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-rw-r--r--drivers/cdrom/Kconfig213
-rw-r--r--drivers/cdrom/Makefile10
-rw-r--r--drivers/cdrom/aztcd.c2492
-rw-r--r--drivers/cdrom/aztcd.h162
-rw-r--r--drivers/cdrom/cdu31a.c3251
-rw-r--r--drivers/cdrom/cdu31a.h411
-rw-r--r--drivers/cdrom/cm206.c1594
-rw-r--r--drivers/cdrom/cm206.h171
-rw-r--r--drivers/cdrom/gscd.c1029
-rw-r--r--drivers/cdrom/gscd.h108
-rw-r--r--drivers/cdrom/isp16.c374
-rw-r--r--drivers/cdrom/isp16.h72
-rw-r--r--drivers/cdrom/mcdx.c1943
-rw-r--r--drivers/cdrom/mcdx.h185
-rw-r--r--drivers/cdrom/optcd.c2105
-rw-r--r--drivers/cdrom/optcd.h52
-rw-r--r--drivers/cdrom/sbpcd.c5966
-rw-r--r--drivers/cdrom/sbpcd.h839
-rw-r--r--drivers/cdrom/sjcd.c1815
-rw-r--r--drivers/cdrom/sjcd.h181
-rw-r--r--drivers/cdrom/sonycd535.c1689
-rw-r--r--drivers/cdrom/sonycd535.h183
22 files changed, 0 insertions, 24845 deletions
diff --git a/drivers/cdrom/Kconfig b/drivers/cdrom/Kconfig
deleted file mode 100644
index 4b12e9031fb3..000000000000
--- a/drivers/cdrom/Kconfig
+++ /dev/null
@@ -1,213 +0,0 @@
1#
2# CDROM driver configuration
3#
4
5menu "Old CD-ROM drivers (not SCSI, not IDE)"
6 depends on ISA && BLOCK
7
8config CD_NO_IDESCSI
9 bool "Support non-SCSI/IDE/ATAPI CDROM drives"
10 ---help---
11 If you have a CD-ROM drive that is neither SCSI nor IDE/ATAPI, say Y
12 here, otherwise N. Read the CD-ROM-HOWTO, available from
13 <http://www.tldp.org/docs.html#howto>.
14
15 Note that the answer to this question doesn't directly affect the
16 kernel: saying N will just cause the configurator to skip all
17 the questions about these CD-ROM drives. If you are unsure what you
18 have, say Y and find out whether you have one of the following
19 drives.
20
21 For each of these drivers, a <file:Documentation/cdrom/{driver_name}>
22 exists. Especially in cases where you do not know exactly which kind
23 of drive you have you should read there. Most of these drivers use a
24 file drivers/cdrom/{driver_name}.h where you can define your
25 interface parameters and switch some internal goodies.
26
27 To compile these CD-ROM drivers as a module, choose M instead of Y.
28
29 If you want to use any of these CD-ROM drivers, you also have to
30 answer Y or M to "ISO 9660 CD-ROM file system support" below (this
31 answer will get "defaulted" for you if you enable any of the Linux
32 CD-ROM drivers).
33
34config AZTCD
35 tristate "Aztech/Orchid/Okano/Wearnes/TXC/CyDROM CDROM support"
36 depends on CD_NO_IDESCSI
37 ---help---
38 This is your driver if you have an Aztech CDA268-01A, Orchid
39 CD-3110, Okano or Wearnes CDD110, Conrad TXC, or CyCD-ROM CR520 or
40 CR540 CD-ROM drive. This driver -- just like all these CD-ROM
41 drivers -- is NOT for CD-ROM drives with IDE/ATAPI interfaces, such
42 as Aztech CDA269-031SE. Please read the file
43 <file:Documentation/cdrom/aztcd>.
44
45 If you say Y here, you should also say Y or M to "ISO 9660 CD-ROM
46 file system support" below, because that's the file system used on
47 CD-ROMs.
48
49 To compile this driver as a module, choose M here: the
50 module will be called aztcd.
51
52config GSCD
53 tristate "Goldstar R420 CDROM support"
54 depends on CD_NO_IDESCSI
55 ---help---
56 If this is your CD-ROM drive, say Y here. As described in the file
57 <file:Documentation/cdrom/gscd>, you might have to change a setting
58 in the file <file:drivers/cdrom/gscd.h> before compiling the
59 kernel. Please read the file <file:Documentation/cdrom/gscd>.
60
61 If you say Y here, you should also say Y or M to "ISO 9660 CD-ROM
62 file system support" below, because that's the file system used on
63 CD-ROMs.
64
65 To compile this driver as a module, choose M here: the
66 module will be called gscd.
67
68config SBPCD
69 tristate "Matsushita/Panasonic/Creative, Longshine, TEAC CDROM support"
70 depends on CD_NO_IDESCSI && BROKEN_ON_SMP
71 ---help---
72 This driver supports most of the drives which use the Panasonic or
73 Sound Blaster interface. Please read the file
74 <file:Documentation/cdrom/sbpcd>.
75
76 The Matsushita CR-521, CR-522, CR-523, CR-562, CR-563 drives
77 (sometimes labeled "Creative"), the Creative Labs CD200, the
78 Longshine LCS-7260, the "IBM External ISA CD-ROM" (in fact a CR-56x
79 model), the TEAC CD-55A fall under this category. Some other
80 "electrically compatible" drives (Vertos, Genoa, some Funai models)
81 are currently not supported; for the Sanyo H94A drive currently a
82 separate driver (asked later) is responsible. Most drives have a
83 uniquely shaped faceplate, with a caddyless motorized drawer, but
84 without external brand markings. The older CR-52x drives have a
85 caddy and manual loading/eject, but still no external markings. The
86 driver is able to do an extended auto-probing for interface
87 addresses and drive types; this can help to find facts in cases you
88 are not sure, but can consume some time during the boot process if
89 none of the supported drives gets found. Once your drive got found,
90 you should enter the reported parameters into
91 <file:drivers/cdrom/sbpcd.h> and set "DISTRIBUTION 0" there.
92
93 This driver can support up to four CD-ROM controller cards, and each
94 card can support up to four CD-ROM drives; if you say Y here, you
95 will be asked how many controller cards you have. If compiled as a
96 module, only one controller card (but with up to four drives) is
97 usable.
98
99 If you say Y here, you should also say Y or M to "ISO 9660 CD-ROM
100 file system support" below, because that's the file system used on
101 CD-ROMs.
102
103 To compile this driver as a module, choose M here: the
104 module will be called sbpcd.
105
106config MCDX
107 tristate "Mitsumi CDROM support"
108 depends on CD_NO_IDESCSI
109 ---help---
110 Use this driver if you want to be able to use your Mitsumi LU-005,
111 FX-001 or FX-001D CD-ROM drive.
112
113 Please read the file <file:Documentation/cdrom/mcdx>.
114
115 If you say Y here, you should also say Y or M to "ISO 9660 CD-ROM
116 file system support" below, because that's the file system used on
117 CD-ROMs.
118
119 To compile this driver as a module, choose M here: the
120 module will be called mcdx.
121
122config OPTCD
123 tristate "Optics Storage DOLPHIN 8000AT CDROM support"
124 depends on CD_NO_IDESCSI
125 ---help---
126 This is the driver for the 'DOLPHIN' drive with a 34-pin Sony
127 compatible interface. It also works with the Lasermate CR328A. If
128 you have one of those, say Y. This driver does not work for the
129 Optics Storage 8001 drive; use the IDE-ATAPI CD-ROM driver for that
130 one. Please read the file <file:Documentation/cdrom/optcd>.
131
132 If you say Y here, you should also say Y or M to "ISO 9660 CD-ROM
133 file system support" below, because that's the file system used on
134 CD-ROMs.
135
136 To compile this driver as a module, choose M here: the
137 module will be called optcd.
138
139config CM206
140 tristate "Philips/LMS CM206 CDROM support"
141 depends on CD_NO_IDESCSI && BROKEN_ON_SMP
142 ---help---
143 If you have a Philips/LMS CD-ROM drive cm206 in combination with a
144 cm260 host adapter card, say Y here. Please also read the file
145 <file:Documentation/cdrom/cm206>.
146
147 If you say Y here, you should also say Y or M to "ISO 9660 CD-ROM
148 file system support" below, because that's the file system used on
149 CD-ROMs.
150
151 To compile this driver as a module, choose M here: the
152 module will be called cm206.
153
154config SJCD
155 tristate "Sanyo CDR-H94A CDROM support"
156 depends on CD_NO_IDESCSI
157 help
158 If this is your CD-ROM drive, say Y here and read the file
159 <file:Documentation/cdrom/sjcd>. You should then also say Y or M to
160 "ISO 9660 CD-ROM file system support" below, because that's the
161 file system used on CD-ROMs.
162
163 To compile this driver as a module, choose M here: the
164 module will be called sjcd.
165
166config ISP16_CDI
167 tristate "ISP16/MAD16/Mozart soft configurable cdrom interface support"
168 depends on CD_NO_IDESCSI
169 ---help---
170 These are sound cards with built-in cdrom interfaces using the OPTi
171 82C928 or 82C929 chips. Say Y here to have them detected and
172 possibly configured at boot time. In addition, You'll have to say Y
173 to a driver for the particular cdrom drive you have attached to the
174 card. Read <file:Documentation/cdrom/isp16> for details.
175
176 To compile this driver as a module, choose M here: the
177 module will be called isp16.
178
179config CDU31A
180 tristate "Sony CDU31A/CDU33A CDROM support"
181 depends on CD_NO_IDESCSI && BROKEN_ON_SMP
182 ---help---
183 These CD-ROM drives have a spring-pop-out caddyless drawer, and a
184 rectangular green LED centered beneath it. NOTE: these CD-ROM
185 drives will not be auto detected by the kernel at boot time; you
186 have to provide the interface address as an option to the kernel at
187 boot time as described in <file:Documentation/cdrom/cdu31a> or fill
188 in your parameters into <file:drivers/cdrom/cdu31a.c>. Try "man
189 bootparam" or see the documentation of your boot loader (lilo or
190 loadlin) about how to pass options to the kernel.
191
192 If you say Y here, you should also say Y or M to "ISO 9660 CD-ROM
193 file system support" below, because that's the file system used on
194 CD-ROMs.
195
196 To compile this driver as a module, choose M here: the
197 module will be called cdu31a.
198
199config CDU535
200 tristate "Sony CDU535 CDROM support"
201 depends on CD_NO_IDESCSI
202 ---help---
203 This is the driver for the older Sony CDU-535 and CDU-531 CD-ROM
204 drives. Please read the file <file:Documentation/cdrom/sonycd535>.
205
206 If you say Y here, you should also say Y or M to "ISO 9660 CD-ROM
207 file system support" below, because that's the file system used on
208 CD-ROMs.
209
210 To compile this driver as a module, choose M here: the
211 module will be called sonycd535.
212
213endmenu
diff --git a/drivers/cdrom/Makefile b/drivers/cdrom/Makefile
index d1d1e5a4be73..774c180a4e11 100644
--- a/drivers/cdrom/Makefile
+++ b/drivers/cdrom/Makefile
@@ -10,14 +10,4 @@ obj-$(CONFIG_BLK_DEV_SR) += cdrom.o
10obj-$(CONFIG_PARIDE_PCD) += cdrom.o 10obj-$(CONFIG_PARIDE_PCD) += cdrom.o
11obj-$(CONFIG_CDROM_PKTCDVD) += cdrom.o 11obj-$(CONFIG_CDROM_PKTCDVD) += cdrom.o
12 12
13obj-$(CONFIG_AZTCD) += aztcd.o
14obj-$(CONFIG_CDU31A) += cdu31a.o cdrom.o
15obj-$(CONFIG_CM206) += cm206.o cdrom.o
16obj-$(CONFIG_GSCD) += gscd.o
17obj-$(CONFIG_ISP16_CDI) += isp16.o
18obj-$(CONFIG_MCDX) += mcdx.o cdrom.o
19obj-$(CONFIG_OPTCD) += optcd.o
20obj-$(CONFIG_SBPCD) += sbpcd.o cdrom.o
21obj-$(CONFIG_SJCD) += sjcd.o
22obj-$(CONFIG_CDU535) += sonycd535.o
23obj-$(CONFIG_VIOCD) += viocd.o cdrom.o 13obj-$(CONFIG_VIOCD) += viocd.o cdrom.o
diff --git a/drivers/cdrom/aztcd.c b/drivers/cdrom/aztcd.c
deleted file mode 100644
index d7fbfaae2449..000000000000
--- a/drivers/cdrom/aztcd.c
+++ /dev/null
@@ -1,2492 +0,0 @@
1#define AZT_VERSION "2.60"
2
3/* $Id: aztcd.c,v 2.60 1997/11/29 09:51:19 root Exp root $
4 linux/drivers/block/aztcd.c - Aztech CD268 CDROM driver
5
6 Copyright (C) 1994-98 Werner Zimmermann(Werner.Zimmermann@fht-esslingen.de)
7
8 based on Mitsumi CDROM driver by Martin Hariss and preworks by
9 Eberhard Moenkeberg; contains contributions by Joe Nardone and Robby
10 Schirmer.
11
12 This program is free software; you can redistribute it and/or modify
13 it under the terms of the GNU General Public License as published by
14 the Free Software Foundation; either version 2, or (at your option)
15 any later version.
16
17 This program is distributed in the hope that it will be useful,
18 but WITHOUT ANY WARRANTY; without even the implied warranty of
19 MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
20 GNU General Public License for more details.
21
22 You should have received a copy of the GNU General Public License
23 along with this program; if not, write to the Free Software
24 Foundation, Inc., 675 Mass Ave, Cambridge, MA 02139, USA.
25
26 HISTORY
27 V0.0 Adaption to Aztech CD268-01A Version 1.3
28 Version is PRE_ALPHA, unresolved points:
29 1. I use busy wait instead of timer wait in STEN_LOW,DTEN_LOW
30 thus driver causes CPU overhead and is very slow
31 2. could not find a way to stop the drive, when it is
32 in data read mode, therefore I had to set
33 msf.end.min/sec/frame to 0:0:1 (in azt_poll); so only one
34 frame can be read in sequence, this is also the reason for
35 3. getting 'timeout in state 4' messages, but nevertheless
36 it works
37 W.Zimmermann, Oct. 31, 1994
38 V0.1 Version is ALPHA, problems #2 and #3 resolved.
39 W.Zimmermann, Nov. 3, 1994
40 V0.2 Modification to some comments, debugging aids for partial test
41 with Borland C under DOS eliminated. Timer interrupt wait
42 STEN_LOW_WAIT additionally to busy wait for STEN_LOW implemented;
43 use it only for the 'slow' commands (ACMD_GET_Q_CHANNEL, ACMD_
44 SEEK_TO_LEAD_IN), all other commands are so 'fast', that busy
45 waiting seems better to me than interrupt rescheduling.
46 Besides that, when used in the wrong place, STEN_LOW_WAIT causes
47 kernel panic.
48 In function aztPlay command ACMD_PLAY_AUDIO added, should make
49 audio functions work. The Aztech drive needs different commands
50 to read data tracks and play audio tracks.
51 W.Zimmermann, Nov. 8, 1994
52 V0.3 Recognition of missing drive during boot up improved (speeded up).
53 W.Zimmermann, Nov. 13, 1994
54 V0.35 Rewrote the control mechanism in azt_poll (formerly mcd_poll)
55 including removal of all 'goto' commands. :-);
56 J. Nardone, Nov. 14, 1994
57 V0.4 Renamed variables and constants to 'azt' instead of 'mcd'; had
58 to make some "compatibility" defines in azt.h; please note,
59 that the source file was renamed to azt.c, the include file to
60 azt.h
61 Speeded up drive recognition during init (will be a little bit
62 slower than before if no drive is installed!); suggested by
63 Robby Schirmer.
64 read_count declared volatile and set to AZT_BUF_SIZ to make
65 drive faster (now 300kB/sec, was 60kB/sec before, measured
66 by 'time dd if=/dev/cdrom of=/dev/null bs=2048 count=4096';
67 different AZT_BUF_SIZes were test, above 16 no further im-
68 provement seems to be possible; suggested by E.Moenkeberg.
69 W.Zimmermann, Nov. 18, 1994
70 V0.42 Included getAztStatus command in GetQChannelInfo() to allow
71 reading Q-channel info on audio disks, if drive is stopped,
72 and some other bug fixes in the audio stuff, suggested by
73 Robby Schirmer.
74 Added more ioctls (reading data in mode 1 and mode 2).
75 Completely removed the old azt_poll() routine.
76 Detection of ORCHID CDS-3110 in aztcd_init implemented.
77 Additional debugging aids (see the readme file).
78 W.Zimmermann, Dec. 9, 1994
79 V0.50 Autodetection of drives implemented.
80 W.Zimmermann, Dec. 12, 1994
81 V0.52 Prepared for including in the standard kernel, renamed most
82 variables to contain 'azt', included autoconf.h
83 W.Zimmermann, Dec. 16, 1994
84 V0.6 Version for being included in the standard Linux kernel.
85 Renamed source and header file to aztcd.c and aztcd.h
86 W.Zimmermann, Dec. 24, 1994
87 V0.7 Changed VERIFY_READ to VERIFY_WRITE in aztcd_ioctl, case
88 CDROMREADMODE1 and CDROMREADMODE2; bug fix in the ioctl,
89 which causes kernel crashes when playing audio, changed
90 include-files (config.h instead of autoconf.h, removed
91 delay.h)
92 W.Zimmermann, Jan. 8, 1995
93 V0.72 Some more modifications for adaption to the standard kernel.
94 W.Zimmermann, Jan. 16, 1995
95 V0.80 aztcd is now part of the standard kernel since version 1.1.83.
96 Modified the SET_TIMER and CLEAR_TIMER macros to comply with
97 the new timer scheme.
98 W.Zimmermann, Jan. 21, 1995
99 V0.90 Included CDROMVOLCTRL, but with my Aztech drive I can only turn
100 the channels on and off. If it works better with your drive,
101 please mail me. Also implemented ACMD_CLOSE for CDROMSTART.
102 W.Zimmermann, Jan. 24, 1995
103 V1.00 Implemented close and lock tray commands. Patches supplied by
104 Frank Racis
105 Added support for loadable MODULEs, so aztcd can now also be
106 loaded by insmod and removed by rmmod during run time
107 Werner Zimmermann, Mar. 24, 95
108 V1.10 Implemented soundcard configuration for Orchid CDS-3110 drives
109 connected to Soundwave32 cards. Release for LST 2.1.
110 (still experimental)
111 Werner Zimmermann, May 8, 95
112 V1.20 Implemented limited support for DOSEMU0.60's cdrom.c. Now it works, but
113 sometimes DOSEMU may hang for 30 seconds or so. A fully functional ver-
114 sion needs an update of Dosemu0.60's cdrom.c, which will come with the
115 next revision of Dosemu.
116 Also Soundwave32 support now works.
117 Werner Zimmermann, May 22, 95
118 V1.30 Auto-eject feature. Inspired by Franc Racis (racis@psu.edu)
119 Werner Zimmermann, July 4, 95
120 V1.40 Started multisession support. Implementation copied from mcdx.c
121 by Heiko Schlittermann. Not tested yet.
122 Werner Zimmermann, July 15, 95
123 V1.50 Implementation of ioctl CDROMRESET, continued multisession, began
124 XA, but still untested. Heavy modifications to drive status de-
125 tection.
126 Werner Zimmermann, July 25, 95
127 V1.60 XA support now should work. Speeded up drive recognition in cases,
128 where no drive is installed.
129 Werner Zimmermann, August 8, 1995
130 V1.70 Multisession support now is completed, but there is still not
131 enough testing done. If you can test it, please contact me. For
132 details please read Documentation/cdrom/aztcd
133 Werner Zimmermann, August 19, 1995
134 V1.80 Modification to suit the new kernel boot procedure introduced
135 with kernel 1.3.33. Will definitely not work with older kernels.
136 Programming done by Linus himself.
137 Werner Zimmermann, October 11, 1995
138 V1.90 Support for Conrad TXC drives, thank's to Jochen Kunz and Olaf Kaluza.
139 Werner Zimmermann, October 21, 1995
140 V2.00 Changed #include "blk.h" to <linux/blk.h> as the directory
141 structure was changed. README.aztcd is now /usr/src/docu-
142 mentation/cdrom/aztcd
143 Werner Zimmermann, November 10, 95
144 V2.10 Started to modify azt_poll to prevent reading beyond end of
145 tracks.
146 Werner Zimmermann, December 3, 95
147 V2.20 Changed some comments
148 Werner Zimmermann, April 1, 96
149 V2.30 Implemented support for CyCDROM CR520, CR940, Code for CR520
150 delivered by H.Berger with preworks by E.Moenkeberg.
151 Werner Zimmermann, April 29, 96
152 V2.40 Reorganized the placement of functions in the source code file
153 to reflect the layered approach; did not actually change code
154 Werner Zimmermann, May 1, 96
155 V2.50 Heiko Eissfeldt suggested to remove some VERIFY_READs in
156 aztcd_ioctl; check_aztcd_media_change modified
157 Werner Zimmermann, May 16, 96
158 V2.60 Implemented Auto-Probing; made changes for kernel's 2.1.xx blocksize
159 Adaption to linux kernel > 2.1.0
160 Werner Zimmermann, Nov 29, 97
161
162 November 1999 -- Make kernel-parameter implementation work with 2.3.x
163 Removed init_module & cleanup_module in favor of
164 module_init & module_exit.
165 Torben Mathiasen <tmm@image.dk>
166*/
167
168#include <linux/blkdev.h>
169#include "aztcd.h"
170
171#include <linux/module.h>
172#include <linux/errno.h>
173#include <linux/mm.h>
174#include <linux/timer.h>
175#include <linux/fs.h>
176#include <linux/kernel.h>
177#include <linux/cdrom.h>
178#include <linux/ioport.h>
179#include <linux/string.h>
180#include <linux/major.h>
181
182#include <linux/init.h>
183
184#include <asm/system.h>
185#include <asm/io.h>
186
187#include <asm/uaccess.h>
188
189/*###########################################################################
190 Defines
191 ###########################################################################
192*/
193
194#define MAJOR_NR AZTECH_CDROM_MAJOR
195#define QUEUE (azt_queue)
196#define CURRENT elv_next_request(azt_queue)
197#define SET_TIMER(func, jifs) delay_timer.expires = jiffies + (jifs); \
198 delay_timer.function = (void *) (func); \
199 add_timer(&delay_timer);
200
201#define CLEAR_TIMER del_timer(&delay_timer);
202
203#define RETURNM(message,value) {printk("aztcd: Warning: %s failed\n",message);\
204 return value;}
205#define RETURN(message) {printk("aztcd: Warning: %s failed\n",message);\
206 return;}
207
208/* Macros to switch the IDE-interface to the slave device and back to the master*/
209#define SWITCH_IDE_SLAVE outb_p(0xa0,azt_port+6); \
210 outb_p(0x10,azt_port+6); \
211 outb_p(0x00,azt_port+7); \
212 outb_p(0x10,azt_port+6);
213#define SWITCH_IDE_MASTER outb_p(0xa0,azt_port+6);
214
215
216#if 0
217#define AZT_TEST
218#define AZT_TEST1 /* <int-..> */
219#define AZT_TEST2 /* do_aztcd_request */
220#define AZT_TEST3 /* AZT_S_state */
221#define AZT_TEST4 /* QUICK_LOOP-counter */
222#define AZT_TEST5 /* port(1) state */
223#define AZT_DEBUG
224#define AZT_DEBUG_MULTISESSION
225#endif
226
227static struct request_queue *azt_queue;
228
229static int current_valid(void)
230{
231 return CURRENT &&
232 rq_data_dir(CURRENT) == READ &&
233 CURRENT->sector != -1;
234}
235
236#define AFL_STATUSorDATA (AFL_STATUS | AFL_DATA)
237#define AZT_BUF_SIZ 16
238
239#define READ_TIMEOUT 3000
240
241#define azt_port aztcd /*needed for the modutils */
242
243/*##########################################################################
244 Type Definitions
245 ##########################################################################
246*/
247enum azt_state_e { AZT_S_IDLE, /* 0 */
248 AZT_S_START, /* 1 */
249 AZT_S_MODE, /* 2 */
250 AZT_S_READ, /* 3 */
251 AZT_S_DATA, /* 4 */
252 AZT_S_STOP, /* 5 */
253 AZT_S_STOPPING /* 6 */
254};
255enum azt_read_modes { AZT_MODE_0, /*read mode for audio disks, not supported by Aztech firmware */
256 AZT_MODE_1, /*read mode for normal CD-ROMs */
257 AZT_MODE_2 /*read mode for XA CD-ROMs */
258};
259
260/*##########################################################################
261 Global Variables
262 ##########################################################################
263*/
264static int aztPresent = 0;
265
266static volatile int azt_transfer_is_active = 0;
267
268static char azt_buf[CD_FRAMESIZE_RAW * AZT_BUF_SIZ]; /*buffer for block size conversion */
269#if AZT_PRIVATE_IOCTLS
270static char buf[CD_FRAMESIZE_RAW]; /*separate buffer for the ioctls */
271#endif
272
273static volatile int azt_buf_bn[AZT_BUF_SIZ], azt_next_bn;
274static volatile int azt_buf_in, azt_buf_out = -1;
275static volatile int azt_error = 0;
276static int azt_open_count = 0;
277static volatile enum azt_state_e azt_state = AZT_S_IDLE;
278#ifdef AZT_TEST3
279static volatile enum azt_state_e azt_state_old = AZT_S_STOP;
280static volatile int azt_st_old = 0;
281#endif
282static volatile enum azt_read_modes azt_read_mode = AZT_MODE_1;
283
284static int azt_mode = -1;
285static volatile int azt_read_count = 1;
286
287static int azt_port = AZT_BASE_ADDR;
288
289module_param(azt_port, int, 0);
290
291static int azt_port_auto[16] = AZT_BASE_AUTO;
292
293static char azt_cont = 0;
294static char azt_init_end = 0;
295static char azt_auto_eject = AZT_AUTO_EJECT;
296
297static int AztTimeout, AztTries;
298static DECLARE_WAIT_QUEUE_HEAD(azt_waitq);
299static DEFINE_TIMER(delay_timer, NULL, 0, 0);
300
301static struct azt_DiskInfo DiskInfo;
302static struct azt_Toc Toc[MAX_TRACKS];
303static struct azt_Play_msf azt_Play;
304
305static int aztAudioStatus = CDROM_AUDIO_NO_STATUS;
306static char aztDiskChanged = 1;
307static char aztTocUpToDate = 0;
308
309static unsigned char aztIndatum;
310static unsigned long aztTimeOutCount;
311static int aztCmd = 0;
312
313static DEFINE_SPINLOCK(aztSpin);
314
315/*###########################################################################
316 Function Prototypes
317 ###########################################################################
318*/
319/* CDROM Drive Low Level I/O Functions */
320static void aztStatTimer(void);
321
322/* CDROM Drive Command Functions */
323static int aztGetDiskInfo(void);
324#if AZT_MULTISESSION
325static int aztGetMultiDiskInfo(void);
326#endif
327static int aztGetToc(int multi);
328
329/* Kernel Interface Functions */
330static int check_aztcd_media_change(struct gendisk *disk);
331static int aztcd_ioctl(struct inode *ip, struct file *fp, unsigned int cmd,
332 unsigned long arg);
333static int aztcd_open(struct inode *ip, struct file *fp);
334static int aztcd_release(struct inode *inode, struct file *file);
335
336static struct block_device_operations azt_fops = {
337 .owner = THIS_MODULE,
338 .open = aztcd_open,
339 .release = aztcd_release,
340 .ioctl = aztcd_ioctl,
341 .media_changed = check_aztcd_media_change,
342};
343
344/* Aztcd State Machine: Controls Drive Operating State */
345static void azt_poll(void);
346
347/* Miscellaneous support functions */
348static void azt_hsg2msf(long hsg, struct msf *msf);
349static long azt_msf2hsg(struct msf *mp);
350static void azt_bin2bcd(unsigned char *p);
351static int azt_bcd2bin(unsigned char bcd);
352
353/*##########################################################################
354 CDROM Drive Low Level I/O Functions
355 ##########################################################################
356*/
357/* Macros for the drive hardware interface handshake, these macros use
358 busy waiting */
359/* Wait for OP_OK = drive answers with AFL_OP_OK after receiving a command*/
360# define OP_OK op_ok()
361static void op_ok(void)
362{
363 aztTimeOutCount = 0;
364 do {
365 aztIndatum = inb(DATA_PORT);
366 aztTimeOutCount++;
367 if (aztTimeOutCount >= AZT_TIMEOUT) {
368 printk("aztcd: Error Wait OP_OK\n");
369 break;
370 }
371 } while (aztIndatum != AFL_OP_OK);
372}
373
374/* Wait for PA_OK = drive answers with AFL_PA_OK after receiving parameters*/
375#if 0
376# define PA_OK pa_ok()
377static void pa_ok(void)
378{
379 aztTimeOutCount = 0;
380 do {
381 aztIndatum = inb(DATA_PORT);
382 aztTimeOutCount++;
383 if (aztTimeOutCount >= AZT_TIMEOUT) {
384 printk("aztcd: Error Wait PA_OK\n");
385 break;
386 }
387 } while (aztIndatum != AFL_PA_OK);
388}
389#endif
390
391/* Wait for STEN=Low = handshake signal 'AFL_.._OK available or command executed*/
392# define STEN_LOW sten_low()
393static void sten_low(void)
394{
395 aztTimeOutCount = 0;
396 do {
397 aztIndatum = inb(STATUS_PORT);
398 aztTimeOutCount++;
399 if (aztTimeOutCount >= AZT_TIMEOUT) {
400 if (azt_init_end)
401 printk
402 ("aztcd: Error Wait STEN_LOW commands:%x\n",
403 aztCmd);
404 break;
405 }
406 } while (aztIndatum & AFL_STATUS);
407}
408
409/* Wait for DTEN=Low = handshake signal 'Data available'*/
410# define DTEN_LOW dten_low()
411static void dten_low(void)
412{
413 aztTimeOutCount = 0;
414 do {
415 aztIndatum = inb(STATUS_PORT);
416 aztTimeOutCount++;
417 if (aztTimeOutCount >= AZT_TIMEOUT) {
418 printk("aztcd: Error Wait DTEN_OK\n");
419 break;
420 }
421 } while (aztIndatum & AFL_DATA);
422}
423
424/*
425 * Macro for timer wait on STEN=Low, should only be used for 'slow' commands;
426 * may cause kernel panic when used in the wrong place
427*/
428#define STEN_LOW_WAIT statusAzt()
429static void statusAzt(void)
430{
431 AztTimeout = AZT_STATUS_DELAY;
432 SET_TIMER(aztStatTimer, HZ / 100);
433 sleep_on(&azt_waitq);
434 if (AztTimeout <= 0)
435 printk("aztcd: Error Wait STEN_LOW_WAIT command:%x\n",
436 aztCmd);
437 return;
438}
439
440static void aztStatTimer(void)
441{
442 if (!(inb(STATUS_PORT) & AFL_STATUS)) {
443 wake_up(&azt_waitq);
444 return;
445 }
446 AztTimeout--;
447 if (AztTimeout <= 0) {
448 wake_up(&azt_waitq);
449 printk("aztcd: Error aztStatTimer: Timeout\n");
450 return;
451 }
452 SET_TIMER(aztStatTimer, HZ / 100);
453}
454
455/*##########################################################################
456 CDROM Drive Command Functions
457 ##########################################################################
458*/
459/*
460 * Send a single command, return -1 on error, else 0
461*/
462static int aztSendCmd(int cmd)
463{
464 unsigned char data;
465 int retry;
466
467#ifdef AZT_DEBUG
468 printk("aztcd: Executing command %x\n", cmd);
469#endif
470
471 if ((azt_port == 0x1f0) || (azt_port == 0x170))
472 SWITCH_IDE_SLAVE; /*switch IDE interface to slave configuration */
473
474 aztCmd = cmd;
475 outb(POLLED, MODE_PORT);
476 do {
477 if (inb(STATUS_PORT) & AFL_STATUS)
478 break;
479 inb(DATA_PORT); /* if status left from last command, read and */
480 } while (1); /* discard it */
481 do {
482 if (inb(STATUS_PORT) & AFL_DATA)
483 break;
484 inb(DATA_PORT); /* if data left from last command, read and */
485 } while (1); /* discard it */
486 for (retry = 0; retry < AZT_RETRY_ATTEMPTS; retry++) {
487 outb((unsigned char) cmd, CMD_PORT);
488 STEN_LOW;
489 data = inb(DATA_PORT);
490 if (data == AFL_OP_OK) {
491 return 0;
492 } /*OP_OK? */
493 if (data == AFL_OP_ERR) {
494 STEN_LOW;
495 data = inb(DATA_PORT);
496 printk
497 ("### Error 1 aztcd: aztSendCmd %x Error Code %x\n",
498 cmd, data);
499 }
500 }
501 if (retry >= AZT_RETRY_ATTEMPTS) {
502 printk("### Error 2 aztcd: aztSendCmd %x \n", cmd);
503 azt_error = 0xA5;
504 }
505 RETURNM("aztSendCmd", -1);
506}
507
508/*
509 * Send a play or read command to the drive, return -1 on error, else 0
510*/
511static int sendAztCmd(int cmd, struct azt_Play_msf *params)
512{
513 unsigned char data;
514 int retry;
515
516#ifdef AZT_DEBUG
517 printk("aztcd: play start=%02x:%02x:%02x end=%02x:%02x:%02x\n",
518 params->start.min, params->start.sec, params->start.frame,
519 params->end.min, params->end.sec, params->end.frame);
520#endif
521 for (retry = 0; retry < AZT_RETRY_ATTEMPTS; retry++) {
522 aztSendCmd(cmd);
523 outb(params->start.min, CMD_PORT);
524 outb(params->start.sec, CMD_PORT);
525 outb(params->start.frame, CMD_PORT);
526 outb(params->end.min, CMD_PORT);
527 outb(params->end.sec, CMD_PORT);
528 outb(params->end.frame, CMD_PORT);
529 STEN_LOW;
530 data = inb(DATA_PORT);
531 if (data == AFL_PA_OK) {
532 return 0;
533 } /*PA_OK ? */
534 if (data == AFL_PA_ERR) {
535 STEN_LOW;
536 data = inb(DATA_PORT);
537 printk
538 ("### Error 1 aztcd: sendAztCmd %x Error Code %x\n",
539 cmd, data);
540 }
541 }
542 if (retry >= AZT_RETRY_ATTEMPTS) {
543 printk("### Error 2 aztcd: sendAztCmd %x\n ", cmd);
544 azt_error = 0xA5;
545 }
546 RETURNM("sendAztCmd", -1);
547}
548
549/*
550 * Send a seek command to the drive, return -1 on error, else 0
551*/
552static int aztSeek(struct azt_Play_msf *params)
553{
554 unsigned char data;
555 int retry;
556
557#ifdef AZT_DEBUG
558 printk("aztcd: aztSeek %02x:%02x:%02x\n",
559 params->start.min, params->start.sec, params->start.frame);
560#endif
561 for (retry = 0; retry < AZT_RETRY_ATTEMPTS; retry++) {
562 aztSendCmd(ACMD_SEEK);
563 outb(params->start.min, CMD_PORT);
564 outb(params->start.sec, CMD_PORT);
565 outb(params->start.frame, CMD_PORT);
566 STEN_LOW;
567 data = inb(DATA_PORT);
568 if (data == AFL_PA_OK) {
569 return 0;
570 } /*PA_OK ? */
571 if (data == AFL_PA_ERR) {
572 STEN_LOW;
573 data = inb(DATA_PORT);
574 printk("### Error 1 aztcd: aztSeek\n");
575 }
576 }
577 if (retry >= AZT_RETRY_ATTEMPTS) {
578 printk("### Error 2 aztcd: aztSeek\n ");
579 azt_error = 0xA5;
580 }
581 RETURNM("aztSeek", -1);
582}
583
584/* Send a Set Disk Type command
585 does not seem to work with Aztech drives, behavior is completely indepen-
586 dent on which mode is set ???
587*/
588static int aztSetDiskType(int type)
589{
590 unsigned char data;
591 int retry;
592
593#ifdef AZT_DEBUG
594 printk("aztcd: set disk type command: type= %i\n", type);
595#endif
596 for (retry = 0; retry < AZT_RETRY_ATTEMPTS; retry++) {
597 aztSendCmd(ACMD_SET_DISK_TYPE);
598 outb(type, CMD_PORT);
599 STEN_LOW;
600 data = inb(DATA_PORT);
601 if (data == AFL_PA_OK) { /*PA_OK ? */
602 azt_read_mode = type;
603 return 0;
604 }
605 if (data == AFL_PA_ERR) {
606 STEN_LOW;
607 data = inb(DATA_PORT);
608 printk
609 ("### Error 1 aztcd: aztSetDiskType %x Error Code %x\n",
610 type, data);
611 }
612 }
613 if (retry >= AZT_RETRY_ATTEMPTS) {
614 printk("### Error 2 aztcd: aztSetDiskType %x\n ", type);
615 azt_error = 0xA5;
616 }
617 RETURNM("aztSetDiskType", -1);
618}
619
620
621/* used in azt_poll to poll the status, expects another program to issue a
622 * ACMD_GET_STATUS directly before
623 */
624static int aztStatus(void)
625{
626 int st;
627/* int i;
628
629 i = inb(STATUS_PORT) & AFL_STATUS; is STEN=0? ???
630 if (!i)
631*/ STEN_LOW;
632 if (aztTimeOutCount < AZT_TIMEOUT) {
633 st = inb(DATA_PORT) & 0xFF;
634 return st;
635 } else
636 RETURNM("aztStatus", -1);
637}
638
639/*
640 * Get the drive status
641 */
642static int getAztStatus(void)
643{
644 int st;
645
646 if (aztSendCmd(ACMD_GET_STATUS))
647 RETURNM("getAztStatus 1", -1);
648 STEN_LOW;
649 st = inb(DATA_PORT) & 0xFF;
650#ifdef AZT_DEBUG
651 printk("aztcd: Status = %x\n", st);
652#endif
653 if ((st == 0xFF) || (st & AST_CMD_CHECK)) {
654 printk
655 ("aztcd: AST_CMD_CHECK error or no status available\n");
656 return -1;
657 }
658
659 if (((st & AST_MODE_BITS) != AST_BUSY)
660 && (aztAudioStatus == CDROM_AUDIO_PLAY))
661 /* XXX might be an error? look at q-channel? */
662 aztAudioStatus = CDROM_AUDIO_COMPLETED;
663
664 if ((st & AST_DSK_CHG) || (st & AST_NOT_READY)) {
665 aztDiskChanged = 1;
666 aztTocUpToDate = 0;
667 aztAudioStatus = CDROM_AUDIO_NO_STATUS;
668 }
669 return st;
670}
671
672
673/*
674 * Send a 'Play' command and get the status. Use only from the top half.
675 */
676static int aztPlay(struct azt_Play_msf *arg)
677{
678 if (sendAztCmd(ACMD_PLAY_AUDIO, arg) < 0)
679 RETURNM("aztPlay", -1);
680 return 0;
681}
682
683/*
684 * Subroutines to automatically close the door (tray) and
685 * lock it closed when the cd is mounted. Leave the tray
686 * locking as an option
687 */
688static void aztCloseDoor(void)
689{
690 aztSendCmd(ACMD_CLOSE);
691 STEN_LOW;
692 return;
693}
694
695static void aztLockDoor(void)
696{
697#if AZT_ALLOW_TRAY_LOCK
698 aztSendCmd(ACMD_LOCK);
699 STEN_LOW;
700#endif
701 return;
702}
703
704static void aztUnlockDoor(void)
705{
706#if AZT_ALLOW_TRAY_LOCK
707 aztSendCmd(ACMD_UNLOCK);
708 STEN_LOW;
709#endif
710 return;
711}
712
713/*
714 * Read a value from the drive. Should return quickly, so a busy wait
715 * is used to avoid excessive rescheduling. The read command itself must
716 * be issued with aztSendCmd() directly before
717 */
718static int aztGetValue(unsigned char *result)
719{
720 int s;
721
722 STEN_LOW;
723 if (aztTimeOutCount >= AZT_TIMEOUT) {
724 printk("aztcd: aztGetValue timeout\n");
725 return -1;
726 }
727 s = inb(DATA_PORT) & 0xFF;
728 *result = (unsigned char) s;
729 return 0;
730}
731
732/*
733 * Read the current Q-channel info. Also used for reading the
734 * table of contents.
735 */
736static int aztGetQChannelInfo(struct azt_Toc *qp)
737{
738 unsigned char notUsed;
739 int st;
740
741#ifdef AZT_DEBUG
742 printk("aztcd: starting aztGetQChannelInfo Time:%li\n", jiffies);
743#endif
744 if ((st = getAztStatus()) == -1)
745 RETURNM("aztGetQChannelInfo 1", -1);
746 if (aztSendCmd(ACMD_GET_Q_CHANNEL))
747 RETURNM("aztGetQChannelInfo 2", -1);
748 /*STEN_LOW_WAIT; ??? Dosemu0.60's cdrom.c does not like STEN_LOW_WAIT here */
749 if (aztGetValue(&notUsed))
750 RETURNM("aztGetQChannelInfo 3", -1); /*??? Nullbyte einlesen */
751 if ((st & AST_MODE_BITS) == AST_INITIAL) {
752 qp->ctrl_addr = 0; /* when audio stop ACMD_GET_Q_CHANNEL returns */
753 qp->track = 0; /* only one byte with Aztech drives */
754 qp->pointIndex = 0;
755 qp->trackTime.min = 0;
756 qp->trackTime.sec = 0;
757 qp->trackTime.frame = 0;
758 qp->diskTime.min = 0;
759 qp->diskTime.sec = 0;
760 qp->diskTime.frame = 0;
761 return 0;
762 } else {
763 if (aztGetValue(&qp->ctrl_addr) < 0)
764 RETURNM("aztGetQChannelInfo 4", -1);
765 if (aztGetValue(&qp->track) < 0)
766 RETURNM("aztGetQChannelInfo 4", -1);
767 if (aztGetValue(&qp->pointIndex) < 0)
768 RETURNM("aztGetQChannelInfo 4", -1);
769 if (aztGetValue(&qp->trackTime.min) < 0)
770 RETURNM("aztGetQChannelInfo 4", -1);
771 if (aztGetValue(&qp->trackTime.sec) < 0)
772 RETURNM("aztGetQChannelInfo 4", -1);
773 if (aztGetValue(&qp->trackTime.frame) < 0)
774 RETURNM("aztGetQChannelInfo 4", -1);
775 if (aztGetValue(&notUsed) < 0)
776 RETURNM("aztGetQChannelInfo 4", -1);
777 if (aztGetValue(&qp->diskTime.min) < 0)
778 RETURNM("aztGetQChannelInfo 4", -1);
779 if (aztGetValue(&qp->diskTime.sec) < 0)
780 RETURNM("aztGetQChannelInfo 4", -1);
781 if (aztGetValue(&qp->diskTime.frame) < 0)
782 RETURNM("aztGetQChannelInfo 4", -1);
783 }
784#ifdef AZT_DEBUG
785 printk("aztcd: exiting aztGetQChannelInfo Time:%li\n", jiffies);
786#endif
787 return 0;
788}
789
790/*
791 * Read the table of contents (TOC) and TOC header if necessary
792 */
793static int aztUpdateToc(void)
794{
795 int st;
796
797#ifdef AZT_DEBUG
798 printk("aztcd: starting aztUpdateToc Time:%li\n", jiffies);
799#endif
800 if (aztTocUpToDate)
801 return 0;
802
803 if (aztGetDiskInfo() < 0)
804 return -EIO;
805
806 if (aztGetToc(0) < 0)
807 return -EIO;
808
809 /*audio disk detection
810 with my Aztech drive there is no audio status bit, so I use the copy
811 protection bit of the first track. If this track is copy protected
812 (copy bit = 0), I assume, it's an audio disk. Strange, but works ??? */
813 if (!(Toc[DiskInfo.first].ctrl_addr & 0x40))
814 DiskInfo.audio = 1;
815 else
816 DiskInfo.audio = 0;
817
818 /* XA detection */
819 if (!DiskInfo.audio) {
820 azt_Play.start.min = 0; /*XA detection only seems to work */
821 azt_Play.start.sec = 2; /*when we play a track */
822 azt_Play.start.frame = 0;
823 azt_Play.end.min = 0;
824 azt_Play.end.sec = 0;
825 azt_Play.end.frame = 1;
826 if (sendAztCmd(ACMD_PLAY_READ, &azt_Play))
827 return -1;
828 DTEN_LOW;
829 for (st = 0; st < CD_FRAMESIZE; st++)
830 inb(DATA_PORT);
831 }
832 DiskInfo.xa = getAztStatus() & AST_MODE;
833 if (DiskInfo.xa) {
834 printk
835 ("aztcd: XA support experimental - mail results to Werner.Zimmermann@fht-esslingen.de\n");
836 }
837
838 /*multisession detection
839 support for multisession CDs is done automatically with Aztech drives,
840 we don't have to take care about TOC redirection; if we want the isofs
841 to take care about redirection, we have to set AZT_MULTISESSION to 1 */
842 DiskInfo.multi = 0;
843#if AZT_MULTISESSION
844 if (DiskInfo.xa) {
845 aztGetMultiDiskInfo(); /*here Disk.Info.multi is set */
846 }
847#endif
848 if (DiskInfo.multi) {
849 DiskInfo.lastSession.min = Toc[DiskInfo.next].diskTime.min;
850 DiskInfo.lastSession.sec = Toc[DiskInfo.next].diskTime.sec;
851 DiskInfo.lastSession.frame =
852 Toc[DiskInfo.next].diskTime.frame;
853 printk("aztcd: Multisession support experimental\n");
854 } else {
855 DiskInfo.lastSession.min =
856 Toc[DiskInfo.first].diskTime.min;
857 DiskInfo.lastSession.sec =
858 Toc[DiskInfo.first].diskTime.sec;
859 DiskInfo.lastSession.frame =
860 Toc[DiskInfo.first].diskTime.frame;
861 }
862
863 aztTocUpToDate = 1;
864#ifdef AZT_DEBUG
865 printk("aztcd: exiting aztUpdateToc Time:%li\n", jiffies);
866#endif
867 return 0;
868}
869
870
871/* Read the table of contents header, i.e. no. of tracks and start of first
872 * track
873 */
874static int aztGetDiskInfo(void)
875{
876 int limit;
877 unsigned char test;
878 struct azt_Toc qInfo;
879
880#ifdef AZT_DEBUG
881 printk("aztcd: starting aztGetDiskInfo Time:%li\n", jiffies);
882#endif
883 if (aztSendCmd(ACMD_SEEK_TO_LEADIN))
884 RETURNM("aztGetDiskInfo 1", -1);
885 STEN_LOW_WAIT;
886 test = 0;
887 for (limit = 300; limit > 0; limit--) {
888 if (aztGetQChannelInfo(&qInfo) < 0)
889 RETURNM("aztGetDiskInfo 2", -1);
890 if (qInfo.pointIndex == 0xA0) { /*Number of FirstTrack */
891 DiskInfo.first = qInfo.diskTime.min;
892 DiskInfo.first = azt_bcd2bin(DiskInfo.first);
893 test = test | 0x01;
894 }
895 if (qInfo.pointIndex == 0xA1) { /*Number of LastTrack */
896 DiskInfo.last = qInfo.diskTime.min;
897 DiskInfo.last = azt_bcd2bin(DiskInfo.last);
898 test = test | 0x02;
899 }
900 if (qInfo.pointIndex == 0xA2) { /*DiskLength */
901 DiskInfo.diskLength.min = qInfo.diskTime.min;
902 DiskInfo.diskLength.sec = qInfo.diskTime.sec;
903 DiskInfo.diskLength.frame = qInfo.diskTime.frame;
904 test = test | 0x04;
905 }
906 if ((qInfo.pointIndex == DiskInfo.first) && (test & 0x01)) { /*StartTime of First Track */
907 DiskInfo.firstTrack.min = qInfo.diskTime.min;
908 DiskInfo.firstTrack.sec = qInfo.diskTime.sec;
909 DiskInfo.firstTrack.frame = qInfo.diskTime.frame;
910 test = test | 0x08;
911 }
912 if (test == 0x0F)
913 break;
914 }
915#ifdef AZT_DEBUG
916 printk("aztcd: exiting aztGetDiskInfo Time:%li\n", jiffies);
917 printk
918 ("Disk Info: first %d last %d length %02X:%02X.%02X dez first %02X:%02X.%02X dez\n",
919 DiskInfo.first, DiskInfo.last, DiskInfo.diskLength.min,
920 DiskInfo.diskLength.sec, DiskInfo.diskLength.frame,
921 DiskInfo.firstTrack.min, DiskInfo.firstTrack.sec,
922 DiskInfo.firstTrack.frame);
923#endif
924 if (test != 0x0F)
925 return -1;
926 return 0;
927}
928
929#if AZT_MULTISESSION
930/*
931 * Get Multisession Disk Info
932 */
933static int aztGetMultiDiskInfo(void)
934{
935 int limit, k = 5;
936 unsigned char test;
937 struct azt_Toc qInfo;
938
939#ifdef AZT_DEBUG
940 printk("aztcd: starting aztGetMultiDiskInfo\n");
941#endif
942
943 do {
944 azt_Play.start.min = Toc[DiskInfo.last + 1].diskTime.min;
945 azt_Play.start.sec = Toc[DiskInfo.last + 1].diskTime.sec;
946 azt_Play.start.frame =
947 Toc[DiskInfo.last + 1].diskTime.frame;
948 test = 0;
949
950 for (limit = 30; limit > 0; limit--) { /*Seek for LeadIn of next session */
951 if (aztSeek(&azt_Play))
952 RETURNM("aztGetMultiDiskInfo 1", -1);
953 if (aztGetQChannelInfo(&qInfo) < 0)
954 RETURNM("aztGetMultiDiskInfo 2", -1);
955 if ((qInfo.track == 0) && (qInfo.pointIndex))
956 break; /*LeadIn found */
957 if ((azt_Play.start.sec += 10) > 59) {
958 azt_Play.start.sec = 0;
959 azt_Play.start.min++;
960 }
961 }
962 if (!limit)
963 break; /*Check, if a leadin track was found, if not we're
964 at the end of the disk */
965#ifdef AZT_DEBUG_MULTISESSION
966 printk("leadin found track %d pointIndex %x limit %d\n",
967 qInfo.track, qInfo.pointIndex, limit);
968#endif
969 for (limit = 300; limit > 0; limit--) {
970 if (++azt_Play.start.frame > 74) {
971 azt_Play.start.frame = 0;
972 if (azt_Play.start.sec > 59) {
973 azt_Play.start.sec = 0;
974 azt_Play.start.min++;
975 }
976 }
977 if (aztSeek(&azt_Play))
978 RETURNM("aztGetMultiDiskInfo 3", -1);
979 if (aztGetQChannelInfo(&qInfo) < 0)
980 RETURNM("aztGetMultiDiskInfo 4", -1);
981 if (qInfo.pointIndex == 0xA0) { /*Number of NextTrack */
982 DiskInfo.next = qInfo.diskTime.min;
983 DiskInfo.next = azt_bcd2bin(DiskInfo.next);
984 test = test | 0x01;
985 }
986 if (qInfo.pointIndex == 0xA1) { /*Number of LastTrack */
987 DiskInfo.last = qInfo.diskTime.min;
988 DiskInfo.last = azt_bcd2bin(DiskInfo.last);
989 test = test | 0x02;
990 }
991 if (qInfo.pointIndex == 0xA2) { /*DiskLength */
992 DiskInfo.diskLength.min =
993 qInfo.diskTime.min;
994 DiskInfo.diskLength.sec =
995 qInfo.diskTime.sec;
996 DiskInfo.diskLength.frame =
997 qInfo.diskTime.frame;
998 test = test | 0x04;
999 }
1000 if ((qInfo.pointIndex == DiskInfo.next) && (test & 0x01)) { /*StartTime of Next Track */
1001 DiskInfo.nextSession.min =
1002 qInfo.diskTime.min;
1003 DiskInfo.nextSession.sec =
1004 qInfo.diskTime.sec;
1005 DiskInfo.nextSession.frame =
1006 qInfo.diskTime.frame;
1007 test = test | 0x08;
1008 }
1009 if (test == 0x0F)
1010 break;
1011 }
1012#ifdef AZT_DEBUG_MULTISESSION
1013 printk
1014 ("MultiDisk Info: first %d next %d last %d length %02x:%02x.%02x dez first %02x:%02x.%02x dez next %02x:%02x.%02x dez\n",
1015 DiskInfo.first, DiskInfo.next, DiskInfo.last,
1016 DiskInfo.diskLength.min, DiskInfo.diskLength.sec,
1017 DiskInfo.diskLength.frame, DiskInfo.firstTrack.min,
1018 DiskInfo.firstTrack.sec, DiskInfo.firstTrack.frame,
1019 DiskInfo.nextSession.min, DiskInfo.nextSession.sec,
1020 DiskInfo.nextSession.frame);
1021#endif
1022 if (test != 0x0F)
1023 break;
1024 else
1025 DiskInfo.multi = 1; /*found TOC of more than one session */
1026 aztGetToc(1);
1027 } while (--k);
1028
1029#ifdef AZT_DEBUG
1030 printk("aztcd: exiting aztGetMultiDiskInfo Time:%li\n", jiffies);
1031#endif
1032 return 0;
1033}
1034#endif
1035
1036/*
1037 * Read the table of contents (TOC)
1038 */
1039static int aztGetToc(int multi)
1040{
1041 int i, px;
1042 int limit;
1043 struct azt_Toc qInfo;
1044
1045#ifdef AZT_DEBUG
1046 printk("aztcd: starting aztGetToc Time:%li\n", jiffies);
1047#endif
1048 if (!multi) {
1049 for (i = 0; i < MAX_TRACKS; i++)
1050 Toc[i].pointIndex = 0;
1051 i = DiskInfo.last + 3;
1052 } else {
1053 for (i = DiskInfo.next; i < MAX_TRACKS; i++)
1054 Toc[i].pointIndex = 0;
1055 i = DiskInfo.last + 4 - DiskInfo.next;
1056 }
1057
1058/*Is there a good reason to stop motor before TOC read?
1059 if (aztSendCmd(ACMD_STOP)) RETURNM("aztGetToc 1",-1);
1060 STEN_LOW_WAIT;
1061*/
1062
1063 if (!multi) {
1064 azt_mode = 0x05;
1065 if (aztSendCmd(ACMD_SEEK_TO_LEADIN))
1066 RETURNM("aztGetToc 2", -1);
1067 STEN_LOW_WAIT;
1068 }
1069 for (limit = 300; limit > 0; limit--) {
1070 if (multi) {
1071 if (++azt_Play.start.sec > 59) {
1072 azt_Play.start.sec = 0;
1073 azt_Play.start.min++;
1074 }
1075 if (aztSeek(&azt_Play))
1076 RETURNM("aztGetToc 3", -1);
1077 }
1078 if (aztGetQChannelInfo(&qInfo) < 0)
1079 break;
1080
1081 px = azt_bcd2bin(qInfo.pointIndex);
1082
1083 if (px > 0 && px < MAX_TRACKS && qInfo.track == 0)
1084 if (Toc[px].pointIndex == 0) {
1085 Toc[px] = qInfo;
1086 i--;
1087 }
1088
1089 if (i <= 0)
1090 break;
1091 }
1092
1093 Toc[DiskInfo.last + 1].diskTime = DiskInfo.diskLength;
1094 Toc[DiskInfo.last].trackTime = DiskInfo.diskLength;
1095
1096#ifdef AZT_DEBUG_MULTISESSION
1097 printk("aztcd: exiting aztGetToc\n");
1098 for (i = 1; i <= DiskInfo.last + 1; i++)
1099 printk
1100 ("i = %2d ctl-adr = %02X track %2d px %02X %02X:%02X.%02X dez %02X:%02X.%02X dez\n",
1101 i, Toc[i].ctrl_addr, Toc[i].track, Toc[i].pointIndex,
1102 Toc[i].trackTime.min, Toc[i].trackTime.sec,
1103 Toc[i].trackTime.frame, Toc[i].diskTime.min,
1104 Toc[i].diskTime.sec, Toc[i].diskTime.frame);
1105 for (i = 100; i < 103; i++)
1106 printk
1107 ("i = %2d ctl-adr = %02X track %2d px %02X %02X:%02X.%02X dez %02X:%02X.%02X dez\n",
1108 i, Toc[i].ctrl_addr, Toc[i].track, Toc[i].pointIndex,
1109 Toc[i].trackTime.min, Toc[i].trackTime.sec,
1110 Toc[i].trackTime.frame, Toc[i].diskTime.min,
1111 Toc[i].diskTime.sec, Toc[i].diskTime.frame);
1112#endif
1113
1114 return limit > 0 ? 0 : -1;
1115}
1116
1117
1118/*##########################################################################
1119 Kernel Interface Functions
1120 ##########################################################################
1121*/
1122
1123#ifndef MODULE
1124static int __init aztcd_setup(char *str)
1125{
1126 int ints[4];
1127
1128 (void) get_options(str, ARRAY_SIZE(ints), ints);
1129
1130 if (ints[0] > 0)
1131 azt_port = ints[1];
1132 if (ints[1] > 1)
1133 azt_cont = ints[2];
1134 return 1;
1135}
1136
1137__setup("aztcd=", aztcd_setup);
1138
1139#endif /* !MODULE */
1140
1141/*
1142 * Checking if the media has been changed
1143*/
1144static int check_aztcd_media_change(struct gendisk *disk)
1145{
1146 if (aztDiskChanged) { /* disk changed */
1147 aztDiskChanged = 0;
1148 return 1;
1149 } else
1150 return 0; /* no change */
1151}
1152
1153/*
1154 * Kernel IO-controls
1155*/
1156static int aztcd_ioctl(struct inode *ip, struct file *fp, unsigned int cmd,
1157 unsigned long arg)
1158{
1159 int i;
1160 struct azt_Toc qInfo;
1161 struct cdrom_ti ti;
1162 struct cdrom_tochdr tocHdr;
1163 struct cdrom_msf msf;
1164 struct cdrom_tocentry entry;
1165 struct azt_Toc *tocPtr;
1166 struct cdrom_subchnl subchnl;
1167 struct cdrom_volctrl volctrl;
1168 void __user *argp = (void __user *)arg;
1169
1170#ifdef AZT_DEBUG
1171 printk("aztcd: starting aztcd_ioctl - Command:%x Time: %li\n",
1172 cmd, jiffies);
1173 printk("aztcd Status %x\n", getAztStatus());
1174#endif
1175 if (!ip)
1176 RETURNM("aztcd_ioctl 1", -EINVAL);
1177 if (getAztStatus() < 0)
1178 RETURNM("aztcd_ioctl 2", -EIO);
1179 if ((!aztTocUpToDate) || (aztDiskChanged)) {
1180 if ((i = aztUpdateToc()) < 0)
1181 RETURNM("aztcd_ioctl 3", i); /* error reading TOC */
1182 }
1183
1184 switch (cmd) {
1185 case CDROMSTART: /* Spin up the drive. Don't know, what to do,
1186 at least close the tray */
1187#if AZT_PRIVATE_IOCTLS
1188 if (aztSendCmd(ACMD_CLOSE))
1189 RETURNM("aztcd_ioctl 4", -1);
1190 STEN_LOW_WAIT;
1191#endif
1192 break;
1193 case CDROMSTOP: /* Spin down the drive */
1194 if (aztSendCmd(ACMD_STOP))
1195 RETURNM("aztcd_ioctl 5", -1);
1196 STEN_LOW_WAIT;
1197 /* should we do anything if it fails? */
1198 aztAudioStatus = CDROM_AUDIO_NO_STATUS;
1199 break;
1200 case CDROMPAUSE: /* Pause the drive */
1201 if (aztAudioStatus != CDROM_AUDIO_PLAY)
1202 return -EINVAL;
1203
1204 if (aztGetQChannelInfo(&qInfo) < 0) { /* didn't get q channel info */
1205 aztAudioStatus = CDROM_AUDIO_NO_STATUS;
1206 RETURNM("aztcd_ioctl 7", 0);
1207 }
1208 azt_Play.start = qInfo.diskTime; /* remember restart point */
1209
1210 if (aztSendCmd(ACMD_PAUSE))
1211 RETURNM("aztcd_ioctl 8", -1);
1212 STEN_LOW_WAIT;
1213 aztAudioStatus = CDROM_AUDIO_PAUSED;
1214 break;
1215 case CDROMRESUME: /* Play it again, Sam */
1216 if (aztAudioStatus != CDROM_AUDIO_PAUSED)
1217 return -EINVAL;
1218 /* restart the drive at the saved position. */
1219 i = aztPlay(&azt_Play);
1220 if (i < 0) {
1221 aztAudioStatus = CDROM_AUDIO_ERROR;
1222 return -EIO;
1223 }
1224 aztAudioStatus = CDROM_AUDIO_PLAY;
1225 break;
1226 case CDROMMULTISESSION: /*multisession support -- experimental */
1227 {
1228 struct cdrom_multisession ms;
1229#ifdef AZT_DEBUG
1230 printk("aztcd ioctl MULTISESSION\n");
1231#endif
1232 if (copy_from_user(&ms, argp,
1233 sizeof(struct cdrom_multisession)))
1234 return -EFAULT;
1235 if (ms.addr_format == CDROM_MSF) {
1236 ms.addr.msf.minute =
1237 azt_bcd2bin(DiskInfo.lastSession.min);
1238 ms.addr.msf.second =
1239 azt_bcd2bin(DiskInfo.lastSession.sec);
1240 ms.addr.msf.frame =
1241 azt_bcd2bin(DiskInfo.lastSession.
1242 frame);
1243 } else if (ms.addr_format == CDROM_LBA)
1244 ms.addr.lba =
1245 azt_msf2hsg(&DiskInfo.lastSession);
1246 else
1247 return -EINVAL;
1248 ms.xa_flag = DiskInfo.xa;
1249 if (copy_to_user(argp, &ms,
1250 sizeof(struct cdrom_multisession)))
1251 return -EFAULT;
1252#ifdef AZT_DEBUG
1253 if (ms.addr_format == CDROM_MSF)
1254 printk
1255 ("aztcd multisession xa:%d, msf:%02x:%02x.%02x [%02x:%02x.%02x])\n",
1256 ms.xa_flag, ms.addr.msf.minute,
1257 ms.addr.msf.second, ms.addr.msf.frame,
1258 DiskInfo.lastSession.min,
1259 DiskInfo.lastSession.sec,
1260 DiskInfo.lastSession.frame);
1261 else
1262 printk
1263 ("aztcd multisession %d, lba:0x%08x [%02x:%02x.%02x])\n",
1264 ms.xa_flag, ms.addr.lba,
1265 DiskInfo.lastSession.min,
1266 DiskInfo.lastSession.sec,
1267 DiskInfo.lastSession.frame);
1268#endif
1269 return 0;
1270 }
1271 case CDROMPLAYTRKIND: /* Play a track. This currently ignores index. */
1272 if (copy_from_user(&ti, argp, sizeof ti))
1273 return -EFAULT;
1274 if (ti.cdti_trk0 < DiskInfo.first
1275 || ti.cdti_trk0 > DiskInfo.last
1276 || ti.cdti_trk1 < ti.cdti_trk0) {
1277 return -EINVAL;
1278 }
1279 if (ti.cdti_trk1 > DiskInfo.last)
1280 ti.cdti_trk1 = DiskInfo.last;
1281 azt_Play.start = Toc[ti.cdti_trk0].diskTime;
1282 azt_Play.end = Toc[ti.cdti_trk1 + 1].diskTime;
1283#ifdef AZT_DEBUG
1284 printk("aztcd play: %02x:%02x.%02x to %02x:%02x.%02x\n",
1285 azt_Play.start.min, azt_Play.start.sec,
1286 azt_Play.start.frame, azt_Play.end.min,
1287 azt_Play.end.sec, azt_Play.end.frame);
1288#endif
1289 i = aztPlay(&azt_Play);
1290 if (i < 0) {
1291 aztAudioStatus = CDROM_AUDIO_ERROR;
1292 return -EIO;
1293 }
1294 aztAudioStatus = CDROM_AUDIO_PLAY;
1295 break;
1296 case CDROMPLAYMSF: /* Play starting at the given MSF address. */
1297/* if (aztAudioStatus == CDROM_AUDIO_PLAY)
1298 { if (aztSendCmd(ACMD_STOP)) RETURNM("aztcd_ioctl 9",-1);
1299 STEN_LOW;
1300 aztAudioStatus = CDROM_AUDIO_NO_STATUS;
1301 }
1302*/
1303 if (copy_from_user(&msf, argp, sizeof msf))
1304 return -EFAULT;
1305 /* convert to bcd */
1306 azt_bin2bcd(&msf.cdmsf_min0);
1307 azt_bin2bcd(&msf.cdmsf_sec0);
1308 azt_bin2bcd(&msf.cdmsf_frame0);
1309 azt_bin2bcd(&msf.cdmsf_min1);
1310 azt_bin2bcd(&msf.cdmsf_sec1);
1311 azt_bin2bcd(&msf.cdmsf_frame1);
1312 azt_Play.start.min = msf.cdmsf_min0;
1313 azt_Play.start.sec = msf.cdmsf_sec0;
1314 azt_Play.start.frame = msf.cdmsf_frame0;
1315 azt_Play.end.min = msf.cdmsf_min1;
1316 azt_Play.end.sec = msf.cdmsf_sec1;
1317 azt_Play.end.frame = msf.cdmsf_frame1;
1318#ifdef AZT_DEBUG
1319 printk("aztcd play: %02x:%02x.%02x to %02x:%02x.%02x\n",
1320 azt_Play.start.min, azt_Play.start.sec,
1321 azt_Play.start.frame, azt_Play.end.min,
1322 azt_Play.end.sec, azt_Play.end.frame);
1323#endif
1324 i = aztPlay(&azt_Play);
1325 if (i < 0) {
1326 aztAudioStatus = CDROM_AUDIO_ERROR;
1327 return -EIO;
1328 }
1329 aztAudioStatus = CDROM_AUDIO_PLAY;
1330 break;
1331
1332 case CDROMREADTOCHDR: /* Read the table of contents header */
1333 tocHdr.cdth_trk0 = DiskInfo.first;
1334 tocHdr.cdth_trk1 = DiskInfo.last;
1335 if (copy_to_user(argp, &tocHdr, sizeof tocHdr))
1336 return -EFAULT;
1337 break;
1338 case CDROMREADTOCENTRY: /* Read an entry in the table of contents */
1339 if (copy_from_user(&entry, argp, sizeof entry))
1340 return -EFAULT;
1341 if ((!aztTocUpToDate) || aztDiskChanged)
1342 aztUpdateToc();
1343 if (entry.cdte_track == CDROM_LEADOUT)
1344 tocPtr = &Toc[DiskInfo.last + 1];
1345 else if (entry.cdte_track > DiskInfo.last
1346 || entry.cdte_track < DiskInfo.first) {
1347 return -EINVAL;
1348 } else
1349 tocPtr = &Toc[entry.cdte_track];
1350 entry.cdte_adr = tocPtr->ctrl_addr;
1351 entry.cdte_ctrl = tocPtr->ctrl_addr >> 4;
1352 if (entry.cdte_format == CDROM_LBA)
1353 entry.cdte_addr.lba =
1354 azt_msf2hsg(&tocPtr->diskTime);
1355 else if (entry.cdte_format == CDROM_MSF) {
1356 entry.cdte_addr.msf.minute =
1357 azt_bcd2bin(tocPtr->diskTime.min);
1358 entry.cdte_addr.msf.second =
1359 azt_bcd2bin(tocPtr->diskTime.sec);
1360 entry.cdte_addr.msf.frame =
1361 azt_bcd2bin(tocPtr->diskTime.frame);
1362 } else {
1363 return -EINVAL;
1364 }
1365 if (copy_to_user(argp, &entry, sizeof entry))
1366 return -EFAULT;
1367 break;
1368 case CDROMSUBCHNL: /* Get subchannel info */
1369 if (copy_from_user
1370 (&subchnl, argp, sizeof(struct cdrom_subchnl)))
1371 return -EFAULT;
1372 if (aztGetQChannelInfo(&qInfo) < 0) {
1373#ifdef AZT_DEBUG
1374 printk
1375 ("aztcd: exiting aztcd_ioctl - Error 3 - Command:%x\n",
1376 cmd);
1377#endif
1378 return -EIO;
1379 }
1380 subchnl.cdsc_audiostatus = aztAudioStatus;
1381 subchnl.cdsc_adr = qInfo.ctrl_addr;
1382 subchnl.cdsc_ctrl = qInfo.ctrl_addr >> 4;
1383 subchnl.cdsc_trk = azt_bcd2bin(qInfo.track);
1384 subchnl.cdsc_ind = azt_bcd2bin(qInfo.pointIndex);
1385 if (subchnl.cdsc_format == CDROM_LBA) {
1386 subchnl.cdsc_absaddr.lba =
1387 azt_msf2hsg(&qInfo.diskTime);
1388 subchnl.cdsc_reladdr.lba =
1389 azt_msf2hsg(&qInfo.trackTime);
1390 } else { /*default */
1391 subchnl.cdsc_format = CDROM_MSF;
1392 subchnl.cdsc_absaddr.msf.minute =
1393 azt_bcd2bin(qInfo.diskTime.min);
1394 subchnl.cdsc_absaddr.msf.second =
1395 azt_bcd2bin(qInfo.diskTime.sec);
1396 subchnl.cdsc_absaddr.msf.frame =
1397 azt_bcd2bin(qInfo.diskTime.frame);
1398 subchnl.cdsc_reladdr.msf.minute =
1399 azt_bcd2bin(qInfo.trackTime.min);
1400 subchnl.cdsc_reladdr.msf.second =
1401 azt_bcd2bin(qInfo.trackTime.sec);
1402 subchnl.cdsc_reladdr.msf.frame =
1403 azt_bcd2bin(qInfo.trackTime.frame);
1404 }
1405 if (copy_to_user(argp, &subchnl, sizeof(struct cdrom_subchnl)))
1406 return -EFAULT;
1407 break;
1408 case CDROMVOLCTRL: /* Volume control
1409 * With my Aztech CD268-01A volume control does not work, I can only
1410 turn the channels on (any value !=0) or off (value==0). Maybe it
1411 works better with your drive */
1412 if (copy_from_user(&volctrl, argp, sizeof(volctrl)))
1413 return -EFAULT;
1414 azt_Play.start.min = 0x21;
1415 azt_Play.start.sec = 0x84;
1416 azt_Play.start.frame = volctrl.channel0;
1417 azt_Play.end.min = volctrl.channel1;
1418 azt_Play.end.sec = volctrl.channel2;
1419 azt_Play.end.frame = volctrl.channel3;
1420 sendAztCmd(ACMD_SET_VOLUME, &azt_Play);
1421 STEN_LOW_WAIT;
1422 break;
1423 case CDROMEJECT:
1424 aztUnlockDoor(); /* Assume user knows what they're doing */
1425 /* all drives can at least stop! */
1426 if (aztAudioStatus == CDROM_AUDIO_PLAY) {
1427 if (aztSendCmd(ACMD_STOP))
1428 RETURNM("azt_ioctl 10", -1);
1429 STEN_LOW_WAIT;
1430 }
1431 if (aztSendCmd(ACMD_EJECT))
1432 RETURNM("azt_ioctl 11", -1);
1433 STEN_LOW_WAIT;
1434 aztAudioStatus = CDROM_AUDIO_NO_STATUS;
1435 break;
1436 case CDROMEJECT_SW:
1437 azt_auto_eject = (char) arg;
1438 break;
1439 case CDROMRESET:
1440 outb(ACMD_SOFT_RESET, CMD_PORT); /*send reset */
1441 STEN_LOW;
1442 if (inb(DATA_PORT) != AFL_OP_OK) { /*OP_OK? */
1443 printk
1444 ("aztcd: AZTECH CD-ROM drive does not respond\n");
1445 }
1446 break;
1447/*Take care, the following code is not compatible with other CD-ROM drivers,
1448 use it at your own risk with cdplay.c. Set AZT_PRIVATE_IOCTLS to 0 in aztcd.h,
1449 if you do not want to use it!
1450*/
1451#if AZT_PRIVATE_IOCTLS
1452 case CDROMREADCOOKED: /*read data in mode 1 (2048 Bytes) */
1453 case CDROMREADRAW: /*read data in mode 2 (2336 Bytes) */
1454 {
1455 if (copy_from_user(&msf, argp, sizeof msf))
1456 return -EFAULT;
1457 /* convert to bcd */
1458 azt_bin2bcd(&msf.cdmsf_min0);
1459 azt_bin2bcd(&msf.cdmsf_sec0);
1460 azt_bin2bcd(&msf.cdmsf_frame0);
1461 msf.cdmsf_min1 = 0;
1462 msf.cdmsf_sec1 = 0;
1463 msf.cdmsf_frame1 = 1; /*read only one frame */
1464 azt_Play.start.min = msf.cdmsf_min0;
1465 azt_Play.start.sec = msf.cdmsf_sec0;
1466 azt_Play.start.frame = msf.cdmsf_frame0;
1467 azt_Play.end.min = msf.cdmsf_min1;
1468 azt_Play.end.sec = msf.cdmsf_sec1;
1469 azt_Play.end.frame = msf.cdmsf_frame1;
1470 if (cmd == CDROMREADRAW) {
1471 if (DiskInfo.xa) {
1472 return -1; /*XA Disks can't be read raw */
1473 } else {
1474 if (sendAztCmd(ACMD_PLAY_READ_RAW, &azt_Play))
1475 return -1;
1476 DTEN_LOW;
1477 insb(DATA_PORT, buf, CD_FRAMESIZE_RAW);
1478 if (copy_to_user(argp, &buf, CD_FRAMESIZE_RAW))
1479 return -EFAULT;
1480 }
1481 } else
1482 /*CDROMREADCOOKED*/ {
1483 if (sendAztCmd(ACMD_PLAY_READ, &azt_Play))
1484 return -1;
1485 DTEN_LOW;
1486 insb(DATA_PORT, buf, CD_FRAMESIZE);
1487 if (copy_to_user(argp, &buf, CD_FRAMESIZE))
1488 return -EFAULT;
1489 }
1490 }
1491 break;
1492 case CDROMSEEK: /*seek msf address */
1493 if (copy_from_user(&msf, argp, sizeof msf))
1494 return -EFAULT;
1495 /* convert to bcd */
1496 azt_bin2bcd(&msf.cdmsf_min0);
1497 azt_bin2bcd(&msf.cdmsf_sec0);
1498 azt_bin2bcd(&msf.cdmsf_frame0);
1499 azt_Play.start.min = msf.cdmsf_min0;
1500 azt_Play.start.sec = msf.cdmsf_sec0;
1501 azt_Play.start.frame = msf.cdmsf_frame0;
1502 if (aztSeek(&azt_Play))
1503 return -1;
1504 break;
1505#endif /*end of incompatible code */
1506 case CDROMREADMODE1: /*set read data in mode 1 */
1507 return aztSetDiskType(AZT_MODE_1);
1508 case CDROMREADMODE2: /*set read data in mode 2 */
1509 return aztSetDiskType(AZT_MODE_2);
1510 default:
1511 return -EINVAL;
1512 }
1513#ifdef AZT_DEBUG
1514 printk("aztcd: exiting aztcd_ioctl Command:%x Time:%li\n", cmd,
1515 jiffies);
1516#endif
1517 return 0;
1518}
1519
1520/*
1521 * Take care of the different block sizes between cdrom and Linux.
1522 * When Linux gets variable block sizes this will probably go away.
1523 */
1524static void azt_transfer(void)
1525{
1526#ifdef AZT_TEST
1527 printk("aztcd: executing azt_transfer Time:%li\n", jiffies);
1528#endif
1529 if (!current_valid())
1530 return;
1531
1532 while (CURRENT->nr_sectors) {
1533 int bn = CURRENT->sector / 4;
1534 int i;
1535 for (i = 0; i < AZT_BUF_SIZ && azt_buf_bn[i] != bn; ++i);
1536 if (i < AZT_BUF_SIZ) {
1537 int offs = (i * 4 + (CURRENT->sector & 3)) * 512;
1538 int nr_sectors = 4 - (CURRENT->sector & 3);
1539 if (azt_buf_out != i) {
1540 azt_buf_out = i;
1541 if (azt_buf_bn[i] != bn) {
1542 azt_buf_out = -1;
1543 continue;
1544 }
1545 }
1546 if (nr_sectors > CURRENT->nr_sectors)
1547 nr_sectors = CURRENT->nr_sectors;
1548 memcpy(CURRENT->buffer, azt_buf + offs,
1549 nr_sectors * 512);
1550 CURRENT->nr_sectors -= nr_sectors;
1551 CURRENT->sector += nr_sectors;
1552 CURRENT->buffer += nr_sectors * 512;
1553 } else {
1554 azt_buf_out = -1;
1555 break;
1556 }
1557 }
1558}
1559
1560static void do_aztcd_request(request_queue_t * q)
1561{
1562#ifdef AZT_TEST
1563 printk(" do_aztcd_request(%ld+%ld) Time:%li\n", CURRENT->sector,
1564 CURRENT->nr_sectors, jiffies);
1565#endif
1566 if (DiskInfo.audio) {
1567 printk("aztcd: Error, tried to mount an Audio CD\n");
1568 end_request(CURRENT, 0);
1569 return;
1570 }
1571 azt_transfer_is_active = 1;
1572 while (current_valid()) {
1573 azt_transfer();
1574 if (CURRENT->nr_sectors == 0) {
1575 end_request(CURRENT, 1);
1576 } else {
1577 azt_buf_out = -1; /* Want to read a block not in buffer */
1578 if (azt_state == AZT_S_IDLE) {
1579 if ((!aztTocUpToDate) || aztDiskChanged) {
1580 if (aztUpdateToc() < 0) {
1581 while (current_valid())
1582 end_request(CURRENT, 0);
1583 break;
1584 }
1585 }
1586 azt_state = AZT_S_START;
1587 AztTries = 5;
1588 SET_TIMER(azt_poll, HZ / 100);
1589 }
1590 break;
1591 }
1592 }
1593 azt_transfer_is_active = 0;
1594#ifdef AZT_TEST2
1595 printk
1596 ("azt_next_bn:%x azt_buf_in:%x azt_buf_out:%x azt_buf_bn:%x\n",
1597 azt_next_bn, azt_buf_in, azt_buf_out, azt_buf_bn[azt_buf_in]);
1598 printk(" do_aztcd_request ends Time:%li\n", jiffies);
1599#endif
1600}
1601
1602
1603static void azt_invalidate_buffers(void)
1604{
1605 int i;
1606
1607#ifdef AZT_DEBUG
1608 printk("aztcd: executing azt_invalidate_buffers\n");
1609#endif
1610 for (i = 0; i < AZT_BUF_SIZ; ++i)
1611 azt_buf_bn[i] = -1;
1612 azt_buf_out = -1;
1613}
1614
1615/*
1616 * Open the device special file. Check that a disk is in.
1617 */
1618static int aztcd_open(struct inode *ip, struct file *fp)
1619{
1620 int st;
1621
1622#ifdef AZT_DEBUG
1623 printk("aztcd: starting aztcd_open\n");
1624#endif
1625
1626 if (aztPresent == 0)
1627 return -ENXIO; /* no hardware */
1628
1629 if (!azt_open_count && azt_state == AZT_S_IDLE) {
1630 azt_invalidate_buffers();
1631
1632 st = getAztStatus(); /* check drive status */
1633 if (st == -1)
1634 goto err_out; /* drive doesn't respond */
1635
1636 if (st & AST_DOOR_OPEN) { /* close door, then get the status again. */
1637 printk("aztcd: Door Open?\n");
1638 aztCloseDoor();
1639 st = getAztStatus();
1640 }
1641
1642 if ((st & AST_NOT_READY) || (st & AST_DSK_CHG)) { /*no disk in drive or changed */
1643 printk
1644 ("aztcd: Disk Changed or No Disk in Drive?\n");
1645 aztTocUpToDate = 0;
1646 }
1647 if (aztUpdateToc())
1648 goto err_out;
1649
1650 }
1651 ++azt_open_count;
1652 aztLockDoor();
1653
1654#ifdef AZT_DEBUG
1655 printk("aztcd: exiting aztcd_open\n");
1656#endif
1657 return 0;
1658
1659 err_out:
1660 return -EIO;
1661}
1662
1663
1664/*
1665 * On close, we flush all azt blocks from the buffer cache.
1666 */
1667static int aztcd_release(struct inode *inode, struct file *file)
1668{
1669#ifdef AZT_DEBUG
1670 printk("aztcd: executing aztcd_release\n");
1671 printk("inode: %p, device: %s file: %p\n", inode,
1672 inode->i_bdev->bd_disk->disk_name, file);
1673#endif
1674 if (!--azt_open_count) {
1675 azt_invalidate_buffers();
1676 aztUnlockDoor();
1677 if (azt_auto_eject)
1678 aztSendCmd(ACMD_EJECT);
1679 CLEAR_TIMER;
1680 }
1681 return 0;
1682}
1683
1684static struct gendisk *azt_disk;
1685
1686/*
1687 * Test for presence of drive and initialize it. Called at boot time.
1688 */
1689
1690static int __init aztcd_init(void)
1691{
1692 long int count, max_count;
1693 unsigned char result[50];
1694 int st;
1695 void* status = NULL;
1696 int i = 0;
1697 int ret = 0;
1698
1699 if (azt_port == 0) {
1700 printk(KERN_INFO "aztcd: no Aztech CD-ROM Initialization");
1701 return -EIO;
1702 }
1703
1704 printk(KERN_INFO "aztcd: AZTECH, ORCHID, OKANO, WEARNES, TXC, CyDROM "
1705 "CD-ROM Driver\n");
1706 printk(KERN_INFO "aztcd: (C) 1994-98 W.Zimmermann\n");
1707 if (azt_port == -1) {
1708 printk
1709 ("aztcd: DriverVersion=%s For IDE/ATAPI-drives use ide-cd.c\n",
1710 AZT_VERSION);
1711 } else
1712 printk
1713 ("aztcd: DriverVersion=%s BaseAddress=0x%x For IDE/ATAPI-drives use ide-cd.c\n",
1714 AZT_VERSION, azt_port);
1715 printk(KERN_INFO "aztcd: If you have problems, read /usr/src/linux/"
1716 "Documentation/cdrom/aztcd\n");
1717
1718
1719#ifdef AZT_SW32 /*CDROM connected to Soundwave32 card */
1720 if ((0xFF00 & inw(AZT_SW32_ID_REG)) != 0x4500) {
1721 printk
1722 ("aztcd: no Soundwave32 card detected at base:%x init:%x config:%x id:%x\n",
1723 AZT_SW32_BASE_ADDR, AZT_SW32_INIT,
1724 AZT_SW32_CONFIG_REG, AZT_SW32_ID_REG);
1725 return -EIO;
1726 } else {
1727 printk(KERN_INFO
1728 "aztcd: Soundwave32 card detected at %x Version %x\n",
1729 AZT_SW32_BASE_ADDR, inw(AZT_SW32_ID_REG));
1730 outw(AZT_SW32_INIT, AZT_SW32_CONFIG_REG);
1731 for (count = 0; count < 10000; count++); /*delay a bit */
1732 }
1733#endif
1734
1735 /* check for presence of drive */
1736
1737 if (azt_port == -1) { /* autoprobing for proprietary interface */
1738 for (i = 0; (azt_port_auto[i] != 0) && (i < 16); i++) {
1739 azt_port = azt_port_auto[i];
1740 printk(KERN_INFO "aztcd: Autoprobing BaseAddress=0x%x"
1741 "\n", azt_port);
1742 /*proprietary interfaces need 4 bytes */
1743 if (!request_region(azt_port, 4, "aztcd")) {
1744 continue;
1745 }
1746 outb(POLLED, MODE_PORT);
1747 inb(CMD_PORT);
1748 inb(CMD_PORT);
1749 outb(ACMD_GET_VERSION, CMD_PORT); /*Try to get version info */
1750
1751 aztTimeOutCount = 0;
1752 do {
1753 aztIndatum = inb(STATUS_PORT);
1754 aztTimeOutCount++;
1755 if (aztTimeOutCount >= AZT_FAST_TIMEOUT)
1756 break;
1757 } while (aztIndatum & AFL_STATUS);
1758 if (inb(DATA_PORT) == AFL_OP_OK) { /* OK drive found */
1759 break;
1760 }
1761 else { /* Drive not found on this port - try next one */
1762 release_region(azt_port, 4);
1763 }
1764 }
1765 if ((i == 16) || (azt_port_auto[i] == 0)) {
1766 printk(KERN_INFO "aztcd: no AZTECH CD-ROM drive found\n");
1767 return -EIO;
1768 }
1769 } else { /* no autoprobing */
1770 if ((azt_port == 0x1f0) || (azt_port == 0x170))
1771 status = request_region(azt_port, 8, "aztcd"); /*IDE-interfaces need 8 bytes */
1772 else
1773 status = request_region(azt_port, 4, "aztcd"); /*proprietary interfaces need 4 bytes */
1774 if (!status) {
1775 printk(KERN_WARNING "aztcd: conflict, I/O port (%X) "
1776 "already used\n", azt_port);
1777 return -EIO;
1778 }
1779
1780 if ((azt_port == 0x1f0) || (azt_port == 0x170))
1781 SWITCH_IDE_SLAVE; /*switch IDE interface to slave configuration */
1782
1783 outb(POLLED, MODE_PORT);
1784 inb(CMD_PORT);
1785 inb(CMD_PORT);
1786 outb(ACMD_GET_VERSION, CMD_PORT); /*Try to get version info */
1787
1788 aztTimeOutCount = 0;
1789 do {
1790 aztIndatum = inb(STATUS_PORT);
1791 aztTimeOutCount++;
1792 if (aztTimeOutCount >= AZT_FAST_TIMEOUT)
1793 break;
1794 } while (aztIndatum & AFL_STATUS);
1795
1796 if (inb(DATA_PORT) != AFL_OP_OK) { /*OP_OK? If not, reset and try again */
1797#ifndef MODULE
1798 if (azt_cont != 0x79) {
1799 printk(KERN_WARNING "aztcd: no AZTECH CD-ROM "
1800 "drive found-Try boot parameter aztcd="
1801 "<BaseAddress>,0x79\n");
1802 ret = -EIO;
1803 goto err_out;
1804 }
1805#else
1806 if (0) {
1807 }
1808#endif
1809 else {
1810 printk(KERN_INFO "aztcd: drive reset - "
1811 "please wait\n");
1812 for (count = 0; count < 50; count++) {
1813 inb(STATUS_PORT); /*removing all data from earlier tries */
1814 inb(DATA_PORT);
1815 }
1816 outb(POLLED, MODE_PORT);
1817 inb(CMD_PORT);
1818 inb(CMD_PORT);
1819 getAztStatus(); /*trap errors */
1820 outb(ACMD_SOFT_RESET, CMD_PORT); /*send reset */
1821 STEN_LOW;
1822 if (inb(DATA_PORT) != AFL_OP_OK) { /*OP_OK? */
1823 printk(KERN_WARNING "aztcd: no AZTECH "
1824 "CD-ROM drive found\n");
1825 ret = -EIO;
1826 goto err_out;
1827 }
1828
1829 for (count = 0; count < AZT_TIMEOUT;
1830 count++)
1831 barrier(); /* Stop gcc 2.96 being smart */
1832 /* use udelay(), damnit -- AV */
1833
1834 if ((st = getAztStatus()) == -1) {
1835 printk(KERN_WARNING "aztcd: Drive Status"
1836 " Error Status=%x\n", st);
1837 ret = -EIO;
1838 goto err_out;
1839 }
1840#ifdef AZT_DEBUG
1841 printk(KERN_DEBUG "aztcd: Status = %x\n", st);
1842#endif
1843 outb(POLLED, MODE_PORT);
1844 inb(CMD_PORT);
1845 inb(CMD_PORT);
1846 outb(ACMD_GET_VERSION, CMD_PORT); /*GetVersion */
1847 STEN_LOW;
1848 OP_OK;
1849 }
1850 }
1851 }
1852
1853 azt_init_end = 1;
1854 STEN_LOW;
1855 result[0] = inb(DATA_PORT); /*reading in a null byte??? */
1856 for (count = 1; count < 50; count++) { /*Reading version string */
1857 aztTimeOutCount = 0; /*here we must implement STEN_LOW differently */
1858 do {
1859 aztIndatum = inb(STATUS_PORT); /*because we want to exit by timeout */
1860 aztTimeOutCount++;
1861 if (aztTimeOutCount >= AZT_FAST_TIMEOUT)
1862 break;
1863 } while (aztIndatum & AFL_STATUS);
1864 if (aztTimeOutCount >= AZT_FAST_TIMEOUT)
1865 break; /*all chars read? */
1866 result[count] = inb(DATA_PORT);
1867 }
1868 if (count > 30)
1869 max_count = 30; /*print max.30 chars of the version string */
1870 else
1871 max_count = count;
1872 printk(KERN_INFO "aztcd: FirmwareVersion=");
1873 for (count = 1; count < max_count; count++)
1874 printk("%c", result[count]);
1875 printk("<<>> ");
1876
1877 if ((result[1] == 'A') && (result[2] == 'Z') && (result[3] == 'T')) {
1878 printk("AZTECH drive detected\n");
1879 /*AZTECH*/}
1880 else if ((result[2] == 'C') && (result[3] == 'D')
1881 && (result[4] == 'D')) {
1882 printk("ORCHID or WEARNES drive detected\n"); /*ORCHID or WEARNES */
1883 } else if ((result[1] == 0x03) && (result[2] == '5')) {
1884 printk("TXC or CyCDROM drive detected\n"); /*Conrad TXC, CyCDROM */
1885 } else { /*OTHERS or none */
1886 printk("\nunknown drive or firmware version detected\n");
1887 printk
1888 ("aztcd may not run stable, if you want to try anyhow,\n");
1889 printk("boot with: aztcd=<BaseAddress>,0x79\n");
1890 if ((azt_cont != 0x79)) {
1891 printk("aztcd: FirmwareVersion=");
1892 for (count = 1; count < 5; count++)
1893 printk("%c", result[count]);
1894 printk("<<>> ");
1895 printk("Aborted\n");
1896 ret = -EIO;
1897 goto err_out;
1898 }
1899 }
1900 azt_disk = alloc_disk(1);
1901 if (!azt_disk)
1902 goto err_out;
1903
1904 if (register_blkdev(MAJOR_NR, "aztcd")) {
1905 ret = -EIO;
1906 goto err_out2;
1907 }
1908
1909 azt_queue = blk_init_queue(do_aztcd_request, &aztSpin);
1910 if (!azt_queue) {
1911 ret = -ENOMEM;
1912 goto err_out3;
1913 }
1914
1915 blk_queue_hardsect_size(azt_queue, 2048);
1916 azt_disk->major = MAJOR_NR;
1917 azt_disk->first_minor = 0;
1918 azt_disk->fops = &azt_fops;
1919 sprintf(azt_disk->disk_name, "aztcd");
1920 azt_disk->queue = azt_queue;
1921 add_disk(azt_disk);
1922 azt_invalidate_buffers();
1923 aztPresent = 1;
1924 aztCloseDoor();
1925 return 0;
1926err_out3:
1927 unregister_blkdev(MAJOR_NR, "aztcd");
1928err_out2:
1929 put_disk(azt_disk);
1930err_out:
1931 if ((azt_port == 0x1f0) || (azt_port == 0x170)) {
1932 SWITCH_IDE_MASTER;
1933 release_region(azt_port, 8); /*IDE-interface */
1934 } else
1935 release_region(azt_port, 4); /*proprietary interface */
1936 return ret;
1937
1938}
1939
1940static void __exit aztcd_exit(void)
1941{
1942 del_gendisk(azt_disk);
1943 put_disk(azt_disk);
1944 if ((unregister_blkdev(MAJOR_NR, "aztcd") == -EINVAL)) {
1945 printk("What's that: can't unregister aztcd\n");
1946 return;
1947 }
1948 blk_cleanup_queue(azt_queue);
1949 if ((azt_port == 0x1f0) || (azt_port == 0x170)) {
1950 SWITCH_IDE_MASTER;
1951 release_region(azt_port, 8); /*IDE-interface */
1952 } else
1953 release_region(azt_port, 4); /*proprietary interface */
1954 printk(KERN_INFO "aztcd module released.\n");
1955}
1956
1957module_init(aztcd_init);
1958module_exit(aztcd_exit);
1959
1960/*##########################################################################
1961 Aztcd State Machine: Controls Drive Operating State
1962 ##########################################################################
1963*/
1964static void azt_poll(void)
1965{
1966 int st = 0;
1967 int loop_ctl = 1;
1968 int skip = 0;
1969
1970 if (azt_error) {
1971 if (aztSendCmd(ACMD_GET_ERROR))
1972 RETURN("azt_poll 1");
1973 STEN_LOW;
1974 azt_error = inb(DATA_PORT) & 0xFF;
1975 printk("aztcd: I/O error 0x%02x\n", azt_error);
1976 azt_invalidate_buffers();
1977#ifdef WARN_IF_READ_FAILURE
1978 if (AztTries == 5)
1979 printk
1980 ("aztcd: Read of Block %d Failed - Maybe Audio Disk?\n",
1981 azt_next_bn);
1982#endif
1983 if (!AztTries--) {
1984 printk
1985 ("aztcd: Read of Block %d Failed, Maybe Audio Disk? Giving up\n",
1986 azt_next_bn);
1987 if (azt_transfer_is_active) {
1988 AztTries = 0;
1989 loop_ctl = 0;
1990 }
1991 if (current_valid())
1992 end_request(CURRENT, 0);
1993 AztTries = 5;
1994 }
1995 azt_error = 0;
1996 azt_state = AZT_S_STOP;
1997 }
1998
1999 while (loop_ctl) {
2000 loop_ctl = 0; /* each case must flip this back to 1 if we want
2001 to come back up here */
2002 switch (azt_state) {
2003
2004 case AZT_S_IDLE:
2005#ifdef AZT_TEST3
2006 if (azt_state != azt_state_old) {
2007 azt_state_old = azt_state;
2008 printk("AZT_S_IDLE\n");
2009 }
2010#endif
2011 return;
2012
2013 case AZT_S_START:
2014#ifdef AZT_TEST3
2015 if (azt_state != azt_state_old) {
2016 azt_state_old = azt_state;
2017 printk("AZT_S_START\n");
2018 }
2019#endif
2020 if (aztSendCmd(ACMD_GET_STATUS))
2021 RETURN("azt_poll 2"); /*result will be checked by aztStatus() */
2022 azt_state =
2023 azt_mode == 1 ? AZT_S_READ : AZT_S_MODE;
2024 AztTimeout = 3000;
2025 break;
2026
2027 case AZT_S_MODE:
2028#ifdef AZT_TEST3
2029 if (azt_state != azt_state_old) {
2030 azt_state_old = azt_state;
2031 printk("AZT_S_MODE\n");
2032 }
2033#endif
2034 if (!skip) {
2035 if ((st = aztStatus()) != -1) {
2036 if ((st & AST_DSK_CHG)
2037 || (st & AST_NOT_READY)) {
2038 aztDiskChanged = 1;
2039 aztTocUpToDate = 0;
2040 azt_invalidate_buffers();
2041 end_request(CURRENT, 0);
2042 printk
2043 ("aztcd: Disk Changed or Not Ready 1 - Unmount Disk!\n");
2044 }
2045 } else
2046 break;
2047 }
2048 skip = 0;
2049
2050 if ((st & AST_DOOR_OPEN) || (st & AST_NOT_READY)) {
2051 aztDiskChanged = 1;
2052 aztTocUpToDate = 0;
2053 printk
2054 ("aztcd: Disk Changed or Not Ready 2 - Unmount Disk!\n");
2055 end_request(CURRENT, 0);
2056 printk((st & AST_DOOR_OPEN) ?
2057 "aztcd: door open\n" :
2058 "aztcd: disk removed\n");
2059 if (azt_transfer_is_active) {
2060 azt_state = AZT_S_START;
2061 loop_ctl = 1; /* goto immediately */
2062 break;
2063 }
2064 azt_state = AZT_S_IDLE;
2065 while (current_valid())
2066 end_request(CURRENT, 0);
2067 return;
2068 }
2069
2070/* if (aztSendCmd(ACMD_SET_MODE)) RETURN("azt_poll 3");
2071 outb(0x01, DATA_PORT);
2072 PA_OK;
2073 STEN_LOW;
2074*/
2075 if (aztSendCmd(ACMD_GET_STATUS))
2076 RETURN("azt_poll 4");
2077 STEN_LOW;
2078 azt_mode = 1;
2079 azt_state = AZT_S_READ;
2080 AztTimeout = 3000;
2081
2082 break;
2083
2084
2085 case AZT_S_READ:
2086#ifdef AZT_TEST3
2087 if (azt_state != azt_state_old) {
2088 azt_state_old = azt_state;
2089 printk("AZT_S_READ\n");
2090 }
2091#endif
2092 if (!skip) {
2093 if ((st = aztStatus()) != -1) {
2094 if ((st & AST_DSK_CHG)
2095 || (st & AST_NOT_READY)) {
2096 aztDiskChanged = 1;
2097 aztTocUpToDate = 0;
2098 azt_invalidate_buffers();
2099 printk
2100 ("aztcd: Disk Changed or Not Ready 3 - Unmount Disk!\n");
2101 end_request(CURRENT, 0);
2102 }
2103 } else
2104 break;
2105 }
2106
2107 skip = 0;
2108 if ((st & AST_DOOR_OPEN) || (st & AST_NOT_READY)) {
2109 aztDiskChanged = 1;
2110 aztTocUpToDate = 0;
2111 printk((st & AST_DOOR_OPEN) ?
2112 "aztcd: door open\n" :
2113 "aztcd: disk removed\n");
2114 if (azt_transfer_is_active) {
2115 azt_state = AZT_S_START;
2116 loop_ctl = 1;
2117 break;
2118 }
2119 azt_state = AZT_S_IDLE;
2120 while (current_valid())
2121 end_request(CURRENT, 0);
2122 return;
2123 }
2124
2125 if (current_valid()) {
2126 struct azt_Play_msf msf;
2127 int i;
2128 azt_next_bn = CURRENT->sector / 4;
2129 azt_hsg2msf(azt_next_bn, &msf.start);
2130 i = 0;
2131 /* find out in which track we are */
2132 while (azt_msf2hsg(&msf.start) >
2133 azt_msf2hsg(&Toc[++i].trackTime)) {
2134 };
2135 if (azt_msf2hsg(&msf.start) <
2136 azt_msf2hsg(&Toc[i].trackTime) -
2137 AZT_BUF_SIZ) {
2138 azt_read_count = AZT_BUF_SIZ; /*fast, because we read ahead */
2139 /*azt_read_count=CURRENT->nr_sectors; slow, no read ahead */
2140 } else /* don't read beyond end of track */
2141#if AZT_MULTISESSION
2142 {
2143 azt_read_count =
2144 (azt_msf2hsg(&Toc[i].trackTime)
2145 / 4) * 4 -
2146 azt_msf2hsg(&msf.start);
2147 if (azt_read_count < 0)
2148 azt_read_count = 0;
2149 if (azt_read_count > AZT_BUF_SIZ)
2150 azt_read_count =
2151 AZT_BUF_SIZ;
2152 printk
2153 ("aztcd: warning - trying to read beyond end of track\n");
2154/* printk("%i %i %li %li\n",i,azt_read_count,azt_msf2hsg(&msf.start),azt_msf2hsg(&Toc[i].trackTime));
2155*/ }
2156#else
2157 {
2158 azt_read_count = AZT_BUF_SIZ;
2159 }
2160#endif
2161 msf.end.min = 0;
2162 msf.end.sec = 0;
2163 msf.end.frame = azt_read_count; /*Mitsumi here reads 0xffffff sectors */
2164#ifdef AZT_TEST3
2165 printk
2166 ("---reading msf-address %x:%x:%x %x:%x:%x\n",
2167 msf.start.min, msf.start.sec,
2168 msf.start.frame, msf.end.min,
2169 msf.end.sec, msf.end.frame);
2170 printk
2171 ("azt_next_bn:%x azt_buf_in:%x azt_buf_out:%x azt_buf_bn:%x\n",
2172 azt_next_bn, azt_buf_in, azt_buf_out,
2173 azt_buf_bn[azt_buf_in]);
2174#endif
2175 if (azt_read_mode == AZT_MODE_2) {
2176 sendAztCmd(ACMD_PLAY_READ_RAW, &msf); /*XA disks in raw mode */
2177 } else {
2178 sendAztCmd(ACMD_PLAY_READ, &msf); /*others in cooked mode */
2179 }
2180 azt_state = AZT_S_DATA;
2181 AztTimeout = READ_TIMEOUT;
2182 } else {
2183 azt_state = AZT_S_STOP;
2184 loop_ctl = 1;
2185 break;
2186 }
2187
2188 break;
2189
2190
2191 case AZT_S_DATA:
2192#ifdef AZT_TEST3
2193 if (azt_state != azt_state_old) {
2194 azt_state_old = azt_state;
2195 printk("AZT_S_DATA\n");
2196 }
2197#endif
2198
2199 st = inb(STATUS_PORT) & AFL_STATUSorDATA;
2200
2201 switch (st) {
2202
2203 case AFL_DATA:
2204#ifdef AZT_TEST3
2205 if (st != azt_st_old) {
2206 azt_st_old = st;
2207 printk("---AFL_DATA st:%x\n", st);
2208 }
2209#endif
2210 if (!AztTries--) {
2211 printk
2212 ("aztcd: Read of Block %d Failed, Maybe Audio Disk ? Giving up\n",
2213 azt_next_bn);
2214 if (azt_transfer_is_active) {
2215 AztTries = 0;
2216 break;
2217 }
2218 if (current_valid())
2219 end_request(CURRENT, 0);
2220 AztTries = 5;
2221 }
2222 azt_state = AZT_S_START;
2223 AztTimeout = READ_TIMEOUT;
2224 loop_ctl = 1;
2225 break;
2226
2227 case AFL_STATUSorDATA:
2228#ifdef AZT_TEST3
2229 if (st != azt_st_old) {
2230 azt_st_old = st;
2231 printk
2232 ("---AFL_STATUSorDATA st:%x\n",
2233 st);
2234 }
2235#endif
2236 break;
2237
2238 default:
2239#ifdef AZT_TEST3
2240 if (st != azt_st_old) {
2241 azt_st_old = st;
2242 printk("---default: st:%x\n", st);
2243 }
2244#endif
2245 AztTries = 5;
2246 if (!current_valid() && azt_buf_in == azt_buf_out) {
2247 azt_state = AZT_S_STOP;
2248 loop_ctl = 1;
2249 break;
2250 }
2251 if (azt_read_count <= 0)
2252 printk
2253 ("aztcd: warning - try to read 0 frames\n");
2254 while (azt_read_count) { /*??? fast read ahead loop */
2255 azt_buf_bn[azt_buf_in] = -1;
2256 DTEN_LOW; /*??? unsolved problem, very
2257 seldom we get timeouts
2258 here, don't now the real
2259 reason. With my drive this
2260 sometimes also happens with
2261 Aztech's original driver under
2262 DOS. Is it a hardware bug?
2263 I tried to recover from such
2264 situations here. Zimmermann */
2265 if (aztTimeOutCount >= AZT_TIMEOUT) {
2266 printk
2267 ("read_count:%d CURRENT->nr_sectors:%ld azt_buf_in:%d\n",
2268 azt_read_count,
2269 CURRENT->nr_sectors,
2270 azt_buf_in);
2271 printk
2272 ("azt_transfer_is_active:%x\n",
2273 azt_transfer_is_active);
2274 azt_read_count = 0;
2275 azt_state = AZT_S_STOP;
2276 loop_ctl = 1;
2277 end_request(CURRENT, 1); /*should we have here (1) or (0)? */
2278 } else {
2279 if (azt_read_mode ==
2280 AZT_MODE_2) {
2281 insb(DATA_PORT,
2282 azt_buf +
2283 CD_FRAMESIZE_RAW
2284 * azt_buf_in,
2285 CD_FRAMESIZE_RAW);
2286 } else {
2287 insb(DATA_PORT,
2288 azt_buf +
2289 CD_FRAMESIZE *
2290 azt_buf_in,
2291 CD_FRAMESIZE);
2292 }
2293 azt_read_count--;
2294#ifdef AZT_TEST3
2295 printk
2296 ("AZT_S_DATA; ---I've read data- read_count: %d\n",
2297 azt_read_count);
2298 printk
2299 ("azt_next_bn:%d azt_buf_in:%d azt_buf_out:%d azt_buf_bn:%d\n",
2300 azt_next_bn,
2301 azt_buf_in,
2302 azt_buf_out,
2303 azt_buf_bn
2304 [azt_buf_in]);
2305#endif
2306 azt_buf_bn[azt_buf_in] =
2307 azt_next_bn++;
2308 if (azt_buf_out == -1)
2309 azt_buf_out =
2310 azt_buf_in;
2311 azt_buf_in =
2312 azt_buf_in + 1 ==
2313 AZT_BUF_SIZ ? 0 :
2314 azt_buf_in + 1;
2315 }
2316 }
2317 if (!azt_transfer_is_active) {
2318 while (current_valid()) {
2319 azt_transfer();
2320 if (CURRENT->nr_sectors ==
2321 0)
2322 end_request(CURRENT, 1);
2323 else
2324 break;
2325 }
2326 }
2327
2328 if (current_valid()
2329 && (CURRENT->sector / 4 < azt_next_bn
2330 || CURRENT->sector / 4 >
2331 azt_next_bn + AZT_BUF_SIZ)) {
2332 azt_state = AZT_S_STOP;
2333 loop_ctl = 1;
2334 break;
2335 }
2336 AztTimeout = READ_TIMEOUT;
2337 if (azt_read_count == 0) {
2338 azt_state = AZT_S_STOP;
2339 loop_ctl = 1;
2340 break;
2341 }
2342 break;
2343 }
2344 break;
2345
2346
2347 case AZT_S_STOP:
2348#ifdef AZT_TEST3
2349 if (azt_state != azt_state_old) {
2350 azt_state_old = azt_state;
2351 printk("AZT_S_STOP\n");
2352 }
2353#endif
2354 if (azt_read_count != 0)
2355 printk("aztcd: discard data=%x frames\n",
2356 azt_read_count);
2357 while (azt_read_count != 0) {
2358 int i;
2359 if (!(inb(STATUS_PORT) & AFL_DATA)) {
2360 if (azt_read_mode == AZT_MODE_2)
2361 for (i = 0;
2362 i < CD_FRAMESIZE_RAW;
2363 i++)
2364 inb(DATA_PORT);
2365 else
2366 for (i = 0;
2367 i < CD_FRAMESIZE; i++)
2368 inb(DATA_PORT);
2369 }
2370 azt_read_count--;
2371 }
2372 if (aztSendCmd(ACMD_GET_STATUS))
2373 RETURN("azt_poll 5");
2374 azt_state = AZT_S_STOPPING;
2375 AztTimeout = 1000;
2376 break;
2377
2378 case AZT_S_STOPPING:
2379#ifdef AZT_TEST3
2380 if (azt_state != azt_state_old) {
2381 azt_state_old = azt_state;
2382 printk("AZT_S_STOPPING\n");
2383 }
2384#endif
2385
2386 if ((st = aztStatus()) == -1 && AztTimeout)
2387 break;
2388
2389 if ((st != -1)
2390 && ((st & AST_DSK_CHG)
2391 || (st & AST_NOT_READY))) {
2392 aztDiskChanged = 1;
2393 aztTocUpToDate = 0;
2394 azt_invalidate_buffers();
2395 printk
2396 ("aztcd: Disk Changed or Not Ready 4 - Unmount Disk!\n");
2397 end_request(CURRENT, 0);
2398 }
2399
2400#ifdef AZT_TEST3
2401 printk("CURRENT_VALID %d azt_mode %d\n",
2402 current_valid(), azt_mode);
2403#endif
2404
2405 if (current_valid()) {
2406 if (st != -1) {
2407 if (azt_mode == 1) {
2408 azt_state = AZT_S_READ;
2409 loop_ctl = 1;
2410 skip = 1;
2411 break;
2412 } else {
2413 azt_state = AZT_S_MODE;
2414 loop_ctl = 1;
2415 skip = 1;
2416 break;
2417 }
2418 } else {
2419 azt_state = AZT_S_START;
2420 AztTimeout = 1;
2421 }
2422 } else {
2423 azt_state = AZT_S_IDLE;
2424 return;
2425 }
2426 break;
2427
2428 default:
2429 printk("aztcd: invalid state %d\n", azt_state);
2430 return;
2431 } /* case */
2432 } /* while */
2433
2434
2435 if (!AztTimeout--) {
2436 printk("aztcd: timeout in state %d\n", azt_state);
2437 azt_state = AZT_S_STOP;
2438 if (aztSendCmd(ACMD_STOP))
2439 RETURN("azt_poll 6");
2440 STEN_LOW_WAIT;
2441 };
2442
2443 SET_TIMER(azt_poll, HZ / 100);
2444}
2445
2446
2447/*###########################################################################
2448 * Miscellaneous support functions
2449 ###########################################################################
2450*/
2451static void azt_hsg2msf(long hsg, struct msf *msf)
2452{
2453 hsg += 150;
2454 msf->min = hsg / 4500;
2455 hsg %= 4500;
2456 msf->sec = hsg / 75;
2457 msf->frame = hsg % 75;
2458#ifdef AZT_DEBUG
2459 if (msf->min >= 70)
2460 printk("aztcd: Error hsg2msf address Minutes\n");
2461 if (msf->sec >= 60)
2462 printk("aztcd: Error hsg2msf address Seconds\n");
2463 if (msf->frame >= 75)
2464 printk("aztcd: Error hsg2msf address Frames\n");
2465#endif
2466 azt_bin2bcd(&msf->min); /* convert to BCD */
2467 azt_bin2bcd(&msf->sec);
2468 azt_bin2bcd(&msf->frame);
2469}
2470
2471static long azt_msf2hsg(struct msf *mp)
2472{
2473 return azt_bcd2bin(mp->frame) + azt_bcd2bin(mp->sec) * 75
2474 + azt_bcd2bin(mp->min) * 4500 - CD_MSF_OFFSET;
2475}
2476
2477static void azt_bin2bcd(unsigned char *p)
2478{
2479 int u, t;
2480
2481 u = *p % 10;
2482 t = *p / 10;
2483 *p = u | (t << 4);
2484}
2485
2486static int azt_bcd2bin(unsigned char bcd)
2487{
2488 return (bcd >> 4) * 10 + (bcd & 0xF);
2489}
2490
2491MODULE_LICENSE("GPL");
2492MODULE_ALIAS_BLOCKDEV_MAJOR(AZTECH_CDROM_MAJOR);
diff --git a/drivers/cdrom/aztcd.h b/drivers/cdrom/aztcd.h
deleted file mode 100644
index 057501e31628..000000000000
--- a/drivers/cdrom/aztcd.h
+++ /dev/null
@@ -1,162 +0,0 @@
1/* $Id: aztcd.h,v 2.60 1997/11/29 09:51:22 root Exp root $
2 *
3 * Definitions for a AztechCD268 CD-ROM interface
4 * Copyright (C) 1994-98 Werner Zimmermann
5 *
6 * based on Mitsumi CDROM driver by Martin Harriss
7 *
8 * This program is free software; you can redistribute it and/or modify
9 * it under the terms of the GNU General Public License as published by
10 * the Free Software Foundation; either version 2 of the License, or
11 * (at your option) any later version.
12 *
13 * This program is distributed in the hope that it will be useful,
14 * but WITHOUT ANY WARRANTY; without even the implied warranty of
15 * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
16 * GNU General Public License for more details.
17 *
18 * You should have received a copy of the GNU General Public License
19 * along with this program; if not, write to the Free Software
20 * Foundation, Inc., 675 Mass Ave, Cambridge, MA 02139, USA.
21 *
22 * History: W.Zimmermann adaption to Aztech CD268-01A Version 1.3
23 * October 1994 Email: Werner.Zimmermann@fht-esslingen.de
24 */
25
26/* *** change this to set the I/O port address of your CD-ROM drive,
27 set to '-1', if you want autoprobing */
28#define AZT_BASE_ADDR -1
29
30/* list of autoprobing addresses (not more than 15), last value must be 0x000
31 Note: Autoprobing is only enabled, if AZT_BASE_ADDR is set to '-1' ! */
32#define AZT_BASE_AUTO { 0x320, 0x300, 0x310, 0x330, 0x000 }
33
34/* Uncomment this, if your CDROM is connected to a Soundwave32-soundcard
35 and configure AZT_BASE_ADDR and AZT_SW32_BASE_ADDR */
36/*#define AZT_SW32 1
37*/
38
39#ifdef AZT_SW32
40#define AZT_SW32_BASE_ADDR 0x220 /*I/O port base address of your soundcard*/
41#endif
42
43/* Set this to 1, if you want your tray to be locked, set to 0 to prevent tray
44 from locking */
45#define AZT_ALLOW_TRAY_LOCK 1
46
47/*Set this to 1 to allow auto-eject when unmounting a disk, set to 0, if you
48 don't want the auto-eject feature*/
49#define AZT_AUTO_EJECT 0
50
51/*Set this to 1, if you want to use incompatible ioctls for reading in raw and
52 cooked mode */
53#define AZT_PRIVATE_IOCTLS 1
54
55/*Set this to 1, if you want multisession support by the ISO fs. Even if you set
56 this value to '0' you can use multisession CDs. In that case the drive's firm-
57 ware will do the appropriate redirection automatically. The CD will then look
58 like a single session CD (but nevertheless all data may be read). Please read
59 chapter '5.1 Multisession support' in README.aztcd for details. Normally it's
60 uncritical to leave this setting untouched */
61#define AZT_MULTISESSION 1
62
63/*Uncomment this, if you are using a linux kernel version prior to 2.1.0 */
64/*#define AZT_KERNEL_PRIOR_2_1 */
65
66/*---------------------------------------------------------------------------*/
67/*-----nothing to be configured for normal applications below this line------*/
68
69
70/* Increase this if you get lots of timeouts; if you get kernel panic, replace
71 STEN_LOW_WAIT by STEN_LOW in the source code */
72#define AZT_STATUS_DELAY 400 /*for timer wait, STEN_LOW_WAIT*/
73#define AZT_TIMEOUT 8000000 /*for busy wait STEN_LOW, DTEN_LOW*/
74#define AZT_FAST_TIMEOUT 10000 /*for reading the version string*/
75
76/* number of times to retry a command before giving up */
77#define AZT_RETRY_ATTEMPTS 3
78
79/* port access macros */
80#define CMD_PORT azt_port
81#define DATA_PORT azt_port
82#define STATUS_PORT azt_port+1
83#define MODE_PORT azt_port+2
84#ifdef AZT_SW32
85 #define AZT_SW32_INIT (unsigned int) (0xFF00 & (AZT_BASE_ADDR*16))
86 #define AZT_SW32_CONFIG_REG AZT_SW32_BASE_ADDR+0x16 /*Soundwave32 Config. Register*/
87 #define AZT_SW32_ID_REG AZT_SW32_BASE_ADDR+0x04 /*Soundwave32 ID Version Register*/
88#endif
89
90/* status bits */
91#define AST_CMD_CHECK 0x80 /* 1 = command error */
92#define AST_DOOR_OPEN 0x40 /* 1 = door is open */
93#define AST_NOT_READY 0x20 /* 1 = no disk in the drive */
94#define AST_DSK_CHG 0x02 /* 1 = disk removed or changed */
95#define AST_MODE 0x01 /* 0=MODE1, 1=MODE2 */
96#define AST_MODE_BITS 0x1C /* Mode Bits */
97#define AST_INITIAL 0x0C /* initial, only valid ... */
98#define AST_BUSY 0x04 /* now playing, only valid
99 in combination with mode
100 bits */
101/* flag bits */
102#define AFL_DATA 0x02 /* data available if low */
103#define AFL_STATUS 0x04 /* status available if low */
104#define AFL_OP_OK 0x01 /* OP_OK command correct*/
105#define AFL_PA_OK 0x02 /* PA_OK parameter correct*/
106#define AFL_OP_ERR 0x05 /* error in command*/
107#define AFL_PA_ERR 0x06 /* error in parameters*/
108#define POLLED 0x04 /* polled mode */
109
110/* commands */
111#define ACMD_SOFT_RESET 0x10 /* reset drive */
112#define ACMD_PLAY_READ 0x20 /* read data track in cooked mode */
113#define ACMD_PLAY_READ_RAW 0x21 /* reading in raw mode*/
114#define ACMD_SEEK 0x30 /* seek msf address*/
115#define ACMD_SEEK_TO_LEADIN 0x31 /* seek to leadin track*/
116#define ACMD_GET_ERROR 0x40 /* get error code */
117#define ACMD_GET_STATUS 0x41 /* get status */
118#define ACMD_GET_Q_CHANNEL 0x50 /* read info from q channel */
119#define ACMD_EJECT 0x60 /* eject/open tray */
120#define ACMD_CLOSE 0x61 /* close tray */
121#define ACMD_LOCK 0x71 /* lock tray closed */
122#define ACMD_UNLOCK 0x72 /* unlock tray */
123#define ACMD_PAUSE 0x80 /* pause */
124#define ACMD_STOP 0x81 /* stop play */
125#define ACMD_PLAY_AUDIO 0x90 /* play audio track */
126#define ACMD_SET_VOLUME 0x93 /* set audio level */
127#define ACMD_GET_VERSION 0xA0 /* get firmware version */
128#define ACMD_SET_DISK_TYPE 0xA1 /* set disk data mode */
129
130#define MAX_TRACKS 104
131
132struct msf {
133 unsigned char min;
134 unsigned char sec;
135 unsigned char frame;
136};
137
138struct azt_Play_msf {
139 struct msf start;
140 struct msf end;
141};
142
143struct azt_DiskInfo {
144 unsigned char first;
145 unsigned char next;
146 unsigned char last;
147 struct msf diskLength;
148 struct msf firstTrack;
149 unsigned char multi;
150 struct msf nextSession;
151 struct msf lastSession;
152 unsigned char xa;
153 unsigned char audio;
154};
155
156struct azt_Toc {
157 unsigned char ctrl_addr;
158 unsigned char track;
159 unsigned char pointIndex;
160 struct msf trackTime;
161 struct msf diskTime;
162};
diff --git a/drivers/cdrom/cdu31a.c b/drivers/cdrom/cdu31a.c
deleted file mode 100644
index 2157c58755e0..000000000000
--- a/drivers/cdrom/cdu31a.c
+++ /dev/null
@@ -1,3251 +0,0 @@
1/*
2* Sony CDU-31A CDROM interface device driver.
