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authorDean Nelson <dcn@sgi.com>2005-03-23 21:50:00 -0500
committerTony Luck <tony.luck@intel.com>2005-05-03 15:36:00 -0400
commit89eb8eb927e324366c3ac0458998aaf9953fc5cd (patch)
treec5f77d88bc42821134de6ea49a5663654df38e56 /arch/ia64/sn
parent21223a9e78050919499d3d9039170e608eb939cc (diff)
[IA64-SGI] SGI Altix cross partition functionality [2/3]
This patch contains the communication module (XPC) for cross partition communication on a partitioned SGI Altix. Signed-off-by: Dean Nelson <dcn@sgi.com> Signed-off-by: Tony Luck <tony.luck@intel.com>
Diffstat (limited to 'arch/ia64/sn')
-rw-r--r--arch/ia64/sn/kernel/Makefile2
-rw-r--r--arch/ia64/sn/kernel/xpc.h991
-rw-r--r--arch/ia64/sn/kernel/xpc_channel.c2297
-rw-r--r--arch/ia64/sn/kernel/xpc_main.c1064
-rw-r--r--arch/ia64/sn/kernel/xpc_partition.c971
5 files changed, 5325 insertions, 0 deletions
diff --git a/arch/ia64/sn/kernel/Makefile b/arch/ia64/sn/kernel/Makefile
index b1a4a23086b9..6959736eadea 100644
--- a/arch/ia64/sn/kernel/Makefile
+++ b/arch/ia64/sn/kernel/Makefile
@@ -13,3 +13,5 @@ obj-$(CONFIG_IA64_GENERIC) += machvec.o
13obj-$(CONFIG_SGI_TIOCX) += tiocx.o 13obj-$(CONFIG_SGI_TIOCX) += tiocx.o
14obj-$(CONFIG_IA64_SGI_SN_XP) += xp.o 14obj-$(CONFIG_IA64_SGI_SN_XP) += xp.o
15xp-y := xp_main.o xp_nofault.o 15xp-y := xp_main.o xp_nofault.o
16obj-$(CONFIG_IA64_SGI_SN_XP) += xpc.o
17xpc-y := xpc_main.o xpc_channel.o xpc_partition.o
diff --git a/arch/ia64/sn/kernel/xpc.h b/arch/ia64/sn/kernel/xpc.h
new file mode 100644
index 000000000000..1a0aed8490d1
--- /dev/null
+++ b/arch/ia64/sn/kernel/xpc.h
@@ -0,0 +1,991 @@
1/*
2 * This file is subject to the terms and conditions of the GNU General Public
3 * License. See the file "COPYING" in the main directory of this archive
4 * for more details.
5 *
6 * Copyright (c) 2004-2005 Silicon Graphics, Inc. All Rights Reserved.
7 */
8
9
10/*
11 * Cross Partition Communication (XPC) structures and macros.
12 */
13
14#ifndef _IA64_SN_KERNEL_XPC_H
15#define _IA64_SN_KERNEL_XPC_H
16
17
18#include <linux/config.h>
19#include <linux/interrupt.h>
20#include <linux/sysctl.h>
21#include <linux/device.h>
22#include <asm/pgtable.h>
23#include <asm/processor.h>
24#include <asm/sn/bte.h>
25#include <asm/sn/clksupport.h>
26#include <asm/sn/addrs.h>
27#include <asm/sn/mspec.h>
28#include <asm/sn/shub_mmr.h>
29#include <asm/sn/xp.h>
30
31
32/*
33 * XPC Version numbers consist of a major and minor number. XPC can always
34 * talk to versions with same major #, and never talk to versions with a
35 * different major #.
36 */
37#define _XPC_VERSION(_maj, _min) (((_maj) << 4) | ((_min) & 0xf))
38#define XPC_VERSION_MAJOR(_v) ((_v) >> 4)
39#define XPC_VERSION_MINOR(_v) ((_v) & 0xf)
40
41
42/*
43 * The next macros define word or bit representations for given
44 * C-brick nasid in either the SAL provided bit array representing
45 * nasids in the partition/machine or the AMO_t array used for
46 * inter-partition initiation communications.
47 *
48 * For SN2 machines, C-Bricks are alway even numbered NASIDs. As
49 * such, some space will be saved by insisting that nasid information
50 * passed from SAL always be packed for C-Bricks and the
51 * cross-partition interrupts use the same packing scheme.
52 */
53#define XPC_NASID_W_INDEX(_n) (((_n) / 64) / 2)
54#define XPC_NASID_B_INDEX(_n) (((_n) / 2) & (64 - 1))
55#define XPC_NASID_IN_ARRAY(_n, _p) ((_p)[XPC_NASID_W_INDEX(_n)] & \
56 (1UL << XPC_NASID_B_INDEX(_n)))
57#define XPC_NASID_FROM_W_B(_w, _b) (((_w) * 64 + (_b)) * 2)
58
59#define XPC_HB_DEFAULT_INTERVAL 5 /* incr HB every x secs */
60#define XPC_HB_CHECK_DEFAULT_TIMEOUT 20 /* check HB every x secs */
61
62/* define the process name of HB checker and the CPU it is pinned to */
63#define XPC_HB_CHECK_THREAD_NAME "xpc_hb"
64#define XPC_HB_CHECK_CPU 0
65
66/* define the process name of the discovery thread */
67#define XPC_DISCOVERY_THREAD_NAME "xpc_discovery"
68
69
70#define XPC_HB_ALLOWED(_p, _v) ((_v)->heartbeating_to_mask & (1UL << (_p)))
71#define XPC_ALLOW_HB(_p, _v) (_v)->heartbeating_to_mask |= (1UL << (_p))
72#define XPC_DISALLOW_HB(_p, _v) (_v)->heartbeating_to_mask &= (~(1UL << (_p)))
73
74
75/*
76 * Reserved Page provided by SAL.
77 *
78 * SAL provides one page per partition of reserved memory. When SAL
79 * initialization is complete, SAL_signature, SAL_version, partid,
80 * part_nasids, and mach_nasids are set.
81 *
82 * Note: Until vars_pa is set, the partition XPC code has not been initialized.
83 */
84struct xpc_rsvd_page {
85 u64 SAL_signature; /* SAL unique signature */
86 u64 SAL_version; /* SAL specified version */
87 u8 partid; /* partition ID from SAL */
88 u8 version;
89 u8 pad[6]; /* pad to u64 align */
90 u64 vars_pa;
91 u64 part_nasids[XP_NASID_MASK_WORDS] ____cacheline_aligned;
92 u64 mach_nasids[XP_NASID_MASK_WORDS] ____cacheline_aligned;
93};
94#define XPC_RP_VERSION _XPC_VERSION(1,0) /* version 1.0 of the reserved page */
95
96#define XPC_RSVD_PAGE_ALIGNED_SIZE \
97 (L1_CACHE_ALIGN(sizeof(struct xpc_rsvd_page)))
98
99
100/*
101 * Define the structures by which XPC variables can be exported to other
102 * partitions. (There are two: struct xpc_vars and struct xpc_vars_part)
103 */
104
105/*
106 * The following structure describes the partition generic variables
107 * needed by other partitions in order to properly initialize.
108 *
109 * struct xpc_vars version number also applies to struct xpc_vars_part.
110 * Changes to either structure and/or related functionality should be
111 * reflected by incrementing either the major or minor version numbers
112 * of struct xpc_vars.
113 */
114struct xpc_vars {
115 u8 version;
116 u64 heartbeat;
117 u64 heartbeating_to_mask;
118 u64 kdb_status; /* 0 = machine running */
119 int act_nasid;
120 int act_phys_cpuid;
121 u64 vars_part_pa;
122 u64 amos_page_pa; /* paddr of page of AMOs from MSPEC driver */
123 AMO_t *amos_page; /* vaddr of page of AMOs from MSPEC driver */
124 AMO_t *act_amos; /* pointer to the first activation AMO */
125};
126#define XPC_V_VERSION _XPC_VERSION(3,0) /* version 3.0 of the cross vars */
127
128#define XPC_VARS_ALIGNED_SIZE (L1_CACHE_ALIGN(sizeof(struct xpc_vars)))
129
130/*
131 * The following structure describes the per partition specific variables.
132 *
133 * An array of these structures, one per partition, will be defined. As a
134 * partition becomes active XPC will copy the array entry corresponding to
135 * itself from that partition. It is desirable that the size of this
136 * structure evenly divide into a cacheline, such that none of the entries
137 * in this array crosses a cacheline boundary. As it is now, each entry
138 * occupies half a cacheline.
139 */
140struct xpc_vars_part {
141 u64 magic;
142
143 u64 openclose_args_pa; /* physical address of open and close args */
144 u64 GPs_pa; /* physical address of Get/Put values */
145
146 u64 IPI_amo_pa; /* physical address of IPI AMO_t structure */
147 int IPI_nasid; /* nasid of where to send IPIs */
148 int IPI_phys_cpuid; /* physical CPU ID of where to send IPIs */
149
150 u8 nchannels; /* #of defined channels supported */
151
152 u8 reserved[23]; /* pad to a full 64 bytes */
153};
154
155/*
156 * The vars_part MAGIC numbers play a part in the first contact protocol.
157 *
158 * MAGIC1 indicates that the per partition specific variables for a remote
159 * partition have been initialized by this partition.
