }
6785
6786 (void)pFnMac->pFnMacStatistic(pAC, IoC, PhysPortIndex,
6787 StatAddr[HelpIndex][MacType].Reg,
6788 &LowVal);
6789
6790 HighVal = pPnmiPrt->CounterHigh[StatIndex];
6791 break;
6792
6793 case SK_PNMI_HTX_COL:
6794 case SK_PNMI_HRX_UNDERSIZE:
6795 /* Not supported by XMAC */
6796 if (MacType == SK_MAC_XMAC) {
6797 return (Val);
6798 }
6799
6800 (void)pFnMac->pFnMacStatistic(pAC, IoC, PhysPortIndex,
6801 StatAddr[StatIndex][MacType].Reg,
6802 &LowVal);
6803 HighVal = pPnmiPrt->CounterHigh[StatIndex];
6804 break;
6805
6806 case SK_PNMI_HTX_DEFFERAL:
6807 /* Not supported by GMAC */
6808 if (MacType == SK_MAC_GMAC) {
6809 return (Val);
6810 }
6811
6812 /*
6813 * XMAC counts frames with deferred transmission
6814 * even in full-duplex mode.
6815 *
6816 * In full-duplex mode the counter remains constant!
6817 */
6818 if ((pPrt->PLinkModeStatus == SK_LMODE_STAT_AUTOFULL) ||
6819 (pPrt->PLinkModeStatus == SK_LMODE_STAT_FULL)) {
6820
6821 LowVal = 0;
6822 HighVal = 0;
6823 }
6824 else {
6825 /* Otherwise get contents of hardware register */
6826 (void)pFnMac->pFnMacStatistic(pAC, IoC, PhysPortIndex,
6827 StatAddr[StatIndex][MacType].Reg,
6828 &LowVal);
6829 HighVal = pPnmiPrt->CounterHigh[StatIndex];
6830 }
6831 break;
6832
6833 case SK_PNMI_HRX_BADOCTET:
6834 /* Not supported by XMAC */
6835 if (MacType == SK_MAC_XMAC) {
6836 return (Val);
6837 }
6838
6839 (void)pFnMac->pFnMacStatistic(pAC, IoC, PhysPortIndex,
6840 StatAddr[StatIndex][MacType].Reg,
6841 &HighVal);
6842 (void)pFnMac->pFnMacStatistic(pAC, IoC, PhysPortIndex,
6843 StatAddr[StatIndex + 1][MacType].Reg,
6844 &LowVal);
6845 break;
6846
6847 case SK_PNMI_HTX_OCTETLOW:
6848 case SK_PNMI_HRX_OCTETLOW:
6849 case SK_PNMI_HRX_BADOCTETLOW:
6850 return (Val);
6851
6852 case SK_PNMI_HRX_LONGFRAMES:
6853 /* For XMAC the SW counter is managed by PNMI */
6854 if (MacType == SK_MAC_XMAC) {
6855 return (pPnmiPrt->StatRxLongFrameCts);
6856 }
6857
6858 (void)pFnMac->pFnMacStatistic(pAC, IoC, PhysPortIndex,
6859 StatAddr[StatIndex][MacType].Reg,
6860 &LowVal);
6861 HighVal = pPnmiPrt->CounterHigh[StatIndex];
6862 break;
6863
6864 case SK_PNMI_HRX_TOO_LONG:
6865 (void)pFnMac->pFnMacStatistic(pAC, IoC, PhysPortIndex,
6866 StatAddr[StatIndex][MacType].Reg,
6867 &LowVal);
6868 HighVal = pPnmiPrt->CounterHigh[StatIndex];
6869
6870 Val = (((SK_U64)HighVal << 32) | (SK_U64)LowVal);
6871
6872 if (MacType == SK_MAC_GMAC) {
6873 /* For GMAC the SW counter is additionally managed by PNMI */
6874 Val += pPnmiPrt->StatRxFrameTooLongCts;
6875 }
6876 else {
6877 /*
6878 * Frames longer than IEEE 802.3 frame max size are counted
6879 * by XMAC in frame_too_long counter even reception of long
6880 * frames was enabled and the frame was correct.
6881 * So correct the value by subtracting RxLongFrame counter.
6882 */
6883 Val -= pPnmiPrt->StatRxLongFrameCts;
6884 }
6885
6886 LowVal = (SK_U32)Val;
6887 HighVal = (SK_U32)(Val >> 32);
6888 break;
6889
6890 case SK_PNMI_HRX_SHORTS:
6891 /* Not supported by GMAC */
6892 if (MacType == SK_MAC_GMAC) {
6893 /* GM_RXE_FRAG?? */
6894 return (Val);
6895 }
6896
6897 /*
6898 * XMAC counts short frame errors even if link down (#10620)
6899 *
6900 * If link-down the counter remains constant
6901 */
6902 if (pPrt->PLinkModeStatus != SK_LMODE_STAT_UNKNOWN) {
6903
6904 /* Otherwise get incremental difference */
6905 (void)pFnMac->pFnMacStatistic(pAC, IoC, PhysPortIndex,
6906 StatAddr[StatIndex][MacType].Reg,
6907 &LowVal);
6908 HighVal = pPnmiPrt->CounterHigh[StatIndex];
6909
6910 Val = (((SK_U64)HighVal << 32) | (SK_U64)LowVal);
6911 Val -= pPnmiPrt->RxShortZeroMark;
6912
6913 LowVal = (SK_U32)Val;
6914 HighVal = (SK_U32)(Val >> 32);
6915 }
6916 break;
6917
6918 case SK_PNMI_HRX_MACC:
6919 case SK_PNMI_HRX_MACC_UNKWN:
6920 case SK_PNMI_HRX_BURST:
6921 case SK_PNMI_HRX_MISSED:
6922 case SK_PNMI_HRX_FRAMING:
6923 case SK_PNMI_HRX_CARRIER:
6924 case SK_PNMI_HRX_IRLENGTH:
6925 case SK_PNMI_HRX_SYMBOL:
6926 case SK_PNMI_HRX_CEXT:
6927 /* Not supported by GMAC */
6928 if (MacType == SK_MAC_GMAC) {
6929 return (Val);
6930 }
6931
6932 (void)pFnMac->pFnMacStatistic(pAC, IoC, PhysPortIndex,
6933 StatAddr[StatIndex][MacType].Reg,
6934 &LowVal);
6935 HighVal = pPnmiPrt->CounterHigh[StatIndex];
6936 break;
6937
6938 case SK_PNMI_HRX_PMACC_ERR:
6939 /* For GMAC the SW counter is managed by PNMI */
6940 if (MacType == SK_MAC_GMAC) {
6941 return (pPnmiPrt->StatRxPMaccErr);
6942 }
6943
6944 (void)pFnMac->pFnMacStatistic(pAC, IoC, PhysPortIndex,
6945 StatAddr[StatIndex][MacType].Reg,
6946 &LowVal);
6947 HighVal = pPnmiPrt->CounterHigh[StatIndex];
6948 break;
6949
6950 /* SW counter managed by PNMI */
6951 case SK_PNMI_HTX_SYNC:
6952 LowVal = (SK_U32)pPnmiPrt->StatSyncCts;
6953 HighVal = (SK_U32)(pPnmiPrt->StatSyncCts >> 32);
6954 break;
6955
6956 /* SW counter managed by PNMI */
6957 case SK_PNMI_HTX_SYNC_OCTET:
6958 LowVal = (SK_U32)pPnmiPrt->StatSyncOctetsCts;
6959 HighVal = (SK_U32)(pPnmiPrt->StatSyncOctetsCts >> 32);
6960 break;
6961
6962 case SK_PNMI_HRX_FCS:
6963 /*
6964 * Broadcom filters FCS errors and counts it in
6965 * Receive Error Counter register
6966 */
6967 if (pPrt->PhyType == SK_PHY_BCOM) {
6968 /* do not read while not initialized (PHY_READ hangs!)*/
6969 if (pPrt->PState != SK_PRT_RESET) {
6970 SkXmPhyRead(pAC, IoC, PhysPortIndex, PHY_BCOM_RE_CTR, &Word);
6971
6972 LowVal = Word;
6973 }
6974 HighVal = pPnmiPrt->CounterHigh[StatIndex];
6975 }
6976 else {
6977 (void)pFnMac->pFnMacStatistic(pAC, IoC, PhysPortIndex,
6978 StatAddr[StatIndex][MacType].Reg,
6979 &LowVal);
6980 HighVal = pPnmiPrt->CounterHigh[StatIndex];
6981 }
6982 break;
6983
6984 default:
6985 (void)pFnMac->pFnMacStatistic(pAC, IoC, PhysPortIndex,
6986 StatAddr[StatIndex][MacType].Reg,
6987 &LowVal);
6988 HighVal = pPnmiPrt->CounterHigh[StatIndex];
6989 break;
6990 }
6991
6992 Val = (((SK_U64)HighVal << 32) | (SK_U64)LowVal);
6993
6994 /* Correct value because of possible XMAC reset. XMAC Errata #2 */
6995 Val += pPnmiPrt->CounterOffset[StatIndex];
6996
6997 return (Val);
6998}
6999
7000/*****************************************************************************
7001 *
7002 * ResetCounter - Set all counters and timestamps to zero
7003 *
7004 * Description:
7005 * Notifies other common modules which store statistic data to
7006 * reset their counters and finally reset our own counters.
7007 *
7008 * Returns:
7009 * Nothing
7010 */
7011PNMI_STATIC void ResetCounter(
7012SK_AC *pAC, /* Pointer to adapter context */
7013SK_IOC IoC, /* IO context handle */
7014SK_U32 NetIndex)
7015{
7016 unsigned int PhysPortIndex;
7017 SK_EVPARA EventParam;
7018
7019
7020 SK_MEMSET((char *)&EventParam, 0, sizeof(EventParam));
7021
7022 /* Notify sensor module */
7023 SkEventQueue(pAC, SKGE_I2C, SK_I2CEV_CLEAR, EventParam);
7024
7025 /* Notify RLMT module */
7026 EventParam.Para32[0] = NetIndex;
7027 EventParam.Para32[1] = (SK_U32)-1;
7028 SkEventQueue(pAC, SKGE_RLMT, SK_RLMT_STATS_CLEAR, EventParam);
7029 EventParam.Para32[1] = 0;
7030
7031 /* Notify SIRQ module */
7032 SkEventQueue(pAC, SKGE_HWAC, SK_HWEV_CLEAR_STAT, EventParam);
7033
7034 /* Notify CSUM module */
7035#ifdef SK_USE_CSUM
7036 EventParam.Para32[0] = NetIndex;
7037 EventParam.Para32[1] = (SK_U32)-1;
7038 SkEventQueue(pAC, SKGE_CSUM, SK_CSUM_EVENT_CLEAR_PROTO_STATS,
7039 EventParam);
7040#endif /* SK_USE_CSUM */
7041
7042 /* Clear XMAC statistic */
7043 for (PhysPortIndex = 0; PhysPortIndex <
7044 (unsigned int)pAC->GIni.GIMacsFound; PhysPortIndex ++) {
7045
7046 (void)pAC->GIni.GIFunc.pFnMacResetCounter(pAC, IoC, PhysPortIndex);
7047
7048 SK_MEMSET((char *)&pAC->Pnmi.Port[PhysPortIndex].CounterHigh,
7049 0, sizeof(pAC->Pnmi.Port[PhysPortIndex].CounterHigh));
7050 SK_MEMSET((char *)&pAC->Pnmi.Port[PhysPortIndex].
7051 CounterOffset, 0, sizeof(pAC->Pnmi.Port[
7052 PhysPortIndex].CounterOffset));
7053 SK_MEMSET((char *)&pAC->Pnmi.Port[PhysPortIndex].StatSyncCts,
7054 0, sizeof(pAC->Pnmi.Port[PhysPortIndex].StatSyncCts));
7055 SK_MEMSET((char *)&pAC->Pnmi.Port[PhysPortIndex].
7056 StatSyncOctetsCts, 0, sizeof(pAC->Pnmi.Port[
7057 PhysPortIndex].StatSyncOctetsCts));
7058 SK_MEMSET((char *)&pAC->Pnmi.Port[PhysPortIndex].
7059 StatRxLongFrameCts, 0, sizeof(pAC->Pnmi.Port[
7060 PhysPortIndex].StatRxLongFrameCts));
7061 SK_MEMSET((char *)&pAC->Pnmi.Port[PhysPortIndex].
7062 StatRxFrameTooLongCts, 0, sizeof(pAC->Pnmi.Port[
7063 PhysPortIndex].StatRxFrameTooLongCts));
7064 SK_MEMSET((char *)&pAC->Pnmi.Port[PhysPortIndex].
7065 StatRxPMaccErr, 0, sizeof(pAC->Pnmi.Port[
7066 PhysPortIndex].StatRxPMaccErr));
7067 }
7068
7069 /*
7070 * Clear local statistics
7071 */
7072 SK_MEMSET((char *)&pAC->Pnmi.VirtualCounterOffset, 0,
7073 sizeof(pAC->Pnmi.VirtualCounterOffset));
7074 pAC->Pnmi.RlmtChangeCts = 0;
7075 pAC->Pnmi.RlmtChangeTime = 0;
7076 SK_MEMSET((char *)&pAC->Pnmi.RlmtChangeEstimate.EstValue[0], 0,
7077 sizeof(pAC->Pnmi.RlmtChangeEstimate.EstValue));
7078 pAC->Pnmi.RlmtChangeEstimate.EstValueIndex = 0;
7079 pAC->Pnmi.RlmtChangeEstimate.Estimate = 0;
7080 pAC->Pnmi.Port[NetIndex].TxSwQueueMax = 0;
7081 pAC->Pnmi.Port[NetIndex].TxRetryCts = 0;
7082 pAC->Pnmi.Port[NetIndex].RxIntrCts = 0;
7083 pAC->Pnmi.Port[NetIndex].TxIntrCts = 0;
7084 pAC->Pnmi.Port[NetIndex].RxNoBufCts = 0;
7085 pAC->Pnmi.Port[NetIndex].TxNoBufCts = 0;
7086 pAC->Pnmi.Port[NetIndex].TxUsedDescrNo = 0;
7087 pAC->Pnmi.Port[NetIndex].RxDeliveredCts = 0;
7088 pAC->Pnmi.Port[NetIndex].RxOctetsDeliveredCts = 0;
7089 pAC->Pnmi.Port[NetIndex].ErrRecoveryCts = 0;
7090}
7091
7092/*****************************************************************************
7093 *
7094 * GetTrapEntry - Get an entry in the trap buffer
7095 *
7096 * Description:
7097 * The trap buffer stores various events. A user application somehow
7098 * gets notified that an event occured and retrieves the trap buffer
7099 * contens (or simply polls the buffer). The buffer is organized as
7100 * a ring which stores the newest traps at the beginning. The oldest
7101 * traps are overwritten by the newest ones. Each trap entry has a
7102 * unique number, so that applications may detect new trap entries.
7103 *
7104 * Returns:
7105 * A pointer to the trap entry
7106 */
7107PNMI_STATIC char* GetTrapEntry(
7108SK_AC *pAC, /* Pointer to adapter context */
7109SK_U32 TrapId, /* SNMP ID of the trap */
7110unsigned int Size) /* Space needed for trap entry */
7111{
7112 unsigned int BufPad = pAC->Pnmi.TrapBufPad;
7113 unsigned int BufFree = pAC->Pnmi.TrapBufFree;
7114 unsigned int Beg = pAC->Pnmi.TrapQueueBeg;
7115 unsigned int End = pAC->Pnmi.TrapQueueEnd;
7116 char *pBuf = &pAC->Pnmi.TrapBuf[0];
7117 int Wrap;
7118 unsigned int NeededSpace;
7119 unsigned int EntrySize;
7120 SK_U32 Val32;
7121 SK_U64 Val64;
7122
7123
7124 /* Last byte of entry will get a copy of the entry length */
7125 Size ++;
7126
7127 /*
7128 * Calculate needed buffer space */
7129 if (Beg >= Size) {
7130
7131 NeededSpace = Size;
7132 Wrap = SK_FALSE;
7133 }
7134 else {
7135 NeededSpace = Beg + Size;
7136 Wrap = SK_TRUE;
7137 }
7138
7139 /*
7140 * Check if enough buffer space is provided. Otherwise
7141 * free some entries. Leave one byte space between begin
7142 * and end of buffer to make it possible to detect whether
7143 * the buffer is full or empty
7144 */
7145 while (BufFree < NeededSpace + 1) {
7146
7147 if (End == 0) {
7148
7149 End = SK_PNMI_TRAP_QUEUE_LEN;
7150 }
7151
7152 EntrySize = (unsigned int)*((unsigned char *)pBuf + End - 1);
7153 BufFree += EntrySize;
7154 End -= EntrySize;
7155#ifdef DEBUG
7156 SK_MEMSET(pBuf + End, (char)(-1), EntrySize);
7157#endif /* DEBUG */
7158 if (End == BufPad) {
7159#ifdef DEBUG
7160 SK_MEMSET(pBuf, (char)(-1), End);
7161#endif /* DEBUG */
7162 BufFree += End;
7163 End = 0;
7164 BufPad = 0;
7165 }
7166 }
7167
7168 /*
7169 * Insert new entry as first entry. Newest entries are
7170 * stored at the beginning of the queue.
7171 */
7172 if (Wrap) {
7173
7174 BufPad = Beg;
7175 Beg = SK_PNMI_TRAP_QUEUE_LEN - Size;
7176 }
7177 else {
7178 Beg = Beg - Size;
7179 }
7180 BufFree -= NeededSpace;
7181
7182 /* Save the current offsets */
7183 pAC->Pnmi.TrapQueueBeg = Beg;
7184 pAC->Pnmi.TrapQueueEnd = End;
7185 pAC->Pnmi.TrapBufPad = BufPad;
7186 pAC->Pnmi.TrapBufFree = BufFree;
7187
7188 /* Initialize the trap entry */
7189 *(pBuf + Beg + Size - 1) = (char)Size;
7190 *(pBuf + Beg) = (char)Size;
7191 Val32 = (pAC->Pnmi.TrapUnique) ++;
7192 SK_PNMI_STORE_U32(pBuf + Beg + 1, Val32);
7193 SK_PNMI_STORE_U32(pBuf + Beg + 1 + sizeof(SK_U32), TrapId);
7194 Val64 = SK_PNMI_HUNDREDS_SEC(SkOsGetTime(pAC));
7195 SK_PNMI_STORE_U64(pBuf + Beg + 1 + 2 * sizeof(SK_U32), Val64);
7196
7197 return (pBuf + Beg);
7198}
7199
7200/*****************************************************************************
7201 *
7202 * CopyTrapQueue - Copies the trap buffer for the TRAP OID
7203 *
7204 * Description:
7205 * On a query of the TRAP OID the trap buffer contents will be
7206 * copied continuously to the request buffer, which must be large
7207 * enough. No length check is performed.
7208 *
7209 * Returns:
7210 * Nothing
7211 */
7212PNMI_STATIC void CopyTrapQueue(
7213SK_AC *pAC, /* Pointer to adapter context */
7214char *pDstBuf) /* Buffer to which the queued traps will be copied */
7215{
7216 unsigned int BufPad = pAC->Pnmi.TrapBufPad;
7217 unsigned int Trap = pAC->Pnmi.TrapQueueBeg;
7218 unsigned int End = pAC->Pnmi.TrapQueueEnd;
7219 char *pBuf = &pAC->Pnmi.TrapBuf[0];
7220 unsigned int Len;
7221 unsigned int DstOff = 0;
7222
7223
7224 while (Trap != End) {
7225
7226 Len = (unsigned int)*(pBuf + Trap);
7227
7228 /*
7229 * Last byte containing a copy of the length will
7230 * not be copied.
7231 */
7232 *(pDstBuf + DstOff) = (char)(Len - 1);
7233 SK_MEMCPY(pDstBuf + DstOff + 1, pBuf + Trap + 1, Len - 2);
7234 DstOff += Len - 1;
7235
7236 Trap += Len;
7237 if (Trap == SK_PNMI_TRAP_QUEUE_LEN) {
7238
7239 Trap = BufPad;
7240 }
7241 }
7242}
7243
7244/*****************************************************************************
7245 *
7246 * GetTrapQueueLen - Get the length of the trap buffer
7247 *
7248 * Description:
7249 * Evaluates the number of currently stored traps and the needed
7250 * buffer size to retrieve them.
7251 *
7252 * Returns:
7253 * Nothing
7254 */
7255PNMI_STATIC void GetTrapQueueLen(
7256SK_AC *pAC, /* Pointer to adapter context */
7257unsigned int *pLen, /* Length in Bytes of all queued traps */
7258unsigned int *pEntries) /* Returns number of trapes stored in queue */
7259{
7260 unsigned int BufPad = pAC->Pnmi.TrapBufPad;
7261 unsigned int Trap = pAC->Pnmi.TrapQueueBeg;
7262 unsigned int End = pAC->Pnmi.TrapQueueEnd;
7263 char *pBuf = &pAC->Pnmi.TrapBuf[0];
7264 unsigned int Len;
7265 unsigned int Entries = 0;
7266 unsigned int TotalLen = 0;
7267
7268
7269 while (Trap != End) {
7270
7271 Len = (unsigned int)*(pBuf + Trap);
7272 TotalLen += Len - 1;
7273 Entries ++;
7274
7275 Trap += Len;
7276 if (Trap == SK_PNMI_TRAP_QUEUE_LEN) {
7277
7278 Trap = BufPad;
7279 }
7280 }
7281
7282 *pEntries = Entries;
7283 *pLen = TotalLen;
7284}
7285
7286/*****************************************************************************
7287 *
7288 * QueueSimpleTrap - Store a simple trap to the trap buffer
7289 *
7290 * Description:
7291 * A simple trap is a trap with now additional data. It consists
7292 * simply of a trap code.
7293 *
7294 * Returns:
7295 * Nothing
7296 */
7297PNMI_STATIC void QueueSimpleTrap(
7298SK_AC *pAC, /* Pointer to adapter context */
7299SK_U32 TrapId) /* Type of sensor trap */
7300{
7301 GetTrapEntry(pAC, TrapId, SK_PNMI_TRAP_SIMPLE_LEN);
7302}
7303
7304/*****************************************************************************
7305 *
7306 * QueueSensorTrap - Stores a sensor trap in the trap buffer
7307 *
7308 * Description:
7309 * Gets an entry in the trap buffer and fills it with sensor related
7310 * data.
7311 *
7312 * Returns:
7313 * Nothing
7314 */
7315PNMI_STATIC void QueueSensorTrap(
7316SK_AC *pAC, /* Pointer to adapter context */
7317SK_U32 TrapId, /* Type of sensor trap */
7318unsigned int SensorIndex) /* Index of sensor which caused the trap */
7319{
7320 char *pBuf;
7321 unsigned int Offset;
7322 unsigned int DescrLen;
7323 SK_U32 Val32;
7324
7325
7326 /* Get trap buffer entry */
7327 DescrLen = SK_STRLEN(pAC->I2c.SenTable[SensorIndex].SenDesc);
7328 pBuf = GetTrapEntry(pAC, TrapId,
7329 SK_PNMI_TRAP_SENSOR_LEN_BASE + DescrLen);
7330 Offset = SK_PNMI_TRAP_SIMPLE_LEN;
7331
7332 /* Store additionally sensor trap related data */
7333 Val32 = OID_SKGE_SENSOR_INDEX;
7334 SK_PNMI_STORE_U32(pBuf + Offset, Val32);
7335 *(pBuf + Offset + 4) = 4;
7336 Val32 = (SK_U32)SensorIndex;
7337 SK_PNMI_STORE_U32(pBuf + Offset + 5, Val32);
7338 Offset += 9;
7339
7340 Val32 = (SK_U32)OID_SKGE_SENSOR_DESCR;
7341 SK_PNMI_STORE_U32(pBuf + Offset, Val32);
7342 *(pBuf + Offset + 4) = (char)DescrLen;
7343 SK_MEMCPY(pBuf + Offset + 5, pAC->I2c.SenTable[SensorIndex].SenDesc,
7344 DescrLen);
7345 Offset += DescrLen + 5;
7346
7347 Val32 = OID_SKGE_SENSOR_TYPE;
7348 SK_PNMI_STORE_U32(pBuf + Offset, Val32);
7349 *(pBuf + Offset + 4) = 1;
7350 *(pBuf + Offset + 5) = (char)pAC->I2c.SenTable[SensorIndex].SenType;
7351 Offset += 6;
7352
7353 Val32 = OID_SKGE_SENSOR_VALUE;
7354 SK_PNMI_STORE_U32(pBuf + Offset, Val32);
7355 *(pBuf + Offset + 4) = 4;
7356 Val32 = (SK_U32)pAC->I2c.SenTable[SensorIndex].SenValue;
7357 SK_PNMI_STORE_U32(pBuf + Offset + 5, Val32);
7358}
7359
7360/*****************************************************************************
7361 *
7362 * QueueRlmtNewMacTrap - Store a port switch trap in the trap buffer
7363 *
7364 * Description:
7365 * Nothing further to explain.
7366 *
7367 * Returns:
7368 * Nothing
7369 */
7370PNMI_STATIC void QueueRlmtNewMacTrap(
7371SK_AC *pAC, /* Pointer to adapter context */
7372unsigned int ActiveMac) /* Index (0..n) of the currently active port */
7373{
7374 char *pBuf;
7375 SK_U32 Val32;
7376
7377
7378 pBuf = GetTrapEntry(pAC, OID_SKGE_TRAP_RLMT_CHANGE_PORT,
7379 SK_PNMI_TRAP_RLMT_CHANGE_LEN);
7380
7381 Val32 = OID_SKGE_RLMT_PORT_ACTIVE;
7382 SK_PNMI_STORE_U32(pBuf + SK_PNMI_TRAP_SIMPLE_LEN, Val32);
7383 *(pBuf + SK_PNMI_TRAP_SIMPLE_LEN + 4) = 1;
7384 *(pBuf + SK_PNMI_TRAP_SIMPLE_LEN + 5) = (char)ActiveMac;
7385}
7386
7387/*****************************************************************************
7388 *
7389 * QueueRlmtPortTrap - Store port related RLMT trap to trap buffer
7390 *
7391 * Description:
7392 * Nothing further to explain.
7393 *
7394 * Returns:
7395 * Nothing
7396 */
7397PNMI_STATIC void QueueRlmtPortTrap(
7398SK_AC *pAC, /* Pointer to adapter context */
7399SK_U32 TrapId, /* Type of RLMT port trap */
7400unsigned int PortIndex) /* Index of the port, which changed its state */
7401{
7402 char *pBuf;
7403 SK_U32 Val32;
7404
7405
7406 pBuf = GetTrapEntry(pAC, TrapId, SK_PNMI_TRAP_RLMT_PORT_LEN);
7407
7408 Val32 = OID_SKGE_RLMT_PORT_INDEX;
7409 SK_PNMI_STORE_U32(pBuf + SK_PNMI_TRAP_SIMPLE_LEN, Val32);
7410 *(pBuf + SK_PNMI_TRAP_SIMPLE_LEN + 4) = 1;
7411 *(pBuf + SK_PNMI_TRAP_SIMPLE_LEN + 5) = (char)PortIndex;
7412}
7413
7414/*****************************************************************************
7415 *
7416 * CopyMac - Copies a MAC address
7417 *
7418 * Description:
7419 * Nothing further to explain.
7420 *
7421 * Returns:
7422 * Nothing
7423 */
7424PNMI_STATIC void CopyMac(
7425char *pDst, /* Pointer to destination buffer */
7426SK_MAC_ADDR *pMac) /* Pointer of Source */
7427{
7428 int i;
7429
7430
7431 for (i = 0; i < sizeof(SK_MAC_ADDR); i ++) {
7432
7433 *(pDst + i) = pMac->a[i];
7434 }
7435}
7436
7437#ifdef SK_POWER_MGMT
7438/*****************************************************************************
7439 *
7440 * PowerManagement - OID handler function of PowerManagement OIDs
7441 *
7442 * Description:
7443 * The code is simple. No description necessary.
7444 *
7445 * Returns:
7446 * SK_PNMI_ERR_OK The request was successfully performed.
7447 * SK_PNMI_ERR_GENERAL A general severe internal error occured.
7448 * SK_PNMI_ERR_TOO_SHORT The passed buffer is too short to contain
7449 * the correct data (e.g. a 32bit value is
7450 * needed, but a 16 bit value was passed).
7451 * SK_PNMI_ERR_UNKNOWN_INST The requested instance of the OID doesn't
7452 * exist (e.g. port instance 3 on a two port
7453 * adapter.
7454 */
7455
7456PNMI_STATIC int PowerManagement(
7457SK_AC *pAC, /* Pointer to adapter context */
7458SK_IOC IoC, /* IO context handle */
7459int Action, /* Get/PreSet/Set action */
7460SK_U32 Id, /* Object ID that is to be processed */
7461char *pBuf, /* Buffer to which to mgmt data will be retrieved */
7462unsigned int *pLen, /* On call: buffer length. On return: used buffer */
7463SK_U32 Instance, /* Instance (1..n) that is to be queried or -1 */
7464unsigned int TableIndex, /* Index to the Id table */
7465SK_U32 NetIndex) /* NetIndex (0..n), in single net mode allways zero */
7466{
7467
7468 SK_U32 RetCode = SK_PNMI_ERR_GENERAL;
7469
7470 /*
7471 * Check instance. We only handle single instance variables
7472 */
7473 if (Instance != (SK_U32)(-1) && Instance != 1) {
7474
7475 *pLen = 0;
7476 return (SK_PNMI_ERR_UNKNOWN_INST);
7477 }
7478
7479
7480 /* Check length */
7481 switch (Id) {
7482
7483 case OID_PNP_CAPABILITIES:
7484 if (*pLen < sizeof(SK_PNP_CAPABILITIES)) {
7485
7486 *pLen = sizeof(SK_PNP_CAPABILITIES);
7487 return (SK_PNMI_ERR_TOO_SHORT);
7488 }
7489 break;
7490
7491 case OID_PNP_SET_POWER:
7492 case OID_PNP_QUERY_POWER:
7493 if (*pLen < sizeof(SK_DEVICE_POWER_STATE))
7494 {
7495 *pLen = sizeof(SK_DEVICE_POWER_STATE);
7496 return (SK_PNMI_ERR_TOO_SHORT);
7497 }
7498 break;
7499
7500 case OID_PNP_ADD_WAKE_UP_PATTERN:
7501 case OID_PNP_REMOVE_WAKE_UP_PATTERN:
7502 if (*pLen < sizeof(SK_PM_PACKET_PATTERN)) {
7503
7504 *pLen = sizeof(SK_PM_PACKET_PATTERN);
7505 return (SK_PNMI_ERR_TOO_SHORT);
7506 }
7507 break;
7508
7509 case OID_PNP_ENABLE_WAKE_UP:
7510 if (*pLen < sizeof(SK_U32)) {
7511
7512 *pLen = sizeof(SK_U32);
7513 return (SK_PNMI_ERR_TOO_SHORT);
7514 }
7515 break;
7516 }
7517
7518 /*
7519 * Perform action
7520 */
7521 if (Action == SK_PNMI_GET) {
7522
7523 /*
7524 * Get value
7525 */
7526 switch (Id) {
7527
7528 case OID_PNP_CAPABILITIES:
7529 RetCode = SkPowerQueryPnPCapabilities(pAC, IoC, pBuf, pLen);
7530 break;
7531
7532 case OID_PNP_QUERY_POWER:
7533 /* The Windows DDK describes: An OID_PNP_QUERY_POWER requests
7534 the miniport to indicate whether it can transition its NIC
7535 to the low-power state.
7536 A miniport driver must always return NDIS_STATUS_SUCCESS
7537 to a query of OID_PNP_QUERY_POWER. */
7538 *pLen = sizeof(SK_DEVICE_POWER_STATE);
7539 RetCode = SK_PNMI_ERR_OK;
7540 break;
7541
7542 /* NDIS handles these OIDs as write-only.
7543 * So in case of get action the buffer with written length = 0
7544 * is returned
7545 */
7546 case OID_PNP_SET_POWER:
7547 case OID_PNP_ADD_WAKE_UP_PATTERN:
7548 case OID_PNP_REMOVE_WAKE_UP_PATTERN:
7549 *pLen = 0;
7550 RetCode = SK_PNMI_ERR_NOT_SUPPORTED;
7551 break;
7552
7553 case OID_PNP_ENABLE_WAKE_UP:
7554 RetCode = SkPowerGetEnableWakeUp(pAC, IoC, pBuf, pLen);
7555 break;
7556
7557 default:
7558 RetCode = SK_PNMI_ERR_GENERAL;
7559 break;
7560 }
7561
7562 return (RetCode);
7563 }
7564
7565
7566 /*
7567 * Perform preset or set
7568 */
7569
7570 /* POWER module does not support PRESET action */
7571 if (Action == SK_PNMI_PRESET) {
7572 return (SK_PNMI_ERR_OK);
7573 }
7574
7575 switch (Id) {
7576 case OID_PNP_SET_POWER:
7577 RetCode = SkPowerSetPower(pAC, IoC, pBuf, pLen);
7578 break;
7579
7580 case OID_PNP_ADD_WAKE_UP_PATTERN:
7581 RetCode = SkPowerAddWakeUpPattern(pAC, IoC, pBuf, pLen);
7582 break;
7583
7584 case OID_PNP_REMOVE_WAKE_UP_PATTERN:
7585 RetCode = SkPowerRemoveWakeUpPattern(pAC, IoC, pBuf, pLen);
7586 break;
7587
7588 case OID_PNP_ENABLE_WAKE_UP:
7589 RetCode = SkPowerSetEnableWakeUp(pAC, IoC, pBuf, pLen);
7590 break;
7591
7592 default:
7593 RetCode = SK_PNMI_ERR_READ_ONLY;
7594 }
7595
7596 return (RetCode);
7597}
7598#endif /* SK_POWER_MGMT */
7599
7600#ifdef SK_DIAG_SUPPORT
7601/*****************************************************************************
7602 *
7603 * DiagActions - OID handler function of Diagnostic driver
7604 *
7605 * Description:
7606 * The code is simple. No description necessary.
7607 *
7608 * Returns:
7609 * SK_PNMI_ERR_OK The request was successfully performed.
7610 * SK_PNMI_ERR_GENERAL A general severe internal error occured.
7611 * SK_PNMI_ERR_TOO_SHORT The passed buffer is too short to contain
7612 * the correct data (e.g. a 32bit value is
7613 * needed, but a 16 bit value was passed).
7614 * SK_PNMI_ERR_UNKNOWN_INST The requested instance of the OID doesn't
7615 * exist (e.g. port instance 3 on a two port
7616 * adapter.
7617 */
7618
7619PNMI_STATIC int DiagActions(
7620SK_AC *pAC, /* Pointer to adapter context */
7621SK_IOC IoC, /* IO context handle */
7622int Action, /* GET/PRESET/SET action */
7623SK_U32 Id, /* Object ID that is to be processed */
7624char *pBuf, /* Buffer used for the management data transfer */
7625unsigned int *pLen, /* On call: pBuf buffer length. On return: used buffer */
7626SK_U32 Instance, /* Instance (1..n) that is to be queried or -1 */
7627unsigned int TableIndex, /* Index to the Id table */
7628SK_U32 NetIndex) /* NetIndex (0..n), in single net mode always zero */
7629{
7630
7631 SK_U32 DiagStatus;
7632 SK_U32 RetCode = SK_PNMI_ERR_GENERAL;
7633
7634 /*
7635 * Check instance. We only handle single instance variables.
7636 */
7637 if (Instance != (SK_U32)(-1) && Instance != 1) {
7638
7639 *pLen = 0;
7640 return (SK_PNMI_ERR_UNKNOWN_INST);
7641 }
7642
7643 /*
7644 * Check length.
7645 */
7646 switch (Id) {
7647
7648 case OID_SKGE_DIAG_MODE:
7649 if (*pLen < sizeof(SK_U32)) {
7650
7651 *pLen = sizeof(SK_U32);
7652 return (SK_PNMI_ERR_TOO_SHORT);
7653 }
7654 break;
7655
7656 default:
7657 SK_ERR_LOG(pAC, SK_ERRCL_SW, SK_PNMI_ERR040, SK_PNMI_ERR040MSG);
7658 *pLen = 0;
7659 return (SK_PNMI_ERR_GENERAL);
7660 }
7661
7662 /* Perform action. */
7663
7664 /* GET value. */
7665 if (Action == SK_PNMI_GET) {
7666
7667 switch (Id) {
7668
7669 case OID_SKGE_DIAG_MODE:
7670 DiagStatus = pAC->Pnmi.DiagAttached;
7671 SK_PNMI_STORE_U32(pBuf, DiagStatus);
7672 *pLen = sizeof(SK_U32);
7673 RetCode = SK_PNMI_ERR_OK;
7674 break;
7675
7676 default:
7677 *pLen = 0;
7678 RetCode = SK_PNMI_ERR_GENERAL;
7679 break;
7680 }
7681 return (RetCode);
7682 }
7683
7684 /* From here SET or PRESET value. */
7685
7686 /* PRESET value is not supported. */
7687 if (Action == SK_PNMI_PRESET) {
7688 return (SK_PNMI_ERR_OK);
7689 }
7690
7691 /* SET value. */
7692 switch (Id) {
7693 case OID_SKGE_DIAG_MODE:
7694
7695 /* Handle the SET. */
7696 switch (*pBuf) {
7697
7698 /* Attach the DIAG to this adapter. */
7699 case SK_DIAG_ATTACHED:
7700 /* Check if we come from running */
7701 if (pAC->Pnmi.DiagAttached == SK_DIAG_RUNNING) {
7702
7703 RetCode = SkDrvLeaveDiagMode(pAC);
7704
7705 }
7706 else if (pAC->Pnmi.DiagAttached == SK_DIAG_IDLE) {
7707
7708 RetCode = SK_PNMI_ERR_OK;
7709 }
7710
7711 else {
7712
7713 RetCode = SK_PNMI_ERR_GENERAL;
7714
7715 }
7716
7717 if (RetCode == SK_PNMI_ERR_OK) {
7718
7719 pAC->Pnmi.DiagAttached = SK_DIAG_ATTACHED;
7720 }
7721 break;
7722
7723 /* Enter the DIAG mode in the driver. */
7724 case SK_DIAG_RUNNING:
7725 RetCode = SK_PNMI_ERR_OK;
7726
7727 /*
7728 * If DiagAttached is set, we can tell the driver
7729 * to enter the DIAG mode.
7730 */
7731 if (pAC->Pnmi.DiagAttached == SK_DIAG_ATTACHED) {
7732 /* If DiagMode is not active, we can enter it. */
7733 if (!pAC->DiagModeActive) {
7734
7735 RetCode = SkDrvEnterDiagMode(pAC);
7736 }
7737 else {
7738
7739 RetCode = SK_PNMI_ERR_GENERAL;
7740 }
7741 }
7742 else {
7743
7744 RetCode = SK_PNMI_ERR_GENERAL;
7745 }
7746
7747 if (RetCode == SK_PNMI_ERR_OK) {
7748
7749 pAC->Pnmi.DiagAttached = SK_DIAG_RUNNING;
7750 }
7751 break;
7752
7753 case SK_DIAG_IDLE:
7754 /* Check if we come from running */
7755 if (pAC->Pnmi.DiagAttached == SK_DIAG_RUNNING) {
7756
7757 RetCode = SkDrvLeaveDiagMode(pAC);
7758
7759 }
7760 else if (pAC->Pnmi.DiagAttached == SK_DIAG_ATTACHED) {
7761
7762 RetCode = SK_PNMI_ERR_OK;
7763 }
7764
7765 else {
7766
7767 RetCode = SK_PNMI_ERR_GENERAL;
7768
7769 }
7770
7771 if (RetCode == SK_PNMI_ERR_OK) {
7772
7773 pAC->Pnmi.DiagAttached = SK_DIAG_IDLE;
7774 }
7775 break;
7776
7777 default:
7778 RetCode = SK_PNMI_ERR_BAD_VALUE;
7779 break;
7780 }
7781 break;
7782
7783 default:
7784 RetCode = SK_PNMI_ERR_GENERAL;
7785 }
7786
7787 if (RetCode == SK_PNMI_ERR_OK) {
7788 *pLen = sizeof(SK_U32);
7789 }
7790 else {
7791
7792 *pLen = 0;
7793 }
7794 return (RetCode);
7795}
7796#endif /* SK_DIAG_SUPPORT */
7797
7798/*****************************************************************************
7799 *
7800 * Vct - OID handler function of OIDs
7801 *
7802 * Description:
7803 * The code is simple. No description necessary.
7804 *
7805 * Returns:
7806 * SK_PNMI_ERR_OK The request was performed successfully.
7807 * SK_PNMI_ERR_GENERAL A general severe internal error occured.
7808 * SK_PNMI_ERR_TOO_SHORT The passed buffer is too short to contain
7809 * the correct data (e.g. a 32bit value is
7810 * needed, but a 16 bit value was passed).
7811 * SK_PNMI_ERR_UNKNOWN_INST The requested instance of the OID doesn't
7812 * exist (e.g. port instance 3 on a two port
7813 * adapter).
7814 * SK_PNMI_ERR_READ_ONLY Only the Get action is allowed.
7815 *
7816 */
7817
7818PNMI_STATIC int Vct(
7819SK_AC *pAC, /* Pointer to adapter context */
7820SK_IOC IoC, /* IO context handle */
7821int Action, /* GET/PRESET/SET action */
7822SK_U32 Id, /* Object ID that is to be processed */
7823char *pBuf, /* Buffer used for the management data transfer */
7824unsigned int *pLen, /* On call: pBuf buffer length. On return: used buffer */
7825SK_U32 Instance, /* Instance (-1,2..n) that is to be queried */
7826unsigned int TableIndex, /* Index to the Id table */
7827SK_U32 NetIndex) /* NetIndex (0..n), in single net mode always zero */
7828{
7829 SK_GEPORT *pPrt;
7830 SK_PNMI_VCT *pVctBackupData;
7831 SK_U32 LogPortMax;
7832 SK_U32 PhysPortMax;
7833 SK_U32 PhysPortIndex;
7834 SK_U32 Limit;
7835 SK_U32 Offset;
7836 SK_BOOL Link;
7837 SK_U32 RetCode = SK_PNMI_ERR_GENERAL;
7838 int i;
7839 SK_EVPARA Para;
7840 SK_U32 CableLength;
7841
7842 /*
7843 * Calculate the port indexes from the instance.
7844 */
7845 PhysPortMax = pAC->GIni.GIMacsFound;
7846 LogPortMax = SK_PNMI_PORT_PHYS2LOG(PhysPortMax);
7847
7848 /* Dual net mode? */
7849 if (pAC->Pnmi.DualNetActiveFlag == SK_TRUE) {
7850 LogPortMax--;
7851 }
7852
7853 if ((Instance != (SK_U32) (-1))) {
7854 /* Check instance range. */
7855 if ((Instance < 2) || (Instance > LogPortMax)) {
7856 *pLen = 0;
7857 return (SK_PNMI_ERR_UNKNOWN_INST);
7858 }
7859
7860 if (pAC->Pnmi.DualNetActiveFlag == SK_TRUE) {
7861 PhysPortIndex = NetIndex;
7862 }
7863 else {
7864 PhysPortIndex = Instance - 2;
7865 }
7866 Limit = PhysPortIndex + 1;
7867 }
7868 else {
7869 /*
7870 * Instance == (SK_U32) (-1), get all Instances of that OID.
7871 *
7872 * Not implemented yet. May be used in future releases.
7873 */
7874 PhysPortIndex = 0;
7875 Limit = PhysPortMax;
7876 }
7877
7878 pPrt = &pAC->GIni.GP[PhysPortIndex];
7879 if (pPrt->PHWLinkUp) {
7880 Link = SK_TRUE;
7881 }
7882 else {
7883 Link = SK_FALSE;
7884 }
7885
7886 /* Check MAC type */
7887 if (pPrt->PhyType != SK_PHY_MARV_COPPER) {
7888 *pLen = 0;
7889 return (SK_PNMI_ERR_GENERAL);
7890 }
7891
7892 /* Initialize backup data pointer. */
7893 pVctBackupData = &pAC->Pnmi.VctBackup[PhysPortIndex];
7894
7895 /* Check action type */
7896 if (Action == SK_PNMI_GET) {
7897 /* Check length */
7898 switch (Id) {
7899
7900 case OID_SKGE_VCT_GET:
7901 if (*pLen < (Limit - PhysPortIndex) * sizeof(SK_PNMI_VCT)) {
7902 *pLen = (Limit - PhysPortIndex) * sizeof(SK_PNMI_VCT);
7903 return (SK_PNMI_ERR_TOO_SHORT);
7904 }
7905 break;
7906
7907 case OID_SKGE_VCT_STATUS:
7908 if (*pLen < (Limit - PhysPortIndex) * sizeof(SK_U8)) {
7909 *pLen = (Limit - PhysPortIndex) * sizeof(SK_U8);
7910 return (SK_PNMI_ERR_TOO_SHORT);
7911 }
7912 break;
7913
7914 default:
7915 *pLen = 0;
7916 return (SK_PNMI_ERR_GENERAL);
7917 }
7918
7919 /* Get value */
7920 Offset = 0;
7921 for (; PhysPortIndex < Limit; PhysPortIndex++) {
7922 switch (Id) {
7923
7924 case OID_SKGE_VCT_GET:
7925 if ((Link == SK_FALSE) &&
7926 (pAC->Pnmi.VctStatus[PhysPortIndex] & SK_PNMI_VCT_PENDING)) {
7927 RetCode = SkGmCableDiagStatus(pAC, IoC, PhysPortIndex, SK_FALSE);
7928 if (RetCode == 0) {
7929 pAC->Pnmi.VctStatus[PhysPortIndex] &= ~SK_PNMI_VCT_PENDING;
7930 pAC->Pnmi.VctStatus[PhysPortIndex] |=
7931 (SK_PNMI_VCT_NEW_VCT_DATA | SK_PNMI_VCT_TEST_DONE);
7932
7933 /* Copy results for later use to PNMI struct. */
7934 for (i = 0; i < 4; i++) {
7935 if (pPrt->PMdiPairSts[i] == SK_PNMI_VCT_NORMAL_CABLE) {
7936 if ((pPrt->PMdiPairLen[i] > 35) && (pPrt->PMdiPairLen[i] < 0xff)) {
7937 pPrt->PMdiPairSts[i] = SK_PNMI_VCT_IMPEDANCE_MISMATCH;
7938 }
7939 }
7940 if ((pPrt->PMdiPairLen[i] > 35) && (pPrt->PMdiPairLen[i] != 0xff)) {
7941 CableLength = 1000 * (((175 * pPrt->PMdiPairLen[i]) / 210) - 28);
7942 }
7943 else {
7944 CableLength = 0;
7945 }
7946 pVctBackupData->PMdiPairLen[i] = CableLength;
7947 pVctBackupData->PMdiPairSts[i] = pPrt->PMdiPairSts[i];
7948 }
7949
7950 Para.Para32[0] = PhysPortIndex;
7951 Para.Para32[1] = -1;
7952 SkEventQueue(pAC, SKGE_DRV, SK_DRV_PORT_RESET, Para);
7953 SkEventDispatcher(pAC, IoC);
7954 }
7955 else {
7956 ; /* VCT test is running. */
7957 }
7958 }
7959
7960 /* Get all results. */
7961 CheckVctStatus(pAC, IoC, pBuf, Offset, PhysPortIndex);
7962 Offset += sizeof(SK_U8);
7963 *(pBuf + Offset) = pPrt->PCableLen;
7964 Offset += sizeof(SK_U8);
7965 for (i = 0; i < 4; i++) {
7966 SK_PNMI_STORE_U32((pBuf + Offset), pVctBackupData->PMdiPairLen[i]);
7967 Offset += sizeof(SK_U32);
7968 }
7969 for (i = 0; i < 4; i++) {
7970 *(pBuf + Offset) = pVctBackupData->PMdiPairSts[i];
7971 Offset += sizeof(SK_U8);
7972 }
7973
7974 RetCode = SK_PNMI_ERR_OK;
7975 break;
7976
7977 case OID_SKGE_VCT_STATUS:
7978 CheckVctStatus(pAC, IoC, pBuf, Offset, PhysPortIndex);
7979 Offset += sizeof(SK_U8);
7980 RetCode = SK_PNMI_ERR_OK;
7981 break;
7982
7983 default:
7984 *pLen = 0;
7985 return (SK_PNMI_ERR_GENERAL);
7986 }
7987 } /* for */
7988 *pLen = Offset;
7989 return (RetCode);
7990
7991 } /* if SK_PNMI_GET */
7992
7993 /*
7994 * From here SET or PRESET action. Check if the passed
7995 * buffer length is plausible.
7996 */
7997
7998 /* Check length */
7999 switch (Id) {
8000 case OID_SKGE_VCT_SET:
8001 if (*pLen < (Limit - PhysPortIndex) * sizeof(SK_U32)) {
8002 *pLen = (Limit - PhysPortIndex) * sizeof(SK_U32);
8003 return (SK_PNMI_ERR_TOO_SHORT);
8004 }
8005 break;
8006
8007 default:
8008 *pLen = 0;
8009 return (SK_PNMI_ERR_GENERAL);
8010 }
8011
8012 /*
8013 * Perform preset or set.
8014 */
8015
8016 /* VCT does not support PRESET action. */
8017 if (Action == SK_PNMI_PRESET) {
8018 return (SK_PNMI_ERR_OK);
8019 }
8020
8021 Offset = 0;
8022 for (; PhysPortIndex < Limit; PhysPortIndex++) {
8023 switch (Id) {
8024 case OID_SKGE_VCT_SET: /* Start VCT test. */
8025 if (Link == SK_FALSE) {
8026 SkGeStopPort(pAC, IoC, PhysPortIndex, SK_STOP_ALL, SK_SOFT_RST);
8027
8028 RetCode = SkGmCableDiagStatus(pAC, IoC, PhysPortIndex, SK_TRUE);
8029 if (RetCode == 0) { /* RetCode: 0 => Start! */
8030 pAC->Pnmi.VctStatus[PhysPortIndex] |= SK_PNMI_VCT_PENDING;
8031 pAC->Pnmi.VctStatus[PhysPortIndex] &= ~SK_PNMI_VCT_NEW_VCT_DATA;
8032 pAC->Pnmi.VctStatus[PhysPortIndex] &= ~SK_PNMI_VCT_LINK;
8033
8034 /*
8035 * Start VCT timer counter.
8036 */
8037 SK_MEMSET((char *) &Para, 0, sizeof(Para));
8038 Para.Para32[0] = PhysPortIndex;
8039 Para.Para32[1] = -1;
8040 SkTimerStart(pAC, IoC, &pAC->Pnmi.VctTimeout[PhysPortIndex].VctTimer,
8041 4000000, SKGE_PNMI, SK_PNMI_EVT_VCT_RESET, Para);
8042 SK_PNMI_STORE_U32((pBuf + Offset), RetCode);
8043 RetCode = SK_PNMI_ERR_OK;
8044 }
8045 else { /* RetCode: 2 => Running! */
8046 SK_PNMI_STORE_U32((pBuf + Offset), RetCode);
8047 RetCode = SK_PNMI_ERR_OK;
8048 }
8049 }
8050 else { /* RetCode: 4 => Link! */
8051 RetCode = 4;
8052 SK_PNMI_STORE_U32((pBuf + Offset), RetCode);
8053 RetCode = SK_PNMI_ERR_OK;
8054 }
8055 Offset += sizeof(SK_U32);
8056 break;
8057
8058 default:
8059 *pLen = 0;
8060 return (SK_PNMI_ERR_GENERAL);
8061 }
8062 } /* for */
8063 *pLen = Offset;
8064 return (RetCode);
8065
8066} /* Vct */
8067
8068
8069PNMI_STATIC void CheckVctStatus(
8070SK_AC *pAC,
8071SK_IOC IoC,
8072char *pBuf,
8073SK_U32 Offset,
8074SK_U32 PhysPortIndex)
8075{
8076 SK_GEPORT *pPrt;
8077 SK_PNMI_VCT *pVctData;
8078 SK_U32 RetCode;
8079
8080 pPrt = &pAC->GIni.GP[PhysPortIndex];
8081
8082 pVctData = (SK_PNMI_VCT *) (pBuf + Offset);
8083 pVctData->VctStatus = SK_PNMI_VCT_NONE;
8084
8085 if (!pPrt->PHWLinkUp) {
8086
8087 /* Was a VCT test ever made before? */
8088 if (pAC->Pnmi.VctStatus[PhysPortIndex] & SK_PNMI_VCT_TEST_DONE) {
8089 if ((pAC->Pnmi.VctStatus[PhysPortIndex] & SK_PNMI_VCT_LINK)) {
8090 pVctData->VctStatus |= SK_PNMI_VCT_OLD_VCT_DATA;
8091 }
8092 else {
8093 pVctData->VctStatus |= SK_PNMI_VCT_NEW_VCT_DATA;
8094 }
8095 }
8096
8097 /* Check VCT test status. */
8098 RetCode = SkGmCableDiagStatus(pAC,IoC, PhysPortIndex, SK_FALSE);
8099 if (RetCode == 2) { /* VCT test is running. */
8100 pVctData->VctStatus |= SK_PNMI_VCT_RUNNING;
8101 }
8102 else { /* VCT data was copied to pAC here. Check PENDING state. */
8103 if (pAC->Pnmi.VctStatus[PhysPortIndex] & SK_PNMI_VCT_PENDING) {
8104 pVctData->VctStatus |= SK_PNMI_VCT_NEW_VCT_DATA;
8105 }
8106 }
8107
8108 if (pPrt->PCableLen != 0xff) { /* Old DSP value. */
8109 pVctData->VctStatus |= SK_PNMI_VCT_OLD_DSP_DATA;
8110 }
8111 }
8112 else {
8113
8114 /* Was a VCT test ever made before? */
8115 if (pAC->Pnmi.VctStatus[PhysPortIndex] & SK_PNMI_VCT_TEST_DONE) {
8116 pVctData->VctStatus &= ~SK_PNMI_VCT_NEW_VCT_DATA;
8117 pVctData->VctStatus |= SK_PNMI_VCT_OLD_VCT_DATA;
8118 }
8119
8120 /* DSP only valid in 100/1000 modes. */
8121 if (pAC->GIni.GP[PhysPortIndex].PLinkSpeedUsed !=
8122 SK_LSPEED_STAT_10MBPS) {
8123 pVctData->VctStatus |= SK_PNMI_VCT_NEW_DSP_DATA;
8124 }
8125 }
8126} /* CheckVctStatus */
8127
8128
8129/*****************************************************************************
8130 *
8131 * SkPnmiGenIoctl - Handles new generic PNMI IOCTL, calls the needed
8132 * PNMI function depending on the subcommand and
8133 * returns all data belonging to the complete database
8134 * or OID request.
8135 *
8136 * Description:
8137 * Looks up the requested subcommand, calls the corresponding handler
8138 * function and passes all required parameters to it.
8139 * The function is called by the driver. It is needed to handle the new
8140 * generic PNMI IOCTL. This IOCTL is given to the driver and contains both
8141 * the OID and a subcommand to decide what kind of request has to be done.
8142 *
8143 * Returns:
8144 * SK_PNMI_ERR_OK The request was successfully performed
8145 * SK_PNMI_ERR_GENERAL A general severe internal error occured
8146 * SK_PNMI_ERR_TOO_SHORT The passed buffer is too short to take
8147 * the data.
8148 * SK_PNMI_ERR_UNKNOWN_OID The requested OID is unknown
8149 * SK_PNMI_ERR_UNKNOWN_INST The requested instance of the OID doesn't
8150 * exist (e.g. port instance 3 on a two port
8151 * adapter.
8152 */
8153int SkPnmiGenIoctl(
8154SK_AC *pAC, /* Pointer to adapter context struct */
8155SK_IOC IoC, /* I/O context */
8156void *pBuf, /* Buffer used for the management data transfer */
8157unsigned int *pLen, /* Length of buffer */
8158SK_U32 NetIndex) /* NetIndex (0..n), in single net mode always zero */
8159{
8160SK_I32 Mode; /* Store value of subcommand. */
8161SK_U32 Oid; /* Store value of OID. */
8162int ReturnCode; /* Store return value to show status of PNMI action. */
8163int HeaderLength; /* Length of desired action plus OID. */
8164
8165 ReturnCode = SK_PNMI_ERR_GENERAL;
8166
8167 SK_MEMCPY(&Mode, pBuf, sizeof(SK_I32));
8168 SK_MEMCPY(&Oid, (char *) pBuf + sizeof(SK_I32), sizeof(SK_U32));
8169 HeaderLength = sizeof(SK_I32) + sizeof(SK_U32);
8170 *pLen = *pLen - HeaderLength;
8171 SK_MEMCPY((char *) pBuf + sizeof(SK_I32), (char *) pBuf + HeaderLength, *pLen);
8172
8173 switch(Mode) {
8174 case SK_GET_SINGLE_VAR:
8175 ReturnCode = SkPnmiGetVar(pAC, IoC, Oid,
8176 (char *) pBuf + sizeof(SK_I32), pLen,
8177 ((SK_U32) (-1)), NetIndex);
8178 SK_PNMI_STORE_U32(pBuf, ReturnCode);
8179 *pLen = *pLen + sizeof(SK_I32);
8180 break;
8181 case SK_PRESET_SINGLE_VAR:
8182 ReturnCode = SkPnmiPreSetVar(pAC, IoC, Oid,
8183 (char *) pBuf + sizeof(SK_I32), pLen,
8184 ((SK_U32) (-1)), NetIndex);
8185 SK_PNMI_STORE_U32(pBuf, ReturnCode);
8186 *pLen = *pLen + sizeof(SK_I32);
8187 break;
8188 case SK_SET_SINGLE_VAR:
8189 ReturnCode = SkPnmiSetVar(pAC, IoC, Oid,
8190 (char *) pBuf + sizeof(SK_I32), pLen,
8191 ((SK_U32) (-1)), NetIndex);
8192 SK_PNMI_STORE_U32(pBuf, ReturnCode);
8193 *pLen = *pLen + sizeof(SK_I32);
8194 break;
8195 case SK_GET_FULL_MIB:
8196 ReturnCode = SkPnmiGetStruct(pAC, IoC, pBuf, pLen, NetIndex);
8197 break;
8198 case SK_PRESET_FULL_MIB:
8199 ReturnCode = SkPnmiPreSetStruct(pAC, IoC, pBuf, pLen, NetIndex);
8200 break;
8201 case SK_SET_FULL_MIB:
8202 ReturnCode = SkPnmiSetStruct(pAC, IoC, pBuf, pLen, NetIndex);
8203 break;
8204 default:
8205 break;
8206 }
8207
8208 return (ReturnCode);
8209
8210} /* SkGeIocGen */
diff --git a/drivers/net/sk98lin/skgesirq.c b/drivers/net/sk98lin/skgesirq.c
new file mode 100644
index 000000000000..3e7aa49afd00
--- /dev/null
+++ b/drivers/net/sk98lin/skgesirq.c
@@ -0,0 +1,2229 @@
1/******************************************************************************
2 *
3 * Name: skgesirq.c
4 * Project: Gigabit Ethernet Adapters, Common Modules
5 * Version: $Revision: 1.92 $
6 * Date: $Date: 2003/09/16 14:37:07 $
7 * Purpose: Special IRQ module
8 *
9 ******************************************************************************/
10
11/******************************************************************************
12 *
13 * (C)Copyright 1998-2002 SysKonnect.
14 * (C)Copyright 2002-2003 Marvell.
15 *
16 * This program is free software; you can redistribute it and/or modify
17 * it under the terms of the GNU General Public License as published by
18 * the Free Software Foundation; either version 2 of the License, or
19 * (at your option) any later version.
20 *
21 * The information in this file is provided "AS IS" without warranty.
22 *
23 ******************************************************************************/
24
25/*
26 * Special Interrupt handler
27 *
28 * The following abstract should show how this module is included
29 * in the driver path:
30 *
31 * In the ISR of the driver the bits for frame transmission complete and
32 * for receive complete are checked and handled by the driver itself.
33 * The bits of the slow path mask are checked after that and then the
34 * entry into the so-called "slow path" is prepared. It is an implementors
35 * decision whether this is executed directly or just scheduled by
36 * disabling the mask. In the interrupt service routine some events may be
37 * generated, so it would be a good idea to call the EventDispatcher
38 * right after this ISR.
39 *
40 * The Interrupt source register of the adapter is NOT read by this module.
41 * SO if the drivers implementor needs a while loop around the
42 * slow data paths interrupt bits, he needs to call the SkGeSirqIsr() for
43 * each loop entered.
44 *
45 * However, the MAC Interrupt status registers are read in a while loop.
46 *
47 */
48
49#if (defined(DEBUG) || ((!defined(LINT)) && (!defined(SK_SLIM))))
50static const char SysKonnectFileId[] =
51 "@(#) $Id: skgesirq.c,v 1.92 2003/09/16 14:37:07 rschmidt Exp $ (C) Marvell.";
52#endif
53
54#include "h/skdrv1st.h" /* Driver Specific Definitions */
55#ifndef SK_SLIM
56#include "h/skgepnmi.h" /* PNMI Definitions */
57#include "h/skrlmt.h" /* RLMT Definitions */
58#endif
59#include "h/skdrv2nd.h" /* Adapter Control and Driver specific Def. */
60
61/* local function prototypes */
62#ifdef GENESIS
63static int SkGePortCheckUpXmac(SK_AC*, SK_IOC, int, SK_BOOL);
64static int SkGePortCheckUpBcom(SK_AC*, SK_IOC, int, SK_BOOL);
65static void SkPhyIsrBcom(SK_AC*, SK_IOC, int, SK_U16);
66#endif /* GENESIS */
67#ifdef YUKON
68static int SkGePortCheckUpGmac(SK_AC*, SK_IOC, int, SK_BOOL);
69static void SkPhyIsrGmac(SK_AC*, SK_IOC, int, SK_U16);
70#endif /* YUKON */
71#ifdef OTHER_PHY
72static int SkGePortCheckUpLone(SK_AC*, SK_IOC, int, SK_BOOL);
73static int SkGePortCheckUpNat(SK_AC*, SK_IOC, int, SK_BOOL);
74static void SkPhyIsrLone(SK_AC*, SK_IOC, int, SK_U16);
75#endif /* OTHER_PHY */
76
77#ifdef GENESIS
78/*
79 * array of Rx counter from XMAC which are checked
80 * in AutoSense mode to check whether a link is not able to auto-negotiate.
81 */
82static const SK_U16 SkGeRxRegs[]= {
83 XM_RXF_64B,
84 XM_RXF_127B,
85 XM_RXF_255B,
86 XM_RXF_511B,
87 XM_RXF_1023B,
88 XM_RXF_MAX_SZ
89} ;
90#endif /* GENESIS */
91
92#ifdef __C2MAN__
93/*
94 * Special IRQ function
95 *
96 * General Description:
97 *
98 */
99intro()
100{}
101#endif
102
103/******************************************************************************
104 *
105 * SkHWInitDefSense() - Default Autosensing mode initialization
106 *
107 * Description: sets the PLinkMode for HWInit
108 *
109 * Returns: N/A
110 */
111static void SkHWInitDefSense(
112SK_AC *pAC, /* adapter context */
113SK_IOC IoC, /* IO context */
114int Port) /* Port Index (MAC_1 + n) */
115{
116 SK_GEPORT *pPrt; /* GIni Port struct pointer */
117
118 pPrt = &pAC->GIni.GP[Port];
119
120 pPrt->PAutoNegTimeOut = 0;
121
122 if (pPrt->PLinkModeConf != SK_LMODE_AUTOSENSE) {
123 pPrt->PLinkMode = pPrt->PLinkModeConf;
124 return;
125 }
126
127 SK_DBG_MSG(pAC, SK_DBGMOD_HWM, SK_DBGCAT_IRQ,
128 ("AutoSensing: First mode %d on Port %d\n",
129 (int)SK_LMODE_AUTOFULL, Port));
130
131 pPrt->PLinkMode = (SK_U8)SK_LMODE_AUTOFULL;
132
133 return;
134} /* SkHWInitDefSense */
135
136
137#ifdef GENESIS
138/******************************************************************************
139 *
140 * SkHWSenseGetNext() - Get Next Autosensing Mode
141 *
142 * Description: gets the appropriate next mode
143 *
144 * Note:
145 *
146 */
147static SK_U8 SkHWSenseGetNext(
148SK_AC *pAC, /* adapter context */
149SK_IOC IoC, /* IO context */
150int Port) /* Port Index (MAC_1 + n) */
151{
152 SK_GEPORT *pPrt; /* GIni Port struct pointer */
153
154 pPrt = &pAC->GIni.GP[Port];
155
156 pPrt->PAutoNegTimeOut = 0;
157
158 if (pPrt->PLinkModeConf != (SK_U8)SK_LMODE_AUTOSENSE) {
159 /* Leave all as configured */
160 return(pPrt->PLinkModeConf);
161 }
162
163 if (pPrt->PLinkMode == (SK_U8)SK_LMODE_AUTOFULL) {
164 /* Return next mode AUTOBOTH */
165 return ((SK_U8)SK_LMODE_AUTOBOTH);
166 }
167
168 /* Return default autofull */
169 return ((SK_U8)SK_LMODE_AUTOFULL);
170} /* SkHWSenseGetNext */
171
172
173/******************************************************************************
174 *
175 * SkHWSenseSetNext() - Autosensing Set next mode
176 *
177 * Description: sets the appropriate next mode
178 *
179 * Returns: N/A
180 */
181static void SkHWSenseSetNext(
182SK_AC *pAC, /* adapter context */
183SK_IOC IoC, /* IO context */
184int Port, /* Port Index (MAC_1 + n) */
185SK_U8 NewMode) /* New Mode to be written in sense mode */
186{
187 SK_GEPORT *pPrt; /* GIni Port struct pointer */
188
189 pPrt = &pAC->GIni.GP[Port];
190
191 pPrt->PAutoNegTimeOut = 0;
192
193 if (pPrt->PLinkModeConf != (SK_U8)SK_LMODE_AUTOSENSE) {
194 return;
195 }
196
197 SK_DBG_MSG(pAC, SK_DBGMOD_HWM, SK_DBGCAT_IRQ,
198 ("AutoSensing: next mode %d on Port %d\n",
199 (int)NewMode, Port));
200
201 pPrt->PLinkMode = NewMode;
202
203 return;
204} /* SkHWSenseSetNext */
205#endif /* GENESIS */
206
207
208/******************************************************************************
209 *
210 * SkHWLinkDown() - Link Down handling
211 *
212 * Description: handles the hardware link down signal
213 *
214 * Returns: N/A
215 */
216void SkHWLinkDown(
217SK_AC *pAC, /* adapter context */
218SK_IOC IoC, /* IO context */
219int Port) /* Port Index (MAC_1 + n) */
220{
221 SK_GEPORT *pPrt; /* GIni Port struct pointer */
222
223 pPrt = &pAC->GIni.GP[Port];
224
225 /* Disable all MAC interrupts */
226 SkMacIrqDisable(pAC, IoC, Port);
227
228 /* Disable Receiver and Transmitter */
229 SkMacRxTxDisable(pAC, IoC, Port);
230
231 /* Init default sense mode */
232 SkHWInitDefSense(pAC, IoC, Port);
233
234 if (pPrt->PHWLinkUp == SK_FALSE) {
235 return;
236 }
237
238 SK_DBG_MSG(pAC, SK_DBGMOD_HWM, SK_DBGCAT_IRQ,
239 ("Link down Port %d\n", Port));
240
241 /* Set Link to DOWN */
242 pPrt->PHWLinkUp = SK_FALSE;
243
244 /* Reset Port stati */
245 pPrt->PLinkModeStatus = (SK_U8)SK_LMODE_STAT_UNKNOWN;
246 pPrt->PFlowCtrlStatus = (SK_U8)SK_FLOW_STAT_NONE;
247 pPrt->PLinkSpeedUsed = (SK_U8)SK_LSPEED_STAT_INDETERMINATED;
248
249 /* Re-init Phy especially when the AutoSense default is set now */
250 SkMacInitPhy(pAC, IoC, Port, SK_FALSE);
251
252 /* GP0: used for workaround of Rev. C Errata 2 */
253
254 /* Do NOT signal to RLMT */
255
256 /* Do NOT start the timer here */
257} /* SkHWLinkDown */
258
259
260/******************************************************************************
261 *
262 * SkHWLinkUp() - Link Up handling
263 *
264 * Description: handles the hardware link up signal
265 *
266 * Returns: N/A
267 */
268static void SkHWLinkUp(
269SK_AC *pAC, /* adapter context */
270SK_IOC IoC, /* IO context */
271int Port) /* Port Index (MAC_1 + n) */
272{
273 SK_GEPORT *pPrt; /* GIni Port struct pointer */
274
275 pPrt = &pAC->GIni.GP[Port];
276
277 if (pPrt->PHWLinkUp) {
278 /* We do NOT need to proceed on active link */
279 return;
280 }
281
282 pPrt->PHWLinkUp = SK_TRUE;
283 pPrt->PAutoNegFail = SK_FALSE;
284 pPrt->PLinkModeStatus = (SK_U8)SK_LMODE_STAT_UNKNOWN;
285
286 if (pPrt->PLinkMode != (SK_U8)SK_LMODE_AUTOHALF &&
287 pPrt->PLinkMode != (SK_U8)SK_LMODE_AUTOFULL &&
288 pPrt->PLinkMode != (SK_U8)SK_LMODE_AUTOBOTH) {
289 /* Link is up and no Auto-negotiation should be done */
290
291 /* Link speed should be the configured one */
292 switch (pPrt->PLinkSpeed) {
293 case SK_LSPEED_AUTO:
294 /* default is 1000 Mbps */
295 case SK_LSPEED_1000MBPS:
296 pPrt->PLinkSpeedUsed = (SK_U8)SK_LSPEED_STAT_1000MBPS;
297 break;
298 case SK_LSPEED_100MBPS:
299 pPrt->PLinkSpeedUsed = (SK_U8)SK_LSPEED_STAT_100MBPS;
300 break;
301 case SK_LSPEED_10MBPS:
302 pPrt->PLinkSpeedUsed = (SK_U8)SK_LSPEED_STAT_10MBPS;
303 break;
304 }
305
306 /* Set Link Mode Status */
307 if (pPrt->PLinkMode == SK_LMODE_FULL) {
308 pPrt->PLinkModeStatus = (SK_U8)SK_LMODE_STAT_FULL;
309 }
310 else {
311 pPrt->PLinkModeStatus = (SK_U8)SK_LMODE_STAT_HALF;
312 }
313
314 /* No flow control without auto-negotiation */
315 pPrt->PFlowCtrlStatus = (SK_U8)SK_FLOW_STAT_NONE;
316
317 /* enable Rx/Tx */
318 (void)SkMacRxTxEnable(pAC, IoC, Port);
319 }
320} /* SkHWLinkUp */
321
322
323/******************************************************************************
324 *
325 * SkMacParity() - MAC parity workaround
326 *
327 * Description: handles MAC parity errors correctly
328 *
329 * Returns: N/A
330 */
331static void SkMacParity(
332SK_AC *pAC, /* adapter context */
333SK_IOC IoC, /* IO context */
334int Port) /* Port Index of the port failed */
335{
336 SK_EVPARA Para;
337 SK_GEPORT *pPrt; /* GIni Port struct pointer */
338 SK_U32 TxMax; /* Tx Max Size Counter */
339
340 pPrt = &pAC->GIni.GP[Port];
341
342 /* Clear IRQ Tx Parity Error */
343#ifdef GENESIS
344 if (pAC->GIni.GIGenesis) {
345
346 SK_OUT16(IoC, MR_ADDR(Port, TX_MFF_CTRL1), MFF_CLR_PERR);
347 }
348#endif /* GENESIS */
349
350#ifdef YUKON
351 if (pAC->GIni.GIYukon) {
352 /* HW-Bug #8: cleared by GMF_CLI_TX_FC instead of GMF_CLI_TX_PE */
353 SK_OUT8(IoC, MR_ADDR(Port, TX_GMF_CTRL_T),
354 (SK_U8)((pAC->GIni.GIChipId == CHIP_ID_YUKON &&
355 pAC->GIni.GIChipRev == 0) ? GMF_CLI_TX_FC : GMF_CLI_TX_PE));
356 }
357#endif /* YUKON */
358
359 if (pPrt->PCheckPar) {
360
361 if (Port == MAC_1) {
362 SK_ERR_LOG(pAC, SK_ERRCL_HW, SKERR_SIRQ_E016, SKERR_SIRQ_E016MSG);
363 }
364 else {
365 SK_ERR_LOG(pAC, SK_ERRCL_HW, SKERR_SIRQ_E017, SKERR_SIRQ_E017MSG);
366 }
367 Para.Para64 = Port;
368 SkEventQueue(pAC, SKGE_DRV, SK_DRV_PORT_FAIL, Para);
369
370 Para.Para32[0] = Port;
371 SkEventQueue(pAC, SKGE_RLMT, SK_RLMT_LINK_DOWN, Para);
372
373 return;
374 }
375
376 /* Check whether frames with a size of 1k were sent */
377#ifdef GENESIS
378 if (pAC->GIni.GIGenesis) {
379 /* Snap statistic counters */
380 (void)SkXmUpdateStats(pAC, IoC, Port);
381
382 (void)SkXmMacStatistic(pAC, IoC, Port, XM_TXF_MAX_SZ, &TxMax);
383 }
384#endif /* GENESIS */
385
386#ifdef YUKON
387 if (pAC->GIni.GIYukon) {
388
389 (void)SkGmMacStatistic(pAC, IoC, Port, GM_TXF_1518B, &TxMax);
390 }
391#endif /* YUKON */
392
393 if (TxMax > 0) {
394 /* From now on check the parity */
395 pPrt->PCheckPar = SK_TRUE;
396 }
397} /* SkMacParity */
398
399
400/******************************************************************************
401 *
402 * SkGeHwErr() - Hardware Error service routine
403 *
404 * Description: handles all HW Error interrupts
405 *
406 * Returns: N/A
407 */
408static void SkGeHwErr(
409SK_AC *pAC, /* adapter context */
410SK_IOC IoC, /* IO context */
411SK_U32 HwStatus) /* Interrupt status word */
412{
413 SK_EVPARA Para;
414 SK_U16 Word;
415
416 if ((HwStatus & (IS_IRQ_MST_ERR | IS_IRQ_STAT)) != 0) {
417 /* PCI Errors occured */
418 if ((HwStatus & IS_IRQ_STAT) != 0) {
419 SK_ERR_LOG(pAC, SK_ERRCL_HW, SKERR_SIRQ_E013, SKERR_SIRQ_E013MSG);
420 }
421 else {
422 SK_ERR_LOG(pAC, SK_ERRCL_HW, SKERR_SIRQ_E012, SKERR_SIRQ_E012MSG);
423 }
424
425 /* Reset all bits in the PCI STATUS register */
426 SK_IN16(IoC, PCI_C(PCI_STATUS), &Word);
427
428 SK_OUT8(IoC, B2_TST_CTRL1, TST_CFG_WRITE_ON);
429 SK_OUT16(IoC, PCI_C(PCI_STATUS), (SK_U16)(Word | PCI_ERRBITS));
430 SK_OUT8(IoC, B2_TST_CTRL1, TST_CFG_WRITE_OFF);
431
432 Para.Para64 = 0;
433 SkEventQueue(pAC, SKGE_DRV, SK_DRV_ADAP_FAIL, Para);
434 }
435
436#ifdef GENESIS
437 if (pAC->GIni.GIGenesis) {
438
439 if ((HwStatus & IS_NO_STAT_M1) != 0) {
440 /* Ignore it */
441 /* This situation is also indicated in the descriptor */
442 SK_OUT16(IoC, MR_ADDR(MAC_1, RX_MFF_CTRL1), MFF_CLR_INSTAT);
443 }
444
445 if ((HwStatus & IS_NO_STAT_M2) != 0) {
446 /* Ignore it */
447 /* This situation is also indicated in the descriptor */
448 SK_OUT16(IoC, MR_ADDR(MAC_2, RX_MFF_CTRL1), MFF_CLR_INSTAT);
449 }
450
451 if ((HwStatus & IS_NO_TIST_M1) != 0) {
452 /* Ignore it */
453 /* This situation is also indicated in the descriptor */
454 SK_OUT16(IoC, MR_ADDR(MAC_1, RX_MFF_CTRL1), MFF_CLR_INTIST);
455 }
456
457 if ((HwStatus & IS_NO_TIST_M2) != 0) {
458 /* Ignore it */
459 /* This situation is also indicated in the descriptor */
460 SK_OUT16(IoC, MR_ADDR(MAC_2, RX_MFF_CTRL1), MFF_CLR_INTIST);
461 }
462 }
463#endif /* GENESIS */
464
465#ifdef YUKON
466 if (pAC->GIni.GIYukon) {
467 /* This is necessary only for Rx timing measurements */
468 if ((HwStatus & IS_IRQ_TIST_OV) != 0) {
469 /* increment Time Stamp Timer counter (high) */
470 pAC->GIni.GITimeStampCnt++;
471
472 /* Clear Time Stamp Timer IRQ */
473 SK_OUT8(IoC, GMAC_TI_ST_CTRL, (SK_U8)GMT_ST_CLR_IRQ);
474 }
475
476 if ((HwStatus & IS_IRQ_SENSOR) != 0) {
477 /* no sensors on 32-bit Yukon */
478 if (pAC->GIni.GIYukon32Bit) {
479 /* disable HW Error IRQ */
480 pAC->GIni.GIValIrqMask &= ~IS_HW_ERR;
481 }
482 }
483 }
484#endif /* YUKON */
485
486 if ((HwStatus & IS_RAM_RD_PAR) != 0) {
487 SK_OUT16(IoC, B3_RI_CTRL, RI_CLR_RD_PERR);
488 SK_ERR_LOG(pAC, SK_ERRCL_HW, SKERR_SIRQ_E014, SKERR_SIRQ_E014MSG);
489 Para.Para64 = 0;
490 SkEventQueue(pAC, SKGE_DRV, SK_DRV_ADAP_FAIL, Para);
491 }
492
493 if ((HwStatus & IS_RAM_WR_PAR) != 0) {
494 SK_OUT16(IoC, B3_RI_CTRL, RI_CLR_WR_PERR);
495 SK_ERR_LOG(pAC, SK_ERRCL_HW, SKERR_SIRQ_E015, SKERR_SIRQ_E015MSG);
496 Para.Para64 = 0;
497 SkEventQueue(pAC, SKGE_DRV, SK_DRV_ADAP_FAIL, Para);
498 }
499
500 if ((HwStatus & IS_M1_PAR_ERR) != 0) {
501 SkMacParity(pAC, IoC, MAC_1);
502 }
503
504 if ((HwStatus & IS_M2_PAR_ERR) != 0) {
505 SkMacParity(pAC, IoC, MAC_2);
506 }
507
508 if ((HwStatus & IS_R1_PAR_ERR) != 0) {
509 /* Clear IRQ */
510 SK_OUT32(IoC, B0_R1_CSR, CSR_IRQ_CL_P);
511
512 SK_ERR_LOG(pAC, SK_ERRCL_HW, SKERR_SIRQ_E018, SKERR_SIRQ_E018MSG);
513 Para.Para64 = MAC_1;
514 SkEventQueue(pAC, SKGE_DRV, SK_DRV_PORT_FAIL, Para);
515
516 Para.Para32[0] = MAC_1;
517 SkEventQueue(pAC, SKGE_RLMT, SK_RLMT_LINK_DOWN, Para);
518 }
519
520 if ((HwStatus & IS_R2_PAR_ERR) != 0) {
521 /* Clear IRQ */
522 SK_OUT32(IoC, B0_R2_CSR, CSR_IRQ_CL_P);
523
524 SK_ERR_LOG(pAC, SK_ERRCL_HW, SKERR_SIRQ_E019, SKERR_SIRQ_E019MSG);
525 Para.Para64 = MAC_2;
526 SkEventQueue(pAC, SKGE_DRV, SK_DRV_PORT_FAIL, Para);
527
528 Para.Para32[0] = MAC_2;
529 SkEventQueue(pAC, SKGE_RLMT, SK_RLMT_LINK_DOWN, Para);
530 }
531} /* SkGeHwErr */
532
533
534/******************************************************************************
535 *
536 * SkGeSirqIsr() - Special Interrupt Service Routine
537 *
538 * Description: handles all non data transfer specific interrupts (slow path)
539 *
540 * Returns: N/A
541 */
542void SkGeSirqIsr(
543SK_AC *pAC, /* adapter context */
544SK_IOC IoC, /* IO context */
545SK_U32 Istatus) /* Interrupt status word */
546{
547 SK_EVPARA Para;
548 SK_U32 RegVal32; /* Read register value */
549 SK_GEPORT *pPrt; /* GIni Port struct pointer */
550 SK_U16 PhyInt;
551 int i;
552
553 if (((Istatus & IS_HW_ERR) & pAC->GIni.GIValIrqMask) != 0) {
554 /* read the HW Error Interrupt source */
555 SK_IN32(IoC, B0_HWE_ISRC, &RegVal32);
556
557 SkGeHwErr(pAC, IoC, RegVal32);
558 }
559
560 /*
561 * Packet Timeout interrupts
562 */
563 /* Check whether MACs are correctly initialized */
564 if (((Istatus & (IS_PA_TO_RX1 | IS_PA_TO_TX1)) != 0) &&
565 pAC->GIni.GP[MAC_1].PState == SK_PRT_RESET) {
566 /* MAC 1 was not initialized but Packet timeout occured */
567 SK_ERR_LOG(pAC, SK_ERRCL_SW | SK_ERRCL_INIT, SKERR_SIRQ_E004,
568 SKERR_SIRQ_E004MSG);
569 }
570
571 if (((Istatus & (IS_PA_TO_RX2 | IS_PA_TO_TX2)) != 0) &&
572 pAC->GIni.GP[MAC_2].PState == SK_PRT_RESET) {
573 /* MAC 2 was not initialized but Packet timeout occured */
574 SK_ERR_LOG(pAC, SK_ERRCL_SW | SK_ERRCL_INIT, SKERR_SIRQ_E005,
575 SKERR_SIRQ_E005MSG);
576 }
577
578 if ((Istatus & IS_PA_TO_RX1) != 0) {
579 /* Means network is filling us up */
580 SK_ERR_LOG(pAC, SK_ERRCL_HW | SK_ERRCL_INIT, SKERR_SIRQ_E002,
581 SKERR_SIRQ_E002MSG);
582 SK_OUT16(IoC, B3_PA_CTRL, PA_CLR_TO_RX1);
583 }
584
585 if ((Istatus & IS_PA_TO_RX2) != 0) {
586 /* Means network is filling us up */
587 SK_ERR_LOG(pAC, SK_ERRCL_HW | SK_ERRCL_INIT, SKERR_SIRQ_E003,
588 SKERR_SIRQ_E003MSG);
589 SK_OUT16(IoC, B3_PA_CTRL, PA_CLR_TO_RX2);
590 }
591
592 if ((Istatus & IS_PA_TO_TX1) != 0) {
593
594 pPrt = &pAC->GIni.GP[0];
595
596 /* May be a normal situation in a server with a slow network */
597 SK_OUT16(IoC, B3_PA_CTRL, PA_CLR_TO_TX1);
598
599#ifdef GENESIS
600 if (pAC->GIni.GIGenesis) {
601 /*
602 * workaround: if in half duplex mode, check for Tx hangup.