3*
4* Corey Minyard (minyard@wf-rch.cirr.com)
5*
6* Colossians 3:17
7*
8* See Documentation/cdrom/cdu31a for additional details about this driver.
9*
10* The Sony interface device driver handles Sony interface CDROM
11* drives and provides a complete block-level interface as well as an
12* ioctl() interface compatible with the Sun (as specified in
13* include/linux/cdrom.h). With this interface, CDROMs can be
14* accessed and standard audio CDs can be played back normally.
15*
16* WARNING - All autoprobes have been removed from the driver.
17* You MUST configure the CDU31A via a LILO config
18* at boot time or in lilo.conf. I have the
19* following in my lilo.conf:
20*
21* append="cdu31a=0x1f88,0,PAS"
22*
23* The first number is the I/O base address of the
24* card. The second is the interrupt (0 means none).
25 * The third should be "PAS" if on a Pro-Audio
26 * spectrum, or nothing if on something else.
27 *
28 * This interface is (unfortunately) a polled interface. This is
29 * because most Sony interfaces are set up with DMA and interrupts
30 * disables. Some (like mine) do not even have the capability to
31 * handle interrupts or DMA. For this reason you will see a lot of
32 * the following:
33 *
34 * retry_count = jiffies+ SONY_JIFFIES_TIMEOUT;
35 * while (time_before(jiffies, retry_count) && (! <some condition to wait for))
36 * {
37 * while (handle_sony_cd_attention())
38 * ;
39 *
40 * sony_sleep();
41 * }
42 * if (the condition not met)
43 * {
44 * return an error;
45 * }
46 *
47 * This ugly hack waits for something to happen, sleeping a little
48 * between every try. it also handles attentions, which are
49 * asynchronous events from the drive informing the driver that a disk
50 * has been inserted, removed, etc.
51 *
52 * NEWS FLASH - The driver now supports interrupts but they are
53 * turned off by default. Use of interrupts is highly encouraged, it
54 * cuts CPU usage down to a reasonable level. I had DMA in for a while
55 * but PC DMA is just too slow. Better to just insb() it.
56 *
57 * One thing about these drives: They talk in MSF (Minute Second Frame) format.
58 * There are 75 frames a second, 60 seconds a minute, and up to 75 minutes on a
59 * disk. The funny thing is that these are sent to the drive in BCD, but the
60 * interface wants to see them in decimal. A lot of conversion goes on.
61 *
62 * DRIVER SPECIAL FEATURES
63 * -----------------------
64 *
65 * This section describes features beyond the normal audio and CD-ROM
66 * functions of the drive.
67 *
68 * XA compatibility
69 *
70 * The driver should support XA disks for both the CDU31A and CDU33A.
71 * It does this transparently, the using program doesn't need to set it.
72 *
73 * Multi-Session
74 *
75 * A multi-session disk looks just like a normal disk to the user.
76 * Just mount one normally, and all the data should be there.
77 * A special thanks to Koen for help with this!
78 *
79 * Raw sector I/O
80 *
81 * Using the CDROMREADAUDIO it is possible to read raw audio and data
82 * tracks. Both operations return 2352 bytes per sector. On the data
83 * tracks, the first 12 bytes is not returned by the drive and the value
84 * of that data is indeterminate.
85 *
86 *
87 * Copyright (C) 1993 Corey Minyard
88 *
89 * This program is free software; you can redistribute it and/or modify
90 * it under the terms of the GNU General Public License as published by
91 * the Free Software Foundation; either version 2 of the License, or
92 * (at your option) any later version.
93 *
94 * This program is distributed in the hope that it will be useful,
95 * but WITHOUT ANY WARRANTY; without even the implied warranty of
96 * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
97 * GNU General Public License for more details.
98 *
99 * You should have received a copy of the GNU General Public License
100 * along with this program; if not, write to the Free Software
101 * Foundation, Inc., 675 Mass Ave, Cambridge, MA 02139, USA.
102 *
103 * TODO:
104 * CDs with form1 and form2 sectors cause problems
105 * with current read-ahead strategy.
106 *
107 * Credits:
108 * Heiko Eissfeldt <heiko@colossus.escape.de>
109 * For finding abug in the return of the track numbers.
110 * TOC processing redone for proper multisession support.
111 *
112 *
113 * It probably a little late to be adding a history, but I guess I
114 * will start.
115 *
116 * 10/24/95 - Added support for disabling the eject button when the
117 * drive is open. Note that there is a small problem
118 * still here, if the eject button is pushed while the
119 * drive light is flashing, the drive will return a bad
120 * status and be reset. It recovers, though.
121 *
122 * 03/07/97 - Fixed a problem with timers.
123 *
124 *
125 * 18 Spetember 1997 -- Ported to Uniform CD-ROM driver by
126 * Heiko Eissfeldt <heiko@colossus.escape.de> with additional
127 * changes by Erik Andersen <andersee@debian.org>
128 *
129 * 24 January 1998 -- Removed the scd_disc_status() function, which was now
130 * just dead code left over from the port.
131 * Erik Andersen <andersee@debian.org>
132 *
133 * 16 July 1998 -- Drive donated to Erik Andersen by John Kodis
134 * <kodis@jagunet.com>. Work begun on fixing driver to
135 * work under 2.1.X. Added temporary extra printks
136 * which seem to slow it down enough to work.
137 *
138 * 9 November 1999 -- Make kernel-parameter implementation work with 2.3.x
139 * Removed init_module & cleanup_module in favor of
140 * module_init & module_exit.
141 * Torben Mathiasen <tmm@image.dk>
142 *
143 * 22 October 2004 -- Make the driver work in 2.6.X
144 * Added workaround to fix hard lockups on eject
145 * Fixed door locking problem after mounting empty drive
146 * Set double-speed drives to double speed by default
147 * Removed all readahead things - not needed anymore
148 * Ondrej Zary <rainbow@rainbow-software.org>
149*/
150
151#define DEBUG 1
152
153#include <linux/major.h>
154#include <linux/module.h>
155#include <linux/errno.h>
156#include <linux/signal.h>
157#include <linux/sched.h>
158#include <linux/timer.h>
159#include <linux/fs.h>
160#include <linux/kernel.h>
161#include <linux/hdreg.h>
162#include <linux/genhd.h>
163#include <linux/ioport.h>
164#include <linux/string.h>
165#include <linux/slab.h>
166#include <linux/init.h>
167#include <linux/interrupt.h>
168#include <linux/cdrom.h>
169
170#include <asm/system.h>
171#include <asm/io.h>
172#include <asm/uaccess.h>
173#include <asm/dma.h>
174
175#include "cdu31a.h"
176
177#define MAJOR_NR CDU31A_CDROM_MAJOR
178#include <linux/blkdev.h>
179
180#define CDU31A_MAX_CONSECUTIVE_ATTENTIONS 10
181
182#define PFX "CDU31A: "
183
184/*
185** Edit the following data to change interrupts, DMA channels, etc.
186** Default is polled and no DMA. DMA is not recommended for double-speed
187** drives.
188*/
189static struct {
190 unsigned short base; /* I/O Base Address */
191 short int_num; /* Interrupt Number (-1 means scan for it,
192 0 means don't use) */
193} cdu31a_addresses[] __initdata = {
194 {0}
195};
196
197static int handle_sony_cd_attention(void);
198static int read_subcode(void);
199static void sony_get_toc(void);
200static int scd_spinup(void);
201/*static int scd_open(struct inode *inode, struct file *filp);*/
202static int scd_open(struct cdrom_device_info *, int);
203static void do_sony_cd_cmd(unsigned char cmd,
204 unsigned char *params,
205 unsigned int num_params,
206 unsigned char *result_buffer,
207 unsigned int *result_size);
208static void size_to_buf(unsigned int size, unsigned char *buf);
209
210/* Parameters for the read-ahead. */
211static unsigned int sony_next_block; /* Next 512 byte block offset */
212static unsigned int sony_blocks_left = 0; /* Number of 512 byte blocks left
213 in the current read command. */
214
215
216/* The base I/O address of the Sony Interface. This is a variable (not a
217 #define) so it can be easily changed via some future ioctl() */
218static unsigned int cdu31a_port = 0;
219module_param(cdu31a_port, uint, 0);
220
221/*
222 * The following are I/O addresses of the various registers for the drive. The
223 * comment for the base address also applies here.
224 */
225static volatile unsigned short sony_cd_cmd_reg;
226static volatile unsigned short sony_cd_param_reg;
227static volatile unsigned short sony_cd_write_reg;
228static volatile unsigned short sony_cd_control_reg;
229static volatile unsigned short sony_cd_status_reg;
230static volatile unsigned short sony_cd_result_reg;
231static volatile unsigned short sony_cd_read_reg;
232static volatile unsigned short sony_cd_fifost_reg;
233
234static struct request_queue *cdu31a_queue;
235static DEFINE_SPINLOCK(cdu31a_lock); /* queue lock */
236
237static int sony_spun_up = 0; /* Has the drive been spun up? */
238
239static int sony_speed = 0; /* Last wanted speed */
240
241static int sony_xa_mode = 0; /* Is an XA disk in the drive
242 and the drive a CDU31A? */
243
244static int sony_raw_data_mode = 1; /* 1 if data tracks, 0 if audio.
245 For raw data reads. */
246
247static unsigned int sony_usage = 0; /* How many processes have the
248 drive open. */
249
250static int sony_pas_init = 0; /* Initialize the Pro-Audio
251 Spectrum card? */
252
253static struct s_sony_session_toc single_toc; /* Holds the
254 table of
255 contents. */
256
257static struct s_all_sessions_toc sony_toc; /* entries gathered from all
258 sessions */
259
260static int sony_toc_read = 0; /* Has the TOC been read for
261 the drive? */
262
263static struct s_sony_subcode last_sony_subcode; /* Points to the last
264 subcode address read */
265
266static DECLARE_MUTEX(sony_sem); /* Semaphore for drive hardware access */
267
268static int is_double_speed = 0; /* does the drive support double speed ? */
269
270static int is_auto_eject = 1; /* Door has been locked? 1=No/0=Yes */
271
272/*
273 * The audio status uses the values from read subchannel data as specified
274 * in include/linux/cdrom.h.
275 */
276static volatile int sony_audio_status = CDROM_AUDIO_NO_STATUS;
277
278/*
279 * The following are a hack for pausing and resuming audio play. The drive
280 * does not work as I would expect it, if you stop it then start it again,
281 * the drive seeks back to the beginning and starts over. This holds the
282 * position during a pause so a resume can restart it. It uses the
283 * audio status variable above to tell if it is paused.
284 */
285static unsigned volatile char cur_pos_msf[3] = { 0, 0, 0 };
286static unsigned volatile char final_pos_msf[3] = { 0, 0, 0 };
287
288/* What IRQ is the drive using? 0 if none. */
289static int cdu31a_irq = 0;
290module_param(cdu31a_irq, int, 0);
291
292/* The interrupt handler will wake this queue up when it gets an
293 interrupts. */
294static DECLARE_WAIT_QUEUE_HEAD(cdu31a_irq_wait);
295static int irq_flag = 0;
296
297static int curr_control_reg = 0; /* Current value of the control register */
298
299/* A disk changed variable. When a disk change is detected, it will
300 all be set to TRUE. As the upper layers ask for disk_changed status
301 it will be cleared. */
302static char disk_changed;
303
304/* This was readahead_buffer once... Now it's used only for audio reads */
305static char audio_buffer[CD_FRAMESIZE_RAW];
306
307/* Used to time a short period to abort an operation after the
308 drive has been idle for a while. This keeps the light on
309 the drive from flashing for very long. */
310static struct timer_list cdu31a_abort_timer;
311
312/* Marks if the timeout has started an abort read. This is used
313 on entry to the drive to tell the code to read out the status
314 from the abort read. */
315static int abort_read_started = 0;
316
317/*
318 * Uniform cdrom interface function
319 * report back, if disc has changed from time of last request.
320 */
321static int scd_media_changed(struct cdrom_device_info *cdi, int disc_nr)
322{
323 int retval;
324
325 retval = disk_changed;
326 disk_changed = 0;
327
328 return retval;
329}
330
331/*
332 * Uniform cdrom interface function
333 * report back, if drive is ready
334 */
335static int scd_drive_status(struct cdrom_device_info *cdi, int slot_nr)
336{
337 if (CDSL_CURRENT != slot_nr)
338 /* we have no changer support */
339 return -EINVAL;
340 if (sony_spun_up)
341 return CDS_DISC_OK;
342 if (down_interruptible(&sony_sem))
343 return -ERESTARTSYS;
344 if (scd_spinup() == 0)
345 sony_spun_up = 1;
346 up(&sony_sem);
347 return sony_spun_up ? CDS_DISC_OK : CDS_DRIVE_NOT_READY;
348}
349
350static inline void enable_interrupts(void)
351{
352 curr_control_reg |= (SONY_ATTN_INT_EN_BIT
353 | SONY_RES_RDY_INT_EN_BIT
354 | SONY_DATA_RDY_INT_EN_BIT);
355 outb(curr_control_reg, sony_cd_control_reg);
356}
357
358static inline void disable_interrupts(void)
359{
360 curr_control_reg &= ~(SONY_ATTN_INT_EN_BIT
361 | SONY_RES_RDY_INT_EN_BIT
362 | SONY_DATA_RDY_INT_EN_BIT);
363 outb(curr_control_reg, sony_cd_control_reg);
364}
365
366/*
367 * Wait a little while (used for polling the drive). If in initialization,
368 * setting a timeout doesn't work, so just loop for a while.
369 */
370static inline void sony_sleep(void)
371{
372 if (cdu31a_irq <= 0) {
373 yield();
374 } else { /* Interrupt driven */
375 DEFINE_WAIT(w);
376 int first = 1;
377
378 while (1) {
379 prepare_to_wait(&cdu31a_irq_wait, &w,
380 TASK_INTERRUPTIBLE);
381 if (first) {
382 enable_interrupts();
383 first = 0;
384 }
385
386 if (irq_flag != 0)
387 break;
388 if (!signal_pending(current)) {
389 schedule();
390 continue;
391 } else
392 disable_interrupts();
393 break;
394 }
395 finish_wait(&cdu31a_irq_wait, &w);
396 irq_flag = 0;
397 }
398}
399
400
401/*
402 * The following are convenience routine to read various status and set
403 * various conditions in the drive.
404 */
405static inline int is_attention(void)
406{
407 return (inb(sony_cd_status_reg) & SONY_ATTN_BIT) != 0;
408}
409
410static inline int is_busy(void)
411{
412 return (inb(sony_cd_status_reg) & SONY_BUSY_BIT) != 0;
413}
414
415static inline int is_data_ready(void)
416{
417 return (inb(sony_cd_status_reg) & SONY_DATA_RDY_BIT) != 0;
418}
419
420static inline int is_data_requested(void)
421{
422 return (inb(sony_cd_status_reg) & SONY_DATA_REQUEST_BIT) != 0;
423}
424
425static inline int is_result_ready(void)
426{
427 return (inb(sony_cd_status_reg) & SONY_RES_RDY_BIT) != 0;
428}
429
430static inline int is_param_write_rdy(void)
431{
432 return (inb(sony_cd_fifost_reg) & SONY_PARAM_WRITE_RDY_BIT) != 0;
433}
434
435static inline int is_result_reg_not_empty(void)
436{
437 return (inb(sony_cd_fifost_reg) & SONY_RES_REG_NOT_EMP_BIT) != 0;
438}
439
440static inline void reset_drive(void)
441{
442 curr_control_reg = 0;
443 sony_toc_read = 0;
444 outb(SONY_DRIVE_RESET_BIT, sony_cd_control_reg);
445}
446
447/*
448 * Uniform cdrom interface function
449 * reset drive and return when it is ready
450 */
451static int scd_reset(struct cdrom_device_info *cdi)
452{
453 unsigned long retry_count;
454
455 if (down_interruptible(&sony_sem))
456 return -ERESTARTSYS;
457 reset_drive();
458
459 retry_count = jiffies + SONY_RESET_TIMEOUT;
460 while (time_before(jiffies, retry_count) && (!is_attention())) {
461 sony_sleep();
462 }
463
464 up(&sony_sem);
465 return 0;
466}
467
468static inline void clear_attention(void)
469{
470 outb(curr_control_reg | SONY_ATTN_CLR_BIT, sony_cd_control_reg);
471}
472
473static inline void clear_result_ready(void)
474{
475 outb(curr_control_reg | SONY_RES_RDY_CLR_BIT, sony_cd_control_reg);
476}
477
478static inline void clear_data_ready(void)
479{
480 outb(curr_control_reg | SONY_DATA_RDY_CLR_BIT,
481 sony_cd_control_reg);
482}
483
484static inline void clear_param_reg(void)
485{
486 outb(curr_control_reg | SONY_PARAM_CLR_BIT, sony_cd_control_reg);
487}
488
489static inline unsigned char read_status_register(void)
490{
491 return inb(sony_cd_status_reg);
492}
493
494static inline unsigned char read_result_register(void)
495{
496 return inb(sony_cd_result_reg);
497}
498
499static inline unsigned char read_data_register(void)
500{
501 return inb(sony_cd_read_reg);
502}
503
504static inline void write_param(unsigned char param)
505{
506 outb(param, sony_cd_param_reg);
507}
508
509static inline void write_cmd(unsigned char cmd)
510{
511 outb(curr_control_reg | SONY_RES_RDY_INT_EN_BIT,
512 sony_cd_control_reg);
513 outb(cmd, sony_cd_cmd_reg);
514}
515
516static irqreturn_t cdu31a_interrupt(int irq, void *dev_id)
517{
518 unsigned char val;
519
520 if (abort_read_started) {
521 /* We might be waiting for an abort to finish. Don't
522 disable interrupts yet, though, because we handle
523 this one here. */
524 /* Clear out the result registers. */
525 while (is_result_reg_not_empty()) {
526 val = read_result_register();
527 }
528 clear_data_ready();
529 clear_result_ready();
530
531 /* Clear out the data */
532 while (is_data_requested()) {
533 val = read_data_register();
534 }
535 abort_read_started = 0;
536
537 /* If something was waiting, wake it up now. */
538 if (waitqueue_active(&cdu31a_irq_wait)) {
539 disable_interrupts();
540 irq_flag = 1;
541 wake_up_interruptible(&cdu31a_irq_wait);
542 }
543 } else if (waitqueue_active(&cdu31a_irq_wait)) {
544 disable_interrupts();
545 irq_flag = 1;
546 wake_up_interruptible(&cdu31a_irq_wait);
547 } else {
548 disable_interrupts();
549 printk(KERN_NOTICE PFX
550 "Got an interrupt but nothing was waiting\n");
551 }
552 return IRQ_HANDLED;
553}
554
555/*
556 * give more verbose error messages
557 */
558static unsigned char *translate_error(unsigned char err_code)
559{
560 static unsigned char errbuf[80];
561
562 switch (err_code) {
563 case 0x10: return "illegal command ";
564 case 0x11: return "illegal parameter ";
565
566 case 0x20: return "not loaded ";
567 case 0x21: return "no disc ";
568 case 0x22: return "not spinning ";
569 case 0x23: return "spinning ";
570 case 0x25: return "spindle servo ";
571 case 0x26: return "focus servo ";
572 case 0x29: return "eject mechanism ";
573 case 0x2a: return "audio playing ";
574 case 0x2c: return "emergency eject ";
575
576 case 0x30: return "focus ";
577 case 0x31: return "frame sync ";
578 case 0x32: return "subcode address ";
579 case 0x33: return "block sync ";
580 case 0x34: return "header address ";
581
582 case 0x40: return "illegal track read ";
583 case 0x41: return "mode 0 read ";
584 case 0x42: return "illegal mode read ";
585 case 0x43: return "illegal block size read ";
586 case 0x44: return "mode read ";
587 case 0x45: return "form read ";
588 case 0x46: return "leadout read ";
589 case 0x47: return "buffer overrun ";
590
591 case 0x53: return "unrecoverable CIRC ";
592 case 0x57: return "unrecoverable LECC ";
593
594 case 0x60: return "no TOC ";
595 case 0x61: return "invalid subcode data ";
596 case 0x63: return "focus on TOC read ";
597 case 0x64: return "frame sync on TOC read ";
598 case 0x65: return "TOC data ";
599
600 case 0x70: return "hardware failure ";
601 case 0x91: return "leadin ";
602 case 0x92: return "leadout ";
603 case 0x93: return "data track ";
604 }
605 sprintf(errbuf, "unknown 0x%02x ", err_code);
606 return errbuf;
607}
608
609/*
610 * Set the drive parameters so the drive will auto-spin-up when a
611 * disk is inserted.
612 */
613static void set_drive_params(int want_doublespeed)
614{
615 unsigned char res_reg[12];
616 unsigned int res_size;
617 unsigned char params[3];
618
619
620 params[0] = SONY_SD_AUTO_SPIN_DOWN_TIME;
621 params[1] = 0x00; /* Never spin down the drive. */
622 do_sony_cd_cmd(SONY_SET_DRIVE_PARAM_CMD,
623 params, 2, res_reg, &res_size);
624 if ((res_size < 2) || ((res_reg[0] & 0xf0) == 0x20)) {
625 printk(KERN_NOTICE PFX
626 "Unable to set spin-down time: 0x%2.2x\n", res_reg[1]);
627 }
628
629 params[0] = SONY_SD_MECH_CONTROL;
630 params[1] = SONY_AUTO_SPIN_UP_BIT; /* Set auto spin up */
631
632 if (is_auto_eject)
633 params[1] |= SONY_AUTO_EJECT_BIT;
634
635 if (is_double_speed && want_doublespeed) {
636 params[1] |= SONY_DOUBLE_SPEED_BIT; /* Set the drive to double speed if
637 possible */
638 }
639 do_sony_cd_cmd(SONY_SET_DRIVE_PARAM_CMD,
640 params, 2, res_reg, &res_size);
641 if ((res_size < 2) || ((res_reg[0] & 0xf0) == 0x20)) {
642 printk(KERN_NOTICE PFX "Unable to set mechanical "
643 "parameters: 0x%2.2x\n", res_reg[1]);
644 }
645}
646
647/*
648 * Uniform cdrom interface function
649 * select reading speed for data access
650 */
651static int scd_select_speed(struct cdrom_device_info *cdi, int speed)
652{
653 if (speed == 0)
654 sony_speed = 1;
655 else
656 sony_speed = speed - 1;
657
658 if (down_interruptible(&sony_sem))
659 return -ERESTARTSYS;
660 set_drive_params(sony_speed);
661 up(&sony_sem);
662 return 0;
663}
664
665/*
666 * Uniform cdrom interface function
667 * lock or unlock eject button
668 */
669static int scd_lock_door(struct cdrom_device_info *cdi, int lock)
670{
671 if (lock == 0) {
672 is_auto_eject = 1;
673 } else {
674 is_auto_eject = 0;
675 }
676 if (down_interruptible(&sony_sem))
677 return -ERESTARTSYS;
678 set_drive_params(sony_speed);
679 up(&sony_sem);
680 return 0;
681}
682
683/*
684 * This code will reset the drive and attempt to restore sane parameters.
685 */
686static void restart_on_error(void)
687{
688 unsigned char res_reg[12];
689 unsigned int res_size;
690 unsigned long retry_count;
691
692
693 printk(KERN_NOTICE PFX "Resetting drive on error\n");
694 reset_drive();
695 retry_count = jiffies + SONY_RESET_TIMEOUT;
696 while (time_before(jiffies, retry_count) && (!is_attention())) {
697 sony_sleep();
698 }
699 set_drive_params(sony_speed);
700 do_sony_cd_cmd(SONY_SPIN_UP_CMD, NULL, 0, res_reg, &res_size);
701 if ((res_size < 2) || ((res_reg[0] & 0xf0) == 0x20)) {
702 printk(KERN_NOTICE PFX "Unable to spin up drive: 0x%2.2x\n",
703 res_reg[1]);
704 }
705
706 msleep(2000);
707
708 sony_get_toc();
709}
710
711/*
712 * This routine writes data to the parameter register. Since this should
713 * happen fairly fast, it is polled with no OS waits between.
714 */
715static int write_params(unsigned char *params, int num_params)
716{
717 unsigned int retry_count;
718
719
720 retry_count = SONY_READY_RETRIES;
721 while ((retry_count > 0) && (!is_param_write_rdy())) {
722 retry_count--;
723 }
724 if (!is_param_write_rdy()) {
725 return -EIO;
726 }
727
728 while (num_params > 0) {
729 write_param(*params);
730 params++;
731 num_params--;
732 }
733
734 return 0;
735}
736
737
738/*
739 * The following reads data from the command result register. It is a
740 * fairly complex routine, all status info flows back through this
741 * interface. The algorithm is stolen directly from the flowcharts in
742 * the drive manual.
743 */
744static void
745get_result(unsigned char *result_buffer, unsigned int *result_size)
746{
747 unsigned char a, b;
748 int i;
749 unsigned long retry_count;
750
751
752 while (handle_sony_cd_attention());
753 /* Wait for the result data to be ready */
754 retry_count = jiffies + SONY_JIFFIES_TIMEOUT;
755 while (time_before(jiffies, retry_count)
756 && (is_busy() || (!(is_result_ready())))) {
757 sony_sleep();
758
759 while (handle_sony_cd_attention());
760 }
761 if (is_busy() || (!(is_result_ready()))) {
762 pr_debug(PFX "timeout out %d\n", __LINE__);
763 result_buffer[0] = 0x20;
764 result_buffer[1] = SONY_TIMEOUT_OP_ERR;
765 *result_size = 2;
766 return;
767 }
768
769 /*
770 * Get the first two bytes. This determines what else needs
771 * to be done.
772 */
773 clear_result_ready();
774 a = read_result_register();
775 *result_buffer = a;
776 result_buffer++;
777
778 /* Check for block error status result. */
779 if ((a & 0xf0) == 0x50) {
780 *result_size = 1;
781 return;
782 }
783
784 b = read_result_register();
785 *result_buffer = b;
786 result_buffer++;
787 *result_size = 2;
788
789 /*
790 * 0x20 means an error occurred. Byte 2 will have the error code.
791 * Otherwise, the command succeeded, byte 2 will have the count of
792 * how many more status bytes are coming.
793 *
794 * The result register can be read 10 bytes at a time, a wait for
795 * result ready to be asserted must be done between every 10 bytes.
796 */
797 if ((a & 0xf0) != 0x20) {
798 if (b > 8) {
799 for (i = 0; i < 8; i++) {
800 *result_buffer = read_result_register();
801 result_buffer++;
802 (*result_size)++;
803 }
804 b = b - 8;
805
806 while (b > 10) {
807 retry_count = SONY_READY_RETRIES;
808 while ((retry_count > 0)
809 && (!is_result_ready())) {
810 retry_count--;
811 }
812 if (!is_result_ready()) {
813 pr_debug(PFX "timeout out %d\n",
814 __LINE__);
815 result_buffer[0] = 0x20;
816 result_buffer[1] =
817 SONY_TIMEOUT_OP_ERR;
818 *result_size = 2;
819 return;
820 }
821
822 clear_result_ready();
823
824 for (i = 0; i < 10; i++) {
825 *result_buffer =
826 read_result_register();
827 result_buffer++;
828 (*result_size)++;
829 }
830 b = b - 10;
831 }
832
833 if (b > 0) {
834 retry_count = SONY_READY_RETRIES;
835 while ((retry_count > 0)
836 && (!is_result_ready())) {
837 retry_count--;
838 }
839 if (!is_result_ready()) {
840 pr_debug(PFX "timeout out %d\n",
841 __LINE__);
842 result_buffer[0] = 0x20;
843 result_buffer[1] =
844 SONY_TIMEOUT_OP_ERR;
845 *result_size = 2;
846 return;
847 }
848 }
849 }
850
851 while (b > 0) {
852 *result_buffer = read_result_register();
853 result_buffer++;
854 (*result_size)++;
855 b--;
856 }
857 }
858}
859
860/*
861 * Do a command that does not involve data transfer. This routine must
862 * be re-entrant from the same task to support being called from the
863 * data operation code when an error occurs.
864 */
865static void
866do_sony_cd_cmd(unsigned char cmd,
867 unsigned char *params,
868 unsigned int num_params,
869 unsigned char *result_buffer, unsigned int *result_size)
870{
871 unsigned long retry_count;
872 int num_retries = 0;
873
874retry_cd_operation:
875
876 while (handle_sony_cd_attention());
877
878 retry_count = jiffies + SONY_JIFFIES_TIMEOUT;
879 while (time_before(jiffies, retry_count) && (is_busy())) {
880 sony_sleep();
881
882 while (handle_sony_cd_attention());
883 }
884 if (is_busy()) {
885 pr_debug(PFX "timeout out %d\n", __LINE__);
886 result_buffer[0] = 0x20;
887 result_buffer[1] = SONY_TIMEOUT_OP_ERR;
888 *result_size = 2;
889 } else {
890 clear_result_ready();
891 clear_param_reg();
892
893 write_params(params, num_params);
894 write_cmd(cmd);
895
896 get_result(result_buffer, result_size);
897 }
898
899 if (((result_buffer[0] & 0xf0) == 0x20)
900 && (num_retries < MAX_CDU31A_RETRIES)) {
901 num_retries++;
902 msleep(100);
903 goto retry_cd_operation;
904 }
905}
906
907
908/*
909 * Handle an attention from the drive. This will return 1 if it found one
910 * or 0 if not (if one is found, the caller might want to call again).
911 *
912 * This routine counts the number of consecutive times it is called
913 * (since this is always called from a while loop until it returns
914 * a 0), and returns a 0 if it happens too many times. This will help
915 * prevent a lockup.
916 */
917static int handle_sony_cd_attention(void)
918{
919 unsigned char atten_code;
920 static int num_consecutive_attentions = 0;
921 volatile int val;
922
923
924#if 0
925 pr_debug(PFX "Entering %s\n", __FUNCTION__);
926#endif
927 if (is_attention()) {
928 if (num_consecutive_attentions >
929 CDU31A_MAX_CONSECUTIVE_ATTENTIONS) {
930 printk(KERN_NOTICE PFX "Too many consecutive "
931 "attentions: %d\n", num_consecutive_attentions);
932 num_consecutive_attentions = 0;
933 pr_debug(PFX "Leaving %s at %d\n", __FUNCTION__,
934 __LINE__);
935 return 0;
936 }
937
938 clear_attention();
939 atten_code = read_result_register();
940
941 switch (atten_code) {
942 /* Someone changed the CD. Mark it as changed */
943 case SONY_MECH_LOADED_ATTN:
944 disk_changed = 1;
945 sony_toc_read = 0;
946 sony_audio_status = CDROM_AUDIO_NO_STATUS;
947 sony_blocks_left = 0;
948 break;
949
950 case SONY_SPIN_DOWN_COMPLETE_ATTN:
951 /* Mark the disk as spun down. */
952 sony_spun_up = 0;
953 break;
954
955 case SONY_AUDIO_PLAY_DONE_ATTN:
956 sony_audio_status = CDROM_AUDIO_COMPLETED;
957 read_subcode();
958 break;
959
960 case SONY_EJECT_PUSHED_ATTN:
961 if (is_auto_eject) {
962 sony_audio_status = CDROM_AUDIO_INVALID;
963 }
964 break;
965
966 case SONY_LEAD_IN_ERR_ATTN:
967 case SONY_LEAD_OUT_ERR_ATTN:
968 case SONY_DATA_TRACK_ERR_ATTN:
969 case SONY_AUDIO_PLAYBACK_ERR_ATTN:
970 sony_audio_status = CDROM_AUDIO_ERROR;
971 break;
972 }
973
974 num_consecutive_attentions++;
975 pr_debug(PFX "Leaving %s at %d\n", __FUNCTION__, __LINE__);
976 return 1;
977 } else if (abort_read_started) {
978 while (is_result_reg_not_empty()) {
979 val = read_result_register();
980 }
981 clear_data_ready();
982 clear_result_ready();
983 /* Clear out the data */
984 while (is_data_requested()) {
985 val = read_data_register();
986 }
987 abort_read_started = 0;
988 pr_debug(PFX "Leaving %s at %d\n", __FUNCTION__, __LINE__);
989 return 1;
990 }
991
992 num_consecutive_attentions = 0;
993#if 0
994 pr_debug(PFX "Leaving %s at %d\n", __FUNCTION__, __LINE__);
995#endif
996 return 0;
997}
998
999
1000/* Convert from an integer 0-99 to BCD */
1001static inline unsigned int int_to_bcd(unsigned int val)
1002{
1003 int retval;
1004
1005
1006 retval = (val / 10) << 4;
1007 retval = retval | val % 10;
1008 return retval;
1009}
1010
1011
1012/* Convert from BCD to an integer from 0-99 */
1013static unsigned int bcd_to_int(unsigned int bcd)
1014{
1015 return (((bcd >> 4) & 0x0f) * 10) + (bcd & 0x0f);
1016}
1017
1018
1019/*
1020 * Convert a logical sector value (like the OS would want to use for
1021 * a block device) to an MSF format.
1022 */
1023static void log_to_msf(unsigned int log, unsigned char *msf)
1024{
1025 log = log + LOG_START_OFFSET;
1026 msf[0] = int_to_bcd(log / 4500);
1027 log = log % 4500;
1028 msf[1] = int_to_bcd(log / 75);
1029 msf[2] = int_to_bcd(log % 75);
1030}
1031
1032
1033/*
1034 * Convert an MSF format to a logical sector.
1035 */
1036static unsigned int msf_to_log(unsigned char *msf)
1037{
1038 unsigned int log;
1039
1040
1041 log = msf[2];
1042 log += msf[1] * 75;
1043 log += msf[0] * 4500;
1044 log = log - LOG_START_OFFSET;
1045
1046 return log;
1047}
1048
1049
1050/*
1051 * Take in integer size value and put it into a buffer like
1052 * the drive would want to see a number-of-sector value.
1053 */
1054static void size_to_buf(unsigned int size, unsigned char *buf)
1055{
1056 buf[0] = size / 65536;
1057 size = size % 65536;
1058 buf[1] = size / 256;
1059 buf[2] = size % 256;
1060}
1061
1062/* Starts a read operation. Returns 0 on success and 1 on failure.
1063 The read operation used here allows multiple sequential sectors
1064 to be read and status returned for each sector. The driver will
1065 read the output one at a time as the requests come and abort the
1066 operation if the requested sector is not the next one from the
1067 drive. */
1068static int
1069start_request(unsigned int sector, unsigned int nsect)
1070{
1071 unsigned char params[6];
1072 unsigned long retry_count;
1073
1074
1075 pr_debug(PFX "Entering %s\n", __FUNCTION__);
1076 log_to_msf(sector, params);
1077 size_to_buf(nsect, &params[3]);
1078
1079 /*
1080 * Clear any outstanding attentions and wait for the drive to
1081 * complete any pending operations.
1082 */
1083 while (handle_sony_cd_attention());
1084
1085 retry_count = jiffies + SONY_JIFFIES_TIMEOUT;
1086 while (time_before(jiffies, retry_count) && (is_busy())) {
1087 sony_sleep();
1088
1089 while (handle_sony_cd_attention());
1090 }
1091
1092 if (is_busy()) {
1093 printk(KERN_NOTICE PFX "Timeout while waiting "
1094 "to issue command\n");
1095 pr_debug(PFX "Leaving %s at %d\n", __FUNCTION__, __LINE__);
1096 return 1;
1097 } else {
1098 /* Issue the command */
1099 clear_result_ready();
1100 clear_param_reg();
1101
1102 write_params(params, 6);
1103 write_cmd(SONY_READ_BLKERR_STAT_CMD);
1104
1105 sony_blocks_left = nsect * 4;
1106 sony_next_block = sector * 4;
1107 pr_debug(PFX "Leaving %s at %d\n", __FUNCTION__, __LINE__);
1108 return 0;
1109 }
1110 pr_debug(PFX "Leaving %s at %d\n", __FUNCTION__, __LINE__);
1111}
1112
1113/* Abort a pending read operation. Clear all the drive status variables. */
1114static void abort_read(void)
1115{
1116 unsigned char result_reg[2];
1117 int result_size;
1118 volatile int val;
1119
1120
1121 do_sony_cd_cmd(SONY_ABORT_CMD, NULL, 0, result_reg, &result_size);
1122 if ((result_reg[0] & 0xf0) == 0x20) {
1123 printk(KERN_ERR PFX "Aborting read, %s error\n",
1124 translate_error(result_reg[1]));
1125 }
1126
1127 while (is_result_reg_not_empty()) {
1128 val = read_result_register();
1129 }
1130 clear_data_ready();
1131 clear_result_ready();
1132 /* Clear out the data */
1133 while (is_data_requested()) {
1134 val = read_data_register();
1135 }
1136
1137 sony_blocks_left = 0;
1138}
1139
1140/* Called when the timer times out. This will abort the
1141 pending read operation. */
1142static void handle_abort_timeout(unsigned long data)
1143{
1144 pr_debug(PFX "Entering %s\n", __FUNCTION__);
1145 /* If it is in use, ignore it. */
1146 if (down_trylock(&sony_sem) == 0) {
1147 /* We can't use abort_read(), because it will sleep
1148 or schedule in the timer interrupt. Just start
1149 the operation, finish it on the next access to
1150 the drive. */
1151 clear_result_ready();
1152 clear_param_reg();
1153 write_cmd(SONY_ABORT_CMD);
1154
1155 sony_blocks_left = 0;
1156 abort_read_started = 1;
1157 up(&sony_sem);
1158 }
1159 pr_debug(PFX "Leaving %s\n", __FUNCTION__);
1160}
1161
1162/* Actually get one sector of data from the drive. */
1163static void
1164input_data_sector(char *buffer)
1165{
1166 pr_debug(PFX "Entering %s\n", __FUNCTION__);
1167
1168 /* If an XA disk on a CDU31A, skip the first 12 bytes of data from
1169 the disk. The real data is after that. We can use audio_buffer. */
1170 if (sony_xa_mode)
1171 insb(sony_cd_read_reg, audio_buffer, CD_XA_HEAD);
1172
1173 clear_data_ready();
1174
1175 insb(sony_cd_read_reg, buffer, 2048);
1176
1177 /* If an XA disk, we have to clear out the rest of the unused
1178 error correction data. We can use audio_buffer for that. */
1179 if (sony_xa_mode)
1180 insb(sony_cd_read_reg, audio_buffer, CD_XA_TAIL);
1181
1182 pr_debug(PFX "Leaving %s\n", __FUNCTION__);
1183}
1184
1185/* read data from the drive. Note the nsect must be <= 4. */
1186static void
1187read_data_block(char *buffer,
1188 unsigned int block,
1189 unsigned int nblocks,
1190 unsigned char res_reg[], int *res_size)
1191{
1192 unsigned long retry_count;
1193
1194 pr_debug(PFX "Entering %s\n", __FUNCTION__);
1195
1196 res_reg[0] = 0;
1197 res_reg[1] = 0;
1198 *res_size = 0;
1199
1200 /* Wait for the drive to tell us we have something */
1201 retry_count = jiffies + SONY_JIFFIES_TIMEOUT;
1202 while (time_before(jiffies, retry_count) && !(is_data_ready())) {
1203 while (handle_sony_cd_attention());
1204
1205 sony_sleep();
1206 }
1207 if (!(is_data_ready())) {
1208 if (is_result_ready()) {
1209 get_result(res_reg, res_size);
1210 if ((res_reg[0] & 0xf0) != 0x20) {
1211 printk(KERN_NOTICE PFX "Got result that should"
1212 " have been error: %d\n", res_reg[0]);
1213 res_reg[0] = 0x20;
1214 res_reg[1] = SONY_BAD_DATA_ERR;
1215 *res_size = 2;
1216 }
1217 abort_read();
1218 } else {
1219 pr_debug(PFX "timeout out %d\n", __LINE__);
1220 res_reg[0] = 0x20;
1221 res_reg[1] = SONY_TIMEOUT_OP_ERR;
1222 *res_size = 2;
1223 abort_read();
1224 }
1225 } else {
1226 input_data_sector(buffer);
1227 sony_blocks_left -= nblocks;
1228 sony_next_block += nblocks;
1229
1230 /* Wait for the status from the drive. */
1231 retry_count = jiffies + SONY_JIFFIES_TIMEOUT;
1232 while (time_before(jiffies, retry_count)
1233 && !(is_result_ready())) {
1234 while (handle_sony_cd_attention());
1235
1236 sony_sleep();
1237 }
1238
1239 if (!is_result_ready()) {
1240 pr_debug(PFX "timeout out %d\n", __LINE__);
1241 res_reg[0] = 0x20;
1242 res_reg[1] = SONY_TIMEOUT_OP_ERR;
1243 *res_size = 2;
1244 abort_read();
1245 } else {
1246 get_result(res_reg, res_size);
1247
1248 /* If we got a buffer status, handle that. */
1249 if ((res_reg[0] & 0xf0) == 0x50) {
1250
1251 if ((res_reg[0] ==
1252 SONY_NO_CIRC_ERR_BLK_STAT)
1253 || (res_reg[0] ==
1254 SONY_NO_LECC_ERR_BLK_STAT)
1255 || (res_reg[0] ==
1256 SONY_RECOV_LECC_ERR_BLK_STAT)) {
1257 /* nothing here */
1258 } else {
1259 printk(KERN_ERR PFX "Data block "
1260 "error: 0x%x\n", res_reg[0]);
1261 res_reg[0] = 0x20;
1262 res_reg[1] = SONY_BAD_DATA_ERR;
1263 *res_size = 2;
1264 }
1265
1266 /* Final transfer is done for read command, get final result. */
1267 if (sony_blocks_left == 0) {
1268 get_result(res_reg, res_size);
1269 }
1270 } else if ((res_reg[0] & 0xf0) != 0x20) {
1271 /* The drive gave me bad status, I don't know what to do.
1272 Reset the driver and return an error. */
1273 printk(KERN_ERR PFX "Invalid block "
1274 "status: 0x%x\n", res_reg[0]);
1275 restart_on_error();
1276 res_reg[0] = 0x20;
1277 res_reg[1] = SONY_BAD_DATA_ERR;
1278 *res_size = 2;
1279 }
1280 }
1281 }
1282 pr_debug(PFX "Leaving %s at %d\n", __FUNCTION__, __LINE__);
1283}
1284
1285
1286/*
1287 * The OS calls this to perform a read or write operation to the drive.
1288 * Write obviously fail. Reads to a read ahead of sony_buffer_size
1289 * bytes to help speed operations. This especially helps since the OS
1290 * uses 1024 byte blocks and the drive uses 2048 byte blocks. Since most
1291 * data access on a CD is done sequentially, this saves a lot of operations.
1292 */
1293static void do_cdu31a_request(request_queue_t * q)
1294{
1295 struct request *req;
1296 int block, nblock, num_retries;
1297 unsigned char res_reg[12];
1298 unsigned int res_size;
1299
1300 pr_debug(PFX "Entering %s\n", __FUNCTION__);
1301
1302 spin_unlock_irq(q->queue_lock);
1303 if (down_interruptible(&sony_sem)) {
1304 spin_lock_irq(q->queue_lock);
1305 return;
1306 }
1307
1308 /* Get drive status before doing anything. */
1309 while (handle_sony_cd_attention());
1310
1311 /* Make sure we have a valid TOC. */
1312 sony_get_toc();
1313
1314
1315 /* Make sure the timer is cancelled. */
1316 del_timer(&cdu31a_abort_timer);
1317
1318 while (1) {
1319 /*
1320 * The beginning here is stolen from the hard disk driver. I hope
1321 * it's right.
1322 */
1323 req = elv_next_request(q);
1324 if (!req)
1325 goto end_do_cdu31a_request;
1326
1327 if (!sony_spun_up)
1328 scd_spinup();
1329
1330 block = req->sector;
1331 nblock = req->nr_sectors;
1332 pr_debug(PFX "request at block %d, length %d blocks\n",
1333 block, nblock);
1334 if (!sony_toc_read) {
1335 printk(KERN_NOTICE PFX "TOC not read\n");
1336 end_request(req, 0);
1337 continue;
1338 }
1339
1340 /* WTF??? */
1341 if (!blk_fs_request(req)) {
1342 end_request(req, 0);
1343 continue;
1344 }
1345 if (rq_data_dir(req) == WRITE) {
1346 end_request(req, 0);
1347 continue;
1348 }
1349
1350 /*
1351 * If the block address is invalid or the request goes beyond the end of
1352 * the media, return an error.
1353 */
1354 if (((block + nblock) / 4) >= sony_toc.lead_out_start_lba) {
1355 printk(KERN_NOTICE PFX "Request past end of media\n");
1356 end_request(req, 0);
1357 continue;
1358 }
1359
1360 if (nblock > 4)
1361 nblock = 4;
1362 num_retries = 0;
1363
1364 try_read_again:
1365 while (handle_sony_cd_attention());
1366
1367 if (!sony_toc_read) {
1368 printk(KERN_NOTICE PFX "TOC not read\n");
1369 end_request(req, 0);
1370 continue;
1371 }
1372
1373 /* If no data is left to be read from the drive, start the
1374 next request. */
1375 if (sony_blocks_left == 0) {
1376 if (start_request(block / 4, nblock / 4)) {
1377 end_request(req, 0);
1378 continue;
1379 }
1380 }
1381 /* If the requested block is not the next one waiting in
1382 the driver, abort the current operation and start a
1383 new one. */
1384 else if (block != sony_next_block) {
1385 pr_debug(PFX "Read for block %d, expected %d\n",
1386 block, sony_next_block);
1387 abort_read();
1388 if (!sony_toc_read) {
1389 printk(KERN_NOTICE PFX "TOC not read\n");
1390 end_request(req, 0);
1391 continue;
1392 }
1393 if (start_request(block / 4, nblock / 4)) {
1394 printk(KERN_NOTICE PFX "start request failed\n");
1395 end_request(req, 0);
1396 continue;
1397 }
1398 }
1399
1400 read_data_block(req->buffer, block, nblock, res_reg, &res_size);
1401
1402 if (res_reg[0] != 0x20) {
1403 if (!end_that_request_first(req, 1, nblock)) {
1404 spin_lock_irq(q->queue_lock);
1405 blkdev_dequeue_request(req);
1406 end_that_request_last(req, 1);
1407 spin_unlock_irq(q->queue_lock);
1408 }
1409 continue;
1410 }
1411
1412 if (num_retries > MAX_CDU31A_RETRIES) {
1413 end_request(req, 0);
1414 continue;
1415 }
1416
1417 num_retries++;
1418 if (res_reg[1] == SONY_NOT_SPIN_ERR) {
1419 do_sony_cd_cmd(SONY_SPIN_UP_CMD, NULL, 0, res_reg,
1420 &res_size);
1421 } else {
1422 printk(KERN_NOTICE PFX "%s error for block %d, nblock %d\n",
1423 translate_error(res_reg[1]), block, nblock);
1424 }
1425 goto try_read_again;
1426 }
1427 end_do_cdu31a_request:
1428#if 0
1429 /* After finished, cancel any pending operations. */
1430 abort_read();
1431#else
1432 /* Start a timer to time out after a while to disable
1433 the read. */
1434 cdu31a_abort_timer.expires = jiffies + 2 * HZ; /* Wait 2 seconds */
1435 add_timer(&cdu31a_abort_timer);
1436#endif
1437
1438 up(&sony_sem);
1439 spin_lock_irq(q->queue_lock);
1440 pr_debug(PFX "Leaving %s at %d\n", __FUNCTION__, __LINE__);
1441}
1442
1443
1444/*
1445 * Read the table of contents from the drive and set up TOC if
1446 * successful.
1447 */
1448static void sony_get_toc(void)
1449{
1450 unsigned char res_reg[2];
1451 unsigned int res_size;
1452 unsigned char parms[1];
1453 int session;
1454 int num_spin_ups;
1455 int totaltracks = 0;
1456 int mint = 99;
1457 int maxt = 0;
1458
1459 pr_debug(PFX "Entering %s\n", __FUNCTION__);
1460
1461 num_spin_ups = 0;
1462 if (!sony_toc_read) {
1463 respinup_on_gettoc:
1464 /* Ignore the result, since it might error if spinning already. */
1465 do_sony_cd_cmd(SONY_SPIN_UP_CMD, NULL, 0, res_reg,
1466 &res_size);
1467
1468 do_sony_cd_cmd(SONY_READ_TOC_CMD, NULL, 0, res_reg,
1469 &res_size);
1470
1471 /* The drive sometimes returns error 0. I don't know why, but ignore
1472 it. It seems to mean the drive has already done the operation. */
1473 if ((res_size < 2)
1474 || ((res_reg[0] != 0) && (res_reg[1] != 0))) {
1475 /* If the drive is already playing, it's ok. */
1476 if ((res_reg[1] == SONY_AUDIO_PLAYING_ERR)
1477 || (res_reg[1] == 0)) {
1478 goto gettoc_drive_spinning;
1479 }
1480
1481 /* If the drive says it is not spun up (even though we just did it!)
1482 then retry the operation at least a few times. */
1483 if ((res_reg[1] == SONY_NOT_SPIN_ERR)
1484 && (num_spin_ups < MAX_CDU31A_RETRIES)) {
1485 num_spin_ups++;
1486 goto respinup_on_gettoc;
1487 }
1488
1489 printk("cdu31a: Error reading TOC: %x %s\n",
1490 res_reg[0], translate_error(res_reg[1]));
1491 return;
1492 }
1493
1494 gettoc_drive_spinning:
1495
1496 /* The idea here is we keep asking for sessions until the command
1497 fails. Then we know what the last valid session on the disk is.
1498 No need to check session 0, since session 0 is the same as session
1499 1; the command returns different information if you give it 0.
1500 */
1501#if DEBUG
1502 memset(&sony_toc, 0x0e, sizeof(sony_toc));
1503 memset(&single_toc, 0x0f, sizeof(single_toc));
1504#endif
1505 session = 1;
1506 while (1) {
1507/* This seems to slow things down enough to make it work. This
1508 * appears to be a problem in do_sony_cd_cmd. This printk seems
1509 * to address the symptoms... -Erik */
1510 pr_debug(PFX "Trying session %d\n", session);
1511 parms[0] = session;
1512 do_sony_cd_cmd(SONY_READ_TOC_SPEC_CMD,
1513 parms, 1, res_reg, &res_size);
1514
1515 pr_debug(PFX "%2.2x %2.2x\n", res_reg[0], res_reg[1]);
1516
1517 if ((res_size < 2)
1518 || ((res_reg[0] & 0xf0) == 0x20)) {
1519 /* An error reading the TOC, this must be past the last session. */
1520 if (session == 1)
1521 printk
1522 ("Yikes! Couldn't read any sessions!");
1523 break;
1524 }
1525 pr_debug(PFX "Reading session %d\n", session);
1526
1527 parms[0] = session;
1528 do_sony_cd_cmd(SONY_REQ_TOC_DATA_SPEC_CMD,
1529 parms,
1530 1,
1531 (unsigned char *) &single_toc,
1532 &res_size);
1533 if ((res_size < 2)
1534 || ((single_toc.exec_status[0] & 0xf0) ==
1535 0x20)) {
1536 printk(KERN_ERR PFX "Error reading "
1537 "session %d: %x %s\n",
1538 session, single_toc.exec_status[0],
1539 translate_error(single_toc.
1540 exec_status[1]));
1541 /* An error reading the TOC. Return without sony_toc_read
1542 set. */
1543 return;
1544 }
1545 pr_debug(PFX "add0 %01x, con0 %01x, poi0 %02x, "
1546 "1st trk %d, dsktyp %x, dum0 %x\n",
1547 single_toc.address0, single_toc.control0,
1548 single_toc.point0,
1549 bcd_to_int(single_toc.first_track_num),
1550 single_toc.disk_type, single_toc.dummy0);
1551 pr_debug(PFX "add1 %01x, con1 %01x, poi1 %02x, "
1552 "lst trk %d, dummy1 %x, dum2 %x\n",
1553 single_toc.address1, single_toc.control1,
1554 single_toc.point1,
1555 bcd_to_int(single_toc.last_track_num),
1556 single_toc.dummy1, single_toc.dummy2);
1557 pr_debug(PFX "add2 %01x, con2 %01x, poi2 %02x "
1558 "leadout start min %d, sec %d, frame %d\n",
1559 single_toc.address2, single_toc.control2,
1560 single_toc.point2,
1561 bcd_to_int(single_toc.lead_out_start_msf[0]),
1562 bcd_to_int(single_toc.lead_out_start_msf[1]),
1563 bcd_to_int(single_toc.lead_out_start_msf[2]));
1564 if (res_size > 18 && single_toc.pointb0 > 0xaf)
1565 pr_debug(PFX "addb0 %01x, conb0 %01x, poib0 %02x, nextsession min %d, sec %d, frame %d\n"
1566 "#mode5_ptrs %02d, max_start_outer_leadout_msf min %d, sec %d, frame %d\n",
1567 single_toc.addressb0,
1568 single_toc.controlb0,
1569 single_toc.pointb0,
1570 bcd_to_int(single_toc.
1571 next_poss_prog_area_msf
1572 [0]),
1573 bcd_to_int(single_toc.
1574 next_poss_prog_area_msf
1575 [1]),
1576 bcd_to_int(single_toc.
1577 next_poss_prog_area_msf
1578 [2]),
1579 single_toc.num_mode_5_pointers,
1580 bcd_to_int(single_toc.
1581 max_start_outer_leadout_msf
1582 [0]),
1583 bcd_to_int(single_toc.
1584 max_start_outer_leadout_msf
1585 [1]),
1586 bcd_to_int(single_toc.
1587 max_start_outer_leadout_msf
1588 [2]));
1589 if (res_size > 27 && single_toc.pointb1 > 0xaf)
1590 pr_debug(PFX "addb1 %01x, conb1 %01x, poib1 %02x, %x %x %x %x #skipint_ptrs %d, #skiptrkassign %d %x\n",
1591 single_toc.addressb1,
1592 single_toc.controlb1,
1593 single_toc.pointb1,
1594 single_toc.dummyb0_1[0],
1595 single_toc.dummyb0_1[1],
1596 single_toc.dummyb0_1[2],
1597 single_toc.dummyb0_1[3],
1598 single_toc.num_skip_interval_pointers,
1599 single_toc.num_skip_track_assignments,
1600 single_toc.dummyb0_2);
1601 if (res_size > 36 && single_toc.pointb2 > 0xaf)
1602 pr_debug(PFX "addb2 %01x, conb2 %01x, poib2 %02x, %02x %02x %02x %02x %02x %02x %02x\n",
1603 single_toc.addressb2,
1604 single_toc.controlb2,
1605 single_toc.pointb2,
1606 single_toc.tracksb2[0],
1607 single_toc.tracksb2[1],
1608 single_toc.tracksb2[2],
1609 single_toc.tracksb2[3],
1610 single_toc.tracksb2[4],
1611 single_toc.tracksb2[5],
1612 single_toc.tracksb2[6]);
1613 if (res_size > 45 && single_toc.pointb3 > 0xaf)
1614 pr_debug(PFX "addb3 %01x, conb3 %01x, poib3 %02x, %02x %02x %02x %02x %02x %02x %02x\n",
1615 single_toc.addressb3,
1616 single_toc.controlb3,
1617 single_toc.pointb3,
1618 single_toc.tracksb3[0],
1619 single_toc.tracksb3[1],
1620 single_toc.tracksb3[2],
1621 single_toc.tracksb3[3],
1622 single_toc.tracksb3[4],
1623 single_toc.tracksb3[5],
1624 single_toc.tracksb3[6]);
1625 if (res_size > 54 && single_toc.pointb4 > 0xaf)
1626 pr_debug(PFX "addb4 %01x, conb4 %01x, poib4 %02x, %02x %02x %02x %02x %02x %02x %02x\n",
1627 single_toc.addressb4,
1628 single_toc.controlb4,
1629 single_toc.pointb4,
1630 single_toc.tracksb4[0],
1631 single_toc.tracksb4[1],
1632 single_toc.tracksb4[2],
1633 single_toc.tracksb4[3],
1634 single_toc.tracksb4[4],
1635 single_toc.tracksb4[5],
1636 single_toc.tracksb4[6]);
1637 if (res_size > 63 && single_toc.pointc0 > 0xaf)
1638 pr_debug(PFX "addc0 %01x, conc0 %01x, poic0 %02x, %02x %02x %02x %02x %02x %02x %02x\n",
1639 single_toc.addressc0,
1640 single_toc.controlc0,
1641 single_toc.pointc0,
1642 single_toc.dummyc0[0],
1643 single_toc.dummyc0[1],
1644 single_toc.dummyc0[2],
1645 single_toc.dummyc0[3],
1646 single_toc.dummyc0[4],
1647 single_toc.dummyc0[5],
1648 single_toc.dummyc0[6]);
1649#undef DEBUG
1650#define DEBUG 0
1651
1652 sony_toc.lead_out_start_msf[0] =
1653 bcd_to_int(single_toc.lead_out_start_msf[0]);
1654 sony_toc.lead_out_start_msf[1] =
1655 bcd_to_int(single_toc.lead_out_start_msf[1]);
1656 sony_toc.lead_out_start_msf[2] =
1657 bcd_to_int(single_toc.lead_out_start_msf[2]);
1658 sony_toc.lead_out_start_lba =
1659 single_toc.lead_out_start_lba =
1660 msf_to_log(sony_toc.lead_out_start_msf);
1661
1662 /* For points that do not exist, move the data over them
1663 to the right location. */
1664 if (single_toc.pointb0 != 0xb0) {
1665 memmove(((char *) &single_toc) + 27,
1666 ((char *) &single_toc) + 18,
1667 res_size - 18);
1668 res_size += 9;
1669 } else if (res_size > 18) {
1670 sony_toc.lead_out_start_msf[0] =
1671 bcd_to_int(single_toc.
1672 max_start_outer_leadout_msf
1673 [0]);
1674 sony_toc.lead_out_start_msf[1] =
1675 bcd_to_int(single_toc.
1676 max_start_outer_leadout_msf
1677 [1]);
1678 sony_toc.lead_out_start_msf[2] =
1679 bcd_to_int(single_toc.
1680 max_start_outer_leadout_msf
1681 [2]);
1682 sony_toc.lead_out_start_lba =
1683 msf_to_log(sony_toc.
1684 lead_out_start_msf);
1685 }
1686 if (single_toc.pointb1 != 0xb1) {
1687 memmove(((char *) &single_toc) + 36,
1688 ((char *) &single_toc) + 27,
1689 res_size - 27);
1690 res_size += 9;
1691 }
1692 if (single_toc.pointb2 != 0xb2) {
1693 memmove(((char *) &single_toc) + 45,
1694 ((char *) &single_toc) + 36,
1695 res_size - 36);
1696 res_size += 9;
1697 }
1698 if (single_toc.pointb3 != 0xb3) {
1699 memmove(((char *) &single_toc) + 54,
1700 ((char *) &single_toc) + 45,
1701 res_size - 45);
1702 res_size += 9;
1703 }
1704 if (single_toc.pointb4 != 0xb4) {
1705 memmove(((char *) &single_toc) + 63,
1706 ((char *) &single_toc) + 54,
1707 res_size - 54);
1708 res_size += 9;
1709 }
1710 if (single_toc.pointc0 != 0xc0) {
1711 memmove(((char *) &single_toc) + 72,
1712 ((char *) &single_toc) + 63,
1713 res_size - 63);
1714 res_size += 9;
1715 }
1716#if DEBUG
1717 printk(PRINT_INFO PFX "start track lba %u, "
1718 "leadout start lba %u\n",
1719 single_toc.start_track_lba,
1720 single_toc.lead_out_start_lba);
1721 {
1722 int i;
1723 for (i = 0;
1724 i <
1725 1 +
1726 bcd_to_int(single_toc.last_track_num)
1727 -
1728 bcd_to_int(single_toc.
1729 first_track_num); i++) {
1730 printk(KERN_INFO PFX "trk %02d: add 0x%01x, con 0x%01x, track %02d, start min %02d, sec %02d, frame %02d\n",
1731 i,
1732 single_toc.tracks[i].address,
1733 single_toc.tracks[i].control,
1734 bcd_to_int(single_toc.
1735 tracks[i].track),
1736 bcd_to_int(single_toc.
1737 tracks[i].
1738 track_start_msf
1739 [0]),
1740 bcd_to_int(single_toc.
1741 tracks[i].
1742 track_start_msf
1743 [1]),
1744 bcd_to_int(single_toc.
1745 tracks[i].
1746 track_start_msf
1747 [2]));
1748 if (mint >
1749 bcd_to_int(single_toc.
1750 tracks[i].track))
1751 mint =
1752 bcd_to_int(single_toc.
1753 tracks[i].
1754 track);
1755 if (maxt <
1756 bcd_to_int(single_toc.
1757 tracks[i].track))
1758 maxt =
1759 bcd_to_int(single_toc.
1760 tracks[i].
1761 track);
1762 }
1763 printk(KERN_INFO PFX "min track number %d, "
1764 "max track number %d\n",
1765 mint, maxt);
1766 }
1767#endif
1768
1769 /* prepare a special table of contents for a CD-I disc. They don't have one. */
1770 if (single_toc.disk_type == 0x10 &&
1771 single_toc.first_track_num == 2 &&
1772 single_toc.last_track_num == 2 /* CD-I */ ) {
1773 sony_toc.tracks[totaltracks].address = 1;
1774 sony_toc.tracks[totaltracks].control = 4; /* force data tracks */
1775 sony_toc.tracks[totaltracks].track = 1;
1776 sony_toc.tracks[totaltracks].
1777 track_start_msf[0] = 0;
1778 sony_toc.tracks[totaltracks].
1779 track_start_msf[1] = 2;
1780 sony_toc.tracks[totaltracks].
1781 track_start_msf[2] = 0;
1782 mint = maxt = 1;
1783 totaltracks++;
1784 } else
1785 /* gather track entries from this session */
1786 {
1787 int i;
1788 for (i = 0;
1789 i <
1790 1 +
1791 bcd_to_int(single_toc.last_track_num)
1792 -
1793 bcd_to_int(single_toc.
1794 first_track_num);
1795 i++, totaltracks++) {
1796 sony_toc.tracks[totaltracks].
1797 address =
1798 single_toc.tracks[i].address;
1799 sony_toc.tracks[totaltracks].
1800 control =
1801 single_toc.tracks[i].control;
1802 sony_toc.tracks[totaltracks].
1803 track =
1804 bcd_to_int(single_toc.
1805 tracks[i].track);
1806 sony_toc.tracks[totaltracks].
1807 track_start_msf[0] =
1808 bcd_to_int(single_toc.
1809 tracks[i].
1810 track_start_msf[0]);
1811 sony_toc.tracks[totaltracks].
1812 track_start_msf[1] =
1813 bcd_to_int(single_toc.
1814 tracks[i].
1815 track_start_msf[1]);
1816 sony_toc.tracks[totaltracks].
1817 track_start_msf[2] =
1818 bcd_to_int(single_toc.
1819 tracks[i].
1820 track_start_msf[2]);
1821 if (i == 0)
1822 single_toc.
1823 start_track_lba =
1824 msf_to_log(sony_toc.
1825 tracks
1826 [totaltracks].
1827 track_start_msf);
1828 if (mint >
1829 sony_toc.tracks[totaltracks].
1830 track)
1831 mint =
1832 sony_toc.
1833 tracks[totaltracks].
1834 track;
1835 if (maxt <
1836 sony_toc.tracks[totaltracks].
1837 track)
1838 maxt =
1839 sony_toc.
1840 tracks[totaltracks].
1841 track;
1842 }
1843 }
1844 sony_toc.first_track_num = mint;
1845 sony_toc.last_track_num = maxt;
1846 /* Disk type of last session wins. For example:
1847 CD-Extra has disk type 0 for the first session, so
1848 a dumb HiFi CD player thinks it is a plain audio CD.
1849 We are interested in the disk type of the last session,
1850 which is 0x20 (XA) for CD-Extra, so we can access the
1851 data track ... */
1852 sony_toc.disk_type = single_toc.disk_type;
1853 sony_toc.sessions = session;
1854
1855 /* don't believe everything :-) */
1856 if (session == 1)
1857 single_toc.start_track_lba = 0;
1858 sony_toc.start_track_lba =
1859 single_toc.start_track_lba;
1860
1861 if (session > 1 && single_toc.pointb0 == 0xb0 &&
1862 sony_toc.lead_out_start_lba ==
1863 single_toc.lead_out_start_lba) {
1864 break;
1865 }
1866
1867 /* Let's not get carried away... */
1868 if (session > 40) {
1869 printk(KERN_NOTICE PFX "too many sessions: "
1870 "%d\n", session);
1871 break;
1872 }
1873 session++;
1874 }
1875 sony_toc.track_entries = totaltracks;
1876 /* add one entry for the LAST track with track number CDROM_LEADOUT */
1877 sony_toc.tracks[totaltracks].address = single_toc.address2;
1878 sony_toc.tracks[totaltracks].control = single_toc.control2;
1879 sony_toc.tracks[totaltracks].track = CDROM_LEADOUT;
1880 sony_toc.tracks[totaltracks].track_start_msf[0] =
1881 sony_toc.lead_out_start_msf[0];
1882 sony_toc.tracks[totaltracks].track_start_msf[1] =
1883 sony_toc.lead_out_start_msf[1];
1884 sony_toc.tracks[totaltracks].track_start_msf[2] =
1885 sony_toc.lead_out_start_msf[2];
1886
1887 sony_toc_read = 1;
1888
1889 pr_debug(PFX "Disk session %d, start track: %d, "
1890 "stop track: %d\n",
1891 session, single_toc.start_track_lba,
1892 single_toc.lead_out_start_lba);
1893 }
1894 pr_debug(PFX "Leaving %s\n", __FUNCTION__);
1895}
1896
1897
1898/*
1899 * Uniform cdrom interface function
1900 * return multisession offset and sector information
1901 */
1902static int scd_get_last_session(struct cdrom_device_info *cdi,
1903 struct cdrom_multisession *ms_info)
1904{
1905 if (ms_info == NULL)
1906 return 1;
1907
1908 if (!sony_toc_read) {
1909 if (down_interruptible(&sony_sem))
1910 return -ERESTARTSYS;
1911 sony_get_toc();
1912 up(&sony_sem);
1913 }
1914
1915 ms_info->addr_format = CDROM_LBA;
1916 ms_info->addr.lba = sony_toc.start_track_lba;
1917 ms_info->xa_flag = sony_toc.disk_type == SONY_XA_DISK_TYPE ||
1918 sony_toc.disk_type == 0x10 /* CDI */ ;
1919
1920 return 0;
1921}
1922
1923/*
1924 * Search for a specific track in the table of contents.
1925 */
1926static int find_track(int track)
1927{
1928 int i;
1929
1930 for (i = 0; i <= sony_toc.track_entries; i++) {
1931 if (sony_toc.tracks[i].track == track) {
1932 return i;
1933 }
1934 }
1935
1936 return -1;
1937}
1938
1939
1940/*
1941 * Read the subcode and put it in last_sony_subcode for future use.
1942 */
1943static int read_subcode(void)
1944{
1945 unsigned int res_size;
1946
1947
1948 do_sony_cd_cmd(SONY_REQ_SUBCODE_ADDRESS_CMD,
1949 NULL,
1950 0, (unsigned char *) &last_sony_subcode, &res_size);
1951 if ((res_size < 2)
1952 || ((last_sony_subcode.exec_status[0] & 0xf0) == 0x20)) {
1953 printk(KERN_ERR PFX "Sony CDROM error %s (read_subcode)\n",
1954 translate_error(last_sony_subcode.exec_status[1]));
1955 return -EIO;
1956 }
1957
1958 last_sony_subcode.track_num =
1959 bcd_to_int(last_sony_subcode.track_num);
1960 last_sony_subcode.index_num =
1961 bcd_to_int(last_sony_subcode.index_num);
1962 last_sony_subcode.abs_msf[0] =
1963 bcd_to_int(last_sony_subcode.abs_msf[0]);
1964 last_sony_subcode.abs_msf[1] =
1965 bcd_to_int(last_sony_subcode.abs_msf[1]);
1966 last_sony_subcode.abs_msf[2] =
1967 bcd_to_int(last_sony_subcode.abs_msf[2]);
1968
1969 last_sony_subcode.rel_msf[0] =
1970 bcd_to_int(last_sony_subcode.rel_msf[0]);
1971 last_sony_subcode.rel_msf[1] =
1972 bcd_to_int(last_sony_subcode.rel_msf[1]);
1973 last_sony_subcode.rel_msf[2] =
1974 bcd_to_int(last_sony_subcode.rel_msf[2]);
1975 return 0;
1976}
1977
1978/*
1979 * Uniform cdrom interface function
1980 * return the media catalog number found on some older audio cds
1981 */
1982static int
1983scd_get_mcn(struct cdrom_device_info *cdi, struct cdrom_mcn *mcn)
1984{
1985 unsigned char resbuffer[2 + 14];
1986 unsigned char *mcnp = mcn->medium_catalog_number;
1987 unsigned char *resp = resbuffer + 3;
1988 unsigned int res_size;
1989
1990 memset(mcn->medium_catalog_number, 0, 14);
1991 if (down_interruptible(&sony_sem))
1992 return -ERESTARTSYS;
1993 do_sony_cd_cmd(SONY_REQ_UPC_EAN_CMD,
1994 NULL, 0, resbuffer, &res_size);
1995 up(&sony_sem);
1996 if ((res_size < 2) || ((resbuffer[0] & 0xf0) == 0x20));
1997 else {
1998 /* packed bcd to single ASCII digits */
1999 *mcnp++ = (*resp >> 4) + '0';
2000 *mcnp++ = (*resp++ & 0x0f) + '0';
2001 *mcnp++ = (*resp >> 4) + '0';
2002 *mcnp++ = (*resp++ & 0x0f) + '0';
2003 *mcnp++ = (*resp >> 4) + '0';
2004 *mcnp++ = (*resp++ & 0x0f) + '0';
2005 *mcnp++ = (*resp >> 4) + '0';
2006 *mcnp++ = (*resp++ & 0x0f) + '0';
2007 *mcnp++ = (*resp >> 4) + '0';
2008 *mcnp++ = (*resp++ & 0x0f) + '0';
2009 *mcnp++ = (*resp >> 4) + '0';
2010 *mcnp++ = (*resp++ & 0x0f) + '0';
2011 *mcnp++ = (*resp >> 4) + '0';
2012 }
2013 *mcnp = '\0';
2014 return 0;
2015}
2016
2017
2018/*
2019 * Get the subchannel info like the CDROMSUBCHNL command wants to see it. If
2020 * the drive is playing, the subchannel needs to be read (since it would be
2021 * changing). If the drive is paused or completed, the subcode information has
2022 * already been stored, just use that. The ioctl call wants things in decimal
2023 * (not BCD), so all the conversions are done.
2024 */
2025static int sony_get_subchnl_info(struct cdrom_subchnl *schi)
2026{
2027 /* Get attention stuff */
2028 while (handle_sony_cd_attention());
2029
2030 sony_get_toc();
2031 if (!sony_toc_read) {
2032 return -EIO;
2033 }
2034
2035 switch (sony_audio_status) {
2036 case CDROM_AUDIO_NO_STATUS:
2037 case CDROM_AUDIO_PLAY:
2038 if (read_subcode() < 0) {
2039 return -EIO;
2040 }
2041 break;
2042
2043 case CDROM_AUDIO_PAUSED:
2044 case CDROM_AUDIO_COMPLETED:
2045 break;
2046
2047#if 0
2048 case CDROM_AUDIO_NO_STATUS:
2049 schi->cdsc_audiostatus = sony_audio_status;
2050 return 0;
2051 break;
2052#endif
2053 case CDROM_AUDIO_INVALID:
2054 case CDROM_AUDIO_ERROR:
2055 default:
2056 return -EIO;
2057 }
2058
2059 schi->cdsc_audiostatus = sony_audio_status;
2060 schi->cdsc_adr = last_sony_subcode.address;
2061 schi->cdsc_ctrl = last_sony_subcode.control;
2062 schi->cdsc_trk = last_sony_subcode.track_num;
2063 schi->cdsc_ind = last_sony_subcode.index_num;
2064 if (schi->cdsc_format == CDROM_MSF) {
2065 schi->cdsc_absaddr.msf.minute =
2066 last_sony_subcode.abs_msf[0];
2067 schi->cdsc_absaddr.msf.second =
2068 last_sony_subcode.abs_msf[1];
2069 schi->cdsc_absaddr.msf.frame =
2070 last_sony_subcode.abs_msf[2];
2071
2072 schi->cdsc_reladdr.msf.minute =
2073 last_sony_subcode.rel_msf[0];
2074 schi->cdsc_reladdr.msf.second =
2075 last_sony_subcode.rel_msf[1];
2076 schi->cdsc_reladdr.msf.frame =
2077 last_sony_subcode.rel_msf[2];
2078 } else if (schi->cdsc_format == CDROM_LBA) {
2079 schi->cdsc_absaddr.lba =
2080 msf_to_log(last_sony_subcode.abs_msf);
2081 schi->cdsc_reladdr.lba =
2082 msf_to_log(last_sony_subcode.rel_msf);
2083 }
2084
2085 return 0;
2086}
2087
2088/* Get audio data from the drive. This is fairly complex because I
2089 am looking for status and data at the same time, but if I get status
2090 then I just look for data. I need to get the status immediately so
2091 the switch from audio to data tracks will happen quickly. */
2092static void
2093read_audio_data(char *buffer, unsigned char res_reg[], int *res_size)
2094{
2095 unsigned long retry_count;
2096 int result_read;
2097
2098
2099 res_reg[0] = 0;
2100 res_reg[1] = 0;
2101 *res_size = 0;
2102 result_read = 0;
2103
2104 /* Wait for the drive to tell us we have something */
2105 retry_count = jiffies + SONY_JIFFIES_TIMEOUT;
2106 continue_read_audio_wait:
2107 while (time_before(jiffies, retry_count) && !(is_data_ready())
2108 && !(is_result_ready() || result_read)) {
2109 while (handle_sony_cd_attention());
2110
2111 sony_sleep();
2112 }
2113 if (!(is_data_ready())) {
2114 if (is_result_ready() && !result_read) {
2115 get_result(res_reg, res_size);
2116
2117 /* Read block status and continue waiting for data. */
2118 if ((res_reg[0] & 0xf0) == 0x50) {
2119 result_read = 1;
2120 goto continue_read_audio_wait;
2121 }
2122 /* Invalid data from the drive. Shut down the operation. */
2123 else if ((res_reg[0] & 0xf0) != 0x20) {
2124 printk(KERN_WARNING PFX "Got result that "
2125 "should have been error: %d\n",
2126 res_reg[0]);
2127 res_reg[0] = 0x20;
2128 res_reg[1] = SONY_BAD_DATA_ERR;
2129 *res_size = 2;
2130 }
2131 abort_read();
2132 } else {
2133 pr_debug(PFX "timeout out %d\n", __LINE__);
2134 res_reg[0] = 0x20;
2135 res_reg[1] = SONY_TIMEOUT_OP_ERR;
2136 *res_size = 2;
2137 abort_read();
2138 }
2139 } else {
2140 clear_data_ready();
2141
2142 /* If data block, then get 2340 bytes offset by 12. */
2143 if (sony_raw_data_mode) {
2144 insb(sony_cd_read_reg, buffer + CD_XA_HEAD,
2145 CD_FRAMESIZE_RAW1);
2146 } else {
2147 /* Audio gets the whole 2352 bytes. */
2148 insb(sony_cd_read_reg, buffer, CD_FRAMESIZE_RAW);
2149 }
2150
2151 /* If I haven't already gotten the result, get it now. */
2152 if (!result_read) {
2153 /* Wait for the drive to tell us we have something */
2154 retry_count = jiffies + SONY_JIFFIES_TIMEOUT;
2155 while (time_before(jiffies, retry_count)
2156 && !(is_result_ready())) {
2157 while (handle_sony_cd_attention());
2158
2159 sony_sleep();
2160 }
2161
2162 if (!is_result_ready()) {
2163 pr_debug(PFX "timeout out %d\n", __LINE__);
2164 res_reg[0] = 0x20;
2165 res_reg[1] = SONY_TIMEOUT_OP_ERR;
2166 *res_size = 2;
2167 abort_read();
2168 return;
2169 } else {
2170 get_result(res_reg, res_size);
2171 }
2172 }
2173
2174 if ((res_reg[0] & 0xf0) == 0x50) {
2175 if ((res_reg[0] == SONY_NO_CIRC_ERR_BLK_STAT)
2176 || (res_reg[0] == SONY_NO_LECC_ERR_BLK_STAT)
2177 || (res_reg[0] == SONY_RECOV_LECC_ERR_BLK_STAT)
2178 || (res_reg[0] == SONY_NO_ERR_DETECTION_STAT)) {
2179 /* Ok, nothing to do. */
2180 } else {
2181 printk(KERN_ERR PFX "Data block error: 0x%x\n",
2182 res_reg[0]);
2183 res_reg[0] = 0x20;
2184 res_reg[1] = SONY_BAD_DATA_ERR;
2185 *res_size = 2;
2186 }
2187 } else if ((res_reg[0] & 0xf0) != 0x20) {
2188 /* The drive gave me bad status, I don't know what to do.
2189 Reset the driver and return an error. */
2190 printk(KERN_NOTICE PFX "Invalid block status: 0x%x\n",
2191 res_reg[0]);
2192 restart_on_error();
2193 res_reg[0] = 0x20;
2194 res_reg[1] = SONY_BAD_DATA_ERR;
2195 *res_size = 2;
2196 }
2197 }
2198}
2199
2200/* Perform a raw data read. This will automatically detect the
2201 track type and read the proper data (audio or data). */
2202static int read_audio(struct cdrom_read_audio *ra)
2203{
2204 int retval;
2205 unsigned char params[2];
2206 unsigned char res_reg[12];
2207 unsigned int res_size;
2208 unsigned int cframe;
2209
2210 if (down_interruptible(&sony_sem))
2211 return -ERESTARTSYS;
2212 if (!sony_spun_up)
2213 scd_spinup();
2214
2215 /* Set the drive to do raw operations. */
2216 params[0] = SONY_SD_DECODE_PARAM;
2217 params[1] = 0x06 | sony_raw_data_mode;
2218 do_sony_cd_cmd(SONY_SET_DRIVE_PARAM_CMD,
2219 params, 2, res_reg, &res_size);
2220 if ((res_size < 2) || ((res_reg[0] & 0xf0) == 0x20)) {
2221 printk(KERN_ERR PFX "Unable to set decode params: 0x%2.2x\n",
2222 res_reg[1]);
2223 retval = -EIO;
2224 goto out_up;
2225 }
2226
2227 /* From here down, we have to goto exit_read_audio instead of returning
2228 because the drive parameters have to be set back to data before
2229 return. */
2230
2231 retval = 0;
2232 if (start_request(ra->addr.lba, ra->nframes)) {
2233 retval = -EIO;
2234 goto exit_read_audio;
2235 }
2236
2237 /* For every requested frame. */
2238 cframe = 0;
2239 while (cframe < ra->nframes) {
2240 read_audio_data(audio_buffer, res_reg, &res_size);
2241 if ((res_reg[0] & 0xf0) == 0x20) {
2242 if (res_reg[1] == SONY_BAD_DATA_ERR) {
2243 printk(KERN_ERR PFX "Data error on audio "
2244 "sector %d\n",
2245 ra->addr.lba + cframe);
2246 } else if (res_reg[1] == SONY_ILL_TRACK_R_ERR) {
2247 /* Illegal track type, change track types and start over. */
2248 sony_raw_data_mode =
2249 (sony_raw_data_mode) ? 0 : 1;
2250
2251 /* Set the drive mode. */
2252 params[0] = SONY_SD_DECODE_PARAM;
2253 params[1] = 0x06 | sony_raw_data_mode;
2254 do_sony_cd_cmd(SONY_SET_DRIVE_PARAM_CMD,
2255 params,
2256 2, res_reg, &res_size);
2257 if ((res_size < 2)
2258 || ((res_reg[0] & 0xf0) == 0x20)) {
2259 printk(KERN_ERR PFX "Unable to set "
2260 "decode params: 0x%2.2x\n",
2261 res_reg[1]);
2262 retval = -EIO;
2263 goto exit_read_audio;
2264 }
2265
2266 /* Restart the request on the current frame. */
2267 if (start_request
2268 (ra->addr.lba + cframe,
2269 ra->nframes - cframe)) {
2270 retval = -EIO;
2271 goto exit_read_audio;
2272 }
2273
2274 /* Don't go back to the top because don't want to get into
2275 and infinite loop. A lot of code gets duplicated, but
2276 that's no big deal, I don't guess. */
2277 read_audio_data(audio_buffer, res_reg,
2278 &res_size);
2279 if ((res_reg[0] & 0xf0) == 0x20) {
2280 if (res_reg[1] ==
2281 SONY_BAD_DATA_ERR) {
2282 printk(KERN_ERR PFX "Data error"
2283 " on audio sector %d\n",
2284 ra->addr.lba +
2285 cframe);
2286 } else {
2287 printk(KERN_ERR PFX "Error reading audio data on sector %d: %s\n",
2288 ra->addr.lba + cframe,
2289 translate_error
2290 (res_reg[1]));
2291 retval = -EIO;
2292 goto exit_read_audio;
2293 }
2294 } else if (copy_to_user(ra->buf +
2295 (CD_FRAMESIZE_RAW
2296 * cframe),
2297 audio_buffer,
2298 CD_FRAMESIZE_RAW)) {
2299 retval = -EFAULT;
2300 goto exit_read_audio;
2301 }
2302 } else {
2303 printk(KERN_ERR PFX "Error reading audio "
2304 "data on sector %d: %s\n",
2305 ra->addr.lba + cframe,
2306 translate_error(res_reg[1]));
2307 retval = -EIO;
2308 goto exit_read_audio;
2309 }
2310 } else if (copy_to_user(ra->buf + (CD_FRAMESIZE_RAW * cframe),
2311 (char *)audio_buffer,
2312 CD_FRAMESIZE_RAW)) {
2313 retval = -EFAULT;
2314 goto exit_read_audio;
2315 }
2316
2317 cframe++;
2318 }
2319
2320 get_result(res_reg, &res_size);
2321 if ((res_reg[0] & 0xf0) == 0x20) {
2322 printk(KERN_ERR PFX "Error return from audio read: %s\n",
2323 translate_error(res_reg[1]));
2324 retval = -EIO;
2325 goto exit_read_audio;
2326 }
2327
2328 exit_read_audio:
2329
2330 /* Set the drive mode back to the proper one for the disk. */
2331 params[0] = SONY_SD_DECODE_PARAM;
2332 if (!sony_xa_mode) {
2333 params[1] = 0x0f;
2334 } else {
2335 params[1] = 0x07;
2336 }
2337 do_sony_cd_cmd(SONY_SET_DRIVE_PARAM_CMD,
2338 params, 2, res_reg, &res_size);
2339 if ((res_size < 2) || ((res_reg[0] & 0xf0) == 0x20)) {
2340 printk(KERN_ERR PFX "Unable to reset decode params: 0x%2.2x\n",
2341 res_reg[1]);
2342 retval = -EIO;
2343 }
2344
2345 out_up:
2346 up(&sony_sem);
2347
2348 return retval;
2349}
2350
2351static int
2352do_sony_cd_cmd_chk(const char *name,
2353 unsigned char cmd,
2354 unsigned char *params,
2355 unsigned int num_params,
2356 unsigned char *result_buffer, unsigned int *result_size)
2357{
2358 do_sony_cd_cmd(cmd, params, num_params, result_buffer,
2359 result_size);
2360 if ((*result_size < 2) || ((result_buffer[0] & 0xf0) == 0x20)) {
2361 printk(KERN_ERR PFX "Error %s (CDROM%s)\n",
2362 translate_error(result_buffer[1]), name);
2363 return -EIO;
2364 }
2365 return 0;
2366}
2367
2368/*
2369 * Uniform cdrom interface function
2370 * open the tray
2371 */
2372static int scd_tray_move(struct cdrom_device_info *cdi, int position)
2373{
2374 int retval;
2375
2376 if (down_interruptible(&sony_sem))
2377 return -ERESTARTSYS;
2378 if (position == 1 /* open tray */ ) {
2379 unsigned char res_reg[12];
2380 unsigned int res_size;
2381
2382 do_sony_cd_cmd(SONY_AUDIO_STOP_CMD, NULL, 0, res_reg,
2383 &res_size);
2384 do_sony_cd_cmd(SONY_SPIN_DOWN_CMD, NULL, 0, res_reg,
2385 &res_size);
2386
2387 sony_audio_status = CDROM_AUDIO_INVALID;
2388 retval = do_sony_cd_cmd_chk("EJECT", SONY_EJECT_CMD, NULL, 0,
2389 res_reg, &res_size);
2390 } else {
2391 if (0 == scd_spinup())
2392 sony_spun_up = 1;
2393 retval = 0;
2394 }
2395 up(&sony_sem);
2396 return retval;
2397}
2398
2399/*
2400 * The big ugly ioctl handler.
2401 */
2402static int scd_audio_ioctl(struct cdrom_device_info *cdi,
2403 unsigned int cmd, void *arg)
2404{
2405 unsigned char res_reg[12];
2406 unsigned int res_size;
2407 unsigned char params[7];
2408 int i, retval;
2409
2410 if (down_interruptible(&sony_sem))
2411 return -ERESTARTSYS;
2412 switch (cmd) {
2413 case CDROMSTART: /* Spin up the drive */
2414 retval = do_sony_cd_cmd_chk("START", SONY_SPIN_UP_CMD, NULL,
2415 0, res_reg, &res_size);
2416 break;
2417
2418 case CDROMSTOP: /* Spin down the drive */
2419 do_sony_cd_cmd(SONY_AUDIO_STOP_CMD, NULL, 0, res_reg,
2420 &res_size);
2421
2422 /*
2423 * Spin the drive down, ignoring the error if the disk was
2424 * already not spinning.
2425 */
2426 sony_audio_status = CDROM_AUDIO_NO_STATUS;
2427 retval = do_sony_cd_cmd_chk("STOP", SONY_SPIN_DOWN_CMD, NULL,
2428 0, res_reg, &res_size);
2429 break;
2430
2431 case CDROMPAUSE: /* Pause the drive */
2432 if (do_sony_cd_cmd_chk
2433 ("PAUSE", SONY_AUDIO_STOP_CMD, NULL, 0, res_reg,
2434 &res_size)) {
2435 retval = -EIO;
2436 break;
2437 }
2438 /* Get the current position and save it for resuming */
2439 if (read_subcode() < 0) {
2440 retval = -EIO;
2441 break;
2442 }
2443 cur_pos_msf[0] = last_sony_subcode.abs_msf[0];
2444 cur_pos_msf[1] = last_sony_subcode.abs_msf[1];
2445 cur_pos_msf[2] = last_sony_subcode.abs_msf[2];
2446 sony_audio_status = CDROM_AUDIO_PAUSED;
2447 retval = 0;
2448 break;
2449
2450 case CDROMRESUME: /* Start the drive after being paused */
2451 if (sony_audio_status != CDROM_AUDIO_PAUSED) {
2452 retval = -EINVAL;
2453 break;
2454 }
2455
2456 do_sony_cd_cmd(SONY_SPIN_UP_CMD, NULL, 0, res_reg,
2457 &res_size);
2458
2459 /* Start the drive at the saved position. */
2460 params[1] = int_to_bcd(cur_pos_msf[0]);
2461 params[2] = int_to_bcd(cur_pos_msf[1]);
2462 params[3] = int_to_bcd(cur_pos_msf[2]);
2463 params[4] = int_to_bcd(final_pos_msf[0]);
2464 params[5] = int_to_bcd(final_pos_msf[1]);
2465 params[6] = int_to_bcd(final_pos_msf[2]);
2466 params[0] = 0x03;
2467 if (do_sony_cd_cmd_chk
2468 ("RESUME", SONY_AUDIO_PLAYBACK_CMD, params, 7, res_reg,
2469 &res_size) < 0) {
2470 retval = -EIO;
2471 break;
2472 }
2473 sony_audio_status = CDROM_AUDIO_PLAY;
2474 retval = 0;
2475 break;
2476
2477 case CDROMPLAYMSF: /* Play starting at the given MSF address. */
2478 do_sony_cd_cmd(SONY_SPIN_UP_CMD, NULL, 0, res_reg,
2479 &res_size);
2480
2481 /* The parameters are given in int, must be converted */
2482 for (i = 1; i < 7; i++) {
2483 params[i] =
2484 int_to_bcd(((unsigned char *) arg)[i - 1]);
2485 }
2486 params[0] = 0x03;
2487 if (do_sony_cd_cmd_chk
2488 ("PLAYMSF", SONY_AUDIO_PLAYBACK_CMD, params, 7,
2489 res_reg, &res_size) < 0) {
2490 retval = -EIO;
2491 break;
2492 }
2493
2494 /* Save the final position for pauses and resumes */
2495 final_pos_msf[0] = bcd_to_int(params[4]);
2496 final_pos_msf[1] = bcd_to_int(params[5]);
2497 final_pos_msf[2] = bcd_to_int(params[6]);
2498 sony_audio_status = CDROM_AUDIO_PLAY;
2499 retval = 0;
2500 break;
2501
2502 case CDROMREADTOCHDR: /* Read the table of contents header */
2503 {
2504 struct cdrom_tochdr *hdr;
2505
2506 sony_get_toc();
2507 if (!sony_toc_read) {
2508 retval = -EIO;
2509 break;
2510 }
2511
2512 hdr = (struct cdrom_tochdr *) arg;
2513 hdr->cdth_trk0 = sony_toc.first_track_num;
2514 hdr->cdth_trk1 = sony_toc.last_track_num;
2515 }
2516 retval = 0;
2517 break;
2518
2519 case CDROMREADTOCENTRY: /* Read a given table of contents entry */
2520 {
2521 struct cdrom_tocentry *entry;
2522 int track_idx;
2523 unsigned char *msf_val = NULL;
2524
2525 sony_get_toc();
2526 if (!sony_toc_read) {
2527 retval = -EIO;
2528 break;
2529 }
2530
2531 entry = (struct cdrom_tocentry *) arg;
2532
2533 track_idx = find_track(entry->cdte_track);
2534 if (track_idx < 0) {
2535 retval = -EINVAL;
2536 break;
2537 }
2538
2539 entry->cdte_adr =
2540 sony_toc.tracks[track_idx].address;
2541 entry->cdte_ctrl =
2542 sony_toc.tracks[track_idx].control;
2543 msf_val =
2544 sony_toc.tracks[track_idx].track_start_msf;
2545
2546 /* Logical buffer address or MSF format requested? */
2547 if (entry->cdte_format == CDROM_LBA) {
2548 entry->cdte_addr.lba = msf_to_log(msf_val);
2549 } else if (entry->cdte_format == CDROM_MSF) {
2550 entry->cdte_addr.msf.minute = *msf_val;
2551 entry->cdte_addr.msf.second =
2552 *(msf_val + 1);
2553 entry->cdte_addr.msf.frame =
2554 *(msf_val + 2);
2555 }
2556 }
2557 retval = 0;
2558 break;
2559
2560 case CDROMPLAYTRKIND: /* Play a track. This currently ignores index. */
2561 {
2562 struct cdrom_ti *ti = (struct cdrom_ti *) arg;
2563 int track_idx;
2564
2565 sony_get_toc();
2566 if (!sony_toc_read) {
2567 retval = -EIO;
2568 break;
2569 }
2570
2571 if ((ti->cdti_trk0 < sony_toc.first_track_num)
2572 || (ti->cdti_trk0 > sony_toc.last_track_num)
2573 || (ti->cdti_trk1 < ti->cdti_trk0)) {
2574 retval = -EINVAL;
2575 break;
2576 }
2577
2578 track_idx = find_track(ti->cdti_trk0);
2579 if (track_idx < 0) {
2580 retval = -EINVAL;
2581 break;
2582 }
2583 params[1] =
2584 int_to_bcd(sony_toc.tracks[track_idx].
2585 track_start_msf[0]);
2586 params[2] =
2587 int_to_bcd(sony_toc.tracks[track_idx].
2588 track_start_msf[1]);
2589 params[3] =
2590 int_to_bcd(sony_toc.tracks[track_idx].
2591 track_start_msf[2]);
2592
2593 /*
2594 * If we want to stop after the last track, use the lead-out
2595 * MSF to do that.
2596 */
2597 if (ti->cdti_trk1 >= sony_toc.last_track_num) {
2598 track_idx = find_track(CDROM_LEADOUT);
2599 } else {
2600 track_idx = find_track(ti->cdti_trk1 + 1);
2601 }
2602 if (track_idx < 0) {
2603 retval = -EINVAL;
2604 break;
2605 }
2606 params[4] =
2607 int_to_bcd(sony_toc.tracks[track_idx].
2608 track_start_msf[0]);
2609 params[5] =
2610 int_to_bcd(sony_toc.tracks[track_idx].
2611 track_start_msf[1]);
2612 params[6] =
2613 int_to_bcd(sony_toc.tracks[track_idx].
2614 track_start_msf[2]);
2615 params[0] = 0x03;
2616
2617 do_sony_cd_cmd(SONY_SPIN_UP_CMD, NULL, 0, res_reg,
2618 &res_size);
2619
2620 do_sony_cd_cmd(SONY_AUDIO_PLAYBACK_CMD, params, 7,
2621 res_reg, &res_size);
2622
2623 if ((res_size < 2)
2624 || ((res_reg[0] & 0xf0) == 0x20)) {
2625 printk(KERN_ERR PFX
2626 "Params: %x %x %x %x %x %x %x\n",
2627 params[0], params[1], params[2],
2628 params[3], params[4], params[5],
2629 params[6]);
2630 printk(KERN_ERR PFX
2631 "Error %s (CDROMPLAYTRKIND)\n",
2632 translate_error(res_reg[1]));
2633 retval = -EIO;
2634 break;
2635 }
2636
2637 /* Save the final position for pauses and resumes */
2638 final_pos_msf[0] = bcd_to_int(params[4]);
2639 final_pos_msf[1] = bcd_to_int(params[5]);
2640 final_pos_msf[2] = bcd_to_int(params[6]);
2641 sony_audio_status = CDROM_AUDIO_PLAY;
2642 retval = 0;
2643 break;
2644 }
2645
2646 case CDROMVOLCTRL: /* Volume control. What volume does this change, anyway? */
2647 {
2648 struct cdrom_volctrl *volctrl =
2649 (struct cdrom_volctrl *) arg;
2650
2651 params[0] = SONY_SD_AUDIO_VOLUME;
2652 params[1] = volctrl->channel0;
2653 params[2] = volctrl->channel1;
2654 retval = do_sony_cd_cmd_chk("VOLCTRL",
2655 SONY_SET_DRIVE_PARAM_CMD,
2656 params, 3, res_reg,
2657 &res_size);
2658 break;
2659 }
2660 case CDROMSUBCHNL: /* Get subchannel info */
2661 retval = sony_get_subchnl_info((struct cdrom_subchnl *) arg);
2662 break;
2663
2664 default:
2665 retval = -EINVAL;
2666 break;
2667 }
2668 up(&sony_sem);
2669 return retval;
2670}
2671
2672static int scd_read_audio(struct cdrom_device_info *cdi,
2673 unsigned int cmd, unsigned long arg)
2674{
2675 void __user *argp = (void __user *)arg;
2676 int retval;
2677
2678 if (down_interruptible(&sony_sem))
2679 return -ERESTARTSYS;
2680 switch (cmd) {
2681 case CDROMREADAUDIO: /* Read 2352 byte audio tracks and 2340 byte
2682 raw data tracks. */
2683 {
2684 struct cdrom_read_audio ra;
2685
2686
2687 sony_get_toc();
2688 if (!sony_toc_read) {
2689 retval = -EIO;
2690 break;
2691 }
2692
2693 if (copy_from_user(&ra, argp, sizeof(ra))) {
2694 retval = -EFAULT;
2695 break;
2696 }
2697
2698 if (ra.nframes == 0) {
2699 retval = 0;
2700 break;
2701 }
2702
2703 if (!access_ok(VERIFY_WRITE, ra.buf,
2704 CD_FRAMESIZE_RAW * ra.nframes))
2705 return -EFAULT;
2706
2707 if (ra.addr_format == CDROM_LBA) {
2708 if ((ra.addr.lba >=
2709 sony_toc.lead_out_start_lba)
2710 || (ra.addr.lba + ra.nframes >=
2711 sony_toc.lead_out_start_lba)) {
2712 retval = -EINVAL;
2713 break;
2714 }
2715 } else if (ra.addr_format == CDROM_MSF) {
2716 if ((ra.addr.msf.minute >= 75)
2717 || (ra.addr.msf.second >= 60)
2718 || (ra.addr.msf.frame >= 75)) {
2719 retval = -EINVAL;
2720 break;
2721 }
2722
2723 ra.addr.lba = ((ra.addr.msf.minute * 4500)
2724 + (ra.addr.msf.second * 75)
2725 + ra.addr.msf.frame);
2726 if ((ra.addr.lba >=
2727 sony_toc.lead_out_start_lba)
2728 || (ra.addr.lba + ra.nframes >=
2729 sony_toc.lead_out_start_lba)) {
2730 retval = -EINVAL;
2731 break;
2732 }
2733
2734 /* I know, this can go negative on an unsigned. However,
2735 the first thing done to the data is to add this value,
2736 so this should compensate and allow direct msf access. */
2737 ra.addr.lba -= LOG_START_OFFSET;
2738 } else {
2739 retval = -EINVAL;
2740 break;
2741 }
2742
2743 retval = read_audio(&ra);
2744 break;
2745 }
2746 retval = 0;
2747 break;
2748
2749 default:
2750 retval = -EINVAL;
2751 }
2752 up(&sony_sem);
2753 return retval;
2754}
2755
2756static int scd_spinup(void)
2757{
2758 unsigned char res_reg[12];
2759 unsigned int res_size;
2760 int num_spin_ups;
2761
2762 num_spin_ups = 0;
2763
2764 respinup_on_open:
2765 do_sony_cd_cmd(SONY_SPIN_UP_CMD, NULL, 0, res_reg, &res_size);
2766
2767 /* The drive sometimes returns error 0. I don't know why, but ignore
2768 it. It seems to mean the drive has already done the operation. */
2769 if ((res_size < 2) || ((res_reg[0] != 0) && (res_reg[1] != 0))) {
2770 printk(KERN_ERR PFX "%s error (scd_open, spin up)\n",
2771 translate_error(res_reg[1]));
2772 return 1;
2773 }
2774
2775 do_sony_cd_cmd(SONY_READ_TOC_CMD, NULL, 0, res_reg, &res_size);
2776
2777 /* The drive sometimes returns error 0. I don't know why, but ignore
2778 it. It seems to mean the drive has already done the operation. */
2779 if ((res_size < 2) || ((res_reg[0] != 0) && (res_reg[1] != 0))) {
2780 /* If the drive is already playing, it's ok. */
2781 if ((res_reg[1] == SONY_AUDIO_PLAYING_ERR)
2782 || (res_reg[1] == 0)) {
2783 return 0;
2784 }
2785
2786 /* If the drive says it is not spun up (even though we just did it!)
2787 then retry the operation at least a few times. */
2788 if ((res_reg[1] == SONY_NOT_SPIN_ERR)
2789 && (num_spin_ups < MAX_CDU31A_RETRIES)) {
2790 num_spin_ups++;
2791 goto respinup_on_open;
2792 }
2793
2794 printk(KERN_ERR PFX "Error %s (scd_open, read toc)\n",
2795 translate_error(res_reg[1]));
2796 do_sony_cd_cmd(SONY_SPIN_DOWN_CMD, NULL, 0, res_reg,
2797 &res_size);
2798 return 1;
2799 }
2800 return 0;
2801}
2802
2803/*
2804 * Open the drive for operations. Spin the drive up and read the table of
2805 * contents if these have not already been done.
2806 */
2807static int scd_open(struct cdrom_device_info *cdi, int purpose)
2808{
2809 unsigned char res_reg[12];
2810 unsigned int res_size;
2811 unsigned char params[2];
2812
2813 if (purpose == 1) {
2814 /* Open for IOCTLs only - no media check */
2815 sony_usage++;
2816 return 0;
2817 }
2818
2819 if (sony_usage == 0) {
2820 if (scd_spinup() != 0)
2821 return -EIO;
2822 sony_get_toc();
2823 if (!sony_toc_read) {
2824 do_sony_cd_cmd(SONY_SPIN_DOWN_CMD, NULL, 0,
2825 res_reg, &res_size);
2826 return -EIO;
2827 }
2828
2829 /* For XA on the CDU31A only, we have to do special reads.
2830 The CDU33A handles XA automagically. */
2831 /* if ( (sony_toc.disk_type == SONY_XA_DISK_TYPE) */
2832 if ((sony_toc.disk_type != 0x00)
2833 && (!is_double_speed)) {
2834 params[0] = SONY_SD_DECODE_PARAM;
2835 params[1] = 0x07;
2836 do_sony_cd_cmd(SONY_SET_DRIVE_PARAM_CMD,
2837 params, 2, res_reg, &res_size);
2838 if ((res_size < 2)
2839 || ((res_reg[0] & 0xf0) == 0x20)) {
2840 printk(KERN_WARNING PFX "Unable to set "
2841 "XA params: 0x%2.2x\n", res_reg[1]);
2842 }
2843 sony_xa_mode = 1;
2844 }
2845 /* A non-XA disk. Set the parms back if necessary. */
2846 else if (sony_xa_mode) {
2847 params[0] = SONY_SD_DECODE_PARAM;
2848 params[1] = 0x0f;
2849 do_sony_cd_cmd(SONY_SET_DRIVE_PARAM_CMD,
2850 params, 2, res_reg, &res_size);
2851 if ((res_size < 2)
2852 || ((res_reg[0] & 0xf0) == 0x20)) {
2853 printk(KERN_WARNING PFX "Unable to reset "
2854 "XA params: 0x%2.2x\n", res_reg[1]);
2855 }
2856 sony_xa_mode = 0;
2857 }
2858
2859 sony_spun_up = 1;
2860 }
2861
2862 sony_usage++;
2863
2864 return 0;
2865}
2866
2867
2868/*
2869 * Close the drive. Spin it down if no task is using it. The spin
2870 * down will fail if playing audio, so audio play is OK.
2871 */
2872static void scd_release(struct cdrom_device_info *cdi)
2873{
2874 if (sony_usage == 1) {
2875 unsigned char res_reg[12];
2876 unsigned int res_size;
2877
2878 do_sony_cd_cmd(SONY_SPIN_DOWN_CMD, NULL, 0, res_reg,
2879 &res_size);
2880
2881 sony_spun_up = 0;
2882 }
2883 sony_usage--;
2884}
2885
2886static struct cdrom_device_ops scd_dops = {
2887 .open = scd_open,
2888 .release = scd_release,
2889 .drive_status = scd_drive_status,
2890 .media_changed = scd_media_changed,
2891 .tray_move = scd_tray_move,
2892 .lock_door = scd_lock_door,
2893 .select_speed = scd_select_speed,
2894 .get_last_session = scd_get_last_session,
2895 .get_mcn = scd_get_mcn,
2896 .reset = scd_reset,
2897 .audio_ioctl = scd_audio_ioctl,
2898 .capability = CDC_OPEN_TRAY | CDC_CLOSE_TRAY | CDC_LOCK |
2899 CDC_SELECT_SPEED | CDC_MULTI_SESSION |
2900 CDC_MCN | CDC_MEDIA_CHANGED | CDC_PLAY_AUDIO |
2901 CDC_RESET | CDC_DRIVE_STATUS,
2902 .n_minors = 1,
2903};
2904
2905static struct cdrom_device_info scd_info = {
2906 .ops = &scd_dops,
2907 .speed = 2,
2908 .capacity = 1,
2909 .name = "cdu31a"
2910};
2911
2912static int scd_block_open(struct inode *inode, struct file *file)
2913{
2914 return cdrom_open(&scd_info, inode, file);
2915}
2916
2917static int scd_block_release(struct inode *inode, struct file *file)
2918{
2919 return cdrom_release(&scd_info, file);
2920}
2921
2922static int scd_block_ioctl(struct inode *inode, struct file *file,
2923 unsigned cmd, unsigned long arg)
2924{
2925 int retval;
2926
2927 /* The eject and close commands should be handled by Uniform CD-ROM
2928 * driver - but I always got hard lockup instead of eject
2929 * until I put this here.
2930 */
2931 switch (cmd) {
2932 case CDROMEJECT:
2933 scd_lock_door(&scd_info, 0);
2934 retval = scd_tray_move(&scd_info, 1);
2935 break;
2936 case CDROMCLOSETRAY:
2937 retval = scd_tray_move(&scd_info, 0);
2938 break;
2939 case CDROMREADAUDIO:
2940 retval = scd_read_audio(&scd_info, CDROMREADAUDIO, arg);
2941 break;
2942 default:
2943 retval = cdrom_ioctl(file, &scd_info, inode, cmd, arg);
2944 }
2945 return retval;
2946}
2947
2948static int scd_block_media_changed(struct gendisk *disk)
2949{
2950 return cdrom_media_changed(&scd_info);
2951}
2952
2953static struct block_device_operations scd_bdops =
2954{
2955 .owner = THIS_MODULE,
2956 .open = scd_block_open,
2957 .release = scd_block_release,
2958 .ioctl = scd_block_ioctl,
2959 .media_changed = scd_block_media_changed,
2960};
2961
2962static struct gendisk *scd_gendisk;
2963
2964/* The different types of disc loading mechanisms supported */
2965static char *load_mech[] __initdata =
2966 { "caddy", "tray", "pop-up", "unknown" };
2967
2968static int __init
2969get_drive_configuration(unsigned short base_io,
2970 unsigned char res_reg[], unsigned int *res_size)
2971{
2972 unsigned long retry_count;
2973
2974
2975 if (!request_region(base_io, 4, "cdu31a"))
2976 return 0;
2977
2978 /* Set the base address */
2979 cdu31a_port = base_io;
2980
2981 /* Set up all the register locations */
2982 sony_cd_cmd_reg = cdu31a_port + SONY_CMD_REG_OFFSET;
2983 sony_cd_param_reg = cdu31a_port + SONY_PARAM_REG_OFFSET;
2984 sony_cd_write_reg = cdu31a_port + SONY_WRITE_REG_OFFSET;
2985 sony_cd_control_reg = cdu31a_port + SONY_CONTROL_REG_OFFSET;
2986 sony_cd_status_reg = cdu31a_port + SONY_STATUS_REG_OFFSET;
2987 sony_cd_result_reg = cdu31a_port + SONY_RESULT_REG_OFFSET;
2988 sony_cd_read_reg = cdu31a_port + SONY_READ_REG_OFFSET;
2989 sony_cd_fifost_reg = cdu31a_port + SONY_FIFOST_REG_OFFSET;
2990
2991 /*
2992 * Check to see if anything exists at the status register location.
2993 * I don't know if this is a good way to check, but it seems to work
2994 * ok for me.
2995 */
2996 if (read_status_register() != 0xff) {
2997 /*
2998 * Reset the drive and wait for attention from it (to say it's reset).
2999 * If you don't wait, the next operation will probably fail.
3000 */
3001 reset_drive();
3002 retry_count = jiffies + SONY_RESET_TIMEOUT;
3003 while (time_before(jiffies, retry_count)
3004 && (!is_attention())) {
3005 sony_sleep();
3006 }
3007
3008#if 0
3009 /* If attention is never seen probably not a CDU31a present */
3010 if (!is_attention()) {
3011 res_reg[0] = 0x20;
3012 goto out_err;
3013 }
3014#endif
3015
3016 /*
3017 * Get the drive configuration.
3018 */
3019 do_sony_cd_cmd(SONY_REQ_DRIVE_CONFIG_CMD,
3020 NULL,
3021 0, (unsigned char *) res_reg, res_size);
3022 if (*res_size <= 2 || (res_reg[0] & 0xf0) != 0)
3023 goto out_err;
3024 return 1;
3025 }
3026
3027 /* Return an error */
3028 res_reg[0] = 0x20;
3029out_err:
3030 release_region(cdu31a_port, 4);
3031 cdu31a_port = 0;
3032 return 0;
3033}
3034
3035#ifndef MODULE
3036/*
3037 * Set up base I/O and interrupts, called from main.c.
3038 */
3039
3040static int __init cdu31a_setup(char *strings)
3041{
3042 int ints[4];
3043
3044 (void) get_options(strings, ARRAY_SIZE(ints), ints);
3045
3046 if (ints[0] > 0) {
3047 cdu31a_port = ints[1];
3048 }
3049 if (ints[0] > 1) {
3050 cdu31a_irq = ints[2];
3051 }
3052 if ((strings != NULL) && (*strings != '\0')) {
3053 if (strcmp(strings, "PAS") == 0) {
3054 sony_pas_init = 1;
3055 } else {
3056 printk(KERN_NOTICE PFX "Unknown interface type: %s\n",
3057 strings);
3058 }
3059 }
3060
3061 return 1;
3062}
3063
3064__setup("cdu31a=", cdu31a_setup);
3065
3066#endif
3067
3068/*
3069 * Initialize the driver.
3070 */
3071int __init cdu31a_init(void)
3072{
3073 struct s_sony_drive_config drive_config;
3074 struct gendisk *disk;
3075 int deficiency = 0;
3076 unsigned int res_size;
3077 char msg[255];
3078 char buf[40];
3079 int i;
3080 int tmp_irq;
3081
3082 /*
3083 * According to Alex Freed (freed@europa.orion.adobe.com), this is
3084 * required for the Fusion CD-16 package. If the sound driver is
3085 * loaded, it should work fine, but just in case...
3086 *
3087 * The following turn on the CD-ROM interface for a Fusion CD-16.
3088 */
3089 if (sony_pas_init) {
3090 outb(0xbc, 0x9a01);
3091 outb(0xe2, 0x9a01);
3092 }
3093
3094 /* Setting the base I/O address to 0xffff will disable it. */
3095 if (cdu31a_port == 0xffff)
3096 goto errout3;
3097
3098 if (cdu31a_port != 0) {
3099 /* Need IRQ 0 because we can't sleep here. */
3100 tmp_irq = cdu31a_irq;
3101 cdu31a_irq = 0;
3102 if (!get_drive_configuration(cdu31a_port,
3103 drive_config.exec_status,
3104 &res_size))
3105 goto errout3;
3106 cdu31a_irq = tmp_irq;
3107 } else {
3108 cdu31a_irq = 0;
3109 for (i = 0; cdu31a_addresses[i].base; i++) {
3110 if (get_drive_configuration(cdu31a_addresses[i].base,
3111 drive_config.exec_status,
3112 &res_size)) {
3113 cdu31a_irq = cdu31a_addresses[i].int_num;
3114 break;
3115 }
3116 }
3117 if (!cdu31a_port)
3118 goto errout3;
3119 }
3120
3121 if (register_blkdev(MAJOR_NR, "cdu31a"))
3122 goto errout2;
3123
3124 disk = alloc_disk(1);
3125 if (!disk)
3126 goto errout1;
3127 disk->major = MAJOR_NR;
3128 disk->first_minor = 0;
3129 sprintf(disk->disk_name, "cdu31a");
3130 disk->fops = &scd_bdops;
3131 disk->flags = GENHD_FL_CD;
3132
3133 if (SONY_HWC_DOUBLE_SPEED(drive_config))
3134 is_double_speed = 1;
3135
3136 tmp_irq = cdu31a_irq; /* Need IRQ 0 because we can't sleep here. */
3137 cdu31a_irq = 0;
3138
3139 sony_speed = is_double_speed; /* Set 2X drives to 2X by default */
3140 set_drive_params(sony_speed);
3141
3142 cdu31a_irq = tmp_irq;
3143
3144 if (cdu31a_irq > 0) {
3145 if (request_irq
3146 (cdu31a_irq, cdu31a_interrupt, IRQF_DISABLED,
3147 "cdu31a", NULL)) {
3148 printk(KERN_WARNING PFX "Unable to grab IRQ%d for "
3149 "the CDU31A driver\n", cdu31a_irq);
3150 cdu31a_irq = 0;
3151 }
3152 }
3153
3154 sprintf(msg, "Sony I/F CDROM : %8.8s %16.16s %8.8s\n",
3155 drive_config.vendor_id,
3156 drive_config.product_id,
3157 drive_config.product_rev_level);
3158 sprintf(buf, " Capabilities: %s",
3159 load_mech[SONY_HWC_GET_LOAD_MECH(drive_config)]);
3160 strcat(msg, buf);
3161 if (SONY_HWC_AUDIO_PLAYBACK(drive_config))
3162 strcat(msg, ", audio");
3163 else
3164 deficiency |= CDC_PLAY_AUDIO;
3165 if (SONY_HWC_EJECT(drive_config))
3166 strcat(msg, ", eject");
3167 else
3168 deficiency |= CDC_OPEN_TRAY;
3169 if (SONY_HWC_LED_SUPPORT(drive_config))
3170 strcat(msg, ", LED");
3171 if (SONY_HWC_ELECTRIC_VOLUME(drive_config))
3172 strcat(msg, ", elec. Vol");
3173 if (SONY_HWC_ELECTRIC_VOLUME_CTL(drive_config))
3174 strcat(msg, ", sep. Vol");
3175 if (is_double_speed)
3176 strcat(msg, ", double speed");
3177 else
3178 deficiency |= CDC_SELECT_SPEED;
3179 if (cdu31a_irq > 0) {
3180 sprintf(buf, ", irq %d", cdu31a_irq);
3181 strcat(msg, buf);
3182 }
3183 strcat(msg, "\n");
3184 printk(KERN_INFO PFX "%s",msg);
3185
3186 cdu31a_queue = blk_init_queue(do_cdu31a_request, &cdu31a_lock);
3187 if (!cdu31a_queue)
3188 goto errout0;
3189 blk_queue_hardsect_size(cdu31a_queue, 2048);
3190
3191 init_timer(&cdu31a_abort_timer);
3192 cdu31a_abort_timer.function = handle_abort_timeout;
3193
3194 scd_info.mask = deficiency;
3195 scd_gendisk = disk;
3196 if (register_cdrom(&scd_info))
3197 goto err;
3198 disk->queue = cdu31a_queue;
3199 add_disk(disk);
3200
3201 disk_changed = 1;
3202 return 0;
3203
3204err:
3205 blk_cleanup_queue(cdu31a_queue);
3206errout0:
3207 if (cdu31a_irq)
3208 free_irq(cdu31a_irq, NULL);
3209 printk(KERN_ERR PFX "Unable to register with Uniform cdrom driver\n");
3210 put_disk(disk);
3211errout1:
3212 if (unregister_blkdev(MAJOR_NR, "cdu31a")) {
3213 printk(KERN_WARNING PFX "Can't unregister block device\n");
3214 }
3215errout2:
3216 release_region(cdu31a_port, 4);
3217errout3:
3218 return -EIO;
3219}
3220
3221
3222static void __exit cdu31a_exit(void)
3223{
3224 del_gendisk(scd_gendisk);
3225 put_disk(scd_gendisk);
3226 if (unregister_cdrom(&scd_info)) {
3227 printk(KERN_WARNING PFX "Can't unregister from Uniform "
3228 "cdrom driver\n");
3229 return;
3230 }
3231 if ((unregister_blkdev(MAJOR_NR, "cdu31a") == -EINVAL)) {
3232 printk(KERN_WARNING PFX "Can't unregister\n");
3233 return;
3234 }
3235
3236 blk_cleanup_queue(cdu31a_queue);
3237
3238 if (cdu31a_irq > 0)
3239 free_irq(cdu31a_irq, NULL);
3240
3241 release_region(cdu31a_port, 4);
3242 printk(KERN_INFO PFX "module released.\n");
3243}
3244
3245#ifdef MODULE
3246module_init(cdu31a_init);
3247#endif
3248module_exit(cdu31a_exit);
3249
3250MODULE_LICENSE("GPL");
3251MODULE_ALIAS_BLOCKDEV_MAJOR(CDU31A_CDROM_MAJOR);
diff --git a/drivers/cdrom/cdu31a.h b/drivers/cdrom/cdu31a.h
deleted file mode 100644
index 61d4768c412e..000000000000
--- a/drivers/cdrom/cdu31a.h
+++ /dev/null
@@ -1,411 +0,0 @@
1/*
2 * Definitions for a Sony interface CDROM drive.