160 *
161 * MAGIC2 indicates that this partition has pulled the remote partititions
162 * per partition variables that pertain to this partition.
163 */
164#define XPC_VP_MAGIC1 0x0053524156435058L /* 'XPCVARS\0'L (little endian) */
165#define XPC_VP_MAGIC2 0x0073726176435058L /* 'XPCvars\0'L (little endian) */
166
167
168
169/*
170 * Functions registered by add_timer() or called by kernel_thread() only
171 * allow for a single 64-bit argument. The following macros can be used to
172 * pack and unpack two (32-bit, 16-bit or 8-bit) arguments into or out from
173 * the passed argument.
174 */
175#define XPC_PACK_ARGS(_arg1, _arg2) \
176 ((((u64) _arg1) & 0xffffffff) | \
177 ((((u64) _arg2) & 0xffffffff) << 32))
178
179#define XPC_UNPACK_ARG1(_args) (((u64) _args) & 0xffffffff)
180#define XPC_UNPACK_ARG2(_args) ((((u64) _args) >> 32) & 0xffffffff)
181
182
183
184/*
185 * Define a Get/Put value pair (pointers) used with a message queue.
186 */
187struct xpc_gp {
188 s64 get; /* Get value */
189 s64 put; /* Put value */
190};
191
192#define XPC_GP_SIZE \
193 L1_CACHE_ALIGN(sizeof(struct xpc_gp) * XPC_NCHANNELS)
194
195
196
197/*
198 * Define a structure that contains arguments associated with opening and
199 * closing a channel.
200 */
201struct xpc_openclose_args {
202 u16 reason; /* reason why channel is closing */
203 u16 msg_size; /* sizeof each message entry */
204 u16 remote_nentries; /* #of message entries in remote msg queue */
205 u16 local_nentries; /* #of message entries in local msg queue */
206 u64 local_msgqueue_pa; /* physical address of local message queue */
207};
208
209#define XPC_OPENCLOSE_ARGS_SIZE \
210 L1_CACHE_ALIGN(sizeof(struct xpc_openclose_args) * XPC_NCHANNELS)
211
212
213
214/* struct xpc_msg flags */
215
216#define XPC_M_DONE 0x01 /* msg has been received/consumed */
217#define XPC_M_READY 0x02 /* msg is ready to be sent */
218#define XPC_M_INTERRUPT 0x04 /* send interrupt when msg consumed */
219
220
221#define XPC_MSG_ADDRESS(_payload) \
222 ((struct xpc_msg *)((u8 *)(_payload) - XPC_MSG_PAYLOAD_OFFSET))
223
224
225
226/*
227 * Defines notify entry.
228 *
229 * This is used to notify a message's sender that their message was received
230 * and consumed by the intended recipient.
231 */
232struct xpc_notify {
233 struct semaphore sema; /* notify semaphore */
234 u8 type; /* type of notification */
235
236 /* the following two fields are only used if type == XPC_N_CALL */
237 xpc_notify_func func; /* user's notify function */
238 void *key; /* pointer to user's key */
239};
240
241/* struct xpc_notify type of notification */
242
243#define XPC_N_CALL 0x01 /* notify function provided by user */
244
245
246
247/*
248 * Define the structure that manages all the stuff required by a channel. In
249 * particular, they are used to manage the messages sent across the channel.
250 *
251 * This structure is private to a partition, and is NOT shared across the
252 * partition boundary.
253 *
254 * There is an array of these structures for each remote partition. It is
255 * allocated at the time a partition becomes active. The array contains one
256 * of these structures for each potential channel connection to that partition.
257 *
258 * Each of these structures manages two message queues (circular buffers).
259 * They are allocated at the time a channel connection is made. One of
260 * these message queues (local_msgqueue) holds the locally created messages
261 * that are destined for the remote partition. The other of these message
262 * queues (remote_msgqueue) is a locally cached copy of the remote partition's
263 * own local_msgqueue.
264 *
265 * The following is a description of the Get/Put pointers used to manage these
266 * two message queues. Consider the local_msgqueue to be on one partition
267 * and the remote_msgqueue to be its cached copy on another partition. A
268 * description of what each of the lettered areas contains is included.
269 *
270 *
271 * local_msgqueue remote_msgqueue
272 *
273 * |/////////| |/////////|
274 * w_remote_GP.get --> +---------+ |/////////|
275 * | F | |/////////|
276 * remote_GP.get --> +---------+ +---------+ <-- local_GP->get
277 * | | | |
278 * | | | E |
279 * | | | |
280 * | | +---------+ <-- w_local_GP.get
281 * | B | |/////////|
282 * | | |////D////|
283 * | | |/////////|
284 * | | +---------+ <-- w_remote_GP.put
285 * | | |////C////|
286 * local_GP->put --> +---------+ +---------+ <-- remote_GP.put
287 * | | |/////////|
288 * | A | |/////////|
289 * | | |/////////|
290 * w_local_GP.put --> +---------+ |/////////|
291 * |/////////| |/////////|
292 *
293 *
294 * ( remote_GP.[get|put] are cached copies of the remote
295 * partition's local_GP->[get|put], and thus their values can
296 * lag behind their counterparts on the remote partition. )
297 *
298 *
299 * A - Messages that have been allocated, but have not yet been sent to the
300 * remote partition.
301 *
302 * B - Messages that have been sent, but have not yet been acknowledged by the
303 * remote partition as having been received.
304 *
305 * C - Area that needs to be prepared for the copying of sent messages, by
306 * the clearing of the message flags of any previously received messages.
307 *
308 * D - Area into which sent messages are to be copied from the remote
309 * partition's local_msgqueue and then delivered to their intended
310 * recipients. [ To allow for a multi-message copy, another pointer
311 * (next_msg_to_pull) has been added to keep track of the next message
312 * number needing to be copied (pulled). It chases after w_remote_GP.put.
313 * Any messages lying between w_local_GP.get and next_msg_to_pull have
314 * been copied and are ready to be delivered. ]
315 *
316 * E - Messages that have been copied and delivered, but have not yet been
317 * acknowledged by the recipient as having been received.
318 *
319 * F - Messages that have been acknowledged, but XPC has not yet notified the
320 * sender that the message was received by its intended recipient.
321 * This is also an area that needs to be prepared for the allocating of
322 * new messages, by the clearing of the message flags of the acknowledged
323 * messages.
324 */
325struct xpc_channel {
326 partid_t partid; /* ID of remote partition connected */
327 spinlock_t lock; /* lock for updating this structure */
328 u32 flags; /* general flags */
329
330 enum xpc_retval reason; /* reason why channel is disconnect'g */
331 int reason_line; /* line# disconnect initiated from */
332
333 u16 number; /* channel # */
334
335 u16 msg_size; /* sizeof each msg entry */
336 u16 local_nentries; /* #of msg entries in local msg queue */
337 u16 remote_nentries; /* #of msg entries in remote msg queue*/
338
339 void *local_msgqueue_base; /* base address of kmalloc'd space */
340 struct xpc_msg *local_msgqueue; /* local message queue */
341 void *remote_msgqueue_base; /* base address of kmalloc'd space */
342 struct xpc_msg *remote_msgqueue;/* cached copy of remote partition's */
343 /* local message queue */
344 u64 remote_msgqueue_pa; /* phys addr of remote partition's */
345 /* local message queue */
346
347 atomic_t references; /* #of external references to queues */
348
349 atomic_t n_on_msg_allocate_wq; /* #on msg allocation wait queue */
350 wait_queue_head_t msg_allocate_wq; /* msg allocation wait queue */
351
352 /* queue of msg senders who want to be notified when msg received */
353
354 atomic_t n_to_notify; /* #of msg senders to notify */
355 struct xpc_notify *notify_queue;/* notify queue for messages sent */
356
357 xpc_channel_func func; /* user's channel function */
358 void *key; /* pointer to user's key */
359
360 struct semaphore msg_to_pull_sema; /* next msg to pull serialization */
361 struct semaphore teardown_sema; /* wait for teardown completion */
362
363 struct xpc_openclose_args *local_openclose_args; /* args passed on */
364 /* opening or closing of channel */
365
366 /* various flavors of local and remote Get/Put values */
367
368 struct xpc_gp *local_GP; /* local Get/Put values */
369 struct xpc_gp remote_GP; /* remote Get/Put values */
370 struct xpc_gp w_local_GP; /* working local Get/Put values */
371 struct xpc_gp w_remote_GP; /* working remote Get/Put values */
372 s64 next_msg_to_pull; /* Put value of next msg to pull */
373
374 /* kthread management related fields */
375
376// >>> rethink having kthreads_assigned_limit and kthreads_idle_limit; perhaps
377// >>> allow the assigned limit be unbounded and let the idle limit be dynamic
378// >>> dependent on activity over the last interval of time
379 atomic_t kthreads_assigned; /* #of kthreads assigned to channel */
380 u32 kthreads_assigned_limit; /* limit on #of kthreads assigned */
381 atomic_t kthreads_idle; /* #of kthreads idle waiting for work */
382 u32 kthreads_idle_limit; /* limit on #of kthreads idle */
383 atomic_t kthreads_active; /* #of kthreads actively working */
384 // >>> following field is temporary
385 u32 kthreads_created; /* total #of kthreads created */
386
387 wait_queue_head_t idle_wq; /* idle kthread wait queue */
388
389} ____cacheline_aligned;
390
391
392/* struct xpc_channel flags */
393
394#define XPC_C_WASCONNECTED 0x00000001 /* channel was connected */
395
396#define XPC_C_ROPENREPLY 0x00000002 /* remote open channel reply */
397#define XPC_C_OPENREPLY 0x00000004 /* local open channel reply */
398#define XPC_C_ROPENREQUEST 0x00000008 /* remote open channel request */
399#define XPC_C_OPENREQUEST 0x00000010 /* local open channel request */
400
401#define XPC_C_SETUP 0x00000020 /* channel's msgqueues are alloc'd */
402#define XPC_C_CONNECTCALLOUT 0x00000040 /* channel connected callout made */
403#define XPC_C_CONNECTED 0x00000080 /* local channel is connected */
404#define XPC_C_CONNECTING 0x00000100 /* channel is being connected */
405
406#define XPC_C_RCLOSEREPLY 0x00000200 /* remote close channel reply */
407#define XPC_C_CLOSEREPLY 0x00000400 /* local close channel reply */
408#define XPC_C_RCLOSEREQUEST 0x00000800 /* remote close channel request */
409#define XPC_C_CLOSEREQUEST 0x00001000 /* local close channel request */
410
411#define XPC_C_DISCONNECTED 0x00002000 /* channel is disconnected */
412#define XPC_C_DISCONNECTING 0x00004000 /* channel is being disconnected */
413
414
415
416/*
417 * Manages channels on a partition basis. There is one of these structures
418 * for each partition (a partition will never utilize the structure that
419 * represents itself).