603 * Read number of TX'ed bytes, wait for 10 ms, then compare
604 * the number with current value. If nothing changed, we assume
605 * that Tx is hanging and do a FIFO flush (see event routine).
606 */
607 if ((pPrt->PLinkModeStatus == SK_LMODE_STAT_HALF ||
608 pPrt->PLinkModeStatus == SK_LMODE_STAT_AUTOHALF) &&
609 !pPrt->HalfDupTimerActive) {
610 /*
611 * many more pack. arb. timeouts may come in between,
612 * we ignore those
613 */
614 pPrt->HalfDupTimerActive = SK_TRUE;
615 /* Snap statistic counters */
616 (void)SkXmUpdateStats(pAC, IoC, 0);
617
618 (void)SkXmMacStatistic(pAC, IoC, 0, XM_TXO_OK_HI, &RegVal32);
619
620 pPrt->LastOctets = (SK_U64)RegVal32 << 32;
621
622 (void)SkXmMacStatistic(pAC, IoC, 0, XM_TXO_OK_LO, &RegVal32);
623
624 pPrt->LastOctets += RegVal32;
625
626 Para.Para32[0] = 0;
627 SkTimerStart(pAC, IoC, &pPrt->HalfDupChkTimer, SK_HALFDUP_CHK_TIME,
628 SKGE_HWAC, SK_HWEV_HALFDUP_CHK, Para);
629 }
630 }
631#endif /* GENESIS */
632 }
633
634 if ((Istatus & IS_PA_TO_TX2) != 0) {
635
636 pPrt = &pAC->GIni.GP[1];
637
638 /* May be a normal situation in a server with a slow network */
639 SK_OUT16(IoC, B3_PA_CTRL, PA_CLR_TO_TX2);
640
641#ifdef GENESIS
642 if (pAC->GIni.GIGenesis) {
643 /* workaround: see above */
644 if ((pPrt->PLinkModeStatus == SK_LMODE_STAT_HALF ||
645 pPrt->PLinkModeStatus == SK_LMODE_STAT_AUTOHALF) &&
646 !pPrt->HalfDupTimerActive) {
647 pPrt->HalfDupTimerActive = SK_TRUE;
648 /* Snap statistic counters */
649 (void)SkXmUpdateStats(pAC, IoC, 1);
650
651 (void)SkXmMacStatistic(pAC, IoC, 1, XM_TXO_OK_HI, &RegVal32);
652
653 pPrt->LastOctets = (SK_U64)RegVal32 << 32;
654
655 (void)SkXmMacStatistic(pAC, IoC, 1, XM_TXO_OK_LO, &RegVal32);
656
657 pPrt->LastOctets += RegVal32;
658
659 Para.Para32[0] = 1;
660 SkTimerStart(pAC, IoC, &pPrt->HalfDupChkTimer, SK_HALFDUP_CHK_TIME,
661 SKGE_HWAC, SK_HWEV_HALFDUP_CHK, Para);
662 }
663 }
664#endif /* GENESIS */
665 }
666
667 /* Check interrupts of the particular queues */
668 if ((Istatus & IS_R1_C) != 0) {
669 /* Clear IRQ */
670 SK_OUT32(IoC, B0_R1_CSR, CSR_IRQ_CL_C);
671 SK_ERR_LOG(pAC, SK_ERRCL_SW | SK_ERRCL_INIT, SKERR_SIRQ_E006,
672 SKERR_SIRQ_E006MSG);
673 Para.Para64 = MAC_1;
674 SkEventQueue(pAC, SKGE_DRV, SK_DRV_PORT_FAIL, Para);
675 Para.Para32[0] = MAC_1;
676 SkEventQueue(pAC, SKGE_RLMT, SK_RLMT_LINK_DOWN, Para);
677 }
678
679 if ((Istatus & IS_R2_C) != 0) {
680 /* Clear IRQ */
681 SK_OUT32(IoC, B0_R2_CSR, CSR_IRQ_CL_C);
682 SK_ERR_LOG(pAC, SK_ERRCL_SW | SK_ERRCL_INIT, SKERR_SIRQ_E007,
683 SKERR_SIRQ_E007MSG);
684 Para.Para64 = MAC_2;
685 SkEventQueue(pAC, SKGE_DRV, SK_DRV_PORT_FAIL, Para);
686 Para.Para32[0] = MAC_2;
687 SkEventQueue(pAC, SKGE_RLMT, SK_RLMT_LINK_DOWN, Para);
688 }
689
690 if ((Istatus & IS_XS1_C) != 0) {
691 /* Clear IRQ */
692 SK_OUT32(IoC, B0_XS1_CSR, CSR_IRQ_CL_C);
693 SK_ERR_LOG(pAC, SK_ERRCL_SW | SK_ERRCL_INIT, SKERR_SIRQ_E008,
694 SKERR_SIRQ_E008MSG);
695 Para.Para64 = MAC_1;
696 SkEventQueue(pAC, SKGE_DRV, SK_DRV_PORT_FAIL, Para);
697 Para.Para32[0] = MAC_1;
698 SkEventQueue(pAC, SKGE_RLMT, SK_RLMT_LINK_DOWN, Para);
699 }
700
701 if ((Istatus & IS_XA1_C) != 0) {
702 /* Clear IRQ */
703 SK_OUT32(IoC, B0_XA1_CSR, CSR_IRQ_CL_C);
704 SK_ERR_LOG(pAC, SK_ERRCL_SW | SK_ERRCL_INIT, SKERR_SIRQ_E009,
705 SKERR_SIRQ_E009MSG);
706 Para.Para64 = MAC_1;
707 SkEventQueue(pAC, SKGE_DRV, SK_DRV_PORT_FAIL, Para);
708 Para.Para32[0] = MAC_1;
709 SkEventQueue(pAC, SKGE_RLMT, SK_RLMT_LINK_DOWN, Para);
710 }
711
712 if ((Istatus & IS_XS2_C) != 0) {
713 /* Clear IRQ */
714 SK_OUT32(IoC, B0_XS2_CSR, CSR_IRQ_CL_C);
715 SK_ERR_LOG(pAC, SK_ERRCL_SW | SK_ERRCL_INIT, SKERR_SIRQ_E010,
716 SKERR_SIRQ_E010MSG);
717 Para.Para64 = MAC_2;
718 SkEventQueue(pAC, SKGE_DRV, SK_DRV_PORT_FAIL, Para);
719 Para.Para32[0] = MAC_2;
720 SkEventQueue(pAC, SKGE_RLMT, SK_RLMT_LINK_DOWN, Para);
721 }
722
723 if ((Istatus & IS_XA2_C) != 0) {
724 /* Clear IRQ */
725 SK_OUT32(IoC, B0_XA2_CSR, CSR_IRQ_CL_C);
726 SK_ERR_LOG(pAC, SK_ERRCL_SW | SK_ERRCL_INIT, SKERR_SIRQ_E011,
727 SKERR_SIRQ_E011MSG);
728 Para.Para64 = MAC_2;
729 SkEventQueue(pAC, SKGE_DRV, SK_DRV_PORT_FAIL, Para);
730 Para.Para32[0] = MAC_2;
731 SkEventQueue(pAC, SKGE_RLMT, SK_RLMT_LINK_DOWN, Para);
732 }
733
734 /* External reg interrupt */
735 if ((Istatus & IS_EXT_REG) != 0) {
736 /* Test IRQs from PHY */
737 for (i = 0; i < pAC->GIni.GIMacsFound; i++) {
738
739 pPrt = &pAC->GIni.GP[i];
740
741 if (pPrt->PState == SK_PRT_RESET) {
742 continue;
743 }
744
745#ifdef GENESIS
746 if (pAC->GIni.GIGenesis) {
747
748 switch (pPrt->PhyType) {
749
750 case SK_PHY_XMAC:
751 break;
752
753 case SK_PHY_BCOM:
754 SkXmPhyRead(pAC, IoC, i, PHY_BCOM_INT_STAT, &PhyInt);
755
756 if ((PhyInt & ~PHY_B_DEF_MSK) != 0) {
757 SK_DBG_MSG(pAC, SK_DBGMOD_HWM, SK_DBGCAT_IRQ,
758 ("Port %d Bcom Int: 0x%04X\n",
759 i, PhyInt));
760 SkPhyIsrBcom(pAC, IoC, i, PhyInt);
761 }
762 break;
763#ifdef OTHER_PHY
764 case SK_PHY_LONE:
765 SkXmPhyRead(pAC, IoC, i, PHY_LONE_INT_STAT, &PhyInt);
766
767 if ((PhyInt & PHY_L_DEF_MSK) != 0) {
768 SK_DBG_MSG(pAC, SK_DBGMOD_HWM, SK_DBGCAT_IRQ,
769 ("Port %d Lone Int: %x\n",
770 i, PhyInt));
771 SkPhyIsrLone(pAC, IoC, i, PhyInt);
772 }
773 break;
774#endif /* OTHER_PHY */
775 }
776 }
777#endif /* GENESIS */
778
779#ifdef YUKON
780 if (pAC->GIni.GIYukon) {
781 /* Read PHY Interrupt Status */
782 SkGmPhyRead(pAC, IoC, i, PHY_MARV_INT_STAT, &PhyInt);
783
784 if ((PhyInt & PHY_M_DEF_MSK) != 0) {
785 SK_DBG_MSG(pAC, SK_DBGMOD_HWM, SK_DBGCAT_IRQ,
786 ("Port %d Marv Int: 0x%04X\n",
787 i, PhyInt));
788 SkPhyIsrGmac(pAC, IoC, i, PhyInt);
789 }
790 }
791#endif /* YUKON */
792 }
793 }
794
795 /* I2C Ready interrupt */
796 if ((Istatus & IS_I2C_READY) != 0) {
797#ifdef SK_SLIM
798 SK_OUT32(IoC, B2_I2C_IRQ, I2C_CLR_IRQ);
799#else
800 SkI2cIsr(pAC, IoC);
801#endif
802 }
803
804 /* SW forced interrupt */
805 if ((Istatus & IS_IRQ_SW) != 0) {
806 /* clear the software IRQ */
807 SK_OUT8(IoC, B0_CTST, CS_CL_SW_IRQ);
808 }
809
810 if ((Istatus & IS_LNK_SYNC_M1) != 0) {
811 /*
812 * We do NOT need the Link Sync interrupt, because it shows
813 * us only a link going down.
814 */
815 /* clear interrupt */
816 SK_OUT8(IoC, MR_ADDR(MAC_1, LNK_SYNC_CTRL), LED_CLR_IRQ);
817 }
818
819 /* Check MAC after link sync counter */
820 if ((Istatus & IS_MAC1) != 0) {
821 /* IRQ from MAC 1 */
822 SkMacIrq(pAC, IoC, MAC_1);
823 }
824
825 if ((Istatus & IS_LNK_SYNC_M2) != 0) {
826 /*
827 * We do NOT need the Link Sync interrupt, because it shows
828 * us only a link going down.
829 */
830 /* clear interrupt */
831 SK_OUT8(IoC, MR_ADDR(MAC_2, LNK_SYNC_CTRL), LED_CLR_IRQ);
832 }
833
834 /* Check MAC after link sync counter */
835 if ((Istatus & IS_MAC2) != 0) {
836 /* IRQ from MAC 2 */
837 SkMacIrq(pAC, IoC, MAC_2);
838 }
839
840 /* Timer interrupt (served last) */
841 if ((Istatus & IS_TIMINT) != 0) {
842 /* check for HW Errors */
843 if (((Istatus & IS_HW_ERR) & ~pAC->GIni.GIValIrqMask) != 0) {
844 /* read the HW Error Interrupt source */
845 SK_IN32(IoC, B0_HWE_ISRC, &RegVal32);
846
847 SkGeHwErr(pAC, IoC, RegVal32);
848 }
849
850 SkHwtIsr(pAC, IoC);
851 }
852
853} /* SkGeSirqIsr */
854
855
856#ifdef GENESIS
857/******************************************************************************
858 *
859 * SkGePortCheckShorts() - Implementing XMAC Workaround Errata # 2
860 *
861 * return:
862 * 0 o.k. nothing needed
863 * 1 Restart needed on this port
864 */
865static int SkGePortCheckShorts(
866SK_AC *pAC, /* Adapter Context */
867SK_IOC IoC, /* IO Context */
868int Port) /* Which port should be checked */
869{
870 SK_U32 Shorts; /* Short Event Counter */
871 SK_U32 CheckShorts; /* Check value for Short Event Counter */
872 SK_U64 RxCts; /* Rx Counter (packets on network) */
873 SK_U32 RxTmp; /* Rx temp. Counter */
874 SK_U32 FcsErrCts; /* FCS Error Counter */
875 SK_GEPORT *pPrt; /* GIni Port struct pointer */
876 int Rtv; /* Return value */
877 int i;
878
879 pPrt = &pAC->GIni.GP[Port];
880
881 /* Default: no action */
882 Rtv = SK_HW_PS_NONE;
883
884 (void)SkXmUpdateStats(pAC, IoC, Port);
885
886 /* Extra precaution: check for short Event counter */
887 (void)SkXmMacStatistic(pAC, IoC, Port, XM_RXE_SHT_ERR, &Shorts);
888
889 /*
890 * Read Rx counters (packets seen on the network and not necessarily
891 * really received.
892 */
893 RxCts = 0;
894
895 for (i = 0; i < sizeof(SkGeRxRegs)/sizeof(SkGeRxRegs[0]); i++) {
896
897 (void)SkXmMacStatistic(pAC, IoC, Port, SkGeRxRegs[i], &RxTmp);
898
899 RxCts += (SK_U64)RxTmp;
900 }
901
902 /* On default: check shorts against zero */
903 CheckShorts = 0;
904
905 /* Extra precaution on active links */
906 if (pPrt->PHWLinkUp) {
907 /* Reset Link Restart counter */
908 pPrt->PLinkResCt = 0;
909 pPrt->PAutoNegTOCt = 0;
910
911 /* If link is up check for 2 */
912 CheckShorts = 2;
913
914 (void)SkXmMacStatistic(pAC, IoC, Port, XM_RXF_FCS_ERR, &FcsErrCts);
915
916 if (pPrt->PLinkModeConf == SK_LMODE_AUTOSENSE &&
917 pPrt->PLipaAutoNeg == SK_LIPA_UNKNOWN &&
918 (pPrt->PLinkMode == SK_LMODE_HALF ||
919 pPrt->PLinkMode == SK_LMODE_FULL)) {
920 /*
921 * This is autosensing and we are in the fallback
922 * manual full/half duplex mode.
923 */
924 if (RxCts == pPrt->PPrevRx) {
925 /* Nothing received, restart link */
926 pPrt->PPrevFcs = FcsErrCts;
927 pPrt->PPrevShorts = Shorts;
928
929 return(SK_HW_PS_RESTART);
930 }
931 else {
932 pPrt->PLipaAutoNeg = SK_LIPA_MANUAL;
933 }
934 }
935
936 if (((RxCts - pPrt->PPrevRx) > pPrt->PRxLim) ||
937 (!(FcsErrCts - pPrt->PPrevFcs))) {
938 /*
939 * Note: The compare with zero above has to be done the way shown,
940 * otherwise the Linux driver will have a problem.
941 */
942 /*
943 * We received a bunch of frames or no CRC error occured on the
944 * network -> ok.
945 */
946 pPrt->PPrevRx = RxCts;
947 pPrt->PPrevFcs = FcsErrCts;
948 pPrt->PPrevShorts = Shorts;
949
950 return(SK_HW_PS_NONE);
951 }
952
953 pPrt->PPrevFcs = FcsErrCts;
954 }
955
956
957 if ((Shorts - pPrt->PPrevShorts) > CheckShorts) {
958 SK_DBG_MSG(pAC, SK_DBGMOD_HWM, SK_DBGCAT_IRQ,
959 ("Short Event Count Restart Port %d \n", Port));
960 Rtv = SK_HW_PS_RESTART;
961 }
962
963 pPrt->PPrevShorts = Shorts;
964 pPrt->PPrevRx = RxCts;
965
966 return(Rtv);
967} /* SkGePortCheckShorts */
968#endif /* GENESIS */
969
970
971/******************************************************************************
972 *
973 * SkGePortCheckUp() - Check if the link is up
974 *
975 * return:
976 * 0 o.k. nothing needed
977 * 1 Restart needed on this port
978 * 2 Link came up
979 */
980static int SkGePortCheckUp(
981SK_AC *pAC, /* Adapter Context */
982SK_IOC IoC, /* IO Context */
983int Port) /* Which port should be checked */
984{
985 SK_GEPORT *pPrt; /* GIni Port struct pointer */
986 SK_BOOL AutoNeg; /* Is Auto-negotiation used ? */
987 int Rtv; /* Return value */
988
989 Rtv = SK_HW_PS_NONE;
990
991 pPrt = &pAC->GIni.GP[Port];
992
993 if (pPrt->PLinkMode == SK_LMODE_HALF || pPrt->PLinkMode == SK_LMODE_FULL) {
994 AutoNeg = SK_FALSE;
995 }
996 else {
997 AutoNeg = SK_TRUE;
998 }
999
1000#ifdef GENESIS
1001 if (pAC->GIni.GIGenesis) {
1002
1003 switch (pPrt->PhyType) {
1004
1005 case SK_PHY_XMAC:
1006 Rtv = SkGePortCheckUpXmac(pAC, IoC, Port, AutoNeg);
1007 break;
1008 case SK_PHY_BCOM:
1009 Rtv = SkGePortCheckUpBcom(pAC, IoC, Port, AutoNeg);
1010 break;
1011#ifdef OTHER_PHY
1012 case SK_PHY_LONE:
1013 Rtv = SkGePortCheckUpLone(pAC, IoC, Port, AutoNeg);
1014 break;
1015 case SK_PHY_NAT:
1016 Rtv = SkGePortCheckUpNat(pAC, IoC, Port, AutoNeg);
1017 break;
1018#endif /* OTHER_PHY */
1019 }
1020 }
1021#endif /* GENESIS */
1022
1023#ifdef YUKON
1024 if (pAC->GIni.GIYukon) {
1025
1026 Rtv = SkGePortCheckUpGmac(pAC, IoC, Port, AutoNeg);
1027 }
1028#endif /* YUKON */
1029
1030 return(Rtv);
1031} /* SkGePortCheckUp */
1032
1033
1034#ifdef GENESIS
1035/******************************************************************************
1036 *
1037 * SkGePortCheckUpXmac() - Implementing of the Workaround Errata # 2
1038 *
1039 * return:
1040 * 0 o.k. nothing needed
1041 * 1 Restart needed on this port
1042 * 2 Link came up
1043 */
1044static int SkGePortCheckUpXmac(
1045SK_AC *pAC, /* Adapter Context */
1046SK_IOC IoC, /* IO Context */
1047int Port, /* Which port should be checked */
1048SK_BOOL AutoNeg) /* Is Auto-negotiation used ? */
1049{
1050 SK_U32 Shorts; /* Short Event Counter */
1051 SK_GEPORT *pPrt; /* GIni Port struct pointer */
1052 int Done;
1053 SK_U32 GpReg; /* General Purpose register value */
1054 SK_U16 Isrc; /* Interrupt source register */
1055 SK_U16 IsrcSum; /* Interrupt source register sum */
1056 SK_U16 LpAb; /* Link Partner Ability */
1057 SK_U16 ResAb; /* Resolved Ability */
1058 SK_U16 ExtStat; /* Extended Status Register */
1059 SK_U8 NextMode; /* Next AutoSensing Mode */
1060
1061 pPrt = &pAC->GIni.GP[Port];
1062
1063 if (pPrt->PHWLinkUp) {
1064 if (pPrt->PhyType != SK_PHY_XMAC) {
1065 return(SK_HW_PS_NONE);
1066 }
1067 else {
1068 return(SkGePortCheckShorts(pAC, IoC, Port));
1069 }
1070 }
1071
1072 IsrcSum = pPrt->PIsave;
1073 pPrt->PIsave = 0;
1074
1075 /* Now wait for each port's link */
1076 if (pPrt->PLinkBroken) {
1077 /* Link was broken */
1078 XM_IN32(IoC, Port, XM_GP_PORT, &GpReg);
1079
1080 if ((GpReg & XM_GP_INP_ASS) == 0) {
1081 /* The Link is in sync */
1082 XM_IN16(IoC, Port, XM_ISRC, &Isrc);
1083 IsrcSum |= Isrc;
1084 SkXmAutoNegLipaXmac(pAC, IoC, Port, IsrcSum);
1085
1086 if ((Isrc & XM_IS_INP_ASS) == 0) {
1087 /* It has been in sync since last time */
1088 /* Restart the PORT */
1089 SK_DBG_MSG(pAC, SK_DBGMOD_HWM, SK_DBGCAT_IRQ,
1090 ("Link in sync Restart Port %d\n", Port));
1091
1092 (void)SkXmUpdateStats(pAC, IoC, Port);
1093
1094 /* We now need to reinitialize the PrevShorts counter */
1095 (void)SkXmMacStatistic(pAC, IoC, Port, XM_RXE_SHT_ERR, &Shorts);
1096 pPrt->PPrevShorts = Shorts;
1097
1098 pPrt->PLinkBroken = SK_FALSE;
1099
1100 /*
1101 * Link Restart Workaround:
1102 * it may be possible that the other Link side
1103 * restarts its link as well an we detect
1104 * another LinkBroken. To prevent this
1105 * happening we check for a maximum number
1106 * of consecutive restart. If those happens,
1107 * we do NOT restart the active link and
1108 * check whether the link is now o.k.
1109 */
1110 pPrt->PLinkResCt++;
1111
1112 pPrt->PAutoNegTimeOut = 0;
1113
1114 if (pPrt->PLinkResCt < SK_MAX_LRESTART) {
1115 return(SK_HW_PS_RESTART);
1116 }
1117
1118 pPrt->PLinkResCt = 0;
1119
1120 SK_DBG_MSG(pAC, SK_DBGMOD_HWM, SK_DBGCAT_CTRL,
1121 ("Do NOT restart on Port %d %x %x\n", Port, Isrc, IsrcSum));
1122 }
1123 else {
1124 pPrt->PIsave = (SK_U16)(IsrcSum & XM_IS_AND);
1125
1126 SK_DBG_MSG(pAC, SK_DBGMOD_HWM, SK_DBGCAT_CTRL,
1127 ("Save Sync/nosync Port %d %x %x\n", Port, Isrc, IsrcSum));
1128
1129 /* Do nothing more if link is broken */
1130 return(SK_HW_PS_NONE);
1131 }
1132 }
1133 else {
1134 /* Do nothing more if link is broken */
1135 return(SK_HW_PS_NONE);
1136 }
1137
1138 }
1139 else {
1140 /* Link was not broken, check if it is */
1141 XM_IN16(IoC, Port, XM_ISRC, &Isrc);
1142 IsrcSum |= Isrc;
1143 if ((Isrc & XM_IS_INP_ASS) != 0) {
1144 XM_IN16(IoC, Port, XM_ISRC, &Isrc);
1145 IsrcSum |= Isrc;
1146 if ((Isrc & XM_IS_INP_ASS) != 0) {
1147 XM_IN16(IoC, Port, XM_ISRC, &Isrc);
1148 IsrcSum |= Isrc;
1149 if ((Isrc & XM_IS_INP_ASS) != 0) {
1150 pPrt->PLinkBroken = SK_TRUE;
1151 /* Re-Init Link partner Autoneg flag */
1152 pPrt->PLipaAutoNeg = SK_LIPA_UNKNOWN;
1153 SK_DBG_MSG(pAC, SK_DBGMOD_HWM, SK_DBGCAT_IRQ,
1154 ("Link broken Port %d\n", Port));
1155
1156 /* Cable removed-> reinit sense mode */
1157 SkHWInitDefSense(pAC, IoC, Port);
1158
1159 return(SK_HW_PS_RESTART);
1160 }
1161 }
1162 }
1163 else {
1164 SkXmAutoNegLipaXmac(pAC, IoC, Port, Isrc);
1165
1166 if (SkGePortCheckShorts(pAC, IoC, Port) == SK_HW_PS_RESTART) {
1167 return(SK_HW_PS_RESTART);
1168 }
1169 }
1170 }
1171
1172 /*
1173 * here we usually can check whether the link is in sync and
1174 * auto-negotiation is done.
1175 */
1176 XM_IN32(IoC, Port, XM_GP_PORT, &GpReg);
1177 XM_IN16(IoC, Port, XM_ISRC, &Isrc);
1178 IsrcSum |= Isrc;
1179
1180 SkXmAutoNegLipaXmac(pAC, IoC, Port, IsrcSum);
1181
1182 if ((GpReg & XM_GP_INP_ASS) != 0 || (IsrcSum & XM_IS_INP_ASS) != 0) {
1183 if ((GpReg & XM_GP_INP_ASS) == 0) {
1184 /* Save Auto-negotiation Done interrupt only if link is in sync */
1185 pPrt->PIsave = (SK_U16)(IsrcSum & XM_IS_AND);
1186 }
1187#ifdef DEBUG
1188 if ((pPrt->PIsave & XM_IS_AND) != 0) {
1189 SK_DBG_MSG(pAC, SK_DBGMOD_HWM, SK_DBGCAT_CTRL,
1190 ("AutoNeg done rescheduled Port %d\n", Port));
1191 }
1192#endif /* DEBUG */
1193 return(SK_HW_PS_NONE);
1194 }
1195
1196 if (AutoNeg) {
1197 if ((IsrcSum & XM_IS_AND) != 0) {
1198 SkHWLinkUp(pAC, IoC, Port);
1199 Done = SkMacAutoNegDone(pAC, IoC, Port);
1200 if (Done != SK_AND_OK) {
1201 /* Get PHY parameters, for debugging only */
1202 SkXmPhyRead(pAC, IoC, Port, PHY_XMAC_AUNE_LP, &LpAb);
1203 SkXmPhyRead(pAC, IoC, Port, PHY_XMAC_RES_ABI, &ResAb);
1204 SK_DBG_MSG(pAC, SK_DBGMOD_HWM, SK_DBGCAT_CTRL,
1205 ("AutoNeg FAIL Port %d (LpAb %x, ResAb %x)\n",
1206 Port, LpAb, ResAb));
1207
1208 /* Try next possible mode */
1209 NextMode = SkHWSenseGetNext(pAC, IoC, Port);
1210 SkHWLinkDown(pAC, IoC, Port);
1211 if (Done == SK_AND_DUP_CAP) {
1212 /* GoTo next mode */
1213 SkHWSenseSetNext(pAC, IoC, Port, NextMode);
1214 }
1215
1216 return(SK_HW_PS_RESTART);
1217 }
1218 /*
1219 * Dummy Read extended status to prevent extra link down/ups
1220 * (clear Page Received bit if set)
1221 */
1222 SkXmPhyRead(pAC, IoC, Port, PHY_XMAC_AUNE_EXP, &ExtStat);
1223
1224 return(SK_HW_PS_LINK);
1225 }
1226
1227 /* AutoNeg not done, but HW link is up. Check for timeouts */
1228 pPrt->PAutoNegTimeOut++;
1229 if (pPrt->PAutoNegTimeOut >= SK_AND_MAX_TO) {
1230 /* Increase the Timeout counter */
1231 pPrt->PAutoNegTOCt++;
1232
1233 /* Timeout occured */
1234 SK_DBG_MSG(pAC, SK_DBGMOD_HWM, SK_DBGCAT_IRQ,
1235 ("AutoNeg timeout Port %d\n", Port));
1236 if (pPrt->PLinkModeConf == SK_LMODE_AUTOSENSE &&
1237 pPrt->PLipaAutoNeg != SK_LIPA_AUTO) {
1238 /* Set Link manually up */
1239 SkHWSenseSetNext(pAC, IoC, Port, SK_LMODE_FULL);
1240 SK_DBG_MSG(pAC, SK_DBGMOD_HWM, SK_DBGCAT_IRQ,
1241 ("Set manual full duplex Port %d\n", Port));
1242 }
1243
1244 if (pPrt->PLinkModeConf == SK_LMODE_AUTOSENSE &&
1245 pPrt->PLipaAutoNeg == SK_LIPA_AUTO &&
1246 pPrt->PAutoNegTOCt >= SK_MAX_ANEG_TO) {
1247 /*
1248 * This is rather complicated.
1249 * we need to check here whether the LIPA_AUTO
1250 * we saw before is false alert. We saw at one
1251 * switch ( SR8800) that on boot time it sends
1252 * just one auto-neg packet and does no further
1253 * auto-negotiation.
1254 * Solution: we restart the autosensing after
1255 * a few timeouts.
1256 */
1257 pPrt->PAutoNegTOCt = 0;
1258 pPrt->PLipaAutoNeg = SK_LIPA_UNKNOWN;
1259 SkHWInitDefSense(pAC, IoC, Port);
1260 }
1261
1262 /* Do the restart */
1263 return(SK_HW_PS_RESTART);
1264 }
1265 }
1266 else {
1267 /* Link is up and we don't need more */
1268#ifdef DEBUG
1269 if (pPrt->PLipaAutoNeg == SK_LIPA_AUTO) {
1270 SK_DBG_MSG(pAC, SK_DBGMOD_HWM, SK_DBGCAT_CTRL,
1271 ("ERROR: Lipa auto detected on port %d\n", Port));
1272 }
1273#endif /* DEBUG */
1274 SK_DBG_MSG(pAC, SK_DBGMOD_HWM, SK_DBGCAT_IRQ,
1275 ("Link sync(GP), Port %d\n", Port));
1276 SkHWLinkUp(pAC, IoC, Port);
1277
1278 /*
1279 * Link sync (GP) and so assume a good connection. But if not received
1280 * a bunch of frames received in a time slot (maybe broken tx cable)
1281 * the port is restart.
1282 */
1283 return(SK_HW_PS_LINK);
1284 }
1285
1286 return(SK_HW_PS_NONE);
1287} /* SkGePortCheckUpXmac */
1288
1289
1290/******************************************************************************
1291 *
1292 * SkGePortCheckUpBcom() - Check if the link is up on Bcom PHY
1293 *
1294 * return:
1295 * 0 o.k. nothing needed
1296 * 1 Restart needed on this port
1297 * 2 Link came up
1298 */
1299static int SkGePortCheckUpBcom(
1300SK_AC *pAC, /* Adapter Context */
1301SK_IOC IoC, /* IO Context */
1302int Port, /* Which port should be checked */
1303SK_BOOL AutoNeg) /* Is Auto-negotiation used ? */
1304{
1305 SK_GEPORT *pPrt; /* GIni Port struct pointer */
1306 int Done;
1307 SK_U16 Isrc; /* Interrupt source register */
1308 SK_U16 PhyStat; /* Phy Status Register */
1309 SK_U16 ResAb; /* Master/Slave resolution */
1310 SK_U16 Ctrl; /* Broadcom control flags */
1311#ifdef DEBUG
1312 SK_U16 LpAb;
1313 SK_U16 ExtStat;
1314#endif /* DEBUG */
1315
1316 pPrt = &pAC->GIni.GP[Port];
1317
1318 /* Check for No HCD Link events (#10523) */
1319 SkXmPhyRead(pAC, IoC, Port, PHY_BCOM_INT_STAT, &Isrc);
1320
1321#ifdef xDEBUG
1322 if ((Isrc & ~(PHY_B_IS_HCT | PHY_B_IS_LCT)) ==
1323 (PHY_B_IS_SCR_S_ER | PHY_B_IS_RRS_CHANGE | PHY_B_IS_LRS_CHANGE)) {
1324
1325 SK_U32 Stat1, Stat2, Stat3;
1326
1327 Stat1 = 0;
1328 SkXmPhyRead(pAC, IoC, Port, PHY_BCOM_INT_MASK, &Stat1);
1329 CMSMPrintString(
1330 pAC->pConfigTable,
1331 MSG_TYPE_RUNTIME_INFO,
1332 "CheckUp1 - Stat: %x, Mask: %x",
1333 (void *)Isrc,
1334 (void *)Stat1);
1335
1336 Stat1 = 0;
1337 SkXmPhyRead(pAC, IoC, Port, PHY_BCOM_CTRL, &Stat1);
1338 Stat2 = 0;
1339 SkXmPhyRead(pAC, IoC, Port, PHY_BCOM_STAT, &Stat2);
1340 Stat1 = Stat1 << 16 | Stat2;
1341 Stat2 = 0;
1342 SkXmPhyRead(pAC, IoC, Port, PHY_BCOM_AUNE_ADV, &Stat2);
1343 Stat3 = 0;
1344 SkXmPhyRead(pAC, IoC, Port, PHY_BCOM_AUNE_LP, &Stat3);
1345 Stat2 = Stat2 << 16 | Stat3;
1346 CMSMPrintString(
1347 pAC->pConfigTable,
1348 MSG_TYPE_RUNTIME_INFO,
1349 "Ctrl/Stat: %x, AN Adv/LP: %x",
1350 (void *)Stat1,
1351 (void *)Stat2);
1352
1353 Stat1 = 0;
1354 SkXmPhyRead(pAC, IoC, Port, PHY_BCOM_AUNE_EXP, &Stat1);
1355 Stat2 = 0;
1356 SkXmPhyRead(pAC, IoC, Port, PHY_BCOM_EXT_STAT, &Stat2);
1357 Stat1 = Stat1 << 16 | Stat2;
1358 Stat2 = 0;
1359 SkXmPhyRead(pAC, IoC, Port, PHY_BCOM_1000T_CTRL, &Stat2);
1360 Stat3 = 0;
1361 SkXmPhyRead(pAC, IoC, Port, PHY_BCOM_1000T_STAT, &Stat3);
1362 Stat2 = Stat2 << 16 | Stat3;
1363 CMSMPrintString(
1364 pAC->pConfigTable,
1365 MSG_TYPE_RUNTIME_INFO,
1366 "AN Exp/IEEE Ext: %x, 1000T Ctrl/Stat: %x",
1367 (void *)Stat1,
1368 (void *)Stat2);
1369
1370 Stat1 = 0;
1371 SkXmPhyRead(pAC, IoC, Port, PHY_BCOM_P_EXT_CTRL, &Stat1);
1372 Stat2 = 0;
1373 SkXmPhyRead(pAC, IoC, Port, PHY_BCOM_P_EXT_STAT, &Stat2);
1374 Stat1 = Stat1 << 16 | Stat2;
1375 Stat2 = 0;
1376 SkXmPhyRead(pAC, IoC, Port, PHY_BCOM_AUX_CTRL, &Stat2);
1377 Stat3 = 0;
1378 SkXmPhyRead(pAC, IoC, Port, PHY_BCOM_AUX_STAT, &Stat3);
1379 Stat2 = Stat2 << 16 | Stat3;
1380 CMSMPrintString(
1381 pAC->pConfigTable,
1382 MSG_TYPE_RUNTIME_INFO,
1383 "PHY Ext Ctrl/Stat: %x, Aux Ctrl/Stat: %x",
1384 (void *)Stat1,
1385 (void *)Stat2);
1386 }
1387#endif /* DEBUG */
1388
1389 if ((Isrc & (PHY_B_IS_NO_HDCL /* | PHY_B_IS_NO_HDC */)) != 0) {
1390 /*
1391 * Workaround BCom Errata:
1392 * enable and disable loopback mode if "NO HCD" occurs.
1393 */
1394 SkXmPhyRead(pAC, IoC, Port, PHY_BCOM_CTRL, &Ctrl);
1395 SkXmPhyWrite(pAC, IoC, Port, PHY_BCOM_CTRL,
1396 (SK_U16)(Ctrl | PHY_CT_LOOP));
1397 SkXmPhyWrite(pAC, IoC, Port, PHY_BCOM_CTRL,
1398 (SK_U16)(Ctrl & ~PHY_CT_LOOP));
1399 SK_DBG_MSG(pAC, SK_DBGMOD_HWM, SK_DBGCAT_CTRL,
1400 ("No HCD Link event, Port %d\n", Port));
1401#ifdef xDEBUG
1402 CMSMPrintString(
1403 pAC->pConfigTable,
1404 MSG_TYPE_RUNTIME_INFO,
1405 "No HCD link event, port %d.",
1406 (void *)Port,
1407 (void *)NULL);
1408#endif /* DEBUG */
1409 }
1410
1411 /* Not obsolete: link status bit is latched to 0 and autoclearing! */
1412 SkXmPhyRead(pAC, IoC, Port, PHY_BCOM_STAT, &PhyStat);
1413
1414 if (pPrt->PHWLinkUp) {
1415 return(SK_HW_PS_NONE);
1416 }
1417
1418#ifdef xDEBUG
1419 {
1420 SK_U32 Stat1, Stat2, Stat3;
1421
1422 Stat1 = 0;
1423 SkXmPhyRead(pAC, IoC, Port, PHY_BCOM_INT_MASK, &Stat1);
1424 CMSMPrintString(
1425 pAC->pConfigTable,
1426 MSG_TYPE_RUNTIME_INFO,
1427 "CheckUp1a - Stat: %x, Mask: %x",
1428 (void *)Isrc,
1429 (void *)Stat1);
1430
1431 Stat1 = 0;
1432 SkXmPhyRead(pAC, IoC, Port, PHY_BCOM_CTRL, &Stat1);
1433 Stat2 = 0;
1434 SkXmPhyRead(pAC, IoC, Port, PHY_BCOM_STAT, &PhyStat);
1435 Stat1 = Stat1 << 16 | PhyStat;
1436 Stat2 = 0;
1437 SkXmPhyRead(pAC, IoC, Port, PHY_BCOM_AUNE_ADV, &Stat2);
1438 Stat3 = 0;
1439 SkXmPhyRead(pAC, IoC, Port, PHY_BCOM_AUNE_LP, &Stat3);
1440 Stat2 = Stat2 << 16 | Stat3;
1441 CMSMPrintString(
1442 pAC->pConfigTable,
1443 MSG_TYPE_RUNTIME_INFO,
1444 "Ctrl/Stat: %x, AN Adv/LP: %x",
1445 (void *)Stat1,
1446 (void *)Stat2);
1447
1448 Stat1 = 0;
1449 SkXmPhyRead(pAC, IoC, Port, PHY_BCOM_AUNE_EXP, &Stat1);
1450 Stat2 = 0;
1451 SkXmPhyRead(pAC, IoC, Port, PHY_BCOM_EXT_STAT, &Stat2);
1452 Stat1 = Stat1 << 16 | Stat2;
1453 Stat2 = 0;
1454 SkXmPhyRead(pAC, IoC, Port, PHY_BCOM_1000T_CTRL, &Stat2);
1455 Stat3 = 0;
1456 SkXmPhyRead(pAC, IoC, Port, PHY_BCOM_1000T_STAT, &ResAb);
1457 Stat2 = Stat2 << 16 | ResAb;
1458 CMSMPrintString(
1459 pAC->pConfigTable,
1460 MSG_TYPE_RUNTIME_INFO,
1461 "AN Exp/IEEE Ext: %x, 1000T Ctrl/Stat: %x",
1462 (void *)Stat1,
1463 (void *)Stat2);
1464
1465 Stat1 = 0;
1466 SkXmPhyRead(pAC, IoC, Port, PHY_BCOM_P_EXT_CTRL, &Stat1);
1467 Stat2 = 0;
1468 SkXmPhyRead(pAC, IoC, Port, PHY_BCOM_P_EXT_STAT, &Stat2);
1469 Stat1 = Stat1 << 16 | Stat2;
1470 Stat2 = 0;
1471 SkXmPhyRead(pAC, IoC, Port, PHY_BCOM_AUX_CTRL, &Stat2);
1472 Stat3 = 0;
1473 SkXmPhyRead(pAC, IoC, Port, PHY_BCOM_AUX_STAT, &Stat3);
1474 Stat2 = Stat2 << 16 | Stat3;
1475 CMSMPrintString(
1476 pAC->pConfigTable,
1477 MSG_TYPE_RUNTIME_INFO,
1478 "PHY Ext Ctrl/Stat: %x, Aux Ctrl/Stat: %x",
1479 (void *)Stat1,
1480 (void *)Stat2);
1481 }
1482#endif /* DEBUG */
1483
1484 /*
1485 * Here we usually can check whether the link is in sync and
1486 * auto-negotiation is done.
1487 */
1488
1489 SkXmPhyRead(pAC, IoC, Port, PHY_BCOM_STAT, &PhyStat);
1490
1491 SkMacAutoNegLipaPhy(pAC, IoC, Port, PhyStat);
1492
1493 SK_DBG_MSG(pAC, SK_DBGMOD_HWM, SK_DBGCAT_CTRL,
1494 ("CheckUp Port %d, PhyStat: 0x%04X\n", Port, PhyStat));
1495
1496 SkXmPhyRead(pAC, IoC, Port, PHY_BCOM_1000T_STAT, &ResAb);
1497
1498 if ((ResAb & PHY_B_1000S_MSF) != 0) {
1499 /* Error */
1500 SK_DBG_MSG(pAC, SK_DBGMOD_HWM, SK_DBGCAT_CTRL,
1501 ("Master/Slave Fault port %d\n", Port));
1502
1503 pPrt->PAutoNegFail = SK_TRUE;
1504 pPrt->PMSStatus = SK_MS_STAT_FAULT;
1505
1506 return(SK_HW_PS_RESTART);
1507 }
1508
1509 if ((PhyStat & PHY_ST_LSYNC) == 0) {
1510 return(SK_HW_PS_NONE);
1511 }
1512
1513 pPrt->PMSStatus = ((ResAb & PHY_B_1000S_MSR) != 0) ?
1514 SK_MS_STAT_MASTER : SK_MS_STAT_SLAVE;
1515
1516 SK_DBG_MSG(pAC, SK_DBGMOD_HWM, SK_DBGCAT_CTRL,
1517 ("Port %d, ResAb: 0x%04X\n", Port, ResAb));
1518
1519 if (AutoNeg) {
1520 if ((PhyStat & PHY_ST_AN_OVER) != 0) {
1521
1522 SkHWLinkUp(pAC, IoC, Port);
1523
1524 Done = SkMacAutoNegDone(pAC, IoC, Port);
1525
1526 if (Done != SK_AND_OK) {
1527#ifdef DEBUG
1528 /* Get PHY parameters, for debugging only */
1529 SkXmPhyRead(pAC, IoC, Port, PHY_BCOM_AUNE_LP, &LpAb);
1530 SkXmPhyRead(pAC, IoC, Port, PHY_BCOM_1000T_STAT, &ExtStat);
1531 SK_DBG_MSG(pAC, SK_DBGMOD_HWM, SK_DBGCAT_CTRL,
1532 ("AutoNeg FAIL Port %d (LpAb %x, 1000TStat %x)\n",
1533 Port, LpAb, ExtStat));
1534#endif /* DEBUG */
1535 return(SK_HW_PS_RESTART);
1536 }
1537 else {
1538#ifdef xDEBUG
1539 /* Dummy read ISR to prevent extra link downs/ups */
1540 SkXmPhyRead(pAC, IoC, Port, PHY_BCOM_INT_STAT, &ExtStat);
1541
1542 if ((ExtStat & ~(PHY_B_IS_HCT | PHY_B_IS_LCT)) != 0) {
1543 CMSMPrintString(
1544 pAC->pConfigTable,
1545 MSG_TYPE_RUNTIME_INFO,
1546 "CheckUp2 - Stat: %x",
1547 (void *)ExtStat,
1548 (void *)NULL);
1549 }
1550#endif /* DEBUG */
1551 return(SK_HW_PS_LINK);
1552 }
1553 }
1554 }
1555 else { /* !AutoNeg */
1556 /* Link is up and we don't need more. */
1557#ifdef DEBUG
1558 if (pPrt->PLipaAutoNeg == SK_LIPA_AUTO) {
1559 SK_DBG_MSG(pAC, SK_DBGMOD_HWM, SK_DBGCAT_CTRL,
1560 ("ERROR: Lipa auto detected on port %d\n", Port));
1561 }
1562#endif /* DEBUG */
1563
1564#ifdef xDEBUG
1565 /* Dummy read ISR to prevent extra link downs/ups */
1566 SkXmPhyRead(pAC, IoC, Port, PHY_BCOM_INT_STAT, &ExtStat);
1567
1568 if ((ExtStat & ~(PHY_B_IS_HCT | PHY_B_IS_LCT)) != 0) {
1569 CMSMPrintString(
1570 pAC->pConfigTable,
1571 MSG_TYPE_RUNTIME_INFO,
1572 "CheckUp3 - Stat: %x",
1573 (void *)ExtStat,
1574 (void *)NULL);
1575 }
1576#endif /* DEBUG */
1577
1578 SK_DBG_MSG(pAC, SK_DBGMOD_HWM, SK_DBGCAT_IRQ,
1579 ("Link sync(GP), Port %d\n", Port));
1580 SkHWLinkUp(pAC, IoC, Port);
1581
1582 return(SK_HW_PS_LINK);
1583 }
1584
1585 return(SK_HW_PS_NONE);
1586} /* SkGePortCheckUpBcom */
1587#endif /* GENESIS */
1588
1589
1590#ifdef YUKON
1591/******************************************************************************
1592 *
1593 * SkGePortCheckUpGmac() - Check if the link is up on Marvell PHY
1594 *
1595 * return:
1596 * 0 o.k. nothing needed
1597 * 1 Restart needed on this port
1598 * 2 Link came up
1599 */
1600static int SkGePortCheckUpGmac(
1601SK_AC *pAC, /* Adapter Context */
1602SK_IOC IoC, /* IO Context */
1603int Port, /* Which port should be checked */
1604SK_BOOL AutoNeg) /* Is Auto-negotiation used ? */
1605{
1606 SK_GEPORT *pPrt; /* GIni Port struct pointer */
1607 int Done;
1608 SK_U16 PhyIsrc; /* PHY Interrupt source */
1609 SK_U16 PhyStat; /* PPY Status */
1610 SK_U16 PhySpecStat;/* PHY Specific Status */
1611 SK_U16 ResAb; /* Master/Slave resolution */
1612 SK_EVPARA Para;
1613#ifdef DEBUG
1614 SK_U16 Word; /* I/O helper */
1615#endif /* DEBUG */
1616
1617 pPrt = &pAC->GIni.GP[Port];
1618
1619 if (pPrt->PHWLinkUp) {
1620 return(SK_HW_PS_NONE);
1621 }
1622
1623 /* Read PHY Status */
1624 SkGmPhyRead(pAC, IoC, Port, PHY_MARV_STAT, &PhyStat);
1625
1626 SK_DBG_MSG(pAC, SK_DBGMOD_HWM, SK_DBGCAT_CTRL,
1627 ("CheckUp Port %d, PhyStat: 0x%04X\n", Port, PhyStat));
1628
1629 /* Read PHY Interrupt Status */
1630 SkGmPhyRead(pAC, IoC, Port, PHY_MARV_INT_STAT, &PhyIsrc);
1631
1632 if ((PhyIsrc & PHY_M_IS_AN_COMPL) != 0) {
1633 SK_DBG_MSG(pAC, SK_DBGMOD_HWM, SK_DBGCAT_CTRL,
1634 ("Auto-Negotiation Completed, PhyIsrc: 0x%04X\n", PhyIsrc));
1635 }
1636
1637 if ((PhyIsrc & PHY_M_IS_LSP_CHANGE) != 0) {
1638 SK_DBG_MSG(pAC, SK_DBGMOD_HWM, SK_DBGCAT_CTRL,
1639 ("Link Speed Changed, PhyIsrc: 0x%04X\n", PhyIsrc));
1640 }
1641
1642 SkMacAutoNegLipaPhy(pAC, IoC, Port, PhyStat);
1643
1644 SkGmPhyRead(pAC, IoC, Port, PHY_MARV_1000T_STAT, &ResAb);
1645
1646 if ((ResAb & PHY_B_1000S_MSF) != 0) {
1647 /* Error */
1648 SK_DBG_MSG(pAC, SK_DBGMOD_HWM, SK_DBGCAT_CTRL,
1649 ("Master/Slave Fault port %d\n", Port));
1650
1651 pPrt->PAutoNegFail = SK_TRUE;
1652 pPrt->PMSStatus = SK_MS_STAT_FAULT;
1653
1654 return(SK_HW_PS_RESTART);
1655 }
1656
1657 /* Read PHY Specific Status */
1658 SkGmPhyRead(pAC, IoC, Port, PHY_MARV_PHY_STAT, &PhySpecStat);
1659
1660 SK_DBG_MSG(pAC, SK_DBGMOD_HWM, SK_DBGCAT_CTRL,
1661 ("Phy1000BT: 0x%04X, PhySpecStat: 0x%04X\n", ResAb, PhySpecStat));
1662
1663#ifdef DEBUG
1664 SkGmPhyRead(pAC, IoC, Port, PHY_MARV_AUNE_EXP, &Word);
1665
1666 if ((PhyIsrc & PHY_M_IS_AN_PR) != 0 || (Word & PHY_ANE_RX_PG) != 0 ||
1667 (PhySpecStat & PHY_M_PS_PAGE_REC) != 0) {
1668 /* Read PHY Next Page Link Partner */
1669 SkGmPhyRead(pAC, IoC, Port, PHY_MARV_NEPG_LP, &Word);
1670
1671 SK_DBG_MSG(pAC, SK_DBGMOD_HWM, SK_DBGCAT_CTRL,
1672 ("Page Received, NextPage: 0x%04X\n", Word));
1673 }
1674#endif /* DEBUG */
1675
1676 if ((PhySpecStat & PHY_M_PS_LINK_UP) == 0) {
1677 return(SK_HW_PS_NONE);
1678 }
1679
1680 if ((PhySpecStat & PHY_M_PS_DOWNS_STAT) != 0 ||
1681 (PhyIsrc & PHY_M_IS_DOWNSH_DET) != 0) {
1682 /* Downshift detected */
1683 SK_ERR_LOG(pAC, SK_ERRCL_HW, SKERR_SIRQ_E025, SKERR_SIRQ_E025MSG);
1684
1685 Para.Para64 = Port;
1686 SkEventQueue(pAC, SKGE_DRV, SK_DRV_DOWNSHIFT_DET, Para);
1687
1688 SK_DBG_MSG(pAC, SK_DBGMOD_HWM, SK_DBGCAT_CTRL,
1689 ("Downshift detected, PhyIsrc: 0x%04X\n", PhyIsrc));
1690 }
1691
1692 pPrt->PMSStatus = ((ResAb & PHY_B_1000S_MSR) != 0) ?
1693 SK_MS_STAT_MASTER : SK_MS_STAT_SLAVE;
1694
1695 pPrt->PCableLen = (SK_U8)((PhySpecStat & PHY_M_PS_CABLE_MSK) >> 7);
1696
1697 if (AutoNeg) {
1698 /* Auto-Negotiation Over ? */
1699 if ((PhyStat & PHY_ST_AN_OVER) != 0) {
1700
1701 SkHWLinkUp(pAC, IoC, Port);
1702
1703 Done = SkMacAutoNegDone(pAC, IoC, Port);
1704
1705 if (Done != SK_AND_OK) {
1706 return(SK_HW_PS_RESTART);
1707 }
1708
1709 return(SK_HW_PS_LINK);
1710 }
1711 }
1712 else { /* !AutoNeg */
1713 /* Link is up and we don't need more */
1714#ifdef DEBUG
1715 if (pPrt->PLipaAutoNeg == SK_LIPA_AUTO) {
1716 SK_DBG_MSG(pAC, SK_DBGMOD_HWM, SK_DBGCAT_CTRL,
1717 ("ERROR: Lipa auto detected on port %d\n", Port));
1718 }
1719#endif /* DEBUG */
1720
1721 SK_DBG_MSG(pAC, SK_DBGMOD_HWM, SK_DBGCAT_IRQ,
1722 ("Link sync, Port %d\n", Port));
1723 SkHWLinkUp(pAC, IoC, Port);
1724
1725 return(SK_HW_PS_LINK);
1726 }
1727
1728 return(SK_HW_PS_NONE);
1729} /* SkGePortCheckUpGmac */
1730#endif /* YUKON */
1731
1732
1733#ifdef OTHER_PHY
1734/******************************************************************************
1735 *
1736 * SkGePortCheckUpLone() - Check if the link is up on Level One PHY
1737 *
1738 * return:
1739 * 0 o.k. nothing needed
1740 * 1 Restart needed on this port
1741 * 2 Link came up
1742 */
1743static int SkGePortCheckUpLone(
1744SK_AC *pAC, /* Adapter Context */
1745SK_IOC IoC, /* IO Context */
1746int Port, /* Which port should be checked */
1747SK_BOOL AutoNeg) /* Is Auto-negotiation used ? */
1748{
1749 SK_GEPORT *pPrt; /* GIni Port struct pointer */
1750 int Done;
1751 SK_U16 Isrc; /* Interrupt source register */
1752 SK_U16 LpAb; /* Link Partner Ability */
1753 SK_U16 ExtStat; /* Extended Status Register */
1754 SK_U16 PhyStat; /* Phy Status Register */
1755 SK_U16 StatSum;
1756 SK_U8 NextMode; /* Next AutoSensing Mode */
1757
1758 pPrt = &pAC->GIni.GP[Port];
1759
1760 if (pPrt->PHWLinkUp) {
1761 return(SK_HW_PS_NONE);
1762 }
1763
1764 StatSum = pPrt->PIsave;
1765 pPrt->PIsave = 0;
1766
1767 /*
1768 * here we usually can check whether the link is in sync and
1769 * auto-negotiation is done.
1770 */
1771 SkXmPhyRead(pAC, IoC, Port, PHY_LONE_STAT, &PhyStat);
1772 StatSum |= PhyStat;
1773
1774 SkMacAutoNegLipaPhy(pAC, IoC, Port, PhyStat);
1775
1776 if ((PhyStat & PHY_ST_LSYNC) == 0) {
1777 /* Save Auto-negotiation Done bit */
1778 pPrt->PIsave = (SK_U16)(StatSum & PHY_ST_AN_OVER);
1779#ifdef DEBUG
1780 if ((pPrt->PIsave & PHY_ST_AN_OVER) != 0) {
1781 SK_DBG_MSG(pAC, SK_DBGMOD_HWM, SK_DBGCAT_CTRL,
1782 ("AutoNeg done rescheduled Port %d\n", Port));
1783 }
1784#endif /* DEBUG */
1785 return(SK_HW_PS_NONE);
1786 }
1787
1788 if (AutoNeg) {
1789 if ((StatSum & PHY_ST_AN_OVER) != 0) {
1790 SkHWLinkUp(pAC, IoC, Port);
1791 Done = SkMacAutoNegDone(pAC, IoC, Port);
1792 if (Done != SK_AND_OK) {
1793 /* Get PHY parameters, for debugging only */
1794 SkXmPhyRead(pAC, IoC, Port, PHY_LONE_AUNE_LP, &LpAb);
1795 SkXmPhyRead(pAC, IoC, Port, PHY_LONE_1000T_STAT, &ExtStat);
1796 SK_DBG_MSG(pAC, SK_DBGMOD_HWM, SK_DBGCAT_CTRL,
1797 ("AutoNeg FAIL Port %d (LpAb %x, 1000TStat %x)\n",
1798 Port, LpAb, ExtStat));
1799
1800 /* Try next possible mode */
1801 NextMode = SkHWSenseGetNext(pAC, IoC, Port);
1802 SkHWLinkDown(pAC, IoC, Port);
1803 if (Done == SK_AND_DUP_CAP) {
1804 /* GoTo next mode */
1805 SkHWSenseSetNext(pAC, IoC, Port, NextMode);
1806 }
1807
1808 return(SK_HW_PS_RESTART);
1809
1810 }
1811 else {
1812 /*
1813 * Dummy Read interrupt status to prevent
1814 * extra link down/ups
1815 */
1816 SkXmPhyRead(pAC, IoC, Port, PHY_LONE_INT_STAT, &ExtStat);
1817 return(SK_HW_PS_LINK);
1818 }
1819 }
1820
1821 /* AutoNeg not done, but HW link is up. Check for timeouts */
1822 pPrt->PAutoNegTimeOut++;
1823 if (pPrt->PAutoNegTimeOut >= SK_AND_MAX_TO) {
1824 /* Timeout occured */
1825 SK_DBG_MSG(pAC, SK_DBGMOD_HWM, SK_DBGCAT_IRQ,
1826 ("AutoNeg timeout Port %d\n", Port));
1827 if (pPrt->PLinkModeConf == SK_LMODE_AUTOSENSE &&
1828 pPrt->PLipaAutoNeg != SK_LIPA_AUTO) {
1829 /* Set Link manually up */
1830 SkHWSenseSetNext(pAC, IoC, Port, SK_LMODE_FULL);
1831 SK_DBG_MSG(pAC, SK_DBGMOD_HWM, SK_DBGCAT_IRQ,
1832 ("Set manual full duplex Port %d\n", Port));
1833 }
1834
1835 /* Do the restart */
1836 return(SK_HW_PS_RESTART);
1837 }
1838 }
1839 else {
1840 /* Link is up and we don't need more */
1841#ifdef DEBUG
1842 if (pPrt->PLipaAutoNeg == SK_LIPA_AUTO) {
1843 SK_DBG_MSG(pAC, SK_DBGMOD_HWM, SK_DBGCAT_CTRL,
1844 ("ERROR: Lipa auto detected on port %d\n", Port));
1845 }
1846#endif /* DEBUG */
1847
1848 /*
1849 * Dummy Read interrupt status to prevent
1850 * extra link down/ups
1851 */
1852 SkXmPhyRead(pAC, IoC, Port, PHY_LONE_INT_STAT, &ExtStat);
1853
1854 SK_DBG_MSG(pAC, SK_DBGMOD_HWM, SK_DBGCAT_IRQ,
1855 ("Link sync(GP), Port %d\n", Port));
1856 SkHWLinkUp(pAC, IoC, Port);
1857
1858 return(SK_HW_PS_LINK);
1859 }
1860
1861 return(SK_HW_PS_NONE);
1862} /* SkGePortCheckUpLone */
1863
1864
1865/******************************************************************************
1866 *
1867 * SkGePortCheckUpNat() - Check if the link is up on National PHY
1868 *
1869 * return:
1870 * 0 o.k. nothing needed
1871 * 1 Restart needed on this port
1872 * 2 Link came up
1873 */
1874static int SkGePortCheckUpNat(
1875SK_AC *pAC, /* Adapter Context */
1876SK_IOC IoC, /* IO Context */
1877int Port, /* Which port should be checked */
1878SK_BOOL AutoNeg) /* Is Auto-negotiation used ? */
1879{
1880 /* todo: National */
1881 return(SK_HW_PS_NONE);
1882} /* SkGePortCheckUpNat */
1883#endif /* OTHER_PHY */
1884
1885
1886/******************************************************************************
1887 *
1888 * SkGeSirqEvent() - Event Service Routine
1889 *
1890 * Description:
1891 *
1892 * Notes:
1893 */
1894int SkGeSirqEvent(
1895SK_AC *pAC, /* Adapter Context */
1896SK_IOC IoC, /* Io Context */
1897SK_U32 Event, /* Module specific Event */
1898SK_EVPARA Para) /* Event specific Parameter */
1899{
1900 SK_GEPORT *pPrt; /* GIni Port struct pointer */
1901 SK_U32 Port;
1902 SK_U32 Val32;
1903 int PortStat;
1904 SK_U8 Val8;
1905#ifdef GENESIS
1906 SK_U64 Octets;
1907#endif /* GENESIS */
1908
1909 Port = Para.Para32[0];
1910 pPrt = &pAC->GIni.GP[Port];
1911
1912 switch (Event) {
1913 case SK_HWEV_WATIM:
1914 if (pPrt->PState == SK_PRT_RESET) {
1915
1916 PortStat = SK_HW_PS_NONE;
1917 }
1918 else {
1919 /* Check whether port came up */
1920 PortStat = SkGePortCheckUp(pAC, IoC, (int)Port);
1921 }
1922
1923 switch (PortStat) {
1924 case SK_HW_PS_RESTART:
1925 if (pPrt->PHWLinkUp) {
1926 /* Set Link to down */
1927 SkHWLinkDown(pAC, IoC, (int)Port);
1928
1929 /*
1930 * Signal directly to RLMT to ensure correct
1931 * sequence of SWITCH and RESET event.
1932 */
1933 SkRlmtEvent(pAC, IoC, SK_RLMT_LINK_DOWN, Para);
1934 }
1935
1936 /* Restart needed */
1937 SkEventQueue(pAC, SKGE_DRV, SK_DRV_PORT_RESET, Para);
1938 break;
1939
1940 case SK_HW_PS_LINK:
1941 /* Signal to RLMT */
1942 SkEventQueue(pAC, SKGE_RLMT, SK_RLMT_LINK_UP, Para);
1943 break;
1944 }
1945
1946 /* Start again the check Timer */
1947 if (pPrt->PHWLinkUp) {
1948 Val32 = SK_WA_ACT_TIME;
1949 }
1950 else {
1951 Val32 = SK_WA_INA_TIME;
1952 }
1953
1954 /* Todo: still needed for non-XMAC PHYs??? */
1955 /* Start workaround Errata #2 timer */
1956 SkTimerStart(pAC, IoC, &pPrt->PWaTimer, Val32,
1957 SKGE_HWAC, SK_HWEV_WATIM, Para);
1958 break;
1959
1960 case SK_HWEV_PORT_START:
1961 if (pPrt->PHWLinkUp) {
1962 /*
1963 * Signal directly to RLMT to ensure correct
1964 * sequence of SWITCH and RESET event.
1965 */
1966 SkRlmtEvent(pAC, IoC, SK_RLMT_LINK_DOWN, Para);
1967 }
1968
1969 SkHWLinkDown(pAC, IoC, (int)Port);
1970
1971 /* Schedule Port RESET */
1972 SkEventQueue(pAC, SKGE_DRV, SK_DRV_PORT_RESET, Para);
1973
1974 /* Start workaround Errata #2 timer */
1975 SkTimerStart(pAC, IoC, &pPrt->PWaTimer, SK_WA_INA_TIME,
1976 SKGE_HWAC, SK_HWEV_WATIM, Para);
1977 break;
1978
1979 case SK_HWEV_PORT_STOP:
1980 if (pPrt->PHWLinkUp) {
1981 /*
1982 * Signal directly to RLMT to ensure correct
1983 * sequence of SWITCH and RESET event.
1984 */
1985 SkRlmtEvent(pAC, IoC, SK_RLMT_LINK_DOWN, Para);
1986 }
1987
1988 /* Stop Workaround Timer */
1989 SkTimerStop(pAC, IoC, &pPrt->PWaTimer);
1990
1991 SkHWLinkDown(pAC, IoC, (int)Port);
1992 break;
1993
1994 case SK_HWEV_UPDATE_STAT:
1995 /* We do NOT need to update any statistics */
1996 break;
1997
1998 case SK_HWEV_CLEAR_STAT:
1999 /* We do NOT need to clear any statistics */
2000 for (Port = 0; Port < (SK_U32)pAC->GIni.GIMacsFound; Port++) {
2001 pPrt->PPrevRx = 0;
2002 pPrt->PPrevFcs = 0;
2003 pPrt->PPrevShorts = 0;
2004 }
2005 break;
2006
2007 case SK_HWEV_SET_LMODE:
2008 Val8 = (SK_U8)Para.Para32[1];
2009 if (pPrt->PLinkModeConf != Val8) {
2010 /* Set New link mode */
2011 pPrt->PLinkModeConf = Val8;
2012
2013 /* Restart Port */
2014 SkEventQueue(pAC, SKGE_HWAC, SK_HWEV_PORT_STOP, Para);
2015 SkEventQueue(pAC, SKGE_HWAC, SK_HWEV_PORT_START, Para);
2016 }
2017 break;
2018
2019 case SK_HWEV_SET_FLOWMODE:
2020 Val8 = (SK_U8)Para.Para32[1];
2021 if (pPrt->PFlowCtrlMode != Val8) {
2022 /* Set New Flow Control mode */
2023 pPrt->PFlowCtrlMode = Val8;
2024
2025 /* Restart Port */
2026 SkEventQueue(pAC, SKGE_HWAC, SK_HWEV_PORT_STOP, Para);
2027 SkEventQueue(pAC, SKGE_HWAC, SK_HWEV_PORT_START, Para);
2028 }
2029 break;
2030
2031 case SK_HWEV_SET_ROLE:
2032 /* not possible for fiber */
2033 if (!pAC->GIni.GICopperType) {
2034 break;
2035 }
2036 Val8 = (SK_U8)Para.Para32[1];
2037 if (pPrt->PMSMode != Val8) {
2038 /* Set New Role (Master/Slave) mode */
2039 pPrt->PMSMode = Val8;
2040
2041 /* Restart Port */
2042 SkEventQueue(pAC, SKGE_HWAC, SK_HWEV_PORT_STOP, Para);
2043 SkEventQueue(pAC, SKGE_HWAC, SK_HWEV_PORT_START, Para);
2044 }
2045 break;
2046
2047 case SK_HWEV_SET_SPEED:
2048 if (pPrt->PhyType != SK_PHY_MARV_COPPER) {
2049 break;
2050 }
2051 Val8 = (SK_U8)Para.Para32[1];
2052 if (pPrt->PLinkSpeed != Val8) {
2053 /* Set New Speed parameter */
2054 pPrt->PLinkSpeed = Val8;
2055
2056 /* Restart Port */
2057 SkEventQueue(pAC, SKGE_HWAC, SK_HWEV_PORT_STOP, Para);
2058 SkEventQueue(pAC, SKGE_HWAC, SK_HWEV_PORT_START, Para);
2059 }
2060 break;
2061
2062#ifdef GENESIS
2063 case SK_HWEV_HALFDUP_CHK:
2064 if (pAC->GIni.GIGenesis) {
2065 /*
2066 * half duplex hangup workaround.