3 *
4 * Corey Minyard (minyard@wf-rch.cirr.com)
5 *
6 * Copyright (C) 1993 Corey Minyard
7 *
8 * This program is free software; you can redistribute it and/or modify
9 * it under the terms of the GNU General Public License as published by
10 * the Free Software Foundation; either version 2 of the License, or
11 * (at your option) any later version.
12 *
13 * This program is distributed in the hope that it will be useful,
14 * but WITHOUT ANY WARRANTY; without even the implied warranty of
15 * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
16 * GNU General Public License for more details.
17 *
18 * You should have received a copy of the GNU General Public License
19 * along with this program; if not, write to the Free Software
20 * Foundation, Inc., 675 Mass Ave, Cambridge, MA 02139, USA.
21 *
22 */
23
24/*
25 * General defines.
26 */
27#define SONY_XA_DISK_TYPE 0x20
28
29/*
30 * Offsets (from the base address) and bits for the various write registers
31 * of the drive.
32 */
33#define SONY_CMD_REG_OFFSET 0
34#define SONY_PARAM_REG_OFFSET 1
35#define SONY_WRITE_REG_OFFSET 2
36#define SONY_CONTROL_REG_OFFSET 3
37# define SONY_ATTN_CLR_BIT 0x01
38# define SONY_RES_RDY_CLR_BIT 0x02
39# define SONY_DATA_RDY_CLR_BIT 0x04
40# define SONY_ATTN_INT_EN_BIT 0x08
41# define SONY_RES_RDY_INT_EN_BIT 0x10
42# define SONY_DATA_RDY_INT_EN_BIT 0x20
43# define SONY_PARAM_CLR_BIT 0x40
44# define SONY_DRIVE_RESET_BIT 0x80
45
46/*
47 * Offsets (from the base address) and bits for the various read registers
48 * of the drive.
49 */
50#define SONY_STATUS_REG_OFFSET 0
51# define SONY_ATTN_BIT 0x01
52# define SONY_RES_RDY_BIT 0x02
53# define SONY_DATA_RDY_BIT 0x04
54# define SONY_ATTN_INT_ST_BIT 0x08
55# define SONY_RES_RDY_INT_ST_BIT 0x10
56# define SONY_DATA_RDY_INT_ST_BIT 0x20
57# define SONY_DATA_REQUEST_BIT 0x40
58# define SONY_BUSY_BIT 0x80
59#define SONY_RESULT_REG_OFFSET 1
60#define SONY_READ_REG_OFFSET 2
61#define SONY_FIFOST_REG_OFFSET 3
62# define SONY_PARAM_WRITE_RDY_BIT 0x01
63# define SONY_PARAM_REG_EMPTY_BIT 0x02
64# define SONY_RES_REG_NOT_EMP_BIT 0x04
65# define SONY_RES_REG_FULL_BIT 0x08
66
67#define LOG_START_OFFSET 150 /* Offset of first logical sector */
68
69#define SONY_DETECT_TIMEOUT (8*HZ/10) /* Maximum amount of time
70 that drive detection code
71 will wait for response
72 from drive (in 1/100th's
73 of seconds). */
74
75#define SONY_JIFFIES_TIMEOUT (10*HZ) /* Maximum number of times the
76 drive will wait/try for an
77 operation */
78#define SONY_RESET_TIMEOUT HZ /* Maximum number of times the
79 drive will wait/try a reset
80 operation */
81#define SONY_READY_RETRIES 20000 /* How many times to retry a
82 spin waiting for a register
83 to come ready */
84
85#define MAX_CDU31A_RETRIES 3 /* How many times to retry an
86 operation */
87
88/* Commands to request or set drive control parameters and disc information */
89#define SONY_REQ_DRIVE_CONFIG_CMD 0x00 /* Returns s_sony_drive_config */
90#define SONY_REQ_DRIVE_MODE_CMD 0x01
91#define SONY_REQ_DRIVE_PARAM_CMD 0x02
92#define SONY_REQ_MECH_STATUS_CMD 0x03
93#define SONY_REQ_AUDIO_STATUS_CMD 0x04
94#define SONY_SET_DRIVE_PARAM_CMD 0x10
95#define SONY_REQ_TOC_DATA_CMD 0x20 /* Returns s_sony_toc */
96#define SONY_REQ_SUBCODE_ADDRESS_CMD 0x21 /* Returns s_sony_subcode */
97#define SONY_REQ_UPC_EAN_CMD 0x22
98#define SONY_REQ_ISRC_CMD 0x23
99#define SONY_REQ_TOC_DATA_SPEC_CMD 0x24 /* Returns s_sony_session_toc */
100
101/* Commands to request information from the drive */
102#define SONY_READ_TOC_CMD 0x30 /* let the drive firmware grab the TOC */
103#define SONY_SEEK_CMD 0x31
104#define SONY_READ_CMD 0x32
105#define SONY_READ_BLKERR_STAT_CMD 0x34
106#define SONY_ABORT_CMD 0x35
107#define SONY_READ_TOC_SPEC_CMD 0x36
108
109/* Commands to control audio */
110#define SONY_AUDIO_PLAYBACK_CMD 0x40
111#define SONY_AUDIO_STOP_CMD 0x41
112#define SONY_AUDIO_SCAN_CMD 0x42
113
114/* Miscellaneous control commands */
115#define SONY_EJECT_CMD 0x50
116#define SONY_SPIN_UP_CMD 0x51
117#define SONY_SPIN_DOWN_CMD 0x52
118
119/* Diagnostic commands */
120#define SONY_WRITE_BUFFER_CMD 0x60
121#define SONY_READ_BUFFER_CMD 0x61
122#define SONY_DIAGNOSTICS_CMD 0x62
123
124
125/*
126 * The following are command parameters for the set drive parameter command
127 */
128#define SONY_SD_DECODE_PARAM 0x00
129#define SONY_SD_INTERFACE_PARAM 0x01
130#define SONY_SD_BUFFERING_PARAM 0x02
131#define SONY_SD_AUDIO_PARAM 0x03
132#define SONY_SD_AUDIO_VOLUME 0x04
133#define SONY_SD_MECH_CONTROL 0x05
134#define SONY_SD_AUTO_SPIN_DOWN_TIME 0x06
135
136/*
137 * The following are parameter bits for the mechanical control command
138 */
139#define SONY_AUTO_SPIN_UP_BIT 0x01
140#define SONY_AUTO_EJECT_BIT 0x02
141#define SONY_DOUBLE_SPEED_BIT 0x04
142
143/*
144 * The following extract information from the drive configuration about
145 * the drive itself.
146 */
147#define SONY_HWC_GET_LOAD_MECH(c) (c.hw_config[0] & 0x03)
148#define SONY_HWC_EJECT(c) (c.hw_config[0] & 0x04)
149#define SONY_HWC_LED_SUPPORT(c) (c.hw_config[0] & 0x08)
150#define SONY_HWC_DOUBLE_SPEED(c) (c.hw_config[0] & 0x10)
151#define SONY_HWC_GET_BUF_MEM_SIZE(c) ((c.hw_config[0] & 0xc0) >> 6)
152#define SONY_HWC_AUDIO_PLAYBACK(c) (c.hw_config[1] & 0x01)
153#define SONY_HWC_ELECTRIC_VOLUME(c) (c.hw_config[1] & 0x02)
154#define SONY_HWC_ELECTRIC_VOLUME_CTL(c) (c.hw_config[1] & 0x04)
155
156#define SONY_HWC_CADDY_LOAD_MECH 0x00
157#define SONY_HWC_TRAY_LOAD_MECH 0x01
158#define SONY_HWC_POPUP_LOAD_MECH 0x02
159#define SONY_HWC_UNKWN_LOAD_MECH 0x03
160
161#define SONY_HWC_8KB_BUFFER 0x00
162#define SONY_HWC_32KB_BUFFER 0x01
163#define SONY_HWC_64KB_BUFFER 0x02
164#define SONY_HWC_UNKWN_BUFFER 0x03
165
166/*
167 * This is the complete status returned from the drive configuration request
168 * command.
169 */
170struct s_sony_drive_config
171{
172 unsigned char exec_status[2];
173 char vendor_id[8];
174 char product_id[16];
175 char product_rev_level[8];
176 unsigned char hw_config[2];
177};
178
179/* The following is returned from the request subcode address command */
180struct s_sony_subcode
181{
182 unsigned char exec_status[2];
183 unsigned char address :4;
184 unsigned char control :4;
185 unsigned char track_num;
186 unsigned char index_num;
187 unsigned char rel_msf[3];
188 unsigned char reserved1;
189 unsigned char abs_msf[3];
190};
191
192#define MAX_TRACKS 100 /* The maximum tracks a disk may have. */
193/*
194 * The following is returned from the request TOC (Table Of Contents) command.
195 * (last_track_num-first_track_num+1) values are valid in tracks.
196 */
197struct s_sony_toc
198{
199 unsigned char exec_status[2];
200 unsigned char address0 :4;
201 unsigned char control0 :4;
202 unsigned char point0;
203 unsigned char first_track_num;
204 unsigned char disk_type;
205 unsigned char dummy0;
206 unsigned char address1 :4;
207 unsigned char control1 :4;
208 unsigned char point1;
209 unsigned char last_track_num;
210 unsigned char dummy1;
211 unsigned char dummy2;
212 unsigned char address2 :4;
213 unsigned char control2 :4;
214 unsigned char point2;
215 unsigned char lead_out_start_msf[3];
216 struct
217 {
218 unsigned char address :4;
219 unsigned char control :4;
220 unsigned char track;
221 unsigned char track_start_msf[3];
222 } tracks[MAX_TRACKS];
223
224 unsigned int lead_out_start_lba;
225};
226
227struct s_sony_session_toc
228{
229 unsigned char exec_status[2];
230 unsigned char session_number;
231 unsigned char address0 :4;
232 unsigned char control0 :4;
233 unsigned char point0;
234 unsigned char first_track_num;
235 unsigned char disk_type;
236 unsigned char dummy0;
237 unsigned char address1 :4;
238 unsigned char control1 :4;
239 unsigned char point1;
240 unsigned char last_track_num;
241 unsigned char dummy1;
242 unsigned char dummy2;
243 unsigned char address2 :4;
244 unsigned char control2 :4;
245 unsigned char point2;
246 unsigned char lead_out_start_msf[3];
247 unsigned char addressb0 :4;
248 unsigned char controlb0 :4;
249 unsigned char pointb0;
250 unsigned char next_poss_prog_area_msf[3];
251 unsigned char num_mode_5_pointers;
252 unsigned char max_start_outer_leadout_msf[3];
253 unsigned char addressb1 :4;
254 unsigned char controlb1 :4;
255 unsigned char pointb1;
256 unsigned char dummyb0_1[4];
257 unsigned char num_skip_interval_pointers;
258 unsigned char num_skip_track_assignments;
259 unsigned char dummyb0_2;
260 unsigned char addressb2 :4;
261 unsigned char controlb2 :4;
262 unsigned char pointb2;
263 unsigned char tracksb2[7];
264 unsigned char addressb3 :4;
265 unsigned char controlb3 :4;
266 unsigned char pointb3;
267 unsigned char tracksb3[7];
268 unsigned char addressb4 :4;
269 unsigned char controlb4 :4;
270 unsigned char pointb4;
271 unsigned char tracksb4[7];
272 unsigned char addressc0 :4;
273 unsigned char controlc0 :4;
274 unsigned char pointc0;
275 unsigned char dummyc0[7];
276 struct
277 {
278 unsigned char address :4;
279 unsigned char control :4;
280 unsigned char track;
281 unsigned char track_start_msf[3];
282 } tracks[MAX_TRACKS];
283
284 unsigned int start_track_lba;
285 unsigned int lead_out_start_lba;
286 unsigned int mint;
287 unsigned int maxt;
288};
289
290struct s_all_sessions_toc
291{
292 unsigned char sessions;
293 unsigned int track_entries;
294 unsigned char first_track_num;
295 unsigned char last_track_num;
296 unsigned char disk_type;
297 unsigned char lead_out_start_msf[3];
298 struct
299 {
300 unsigned char address :4;
301 unsigned char control :4;
302 unsigned char track;
303 unsigned char track_start_msf[3];
304 } tracks[MAX_TRACKS];
305
306 unsigned int start_track_lba;
307 unsigned int lead_out_start_lba;
308};
309
310
311/*
312 * The following are errors returned from the drive.
313 */
314
315/* Command error group */
316#define SONY_ILL_CMD_ERR 0x10
317#define SONY_ILL_PARAM_ERR 0x11
318
319/* Mechanism group */
320#define SONY_NOT_LOAD_ERR 0x20
321#define SONY_NO_DISK_ERR 0x21
322#define SONY_NOT_SPIN_ERR 0x22
323#define SONY_SPIN_ERR 0x23
324#define SONY_SPINDLE_SERVO_ERR 0x25
325#define SONY_FOCUS_SERVO_ERR 0x26
326#define SONY_EJECT_MECH_ERR 0x29
327#define SONY_AUDIO_PLAYING_ERR 0x2a
328#define SONY_EMERGENCY_EJECT_ERR 0x2c
329
330/* Seek error group */
331#define SONY_FOCUS_ERR 0x30
332#define SONY_FRAME_SYNC_ERR 0x31
333#define SONY_SUBCODE_ADDR_ERR 0x32
334#define SONY_BLOCK_SYNC_ERR 0x33
335#define SONY_HEADER_ADDR_ERR 0x34
336
337/* Read error group */
338#define SONY_ILL_TRACK_R_ERR 0x40
339#define SONY_MODE_0_R_ERR 0x41
340#define SONY_ILL_MODE_R_ERR 0x42
341#define SONY_ILL_BLOCK_SIZE_R_ERR 0x43
342#define SONY_MODE_R_ERR 0x44
343#define SONY_FORM_R_ERR 0x45
344#define SONY_LEAD_OUT_R_ERR 0x46
345#define SONY_BUFFER_OVERRUN_R_ERR 0x47
346
347/* Data error group */
348#define SONY_UNREC_CIRC_ERR 0x53
349#define SONY_UNREC_LECC_ERR 0x57
350
351/* Subcode error group */
352#define SONY_NO_TOC_ERR 0x60
353#define SONY_SUBCODE_DATA_NVAL_ERR 0x61
354#define SONY_FOCUS_ON_TOC_READ_ERR 0x63
355#define SONY_FRAME_SYNC_ON_TOC_READ_ERR 0x64
356#define SONY_TOC_DATA_ERR 0x65
357
358/* Hardware failure group */
359#define SONY_HW_FAILURE_ERR 0x70
360#define SONY_LEAD_IN_A_ERR 0x91
361#define SONY_LEAD_OUT_A_ERR 0x92
362#define SONY_DATA_TRACK_A_ERR 0x93
363
364/*
365 * The following are returned from the Read With Block Error Status command.
366 * They are not errors but information (Errors from the 0x5x group above may
367 * also be returned
368 */
369#define SONY_NO_CIRC_ERR_BLK_STAT 0x50
370#define SONY_NO_LECC_ERR_BLK_STAT 0x54
371#define SONY_RECOV_LECC_ERR_BLK_STAT 0x55
372#define SONY_NO_ERR_DETECTION_STAT 0x59
373
374/*
375 * The following is not an error returned by the drive, but by the code
376 * that talks to the drive. It is returned because of a timeout.
377 */
378#define SONY_TIMEOUT_OP_ERR 0x01
379#define SONY_SIGNAL_OP_ERR 0x02
380#define SONY_BAD_DATA_ERR 0x03
381
382
383/*
384 * The following are attention code for asynchronous events from the drive.
385 */
386
387/* Standard attention group */
388#define SONY_EMER_EJECT_ATTN 0x2c
389#define SONY_HW_FAILURE_ATTN 0x70
390#define SONY_MECH_LOADED_ATTN 0x80
391#define SONY_EJECT_PUSHED_ATTN 0x81
392
393/* Audio attention group */
394#define SONY_AUDIO_PLAY_DONE_ATTN 0x90
395#define SONY_LEAD_IN_ERR_ATTN 0x91
396#define SONY_LEAD_OUT_ERR_ATTN 0x92
397#define SONY_DATA_TRACK_ERR_ATTN 0x93
398#define SONY_AUDIO_PLAYBACK_ERR_ATTN 0x94
399
400/* Auto spin up group */
401#define SONY_SPIN_UP_COMPLETE_ATTN 0x24
402#define SONY_SPINDLE_SERVO_ERR_ATTN 0x25
403#define SONY_FOCUS_SERVO_ERR_ATTN 0x26
404#define SONY_TOC_READ_DONE_ATTN 0x62
405#define SONY_FOCUS_ON_TOC_READ_ERR_ATTN 0x63
406#define SONY_SYNC_ON_TOC_READ_ERR_ATTN 0x65
407
408/* Auto eject group */
409#define SONY_SPIN_DOWN_COMPLETE_ATTN 0x27
410#define SONY_EJECT_COMPLETE_ATTN 0x28
411#define SONY_EJECT_MECH_ERR_ATTN 0x29
diff --git a/drivers/cdrom/cm206.c b/drivers/cdrom/cm206.c
deleted file mode 100644
index 2f8fe3b6bbd0..000000000000
--- a/drivers/cdrom/cm206.c
+++ /dev/null
@@ -1,1594 +0,0 @@
1/* cm206.c. A linux-driver for the cm206 cdrom player with cm260 adapter card.
2 Copyright (c) 1995--1997 David A. van Leeuwen.
3 $Id: cm206.c,v 1.5 1997/12/26 11:02:51 david Exp $
4
5 This program is free software; you can redistribute it and/or modify
6 it under the terms of the GNU General Public License as published by
7 the Free Software Foundation; either version 2 of the License, or
8 (at your option) any later version.
9
10 This program is distributed in the hope that it will be useful,
11 but WITHOUT ANY WARRANTY; without even the implied warranty of
12 MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
13 GNU General Public License for more details.
14
15 You should have received a copy of the GNU General Public License
16 along with this program; if not, write to the Free Software
17 Foundation, Inc., 675 Mass Ave, Cambridge, MA 02139, USA.
18
19History:
20 Started 25 jan 1994. Waiting for documentation...
21 22 feb 1995: 0.1a first reasonably safe polling driver.
22 Two major bugs, one in read_sector and one in
23 do_cm206_request, happened to cancel!
24 25 feb 1995: 0.2a first reasonable interrupt driven version of above.
25 uart writes are still done in polling mode.
26 25 feb 1995: 0.21a writes also in interrupt mode, still some
27 small bugs to be found... Larger buffer.
28 2 mrt 1995: 0.22 Bug found (cd-> nowhere, interrupt was called in
29 initialization), read_ahead of 16. Timeouts implemented.
30 unclear if they do something...
31 7 mrt 1995: 0.23 Start of background read-ahead.
32 18 mrt 1995: 0.24 Working background read-ahead. (still problems)
33 26 mrt 1995: 0.25 Multi-session ioctl added (kernel v1.2).
34 Statistics implemented, though separate stats206.h.
35 Accessible through ioctl 0x1000 (just a number).
36 Hard to choose between v1.2 development and 1.1.75.
37 Bottom-half doesn't work with 1.2...
38 0.25a: fixed... typo. Still problems...
39 1 apr 1995: 0.26 Module support added. Most bugs found. Use kernel 1.2.n.
40 5 apr 1995: 0.27 Auto-probe for the adapter card base address.
41 Auto-probe for the adaptor card irq line.
42 7 apr 1995: 0.28 Added lilo setup support for base address and irq.
43 Use major number 32 (not in this source), officially
44 assigned to this driver.
45 9 apr 1995: 0.29 Added very limited audio support. Toc_header, stop, pause,
46 resume, eject. Play_track ignores track info, because we can't
47 read a table-of-contents entry. Toc_entry is implemented
48 as a `placebo' function: always returns start of disc.
49 3 may 1995: 0.30 Audio support completed. The get_toc_entry function
50 is implemented as a binary search.
51 15 may 1995: 0.31 More work on audio stuff. Workman is not easy to
52 satisfy; changed binary search into linear search.
53 Auto-probe for base address somewhat relaxed.
54 1 jun 1995: 0.32 Removed probe_irq_on/off for module version.
55 10 jun 1995: 0.33 Workman still behaves funny, but you should be
56 able to eject and substitute another disc.
57
58 An adaptation of 0.33 is included in linux-1.3.7 by Eberhard Moenkeberg
59
60 18 jul 1995: 0.34 Patch by Heiko Eissfeldt included, mainly considering
61 verify_area's in the ioctls. Some bugs introduced by
62 EM considering the base port and irq fixed.
63
64 18 dec 1995: 0.35 Add some code for error checking... no luck...
65
66 We jump to reach our goal: version 1.0 in the next stable linux kernel.
67
68 19 mar 1996: 0.95 Different implementation of CDROM_GET_UPC, on
69 request of Thomas Quinot.
70 25 mar 1996: 0.96 Interpretation of opening with O_WRONLY or O_RDWR:
71 open only for ioctl operation, e.g., for operation of
72 tray etc.
73 4 apr 1996: 0.97 First implementation of layer between VFS and cdrom
74 driver, a generic interface. Much of the functionality
75 of cm206_open() and cm206_ioctl() is transferred to a
76 new file cdrom.c and its header ucdrom.h.
77
78 Upgrade to Linux kernel 1.3.78.
79
80 11 apr 1996 0.98 Upgrade to Linux kernel 1.3.85
81 More code moved to cdrom.c
82
83 0.99 Some more small changes to decrease number
84 of oopses at module load;
85
86 27 jul 1996 0.100 Many hours of debugging, kernel change from 1.2.13
87 to 2.0.7 seems to have introduced some weird behavior
88 in (interruptible_)sleep_on(&cd->data): the process
89 seems to be woken without any explicit wake_up in my own
90 code. Patch to try 100x in case such untriggered wake_up's
91 occur.
92
93 28 jul 1996 0.101 Rewriting of the code that receives the command echo,
94 using a fifo to store echoed bytes.
95
96 Branch from 0.99:
97
98 0.99.1.0 Update to kernel release 2.0.10 dev_t -> kdev_t
99 (emoenke) various typos found by others. extra
100 module-load oops protection.
101
102 0.99.1.1 Initialization constant cdrom_dops.speed
103 changed from float (2.0) to int (2); Cli()-sti() pair
104 around cm260_reset() in module initialization code.
105
106 0.99.1.2 Changes literally as proposed by Scott Snyder
107 <snyder@d0sgif.fnal.gov> for the 2.1 kernel line, which
108 have to do mainly with the poor minor support i had. The
109 major new concept is to change a cdrom driver's
110 operations struct from the capabilities struct. This
111 reflects the fact that there is one major for a driver,
112 whilst there can be many minors whith completely
113 different capabilities.
114
115 0.99.1.3 More changes for operations/info separation.
116
117 0.99.1.4 Added speed selection (someone had to do this
118 first).
119
120 23 jan 1997 0.99.1.5 MODULE_PARMS call added.
121
122 23 jan 1997 0.100.1.2--0.100.1.5 following similar lines as
123 0.99.1.1--0.99.1.5. I get too many complaints about the
124 drive making read errors. What't wrong with the 2.0+
125 kernel line? Why get i (and othe cm206 owners) weird
126 results? Why were things good in the good old 1.1--1.2
127 era? Why don't i throw away the drive?
128
129 2 feb 1997 0.102 Added `volatile' to values in cm206_struct. Seems to
130 reduce many of the problems. Rewrote polling routines
131 to use fixed delays between polls.
132 0.103 Changed printk behavior.
133 0.104 Added a 0.100 -> 0.100.1.1 change
134
13511 feb 1997 0.105 Allow auto_probe during module load, disable
136 with module option "auto_probe=0". Moved some debugging
137 statements to lower priority. Implemented select_speed()
138 function.
139
14013 feb 1997 1.0 Final version for 2.0 kernel line.
141
142 All following changes will be for the 2.1 kernel line.
143
14415 feb 1997 1.1 Keep up with kernel 2.1.26, merge in changes from
145 cdrom.c 0.100.1.1--1.0. Add some more MODULE_PARMS.
146
14714 sep 1997 1.2 Upgrade to Linux 2.1.55. Added blksize_size[], patch
148 sent by James Bottomley <James.Bottomley@columbiasc.ncr.com>.
149
15021 dec 1997 1.4 Upgrade to Linux 2.1.72.
151
15224 jan 1998 Removed the cm206_disc_status() function, as it was now dead
153 code. The Uniform CDROM driver now provides this functionality.
154
1559 Nov. 1999 Make kernel-parameter implementation work with 2.3.x
156 Removed init_module & cleanup_module in favor of
157 module_init & module_exit.
158 Torben Mathiasen <tmm@image.dk>
159 *
160 * Parts of the code are based upon lmscd.c written by Kai Petzke,
161 * sbpcd.c written by Eberhard Moenkeberg, and mcd.c by Martin
162 * Harriss, but any off-the-shelf dynamic programming algorithm won't
163 * be able to find them.
164 *
165 * The cm206 drive interface and the cm260 adapter card seem to be
166 * sufficiently different from their cm205/cm250 counterparts
167 * in order to write a complete new driver.
168 *
169 * I call all routines connected to the Linux kernel something
170 * with `cm206' in it, as this stuff is too series-dependent.
171 *
172 * Currently, my limited knowledge is based on:
173 * - The Linux Kernel Hacker's guide, v. 0.5, by Michael K. Johnson
174 * - Linux Kernel Programmierung, by Michael Beck and others
175 * - Philips/LMS cm206 and cm226 product specification
176 * - Philips/LMS cm260 product specification
177 *
178 * David van Leeuwen, david@tm.tno.nl. */
179#define REVISION "$Revision: 1.5 $"
180
181#include <linux/module.h>
182
183#include <linux/errno.h> /* These include what we really need */
184#include <linux/delay.h>
185#include <linux/string.h>
186#include <linux/interrupt.h>
187#include <linux/timer.h>
188#include <linux/cdrom.h>
189#include <linux/ioport.h>
190#include <linux/mm.h>
191#include <linux/slab.h>
192#include <linux/init.h>
193
194/* #include <linux/ucdrom.h> */
195
196#include <asm/io.h>
197
198#define MAJOR_NR CM206_CDROM_MAJOR
199
200#include <linux/blkdev.h>
201
202#undef DEBUG
203#define STATISTICS /* record times and frequencies of events */
204#define AUTO_PROBE_MODULE
205#define USE_INSW
206
207#include "cm206.h"
208
209/* This variable defines whether or not to probe for adapter base port
210 address and interrupt request. It can be overridden by the boot
211 parameter `auto'.
212*/
213static int auto_probe = 1; /* Yes, why not? */
214
215static int cm206_base = CM206_BASE;
216static int cm206_irq = CM206_IRQ;
217#ifdef MODULE
218static int cm206[2] = { 0, 0 }; /* for compatible `insmod' parameter passing */
219module_param_array(cm206, int, NULL, 0); /* base,irq or irq,base */
220#endif
221
222module_param(cm206_base, int, 0); /* base */
223module_param(cm206_irq, int, 0); /* irq */
224module_param(auto_probe, bool, 0); /* auto probe base and irq */
225MODULE_LICENSE("GPL");
226
227#define POLLOOP 100 /* milliseconds */
228#define READ_AHEAD 1 /* defines private buffer, waste! */
229#define BACK_AHEAD 1 /* defines adapter-read ahead */
230#define DATA_TIMEOUT (3*HZ) /* measured in jiffies (10 ms) */
231#define UART_TIMEOUT (5*HZ/100)
232#define DSB_TIMEOUT (7*HZ) /* time for the slowest command to finish */
233#define UR_SIZE 4 /* uart receive buffer fifo size */
234
235#define LINUX_BLOCK_SIZE 512 /* WHERE is this defined? */
236#define RAW_SECTOR_SIZE 2352 /* ok, is also defined in cdrom.h */
237#define ISO_SECTOR_SIZE 2048
238#define BLOCKS_ISO (ISO_SECTOR_SIZE/LINUX_BLOCK_SIZE) /* 4 */
239#define CD_SYNC_HEAD 16 /* CD_SYNC + CD_HEAD */
240
241#ifdef STATISTICS /* keep track of errors in counters */
242#define stats(i) { ++cd->stats[st_ ## i]; \
243 cd->last_stat[st_ ## i] = cd->stat_counter++; \
244 }
245#else
246#define stats(i) (void) 0;
247#endif
248
249#define Debug(a) {printk (KERN_DEBUG); printk a;}
250#ifdef DEBUG
251#define debug(a) Debug(a)
252#else
253#define debug(a) (void) 0;
254#endif
255
256typedef unsigned char uch; /* 8-bits */
257typedef unsigned short ush; /* 16-bits */
258
259struct toc_struct { /* private copy of Table of Contents */
260 uch track, fsm[3], q0;
261};
262
263struct cm206_struct {
264 volatile ush intr_ds; /* data status read on last interrupt */
265 volatile ush intr_ls; /* uart line status read on last interrupt */
266 volatile uch ur[UR_SIZE]; /* uart receive buffer fifo */
267 volatile uch ur_w, ur_r; /* write/read buffer index */
268 volatile uch dsb, cc; /* drive status byte and condition (error) code */
269 int command; /* command to be written to the uart */
270 int openfiles;
271 ush sector[READ_AHEAD * RAW_SECTOR_SIZE / 2]; /* buffered cd-sector */
272 int sector_first, sector_last; /* range of these sectors */
273 wait_queue_head_t uart; /* wait queues for interrupt */
274 wait_queue_head_t data;
275 struct timer_list timer; /* time-out */
276 char timed_out;
277 signed char max_sectors; /* number of sectors that fit in adapter mem */
278 char wait_back; /* we're waiting for a background-read */
279 char background; /* is a read going on in the background? */
280 int adapter_first; /* if so, that's the starting sector */
281 int adapter_last;
282 char fifo_overflowed;
283 uch disc_status[7]; /* result of get_disc_status command */
284#ifdef STATISTICS
285 int stats[NR_STATS];
286 int last_stat[NR_STATS]; /* `time' at which stat was stat */
287 int stat_counter;
288#endif
289 struct toc_struct toc[101]; /* The whole table of contents + lead-out */
290 uch q[10]; /* Last read q-channel info */
291 uch audio_status[5]; /* last read position on pause */
292 uch media_changed; /* record if media changed */
293};
294
295#define DISC_STATUS cd->disc_status[0]
296#define FIRST_TRACK cd->disc_status[1]
297#define LAST_TRACK cd->disc_status[2]
298#define PAUSED cd->audio_status[0] /* misuse this memory byte! */
299#define PLAY_TO cd->toc[0] /* toc[0] records end-time in play */
300
301static struct cm206_struct *cd; /* the main memory structure */
302static struct request_queue *cm206_queue;
303static DEFINE_SPINLOCK(cm206_lock);
304
305/* First, we define some polling functions. These are actually
306 only being used in the initialization. */
307
308static void send_command_polled(int command)
309{
310 int loop = POLLOOP;
311 while (!(inw(r_line_status) & ls_transmitter_buffer_empty)
312 && loop > 0) {
313 mdelay(1); /* one millisec delay */
314 --loop;
315 }
316 outw(command, r_uart_transmit);
317}
318
319static uch receive_echo_polled(void)
320{
321 int loop = POLLOOP;
322 while (!(inw(r_line_status) & ls_receive_buffer_full) && loop > 0) {
323 mdelay(1);
324 --loop;
325 }
326 return ((uch) inw(r_uart_receive));
327}
328
329static uch send_receive_polled(int command)
330{
331 send_command_polled(command);
332 return receive_echo_polled();
333}
334
335static inline void clear_ur(void)
336{
337 if (cd->ur_r != cd->ur_w) {
338 debug(("Deleting bytes from fifo:"));
339 for (; cd->ur_r != cd->ur_w;
340 cd->ur_r++, cd->ur_r %= UR_SIZE)
341 debug((" 0x%x", cd->ur[cd->ur_r]));
342 debug(("\n"));
343 }
344}
345
346static struct tasklet_struct cm206_tasklet;
347
348/* The interrupt handler. When the cm260 generates an interrupt, very
349 much care has to be taken in reading out the registers in the right
350 order; in case of a receive_buffer_full interrupt, first the
351 uart_receive must be read, and then the line status again to
352 de-assert the interrupt line. It took me a couple of hours to find
353 this out:-(
354
355 The function reset_cm206 appears to cause an interrupt, because
356 pulling up the INIT line clears both the uart-write-buffer /and/
357 the uart-write-buffer-empty mask. We call this a `lost interrupt,'
358 as there seems so reason for this to happen.
359*/
360
361static irqreturn_t cm206_interrupt(int sig, void *dev_id)
362{
363 volatile ush fool;
364 cd->intr_ds = inw(r_data_status); /* resets data_ready, data_error,
365 crc_error, sync_error, toc_ready
366 interrupts */
367 cd->intr_ls = inw(r_line_status); /* resets overrun bit */
368 debug(("Intr, 0x%x 0x%x, %d\n", cd->intr_ds, cd->intr_ls,
369 cd->background));
370 if (cd->intr_ls & ls_attention)
371 stats(attention);
372 /* receive buffer full? */
373 if (cd->intr_ls & ls_receive_buffer_full) {
374 cd->ur[cd->ur_w] = inb(r_uart_receive); /* get order right! */
375 cd->intr_ls = inw(r_line_status); /* resets rbf interrupt */
376 debug(("receiving #%d: 0x%x\n", cd->ur_w,
377 cd->ur[cd->ur_w]));
378 cd->ur_w++;
379 cd->ur_w %= UR_SIZE;
380 if (cd->ur_w == cd->ur_r)
381 debug(("cd->ur overflow!\n"));
382 if (waitqueue_active(&cd->uart) && cd->background < 2) {
383 del_timer(&cd->timer);
384 wake_up_interruptible(&cd->uart);
385 }
386 }
387 /* data ready in fifo? */
388 else if (cd->intr_ds & ds_data_ready) {
389 if (cd->background)
390 ++cd->adapter_last;
391 if (waitqueue_active(&cd->data)
392 && (cd->wait_back || !cd->background)) {
393 del_timer(&cd->timer);
394 wake_up_interruptible(&cd->data);
395 }
396 stats(data_ready);
397 }
398 /* ready to issue a write command? */
399 else if (cd->command && cd->intr_ls & ls_transmitter_buffer_empty) {
400 outw(dc_normal | (inw(r_data_status) & 0x7f),
401 r_data_control);
402 outw(cd->command, r_uart_transmit);
403 cd->command = 0;
404 if (!cd->background)
405 wake_up_interruptible(&cd->uart);
406 }
407 /* now treat errors (at least, identify them for debugging) */
408 else if (cd->intr_ds & ds_fifo_overflow) {
409 debug(("Fifo overflow at sectors 0x%x\n",
410 cd->sector_first));
411 fool = inw(r_fifo_output_buffer); /* de-assert the interrupt */
412 cd->fifo_overflowed = 1; /* signal one word less should be read */
413 stats(fifo_overflow);
414 } else if (cd->intr_ds & ds_data_error) {
415 debug(("Data error at sector 0x%x\n", cd->sector_first));
416 stats(data_error);
417 } else if (cd->intr_ds & ds_crc_error) {
418 debug(("CRC error at sector 0x%x\n", cd->sector_first));
419 stats(crc_error);
420 } else if (cd->intr_ds & ds_sync_error) {
421 debug(("Sync at sector 0x%x\n", cd->sector_first));
422 stats(sync_error);
423 } else if (cd->intr_ds & ds_toc_ready) {
424 /* do something appropriate */
425 }
426 /* couldn't see why this interrupt, maybe due to init */
427 else {
428 outw(dc_normal | READ_AHEAD, r_data_control);
429 stats(lost_intr);
430 }
431 if (cd->background
432 && (cd->adapter_last - cd->adapter_first == cd->max_sectors
433 || cd->fifo_overflowed))
434 tasklet_schedule(&cm206_tasklet); /* issue a stop read command */
435 stats(interrupt);
436 return IRQ_HANDLED;
437}
438
439/* we have put the address of the wait queue in who */
440static void cm206_timeout(unsigned long who)
441{
442 cd->timed_out = 1;
443 debug(("Timing out\n"));
444 wake_up_interruptible((wait_queue_head_t *) who);
445}
446
447/* This function returns 1 if a timeout occurred, 0 if an interrupt
448 happened */
449static int sleep_or_timeout(wait_queue_head_t * wait, int timeout)
450{
451 cd->timed_out = 0;
452 init_timer(&cd->timer);
453 cd->timer.data = (unsigned long) wait;
454 cd->timer.expires = jiffies + timeout;
455 add_timer(&cd->timer);
456 debug(("going to sleep\n"));
457 interruptible_sleep_on(wait);
458 del_timer(&cd->timer);
459 if (cd->timed_out) {
460 cd->timed_out = 0;
461 return 1;
462 } else
463 return 0;
464}
465
466static void send_command(int command)
467{
468 debug(("Sending 0x%x\n", command));
469 if (!(inw(r_line_status) & ls_transmitter_buffer_empty)) {
470 cd->command = command;
471 cli(); /* don't interrupt before sleep */
472 outw(dc_mask_sync_error | dc_no_stop_on_error |
473 (inw(r_data_status) & 0x7f), r_data_control);
474 /* interrupt routine sends command */
475 if (sleep_or_timeout(&cd->uart, UART_TIMEOUT)) {
476 debug(("Time out on write-buffer\n"));
477 stats(write_timeout);
478 outw(command, r_uart_transmit);
479 }
480 debug(("Write commmand delayed\n"));
481 } else
482 outw(command, r_uart_transmit);
483}
484
485static uch receive_byte(int timeout)
486{
487 uch ret;
488 cli();
489 debug(("cli\n"));
490 ret = cd->ur[cd->ur_r];
491 if (cd->ur_r != cd->ur_w) {
492 sti();
493 debug(("returning #%d: 0x%x\n", cd->ur_r,
494 cd->ur[cd->ur_r]));
495 cd->ur_r++;
496 cd->ur_r %= UR_SIZE;
497 return ret;
498 } else if (sleep_or_timeout(&cd->uart, timeout)) { /* does sti() */
499 debug(("Time out on receive-buffer\n"));
500#ifdef STATISTICS
501 if (timeout == UART_TIMEOUT)
502 stats(receive_timeout) /* no `;'! */
503 else
504 stats(dsb_timeout);
505#endif
506 return 0xda;
507 }
508 ret = cd->ur[cd->ur_r];
509 debug(("slept; returning #%d: 0x%x\n", cd->ur_r,
510 cd->ur[cd->ur_r]));
511 cd->ur_r++;
512 cd->ur_r %= UR_SIZE;
513 return ret;
514}
515
516static inline uch receive_echo(void)
517{
518 return receive_byte(UART_TIMEOUT);
519}
520
521static inline uch send_receive(int command)
522{
523 send_command(command);
524 return receive_echo();
525}
526
527static inline uch wait_dsb(void)
528{
529 return receive_byte(DSB_TIMEOUT);
530}
531
532static int type_0_command(int command, int expect_dsb)
533{
534 int e;
535 clear_ur();
536 if (command != (e = send_receive(command))) {
537 debug(("command 0x%x echoed as 0x%x\n", command, e));
538 stats(echo);
539 return -1;
540 }
541 if (expect_dsb) {
542 cd->dsb = wait_dsb(); /* wait for command to finish */
543 }
544 return 0;
545}
546
547static int type_1_command(int command, int bytes, uch * status)
548{ /* returns info */
549 int i;
550 if (type_0_command(command, 0))
551 return -1;
552 for (i = 0; i < bytes; i++)
553 status[i] = send_receive(c_gimme);
554 return 0;
555}
556
557/* This function resets the adapter card. We'd better not do this too
558 * often, because it tends to generate `lost interrupts.' */
559static void reset_cm260(void)
560{
561 outw(dc_normal | dc_initialize | READ_AHEAD, r_data_control);
562 udelay(10); /* 3.3 mu sec minimum */
563 outw(dc_normal | READ_AHEAD, r_data_control);
564}
565
566/* fsm: frame-sec-min from linear address; one of many */
567static void fsm(int lba, uch * fsm)
568{
569 fsm[0] = lba % 75;
570 lba /= 75;
571 lba += 2;
572 fsm[1] = lba % 60;
573 fsm[2] = lba / 60;
574}
575
576static inline int fsm2lba(uch * fsm)
577{
578 return fsm[0] + 75 * (fsm[1] - 2 + 60 * fsm[2]);
579}
580
581static inline int f_s_m2lba(uch f, uch s, uch m)
582{
583 return f + 75 * (s - 2 + 60 * m);
584}
585
586static int start_read(int start)
587{
588 uch read_sector[4] = { c_read_data, };
589 int i, e;
590
591 fsm(start, &read_sector[1]);
592 clear_ur();
593 for (i = 0; i < 4; i++)
594 if (read_sector[i] != (e = send_receive(read_sector[i]))) {
595 debug(("read_sector: %x echoes %x\n",
596 read_sector[i], e));
597 stats(echo);
598 if (e == 0xff) { /* this seems to happen often */
599 e = receive_echo();
600 debug(("Second try %x\n", e));
601 if (e != read_sector[i])
602 return -1;
603 }
604 }
605 return 0;
606}
607
608static int stop_read(void)
609{
610 int e;
611 type_0_command(c_stop, 0);
612 if ((e = receive_echo()) != 0xff) {
613 debug(("c_stop didn't send 0xff, but 0x%x\n", e));
614 stats(stop_0xff);
615 return -1;
616 }
617 return 0;
618}
619
620/* This function starts to read sectors in adapter memory, the
621 interrupt routine should stop the read. In fact, the bottom_half
622 routine takes care of this. Set a flag `background' in the cd
623 struct to indicate the process. */
624
625static int read_background(int start, int reading)
626{
627 if (cd->background)
628 return -1; /* can't do twice */
629 outw(dc_normal | BACK_AHEAD, r_data_control);
630 if (!reading && start_read(start))
631 return -2;
632 cd->adapter_first = cd->adapter_last = start;
633 cd->background = 1; /* flag a read is going on */
634 return 0;
635}
636
637#ifdef USE_INSW
638#define transport_data insw
639#else
640/* this routine implements insw(,,). There was a time i had the
641 impression that there would be any difference in error-behaviour. */
642void transport_data(int port, ush * dest, int count)
643{
644 int i;
645 ush *d;
646 for (i = 0, d = dest; i < count; i++, d++)
647 *d = inw(port);
648}
649#endif
650
651
652#define MAX_TRIES 100
653static int read_sector(int start)
654{
655 int tries = 0;
656 if (cd->background) {
657 cd->background = 0;
658 cd->adapter_last = -1; /* invalidate adapter memory */
659 stop_read();
660 }
661 cd->fifo_overflowed = 0;
662 reset_cm260(); /* empty fifo etc. */
663 if (start_read(start))
664 return -1;
665 do {
666 if (sleep_or_timeout(&cd->data, DATA_TIMEOUT)) {
667 debug(("Read timed out sector 0x%x\n", start));
668 stats(read_timeout);
669 stop_read();
670 return -3;
671 }
672 tries++;
673 } while (cd->intr_ds & ds_fifo_empty && tries < MAX_TRIES);
674 if (tries > 1)
675 debug(("Took me some tries\n"))
676 else
677 if (tries == MAX_TRIES)
678 debug(("MAX_TRIES tries for read sector\n"));
679 transport_data(r_fifo_output_buffer, cd->sector,
680 READ_AHEAD * RAW_SECTOR_SIZE / 2);
681 if (read_background(start + READ_AHEAD, 1))
682 stats(read_background);
683 cd->sector_first = start;
684 cd->sector_last = start + READ_AHEAD;
685 stats(read_restarted);
686 return 0;
687}
688
689/* The function of bottom-half is to send a stop command to the drive
690 This isn't easy because the routine is not `owned' by any process;
691 we can't go to sleep! The variable cd->background gives the status:
692 0 no read pending
693 1 a read is pending
694 2 c_stop waits for write_buffer_empty
695 3 c_stop waits for receive_buffer_full: echo
696 4 c_stop waits for receive_buffer_full: 0xff
697*/
698
699static void cm206_tasklet_func(unsigned long ignore)
700{
701 debug(("bh: %d\n", cd->background));
702 switch (cd->background) {
703 case 1:
704 stats(bh);
705 if (!(cd->intr_ls & ls_transmitter_buffer_empty)) {
706 cd->command = c_stop;
707 outw(dc_mask_sync_error | dc_no_stop_on_error |
708 (inw(r_data_status) & 0x7f), r_data_control);
709 cd->background = 2;
710 break; /* we'd better not time-out here! */
711 } else
712 outw(c_stop, r_uart_transmit);
713 /* fall into case 2: */
714 case 2:
715 /* the write has been satisfied by interrupt routine */
716 cd->background = 3;
717 break;
718 case 3:
719 if (cd->ur_r != cd->ur_w) {
720 if (cd->ur[cd->ur_r] != c_stop) {
721 debug(("cm206_bh: c_stop echoed 0x%x\n",
722 cd->ur[cd->ur_r]));
723 stats(echo);
724 }
725 cd->ur_r++;
726 cd->ur_r %= UR_SIZE;
727 }
728 cd->background++;
729 break;
730 case 4:
731 if (cd->ur_r != cd->ur_w) {
732 if (cd->ur[cd->ur_r] != 0xff) {
733 debug(("cm206_bh: c_stop reacted with 0x%x\n", cd->ur[cd->ur_r]));
734 stats(stop_0xff);
735 }
736 cd->ur_r++;
737 cd->ur_r %= UR_SIZE;
738 }
739 cd->background = 0;
740 }
741}
742
743static DECLARE_TASKLET(cm206_tasklet, cm206_tasklet_func, 0);
744
745/* This command clears the dsb_possible_media_change flag, so we must
746 * retain it.
747 */
748static void get_drive_status(void)
749{
750 uch status[2];
751 type_1_command(c_drive_status, 2, status); /* this might be done faster */
752 cd->dsb = status[0];
753 cd->cc = status[1];
754 cd->media_changed |=
755 !!(cd->dsb & (dsb_possible_media_change |
756 dsb_drive_not_ready | dsb_tray_not_closed));
757}
758
759static void get_disc_status(void)
760{
761 if (type_1_command(c_disc_status, 7, cd->disc_status)) {
762 debug(("get_disc_status: error\n"));
763 }
764}
765
766/* The new open. The real opening strategy is defined in cdrom.c. */
767
768static int cm206_open(struct cdrom_device_info *cdi, int purpose)
769{
770 if (!cd->openfiles) { /* reset only first time */
771 cd->background = 0;
772 reset_cm260();
773 cd->adapter_last = -1; /* invalidate adapter memory */
774 cd->sector_last = -1;
775 }
776 ++cd->openfiles;
777 stats(open);
778 return 0;
779}
780
781static void cm206_release(struct cdrom_device_info *cdi)
782{
783 if (cd->openfiles == 1) {
784 if (cd->background) {
785 cd->background = 0;
786 stop_read();
787 }
788 cd->sector_last = -1; /* Make our internal buffer invalid */
789 FIRST_TRACK = 0; /* No valid disc status */
790 }
791 --cd->openfiles;
792}
793
794/* Empty buffer empties $sectors$ sectors of the adapter card buffer,
795 * and then reads a sector in kernel memory. */
796static void empty_buffer(int sectors)
797{
798 while (sectors >= 0) {
799 transport_data(r_fifo_output_buffer,
800 cd->sector + cd->fifo_overflowed,
801 RAW_SECTOR_SIZE / 2 - cd->fifo_overflowed);
802 --sectors;
803 ++cd->adapter_first; /* update the current adapter sector */
804 cd->fifo_overflowed = 0; /* reset overflow bit */
805 stats(sector_transferred);
806 }
807 cd->sector_first = cd->adapter_first - 1;
808 cd->sector_last = cd->adapter_first; /* update the buffer sector */
809}
810
811/* try_adapter. This function determines if the requested sector is
812 in adapter memory, or will appear there soon. Returns 0 upon
813 success */
814static int try_adapter(int sector)
815{
816 if (cd->adapter_first <= sector && sector < cd->adapter_last) {
817 /* sector is in adapter memory */
818 empty_buffer(sector - cd->adapter_first);
819 return 0;
820 } else if (cd->background == 1 && cd->adapter_first <= sector
821 && sector < cd->adapter_first + cd->max_sectors) {
822 /* a read is going on, we can wait for it */
823 cd->wait_back = 1;
824 while (sector >= cd->adapter_last) {
825 if (sleep_or_timeout(&cd->data, DATA_TIMEOUT)) {
826 debug(("Timed out during background wait: %d %d %d %d\n", sector, cd->adapter_last, cd->adapter_first, cd->background));
827 stats(back_read_timeout);
828 cd->wait_back = 0;
829 return -1;
830 }
831 }
832 cd->wait_back = 0;
833 empty_buffer(sector - cd->adapter_first);
834 return 0;
835 } else
836 return -2;
837}
838
839/* This is not a very smart implementation. We could optimize for
840 consecutive block numbers. I'm not convinced this would really
841 bring down the processor load. */
842static void do_cm206_request(request_queue_t * q)
843{
844 long int i, cd_sec_no;
845 int quarter, error;
846 uch *source, *dest;
847 struct request *req;
848
849 while (1) { /* repeat until all requests have been satisfied */
850 req = elv_next_request(q);
851 if (!req)
852 return;
853
854 if (rq_data_dir(req) != READ) {
855 debug(("Non-read command %d on cdrom\n", req->cmd));
856 end_request(req, 0);
857 continue;
858 }
859 spin_unlock_irq(q->queue_lock);
860 error = 0;
861 for (i = 0; i < req->nr_sectors; i++) {
862 int e1, e2;
863 cd_sec_no = (req->sector + i) / BLOCKS_ISO; /* 4 times 512 bytes */
864 quarter = (req->sector + i) % BLOCKS_ISO;
865 dest = req->buffer + i * LINUX_BLOCK_SIZE;
866 /* is already in buffer memory? */
867 if (cd->sector_first <= cd_sec_no
868 && cd_sec_no < cd->sector_last) {
869 source =
870 ((uch *) cd->sector) + 16 +
871 quarter * LINUX_BLOCK_SIZE +
872 (cd_sec_no -
873 cd->sector_first) * RAW_SECTOR_SIZE;
874 memcpy(dest, source, LINUX_BLOCK_SIZE);
875 } else if (!(e1 = try_adapter(cd_sec_no)) ||
876 !(e2 = read_sector(cd_sec_no))) {
877 source =
878 ((uch *) cd->sector) + 16 +
879 quarter * LINUX_BLOCK_SIZE;
880 memcpy(dest, source, LINUX_BLOCK_SIZE);
881 } else {
882 error = 1;
883 debug(("cm206_request: %d %d\n", e1, e2));
884 }
885 }
886 spin_lock_irq(q->queue_lock);
887 end_request(req, !error);
888 }
889}
890
891/* Audio support. I've tried very hard, but the cm206 drive doesn't
892 seem to have a get_toc (table-of-contents) function, while i'm
893 pretty sure it must read the toc upon disc insertion. Therefore
894 this function has been implemented through a binary search
895 strategy. All track starts that happen to be found are stored in
896 cd->toc[], for future use.
897
898 I've spent a whole day on a bug that only shows under Workman---
899 I don't get it. Tried everything, nothing works. If workman asks
900 for track# 0xaa, it'll get the wrong time back. Any other program
901 receives the correct value. I'm stymied.
902*/
903
904/* seek seeks to address lba. It does wait to arrive there. */
905static void seek(int lba)
906{
907 int i;
908 uch seek_command[4] = { c_seek, };
909
910 fsm(lba, &seek_command[1]);
911 for (i = 0; i < 4; i++)
912 type_0_command(seek_command[i], 0);
913 cd->dsb = wait_dsb();
914}
915
916static uch bcdbin(unsigned char bcd)
917{ /* stolen from mcd.c! */
918 return (bcd >> 4) * 10 + (bcd & 0xf);
919}
920
921static inline uch normalize_track(uch track)
922{
923 if (track < 1)
924 return 1;
925 if (track > LAST_TRACK)
926 return LAST_TRACK + 1;
927 return track;
928}
929
930/* This function does a binary search for track start. It records all
931 * tracks seen in the process. Input $track$ must be between 1 and
932 * #-of-tracks+1. Note that the start of the disc must be in toc[1].fsm.
933 */
934static int get_toc_lba(uch track)
935{
936 int max = 74 * 60 * 75 - 150, min = fsm2lba(cd->toc[1].fsm);
937 int i, lba, l, old_lba = 0;
938 uch *q = cd->q;
939 uch ct; /* current track */
940 int binary = 0;
941 const int skip = 3 * 60 * 75; /* 3 minutes */
942
943 for (i = track; i > 0; i--)
944 if (cd->toc[i].track) {
945 min = fsm2lba(cd->toc[i].fsm);
946 break;
947 }
948 lba = min + skip;
949 do {
950 seek(lba);
951 type_1_command(c_read_current_q, 10, q);
952 ct = normalize_track(q[1]);
953 if (!cd->toc[ct].track) {
954 l = q[9] - bcdbin(q[5]) + 75 * (q[8] -
955 bcdbin(q[4]) - 2 +
956 60 * (q[7] -
957 bcdbin(q
958 [3])));
959 cd->toc[ct].track = q[1]; /* lead out still 0xaa */
960 fsm(l, cd->toc[ct].fsm);
961 cd->toc[ct].q0 = q[0]; /* contains adr and ctrl info */
962 if (ct == track)
963 return l;
964 }
965 old_lba = lba;
966 if (binary) {
967 if (ct < track)
968 min = lba;
969 else
970 max = lba;
971 lba = (min + max) / 2;
972 } else {
973 if (ct < track)
974 lba += skip;
975 else {
976 binary = 1;
977 max = lba;
978 min = lba - skip;
979 lba = (min + max) / 2;
980 }
981 }
982 } while (lba != old_lba);
983 return lba;
984}
985
986static void update_toc_entry(uch track)
987{
988 track = normalize_track(track);
989 if (!cd->toc[track].track)
990 get_toc_lba(track);
991}
992
993/* return 0 upon success */
994static int read_toc_header(struct cdrom_tochdr *hp)
995{
996 if (!FIRST_TRACK)
997 get_disc_status();
998 if (hp) {
999 int i;
1000 hp->cdth_trk0 = FIRST_TRACK;
1001 hp->cdth_trk1 = LAST_TRACK;
1002 /* fill in first track position */
1003 for (i = 0; i < 3; i++)
1004 cd->toc[1].fsm[i] = cd->disc_status[3 + i];
1005 update_toc_entry(LAST_TRACK + 1); /* find most entries */
1006 return 0;
1007 }
1008 return -1;
1009}
1010
1011static void play_from_to_msf(struct cdrom_msf *msfp)
1012{
1013 uch play_command[] = { c_play,
1014 msfp->cdmsf_frame0, msfp->cdmsf_sec0, msfp->cdmsf_min0,
1015 msfp->cdmsf_frame1, msfp->cdmsf_sec1, msfp->cdmsf_min1, 2,
1016 2
1017 };
1018 int i;
1019 for (i = 0; i < 9; i++)
1020 type_0_command(play_command[i], 0);
1021 for (i = 0; i < 3; i++)
1022 PLAY_TO.fsm[i] = play_command[i + 4];
1023 PLAY_TO.track = 0; /* say no track end */
1024 cd->dsb = wait_dsb();
1025}
1026
1027static void play_from_to_track(int from, int to)
1028{
1029 uch play_command[8] = { c_play, };
1030 int i;
1031
1032 if (from == 0) { /* continue paused play */
1033 for (i = 0; i < 3; i++) {
1034 play_command[i + 1] = cd->audio_status[i + 2];
1035 play_command[i + 4] = PLAY_TO.fsm[i];
1036 }
1037 } else {
1038 update_toc_entry(from);
1039 update_toc_entry(to + 1);
1040 for (i = 0; i < 3; i++) {
1041 play_command[i + 1] = cd->toc[from].fsm[i];
1042 PLAY_TO.fsm[i] = play_command[i + 4] =
1043 cd->toc[to + 1].fsm[i];
1044 }
1045 PLAY_TO.track = to;
1046 }
1047 for (i = 0; i < 7; i++)
1048 type_0_command(play_command[i], 0);
1049 for (i = 0; i < 2; i++)
1050 type_0_command(0x2, 0); /* volume */
1051 cd->dsb = wait_dsb();
1052}
1053
1054static int get_current_q(struct cdrom_subchnl *qp)
1055{
1056 int i;
1057 uch *q = cd->q;
1058 if (type_1_command(c_read_current_q, 10, q))
1059 return 0;
1060/* q[0] = bcdbin(q[0]); Don't think so! */
1061 for (i = 2; i < 6; i++)
1062 q[i] = bcdbin(q[i]);
1063 qp->cdsc_adr = q[0] & 0xf;
1064 qp->cdsc_ctrl = q[0] >> 4; /* from mcd.c */
1065 qp->cdsc_trk = q[1];
1066 qp->cdsc_ind = q[2];
1067 if (qp->cdsc_format == CDROM_MSF) {
1068 qp->cdsc_reladdr.msf.minute = q[3];
1069 qp->cdsc_reladdr.msf.second = q[4];
1070 qp->cdsc_reladdr.msf.frame = q[5];
1071 qp->cdsc_absaddr.msf.minute = q[7];
1072 qp->cdsc_absaddr.msf.second = q[8];
1073 qp->cdsc_absaddr.msf.frame = q[9];
1074 } else {
1075 qp->cdsc_reladdr.lba = f_s_m2lba(q[5], q[4], q[3]);
1076 qp->cdsc_absaddr.lba = f_s_m2lba(q[9], q[8], q[7]);
1077 }
1078 get_drive_status();
1079 if (cd->dsb & dsb_play_in_progress)
1080 qp->cdsc_audiostatus = CDROM_AUDIO_PLAY;
1081 else if (PAUSED)
1082 qp->cdsc_audiostatus = CDROM_AUDIO_PAUSED;
1083 else
1084 qp->cdsc_audiostatus = CDROM_AUDIO_NO_STATUS;
1085 return 0;
1086}
1087
1088static void invalidate_toc(void)
1089{
1090 memset(cd->toc, 0, sizeof(cd->toc));
1091 memset(cd->disc_status, 0, sizeof(cd->disc_status));
1092}
1093
1094/* cdrom.c guarantees that cdte_format == CDROM_MSF */
1095static void get_toc_entry(struct cdrom_tocentry *ep)
1096{
1097 uch track = normalize_track(ep->cdte_track);
1098 update_toc_entry(track);
1099 ep->cdte_addr.msf.frame = cd->toc[track].fsm[0];
1100 ep->cdte_addr.msf.second = cd->toc[track].fsm[1];
1101 ep->cdte_addr.msf.minute = cd->toc[track].fsm[2];
1102 ep->cdte_adr = cd->toc[track].q0 & 0xf;
1103 ep->cdte_ctrl = cd->toc[track].q0 >> 4;
1104 ep->cdte_datamode = 0;
1105}
1106
1107/* Audio ioctl. Ioctl commands connected to audio are in such an
1108 * idiosyncratic i/o format, that we leave these untouched. Return 0
1109 * upon success. Memory checking has been done by cdrom_ioctl(), the
1110 * calling function, as well as LBA/MSF sanitization.
1111*/
1112static int cm206_audio_ioctl(struct cdrom_device_info *cdi, unsigned int cmd,
1113 void *arg)
1114{
1115 switch (cmd) {
1116 case CDROMREADTOCHDR:
1117 return read_toc_header((struct cdrom_tochdr *) arg);
1118 case CDROMREADTOCENTRY:
1119 get_toc_entry((struct cdrom_tocentry *) arg);
1120 return 0;
1121 case CDROMPLAYMSF:
1122 play_from_to_msf((struct cdrom_msf *) arg);
1123 return 0;
1124 case CDROMPLAYTRKIND: /* admittedly, not particularly beautiful */
1125 play_from_to_track(((struct cdrom_ti *) arg)->cdti_trk0,
1126 ((struct cdrom_ti *) arg)->cdti_trk1);
1127 return 0;
1128 case CDROMSTOP:
1129 PAUSED = 0;
1130 if (cd->dsb & dsb_play_in_progress)
1131 return type_0_command(c_stop, 1);
1132 else
1133 return 0;
1134 case CDROMPAUSE:
1135 get_drive_status();
1136 if (cd->dsb & dsb_play_in_progress) {
1137 type_0_command(c_stop, 1);
1138 type_1_command(c_audio_status, 5,
1139 cd->audio_status);
1140 PAUSED = 1; /* say we're paused */
1141 }
1142 return 0;
1143 case CDROMRESUME:
1144 if (PAUSED)
1145 play_from_to_track(0, 0);
1146 PAUSED = 0;
1147 return 0;
1148 case CDROMSTART:
1149 case CDROMVOLCTRL:
1150 return 0;
1151 case CDROMSUBCHNL:
1152 return get_current_q((struct cdrom_subchnl *) arg);
1153 default:
1154 return -EINVAL;
1155 }
1156}
1157
1158static int cm206_media_changed(struct cdrom_device_info *cdi, int disc_nr)
1159{
1160 if (cd != NULL) {
1161 int r;
1162 get_drive_status(); /* ensure cd->media_changed OK */
1163 r = cd->media_changed;
1164 cd->media_changed = 0; /* clear bit */
1165 return r;
1166 } else
1167 return -EIO;
1168}
1169
1170/* The new generic cdrom support. Routines should be concise, most of
1171 the logic should be in cdrom.c */
1172
1173
1174/* controls tray movement */
1175static int cm206_tray_move(struct cdrom_device_info *cdi, int position)
1176{
1177 if (position) { /* 1: eject */
1178 type_0_command(c_open_tray, 1);
1179 invalidate_toc();
1180 } else
1181 type_0_command(c_close_tray, 1); /* 0: close */
1182 return 0;
1183}
1184
1185/* gives current state of the drive */
1186static int cm206_drive_status(struct cdrom_device_info *cdi, int slot_nr)
1187{
1188 get_drive_status();
1189 if (cd->dsb & dsb_tray_not_closed)
1190 return CDS_TRAY_OPEN;
1191 if (!(cd->dsb & dsb_disc_present))
1192 return CDS_NO_DISC;
1193 if (cd->dsb & dsb_drive_not_ready)
1194 return CDS_DRIVE_NOT_READY;
1195 return CDS_DISC_OK;
1196}
1197
1198/* locks or unlocks door lock==1: lock; return 0 upon success */
1199static int cm206_lock_door(struct cdrom_device_info *cdi, int lock)
1200{
1201 uch command = (lock) ? c_lock_tray : c_unlock_tray;
1202 type_0_command(command, 1); /* wait and get dsb */
1203 /* the logic calculates the success, 0 means successful */
1204 return lock ^ ((cd->dsb & dsb_tray_locked) != 0);
1205}
1206
1207/* Although a session start should be in LBA format, we return it in
1208 MSF format because it is slightly easier, and the new generic ioctl
1209 will take care of the necessary conversion. */
1210static int cm206_get_last_session(struct cdrom_device_info *cdi,
1211 struct cdrom_multisession *mssp)
1212{
1213 if (!FIRST_TRACK)
1214 get_disc_status();
1215 if (mssp != NULL) {
1216 if (DISC_STATUS & cds_multi_session) { /* multi-session */
1217 mssp->addr.msf.frame = cd->disc_status[3];
1218 mssp->addr.msf.second = cd->disc_status[4];
1219 mssp->addr.msf.minute = cd->disc_status[5];
1220 mssp->addr_format = CDROM_MSF;
1221 mssp->xa_flag = 1;
1222 } else {
1223 mssp->xa_flag = 0;
1224 }
1225 return 1;
1226 }
1227 return 0;
1228}
1229
1230static int cm206_get_upc(struct cdrom_device_info *cdi, struct cdrom_mcn *mcn)
1231{
1232 uch upc[10];
1233 char *ret = mcn->medium_catalog_number;
1234 int i;
1235
1236 if (type_1_command(c_read_upc, 10, upc))
1237 return -EIO;
1238 for (i = 0; i < 13; i++) {
1239 int w = i / 2 + 1, r = i % 2;
1240 if (r)
1241 ret[i] = 0x30 | (upc[w] & 0x0f);
1242 else
1243 ret[i] = 0x30 | ((upc[w] >> 4) & 0x0f);
1244 }
1245 ret[13] = '\0';
1246 return 0;
1247}
1248
1249static int cm206_reset(struct cdrom_device_info *cdi)
1250{
1251 stop_read();
1252 reset_cm260();
1253 outw(dc_normal | dc_break | READ_AHEAD, r_data_control);
1254 mdelay(1); /* 750 musec minimum */
1255 outw(dc_normal | READ_AHEAD, r_data_control);
1256 cd->sector_last = -1; /* flag no data buffered */
1257 cd->adapter_last = -1;
1258 invalidate_toc();
1259 return 0;
1260}
1261
1262static int cm206_select_speed(struct cdrom_device_info *cdi, int speed)
1263{
1264 int r;
1265 switch (speed) {
1266 case 0:
1267 r = type_0_command(c_auto_mode, 1);
1268 break;
1269 case 1:
1270 r = type_0_command(c_force_1x, 1);
1271 break;
1272 case 2:
1273 r = type_0_command(c_force_2x, 1);
1274 break;
1275 default:
1276 return -1;
1277 }
1278 if (r < 0)
1279 return r;
1280 else
1281 return 1;
1282}
1283
1284static struct cdrom_device_ops cm206_dops = {
1285 .open = cm206_open,
1286 .release = cm206_release,
1287 .drive_status = cm206_drive_status,
1288 .media_changed = cm206_media_changed,
1289 .tray_move = cm206_tray_move,
1290 .lock_door = cm206_lock_door,
1291 .select_speed = cm206_select_speed,
1292 .get_last_session = cm206_get_last_session,
1293 .get_mcn = cm206_get_upc,
1294 .reset = cm206_reset,
1295 .audio_ioctl = cm206_audio_ioctl,
1296 .capability = CDC_CLOSE_TRAY | CDC_OPEN_TRAY | CDC_LOCK |
1297 CDC_MULTI_SESSION | CDC_MEDIA_CHANGED |
1298 CDC_MCN | CDC_PLAY_AUDIO | CDC_SELECT_SPEED |
1299 CDC_DRIVE_STATUS,
1300 .n_minors = 1,
1301};
1302
1303
1304static struct cdrom_device_info cm206_info = {
1305 .ops = &cm206_dops,
1306 .speed = 2,
1307 .capacity = 1,
1308 .name = "cm206",
1309};
1310
1311static int cm206_block_open(struct inode *inode, struct file *file)
1312{
1313 return cdrom_open(&cm206_info, inode, file);
1314}
1315
1316static int cm206_block_release(struct inode *inode, struct file *file)
1317{
1318 return cdrom_release(&cm206_info, file);
1319}
1320
1321static int cm206_block_ioctl(struct inode *inode, struct file *file,
1322 unsigned cmd, unsigned long arg)
1323{
1324 switch (cmd) {
1325#ifdef STATISTICS
1326 case CM206CTL_GET_STAT:
1327 if (arg >= NR_STATS)
1328 return -EINVAL;
1329 return cd->stats[arg];
1330 case CM206CTL_GET_LAST_STAT:
1331 if (arg >= NR_STATS)
1332 return -EINVAL;
1333 return cd->last_stat[arg];
1334#endif
1335 default:
1336 break;
1337 }
1338
1339 return cdrom_ioctl(file, &cm206_info, inode, cmd, arg);
1340}
1341
1342static int cm206_block_media_changed(struct gendisk *disk)
1343{
1344 return cdrom_media_changed(&cm206_info);
1345}
1346
1347static struct block_device_operations cm206_bdops =
1348{
1349 .owner = THIS_MODULE,
1350 .open = cm206_block_open,
1351 .release = cm206_block_release,
1352 .ioctl = cm206_block_ioctl,
1353 .media_changed = cm206_block_media_changed,
1354};
1355
1356static struct gendisk *cm206_gendisk;
1357
1358/* This function probes for the adapter card. It returns the base
1359 address if it has found the adapter card. One can specify a base
1360 port to probe specifically, or 0 which means span all possible
1361 bases.
1362
1363 Linus says it is too dangerous to use writes for probing, so we
1364 stick with pure reads for a while. Hope that 8 possible ranges,
1365 request_region, 15 bits of one port and 6 of another make things
1366 likely enough to accept the region on the first hit...
1367 */
1368static int __init probe_base_port(int base)
1369{
1370 int b = 0x300, e = 0x370; /* this is the range of start addresses */
1371 volatile int fool, i;
1372
1373 if (base)
1374 b = e = base;
1375 for (base = b; base <= e; base += 0x10) {
1376 if (!request_region(base, 0x10,"cm206"))
1377 continue;
1378 for (i = 0; i < 3; i++)
1379 fool = inw(base + 2); /* empty possibly uart_receive_buffer */
1380 if ((inw(base + 6) & 0xffef) != 0x0001 || /* line_status */
1381 (inw(base) & 0xad00) != 0) { /* data status */
1382 release_region(base,0x10);
1383 continue;
1384 }
1385 return (base);
1386 }
1387 return 0;
1388}
1389
1390#if !defined(MODULE) || defined(AUTO_PROBE_MODULE)
1391/* Probe for irq# nr. If nr==0, probe for all possible irq's. */
1392static int __init probe_irq(int nr)
1393{
1394 int irqs, irq;
1395 outw(dc_normal | READ_AHEAD, r_data_control); /* disable irq-generation */
1396 sti();
1397 irqs = probe_irq_on();
1398 reset_cm260(); /* causes interrupt */
1399 udelay(100); /* wait for it */
1400 irq = probe_irq_off(irqs);
1401 outw(dc_normal | READ_AHEAD, r_data_control); /* services interrupt */
1402 if (nr && irq != nr && irq > 0)
1403 return 0; /* wrong interrupt happened */
1404 else
1405 return irq;
1406}
1407#endif
1408
1409int __init cm206_init(void)
1410{
1411 uch e = 0;
1412 long int size = sizeof(struct cm206_struct);
1413 struct gendisk *disk;
1414
1415 printk(KERN_INFO "cm206 cdrom driver " REVISION);
1416 cm206_base = probe_base_port(auto_probe ? 0 : cm206_base);
1417 if (!cm206_base) {
1418 printk(" can't find adapter!\n");
1419 return -EIO;
1420 }
1421 printk(" adapter at 0x%x", cm206_base);
1422 cd = kmalloc(size, GFP_KERNEL);
1423 if (!cd)
1424 goto out_base;
1425 /* Now we have found the adaptor card, try to reset it. As we have
1426 * found out earlier, this process generates an interrupt as well,
1427 * so we might just exploit that fact for irq probing! */
1428#if !defined(MODULE) || defined(AUTO_PROBE_MODULE)
1429 cm206_irq = probe_irq(auto_probe ? 0 : cm206_irq);
1430 if (cm206_irq <= 0) {
1431 printk("can't find IRQ!\n");
1432 goto out_probe;
1433 } else
1434 printk(" IRQ %d found\n", cm206_irq);
1435#else
1436 cli();
1437 reset_cm260();
1438 /* Now, the problem here is that reset_cm260 can generate an
1439 interrupt. It seems that this can cause a kernel oops some time
1440 later. So we wait a while and `service' this interrupt. */
1441 mdelay(1);
1442 outw(dc_normal | READ_AHEAD, r_data_control);
1443 sti();
1444 printk(" using IRQ %d\n", cm206_irq);
1445#endif
1446 if (send_receive_polled(c_drive_configuration) !=
1447 c_drive_configuration) {
1448 printk(KERN_INFO " drive not there\n");
1449 goto out_probe;
1450 }
1451 e = send_receive_polled(c_gimme);
1452 printk(KERN_INFO "Firmware revision %d", e & dcf_revision_code);
1453 if (e & dcf_transfer_rate)
1454 printk(" double");
1455 else
1456 printk(" single");
1457 printk(" speed drive");
1458 if (e & dcf_motorized_tray)
1459 printk(", motorized tray");
1460 if (request_irq(cm206_irq, cm206_interrupt, 0, "cm206", NULL)) {
1461 printk("\nUnable to reserve IRQ---aborted\n");
1462 goto out_probe;
1463 }
1464 printk(".\n");
1465
1466 if (register_blkdev(MAJOR_NR, "cm206"))
1467 goto out_blkdev;
1468
1469 disk = alloc_disk(1);
1470 if (!disk)
1471 goto out_disk;
1472 disk->major = MAJOR_NR;
1473 disk->first_minor = 0;
1474 sprintf(disk->disk_name, "cm206cd");
1475 disk->fops = &cm206_bdops;
1476 disk->flags = GENHD_FL_CD;
1477 cm206_gendisk = disk;
1478 if (register_cdrom(&cm206_info) != 0) {
1479 printk(KERN_INFO "Cannot register for cdrom %d!\n", MAJOR_NR);
1480 goto out_cdrom;
1481 }
1482 cm206_queue = blk_init_queue(do_cm206_request, &cm206_lock);
1483 if (!cm206_queue)
1484 goto out_queue;
1485
1486 blk_queue_hardsect_size(cm206_queue, 2048);
1487 disk->queue = cm206_queue;
1488 add_disk(disk);
1489
1490 memset(cd, 0, sizeof(*cd)); /* give'm some reasonable value */
1491 cd->sector_last = -1; /* flag no data buffered */
1492 cd->adapter_last = -1;
1493 init_timer(&cd->timer);
1494 cd->timer.function = cm206_timeout;
1495 cd->max_sectors = (inw(r_data_status) & ds_ram_size) ? 24 : 97;
1496 printk(KERN_INFO "%d kB adapter memory available, "
1497 " %ld bytes kernel memory used.\n", cd->max_sectors * 2,
1498 size);
1499 return 0;
1500
1501out_queue:
1502 unregister_cdrom(&cm206_info);
1503out_cdrom:
1504 put_disk(disk);
1505out_disk:
1506 unregister_blkdev(MAJOR_NR, "cm206");
1507out_blkdev:
1508 free_irq(cm206_irq, NULL);
1509out_probe:
1510 kfree(cd);
1511out_base:
1512 release_region(cm206_base, 16);
1513 return -EIO;
1514}
1515
1516#ifdef MODULE
1517
1518
1519static void __init parse_options(void)
1520{
1521 int i;
1522 for (i = 0; i < 2; i++) {
1523 if (0x300 <= cm206[i] && i <= 0x370
1524 && cm206[i] % 0x10 == 0) {
1525 cm206_base = cm206[i];
1526 auto_probe = 0;
1527 } else if (3 <= cm206[i] && cm206[i] <= 15) {
1528 cm206_irq = cm206[i];
1529 auto_probe = 0;
1530 }
1531 }
1532}
1533
1534static int __init __cm206_init(void)
1535{
1536 parse_options();
1537#if !defined(AUTO_PROBE_MODULE)
1538 auto_probe = 0;
1539#endif
1540 return cm206_init();
1541}
1542
1543static void __exit cm206_exit(void)
1544{
1545 del_gendisk(cm206_gendisk);
1546 put_disk(cm206_gendisk);
1547 if (unregister_cdrom(&cm206_info)) {
1548 printk("Can't unregister cdrom cm206\n");
1549 return;
1550 }
1551 if (unregister_blkdev(MAJOR_NR, "cm206")) {
1552 printk("Can't unregister major cm206\n");
1553 return;
1554 }
1555 blk_cleanup_queue(cm206_queue);
1556 free_irq(cm206_irq, NULL);
1557 kfree(cd);
1558 release_region(cm206_base, 16);
1559 printk(KERN_INFO "cm206 removed\n");
1560}
1561
1562module_init(__cm206_init);
1563module_exit(cm206_exit);
1564
1565#else /* !MODULE */
1566
1567/* This setup function accepts either `auto' or numbers in the range
1568 * 3--11 (for irq) or 0x300--0x370 (for base port) or both. */
1569
1570static int __init cm206_setup(char *s)
1571{
1572 int i, p[4];
1573
1574 (void) get_options(s, ARRAY_SIZE(p), p);
1575
1576 if (!strcmp(s, "auto"))
1577 auto_probe = 1;
1578 for (i = 1; i <= p[0]; i++) {
1579 if (0x300 <= p[i] && i <= 0x370 && p[i] % 0x10 == 0) {
1580 cm206_base = p[i];
1581 auto_probe = 0;
1582 } else if (3 <= p[i] && p[i] <= 15) {
1583 cm206_irq = p[i];
1584 auto_probe = 0;
1585 }
1586 }
1587 return 1;
1588}
1589
1590__setup("cm206=", cm206_setup);
1591
1592#endif /* !MODULE */
1593MODULE_ALIAS_BLOCKDEV_MAJOR(CM206_CDROM_MAJOR);
1594
diff --git a/drivers/cdrom/cm206.h b/drivers/cdrom/cm206.h
deleted file mode 100644
index 0ae51c1a0dac..000000000000
--- a/drivers/cdrom/cm206.h
+++ /dev/null
@@ -1,171 +0,0 @@
1/* cm206.h Header file for cm206.c.
2 Copyright (c) 1995 David van Leeuwen
3*/
4
5#ifndef LINUX_CM206_H
6#define LINUX_CM206_H
7
8#include <linux/ioctl.h>
9
10/* First, the cm260 stuff */
11/* The ports and irq used. Although CM206_BASE and CM206_IRQ are defined
12 below, the values are not used unless autoprobing is turned off and
13 no LILO boot options or module command line options are given. Change
14 these values to your own as last resort if autoprobing and options
15 don't work. */
16
17#define CM206_BASE 0x340
18#define CM206_IRQ 11
19
20#define r_data_status (cm206_base)
21#define r_uart_receive (cm206_base+0x2)
22#define r_fifo_output_buffer (cm206_base+0x4)
23#define r_line_status (cm206_base+0x6)
24#define r_data_control (cm206_base+0x8)
25#define r_uart_transmit (cm206_base+0xa)
26#define r_test_clock (cm206_base+0xc)
27#define r_test_control (cm206_base+0xe)
28
29/* the data_status flags */
30#define ds_ram_size 0x4000
31#define ds_toc_ready 0x2000
32#define ds_fifo_empty 0x1000
33#define ds_sync_error 0x800
34#define ds_crc_error 0x400
35#define ds_data_error 0x200
36#define ds_fifo_overflow 0x100
37#define ds_data_ready 0x80
38
39/* the line_status flags */
40#define ls_attention 0x10
41#define ls_parity_error 0x8
42#define ls_overrun 0x4
43#define ls_receive_buffer_full 0x2
44#define ls_transmitter_buffer_empty 0x1
45
46/* the data control register flags */
47#define dc_read_q_channel 0x4000
48#define dc_mask_sync_error 0x2000
49#define dc_toc_enable 0x1000
50#define dc_no_stop_on_error 0x800
51#define dc_break 0x400
52#define dc_initialize 0x200
53#define dc_mask_transmit_ready 0x100
54#define dc_flag_enable 0x80
55
56/* Define the default data control register flags here */
57#define dc_normal (dc_mask_sync_error | dc_no_stop_on_error | \
58 dc_mask_transmit_ready)
59
60/* now some constants related to the cm206 */
61/* another drive status byte, echoed by the cm206 on most commands */
62
63#define dsb_error_condition 0x1
64#define dsb_play_in_progress 0x4
65#define dsb_possible_media_change 0x8
66#define dsb_disc_present 0x10
67#define dsb_drive_not_ready 0x20
68#define dsb_tray_locked 0x40
69#define dsb_tray_not_closed 0x80
70
71#define dsb_not_useful (dsb_drive_not_ready | dsb_tray_not_closed)
72
73/* the cm206 command set */
74
75#define c_close_tray 0
76#define c_lock_tray 0x01
77#define c_unlock_tray 0x04
78#define c_open_tray 0x05
79#define c_seek 0x10
80#define c_read_data 0x20
81#define c_force_1x 0x21
82#define c_force_2x 0x22
83#define c_auto_mode 0x23
84#define c_play 0x30
85#define c_set_audio_mode 0x31
86#define c_read_current_q 0x41
87#define c_stream_q 0x42
88#define c_drive_status 0x50
89#define c_disc_status 0x51
90#define c_audio_status 0x52
91#define c_drive_configuration 0x53
92#define c_read_upc 0x60
93#define c_stop 0x70
94#define c_calc_checksum 0xe5
95
96#define c_gimme 0xf8
97
98/* finally, the (error) condition that the drive can be in *
99 * OK, this is not always an error, but let's prefix it with e_ */
100
101#define e_none 0
102#define e_illegal_command 0x01
103#define e_sync 0x02
104#define e_seek 0x03
105#define e_parity 0x04
106#define e_focus 0x05
107#define e_header_sync 0x06
108#define e_code_incompatibility 0x07
109#define e_reset_done 0x08
110#define e_bad_parameter 0x09
111#define e_radial 0x0a
112#define e_sub_code 0x0b
113#define e_no_data_track 0x0c
114#define e_scan 0x0d
115#define e_tray_open 0x0f
116#define e_no_disc 0x10
117#define e_tray stalled 0x11
118
119/* drive configuration masks */
120
121#define dcf_revision_code 0x7
122#define dcf_transfer_rate 0x60
123#define dcf_motorized_tray 0x80
124
125/* disc status byte */
126
127#define cds_multi_session 0x2
128#define cds_all_audio 0x8
129#define cds_xa_mode 0xf0
130
131/* finally some ioctls for the driver */
132
133#define CM206CTL_GET_STAT _IO( 0x20, 0 )
134#define CM206CTL_GET_LAST_STAT _IO( 0x20, 1 )
135
136#ifdef STATISTICS
137
138/* This is an ugly way to guarantee that the names of the statistics
139 * are the same in the code and in the diagnostics program. */
140
141#ifdef __KERNEL__
142#define x(a) st_ ## a
143#define y enum
144#else
145#define x(a) #a
146#define y char * stats_name[] =
147#endif
148
149y {x(interrupt), x(data_ready), x(fifo_overflow), x(data_error),
150 x(crc_error), x(sync_error), x(lost_intr), x(echo),
151 x(write_timeout), x(receive_timeout), x(read_timeout),
152 x(dsb_timeout), x(stop_0xff), x(back_read_timeout),
153 x(sector_transferred), x(read_restarted), x(read_background),
154 x(bh), x(open), x(ioctl_multisession), x(attention)
155#ifdef __KERNEL__
156 , x(last_entry)
157#endif
158 };
159
160#ifdef __KERNEL__
161#define NR_STATS st_last_entry
162#else
163#define NR_STATS (sizeof(stats_name)/sizeof(char*))
164#endif
165
166#undef y
167#undef x
168
169#endif /* STATISTICS */
170
171#endif /* LINUX_CM206_H */
diff --git a/drivers/cdrom/gscd.c b/drivers/cdrom/gscd.c
deleted file mode 100644
index 176742ed007b..000000000000
--- a/drivers/cdrom/gscd.c
+++ /dev/null
@@ -1,1029 +0,0 @@
1#define GSCD_VERSION "0.4a Oliver Raupach <raupach@nwfs1.rz.fh-hannover.de>"
2
3/*
4 linux/drivers/block/gscd.c - GoldStar R420 CDROM driver
5
6 Copyright (C) 1995 Oliver Raupach <raupach@nwfs1.rz.fh-hannover.de>
7 based upon pre-works by Eberhard Moenkeberg <emoenke@gwdg.de>
8
9
10 For all kind of other information about the GoldStar CDROM
11 and this Linux device driver I installed a WWW-URL:
12 http://linux.rz.fh-hannover.de/~raupach
13
14
15 If you are the editor of a Linux CD, you should
16 enable gscd.c within your boot floppy kernel and
17 send me one of your CDs for free.
18
19
20 --------------------------------------------------------------------
21 This program is free software; you can redistribute it and/or modify
22 it under the terms of the GNU General Public License as published by
23 the Free Software Foundation; either version 2, or (at your option)
24 any later version.
25
26 This program is distributed in the hope that it will be useful,
27 but WITHOUT ANY WARRANTY; without even the implied warranty of
28 MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
29 GNU General Public License for more details.
30
31 You should have received a copy of the GNU General Public License
32 along with this program; if not, write to the Free Software
33 Foundation, Inc., 675 Mass Ave, Cambridge, MA 02139, USA.
34
35 --------------------------------------------------------------------
36
37 9 November 1999 -- Make kernel-parameter implementation work with 2.3.x
38 Removed init_module & cleanup_module in favor of
39 module_init & module_exit.
40 Torben Mathiasen <tmm@image.dk>
41
42*/
43
44/* These settings are for various debug-level. Leave they untouched ... */
45#define NO_GSCD_DEBUG
46#define NO_IOCTL_DEBUG
47#define NO_MODULE_DEBUG
48#define NO_FUTURE_WORK
49/*------------------------*/
50
51#include <linux/module.h>
52
53#include <linux/slab.h>
54#include <linux/errno.h>
55#include <linux/signal.h>
56#include <linux/timer.h>
57#include <linux/fs.h>
58#include <linux/mm.h>
59#include <linux/kernel.h>
60#include <linux/cdrom.h>
61#include <linux/ioport.h>
62#include <linux/major.h>
63#include <linux/string.h>
64#include <linux/init.h>
65
66#include <asm/system.h>
67#include <asm/io.h>
68#include <asm/uaccess.h>
69
70#define MAJOR_NR GOLDSTAR_CDROM_MAJOR
71#include <linux/blkdev.h>
72#include "gscd.h"
73
74static int gscdPresent = 0;
75
76static unsigned char gscd_buf[2048]; /* buffer for block size conversion */
77static int gscd_bn = -1;
78static short gscd_port = GSCD_BASE_ADDR;
79module_param_named(gscd, gscd_port, short, 0);
80
81/* Kommt spaeter vielleicht noch mal dran ...
82 * static DECLARE_WAIT_QUEUE_HEAD(gscd_waitq);
83 */
84
85static void gscd_read_cmd(struct request *req);
86static void gscd_hsg2msf(long hsg, struct msf *msf);
87static void gscd_bin2bcd(unsigned char *p);
88
89/* Schnittstellen zum Kern/FS */
90
91static void __do_gscd_request(unsigned long dummy);
92static int gscd_ioctl(struct inode *, struct file *, unsigned int,
93 unsigned long);
94static int gscd_open(struct inode *, struct file *);
95static int gscd_release(struct inode *, struct file *);
96static int check_gscd_med_chg(struct gendisk *disk);
97
98/* GoldStar Funktionen */
99
100static void cmd_out(int, char *, char *, int);
101static void cmd_status(void);
102static void init_cd_drive(int);
103
104static int get_status(void);
105static void clear_Audio(void);
106static void cc_invalidate(void);
107
108/* some things for the next version */
109#ifdef FUTURE_WORK
110static void update_state(void);
111static long gscd_msf2hsg(struct msf *mp);
112static int gscd_bcd2bin(unsigned char bcd);
113#endif
114
115
116/* lo-level cmd-Funktionen */
117
118static void cmd_info_in(char *, int);
119static void cmd_end(void);
120static void cmd_read_b(char *, int, int);
121static void cmd_read_w(char *, int, int);
122static int cmd_unit_alive(void);
123static void cmd_write_cmd(char *);
124
125
126/* GoldStar Variablen */
127
128static int curr_drv_state;
129static int drv_states[] = { 0, 0, 0, 0, 0, 0, 0, 0 };
130static int drv_mode;
131static int disk_state;
132static int speed;
133static int ndrives;
134
135static unsigned char drv_num_read;
136static unsigned char f_dsk_valid;
137static unsigned char current_drive;
138static unsigned char f_drv_ok;
139
140
141static char f_AudioPlay;
142static char f_AudioPause;
143static int AudioStart_m;
144static int AudioStart_f;
145static int AudioEnd_m;
146static int AudioEnd_f;
147
148static DEFINE_TIMER(gscd_timer, NULL, 0, 0);
149static DEFINE_SPINLOCK(gscd_lock);
150static struct request_queue *gscd_queue;
151
152static struct block_device_operations gscd_fops = {
153 .owner = THIS_MODULE,
154 .open = gscd_open,
155 .release = gscd_release,
156 .ioctl = gscd_ioctl,
157 .media_changed = check_gscd_med_chg,
158};
159
160/*
161 * Checking if the media has been changed
162 * (not yet implemented)
163 */
164static int check_gscd_med_chg(struct gendisk *disk)
165{
166#ifdef GSCD_DEBUG
167 printk("gscd: check_med_change\n");
168#endif
169 return 0;
170}
171
172
173#ifndef MODULE
174/* Using new interface for kernel-parameters */
175
176static int __init gscd_setup(char *str)
177{
178 int ints[2];
179 (void) get_options(str, ARRAY_SIZE(ints), ints);
180
181 if (ints[0] > 0) {
182 gscd_port = ints[1];
183 }
184 return 1;
185}
186
187__setup("gscd=", gscd_setup);
188
189#endif
190
191static int gscd_ioctl(struct inode *ip, struct file *fp, unsigned int cmd,
192 unsigned long arg)
193{
194 unsigned char to_do[10];
195 unsigned char dummy;
196
197
198 switch (cmd) {
199 case CDROMSTART: /* Spin up the drive */
200 /* Don't think we can do this. Even if we could,
201 * I think the drive times out and stops after a while
202 * anyway. For now, ignore it.
203 */
204 return 0;
205
206 case CDROMRESUME: /* keine Ahnung was das ist */
207 return 0;
208
209
210 case CDROMEJECT:
211 cmd_status();
212 to_do[0] = CMD_TRAY_CTL;
213 cmd_out(TYPE_INFO, (char *) &to_do, (char *) &dummy, 0);
214
215 return 0;
216
217 default:
218 return -EINVAL;
219 }
220
221}
222
223
224/*
225 * Take care of the different block sizes between cdrom and Linux.
226 * When Linux gets variable block sizes this will probably go away.
227 */
228
229static void gscd_transfer(struct request *req)
230{
231 while (req->nr_sectors > 0 && gscd_bn == req->sector / 4) {
232 long offs = (req->sector & 3) * 512;
233 memcpy(req->buffer, gscd_buf + offs, 512);
234 req->nr_sectors--;
235 req->sector++;
236 req->buffer += 512;
237 }
238}
239
240
241/*
242 * I/O request routine called from Linux kernel.
243 */
244
245static void do_gscd_request(request_queue_t * q)
246{
247 __do_gscd_request(0);
248}
249
250static void __do_gscd_request(unsigned long dummy)
251{
252 struct request *req;
253 unsigned int block;
254 unsigned int nsect;
255
256repeat:
257 req = elv_next_request(gscd_queue);
258 if (!req)
259 return;
260
261 block = req->sector;
262 nsect = req->nr_sectors;
263
264 if (req->sector == -1)
265 goto out;
266
267 if (rq_data_dir(req) != READ) {
268 printk("GSCD: bad cmd %u\n", rq_data_dir(req));
269 end_request(req, 0);
270 goto repeat;
271 }
272
273 gscd_transfer(req);
274
275 /* if we satisfied the request from the buffer, we're done. */
276
277 if (req->nr_sectors == 0) {
278 end_request(req, 1);
279 goto repeat;
280 }
281#ifdef GSCD_DEBUG
282 printk("GSCD: block %d, nsect %d\n", block, nsect);
283#endif
284 gscd_read_cmd(req);
285out:
286 return;
287}
288
289
290
291/*
292 * Check the result of the set-mode command. On success, send the
293 * read-data command.
294 */
295
296static void gscd_read_cmd(struct request *req)
297{
298 long block;
299 struct gscd_Play_msf gscdcmd;
300 char cmd[] = { CMD_READ, 0x80, 0, 0, 0, 0, 1 }; /* cmd mode M-S-F secth sectl */
301
302 cmd_status();
303 if (disk_state & (ST_NO_DISK | ST_DOOR_OPEN)) {
304 printk("GSCD: no disk or door open\n");
305 end_request(req, 0);
306 } else {
307 if (disk_state & ST_INVALID) {
308 printk("GSCD: disk invalid\n");
309 end_request(req, 0);
310 } else {
311 gscd_bn = -1; /* purge our buffer */
312 block = req->sector / 4;
313 gscd_hsg2msf(block, &gscdcmd.start); /* cvt to msf format */
314
315 cmd[2] = gscdcmd.start.min;
316 cmd[3] = gscdcmd.start.sec;
317 cmd[4] = gscdcmd.start.frame;
318
319#ifdef GSCD_DEBUG
320 printk("GSCD: read msf %d:%d:%d\n", cmd[2], cmd[3],
321 cmd[4]);
322#endif
323 cmd_out(TYPE_DATA, (char *) &cmd,
324 (char *) &gscd_buf[0], 1);
325
326 gscd_bn = req->sector / 4;
327 gscd_transfer(req);
328 end_request(req, 1);
329 }
330 }
331 SET_TIMER(__do_gscd_request, 1);
332}
333
334
335/*
336 * Open the device special file. Check that a disk is in.
337 */
338
339static int gscd_open(struct inode *ip, struct file *fp)
340{
341 int st;
342
343#ifdef GSCD_DEBUG
344 printk("GSCD: open\n");
345#endif
346
347 if (gscdPresent == 0)
348 return -ENXIO; /* no hardware */
349
350 get_status();
351 st = disk_state & (ST_NO_DISK | ST_DOOR_OPEN);
352 if (st) {
353 printk("GSCD: no disk or door open\n");
354 return -ENXIO;
355 }
356
357/* if (updateToc() < 0)
358 return -EIO;
359*/
360
361 return 0;
362}
363
364
365/*
366 * On close, we flush all gscd blocks from the buffer cache.
367 */
368
369static int gscd_release(struct inode *inode, struct file *file)
370{
371
372#ifdef GSCD_DEBUG
373 printk("GSCD: release\n");
374#endif
375
376 gscd_bn = -1;
377
378 return 0;
379}
380
381
382static int get_status(void)
383{
384 int status;
385
386 cmd_status();
387 status = disk_state & (ST_x08 | ST_x04 | ST_INVALID | ST_x01);
388
389 if (status == (ST_x08 | ST_x04 | ST_INVALID | ST_x01)) {
390 cc_invalidate();
391 return 1;
392 } else {
393 return 0;
394 }
395}
396
397
398static void cc_invalidate(void)
399{
400 drv_num_read = 0xFF;
401 f_dsk_valid = 0xFF;
402 current_drive = 0xFF;
403 f_drv_ok = 0xFF;
404
405 clear_Audio();
406
407}
408
409static void clear_Audio(void)
410{
411
412 f_AudioPlay = 0;
413 f_AudioPause = 0;
414 AudioStart_m = 0;
415 AudioStart_f = 0;
416 AudioEnd_m = 0;
417 AudioEnd_f = 0;
418
419}
420
421/*
422 * waiting ?
423 */
424
425static int wait_drv_ready(void)
426{
427 int found, read;
428
429 do {
430 found = inb(GSCDPORT(0));
431 found &= 0x0f;
432 read = inb(GSCDPORT(0));
433 read &= 0x0f;
434 } while (read != found);
435
436#ifdef GSCD_DEBUG
437 printk("Wait for: %d\n", read);
438#endif
439
440 return read;
441}
442
443static void cc_Ident(char *respons)
444{
445 char to_do[] = { CMD_IDENT, 0, 0 };
446
447 cmd_out(TYPE_INFO, (char *) &to_do, (char *) respons, (int) 0x1E);
448
449}
450
451static void cc_SetSpeed(void)
452{
453 char to_do[] = { CMD_SETSPEED, 0, 0 };
454 char dummy;
455
456 if (speed > 0) {
457 to_do[1] = speed & 0x0F;
458 cmd_out(TYPE_INFO, (char *) &to_do, (char *) &dummy, 0);
459 }
460}
461
462static void cc_Reset(void)
463{
464 char to_do[] = { CMD_RESET, 0 };
465 char dummy;
466
467 cmd_out(TYPE_INFO, (char *) &to_do, (char *) &dummy, 0);
468}
469
470static void cmd_status(void)
471{
472 char to_do[] = { CMD_STATUS, 0 };
473 char dummy;
474
475 cmd_out(TYPE_INFO, (char *) &to_do, (char *) &dummy, 0);
476
477#ifdef GSCD_DEBUG
478 printk("GSCD: Status: %d\n", disk_state);
479#endif
480
481}
482
483static void cmd_out(int cmd_type, char *cmd, char *respo_buf, int respo_count)
484{
485 int result;
486
487
488 result = wait_drv_ready();
489 if (result != drv_mode) {
490 unsigned long test_loops = 0xFFFF;
491 int i, dummy;
492
493 outb(curr_drv_state, GSCDPORT(0));
494
495 /* LOCLOOP_170 */
496 do {
497 result = wait_drv_ready();
498 test_loops--;
499 } while ((result != drv_mode) && (test_loops > 0));
500
501 if (result != drv_mode) {
502 disk_state = ST_x08 | ST_x04 | ST_INVALID;
503 return;
504 }
505
506 /* ...and waiting */
507 for (i = 1, dummy = 1; i < 0xFFFF; i++) {
508 dummy *= i;
509 }
510 }
511
512 /* LOC_172 */
513 /* check the unit */
514 /* and wake it up */
515 if (cmd_unit_alive() != 0x08) {
516 /* LOC_174 */
517 /* game over for this unit */
518 disk_state = ST_x08 | ST_x04 | ST_INVALID;
519 return;
520 }
521
522 /* LOC_176 */
523#ifdef GSCD_DEBUG
524 printk("LOC_176 ");
525#endif
526 if (drv_mode == 0x09) {
527 /* magic... */
528 printk("GSCD: magic ...\n");
529 outb(result, GSCDPORT(2));
530 }
531
532 /* write the command to the drive */
533 cmd_write_cmd(cmd);
534
535 /* LOC_178 */
536 for (;;) {
537 result = wait_drv_ready();
538 if (result != drv_mode) {
539 /* LOC_179 */
540 if (result == 0x04) { /* Mode 4 */
541 /* LOC_205 */
542#ifdef GSCD_DEBUG
543 printk("LOC_205 ");
544#endif
545 disk_state = inb(GSCDPORT(2));
546
547 do {
548 result = wait_drv_ready();
549 } while (result != drv_mode);
550 return;
551
552 } else {
553 if (result == 0x06) { /* Mode 6 */
554 /* LOC_181 */
555#ifdef GSCD_DEBUG
556 printk("LOC_181 ");
557#endif
558
559 if (cmd_type == TYPE_DATA) {
560 /* read data */
561 /* LOC_184 */
562 if (drv_mode == 9) {
563 /* read the data to the buffer (word) */
564
565 /* (*(cmd+1))?(CD_FRAMESIZE/2):(CD_FRAMESIZE_RAW/2) */
566 cmd_read_w
567 (respo_buf,
568 respo_count,
569 CD_FRAMESIZE /
570 2);
571 return;
572 } else {
573 /* read the data to the buffer (byte) */
574
575 /* (*(cmd+1))?(CD_FRAMESIZE):(CD_FRAMESIZE_RAW) */
576 cmd_read_b
577 (respo_buf,
578 respo_count,
579 CD_FRAMESIZE);
580 return;
581 }
582 } else {
583 /* read the info to the buffer */
584 cmd_info_in(respo_buf,
585 respo_count);
586 return;
587 }
588
589 return;
590 }
591 }
592
593 } else {
594 disk_state = ST_x08 | ST_x04 | ST_INVALID;
595 return;
596 }
597 } /* for (;;) */
598
599
600#ifdef GSCD_DEBUG
601 printk("\n");
602#endif
603}
604
605
606static void cmd_write_cmd(char *pstr)
607{
608 int i, j;
609
610 /* LOC_177 */
611#ifdef GSCD_DEBUG
612 printk("LOC_177 ");
613#endif
614
615 /* calculate the number of parameter */
616 j = *pstr & 0x0F;
617
618 /* shift it out */
619 for (i = 0; i < j; i++) {
620 outb(*pstr, GSCDPORT(2));
621 pstr++;
622 }
623}
624
625
626static int cmd_unit_alive(void)
627{
628 int result;
629 unsigned long max_test_loops;
630
631
632 /* LOC_172 */
633#ifdef GSCD_DEBUG
634 printk("LOC_172 ");
635#endif
636
637 outb(curr_drv_state, GSCDPORT(0));
638 max_test_loops = 0xFFFF;
639
640 do {
641 result = wait_drv_ready();
642 max_test_loops--;
643 } while ((result != 0x08) && (max_test_loops > 0));
644
645 return result;
646}
647
648
649static void cmd_info_in(char *pb, int count)
650{
651 int result;
652 char read;
653
654
655 /* read info */
656 /* LOC_182 */
657#ifdef GSCD_DEBUG
658 printk("LOC_182 ");
659#endif
660
661 do {
662 read = inb(GSCDPORT(2));
663 if (count > 0) {
664 *pb = read;
665 pb++;
666 count--;
667 }
668
669 /* LOC_183 */
670 do {
671 result = wait_drv_ready();
672 } while (result == 0x0E);
673 } while (result == 6);
674
675 cmd_end();
676 return;
677}
678
679
680static void cmd_read_b(char *pb, int count, int size)
681{
682 int result;
683 int i;
684
685
686 /* LOC_188 */
687 /* LOC_189 */
688#ifdef GSCD_DEBUG
689 printk("LOC_189 ");
690#endif
691
692 do {
693 do {
694 result = wait_drv_ready();
695 } while (result != 6 || result == 0x0E);
696
697 if (result != 6) {
698 cmd_end();
699 return;
700 }
701#ifdef GSCD_DEBUG
702 printk("LOC_191 ");
703#endif
704
705 for (i = 0; i < size; i++) {
706 *pb = inb(GSCDPORT(2));
707 pb++;
708 }
709 count--;
710 } while (count > 0);
711
712 cmd_end();
713 return;
714}
715
716
717static void cmd_end(void)
718{
719 int result;
720
721
722 /* LOC_204 */
723#ifdef GSCD_DEBUG
724 printk("LOC_204 ");
725#endif
726
727 do {
728 result = wait_drv_ready();
729 if (result == drv_mode) {
730 return;
731 }
732 } while (result != 4);
733
734 /* LOC_205 */
735#ifdef GSCD_DEBUG
736 printk("LOC_205 ");
737#endif
738
739 disk_state = inb(GSCDPORT(2));
740
741 do {
742 result = wait_drv_ready();
743 } while (result != drv_mode);
744 return;
745
746}
747
748
749static void cmd_read_w(char *pb, int count, int size)
750{
751 int result;
752 int i;
753
754
755#ifdef GSCD_DEBUG
756 printk("LOC_185 ");
757#endif
758
759 do {
760 /* LOC_185 */
761 do {
762 result = wait_drv_ready();
763 } while (result != 6 || result == 0x0E);
764
765 if (result != 6) {
766 cmd_end();
767 return;
768 }
769
770 for (i = 0; i < size; i++) {
771 /* na, hier muss ich noch mal drueber nachdenken */
772 *pb = inw(GSCDPORT(2));
773 pb++;
774 }
775 count--;
776 } while (count > 0);
777
778 cmd_end();
779 return;
780}
781
782static int __init find_drives(void)
783{
784 int *pdrv;
785 int drvnum;
786 int subdrv;
787 int i;
788
789 speed = 0;
790 pdrv = (int *) &drv_states;
791 curr_drv_state = 0xFE;
792 subdrv = 0;
793 drvnum = 0;
794
795 for (i = 0; i < 8; i++) {
796 subdrv++;
797 cmd_status();
798 disk_state &= ST_x08 | ST_x04 | ST_INVALID | ST_x01;
799 if (disk_state != (ST_x08 | ST_x04 | ST_INVALID)) {
800 /* LOC_240 */
801 *pdrv = curr_drv_state;
802 init_cd_drive(drvnum);
803 pdrv++;
804 drvnum++;
805 } else {
806 if (subdrv < 2) {
807 continue;
808 } else {
809 subdrv = 0;
810 }
811 }
812
813/* curr_drv_state<<1; <-- das geht irgendwie nicht */
814/* muss heissen: curr_drv_state <<= 1; (ist ja Wert-Zuweisung) */
815 curr_drv_state *= 2;
816 curr_drv_state |= 1;
817#ifdef GSCD_DEBUG
818 printk("DriveState: %d\n", curr_drv_state);
819#endif
820 }
821
822 ndrives = drvnum;
823 return drvnum;
824}
825
826static void __init init_cd_drive(int num)
827{
828 char resp[50];
829 int i;
830
831 printk("GSCD: init unit %d\n", num);
832 cc_Ident((char *) &resp);
833
834 printk("GSCD: identification: ");
835 for (i = 0; i < 0x1E; i++) {
836 printk("%c", resp[i]);
837 }
838 printk("\n");
839
840 cc_SetSpeed();
841
842}
843
844#ifdef FUTURE_WORK
845/* return_done */
846static void update_state(void)
847{
848 unsigned int AX;
849
850
851 if ((disk_state & (ST_x08 | ST_x04 | ST_INVALID | ST_x01)) == 0) {
852 if (disk_state == (ST_x08 | ST_x04 | ST_INVALID)) {
853 AX = ST_INVALID;
854 }
855
856 if ((disk_state & (ST_x08 | ST_x04 | ST_INVALID | ST_x01))
857 == 0) {
858 invalidate();
859 f_drv_ok = 0;
860 }
861
862 AX |= 0x8000;
863 }
864
865 if (disk_state & ST_PLAYING) {
866 AX |= 0x200;
867 }
868
869 AX |= 0x100;
870 /* pkt_esbx = AX; */
871
872 disk_state = 0;
873
874}
875#endif
876
877static struct gendisk *gscd_disk;
878
879static void __exit gscd_exit(void)
880{
881 CLEAR_TIMER;
882
883 del_gendisk(gscd_disk);
884 put_disk(gscd_disk);
885 if ((unregister_blkdev(MAJOR_NR, "gscd") == -EINVAL)) {
886 printk("What's that: can't unregister GoldStar-module\n");
887 return;
888 }
889 blk_cleanup_queue(gscd_queue);
890 release_region(gscd_port, GSCD_IO_EXTENT);
891 printk(KERN_INFO "GoldStar-module released.\n");
892}
893
894/* This is the common initialisation for the GoldStar drive. */
895/* It is called at boot time AND for module init. */
896static int __init gscd_init(void)
897{
898 int i;
899 int result;
900 int ret=0;
901
902 printk(KERN_INFO "GSCD: version %s\n", GSCD_VERSION);
903 printk(KERN_INFO
904 "GSCD: Trying to detect a Goldstar R420 CD-ROM drive at 0x%X.\n",
905 gscd_port);
906
907 if (!request_region(gscd_port, GSCD_IO_EXTENT, "gscd")) {
908 printk(KERN_WARNING "GSCD: Init failed, I/O port (%X) already"
909 " in use.\n", gscd_port);
910 return -EIO;
911 }
912
913
914 /* check for card */
915 result = wait_drv_ready();
916 if (result == 0x09) {
917 printk(KERN_WARNING "GSCD: DMA kann ich noch nicht!\n");
918 ret = -EIO;
919 goto err_out1;
920 }
921
922 if (result == 0x0b) {
923 drv_mode = result;
924 i = find_drives();
925 if (i == 0) {
926 printk(KERN_WARNING "GSCD: GoldStar CD-ROM Drive is"
927 " not found.\n");
928 ret = -EIO;
929 goto err_out1;
930 }
931 }
932
933 if ((result != 0x0b) && (result != 0x09)) {
934 printk(KERN_WARNING "GSCD: GoldStar Interface Adapter does not "
935 "exist or H/W error\n");
936 ret = -EIO;
937 goto err_out1;
938 }
939
940 /* reset all drives */
941 i = 0;
942 while (drv_states[i] != 0) {
943 curr_drv_state = drv_states[i];
944 printk(KERN_INFO "GSCD: Reset unit %d ... ", i);
945 cc_Reset();
946 printk("done\n");
947 i++;
948 }
949
950 gscd_disk = alloc_disk(1);
951 if (!gscd_disk)
952 goto err_out1;
953 gscd_disk->major = MAJOR_NR;
954 gscd_disk->first_minor = 0;
955 gscd_disk->fops = &gscd_fops;
956 sprintf(gscd_disk->disk_name, "gscd");
957
958 if (register_blkdev(MAJOR_NR, "gscd")) {
959 ret = -EIO;
960 goto err_out2;
961 }
962
963 gscd_queue = blk_init_queue(do_gscd_request, &gscd_lock);
964 if (!gscd_queue) {
965 ret = -ENOMEM;
966 goto err_out3;
967 }
968
969 disk_state = 0;
970 gscdPresent = 1;
971
972 gscd_disk->queue = gscd_queue;
973 add_disk(gscd_disk);
974
975 printk(KERN_INFO "GSCD: GoldStar CD-ROM Drive found.\n");
976 return 0;
977
978err_out3:
979 unregister_blkdev(MAJOR_NR, "gscd");
980err_out2:
981 put_disk(gscd_disk);
982err_out1:
983 release_region(gscd_port, GSCD_IO_EXTENT);
984 return ret;
985}
986
987static void gscd_hsg2msf(long hsg, struct msf *msf)
988{
989 hsg += CD_MSF_OFFSET;
990 msf->min = hsg / (CD_FRAMES * CD_SECS);
991 hsg %= CD_FRAMES * CD_SECS;
992 msf->sec = hsg / CD_FRAMES;
993 msf->frame = hsg % CD_FRAMES;
994
995 gscd_bin2bcd(&msf->min); /* convert to BCD */
996 gscd_bin2bcd(&msf->sec);
997 gscd_bin2bcd(&msf->frame);
998}
999
1000
1001static void gscd_bin2bcd(unsigned char *p)
1002{
1003 int u, t;
1004
1005 u = *p % 10;
1006 t = *p / 10;
1007 *p = u | (t << 4);
1008}
1009
1010
1011#ifdef FUTURE_WORK
1012static long gscd_msf2hsg(struct msf *mp)
1013{
1014 return gscd_bcd2bin(mp->frame)
1015 + gscd_bcd2bin(mp->sec) * CD_FRAMES
1016 + gscd_bcd2bin(mp->min) * CD_FRAMES * CD_SECS - CD_MSF_OFFSET;
1017}
1018
1019static int gscd_bcd2bin(unsigned char bcd)
1020{
1021 return (bcd >> 4) * 10 + (bcd & 0xF);
1022}
1023#endif
1024
1025MODULE_AUTHOR("Oliver Raupach <raupach@nwfs1.rz.fh-hannover.de>");
1026MODULE_LICENSE("GPL");
1027module_init(gscd_init);
1028module_exit(gscd_exit);
1029MODULE_ALIAS_BLOCKDEV_MAJOR(GOLDSTAR_CDROM_MAJOR);
diff --git a/drivers/cdrom/gscd.h b/drivers/cdrom/gscd.h
deleted file mode 100644
index a41e64bfc061..000000000000
--- a/drivers/cdrom/gscd.h
+++ /dev/null
@@ -1,108 +0,0 @@
1/*
2 * Definitions for a GoldStar R420 CD-ROM interface
3 *
4 * Copyright (C) 1995 Oliver Raupach <raupach@nwfs1.rz.fh-hannover.de>
5 * Eberhard Moenkeberg <emoenke@gwdg.de>
6 *
7 * Published under the GPL.
8 *
9 */
10
11
12/* The Interface Card default address is 0x340. This will work for most
13 applications. Address selection is accomplished by jumpers PN801-1 to
14 PN801-4 on the GoldStar Interface Card.
15 Appropriate settings are: 0x300, 0x310, 0x320, 0x330, 0x340, 0x350, 0x360
16 0x370, 0x380, 0x390, 0x3A0, 0x3B0, 0x3C0, 0x3D0, 0x3E0, 0x3F0 */
17
18/* insert here the I/O port address and extent */
19#define GSCD_BASE_ADDR 0x340
20#define GSCD_IO_EXTENT 4
21
22
23/************** nothing to set up below here *********************/
24
25/* port access macro */
26#define GSCDPORT(x) (gscd_port + (x))
27
28/*
29 * commands
30 * the lower nibble holds the command length
31 */
32#define CMD_STATUS 0x01
33#define CMD_READSUBQ 0x02 /* 1: ?, 2: UPC, 5: ? */
34#define CMD_SEEK 0x05 /* read_mode M-S-F */
35#define CMD_READ 0x07 /* read_mode M-S-F nsec_h nsec_l */
36#define CMD_RESET 0x11
37#define CMD_SETMODE 0x15
38#define CMD_PLAY 0x17 /* M-S-F M-S-F */
39#define CMD_LOCK_CTL 0x22 /* 0: unlock, 1: lock */
40#define CMD_IDENT 0x31
41#define CMD_SETSPEED 0x32 /* 0: auto */ /* ??? */
42#define CMD_GETMODE 0x41
43#define CMD_PAUSE 0x51
44#define CMD_READTOC 0x61
45#define CMD_DISKINFO 0x71
46#define CMD_TRAY_CTL 0x81
47
48/*
49 * disk_state:
50 */
51#define ST_PLAYING 0x80
52#define ST_UNLOCKED 0x40
53#define ST_NO_DISK 0x20
54#define ST_DOOR_OPEN 0x10
55#define ST_x08 0x08
56#define ST_x04 0x04
57#define ST_INVALID 0x02
58#define ST_x01 0x01
59
60/*
61 * cmd_type:
62 */
63#define TYPE_INFO 0x01
64#define TYPE_DATA 0x02
65
66/*
67 * read_mode:
68 */
69#define MOD_POLLED 0x80
70#define MOD_x08 0x08
71#define MOD_RAW 0x04
72
73#define READ_DATA(port, buf, nr) insb(port, buf, nr)
74
75#define SET_TIMER(func, jifs) \
76 ((mod_timer(&gscd_timer, jiffies + jifs)), \
77 (gscd_timer.function = func))
78
79#define CLEAR_TIMER del_timer_sync(&gscd_timer)
80
81#define MAX_TRACKS 104
82
83struct msf {
84 unsigned char min;
85 unsigned char sec;
86 unsigned char frame;
87};
88
89struct gscd_Play_msf {
90 struct msf start;
91 struct msf end;
92};
93
94struct gscd_DiskInfo {
95 unsigned char first;
96 unsigned char last;
97 struct msf diskLength;
98 struct msf firstTrack;
99};
100
101struct gscd_Toc {
102 unsigned char ctrl_addr;
103 unsigned char track;
104 unsigned char pointIndex;
105 struct msf trackTime;
106 struct msf diskTime;
107};
108
diff --git a/drivers/cdrom/isp16.c b/drivers/cdrom/isp16.c
deleted file mode 100644
index db0fd9a240e3..000000000000
--- a/drivers/cdrom/isp16.c
+++ /dev/null
@@ -1,374 +0,0 @@
1/* -- ISP16 cdrom detection and configuration
2 *
3 * Copyright (c) 1995,1996 Eric van der Maarel <H.T.M.v.d.Maarel@marin.nl>
4 *
5 * Version 0.6
6 *
7 * History:
8 * 0.5 First release.
9 * Was included in the sjcd and optcd cdrom drivers.
10 * 0.6 First "stand-alone" version.
11 * Removed sound configuration.
12 * Added "module" support.
13 *
14 * 9 November 1999 -- Make kernel-parameter implementation work with 2.3.x
15 * Removed init_module & cleanup_module in favor of
16 * module_init & module_exit.
17 * Torben Mathiasen <tmm@image.dk>
18 *
19 * 19 June 2004 -- check_region() converted to request_region()
20 * and return statement cleanups.
21 * - Jesper Juhl
22 *
23 * Detect cdrom interface on ISP16 sound card.
24 * Configure cdrom interface.
25 *
26 * Algorithm for the card with OPTi 82C928 taken
27 * from the CDSETUP.SYS driver for MSDOS,
28 * by OPTi Computers, version 2.03.
29 * Algorithm for the card with OPTi 82C929 as communicated
30 * to me by Vadim Model and Leo Spiekman.
31 *
32 * This program is free software; you can redistribute it and/or modify
33 * it under the terms of the GNU General Public License as published by
34 * the Free Software Foundation; either version 2 of the License, or
35 * (at your option) any later version.