420 */
421struct xpc_partition {
422
423 /* XPC HB infrastructure */
424
425 u64 remote_rp_pa; /* phys addr of partition's rsvd pg */
426 u64 remote_vars_pa; /* phys addr of partition's vars */
427 u64 remote_vars_part_pa; /* phys addr of partition's vars part */
428 u64 last_heartbeat; /* HB at last read */
429 u64 remote_amos_page_pa; /* phys addr of partition's amos page */
430 int remote_act_nasid; /* active part's act/deact nasid */
431 int remote_act_phys_cpuid; /* active part's act/deact phys cpuid */
432 u32 act_IRQ_rcvd; /* IRQs since activation */
433 spinlock_t act_lock; /* protect updating of act_state */
434 u8 act_state; /* from XPC HB viewpoint */
435 enum xpc_retval reason; /* reason partition is deactivating */
436 int reason_line; /* line# deactivation initiated from */
437 int reactivate_nasid; /* nasid in partition to reactivate */
438
439
440 /* XPC infrastructure referencing and teardown control */
441
442 u8 setup_state; /* infrastructure setup state */
443 wait_queue_head_t teardown_wq; /* kthread waiting to teardown infra */
444 atomic_t references; /* #of references to infrastructure */
445
446
447 /*
448 * NONE OF THE PRECEDING FIELDS OF THIS STRUCTURE WILL BE CLEARED WHEN
449 * XPC SETS UP THE NECESSARY INFRASTRUCTURE TO SUPPORT CROSS PARTITION
450 * COMMUNICATION. ALL OF THE FOLLOWING FIELDS WILL BE CLEARED. (THE
451 * 'nchannels' FIELD MUST BE THE FIRST OF THE FIELDS TO BE CLEARED.)
452 */
453
454
455 u8 nchannels; /* #of defined channels supported */
456 atomic_t nchannels_active; /* #of channels that are not DISCONNECTED */
457 struct xpc_channel *channels;/* array of channel structures */
458
459 void *local_GPs_base; /* base address of kmalloc'd space */
460 struct xpc_gp *local_GPs; /* local Get/Put values */
461 void *remote_GPs_base; /* base address of kmalloc'd space */
462 struct xpc_gp *remote_GPs;/* copy of remote partition's local Get/Put */
463 /* values */
464 u64 remote_GPs_pa; /* phys address of remote partition's local */
465 /* Get/Put values */
466
467
468 /* fields used to pass args when opening or closing a channel */
469
470 void *local_openclose_args_base; /* base address of kmalloc'd space */
471 struct xpc_openclose_args *local_openclose_args; /* local's args */
472 void *remote_openclose_args_base; /* base address of kmalloc'd space */
473 struct xpc_openclose_args *remote_openclose_args; /* copy of remote's */
474 /* args */
475 u64 remote_openclose_args_pa; /* phys addr of remote's args */
476
477
478 /* IPI sending, receiving and handling related fields */
479
480 int remote_IPI_nasid; /* nasid of where to send IPIs */
481 int remote_IPI_phys_cpuid; /* phys CPU ID of where to send IPIs */
482 AMO_t *remote_IPI_amo_va; /* address of remote IPI AMO_t structure */
483
484 AMO_t *local_IPI_amo_va; /* address of IPI AMO_t structure */
485 u64 local_IPI_amo; /* IPI amo flags yet to be handled */
486 char IPI_owner[8]; /* IPI owner's name */
487 struct timer_list dropped_IPI_timer; /* dropped IPI timer */
488
489 spinlock_t IPI_lock; /* IPI handler lock */
490
491
492 /* channel manager related fields */
493
494 atomic_t channel_mgr_requests; /* #of requests to activate chan mgr */
495 wait_queue_head_t channel_mgr_wq; /* channel mgr's wait queue */
496
497} ____cacheline_aligned;
498
499
500/* struct xpc_partition act_state values (for XPC HB) */
501
502#define XPC_P_INACTIVE 0x00 /* partition is not active */
503#define XPC_P_ACTIVATION_REQ 0x01 /* created thread to activate */
504#define XPC_P_ACTIVATING 0x02 /* activation thread started */
505#define XPC_P_ACTIVE 0x03 /* xpc_partition_up() was called */
506#define XPC_P_DEACTIVATING 0x04 /* partition deactivation initiated */
507
508
509#define XPC_DEACTIVATE_PARTITION(_p, _reason) \
510 xpc_deactivate_partition(__LINE__, (_p), (_reason))
511
512
513/* struct xpc_partition setup_state values */
514
515#define XPC_P_UNSET 0x00 /* infrastructure was never setup */
516#define XPC_P_SETUP 0x01 /* infrastructure is setup */
517#define XPC_P_WTEARDOWN 0x02 /* waiting to teardown infrastructure */
518#define XPC_P_TORNDOWN 0x03 /* infrastructure is torndown */
519
520
521/*
522 * struct xpc_partition IPI_timer #of seconds to wait before checking for
523 * dropped IPIs. These occur whenever an IPI amo write doesn't complete until
524 * after the IPI was received.
525 */
526#define XPC_P_DROPPED_IPI_WAIT (0.25 * HZ)
527
528
529#define XPC_PARTID(_p) ((partid_t) ((_p) - &xpc_partitions[0]))
530
531
532
533/* found in xp_main.c */
534extern struct xpc_registration xpc_registrations[];
535
536
537/* >>> found in xpc_main.c only */
538extern struct device *xpc_part;
539extern struct device *xpc_chan;
540extern irqreturn_t xpc_notify_IRQ_handler(int, void *, struct pt_regs *);
541extern void xpc_dropped_IPI_check(struct xpc_partition *);
542extern void xpc_activate_kthreads(struct xpc_channel *, int);
543extern void xpc_create_kthreads(struct xpc_channel *, int);
544extern void xpc_disconnect_wait(int);
545
546
547/* found in xpc_main.c and efi-xpc.c */
548extern void xpc_activate_partition(struct xpc_partition *);
549
550
551/* found in xpc_partition.c */
552extern int xpc_exiting;
553extern int xpc_hb_interval;
554extern int xpc_hb_check_interval;
555extern struct xpc_vars *xpc_vars;
556extern struct xpc_rsvd_page *xpc_rsvd_page;
557extern struct xpc_vars_part *xpc_vars_part;
558extern struct xpc_partition xpc_partitions[XP_MAX_PARTITIONS + 1];
559extern char xpc_remote_copy_buffer[];
560extern struct xpc_rsvd_page *xpc_rsvd_page_init(void);
561extern void xpc_allow_IPI_ops(void);
562extern void xpc_restrict_IPI_ops(void);
563extern int xpc_identify_act_IRQ_sender(void);
564extern enum xpc_retval xpc_mark_partition_active(struct xpc_partition *);
565extern void xpc_mark_partition_inactive(struct xpc_partition *);
566extern void xpc_discovery(void);
567extern void xpc_check_remote_hb(void);
568extern void xpc_deactivate_partition(const int, struct xpc_partition *,
569 enum xpc_retval);
570extern enum xpc_retval xpc_initiate_partid_to_nasids(partid_t, void *);
571
572
573/* found in xpc_channel.c */
574extern void xpc_initiate_connect(int);
575extern void xpc_initiate_disconnect(int);
576extern enum xpc_retval xpc_initiate_allocate(partid_t, int, u32, void **);
577extern enum xpc_retval xpc_initiate_send(partid_t, int, void *);
578extern enum xpc_retval xpc_initiate_send_notify(partid_t, int, void *,
579 xpc_notify_func, void *);
580extern void xpc_initiate_received(partid_t, int, void *);
581extern enum xpc_retval xpc_setup_infrastructure(struct xpc_partition *);
582extern enum xpc_retval xpc_pull_remote_vars_part(struct xpc_partition *);
583extern void xpc_process_channel_activity(struct xpc_partition *);
584extern void xpc_connected_callout(struct xpc_channel *);
585extern void xpc_deliver_msg(struct xpc_channel *);
586extern void xpc_disconnect_channel(const int, struct xpc_channel *,
587 enum xpc_retval, unsigned long *);
588extern void xpc_disconnected_callout(struct xpc_channel *);
589extern void xpc_partition_down(struct xpc_partition *, enum xpc_retval);
590extern void xpc_teardown_infrastructure(struct xpc_partition *);
591
592
593
594static inline void
595xpc_wakeup_channel_mgr(struct xpc_partition *part)
596{
597 if (atomic_inc_return(&part->channel_mgr_requests) == 1) {
598 wake_up(&part->channel_mgr_wq);
599 }
600}
601
602
603
604/*
605 * These next two inlines are used to keep us from tearing down a channel's
606 * msg queues while a thread may be referencing them.