2067 * See packet arbiter timeout interrupt for description
2068 */
2069 pPrt->HalfDupTimerActive = SK_FALSE;
2070 if (pPrt->PLinkModeStatus == SK_LMODE_STAT_HALF ||
2071 pPrt->PLinkModeStatus == SK_LMODE_STAT_AUTOHALF) {
2072 /* Snap statistic counters */
2073 (void)SkXmUpdateStats(pAC, IoC, Port);
2074
2075 (void)SkXmMacStatistic(pAC, IoC, Port, XM_TXO_OK_HI, &Val32);
2076
2077 Octets = (SK_U64)Val32 << 32;
2078
2079 (void)SkXmMacStatistic(pAC, IoC, Port, XM_TXO_OK_LO, &Val32);
2080
2081 Octets += Val32;
2082
2083 if (pPrt->LastOctets == Octets) {
2084 /* Tx hanging, a FIFO flush restarts it */
2085 SkMacFlushTxFifo(pAC, IoC, Port);
2086 }
2087 }
2088 }
2089 break;
2090#endif /* GENESIS */
2091
2092 default:
2093 SK_ERR_LOG(pAC, SK_ERRCL_SW, SKERR_SIRQ_E001, SKERR_SIRQ_E001MSG);
2094 break;
2095 }
2096
2097 return(0);
2098} /* SkGeSirqEvent */
2099
2100
2101#ifdef GENESIS
2102/******************************************************************************
2103 *
2104 * SkPhyIsrBcom() - PHY interrupt service routine
2105 *
2106 * Description: handles all interrupts from BCom PHY
2107 *
2108 * Returns: N/A
2109 */
2110static void SkPhyIsrBcom(
2111SK_AC *pAC, /* Adapter Context */
2112SK_IOC IoC, /* Io Context */
2113int Port, /* Port Num = PHY Num */
2114SK_U16 IStatus) /* Interrupt Status */
2115{
2116 SK_GEPORT *pPrt; /* GIni Port struct pointer */
2117 SK_EVPARA Para;
2118
2119 pPrt = &pAC->GIni.GP[Port];
2120
2121 if ((IStatus & PHY_B_IS_PSE) != 0) {
2122 /* Incorrectable pair swap error */
2123 SK_ERR_LOG(pAC, SK_ERRCL_HW | SK_ERRCL_INIT, SKERR_SIRQ_E022,
2124 SKERR_SIRQ_E022MSG);
2125 }
2126
2127 if ((IStatus & (PHY_B_IS_AN_PR | PHY_B_IS_LST_CHANGE)) != 0) {
2128
2129 SkHWLinkDown(pAC, IoC, Port);
2130
2131 Para.Para32[0] = (SK_U32)Port;
2132 /* Signal to RLMT */
2133 SkEventQueue(pAC, SKGE_RLMT, SK_RLMT_LINK_DOWN, Para);
2134
2135 /* Start workaround Errata #2 timer */
2136 SkTimerStart(pAC, IoC, &pPrt->PWaTimer, SK_WA_INA_TIME,
2137 SKGE_HWAC, SK_HWEV_WATIM, Para);
2138 }
2139
2140} /* SkPhyIsrBcom */
2141#endif /* GENESIS */
2142
2143
2144#ifdef YUKON
2145/******************************************************************************
2146 *
2147 * SkPhyIsrGmac() - PHY interrupt service routine
2148 *
2149 * Description: handles all interrupts from Marvell PHY
2150 *
2151 * Returns: N/A
2152 */
2153static void SkPhyIsrGmac(
2154SK_AC *pAC, /* Adapter Context */
2155SK_IOC IoC, /* Io Context */
2156int Port, /* Port Num = PHY Num */
2157SK_U16 IStatus) /* Interrupt Status */
2158{
2159 SK_GEPORT *pPrt; /* GIni Port struct pointer */
2160 SK_EVPARA Para;
2161 SK_U16 Word;
2162
2163 pPrt = &pAC->GIni.GP[Port];
2164
2165 if ((IStatus & (PHY_M_IS_AN_PR | PHY_M_IS_LST_CHANGE)) != 0) {
2166
2167 SkHWLinkDown(pAC, IoC, Port);
2168
2169 SkGmPhyRead(pAC, IoC, Port, PHY_MARV_AUNE_ADV, &Word);
2170
2171 SK_DBG_MSG(pAC, SK_DBGMOD_HWM, SK_DBGCAT_CTRL,
2172 ("AutoNeg.Adv: 0x%04X\n", Word));
2173
2174 /* Set Auto-negotiation advertisement */
2175 if (pPrt->PFlowCtrlMode == SK_FLOW_MODE_SYM_OR_REM) {
2176 /* restore Asymmetric Pause bit */
2177 SkGmPhyWrite(pAC, IoC, Port, PHY_MARV_AUNE_ADV,
2178 (SK_U16)(Word | PHY_M_AN_ASP));
2179 }
2180
2181 Para.Para32[0] = (SK_U32)Port;
2182 /* Signal to RLMT */
2183 SkEventQueue(pAC, SKGE_RLMT, SK_RLMT_LINK_DOWN, Para);
2184 }
2185
2186 if ((IStatus & PHY_M_IS_AN_ERROR) != 0) {
2187 /* Auto-Negotiation Error */
2188 SK_ERR_LOG(pAC, SK_ERRCL_HW, SKERR_SIRQ_E023, SKERR_SIRQ_E023MSG);
2189 }
2190
2191 if ((IStatus & PHY_M_IS_FIFO_ERROR) != 0) {
2192 /* FIFO Overflow/Underrun Error */
2193 SK_ERR_LOG(pAC, SK_ERRCL_HW, SKERR_SIRQ_E024, SKERR_SIRQ_E024MSG);
2194 }
2195
2196} /* SkPhyIsrGmac */
2197#endif /* YUKON */
2198
2199
2200#ifdef OTHER_PHY
2201/******************************************************************************
2202 *
2203 * SkPhyIsrLone() - PHY interrupt service routine
2204 *
2205 * Description: handles all interrupts from LONE PHY
2206 *
2207 * Returns: N/A
2208 */
2209static void SkPhyIsrLone(
2210SK_AC *pAC, /* Adapter Context */
2211SK_IOC IoC, /* Io Context */
2212int Port, /* Port Num = PHY Num */
2213SK_U16 IStatus) /* Interrupt Status */
2214{
2215 SK_EVPARA Para;
2216
2217 if (IStatus & (PHY_L_IS_DUP | PHY_L_IS_ISOL)) {
2218
2219 SkHWLinkDown(pAC, IoC, Port);
2220
2221 Para.Para32[0] = (SK_U32)Port;
2222 /* Signal to RLMT */
2223 SkEventQueue(pAC, SKGE_RLMT, SK_RLMT_LINK_DOWN, Para);
2224 }
2225
2226} /* SkPhyIsrLone */
2227#endif /* OTHER_PHY */
2228
2229/* End of File */
diff --git a/drivers/net/sk98lin/ski2c.c b/drivers/net/sk98lin/ski2c.c
new file mode 100644
index 000000000000..79bf57cb5326
--- /dev/null
+++ b/drivers/net/sk98lin/ski2c.c
@@ -0,0 +1,1296 @@
1/******************************************************************************
2 *
3 * Name: ski2c.c
4 * Project: Gigabit Ethernet Adapters, TWSI-Module
5 * Version: $Revision: 1.59 $
6 * Date: $Date: 2003/10/20 09:07:25 $
7 * Purpose: Functions to access Voltage and Temperature Sensor
8 *
9 ******************************************************************************/
10
11/******************************************************************************
12 *
13 * (C)Copyright 1998-2002 SysKonnect.
14 * (C)Copyright 2002-2003 Marvell.
15 *
16 * This program is free software; you can redistribute it and/or modify
17 * it under the terms of the GNU General Public License as published by
18 * the Free Software Foundation; either version 2 of the License, or
19 * (at your option) any later version.
20 *
21 * The information in this file is provided "AS IS" without warranty.
22 *
23 ******************************************************************************/
24
25/*
26 * I2C Protocol
27 */
28#if (defined(DEBUG) || ((!defined(LINT)) && (!defined(SK_SLIM))))
29static const char SysKonnectFileId[] =
30 "@(#) $Id: ski2c.c,v 1.59 2003/10/20 09:07:25 rschmidt Exp $ (C) Marvell. ";
31#endif
32
33#include "h/skdrv1st.h" /* Driver Specific Definitions */
34#include "h/lm80.h"
35#include "h/skdrv2nd.h" /* Adapter Control- and Driver specific Def. */
36
37#ifdef __C2MAN__
38/*
39 I2C protocol implementation.
40
41 General Description:
42
43 The I2C protocol is used for the temperature sensors and for
44 the serial EEPROM which hold the configuration.
45
46 This file covers functions that allow to read write and do
47 some bulk requests a specified I2C address.
48
49 The Genesis has 2 I2C buses. One for the EEPROM which holds
50 the VPD Data and one for temperature and voltage sensor.
51 The following picture shows the I2C buses, I2C devices and
52 their control registers.
53
54 Note: The VPD functions are in skvpd.c
55.
56. PCI Config I2C Bus for VPD Data:
57.
58. +------------+
59. | VPD EEPROM |
60. +------------+
61. |
62. | <-- I2C
63. |
64. +-----------+-----------+
65. | |
66. +-----------------+ +-----------------+
67. | PCI_VPD_ADR_REG | | PCI_VPD_DAT_REG |
68. +-----------------+ +-----------------+
69.
70.
71. I2C Bus for LM80 sensor:
72.
73. +-----------------+
74. | Temperature and |
75. | Voltage Sensor |
76. | LM80 |
77. +-----------------+
78. |
79. |
80. I2C --> |
81. |
82. +----+
83. +-------------->| OR |<--+
84. | +----+ |
85. +------+------+ |
86. | | |
87. +--------+ +--------+ +----------+
88. | B2_I2C | | B2_I2C | | B2_I2C |
89. | _CTRL | | _DATA | | _SW |
90. +--------+ +--------+ +----------+
91.
92 The I2C bus may be driven by the B2_I2C_SW or by the B2_I2C_CTRL
93 and B2_I2C_DATA registers.
94 For driver software it is recommended to use the I2C control and
95 data register, because I2C bus timing is done by the ASIC and
96 an interrupt may be received when the I2C request is completed.
97
98 Clock Rate Timing: MIN MAX generated by
99 VPD EEPROM: 50 kHz 100 kHz HW
100 LM80 over I2C Ctrl/Data reg. 50 kHz 100 kHz HW
101 LM80 over B2_I2C_SW register 0 400 kHz SW
102
103 Note: The clock generated by the hardware is dependend on the
104 PCI clock. If the PCI bus clock is 33 MHz, the I2C/VPD
105 clock is 50 kHz.
106 */
107intro()
108{}
109#endif
110
111#ifdef SK_DIAG
112/*
113 * I2C Fast Mode timing values used by the LM80.
114 * If new devices are added to the I2C bus the timing values have to be checked.
115 */
116#ifndef I2C_SLOW_TIMING
117#define T_CLK_LOW 1300L /* clock low time in ns */
118#define T_CLK_HIGH 600L /* clock high time in ns */
119#define T_DATA_IN_SETUP 100L /* data in Set-up Time */
120#define T_START_HOLD 600L /* start condition hold time */
121#define T_START_SETUP 600L /* start condition Set-up time */
122#define T_STOP_SETUP 600L /* stop condition Set-up time */
123#define T_BUS_IDLE 1300L /* time the bus must free after Tx */
124#define T_CLK_2_DATA_OUT 900L /* max. clock low to data output valid */
125#else /* I2C_SLOW_TIMING */
126/* I2C Standard Mode Timing */
127#define T_CLK_LOW 4700L /* clock low time in ns */
128#define T_CLK_HIGH 4000L /* clock high time in ns */
129#define T_DATA_IN_SETUP 250L /* data in Set-up Time */
130#define T_START_HOLD 4000L /* start condition hold time */
131#define T_START_SETUP 4700L /* start condition Set-up time */
132#define T_STOP_SETUP 4000L /* stop condition Set-up time */
133#define T_BUS_IDLE 4700L /* time the bus must free after Tx */
134#endif /* !I2C_SLOW_TIMING */
135
136#define NS2BCLK(x) (((x)*125)/10000)
137
138/*
139 * I2C Wire Operations
140 *
141 * About I2C_CLK_LOW():
142 *
143 * The Data Direction bit (I2C_DATA_DIR) has to be set to input when setting
144 * clock to low, to prevent the ASIC and the I2C data client from driving the
145 * serial data line simultaneously (ASIC: last bit of a byte = '1', I2C client
146 * send an 'ACK'). See also Concentrator Bugreport No. 10192.
147 */
148#define I2C_DATA_HIGH(IoC) SK_I2C_SET_BIT(IoC, I2C_DATA)
149#define I2C_DATA_LOW(IoC) SK_I2C_CLR_BIT(IoC, I2C_DATA)
150#define I2C_DATA_OUT(IoC) SK_I2C_SET_BIT(IoC, I2C_DATA_DIR)
151#define I2C_DATA_IN(IoC) SK_I2C_CLR_BIT(IoC, I2C_DATA_DIR | I2C_DATA)
152#define I2C_CLK_HIGH(IoC) SK_I2C_SET_BIT(IoC, I2C_CLK)
153#define I2C_CLK_LOW(IoC) SK_I2C_CLR_BIT(IoC, I2C_CLK | I2C_DATA_DIR)
154#define I2C_START_COND(IoC) SK_I2C_CLR_BIT(IoC, I2C_CLK)
155
156#define NS2CLKT(x) ((x*125L)/10000)
157
158/*--------------- I2C Interface Register Functions --------------- */
159
160/*
161 * sending one bit
162 */
163void SkI2cSndBit(
164SK_IOC IoC, /* I/O Context */
165SK_U8 Bit) /* Bit to send */
166{
167 I2C_DATA_OUT(IoC);
168 if (Bit) {
169 I2C_DATA_HIGH(IoC);
170 }
171 else {
172 I2C_DATA_LOW(IoC);
173 }
174 SkDgWaitTime(IoC, NS2BCLK(T_DATA_IN_SETUP));
175 I2C_CLK_HIGH(IoC);
176 SkDgWaitTime(IoC, NS2BCLK(T_CLK_HIGH));
177 I2C_CLK_LOW(IoC);
178} /* SkI2cSndBit*/
179
180
181/*
182 * Signal a start to the I2C Bus.
183 *
184 * A start is signaled when data goes to low in a high clock cycle.
185 *
186 * Ends with Clock Low.
187 *
188 * Status: not tested
189 */
190void SkI2cStart(
191SK_IOC IoC) /* I/O Context */
192{
193 /* Init data and Clock to output lines */
194 /* Set Data high */
195 I2C_DATA_OUT(IoC);
196 I2C_DATA_HIGH(IoC);
197 /* Set Clock high */
198 I2C_CLK_HIGH(IoC);
199
200 SkDgWaitTime(IoC, NS2BCLK(T_START_SETUP));
201
202 /* Set Data Low */
203 I2C_DATA_LOW(IoC);
204
205 SkDgWaitTime(IoC, NS2BCLK(T_START_HOLD));
206
207 /* Clock low without Data to Input */
208 I2C_START_COND(IoC);
209
210 SkDgWaitTime(IoC, NS2BCLK(T_CLK_LOW));
211} /* SkI2cStart */
212
213
214void SkI2cStop(
215SK_IOC IoC) /* I/O Context */
216{
217 /* Init data and Clock to output lines */
218 /* Set Data low */
219 I2C_DATA_OUT(IoC);
220 I2C_DATA_LOW(IoC);
221
222 SkDgWaitTime(IoC, NS2BCLK(T_CLK_2_DATA_OUT));
223
224 /* Set Clock high */
225 I2C_CLK_HIGH(IoC);
226
227 SkDgWaitTime(IoC, NS2BCLK(T_STOP_SETUP));
228
229 /*
230 * Set Data High: Do it by setting the Data Line to Input.
231 * Because of a pull up resistor the Data Line
232 * floods to high.
233 */
234 I2C_DATA_IN(IoC);
235
236 /*
237 * When I2C activity is stopped
238 * o DATA should be set to input and
239 * o CLOCK should be set to high!
240 */
241 SkDgWaitTime(IoC, NS2BCLK(T_BUS_IDLE));
242} /* SkI2cStop */
243
244
245/*
246 * Receive just one bit via the I2C bus.
247 *
248 * Note: Clock must be set to LOW before calling this function.
249 *
250 * Returns The received bit.
251 */
252int SkI2cRcvBit(
253SK_IOC IoC) /* I/O Context */
254{
255 int Bit;
256 SK_U8 I2cSwCtrl;
257
258 /* Init data as input line */
259 I2C_DATA_IN(IoC);
260
261 SkDgWaitTime(IoC, NS2BCLK(T_CLK_2_DATA_OUT));
262
263 I2C_CLK_HIGH(IoC);
264
265 SkDgWaitTime(IoC, NS2BCLK(T_CLK_HIGH));
266
267 SK_I2C_GET_SW(IoC, &I2cSwCtrl);
268
269 Bit = (I2cSwCtrl & I2C_DATA) ? 1 : 0;
270
271 I2C_CLK_LOW(IoC);
272 SkDgWaitTime(IoC, NS2BCLK(T_CLK_LOW-T_CLK_2_DATA_OUT));
273
274 return(Bit);
275} /* SkI2cRcvBit */
276
277
278/*
279 * Receive an ACK.
280 *
281 * returns 0 If acknowledged
282 * 1 in case of an error
283 */
284int SkI2cRcvAck(
285SK_IOC IoC) /* I/O Context */
286{
287 /*
288 * Received bit must be zero.
289 */
290 return(SkI2cRcvBit(IoC) != 0);
291} /* SkI2cRcvAck */
292
293
294/*
295 * Send an NACK.
296 */
297void SkI2cSndNAck(
298SK_IOC IoC) /* I/O Context */
299{
300 /*
301 * Received bit must be zero.
302 */
303 SkI2cSndBit(IoC, 1);
304} /* SkI2cSndNAck */
305
306
307/*
308 * Send an ACK.
309 */
310void SkI2cSndAck(
311SK_IOC IoC) /* I/O Context */
312{
313 /*
314 * Received bit must be zero.
315 */
316 SkI2cSndBit(IoC, 0);
317} /* SkI2cSndAck */
318
319
320/*
321 * Send one byte to the I2C device and wait for ACK.
322 *
323 * Return acknowleged status.
324 */
325int SkI2cSndByte(
326SK_IOC IoC, /* I/O Context */
327int Byte) /* byte to send */
328{
329 int i;
330
331 for (i = 0; i < 8; i++) {
332 if (Byte & (1<<(7-i))) {
333 SkI2cSndBit(IoC, 1);
334 }
335 else {
336 SkI2cSndBit(IoC, 0);
337 }
338 }
339
340 return(SkI2cRcvAck(IoC));
341} /* SkI2cSndByte */
342
343
344/*
345 * Receive one byte and ack it.
346 *
347 * Return byte.
348 */
349int SkI2cRcvByte(
350SK_IOC IoC, /* I/O Context */
351int Last) /* Last Byte Flag */
352{
353 int i;
354 int Byte = 0;
355
356 for (i = 0; i < 8; i++) {
357 Byte <<= 1;
358 Byte |= SkI2cRcvBit(IoC);
359 }
360
361 if (Last) {
362 SkI2cSndNAck(IoC);
363 }
364 else {
365 SkI2cSndAck(IoC);
366 }
367
368 return(Byte);
369} /* SkI2cRcvByte */
370
371
372/*
373 * Start dialog and send device address
374 *
375 * Return 0 if acknowleged, 1 in case of an error
376 */
377int SkI2cSndDev(
378SK_IOC IoC, /* I/O Context */
379int Addr, /* Device Address */
380int Rw) /* Read / Write Flag */
381{
382 SkI2cStart(IoC);
383 Rw = ~Rw;
384 Rw &= I2C_WRITE;
385 return(SkI2cSndByte(IoC, (Addr<<1) | Rw));
386} /* SkI2cSndDev */
387
388#endif /* SK_DIAG */
389
390/*----------------- I2C CTRL Register Functions ----------*/
391
392/*
393 * waits for a completion of an I2C transfer
394 *
395 * returns 0: success, transfer completes
396 * 1: error, transfer does not complete, I2C transfer
397 * killed, wait loop terminated.
398 */
399static int SkI2cWait(
400SK_AC *pAC, /* Adapter Context */
401SK_IOC IoC, /* I/O Context */
402int Event) /* complete event to wait for (I2C_READ or I2C_WRITE) */
403{
404 SK_U64 StartTime;
405 SK_U64 CurrentTime;
406 SK_U32 I2cCtrl;
407
408 StartTime = SkOsGetTime(pAC);
409
410 do {
411 CurrentTime = SkOsGetTime(pAC);
412
413 if (CurrentTime - StartTime > SK_TICKS_PER_SEC / 8) {
414
415 SK_I2C_STOP(IoC);
416#ifndef SK_DIAG
417 SK_ERR_LOG(pAC, SK_ERRCL_SW, SKERR_I2C_E002, SKERR_I2C_E002MSG);
418#endif /* !SK_DIAG */
419 return(1);
420 }
421
422 SK_I2C_GET_CTL(IoC, &I2cCtrl);
423
424#ifdef xYUKON_DBG
425 printf("StartTime=%lu, CurrentTime=%lu\n",
426 StartTime, CurrentTime);
427 if (kbhit()) {
428 return(1);
429 }
430#endif /* YUKON_DBG */
431
432 } while ((I2cCtrl & I2C_FLAG) == (SK_U32)Event << 31);
433
434 return(0);
435} /* SkI2cWait */
436
437
438/*
439 * waits for a completion of an I2C transfer
440 *
441 * Returns
442 * Nothing
443 */
444void SkI2cWaitIrq(
445SK_AC *pAC, /* Adapter Context */
446SK_IOC IoC) /* I/O Context */
447{
448 SK_SENSOR *pSen;
449 SK_U64 StartTime;
450 SK_U32 IrqSrc;
451
452 pSen = &pAC->I2c.SenTable[pAC->I2c.CurrSens];
453
454 if (pSen->SenState == SK_SEN_IDLE) {
455 return;
456 }
457
458 StartTime = SkOsGetTime(pAC);
459
460 do {
461 if (SkOsGetTime(pAC) - StartTime > SK_TICKS_PER_SEC / 8) {
462
463 SK_I2C_STOP(IoC);
464#ifndef SK_DIAG
465 SK_ERR_LOG(pAC, SK_ERRCL_SW, SKERR_I2C_E016, SKERR_I2C_E016MSG);
466#endif /* !SK_DIAG */
467 return;
468 }
469
470 SK_IN32(IoC, B0_ISRC, &IrqSrc);
471
472 } while ((IrqSrc & IS_I2C_READY) == 0);
473
474 pSen->SenState = SK_SEN_IDLE;
475 return;
476} /* SkI2cWaitIrq */
477
478/*
479 * writes a single byte or 4 bytes into the I2C device
480 *
481 * returns 0: success
482 * 1: error
483 */
484static int SkI2cWrite(
485SK_AC *pAC, /* Adapter Context */
486SK_IOC IoC, /* I/O Context */
487SK_U32 I2cData, /* I2C Data to write */
488int I2cDev, /* I2C Device Address */
489int I2cDevSize, /* I2C Device Size (e.g. I2C_025K_DEV or I2C_2K_DEV) */
490int I2cReg, /* I2C Device Register Address */
491int I2cBurst) /* I2C Burst Flag */
492{
493 SK_OUT32(IoC, B2_I2C_DATA, I2cData);
494
495 SK_I2C_CTL(IoC, I2C_WRITE, I2cDev, I2cDevSize, I2cReg, I2cBurst);
496
497 return(SkI2cWait(pAC, IoC, I2C_WRITE));
498} /* SkI2cWrite*/
499
500
501#ifdef SK_DIAG
502/*
503 * reads a single byte or 4 bytes from the I2C device
504 *
505 * returns the word read
506 */
507SK_U32 SkI2cRead(
508SK_AC *pAC, /* Adapter Context */
509SK_IOC IoC, /* I/O Context */
510int I2cDev, /* I2C Device Address */
511int I2cDevSize, /* I2C Device Size (e.g. I2C_025K_DEV or I2C_2K_DEV) */
512int I2cReg, /* I2C Device Register Address */
513int I2cBurst) /* I2C Burst Flag */
514{
515 SK_U32 Data;
516
517 SK_OUT32(IoC, B2_I2C_DATA, 0);
518 SK_I2C_CTL(IoC, I2C_READ, I2cDev, I2cDevSize, I2cReg, I2cBurst);
519
520 if (SkI2cWait(pAC, IoC, I2C_READ) != 0) {
521 w_print("%s\n", SKERR_I2C_E002MSG);
522 }
523
524 SK_IN32(IoC, B2_I2C_DATA, &Data);
525
526 return(Data);
527} /* SkI2cRead */
528#endif /* SK_DIAG */
529
530
531/*
532 * read a sensor's value
533 *
534 * This function reads a sensor's value from the I2C sensor chip. The sensor
535 * is defined by its index into the sensors database in the struct pAC points
536 * to.
537 * Returns
538 * 1 if the read is completed
539 * 0 if the read must be continued (I2C Bus still allocated)
540 */
541static int SkI2cReadSensor(
542SK_AC *pAC, /* Adapter Context */
543SK_IOC IoC, /* I/O Context */
544SK_SENSOR *pSen) /* Sensor to be read */
545{
546 if (pSen->SenRead != NULL) {
547 return((*pSen->SenRead)(pAC, IoC, pSen));
548 }
549 else {
550 return(0); /* no success */
551 }
552} /* SkI2cReadSensor */
553
554/*
555 * Do the Init state 0 initialization
556 */
557static int SkI2cInit0(
558SK_AC *pAC) /* Adapter Context */
559{
560 int i;
561
562 /* Begin with first sensor */
563 pAC->I2c.CurrSens = 0;
564
565 /* Begin with timeout control for state machine */
566 pAC->I2c.TimerMode = SK_TIMER_WATCH_SM;
567
568 /* Set sensor number to zero */
569 pAC->I2c.MaxSens = 0;
570
571#ifndef SK_DIAG
572 /* Initialize Number of Dummy Reads */
573 pAC->I2c.DummyReads = SK_MAX_SENSORS;
574#endif
575
576 for (i = 0; i < SK_MAX_SENSORS; i++) {
577 pAC->I2c.SenTable[i].SenDesc = "unknown";
578 pAC->I2c.SenTable[i].SenType = SK_SEN_UNKNOWN;
579 pAC->I2c.SenTable[i].SenThreErrHigh = 0;
580 pAC->I2c.SenTable[i].SenThreErrLow = 0;
581 pAC->I2c.SenTable[i].SenThreWarnHigh = 0;
582 pAC->I2c.SenTable[i].SenThreWarnLow = 0;
583 pAC->I2c.SenTable[i].SenReg = LM80_FAN2_IN;
584 pAC->I2c.SenTable[i].SenInit = SK_SEN_DYN_INIT_NONE;
585 pAC->I2c.SenTable[i].SenValue = 0;
586 pAC->I2c.SenTable[i].SenErrFlag = SK_SEN_ERR_NOT_PRESENT;
587 pAC->I2c.SenTable[i].SenErrCts = 0;
588 pAC->I2c.SenTable[i].SenBegErrTS = 0;
589 pAC->I2c.SenTable[i].SenState = SK_SEN_IDLE;
590 pAC->I2c.SenTable[i].SenRead = NULL;
591 pAC->I2c.SenTable[i].SenDev = 0;
592 }
593
594 /* Now we are "INIT data"ed */
595 pAC->I2c.InitLevel = SK_INIT_DATA;
596 return(0);
597} /* SkI2cInit0*/
598
599
600/*
601 * Do the init state 1 initialization
602 *
603 * initialize the following register of the LM80:
604 * Configuration register:
605 * - START, noINT, activeLOW, noINT#Clear, noRESET, noCI, noGPO#, noINIT
606 *
607 * Interrupt Mask Register 1:
608 * - all interrupts are Disabled (0xff)
609 *
610 * Interrupt Mask Register 2:
611 * - all interrupts are Disabled (0xff) Interrupt modi doesn't matter.
612 *
613 * Fan Divisor/RST_OUT register:
614 * - Divisors set to 1 (bits 00), all others 0s.
615 *
616 * OS# Configuration/Temperature resolution Register:
617 * - all 0s
618 *
619 */
620static int SkI2cInit1(
621SK_AC *pAC, /* Adapter Context */
622SK_IOC IoC) /* I/O Context */
623{
624 int i;
625 SK_U8 I2cSwCtrl;
626 SK_GEPORT *pPrt; /* GIni Port struct pointer */
627
628 if (pAC->I2c.InitLevel != SK_INIT_DATA) {
629 /* ReInit not needed in I2C module */
630 return(0);
631 }
632
633 /* Set the Direction of I2C-Data Pin to IN */
634 SK_I2C_CLR_BIT(IoC, I2C_DATA_DIR | I2C_DATA);
635 /* Check for 32-Bit Yukon with Low at I2C-Data Pin */
636 SK_I2C_GET_SW(IoC, &I2cSwCtrl);
637
638 if ((I2cSwCtrl & I2C_DATA) == 0) {
639 /* this is a 32-Bit board */
640 pAC->GIni.GIYukon32Bit = SK_TRUE;
641 return(0);
642 }
643
644 /* Check for 64 Bit Yukon without sensors */
645 if (SkI2cWrite(pAC, IoC, 0, LM80_ADDR, I2C_025K_DEV, LM80_CFG, 0) != 0) {
646 return(0);
647 }
648
649 (void)SkI2cWrite(pAC, IoC, 0xffUL, LM80_ADDR, I2C_025K_DEV, LM80_IMSK_1, 0);
650
651 (void)SkI2cWrite(pAC, IoC, 0xffUL, LM80_ADDR, I2C_025K_DEV, LM80_IMSK_2, 0);
652
653 (void)SkI2cWrite(pAC, IoC, 0, LM80_ADDR, I2C_025K_DEV, LM80_FAN_CTRL, 0);
654
655 (void)SkI2cWrite(pAC, IoC, 0, LM80_ADDR, I2C_025K_DEV, LM80_TEMP_CTRL, 0);
656
657 (void)SkI2cWrite(pAC, IoC, (SK_U32)LM80_CFG_START, LM80_ADDR, I2C_025K_DEV,
658 LM80_CFG, 0);
659
660 /*
661 * MaxSens has to be updated here, because PhyType is not
662 * set when performing Init Level 0
663 */
664 pAC->I2c.MaxSens = 5;
665
666 pPrt = &pAC->GIni.GP[0];
667
668 if (pAC->GIni.GIGenesis) {
669 if (pPrt->PhyType == SK_PHY_BCOM) {
670 if (pAC->GIni.GIMacsFound == 1) {
671 pAC->I2c.MaxSens += 1;
672 }
673 else {
674 pAC->I2c.MaxSens += 3;
675 }
676 }
677 }
678 else {
679 pAC->I2c.MaxSens += 3;
680 }
681
682 for (i = 0; i < pAC->I2c.MaxSens; i++) {
683 switch (i) {
684 case 0:
685 pAC->I2c.SenTable[i].SenDesc = "Temperature";
686 pAC->I2c.SenTable[i].SenType = SK_SEN_TEMP;
687 pAC->I2c.SenTable[i].SenThreErrHigh = SK_SEN_TEMP_HIGH_ERR;
688 pAC->I2c.SenTable[i].SenThreWarnHigh = SK_SEN_TEMP_HIGH_WARN;
689 pAC->I2c.SenTable[i].SenThreWarnLow = SK_SEN_TEMP_LOW_WARN;
690 pAC->I2c.SenTable[i].SenThreErrLow = SK_SEN_TEMP_LOW_ERR;
691 pAC->I2c.SenTable[i].SenReg = LM80_TEMP_IN;
692 break;
693 case 1:
694 pAC->I2c.SenTable[i].SenDesc = "Voltage PCI";
695 pAC->I2c.SenTable[i].SenType = SK_SEN_VOLT;
696 pAC->I2c.SenTable[i].SenThreErrHigh = SK_SEN_PCI_5V_HIGH_ERR;
697 pAC->I2c.SenTable[i].SenThreWarnHigh = SK_SEN_PCI_5V_HIGH_WARN;
698 pAC->I2c.SenTable[i].SenThreWarnLow = SK_SEN_PCI_5V_LOW_WARN;
699 pAC->I2c.SenTable[i].SenThreErrLow = SK_SEN_PCI_5V_LOW_ERR;
700 pAC->I2c.SenTable[i].SenReg = LM80_VT0_IN;
701 break;
702 case 2:
703 pAC->I2c.SenTable[i].SenDesc = "Voltage PCI-IO";
704 pAC->I2c.SenTable[i].SenType = SK_SEN_VOLT;
705 pAC->I2c.SenTable[i].SenThreErrHigh = SK_SEN_PCI_IO_5V_HIGH_ERR;
706 pAC->I2c.SenTable[i].SenThreWarnHigh = SK_SEN_PCI_IO_5V_HIGH_WARN;
707 pAC->I2c.SenTable[i].SenThreWarnLow = SK_SEN_PCI_IO_3V3_LOW_WARN;
708 pAC->I2c.SenTable[i].SenThreErrLow = SK_SEN_PCI_IO_3V3_LOW_ERR;
709 pAC->I2c.SenTable[i].SenReg = LM80_VT1_IN;
710 pAC->I2c.SenTable[i].SenInit = SK_SEN_DYN_INIT_PCI_IO;
711 break;
712 case 3:
713 pAC->I2c.SenTable[i].SenDesc = "Voltage ASIC";
714 pAC->I2c.SenTable[i].SenType = SK_SEN_VOLT;
715 pAC->I2c.SenTable[i].SenThreErrHigh = SK_SEN_VDD_HIGH_ERR;
716 pAC->I2c.SenTable[i].SenThreWarnHigh = SK_SEN_VDD_HIGH_WARN;
717 pAC->I2c.SenTable[i].SenThreWarnLow = SK_SEN_VDD_LOW_WARN;
718 pAC->I2c.SenTable[i].SenThreErrLow = SK_SEN_VDD_LOW_ERR;
719 pAC->I2c.SenTable[i].SenReg = LM80_VT2_IN;
720 break;
721 case 4:
722 if (pAC->GIni.GIGenesis) {
723 if (pPrt->PhyType == SK_PHY_BCOM) {
724 pAC->I2c.SenTable[i].SenDesc = "Voltage PHY A PLL";
725 pAC->I2c.SenTable[i].SenThreErrHigh = SK_SEN_PLL_3V3_HIGH_ERR;
726 pAC->I2c.SenTable[i].SenThreWarnHigh = SK_SEN_PLL_3V3_HIGH_WARN;
727 pAC->I2c.SenTable[i].SenThreWarnLow = SK_SEN_PLL_3V3_LOW_WARN;
728 pAC->I2c.SenTable[i].SenThreErrLow = SK_SEN_PLL_3V3_LOW_ERR;
729 }
730 else {
731 pAC->I2c.SenTable[i].SenDesc = "Voltage PMA";
732 pAC->I2c.SenTable[i].SenThreErrHigh = SK_SEN_PLL_3V3_HIGH_ERR;
733 pAC->I2c.SenTable[i].SenThreWarnHigh = SK_SEN_PLL_3V3_HIGH_WARN;
734 pAC->I2c.SenTable[i].SenThreWarnLow = SK_SEN_PLL_3V3_LOW_WARN;
735 pAC->I2c.SenTable[i].SenThreErrLow = SK_SEN_PLL_3V3_LOW_ERR;
736 }
737 }
738 else {
739 pAC->I2c.SenTable[i].SenDesc = "Voltage VAUX";
740 pAC->I2c.SenTable[i].SenThreErrHigh = SK_SEN_VAUX_3V3_HIGH_ERR;
741 pAC->I2c.SenTable[i].SenThreWarnHigh = SK_SEN_VAUX_3V3_HIGH_WARN;
742 if (pAC->GIni.GIVauxAvail) {
743 pAC->I2c.SenTable[i].SenThreWarnLow = SK_SEN_VAUX_3V3_LOW_WARN;
744 pAC->I2c.SenTable[i].SenThreErrLow = SK_SEN_VAUX_3V3_LOW_ERR;
745 }
746 else {
747 pAC->I2c.SenTable[i].SenThreErrLow = SK_SEN_VAUX_0V_WARN_ERR;
748 pAC->I2c.SenTable[i].SenThreWarnLow = SK_SEN_VAUX_0V_WARN_ERR;
749 }
750 }
751 pAC->I2c.SenTable[i].SenType = SK_SEN_VOLT;
752 pAC->I2c.SenTable[i].SenReg = LM80_VT3_IN;
753 break;
754 case 5:
755 if (pAC->GIni.GIGenesis) {
756 pAC->I2c.SenTable[i].SenDesc = "Voltage PHY 2V5";
757 pAC->I2c.SenTable[i].SenThreErrHigh = SK_SEN_PHY_2V5_HIGH_ERR;
758 pAC->I2c.SenTable[i].SenThreWarnHigh = SK_SEN_PHY_2V5_HIGH_WARN;
759 pAC->I2c.SenTable[i].SenThreWarnLow = SK_SEN_PHY_2V5_LOW_WARN;
760 pAC->I2c.SenTable[i].SenThreErrLow = SK_SEN_PHY_2V5_LOW_ERR;
761 }
762 else {
763 pAC->I2c.SenTable[i].SenDesc = "Voltage Core 1V5";
764 pAC->I2c.SenTable[i].SenThreErrHigh = SK_SEN_CORE_1V5_HIGH_ERR;
765 pAC->I2c.SenTable[i].SenThreWarnHigh = SK_SEN_CORE_1V5_HIGH_WARN;
766 pAC->I2c.SenTable[i].SenThreWarnLow = SK_SEN_CORE_1V5_LOW_WARN;
767 pAC->I2c.SenTable[i].SenThreErrLow = SK_SEN_CORE_1V5_LOW_ERR;
768 }
769 pAC->I2c.SenTable[i].SenType = SK_SEN_VOLT;
770 pAC->I2c.SenTable[i].SenReg = LM80_VT4_IN;
771 break;
772 case 6:
773 if (pAC->GIni.GIGenesis) {
774 pAC->I2c.SenTable[i].SenDesc = "Voltage PHY B PLL";
775 }
776 else {
777 pAC->I2c.SenTable[i].SenDesc = "Voltage PHY 3V3";
778 }
779 pAC->I2c.SenTable[i].SenType = SK_SEN_VOLT;
780 pAC->I2c.SenTable[i].SenThreErrHigh = SK_SEN_PLL_3V3_HIGH_ERR;
781 pAC->I2c.SenTable[i].SenThreWarnHigh = SK_SEN_PLL_3V3_HIGH_WARN;
782 pAC->I2c.SenTable[i].SenThreWarnLow = SK_SEN_PLL_3V3_LOW_WARN;
783 pAC->I2c.SenTable[i].SenThreErrLow = SK_SEN_PLL_3V3_LOW_ERR;
784 pAC->I2c.SenTable[i].SenReg = LM80_VT5_IN;
785 break;
786 case 7:
787 if (pAC->GIni.GIGenesis) {
788 pAC->I2c.SenTable[i].SenDesc = "Speed Fan";
789 pAC->I2c.SenTable[i].SenType = SK_SEN_FAN;
790 pAC->I2c.SenTable[i].SenThreErrHigh = SK_SEN_FAN_HIGH_ERR;
791 pAC->I2c.SenTable[i].SenThreWarnHigh = SK_SEN_FAN_HIGH_WARN;
792 pAC->I2c.SenTable[i].SenThreWarnLow = SK_SEN_FAN_LOW_WARN;
793 pAC->I2c.SenTable[i].SenThreErrLow = SK_SEN_FAN_LOW_ERR;
794 pAC->I2c.SenTable[i].SenReg = LM80_FAN2_IN;
795 }
796 else {
797 pAC->I2c.SenTable[i].SenDesc = "Voltage PHY 2V5";
798 pAC->I2c.SenTable[i].SenType = SK_SEN_VOLT;
799 pAC->I2c.SenTable[i].SenThreErrHigh = SK_SEN_PHY_2V5_HIGH_ERR;
800 pAC->I2c.SenTable[i].SenThreWarnHigh = SK_SEN_PHY_2V5_HIGH_WARN;
801 pAC->I2c.SenTable[i].SenThreWarnLow = SK_SEN_PHY_2V5_LOW_WARN;
802 pAC->I2c.SenTable[i].SenThreErrLow = SK_SEN_PHY_2V5_LOW_ERR;
803 pAC->I2c.SenTable[i].SenReg = LM80_VT6_IN;
804 }
805 break;
806 default:
807 SK_ERR_LOG(pAC, SK_ERRCL_INIT | SK_ERRCL_SW,
808 SKERR_I2C_E001, SKERR_I2C_E001MSG);
809 break;
810 }
811
812 pAC->I2c.SenTable[i].SenValue = 0;
813 pAC->I2c.SenTable[i].SenErrFlag = SK_SEN_ERR_OK;
814 pAC->I2c.SenTable[i].SenErrCts = 0;
815 pAC->I2c.SenTable[i].SenBegErrTS = 0;
816 pAC->I2c.SenTable[i].SenState = SK_SEN_IDLE;
817 pAC->I2c.SenTable[i].SenRead = SkLm80ReadSensor;
818 pAC->I2c.SenTable[i].SenDev = LM80_ADDR;
819 }
820
821#ifndef SK_DIAG
822 pAC->I2c.DummyReads = pAC->I2c.MaxSens;
823#endif /* !SK_DIAG */
824
825 /* Clear I2C IRQ */
826 SK_OUT32(IoC, B2_I2C_IRQ, I2C_CLR_IRQ);
827
828 /* Now we are I/O initialized */
829 pAC->I2c.InitLevel = SK_INIT_IO;
830 return(0);
831} /* SkI2cInit1 */
832
833
834/*
835 * Init level 2: Start first sensor read.
836 */
837static int SkI2cInit2(
838SK_AC *pAC, /* Adapter Context */
839SK_IOC IoC) /* I/O Context */
840{
841 int ReadComplete;
842 SK_SENSOR *pSen;
843
844 if (pAC->I2c.InitLevel != SK_INIT_IO) {
845 /* ReInit not needed in I2C module */
846 /* Init0 and Init2 not permitted */
847 return(0);
848 }
849
850 pSen = &pAC->I2c.SenTable[pAC->I2c.CurrSens];
851 ReadComplete = SkI2cReadSensor(pAC, IoC, pSen);
852
853 if (ReadComplete) {
854 SK_ERR_LOG(pAC, SK_ERRCL_INIT, SKERR_I2C_E008, SKERR_I2C_E008MSG);
855 }
856
857 /* Now we are correctly initialized */
858 pAC->I2c.InitLevel = SK_INIT_RUN;
859
860 return(0);
861} /* SkI2cInit2*/
862
863
864/*
865 * Initialize I2C devices
866 *
867 * Get the first voltage value and discard it.
868 * Go into temperature read mode. A default pointer is not set.
869 *
870 * The things to be done depend on the init level in the parameter list:
871 * Level 0:
872 * Initialize only the data structures. Do NOT access hardware.
873 * Level 1:
874 * Initialize hardware through SK_IN / SK_OUT commands. Do NOT use interrupts.
875 * Level 2:
876 * Everything is possible. Interrupts may be used from now on.
877 *
878 * return:
879 * 0 = success
880 * other = error.
881 */
882int SkI2cInit(
883SK_AC *pAC, /* Adapter Context */
884SK_IOC IoC, /* I/O Context needed in levels 1 and 2 */
885int Level) /* Init Level */
886{
887
888 switch (Level) {
889 case SK_INIT_DATA:
890 return(SkI2cInit0(pAC));
891 case SK_INIT_IO:
892 return(SkI2cInit1(pAC, IoC));
893 case SK_INIT_RUN:
894 return(SkI2cInit2(pAC, IoC));
895 default:
896 break;
897 }
898
899 return(0);
900} /* SkI2cInit */
901
902
903#ifndef SK_DIAG
904
905/*
906 * Interrupt service function for the I2C Interface
907 *
908 * Clears the Interrupt source
909 *
910 * Reads the register and check it for sending a trap.
911 *
912 * Starts the timer if necessary.
913 */
914void SkI2cIsr(
915SK_AC *pAC, /* Adapter Context */
916SK_IOC IoC) /* I/O Context */
917{
918 SK_EVPARA Para;
919
920 /* Clear I2C IRQ */
921 SK_OUT32(IoC, B2_I2C_IRQ, I2C_CLR_IRQ);
922
923 Para.Para64 = 0;
924 SkEventQueue(pAC, SKGE_I2C, SK_I2CEV_IRQ, Para);
925} /* SkI2cIsr */
926
927
928/*
929 * Check this sensors Value against the threshold and send events.
930 */
931static void SkI2cCheckSensor(
932SK_AC *pAC, /* Adapter Context */
933SK_SENSOR *pSen)
934{
935 SK_EVPARA ParaLocal;
936 SK_BOOL TooHigh; /* Is sensor too high? */
937 SK_BOOL TooLow; /* Is sensor too low? */
938 SK_U64 CurrTime; /* Current Time */
939 SK_BOOL DoTrapSend; /* We need to send a trap */
940 SK_BOOL DoErrLog; /* We need to log the error */
941 SK_BOOL IsError; /* We need to log the error */
942
943 /* Check Dummy Reads first */
944 if (pAC->I2c.DummyReads > 0) {
945 pAC->I2c.DummyReads--;
946 return;
947 }
948
949 /* Get the current time */
950 CurrTime = SkOsGetTime(pAC);
951
952 /* Set para to the most useful setting: The current sensor. */
953 ParaLocal.Para64 = (SK_U64)pAC->I2c.CurrSens;
954
955 /* Check the Value against the thresholds. First: Error Thresholds */
956 TooHigh = (pSen->SenValue > pSen->SenThreErrHigh);
957 TooLow = (pSen->SenValue < pSen->SenThreErrLow);
958
959 IsError = SK_FALSE;
960 if (TooHigh || TooLow) {
961 /* Error condition is satisfied */
962 DoTrapSend = SK_TRUE;
963 DoErrLog = SK_TRUE;
964
965 /* Now error condition is satisfied */
966 IsError = SK_TRUE;
967
968 if (pSen->SenErrFlag == SK_SEN_ERR_ERR) {
969 /* This state is the former one */
970
971 /* So check first whether we have to send a trap */
972 if (pSen->SenLastErrTrapTS + SK_SEN_ERR_TR_HOLD >
973 CurrTime) {
974 /*
975 * Do NOT send the Trap. The hold back time
976 * has to run out first.
977 */
978 DoTrapSend = SK_FALSE;
979 }
980
981 /* Check now whether we have to log an Error */
982 if (pSen->SenLastErrLogTS + SK_SEN_ERR_LOG_HOLD >
983 CurrTime) {
984 /*
985 * Do NOT log the error. The hold back time
986 * has to run out first.
987 */
988 DoErrLog = SK_FALSE;
989 }
990 }
991 else {
992 /* We came from a different state -> Set Begin Time Stamp */
993 pSen->SenBegErrTS = CurrTime;
994 pSen->SenErrFlag = SK_SEN_ERR_ERR;
995 }
996
997 if (DoTrapSend) {
998 /* Set current Time */
999 pSen->SenLastErrTrapTS = CurrTime;
1000 pSen->SenErrCts++;
1001
1002 /* Queue PNMI Event */
1003 SkEventQueue(pAC, SKGE_PNMI, (TooHigh ?
1004 SK_PNMI_EVT_SEN_ERR_UPP :
1005 SK_PNMI_EVT_SEN_ERR_LOW),
1006 ParaLocal);
1007 }
1008
1009 if (DoErrLog) {
1010 /* Set current Time */
1011 pSen->SenLastErrLogTS = CurrTime;
1012
1013 if (pSen->SenType == SK_SEN_TEMP) {
1014 SK_ERR_LOG(pAC, SK_ERRCL_HW, SKERR_I2C_E011, SKERR_I2C_E011MSG);
1015 }
1016 else if (pSen->SenType == SK_SEN_VOLT) {
1017 SK_ERR_LOG(pAC, SK_ERRCL_HW, SKERR_I2C_E012, SKERR_I2C_E012MSG);
1018 }
1019 else {
1020 SK_ERR_LOG(pAC, SK_ERRCL_HW, SKERR_I2C_E015, SKERR_I2C_E015MSG);
1021 }
1022 }
1023 }
1024
1025 /* Check the Value against the thresholds */
1026 /* 2nd: Warning thresholds */
1027 TooHigh = (pSen->SenValue > pSen->SenThreWarnHigh);
1028 TooLow = (pSen->SenValue < pSen->SenThreWarnLow);
1029
1030 if (!IsError && (TooHigh || TooLow)) {
1031 /* Error condition is satisfied */
1032 DoTrapSend = SK_TRUE;
1033 DoErrLog = SK_TRUE;
1034
1035 if (pSen->SenErrFlag == SK_SEN_ERR_WARN) {
1036 /* This state is the former one */
1037
1038 /* So check first whether we have to send a trap */
1039 if (pSen->SenLastWarnTrapTS + SK_SEN_WARN_TR_HOLD > CurrTime) {
1040 /*
1041 * Do NOT send the Trap. The hold back time
1042 * has to run out first.
1043 */
1044 DoTrapSend = SK_FALSE;
1045 }
1046
1047 /* Check now whether we have to log an Error */
1048 if (pSen->SenLastWarnLogTS + SK_SEN_WARN_LOG_HOLD > CurrTime) {
1049 /*
1050 * Do NOT log the error. The hold back time
1051 * has to run out first.
1052 */
1053 DoErrLog = SK_FALSE;
1054 }
1055 }
1056 else {
1057 /* We came from a different state -> Set Begin Time Stamp */
1058 pSen->SenBegWarnTS = CurrTime;
1059 pSen->SenErrFlag = SK_SEN_ERR_WARN;
1060 }
1061
1062 if (DoTrapSend) {
1063 /* Set current Time */
1064 pSen->SenLastWarnTrapTS = CurrTime;
1065 pSen->SenWarnCts++;
1066
1067 /* Queue PNMI Event */
1068 SkEventQueue(pAC, SKGE_PNMI, (TooHigh ?
1069 SK_PNMI_EVT_SEN_WAR_UPP :
1070 SK_PNMI_EVT_SEN_WAR_LOW),
1071 ParaLocal);
1072 }
1073
1074 if (DoErrLog) {
1075 /* Set current Time */
1076 pSen->SenLastWarnLogTS = CurrTime;
1077
1078 if (pSen->SenType == SK_SEN_TEMP) {
1079 SK_ERR_LOG(pAC, SK_ERRCL_HW, SKERR_I2C_E009, SKERR_I2C_E009MSG);
1080 }
1081 else if (pSen->SenType == SK_SEN_VOLT) {
1082 SK_ERR_LOG(pAC, SK_ERRCL_HW, SKERR_I2C_E010, SKERR_I2C_E010MSG);
1083 }
1084 else {
1085 SK_ERR_LOG(pAC, SK_ERRCL_HW, SKERR_I2C_E014, SKERR_I2C_E014MSG);
1086 }
1087 }
1088 }
1089
1090 /* Check for NO error at all */
1091 if (!IsError && !TooHigh && !TooLow) {
1092 /* Set o.k. Status if no error and no warning condition */
1093 pSen->SenErrFlag = SK_SEN_ERR_OK;
1094 }
1095
1096 /* End of check against the thresholds */
1097
1098 /* Bug fix AF: 16.Aug.2001: Correct the init base
1099 * of LM80 sensor.
1100 */
1101 if (pSen->SenInit == SK_SEN_DYN_INIT_PCI_IO) {
1102
1103 pSen->SenInit = SK_SEN_DYN_INIT_NONE;
1104
1105 if (pSen->SenValue > SK_SEN_PCI_IO_RANGE_LIMITER) {
1106 /* 5V PCI-IO Voltage */
1107 pSen->SenThreWarnLow = SK_SEN_PCI_IO_5V_LOW_WARN;
1108 pSen->SenThreErrLow = SK_SEN_PCI_IO_5V_LOW_ERR;
1109 }
1110 else {
1111 /* 3.3V PCI-IO Voltage */
1112 pSen->SenThreWarnHigh = SK_SEN_PCI_IO_3V3_HIGH_WARN;
1113 pSen->SenThreErrHigh = SK_SEN_PCI_IO_3V3_HIGH_ERR;
1114 }
1115 }
1116
1117#ifdef TEST_ONLY
1118 /* Dynamic thresholds also for VAUX of LM80 sensor */
1119 if (pSen->SenInit == SK_SEN_DYN_INIT_VAUX) {
1120
1121 pSen->SenInit = SK_SEN_DYN_INIT_NONE;
1122
1123 /* 3.3V VAUX Voltage */
1124 if (pSen->SenValue > SK_SEN_VAUX_RANGE_LIMITER) {
1125 pSen->SenThreWarnLow = SK_SEN_VAUX_3V3_LOW_WARN;
1126 pSen->SenThreErrLow = SK_SEN_VAUX_3V3_LOW_ERR;
1127 }
1128 /* 0V VAUX Voltage */
1129 else {
1130 pSen->SenThreWarnHigh = SK_SEN_VAUX_0V_WARN_ERR;
1131 pSen->SenThreErrHigh = SK_SEN_VAUX_0V_WARN_ERR;
1132 }
1133 }
1134
1135 /*
1136 * Check initialization state:
1137 * The VIO Thresholds need adaption
1138 */
1139 if (!pSen->SenInit && pSen->SenReg == LM80_VT1_IN &&
1140 pSen->SenValue > SK_SEN_WARNLOW2C &&
1141 pSen->SenValue < SK_SEN_WARNHIGH2) {
1142 pSen->SenThreErrLow = SK_SEN_ERRLOW2C;
1143 pSen->SenThreWarnLow = SK_SEN_WARNLOW2C;
1144 pSen->SenInit = SK_TRUE;
1145 }
1146
1147 if (!pSen->SenInit && pSen->SenReg == LM80_VT1_IN &&
1148 pSen->SenValue > SK_SEN_WARNLOW2 &&
1149 pSen->SenValue < SK_SEN_WARNHIGH2C) {
1150 pSen->SenThreErrHigh = SK_SEN_ERRHIGH2C;
1151 pSen->SenThreWarnHigh = SK_SEN_WARNHIGH2C;
1152 pSen->SenInit = SK_TRUE;
1153 }
1154#endif
1155
1156 if (pSen->SenInit != SK_SEN_DYN_INIT_NONE) {
1157 SK_ERR_LOG(pAC, SK_ERRCL_HW, SKERR_I2C_E013, SKERR_I2C_E013MSG);
1158 }
1159} /* SkI2cCheckSensor */
1160
1161
1162/*
1163 * The only Event to be served is the timeout event
1164 *
1165 */
1166int SkI2cEvent(
1167SK_AC *pAC, /* Adapter Context */
1168SK_IOC IoC, /* I/O Context */
1169SK_U32 Event, /* Module specific Event */
1170SK_EVPARA Para) /* Event specific Parameter */
1171{
1172 int ReadComplete;
1173 SK_SENSOR *pSen;
1174 SK_U32 Time;
1175 SK_EVPARA ParaLocal;
1176 int i;
1177
1178 /* New case: no sensors */
1179 if (pAC->I2c.MaxSens == 0) {
1180 return(0);
1181 }
1182
1183 switch (Event) {
1184 case SK_I2CEV_IRQ:
1185 pSen = &pAC->I2c.SenTable[pAC->I2c.CurrSens];
1186 ReadComplete = SkI2cReadSensor(pAC, IoC, pSen);
1187
1188 if (ReadComplete) {
1189 /* Check sensor against defined thresholds */
1190 SkI2cCheckSensor(pAC, pSen);
1191
1192 /* Increment Current sensor and set appropriate Timeout */
1193 pAC->I2c.CurrSens++;
1194 if (pAC->I2c.CurrSens >= pAC->I2c.MaxSens) {
1195 pAC->I2c.CurrSens = 0;
1196 Time = SK_I2C_TIM_LONG;
1197 }
1198 else {
1199 Time = SK_I2C_TIM_SHORT;
1200 }
1201
1202 /* Start Timer */
1203 ParaLocal.Para64 = (SK_U64)0;
1204
1205 pAC->I2c.TimerMode = SK_TIMER_NEW_GAUGING;
1206
1207 SkTimerStart(pAC, IoC, &pAC->I2c.SenTimer, Time,
1208 SKGE_I2C, SK_I2CEV_TIM, ParaLocal);
1209 }
1210 else {
1211 /* Start Timer */
1212 ParaLocal.Para64 = (SK_U64)0;
1213
1214 pAC->I2c.TimerMode = SK_TIMER_WATCH_SM;
1215
1216 SkTimerStart(pAC, IoC, &pAC->I2c.SenTimer, SK_I2C_TIM_WATCH,
1217 SKGE_I2C, SK_I2CEV_TIM, ParaLocal);
1218 }
1219 break;
1220 case SK_I2CEV_TIM:
1221 if (pAC->I2c.TimerMode == SK_TIMER_NEW_GAUGING) {
1222
1223 ParaLocal.Para64 = (SK_U64)0;
1224 SkTimerStop(pAC, IoC, &pAC->I2c.SenTimer);
1225
1226 pSen = &pAC->I2c.SenTable[pAC->I2c.CurrSens];
1227 ReadComplete = SkI2cReadSensor(pAC, IoC, pSen);
1228
1229 if (ReadComplete) {
1230 /* Check sensor against defined thresholds */
1231 SkI2cCheckSensor(pAC, pSen);
1232
1233 /* Increment Current sensor and set appropriate Timeout */
1234 pAC->I2c.CurrSens++;
1235 if (pAC->I2c.CurrSens == pAC->I2c.MaxSens) {
1236 pAC->I2c.CurrSens = 0;
1237 Time = SK_I2C_TIM_LONG;
1238 }
1239 else {
1240 Time = SK_I2C_TIM_SHORT;
1241 }
1242
1243 /* Start Timer */
1244 ParaLocal.Para64 = (SK_U64)0;
1245
1246 pAC->I2c.TimerMode = SK_TIMER_NEW_GAUGING;
1247
1248 SkTimerStart(pAC, IoC, &pAC->I2c.SenTimer, Time,
1249 SKGE_I2C, SK_I2CEV_TIM, ParaLocal);
1250 }
1251 }
1252 else {
1253 pSen = &pAC->I2c.SenTable[pAC->I2c.CurrSens];
1254 pSen->SenErrFlag = SK_SEN_ERR_FAULTY;
1255 SK_I2C_STOP(IoC);
1256
1257 /* Increment Current sensor and set appropriate Timeout */
1258 pAC->I2c.CurrSens++;
1259 if (pAC->I2c.CurrSens == pAC->I2c.MaxSens) {
1260 pAC->I2c.CurrSens = 0;
1261 Time = SK_I2C_TIM_LONG;
1262 }
1263 else {
1264 Time = SK_I2C_TIM_SHORT;
1265 }
1266
1267 /* Start Timer */
1268 ParaLocal.Para64 = (SK_U64)0;
1269
1270 pAC->I2c.TimerMode = SK_TIMER_NEW_GAUGING;
1271
1272 SkTimerStart(pAC, IoC, &pAC->I2c.SenTimer, Time,
1273 SKGE_I2C, SK_I2CEV_TIM, ParaLocal);
1274 }
1275 break;
1276 case SK_I2CEV_CLEAR:
1277 for (i = 0; i < SK_MAX_SENSORS; i++) {
1278 pAC->I2c.SenTable[i].SenErrFlag = SK_SEN_ERR_OK;
1279 pAC->I2c.SenTable[i].SenErrCts = 0;
1280 pAC->I2c.SenTable[i].SenWarnCts = 0;
1281 pAC->I2c.SenTable[i].SenBegErrTS = 0;
1282 pAC->I2c.SenTable[i].SenBegWarnTS = 0;
1283 pAC->I2c.SenTable[i].SenLastErrTrapTS = (SK_U64)0;
1284 pAC->I2c.SenTable[i].SenLastErrLogTS = (SK_U64)0;
1285 pAC->I2c.SenTable[i].SenLastWarnTrapTS = (SK_U64)0;
1286 pAC->I2c.SenTable[i].SenLastWarnLogTS = (SK_U64)0;
1287 }
1288 break;
1289 default:
1290 SK_ERR_LOG(pAC, SK_ERRCL_SW, SKERR_I2C_E006, SKERR_I2C_E006MSG);
1291 }
1292
1293 return(0);
1294} /* SkI2cEvent*/
1295
1296#endif /* !SK_DIAG */
diff --git a/drivers/net/sk98lin/sklm80.c b/drivers/net/sk98lin/sklm80.c
new file mode 100644
index 000000000000..a204f5bb55d4
--- /dev/null
+++ b/drivers/net/sk98lin/sklm80.c
@@ -0,0 +1,141 @@
1/******************************************************************************
2 *
3 * Name: sklm80.c
4 * Project: Gigabit Ethernet Adapters, TWSI-Module
5 * Version: $Revision: 1.22 $
6 * Date: $Date: 2003/10/20 09:08:21 $
7 * Purpose: Functions to access Voltage and Temperature Sensor (LM80)
8 *
9 ******************************************************************************/
10
11/******************************************************************************
12 *
13 * (C)Copyright 1998-2002 SysKonnect.
14 * (C)Copyright 2002-2003 Marvell.
15 *
16 * This program is free software; you can redistribute it and/or modify
17 * it under the terms of the GNU General Public License as published by
18 * the Free Software Foundation; either version 2 of the License, or
19 * (at your option) any later version.
20 *
21 * The information in this file is provided "AS IS" without warranty.
22 *
23 ******************************************************************************/
24
25/*
26 LM80 functions
27*/
28#if (defined(DEBUG) || ((!defined(LINT)) && (!defined(SK_SLIM))))
29static const char SysKonnectFileId[] =
30 "@(#) $Id: sklm80.c,v 1.22 2003/10/20 09:08:21 rschmidt Exp $ (C) Marvell. ";
31#endif
32
33#include "h/skdrv1st.h" /* Driver Specific Definitions */
34#include "h/lm80.h"
35#include "h/skdrv2nd.h" /* Adapter Control- and Driver specific Def. */
36
37#define BREAK_OR_WAIT(pAC,IoC,Event) break
38
39/*
40 * read a sensors value (LM80 specific)
41 *
42 * This function reads a sensors value from the I2C sensor chip LM80.
43 * The sensor is defined by its index into the sensors database in the struct
44 * pAC points to.
45 *
46 * Returns 1 if the read is completed
47 * 0 if the read must be continued (I2C Bus still allocated)
48 */
49int SkLm80ReadSensor(
50SK_AC *pAC, /* Adapter Context */
51SK_IOC IoC, /* I/O Context needed in level 1 and 2 */
52SK_SENSOR *pSen) /* Sensor to be read */
53{
54 SK_I32 Value;
55
56 switch (pSen->SenState) {
57 case SK_SEN_IDLE:
58 /* Send address to ADDR register */
59 SK_I2C_CTL(IoC, I2C_READ, pSen->SenDev, I2C_025K_DEV, pSen->SenReg, 0);
60
61 pSen->SenState = SK_SEN_VALUE ;
62 BREAK_OR_WAIT(pAC, IoC, I2C_READ);
63
64 case SK_SEN_VALUE:
65 /* Read value from data register */
66 SK_IN32(IoC, B2_I2C_DATA, ((SK_U32 *)&Value));
67
68 Value &= 0xff; /* only least significant byte is valid */
69
70 /* Do NOT check the Value against the thresholds */
71 /* Checking is done in the calling instance */
72
73 if (pSen->SenType == SK_SEN_VOLT) {
74 /* Voltage sensor */
75 pSen->SenValue = Value * SK_LM80_VT_LSB;
76 pSen->SenState = SK_SEN_IDLE ;
77 return(1);
78 }
79
80 if (pSen->SenType == SK_SEN_FAN) {
81 if (Value != 0 && Value != 0xff) {
82 /* Fan speed counter */
83 pSen->SenValue = SK_LM80_FAN_FAKTOR/Value;
84 }
85 else {
86 /* Indicate Fan error */
87 pSen->SenValue = 0;
88 }
89 pSen->SenState = SK_SEN_IDLE ;
90 return(1);
91 }
92
93 /* First: correct the value: it might be negative */
94 if ((Value & 0x80) != 0) {
95 /* Value is negative */
96 Value = Value - 256;
97 }
98
99 /* We have a temperature sensor and need to get the signed extension.
100 * For now we get the extension from the last reading, so in the normal
101 * case we won't see flickering temperatures.
102 */
103 pSen->SenValue = (Value * SK_LM80_TEMP_LSB) +
104 (pSen->SenValue % SK_LM80_TEMP_LSB);
105
106 /* Send address to ADDR register */
107 SK_I2C_CTL(IoC, I2C_READ, pSen->SenDev, I2C_025K_DEV, LM80_TEMP_CTRL, 0);
108
109 pSen->SenState = SK_SEN_VALEXT ;
110 BREAK_OR_WAIT(pAC, IoC, I2C_READ);
111
112 case SK_SEN_VALEXT:
113 /* Read value from data register */
114 SK_IN32(IoC, B2_I2C_DATA, ((SK_U32 *)&Value));
115 Value &= LM80_TEMP_LSB_9; /* only bit 7 is valid */
116
117 /* cut the LSB bit */
118 pSen->SenValue = ((pSen->SenValue / SK_LM80_TEMP_LSB) *
119 SK_LM80_TEMP_LSB);
120
121 if (pSen->SenValue < 0) {
122 /* Value negative: The bit value must be subtracted */
123 pSen->SenValue -= ((Value >> 7) * SK_LM80_TEMPEXT_LSB);
124 }
125 else {
126 /* Value positive: The bit value must be added */
127 pSen->SenValue += ((Value >> 7) * SK_LM80_TEMPEXT_LSB);
128 }
129
130 pSen->SenState = SK_SEN_IDLE ;
131 return(1);
132
133 default:
134 SK_ERR_LOG(pAC, SK_ERRCL_SW, SKERR_I2C_E007, SKERR_I2C_E007MSG);
135 return(1);
136 }
137
138 /* Not completed */
139 return(0);
140}
141
diff --git a/drivers/net/sk98lin/skqueue.c b/drivers/net/sk98lin/skqueue.c
new file mode 100644
index 000000000000..0275b4f71d9b
--- /dev/null
+++ b/drivers/net/sk98lin/skqueue.c
@@ -0,0 +1,179 @@
1/******************************************************************************
2 *
3 * Name: skqueue.c
4 * Project: Gigabit Ethernet Adapters, Event Scheduler Module
5 * Version: $Revision: 1.20 $
6 * Date: $Date: 2003/09/16 13:44:00 $
7 * Purpose: Management of an event queue.
8 *
9 ******************************************************************************/
10
11/******************************************************************************
12 *
13 * (C)Copyright 1998-2002 SysKonnect GmbH.
14 * (C)Copyright 2002-2003 Marvell.
15 *
16 * This program is free software; you can redistribute it and/or modify
17 * it under the terms of the GNU General Public License as published by
18 * the Free Software Foundation; either version 2 of the License, or
19 * (at your option) any later version.
20 *
21 * The information in this file is provided "AS IS" without warranty.
22 *
23 ******************************************************************************/
24
25
26/*
27 * Event queue and dispatcher
28 */
29#if (defined(DEBUG) || ((!defined(LINT)) && (!defined(SK_SLIM))))
30static const char SysKonnectFileId[] =
31 "@(#) $Id: skqueue.c,v 1.20 2003/09/16 13:44:00 rschmidt Exp $ (C) Marvell.";
32#endif
33
34#include "h/skdrv1st.h" /* Driver Specific Definitions */
35#include "h/skqueue.h" /* Queue Definitions */
36#include "h/skdrv2nd.h" /* Adapter Control- and Driver specific Def. */
37
38#ifdef __C2MAN__
39/*
40 Event queue management.
41
42 General Description:
43
44 */
45intro()
46{}
47#endif
48
49#define PRINTF(a,b,c)
50
51/*
52 * init event queue management
53 *
54 * Must be called during init level 0.
55 */
56void SkEventInit(
57SK_AC *pAC, /* Adapter context */
58SK_IOC Ioc, /* IO context */
59int Level) /* Init level */
60{
61 switch (Level) {
62 case SK_INIT_DATA:
63 pAC->Event.EvPut = pAC->Event.EvGet = pAC->Event.EvQueue;
64 break;
65 default:
66 break;
67 }
68}
69
70/*
71 * add event to queue
72 */
73void SkEventQueue(
74SK_AC *pAC, /* Adapters context */
75SK_U32 Class, /* Event Class */
76SK_U32 Event, /* Event to be queued */
77SK_EVPARA Para) /* Event parameter */
78{
79 pAC->Event.EvPut->Class = Class;
80 pAC->Event.EvPut->Event = Event;
81 pAC->Event.EvPut->Para = Para;
82
83 if (++pAC->Event.EvPut == &pAC->Event.EvQueue[SK_MAX_EVENT])
84 pAC->Event.EvPut = pAC->Event.EvQueue;
85
86 if (pAC->Event.EvPut == pAC->Event.EvGet) {
87 SK_ERR_LOG(pAC, SK_ERRCL_NORES, SKERR_Q_E001, SKERR_Q_E001MSG);
88 }
89}
90
91/*
92 * event dispatcher
93 * while event queue is not empty
94 * get event from queue
95 * send command to state machine
96 * end
97 * return error reported by individual Event function
98 * 0 if no error occured.
99 */
100int SkEventDispatcher(
101SK_AC *pAC, /* Adapters Context */
102SK_IOC Ioc) /* Io context */
103{
104 SK_EVENTELEM *pEv; /* pointer into queue */
105 SK_U32 Class;
106 int Rtv;
107
108 pEv = pAC->Event.EvGet;
109
110 PRINTF("dispatch get %x put %x\n", pEv, pAC->Event.ev_put);
111
112 while (pEv != pAC->Event.EvPut) {
113 PRINTF("dispatch Class %d Event %d\n", pEv->Class, pEv->Event);
114
115 switch (Class = pEv->Class) {
116#ifndef SK_USE_LAC_EV
117#ifndef SK_SLIM
118 case SKGE_RLMT: /* RLMT Event */
119 Rtv = SkRlmtEvent(pAC, Ioc, pEv->Event, pEv->Para);
120 break;
121 case SKGE_I2C: /* I2C Event */
122 Rtv = SkI2cEvent(pAC, Ioc, pEv->Event, pEv->Para);
123 break;
124 case SKGE_PNMI: /* PNMI Event */
125 Rtv = SkPnmiEvent(pAC, Ioc, pEv->Event, pEv->Para);
126 break;
127#endif /* not SK_SLIM */
128#endif /* not SK_USE_LAC_EV */
129 case SKGE_DRV: /* Driver Event */
130 Rtv = SkDrvEvent(pAC, Ioc, pEv->Event, pEv->Para);
131 break;
132#ifndef SK_USE_SW_TIMER
133 case SKGE_HWAC:
134 Rtv = SkGeSirqEvent(pAC, Ioc, pEv->Event, pEv->Para);
135 break;
136#else /* !SK_USE_SW_TIMER */
137 case SKGE_SWT :
138 Rtv = SkSwtEvent(pAC, Ioc, pEv->Event, pEv->Para);
139 break;
140#endif /* !SK_USE_SW_TIMER */
141#ifdef SK_USE_LAC_EV
142 case SKGE_LACP :
143 Rtv = SkLacpEvent(pAC, Ioc, pEv->Event, pEv->Para);
144 break;
145 case SKGE_RSF :
146 Rtv = SkRsfEvent(pAC, Ioc, pEv->Event, pEv->Para);
147 break;
148 case SKGE_MARKER :
149 Rtv = SkMarkerEvent(pAC, Ioc, pEv->Event, pEv->Para);
150 break;
151 case SKGE_FD :
152 Rtv = SkFdEvent(pAC, Ioc, pEv->Event, pEv->Para);
153 break;
154#endif /* SK_USE_LAC_EV */
155#ifdef SK_USE_CSUM
156 case SKGE_CSUM :
157 Rtv = SkCsEvent(pAC, Ioc, pEv->Event, pEv->Para);
158 break;
159#endif /* SK_USE_CSUM */
160 default :
161 SK_ERR_LOG(pAC, SK_ERRCL_SW, SKERR_Q_E002, SKERR_Q_E002MSG);
162 Rtv = 0;
163 }
164
165 if (Rtv != 0) {
166 return(Rtv);
167 }
168
169 if (++pEv == &pAC->Event.EvQueue[SK_MAX_EVENT])
170 pEv = pAC->Event.EvQueue;
171
172 /* Renew get: it is used in queue_events to detect overruns */
173 pAC->Event.EvGet = pEv;
174 }
175
176 return(0);
177}
178
179/* End of file */
diff --git a/drivers/net/sk98lin/skrlmt.c b/drivers/net/sk98lin/skrlmt.c
new file mode 100644
index 000000000000..be8d1ccddf6d
--- /dev/null
+++ b/drivers/net/sk98lin/skrlmt.c
@@ -0,0 +1,3257 @@
1/******************************************************************************
2 *
3 * Name: skrlmt.c
4 * Project: GEnesis, PCI Gigabit Ethernet Adapter
5 * Version: $Revision: 1.69 $
6 * Date: $Date: 2003/04/15 09:39:22 $
7 * Purpose: Manage links on SK-NET Adapters, esp. redundant ones.
8 *
9 ******************************************************************************/
10
11/******************************************************************************
12 *
13 * (C)Copyright 1998-2002 SysKonnect GmbH.
14 * (C)Copyright 2002-2003 Marvell.
15 *
16 * This program is free software; you can redistribute it and/or modify
17 * it under the terms of the GNU General Public License as published by
18 * the Free Software Foundation; either version 2 of the License, or
19 * (at your option) any later version.
20 *
21 * The information in this file is provided "AS IS" without warranty.
22 *
23 ******************************************************************************/
24
25/******************************************************************************
26 *
27 * Description:
28 *
29 * This module contains code for Link ManagemenT (LMT) of SK-NET Adapters.
30 * It is mainly intended for adapters with more than one link.
31 * For such adapters, this module realizes Redundant Link ManagemenT (RLMT).
32 *
33 * Include File Hierarchy:
34 *
35 * "skdrv1st.h"
36 * "skdrv2nd.h"
37 *
38 ******************************************************************************/
39
40#ifndef lint
41static const char SysKonnectFileId[] =
42 "@(#) $Id: skrlmt.c,v 1.69 2003/04/15 09:39:22 tschilli Exp $ (C) Marvell.";
43#endif /* !defined(lint) */
44
45#define __SKRLMT_C
46
47#ifdef __cplusplus
48extern "C" {
49#endif /* cplusplus */
50
51#include "h/skdrv1st.h"
52#include "h/skdrv2nd.h"
53
54/* defines ********************************************************************/
55
56#ifndef SK_HWAC_LINK_LED
57#define SK_HWAC_LINK_LED(a,b,c,d)
58#endif /* !defined(SK_HWAC_LINK_LED) */
59
60#ifndef DEBUG
61#define RLMT_STATIC static
62#else /* DEBUG */
63#define RLMT_STATIC
64
65#ifndef SK_LITTLE_ENDIAN
66/* First 32 bits */
67#define OFFS_LO32 1
68
69/* Second 32 bits */
70#define OFFS_HI32 0
71#else /* SK_LITTLE_ENDIAN */
72/* First 32 bits */
73#define OFFS_LO32 0
74
75/* Second 32 bits */
76#define OFFS_HI32 1
77#endif /* SK_LITTLE_ENDIAN */
78
79#endif /* DEBUG */
80
81/* ----- Private timeout values ----- */
82
83#define SK_RLMT_MIN_TO_VAL 125000 /* 1/8 sec. */
84#define SK_RLMT_DEF_TO_VAL 1000000 /* 1 sec. */
85#define SK_RLMT_PORTDOWN_TIM_VAL 900000 /* another 0.9 sec. */
86#define SK_RLMT_PORTSTART_TIM_VAL 100000 /* 0.1 sec. */
87#define SK_RLMT_PORTUP_TIM_VAL 2500000 /* 2.5 sec. */
88#define SK_RLMT_SEG_TO_VAL 900000000 /* 15 min. */
89
90/* Assume tick counter increment is 1 - may be set OS-dependent. */
91#ifndef SK_TICK_INCR
92#define SK_TICK_INCR SK_CONSTU64(1)
93#endif /* !defined(SK_TICK_INCR) */
94
95/*
96 * Amount that a time stamp must be later to be recognized as "substantially
97 * later". This is about 1/128 sec, but above 1 tick counter increment.