36 *
37 * This program is distributed in the hope that it will be useful,
38 * but WITHOUT ANY WARRANTY; without even the implied warranty of
39 * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
40 * GNU General Public License for more details.
41 *
42 * You should have received a copy of the GNU General Public License
43 * along with this program; if not, write to the Free Software
44 * Foundation, Inc., 675 Mass Ave, Cambridge, MA 02139, USA.
45 *
46 */
47
48#define ISP16_VERSION_MAJOR 0
49#define ISP16_VERSION_MINOR 6
50
51#include <linux/module.h>
52
53#include <linux/fs.h>
54#include <linux/kernel.h>
55#include <linux/string.h>
56#include <linux/ioport.h>
57#include <linux/init.h>
58#include <asm/io.h>
59#include "isp16.h"
60
61static short isp16_detect(void);
62static short isp16_c928__detect(void);
63static short isp16_c929__detect(void);
64static short isp16_cdi_config(int base, u_char drive_type, int irq,
65 int dma);
66static short isp16_type; /* dependent on type of interface card */
67static u_char isp16_ctrl;
68static u_short isp16_enable_port;
69
70static int isp16_cdrom_base = ISP16_CDROM_IO_BASE;
71static int isp16_cdrom_irq = ISP16_CDROM_IRQ;
72static int isp16_cdrom_dma = ISP16_CDROM_DMA;
73static char *isp16_cdrom_type = ISP16_CDROM_TYPE;
74
75module_param(isp16_cdrom_base, int, 0);
76module_param(isp16_cdrom_irq, int, 0);
77module_param(isp16_cdrom_dma, int, 0);
78module_param(isp16_cdrom_type, charp, 0);
79
80#define ISP16_IN(p) (outb(isp16_ctrl,ISP16_CTRL_PORT), inb(p))
81#define ISP16_OUT(p,b) (outb(isp16_ctrl,ISP16_CTRL_PORT), outb(b,p))
82
83#ifndef MODULE
84
85static int
86__init isp16_setup(char *str)
87{
88 int ints[4];
89
90 (void) get_options(str, ARRAY_SIZE(ints), ints);
91 if (ints[0] > 0)
92 isp16_cdrom_base = ints[1];
93 if (ints[0] > 1)
94 isp16_cdrom_irq = ints[2];
95 if (ints[0] > 2)
96 isp16_cdrom_dma = ints[3];
97 if (str)
98 isp16_cdrom_type = str;
99
100 return 1;
101}
102
103__setup("isp16=", isp16_setup);
104
105#endif /* MODULE */
106
107/*
108 * ISP16 initialisation.
109 *
110 */
111static int __init isp16_init(void)
112{
113 u_char expected_drive;
114
115 printk(KERN_INFO
116 "ISP16: configuration cdrom interface, version %d.%d.\n",
117 ISP16_VERSION_MAJOR, ISP16_VERSION_MINOR);
118
119 if (!strcmp(isp16_cdrom_type, "noisp16")) {
120 printk("ISP16: no cdrom interface configured.\n");
121 return 0;
122 }
123
124 if (!request_region(ISP16_IO_BASE, ISP16_IO_SIZE, "isp16")) {
125 printk("ISP16: i/o ports already in use.\n");
126 goto out;
127 }
128
129 if ((isp16_type = isp16_detect()) < 0) {
130 printk("ISP16: no cdrom interface found.\n");
131 goto cleanup_out;
132 }
133
134 printk(KERN_INFO
135 "ISP16: cdrom interface (with OPTi 82C92%d chip) detected.\n",
136 (isp16_type == 2) ? 9 : 8);
137
138 if (!strcmp(isp16_cdrom_type, "Sanyo"))
139 expected_drive =
140 (isp16_type ? ISP16_SANYO1 : ISP16_SANYO0);
141 else if (!strcmp(isp16_cdrom_type, "Sony"))
142 expected_drive = ISP16_SONY;
143 else if (!strcmp(isp16_cdrom_type, "Panasonic"))
144 expected_drive =
145 (isp16_type ? ISP16_PANASONIC1 : ISP16_PANASONIC0);
146 else if (!strcmp(isp16_cdrom_type, "Mitsumi"))
147 expected_drive = ISP16_MITSUMI;
148 else {
149 printk("ISP16: %s not supported by cdrom interface.\n",
150 isp16_cdrom_type);
151 goto cleanup_out;
152 }
153
154 if (isp16_cdi_config(isp16_cdrom_base, expected_drive,
155 isp16_cdrom_irq, isp16_cdrom_dma) < 0) {
156 printk
157 ("ISP16: cdrom interface has not been properly configured.\n");
158 goto cleanup_out;
159 }
160 printk(KERN_INFO
161 "ISP16: cdrom interface set up with io base 0x%03X, irq %d, dma %d,"
162 " type %s.\n", isp16_cdrom_base, isp16_cdrom_irq,
163 isp16_cdrom_dma, isp16_cdrom_type);
164 return 0;
165
166cleanup_out:
167 release_region(ISP16_IO_BASE, ISP16_IO_SIZE);
168out:
169 return -EIO;
170}
171
172static short __init isp16_detect(void)
173{
174
175 if (isp16_c929__detect() >= 0)
176 return 2;
177 else
178 return (isp16_c928__detect());
179}
180
181static short __init isp16_c928__detect(void)
182{
183 u_char ctrl;
184 u_char enable_cdrom;
185 u_char io;
186 short i = -1;
187
188 isp16_ctrl = ISP16_C928__CTRL;
189 isp16_enable_port = ISP16_C928__ENABLE_PORT;
190
191 /* read' and write' are a special read and write, respectively */
192
193 /* read' ISP16_CTRL_PORT, clear last two bits and write' back the result */
194 ctrl = ISP16_IN(ISP16_CTRL_PORT) & 0xFC;
195 ISP16_OUT(ISP16_CTRL_PORT, ctrl);
196
197 /* read' 3,4 and 5-bit from the cdrom enable port */
198 enable_cdrom = ISP16_IN(ISP16_C928__ENABLE_PORT) & 0x38;
199
200 if (!(enable_cdrom & 0x20)) { /* 5-bit not set */
201 /* read' last 2 bits of ISP16_IO_SET_PORT */
202 io = ISP16_IN(ISP16_IO_SET_PORT) & 0x03;
203 if (((io & 0x01) << 1) == (io & 0x02)) { /* bits are the same */
204 if (io == 0) { /* ...the same and 0 */
205 i = 0;
206 enable_cdrom |= 0x20;
207 } else { /* ...the same and 1 *//* my card, first time 'round */
208 i = 1;
209 enable_cdrom |= 0x28;
210 }
211 ISP16_OUT(ISP16_C928__ENABLE_PORT, enable_cdrom);
212 } else { /* bits are not the same */
213 ISP16_OUT(ISP16_CTRL_PORT, ctrl);
214 return i; /* -> not detected: possibly incorrect conclusion */
215 }
216 } else if (enable_cdrom == 0x20)
217 i = 0;
218 else if (enable_cdrom == 0x28) /* my card, already initialised */
219 i = 1;
220
221 ISP16_OUT(ISP16_CTRL_PORT, ctrl);
222
223 return i;
224}
225
226static short __init isp16_c929__detect(void)
227{
228 u_char ctrl;
229 u_char tmp;
230
231 isp16_ctrl = ISP16_C929__CTRL;
232 isp16_enable_port = ISP16_C929__ENABLE_PORT;
233
234 /* read' and write' are a special read and write, respectively */
235
236 /* read' ISP16_CTRL_PORT and save */
237 ctrl = ISP16_IN(ISP16_CTRL_PORT);
238
239 /* write' zero to the ctrl port and get response */
240 ISP16_OUT(ISP16_CTRL_PORT, 0);
241 tmp = ISP16_IN(ISP16_CTRL_PORT);
242
243 if (tmp != 2) /* isp16 with 82C929 not detected */
244 return -1;
245
246 /* restore ctrl port value */
247 ISP16_OUT(ISP16_CTRL_PORT, ctrl);
248
249 return 2;
250}
251
252static short __init
253isp16_cdi_config(int base, u_char drive_type, int irq, int dma)
254{
255 u_char base_code;
256 u_char irq_code;
257 u_char dma_code;
258 u_char i;
259
260 if ((drive_type == ISP16_MITSUMI) && (dma != 0))
261 printk("ISP16: Mitsumi cdrom drive has no dma support.\n");
262
263 switch (base) {
264 case 0x340:
265 base_code = ISP16_BASE_340;
266 break;
267 case 0x330:
268 base_code = ISP16_BASE_330;
269 break;
270 case 0x360:
271 base_code = ISP16_BASE_360;
272 break;
273 case 0x320:
274 base_code = ISP16_BASE_320;
275 break;
276 default:
277 printk
278 ("ISP16: base address 0x%03X not supported by cdrom interface.\n",
279 base);
280 return -1;
281 }
282 switch (irq) {
283 case 0:
284 irq_code = ISP16_IRQ_X;
285 break; /* disable irq */
286 case 5:
287 irq_code = ISP16_IRQ_5;
288 printk("ISP16: irq 5 shouldn't be used by cdrom interface,"
289 " due to possible conflicts with the sound card.\n");
290 break;
291 case 7:
292 irq_code = ISP16_IRQ_7;
293 printk("ISP16: irq 7 shouldn't be used by cdrom interface,"
294 " due to possible conflicts with the sound card.\n");
295 break;
296 case 3:
297 irq_code = ISP16_IRQ_3;
298 break;
299 case 9:
300 irq_code = ISP16_IRQ_9;
301 break;
302 case 10:
303 irq_code = ISP16_IRQ_10;
304 break;
305 case 11:
306 irq_code = ISP16_IRQ_11;
307 break;
308 default:
309 printk("ISP16: irq %d not supported by cdrom interface.\n",
310 irq);
311 return -1;
312 }
313 switch (dma) {
314 case 0:
315 dma_code = ISP16_DMA_X;
316 break; /* disable dma */
317 case 1:
318 printk("ISP16: dma 1 cannot be used by cdrom interface,"
319 " due to conflict with the sound card.\n");
320 return -1;
321 break;
322 case 3:
323 dma_code = ISP16_DMA_3;
324 break;
325 case 5:
326 dma_code = ISP16_DMA_5;
327 break;
328 case 6:
329 dma_code = ISP16_DMA_6;
330 break;
331 case 7:
332 dma_code = ISP16_DMA_7;
333 break;
334 default:
335 printk("ISP16: dma %d not supported by cdrom interface.\n",
336 dma);
337 return -1;
338 }
339
340 if (drive_type != ISP16_SONY && drive_type != ISP16_PANASONIC0 &&
341 drive_type != ISP16_PANASONIC1 && drive_type != ISP16_SANYO0 &&
342 drive_type != ISP16_SANYO1 && drive_type != ISP16_MITSUMI &&
343 drive_type != ISP16_DRIVE_X) {
344 printk
345 ("ISP16: drive type (code 0x%02X) not supported by cdrom"
346 " interface.\n", drive_type);
347 return -1;
348 }
349
350 /* set type of interface */
351 i = ISP16_IN(ISP16_DRIVE_SET_PORT) & ISP16_DRIVE_SET_MASK; /* clear some bits */
352 ISP16_OUT(ISP16_DRIVE_SET_PORT, i | drive_type);
353
354 /* enable cdrom on interface with 82C929 chip */
355 if (isp16_type > 1)
356 ISP16_OUT(isp16_enable_port, ISP16_ENABLE_CDROM);
357
358 /* set base address, irq and dma */
359 i = ISP16_IN(ISP16_IO_SET_PORT) & ISP16_IO_SET_MASK; /* keep some bits */
360 ISP16_OUT(ISP16_IO_SET_PORT, i | base_code | irq_code | dma_code);
361
362 return 0;
363}
364
365static void __exit isp16_exit(void)
366{
367 release_region(ISP16_IO_BASE, ISP16_IO_SIZE);
368 printk(KERN_INFO "ISP16: module released.\n");
369}
370
371module_init(isp16_init);
372module_exit(isp16_exit);
373
374MODULE_LICENSE("GPL");
diff --git a/drivers/cdrom/isp16.h b/drivers/cdrom/isp16.h
deleted file mode 100644
index 5bd22c8f7a96..000000000000
--- a/drivers/cdrom/isp16.h
+++ /dev/null
@@ -1,72 +0,0 @@
1/* -- isp16.h
2 *
3 * Header for detection and initialisation of cdrom interface (only) on
4 * ISP16 (MAD16, Mozart) sound card.
5 *
6 * This program is free software; you can redistribute it and/or modify
7 * it under the terms of the GNU General Public License as published by
8 * the Free Software Foundation; either version 2 of the License, or
9 * (at your option) any later version.
10 *
11 * This program is distributed in the hope that it will be useful,
12 * but WITHOUT ANY WARRANTY; without even the implied warranty of
13 * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
14 * GNU General Public License for more details.
15 *
16 * You should have received a copy of the GNU General Public License
17 * along with this program; if not, write to the Free Software
18 * Foundation, Inc., 675 Mass Ave, Cambridge, MA 02139, USA.
19 *
20 */
21
22/* These are the default values */
23#define ISP16_CDROM_TYPE "Sanyo"
24#define ISP16_CDROM_IO_BASE 0x340
25#define ISP16_CDROM_IRQ 0
26#define ISP16_CDROM_DMA 0
27
28/* Some (Media)Magic */
29/* define types of drive the interface on an ISP16 card may be looking at */
30#define ISP16_DRIVE_X 0x00
31#define ISP16_SONY 0x02
32#define ISP16_PANASONIC0 0x02
33#define ISP16_SANYO0 0x02
34#define ISP16_MITSUMI 0x04
35#define ISP16_PANASONIC1 0x06
36#define ISP16_SANYO1 0x06
37#define ISP16_DRIVE_NOT_USED 0x08 /* not used */
38#define ISP16_DRIVE_SET_MASK 0xF1 /* don't change 0-bit or 4-7-bits*/
39/* ...for port */
40#define ISP16_DRIVE_SET_PORT 0xF8D
41/* set io parameters */
42#define ISP16_BASE_340 0x00
43#define ISP16_BASE_330 0x40
44#define ISP16_BASE_360 0x80
45#define ISP16_BASE_320 0xC0
46#define ISP16_IRQ_X 0x00
47#define ISP16_IRQ_5 0x04 /* shouldn't be used to avoid sound card conflicts */
48#define ISP16_IRQ_7 0x08 /* shouldn't be used to avoid sound card conflicts */
49#define ISP16_IRQ_3 0x0C
50#define ISP16_IRQ_9 0x10
51#define ISP16_IRQ_10 0x14
52#define ISP16_IRQ_11 0x18
53#define ISP16_DMA_X 0x03
54#define ISP16_DMA_3 0x00
55#define ISP16_DMA_5 0x00
56#define ISP16_DMA_6 0x01
57#define ISP16_DMA_7 0x02
58#define ISP16_IO_SET_MASK 0x20 /* don't change 5-bit */
59/* ...for port */
60#define ISP16_IO_SET_PORT 0xF8E
61/* enable the card */
62#define ISP16_C928__ENABLE_PORT 0xF90 /* ISP16 with OPTi 82C928 chip */
63#define ISP16_C929__ENABLE_PORT 0xF91 /* ISP16 with OPTi 82C929 chip */
64#define ISP16_ENABLE_CDROM 0x80 /* seven bit */
65
66/* the magic stuff */
67#define ISP16_CTRL_PORT 0xF8F
68#define ISP16_C928__CTRL 0xE2 /* ISP16 with OPTi 82C928 chip */
69#define ISP16_C929__CTRL 0xE3 /* ISP16 with OPTi 82C929 chip */
70
71#define ISP16_IO_BASE 0xF8D
72#define ISP16_IO_SIZE 5 /* ports used from 0xF8D up to 0xF91 */
diff --git a/drivers/cdrom/mcdx.c b/drivers/cdrom/mcdx.c
deleted file mode 100644
index 972ee9c8247c..000000000000
--- a/drivers/cdrom/mcdx.c
+++ /dev/null
@@ -1,1943 +0,0 @@
1/*
2 * The Mitsumi CDROM interface
3 * Copyright (C) 1995 1996 Heiko Schlittermann <heiko@lotte.sax.de>
4 * VERSION: 2.14(hs)
5 *
6 * ... anyway, I'm back again, thanks to Marcin, he adopted
7 * large portions of my code (at least the parts containing
8 * my main thoughts ...)
9 *
10 ****************** H E L P *********************************
11 * If you ever plan to update your CD ROM drive and perhaps
12 * want to sell or simply give away your Mitsumi FX-001[DS]
13 * -- Please --
14 * mail me (heiko@lotte.sax.de). When my last drive goes
15 * ballistic no more driver support will be available from me!
16 *************************************************************
17 *
18 * This program is free software; you can redistribute it and/or modify
19 * it under the terms of the GNU General Public License as published by
20 * the Free Software Foundation; either version 2, or (at your option)
21 * any later version.
22 *
23 * This program is distributed in the hope that it will be useful,
24 * but WITHOUT ANY WARRANTY; without even the implied warranty of
25 * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
26 * GNU General Public License for more details.
27 *
28 * You should have received a copy of the GNU General Public License
29 * along with this program; see the file COPYING. If not, write to
30 * the Free Software Foundation, 675 Mass Ave, Cambridge, MA 02139, USA.
31 *
32 * Thanks to
33 * The Linux Community at all and ...
34 * Martin Harriss (he wrote the first Mitsumi Driver)
35 * Eberhard Moenkeberg (he gave me much support and the initial kick)
36 * Bernd Huebner, Ruediger Helsch (Unifix-Software GmbH, they
37 * improved the original driver)
38 * Jon Tombs, Bjorn Ekwall (module support)
39 * Daniel v. Mosnenck (he sent me the Technical and Programming Reference)
40 * Gerd Knorr (he lent me his PhotoCD)
41 * Nils Faerber and Roger E. Wolff (extensively tested the LU portion)
42 * Andreas Kies (testing the mysterious hang-ups)
43 * Heiko Eissfeldt (VERIFY_READ/WRITE)
44 * Marcin Dalecki (improved performance, shortened code)
45 * ... somebody forgotten?
46 *
47 * 9 November 1999 -- Make kernel-parameter implementation work with 2.3.x
48 * Removed init_module & cleanup_module in favor of
49 * module_init & module_exit.
50 * Torben Mathiasen <tmm@image.dk>
51 */
52
53
54#ifdef RCS
55static const char *mcdx_c_version
56 = "$Id: mcdx.c,v 1.21 1997/01/26 07:12:59 davem Exp $";
57#endif
58
59#include <linux/module.h>
60
61#include <linux/errno.h>
62#include <linux/interrupt.h>
63#include <linux/fs.h>
64#include <linux/kernel.h>
65#include <linux/cdrom.h>
66#include <linux/ioport.h>
67#include <linux/mm.h>
68#include <linux/slab.h>
69#include <linux/init.h>
70#include <asm/io.h>
71#include <asm/current.h>
72#include <asm/uaccess.h>
73
74#include <linux/major.h>
75#define MAJOR_NR MITSUMI_X_CDROM_MAJOR
76#include <linux/blkdev.h>
77
78#include "mcdx.h"
79
80#ifndef HZ
81#error HZ not defined
82#endif
83
84#define xwarn(fmt, args...) printk(KERN_WARNING MCDX " " fmt, ## args)
85
86#if !MCDX_QUIET
87#define xinfo(fmt, args...) printk(KERN_INFO MCDX " " fmt, ## args)
88#else
89#define xinfo(fmt, args...) { ; }
90#endif
91
92#if MCDX_DEBUG
93#define xtrace(lvl, fmt, args...) \
94 { if (lvl > 0) \
95 { printk(KERN_DEBUG MCDX ":: " fmt, ## args); } }
96#define xdebug(fmt, args...) printk(KERN_DEBUG MCDX ":: " fmt, ## args)
97#else
98#define xtrace(lvl, fmt, args...) { ; }
99#define xdebug(fmt, args...) { ; }
100#endif
101
102/* CONSTANTS *******************************************************/
103
104/* Following are the number of sectors we _request_ from the drive
105 every time an access outside the already requested range is done.
106 The _direct_ size is the number of sectors we're allowed to skip
107 directly (performing a read instead of requesting the new sector
108 needed */
109static const int REQUEST_SIZE = 800; /* should be less then 255 * 4 */
110static const int DIRECT_SIZE = 400; /* should be less then REQUEST_SIZE */
111
112enum drivemodes { TOC, DATA, RAW, COOKED };
113enum datamodes { MODE0, MODE1, MODE2 };
114enum resetmodes { SOFT, HARD };
115
116static const int SINGLE = 0x01; /* single speed drive (FX001S, LU) */
117static const int DOUBLE = 0x02; /* double speed drive (FX001D, ..? */
118static const int DOOR = 0x04; /* door locking capability */
119static const int MULTI = 0x08; /* multi session capability */
120
121static const unsigned char READ1X = 0xc0;
122static const unsigned char READ2X = 0xc1;
123
124
125/* DECLARATIONS ****************************************************/
126struct s_subqcode {
127 unsigned char control;
128 unsigned char tno;
129 unsigned char index;
130 struct cdrom_msf0 tt;
131 struct cdrom_msf0 dt;
132};
133
134struct s_diskinfo {
135 unsigned int n_first;
136 unsigned int n_last;
137 struct cdrom_msf0 msf_leadout;
138 struct cdrom_msf0 msf_first;
139};
140
141struct s_multi {
142 unsigned char multi;
143 struct cdrom_msf0 msf_last;
144};
145
146struct s_version {
147 unsigned char code;
148 unsigned char ver;
149};
150
151/* Per drive/controller stuff **************************************/
152
153struct s_drive_stuff {
154 /* waitqueues */
155 wait_queue_head_t busyq;
156 wait_queue_head_t lockq;
157 wait_queue_head_t sleepq;
158
159 /* flags */
160 volatile int introk; /* status of last irq operation */
161 volatile int busy; /* drive performs an operation */
162 volatile int lock; /* exclusive usage */
163
164 /* cd infos */
165 struct s_diskinfo di;
166 struct s_multi multi;
167 struct s_subqcode *toc; /* first entry of the toc array */
168 struct s_subqcode start;
169 struct s_subqcode stop;
170 int xa; /* 1 if xa disk */
171 int audio; /* 1 if audio disk */
172 int audiostatus;
173
174 /* `buffer' control */
175 volatile int valid; /* pending, ..., values are valid */
176 volatile int pending; /* next sector to be read */
177 volatile int low_border; /* first sector not to be skipped direct */
178 volatile int high_border; /* first sector `out of area' */
179#ifdef AK2
180 volatile int int_err;
181#endif /* AK2 */
182
183 /* adds and odds */
184 unsigned wreg_data; /* w data */
185 unsigned wreg_reset; /* w hardware reset */
186 unsigned wreg_hcon; /* w hardware conf */
187 unsigned wreg_chn; /* w channel */
188 unsigned rreg_data; /* r data */
189 unsigned rreg_status; /* r status */
190
191 int irq; /* irq used by this drive */
192 int present; /* drive present and its capabilities */
193 unsigned char readcmd; /* read cmd depends on single/double speed */
194 unsigned char playcmd; /* play should always be single speed */
195 unsigned int xxx; /* set if changed, reset while open */
196 unsigned int yyy; /* set if changed, reset by media_changed */
197 int users; /* keeps track of open/close */
198 int lastsector; /* last block accessible */
199 int status; /* last operation's error / status */
200 int readerrs; /* # of blocks read w/o error */
201 struct cdrom_device_info info;
202 struct gendisk *disk;
203};
204
205
206/* Prototypes ******************************************************/
207
208/* The following prototypes are already declared elsewhere. They are
209 repeated here to show what's going on. And to sense, if they're
210 changed elsewhere. */
211
212static int mcdx_init(void);
213
214static int mcdx_block_open(struct inode *inode, struct file *file)
215{
216 struct s_drive_stuff *p = inode->i_bdev->bd_disk->private_data;
217 return cdrom_open(&p->info, inode, file);
218}
219
220static int mcdx_block_release(struct inode *inode, struct file *file)
221{
222 struct s_drive_stuff *p = inode->i_bdev->bd_disk->private_data;
223 return cdrom_release(&p->info, file);
224}
225
226static int mcdx_block_ioctl(struct inode *inode, struct file *file,
227 unsigned cmd, unsigned long arg)
228{
229 struct s_drive_stuff *p = inode->i_bdev->bd_disk->private_data;
230 return cdrom_ioctl(file, &p->info, inode, cmd, arg);
231}
232
233static int mcdx_block_media_changed(struct gendisk *disk)
234{
235 struct s_drive_stuff *p = disk->private_data;
236 return cdrom_media_changed(&p->info);
237}
238
239static struct block_device_operations mcdx_bdops =
240{
241 .owner = THIS_MODULE,
242 .open = mcdx_block_open,
243 .release = mcdx_block_release,
244 .ioctl = mcdx_block_ioctl,
245 .media_changed = mcdx_block_media_changed,
246};
247
248
249/* Indirect exported functions. These functions are exported by their
250 addresses, such as mcdx_open and mcdx_close in the
251 structure mcdx_dops. */
252
253/* exported by file_ops */
254static int mcdx_open(struct cdrom_device_info *cdi, int purpose);
255static void mcdx_close(struct cdrom_device_info *cdi);
256static int mcdx_media_changed(struct cdrom_device_info *cdi, int disc_nr);
257static int mcdx_tray_move(struct cdrom_device_info *cdi, int position);
258static int mcdx_lockdoor(struct cdrom_device_info *cdi, int lock);
259static int mcdx_audio_ioctl(struct cdrom_device_info *cdi,
260 unsigned int cmd, void *arg);
261
262/* misc internal support functions */
263static void log2msf(unsigned int, struct cdrom_msf0 *);
264static unsigned int msf2log(const struct cdrom_msf0 *);
265static unsigned int uint2bcd(unsigned int);
266static unsigned int bcd2uint(unsigned char);
267static unsigned port(int *);
268static int irq(int *);
269static void mcdx_delay(struct s_drive_stuff *, long jifs);
270static int mcdx_transfer(struct s_drive_stuff *, char *buf, int sector,
271 int nr_sectors);
272static int mcdx_xfer(struct s_drive_stuff *, char *buf, int sector,
273 int nr_sectors);
274
275static int mcdx_config(struct s_drive_stuff *, int);
276static int mcdx_requestversion(struct s_drive_stuff *, struct s_version *,
277 int);
278static int mcdx_stop(struct s_drive_stuff *, int);
279static int mcdx_hold(struct s_drive_stuff *, int);
280static int mcdx_reset(struct s_drive_stuff *, enum resetmodes, int);
281static int mcdx_setdrivemode(struct s_drive_stuff *, enum drivemodes, int);
282static int mcdx_setdatamode(struct s_drive_stuff *, enum datamodes, int);
283static int mcdx_requestsubqcode(struct s_drive_stuff *,
284 struct s_subqcode *, int);
285static int mcdx_requestmultidiskinfo(struct s_drive_stuff *,
286 struct s_multi *, int);
287static int mcdx_requesttocdata(struct s_drive_stuff *, struct s_diskinfo *,
288 int);
289static int mcdx_getstatus(struct s_drive_stuff *, int);
290static int mcdx_getval(struct s_drive_stuff *, int to, int delay, char *);
291static int mcdx_talk(struct s_drive_stuff *,
292 const unsigned char *cmd, size_t,
293 void *buffer, size_t size, unsigned int timeout, int);
294static int mcdx_readtoc(struct s_drive_stuff *);
295static int mcdx_playtrk(struct s_drive_stuff *, const struct cdrom_ti *);
296static int mcdx_playmsf(struct s_drive_stuff *, const struct cdrom_msf *);
297static int mcdx_setattentuator(struct s_drive_stuff *,
298 struct cdrom_volctrl *, int);
299
300/* static variables ************************************************/
301
302static int mcdx_drive_map[][2] = MCDX_DRIVEMAP;
303static struct s_drive_stuff *mcdx_stuffp[MCDX_NDRIVES];
304static DEFINE_SPINLOCK(mcdx_lock);
305static struct request_queue *mcdx_queue;
306
307/* You can only set the first two pairs, from old MODULE_PARM code. */
308static int mcdx_set(const char *val, struct kernel_param *kp)
309{
310 get_options((char *)val, 4, (int *)mcdx_drive_map);
311 return 0;
312}
313module_param_call(mcdx, mcdx_set, NULL, NULL, 0);
314
315static struct cdrom_device_ops mcdx_dops = {
316 .open = mcdx_open,
317 .release = mcdx_close,
318 .media_changed = mcdx_media_changed,
319 .tray_move = mcdx_tray_move,
320 .lock_door = mcdx_lockdoor,
321 .audio_ioctl = mcdx_audio_ioctl,
322 .capability = CDC_OPEN_TRAY | CDC_LOCK | CDC_MEDIA_CHANGED |
323 CDC_PLAY_AUDIO | CDC_DRIVE_STATUS,
324};
325
326/* KERNEL INTERFACE FUNCTIONS **************************************/
327
328
329static int mcdx_audio_ioctl(struct cdrom_device_info *cdi,
330 unsigned int cmd, void *arg)
331{
332 struct s_drive_stuff *stuffp = cdi->handle;
333
334 if (!stuffp->present)
335 return -ENXIO;
336
337 if (stuffp->xxx) {
338 if (-1 == mcdx_requesttocdata(stuffp, &stuffp->di, 1)) {
339 stuffp->lastsector = -1;
340 } else {
341 stuffp->lastsector = (CD_FRAMESIZE / 512)
342 * msf2log(&stuffp->di.msf_leadout) - 1;
343 }
344
345 if (stuffp->toc) {
346 kfree(stuffp->toc);
347 stuffp->toc = NULL;
348 if (-1 == mcdx_readtoc(stuffp))
349 return -1;
350 }
351
352 stuffp->xxx = 0;
353 }
354
355 switch (cmd) {
356 case CDROMSTART:{
357 xtrace(IOCTL, "ioctl() START\n");
358 /* Spin up the drive. Don't think we can do this.
359 * For now, ignore it.
360 */
361 return 0;
362 }
363
364 case CDROMSTOP:{
365 xtrace(IOCTL, "ioctl() STOP\n");
366 stuffp->audiostatus = CDROM_AUDIO_INVALID;
367 if (-1 == mcdx_stop(stuffp, 1))
368 return -EIO;
369 return 0;
370 }
371
372 case CDROMPLAYTRKIND:{
373 struct cdrom_ti *ti = (struct cdrom_ti *) arg;
374
375 xtrace(IOCTL, "ioctl() PLAYTRKIND\n");
376 if ((ti->cdti_trk0 < stuffp->di.n_first)
377 || (ti->cdti_trk0 > stuffp->di.n_last)
378 || (ti->cdti_trk1 < stuffp->di.n_first))
379 return -EINVAL;
380 if (ti->cdti_trk1 > stuffp->di.n_last)
381 ti->cdti_trk1 = stuffp->di.n_last;
382 xtrace(PLAYTRK, "ioctl() track %d to %d\n",
383 ti->cdti_trk0, ti->cdti_trk1);
384 return mcdx_playtrk(stuffp, ti);
385 }
386
387 case CDROMPLAYMSF:{
388 struct cdrom_msf *msf = (struct cdrom_msf *) arg;
389
390 xtrace(IOCTL, "ioctl() PLAYMSF\n");
391
392 if ((stuffp->audiostatus == CDROM_AUDIO_PLAY)
393 && (-1 == mcdx_hold(stuffp, 1)))
394 return -EIO;
395
396 msf->cdmsf_min0 = uint2bcd(msf->cdmsf_min0);
397 msf->cdmsf_sec0 = uint2bcd(msf->cdmsf_sec0);
398 msf->cdmsf_frame0 = uint2bcd(msf->cdmsf_frame0);
399
400 msf->cdmsf_min1 = uint2bcd(msf->cdmsf_min1);
401 msf->cdmsf_sec1 = uint2bcd(msf->cdmsf_sec1);
402 msf->cdmsf_frame1 = uint2bcd(msf->cdmsf_frame1);
403
404 stuffp->stop.dt.minute = msf->cdmsf_min1;
405 stuffp->stop.dt.second = msf->cdmsf_sec1;
406 stuffp->stop.dt.frame = msf->cdmsf_frame1;
407
408 return mcdx_playmsf(stuffp, msf);
409 }
410
411 case CDROMRESUME:{
412 xtrace(IOCTL, "ioctl() RESUME\n");
413 return mcdx_playtrk(stuffp, NULL);
414 }
415
416 case CDROMREADTOCENTRY:{
417 struct cdrom_tocentry *entry =
418 (struct cdrom_tocentry *) arg;
419 struct s_subqcode *tp = NULL;
420 xtrace(IOCTL, "ioctl() READTOCENTRY\n");
421
422 if (-1 == mcdx_readtoc(stuffp))
423 return -1;
424 if (entry->cdte_track == CDROM_LEADOUT)
425 tp = &stuffp->toc[stuffp->di.n_last -
426 stuffp->di.n_first + 1];
427 else if (entry->cdte_track > stuffp->di.n_last
428 || entry->cdte_track < stuffp->di.n_first)
429 return -EINVAL;
430 else
431 tp = &stuffp->toc[entry->cdte_track -
432 stuffp->di.n_first];
433
434 if (NULL == tp)
435 return -EIO;
436 entry->cdte_adr = tp->control;
437 entry->cdte_ctrl = tp->control >> 4;
438 /* Always return stuff in MSF, and let the Uniform cdrom driver
439 worry about what the user actually wants */
440 entry->cdte_addr.msf.minute =
441 bcd2uint(tp->dt.minute);
442 entry->cdte_addr.msf.second =
443 bcd2uint(tp->dt.second);
444 entry->cdte_addr.msf.frame =
445 bcd2uint(tp->dt.frame);
446 return 0;
447 }
448
449 case CDROMSUBCHNL:{
450 struct cdrom_subchnl *sub =
451 (struct cdrom_subchnl *) arg;
452 struct s_subqcode q;
453
454 xtrace(IOCTL, "ioctl() SUBCHNL\n");
455
456 if (-1 == mcdx_requestsubqcode(stuffp, &q, 2))
457 return -EIO;
458
459 xtrace(SUBCHNL, "audiostatus: %x\n",
460 stuffp->audiostatus);
461 sub->cdsc_audiostatus = stuffp->audiostatus;
462 sub->cdsc_adr = q.control;
463 sub->cdsc_ctrl = q.control >> 4;
464 sub->cdsc_trk = bcd2uint(q.tno);
465 sub->cdsc_ind = bcd2uint(q.index);
466
467 xtrace(SUBCHNL, "trk %d, ind %d\n",
468 sub->cdsc_trk, sub->cdsc_ind);
469 /* Always return stuff in MSF, and let the Uniform cdrom driver
470 worry about what the user actually wants */
471 sub->cdsc_absaddr.msf.minute =
472 bcd2uint(q.dt.minute);
473 sub->cdsc_absaddr.msf.second =
474 bcd2uint(q.dt.second);
475 sub->cdsc_absaddr.msf.frame = bcd2uint(q.dt.frame);
476 sub->cdsc_reladdr.msf.minute =
477 bcd2uint(q.tt.minute);
478 sub->cdsc_reladdr.msf.second =
479 bcd2uint(q.tt.second);
480 sub->cdsc_reladdr.msf.frame = bcd2uint(q.tt.frame);
481 xtrace(SUBCHNL,
482 "msf: abs %02d:%02d:%02d, rel %02d:%02d:%02d\n",
483 sub->cdsc_absaddr.msf.minute,
484 sub->cdsc_absaddr.msf.second,
485 sub->cdsc_absaddr.msf.frame,
486 sub->cdsc_reladdr.msf.minute,
487 sub->cdsc_reladdr.msf.second,
488 sub->cdsc_reladdr.msf.frame);
489
490 return 0;
491 }
492
493 case CDROMREADTOCHDR:{
494 struct cdrom_tochdr *toc =
495 (struct cdrom_tochdr *) arg;
496
497 xtrace(IOCTL, "ioctl() READTOCHDR\n");
498 toc->cdth_trk0 = stuffp->di.n_first;
499 toc->cdth_trk1 = stuffp->di.n_last;
500 xtrace(TOCHDR,
501 "ioctl() track0 = %d, track1 = %d\n",
502 stuffp->di.n_first, stuffp->di.n_last);
503 return 0;
504 }
505
506 case CDROMPAUSE:{
507 xtrace(IOCTL, "ioctl() PAUSE\n");
508 if (stuffp->audiostatus != CDROM_AUDIO_PLAY)
509 return -EINVAL;
510 if (-1 == mcdx_stop(stuffp, 1))
511 return -EIO;
512 stuffp->audiostatus = CDROM_AUDIO_PAUSED;
513 if (-1 ==
514 mcdx_requestsubqcode(stuffp, &stuffp->start,
515 1))
516 return -EIO;
517 return 0;
518 }
519
520 case CDROMMULTISESSION:{
521 struct cdrom_multisession *ms =
522 (struct cdrom_multisession *) arg;
523 xtrace(IOCTL, "ioctl() MULTISESSION\n");
524 /* Always return stuff in LBA, and let the Uniform cdrom driver
525 worry about what the user actually wants */
526 ms->addr.lba = msf2log(&stuffp->multi.msf_last);
527 ms->xa_flag = !!stuffp->multi.multi;
528 xtrace(MS,
529 "ioctl() (%d, 0x%08x [%02x:%02x.%02x])\n",
530 ms->xa_flag, ms->addr.lba,
531 stuffp->multi.msf_last.minute,
532 stuffp->multi.msf_last.second,
533 stuffp->multi.msf_last.frame);
534
535 return 0;
536 }
537
538 case CDROMEJECT:{
539 xtrace(IOCTL, "ioctl() EJECT\n");
540 if (stuffp->users > 1)
541 return -EBUSY;
542 return (mcdx_tray_move(cdi, 1));
543 }
544
545 case CDROMCLOSETRAY:{
546 xtrace(IOCTL, "ioctl() CDROMCLOSETRAY\n");
547 return (mcdx_tray_move(cdi, 0));
548 }
549
550 case CDROMVOLCTRL:{
551 struct cdrom_volctrl *volctrl =
552 (struct cdrom_volctrl *) arg;
553 xtrace(IOCTL, "ioctl() VOLCTRL\n");
554
555#if 0 /* not tested! */
556 /* adjust for the weirdness of workman (md) */
557 /* can't test it (hs) */
558 volctrl.channel2 = volctrl.channel1;
559 volctrl.channel1 = volctrl.channel3 = 0x00;
560#endif
561 return mcdx_setattentuator(stuffp, volctrl, 2);
562 }
563
564 default:
565 return -EINVAL;
566 }
567}
568
569static void do_mcdx_request(request_queue_t * q)
570{
571 struct s_drive_stuff *stuffp;
572 struct request *req;
573
574 again:
575
576 req = elv_next_request(q);
577 if (!req)
578 return;
579
580 stuffp = req->rq_disk->private_data;
581
582 if (!stuffp->present) {
583 xwarn("do_request(): bad device: %s\n",req->rq_disk->disk_name);
584 xtrace(REQUEST, "end_request(0): bad device\n");
585 end_request(req, 0);
586 return;
587 }
588
589 if (stuffp->audio) {
590 xwarn("do_request() attempt to read from audio cd\n");
591 xtrace(REQUEST, "end_request(0): read from audio\n");
592 end_request(req, 0);
593 return;
594 }
595
596 xtrace(REQUEST, "do_request() (%lu + %lu)\n",
597 req->sector, req->nr_sectors);
598
599 if (rq_data_dir(req) != READ) {
600 xwarn("do_request(): non-read command to cd!!\n");
601 xtrace(REQUEST, "end_request(0): write\n");
602 end_request(req, 0);
603 return;
604 }
605 else {
606 stuffp->status = 0;
607 while (req->nr_sectors) {
608 int i;
609
610 i = mcdx_transfer(stuffp,
611 req->buffer,
612 req->sector,
613 req->nr_sectors);
614
615 if (i == -1) {
616 end_request(req, 0);
617 goto again;
618 }
619 req->sector += i;
620 req->nr_sectors -= i;
621 req->buffer += (i * 512);
622 }
623 end_request(req, 1);
624 goto again;
625
626 xtrace(REQUEST, "end_request(1)\n");
627 end_request(req, 1);
628 }
629
630 goto again;
631}
632
633static int mcdx_open(struct cdrom_device_info *cdi, int purpose)
634{
635 struct s_drive_stuff *stuffp;
636 xtrace(OPENCLOSE, "open()\n");
637 stuffp = cdi->handle;
638 if (!stuffp->present)
639 return -ENXIO;
640
641 /* Make the modules looking used ... (thanx bjorn).
642 * But we shouldn't forget to decrement the module counter
643 * on error return */
644
645 /* this is only done to test if the drive talks with us */
646 if (-1 == mcdx_getstatus(stuffp, 1))
647 return -EIO;
648
649 if (stuffp->xxx) {
650
651 xtrace(OPENCLOSE, "open() media changed\n");
652 stuffp->audiostatus = CDROM_AUDIO_INVALID;
653 stuffp->readcmd = 0;
654 xtrace(OPENCLOSE, "open() Request multisession info\n");
655 if (-1 ==
656 mcdx_requestmultidiskinfo(stuffp, &stuffp->multi, 6))
657 xinfo("No multidiskinfo\n");
658 } else {
659 /* multisession ? */
660 if (!stuffp->multi.multi)
661 stuffp->multi.msf_last.second = 2;
662
663 xtrace(OPENCLOSE, "open() MS: %d, last @ %02x:%02x.%02x\n",
664 stuffp->multi.multi,
665 stuffp->multi.msf_last.minute,
666 stuffp->multi.msf_last.second,
667 stuffp->multi.msf_last.frame);
668
669 {;
670 } /* got multisession information */
671 /* request the disks table of contents (aka diskinfo) */
672 if (-1 == mcdx_requesttocdata(stuffp, &stuffp->di, 1)) {
673
674 stuffp->lastsector = -1;
675
676 } else {
677
678 stuffp->lastsector = (CD_FRAMESIZE / 512)
679 * msf2log(&stuffp->di.msf_leadout) - 1;
680
681 xtrace(OPENCLOSE,
682 "open() start %d (%02x:%02x.%02x) %d\n",
683 stuffp->di.n_first,
684 stuffp->di.msf_first.minute,
685 stuffp->di.msf_first.second,
686 stuffp->di.msf_first.frame,
687 msf2log(&stuffp->di.msf_first));
688 xtrace(OPENCLOSE,
689 "open() last %d (%02x:%02x.%02x) %d\n",
690 stuffp->di.n_last,
691 stuffp->di.msf_leadout.minute,
692 stuffp->di.msf_leadout.second,
693 stuffp->di.msf_leadout.frame,
694 msf2log(&stuffp->di.msf_leadout));
695 }
696
697 if (stuffp->toc) {
698 xtrace(MALLOC, "open() free old toc @ %p\n",
699 stuffp->toc);
700 kfree(stuffp->toc);
701
702 stuffp->toc = NULL;
703 }
704
705 xtrace(OPENCLOSE, "open() init irq generation\n");
706 if (-1 == mcdx_config(stuffp, 1))
707 return -EIO;
708#ifdef FALLBACK
709 /* Set the read speed */
710 xwarn("AAA %x AAA\n", stuffp->readcmd);
711 if (stuffp->readerrs)
712 stuffp->readcmd = READ1X;
713 else
714 stuffp->readcmd =
715 stuffp->present | SINGLE ? READ1X : READ2X;
716 xwarn("XXX %x XXX\n", stuffp->readcmd);
717#else
718 stuffp->readcmd =
719 stuffp->present | SINGLE ? READ1X : READ2X;
720#endif
721
722 /* try to get the first sector, iff any ... */
723 if (stuffp->lastsector >= 0) {
724 char buf[512];
725 int ans;
726 int tries;
727
728 stuffp->xa = 0;
729 stuffp->audio = 0;
730
731 for (tries = 6; tries; tries--) {
732
733 stuffp->introk = 1;
734
735 xtrace(OPENCLOSE, "open() try as %s\n",
736 stuffp->xa ? "XA" : "normal");
737 /* set data mode */
738 if (-1 == (ans = mcdx_setdatamode(stuffp,
739 stuffp->
740 xa ?
741 MODE2 :
742 MODE1,
743 1))) {
744 /* return -EIO; */
745 stuffp->xa = 0;
746 break;
747 }
748
749 if ((stuffp->audio = e_audio(ans)))
750 break;
751
752 while (0 ==
753 (ans =
754 mcdx_transfer(stuffp, buf, 0, 1)));
755
756 if (ans == 1)
757 break;
758 stuffp->xa = !stuffp->xa;
759 }
760 }
761 /* xa disks will be read in raw mode, others not */
762 if (-1 == mcdx_setdrivemode(stuffp,
763 stuffp->xa ? RAW : COOKED,
764 1))
765 return -EIO;
766 if (stuffp->audio) {
767 xinfo("open() audio disk found\n");
768 } else if (stuffp->lastsector >= 0) {
769 xinfo("open() %s%s disk found\n",
770 stuffp->xa ? "XA / " : "",
771 stuffp->multi.
772 multi ? "Multi Session" : "Single Session");
773 }
774 }
775 stuffp->xxx = 0;
776 stuffp->users++;
777 return 0;
778}
779
780static void mcdx_close(struct cdrom_device_info *cdi)
781{
782 struct s_drive_stuff *stuffp;
783
784 xtrace(OPENCLOSE, "close()\n");
785
786 stuffp = cdi->handle;
787
788 --stuffp->users;
789}
790
791static int mcdx_media_changed(struct cdrom_device_info *cdi, int disc_nr)
792/* Return: 1 if media changed since last call to this function
793 0 otherwise */
794{
795 struct s_drive_stuff *stuffp;
796
797 xinfo("mcdx_media_changed called for device %s\n", cdi->name);
798
799 stuffp = cdi->handle;
800 mcdx_getstatus(stuffp, 1);
801
802 if (stuffp->yyy == 0)
803 return 0;
804
805 stuffp->yyy = 0;
806 return 1;
807}
808
809#ifndef MODULE
810static int __init mcdx_setup(char *str)
811{
812 int pi[4];
813 (void) get_options(str, ARRAY_SIZE(pi), pi);
814
815 if (pi[0] > 0)
816 mcdx_drive_map[0][0] = pi[1];
817 if (pi[0] > 1)
818 mcdx_drive_map[0][1] = pi[2];
819 return 1;
820}
821
822__setup("mcdx=", mcdx_setup);
823
824#endif
825
826/* DIRTY PART ******************************************************/
827
828static void mcdx_delay(struct s_drive_stuff *stuff, long jifs)
829/* This routine is used for sleeping.
830 * A jifs value <0 means NO sleeping,
831 * =0 means minimal sleeping (let the kernel
832 * run for other processes)
833 * >0 means at least sleep for that amount.
834 * May be we could use a simple count loop w/ jumps to itself, but
835 * I wanna make this independent of cpu speed. [1 jiffy is 1/HZ] sec */
836{
837 if (jifs < 0)
838 return;
839
840 xtrace(SLEEP, "*** delay: sleepq\n");
841 interruptible_sleep_on_timeout(&stuff->sleepq, jifs);
842 xtrace(SLEEP, "delay awoken\n");
843 if (signal_pending(current)) {
844 xtrace(SLEEP, "got signal\n");
845 }
846}
847
848static irqreturn_t mcdx_intr(int irq, void *dev_id)
849{
850 struct s_drive_stuff *stuffp = dev_id;
851 unsigned char b;
852
853#ifdef AK2
854 if (!stuffp->busy && stuffp->pending)
855 stuffp->int_err = 1;
856
857#endif /* AK2 */
858 /* get the interrupt status */
859 b = inb(stuffp->rreg_status);
860 stuffp->introk = ~b & MCDX_RBIT_DTEN;
861
862 /* NOTE: We only should get interrupts if the data we
863 * requested are ready to transfer.
864 * But the drive seems to generate ``asynchronous'' interrupts
865 * on several error conditions too. (Despite the err int enable
866 * setting during initialisation) */
867
868 /* if not ok, read the next byte as the drives status */
869 if (!stuffp->introk) {
870 xtrace(IRQ, "intr() irq %d hw status 0x%02x\n", irq, b);
871 if (~b & MCDX_RBIT_STEN) {
872 xinfo("intr() irq %d status 0x%02x\n",
873 irq, inb(stuffp->rreg_data));
874 } else {
875 xinfo("intr() irq %d ambiguous hw status\n", irq);
876 }
877 } else {
878 xtrace(IRQ, "irq() irq %d ok, status %02x\n", irq, b);
879 }
880
881 stuffp->busy = 0;
882 wake_up_interruptible(&stuffp->busyq);
883 return IRQ_HANDLED;
884}
885
886
887static int mcdx_talk(struct s_drive_stuff *stuffp,
888 const unsigned char *cmd, size_t cmdlen,
889 void *buffer, size_t size, unsigned int timeout, int tries)
890/* Send a command to the drive, wait for the result.
891 * returns -1 on timeout, drive status otherwise
892 * If buffer is not zero, the result (length size) is stored there.
893 * If buffer is zero the size should be the number of bytes to read
894 * from the drive. These bytes are discarded.
895 */
896{
897 int st;
898 char c;
899 int discard;
900
901 /* Somebody wants the data read? */
902 if ((discard = (buffer == NULL)))
903 buffer = &c;
904
905 while (stuffp->lock) {
906 xtrace(SLEEP, "*** talk: lockq\n");
907 interruptible_sleep_on(&stuffp->lockq);
908 xtrace(SLEEP, "talk: awoken\n");
909 }
910
911 stuffp->lock = 1;
912
913 /* An operation other then reading data destroys the
914 * data already requested and remembered in stuffp->request, ... */
915 stuffp->valid = 0;
916
917#if MCDX_DEBUG & TALK
918 {
919 unsigned char i;
920 xtrace(TALK,
921 "talk() %d / %d tries, res.size %d, command 0x%02x",
922 tries, timeout, size, (unsigned char) cmd[0]);
923 for (i = 1; i < cmdlen; i++)
924 xtrace(TALK, " 0x%02x", cmd[i]);
925 xtrace(TALK, "\n");
926 }
927#endif
928
929 /* give up if all tries are done (bad) or if the status
930 * st != -1 (good) */
931 for (st = -1; st == -1 && tries; tries--) {
932
933 char *bp = (char *) buffer;
934 size_t sz = size;
935
936 outsb(stuffp->wreg_data, cmd, cmdlen);
937 xtrace(TALK, "talk() command sent\n");
938
939 /* get the status byte */
940 if (-1 == mcdx_getval(stuffp, timeout, 0, bp)) {
941 xinfo("talk() %02x timed out (status), %d tr%s left\n",
942 cmd[0], tries - 1, tries == 2 ? "y" : "ies");
943 continue;
944 }
945 st = *bp;
946 sz--;
947 if (!discard)
948 bp++;
949
950 xtrace(TALK, "talk() got status 0x%02x\n", st);
951
952 /* command error? */
953 if (e_cmderr(st)) {
954 xwarn("command error cmd = %02x %s \n",
955 cmd[0], cmdlen > 1 ? "..." : "");
956 st = -1;
957 continue;
958 }
959
960 /* audio status? */
961 if (stuffp->audiostatus == CDROM_AUDIO_INVALID)
962 stuffp->audiostatus =
963 e_audiobusy(st) ? CDROM_AUDIO_PLAY :
964 CDROM_AUDIO_NO_STATUS;
965 else if (stuffp->audiostatus == CDROM_AUDIO_PLAY
966 && e_audiobusy(st) == 0)
967 stuffp->audiostatus = CDROM_AUDIO_COMPLETED;
968
969 /* media change? */
970 if (e_changed(st)) {
971 xinfo("talk() media changed\n");
972 stuffp->xxx = stuffp->yyy = 1;
973 }
974
975 /* now actually get the data */
976 while (sz--) {
977 if (-1 == mcdx_getval(stuffp, timeout, 0, bp)) {
978 xinfo("talk() %02x timed out (data), %d tr%s left\n",
979 cmd[0], tries - 1,
980 tries == 2 ? "y" : "ies");
981 st = -1;
982 break;
983 }
984 if (!discard)
985 bp++;
986 xtrace(TALK, "talk() got 0x%02x\n", *(bp - 1));
987 }
988 }
989
990#if !MCDX_QUIET
991 if (!tries && st == -1)
992 xinfo("talk() giving up\n");
993#endif
994
995 stuffp->lock = 0;
996 wake_up_interruptible(&stuffp->lockq);
997
998 xtrace(TALK, "talk() done with 0x%02x\n", st);
999 return st;
1000}
1001
1002/* MODULE STUFF ***********************************************************/
1003
1004static int __init __mcdx_init(void)
1005{
1006 int i;
1007 int drives = 0;
1008
1009 mcdx_init();
1010 for (i = 0; i < MCDX_NDRIVES; i++) {
1011 if (mcdx_stuffp[i]) {
1012 xtrace(INIT, "init_module() drive %d stuff @ %p\n",
1013 i, mcdx_stuffp[i]);
1014 drives++;
1015 }
1016 }
1017
1018 if (!drives)
1019 return -EIO;
1020
1021 return 0;
1022}
1023
1024static void __exit mcdx_exit(void)
1025{
1026 int i;
1027
1028 xinfo("cleanup_module called\n");
1029
1030 for (i = 0; i < MCDX_NDRIVES; i++) {
1031 struct s_drive_stuff *stuffp = mcdx_stuffp[i];
1032 if (!stuffp)
1033 continue;
1034 del_gendisk(stuffp->disk);
1035 if (unregister_cdrom(&stuffp->info)) {
1036 printk(KERN_WARNING "Can't unregister cdrom mcdx\n");
1037 continue;
1038 }
1039 put_disk(stuffp->disk);
1040 release_region(stuffp->wreg_data, MCDX_IO_SIZE);
1041 free_irq(stuffp->irq, NULL);
1042 if (stuffp->toc) {
1043 xtrace(MALLOC, "cleanup_module() free toc @ %p\n",
1044 stuffp->toc);
1045 kfree(stuffp->toc);
1046 }
1047 xtrace(MALLOC, "cleanup_module() free stuffp @ %p\n",
1048 stuffp);
1049 mcdx_stuffp[i] = NULL;
1050 kfree(stuffp);
1051 }
1052
1053 if (unregister_blkdev(MAJOR_NR, "mcdx") != 0) {
1054 xwarn("cleanup() unregister_blkdev() failed\n");
1055 }
1056#if !MCDX_QUIET
1057 else
1058 xinfo("cleanup() succeeded\n");
1059#endif
1060 blk_cleanup_queue(mcdx_queue);
1061}
1062
1063#ifdef MODULE
1064module_init(__mcdx_init);
1065#endif
1066module_exit(mcdx_exit);
1067
1068
1069/* Support functions ************************************************/
1070
1071static int __init mcdx_init_drive(int drive)
1072{
1073 struct s_version version;
1074 struct gendisk *disk;
1075 struct s_drive_stuff *stuffp;
1076 int size = sizeof(*stuffp);
1077 char msg[80];
1078
1079 xtrace(INIT, "init() try drive %d\n", drive);
1080
1081 xtrace(INIT, "kmalloc space for stuffpt's\n");
1082 xtrace(MALLOC, "init() malloc %d bytes\n", size);
1083 if (!(stuffp = kzalloc(size, GFP_KERNEL))) {
1084 xwarn("init() malloc failed\n");
1085 return 1;
1086 }
1087
1088 disk = alloc_disk(1);
1089 if (!disk) {
1090 xwarn("init() malloc failed\n");
1091 kfree(stuffp);
1092 return 1;
1093 }
1094
1095 xtrace(INIT, "init() got %d bytes for drive stuff @ %p\n",
1096 sizeof(*stuffp), stuffp);
1097
1098 /* set default values */
1099 stuffp->present = 0; /* this should be 0 already */
1100 stuffp->toc = NULL; /* this should be NULL already */
1101
1102 /* setup our irq and i/o addresses */
1103 stuffp->irq = irq(mcdx_drive_map[drive]);
1104 stuffp->wreg_data = stuffp->rreg_data = port(mcdx_drive_map[drive]);
1105 stuffp->wreg_reset = stuffp->rreg_status = stuffp->wreg_data + 1;
1106 stuffp->wreg_hcon = stuffp->wreg_reset + 1;
1107 stuffp->wreg_chn = stuffp->wreg_hcon + 1;
1108
1109 init_waitqueue_head(&stuffp->busyq);
1110 init_waitqueue_head(&stuffp->lockq);
1111 init_waitqueue_head(&stuffp->sleepq);
1112
1113 /* check if i/o addresses are available */
1114 if (!request_region(stuffp->wreg_data, MCDX_IO_SIZE, "mcdx")) {
1115 xwarn("0x%03x,%d: Init failed. "
1116 "I/O ports (0x%03x..0x%03x) already in use.\n",
1117 stuffp->wreg_data, stuffp->irq,
1118 stuffp->wreg_data,
1119 stuffp->wreg_data + MCDX_IO_SIZE - 1);
1120 xtrace(MALLOC, "init() free stuffp @ %p\n", stuffp);
1121 kfree(stuffp);
1122 put_disk(disk);
1123 xtrace(INIT, "init() continue at next drive\n");
1124 return 0; /* next drive */
1125 }
1126
1127 xtrace(INIT, "init() i/o port is available at 0x%03x\n"
1128 stuffp->wreg_data);
1129 xtrace(INIT, "init() hardware reset\n");
1130 mcdx_reset(stuffp, HARD, 1);
1131
1132 xtrace(INIT, "init() get version\n");
1133 if (-1 == mcdx_requestversion(stuffp, &version, 4)) {
1134 /* failed, next drive */
1135 release_region(stuffp->wreg_data, MCDX_IO_SIZE);
1136 xwarn("%s=0x%03x,%d: Init failed. Can't get version.\n",
1137 MCDX, stuffp->wreg_data, stuffp->irq);
1138 xtrace(MALLOC, "init() free stuffp @ %p\n", stuffp);
1139 kfree(stuffp);
1140 put_disk(disk);
1141 xtrace(INIT, "init() continue at next drive\n");
1142 return 0;
1143 }
1144
1145 switch (version.code) {
1146 case 'D':
1147 stuffp->readcmd = READ2X;
1148 stuffp->present = DOUBLE | DOOR | MULTI;
1149 break;
1150 case 'F':
1151 stuffp->readcmd = READ1X;
1152 stuffp->present = SINGLE | DOOR | MULTI;
1153 break;
1154 case 'M':
1155 stuffp->readcmd = READ1X;
1156 stuffp->present = SINGLE;
1157 break;
1158 default:
1159 stuffp->present = 0;
1160 break;
1161 }
1162
1163 stuffp->playcmd = READ1X;
1164
1165 if (!stuffp->present) {
1166 release_region(stuffp->wreg_data, MCDX_IO_SIZE);
1167 xwarn("%s=0x%03x,%d: Init failed. No Mitsumi CD-ROM?.\n",
1168 MCDX, stuffp->wreg_data, stuffp->irq);
1169 kfree(stuffp);
1170 put_disk(disk);
1171 return 0; /* next drive */
1172 }
1173
1174 xtrace(INIT, "init() register blkdev\n");
1175 if (register_blkdev(MAJOR_NR, "mcdx")) {
1176 release_region(stuffp->wreg_data, MCDX_IO_SIZE);
1177 kfree(stuffp);
1178 put_disk(disk);
1179 return 1;
1180 }
1181
1182 mcdx_queue = blk_init_queue(do_mcdx_request, &mcdx_lock);
1183 if (!mcdx_queue) {
1184 unregister_blkdev(MAJOR_NR, "mcdx");
1185 release_region(stuffp->wreg_data, MCDX_IO_SIZE);
1186 kfree(stuffp);
1187 put_disk(disk);
1188 return 1;
1189 }
1190
1191 xtrace(INIT, "init() subscribe irq and i/o\n");
1192 if (request_irq(stuffp->irq, mcdx_intr, IRQF_DISABLED, "mcdx", stuffp)) {
1193 release_region(stuffp->wreg_data, MCDX_IO_SIZE);
1194 xwarn("%s=0x%03x,%d: Init failed. Can't get irq (%d).\n",
1195 MCDX, stuffp->wreg_data, stuffp->irq, stuffp->irq);
1196 stuffp->irq = 0;
1197 blk_cleanup_queue(mcdx_queue);
1198 kfree(stuffp);
1199 put_disk(disk);
1200 return 0;
1201 }
1202
1203 xtrace(INIT, "init() get garbage\n");
1204 {
1205 int i;
1206 mcdx_delay(stuffp, HZ / 2);
1207 for (i = 100; i; i--)
1208 (void) inb(stuffp->rreg_status);
1209 }
1210
1211
1212#ifdef WE_KNOW_WHY
1213 /* irq 11 -> channel register */
1214 outb(0x50, stuffp->wreg_chn);
1215#endif
1216
1217 xtrace(INIT, "init() set non dma but irq mode\n");
1218 mcdx_config(stuffp, 1);
1219
1220 stuffp->info.ops = &mcdx_dops;
1221 stuffp->info.speed = 2;
1222 stuffp->info.capacity = 1;
1223 stuffp->info.handle = stuffp;
1224 sprintf(stuffp->info.name, "mcdx%d", drive);
1225 disk->major = MAJOR_NR;
1226 disk->first_minor = drive;
1227 strcpy(disk->disk_name, stuffp->info.name);
1228 disk->fops = &mcdx_bdops;
1229 disk->flags = GENHD_FL_CD;
1230 stuffp->disk = disk;
1231
1232 sprintf(msg, " mcdx: Mitsumi CD-ROM installed at 0x%03x, irq %d."
1233 " (Firmware version %c %x)\n",
1234 stuffp->wreg_data, stuffp->irq, version.code, version.ver);
1235 mcdx_stuffp[drive] = stuffp;
1236 xtrace(INIT, "init() mcdx_stuffp[%d] = %p\n", drive, stuffp);
1237 if (register_cdrom(&stuffp->info) != 0) {
1238 printk("Cannot register Mitsumi CD-ROM!\n");
1239 free_irq(stuffp->irq, NULL);
1240 release_region(stuffp->wreg_data, MCDX_IO_SIZE);
1241 kfree(stuffp);
1242 put_disk(disk);
1243 if (unregister_blkdev(MAJOR_NR, "mcdx") != 0)
1244 xwarn("cleanup() unregister_blkdev() failed\n");
1245 blk_cleanup_queue(mcdx_queue);
1246 return 2;
1247 }
1248 disk->private_data = stuffp;
1249 disk->queue = mcdx_queue;
1250 add_disk(disk);
1251 printk(msg);
1252 return 0;
1253}
1254
1255static int __init mcdx_init(void)
1256{
1257 int drive;
1258 xwarn("Version 2.14(hs) \n");
1259
1260 xwarn("$Id: mcdx.c,v 1.21 1997/01/26 07:12:59 davem Exp $\n");
1261
1262 /* zero the pointer array */
1263 for (drive = 0; drive < MCDX_NDRIVES; drive++)
1264 mcdx_stuffp[drive] = NULL;
1265
1266 /* do the initialisation */
1267 for (drive = 0; drive < MCDX_NDRIVES; drive++) {
1268 switch (mcdx_init_drive(drive)) {
1269 case 2:
1270 return -EIO;
1271 case 1:
1272 break;
1273 }
1274 }
1275 return 0;
1276}
1277
1278static int mcdx_transfer(struct s_drive_stuff *stuffp,
1279 char *p, int sector, int nr_sectors)
1280/* This seems to do the actually transfer. But it does more. It
1281 keeps track of errors occurred and will (if possible) fall back
1282 to single speed on error.
1283 Return: -1 on timeout or other error
1284 else status byte (as in stuff->st) */
1285{
1286 int ans;
1287
1288 ans = mcdx_xfer(stuffp, p, sector, nr_sectors);
1289 return ans;
1290#ifdef FALLBACK
1291 if (-1 == ans)
1292 stuffp->readerrs++;
1293 else
1294 return ans;
1295
1296 if (stuffp->readerrs && stuffp->readcmd == READ1X) {
1297 xwarn("XXX Already reading 1x -- no chance\n");
1298 return -1;
1299 }
1300
1301 xwarn("XXX Fallback to 1x\n");
1302
1303 stuffp->readcmd = READ1X;
1304 return mcdx_transfer(stuffp, p, sector, nr_sectors);
1305#endif
1306
1307}
1308
1309
1310static int mcdx_xfer(struct s_drive_stuff *stuffp,
1311 char *p, int sector, int nr_sectors)
1312/* This does actually the transfer from the drive.
1313 Return: -1 on timeout or other error
1314 else status byte (as in stuff->st) */
1315{
1316 int border;
1317 int done = 0;
1318 long timeout;
1319
1320 if (stuffp->audio) {
1321 xwarn("Attempt to read from audio CD.\n");
1322 return -1;
1323 }
1324
1325 if (!stuffp->readcmd) {
1326 xinfo("Can't transfer from missing disk.\n");
1327 return -1;
1328 }
1329
1330 while (stuffp->lock) {
1331 interruptible_sleep_on(&stuffp->lockq);
1332 }
1333
1334 if (stuffp->valid && (sector >= stuffp->pending)
1335 && (sector < stuffp->low_border)) {
1336
1337 /* All (or at least a part of the sectors requested) seems
1338 * to be already requested, so we don't need to bother the
1339 * drive with new requests ...
1340 * Wait for the drive become idle, but first
1341 * check for possible occurred errors --- the drive
1342 * seems to report them asynchronously */
1343
1344
1345 border = stuffp->high_border < (border =
1346 sector + nr_sectors)
1347 ? stuffp->high_border : border;
1348
1349 stuffp->lock = current->pid;
1350
1351 do {
1352
1353 while (stuffp->busy) {
1354
1355 timeout =
1356 interruptible_sleep_on_timeout
1357 (&stuffp->busyq, 5 * HZ);
1358
1359 if (!stuffp->introk) {
1360 xtrace(XFER,
1361 "error via interrupt\n");
1362 } else if (!timeout) {
1363 xtrace(XFER, "timeout\n");
1364 } else if (signal_pending(current)) {
1365 xtrace(XFER, "signal\n");
1366 } else
1367 continue;
1368
1369 stuffp->lock = 0;
1370 stuffp->busy = 0;
1371 stuffp->valid = 0;
1372
1373 wake_up_interruptible(&stuffp->lockq);
1374 xtrace(XFER, "transfer() done (-1)\n");
1375 return -1;
1376 }
1377
1378 /* check if we need to set the busy flag (as we
1379 * expect an interrupt */
1380 stuffp->busy = (3 == (stuffp->pending & 3));
1381
1382 /* Test if it's the first sector of a block,
1383 * there we have to skip some bytes as we read raw data */
1384 if (stuffp->xa && (0 == (stuffp->pending & 3))) {
1385 const int HEAD =
1386 CD_FRAMESIZE_RAW - CD_XA_TAIL -
1387 CD_FRAMESIZE;
1388 insb(stuffp->rreg_data, p, HEAD);
1389 }
1390
1391 /* now actually read the data */
1392 insb(stuffp->rreg_data, p, 512);
1393
1394 /* test if it's the last sector of a block,
1395 * if so, we have to handle XA special */
1396 if ((3 == (stuffp->pending & 3)) && stuffp->xa) {
1397 char dummy[CD_XA_TAIL];
1398 insb(stuffp->rreg_data, &dummy[0], CD_XA_TAIL);
1399 }
1400
1401 if (stuffp->pending == sector) {
1402 p += 512;
1403 done++;
1404 sector++;
1405 }
1406 } while (++(stuffp->pending) < border);
1407
1408 stuffp->lock = 0;
1409 wake_up_interruptible(&stuffp->lockq);
1410
1411 } else {
1412
1413 /* The requested sector(s) is/are out of the
1414 * already requested range, so we have to bother the drive
1415 * with a new request. */
1416
1417 static unsigned char cmd[] = {
1418 0,
1419 0, 0, 0,
1420 0, 0, 0
1421 };
1422
1423 cmd[0] = stuffp->readcmd;
1424
1425 /* The numbers held in ->pending, ..., should be valid */
1426 stuffp->valid = 1;
1427 stuffp->pending = sector & ~3;
1428
1429 /* do some sanity checks */
1430 if (stuffp->pending > stuffp->lastsector) {
1431 xwarn
1432 ("transfer() sector %d from nirvana requested.\n",
1433 stuffp->pending);
1434 stuffp->status = MCDX_ST_EOM;
1435 stuffp->valid = 0;
1436 xtrace(XFER, "transfer() done (-1)\n");
1437 return -1;
1438 }
1439
1440 if ((stuffp->low_border = stuffp->pending + DIRECT_SIZE)
1441 > stuffp->lastsector + 1) {
1442 xtrace(XFER, "cut low_border\n");
1443 stuffp->low_border = stuffp->lastsector + 1;
1444 }
1445 if ((stuffp->high_border = stuffp->pending + REQUEST_SIZE)
1446 > stuffp->lastsector + 1) {
1447 xtrace(XFER, "cut high_border\n");
1448 stuffp->high_border = stuffp->lastsector + 1;
1449 }
1450
1451 { /* Convert the sector to be requested to MSF format */
1452 struct cdrom_msf0 pending;
1453 log2msf(stuffp->pending / 4, &pending);
1454 cmd[1] = pending.minute;
1455 cmd[2] = pending.second;
1456 cmd[3] = pending.frame;
1457 }
1458
1459 cmd[6] =
1460 (unsigned
1461 char) ((stuffp->high_border - stuffp->pending) / 4);
1462 xtrace(XFER, "[%2d]\n", cmd[6]);
1463
1464 stuffp->busy = 1;
1465 /* Now really issue the request command */
1466 outsb(stuffp->wreg_data, cmd, sizeof cmd);
1467
1468 }
1469#ifdef AK2
1470 if (stuffp->int_err) {
1471 stuffp->valid = 0;
1472 stuffp->int_err = 0;
1473 return -1;
1474 }
1475#endif /* AK2 */
1476
1477 stuffp->low_border = (stuffp->low_border +=
1478 done) <
1479 stuffp->high_border ? stuffp->low_border : stuffp->high_border;
1480
1481 return done;
1482}
1483
1484
1485/* Access to elements of the mcdx_drive_map members */
1486
1487static unsigned port(int *ip)
1488{
1489 return ip[0];
1490}
1491static int irq(int *ip)
1492{
1493 return ip[1];
1494}
1495
1496/* Misc number converters */
1497
1498static unsigned int bcd2uint(unsigned char c)
1499{
1500 return (c >> 4) * 10 + (c & 0x0f);
1501}
1502
1503static unsigned int uint2bcd(unsigned int ival)
1504{
1505 return ((ival / 10) << 4) | (ival % 10);
1506}
1507
1508static void log2msf(unsigned int l, struct cdrom_msf0 *pmsf)
1509{
1510 l += CD_MSF_OFFSET;
1511 pmsf->minute = uint2bcd(l / 4500), l %= 4500;
1512 pmsf->second = uint2bcd(l / 75);
1513 pmsf->frame = uint2bcd(l % 75);
1514}
1515
1516static unsigned int msf2log(const struct cdrom_msf0 *pmsf)
1517{
1518 return bcd2uint(pmsf->frame)
1519 + bcd2uint(pmsf->second) * 75
1520 + bcd2uint(pmsf->minute) * 4500 - CD_MSF_OFFSET;
1521}
1522
1523int mcdx_readtoc(struct s_drive_stuff *stuffp)
1524/* Read the toc entries from the CD,
1525 * Return: -1 on failure, else 0 */
1526{
1527
1528 if (stuffp->toc) {
1529 xtrace(READTOC, "ioctl() toc already read\n");
1530 return 0;
1531 }
1532
1533 xtrace(READTOC, "ioctl() readtoc for %d tracks\n",
1534 stuffp->di.n_last - stuffp->di.n_first + 1);
1535
1536 if (-1 == mcdx_hold(stuffp, 1))
1537 return -1;
1538
1539 xtrace(READTOC, "ioctl() tocmode\n");
1540 if (-1 == mcdx_setdrivemode(stuffp, TOC, 1))
1541 return -EIO;
1542
1543 /* all seems to be ok so far ... malloc */
1544 {
1545 int size;
1546 size =
1547 sizeof(struct s_subqcode) * (stuffp->di.n_last -
1548 stuffp->di.n_first + 2);
1549
1550 xtrace(MALLOC, "ioctl() malloc %d bytes\n", size);
1551 stuffp->toc = kmalloc(size, GFP_KERNEL);
1552 if (!stuffp->toc) {
1553 xwarn("Cannot malloc %d bytes for toc\n", size);
1554 mcdx_setdrivemode(stuffp, DATA, 1);
1555 return -EIO;
1556 }
1557 }
1558
1559 /* now read actually the index */
1560 {
1561 int trk;
1562 int retries;
1563
1564 for (trk = 0;
1565 trk < (stuffp->di.n_last - stuffp->di.n_first + 1);
1566 trk++)
1567 stuffp->toc[trk].index = 0;
1568
1569 for (retries = 300; retries; retries--) { /* why 300? */
1570 struct s_subqcode q;
1571 unsigned int idx;
1572
1573 if (-1 == mcdx_requestsubqcode(stuffp, &q, 1)) {
1574 mcdx_setdrivemode(stuffp, DATA, 1);
1575 return -EIO;
1576 }
1577
1578 idx = bcd2uint(q.index);
1579
1580 if ((idx > 0)
1581 && (idx <= stuffp->di.n_last)
1582 && (q.tno == 0)
1583 && (stuffp->toc[idx - stuffp->di.n_first].
1584 index == 0)) {
1585 stuffp->toc[idx - stuffp->di.n_first] = q;
1586 xtrace(READTOC,
1587 "ioctl() toc idx %d (trk %d)\n",
1588 idx, trk);
1589 trk--;
1590 }
1591 if (trk == 0)
1592 break;
1593 }
1594 memset(&stuffp->
1595 toc[stuffp->di.n_last - stuffp->di.n_first + 1], 0,
1596 sizeof(stuffp->toc[0]));
1597 stuffp->toc[stuffp->di.n_last - stuffp->di.n_first +
1598 1].dt = stuffp->di.msf_leadout;
1599 }
1600
1601 /* unset toc mode */
1602 xtrace(READTOC, "ioctl() undo toc mode\n");
1603 if (-1 == mcdx_setdrivemode(stuffp, DATA, 2))
1604 return -EIO;
1605
1606#if MCDX_DEBUG && READTOC
1607 {
1608 int trk;
1609 for (trk = 0;
1610 trk < (stuffp->di.n_last - stuffp->di.n_first + 2);
1611 trk++)
1612 xtrace(READTOC, "ioctl() %d readtoc %02x %02x %02x"
1613 " %02x:%02x.%02x %02x:%02x.%02x\n",
1614 trk + stuffp->di.n_first,
1615 stuffp->toc[trk].control,
1616 stuffp->toc[trk].tno,
1617 stuffp->toc[trk].index,
1618 stuffp->toc[trk].tt.minute,
1619 stuffp->toc[trk].tt.second,
1620 stuffp->toc[trk].tt.frame,
1621 stuffp->toc[trk].dt.minute,
1622 stuffp->toc[trk].dt.second,
1623 stuffp->toc[trk].dt.frame);
1624 }
1625#endif
1626
1627 return 0;
1628}
1629
1630static int
1631mcdx_playmsf(struct s_drive_stuff *stuffp, const struct cdrom_msf *msf)
1632{
1633 unsigned char cmd[7] = {
1634 0, 0, 0, 0, 0, 0, 0
1635 };
1636
1637 if (!stuffp->readcmd) {
1638 xinfo("Can't play from missing disk.\n");
1639 return -1;
1640 }
1641
1642 cmd[0] = stuffp->playcmd;
1643
1644 cmd[1] = msf->cdmsf_min0;
1645 cmd[2] = msf->cdmsf_sec0;
1646 cmd[3] = msf->cdmsf_frame0;
1647 cmd[4] = msf->cdmsf_min1;
1648 cmd[5] = msf->cdmsf_sec1;
1649 cmd[6] = msf->cdmsf_frame1;
1650
1651 xtrace(PLAYMSF, "ioctl(): play %x "
1652 "%02x:%02x:%02x -- %02x:%02x:%02x\n",
1653 cmd[0], cmd[1], cmd[2], cmd[3], cmd[4], cmd[5], cmd[6]);
1654
1655 outsb(stuffp->wreg_data, cmd, sizeof cmd);
1656
1657 if (-1 == mcdx_getval(stuffp, 3 * HZ, 0, NULL)) {
1658 xwarn("playmsf() timeout\n");
1659 return -1;
1660 }
1661
1662 stuffp->audiostatus = CDROM_AUDIO_PLAY;
1663 return 0;
1664}
1665
1666static int
1667mcdx_playtrk(struct s_drive_stuff *stuffp, const struct cdrom_ti *ti)
1668{
1669 struct s_subqcode *p;
1670 struct cdrom_msf msf;
1671
1672 if (-1 == mcdx_readtoc(stuffp))
1673 return -1;
1674
1675 if (ti)
1676 p = &stuffp->toc[ti->cdti_trk0 - stuffp->di.n_first];
1677 else
1678 p = &stuffp->start;
1679
1680 msf.cdmsf_min0 = p->dt.minute;
1681 msf.cdmsf_sec0 = p->dt.second;
1682 msf.cdmsf_frame0 = p->dt.frame;
1683
1684 if (ti) {
1685 p = &stuffp->toc[ti->cdti_trk1 - stuffp->di.n_first + 1];
1686 stuffp->stop = *p;
1687 } else
1688 p = &stuffp->stop;
1689
1690 msf.cdmsf_min1 = p->dt.minute;
1691 msf.cdmsf_sec1 = p->dt.second;
1692 msf.cdmsf_frame1 = p->dt.frame;
1693
1694 return mcdx_playmsf(stuffp, &msf);
1695}
1696
1697
1698/* Drive functions ************************************************/
1699
1700static int mcdx_tray_move(struct cdrom_device_info *cdi, int position)
1701{
1702 struct s_drive_stuff *stuffp = cdi->handle;
1703
1704 if (!stuffp->present)
1705 return -ENXIO;
1706 if (!(stuffp->present & DOOR))
1707 return -ENOSYS;
1708
1709 if (position) /* 1: eject */
1710 return mcdx_talk(stuffp, "\xf6", 1, NULL, 1, 5 * HZ, 3);
1711 else /* 0: close */
1712 return mcdx_talk(stuffp, "\xf8", 1, NULL, 1, 5 * HZ, 3);
1713 return 1;
1714}
1715
1716static int mcdx_stop(struct s_drive_stuff *stuffp, int tries)
1717{
1718 return mcdx_talk(stuffp, "\xf0", 1, NULL, 1, 2 * HZ, tries);
1719}
1720
1721static int mcdx_hold(struct s_drive_stuff *stuffp, int tries)
1722{
1723 return mcdx_talk(stuffp, "\x70", 1, NULL, 1, 2 * HZ, tries);
1724}
1725
1726static int mcdx_requestsubqcode(struct s_drive_stuff *stuffp,
1727 struct s_subqcode *sub, int tries)
1728{
1729 char buf[11];
1730 int ans;
1731
1732 if (-1 == (ans = mcdx_talk(stuffp, "\x20", 1, buf, sizeof(buf),
1733 2 * HZ, tries)))
1734 return -1;
1735 sub->control = buf[1];
1736 sub->tno = buf[2];
1737 sub->index = buf[3];
1738 sub->tt.minute = buf[4];
1739 sub->tt.second = buf[5];
1740 sub->tt.frame = buf[6];
1741 sub->dt.minute = buf[8];
1742 sub->dt.second = buf[9];
1743 sub->dt.frame = buf[10];
1744
1745 return ans;
1746}
1747
1748static int mcdx_requestmultidiskinfo(struct s_drive_stuff *stuffp,
1749 struct s_multi *multi, int tries)
1750{
1751 char buf[5];
1752 int ans;
1753
1754 if (stuffp->present & MULTI) {
1755 ans =
1756 mcdx_talk(stuffp, "\x11", 1, buf, sizeof(buf), 2 * HZ,
1757 tries);
1758 multi->multi = buf[1];
1759 multi->msf_last.minute = buf[2];
1760 multi->msf_last.second = buf[3];
1761 multi->msf_last.frame = buf[4];
1762 return ans;
1763 } else {
1764 multi->multi = 0;
1765 return 0;
1766 }
1767}
1768
1769static int mcdx_requesttocdata(struct s_drive_stuff *stuffp, struct s_diskinfo *info,
1770 int tries)
1771{
1772 char buf[9];
1773 int ans;
1774 ans =
1775 mcdx_talk(stuffp, "\x10", 1, buf, sizeof(buf), 2 * HZ, tries);
1776 if (ans == -1) {
1777 info->n_first = 0;
1778 info->n_last = 0;
1779 } else {
1780 info->n_first = bcd2uint(buf[1]);
1781 info->n_last = bcd2uint(buf[2]);
1782 info->msf_leadout.minute = buf[3];
1783 info->msf_leadout.second = buf[4];
1784 info->msf_leadout.frame = buf[5];
1785 info->msf_first.minute = buf[6];
1786 info->msf_first.second = buf[7];
1787 info->msf_first.frame = buf[8];
1788 }
1789 return ans;
1790}
1791
1792static int mcdx_setdrivemode(struct s_drive_stuff *stuffp, enum drivemodes mode,
1793 int tries)
1794{
1795 char cmd[2];
1796 int ans;
1797
1798 xtrace(HW, "setdrivemode() %d\n", mode);
1799
1800 if (-1 == (ans = mcdx_talk(stuffp, "\xc2", 1, cmd, sizeof(cmd), 5 * HZ, tries)))
1801 return -1;
1802
1803 switch (mode) {
1804 case TOC:
1805 cmd[1] |= 0x04;
1806 break;
1807 case DATA:
1808 cmd[1] &= ~0x04;
1809 break;
1810 case RAW:
1811 cmd[1] |= 0x40;
1812 break;
1813 case COOKED:
1814 cmd[1] &= ~0x40;
1815 break;
1816 default:
1817 break;
1818 }
1819 cmd[0] = 0x50;
1820 return mcdx_talk(stuffp, cmd, 2, NULL, 1, 5 * HZ, tries);
1821}
1822
1823static int mcdx_setdatamode(struct s_drive_stuff *stuffp, enum datamodes mode,
1824 int tries)
1825{
1826 unsigned char cmd[2] = { 0xa0 };
1827 xtrace(HW, "setdatamode() %d\n", mode);
1828 switch (mode) {
1829 case MODE0:
1830 cmd[1] = 0x00;
1831 break;
1832 case MODE1:
1833 cmd[1] = 0x01;
1834 break;
1835 case MODE2:
1836 cmd[1] = 0x02;
1837 break;
1838 default:
1839 return -EINVAL;
1840 }
1841 return mcdx_talk(stuffp, cmd, 2, NULL, 1, 5 * HZ, tries);
1842}
1843
1844static int mcdx_config(struct s_drive_stuff *stuffp, int tries)
1845{
1846 char cmd[4];
1847
1848 xtrace(HW, "config()\n");
1849
1850 cmd[0] = 0x90;
1851
1852 cmd[1] = 0x10; /* irq enable */
1853 cmd[2] = 0x05; /* pre, err irq enable */
1854
1855 if (-1 == mcdx_talk(stuffp, cmd, 3, NULL, 1, 1 * HZ, tries))
1856 return -1;
1857
1858 cmd[1] = 0x02; /* dma select */
1859 cmd[2] = 0x00; /* no dma */
1860
1861 return mcdx_talk(stuffp, cmd, 3, NULL, 1, 1 * HZ, tries);
1862}
1863
1864static int mcdx_requestversion(struct s_drive_stuff *stuffp, struct s_version *ver,
1865 int tries)
1866{
1867 char buf[3];
1868 int ans;
1869
1870 if (-1 == (ans = mcdx_talk(stuffp, "\xdc",
1871 1, buf, sizeof(buf), 2 * HZ, tries)))
1872 return ans;
1873
1874 ver->code = buf[1];
1875 ver->ver = buf[2];
1876
1877 return ans;
1878}
1879
1880static int mcdx_reset(struct s_drive_stuff *stuffp, enum resetmodes mode, int tries)
1881{
1882 if (mode == HARD) {
1883 outb(0, stuffp->wreg_chn); /* no dma, no irq -> hardware */
1884 outb(0, stuffp->wreg_reset); /* hw reset */
1885 return 0;
1886 } else
1887 return mcdx_talk(stuffp, "\x60", 1, NULL, 1, 5 * HZ, tries);
1888}
1889
1890static int mcdx_lockdoor(struct cdrom_device_info *cdi, int lock)
1891{
1892 struct s_drive_stuff *stuffp = cdi->handle;
1893 char cmd[2] = { 0xfe };
1894
1895 if (!(stuffp->present & DOOR))
1896 return -ENOSYS;
1897 if (stuffp->present & DOOR) {
1898 cmd[1] = lock ? 0x01 : 0x00;
1899 return mcdx_talk(stuffp, cmd, sizeof(cmd), NULL, 1, 5 * HZ, 3);
1900 } else
1901 return 0;
1902}
1903
1904static int mcdx_getstatus(struct s_drive_stuff *stuffp, int tries)
1905{
1906 return mcdx_talk(stuffp, "\x40", 1, NULL, 1, 5 * HZ, tries);
1907}
1908
1909static int
1910mcdx_getval(struct s_drive_stuff *stuffp, int to, int delay, char *buf)
1911{
1912 unsigned long timeout = to + jiffies;
1913 char c;
1914
1915 if (!buf)
1916 buf = &c;
1917
1918 while (inb(stuffp->rreg_status) & MCDX_RBIT_STEN) {
1919 if (time_after(jiffies, timeout))
1920 return -1;
1921 mcdx_delay(stuffp, delay);
1922 }
1923
1924 *buf = (unsigned char) inb(stuffp->rreg_data) & 0xff;
1925
1926 return 0;
1927}
1928
1929static int mcdx_setattentuator(struct s_drive_stuff *stuffp,
1930 struct cdrom_volctrl *vol, int tries)
1931{
1932 char cmd[5];
1933 cmd[0] = 0xae;
1934 cmd[1] = vol->channel0;
1935 cmd[2] = 0;
1936 cmd[3] = vol->channel1;
1937 cmd[4] = 0;
1938
1939 return mcdx_talk(stuffp, cmd, sizeof(cmd), NULL, 5, 200, tries);
1940}
1941
1942MODULE_LICENSE("GPL");
1943MODULE_ALIAS_BLOCKDEV_MAJOR(MITSUMI_X_CDROM_MAJOR);
diff --git a/drivers/cdrom/mcdx.h b/drivers/cdrom/mcdx.h
deleted file mode 100644
index 83c364a74dc4..000000000000
--- a/drivers/cdrom/mcdx.h
+++ /dev/null
@@ -1,185 +0,0 @@
1/*
2 * Definitions for the Mitsumi CDROM interface
3 * Copyright (C) 1995 1996 Heiko Schlittermann <heiko@lotte.sax.de>
4 * VERSION: @VERSION@
5 *
6 * This program is free software; you can redistribute it and/or modify
7 * it under the terms of the GNU General Public License as published by
8 * the Free Software Foundation; either version 2, or (at your option)
9 * any later version.
10 *
11 * This program is distributed in the hope that it will be useful,
12 * but WITHOUT ANY WARRANTY; without even the implied warranty of
13 * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
14 * GNU General Public License for more details.
15 *
16 * You should have received a copy of the GNU General Public License
17 * along with this program; see the file COPYING. If not, write to
18 * the Free Software Foundation, 675 Mass Ave, Cambridge, MA 02139, USA.
19 *
20 * Thanks to
21 * The Linux Community at all and ...
22 * Martin Harris (he wrote the first Mitsumi Driver)
23 * Eberhard Moenkeberg (he gave me much support and the initial kick)
24 * Bernd Huebner, Ruediger Helsch (Unifix-Software Gmbh, they
25 * improved the original driver)
26 * Jon Tombs, Bjorn Ekwall (module support)
27 * Daniel v. Mosnenck (he sent me the Technical and Programming Reference)
28 * Gerd Knorr (he lent me his PhotoCD)
29 * Nils Faerber and Roger E. Wolff (extensively tested the LU portion)
30 * Andreas Kies (testing the mysterious hang up's)
31 * ... somebody forgotten?
32 * Marcin Dalecki
33 *
34 */
35
36/*
37 * The following lines are for user configuration
38 * ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
39 *
40 * {0|1} -- 1 if you want the driver detect your drive, may crash and
41 * needs a long time to seek. The higher the address the longer the
42 * seek.
43 *
44 * WARNING: AUTOPROBE doesn't work.
45 */
46#define MCDX_AUTOPROBE 0
47
48/*
49 * Drive specific settings according to the jumpers on the controller
50 * board(s).
51 * o MCDX_NDRIVES : number of used entries of the following table
52 * o MCDX_DRIVEMAP : table of {i/o base, irq} per controller
53 *
54 * NOTE: I didn't get a drive at irq 9(2) working. Not even alone.
55 */
56#if MCDX_AUTOPROBE == 0
57 #define MCDX_NDRIVES 1
58 #define MCDX_DRIVEMAP { \
59 {0x300, 11}, \
60 {0x304, 05}, \
61 {0x000, 00}, \
62 {0x000, 00}, \
63 {0x000, 00}, \
64 }
65#else
66 #error Autoprobing is not implemented yet.
67#endif
68
69#ifndef MCDX_QUIET
70#define MCDX_QUIET 1
71#endif
72
73#ifndef MCDX_DEBUG
74#define MCDX_DEBUG 0
75#endif
76
77/* *** make the following line uncommented, if you're sure,
78 * *** all configuration is done */
79/* #define I_WAS_HERE */
80
81/* The name of the device */
82#define MCDX "mcdx"
83
84/* Flags for DEBUGGING */
85#define INIT 0
86#define MALLOC 0
87#define IOCTL 0
88#define PLAYTRK 0
89#define SUBCHNL 0
90#define TOCHDR 0
91#define MS 0
92#define PLAYMSF 0
93#define READTOC 0
94#define OPENCLOSE 0
95#define HW 0
96#define TALK 0
97#define IRQ 0
98#define XFER 0
99#define REQUEST 0
100#define SLEEP 0
101
102/* The following addresses are taken from the Mitsumi Reference
103 * and describe the possible i/o range for the controller.
104 */
105#define MCDX_IO_BEGIN ((char*) 0x300) /* first base of i/o addr */
106#define MCDX_IO_END ((char*) 0x3fc) /* last base of i/o addr */
107
108/* Per controller 4 bytes i/o are needed. */
109#define MCDX_IO_SIZE 4
110
111/*
112 * Bits
113 */
114
115/* The status byte, returned from every command, set if
116 * the description is true */
117#define MCDX_RBIT_OPEN 0x80 /* door is open */
118#define MCDX_RBIT_DISKSET 0x40 /* disk set (recognised) */
119#define MCDX_RBIT_CHANGED 0x20 /* disk was changed */
120#define MCDX_RBIT_CHECK 0x10 /* disk rotates, servo is on */
121#define MCDX_RBIT_AUDIOTR 0x08 /* current track is audio */
122#define MCDX_RBIT_RDERR 0x04 /* read error, refer SENSE KEY */
123#define MCDX_RBIT_AUDIOBS 0x02 /* currently playing audio */
124#define MCDX_RBIT_CMDERR 0x01 /* command, param or format error */
125
126/* The I/O Register holding the h/w status of the drive,
127 * can be read at i/o base + 1 */
128#define MCDX_RBIT_DOOR 0x10 /* door is open */
129#define MCDX_RBIT_STEN 0x04 /* if 0, i/o base contains drive status */
130#define MCDX_RBIT_DTEN 0x02 /* if 0, i/o base contains data */
131
132/*
133 * The commands.
134 */
135
136#define OPCODE 1 /* offset of opcode */
137#define MCDX_CMD_REQUEST_TOC 1, 0x10
138#define MCDX_CMD_REQUEST_STATUS 1, 0x40
139#define MCDX_CMD_RESET 1, 0x60
140#define MCDX_CMD_REQUEST_DRIVE_MODE 1, 0xc2
141#define MCDX_CMD_SET_INTERLEAVE 2, 0xc8, 0
142#define MCDX_CMD_DATAMODE_SET 2, 0xa0, 0
143 #define MCDX_DATAMODE1 0x01
144 #define MCDX_DATAMODE2 0x02
145#define MCDX_CMD_LOCK_DOOR 2, 0xfe, 0
146
147#define READ_AHEAD 4 /* 8 Sectors (4K) */
148
149/* Useful macros */
150#define e_door(x) ((x) & MCDX_RBIT_OPEN)
151#define e_check(x) (~(x) & MCDX_RBIT_CHECK)
152#define e_notset(x) (~(x) & MCDX_RBIT_DISKSET)
153#define e_changed(x) ((x) & MCDX_RBIT_CHANGED)
154#define e_audio(x) ((x) & MCDX_RBIT_AUDIOTR)
155#define e_audiobusy(x) ((x) & MCDX_RBIT_AUDIOBS)
156#define e_cmderr(x) ((x) & MCDX_RBIT_CMDERR)
157#define e_readerr(x) ((x) & MCDX_RBIT_RDERR)
158
159/** no drive specific */
160#define MCDX_CDBLK 2048 /* 2048 cooked data each blk */
161
162#define MCDX_DATA_TIMEOUT (HZ/10) /* 0.1 second */
163
164/*
165 * Access to the msf array
166 */
167#define MSF_MIN 0 /* minute */
168#define MSF_SEC 1 /* second */
169#define MSF_FRM 2 /* frame */
170
171/*
172 * Errors
173 */
174#define MCDX_E 1 /* unspec error */
175#define MCDX_ST_EOM 0x0100 /* end of media */
176#define MCDX_ST_DRV 0x00ff /* mask to query the drive status */
177
178#ifndef I_WAS_HERE
179#ifndef MODULE
180#warning You have not edited mcdx.h
181#warning Perhaps irq and i/o settings are wrong.
182#endif
183#endif
184
185/* ex:set ts=4 sw=4: */
diff --git a/drivers/cdrom/optcd.c b/drivers/cdrom/optcd.c
deleted file mode 100644
index efd619c0fe10..000000000000
--- a/drivers/cdrom/optcd.c
+++ /dev/null
@@ -1,2105 +0,0 @@
1/* linux/drivers/cdrom/optcd.c - Optics Storage 8000 AT CDROM driver
2 $Id: optcd.c,v 1.11 1997/01/26 07:13:00 davem Exp $
3
4 Copyright (C) 1995 Leo Spiekman (spiekman@dutette.et.tudelft.nl)
5
6
7 Based on Aztech CD268 CDROM driver by Werner Zimmermann and preworks
8 by Eberhard Moenkeberg (emoenke@gwdg.de).
9
10 This program is free software; you can redistribute it and/or modify
11 it under the terms of the GNU General Public License as published by
12 the Free Software Foundation; either version 2, or (at your option)
13 any later version.
14
15 This program is distributed in the hope that it will be useful,
16 but WITHOUT ANY WARRANTY; without even the implied warranty of
17 MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
18 GNU General Public License for more details.
19
20 You should have received a copy of the GNU General Public License
21 along with this program; if not, write to the Free Software
22 Foundation, Inc., 675 Mass Ave, Cambridge, MA 02139, USA.
23*/
24
25/* Revision history
26
27
28 14-5-95 v0.0 Plays sound tracks. No reading of data CDs yet.
29 Detection of disk change doesn't work.
30 21-5-95 v0.1 First ALPHA version. CD can be mounted. The
31 device major nr is borrowed from the Aztech
32 driver. Speed is around 240 kb/s, as measured
33 with "time dd if=/dev/cdrom of=/dev/null \
34 bs=2048 count=4096".
35 24-6-95 v0.2 Reworked the #defines for the command codes
36 and the like, as well as the structure of
37 the hardware communication protocol, to
38 reflect the "official" documentation, kindly
39 supplied by C.K. Tan, Optics Storage Pte. Ltd.
40 Also tidied up the state machine somewhat.
41 28-6-95 v0.3 Removed the ISP-16 interface code, as this
42 should go into its own driver. The driver now
43 has its own major nr.
44 Disk change detection now seems to work, too.
45 This version became part of the standard
46 kernel as of version 1.3.7
47 24-9-95 v0.4 Re-inserted ISP-16 interface code which I
48 copied from sjcd.c, with a few changes.
49 Updated README.optcd. Submitted for
50 inclusion in 1.3.21
51 29-9-95 v0.4a Fixed bug that prevented compilation as module
52 25-10-95 v0.5 Started multisession code. Implementation
53 copied from Werner Zimmermann, who copied it
54 from Heiko Schlittermann's mcdx.
55 17-1-96 v0.6 Multisession works; some cleanup too.
56 18-4-96 v0.7 Increased some timing constants;
57 thanks to Luke McFarlane. Also tidied up some
58 printk behaviour. ISP16 initialization
59 is now handled by a separate driver.
60
61 09-11-99 Make kernel-parameter implementation work with 2.3.x
62 Removed init_module & cleanup_module in favor of
63 module_init & module_exit.
64 Torben Mathiasen <tmm@image.dk>
65*/
66
67/* Includes */
68
69
70#include <linux/module.h>
71#include <linux/mm.h>
72#include <linux/ioport.h>
73#include <linux/init.h>
74
75#include <asm/io.h>
76#include <linux/blkdev.h>
77
78#include <linux/cdrom.h>
79#include "optcd.h"
80
81#include <asm/uaccess.h>
82
83#define MAJOR_NR OPTICS_CDROM_MAJOR
84#define QUEUE (opt_queue)
85#define CURRENT elv_next_request(opt_queue)
86
87
88/* Debug support */
89
90
91/* Don't forget to add new debug flags here. */
92#if DEBUG_DRIVE_IF | DEBUG_VFS | DEBUG_CONV | DEBUG_TOC | \
93 DEBUG_BUFFERS | DEBUG_REQUEST | DEBUG_STATE | DEBUG_MULTIS
94#define DEBUG(x) debug x
95static void debug(int debug_this, const char* fmt, ...)
96{
97 char s[1024];
98 va_list args;
99
100 if (!debug_this)
101 return;
102
103 va_start(args, fmt);
104 vsnprintf(s, sizeof(s), fmt, args);
105 printk(KERN_DEBUG "optcd: %s\n", s);
106 va_end(args);
107}
108#else
109#define DEBUG(x)
110#endif
111
112
113/* Drive hardware/firmware characteristics
114 Identifiers in accordance with Optics Storage documentation */
115
116
117#define optcd_port optcd /* Needed for the modutils. */
118static short optcd_port = OPTCD_PORTBASE; /* I/O base of drive. */
119module_param(optcd_port, short, 0);
120/* Drive registers, read */
121#define DATA_PORT optcd_port /* Read data/status */
122#define STATUS_PORT optcd_port+1 /* Indicate data/status availability */
123
124/* Drive registers, write */
125#define COMIN_PORT optcd_port /* For passing command/parameter */
126#define RESET_PORT optcd_port+1 /* Write anything and wait 0.5 sec */
127#define HCON_PORT optcd_port+2 /* Host Xfer Configuration */
128
129
130/* Command completion/status read from DATA register */
131#define ST_DRVERR 0x80
132#define ST_DOOR_OPEN 0x40
133#define ST_MIXEDMODE_DISK 0x20
134#define ST_MODE_BITS 0x1c
135#define ST_M_STOP 0x00
136#define ST_M_READ 0x04
137#define ST_M_AUDIO 0x04
138#define ST_M_PAUSE 0x08
139#define ST_M_INITIAL 0x0c
140#define ST_M_ERROR 0x10
141#define ST_M_OTHERS 0x14
142#define ST_MODE2TRACK 0x02
143#define ST_DSK_CHG 0x01
144#define ST_L_LOCK 0x01
145#define ST_CMD_OK 0x00
146#define ST_OP_OK 0x01
147#define ST_PA_OK 0x02
148#define ST_OP_ERROR 0x05
149#define ST_PA_ERROR 0x06
150
151
152/* Error codes (appear as command completion code from DATA register) */
153/* Player related errors */
154#define ERR_ILLCMD 0x11 /* Illegal command to player module */
155#define ERR_ILLPARM 0x12 /* Illegal parameter to player module */
156#define ERR_SLEDGE 0x13
157#define ERR_FOCUS 0x14
158#define ERR_MOTOR 0x15
159#define ERR_RADIAL 0x16
160#define ERR_PLL 0x17 /* PLL lock error */
161#define ERR_SUB_TIM 0x18 /* Subcode timeout error */
162#define ERR_SUB_NF 0x19 /* Subcode not found error */
163#define ERR_TRAY 0x1a
164#define ERR_TOC 0x1b /* Table of Contents read error */
165#define ERR_JUMP 0x1c
166/* Data errors */
167#define ERR_MODE 0x21
168#define ERR_FORM 0x22
169#define ERR_HEADADDR 0x23 /* Header Address not found */
170#define ERR_CRC 0x24
171#define ERR_ECC 0x25 /* Uncorrectable ECC error */
172#define ERR_CRC_UNC 0x26 /* CRC error and uncorrectable error */
173#define ERR_ILLBSYNC 0x27 /* Illegal block sync error */
174#define ERR_VDST 0x28 /* VDST not found */
175/* Timeout errors */
176#define ERR_READ_TIM 0x31 /* Read timeout error */
177#define ERR_DEC_STP 0x32 /* Decoder stopped */
178#define ERR_DEC_TIM 0x33 /* Decoder interrupt timeout error */
179/* Function abort codes */
180#define ERR_KEY 0x41 /* Key -Detected abort */
181#define ERR_READ_FINISH 0x42 /* Read Finish */
182/* Second Byte diagnostic codes */
183#define ERR_NOBSYNC 0x01 /* No block sync */
184#define ERR_SHORTB 0x02 /* Short block */
185#define ERR_LONGB 0x03 /* Long block */
186#define ERR_SHORTDSP 0x04 /* Short DSP word */
187#define ERR_LONGDSP 0x05 /* Long DSP word */
188
189
190/* Status availability flags read from STATUS register */
191#define FL_EJECT 0x20
192#define FL_WAIT 0x10 /* active low */
193#define FL_EOP 0x08 /* active low */
194#define FL_STEN 0x04 /* Status available when low */
195#define FL_DTEN 0x02 /* Data available when low */
196#define FL_DRQ 0x01 /* active low */
197#define FL_RESET 0xde /* These bits are high after a reset */
198#define FL_STDT (FL_STEN|FL_DTEN)
199
200
201/* Transfer mode, written to HCON register */
202#define HCON_DTS 0x08
203#define HCON_SDRQB 0x04
204#define HCON_LOHI 0x02
205#define HCON_DMA16 0x01
206
207
208/* Drive command set, written to COMIN register */
209/* Quick response commands */
210#define COMDRVST 0x20 /* Drive Status Read */
211#define COMERRST 0x21 /* Error Status Read */
212#define COMIOCTLISTAT 0x22 /* Status Read; reset disk changed bit */
213#define COMINITSINGLE 0x28 /* Initialize Single Speed */
214#define COMINITDOUBLE 0x29 /* Initialize Double Speed */
215#define COMUNLOCK 0x30 /* Unlock */
216#define COMLOCK 0x31 /* Lock */
217#define COMLOCKST 0x32 /* Lock/Unlock Status */
218#define COMVERSION 0x40 /* Get Firmware Revision */
219#define COMVOIDREADMODE 0x50 /* Void Data Read Mode */
220/* Read commands */
221#define COMFETCH 0x60 /* Prefetch Data */
222#define COMREAD 0x61 /* Read */
223#define COMREADRAW 0x62 /* Read Raw Data */
224#define COMREADALL 0x63 /* Read All 2646 Bytes */
225/* Player control commands */
226#define COMLEADIN 0x70 /* Seek To Lead-in */
227#define COMSEEK 0x71 /* Seek */
228#define COMPAUSEON 0x80 /* Pause On */
229#define COMPAUSEOFF 0x81 /* Pause Off */
230#define COMSTOP 0x82 /* Stop */
231#define COMOPEN 0x90 /* Open Tray Door */
232#define COMCLOSE 0x91 /* Close Tray Door */
233#define COMPLAY 0xa0 /* Audio Play */
234#define COMPLAY_TNO 0xa2 /* Audio Play By Track Number */
235#define COMSUBQ 0xb0 /* Read Sub-q Code */
236#define COMLOCATION 0xb1 /* Read Head Position */
237/* Audio control commands */
238#define COMCHCTRL 0xc0 /* Audio Channel Control */
239/* Miscellaneous (test) commands */
240#define COMDRVTEST 0xd0 /* Write Test Bytes */
241#define COMTEST 0xd1 /* Diagnostic Test */
242
243/* Low level drive interface. Only here we do actual I/O
244 Waiting for status / data available */
245
246
247/* Busy wait until FLAG goes low. Return 0 on timeout. */
248static inline int flag_low(int flag, unsigned long timeout)
249{
250 int flag_high;
251 unsigned long count = 0;
252
253 while ((flag_high = (inb(STATUS_PORT) & flag)))
254 if (++count >= timeout)
255 break;
256
257 DEBUG((DEBUG_DRIVE_IF, "flag_low 0x%x count %ld%s",
258 flag, count, flag_high ? " timeout" : ""));
259 return !flag_high;
260}
261
262
263/* Timed waiting for status or data */
264static int sleep_timeout; /* max # of ticks to sleep */
265static DECLARE_WAIT_QUEUE_HEAD(waitq);
266static void sleep_timer(unsigned long data);
267static DEFINE_TIMER(delay_timer, sleep_timer, 0, 0);
268static DEFINE_SPINLOCK(optcd_lock);
269static struct request_queue *opt_queue;
270
271/* Timer routine: wake up when desired flag goes low,
272 or when timeout expires. */
273static void sleep_timer(unsigned long data)
274{
275 int flags = inb(STATUS_PORT) & FL_STDT;
276
277 if (flags == FL_STDT && --sleep_timeout > 0) {
278 mod_timer(&delay_timer, jiffies + HZ/100); /* multi-statement macro */
279 } else
280 wake_up(&waitq);
281}
282
283
284/* Sleep until FLAG goes low. Return 0 on timeout or wrong flag low. */
285static int sleep_flag_low(int flag, unsigned long timeout)
286{
287 int flag_high;
288
289 DEBUG((DEBUG_DRIVE_IF, "sleep_flag_low"));
290
291 sleep_timeout = timeout;
292 flag_high = inb(STATUS_PORT) & flag;
293 if (flag_high && sleep_timeout > 0) {
294 mod_timer(&delay_timer, jiffies + HZ/100);
295 sleep_on(&waitq);
296 flag_high = inb(STATUS_PORT) & flag;
297 }
298
299 DEBUG((DEBUG_DRIVE_IF, "flag 0x%x count %ld%s",
300 flag, timeout, flag_high ? " timeout" : ""));
301 return !flag_high;
302}
303
304/* Low level drive interface. Only here we do actual I/O
305 Sending commands and parameters */
306
307
308/* Errors in the command protocol */
309#define ERR_IF_CMD_TIMEOUT 0x100
310#define ERR_IF_ERR_TIMEOUT 0x101
311#define ERR_IF_RESP_TIMEOUT 0x102
312#define ERR_IF_DATA_TIMEOUT 0x103
313#define ERR_IF_NOSTAT 0x104
314
315
316/* Send command code. Return <0 indicates error */
317static int send_cmd(int cmd)
318{
319 unsigned char ack;
320
321 DEBUG((DEBUG_DRIVE_IF, "sending command 0x%02x\n", cmd));
322
323 outb(HCON_DTS, HCON_PORT); /* Enable Suspend Data Transfer */
324 outb(cmd, COMIN_PORT); /* Send command code */
325 if (!flag_low(FL_STEN, BUSY_TIMEOUT)) /* Wait for status */
326 return -ERR_IF_CMD_TIMEOUT;
327 ack = inb(DATA_PORT); /* read command acknowledge */
328 outb(HCON_SDRQB, HCON_PORT); /* Disable Suspend Data Transfer */
329 return ack==ST_OP_OK ? 0 : -ack;
330}
331
332
333/* Send command parameters. Return <0 indicates error */
334static int send_params(struct cdrom_msf *params)
335{
336 unsigned char ack;
337
338 DEBUG((DEBUG_DRIVE_IF, "sending parameters"
339 " %02x:%02x:%02x"
340 " %02x:%02x:%02x",
341 params->cdmsf_min0,
342 params->cdmsf_sec0,
343 params->cdmsf_frame0,
344 params->cdmsf_min1,
345 params->cdmsf_sec1,
346 params->cdmsf_frame1));
347
348 outb(params->cdmsf_min0, COMIN_PORT);
349 outb(params->cdmsf_sec0, COMIN_PORT);
350 outb(params->cdmsf_frame0, COMIN_PORT);
351 outb(params->cdmsf_min1, COMIN_PORT);
352 outb(params->cdmsf_sec1, COMIN_PORT);
353 outb(params->cdmsf_frame1, COMIN_PORT);
354 if (!flag_low(FL_STEN, BUSY_TIMEOUT)) /* Wait for status */
355 return -ERR_IF_CMD_TIMEOUT;
356 ack = inb(DATA_PORT); /* read command acknowledge */
357 return ack==ST_PA_OK ? 0 : -ack;
358}
359
360
361/* Send parameters for SEEK command. Return <0 indicates error */
362static int send_seek_params(struct cdrom_msf *params)
363{
364 unsigned char ack;
365
366 DEBUG((DEBUG_DRIVE_IF, "sending seek parameters"
367 " %02x:%02x:%02x",
368 params->cdmsf_min0,
369 params->cdmsf_sec0,
370 params->cdmsf_frame0));
371
372 outb(params->cdmsf_min0, COMIN_PORT);
373 outb(params->cdmsf_sec0, COMIN_PORT);
374 outb(params->cdmsf_frame0, COMIN_PORT);
375 if (!flag_low(FL_STEN, BUSY_TIMEOUT)) /* Wait for status */
376 return -ERR_IF_CMD_TIMEOUT;
377 ack = inb(DATA_PORT); /* read command acknowledge */
378 return ack==ST_PA_OK ? 0 : -ack;
379}
380
381
382/* Wait for command execution status. Choice between busy waiting
383 and sleeping. Return value <0 indicates timeout. */
384static inline int get_exec_status(int busy_waiting)
385{
386 unsigned char exec_status;
387
388 if (busy_waiting
389 ? !flag_low(FL_STEN, BUSY_TIMEOUT)
390 : !sleep_flag_low(FL_STEN, SLEEP_TIMEOUT))
391 return -ERR_IF_CMD_TIMEOUT;
392
393 exec_status = inb(DATA_PORT);
394 DEBUG((DEBUG_DRIVE_IF, "returned exec status 0x%02x", exec_status));
395 return exec_status;
396}
397
398
399/* Wait busy for extra byte of data that a command returns.