607 */
608static inline void
609xpc_msgqueue_ref(struct xpc_channel *ch)
610{
611 atomic_inc(&ch->references);
612}
613
614static inline void
615xpc_msgqueue_deref(struct xpc_channel *ch)
616{
617 s32 refs = atomic_dec_return(&ch->references);
618
619 DBUG_ON(refs < 0);
620 if (refs == 0) {
621 xpc_wakeup_channel_mgr(&xpc_partitions[ch->partid]);
622 }
623}
624
625
626
627#define XPC_DISCONNECT_CHANNEL(_ch, _reason, _irqflgs) \
628 xpc_disconnect_channel(__LINE__, _ch, _reason, _irqflgs)
629
630
631/*
632 * These two inlines are used to keep us from tearing down a partition's
633 * setup infrastructure while a thread may be referencing it.
634 */
635static inline void
636xpc_part_deref(struct xpc_partition *part)
637{
638 s32 refs = atomic_dec_return(&part->references);
639
640
641 DBUG_ON(refs < 0);
642 if (refs == 0 && part->setup_state == XPC_P_WTEARDOWN) {
643 wake_up(&part->teardown_wq);
644 }
645}
646
647static inline int
648xpc_part_ref(struct xpc_partition *part)
649{
650 int setup;
651
652
653 atomic_inc(&part->references);
654 setup = (part->setup_state == XPC_P_SETUP);
655 if (!setup) {
656 xpc_part_deref(part);
657 }
658 return setup;
659}
660
661
662
663/*
664 * The following macro is to be used for the setting of the reason and
665 * reason_line fields in both the struct xpc_channel and struct xpc_partition
666 * structures.
667 */
668#define XPC_SET_REASON(_p, _reason, _line) \
669 { \
670 (_p)->reason = _reason; \
671 (_p)->reason_line = _line; \
672 }
673
674
675
676/*
677 * The following set of macros and inlines are used for the sending and
678 * receiving of IPIs (also known as IRQs). There are two flavors of IPIs,
679 * one that is associated with partition activity (SGI_XPC_ACTIVATE) and
680 * the other that is associated with channel activity (SGI_XPC_NOTIFY).
681 */
682
683static inline u64
684xpc_IPI_receive(AMO_t *amo)
685{
686 return FETCHOP_LOAD_OP(TO_AMO((u64) &amo->variable), FETCHOP_CLEAR);
687}
688
689
690static inline enum xpc_retval
691xpc_IPI_send(AMO_t *amo, u64 flag, int nasid, int phys_cpuid, int vector)
692{
693 int ret = 0;
694 unsigned long irq_flags;
695
696
697 local_irq_save(irq_flags);
698
699 FETCHOP_STORE_OP(TO_AMO((u64) &amo->variable), FETCHOP_OR, flag);
700 sn_send_IPI_phys(nasid, phys_cpuid, vector, 0);
701
702 /*
703 * We must always use the nofault function regardless of whether we
704 * are on a Shub 1.1 system or a Shub 1.2 slice 0xc processor. If we
705 * didn't, we'd never know that the other partition is down and would
706 * keep sending IPIs and AMOs to it until the heartbeat times out.
707 */
708 ret = xp_nofault_PIOR((u64 *) GLOBAL_MMR_ADDR(NASID_GET(&amo->variable),
709 xp_nofault_PIOR_target));
710
711 local_irq_restore(irq_flags);
712
713 return ((ret == 0) ? xpcSuccess : xpcPioReadError);
714}
715
716
717/*
718 * IPIs associated with SGI_XPC_ACTIVATE IRQ.
719 */
720
721/*
722 * Flag the appropriate AMO variable and send an IPI to the specified node.
723 */
724static inline void
725xpc_activate_IRQ_send(u64 amos_page, int from_nasid, int to_nasid,
726 int to_phys_cpuid)
727{
728 int w_index = XPC_NASID_W_INDEX(from_nasid);
729 int b_index = XPC_NASID_B_INDEX(from_nasid);
730 AMO_t *amos = (AMO_t *) __va(amos_page +
731 (XP_MAX_PARTITIONS * sizeof(AMO_t)));
732
733
734 (void) xpc_IPI_send(&amos[w_index], (1UL << b_index), to_nasid,
735 to_phys_cpuid, SGI_XPC_ACTIVATE);
736}
737
738static inline void
739xpc_IPI_send_activate(struct xpc_vars *vars)
740{
741 xpc_activate_IRQ_send(vars->amos_page_pa, cnodeid_to_nasid(0),
742 vars->act_nasid, vars->act_phys_cpuid);
743}
744
745static inline void
746xpc_IPI_send_activated(struct xpc_partition *part)
747{
748 xpc_activate_IRQ_send(part->remote_amos_page_pa, cnodeid_to_nasid(0),
749 part->remote_act_nasid, part->remote_act_phys_cpuid);
750}
751
752static inline void
753xpc_IPI_send_reactivate(struct xpc_partition *part)
754{
755 xpc_activate_IRQ_send(xpc_vars->amos_page_pa, part->reactivate_nasid,
756 xpc_vars->act_nasid, xpc_vars->act_phys_cpuid);
757}
758
759
760/*
761 * IPIs associated with SGI_XPC_NOTIFY IRQ.
762 */
763
764/*
765 * Send an IPI to the remote partition that is associated with the
766 * specified channel.
767 */
768#define XPC_NOTIFY_IRQ_SEND(_ch, _ipi_f, _irq_f) \
769 xpc_notify_IRQ_send(_ch, _ipi_f, #_ipi_f, _irq_f)
770
771static inline void
772xpc_notify_IRQ_send(struct xpc_channel *ch, u8 ipi_flag, char *ipi_flag_string,
773 unsigned long *irq_flags)
774{
775 struct xpc_partition *part = &xpc_partitions[ch->partid];
776 enum xpc_retval ret;
777
778
779 if (likely(part->act_state != XPC_P_DEACTIVATING)) {
780 ret = xpc_IPI_send(part->remote_IPI_amo_va,
781 (u64) ipi_flag << (ch->number * 8),
782 part->remote_IPI_nasid,
783 part->remote_IPI_phys_cpuid,
784 SGI_XPC_NOTIFY);
785 dev_dbg(xpc_chan, "%s sent to partid=%d, channel=%d, ret=%d\n",
786 ipi_flag_string, ch->partid, ch->number, ret);
787 if (unlikely(ret != xpcSuccess)) {
788 if (irq_flags != NULL) {
789 spin_unlock_irqrestore(&ch->lock, *irq_flags);
790 }
791 XPC_DEACTIVATE_PARTITION(part, ret);
792 if (irq_flags != NULL) {
793 spin_lock_irqsave(&ch->lock, *irq_flags);
794 }
795 }
796 }
797}
798
799
800/*
801 * Make it look like the remote partition, which is associated with the
802 * specified channel, sent us an IPI. This faked IPI will be handled
803 * by xpc_dropped_IPI_check().
804 */
805#define XPC_NOTIFY_IRQ_SEND_LOCAL(_ch, _ipi_f) \
806 xpc_notify_IRQ_send_local(_ch, _ipi_f, #_ipi_f)
807
808static inline void
809xpc_notify_IRQ_send_local(struct xpc_channel *ch, u8 ipi_flag,
810 char *ipi_flag_string)
811{
812 struct xpc_partition *part = &xpc_partitions[ch->partid];
813
814
815 FETCHOP_STORE_OP(TO_AMO((u64) &part->local_IPI_amo_va->variable),
816 FETCHOP_OR, ((u64) ipi_flag << (ch->number * 8)));
817 dev_dbg(xpc_chan, "%s sent local from partid=%d, channel=%d\n",
818 ipi_flag_string, ch->partid, ch->number);
819}
820
821
822/*
823 * The sending and receiving of IPIs includes the setting of an AMO variable
824 * to indicate the reason the IPI was sent. The 64-bit variable is divided
825 * up into eight bytes, ordered from right to left. Byte zero pertains to
826 * channel 0, byte one to channel 1, and so on. Each byte is described by
827 * the following IPI flags.