98 */
99#define SK_RLMT_BC_DELTA (1 + ((SK_TICKS_PER_SEC >> 7) > SK_TICK_INCR ? \
100 (SK_TICKS_PER_SEC >> 7) : SK_TICK_INCR))
101
102/* ----- Private RLMT defaults ----- */
103
104#define SK_RLMT_DEF_PREF_PORT 0 /* "Lower" port. */
105#define SK_RLMT_DEF_MODE SK_RLMT_CHECK_LINK /* Default RLMT Mode. */
106
107/* ----- Private RLMT checking states ----- */
108
109#define SK_RLMT_RCS_SEG 1 /* RLMT Check State: check seg. */
110#define SK_RLMT_RCS_START_SEG 2 /* RLMT Check State: start check seg. */
111#define SK_RLMT_RCS_SEND_SEG 4 /* RLMT Check State: send BPDU packet */
112#define SK_RLMT_RCS_REPORT_SEG 8 /* RLMT Check State: report seg. */
113
114/* ----- Private PORT checking states ----- */
115
116#define SK_RLMT_PCS_TX 1 /* Port Check State: check tx. */
117#define SK_RLMT_PCS_RX 2 /* Port Check State: check rx. */
118
119/* ----- Private PORT events ----- */
120
121/* Note: Update simulation when changing these. */
122#define SK_RLMT_PORTSTART_TIM 1100 /* Port start timeout. */
123#define SK_RLMT_PORTUP_TIM 1101 /* Port can now go up. */
124#define SK_RLMT_PORTDOWN_RX_TIM 1102 /* Port did not receive once ... */
125#define SK_RLMT_PORTDOWN 1103 /* Port went down. */
126#define SK_RLMT_PORTDOWN_TX_TIM 1104 /* Partner did not receive ... */
127
128/* ----- Private RLMT events ----- */
129
130/* Note: Update simulation when changing these. */
131#define SK_RLMT_TIM 2100 /* RLMT timeout. */
132#define SK_RLMT_SEG_TIM 2101 /* RLMT segmentation check timeout. */
133
134#define TO_SHORTEN(tim) ((tim) / 2)
135
136/* Error numbers and messages. */
137#define SKERR_RLMT_E001 (SK_ERRBASE_RLMT + 0)
138#define SKERR_RLMT_E001_MSG "No Packet."
139#define SKERR_RLMT_E002 (SKERR_RLMT_E001 + 1)
140#define SKERR_RLMT_E002_MSG "Short Packet."
141#define SKERR_RLMT_E003 (SKERR_RLMT_E002 + 1)
142#define SKERR_RLMT_E003_MSG "Unknown RLMT event."
143#define SKERR_RLMT_E004 (SKERR_RLMT_E003 + 1)
144#define SKERR_RLMT_E004_MSG "PortsUp incorrect."
145#define SKERR_RLMT_E005 (SKERR_RLMT_E004 + 1)
146#define SKERR_RLMT_E005_MSG \
147 "Net seems to be segmented (different root bridges are reported on the ports)."
148#define SKERR_RLMT_E006 (SKERR_RLMT_E005 + 1)
149#define SKERR_RLMT_E006_MSG "Duplicate MAC Address detected."
150#define SKERR_RLMT_E007 (SKERR_RLMT_E006 + 1)
151#define SKERR_RLMT_E007_MSG "LinksUp incorrect."
152#define SKERR_RLMT_E008 (SKERR_RLMT_E007 + 1)
153#define SKERR_RLMT_E008_MSG "Port not started but link came up."
154#define SKERR_RLMT_E009 (SKERR_RLMT_E008 + 1)
155#define SKERR_RLMT_E009_MSG "Corrected illegal setting of Preferred Port."
156#define SKERR_RLMT_E010 (SKERR_RLMT_E009 + 1)
157#define SKERR_RLMT_E010_MSG "Ignored illegal Preferred Port."
158
159/* LLC field values. */
160#define LLC_COMMAND_RESPONSE_BIT 1
161#define LLC_TEST_COMMAND 0xE3
162#define LLC_UI 0x03
163
164/* RLMT Packet fields. */
165#define SK_RLMT_DSAP 0
166#define SK_RLMT_SSAP 0
167#define SK_RLMT_CTRL (LLC_TEST_COMMAND)
168#define SK_RLMT_INDICATOR0 0x53 /* S */
169#define SK_RLMT_INDICATOR1 0x4B /* K */
170#define SK_RLMT_INDICATOR2 0x2D /* - */
171#define SK_RLMT_INDICATOR3 0x52 /* R */
172#define SK_RLMT_INDICATOR4 0x4C /* L */
173#define SK_RLMT_INDICATOR5 0x4D /* M */
174#define SK_RLMT_INDICATOR6 0x54 /* T */
175#define SK_RLMT_PACKET_VERSION 0
176
177/* RLMT SPT Flag values. */
178#define SK_RLMT_SPT_FLAG_CHANGE 0x01
179#define SK_RLMT_SPT_FLAG_CHANGE_ACK 0x80
180
181/* RLMT SPT Packet fields. */
182#define SK_RLMT_SPT_DSAP 0x42
183#define SK_RLMT_SPT_SSAP 0x42
184#define SK_RLMT_SPT_CTRL (LLC_UI)
185#define SK_RLMT_SPT_PROTOCOL_ID0 0x00
186#define SK_RLMT_SPT_PROTOCOL_ID1 0x00
187#define SK_RLMT_SPT_PROTOCOL_VERSION_ID 0x00
188#define SK_RLMT_SPT_BPDU_TYPE 0x00
189#define SK_RLMT_SPT_FLAGS 0x00 /* ?? */
190#define SK_RLMT_SPT_ROOT_ID0 0xFF /* Lowest possible priority. */
191#define SK_RLMT_SPT_ROOT_ID1 0xFF /* Lowest possible priority. */
192
193/* Remaining 6 bytes will be the current port address. */
194#define SK_RLMT_SPT_ROOT_PATH_COST0 0x00
195#define SK_RLMT_SPT_ROOT_PATH_COST1 0x00
196#define SK_RLMT_SPT_ROOT_PATH_COST2 0x00
197#define SK_RLMT_SPT_ROOT_PATH_COST3 0x00
198#define SK_RLMT_SPT_BRIDGE_ID0 0xFF /* Lowest possible priority. */
199#define SK_RLMT_SPT_BRIDGE_ID1 0xFF /* Lowest possible priority. */
200
201/* Remaining 6 bytes will be the current port address. */
202#define SK_RLMT_SPT_PORT_ID0 0xFF /* Lowest possible priority. */
203#define SK_RLMT_SPT_PORT_ID1 0xFF /* Lowest possible priority. */
204#define SK_RLMT_SPT_MSG_AGE0 0x00
205#define SK_RLMT_SPT_MSG_AGE1 0x00
206#define SK_RLMT_SPT_MAX_AGE0 0x00
207#define SK_RLMT_SPT_MAX_AGE1 0xFF
208#define SK_RLMT_SPT_HELLO_TIME0 0x00
209#define SK_RLMT_SPT_HELLO_TIME1 0xFF
210#define SK_RLMT_SPT_FWD_DELAY0 0x00
211#define SK_RLMT_SPT_FWD_DELAY1 0x40
212
213/* Size defines. */
214#define SK_RLMT_MIN_PACKET_SIZE 34
215#define SK_RLMT_MAX_PACKET_SIZE (SK_RLMT_MAX_TX_BUF_SIZE)
216#define SK_PACKET_DATA_LEN (SK_RLMT_MAX_PACKET_SIZE - \
217 SK_RLMT_MIN_PACKET_SIZE)
218
219/* ----- RLMT packet types ----- */
220#define SK_PACKET_ANNOUNCE 1 /* Port announcement. */
221#define SK_PACKET_ALIVE 2 /* Alive packet to port. */
222#define SK_PACKET_ADDR_CHANGED 3 /* Port address changed. */
223#define SK_PACKET_CHECK_TX 4 /* Check your tx line. */
224
225#ifdef SK_LITTLE_ENDIAN
226#define SK_U16_TO_NETWORK_ORDER(Val,Addr) { \
227 SK_U8 *_Addr = (SK_U8*)(Addr); \
228 SK_U16 _Val = (SK_U16)(Val); \
229 *_Addr++ = (SK_U8)(_Val >> 8); \
230 *_Addr = (SK_U8)(_Val & 0xFF); \
231}
232#endif /* SK_LITTLE_ENDIAN */
233
234#ifdef SK_BIG_ENDIAN
235#define SK_U16_TO_NETWORK_ORDER(Val,Addr) (*(SK_U16*)(Addr) = (SK_U16)(Val))
236#endif /* SK_BIG_ENDIAN */
237
238#define AUTONEG_FAILED SK_FALSE
239#define AUTONEG_SUCCESS SK_TRUE
240
241
242/* typedefs *******************************************************************/
243
244/* RLMT packet. Length: SK_RLMT_MAX_PACKET_SIZE (60) bytes. */
245typedef struct s_RlmtPacket {
246 SK_U8 DstAddr[SK_MAC_ADDR_LEN];
247 SK_U8 SrcAddr[SK_MAC_ADDR_LEN];
248 SK_U8 TypeLen[2];
249 SK_U8 DSap;
250 SK_U8 SSap;
251 SK_U8 Ctrl;
252 SK_U8 Indicator[7];
253 SK_U8 RlmtPacketType[2];
254 SK_U8 Align1[2];
255 SK_U8 Random[4]; /* Random value of requesting(!) station. */
256 SK_U8 RlmtPacketVersion[2]; /* RLMT Packet version. */
257 SK_U8 Data[SK_PACKET_DATA_LEN];
258} SK_RLMT_PACKET;
259
260typedef struct s_SpTreeRlmtPacket {
261 SK_U8 DstAddr[SK_MAC_ADDR_LEN];
262 SK_U8 SrcAddr[SK_MAC_ADDR_LEN];
263 SK_U8 TypeLen[2];
264 SK_U8 DSap;
265 SK_U8 SSap;
266 SK_U8 Ctrl;
267 SK_U8 ProtocolId[2];
268 SK_U8 ProtocolVersionId;
269 SK_U8 BpduType;
270 SK_U8 Flags;
271 SK_U8 RootId[8];
272 SK_U8 RootPathCost[4];
273 SK_U8 BridgeId[8];
274 SK_U8 PortId[2];
275 SK_U8 MessageAge[2];
276 SK_U8 MaxAge[2];
277 SK_U8 HelloTime[2];
278 SK_U8 ForwardDelay[2];
279} SK_SPTREE_PACKET;
280
281/* global variables ***********************************************************/
282
283SK_MAC_ADDR SkRlmtMcAddr = {{0x01, 0x00, 0x5A, 0x52, 0x4C, 0x4D}};
284SK_MAC_ADDR BridgeMcAddr = {{0x01, 0x80, 0xC2, 0x00, 0x00, 0x00}};
285
286/* local variables ************************************************************/
287
288/* None. */
289
290/* functions ******************************************************************/
291
292RLMT_STATIC void SkRlmtCheckSwitch(
293 SK_AC *pAC,
294 SK_IOC IoC,
295 SK_U32 NetIdx);
296RLMT_STATIC void SkRlmtCheckSeg(
297 SK_AC *pAC,
298 SK_IOC IoC,
299 SK_U32 NetIdx);
300RLMT_STATIC void SkRlmtEvtSetNets(
301 SK_AC *pAC,
302 SK_IOC IoC,
303 SK_EVPARA Para);
304
305/******************************************************************************
306 *
307 * SkRlmtInit - initialize data, set state to init
308 *
309 * Description:
310 *
311 * SK_INIT_DATA
312 * ============
313 *
314 * This routine initializes all RLMT-related variables to a known state.
315 * The initial state is SK_RLMT_RS_INIT.
316 * All ports are initialized to SK_RLMT_PS_INIT.
317 *
318 *
319 * SK_INIT_IO
320 * ==========
321 *
322 * Nothing.
323 *
324 *
325 * SK_INIT_RUN
326 * ===========
327 *
328 * Determine the adapter's random value.
329 * Set the hw registers, the "logical MAC address", the
330 * RLMT multicast address, and eventually the BPDU multicast address.
331 *
332 * Context:
333 * init, pageable
334 *
335 * Returns:
336 * Nothing.
337 */
338void SkRlmtInit(
339SK_AC *pAC, /* Adapter Context */
340SK_IOC IoC, /* I/O Context */
341int Level) /* Initialization Level */
342{
343 SK_U32 i, j;
344 SK_U64 Random;
345 SK_EVPARA Para;
346 SK_MAC_ADDR VirtualMacAddress;
347 SK_MAC_ADDR PhysicalAMacAddress;
348 SK_BOOL VirtualMacAddressSet;
349 SK_BOOL PhysicalAMacAddressSet;
350
351 SK_DBG_MSG(pAC, SK_DBGMOD_RLMT, SK_DBGCAT_INIT,
352 ("RLMT Init level %d.\n", Level))
353
354 switch (Level) {
355 case SK_INIT_DATA: /* Initialize data structures. */
356 SK_MEMSET((char *)&pAC->Rlmt, 0, sizeof(SK_RLMT));
357
358 for (i = 0; i < SK_MAX_MACS; i++) {
359 pAC->Rlmt.Port[i].PortState = SK_RLMT_PS_INIT;
360 pAC->Rlmt.Port[i].LinkDown = SK_TRUE;
361 pAC->Rlmt.Port[i].PortDown = SK_TRUE;
362 pAC->Rlmt.Port[i].PortStarted = SK_FALSE;
363 pAC->Rlmt.Port[i].PortNoRx = SK_FALSE;
364 pAC->Rlmt.Port[i].RootIdSet = SK_FALSE;
365 pAC->Rlmt.Port[i].PortNumber = i;
366 pAC->Rlmt.Port[i].Net = &pAC->Rlmt.Net[0];
367 pAC->Rlmt.Port[i].AddrPort = &pAC->Addr.Port[i];
368 }
369
370 pAC->Rlmt.NumNets = 1;
371 for (i = 0; i < SK_MAX_NETS; i++) {
372 pAC->Rlmt.Net[i].RlmtState = SK_RLMT_RS_INIT;
373 pAC->Rlmt.Net[i].RootIdSet = SK_FALSE;
374 pAC->Rlmt.Net[i].PrefPort = SK_RLMT_DEF_PREF_PORT;
375 pAC->Rlmt.Net[i].Preference = 0xFFFFFFFF; /* Automatic. */
376 /* Just assuming. */
377 pAC->Rlmt.Net[i].ActivePort = pAC->Rlmt.Net[i].PrefPort;
378 pAC->Rlmt.Net[i].RlmtMode = SK_RLMT_DEF_MODE;
379 pAC->Rlmt.Net[i].TimeoutValue = SK_RLMT_DEF_TO_VAL;
380 pAC->Rlmt.Net[i].NetNumber = i;
381 }
382
383 pAC->Rlmt.Net[0].Port[0] = &pAC->Rlmt.Port[0];
384 pAC->Rlmt.Net[0].Port[1] = &pAC->Rlmt.Port[1];
385#if SK_MAX_NETS > 1
386 pAC->Rlmt.Net[1].Port[0] = &pAC->Rlmt.Port[1];
387#endif /* SK_MAX_NETS > 1 */
388 break;
389
390 case SK_INIT_IO: /* GIMacsFound first available here. */
391 SK_DBG_MSG(pAC, SK_DBGMOD_RLMT, SK_DBGCAT_INIT,
392 ("RLMT: %d MACs were detected.\n", pAC->GIni.GIMacsFound))
393
394 pAC->Rlmt.Net[0].NumPorts = pAC->GIni.GIMacsFound;
395
396 /* Initialize HW registers? */
397 if (pAC->GIni.GIMacsFound == 1) {
398 Para.Para32[0] = SK_RLMT_MODE_CLS;
399 Para.Para32[1] = 0;
400 (void)SkRlmtEvent(pAC, IoC, SK_RLMT_MODE_CHANGE, Para);
401 }
402 break;
403
404 case SK_INIT_RUN:
405 /* Ensure RLMT is set to one net. */
406 if (pAC->Rlmt.NumNets > 1) {
407 Para.Para32[0] = 1;
408 Para.Para32[1] = -1;
409 SkRlmtEvtSetNets(pAC, IoC, Para);
410 }
411
412 for (i = 0; i < (SK_U32)pAC->GIni.GIMacsFound; i++) {
413 Random = SkOsGetTime(pAC);
414 *(SK_U32*)&pAC->Rlmt.Port[i].Random = *(SK_U32*)&Random;
415
416 for (j = 0; j < 4; j++) {
417 pAC->Rlmt.Port[i].Random[j] ^= pAC->Rlmt.Port[i].AddrPort->
418 CurrentMacAddress.a[SK_MAC_ADDR_LEN - 1 - j];
419 }
420
421 (void)SkAddrMcClear(pAC, IoC, i, SK_ADDR_PERMANENT | SK_MC_SW_ONLY);
422
423 /* Add RLMT MC address. */
424 (void)SkAddrMcAdd(pAC, IoC, i, &SkRlmtMcAddr, SK_ADDR_PERMANENT);
425
426 if (pAC->Rlmt.Net[0].RlmtMode & SK_RLMT_CHECK_SEG) {
427 /* Add BPDU MC address. */
428 (void)SkAddrMcAdd(pAC, IoC, i, &BridgeMcAddr, SK_ADDR_PERMANENT);
429 }
430
431 (void)SkAddrMcUpdate(pAC, IoC, i);
432 }
433
434 VirtualMacAddressSet = SK_FALSE;
435 /* Read virtual MAC address from Control Register File. */
436 for (j = 0; j < SK_MAC_ADDR_LEN; j++) {
437
438 SK_IN8(IoC, B2_MAC_1 + j, &VirtualMacAddress.a[j]);
439 VirtualMacAddressSet |= VirtualMacAddress.a[j];
440 }
441
442 PhysicalAMacAddressSet = SK_FALSE;
443 /* Read physical MAC address for MAC A from Control Register File. */
444 for (j = 0; j < SK_MAC_ADDR_LEN; j++) {
445
446 SK_IN8(IoC, B2_MAC_2 + j, &PhysicalAMacAddress.a[j]);
447 PhysicalAMacAddressSet |= PhysicalAMacAddress.a[j];
448 }
449
450 /* check if the two mac addresses contain reasonable values */
451 if (!VirtualMacAddressSet || !PhysicalAMacAddressSet) {
452
453 pAC->Rlmt.RlmtOff = SK_TRUE;
454 }
455
456 /* if the two mac addresses are equal switch off the RLMT_PRE_LOOKAHEAD
457 and the RLMT_LOOKAHEAD macros */
458 else if (SK_ADDR_EQUAL(PhysicalAMacAddress.a, VirtualMacAddress.a)) {
459
460 pAC->Rlmt.RlmtOff = SK_TRUE;
461 }
462 else {
463 pAC->Rlmt.RlmtOff = SK_FALSE;
464 }
465 break;
466
467 default: /* error */
468 break;
469 }
470 return;
471} /* SkRlmtInit */
472
473
474/******************************************************************************
475 *
476 * SkRlmtBuildCheckChain - build the check chain
477 *
478 * Description:
479 * This routine builds the local check chain:
480 * - Each port that is up checks the next port.
481 * - The last port that is up checks the first port that is up.
482 *
483 * Notes:
484 * - Currently only local ports are considered when building the chain.
485 * - Currently the SuspectState is just reset;
486 * it would be better to save it ...
487 *
488 * Context:
489 * runtime, pageable?
490 *
491 * Returns:
492 * Nothing
493 */
494RLMT_STATIC void SkRlmtBuildCheckChain(
495SK_AC *pAC, /* Adapter Context */
496SK_U32 NetIdx) /* Net Number */
497{
498 SK_U32 i;
499 SK_U32 NumMacsUp;
500 SK_RLMT_PORT * FirstMacUp;
501 SK_RLMT_PORT * PrevMacUp;
502
503 FirstMacUp = NULL;
504 PrevMacUp = NULL;
505
506 if (!(pAC->Rlmt.Net[NetIdx].RlmtMode & SK_RLMT_CHECK_LOC_LINK)) {
507 for (i = 0; i < pAC->Rlmt.Net[i].NumPorts; i++) {
508 pAC->Rlmt.Net[NetIdx].Port[i]->PortsChecked = 0;
509 }
510 return; /* Done. */
511 }
512
513 SK_DBG_MSG(pAC, SK_DBGMOD_RLMT, SK_DBGCAT_CTRL,
514 ("SkRlmtBuildCheckChain.\n"))
515
516 NumMacsUp = 0;
517
518 for (i = 0; i < pAC->Rlmt.Net[NetIdx].NumPorts; i++) {
519 pAC->Rlmt.Net[NetIdx].Port[i]->PortsChecked = 0;
520 pAC->Rlmt.Net[NetIdx].Port[i]->PortsSuspect = 0;
521 pAC->Rlmt.Net[NetIdx].Port[i]->CheckingState &=
522 ~(SK_RLMT_PCS_RX | SK_RLMT_PCS_TX);
523
524 /*
525 * If more than two links are detected we should consider
526 * checking at least two other ports:
527 * 1. the next port that is not LinkDown and
528 * 2. the next port that is not PortDown.
529 */
530 if (!pAC->Rlmt.Net[NetIdx].Port[i]->LinkDown) {
531 if (NumMacsUp == 0) {
532 FirstMacUp = pAC->Rlmt.Net[NetIdx].Port[i];
533 }
534 else {
535 PrevMacUp->PortCheck[
536 pAC->Rlmt.Net[NetIdx].Port[i]->PortsChecked].CheckAddr =
537 pAC->Rlmt.Net[NetIdx].Port[i]->AddrPort->CurrentMacAddress;
538 PrevMacUp->PortCheck[
539 PrevMacUp->PortsChecked].SuspectTx = SK_FALSE;
540 PrevMacUp->PortsChecked++;
541 }
542 PrevMacUp = pAC->Rlmt.Net[NetIdx].Port[i];
543 NumMacsUp++;
544 }
545 }
546
547 if (NumMacsUp > 1) {
548 PrevMacUp->PortCheck[PrevMacUp->PortsChecked].CheckAddr =
549 FirstMacUp->AddrPort->CurrentMacAddress;
550 PrevMacUp->PortCheck[PrevMacUp->PortsChecked].SuspectTx =
551 SK_FALSE;
552 PrevMacUp->PortsChecked++;
553 }
554
555#ifdef DEBUG
556 for (i = 0; i < pAC->Rlmt.Net[NetIdx].NumPorts; i++) {
557 SK_DBG_MSG(pAC, SK_DBGMOD_RLMT, SK_DBGCAT_CTRL,
558 ("Port %d checks %d other ports: %2X.\n", i,
559 pAC->Rlmt.Net[NetIdx].Port[i]->PortsChecked,
560 pAC->Rlmt.Net[NetIdx].Port[i]->PortCheck[0].CheckAddr.a[5]))
561 }
562#endif /* DEBUG */
563
564 return;
565} /* SkRlmtBuildCheckChain */
566
567
568/******************************************************************************
569 *
570 * SkRlmtBuildPacket - build an RLMT packet
571 *
572 * Description:
573 * This routine sets up an RLMT packet.
574 *
575 * Context:
576 * runtime, pageable?
577 *
578 * Returns:
579 * NULL or pointer to RLMT mbuf
580 */
581RLMT_STATIC SK_MBUF *SkRlmtBuildPacket(
582SK_AC *pAC, /* Adapter Context */
583SK_IOC IoC, /* I/O Context */
584SK_U32 PortNumber, /* Sending port */
585SK_U16 PacketType, /* RLMT packet type */
586SK_MAC_ADDR *SrcAddr, /* Source address */
587SK_MAC_ADDR *DestAddr) /* Destination address */
588{
589 int i;
590 SK_U16 Length;
591 SK_MBUF *pMb;
592 SK_RLMT_PACKET *pPacket;
593
594#ifdef DEBUG
595 SK_U8 CheckSrc = 0;
596 SK_U8 CheckDest = 0;
597
598 for (i = 0; i < SK_MAC_ADDR_LEN; ++i) {
599 CheckSrc |= SrcAddr->a[i];
600 CheckDest |= DestAddr->a[i];
601 }
602
603 if ((CheckSrc == 0) || (CheckDest == 0)) {
604 SK_DBG_MSG(pAC, SK_DBGMOD_RLMT, SK_DBGCAT_ERR,
605 ("SkRlmtBuildPacket: Invalid %s%saddr.\n",
606 (CheckSrc == 0 ? "Src" : ""), (CheckDest == 0 ? "Dest" : "")))
607 }
608#endif
609
610 if ((pMb = SkDrvAllocRlmtMbuf(pAC, IoC, SK_RLMT_MAX_PACKET_SIZE)) != NULL) {
611 pPacket = (SK_RLMT_PACKET*)pMb->pData;
612 for (i = 0; i < SK_MAC_ADDR_LEN; i++) {
613 pPacket->DstAddr[i] = DestAddr->a[i];
614 pPacket->SrcAddr[i] = SrcAddr->a[i];
615 }
616 pPacket->DSap = SK_RLMT_DSAP;
617 pPacket->SSap = SK_RLMT_SSAP;
618 pPacket->Ctrl = SK_RLMT_CTRL;
619 pPacket->Indicator[0] = SK_RLMT_INDICATOR0;
620 pPacket->Indicator[1] = SK_RLMT_INDICATOR1;
621 pPacket->Indicator[2] = SK_RLMT_INDICATOR2;
622 pPacket->Indicator[3] = SK_RLMT_INDICATOR3;
623 pPacket->Indicator[4] = SK_RLMT_INDICATOR4;
624 pPacket->Indicator[5] = SK_RLMT_INDICATOR5;
625 pPacket->Indicator[6] = SK_RLMT_INDICATOR6;
626
627 SK_U16_TO_NETWORK_ORDER(PacketType, &pPacket->RlmtPacketType[0]);
628
629 for (i = 0; i < 4; i++) {
630 pPacket->Random[i] = pAC->Rlmt.Port[PortNumber].Random[i];
631 }
632
633 SK_U16_TO_NETWORK_ORDER(
634 SK_RLMT_PACKET_VERSION, &pPacket->RlmtPacketVersion[0]);
635
636 for (i = 0; i < SK_PACKET_DATA_LEN; i++) {
637 pPacket->Data[i] = 0x00;
638 }
639
640 Length = SK_RLMT_MAX_PACKET_SIZE; /* Or smaller. */
641 pMb->Length = Length;
642 pMb->PortIdx = PortNumber;
643 Length -= 14;
644 SK_U16_TO_NETWORK_ORDER(Length, &pPacket->TypeLen[0]);
645
646 if (PacketType == SK_PACKET_ALIVE) {
647 pAC->Rlmt.Port[PortNumber].TxHelloCts++;
648 }
649 }
650
651 return (pMb);
652} /* SkRlmtBuildPacket */
653
654
655/******************************************************************************
656 *
657 * SkRlmtBuildSpanningTreePacket - build spanning tree check packet
658 *
659 * Description:
660 * This routine sets up a BPDU packet for spanning tree check.
661 *
662 * Context:
663 * runtime, pageable?
664 *
665 * Returns:
666 * NULL or pointer to RLMT mbuf
667 */
668RLMT_STATIC SK_MBUF *SkRlmtBuildSpanningTreePacket(
669SK_AC *pAC, /* Adapter Context */
670SK_IOC IoC, /* I/O Context */
671SK_U32 PortNumber) /* Sending port */
672{
673 unsigned i;
674 SK_U16 Length;
675 SK_MBUF *pMb;
676 SK_SPTREE_PACKET *pSPacket;
677
678 if ((pMb = SkDrvAllocRlmtMbuf(pAC, IoC, SK_RLMT_MAX_PACKET_SIZE)) !=
679 NULL) {
680 pSPacket = (SK_SPTREE_PACKET*)pMb->pData;
681 for (i = 0; i < SK_MAC_ADDR_LEN; i++) {
682 pSPacket->DstAddr[i] = BridgeMcAddr.a[i];
683 pSPacket->SrcAddr[i] =
684 pAC->Addr.Port[PortNumber].CurrentMacAddress.a[i];
685 }
686 pSPacket->DSap = SK_RLMT_SPT_DSAP;
687 pSPacket->SSap = SK_RLMT_SPT_SSAP;
688 pSPacket->Ctrl = SK_RLMT_SPT_CTRL;
689
690 pSPacket->ProtocolId[0] = SK_RLMT_SPT_PROTOCOL_ID0;
691 pSPacket->ProtocolId[1] = SK_RLMT_SPT_PROTOCOL_ID1;
692 pSPacket->ProtocolVersionId = SK_RLMT_SPT_PROTOCOL_VERSION_ID;
693 pSPacket->BpduType = SK_RLMT_SPT_BPDU_TYPE;
694 pSPacket->Flags = SK_RLMT_SPT_FLAGS;
695 pSPacket->RootId[0] = SK_RLMT_SPT_ROOT_ID0;
696 pSPacket->RootId[1] = SK_RLMT_SPT_ROOT_ID1;
697 pSPacket->RootPathCost[0] = SK_RLMT_SPT_ROOT_PATH_COST0;
698 pSPacket->RootPathCost[1] = SK_RLMT_SPT_ROOT_PATH_COST1;
699 pSPacket->RootPathCost[2] = SK_RLMT_SPT_ROOT_PATH_COST2;
700 pSPacket->RootPathCost[3] = SK_RLMT_SPT_ROOT_PATH_COST3;
701 pSPacket->BridgeId[0] = SK_RLMT_SPT_BRIDGE_ID0;
702 pSPacket->BridgeId[1] = SK_RLMT_SPT_BRIDGE_ID1;
703
704 /*
705 * Use logical MAC address as bridge ID and filter these packets
706 * on receive.
707 */
708 for (i = 0; i < SK_MAC_ADDR_LEN; i++) {
709 pSPacket->BridgeId[i + 2] = pSPacket->RootId[i + 2] =
710 pAC->Addr.Net[pAC->Rlmt.Port[PortNumber].Net->NetNumber].
711 CurrentMacAddress.a[i];
712 }
713 pSPacket->PortId[0] = SK_RLMT_SPT_PORT_ID0;
714 pSPacket->PortId[1] = SK_RLMT_SPT_PORT_ID1;
715 pSPacket->MessageAge[0] = SK_RLMT_SPT_MSG_AGE0;
716 pSPacket->MessageAge[1] = SK_RLMT_SPT_MSG_AGE1;
717 pSPacket->MaxAge[0] = SK_RLMT_SPT_MAX_AGE0;
718 pSPacket->MaxAge[1] = SK_RLMT_SPT_MAX_AGE1;
719 pSPacket->HelloTime[0] = SK_RLMT_SPT_HELLO_TIME0;
720 pSPacket->HelloTime[1] = SK_RLMT_SPT_HELLO_TIME1;
721 pSPacket->ForwardDelay[0] = SK_RLMT_SPT_FWD_DELAY0;
722 pSPacket->ForwardDelay[1] = SK_RLMT_SPT_FWD_DELAY1;
723
724 Length = SK_RLMT_MAX_PACKET_SIZE; /* Or smaller. */
725 pMb->Length = Length;
726 pMb->PortIdx = PortNumber;
727 Length -= 14;
728 SK_U16_TO_NETWORK_ORDER(Length, &pSPacket->TypeLen[0]);
729
730 pAC->Rlmt.Port[PortNumber].TxSpHelloReqCts++;
731 }
732
733 return (pMb);
734} /* SkRlmtBuildSpanningTreePacket */
735
736
737/******************************************************************************
738 *
739 * SkRlmtSend - build and send check packets
740 *
741 * Description:
742 * Depending on the RLMT state and the checking state, several packets
743 * are sent through the indicated port.
744 *
745 * Context:
746 * runtime, pageable?
747 *
748 * Returns:
749 * Nothing.
750 */
751RLMT_STATIC void SkRlmtSend(
752SK_AC *pAC, /* Adapter Context */
753SK_IOC IoC, /* I/O Context */
754SK_U32 PortNumber) /* Sending port */
755{
756 unsigned j;
757 SK_EVPARA Para;
758 SK_RLMT_PORT *pRPort;
759
760 pRPort = &pAC->Rlmt.Port[PortNumber];
761 if (pAC->Rlmt.Port[PortNumber].Net->RlmtMode & SK_RLMT_CHECK_LOC_LINK) {
762 if (pRPort->CheckingState & (SK_RLMT_PCS_TX | SK_RLMT_PCS_RX)) {
763 /* Port is suspicious. Send the RLMT packet to the RLMT mc addr. */
764 if ((Para.pParaPtr = SkRlmtBuildPacket(pAC, IoC, PortNumber,
765 SK_PACKET_ALIVE, &pAC->Addr.Port[PortNumber].CurrentMacAddress,
766 &SkRlmtMcAddr)) != NULL) {
767 SkEventQueue(pAC, SKGE_DRV, SK_DRV_RLMT_SEND, Para);
768 }
769 }
770 else {
771 /*
772 * Send a directed RLMT packet to all ports that are
773 * checked by the indicated port.
774 */
775 for (j = 0; j < pRPort->PortsChecked; j++) {
776 if ((Para.pParaPtr = SkRlmtBuildPacket(pAC, IoC, PortNumber,
777 SK_PACKET_ALIVE, &pAC->Addr.Port[PortNumber].CurrentMacAddress,
778 &pRPort->PortCheck[j].CheckAddr)) != NULL) {
779 SkEventQueue(pAC, SKGE_DRV, SK_DRV_RLMT_SEND, Para);
780 }
781 }
782 }
783 }
784
785 if ((pAC->Rlmt.Port[PortNumber].Net->RlmtMode & SK_RLMT_CHECK_SEG) &&
786 (pAC->Rlmt.Port[PortNumber].Net->CheckingState & SK_RLMT_RCS_SEND_SEG)) {
787 /*
788 * Send a BPDU packet to make a connected switch tell us
789 * the correct root bridge.
790 */
791 if ((Para.pParaPtr =
792 SkRlmtBuildSpanningTreePacket(pAC, IoC, PortNumber)) != NULL) {
793 pAC->Rlmt.Port[PortNumber].Net->CheckingState &= ~SK_RLMT_RCS_SEND_SEG;
794 pRPort->RootIdSet = SK_FALSE;
795
796 SkEventQueue(pAC, SKGE_DRV, SK_DRV_RLMT_SEND, Para);
797 SK_DBG_MSG(pAC, SK_DBGMOD_RLMT, SK_DBGCAT_TX,
798 ("SkRlmtSend: BPDU Packet on Port %u.\n", PortNumber))
799 }
800 }
801 return;
802} /* SkRlmtSend */
803
804
805/******************************************************************************
806 *
807 * SkRlmtPortReceives - check if port is (going) down and bring it up
808 *
809 * Description:
810 * This routine checks if a port who received a non-BPDU packet
811 * needs to go up or needs to be stopped going down.
812 *
813 * Context:
814 * runtime, pageable?
815 *
816 * Returns:
817 * Nothing.
818 */
819RLMT_STATIC void SkRlmtPortReceives(
820SK_AC *pAC, /* Adapter Context */
821SK_IOC IoC, /* I/O Context */
822SK_U32 PortNumber) /* Port to check */
823{
824 SK_RLMT_PORT *pRPort;
825 SK_EVPARA Para;
826
827 pRPort = &pAC->Rlmt.Port[PortNumber];
828 pRPort->PortNoRx = SK_FALSE;
829
830 if ((pRPort->PortState == SK_RLMT_PS_DOWN) &&
831 !(pRPort->CheckingState & SK_RLMT_PCS_TX)) {
832 /*
833 * Port is marked down (rx), but received a non-BPDU packet.
834 * Bring it up.
835 */
836 SK_DBG_MSG(pAC, SK_DBGMOD_RLMT, SK_DBGCAT_RX,
837 ("SkRlmtPacketReceive: Received on PortDown.\n"))
838
839 pRPort->PortState = SK_RLMT_PS_GOING_UP;
840 pRPort->GuTimeStamp = SkOsGetTime(pAC);
841 Para.Para32[0] = PortNumber;
842 Para.Para32[1] = (SK_U32)-1;
843 SkTimerStart(pAC, IoC, &pRPort->UpTimer, SK_RLMT_PORTUP_TIM_VAL,
844 SKGE_RLMT, SK_RLMT_PORTUP_TIM, Para);
845 pRPort->CheckingState &= ~SK_RLMT_PCS_RX;
846 /* pAC->Rlmt.CheckSwitch = SK_TRUE; */
847 SkRlmtCheckSwitch(pAC, IoC, pRPort->Net->NetNumber);
848 } /* PortDown && !SuspectTx */
849 else if (pRPort->CheckingState & SK_RLMT_PCS_RX) {
850 SK_DBG_MSG(pAC, SK_DBGMOD_RLMT, SK_DBGCAT_RX,
851 ("SkRlmtPacketReceive: Stop bringing port down.\n"))
852 SkTimerStop(pAC, IoC, &pRPort->DownRxTimer);
853 pRPort->CheckingState &= ~SK_RLMT_PCS_RX;
854 /* pAC->Rlmt.CheckSwitch = SK_TRUE; */
855 SkRlmtCheckSwitch(pAC, IoC, pRPort->Net->NetNumber);
856 } /* PortGoingDown */
857
858 return;
859} /* SkRlmtPortReceives */
860
861
862/******************************************************************************
863 *
864 * SkRlmtPacketReceive - receive a packet for closer examination
865 *
866 * Description:
867 * This routine examines a packet more closely than SK_RLMT_LOOKAHEAD.
868 *
869 * Context:
870 * runtime, pageable?
871 *
872 * Returns:
873 * Nothing.
874 */
875RLMT_STATIC void SkRlmtPacketReceive(
876SK_AC *pAC, /* Adapter Context */
877SK_IOC IoC, /* I/O Context */
878SK_MBUF *pMb) /* Received packet */
879{
880#ifdef xDEBUG
881 extern void DumpData(char *p, int size);
882#endif /* DEBUG */
883 int i;
884 unsigned j;
885 SK_U16 PacketType;
886 SK_U32 PortNumber;
887 SK_ADDR_PORT *pAPort;
888 SK_RLMT_PORT *pRPort;
889 SK_RLMT_PACKET *pRPacket;
890 SK_SPTREE_PACKET *pSPacket;
891 SK_EVPARA Para;
892
893 PortNumber = pMb->PortIdx;
894 pAPort = &pAC->Addr.Port[PortNumber];
895 pRPort = &pAC->Rlmt.Port[PortNumber];
896
897 SK_DBG_MSG(pAC, SK_DBGMOD_RLMT, SK_DBGCAT_RX,
898 ("SkRlmtPacketReceive: PortNumber == %d.\n", PortNumber))
899
900 pRPacket = (SK_RLMT_PACKET*)pMb->pData;
901 pSPacket = (SK_SPTREE_PACKET*)pRPacket;
902
903#ifdef xDEBUG
904 DumpData((char *)pRPacket, 32);
905#endif /* DEBUG */
906
907 if ((pRPort->PacketsPerTimeSlot - pRPort->BpduPacketsPerTimeSlot) != 0) {
908 SkRlmtPortReceives(pAC, IoC, PortNumber);
909 }
910
911 /* Check destination address. */
912
913 if (!SK_ADDR_EQUAL(pAPort->CurrentMacAddress.a, pRPacket->DstAddr) &&
914 !SK_ADDR_EQUAL(SkRlmtMcAddr.a, pRPacket->DstAddr) &&
915 !SK_ADDR_EQUAL(BridgeMcAddr.a, pRPacket->DstAddr)) {
916
917 /* Not sent to current MAC or registered MC address => Trash it. */
918 SK_DBG_MSG(pAC, SK_DBGMOD_RLMT, SK_DBGCAT_RX,
919 ("SkRlmtPacketReceive: Not for me.\n"))
920
921 SkDrvFreeRlmtMbuf(pAC, IoC, pMb);
922 return;
923 }
924 else if (SK_ADDR_EQUAL(pAPort->CurrentMacAddress.a, pRPacket->SrcAddr)) {
925
926 /*
927 * Was sent by same port (may happen during port switching
928 * or in case of duplicate MAC addresses).
929 */
930
931 /*
932 * Check for duplicate address here:
933 * If Packet.Random != My.Random => DupAddr.
934 */
935 for (i = 3; i >= 0; i--) {
936 if (pRPort->Random[i] != pRPacket->Random[i]) {
937 break;
938 }
939 }
940
941 /*
942 * CAUTION: Do not check for duplicate MAC address in RLMT Alive Reply
943 * packets (they have the LLC_COMMAND_RESPONSE_BIT set in
944 * pRPacket->SSap).
945 */
946 if (i >= 0 && pRPacket->DSap == SK_RLMT_DSAP &&
947 pRPacket->Ctrl == SK_RLMT_CTRL &&
948 pRPacket->SSap == SK_RLMT_SSAP &&
949 pRPacket->Indicator[0] == SK_RLMT_INDICATOR0 &&
950 pRPacket->Indicator[1] == SK_RLMT_INDICATOR1 &&
951 pRPacket->Indicator[2] == SK_RLMT_INDICATOR2 &&
952 pRPacket->Indicator[3] == SK_RLMT_INDICATOR3 &&
953 pRPacket->Indicator[4] == SK_RLMT_INDICATOR4 &&
954 pRPacket->Indicator[5] == SK_RLMT_INDICATOR5 &&
955 pRPacket->Indicator[6] == SK_RLMT_INDICATOR6) {
956 SK_DBG_MSG(pAC, SK_DBGMOD_RLMT, SK_DBGCAT_RX,
957 ("SkRlmtPacketReceive: Duplicate MAC Address.\n"))
958
959 /* Error Log entry. */
960 SK_ERR_LOG(pAC, SK_ERRCL_COMM, SKERR_RLMT_E006, SKERR_RLMT_E006_MSG);
961 }
962 else {
963 /* Simply trash it. */
964 SK_DBG_MSG(pAC, SK_DBGMOD_RLMT, SK_DBGCAT_RX,
965 ("SkRlmtPacketReceive: Sent by me.\n"))
966 }
967
968 SkDrvFreeRlmtMbuf(pAC, IoC, pMb);
969 return;
970 }
971
972 /* Check SuspectTx entries. */
973 if (pRPort->PortsSuspect > 0) {
974 for (j = 0; j < pRPort->PortsChecked; j++) {
975 if (pRPort->PortCheck[j].SuspectTx &&
976 SK_ADDR_EQUAL(
977 pRPacket->SrcAddr, pRPort->PortCheck[j].CheckAddr.a)) {
978 pRPort->PortCheck[j].SuspectTx = SK_FALSE;
979 pRPort->PortsSuspect--;
980 break;
981 }
982 }
983 }
984
985 /* Determine type of packet. */
986 if (pRPacket->DSap == SK_RLMT_DSAP &&
987 pRPacket->Ctrl == SK_RLMT_CTRL &&
988 (pRPacket->SSap & ~LLC_COMMAND_RESPONSE_BIT) == SK_RLMT_SSAP &&
989 pRPacket->Indicator[0] == SK_RLMT_INDICATOR0 &&
990 pRPacket->Indicator[1] == SK_RLMT_INDICATOR1 &&
991 pRPacket->Indicator[2] == SK_RLMT_INDICATOR2 &&
992 pRPacket->Indicator[3] == SK_RLMT_INDICATOR3 &&
993 pRPacket->Indicator[4] == SK_RLMT_INDICATOR4 &&
994 pRPacket->Indicator[5] == SK_RLMT_INDICATOR5 &&
995 pRPacket->Indicator[6] == SK_RLMT_INDICATOR6) {
996
997 /* It's an RLMT packet. */
998 PacketType = (SK_U16)((pRPacket->RlmtPacketType[0] << 8) |
999 pRPacket->RlmtPacketType[1]);
1000
1001 switch (PacketType) {
1002 case SK_PACKET_ANNOUNCE: /* Not yet used. */
1003#if 0
1004 /* Build the check chain. */
1005 SkRlmtBuildCheckChain(pAC);
1006#endif /* 0 */
1007
1008 SK_DBG_MSG(pAC, SK_DBGMOD_RLMT, SK_DBGCAT_RX,
1009 ("SkRlmtPacketReceive: Announce.\n"))
1010
1011 SkDrvFreeRlmtMbuf(pAC, IoC, pMb);
1012 break;
1013
1014 case SK_PACKET_ALIVE:
1015 if (pRPacket->SSap & LLC_COMMAND_RESPONSE_BIT) {
1016 SK_DBG_MSG(pAC, SK_DBGMOD_RLMT, SK_DBGCAT_RX,
1017 ("SkRlmtPacketReceive: Alive Reply.\n"))
1018
1019 if (!(pAC->Addr.Port[PortNumber].PromMode & SK_PROM_MODE_LLC) ||
1020 SK_ADDR_EQUAL(
1021 pRPacket->DstAddr, pAPort->CurrentMacAddress.a)) {
1022 /* Obviously we could send something. */
1023 if (pRPort->CheckingState & SK_RLMT_PCS_TX) {
1024 pRPort->CheckingState &= ~SK_RLMT_PCS_TX;
1025 SkTimerStop(pAC, IoC, &pRPort->DownTxTimer);
1026 }
1027
1028 if ((pRPort->PortState == SK_RLMT_PS_DOWN) &&
1029 !(pRPort->CheckingState & SK_RLMT_PCS_RX)) {
1030 pRPort->PortState = SK_RLMT_PS_GOING_UP;
1031 pRPort->GuTimeStamp = SkOsGetTime(pAC);
1032
1033 SkTimerStop(pAC, IoC, &pRPort->DownTxTimer);
1034
1035 Para.Para32[0] = PortNumber;
1036 Para.Para32[1] = (SK_U32)-1;
1037 SkTimerStart(pAC, IoC, &pRPort->UpTimer,
1038 SK_RLMT_PORTUP_TIM_VAL, SKGE_RLMT,
1039 SK_RLMT_PORTUP_TIM, Para);
1040 }
1041 }
1042
1043 /* Mark sending port as alive? */
1044 SkDrvFreeRlmtMbuf(pAC, IoC, pMb);
1045 }
1046 else { /* Alive Request Packet. */
1047 SK_DBG_MSG(pAC, SK_DBGMOD_RLMT, SK_DBGCAT_RX,
1048 ("SkRlmtPacketReceive: Alive Request.\n"))
1049
1050 pRPort->RxHelloCts++;
1051
1052 /* Answer. */
1053 for (i = 0; i < SK_MAC_ADDR_LEN; i++) {
1054 pRPacket->DstAddr[i] = pRPacket->SrcAddr[i];
1055 pRPacket->SrcAddr[i] =
1056 pAC->Addr.Port[PortNumber].CurrentMacAddress.a[i];
1057 }
1058 pRPacket->SSap |= LLC_COMMAND_RESPONSE_BIT;
1059
1060 Para.pParaPtr = pMb;
1061 SkEventQueue(pAC, SKGE_DRV, SK_DRV_RLMT_SEND, Para);
1062 }
1063 break;
1064
1065 case SK_PACKET_CHECK_TX:
1066 SK_DBG_MSG(pAC, SK_DBGMOD_RLMT, SK_DBGCAT_RX,
1067 ("SkRlmtPacketReceive: Check your tx line.\n"))
1068
1069 /* A port checking us requests us to check our tx line. */
1070 pRPort->CheckingState |= SK_RLMT_PCS_TX;
1071
1072 /* Start PortDownTx timer. */
1073 Para.Para32[0] = PortNumber;
1074 Para.Para32[1] = (SK_U32)-1;
1075 SkTimerStart(pAC, IoC, &pRPort->DownTxTimer,
1076 SK_RLMT_PORTDOWN_TIM_VAL, SKGE_RLMT,
1077 SK_RLMT_PORTDOWN_TX_TIM, Para);
1078
1079 SkDrvFreeRlmtMbuf(pAC, IoC, pMb);
1080
1081 if ((Para.pParaPtr = SkRlmtBuildPacket(pAC, IoC, PortNumber,
1082 SK_PACKET_ALIVE, &pAC->Addr.Port[PortNumber].CurrentMacAddress,
1083 &SkRlmtMcAddr)) != NULL) {
1084 SkEventQueue(pAC, SKGE_DRV, SK_DRV_RLMT_SEND, Para);
1085 }
1086 break;
1087
1088 case SK_PACKET_ADDR_CHANGED:
1089 SK_DBG_MSG(pAC, SK_DBGMOD_RLMT, SK_DBGCAT_RX,
1090 ("SkRlmtPacketReceive: Address Change.\n"))
1091
1092 /* Build the check chain. */
1093 SkRlmtBuildCheckChain(pAC, pRPort->Net->NetNumber);
1094 SkDrvFreeRlmtMbuf(pAC, IoC, pMb);
1095 break;
1096
1097 default:
1098 SK_DBG_MSG(pAC, SK_DBGMOD_RLMT, SK_DBGCAT_RX,
1099 ("SkRlmtPacketReceive: Unknown RLMT packet.\n"))
1100
1101 /* RA;:;: ??? */
1102 SkDrvFreeRlmtMbuf(pAC, IoC, pMb);
1103 }
1104 }
1105 else if (pSPacket->DSap == SK_RLMT_SPT_DSAP &&
1106 pSPacket->Ctrl == SK_RLMT_SPT_CTRL &&
1107 (pSPacket->SSap & ~LLC_COMMAND_RESPONSE_BIT) == SK_RLMT_SPT_SSAP) {
1108 SK_DBG_MSG(pAC, SK_DBGMOD_RLMT, SK_DBGCAT_RX,
1109 ("SkRlmtPacketReceive: BPDU Packet.\n"))
1110
1111 /* Spanning Tree packet. */
1112 pRPort->RxSpHelloCts++;
1113
1114 if (!SK_ADDR_EQUAL(&pSPacket->RootId[2], &pAC->Addr.Net[pAC->Rlmt.
1115 Port[PortNumber].Net->NetNumber].CurrentMacAddress.a[0])) {
1116 /*
1117 * Check segmentation if a new root bridge is set and
1118 * the segmentation check is not currently running.
1119 */
1120 if (!SK_ADDR_EQUAL(&pSPacket->RootId[2], &pRPort->Root.Id[2]) &&
1121 (pAC->Rlmt.Port[PortNumber].Net->LinksUp > 1) &&
1122 (pAC->Rlmt.Port[PortNumber].Net->RlmtMode & SK_RLMT_CHECK_SEG)
1123 != 0 && (pAC->Rlmt.Port[PortNumber].Net->CheckingState &
1124 SK_RLMT_RCS_SEG) == 0) {
1125 pAC->Rlmt.Port[PortNumber].Net->CheckingState |=
1126 SK_RLMT_RCS_START_SEG | SK_RLMT_RCS_SEND_SEG;
1127 }
1128
1129 /* Store tree view of this port. */
1130 for (i = 0; i < 8; i++) {
1131 pRPort->Root.Id[i] = pSPacket->RootId[i];
1132 }
1133 pRPort->RootIdSet = SK_TRUE;
1134
1135 SK_DBG_MSG(pAC, SK_DBGMOD_RLMT, SK_DBGCAT_DUMP,
1136 ("Root ID %d: %02x %02x %02x %02x %02x %02x %02x %02x.\n",
1137 PortNumber,
1138 pRPort->Root.Id[0], pRPort->Root.Id[1],
1139 pRPort->Root.Id[2], pRPort->Root.Id[3],
1140 pRPort->Root.Id[4], pRPort->Root.Id[5],
1141 pRPort->Root.Id[6], pRPort->Root.Id[7]))
1142 }
1143
1144 SkDrvFreeRlmtMbuf(pAC, IoC, pMb);
1145 if ((pAC->Rlmt.Port[PortNumber].Net->CheckingState &
1146 SK_RLMT_RCS_REPORT_SEG) != 0) {
1147 SkRlmtCheckSeg(pAC, IoC, pAC->Rlmt.Port[PortNumber].Net->NetNumber);
1148 }
1149 }
1150 else {
1151 SK_DBG_MSG(pAC, SK_DBGMOD_RLMT, SK_DBGCAT_RX,
1152 ("SkRlmtPacketReceive: Unknown Packet Type.\n"))
1153
1154 /* Unknown packet. */
1155 SkDrvFreeRlmtMbuf(pAC, IoC, pMb);
1156 }
1157 return;
1158} /* SkRlmtPacketReceive */
1159
1160
1161/******************************************************************************
1162 *
1163 * SkRlmtCheckPort - check if a port works
1164 *
1165 * Description:
1166 * This routine checks if a port whose link is up received something
1167 * and if it seems to transmit successfully.
1168 *
1169 * # PortState: PsInit, PsLinkDown, PsDown, PsGoingUp, PsUp
1170 * # PortCheckingState (Bitfield): ChkTx, ChkRx, ChkSeg
1171 * # RlmtCheckingState (Bitfield): ChkSeg, StartChkSeg, ReportSeg
1172 *
1173 * if (Rx - RxBpdu == 0) { # No rx.
1174 * if (state == PsUp) {
1175 * PortCheckingState |= ChkRx
1176 * }
1177 * if (ModeCheckSeg && (Timeout ==
1178 * TO_SHORTEN(RLMT_DEFAULT_TIMEOUT))) {
1179 * RlmtCheckingState |= ChkSeg)
1180 * PortCheckingState |= ChkSeg
1181 * }
1182 * NewTimeout = TO_SHORTEN(Timeout)
1183 * if (NewTimeout < RLMT_MIN_TIMEOUT) {
1184 * NewTimeout = RLMT_MIN_TIMEOUT
1185 * PortState = PsDown
1186 * ...
1187 * }
1188 * }
1189 * else { # something was received
1190 * # Set counter to 0 at LinkDown?
1191 * # No - rx may be reported after LinkDown ???
1192 * PortCheckingState &= ~ChkRx
1193 * NewTimeout = RLMT_DEFAULT_TIMEOUT
1194 * if (RxAck == 0) {
1195 * possible reasons:
1196 * is my tx line bad? --
1197 * send RLMT multicast and report
1198 * back internally? (only possible
1199 * between ports on same adapter)
1200 * }
1201 * if (RxChk == 0) {
1202 * possible reasons:
1203 * - tx line of port set to check me
1204 * maybe bad
1205 * - no other port/adapter available or set
1206 * to check me
1207 * - adapter checking me has a longer
1208 * timeout
1209 * ??? anything that can be done here?
1210 * }
1211 * }
1212 *
1213 * Context:
1214 * runtime, pageable?
1215 *
1216 * Returns:
1217 * New timeout value.
1218 */
1219RLMT_STATIC SK_U32 SkRlmtCheckPort(
1220SK_AC *pAC, /* Adapter Context */
1221SK_IOC IoC, /* I/O Context */
1222SK_U32 PortNumber) /* Port to check */
1223{
1224 unsigned i;
1225 SK_U32 NewTimeout;
1226 SK_RLMT_PORT *pRPort;
1227 SK_EVPARA Para;
1228
1229 pRPort = &pAC->Rlmt.Port[PortNumber];
1230
1231 if ((pRPort->PacketsPerTimeSlot - pRPort->BpduPacketsPerTimeSlot) == 0) {
1232 SK_DBG_MSG(pAC, SK_DBGMOD_RLMT, SK_DBGCAT_CTRL,
1233 ("SkRlmtCheckPort %d: No (%d) receives in last time slot.\n",
1234 PortNumber, pRPort->PacketsPerTimeSlot))
1235
1236 /*
1237 * Check segmentation if there was no receive at least twice
1238 * in a row (PortNoRx is already set) and the segmentation
1239 * check is not currently running.
1240 */
1241
1242 if (pRPort->PortNoRx && (pAC->Rlmt.Port[PortNumber].Net->LinksUp > 1) &&
1243 (pAC->Rlmt.Port[PortNumber].Net->RlmtMode & SK_RLMT_CHECK_SEG) &&
1244 !(pAC->Rlmt.Port[PortNumber].Net->CheckingState & SK_RLMT_RCS_SEG)) {
1245 pAC->Rlmt.Port[PortNumber].Net->CheckingState |=
1246 SK_RLMT_RCS_START_SEG | SK_RLMT_RCS_SEND_SEG;
1247 }
1248
1249 SK_DBG_MSG(pAC, SK_DBGMOD_RLMT, SK_DBGCAT_CTRL,
1250 ("SkRlmtCheckPort: PortsSuspect %d, PcsRx %d.\n",
1251 pRPort->PortsSuspect, pRPort->CheckingState & SK_RLMT_PCS_RX))
1252
1253 if (pRPort->PortState != SK_RLMT_PS_DOWN) {
1254 NewTimeout = TO_SHORTEN(pAC->Rlmt.Port[PortNumber].Net->TimeoutValue);
1255 if (NewTimeout < SK_RLMT_MIN_TO_VAL) {
1256 NewTimeout = SK_RLMT_MIN_TO_VAL;
1257 }
1258
1259 if (!(pRPort->CheckingState & SK_RLMT_PCS_RX)) {
1260 Para.Para32[0] = PortNumber;
1261 pRPort->CheckingState |= SK_RLMT_PCS_RX;
1262
1263 /*
1264 * What shall we do if the port checked by this one receives
1265 * our request frames? What's bad - our rx line or his tx line?
1266 */
1267 Para.Para32[1] = (SK_U32)-1;
1268 SkTimerStart(pAC, IoC, &pRPort->DownRxTimer,
1269 SK_RLMT_PORTDOWN_TIM_VAL, SKGE_RLMT,
1270 SK_RLMT_PORTDOWN_RX_TIM, Para);
1271
1272 for (i = 0; i < pRPort->PortsChecked; i++) {
1273 if (pRPort->PortCheck[i].SuspectTx) {
1274 continue;
1275 }
1276 pRPort->PortCheck[i].SuspectTx = SK_TRUE;
1277 pRPort->PortsSuspect++;
1278 if ((Para.pParaPtr =
1279 SkRlmtBuildPacket(pAC, IoC, PortNumber, SK_PACKET_CHECK_TX,
1280 &pAC->Addr.Port[PortNumber].CurrentMacAddress,
1281 &pRPort->PortCheck[i].CheckAddr)) != NULL) {
1282 SkEventQueue(pAC, SKGE_DRV, SK_DRV_RLMT_SEND, Para);
1283 }
1284 }
1285 }
1286 }
1287 else { /* PortDown -- or all partners suspect. */
1288 NewTimeout = SK_RLMT_DEF_TO_VAL;
1289 }
1290 pRPort->PortNoRx = SK_TRUE;
1291 }
1292 else { /* A non-BPDU packet was received. */
1293 SK_DBG_MSG(pAC, SK_DBGMOD_RLMT, SK_DBGCAT_CTRL,
1294 ("SkRlmtCheckPort %d: %d (%d) receives in last time slot.\n",
1295 PortNumber,
1296 pRPort->PacketsPerTimeSlot - pRPort->BpduPacketsPerTimeSlot,
1297 pRPort->PacketsPerTimeSlot))
1298
1299 SkRlmtPortReceives(pAC, IoC, PortNumber);
1300 if (pAC->Rlmt.CheckSwitch) {
1301 SkRlmtCheckSwitch(pAC, IoC, pRPort->Net->NetNumber);
1302 }
1303
1304 NewTimeout = SK_RLMT_DEF_TO_VAL;
1305 }
1306
1307 return (NewTimeout);
1308} /* SkRlmtCheckPort */
1309
1310
1311/******************************************************************************
1312 *
1313 * SkRlmtSelectBcRx - select new active port, criteria 1 (CLP)
1314 *
1315 * Description:
1316 * This routine selects the port that received a broadcast frame
1317 * substantially later than all other ports.
1318 *
1319 * Context:
1320 * runtime, pageable?
1321 *
1322 * Returns:
1323 * SK_BOOL
1324 */
1325RLMT_STATIC SK_BOOL SkRlmtSelectBcRx(
1326SK_AC *pAC, /* Adapter Context */
1327SK_IOC IoC, /* I/O Context */
1328SK_U32 Active, /* Active port */
1329SK_U32 PrefPort, /* Preferred port */
1330SK_U32 *pSelect) /* New active port */
1331{
1332 SK_U64 BcTimeStamp;
1333 SK_U32 i;
1334 SK_BOOL PortFound;
1335
1336 BcTimeStamp = 0; /* Not totally necessary, but feeling better. */
1337 PortFound = SK_FALSE;
1338
1339 /* Select port with the latest TimeStamp. */
1340 for (i = 0; i < (SK_U32)pAC->GIni.GIMacsFound; i++) {
1341
1342 SK_DBG_MSG(pAC, SK_DBGMOD_RLMT, SK_DBGCAT_CTRL,
1343 ("TimeStamp Port %d (Down: %d, NoRx: %d): %08x %08x.\n",
1344 i,
1345 pAC->Rlmt.Port[i].PortDown, pAC->Rlmt.Port[i].PortNoRx,
1346 *((SK_U32*)(&pAC->Rlmt.Port[i].BcTimeStamp) + OFFS_HI32),
1347 *((SK_U32*)(&pAC->Rlmt.Port[i].BcTimeStamp) + OFFS_LO32)))
1348
1349 if (!pAC->Rlmt.Port[i].PortDown && !pAC->Rlmt.Port[i].PortNoRx) {
1350 if (!PortFound || pAC->Rlmt.Port[i].BcTimeStamp > BcTimeStamp) {
1351 BcTimeStamp = pAC->Rlmt.Port[i].BcTimeStamp;
1352 *pSelect = i;
1353 PortFound = SK_TRUE;
1354 }
1355 }
1356 }
1357
1358 if (PortFound) {
1359 SK_DBG_MSG(pAC, SK_DBGMOD_RLMT, SK_DBGCAT_CTRL,
1360 ("Port %d received the last broadcast.\n", *pSelect))
1361
1362 /* Look if another port's time stamp is similar. */
1363 for (i = 0; i < (SK_U32)pAC->GIni.GIMacsFound; i++) {
1364 if (i == *pSelect) {
1365 continue;
1366 }
1367 if (!pAC->Rlmt.Port[i].PortDown && !pAC->Rlmt.Port[i].PortNoRx &&
1368 (pAC->Rlmt.Port[i].BcTimeStamp >
1369 BcTimeStamp - SK_RLMT_BC_DELTA ||
1370 pAC->Rlmt.Port[i].BcTimeStamp +
1371 SK_RLMT_BC_DELTA > BcTimeStamp)) {
1372 PortFound = SK_FALSE;
1373
1374 SK_DBG_MSG(pAC, SK_DBGMOD_RLMT, SK_DBGCAT_CTRL,
1375 ("Port %d received a broadcast at a similar time.\n", i))
1376 break;
1377 }
1378 }
1379 }
1380
1381#ifdef DEBUG
1382 if (PortFound) {
1383 SK_DBG_MSG(pAC, SK_DBGMOD_RLMT, SK_DBGCAT_CTRL,
1384 ("SK_RLMT_SELECT_BCRX found Port %d receiving the substantially "
1385 "latest broadcast (%u).\n",
1386 *pSelect,
1387 BcTimeStamp - pAC->Rlmt.Port[1 - *pSelect].BcTimeStamp))
1388 }
1389#endif /* DEBUG */
1390
1391 return (PortFound);
1392} /* SkRlmtSelectBcRx */
1393
1394
1395/******************************************************************************
1396 *
1397 * SkRlmtSelectNotSuspect - select new active port, criteria 2 (CLP)
1398 *
1399 * Description:
1400 * This routine selects a good port (it is PortUp && !SuspectRx).
1401 *
1402 * Context:
1403 * runtime, pageable?
1404 *
1405 * Returns:
1406 * SK_BOOL
1407 */
1408RLMT_STATIC SK_BOOL SkRlmtSelectNotSuspect(
1409SK_AC *pAC, /* Adapter Context */
1410SK_IOC IoC, /* I/O Context */
1411SK_U32 Active, /* Active port */
1412SK_U32 PrefPort, /* Preferred port */
1413SK_U32 *pSelect) /* New active port */
1414{
1415 SK_U32 i;
1416 SK_BOOL PortFound;
1417
1418 PortFound = SK_FALSE;
1419
1420 /* Select first port that is PortUp && !SuspectRx. */
1421 for (i = 0; i < (SK_U32)pAC->GIni.GIMacsFound; i++) {
1422 if (!pAC->Rlmt.Port[i].PortDown &&
1423 !(pAC->Rlmt.Port[i].CheckingState & SK_RLMT_PCS_RX)) {
1424 *pSelect = i;
1425 if (!pAC->Rlmt.Port[Active].PortDown &&
1426 !(pAC->Rlmt.Port[Active].CheckingState & SK_RLMT_PCS_RX)) {
1427 *pSelect = Active;
1428 }
1429 if (!pAC->Rlmt.Port[PrefPort].PortDown &&
1430 !(pAC->Rlmt.Port[PrefPort].CheckingState & SK_RLMT_PCS_RX)) {
1431 *pSelect = PrefPort;
1432 }
1433 PortFound = SK_TRUE;
1434 SK_DBG_MSG(pAC, SK_DBGMOD_RLMT, SK_DBGCAT_CTRL,
1435 ("SK_RLMT_SELECT_NOTSUSPECT found Port %d up and not check RX.\n",
1436 *pSelect))
1437 break;
1438 }
1439 }
1440 return (PortFound);
1441} /* SkRlmtSelectNotSuspect */
1442
1443
1444/******************************************************************************
1445 *
1446 * SkRlmtSelectUp - select new active port, criteria 3, 4 (CLP)
1447 *
1448 * Description:
1449 * This routine selects a port that is up.
1450 *
1451 * Context:
1452 * runtime, pageable?
1453 *
1454 * Returns:
1455 * SK_BOOL
1456 */
1457RLMT_STATIC SK_BOOL SkRlmtSelectUp(
1458SK_AC *pAC, /* Adapter Context */
1459SK_IOC IoC, /* I/O Context */
1460SK_U32 Active, /* Active port */
1461SK_U32 PrefPort, /* Preferred port */
1462SK_U32 *pSelect, /* New active port */
1463SK_BOOL AutoNegDone) /* Successfully auto-negotiated? */
1464{
1465 SK_U32 i;
1466 SK_BOOL PortFound;
1467
1468 PortFound = SK_FALSE;
1469
1470 /* Select first port that is PortUp. */
1471 for (i = 0; i < (SK_U32)pAC->GIni.GIMacsFound; i++) {
1472 if (pAC->Rlmt.Port[i].PortState == SK_RLMT_PS_UP &&
1473 pAC->GIni.GP[i].PAutoNegFail != AutoNegDone) {
1474 *pSelect = i;
1475 if (pAC->Rlmt.Port[Active].PortState == SK_RLMT_PS_UP &&
1476 pAC->GIni.GP[Active].PAutoNegFail != AutoNegDone) {
1477 *pSelect = Active;
1478 }
1479 if (pAC->Rlmt.Port[PrefPort].PortState == SK_RLMT_PS_UP &&
1480 pAC->GIni.GP[PrefPort].PAutoNegFail != AutoNegDone) {
1481 *pSelect = PrefPort;
1482 }
1483 PortFound = SK_TRUE;
1484 SK_DBG_MSG(pAC, SK_DBGMOD_RLMT, SK_DBGCAT_CTRL,
1485 ("SK_RLMT_SELECT_UP found Port %d up.\n", *pSelect))
1486 break;
1487 }
1488 }
1489 return (PortFound);
1490} /* SkRlmtSelectUp */
1491
1492
1493/******************************************************************************
1494 *
1495 * SkRlmtSelectGoingUp - select new active port, criteria 5, 6 (CLP)
1496 *
1497 * Description:
1498 * This routine selects the port that is going up for the longest time.
1499 *
1500 * Context:
1501 * runtime, pageable?
1502 *
1503 * Returns:
1504 * SK_BOOL
1505 */
1506RLMT_STATIC SK_BOOL SkRlmtSelectGoingUp(
1507SK_AC *pAC, /* Adapter Context */
1508SK_IOC IoC, /* I/O Context */
1509SK_U32 Active, /* Active port */
1510SK_U32 PrefPort, /* Preferred port */
1511SK_U32 *pSelect, /* New active port */
1512SK_BOOL AutoNegDone) /* Successfully auto-negotiated? */
1513{
1514 SK_U64 GuTimeStamp;
1515 SK_U32 i;
1516 SK_BOOL PortFound;
1517
1518 GuTimeStamp = 0;
1519 PortFound = SK_FALSE;
1520
1521 /* Select port that is PortGoingUp for the longest time. */
1522 for (i = 0; i < (SK_U32)pAC->GIni.GIMacsFound; i++) {
1523 if (pAC->Rlmt.Port[i].PortState == SK_RLMT_PS_GOING_UP &&
1524 pAC->GIni.GP[i].PAutoNegFail != AutoNegDone) {
1525 GuTimeStamp = pAC->Rlmt.Port[i].GuTimeStamp;
1526 *pSelect = i;
1527 PortFound = SK_TRUE;
1528 break;
1529 }
1530 }
1531
1532 if (!PortFound) {
1533 return (SK_FALSE);
1534 }
1535
1536 for (i = *pSelect + 1; i < (SK_U32)pAC->GIni.GIMacsFound; i++) {
1537 if (pAC->Rlmt.Port[i].PortState == SK_RLMT_PS_GOING_UP &&
1538 pAC->Rlmt.Port[i].GuTimeStamp < GuTimeStamp &&
1539 pAC->GIni.GP[i].PAutoNegFail != AutoNegDone) {
1540 GuTimeStamp = pAC->Rlmt.Port[i].GuTimeStamp;
1541 *pSelect = i;
1542 }
1543 }
1544
1545 SK_DBG_MSG(pAC, SK_DBGMOD_RLMT, SK_DBGCAT_CTRL,
1546 ("SK_RLMT_SELECT_GOINGUP found Port %d going up.\n", *pSelect))
1547 return (SK_TRUE);
1548} /* SkRlmtSelectGoingUp */
1549
1550
1551/******************************************************************************
1552 *
1553 * SkRlmtSelectDown - select new active port, criteria 7, 8 (CLP)
1554 *
1555 * Description:
1556 * This routine selects a port that is down.
1557 *
1558 * Context:
1559 * runtime, pageable?
1560 *
1561 * Returns:
1562 * SK_BOOL
1563 */
1564RLMT_STATIC SK_BOOL SkRlmtSelectDown(
1565SK_AC *pAC, /* Adapter Context */
1566SK_IOC IoC, /* I/O Context */
1567SK_U32 Active, /* Active port */
1568SK_U32 PrefPort, /* Preferred port */
1569SK_U32 *pSelect, /* New active port */
1570SK_BOOL AutoNegDone) /* Successfully auto-negotiated? */
1571{
1572 SK_U32 i;
1573 SK_BOOL PortFound;
1574
1575 PortFound = SK_FALSE;
1576
1577 /* Select first port that is PortDown. */
1578 for (i = 0; i < (SK_U32)pAC->GIni.GIMacsFound; i++) {
1579 if (pAC->Rlmt.Port[i].PortState == SK_RLMT_PS_DOWN &&
1580 pAC->GIni.GP[i].PAutoNegFail != AutoNegDone) {
1581 *pSelect = i;
1582 if (pAC->Rlmt.Port[Active].PortState == SK_RLMT_PS_DOWN &&
1583 pAC->GIni.GP[Active].PAutoNegFail != AutoNegDone) {
1584 *pSelect = Active;
1585 }
1586 if (pAC->Rlmt.Port[PrefPort].PortState == SK_RLMT_PS_DOWN &&
1587 pAC->GIni.GP[PrefPort].PAutoNegFail != AutoNegDone) {
1588 *pSelect = PrefPort;
1589 }
1590 PortFound = SK_TRUE;
1591 SK_DBG_MSG(pAC, SK_DBGMOD_RLMT, SK_DBGCAT_CTRL,
1592 ("SK_RLMT_SELECT_DOWN found Port %d down.\n", *pSelect))
1593 break;
1594 }
1595 }
1596 return (PortFound);
1597} /* SkRlmtSelectDown */
1598
1599
1600/******************************************************************************
1601 *
1602 * SkRlmtCheckSwitch - select new active port and switch to it
1603 *
1604 * Description:
1605 * This routine decides which port should be the active one and queues
1606 * port switching if necessary.
1607 *
1608 * Context:
1609 * runtime, pageable?
1610 *
1611 * Returns:
1612 * Nothing.
1613 */
1614RLMT_STATIC void SkRlmtCheckSwitch(
1615SK_AC *pAC, /* Adapter Context */
1616SK_IOC IoC, /* I/O Context */
1617SK_U32 NetIdx) /* Net index */
1618{
1619 SK_EVPARA Para;
1620 SK_U32 Active;
1621 SK_U32 PrefPort;
1622 SK_U32 i;
1623 SK_BOOL PortFound;
1624
1625 Active = pAC->Rlmt.Net[NetIdx].ActivePort; /* Index of active port. */
1626 PrefPort = pAC->Rlmt.Net[NetIdx].PrefPort; /* Index of preferred port. */
1627 PortFound = SK_FALSE;
1628 pAC->Rlmt.CheckSwitch = SK_FALSE;
1629
1630#if 0 /* RW 2001/10/18 - active port becomes always prefered one */
1631 if (pAC->Rlmt.Net[NetIdx].Preference == 0xFFFFFFFF) { /* Automatic */
1632 /* disable auto-fail back */
1633 PrefPort = Active;
1634 }
1635#endif
1636
1637 if (pAC->Rlmt.Net[NetIdx].LinksUp == 0) {
1638 /* Last link went down - shut down the net. */
1639 pAC->Rlmt.Net[NetIdx].RlmtState = SK_RLMT_RS_NET_DOWN;
1640 Para.Para32[0] = SK_RLMT_NET_DOWN_TEMP;
1641 Para.Para32[1] = NetIdx;
1642 SkEventQueue(pAC, SKGE_DRV, SK_DRV_NET_DOWN, Para);
1643
1644 Para.Para32[0] = pAC->Rlmt.Net[NetIdx].
1645 Port[pAC->Rlmt.Net[NetIdx].ActivePort]->PortNumber;
1646 Para.Para32[1] = NetIdx;
1647 SkEventQueue(pAC, SKGE_PNMI, SK_PNMI_EVT_RLMT_ACTIVE_DOWN, Para);
1648 return;
1649 } /* pAC->Rlmt.LinksUp == 0 */
1650 else if (pAC->Rlmt.Net[NetIdx].LinksUp == 1 &&
1651 pAC->Rlmt.Net[NetIdx].RlmtState == SK_RLMT_RS_NET_DOWN) {
1652 /* First link came up - get the net up. */
1653 pAC->Rlmt.Net[NetIdx].RlmtState = SK_RLMT_RS_NET_UP;
1654
1655 /*
1656 * If pAC->Rlmt.ActivePort != Para.Para32[0],
1657 * the DRV switches to the port that came up.
1658 */
1659 for (i = 0; i < pAC->Rlmt.Net[NetIdx].NumPorts; i++) {
1660 if (!pAC->Rlmt.Net[NetIdx].Port[i]->LinkDown) {
1661 if (!pAC->Rlmt.Net[NetIdx].Port[Active]->LinkDown) {
1662 i = Active;
1663 }
1664 if (!pAC->Rlmt.Net[NetIdx].Port[PrefPort]->LinkDown) {
1665 i = PrefPort;
1666 }
1667 PortFound = SK_TRUE;
1668 break;
1669 }
1670 }
1671
1672 if (PortFound) {
1673 Para.Para32[0] = pAC->Rlmt.Net[NetIdx].Port[i]->PortNumber;
1674 Para.Para32[1] = NetIdx;
1675 SkEventQueue(pAC, SKGE_PNMI, SK_PNMI_EVT_RLMT_ACTIVE_UP, Para);
1676
1677 pAC->Rlmt.Net[NetIdx].ActivePort = i;
1678 Para.Para32[0] = pAC->Rlmt.Net[NetIdx].Port[i]->PortNumber;
1679 Para.Para32[1] = NetIdx;
1680 SkEventQueue(pAC, SKGE_DRV, SK_DRV_NET_UP, Para);
1681
1682 if ((pAC->Rlmt.Net[NetIdx].RlmtMode & SK_RLMT_TRANSPARENT) == 0 &&
1683 (Para.pParaPtr = SkRlmtBuildPacket(pAC, IoC,
1684 pAC->Rlmt.Net[NetIdx].Port[i]->PortNumber,
1685 SK_PACKET_ANNOUNCE, &pAC->Addr.Net[NetIdx].
1686 CurrentMacAddress, &SkRlmtMcAddr)) != NULL) {
1687 /*
1688 * Send announce packet to RLMT multicast address to force
1689 * switches to learn the new location of the logical MAC address.