400 Return value <0 indicates timeout. */
401static inline int get_data(int short_timeout)
402{
403 unsigned char data;
404
405 if (!flag_low(FL_STEN, short_timeout ? FAST_TIMEOUT : BUSY_TIMEOUT))
406 return -ERR_IF_DATA_TIMEOUT;
407
408 data = inb(DATA_PORT);
409 DEBUG((DEBUG_DRIVE_IF, "returned data 0x%02x", data));
410 return data;
411}
412
413
414/* Returns 0 if failed */
415static int reset_drive(void)
416{
417 unsigned long count = 0;
418 int flags;
419
420 DEBUG((DEBUG_DRIVE_IF, "reset drive"));
421
422 outb(0, RESET_PORT);
423 while (++count < RESET_WAIT)
424 inb(DATA_PORT);
425
426 count = 0;
427 while ((flags = (inb(STATUS_PORT) & FL_RESET)) != FL_RESET)
428 if (++count >= BUSY_TIMEOUT)
429 break;
430
431 DEBUG((DEBUG_DRIVE_IF, "reset %s",
432 flags == FL_RESET ? "succeeded" : "failed"));
433
434 if (flags != FL_RESET)
435 return 0; /* Reset failed */
436 outb(HCON_SDRQB, HCON_PORT); /* Disable Suspend Data Transfer */
437 return 1; /* Reset succeeded */
438}
439
440
441/* Facilities for asynchronous operation */
442
443/* Read status/data availability flags FL_STEN and FL_DTEN */
444static inline int stdt_flags(void)
445{
446 return inb(STATUS_PORT) & FL_STDT;
447}
448
449
450/* Fetch status that has previously been waited for. <0 means not available */
451static inline int fetch_status(void)
452{
453 unsigned char status;
454
455 if (inb(STATUS_PORT) & FL_STEN)
456 return -ERR_IF_NOSTAT;
457
458 status = inb(DATA_PORT);
459 DEBUG((DEBUG_DRIVE_IF, "fetched exec status 0x%02x", status));
460 return status;
461}
462
463
464/* Fetch data that has previously been waited for. */
465static inline void fetch_data(char *buf, int n)
466{
467 insb(DATA_PORT, buf, n);
468 DEBUG((DEBUG_DRIVE_IF, "fetched 0x%x bytes", n));
469}
470
471
472/* Flush status and data fifos */
473static inline void flush_data(void)
474{
475 while ((inb(STATUS_PORT) & FL_STDT) != FL_STDT)
476 inb(DATA_PORT);
477 DEBUG((DEBUG_DRIVE_IF, "flushed fifos"));
478}
479
480/* Command protocol */
481
482
483/* Send a simple command and wait for response. Command codes < COMFETCH
484 are quick response commands */
485static inline int exec_cmd(int cmd)
486{
487 int ack = send_cmd(cmd);
488 if (ack < 0)
489 return ack;
490 return get_exec_status(cmd < COMFETCH);
491}
492
493
494/* Send a command with parameters. Don't wait for the response,
495 * which consists of data blocks read from the CD. */
496static inline int exec_read_cmd(int cmd, struct cdrom_msf *params)
497{
498 int ack = send_cmd(cmd);
499 if (ack < 0)
500 return ack;
501 return send_params(params);
502}
503
504
505/* Send a seek command with parameters and wait for response */
506static inline int exec_seek_cmd(int cmd, struct cdrom_msf *params)
507{
508 int ack = send_cmd(cmd);
509 if (ack < 0)
510 return ack;
511 ack = send_seek_params(params);
512 if (ack < 0)
513 return ack;
514 return 0;
515}
516
517
518/* Send a command with parameters and wait for response */
519static inline int exec_long_cmd(int cmd, struct cdrom_msf *params)
520{
521 int ack = exec_read_cmd(cmd, params);
522 if (ack < 0)
523 return ack;
524 return get_exec_status(0);
525}
526
527/* Address conversion routines */
528
529
530/* Binary to BCD (2 digits) */
531static inline void single_bin2bcd(u_char *p)
532{
533 DEBUG((DEBUG_CONV, "bin2bcd %02d", *p));
534 *p = (*p % 10) | ((*p / 10) << 4);
535}
536
537
538/* Convert entire msf struct */
539static void bin2bcd(struct cdrom_msf *msf)
540{
541 single_bin2bcd(&msf->cdmsf_min0);
542 single_bin2bcd(&msf->cdmsf_sec0);
543 single_bin2bcd(&msf->cdmsf_frame0);
544 single_bin2bcd(&msf->cdmsf_min1);
545 single_bin2bcd(&msf->cdmsf_sec1);
546 single_bin2bcd(&msf->cdmsf_frame1);
547}
548
549
550/* Linear block address to minute, second, frame form */
551#define CD_FPM (CD_SECS * CD_FRAMES) /* frames per minute */
552
553static void lba2msf(int lba, struct cdrom_msf *msf)
554{
555 DEBUG((DEBUG_CONV, "lba2msf %d", lba));
556 lba += CD_MSF_OFFSET;
557 msf->cdmsf_min0 = lba / CD_FPM; lba %= CD_FPM;
558 msf->cdmsf_sec0 = lba / CD_FRAMES;
559 msf->cdmsf_frame0 = lba % CD_FRAMES;
560 msf->cdmsf_min1 = 0;
561 msf->cdmsf_sec1 = 0;
562 msf->cdmsf_frame1 = 0;
563 bin2bcd(msf);
564}
565
566
567/* Two BCD digits to binary */
568static inline u_char bcd2bin(u_char bcd)
569{
570 DEBUG((DEBUG_CONV, "bcd2bin %x%02x", bcd));
571 return (bcd >> 4) * 10 + (bcd & 0x0f);
572}
573
574
575static void msf2lba(union cdrom_addr *addr)
576{
577 addr->lba = addr->msf.minute * CD_FPM
578 + addr->msf.second * CD_FRAMES
579 + addr->msf.frame - CD_MSF_OFFSET;
580}
581
582
583/* Minute, second, frame address BCD to binary or to linear address,
584 depending on MODE */
585static void msf_bcd2bin(union cdrom_addr *addr)
586{
587 addr->msf.minute = bcd2bin(addr->msf.minute);
588 addr->msf.second = bcd2bin(addr->msf.second);
589 addr->msf.frame = bcd2bin(addr->msf.frame);
590}
591
592/* High level drive commands */
593
594
595static int audio_status = CDROM_AUDIO_NO_STATUS;
596static char toc_uptodate = 0;
597static char disk_changed = 1;
598
599/* Get drive status, flagging completion of audio play and disk changes. */
600static int drive_status(void)
601{
602 int status;
603
604 status = exec_cmd(COMIOCTLISTAT);
605 DEBUG((DEBUG_DRIVE_IF, "IOCTLISTAT: %03x", status));
606 if (status < 0)
607 return status;
608 if (status == 0xff) /* No status available */
609 return -ERR_IF_NOSTAT;
610
611 if (((status & ST_MODE_BITS) != ST_M_AUDIO) &&
612 (audio_status == CDROM_AUDIO_PLAY)) {
613 audio_status = CDROM_AUDIO_COMPLETED;
614 }
615
616 if (status & ST_DSK_CHG) {
617 toc_uptodate = 0;
618 disk_changed = 1;
619 audio_status = CDROM_AUDIO_NO_STATUS;
620 }
621
622 return status;
623}
624
625
626/* Read the current Q-channel info. Also used for reading the
627 table of contents. qp->cdsc_format must be set on entry to
628 indicate the desired address format */
629static int get_q_channel(struct cdrom_subchnl *qp)
630{
631 int status, d1, d2, d3, d4, d5, d6, d7, d8, d9, d10;
632
633 status = drive_status();
634 if (status < 0)
635 return status;
636 qp->cdsc_audiostatus = audio_status;
637
638 status = exec_cmd(COMSUBQ);
639 if (status < 0)
640 return status;
641
642 d1 = get_data(0);
643 if (d1 < 0)
644 return d1;
645 qp->cdsc_adr = d1;
646 qp->cdsc_ctrl = d1 >> 4;
647
648 d2 = get_data(0);
649 if (d2 < 0)
650 return d2;
651 qp->cdsc_trk = bcd2bin(d2);
652
653 d3 = get_data(0);
654 if (d3 < 0)
655 return d3;
656 qp->cdsc_ind = bcd2bin(d3);
657
658 d4 = get_data(0);
659 if (d4 < 0)
660 return d4;
661 qp->cdsc_reladdr.msf.minute = d4;
662
663 d5 = get_data(0);
664 if (d5 < 0)
665 return d5;
666 qp->cdsc_reladdr.msf.second = d5;
667
668 d6 = get_data(0);
669 if (d6 < 0)
670 return d6;
671 qp->cdsc_reladdr.msf.frame = d6;
672
673 d7 = get_data(0);
674 if (d7 < 0)
675 return d7;
676 /* byte not used */
677
678 d8 = get_data(0);
679 if (d8 < 0)
680 return d8;
681 qp->cdsc_absaddr.msf.minute = d8;
682
683 d9 = get_data(0);
684 if (d9 < 0)
685 return d9;
686 qp->cdsc_absaddr.msf.second = d9;
687
688 d10 = get_data(0);
689 if (d10 < 0)
690 return d10;
691 qp->cdsc_absaddr.msf.frame = d10;
692
693 DEBUG((DEBUG_TOC, "%02x %02x %02x %02x %02x %02x %02x %02x %02x %02x",
694 d1, d2, d3, d4, d5, d6, d7, d8, d9, d10));
695
696 msf_bcd2bin(&qp->cdsc_absaddr);
697 msf_bcd2bin(&qp->cdsc_reladdr);
698 if (qp->cdsc_format == CDROM_LBA) {
699 msf2lba(&qp->cdsc_absaddr);
700 msf2lba(&qp->cdsc_reladdr);
701 }
702
703 return 0;
704}
705
706/* Table of contents handling */
707
708
709/* Errors in table of contents */
710#define ERR_TOC_MISSINGINFO 0x120
711#define ERR_TOC_MISSINGENTRY 0x121
712
713
714struct cdrom_disk_info {
715 unsigned char first;
716 unsigned char last;
717 struct cdrom_msf0 disk_length;
718 struct cdrom_msf0 first_track;
719 /* Multisession info: */
720 unsigned char next;
721 struct cdrom_msf0 next_session;
722 struct cdrom_msf0 last_session;
723 unsigned char multi;
724 unsigned char xa;
725 unsigned char audio;
726};
727static struct cdrom_disk_info disk_info;
728
729#define MAX_TRACKS 111
730static struct cdrom_subchnl toc[MAX_TRACKS];
731
732#define QINFO_FIRSTTRACK 100 /* bcd2bin(0xa0) */
733#define QINFO_LASTTRACK 101 /* bcd2bin(0xa1) */
734#define QINFO_DISKLENGTH 102 /* bcd2bin(0xa2) */
735#define QINFO_NEXTSESSION 110 /* bcd2bin(0xb0) */
736
737#define I_FIRSTTRACK 0x01
738#define I_LASTTRACK 0x02
739#define I_DISKLENGTH 0x04
740#define I_NEXTSESSION 0x08
741#define I_ALL (I_FIRSTTRACK | I_LASTTRACK | I_DISKLENGTH)
742
743
744#if DEBUG_TOC
745static void toc_debug_info(int i)
746{
747 printk(KERN_DEBUG "#%3d ctl %1x, adr %1x, track %2d index %3d"
748 " %2d:%02d.%02d %2d:%02d.%02d\n",
749 i, toc[i].cdsc_ctrl, toc[i].cdsc_adr,
750 toc[i].cdsc_trk, toc[i].cdsc_ind,
751 toc[i].cdsc_reladdr.msf.minute,
752 toc[i].cdsc_reladdr.msf.second,
753 toc[i].cdsc_reladdr.msf.frame,
754 toc[i].cdsc_absaddr.msf.minute,
755 toc[i].cdsc_absaddr.msf.second,
756 toc[i].cdsc_absaddr.msf.frame);
757}
758#endif
759
760
761static int read_toc(void)
762{
763 int status, limit, count;
764 unsigned char got_info = 0;
765 struct cdrom_subchnl q_info;
766#if DEBUG_TOC
767 int i;
768#endif
769
770 DEBUG((DEBUG_TOC, "starting read_toc"));
771
772 count = 0;
773 for (limit = 60; limit > 0; limit--) {
774 int index;
775
776 q_info.cdsc_format = CDROM_MSF;
777 status = get_q_channel(&q_info);
778 if (status < 0)
779 return status;
780
781 index = q_info.cdsc_ind;
782 if (index > 0 && index < MAX_TRACKS
783 && q_info.cdsc_trk == 0 && toc[index].cdsc_ind == 0) {
784 toc[index] = q_info;
785 DEBUG((DEBUG_TOC, "got %d", index));
786 if (index < 100)
787 count++;
788
789 switch (q_info.cdsc_ind) {
790 case QINFO_FIRSTTRACK:
791 got_info |= I_FIRSTTRACK;
792 break;
793 case QINFO_LASTTRACK:
794 got_info |= I_LASTTRACK;
795 break;
796 case QINFO_DISKLENGTH:
797 got_info |= I_DISKLENGTH;
798 break;
799 case QINFO_NEXTSESSION:
800 got_info |= I_NEXTSESSION;
801 break;
802 }
803 }
804
805 if ((got_info & I_ALL) == I_ALL
806 && toc[QINFO_FIRSTTRACK].cdsc_absaddr.msf.minute + count
807 >= toc[QINFO_LASTTRACK].cdsc_absaddr.msf.minute + 1)
808 break;
809 }
810
811 /* Construct disk_info from TOC */
812 if (disk_info.first == 0) {
813 disk_info.first = toc[QINFO_FIRSTTRACK].cdsc_absaddr.msf.minute;
814 disk_info.first_track.minute =
815 toc[disk_info.first].cdsc_absaddr.msf.minute;
816 disk_info.first_track.second =
817 toc[disk_info.first].cdsc_absaddr.msf.second;
818 disk_info.first_track.frame =
819 toc[disk_info.first].cdsc_absaddr.msf.frame;
820 }
821 disk_info.last = toc[QINFO_LASTTRACK].cdsc_absaddr.msf.minute;
822 disk_info.disk_length.minute =
823 toc[QINFO_DISKLENGTH].cdsc_absaddr.msf.minute;
824 disk_info.disk_length.second =
825 toc[QINFO_DISKLENGTH].cdsc_absaddr.msf.second-2;
826 disk_info.disk_length.frame =
827 toc[QINFO_DISKLENGTH].cdsc_absaddr.msf.frame;
828 disk_info.next_session.minute =
829 toc[QINFO_NEXTSESSION].cdsc_reladdr.msf.minute;
830 disk_info.next_session.second =
831 toc[QINFO_NEXTSESSION].cdsc_reladdr.msf.second;
832 disk_info.next_session.frame =
833 toc[QINFO_NEXTSESSION].cdsc_reladdr.msf.frame;
834 disk_info.next = toc[QINFO_FIRSTTRACK].cdsc_absaddr.msf.minute;
835 disk_info.last_session.minute =
836 toc[disk_info.next].cdsc_absaddr.msf.minute;
837 disk_info.last_session.second =
838 toc[disk_info.next].cdsc_absaddr.msf.second;
839 disk_info.last_session.frame =
840 toc[disk_info.next].cdsc_absaddr.msf.frame;
841 toc[disk_info.last + 1].cdsc_absaddr.msf.minute =
842 disk_info.disk_length.minute;
843 toc[disk_info.last + 1].cdsc_absaddr.msf.second =
844 disk_info.disk_length.second;
845 toc[disk_info.last + 1].cdsc_absaddr.msf.frame =
846 disk_info.disk_length.frame;
847#if DEBUG_TOC
848 for (i = 1; i <= disk_info.last + 1; i++)
849 toc_debug_info(i);
850 toc_debug_info(QINFO_FIRSTTRACK);
851 toc_debug_info(QINFO_LASTTRACK);
852 toc_debug_info(QINFO_DISKLENGTH);
853 toc_debug_info(QINFO_NEXTSESSION);
854#endif
855
856 DEBUG((DEBUG_TOC, "exiting read_toc, got_info %x, count %d",
857 got_info, count));
858 if ((got_info & I_ALL) != I_ALL
859 || toc[QINFO_FIRSTTRACK].cdsc_absaddr.msf.minute + count
860 < toc[QINFO_LASTTRACK].cdsc_absaddr.msf.minute + 1)
861 return -ERR_TOC_MISSINGINFO;
862 return 0;
863}
864
865
866#ifdef MULTISESSION
867static int get_multi_disk_info(void)
868{
869 int sessions, status;
870 struct cdrom_msf multi_index;
871
872
873 for (sessions = 2; sessions < 10 /* %%for now */; sessions++) {
874 int count;
875
876 for (count = 100; count < MAX_TRACKS; count++)
877 toc[count].cdsc_ind = 0;
878
879 multi_index.cdmsf_min0 = disk_info.next_session.minute;
880 multi_index.cdmsf_sec0 = disk_info.next_session.second;
881 multi_index.cdmsf_frame0 = disk_info.next_session.frame;
882 if (multi_index.cdmsf_sec0 >= 20)
883 multi_index.cdmsf_sec0 -= 20;
884 else {
885 multi_index.cdmsf_sec0 += 40;
886 multi_index.cdmsf_min0--;
887 }
888 DEBUG((DEBUG_MULTIS, "Try %d: %2d:%02d.%02d", sessions,
889 multi_index.cdmsf_min0,
890 multi_index.cdmsf_sec0,
891 multi_index.cdmsf_frame0));
892 bin2bcd(&multi_index);
893 multi_index.cdmsf_min1 = 0;
894 multi_index.cdmsf_sec1 = 0;
895 multi_index.cdmsf_frame1 = 1;
896
897 status = exec_read_cmd(COMREAD, &multi_index);
898 if (status < 0) {
899 DEBUG((DEBUG_TOC, "exec_read_cmd COMREAD: %02x",
900 -status));
901 break;
902 }
903 status = sleep_flag_low(FL_DTEN, MULTI_SEEK_TIMEOUT) ?
904 0 : -ERR_TOC_MISSINGINFO;
905 flush_data();
906 if (status < 0) {
907 DEBUG((DEBUG_TOC, "sleep_flag_low: %02x", -status));
908 break;
909 }
910
911 status = read_toc();
912 if (status < 0) {
913 DEBUG((DEBUG_TOC, "read_toc: %02x", -status));
914 break;
915 }
916
917 disk_info.multi = 1;
918 }
919
920 exec_cmd(COMSTOP);
921
922 if (status < 0)
923 return -EIO;
924 return 0;
925}
926#endif /* MULTISESSION */
927
928
929static int update_toc(void)
930{
931 int status, count;
932
933 if (toc_uptodate)
934 return 0;
935
936 DEBUG((DEBUG_TOC, "starting update_toc"));
937
938 disk_info.first = 0;
939 for (count = 0; count < MAX_TRACKS; count++)
940 toc[count].cdsc_ind = 0;
941
942 status = exec_cmd(COMLEADIN);
943 if (status < 0)
944 return -EIO;
945
946 status = read_toc();
947 if (status < 0) {
948 DEBUG((DEBUG_TOC, "read_toc: %02x", -status));
949 return -EIO;
950 }
951
952 /* Audio disk detection. Look at first track. */
953 disk_info.audio =
954 (toc[disk_info.first].cdsc_ctrl & CDROM_DATA_TRACK) ? 0 : 1;
955
956 /* XA detection */
957 disk_info.xa = drive_status() & ST_MODE2TRACK;
958
959 /* Multisession detection: if we want this, define MULTISESSION */
960 disk_info.multi = 0;
961#ifdef MULTISESSION
962 if (disk_info.xa)
963 get_multi_disk_info(); /* Here disk_info.multi is set */
964#endif /* MULTISESSION */
965 if (disk_info.multi)
966 printk(KERN_WARNING "optcd: Multisession support experimental, "
967 "see Documentation/cdrom/optcd\n");
968
969 DEBUG((DEBUG_TOC, "exiting update_toc"));
970
971 toc_uptodate = 1;
972 return 0;
973}
974
975/* Request handling */
976
977static int current_valid(void)
978{
979 return CURRENT &&
980 rq_data_dir(CURRENT) == READ &&
981 CURRENT->sector != -1;
982}
983
984/* Buffers for block size conversion. */
985#define NOBUF -1
986
987static char buf[CD_FRAMESIZE * N_BUFS];
988static volatile int buf_bn[N_BUFS], next_bn;
989static volatile int buf_in = 0, buf_out = NOBUF;
990
991static inline void opt_invalidate_buffers(void)
992{
993 int i;
994
995 DEBUG((DEBUG_BUFFERS, "executing opt_invalidate_buffers"));
996
997 for (i = 0; i < N_BUFS; i++)
998 buf_bn[i] = NOBUF;
999 buf_out = NOBUF;
1000}
1001
1002
1003/* Take care of the different block sizes between cdrom and Linux.
1004 When Linux gets variable block sizes this will probably go away. */
1005static void transfer(void)
1006{
1007#if DEBUG_BUFFERS | DEBUG_REQUEST
1008 printk(KERN_DEBUG "optcd: executing transfer\n");
1009#endif
1010
1011 if (!current_valid())
1012 return;
1013 while (CURRENT -> nr_sectors) {
1014 int bn = CURRENT -> sector / 4;
1015 int i, offs, nr_sectors;
1016 for (i = 0; i < N_BUFS && buf_bn[i] != bn; ++i);
1017
1018 DEBUG((DEBUG_REQUEST, "found %d", i));
1019
1020 if (i >= N_BUFS) {
1021 buf_out = NOBUF;
1022 break;
1023 }
1024
1025 offs = (i * 4 + (CURRENT -> sector & 3)) * 512;
1026 nr_sectors = 4 - (CURRENT -> sector & 3);
1027
1028 if (buf_out != i) {
1029 buf_out = i;
1030 if (buf_bn[i] != bn) {
1031 buf_out = NOBUF;
1032 continue;
1033 }
1034 }
1035
1036 if (nr_sectors > CURRENT -> nr_sectors)
1037 nr_sectors = CURRENT -> nr_sectors;
1038 memcpy(CURRENT -> buffer, buf + offs, nr_sectors * 512);
1039 CURRENT -> nr_sectors -= nr_sectors;
1040 CURRENT -> sector += nr_sectors;
1041 CURRENT -> buffer += nr_sectors * 512;
1042 }
1043}
1044
1045
1046/* State machine for reading disk blocks */
1047
1048enum state_e {
1049 S_IDLE, /* 0 */
1050 S_START, /* 1 */
1051 S_READ, /* 2 */
1052 S_DATA, /* 3 */
1053 S_STOP, /* 4 */
1054 S_STOPPING /* 5 */
1055};
1056
1057static volatile enum state_e state = S_IDLE;
1058#if DEBUG_STATE
1059static volatile enum state_e state_old = S_STOP;
1060static volatile int flags_old = 0;
1061static volatile long state_n = 0;
1062#endif
1063
1064
1065/* Used as mutex to keep do_optcd_request (and other processes calling
1066 ioctl) out while some process is inside a VFS call.
1067 Reverse is accomplished by checking if state = S_IDLE upon entry
1068 of opt_ioctl and opt_media_change. */
1069static int in_vfs = 0;
1070
1071
1072static volatile int transfer_is_active = 0;
1073static volatile int error = 0; /* %% do something with this?? */
1074static int tries; /* ibid?? */
1075static int timeout = 0;
1076
1077static void poll(unsigned long data);
1078static struct timer_list req_timer = {.function = poll};
1079
1080
1081static void poll(unsigned long data)
1082{
1083 static volatile int read_count = 1;
1084 int flags;
1085 int loop_again = 1;
1086 int status = 0;
1087 int skip = 0;
1088
1089 if (error) {
1090 printk(KERN_ERR "optcd: I/O error 0x%02x\n", error);
1091 opt_invalidate_buffers();
1092 if (!tries--) {
1093 printk(KERN_ERR "optcd: read block %d failed;"
1094 " Giving up\n", next_bn);
1095 if (transfer_is_active)
1096 loop_again = 0;
1097 if (current_valid())
1098 end_request(CURRENT, 0);
1099 tries = 5;
1100 }
1101 error = 0;
1102 state = S_STOP;
1103 }
1104
1105 while (loop_again)
1106 {
1107 loop_again = 0; /* each case must flip this back to 1 if we want
1108 to come back up here */
1109
1110#if DEBUG_STATE
1111 if (state == state_old)
1112 state_n++;
1113 else {
1114 state_old = state;
1115 if (++state_n > 1)
1116 printk(KERN_DEBUG "optcd: %ld times "
1117 "in previous state\n", state_n);
1118 printk(KERN_DEBUG "optcd: state %d\n", state);
1119 state_n = 0;
1120 }
1121#endif
1122
1123 switch (state) {
1124 case S_IDLE:
1125 return;
1126 case S_START:
1127 if (in_vfs)
1128 break;
1129 if (send_cmd(COMDRVST)) {
1130 state = S_IDLE;
1131 while (current_valid())
1132 end_request(CURRENT, 0);
1133 return;
1134 }
1135 state = S_READ;
1136 timeout = READ_TIMEOUT;
1137 break;
1138 case S_READ: {
1139 struct cdrom_msf msf;
1140 if (!skip) {
1141 status = fetch_status();
1142 if (status < 0)
1143 break;
1144 if (status & ST_DSK_CHG) {
1145 toc_uptodate = 0;
1146 opt_invalidate_buffers();
1147 }
1148 }
1149 skip = 0;
1150 if ((status & ST_DOOR_OPEN) || (status & ST_DRVERR)) {
1151 toc_uptodate = 0;
1152 opt_invalidate_buffers();
1153 printk(KERN_WARNING "optcd: %s\n",
1154 (status & ST_DOOR_OPEN)
1155 ? "door open"
1156 : "disk removed");
1157 state = S_IDLE;
1158 while (current_valid())
1159 end_request(CURRENT, 0);
1160 return;
1161 }
1162 if (!current_valid()) {
1163 state = S_STOP;
1164 loop_again = 1;
1165 break;
1166 }
1167 next_bn = CURRENT -> sector / 4;
1168 lba2msf(next_bn, &msf);
1169 read_count = N_BUFS;
1170 msf.cdmsf_frame1 = read_count; /* Not BCD! */
1171
1172 DEBUG((DEBUG_REQUEST, "reading %x:%x.%x %x:%x.%x",
1173 msf.cdmsf_min0,
1174 msf.cdmsf_sec0,
1175 msf.cdmsf_frame0,
1176 msf.cdmsf_min1,
1177 msf.cdmsf_sec1,
1178 msf.cdmsf_frame1));
1179 DEBUG((DEBUG_REQUEST, "next_bn:%d buf_in:%d"
1180 " buf_out:%d buf_bn:%d",
1181 next_bn,
1182 buf_in,
1183 buf_out,
1184 buf_bn[buf_in]));
1185
1186 exec_read_cmd(COMREAD, &msf);
1187 state = S_DATA;
1188 timeout = READ_TIMEOUT;
1189 break;
1190 }
1191 case S_DATA:
1192 flags = stdt_flags() & (FL_STEN|FL_DTEN);
1193
1194#if DEBUG_STATE
1195 if (flags != flags_old) {
1196 flags_old = flags;
1197 printk(KERN_DEBUG "optcd: flags:%x\n", flags);
1198 }
1199 if (flags == FL_STEN)
1200 printk(KERN_DEBUG "timeout cnt: %d\n", timeout);
1201#endif
1202
1203 switch (flags) {
1204 case FL_DTEN: /* only STEN low */
1205 if (!tries--) {
1206 printk(KERN_ERR
1207 "optcd: read block %d failed; "
1208 "Giving up\n", next_bn);
1209 if (transfer_is_active) {
1210 tries = 0;
1211 break;
1212 }
1213 if (current_valid())
1214 end_request(CURRENT, 0);
1215 tries = 5;
1216 }
1217 state = S_START;
1218 timeout = READ_TIMEOUT;
1219 loop_again = 1;
1220 case (FL_STEN|FL_DTEN): /* both high */
1221 break;
1222 default: /* DTEN low */
1223 tries = 5;
1224 if (!current_valid() && buf_in == buf_out) {
1225 state = S_STOP;
1226 loop_again = 1;
1227 break;
1228 }
1229 if (read_count<=0)
1230 printk(KERN_WARNING
1231 "optcd: warning - try to read"
1232 " 0 frames\n");
1233 while (read_count) {
1234 buf_bn[buf_in] = NOBUF;
1235 if (!flag_low(FL_DTEN, BUSY_TIMEOUT)) {
1236 /* should be no waiting here!?? */
1237 printk(KERN_ERR
1238 "read_count:%d "
1239 "CURRENT->nr_sectors:%ld "
1240 "buf_in:%d\n",
1241 read_count,
1242 CURRENT->nr_sectors,
1243 buf_in);
1244 printk(KERN_ERR
1245 "transfer active: %x\n",
1246 transfer_is_active);
1247 read_count = 0;
1248 state = S_STOP;
1249 loop_again = 1;
1250 end_request(CURRENT, 0);
1251 break;
1252 }
1253 fetch_data(buf+
1254 CD_FRAMESIZE*buf_in,
1255 CD_FRAMESIZE);
1256 read_count--;
1257
1258 DEBUG((DEBUG_REQUEST,
1259 "S_DATA; ---I've read data- "
1260 "read_count: %d",
1261 read_count));
1262 DEBUG((DEBUG_REQUEST,
1263 "next_bn:%d buf_in:%d "
1264 "buf_out:%d buf_bn:%d",
1265 next_bn,
1266 buf_in,
1267 buf_out,
1268 buf_bn[buf_in]));
1269
1270 buf_bn[buf_in] = next_bn++;
1271 if (buf_out == NOBUF)
1272 buf_out = buf_in;
1273 buf_in = buf_in + 1 ==
1274 N_BUFS ? 0 : buf_in + 1;
1275 }
1276 if (!transfer_is_active) {
1277 while (current_valid()) {
1278 transfer();
1279 if (CURRENT -> nr_sectors == 0)
1280 end_request(CURRENT, 1);
1281 else
1282 break;
1283 }
1284 }
1285
1286 if (current_valid()
1287 && (CURRENT -> sector / 4 < next_bn ||
1288 CURRENT -> sector / 4 >
1289 next_bn + N_BUFS)) {
1290 state = S_STOP;
1291 loop_again = 1;
1292 break;
1293 }
1294 timeout = READ_TIMEOUT;
1295 if (read_count == 0) {
1296 state = S_STOP;
1297 loop_again = 1;
1298 break;
1299 }
1300 }
1301 break;
1302 case S_STOP:
1303 if (read_count != 0)
1304 printk(KERN_ERR
1305 "optcd: discard data=%x frames\n",
1306 read_count);
1307 flush_data();
1308 if (send_cmd(COMDRVST)) {
1309 state = S_IDLE;
1310 while (current_valid())
1311 end_request(CURRENT, 0);
1312 return;
1313 }
1314 state = S_STOPPING;
1315 timeout = STOP_TIMEOUT;
1316 break;
1317 case S_STOPPING:
1318 status = fetch_status();
1319 if (status < 0 && timeout)
1320 break;
1321 if ((status >= 0) && (status & ST_DSK_CHG)) {
1322 toc_uptodate = 0;
1323 opt_invalidate_buffers();
1324 }
1325 if (current_valid()) {
1326 if (status >= 0) {
1327 state = S_READ;
1328 loop_again = 1;
1329 skip = 1;
1330 break;
1331 } else {
1332 state = S_START;
1333 timeout = 1;
1334 }
1335 } else {
1336 state = S_IDLE;
1337 return;
1338 }
1339 break;
1340 default:
1341 printk(KERN_ERR "optcd: invalid state %d\n", state);
1342 return;
1343 } /* case */
1344 } /* while */
1345
1346 if (!timeout--) {
1347 printk(KERN_ERR "optcd: timeout in state %d\n", state);
1348 state = S_STOP;
1349 if (exec_cmd(COMSTOP) < 0) {
1350 state = S_IDLE;
1351 while (current_valid())
1352 end_request(CURRENT, 0);
1353 return;
1354 }
1355 }
1356
1357 mod_timer(&req_timer, jiffies + HZ/100);
1358}
1359
1360
1361static void do_optcd_request(request_queue_t * q)
1362{
1363 DEBUG((DEBUG_REQUEST, "do_optcd_request(%ld+%ld)",
1364 CURRENT -> sector, CURRENT -> nr_sectors));
1365
1366 if (disk_info.audio) {
1367 printk(KERN_WARNING "optcd: tried to mount an Audio CD\n");
1368 end_request(CURRENT, 0);
1369 return;
1370 }
1371
1372 transfer_is_active = 1;
1373 while (current_valid()) {
1374 transfer(); /* First try to transfer block from buffers */
1375 if (CURRENT -> nr_sectors == 0) {
1376 end_request(CURRENT, 1);
1377 } else { /* Want to read a block not in buffer */
1378 buf_out = NOBUF;
1379 if (state == S_IDLE) {
1380 /* %% Should this block the request queue?? */
1381 if (update_toc() < 0) {
1382 while (current_valid())
1383 end_request(CURRENT, 0);
1384 break;
1385 }
1386 /* Start state machine */
1387 state = S_START;
1388 timeout = READ_TIMEOUT;
1389 tries = 5;
1390 /* %% why not start right away?? */
1391 mod_timer(&req_timer, jiffies + HZ/100);
1392 }
1393 break;
1394 }
1395 }
1396 transfer_is_active = 0;
1397
1398 DEBUG((DEBUG_REQUEST, "next_bn:%d buf_in:%d buf_out:%d buf_bn:%d",
1399 next_bn, buf_in, buf_out, buf_bn[buf_in]));
1400 DEBUG((DEBUG_REQUEST, "do_optcd_request ends"));
1401}
1402
1403/* IOCTLs */
1404
1405
1406static char auto_eject = 0;
1407
1408static int cdrompause(void)
1409{
1410 int status;
1411
1412 if (audio_status != CDROM_AUDIO_PLAY)
1413 return -EINVAL;
1414
1415 status = exec_cmd(COMPAUSEON);
1416 if (status < 0) {
1417 DEBUG((DEBUG_VFS, "exec_cmd COMPAUSEON: %02x", -status));
1418 return -EIO;
1419 }
1420 audio_status = CDROM_AUDIO_PAUSED;
1421 return 0;
1422}
1423
1424
1425static int cdromresume(void)
1426{
1427 int status;
1428
1429 if (audio_status != CDROM_AUDIO_PAUSED)
1430 return -EINVAL;
1431
1432 status = exec_cmd(COMPAUSEOFF);
1433 if (status < 0) {
1434 DEBUG((DEBUG_VFS, "exec_cmd COMPAUSEOFF: %02x", -status));
1435 audio_status = CDROM_AUDIO_ERROR;
1436 return -EIO;
1437 }
1438 audio_status = CDROM_AUDIO_PLAY;
1439 return 0;
1440}
1441
1442
1443static int cdromplaymsf(void __user *arg)
1444{
1445 int status;
1446 struct cdrom_msf msf;
1447
1448 if (copy_from_user(&msf, arg, sizeof msf))
1449 return -EFAULT;
1450
1451 bin2bcd(&msf);
1452 status = exec_long_cmd(COMPLAY, &msf);
1453 if (status < 0) {
1454 DEBUG((DEBUG_VFS, "exec_long_cmd COMPLAY: %02x", -status));
1455 audio_status = CDROM_AUDIO_ERROR;
1456 return -EIO;
1457 }
1458
1459 audio_status = CDROM_AUDIO_PLAY;
1460 return 0;
1461}
1462
1463
1464static int cdromplaytrkind(void __user *arg)
1465{
1466 int status;
1467 struct cdrom_ti ti;
1468 struct cdrom_msf msf;
1469
1470 if (copy_from_user(&ti, arg, sizeof ti))
1471 return -EFAULT;
1472
1473 if (ti.cdti_trk0 < disk_info.first
1474 || ti.cdti_trk0 > disk_info.last
1475 || ti.cdti_trk1 < ti.cdti_trk0)
1476 return -EINVAL;
1477 if (ti.cdti_trk1 > disk_info.last)
1478 ti.cdti_trk1 = disk_info.last;
1479
1480 msf.cdmsf_min0 = toc[ti.cdti_trk0].cdsc_absaddr.msf.minute;
1481 msf.cdmsf_sec0 = toc[ti.cdti_trk0].cdsc_absaddr.msf.second;
1482 msf.cdmsf_frame0 = toc[ti.cdti_trk0].cdsc_absaddr.msf.frame;
1483 msf.cdmsf_min1 = toc[ti.cdti_trk1 + 1].cdsc_absaddr.msf.minute;
1484 msf.cdmsf_sec1 = toc[ti.cdti_trk1 + 1].cdsc_absaddr.msf.second;
1485 msf.cdmsf_frame1 = toc[ti.cdti_trk1 + 1].cdsc_absaddr.msf.frame;
1486
1487 DEBUG((DEBUG_VFS, "play %02d:%02d.%02d to %02d:%02d.%02d",
1488 msf.cdmsf_min0,
1489 msf.cdmsf_sec0,
1490 msf.cdmsf_frame0,
1491 msf.cdmsf_min1,
1492 msf.cdmsf_sec1,
1493 msf.cdmsf_frame1));
1494
1495 bin2bcd(&msf);
1496 status = exec_long_cmd(COMPLAY, &msf);
1497 if (status < 0) {
1498 DEBUG((DEBUG_VFS, "exec_long_cmd COMPLAY: %02x", -status));
1499 audio_status = CDROM_AUDIO_ERROR;
1500 return -EIO;
1501 }
1502
1503 audio_status = CDROM_AUDIO_PLAY;
1504 return 0;
1505}
1506
1507
1508static int cdromreadtochdr(void __user *arg)
1509{
1510 struct cdrom_tochdr tochdr;
1511
1512 tochdr.cdth_trk0 = disk_info.first;
1513 tochdr.cdth_trk1 = disk_info.last;
1514
1515 return copy_to_user(arg, &tochdr, sizeof tochdr) ? -EFAULT : 0;
1516}
1517
1518
1519static int cdromreadtocentry(void __user *arg)
1520{
1521 struct cdrom_tocentry entry;
1522 struct cdrom_subchnl *tocptr;
1523
1524 if (copy_from_user(&entry, arg, sizeof entry))
1525 return -EFAULT;
1526
1527 if (entry.cdte_track == CDROM_LEADOUT)
1528 tocptr = &toc[disk_info.last + 1];
1529 else if (entry.cdte_track > disk_info.last
1530 || entry.cdte_track < disk_info.first)
1531 return -EINVAL;
1532 else
1533 tocptr = &toc[entry.cdte_track];
1534
1535 entry.cdte_adr = tocptr->cdsc_adr;
1536 entry.cdte_ctrl = tocptr->cdsc_ctrl;
1537 entry.cdte_addr.msf.minute = tocptr->cdsc_absaddr.msf.minute;
1538 entry.cdte_addr.msf.second = tocptr->cdsc_absaddr.msf.second;
1539 entry.cdte_addr.msf.frame = tocptr->cdsc_absaddr.msf.frame;
1540 /* %% What should go into entry.cdte_datamode? */
1541
1542 if (entry.cdte_format == CDROM_LBA)
1543 msf2lba(&entry.cdte_addr);
1544 else if (entry.cdte_format != CDROM_MSF)
1545 return -EINVAL;
1546
1547 return copy_to_user(arg, &entry, sizeof entry) ? -EFAULT : 0;
1548}
1549
1550
1551static int cdromvolctrl(void __user *arg)
1552{
1553 int status;
1554 struct cdrom_volctrl volctrl;
1555 struct cdrom_msf msf;
1556
1557 if (copy_from_user(&volctrl, arg, sizeof volctrl))
1558 return -EFAULT;
1559
1560 msf.cdmsf_min0 = 0x10;
1561 msf.cdmsf_sec0 = 0x32;
1562 msf.cdmsf_frame0 = volctrl.channel0;
1563 msf.cdmsf_min1 = volctrl.channel1;
1564 msf.cdmsf_sec1 = volctrl.channel2;
1565 msf.cdmsf_frame1 = volctrl.channel3;
1566
1567 status = exec_long_cmd(COMCHCTRL, &msf);
1568 if (status < 0) {
1569 DEBUG((DEBUG_VFS, "exec_long_cmd COMCHCTRL: %02x", -status));
1570 return -EIO;
1571 }
1572 return 0;
1573}
1574
1575
1576static int cdromsubchnl(void __user *arg)
1577{
1578 int status;
1579 struct cdrom_subchnl subchnl;
1580
1581 if (copy_from_user(&subchnl, arg, sizeof subchnl))
1582 return -EFAULT;
1583
1584 if (subchnl.cdsc_format != CDROM_LBA
1585 && subchnl.cdsc_format != CDROM_MSF)
1586 return -EINVAL;
1587
1588 status = get_q_channel(&subchnl);
1589 if (status < 0) {
1590 DEBUG((DEBUG_VFS, "get_q_channel: %02x", -status));
1591 return -EIO;
1592 }
1593
1594 if (copy_to_user(arg, &subchnl, sizeof subchnl))
1595 return -EFAULT;
1596 return 0;
1597}
1598
1599
1600static struct gendisk *optcd_disk;
1601
1602
1603static int cdromread(void __user *arg, int blocksize, int cmd)
1604{
1605 int status;
1606 struct cdrom_msf msf;
1607
1608 if (copy_from_user(&msf, arg, sizeof msf))
1609 return -EFAULT;
1610
1611 bin2bcd(&msf);
1612 msf.cdmsf_min1 = 0;
1613 msf.cdmsf_sec1 = 0;
1614 msf.cdmsf_frame1 = 1; /* read only one frame */
1615 status = exec_read_cmd(cmd, &msf);
1616
1617 DEBUG((DEBUG_VFS, "read cmd status 0x%x", status));
1618
1619 if (!sleep_flag_low(FL_DTEN, SLEEP_TIMEOUT))
1620 return -EIO;
1621
1622 fetch_data(optcd_disk->private_data, blocksize);
1623
1624 if (copy_to_user(arg, optcd_disk->private_data, blocksize))
1625 return -EFAULT;
1626
1627 return 0;
1628}
1629
1630
1631static int cdromseek(void __user *arg)
1632{
1633 int status;
1634 struct cdrom_msf msf;
1635
1636 if (copy_from_user(&msf, arg, sizeof msf))
1637 return -EFAULT;
1638
1639 bin2bcd(&msf);
1640 status = exec_seek_cmd(COMSEEK, &msf);
1641
1642 DEBUG((DEBUG_VFS, "COMSEEK status 0x%x", status));
1643
1644 if (status < 0)
1645 return -EIO;
1646 return 0;
1647}
1648
1649
1650#ifdef MULTISESSION
1651static int cdrommultisession(void __user *arg)
1652{
1653 struct cdrom_multisession ms;
1654
1655 if (copy_from_user(&ms, arg, sizeof ms))
1656 return -EFAULT;
1657
1658 ms.addr.msf.minute = disk_info.last_session.minute;
1659 ms.addr.msf.second = disk_info.last_session.second;
1660 ms.addr.msf.frame = disk_info.last_session.frame;
1661
1662 if (ms.addr_format != CDROM_LBA
1663 && ms.addr_format != CDROM_MSF)
1664 return -EINVAL;
1665 if (ms.addr_format == CDROM_LBA)
1666 msf2lba(&ms.addr);
1667
1668 ms.xa_flag = disk_info.xa;
1669
1670 if (copy_to_user(arg, &ms, sizeof(struct cdrom_multisession)))
1671 return -EFAULT;
1672
1673#if DEBUG_MULTIS
1674 if (ms.addr_format == CDROM_MSF)
1675 printk(KERN_DEBUG
1676 "optcd: multisession xa:%d, msf:%02d:%02d.%02d\n",
1677 ms.xa_flag,
1678 ms.addr.msf.minute,
1679 ms.addr.msf.second,
1680 ms.addr.msf.frame);
1681 else
1682 printk(KERN_DEBUG
1683 "optcd: multisession %d, lba:0x%08x [%02d:%02d.%02d])\n",
1684 ms.xa_flag,
1685 ms.addr.lba,
1686 disk_info.last_session.minute,
1687 disk_info.last_session.second,
1688 disk_info.last_session.frame);
1689#endif /* DEBUG_MULTIS */
1690
1691 return 0;
1692}
1693#endif /* MULTISESSION */
1694
1695
1696static int cdromreset(void)
1697{
1698 if (state != S_IDLE) {
1699 error = 1;
1700 tries = 0;
1701 }
1702
1703 toc_uptodate = 0;
1704 disk_changed = 1;
1705 opt_invalidate_buffers();
1706 audio_status = CDROM_AUDIO_NO_STATUS;
1707
1708 if (!reset_drive())
1709 return -EIO;
1710 return 0;
1711}
1712
1713/* VFS calls */
1714
1715
1716static int opt_ioctl(struct inode *ip, struct file *fp,
1717 unsigned int cmd, unsigned long arg)
1718{
1719 int status, err, retval = 0;
1720 void __user *argp = (void __user *)arg;
1721
1722 DEBUG((DEBUG_VFS, "starting opt_ioctl"));
1723
1724 if (!ip)
1725 return -EINVAL;
1726
1727 if (cmd == CDROMRESET)
1728 return cdromreset();
1729
1730 /* is do_optcd_request or another ioctl busy? */
1731 if (state != S_IDLE || in_vfs)
1732 return -EBUSY;
1733
1734 in_vfs = 1;
1735
1736 status = drive_status();
1737 if (status < 0) {
1738 DEBUG((DEBUG_VFS, "drive_status: %02x", -status));
1739 in_vfs = 0;
1740 return -EIO;
1741 }
1742
1743 if (status & ST_DOOR_OPEN)
1744 switch (cmd) { /* Actions that can be taken with door open */
1745 case CDROMCLOSETRAY:
1746 /* We do this before trying to read the toc. */
1747 err = exec_cmd(COMCLOSE);
1748 if (err < 0) {
1749 DEBUG((DEBUG_VFS,
1750 "exec_cmd COMCLOSE: %02x", -err));
1751 in_vfs = 0;
1752 return -EIO;
1753 }
1754 break;
1755 default: in_vfs = 0;
1756 return -EBUSY;
1757 }
1758
1759 err = update_toc();
1760 if (err < 0) {
1761 DEBUG((DEBUG_VFS, "update_toc: %02x", -err));
1762 in_vfs = 0;
1763 return -EIO;
1764 }
1765
1766 DEBUG((DEBUG_VFS, "ioctl cmd 0x%x", cmd));
1767
1768 switch (cmd) {
1769 case CDROMPAUSE: retval = cdrompause(); break;
1770 case CDROMRESUME: retval = cdromresume(); break;
1771 case CDROMPLAYMSF: retval = cdromplaymsf(argp); break;
1772 case CDROMPLAYTRKIND: retval = cdromplaytrkind(argp); break;
1773 case CDROMREADTOCHDR: retval = cdromreadtochdr(argp); break;
1774 case CDROMREADTOCENTRY: retval = cdromreadtocentry(argp); break;
1775
1776 case CDROMSTOP: err = exec_cmd(COMSTOP);
1777 if (err < 0) {
1778 DEBUG((DEBUG_VFS,
1779 "exec_cmd COMSTOP: %02x",
1780 -err));
1781 retval = -EIO;
1782 } else
1783 audio_status = CDROM_AUDIO_NO_STATUS;
1784 break;
1785 case CDROMSTART: break; /* This is a no-op */
1786 case CDROMEJECT: err = exec_cmd(COMUNLOCK);
1787 if (err < 0) {
1788 DEBUG((DEBUG_VFS,
1789 "exec_cmd COMUNLOCK: %02x",
1790 -err));
1791 retval = -EIO;
1792 break;
1793 }
1794 err = exec_cmd(COMOPEN);
1795 if (err < 0) {
1796 DEBUG((DEBUG_VFS,
1797 "exec_cmd COMOPEN: %02x",
1798 -err));
1799 retval = -EIO;
1800 }
1801 break;
1802
1803 case CDROMVOLCTRL: retval = cdromvolctrl(argp); break;
1804 case CDROMSUBCHNL: retval = cdromsubchnl(argp); break;
1805
1806 /* The drive detects the mode and automatically delivers the
1807 correct 2048 bytes, so we don't need these IOCTLs */
1808 case CDROMREADMODE2: retval = -EINVAL; break;
1809 case CDROMREADMODE1: retval = -EINVAL; break;
1810
1811 /* Drive doesn't support reading audio */
1812 case CDROMREADAUDIO: retval = -EINVAL; break;
1813
1814 case CDROMEJECT_SW: auto_eject = (char) arg;
1815 break;
1816
1817#ifdef MULTISESSION
1818 case CDROMMULTISESSION: retval = cdrommultisession(argp); break;
1819#endif
1820
1821 case CDROM_GET_MCN: retval = -EINVAL; break; /* not implemented */
1822 case CDROMVOLREAD: retval = -EINVAL; break; /* not implemented */
1823
1824 case CDROMREADRAW:
1825 /* this drive delivers 2340 bytes in raw mode */
1826 retval = cdromread(argp, CD_FRAMESIZE_RAW1, COMREADRAW);
1827 break;
1828 case CDROMREADCOOKED:
1829 retval = cdromread(argp, CD_FRAMESIZE, COMREAD);
1830 break;
1831 case CDROMREADALL:
1832 retval = cdromread(argp, CD_FRAMESIZE_RAWER, COMREADALL);
1833 break;
1834
1835 case CDROMSEEK: retval = cdromseek(argp); break;
1836 case CDROMPLAYBLK: retval = -EINVAL; break; /* not implemented */
1837 case CDROMCLOSETRAY: break; /* The action was taken earlier */
1838 default: retval = -EINVAL;
1839 }
1840 in_vfs = 0;
1841 return retval;
1842}
1843
1844
1845static int open_count = 0;
1846
1847/* Open device special file; check that a disk is in. */
1848static int opt_open(struct inode *ip, struct file *fp)
1849{
1850 DEBUG((DEBUG_VFS, "starting opt_open"));
1851
1852 if (!open_count && state == S_IDLE) {
1853 int status;
1854 char *buf;
1855
1856 buf = kmalloc(CD_FRAMESIZE_RAWER, GFP_KERNEL);
1857 if (!buf) {
1858 printk(KERN_INFO "optcd: cannot allocate read buffer\n");
1859 return -ENOMEM;
1860 }
1861 optcd_disk->private_data = buf; /* save read buffer */
1862
1863 toc_uptodate = 0;
1864 opt_invalidate_buffers();
1865
1866 status = exec_cmd(COMCLOSE); /* close door */
1867 if (status < 0) {
1868 DEBUG((DEBUG_VFS, "exec_cmd COMCLOSE: %02x", -status));
1869 }
1870
1871 status = drive_status();
1872 if (status < 0) {
1873 DEBUG((DEBUG_VFS, "drive_status: %02x", -status));
1874 goto err_out;
1875 }
1876 DEBUG((DEBUG_VFS, "status: %02x", status));
1877 if ((status & ST_DOOR_OPEN) || (status & ST_DRVERR)) {
1878 printk(KERN_INFO "optcd: no disk or door open\n");
1879 goto err_out;
1880 }
1881 status = exec_cmd(COMLOCK); /* Lock door */
1882 if (status < 0) {
1883 DEBUG((DEBUG_VFS, "exec_cmd COMLOCK: %02x", -status));
1884 }
1885 status = update_toc(); /* Read table of contents */
1886 if (status < 0) {
1887 DEBUG((DEBUG_VFS, "update_toc: %02x", -status));
1888 status = exec_cmd(COMUNLOCK); /* Unlock door */
1889 if (status < 0) {
1890 DEBUG((DEBUG_VFS,
1891 "exec_cmd COMUNLOCK: %02x", -status));
1892 }
1893 goto err_out;
1894 }
1895 open_count++;
1896 }
1897
1898 DEBUG((DEBUG_VFS, "exiting opt_open"));
1899
1900 return 0;
1901
1902err_out:
1903 return -EIO;
1904}
1905
1906
1907/* Release device special file; flush all blocks from the buffer cache */
1908static int opt_release(struct inode *ip, struct file *fp)
1909{
1910 int status;
1911
1912 DEBUG((DEBUG_VFS, "executing opt_release"));
1913 DEBUG((DEBUG_VFS, "inode: %p, device: %s, file: %p\n",
1914 ip, ip->i_bdev->bd_disk->disk_name, fp));
1915
1916 if (!--open_count) {
1917 toc_uptodate = 0;
1918 opt_invalidate_buffers();
1919 status = exec_cmd(COMUNLOCK); /* Unlock door */
1920 if (status < 0) {
1921 DEBUG((DEBUG_VFS, "exec_cmd COMUNLOCK: %02x", -status));
1922 }
1923 if (auto_eject) {
1924 status = exec_cmd(COMOPEN);
1925 DEBUG((DEBUG_VFS, "exec_cmd COMOPEN: %02x", -status));
1926 }
1927 kfree(optcd_disk->private_data);
1928 del_timer(&delay_timer);
1929 del_timer(&req_timer);
1930 }
1931 return 0;
1932}
1933
1934
1935/* Check if disk has been changed */
1936static int opt_media_change(struct gendisk *disk)
1937{
1938 DEBUG((DEBUG_VFS, "executing opt_media_change"));
1939 DEBUG((DEBUG_VFS, "dev: %s; disk_changed = %d\n",
1940 disk->disk_name, disk_changed));
1941
1942 if (disk_changed) {
1943 disk_changed = 0;
1944 return 1;
1945 }
1946 return 0;
1947}
1948
1949/* Driver initialisation */
1950
1951
1952/* Returns 1 if a drive is detected with a version string
1953 starting with "DOLPHIN". Otherwise 0. */
1954static int __init version_ok(void)
1955{
1956 char devname[100];
1957 int count, i, ch, status;
1958
1959 status = exec_cmd(COMVERSION);
1960 if (status < 0) {
1961 DEBUG((DEBUG_VFS, "exec_cmd COMVERSION: %02x", -status));
1962 return 0;
1963 }
1964 if ((count = get_data(1)) < 0) {
1965 DEBUG((DEBUG_VFS, "get_data(1): %02x", -count));
1966 return 0;
1967 }
1968 for (i = 0, ch = -1; count > 0; count--) {
1969 if ((ch = get_data(1)) < 0) {
1970 DEBUG((DEBUG_VFS, "get_data(1): %02x", -ch));
1971 break;
1972 }
1973 if (i < 99)
1974 devname[i++] = ch;
1975 }
1976 devname[i] = '\0';
1977 if (ch < 0)
1978 return 0;
1979
1980 printk(KERN_INFO "optcd: Device %s detected\n", devname);
1981 return ((devname[0] == 'D')
1982 && (devname[1] == 'O')
1983 && (devname[2] == 'L')
1984 && (devname[3] == 'P')
1985 && (devname[4] == 'H')
1986 && (devname[5] == 'I')
1987 && (devname[6] == 'N'));
1988}
1989
1990
1991static struct block_device_operations opt_fops = {
1992 .owner = THIS_MODULE,
1993 .open = opt_open,
1994 .release = opt_release,
1995 .ioctl = opt_ioctl,
1996 .media_changed = opt_media_change,
1997};
1998
1999#ifndef MODULE
2000/* Get kernel parameter when used as a kernel driver */
2001static int optcd_setup(char *str)
2002{
2003 int ints[4];
2004 (void)get_options(str, ARRAY_SIZE(ints), ints);
2005
2006 if (ints[0] > 0)
2007 optcd_port = ints[1];
2008
2009 return 1;
2010}
2011
2012__setup("optcd=", optcd_setup);
2013
2014#endif /* MODULE */
2015
2016/* Test for presence of drive and initialize it. Called at boot time
2017 or during module initialisation. */
2018static int __init optcd_init(void)
2019{
2020 int status;
2021
2022 if (optcd_port <= 0) {
2023 printk(KERN_INFO
2024 "optcd: no Optics Storage CDROM Initialization\n");
2025 return -EIO;
2026 }
2027 optcd_disk = alloc_disk(1);
2028 if (!optcd_disk) {
2029 printk(KERN_ERR "optcd: can't allocate disk\n");
2030 return -ENOMEM;
2031 }
2032 optcd_disk->major = MAJOR_NR;
2033 optcd_disk->first_minor = 0;
2034 optcd_disk->fops = &opt_fops;
2035 sprintf(optcd_disk->disk_name, "optcd");
2036
2037 if (!request_region(optcd_port, 4, "optcd")) {
2038 printk(KERN_ERR "optcd: conflict, I/O port 0x%x already used\n",
2039 optcd_port);
2040 put_disk(optcd_disk);
2041 return -EIO;
2042 }
2043
2044 if (!reset_drive()) {
2045 printk(KERN_ERR "optcd: drive at 0x%x not ready\n", optcd_port);
2046 release_region(optcd_port, 4);
2047 put_disk(optcd_disk);
2048 return -EIO;
2049 }
2050 if (!version_ok()) {
2051 printk(KERN_ERR "optcd: unknown drive detected; aborting\n");
2052 release_region(optcd_port, 4);
2053 put_disk(optcd_disk);
2054 return -EIO;
2055 }
2056 status = exec_cmd(COMINITDOUBLE);
2057 if (status < 0) {
2058 printk(KERN_ERR "optcd: cannot init double speed mode\n");
2059 release_region(optcd_port, 4);
2060 DEBUG((DEBUG_VFS, "exec_cmd COMINITDOUBLE: %02x", -status));
2061 put_disk(optcd_disk);
2062 return -EIO;
2063 }
2064 if (register_blkdev(MAJOR_NR, "optcd")) {
2065 release_region(optcd_port, 4);
2066 put_disk(optcd_disk);
2067 return -EIO;
2068 }
2069
2070
2071 opt_queue = blk_init_queue(do_optcd_request, &optcd_lock);
2072 if (!opt_queue) {
2073 unregister_blkdev(MAJOR_NR, "optcd");
2074 release_region(optcd_port, 4);
2075 put_disk(optcd_disk);
2076 return -ENOMEM;
2077 }
2078
2079 blk_queue_hardsect_size(opt_queue, 2048);
2080 optcd_disk->queue = opt_queue;
2081 add_disk(optcd_disk);
2082
2083 printk(KERN_INFO "optcd: DOLPHIN 8000 AT CDROM at 0x%x\n", optcd_port);
2084 return 0;
2085}
2086
2087
2088static void __exit optcd_exit(void)
2089{
2090 del_gendisk(optcd_disk);
2091 put_disk(optcd_disk);
2092 if (unregister_blkdev(MAJOR_NR, "optcd") == -EINVAL) {
2093 printk(KERN_ERR "optcd: what's that: can't unregister\n");
2094 return;
2095 }
2096 blk_cleanup_queue(opt_queue);
2097 release_region(optcd_port, 4);
2098 printk(KERN_INFO "optcd: module released.\n");
2099}
2100
2101module_init(optcd_init);
2102module_exit(optcd_exit);
2103
2104MODULE_LICENSE("GPL");
2105MODULE_ALIAS_BLOCKDEV_MAJOR(OPTICS_CDROM_MAJOR);
diff --git a/drivers/cdrom/optcd.h b/drivers/cdrom/optcd.h
deleted file mode 100644
index 1911bb92ee28..000000000000
--- a/drivers/cdrom/optcd.h
+++ /dev/null
@@ -1,52 +0,0 @@
1/* linux/include/linux/optcd.h - Optics Storage 8000 AT CDROM driver
2 $Id: optcd.h,v 1.2 1996/01/15 18:43:44 root Exp root $
3
4 Copyright (C) 1995 Leo Spiekman (spiekman@dutette.et.tudelft.nl)
5
6
7 Configuration file for linux/drivers/cdrom/optcd.c
8*/
9
10#ifndef _LINUX_OPTCD_H
11#define _LINUX_OPTCD_H
12
13
14/* I/O base of drive. Drive uses base to base+2.
15 This setting can be overridden with the kernel or insmod command
16 line option 'optcd=<portbase>'. Use address of 0 to disable driver. */
17#define OPTCD_PORTBASE 0x340
18
19
20/* enable / disable parts of driver by define / undef */
21#define MULTISESSION /* multisession support (ALPHA) */
22
23
24/* Change 0 to 1 to debug various parts of the driver */
25#define DEBUG_DRIVE_IF 0 /* Low level drive interface */
26#define DEBUG_CONV 0 /* Address conversions */
27#define DEBUG_BUFFERS 0 /* Buffering and block size conversion */
28#define DEBUG_REQUEST 0 /* Request mechanism */
29#define DEBUG_STATE 0 /* State machine */
30#define DEBUG_TOC 0 /* Q-channel and Table of Contents */
31#define DEBUG_MULTIS 0 /* Multisession code */
32#define DEBUG_VFS 0 /* VFS interface */
33
34
35/* Don't touch these unless you know what you're doing. */
36
37/* Various timeout loop repetition counts. */
38#define BUSY_TIMEOUT 10000000 /* for busy wait */
39#define FAST_TIMEOUT 100000 /* ibid. for probing */
40#define SLEEP_TIMEOUT 6000 /* for timer wait */
41#define MULTI_SEEK_TIMEOUT 1000 /* for timer wait */
42#define READ_TIMEOUT 6000 /* for poll wait */
43#define STOP_TIMEOUT 2000 /* for poll wait */
44#define RESET_WAIT 5000 /* busy wait at drive reset */
45
46/* # of buffers for block size conversion. 6 is optimal for my setup (P75),
47 giving 280 kb/s, with 0.4% CPU usage. Experiment to find your optimal
48 setting */
49#define N_BUFS 6
50
51
52#endif /* _LINUX_OPTCD_H */
diff --git a/drivers/cdrom/sbpcd.c b/drivers/cdrom/sbpcd.c
deleted file mode 100644
index a1283b1ef989..000000000000
--- a/drivers/cdrom/sbpcd.c
+++ /dev/null
@@ -1,5966 +0,0 @@
1/*
2 * sbpcd.c CD-ROM device driver for the whole family of traditional,
3 * non-ATAPI IDE-style Matsushita/Panasonic CR-5xx drives.
4 * Works with SoundBlaster compatible cards and with "no-sound"
5 * interface cards like Lasermate, Panasonic CI-101P, Teac, ...
6 * Also for the Longshine LCS-7260 drive.
7 * Also for the IBM "External ISA CD-Rom" drive.
8 * Also for the CreativeLabs CD200 drive.
9 * Also for the TEAC CD-55A drive.
10 * Also for the ECS-AT "Vertos 100" drive.
11 * Not for Sanyo drives (but for the H94A, sjcd is there...).
12 * Not for any other Funai drives than the CD200 types (sometimes
13 * labelled E2550UA or MK4015 or 2800F).
14 */
15
16#define VERSION "v4.63 Andrew J. Kroll <ag784@freenet.buffalo.edu> Wed Jul 26 04:24:10 EDT 2000"
17
18/* Copyright (C) 1993, 1994, 1995 Eberhard Moenkeberg <emoenke@gwdg.de>
19 *
20 * This program is free software; you can redistribute it and/or modify
21 * it under the terms of the GNU General Public License as published by
22 * the Free Software Foundation; either version 2, or (at your option)
23 * any later version.
24 *
25 * You should have received a copy of the GNU General Public License
26 * (for example /usr/src/linux/COPYING); if not, write to the Free
27 * Software Foundation, Inc., 675 Mass Ave, Cambridge, MA 02139, USA.
28 *
29 * If you change this software, you should mail a .diff file with some
30 * description lines to emoenke@gwdg.de. I want to know about it.
31 *
32 * If you are the editor of a Linux CD, you should enable sbpcd.c within
33 * your boot floppy kernel and send me one of your CDs for free.
34 *
35 * If you would like to port the driver to an other operating system (f.e.
36 * FreeBSD or NetBSD) or use it as an information source, you shall not be
37 * restricted by the GPL under the following conditions:
38 * a) the source code of your work is freely available
39 * b) my part of the work gets mentioned at all places where your
40 * authorship gets mentioned
41 * c) I receive a copy of your code together with a full installation
42 * package of your operating system for free.
43 *
44 *
45 * VERSION HISTORY
46 *
47 * 0.1 initial release, April/May 93, after mcd.c (Martin Harriss)
48 *
49 * 0.2 thek "repeat:"-loop in do_sbpcd_request did not check for
50 * end-of-request_queue (resulting in kernel panic).
51 * Flow control seems stable, but throughput is not better.
52 *
53 * 0.3 interrupt locking totally eliminated (maybe "inb" and "outb"
54 * are still locking) - 0.2 made keyboard-type-ahead losses.
55 * check_sbpcd_media_change added (to use by isofs/inode.c)
56 * - but it detects almost nothing.
57 *
58 * 0.4 use MAJOR 25 definitely.
59 * Almost total re-design to support double-speed drives and
60 * "naked" (no sound) interface cards ("LaserMate" interface type).
61 * Flow control should be exact now.
62 * Don't occupy the SbPro IRQ line (not needed either); will
63 * live together with Hannu Savolainen's sndkit now.
64 * Speeded up data transfer to 150 kB/sec, with help from Kai
65 * Makisara, the "provider" of the "mt" tape utility.
66 * Give "SpinUp" command if necessary.
67 * First steps to support up to 4 drives (but currently only one).
68 * Implemented audio capabilities - workman should work, xcdplayer
69 * gives some problems.
70 * This version is still consuming too much CPU time, and
71 * sleeping still has to be worked on.
72 * During "long" implied seeks, it seems possible that a
73 * ReadStatus command gets ignored. That gives the message
74 * "ResponseStatus timed out" (happens about 6 times here during
75 * a "ls -alR" of the YGGDRASIL LGX-Beta CD). Such a case is
76 * handled without data error, but it should get done better.
77 *
78 * 0.5 Free CPU during waits (again with help from Kai Makisara).
79 * Made it work together with the LILO/kernel setup standard.
80 * Included auto-probing code, as suggested by YGGDRASIL.
81 * Formal redesign to add DDI debugging.
82 * There are still flaws in IOCTL (workman with double speed drive).
83 *
84 * 1.0 Added support for all drive IDs (0...3, no longer only 0)
85 * and up to 4 drives on one controller.
86 * Added "#define MANY_SESSION" for "old" multi session CDs.
87 *
88 * 1.1 Do SpinUp for new drives, too.
89 * Revised for clean compile under "old" kernels (0.99pl9).
90 *
91 * 1.2 Found the "workman with double-speed drive" bug: use the driver's
92 * audio_state, not what the drive is reporting with ReadSubQ.
93 *
94 * 1.3 Minor cleanups.
95 * Refinements regarding Workman.
96 *
97 * 1.4 Read XA disks (PhotoCDs) with "old" drives, too (but only the first
98 * session - no chance to fully access a "multi-session" CD).
99 * This currently still is too slow (50 kB/sec) - but possibly
100 * the old drives won't do it faster.
101 * Implemented "door (un)lock" for new drives (still does not work
102 * as wanted - no lock possible after an unlock).
103 * Added some debugging printout for the UPC/EAN code - but my drives
104 * return only zeroes. Is there no UPC/EAN code written?
105 *
106 * 1.5 Laborate with UPC/EAN code (not better yet).
107 * Adapt to kernel 1.1.8 change (have to explicitly include
108 * <linux/string.h> now).
109 *
110 * 1.6 Trying to read audio frames as data. Impossible with the current
111 * drive firmware levels, as it seems. Awaiting any hint. ;-)
112 * Changed "door unlock": repeat it until success.
113 * Changed CDROMSTOP routine (stop somewhat "softer" so that Workman
114 * won't get confused).
115 * Added a third interface type: Sequoia S-1000, as used with the SPEA
116 * Media FX sound card. This interface (usable for Sony and Mitsumi
117 * drives, too) needs a special configuration setup and behaves like a
118 * LaserMate type after that. Still experimental - I do not have such
119 * an interface.
120 * Use the "variable BLOCK_SIZE" feature (2048). But it does only work
121 * if you give the mount option "block=2048".
122 * The media_check routine is currently disabled; now that it gets
123 * called as it should I fear it must get synchronized for not to
124 * disturb the normal driver's activity.
125 *
126 * 2.0 Version number bumped - two reasons:
127 * - reading audio tracks as data works now with CR-562 and CR-563. We
128 * currently do it by an IOCTL (yet has to get standardized), one frame
129 * at a time; that is pretty slow. But it works.
130 * - we are maintaining now up to 4 interfaces (each up to 4 drives):
131 * did it the easy way - a different MAJOR (25, 26, ...) and a different
132 * copy of the driver (sbpcd.c, sbpcd2.c, sbpcd3.c, sbpcd4.c - only
133 * distinguished by the value of SBPCD_ISSUE and the driver's name),
134 * and a common sbpcd.h file.
135 * Bettered the "ReadCapacity error" problem with old CR-52x drives (the
136 * drives sometimes need a manual "eject/insert" before work): just
137 * reset the drive and do again. Needs lots of resets here and sometimes
138 * that does not cure, so this can't be the solution.
139 *
140 * 2.1 Found bug with multisession CDs (accessing frame 16).
141 * "read audio" works now with address type CDROM_MSF, too.
142 * Bigger audio frame buffer: allows reading max. 4 frames at time; this
143 * gives a significant speedup, but reading more than one frame at once
144 * gives missing chunks at each single frame boundary.
145 *
146 * 2.2 Kernel interface cleanups: timers, init, setup, media check.
147 *
148 * 2.3 Let "door lock" and "eject" live together.
149 * Implemented "close tray" (done automatically during open).
150 *
151 * 2.4 Use different names for device registering.
152 *
153 * 2.5 Added "#if EJECT" code (default: enabled) to automatically eject
154 * the tray during last call to "sbpcd_release".
155 * Added "#if JUKEBOX" code (default: disabled) to automatically eject
156 * the tray during call to "sbpcd_open" if no disk is in.
157 * Turn on the CD volume of "compatible" sound cards, too; just define
158 * SOUND_BASE (in sbpcd.h) accordingly (default: disabled).
159 *
160 * 2.6 Nothing new.
161 *
162 * 2.7 Added CDROMEJECT_SW ioctl to set the "EJECT" behavior on the fly:
163 * 0 disables, 1 enables auto-ejecting. Useful to keep the tray in
164 * during shutdown.
165 *
166 * 2.8 Added first support (still BETA, I need feedback or a drive) for
167 * the Longshine LCS-7260 drives. They appear as double-speed drives
168 * using the "old" command scheme, extended by tray control and door
169 * lock functions.
170 * Found (and fixed preliminary) a flaw with some multisession CDs: we
171 * have to re-direct not only the accesses to frame 16 (the isofs
172 * routines drive it up to max. 100), but also those to the continuation
173 * (repetition) frames (as far as they exist - currently set fix as
174 * 16..20).
175 * Changed default of the "JUKEBOX" define. If you use this default,
176 * your tray will eject if you try to mount without a disk in. Next
177 * mount command will insert the tray - so, just fill in a disk. ;-)
178 *
179 * 2.9 Fulfilled the Longshine LCS-7260 support; with great help and
180 * experiments by Serge Robyns.
181 * First attempts to support the TEAC CD-55A drives; but still not
182 * usable yet.
183 * Implemented the CDROMMULTISESSION ioctl; this is an attempt to handle
184 * multi session CDs more "transparent" (redirection handling has to be
185 * done within the isofs routines, and only for the special purpose of
186 * obtaining the "right" volume descriptor; accesses to the raw device
187 * should not get redirected).
188 *
189 * 3.0 Just a "normal" increment, with some provisions to do it better. ;-)
190 * Introduced "#define READ_AUDIO" to specify the maximum number of
191 * audio frames to grab with one request. This defines a buffer size
192 * within kernel space; a value of 0 will reserve no such space and
193 * disable the CDROMREADAUDIO ioctl. A value of 75 enables the reading
194 * of a whole second with one command, but will use a buffer of more
195 * than 172 kB.
196 * Started CD200 support. Drive detection should work, but nothing
197 * more.
198 *
199 * 3.1 Working to support the CD200 and the Teac CD-55A drives.
200 * AT-BUS style device numbering no longer used: use SCSI style now.
201 * So, the first "found" device has MINOR 0, regardless of the
202 * jumpered drive ID. This implies modifications to the /dev/sbpcd*
203 * entries for some people, but will help the DAU (german TLA, english:
204 * "newbie", maybe ;-) to install his "first" system from a CD.
205 *
206 * 3.2 Still testing with CD200 and CD-55A drives.
207 *
208 * 3.3 Working with CD200 support.
209 *
210 * 3.4 Auto-probing stops if an address of 0 is seen (to be entered with
211 * the kernel command line).
212 * Made the driver "loadable". If used as a module, "audio copy" is
213 * disabled, and the internal read ahead data buffer has a reduced size
214 * of 4 kB; so, throughput may be reduced a little bit with slow CPUs.
215 *
216 * 3.5 Provisions to handle weird photoCDs which have an interrupted
217 * "formatting" immediately after the last frames of some files: simply
218 * never "read ahead" with MultiSession CDs. By this, CPU usage may be
219 * increased with those CDs, and there may be a loss in speed.
220 * Re-structured the messaging system.
221 * The "loadable" version no longer has a limited READ_AUDIO buffer
222 * size.
223 * Removed "MANY_SESSION" handling for "old" multi session CDs.
224 * Added "private" IOCTLs CDROMRESET and CDROMVOLREAD.
225 * Started again to support the TEAC CD-55A drives, now that I found
226 * the money for "my own" drive. ;-)
227 * The TEAC CD-55A support is fairly working now.
228 * I have measured that the drive "delivers" at 600 kB/sec (even with
229 * bigger requests than the drive's 64 kB buffer can satisfy), but
230 * the "real" rate does not exceed 520 kB/sec at the moment.
231 * Caused by the various changes to build in TEAC support, the timed
232 * loops are de-optimized at the moment (less throughput with CR-52x
233 * drives, and the TEAC will give speed only with SBP_BUFFER_FRAMES 64).
234 *
235 * 3.6 Fixed TEAC data read problems with SbPro interfaces.
236 * Initial size of the READ_AUDIO buffer is 0. Can get set to any size
237 * during runtime.
238 *
239 * 3.7 Introduced MAX_DRIVES for some poor interface cards (seen with TEAC
240 * drives) which allow only one drive (ID 0); this avoids repetitive
241 * detection under IDs 1..3.
242 * Elongated cmd_out_T response waiting; necessary for photo CDs with
243 * a lot of sessions.
244 * Bettered the sbpcd_open() behavior with TEAC drives.
245 *
246 * 3.8 Elongated max_latency for CR-56x drives.
247 *
248 * 3.9 Finally fixed the long-known SoundScape/SPEA/Sequoia S-1000 interface
249 * configuration bug.
250 * Now Corey, Heiko, Ken, Leo, Vadim/Eric & Werner are invited to copy
251 * the config_spea() routine into their drivers. ;-)
252 *
253 * 4.0 No "big step" - normal version increment.
254 * Adapted the benefits from 1.3.33.
255 * Fiddled with CDROMREADAUDIO flaws.
256 * Avoid ReadCapacity command with CD200 drives (the MKE 1.01 version
257 * seems not to support it).
258 * Fulfilled "read audio" for CD200 drives, with help of Pete Heist
259 * (heistp@rpi.edu).
260 *
261 * 4.1 Use loglevel KERN_INFO with printk().
262 * Added support for "Vertos 100" drive ("ECS-AT") - it is very similar
263 * to the Longshine LCS-7260. Give feedback if you can - I never saw
264 * such a drive, and I have no specs.
265 *
266 * 4.2 Support for Teac 16-bit interface cards. Can't get auto-detected,
267 * so you have to jumper your card to 0x2C0. Still not 100% - come
268 * in contact if you can give qualified feedback.
269 * Use loglevel KERN_NOTICE with printk(). If you get annoyed by a
270 * flood of unwanted messages and the accompanied delay, try to read
271 * my documentation. Especially the Linux CDROM drivers have to do an
272 * important job for the newcomers, so the "distributed" version has
273 * to fit some special needs. Since generations, the flood of messages
274 * is user-configurable (even at runtime), but to get aware of this, one
275 * needs a special mental quality: the ability to read.
276 *
277 * 4.3 CD200F does not like to receive a command while the drive is
278 * reading the ToC; still trying to solve it.
279 * Removed some redundant verify_area calls (yes, Heiko Eissfeldt
280 * is visiting all the Linux CDROM drivers ;-).
281 *
282 * 4.4 Adapted one idea from tiensivu@pilot.msu.edu's "stripping-down"
283 * experiments: "KLOGD_PAUSE".
284 * Inhibited "play audio" attempts with data CDs. Provisions for a
285 * "data-safe" handling of "mixed" (data plus audio) Cds.
286 *
287 * 4.5 Meanwhile Gonzalo Tornaria <tornaria@cmat.edu.uy> (GTL) built a
288 * special end_request routine: we seem to have to take care for not
289 * to have two processes working at the request list. My understanding
290 * was and is that ll_rw_blk should not call do_sbpcd_request as long
291 * as there is still one call active (the first call will care for all
292 * outstanding I/Os, and if a second call happens, that is a bug in
293 * ll_rw_blk.c).
294 * "Check media change" without touching any drive.
295 *
296 * 4.6 Use a semaphore to synchronize multi-activity; elaborated by Rob
297 * Riggs <rriggs@tesser.com>. At the moment, we simply block "read"
298 * against "ioctl" and vice versa. This could be refined further, but
299 * I guess with almost no performance increase.
300 * Experiments to speed up the CD-55A; again with help of Rob Riggs
301 * (to be true, he gave both, idea & code. ;-)
302 *
303 * 4.61 Ported to Uniform CD-ROM driver by
304 * Heiko Eissfeldt <heiko@colossus.escape.de> with additional
305 * changes by Erik Andersen <andersee@debian.org>
306 *
307 * 4.62 Fix a bug where playing audio left the drive in an unusable state.
308 * Heiko Eissfeldt <heiko@colossus.escape.de>
309 *
310 * November 1999 -- Make kernel-parameter implementation work with 2.3.x
311 * Removed init_module & cleanup_module in favor of
312 * module_init & module_exit.
313 * Torben Mathiasen <tmm@image.dk>
314 *
315 * 4.63 Bug fixes for audio annoyances, new legacy CDROM maintainer.
316 * Annoying things fixed:
317 * TOC reread on automated disk changes
318 * TOC reread on manual cd changes
319 * Play IOCTL tries to play CD before it's actually ready... sometimes.
320 * CD_AUDIO_COMPLETED state so workman (and other playes) can repeat play.
321 * Andrew J. Kroll <ag784@freenet.buffalo.edu> Wed Jul 26 04:24:10 EDT 2000
322 *
323 * 4.64 Fix module parameters - were being completely ignored.
324 * Can also specify max_drives=N as a setup int to get rid of
325 * "ghost" drives on crap hardware (aren't they all?) Paul Gortmaker
326 *
327 * TODO
328 * implement "read all subchannel data" (96 bytes per frame)
329 * remove alot of the virtual status bits and deal with hardware status
330 * move the change of cd for audio to a better place
331 * add debug levels to insmod parameters (trivial)
332 *
333 * special thanks to Kai Makisara (kai.makisara@vtt.fi) for his fine
334 * elaborated speed-up experiments (and the fabulous results!), for
335 * the "push" towards load-free wait loops, and for the extensive mail
336 * thread which brought additional hints and bug fixes.
337 *
338 */
339
340/*
341 * Trying to merge requests breaks this driver horribly (as in it goes
342 * boom and apparently has done so since 2.3.41). As it is a legacy
343 * driver for a horribly slow double speed CD on a hideous interface
344 * designed for polled operation, I won't lose any sleep in simply
345 * disallowing merging. Paul G. 02/2001
346 *
347 * Thu May 30 14:14:47 CEST 2002:
348 *
349 * I have presumably found the reson for the above - there was a bogous
350 * end_request substitute, which was manipulating the request queues
351 * incorrectly. If someone has access to the actual hardware, and it's
352 * still operations - well please free to test it.
353 *
354 * Marcin Dalecki
355 */
356
357/*
358 * Add bio/kdev_t changes for 2.5.x required to make it work again.
359 * Still room for improvement in the request handling here if anyone
360 * actually cares. Bring your own chainsaw. Paul G. 02/2002
361 */
362
363
364#include <linux/module.h>
365
366#include <linux/errno.h>
367#include <linux/sched.h>
368#include <linux/mm.h>
369#include <linux/timer.h>
370#include <linux/fs.h>
371#include <linux/kernel.h>
372#include <linux/cdrom.h>
373#include <linux/ioport.h>
374#include <linux/major.h>
375#include <linux/string.h>
376#include <linux/vmalloc.h>
377#include <linux/init.h>
378#include <linux/interrupt.h>
379
380#include <asm/system.h>
381#include <asm/io.h>
382#include <asm/uaccess.h>
383#include <stdarg.h>
384#include "sbpcd.h"
385
386#define MAJOR_NR MATSUSHITA_CDROM_MAJOR
387#include <linux/blkdev.h>
388
389/*==========================================================================*/
390#if SBPCD_DIS_IRQ
391# define SBPCD_CLI cli()
392# define SBPCD_STI sti()
393#else
394# define SBPCD_CLI
395# define SBPCD_STI
396#endif
397
398/*==========================================================================*/
399/*
400 * auto-probing address list
401 * inspired by Adam J. Richter from Yggdrasil
402 *
403 * still not good enough - can cause a hang.
404 * example: a NE 2000 ethernet card at 300 will cause a hang probing 310.
405 * if that happens, reboot and use the LILO (kernel) command line.
406 * The possibly conflicting ethernet card addresses get NOT probed
407 * by default - to minimize the hang possibilities.
408 *
409 * The SB Pro addresses get "mirrored" at 0x6xx and some more locations - to
410 * avoid a type error, the 0x2xx-addresses must get checked before 0x6xx.
411 *
412 * send mail to emoenke@gwdg.de if your interface card is not FULLY
413 * represented here.
414 */
415static int sbpcd[] =
416{
417 CDROM_PORT, SBPRO, /* probe with user's setup first */
418#if DISTRIBUTION
419 0x230, 1, /* Soundblaster Pro and 16 (default) */
420#if 0
421 0x300, 0, /* CI-101P (default), WDH-7001C (default),
422 Galaxy (default), Reveal (one default) */
423 0x250, 1, /* OmniCD default, Soundblaster Pro and 16 */
424 0x2C0, 3, /* Teac 16-bit cards */
425 0x260, 1, /* OmniCD */
426 0x320, 0, /* Lasermate, CI-101P, WDH-7001C, Galaxy, Reveal (other default),
427 Longshine LCS-6853 (default) */
428 0x338, 0, /* Reveal Sound Wave 32 card model #SC600 */
429 0x340, 0, /* Mozart sound card (default), Lasermate, CI-101P */
430 0x360, 0, /* Lasermate, CI-101P */
431 0x270, 1, /* Soundblaster 16 */
432 0x670, 0, /* "sound card #9" */
433 0x690, 0, /* "sound card #9" */
434 0x338, 2, /* SPEA Media FX, Ensonic SoundScape (default) */
435 0x328, 2, /* SPEA Media FX */
436 0x348, 2, /* SPEA Media FX */
437 0x634, 0, /* some newer sound cards */
438 0x638, 0, /* some newer sound cards */
439 0x230, 1, /* some newer sound cards */
440 /* due to incomplete address decoding of the SbPro card, these must be last */
441 0x630, 0, /* "sound card #9" (default) */
442 0x650, 0, /* "sound card #9" */
443#ifdef MODULE
444 /*
445 * some "hazardous" locations (no harm with the loadable version)
446 * (will stop the bus if a NE2000 ethernet card resides at offset -0x10)
447 */
448 0x330, 0, /* Lasermate, CI-101P, WDH-7001C */
449 0x350, 0, /* Lasermate, CI-101P */
450 0x358, 2, /* SPEA Media FX */
451 0x370, 0, /* Lasermate, CI-101P */
452 0x290, 1, /* Soundblaster 16 */
453 0x310, 0, /* Lasermate, CI-101P, WDH-7001C */
454#endif /* MODULE */
455#endif
456#endif /* DISTRIBUTION */
457};
458
459/*
460 * Protects access to global structures etc.
461 */
462static __cacheline_aligned DEFINE_SPINLOCK(sbpcd_lock);
463static struct request_queue *sbpcd_queue;
464
465/* You can only set the first pair, from old MODULE_PARM code. */
466static int sbpcd_set(const char *val, struct kernel_param *kp)
467{
468 get_options((char *)val, 2, (int *)sbpcd);
469 return 0;
470}
471module_param_call(sbpcd, sbpcd_set, NULL, NULL, 0);
472
473#define NUM_PROBE (sizeof(sbpcd) / sizeof(int))
474
475/*==========================================================================*/
476
477#define INLINE inline
478
479/*==========================================================================*/
480/*
481 * the forward references:
482 */
483static void sbp_sleep(u_int);
484static void mark_timeout_delay(u_long);
485static void mark_timeout_data(u_long);
486#if 0
487static void mark_timeout_audio(u_long);
488#endif
489static void sbp_read_cmd(struct request *req);
490static int sbp_data(struct request *req);
491static int cmd_out(void);
492static int DiskInfo(void);
493
494/*==========================================================================*/
495
496/*
497 * pattern for printk selection:
498 *
499 * (1<<DBG_INF) necessary information
500 * (1<<DBG_BSZ) BLOCK_SIZE trace
501 * (1<<DBG_REA) "read" status trace
502 * (1<<DBG_CHK) "media check" trace
503 * (1<<DBG_TIM) datarate timer test
504 * (1<<DBG_INI) initialization trace
505 * (1<<DBG_TOC) tell TocEntry values
506 * (1<<DBG_IOC) ioctl trace
507 * (1<<DBG_STA) "ResponseStatus" trace
508 * (1<<DBG_ERR) "cc_ReadError" trace
509 * (1<<DBG_CMD) "cmd_out" trace
510 * (1<<DBG_WRN) give explanation before auto-probing
511 * (1<<DBG_MUL) multi session code test
512 * (1<<DBG_IDX) "drive_id != 0" test code
513 * (1<<DBG_IOX) some special information
514 * (1<<DBG_DID) drive ID test
515 * (1<<DBG_RES) drive reset info
516 * (1<<DBG_SPI) SpinUp test info
517 * (1<<DBG_IOS) ioctl trace: "subchannel"
518 * (1<<DBG_IO2) ioctl trace: general
519 * (1<<DBG_UPC) show UPC info
520 * (1<<DBG_XA1) XA mode debugging
521 * (1<<DBG_LCK) door (un)lock info
522 * (1<<DBG_SQ1) dump SubQ frame
523 * (1<<DBG_AUD) "read audio" debugging
524 * (1<<DBG_SEQ) Sequoia interface configuration trace
525 * (1<<DBG_LCS) Longshine LCS-7260 debugging trace
526 * (1<<DBG_CD2) MKE/Funai CD200 debugging trace
527 * (1<<DBG_TEA) TEAC CD-55A debugging trace
528 * (1<<DBG_ECS) ECS-AT (Vertos-100) debugging trace
529 * (1<<DBG_000) unnecessary information
530 */
531#if DISTRIBUTION
532static int sbpcd_debug = (1<<DBG_INF);
533#else
534static int sbpcd_debug = 0 & ((1<<DBG_INF) |
535 (1<<DBG_TOC) |
536 (1<<DBG_MUL) |
537 (1<<DBG_UPC));
538#endif /* DISTRIBUTION */
539
540static int sbpcd_ioaddr = CDROM_PORT; /* default I/O base address */
541static int sbpro_type = SBPRO;
542static unsigned char f_16bit;
543static unsigned char do_16bit;
544static int CDo_command, CDo_reset;
545static int CDo_sel_i_d, CDo_enable;
546static int CDi_info, CDi_status, CDi_data;
547static struct cdrom_msf msf;
548static struct cdrom_ti ti;
549static struct cdrom_tochdr tochdr;
550static struct cdrom_tocentry tocentry;
551static struct cdrom_subchnl SC;
552static struct cdrom_volctrl volctrl;
553static struct cdrom_read_audio read_audio;
554
555static unsigned char msgnum;
556static char msgbuf[80];
557
558static int max_drives = MAX_DRIVES;
559module_param(max_drives, int, 0);
560#ifndef MODULE
561static unsigned char setup_done;
562static const char *str_sb_l = "soundblaster";
563static const char *str_sp_l = "spea";
564static const char *str_ss_l = "soundscape";
565static const char *str_t16_l = "teac16bit";
566static const char *str_ss = "SoundScape";
567#endif
568static const char *str_sb = "SoundBlaster";
569static const char *str_lm = "LaserMate";
570static const char *str_sp = "SPEA";
571static const char *str_t16 = "Teac16bit";
572static const char *type;
573static const char *major_name="sbpcd";
574
575/*==========================================================================*/
576
577#ifdef FUTURE
578static DECLARE_WAIT_QUEUE_HEAD(sbp_waitq);
579#endif /* FUTURE */
580
581static int teac=SBP_TEAC_SPEED;
582static int buffers=SBP_BUFFER_FRAMES;
583
584static u_char family0[]="MATSHITA"; /* MKE CR-521, CR-522, CR-523 */
585static u_char family1[]="CR-56"; /* MKE CR-562, CR-563 */
586static u_char family2[]="CD200"; /* MKE CD200, Funai CD200F */
587static u_char familyL[]="LCS-7260"; /* Longshine LCS-7260 */
588static u_char familyT[]="CD-55"; /* TEAC CD-55A */
589static u_char familyV[]="ECS-AT"; /* ECS Vertos 100 */
590
591static u_int recursion; /* internal testing only */
592static u_int fatal_err; /* internal testing only */
593static u_int response_count;
594static u_int flags_cmd_out;
595static u_char cmd_type;
596static u_char drvcmd[10];
597static u_char infobuf[20];
598static u_char xa_head_buf[CD_XA_HEAD];
599static u_char xa_tail_buf[CD_XA_TAIL];
600
601#if OLD_BUSY
602static volatile u_char busy_data;
603static volatile u_char busy_audio; /* true semaphores would be safer */
604#endif /* OLD_BUSY */
605static DECLARE_MUTEX(ioctl_read_sem);
606static u_long timeout;
607static volatile u_char timed_out_delay;
608static volatile u_char timed_out_data;
609#if 0
610static volatile u_char timed_out_audio;
611#endif
612static u_int datarate= 1000000;
613static u_int maxtim16=16000000;
614static u_int maxtim04= 4000000;
615static u_int maxtim02= 2000000;
616static u_int maxtim_8= 30000;
617#if LONG_TIMING
618static u_int maxtim_data= 9000;
619#else
620static u_int maxtim_data= 3000;
621#endif /* LONG_TIMING */
622#if DISTRIBUTION
623static int n_retries=6;
624#else
625static int n_retries=6;
626#endif
627/*==========================================================================*/
628
629static int ndrives;
630static u_char drv_pattern[NR_SBPCD]={speed_auto,speed_auto,speed_auto,speed_auto};
631
632/*==========================================================================*/
633/*
634 * drive space begins here (needed separate for each unit)
635 */
636static struct sbpcd_drive {
637 char drv_id; /* "jumpered" drive ID or -1 */
638 char drv_sel; /* drive select lines bits */
639
640 char drive_model[9];
641 u_char firmware_version[4];
642 char f_eject; /* auto-eject flag: 0 or 1 */
643 u_char *sbp_buf; /* Pointer to internal data buffer,
644 space allocated during sbpcd_init() */
645 u_int sbp_bufsiz; /* size of sbp_buf (# of frames) */
646 int sbp_first_frame; /* First frame in buffer */
647 int sbp_last_frame; /* Last frame in buffer */
648 int sbp_read_frames; /* Number of frames being read to buffer */
649 int sbp_current; /* Frame being currently read */
650
651 u_char mode; /* read_mode: READ_M1, READ_M2, READ_SC, READ_AU */
652 u_char *aud_buf; /* Pointer to audio data buffer,
653 space allocated during sbpcd_init() */
654 u_int sbp_audsiz; /* size of aud_buf (# of raw frames) */
655 u_int drv_type;
656 u_char drv_options;
657 int status_bits;
658 u_char diskstate_flags;
659 u_char sense_byte;
660
661 u_char CD_changed;
662 char open_count;
663 u_char error_byte;
664
665 u_char f_multisession;
666 u_int lba_multi;
667 int first_session;
668 int last_session;
669 int track_of_last_session;
670
671 u_char audio_state;
672 u_int pos_audio_start;
673 u_int pos_audio_end;
674 char vol_chan0;
675 u_char vol_ctrl0;
676 char vol_chan1;
677 u_char vol_ctrl1;
678#if 000 /* no supported drive has it */
679 char vol_chan2;
680 u_char vol_ctrl2;
681 char vol_chan3;
682 u_char vol_ctrl3;
683#endif /*000 */
684 u_char volume_control; /* TEAC on/off bits */
685
686 u_char SubQ_ctl_adr;
687 u_char SubQ_trk;
688 u_char SubQ_pnt_idx;
689 u_int SubQ_run_tot;
690 u_int SubQ_run_trk;
691 u_char SubQ_whatisthis;
692
693 u_char UPC_ctl_adr;
694 u_char UPC_buf[7];
695
696 int frame_size;
697 int CDsize_frm;
698
699 u_char xa_byte; /* 0x20: XA capabilities */
700 u_char n_first_track; /* binary */
701 u_char n_last_track; /* binary (not bcd), 0x01...0x63 */
702 u_int size_msf; /* time of whole CD, position of LeadOut track */
703 u_int size_blk;
704
705 u_char TocEnt_nixbyte; /* em */
706 u_char TocEnt_ctl_adr;
707 u_char TocEnt_number;
708 u_char TocEnt_format; /* em */
709 u_int TocEnt_address;
710#ifdef SAFE_MIXED
711 char has_data;
712#endif /* SAFE_MIXED */
713 u_char ored_ctl_adr; /* to detect if CDROM contains data tracks */
714
715 struct {
716 u_char nixbyte; /* em */
717 u_char ctl_adr; /* 0x4x: data, 0x0x: audio */
718 u_char number;
719 u_char format; /* em */ /* 0x00: lba, 0x01: msf */
720 u_int address;
721 } TocBuffer[MAX_TRACKS+1]; /* last entry faked */
722
723 int in_SpinUp; /* CR-52x test flag */
724 int n_bytes; /* TEAC awaited response count */
725 u_char error_state, b3, b4; /* TEAC command error state */
726 u_char f_drv_error; /* TEAC command error flag */
727 u_char speed_byte;
728 int frmsiz;
729 u_char f_XA; /* 1: XA */
730 u_char type_byte; /* 0, 1, 3 */
731 u_char mode_xb_6;
732 u_char mode_yb_7;
733 u_char mode_xb_8;
734 u_char delay;
735 struct cdrom_device_info *sbpcd_infop;
736 struct gendisk *disk;
737} D_S[NR_SBPCD];
738
739static struct sbpcd_drive *current_drive = D_S;
740
741/*
742 * drive space ends here (needed separate for each unit)
743 */
744/*==========================================================================*/
745#if 0
746unsigned long cli_sti; /* for saving the processor flags */
747#endif
748/*==========================================================================*/
749static DEFINE_TIMER(delay_timer, mark_timeout_delay, 0, 0);
750static DEFINE_TIMER(data_timer, mark_timeout_data, 0, 0);
751#if 0
752static DEFINE_TIMER(audio_timer, mark_timeout_audio, 0, 0);
753#endif
754/*==========================================================================*/
755/*
756 * DDI interface
757 */
758static void msg(int level, const char *fmt, ...)
759{
760#if DISTRIBUTION
761#define MSG_LEVEL KERN_NOTICE
762#else
763#define MSG_LEVEL KERN_INFO
764#endif /* DISTRIBUTION */
765
766 char buf[256];
767 va_list args;
768
769 if (!(sbpcd_debug&(1<<level))) return;
770
771 msgnum++;
772 if (msgnum>99) msgnum=0;
773 va_start(args, fmt);
774 vsnprintf(buf, sizeof(buf), fmt, args);
775 va_end(args);
776 printk(MSG_LEVEL "%s-%d [%02d]: %s", major_name, current_drive - D_S, msgnum, buf);
777#if KLOGD_PAUSE
778 sbp_sleep(KLOGD_PAUSE); /* else messages get lost */
779#endif /* KLOGD_PAUSE */
780 return;
781}
782/*==========================================================================*/
783/*
784 * DDI interface: runtime trace bit pattern maintenance
785 */
786static int sbpcd_dbg_ioctl(unsigned long arg, int level)
787{
788 switch(arg)
789 {
790 case 0: /* OFF */
791 sbpcd_debug = DBG_INF;
792 break;
793
794 default:
795 if (arg>=128) sbpcd_debug &= ~(1<<(arg-128));
796 else sbpcd_debug |= (1<<arg);
797 }
798 return (arg);
799}
800/*==========================================================================*/
801static void mark_timeout_delay(u_long i)
802{
803 timed_out_delay=1;
804#if 0
805 msg(DBG_TIM,"delay timer expired.\n");
806#endif
807}
808/*==========================================================================*/
809static void mark_timeout_data(u_long i)
810{
811 timed_out_data=1;
812#if 0
813 msg(DBG_TIM,"data timer expired.\n");
814#endif
815}
816/*==========================================================================*/
817#if 0
818static void mark_timeout_audio(u_long i)
819{
820 timed_out_audio=1;
821#if 0
822 msg(DBG_TIM,"audio timer expired.\n");
823#endif
824}
825#endif
826/*==========================================================================*/
827/*
828 * Wait a little while (used for polling the drive).
829 */
830static void sbp_sleep(u_int time)
831{
832 sti();
833 schedule_timeout_interruptible(time);
834 sti();
835}
836/*==========================================================================*/
837#define RETURN_UP(rc) {up(&ioctl_read_sem); return(rc);}
838/*==========================================================================*/
839/*
840 * convert logical_block_address to m-s-f_number (3 bytes only)
841 */
842static INLINE void lba2msf(int lba, u_char *msf)
843{
844 lba += CD_MSF_OFFSET;
845 msf[0] = lba / (CD_SECS*CD_FRAMES);
846 lba %= CD_SECS*CD_FRAMES;
847 msf[1] = lba / CD_FRAMES;
848 msf[2] = lba % CD_FRAMES;
849}
850/*==========================================================================*/
851/*==========================================================================*/
852/*
853 * convert msf-bin to msf-bcd
854 */
855static INLINE void bin2bcdx(u_char *p) /* must work only up to 75 or 99 */
856{
857 *p=((*p/10)<<4)|(*p%10);
858}
859/*==========================================================================*/
860static INLINE u_int blk2msf(u_int blk)
861{
862 MSF msf;
863 u_int mm;
864
865 msf.c[3] = 0;
866 msf.c[2] = (blk + CD_MSF_OFFSET) / (CD_SECS * CD_FRAMES);
867 mm = (blk + CD_MSF_OFFSET) % (CD_SECS * CD_FRAMES);
868 msf.c[1] = mm / CD_FRAMES;
869 msf.c[0] = mm % CD_FRAMES;
870 return (msf.n);
871}
872/*==========================================================================*/
873static INLINE u_int make16(u_char rh, u_char rl)
874{
875 return ((rh<<8)|rl);
876}
877/*==========================================================================*/
878static INLINE u_int make32(u_int rh, u_int rl)
879{
880 return ((rh<<16)|rl);
881}
882/*==========================================================================*/
883static INLINE u_char swap_nibbles(u_char i)
884{
885 return ((i<<4)|(i>>4));
886}
887/*==========================================================================*/
888static INLINE u_char byt2bcd(u_char i)
889{
890 return (((i/10)<<4)+i%10);
891}
892/*==========================================================================*/
893static INLINE u_char bcd2bin(u_char bcd)
894{
895 return ((bcd>>4)*10+(bcd&0x0F));
896}
897/*==========================================================================*/
898static INLINE int msf2blk(int msfx)
899{
900 MSF msf;
901 int i;
902
903 msf.n=msfx;
904 i=(msf.c[2] * CD_SECS + msf.c[1]) * CD_FRAMES + msf.c[0] - CD_MSF_OFFSET;
905 if (i<0) return (0);
906 return (i);
907}
908/*==========================================================================*/
909/*
910 * convert m-s-f_number (3 bytes only) to logical_block_address
911 */
912static INLINE int msf2lba(u_char *msf)
913{
914 int i;
915
916 i=(msf[0] * CD_SECS + msf[1]) * CD_FRAMES + msf[2] - CD_MSF_OFFSET;
917 if (i<0) return (0);
918 return (i);
919}
920/*==========================================================================*/
921/* evaluate cc_ReadError code */
922static int sta2err(int sta)
923{
924 if (famT_drive)
925 {
926 if (sta==0x00) return (0);
927 if (sta==0x01) return (-604); /* CRC error */
928 if (sta==0x02) return (-602); /* drive not ready */
929 if (sta==0x03) return (-607); /* unknown media */
930 if (sta==0x04) return (-612); /* general failure */
931 if (sta==0x05) return (0);
932 if (sta==0x06) return (-ERR_DISKCHANGE); /* disk change */
933 if (sta==0x0b) return (-612); /* general failure */
934 if (sta==0xff) return (-612); /* general failure */
935 return (0);
936 }
937 else
938 {
939 if (sta<=2) return (sta);
940 if (sta==0x05) return (-604); /* CRC error */
941 if (sta==0x06) return (-606); /* seek error */
942 if (sta==0x0d) return (-606); /* seek error */
943 if (sta==0x0e) return (-603); /* unknown command */
944 if (sta==0x14) return (-603); /* unknown command */
945 if (sta==0x0c) return (-611); /* read fault */
946 if (sta==0x0f) return (-611); /* read fault */
947 if (sta==0x10) return (-611); /* read fault */
948 if (sta>=0x16) return (-612); /* general failure */
949 if (sta==0x11) return (-ERR_DISKCHANGE); /* disk change (LCS: removed) */
950 if (famL_drive)
951 if (sta==0x12) return (-ERR_DISKCHANGE); /* disk change (inserted) */
952 return (-602); /* drive not ready */
953 }
954}
955/*==========================================================================*/
956static INLINE void clr_cmdbuf(void)
957{
958 int i;
959
960 for (i=0;i<10;i++) drvcmd[i]=0;
961 cmd_type=0;
962}
963/*==========================================================================*/
964static void flush_status(void)
965{
966 int i;
967
968 sbp_sleep(15*HZ/10);
969 for (i=maxtim_data;i!=0;i--) inb(CDi_status);
970}
971/*====================================================================*/
972/*
973 * CDi status loop for Teac CD-55A (Rob Riggs)
974 *
975 * This is needed because for some strange reason
976 * the CD-55A can take a real long time to give a
977 * status response. This seems to happen after we
978 * issue a READ command where a long seek is involved.
979 *
980 * I tried to ensure that we get max throughput with
981 * minimal busy waiting. We busy wait at first, then
982 * "switch gears" and start sleeping. We sleep for
983 * longer periods of time the longer we wait.