828 */
829
830#define XPC_IPI_CLOSEREQUEST 0x01
831#define XPC_IPI_CLOSEREPLY 0x02
832#define XPC_IPI_OPENREQUEST 0x04
833#define XPC_IPI_OPENREPLY 0x08
834#define XPC_IPI_MSGREQUEST 0x10
835
836
837/* given an AMO variable and a channel#, get its associated IPI flags */
838#define XPC_GET_IPI_FLAGS(_amo, _c) ((u8) (((_amo) >> ((_c) * 8)) & 0xff))
839
840#define XPC_ANY_OPENCLOSE_IPI_FLAGS_SET(_amo) ((_amo) & 0x0f0f0f0f0f0f0f0f)
841#define XPC_ANY_MSG_IPI_FLAGS_SET(_amo) ((_amo) & 0x1010101010101010)
842
843
844static inline void
845xpc_IPI_send_closerequest(struct xpc_channel *ch, unsigned long *irq_flags)
846{
847 struct xpc_openclose_args *args = ch->local_openclose_args;
848
849
850 args->reason = ch->reason;
851
852 XPC_NOTIFY_IRQ_SEND(ch, XPC_IPI_CLOSEREQUEST, irq_flags);
853}
854
855static inline void
856xpc_IPI_send_closereply(struct xpc_channel *ch, unsigned long *irq_flags)
857{
858 XPC_NOTIFY_IRQ_SEND(ch, XPC_IPI_CLOSEREPLY, irq_flags);
859}
860
861static inline void
862xpc_IPI_send_openrequest(struct xpc_channel *ch, unsigned long *irq_flags)
863{
864 struct xpc_openclose_args *args = ch->local_openclose_args;
865
866
867 args->msg_size = ch->msg_size;
868 args->local_nentries = ch->local_nentries;
869
870 XPC_NOTIFY_IRQ_SEND(ch, XPC_IPI_OPENREQUEST, irq_flags);
871}
872
873static inline void
874xpc_IPI_send_openreply(struct xpc_channel *ch, unsigned long *irq_flags)
875{
876 struct xpc_openclose_args *args = ch->local_openclose_args;
877
878
879 args->remote_nentries = ch->remote_nentries;
880 args->local_nentries = ch->local_nentries;
881 args->local_msgqueue_pa = __pa(ch->local_msgqueue);
882
883 XPC_NOTIFY_IRQ_SEND(ch, XPC_IPI_OPENREPLY, irq_flags);
884}
885
886static inline void
887xpc_IPI_send_msgrequest(struct xpc_channel *ch)
888{
889 XPC_NOTIFY_IRQ_SEND(ch, XPC_IPI_MSGREQUEST, NULL);
890}
891
892static inline void
893xpc_IPI_send_local_msgrequest(struct xpc_channel *ch)
894{
895 XPC_NOTIFY_IRQ_SEND_LOCAL(ch, XPC_IPI_MSGREQUEST);
896}
897
898
899/*
900 * Memory for XPC's AMO variables is allocated by the MSPEC driver. These
901 * pages are located in the lowest granule. The lowest granule uses 4k pages
902 * for cached references and an alternate TLB handler to never provide a
903 * cacheable mapping for the entire region. This will prevent speculative
904 * reading of cached copies of our lines from being issued which will cause
905 * a PI FSB Protocol error to be generated by the SHUB. For XPC, we need 64
906 * (XP_MAX_PARTITIONS) AMO variables for message notification (xpc_main.c)
907 * and an additional 16 AMO variables for partition activation (xpc_hb.c).
908 */
909static inline AMO_t *
910xpc_IPI_init(partid_t partid)
911{
912 AMO_t *part_amo = xpc_vars->amos_page + partid;
913
914
915 xpc_IPI_receive(part_amo);
916 return part_amo;
917}
918
919
920
921static inline enum xpc_retval
922xpc_map_bte_errors(bte_result_t error)
923{
924 switch (error) {
925 case BTE_SUCCESS: return xpcSuccess;
926 case BTEFAIL_DIR: return xpcBteDirectoryError;
927 case BTEFAIL_POISON: return xpcBtePoisonError;
928 case BTEFAIL_WERR: return xpcBteWriteError;
929 case BTEFAIL_ACCESS: return xpcBteAccessError;
930 case BTEFAIL_PWERR: return xpcBtePWriteError;
931 case BTEFAIL_PRERR: return xpcBtePReadError;
932 case BTEFAIL_TOUT: return xpcBteTimeOutError;
933 case BTEFAIL_XTERR: return xpcBteXtalkError;
934 case BTEFAIL_NOTAVAIL: return xpcBteNotAvailable;
935 default: return xpcBteUnmappedError;
936 }
937}
938
939
940
941static inline void *
942xpc_kmalloc_cacheline_aligned(size_t size, int flags, void **base)
943{
944 /* see if kmalloc will give us cachline aligned memory by default */
945 *base = kmalloc(size, flags);
946 if (*base == NULL) {
947 return NULL;
948 }
949 if ((u64) *base == L1_CACHE_ALIGN((u64) *base)) {
950 return *base;
951 }
952 kfree(*base);
953
954 /* nope, we'll have to do it ourselves */
955 *base = kmalloc(size + L1_CACHE_BYTES, flags);
956 if (*base == NULL) {
957 return NULL;
958 }
959 return (void *) L1_CACHE_ALIGN((u64) *base);
960}
961
962
963/*
964 * Check to see if there is any channel activity to/from the specified
965 * partition.
966 */
967static inline void
968xpc_check_for_channel_activity(struct xpc_partition *part)
969{
970 u64 IPI_amo;
971 unsigned long irq_flags;
972
973
974 IPI_amo = xpc_IPI_receive(part->local_IPI_amo_va);
975 if (IPI_amo == 0) {
976 return;
977 }
978
979 spin_lock_irqsave(&part->IPI_lock, irq_flags);
980 part->local_IPI_amo |= IPI_amo;
981 spin_unlock_irqrestore(&part->IPI_lock, irq_flags);
982
983 dev_dbg(xpc_chan, "received IPI from partid=%d, IPI_amo=0x%lx\n",
984 XPC_PARTID(part), IPI_amo);
985
986 xpc_wakeup_channel_mgr(part);
987}
988
989
990#endif /* _IA64_SN_KERNEL_XPC_H */
991
diff --git a/arch/ia64/sn/kernel/xpc_channel.c b/arch/ia64/sn/kernel/xpc_channel.c
new file mode 100644
index 000000000000..0bf6fbcc46d2
--- /dev/null
+++ b/arch/ia64/sn/kernel/xpc_channel.c
@@ -0,0 +1,2297 @@
1/*
2 * This file is subject to the terms and conditions of the GNU General Public
3 * License. See the file "COPYING" in the main directory of this archive
4 * for more details.
5 *
6 * Copyright (c) 2004-2005 Silicon Graphics, Inc. All Rights Reserved.
7 */
8
9
10/*
11 * Cross Partition Communication (XPC) channel support.
12 *
13 * This is the part of XPC that manages the channels and
14 * sends/receives messages across them to/from other partitions.
15 *
16 */
17
18
19#include <linux/kernel.h>
20#include <linux/init.h>
21#include <linux/sched.h>
22#include <linux/cache.h>
23#include <linux/interrupt.h>
24#include <linux/slab.h>
25#include <asm/sn/bte.h>
26#include <asm/sn/sn_sal.h>
27#include "xpc.h"
28
29
30/*
31 * Set up the initial values for the XPartition Communication channels.
32 */
33static void
34xpc_initialize_channels(struct xpc_partition *part, partid_t partid)
35{
36 int ch_number;
37 struct xpc_channel *ch;
38
39
40 for (ch_number = 0; ch_number < part->nchannels; ch_number++) {
41 ch = &part->channels[ch_number];
42
43 ch->partid = partid;
44 ch->number = ch_number;
45 ch->flags = XPC_C_DISCONNECTED;
46
47 ch->local_GP = &part->local_GPs[ch_number];
48 ch->local_openclose_args =
49 &part->local_openclose_args[ch_number];
50
51 atomic_set(&ch->kthreads_assigned, 0);
52 atomic_set(&ch->kthreads_idle, 0);
53 atomic_set(&ch->kthreads_active, 0);
54
55 atomic_set(&ch->references, 0);
56 atomic_set(&ch->n_to_notify, 0);
57
58 spin_lock_init(&ch->lock);
59 sema_init(&ch->msg_to_pull_sema, 1); /* mutex */
60
61 atomic_set(&ch->n_on_msg_allocate_wq, 0);
62 init_waitqueue_head(&ch->msg_allocate_wq);
63 init_waitqueue_head(&ch->idle_wq);
64 }
65}
66
67
68/*
69 * Setup the infrastructure necessary to support XPartition Communication
70 * between the specified remote partition and the local one.
71 */
72enum xpc_retval
73xpc_setup_infrastructure(struct xpc_partition *part)
74{
75 int ret;
76 struct timer_list *timer;
77 partid_t partid = XPC_PARTID(part);
78
79
80 /*
81 * Zero out MOST of the entry for this partition. Only the fields
82 * starting with `nchannels' will be zeroed. The preceding fields must
83 * remain `viable' across partition ups and downs, since they may be
84 * referenced during this memset() operation.
85 */
86 memset(&part->nchannels, 0, sizeof(struct xpc_partition) -
87 offsetof(struct xpc_partition, nchannels));
88
89 /*
90 * Allocate all of the channel structures as a contiguous chunk of
91 * memory.