1690 */
1691 SkEventQueue(pAC, SKGE_DRV, SK_DRV_RLMT_SEND, Para);
1692 }
1693 }
1694 else {
1695 SK_ERR_LOG(pAC, SK_ERRCL_SW, SKERR_RLMT_E007, SKERR_RLMT_E007_MSG);
1696 }
1697
1698 return;
1699 } /* LinksUp == 1 && RlmtState == SK_RLMT_RS_NET_DOWN */
1700 else { /* Cannot be reached in dual-net mode. */
1701 Para.Para32[0] = Active;
1702
1703 /*
1704 * Preselection:
1705 * If RLMT Mode != CheckLinkState
1706 * select port that received a broadcast frame substantially later
1707 * than all other ports
1708 * else select first port that is not SuspectRx
1709 * else select first port that is PortUp
1710 * else select port that is PortGoingUp for the longest time
1711 * else select first port that is PortDown
1712 * else stop.
1713 *
1714 * For the preselected port:
1715 * If ActivePort is equal in quality, select ActivePort.
1716 *
1717 * If PrefPort is equal in quality, select PrefPort.
1718 *
1719 * If ActivePort != SelectedPort,
1720 * If old ActivePort is LinkDown,
1721 * SwitchHard
1722 * else
1723 * SwitchSoft
1724 */
1725 /* check of ChgBcPrio flag added */
1726 if ((pAC->Rlmt.Net[0].RlmtMode != SK_RLMT_MODE_CLS) &&
1727 (!pAC->Rlmt.Net[0].ChgBcPrio)) {
1728
1729 if (!PortFound) {
1730 PortFound = SkRlmtSelectBcRx(
1731 pAC, IoC, Active, PrefPort, &Para.Para32[1]);
1732 }
1733
1734 if (!PortFound) {
1735 PortFound = SkRlmtSelectNotSuspect(
1736 pAC, IoC, Active, PrefPort, &Para.Para32[1]);
1737 }
1738 } /* pAC->Rlmt.RlmtMode != SK_RLMT_MODE_CLS */
1739
1740 /* with changed priority for last broadcast received */
1741 if ((pAC->Rlmt.Net[0].RlmtMode != SK_RLMT_MODE_CLS) &&
1742 (pAC->Rlmt.Net[0].ChgBcPrio)) {
1743 if (!PortFound) {
1744 PortFound = SkRlmtSelectNotSuspect(
1745 pAC, IoC, Active, PrefPort, &Para.Para32[1]);
1746 }
1747
1748 if (!PortFound) {
1749 PortFound = SkRlmtSelectBcRx(
1750 pAC, IoC, Active, PrefPort, &Para.Para32[1]);
1751 }
1752 } /* pAC->Rlmt.RlmtMode != SK_RLMT_MODE_CLS */
1753
1754 if (!PortFound) {
1755 PortFound = SkRlmtSelectUp(
1756 pAC, IoC, Active, PrefPort, &Para.Para32[1], AUTONEG_SUCCESS);
1757 }
1758
1759 if (!PortFound) {
1760 PortFound = SkRlmtSelectUp(
1761 pAC, IoC, Active, PrefPort, &Para.Para32[1], AUTONEG_FAILED);
1762 }
1763
1764 if (!PortFound) {
1765 PortFound = SkRlmtSelectGoingUp(
1766 pAC, IoC, Active, PrefPort, &Para.Para32[1], AUTONEG_SUCCESS);
1767 }
1768
1769 if (!PortFound) {
1770 PortFound = SkRlmtSelectGoingUp(
1771 pAC, IoC, Active, PrefPort, &Para.Para32[1], AUTONEG_FAILED);
1772 }
1773
1774 if (pAC->Rlmt.Net[0].RlmtMode != SK_RLMT_MODE_CLS) {
1775 if (!PortFound) {
1776 PortFound = SkRlmtSelectDown(pAC, IoC,
1777 Active, PrefPort, &Para.Para32[1], AUTONEG_SUCCESS);
1778 }
1779
1780 if (!PortFound) {
1781 PortFound = SkRlmtSelectDown(pAC, IoC,
1782 Active, PrefPort, &Para.Para32[1], AUTONEG_FAILED);
1783 }
1784 } /* pAC->Rlmt.RlmtMode != SK_RLMT_MODE_CLS */
1785
1786 if (PortFound) {
1787
1788 if (Para.Para32[1] != Active) {
1789 SK_DBG_MSG(pAC, SK_DBGMOD_RLMT, SK_DBGCAT_CTRL,
1790 ("Active: %d, Para1: %d.\n", Active, Para.Para32[1]))
1791 pAC->Rlmt.Net[NetIdx].ActivePort = Para.Para32[1];
1792 Para.Para32[0] = pAC->Rlmt.Net[NetIdx].
1793 Port[Para.Para32[0]]->PortNumber;
1794 Para.Para32[1] = pAC->Rlmt.Net[NetIdx].
1795 Port[Para.Para32[1]]->PortNumber;
1796 SK_HWAC_LINK_LED(pAC, IoC, Para.Para32[1], SK_LED_ACTIVE);
1797 if (pAC->Rlmt.Port[Active].LinkDown) {
1798 SkEventQueue(pAC, SKGE_DRV, SK_DRV_SWITCH_HARD, Para);
1799 }
1800 else {
1801 SK_HWAC_LINK_LED(pAC, IoC, Para.Para32[0], SK_LED_STANDBY);
1802 SkEventQueue(pAC, SKGE_DRV, SK_DRV_SWITCH_SOFT, Para);
1803 }
1804 Para.Para32[1] = NetIdx;
1805 Para.Para32[0] =
1806 pAC->Rlmt.Net[NetIdx].Port[Para.Para32[0]]->PortNumber;
1807 SkEventQueue(pAC, SKGE_PNMI, SK_PNMI_EVT_RLMT_ACTIVE_DOWN, Para);
1808 Para.Para32[0] = pAC->Rlmt.Net[NetIdx].
1809 Port[pAC->Rlmt.Net[NetIdx].ActivePort]->PortNumber;
1810 SkEventQueue(pAC, SKGE_PNMI, SK_PNMI_EVT_RLMT_ACTIVE_UP, Para);
1811 if ((pAC->Rlmt.Net[NetIdx].RlmtMode & SK_RLMT_TRANSPARENT) == 0 &&
1812 (Para.pParaPtr = SkRlmtBuildPacket(pAC, IoC, Para.Para32[0],
1813 SK_PACKET_ANNOUNCE, &pAC->Addr.Net[NetIdx].CurrentMacAddress,
1814 &SkRlmtMcAddr)) != NULL) {
1815 /*
1816 * Send announce packet to RLMT multicast address to force
1817 * switches to learn the new location of the logical
1818 * MAC address.
1819 */
1820 SkEventQueue(pAC, SKGE_DRV, SK_DRV_RLMT_SEND, Para);
1821 } /* (Para.pParaPtr = SkRlmtBuildPacket(...)) != NULL */
1822 } /* Para.Para32[1] != Active */
1823 } /* PortFound */
1824 else {
1825 SK_ERR_LOG(pAC, SK_ERRCL_SW, SKERR_RLMT_E004, SKERR_RLMT_E004_MSG);
1826 }
1827 } /* LinksUp > 1 || LinksUp == 1 && RlmtState != SK_RLMT_RS_NET_DOWN */
1828 return;
1829} /* SkRlmtCheckSwitch */
1830
1831
1832/******************************************************************************
1833 *
1834 * SkRlmtCheckSeg - Report if segmentation is detected
1835 *
1836 * Description:
1837 * This routine checks if the ports see different root bridges and reports
1838 * segmentation in such a case.
1839 *
1840 * Context:
1841 * runtime, pageable?
1842 *
1843 * Returns:
1844 * Nothing.
1845 */
1846RLMT_STATIC void SkRlmtCheckSeg(
1847SK_AC *pAC, /* Adapter Context */
1848SK_IOC IoC, /* I/O Context */
1849SK_U32 NetIdx) /* Net number */
1850{
1851 SK_EVPARA Para;
1852 SK_RLMT_NET *pNet;
1853 SK_U32 i, j;
1854 SK_BOOL Equal;
1855
1856 pNet = &pAC->Rlmt.Net[NetIdx];
1857 pNet->RootIdSet = SK_FALSE;
1858 Equal = SK_TRUE;
1859
1860 for (i = 0; i < pNet->NumPorts; i++) {
1861 if (pNet->Port[i]->LinkDown || !pNet->Port[i]->RootIdSet) {
1862 continue;
1863 }
1864
1865 SK_DBG_MSG(pAC, SK_DBGMOD_RLMT, SK_DBGCAT_DUMP,
1866 ("Root ID %d: %02x %02x %02x %02x %02x %02x %02x %02x.\n", i,
1867 pNet->Port[i]->Root.Id[0], pNet->Port[i]->Root.Id[1],
1868 pNet->Port[i]->Root.Id[2], pNet->Port[i]->Root.Id[3],
1869 pNet->Port[i]->Root.Id[4], pNet->Port[i]->Root.Id[5],
1870 pNet->Port[i]->Root.Id[6], pNet->Port[i]->Root.Id[7]))
1871
1872 if (!pNet->RootIdSet) {
1873 pNet->Root = pNet->Port[i]->Root;
1874 pNet->RootIdSet = SK_TRUE;
1875 continue;
1876 }
1877
1878 for (j = 0; j < 8; j ++) {
1879 Equal &= pNet->Port[i]->Root.Id[j] == pNet->Root.Id[j];
1880 if (!Equal) {
1881 break;
1882 }
1883 }
1884
1885 if (!Equal) {
1886 SK_ERR_LOG(pAC, SK_ERRCL_COMM, SKERR_RLMT_E005, SKERR_RLMT_E005_MSG);
1887 Para.Para32[0] = NetIdx;
1888 Para.Para32[1] = (SK_U32)-1;
1889 SkEventQueue(pAC, SKGE_PNMI, SK_PNMI_EVT_RLMT_SEGMENTATION, Para);
1890
1891 pNet->CheckingState &= ~SK_RLMT_RCS_REPORT_SEG;
1892
1893 /* 2000-03-06 RA: New. */
1894 Para.Para32[0] = NetIdx;
1895 Para.Para32[1] = (SK_U32)-1;
1896 SkTimerStart(pAC, IoC, &pNet->SegTimer, SK_RLMT_SEG_TO_VAL,
1897 SKGE_RLMT, SK_RLMT_SEG_TIM, Para);
1898 break;
1899 }
1900 } /* for (i = 0; i < pNet->NumPorts; i++) */
1901
1902 /* 2000-03-06 RA: Moved here. */
1903 /* Segmentation check not running anymore. */
1904 pNet->CheckingState &= ~SK_RLMT_RCS_SEG;
1905
1906} /* SkRlmtCheckSeg */
1907
1908
1909/******************************************************************************
1910 *
1911 * SkRlmtPortStart - initialize port variables and start port
1912 *
1913 * Description:
1914 * This routine initializes a port's variables and issues a PORT_START
1915 * to the HWAC module. This handles retries if the start fails or the
1916 * link eventually goes down.
1917 *
1918 * Context:
1919 * runtime, pageable?
1920 *
1921 * Returns:
1922 * Nothing
1923 */
1924RLMT_STATIC void SkRlmtPortStart(
1925SK_AC *pAC, /* Adapter Context */
1926SK_IOC IoC, /* I/O Context */
1927SK_U32 PortNumber) /* Port number */
1928{
1929 SK_EVPARA Para;
1930
1931 pAC->Rlmt.Port[PortNumber].PortState = SK_RLMT_PS_LINK_DOWN;
1932 pAC->Rlmt.Port[PortNumber].PortStarted = SK_TRUE;
1933 pAC->Rlmt.Port[PortNumber].LinkDown = SK_TRUE;
1934 pAC->Rlmt.Port[PortNumber].PortDown = SK_TRUE;
1935 pAC->Rlmt.Port[PortNumber].CheckingState = 0;
1936 pAC->Rlmt.Port[PortNumber].RootIdSet = SK_FALSE;
1937 Para.Para32[0] = PortNumber;
1938 Para.Para32[1] = (SK_U32)-1;
1939 SkEventQueue(pAC, SKGE_HWAC, SK_HWEV_PORT_START, Para);
1940} /* SkRlmtPortStart */
1941
1942
1943/******************************************************************************
1944 *
1945 * SkRlmtEvtPortStartTim - PORT_START_TIM
1946 *
1947 * Description:
1948 * This routine handles PORT_START_TIM events.
1949 *
1950 * Context:
1951 * runtime, pageable?
1952 * may be called after SK_INIT_IO
1953 *
1954 * Returns:
1955 * Nothing
1956 */
1957RLMT_STATIC void SkRlmtEvtPortStartTim(
1958SK_AC *pAC, /* Adapter Context */
1959SK_IOC IoC, /* I/O Context */
1960SK_EVPARA Para) /* SK_U32 PortNumber; SK_U32 -1 */
1961{
1962 SK_U32 i;
1963
1964 SK_DBG_MSG(pAC, SK_DBGMOD_RLMT, SK_DBGCAT_CTRL,
1965 ("SK_RLMT_PORTSTART_TIMEOUT Port %d Event BEGIN.\n", Para.Para32[0]))
1966
1967 if (Para.Para32[1] != (SK_U32)-1) {
1968 SK_DBG_MSG(pAC, SK_DBGMOD_RLMT, SK_DBGCAT_CTRL,
1969 ("Bad Parameter.\n"))
1970 SK_DBG_MSG(pAC, SK_DBGMOD_RLMT, SK_DBGCAT_CTRL,
1971 ("SK_RLMT_PORTSTART_TIMEOUT Event EMPTY.\n"))
1972 return;
1973 }
1974
1975 /*
1976 * Used to start non-preferred ports if the preferred one
1977 * does not come up.
1978 * This timeout needs only be set when starting the first
1979 * (preferred) port.
1980 */
1981 if (pAC->Rlmt.Port[Para.Para32[0]].LinkDown) {
1982 /* PORT_START failed. */
1983 for (i = 0; i < pAC->Rlmt.Port[Para.Para32[0]].Net->NumPorts; i++) {
1984 if (!pAC->Rlmt.Port[Para.Para32[0]].Net->Port[i]->PortStarted) {
1985 SkRlmtPortStart(pAC, IoC,
1986 pAC->Rlmt.Port[Para.Para32[0]].Net->Port[i]->PortNumber);
1987 }
1988 }
1989 }
1990
1991 SK_DBG_MSG(pAC, SK_DBGMOD_RLMT, SK_DBGCAT_CTRL,
1992 ("SK_RLMT_PORTSTART_TIMEOUT Event END.\n"))
1993} /* SkRlmtEvtPortStartTim */
1994
1995
1996/******************************************************************************
1997 *
1998 * SkRlmtEvtLinkUp - LINK_UP
1999 *
2000 * Description:
2001 * This routine handles LLINK_UP events.
2002 *
2003 * Context:
2004 * runtime, pageable?
2005 * may be called after SK_INIT_IO
2006 *
2007 * Returns:
2008 * Nothing
2009 */
2010RLMT_STATIC void SkRlmtEvtLinkUp(
2011SK_AC *pAC, /* Adapter Context */
2012SK_IOC IoC, /* I/O Context */
2013SK_EVPARA Para) /* SK_U32 PortNumber; SK_U32 Undefined */
2014{
2015 SK_U32 i;
2016 SK_RLMT_PORT *pRPort;
2017 SK_EVPARA Para2;
2018
2019 SK_DBG_MSG(pAC, SK_DBGMOD_RLMT, SK_DBGCAT_CTRL,
2020 ("SK_RLMT_LINK_UP Port %d Event BEGIN.\n", Para.Para32[0]))
2021
2022 pRPort = &pAC->Rlmt.Port[Para.Para32[0]];
2023 if (!pRPort->PortStarted) {
2024 SK_ERR_LOG(pAC, SK_ERRCL_SW, SKERR_RLMT_E008, SKERR_RLMT_E008_MSG);
2025
2026 SK_DBG_MSG(pAC, SK_DBGMOD_RLMT, SK_DBGCAT_CTRL,
2027 ("SK_RLMT_LINK_UP Event EMPTY.\n"))
2028 return;
2029 }
2030
2031 if (!pRPort->LinkDown) {
2032 /* RA;:;: Any better solution? */
2033 SK_DBG_MSG(pAC, SK_DBGMOD_RLMT, SK_DBGCAT_CTRL,
2034 ("SK_RLMT_LINK_UP Event EMPTY.\n"))
2035 return;
2036 }
2037
2038 SkTimerStop(pAC, IoC, &pRPort->UpTimer);
2039 SkTimerStop(pAC, IoC, &pRPort->DownRxTimer);
2040 SkTimerStop(pAC, IoC, &pRPort->DownTxTimer);
2041
2042 /* Do something if timer already fired? */
2043
2044 pRPort->LinkDown = SK_FALSE;
2045 pRPort->PortState = SK_RLMT_PS_GOING_UP;
2046 pRPort->GuTimeStamp = SkOsGetTime(pAC);
2047 pRPort->BcTimeStamp = 0;
2048 pRPort->Net->LinksUp++;
2049 if (pRPort->Net->LinksUp == 1) {
2050 SK_HWAC_LINK_LED(pAC, IoC, Para.Para32[0], SK_LED_ACTIVE);
2051 }
2052 else {
2053 SK_HWAC_LINK_LED(pAC, IoC, Para.Para32[0], SK_LED_STANDBY);
2054 }
2055
2056 for (i = 0; i < pRPort->Net->NumPorts; i++) {
2057 if (!pRPort->Net->Port[i]->PortStarted) {
2058 SkRlmtPortStart(pAC, IoC, pRPort->Net->Port[i]->PortNumber);
2059 }
2060 }
2061
2062 SkRlmtCheckSwitch(pAC, IoC, pRPort->Net->NetNumber);
2063
2064 if (pRPort->Net->LinksUp >= 2) {
2065 if (pRPort->Net->RlmtMode & SK_RLMT_CHECK_LOC_LINK) {
2066 /* Build the check chain. */
2067 SkRlmtBuildCheckChain(pAC, pRPort->Net->NetNumber);
2068 }
2069 }
2070
2071 /* If the first link comes up, start the periodical RLMT timeout. */
2072 if (pRPort->Net->NumPorts > 1 && pRPort->Net->LinksUp == 1 &&
2073 (pRPort->Net->RlmtMode & SK_RLMT_CHECK_OTHERS) != 0) {
2074 Para2.Para32[0] = pRPort->Net->NetNumber;
2075 Para2.Para32[1] = (SK_U32)-1;
2076 SkTimerStart(pAC, IoC, &pRPort->Net->LocTimer,
2077 pRPort->Net->TimeoutValue, SKGE_RLMT, SK_RLMT_TIM, Para2);
2078 }
2079
2080 Para2 = Para;
2081 Para2.Para32[1] = (SK_U32)-1;
2082 SkTimerStart(pAC, IoC, &pRPort->UpTimer, SK_RLMT_PORTUP_TIM_VAL,
2083 SKGE_RLMT, SK_RLMT_PORTUP_TIM, Para2);
2084
2085 /* Later: if (pAC->Rlmt.RlmtMode & SK_RLMT_CHECK_LOC_LINK) && */
2086 if ((pRPort->Net->RlmtMode & SK_RLMT_TRANSPARENT) == 0 &&
2087 (pRPort->Net->RlmtMode & SK_RLMT_CHECK_LINK) != 0 &&
2088 (Para2.pParaPtr =
2089 SkRlmtBuildPacket(pAC, IoC, Para.Para32[0], SK_PACKET_ANNOUNCE,
2090 &pAC->Addr.Port[Para.Para32[0]].CurrentMacAddress, &SkRlmtMcAddr)
2091 ) != NULL) {
2092 /* Send "new" packet to RLMT multicast address. */
2093 SkEventQueue(pAC, SKGE_DRV, SK_DRV_RLMT_SEND, Para2);
2094 }
2095
2096 if (pRPort->Net->RlmtMode & SK_RLMT_CHECK_SEG) {
2097 if ((Para2.pParaPtr =
2098 SkRlmtBuildSpanningTreePacket(pAC, IoC, Para.Para32[0])) != NULL) {
2099 pAC->Rlmt.Port[Para.Para32[0]].RootIdSet = SK_FALSE;
2100 pRPort->Net->CheckingState |=
2101 SK_RLMT_RCS_SEG | SK_RLMT_RCS_REPORT_SEG;
2102
2103 SkEventQueue(pAC, SKGE_DRV, SK_DRV_RLMT_SEND, Para2);
2104
2105 Para.Para32[1] = (SK_U32)-1;
2106 SkTimerStart(pAC, IoC, &pRPort->Net->SegTimer,
2107 SK_RLMT_SEG_TO_VAL, SKGE_RLMT, SK_RLMT_SEG_TIM, Para);
2108 }
2109 }
2110
2111 SK_DBG_MSG(pAC, SK_DBGMOD_RLMT, SK_DBGCAT_CTRL,
2112 ("SK_RLMT_LINK_UP Event END.\n"))
2113} /* SkRlmtEvtLinkUp */
2114
2115
2116/******************************************************************************
2117 *
2118 * SkRlmtEvtPortUpTim - PORT_UP_TIM
2119 *
2120 * Description:
2121 * This routine handles PORT_UP_TIM events.
2122 *
2123 * Context:
2124 * runtime, pageable?
2125 * may be called after SK_INIT_IO
2126 *
2127 * Returns:
2128 * Nothing
2129 */
2130RLMT_STATIC void SkRlmtEvtPortUpTim(
2131SK_AC *pAC, /* Adapter Context */
2132SK_IOC IoC, /* I/O Context */
2133SK_EVPARA Para) /* SK_U32 PortNumber; SK_U32 -1 */
2134{
2135 SK_RLMT_PORT *pRPort;
2136
2137 SK_DBG_MSG(pAC, SK_DBGMOD_RLMT, SK_DBGCAT_CTRL,
2138 ("SK_RLMT_PORTUP_TIM Port %d Event BEGIN.\n", Para.Para32[0]))
2139
2140 if (Para.Para32[1] != (SK_U32)-1) {
2141 SK_DBG_MSG(pAC, SK_DBGMOD_RLMT, SK_DBGCAT_CTRL,
2142 ("Bad Parameter.\n"))
2143 SK_DBG_MSG(pAC, SK_DBGMOD_RLMT, SK_DBGCAT_CTRL,
2144 ("SK_RLMT_PORTUP_TIM Event EMPTY.\n"))
2145 return;
2146 }
2147
2148 pRPort = &pAC->Rlmt.Port[Para.Para32[0]];
2149 if (pRPort->LinkDown || (pRPort->PortState == SK_RLMT_PS_UP)) {
2150 SK_DBG_MSG(pAC, SK_DBGMOD_RLMT, SK_DBGCAT_CTRL,
2151 ("SK_RLMT_PORTUP_TIM Port %d Event EMPTY.\n", Para.Para32[0]))
2152 return;
2153 }
2154
2155 pRPort->PortDown = SK_FALSE;
2156 pRPort->PortState = SK_RLMT_PS_UP;
2157 pRPort->Net->PortsUp++;
2158 if (pRPort->Net->RlmtState != SK_RLMT_RS_INIT) {
2159 if (pAC->Rlmt.NumNets <= 1) {
2160 SkRlmtCheckSwitch(pAC, IoC, pRPort->Net->NetNumber);
2161 }
2162 SkEventQueue(pAC, SKGE_PNMI, SK_PNMI_EVT_RLMT_PORT_UP, Para);
2163 }
2164
2165 SK_DBG_MSG(pAC, SK_DBGMOD_RLMT, SK_DBGCAT_CTRL,
2166 ("SK_RLMT_PORTUP_TIM Event END.\n"))
2167} /* SkRlmtEvtPortUpTim */
2168
2169
2170/******************************************************************************
2171 *
2172 * SkRlmtEvtPortDownTim - PORT_DOWN_*
2173 *
2174 * Description:
2175 * This routine handles PORT_DOWN_* events.
2176 *
2177 * Context:
2178 * runtime, pageable?
2179 * may be called after SK_INIT_IO
2180 *
2181 * Returns:
2182 * Nothing
2183 */
2184RLMT_STATIC void SkRlmtEvtPortDownX(
2185SK_AC *pAC, /* Adapter Context */
2186SK_IOC IoC, /* I/O Context */
2187SK_U32 Event, /* Event code */
2188SK_EVPARA Para) /* SK_U32 PortNumber; SK_U32 -1 */
2189{
2190 SK_RLMT_PORT *pRPort;
2191
2192 SK_DBG_MSG(pAC, SK_DBGMOD_RLMT, SK_DBGCAT_CTRL,
2193 ("SK_RLMT_PORTDOWN* Port %d Event (%d) BEGIN.\n",
2194 Para.Para32[0], Event))
2195
2196 if (Para.Para32[1] != (SK_U32)-1) {
2197 SK_DBG_MSG(pAC, SK_DBGMOD_RLMT, SK_DBGCAT_CTRL,
2198 ("Bad Parameter.\n"))
2199 SK_DBG_MSG(pAC, SK_DBGMOD_RLMT, SK_DBGCAT_CTRL,
2200 ("SK_RLMT_PORTDOWN* Event EMPTY.\n"))
2201 return;
2202 }
2203
2204 pRPort = &pAC->Rlmt.Port[Para.Para32[0]];
2205 if (!pRPort->PortStarted || (Event == SK_RLMT_PORTDOWN_TX_TIM &&
2206 !(pRPort->CheckingState & SK_RLMT_PCS_TX))) {
2207 SK_DBG_MSG(pAC, SK_DBGMOD_RLMT, SK_DBGCAT_CTRL,
2208 ("SK_RLMT_PORTDOWN* Event (%d) EMPTY.\n", Event))
2209 return;
2210 }
2211
2212 /* Stop port's timers. */
2213 SkTimerStop(pAC, IoC, &pRPort->UpTimer);
2214 SkTimerStop(pAC, IoC, &pRPort->DownRxTimer);
2215 SkTimerStop(pAC, IoC, &pRPort->DownTxTimer);
2216
2217 if (pRPort->PortState != SK_RLMT_PS_LINK_DOWN) {
2218 pRPort->PortState = SK_RLMT_PS_DOWN;
2219 }
2220
2221 if (!pRPort->PortDown) {
2222 pRPort->Net->PortsUp--;
2223 pRPort->PortDown = SK_TRUE;
2224 SkEventQueue(pAC, SKGE_PNMI, SK_PNMI_EVT_RLMT_PORT_DOWN, Para);
2225 }
2226
2227 pRPort->PacketsPerTimeSlot = 0;
2228 /* pRPort->DataPacketsPerTimeSlot = 0; */
2229 pRPort->BpduPacketsPerTimeSlot = 0;
2230 pRPort->BcTimeStamp = 0;
2231
2232 /*
2233 * RA;:;: To be checked:
2234 * - actions at RLMT_STOP: We should not switch anymore.
2235 */
2236 if (pRPort->Net->RlmtState != SK_RLMT_RS_INIT) {
2237 if (Para.Para32[0] ==
2238 pRPort->Net->Port[pRPort->Net->ActivePort]->PortNumber) {
2239 /* Active Port went down. */
2240 SkRlmtCheckSwitch(pAC, IoC, pRPort->Net->NetNumber);
2241 }
2242 }
2243
2244 SK_DBG_MSG(pAC, SK_DBGMOD_RLMT, SK_DBGCAT_CTRL,
2245 ("SK_RLMT_PORTDOWN* Event (%d) END.\n", Event))
2246} /* SkRlmtEvtPortDownX */
2247
2248
2249/******************************************************************************
2250 *
2251 * SkRlmtEvtLinkDown - LINK_DOWN
2252 *
2253 * Description:
2254 * This routine handles LINK_DOWN events.
2255 *
2256 * Context:
2257 * runtime, pageable?
2258 * may be called after SK_INIT_IO
2259 *
2260 * Returns:
2261 * Nothing
2262 */
2263RLMT_STATIC void SkRlmtEvtLinkDown(
2264SK_AC *pAC, /* Adapter Context */
2265SK_IOC IoC, /* I/O Context */
2266SK_EVPARA Para) /* SK_U32 PortNumber; SK_U32 Undefined */
2267{
2268 SK_RLMT_PORT *pRPort;
2269
2270 pRPort = &pAC->Rlmt.Port[Para.Para32[0]];
2271 SK_DBG_MSG(pAC, SK_DBGMOD_RLMT, SK_DBGCAT_CTRL,
2272 ("SK_RLMT_LINK_DOWN Port %d Event BEGIN.\n", Para.Para32[0]))
2273
2274 if (!pAC->Rlmt.Port[Para.Para32[0]].LinkDown) {
2275 pRPort->Net->LinksUp--;
2276 pRPort->LinkDown = SK_TRUE;
2277 pRPort->PortState = SK_RLMT_PS_LINK_DOWN;
2278 SK_HWAC_LINK_LED(pAC, IoC, Para.Para32[0], SK_LED_OFF);
2279
2280 if ((pRPort->Net->RlmtMode & SK_RLMT_CHECK_LOC_LINK) != 0) {
2281 /* Build the check chain. */
2282 SkRlmtBuildCheckChain(pAC, pRPort->Net->NetNumber);
2283 }
2284
2285 /* Ensure that port is marked down. */
2286 Para.Para32[1] = -1;
2287 (void)SkRlmtEvent(pAC, IoC, SK_RLMT_PORTDOWN, Para);
2288 }
2289
2290 SK_DBG_MSG(pAC, SK_DBGMOD_RLMT, SK_DBGCAT_CTRL,
2291 ("SK_RLMT_LINK_DOWN Event END.\n"))
2292} /* SkRlmtEvtLinkDown */
2293
2294
2295/******************************************************************************
2296 *
2297 * SkRlmtEvtPortAddr - PORT_ADDR
2298 *
2299 * Description:
2300 * This routine handles PORT_ADDR events.
2301 *
2302 * Context:
2303 * runtime, pageable?
2304 * may be called after SK_INIT_IO
2305 *
2306 * Returns:
2307 * Nothing
2308 */
2309RLMT_STATIC void SkRlmtEvtPortAddr(
2310SK_AC *pAC, /* Adapter Context */
2311SK_IOC IoC, /* I/O Context */
2312SK_EVPARA Para) /* SK_U32 PortNumber; SK_U32 -1 */
2313{
2314 SK_U32 i, j;
2315 SK_RLMT_PORT *pRPort;
2316 SK_MAC_ADDR *pOldMacAddr;
2317 SK_MAC_ADDR *pNewMacAddr;
2318
2319 SK_DBG_MSG(pAC, SK_DBGMOD_RLMT, SK_DBGCAT_CTRL,
2320 ("SK_RLMT_PORT_ADDR Port %d Event BEGIN.\n", Para.Para32[0]))
2321
2322 if (Para.Para32[1] != (SK_U32)-1) {
2323 SK_DBG_MSG(pAC, SK_DBGMOD_RLMT, SK_DBGCAT_CTRL,
2324 ("Bad Parameter.\n"))
2325 SK_DBG_MSG(pAC, SK_DBGMOD_RLMT, SK_DBGCAT_CTRL,
2326 ("SK_RLMT_PORT_ADDR Event EMPTY.\n"))
2327 return;
2328 }
2329
2330 /* Port's physical MAC address changed. */
2331 pOldMacAddr = &pAC->Addr.Port[Para.Para32[0]].PreviousMacAddress;
2332 pNewMacAddr = &pAC->Addr.Port[Para.Para32[0]].CurrentMacAddress;
2333
2334 /*
2335 * NOTE: This is not scalable for solutions where ports are
2336 * checked remotely. There, we need to send an RLMT
2337 * address change packet - and how do we ensure delivery?
2338 */
2339 for (i = 0; i < (SK_U32)pAC->GIni.GIMacsFound; i++) {
2340 pRPort = &pAC->Rlmt.Port[i];
2341 for (j = 0; j < pRPort->PortsChecked; j++) {
2342 if (SK_ADDR_EQUAL(
2343 pRPort->PortCheck[j].CheckAddr.a, pOldMacAddr->a)) {
2344 pRPort->PortCheck[j].CheckAddr = *pNewMacAddr;
2345 }
2346 }
2347 }
2348
2349 SK_DBG_MSG(pAC, SK_DBGMOD_RLMT, SK_DBGCAT_CTRL,
2350 ("SK_RLMT_PORT_ADDR Event END.\n"))
2351} /* SkRlmtEvtPortAddr */
2352
2353
2354/******************************************************************************
2355 *
2356 * SkRlmtEvtStart - START
2357 *
2358 * Description:
2359 * This routine handles START events.
2360 *
2361 * Context:
2362 * runtime, pageable?
2363 * may be called after SK_INIT_IO
2364 *
2365 * Returns:
2366 * Nothing
2367 */
2368RLMT_STATIC void SkRlmtEvtStart(
2369SK_AC *pAC, /* Adapter Context */
2370SK_IOC IoC, /* I/O Context */
2371SK_EVPARA Para) /* SK_U32 NetNumber; SK_U32 -1 */
2372{
2373 SK_EVPARA Para2;
2374 SK_U32 PortIdx;
2375 SK_U32 PortNumber;
2376
2377 SK_DBG_MSG(pAC, SK_DBGMOD_RLMT, SK_DBGCAT_CTRL,
2378 ("SK_RLMT_START Net %d Event BEGIN.\n", Para.Para32[0]))
2379
2380 if (Para.Para32[1] != (SK_U32)-1) {
2381 SK_DBG_MSG(pAC, SK_DBGMOD_RLMT, SK_DBGCAT_CTRL,
2382 ("Bad Parameter.\n"))
2383 SK_DBG_MSG(pAC, SK_DBGMOD_RLMT, SK_DBGCAT_CTRL,
2384 ("SK_RLMT_START Event EMPTY.\n"))
2385 return;
2386 }
2387
2388 if (Para.Para32[0] >= pAC->Rlmt.NumNets) {
2389 SK_DBG_MSG(pAC, SK_DBGMOD_RLMT, SK_DBGCAT_CTRL,
2390 ("Bad NetNumber %d.\n", Para.Para32[0]))
2391 SK_DBG_MSG(pAC, SK_DBGMOD_RLMT, SK_DBGCAT_CTRL,
2392 ("SK_RLMT_START Event EMPTY.\n"))
2393 return;
2394 }
2395
2396 if (pAC->Rlmt.Net[Para.Para32[0]].RlmtState != SK_RLMT_RS_INIT) {
2397 SK_DBG_MSG(pAC, SK_DBGMOD_RLMT, SK_DBGCAT_CTRL,
2398 ("SK_RLMT_START Event EMPTY.\n"))
2399 return;
2400 }
2401
2402 if (pAC->Rlmt.NetsStarted >= pAC->Rlmt.NumNets) {
2403 SK_DBG_MSG(pAC, SK_DBGMOD_RLMT, SK_DBGCAT_CTRL,
2404 ("All nets should have been started.\n"))
2405 SK_DBG_MSG(pAC, SK_DBGMOD_RLMT, SK_DBGCAT_CTRL,
2406 ("SK_RLMT_START Event EMPTY.\n"))
2407 return;
2408 }
2409
2410 if (pAC->Rlmt.Net[Para.Para32[0]].PrefPort >=
2411 pAC->Rlmt.Net[Para.Para32[0]].NumPorts) {
2412 SK_ERR_LOG(pAC, SK_ERRCL_SW, SKERR_RLMT_E009, SKERR_RLMT_E009_MSG);
2413
2414 /* Change PrefPort to internal default. */
2415 Para2.Para32[0] = 0xFFFFFFFF;
2416 Para2.Para32[1] = Para.Para32[0];
2417 (void)SkRlmtEvent(pAC, IoC, SK_RLMT_PREFPORT_CHANGE, Para2);
2418 }
2419
2420 PortIdx = pAC->Rlmt.Net[Para.Para32[0]].PrefPort;
2421 PortNumber = pAC->Rlmt.Net[Para.Para32[0]].Port[PortIdx]->PortNumber;
2422
2423 pAC->Rlmt.Net[Para.Para32[0]].LinksUp = 0;
2424 pAC->Rlmt.Net[Para.Para32[0]].PortsUp = 0;
2425 pAC->Rlmt.Net[Para.Para32[0]].CheckingState = 0;
2426 pAC->Rlmt.Net[Para.Para32[0]].RlmtState = SK_RLMT_RS_NET_DOWN;
2427
2428 /* Start preferred port. */
2429 SkRlmtPortStart(pAC, IoC, PortNumber);
2430
2431 /* Start Timer (for first port only). */
2432 Para2.Para32[0] = PortNumber;
2433 Para2.Para32[1] = (SK_U32)-1;
2434 SkTimerStart(pAC, IoC, &pAC->Rlmt.Port[PortNumber].UpTimer,
2435 SK_RLMT_PORTSTART_TIM_VAL, SKGE_RLMT, SK_RLMT_PORTSTART_TIM, Para2);
2436
2437 pAC->Rlmt.NetsStarted++;
2438
2439 SK_DBG_MSG(pAC, SK_DBGMOD_RLMT, SK_DBGCAT_CTRL,
2440 ("SK_RLMT_START Event END.\n"))
2441} /* SkRlmtEvtStart */
2442
2443
2444/******************************************************************************
2445 *
2446 * SkRlmtEvtStop - STOP
2447 *
2448 * Description:
2449 * This routine handles STOP events.
2450 *
2451 * Context:
2452 * runtime, pageable?
2453 * may be called after SK_INIT_IO
2454 *
2455 * Returns:
2456 * Nothing
2457 */
2458RLMT_STATIC void SkRlmtEvtStop(
2459SK_AC *pAC, /* Adapter Context */
2460SK_IOC IoC, /* I/O Context */
2461SK_EVPARA Para) /* SK_U32 NetNumber; SK_U32 -1 */
2462{
2463 SK_EVPARA Para2;
2464 SK_U32 PortNumber;
2465 SK_U32 i;
2466
2467 SK_DBG_MSG(pAC, SK_DBGMOD_RLMT, SK_DBGCAT_CTRL,
2468 ("SK_RLMT_STOP Net %d Event BEGIN.\n", Para.Para32[0]))
2469
2470 if (Para.Para32[1] != (SK_U32)-1) {
2471 SK_DBG_MSG(pAC, SK_DBGMOD_RLMT, SK_DBGCAT_CTRL,
2472 ("Bad Parameter.\n"))
2473 SK_DBG_MSG(pAC, SK_DBGMOD_RLMT, SK_DBGCAT_CTRL,
2474 ("SK_RLMT_STOP Event EMPTY.\n"))
2475 return;
2476 }
2477
2478 if (Para.Para32[0] >= pAC->Rlmt.NumNets) {
2479 SK_DBG_MSG(pAC, SK_DBGMOD_RLMT, SK_DBGCAT_CTRL,
2480 ("Bad NetNumber %d.\n", Para.Para32[0]))
2481 SK_DBG_MSG(pAC, SK_DBGMOD_RLMT, SK_DBGCAT_CTRL,
2482 ("SK_RLMT_STOP Event EMPTY.\n"))
2483 return;
2484 }
2485
2486 if (pAC->Rlmt.Net[Para.Para32[0]].RlmtState == SK_RLMT_RS_INIT) {
2487 SK_DBG_MSG(pAC, SK_DBGMOD_RLMT, SK_DBGCAT_CTRL,
2488 ("SK_RLMT_STOP Event EMPTY.\n"))
2489 return;
2490 }
2491
2492 if (pAC->Rlmt.NetsStarted == 0) {
2493 SK_DBG_MSG(pAC, SK_DBGMOD_RLMT, SK_DBGCAT_CTRL,
2494 ("All nets are stopped.\n"))
2495 SK_DBG_MSG(pAC, SK_DBGMOD_RLMT, SK_DBGCAT_CTRL,
2496 ("SK_RLMT_STOP Event EMPTY.\n"))
2497 return;
2498 }
2499
2500 /* Stop RLMT timers. */
2501 SkTimerStop(pAC, IoC, &pAC->Rlmt.Net[Para.Para32[0]].LocTimer);
2502 SkTimerStop(pAC, IoC, &pAC->Rlmt.Net[Para.Para32[0]].SegTimer);
2503
2504 /* Stop net. */
2505 pAC->Rlmt.Net[Para.Para32[0]].RlmtState = SK_RLMT_RS_INIT;
2506 pAC->Rlmt.Net[Para.Para32[0]].RootIdSet = SK_FALSE;
2507 Para2.Para32[0] = SK_RLMT_NET_DOWN_FINAL;
2508 Para2.Para32[1] = Para.Para32[0]; /* Net# */
2509 SkEventQueue(pAC, SKGE_DRV, SK_DRV_NET_DOWN, Para2);
2510
2511 /* Stop ports. */
2512 for (i = 0; i < pAC->Rlmt.Net[Para.Para32[0]].NumPorts; i++) {
2513 PortNumber = pAC->Rlmt.Net[Para.Para32[0]].Port[i]->PortNumber;
2514 if (pAC->Rlmt.Port[PortNumber].PortState != SK_RLMT_PS_INIT) {
2515 SkTimerStop(pAC, IoC, &pAC->Rlmt.Port[PortNumber].UpTimer);
2516 SkTimerStop(pAC, IoC, &pAC->Rlmt.Port[PortNumber].DownRxTimer);
2517 SkTimerStop(pAC, IoC, &pAC->Rlmt.Port[PortNumber].DownTxTimer);
2518
2519 pAC->Rlmt.Port[PortNumber].PortState = SK_RLMT_PS_INIT;
2520 pAC->Rlmt.Port[PortNumber].RootIdSet = SK_FALSE;
2521 pAC->Rlmt.Port[PortNumber].PortStarted = SK_FALSE;
2522 Para2.Para32[0] = PortNumber;
2523 Para2.Para32[1] = (SK_U32)-1;
2524 SkEventQueue(pAC, SKGE_HWAC, SK_HWEV_PORT_STOP, Para2);
2525 }
2526 }
2527
2528 pAC->Rlmt.NetsStarted--;
2529
2530 SK_DBG_MSG(pAC, SK_DBGMOD_RLMT, SK_DBGCAT_CTRL,
2531 ("SK_RLMT_STOP Event END.\n"))
2532} /* SkRlmtEvtStop */
2533
2534
2535/******************************************************************************
2536 *
2537 * SkRlmtEvtTim - TIM
2538 *
2539 * Description:
2540 * This routine handles TIM events.
2541 *
2542 * Context:
2543 * runtime, pageable?
2544 * may be called after SK_INIT_IO
2545 *
2546 * Returns:
2547 * Nothing
2548 */
2549RLMT_STATIC void SkRlmtEvtTim(
2550SK_AC *pAC, /* Adapter Context */
2551SK_IOC IoC, /* I/O Context */
2552SK_EVPARA Para) /* SK_U32 NetNumber; SK_U32 -1 */
2553{
2554 SK_RLMT_PORT *pRPort;
2555 SK_U32 Timeout;
2556 SK_U32 NewTimeout;
2557 SK_U32 PortNumber;
2558 SK_U32 i;
2559
2560 SK_DBG_MSG(pAC, SK_DBGMOD_RLMT, SK_DBGCAT_CTRL,
2561 ("SK_RLMT_TIM Event BEGIN.\n"))
2562
2563 if (Para.Para32[1] != (SK_U32)-1) {
2564 SK_DBG_MSG(pAC, SK_DBGMOD_RLMT, SK_DBGCAT_CTRL,
2565 ("Bad Parameter.\n"))
2566 SK_DBG_MSG(pAC, SK_DBGMOD_RLMT, SK_DBGCAT_CTRL,
2567 ("SK_RLMT_TIM Event EMPTY.\n"))
2568 return;
2569 }
2570
2571 if ((pAC->Rlmt.Net[Para.Para32[0]].RlmtMode & SK_RLMT_CHECK_OTHERS) == 0 ||
2572 pAC->Rlmt.Net[Para.Para32[0]].LinksUp == 0) {
2573 /* Mode changed or all links down: No more link checking. */
2574 return;
2575 }
2576
2577#if 0
2578 pAC->Rlmt.SwitchCheckCounter--;
2579 if (pAC->Rlmt.SwitchCheckCounter == 0) {
2580 pAC->Rlmt.SwitchCheckCounter;
2581 }
2582#endif /* 0 */
2583
2584 NewTimeout = SK_RLMT_DEF_TO_VAL;
2585 for (i = 0; i < pAC->Rlmt.Net[Para.Para32[0]].NumPorts; i++) {
2586 PortNumber = pAC->Rlmt.Net[Para.Para32[0]].Port[i]->PortNumber;
2587 pRPort = &pAC->Rlmt.Port[PortNumber];
2588 if (!pRPort->LinkDown) {
2589 Timeout = SkRlmtCheckPort(pAC, IoC, PortNumber);
2590 if (Timeout < NewTimeout) {
2591 NewTimeout = Timeout;
2592 }
2593
2594 /*
2595 * These counters should be set to 0 for all ports before the
2596 * first frame is sent in the next loop.
2597 */
2598 pRPort->PacketsPerTimeSlot = 0;
2599 /* pRPort->DataPacketsPerTimeSlot = 0; */
2600 pRPort->BpduPacketsPerTimeSlot = 0;
2601 }
2602 }
2603 pAC->Rlmt.Net[Para.Para32[0]].TimeoutValue = NewTimeout;
2604
2605 if (pAC->Rlmt.Net[Para.Para32[0]].LinksUp > 1) {
2606 /*
2607 * If checking remote ports, also send packets if
2608 * (LinksUp == 1) &&
2609 * this port checks at least one (remote) port.
2610 */
2611
2612 /*
2613 * Must be new loop, as SkRlmtCheckPort can request to
2614 * check segmentation when e.g. checking the last port.
2615 */
2616 for (i = 0; i < pAC->Rlmt.Net[Para.Para32[0]].NumPorts; i++) {
2617 if (!pAC->Rlmt.Net[Para.Para32[0]].Port[i]->LinkDown) {
2618 SkRlmtSend(pAC, IoC,
2619 pAC->Rlmt.Net[Para.Para32[0]].Port[i]->PortNumber);
2620 }
2621 }
2622 }
2623
2624 SkTimerStart(pAC, IoC, &pAC->Rlmt.Net[Para.Para32[0]].LocTimer,
2625 pAC->Rlmt.Net[Para.Para32[0]].TimeoutValue, SKGE_RLMT, SK_RLMT_TIM,
2626 Para);
2627
2628 if (pAC->Rlmt.Net[Para.Para32[0]].LinksUp > 1 &&
2629 (pAC->Rlmt.Net[Para.Para32[0]].RlmtMode & SK_RLMT_CHECK_SEG) &&
2630 (pAC->Rlmt.Net[Para.Para32[0]].CheckingState & SK_RLMT_RCS_START_SEG)) {
2631 SkTimerStart(pAC, IoC, &pAC->Rlmt.Net[Para.Para32[0]].SegTimer,
2632 SK_RLMT_SEG_TO_VAL, SKGE_RLMT, SK_RLMT_SEG_TIM, Para);
2633 pAC->Rlmt.Net[Para.Para32[0]].CheckingState &= ~SK_RLMT_RCS_START_SEG;
2634 pAC->Rlmt.Net[Para.Para32[0]].CheckingState |=
2635 SK_RLMT_RCS_SEG | SK_RLMT_RCS_REPORT_SEG;
2636 }
2637
2638 SK_DBG_MSG(pAC, SK_DBGMOD_RLMT, SK_DBGCAT_CTRL,
2639 ("SK_RLMT_TIM Event END.\n"))
2640} /* SkRlmtEvtTim */
2641
2642
2643/******************************************************************************
2644 *
2645 * SkRlmtEvtSegTim - SEG_TIM
2646 *
2647 * Description:
2648 * This routine handles SEG_TIM events.
2649 *
2650 * Context:
2651 * runtime, pageable?
2652 * may be called after SK_INIT_IO
2653 *
2654 * Returns:
2655 * Nothing
2656 */
2657RLMT_STATIC void SkRlmtEvtSegTim(
2658SK_AC *pAC, /* Adapter Context */
2659SK_IOC IoC, /* I/O Context */
2660SK_EVPARA Para) /* SK_U32 NetNumber; SK_U32 -1 */
2661{
2662#ifdef xDEBUG
2663 int j;
2664#endif /* DEBUG */
2665
2666 SK_DBG_MSG(pAC, SK_DBGMOD_RLMT, SK_DBGCAT_CTRL,
2667 ("SK_RLMT_SEG_TIM Event BEGIN.\n"))
2668
2669 if (Para.Para32[1] != (SK_U32)-1) {
2670 SK_DBG_MSG(pAC, SK_DBGMOD_RLMT, SK_DBGCAT_CTRL,
2671 ("Bad Parameter.\n"))
2672 SK_DBG_MSG(pAC, SK_DBGMOD_RLMT, SK_DBGCAT_CTRL,
2673 ("SK_RLMT_SEG_TIM Event EMPTY.\n"))
2674 return;
2675 }
2676
2677#ifdef xDEBUG
2678 for (j = 0; j < pAC->Rlmt.Net[Para.Para32[0]].NumPorts; j++) {
2679 SK_ADDR_PORT *pAPort;
2680 SK_U32 k;
2681 SK_U16 *InAddr;
2682 SK_U8 InAddr8[6];
2683
2684 InAddr = (SK_U16 *)&InAddr8[0];
2685 pAPort = pAC->Rlmt.Net[Para.Para32[0]].Port[j]->AddrPort;
2686 for (k = 0; k < pAPort->NextExactMatchRlmt; k++) {
2687 /* Get exact match address k from port j. */
2688 XM_INADDR(IoC, pAC->Rlmt.Net[Para.Para32[0]].Port[j]->PortNumber,
2689 XM_EXM(k), InAddr);
2690 SK_DBG_MSG(pAC, SK_DBGMOD_RLMT, SK_DBGCAT_CTRL,
2691 ("MC address %d on Port %u: %02x %02x %02x %02x %02x %02x -- %02x %02x %02x %02x %02x %02x.\n",
2692 k, pAC->Rlmt.Net[Para.Para32[0]].Port[j]->PortNumber,
2693 InAddr8[0], InAddr8[1], InAddr8[2],
2694 InAddr8[3], InAddr8[4], InAddr8[5],
2695 pAPort->Exact[k].a[0], pAPort->Exact[k].a[1],
2696 pAPort->Exact[k].a[2], pAPort->Exact[k].a[3],
2697 pAPort->Exact[k].a[4], pAPort->Exact[k].a[5]))
2698 }
2699 }
2700#endif /* xDEBUG */
2701
2702 SkRlmtCheckSeg(pAC, IoC, Para.Para32[0]);
2703
2704 SK_DBG_MSG(pAC, SK_DBGMOD_RLMT, SK_DBGCAT_CTRL,
2705 ("SK_RLMT_SEG_TIM Event END.\n"))
2706} /* SkRlmtEvtSegTim */
2707
2708
2709/******************************************************************************
2710 *
2711 * SkRlmtEvtPacketRx - PACKET_RECEIVED
2712 *
2713 * Description:
2714 * This routine handles PACKET_RECEIVED events.
2715 *
2716 * Context:
2717 * runtime, pageable?
2718 * may be called after SK_INIT_IO
2719 *
2720 * Returns:
2721 * Nothing
2722 */
2723RLMT_STATIC void SkRlmtEvtPacketRx(
2724SK_AC *pAC, /* Adapter Context */
2725SK_IOC IoC, /* I/O Context */
2726SK_EVPARA Para) /* SK_MBUF *pMb */
2727{
2728 SK_MBUF *pMb;
2729 SK_MBUF *pNextMb;
2730 SK_U32 NetNumber;
2731
2732
2733 SK_DBG_MSG(pAC, SK_DBGMOD_RLMT, SK_DBGCAT_CTRL,
2734 ("SK_RLMT_PACKET_RECEIVED Event BEGIN.\n"))
2735
2736 /* Should we ignore frames during port switching? */
2737
2738#ifdef DEBUG
2739 pMb = Para.pParaPtr;
2740 if (pMb == NULL) {
2741 SK_DBG_MSG(pAC, SK_DBGMOD_RLMT, SK_DBGCAT_CTRL, ("No mbuf.\n"))
2742 }
2743 else if (pMb->pNext != NULL) {
2744 SK_DBG_MSG(pAC, SK_DBGMOD_RLMT, SK_DBGCAT_CTRL,
2745 ("More than one mbuf or pMb->pNext not set.\n"))
2746 }
2747#endif /* DEBUG */
2748
2749 for (pMb = Para.pParaPtr; pMb != NULL; pMb = pNextMb) {
2750 pNextMb = pMb->pNext;
2751 pMb->pNext = NULL;
2752
2753 NetNumber = pAC->Rlmt.Port[pMb->PortIdx].Net->NetNumber;
2754 if (pAC->Rlmt.Net[NetNumber].RlmtState == SK_RLMT_RS_INIT) {
2755 SkDrvFreeRlmtMbuf(pAC, IoC, pMb);
2756 }
2757 else {
2758 SkRlmtPacketReceive(pAC, IoC, pMb);
2759 }
2760 }
2761
2762 SK_DBG_MSG(pAC, SK_DBGMOD_RLMT, SK_DBGCAT_CTRL,
2763 ("SK_RLMT_PACKET_RECEIVED Event END.\n"))
2764} /* SkRlmtEvtPacketRx */
2765
2766
2767/******************************************************************************
2768 *
2769 * SkRlmtEvtStatsClear - STATS_CLEAR
2770 *
2771 * Description:
2772 * This routine handles STATS_CLEAR events.
2773 *
2774 * Context:
2775 * runtime, pageable?
2776 * may be called after SK_INIT_IO
2777 *
2778 * Returns:
2779 * Nothing
2780 */
2781RLMT_STATIC void SkRlmtEvtStatsClear(
2782SK_AC *pAC, /* Adapter Context */
2783SK_IOC IoC, /* I/O Context */
2784SK_EVPARA Para) /* SK_U32 NetNumber; SK_U32 -1 */
2785{
2786 SK_U32 i;
2787 SK_RLMT_PORT *pRPort;
2788
2789 SK_DBG_MSG(pAC, SK_DBGMOD_RLMT, SK_DBGCAT_CTRL,
2790 ("SK_RLMT_STATS_CLEAR Event BEGIN.\n"))
2791
2792 if (Para.Para32[1] != (SK_U32)-1) {
2793 SK_DBG_MSG(pAC, SK_DBGMOD_RLMT, SK_DBGCAT_CTRL,
2794 ("Bad Parameter.\n"))
2795 SK_DBG_MSG(pAC, SK_DBGMOD_RLMT, SK_DBGCAT_CTRL,
2796 ("SK_RLMT_STATS_CLEAR Event EMPTY.\n"))
2797 return;
2798 }
2799
2800 if (Para.Para32[0] >= pAC->Rlmt.NumNets) {
2801 SK_DBG_MSG(pAC, SK_DBGMOD_RLMT, SK_DBGCAT_CTRL,
2802 ("Bad NetNumber %d.\n", Para.Para32[0]))
2803 SK_DBG_MSG(pAC, SK_DBGMOD_RLMT, SK_DBGCAT_CTRL,
2804 ("SK_RLMT_STATS_CLEAR Event EMPTY.\n"))
2805 return;
2806 }
2807
2808 /* Clear statistics for logical and physical ports. */
2809 for (i = 0; i < pAC->Rlmt.Net[Para.Para32[0]].NumPorts; i++) {
2810 pRPort =
2811 &pAC->Rlmt.Port[pAC->Rlmt.Net[Para.Para32[0]].Port[i]->PortNumber];
2812 pRPort->TxHelloCts = 0;
2813 pRPort->RxHelloCts = 0;
2814 pRPort->TxSpHelloReqCts = 0;
2815 pRPort->RxSpHelloCts = 0;
2816 }
2817
2818 SK_DBG_MSG(pAC, SK_DBGMOD_RLMT, SK_DBGCAT_CTRL,
2819 ("SK_RLMT_STATS_CLEAR Event END.\n"))
2820} /* SkRlmtEvtStatsClear */
2821
2822
2823/******************************************************************************
2824 *
2825 * SkRlmtEvtStatsUpdate - STATS_UPDATE
2826 *
2827 * Description:
2828 * This routine handles STATS_UPDATE events.
2829 *
2830 * Context:
2831 * runtime, pageable?
2832 * may be called after SK_INIT_IO
2833 *
2834 * Returns:
2835 * Nothing
2836 */
2837RLMT_STATIC void SkRlmtEvtStatsUpdate(
2838SK_AC *pAC, /* Adapter Context */
2839SK_IOC IoC, /* I/O Context */
2840SK_EVPARA Para) /* SK_U32 NetNumber; SK_U32 -1 */
2841{
2842 SK_DBG_MSG(pAC, SK_DBGMOD_RLMT, SK_DBGCAT_CTRL,
2843 ("SK_RLMT_STATS_UPDATE Event BEGIN.\n"))
2844
2845 if (Para.Para32[1] != (SK_U32)-1) {
2846 SK_DBG_MSG(pAC, SK_DBGMOD_RLMT, SK_DBGCAT_CTRL,
2847 ("Bad Parameter.\n"))
2848 SK_DBG_MSG(pAC, SK_DBGMOD_RLMT, SK_DBGCAT_CTRL,
2849 ("SK_RLMT_STATS_UPDATE Event EMPTY.\n"))
2850 return;
2851 }
2852
2853 if (Para.Para32[0] >= pAC->Rlmt.NumNets) {
2854 SK_DBG_MSG(pAC, SK_DBGMOD_RLMT, SK_DBGCAT_CTRL,
2855 ("Bad NetNumber %d.\n", Para.Para32[0]))
2856 SK_DBG_MSG(pAC, SK_DBGMOD_RLMT, SK_DBGCAT_CTRL,
2857 ("SK_RLMT_STATS_UPDATE Event EMPTY.\n"))
2858 return;
2859 }
2860
2861 /* Update statistics - currently always up-to-date. */
2862
2863 SK_DBG_MSG(pAC, SK_DBGMOD_RLMT, SK_DBGCAT_CTRL,
2864 ("SK_RLMT_STATS_UPDATE Event END.\n"))
2865} /* SkRlmtEvtStatsUpdate */
2866
2867
2868/******************************************************************************
2869 *
2870 * SkRlmtEvtPrefportChange - PREFPORT_CHANGE
2871 *
2872 * Description:
2873 * This routine handles PREFPORT_CHANGE events.
2874 *
2875 * Context:
2876 * runtime, pageable?
2877 * may be called after SK_INIT_IO
2878 *
2879 * Returns:
2880 * Nothing
2881 */
2882RLMT_STATIC void SkRlmtEvtPrefportChange(
2883SK_AC *pAC, /* Adapter Context */
2884SK_IOC IoC, /* I/O Context */
2885SK_EVPARA Para) /* SK_U32 PortIndex; SK_U32 NetNumber */
2886{
2887 SK_DBG_MSG(pAC, SK_DBGMOD_RLMT, SK_DBGCAT_CTRL,
2888 ("SK_RLMT_PREFPORT_CHANGE to Port %d Event BEGIN.\n", Para.Para32[0]))
2889
2890 if (Para.Para32[1] >= pAC->Rlmt.NumNets) {
2891 SK_DBG_MSG(pAC, SK_DBGMOD_RLMT, SK_DBGCAT_CTRL,
2892 ("Bad NetNumber %d.\n", Para.Para32[1]))
2893 SK_DBG_MSG(pAC, SK_DBGMOD_RLMT, SK_DBGCAT_CTRL,
2894 ("SK_RLMT_PREFPORT_CHANGE Event EMPTY.\n"))
2895 return;
2896 }
2897
2898 /* 0xFFFFFFFF == auto-mode. */
2899 if (Para.Para32[0] == 0xFFFFFFFF) {
2900 pAC->Rlmt.Net[Para.Para32[1]].PrefPort = SK_RLMT_DEF_PREF_PORT;
2901 }
2902 else {
2903 if (Para.Para32[0] >= pAC->Rlmt.Net[Para.Para32[1]].NumPorts) {
2904 SK_ERR_LOG(pAC, SK_ERRCL_SW, SKERR_RLMT_E010, SKERR_RLMT_E010_MSG);
2905
2906 SK_DBG_MSG(pAC, SK_DBGMOD_RLMT, SK_DBGCAT_CTRL,
2907 ("SK_RLMT_PREFPORT_CHANGE Event EMPTY.\n"))
2908 return;
2909 }
2910
2911 pAC->Rlmt.Net[Para.Para32[1]].PrefPort = Para.Para32[0];
2912 }
2913
2914 pAC->Rlmt.Net[Para.Para32[1]].Preference = Para.Para32[0];
2915
2916 if (pAC->Rlmt.Net[Para.Para32[1]].RlmtState != SK_RLMT_RS_INIT) {
2917 SkRlmtCheckSwitch(pAC, IoC, Para.Para32[1]);
2918 }
2919
2920 SK_DBG_MSG(pAC, SK_DBGMOD_RLMT, SK_DBGCAT_CTRL,
2921 ("SK_RLMT_PREFPORT_CHANGE Event END.\n"))
2922} /* SkRlmtEvtPrefportChange */
2923
2924
2925/******************************************************************************
2926 *
2927 * SkRlmtEvtSetNets - SET_NETS
2928 *
2929 * Description:
2930 * This routine handles SET_NETS events.
2931 *
2932 * Context:
2933 * runtime, pageable?
2934 * may be called after SK_INIT_IO
2935 *
2936 * Returns:
2937 * Nothing
2938 */
2939RLMT_STATIC void SkRlmtEvtSetNets(
2940SK_AC *pAC, /* Adapter Context */
2941SK_IOC IoC, /* I/O Context */
2942SK_EVPARA Para) /* SK_U32 NumNets; SK_U32 -1 */
2943{
2944 int i;
2945
2946 SK_DBG_MSG(pAC, SK_DBGMOD_RLMT, SK_DBGCAT_CTRL,
2947 ("SK_RLMT_SET_NETS Event BEGIN.\n"))
2948
2949 if (Para.Para32[1] != (SK_U32)-1) {
2950 SK_DBG_MSG(pAC, SK_DBGMOD_RLMT, SK_DBGCAT_CTRL,
2951 ("Bad Parameter.\n"))
2952 SK_DBG_MSG(pAC, SK_DBGMOD_RLMT, SK_DBGCAT_CTRL,
2953 ("SK_RLMT_SET_NETS Event EMPTY.\n"))
2954 return;
2955 }
2956
2957 if (Para.Para32[0] == 0 || Para.Para32[0] > SK_MAX_NETS ||
2958 Para.Para32[0] > (SK_U32)pAC->GIni.GIMacsFound) {
2959 SK_DBG_MSG(pAC, SK_DBGMOD_RLMT, SK_DBGCAT_CTRL,
2960 ("Bad number of nets: %d.\n", Para.Para32[0]))
2961 SK_DBG_MSG(pAC, SK_DBGMOD_RLMT, SK_DBGCAT_CTRL,
2962 ("SK_RLMT_SET_NETS Event EMPTY.\n"))
2963 return;
2964 }
2965
2966 if (Para.Para32[0] == pAC->Rlmt.NumNets) { /* No change. */
2967 SK_DBG_MSG(pAC, SK_DBGMOD_RLMT, SK_DBGCAT_CTRL,
2968 ("SK_RLMT_SET_NETS Event EMPTY.\n"))
2969 return;
2970 }
2971
2972 /* Entering and leaving dual mode only allowed while nets are stopped. */
2973 if (pAC->Rlmt.NetsStarted > 0) {
2974 SK_DBG_MSG(pAC, SK_DBGMOD_RLMT, SK_DBGCAT_CTRL,
2975 ("Changing dual mode only allowed while all nets are stopped.\n"))
2976 SK_DBG_MSG(pAC, SK_DBGMOD_RLMT, SK_DBGCAT_CTRL,
2977 ("SK_RLMT_SET_NETS Event EMPTY.\n"))
2978 return;
2979 }
2980
2981 if (Para.Para32[0] == 1) {
2982 if (pAC->Rlmt.NumNets > 1) {
2983 /* Clear logical MAC addr from second net's active port. */
2984 (void)SkAddrOverride(pAC, IoC, pAC->Rlmt.Net[1].Port[pAC->Addr.
2985 Net[1].ActivePort]->PortNumber, NULL, SK_ADDR_CLEAR_LOGICAL);
2986 pAC->Rlmt.Net[1].NumPorts = 0;
2987 }
2988
2989 pAC->Rlmt.NumNets = Para.Para32[0];
2990 for (i = 0; (SK_U32)i < pAC->Rlmt.NumNets; i++) {
2991 pAC->Rlmt.Net[i].RlmtState = SK_RLMT_RS_INIT;
2992 pAC->Rlmt.Net[i].RootIdSet = SK_FALSE;
2993 pAC->Rlmt.Net[i].Preference = 0xFFFFFFFF; /* "Automatic" */
2994 pAC->Rlmt.Net[i].PrefPort = SK_RLMT_DEF_PREF_PORT;
2995 /* Just assuming. */
2996 pAC->Rlmt.Net[i].ActivePort = pAC->Rlmt.Net[i].PrefPort;
2997 pAC->Rlmt.Net[i].RlmtMode = SK_RLMT_DEF_MODE;
2998 pAC->Rlmt.Net[i].TimeoutValue = SK_RLMT_DEF_TO_VAL;
2999 pAC->Rlmt.Net[i].NetNumber = i;
3000 }
3001
3002 pAC->Rlmt.Port[1].Net= &pAC->Rlmt.Net[0];
3003 pAC->Rlmt.Net[0].NumPorts = pAC->GIni.GIMacsFound;
3004
3005 SkEventQueue(pAC, SKGE_PNMI, SK_PNMI_EVT_RLMT_SET_NETS, Para);
3006
3007 SK_DBG_MSG(pAC, SK_DBGMOD_RLMT, SK_DBGCAT_CTRL,
3008 ("RLMT: Changed to one net with two ports.\n"))
3009 }
3010 else if (Para.Para32[0] == 2) {
3011 pAC->Rlmt.Port[1].Net= &pAC->Rlmt.Net[1];
3012 pAC->Rlmt.Net[1].NumPorts = pAC->GIni.GIMacsFound - 1;
3013 pAC->Rlmt.Net[0].NumPorts =
3014 pAC->GIni.GIMacsFound - pAC->Rlmt.Net[1].NumPorts;
3015
3016 pAC->Rlmt.NumNets = Para.Para32[0];
3017 for (i = 0; (SK_U32)i < pAC->Rlmt.NumNets; i++) {
3018 pAC->Rlmt.Net[i].RlmtState = SK_RLMT_RS_INIT;
3019 pAC->Rlmt.Net[i].RootIdSet = SK_FALSE;
3020 pAC->Rlmt.Net[i].Preference = 0xFFFFFFFF; /* "Automatic" */
3021 pAC->Rlmt.Net[i].PrefPort = SK_RLMT_DEF_PREF_PORT;
3022 /* Just assuming. */
3023 pAC->Rlmt.Net[i].ActivePort = pAC->Rlmt.Net[i].PrefPort;
3024 pAC->Rlmt.Net[i].RlmtMode = SK_RLMT_DEF_MODE;
3025 pAC->Rlmt.Net[i].TimeoutValue = SK_RLMT_DEF_TO_VAL;
3026
3027 pAC->Rlmt.Net[i].NetNumber = i;
3028 }
3029
3030 /* Set logical MAC addr on second net's active port. */
3031 (void)SkAddrOverride(pAC, IoC, pAC->Rlmt.Net[1].Port[pAC->Addr.
3032 Net[1].ActivePort]->PortNumber, NULL, SK_ADDR_SET_LOGICAL);
3033
3034 SkEventQueue(pAC, SKGE_PNMI, SK_PNMI_EVT_RLMT_SET_NETS, Para);
3035
3036 SK_DBG_MSG(pAC, SK_DBGMOD_RLMT, SK_DBGCAT_CTRL,
3037 ("RLMT: Changed to two nets with one port each.\n"))
3038 }
3039 else {
3040 /* Not implemented for more than two nets. */
3041 SK_DBG_MSG(pAC, SK_DBGMOD_RLMT, SK_DBGCAT_CTRL,
3042 ("SetNets not implemented for more than two nets.\n"))
3043 SK_DBG_MSG(pAC, SK_DBGMOD_RLMT, SK_DBGCAT_CTRL,
3044 ("SK_RLMT_SET_NETS Event EMPTY.\n"))
3045 return;
3046 }
3047
3048 SK_DBG_MSG(pAC, SK_DBGMOD_RLMT, SK_DBGCAT_CTRL,
3049 ("SK_RLMT_SET_NETS Event END.\n"))
3050} /* SkRlmtSetNets */
3051
3052
3053/******************************************************************************
3054 *
3055 * SkRlmtEvtModeChange - MODE_CHANGE
3056 *
3057 * Description:
3058 * This routine handles MODE_CHANGE events.
3059 *
3060 * Context:
3061 * runtime, pageable?
3062 * may be called after SK_INIT_IO
3063 *
3064 * Returns:
3065 * Nothing
3066 */
3067RLMT_STATIC void SkRlmtEvtModeChange(
3068SK_AC *pAC, /* Adapter Context */
3069SK_IOC IoC, /* I/O Context */
3070SK_EVPARA Para) /* SK_U32 NewMode; SK_U32 NetNumber */
3071{
3072 SK_EVPARA Para2;
3073 SK_U32 i;
3074 SK_U32 PrevRlmtMode;
3075
3076 SK_DBG_MSG(pAC, SK_DBGMOD_RLMT, SK_DBGCAT_CTRL,
3077 ("SK_RLMT_MODE_CHANGE Event BEGIN.\n"))
3078
3079 if (Para.Para32[1] >= pAC->Rlmt.NumNets) {
3080 SK_DBG_MSG(pAC, SK_DBGMOD_RLMT, SK_DBGCAT_CTRL,
3081 ("Bad NetNumber %d.\n", Para.Para32[1]))
3082 SK_DBG_MSG(pAC, SK_DBGMOD_RLMT, SK_DBGCAT_CTRL,
3083 ("SK_RLMT_MODE_CHANGE Event EMPTY.\n"))
3084 return;
3085 }
3086
3087 Para.Para32[0] |= SK_RLMT_CHECK_LINK;
3088
3089 if ((pAC->Rlmt.Net[Para.Para32[1]].NumPorts == 1) &&
3090 Para.Para32[0] != SK_RLMT_MODE_CLS) {
3091 pAC->Rlmt.Net[Para.Para32[1]].RlmtMode = SK_RLMT_MODE_CLS;
3092 SK_DBG_MSG(pAC, SK_DBGMOD_RLMT, SK_DBGCAT_CTRL,
3093 ("Forced RLMT mode to CLS on single port net.\n"))
3094 SK_DBG_MSG(pAC, SK_DBGMOD_RLMT, SK_DBGCAT_CTRL,
3095 ("SK_RLMT_MODE_CHANGE Event EMPTY.\n"))
3096 return;
3097 }
3098
3099 /* Update RLMT mode. */
3100 PrevRlmtMode = pAC->Rlmt.Net[Para.Para32[1]].RlmtMode;
3101 pAC->Rlmt.Net[Para.Para32[1]].RlmtMode = Para.Para32[0];
3102
3103 if ((PrevRlmtMode & SK_RLMT_CHECK_LOC_LINK) !=
3104 (pAC->Rlmt.Net[Para.Para32[1]].RlmtMode & SK_RLMT_CHECK_LOC_LINK)) {
3105 /* SK_RLMT_CHECK_LOC_LINK bit changed. */
3106 if ((PrevRlmtMode & SK_RLMT_CHECK_OTHERS) == 0 &&
3107 pAC->Rlmt.Net[Para.Para32[1]].NumPorts > 1 &&
3108 pAC->Rlmt.Net[Para.Para32[1]].PortsUp >= 1) {
3109 /* 20001207 RA: Was "PortsUp == 1". */
3110 Para2.Para32[0] = Para.Para32[1];
3111 Para2.Para32[1] = (SK_U32)-1;
3112 SkTimerStart(pAC, IoC, &pAC->Rlmt.Net[Para.Para32[1]].LocTimer,
3113 pAC->Rlmt.Net[Para.Para32[1]].TimeoutValue,
3114 SKGE_RLMT, SK_RLMT_TIM, Para2);
3115 }
3116 }
3117
3118 if ((PrevRlmtMode & SK_RLMT_CHECK_SEG) !=
3119 (pAC->Rlmt.Net[Para.Para32[1]].RlmtMode & SK_RLMT_CHECK_SEG)) {
3120 /* SK_RLMT_CHECK_SEG bit changed. */
3121 for (i = 0; i < pAC->Rlmt.Net[Para.Para32[1]].NumPorts; i++) {
3122 (void)SkAddrMcClear(pAC, IoC,
3123 pAC->Rlmt.Net[Para.Para32[1]].Port[i]->PortNumber,
3124 SK_ADDR_PERMANENT | SK_MC_SW_ONLY);
3125
3126 /* Add RLMT MC address. */
3127 (void)SkAddrMcAdd(pAC, IoC,
3128 pAC->Rlmt.Net[Para.Para32[1]].Port[i]->PortNumber,
3129 &SkRlmtMcAddr, SK_ADDR_PERMANENT);
3130
3131 if ((pAC->Rlmt.Net[Para.Para32[1]].RlmtMode &
3132 SK_RLMT_CHECK_SEG) != 0) {
3133 /* Add BPDU MC address. */
3134 (void)SkAddrMcAdd(pAC, IoC,
3135 pAC->Rlmt.Net[Para.Para32[1]].Port[i]->PortNumber,
3136 &BridgeMcAddr, SK_ADDR_PERMANENT);
3137
3138 if (pAC->Rlmt.Net[Para.Para32[1]].RlmtState != SK_RLMT_RS_INIT) {
3139 if (!pAC->Rlmt.Net[Para.Para32[1]].Port[i]->LinkDown &&
3140 (Para2.pParaPtr = SkRlmtBuildSpanningTreePacket(
3141 pAC, IoC, i)) != NULL) {
3142 pAC->Rlmt.Net[Para.Para32[1]].Port[i]->RootIdSet =
3143 SK_FALSE;
3144 SkEventQueue(pAC, SKGE_DRV, SK_DRV_RLMT_SEND, Para2);
3145 }
3146 }
3147 }
3148 (void)SkAddrMcUpdate(pAC, IoC,
3149 pAC->Rlmt.Net[Para.Para32[1]].Port[i]->PortNumber);
3150 } /* for ... */
3151
3152 if ((pAC->Rlmt.Net[Para.Para32[1]].RlmtMode & SK_RLMT_CHECK_SEG) != 0) {
3153 Para2.Para32[0] = Para.Para32[1];
3154 Para2.Para32[1] = (SK_U32)-1;
3155 SkTimerStart(pAC, IoC, &pAC->Rlmt.Net[Para.Para32[1]].SegTimer,
3156 SK_RLMT_SEG_TO_VAL, SKGE_RLMT, SK_RLMT_SEG_TIM, Para2);
3157 }
3158 } /* SK_RLMT_CHECK_SEG bit changed. */
3159
3160 SK_DBG_MSG(pAC, SK_DBGMOD_RLMT, SK_DBGCAT_CTRL,
3161 ("SK_RLMT_MODE_CHANGE Event END.\n"))
3162} /* SkRlmtEvtModeChange */
3163
3164
3165/******************************************************************************
3166 *
3167 * SkRlmtEvent - a PORT- or an RLMT-specific event happened
3168 *
3169 * Description:
3170 * This routine calls subroutines to handle PORT- and RLMT-specific events.