984 *
985 */
986static int CDi_stat_loop_T(void)
987{
988 int i, gear=1;
989 u_long timeout_1, timeout_2, timeout_3, timeout_4;
990
991 timeout_1 = jiffies + HZ / 50; /* sbp_sleep(0) for a short period */
992 timeout_2 = jiffies + HZ / 5; /* nap for no more than 200ms */
993 timeout_3 = jiffies + 5 * HZ; /* sleep for up to 5s */
994 timeout_4 = jiffies + 45 * HZ; /* long sleep for up to 45s. */
995 do
996 {
997 i = inb(CDi_status);
998 if (!(i&s_not_data_ready)) return (i);
999 if (!(i&s_not_result_ready)) return (i);
1000 switch(gear)
1001 {
1002 case 4:
1003 sbp_sleep(HZ);
1004 if (time_after(jiffies, timeout_4)) gear++;
1005 msg(DBG_TEA, "CDi_stat_loop_T: long sleep active.\n");
1006 break;
1007 case 3:
1008 sbp_sleep(HZ/10);
1009 if (time_after(jiffies, timeout_3)) gear++;
1010 break;
1011 case 2:
1012 sbp_sleep(HZ/100);
1013 if (time_after(jiffies, timeout_2)) gear++;
1014 break;
1015 case 1:
1016 sbp_sleep(0);
1017 if (time_after(jiffies, timeout_1)) gear++;
1018 }
1019 } while (gear < 5);
1020 return -1;
1021}
1022/*==========================================================================*/
1023static int CDi_stat_loop(void)
1024{
1025 int i,j;
1026
1027 for(timeout = jiffies + 10*HZ, i=maxtim_data; time_before(jiffies, timeout); )
1028 {
1029 for ( ;i!=0;i--)
1030 {
1031 j=inb(CDi_status);
1032 if (!(j&s_not_data_ready)) return (j);
1033 if (!(j&s_not_result_ready)) return (j);
1034 if (fam0L_drive) if (j&s_attention) return (j);
1035 }
1036 sbp_sleep(1);
1037 i = 1;
1038 }
1039 msg(DBG_LCS,"CDi_stat_loop failed in line %d\n", __LINE__);
1040 return (-1);
1041}
1042/*==========================================================================*/
1043#if 00000
1044/*==========================================================================*/
1045static int tst_DataReady(void)
1046{
1047 int i;
1048
1049 i=inb(CDi_status);
1050 if (i&s_not_data_ready) return (0);
1051 return (1);
1052}
1053/*==========================================================================*/
1054static int tst_ResultReady(void)
1055{
1056 int i;
1057
1058 i=inb(CDi_status);
1059 if (i&s_not_result_ready) return (0);
1060 return (1);
1061}
1062/*==========================================================================*/
1063static int tst_Attention(void)
1064{
1065 int i;
1066
1067 i=inb(CDi_status);
1068 if (i&s_attention) return (1);
1069 return (0);
1070}
1071/*==========================================================================*/
1072#endif
1073/*==========================================================================*/
1074static int ResponseInfo(void)
1075{
1076 int i,j,st=0;
1077 u_long timeout;
1078
1079 for (i=0,timeout=jiffies+HZ;i<response_count;i++)
1080 {
1081 for (j=maxtim_data; ; )
1082 {
1083 for ( ;j!=0;j-- )
1084 {
1085 st=inb(CDi_status);
1086 if (!(st&s_not_result_ready)) break;
1087 }
1088 if ((j!=0)||time_after_eq(jiffies, timeout)) break;
1089 sbp_sleep(1);
1090 j = 1;
1091 }
1092 if (time_after_eq(jiffies, timeout)) break;
1093 infobuf[i]=inb(CDi_info);
1094 }
1095#if 000
1096 while (!(inb(CDi_status)&s_not_result_ready))
1097 {
1098 infobuf[i++]=inb(CDi_info);
1099 }
1100 j=i-response_count;
1101 if (j>0) msg(DBG_INF,"ResponseInfo: got %d trailing bytes.\n",j);
1102#endif /* 000 */
1103 for (j=0;j<i;j++)
1104 sprintf(&msgbuf[j*3]," %02X",infobuf[j]);
1105 msgbuf[j*3]=0;
1106 msg(DBG_CMD,"ResponseInfo:%s (%d,%d)\n",msgbuf,response_count,i);
1107 j=response_count-i;
1108 if (j>0) return (-j);
1109 else return (i);
1110}
1111/*==========================================================================*/
1112static void EvaluateStatus(int st)
1113{
1114 current_drive->status_bits=0;
1115 if (fam1_drive) current_drive->status_bits=st|p_success;
1116 else if (fam0_drive)
1117 {
1118 if (st&p_caddin_old) current_drive->status_bits |= p_door_closed|p_caddy_in;
1119 if (st&p_spinning) current_drive->status_bits |= p_spinning;
1120 if (st&p_check) current_drive->status_bits |= p_check;
1121 if (st&p_success_old) current_drive->status_bits |= p_success;
1122 if (st&p_busy_old) current_drive->status_bits |= p_busy_new;
1123 if (st&p_disk_ok) current_drive->status_bits |= p_disk_ok;
1124 }
1125 else if (famLV_drive)
1126 {
1127 current_drive->status_bits |= p_success;
1128 if (st&p_caddin_old) current_drive->status_bits |= p_disk_ok|p_caddy_in;
1129 if (st&p_spinning) current_drive->status_bits |= p_spinning;
1130 if (st&p_check) current_drive->status_bits |= p_check;
1131 if (st&p_busy_old) current_drive->status_bits |= p_busy_new;
1132 if (st&p_lcs_door_closed) current_drive->status_bits |= p_door_closed;
1133 if (st&p_lcs_door_locked) current_drive->status_bits |= p_door_locked;
1134 }
1135 else if (fam2_drive)
1136 {
1137 current_drive->status_bits |= p_success;
1138 if (st&p2_check) current_drive->status_bits |= p1_check;
1139 if (st&p2_door_closed) current_drive->status_bits |= p1_door_closed;
1140 if (st&p2_disk_in) current_drive->status_bits |= p1_disk_in;
1141 if (st&p2_busy1) current_drive->status_bits |= p1_busy;
1142 if (st&p2_busy2) current_drive->status_bits |= p1_busy;
1143 if (st&p2_spinning) current_drive->status_bits |= p1_spinning;
1144 if (st&p2_door_locked) current_drive->status_bits |= p1_door_locked;
1145 if (st&p2_disk_ok) current_drive->status_bits |= p1_disk_ok;
1146 }
1147 else if (famT_drive)
1148 {
1149 return; /* still needs to get coded */
1150 current_drive->status_bits |= p_success;
1151 if (st&p2_check) current_drive->status_bits |= p1_check;
1152 if (st&p2_door_closed) current_drive->status_bits |= p1_door_closed;
1153 if (st&p2_disk_in) current_drive->status_bits |= p1_disk_in;
1154 if (st&p2_busy1) current_drive->status_bits |= p1_busy;
1155 if (st&p2_busy2) current_drive->status_bits |= p1_busy;
1156 if (st&p2_spinning) current_drive->status_bits |= p1_spinning;
1157 if (st&p2_door_locked) current_drive->status_bits |= p1_door_locked;
1158 if (st&p2_disk_ok) current_drive->status_bits |= p1_disk_ok;
1159 }
1160 return;
1161}
1162/*==========================================================================*/
1163static int cmd_out_T(void);
1164
1165static int get_state_T(void)
1166{
1167 int i;
1168
1169 clr_cmdbuf();
1170 current_drive->n_bytes=1;
1171 drvcmd[0]=CMDT_STATUS;
1172 i=cmd_out_T();
1173 if (i>=0) i=infobuf[0];
1174 else
1175 {
1176 msg(DBG_TEA,"get_state_T error %d\n", i);
1177 return (i);
1178 }
1179 if (i>=0)
1180 /* 2: closed, disk in */
1181 current_drive->status_bits=p1_door_closed|p1_disk_in|p1_spinning|p1_disk_ok;
1182 else if (current_drive->error_state==6)
1183 {
1184 /* 3: closed, disk in, changed ("06 xx xx") */
1185 current_drive->status_bits=p1_door_closed|p1_disk_in;
1186 current_drive->CD_changed=0xFF;
1187 current_drive->diskstate_flags &= ~toc_bit;
1188 }
1189 else if ((current_drive->error_state!=2)||(current_drive->b3!=0x3A)||(current_drive->b4==0x00))
1190 {
1191 /* 1: closed, no disk ("xx yy zz"or "02 3A 00") */
1192 current_drive->status_bits=p1_door_closed;
1193 current_drive->open_count=0;
1194 }
1195 else if (current_drive->b4==0x01)
1196 {
1197 /* 0: open ("02 3A 01") */
1198 current_drive->status_bits=0;
1199 current_drive->open_count=0;
1200 }
1201 else
1202 {
1203 /* 1: closed, no disk ("02 3A xx") */
1204 current_drive->status_bits=p1_door_closed;
1205 current_drive->open_count=0;
1206 }
1207 return (current_drive->status_bits);
1208}
1209/*==========================================================================*/
1210static int ResponseStatus(void)
1211{
1212 int i,j;
1213 u_long timeout;
1214
1215 msg(DBG_STA,"doing ResponseStatus...\n");
1216 if (famT_drive) return (get_state_T());
1217 if (flags_cmd_out & f_respo3) timeout = jiffies;
1218 else if (flags_cmd_out & f_respo2) timeout = jiffies + 16*HZ;
1219 else timeout = jiffies + 4*HZ;
1220 j=maxtim_8;
1221 do
1222 {
1223 for ( ;j!=0;j--)
1224 {
1225 i=inb(CDi_status);
1226 if (!(i&s_not_result_ready)) break;
1227 }
1228 if ((j!=0)||time_after(jiffies, timeout)) break;
1229 sbp_sleep(1);
1230 j = 1;
1231 }
1232 while (1);
1233 if (j==0)
1234 {
1235 if ((flags_cmd_out & f_respo3) == 0)
1236 msg(DBG_STA,"ResponseStatus: timeout.\n");
1237 current_drive->status_bits=0;
1238 return (-401);
1239 }
1240 i=inb(CDi_info);
1241 msg(DBG_STA,"ResponseStatus: response %02X.\n", i);
1242 EvaluateStatus(i);
1243 msg(DBG_STA,"status_bits=%02X, i=%02X\n",current_drive->status_bits,i);
1244 return (current_drive->status_bits);
1245}
1246/*==========================================================================*/
1247static void cc_ReadStatus(void)
1248{
1249 int i;
1250
1251 msg(DBG_STA,"giving cc_ReadStatus command\n");
1252 if (famT_drive) return;
1253 SBPCD_CLI;
1254 if (fam0LV_drive) OUT(CDo_command,CMD0_STATUS);
1255 else if (fam1_drive) OUT(CDo_command,CMD1_STATUS);
1256 else if (fam2_drive) OUT(CDo_command,CMD2_STATUS);
1257 if (!fam0LV_drive) for (i=0;i<6;i++) OUT(CDo_command,0);
1258 SBPCD_STI;
1259}
1260/*==========================================================================*/
1261static int cc_ReadError(void)
1262{
1263 int i;
1264
1265 clr_cmdbuf();
1266 msg(DBG_ERR,"giving cc_ReadError command.\n");
1267 if (fam1_drive)
1268 {
1269 drvcmd[0]=CMD1_READ_ERR;
1270 response_count=8;
1271 flags_cmd_out=f_putcmd|f_ResponseStatus;
1272 }
1273 else if (fam0LV_drive)
1274 {
1275 drvcmd[0]=CMD0_READ_ERR;
1276 response_count=6;
1277 if (famLV_drive)
1278 flags_cmd_out=f_putcmd;
1279 else
1280 flags_cmd_out=f_putcmd|f_getsta|f_ResponseStatus;
1281 }
1282 else if (fam2_drive)
1283 {
1284 drvcmd[0]=CMD2_READ_ERR;
1285 response_count=6;
1286 flags_cmd_out=f_putcmd;
1287 }
1288 else if (famT_drive)
1289 {
1290 response_count=5;
1291 drvcmd[0]=CMDT_READ_ERR;
1292 }
1293 i=cmd_out();
1294 current_drive->error_byte=0;
1295 msg(DBG_ERR,"cc_ReadError: cmd_out(CMDx_READ_ERR) returns %d (%02X)\n",i,i);
1296 if (i<0) return (i);
1297 if (fam0V_drive) i=1;
1298 else i=2;
1299 current_drive->error_byte=infobuf[i];
1300 msg(DBG_ERR,"cc_ReadError: infobuf[%d] is %d (%02X)\n",i,current_drive->error_byte,current_drive->error_byte);
1301 i=sta2err(infobuf[i]);
1302 if (i==-ERR_DISKCHANGE)
1303 {
1304 current_drive->CD_changed=0xFF;
1305 current_drive->diskstate_flags &= ~toc_bit;
1306 }
1307 return (i);
1308}
1309/*==========================================================================*/
1310static int cc_DriveReset(void);
1311
1312static int cmd_out_T(void)
1313{
1314#undef CMDT_TRIES
1315#define CMDT_TRIES 1000
1316#define TEST_FALSE_FF 1
1317
1318 int i, j, l=0, m, ntries;
1319 unsigned long flags;
1320
1321 current_drive->error_state=0;
1322 current_drive->b3=0;
1323 current_drive->b4=0;
1324 current_drive->f_drv_error=0;
1325 for (i=0;i<10;i++) sprintf(&msgbuf[i*3]," %02X",drvcmd[i]);
1326 msgbuf[i*3]=0;
1327 msg(DBG_CMD,"cmd_out_T:%s\n",msgbuf);
1328
1329 OUT(CDo_sel_i_d,0);
1330 OUT(CDo_enable,current_drive->drv_sel);
1331 i=inb(CDi_status);
1332 do_16bit=0;
1333 if ((f_16bit)&&(!(i&0x80)))
1334 {
1335 do_16bit=1;
1336 msg(DBG_TEA,"cmd_out_T: do_16bit set.\n");
1337 }
1338 if (!(i&s_not_result_ready))
1339 do
1340 {
1341 j=inb(CDi_info);
1342 i=inb(CDi_status);
1343 sbp_sleep(0);
1344 msg(DBG_TEA,"cmd_out_T: spurious !s_not_result_ready. (%02X)\n", j);
1345 }
1346 while (!(i&s_not_result_ready));
1347 save_flags(flags); cli();
1348 for (i=0;i<10;i++) OUT(CDo_command,drvcmd[i]);
1349 restore_flags(flags);
1350 for (ntries=CMDT_TRIES;ntries>0;ntries--)
1351 {
1352 if (drvcmd[0]==CMDT_READ_VER) sbp_sleep(HZ); /* fixme */
1353#if 01
1354 OUT(CDo_sel_i_d,1);
1355#endif /* 01 */
1356 if (teac==2)
1357 {
1358 if ((i=CDi_stat_loop_T()) == -1) break;
1359 }
1360 else
1361 {
1362#if 0
1363 OUT(CDo_sel_i_d,1);
1364#endif /* 0 */
1365 i=inb(CDi_status);
1366 }
1367 if (!(i&s_not_data_ready)) /* f.e. CMDT_DISKINFO */
1368 {
1369 OUT(CDo_sel_i_d,1);
1370 if (drvcmd[0]==CMDT_READ) return (0); /* handled elsewhere */
1371 if (drvcmd[0]==CMDT_DISKINFO)
1372 {
1373 l=0;
1374 do
1375 {
1376 if (do_16bit)
1377 {
1378 i=inw(CDi_data);
1379 infobuf[l++]=i&0x0ff;
1380 infobuf[l++]=i>>8;
1381#if TEST_FALSE_FF
1382 if ((l==2)&&(infobuf[0]==0x0ff))
1383 {
1384 infobuf[0]=infobuf[1];
1385 l=1;
1386 msg(DBG_TEA,"cmd_out_T: do_16bit: false first byte!\n");
1387 }
1388#endif /* TEST_FALSE_FF */
1389 }
1390 else infobuf[l++]=inb(CDi_data);
1391 i=inb(CDi_status);
1392 }
1393 while (!(i&s_not_data_ready));
1394 for (j=0;j<l;j++) sprintf(&msgbuf[j*3]," %02X",infobuf[j]);
1395 msgbuf[j*3]=0;
1396 msg(DBG_CMD,"cmd_out_T data response:%s\n", msgbuf);
1397 }
1398 else
1399 {
1400 msg(DBG_TEA,"cmd_out_T: data response with cmd_%02X!\n",
1401 drvcmd[0]);
1402 j=0;
1403 do
1404 {
1405 if (do_16bit) i=inw(CDi_data);
1406 else i=inb(CDi_data);
1407 j++;
1408 i=inb(CDi_status);
1409 }
1410 while (!(i&s_not_data_ready));
1411 msg(DBG_TEA,"cmd_out_T: data response: discarded %d bytes/words.\n", j);
1412 fatal_err++;
1413 }
1414 }
1415 i=inb(CDi_status);
1416 if (!(i&s_not_result_ready))
1417 {
1418 OUT(CDo_sel_i_d,0);
1419 if (drvcmd[0]==CMDT_DISKINFO) m=l;
1420 else m=0;
1421 do
1422 {
1423 infobuf[m++]=inb(CDi_info);
1424 i=inb(CDi_status);
1425 }
1426 while (!(i&s_not_result_ready));
1427 for (j=0;j<m;j++) sprintf(&msgbuf[j*3]," %02X",infobuf[j]);
1428 msgbuf[j*3]=0;
1429 msg(DBG_CMD,"cmd_out_T info response:%s\n", msgbuf);
1430 if (drvcmd[0]==CMDT_DISKINFO)
1431 {
1432 infobuf[0]=infobuf[l];
1433 if (infobuf[0]!=0x02) return (l); /* data length */
1434 }
1435 else if (infobuf[0]!=0x02) return (m); /* info length */
1436 do
1437 {
1438 ++recursion;
1439 if (recursion>1) msg(DBG_TEA,"cmd_out_T READ_ERR recursion (%02X): %d !!!!!!!!!!!!!!!!!!!!!!!!!!!!!!\n", drvcmd[0], recursion);
1440 clr_cmdbuf();
1441 drvcmd[0]=CMDT_READ_ERR;
1442 j=cmd_out_T(); /* !!! recursive here !!! */
1443 --recursion;
1444 sbp_sleep(1);
1445 }
1446 while (j<0);
1447 current_drive->error_state=infobuf[2];
1448 current_drive->b3=infobuf[3];
1449 current_drive->b4=infobuf[4];
1450 if (current_drive->f_drv_error)
1451 {
1452 current_drive->f_drv_error=0;
1453 cc_DriveReset();
1454 current_drive->error_state=2;
1455 }
1456 return (-current_drive->error_state-400);
1457 }
1458 if (drvcmd[0]==CMDT_READ) return (0); /* handled elsewhere */
1459 if ((teac==0)||(ntries<(CMDT_TRIES-5))) sbp_sleep(HZ/10);
1460 else sbp_sleep(HZ/100);
1461 if (ntries>(CMDT_TRIES-50)) continue;
1462 msg(DBG_TEA,"cmd_out_T: next CMDT_TRIES (%02X): %d.\n", drvcmd[0], ntries-1);
1463 }
1464 current_drive->f_drv_error=1;
1465 cc_DriveReset();
1466 current_drive->error_state=2;
1467 return (-99);
1468}
1469/*==========================================================================*/
1470static int cmd_out(void)
1471{
1472 int i=0;
1473
1474 if (famT_drive) return(cmd_out_T());
1475
1476 if (flags_cmd_out&f_putcmd)
1477 {
1478 unsigned long flags;
1479 for (i=0;i<7;i++)
1480 sprintf(&msgbuf[i*3], " %02X", drvcmd[i]);
1481 msgbuf[i*3]=0;
1482 msg(DBG_CMD,"cmd_out:%s\n", msgbuf);
1483 save_flags(flags); cli();
1484 for (i=0;i<7;i++) OUT(CDo_command,drvcmd[i]);
1485 restore_flags(flags);
1486 }
1487 if (response_count!=0)
1488 {
1489 if (cmd_type!=0)
1490 {
1491 if (sbpro_type==1) OUT(CDo_sel_i_d,1);
1492 msg(DBG_INF,"misleaded to try ResponseData.\n");
1493 if (sbpro_type==1) OUT(CDo_sel_i_d,0);
1494 return (-22);
1495 }
1496 else i=ResponseInfo();
1497 if (i<0) return (i);
1498 }
1499 if (current_drive->in_SpinUp) msg(DBG_SPI,"in_SpinUp: to CDi_stat_loop.\n");
1500 if (flags_cmd_out&f_lopsta)
1501 {
1502 i=CDi_stat_loop();
1503 if ((i<0)||!(i&s_attention)) return (-8);
1504 }
1505 if (!(flags_cmd_out&f_getsta)) goto LOC_229;
1506
1507 LOC_228:
1508 if (current_drive->in_SpinUp) msg(DBG_SPI,"in_SpinUp: to cc_ReadStatus.\n");
1509 cc_ReadStatus();
1510
1511 LOC_229:
1512 if (flags_cmd_out&f_ResponseStatus)
1513 {
1514 if (current_drive->in_SpinUp) msg(DBG_SPI,"in_SpinUp: to ResponseStatus.\n");
1515 i=ResponseStatus();
1516 /* builds status_bits, returns orig. status or p_busy_new */
1517 if (i<0) return (i);
1518 if (flags_cmd_out&(f_bit1|f_wait_if_busy))
1519 {
1520 if (!st_check)
1521 {
1522 if ((flags_cmd_out&f_bit1)&&(i&p_success)) goto LOC_232;
1523 if ((!(flags_cmd_out&f_wait_if_busy))||(!st_busy)) goto LOC_228;
1524 }
1525 }
1526 }
1527 LOC_232:
1528 if (!(flags_cmd_out&f_obey_p_check)) return (0);
1529 if (!st_check) return (0);
1530 if (current_drive->in_SpinUp) msg(DBG_SPI,"in_SpinUp: to cc_ReadError.\n");
1531 i=cc_ReadError();
1532 if (current_drive->in_SpinUp) msg(DBG_SPI,"in_SpinUp: to cmd_out OK.\n");
1533 msg(DBG_000,"cmd_out: cc_ReadError=%d\n", i);
1534 return (i);
1535}
1536/*==========================================================================*/
1537static int cc_Seek(u_int pos, char f_blk_msf)
1538{
1539 int i;
1540
1541 clr_cmdbuf();
1542 if (f_blk_msf>1) return (-3);
1543 if (fam0V_drive)
1544 {
1545 drvcmd[0]=CMD0_SEEK;
1546 if (f_blk_msf==1) pos=msf2blk(pos);
1547 drvcmd[2]=(pos>>16)&0x00FF;
1548 drvcmd[3]=(pos>>8)&0x00FF;
1549 drvcmd[4]=pos&0x00FF;
1550 if (fam0_drive)
1551 flags_cmd_out = f_putcmd | f_respo2 | f_lopsta | f_getsta |
1552 f_ResponseStatus | f_obey_p_check | f_bit1;
1553 else
1554 flags_cmd_out = f_putcmd;
1555 }
1556 else if (fam1L_drive)
1557 {
1558 drvcmd[0]=CMD1_SEEK; /* same as CMD1_ and CMDL_ */
1559 if (f_blk_msf==0) pos=blk2msf(pos);
1560 drvcmd[1]=(pos>>16)&0x00FF;
1561 drvcmd[2]=(pos>>8)&0x00FF;
1562 drvcmd[3]=pos&0x00FF;
1563 if (famL_drive)
1564 flags_cmd_out=f_putcmd|f_respo2|f_lopsta|f_getsta|f_ResponseStatus|f_obey_p_check|f_bit1;
1565 else
1566 flags_cmd_out=f_putcmd|f_respo2|f_ResponseStatus|f_obey_p_check;
1567 }
1568 else if (fam2_drive)
1569 {
1570 drvcmd[0]=CMD2_SEEK;
1571 if (f_blk_msf==0) pos=blk2msf(pos);
1572 drvcmd[2]=(pos>>24)&0x00FF;
1573 drvcmd[3]=(pos>>16)&0x00FF;
1574 drvcmd[4]=(pos>>8)&0x00FF;
1575 drvcmd[5]=pos&0x00FF;
1576 flags_cmd_out=f_putcmd|f_ResponseStatus;
1577 }
1578 else if (famT_drive)
1579 {
1580 drvcmd[0]=CMDT_SEEK;
1581 if (f_blk_msf==1) pos=msf2blk(pos);
1582 drvcmd[2]=(pos>>24)&0x00FF;
1583 drvcmd[3]=(pos>>16)&0x00FF;
1584 drvcmd[4]=(pos>>8)&0x00FF;
1585 drvcmd[5]=pos&0x00FF;
1586 current_drive->n_bytes=1;
1587 }
1588 response_count=0;
1589 i=cmd_out();
1590 return (i);
1591}
1592/*==========================================================================*/
1593static int cc_SpinUp(void)
1594{
1595 int i;
1596
1597 msg(DBG_SPI,"SpinUp.\n");
1598 current_drive->in_SpinUp = 1;
1599 clr_cmdbuf();
1600 if (fam0LV_drive)
1601 {
1602 drvcmd[0]=CMD0_SPINUP;
1603 if (fam0L_drive)
1604 flags_cmd_out=f_putcmd|f_respo2|f_lopsta|f_getsta|
1605 f_ResponseStatus|f_obey_p_check|f_bit1;
1606 else
1607 flags_cmd_out=f_putcmd;
1608 }
1609 else if (fam1_drive)
1610 {
1611 drvcmd[0]=CMD1_SPINUP;
1612 flags_cmd_out=f_putcmd|f_respo2|f_ResponseStatus|f_obey_p_check;
1613 }
1614 else if (fam2_drive)
1615 {
1616 drvcmd[0]=CMD2_TRAY_CTL;
1617 drvcmd[4]=0x01; /* "spinup" */
1618 flags_cmd_out=f_putcmd|f_respo2|f_ResponseStatus|f_obey_p_check;
1619 }
1620 else if (famT_drive)
1621 {
1622 drvcmd[0]=CMDT_TRAY_CTL;
1623 drvcmd[4]=0x03; /* "insert", it hopefully spins the drive up */
1624 }
1625 response_count=0;
1626 i=cmd_out();
1627 current_drive->in_SpinUp = 0;
1628 return (i);
1629}
1630/*==========================================================================*/
1631static int cc_SpinDown(void)
1632{
1633 int i;
1634
1635 if (fam0_drive) return (0);
1636 clr_cmdbuf();
1637 response_count=0;
1638 if (fam1_drive)
1639 {
1640 drvcmd[0]=CMD1_SPINDOWN;
1641 flags_cmd_out=f_putcmd|f_respo2|f_ResponseStatus|f_obey_p_check;
1642 }
1643 else if (fam2_drive)
1644 {
1645 drvcmd[0]=CMD2_TRAY_CTL;
1646 drvcmd[4]=0x02; /* "eject" */
1647 flags_cmd_out=f_putcmd|f_ResponseStatus;
1648 }
1649 else if (famL_drive)
1650 {
1651 drvcmd[0]=CMDL_SPINDOWN;
1652 drvcmd[1]=1;
1653 flags_cmd_out=f_putcmd|f_respo2|f_lopsta|f_getsta|f_ResponseStatus|f_obey_p_check|f_bit1;
1654 }
1655 else if (famV_drive)
1656 {
1657 drvcmd[0]=CMDV_SPINDOWN;
1658 flags_cmd_out=f_putcmd;
1659 }
1660 else if (famT_drive)
1661 {
1662 drvcmd[0]=CMDT_TRAY_CTL;
1663 drvcmd[4]=0x02; /* "eject" */
1664 }
1665 i=cmd_out();
1666 return (i);
1667}
1668/*==========================================================================*/
1669static int cc_get_mode_T(void)
1670{
1671 int i;
1672
1673 clr_cmdbuf();
1674 response_count=10;
1675 drvcmd[0]=CMDT_GETMODE;
1676 drvcmd[4]=response_count;
1677 i=cmd_out_T();
1678 return (i);
1679}
1680/*==========================================================================*/
1681static int cc_set_mode_T(void)
1682{
1683 int i;
1684
1685 clr_cmdbuf();
1686 response_count=1;
1687 drvcmd[0]=CMDT_SETMODE;
1688 drvcmd[1]=current_drive->speed_byte;
1689 drvcmd[2]=current_drive->frmsiz>>8;
1690 drvcmd[3]=current_drive->frmsiz&0x0FF;
1691 drvcmd[4]=current_drive->f_XA; /* 1: XA */
1692 drvcmd[5]=current_drive->type_byte; /* 0, 1, 3 */
1693 drvcmd[6]=current_drive->mode_xb_6;
1694 drvcmd[7]=current_drive->mode_yb_7|current_drive->volume_control;
1695 drvcmd[8]=current_drive->mode_xb_8;
1696 drvcmd[9]=current_drive->delay;
1697 i=cmd_out_T();
1698 return (i);
1699}
1700/*==========================================================================*/
1701static int cc_prep_mode_T(void)
1702{
1703 int i, j;
1704
1705 i=cc_get_mode_T();
1706 if (i<0) return (i);
1707 for (i=0;i<10;i++)
1708 sprintf(&msgbuf[i*3], " %02X", infobuf[i]);
1709 msgbuf[i*3]=0;
1710 msg(DBG_TEA,"CMDT_GETMODE:%s\n", msgbuf);
1711 current_drive->speed_byte=0x02; /* 0x02: auto quad, 0x82: quad, 0x81: double, 0x80: single */
1712 current_drive->frmsiz=make16(infobuf[2],infobuf[3]);
1713 current_drive->f_XA=infobuf[4];
1714 if (current_drive->f_XA==0) current_drive->type_byte=0;
1715 else current_drive->type_byte=1;
1716 current_drive->mode_xb_6=infobuf[6];
1717 current_drive->mode_yb_7=1;
1718 current_drive->mode_xb_8=infobuf[8];
1719 current_drive->delay=0; /* 0, 1, 2, 3 */
1720 j=cc_set_mode_T();
1721 i=cc_get_mode_T();
1722 for (i=0;i<10;i++)
1723 sprintf(&msgbuf[i*3], " %02X", infobuf[i]);
1724 msgbuf[i*3]=0;
1725 msg(DBG_TEA,"CMDT_GETMODE:%s\n", msgbuf);
1726 return (j);
1727}
1728/*==========================================================================*/
1729static int cc_SetSpeed(u_char speed, u_char x1, u_char x2)
1730{
1731 int i;
1732
1733 if (fam0LV_drive) return (0);
1734 clr_cmdbuf();
1735 response_count=0;
1736 if (fam1_drive)
1737 {
1738 drvcmd[0]=CMD1_SETMODE;
1739 drvcmd[1]=0x03;
1740 drvcmd[2]=speed;
1741 drvcmd[3]=x1;
1742 drvcmd[4]=x2;
1743 flags_cmd_out=f_putcmd|f_ResponseStatus|f_obey_p_check;
1744 }
1745 else if (fam2_drive)
1746 {
1747 drvcmd[0]=CMD2_SETSPEED;
1748 if (speed&speed_auto)
1749 {
1750 drvcmd[2]=0xFF;
1751 drvcmd[3]=0xFF;
1752 }
1753 else
1754 {
1755 drvcmd[2]=0;
1756 drvcmd[3]=150;
1757 }
1758 flags_cmd_out=f_putcmd|f_ResponseStatus|f_obey_p_check;
1759 }
1760 else if (famT_drive)
1761 {
1762 return (0);
1763 }
1764 i=cmd_out();
1765 return (i);
1766}
1767/*==========================================================================*/
1768static int cc_SetVolume(void)
1769{
1770 int i;
1771 u_char channel0,channel1,volume0,volume1;
1772 u_char control0,value0,control1,value1;
1773
1774 current_drive->diskstate_flags &= ~volume_bit;
1775 clr_cmdbuf();
1776 channel0=current_drive->vol_chan0;
1777 volume0=current_drive->vol_ctrl0;
1778 channel1=control1=current_drive->vol_chan1;
1779 volume1=value1=current_drive->vol_ctrl1;
1780 control0=value0=0;
1781
1782 if (famV_drive) return (0);
1783
1784 if (((current_drive->drv_options&audio_mono)!=0)&&(current_drive->drv_type>=drv_211))
1785 {
1786 if ((volume0!=0)&&(volume1==0))
1787 {
1788 volume1=volume0;
1789 channel1=channel0;
1790 }
1791 else if ((volume0==0)&&(volume1!=0))
1792 {
1793 volume0=volume1;
1794 channel0=channel1;
1795 }
1796 }
1797 if (channel0>1)
1798 {
1799 channel0=0;
1800 volume0=0;
1801 }
1802 if (channel1>1)
1803 {
1804 channel1=1;
1805 volume1=0;
1806 }
1807
1808 if (fam1_drive)
1809 {
1810 control0=channel0+1;
1811 control1=channel1+1;
1812 value0=(volume0>volume1)?volume0:volume1;
1813 value1=value0;
1814 if (volume0==0) control0=0;
1815 if (volume1==0) control1=0;
1816 drvcmd[0]=CMD1_SETMODE;
1817 drvcmd[1]=0x05;
1818 drvcmd[3]=control0;
1819 drvcmd[4]=value0;
1820 drvcmd[5]=control1;
1821 drvcmd[6]=value1;
1822 flags_cmd_out=f_putcmd|f_ResponseStatus|f_obey_p_check;
1823 }
1824 else if (fam2_drive)
1825 {
1826 control0=channel0+1;
1827 control1=channel1+1;
1828 value0=(volume0>volume1)?volume0:volume1;
1829 value1=value0;
1830 if (volume0==0) control0=0;
1831 if (volume1==0) control1=0;
1832 drvcmd[0]=CMD2_SETMODE;
1833 drvcmd[1]=0x0E;
1834 drvcmd[3]=control0;
1835 drvcmd[4]=value0;
1836 drvcmd[5]=control1;
1837 drvcmd[6]=value1;
1838 flags_cmd_out=f_putcmd|f_ResponseStatus;
1839 }
1840 else if (famL_drive)
1841 {
1842 if ((volume0==0)||(channel0!=0)) control0 |= 0x80;
1843 if ((volume1==0)||(channel1!=1)) control0 |= 0x40;
1844 if (volume0|volume1) value0=0x80;
1845 drvcmd[0]=CMDL_SETMODE;
1846 drvcmd[1]=0x03;
1847 drvcmd[4]=control0;
1848 drvcmd[5]=value0;
1849 flags_cmd_out=f_putcmd|f_lopsta|f_getsta|f_ResponseStatus|f_obey_p_check|f_bit1;
1850 }
1851 else if (fam0_drive) /* different firmware levels */
1852 {
1853 if (current_drive->drv_type>=drv_300)
1854 {
1855 control0=volume0&0xFC;
1856 value0=volume1&0xFC;
1857 if ((volume0!=0)&&(volume0<4)) control0 |= 0x04;
1858 if ((volume1!=0)&&(volume1<4)) value0 |= 0x04;
1859 if (channel0!=0) control0 |= 0x01;
1860 if (channel1==1) value0 |= 0x01;
1861 }
1862 else
1863 {
1864 value0=(volume0>volume1)?volume0:volume1;
1865 if (current_drive->drv_type<drv_211)
1866 {
1867 if (channel0!=0)
1868 {
1869 i=channel1;
1870 channel1=channel0;
1871 channel0=i;
1872 i=volume1;
1873 volume1=volume0;
1874 volume0=i;
1875 }
1876 if (channel0==channel1)
1877 {
1878 if (channel0==0)
1879 {
1880 channel1=1;
1881 volume1=0;
1882 volume0=value0;
1883 }
1884 else
1885 {
1886 channel0=0;
1887 volume0=0;
1888 volume1=value0;
1889 }
1890 }
1891 }
1892
1893 if ((volume0!=0)&&(volume1!=0))
1894 {
1895 if (volume0==0xFF) volume1=0xFF;
1896 else if (volume1==0xFF) volume0=0xFF;
1897 }
1898 else if (current_drive->drv_type<drv_201) volume0=volume1=value0;
1899
1900 if (current_drive->drv_type>=drv_201)
1901 {
1902 if (volume0==0) control0 |= 0x80;
1903 if (volume1==0) control0 |= 0x40;
1904 }
1905 if (current_drive->drv_type>=drv_211)
1906 {
1907 if (channel0!=0) control0 |= 0x20;
1908 if (channel1!=1) control0 |= 0x10;
1909 }
1910 }
1911 drvcmd[0]=CMD0_SETMODE;
1912 drvcmd[1]=0x83;
1913 drvcmd[4]=control0;
1914 drvcmd[5]=value0;
1915 flags_cmd_out=f_putcmd|f_getsta|f_ResponseStatus|f_obey_p_check;
1916 }
1917 else if (famT_drive)
1918 {
1919 current_drive->volume_control=0;
1920 if (!volume0) current_drive->volume_control|=0x10;
1921 if (!volume1) current_drive->volume_control|=0x20;
1922 i=cc_prep_mode_T();
1923 if (i<0) return (i);
1924 }
1925 if (!famT_drive)
1926 {
1927 response_count=0;
1928 i=cmd_out();
1929 if (i<0) return (i);
1930 }
1931 current_drive->diskstate_flags |= volume_bit;
1932 return (0);
1933}
1934/*==========================================================================*/
1935static int GetStatus(void)
1936{
1937 int i;
1938
1939 if (famT_drive) return (0);
1940 flags_cmd_out=f_getsta|f_ResponseStatus|f_obey_p_check;
1941 response_count=0;
1942 cmd_type=0;
1943 i=cmd_out();
1944 return (i);
1945}
1946/*==========================================================================*/
1947static int cc_DriveReset(void)
1948{
1949 int i;
1950
1951 msg(DBG_RES,"cc_DriveReset called.\n");
1952 clr_cmdbuf();
1953 response_count=0;
1954 if (fam0LV_drive) OUT(CDo_reset,0x00);
1955 else if (fam1_drive)
1956 {
1957 drvcmd[0]=CMD1_RESET;
1958 flags_cmd_out=f_putcmd;
1959 i=cmd_out();
1960 }
1961 else if (fam2_drive)
1962 {
1963 drvcmd[0]=CMD2_RESET;
1964 flags_cmd_out=f_putcmd;
1965 i=cmd_out();
1966 OUT(CDo_reset,0x00);
1967 }
1968 else if (famT_drive)
1969 {
1970 OUT(CDo_sel_i_d,0);
1971 OUT(CDo_enable,current_drive->drv_sel);
1972 OUT(CDo_command,CMDT_RESET);
1973 for (i=1;i<10;i++) OUT(CDo_command,0);
1974 }
1975 if (fam0LV_drive) sbp_sleep(5*HZ); /* wait 5 seconds */
1976 else sbp_sleep(1*HZ); /* wait a second */
1977#if 1
1978 if (famT_drive)
1979 {
1980 msg(DBG_TEA, "================CMDT_RESET given=================.\n");
1981 sbp_sleep(3*HZ);
1982 }
1983#endif /* 1 */
1984 flush_status();
1985 i=GetStatus();
1986 if (i<0) return i;
1987 if (!famT_drive)
1988 if (current_drive->error_byte!=aud_12) return -501;
1989 return (0);
1990}
1991
1992/*==========================================================================*/
1993static int SetSpeed(void)
1994{
1995 int i, speed;
1996
1997 if (!(current_drive->drv_options&(speed_auto|speed_300|speed_150))) return (0);
1998 speed=speed_auto;
1999 if (!(current_drive->drv_options&speed_auto))
2000 {
2001 speed |= speed_300;
2002 if (!(current_drive->drv_options&speed_300)) speed=0;
2003 }
2004 i=cc_SetSpeed(speed,0,0);
2005 return (i);
2006}
2007
2008static void switch_drive(struct sbpcd_drive *);
2009
2010static int sbpcd_select_speed(struct cdrom_device_info *cdi, int speed)
2011{
2012 struct sbpcd_drive *p = cdi->handle;
2013 if (p != current_drive)
2014 switch_drive(p);
2015
2016 return cc_SetSpeed(speed == 2 ? speed_300 : speed_150, 0, 0);
2017}
2018
2019/*==========================================================================*/
2020static int DriveReset(void)
2021{
2022 int i;
2023
2024 i=cc_DriveReset();
2025 if (i<0) return (-22);
2026 do
2027 {
2028 i=GetStatus();
2029 if ((i<0)&&(i!=-ERR_DISKCHANGE)) {
2030 return (-2); /* from sta2err */
2031 }
2032 if (!st_caddy_in) break;
2033 sbp_sleep(1);
2034 }
2035 while (!st_diskok);
2036#if 000
2037 current_drive->CD_changed=1;
2038#endif
2039 if ((st_door_closed) && (st_caddy_in))
2040 {
2041 i=DiskInfo();
2042 if (i<0) return (-23);
2043 }
2044 return (0);
2045}
2046
2047static int sbpcd_reset(struct cdrom_device_info *cdi)
2048{
2049 struct sbpcd_drive *p = cdi->handle;
2050 if (p != current_drive)
2051 switch_drive(p);
2052 return DriveReset();
2053}
2054
2055/*==========================================================================*/
2056static int cc_PlayAudio(int pos_audio_start,int pos_audio_end)
2057{
2058 int i, j, n;
2059
2060 if (current_drive->audio_state==audio_playing) return (-EINVAL);
2061 clr_cmdbuf();
2062 response_count=0;
2063 if (famLV_drive)
2064 {
2065 drvcmd[0]=CMDL_PLAY;
2066 i=msf2blk(pos_audio_start);
2067 n=msf2blk(pos_audio_end)+1-i;
2068 drvcmd[1]=(i>>16)&0x00FF;
2069 drvcmd[2]=(i>>8)&0x00FF;
2070 drvcmd[3]=i&0x00FF;
2071 drvcmd[4]=(n>>16)&0x00FF;
2072 drvcmd[5]=(n>>8)&0x00FF;
2073 drvcmd[6]=n&0x00FF;
2074 if (famL_drive)
2075 flags_cmd_out = f_putcmd | f_respo2 | f_lopsta | f_getsta |
2076 f_ResponseStatus | f_obey_p_check | f_wait_if_busy;
2077 else
2078 flags_cmd_out = f_putcmd;
2079 }
2080 else
2081 {
2082 j=1;
2083 if (fam1_drive)
2084 {
2085 drvcmd[0]=CMD1_PLAY_MSF;
2086 flags_cmd_out = f_putcmd | f_respo2 | f_ResponseStatus |
2087 f_obey_p_check | f_wait_if_busy;
2088 }
2089 else if (fam2_drive)
2090 {
2091 drvcmd[0]=CMD2_PLAY_MSF;
2092 flags_cmd_out = f_putcmd | f_ResponseStatus | f_obey_p_check;
2093 }
2094 else if (famT_drive)
2095 {
2096 drvcmd[0]=CMDT_PLAY_MSF;
2097 j=3;
2098 response_count=1;
2099 }
2100 else if (fam0_drive)
2101 {
2102 drvcmd[0]=CMD0_PLAY_MSF;
2103 flags_cmd_out = f_putcmd | f_respo2 | f_lopsta | f_getsta |
2104 f_ResponseStatus | f_obey_p_check | f_wait_if_busy;
2105 }
2106 drvcmd[j]=(pos_audio_start>>16)&0x00FF;
2107 drvcmd[j+1]=(pos_audio_start>>8)&0x00FF;
2108 drvcmd[j+2]=pos_audio_start&0x00FF;
2109 drvcmd[j+3]=(pos_audio_end>>16)&0x00FF;
2110 drvcmd[j+4]=(pos_audio_end>>8)&0x00FF;
2111 drvcmd[j+5]=pos_audio_end&0x00FF;
2112 }
2113 i=cmd_out();
2114 return (i);
2115}
2116/*==========================================================================*/
2117static int cc_Pause_Resume(int pau_res)
2118{
2119 int i;
2120
2121 clr_cmdbuf();
2122 response_count=0;
2123 if (fam1_drive)
2124 {
2125 drvcmd[0]=CMD1_PAU_RES;
2126 if (pau_res!=1) drvcmd[1]=0x80;
2127 flags_cmd_out=f_putcmd|f_respo2|f_ResponseStatus|f_obey_p_check;
2128 }
2129 else if (fam2_drive)
2130 {
2131 drvcmd[0]=CMD2_PAU_RES;
2132 if (pau_res!=1) drvcmd[2]=0x01;
2133 flags_cmd_out=f_putcmd|f_ResponseStatus;
2134 }
2135 else if (fam0LV_drive)
2136 {
2137 drvcmd[0]=CMD0_PAU_RES;
2138 if (pau_res!=1) drvcmd[1]=0x80;
2139 if (famL_drive)
2140 flags_cmd_out=f_putcmd|f_respo2|f_lopsta|f_getsta|f_ResponseStatus|
2141 f_obey_p_check|f_bit1;
2142 else if (famV_drive)
2143 flags_cmd_out=f_putcmd;
2144 else
2145 flags_cmd_out=f_putcmd|f_respo2|f_lopsta|f_getsta|f_ResponseStatus|
2146 f_obey_p_check;
2147 }
2148 else if (famT_drive)
2149 {
2150 if (pau_res==3) return (cc_PlayAudio(current_drive->pos_audio_start,current_drive->pos_audio_end));
2151 else if (pau_res==1) drvcmd[0]=CMDT_PAUSE;
2152 else return (-56);
2153 }
2154 i=cmd_out();
2155 return (i);
2156}
2157/*==========================================================================*/
2158static int cc_LockDoor(char lock)
2159{
2160 int i;
2161
2162 if (fam0_drive) return (0);
2163 msg(DBG_LCK,"cc_LockDoor: %d (drive %d)\n", lock, current_drive - D_S);
2164 msg(DBG_LCS,"p_door_locked bit %d before\n", st_door_locked);
2165 clr_cmdbuf();
2166 response_count=0;
2167 if (fam1_drive)
2168 {
2169 drvcmd[0]=CMD1_LOCK_CTL;
2170 if (lock==1) drvcmd[1]=0x01;
2171 flags_cmd_out=f_putcmd|f_ResponseStatus|f_obey_p_check;
2172 }
2173 else if (fam2_drive)
2174 {
2175 drvcmd[0]=CMD2_LOCK_CTL;
2176 if (lock==1) drvcmd[4]=0x01;
2177 flags_cmd_out=f_putcmd|f_ResponseStatus;
2178 }
2179 else if (famLV_drive)
2180 {
2181 drvcmd[0]=CMDL_LOCK_CTL;
2182 if (lock==1) drvcmd[1]=0x01;
2183 if (famL_drive)
2184 flags_cmd_out=f_putcmd|f_respo2|f_lopsta|f_getsta|f_ResponseStatus|f_obey_p_check|f_bit1;
2185 else
2186 flags_cmd_out=f_putcmd;
2187 }
2188 else if (famT_drive)
2189 {
2190 drvcmd[0]=CMDT_LOCK_CTL;
2191 if (lock==1) drvcmd[4]=0x01;
2192 }
2193 i=cmd_out();
2194 msg(DBG_LCS,"p_door_locked bit %d after\n", st_door_locked);
2195 return (i);
2196}
2197/*==========================================================================*/
2198/*==========================================================================*/
2199static int UnLockDoor(void)
2200{
2201 int i,j;
2202
2203 j=20;
2204 do
2205 {
2206 i=cc_LockDoor(0);
2207 --j;
2208 sbp_sleep(1);
2209 }
2210 while ((i<0)&&(j));
2211 if (i<0)
2212 {
2213 cc_DriveReset();
2214 return -84;
2215 }
2216 return (0);
2217}
2218/*==========================================================================*/
2219static int LockDoor(void)
2220{
2221 int i,j;
2222
2223 j=20;
2224 do
2225 {
2226 i=cc_LockDoor(1);
2227 --j;
2228 sbp_sleep(1);
2229 }
2230 while ((i<0)&&(j));
2231 if (j==0)
2232 {
2233 cc_DriveReset();
2234 j=20;
2235 do
2236 {
2237 i=cc_LockDoor(1);
2238 --j;
2239 sbp_sleep(1);
2240 }
2241 while ((i<0)&&(j));
2242 }
2243 return (i);
2244}
2245
2246static int sbpcd_lock_door(struct cdrom_device_info *cdi, int lock)
2247{
2248 return lock ? LockDoor() : UnLockDoor();
2249}
2250
2251/*==========================================================================*/
2252static int cc_CloseTray(void)
2253{
2254 int i;
2255
2256 if (fam0_drive) return (0);
2257 msg(DBG_LCK,"cc_CloseTray (drive %d)\n", current_drive - D_S);
2258 msg(DBG_LCS,"p_door_closed bit %d before\n", st_door_closed);
2259
2260 clr_cmdbuf();
2261 response_count=0;
2262 if (fam1_drive)
2263 {
2264 drvcmd[0]=CMD1_TRAY_CTL;
2265 flags_cmd_out=f_putcmd|f_respo2|f_ResponseStatus|f_obey_p_check;
2266 }
2267 else if (fam2_drive)
2268 {
2269 drvcmd[0]=CMD2_TRAY_CTL;
2270 drvcmd[1]=0x01;
2271 drvcmd[4]=0x03; /* "insert" */
2272 flags_cmd_out=f_putcmd|f_ResponseStatus;
2273 }
2274 else if (famLV_drive)
2275 {
2276 drvcmd[0]=CMDL_TRAY_CTL;
2277 if (famLV_drive)
2278 flags_cmd_out=f_putcmd|f_respo2|f_lopsta|f_getsta|
2279 f_ResponseStatus|f_obey_p_check|f_bit1;
2280 else
2281 flags_cmd_out=f_putcmd;
2282 }
2283 else if (famT_drive)
2284 {
2285 drvcmd[0]=CMDT_TRAY_CTL;
2286 drvcmd[4]=0x03; /* "insert" */
2287 }
2288 i=cmd_out();
2289 msg(DBG_LCS,"p_door_closed bit %d after\n", st_door_closed);
2290
2291 i=cc_ReadError();
2292 flags_cmd_out |= f_respo2;
2293 cc_ReadStatus(); /* command: give 1-byte status */
2294 i=ResponseStatus();
2295 if (famT_drive&&(i<0))
2296 {
2297 cc_DriveReset();
2298 i=ResponseStatus();
2299#if 0
2300 sbp_sleep(HZ);
2301#endif /* 0 */
2302 i=ResponseStatus();
2303 }
2304 if (i<0)
2305 {
2306 msg(DBG_INF,"sbpcd cc_CloseTray: ResponseStatus timed out (%d).\n",i);
2307 }
2308 if (!(famT_drive))
2309 {
2310 if (!st_spinning)
2311 {
2312 cc_SpinUp();
2313 if (st_check) i=cc_ReadError();
2314 flags_cmd_out |= f_respo2;
2315 cc_ReadStatus();
2316 i=ResponseStatus();
2317 } else {
2318 }
2319 }
2320 i=DiskInfo();
2321 return (i);
2322}
2323
2324static int sbpcd_tray_move(struct cdrom_device_info *cdi, int position)
2325{
2326 int retval=0;
2327 switch_drive(cdi->handle);
2328 /* DUH! --AJK */
2329 if(current_drive->CD_changed != 0xFF) {
2330 current_drive->CD_changed=0xFF;
2331 current_drive->diskstate_flags &= ~cd_size_bit;
2332 }
2333 if (position == 1) {
2334 cc_SpinDown();
2335 } else {
2336 retval=cc_CloseTray();
2337 }
2338 return retval;
2339}
2340
2341/*==========================================================================*/
2342static int cc_ReadSubQ(void)
2343{
2344 int i,j;
2345
2346 current_drive->diskstate_flags &= ~subq_bit;
2347 for (j=255;j>0;j--)
2348 {
2349 clr_cmdbuf();
2350 if (fam1_drive)
2351 {
2352 drvcmd[0]=CMD1_READSUBQ;
2353 flags_cmd_out=f_putcmd|f_ResponseStatus|f_obey_p_check;
2354 response_count=11;
2355 }
2356 else if (fam2_drive)
2357 {
2358 drvcmd[0]=CMD2_READSUBQ;
2359 drvcmd[1]=0x02;
2360 drvcmd[3]=0x01;
2361 flags_cmd_out=f_putcmd;
2362 response_count=10;
2363 }
2364 else if (fam0LV_drive)
2365 {
2366 drvcmd[0]=CMD0_READSUBQ;
2367 drvcmd[1]=0x02;
2368 if (famLV_drive)
2369 flags_cmd_out=f_putcmd;
2370 else
2371 flags_cmd_out=f_putcmd|f_getsta|f_ResponseStatus|f_obey_p_check;
2372 response_count=13;
2373 }
2374 else if (famT_drive)
2375 {
2376 response_count=12;
2377 drvcmd[0]=CMDT_READSUBQ;
2378 drvcmd[1]=0x02;
2379 drvcmd[2]=0x40;
2380 drvcmd[3]=0x01;
2381 drvcmd[8]=response_count;
2382 }
2383 i=cmd_out();
2384 if (i<0) return (i);
2385 for (i=0;i<response_count;i++)
2386 {
2387 sprintf(&msgbuf[i*3], " %02X", infobuf[i]);
2388 msgbuf[i*3]=0;
2389 msg(DBG_SQ1,"cc_ReadSubQ:%s\n", msgbuf);
2390 }
2391 if (famT_drive) break;
2392 if (infobuf[0]!=0) break;
2393 if ((!st_spinning) || (j==1))
2394 {
2395 current_drive->SubQ_ctl_adr=current_drive->SubQ_trk=current_drive->SubQ_pnt_idx=current_drive->SubQ_whatisthis=0;
2396 current_drive->SubQ_run_tot=current_drive->SubQ_run_trk=0;
2397 return (0);
2398 }
2399 }
2400 if (famT_drive) current_drive->SubQ_ctl_adr=infobuf[1];
2401 else current_drive->SubQ_ctl_adr=swap_nibbles(infobuf[1]);
2402 current_drive->SubQ_trk=byt2bcd(infobuf[2]);
2403 current_drive->SubQ_pnt_idx=byt2bcd(infobuf[3]);
2404 if (fam0LV_drive) i=5;
2405 else if (fam12_drive) i=4;
2406 else if (famT_drive) i=8;
2407 current_drive->SubQ_run_tot=make32(make16(0,infobuf[i]),make16(infobuf[i+1],infobuf[i+2])); /* msf-bin */
2408 i=7;
2409 if (fam0LV_drive) i=9;
2410 else if (fam12_drive) i=7;
2411 else if (famT_drive) i=4;
2412 current_drive->SubQ_run_trk=make32(make16(0,infobuf[i]),make16(infobuf[i+1],infobuf[i+2])); /* msf-bin */
2413 current_drive->SubQ_whatisthis=infobuf[i+3];
2414 current_drive->diskstate_flags |= subq_bit;
2415 return (0);
2416}
2417/*==========================================================================*/
2418static int cc_ModeSense(void)
2419{
2420 int i;
2421
2422 if (fam2_drive) return (0);
2423 if (famV_drive) return (0);
2424 current_drive->diskstate_flags &= ~frame_size_bit;
2425 clr_cmdbuf();
2426 if (fam1_drive)
2427 {
2428 response_count=5;
2429 drvcmd[0]=CMD1_GETMODE;
2430 flags_cmd_out=f_putcmd|f_ResponseStatus|f_obey_p_check;
2431 }
2432 else if (fam0L_drive)
2433 {
2434 response_count=2;
2435 drvcmd[0]=CMD0_GETMODE;
2436 if (famL_drive) flags_cmd_out=f_putcmd;
2437 else flags_cmd_out=f_putcmd|f_getsta|f_ResponseStatus|f_obey_p_check;
2438 }
2439 else if (famT_drive)
2440 {
2441 response_count=10;
2442 drvcmd[0]=CMDT_GETMODE;
2443 drvcmd[4]=response_count;
2444 }
2445 i=cmd_out();
2446 if (i<0) return (i);
2447 i=0;
2448 current_drive->sense_byte=0;
2449 if (fam1_drive) current_drive->sense_byte=infobuf[i++];
2450 else if (famT_drive)
2451 {
2452 if (infobuf[4]==0x01) current_drive->xa_byte=0x20;
2453 else current_drive->xa_byte=0;
2454 i=2;
2455 }
2456 current_drive->frame_size=make16(infobuf[i],infobuf[i+1]);
2457 for (i=0;i<response_count;i++)
2458 sprintf(&msgbuf[i*3], " %02X", infobuf[i]);
2459 msgbuf[i*3]=0;
2460 msg(DBG_XA1,"cc_ModeSense:%s\n", msgbuf);
2461
2462 current_drive->diskstate_flags |= frame_size_bit;
2463 return (0);
2464}
2465/*==========================================================================*/
2466/*==========================================================================*/
2467static int cc_ModeSelect(int framesize)
2468{
2469 int i;
2470
2471 if (fam2_drive) return (0);
2472 if (famV_drive) return (0);
2473 current_drive->diskstate_flags &= ~frame_size_bit;
2474 clr_cmdbuf();
2475 current_drive->frame_size=framesize;
2476 if (framesize==CD_FRAMESIZE_RAW) current_drive->sense_byte=0x82;
2477 else current_drive->sense_byte=0x00;
2478
2479 msg(DBG_XA1,"cc_ModeSelect: %02X %04X\n",
2480 current_drive->sense_byte, current_drive->frame_size);
2481
2482 if (fam1_drive)
2483 {
2484 drvcmd[0]=CMD1_SETMODE;
2485 drvcmd[1]=0x00;
2486 drvcmd[2]=current_drive->sense_byte;
2487 drvcmd[3]=(current_drive->frame_size>>8)&0xFF;
2488 drvcmd[4]=current_drive->frame_size&0xFF;
2489 flags_cmd_out=f_putcmd|f_ResponseStatus|f_obey_p_check;
2490 }
2491 else if (fam0L_drive)
2492 {
2493 drvcmd[0]=CMD0_SETMODE;
2494 drvcmd[1]=0x00;
2495 drvcmd[2]=(current_drive->frame_size>>8)&0xFF;
2496 drvcmd[3]=current_drive->frame_size&0xFF;
2497 drvcmd[4]=0x00;
2498 if(famL_drive)
2499 flags_cmd_out=f_putcmd|f_lopsta|f_getsta|f_ResponseStatus|f_obey_p_check;
2500 else
2501 flags_cmd_out=f_putcmd|f_getsta|f_ResponseStatus|f_obey_p_check;
2502 }
2503 else if (famT_drive)
2504 {
2505 return (-1);
2506 }
2507 response_count=0;
2508 i=cmd_out();
2509 if (i<0) return (i);
2510 current_drive->diskstate_flags |= frame_size_bit;
2511 return (0);
2512}
2513/*==========================================================================*/
2514static int cc_GetVolume(void)
2515{
2516 int i;
2517 u_char switches;
2518 u_char chan0=0;
2519 u_char vol0=0;
2520 u_char chan1=1;
2521 u_char vol1=0;
2522
2523 if (famV_drive) return (0);
2524 current_drive->diskstate_flags &= ~volume_bit;
2525 clr_cmdbuf();
2526 if (fam1_drive)
2527 {
2528 drvcmd[0]=CMD1_GETMODE;
2529 drvcmd[1]=0x05;
2530 response_count=5;
2531 flags_cmd_out=f_putcmd|f_ResponseStatus|f_obey_p_check;
2532 }
2533 else if (fam2_drive)
2534 {
2535 drvcmd[0]=CMD2_GETMODE;
2536 drvcmd[1]=0x0E;
2537 response_count=5;
2538 flags_cmd_out=f_putcmd;
2539 }
2540 else if (fam0L_drive)
2541 {
2542 drvcmd[0]=CMD0_GETMODE;
2543 drvcmd[1]=0x03;
2544 response_count=2;
2545 if(famL_drive)
2546 flags_cmd_out=f_putcmd;
2547 else
2548 flags_cmd_out=f_putcmd|f_getsta|f_ResponseStatus|f_obey_p_check;
2549 }
2550 else if (famT_drive)
2551 {
2552 i=cc_get_mode_T();
2553 if (i<0) return (i);
2554 }
2555 if (!famT_drive)
2556 {
2557 i=cmd_out();
2558 if (i<0) return (i);
2559 }
2560 if (fam1_drive)
2561 {
2562 chan0=infobuf[1]&0x0F;
2563 vol0=infobuf[2];
2564 chan1=infobuf[3]&0x0F;
2565 vol1=infobuf[4];
2566 if (chan0==0)
2567 {
2568 chan0=1;
2569 vol0=0;
2570 }
2571 if (chan1==0)
2572 {
2573 chan1=2;
2574 vol1=0;
2575 }
2576 chan0 >>= 1;
2577 chan1 >>= 1;
2578 }
2579 else if (fam2_drive)
2580 {
2581 chan0=infobuf[1];
2582 vol0=infobuf[2];
2583 chan1=infobuf[3];
2584 vol1=infobuf[4];
2585 }
2586 else if (famL_drive)
2587 {
2588 chan0=0;
2589 chan1=1;
2590 vol0=vol1=infobuf[1];
2591 switches=infobuf[0];
2592 if ((switches&0x80)!=0) chan0=1;
2593 if ((switches&0x40)!=0) chan1=0;
2594 }
2595 else if (fam0_drive) /* different firmware levels */
2596 {
2597 chan0=0;
2598 chan1=1;
2599 vol0=vol1=infobuf[1];
2600 if (current_drive->drv_type>=drv_201)
2601 {
2602 if (current_drive->drv_type<drv_300)
2603 {
2604 switches=infobuf[0];
2605 if ((switches&0x80)!=0) vol0=0;
2606 if ((switches&0x40)!=0) vol1=0;
2607 if (current_drive->drv_type>=drv_211)
2608 {
2609 if ((switches&0x20)!=0) chan0=1;
2610 if ((switches&0x10)!=0) chan1=0;
2611 }
2612 }
2613 else
2614 {
2615 vol0=infobuf[0];
2616 if ((vol0&0x01)!=0) chan0=1;
2617 if ((vol1&0x01)==0) chan1=0;
2618 vol0 &= 0xFC;
2619 vol1 &= 0xFC;
2620 if (vol0!=0) vol0 += 3;
2621 if (vol1!=0) vol1 += 3;
2622 }
2623 }
2624 }
2625 else if (famT_drive)
2626 {
2627 current_drive->volume_control=infobuf[7];
2628 chan0=0;
2629 chan1=1;
2630 if (current_drive->volume_control&0x10) vol0=0;
2631 else vol0=0xff;
2632 if (current_drive->volume_control&0x20) vol1=0;
2633 else vol1=0xff;
2634 }
2635 current_drive->vol_chan0=chan0;
2636 current_drive->vol_ctrl0=vol0;
2637 current_drive->vol_chan1=chan1;
2638 current_drive->vol_ctrl1=vol1;
2639#if 000
2640 current_drive->vol_chan2=2;
2641 current_drive->vol_ctrl2=0xFF;
2642 current_drive->vol_chan3=3;
2643 current_drive->vol_ctrl3=0xFF;
2644#endif /* 000 */
2645 current_drive->diskstate_flags |= volume_bit;
2646 return (0);
2647}
2648/*==========================================================================*/
2649static int cc_ReadCapacity(void)
2650{
2651 int i, j;
2652
2653 if (fam2_drive) return (0); /* some firmware lacks this command */
2654 if (famLV_drive) return (0); /* some firmware lacks this command */
2655 if (famT_drive) return (0); /* done with cc_ReadTocDescr() */
2656 current_drive->diskstate_flags &= ~cd_size_bit;
2657 for (j=3;j>0;j--)
2658 {
2659 clr_cmdbuf();
2660 if (fam1_drive)
2661 {
2662 drvcmd[0]=CMD1_CAPACITY;
2663 response_count=5;
2664 flags_cmd_out=f_putcmd|f_ResponseStatus|f_obey_p_check;
2665 }
2666#if 00
2667 else if (fam2_drive)
2668 {
2669 drvcmd[0]=CMD2_CAPACITY;
2670 response_count=8;
2671 flags_cmd_out=f_putcmd;
2672 }
2673#endif
2674 else if (fam0_drive)
2675 {
2676 drvcmd[0]=CMD0_CAPACITY;
2677 response_count=5;
2678 flags_cmd_out=f_putcmd|f_getsta|f_ResponseStatus|f_obey_p_check;
2679 }
2680 i=cmd_out();
2681 if (i>=0) break;
2682 msg(DBG_000,"cc_ReadCapacity: cmd_out: err %d\n", i);
2683 cc_ReadError();
2684 }
2685 if (j==0) return (i);
2686 if (fam1_drive) current_drive->CDsize_frm=msf2blk(make32(make16(0,infobuf[0]),make16(infobuf[1],infobuf[2])))+CD_MSF_OFFSET;
2687 else if (fam0_drive) current_drive->CDsize_frm=make32(make16(0,infobuf[0]),make16(infobuf[1],infobuf[2]));
2688#if 00
2689 else if (fam2_drive) current_drive->CDsize_frm=make32(make16(infobuf[0],infobuf[1]),make16(infobuf[2],infobuf[3]));
2690#endif
2691 current_drive->diskstate_flags |= cd_size_bit;
2692 msg(DBG_000,"cc_ReadCapacity: %d frames.\n", current_drive->CDsize_frm);
2693 return (0);
2694}
2695/*==========================================================================*/
2696static int cc_ReadTocDescr(void)
2697{
2698 int i;
2699
2700 current_drive->diskstate_flags &= ~toc_bit;
2701 clr_cmdbuf();
2702 if (fam1_drive)
2703 {
2704 drvcmd[0]=CMD1_DISKINFO;
2705 response_count=6;
2706 flags_cmd_out=f_putcmd|f_ResponseStatus|f_obey_p_check;
2707 }
2708 else if (fam0LV_drive)
2709 {
2710 drvcmd[0]=CMD0_DISKINFO;
2711 response_count=6;
2712 if(famLV_drive)
2713 flags_cmd_out=f_putcmd;
2714 else
2715 flags_cmd_out=f_putcmd|f_getsta|f_ResponseStatus|f_obey_p_check;
2716 }
2717 else if (fam2_drive)
2718 {
2719 /* possibly longer timeout periods necessary */
2720 current_drive->f_multisession=0;
2721 drvcmd[0]=CMD2_DISKINFO;
2722 drvcmd[1]=0x02;
2723 drvcmd[2]=0xAB;
2724 drvcmd[3]=0xFF; /* session */
2725 response_count=8;
2726 flags_cmd_out=f_putcmd;
2727 }
2728 else if (famT_drive)
2729 {
2730 current_drive->f_multisession=0;
2731 response_count=12;
2732 drvcmd[0]=CMDT_DISKINFO;
2733 drvcmd[1]=0x02;
2734 drvcmd[6]=CDROM_LEADOUT;
2735 drvcmd[8]=response_count;
2736 drvcmd[9]=0x00;
2737 }
2738 i=cmd_out();
2739 if (i<0) return (i);
2740 if ((famT_drive)&&(i<response_count)) return (-100-i);
2741 if ((fam1_drive)||(fam2_drive)||(fam0LV_drive))
2742 current_drive->xa_byte=infobuf[0];
2743 if (fam2_drive)
2744 {
2745 current_drive->first_session=infobuf[1];
2746 current_drive->last_session=infobuf[2];
2747 current_drive->n_first_track=infobuf[3];
2748 current_drive->n_last_track=infobuf[4];
2749 if (current_drive->first_session!=current_drive->last_session)
2750 {
2751 current_drive->f_multisession=1;
2752 current_drive->lba_multi=msf2blk(make32(make16(0,infobuf[5]),make16(infobuf[6],infobuf[7])));
2753 }
2754#if 0
2755 if (current_drive->first_session!=current_drive->last_session)
2756 {
2757 if (current_drive->last_session<=20)
2758 zwanzig=current_drive->last_session+1;
2759 else zwanzig=20;
2760 for (count=current_drive->first_session;count<zwanzig;count++)
2761 {
2762 drvcmd[0]=CMD2_DISKINFO;
2763 drvcmd[1]=0x02;
2764 drvcmd[2]=0xAB;
2765 drvcmd[3]=count;
2766 response_count=8;
2767 flags_cmd_out=f_putcmd;
2768 i=cmd_out();
2769 if (i<0) return (i);
2770 current_drive->msf_multi_n[count]=make32(make16(0,infobuf[5]),make16(infobuf[6],infobuf[7]));
2771 }
2772 current_drive->diskstate_flags |= multisession_bit;
2773 }
2774#endif
2775 drvcmd[0]=CMD2_DISKINFO;
2776 drvcmd[1]=0x02;
2777 drvcmd[2]=0xAA;
2778 drvcmd[3]=0xFF;
2779 response_count=5;
2780 flags_cmd_out=f_putcmd;
2781 i=cmd_out();
2782 if (i<0) return (i);
2783 current_drive->size_msf=make32(make16(0,infobuf[2]),make16(infobuf[3],infobuf[4]));
2784 current_drive->size_blk=msf2blk(current_drive->size_msf);
2785 current_drive->CDsize_frm=current_drive->size_blk+1;
2786 }
2787 else if (famT_drive)
2788 {
2789 current_drive->size_msf=make32(make16(infobuf[8],infobuf[9]),make16(infobuf[10],infobuf[11]));
2790 current_drive->size_blk=msf2blk(current_drive->size_msf);
2791 current_drive->CDsize_frm=current_drive->size_blk+1;
2792 current_drive->n_first_track=infobuf[2];
2793 current_drive->n_last_track=infobuf[3];
2794 }
2795 else
2796 {
2797 current_drive->n_first_track=infobuf[1];
2798 current_drive->n_last_track=infobuf[2];
2799 current_drive->size_msf=make32(make16(0,infobuf[3]),make16(infobuf[4],infobuf[5]));
2800 current_drive->size_blk=msf2blk(current_drive->size_msf);
2801 if (famLV_drive) current_drive->CDsize_frm=current_drive->size_blk+1;
2802 }
2803 current_drive->diskstate_flags |= toc_bit;
2804 msg(DBG_TOC,"TocDesc: xa %02X firstt %02X lastt %02X size %08X firstses %02X lastsess %02X\n",
2805 current_drive->xa_byte,
2806 current_drive->n_first_track,
2807 current_drive->n_last_track,
2808 current_drive->size_msf,
2809 current_drive->first_session,
2810 current_drive->last_session);
2811 return (0);
2812}
2813/*==========================================================================*/
2814static int cc_ReadTocEntry(int num)
2815{
2816 int i;
2817
2818 clr_cmdbuf();
2819 if (fam1_drive)
2820 {
2821 drvcmd[0]=CMD1_READTOC;
2822 drvcmd[2]=num;
2823 response_count=8;
2824 flags_cmd_out=f_putcmd|f_ResponseStatus|f_obey_p_check;
2825 }
2826 else if (fam2_drive)
2827 {
2828 /* possibly longer timeout periods necessary */
2829 drvcmd[0]=CMD2_DISKINFO;
2830 drvcmd[1]=0x02;
2831 drvcmd[2]=num;
2832 response_count=5;
2833 flags_cmd_out=f_putcmd;
2834 }
2835 else if (fam0LV_drive)
2836 {
2837 drvcmd[0]=CMD0_READTOC;
2838 drvcmd[1]=0x02;
2839 drvcmd[2]=num;
2840 response_count=8;
2841 if (famLV_drive)
2842 flags_cmd_out=f_putcmd;
2843 else
2844 flags_cmd_out=f_putcmd|f_getsta|f_ResponseStatus|f_obey_p_check;
2845 }
2846 else if (famT_drive)
2847 {
2848 response_count=12;
2849 drvcmd[0]=CMDT_DISKINFO;
2850 drvcmd[1]=0x02;
2851 drvcmd[6]=num;
2852 drvcmd[8]=response_count;
2853 drvcmd[9]=0x00;
2854 }
2855 i=cmd_out();
2856 if (i<0) return (i);
2857 if ((famT_drive)&&(i<response_count)) return (-100-i);
2858 if ((fam1_drive)||(fam0LV_drive))
2859 {
2860 current_drive->TocEnt_nixbyte=infobuf[0];
2861 i=1;
2862 }
2863 else if (fam2_drive) i=0;
2864 else if (famT_drive) i=5;
2865 current_drive->TocEnt_ctl_adr=swap_nibbles(infobuf[i++]);
2866 if ((fam1_drive)||(fam0L_drive))
2867 {
2868 current_drive->TocEnt_number=infobuf[i++];
2869 current_drive->TocEnt_format=infobuf[i];
2870 }
2871 else
2872 {
2873 current_drive->TocEnt_number=num;
2874 current_drive->TocEnt_format=0;
2875 }
2876 if (fam1_drive) i=4;
2877 else if (fam0LV_drive) i=5;
2878 else if (fam2_drive) i=2;
2879 else if (famT_drive) i=9;
2880 current_drive->TocEnt_address=make32(make16(0,infobuf[i]),
2881 make16(infobuf[i+1],infobuf[i+2]));
2882 for (i=0;i<response_count;i++)
2883 sprintf(&msgbuf[i*3], " %02X", infobuf[i]);
2884 msgbuf[i*3]=0;
2885 msg(DBG_ECS,"TocEntry:%s\n", msgbuf);
2886 msg(DBG_TOC,"TocEntry: %02X %02X %02X %02X %08X\n",
2887 current_drive->TocEnt_nixbyte, current_drive->TocEnt_ctl_adr,
2888 current_drive->TocEnt_number, current_drive->TocEnt_format,
2889 current_drive->TocEnt_address);
2890 return (0);
2891}
2892/*==========================================================================*/
2893static int cc_ReadPacket(void)
2894{
2895 int i;
2896
2897 clr_cmdbuf();
2898 drvcmd[0]=CMD0_PACKET;
2899 drvcmd[1]=response_count;
2900 if(famL_drive) flags_cmd_out=f_putcmd;
2901 else if (fam01_drive)
2902 flags_cmd_out=f_putcmd|f_getsta|f_ResponseStatus|f_obey_p_check;
2903 else if (fam2_drive) return (-1); /* not implemented yet */
2904 else if (famT_drive)
2905 {
2906 return (-1);
2907 }
2908 i=cmd_out();
2909 return (i);
2910}
2911/*==========================================================================*/
2912static int convert_UPC(u_char *p)
2913{
2914 int i;
2915
2916 p++;
2917 if (fam0L_drive) p[13]=0;
2918 for (i=0;i<7;i++)
2919 {
2920 if (fam1_drive) current_drive->UPC_buf[i]=swap_nibbles(*p++);
2921 else if (fam0L_drive)
2922 {
2923 current_drive->UPC_buf[i]=((*p++)<<4)&0xFF;
2924 current_drive->UPC_buf[i] |= *p++;
2925 }
2926 else if (famT_drive)
2927 {
2928 return (-1);
2929 }
2930 else /* CD200 */
2931 {
2932 return (-1);
2933 }
2934 }
2935 current_drive->UPC_buf[6] &= 0xF0;
2936 return (0);
2937}
2938/*==========================================================================*/
2939static int cc_ReadUPC(void)
2940{
2941 int i;
2942#if TEST_UPC
2943 int block, checksum;
2944#endif /* TEST_UPC */
2945
2946 if (fam2_drive) return (0); /* not implemented yet */
2947 if (famT_drive) return (0); /* not implemented yet */
2948 if (famV_drive) return (0); /* not implemented yet */
2949#if 1
2950 if (fam0_drive) return (0); /* but it should work */
2951#endif
2952
2953 current_drive->diskstate_flags &= ~upc_bit;
2954#if TEST_UPC
2955 for (block=CD_MSF_OFFSET+1;block<CD_MSF_OFFSET+200;block++)
2956 {
2957#endif /* TEST_UPC */
2958 clr_cmdbuf();
2959 if (fam1_drive)
2960 {
2961 drvcmd[0]=CMD1_READ_UPC;
2962#if TEST_UPC
2963 drvcmd[1]=(block>>16)&0xFF;
2964 drvcmd[2]=(block>>8)&0xFF;
2965 drvcmd[3]=block&0xFF;
2966#endif /* TEST_UPC */
2967 response_count=8;
2968 flags_cmd_out=f_putcmd|f_ResponseStatus|f_obey_p_check;
2969 }
2970 else if (fam0L_drive)
2971 {
2972 drvcmd[0]=CMD0_READ_UPC;
2973#if TEST_UPC
2974 drvcmd[2]=(block>>16)&0xFF;
2975 drvcmd[3]=(block>>8)&0xFF;
2976 drvcmd[4]=block&0xFF;
2977#endif /* TEST_UPC */
2978 response_count=0;
2979 flags_cmd_out=f_putcmd|f_lopsta|f_getsta|f_ResponseStatus|f_obey_p_check|f_bit1;
2980 }
2981 else if (fam2_drive)
2982 {
2983 return (-1);
2984 }
2985 else if (famT_drive)
2986 {
2987 return (-1);
2988 }
2989 i=cmd_out();
2990 if (i<0)
2991 {
2992 msg(DBG_000,"cc_ReadUPC cmd_out: err %d\n", i);
2993 return (i);
2994 }
2995 if (fam0L_drive)
2996 {
2997 response_count=16;
2998 if (famL_drive) flags_cmd_out=f_putcmd;
2999 i=cc_ReadPacket();
3000 if (i<0)
3001 {
3002 msg(DBG_000,"cc_ReadUPC ReadPacket: err %d\n", i);
3003 return (i);
3004 }
3005 }
3006#if TEST_UPC
3007 checksum=0;
3008#endif /* TEST_UPC */
3009 for (i=0;i<(fam1_drive?8:16);i++)
3010 {
3011#if TEST_UPC
3012 checksum |= infobuf[i];
3013#endif /* TEST_UPC */
3014 sprintf(&msgbuf[i*3], " %02X", infobuf[i]);
3015 }
3016 msgbuf[i*3]=0;
3017 msg(DBG_UPC,"UPC info:%s\n", msgbuf);
3018#if TEST_UPC
3019 if ((checksum&0x7F)!=0) break;
3020 }
3021#endif /* TEST_UPC */
3022 current_drive->UPC_ctl_adr=0;
3023 if (fam1_drive) i=0;
3024 else i=2;
3025 if ((infobuf[i]&0x80)!=0)
3026 {
3027 convert_UPC(&infobuf[i]);
3028 current_drive->UPC_ctl_adr = (current_drive->TocEnt_ctl_adr & 0xF0) | 0x02;
3029 }
3030 for (i=0;i<7;i++)
3031 sprintf(&msgbuf[i*3], " %02X", current_drive->UPC_buf[i]);
3032 sprintf(&msgbuf[i*3], " (%02X)", current_drive->UPC_ctl_adr);
3033 msgbuf[i*3+5]=0;
3034 msg(DBG_UPC,"UPC code:%s\n", msgbuf);
3035 current_drive->diskstate_flags |= upc_bit;
3036 return (0);
3037}
3038
3039static int sbpcd_get_mcn(struct cdrom_device_info *cdi, struct cdrom_mcn *mcn)
3040{
3041 int i;
3042 unsigned char *mcnp = mcn->medium_catalog_number;
3043 unsigned char *resp;
3044
3045 current_drive->diskstate_flags &= ~upc_bit;
3046 clr_cmdbuf();
3047 if (fam1_drive)
3048 {
3049 drvcmd[0]=CMD1_READ_UPC;
3050 response_count=8;
3051 flags_cmd_out=f_putcmd|f_ResponseStatus|f_obey_p_check;
3052 }
3053 else if (fam0L_drive)
3054 {
3055 drvcmd[0]=CMD0_READ_UPC;
3056 response_count=0;
3057 flags_cmd_out=f_putcmd|f_lopsta|f_getsta|f_ResponseStatus|f_obey_p_check|f_bit1;
3058 }
3059 else if (fam2_drive)
3060 {
3061 return (-1);
3062 }
3063 else if (famT_drive)
3064 {
3065 return (-1);
3066 }
3067 i=cmd_out();
3068 if (i<0)
3069 {
3070 msg(DBG_000,"cc_ReadUPC cmd_out: err %d\n", i);
3071 return (i);
3072 }
3073 if (fam0L_drive)
3074 {
3075 response_count=16;
3076 if (famL_drive) flags_cmd_out=f_putcmd;
3077 i=cc_ReadPacket();
3078 if (i<0)
3079 {
3080 msg(DBG_000,"cc_ReadUPC ReadPacket: err %d\n", i);
3081 return (i);
3082 }
3083 }
3084 current_drive->UPC_ctl_adr=0;
3085 if (fam1_drive) i=0;
3086 else i=2;
3087
3088 resp = infobuf + i;
3089 if (*resp++ == 0x80) {
3090 /* packed bcd to single ASCII digits */
3091 *mcnp++ = (*resp >> 4) + '0';
3092 *mcnp++ = (*resp++ & 0x0f) + '0';
3093 *mcnp++ = (*resp >> 4) + '0';
3094 *mcnp++ = (*resp++ & 0x0f) + '0';
3095 *mcnp++ = (*resp >> 4) + '0';
3096 *mcnp++ = (*resp++ & 0x0f) + '0';
3097 *mcnp++ = (*resp >> 4) + '0';
3098 *mcnp++ = (*resp++ & 0x0f) + '0';
3099 *mcnp++ = (*resp >> 4) + '0';
3100 *mcnp++ = (*resp++ & 0x0f) + '0';
3101 *mcnp++ = (*resp >> 4) + '0';
3102 *mcnp++ = (*resp++ & 0x0f) + '0';
3103 *mcnp++ = (*resp >> 4) + '0';
3104 }
3105 *mcnp = '\0';
3106
3107 current_drive->diskstate_flags |= upc_bit;
3108 return (0);
3109}
3110
3111/*==========================================================================*/
3112static int cc_CheckMultiSession(void)
3113{
3114 int i;
3115
3116 if (fam2_drive) return (0);
3117 current_drive->f_multisession=0;
3118 current_drive->lba_multi=0;
3119 if (fam0_drive) return (0);
3120 clr_cmdbuf();
3121 if (fam1_drive)
3122 {
3123 drvcmd[0]=CMD1_MULTISESS;
3124 response_count=6;
3125 flags_cmd_out=f_putcmd|f_ResponseStatus|f_obey_p_check;
3126 i=cmd_out();
3127 if (i<0) return (i);
3128 if ((infobuf[0]&0x80)!=0)
3129 {
3130 current_drive->f_multisession=1;
3131 current_drive->lba_multi=msf2blk(make32(make16(0,infobuf[1]),
3132 make16(infobuf[2],infobuf[3])));
3133 }
3134 }
3135 else if (famLV_drive)
3136 {
3137 drvcmd[0]=CMDL_MULTISESS;
3138 drvcmd[1]=3;
3139 drvcmd[2]=1;
3140 response_count=8;
3141 flags_cmd_out=f_putcmd;
3142 i=cmd_out();
3143 if (i<0) return (i);
3144 current_drive->lba_multi=msf2blk(make32(make16(0,infobuf[5]),
3145 make16(infobuf[6],infobuf[7])));
3146 }
3147 else if (famT_drive)
3148 {
3149 response_count=12;
3150 drvcmd[0]=CMDT_DISKINFO;
3151 drvcmd[1]=0x02;
3152 drvcmd[6]=0;
3153 drvcmd[8]=response_count;
3154 drvcmd[9]=0x40;
3155 i=cmd_out();
3156 if (i<0) return (i);
3157 if (i<response_count) return (-100-i);
3158 current_drive->first_session=infobuf[2];
3159 current_drive->last_session=infobuf[3];
3160 current_drive->track_of_last_session=infobuf[6];
3161 if (current_drive->first_session!=current_drive->last_session)
3162 {
3163 current_drive->f_multisession=1;
3164 current_drive->lba_multi=msf2blk(make32(make16(0,infobuf[9]),make16(infobuf[10],infobuf[11])));
3165 }
3166 }
3167 for (i=0;i<response_count;i++)
3168 sprintf(&msgbuf[i*3], " %02X", infobuf[i]);
3169 msgbuf[i*3]=0;
3170 msg(DBG_MUL,"MultiSession Info:%s (%d)\n", msgbuf, current_drive->lba_multi);
3171 if (current_drive->lba_multi>200)
3172 {
3173 current_drive->f_multisession=1;
3174 msg(DBG_MUL,"MultiSession base: %06X\n", current_drive->lba_multi);
3175 }
3176 return (0);
3177}
3178/*==========================================================================*/
3179#ifdef FUTURE
3180static int cc_SubChanInfo(int frame, int count, u_char *buffer)
3181 /* "frame" is a RED BOOK (msf-bin) address */
3182{
3183 int i;
3184
3185 if (fam0LV_drive) return (-ENOSYS); /* drive firmware lacks it */
3186 if (famT_drive)
3187 {
3188 return (-1);
3189 }
3190#if 0
3191 if (current_drive->audio_state!=audio_playing) return (-ENODATA);
3192#endif
3193 clr_cmdbuf();
3194 drvcmd[0]=CMD1_SUBCHANINF;
3195 drvcmd[1]=(frame>>16)&0xFF;
3196 drvcmd[2]=(frame>>8)&0xFF;
3197 drvcmd[3]=frame&0xFF;
3198 drvcmd[5]=(count>>8)&0xFF;
3199 drvcmd[6]=count&0xFF;
3200 flags_cmd_out=f_putcmd|f_respo2|f_ResponseStatus|f_obey_p_check;
3201 cmd_type=READ_SC;
3202 current_drive->frame_size=CD_FRAMESIZE_SUB;
3203 i=cmd_out(); /* which buffer to use? */
3204 return (i);
3205}
3206#endif /* FUTURE */
3207/*==========================================================================*/
3208static void __init check_datarate(void)
3209{
3210 int i=0;
3211
3212 msg(DBG_IOX,"check_datarate entered.\n");
3213 datarate=0;
3214#if TEST_STI
3215 for (i=0;i<=1000;i++) printk(".");
3216#endif
3217 /* set a timer to make (timed_out_delay!=0) after 1.1 seconds */
3218#if 1
3219 del_timer(&delay_timer);
3220#endif
3221 delay_timer.expires=jiffies+11*HZ/10;
3222 timed_out_delay=0;
3223 add_timer(&delay_timer);
3224#if 0
3225 msg(DBG_TIM,"delay timer started (11*HZ/10).\n");
3226#endif
3227 do
3228 {
3229 i=inb(CDi_status);
3230 datarate++;
3231#if 1
3232 if (datarate>0x6FFFFFFF) break;
3233#endif
3234 }
3235 while (!timed_out_delay);
3236 del_timer(&delay_timer);
3237#if 0
3238 msg(DBG_TIM,"datarate: %04X\n", datarate);
3239#endif
3240 if (datarate<65536) datarate=65536;
3241 maxtim16=datarate*16;
3242 maxtim04=datarate*4;
3243 maxtim02=datarate*2;
3244 maxtim_8=datarate/32;
3245#if LONG_TIMING
3246 maxtim_data=datarate/100;
3247#else
3248 maxtim_data=datarate/300;
3249#endif /* LONG_TIMING */
3250#if 0
3251 msg(DBG_TIM,"maxtim_8 %d, maxtim_data %d.\n", maxtim_8, maxtim_data);
3252#endif
3253}
3254/*==========================================================================*/
3255#if 0
3256static int c2_ReadError(int fam)
3257{
3258 int i;
3259
3260 clr_cmdbuf();
3261 response_count=9;
3262 clr_respo_buf(9);
3263 if (fam==1)
3264 {
3265 drvcmd[0]=CMD0_READ_ERR; /* same as CMD1_ and CMDL_ */
3266 i=do_cmd(f_putcmd|f_lopsta|f_getsta|f_ResponseStatus);
3267 }
3268 else if (fam==2)
3269 {
3270 drvcmd[0]=CMD2_READ_ERR;
3271 i=do_cmd(f_putcmd);
3272 }
3273 else return (-1);
3274 return (i);
3275}
3276#endif
3277/*==========================================================================*/
3278static void __init ask_mail(void)
3279{
3280 int i;
3281
3282 msg(DBG_INF, "please mail the following lines to emoenke@gwdg.de\n");
3283 msg(DBG_INF, "(don't mail if you are not using the actual kernel):\n");
3284 msg(DBG_INF, "%s\n", VERSION);
3285 msg(DBG_INF, "address %03X, type %s, drive %s (ID %d)\n",
3286 CDo_command, type, current_drive->drive_model, current_drive->drv_id);
3287 for (i=0;i<12;i++)
3288 sprintf(&msgbuf[i*3], " %02X", infobuf[i]);
3289 msgbuf[i*3]=0;
3290 msg(DBG_INF,"infobuf =%s\n", msgbuf);
3291 for (i=0;i<12;i++)
3292 sprintf(&msgbuf[i*3], " %c ", infobuf[i]);
3293 msgbuf[i*3]=0;
3294 msg(DBG_INF,"infobuf =%s\n", msgbuf);
3295}
3296/*==========================================================================*/
3297static int __init check_version(void)
3298{
3299 int i, j, l;
3300 int teac_possible=0;
3301
3302 msg(DBG_INI,"check_version: id=%d, d=%d.\n", current_drive->drv_id, current_drive - D_S);
3303 current_drive->drv_type=0;
3304
3305 /* check for CR-52x, CR-56x, LCS-7260 and ECS-AT */
3306 /* clear any pending error state */
3307 clr_cmdbuf();
3308 drvcmd[0]=CMD0_READ_ERR; /* same as CMD1_ and CMDL_ */
3309 response_count=9;
3310 flags_cmd_out=f_putcmd;
3311 i=cmd_out();
3312 if (i<0) msg(DBG_INI,"CMD0_READ_ERR returns %d (ok anyway).\n",i);
3313 /* read drive version */
3314 clr_cmdbuf();
3315 for (i=0;i<12;i++) infobuf[i]=0;
3316 drvcmd[0]=CMD0_READ_VER; /* same as CMD1_ and CMDL_ */
3317 response_count=12; /* fam1: only 11 */
3318 flags_cmd_out=f_putcmd;
3319 i=cmd_out();
3320 if (i<-1) msg(DBG_INI,"CMD0_READ_VER returns %d\n",i);
3321 if (i==-11) teac_possible++;
3322 j=0;
3323 for (i=0;i<12;i++) j+=infobuf[i];
3324 if (j)
3325 {
3326 for (i=0;i<12;i++)
3327 sprintf(&msgbuf[i*3], " %02X", infobuf[i]);
3328 msgbuf[i*3]=0;
3329 msg(DBG_ECS,"infobuf =%s\n", msgbuf);
3330 for (i=0;i<12;i++)
3331 sprintf(&msgbuf[i*3], " %c ", infobuf[i]);
3332 msgbuf[i*3]=0;
3333 msg(DBG_ECS,"infobuf =%s\n", msgbuf);
3334 }
3335 for (i=0;i<4;i++) if (infobuf[i]!=family1[i]) break;
3336 if (i==4)
3337 {
3338 current_drive->drive_model[0]='C';
3339 current_drive->drive_model[1]='R';
3340 current_drive->drive_model[2]='-';
3341 current_drive->drive_model[3]='5';
3342 current_drive->drive_model[4]=infobuf[i++];
3343 current_drive->drive_model[5]=infobuf[i++];
3344 current_drive->drive_model[6]=0;
3345 current_drive->drv_type=drv_fam1;
3346 }
3347 if (!current_drive->drv_type)
3348 {
3349 for (i=0;i<8;i++) if (infobuf[i]!=family0[i]) break;
3350 if (i==8)
3351 {
3352 current_drive->drive_model[0]='C';
3353 current_drive->drive_model[1]='R';
3354 current_drive->drive_model[2]='-';
3355 current_drive->drive_model[3]='5';
3356 current_drive->drive_model[4]='2';
3357 current_drive->drive_model[5]='x';
3358 current_drive->drive_model[6]=0;
3359 current_drive->drv_type=drv_fam0;
3360 }
3361 }
3362 if (!current_drive->drv_type)
3363 {
3364 for (i=0;i<8;i++) if (infobuf[i]!=familyL[i]) break;
3365 if (i==8)
3366 {
3367 for (j=0;j<8;j++)
3368 current_drive->drive_model[j]=infobuf[j];
3369 current_drive->drive_model[8]=0;
3370 current_drive->drv_type=drv_famL;
3371 }
3372 }
3373 if (!current_drive->drv_type)
3374 {
3375 for (i=0;i<6;i++) if (infobuf[i]!=familyV[i]) break;
3376 if (i==6)
3377 {
3378 for (j=0;j<6;j++)
3379 current_drive->drive_model[j]=infobuf[j];
3380 current_drive->drive_model[6]=0;
3381 current_drive->drv_type=drv_famV;
3382 i+=2; /* 2 blanks before version */
3383 }
3384 }
3385 if (!current_drive->drv_type)
3386 {
3387 /* check for CD200 */
3388 clr_cmdbuf();
3389 drvcmd[0]=CMD2_READ_ERR;
3390 response_count=9;
3391 flags_cmd_out=f_putcmd;
3392 i=cmd_out();
3393 if (i<0) msg(DBG_INI,"CMD2_READERR returns %d (ok anyway).\n",i);
3394 if (i<0) msg(DBG_000,"CMD2_READERR returns %d (ok anyway).\n",i);
3395 /* read drive version */
3396 clr_cmdbuf();
3397 for (i=0;i<12;i++) infobuf[i]=0;
3398 if (sbpro_type==1) OUT(CDo_sel_i_d,0);
3399#if 0
3400 OUT(CDo_reset,0);
3401 sbp_sleep(6*HZ);
3402 OUT(CDo_enable,current_drive->drv_sel);
3403#endif
3404 drvcmd[0]=CMD2_READ_VER;
3405 response_count=12;
3406 flags_cmd_out=f_putcmd;
3407 i=cmd_out();
3408 if (i<0) msg(DBG_INI,"CMD2_READ_VER returns %d\n",i);
3409 if (i==-7) teac_possible++;
3410 j=0;
3411 for (i=0;i<12;i++) j+=infobuf[i];
3412 if (j)
3413 {
3414 for (i=0;i<12;i++)
3415 sprintf(&msgbuf[i*3], " %02X", infobuf[i]);
3416 msgbuf[i*3]=0;
3417 msg(DBG_IDX,"infobuf =%s\n", msgbuf);
3418 for (i=0;i<12;i++)
3419 sprintf(&msgbuf[i*3], " %c ", infobuf[i]);
3420 msgbuf[i*3]=0;
3421 msg(DBG_IDX,"infobuf =%s\n", msgbuf);
3422 }
3423 if (i>=0)
3424 {
3425 for (i=0;i<5;i++) if (infobuf[i]!=family2[i]) break;
3426 if (i==5)
3427 {
3428 current_drive->drive_model[0]='C';
3429 current_drive->drive_model[1]='D';
3430 current_drive->drive_model[2]='2';
3431 current_drive->drive_model[3]='0';
3432 current_drive->drive_model[4]='0';
3433 current_drive->drive_model[5]=infobuf[i++];
3434 current_drive->drive_model[6]=infobuf[i++];
3435 current_drive->drive_model[7]=0;
3436 current_drive->drv_type=drv_fam2;
3437 }
3438 }
3439 }
3440 if (!current_drive->drv_type)
3441 {
3442 /* check for TEAC CD-55A */
3443 msg(DBG_TEA,"teac_possible: %d\n",teac_possible);
3444 for (j=1;j<=((current_drive->drv_id==0)?3:1);j++)
3445 {
3446 for (l=1;l<=((current_drive->drv_id==0)?10:1);l++)
3447 {
3448 msg(DBG_TEA,"TEAC reset #%d-%d.\n", j, l);
3449 if (sbpro_type==1) OUT(CDo_reset,0);
3450 else
3451 {
3452 OUT(CDo_enable,current_drive->drv_sel);
3453 OUT(CDo_sel_i_d,0);
3454 OUT(CDo_command,CMDT_RESET);
3455 for (i=0;i<9;i++) OUT(CDo_command,0);
3456 }
3457 sbp_sleep(5*HZ/10);
3458 OUT(CDo_enable,current_drive->drv_sel);
3459 OUT(CDo_sel_i_d,0);
3460 i=inb(CDi_status);
3461 msg(DBG_TEA,"TEAC CDi_status: %02X.\n",i);
3462#if 0
3463 if (i&s_not_result_ready) continue; /* drive not present or ready */
3464#endif
3465 i=inb(CDi_info);
3466 msg(DBG_TEA,"TEAC CDi_info: %02X.\n",i);
3467 if (i==0x55) break; /* drive found */
3468 }
3469 if (i==0x55) break; /* drive found */
3470 }
3471 if (i==0x55) /* drive found */
3472 {
3473 msg(DBG_TEA,"TEAC drive found.\n");
3474 clr_cmdbuf();
3475 flags_cmd_out=f_putcmd;
3476 response_count=12;
3477 drvcmd[0]=CMDT_READ_VER;
3478 drvcmd[4]=response_count;
3479 for (i=0;i<12;i++) infobuf[i]=0;
3480 i=cmd_out_T();
3481 if (i!=0) msg(DBG_TEA,"cmd_out_T(CMDT_READ_VER) returns %d.\n",i);
3482 for (i=1;i<6;i++) if (infobuf[i]!=familyT[i-1]) break;
3483 if (i==6)
3484 {
3485 current_drive->drive_model[0]='C';
3486 current_drive->drive_model[1]='D';
3487 current_drive->drive_model[2]='-';
3488 current_drive->drive_model[3]='5';
3489 current_drive->drive_model[4]='5';
3490 current_drive->drive_model[5]=0;
3491 current_drive->drv_type=drv_famT;
3492 }
3493 }
3494 }
3495 if (!current_drive->drv_type)
3496 {
3497 msg(DBG_TEA,"no drive found at address %03X under ID %d.\n",CDo_command,current_drive->drv_id);
3498 return (-522);
3499 }
3500 for (j=0;j<4;j++) current_drive->firmware_version[j]=infobuf[i+j];
3501 if (famL_drive)
3502 {
3503 u_char lcs_firm_e1[]="A E1";
3504 u_char lcs_firm_f4[]="A4F4";
3505
3506 for (j=0;j<4;j++)
3507 if (current_drive->firmware_version[j]!=lcs_firm_e1[j]) break;
3508 if (j==4) current_drive->drv_type=drv_e1;
3509
3510 for (j=0;j<4;j++)
3511 if (current_drive->firmware_version[j]!=lcs_firm_f4[j]) break;
3512 if (j==4) current_drive->drv_type=drv_f4;
3513
3514 if (current_drive->drv_type==drv_famL) ask_mail();
3515 }
3516 else if (famT_drive)
3517 {
3518 j=infobuf[4]; /* one-byte version??? - here: 0x15 */
3519 if (j=='5')
3520 {
3521 current_drive->firmware_version[0]=infobuf[7];
3522 current_drive->firmware_version[1]=infobuf[8];
3523 current_drive->firmware_version[2]=infobuf[10];
3524 current_drive->firmware_version[3]=infobuf[11];
3525 }
3526 else
3527 {
3528 if (j!=0x15) ask_mail();
3529 current_drive->firmware_version[0]='0';
3530 current_drive->firmware_version[1]='.';
3531 current_drive->firmware_version[2]='0'+(j>>4);
3532 current_drive->firmware_version[3]='0'+(j&0x0f);
3533 }
3534 }
3535 else /* CR-52x, CR-56x, CD200, ECS-AT */
3536 {
3537 j = (current_drive->firmware_version[0] & 0x0F) * 100 +
3538 (current_drive->firmware_version[2] & 0x0F) *10 +
3539 (current_drive->firmware_version[3] & 0x0F);
3540 if (fam0_drive)
3541 {
3542 if (j<200) current_drive->drv_type=drv_199;
3543 else if (j<201) current_drive->drv_type=drv_200;
3544 else if (j<210) current_drive->drv_type=drv_201;
3545 else if (j<211) current_drive->drv_type=drv_210;
3546 else if (j<300) current_drive->drv_type=drv_211;
3547 else if (j>=300) current_drive->drv_type=drv_300;
3548 }
3549 else if (fam1_drive)
3550 {
3551 if (j<100) current_drive->drv_type=drv_099;
3552 else
3553 {
3554 current_drive->drv_type=drv_100;
3555 if ((j!=500)&&(j!=102)) ask_mail();
3556 }
3557 }
3558 else if (fam2_drive)
3559 {
3560 if (current_drive->drive_model[5]=='F')
3561 {
3562 if ((j!=1)&&(j!=35)&&(j!=200)&&(j!=210))
3563 ask_mail(); /* unknown version at time */
3564 }
3565 else
3566 {
3567 msg(DBG_INF,"this CD200 drive is not fully supported yet - only audio will work.\n");
3568 if ((j!=101)&&(j!=35))
3569 ask_mail(); /* unknown version at time */
3570 }
3571 }
3572 else if (famV_drive)
3573 {
3574 if ((j==100)||(j==150)) current_drive->drv_type=drv_at;
3575 ask_mail(); /* hopefully we get some feedback by this */
3576 }
3577 }
3578 msg(DBG_LCS,"drive type %02X\n",current_drive->drv_type);
3579 msg(DBG_INI,"check_version done.\n");
3580 return (0);
3581}
3582/*==========================================================================*/
3583static void switch_drive(struct sbpcd_drive *p)
3584{
3585 current_drive = p;
3586 OUT(CDo_enable,current_drive->drv_sel);
3587 msg(DBG_DID,"drive %d (ID=%d) activated.\n",
3588 current_drive - D_S, current_drive->drv_id);
3589 return;
3590}
3591/*==========================================================================*/
3592#ifdef PATH_CHECK
3593/*
3594 * probe for the presence of an interface card
3595 */
3596static int __init check_card(int port)
3597{
3598#undef N_RESPO
3599#define N_RESPO 20
3600 int i, j, k;
3601 u_char response[N_RESPO];
3602 u_char save_port0;
3603 u_char save_port3;
3604
3605 msg(DBG_INI,"check_card entered.\n");
3606 save_port0=inb(port+0);
3607 save_port3=inb(port+3);
3608
3609 for (j=0;j<NR_SBPCD;j++)
3610 {
3611 OUT(port+3,j) ; /* enable drive #j */
3612 OUT(port+0,CMD0_PATH_CHECK);
3613 for (i=10;i>0;i--) OUT(port+0,0);
3614 for (k=0;k<N_RESPO;k++) response[k]=0;
3615 for (k=0;k<N_RESPO;k++)
3616 {
3617 for (i=10000;i>0;i--)
3618 {
3619 if (inb(port+1)&s_not_result_ready) continue;
3620 response[k]=inb(port+0);
3621 break;
3622 }
3623 }
3624 for (i=0;i<N_RESPO;i++)
3625 sprintf(&msgbuf[i*3], " %02X", response[i]);
3626 msgbuf[i*3]=0;
3627 msg(DBG_TEA,"path check 00 (%d): %s\n", j, msgbuf);
3628 OUT(port+0,CMD0_PATH_CHECK);
3629 for (i=10;i>0;i--) OUT(port+0,0);
3630 for (k=0;k<N_RESPO;k++) response[k]=0xFF;
3631 for (k=0;k<N_RESPO;k++)
3632 {
3633 for (i=10000;i>0;i--)
3634 {
3635 if (inb(port+1)&s_not_result_ready) continue;
3636 response[k]=inb(port+0);
3637 break;
3638 }
3639 }
3640 for (i=0;i<N_RESPO;i++)
3641 sprintf(&msgbuf[i*3], " %02X", response[i]);
3642 msgbuf[i*3]=0;
3643 msg(DBG_TEA,"path check 00 (%d): %s\n", j, msgbuf);
3644
3645 if (response[0]==0xAA)
3646 if (response[1]==0x55)
3647 return (0);
3648 }
3649 for (j=0;j<NR_SBPCD;j++)
3650 {
3651 OUT(port+3,j) ; /* enable drive #j */
3652 OUT(port+0,CMD2_READ_VER);
3653 for (i=10;i>0;i--) OUT(port+0,0);
3654 for (k=0;k<N_RESPO;k++) response[k]=0;
3655 for (k=0;k<N_RESPO;k++)
3656 {
3657 for (i=1000000;i>0;i--)
3658 {
3659 if (inb(port+1)&s_not_result_ready) continue;
3660 response[k]=inb(port+0);
3661 break;
3662 }
3663 }
3664 for (i=0;i<N_RESPO;i++)
3665 sprintf(&msgbuf[i*3], " %02X", response[i]);
3666 msgbuf[i*3]=0;
3667 msg(DBG_TEA,"path check 12 (%d): %s\n", j, msgbuf);
3668
3669 OUT(port+0,CMD2_READ_VER);
3670 for (i=10;i>0;i--) OUT(port+0,0);
3671 for (k=0;k<N_RESPO;k++) response[k]=0xFF;
3672 for (k=0;k<N_RESPO;k++)
3673 {
3674 for (i=1000000;i>0;i--)
3675 {
3676 if (inb(port+1)&s_not_result_ready) continue;
3677 response[k]=inb(port+0);
3678 break;
3679 }
3680 }
3681 for (i=0;i<N_RESPO;i++)
3682 sprintf(&msgbuf[i*3], " %02X", response[i]);
3683 msgbuf[i*3]=0;
3684 msg(DBG_TEA,"path check 12 (%d): %s\n", j, msgbuf);
3685
3686 if (response[0]==0xAA)
3687 if (response[1]==0x55)
3688 return (0);
3689 }
3690 OUT(port+0,save_port0);
3691 OUT(port+3,save_port3);
3692 return (0); /* in any case - no real "function" at time */
3693}
3694#endif /* PATH_CHECK */
3695/*==========================================================================*/
3696/*==========================================================================*/
3697/*
3698 * probe for the presence of drives on the selected controller
3699 */
3700static int __init check_drives(void)
3701{
3702 int i, j;
3703
3704 msg(DBG_INI,"check_drives entered.\n");
3705 ndrives=0;
3706 for (j=0;j<max_drives;j++)
3707 {
3708 struct sbpcd_drive *p = D_S + ndrives;
3709 p->drv_id=j;
3710 if (sbpro_type==1) p->drv_sel=(j&0x01)<<1|(j&0x02)>>1;
3711 else p->drv_sel=j;
3712 switch_drive(p);
3713 msg(DBG_INI,"check_drives: drive %d (ID=%d) activated.\n",ndrives,j);
3714 msg(DBG_000,"check_drives: drive %d (ID=%d) activated.\n",ndrives,j);
3715 i=check_version();
3716 if (i<0) msg(DBG_INI,"check_version returns %d.\n",i);
3717 else
3718 {
3719 current_drive->drv_options=drv_pattern[j];
3720 if (fam0L_drive) current_drive->drv_options&=~(speed_auto|speed_300|speed_150);
3721 msg(DBG_INF, "Drive %d (ID=%d): %.9s (%.4s) at 0x%03X (type %d)\n",
3722 current_drive - D_S,
3723 current_drive->drv_id,
3724 current_drive->drive_model,
3725 current_drive->firmware_version,
3726 CDo_command,
3727 sbpro_type);
3728 ndrives++;
3729 }
3730 }
3731 for (j=ndrives;j<NR_SBPCD;j++) D_S[j].drv_id=-1;
3732 if (ndrives==0) return (-1);
3733 return (0);
3734}
3735/*==========================================================================*/
3736#ifdef FUTURE
3737/*
3738 * obtain if requested service disturbs current audio state
3739 */
3740static int obey_audio_state(u_char audio_state, u_char func,u_char subfunc)
3741{
3742 switch (audio_state) /* audio status from controller */
3743 {
3744 case aud_11: /* "audio play in progress" */
3745 case audx11:
3746 switch (func) /* DOS command code */
3747 {
3748 case cmd_07: /* input flush */
3749 case cmd_0d: /* open device */
3750 case cmd_0e: /* close device */
3751 case cmd_0c: /* ioctl output */
3752 return (1);
3753 case cmd_03: /* ioctl input */
3754 switch (subfunc)
3755 /* DOS ioctl input subfunction */
3756 {
3757 case cxi_00:
3758 case cxi_06:
3759 case cxi_09:
3760 return (1);
3761 default:
3762 return (ERROR15);
3763 }
3764 return (1);
3765 default:
3766 return (ERROR15);
3767 }
3768 return (1);
3769 case aud_12: /* "audio play paused" */
3770 case audx12:
3771 return (1);
3772 default:
3773 return (2);
3774 }
3775}
3776/*==========================================================================*/
3777/* allowed is only
3778 * ioctl_o, flush_input, open_device, close_device,
3779 * tell_address, tell_volume, tell_capabiliti,
3780 * tell_framesize, tell_CD_changed, tell_audio_posi
3781 */
3782static int check_allowed1(u_char func1, u_char func2)
3783{
3784#if 000
3785 if (func1==ioctl_o) return (0);
3786 if (func1==read_long) return (-1);
3787 if (func1==read_long_prefetch) return (-1);
3788 if (func1==seek) return (-1);
3789 if (func1==audio_play) return (-1);
3790 if (func1==audio_pause) return (-1);
3791 if (func1==audio_resume) return (-1);
3792 if (func1!=ioctl_i) return (0);
3793 if (func2==tell_SubQ_run_tot) return (-1);
3794 if (func2==tell_cdsize) return (-1);
3795 if (func2==tell_TocDescrip) return (-1);
3796 if (func2==tell_TocEntry) return (-1);
3797 if (func2==tell_subQ_info) return (-1);
3798 if (fam1_drive) if (func2==tell_SubChanInfo) return (-1);
3799 if (func2==tell_UPC) return (-1);
3800#else
3801 return (0);
3802#endif
3803}
3804/*==========================================================================*/
3805static int check_allowed2(u_char func1, u_char func2)
3806{
3807#if 000
3808 if (func1==read_long) return (-1);
3809 if (func1==read_long_prefetch) return (-1);
3810 if (func1==seek) return (-1);
3811 if (func1==audio_play) return (-1);
3812 if (func1!=ioctl_o) return (0);
3813 if (fam1_drive)
3814 {
3815 if (func2==EjectDisk) return (-1);
3816 if (func2==CloseTray) return (-1);
3817 }
3818#else
3819 return (0);
3820#endif
3821}
3822/*==========================================================================*/
3823static int check_allowed3(u_char func1, u_char func2)
3824{
3825#if 000
3826 if (func1==ioctl_i)
3827 {
3828 if (func2==tell_address) return (0);
3829 if (func2==tell_capabiliti) return (0);
3830 if (func2==tell_CD_changed) return (0);
3831 if (fam0L_drive) if (func2==tell_SubChanInfo) return (0);
3832 return (-1);
3833 }
3834 if (func1==ioctl_o)
3835 {
3836 if (func2==DriveReset) return (0);
3837 if (fam0L_drive)
3838 {
3839 if (func2==EjectDisk) return (0);
3840 if (func2==LockDoor) return (0);
3841 if (func2==CloseTray) return (0);
3842 }
3843 return (-1);
3844 }
3845 if (func1==flush_input) return (-1);
3846 if (func1==read_long) return (-1);
3847 if (func1==read_long_prefetch) return (-1);
3848 if (func1==seek) return (-1);
3849 if (func1==audio_play) return (-1);
3850 if (func1==audio_pause) return (-1);
3851 if (func1==audio_resume) return (-1);
3852#else
3853 return (0);
3854#endif
3855}
3856/*==========================================================================*/
3857static int seek_pos_audio_end(void)
3858{
3859 int i;
3860
3861 i=msf2blk(current_drive->pos_audio_end)-1;
3862 if (i<0) return (-1);
3863 i=cc_Seek(i,0);
3864 return (i);
3865}
3866#endif /* FUTURE */
3867/*==========================================================================*/
3868static int ReadToC(void)
3869{
3870 int i, j;
3871 current_drive->diskstate_flags &= ~toc_bit;
3872 current_drive->ored_ctl_adr=0;
3873 /* special handling of CD-I HE */
3874 if ((current_drive->n_first_track == 2 && current_drive->n_last_track == 2) ||
3875 current_drive->xa_byte == 0x10)
3876 {
3877 current_drive->TocBuffer[1].nixbyte=0;
3878 current_drive->TocBuffer[1].ctl_adr=0x40;
3879 current_drive->TocBuffer[1].number=1;
3880 current_drive->TocBuffer[1].format=0;
3881 current_drive->TocBuffer[1].address=blk2msf(0);
3882 current_drive->ored_ctl_adr |= 0x40;
3883 current_drive->n_first_track = 1;
3884 current_drive->n_last_track = 1;
3885 current_drive->xa_byte = 0x10;
3886 j = 2;
3887 } else
3888 for (j=current_drive->n_first_track;j<=current_drive->n_last_track;j++)
3889 {
3890 i=cc_ReadTocEntry(j);
3891 if (i<0)
3892 {
3893 msg(DBG_INF,"cc_ReadTocEntry(%d) returns %d.\n",j,i);
3894 return (i);
3895 }
3896 current_drive->TocBuffer[j].nixbyte=current_drive->TocEnt_nixbyte;
3897 current_drive->TocBuffer[j].ctl_adr=current_drive->TocEnt_ctl_adr;
3898 current_drive->TocBuffer[j].number=current_drive->TocEnt_number;
3899 current_drive->TocBuffer[j].format=current_drive->TocEnt_format;
3900 current_drive->TocBuffer[j].address=current_drive->TocEnt_address;
3901 current_drive->ored_ctl_adr |= current_drive->TocEnt_ctl_adr;
3902 }
3903 /* fake entry for LeadOut Track */
3904 current_drive->TocBuffer[j].nixbyte=0;
3905 current_drive->TocBuffer[j].ctl_adr=0;
3906 current_drive->TocBuffer[j].number=CDROM_LEADOUT;
3907 current_drive->TocBuffer[j].format=0;
3908 current_drive->TocBuffer[j].address=current_drive->size_msf;
3909
3910 current_drive->diskstate_flags |= toc_bit;
3911 return (0);
3912}
3913/*==========================================================================*/
3914static int DiskInfo(void)
3915{
3916 int i, j;
3917
3918 current_drive->mode=READ_M1;
3919
3920#undef LOOP_COUNT
3921#define LOOP_COUNT 10 /* needed for some "old" drives */
3922
3923 msg(DBG_000,"DiskInfo entered.\n");
3924 for (j=1;j<LOOP_COUNT;j++)
3925 {
3926#if 0
3927 i=SetSpeed();
3928 if (i<0)
3929 {
3930 msg(DBG_INF,"DiskInfo: SetSpeed returns %d\n", i);
3931 continue;
3932 }
3933 i=cc_ModeSense();
3934 if (i<0)
3935 {
3936 msg(DBG_INF,"DiskInfo: cc_ModeSense returns %d\n", i);
3937 continue;
3938 }
3939#endif
3940 i=cc_ReadCapacity();
3941 if (i>=0) break;
3942 msg(DBG_INF,"DiskInfo: ReadCapacity #%d returns %d\n", j, i);
3943#if 0
3944 i=cc_DriveReset();
3945#endif
3946 if (!fam0_drive && j == 2) break;
3947 }
3948 if (j==LOOP_COUNT) return (-33); /* give up */
3949
3950 i=cc_ReadTocDescr();
3951 if (i<0)
3952 {
3953 msg(DBG_INF,"DiskInfo: ReadTocDescr returns %d\n", i);
3954 return (i);
3955 }
3956 i=ReadToC();
3957 if (i<0)
3958 {
3959 msg(DBG_INF,"DiskInfo: ReadToC returns %d\n", i);
3960 return (i);
3961 }
3962 i=cc_CheckMultiSession();
3963 if (i<0)
3964 {
3965 msg(DBG_INF,"DiskInfo: cc_CheckMultiSession returns %d\n", i);
3966 return (i);
3967 }
3968 if (current_drive->f_multisession) current_drive->sbp_bufsiz=1; /* possibly a weird PhotoCD */
3969 else current_drive->sbp_bufsiz=buffers;
3970 i=cc_ReadTocEntry(current_drive->n_first_track);
3971 if (i<0)
3972 {
3973 msg(DBG_INF,"DiskInfo: cc_ReadTocEntry(1) returns %d\n", i);
3974 return (i);
3975 }
3976 i=cc_ReadUPC();
3977 if (i<0) msg(DBG_INF,"DiskInfo: cc_ReadUPC returns %d\n", i);
3978 if ((fam0L_drive) && (current_drive->xa_byte==0x20 || current_drive->xa_byte == 0x10))
3979 {
3980 /* XA disk with old drive */
3981 cc_ModeSelect(CD_FRAMESIZE_RAW1);
3982 cc_ModeSense();
3983 }
3984 if (famT_drive) cc_prep_mode_T();
3985 msg(DBG_000,"DiskInfo done.\n");
3986 return (0);
3987}
3988
3989static int sbpcd_drive_status(struct cdrom_device_info *cdi, int slot_nr)
3990{
3991 struct sbpcd_drive *p = cdi->handle;
3992 int st;
3993
3994 if (CDSL_CURRENT != slot_nr) {
3995 /* we have no changer support */
3996 return -EINVAL;
3997 }
3998
3999 cc_ReadStatus();
4000 st=ResponseStatus();
4001 if (st<0)
4002 {
4003 msg(DBG_INF,"sbpcd_drive_status: timeout.\n");
4004 return (0);
4005 }
4006 msg(DBG_000,"Drive Status: door_locked =%d.\n", st_door_locked);
4007 msg(DBG_000,"Drive Status: door_closed =%d.\n", st_door_closed);
4008 msg(DBG_000,"Drive Status: caddy_in =%d.\n", st_caddy_in);
4009 msg(DBG_000,"Drive Status: disk_ok =%d.\n", st_diskok);
4010 msg(DBG_000,"Drive Status: spinning =%d.\n", st_spinning);
4011 msg(DBG_000,"Drive Status: busy =%d.\n", st_busy);
4012
4013#if 0
4014 if (!(p->status_bits & p_door_closed)) return CDS_TRAY_OPEN;
4015 if (p->status_bits & p_disk_ok) return CDS_DISC_OK;
4016 if (p->status_bits & p_disk_in) return CDS_DRIVE_NOT_READY;
4017
4018 return CDS_NO_DISC;
4019#else
4020 if (p->status_bits & p_spinning) return CDS_DISC_OK;
4021/* return CDS_TRAY_OPEN; */
4022 return CDS_NO_DISC;
4023
4024#endif
4025
4026}
4027
4028
4029/*==========================================================================*/
4030#ifdef FUTURE
4031/*
4032 * called always if driver gets entered
4033 * returns 0 or ERROR2 or ERROR15
4034 */
4035static int prepare(u_char func, u_char subfunc)
4036{
4037 int i;
4038
4039 if (fam0L_drive)
4040 {
4041 i=inb(CDi_status);
4042 if (i&s_attention) GetStatus();
4043 }
4044 else if (fam1_drive) GetStatus();
4045 else if (fam2_drive) GetStatus();
4046 else if (famT_drive) GetStatus();
4047 if (current_drive->CD_changed==0xFF)
4048 {
4049 current_drive->diskstate_flags=0;
4050 current_drive->audio_state=0;
4051 if (!st_diskok)
4052 {
4053 i=check_allowed1(func,subfunc);
4054 if (i<0) return (-2);
4055 }
4056 else
4057 {
4058 i=check_allowed3(func,subfunc);
4059 if (i<0)
4060 {
4061 current_drive->CD_changed=1;
4062 return (-15);
4063 }
4064 }
4065 }
4066 else
4067 {
4068 if (!st_diskok)
4069 {
4070 current_drive->diskstate_flags=0;
4071 current_drive->audio_state=0;
4072 i=check_allowed1(func,subfunc);
4073 if (i<0) return (-2);
4074 }
4075 else
4076 {
4077 if (st_busy)
4078 {
4079 if (current_drive->audio_state!=audio_pausing)
4080 {
4081 i=check_allowed2(func,subfunc);
4082 if (i<0) return (-2);
4083 }
4084 }
4085 else
4086 {
4087 if (current_drive->audio_state==audio_playing) seek_pos_audio_end();
4088 current_drive->audio_state=0;
4089 }
4090 if (!frame_size_valid)
4091 {
4092 i=DiskInfo();
4093 if (i<0)
4094 {
4095 current_drive->diskstate_flags=0;
4096 current_drive->audio_state=0;
4097 i=check_allowed1(func,subfunc);
4098 if (i<0) return (-2);
4099 }
4100 }
4101 }
4102 }
4103 return (0);
4104}
4105#endif /* FUTURE */
4106/*==========================================================================*/
4107/*==========================================================================*/
4108/*
4109 * Check the results of the "get status" command.
4110 */
4111static int sbp_status(void)
4112{
4113 int st;
4114
4115 st=ResponseStatus();
4116 if (st<0)
4117 {
4118 msg(DBG_INF,"sbp_status: timeout.\n");
4119 return (0);
4120 }
4121
4122 if (!st_spinning) msg(DBG_SPI,"motor got off - ignoring.\n");
4123
4124 if (st_check)
4125 {
4126 msg(DBG_INF,"st_check detected - retrying.\n");
4127 return (0);
4128 }
4129 if (!st_door_closed)
4130 {
4131 msg(DBG_INF,"door is open - retrying.\n");
4132 return (0);
4133 }
4134 if (!st_caddy_in)
4135 {
4136 msg(DBG_INF,"disk removed - retrying.\n");
4137 return (0);
4138 }
4139 if (!st_diskok)
4140 {
4141 msg(DBG_INF,"!st_diskok detected - retrying.\n");
4142 return (0);
4143 }
4144 if (st_busy)
4145 {
4146 msg(DBG_INF,"st_busy detected - retrying.\n");
4147 return (0);
4148 }
4149 return (1);
4150}
4151/*==========================================================================*/
4152
4153static int sbpcd_get_last_session(struct cdrom_device_info *cdi, struct cdrom_multisession *ms_infp)
4154{
4155 struct sbpcd_drive *p = cdi->handle;
4156 ms_infp->addr_format = CDROM_LBA;
4157 ms_infp->addr.lba = p->lba_multi;
4158 if (p->f_multisession)
4159 ms_infp->xa_flag=1; /* valid redirection address */
4160 else
4161 ms_infp->xa_flag=0; /* invalid redirection address */
4162
4163 return 0;
4164}
4165
4166static int sbpcd_audio_ioctl(struct cdrom_device_info *cdi, u_int cmd,
4167 void * arg)
4168{
4169 struct sbpcd_drive *p = cdi->handle;
4170 int i, st, j;
4171
4172 msg(DBG_IO2,"ioctl(%s, 0x%08lX, 0x%08p)\n", cdi->name, cmd, arg);
4173 if (p->drv_id==-1) {
4174 msg(DBG_INF, "ioctl: bad device: %s\n", cdi->name);
4175 return (-ENXIO); /* no such drive */
4176 }
4177 down(&ioctl_read_sem);
4178 if (p != current_drive)
4179 switch_drive(p);
4180
4181 msg(DBG_IO2,"ioctl: device %s, request %04X\n",cdi->name,cmd);
4182 switch (cmd) /* Sun-compatible */
4183 {
4184
4185 case CDROMPAUSE: /* Pause the drive */
4186 msg(DBG_IOC,"ioctl: CDROMPAUSE entered.\n");
4187 /* pause the drive unit when it is currently in PLAY mode, */
4188 /* or reset the starting and ending locations when in PAUSED mode. */
4189 /* If applicable, at the next stopping point it reaches */
4190 /* the drive will discontinue playing. */
4191 switch (current_drive->audio_state)
4192 {
4193 case audio_playing:
4194 if (famL_drive) i=cc_ReadSubQ();
4195 else i=cc_Pause_Resume(1);
4196 if (i<0) RETURN_UP(-EIO);
4197 if (famL_drive) i=cc_Pause_Resume(1);
4198 else i=cc_ReadSubQ();
4199 if (i<0) RETURN_UP(-EIO);
4200 current_drive->pos_audio_start=current_drive->SubQ_run_tot;
4201 current_drive->audio_state=audio_pausing;
4202 RETURN_UP(0);
4203 case audio_pausing:
4204 i=cc_Seek(current_drive->pos_audio_start,1);
4205 if (i<0) RETURN_UP(-EIO);
4206 RETURN_UP(0);
4207 default:
4208 RETURN_UP(-EINVAL);
4209 }
4210
4211 case CDROMRESUME: /* resume paused audio play */
4212 msg(DBG_IOC,"ioctl: CDROMRESUME entered.\n");
4213 /* resume playing audio tracks when a previous PLAY AUDIO call has */
4214 /* been paused with a PAUSE command. */
4215 /* It will resume playing from the location saved in SubQ_run_tot. */
4216 if (current_drive->audio_state!=audio_pausing) RETURN_UP(-EINVAL);
4217 if (famL_drive)
4218 i=cc_PlayAudio(current_drive->pos_audio_start,
4219 current_drive->pos_audio_end);
4220 else i=cc_Pause_Resume(3);
4221 if (i<0) RETURN_UP(-EIO);
4222 current_drive->audio_state=audio_playing;
4223 RETURN_UP(0);
4224
4225 case CDROMPLAYMSF:
4226 msg(DBG_IOC,"ioctl: CDROMPLAYMSF entered.\n");
4227#ifdef SAFE_MIXED
4228 if (current_drive->has_data>1) RETURN_UP(-EBUSY);
4229#endif /* SAFE_MIXED */
4230 if (current_drive->audio_state==audio_playing)
4231 {
4232 i=cc_Pause_Resume(1);
4233 if (i<0) RETURN_UP(-EIO);
4234 i=cc_ReadSubQ();
4235 if (i<0) RETURN_UP(-EIO);
4236 current_drive->pos_audio_start=current_drive->SubQ_run_tot;
4237 i=cc_Seek(current_drive->pos_audio_start,1);
4238 }
4239 memcpy(&msf, (void *) arg, sizeof(struct cdrom_msf));
4240 /* values come as msf-bin */
4241 current_drive->pos_audio_start = (msf.cdmsf_min0<<16) |
4242 (msf.cdmsf_sec0<<8) |
4243 msf.cdmsf_frame0;
4244 current_drive->pos_audio_end = (msf.cdmsf_min1<<16) |
4245 (msf.cdmsf_sec1<<8) |
4246 msf.cdmsf_frame1;
4247 msg(DBG_IOX,"ioctl: CDROMPLAYMSF %08X %08X\n",
4248 current_drive->pos_audio_start,current_drive->pos_audio_end);
4249 i=cc_PlayAudio(current_drive->pos_audio_start,current_drive->pos_audio_end);
4250 if (i<0)
4251 {
4252 msg(DBG_INF,"ioctl: cc_PlayAudio returns %d\n",i);
4253 DriveReset();
4254 current_drive->audio_state=0;
4255 RETURN_UP(-EIO);
4256 }
4257 current_drive->audio_state=audio_playing;
4258 RETURN_UP(0);
4259
4260 case CDROMPLAYTRKIND: /* Play a track. This currently ignores index. */
4261 msg(DBG_IOC,"ioctl: CDROMPLAYTRKIND entered.\n");
4262#ifdef SAFE_MIXED
4263 if (current_drive->has_data>1) RETURN_UP(-EBUSY);
4264#endif /* SAFE_MIXED */
4265 if (current_drive->audio_state==audio_playing)
4266 {
4267 msg(DBG_IOX,"CDROMPLAYTRKIND: already audio_playing.\n");
4268#if 1
4269 RETURN_UP(0); /* just let us play on */
4270#else
4271 RETURN_UP(-EINVAL); /* play on, but say "error" */
4272#endif
4273 }
4274 memcpy(&ti,(void *) arg,sizeof(struct cdrom_ti));
4275 msg(DBG_IOX,"ioctl: trk0: %d, ind0: %d, trk1:%d, ind1:%d\n",
4276 ti.cdti_trk0,ti.cdti_ind0,ti.cdti_trk1,ti.cdti_ind1);
4277 if (ti.cdti_trk0<current_drive->n_first_track) RETURN_UP(-EINVAL);
4278 if (ti.cdti_trk0>current_drive->n_last_track) RETURN_UP(-EINVAL);
4279 if (ti.cdti_trk1<ti.cdti_trk0) ti.cdti_trk1=ti.cdti_trk0;
4280 if (ti.cdti_trk1>current_drive->n_last_track) ti.cdti_trk1=current_drive->n_last_track;
4281 current_drive->pos_audio_start=current_drive->TocBuffer[ti.cdti_trk0].address;
4282 current_drive->pos_audio_end=current_drive->TocBuffer[ti.cdti_trk1+1].address;
4283 i=cc_PlayAudio(current_drive->pos_audio_start,current_drive->pos_audio_end);
4284 if (i<0)
4285 {
4286 msg(DBG_INF,"ioctl: cc_PlayAudio returns %d\n",i);
4287 DriveReset();
4288 current_drive->audio_state=0;
4289 RETURN_UP(-EIO);
4290 }
4291 current_drive->audio_state=audio_playing;
4292 RETURN_UP(0);
4293
4294 case CDROMREADTOCHDR: /* Read the table of contents header */
4295 msg(DBG_IOC,"ioctl: CDROMREADTOCHDR entered.\n");
4296 tochdr.cdth_trk0=current_drive->n_first_track;
4297 tochdr.cdth_trk1=current_drive->n_last_track;
4298 memcpy((void *) arg, &tochdr, sizeof(struct cdrom_tochdr));
4299 RETURN_UP(0);
4300
4301 case CDROMREADTOCENTRY: /* Read an entry in the table of contents */
4302 msg(DBG_IOC,"ioctl: CDROMREADTOCENTRY entered.\n");
4303 memcpy(&tocentry, (void *) arg, sizeof(struct cdrom_tocentry));
4304 i=tocentry.cdte_track;
4305 if (i==CDROM_LEADOUT) i=current_drive->n_last_track+1;
4306 else if (i<current_drive->n_first_track||i>current_drive->n_last_track)
4307 RETURN_UP(-EINVAL);
4308 tocentry.cdte_adr=current_drive->TocBuffer[i].ctl_adr&0x0F;
4309 tocentry.cdte_ctrl=(current_drive->TocBuffer[i].ctl_adr>>4)&0x0F;
4310 tocentry.cdte_datamode=current_drive->TocBuffer[i].format;
4311 if (tocentry.cdte_format==CDROM_MSF) /* MSF-bin required */
4312 {
4313 tocentry.cdte_addr.msf.minute=(current_drive->TocBuffer[i].address>>16)&0x00FF;
4314 tocentry.cdte_addr.msf.second=(current_drive->TocBuffer[i].address>>8)&0x00FF;
4315 tocentry.cdte_addr.msf.frame=current_drive->TocBuffer[i].address&0x00FF;
4316 }
4317 else if (tocentry.cdte_format==CDROM_LBA) /* blk required */
4318 tocentry.cdte_addr.lba=msf2blk(current_drive->TocBuffer[i].address);
4319 else RETURN_UP(-EINVAL);
4320 memcpy((void *) arg, &tocentry, sizeof(struct cdrom_tocentry));
4321 RETURN_UP(0);
4322
4323 case CDROMSTOP: /* Spin down the drive */
4324 msg(DBG_IOC,"ioctl: CDROMSTOP entered.\n");
4325#ifdef SAFE_MIXED
4326 if (current_drive->has_data>1) RETURN_UP(-EBUSY);
4327#endif /* SAFE_MIXED */
4328 i=cc_Pause_Resume(1);
4329 current_drive->audio_state=0;
4330#if 0
4331 cc_DriveReset();
4332#endif
4333 RETURN_UP(i);
4334
4335 case CDROMSTART: /* Spin up the drive */
4336 msg(DBG_IOC,"ioctl: CDROMSTART entered.\n");
4337 cc_SpinUp();
4338 current_drive->audio_state=0;
4339 RETURN_UP(0);
4340
4341 case CDROMVOLCTRL: /* Volume control */
4342 msg(DBG_IOC,"ioctl: CDROMVOLCTRL entered.\n");
4343 memcpy(&volctrl,(char *) arg,sizeof(volctrl));
4344 current_drive->vol_chan0=0;
4345 current_drive->vol_ctrl0=volctrl.channel0;
4346 current_drive->vol_chan1=1;
4347 current_drive->vol_ctrl1=volctrl.channel1;
4348 i=cc_SetVolume();
4349 RETURN_UP(0);
4350
4351 case CDROMVOLREAD: /* read Volume settings from drive */
4352 msg(DBG_IOC,"ioctl: CDROMVOLREAD entered.\n");
4353 st=cc_GetVolume();
4354 if (st<0) RETURN_UP(st);
4355 volctrl.channel0=current_drive->vol_ctrl0;
4356 volctrl.channel1=current_drive->vol_ctrl1;
4357 volctrl.channel2=0;
4358 volctrl.channel2=0;
4359 memcpy((void *)arg,&volctrl,sizeof(volctrl));
4360 RETURN_UP(0);
4361
4362 case CDROMSUBCHNL: /* Get subchannel info */
4363 msg(DBG_IOS,"ioctl: CDROMSUBCHNL entered.\n");
4364 /* Bogus, I can do better than this! --AJK
4365 if ((st_spinning)||(!subq_valid)) {
4366 i=cc_ReadSubQ();
4367 if (i<0) RETURN_UP(-EIO);
4368 }
4369 */
4370 i=cc_ReadSubQ();
4371 if (i<0) {
4372 j=cc_ReadError(); /* clear out error status from drive */
4373 current_drive->audio_state=CDROM_AUDIO_NO_STATUS;
4374 /* get and set the disk state here,
4375 probably not the right place, but who cares!
4376 It makes it work properly! --AJK */
4377 if (current_drive->CD_changed==0xFF) {
4378 msg(DBG_000,"Disk changed detect\n");
4379 current_drive->diskstate_flags &= ~cd_size_bit;
4380 }
4381 RETURN_UP(-EIO);
4382 }
4383 if (current_drive->CD_changed==0xFF) {
4384 /* reread the TOC because the disk has changed! --AJK */
4385 msg(DBG_000,"Disk changed STILL detected, rereading TOC!\n");
4386 i=DiskInfo();
4387 if(i==0) {
4388 current_drive->CD_changed=0x00; /* cd has changed, procede, */
4389 RETURN_UP(-EIO); /* and get TOC, etc on next try! --AJK */
4390 } else {
4391 RETURN_UP(-EIO); /* we weren't ready yet! --AJK */
4392 }
4393 }
4394 memcpy(&SC, (void *) arg, sizeof(struct cdrom_subchnl));
4395 /*
4396 This virtual crap is very bogus!
4397 It doesn't detect when the cd is done playing audio!
4398 Lets do this right with proper hardware register reading!
4399 */
4400 cc_ReadStatus();
4401 i=ResponseStatus();
4402 msg(DBG_000,"Drive Status: door_locked =%d.\n", st_door_locked);
4403 msg(DBG_000,"Drive Status: door_closed =%d.\n", st_door_closed);
4404 msg(DBG_000,"Drive Status: caddy_in =%d.\n", st_caddy_in);
4405 msg(DBG_000,"Drive Status: disk_ok =%d.\n", st_diskok);
4406 msg(DBG_000,"Drive Status: spinning =%d.\n", st_spinning);
4407 msg(DBG_000,"Drive Status: busy =%d.\n", st_busy);
4408 /* st_busy indicates if it's _ACTUALLY_ playing audio */
4409 switch (current_drive->audio_state)
4410 {
4411 case audio_playing:
4412 if(st_busy==0) {
4413 /* CD has stopped playing audio --AJK */
4414 current_drive->audio_state=audio_completed;
4415 SC.cdsc_audiostatus=CDROM_AUDIO_COMPLETED;
4416 } else {
4417 SC.cdsc_audiostatus=CDROM_AUDIO_PLAY;
4418 }
4419 break;
4420 case audio_pausing:
4421 SC.cdsc_audiostatus=CDROM_AUDIO_PAUSED;
4422 break;
4423 case audio_completed:
4424 SC.cdsc_audiostatus=CDROM_AUDIO_COMPLETED;
4425 break;
4426 default:
4427 SC.cdsc_audiostatus=CDROM_AUDIO_NO_STATUS;
4428 break;
4429 }
4430 SC.cdsc_adr=current_drive->SubQ_ctl_adr;
4431 SC.cdsc_ctrl=current_drive->SubQ_ctl_adr>>4;
4432 SC.cdsc_trk=bcd2bin(current_drive->SubQ_trk);
4433 SC.cdsc_ind=bcd2bin(current_drive->SubQ_pnt_idx);
4434 if (SC.cdsc_format==CDROM_LBA)
4435 {
4436 SC.cdsc_absaddr.lba=msf2blk(current_drive->SubQ_run_tot);
4437 SC.cdsc_reladdr.lba=msf2blk(current_drive->SubQ_run_trk);
4438 }
4439 else /* not only if (SC.cdsc_format==CDROM_MSF) */
4440 {
4441 SC.cdsc_absaddr.msf.minute=(current_drive->SubQ_run_tot>>16)&0x00FF;
4442 SC.cdsc_absaddr.msf.second=(current_drive->SubQ_run_tot>>8)&0x00FF;
4443 SC.cdsc_absaddr.msf.frame=current_drive->SubQ_run_tot&0x00FF;
4444 SC.cdsc_reladdr.msf.minute=(current_drive->SubQ_run_trk>>16)&0x00FF;
4445 SC.cdsc_reladdr.msf.second=(current_drive->SubQ_run_trk>>8)&0x00FF;
4446 SC.cdsc_reladdr.msf.frame=current_drive->SubQ_run_trk&0x00FF;
4447 }
4448 memcpy((void *) arg, &SC, sizeof(struct cdrom_subchnl));
4449 msg(DBG_IOS,"CDROMSUBCHNL: %1X %02X %08X %08X %02X %02X %06X %06X\n",
4450 SC.cdsc_format,SC.cdsc_audiostatus,
4451 SC.cdsc_adr,SC.cdsc_ctrl,
4452 SC.cdsc_trk,SC.cdsc_ind,
4453 SC.cdsc_absaddr,SC.cdsc_reladdr);
4454 RETURN_UP(0);
4455
4456 default:
4457 msg(DBG_IOC,"ioctl: unknown function request %04X\n", cmd);
4458 RETURN_UP(-EINVAL);
4459 } /* end switch(cmd) */
4460}
4461/*==========================================================================*/
4462/*
4463 * Take care of the different block sizes between cdrom and Linux.