92 */
93 part->channels = kmalloc(sizeof(struct xpc_channel) * XPC_NCHANNELS,
94 GFP_KERNEL);
95 if (part->channels == NULL) {
96 dev_err(xpc_chan, "can't get memory for channels\n");
97 return xpcNoMemory;
98 }
99 memset(part->channels, 0, sizeof(struct xpc_channel) * XPC_NCHANNELS);
100
101 part->nchannels = XPC_NCHANNELS;
102
103
104 /* allocate all the required GET/PUT values */
105
106 part->local_GPs = xpc_kmalloc_cacheline_aligned(XPC_GP_SIZE,
107 GFP_KERNEL, &part->local_GPs_base);
108 if (part->local_GPs == NULL) {
109 kfree(part->channels);
110 part->channels = NULL;
111 dev_err(xpc_chan, "can't get memory for local get/put "
112 "values\n");
113 return xpcNoMemory;
114 }
115 memset(part->local_GPs, 0, XPC_GP_SIZE);
116
117 part->remote_GPs = xpc_kmalloc_cacheline_aligned(XPC_GP_SIZE,
118 GFP_KERNEL, &part->remote_GPs_base);
119 if (part->remote_GPs == NULL) {
120 kfree(part->channels);
121 part->channels = NULL;
122 kfree(part->local_GPs_base);
123 part->local_GPs = NULL;
124 dev_err(xpc_chan, "can't get memory for remote get/put "
125 "values\n");
126 return xpcNoMemory;
127 }
128 memset(part->remote_GPs, 0, XPC_GP_SIZE);
129
130
131 /* allocate all the required open and close args */
132
133 part->local_openclose_args = xpc_kmalloc_cacheline_aligned(
134 XPC_OPENCLOSE_ARGS_SIZE, GFP_KERNEL,
135 &part->local_openclose_args_base);
136 if (part->local_openclose_args == NULL) {
137 kfree(part->channels);
138 part->channels = NULL;
139 kfree(part->local_GPs_base);
140 part->local_GPs = NULL;
141 kfree(part->remote_GPs_base);
142 part->remote_GPs = NULL;
143 dev_err(xpc_chan, "can't get memory for local connect args\n");
144 return xpcNoMemory;
145 }
146 memset(part->local_openclose_args, 0, XPC_OPENCLOSE_ARGS_SIZE);
147
148 part->remote_openclose_args = xpc_kmalloc_cacheline_aligned(
149 XPC_OPENCLOSE_ARGS_SIZE, GFP_KERNEL,
150 &part->remote_openclose_args_base);
151 if (part->remote_openclose_args == NULL) {
152 kfree(part->channels);
153 part->channels = NULL;
154 kfree(part->local_GPs_base);
155 part->local_GPs = NULL;
156 kfree(part->remote_GPs_base);
157 part->remote_GPs = NULL;
158 kfree(part->local_openclose_args_base);
159 part->local_openclose_args = NULL;
160 dev_err(xpc_chan, "can't get memory for remote connect args\n");
161 return xpcNoMemory;
162 }
163 memset(part->remote_openclose_args, 0, XPC_OPENCLOSE_ARGS_SIZE);
164
165
166 xpc_initialize_channels(part, partid);
167
168 atomic_set(&part->nchannels_active, 0);
169
170
171 /* local_IPI_amo were set to 0 by an earlier memset() */
172
173 /* Initialize this partitions AMO_t structure */
174 part->local_IPI_amo_va = xpc_IPI_init(partid);
175
176 spin_lock_init(&part->IPI_lock);
177
178 atomic_set(&part->channel_mgr_requests, 1);
179 init_waitqueue_head(&part->channel_mgr_wq);
180
181 sprintf(part->IPI_owner, "xpc%02d", partid);
182 ret = request_irq(SGI_XPC_NOTIFY, xpc_notify_IRQ_handler, SA_SHIRQ,
183 part->IPI_owner, (void *) (u64) partid);
184 if (ret != 0) {
185 kfree(part->channels);
186 part->channels = NULL;
187 kfree(part->local_GPs_base);
188 part->local_GPs = NULL;
189 kfree(part->remote_GPs_base);
190 part->remote_GPs = NULL;
191 kfree(part->local_openclose_args_base);
192 part->local_openclose_args = NULL;
193 kfree(part->remote_openclose_args_base);
194 part->remote_openclose_args = NULL;
195 dev_err(xpc_chan, "can't register NOTIFY IRQ handler, "
196 "errno=%d\n", -ret);
197 return xpcLackOfResources;
198 }
199
200 /* Setup a timer to check for dropped IPIs */
201 timer = &part->dropped_IPI_timer;
202 init_timer(timer);
203 timer->function = (void (*)(unsigned long)) xpc_dropped_IPI_check;
204 timer->data = (unsigned long) part;
205 timer->expires = jiffies + XPC_P_DROPPED_IPI_WAIT;
206 add_timer(timer);
207
208 /*
209 * With the setting of the partition setup_state to XPC_P_SETUP, we're
210 * declaring that this partition is ready to go.
211 */
212 (volatile u8) part->setup_state = XPC_P_SETUP;
213
214
215 /*
216 * Setup the per partition specific variables required by the
217 * remote partition to establish channel connections with us.
218 *
219 * The setting of the magic # indicates that these per partition
220 * specific variables are ready to be used.
221 */
222 xpc_vars_part[partid].GPs_pa = __pa(part->local_GPs);
223 xpc_vars_part[partid].openclose_args_pa =
224 __pa(part->local_openclose_args);
225 xpc_vars_part[partid].IPI_amo_pa = __pa(part->local_IPI_amo_va);
226 xpc_vars_part[partid].IPI_nasid = cpuid_to_nasid(smp_processor_id());
227 xpc_vars_part[partid].IPI_phys_cpuid =
228 cpu_physical_id(smp_processor_id());
229 xpc_vars_part[partid].nchannels = part->nchannels;
230 (volatile u64) xpc_vars_part[partid].magic = XPC_VP_MAGIC1;
231
232 return xpcSuccess;
233}
234
235
236/*
237 * Create a wrapper that hides the underlying mechanism for pulling a cacheline
238 * (or multiple cachelines) from a remote partition.
239 *
240 * src must be a cacheline aligned physical address on the remote partition.
241 * dst must be a cacheline aligned virtual address on this partition.
242 * cnt must be an cacheline sized
243 */
244static enum xpc_retval
245xpc_pull_remote_cachelines(struct xpc_partition *part, void *dst,
246 const void *src, size_t cnt)
247{
248 bte_result_t bte_ret;
249
250
251 DBUG_ON((u64) src != L1_CACHE_ALIGN((u64) src));
252 DBUG_ON((u64) dst != L1_CACHE_ALIGN((u64) dst));
253 DBUG_ON(cnt != L1_CACHE_ALIGN(cnt));
254
255 if (part->act_state == XPC_P_DEACTIVATING) {
256 return part->reason;
257 }
258
259 bte_ret = xp_bte_copy((u64) src, (u64) ia64_tpa((u64) dst),
260 (u64) cnt, (BTE_NORMAL | BTE_WACQUIRE), NULL);
261 if (bte_ret == BTE_SUCCESS) {
262 return xpcSuccess;
263 }
264
265 dev_dbg(xpc_chan, "xp_bte_copy() from partition %d failed, ret=%d\n",
266 XPC_PARTID(part), bte_ret);
267
268 return xpc_map_bte_errors(bte_ret);
269}
270
271
272/*
273 * Pull the remote per partititon specific variables from the specified
274 * partition.