3171 *
3172 * Context:
3173 * runtime, pageable?
3174 * may be called after SK_INIT_IO
3175 *
3176 * Returns:
3177 * 0
3178 */
3179int SkRlmtEvent(
3180SK_AC *pAC, /* Adapter Context */
3181SK_IOC IoC, /* I/O Context */
3182SK_U32 Event, /* Event code */
3183SK_EVPARA Para) /* Event-specific parameter */
3184{
3185 switch (Event) {
3186
3187 /* ----- PORT events ----- */
3188
3189 case SK_RLMT_PORTSTART_TIM: /* From RLMT via TIME. */
3190 SkRlmtEvtPortStartTim(pAC, IoC, Para);
3191 break;
3192 case SK_RLMT_LINK_UP: /* From SIRQ. */
3193 SkRlmtEvtLinkUp(pAC, IoC, Para);
3194 break;
3195 case SK_RLMT_PORTUP_TIM: /* From RLMT via TIME. */
3196 SkRlmtEvtPortUpTim(pAC, IoC, Para);
3197 break;
3198 case SK_RLMT_PORTDOWN: /* From RLMT. */
3199 case SK_RLMT_PORTDOWN_RX_TIM: /* From RLMT via TIME. */
3200 case SK_RLMT_PORTDOWN_TX_TIM: /* From RLMT via TIME. */
3201 SkRlmtEvtPortDownX(pAC, IoC, Event, Para);
3202 break;
3203 case SK_RLMT_LINK_DOWN: /* From SIRQ. */
3204 SkRlmtEvtLinkDown(pAC, IoC, Para);
3205 break;
3206 case SK_RLMT_PORT_ADDR: /* From ADDR. */
3207 SkRlmtEvtPortAddr(pAC, IoC, Para);
3208 break;
3209
3210 /* ----- RLMT events ----- */
3211
3212 case SK_RLMT_START: /* From DRV. */
3213 SkRlmtEvtStart(pAC, IoC, Para);
3214 break;
3215 case SK_RLMT_STOP: /* From DRV. */
3216 SkRlmtEvtStop(pAC, IoC, Para);
3217 break;
3218 case SK_RLMT_TIM: /* From RLMT via TIME. */
3219 SkRlmtEvtTim(pAC, IoC, Para);
3220 break;
3221 case SK_RLMT_SEG_TIM:
3222 SkRlmtEvtSegTim(pAC, IoC, Para);
3223 break;
3224 case SK_RLMT_PACKET_RECEIVED: /* From DRV. */
3225 SkRlmtEvtPacketRx(pAC, IoC, Para);
3226 break;
3227 case SK_RLMT_STATS_CLEAR: /* From PNMI. */
3228 SkRlmtEvtStatsClear(pAC, IoC, Para);
3229 break;
3230 case SK_RLMT_STATS_UPDATE: /* From PNMI. */
3231 SkRlmtEvtStatsUpdate(pAC, IoC, Para);
3232 break;
3233 case SK_RLMT_PREFPORT_CHANGE: /* From PNMI. */
3234 SkRlmtEvtPrefportChange(pAC, IoC, Para);
3235 break;
3236 case SK_RLMT_MODE_CHANGE: /* From PNMI. */
3237 SkRlmtEvtModeChange(pAC, IoC, Para);
3238 break;
3239 case SK_RLMT_SET_NETS: /* From DRV. */
3240 SkRlmtEvtSetNets(pAC, IoC, Para);
3241 break;
3242
3243 /* ----- Unknown events ----- */
3244
3245 default: /* Create error log entry. */
3246 SK_DBG_MSG(pAC, SK_DBGMOD_RLMT, SK_DBGCAT_CTRL,
3247 ("Unknown RLMT Event %d.\n", Event))
3248 SK_ERR_LOG(pAC, SK_ERRCL_SW, SKERR_RLMT_E003, SKERR_RLMT_E003_MSG);
3249 break;
3250 } /* switch() */
3251
3252 return (0);
3253} /* SkRlmtEvent */
3254
3255#ifdef __cplusplus
3256}
3257#endif /* __cplusplus */
diff --git a/drivers/net/sk98lin/sktimer.c b/drivers/net/sk98lin/sktimer.c
new file mode 100644
index 000000000000..4e462955ecd8
--- /dev/null
+++ b/drivers/net/sk98lin/sktimer.c
@@ -0,0 +1,250 @@
1/******************************************************************************
2 *
3 * Name: sktimer.c
4 * Project: Gigabit Ethernet Adapters, Event Scheduler Module
5 * Version: $Revision: 1.14 $
6 * Date: $Date: 2003/09/16 13:46:51 $
7 * Purpose: High level timer functions.
8 *
9 ******************************************************************************/
10
11/******************************************************************************
12 *
13 * (C)Copyright 1998-2002 SysKonnect GmbH.
14 * (C)Copyright 2002-2003 Marvell.
15 *
16 * This program is free software; you can redistribute it and/or modify
17 * it under the terms of the GNU General Public License as published by
18 * the Free Software Foundation; either version 2 of the License, or
19 * (at your option) any later version.
20 *
21 * The information in this file is provided "AS IS" without warranty.
22 *
23 ******************************************************************************/
24
25
26/*
27 * Event queue and dispatcher
28 */
29#if (defined(DEBUG) || ((!defined(LINT)) && (!defined(SK_SLIM))))
30static const char SysKonnectFileId[] =
31 "@(#) $Id: sktimer.c,v 1.14 2003/09/16 13:46:51 rschmidt Exp $ (C) Marvell.";
32#endif
33
34#include "h/skdrv1st.h" /* Driver Specific Definitions */
35#include "h/skdrv2nd.h" /* Adapter Control- and Driver specific Def. */
36
37#ifdef __C2MAN__
38/*
39 Event queue management.
40
41 General Description:
42
43 */
44intro()
45{}
46#endif
47
48
49/* Forward declaration */
50static void timer_done(SK_AC *pAC,SK_IOC Ioc,int Restart);
51
52
53/*
54 * Inits the software timer
55 *
56 * needs to be called during Init level 1.
57 */
58void SkTimerInit(
59SK_AC *pAC, /* Adapters context */
60SK_IOC Ioc, /* IoContext */
61int Level) /* Init Level */
62{
63 switch (Level) {
64 case SK_INIT_DATA:
65 pAC->Tim.StQueue = NULL;
66 break;
67 case SK_INIT_IO:
68 SkHwtInit(pAC, Ioc);
69 SkTimerDone(pAC, Ioc);
70 break;
71 default:
72 break;
73 }
74}
75
76/*
77 * Stops a high level timer
78 * - If a timer is not in the queue the function returns normally, too.
79 */
80void SkTimerStop(
81SK_AC *pAC, /* Adapters context */
82SK_IOC Ioc, /* IoContext */
83SK_TIMER *pTimer) /* Timer Pointer to be started */
84{
85 SK_TIMER **ppTimPrev;
86 SK_TIMER *pTm;
87
88 /*
89 * remove timer from queue
90 */
91 pTimer->TmActive = SK_FALSE;
92
93 if (pAC->Tim.StQueue == pTimer && !pTimer->TmNext) {
94 SkHwtStop(pAC, Ioc);
95 }
96
97 for (ppTimPrev = &pAC->Tim.StQueue; (pTm = *ppTimPrev);
98 ppTimPrev = &pTm->TmNext ) {
99
100 if (pTm == pTimer) {
101 /*
102 * Timer found in queue
103 * - dequeue it and
104 * - correct delta of the next timer
105 */
106 *ppTimPrev = pTm->TmNext;
107
108 if (pTm->TmNext) {
109 /* correct delta of next timer in queue */
110 pTm->TmNext->TmDelta += pTm->TmDelta;
111 }
112 return;
113 }
114 }
115}
116
117/*
118 * Start a high level software timer
119 */
120void SkTimerStart(
121SK_AC *pAC, /* Adapters context */
122SK_IOC Ioc, /* IoContext */
123SK_TIMER *pTimer, /* Timer Pointer to be started */
124SK_U32 Time, /* Time value */
125SK_U32 Class, /* Event Class for this timer */
126SK_U32 Event, /* Event Value for this timer */
127SK_EVPARA Para) /* Event Parameter for this timer */
128{
129 SK_TIMER **ppTimPrev;
130 SK_TIMER *pTm;
131 SK_U32 Delta;
132
133 Time /= 16; /* input is uS, clock ticks are 16uS */
134
135 if (!Time)
136 Time = 1;
137
138 SkTimerStop(pAC, Ioc, pTimer);
139
140 pTimer->TmClass = Class;
141 pTimer->TmEvent = Event;
142 pTimer->TmPara = Para;
143 pTimer->TmActive = SK_TRUE;
144
145 if (!pAC->Tim.StQueue) {
146 /* First Timer to be started */
147 pAC->Tim.StQueue = pTimer;
148 pTimer->TmNext = NULL;
149 pTimer->TmDelta = Time;
150
151 SkHwtStart(pAC, Ioc, Time);
152
153 return;
154 }
155
156 /*
157 * timer correction
158 */
159 timer_done(pAC, Ioc, 0);
160
161 /*
162 * find position in queue
163 */
164 Delta = 0;
165 for (ppTimPrev = &pAC->Tim.StQueue; (pTm = *ppTimPrev);
166 ppTimPrev = &pTm->TmNext ) {
167
168 if (Delta + pTm->TmDelta > Time) {
169 /* Position found */
170 /* Here the timer needs to be inserted. */
171 break;
172 }
173 Delta += pTm->TmDelta;
174 }
175
176 /* insert in queue */
177 *ppTimPrev = pTimer;
178 pTimer->TmNext = pTm;
179 pTimer->TmDelta = Time - Delta;
180
181 if (pTm) {
182 /* There is a next timer
183 * -> correct its Delta value.
184 */
185 pTm->TmDelta -= pTimer->TmDelta;
186 }
187
188 /* restart with first */
189 SkHwtStart(pAC, Ioc, pAC->Tim.StQueue->TmDelta);
190}
191
192
193void SkTimerDone(
194SK_AC *pAC, /* Adapters context */
195SK_IOC Ioc) /* IoContext */
196{
197 timer_done(pAC, Ioc, 1);
198}
199
200
201static void timer_done(
202SK_AC *pAC, /* Adapters context */
203SK_IOC Ioc, /* IoContext */
204int Restart) /* Do we need to restart the Hardware timer ? */
205{
206 SK_U32 Delta;
207 SK_TIMER *pTm;
208 SK_TIMER *pTComp; /* Timer completed now now */
209 SK_TIMER **ppLast; /* Next field of Last timer to be deq */
210 int Done = 0;
211
212 Delta = SkHwtRead(pAC, Ioc);
213
214 ppLast = &pAC->Tim.StQueue;
215 pTm = pAC->Tim.StQueue;
216 while (pTm && !Done) {
217 if (Delta >= pTm->TmDelta) {
218 /* Timer ran out */
219 pTm->TmActive = SK_FALSE;
220 Delta -= pTm->TmDelta;
221 ppLast = &pTm->TmNext;
222 pTm = pTm->TmNext;
223 }
224 else {
225 /* We found the first timer that did not run out */
226 pTm->TmDelta -= Delta;
227 Delta = 0;
228 Done = 1;
229 }
230 }
231 *ppLast = NULL;
232 /*
233 * pTm points to the first Timer that did not run out.
234 * StQueue points to the first Timer that run out.
235 */
236
237 for ( pTComp = pAC->Tim.StQueue; pTComp; pTComp = pTComp->TmNext) {
238 SkEventQueue(pAC,pTComp->TmClass, pTComp->TmEvent, pTComp->TmPara);
239 }
240
241 /* Set head of timer queue to the first timer that did not run out */
242 pAC->Tim.StQueue = pTm;
243
244 if (Restart && pAC->Tim.StQueue) {
245 /* Restart HW timer */
246 SkHwtStart(pAC, Ioc, pAC->Tim.StQueue->TmDelta);
247 }
248}
249
250/* End of file */
diff --git a/drivers/net/sk98lin/skvpd.c b/drivers/net/sk98lin/skvpd.c
new file mode 100644
index 000000000000..1e662aaebf84
--- /dev/null
+++ b/drivers/net/sk98lin/skvpd.c
@@ -0,0 +1,1091 @@
1/******************************************************************************
2 *
3 * Name: skvpd.c
4 * Project: GEnesis, PCI Gigabit Ethernet Adapter
5 * Version: $Revision: 1.37 $
6 * Date: $Date: 2003/01/13 10:42:45 $
7 * Purpose: Shared software to read and write VPD data
8 *
9 ******************************************************************************/
10
11/******************************************************************************
12 *
13 * (C)Copyright 1998-2003 SysKonnect GmbH.
14 *
15 * This program is free software; you can redistribute it and/or modify
16 * it under the terms of the GNU General Public License as published by
17 * the Free Software Foundation; either version 2 of the License, or
18 * (at your option) any later version.
19 *
20 * The information in this file is provided "AS IS" without warranty.
21 *
22 ******************************************************************************/
23
24/*
25 Please refer skvpd.txt for information how to include this module
26 */
27static const char SysKonnectFileId[] =
28 "@(#)$Id: skvpd.c,v 1.37 2003/01/13 10:42:45 rschmidt Exp $ (C) SK";
29
30#include "h/skdrv1st.h"
31#include "h/sktypes.h"
32#include "h/skdebug.h"
33#include "h/skdrv2nd.h"
34
35/*
36 * Static functions
37 */
38#ifndef SK_KR_PROTO
39static SK_VPD_PARA *vpd_find_para(
40 SK_AC *pAC,
41 const char *key,
42 SK_VPD_PARA *p);
43#else /* SK_KR_PROTO */
44static SK_VPD_PARA *vpd_find_para();
45#endif /* SK_KR_PROTO */
46
47/*
48 * waits for a completion of a VPD transfer
49 * The VPD transfer must complete within SK_TICKS_PER_SEC/16
50 *
51 * returns 0: success, transfer completes
52 * error exit(9) with a error message
53 */
54static int VpdWait(
55SK_AC *pAC, /* Adapters context */
56SK_IOC IoC, /* IO Context */
57int event) /* event to wait for (VPD_READ / VPD_write) completion*/
58{
59 SK_U64 start_time;
60 SK_U16 state;
61
62 SK_DBG_MSG(pAC,SK_DBGMOD_VPD, SK_DBGCAT_CTRL,
63 ("VPD wait for %s\n", event?"Write":"Read"));
64 start_time = SkOsGetTime(pAC);
65 do {
66 if (SkOsGetTime(pAC) - start_time > SK_TICKS_PER_SEC) {
67
68 /* Bug fix AF: Thu Mar 28 2002
69 * Do not call: VPD_STOP(pAC, IoC);
70 * A pending VPD read cycle can not be aborted by writing
71 * VPD_WRITE to the PCI_VPD_ADR_REG (VPD address register).
72 * Although the write threshold in the OUR-register protects
73 * VPD read only space from being overwritten this does not
74 * protect a VPD read from being `converted` into a VPD write
75 * operation (on the fly). As a consequence the VPD_STOP would
76 * delete VPD read only data. In case of any problems with the
77 * I2C bus we exit the loop here. The I2C read operation can
78 * not be aborted except by a reset (->LR).
79 */
80 SK_DBG_MSG(pAC, SK_DBGMOD_VPD, SK_DBGCAT_FATAL | SK_DBGCAT_ERR,
81 ("ERROR:VPD wait timeout\n"));
82 return(1);
83 }
84
85 VPD_IN16(pAC, IoC, PCI_VPD_ADR_REG, &state);
86
87 SK_DBG_MSG(pAC, SK_DBGMOD_VPD, SK_DBGCAT_CTRL,
88 ("state = %x, event %x\n",state,event));
89 } while((int)(state & PCI_VPD_FLAG) == event);
90
91 return(0);
92}
93
94#ifdef SKDIAG
95
96/*
97 * Read the dword at address 'addr' from the VPD EEPROM.
98 *
99 * Needed Time: MIN 1,3 ms MAX 2,6 ms
100 *
101 * Note: The DWord is returned in the endianess of the machine the routine
102 * is running on.
103 *
104 * Returns the data read.
105 */
106SK_U32 VpdReadDWord(
107SK_AC *pAC, /* Adapters context */
108SK_IOC IoC, /* IO Context */
109int addr) /* VPD address */
110{
111 SK_U32 Rtv;
112
113 /* start VPD read */
114 SK_DBG_MSG(pAC, SK_DBGMOD_VPD, SK_DBGCAT_CTRL,
115 ("VPD read dword at 0x%x\n",addr));
116 addr &= ~VPD_WRITE; /* ensure the R/W bit is set to read */
117
118 VPD_OUT16(pAC, IoC, PCI_VPD_ADR_REG, (SK_U16)addr);
119
120 /* ignore return code here */
121 (void)VpdWait(pAC, IoC, VPD_READ);
122
123 /* Don't swap here, it's a data stream of bytes */
124 Rtv = 0;
125
126 VPD_IN32(pAC, IoC, PCI_VPD_DAT_REG, &Rtv);
127
128 SK_DBG_MSG(pAC, SK_DBGMOD_VPD, SK_DBGCAT_CTRL,
129 ("VPD read dword data = 0x%x\n",Rtv));
130 return(Rtv);
131}
132
133#endif /* SKDIAG */
134
135/*
136 * Read one Stream of 'len' bytes of VPD data, starting at 'addr' from
137 * or to the I2C EEPROM.
138 *
139 * Returns number of bytes read / written.
140 */
141static int VpdWriteStream(
142SK_AC *pAC, /* Adapters context */
143SK_IOC IoC, /* IO Context */
144char *buf, /* data buffer */
145int Addr, /* VPD start address */
146int Len) /* number of bytes to read / to write */
147{
148 int i;
149 int j;
150 SK_U16 AdrReg;
151 int Rtv;
152 SK_U8 * pComp; /* Compare pointer */
153 SK_U8 Data; /* Input Data for Compare */
154
155 /* Init Compare Pointer */
156 pComp = (SK_U8 *) buf;
157
158 for (i = 0; i < Len; i++, buf++) {
159 if ((i%sizeof(SK_U32)) == 0) {
160 /*
161 * At the begin of each cycle read the Data Reg
162 * So it is initialized even if only a few bytes
163 * are written.
164 */
165 AdrReg = (SK_U16) Addr;
166 AdrReg &= ~VPD_WRITE; /* READ operation */
167
168 VPD_OUT16(pAC, IoC, PCI_VPD_ADR_REG, AdrReg);
169
170 /* Wait for termination */
171 Rtv = VpdWait(pAC, IoC, VPD_READ);
172 if (Rtv != 0) {
173 return(i);
174 }
175 }
176
177 /* Write current Byte */
178 VPD_OUT8(pAC, IoC, PCI_VPD_DAT_REG + (i%sizeof(SK_U32)),
179 *(SK_U8*)buf);
180
181 if (((i%sizeof(SK_U32)) == 3) || (i == (Len - 1))) {
182 /* New Address needs to be written to VPD_ADDR reg */
183 AdrReg = (SK_U16) Addr;
184 Addr += sizeof(SK_U32);
185 AdrReg |= VPD_WRITE; /* WRITE operation */
186
187 VPD_OUT16(pAC, IoC, PCI_VPD_ADR_REG, AdrReg);
188
189 /* Wait for termination */
190 Rtv = VpdWait(pAC, IoC, VPD_WRITE);
191 if (Rtv != 0) {
192 SK_DBG_MSG(pAC, SK_DBGMOD_VPD, SK_DBGCAT_ERR,
193 ("Write Timed Out\n"));
194 return(i - (i%sizeof(SK_U32)));
195 }
196
197 /*
198 * Now re-read to verify
199 */
200 AdrReg &= ~VPD_WRITE; /* READ operation */
201
202 VPD_OUT16(pAC, IoC, PCI_VPD_ADR_REG, AdrReg);
203
204 /* Wait for termination */
205 Rtv = VpdWait(pAC, IoC, VPD_READ);
206 if (Rtv != 0) {
207 SK_DBG_MSG(pAC, SK_DBGMOD_VPD, SK_DBGCAT_ERR,
208 ("Verify Timed Out\n"));
209 return(i - (i%sizeof(SK_U32)));
210 }
211
212 for (j = 0; j <= (int)(i%sizeof(SK_U32)); j++, pComp++) {
213
214 VPD_IN8(pAC, IoC, PCI_VPD_DAT_REG + j, &Data);
215
216 if (Data != *pComp) {
217 /* Verify Error */
218 SK_DBG_MSG(pAC, SK_DBGMOD_VPD, SK_DBGCAT_ERR,
219 ("WriteStream Verify Error\n"));
220 return(i - (i%sizeof(SK_U32)) + j);
221 }
222 }
223 }
224 }
225
226 return(Len);
227}
228
229
230/*
231 * Read one Stream of 'len' bytes of VPD data, starting at 'addr' from
232 * or to the I2C EEPROM.
233 *
234 * Returns number of bytes read / written.
235 */
236static int VpdReadStream(
237SK_AC *pAC, /* Adapters context */
238SK_IOC IoC, /* IO Context */
239char *buf, /* data buffer */
240int Addr, /* VPD start address */
241int Len) /* number of bytes to read / to write */
242{
243 int i;
244 SK_U16 AdrReg;
245 int Rtv;
246
247 for (i = 0; i < Len; i++, buf++) {
248 if ((i%sizeof(SK_U32)) == 0) {
249 /* New Address needs to be written to VPD_ADDR reg */
250 AdrReg = (SK_U16) Addr;
251 Addr += sizeof(SK_U32);
252 AdrReg &= ~VPD_WRITE; /* READ operation */
253
254 VPD_OUT16(pAC, IoC, PCI_VPD_ADR_REG, AdrReg);
255
256 /* Wait for termination */
257 Rtv = VpdWait(pAC, IoC, VPD_READ);
258 if (Rtv != 0) {
259 return(i);
260 }
261 }
262 VPD_IN8(pAC, IoC, PCI_VPD_DAT_REG + (i%sizeof(SK_U32)),
263 (SK_U8 *)buf);
264 }
265
266 return(Len);
267}
268
269/*
270 * Read ore writes 'len' bytes of VPD data, starting at 'addr' from
271 * or to the I2C EEPROM.
272 *
273 * Returns number of bytes read / written.
274 */
275static int VpdTransferBlock(
276SK_AC *pAC, /* Adapters context */
277SK_IOC IoC, /* IO Context */
278char *buf, /* data buffer */
279int addr, /* VPD start address */
280int len, /* number of bytes to read / to write */
281int dir) /* transfer direction may be VPD_READ or VPD_WRITE */
282{
283 int Rtv; /* Return value */
284 int vpd_rom_size;
285
286 SK_DBG_MSG(pAC, SK_DBGMOD_VPD, SK_DBGCAT_CTRL,
287 ("VPD %s block, addr = 0x%x, len = %d\n",
288 dir ? "write" : "read", addr, len));
289
290 if (len == 0)
291 return(0);
292
293 vpd_rom_size = pAC->vpd.rom_size;
294
295 if (addr > vpd_rom_size - 4) {
296 SK_DBG_MSG(pAC, SK_DBGMOD_VPD, SK_DBGCAT_ERR | SK_DBGCAT_FATAL,
297 ("Address error: 0x%x, exp. < 0x%x\n",
298 addr, vpd_rom_size - 4));
299 return(0);
300 }
301
302 if (addr + len > vpd_rom_size) {
303 len = vpd_rom_size - addr;
304 SK_DBG_MSG(pAC, SK_DBGMOD_VPD, SK_DBGCAT_ERR,
305 ("Warning: len was cut to %d\n", len));
306 }
307
308 if (dir == VPD_READ) {
309 Rtv = VpdReadStream(pAC, IoC, buf, addr, len);
310 }
311 else {
312 Rtv = VpdWriteStream(pAC, IoC, buf, addr, len);
313 }
314
315 return(Rtv);
316}
317
318#ifdef SKDIAG
319
320/*
321 * Read 'len' bytes of VPD data, starting at 'addr'.
322 *
323 * Returns number of bytes read.
324 */
325int VpdReadBlock(
326SK_AC *pAC, /* pAC pointer */
327SK_IOC IoC, /* IO Context */
328char *buf, /* buffer were the data should be stored */
329int addr, /* start reading at the VPD address */
330int len) /* number of bytes to read */
331{
332 return(VpdTransferBlock(pAC, IoC, buf, addr, len, VPD_READ));
333}
334
335/*
336 * Write 'len' bytes of *but to the VPD EEPROM, starting at 'addr'.
337 *
338 * Returns number of bytes writes.
339 */
340int VpdWriteBlock(
341SK_AC *pAC, /* pAC pointer */
342SK_IOC IoC, /* IO Context */
343char *buf, /* buffer, holds the data to write */
344int addr, /* start writing at the VPD address */
345int len) /* number of bytes to write */
346{
347 return(VpdTransferBlock(pAC, IoC, buf, addr, len, VPD_WRITE));
348}
349#endif /* SKDIAG */
350
351/*
352 * (re)initialize the VPD buffer
353 *
354 * Reads the VPD data from the EEPROM into the VPD buffer.
355 * Get the remaining read only and read / write space.
356 *
357 * return 0: success
358 * 1: fatal VPD error
359 */
360static int VpdInit(
361SK_AC *pAC, /* Adapters context */
362SK_IOC IoC) /* IO Context */
363{
364 SK_VPD_PARA *r, rp; /* RW or RV */
365 int i;
366 unsigned char x;
367 int vpd_size;
368 SK_U16 dev_id;
369 SK_U32 our_reg2;
370
371 SK_DBG_MSG(pAC, SK_DBGMOD_VPD, SK_DBGCAT_INIT, ("VpdInit .. "));
372
373 VPD_IN16(pAC, IoC, PCI_DEVICE_ID, &dev_id);
374
375 VPD_IN32(pAC, IoC, PCI_OUR_REG_2, &our_reg2);
376
377 pAC->vpd.rom_size = 256 << ((our_reg2 & PCI_VPD_ROM_SZ) >> 14);
378
379 /*
380 * this function might get used before the hardware is initialized
381 * therefore we cannot always trust in GIChipId
382 */
383 if (((pAC->vpd.v.vpd_status & VPD_VALID) == 0 &&
384 dev_id != VPD_DEV_ID_GENESIS) ||
385 ((pAC->vpd.v.vpd_status & VPD_VALID) != 0 &&
386 !pAC->GIni.GIGenesis)) {
387
388 /* for Yukon the VPD size is always 256 */
389 vpd_size = VPD_SIZE_YUKON;
390 }
391 else {
392 /* Genesis uses the maximum ROM size up to 512 for VPD */
393 if (pAC->vpd.rom_size > VPD_SIZE_GENESIS) {
394 vpd_size = VPD_SIZE_GENESIS;
395 }
396 else {
397 vpd_size = pAC->vpd.rom_size;
398 }
399 }
400
401 /* read the VPD data into the VPD buffer */
402 if (VpdTransferBlock(pAC, IoC, pAC->vpd.vpd_buf, 0, vpd_size, VPD_READ)
403 != vpd_size) {
404
405 SK_DBG_MSG(pAC, SK_DBGMOD_VPD, SK_DBGCAT_ERR,
406 ("Block Read Error\n"));
407 return(1);
408 }
409
410 pAC->vpd.vpd_size = vpd_size;
411
412 /* Asus K8V Se Deluxe bugfix. Correct VPD content */
413 /* MBo April 2004 */
414 if (((unsigned char)pAC->vpd.vpd_buf[0x3f] == 0x38) &&
415 ((unsigned char)pAC->vpd.vpd_buf[0x40] == 0x3c) &&
416 ((unsigned char)pAC->vpd.vpd_buf[0x41] == 0x45)) {
417 printk("sk98lin: Asus mainboard with buggy VPD? "
418 "Correcting data.\n");
419 pAC->vpd.vpd_buf[0x40] = 0x38;
420 }
421
422
423 /* find the end tag of the RO area */
424 if (!(r = vpd_find_para(pAC, VPD_RV, &rp))) {
425 SK_DBG_MSG(pAC, SK_DBGMOD_VPD, SK_DBGCAT_ERR | SK_DBGCAT_FATAL,
426 ("Encoding Error: RV Tag not found\n"));
427 return(1);
428 }
429
430 if (r->p_val + r->p_len > pAC->vpd.vpd_buf + vpd_size/2) {
431 SK_DBG_MSG(pAC,SK_DBGMOD_VPD,SK_DBGCAT_ERR | SK_DBGCAT_FATAL,
432 ("Encoding Error: Invalid VPD struct size\n"));
433 return(1);
434 }
435 pAC->vpd.v.vpd_free_ro = r->p_len - 1;
436
437 /* test the checksum */
438 for (i = 0, x = 0; (unsigned)i <= (unsigned)vpd_size/2 - r->p_len; i++) {
439 x += pAC->vpd.vpd_buf[i];
440 }
441
442 if (x != 0) {
443 /* checksum error */
444 SK_DBG_MSG(pAC, SK_DBGMOD_VPD, SK_DBGCAT_ERR | SK_DBGCAT_FATAL,
445 ("VPD Checksum Error\n"));
446 return(1);
447 }
448
449 /* find and check the end tag of the RW area */
450 if (!(r = vpd_find_para(pAC, VPD_RW, &rp))) {
451 SK_DBG_MSG(pAC, SK_DBGMOD_VPD, SK_DBGCAT_ERR | SK_DBGCAT_FATAL,
452 ("Encoding Error: RV Tag not found\n"));
453 return(1);
454 }
455
456 if (r->p_val < pAC->vpd.vpd_buf + vpd_size/2) {
457 SK_DBG_MSG(pAC, SK_DBGMOD_VPD, SK_DBGCAT_ERR | SK_DBGCAT_FATAL,
458 ("Encoding Error: Invalid VPD struct size\n"));
459 return(1);
460 }
461 pAC->vpd.v.vpd_free_rw = r->p_len;
462
463 /* everything seems to be ok */
464 if (pAC->GIni.GIChipId != 0) {
465 pAC->vpd.v.vpd_status |= VPD_VALID;
466 }
467
468 SK_DBG_MSG(pAC, SK_DBGMOD_VPD, SK_DBGCAT_INIT,
469 ("done. Free RO = %d, Free RW = %d\n",
470 pAC->vpd.v.vpd_free_ro, pAC->vpd.v.vpd_free_rw));
471
472 return(0);
473}
474
475/*
476 * find the Keyword 'key' in the VPD buffer and fills the
477 * parameter struct 'p' with it's values
478 *
479 * returns *p success
480 * 0: parameter was not found or VPD encoding error
481 */
482static SK_VPD_PARA *vpd_find_para(
483SK_AC *pAC, /* common data base */
484const char *key, /* keyword to find (e.g. "MN") */
485SK_VPD_PARA *p) /* parameter description struct */
486{
487 char *v ; /* points to VPD buffer */
488 int max; /* Maximum Number of Iterations */
489
490 v = pAC->vpd.vpd_buf;
491 max = 128;
492
493 SK_DBG_MSG(pAC, SK_DBGMOD_VPD, SK_DBGCAT_CTRL,
494 ("VPD find para %s .. ",key));
495
496 /* check mandatory resource type ID string (Product Name) */
497 if (*v != (char)RES_ID) {
498 SK_DBG_MSG(pAC, SK_DBGMOD_VPD, SK_DBGCAT_ERR | SK_DBGCAT_FATAL,
499 ("Error: 0x%x missing\n", RES_ID));
500 return NULL;
501 }
502
503 if (strcmp(key, VPD_NAME) == 0) {
504 p->p_len = VPD_GET_RES_LEN(v);
505 p->p_val = VPD_GET_VAL(v);
506 SK_DBG_MSG(pAC, SK_DBGMOD_VPD, SK_DBGCAT_CTRL,
507 ("found, len = %d\n", p->p_len));
508 return(p);
509 }
510
511 v += 3 + VPD_GET_RES_LEN(v) + 3;
512 for (;; ) {
513 if (SK_MEMCMP(key,v,2) == 0) {
514 p->p_len = VPD_GET_VPD_LEN(v);
515 p->p_val = VPD_GET_VAL(v);
516 SK_DBG_MSG(pAC, SK_DBGMOD_VPD, SK_DBGCAT_CTRL,
517 ("found, len = %d\n",p->p_len));
518 return(p);
519 }
520
521 /* exit when reaching the "RW" Tag or the maximum of itera. */
522 max--;
523 if (SK_MEMCMP(VPD_RW,v,2) == 0 || max == 0) {
524 break;
525 }
526
527 if (SK_MEMCMP(VPD_RV,v,2) == 0) {
528 v += 3 + VPD_GET_VPD_LEN(v) + 3; /* skip VPD-W */
529 }
530 else {
531 v += 3 + VPD_GET_VPD_LEN(v);
532 }
533 SK_DBG_MSG(pAC, SK_DBGMOD_VPD, SK_DBGCAT_CTRL,
534 ("scanning '%c%c' len = %d\n",v[0],v[1],v[2]));
535 }
536
537#ifdef DEBUG
538 SK_DBG_MSG(pAC, SK_DBGMOD_VPD, SK_DBGCAT_CTRL, ("not found\n"));
539 if (max == 0) {
540 SK_DBG_MSG(pAC, SK_DBGMOD_VPD, SK_DBGCAT_ERR | SK_DBGCAT_FATAL,
541 ("Key/Len Encoding error\n"));
542 }
543#endif /* DEBUG */
544 return NULL;
545}
546
547/*
548 * Move 'n' bytes. Begin with the last byte if 'n' is > 0,
549 * Start with the last byte if n is < 0.
550 *
551 * returns nothing
552 */
553static void vpd_move_para(
554char *start, /* start of memory block */
555char *end, /* end of memory block to move */
556int n) /* number of bytes the memory block has to be moved */
557{
558 char *p;
559 int i; /* number of byte copied */
560
561 if (n == 0)
562 return;
563
564 i = (int) (end - start + 1);
565 if (n < 0) {
566 p = start + n;
567 while (i != 0) {
568 *p++ = *start++;
569 i--;
570 }
571 }
572 else {
573 p = end + n;
574 while (i != 0) {
575 *p-- = *end--;
576 i--;
577 }
578 }
579}
580
581/*
582 * setup the VPD keyword 'key' at 'ip'.
583 *
584 * returns nothing
585 */
586static void vpd_insert_key(
587const char *key, /* keyword to insert */
588const char *buf, /* buffer with the keyword value */
589int len, /* length of the value string */
590char *ip) /* inseration point */
591{
592 SK_VPD_KEY *p;
593
594 p = (SK_VPD_KEY *) ip;
595 p->p_key[0] = key[0];
596 p->p_key[1] = key[1];
597 p->p_len = (unsigned char) len;
598 SK_MEMCPY(&p->p_val,buf,len);
599}
600
601/*
602 * Setup the VPD end tag "RV" / "RW".
603 * Also correct the remaining space variables vpd_free_ro / vpd_free_rw.
604 *
605 * returns 0: success
606 * 1: encoding error
607 */
608static int vpd_mod_endtag(
609SK_AC *pAC, /* common data base */
610char *etp) /* end pointer input position */
611{
612 SK_VPD_KEY *p;
613 unsigned char x;
614 int i;
615 int vpd_size;
616
617 SK_DBG_MSG(pAC, SK_DBGMOD_VPD, SK_DBGCAT_CTRL,
618 ("VPD modify endtag at 0x%x = '%c%c'\n",etp,etp[0],etp[1]));
619
620 vpd_size = pAC->vpd.vpd_size;
621
622 p = (SK_VPD_KEY *) etp;
623
624 if (p->p_key[0] != 'R' || (p->p_key[1] != 'V' && p->p_key[1] != 'W')) {
625 /* something wrong here, encoding error */
626 SK_DBG_MSG(pAC,SK_DBGMOD_VPD,SK_DBGCAT_ERR | SK_DBGCAT_FATAL,
627 ("Encoding Error: invalid end tag\n"));
628 return(1);
629 }
630 if (etp > pAC->vpd.vpd_buf + vpd_size/2) {
631 /* create "RW" tag */
632 p->p_len = (unsigned char)(pAC->vpd.vpd_buf+vpd_size-etp-3-1);
633 pAC->vpd.v.vpd_free_rw = (int) p->p_len;
634 i = pAC->vpd.v.vpd_free_rw;
635 etp += 3;
636 }
637 else {
638 /* create "RV" tag */
639 p->p_len = (unsigned char)(pAC->vpd.vpd_buf+vpd_size/2-etp-3);
640 pAC->vpd.v.vpd_free_ro = (int) p->p_len - 1;
641
642 /* setup checksum */
643 for (i = 0, x = 0; i < vpd_size/2 - p->p_len; i++) {
644 x += pAC->vpd.vpd_buf[i];
645 }
646 p->p_val = (char) 0 - x;
647 i = pAC->vpd.v.vpd_free_ro;
648 etp += 4;
649 }
650 while (i) {
651 *etp++ = 0x00;
652 i--;
653 }
654
655 return(0);
656}
657
658/*
659 * Insert a VPD keyword into the VPD buffer.
660 *
661 * The keyword 'key' is inserted at the position 'ip' in the
662 * VPD buffer.
663 * The keywords behind the input position will
664 * be moved. The VPD end tag "RV" or "RW" is generated again.
665 *
666 * returns 0: success
667 * 2: value string was cut
668 * 4: VPD full, keyword was not written
669 * 6: fatal VPD error
670 *
671 */
672static int VpdSetupPara(
673SK_AC *pAC, /* common data base */
674const char *key, /* keyword to insert */
675const char *buf, /* buffer with the keyword value */
676int len, /* length of the keyword value */
677int type, /* VPD_RO_KEY or VPD_RW_KEY */
678int op) /* operation to do: ADD_KEY or OWR_KEY */
679{
680 SK_VPD_PARA vp;
681 char *etp; /* end tag position */
682 int free; /* remaining space in selected area */
683 char *ip; /* input position inside the VPD buffer */
684 int rtv; /* return code */
685 int head; /* additional haeder bytes to move */
686 int found; /* additinoal bytes if the keyword was found */
687 int vpd_size;
688
689 SK_DBG_MSG(pAC, SK_DBGMOD_VPD, SK_DBGCAT_CTRL,
690 ("VPD setup para key = %s, val = %s\n",key,buf));
691
692 vpd_size = pAC->vpd.vpd_size;
693
694 rtv = 0;
695 ip = NULL;
696 if (type == VPD_RW_KEY) {
697 /* end tag is "RW" */
698 free = pAC->vpd.v.vpd_free_rw;
699 etp = pAC->vpd.vpd_buf + (vpd_size - free - 1 - 3);
700 }
701 else {
702 /* end tag is "RV" */
703 free = pAC->vpd.v.vpd_free_ro;
704 etp = pAC->vpd.vpd_buf + (vpd_size/2 - free - 4);
705 }
706 SK_DBG_MSG(pAC, SK_DBGMOD_VPD, SK_DBGCAT_CTRL,
707 ("Free RO = %d, Free RW = %d\n",
708 pAC->vpd.v.vpd_free_ro, pAC->vpd.v.vpd_free_rw));
709
710 head = 0;
711 found = 0;
712 if (op == OWR_KEY) {
713 if (vpd_find_para(pAC, key, &vp)) {
714 found = 3;
715 ip = vp.p_val - 3;
716 free += vp.p_len + 3;
717 SK_DBG_MSG(pAC, SK_DBGMOD_VPD, SK_DBGCAT_CTRL,
718 ("Overwrite Key\n"));
719 }
720 else {
721 op = ADD_KEY;
722 SK_DBG_MSG(pAC, SK_DBGMOD_VPD, SK_DBGCAT_CTRL,
723 ("Add Key\n"));
724 }
725 }
726 if (op == ADD_KEY) {
727 ip = etp;
728 vp.p_len = 0;
729 head = 3;
730 }
731
732 if (len + 3 > free) {
733 if (free < 7) {
734 SK_DBG_MSG(pAC, SK_DBGMOD_VPD, SK_DBGCAT_ERR,
735 ("VPD Buffer Overflow, keyword not written\n"));
736 return(4);
737 }
738 /* cut it again */
739 len = free - 3;
740 rtv = 2;
741 SK_DBG_MSG(pAC, SK_DBGMOD_VPD, SK_DBGCAT_ERR,
742 ("VPD Buffer Full, Keyword was cut\n"));
743 }
744
745 vpd_move_para(ip + vp.p_len + found, etp+2, len-vp.p_len+head);
746 vpd_insert_key(key, buf, len, ip);
747 if (vpd_mod_endtag(pAC, etp + len - vp.p_len + head)) {
748 pAC->vpd.v.vpd_status &= ~VPD_VALID;
749 SK_DBG_MSG(pAC, SK_DBGMOD_VPD, SK_DBGCAT_ERR,
750 ("VPD Encoding Error\n"));
751 return(6);
752 }
753
754 return(rtv);
755}
756
757
758/*
759 * Read the contents of the VPD EEPROM and copy it to the
760 * VPD buffer if not already done.
761 *
762 * return: A pointer to the vpd_status structure. The structure contains
763 * this fields.
764 */
765SK_VPD_STATUS *VpdStat(
766SK_AC *pAC, /* Adapters context */
767SK_IOC IoC) /* IO Context */
768{
769 if ((pAC->vpd.v.vpd_status & VPD_VALID) == 0) {
770 (void)VpdInit(pAC, IoC);
771 }
772 return(&pAC->vpd.v);
773}
774
775
776/*
777 * Read the contents of the VPD EEPROM and copy it to the VPD
778 * buffer if not already done.
779 * Scan the VPD buffer for VPD keywords and create the VPD
780 * keyword list by copying the keywords to 'buf', all after
781 * each other and terminated with a '\0'.
782 *
783 * Exceptions: o The Resource Type ID String (product name) is called "Name"
784 * o The VPD end tags 'RV' and 'RW' are not listed
785 *
786 * The number of copied keywords is counted in 'elements'.
787 *
788 * returns 0: success
789 * 2: buffer overfull, one or more keywords are missing
790 * 6: fatal VPD error
791 *
792 * example values after returning:
793 *
794 * buf = "Name\0PN\0EC\0MN\0SN\0CP\0VF\0VL\0YA\0"
795 * *len = 30
796 * *elements = 9
797 */
798int VpdKeys(
799SK_AC *pAC, /* common data base */
800SK_IOC IoC, /* IO Context */
801char *buf, /* buffer where to copy the keywords */
802int *len, /* buffer length */
803int *elements) /* number of keywords returned */
804{
805 char *v;
806 int n;
807
808 SK_DBG_MSG(pAC, SK_DBGMOD_VPD, SK_DBGCAT_RX, ("list VPD keys .. "));
809 *elements = 0;
810 if ((pAC->vpd.v.vpd_status & VPD_VALID) == 0) {
811 if (VpdInit(pAC, IoC) != 0) {
812 *len = 0;
813 SK_DBG_MSG(pAC, SK_DBGMOD_VPD, SK_DBGCAT_ERR,
814 ("VPD Init Error, terminated\n"));
815 return(6);
816 }
817 }
818
819 if ((signed)strlen(VPD_NAME) + 1 <= *len) {
820 v = pAC->vpd.vpd_buf;
821 strcpy(buf,VPD_NAME);
822 n = strlen(VPD_NAME) + 1;
823 buf += n;
824 *elements = 1;
825 SK_DBG_MSG(pAC, SK_DBGMOD_VPD, SK_DBGCAT_RX,
826 ("'%c%c' ",v[0],v[1]));
827 }
828 else {
829 *len = 0;
830 SK_DBG_MSG(pAC,SK_DBGMOD_VPD,SK_DBGCAT_ERR,
831 ("buffer overflow\n"));
832 return(2);
833 }
834
835 v += 3 + VPD_GET_RES_LEN(v) + 3;
836 for (;; ) {
837 /* exit when reaching the "RW" Tag */
838 if (SK_MEMCMP(VPD_RW,v,2) == 0) {
839 break;
840 }
841
842 if (SK_MEMCMP(VPD_RV,v,2) == 0) {
843 v += 3 + VPD_GET_VPD_LEN(v) + 3; /* skip VPD-W */
844 continue;
845 }
846
847 if (n+3 <= *len) {
848 SK_MEMCPY(buf,v,2);
849 buf += 2;
850 *buf++ = '\0';
851 n += 3;
852 v += 3 + VPD_GET_VPD_LEN(v);
853 *elements += 1;
854 SK_DBG_MSG(pAC, SK_DBGMOD_VPD, SK_DBGCAT_RX,
855 ("'%c%c' ",v[0],v[1]));
856 }
857 else {
858 *len = n;
859 SK_DBG_MSG(pAC, SK_DBGMOD_VPD, SK_DBGCAT_ERR,
860 ("buffer overflow\n"));
861 return(2);
862 }
863 }
864
865 SK_DBG_MSG(pAC, SK_DBGMOD_VPD, SK_DBGCAT_RX, ("\n"));
866 *len = n;
867 return(0);
868}
869
870
871/*
872 * Read the contents of the VPD EEPROM and copy it to the
873 * VPD buffer if not already done. Search for the VPD keyword
874 * 'key' and copy its value to 'buf'. Add a terminating '\0'.
875 * If the value does not fit into the buffer cut it after
876 * 'len' - 1 bytes.
877 *
878 * returns 0: success
879 * 1: keyword not found
880 * 2: value string was cut
881 * 3: VPD transfer timeout
882 * 6: fatal VPD error
883 */
884int VpdRead(
885SK_AC *pAC, /* common data base */
886SK_IOC IoC, /* IO Context */
887const char *key, /* keyword to read (e.g. "MN") */
888char *buf, /* buffer where to copy the keyword value */
889int *len) /* buffer length */
890{
891 SK_VPD_PARA *p, vp;
892
893 SK_DBG_MSG(pAC, SK_DBGMOD_VPD, SK_DBGCAT_RX, ("VPD read %s .. ", key));
894 if ((pAC->vpd.v.vpd_status & VPD_VALID) == 0) {
895 if (VpdInit(pAC, IoC) != 0) {
896 *len = 0;
897 SK_DBG_MSG(pAC, SK_DBGMOD_VPD, SK_DBGCAT_ERR,
898 ("VPD init error\n"));
899 return(6);
900 }
901 }
902
903 if ((p = vpd_find_para(pAC, key, &vp)) != NULL) {
904 if (p->p_len > (*(unsigned *)len)-1) {
905 p->p_len = *len - 1;
906 }
907 SK_MEMCPY(buf, p->p_val, p->p_len);
908 buf[p->p_len] = '\0';
909 *len = p->p_len;
910 SK_DBG_MSG(pAC, SK_DBGMOD_VPD, SK_DBGCAT_RX,
911 ("%c%c%c%c.., len = %d\n",
912 buf[0],buf[1],buf[2],buf[3],*len));
913 }
914 else {
915 *len = 0;
916 SK_DBG_MSG(pAC, SK_DBGMOD_VPD, SK_DBGCAT_ERR, ("not found\n"));
917 return(1);
918 }
919 return(0);
920}
921
922
923/*
924 * Check whether a given key may be written
925 *
926 * returns
927 * SK_TRUE Yes it may be written
928 * SK_FALSE No it may be written
929 */
930SK_BOOL VpdMayWrite(
931char *key) /* keyword to write (allowed values "Yx", "Vx") */
932{
933 if ((*key != 'Y' && *key != 'V') ||
934 key[1] < '0' || key[1] > 'Z' ||
935 (key[1] > '9' && key[1] < 'A') || strlen(key) != 2) {
936
937 return(SK_FALSE);
938 }
939 return(SK_TRUE);
940}
941
942/*
943 * Read the contents of the VPD EEPROM and copy it to the VPD
944 * buffer if not already done. Insert/overwrite the keyword 'key'
945 * in the VPD buffer. Cut the keyword value if it does not fit
946 * into the VPD read / write area.
947 *
948 * returns 0: success
949 * 2: value string was cut
950 * 3: VPD transfer timeout
951 * 4: VPD full, keyword was not written
952 * 5: keyword cannot be written
953 * 6: fatal VPD error
954 */
955int VpdWrite(
956SK_AC *pAC, /* common data base */
957SK_IOC IoC, /* IO Context */
958const char *key, /* keyword to write (allowed values "Yx", "Vx") */
959const char *buf) /* buffer where the keyword value can be read from */
960{
961 int len; /* length of the keyword to write */
962 int rtv; /* return code */
963 int rtv2;
964
965 SK_DBG_MSG(pAC, SK_DBGMOD_VPD, SK_DBGCAT_TX,
966 ("VPD write %s = %s\n",key,buf));
967
968 if ((*key != 'Y' && *key != 'V') ||
969 key[1] < '0' || key[1] > 'Z' ||
970 (key[1] > '9' && key[1] < 'A') || strlen(key) != 2) {
971
972 SK_DBG_MSG(pAC, SK_DBGMOD_VPD, SK_DBGCAT_ERR,
973 ("illegal key tag, keyword not written\n"));
974 return(5);
975 }
976
977 if ((pAC->vpd.v.vpd_status & VPD_VALID) == 0) {
978 if (VpdInit(pAC, IoC) != 0) {
979 SK_DBG_MSG(pAC, SK_DBGMOD_VPD, SK_DBGCAT_ERR,
980 ("VPD init error\n"));
981 return(6);
982 }
983 }
984
985 rtv = 0;
986 len = strlen(buf);
987 if (len > VPD_MAX_LEN) {
988 /* cut it */
989 len = VPD_MAX_LEN;
990 rtv = 2;
991 SK_DBG_MSG(pAC, SK_DBGMOD_VPD, SK_DBGCAT_ERR,
992 ("keyword too long, cut after %d bytes\n",VPD_MAX_LEN));
993 }
994 if ((rtv2 = VpdSetupPara(pAC, key, buf, len, VPD_RW_KEY, OWR_KEY)) != 0) {
995 SK_DBG_MSG(pAC, SK_DBGMOD_VPD, SK_DBGCAT_ERR,
996 ("VPD write error\n"));
997 return(rtv2);
998 }
999
1000 return(rtv);
1001}
1002
1003/*
1004 * Read the contents of the VPD EEPROM and copy it to the
1005 * VPD buffer if not already done. Remove the VPD keyword
1006 * 'key' from the VPD buffer.
1007 * Only the keywords in the read/write area can be deleted.
1008 * Keywords in the read only area cannot be deleted.
1009 *
1010 * returns 0: success, keyword was removed
1011 * 1: keyword not found
1012 * 5: keyword cannot be deleted
1013 * 6: fatal VPD error
1014 */
1015int VpdDelete(
1016SK_AC *pAC, /* common data base */
1017SK_IOC IoC, /* IO Context */
1018char *key) /* keyword to read (e.g. "MN") */
1019{
1020 SK_VPD_PARA *p, vp;
1021 char *etp;
1022 int vpd_size;
1023
1024 vpd_size = pAC->vpd.vpd_size;
1025
1026 SK_DBG_MSG(pAC,SK_DBGMOD_VPD,SK_DBGCAT_TX,("VPD delete key %s\n",key));
1027 if ((pAC->vpd.v.vpd_status & VPD_VALID) == 0) {
1028 if (VpdInit(pAC, IoC) != 0) {
1029 SK_DBG_MSG(pAC, SK_DBGMOD_VPD, SK_DBGCAT_ERR,
1030 ("VPD init error\n"));
1031 return(6);
1032 }
1033 }
1034
1035 if ((p = vpd_find_para(pAC, key, &vp)) != NULL) {
1036 if (p->p_val < pAC->vpd.vpd_buf + vpd_size/2) {
1037 /* try to delete read only keyword */
1038 SK_DBG_MSG(pAC, SK_DBGMOD_VPD, SK_DBGCAT_ERR,
1039 ("cannot delete RO keyword\n"));
1040 return(5);
1041 }
1042
1043 etp = pAC->vpd.vpd_buf + (vpd_size-pAC->vpd.v.vpd_free_rw-1-3);
1044
1045 vpd_move_para(vp.p_val+vp.p_len, etp+2,
1046 - ((int)(vp.p_len + 3)));
1047 if (vpd_mod_endtag(pAC, etp - vp.p_len - 3)) {
1048 pAC->vpd.v.vpd_status &= ~VPD_VALID;
1049 SK_DBG_MSG(pAC, SK_DBGMOD_VPD, SK_DBGCAT_ERR,
1050 ("VPD encoding error\n"));
1051 return(6);
1052 }
1053 }
1054 else {
1055 SK_DBG_MSG(pAC, SK_DBGMOD_VPD, SK_DBGCAT_ERR,
1056 ("keyword not found\n"));
1057 return(1);
1058 }
1059
1060 return(0);
1061}
1062
1063/*
1064 * If the VPD buffer contains valid data write the VPD
1065 * read/write area back to the VPD EEPROM.
1066 *
1067 * returns 0: success
1068 * 3: VPD transfer timeout
1069 */
1070int VpdUpdate(
1071SK_AC *pAC, /* Adapters context */
1072SK_IOC IoC) /* IO Context */
1073{
1074 int vpd_size;
1075
1076 vpd_size = pAC->vpd.vpd_size;
1077
1078 SK_DBG_MSG(pAC, SK_DBGMOD_VPD, SK_DBGCAT_TX, ("VPD update .. "));
1079 if ((pAC->vpd.v.vpd_status & VPD_VALID) != 0) {
1080 if (VpdTransferBlock(pAC, IoC, pAC->vpd.vpd_buf + vpd_size/2,
1081 vpd_size/2, vpd_size/2, VPD_WRITE) != vpd_size/2) {
1082
1083 SK_DBG_MSG(pAC, SK_DBGMOD_VPD, SK_DBGCAT_ERR,
1084 ("transfer timed out\n"));
1085 return(3);
1086 }
1087 }
1088 SK_DBG_MSG(pAC, SK_DBGMOD_VPD, SK_DBGCAT_TX, ("done\n"));
1089 return(0);
1090}
1091
diff --git a/drivers/net/sk98lin/skxmac2.c b/drivers/net/sk98lin/skxmac2.c
new file mode 100644
index 000000000000..b4e75022a657
--- /dev/null
+++ b/drivers/net/sk98lin/skxmac2.c
@@ -0,0 +1,4160 @@
1/******************************************************************************
2 *
3 * Name: skxmac2.c
4 * Project: Gigabit Ethernet Adapters, Common Modules
5 * Version: $Revision: 1.102 $
6 * Date: $Date: 2003/10/02 16:53:58 $
7 * Purpose: Contains functions to initialize the MACs and PHYs
8 *
9 ******************************************************************************/
10
11/******************************************************************************
12 *
13 * (C)Copyright 1998-2002 SysKonnect.
14 * (C)Copyright 2002-2003 Marvell.
15 *
16 * This program is free software; you can redistribute it and/or modify
17 * it under the terms of the GNU General Public License as published by
18 * the Free Software Foundation; either version 2 of the License, or
19 * (at your option) any later version.
20 *
21 * The information in this file is provided "AS IS" without warranty.
22 *
23 ******************************************************************************/
24
25#include "h/skdrv1st.h"
26#include "h/skdrv2nd.h"
27
28/* typedefs *******************************************************************/
29
30/* BCOM PHY magic pattern list */
31typedef struct s_PhyHack {
32 int PhyReg; /* Phy register */
33 SK_U16 PhyVal; /* Value to write */
34} BCOM_HACK;
35
36/* local variables ************************************************************/
37
38#if (defined(DEBUG) || ((!defined(LINT)) && (!defined(SK_SLIM))))
39static const char SysKonnectFileId[] =
40 "@(#) $Id: skxmac2.c,v 1.102 2003/10/02 16:53:58 rschmidt Exp $ (C) Marvell.";
41#endif
42
43#ifdef GENESIS
44static BCOM_HACK BcomRegA1Hack[] = {
45 { 0x18, 0x0c20 }, { 0x17, 0x0012 }, { 0x15, 0x1104 }, { 0x17, 0x0013 },
46 { 0x15, 0x0404 }, { 0x17, 0x8006 }, { 0x15, 0x0132 }, { 0x17, 0x8006 },
47 { 0x15, 0x0232 }, { 0x17, 0x800D }, { 0x15, 0x000F }, { 0x18, 0x0420 },
48 { 0, 0 }
49};
50static BCOM_HACK BcomRegC0Hack[] = {
51 { 0x18, 0x0c20 }, { 0x17, 0x0012 }, { 0x15, 0x1204 }, { 0x17, 0x0013 },
52 { 0x15, 0x0A04 }, { 0x18, 0x0420 },
53 { 0, 0 }
54};
55#endif
56
57/* function prototypes ********************************************************/
58#ifdef GENESIS
59static void SkXmInitPhyXmac(SK_AC*, SK_IOC, int, SK_BOOL);
60static void SkXmInitPhyBcom(SK_AC*, SK_IOC, int, SK_BOOL);
61static int SkXmAutoNegDoneXmac(SK_AC*, SK_IOC, int);
62static int SkXmAutoNegDoneBcom(SK_AC*, SK_IOC, int);
63#endif /* GENESIS */
64#ifdef YUKON
65static void SkGmInitPhyMarv(SK_AC*, SK_IOC, int, SK_BOOL);
66static int SkGmAutoNegDoneMarv(SK_AC*, SK_IOC, int);
67#endif /* YUKON */
68#ifdef OTHER_PHY
69static void SkXmInitPhyLone(SK_AC*, SK_IOC, int, SK_BOOL);
70static void SkXmInitPhyNat (SK_AC*, SK_IOC, int, SK_BOOL);
71static int SkXmAutoNegDoneLone(SK_AC*, SK_IOC, int);
72static int SkXmAutoNegDoneNat (SK_AC*, SK_IOC, int);
73#endif /* OTHER_PHY */
74
75
76#ifdef GENESIS
77/******************************************************************************
78 *
79 * SkXmPhyRead() - Read from XMAC PHY register
80 *
81 * Description: reads a 16-bit word from XMAC PHY or ext. PHY
82 *
83 * Returns:
84 * nothing
85 */
86void SkXmPhyRead(
87SK_AC *pAC, /* Adapter Context */
88SK_IOC IoC, /* I/O Context */
89int Port, /* Port Index (MAC_1 + n) */
90int PhyReg, /* Register Address (Offset) */
91SK_U16 SK_FAR *pVal) /* Pointer to Value */
92{
93 SK_U16 Mmu;
94 SK_GEPORT *pPrt;
95
96 pPrt = &pAC->GIni.GP[Port];
97
98 /* write the PHY register's address */
99 XM_OUT16(IoC, Port, XM_PHY_ADDR, PhyReg | pPrt->PhyAddr);
100
101 /* get the PHY register's value */
102 XM_IN16(IoC, Port, XM_PHY_DATA, pVal);
103
104 if (pPrt->PhyType != SK_PHY_XMAC) {
105 do {
106 XM_IN16(IoC, Port, XM_MMU_CMD, &Mmu);
107 /* wait until 'Ready' is set */
108 } while ((Mmu & XM_MMU_PHY_RDY) == 0);
109
110 /* get the PHY register's value */
111 XM_IN16(IoC, Port, XM_PHY_DATA, pVal);
112 }
113} /* SkXmPhyRead */
114
115
116/******************************************************************************
117 *
118 * SkXmPhyWrite() - Write to XMAC PHY register
119 *
120 * Description: writes a 16-bit word to XMAC PHY or ext. PHY
121 *
122 * Returns:
123 * nothing
124 */
125void SkXmPhyWrite(
126SK_AC *pAC, /* Adapter Context */
127SK_IOC IoC, /* I/O Context */
128int Port, /* Port Index (MAC_1 + n) */
129int PhyReg, /* Register Address (Offset) */
130SK_U16 Val) /* Value */
131{
132 SK_U16 Mmu;
133 SK_GEPORT *pPrt;
134
135 pPrt = &pAC->GIni.GP[Port];
136
137 if (pPrt->PhyType != SK_PHY_XMAC) {
138 do {
139 XM_IN16(IoC, Port, XM_MMU_CMD, &Mmu);
140 /* wait until 'Busy' is cleared */
141 } while ((Mmu & XM_MMU_PHY_BUSY) != 0);
142 }
143
144 /* write the PHY register's address */
145 XM_OUT16(IoC, Port, XM_PHY_ADDR, PhyReg | pPrt->PhyAddr);
146
147 /* write the PHY register's value */
148 XM_OUT16(IoC, Port, XM_PHY_DATA, Val);
149
150 if (pPrt->PhyType != SK_PHY_XMAC) {
151 do {
152 XM_IN16(IoC, Port, XM_MMU_CMD, &Mmu);
153 /* wait until 'Busy' is cleared */
154 } while ((Mmu & XM_MMU_PHY_BUSY) != 0);
155 }
156} /* SkXmPhyWrite */
157#endif /* GENESIS */
158
159
160#ifdef YUKON
161/******************************************************************************
162 *
163 * SkGmPhyRead() - Read from GPHY register
164 *
165 * Description: reads a 16-bit word from GPHY through MDIO
166 *
167 * Returns:
168 * nothing
169 */
170void SkGmPhyRead(
171SK_AC *pAC, /* Adapter Context */
172SK_IOC IoC, /* I/O Context */
173int Port, /* Port Index (MAC_1 + n) */
174int PhyReg, /* Register Address (Offset) */
175SK_U16 SK_FAR *pVal) /* Pointer to Value */
176{
177 SK_U16 Ctrl;
178 SK_GEPORT *pPrt;
179#ifdef VCPU
180 u_long SimCyle;
181 u_long SimLowTime;
182
183 VCPUgetTime(&SimCyle, &SimLowTime);
184 VCPUprintf(0, "SkGmPhyRead(%u), SimCyle=%u, SimLowTime=%u\n",
185 PhyReg, SimCyle, SimLowTime);
186#endif /* VCPU */
187
188 pPrt = &pAC->GIni.GP[Port];
189
190 /* set PHY-Register offset and 'Read' OpCode (= 1) */
191 *pVal = (SK_U16)(GM_SMI_CT_PHY_AD(pPrt->PhyAddr) |
192 GM_SMI_CT_REG_AD(PhyReg) | GM_SMI_CT_OP_RD);
193
194 GM_OUT16(IoC, Port, GM_SMI_CTRL, *pVal);
195
196 GM_IN16(IoC, Port, GM_SMI_CTRL, &Ctrl);
197
198 /* additional check for MDC/MDIO activity */
199 if ((Ctrl & GM_SMI_CT_BUSY) == 0) {
200 *pVal = 0;
201 return;
202 }
203
204 *pVal |= GM_SMI_CT_BUSY;
205
206 do {
207#ifdef VCPU
208 VCPUwaitTime(1000);
209#endif /* VCPU */
210
211 GM_IN16(IoC, Port, GM_SMI_CTRL, &Ctrl);
212
213 /* wait until 'ReadValid' is set */
214 } while (Ctrl == *pVal);
215
216 /* get the PHY register's value */
217 GM_IN16(IoC, Port, GM_SMI_DATA, pVal);
218
219#ifdef VCPU
220 VCPUgetTime(&SimCyle, &SimLowTime);
221 VCPUprintf(0, "VCPUgetTime(), SimCyle=%u, SimLowTime=%u\n",
222 SimCyle, SimLowTime);
223#endif /* VCPU */
224
225} /* SkGmPhyRead */
226
227
228/******************************************************************************
229 *
230 * SkGmPhyWrite() - Write to GPHY register
231 *
232 * Description: writes a 16-bit word to GPHY through MDIO
233 *
234 * Returns:
235 * nothing
236 */
237void SkGmPhyWrite(
238SK_AC *pAC, /* Adapter Context */
239SK_IOC IoC, /* I/O Context */
240int Port, /* Port Index (MAC_1 + n) */
241int PhyReg, /* Register Address (Offset) */
242SK_U16 Val) /* Value */
243{
244 SK_U16 Ctrl;
245 SK_GEPORT *pPrt;
246#ifdef VCPU
247 SK_U32 DWord;
248 u_long SimCyle;
249 u_long SimLowTime;
250
251 VCPUgetTime(&SimCyle, &SimLowTime);
252 VCPUprintf(0, "SkGmPhyWrite(Reg=%u, Val=0x%04x), SimCyle=%u, SimLowTime=%u\n",
253 PhyReg, Val, SimCyle, SimLowTime);
254#endif /* VCPU */
255
256 pPrt = &pAC->GIni.GP[Port];
257
258 /* write the PHY register's value */
259 GM_OUT16(IoC, Port, GM_SMI_DATA, Val);
260
261 /* set PHY-Register offset and 'Write' OpCode (= 0) */
262 Val = GM_SMI_CT_PHY_AD(pPrt->PhyAddr) | GM_SMI_CT_REG_AD(PhyReg);
263
264 GM_OUT16(IoC, Port, GM_SMI_CTRL, Val);
265
266 GM_IN16(IoC, Port, GM_SMI_CTRL, &Ctrl);
267
268 /* additional check for MDC/MDIO activity */
269 if ((Ctrl & GM_SMI_CT_BUSY) == 0) {
270 return;
271 }
272
273 Val |= GM_SMI_CT_BUSY;
274
275 do {
276#ifdef VCPU
277 /* read Timer value */
278 SK_IN32(IoC, B2_TI_VAL, &DWord);
279
280 VCPUwaitTime(1000);
281#endif /* VCPU */
282
283 GM_IN16(IoC, Port, GM_SMI_CTRL, &Ctrl);
284
285 /* wait until 'Busy' is cleared */
286 } while (Ctrl == Val);
287
288#ifdef VCPU
289 VCPUgetTime(&SimCyle, &SimLowTime);
290 VCPUprintf(0, "VCPUgetTime(), SimCyle=%u, SimLowTime=%u\n",
291 SimCyle, SimLowTime);
292#endif /* VCPU */
293
294} /* SkGmPhyWrite */
295#endif /* YUKON */
296
297
298#ifdef SK_DIAG
299/******************************************************************************
300 *
301 * SkGePhyRead() - Read from PHY register
302 *
303 * Description: calls a read PHY routine dep. on board type
304 *
305 * Returns:
306 * nothing
307 */
308void SkGePhyRead(
309SK_AC *pAC, /* Adapter Context */
310SK_IOC IoC, /* I/O Context */
311int Port, /* Port Index (MAC_1 + n) */
312int PhyReg, /* Register Address (Offset) */
313SK_U16 *pVal) /* Pointer to Value */
314{
315 void (*r_func)(SK_AC *pAC, SK_IOC IoC, int Port, int Reg, SK_U16 *pVal);
316
317 if (pAC->GIni.GIGenesis) {
318 r_func = SkXmPhyRead;
319 }
320 else {
321 r_func = SkGmPhyRead;
322 }
323
324 r_func(pAC, IoC, Port, PhyReg, pVal);
325} /* SkGePhyRead */
326
327
328/******************************************************************************
329 *
330 * SkGePhyWrite() - Write to PHY register
331 *
332 * Description: calls a write PHY routine dep. on board type
333 *
334 * Returns:
335 * nothing
336 */
337void SkGePhyWrite(
338SK_AC *pAC, /* Adapter Context */
339SK_IOC IoC, /* I/O Context */
340int Port, /* Port Index (MAC_1 + n) */
341int PhyReg, /* Register Address (Offset) */
342SK_U16 Val) /* Value */
343{
344 void (*w_func)(SK_AC *pAC, SK_IOC IoC, int Port, int Reg, SK_U16 Val);
345
346 if (pAC->GIni.GIGenesis) {
347 w_func = SkXmPhyWrite;
348 }
349 else {
350 w_func = SkGmPhyWrite;
351 }
352
353 w_func(pAC, IoC, Port, PhyReg, Val);
354} /* SkGePhyWrite */
355#endif /* SK_DIAG */
356
357
358/******************************************************************************
359 *
360 * SkMacPromiscMode() - Enable / Disable Promiscuous Mode
361 *
362 * Description:
363 * enables / disables promiscuous mode by setting Mode Register (XMAC) or
364 * Receive Control Register (GMAC) dep. on board type
365 *
366 * Returns:
367 * nothing
368 */
369void SkMacPromiscMode(
370SK_AC *pAC, /* adapter context */
371SK_IOC IoC, /* IO context */
372int Port, /* Port Index (MAC_1 + n) */
373SK_BOOL Enable) /* Enable / Disable */
374{
375#ifdef YUKON
376 SK_U16 RcReg;
377#endif
378#ifdef GENESIS
379 SK_U32 MdReg;
380#endif
381
382#ifdef GENESIS
383 if (pAC->GIni.GIGenesis) {
384
385 XM_IN32(IoC, Port, XM_MODE, &MdReg);
386 /* enable or disable promiscuous mode */
387 if (Enable) {
388 MdReg |= XM_MD_ENA_PROM;
389 }
390 else {
391 MdReg &= ~XM_MD_ENA_PROM;
392 }
393 /* setup Mode Register */
394 XM_OUT32(IoC, Port, XM_MODE, MdReg);
395 }
396#endif /* GENESIS */
397
398#ifdef YUKON
399 if (pAC->GIni.GIYukon) {
400
401 GM_IN16(IoC, Port, GM_RX_CTRL, &RcReg);
402
403 /* enable or disable unicast and multicast filtering */
404 if (Enable) {
405 RcReg &= ~(GM_RXCR_UCF_ENA | GM_RXCR_MCF_ENA);
406 }
407 else {
408 RcReg |= (GM_RXCR_UCF_ENA | GM_RXCR_MCF_ENA);
409 }
410 /* setup Receive Control Register */
411 GM_OUT16(IoC, Port, GM_RX_CTRL, RcReg);
412 }
413#endif /* YUKON */
414
415} /* SkMacPromiscMode*/
416
417
418/******************************************************************************
419 *
420 * SkMacHashing() - Enable / Disable Hashing
421 *
422 * Description:
423 * enables / disables hashing by setting Mode Register (XMAC) or
424 * Receive Control Register (GMAC) dep. on board type
425 *
426 * Returns:
427 * nothing
428 */
429void SkMacHashing(
430SK_AC *pAC, /* adapter context */
431SK_IOC IoC, /* IO context */
432int Port, /* Port Index (MAC_1 + n) */
433SK_BOOL Enable) /* Enable / Disable */
434{
435#ifdef YUKON
436 SK_U16 RcReg;
437#endif
438#ifdef GENESIS
439 SK_U32 MdReg;
440#endif
441
442#ifdef GENESIS
443 if (pAC->GIni.GIGenesis) {
444
445 XM_IN32(IoC, Port, XM_MODE, &MdReg);
446 /* enable or disable hashing */
447 if (Enable) {
448 MdReg |= XM_MD_ENA_HASH;
449 }
450 else {
451 MdReg &= ~XM_MD_ENA_HASH;
452 }
453 /* setup Mode Register */
454 XM_OUT32(IoC, Port, XM_MODE, MdReg);
455 }
456#endif /* GENESIS */
457
458#ifdef YUKON
459 if (pAC->GIni.GIYukon) {
460
461 GM_IN16(IoC, Port, GM_RX_CTRL, &RcReg);
462
463 /* enable or disable multicast filtering */
464 if (Enable) {
465 RcReg |= GM_RXCR_MCF_ENA;
466 }
467 else {
468 RcReg &= ~GM_RXCR_MCF_ENA;
469 }
470 /* setup Receive Control Register */
471 GM_OUT16(IoC, Port, GM_RX_CTRL, RcReg);
472 }
473#endif /* YUKON */
474
475} /* SkMacHashing*/
476
477
478#ifdef SK_DIAG
479/******************************************************************************
480 *
481 * SkXmSetRxCmd() - Modify the value of the XMAC's Rx Command Register
482 *
483 * Description:
484 * The features
485 * - FCS stripping, SK_STRIP_FCS_ON/OFF
486 * - pad byte stripping, SK_STRIP_PAD_ON/OFF
487 * - don't set XMR_FS_ERR in status SK_LENERR_OK_ON/OFF
488 * for inrange length error frames
489 * - don't set XMR_FS_ERR in status SK_BIG_PK_OK_ON/OFF
490 * for frames > 1514 bytes
491 * - enable Rx of own packets SK_SELF_RX_ON/OFF
492 *
493 * for incoming packets may be enabled/disabled by this function.
494 * Additional modes may be added later.
495 * Multiple modes can be enabled/disabled at the same time.
496 * The new configuration is written to the Rx Command register immediately.
497 *
498 * Returns:
499 * nothing
500 */
501static void SkXmSetRxCmd(
502SK_AC *pAC, /* adapter context */
503SK_IOC IoC, /* IO context */
504int Port, /* Port Index (MAC_1 + n) */
505int Mode) /* Mode is SK_STRIP_FCS_ON/OFF, SK_STRIP_PAD_ON/OFF,
506 SK_LENERR_OK_ON/OFF, or SK_BIG_PK_OK_ON/OFF */
507{
508 SK_U16 OldRxCmd;
509 SK_U16 RxCmd;
510
511 XM_IN16(IoC, Port, XM_RX_CMD, &OldRxCmd);
512
513 RxCmd = OldRxCmd;
514
515 switch (Mode & (SK_STRIP_FCS_ON | SK_STRIP_FCS_OFF)) {
516 case SK_STRIP_FCS_ON:
517 RxCmd |= XM_RX_STRIP_FCS;
518 break;
519 case SK_STRIP_FCS_OFF:
520 RxCmd &= ~XM_RX_STRIP_FCS;
521 break;
522 }
523
524 switch (Mode & (SK_STRIP_PAD_ON | SK_STRIP_PAD_OFF)) {
525 case SK_STRIP_PAD_ON:
526 RxCmd |= XM_RX_STRIP_PAD;
527 break;
528 case SK_STRIP_PAD_OFF:
529 RxCmd &= ~XM_RX_STRIP_PAD;
530 break;
531 }
532
533 switch (Mode & (SK_LENERR_OK_ON | SK_LENERR_OK_OFF)) {
534 case SK_LENERR_OK_ON:
535 RxCmd |= XM_RX_LENERR_OK;
536 break;
537 case SK_LENERR_OK_OFF:
538 RxCmd &= ~XM_RX_LENERR_OK;
539 break;
540 }
541
542 switch (Mode & (SK_BIG_PK_OK_ON | SK_BIG_PK_OK_OFF)) {
543 case SK_BIG_PK_OK_ON:
544 RxCmd |= XM_RX_BIG_PK_OK;
545 break;
546 case SK_BIG_PK_OK_OFF:
547 RxCmd &= ~XM_RX_BIG_PK_OK;
548 break;
549 }
550
551 switch (Mode & (SK_SELF_RX_ON | SK_SELF_RX_OFF)) {
552 case SK_SELF_RX_ON:
553 RxCmd |= XM_RX_SELF_RX;
554 break;
555 case SK_SELF_RX_OFF:
556 RxCmd &= ~XM_RX_SELF_RX;
557 break;
558 }
559
560 /* Write the new mode to the Rx command register if required */
561 if (OldRxCmd != RxCmd) {
562 XM_OUT16(IoC, Port, XM_RX_CMD, RxCmd);
563 }
564} /* SkXmSetRxCmd */
565
566
567/******************************************************************************
568 *
569 * SkGmSetRxCmd() - Modify the value of the GMAC's Rx Control Register
570 *
571 * Description:
572 * The features
573 * - FCS (CRC) stripping, SK_STRIP_FCS_ON/OFF
574 * - don't set GMR_FS_LONG_ERR SK_BIG_PK_OK_ON/OFF
575 * for frames > 1514 bytes
576 * - enable Rx of own packets SK_SELF_RX_ON/OFF
577 *
578 * for incoming packets may be enabled/disabled by this function.