4464 */
4465static void sbp_transfer(struct request *req)
4466{
4467 long offs;
4468
4469 while ( (req->nr_sectors > 0) &&
4470 (req->sector/4 >= current_drive->sbp_first_frame) &&
4471 (req->sector/4 <= current_drive->sbp_last_frame) )
4472 {
4473 offs = (req->sector - current_drive->sbp_first_frame * 4) * 512;
4474 memcpy(req->buffer, current_drive->sbp_buf + offs, 512);
4475 req->nr_sectors--;
4476 req->sector++;
4477 req->buffer += 512;
4478 }
4479}
4480/*==========================================================================*/
4481/*
4482 * special end_request for sbpcd to solve CURRENT==NULL bug. (GTL)
4483 * GTL = Gonzalo Tornaria <tornaria@cmat.edu.uy>
4484 *
4485 * This is a kludge so we don't need to modify end_request.
4486 * We put the req we take out after INIT_REQUEST in the requests list,
4487 * so that end_request will discard it.
4488 *
4489 * The bug could be present in other block devices, perhaps we
4490 * should modify INIT_REQUEST and end_request instead, and
4491 * change every block device..
4492 *
4493 * Could be a race here?? Could e.g. a timer interrupt schedule() us?
4494 * If so, we should copy end_request here, and do it right.. (or
4495 * modify end_request and the block devices).
4496 *
4497 * In any case, the race here would be much small than it was, and
4498 * I couldn't reproduce..
4499 *
4500 * The race could be: suppose CURRENT==NULL. We put our req in the list,
4501 * and we are scheduled. Other process takes over, and gets into
4502 * do_sbpcd_request. It sees CURRENT!=NULL (it is == to our req), so
4503 * proceeds. It ends, so CURRENT is now NULL.. Now we awake somewhere in
4504 * end_request, but now CURRENT==NULL... oops!
4505 *
4506 */
4507#undef DEBUG_GTL
4508
4509/*==========================================================================*/
4510/*
4511 * I/O request routine, called from Linux kernel.
4512 */
4513static void do_sbpcd_request(request_queue_t * q)
4514{
4515 u_int block;
4516 u_int nsect;
4517 int status_tries, data_tries;
4518 struct request *req;
4519 struct sbpcd_drive *p;
4520#ifdef DEBUG_GTL
4521 static int xx_nr=0;
4522 int xnr;
4523#endif
4524
4525 request_loop:
4526#ifdef DEBUG_GTL
4527 xnr=++xx_nr;
4528
4529 req = elv_next_request(q);
4530
4531 if (!req)
4532 {
4533 printk( "do_sbpcd_request[%di](NULL), Pid:%d, Time:%li\n",
4534 xnr, current->pid, jiffies);
4535 printk( "do_sbpcd_request[%do](NULL) end 0 (null), Time:%li\n",
4536 xnr, jiffies);
4537 return;
4538 }
4539
4540 printk(" do_sbpcd_request[%di](%p:%ld+%ld), Pid:%d, Time:%li\n",
4541 xnr, req, req->sector, req->nr_sectors, current->pid, jiffies);
4542#endif
4543
4544 req = elv_next_request(q); /* take out our request so no other */
4545 if (!req)
4546 return;
4547
4548 if (req -> sector == -1)
4549 end_request(req, 0);
4550 spin_unlock_irq(q->queue_lock);
4551
4552 down(&ioctl_read_sem);
4553 if (rq_data_dir(elv_next_request(q)) != READ)
4554 {
4555 msg(DBG_INF, "bad cmd %d\n", req->cmd[0]);
4556 goto err_done;
4557 }
4558 p = req->rq_disk->private_data;
4559#if OLD_BUSY
4560 while (busy_audio) sbp_sleep(HZ); /* wait a bit */
4561 busy_data=1;
4562#endif /* OLD_BUSY */
4563
4564 if (p->audio_state==audio_playing) goto err_done;
4565 if (p != current_drive)
4566 switch_drive(p);
4567
4568 block = req->sector; /* always numbered as 512-byte-pieces */
4569 nsect = req->nr_sectors; /* always counted as 512-byte-pieces */
4570
4571 msg(DBG_BSZ,"read sector %d (%d sectors)\n", block, nsect);
4572#if 0
4573 msg(DBG_MUL,"read LBA %d\n", block/4);
4574#endif
4575
4576 sbp_transfer(req);
4577 /* if we satisfied the request from the buffer, we're done. */
4578 if (req->nr_sectors == 0)
4579 {
4580#ifdef DEBUG_GTL
4581 printk(" do_sbpcd_request[%do](%p:%ld+%ld) end 2, Time:%li\n",
4582 xnr, req, req->sector, req->nr_sectors, jiffies);
4583#endif
4584 up(&ioctl_read_sem);
4585 spin_lock_irq(q->queue_lock);
4586 end_request(req, 1);
4587 goto request_loop;
4588 }
4589
4590#ifdef FUTURE
4591 i=prepare(0,0); /* at moment not really a hassle check, but ... */
4592 if (i!=0)
4593 msg(DBG_INF,"\"prepare\" tells error %d -- ignored\n", i);
4594#endif /* FUTURE */
4595
4596 if (!st_spinning) cc_SpinUp();
4597
4598 for (data_tries=n_retries; data_tries > 0; data_tries--)
4599 {
4600 for (status_tries=3; status_tries > 0; status_tries--)
4601 {
4602 flags_cmd_out |= f_respo3;
4603 cc_ReadStatus();
4604 if (sbp_status() != 0) break;
4605 if (st_check) cc_ReadError();
4606 sbp_sleep(1); /* wait a bit, try again */
4607 }
4608 if (status_tries == 0)
4609 {
4610 msg(DBG_INF,"sbp_status: failed after 3 tries in line %d\n", __LINE__);
4611 break;
4612 }
4613
4614 sbp_read_cmd(req);
4615 sbp_sleep(0);
4616 if (sbp_data(req) != 0)
4617 {
4618#ifdef SAFE_MIXED
4619 current_drive->has_data=2; /* is really a data disk */
4620#endif /* SAFE_MIXED */
4621#ifdef DEBUG_GTL
4622 printk(" do_sbpcd_request[%do](%p:%ld+%ld) end 3, Time:%li\n",
4623 xnr, req, req->sector, req->nr_sectors, jiffies);
4624#endif
4625 up(&ioctl_read_sem);
4626 spin_lock_irq(q->queue_lock);
4627 end_request(req, 1);
4628 goto request_loop;
4629 }
4630 }
4631
4632 err_done:
4633#if OLD_BUSY
4634 busy_data=0;
4635#endif /* OLD_BUSY */
4636#ifdef DEBUG_GTL
4637 printk(" do_sbpcd_request[%do](%p:%ld+%ld) end 4 (error), Time:%li\n",
4638 xnr, req, req->sector, req->nr_sectors, jiffies);
4639#endif
4640 up(&ioctl_read_sem);
4641 sbp_sleep(0); /* wait a bit, try again */
4642 spin_lock_irq(q->queue_lock);
4643 end_request(req, 0);
4644 goto request_loop;
4645}
4646/*==========================================================================*/
4647/*
4648 * build and send the READ command.
4649 */
4650static void sbp_read_cmd(struct request *req)
4651{
4652#undef OLD
4653
4654 int i;
4655 int block;
4656
4657 current_drive->sbp_first_frame=current_drive->sbp_last_frame=-1; /* purge buffer */
4658 current_drive->sbp_current = 0;
4659 block=req->sector/4;
4660 if (block+current_drive->sbp_bufsiz <= current_drive->CDsize_frm)
4661 current_drive->sbp_read_frames = current_drive->sbp_bufsiz;
4662 else
4663 {
4664 current_drive->sbp_read_frames=current_drive->CDsize_frm-block;
4665 /* avoid reading past end of data */
4666 if (current_drive->sbp_read_frames < 1)
4667 {
4668 msg(DBG_INF,"requested frame %d, CD size %d ???\n",
4669 block, current_drive->CDsize_frm);
4670 current_drive->sbp_read_frames=1;
4671 }
4672 }
4673
4674 flags_cmd_out = f_putcmd | f_respo2 | f_ResponseStatus | f_obey_p_check;
4675 clr_cmdbuf();
4676 if (famV_drive)
4677 {
4678 drvcmd[0]=CMDV_READ;
4679 lba2msf(block,&drvcmd[1]); /* msf-bcd format required */
4680 bin2bcdx(&drvcmd[1]);
4681 bin2bcdx(&drvcmd[2]);
4682 bin2bcdx(&drvcmd[3]);
4683 drvcmd[4]=current_drive->sbp_read_frames>>8;
4684 drvcmd[5]=current_drive->sbp_read_frames&0xff;
4685 drvcmd[6]=0x02; /* flag "msf-bcd" */
4686 }
4687 else if (fam0L_drive)
4688 {
4689 flags_cmd_out |= f_lopsta | f_getsta | f_bit1;
4690 if (current_drive->xa_byte==0x20)
4691 {
4692 cmd_type=READ_M2;
4693 drvcmd[0]=CMD0_READ_XA; /* "read XA frames", old drives */
4694 drvcmd[1]=(block>>16)&0x0ff;
4695 drvcmd[2]=(block>>8)&0x0ff;
4696 drvcmd[3]=block&0x0ff;
4697 drvcmd[4]=(current_drive->sbp_read_frames>>8)&0x0ff;
4698 drvcmd[5]=current_drive->sbp_read_frames&0x0ff;
4699 }
4700 else
4701 {
4702 drvcmd[0]=CMD0_READ; /* "read frames", old drives */
4703 if (current_drive->drv_type>=drv_201)
4704 {
4705 lba2msf(block,&drvcmd[1]); /* msf-bcd format required */
4706 bin2bcdx(&drvcmd[1]);
4707 bin2bcdx(&drvcmd[2]);
4708 bin2bcdx(&drvcmd[3]);
4709 }
4710 else
4711 {
4712 drvcmd[1]=(block>>16)&0x0ff;
4713 drvcmd[2]=(block>>8)&0x0ff;
4714 drvcmd[3]=block&0x0ff;
4715 }
4716 drvcmd[4]=(current_drive->sbp_read_frames>>8)&0x0ff;
4717 drvcmd[5]=current_drive->sbp_read_frames&0x0ff;
4718 drvcmd[6]=(current_drive->drv_type<drv_201)?0:2; /* flag "lba or msf-bcd format" */
4719 }
4720 }
4721 else if (fam1_drive)
4722 {
4723 drvcmd[0]=CMD1_READ;
4724 lba2msf(block,&drvcmd[1]); /* msf-bin format required */
4725 drvcmd[5]=(current_drive->sbp_read_frames>>8)&0x0ff;
4726 drvcmd[6]=current_drive->sbp_read_frames&0x0ff;
4727 }
4728 else if (fam2_drive)
4729 {
4730 drvcmd[0]=CMD2_READ;
4731 lba2msf(block,&drvcmd[1]); /* msf-bin format required */
4732 drvcmd[4]=(current_drive->sbp_read_frames>>8)&0x0ff;
4733 drvcmd[5]=current_drive->sbp_read_frames&0x0ff;
4734 drvcmd[6]=0x02;
4735 }
4736 else if (famT_drive)
4737 {
4738 drvcmd[0]=CMDT_READ;
4739 drvcmd[2]=(block>>24)&0x0ff;
4740 drvcmd[3]=(block>>16)&0x0ff;
4741 drvcmd[4]=(block>>8)&0x0ff;
4742 drvcmd[5]=block&0x0ff;
4743 drvcmd[7]=(current_drive->sbp_read_frames>>8)&0x0ff;
4744 drvcmd[8]=current_drive->sbp_read_frames&0x0ff;
4745 }
4746 flags_cmd_out=f_putcmd;
4747 response_count=0;
4748 i=cmd_out();
4749 if (i<0) msg(DBG_INF,"error giving READ command: %0d\n", i);
4750 return;
4751}
4752/*==========================================================================*/
4753/*
4754 * Check the completion of the read-data command. On success, read
4755 * the current_drive->sbp_bufsiz * 2048 bytes of data from the disk into buffer.
4756 */
4757static int sbp_data(struct request *req)
4758{
4759 int i=0, j=0, l, frame;
4760 u_int try=0;
4761 u_long timeout;
4762 u_char *p;
4763 u_int data_tries = 0;
4764 u_int data_waits = 0;
4765 u_int data_retrying = 0;
4766 int error_flag;
4767 int xa_count;
4768 int max_latency;
4769 int success;
4770 int wait;
4771 int duration;
4772
4773 error_flag=0;
4774 success=0;
4775#if LONG_TIMING
4776 max_latency=9*HZ;
4777#else
4778 if (current_drive->f_multisession) max_latency=15*HZ;
4779 else max_latency=5*HZ;
4780#endif
4781 duration=jiffies;
4782 for (frame=0;frame<current_drive->sbp_read_frames&&!error_flag; frame++)
4783 {
4784 SBPCD_CLI;
4785
4786 del_timer(&data_timer);
4787 data_timer.expires=jiffies+max_latency;
4788 timed_out_data=0;
4789 add_timer(&data_timer);
4790 while (!timed_out_data)
4791 {
4792 if (current_drive->f_multisession) try=maxtim_data*4;
4793 else try=maxtim_data;
4794 msg(DBG_000,"sbp_data: CDi_status loop: try=%d.\n",try);
4795 for ( ; try!=0;try--)
4796 {
4797 j=inb(CDi_status);
4798 if (!(j&s_not_data_ready)) break;
4799 if (!(j&s_not_result_ready)) break;
4800 if (fam0LV_drive) if (j&s_attention) break;
4801 }
4802 if (!(j&s_not_data_ready)) goto data_ready;
4803 if (try==0)
4804 {
4805 if (data_retrying == 0) data_waits++;
4806 data_retrying = 1;
4807 msg(DBG_000,"sbp_data: CDi_status loop: sleeping.\n");
4808 sbp_sleep(1);
4809 try = 1;
4810 }
4811 }
4812 msg(DBG_INF,"sbp_data: CDi_status loop expired.\n");
4813 data_ready:
4814 del_timer(&data_timer);
4815
4816 if (timed_out_data)
4817 {
4818 msg(DBG_INF,"sbp_data: CDi_status timeout (timed_out_data) (%02X).\n", j);
4819 error_flag++;
4820 }
4821 if (try==0)
4822 {
4823 msg(DBG_INF,"sbp_data: CDi_status timeout (try=0) (%02X).\n", j);
4824 error_flag++;
4825 }
4826 if (!(j&s_not_result_ready))
4827 {
4828 msg(DBG_INF, "sbp_data: RESULT_READY where DATA_READY awaited (%02X).\n", j);
4829 response_count=20;
4830 j=ResponseInfo();
4831 j=inb(CDi_status);
4832 }
4833 if (j&s_not_data_ready)
4834 {
4835 if ((current_drive->ored_ctl_adr&0x40)==0)
4836 msg(DBG_INF, "CD contains no data tracks.\n");
4837 else msg(DBG_INF, "sbp_data: DATA_READY timeout (%02X).\n", j);
4838 error_flag++;
4839 }
4840 SBPCD_STI;
4841 if (error_flag) break;
4842
4843 msg(DBG_000, "sbp_data: beginning to read.\n");
4844 p = current_drive->sbp_buf + frame * CD_FRAMESIZE;
4845 if (sbpro_type==1) OUT(CDo_sel_i_d,1);
4846 if (cmd_type==READ_M2) {
4847 if (do_16bit) insw(CDi_data, xa_head_buf, CD_XA_HEAD>>1);
4848 else insb(CDi_data, xa_head_buf, CD_XA_HEAD);
4849 }
4850 if (do_16bit) insw(CDi_data, p, CD_FRAMESIZE>>1);
4851 else insb(CDi_data, p, CD_FRAMESIZE);
4852 if (cmd_type==READ_M2) {
4853 if (do_16bit) insw(CDi_data, xa_tail_buf, CD_XA_TAIL>>1);
4854 else insb(CDi_data, xa_tail_buf, CD_XA_TAIL);
4855 }
4856 current_drive->sbp_current++;
4857 if (sbpro_type==1) OUT(CDo_sel_i_d,0);
4858 if (cmd_type==READ_M2)
4859 {
4860 for (xa_count=0;xa_count<CD_XA_HEAD;xa_count++)
4861 sprintf(&msgbuf[xa_count*3], " %02X", xa_head_buf[xa_count]);
4862 msgbuf[xa_count*3]=0;
4863 msg(DBG_XA1,"xa head:%s\n", msgbuf);
4864 }
4865 data_retrying = 0;
4866 data_tries++;
4867 if (data_tries >= 1000)
4868 {
4869 msg(DBG_INF,"sbp_data() statistics: %d waits in %d frames.\n", data_waits, data_tries);
4870 data_waits = data_tries = 0;
4871 }
4872 }
4873 duration=jiffies-duration;
4874 msg(DBG_TEA,"time to read %d frames: %d jiffies .\n",frame,duration);
4875 if (famT_drive)
4876 {
4877 wait=8;
4878 do
4879 {
4880 if (teac==2)
4881 {
4882 if ((i=CDi_stat_loop_T()) == -1) break;
4883 }
4884 else
4885 {
4886 sbp_sleep(1);
4887 OUT(CDo_sel_i_d,0);
4888 i=inb(CDi_status);
4889 }
4890 if (!(i&s_not_data_ready))
4891 {
4892 OUT(CDo_sel_i_d,1);
4893 j=0;
4894 do
4895 {
4896 if (do_16bit) i=inw(CDi_data);
4897 else i=inb(CDi_data);
4898 j++;
4899 i=inb(CDi_status);
4900 }
4901 while (!(i&s_not_data_ready));
4902 msg(DBG_TEA, "==========too much data (%d bytes/words)==============.\n", j);
4903 }
4904 if (!(i&s_not_result_ready))
4905 {
4906 OUT(CDo_sel_i_d,0);
4907 l=0;
4908 do
4909 {
4910 infobuf[l++]=inb(CDi_info);
4911 i=inb(CDi_status);
4912 }
4913 while (!(i&s_not_result_ready));
4914 if (infobuf[0]==0x00) success=1;
4915#if 1
4916 for (j=0;j<l;j++) sprintf(&msgbuf[j*3], " %02X", infobuf[j]);
4917 msgbuf[j*3]=0;
4918 msg(DBG_TEA,"sbp_data info response:%s\n", msgbuf);
4919#endif
4920 if (infobuf[0]==0x02)
4921 {
4922 error_flag++;
4923 do
4924 {
4925 ++recursion;
4926 if (recursion>1) msg(DBG_TEA,"cmd_out_T READ_ERR recursion (sbp_data): %d !!!!!!!!!!!!!!!!!!!!!!!!!!!!!!\n",recursion);
4927 else msg(DBG_TEA,"sbp_data: CMDT_READ_ERR necessary.\n");
4928 clr_cmdbuf();
4929 drvcmd[0]=CMDT_READ_ERR;
4930 j=cmd_out_T(); /* !!! recursive here !!! */
4931 --recursion;
4932 sbp_sleep(1);
4933 }
4934 while (j<0);
4935 current_drive->error_state=infobuf[2];
4936 current_drive->b3=infobuf[3];
4937 current_drive->b4=infobuf[4];
4938 }
4939 break;
4940 }
4941 else
4942 {
4943#if 0
4944 msg(DBG_TEA, "============= waiting for result=================.\n");
4945 sbp_sleep(1);
4946#endif
4947 }
4948 }
4949 while (wait--);
4950 }
4951
4952 if (error_flag) /* must have been spurious D_RDY or (ATTN&&!D_RDY) */
4953 {
4954 msg(DBG_TEA, "================error flag: %d=================.\n", error_flag);
4955 msg(DBG_INF,"sbp_data: read aborted by drive.\n");
4956#if 1
4957 i=cc_DriveReset(); /* ugly fix to prevent a hang */
4958#else
4959 i=cc_ReadError();
4960#endif
4961 return (0);
4962 }
4963
4964 if (fam0LV_drive)
4965 {
4966 SBPCD_CLI;
4967 i=maxtim_data;
4968 for (timeout=jiffies+HZ; time_before(jiffies, timeout); timeout--)
4969 {
4970 for ( ;i!=0;i--)
4971 {
4972 j=inb(CDi_status);
4973 if (!(j&s_not_data_ready)) break;
4974 if (!(j&s_not_result_ready)) break;
4975 if (j&s_attention) break;
4976 }
4977 if (i != 0 || time_after_eq(jiffies, timeout)) break;
4978 sbp_sleep(0);
4979 i = 1;
4980 }
4981 if (i==0) msg(DBG_INF,"status timeout after READ.\n");
4982 if (!(j&s_attention))
4983 {
4984 msg(DBG_INF,"sbp_data: timeout waiting DRV_ATTN - retrying.\n");
4985 i=cc_DriveReset(); /* ugly fix to prevent a hang */
4986 SBPCD_STI;
4987 return (0);
4988 }
4989 SBPCD_STI;
4990 }
4991
4992#if 0
4993 if (!success)
4994#endif
4995 do
4996 {
4997 if (fam0LV_drive) cc_ReadStatus();
4998#if 1
4999 if (famT_drive) msg(DBG_TEA, "================before ResponseStatus=================.\n", i);
5000#endif
5001 i=ResponseStatus(); /* builds status_bits, returns orig. status (old) or faked p_success (new) */
5002#if 1
5003 if (famT_drive) msg(DBG_TEA, "================ResponseStatus: %d=================.\n", i);
5004#endif
5005 if (i<0)
5006 {
5007 msg(DBG_INF,"bad cc_ReadStatus after read: %02X\n", current_drive->status_bits);
5008 return (0);
5009 }
5010 }
5011 while ((fam0LV_drive)&&(!st_check)&&(!(i&p_success)));
5012 if (st_check)
5013 {
5014 i=cc_ReadError();
5015 msg(DBG_INF,"cc_ReadError was necessary after read: %d\n",i);
5016 return (0);
5017 }
5018 if (fatal_err)
5019 {
5020 fatal_err=0;
5021 current_drive->sbp_first_frame=current_drive->sbp_last_frame=-1; /* purge buffer */
5022 current_drive->sbp_current = 0;
5023 msg(DBG_INF,"sbp_data: fatal_err - retrying.\n");
5024 return (0);
5025 }
5026
5027 current_drive->sbp_first_frame = req -> sector / 4;
5028 current_drive->sbp_last_frame = current_drive->sbp_first_frame + current_drive->sbp_read_frames - 1;
5029 sbp_transfer(req);
5030 return (1);
5031}
5032/*==========================================================================*/
5033
5034static int sbpcd_block_open(struct inode *inode, struct file *file)
5035{
5036 struct sbpcd_drive *p = inode->i_bdev->bd_disk->private_data;
5037 return cdrom_open(p->sbpcd_infop, inode, file);
5038}
5039
5040static int sbpcd_block_release(struct inode *inode, struct file *file)
5041{
5042 struct sbpcd_drive *p = inode->i_bdev->bd_disk->private_data;
5043 return cdrom_release(p->sbpcd_infop, file);
5044}
5045
5046static int sbpcd_block_ioctl(struct inode *inode, struct file *file,
5047 unsigned cmd, unsigned long arg)
5048{
5049 struct sbpcd_drive *p = inode->i_bdev->bd_disk->private_data;
5050 struct cdrom_device_info *cdi = p->sbpcd_infop;
5051 int ret, i;
5052
5053 ret = cdrom_ioctl(file, p->sbpcd_infop, inode, cmd, arg);
5054 if (ret != -ENOSYS)
5055 return ret;
5056
5057 msg(DBG_IO2,"ioctl(%s, 0x%08lX, 0x%08lX)\n", cdi->name, cmd, arg);
5058 if (p->drv_id==-1) {
5059 msg(DBG_INF, "ioctl: bad device: %s\n", cdi->name);
5060 return (-ENXIO); /* no such drive */
5061 }
5062 down(&ioctl_read_sem);
5063 if (p != current_drive)
5064 switch_drive(p);
5065
5066 msg(DBG_IO2,"ioctl: device %s, request %04X\n",cdi->name,cmd);
5067 switch (cmd) /* Sun-compatible */
5068 {
5069 case DDIOCSDBG: /* DDI Debug */
5070 if (!capable(CAP_SYS_ADMIN)) RETURN_UP(-EPERM);
5071 i=sbpcd_dbg_ioctl(arg,1);
5072 RETURN_UP(i);
5073 case CDROMRESET: /* hard reset the drive */
5074 msg(DBG_IOC,"ioctl: CDROMRESET entered.\n");
5075 i=DriveReset();
5076 current_drive->audio_state=0;
5077 RETURN_UP(i);
5078
5079 case CDROMREADMODE1:
5080 msg(DBG_IOC,"ioctl: CDROMREADMODE1 requested.\n");
5081#ifdef SAFE_MIXED
5082 if (current_drive->has_data>1) RETURN_UP(-EBUSY);
5083#endif /* SAFE_MIXED */
5084 cc_ModeSelect(CD_FRAMESIZE);
5085 cc_ModeSense();
5086 current_drive->mode=READ_M1;
5087 RETURN_UP(0);
5088
5089 case CDROMREADMODE2: /* not usable at the moment */
5090 msg(DBG_IOC,"ioctl: CDROMREADMODE2 requested.\n");
5091#ifdef SAFE_MIXED
5092 if (current_drive->has_data>1) RETURN_UP(-EBUSY);
5093#endif /* SAFE_MIXED */
5094 cc_ModeSelect(CD_FRAMESIZE_RAW1);
5095 cc_ModeSense();
5096 current_drive->mode=READ_M2;
5097 RETURN_UP(0);
5098
5099 case CDROMAUDIOBUFSIZ: /* configure the audio buffer size */
5100 msg(DBG_IOC,"ioctl: CDROMAUDIOBUFSIZ entered.\n");
5101 if (current_drive->sbp_audsiz>0)
5102 vfree(current_drive->aud_buf);
5103 current_drive->aud_buf=NULL;
5104 current_drive->sbp_audsiz=arg;
5105
5106 if (current_drive->sbp_audsiz>16)
5107 {
5108 current_drive->sbp_audsiz = 0;
5109 RETURN_UP(current_drive->sbp_audsiz);
5110 }
5111
5112 if (current_drive->sbp_audsiz>0)
5113 {
5114 current_drive->aud_buf=(u_char *) vmalloc(current_drive->sbp_audsiz*CD_FRAMESIZE_RAW);
5115 if (current_drive->aud_buf==NULL)
5116 {
5117 msg(DBG_INF,"audio buffer (%d frames) not available.\n",current_drive->sbp_audsiz);
5118 current_drive->sbp_audsiz=0;
5119 }
5120 else msg(DBG_INF,"audio buffer size: %d frames.\n",current_drive->sbp_audsiz);
5121 }
5122 RETURN_UP(current_drive->sbp_audsiz);
5123
5124 case CDROMREADAUDIO:
5125 { /* start of CDROMREADAUDIO */
5126 int i=0, j=0, frame, block=0;
5127 u_int try=0;
5128 u_long timeout;
5129 u_char *p;
5130 u_int data_tries = 0;
5131 u_int data_waits = 0;
5132 u_int data_retrying = 0;
5133 int status_tries;
5134 int error_flag;
5135
5136 msg(DBG_IOC,"ioctl: CDROMREADAUDIO entered.\n");
5137 if (fam0_drive) RETURN_UP(-EINVAL);
5138 if (famL_drive) RETURN_UP(-EINVAL);
5139 if (famV_drive) RETURN_UP(-EINVAL);
5140 if (famT_drive) RETURN_UP(-EINVAL);
5141#ifdef SAFE_MIXED
5142 if (current_drive->has_data>1) RETURN_UP(-EBUSY);
5143#endif /* SAFE_MIXED */
5144 if (current_drive->aud_buf==NULL) RETURN_UP(-EINVAL);
5145 if (copy_from_user(&read_audio, (void __user *)arg,
5146 sizeof(struct cdrom_read_audio)))
5147 RETURN_UP(-EFAULT);
5148 if (read_audio.nframes < 0 || read_audio.nframes>current_drive->sbp_audsiz) RETURN_UP(-EINVAL);
5149 if (!access_ok(VERIFY_WRITE, read_audio.buf,
5150 read_audio.nframes*CD_FRAMESIZE_RAW))
5151 RETURN_UP(-EFAULT);
5152
5153 if (read_audio.addr_format==CDROM_MSF) /* MSF-bin specification of where to start */
5154 block=msf2lba(&read_audio.addr.msf.minute);
5155 else if (read_audio.addr_format==CDROM_LBA) /* lba specification of where to start */
5156 block=read_audio.addr.lba;
5157 else RETURN_UP(-EINVAL);
5158#if 000
5159 i=cc_SetSpeed(speed_150,0,0);
5160 if (i) msg(DBG_AUD,"read_audio: SetSpeed error %d\n", i);
5161#endif
5162 msg(DBG_AUD,"read_audio: lba: %d, msf: %06X\n",
5163 block, blk2msf(block));
5164 msg(DBG_AUD,"read_audio: before cc_ReadStatus.\n");
5165#if OLD_BUSY
5166 while (busy_data) sbp_sleep(HZ/10); /* wait a bit */
5167 busy_audio=1;
5168#endif /* OLD_BUSY */
5169 error_flag=0;
5170 for (data_tries=5; data_tries>0; data_tries--)
5171 {
5172 msg(DBG_AUD,"data_tries=%d ...\n", data_tries);
5173 current_drive->mode=READ_AU;
5174 cc_ModeSelect(CD_FRAMESIZE_RAW);
5175 cc_ModeSense();
5176 for (status_tries=3; status_tries > 0; status_tries--)
5177 {
5178 flags_cmd_out |= f_respo3;
5179 cc_ReadStatus();
5180 if (sbp_status() != 0) break;
5181 if (st_check) cc_ReadError();
5182 sbp_sleep(1); /* wait a bit, try again */
5183 }
5184 if (status_tries == 0)
5185 {
5186 msg(DBG_AUD,"read_audio: sbp_status: failed after 3 tries in line %d.\n", __LINE__);
5187 continue;
5188 }
5189 msg(DBG_AUD,"read_audio: sbp_status: ok.\n");
5190
5191 flags_cmd_out = f_putcmd | f_respo2 | f_ResponseStatus | f_obey_p_check;
5192 if (fam0L_drive)
5193 {
5194 flags_cmd_out |= f_lopsta | f_getsta | f_bit1;
5195 cmd_type=READ_M2;
5196 drvcmd[0]=CMD0_READ_XA; /* "read XA frames", old drives */
5197 drvcmd[1]=(block>>16)&0x000000ff;
5198 drvcmd[2]=(block>>8)&0x000000ff;
5199 drvcmd[3]=block&0x000000ff;
5200 drvcmd[4]=0;
5201 drvcmd[5]=read_audio.nframes; /* # of frames */
5202 drvcmd[6]=0;
5203 }
5204 else if (fam1_drive)
5205 {
5206 drvcmd[0]=CMD1_READ; /* "read frames", new drives */
5207 lba2msf(block,&drvcmd[1]); /* msf-bin format required */
5208 drvcmd[4]=0;
5209 drvcmd[5]=0;
5210 drvcmd[6]=read_audio.nframes; /* # of frames */
5211 }
5212 else if (fam2_drive)
5213 {
5214 drvcmd[0]=CMD2_READ_XA2;
5215 lba2msf(block,&drvcmd[1]); /* msf-bin format required */
5216 drvcmd[4]=0;
5217 drvcmd[5]=read_audio.nframes; /* # of frames */
5218 drvcmd[6]=0x11; /* raw mode */
5219 }
5220 else if (famT_drive) /* CD-55A: not tested yet */
5221 {
5222 }
5223 msg(DBG_AUD,"read_audio: before giving \"read\" command.\n");
5224 flags_cmd_out=f_putcmd;
5225 response_count=0;
5226 i=cmd_out();
5227 if (i<0) msg(DBG_INF,"error giving READ AUDIO command: %0d\n", i);
5228 sbp_sleep(0);
5229 msg(DBG_AUD,"read_audio: after giving \"read\" command.\n");
5230 for (frame=1;frame<2 && !error_flag; frame++)
5231 {
5232 try=maxtim_data;
5233 for (timeout=jiffies+9*HZ; ; )
5234 {
5235 for ( ; try!=0;try--)
5236 {
5237 j=inb(CDi_status);
5238 if (!(j&s_not_data_ready)) break;
5239 if (!(j&s_not_result_ready)) break;
5240 if (fam0L_drive) if (j&s_attention) break;
5241 }
5242 if (try != 0 || time_after_eq(jiffies, timeout)) break;
5243 if (data_retrying == 0) data_waits++;
5244 data_retrying = 1;
5245 sbp_sleep(1);
5246 try = 1;
5247 }
5248 if (try==0)
5249 {
5250 msg(DBG_INF,"read_audio: sbp_data: CDi_status timeout.\n");
5251 error_flag++;
5252 break;
5253 }
5254 msg(DBG_AUD,"read_audio: sbp_data: CDi_status ok.\n");
5255 if (j&s_not_data_ready)
5256 {
5257 msg(DBG_INF, "read_audio: sbp_data: DATA_READY timeout.\n");
5258 error_flag++;
5259 break;
5260 }
5261 msg(DBG_AUD,"read_audio: before reading data.\n");
5262 error_flag=0;
5263 p = current_drive->aud_buf;
5264 if (sbpro_type==1) OUT(CDo_sel_i_d,1);
5265 if (do_16bit)
5266 {
5267 u_short *p2 = (u_short *) p;
5268
5269 for (; (u_char *) p2 < current_drive->aud_buf + read_audio.nframes*CD_FRAMESIZE_RAW;)
5270 {
5271 if ((inb_p(CDi_status)&s_not_data_ready)) continue;
5272
5273 /* get one sample */
5274 *p2++ = inw_p(CDi_data);
5275 *p2++ = inw_p(CDi_data);
5276 }
5277 } else {
5278 for (; p < current_drive->aud_buf + read_audio.nframes*CD_FRAMESIZE_RAW;)
5279 {
5280 if ((inb_p(CDi_status)&s_not_data_ready)) continue;
5281
5282 /* get one sample */
5283 *p++ = inb_p(CDi_data);
5284 *p++ = inb_p(CDi_data);
5285 *p++ = inb_p(CDi_data);
5286 *p++ = inb_p(CDi_data);
5287 }
5288 }
5289 if (sbpro_type==1) OUT(CDo_sel_i_d,0);
5290 data_retrying = 0;
5291 }
5292 msg(DBG_AUD,"read_audio: after reading data.\n");
5293 if (error_flag) /* must have been spurious D_RDY or (ATTN&&!D_RDY) */
5294 {
5295 msg(DBG_AUD,"read_audio: read aborted by drive\n");
5296#if 0000
5297 i=cc_DriveReset(); /* ugly fix to prevent a hang */
5298#else
5299 i=cc_ReadError();
5300#endif
5301 continue;
5302 }
5303 if (fam0L_drive)
5304 {
5305 i=maxtim_data;
5306 for (timeout=jiffies+9*HZ; time_before(jiffies, timeout); timeout--)
5307 {
5308 for ( ;i!=0;i--)
5309 {
5310 j=inb(CDi_status);
5311 if (!(j&s_not_data_ready)) break;
5312 if (!(j&s_not_result_ready)) break;
5313 if (j&s_attention) break;
5314 }
5315 if (i != 0 || time_after_eq(jiffies, timeout)) break;
5316 sbp_sleep(0);
5317 i = 1;
5318 }
5319 if (i==0) msg(DBG_AUD,"read_audio: STATUS TIMEOUT AFTER READ");
5320 if (!(j&s_attention))
5321 {
5322 msg(DBG_AUD,"read_audio: sbp_data: timeout waiting DRV_ATTN - retrying\n");
5323 i=cc_DriveReset(); /* ugly fix to prevent a hang */
5324 continue;
5325 }
5326 }
5327 do
5328 {
5329 if (fam0L_drive) cc_ReadStatus();
5330 i=ResponseStatus(); /* builds status_bits, returns orig. status (old) or faked p_success (new) */
5331 if (i<0) { msg(DBG_AUD,
5332 "read_audio: cc_ReadStatus error after read: %02X\n",
5333 current_drive->status_bits);
5334 continue; /* FIXME */
5335 }
5336 }
5337 while ((fam0L_drive)&&(!st_check)&&(!(i&p_success)));
5338 if (st_check)
5339 {
5340 i=cc_ReadError();
5341 msg(DBG_AUD,"read_audio: cc_ReadError was necessary after read: %02X\n",i);
5342 continue;
5343 }
5344 if (copy_to_user(read_audio.buf,
5345 current_drive->aud_buf,
5346 read_audio.nframes * CD_FRAMESIZE_RAW))
5347 RETURN_UP(-EFAULT);
5348 msg(DBG_AUD,"read_audio: copy_to_user done.\n");
5349 break;
5350 }
5351 cc_ModeSelect(CD_FRAMESIZE);
5352 cc_ModeSense();
5353 current_drive->mode=READ_M1;
5354#if OLD_BUSY
5355 busy_audio=0;
5356#endif /* OLD_BUSY */
5357 if (data_tries == 0)
5358 {
5359 msg(DBG_AUD,"read_audio: failed after 5 tries in line %d.\n", __LINE__);
5360 RETURN_UP(-EIO);
5361 }
5362 msg(DBG_AUD,"read_audio: successful return.\n");
5363 RETURN_UP(0);
5364 } /* end of CDROMREADAUDIO */
5365
5366 default:
5367 msg(DBG_IOC,"ioctl: unknown function request %04X\n", cmd);
5368 RETURN_UP(-EINVAL);
5369 } /* end switch(cmd) */
5370}
5371
5372static int sbpcd_block_media_changed(struct gendisk *disk)
5373{
5374 struct sbpcd_drive *p = disk->private_data;
5375 return cdrom_media_changed(p->sbpcd_infop);
5376}
5377
5378static struct block_device_operations sbpcd_bdops =
5379{
5380 .owner = THIS_MODULE,
5381 .open = sbpcd_block_open,
5382 .release = sbpcd_block_release,
5383 .ioctl = sbpcd_block_ioctl,
5384 .media_changed = sbpcd_block_media_changed,
5385};
5386/*==========================================================================*/
5387/*
5388 * Open the device special file. Check that a disk is in. Read TOC.
5389 */
5390static int sbpcd_open(struct cdrom_device_info *cdi, int purpose)
5391{
5392 struct sbpcd_drive *p = cdi->handle;
5393
5394 down(&ioctl_read_sem);
5395 switch_drive(p);
5396
5397 /*
5398 * try to keep an "open" counter here and lock the door if 0->1.
5399 */
5400 msg(DBG_LCK,"open_count: %d -> %d\n",
5401 current_drive->open_count,current_drive->open_count+1);
5402 if (++current_drive->open_count<=1)
5403 {
5404 int i;
5405 i=LockDoor();
5406 current_drive->open_count=1;
5407 if (famT_drive) msg(DBG_TEA,"sbpcd_open: before i=DiskInfo();.\n");
5408 i=DiskInfo();
5409 if (famT_drive) msg(DBG_TEA,"sbpcd_open: after i=DiskInfo();.\n");
5410 if ((current_drive->ored_ctl_adr&0x40)==0)
5411 {
5412 msg(DBG_INF,"CD contains no data tracks.\n");
5413#ifdef SAFE_MIXED
5414 current_drive->has_data=0;
5415#endif /* SAFE_MIXED */
5416 }
5417#ifdef SAFE_MIXED
5418 else if (current_drive->has_data<1) current_drive->has_data=1;
5419#endif /* SAFE_MIXED */
5420 }
5421 if (!st_spinning) cc_SpinUp();
5422 RETURN_UP(0);
5423}
5424/*==========================================================================*/
5425/*
5426 * On close, we flush all sbp blocks from the buffer cache.
5427 */
5428static void sbpcd_release(struct cdrom_device_info * cdi)
5429{
5430 struct sbpcd_drive *p = cdi->handle;
5431
5432 if (p->drv_id==-1) {
5433 msg(DBG_INF, "release: bad device: %s\n", cdi->name);
5434 return;
5435 }
5436 down(&ioctl_read_sem);
5437 switch_drive(p);
5438 /*
5439 * try to keep an "open" counter here and unlock the door if 1->0.
5440 */
5441 msg(DBG_LCK,"open_count: %d -> %d\n",
5442 p->open_count,p->open_count-1);
5443 if (p->open_count>-2) /* CDROMEJECT may have been done */
5444 {
5445 if (--p->open_count<=0)
5446 {
5447 p->sbp_first_frame=p->sbp_last_frame=-1;
5448 if (p->audio_state!=audio_playing)
5449 if (p->f_eject) cc_SpinDown();
5450 p->diskstate_flags &= ~cd_size_bit;
5451 p->open_count=0;
5452#ifdef SAFE_MIXED
5453 p->has_data=0;
5454#endif /* SAFE_MIXED */
5455 }
5456 }
5457 up(&ioctl_read_sem);
5458 return ;
5459}
5460/*==========================================================================*/
5461/*
5462 *
5463 */
5464static int sbpcd_media_changed( struct cdrom_device_info *cdi, int disc_nr);
5465static struct cdrom_device_ops sbpcd_dops = {
5466 .open = sbpcd_open,
5467 .release = sbpcd_release,
5468 .drive_status = sbpcd_drive_status,
5469 .media_changed = sbpcd_media_changed,
5470 .tray_move = sbpcd_tray_move,
5471 .lock_door = sbpcd_lock_door,
5472 .select_speed = sbpcd_select_speed,
5473 .get_last_session = sbpcd_get_last_session,
5474 .get_mcn = sbpcd_get_mcn,
5475 .reset = sbpcd_reset,
5476 .audio_ioctl = sbpcd_audio_ioctl,
5477 .capability = CDC_CLOSE_TRAY | CDC_OPEN_TRAY | CDC_LOCK |
5478 CDC_MULTI_SESSION | CDC_MEDIA_CHANGED |
5479 CDC_MCN | CDC_PLAY_AUDIO,
5480 .n_minors = 1,
5481};
5482
5483/*==========================================================================*/
5484/*
5485 * accept "kernel command line" parameters
5486 * (suggested by Peter MacDonald with SLS 1.03)
5487 *
5488 * This is only implemented for the first controller. Should be enough to
5489 * allow installing with a "strange" distribution kernel.
5490 *
5491 * use: tell LILO:
5492 * sbpcd=0x230,SoundBlaster
5493 * or
5494 * sbpcd=0x300,LaserMate
5495 * or
5496 * sbpcd=0x338,SoundScape
5497 * or
5498 * sbpcd=0x2C0,Teac16bit
5499 *
5500 * (upper/lower case sensitive here - but all-lowercase is ok!!!).
5501 *
5502 * the address value has to be the CDROM PORT ADDRESS -
5503 * not the soundcard base address.
5504 * For the SPEA/SoundScape setup, DO NOT specify the "configuration port"
5505 * address, but the address which is really used for the CDROM (usually 8
5506 * bytes above).
5507 *
5508 */
5509
5510int sbpcd_setup(char *s)
5511{
5512#ifndef MODULE
5513 int p[4];
5514 (void)get_options(s, ARRAY_SIZE(p), p);
5515 setup_done++;
5516 msg(DBG_INI,"sbpcd_setup called with %04X,%s\n",p[1], s);
5517 sbpro_type=0; /* default: "LaserMate" */
5518 if (p[0]>1) sbpro_type=p[2];
5519 else if (!strcmp(s,str_sb)) sbpro_type=1;
5520 else if (!strcmp(s,str_sb_l)) sbpro_type=1;
5521 else if (!strcmp(s,str_sp)) sbpro_type=2;
5522 else if (!strcmp(s,str_sp_l)) sbpro_type=2;
5523 else if (!strcmp(s,str_ss)) sbpro_type=2;
5524 else if (!strcmp(s,str_ss_l)) sbpro_type=2;
5525 else if (!strcmp(s,str_t16)) sbpro_type=3;
5526 else if (!strcmp(s,str_t16_l)) sbpro_type=3;
5527 if (p[0]>0) sbpcd_ioaddr=p[1];
5528 if (p[0]>2) max_drives=p[3];
5529#else
5530 sbpcd_ioaddr = sbpcd[0];
5531 sbpro_type = sbpcd[1];
5532#endif
5533
5534 CDo_command=sbpcd_ioaddr;
5535 CDi_info=sbpcd_ioaddr;
5536 CDi_status=sbpcd_ioaddr+1;
5537 CDo_sel_i_d=sbpcd_ioaddr+1;
5538 CDo_reset=sbpcd_ioaddr+2;
5539 CDo_enable=sbpcd_ioaddr+3;
5540 f_16bit=0;
5541 if ((sbpro_type==1)||(sbpro_type==3))
5542 {
5543 CDi_data=sbpcd_ioaddr;
5544 if (sbpro_type==3)
5545 {
5546 f_16bit=1;
5547 sbpro_type=1;
5548 }
5549 }
5550 else CDi_data=sbpcd_ioaddr+2;
5551
5552 return 1;
5553}
5554
5555__setup("sbpcd=", sbpcd_setup);
5556
5557
5558/*==========================================================================*/
5559/*
5560 * Sequoia S-1000 CD-ROM Interface Configuration
5561 * as used within SPEA Media FX, Ensonic SoundScape and some Reveal cards
5562 * The soundcard has to get jumpered for the interface type "Panasonic"
5563 * (not Sony or Mitsumi) and to get soft-configured for
5564 * -> configuration port address
5565 * -> CDROM port offset (num_ports): has to be 8 here. Possibly this
5566 * offset value determines the interface type (none, Panasonic,
5567 * Mitsumi, Sony).
5568 * The interface uses a configuration port (0x320, 0x330, 0x340, 0x350)
5569 * some bytes below the real CDROM address.
5570 *
5571 * For the Panasonic style (LaserMate) interface and the configuration
5572 * port 0x330, we have to use an offset of 8; so, the real CDROM port
5573 * address is 0x338.
5574 */
5575static int __init config_spea(void)
5576{
5577 /*
5578 * base address offset between configuration port and CDROM port,
5579 * this probably defines the interface type
5580 * 2 (type=??): 0x00
5581 * 8 (type=LaserMate):0x10
5582 * 16 (type=??):0x20
5583 * 32 (type=??):0x30
5584 */
5585 int n_ports=0x10;
5586
5587 int irq_number=0; /* off:0x00, 2/9:0x01, 7:0x03, 12:0x05, 15:0x07 */
5588 int dma_channel=0; /* off: 0x00, 0:0x08, 1:0x18, 3:0x38, 5:0x58, 6:0x68 */
5589 int dack_polarity=0; /* L:0x00, H:0x80 */
5590 int drq_polarity=0x40; /* L:0x00, H:0x40 */
5591 int i;
5592
5593#define SPEA_REG_1 sbpcd_ioaddr-0x08+4
5594#define SPEA_REG_2 sbpcd_ioaddr-0x08+5
5595
5596 OUT(SPEA_REG_1,0xFF);
5597 i=inb(SPEA_REG_1);
5598 if (i!=0x0F)
5599 {
5600 msg(DBG_SEQ,"no SPEA interface at %04X present.\n", sbpcd_ioaddr);
5601 return (-1); /* no interface found */
5602 }
5603 OUT(SPEA_REG_1,0x04);
5604 OUT(SPEA_REG_2,0xC0);
5605
5606 OUT(SPEA_REG_1,0x05);
5607 OUT(SPEA_REG_2,0x10|drq_polarity|dack_polarity);
5608
5609#if 1
5610#define SPEA_PATTERN 0x80
5611#else
5612#define SPEA_PATTERN 0x00
5613#endif
5614 OUT(SPEA_REG_1,0x06);
5615 OUT(SPEA_REG_2,dma_channel|irq_number|SPEA_PATTERN);
5616 OUT(SPEA_REG_2,dma_channel|irq_number|SPEA_PATTERN);
5617
5618 OUT(SPEA_REG_1,0x09);
5619 i=(inb(SPEA_REG_2)&0xCF)|n_ports;
5620 OUT(SPEA_REG_2,i);
5621
5622 sbpro_type = 0; /* acts like a LaserMate interface now */
5623 msg(DBG_SEQ,"found SoundScape interface at %04X.\n", sbpcd_ioaddr);
5624 return (0);
5625}
5626
5627/*==========================================================================*/
5628/*
5629 * Test for presence of drive and initialize it.
5630 * Called once at boot or load time.
5631 */
5632
5633/* FIXME: cleanups after failed allocations are too ugly for words */
5634#ifdef MODULE
5635int __init __sbpcd_init(void)
5636#else
5637int __init sbpcd_init(void)
5638#endif
5639{
5640 int i=0, j=0;
5641 int addr[2]={1, CDROM_PORT};
5642 int port_index;
5643
5644 sti();
5645
5646 msg(DBG_INF,"sbpcd.c %s\n", VERSION);
5647#ifndef MODULE
5648#if DISTRIBUTION
5649 if (!setup_done)
5650 {
5651 msg(DBG_INF,"Looking for Matsushita/Panasonic, CreativeLabs, Longshine, TEAC CD-ROM drives\n");
5652 msg(DBG_INF,"= = = = = = = = = = W A R N I N G = = = = = = = = = =\n");
5653 msg(DBG_INF,"Auto-Probing can cause a hang (f.e. touching an NE2000 card).\n");
5654 msg(DBG_INF,"If that happens, you have to reboot and use the\n");
5655 msg(DBG_INF,"LILO (kernel) command line feature like:\n");
5656 msg(DBG_INF," LILO boot: ... sbpcd=0x230,SoundBlaster\n");
5657 msg(DBG_INF,"or like:\n");
5658 msg(DBG_INF," LILO boot: ... sbpcd=0x300,LaserMate\n");
5659 msg(DBG_INF,"or like:\n");
5660 msg(DBG_INF," LILO boot: ... sbpcd=0x338,SoundScape\n");
5661 msg(DBG_INF,"with your REAL address.\n");
5662 msg(DBG_INF,"= = = = = = = = = = END of WARNING = = = = = == = = =\n");
5663 }
5664#endif /* DISTRIBUTION */
5665 sbpcd[0]=sbpcd_ioaddr; /* possibly changed by kernel command line */
5666 sbpcd[1]=sbpro_type; /* possibly changed by kernel command line */
5667#endif /* MODULE */
5668
5669 for (port_index=0;port_index<NUM_PROBE;port_index+=2)
5670 {
5671 addr[1]=sbpcd[port_index];
5672 if (addr[1]==0) break;
5673 if (check_region(addr[1],4))
5674 {
5675 msg(DBG_INF,"check_region: %03X is not free.\n",addr[1]);
5676 continue;
5677 }
5678 if (sbpcd[port_index+1]==2) type=str_sp;
5679 else if (sbpcd[port_index+1]==1) type=str_sb;
5680 else if (sbpcd[port_index+1]==3) type=str_t16;
5681 else type=str_lm;
5682 sbpcd_setup((char *)type);
5683#if DISTRIBUTION
5684 msg(DBG_INF,"Scanning 0x%X (%s)...\n", CDo_command, type);
5685#endif /* DISTRIBUTION */
5686 if (sbpcd[port_index+1]==2)
5687 {
5688 i=config_spea();
5689 if (i<0) continue;
5690 }
5691#ifdef PATH_CHECK
5692 if (check_card(addr[1])) continue;
5693#endif /* PATH_CHECK */
5694 i=check_drives();
5695 msg(DBG_INI,"check_drives done.\n");
5696 if (i>=0) break; /* drive found */
5697 } /* end of cycling through the set of possible I/O port addresses */
5698
5699 if (ndrives==0)
5700 {
5701 msg(DBG_INF, "No drive found.\n");
5702#ifdef MODULE
5703 return -EIO;
5704#else
5705 goto init_done;
5706#endif /* MODULE */
5707 }
5708
5709 if (port_index>0)
5710 {
5711 msg(DBG_INF, "You should read Documentation/cdrom/sbpcd\n");
5712 msg(DBG_INF, "and then configure sbpcd.h for your hardware.\n");
5713 }
5714 check_datarate();
5715 msg(DBG_INI,"check_datarate done.\n");
5716
5717 for (j=0;j<NR_SBPCD;j++)
5718 {
5719 struct sbpcd_drive *p = D_S + j;
5720 if (p->drv_id==-1)
5721 continue;
5722 switch_drive(p);
5723#if 1
5724 if (!famL_drive) cc_DriveReset();
5725#endif
5726 if (!st_spinning) cc_SpinUp();
5727 p->sbp_first_frame = -1; /* First frame in buffer */
5728 p->sbp_last_frame = -1; /* Last frame in buffer */
5729 p->sbp_read_frames = 0; /* Number of frames being read to buffer */
5730 p->sbp_current = 0; /* Frame being currently read */
5731 p->CD_changed=1;
5732 p->frame_size=CD_FRAMESIZE;
5733 p->f_eject=0;
5734#if EJECT
5735 if (!fam0_drive) p->f_eject=1;
5736#endif /* EJECT */
5737 cc_ReadStatus();
5738 i=ResponseStatus(); /* returns orig. status or p_busy_new */
5739 if (famT_drive) i=ResponseStatus(); /* returns orig. status or p_busy_new */
5740 if (i<0)
5741 {
5742 if (i!=-402)
5743 msg(DBG_INF,"init: ResponseStatus returns %d.\n",i);
5744 }
5745 else
5746 {
5747 if (st_check)
5748 {
5749 i=cc_ReadError();
5750 msg(DBG_INI,"init: cc_ReadError returns %d\n",i);
5751 }
5752 }
5753 msg(DBG_INI,"init: first GetStatus: %d\n",i);
5754 msg(DBG_LCS,"init: first GetStatus: error_byte=%d\n",
5755 p->error_byte);
5756 if (p->error_byte==aud_12)
5757 {
5758 timeout=jiffies+2*HZ;
5759 do
5760 {
5761 i=GetStatus();
5762 msg(DBG_INI,"init: second GetStatus: %02X\n",i);
5763 msg(DBG_LCS,
5764 "init: second GetStatus: error_byte=%d\n",
5765 p->error_byte);
5766 if (i<0) break;
5767 if (!st_caddy_in) break;
5768 }
5769 while ((!st_diskok)||time_after(jiffies, timeout));
5770 }
5771 i=SetSpeed();
5772 if (i>=0) p->CD_changed=1;
5773 }
5774
5775 if (!request_region(CDo_command,4,major_name))
5776 {
5777 printk(KERN_WARNING "sbpcd: Unable to request region 0x%x\n", CDo_command);
5778 return -EIO;
5779 }
5780
5781 /*
5782 * Turn on the CD audio channels.
5783 * The addresses are obtained from SOUND_BASE (see sbpcd.h).
5784 */
5785#if SOUND_BASE
5786 OUT(MIXER_addr,MIXER_CD_Volume); /* select SB Pro mixer register */
5787 OUT(MIXER_data,0xCC); /* one nibble per channel, max. value: 0xFF */
5788#endif /* SOUND_BASE */
5789
5790 if (register_blkdev(MAJOR_NR, major_name)) {
5791#ifdef MODULE
5792 return -EIO;
5793#else
5794 goto init_done;
5795#endif /* MODULE */
5796 }
5797
5798 /*
5799 * init error handling is broken beyond belief in this driver...
5800 */
5801 sbpcd_queue = blk_init_queue(do_sbpcd_request, &sbpcd_lock);
5802 if (!sbpcd_queue) {
5803 release_region(CDo_command,4);
5804 unregister_blkdev(MAJOR_NR, major_name);
5805 return -ENOMEM;
5806 }
5807
5808 for (j=0;j<NR_SBPCD;j++)
5809 {
5810 struct cdrom_device_info * sbpcd_infop;
5811 struct gendisk *disk;
5812 struct sbpcd_drive *p = D_S + j;
5813
5814 if (p->drv_id==-1) continue;
5815 switch_drive(p);
5816#ifdef SAFE_MIXED
5817 p->has_data=0;
5818#endif /* SAFE_MIXED */
5819 /*
5820 * allocate memory for the frame buffers
5821 */
5822 p->aud_buf=NULL;
5823 p->sbp_audsiz=0;
5824 p->sbp_bufsiz=buffers;
5825 if (p->drv_type&drv_fam1)
5826 if (READ_AUDIO>0)
5827 p->sbp_audsiz = READ_AUDIO;
5828 p->sbp_buf=(u_char *) vmalloc(buffers*CD_FRAMESIZE);
5829 if (!p->sbp_buf) {
5830 msg(DBG_INF,"data buffer (%d frames) not available.\n",
5831 buffers);
5832 if ((unregister_blkdev(MAJOR_NR, major_name) == -EINVAL))
5833 {
5834 printk("Can't unregister %s\n", major_name);
5835 }
5836 release_region(CDo_command,4);
5837 blk_cleanup_queue(sbpcd_queue);
5838 return -EIO;
5839 }
5840#ifdef MODULE
5841 msg(DBG_INF,"data buffer size: %d frames.\n",buffers);
5842#endif /* MODULE */
5843 if (p->sbp_audsiz>0)
5844 {
5845 p->aud_buf=(u_char *) vmalloc(p->sbp_audsiz*CD_FRAMESIZE_RAW);
5846 if (p->aud_buf==NULL) msg(DBG_INF,"audio buffer (%d frames) not available.\n",p->sbp_audsiz);
5847 else msg(DBG_INF,"audio buffer size: %d frames.\n",p->sbp_audsiz);
5848 }
5849 sbpcd_infop = vmalloc(sizeof (struct cdrom_device_info));
5850 if (sbpcd_infop == NULL)
5851 {
5852 release_region(CDo_command,4);
5853 blk_cleanup_queue(sbpcd_queue);
5854 return -ENOMEM;
5855 }
5856 memset(sbpcd_infop, 0, sizeof(struct cdrom_device_info));
5857 sbpcd_infop->ops = &sbpcd_dops;
5858 sbpcd_infop->speed = 2;
5859 sbpcd_infop->capacity = 1;
5860 sprintf(sbpcd_infop->name, "sbpcd%d", j);
5861 sbpcd_infop->handle = p;
5862 p->sbpcd_infop = sbpcd_infop;
5863 disk = alloc_disk(1);
5864 disk->major = MAJOR_NR;
5865 disk->first_minor = j;
5866 disk->fops = &sbpcd_bdops;
5867 strcpy(disk->disk_name, sbpcd_infop->name);
5868 disk->flags = GENHD_FL_CD;
5869 p->disk = disk;
5870 if (register_cdrom(sbpcd_infop))
5871 {
5872 printk(" sbpcd: Unable to register with Uniform CD-ROm driver\n");
5873 }
5874 disk->private_data = p;
5875 disk->queue = sbpcd_queue;
5876 add_disk(disk);
5877 }
5878 blk_queue_hardsect_size(sbpcd_queue, CD_FRAMESIZE);
5879
5880#ifndef MODULE
5881 init_done:
5882#endif
5883 return 0;
5884}
5885/*==========================================================================*/
5886#ifdef MODULE
5887static void sbpcd_exit(void)
5888{
5889 int j;
5890
5891 if ((unregister_blkdev(MAJOR_NR, major_name) == -EINVAL))
5892 {
5893 msg(DBG_INF, "What's that: can't unregister %s.\n", major_name);
5894 return;
5895 }
5896 release_region(CDo_command,4);
5897 blk_cleanup_queue(sbpcd_queue);
5898 for (j=0;j<NR_SBPCD;j++)
5899 {
5900 if (D_S[j].drv_id==-1) continue;
5901 del_gendisk(D_S[j].disk);
5902 put_disk(D_S[j].disk);
5903 vfree(D_S[j].sbp_buf);
5904 if (D_S[j].sbp_audsiz>0)
5905 vfree(D_S[j].aud_buf);
5906 if ((unregister_cdrom(D_S[j].sbpcd_infop) == -EINVAL))
5907 {
5908 msg(DBG_INF, "What's that: can't unregister info %s.\n", major_name);
5909 return;
5910 }
5911 vfree(D_S[j].sbpcd_infop);
5912 }
5913 msg(DBG_INF, "%s module released.\n", major_name);
5914}
5915
5916
5917module_init(__sbpcd_init) /*HACK!*/;
5918module_exit(sbpcd_exit);
5919
5920
5921#endif /* MODULE */
5922static int sbpcd_media_changed(struct cdrom_device_info *cdi, int disc_nr)
5923{
5924 struct sbpcd_drive *p = cdi->handle;
5925 msg(DBG_CHK,"media_check (%s) called\n", cdi->name);
5926
5927 if (p->CD_changed==0xFF)
5928 {
5929 p->CD_changed=0;
5930 msg(DBG_CHK,"medium changed (drive %s)\n", cdi->name);
5931 current_drive->diskstate_flags &= ~toc_bit;
5932 /* we *don't* need invalidate here, it's done by caller */
5933 current_drive->diskstate_flags &= ~cd_size_bit;
5934#ifdef SAFE_MIXED
5935 current_drive->has_data=0;
5936#endif /* SAFE_MIXED */
5937
5938 return (1);
5939 }
5940 else
5941 return (0);
5942}
5943
5944MODULE_LICENSE("GPL");
5945/* FIXME: Old modules.conf claims MATSUSHITA_CDROM2_MAJOR and CDROM3, but
5946 AFAICT this doesn't support those majors, so why? --RR 30 Jul 2003 */
5947MODULE_ALIAS_BLOCKDEV_MAJOR(MATSUSHITA_CDROM_MAJOR);
5948
5949/*==========================================================================*/
5950/*
5951 * Overrides for Emacs so that we follow Linus's tabbing style.
5952 * Emacs will notice this stuff at the end of the file and automatically
5953 * adjust the settings for this buffer only. This must remain at the end
5954 * of the file.
5955 * ---------------------------------------------------------------------------
5956 * Local variables:
5957 * c-indent-level: 8
5958 * c-brace-imaginary-offset: 0
5959 * c-brace-offset: -8
5960 * c-argdecl-indent: 8
5961 * c-label-offset: -8
5962 * c-continued-statement-offset: 8
5963 * c-continued-brace-offset: 0
5964 * End:
5965 */
5966
diff --git a/drivers/cdrom/sbpcd.h b/drivers/cdrom/sbpcd.h
deleted file mode 100644
index 2f2225f13c6f..000000000000
--- a/drivers/cdrom/sbpcd.h
+++ /dev/null
@@ -1,839 +0,0 @@
1/*
2 * sbpcd.h Specify interface address and interface type here.
3 */
4
5/*
6 * Attention! This file contains user-serviceable parts!
7 * I recommend to make use of it...
8 * If you feel helpless, look into Documentation/cdrom/sbpcd
9 * (good idea anyway, at least before mailing me).
10 *
11 * The definitions for the first controller can get overridden by
12 * the kernel command line ("lilo boot option").
13 * Examples:
14 * sbpcd=0x300,LaserMate
15 * or
16 * sbpcd=0x230,SoundBlaster
17 * or
18 * sbpcd=0x338,SoundScape
19 * or
20 * sbpcd=0x2C0,Teac16bit
21 *
22 * If sbpcd gets used as a module, you can load it with
23 * insmod sbpcd.o sbpcd=0x300,0
24 * or
25 * insmod sbpcd.o sbpcd=0x230,1
26 * or
27 * insmod sbpcd.o sbpcd=0x338,2
28 * or
29 * insmod sbpcd.o sbpcd=0x2C0,3
30 * respective to override the configured address and type.
31 */
32
33/*
34 * define your CDROM port base address as CDROM_PORT
35 * and specify the type of your interface card as SBPRO.
36 *
37 * address:
38 * ========
39 * SBPRO type addresses typically are 0x0230 (=0x220+0x10), 0x0250, ...
40 * LASERMATE type (CI-101P, WDH-7001C) addresses typically are 0x0300, ...
41 * SOUNDSCAPE addresses are from the LASERMATE type and range. You have to
42 * specify the REAL address here, not the configuration port address. Look
43 * at the CDROM driver's invoking line within your DOS CONFIG.SYS, or let
44 * sbpcd auto-probe, if you are not firm with the address.
45 * There are some soundcards on the market with 0x0630, 0x0650, ...; their
46 * type is not obvious (both types are possible).
47 *
48 * example: if your SBPRO audio address is 0x220, specify 0x230 and SBPRO 1.
49 * if your soundcard has its CDROM port above 0x300, specify
50 * that address and try SBPRO 0 first.
51 * if your SoundScape configuration port is at 0x330, specify
52 * 0x338 and SBPRO 2.
53 *
54 * interface type:
55 * ===============
56 * set SBPRO to 1 for "true" SoundBlaster card
57 * set SBPRO to 0 for "compatible" soundcards and
58 * for "poor" (no sound) interface cards.
59 * set SBPRO to 2 for Ensonic SoundScape or SPEA Media FX cards
60 * set SBPRO to 3 for Teac 16bit interface cards
61 *
62 * Almost all "compatible" sound boards need to set SBPRO to 0.
63 * If SBPRO is set wrong, the drives will get found - but any
64 * data access will give errors (audio access will work).
65 * The "OmniCD" no-sound interface card from CreativeLabs and most Teac
66 * interface cards need SBPRO 1.
67 *
68 * sound base:
69 * ===========
70 * The SOUND_BASE definition tells if we should try to turn the CD sound
71 * channels on. It will only be of use regarding soundcards with a SbPro
72 * compatible mixer.
73 *
74 * Example: #define SOUND_BASE 0x220 enables the sound card's CD channels
75 * #define SOUND_BASE 0 leaves the soundcard untouched
76 */
77#define CDROM_PORT 0x340 /* <-----------<< port address */
78#define SBPRO 0 /* <-----------<< interface type */
79#define MAX_DRIVES 4 /* set to 1 if the card does not use "drive select" */
80#define SOUND_BASE 0x220 /* <-----------<< sound address of this card or 0 */
81
82/*
83 * some more or less user dependent definitions - service them!
84 */
85
86/* Set this to 0 once you have configured your interface definitions right. */
87#define DISTRIBUTION 1
88
89/*
90 * Time to wait after giving a message.
91 * This gets important if you enable non-standard DBG_xxx flags.
92 * You will see what happens if you omit the pause or make it
93 * too short. Be warned!
94 */
95#define KLOGD_PAUSE 1
96
97/* tray control: eject tray if no disk is in */
98#if DISTRIBUTION
99#define JUKEBOX 0
100#else
101#define JUKEBOX 1
102#endif /* DISTRIBUTION */
103
104/* tray control: eject tray after last use */
105#if DISTRIBUTION
106#define EJECT 0
107#else
108#define EJECT 1
109#endif /* DISTRIBUTION */
110
111/* max. number of audio frames to read with one */
112/* request (allocates n* 2352 bytes kernel memory!) */
113/* may be freely adjusted, f.e. 75 (= 1 sec.), at */
114/* runtime by use of the CDROMAUDIOBUFSIZ ioctl. */
115#define READ_AUDIO 0
116
117/* Optimizations for the Teac CD-55A drive read performance.
118 * SBP_TEAC_SPEED can be changed here, or one can set the
119 * variable "teac" when loading as a module.
120 * Valid settings are:
121 * 0 - very slow - the recommended "DISTRIBUTION 1" setup.
122 * 1 - 2x performance with little overhead. No busy waiting.
123 * 2 - 4x performance with 5ms overhead per read. Busy wait.
124 *
125 * Setting SBP_TEAC_SPEED or the variable 'teac' to anything
126 * other than 0 may cause problems. If you run into them, first
127 * change SBP_TEAC_SPEED back to 0 and see if your drive responds
128 * normally. If yes, you are "allowed" to report your case - to help
129 * me with the driver, not to solve your hassle. Don´t mail if you
130 * simply are stuck into your own "tuning" experiments, you know?
131 */
132#define SBP_TEAC_SPEED 1
133
134/*==========================================================================*/
135/*==========================================================================*/
136/*
137 * nothing to change below here if you are not fully aware what you're doing
138 */
139#ifndef _LINUX_SBPCD_H
140
141#define _LINUX_SBPCD_H
142/*==========================================================================*/
143/*==========================================================================*/
144/*
145 * driver's own read_ahead, data mode
146 */
147#define SBP_BUFFER_FRAMES 8
148
149#define LONG_TIMING 0 /* test against timeouts with "gold" CDs on CR-521 */
150#undef FUTURE
151#undef SAFE_MIXED
152
153#define TEST_UPC 0
154#define SPEA_TEST 0
155#define TEST_STI 0
156#define OLD_BUSY 0
157#undef PATH_CHECK
158#ifndef SOUND_BASE
159#define SOUND_BASE 0
160#endif
161#if DISTRIBUTION
162#undef SBP_TEAC_SPEED
163#define SBP_TEAC_SPEED 0
164#endif
165/*==========================================================================*/
166/*
167 * DDI interface definitions
168 * "invented" by Fred N. van Kempen..
169 */
170#define DDIOCSDBG 0x9000
171
172/*==========================================================================*/
173/*
174 * "private" IOCTL functions
175 */
176#define CDROMAUDIOBUFSIZ 0x5382 /* set the audio buffer size */
177
178/*==========================================================================*/
179/*
180 * Debug output levels
181 */
182#define DBG_INF 1 /* necessary information */
183#define DBG_BSZ 2 /* BLOCK_SIZE trace */
184#define DBG_REA 3 /* READ status trace */
185#define DBG_CHK 4 /* MEDIA CHECK trace */
186#define DBG_TIM 5 /* datarate timer test */
187#define DBG_INI 6 /* initialization trace */
188#define DBG_TOC 7 /* tell TocEntry values */
189#define DBG_IOC 8 /* ioctl trace */
190#define DBG_STA 9 /* ResponseStatus() trace */
191#define DBG_ERR 10 /* cc_ReadError() trace */
192#define DBG_CMD 11 /* cmd_out() trace */
193#define DBG_WRN 12 /* give explanation before auto-probing */
194#define DBG_MUL 13 /* multi session code test */
195#define DBG_IDX 14 /* test code for drive_id !=0 */
196#define DBG_IOX 15 /* some special information */
197#define DBG_DID 16 /* drive ID test */
198#define DBG_RES 17 /* drive reset info */
199#define DBG_SPI 18 /* SpinUp test */
200#define DBG_IOS 19 /* ioctl trace: subchannel functions */
201#define DBG_IO2 20 /* ioctl trace: general */
202#define DBG_UPC 21 /* show UPC information */
203#define DBG_XA1 22 /* XA mode debugging */
204#define DBG_LCK 23 /* door (un)lock info */
205#define DBG_SQ1 24 /* dump SubQ frame */
206#define DBG_AUD 25 /* READ AUDIO debugging */
207#define DBG_SEQ 26 /* Sequoia interface configuration trace */
208#define DBG_LCS 27 /* Longshine LCS-7260 debugging trace */
209#define DBG_CD2 28 /* MKE/Funai CD200 debugging trace */
210#define DBG_TEA 29 /* TEAC CD-55A debugging trace */
211#define DBG_ECS 30 /* ECS-AT (Vertos 100) debugging trace */
212#define DBG_000 31 /* unnecessary information */
213
214/*==========================================================================*/
215/*==========================================================================*/
216
217/*
218 * bits of flags_cmd_out:
219 */
220#define f_respo3 0x100
221#define f_putcmd 0x80
222#define f_respo2 0x40
223#define f_lopsta 0x20
224#define f_getsta 0x10
225#define f_ResponseStatus 0x08
226#define f_obey_p_check 0x04
227#define f_bit1 0x02
228#define f_wait_if_busy 0x01
229
230/*
231 * diskstate_flags:
232 */
233#define x80_bit 0x80
234#define upc_bit 0x40
235#define volume_bit 0x20
236#define toc_bit 0x10
237#define multisession_bit 0x08
238#define cd_size_bit 0x04
239#define subq_bit 0x02
240#define frame_size_bit 0x01
241
242/*
243 * disk states (bits of diskstate_flags):
244 */
245#define upc_valid (current_drive->diskstate_flags&upc_bit)
246#define volume_valid (current_drive->diskstate_flags&volume_bit)
247#define toc_valid (current_drive->diskstate_flags&toc_bit)
248#define cd_size_valid (current_drive->diskstate_flags&cd_size_bit)
249#define subq_valid (current_drive->diskstate_flags&subq_bit)
250#define frame_size_valid (current_drive->diskstate_flags&frame_size_bit)
251
252/*
253 * the status_bits variable
254 */
255#define p_success 0x100
256#define p_door_closed 0x80
257#define p_caddy_in 0x40
258#define p_spinning 0x20
259#define p_check 0x10
260#define p_busy_new 0x08
261#define p_door_locked 0x04
262#define p_disk_ok 0x01
263
264/*
265 * LCS-7260 special status result bits:
266 */
267#define p_lcs_door_locked 0x02
268#define p_lcs_door_closed 0x01 /* probably disk_in */
269
270/*
271 * CR-52x special status result bits:
272 */
273#define p_caddin_old 0x40
274#define p_success_old 0x08
275#define p_busy_old 0x04
276#define p_bit_1 0x02 /* hopefully unused now */
277
278/*
279 * "generation specific" defs of the status result bits:
280 */
281#define p0_door_closed 0x80
282#define p0_caddy_in 0x40
283#define p0_spinning 0x20
284#define p0_check 0x10
285#define p0_success 0x08 /* unused */
286#define p0_busy 0x04
287#define p0_bit_1 0x02 /* unused */
288#define p0_disk_ok 0x01
289
290#define pL_disk_in 0x40
291#define pL_spinning 0x20
292#define pL_check 0x10
293#define pL_success 0x08 /* unused ?? */
294#define pL_busy 0x04
295#define pL_door_locked 0x02
296#define pL_door_closed 0x01
297
298#define pV_door_closed 0x40
299#define pV_spinning 0x20
300#define pV_check 0x10
301#define pV_success 0x08
302#define pV_busy 0x04
303#define pV_door_locked 0x02
304#define pV_disk_ok 0x01
305
306#define p1_door_closed 0x80
307#define p1_disk_in 0x40
308#define p1_spinning 0x20
309#define p1_check 0x10
310#define p1_busy 0x08
311#define p1_door_locked 0x04
312#define p1_bit_1 0x02 /* unused */
313#define p1_disk_ok 0x01
314
315#define p2_disk_ok 0x80
316#define p2_door_locked 0x40
317#define p2_spinning 0x20
318#define p2_busy2 0x10
319#define p2_busy1 0x08
320#define p2_door_closed 0x04
321#define p2_disk_in 0x02
322#define p2_check 0x01
323
324/*
325 * used drive states:
326 */
327#define st_door_closed (current_drive->status_bits&p_door_closed)
328#define st_caddy_in (current_drive->status_bits&p_caddy_in)
329#define st_spinning (current_drive->status_bits&p_spinning)
330#define st_check (current_drive->status_bits&p_check)
331#define st_busy (current_drive->status_bits&p_busy_new)
332#define st_door_locked (current_drive->status_bits&p_door_locked)
333#define st_diskok (current_drive->status_bits&p_disk_ok)
334
335/*
336 * bits of the CDi_status register:
337 */
338#define s_not_result_ready 0x04 /* 0: "result ready" */
339#define s_not_data_ready 0x02 /* 0: "data ready" */
340#define s_attention 0x01 /* 1: "attention required" */
341/*
342 * usable as:
343 */
344#define DRV_ATTN ((inb(CDi_status)&s_attention)!=0)
345#define DATA_READY ((inb(CDi_status)&s_not_data_ready)==0)
346#define RESULT_READY ((inb(CDi_status)&s_not_result_ready)==0)
347
348/*
349 * drive families and types (firmware versions):
350 */
351#define drv_fam0 0x0100 /* CR-52x family */
352#define drv_199 (drv_fam0+0x01) /* <200 */
353#define drv_200 (drv_fam0+0x02) /* <201 */
354#define drv_201 (drv_fam0+0x03) /* <210 */
355#define drv_210 (drv_fam0+0x04) /* <211 */
356#define drv_211 (drv_fam0+0x05) /* <300 */
357#define drv_300 (drv_fam0+0x06) /* >=300 */
358
359#define drv_fam1 0x0200 /* CR-56x family */
360#define drv_099 (drv_fam1+0x01) /* <100 */
361#define drv_100 (drv_fam1+0x02) /* >=100, only 1.02 and 5.00 known */
362
363#define drv_fam2 0x0400 /* CD200 family */
364
365#define drv_famT 0x0800 /* TEAC CD-55A */
366
367#define drv_famL 0x1000 /* Longshine family */
368#define drv_260 (drv_famL+0x01) /* LCS-7260 */
369#define drv_e1 (drv_famL+0x01) /* LCS-7260, firmware "A E1" */
370#define drv_f4 (drv_famL+0x02) /* LCS-7260, firmware "A4F4" */
371
372#define drv_famV 0x2000 /* ECS-AT (vertos-100) family */
373#define drv_at (drv_famV+0x01) /* ECS-AT, firmware "1.00" */
374
375#define fam0_drive (current_drive->drv_type&drv_fam0)
376#define famL_drive (current_drive->drv_type&drv_famL)
377#define famV_drive (current_drive->drv_type&drv_famV)
378#define fam1_drive (current_drive->drv_type&drv_fam1)
379#define fam2_drive (current_drive->drv_type&drv_fam2)
380#define famT_drive (current_drive->drv_type&drv_famT)
381#define fam0L_drive (current_drive->drv_type&(drv_fam0|drv_famL))
382#define fam0V_drive (current_drive->drv_type&(drv_fam0|drv_famV))
383#define famLV_drive (current_drive->drv_type&(drv_famL|drv_famV))
384#define fam0LV_drive (current_drive->drv_type&(drv_fam0|drv_famL|drv_famV))
385#define fam1L_drive (current_drive->drv_type&(drv_fam1|drv_famL))
386#define fam1V_drive (current_drive->drv_type&(drv_fam1|drv_famV))
387#define fam1LV_drive (current_drive->drv_type&(drv_fam1|drv_famL|drv_famV))
388#define fam01_drive (current_drive->drv_type&(drv_fam0|drv_fam1))
389#define fam12_drive (current_drive->drv_type&(drv_fam1|drv_fam2))
390#define fam2T_drive (current_drive->drv_type&(drv_fam2|drv_famT))
391
392/*
393 * audio states:
394 */
395#define audio_completed 3 /* Forgot this one! --AJK */
396#define audio_playing 2
397#define audio_pausing 1
398
399/*
400 * drv_pattern, drv_options:
401 */
402#define speed_auto 0x80
403#define speed_300 0x40
404#define speed_150 0x20
405#define audio_mono 0x04
406
407/*
408 * values of cmd_type (0 else):
409 */
410#define READ_M1 0x01 /* "data mode 1": 2048 bytes per frame */
411#define READ_M2 0x02 /* "data mode 2": 12+2048+280 bytes per frame */
412#define READ_SC 0x04 /* "subchannel info": 96 bytes per frame */
413#define READ_AU 0x08 /* "audio frame": 2352 bytes per frame */
414
415/*
416 * sense_byte:
417 *
418 * values: 00
419 * 01
420 * 81
421 * 82 "raw audio" mode
422 * xx from infobuf[0] after 85 00 00 00 00 00 00
423 */
424
425/* audio status (bin) */
426#define aud_00 0x00 /* Audio status byte not supported or not valid */
427#define audx11 0x0b /* Audio play operation in progress */
428#define audx12 0x0c /* Audio play operation paused */
429#define audx13 0x0d /* Audio play operation successfully completed */
430#define audx14 0x0e /* Audio play operation stopped due to error */
431#define audx15 0x0f /* No current audio status to return */
432/* audio status (bcd) */
433#define aud_11 0x11 /* Audio play operation in progress */
434#define aud_12 0x12 /* Audio play operation paused */
435#define aud_13 0x13 /* Audio play operation successfully completed */
436#define aud_14 0x14 /* Audio play operation stopped due to error */
437#define aud_15 0x15 /* No current audio status to return */
438
439/*
440 * highest allowed drive number (MINOR+1)
441 */
442#define NR_SBPCD 4
443
444/*
445 * we try to never disable interrupts - seems to work
446 */
447#define SBPCD_DIS_IRQ 0
448
449/*
450 * "write byte to port"
451 */
452#define OUT(x,y) outb(y,x)
453
454/*==========================================================================*/
455
456#define MIXER_addr SOUND_BASE+4 /* sound card's address register */
457#define MIXER_data SOUND_BASE+5 /* sound card's data register */
458#define MIXER_CD_Volume 0x28 /* internal SB Pro register address */
459
460/*==========================================================================*/
461
462#define MAX_TRACKS 99
463
464#define ERR_DISKCHANGE 615
465
466/*==========================================================================*/
467/*
468 * To make conversions easier (machine dependent!)
469 */
470typedef union _msf
471{
472 u_int n;
473 u_char c[4];
474} MSF;
475
476typedef union _blk
477{
478 u_int n;
479 u_char c[4];
480} BLK;
481
482/*==========================================================================*/
483
484/*============================================================================
485==============================================================================
486
487COMMAND SET of "old" drives like CR-521, CR-522
488 (the CR-562 family is different):
489
490No. Command Code
491--------------------------------------------
492
493Drive Commands:
494 1 Seek 01
495 2 Read Data 02
496 3 Read XA-Data 03
497 4 Read Header 04
498 5 Spin Up 05
499 6 Spin Down 06
500 7 Diagnostic 07
501 8 Read UPC 08
502 9 Read ISRC 09
50310 Play Audio 0A
50411 Play Audio MSF 0B
50512 Play Audio Track/Index 0C
506
507Status Commands:
50813 Read Status 81
50914 Read Error 82
51015 Read Drive Version 83
51116 Mode Select 84
51217 Mode Sense 85
51318 Set XA Parameter 86
51419 Read XA Parameter 87
51520 Read Capacity 88
51621 Read SUB_Q 89
51722 Read Disc Code 8A
51823 Read Disc Information 8B
51924 Read TOC 8C
52025 Pause/Resume 8D
52126 Read Packet 8E
52227 Read Path Check 00
523
524
525all numbers (lba, msf-bin, msf-bcd, counts) to transfer high byte first
526
527mnemo 7-byte command #bytes response (r0...rn)
528________ ____________________ ____
529
530Read Status:
531status: 81. (1) one-byte command, gives the main
532 status byte
533Read Error:
534check1: 82 00 00 00 00 00 00. (6) r1: audio status
535
536Read Packet:
537check2: 8e xx 00 00 00 00 00. (xx) gets xx bytes response, relating
538 to commands 01 04 05 07 08 09
539
540Play Audio:
541play: 0a ll-bb-aa nn-nn-nn. (0) play audio, ll-bb-aa: starting block (lba),
542 nn-nn-nn: #blocks
543Play Audio MSF:
544 0b mm-ss-ff mm-ss-ff (0) play audio from/to
545
546Play Audio Track/Index:
547 0c ...
548
549Pause/Resume:
550pause: 8d pr 00 00 00 00 00. (0) pause (pr=00)
551 resume (pr=80) audio playing
552
553Mode Select:
554 84 00 nn-nn ??.?? 00 (0) nn-nn: 2048 or 2340
555 possibly defines transfer size
556
557set_vol: 84 83 00 00 sw le 00. (0) sw(itch): lrxxxxxx (off=1)
558 le(vel): min=0, max=FF, else half
559 (firmware 2.11)
560
561Mode Sense:
562get_vol: 85 03 00 00 00 00 00. (2) tell current audio volume setting
563
564Read Disc Information:
565tocdesc: 8b 00 00 00 00 00 00. (6) read the toc descriptor ("msf-bin"-format)
566
567Read TOC:
568tocent: 8c fl nn 00 00 00 00. (8) read toc entry #nn
569 (fl=0:"lba"-, =2:"msf-bin"-format)
570
571Read Capacity:
572capacit: 88 00 00 00 00 00 00. (5) "read CD-ROM capacity"
573
574
575Read Path Check:
576ping: 00 00 00 00 00 00 00. (2) r0=AA, r1=55
577 ("ping" if the drive is connected)
578
579Read Drive Version:
580ident: 83 00 00 00 00 00 00. (12) gives "MATSHITAn.nn"
581 (n.nn = 2.01, 2.11., 3.00, ...)
582
583Seek:
584seek: 01 00 ll-bb-aa 00 00. (0)
585seek: 01 02 mm-ss-ff 00 00. (0)
586
587Read Data:
588read: 02 xx-xx-xx nn-nn fl. (?) read nn-nn blocks of 2048 bytes,
589 starting at block xx-xx-xx
590 fl=0: "lba"-, =2:"msf-bcd"-coded xx-xx-xx
591
592Read XA-Data:
593read: 03 xx-xx-xx nn-nn fl. (?) read nn-nn blocks of 2340 bytes,
594 starting at block xx-xx-xx
595 fl=0: "lba"-, =2:"msf-bcd"-coded xx-xx-xx
596
597Read SUB_Q:
598 89 fl 00 00 00 00 00. (13) r0: audio status, r4-r7: lba/msf,
599 fl=0: "lba", fl=2: "msf"
600
601Read Disc Code:
602 8a 00 00 00 00 00 00. (14) possibly extended "check condition"-info
603
604Read Header:
605 04 00 ll-bb-aa 00 00. (0) 4 bytes response with "check2"
606 04 02 mm-ss-ff 00 00. (0) 4 bytes response with "check2"
607
608Spin Up:
609 05 00 ll-bb-aa 00 00. (0) possibly implies a "seek"
610
611Spin Down:
612 06 ...
613
614Diagnostic:
615 07 00 ll-bb-aa 00 00. (2) 2 bytes response with "check2"
616 07 02 mm-ss-ff 00 00. (2) 2 bytes response with "check2"
617
618Read UPC:
619 08 00 ll-bb-aa 00 00. (16)
620 08 02 mm-ss-ff 00 00. (16)
621
622Read ISRC:
623 09 00 ll-bb-aa 00 00. (15) 15 bytes response with "check2"
624 09 02 mm-ss-ff 00 00. (15) 15 bytes response with "check2"
625
626Set XA Parameter:
627 86 ...
628
629Read XA Parameter:
630 87 ...
631
632==============================================================================
633============================================================================*/
634
635/*
636 * commands
637 *
638 * CR-52x: CMD0_
639 * CR-56x: CMD1_
640 * CD200: CMD2_
641 * LCS-7260: CMDL_
642 * TEAC CD-55A: CMDT_
643 * ECS-AT: CMDV_
644 */
645#define CMD1_RESET 0x0a
646#define CMD2_RESET 0x01
647#define CMDT_RESET 0xc0
648
649#define CMD1_LOCK_CTL 0x0c
650#define CMD2_LOCK_CTL 0x1e
651#define CMDT_LOCK_CTL CMD2_LOCK_CTL
652#define CMDL_LOCK_CTL 0x0e
653#define CMDV_LOCK_CTL CMDL_LOCK_CTL
654
655#define CMD1_TRAY_CTL 0x07
656#define CMD2_TRAY_CTL 0x1b
657#define CMDT_TRAY_CTL CMD2_TRAY_CTL
658#define CMDL_TRAY_CTL 0x0d
659#define CMDV_TRAY_CTL CMDL_TRAY_CTL
660
661#define CMD1_MULTISESS 0x8d
662#define CMDL_MULTISESS 0x8c
663#define CMDV_MULTISESS CMDL_MULTISESS
664
665#define CMD1_SUBCHANINF 0x11
666#define CMD2_SUBCHANINF 0x??
667
668#define CMD1_ABORT 0x08
669#define CMD2_ABORT 0x08
670#define CMDT_ABORT 0x08
671
672#define CMD2_x02 0x02
673
674#define CMD2_SETSPEED 0xda
675
676#define CMD0_PATH_CHECK 0x00
677#define CMD1_PATH_CHECK 0x???
678#define CMD2_PATH_CHECK 0x???
679#define CMDT_PATH_CHECK 0x???
680#define CMDL_PATH_CHECK CMD0_PATH_CHECK
681#define CMDV_PATH_CHECK CMD0_PATH_CHECK
682
683#define CMD0_SEEK 0x01
684#define CMD1_SEEK CMD0_SEEK
685#define CMD2_SEEK 0x2b
686#define CMDT_SEEK CMD2_SEEK
687#define CMDL_SEEK CMD0_SEEK
688#define CMDV_SEEK CMD0_SEEK
689
690#define CMD0_READ 0x02
691#define CMD1_READ 0x10
692#define CMD2_READ 0x28
693#define CMDT_READ CMD2_READ
694#define CMDL_READ CMD0_READ
695#define CMDV_READ CMD0_READ
696
697#define CMD0_READ_XA 0x03
698#define CMD2_READ_XA 0xd4
699#define CMD2_READ_XA2 0xd5
700#define CMDL_READ_XA CMD0_READ_XA /* really ?? */
701#define CMDV_READ_XA CMD0_READ_XA
702
703#define CMD0_READ_HEAD 0x04
704
705#define CMD0_SPINUP 0x05
706#define CMD1_SPINUP 0x02
707#define CMD2_SPINUP CMD2_TRAY_CTL
708#define CMDL_SPINUP CMD0_SPINUP
709#define CMDV_SPINUP CMD0_SPINUP
710
711#define CMD0_SPINDOWN 0x06 /* really??? */
712#define CMD1_SPINDOWN 0x06
713#define CMD2_SPINDOWN CMD2_TRAY_CTL
714#define CMDL_SPINDOWN 0x0d
715#define CMDV_SPINDOWN CMD0_SPINDOWN
716
717#define CMD0_DIAG 0x07
718
719#define CMD0_READ_UPC 0x08
720#define CMD1_READ_UPC 0x88
721#define CMD2_READ_UPC 0x???
722#define CMDL_READ_UPC CMD0_READ_UPC
723#define CMDV_READ_UPC 0x8f
724
725#define CMD0_READ_ISRC 0x09
726
727#define CMD0_PLAY 0x0a
728#define CMD1_PLAY 0x???
729#define CMD2_PLAY 0x???
730#define CMDL_PLAY CMD0_PLAY
731#define CMDV_PLAY CMD0_PLAY
732
733#define CMD0_PLAY_MSF 0x0b
734#define CMD1_PLAY_MSF 0x0e
735#define CMD2_PLAY_MSF 0x47
736#define CMDT_PLAY_MSF CMD2_PLAY_MSF
737#define CMDL_PLAY_MSF 0x???
738
739#define CMD0_PLAY_TI 0x0c
740#define CMD1_PLAY_TI 0x0f
741
742#define CMD0_STATUS 0x81
743#define CMD1_STATUS 0x05
744#define CMD2_STATUS 0x00
745#define CMDT_STATUS CMD2_STATUS
746#define CMDL_STATUS CMD0_STATUS
747#define CMDV_STATUS CMD0_STATUS
748#define CMD2_SEEK_LEADIN 0x00
749
750#define CMD0_READ_ERR 0x82
751#define CMD1_READ_ERR CMD0_READ_ERR
752#define CMD2_READ_ERR 0x03
753#define CMDT_READ_ERR CMD2_READ_ERR /* get audio status */
754#define CMDL_READ_ERR CMD0_READ_ERR
755#define CMDV_READ_ERR CMD0_READ_ERR
756
757#define CMD0_READ_VER 0x83
758#define CMD1_READ_VER CMD0_READ_VER
759#define CMD2_READ_VER 0x12
760#define CMDT_READ_VER CMD2_READ_VER /* really ?? */
761#define CMDL_READ_VER CMD0_READ_VER
762#define CMDV_READ_VER CMD0_READ_VER
763
764#define CMD0_SETMODE 0x84
765#define CMD1_SETMODE 0x09
766#define CMD2_SETMODE 0x55
767#define CMDT_SETMODE CMD2_SETMODE
768#define CMDL_SETMODE CMD0_SETMODE
769
770#define CMD0_GETMODE 0x85
771#define CMD1_GETMODE 0x84
772#define CMD2_GETMODE 0x5a
773#define CMDT_GETMODE CMD2_GETMODE
774#define CMDL_GETMODE CMD0_GETMODE
775
776#define CMD0_SET_XA 0x86
777
778#define CMD0_GET_XA 0x87
779
780#define CMD0_CAPACITY 0x88
781#define CMD1_CAPACITY 0x85
782#define CMD2_CAPACITY 0x25
783#define CMDL_CAPACITY CMD0_CAPACITY /* missing in some firmware versions */
784
785#define CMD0_READSUBQ 0x89
786#define CMD1_READSUBQ 0x87
787#define CMD2_READSUBQ 0x42
788#define CMDT_READSUBQ CMD2_READSUBQ
789#define CMDL_READSUBQ CMD0_READSUBQ
790#define CMDV_READSUBQ CMD0_READSUBQ
791
792#define CMD0_DISKCODE 0x8a
793
794#define CMD0_DISKINFO 0x8b
795#define CMD1_DISKINFO CMD0_DISKINFO
796#define CMD2_DISKINFO 0x43
797#define CMDT_DISKINFO CMD2_DISKINFO
798#define CMDL_DISKINFO CMD0_DISKINFO
799#define CMDV_DISKINFO CMD0_DISKINFO
800
801#define CMD0_READTOC 0x8c
802#define CMD1_READTOC CMD0_READTOC
803#define CMD2_READTOC 0x???
804#define CMDL_READTOC CMD0_READTOC
805#define CMDV_READTOC CMD0_READTOC
806
807#define CMD0_PAU_RES 0x8d
808#define CMD1_PAU_RES 0x0d
809#define CMD2_PAU_RES 0x4b
810#define CMDT_PAUSE CMD2_PAU_RES
811#define CMDL_PAU_RES CMD0_PAU_RES
812#define CMDV_PAUSE CMD0_PAU_RES
813
814#define CMD0_PACKET 0x8e
815#define CMD1_PACKET CMD0_PACKET
816#define CMD2_PACKET 0x???
817#define CMDL_PACKET CMD0_PACKET
818#define CMDV_PACKET 0x???
819
820/*==========================================================================*/
821/*==========================================================================*/
822#endif /* _LINUX_SBPCD_H */
823/*==========================================================================*/
824/*
825 * Overrides for Emacs so that we follow Linus's tabbing style.
826 * Emacs will notice this stuff at the end of the file and automatically
827 * adjust the settings for this buffer only. This must remain at the end
828 * of the file.
829 * ---------------------------------------------------------------------------
830 * Local variables:
831 * c-indent-level: 8
832 * c-brace-imaginary-offset: 0
833 * c-brace-offset: -8
834 * c-argdecl-indent: 8
835 * c-label-offset: -8
836 * c-continued-statement-offset: 8
837 * c-continued-brace-offset: 0
838 * End:
839 */
diff --git a/drivers/cdrom/sjcd.c b/drivers/cdrom/sjcd.c
deleted file mode 100644
index 76c24e679e68..000000000000
--- a/drivers/cdrom/sjcd.c
+++ /dev/null
@@ -1,1815 +0,0 @@
1/* -- sjcd.c
2 *
3 * Sanyo CD-ROM device driver implementation, Version 1.6
4 * Copyright (C) 1995 Vadim V. Model
5 *
6 * model@cecmow.enet.dec.com
7 * vadim@rbrf.ru
8 * vadim@ipsun.ras.ru
9 *
10 *
11 * This driver is based on pre-works by Eberhard Moenkeberg (emoenke@gwdg.de);
12 * it was developed under use of mcd.c from Martin Harriss, with help of
13 * Eric van der Maarel (H.T.M.v.d.Maarel@marin.nl).
14 *
15 * It is planned to include these routines into sbpcd.c later - to make
16 * a "mixed use" on one cable possible for all kinds of drives which use
17 * the SoundBlaster/Panasonic style CDROM interface. But today, the
18 * ability to install directly from CDROM is more important than flexibility.
19 *
20 * This program is free software; you can redistribute it and/or modify
21 * it under the terms of the GNU General Public License as published by
22 * the Free Software Foundation; either version 2 of the License, or
23 * (at your option) any later version.
24 *
25 * This program is distributed in the hope that it will be useful,
26 * but WITHOUT ANY WARRANTY; without even the implied warranty of
27 * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
28 * GNU General Public License for more details.
29 *
30 * You should have received a copy of the GNU General Public License
31 * along with this program; if not, write to the Free Software
32 * Foundation, Inc., 675 Mass Ave, Cambridge, MA 02139, USA.
33 *
34 * History:
35 * 1.1 First public release with kernel version 1.3.7.
36 * Written by Vadim Model.
37 * 1.2 Added detection and configuration of cdrom interface
38 * on ISP16 soundcard.
39 * Allow for command line options: sjcd=<io_base>,<irq>,<dma>
40 * 1.3 Some minor changes to README.sjcd.
41 * 1.4 MSS Sound support!! Listen to a CD through the speakers.
42 * 1.5 Module support and bugfixes.
43 * Tray locking.
44 * 1.6 Removed ISP16 code from this driver.
45 * Allow only to set io base address on command line: sjcd=<io_base>
46 * Changes to Documentation/cdrom/sjcd
47 * Added cleanup after any error in the initialisation.
48 * 1.7 Added code to set the sector size tables to prevent the bug present in
49 * the previous version of this driver. Coded added by Anthony Barbachan
50 * from bugfix tip originally suggested by Alan Cox.
51 *
52 * November 1999 -- Make kernel-parameter implementation work with 2.3.x
53 * Removed init_module & cleanup_module in favor of
54 * module_init & module_exit.
55 * Torben Mathiasen <tmm@image.dk>
56 */
57
58#define SJCD_VERSION_MAJOR 1
59#define SJCD_VERSION_MINOR 7
60
61#include <linux/module.h>
62#include <linux/errno.h>
63#include <linux/mm.h>
64#include <linux/timer.h>
65#include <linux/fs.h>
66#include <linux/kernel.h>
67#include <linux/cdrom.h>
68#include <linux/ioport.h>
69#include <linux/string.h>
70#include <linux/major.h>
71#include <linux/init.h>
72
73#include <asm/system.h>
74#include <asm/io.h>
75#include <asm/uaccess.h>
76#include <linux/blkdev.h>
77#include "sjcd.h"
78
79static int sjcd_present = 0;
80static struct request_queue *sjcd_queue;
81
82#define MAJOR_NR SANYO_CDROM_MAJOR
83#define QUEUE (sjcd_queue)
84#define CURRENT elv_next_request(sjcd_queue)
85
86#define SJCD_BUF_SIZ 32 /* cdr-h94a has internal 64K buffer */
87
88/*
89 * buffer for block size conversion
90 */
91static char sjcd_buf[2048 * SJCD_BUF_SIZ];
92static volatile int sjcd_buf_bn[SJCD_BUF_SIZ], sjcd_next_bn;
93static volatile int sjcd_buf_in, sjcd_buf_out = -1;
94
95/*
96 * Status.
97 */
98static unsigned short sjcd_status_valid = 0;
99static unsigned short sjcd_door_closed;
100static unsigned short sjcd_door_was_open;
101static unsigned short sjcd_media_is_available;
102static unsigned short sjcd_media_is_changed;
103static unsigned short sjcd_toc_uptodate = 0;
104static unsigned short sjcd_command_failed;
105static volatile unsigned char sjcd_completion_status = 0;
106static volatile unsigned char sjcd_completion_error = 0;
107static unsigned short sjcd_command_is_in_progress = 0;
108static unsigned short sjcd_error_reported = 0;
109static DEFINE_SPINLOCK(sjcd_lock);
110
111static int sjcd_open_count;
112
113static int sjcd_audio_status;
114static struct sjcd_play_msf sjcd_playing;
115
116static int sjcd_base = SJCD_BASE_ADDR;
117
118module_param(sjcd_base, int, 0);
119
120static DECLARE_WAIT_QUEUE_HEAD(sjcd_waitq);
121
122/*
123 * Data transfer.
124 */
125static volatile unsigned short sjcd_transfer_is_active = 0;
126
127enum sjcd_transfer_state {
128 SJCD_S_IDLE = 0,
129 SJCD_S_START = 1,
130 SJCD_S_MODE = 2,
131 SJCD_S_READ = 3,
132 SJCD_S_DATA = 4,
133 SJCD_S_STOP = 5,
134 SJCD_S_STOPPING = 6
135};
136static enum sjcd_transfer_state sjcd_transfer_state = SJCD_S_IDLE;
137static long sjcd_transfer_timeout = 0;
138static int sjcd_read_count = 0;
139static unsigned char sjcd_mode = 0;
140
141#define SJCD_READ_TIMEOUT 5000
142
143#if defined( SJCD_GATHER_STAT )
144/*
145 * Statistic.
146 */
147static struct sjcd_stat statistic;
148#endif
149
150/*
151 * Timer.
152 */
153static DEFINE_TIMER(sjcd_delay_timer, NULL, 0, 0);
154
155#define SJCD_SET_TIMER( func, tmout ) \
156 ( sjcd_delay_timer.expires = jiffies+tmout, \
157 sjcd_delay_timer.function = ( void * )func, \
158 add_timer( &sjcd_delay_timer ) )
159
160#define CLEAR_TIMER del_timer( &sjcd_delay_timer )
161
162/*
163 * Set up device, i.e., use command line data to set
164 * base address.
165 */
166#ifndef MODULE
167static int __init sjcd_setup(char *str)
168{
169 int ints[2];
170 (void) get_options(str, ARRAY_SIZE(ints), ints);
171 if (ints[0] > 0)
172 sjcd_base = ints[1];
173
174 return 1;
175}
176
177__setup("sjcd=", sjcd_setup);
178
179#endif
180
181/*
182 * Special converters.
183 */
184static unsigned char bin2bcd(int bin)
185{
186 int u, v;
187
188 u = bin % 10;
189 v = bin / 10;
190 return (u | (v << 4));
191}
192
193static int bcd2bin(unsigned char bcd)
194{
195 return ((bcd >> 4) * 10 + (bcd & 0x0F));
196}
197
198static long msf2hsg(struct msf *mp)
199{
200 return (bcd2bin(mp->frame) + bcd2bin(mp->sec) * 75
201 + bcd2bin(mp->min) * 4500 - 150);
202}
203
204static void hsg2msf(long hsg, struct msf *msf)
205{
206 hsg += 150;
207 msf->min = hsg / 4500;
208 hsg %= 4500;
209 msf->sec = hsg / 75;
210 msf->frame = hsg % 75;
211 msf->min = bin2bcd(msf->min); /* convert to BCD */
212 msf->sec = bin2bcd(msf->sec);
213 msf->frame = bin2bcd(msf->frame);
214}
215
216/*
217 * Send a command to cdrom. Invalidate status.
218 */
219static void sjcd_send_cmd(unsigned char cmd)
220{
221#if defined( SJCD_TRACE )
222 printk("SJCD: send_cmd( 0x%x )\n", cmd);
223#endif
224 outb(cmd, SJCDPORT(0));
225 sjcd_command_is_in_progress = 1;
226 sjcd_status_valid = 0;
227 sjcd_command_failed = 0;
228}
229
230/*
231 * Send a command with one arg to cdrom. Invalidate status.
232 */
233static void sjcd_send_1_cmd(unsigned char cmd, unsigned char a)
234{
235#if defined( SJCD_TRACE )
236 printk("SJCD: send_1_cmd( 0x%x, 0x%x )\n", cmd, a);
237#endif
238 outb(cmd, SJCDPORT(0));
239 outb(a, SJCDPORT(0));
240 sjcd_command_is_in_progress = 1;
241 sjcd_status_valid = 0;
242 sjcd_command_failed = 0;
243}
244
245/*
246 * Send a command with four args to cdrom. Invalidate status.
247 */
248static void sjcd_send_4_cmd(unsigned char cmd, unsigned char a,
249 unsigned char b, unsigned char c,
250 unsigned char d)
251{
252#if defined( SJCD_TRACE )
253 printk("SJCD: send_4_cmd( 0x%x )\n", cmd);
254#endif
255 outb(cmd, SJCDPORT(0));
256 outb(a, SJCDPORT(0));
257 outb(b, SJCDPORT(0));
258 outb(c, SJCDPORT(0));
259 outb(d, SJCDPORT(0));
260 sjcd_command_is_in_progress = 1;
261 sjcd_status_valid = 0;
262 sjcd_command_failed = 0;
263}
264
265/*
266 * Send a play or read command to cdrom. Invalidate Status.
267 */
268static void sjcd_send_6_cmd(unsigned char cmd, struct sjcd_play_msf *pms)
269{
270#if defined( SJCD_TRACE )
271 printk("SJCD: send_long_cmd( 0x%x )\n", cmd);
272#endif
273 outb(cmd, SJCDPORT(0));
274 outb(pms->start.min, SJCDPORT(0));
275 outb(pms->start.sec, SJCDPORT(0));
276 outb(pms->start.frame, SJCDPORT(0));
277 outb(pms->end.min, SJCDPORT(0));
278 outb(pms->end.sec, SJCDPORT(0));
279 outb(pms->end.frame, SJCDPORT(0));
280 sjcd_command_is_in_progress = 1;
281 sjcd_status_valid = 0;
282 sjcd_command_failed = 0;
283}
284
285/*
286 * Get a value from the data port. Should not block, so we use a little
287 * wait for a while. Returns 0 if OK.
288 */
289static int sjcd_load_response(void *buf, int len)
290{
291 unsigned char *resp = (unsigned char *) buf;
292
293 for (; len; --len) {
294 int i;
295 for (i = 200;
296 i-- && !SJCD_STATUS_AVAILABLE(inb(SJCDPORT(1))););
297 if (i > 0)
298 *resp++ = (unsigned char) inb(SJCDPORT(0));
299 else
300 break;
301 }
302 return (len);
303}
304
305/*
306 * Load and parse command completion status (drive info byte and maybe error).
307 * Sorry, no error classification yet.
308 */
309static void sjcd_load_status(void)
310{
311 sjcd_media_is_changed = 0;
312 sjcd_completion_error = 0;
313 sjcd_completion_status = inb(SJCDPORT(0));
314 if (sjcd_completion_status & SST_DOOR_OPENED) {
315 sjcd_door_closed = sjcd_media_is_available = 0;
316 } else {
317 sjcd_door_closed = 1;
318 if (sjcd_completion_status & SST_MEDIA_CHANGED)
319 sjcd_media_is_available = sjcd_media_is_changed =
320 1;
321 else if (sjcd_completion_status & 0x0F) {
322 /*
323 * OK, we seem to catch an error ...
324 */
325 while (!SJCD_STATUS_AVAILABLE(inb(SJCDPORT(1))));
326 sjcd_completion_error = inb(SJCDPORT(0));
327 if ((sjcd_completion_status & 0x08) &&
328 (sjcd_completion_error & 0x40))
329 sjcd_media_is_available = 0;
330 else
331 sjcd_command_failed = 1;
332 } else
333 sjcd_media_is_available = 1;
334 }
335 /*
336 * Ok, status loaded successfully.
337 */
338 sjcd_status_valid = 1, sjcd_error_reported = 0;
339 sjcd_command_is_in_progress = 0;
340
341 /*
342 * If the disk is changed, the TOC is not valid.
343 */
344 if (sjcd_media_is_changed)
345 sjcd_toc_uptodate = 0;
346#if defined( SJCD_TRACE )
347 printk("SJCD: status %02x.%02x loaded.\n",
348 (int) sjcd_completion_status, (int) sjcd_completion_error);
349#endif
350}
351
352/*
353 * Read status from cdrom. Check to see if the status is available.
354 */
355static int sjcd_check_status(void)
356{
357 /*
358 * Try to load the response from cdrom into buffer.
359 */
360 if (SJCD_STATUS_AVAILABLE(inb(SJCDPORT(1)))) {
361 sjcd_load_status();
362 return (1);
363 } else {
364 /*
365 * No status is available.
366 */
367 return (0);
368 }
369}
370
371/*
372 * This is just timeout counter, and nothing more. Surprised ? :-)
373 */
374static volatile long sjcd_status_timeout;
375
376/*
377 * We need about 10 seconds to wait. The longest command takes about 5 seconds
378 * to probe the disk (usually after tray closed or drive reset). Other values
379 * should be thought of for other commands.
380 */
381#define SJCD_WAIT_FOR_STATUS_TIMEOUT 1000
382
383static void sjcd_status_timer(void)
384{
385 if (sjcd_check_status()) {
386 /*
387 * The command completed and status is loaded, stop waiting.
388 */
389 wake_up(&sjcd_waitq);
390 } else if (--sjcd_status_timeout <= 0) {
391 /*
392 * We are timed out.
393 */
394 wake_up(&sjcd_waitq);
395 } else {
396 /*
397 * We have still some time to wait. Try again.
398 */
399 SJCD_SET_TIMER(sjcd_status_timer, 1);
400 }
401}
402
403/*
404 * Wait for status for 10 sec approx. Returns non-positive when timed out.
405 * Should not be used while reading data CDs.
406 */
407static int sjcd_wait_for_status(void)
408{
409 sjcd_status_timeout = SJCD_WAIT_FOR_STATUS_TIMEOUT;
410 SJCD_SET_TIMER(sjcd_status_timer, 1);
411 sleep_on(&sjcd_waitq);
412#if defined( SJCD_DIAGNOSTIC ) || defined ( SJCD_TRACE )
413 if (sjcd_status_timeout <= 0)
414 printk("SJCD: Error Wait For Status.\n");
415#endif
416 return (sjcd_status_timeout);
417}
418
419static int sjcd_receive_status(void)
420{
421 int i;
422#if defined( SJCD_TRACE )
423 printk("SJCD: receive_status\n");
424#endif
425 /*
426 * Wait a bit for status available.
427 */
428 for (i = 200; i-- && (sjcd_check_status() == 0););
429 if (i < 0) {
430#if defined( SJCD_TRACE )
431 printk("SJCD: long wait for status\n");
432#endif
433 if (sjcd_wait_for_status() <= 0)
434 printk("SJCD: Timeout when read status.\n");
435 else
436 i = 0;
437 }
438 return (i);
439}
440
441/*
442 * Load the status. Issue get status command and wait for status available.
443 */
444static void sjcd_get_status(void)
445{
446#if defined( SJCD_TRACE )
447 printk("SJCD: get_status\n");
448#endif
449 sjcd_send_cmd(SCMD_GET_STATUS);
450 sjcd_receive_status();
451}
452
453/*
454 * Check the drive if the disk is changed. Should be revised.
455 */
456static int sjcd_disk_change(struct gendisk *disk)
457{
458#if 0
459 printk("SJCD: sjcd_disk_change(%s)\n", disk->disk_name);
460#endif
461 if (!sjcd_command_is_in_progress)
462 sjcd_get_status();
463 return (sjcd_status_valid ? sjcd_media_is_changed : 0);
464}
465
466/*
467 * Read the table of contents (TOC) and TOC header if necessary.
468 * We assume that the drive contains no more than 99 toc entries.
469 */
470static struct sjcd_hw_disk_info sjcd_table_of_contents[SJCD_MAX_TRACKS];
471static unsigned char sjcd_first_track_no, sjcd_last_track_no;
472#define sjcd_disk_length sjcd_table_of_contents[0].un.track_msf
473
474static int sjcd_update_toc(void)
475{
476 struct sjcd_hw_disk_info info;
477 int i;
478#if defined( SJCD_TRACE )
479 printk("SJCD: update toc:\n");
480#endif
481 /*
482 * check to see if we need to do anything
483 */
484 if (sjcd_toc_uptodate)
485 return (0);
486
487 /*
488 * Get the TOC start information.
489 */
490 sjcd_send_1_cmd(SCMD_GET_DISK_INFO, SCMD_GET_1_TRACK);
491 sjcd_receive_status();
492
493 if (!sjcd_status_valid) {
494 printk("SJCD: cannot load status.\n");
495 return (-1);
496 }
497
498 if (!sjcd_media_is_available) {
499 printk("SJCD: no disk in drive\n");
500 return (-1);
501 }
502
503 if (!sjcd_command_failed) {
504 if (sjcd_load_response(&info, sizeof(info)) != 0) {
505 printk
506 ("SJCD: cannot load response about TOC start.\n");
507 return (-1);
508 }
509 sjcd_first_track_no = bcd2bin(info.un.track_no);
510 } else {
511 printk("SJCD: get first failed\n");
512 return (-1);
513 }
514#if defined( SJCD_TRACE )
515 printk("SJCD: TOC start 0x%02x ", sjcd_first_track_no);
516#endif
517 /*
518 * Get the TOC finish information.
519 */
520 sjcd_send_1_cmd(SCMD_GET_DISK_INFO, SCMD_GET_L_TRACK);
521 sjcd_receive_status();
522
523 if (!sjcd_status_valid) {
524 printk("SJCD: cannot load status.\n");
525 return (-1);
526 }
527
528 if (!sjcd_media_is_available) {
529 printk("SJCD: no disk in drive\n");
530 return (-1);
531 }
532
533 if (!sjcd_command_failed) {
534 if (sjcd_load_response(&info, sizeof(info)) != 0) {
535 printk
536 ("SJCD: cannot load response about TOC finish.\n");
537 return (-1);
538 }
539 sjcd_last_track_no = bcd2bin(info.un.track_no);
540 } else {
541 printk("SJCD: get last failed\n");
542 return (-1);
543 }
544#if defined( SJCD_TRACE )
545 printk("SJCD: TOC finish 0x%02x ", sjcd_last_track_no);
546#endif
547 for (i = sjcd_first_track_no; i <= sjcd_last_track_no; i++) {
548 /*
549 * Get the first track information.
550 */
551 sjcd_send_1_cmd(SCMD_GET_DISK_INFO, bin2bcd(i));
552 sjcd_receive_status();
553
554 if (!sjcd_status_valid) {
555 printk("SJCD: cannot load status.\n");
556 return (-1);
557 }
558
559 if (!sjcd_media_is_available) {
560 printk("SJCD: no disk in drive\n");
561 return (-1);
562 }
563
564 if (!sjcd_command_failed) {
565 if (sjcd_load_response(&sjcd_table_of_contents[i],
566 sizeof(struct
567 sjcd_hw_disk_info))
568 != 0) {
569 printk
570 ("SJCD: cannot load info for %d track\n",
571 i);
572 return (-1);
573 }
574 } else {
575 printk("SJCD: get info %d failed\n", i);
576 return (-1);
577 }
578 }
579
580 /*
581 * Get the disk length info.
582 */
583 sjcd_send_1_cmd(SCMD_GET_DISK_INFO, SCMD_GET_D_SIZE);
584 sjcd_receive_status();
585
586 if (!sjcd_status_valid) {
587 printk("SJCD: cannot load status.\n");
588 return (-1);
589 }
590
591 if (!sjcd_media_is_available) {
592 printk("SJCD: no disk in drive\n");
593 return (-1);
594 }
595
596 if (!sjcd_command_failed) {
597 if (sjcd_load_response(&info, sizeof(info)) != 0) {
598 printk
599 ("SJCD: cannot load response about disk size.\n");
600 return (-1);
601 }
602 sjcd_disk_length.min = info.un.track_msf.min;
603 sjcd_disk_length.sec = info.un.track_msf.sec;
604 sjcd_disk_length.frame = info.un.track_msf.frame;
605 } else {
606 printk("SJCD: get size failed\n");
607 return (1);
608 }
609#if defined( SJCD_TRACE )
610 printk("SJCD: (%02x:%02x.%02x)\n", sjcd_disk_length.min,
611 sjcd_disk_length.sec, sjcd_disk_length.frame);
612#endif
613 return (0);
614}
615
616/*
617 * Load subchannel information.
618 */
619static int sjcd_get_q_info(struct sjcd_hw_qinfo *qp)
620{
621 int s;
622#if defined( SJCD_TRACE )
623 printk("SJCD: load sub q\n");
624#endif
625 sjcd_send_cmd(SCMD_GET_QINFO);
626 s = sjcd_receive_status();
627 if (s < 0 || sjcd_command_failed || !sjcd_status_valid) {
628 sjcd_send_cmd(0xF2);
629 s = sjcd_receive_status();
630 if (s < 0 || sjcd_command_failed || !sjcd_status_valid)
631 return (-1);
632 sjcd_send_cmd(SCMD_GET_QINFO);
633 s = sjcd_receive_status();
634 if (s < 0 || sjcd_command_failed || !sjcd_status_valid)
635 return (-1);
636 }
637 if (sjcd_media_is_available)
638 if (sjcd_load_response(qp, sizeof(*qp)) == 0)
639 return (0);
640 return (-1);
641}
642
643/*
644 * Start playing from the specified position.
645 */
646static int sjcd_play(struct sjcd_play_msf *mp)
647{
648 struct sjcd_play_msf msf;
649
650 /*
651 * Turn the device to play mode.
652 */
653 sjcd_send_1_cmd(SCMD_SET_MODE, SCMD_MODE_PLAY);
654 if (sjcd_receive_status() < 0)
655 return (-1);
656
657 /*
658 * Seek to the starting point.
659 */
660 msf.start = mp->start;
661 msf.end.min = msf.end.sec = msf.end.frame = 0x00;
662 sjcd_send_6_cmd(SCMD_SEEK, &msf);
663 if (sjcd_receive_status() < 0)
664 return (-1);
665
666 /*
667 * Start playing.