275 */
276enum xpc_retval
277xpc_pull_remote_vars_part(struct xpc_partition *part)
278{
279 u8 buffer[L1_CACHE_BYTES * 2];
280 struct xpc_vars_part *pulled_entry_cacheline =
281 (struct xpc_vars_part *) L1_CACHE_ALIGN((u64) buffer);
282 struct xpc_vars_part *pulled_entry;
283 u64 remote_entry_cacheline_pa, remote_entry_pa;
284 partid_t partid = XPC_PARTID(part);
285 enum xpc_retval ret;
286
287
288 /* pull the cacheline that contains the variables we're interested in */
289
290 DBUG_ON(part->remote_vars_part_pa !=
291 L1_CACHE_ALIGN(part->remote_vars_part_pa));
292 DBUG_ON(sizeof(struct xpc_vars_part) != L1_CACHE_BYTES / 2);
293
294 remote_entry_pa = part->remote_vars_part_pa +
295 sn_partition_id * sizeof(struct xpc_vars_part);
296
297 remote_entry_cacheline_pa = (remote_entry_pa & ~(L1_CACHE_BYTES - 1));
298
299 pulled_entry = (struct xpc_vars_part *) ((u64) pulled_entry_cacheline +
300 (remote_entry_pa & (L1_CACHE_BYTES - 1)));
301
302 ret = xpc_pull_remote_cachelines(part, pulled_entry_cacheline,
303 (void *) remote_entry_cacheline_pa,
304 L1_CACHE_BYTES);
305 if (ret != xpcSuccess) {
306 dev_dbg(xpc_chan, "failed to pull XPC vars_part from "
307 "partition %d, ret=%d\n", partid, ret);
308 return ret;
309 }
310
311
312 /* see if they've been set up yet */
313
314 if (pulled_entry->magic != XPC_VP_MAGIC1 &&
315 pulled_entry->magic != XPC_VP_MAGIC2) {
316
317 if (pulled_entry->magic != 0) {
318 dev_dbg(xpc_chan, "partition %d's XPC vars_part for "
319 "partition %d has bad magic value (=0x%lx)\n",
320 partid, sn_partition_id, pulled_entry->magic);
321 return xpcBadMagic;
322 }
323
324 /* they've not been initialized yet */
325 return xpcRetry;
326 }
327
328 if (xpc_vars_part[partid].magic == XPC_VP_MAGIC1) {
329
330 /* validate the variables */
331
332 if (pulled_entry->GPs_pa == 0 ||
333 pulled_entry->openclose_args_pa == 0 ||
334 pulled_entry->IPI_amo_pa == 0) {
335
336 dev_err(xpc_chan, "partition %d's XPC vars_part for "
337 "partition %d are not valid\n", partid,
338 sn_partition_id);
339 return xpcInvalidAddress;
340 }
341
342 /* the variables we imported look to be valid */
343
344 part->remote_GPs_pa = pulled_entry->GPs_pa;
345 part->remote_openclose_args_pa =
346 pulled_entry->openclose_args_pa;
347 part->remote_IPI_amo_va =
348 (AMO_t *) __va(pulled_entry->IPI_amo_pa);
349 part->remote_IPI_nasid = pulled_entry->IPI_nasid;
350 part->remote_IPI_phys_cpuid = pulled_entry->IPI_phys_cpuid;
351
352 if (part->nchannels > pulled_entry->nchannels) {
353 part->nchannels = pulled_entry->nchannels;
354 }
355
356 /* let the other side know that we've pulled their variables */
357
358 (volatile u64) xpc_vars_part[partid].magic = XPC_VP_MAGIC2;
359 }
360
361 if (pulled_entry->magic == XPC_VP_MAGIC1) {
362 return xpcRetry;
363 }
364
365 return xpcSuccess;
366}
367
368
369/*
370 * Get the IPI flags and pull the openclose args and/or remote GPs as needed.
371 */
372static u64
373xpc_get_IPI_flags(struct xpc_partition *part)
374{
375 unsigned long irq_flags;
376 u64 IPI_amo;
377 enum xpc_retval ret;
378
379
380 /*
381 * See if there are any IPI flags to be handled.
382 */
383
384 spin_lock_irqsave(&part->IPI_lock, irq_flags);
385 if ((IPI_amo = part->local_IPI_amo) != 0) {
386 part->local_IPI_amo = 0;
387 }
388 spin_unlock_irqrestore(&part->IPI_lock, irq_flags);
389
390
391 if (XPC_ANY_OPENCLOSE_IPI_FLAGS_SET(IPI_amo)) {
392 ret = xpc_pull_remote_cachelines(part,
393 part->remote_openclose_args,
394 (void *) part->remote_openclose_args_pa,
395 XPC_OPENCLOSE_ARGS_SIZE);
396 if (ret != xpcSuccess) {
397 XPC_DEACTIVATE_PARTITION(part, ret);
398
399 dev_dbg(xpc_chan, "failed to pull openclose args from "
400 "partition %d, ret=%d\n", XPC_PARTID(part),
401 ret);
402
403 /* don't bother processing IPIs anymore */
404 IPI_amo = 0;
405 }
406 }
407
408 if (XPC_ANY_MSG_IPI_FLAGS_SET(IPI_amo)) {
409 ret = xpc_pull_remote_cachelines(part, part->remote_GPs,
410 (void *) part->remote_GPs_pa,
411 XPC_GP_SIZE);
412 if (ret != xpcSuccess) {
413 XPC_DEACTIVATE_PARTITION(part, ret);
414
415 dev_dbg(xpc_chan, "failed to pull GPs from partition "
416 "%d, ret=%d\n", XPC_PARTID(part), ret);
417
418 /* don't bother processing IPIs anymore */
419 IPI_amo = 0;
420 }
421 }
422
423 return IPI_amo;
424}
425
426
427/*
428 * Allocate the local message queue and the notify queue.
429 */
430static enum xpc_retval
431xpc_allocate_local_msgqueue(struct xpc_channel *ch)
432{
433 unsigned long irq_flags;
434 int nentries;
435 size_t nbytes;
436
437
438 // >>> may want to check for ch->flags & XPC_C_DISCONNECTING between
439 // >>> iterations of the for-loop, bail if set?
440
441 // >>> should we impose a minumum #of entries? like 4 or 8?
442 for (nentries = ch->local_nentries; nentries > 0; nentries--) {
443
444 nbytes = nentries * ch->msg_size;
445 ch->local_msgqueue = xpc_kmalloc_cacheline_aligned(nbytes,
446 (GFP_KERNEL | GFP_DMA),
447 &ch->local_msgqueue_base);
448 if (ch->local_msgqueue == NULL) {
449 continue;
450 }
451 memset(ch->local_msgqueue, 0, nbytes);
452
453 nbytes = nentries * sizeof(struct xpc_notify);
454 ch->notify_queue = kmalloc(nbytes, (GFP_KERNEL | GFP_DMA));
455 if (ch->notify_queue == NULL) {
456 kfree(ch->local_msgqueue_base);
457 ch->local_msgqueue = NULL;
458 continue;
459 }
460 memset(ch->notify_queue, 0, nbytes);
461
462 spin_lock_irqsave(&ch->lock, irq_flags);
463 if (nentries < ch->local_nentries) {
464 dev_dbg(xpc_chan, "nentries=%d local_nentries=%d, "
465 "partid=%d, channel=%d\n", nentries,
466 ch->local_nentries, ch->partid, ch->number);
467
468 ch->local_nentries = nentries;
469 }
470 spin_unlock_irqrestore(&ch->lock, irq_flags);
471 return xpcSuccess;
472 }
473
474 dev_dbg(xpc_chan, "can't get memory for local message queue and notify "
475 "queue, partid=%d, channel=%d\n", ch->partid, ch->number);
476 return xpcNoMemory;
477}
478
479
480/*
481 * Allocate the cached remote message queue.
482 */
483static enum xpc_retval
484xpc_allocate_remote_msgqueue(struct xpc_channel *ch)
485{
486 unsigned long irq_flags;
487 int nentries;
488 size_t nbytes;
489
490
491 DBUG_ON(ch->remote_nentries <= 0);
492
493 // >>> may want to check for ch->flags & XPC_C_DISCONNECTING between
494 // >>> iterations of the for-loop, bail if set?
495
496 // >>> should we impose a minumum #of entries? like 4 or 8?
497 for (nentries = ch->remote_nentries; nentries > 0; nentries--) {
498
499 nbytes = nentries * ch->msg_size;
500 ch->remote_msgqueue = xpc_kmalloc_cacheline_aligned(nbytes,
501 (GFP_KERNEL | GFP_DMA),
502 &ch->remote_msgqueue_base);
503 if (ch->remote_msgqueue == NULL) {
504 continue;
505 }
506 memset(ch->remote_msgqueue, 0, nbytes);
507
508 spin_lock_irqsave(&ch->lock, irq_flags);
509 if (nentries < ch->remote_nentries) {
510 dev_dbg(xpc_chan, "nentries=%d remote_nentries=%d, "
511 "partid=%d, channel=%d\n", nentries,
512 ch->remote_nentries, ch->partid, ch->number);
513
514 ch->remote_nentries = nentries;
515 }
516 spin_unlock_irqrestore(&ch->lock, irq_flags);
517 return xpcSuccess;
518 }
519
520 dev_dbg(xpc_chan, "can't get memory for cached remote message queue, "
521 "partid=%d, channel=%d\n", ch->partid, ch->number);
522 return xpcNoMemory;
523}
524
525
526/*
527 * Allocate message queues and other stuff associated with a channel.
528 *
529 * Note: Assumes all of the channel sizes are filled in.
530 */
531static enum xpc_retval
532xpc_allocate_msgqueues(struct xpc_channel *ch)
533{
534 unsigned long irq_flags;
535 int i;
536 enum xpc_retval ret;
537
538
539 DBUG_ON(ch->flags & XPC_C_SETUP);
540
541 if ((ret = xpc_allocate_local_msgqueue(ch)) != xpcSuccess) {
542 return ret;
543 }
544
545 if ((ret = xpc_allocate_remote_msgqueue(ch)) != xpcSuccess) {
546 kfree(ch->local_msgqueue_base);
547 ch->local_msgqueue = NULL;
548 kfree(ch->notify_queue);
549 ch->notify_queue = NULL;
550 return ret;
551 }
552
553 for (i = 0; i < ch->local_nentries; i++) {
554 /* use a semaphore as an event wait queue */
555 sema_init(&ch->notify_queue[i].sema, 0);
556 }
557
558 sema_init(&ch->teardown_sema, 0); /* event wait */
559
560 spin_lock_irqsave(&ch->lock, irq_flags);
561 ch->flags |= XPC_C_SETUP;
562 spin_unlock_irqrestore(&ch->lock, irq_flags);
563
564 return xpcSuccess;
565}
566
567
568/*
569 * Process a connect message from a remote partition.
570 *
571 * Note: xpc_process_connect() is expecting to be called with the
572 * spin_lock_irqsave held and will leave it locked upon return.