579 * Additional modes may be added later.
580 * Multiple modes can be enabled/disabled at the same time.
581 * The new configuration is written to the Rx Command register immediately.
582 *
583 * Returns:
584 * nothing
585 */
586static void SkGmSetRxCmd(
587SK_AC *pAC, /* adapter context */
588SK_IOC IoC, /* IO context */
589int Port, /* Port Index (MAC_1 + n) */
590int Mode) /* Mode is SK_STRIP_FCS_ON/OFF, SK_STRIP_PAD_ON/OFF,
591 SK_LENERR_OK_ON/OFF, or SK_BIG_PK_OK_ON/OFF */
592{
593 SK_U16 OldRxCmd;
594 SK_U16 RxCmd;
595
596 if ((Mode & (SK_STRIP_FCS_ON | SK_STRIP_FCS_OFF)) != 0) {
597
598 GM_IN16(IoC, Port, GM_RX_CTRL, &OldRxCmd);
599
600 RxCmd = OldRxCmd;
601
602 if ((Mode & SK_STRIP_FCS_ON) != 0) {
603 RxCmd |= GM_RXCR_CRC_DIS;
604 }
605 else {
606 RxCmd &= ~GM_RXCR_CRC_DIS;
607 }
608 /* Write the new mode to the Rx control register if required */
609 if (OldRxCmd != RxCmd) {
610 GM_OUT16(IoC, Port, GM_RX_CTRL, RxCmd);
611 }
612 }
613
614 if ((Mode & (SK_BIG_PK_OK_ON | SK_BIG_PK_OK_OFF)) != 0) {
615
616 GM_IN16(IoC, Port, GM_SERIAL_MODE, &OldRxCmd);
617
618 RxCmd = OldRxCmd;
619
620 if ((Mode & SK_BIG_PK_OK_ON) != 0) {
621 RxCmd |= GM_SMOD_JUMBO_ENA;
622 }
623 else {
624 RxCmd &= ~GM_SMOD_JUMBO_ENA;
625 }
626 /* Write the new mode to the Rx control register if required */
627 if (OldRxCmd != RxCmd) {
628 GM_OUT16(IoC, Port, GM_SERIAL_MODE, RxCmd);
629 }
630 }
631} /* SkGmSetRxCmd */
632
633
634/******************************************************************************
635 *
636 * SkMacSetRxCmd() - Modify the value of the MAC's Rx Control Register
637 *
638 * Description: modifies the MAC's Rx Control reg. dep. on board type
639 *
640 * Returns:
641 * nothing
642 */
643void SkMacSetRxCmd(
644SK_AC *pAC, /* adapter context */
645SK_IOC IoC, /* IO context */
646int Port, /* Port Index (MAC_1 + n) */
647int Mode) /* Rx Mode */
648{
649 if (pAC->GIni.GIGenesis) {
650
651 SkXmSetRxCmd(pAC, IoC, Port, Mode);
652 }
653 else {
654
655 SkGmSetRxCmd(pAC, IoC, Port, Mode);
656 }
657
658} /* SkMacSetRxCmd */
659
660
661/******************************************************************************
662 *
663 * SkMacCrcGener() - Enable / Disable CRC Generation
664 *
665 * Description: enables / disables CRC generation dep. on board type
666 *
667 * Returns:
668 * nothing
669 */
670void SkMacCrcGener(
671SK_AC *pAC, /* adapter context */
672SK_IOC IoC, /* IO context */
673int Port, /* Port Index (MAC_1 + n) */
674SK_BOOL Enable) /* Enable / Disable */
675{
676 SK_U16 Word;
677
678 if (pAC->GIni.GIGenesis) {
679
680 XM_IN16(IoC, Port, XM_TX_CMD, &Word);
681
682 if (Enable) {
683 Word &= ~XM_TX_NO_CRC;
684 }
685 else {
686 Word |= XM_TX_NO_CRC;
687 }
688 /* setup Tx Command Register */
689 XM_OUT16(IoC, Port, XM_TX_CMD, Word);
690 }
691 else {
692
693 GM_IN16(IoC, Port, GM_TX_CTRL, &Word);
694
695 if (Enable) {
696 Word &= ~GM_TXCR_CRC_DIS;
697 }
698 else {
699 Word |= GM_TXCR_CRC_DIS;
700 }
701 /* setup Tx Control Register */
702 GM_OUT16(IoC, Port, GM_TX_CTRL, Word);
703 }
704
705} /* SkMacCrcGener*/
706
707#endif /* SK_DIAG */
708
709
710#ifdef GENESIS
711/******************************************************************************
712 *
713 * SkXmClrExactAddr() - Clear Exact Match Address Registers
714 *
715 * Description:
716 * All Exact Match Address registers of the XMAC 'Port' will be
717 * cleared starting with 'StartNum' up to (and including) the
718 * Exact Match address number of 'StopNum'.
719 *
720 * Returns:
721 * nothing
722 */
723void SkXmClrExactAddr(
724SK_AC *pAC, /* adapter context */
725SK_IOC IoC, /* IO context */
726int Port, /* Port Index (MAC_1 + n) */
727int StartNum, /* Begin with this Address Register Index (0..15) */
728int StopNum) /* Stop after finished with this Register Idx (0..15) */
729{
730 int i;
731 SK_U16 ZeroAddr[3] = {0x0000, 0x0000, 0x0000};
732
733 if ((unsigned)StartNum > 15 || (unsigned)StopNum > 15 ||
734 StartNum > StopNum) {
735
736 SK_ERR_LOG(pAC, SK_ERRCL_SW, SKERR_HWI_E001, SKERR_HWI_E001MSG);
737 return;
738 }
739
740 for (i = StartNum; i <= StopNum; i++) {
741 XM_OUTADDR(IoC, Port, XM_EXM(i), &ZeroAddr[0]);
742 }
743} /* SkXmClrExactAddr */
744#endif /* GENESIS */
745
746
747/******************************************************************************
748 *
749 * SkMacFlushTxFifo() - Flush the MAC's transmit FIFO
750 *
751 * Description:
752 * Flush the transmit FIFO of the MAC specified by the index 'Port'
753 *
754 * Returns:
755 * nothing
756 */
757void SkMacFlushTxFifo(
758SK_AC *pAC, /* adapter context */
759SK_IOC IoC, /* IO context */
760int Port) /* Port Index (MAC_1 + n) */
761{
762#ifdef GENESIS
763 SK_U32 MdReg;
764
765 if (pAC->GIni.GIGenesis) {
766
767 XM_IN32(IoC, Port, XM_MODE, &MdReg);
768
769 XM_OUT32(IoC, Port, XM_MODE, MdReg | XM_MD_FTF);
770 }
771#endif /* GENESIS */
772
773#ifdef YUKON
774 if (pAC->GIni.GIYukon) {
775 /* no way to flush the FIFO we have to issue a reset */
776 /* TBD */
777 }
778#endif /* YUKON */
779
780} /* SkMacFlushTxFifo */
781
782
783/******************************************************************************
784 *
785 * SkMacFlushRxFifo() - Flush the MAC's receive FIFO
786 *
787 * Description:
788 * Flush the receive FIFO of the MAC specified by the index 'Port'
789 *
790 * Returns:
791 * nothing
792 */
793static void SkMacFlushRxFifo(
794SK_AC *pAC, /* adapter context */
795SK_IOC IoC, /* IO context */
796int Port) /* Port Index (MAC_1 + n) */
797{
798#ifdef GENESIS
799 SK_U32 MdReg;
800
801 if (pAC->GIni.GIGenesis) {
802
803 XM_IN32(IoC, Port, XM_MODE, &MdReg);
804
805 XM_OUT32(IoC, Port, XM_MODE, MdReg | XM_MD_FRF);
806 }
807#endif /* GENESIS */
808
809#ifdef YUKON
810 if (pAC->GIni.GIYukon) {
811 /* no way to flush the FIFO we have to issue a reset */
812 /* TBD */
813 }
814#endif /* YUKON */
815
816} /* SkMacFlushRxFifo */
817
818
819#ifdef GENESIS
820/******************************************************************************
821 *
822 * SkXmSoftRst() - Do a XMAC software reset
823 *
824 * Description:
825 * The PHY registers should not be destroyed during this
826 * kind of software reset. Therefore the XMAC Software Reset
827 * (XM_GP_RES_MAC bit in XM_GP_PORT) must not be used!
828 *
829 * The software reset is done by
830 * - disabling the Rx and Tx state machine,
831 * - resetting the statistics module,
832 * - clear all other significant XMAC Mode,
833 * Command, and Control Registers
834 * - clearing the Hash Register and the
835 * Exact Match Address registers, and
836 * - flushing the XMAC's Rx and Tx FIFOs.
837 *
838 * Note:
839 * Another requirement when stopping the XMAC is to
840 * avoid sending corrupted frames on the network.
841 * Disabling the Tx state machine will NOT interrupt
842 * the currently transmitted frame. But we must take care
843 * that the Tx FIFO is cleared AFTER the current frame
844 * is complete sent to the network.
845 *
846 * It takes about 12ns to send a frame with 1538 bytes.
847 * One PCI clock goes at least 15ns (66MHz). Therefore
848 * after reading XM_GP_PORT back, we are sure that the
849 * transmitter is disabled AND idle. And this means
850 * we may flush the transmit FIFO now.
851 *
852 * Returns:
853 * nothing
854 */
855static void SkXmSoftRst(
856SK_AC *pAC, /* adapter context */
857SK_IOC IoC, /* IO context */
858int Port) /* Port Index (MAC_1 + n) */
859{
860 SK_U16 ZeroAddr[4] = {0x0000, 0x0000, 0x0000, 0x0000};
861
862 /* reset the statistics module */
863 XM_OUT32(IoC, Port, XM_GP_PORT, XM_GP_RES_STAT);
864
865 /* disable all XMAC IRQs */
866 XM_OUT16(IoC, Port, XM_IMSK, 0xffff);
867
868 XM_OUT32(IoC, Port, XM_MODE, 0); /* clear Mode Reg */
869
870 XM_OUT16(IoC, Port, XM_TX_CMD, 0); /* reset TX CMD Reg */
871 XM_OUT16(IoC, Port, XM_RX_CMD, 0); /* reset RX CMD Reg */
872
873 /* disable all PHY IRQs */
874 switch (pAC->GIni.GP[Port].PhyType) {
875 case SK_PHY_BCOM:
876 SkXmPhyWrite(pAC, IoC, Port, PHY_BCOM_INT_MASK, 0xffff);
877 break;
878#ifdef OTHER_PHY
879 case SK_PHY_LONE:
880 SkXmPhyWrite(pAC, IoC, Port, PHY_LONE_INT_ENAB, 0);
881 break;
882 case SK_PHY_NAT:
883 /* todo: National
884 SkXmPhyWrite(pAC, IoC, Port, PHY_NAT_INT_MASK, 0xffff); */
885 break;
886#endif /* OTHER_PHY */
887 }
888
889 /* clear the Hash Register */
890 XM_OUTHASH(IoC, Port, XM_HSM, &ZeroAddr);
891
892 /* clear the Exact Match Address registers */
893 SkXmClrExactAddr(pAC, IoC, Port, 0, 15);
894
895 /* clear the Source Check Address registers */
896 XM_OUTHASH(IoC, Port, XM_SRC_CHK, &ZeroAddr);
897
898} /* SkXmSoftRst */
899
900
901/******************************************************************************
902 *
903 * SkXmHardRst() - Do a XMAC hardware reset
904 *
905 * Description:
906 * The XMAC of the specified 'Port' and all connected devices
907 * (PHY and SERDES) will receive a reset signal on its *Reset pins.
908 * External PHYs must be reset by clearing a bit in the GPIO register
909 * (Timing requirements: Broadcom: 400ns, Level One: none, National: 80ns).
910 *
911 * ATTENTION:
912 * It is absolutely necessary to reset the SW_RST Bit first
913 * before calling this function.
914 *
915 * Returns:
916 * nothing
917 */
918static void SkXmHardRst(
919SK_AC *pAC, /* adapter context */
920SK_IOC IoC, /* IO context */
921int Port) /* Port Index (MAC_1 + n) */
922{
923 SK_U32 Reg;
924 int i;
925 int TOut;
926 SK_U16 Word;
927
928 for (i = 0; i < 4; i++) {
929 /* TX_MFF_CTRL1 has 32 bits, but only the lowest 16 bits are used */
930 SK_OUT16(IoC, MR_ADDR(Port, TX_MFF_CTRL1), MFF_CLR_MAC_RST);
931
932 TOut = 0;
933 do {
934 if (TOut++ > 10000) {
935 /*
936 * Adapter seems to be in RESET state.
937 * Registers cannot be written.
938 */
939 return;
940 }
941
942 SK_OUT16(IoC, MR_ADDR(Port, TX_MFF_CTRL1), MFF_SET_MAC_RST);
943
944 SK_IN16(IoC, MR_ADDR(Port, TX_MFF_CTRL1), &Word);
945
946 } while ((Word & MFF_SET_MAC_RST) == 0);
947 }
948
949 /* For external PHYs there must be special handling */
950 if (pAC->GIni.GP[Port].PhyType != SK_PHY_XMAC) {
951
952 SK_IN32(IoC, B2_GP_IO, &Reg);
953
954 if (Port == 0) {
955 Reg |= GP_DIR_0; /* set to output */
956 Reg &= ~GP_IO_0; /* set PHY reset (active low) */
957 }
958 else {
959 Reg |= GP_DIR_2; /* set to output */
960 Reg &= ~GP_IO_2; /* set PHY reset (active low) */
961 }
962 /* reset external PHY */
963 SK_OUT32(IoC, B2_GP_IO, Reg);
964
965 /* short delay */
966 SK_IN32(IoC, B2_GP_IO, &Reg);
967 }
968} /* SkXmHardRst */
969
970
971/******************************************************************************
972 *
973 * SkXmClearRst() - Release the PHY & XMAC reset
974 *
975 * Description:
976 *
977 * Returns:
978 * nothing
979 */
980static void SkXmClearRst(
981SK_AC *pAC, /* adapter context */
982SK_IOC IoC, /* IO context */
983int Port) /* Port Index (MAC_1 + n) */
984{
985 SK_U32 DWord;
986
987 /* clear HW reset */
988 SK_OUT16(IoC, MR_ADDR(Port, TX_MFF_CTRL1), MFF_CLR_MAC_RST);
989
990 if (pAC->GIni.GP[Port].PhyType != SK_PHY_XMAC) {
991
992 SK_IN32(IoC, B2_GP_IO, &DWord);
993
994 if (Port == 0) {
995 DWord |= (GP_DIR_0 | GP_IO_0); /* set to output */
996 }
997 else {
998 DWord |= (GP_DIR_2 | GP_IO_2); /* set to output */
999 }
1000 /* Clear PHY reset */
1001 SK_OUT32(IoC, B2_GP_IO, DWord);
1002
1003 /* Enable GMII interface */
1004 XM_OUT16(IoC, Port, XM_HW_CFG, XM_HW_GMII_MD);
1005 }
1006} /* SkXmClearRst */
1007#endif /* GENESIS */
1008
1009
1010#ifdef YUKON
1011/******************************************************************************
1012 *
1013 * SkGmSoftRst() - Do a GMAC software reset
1014 *
1015 * Description:
1016 * The GPHY registers should not be destroyed during this
1017 * kind of software reset.
1018 *
1019 * Returns:
1020 * nothing
1021 */
1022static void SkGmSoftRst(
1023SK_AC *pAC, /* adapter context */
1024SK_IOC IoC, /* IO context */
1025int Port) /* Port Index (MAC_1 + n) */
1026{
1027 SK_U16 EmptyHash[4] = {0x0000, 0x0000, 0x0000, 0x0000};
1028 SK_U16 RxCtrl;
1029
1030 /* reset the statistics module */
1031
1032 /* disable all GMAC IRQs */
1033 SK_OUT8(IoC, GMAC_IRQ_MSK, 0);
1034
1035 /* disable all PHY IRQs */
1036 SkGmPhyWrite(pAC, IoC, Port, PHY_MARV_INT_MASK, 0);
1037
1038 /* clear the Hash Register */
1039 GM_OUTHASH(IoC, Port, GM_MC_ADDR_H1, EmptyHash);
1040
1041 /* Enable Unicast and Multicast filtering */
1042 GM_IN16(IoC, Port, GM_RX_CTRL, &RxCtrl);
1043
1044 GM_OUT16(IoC, Port, GM_RX_CTRL,
1045 (SK_U16)(RxCtrl | GM_RXCR_UCF_ENA | GM_RXCR_MCF_ENA));
1046
1047} /* SkGmSoftRst */
1048
1049
1050/******************************************************************************
1051 *
1052 * SkGmHardRst() - Do a GMAC hardware reset
1053 *
1054 * Description:
1055 *
1056 * Returns:
1057 * nothing
1058 */
1059static void SkGmHardRst(
1060SK_AC *pAC, /* adapter context */
1061SK_IOC IoC, /* IO context */
1062int Port) /* Port Index (MAC_1 + n) */
1063{
1064 SK_U32 DWord;
1065
1066 /* WA code for COMA mode */
1067 if (pAC->GIni.GIYukonLite &&
1068 pAC->GIni.GIChipRev >= CHIP_REV_YU_LITE_A3) {
1069
1070 SK_IN32(IoC, B2_GP_IO, &DWord);
1071
1072 DWord |= (GP_DIR_9 | GP_IO_9);
1073
1074 /* set PHY reset */
1075 SK_OUT32(IoC, B2_GP_IO, DWord);
1076 }
1077
1078 /* set GPHY Control reset */
1079 SK_OUT32(IoC, MR_ADDR(Port, GPHY_CTRL), GPC_RST_SET);
1080
1081 /* set GMAC Control reset */
1082 SK_OUT32(IoC, MR_ADDR(Port, GMAC_CTRL), GMC_RST_SET);
1083
1084} /* SkGmHardRst */
1085
1086
1087/******************************************************************************
1088 *
1089 * SkGmClearRst() - Release the GPHY & GMAC reset
1090 *
1091 * Description:
1092 *
1093 * Returns:
1094 * nothing
1095 */
1096static void SkGmClearRst(
1097SK_AC *pAC, /* adapter context */
1098SK_IOC IoC, /* IO context */
1099int Port) /* Port Index (MAC_1 + n) */
1100{
1101 SK_U32 DWord;
1102
1103#ifdef XXX
1104 /* clear GMAC Control reset */
1105 SK_OUT32(IoC, MR_ADDR(Port, GMAC_CTRL), GMC_RST_CLR);
1106
1107 /* set GMAC Control reset */
1108 SK_OUT32(IoC, MR_ADDR(Port, GMAC_CTRL), GMC_RST_SET);
1109#endif /* XXX */
1110
1111 /* WA code for COMA mode */
1112 if (pAC->GIni.GIYukonLite &&
1113 pAC->GIni.GIChipRev >= CHIP_REV_YU_LITE_A3) {
1114
1115 SK_IN32(IoC, B2_GP_IO, &DWord);
1116
1117 DWord |= GP_DIR_9; /* set to output */
1118 DWord &= ~GP_IO_9; /* clear PHY reset (active high) */
1119
1120 /* clear PHY reset */
1121 SK_OUT32(IoC, B2_GP_IO, DWord);
1122 }
1123
1124 /* set HWCFG_MODE */
1125 DWord = GPC_INT_POL_HI | GPC_DIS_FC | GPC_DIS_SLEEP |
1126 GPC_ENA_XC | GPC_ANEG_ADV_ALL_M | GPC_ENA_PAUSE |
1127 (pAC->GIni.GICopperType ? GPC_HWCFG_GMII_COP :
1128 GPC_HWCFG_GMII_FIB);
1129
1130 /* set GPHY Control reset */
1131 SK_OUT32(IoC, MR_ADDR(Port, GPHY_CTRL), DWord | GPC_RST_SET);
1132
1133 /* release GPHY Control reset */
1134 SK_OUT32(IoC, MR_ADDR(Port, GPHY_CTRL), DWord | GPC_RST_CLR);
1135
1136#ifdef VCPU
1137 VCpuWait(9000);
1138#endif /* VCPU */
1139
1140 /* clear GMAC Control reset */
1141 SK_OUT32(IoC, MR_ADDR(Port, GMAC_CTRL), GMC_PAUSE_ON | GMC_RST_CLR);
1142
1143#ifdef VCPU
1144 VCpuWait(2000);
1145
1146 SK_IN32(IoC, MR_ADDR(Port, GPHY_CTRL), &DWord);
1147
1148 SK_IN32(IoC, B0_ISRC, &DWord);
1149#endif /* VCPU */
1150
1151} /* SkGmClearRst */
1152#endif /* YUKON */
1153
1154
1155/******************************************************************************
1156 *
1157 * SkMacSoftRst() - Do a MAC software reset
1158 *
1159 * Description: calls a MAC software reset routine dep. on board type
1160 *
1161 * Returns:
1162 * nothing
1163 */
1164void SkMacSoftRst(
1165SK_AC *pAC, /* adapter context */
1166SK_IOC IoC, /* IO context */
1167int Port) /* Port Index (MAC_1 + n) */
1168{
1169 SK_GEPORT *pPrt;
1170
1171 pPrt = &pAC->GIni.GP[Port];
1172
1173 /* disable receiver and transmitter */
1174 SkMacRxTxDisable(pAC, IoC, Port);
1175
1176#ifdef GENESIS
1177 if (pAC->GIni.GIGenesis) {
1178
1179 SkXmSoftRst(pAC, IoC, Port);
1180 }
1181#endif /* GENESIS */
1182
1183#ifdef YUKON
1184 if (pAC->GIni.GIYukon) {
1185
1186 SkGmSoftRst(pAC, IoC, Port);
1187 }
1188#endif /* YUKON */
1189
1190 /* flush the MAC's Rx and Tx FIFOs */
1191 SkMacFlushTxFifo(pAC, IoC, Port);
1192
1193 SkMacFlushRxFifo(pAC, IoC, Port);
1194
1195 pPrt->PState = SK_PRT_STOP;
1196
1197} /* SkMacSoftRst */
1198
1199
1200/******************************************************************************
1201 *
1202 * SkMacHardRst() - Do a MAC hardware reset
1203 *
1204 * Description: calls a MAC hardware reset routine dep. on board type
1205 *
1206 * Returns:
1207 * nothing
1208 */
1209void SkMacHardRst(
1210SK_AC *pAC, /* adapter context */
1211SK_IOC IoC, /* IO context */
1212int Port) /* Port Index (MAC_1 + n) */
1213{
1214
1215#ifdef GENESIS
1216 if (pAC->GIni.GIGenesis) {
1217
1218 SkXmHardRst(pAC, IoC, Port);
1219 }
1220#endif /* GENESIS */
1221
1222#ifdef YUKON
1223 if (pAC->GIni.GIYukon) {
1224
1225 SkGmHardRst(pAC, IoC, Port);
1226 }
1227#endif /* YUKON */
1228
1229 pAC->GIni.GP[Port].PState = SK_PRT_RESET;
1230
1231} /* SkMacHardRst */
1232
1233
1234#ifdef GENESIS
1235/******************************************************************************
1236 *
1237 * SkXmInitMac() - Initialize the XMAC II
1238 *
1239 * Description:
1240 * Initialize the XMAC of the specified port.
1241 * The XMAC must be reset or stopped before calling this function.
1242 *
1243 * Note:
1244 * The XMAC's Rx and Tx state machine is still disabled when returning.
1245 *
1246 * Returns:
1247 * nothing
1248 */
1249void SkXmInitMac(
1250SK_AC *pAC, /* adapter context */
1251SK_IOC IoC, /* IO context */
1252int Port) /* Port Index (MAC_1 + n) */
1253{
1254 SK_GEPORT *pPrt;
1255 int i;
1256 SK_U16 SWord;
1257
1258 pPrt = &pAC->GIni.GP[Port];
1259
1260 if (pPrt->PState == SK_PRT_STOP) {
1261 /* Port State: SK_PRT_STOP */
1262 /* Verify that the reset bit is cleared */
1263 SK_IN16(IoC, MR_ADDR(Port, TX_MFF_CTRL1), &SWord);
1264
1265 if ((SWord & MFF_SET_MAC_RST) != 0) {
1266 /* PState does not match HW state */
1267 SK_ERR_LOG(pAC, SK_ERRCL_SW, SKERR_HWI_E006, SKERR_HWI_E006MSG);
1268 /* Correct it */
1269 pPrt->PState = SK_PRT_RESET;
1270 }
1271 }
1272
1273 if (pPrt->PState == SK_PRT_RESET) {
1274
1275 SkXmClearRst(pAC, IoC, Port);
1276
1277 if (pPrt->PhyType != SK_PHY_XMAC) {
1278 /* read Id from external PHY (all have the same address) */
1279 SkXmPhyRead(pAC, IoC, Port, PHY_XMAC_ID1, &pPrt->PhyId1);
1280
1281 /*
1282 * Optimize MDIO transfer by suppressing preamble.
1283 * Must be done AFTER first access to BCOM chip.
1284 */
1285 XM_IN16(IoC, Port, XM_MMU_CMD, &SWord);
1286
1287 XM_OUT16(IoC, Port, XM_MMU_CMD, SWord | XM_MMU_NO_PRE);
1288
1289 if (pPrt->PhyId1 == PHY_BCOM_ID1_C0) {
1290 /*
1291 * Workaround BCOM Errata for the C0 type.
1292 * Write magic patterns to reserved registers.
1293 */
1294 i = 0;
1295 while (BcomRegC0Hack[i].PhyReg != 0) {
1296 SkXmPhyWrite(pAC, IoC, Port, BcomRegC0Hack[i].PhyReg,
1297 BcomRegC0Hack[i].PhyVal);
1298 i++;
1299 }
1300 }
1301 else if (pPrt->PhyId1 == PHY_BCOM_ID1_A1) {
1302 /*
1303 * Workaround BCOM Errata for the A1 type.
1304 * Write magic patterns to reserved registers.
1305 */
1306 i = 0;
1307 while (BcomRegA1Hack[i].PhyReg != 0) {
1308 SkXmPhyWrite(pAC, IoC, Port, BcomRegA1Hack[i].PhyReg,
1309 BcomRegA1Hack[i].PhyVal);
1310 i++;
1311 }
1312 }
1313
1314 /*
1315 * Workaround BCOM Errata (#10523) for all BCom PHYs.
1316 * Disable Power Management after reset.
1317 */
1318 SkXmPhyRead(pAC, IoC, Port, PHY_BCOM_AUX_CTRL, &SWord);
1319
1320 SkXmPhyWrite(pAC, IoC, Port, PHY_BCOM_AUX_CTRL,
1321 (SK_U16)(SWord | PHY_B_AC_DIS_PM));
1322
1323 /* PHY LED initialization is done in SkGeXmitLED() */
1324 }
1325
1326 /* Dummy read the Interrupt source register */
1327 XM_IN16(IoC, Port, XM_ISRC, &SWord);
1328
1329 /*
1330 * The auto-negotiation process starts immediately after
1331 * clearing the reset. The auto-negotiation process should be
1332 * started by the SIRQ, therefore stop it here immediately.
1333 */
1334 SkMacInitPhy(pAC, IoC, Port, SK_FALSE);
1335
1336#ifdef TEST_ONLY
1337 /* temp. code: enable signal detect */
1338 /* WARNING: do not override GMII setting above */
1339 XM_OUT16(IoC, Port, XM_HW_CFG, XM_HW_COM4SIG);
1340#endif
1341 }
1342
1343 /*
1344 * configure the XMACs Station Address
1345 * B2_MAC_2 = xx xx xx xx xx x1 is programmed to XMAC A
1346 * B2_MAC_3 = xx xx xx xx xx x2 is programmed to XMAC B
1347 */
1348 for (i = 0; i < 3; i++) {
1349 /*
1350 * The following 2 statements are together endianess
1351 * independent. Remember this when changing.
1352 */
1353 SK_IN16(IoC, (B2_MAC_2 + Port * 8 + i * 2), &SWord);
1354
1355 XM_OUT16(IoC, Port, (XM_SA + i * 2), SWord);
1356 }
1357
1358 /* Tx Inter Packet Gap (XM_TX_IPG): use default */
1359 /* Tx High Water Mark (XM_TX_HI_WM): use default */
1360 /* Tx Low Water Mark (XM_TX_LO_WM): use default */
1361 /* Host Request Threshold (XM_HT_THR): use default */
1362 /* Rx Request Threshold (XM_RX_THR): use default */
1363 /* Rx Low Water Mark (XM_RX_LO_WM): use default */
1364
1365 /* configure Rx High Water Mark (XM_RX_HI_WM) */
1366 XM_OUT16(IoC, Port, XM_RX_HI_WM, SK_XM_RX_HI_WM);
1367
1368 /* Configure Tx Request Threshold */
1369 SWord = SK_XM_THR_SL; /* for single port */
1370
1371 if (pAC->GIni.GIMacsFound > 1) {
1372 switch (pAC->GIni.GIPortUsage) {
1373 case SK_RED_LINK:
1374 SWord = SK_XM_THR_REDL; /* redundant link */
1375 break;
1376 case SK_MUL_LINK:
1377 SWord = SK_XM_THR_MULL; /* load balancing */
1378 break;
1379 case SK_JUMBO_LINK:
1380 SWord = SK_XM_THR_JUMBO; /* jumbo frames */
1381 break;
1382 default:
1383 SK_ERR_LOG(pAC, SK_ERRCL_SW, SKERR_HWI_E014, SKERR_HWI_E014MSG);
1384 break;
1385 }
1386 }
1387 XM_OUT16(IoC, Port, XM_TX_THR, SWord);
1388
1389 /* setup register defaults for the Tx Command Register */
1390 XM_OUT16(IoC, Port, XM_TX_CMD, XM_TX_AUTO_PAD);
1391
1392 /* setup register defaults for the Rx Command Register */
1393 SWord = XM_RX_STRIP_FCS | XM_RX_LENERR_OK;
1394
1395 if (pAC->GIni.GIPortUsage == SK_JUMBO_LINK) {
1396 SWord |= XM_RX_BIG_PK_OK;
1397 }
1398
1399 if (pPrt->PLinkMode == SK_LMODE_HALF) {
1400 /*
1401 * If in manual half duplex mode the other side might be in
1402 * full duplex mode, so ignore if a carrier extension is not seen
1403 * on frames received
1404 */
1405 SWord |= XM_RX_DIS_CEXT;
1406 }
1407
1408 XM_OUT16(IoC, Port, XM_RX_CMD, SWord);
1409
1410 /*
1411 * setup register defaults for the Mode Register
1412 * - Don't strip error frames to avoid Store & Forward
1413 * on the Rx side.
1414 * - Enable 'Check Station Address' bit
1415 * - Enable 'Check Address Array' bit
1416 */
1417 XM_OUT32(IoC, Port, XM_MODE, XM_DEF_MODE);
1418
1419 /*
1420 * Initialize the Receive Counter Event Mask (XM_RX_EV_MSK)
1421 * - Enable all bits excepting 'Octets Rx OK Low CntOv'
1422 * and 'Octets Rx OK Hi Cnt Ov'.
1423 */
1424 XM_OUT32(IoC, Port, XM_RX_EV_MSK, XMR_DEF_MSK);
1425
1426 /*
1427 * Initialize the Transmit Counter Event Mask (XM_TX_EV_MSK)
1428 * - Enable all bits excepting 'Octets Tx OK Low CntOv'
1429 * and 'Octets Tx OK Hi Cnt Ov'.
1430 */
1431 XM_OUT32(IoC, Port, XM_TX_EV_MSK, XMT_DEF_MSK);
1432
1433 /*
1434 * Do NOT init XMAC interrupt mask here.
1435 * All interrupts remain disable until link comes up!
1436 */
1437
1438 /*
1439 * Any additional configuration changes may be done now.
1440 * The last action is to enable the Rx and Tx state machine.
1441 * This should be done after the auto-negotiation process
1442 * has been completed successfully.
1443 */
1444} /* SkXmInitMac */
1445#endif /* GENESIS */
1446
1447
1448#ifdef YUKON
1449/******************************************************************************
1450 *
1451 * SkGmInitMac() - Initialize the GMAC
1452 *
1453 * Description:
1454 * Initialize the GMAC of the specified port.
1455 * The GMAC must be reset or stopped before calling this function.
1456 *
1457 * Note:
1458 * The GMAC's Rx and Tx state machine is still disabled when returning.
1459 *
1460 * Returns:
1461 * nothing
1462 */
1463void SkGmInitMac(
1464SK_AC *pAC, /* adapter context */
1465SK_IOC IoC, /* IO context */
1466int Port) /* Port Index (MAC_1 + n) */
1467{
1468 SK_GEPORT *pPrt;
1469 int i;
1470 SK_U16 SWord;
1471 SK_U32 DWord;
1472
1473 pPrt = &pAC->GIni.GP[Port];
1474
1475 if (pPrt->PState == SK_PRT_STOP) {
1476 /* Port State: SK_PRT_STOP */
1477 /* Verify that the reset bit is cleared */
1478 SK_IN32(IoC, MR_ADDR(Port, GMAC_CTRL), &DWord);
1479
1480 if ((DWord & GMC_RST_SET) != 0) {
1481 /* PState does not match HW state */
1482 SK_ERR_LOG(pAC, SK_ERRCL_SW, SKERR_HWI_E006, SKERR_HWI_E006MSG);
1483 /* Correct it */
1484 pPrt->PState = SK_PRT_RESET;
1485 }
1486 }
1487
1488 if (pPrt->PState == SK_PRT_RESET) {
1489
1490 SkGmHardRst(pAC, IoC, Port);
1491
1492 SkGmClearRst(pAC, IoC, Port);
1493
1494 /* Auto-negotiation ? */
1495 if (pPrt->PLinkMode == SK_LMODE_HALF || pPrt->PLinkMode == SK_LMODE_FULL) {
1496 /* Auto-negotiation disabled */
1497
1498 /* get General Purpose Control */
1499 GM_IN16(IoC, Port, GM_GP_CTRL, &SWord);
1500
1501 /* disable auto-update for speed, duplex and flow-control */
1502 SWord |= GM_GPCR_AU_ALL_DIS;
1503
1504 /* setup General Purpose Control Register */
1505 GM_OUT16(IoC, Port, GM_GP_CTRL, SWord);
1506
1507 SWord = GM_GPCR_AU_ALL_DIS;
1508 }
1509 else {
1510 SWord = 0;
1511 }
1512
1513 /* speed settings */
1514 switch (pPrt->PLinkSpeed) {
1515 case SK_LSPEED_AUTO:
1516 case SK_LSPEED_1000MBPS:
1517 SWord |= GM_GPCR_SPEED_1000 | GM_GPCR_SPEED_100;
1518 break;
1519 case SK_LSPEED_100MBPS:
1520 SWord |= GM_GPCR_SPEED_100;
1521 break;
1522 case SK_LSPEED_10MBPS:
1523 break;
1524 }
1525
1526 /* duplex settings */
1527 if (pPrt->PLinkMode != SK_LMODE_HALF) {
1528 /* set full duplex */
1529 SWord |= GM_GPCR_DUP_FULL;
1530 }
1531
1532 /* flow-control settings */
1533 switch (pPrt->PFlowCtrlMode) {
1534 case SK_FLOW_MODE_NONE:
1535 /* set Pause Off */
1536 SK_OUT32(IoC, MR_ADDR(Port, GMAC_CTRL), GMC_PAUSE_OFF);
1537 /* disable Tx & Rx flow-control */
1538 SWord |= GM_GPCR_FC_TX_DIS | GM_GPCR_FC_RX_DIS | GM_GPCR_AU_FCT_DIS;
1539 break;
1540 case SK_FLOW_MODE_LOC_SEND:
1541 /* disable Rx flow-control */
1542 SWord |= GM_GPCR_FC_RX_DIS | GM_GPCR_AU_FCT_DIS;
1543 break;
1544 case SK_FLOW_MODE_SYMMETRIC:
1545 case SK_FLOW_MODE_SYM_OR_REM:
1546 /* enable Tx & Rx flow-control */
1547 break;
1548 }
1549
1550 /* setup General Purpose Control Register */
1551 GM_OUT16(IoC, Port, GM_GP_CTRL, SWord);
1552
1553 /* dummy read the Interrupt Source Register */
1554 SK_IN16(IoC, GMAC_IRQ_SRC, &SWord);
1555
1556#ifndef VCPU
1557 /* read Id from PHY */
1558 SkGmPhyRead(pAC, IoC, Port, PHY_MARV_ID1, &pPrt->PhyId1);
1559
1560 SkGmInitPhyMarv(pAC, IoC, Port, SK_FALSE);
1561#endif /* VCPU */
1562 }
1563
1564 (void)SkGmResetCounter(pAC, IoC, Port);
1565
1566 /* setup Transmit Control Register */
1567 GM_OUT16(IoC, Port, GM_TX_CTRL, TX_COL_THR(pPrt->PMacColThres));
1568
1569 /* setup Receive Control Register */
1570 GM_OUT16(IoC, Port, GM_RX_CTRL, GM_RXCR_UCF_ENA | GM_RXCR_MCF_ENA |
1571 GM_RXCR_CRC_DIS);
1572
1573 /* setup Transmit Flow Control Register */
1574 GM_OUT16(IoC, Port, GM_TX_FLOW_CTRL, 0xffff);
1575
1576 /* setup Transmit Parameter Register */
1577#ifdef VCPU
1578 GM_IN16(IoC, Port, GM_TX_PARAM, &SWord);
1579#endif /* VCPU */
1580
1581 SWord = TX_JAM_LEN_VAL(pPrt->PMacJamLen) |
1582 TX_JAM_IPG_VAL(pPrt->PMacJamIpgVal) |
1583 TX_IPG_JAM_DATA(pPrt->PMacJamIpgData);
1584
1585 GM_OUT16(IoC, Port, GM_TX_PARAM, SWord);
1586
1587 /* configure the Serial Mode Register */
1588#ifdef VCPU
1589 GM_IN16(IoC, Port, GM_SERIAL_MODE, &SWord);
1590#endif /* VCPU */
1591
1592 SWord = GM_SMOD_VLAN_ENA | IPG_DATA_VAL(pPrt->PMacIpgData);
1593
1594 if (pPrt->PMacLimit4) {
1595 /* reset of collision counter after 4 consecutive collisions */
1596 SWord |= GM_SMOD_LIMIT_4;
1597 }
1598
1599 if (pAC->GIni.GIPortUsage == SK_JUMBO_LINK) {
1600 /* enable jumbo mode (Max. Frame Length = 9018) */
1601 SWord |= GM_SMOD_JUMBO_ENA;
1602 }
1603
1604 GM_OUT16(IoC, Port, GM_SERIAL_MODE, SWord);
1605
1606 /*
1607 * configure the GMACs Station Addresses
1608 * in PROM you can find our addresses at:
1609 * B2_MAC_1 = xx xx xx xx xx x0 virtual address
1610 * B2_MAC_2 = xx xx xx xx xx x1 is programmed to GMAC A
1611 * B2_MAC_3 = xx xx xx xx xx x2 is reserved for DualPort
1612 */
1613
1614 for (i = 0; i < 3; i++) {
1615 /*
1616 * The following 2 statements are together endianess
1617 * independent. Remember this when changing.
1618 */
1619 /* physical address: will be used for pause frames */
1620 SK_IN16(IoC, (B2_MAC_2 + Port * 8 + i * 2), &SWord);
1621
1622#ifdef WA_DEV_16
1623 /* WA for deviation #16 */
1624 if (pAC->GIni.GIChipId == CHIP_ID_YUKON && pAC->GIni.GIChipRev == 0) {
1625 /* swap the address bytes */
1626 SWord = ((SWord & 0xff00) >> 8) | ((SWord & 0x00ff) << 8);
1627
1628 /* write to register in reversed order */
1629 GM_OUT16(IoC, Port, (GM_SRC_ADDR_1L + (2 - i) * 4), SWord);
1630 }
1631 else {
1632 GM_OUT16(IoC, Port, (GM_SRC_ADDR_1L + i * 4), SWord);
1633 }
1634#else
1635 GM_OUT16(IoC, Port, (GM_SRC_ADDR_1L + i * 4), SWord);
1636#endif /* WA_DEV_16 */
1637
1638 /* virtual address: will be used for data */
1639 SK_IN16(IoC, (B2_MAC_1 + Port * 8 + i * 2), &SWord);
1640
1641 GM_OUT16(IoC, Port, (GM_SRC_ADDR_2L + i * 4), SWord);
1642
1643 /* reset Multicast filtering Hash registers 1-3 */
1644 GM_OUT16(IoC, Port, GM_MC_ADDR_H1 + 4*i, 0);
1645 }
1646
1647 /* reset Multicast filtering Hash register 4 */
1648 GM_OUT16(IoC, Port, GM_MC_ADDR_H4, 0);
1649
1650 /* enable interrupt mask for counter overflows */
1651 GM_OUT16(IoC, Port, GM_TX_IRQ_MSK, 0);
1652 GM_OUT16(IoC, Port, GM_RX_IRQ_MSK, 0);
1653 GM_OUT16(IoC, Port, GM_TR_IRQ_MSK, 0);
1654
1655#if defined(SK_DIAG) || defined(DEBUG)
1656 /* read General Purpose Status */
1657 GM_IN16(IoC, Port, GM_GP_STAT, &SWord);
1658
1659 SK_DBG_MSG(pAC, SK_DBGMOD_HWM, SK_DBGCAT_CTRL,
1660 ("MAC Stat Reg.=0x%04X\n", SWord));
1661#endif /* SK_DIAG || DEBUG */
1662
1663#ifdef SK_DIAG
1664 c_print("MAC Stat Reg=0x%04X\n", SWord);
1665#endif /* SK_DIAG */
1666
1667} /* SkGmInitMac */
1668#endif /* YUKON */
1669
1670
1671#ifdef GENESIS
1672/******************************************************************************
1673 *
1674 * SkXmInitDupMd() - Initialize the XMACs Duplex Mode
1675 *
1676 * Description:
1677 * This function initializes the XMACs Duplex Mode.
1678 * It should be called after successfully finishing
1679 * the Auto-negotiation Process
1680 *
1681 * Returns:
1682 * nothing
1683 */
1684static void SkXmInitDupMd(
1685SK_AC *pAC, /* adapter context */
1686SK_IOC IoC, /* IO context */
1687int Port) /* Port Index (MAC_1 + n) */
1688{
1689 switch (pAC->GIni.GP[Port].PLinkModeStatus) {
1690 case SK_LMODE_STAT_AUTOHALF:
1691 case SK_LMODE_STAT_HALF:
1692 /* Configuration Actions for Half Duplex Mode */
1693 /*
1694 * XM_BURST = default value. We are probable not quick
1695 * enough at the 'XMAC' bus to burst 8kB.
1696 * The XMAC stops bursting if no transmit frames
1697 * are available or the burst limit is exceeded.
1698 */
1699 /* XM_TX_RT_LIM = default value (15) */
1700 /* XM_TX_STIME = default value (0xff = 4096 bit times) */
1701 break;
1702 case SK_LMODE_STAT_AUTOFULL:
1703 case SK_LMODE_STAT_FULL:
1704 /* Configuration Actions for Full Duplex Mode */
1705 /*
1706 * The duplex mode is configured by the PHY,
1707 * therefore it seems to be that there is nothing
1708 * to do here.
1709 */
1710 break;
1711 case SK_LMODE_STAT_UNKNOWN:
1712 default:
1713 SK_ERR_LOG(pAC, SK_ERRCL_SW, SKERR_HWI_E007, SKERR_HWI_E007MSG);
1714 break;
1715 }
1716} /* SkXmInitDupMd */
1717
1718
1719/******************************************************************************
1720 *
1721 * SkXmInitPauseMd() - initialize the Pause Mode to be used for this port
1722 *
1723 * Description:
1724 * This function initializes the Pause Mode which should
1725 * be used for this port.
1726 * It should be called after successfully finishing
1727 * the Auto-negotiation Process
1728 *
1729 * Returns:
1730 * nothing
1731 */
1732static void SkXmInitPauseMd(
1733SK_AC *pAC, /* adapter context */
1734SK_IOC IoC, /* IO context */
1735int Port) /* Port Index (MAC_1 + n) */
1736{
1737 SK_GEPORT *pPrt;
1738 SK_U32 DWord;
1739 SK_U16 Word;
1740
1741 pPrt = &pAC->GIni.GP[Port];
1742
1743 XM_IN16(IoC, Port, XM_MMU_CMD, &Word);
1744
1745 if (pPrt->PFlowCtrlStatus == SK_FLOW_STAT_NONE ||
1746 pPrt->PFlowCtrlStatus == SK_FLOW_STAT_LOC_SEND) {
1747
1748 /* Disable Pause Frame Reception */
1749 Word |= XM_MMU_IGN_PF;
1750 }
1751 else {
1752 /*
1753 * enabling pause frame reception is required for 1000BT
1754 * because the XMAC is not reset if the link is going down
1755 */
1756 /* Enable Pause Frame Reception */
1757 Word &= ~XM_MMU_IGN_PF;
1758 }
1759
1760 XM_OUT16(IoC, Port, XM_MMU_CMD, Word);
1761
1762 XM_IN32(IoC, Port, XM_MODE, &DWord);
1763
1764 if (pPrt->PFlowCtrlStatus == SK_FLOW_STAT_SYMMETRIC ||
1765 pPrt->PFlowCtrlStatus == SK_FLOW_STAT_LOC_SEND) {
1766
1767 /*
1768 * Configure Pause Frame Generation
1769 * Use internal and external Pause Frame Generation.
1770 * Sending pause frames is edge triggered.
1771 * Send a Pause frame with the maximum pause time if
1772 * internal oder external FIFO full condition occurs.
1773 * Send a zero pause time frame to re-start transmission.
1774 */
1775
1776 /* XM_PAUSE_DA = '010000C28001' (default) */
1777
1778 /* XM_MAC_PTIME = 0xffff (maximum) */
1779 /* remember this value is defined in big endian (!) */
1780 XM_OUT16(IoC, Port, XM_MAC_PTIME, 0xffff);
1781
1782 /* Set Pause Mode in Mode Register */
1783 DWord |= XM_PAUSE_MODE;
1784
1785 /* Set Pause Mode in MAC Rx FIFO */
1786 SK_OUT16(IoC, MR_ADDR(Port, RX_MFF_CTRL1), MFF_ENA_PAUSE);
1787 }
1788 else {
1789 /*
1790 * disable pause frame generation is required for 1000BT
1791 * because the XMAC is not reset if the link is going down
1792 */
1793 /* Disable Pause Mode in Mode Register */
1794 DWord &= ~XM_PAUSE_MODE;
1795
1796 /* Disable Pause Mode in MAC Rx FIFO */
1797 SK_OUT16(IoC, MR_ADDR(Port, RX_MFF_CTRL1), MFF_DIS_PAUSE);
1798 }
1799
1800 XM_OUT32(IoC, Port, XM_MODE, DWord);
1801} /* SkXmInitPauseMd*/
1802
1803
1804/******************************************************************************
1805 *
1806 * SkXmInitPhyXmac() - Initialize the XMAC Phy registers
1807 *
1808 * Description: initializes all the XMACs Phy registers
1809 *
1810 * Note:
1811 *
1812 * Returns:
1813 * nothing
1814 */
1815static void SkXmInitPhyXmac(
1816SK_AC *pAC, /* adapter context */
1817SK_IOC IoC, /* IO context */
1818int Port, /* Port Index (MAC_1 + n) */
1819SK_BOOL DoLoop) /* Should a Phy LoopBack be set-up? */
1820{
1821 SK_GEPORT *pPrt;
1822 SK_U16 Ctrl;
1823
1824 pPrt = &pAC->GIni.GP[Port];
1825 Ctrl = 0;
1826
1827 /* Auto-negotiation ? */
1828 if (pPrt->PLinkMode == SK_LMODE_HALF || pPrt->PLinkMode == SK_LMODE_FULL) {
1829 SK_DBG_MSG(pAC, SK_DBGMOD_HWM, SK_DBGCAT_CTRL,
1830 ("InitPhyXmac: no auto-negotiation Port %d\n", Port));
1831 /* Set DuplexMode in Config register */
1832 if (pPrt->PLinkMode == SK_LMODE_FULL) {
1833 Ctrl |= PHY_CT_DUP_MD;
1834 }
1835
1836 /*
1837 * Do NOT enable Auto-negotiation here. This would hold
1838 * the link down because no IDLEs are transmitted
1839 */
1840 }
1841 else {
1842 SK_DBG_MSG(pAC, SK_DBGMOD_HWM, SK_DBGCAT_CTRL,
1843 ("InitPhyXmac: with auto-negotiation Port %d\n", Port));
1844 /* Set Auto-negotiation advertisement */
1845
1846 /* Set Full/half duplex capabilities */
1847 switch (pPrt->PLinkMode) {
1848 case SK_LMODE_AUTOHALF:
1849 Ctrl |= PHY_X_AN_HD;
1850 break;
1851 case SK_LMODE_AUTOFULL:
1852 Ctrl |= PHY_X_AN_FD;
1853 break;
1854 case SK_LMODE_AUTOBOTH:
1855 Ctrl |= PHY_X_AN_FD | PHY_X_AN_HD;
1856 break;
1857 default:
1858 SK_ERR_LOG(pAC, SK_ERRCL_SW | SK_ERRCL_INIT, SKERR_HWI_E015,
1859 SKERR_HWI_E015MSG);
1860 }
1861
1862 /* Set Flow-control capabilities */
1863 switch (pPrt->PFlowCtrlMode) {
1864 case SK_FLOW_MODE_NONE:
1865 Ctrl |= PHY_X_P_NO_PAUSE;
1866 break;
1867 case SK_FLOW_MODE_LOC_SEND:
1868 Ctrl |= PHY_X_P_ASYM_MD;
1869 break;
1870 case SK_FLOW_MODE_SYMMETRIC:
1871 Ctrl |= PHY_X_P_SYM_MD;
1872 break;
1873 case SK_FLOW_MODE_SYM_OR_REM:
1874 Ctrl |= PHY_X_P_BOTH_MD;
1875 break;
1876 default:
1877 SK_ERR_LOG(pAC, SK_ERRCL_SW | SK_ERRCL_INIT, SKERR_HWI_E016,
1878 SKERR_HWI_E016MSG);
1879 }
1880
1881 /* Write AutoNeg Advertisement Register */
1882 SkXmPhyWrite(pAC, IoC, Port, PHY_XMAC_AUNE_ADV, Ctrl);
1883
1884 /* Restart Auto-negotiation */
1885 Ctrl = PHY_CT_ANE | PHY_CT_RE_CFG;
1886 }
1887
1888 if (DoLoop) {
1889 /* Set the Phy Loopback bit, too */
1890 Ctrl |= PHY_CT_LOOP;
1891 }
1892
1893 /* Write to the Phy control register */
1894 SkXmPhyWrite(pAC, IoC, Port, PHY_XMAC_CTRL, Ctrl);
1895} /* SkXmInitPhyXmac */
1896
1897
1898/******************************************************************************
1899 *
1900 * SkXmInitPhyBcom() - Initialize the Broadcom Phy registers
1901 *
1902 * Description: initializes all the Broadcom Phy registers
1903 *
1904 * Note:
1905 *
1906 * Returns:
1907 * nothing
1908 */
1909static void SkXmInitPhyBcom(
1910SK_AC *pAC, /* adapter context */
1911SK_IOC IoC, /* IO context */
1912int Port, /* Port Index (MAC_1 + n) */
1913SK_BOOL DoLoop) /* Should a Phy LoopBack be set-up? */
1914{
1915 SK_GEPORT *pPrt;
1916 SK_U16 Ctrl1;
1917 SK_U16 Ctrl2;
1918 SK_U16 Ctrl3;
1919 SK_U16 Ctrl4;
1920 SK_U16 Ctrl5;
1921
1922 Ctrl1 = PHY_CT_SP1000;
1923 Ctrl2 = 0;
1924 Ctrl3 = PHY_SEL_TYPE;
1925 Ctrl4 = PHY_B_PEC_EN_LTR;
1926 Ctrl5 = PHY_B_AC_TX_TST;
1927
1928 pPrt = &pAC->GIni.GP[Port];
1929
1930 /* manually Master/Slave ? */
1931 if (pPrt->PMSMode != SK_MS_MODE_AUTO) {
1932 Ctrl2 |= PHY_B_1000C_MSE;
1933
1934 if (pPrt->PMSMode == SK_MS_MODE_MASTER) {
1935 Ctrl2 |= PHY_B_1000C_MSC;
1936 }
1937 }
1938 /* Auto-negotiation ? */
1939 if (pPrt->PLinkMode == SK_LMODE_HALF || pPrt->PLinkMode == SK_LMODE_FULL) {
1940 SK_DBG_MSG(pAC, SK_DBGMOD_HWM, SK_DBGCAT_CTRL,
1941 ("InitPhyBcom: no auto-negotiation Port %d\n", Port));
1942 /* Set DuplexMode in Config register */
1943 if (pPrt->PLinkMode == SK_LMODE_FULL) {
1944 Ctrl1 |= PHY_CT_DUP_MD;
1945 }
1946
1947 /* Determine Master/Slave manually if not already done */
1948 if (pPrt->PMSMode == SK_MS_MODE_AUTO) {
1949 Ctrl2 |= PHY_B_1000C_MSE; /* set it to Slave */
1950 }
1951
1952 /*
1953 * Do NOT enable Auto-negotiation here. This would hold
1954 * the link down because no IDLES are transmitted
1955 */
1956 }
1957 else {
1958 SK_DBG_MSG(pAC, SK_DBGMOD_HWM, SK_DBGCAT_CTRL,
1959 ("InitPhyBcom: with auto-negotiation Port %d\n", Port));
1960 /* Set Auto-negotiation advertisement */
1961
1962 /*
1963 * Workaround BCOM Errata #1 for the C5 type.
1964 * 1000Base-T Link Acquisition Failure in Slave Mode
1965 * Set Repeater/DTE bit 10 of the 1000Base-T Control Register
1966 */
1967 Ctrl2 |= PHY_B_1000C_RD;
1968
1969 /* Set Full/half duplex capabilities */
1970 switch (pPrt->PLinkMode) {
1971 case SK_LMODE_AUTOHALF:
1972 Ctrl2 |= PHY_B_1000C_AHD;
1973 break;
1974 case SK_LMODE_AUTOFULL:
1975 Ctrl2 |= PHY_B_1000C_AFD;
1976 break;
1977 case SK_LMODE_AUTOBOTH:
1978 Ctrl2 |= PHY_B_1000C_AFD | PHY_B_1000C_AHD;
1979 break;
1980 default:
1981 SK_ERR_LOG(pAC, SK_ERRCL_SW | SK_ERRCL_INIT, SKERR_HWI_E015,
1982 SKERR_HWI_E015MSG);
1983 }
1984
1985 /* Set Flow-control capabilities */
1986 switch (pPrt->PFlowCtrlMode) {
1987 case SK_FLOW_MODE_NONE:
1988 Ctrl3 |= PHY_B_P_NO_PAUSE;
1989 break;
1990 case SK_FLOW_MODE_LOC_SEND:
1991 Ctrl3 |= PHY_B_P_ASYM_MD;
1992 break;
1993 case SK_FLOW_MODE_SYMMETRIC:
1994 Ctrl3 |= PHY_B_P_SYM_MD;
1995 break;
1996 case SK_FLOW_MODE_SYM_OR_REM:
1997 Ctrl3 |= PHY_B_P_BOTH_MD;
1998 break;
1999 default:
2000 SK_ERR_LOG(pAC, SK_ERRCL_SW | SK_ERRCL_INIT, SKERR_HWI_E016,
2001 SKERR_HWI_E016MSG);
2002 }
2003
2004 /* Restart Auto-negotiation */
2005 Ctrl1 |= PHY_CT_ANE | PHY_CT_RE_CFG;
2006 }
2007
2008 /* Initialize LED register here? */
2009 /* No. Please do it in SkDgXmitLed() (if required) and swap
2010 init order of LEDs and XMAC. (MAl) */
2011
2012 /* Write 1000Base-T Control Register */
2013 SkXmPhyWrite(pAC, IoC, Port, PHY_BCOM_1000T_CTRL, Ctrl2);
2014 SK_DBG_MSG(pAC, SK_DBGMOD_HWM, SK_DBGCAT_CTRL,
2015 ("Set 1000B-T Ctrl Reg=0x%04X\n", Ctrl2));
2016
2017 /* Write AutoNeg Advertisement Register */
2018 SkXmPhyWrite(pAC, IoC, Port, PHY_BCOM_AUNE_ADV, Ctrl3);
2019 SK_DBG_MSG(pAC, SK_DBGMOD_HWM, SK_DBGCAT_CTRL,
2020 ("Set Auto-Neg.Adv.Reg=0x%04X\n", Ctrl3));
2021
2022 if (DoLoop) {
2023 /* Set the Phy Loopback bit, too */
2024 Ctrl1 |= PHY_CT_LOOP;
2025 }
2026
2027 if (pAC->GIni.GIPortUsage == SK_JUMBO_LINK) {
2028 /* configure FIFO to high latency for transmission of ext. packets */
2029 Ctrl4 |= PHY_B_PEC_HIGH_LA;
2030
2031 /* configure reception of extended packets */
2032 Ctrl5 |= PHY_B_AC_LONG_PACK;
2033
2034 SkXmPhyWrite(pAC, IoC, Port, PHY_BCOM_AUX_CTRL, Ctrl5);
2035 }
2036
2037 /* Configure LED Traffic Mode and Jumbo Frame usage if specified */
2038 SkXmPhyWrite(pAC, IoC, Port, PHY_BCOM_P_EXT_CTRL, Ctrl4);
2039
2040 /* Write to the Phy control register */
2041 SkXmPhyWrite(pAC, IoC, Port, PHY_BCOM_CTRL, Ctrl1);
2042 SK_DBG_MSG(pAC, SK_DBGMOD_HWM, SK_DBGCAT_CTRL,
2043 ("PHY Control Reg=0x%04X\n", Ctrl1));
2044} /* SkXmInitPhyBcom */
2045#endif /* GENESIS */
2046
2047#ifdef YUKON
2048/******************************************************************************
2049 *
2050 * SkGmInitPhyMarv() - Initialize the Marvell Phy registers
2051 *
2052 * Description: initializes all the Marvell Phy registers
2053 *
2054 * Note:
2055 *
2056 * Returns:
2057 * nothing
2058 */
2059static void SkGmInitPhyMarv(
2060SK_AC *pAC, /* adapter context */
2061SK_IOC IoC, /* IO context */
2062int Port, /* Port Index (MAC_1 + n) */
2063SK_BOOL DoLoop) /* Should a Phy LoopBack be set-up? */
2064{
2065 SK_GEPORT *pPrt;
2066 SK_U16 PhyCtrl;
2067 SK_U16 C1000BaseT;
2068 SK_U16 AutoNegAdv;
2069 SK_U16 ExtPhyCtrl;
2070 SK_U16 LedCtrl;
2071 SK_BOOL AutoNeg;
2072#if defined(SK_DIAG) || defined(DEBUG)
2073 SK_U16 PhyStat;
2074 SK_U16 PhyStat1;
2075 SK_U16 PhySpecStat;
2076#endif /* SK_DIAG || DEBUG */
2077
2078 pPrt = &pAC->GIni.GP[Port];
2079
2080 /* Auto-negotiation ? */
2081 if (pPrt->PLinkMode == SK_LMODE_HALF || pPrt->PLinkMode == SK_LMODE_FULL) {
2082 AutoNeg = SK_FALSE;
2083 }
2084 else {
2085 AutoNeg = SK_TRUE;
2086 }
2087
2088 SK_DBG_MSG(pAC, SK_DBGMOD_HWM, SK_DBGCAT_CTRL,
2089 ("InitPhyMarv: Port %d, auto-negotiation %s\n",
2090 Port, AutoNeg ? "ON" : "OFF"));
2091
2092#ifdef VCPU
2093 VCPUprintf(0, "SkGmInitPhyMarv(), Port=%u, DoLoop=%u\n",
2094 Port, DoLoop);
2095#else /* VCPU */
2096 if (DoLoop) {
2097 /* Set 'MAC Power up'-bit, set Manual MDI configuration */
2098 SkGmPhyWrite(pAC, IoC, Port, PHY_MARV_PHY_CTRL,
2099 PHY_M_PC_MAC_POW_UP);
2100 }
2101 else if (AutoNeg && pPrt->PLinkSpeed == SK_LSPEED_AUTO) {
2102 /* Read Ext. PHY Specific Control */
2103 SkGmPhyRead(pAC, IoC, Port, PHY_MARV_EXT_CTRL, &ExtPhyCtrl);
2104
2105 ExtPhyCtrl &= ~(PHY_M_EC_M_DSC_MSK | PHY_M_EC_S_DSC_MSK |
2106 PHY_M_EC_MAC_S_MSK);
2107
2108 ExtPhyCtrl |= PHY_M_EC_MAC_S(MAC_TX_CLK_25_MHZ) |
2109 PHY_M_EC_M_DSC(0) | PHY_M_EC_S_DSC(1);
2110
2111 SkGmPhyWrite(pAC, IoC, Port, PHY_MARV_EXT_CTRL, ExtPhyCtrl);
2112 SK_DBG_MSG(pAC, SK_DBGMOD_HWM, SK_DBGCAT_CTRL,
2113 ("Set Ext. PHY Ctrl=0x%04X\n", ExtPhyCtrl));
2114 }
2115
2116 /* Read PHY Control */
2117 SkGmPhyRead(pAC, IoC, Port, PHY_MARV_CTRL, &PhyCtrl);
2118
2119 if (!AutoNeg) {
2120 /* Disable Auto-negotiation */
2121 PhyCtrl &= ~PHY_CT_ANE;
2122 }
2123
2124 PhyCtrl |= PHY_CT_RESET;
2125 /* Assert software reset */
2126 SkGmPhyWrite(pAC, IoC, Port, PHY_MARV_CTRL, PhyCtrl);
2127#endif /* VCPU */
2128
2129 PhyCtrl = 0 /* PHY_CT_COL_TST */;
2130 C1000BaseT = 0;
2131 AutoNegAdv = PHY_SEL_TYPE;
2132
2133 /* manually Master/Slave ? */
2134 if (pPrt->PMSMode != SK_MS_MODE_AUTO) {
2135 /* enable Manual Master/Slave */
2136 C1000BaseT |= PHY_M_1000C_MSE;
2137
2138 if (pPrt->PMSMode == SK_MS_MODE_MASTER) {
2139 C1000BaseT |= PHY_M_1000C_MSC; /* set it to Master */
2140 }
2141 }
2142
2143 /* Auto-negotiation ? */
2144 if (!AutoNeg) {
2145
2146 if (pPrt->PLinkMode == SK_LMODE_FULL) {
2147 /* Set Full Duplex Mode */
2148 PhyCtrl |= PHY_CT_DUP_MD;
2149 }
2150
2151 /* Set Master/Slave manually if not already done */
2152 if (pPrt->PMSMode == SK_MS_MODE_AUTO) {
2153 C1000BaseT |= PHY_M_1000C_MSE; /* set it to Slave */
2154 }
2155
2156 /* Set Speed */
2157 switch (pPrt->PLinkSpeed) {
2158 case SK_LSPEED_AUTO:
2159 case SK_LSPEED_1000MBPS:
2160 PhyCtrl |= PHY_CT_SP1000;
2161 break;
2162 case SK_LSPEED_100MBPS:
2163 PhyCtrl |= PHY_CT_SP100;
2164 break;
2165 case SK_LSPEED_10MBPS:
2166 break;
2167 default:
2168 SK_ERR_LOG(pAC, SK_ERRCL_SW | SK_ERRCL_INIT, SKERR_HWI_E019,
2169 SKERR_HWI_E019MSG);
2170 }
2171
2172 if (!DoLoop) {
2173 PhyCtrl |= PHY_CT_RESET;
2174 }
2175 }
2176 else {
2177 /* Set Auto-negotiation advertisement */
2178
2179 if (pAC->GIni.GICopperType) {
2180 /* Set Speed capabilities */
2181 switch (pPrt->PLinkSpeed) {
2182 case SK_LSPEED_AUTO:
2183 C1000BaseT |= PHY_M_1000C_AHD | PHY_M_1000C_AFD;
2184 AutoNegAdv |= PHY_M_AN_100_FD | PHY_M_AN_100_HD |
2185 PHY_M_AN_10_FD | PHY_M_AN_10_HD;
2186 break;
2187 case SK_LSPEED_1000MBPS:
2188 C1000BaseT |= PHY_M_1000C_AHD | PHY_M_1000C_AFD;
2189 break;
2190 case SK_LSPEED_100MBPS:
2191 AutoNegAdv |= PHY_M_AN_100_FD | PHY_M_AN_100_HD |
2192 /* advertise 10Base-T also */
2193 PHY_M_AN_10_FD | PHY_M_AN_10_HD;
2194 break;
2195 case SK_LSPEED_10MBPS:
2196 AutoNegAdv |= PHY_M_AN_10_FD | PHY_M_AN_10_HD;
2197 break;
2198 default:
2199 SK_ERR_LOG(pAC, SK_ERRCL_SW | SK_ERRCL_INIT, SKERR_HWI_E019,
2200 SKERR_HWI_E019MSG);
2201 }
2202
2203 /* Set Full/half duplex capabilities */
2204 switch (pPrt->PLinkMode) {
2205 case SK_LMODE_AUTOHALF:
2206 C1000BaseT &= ~PHY_M_1000C_AFD;
2207 AutoNegAdv &= ~(PHY_M_AN_100_FD | PHY_M_AN_10_FD);
2208 break;
2209 case SK_LMODE_AUTOFULL:
2210 C1000BaseT &= ~PHY_M_1000C_AHD;
2211 AutoNegAdv &= ~(PHY_M_AN_100_HD | PHY_M_AN_10_HD);
2212 break;
2213 case SK_LMODE_AUTOBOTH:
2214 break;
2215 default:
2216 SK_ERR_LOG(pAC, SK_ERRCL_SW | SK_ERRCL_INIT, SKERR_HWI_E015,
2217 SKERR_HWI_E015MSG);
2218 }
2219
2220 /* Set Flow-control capabilities */
2221 switch (pPrt->PFlowCtrlMode) {
2222 case SK_FLOW_MODE_NONE:
2223 AutoNegAdv |= PHY_B_P_NO_PAUSE;
2224 break;
2225 case SK_FLOW_MODE_LOC_SEND:
2226 AutoNegAdv |= PHY_B_P_ASYM_MD;
2227 break;
2228 case SK_FLOW_MODE_SYMMETRIC:
2229 AutoNegAdv |= PHY_B_P_SYM_MD;
2230 break;
2231 case SK_FLOW_MODE_SYM_OR_REM:
2232 AutoNegAdv |= PHY_B_P_BOTH_MD;
2233 break;
2234 default:
2235 SK_ERR_LOG(pAC, SK_ERRCL_SW | SK_ERRCL_INIT, SKERR_HWI_E016,
2236 SKERR_HWI_E016MSG);
2237 }
2238 }
2239 else { /* special defines for FIBER (88E1011S only) */
2240
2241 /* Set Full/half duplex capabilities */
2242 switch (pPrt->PLinkMode) {
2243 case SK_LMODE_AUTOHALF:
2244 AutoNegAdv |= PHY_M_AN_1000X_AHD;
2245 break;
2246 case SK_LMODE_AUTOFULL:
2247 AutoNegAdv |= PHY_M_AN_1000X_AFD;
2248 break;
2249 case SK_LMODE_AUTOBOTH:
2250 AutoNegAdv |= PHY_M_AN_1000X_AHD | PHY_M_AN_1000X_AFD;
2251 break;
2252 default:
2253 SK_ERR_LOG(pAC, SK_ERRCL_SW | SK_ERRCL_INIT, SKERR_HWI_E015,
2254 SKERR_HWI_E015MSG);
2255 }
2256
2257 /* Set Flow-control capabilities */
2258 switch (pPrt->PFlowCtrlMode) {
2259 case SK_FLOW_MODE_NONE:
2260 AutoNegAdv |= PHY_M_P_NO_PAUSE_X;
2261 break;
2262 case SK_FLOW_MODE_LOC_SEND:
2263 AutoNegAdv |= PHY_M_P_ASYM_MD_X;
2264 break;
2265 case SK_FLOW_MODE_SYMMETRIC:
2266 AutoNegAdv |= PHY_M_P_SYM_MD_X;
2267 break;
2268 case SK_FLOW_MODE_SYM_OR_REM:
2269 AutoNegAdv |= PHY_M_P_BOTH_MD_X;
2270 break;
2271 default:
2272 SK_ERR_LOG(pAC, SK_ERRCL_SW | SK_ERRCL_INIT, SKERR_HWI_E016,
2273 SKERR_HWI_E016MSG);
2274 }
2275 }
2276
2277 if (!DoLoop) {
2278 /* Restart Auto-negotiation */
2279 PhyCtrl |= PHY_CT_ANE | PHY_CT_RE_CFG;
2280 }
2281 }
2282
2283#ifdef VCPU
2284 /*
2285 * E-mail from Gu Lin (08-03-2002):
2286 */
2287
2288 /* Program PHY register 30 as 16'h0708 for simulation speed up */
2289 SkGmPhyWrite(pAC, IoC, Port, 30, 0x0700 /* 0x0708 */);
2290
2291 VCpuWait(2000);
2292
2293#else /* VCPU */
2294
2295 /* Write 1000Base-T Control Register */
2296 SkGmPhyWrite(pAC, IoC, Port, PHY_MARV_1000T_CTRL, C1000BaseT);
2297 SK_DBG_MSG(pAC, SK_DBGMOD_HWM, SK_DBGCAT_CTRL,
2298 ("Set 1000B-T Ctrl =0x%04X\n", C1000BaseT));
2299
2300 /* Write AutoNeg Advertisement Register */
2301 SkGmPhyWrite(pAC, IoC, Port, PHY_MARV_AUNE_ADV, AutoNegAdv);
2302 SK_DBG_MSG(pAC, SK_DBGMOD_HWM, SK_DBGCAT_CTRL,
2303 ("Set Auto-Neg.Adv.=0x%04X\n", AutoNegAdv));
2304#endif /* VCPU */
2305
2306 if (DoLoop) {
2307 /* Set the PHY Loopback bit */
2308 PhyCtrl |= PHY_CT_LOOP;
2309
2310#ifdef XXX
2311 /* Program PHY register 16 as 16'h0400 to force link good */
2312 SkGmPhyWrite(pAC, IoC, Port, PHY_MARV_PHY_CTRL, PHY_M_PC_FL_GOOD);
2313#endif /* XXX */
2314
2315#ifndef VCPU
2316 if (pPrt->PLinkSpeed != SK_LSPEED_AUTO) {
2317 /* Write Ext. PHY Specific Control */
2318 SkGmPhyWrite(pAC, IoC, Port, PHY_MARV_EXT_CTRL,
2319 (SK_U16)((pPrt->PLinkSpeed + 2) << 4));
2320 }
2321#endif /* VCPU */
2322 }
2323#ifdef TEST_ONLY
2324 else if (pPrt->PLinkSpeed == SK_LSPEED_10MBPS) {
2325 /* Write PHY Specific Control */
2326 SkGmPhyWrite(pAC, IoC, Port, PHY_MARV_PHY_CTRL,
2327 PHY_M_PC_EN_DET_MSK);
2328 }
2329#endif
2330
2331 /* Write to the PHY Control register */
2332 SkGmPhyWrite(pAC, IoC, Port, PHY_MARV_CTRL, PhyCtrl);
2333 SK_DBG_MSG(pAC, SK_DBGMOD_HWM, SK_DBGCAT_CTRL,
2334 ("Set PHY Ctrl Reg.=0x%04X\n", PhyCtrl));
2335
2336#ifdef VCPU
2337 VCpuWait(2000);
2338#else
2339
2340 LedCtrl = PHY_M_LED_PULS_DUR(PULS_170MS) | PHY_M_LED_BLINK_RT(BLINK_84MS);
2341
2342 if ((pAC->GIni.GILedBlinkCtrl & SK_ACT_LED_BLINK) != 0) {
2343 LedCtrl |= PHY_M_LEDC_RX_CTRL | PHY_M_LEDC_TX_CTRL;
2344 }
2345
2346 if ((pAC->GIni.GILedBlinkCtrl & SK_DUP_LED_NORMAL) != 0) {
2347 LedCtrl |= PHY_M_LEDC_DP_CTRL;
2348 }
2349
2350 SkGmPhyWrite(pAC, IoC, Port, PHY_MARV_LED_CTRL, LedCtrl);
2351
2352 if ((pAC->GIni.GILedBlinkCtrl & SK_LED_LINK100_ON) != 0) {
2353 /* only in forced 100 Mbps mode */
2354 if (!AutoNeg && pPrt->PLinkSpeed == SK_LSPEED_100MBPS) {
2355
2356 SkGmPhyWrite(pAC, IoC, Port, PHY_MARV_LED_OVER,
2357 PHY_M_LED_MO_100(MO_LED_ON));
2358 }
2359 }
2360
2361#ifdef SK_DIAG
2362 c_print("Set PHY Ctrl=0x%04X\n", PhyCtrl);
2363 c_print("Set 1000 B-T=0x%04X\n", C1000BaseT);
2364 c_print("Set Auto-Neg=0x%04X\n", AutoNegAdv);
2365 c_print("Set Ext Ctrl=0x%04X\n", ExtPhyCtrl);
2366#endif /* SK_DIAG */
2367
2368#if defined(SK_DIAG) || defined(DEBUG)
2369 /* Read PHY Control */
2370 SkGmPhyRead(pAC, IoC, Port, PHY_MARV_CTRL, &PhyCtrl);
2371 SK_DBG_MSG(pAC, SK_DBGMOD_HWM, SK_DBGCAT_CTRL,
2372 ("PHY Ctrl Reg.=0x%04X\n", PhyCtrl));
2373
2374 /* Read 1000Base-T Control Register */
2375 SkGmPhyRead(pAC, IoC, Port, PHY_MARV_1000T_CTRL, &C1000BaseT);
2376 SK_DBG_MSG(pAC, SK_DBGMOD_HWM, SK_DBGCAT_CTRL,
2377 ("1000B-T Ctrl =0x%04X\n", C1000BaseT));
2378
2379 /* Read AutoNeg Advertisement Register */
2380 SkGmPhyRead(pAC, IoC, Port, PHY_MARV_AUNE_ADV, &AutoNegAdv);
2381 SK_DBG_MSG(pAC, SK_DBGMOD_HWM, SK_DBGCAT_CTRL,
2382 ("Auto-Neg.Adv.=0x%04X\n", AutoNegAdv));
2383
2384 /* Read Ext. PHY Specific Control */
2385 SkGmPhyRead(pAC, IoC, Port, PHY_MARV_EXT_CTRL, &ExtPhyCtrl);
2386 SK_DBG_MSG(pAC, SK_DBGMOD_HWM, SK_DBGCAT_CTRL,
2387 ("Ext. PHY Ctrl=0x%04X\n", ExtPhyCtrl));
2388
2389 /* Read PHY Status */
2390 SkGmPhyRead(pAC, IoC, Port, PHY_MARV_STAT, &PhyStat);
2391 SK_DBG_MSG(pAC, SK_DBGMOD_HWM, SK_DBGCAT_CTRL,
2392 ("PHY Stat Reg.=0x%04X\n", PhyStat));
2393 SkGmPhyRead(pAC, IoC, Port, PHY_MARV_STAT, &PhyStat1);
2394 SK_DBG_MSG(pAC, SK_DBGMOD_HWM, SK_DBGCAT_CTRL,
2395 ("PHY Stat Reg.=0x%04X\n", PhyStat1));
2396
2397 /* Read PHY Specific Status */
2398 SkGmPhyRead(pAC, IoC, Port, PHY_MARV_PHY_STAT, &PhySpecStat);
2399 SK_DBG_MSG(pAC, SK_DBGMOD_HWM, SK_DBGCAT_CTRL,
2400 ("PHY Spec Stat=0x%04X\n", PhySpecStat));
2401#endif /* SK_DIAG || DEBUG */
2402
2403#ifdef SK_DIAG
2404 c_print("PHY Ctrl Reg=0x%04X\n", PhyCtrl);
2405 c_print("PHY 1000 Reg=0x%04X\n", C1000BaseT);
2406 c_print("PHY AnAd Reg=0x%04X\n", AutoNegAdv);
2407 c_print("Ext Ctrl Reg=0x%04X\n", ExtPhyCtrl);
2408 c_print("PHY Stat Reg=0x%04X\n", PhyStat);
2409 c_print("PHY Stat Reg=0x%04X\n", PhyStat1);
2410 c_print("PHY Spec Reg=0x%04X\n", PhySpecStat);
2411#endif /* SK_DIAG */
2412
2413#endif /* VCPU */
2414
2415} /* SkGmInitPhyMarv */
2416#endif /* YUKON */
2417
2418
2419#ifdef OTHER_PHY
2420/******************************************************************************
2421 *
2422 * SkXmInitPhyLone() - Initialize the Level One Phy registers
2423 *
2424 * Description: initializes all the Level One Phy registers
2425 *
2426 * Note:
2427 *
2428 * Returns:
2429 * nothing
2430 */
2431static void SkXmInitPhyLone(
2432SK_AC *pAC, /* adapter context */
2433SK_IOC IoC, /* IO context */
2434int Port, /* Port Index (MAC_1 + n) */
2435SK_BOOL DoLoop) /* Should a Phy LoopBack be set-up? */
2436{
2437 SK_GEPORT *pPrt;
2438 SK_U16 Ctrl1;
2439 SK_U16 Ctrl2;
2440 SK_U16 Ctrl3;
2441
2442 Ctrl1 = PHY_CT_SP1000;
2443 Ctrl2 = 0;
2444 Ctrl3 = PHY_SEL_TYPE;
2445
2446 pPrt = &pAC->GIni.GP[Port];
2447
2448 /* manually Master/Slave ? */
2449 if (pPrt->PMSMode != SK_MS_MODE_AUTO) {
2450 Ctrl2 |= PHY_L_1000C_MSE;
2451
2452 if (pPrt->PMSMode == SK_MS_MODE_MASTER) {
2453 Ctrl2 |= PHY_L_1000C_MSC;
2454 }
2455 }
2456 /* Auto-negotiation ? */
2457 if (pPrt->PLinkMode == SK_LMODE_HALF || pPrt->PLinkMode == SK_LMODE_FULL) {
2458 /*
2459 * level one spec say: "1000 Mbps: manual mode not allowed"
2460 * but lets see what happens...