668 */
669 sjcd_send_6_cmd(SCMD_PLAY, mp);
670 return (sjcd_receive_status());
671}
672
673/*
674 * Tray control functions.
675 */
676static int sjcd_tray_close(void)
677{
678#if defined( SJCD_TRACE )
679 printk("SJCD: tray_close\n");
680#endif
681 sjcd_send_cmd(SCMD_CLOSE_TRAY);
682 return (sjcd_receive_status());
683}
684
685static int sjcd_tray_lock(void)
686{
687#if defined( SJCD_TRACE )
688 printk("SJCD: tray_lock\n");
689#endif
690 sjcd_send_cmd(SCMD_LOCK_TRAY);
691 return (sjcd_receive_status());
692}
693
694static int sjcd_tray_unlock(void)
695{
696#if defined( SJCD_TRACE )
697 printk("SJCD: tray_unlock\n");
698#endif
699 sjcd_send_cmd(SCMD_UNLOCK_TRAY);
700 return (sjcd_receive_status());
701}
702
703static int sjcd_tray_open(void)
704{
705#if defined( SJCD_TRACE )
706 printk("SJCD: tray_open\n");
707#endif
708 sjcd_send_cmd(SCMD_EJECT_TRAY);
709 return (sjcd_receive_status());
710}
711
712/*
713 * Do some user commands.
714 */
715static int sjcd_ioctl(struct inode *ip, struct file *fp,
716 unsigned int cmd, unsigned long arg)
717{
718 void __user *argp = (void __user *)arg;
719#if defined( SJCD_TRACE )
720 printk("SJCD:ioctl\n");
721#endif
722
723 sjcd_get_status();
724 if (!sjcd_status_valid)
725 return (-EIO);
726 if (sjcd_update_toc() < 0)
727 return (-EIO);
728
729 switch (cmd) {
730 case CDROMSTART:{
731#if defined( SJCD_TRACE )
732 printk("SJCD: ioctl: start\n");
733#endif
734 return (0);
735 }
736
737 case CDROMSTOP:{
738#if defined( SJCD_TRACE )
739 printk("SJCD: ioctl: stop\n");
740#endif
741 sjcd_send_cmd(SCMD_PAUSE);
742 (void) sjcd_receive_status();
743 sjcd_audio_status = CDROM_AUDIO_NO_STATUS;
744 return (0);
745 }
746
747 case CDROMPAUSE:{
748 struct sjcd_hw_qinfo q_info;
749#if defined( SJCD_TRACE )
750 printk("SJCD: ioctl: pause\n");
751#endif
752 if (sjcd_audio_status == CDROM_AUDIO_PLAY) {
753 sjcd_send_cmd(SCMD_PAUSE);
754 (void) sjcd_receive_status();
755 if (sjcd_get_q_info(&q_info) < 0) {
756 sjcd_audio_status =
757 CDROM_AUDIO_NO_STATUS;
758 } else {
759 sjcd_audio_status =
760 CDROM_AUDIO_PAUSED;
761 sjcd_playing.start = q_info.abs;
762 }
763 return (0);
764 } else
765 return (-EINVAL);
766 }
767
768 case CDROMRESUME:{
769#if defined( SJCD_TRACE )
770 printk("SJCD: ioctl: resume\n");
771#endif
772 if (sjcd_audio_status == CDROM_AUDIO_PAUSED) {
773 /*
774 * continue play starting at saved location
775 */
776 if (sjcd_play(&sjcd_playing) < 0) {
777 sjcd_audio_status =
778 CDROM_AUDIO_ERROR;
779 return (-EIO);
780 } else {
781 sjcd_audio_status =
782 CDROM_AUDIO_PLAY;
783 return (0);
784 }
785 } else
786 return (-EINVAL);
787 }
788
789 case CDROMPLAYTRKIND:{
790 struct cdrom_ti ti;
791 int s = -EFAULT;
792#if defined( SJCD_TRACE )
793 printk("SJCD: ioctl: playtrkind\n");
794#endif
795 if (!copy_from_user(&ti, argp, sizeof(ti))) {
796 s = 0;
797 if (ti.cdti_trk0 < sjcd_first_track_no)
798 return (-EINVAL);
799 if (ti.cdti_trk1 > sjcd_last_track_no)
800 ti.cdti_trk1 = sjcd_last_track_no;
801 if (ti.cdti_trk0 > ti.cdti_trk1)
802 return (-EINVAL);
803
804 sjcd_playing.start =
805 sjcd_table_of_contents[ti.cdti_trk0].
806 un.track_msf;
807 sjcd_playing.end =
808 (ti.cdti_trk1 <
809 sjcd_last_track_no) ?
810 sjcd_table_of_contents[ti.cdti_trk1 +
811 1].un.
812 track_msf : sjcd_table_of_contents[0].
813 un.track_msf;
814
815 if (sjcd_play(&sjcd_playing) < 0) {
816 sjcd_audio_status =
817 CDROM_AUDIO_ERROR;
818 return (-EIO);
819 } else
820 sjcd_audio_status =
821 CDROM_AUDIO_PLAY;
822 }
823 return (s);
824 }
825
826 case CDROMPLAYMSF:{
827 struct cdrom_msf sjcd_msf;
828 int s;
829#if defined( SJCD_TRACE )
830 printk("SJCD: ioctl: playmsf\n");
831#endif
832 if ((s =
833 access_ok(VERIFY_READ, argp, sizeof(sjcd_msf))
834 ? 0 : -EFAULT) == 0) {
835 if (sjcd_audio_status == CDROM_AUDIO_PLAY) {
836 sjcd_send_cmd(SCMD_PAUSE);
837 (void) sjcd_receive_status();
838 sjcd_audio_status =
839 CDROM_AUDIO_NO_STATUS;
840 }
841
842 if (copy_from_user(&sjcd_msf, argp,
843 sizeof(sjcd_msf)))
844 return (-EFAULT);
845
846 sjcd_playing.start.min =
847 bin2bcd(sjcd_msf.cdmsf_min0);
848 sjcd_playing.start.sec =
849 bin2bcd(sjcd_msf.cdmsf_sec0);
850 sjcd_playing.start.frame =
851 bin2bcd(sjcd_msf.cdmsf_frame0);
852 sjcd_playing.end.min =
853 bin2bcd(sjcd_msf.cdmsf_min1);
854 sjcd_playing.end.sec =
855 bin2bcd(sjcd_msf.cdmsf_sec1);
856 sjcd_playing.end.frame =
857 bin2bcd(sjcd_msf.cdmsf_frame1);
858
859 if (sjcd_play(&sjcd_playing) < 0) {
860 sjcd_audio_status =
861 CDROM_AUDIO_ERROR;
862 return (-EIO);
863 } else
864 sjcd_audio_status =
865 CDROM_AUDIO_PLAY;
866 }
867 return (s);
868 }
869
870 case CDROMREADTOCHDR:{
871 struct cdrom_tochdr toc_header;
872#if defined (SJCD_TRACE )
873 printk("SJCD: ioctl: readtocheader\n");
874#endif
875 toc_header.cdth_trk0 = sjcd_first_track_no;
876 toc_header.cdth_trk1 = sjcd_last_track_no;
877 if (copy_to_user(argp, &toc_header,
878 sizeof(toc_header)))
879 return -EFAULT;
880 return 0;
881 }
882
883 case CDROMREADTOCENTRY:{
884 struct cdrom_tocentry toc_entry;
885 int s;
886#if defined( SJCD_TRACE )
887 printk("SJCD: ioctl: readtocentry\n");
888#endif
889 if ((s =
890 access_ok(VERIFY_WRITE, argp, sizeof(toc_entry))
891 ? 0 : -EFAULT) == 0) {
892 struct sjcd_hw_disk_info *tp;
893
894 if (copy_from_user(&toc_entry, argp,
895 sizeof(toc_entry)))
896 return (-EFAULT);
897 if (toc_entry.cdte_track == CDROM_LEADOUT)
898 tp = &sjcd_table_of_contents[0];
899 else if (toc_entry.cdte_track <
900 sjcd_first_track_no)
901 return (-EINVAL);
902 else if (toc_entry.cdte_track >
903 sjcd_last_track_no)
904 return (-EINVAL);
905 else
906 tp = &sjcd_table_of_contents
907 [toc_entry.cdte_track];
908
909 toc_entry.cdte_adr =
910 tp->track_control & 0x0F;
911 toc_entry.cdte_ctrl =
912 tp->track_control >> 4;
913
914 switch (toc_entry.cdte_format) {
915 case CDROM_LBA:
916 toc_entry.cdte_addr.lba =
917 msf2hsg(&(tp->un.track_msf));
918 break;
919 case CDROM_MSF:
920 toc_entry.cdte_addr.msf.minute =
921 bcd2bin(tp->un.track_msf.min);
922 toc_entry.cdte_addr.msf.second =
923 bcd2bin(tp->un.track_msf.sec);
924 toc_entry.cdte_addr.msf.frame =
925 bcd2bin(tp->un.track_msf.
926 frame);
927 break;
928 default:
929 return (-EINVAL);
930 }
931 if (copy_to_user(argp, &toc_entry,
932 sizeof(toc_entry)))
933 s = -EFAULT;
934 }
935 return (s);
936 }
937
938 case CDROMSUBCHNL:{
939 struct cdrom_subchnl subchnl;
940 int s;
941#if defined( SJCD_TRACE )
942 printk("SJCD: ioctl: subchnl\n");
943#endif
944 if ((s =
945 access_ok(VERIFY_WRITE, argp, sizeof(subchnl))
946 ? 0 : -EFAULT) == 0) {
947 struct sjcd_hw_qinfo q_info;
948
949 if (copy_from_user(&subchnl, argp,
950 sizeof(subchnl)))
951 return (-EFAULT);
952
953 if (sjcd_get_q_info(&q_info) < 0)
954 return (-EIO);
955
956 subchnl.cdsc_audiostatus =
957 sjcd_audio_status;
958 subchnl.cdsc_adr =
959 q_info.track_control & 0x0F;
960 subchnl.cdsc_ctrl =
961 q_info.track_control >> 4;
962 subchnl.cdsc_trk =
963 bcd2bin(q_info.track_no);
964 subchnl.cdsc_ind = bcd2bin(q_info.x);
965
966 switch (subchnl.cdsc_format) {
967 case CDROM_LBA:
968 subchnl.cdsc_absaddr.lba =
969 msf2hsg(&(q_info.abs));
970 subchnl.cdsc_reladdr.lba =
971 msf2hsg(&(q_info.rel));
972 break;
973 case CDROM_MSF:
974 subchnl.cdsc_absaddr.msf.minute =
975 bcd2bin(q_info.abs.min);
976 subchnl.cdsc_absaddr.msf.second =
977 bcd2bin(q_info.abs.sec);
978 subchnl.cdsc_absaddr.msf.frame =
979 bcd2bin(q_info.abs.frame);
980 subchnl.cdsc_reladdr.msf.minute =
981 bcd2bin(q_info.rel.min);
982 subchnl.cdsc_reladdr.msf.second =
983 bcd2bin(q_info.rel.sec);
984 subchnl.cdsc_reladdr.msf.frame =
985 bcd2bin(q_info.rel.frame);
986 break;
987 default:
988 return (-EINVAL);
989 }
990 if (copy_to_user(argp, &subchnl,
991 sizeof(subchnl)))
992 s = -EFAULT;
993 }
994 return (s);
995 }
996
997 case CDROMVOLCTRL:{
998 struct cdrom_volctrl vol_ctrl;
999 int s;
1000#if defined( SJCD_TRACE )
1001 printk("SJCD: ioctl: volctrl\n");
1002#endif
1003 if ((s =
1004 access_ok(VERIFY_READ, argp, sizeof(vol_ctrl))
1005 ? 0 : -EFAULT) == 0) {
1006 unsigned char dummy[4];
1007
1008 if (copy_from_user(&vol_ctrl, argp,
1009 sizeof(vol_ctrl)))
1010 return (-EFAULT);
1011 sjcd_send_4_cmd(SCMD_SET_VOLUME,
1012 vol_ctrl.channel0, 0xFF,
1013 vol_ctrl.channel1, 0xFF);
1014 if (sjcd_receive_status() < 0)
1015 return (-EIO);
1016 (void) sjcd_load_response(dummy, 4);
1017 }
1018 return (s);
1019 }
1020
1021 case CDROMEJECT:{
1022#if defined( SJCD_TRACE )
1023 printk("SJCD: ioctl: eject\n");
1024#endif
1025 if (!sjcd_command_is_in_progress) {
1026 sjcd_tray_unlock();
1027 sjcd_send_cmd(SCMD_EJECT_TRAY);
1028 (void) sjcd_receive_status();
1029 }
1030 return (0);
1031 }
1032
1033#if defined( SJCD_GATHER_STAT )
1034 case 0xABCD:{
1035#if defined( SJCD_TRACE )
1036 printk("SJCD: ioctl: statistic\n");
1037#endif
1038 if (copy_to_user(argp, &statistic, sizeof(statistic)))
1039 return -EFAULT;
1040 return 0;
1041 }
1042#endif
1043
1044 default:
1045 return (-EINVAL);
1046 }
1047}
1048
1049/*
1050 * Invalidate internal buffers of the driver.
1051 */
1052static void sjcd_invalidate_buffers(void)
1053{
1054 int i;
1055 for (i = 0; i < SJCD_BUF_SIZ; sjcd_buf_bn[i++] = -1);
1056 sjcd_buf_out = -1;
1057}
1058
1059/*
1060 * Take care of the different block sizes between cdrom and Linux.
1061 * When Linux gets variable block sizes this will probably go away.
1062 */
1063
1064static int current_valid(void)
1065{
1066 return CURRENT &&
1067 rq_data_dir(CURRENT) == READ &&
1068 CURRENT->sector != -1;
1069}
1070
1071static void sjcd_transfer(void)
1072{
1073#if defined( SJCD_TRACE )
1074 printk("SJCD: transfer:\n");
1075#endif
1076 if (current_valid()) {
1077 while (CURRENT->nr_sectors) {
1078 int i, bn = CURRENT->sector / 4;
1079 for (i = 0;
1080 i < SJCD_BUF_SIZ && sjcd_buf_bn[i] != bn;
1081 i++);
1082 if (i < SJCD_BUF_SIZ) {
1083 int offs =
1084 (i * 4 + (CURRENT->sector & 3)) * 512;
1085 int nr_sectors = 4 - (CURRENT->sector & 3);
1086 if (sjcd_buf_out != i) {
1087 sjcd_buf_out = i;
1088 if (sjcd_buf_bn[i] != bn) {
1089 sjcd_buf_out = -1;
1090 continue;
1091 }
1092 }
1093 if (nr_sectors > CURRENT->nr_sectors)
1094 nr_sectors = CURRENT->nr_sectors;
1095#if defined( SJCD_TRACE )
1096 printk("SJCD: copy out\n");
1097#endif
1098 memcpy(CURRENT->buffer, sjcd_buf + offs,
1099 nr_sectors * 512);
1100 CURRENT->nr_sectors -= nr_sectors;
1101 CURRENT->sector += nr_sectors;
1102 CURRENT->buffer += nr_sectors * 512;
1103 } else {
1104 sjcd_buf_out = -1;
1105 break;
1106 }
1107 }
1108 }
1109#if defined( SJCD_TRACE )
1110 printk("SJCD: transfer: done\n");
1111#endif
1112}
1113
1114static void sjcd_poll(void)
1115{
1116#if defined( SJCD_GATHER_STAT )
1117 /*
1118 * Update total number of ticks.
1119 */
1120 statistic.ticks++;
1121 statistic.tticks[sjcd_transfer_state]++;
1122#endif
1123
1124 ReSwitch:switch (sjcd_transfer_state) {
1125
1126 case SJCD_S_IDLE:{
1127#if defined( SJCD_GATHER_STAT )
1128 statistic.idle_ticks++;
1129#endif
1130#if defined( SJCD_TRACE )
1131 printk("SJCD_S_IDLE\n");
1132#endif
1133 return;
1134 }
1135
1136 case SJCD_S_START:{
1137#if defined( SJCD_GATHER_STAT )
1138 statistic.start_ticks++;
1139#endif
1140 sjcd_send_cmd(SCMD_GET_STATUS);
1141 sjcd_transfer_state =
1142 sjcd_mode ==
1143 SCMD_MODE_COOKED ? SJCD_S_READ : SJCD_S_MODE;
1144 sjcd_transfer_timeout = 500;
1145#if defined( SJCD_TRACE )
1146 printk("SJCD_S_START: goto SJCD_S_%s mode\n",
1147 sjcd_transfer_state ==
1148 SJCD_S_READ ? "READ" : "MODE");
1149#endif
1150 break;
1151 }
1152
1153 case SJCD_S_MODE:{
1154 if (sjcd_check_status()) {
1155 /*
1156 * Previous command is completed.
1157 */
1158 if (!sjcd_status_valid
1159 || sjcd_command_failed) {
1160#if defined( SJCD_TRACE )
1161 printk
1162 ("SJCD_S_MODE: pre-cmd failed: goto to SJCD_S_STOP mode\n");
1163#endif
1164 sjcd_transfer_state = SJCD_S_STOP;
1165 goto ReSwitch;
1166 }
1167
1168 sjcd_mode = 0; /* unknown mode; should not be valid when failed */
1169 sjcd_send_1_cmd(SCMD_SET_MODE,
1170 SCMD_MODE_COOKED);
1171 sjcd_transfer_state = SJCD_S_READ;
1172 sjcd_transfer_timeout = 1000;
1173#if defined( SJCD_TRACE )
1174 printk
1175 ("SJCD_S_MODE: goto SJCD_S_READ mode\n");
1176#endif
1177 }
1178#if defined( SJCD_GATHER_STAT )
1179 else
1180 statistic.mode_ticks++;
1181#endif
1182 break;
1183 }
1184
1185 case SJCD_S_READ:{
1186 if (sjcd_status_valid ? 1 : sjcd_check_status()) {
1187 /*
1188 * Previous command is completed.
1189 */
1190 if (!sjcd_status_valid
1191 || sjcd_command_failed) {
1192#if defined( SJCD_TRACE )
1193 printk
1194 ("SJCD_S_READ: pre-cmd failed: goto to SJCD_S_STOP mode\n");
1195#endif
1196 sjcd_transfer_state = SJCD_S_STOP;
1197 goto ReSwitch;
1198 }
1199 if (!sjcd_media_is_available) {
1200#if defined( SJCD_TRACE )
1201 printk
1202 ("SJCD_S_READ: no disk: goto to SJCD_S_STOP mode\n");
1203#endif
1204 sjcd_transfer_state = SJCD_S_STOP;
1205 goto ReSwitch;
1206 }
1207 if (sjcd_mode != SCMD_MODE_COOKED) {
1208 /*
1209 * We seem to come from set mode. So discard one byte of result.
1210 */
1211 if (sjcd_load_response
1212 (&sjcd_mode, 1) != 0) {
1213#if defined( SJCD_TRACE )
1214 printk
1215 ("SJCD_S_READ: load failed: goto to SJCD_S_STOP mode\n");
1216#endif
1217 sjcd_transfer_state =
1218 SJCD_S_STOP;
1219 goto ReSwitch;
1220 }
1221 if (sjcd_mode != SCMD_MODE_COOKED) {
1222#if defined( SJCD_TRACE )
1223 printk
1224 ("SJCD_S_READ: mode failed: goto to SJCD_S_STOP mode\n");
1225#endif
1226 sjcd_transfer_state =
1227 SJCD_S_STOP;
1228 goto ReSwitch;
1229 }
1230 }
1231
1232 if (current_valid()) {
1233 struct sjcd_play_msf msf;
1234
1235 sjcd_next_bn = CURRENT->sector / 4;
1236 hsg2msf(sjcd_next_bn, &msf.start);
1237 msf.end.min = 0;
1238 msf.end.sec = 0;
1239 msf.end.frame = sjcd_read_count =
1240 SJCD_BUF_SIZ;
1241#if defined( SJCD_TRACE )
1242 printk
1243 ("SJCD: ---reading msf-address %x:%x:%x %x:%x:%x\n",
1244 msf.start.min, msf.start.sec,
1245 msf.start.frame, msf.end.min,
1246 msf.end.sec, msf.end.frame);
1247 printk
1248 ("sjcd_next_bn:%x buf_in:%x buf_out:%x buf_bn:%x\n",
1249 sjcd_next_bn, sjcd_buf_in,
1250 sjcd_buf_out,
1251 sjcd_buf_bn[sjcd_buf_in]);
1252#endif
1253 sjcd_send_6_cmd(SCMD_DATA_READ,
1254 &msf);
1255 sjcd_transfer_state = SJCD_S_DATA;
1256 sjcd_transfer_timeout = 500;
1257#if defined( SJCD_TRACE )
1258 printk
1259 ("SJCD_S_READ: go to SJCD_S_DATA mode\n");
1260#endif
1261 } else {
1262#if defined( SJCD_TRACE )
1263 printk
1264 ("SJCD_S_READ: nothing to read: go to SJCD_S_STOP mode\n");
1265#endif
1266 sjcd_transfer_state = SJCD_S_STOP;
1267 goto ReSwitch;
1268 }
1269 }
1270#if defined( SJCD_GATHER_STAT )
1271 else
1272 statistic.read_ticks++;
1273#endif
1274 break;
1275 }
1276
1277 case SJCD_S_DATA:{
1278 unsigned char stat;
1279
1280 sjcd_s_data:stat =
1281 inb(SJCDPORT
1282 (1));
1283#if defined( SJCD_TRACE )
1284 printk("SJCD_S_DATA: status = 0x%02x\n", stat);
1285#endif
1286 if (SJCD_STATUS_AVAILABLE(stat)) {
1287 /*
1288 * No data is waiting for us in the drive buffer. Status of operation
1289 * completion is available. Read and parse it.
1290 */
1291 sjcd_load_status();
1292
1293 if (!sjcd_status_valid
1294 || sjcd_command_failed) {
1295#if defined( SJCD_TRACE )
1296 printk
1297 ("SJCD: read block %d failed, maybe audio disk? Giving up\n",
1298 sjcd_next_bn);
1299#endif
1300 if (current_valid())
1301 end_request(CURRENT, 0);
1302#if defined( SJCD_TRACE )
1303 printk
1304 ("SJCD_S_DATA: pre-cmd failed: go to SJCD_S_STOP mode\n");
1305#endif
1306 sjcd_transfer_state = SJCD_S_STOP;
1307 goto ReSwitch;
1308 }
1309
1310 if (!sjcd_media_is_available) {
1311 printk
1312 ("SJCD_S_DATA: no disk: go to SJCD_S_STOP mode\n");
1313 sjcd_transfer_state = SJCD_S_STOP;
1314 goto ReSwitch;
1315 }
1316
1317 sjcd_transfer_state = SJCD_S_READ;
1318 goto ReSwitch;
1319 } else if (SJCD_DATA_AVAILABLE(stat)) {
1320 /*
1321 * One frame is read into device buffer. We must copy it to our memory.
1322 * Otherwise cdrom hangs up. Check to see if we have something to copy
1323 * to.
1324 */
1325 if (!current_valid()
1326 && sjcd_buf_in == sjcd_buf_out) {
1327#if defined( SJCD_TRACE )
1328 printk
1329 ("SJCD_S_DATA: nothing to read: go to SJCD_S_STOP mode\n");
1330 printk
1331 (" ... all the date would be discarded\n");
1332#endif
1333 sjcd_transfer_state = SJCD_S_STOP;
1334 goto ReSwitch;
1335 }
1336
1337 /*
1338 * Everything seems to be OK. Just read the frame and recalculate
1339 * indices.
1340 */
1341 sjcd_buf_bn[sjcd_buf_in] = -1; /* ??? */
1342 insb(SJCDPORT(2),
1343 sjcd_buf + 2048 * sjcd_buf_in, 2048);
1344#if defined( SJCD_TRACE )
1345 printk
1346 ("SJCD_S_DATA: next_bn=%d, buf_in=%d, buf_out=%d, buf_bn=%d\n",
1347 sjcd_next_bn, sjcd_buf_in,
1348 sjcd_buf_out,
1349 sjcd_buf_bn[sjcd_buf_in]);
1350#endif
1351 sjcd_buf_bn[sjcd_buf_in] = sjcd_next_bn++;
1352 if (sjcd_buf_out == -1)
1353 sjcd_buf_out = sjcd_buf_in;
1354 if (++sjcd_buf_in == SJCD_BUF_SIZ)
1355 sjcd_buf_in = 0;
1356
1357 /*
1358 * Only one frame is ready at time. So we should turn over to wait for
1359 * another frame. If we need that, of course.
1360 */
1361 if (--sjcd_read_count == 0) {
1362 /*
1363 * OK, request seems to be precessed. Continue transferring...
1364 */
1365 if (!sjcd_transfer_is_active) {
1366 while (current_valid()) {
1367 /*
1368 * Continue transferring.
1369 */
1370 sjcd_transfer();
1371 if (CURRENT->
1372 nr_sectors ==
1373 0)
1374 end_request
1375 (CURRENT, 1);
1376 else
1377 break;
1378 }
1379 }
1380 if (current_valid() &&
1381 (CURRENT->sector / 4 <
1382 sjcd_next_bn
1383 || CURRENT->sector / 4 >
1384 sjcd_next_bn +
1385 SJCD_BUF_SIZ)) {
1386#if defined( SJCD_TRACE )
1387 printk
1388 ("SJCD_S_DATA: can't read: go to SJCD_S_STOP mode\n");
1389#endif
1390 sjcd_transfer_state =
1391 SJCD_S_STOP;
1392 goto ReSwitch;
1393 }
1394 }
1395 /*
1396 * Now we should turn around rather than wait for while.
1397 */
1398 goto sjcd_s_data;
1399 }
1400#if defined( SJCD_GATHER_STAT )
1401 else
1402 statistic.data_ticks++;
1403#endif
1404 break;
1405 }
1406
1407 case SJCD_S_STOP:{
1408 sjcd_read_count = 0;
1409 sjcd_send_cmd(SCMD_STOP);
1410 sjcd_transfer_state = SJCD_S_STOPPING;
1411 sjcd_transfer_timeout = 500;
1412#if defined( SJCD_GATHER_STAT )
1413 statistic.stop_ticks++;
1414#endif
1415 break;
1416 }
1417
1418 case SJCD_S_STOPPING:{
1419 unsigned char stat;
1420
1421 stat = inb(SJCDPORT(1));
1422#if defined( SJCD_TRACE )
1423 printk("SJCD_S_STOP: status = 0x%02x\n", stat);
1424#endif
1425 if (SJCD_DATA_AVAILABLE(stat)) {
1426 int i;
1427#if defined( SJCD_TRACE )
1428 printk("SJCD_S_STOP: discard data\n");
1429#endif
1430 /*
1431 * Discard all the data from the pipe. Foolish method.
1432 */
1433 for (i = 2048; i--;
1434 (void) inb(SJCDPORT(2)));
1435 sjcd_transfer_timeout = 500;
1436 } else if (SJCD_STATUS_AVAILABLE(stat)) {
1437 sjcd_load_status();
1438 if (sjcd_status_valid
1439 && sjcd_media_is_changed) {
1440 sjcd_toc_uptodate = 0;
1441 sjcd_invalidate_buffers();
1442 }
1443 if (current_valid()) {
1444 if (sjcd_status_valid)
1445 sjcd_transfer_state =
1446 SJCD_S_READ;
1447 else
1448 sjcd_transfer_state =
1449 SJCD_S_START;
1450 } else
1451 sjcd_transfer_state = SJCD_S_IDLE;
1452 goto ReSwitch;
1453 }
1454#if defined( SJCD_GATHER_STAT )
1455 else
1456 statistic.stopping_ticks++;
1457#endif
1458 break;
1459 }
1460
1461 default:
1462 printk("SJCD: poll: invalid state %d\n",
1463 sjcd_transfer_state);
1464 return;
1465 }
1466
1467 if (--sjcd_transfer_timeout == 0) {
1468 printk("SJCD: timeout in state %d\n", sjcd_transfer_state);
1469 while (current_valid())
1470 end_request(CURRENT, 0);
1471 sjcd_send_cmd(SCMD_STOP);
1472 sjcd_transfer_state = SJCD_S_IDLE;
1473 goto ReSwitch;
1474 }
1475
1476 /*
1477 * Get back in some time. 1 should be replaced with count variable to
1478 * avoid unnecessary testings.
1479 */
1480 SJCD_SET_TIMER(sjcd_poll, 1);
1481}
1482
1483static void do_sjcd_request(request_queue_t * q)
1484{
1485#if defined( SJCD_TRACE )
1486 printk("SJCD: do_sjcd_request(%ld+%ld)\n",
1487 CURRENT->sector, CURRENT->nr_sectors);
1488#endif
1489 sjcd_transfer_is_active = 1;
1490 while (current_valid()) {
1491 sjcd_transfer();
1492 if (CURRENT->nr_sectors == 0)
1493 end_request(CURRENT, 1);
1494 else {
1495 sjcd_buf_out = -1; /* Want to read a block not in buffer */
1496 if (sjcd_transfer_state == SJCD_S_IDLE) {
1497 if (!sjcd_toc_uptodate) {
1498 if (sjcd_update_toc() < 0) {
1499 printk
1500 ("SJCD: transfer: discard\n");
1501 while (current_valid())
1502 end_request(CURRENT, 0);
1503 break;
1504 }
1505 }
1506 sjcd_transfer_state = SJCD_S_START;
1507 SJCD_SET_TIMER(sjcd_poll, HZ / 100);
1508 }
1509 break;
1510 }
1511 }
1512 sjcd_transfer_is_active = 0;
1513#if defined( SJCD_TRACE )
1514 printk
1515 ("sjcd_next_bn:%x sjcd_buf_in:%x sjcd_buf_out:%x sjcd_buf_bn:%x\n",
1516 sjcd_next_bn, sjcd_buf_in, sjcd_buf_out,
1517 sjcd_buf_bn[sjcd_buf_in]);
1518 printk("do_sjcd_request ends\n");
1519#endif
1520}
1521
1522/*
1523 * Open the device special file. Check disk is in.
1524 */
1525static int sjcd_open(struct inode *ip, struct file *fp)
1526{
1527 /*
1528 * Check the presence of device.
1529 */
1530 if (!sjcd_present)
1531 return (-ENXIO);
1532
1533 /*
1534 * Only read operations are allowed. Really? (:-)
1535 */
1536 if (fp->f_mode & 2)
1537 return (-EROFS);
1538
1539 if (sjcd_open_count == 0) {
1540 int s, sjcd_open_tries;
1541/* We don't know that, do we? */
1542/*
1543 sjcd_audio_status = CDROM_AUDIO_NO_STATUS;
1544*/
1545 sjcd_mode = 0;
1546 sjcd_door_was_open = 0;
1547 sjcd_transfer_state = SJCD_S_IDLE;
1548 sjcd_invalidate_buffers();
1549 sjcd_status_valid = 0;
1550
1551 /*
1552 * Strict status checking.
1553 */
1554 for (sjcd_open_tries = 4; --sjcd_open_tries;) {
1555 if (!sjcd_status_valid)
1556 sjcd_get_status();
1557 if (!sjcd_status_valid) {
1558#if defined( SJCD_DIAGNOSTIC )
1559 printk
1560 ("SJCD: open: timed out when check status.\n");
1561#endif
1562 goto err_out;
1563 } else if (!sjcd_media_is_available) {
1564#if defined( SJCD_DIAGNOSTIC )
1565 printk("SJCD: open: no disk in drive\n");
1566#endif
1567 if (!sjcd_door_closed) {
1568 sjcd_door_was_open = 1;
1569#if defined( SJCD_TRACE )
1570 printk
1571 ("SJCD: open: close the tray\n");
1572#endif
1573 s = sjcd_tray_close();
1574 if (s < 0 || !sjcd_status_valid
1575 || sjcd_command_failed) {
1576#if defined( SJCD_DIAGNOSTIC )
1577 printk
1578 ("SJCD: open: tray close attempt failed\n");
1579#endif
1580 goto err_out;
1581 }
1582 continue;
1583 } else
1584 goto err_out;
1585 }
1586 break;
1587 }
1588 s = sjcd_tray_lock();
1589 if (s < 0 || !sjcd_status_valid || sjcd_command_failed) {
1590#if defined( SJCD_DIAGNOSTIC )
1591 printk("SJCD: open: tray lock attempt failed\n");
1592#endif
1593 goto err_out;
1594 }
1595#if defined( SJCD_TRACE )
1596 printk("SJCD: open: done\n");
1597#endif
1598 }
1599
1600 ++sjcd_open_count;
1601 return (0);
1602
1603 err_out:
1604 return (-EIO);
1605}
1606
1607/*
1608 * On close, we flush all sjcd blocks from the buffer cache.
1609 */
1610static int sjcd_release(struct inode *inode, struct file *file)
1611{
1612 int s;
1613
1614#if defined( SJCD_TRACE )
1615 printk("SJCD: release\n");
1616#endif
1617 if (--sjcd_open_count == 0) {
1618 sjcd_invalidate_buffers();
1619 s = sjcd_tray_unlock();
1620 if (s < 0 || !sjcd_status_valid || sjcd_command_failed) {
1621#if defined( SJCD_DIAGNOSTIC )
1622 printk
1623 ("SJCD: release: tray unlock attempt failed.\n");
1624#endif
1625 }
1626 if (sjcd_door_was_open) {
1627 s = sjcd_tray_open();
1628 if (s < 0 || !sjcd_status_valid
1629 || sjcd_command_failed) {
1630#if defined( SJCD_DIAGNOSTIC )
1631 printk
1632 ("SJCD: release: tray unload attempt failed.\n");
1633#endif
1634 }
1635 }
1636 }
1637 return 0;
1638}
1639
1640/*
1641 * A list of file operations allowed for this cdrom.
1642 */
1643static struct block_device_operations sjcd_fops = {
1644 .owner = THIS_MODULE,
1645 .open = sjcd_open,
1646 .release = sjcd_release,
1647 .ioctl = sjcd_ioctl,
1648 .media_changed = sjcd_disk_change,
1649};
1650
1651/*
1652 * Following stuff is intended for initialization of the cdrom. It
1653 * first looks for presence of device. If the device is present, it
1654 * will be reset. Then read the version of the drive and load status.
1655 * The version is two BCD-coded bytes.
1656 */
1657static struct {
1658 unsigned char major, minor;
1659} sjcd_version;
1660
1661static struct gendisk *sjcd_disk;
1662
1663/*
1664 * Test for presence of drive and initialize it. Called at boot time.
1665 * Probe cdrom, find out version and status.
1666 */
1667static int __init sjcd_init(void)
1668{
1669 int i;
1670
1671 printk(KERN_INFO
1672 "SJCD: Sanyo CDR-H94A cdrom driver version %d.%d.\n",
1673 SJCD_VERSION_MAJOR, SJCD_VERSION_MINOR);
1674
1675#if defined( SJCD_TRACE )
1676 printk("SJCD: sjcd=0x%x: ", sjcd_base);
1677#endif
1678
1679 if (register_blkdev(MAJOR_NR, "sjcd"))
1680 return -EIO;
1681
1682 sjcd_queue = blk_init_queue(do_sjcd_request, &sjcd_lock);
1683 if (!sjcd_queue)
1684 goto out0;
1685
1686 blk_queue_hardsect_size(sjcd_queue, 2048);
1687
1688 sjcd_disk = alloc_disk(1);
1689 if (!sjcd_disk) {
1690 printk(KERN_ERR "SJCD: can't allocate disk");
1691 goto out1;
1692 }
1693 sjcd_disk->major = MAJOR_NR,
1694 sjcd_disk->first_minor = 0,
1695 sjcd_disk->fops = &sjcd_fops,
1696 sprintf(sjcd_disk->disk_name, "sjcd");
1697
1698 if (!request_region(sjcd_base, 4,"sjcd")) {
1699 printk
1700 ("SJCD: Init failed, I/O port (%X) is already in use\n",
1701 sjcd_base);
1702 goto out2;
1703 }
1704
1705 /*
1706 * Check for card. Since we are booting now, we can't use standard
1707 * wait algorithm.
1708 */
1709 printk(KERN_INFO "SJCD: Resetting: ");
1710 sjcd_send_cmd(SCMD_RESET);
1711 for (i = 1000; i > 0 && !sjcd_status_valid; --i) {
1712 unsigned long timer;
1713
1714 /*
1715 * Wait 10ms approx.
1716 */
1717 for (timer = jiffies; time_before_eq(jiffies, timer););
1718 if ((i % 100) == 0)
1719 printk(".");
1720 (void) sjcd_check_status();
1721 }
1722 if (i == 0 || sjcd_command_failed) {
1723 printk(" reset failed, no drive found.\n");
1724 goto out3;
1725 } else
1726 printk("\n");
1727
1728 /*
1729 * Get and print out cdrom version.
1730 */
1731 printk(KERN_INFO "SJCD: Getting version: ");
1732 sjcd_send_cmd(SCMD_GET_VERSION);
1733 for (i = 1000; i > 0 && !sjcd_status_valid; --i) {
1734 unsigned long timer;
1735
1736 /*
1737 * Wait 10ms approx.
1738 */
1739 for (timer = jiffies; time_before_eq(jiffies, timer););
1740 if ((i % 100) == 0)
1741 printk(".");
1742 (void) sjcd_check_status();
1743 }
1744 if (i == 0 || sjcd_command_failed) {
1745 printk(" get version failed, no drive found.\n");
1746 goto out3;
1747 }
1748
1749 if (sjcd_load_response(&sjcd_version, sizeof(sjcd_version)) == 0) {
1750 printk(" %1x.%02x\n", (int) sjcd_version.major,
1751 (int) sjcd_version.minor);
1752 } else {
1753 printk(" read version failed, no drive found.\n");
1754 goto out3;
1755 }
1756
1757 /*
1758 * Check and print out the tray state. (if it is needed?).
1759 */
1760 if (!sjcd_status_valid) {
1761 printk(KERN_INFO "SJCD: Getting status: ");
1762 sjcd_send_cmd(SCMD_GET_STATUS);
1763 for (i = 1000; i > 0 && !sjcd_status_valid; --i) {
1764 unsigned long timer;
1765
1766 /*
1767 * Wait 10ms approx.
1768 */
1769 for (timer = jiffies;
1770 time_before_eq(jiffies, timer););
1771 if ((i % 100) == 0)
1772 printk(".");
1773 (void) sjcd_check_status();
1774 }
1775 if (i == 0 || sjcd_command_failed) {
1776 printk(" get status failed, no drive found.\n");
1777 goto out3;
1778 } else
1779 printk("\n");
1780 }
1781
1782 printk(KERN_INFO "SJCD: Status: port=0x%x.\n", sjcd_base);
1783 sjcd_disk->queue = sjcd_queue;
1784 add_disk(sjcd_disk);
1785
1786 sjcd_present++;
1787 return (0);
1788out3:
1789 release_region(sjcd_base, 4);
1790out2:
1791 put_disk(sjcd_disk);
1792out1:
1793 blk_cleanup_queue(sjcd_queue);
1794out0:
1795 if ((unregister_blkdev(MAJOR_NR, "sjcd") == -EINVAL))
1796 printk("SJCD: cannot unregister device.\n");
1797 return (-EIO);
1798}
1799
1800static void __exit sjcd_exit(void)
1801{
1802 del_gendisk(sjcd_disk);
1803 put_disk(sjcd_disk);
1804 release_region(sjcd_base, 4);
1805 blk_cleanup_queue(sjcd_queue);
1806 if ((unregister_blkdev(MAJOR_NR, "sjcd") == -EINVAL))
1807 printk("SJCD: cannot unregister device.\n");
1808 printk(KERN_INFO "SJCD: module: removed.\n");
1809}
1810
1811module_init(sjcd_init);
1812module_exit(sjcd_exit);
1813
1814MODULE_LICENSE("GPL");
1815MODULE_ALIAS_BLOCKDEV_MAJOR(SANYO_CDROM_MAJOR);
diff --git a/drivers/cdrom/sjcd.h b/drivers/cdrom/sjcd.h
deleted file mode 100644
index 0aa5e714659d..000000000000
--- a/drivers/cdrom/sjcd.h
+++ /dev/null
@@ -1,181 +0,0 @@
1/*
2 * Definitions for a Sanyo CD-ROM interface.
3 *
4 * Copyright (C) 1995 Vadim V. Model
5 * model@cecmow.enet.dec.com
6 * vadim@rbrf.msk.su
7 * vadim@ipsun.ras.ru
8 * Eric van der Maarel
9 * H.T.M.v.d.Maarel@marin.nl
10 *
11 * This information is based on mcd.c from M. Harriss and sjcd102.lst from
12 * E. Moenkeberg.
13 *
14 * This program is free software; you can redistribute it and/or modify
15 * it under the terms of the GNU General Public License as published by
16 * the Free Software Foundation; either version 2 of the License, or
17 * (at your option) any later version.
18 *
19 * This program is distributed in the hope that it will be useful,
20 * but WITHOUT ANY WARRANTY; without even the implied warranty of
21 * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
22 * GNU General Public License for more details.
23 *
24 * You should have received a copy of the GNU General Public License
25 * along with this program; if not, write to the Free Software
26 * Foundation, Inc., 675 Mass Ave, Cambridge, MA 02139, USA.
27 */
28
29#ifndef __SJCD_H__
30#define __SJCD_H__
31
32/*
33 * Change this to set the I/O port address as default. More flexibility
34 * come with setup implementation.
35 */
36#define SJCD_BASE_ADDR 0x340
37
38/*
39 * Change this to set the irq as default. Really SANYO do not use interrupts
40 * at all.
41 */
42#define SJCD_INTR_NR 0
43
44/*
45 * Change this to set the dma as default value. really SANYO does not use
46 * direct memory access at all.
47 */
48#define SJCD_DMA_NR 0
49
50/*
51 * Macros which allow us to find out the status of the drive.
52 */
53#define SJCD_STATUS_AVAILABLE( x ) (((x)&0x02)==0)
54#define SJCD_DATA_AVAILABLE( x ) (((x)&0x01)==0)
55
56/*
57 * Port access macro. Three ports are available: S-data port (command port),
58 * status port (read only) and D-data port (read only).
59 */
60#define SJCDPORT( x ) ( sjcd_base + ( x ) )
61#define SJCD_STATUS_PORT SJCDPORT( 1 )
62#define SJCD_S_DATA_PORT SJCDPORT( 0 )
63#define SJCD_COMMAND_PORT SJCDPORT( 0 )
64#define SJCD_D_DATA_PORT SJCDPORT( 2 )
65
66/*
67 * Drive info bits. Drive info available as first (mandatory) byte of
68 * command completion status.
69 */
70#define SST_NOT_READY 0x10 /* no disk in the drive (???) */
71#define SST_MEDIA_CHANGED 0x20 /* disk is changed */
72#define SST_DOOR_OPENED 0x40 /* door is open */
73
74/* commands */
75
76#define SCMD_EJECT_TRAY 0xD0 /* eject tray if not locked */
77#define SCMD_LOCK_TRAY 0xD2 /* lock tray when in */
78#define SCMD_UNLOCK_TRAY 0xD4 /* unlock tray when in */
79#define SCMD_CLOSE_TRAY 0xD6 /* load tray in */
80
81#define SCMD_RESET 0xFA /* soft reset */
82#define SCMD_GET_STATUS 0x80
83#define SCMD_GET_VERSION 0xCC
84
85#define SCMD_DATA_READ 0xA0 /* are the same, depend on mode&args */
86#define SCMD_SEEK 0xA0
87#define SCMD_PLAY 0xA0
88
89#define SCMD_GET_QINFO 0xA8
90
91#define SCMD_SET_MODE 0xC4
92#define SCMD_MODE_PLAY 0xE0
93#define SCMD_MODE_COOKED (0xF8 & ~0x20)
94#define SCMD_MODE_RAW 0xF9
95#define SCMD_MODE_x20_BIT 0x20 /* What is it for ? */
96
97#define SCMD_SET_VOLUME 0xAE
98#define SCMD_PAUSE 0xE0
99#define SCMD_STOP 0xE0
100
101#define SCMD_GET_DISK_INFO 0xAA
102
103/*
104 * Some standard arguments for SCMD_GET_DISK_INFO.
105 */
106#define SCMD_GET_1_TRACK 0xA0 /* get the first track information */
107#define SCMD_GET_L_TRACK 0xA1 /* get the last track information */
108#define SCMD_GET_D_SIZE 0xA2 /* get the whole disk information */
109
110/*
111 * Borrowed from hd.c. Allows to optimize multiple port read commands.
112 */
113#define S_READ_DATA( port, buf, nr ) insb( port, buf, nr )
114
115/*
116 * We assume that there are no audio disks with TOC length more than this
117 * number (I personally have never seen disks with more than 20 fragments).
118 */
119#define SJCD_MAX_TRACKS 100
120
121struct msf {
122 unsigned char min;
123 unsigned char sec;
124 unsigned char frame;
125};
126
127struct sjcd_hw_disk_info {
128 unsigned char track_control;
129 unsigned char track_no;
130 unsigned char x, y, z;
131 union {
132 unsigned char track_no;
133 struct msf track_msf;
134 } un;
135};
136
137struct sjcd_hw_qinfo {
138 unsigned char track_control;
139 unsigned char track_no;
140 unsigned char x;
141 struct msf rel;
142 struct msf abs;
143};
144
145struct sjcd_play_msf {
146 struct msf start;
147 struct msf end;
148};
149
150struct sjcd_disk_info {
151 unsigned char first;
152 unsigned char last;
153 struct msf disk_length;
154 struct msf first_track;
155};
156
157struct sjcd_toc {
158 unsigned char ctrl_addr;
159 unsigned char track;
160 unsigned char point_index;
161 struct msf track_time;
162 struct msf disk_time;
163};
164
165#if defined( SJCD_GATHER_STAT )
166
167struct sjcd_stat {
168 int ticks;
169 int tticks[ 8 ];
170 int idle_ticks;
171 int start_ticks;
172 int mode_ticks;
173 int read_ticks;
174 int data_ticks;
175 int stop_ticks;
176 int stopping_ticks;
177};
178
179#endif
180
181#endif
diff --git a/drivers/cdrom/sonycd535.c b/drivers/cdrom/sonycd535.c
deleted file mode 100644
index f77ada933ea0..000000000000
--- a/drivers/cdrom/sonycd535.c
+++ /dev/null
@@ -1,1689 +0,0 @@
1/*
2 * Sony CDU-535 interface device driver
3 *
4 * This is a modified version of the CDU-31A device driver (see below).
5 * Changes were made using documentation for the CDU-531 (which Sony
6 * assures me is very similar to the 535) and partial disassembly of the
7 * DOS driver. I used Minyard's driver and replaced the CDU-31A
8 * commands with the CDU-531 commands. This was complicated by a different
9 * interface protocol with the drive. The driver is still polled.
10 *
11 * Data transfer rate is about 110 Kb/sec, theoretical maximum is 150 Kb/sec.
12 * I tried polling without the sony_sleep during the data transfers but
13 * it did not speed things up any.
14 *
15 * 1993-05-23 (rgj) changed the major number to 21 to get rid of conflict
16 * with CDU-31A driver. This is the also the number from the Linux
17 * Device Driver Registry for the Sony Drive. Hope nobody else is using it.
18 *
19 * 1993-08-29 (rgj) remove the configuring of the interface board address
20 * from the top level configuration, you have to modify it in this file.
21 *
22 * 1995-01-26 Made module-capable (Joel Katz <Stimpson@Panix.COM>)
23 *
24 * 1995-05-20
25 * Modified to support CDU-510/515 series
26 * (Claudio Porfiri<C.Porfiri@nisms.tei.ericsson.se>)
27 * Fixed to report verify_area() failures
28 * (Heiko Eissfeldt <heiko@colossus.escape.de>)
29 *
30 * 1995-06-01
31 * More changes to support CDU-510/515 series
32 * (Claudio Porfiri<C.Porfiri@nisms.tei.ericsson.se>)
33 *
34 * November 1999 -- Make kernel-parameter implementation work with 2.3.x
35 * Removed init_module & cleanup_module in favor of
36 * module_init & module_exit.
37 * Torben Mathiasen <tmm@image.dk>
38 *
39 * September 2003 - Fix SMP support by removing cli/sti calls.
40 * Using spinlocks with a wait_queue instead.
41 * Felipe Damasio <felipewd@terra.com.br>
42 *
43 * Things to do:
44 * - handle errors and status better, put everything into a single word
45 * - use interrupts (code mostly there, but a big hole still missing)
46 * - handle multi-session CDs?
47 * - use DMA?
48 *
49 * Known Bugs:
50 * -
51 *
52 * Ken Pizzini (ken@halcyon.com)
53 *
54 * Original by:
55 * Ron Jeppesen (ronj.an@site007.saic.com)
56 *
57 *
58 *------------------------------------------------------------------------
59 * Sony CDROM interface device driver.
60 *
61 * Corey Minyard (minyard@wf-rch.cirr.com) (CDU-535 complaints to Ken above)
62 *
63 * Colossians 3:17
64 *
65 * The Sony interface device driver handles Sony interface CDROM
66 * drives and provides a complete block-level interface as well as an
67 * ioctl() interface compatible with the Sun (as specified in
68 * include/linux/cdrom.h). With this interface, CDROMs can be
69 * accessed and standard audio CDs can be played back normally.
70 *
71 * This interface is (unfortunately) a polled interface. This is
72 * because most Sony interfaces are set up with DMA and interrupts
73 * disables. Some (like mine) do not even have the capability to
74 * handle interrupts or DMA. For this reason you will see a bit of
75 * the following:
76 *
77 * snap = jiffies;
78 * while (jiffies-snap < SONY_JIFFIES_TIMEOUT)
79 * {
80 * if (some_condition())
81 * break;
82 * sony_sleep();
83 * }
84 * if (some_condition not met)
85 * {
86 * return an_error;
87 * }
88 *
89 * This ugly hack waits for something to happen, sleeping a little
90 * between every try. (The conditional is written so that jiffies
91 * wrap-around is handled properly.)
92 *
93 * One thing about these drives: They talk in MSF (Minute Second Frame) format.
94 * There are 75 frames a second, 60 seconds a minute, and up to 75 minutes on a
95 * disk. The funny thing is that these are sent to the drive in BCD, but the
96 * interface wants to see them in decimal. A lot of conversion goes on.
97 *
98 * Copyright (C) 1993 Corey Minyard
99 *
100 * This program is free software; you can redistribute it and/or modify
101 * it under the terms of the GNU General Public License as published by
102 * the Free Software Foundation; either version 2 of the License, or
103 * (at your option) any later version.
104 *
105 * This program is distributed in the hope that it will be useful,
106 * but WITHOUT ANY WARRANTY; without even the implied warranty of
107 * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
108 * GNU General Public License for more details.
109 *
110 * You should have received a copy of the GNU General Public License
111 * along with this program; if not, write to the Free Software
112 * Foundation, Inc., 675 Mass Ave, Cambridge, MA 02139, USA.
113 *
114 */
115
116
117# include <linux/module.h>
118
119#include <linux/errno.h>
120#include <linux/signal.h>
121#include <linux/sched.h>
122#include <linux/timer.h>
123#include <linux/fs.h>
124#include <linux/kernel.h>
125#include <linux/interrupt.h>
126#include <linux/ioport.h>
127#include <linux/hdreg.h>
128#include <linux/genhd.h>
129#include <linux/mm.h>
130#include <linux/slab.h>
131#include <linux/init.h>
132
133#define REALLY_SLOW_IO
134#include <asm/system.h>
135#include <asm/io.h>
136#include <asm/uaccess.h>
137
138#include <linux/cdrom.h>
139
140#define MAJOR_NR CDU535_CDROM_MAJOR
141#include <linux/blkdev.h>
142
143#define sony535_cd_base_io sonycd535 /* for compatible parameter passing with "insmod" */
144#include "sonycd535.h"
145
146/*
147 * this is the base address of the interface card for the Sony CDU-535
148 * CDROM drive. If your jumpers are set for an address other than
149 * this one (the default), change the following line to the
150 * proper address.
151 */
152#ifndef CDU535_ADDRESS
153# define CDU535_ADDRESS 0x340
154#endif
155#ifndef CDU535_INTERRUPT
156# define CDU535_INTERRUPT 0
157#endif
158#ifndef CDU535_HANDLE
159# define CDU535_HANDLE "cdu535"
160#endif
161#ifndef CDU535_MESSAGE_NAME
162# define CDU535_MESSAGE_NAME "Sony CDU-535"
163#endif
164
165#define CDU535_BLOCK_SIZE 2048
166
167#ifndef MAX_SPINUP_RETRY
168# define MAX_SPINUP_RETRY 3 /* 1 is sufficient for most drives... */
169#endif
170#ifndef RETRY_FOR_BAD_STATUS
171# define RETRY_FOR_BAD_STATUS 100 /* in 10th of second */
172#endif
173
174#ifndef DEBUG
175# define DEBUG 1
176#endif
177
178/*
179 * SONY535_BUFFER_SIZE determines the size of internal buffer used
180 * by the drive. It must be at least 2K and the larger the buffer
181 * the better the transfer rate. It does however take system memory.
182 * On my system I get the following transfer rates using dd to read
183 * 10 Mb off /dev/cdrom.
184 *
185 * 8K buffer 43 Kb/sec
186 * 16K buffer 66 Kb/sec
187 * 32K buffer 91 Kb/sec
188 * 64K buffer 111 Kb/sec
189 * 128K buffer 123 Kb/sec
190 * 512K buffer 123 Kb/sec
191 */
192#define SONY535_BUFFER_SIZE (64*1024)
193
194/*
195 * if LOCK_DOORS is defined then the eject button is disabled while
196 * the device is open.
197 */
198#ifndef NO_LOCK_DOORS
199# define LOCK_DOORS
200#endif
201
202static int read_subcode(void);
203static void sony_get_toc(void);
204static int cdu_open(struct inode *inode, struct file *filp);
205static inline unsigned int int_to_bcd(unsigned int val);
206static unsigned int bcd_to_int(unsigned int bcd);
207static int do_sony_cmd(Byte * cmd, int nCmd, Byte status[2],
208 Byte * response, int n_response, int ignoreStatusBit7);
209
210/* The base I/O address of the Sony Interface. This is a variable (not a
211 #define) so it can be easily changed via some future ioctl() */
212static unsigned int sony535_cd_base_io = CDU535_ADDRESS;
213module_param(sony535_cd_base_io, int, 0);
214
215/*
216 * The following are I/O addresses of the various registers for the drive. The
217 * comment for the base address also applies here.
218 */
219static unsigned short select_unit_reg;
220static unsigned short result_reg;
221static unsigned short command_reg;
222static unsigned short read_status_reg;
223static unsigned short data_reg;
224
225static DEFINE_SPINLOCK(sonycd535_lock); /* queue lock */
226static struct request_queue *sonycd535_queue;
227
228static int initialized; /* Has the drive been initialized? */
229static int sony_disc_changed = 1; /* Has the disk been changed
230 since the last check? */
231static int sony_toc_read; /* Has the table of contents been
232 read? */
233static unsigned int sony_buffer_size; /* Size in bytes of the read-ahead
234 buffer. */
235static unsigned int sony_buffer_sectors; /* Size (in 2048 byte records) of
236 the read-ahead buffer. */
237static unsigned int sony_usage; /* How many processes have the
238 drive open. */
239
240static int sony_first_block = -1; /* First OS block (512 byte) in
241 the read-ahead buffer */
242static int sony_last_block = -1; /* Last OS block (512 byte) in
243 the read-ahead buffer */
244
245static struct s535_sony_toc *sony_toc; /* Points to the table of
246 contents. */
247
248static struct s535_sony_subcode *last_sony_subcode; /* Points to the last
249 subcode address read */
250static Byte **sony_buffer; /* Points to the pointers
251 to the sector buffers */
252
253static int sony_inuse; /* is the drive in use? Only one
254 open at a time allowed */
255
256/*
257 * The audio status uses the values from read subchannel data as specified
258 * in include/linux/cdrom.h.
259 */
260static int sony_audio_status = CDROM_AUDIO_NO_STATUS;
261
262/*
263 * The following are a hack for pausing and resuming audio play. The drive
264 * does not work as I would expect it, if you stop it then start it again,
265 * the drive seeks back to the beginning and starts over. This holds the
266 * position during a pause so a resume can restart it. It uses the
267 * audio status variable above to tell if it is paused.
268 * I just kept the CDU-31A driver behavior rather than using the PAUSE
269 * command on the CDU-535.
270 */
271static Byte cur_pos_msf[3];
272static Byte final_pos_msf[3];
273
274/* What IRQ is the drive using? 0 if none. */
275static int sony535_irq_used = CDU535_INTERRUPT;
276
277/* The interrupt handler will wake this queue up when it gets an interrupt. */
278static DECLARE_WAIT_QUEUE_HEAD(cdu535_irq_wait);
279
280
281/*
282 * This routine returns 1 if the disk has been changed since the last
283 * check or 0 if it hasn't. Setting flag to 0 resets the changed flag.
284 */
285static int
286cdu535_check_media_change(struct gendisk *disk)
287{
288 /* if driver is not initialized, always return 0 */
289 int retval = initialized ? sony_disc_changed : 0;
290 sony_disc_changed = 0;
291 return retval;
292}
293
294static inline void
295enable_interrupts(void)
296{
297#ifdef USE_IRQ
298 /*
299 * This code was taken from cdu31a.c; it will not
300 * directly work for the cdu535 as written...
301 */
302 curr_control_reg |= ( SONY_ATTN_INT_EN_BIT
303 | SONY_RES_RDY_INT_EN_BIT
304 | SONY_DATA_RDY_INT_EN_BIT);
305 outb(curr_control_reg, sony_cd_control_reg);
306#endif
307}
308
309static inline void
310disable_interrupts(void)
311{
312#ifdef USE_IRQ
313 /*
314 * This code was taken from cdu31a.c; it will not
315 * directly work for the cdu535 as written...
316 */
317 curr_control_reg &= ~(SONY_ATTN_INT_EN_BIT
318 | SONY_RES_RDY_INT_EN_BIT
319 | SONY_DATA_RDY_INT_EN_BIT);
320 outb(curr_control_reg, sony_cd_control_reg);
321#endif
322}
323
324static irqreturn_t
325cdu535_interrupt(int irq, void *dev_id)
326{
327 disable_interrupts();
328 if (waitqueue_active(&cdu535_irq_wait)) {
329 wake_up(&cdu535_irq_wait);
330 return IRQ_HANDLED;
331 }
332 printk(CDU535_MESSAGE_NAME
333 ": Got an interrupt but nothing was waiting\n");
334 return IRQ_NONE;
335}
336
337
338/*
339 * Wait a little while.
340 */
341static inline void
342sony_sleep(void)
343{
344 if (sony535_irq_used <= 0) { /* poll */
345 yield();
346 } else { /* Interrupt driven */
347 DEFINE_WAIT(wait);
348
349 spin_lock_irq(&sonycd535_lock);
350 enable_interrupts();
351 prepare_to_wait(&cdu535_irq_wait, &wait, TASK_INTERRUPTIBLE);
352 spin_unlock_irq(&sonycd535_lock);
353 schedule();
354 finish_wait(&cdu535_irq_wait, &wait);
355 }
356}
357
358/*------------------start of SONY CDU535 very specific ---------------------*/
359
360/****************************************************************************
361 * void select_unit( int unit_no )
362 *
363 * Select the specified unit (0-3) so that subsequent commands reference it
364 ****************************************************************************/
365static void
366select_unit(int unit_no)
367{
368 unsigned int select_mask = ~(1 << unit_no);
369 outb(select_mask, select_unit_reg);
370}
371
372/***************************************************************************
373 * int read_result_reg( Byte *data_ptr )
374 *
375 * Read a result byte from the Sony CDU controller, store in location pointed
376 * to by data_ptr. Return zero on success, TIME_OUT if we did not receive
377 * data.
378 ***************************************************************************/
379static int
380read_result_reg(Byte *data_ptr)
381{
382 unsigned long snap;
383 int read_status;
384
385 snap = jiffies;
386 while (jiffies-snap < SONY_JIFFIES_TIMEOUT) {
387 read_status = inb(read_status_reg);
388 if ((read_status & SONY535_RESULT_NOT_READY_BIT) == 0) {
389#if DEBUG > 1
390 printk(CDU535_MESSAGE_NAME
391 ": read_result_reg(): readStatReg = 0x%x\n", read_status);
392#endif
393 *data_ptr = inb(result_reg);
394 return 0;
395 } else {
396 sony_sleep();
397 }
398 }
399 printk(CDU535_MESSAGE_NAME " read_result_reg: TIME OUT!\n");
400 return TIME_OUT;
401}
402
403/****************************************************************************
404 * int read_exec_status( Byte status[2] )
405 *
406 * Read the execution status of the last command and put into status.
407 * Handles reading second status word if available. Returns 0 on success,
408 * TIME_OUT on failure.
409 ****************************************************************************/
410static int
411read_exec_status(Byte status[2])
412{
413 status[1] = 0;
414 if (read_result_reg(&(status[0])) != 0)
415 return TIME_OUT;
416 if ((status[0] & 0x80) != 0) { /* byte two follows */
417 if (read_result_reg(&(status[1])) != 0)
418 return TIME_OUT;
419 }
420#if DEBUG > 1
421 printk(CDU535_MESSAGE_NAME ": read_exec_status: read 0x%x 0x%x\n",
422 status[0], status[1]);
423#endif
424 return 0;
425}
426
427/****************************************************************************
428 * int check_drive_status( void )
429 *
430 * Check the current drive status. Using this before executing a command
431 * takes care of the problem of unsolicited drive status-2 messages.
432 * Add a check of the audio status if we think the disk is playing.
433 ****************************************************************************/
434static int
435check_drive_status(void)
436{
437 Byte status, e_status[2];
438 int CDD, ATN;
439 Byte cmd;
440
441 select_unit(0);
442 if (sony_audio_status == CDROM_AUDIO_PLAY) { /* check status */
443 outb(SONY535_REQUEST_AUDIO_STATUS, command_reg);
444 if (read_result_reg(&status) == 0) {
445 switch (status) {
446 case 0x0:
447 break; /* play in progress */
448 case 0x1:
449 break; /* paused */
450 case 0x3: /* audio play completed */
451 case 0x5: /* play not requested */
452 sony_audio_status = CDROM_AUDIO_COMPLETED;
453 read_subcode();
454 break;
455 case 0x4: /* error during play */
456 sony_audio_status = CDROM_AUDIO_ERROR;
457 break;
458 }
459 }
460 }
461 /* now check drive status */
462 outb(SONY535_REQUEST_DRIVE_STATUS_2, command_reg);
463 if (read_result_reg(&status) != 0)
464 return TIME_OUT;
465
466#if DEBUG > 1
467 printk(CDU535_MESSAGE_NAME ": check_drive_status() got 0x%x\n", status);
468#endif
469
470 if (status == 0)
471 return 0;
472
473 ATN = status & 0xf;
474 CDD = (status >> 4) & 0xf;
475
476 switch (ATN) {
477 case 0x0:
478 break; /* go on to CDD stuff */
479 case SONY535_ATN_BUSY:
480 if (initialized)
481 printk(CDU535_MESSAGE_NAME " error: drive busy\n");
482 return CD_BUSY;
483 case SONY535_ATN_EJECT_IN_PROGRESS:
484 printk(CDU535_MESSAGE_NAME " error: eject in progress\n");
485 sony_audio_status = CDROM_AUDIO_INVALID;
486 return CD_BUSY;
487 case SONY535_ATN_RESET_OCCURRED:
488 case SONY535_ATN_DISC_CHANGED:
489 case SONY535_ATN_RESET_AND_DISC_CHANGED:
490#if DEBUG > 0
491 printk(CDU535_MESSAGE_NAME " notice: reset occurred or disc changed\n");
492#endif
493 sony_disc_changed = 1;
494 sony_toc_read = 0;
495 sony_audio_status = CDROM_AUDIO_NO_STATUS;
496 sony_first_block = -1;
497 sony_last_block = -1;
498 if (initialized) {
499 cmd = SONY535_SPIN_UP;
500 do_sony_cmd(&cmd, 1, e_status, NULL, 0, 0);
501 sony_get_toc();
502 }
503 return 0;
504 default:
505 printk(CDU535_MESSAGE_NAME " error: drive busy (ATN=0x%x)\n", ATN);
506 return CD_BUSY;
507 }
508 switch (CDD) { /* the 531 docs are not helpful in decoding this */
509 case 0x0: /* just use the values from the DOS driver */
510 case 0x2:
511 case 0xa:
512 break; /* no error */
513 case 0xc:
514 printk(CDU535_MESSAGE_NAME
515 ": check_drive_status(): CDD = 0xc! Not properly handled!\n");
516 return CD_BUSY; /* ? */
517 default:
518 return CD_BUSY;
519 }
520 return 0;
521} /* check_drive_status() */
522
523/*****************************************************************************
524 * int do_sony_cmd( Byte *cmd, int n_cmd, Byte status[2],
525 * Byte *response, int n_response, int ignore_status_bit7 )
526 *
527 * Generic routine for executing commands. The command and its parameters
528 * should be placed in the cmd[] array, number of bytes in the command is
529 * stored in nCmd. The response from the command will be stored in the
530 * response array. The number of bytes you expect back (excluding status)
531 * should be passed in n_response. Finally, some
532 * commands set bit 7 of the return status even when there is no second
533 * status byte, on these commands set ignoreStatusBit7 TRUE.
534 * If the command was sent and data received back, then we return 0,
535 * else we return TIME_OUT. You still have to check the status yourself.
536 * You should call check_drive_status() before calling this routine
537 * so that you do not lose notifications of disk changes, etc.
538 ****************************************************************************/
539static int
540do_sony_cmd(Byte * cmd, int n_cmd, Byte status[2],
541 Byte * response, int n_response, int ignore_status_bit7)
542{
543 int i;
544
545 /* write out the command */
546 for (i = 0; i < n_cmd; i++)
547 outb(cmd[i], command_reg);
548
549 /* read back the status */
550 if (read_result_reg(status) != 0)
551 return TIME_OUT;
552 if (!ignore_status_bit7 && ((status[0] & 0x80) != 0)) {
553 /* get second status byte */
554 if (read_result_reg(status + 1) != 0)
555 return TIME_OUT;
556 } else {
557 status[1] = 0;
558 }
559#if DEBUG > 2
560 printk(CDU535_MESSAGE_NAME ": do_sony_cmd %x: %x %x\n",
561 *cmd, status[0], status[1]);
562#endif
563
564 /* do not know about when I should read set of data and when not to */
565 if ((status[0] & ((ignore_status_bit7 ? 0x7f : 0xff) & 0x8f)) != 0)
566 return 0;
567
568 /* else, read in rest of data */
569 for (i = 0; 0 < n_response; n_response--, i++)
570 if (read_result_reg(response + i) != 0)
571 return TIME_OUT;
572 return 0;
573} /* do_sony_cmd() */
574
575/**************************************************************************
576 * int set_drive_mode( int mode, Byte status[2] )
577 *
578 * Set the drive mode to the specified value (mode=0 is audio, mode=e0
579 * is mode-1 CDROM
580 **************************************************************************/
581static int
582set_drive_mode(int mode, Byte status[2])
583{
584 Byte cmd_buff[2];
585 Byte ret_buff[1];
586
587 cmd_buff[0] = SONY535_SET_DRIVE_MODE;
588 cmd_buff[1] = mode;
589 return do_sony_cmd(cmd_buff, 2, status, ret_buff, 1, 1);
590}
591
592/***************************************************************************
593 * int seek_and_read_N_blocks( Byte params[], int n_blocks, Byte status[2],
594 * Byte *data_buff, int buff_size )
595 *
596 * Read n_blocks of data from the CDROM starting at position params[0:2],
597 * number of blocks in stored in params[3:5] -- both these are already
598 * int bcd format.
599 * Transfer the data into the buffer pointed at by data_buff. buff_size
600 * gives the number of bytes available in the buffer.
601 * The routine returns number of bytes read in if successful, otherwise
602 * it returns one of the standard error returns.
603 ***************************************************************************/
604static int
605seek_and_read_N_blocks(Byte params[], int n_blocks, Byte status[2],
606 Byte **buff, int buf_size)
607{
608 Byte cmd_buff[7];
609 int i;
610 int read_status;
611 unsigned long snap;
612 Byte *data_buff;
613 int sector_count = 0;
614
615 if (buf_size < CDU535_BLOCK_SIZE * n_blocks)
616 return NO_ROOM;
617
618 set_drive_mode(SONY535_CDROM_DRIVE_MODE, status);
619
620 /* send command to read the data */
621 cmd_buff[0] = SONY535_SEEK_AND_READ_N_BLOCKS_1;
622 for (i = 0; i < 6; i++)
623 cmd_buff[i + 1] = params[i];
624 for (i = 0; i < 7; i++)
625 outb(cmd_buff[i], command_reg);
626
627 /* read back the data one block at a time */
628 while (0 < n_blocks--) {
629 /* wait for data to be ready */
630 int data_valid = 0;
631 snap = jiffies;
632 while (jiffies-snap < SONY_JIFFIES_TIMEOUT) {
633 read_status = inb(read_status_reg);
634 if ((read_status & SONY535_RESULT_NOT_READY_BIT) == 0) {
635 read_exec_status(status);
636 return BAD_STATUS;
637 }
638 if ((read_status & SONY535_DATA_NOT_READY_BIT) == 0) {
639 /* data is ready, read it */
640 data_buff = buff[sector_count++];
641 for (i = 0; i < CDU535_BLOCK_SIZE; i++)
642 *data_buff++ = inb(data_reg); /* unrolling this loop does not seem to help */
643 data_valid = 1;
644 break; /* exit the timeout loop */
645 }
646 sony_sleep(); /* data not ready, sleep a while */
647 }
648 if (!data_valid)
649 return TIME_OUT; /* if we reach this stage */
650 }
651
652 /* read all the data, now read the status */
653 if ((i = read_exec_status(status)) != 0)
654 return i;
655 return CDU535_BLOCK_SIZE * sector_count;
656} /* seek_and_read_N_blocks() */
657
658/****************************************************************************
659 * int request_toc_data( Byte status[2], struct s535_sony_toc *toc )
660 *
661 * Read in the table of contents data. Converts all the bcd data
662 * into integers in the toc structure.
663 ****************************************************************************/
664static int
665request_toc_data(Byte status[2], struct s535_sony_toc *toc)
666{
667 int to_status;
668 int i, j, n_tracks, track_no;
669 int first_track_num, last_track_num;
670 Byte cmd_no = 0xb2;
671 Byte track_address_buffer[5];
672
673 /* read the fixed portion of the table of contents */
674 if ((to_status = do_sony_cmd(&cmd_no, 1, status, (Byte *) toc, 15, 1)) != 0)
675 return to_status;
676
677 /* convert the data into integers so we can use them */
678 first_track_num = bcd_to_int(toc->first_track_num);
679 last_track_num = bcd_to_int(toc->last_track_num);
680 n_tracks = last_track_num - first_track_num + 1;
681
682 /* read each of the track address descriptors */
683 for (i = 0; i < n_tracks; i++) {
684 /* read the descriptor into a temporary buffer */
685 for (j = 0; j < 5; j++) {
686 if (read_result_reg(track_address_buffer + j) != 0)
687 return TIME_OUT;
688 if (j == 1) /* need to convert from bcd */
689 track_no = bcd_to_int(track_address_buffer[j]);
690 }
691 /* copy the descriptor to proper location - sonycd.c just fills */
692 memcpy(toc->tracks + i, track_address_buffer, 5);
693 }
694 return 0;
695} /* request_toc_data() */
696
697/***************************************************************************
698 * int spin_up_drive( Byte status[2] )
699 *
700 * Spin up the drive (unless it is already spinning).
701 ***************************************************************************/
702static int
703spin_up_drive(Byte status[2])
704{
705 Byte cmd;
706
707 /* first see if the drive is already spinning */
708 cmd = SONY535_REQUEST_DRIVE_STATUS_1;
709 if (do_sony_cmd(&cmd, 1, status, NULL, 0, 0) != 0)
710 return TIME_OUT;
711 if ((status[0] & SONY535_STATUS1_NOT_SPINNING) == 0)
712 return 0; /* it's already spinning */
713
714 /* otherwise, give the spin-up command */
715 cmd = SONY535_SPIN_UP;
716 return do_sony_cmd(&cmd, 1, status, NULL, 0, 0);
717}
718
719/*--------------------end of SONY CDU535 very specific ---------------------*/
720
721/* Convert from an integer 0-99 to BCD */
722static inline unsigned int
723int_to_bcd(unsigned int val)
724{
725 int retval;
726
727 retval = (val / 10) << 4;
728 retval = retval | val % 10;
729 return retval;
730}
731
732
733/* Convert from BCD to an integer from 0-99 */
734static unsigned int
735bcd_to_int(unsigned int bcd)
736{
737 return (((bcd >> 4) & 0x0f) * 10) + (bcd & 0x0f);
738}
739
740
741/*
742 * Convert a logical sector value (like the OS would want to use for
743 * a block device) to an MSF format.
744 */
745static void
746log_to_msf(unsigned int log, Byte *msf)
747{
748 log = log + LOG_START_OFFSET;
749 msf[0] = int_to_bcd(log / 4500);
750 log = log % 4500;
751 msf[1] = int_to_bcd(log / 75);
752 msf[2] = int_to_bcd(log % 75);
753}
754
755
756/*
757 * Convert an MSF format to a logical sector.
758 */
759static unsigned int
760msf_to_log(Byte *msf)
761{
762 unsigned int log;
763
764
765 log = bcd_to_int(msf[2]);
766 log += bcd_to_int(msf[1]) * 75;
767 log += bcd_to_int(msf[0]) * 4500;
768 log = log - LOG_START_OFFSET;
769
770 return log;
771}
772
773
774/*
775 * Take in integer size value and put it into a buffer like
776 * the drive would want to see a number-of-sector value.
777 */
778static void
779size_to_buf(unsigned int size, Byte *buf)
780{
781 buf[0] = size / 65536;
782 size = size % 65536;
783 buf[1] = size / 256;
784 buf[2] = size % 256;
785}
786
787
788/*
789 * The OS calls this to perform a read or write operation to the drive.
790 * Write obviously fail. Reads to a read ahead of sony_buffer_size
791 * bytes to help speed operations. This especially helps since the OS
792 * may use 1024 byte blocks and the drive uses 2048 byte blocks. Since most
793 * data access on a CD is done sequentially, this saves a lot of operations.
794 */
795static void
796do_cdu535_request(request_queue_t * q)
797{
798 struct request *req;
799 unsigned int read_size;
800 int block;
801 int nsect;
802 int copyoff;
803 int spin_up_retry;
804 Byte params[10];
805 Byte status[2];
806 Byte cmd[2];
807
808 while (1) {
809 req = elv_next_request(q);
810 if (!req)
811 return;
812
813 block = req->sector;
814 nsect = req->nr_sectors;
815 if (!blk_fs_request(req)) {
816 end_request(req, 0);
817 continue;
818 }
819 if (rq_data_dir(req) == WRITE) {
820 end_request(req, 0);
821 continue;
822 }
823 /*
824 * If the block address is invalid or the request goes beyond
825 * the end of the media, return an error.
826 */
827 if (sony_toc->lead_out_start_lba <= (block/4)) {
828 end_request(req, 0);
829 return;
830 }
831 if (sony_toc->lead_out_start_lba <= ((block + nsect) / 4)) {
832 end_request(req, 0);
833 return;
834 }
835 while (0 < nsect) {
836 /*
837 * If the requested sector is not currently in
838 * the read-ahead buffer, it must be read in.
839 */
840 if ((block < sony_first_block) || (sony_last_block < block)) {
841 sony_first_block = (block / 4) * 4;
842 log_to_msf(block / 4, params);
843
844 /*
845 * If the full read-ahead would go beyond the end of the media, trim
846 * it back to read just till the end of the media.
847 */
848 if (sony_toc->lead_out_start_lba <= ((block / 4) + sony_buffer_sectors)) {
849 sony_last_block = (sony_toc->lead_out_start_lba * 4) - 1;
850 read_size = sony_toc->lead_out_start_lba - (block / 4);
851 } else {
852 sony_last_block = sony_first_block + (sony_buffer_sectors * 4) - 1;
853 read_size = sony_buffer_sectors;
854 }
855 size_to_buf(read_size, &params[3]);
856
857 /*
858 * Read the data. If the drive was not spinning,
859 * spin it up and try some more.
860 */
861 for (spin_up_retry=0 ;; ++spin_up_retry) {
862 /* This loop has been modified to support the Sony
863 * CDU-510/515 series, thanks to Claudio Porfiri
864 * <C.Porfiri@nisms.tei.ericsson.se>.
865 */
866 /*
867 * This part is to deal with very slow hardware. We
868 * try at most MAX_SPINUP_RETRY times to read the same
869 * block. A check for seek_and_read_N_blocks' result is
870 * performed; if the result is wrong, the CDROM's engine
871 * is restarted and the operation is tried again.
872 */
873 /*
874 * 1995-06-01: The system got problems when downloading
875 * from Slackware CDROM, the problem seems to be:
876 * seek_and_read_N_blocks returns BAD_STATUS and we
877 * should wait for a while before retrying, so a new
878 * part was added to discriminate the return value from
879 * seek_and_read_N_blocks for the various cases.
880 */
881 int readStatus = seek_and_read_N_blocks(params, read_size,
882 status, sony_buffer, (read_size * CDU535_BLOCK_SIZE));
883 if (0 <= readStatus) /* Good data; common case, placed first */
884 break;
885 if (readStatus == NO_ROOM || spin_up_retry == MAX_SPINUP_RETRY) {
886 /* give up */
887 if (readStatus == NO_ROOM)
888 printk(CDU535_MESSAGE_NAME " No room to read from CD\n");
889 else
890 printk(CDU535_MESSAGE_NAME " Read error: 0x%.2x\n",
891 status[0]);
892 sony_first_block = -1;
893 sony_last_block = -1;
894 end_request(req, 0);
895 return;
896 }
897 if (readStatus == BAD_STATUS) {
898 /* Sleep for a while, then retry */
899 set_current_state(TASK_INTERRUPTIBLE);
900 spin_unlock_irq(&sonycd535_lock);
901 schedule_timeout(RETRY_FOR_BAD_STATUS*HZ/10);
902 spin_lock_irq(&sonycd535_lock);
903 }
904#if DEBUG > 0
905 printk(CDU535_MESSAGE_NAME
906 " debug: calling spin up when reading data!\n");
907#endif
908 cmd[0] = SONY535_SPIN_UP;
909 do_sony_cmd(cmd, 1, status, NULL, 0, 0);
910 }
911 }
912 /*
913 * The data is in memory now, copy it to the buffer and advance to the
914 * next block to read.
915 */
916 copyoff = block - sony_first_block;
917 memcpy(req->buffer,
918 sony_buffer[copyoff / 4] + 512 * (copyoff % 4), 512);
919
920 block += 1;
921 nsect -= 1;
922 req->buffer += 512;
923 }
924
925 end_request(req, 1);
926 }
927}
928
929/*
930 * Read the table of contents from the drive and set sony_toc_read if
931 * successful.
932 */
933static void
934sony_get_toc(void)
935{
936 Byte status[2];
937 if (!sony_toc_read) {
938 /* do not call check_drive_status() from here since it can call this routine */
939 if (request_toc_data(status, sony_toc) < 0)
940 return;
941 sony_toc->lead_out_start_lba = msf_to_log(sony_toc->lead_out_start_msf);
942 sony_toc_read = 1;
943 }
944}
945
946
947/*
948 * Search for a specific track in the table of contents. track is
949 * passed in bcd format
950 */
951static int
952find_track(int track)
953{
954 int i;
955 int num_tracks;
956
957
958 num_tracks = bcd_to_int(sony_toc->last_track_num) -
959 bcd_to_int(sony_toc->first_track_num) + 1;
960 for (i = 0; i < num_tracks; i++) {
961 if (sony_toc->tracks[i].track == track) {
962 return i;
963 }
964 }
965
966 return -1;
967}
968
969/*
970 * Read the subcode and put it int last_sony_subcode for future use.
971 */
972static int
973read_subcode(void)
974{
975 Byte cmd = SONY535_REQUEST_SUB_Q_DATA;
976 Byte status[2];
977 int dsc_status;
978
979 if (check_drive_status() != 0)
980 return -EIO;
981
982 if ((dsc_status = do_sony_cmd(&cmd, 1, status, (Byte *) last_sony_subcode,
983 sizeof(struct s535_sony_subcode), 1)) != 0) {
984 printk(CDU535_MESSAGE_NAME " error 0x%.2x, %d (read_subcode)\n",
985 status[0], dsc_status);
986 return -EIO;
987 }
988 return 0;
989}
990
991
992/*
993 * Get the subchannel info like the CDROMSUBCHNL command wants to see it. If
994 * the drive is playing, the subchannel needs to be read (since it would be
995 * changing). If the drive is paused or completed, the subcode information has
996 * already been stored, just use that. The ioctl call wants things in decimal
997 * (not BCD), so all the conversions are done.
998 */
999static int
1000sony_get_subchnl_info(void __user *arg)
1001{
1002 struct cdrom_subchnl schi;
1003
1004 /* Get attention stuff */
1005 if (check_drive_status() != 0)
1006 return -EIO;
1007
1008 sony_get_toc();
1009 if (!sony_toc_read) {
1010 return -EIO;
1011 }
1012 if (copy_from_user(&schi, arg, sizeof schi))
1013 return -EFAULT;
1014
1015 switch (sony_audio_status) {
1016 case CDROM_AUDIO_PLAY:
1017 if (read_subcode() < 0) {
1018 return -EIO;
1019 }
1020 break;
1021
1022 case CDROM_AUDIO_PAUSED:
1023 case CDROM_AUDIO_COMPLETED:
1024 break;
1025
1026 case CDROM_AUDIO_NO_STATUS:
1027 schi.cdsc_audiostatus = sony_audio_status;
1028 if (copy_to_user(arg, &schi, sizeof schi))
1029 return -EFAULT;
1030 return 0;
1031 break;
1032
1033 case CDROM_AUDIO_INVALID:
1034 case CDROM_AUDIO_ERROR:
1035 default:
1036 return -EIO;
1037 }
1038
1039 schi.cdsc_audiostatus = sony_audio_status;
1040 schi.cdsc_adr = last_sony_subcode->address;
1041 schi.cdsc_ctrl = last_sony_subcode->control;
1042 schi.cdsc_trk = bcd_to_int(last_sony_subcode->track_num);
1043 schi.cdsc_ind = bcd_to_int(last_sony_subcode->index_num);
1044 if (schi.cdsc_format == CDROM_MSF) {
1045 schi.cdsc_absaddr.msf.minute = bcd_to_int(last_sony_subcode->abs_msf[0]);
1046 schi.cdsc_absaddr.msf.second = bcd_to_int(last_sony_subcode->abs_msf[1]);
1047 schi.cdsc_absaddr.msf.frame = bcd_to_int(last_sony_subcode->abs_msf[2]);
1048
1049 schi.cdsc_reladdr.msf.minute = bcd_to_int(last_sony_subcode->rel_msf[0]);
1050 schi.cdsc_reladdr.msf.second = bcd_to_int(last_sony_subcode->rel_msf[1]);
1051 schi.cdsc_reladdr.msf.frame = bcd_to_int(last_sony_subcode->rel_msf[2]);
1052 } else if (schi.cdsc_format == CDROM_LBA) {
1053 schi.cdsc_absaddr.lba = msf_to_log(last_sony_subcode->abs_msf);
1054 schi.cdsc_reladdr.lba = msf_to_log(last_sony_subcode->rel_msf);
1055 }
1056 return copy_to_user(arg, &schi, sizeof schi) ? -EFAULT : 0;
1057}
1058
1059
1060/*
1061 * The big ugly ioctl handler.
1062 */
1063static int
1064cdu_ioctl(struct inode *inode,
1065 struct file *file,
1066 unsigned int cmd,
1067 unsigned long arg)
1068{
1069 Byte status[2];
1070 Byte cmd_buff[10], params[10];
1071 int i;
1072 int dsc_status;
1073 void __user *argp = (void __user *)arg;
1074
1075 if (check_drive_status() != 0)
1076 return -EIO;
1077
1078 switch (cmd) {
1079 case CDROMSTART: /* Spin up the drive */
1080 if (spin_up_drive(status) < 0) {
1081 printk(CDU535_MESSAGE_NAME " error 0x%.2x (CDROMSTART)\n",
1082 status[0]);
1083 return -EIO;
1084 }
1085 return 0;
1086 break;
1087
1088 case CDROMSTOP: /* Spin down the drive */
1089 cmd_buff[0] = SONY535_HOLD;
1090 do_sony_cmd(cmd_buff, 1, status, NULL, 0, 0);
1091
1092 /*
1093 * Spin the drive down, ignoring the error if the disk was
1094 * already not spinning.
1095 */
1096 sony_audio_status = CDROM_AUDIO_NO_STATUS;
1097 cmd_buff[0] = SONY535_SPIN_DOWN;
1098 dsc_status = do_sony_cmd(cmd_buff, 1, status, NULL, 0, 0);
1099 if (((dsc_status < 0) && (dsc_status != BAD_STATUS)) ||
1100 ((status[0] & ~(SONY535_STATUS1_NOT_SPINNING)) != 0)) {
1101 printk(CDU535_MESSAGE_NAME " error 0x%.2x (CDROMSTOP)\n",
1102 status[0]);
1103 return -EIO;
1104 }
1105 return 0;
1106 break;
1107
1108 case CDROMPAUSE: /* Pause the drive */
1109 cmd_buff[0] = SONY535_HOLD; /* CDU-31 driver uses AUDIO_STOP, not pause */
1110 if (do_sony_cmd(cmd_buff, 1, status, NULL, 0, 0) != 0) {
1111 printk(CDU535_MESSAGE_NAME " error 0x%.2x (CDROMPAUSE)\n",
1112 status[0]);
1113 return -EIO;
1114 }
1115 /* Get the current position and save it for resuming */
1116 if (read_subcode() < 0) {
1117 return -EIO;
1118 }
1119 cur_pos_msf[0] = last_sony_subcode->abs_msf[0];
1120 cur_pos_msf[1] = last_sony_subcode->abs_msf[1];
1121 cur_pos_msf[2] = last_sony_subcode->abs_msf[2];
1122 sony_audio_status = CDROM_AUDIO_PAUSED;
1123 return 0;
1124 break;
1125
1126 case CDROMRESUME: /* Start the drive after being paused */
1127 set_drive_mode(SONY535_AUDIO_DRIVE_MODE, status);
1128
1129 if (sony_audio_status != CDROM_AUDIO_PAUSED) {
1130 return -EINVAL;
1131 }
1132 spin_up_drive(status);
1133
1134 /* Start the drive at the saved position. */
1135 cmd_buff[0] = SONY535_PLAY_AUDIO;
1136 cmd_buff[1] = 0; /* play back starting at this address */
1137 cmd_buff[2] = cur_pos_msf[0];
1138 cmd_buff[3] = cur_pos_msf[1];
1139 cmd_buff[4] = cur_pos_msf[2];
1140 cmd_buff[5] = SONY535_PLAY_AUDIO;
1141 cmd_buff[6] = 2; /* set ending address */
1142 cmd_buff[7] = final_pos_msf[0];
1143 cmd_buff[8] = final_pos_msf[1];
1144 cmd_buff[9] = final_pos_msf[2];
1145 if ((do_sony_cmd(cmd_buff, 5, status, NULL, 0, 0) != 0) ||
1146 (do_sony_cmd(cmd_buff + 5, 5, status, NULL, 0, 0) != 0)) {
1147 printk(CDU535_MESSAGE_NAME " error 0x%.2x (CDROMRESUME)\n",
1148 status[0]);
1149 return -EIO;
1150 }
1151 sony_audio_status = CDROM_AUDIO_PLAY;
1152 return 0;
1153 break;
1154
1155 case CDROMPLAYMSF: /* Play starting at the given MSF address. */
1156 if (copy_from_user(params, argp, 6))
1157 return -EFAULT;
1158 spin_up_drive(status);
1159 set_drive_mode(SONY535_AUDIO_DRIVE_MODE, status);
1160
1161 /* The parameters are given in int, must be converted */
1162 for (i = 0; i < 3; i++) {
1163 cmd_buff[2 + i] = int_to_bcd(params[i]);
1164 cmd_buff[7 + i] = int_to_bcd(params[i + 3]);
1165 }
1166 cmd_buff[0] = SONY535_PLAY_AUDIO;
1167 cmd_buff[1] = 0; /* play back starting at this address */
1168 /* cmd_buff[2-4] are filled in for loop above */
1169 cmd_buff[5] = SONY535_PLAY_AUDIO;
1170 cmd_buff[6] = 2; /* set ending address */
1171 /* cmd_buff[7-9] are filled in for loop above */
1172 if ((do_sony_cmd(cmd_buff, 5, status, NULL, 0, 0) != 0) ||
1173 (do_sony_cmd(cmd_buff + 5, 5, status, NULL, 0, 0) != 0)) {
1174 printk(CDU535_MESSAGE_NAME " error 0x%.2x (CDROMPLAYMSF)\n",
1175 status[0]);
1176 return -EIO;
1177 }
1178 /* Save the final position for pauses and resumes */
1179 final_pos_msf[0] = cmd_buff[7];
1180 final_pos_msf[1] = cmd_buff[8];
1181 final_pos_msf[2] = cmd_buff[9];
1182 sony_audio_status = CDROM_AUDIO_PLAY;
1183 return 0;
1184 break;
1185
1186 case CDROMREADTOCHDR: /* Read the table of contents header */
1187 {
1188 struct cdrom_tochdr __user *hdr = argp;
1189 struct cdrom_tochdr loc_hdr;
1190
1191 sony_get_toc();
1192 if (!sony_toc_read)
1193 return -EIO;
1194 loc_hdr.cdth_trk0 = bcd_to_int(sony_toc->first_track_num);
1195 loc_hdr.cdth_trk1 = bcd_to_int(sony_toc->last_track_num);
1196 if (copy_to_user(hdr, &loc_hdr, sizeof *hdr))
1197 return -EFAULT;
1198 }
1199 return 0;
1200 break;
1201
1202 case CDROMREADTOCENTRY: /* Read a given table of contents entry */
1203 {
1204 struct cdrom_tocentry __user *entry = argp;
1205 struct cdrom_tocentry loc_entry;
1206 int track_idx;
1207 Byte *msf_val = NULL;
1208
1209 sony_get_toc();
1210 if (!sony_toc_read) {
1211 return -EIO;
1212 }
1213
1214 if (copy_from_user(&loc_entry, entry, sizeof loc_entry))
1215 return -EFAULT;
1216
1217 /* Lead out is handled separately since it is special. */
1218 if (loc_entry.cdte_track == CDROM_LEADOUT) {
1219 loc_entry.cdte_adr = 0 /*sony_toc->address2 */ ;
1220 loc_entry.cdte_ctrl = sony_toc->control2;
1221 msf_val = sony_toc->lead_out_start_msf;
1222 } else {
1223 track_idx = find_track(int_to_bcd(loc_entry.cdte_track));
1224 if (track_idx < 0)
1225 return -EINVAL;
1226 loc_entry.cdte_adr = 0 /*sony_toc->tracks[track_idx].address */ ;
1227 loc_entry.cdte_ctrl = sony_toc->tracks[track_idx].control;
1228 msf_val = sony_toc->tracks[track_idx].track_start_msf;
1229 }
1230
1231 /* Logical buffer address or MSF format requested? */
1232 if (loc_entry.cdte_format == CDROM_LBA) {
1233 loc_entry.cdte_addr.lba = msf_to_log(msf_val);
1234 } else if (loc_entry.cdte_format == CDROM_MSF) {
1235 loc_entry.cdte_addr.msf.minute = bcd_to_int(*msf_val);
1236 loc_entry.cdte_addr.msf.second = bcd_to_int(*(msf_val + 1));
1237 loc_entry.cdte_addr.msf.frame = bcd_to_int(*(msf_val + 2));
1238 }
1239 if (copy_to_user(entry, &loc_entry, sizeof *entry))
1240 return -EFAULT;
1241 }
1242 return 0;
1243 break;
1244
1245 case CDROMPLAYTRKIND: /* Play a track. This currently ignores index. */
1246 {
1247 struct cdrom_ti ti;
1248 int track_idx;
1249
1250 sony_get_toc();
1251 if (!sony_toc_read)
1252 return -EIO;
1253
1254 if (copy_from_user(&ti, argp, sizeof ti))
1255 return -EFAULT;
1256 if ((ti.cdti_trk0 < sony_toc->first_track_num)
1257 || (sony_toc->last_track_num < ti.cdti_trk0)
1258 || (ti.cdti_trk1 < ti.cdti_trk0)) {
1259 return -EINVAL;
1260 }
1261 track_idx = find_track(int_to_bcd(ti.cdti_trk0));
1262 if (track_idx < 0)
1263 return -EINVAL;
1264 params[1] = sony_toc->tracks[track_idx].track_start_msf[0];
1265 params[2] = sony_toc->tracks[track_idx].track_start_msf[1];
1266 params[3] = sony_toc->tracks[track_idx].track_start_msf[2];
1267 /*
1268 * If we want to stop after the last track, use the lead-out
1269 * MSF to do that.
1270 */
1271 if (bcd_to_int(sony_toc->last_track_num) <= ti.cdti_trk1) {
1272 log_to_msf(msf_to_log(sony_toc->lead_out_start_msf) - 1,
1273 &(params[4]));
1274 } else {
1275 track_idx = find_track(int_to_bcd(ti.cdti_trk1 + 1));
1276 if (track_idx < 0)
1277 return -EINVAL;
1278 log_to_msf(msf_to_log(sony_toc->tracks[track_idx].track_start_msf) - 1,
1279 &(params[4]));
1280 }
1281 params[0] = 0x03;
1282
1283 spin_up_drive(status);
1284
1285 set_drive_mode(SONY535_AUDIO_DRIVE_MODE, status);
1286
1287 /* Start the drive at the saved position. */
1288 cmd_buff[0] = SONY535_PLAY_AUDIO;
1289 cmd_buff[1] = 0; /* play back starting at this address */
1290 cmd_buff[2] = params[1];
1291 cmd_buff[3] = params[2];
1292 cmd_buff[4] = params[3];
1293 cmd_buff[5] = SONY535_PLAY_AUDIO;
1294 cmd_buff[6] = 2; /* set ending address */
1295 cmd_buff[7] = params[4];
1296 cmd_buff[8] = params[5];
1297 cmd_buff[9] = params[6];
1298 if ((do_sony_cmd(cmd_buff, 5, status, NULL, 0, 0) != 0) ||
1299 (do_sony_cmd(cmd_buff + 5, 5, status, NULL, 0, 0) != 0)) {
1300 printk(CDU535_MESSAGE_NAME " error 0x%.2x (CDROMPLAYTRKIND)\n",
1301 status[0]);
1302 printk("... Params: %x %x %x %x %x %x %x\n",
1303 params[0], params[1], params[2],
1304 params[3], params[4], params[5], params[6]);
1305 return -EIO;
1306 }
1307 /* Save the final position for pauses and resumes */
1308 final_pos_msf[0] = params[4];
1309 final_pos_msf[1] = params[5];
1310 final_pos_msf[2] = params[6];
1311 sony_audio_status = CDROM_AUDIO_PLAY;
1312 return 0;
1313 }
1314
1315 case CDROMSUBCHNL: /* Get subchannel info */
1316 return sony_get_subchnl_info(argp);
1317
1318 case CDROMVOLCTRL: /* Volume control. What volume does this change, anyway? */
1319 {
1320 struct cdrom_volctrl volctrl;
1321
1322 if (copy_from_user(&volctrl, argp, sizeof volctrl))
1323 return -EFAULT;
1324 cmd_buff[0] = SONY535_SET_VOLUME;
1325 cmd_buff[1] = volctrl.channel0;
1326 cmd_buff[2] = volctrl.channel1;
1327 if (do_sony_cmd(cmd_buff, 3, status, NULL, 0, 0) != 0) {
1328 printk(CDU535_MESSAGE_NAME " error 0x%.2x (CDROMVOLCTRL)\n",
1329 status[0]);
1330 return -EIO;
1331 }
1332 }
1333 return 0;
1334
1335 case CDROMEJECT: /* Eject the drive */
1336 cmd_buff[0] = SONY535_STOP;
1337 do_sony_cmd(cmd_buff, 1, status, NULL, 0, 0);
1338 cmd_buff[0] = SONY535_SPIN_DOWN;
1339 do_sony_cmd(cmd_buff, 1, status, NULL, 0, 0);
1340
1341 sony_audio_status = CDROM_AUDIO_INVALID;
1342 cmd_buff[0] = SONY535_EJECT_CADDY;
1343 if (do_sony_cmd(cmd_buff, 1, status, NULL, 0, 0) != 0) {
1344 printk(CDU535_MESSAGE_NAME " error 0x%.2x (CDROMEJECT)\n",
1345 status[0]);
1346 return -EIO;
1347 }
1348 return 0;
1349 break;
1350
1351 default:
1352 return -EINVAL;
1353 }
1354}
1355
1356
1357/*
1358 * Open the drive for operations. Spin the drive up and read the table of
1359 * contents if these have not already been done.
1360 */
1361static int
1362cdu_open(struct inode *inode,
1363 struct file *filp)
1364{
1365 Byte status[2], cmd_buff[2];
1366
1367 if (sony_inuse)
1368 return -EBUSY;
1369 if (check_drive_status() != 0)
1370 return -EIO;
1371 sony_inuse = 1;
1372
1373 if (spin_up_drive(status) != 0) {
1374 printk(CDU535_MESSAGE_NAME " error 0x%.2x (cdu_open, spin up)\n",
1375 status[0]);
1376 sony_inuse = 0;
1377 return -EIO;
1378 }
1379 sony_get_toc();
1380 if (!sony_toc_read) {
1381 cmd_buff[0] = SONY535_SPIN_DOWN;
1382 do_sony_cmd(cmd_buff, 1, status, NULL, 0, 0);
1383 sony_inuse = 0;
1384 return -EIO;
1385 }
1386 check_disk_change(inode->i_bdev);
1387 sony_usage++;
1388
1389#ifdef LOCK_DOORS
1390 /* disable the eject button while mounted */
1391 cmd_buff[0] = SONY535_DISABLE_EJECT_BUTTON;
1392 do_sony_cmd(cmd_buff, 1, status, NULL, 0, 0);
1393#endif
1394
1395 return 0;
1396}
1397
1398
1399/*
1400 * Close the drive. Spin it down if no task is using it. The spin
1401 * down will fail if playing audio, so audio play is OK.
1402 */
1403static int
1404cdu_release(struct inode *inode,
1405 struct file *filp)
1406{
1407 Byte status[2], cmd_no;
1408
1409 sony_inuse = 0;
1410
1411 if (0 < sony_usage) {
1412 sony_usage--;
1413 }
1414 if (sony_usage == 0) {
1415 check_drive_status();
1416
1417 if (sony_audio_status != CDROM_AUDIO_PLAY) {
1418 cmd_no = SONY535_SPIN_DOWN;
1419 do_sony_cmd(&cmd_no, 1, status, NULL, 0, 0);
1420 }
1421#ifdef LOCK_DOORS
1422 /* enable the eject button after umount */
1423 cmd_no = SONY535_ENABLE_EJECT_BUTTON;
1424 do_sony_cmd(&cmd_no, 1, status, NULL, 0, 0);
1425#endif
1426 }
1427 return 0;
1428}
1429
1430static struct block_device_operations cdu_fops =
1431{
1432 .owner = THIS_MODULE,
1433 .open = cdu_open,
1434 .release = cdu_release,
1435 .ioctl = cdu_ioctl,
1436 .media_changed = cdu535_check_media_change,
1437};
1438
1439static struct gendisk *cdu_disk;
1440
1441/*
1442 * Initialize the driver.
1443 */
1444static int __init sony535_init(void)
1445{
1446 struct s535_sony_drive_config drive_config;
1447 Byte cmd_buff[3];
1448 Byte ret_buff[2];
1449 Byte status[2];
1450 unsigned long snap;
1451 int got_result = 0;
1452 int tmp_irq;
1453 int i;
1454 int err;
1455
1456 /* Setting the base I/O address to 0 will disable it. */
1457 if ((sony535_cd_base_io == 0xffff)||(sony535_cd_base_io == 0))
1458 return 0;
1459
1460 /* Set up all the register locations */
1461 result_reg = sony535_cd_base_io;
1462 command_reg = sony535_cd_base_io;
1463 data_reg = sony535_cd_base_io + 1;
1464 read_status_reg = sony535_cd_base_io + 2;
1465 select_unit_reg = sony535_cd_base_io + 3;
1466
1467#ifndef USE_IRQ
1468 sony535_irq_used = 0; /* polling only until this is ready... */
1469#endif
1470 /* we need to poll until things get initialized */
1471 tmp_irq = sony535_irq_used;
1472 sony535_irq_used = 0;
1473
1474#if DEBUG > 0
1475 printk(KERN_INFO CDU535_MESSAGE_NAME ": probing base address %03X\n",
1476 sony535_cd_base_io);
1477#endif
1478 /* look for the CD-ROM, follows the procedure in the DOS driver */
1479 inb(select_unit_reg);
1480 /* wait for 40 18 Hz ticks (reverse-engineered from DOS driver) */
1481 schedule_timeout_interruptible((HZ+17)*40/18);
1482 inb(result_reg);
1483
1484 outb(0, read_status_reg); /* does a reset? */
1485 snap = jiffies;
1486 while (jiffies-snap < SONY_JIFFIES_TIMEOUT) {
1487 select_unit(0);
1488 if (inb(result_reg) != 0xff) {
1489 got_result = 1;
1490 break;
1491 }
1492 sony_sleep();
1493 }
1494
1495 if (!got_result || check_drive_status() == TIME_OUT)
1496 goto Enodev;
1497
1498 /* CD-ROM drive responded -- get the drive configuration */
1499 cmd_buff[0] = SONY535_INQUIRY;
1500 if (do_sony_cmd(cmd_buff, 1, status, (Byte *)&drive_config, 28, 1) != 0)
1501 goto Enodev;
1502
1503 /* was able to get the configuration,
1504 * set drive mode as rest of init
1505 */
1506#if DEBUG > 0
1507 /* 0x50 == CADDY_NOT_INSERTED | NOT_SPINNING */
1508 if ( (status[0] & 0x7f) != 0 && (status[0] & 0x7f) != 0x50 )
1509 printk(CDU535_MESSAGE_NAME
1510 "Inquiry command returned status = 0x%x\n", status[0]);
1511#endif
1512 /* now ready to use interrupts, if available */
1513 sony535_irq_used = tmp_irq;
1514
1515 /* A negative sony535_irq_used will attempt an autoirq. */
1516 if (sony535_irq_used < 0) {
1517 unsigned long irq_mask, delay;
1518
1519 irq_mask = probe_irq_on();
1520 enable_interrupts();
1521 outb(0, read_status_reg); /* does a reset? */
1522 delay = jiffies + HZ/10;
1523 while (time_before(jiffies, delay)) ;
1524
1525 sony535_irq_used = probe_irq_off(irq_mask);
1526 disable_interrupts();
1527 }
1528 if (sony535_irq_used > 0) {
1529 if (request_irq(sony535_irq_used, cdu535_interrupt,
1530 IRQF_DISABLED, CDU535_HANDLE, NULL)) {
1531 printk("Unable to grab IRQ%d for the " CDU535_MESSAGE_NAME
1532 " driver; polling instead.\n", sony535_irq_used);
1533 sony535_irq_used = 0;
1534 }
1535 }
1536 cmd_buff[0] = SONY535_SET_DRIVE_MODE;
1537 cmd_buff[1] = 0x0; /* default audio */
1538 if (do_sony_cmd(cmd_buff, 2, status, ret_buff, 1, 1) != 0)
1539 goto Enodev_irq;
1540
1541 /* set the drive mode successful, we are set! */
1542 sony_buffer_size = SONY535_BUFFER_SIZE;
1543 sony_buffer_sectors = sony_buffer_size / CDU535_BLOCK_SIZE;
1544
1545 printk(KERN_INFO CDU535_MESSAGE_NAME " I/F CDROM : %8.8s %16.16s %4.4s",
1546 drive_config.vendor_id,
1547 drive_config.product_id,
1548 drive_config.product_rev_level);
1549 printk(" base address %03X, ", sony535_cd_base_io);
1550 if (tmp_irq > 0)
1551 printk("IRQ%d, ", tmp_irq);
1552 printk("using %d byte buffer\n", sony_buffer_size);
1553
1554 if (register_blkdev(MAJOR_NR, CDU535_HANDLE)) {
1555 err = -EIO;
1556 goto out1;
1557 }
1558 sonycd535_queue = blk_init_queue(do_cdu535_request, &sonycd535_lock);
1559 if (!sonycd535_queue) {
1560 err = -ENOMEM;
1561 goto out1a;
1562 }
1563
1564 blk_queue_hardsect_size(sonycd535_queue, CDU535_BLOCK_SIZE);
1565 sony_toc = kmalloc(sizeof(struct s535_sony_toc), GFP_KERNEL);
1566 err = -ENOMEM;
1567 if (!sony_toc)
1568 goto out2;
1569 last_sony_subcode = kmalloc(sizeof(struct s535_sony_subcode), GFP_KERNEL);
1570 if (!last_sony_subcode)
1571 goto out3;
1572 sony_buffer = kmalloc(sizeof(Byte *) * sony_buffer_sectors, GFP_KERNEL);
1573 if (!sony_buffer)
1574 goto out4;
1575 for (i = 0; i < sony_buffer_sectors; i++) {
1576 sony_buffer[i] = kmalloc(CDU535_BLOCK_SIZE, GFP_KERNEL);
1577 if (!sony_buffer[i]) {
1578 while (--i>=0)
1579 kfree(sony_buffer[i]);
1580 goto out5;
1581 }
1582 }
1583 initialized = 1;
1584
1585 cdu_disk = alloc_disk(1);
1586 if (!cdu_disk)
1587 goto out6;
1588 cdu_disk->major = MAJOR_NR;
1589 cdu_disk->first_minor = 0;
1590 cdu_disk->fops = &cdu_fops;
1591 sprintf(cdu_disk->disk_name, "cdu");
1592
1593 if (!request_region(sony535_cd_base_io, 4, CDU535_HANDLE)) {
1594 printk(KERN_WARNING"sonycd535: Unable to request region 0x%x\n",
1595 sony535_cd_base_io);
1596 goto out7;
1597 }
1598 cdu_disk->queue = sonycd535_queue;
1599 add_disk(cdu_disk);
1600 return 0;
1601
1602out7:
1603 put_disk(cdu_disk);
1604out6:
1605 for (i = 0; i < sony_buffer_sectors; i++)
1606 kfree(sony_buffer[i]);
1607out5:
1608 kfree(sony_buffer);
1609out4:
1610 kfree(last_sony_subcode);
1611out3:
1612 kfree(sony_toc);
1613out2:
1614 blk_cleanup_queue(sonycd535_queue);
1615out1a:
1616 unregister_blkdev(MAJOR_NR, CDU535_HANDLE);
1617out1:
1618 if (sony535_irq_used)
1619 free_irq(sony535_irq_used, NULL);
1620 return err;
1621Enodev_irq:
1622 if (sony535_irq_used)
1623 free_irq(sony535_irq_used, NULL);
1624Enodev:
1625 printk("Did not find a " CDU535_MESSAGE_NAME " drive\n");
1626 return -EIO;
1627}
1628
1629#ifndef MODULE
1630
1631/*
1632 * accept "kernel command line" parameters
1633 * (added by emoenke@gwdg.de)
1634 *
1635 * use: tell LILO:
1636 * sonycd535=0x320
1637 *
1638 * the address value has to be the existing CDROM port address.
1639 */
1640static int __init
1641sonycd535_setup(char *strings)
1642{
1643 int ints[3];
1644 (void)get_options(strings, ARRAY_SIZE(ints), ints);
1645 /* if IRQ change and default io base desired,
1646 * then call with io base of 0
1647 */
1648 if (ints[0] > 0)
1649 if (ints[1] != 0)
1650 sony535_cd_base_io = ints[1];
1651 if (ints[0] > 1)
1652 sony535_irq_used = ints[2];
1653 if ((strings != NULL) && (*strings != '\0'))
1654 printk(CDU535_MESSAGE_NAME
1655 ": Warning: Unknown interface type: %s\n", strings);
1656
1657 return 1;
1658}
1659
1660__setup("sonycd535=", sonycd535_setup);
1661
1662#endif /* MODULE */
1663
1664static void __exit
1665sony535_exit(void)
1666{
1667 int i;
1668
1669 release_region(sony535_cd_base_io, 4);
1670 for (i = 0; i < sony_buffer_sectors; i++)
1671 kfree(sony_buffer[i]);
1672 kfree(sony_buffer);
1673 kfree(last_sony_subcode);
1674 kfree(sony_toc);
1675 del_gendisk(cdu_disk);
1676 put_disk(cdu_disk);
1677 blk_cleanup_queue(sonycd535_queue);
1678 if (unregister_blkdev(MAJOR_NR, CDU535_HANDLE) == -EINVAL)
1679 printk("Uh oh, couldn't unregister " CDU535_HANDLE "\n");
1680 else
1681 printk(KERN_INFO CDU535_HANDLE " module released\n");
1682}
1683
1684module_init(sony535_init);
1685module_exit(sony535_exit);
1686
1687
1688MODULE_LICENSE("GPL");
1689MODULE_ALIAS_BLOCKDEV_MAJOR(CDU535_CDROM_MAJOR);
diff --git a/drivers/cdrom/sonycd535.h b/drivers/cdrom/sonycd535.h
deleted file mode 100644
index 5dea1ef168d6..000000000000
--- a/drivers/cdrom/sonycd535.h
+++ /dev/null
@@ -1,183 +0,0 @@
1#ifndef SONYCD535_H
2#define SONYCD535_H
3
4/*
5 * define all the commands recognized by the CDU-531/5
6 */
7#define SONY535_REQUEST_DRIVE_STATUS_1 (0x80)
8#define SONY535_REQUEST_SENSE (0x82)
9#define SONY535_REQUEST_DRIVE_STATUS_2 (0x84)
10#define SONY535_REQUEST_ERROR_STATUS (0x86)
11#define SONY535_REQUEST_AUDIO_STATUS (0x88)
12#define SONY535_INQUIRY (0x8a)
13
14#define SONY535_SET_INACTIVITY_TIME (0x90)
15
16#define SONY535_SEEK_AND_READ_N_BLOCKS_1 (0xa0)
17#define SONY535_SEEK_AND_READ_N_BLOCKS_2 (0xa4)
18#define SONY535_PLAY_AUDIO (0xa6)
19
20#define SONY535_REQUEST_DISC_CAPACITY (0xb0)
21#define SONY535_REQUEST_TOC_DATA (0xb2)
22#define SONY535_REQUEST_SUB_Q_DATA (0xb4)
23#define SONY535_REQUEST_ISRC (0xb6)
24#define SONY535_REQUEST_UPC_EAN (0xb8)
25
26#define SONY535_SET_DRIVE_MODE (0xc0)
27#define SONY535_REQUEST_DRIVE_MODE (0xc2)
28#define SONY535_SET_RETRY_COUNT (0xc4)
29
30#define SONY535_DIAGNOSTIC_1 (0xc6)
31#define SONY535_DIAGNOSTIC_4 (0xcc)
32#define SONY535_DIAGNOSTIC_5 (0xce)
33
34#define SONY535_EJECT_CADDY (0xd0)
35#define SONY535_DISABLE_EJECT_BUTTON (0xd2)
36#define SONY535_ENABLE_EJECT_BUTTON (0xd4)
37
38#define SONY535_HOLD (0xe0)
39#define SONY535_AUDIO_PAUSE_ON_OFF (0xe2)
40#define SONY535_SET_VOLUME (0xe8)
41
42#define SONY535_STOP (0xf0)
43#define SONY535_SPIN_UP (0xf2)
44#define SONY535_SPIN_DOWN (0xf4)
45
46#define SONY535_CLEAR_PARAMETERS (0xf6)
47#define SONY535_CLEAR_ENDING_ADDRESS (0xf8)
48
49/*
50 * define some masks
51 */
52#define SONY535_DATA_NOT_READY_BIT (0x1)
53#define SONY535_RESULT_NOT_READY_BIT (0x2)
54
55/*
56 * drive status 1
57 */
58#define SONY535_STATUS1_COMMAND_ERROR (0x1)
59#define SONY535_STATUS1_DATA_ERROR (0x2)
60#define SONY535_STATUS1_SEEK_ERROR (0x4)
61#define SONY535_STATUS1_DISC_TYPE_ERROR (0x8)
62#define SONY535_STATUS1_NOT_SPINNING (0x10)
63#define SONY535_STATUS1_EJECT_BUTTON_PRESSED (0x20)
64#define SONY535_STATUS1_CADDY_NOT_INSERTED (0x40)
65#define SONY535_STATUS1_BYTE_TWO_FOLLOWS (0x80)
66
67/*
68 * drive status 2
69 */
70#define SONY535_CDD_LOADING_ERROR (0x7)
71#define SONY535_CDD_NO_DISC (0x8)
72#define SONY535_CDD_UNLOADING_ERROR (0x9)
73#define SONY535_CDD_CADDY_NOT_INSERTED (0xd)
74#define SONY535_ATN_RESET_OCCURRED (0x2)
75#define SONY535_ATN_DISC_CHANGED (0x4)
76#define SONY535_ATN_RESET_AND_DISC_CHANGED (0x6)
77#define SONY535_ATN_EJECT_IN_PROGRESS (0xe)
78#define SONY535_ATN_BUSY (0xf)
79
80/*
81 * define some parameters
82 */
83#define SONY535_AUDIO_DRIVE_MODE (0)
84#define SONY535_CDROM_DRIVE_MODE (0xe0)
85
86#define SONY535_PLAY_OP_PLAYBACK (0)
87#define SONY535_PLAY_OP_ENTER_HOLD (1)
88#define SONY535_PLAY_OP_SET_AUDIO_ENDING_ADDR (2)
89#define SONY535_PLAY_OP_SCAN_FORWARD (3)
90#define SONY535_PLAY_OP_SCAN_BACKWARD (4)
91
92/*
93 * convert from msf format to block number
94 */
95#define SONY_BLOCK_NUMBER(m,s,f) (((m)*60L+(s))*75L+(f))
96#define SONY_BLOCK_NUMBER_MSF(x) (((x)[0]*60L+(x)[1])*75L+(x)[2])
97
98/*
99 * error return values from the doSonyCmd() routines
100 */
101#define TIME_OUT (-1)
102#define NO_CDROM (-2)
103#define BAD_STATUS (-3)
104#define CD_BUSY (-4)
105#define NOT_DATA_CD (-5)
106#define NO_ROOM (-6)
107
108#define LOG_START_OFFSET 150 /* Offset of first logical sector */
109
110#define SONY_JIFFIES_TIMEOUT (5*HZ) /* Maximum time
111 the drive will wait/try for an
112 operation */
113#define SONY_READY_RETRIES (50000) /* How many times to retry a
114 spin waiting for a register
115 to come ready */
116#define SONY535_FAST_POLLS (10000) /* how many times recheck
117 status waiting for a data
118 to become ready */
119
120typedef unsigned char Byte;
121
122/*
123 * This is the complete status returned from the drive configuration request
124 * command.
125 */
126struct s535_sony_drive_config
127{
128 char vendor_id[8];
129 char product_id[16];
130 char product_rev_level[4];
131};
132
133/* The following is returned from the request sub-q data command */
134struct s535_sony_subcode
135{
136 unsigned char address :4;
137 unsigned char control :4;
138 unsigned char track_num;
139 unsigned char index_num;
140 unsigned char rel_msf[3];
141 unsigned char abs_msf[3];
142};
143
144struct s535_sony_disc_capacity
145{
146 Byte mFirstTrack, sFirstTrack, fFirstTrack;
147 Byte mLeadOut, sLeadOut, fLeadOut;
148};
149
150/*
151 * The following is returned from the request TOC (Table Of Contents) command.
152 * (last_track_num-first_track_num+1) values are valid in tracks.
153 */
154struct s535_sony_toc
155{
156 unsigned char reserved0 :4;
157 unsigned char control0 :4;
158 unsigned char point0;
159 unsigned char first_track_num;
160 unsigned char reserved0a;
161 unsigned char reserved0b;
162 unsigned char reserved1 :4;
163 unsigned char control1 :4;
164 unsigned char point1;
165 unsigned char last_track_num;
166 unsigned char dummy1;
167 unsigned char dummy2;
168 unsigned char reserved2 :4;
169 unsigned char control2 :4;
170 unsigned char point2;
171 unsigned char lead_out_start_msf[3];
172 struct
173 {
174 unsigned char reserved :4;
175 unsigned char control :4;
176 unsigned char track;
177 unsigned char track_start_msf[3];
178 } tracks[100];
179
180 unsigned int lead_out_start_lba;
181};
182
183#endif /* SONYCD535_H */