2461 */
2462 SK_DBG_MSG(pAC, SK_DBGMOD_HWM, SK_DBGCAT_CTRL,
2463 ("InitPhyLone: no auto-negotiation Port %d\n", Port));
2464 /* Set DuplexMode in Config register */
2465 if (pPrt->PLinkMode == SK_LMODE_FULL) {
2466 Ctrl1 |= PHY_CT_DUP_MD;
2467 }
2468
2469 /* Determine Master/Slave manually if not already done */
2470 if (pPrt->PMSMode == SK_MS_MODE_AUTO) {
2471 Ctrl2 |= PHY_L_1000C_MSE; /* set it to Slave */
2472 }
2473
2474 /*
2475 * Do NOT enable Auto-negotiation here. This would hold
2476 * the link down because no IDLES are transmitted
2477 */
2478 }
2479 else {
2480 SK_DBG_MSG(pAC, SK_DBGMOD_HWM, SK_DBGCAT_CTRL,
2481 ("InitPhyLone: with auto-negotiation Port %d\n", Port));
2482 /* Set Auto-negotiation advertisement */
2483
2484 /* Set Full/half duplex capabilities */
2485 switch (pPrt->PLinkMode) {
2486 case SK_LMODE_AUTOHALF:
2487 Ctrl2 |= PHY_L_1000C_AHD;
2488 break;
2489 case SK_LMODE_AUTOFULL:
2490 Ctrl2 |= PHY_L_1000C_AFD;
2491 break;
2492 case SK_LMODE_AUTOBOTH:
2493 Ctrl2 |= PHY_L_1000C_AFD | PHY_L_1000C_AHD;
2494 break;
2495 default:
2496 SK_ERR_LOG(pAC, SK_ERRCL_SW | SK_ERRCL_INIT, SKERR_HWI_E015,
2497 SKERR_HWI_E015MSG);
2498 }
2499
2500 /* Set Flow-control capabilities */
2501 switch (pPrt->PFlowCtrlMode) {
2502 case SK_FLOW_MODE_NONE:
2503 Ctrl3 |= PHY_L_P_NO_PAUSE;
2504 break;
2505 case SK_FLOW_MODE_LOC_SEND:
2506 Ctrl3 |= PHY_L_P_ASYM_MD;
2507 break;
2508 case SK_FLOW_MODE_SYMMETRIC:
2509 Ctrl3 |= PHY_L_P_SYM_MD;
2510 break;
2511 case SK_FLOW_MODE_SYM_OR_REM:
2512 Ctrl3 |= PHY_L_P_BOTH_MD;
2513 break;
2514 default:
2515 SK_ERR_LOG(pAC, SK_ERRCL_SW | SK_ERRCL_INIT, SKERR_HWI_E016,
2516 SKERR_HWI_E016MSG);
2517 }
2518
2519 /* Restart Auto-negotiation */
2520 Ctrl1 = PHY_CT_ANE | PHY_CT_RE_CFG;
2521 }
2522
2523 /* Write 1000Base-T Control Register */
2524 SkXmPhyWrite(pAC, IoC, Port, PHY_LONE_1000T_CTRL, Ctrl2);
2525 SK_DBG_MSG(pAC, SK_DBGMOD_HWM, SK_DBGCAT_CTRL,
2526 ("1000B-T Ctrl Reg=0x%04X\n", Ctrl2));
2527
2528 /* Write AutoNeg Advertisement Register */
2529 SkXmPhyWrite(pAC, IoC, Port, PHY_LONE_AUNE_ADV, Ctrl3);
2530 SK_DBG_MSG(pAC, SK_DBGMOD_HWM, SK_DBGCAT_CTRL,
2531 ("Auto-Neg.Adv.Reg=0x%04X\n", Ctrl3));
2532
2533 if (DoLoop) {
2534 /* Set the Phy Loopback bit, too */
2535 Ctrl1 |= PHY_CT_LOOP;
2536 }
2537
2538 /* Write to the Phy control register */
2539 SkXmPhyWrite(pAC, IoC, Port, PHY_LONE_CTRL, Ctrl1);
2540 SK_DBG_MSG(pAC, SK_DBGMOD_HWM, SK_DBGCAT_CTRL,
2541 ("PHY Control Reg=0x%04X\n", Ctrl1));
2542} /* SkXmInitPhyLone */
2543
2544
2545/******************************************************************************
2546 *
2547 * SkXmInitPhyNat() - Initialize the National Phy registers
2548 *
2549 * Description: initializes all the National Phy registers
2550 *
2551 * Note:
2552 *
2553 * Returns:
2554 * nothing
2555 */
2556static void SkXmInitPhyNat(
2557SK_AC *pAC, /* adapter context */
2558SK_IOC IoC, /* IO context */
2559int Port, /* Port Index (MAC_1 + n) */
2560SK_BOOL DoLoop) /* Should a Phy LoopBack be set-up? */
2561{
2562/* todo: National */
2563} /* SkXmInitPhyNat */
2564#endif /* OTHER_PHY */
2565
2566
2567/******************************************************************************
2568 *
2569 * SkMacInitPhy() - Initialize the PHY registers
2570 *
2571 * Description: calls the Init PHY routines dep. on board type
2572 *
2573 * Note:
2574 *
2575 * Returns:
2576 * nothing
2577 */
2578void SkMacInitPhy(
2579SK_AC *pAC, /* adapter context */
2580SK_IOC IoC, /* IO context */
2581int Port, /* Port Index (MAC_1 + n) */
2582SK_BOOL DoLoop) /* Should a Phy LoopBack be set-up? */
2583{
2584 SK_GEPORT *pPrt;
2585
2586 pPrt = &pAC->GIni.GP[Port];
2587
2588#ifdef GENESIS
2589 if (pAC->GIni.GIGenesis) {
2590
2591 switch (pPrt->PhyType) {
2592 case SK_PHY_XMAC:
2593 SkXmInitPhyXmac(pAC, IoC, Port, DoLoop);
2594 break;
2595 case SK_PHY_BCOM:
2596 SkXmInitPhyBcom(pAC, IoC, Port, DoLoop);
2597 break;
2598#ifdef OTHER_PHY
2599 case SK_PHY_LONE:
2600 SkXmInitPhyLone(pAC, IoC, Port, DoLoop);
2601 break;
2602 case SK_PHY_NAT:
2603 SkXmInitPhyNat(pAC, IoC, Port, DoLoop);
2604 break;
2605#endif /* OTHER_PHY */
2606 }
2607 }
2608#endif /* GENESIS */
2609
2610#ifdef YUKON
2611 if (pAC->GIni.GIYukon) {
2612
2613 SkGmInitPhyMarv(pAC, IoC, Port, DoLoop);
2614 }
2615#endif /* YUKON */
2616
2617} /* SkMacInitPhy */
2618
2619
2620#ifdef GENESIS
2621/******************************************************************************
2622 *
2623 * SkXmAutoNegDoneXmac() - Auto-negotiation handling
2624 *
2625 * Description:
2626 * This function handles the auto-negotiation if the Done bit is set.
2627 *
2628 * Returns:
2629 * SK_AND_OK o.k.
2630 * SK_AND_DUP_CAP Duplex capability error happened
2631 * SK_AND_OTHER Other error happened
2632 */
2633static int SkXmAutoNegDoneXmac(
2634SK_AC *pAC, /* adapter context */
2635SK_IOC IoC, /* IO context */
2636int Port) /* Port Index (MAC_1 + n) */
2637{
2638 SK_GEPORT *pPrt;
2639 SK_U16 ResAb; /* Resolved Ability */
2640 SK_U16 LPAb; /* Link Partner Ability */
2641
2642 SK_DBG_MSG(pAC, SK_DBGMOD_HWM, SK_DBGCAT_CTRL,
2643 ("AutoNegDoneXmac, Port %d\n", Port));
2644
2645 pPrt = &pAC->GIni.GP[Port];
2646
2647 /* Get PHY parameters */
2648 SkXmPhyRead(pAC, IoC, Port, PHY_XMAC_AUNE_LP, &LPAb);
2649 SkXmPhyRead(pAC, IoC, Port, PHY_XMAC_RES_ABI, &ResAb);
2650
2651 if ((LPAb & PHY_X_AN_RFB) != 0) {
2652 /* At least one of the remote fault bit is set */
2653 /* Error */
2654 SK_DBG_MSG(pAC, SK_DBGMOD_HWM, SK_DBGCAT_CTRL,
2655 ("AutoNegFail: Remote fault bit set Port %d\n", Port));
2656 pPrt->PAutoNegFail = SK_TRUE;
2657 return(SK_AND_OTHER);
2658 }
2659
2660 /* Check Duplex mismatch */
2661 if ((ResAb & (PHY_X_RS_HD | PHY_X_RS_FD)) == PHY_X_RS_FD) {
2662 pPrt->PLinkModeStatus = (SK_U8)SK_LMODE_STAT_AUTOFULL;
2663 }
2664 else if ((ResAb & (PHY_X_RS_HD | PHY_X_RS_FD)) == PHY_X_RS_HD) {
2665 pPrt->PLinkModeStatus = (SK_U8)SK_LMODE_STAT_AUTOHALF;
2666 }
2667 else {
2668 /* Error */
2669 SK_DBG_MSG(pAC, SK_DBGMOD_HWM, SK_DBGCAT_CTRL,
2670 ("AutoNegFail: Duplex mode mismatch Port %d\n", Port));
2671 pPrt->PAutoNegFail = SK_TRUE;
2672 return(SK_AND_DUP_CAP);
2673 }
2674
2675 /* Check PAUSE mismatch */
2676 /* We are NOT using chapter 4.23 of the Xaqti manual */
2677 /* We are using IEEE 802.3z/D5.0 Table 37-4 */
2678 if ((pPrt->PFlowCtrlMode == SK_FLOW_MODE_SYMMETRIC ||
2679 pPrt->PFlowCtrlMode == SK_FLOW_MODE_SYM_OR_REM) &&
2680 (LPAb & PHY_X_P_SYM_MD) != 0) {
2681 /* Symmetric PAUSE */
2682 pPrt->PFlowCtrlStatus = SK_FLOW_STAT_SYMMETRIC;
2683 }
2684 else if (pPrt->PFlowCtrlMode == SK_FLOW_MODE_SYM_OR_REM &&
2685 (LPAb & PHY_X_RS_PAUSE) == PHY_X_P_ASYM_MD) {
2686 /* Enable PAUSE receive, disable PAUSE transmit */
2687 pPrt->PFlowCtrlStatus = SK_FLOW_STAT_REM_SEND;
2688 }
2689 else if (pPrt->PFlowCtrlMode == SK_FLOW_MODE_LOC_SEND &&
2690 (LPAb & PHY_X_RS_PAUSE) == PHY_X_P_BOTH_MD) {
2691 /* Disable PAUSE receive, enable PAUSE transmit */
2692 pPrt->PFlowCtrlStatus = SK_FLOW_STAT_LOC_SEND;
2693 }
2694 else {
2695 /* PAUSE mismatch -> no PAUSE */
2696 pPrt->PFlowCtrlStatus = SK_FLOW_STAT_NONE;
2697 }
2698 pPrt->PLinkSpeedUsed = (SK_U8)SK_LSPEED_STAT_1000MBPS;
2699
2700 return(SK_AND_OK);
2701} /* SkXmAutoNegDoneXmac */
2702
2703
2704/******************************************************************************
2705 *
2706 * SkXmAutoNegDoneBcom() - Auto-negotiation handling
2707 *
2708 * Description:
2709 * This function handles the auto-negotiation if the Done bit is set.
2710 *
2711 * Returns:
2712 * SK_AND_OK o.k.
2713 * SK_AND_DUP_CAP Duplex capability error happened
2714 * SK_AND_OTHER Other error happened
2715 */
2716static int SkXmAutoNegDoneBcom(
2717SK_AC *pAC, /* adapter context */
2718SK_IOC IoC, /* IO context */
2719int Port) /* Port Index (MAC_1 + n) */
2720{
2721 SK_GEPORT *pPrt;
2722 SK_U16 LPAb; /* Link Partner Ability */
2723 SK_U16 AuxStat; /* Auxiliary Status */
2724
2725#ifdef TEST_ONLY
272601-Sep-2000 RA;:;:
2727 SK_U16 ResAb; /* Resolved Ability */
2728#endif /* 0 */
2729
2730 SK_DBG_MSG(pAC, SK_DBGMOD_HWM, SK_DBGCAT_CTRL,
2731 ("AutoNegDoneBcom, Port %d\n", Port));
2732 pPrt = &pAC->GIni.GP[Port];
2733
2734 /* Get PHY parameters */
2735 SkXmPhyRead(pAC, IoC, Port, PHY_BCOM_AUNE_LP, &LPAb);
2736#ifdef TEST_ONLY
273701-Sep-2000 RA;:;:
2738 SkXmPhyRead(pAC, IoC, Port, PHY_BCOM_1000T_STAT, &ResAb);
2739#endif /* 0 */
2740
2741 SkXmPhyRead(pAC, IoC, Port, PHY_BCOM_AUX_STAT, &AuxStat);
2742
2743 if ((LPAb & PHY_B_AN_RF) != 0) {
2744 /* Remote fault bit is set: Error */
2745 SK_DBG_MSG(pAC, SK_DBGMOD_HWM, SK_DBGCAT_CTRL,
2746 ("AutoNegFail: Remote fault bit set Port %d\n", Port));
2747 pPrt->PAutoNegFail = SK_TRUE;
2748 return(SK_AND_OTHER);
2749 }
2750
2751 /* Check Duplex mismatch */
2752 if ((AuxStat & PHY_B_AS_AN_RES_MSK) == PHY_B_RES_1000FD) {
2753 pPrt->PLinkModeStatus = (SK_U8)SK_LMODE_STAT_AUTOFULL;
2754 }
2755 else if ((AuxStat & PHY_B_AS_AN_RES_MSK) == PHY_B_RES_1000HD) {
2756 pPrt->PLinkModeStatus = (SK_U8)SK_LMODE_STAT_AUTOHALF;
2757 }
2758 else {
2759 /* Error */
2760 SK_DBG_MSG(pAC, SK_DBGMOD_HWM, SK_DBGCAT_CTRL,
2761 ("AutoNegFail: Duplex mode mismatch Port %d\n", Port));
2762 pPrt->PAutoNegFail = SK_TRUE;
2763 return(SK_AND_DUP_CAP);
2764 }
2765
2766#ifdef TEST_ONLY
276701-Sep-2000 RA;:;:
2768 /* Check Master/Slave resolution */
2769 if ((ResAb & PHY_B_1000S_MSF) != 0) {
2770 SK_DBG_MSG(pAC, SK_DBGMOD_HWM, SK_DBGCAT_CTRL,
2771 ("Master/Slave Fault Port %d\n", Port));
2772 pPrt->PAutoNegFail = SK_TRUE;
2773 pPrt->PMSStatus = SK_MS_STAT_FAULT;
2774 return(SK_AND_OTHER);
2775 }
2776
2777 pPrt->PMSStatus = ((ResAb & PHY_B_1000S_MSR) != 0) ?
2778 SK_MS_STAT_MASTER : SK_MS_STAT_SLAVE;
2779#endif /* 0 */
2780
2781 /* Check PAUSE mismatch ??? */
2782 /* We are using IEEE 802.3z/D5.0 Table 37-4 */
2783 if ((AuxStat & PHY_B_AS_PAUSE_MSK) == PHY_B_AS_PAUSE_MSK) {
2784 /* Symmetric PAUSE */
2785 pPrt->PFlowCtrlStatus = SK_FLOW_STAT_SYMMETRIC;
2786 }
2787 else if ((AuxStat & PHY_B_AS_PAUSE_MSK) == PHY_B_AS_PRR) {
2788 /* Enable PAUSE receive, disable PAUSE transmit */
2789 pPrt->PFlowCtrlStatus = SK_FLOW_STAT_REM_SEND;
2790 }
2791 else if ((AuxStat & PHY_B_AS_PAUSE_MSK) == PHY_B_AS_PRT) {
2792 /* Disable PAUSE receive, enable PAUSE transmit */
2793 pPrt->PFlowCtrlStatus = SK_FLOW_STAT_LOC_SEND;
2794 }
2795 else {
2796 /* PAUSE mismatch -> no PAUSE */
2797 pPrt->PFlowCtrlStatus = SK_FLOW_STAT_NONE;
2798 }
2799 pPrt->PLinkSpeedUsed = (SK_U8)SK_LSPEED_STAT_1000MBPS;
2800
2801 return(SK_AND_OK);
2802} /* SkXmAutoNegDoneBcom */
2803#endif /* GENESIS */
2804
2805
2806#ifdef YUKON
2807/******************************************************************************
2808 *
2809 * SkGmAutoNegDoneMarv() - Auto-negotiation handling
2810 *
2811 * Description:
2812 * This function handles the auto-negotiation if the Done bit is set.
2813 *
2814 * Returns:
2815 * SK_AND_OK o.k.
2816 * SK_AND_DUP_CAP Duplex capability error happened
2817 * SK_AND_OTHER Other error happened
2818 */
2819static int SkGmAutoNegDoneMarv(
2820SK_AC *pAC, /* adapter context */
2821SK_IOC IoC, /* IO context */
2822int Port) /* Port Index (MAC_1 + n) */
2823{
2824 SK_GEPORT *pPrt;
2825 SK_U16 LPAb; /* Link Partner Ability */
2826 SK_U16 ResAb; /* Resolved Ability */
2827 SK_U16 AuxStat; /* Auxiliary Status */
2828
2829 SK_DBG_MSG(pAC, SK_DBGMOD_HWM, SK_DBGCAT_CTRL,
2830 ("AutoNegDoneMarv, Port %d\n", Port));
2831 pPrt = &pAC->GIni.GP[Port];
2832
2833 /* Get PHY parameters */
2834 SkGmPhyRead(pAC, IoC, Port, PHY_MARV_AUNE_LP, &LPAb);
2835 SK_DBG_MSG(pAC, SK_DBGMOD_HWM, SK_DBGCAT_CTRL,
2836 ("Link P.Abil.=0x%04X\n", LPAb));
2837
2838 if ((LPAb & PHY_M_AN_RF) != 0) {
2839 SK_DBG_MSG(pAC, SK_DBGMOD_HWM, SK_DBGCAT_CTRL,
2840 ("AutoNegFail: Remote fault bit set Port %d\n", Port));
2841 pPrt->PAutoNegFail = SK_TRUE;
2842 return(SK_AND_OTHER);
2843 }
2844
2845 SkGmPhyRead(pAC, IoC, Port, PHY_MARV_1000T_STAT, &ResAb);
2846
2847 /* Check Master/Slave resolution */
2848 if ((ResAb & PHY_B_1000S_MSF) != 0) {
2849 SK_DBG_MSG(pAC, SK_DBGMOD_HWM, SK_DBGCAT_CTRL,
2850 ("Master/Slave Fault Port %d\n", Port));
2851 pPrt->PAutoNegFail = SK_TRUE;
2852 pPrt->PMSStatus = SK_MS_STAT_FAULT;
2853 return(SK_AND_OTHER);
2854 }
2855
2856 pPrt->PMSStatus = ((ResAb & PHY_B_1000S_MSR) != 0) ?
2857 (SK_U8)SK_MS_STAT_MASTER : (SK_U8)SK_MS_STAT_SLAVE;
2858
2859 /* Read PHY Specific Status */
2860 SkGmPhyRead(pAC, IoC, Port, PHY_MARV_PHY_STAT, &AuxStat);
2861
2862 /* Check Speed & Duplex resolved */
2863 if ((AuxStat & PHY_M_PS_SPDUP_RES) == 0) {
2864 SK_DBG_MSG(pAC, SK_DBGMOD_HWM, SK_DBGCAT_CTRL,
2865 ("AutoNegFail: Speed & Duplex not resolved, Port %d\n", Port));
2866 pPrt->PAutoNegFail = SK_TRUE;
2867 pPrt->PLinkModeStatus = (SK_U8)SK_LMODE_STAT_UNKNOWN;
2868 return(SK_AND_DUP_CAP);
2869 }
2870
2871 if ((AuxStat & PHY_M_PS_FULL_DUP) != 0) {
2872 pPrt->PLinkModeStatus = (SK_U8)SK_LMODE_STAT_AUTOFULL;
2873 }
2874 else {
2875 pPrt->PLinkModeStatus = (SK_U8)SK_LMODE_STAT_AUTOHALF;
2876 }
2877
2878 /* Check PAUSE mismatch ??? */
2879 /* We are using IEEE 802.3z/D5.0 Table 37-4 */
2880 if ((AuxStat & PHY_M_PS_PAUSE_MSK) == PHY_M_PS_PAUSE_MSK) {
2881 /* Symmetric PAUSE */
2882 pPrt->PFlowCtrlStatus = SK_FLOW_STAT_SYMMETRIC;
2883 }
2884 else if ((AuxStat & PHY_M_PS_PAUSE_MSK) == PHY_M_PS_RX_P_EN) {
2885 /* Enable PAUSE receive, disable PAUSE transmit */
2886 pPrt->PFlowCtrlStatus = SK_FLOW_STAT_REM_SEND;
2887 }
2888 else if ((AuxStat & PHY_M_PS_PAUSE_MSK) == PHY_M_PS_TX_P_EN) {
2889 /* Disable PAUSE receive, enable PAUSE transmit */
2890 pPrt->PFlowCtrlStatus = SK_FLOW_STAT_LOC_SEND;
2891 }
2892 else {
2893 /* PAUSE mismatch -> no PAUSE */
2894 pPrt->PFlowCtrlStatus = SK_FLOW_STAT_NONE;
2895 }
2896
2897 /* set used link speed */
2898 switch ((unsigned)(AuxStat & PHY_M_PS_SPEED_MSK)) {
2899 case (unsigned)PHY_M_PS_SPEED_1000:
2900 pPrt->PLinkSpeedUsed = (SK_U8)SK_LSPEED_STAT_1000MBPS;
2901 break;
2902 case PHY_M_PS_SPEED_100:
2903 pPrt->PLinkSpeedUsed = (SK_U8)SK_LSPEED_STAT_100MBPS;
2904 break;
2905 default:
2906 pPrt->PLinkSpeedUsed = (SK_U8)SK_LSPEED_STAT_10MBPS;
2907 }
2908
2909 return(SK_AND_OK);
2910} /* SkGmAutoNegDoneMarv */
2911#endif /* YUKON */
2912
2913
2914#ifdef OTHER_PHY
2915/******************************************************************************
2916 *
2917 * SkXmAutoNegDoneLone() - Auto-negotiation handling
2918 *
2919 * Description:
2920 * This function handles the auto-negotiation if the Done bit is set.
2921 *
2922 * Returns:
2923 * SK_AND_OK o.k.
2924 * SK_AND_DUP_CAP Duplex capability error happened
2925 * SK_AND_OTHER Other error happened
2926 */
2927static int SkXmAutoNegDoneLone(
2928SK_AC *pAC, /* adapter context */
2929SK_IOC IoC, /* IO context */
2930int Port) /* Port Index (MAC_1 + n) */
2931{
2932 SK_GEPORT *pPrt;
2933 SK_U16 ResAb; /* Resolved Ability */
2934 SK_U16 LPAb; /* Link Partner Ability */
2935 SK_U16 QuickStat; /* Auxiliary Status */
2936
2937 SK_DBG_MSG(pAC, SK_DBGMOD_HWM, SK_DBGCAT_CTRL,
2938 ("AutoNegDoneLone, Port %d\n", Port));
2939 pPrt = &pAC->GIni.GP[Port];
2940
2941 /* Get PHY parameters */
2942 SkXmPhyRead(pAC, IoC, Port, PHY_LONE_AUNE_LP, &LPAb);
2943 SkXmPhyRead(pAC, IoC, Port, PHY_LONE_1000T_STAT, &ResAb);
2944 SkXmPhyRead(pAC, IoC, Port, PHY_LONE_Q_STAT, &QuickStat);
2945
2946 if ((LPAb & PHY_L_AN_RF) != 0) {
2947 /* Remote fault bit is set */
2948 /* Error */
2949 SK_DBG_MSG(pAC, SK_DBGMOD_HWM, SK_DBGCAT_CTRL,
2950 ("AutoNegFail: Remote fault bit set Port %d\n", Port));
2951 pPrt->PAutoNegFail = SK_TRUE;
2952 return(SK_AND_OTHER);
2953 }
2954
2955 /* Check Duplex mismatch */
2956 if ((QuickStat & PHY_L_QS_DUP_MOD) != 0) {
2957 pPrt->PLinkModeStatus = (SK_U8)SK_LMODE_STAT_AUTOFULL;
2958 }
2959 else {
2960 pPrt->PLinkModeStatus = (SK_U8)SK_LMODE_STAT_AUTOHALF;
2961 }
2962
2963 /* Check Master/Slave resolution */
2964 if ((ResAb & PHY_L_1000S_MSF) != 0) {
2965 /* Error */
2966 SK_DBG_MSG(pAC, SK_DBGMOD_HWM, SK_DBGCAT_CTRL,
2967 ("Master/Slave Fault Port %d\n", Port));
2968 pPrt->PAutoNegFail = SK_TRUE;
2969 pPrt->PMSStatus = SK_MS_STAT_FAULT;
2970 return(SK_AND_OTHER);
2971 }
2972 else if (ResAb & PHY_L_1000S_MSR) {
2973 pPrt->PMSStatus = SK_MS_STAT_MASTER;
2974 }
2975 else {
2976 pPrt->PMSStatus = SK_MS_STAT_SLAVE;
2977 }
2978
2979 /* Check PAUSE mismatch */
2980 /* We are using IEEE 802.3z/D5.0 Table 37-4 */
2981 /* we must manually resolve the abilities here */
2982 pPrt->PFlowCtrlStatus = SK_FLOW_STAT_NONE;
2983
2984 switch (pPrt->PFlowCtrlMode) {
2985 case SK_FLOW_MODE_NONE:
2986 /* default */
2987 break;
2988 case SK_FLOW_MODE_LOC_SEND:
2989 if ((QuickStat & (PHY_L_QS_PAUSE | PHY_L_QS_AS_PAUSE)) ==
2990 (PHY_L_QS_PAUSE | PHY_L_QS_AS_PAUSE)) {
2991 /* Disable PAUSE receive, enable PAUSE transmit */
2992 pPrt->PFlowCtrlStatus = SK_FLOW_STAT_LOC_SEND;
2993 }
2994 break;
2995 case SK_FLOW_MODE_SYMMETRIC:
2996 if ((QuickStat & PHY_L_QS_PAUSE) != 0) {
2997 /* Symmetric PAUSE */
2998 pPrt->PFlowCtrlStatus = SK_FLOW_STAT_SYMMETRIC;
2999 }
3000 break;
3001 case SK_FLOW_MODE_SYM_OR_REM:
3002 if ((QuickStat & (PHY_L_QS_PAUSE | PHY_L_QS_AS_PAUSE)) ==
3003 PHY_L_QS_AS_PAUSE) {
3004 /* Enable PAUSE receive, disable PAUSE transmit */
3005 pPrt->PFlowCtrlStatus = SK_FLOW_STAT_REM_SEND;
3006 }
3007 else if ((QuickStat & PHY_L_QS_PAUSE) != 0) {
3008 /* Symmetric PAUSE */
3009 pPrt->PFlowCtrlStatus = SK_FLOW_STAT_SYMMETRIC;
3010 }
3011 break;
3012 default:
3013 SK_ERR_LOG(pAC, SK_ERRCL_SW | SK_ERRCL_INIT, SKERR_HWI_E016,
3014 SKERR_HWI_E016MSG);
3015 }
3016
3017 return(SK_AND_OK);
3018} /* SkXmAutoNegDoneLone */
3019
3020
3021/******************************************************************************
3022 *
3023 * SkXmAutoNegDoneNat() - Auto-negotiation handling
3024 *
3025 * Description:
3026 * This function handles the auto-negotiation if the Done bit is set.
3027 *
3028 * Returns:
3029 * SK_AND_OK o.k.
3030 * SK_AND_DUP_CAP Duplex capability error happened
3031 * SK_AND_OTHER Other error happened
3032 */
3033static int SkXmAutoNegDoneNat(
3034SK_AC *pAC, /* adapter context */
3035SK_IOC IoC, /* IO context */
3036int Port) /* Port Index (MAC_1 + n) */
3037{
3038/* todo: National */
3039 return(SK_AND_OK);
3040} /* SkXmAutoNegDoneNat */
3041#endif /* OTHER_PHY */
3042
3043
3044/******************************************************************************
3045 *
3046 * SkMacAutoNegDone() - Auto-negotiation handling
3047 *
3048 * Description: calls the auto-negotiation done routines dep. on board type
3049 *
3050 * Returns:
3051 * SK_AND_OK o.k.
3052 * SK_AND_DUP_CAP Duplex capability error happened
3053 * SK_AND_OTHER Other error happened
3054 */
3055int SkMacAutoNegDone(
3056SK_AC *pAC, /* adapter context */
3057SK_IOC IoC, /* IO context */
3058int Port) /* Port Index (MAC_1 + n) */
3059{
3060 SK_GEPORT *pPrt;
3061 int Rtv;
3062
3063 Rtv = SK_AND_OK;
3064
3065 pPrt = &pAC->GIni.GP[Port];
3066
3067#ifdef GENESIS
3068 if (pAC->GIni.GIGenesis) {
3069
3070 switch (pPrt->PhyType) {
3071
3072 case SK_PHY_XMAC:
3073 Rtv = SkXmAutoNegDoneXmac(pAC, IoC, Port);
3074 break;
3075 case SK_PHY_BCOM:
3076 Rtv = SkXmAutoNegDoneBcom(pAC, IoC, Port);
3077 break;
3078#ifdef OTHER_PHY
3079 case SK_PHY_LONE:
3080 Rtv = SkXmAutoNegDoneLone(pAC, IoC, Port);
3081 break;
3082 case SK_PHY_NAT:
3083 Rtv = SkXmAutoNegDoneNat(pAC, IoC, Port);
3084 break;
3085#endif /* OTHER_PHY */
3086 default:
3087 return(SK_AND_OTHER);
3088 }
3089 }
3090#endif /* GENESIS */
3091
3092#ifdef YUKON
3093 if (pAC->GIni.GIYukon) {
3094
3095 Rtv = SkGmAutoNegDoneMarv(pAC, IoC, Port);
3096 }
3097#endif /* YUKON */
3098
3099 if (Rtv != SK_AND_OK) {
3100 return(Rtv);
3101 }
3102
3103 SK_DBG_MSG(pAC, SK_DBGMOD_HWM, SK_DBGCAT_CTRL,
3104 ("AutoNeg done Port %d\n", Port));
3105
3106 /* We checked everything and may now enable the link */
3107 pPrt->PAutoNegFail = SK_FALSE;
3108
3109 SkMacRxTxEnable(pAC, IoC, Port);
3110
3111 return(SK_AND_OK);
3112} /* SkMacAutoNegDone */
3113
3114
3115/******************************************************************************
3116 *
3117 * SkMacRxTxEnable() - Enable Rx/Tx activity if port is up
3118 *
3119 * Description: enables Rx/Tx dep. on board type
3120 *
3121 * Returns:
3122 * 0 o.k.
3123 * != 0 Error happened
3124 */
3125int SkMacRxTxEnable(
3126SK_AC *pAC, /* adapter context */
3127SK_IOC IoC, /* IO context */
3128int Port) /* Port Index (MAC_1 + n) */
3129{
3130 SK_GEPORT *pPrt;
3131 SK_U16 Reg; /* 16-bit register value */
3132 SK_U16 IntMask; /* MAC interrupt mask */
3133#ifdef GENESIS
3134 SK_U16 SWord;
3135#endif
3136
3137 pPrt = &pAC->GIni.GP[Port];
3138
3139 if (!pPrt->PHWLinkUp) {
3140 /* The Hardware link is NOT up */
3141 return(0);
3142 }
3143
3144 if ((pPrt->PLinkMode == SK_LMODE_AUTOHALF ||
3145 pPrt->PLinkMode == SK_LMODE_AUTOFULL ||
3146 pPrt->PLinkMode == SK_LMODE_AUTOBOTH) &&
3147 pPrt->PAutoNegFail) {
3148 /* Auto-negotiation is not done or failed */
3149 return(0);
3150 }
3151
3152#ifdef GENESIS
3153 if (pAC->GIni.GIGenesis) {
3154 /* set Duplex Mode and Pause Mode */
3155 SkXmInitDupMd(pAC, IoC, Port);
3156
3157 SkXmInitPauseMd(pAC, IoC, Port);
3158
3159 /*
3160 * Initialize the Interrupt Mask Register. Default IRQs are...
3161 * - Link Asynchronous Event
3162 * - Link Partner requests config
3163 * - Auto Negotiation Done
3164 * - Rx Counter Event Overflow
3165 * - Tx Counter Event Overflow
3166 * - Transmit FIFO Underrun
3167 */
3168 IntMask = XM_DEF_MSK;
3169
3170#ifdef DEBUG
3171 /* add IRQ for Receive FIFO Overflow */
3172 IntMask &= ~XM_IS_RXF_OV;
3173#endif /* DEBUG */
3174
3175 if (pPrt->PhyType != SK_PHY_XMAC) {
3176 /* disable GP0 interrupt bit */
3177 IntMask |= XM_IS_INP_ASS;
3178 }
3179 XM_OUT16(IoC, Port, XM_IMSK, IntMask);
3180
3181 /* get MMU Command Reg. */
3182 XM_IN16(IoC, Port, XM_MMU_CMD, &Reg);
3183
3184 if (pPrt->PhyType != SK_PHY_XMAC &&
3185 (pPrt->PLinkModeStatus == SK_LMODE_STAT_FULL ||
3186 pPrt->PLinkModeStatus == SK_LMODE_STAT_AUTOFULL)) {
3187 /* set to Full Duplex */
3188 Reg |= XM_MMU_GMII_FD;
3189 }
3190
3191 switch (pPrt->PhyType) {
3192 case SK_PHY_BCOM:
3193 /*
3194 * Workaround BCOM Errata (#10523) for all BCom Phys
3195 * Enable Power Management after link up
3196 */
3197 SkXmPhyRead(pAC, IoC, Port, PHY_BCOM_AUX_CTRL, &SWord);
3198 SkXmPhyWrite(pAC, IoC, Port, PHY_BCOM_AUX_CTRL,
3199 (SK_U16)(SWord & ~PHY_B_AC_DIS_PM));
3200 SkXmPhyWrite(pAC, IoC, Port, PHY_BCOM_INT_MASK,
3201 (SK_U16)PHY_B_DEF_MSK);
3202 break;
3203#ifdef OTHER_PHY
3204 case SK_PHY_LONE:
3205 SkXmPhyWrite(pAC, IoC, Port, PHY_LONE_INT_ENAB, PHY_L_DEF_MSK);
3206 break;
3207 case SK_PHY_NAT:
3208 /* todo National:
3209 SkXmPhyWrite(pAC, IoC, Port, PHY_NAT_INT_MASK, PHY_N_DEF_MSK); */
3210 /* no interrupts possible from National ??? */
3211 break;
3212#endif /* OTHER_PHY */
3213 }
3214
3215 /* enable Rx/Tx */
3216 XM_OUT16(IoC, Port, XM_MMU_CMD, Reg | XM_MMU_ENA_RX | XM_MMU_ENA_TX);
3217 }
3218#endif /* GENESIS */
3219
3220#ifdef YUKON
3221 if (pAC->GIni.GIYukon) {
3222 /*
3223 * Initialize the Interrupt Mask Register. Default IRQs are...
3224 * - Rx Counter Event Overflow
3225 * - Tx Counter Event Overflow
3226 * - Transmit FIFO Underrun
3227 */
3228 IntMask = GMAC_DEF_MSK;
3229
3230#ifdef DEBUG
3231 /* add IRQ for Receive FIFO Overrun */
3232 IntMask |= GM_IS_RX_FF_OR;
3233#endif /* DEBUG */
3234
3235 SK_OUT8(IoC, GMAC_IRQ_MSK, (SK_U8)IntMask);
3236
3237 /* get General Purpose Control */
3238 GM_IN16(IoC, Port, GM_GP_CTRL, &Reg);
3239
3240 if (pPrt->PLinkModeStatus == SK_LMODE_STAT_FULL ||
3241 pPrt->PLinkModeStatus == SK_LMODE_STAT_AUTOFULL) {
3242 /* set to Full Duplex */
3243 Reg |= GM_GPCR_DUP_FULL;
3244 }
3245
3246 /* enable Rx/Tx */
3247 GM_OUT16(IoC, Port, GM_GP_CTRL, (SK_U16)(Reg | GM_GPCR_RX_ENA |
3248 GM_GPCR_TX_ENA));
3249
3250#ifndef VCPU
3251 /* Enable all PHY interrupts */
3252 SkGmPhyWrite(pAC, IoC, Port, PHY_MARV_INT_MASK,
3253 (SK_U16)PHY_M_DEF_MSK);
3254#endif /* VCPU */
3255 }
3256#endif /* YUKON */
3257
3258 return(0);
3259
3260} /* SkMacRxTxEnable */
3261
3262
3263/******************************************************************************
3264 *
3265 * SkMacRxTxDisable() - Disable Receiver and Transmitter
3266 *
3267 * Description: disables Rx/Tx dep. on board type
3268 *
3269 * Returns: N/A
3270 */
3271void SkMacRxTxDisable(
3272SK_AC *pAC, /* Adapter Context */
3273SK_IOC IoC, /* IO context */
3274int Port) /* Port Index (MAC_1 + n) */
3275{
3276 SK_U16 Word;
3277
3278#ifdef GENESIS
3279 if (pAC->GIni.GIGenesis) {
3280
3281 XM_IN16(IoC, Port, XM_MMU_CMD, &Word);
3282
3283 XM_OUT16(IoC, Port, XM_MMU_CMD, Word & ~(XM_MMU_ENA_RX | XM_MMU_ENA_TX));
3284
3285 /* dummy read to ensure writing */
3286 XM_IN16(IoC, Port, XM_MMU_CMD, &Word);
3287 }
3288#endif /* GENESIS */
3289
3290#ifdef YUKON
3291 if (pAC->GIni.GIYukon) {
3292
3293 GM_IN16(IoC, Port, GM_GP_CTRL, &Word);
3294
3295 GM_OUT16(IoC, Port, GM_GP_CTRL, (SK_U16)(Word & ~(GM_GPCR_RX_ENA |
3296 GM_GPCR_TX_ENA)));
3297
3298 /* dummy read to ensure writing */
3299 GM_IN16(IoC, Port, GM_GP_CTRL, &Word);
3300 }
3301#endif /* YUKON */
3302
3303} /* SkMacRxTxDisable */
3304
3305
3306/******************************************************************************
3307 *
3308 * SkMacIrqDisable() - Disable IRQ from MAC
3309 *
3310 * Description: sets the IRQ-mask to disable IRQ dep. on board type
3311 *
3312 * Returns: N/A
3313 */
3314void SkMacIrqDisable(
3315SK_AC *pAC, /* Adapter Context */
3316SK_IOC IoC, /* IO context */
3317int Port) /* Port Index (MAC_1 + n) */
3318{
3319 SK_GEPORT *pPrt;
3320#ifdef GENESIS
3321 SK_U16 Word;
3322#endif
3323
3324 pPrt = &pAC->GIni.GP[Port];
3325
3326#ifdef GENESIS
3327 if (pAC->GIni.GIGenesis) {
3328
3329 /* disable all XMAC IRQs */
3330 XM_OUT16(IoC, Port, XM_IMSK, 0xffff);
3331
3332 /* Disable all PHY interrupts */
3333 switch (pPrt->PhyType) {
3334 case SK_PHY_BCOM:
3335 /* Make sure that PHY is initialized */
3336 if (pPrt->PState != SK_PRT_RESET) {
3337 /* NOT allowed if BCOM is in RESET state */
3338 /* Workaround BCOM Errata (#10523) all BCom */
3339 /* Disable Power Management if link is down */
3340 SkXmPhyRead(pAC, IoC, Port, PHY_BCOM_AUX_CTRL, &Word);
3341 SkXmPhyWrite(pAC, IoC, Port, PHY_BCOM_AUX_CTRL,
3342 (SK_U16)(Word | PHY_B_AC_DIS_PM));
3343 SkXmPhyWrite(pAC, IoC, Port, PHY_BCOM_INT_MASK, 0xffff);
3344 }
3345 break;
3346#ifdef OTHER_PHY
3347 case SK_PHY_LONE:
3348 SkXmPhyWrite(pAC, IoC, Port, PHY_LONE_INT_ENAB, 0);
3349 break;
3350 case SK_PHY_NAT:
3351 /* todo: National
3352 SkXmPhyWrite(pAC, IoC, Port, PHY_NAT_INT_MASK, 0xffff); */
3353 break;
3354#endif /* OTHER_PHY */
3355 }
3356 }
3357#endif /* GENESIS */
3358
3359#ifdef YUKON
3360 if (pAC->GIni.GIYukon) {
3361 /* disable all GMAC IRQs */
3362 SK_OUT8(IoC, GMAC_IRQ_MSK, 0);
3363
3364#ifndef VCPU
3365 /* Disable all PHY interrupts */
3366 SkGmPhyWrite(pAC, IoC, Port, PHY_MARV_INT_MASK, 0);
3367#endif /* VCPU */
3368 }
3369#endif /* YUKON */
3370
3371} /* SkMacIrqDisable */
3372
3373
3374#ifdef SK_DIAG
3375/******************************************************************************
3376 *
3377 * SkXmSendCont() - Enable / Disable Send Continuous Mode
3378 *
3379 * Description: enable / disable Send Continuous Mode on XMAC
3380 *
3381 * Returns:
3382 * nothing
3383 */
3384void SkXmSendCont(
3385SK_AC *pAC, /* adapter context */
3386SK_IOC IoC, /* IO context */
3387int Port, /* Port Index (MAC_1 + n) */
3388SK_BOOL Enable) /* Enable / Disable */
3389{
3390 SK_U32 MdReg;
3391
3392 XM_IN32(IoC, Port, XM_MODE, &MdReg);
3393
3394 if (Enable) {
3395 MdReg |= XM_MD_TX_CONT;
3396 }
3397 else {
3398 MdReg &= ~XM_MD_TX_CONT;
3399 }
3400 /* setup Mode Register */
3401 XM_OUT32(IoC, Port, XM_MODE, MdReg);
3402
3403} /* SkXmSendCont */
3404
3405
3406/******************************************************************************
3407 *
3408 * SkMacTimeStamp() - Enable / Disable Time Stamp
3409 *
3410 * Description: enable / disable Time Stamp generation for Rx packets
3411 *
3412 * Returns:
3413 * nothing
3414 */
3415void SkMacTimeStamp(
3416SK_AC *pAC, /* adapter context */
3417SK_IOC IoC, /* IO context */
3418int Port, /* Port Index (MAC_1 + n) */
3419SK_BOOL Enable) /* Enable / Disable */
3420{
3421 SK_U32 MdReg;
3422 SK_U8 TimeCtrl;
3423
3424 if (pAC->GIni.GIGenesis) {
3425
3426 XM_IN32(IoC, Port, XM_MODE, &MdReg);
3427
3428 if (Enable) {
3429 MdReg |= XM_MD_ATS;
3430 }
3431 else {
3432 MdReg &= ~XM_MD_ATS;
3433 }
3434 /* setup Mode Register */
3435 XM_OUT32(IoC, Port, XM_MODE, MdReg);
3436 }
3437 else {
3438 if (Enable) {
3439 TimeCtrl = GMT_ST_START | GMT_ST_CLR_IRQ;
3440 }
3441 else {
3442 TimeCtrl = GMT_ST_STOP | GMT_ST_CLR_IRQ;
3443 }
3444 /* Start/Stop Time Stamp Timer */
3445 SK_OUT8(IoC, GMAC_TI_ST_CTRL, TimeCtrl);
3446 }
3447
3448} /* SkMacTimeStamp*/
3449
3450#else /* !SK_DIAG */
3451
3452#ifdef GENESIS
3453/******************************************************************************
3454 *
3455 * SkXmAutoNegLipaXmac() - Decides whether Link Partner could do auto-neg
3456 *
3457 * This function analyses the Interrupt status word. If any of the
3458 * Auto-negotiating interrupt bits are set, the PLipaAutoNeg variable
3459 * is set true.
3460 */
3461void SkXmAutoNegLipaXmac(
3462SK_AC *pAC, /* adapter context */
3463SK_IOC IoC, /* IO context */
3464int Port, /* Port Index (MAC_1 + n) */
3465SK_U16 IStatus) /* Interrupt Status word to analyse */
3466{
3467 SK_GEPORT *pPrt;
3468
3469 pPrt = &pAC->GIni.GP[Port];
3470
3471 if (pPrt->PLipaAutoNeg != SK_LIPA_AUTO &&
3472 (IStatus & (XM_IS_LIPA_RC | XM_IS_RX_PAGE | XM_IS_AND)) != 0) {
3473
3474 SK_DBG_MSG(pAC, SK_DBGMOD_HWM, SK_DBGCAT_CTRL,
3475 ("AutoNegLipa: AutoNeg detected on Port %d, IStatus=0x%04X\n",
3476 Port, IStatus));
3477 pPrt->PLipaAutoNeg = SK_LIPA_AUTO;
3478 }
3479} /* SkXmAutoNegLipaXmac */
3480#endif /* GENESIS */
3481
3482
3483/******************************************************************************
3484 *
3485 * SkMacAutoNegLipaPhy() - Decides whether Link Partner could do auto-neg
3486 *
3487 * This function analyses the PHY status word.
3488 * If any of the Auto-negotiating bits are set, the PLipaAutoNeg variable
3489 * is set true.
3490 */
3491void SkMacAutoNegLipaPhy(
3492SK_AC *pAC, /* adapter context */
3493SK_IOC IoC, /* IO context */
3494int Port, /* Port Index (MAC_1 + n) */
3495SK_U16 PhyStat) /* PHY Status word to analyse */
3496{
3497 SK_GEPORT *pPrt;
3498
3499 pPrt = &pAC->GIni.GP[Port];
3500
3501 if (pPrt->PLipaAutoNeg != SK_LIPA_AUTO &&
3502 (PhyStat & PHY_ST_AN_OVER) != 0) {
3503
3504 SK_DBG_MSG(pAC, SK_DBGMOD_HWM, SK_DBGCAT_CTRL,
3505 ("AutoNegLipa: AutoNeg detected on Port %d, PhyStat=0x%04X\n",
3506 Port, PhyStat));
3507 pPrt->PLipaAutoNeg = SK_LIPA_AUTO;
3508 }
3509} /* SkMacAutoNegLipaPhy */
3510
3511
3512#ifdef GENESIS
3513/******************************************************************************
3514 *
3515 * SkXmIrq() - Interrupt Service Routine
3516 *
3517 * Description: services an Interrupt Request of the XMAC
3518 *
3519 * Note:
3520 * With an external PHY, some interrupt bits are not meaningfull any more:
3521 * - LinkAsyncEvent (bit #14) XM_IS_LNK_AE
3522 * - LinkPartnerReqConfig (bit #10) XM_IS_LIPA_RC
3523 * - Page Received (bit #9) XM_IS_RX_PAGE
3524 * - NextPageLoadedForXmt (bit #8) XM_IS_TX_PAGE
3525 * - AutoNegDone (bit #7) XM_IS_AND
3526 * Also probably not valid any more is the GP0 input bit:
3527 * - GPRegisterBit0set XM_IS_INP_ASS
3528 *
3529 * Returns:
3530 * nothing
3531 */
3532static void SkXmIrq(
3533SK_AC *pAC, /* adapter context */
3534SK_IOC IoC, /* IO context */
3535int Port) /* Port Index (MAC_1 + n) */
3536{
3537 SK_GEPORT *pPrt;
3538 SK_EVPARA Para;
3539 SK_U16 IStatus; /* Interrupt status read from the XMAC */
3540 SK_U16 IStatus2;
3541#ifdef SK_SLIM
3542 SK_U64 OverflowStatus;
3543#endif
3544
3545 pPrt = &pAC->GIni.GP[Port];
3546
3547 XM_IN16(IoC, Port, XM_ISRC, &IStatus);
3548
3549 /* LinkPartner Auto-negable? */
3550 if (pPrt->PhyType == SK_PHY_XMAC) {
3551 SkXmAutoNegLipaXmac(pAC, IoC, Port, IStatus);
3552 }
3553 else {
3554 /* mask bits that are not used with ext. PHY */
3555 IStatus &= ~(XM_IS_LNK_AE | XM_IS_LIPA_RC |
3556 XM_IS_RX_PAGE | XM_IS_TX_PAGE |
3557 XM_IS_AND | XM_IS_INP_ASS);
3558 }
3559
3560 SK_DBG_MSG(pAC, SK_DBGMOD_HWM, SK_DBGCAT_IRQ,
3561 ("XmacIrq Port %d Isr 0x%04X\n", Port, IStatus));
3562
3563 if (!pPrt->PHWLinkUp) {
3564 /* Spurious XMAC interrupt */
3565 SK_DBG_MSG(pAC, SK_DBGMOD_HWM, SK_DBGCAT_IRQ,
3566 ("SkXmIrq: spurious interrupt on Port %d\n", Port));
3567 return;
3568 }
3569
3570 if ((IStatus & XM_IS_INP_ASS) != 0) {
3571 /* Reread ISR Register if link is not in sync */
3572 XM_IN16(IoC, Port, XM_ISRC, &IStatus2);
3573
3574 SK_DBG_MSG(pAC, SK_DBGMOD_HWM, SK_DBGCAT_IRQ,
3575 ("SkXmIrq: Link async. Double check Port %d 0x%04X 0x%04X\n",
3576 Port, IStatus, IStatus2));
3577 IStatus &= ~XM_IS_INP_ASS;
3578 IStatus |= IStatus2;
3579 }
3580
3581 if ((IStatus & XM_IS_LNK_AE) != 0) {
3582 /* not used, GP0 is used instead */
3583 }
3584
3585 if ((IStatus & XM_IS_TX_ABORT) != 0) {
3586 /* not used */
3587 }
3588
3589 if ((IStatus & XM_IS_FRC_INT) != 0) {
3590 /* not used, use ASIC IRQ instead if needed */
3591 }
3592
3593 if ((IStatus & (XM_IS_INP_ASS | XM_IS_LIPA_RC | XM_IS_RX_PAGE)) != 0) {
3594 SkHWLinkDown(pAC, IoC, Port);
3595
3596 /* Signal to RLMT */
3597 Para.Para32[0] = (SK_U32)Port;
3598 SkEventQueue(pAC, SKGE_RLMT, SK_RLMT_LINK_DOWN, Para);
3599
3600 /* Start workaround Errata #2 timer */
3601 SkTimerStart(pAC, IoC, &pPrt->PWaTimer, SK_WA_INA_TIME,
3602 SKGE_HWAC, SK_HWEV_WATIM, Para);
3603 }
3604
3605 if ((IStatus & XM_IS_RX_PAGE) != 0) {
3606 /* not used */
3607 }
3608
3609 if ((IStatus & XM_IS_TX_PAGE) != 0) {
3610 /* not used */
3611 }
3612
3613 if ((IStatus & XM_IS_AND) != 0) {
3614 SK_DBG_MSG(pAC, SK_DBGMOD_HWM, SK_DBGCAT_IRQ,
3615 ("SkXmIrq: AND on link that is up Port %d\n", Port));
3616 }
3617
3618 if ((IStatus & XM_IS_TSC_OV) != 0) {
3619 /* not used */
3620 }
3621
3622 /* Combined Tx & Rx Counter Overflow SIRQ Event */
3623 if ((IStatus & (XM_IS_RXC_OV | XM_IS_TXC_OV)) != 0) {
3624#ifdef SK_SLIM
3625 SkXmOverflowStatus(pAC, IoC, Port, IStatus, &OverflowStatus);
3626#else
3627 Para.Para32[0] = (SK_U32)Port;
3628 Para.Para32[1] = (SK_U32)IStatus;
3629 SkPnmiEvent(pAC, IoC, SK_PNMI_EVT_SIRQ_OVERFLOW, Para);
3630#endif /* SK_SLIM */
3631 }
3632
3633 if ((IStatus & XM_IS_RXF_OV) != 0) {
3634 /* normal situation -> no effect */
3635#ifdef DEBUG
3636 pPrt->PRxOverCnt++;
3637#endif /* DEBUG */
3638 }
3639
3640 if ((IStatus & XM_IS_TXF_UR) != 0) {
3641 /* may NOT happen -> error log */
3642 SK_ERR_LOG(pAC, SK_ERRCL_HW, SKERR_SIRQ_E020, SKERR_SIRQ_E020MSG);
3643 }
3644
3645 if ((IStatus & XM_IS_TX_COMP) != 0) {
3646 /* not served here */
3647 }
3648
3649 if ((IStatus & XM_IS_RX_COMP) != 0) {
3650 /* not served here */
3651 }
3652} /* SkXmIrq */
3653#endif /* GENESIS */
3654
3655
3656#ifdef YUKON
3657/******************************************************************************
3658 *
3659 * SkGmIrq() - Interrupt Service Routine
3660 *
3661 * Description: services an Interrupt Request of the GMAC
3662 *
3663 * Note:
3664 *
3665 * Returns:
3666 * nothing
3667 */
3668static void SkGmIrq(
3669SK_AC *pAC, /* adapter context */
3670SK_IOC IoC, /* IO context */
3671int Port) /* Port Index (MAC_1 + n) */
3672{
3673 SK_GEPORT *pPrt;
3674 SK_U8 IStatus; /* Interrupt status */
3675#ifdef SK_SLIM
3676 SK_U64 OverflowStatus;
3677#else
3678 SK_EVPARA Para;
3679#endif
3680
3681 pPrt = &pAC->GIni.GP[Port];
3682
3683 SK_IN8(IoC, GMAC_IRQ_SRC, &IStatus);
3684
3685#ifdef XXX
3686 /* LinkPartner Auto-negable? */
3687 SkMacAutoNegLipaPhy(pAC, IoC, Port, IStatus);
3688#endif /* XXX */
3689
3690 SK_DBG_MSG(pAC, SK_DBGMOD_HWM, SK_DBGCAT_IRQ,
3691 ("GmacIrq Port %d Isr 0x%04X\n", Port, IStatus));
3692
3693 /* Combined Tx & Rx Counter Overflow SIRQ Event */
3694 if (IStatus & (GM_IS_RX_CO_OV | GM_IS_TX_CO_OV)) {
3695 /* these IRQs will be cleared by reading GMACs register */
3696#ifdef SK_SLIM
3697 SkGmOverflowStatus(pAC, IoC, Port, IStatus, &OverflowStatus);
3698#else
3699 Para.Para32[0] = (SK_U32)Port;
3700 Para.Para32[1] = (SK_U32)IStatus;
3701 SkPnmiEvent(pAC, IoC, SK_PNMI_EVT_SIRQ_OVERFLOW, Para);
3702#endif
3703 }
3704
3705 if (IStatus & GM_IS_RX_FF_OR) {
3706 /* clear GMAC Rx FIFO Overrun IRQ */
3707 SK_OUT8(IoC, MR_ADDR(Port, RX_GMF_CTRL_T), (SK_U8)GMF_CLI_RX_FO);
3708#ifdef DEBUG
3709 pPrt->PRxOverCnt++;
3710#endif /* DEBUG */
3711 }
3712
3713 if (IStatus & GM_IS_TX_FF_UR) {
3714 /* clear GMAC Tx FIFO Underrun IRQ */
3715 SK_OUT8(IoC, MR_ADDR(Port, TX_GMF_CTRL_T), (SK_U8)GMF_CLI_TX_FU);
3716 /* may NOT happen -> error log */
3717 SK_ERR_LOG(pAC, SK_ERRCL_HW, SKERR_SIRQ_E020, SKERR_SIRQ_E020MSG);
3718 }
3719
3720 if (IStatus & GM_IS_TX_COMPL) {
3721 /* not served here */
3722 }
3723
3724 if (IStatus & GM_IS_RX_COMPL) {
3725 /* not served here */
3726 }
3727} /* SkGmIrq */
3728#endif /* YUKON */
3729
3730
3731/******************************************************************************
3732 *
3733 * SkMacIrq() - Interrupt Service Routine for MAC
3734 *
3735 * Description: calls the Interrupt Service Routine dep. on board type
3736 *
3737 * Returns:
3738 * nothing
3739 */
3740void SkMacIrq(
3741SK_AC *pAC, /* adapter context */
3742SK_IOC IoC, /* IO context */
3743int Port) /* Port Index (MAC_1 + n) */
3744{
3745#ifdef GENESIS
3746 if (pAC->GIni.GIGenesis) {
3747 /* IRQ from XMAC */
3748 SkXmIrq(pAC, IoC, Port);
3749 }
3750#endif /* GENESIS */
3751
3752#ifdef YUKON
3753 if (pAC->GIni.GIYukon) {
3754 /* IRQ from GMAC */
3755 SkGmIrq(pAC, IoC, Port);
3756 }
3757#endif /* YUKON */
3758
3759} /* SkMacIrq */
3760
3761#endif /* !SK_DIAG */
3762
3763#ifdef GENESIS
3764/******************************************************************************
3765 *
3766 * SkXmUpdateStats() - Force the XMAC to output the current statistic
3767 *
3768 * Description:
3769 * The XMAC holds its statistic internally. To obtain the current
3770 * values a command must be sent so that the statistic data will
3771 * be written to a predefined memory area on the adapter.
3772 *
3773 * Returns:
3774 * 0: success
3775 * 1: something went wrong
3776 */
3777int SkXmUpdateStats(
3778SK_AC *pAC, /* adapter context */
3779SK_IOC IoC, /* IO context */
3780unsigned int Port) /* Port Index (MAC_1 + n) */
3781{
3782 SK_GEPORT *pPrt;
3783 SK_U16 StatReg;
3784 int WaitIndex;
3785
3786 pPrt = &pAC->GIni.GP[Port];
3787 WaitIndex = 0;
3788
3789 /* Send an update command to XMAC specified */
3790 XM_OUT16(IoC, Port, XM_STAT_CMD, XM_SC_SNP_TXC | XM_SC_SNP_RXC);
3791
3792 /*
3793 * It is an auto-clearing register. If the command bits
3794 * went to zero again, the statistics are transferred.
3795 * Normally the command should be executed immediately.
3796 * But just to be sure we execute a loop.
3797 */
3798 do {
3799
3800 XM_IN16(IoC, Port, XM_STAT_CMD, &StatReg);
3801
3802 if (++WaitIndex > 10) {
3803
3804 SK_ERR_LOG(pAC, SK_ERRCL_HW, SKERR_HWI_E021, SKERR_HWI_E021MSG);
3805
3806 return(1);
3807 }
3808 } while ((StatReg & (XM_SC_SNP_TXC | XM_SC_SNP_RXC)) != 0);
3809
3810 return(0);
3811} /* SkXmUpdateStats */
3812
3813
3814/******************************************************************************
3815 *
3816 * SkXmMacStatistic() - Get XMAC counter value
3817 *
3818 * Description:
3819 * Gets the 32bit counter value. Except for the octet counters
3820 * the lower 32bit are counted in hardware and the upper 32bit
3821 * must be counted in software by monitoring counter overflow interrupts.
3822 *
3823 * Returns:
3824 * 0: success
3825 * 1: something went wrong
3826 */
3827int SkXmMacStatistic(
3828SK_AC *pAC, /* adapter context */
3829SK_IOC IoC, /* IO context */
3830unsigned int Port, /* Port Index (MAC_1 + n) */
3831SK_U16 StatAddr, /* MIB counter base address */
3832SK_U32 SK_FAR *pVal) /* ptr to return statistic value */
3833{
3834 if ((StatAddr < XM_TXF_OK) || (StatAddr > XM_RXF_MAX_SZ)) {
3835
3836 SK_ERR_LOG(pAC, SK_ERRCL_SW, SKERR_HWI_E022, SKERR_HWI_E022MSG);
3837
3838 return(1);
3839 }
3840
3841 XM_IN32(IoC, Port, StatAddr, pVal);
3842
3843 return(0);
3844} /* SkXmMacStatistic */
3845
3846
3847/******************************************************************************
3848 *
3849 * SkXmResetCounter() - Clear MAC statistic counter
3850 *
3851 * Description:
3852 * Force the XMAC to clear its statistic counter.
3853 *
3854 * Returns:
3855 * 0: success
3856 * 1: something went wrong
3857 */
3858int SkXmResetCounter(
3859SK_AC *pAC, /* adapter context */
3860SK_IOC IoC, /* IO context */
3861unsigned int Port) /* Port Index (MAC_1 + n) */
3862{
3863 XM_OUT16(IoC, Port, XM_STAT_CMD, XM_SC_CLR_RXC | XM_SC_CLR_TXC);
3864 /* Clear two times according to Errata #3 */
3865 XM_OUT16(IoC, Port, XM_STAT_CMD, XM_SC_CLR_RXC | XM_SC_CLR_TXC);
3866
3867 return(0);
3868} /* SkXmResetCounter */
3869
3870
3871/******************************************************************************
3872 *
3873 * SkXmOverflowStatus() - Gets the status of counter overflow interrupt
3874 *
3875 * Description:
3876 * Checks the source causing an counter overflow interrupt. On success the
3877 * resulting counter overflow status is written to <pStatus>, whereas the
3878 * upper dword stores the XMAC ReceiveCounterEvent register and the lower
3879 * dword the XMAC TransmitCounterEvent register.
3880 *
3881 * Note:
3882 * For XMAC the interrupt source is a self-clearing register, so the source
3883 * must be checked only once. SIRQ module does another check to be sure
3884 * that no interrupt get lost during process time.
3885 *
3886 * Returns:
3887 * 0: success
3888 * 1: something went wrong
3889 */
3890int SkXmOverflowStatus(
3891SK_AC *pAC, /* adapter context */
3892SK_IOC IoC, /* IO context */
3893unsigned int Port, /* Port Index (MAC_1 + n) */
3894SK_U16 IStatus, /* Interupt Status from MAC */
3895SK_U64 SK_FAR *pStatus) /* ptr for return overflow status value */
3896{
3897 SK_U64 Status; /* Overflow status */
3898 SK_U32 RegVal;
3899
3900 Status = 0;
3901
3902 if ((IStatus & XM_IS_RXC_OV) != 0) {
3903
3904 XM_IN32(IoC, Port, XM_RX_CNT_EV, &RegVal);
3905 Status |= (SK_U64)RegVal << 32;
3906 }
3907
3908 if ((IStatus & XM_IS_TXC_OV) != 0) {
3909
3910 XM_IN32(IoC, Port, XM_TX_CNT_EV, &RegVal);
3911 Status |= (SK_U64)RegVal;
3912 }
3913
3914 *pStatus = Status;
3915
3916 return(0);
3917} /* SkXmOverflowStatus */
3918#endif /* GENESIS */
3919
3920
3921#ifdef YUKON
3922/******************************************************************************
3923 *
3924 * SkGmUpdateStats() - Force the GMAC to output the current statistic
3925 *
3926 * Description:
3927 * Empty function for GMAC. Statistic data is accessible in direct way.
3928 *
3929 * Returns:
3930 * 0: success
3931 * 1: something went wrong
3932 */
3933int SkGmUpdateStats(
3934SK_AC *pAC, /* adapter context */
3935SK_IOC IoC, /* IO context */
3936unsigned int Port) /* Port Index (MAC_1 + n) */
3937{
3938 return(0);
3939}
3940
3941
3942/******************************************************************************
3943 *
3944 * SkGmMacStatistic() - Get GMAC counter value
3945 *
3946 * Description:
3947 * Gets the 32bit counter value. Except for the octet counters
3948 * the lower 32bit are counted in hardware and the upper 32bit
3949 * must be counted in software by monitoring counter overflow interrupts.
3950 *
3951 * Returns:
3952 * 0: success
3953 * 1: something went wrong
3954 */
3955int SkGmMacStatistic(
3956SK_AC *pAC, /* adapter context */
3957SK_IOC IoC, /* IO context */
3958unsigned int Port, /* Port Index (MAC_1 + n) */
3959SK_U16 StatAddr, /* MIB counter base address */
3960SK_U32 SK_FAR *pVal) /* ptr to return statistic value */
3961{
3962
3963 if ((StatAddr < GM_RXF_UC_OK) || (StatAddr > GM_TXE_FIFO_UR)) {
3964
3965 SK_ERR_LOG(pAC, SK_ERRCL_SW, SKERR_HWI_E022, SKERR_HWI_E022MSG);
3966
3967 SK_DBG_MSG(pAC, SK_DBGMOD_HWM, SK_DBGCAT_CTRL,
3968 ("SkGmMacStat: wrong MIB counter 0x%04X\n", StatAddr));
3969 return(1);
3970 }
3971
3972 GM_IN32(IoC, Port, StatAddr, pVal);
3973
3974 return(0);
3975} /* SkGmMacStatistic */
3976
3977
3978/******************************************************************************
3979 *
3980 * SkGmResetCounter() - Clear MAC statistic counter
3981 *
3982 * Description:
3983 * Force GMAC to clear its statistic counter.
3984 *
3985 * Returns:
3986 * 0: success
3987 * 1: something went wrong
3988 */
3989int SkGmResetCounter(
3990SK_AC *pAC, /* adapter context */
3991SK_IOC IoC, /* IO context */
3992unsigned int Port) /* Port Index (MAC_1 + n) */
3993{
3994 SK_U16 Reg; /* Phy Address Register */
3995 SK_U16 Word;
3996 int i;
3997
3998 GM_IN16(IoC, Port, GM_PHY_ADDR, &Reg);
3999
4000 /* set MIB Clear Counter Mode */
4001 GM_OUT16(IoC, Port, GM_PHY_ADDR, Reg | GM_PAR_MIB_CLR);
4002
4003 /* read all MIB Counters with Clear Mode set */
4004 for (i = 0; i < GM_MIB_CNT_SIZE; i++) {
4005 /* the reset is performed only when the lower 16 bits are read */
4006 GM_IN16(IoC, Port, GM_MIB_CNT_BASE + 8*i, &Word);
4007 }
4008
4009 /* clear MIB Clear Counter Mode */
4010 GM_OUT16(IoC, Port, GM_PHY_ADDR, Reg);
4011
4012 return(0);
4013} /* SkGmResetCounter */
4014
4015
4016/******************************************************************************
4017 *
4018 * SkGmOverflowStatus() - Gets the status of counter overflow interrupt
4019 *
4020 * Description:
4021 * Checks the source causing an counter overflow interrupt. On success the
4022 * resulting counter overflow status is written to <pStatus>, whereas the
4023 * the following bit coding is used:
4024 * 63:56 - unused
4025 * 55:48 - TxRx interrupt register bit7:0
4026 * 32:47 - Rx interrupt register
4027 * 31:24 - unused
4028 * 23:16 - TxRx interrupt register bit15:8
4029 * 15:0 - Tx interrupt register
4030 *
4031 * Returns:
4032 * 0: success
4033 * 1: something went wrong
4034 */
4035int SkGmOverflowStatus(
4036SK_AC *pAC, /* adapter context */
4037SK_IOC IoC, /* IO context */
4038unsigned int Port, /* Port Index (MAC_1 + n) */
4039SK_U16 IStatus, /* Interupt Status from MAC */
4040SK_U64 SK_FAR *pStatus) /* ptr for return overflow status value */
4041{
4042 SK_U64 Status; /* Overflow status */
4043 SK_U16 RegVal;
4044
4045 Status = 0;
4046
4047 if ((IStatus & GM_IS_RX_CO_OV) != 0) {
4048 /* this register is self-clearing after read */
4049 GM_IN16(IoC, Port, GM_RX_IRQ_SRC, &RegVal);
4050 Status |= (SK_U64)RegVal << 32;
4051 }
4052
4053 if ((IStatus & GM_IS_TX_CO_OV) != 0) {
4054 /* this register is self-clearing after read */
4055 GM_IN16(IoC, Port, GM_TX_IRQ_SRC, &RegVal);
4056 Status |= (SK_U64)RegVal;
4057 }
4058
4059 /* this register is self-clearing after read */
4060 GM_IN16(IoC, Port, GM_TR_IRQ_SRC, &RegVal);
4061 /* Rx overflow interrupt register bits (LoByte)*/
4062 Status |= (SK_U64)((SK_U8)RegVal) << 48;
4063 /* Tx overflow interrupt register bits (HiByte)*/
4064 Status |= (SK_U64)(RegVal >> 8) << 16;
4065
4066 *pStatus = Status;
4067
4068 return(0);
4069} /* SkGmOverflowStatus */
4070
4071
4072#ifndef SK_SLIM
4073/******************************************************************************
4074 *
4075 * SkGmCableDiagStatus() - Starts / Gets status of cable diagnostic test
4076 *
4077 * Description:
4078 * starts the cable diagnostic test if 'StartTest' is true
4079 * gets the results if 'StartTest' is true
4080 *
4081 * NOTE: this test is meaningful only when link is down
4082 *
4083 * Returns:
4084 * 0: success
4085 * 1: no YUKON copper
4086 * 2: test in progress
4087 */
4088int SkGmCableDiagStatus(
4089SK_AC *pAC, /* adapter context */
4090SK_IOC IoC, /* IO context */
4091int Port, /* Port Index (MAC_1 + n) */
4092SK_BOOL StartTest) /* flag for start / get result */
4093{
4094 int i;
4095 SK_U16 RegVal;
4096 SK_GEPORT *pPrt;
4097
4098 pPrt = &pAC->GIni.GP[Port];
4099
4100 if (pPrt->PhyType != SK_PHY_MARV_COPPER) {
4101
4102 return(1);
4103 }
4104
4105 if (StartTest) {
4106 /* only start the cable test */
4107 if ((pPrt->PhyId1 & PHY_I1_REV_MSK) < 4) {
4108 /* apply TDR workaround from Marvell */
4109 SkGmPhyWrite(pAC, IoC, Port, 29, 0x001e);
4110
4111 SkGmPhyWrite(pAC, IoC, Port, 30, 0xcc00);
4112 SkGmPhyWrite(pAC, IoC, Port, 30, 0xc800);
4113 SkGmPhyWrite(pAC, IoC, Port, 30, 0xc400);
4114 SkGmPhyWrite(pAC, IoC, Port, 30, 0xc000);
4115 SkGmPhyWrite(pAC, IoC, Port, 30, 0xc100);
4116 }
4117
4118 /* set address to 0 for MDI[0] */
4119 SkGmPhyWrite(pAC, IoC, Port, PHY_MARV_EXT_ADR, 0);
4120
4121 /* Read Cable Diagnostic Reg */
4122 SkGmPhyRead(pAC, IoC, Port, PHY_MARV_CABLE_DIAG, &RegVal);
4123
4124 /* start Cable Diagnostic Test */
4125 SkGmPhyWrite(pAC, IoC, Port, PHY_MARV_CABLE_DIAG,
4126 (SK_U16)(RegVal | PHY_M_CABD_ENA_TEST));
4127
4128 return(0);
4129 }
4130
4131 /* Read Cable Diagnostic Reg */
4132 SkGmPhyRead(pAC, IoC, Port, PHY_MARV_CABLE_DIAG, &RegVal);
4133
4134 SK_DBG_MSG(pAC, SK_DBGMOD_HWM, SK_DBGCAT_CTRL,
4135 ("PHY Cable Diag.=0x%04X\n", RegVal));
4136
4137 if ((RegVal & PHY_M_CABD_ENA_TEST) != 0) {
4138 /* test is running */
4139 return(2);
4140 }
4141
4142 /* get the test results */
4143 for (i = 0; i < 4; i++) {
4144 /* set address to i for MDI[i] */
4145 SkGmPhyWrite(pAC, IoC, Port, PHY_MARV_EXT_ADR, (SK_U16)i);
4146
4147 /* get Cable Diagnostic values */
4148 SkGmPhyRead(pAC, IoC, Port, PHY_MARV_CABLE_DIAG, &RegVal);
4149
4150 pPrt->PMdiPairLen[i] = (SK_U8)(RegVal & PHY_M_CABD_DIST_MSK);
4151
4152 pPrt->PMdiPairSts[i] = (SK_U8)((RegVal & PHY_M_CABD_STAT_MSK) >> 13);
4153 }
4154
4155 return(0);
4156} /* SkGmCableDiagStatus */
4157#endif /* !SK_SLIM */
4158#endif /* YUKON */
4159
4160/* End of file */