573 */
574static void
575xpc_process_connect(struct xpc_channel *ch, unsigned long *irq_flags)
576{
577 enum xpc_retval ret;
578
579
580 DBUG_ON(!spin_is_locked(&ch->lock));
581
582 if (!(ch->flags & XPC_C_OPENREQUEST) ||
583 !(ch->flags & XPC_C_ROPENREQUEST)) {
584 /* nothing more to do for now */
585 return;
586 }
587 DBUG_ON(!(ch->flags & XPC_C_CONNECTING));
588
589 if (!(ch->flags & XPC_C_SETUP)) {
590 spin_unlock_irqrestore(&ch->lock, *irq_flags);
591 ret = xpc_allocate_msgqueues(ch);
592 spin_lock_irqsave(&ch->lock, *irq_flags);
593
594 if (ret != xpcSuccess) {
595 XPC_DISCONNECT_CHANNEL(ch, ret, irq_flags);
596 }
597 if (ch->flags & (XPC_C_CONNECTED | XPC_C_DISCONNECTING)) {
598 return;
599 }
600
601 DBUG_ON(!(ch->flags & XPC_C_SETUP));
602 DBUG_ON(ch->local_msgqueue == NULL);
603 DBUG_ON(ch->remote_msgqueue == NULL);
604 }
605
606 if (!(ch->flags & XPC_C_OPENREPLY)) {
607 ch->flags |= XPC_C_OPENREPLY;
608 xpc_IPI_send_openreply(ch, irq_flags);
609 }
610
611 if (!(ch->flags & XPC_C_ROPENREPLY)) {
612 return;
613 }
614
615 DBUG_ON(ch->remote_msgqueue_pa == 0);
616
617 ch->flags = (XPC_C_CONNECTED | XPC_C_SETUP); /* clear all else */
618
619 dev_info(xpc_chan, "channel %d to partition %d connected\n",
620 ch->number, ch->partid);
621
622 spin_unlock_irqrestore(&ch->lock, *irq_flags);
623 xpc_create_kthreads(ch, 1);
624 spin_lock_irqsave(&ch->lock, *irq_flags);
625}
626
627
628/*
629 * Free up message queues and other stuff that were allocated for the specified
630 * channel.
631 *
632 * Note: ch->reason and ch->reason_line are left set for debugging purposes,
633 * they're cleared when XPC_C_DISCONNECTED is cleared.
634 */
635static void
636xpc_free_msgqueues(struct xpc_channel *ch)
637{
638 DBUG_ON(!spin_is_locked(&ch->lock));
639 DBUG_ON(atomic_read(&ch->n_to_notify) != 0);
640
641 ch->remote_msgqueue_pa = 0;
642 ch->func = NULL;
643 ch->key = NULL;
644 ch->msg_size = 0;
645 ch->local_nentries = 0;
646 ch->remote_nentries = 0;
647 ch->kthreads_assigned_limit = 0;
648 ch->kthreads_idle_limit = 0;
649
650 ch->local_GP->get = 0;
651 ch->local_GP->put = 0;
652 ch->remote_GP.get = 0;
653 ch->remote_GP.put = 0;
654 ch->w_local_GP.get = 0;
655 ch->w_local_GP.put = 0;
656 ch->w_remote_GP.get = 0;
657 ch->w_remote_GP.put = 0;
658 ch->next_msg_to_pull = 0;
659
660 if (ch->flags & XPC_C_SETUP) {
661 ch->flags &= ~XPC_C_SETUP;
662
663 dev_dbg(xpc_chan, "ch->flags=0x%x, partid=%d, channel=%d\n",
664 ch->flags, ch->partid, ch->number);
665
666 kfree(ch->local_msgqueue_base);
667 ch->local_msgqueue = NULL;
668 kfree(ch->remote_msgqueue_base);
669 ch->remote_msgqueue = NULL;
670 kfree(ch->notify_queue);
671 ch->notify_queue = NULL;
672
673 /* in case someone is waiting for the teardown to complete */
674 up(&ch->teardown_sema);
675 }
676}
677
678
679/*
680 * spin_lock_irqsave() is expected to be held on entry.
681 */
682static void
683xpc_process_disconnect(struct xpc_channel *ch, unsigned long *irq_flags)
684{
685 struct xpc_partition *part = &xpc_partitions[ch->partid];
686 u32 ch_flags = ch->flags;
687
688
689 DBUG_ON(!spin_is_locked(&ch->lock));
690
691 if (!(ch->flags & XPC_C_DISCONNECTING)) {
692 return;
693 }
694
695 DBUG_ON(!(ch->flags & XPC_C_CLOSEREQUEST));
696
697 /* make sure all activity has settled down first */
698
699 if (atomic_read(&ch->references) > 0) {
700 return;
701 }
702 DBUG_ON(atomic_read(&ch->kthreads_assigned) != 0);
703
704 /* it's now safe to free the channel's message queues */
705
706 xpc_free_msgqueues(ch);
707 DBUG_ON(ch->flags & XPC_C_SETUP);
708
709 if (part->act_state != XPC_P_DEACTIVATING) {
710
711 /* as long as the other side is up do the full protocol */
712
713 if (!(ch->flags & XPC_C_RCLOSEREQUEST)) {
714 return;
715 }
716
717 if (!(ch->flags & XPC_C_CLOSEREPLY)) {
718 ch->flags |= XPC_C_CLOSEREPLY;
719 xpc_IPI_send_closereply(ch, irq_flags);
720 }
721
722 if (!(ch->flags & XPC_C_RCLOSEREPLY)) {
723 return;
724 }
725 }
726
727 /* both sides are disconnected now */
728
729 ch->flags = XPC_C_DISCONNECTED; /* clear all flags, but this one */
730
731 atomic_dec(&part->nchannels_active);
732
733 if (ch_flags & XPC_C_WASCONNECTED) {
734 dev_info(xpc_chan, "channel %d to partition %d disconnected, "
735 "reason=%d\n", ch->number, ch->partid, ch->reason);
736 }
737}
738
739
740/*
741 * Process a change in the channel's remote connection state.
742 */
743static void
744xpc_process_openclose_IPI(struct xpc_partition *part, int ch_number,
745 u8 IPI_flags)
746{
747 unsigned long irq_flags;
748 struct xpc_openclose_args *args =
749 &part->remote_openclose_args[ch_number];
750 struct xpc_channel *ch = &part->channels[ch_number];
751 enum xpc_retval reason;
752
753
754
755 spin_lock_irqsave(&ch->lock, irq_flags);
756
757
758 if (IPI_flags & XPC_IPI_CLOSEREQUEST) {
759
760 dev_dbg(xpc_chan, "XPC_IPI_CLOSEREQUEST (reason=%d) received "
761 "from partid=%d, channel=%d\n", args->reason,
762 ch->partid, ch->number);
763
764 /*
765 * If RCLOSEREQUEST is set, we're probably waiting for
766 * RCLOSEREPLY. We should find it and a ROPENREQUEST packed
767 * with this RCLOSEQREUQEST in the IPI_flags.
768 */
769
770 if (ch->flags & XPC_C_RCLOSEREQUEST) {
771 DBUG_ON(!(ch->flags & XPC_C_DISCONNECTING));
772 DBUG_ON(!(ch->flags & XPC_C_CLOSEREQUEST));
773 DBUG_ON(!(ch->flags & XPC_C_CLOSEREPLY));
774 DBUG_ON(ch->flags & XPC_C_RCLOSEREPLY);
775
776 DBUG_ON(!(IPI_flags & XPC_IPI_CLOSEREPLY));
777 IPI_flags &= ~XPC_IPI_CLOSEREPLY;
778 ch->flags |= XPC_C_RCLOSEREPLY;
779
780 /* both sides have finished disconnecting */
781 xpc_process_disconnect(ch, &irq_flags);
782 }
783
784 if (ch->flags & XPC_C_DISCONNECTED) {
785 // >>> explain this section
786
787 if (!(IPI_flags & XPC_IPI_OPENREQUEST)) {
788 DBUG_ON(part->act_state !=
789 XPC_P_DEACTIVATING);
790 spin_unlock_irqrestore(&ch->lock, irq_flags);
791 return;
792 }
793
794 XPC_SET_REASON(ch, 0, 0);
795 ch->flags &= ~XPC_C_DISCONNECTED;
796
797 atomic_inc(&part->nchannels_active);
798 ch->flags |= (XPC_C_CONNECTING | XPC_C_ROPENREQUEST);
799 }
800
801 IPI_flags &= ~(XPC_IPI_OPENREQUEST | XPC_IPI_OPENREPLY);
802
803 /*
804 * The meaningful CLOSEREQUEST connection state fields are:
805 * reason = reason connection is to be closed
806 */
807
808 ch->flags |= XPC_C_RCLOSEREQUEST;
809
810 if (!(ch->flags & XPC_C_DISCONNECTING)) {
811 reason = args->reason;
812 if (reason <= xpcSuccess || reason > xpcUnknownReason) {
813 reason = xpcUnknownReason;
814 } else if (reason == xpcUnregistering) {
815 reason = xpcOtherUnregistering;
816 }
817
818 XPC_DISCONNECT_CHANNEL(ch, reason, &irq_flags);
819 } else {
820 xpc_process_disconnect(ch, &irq_flags);
821 }
822 }
823
824
825 if (IPI_flags & XPC_IPI_CLOSEREPLY) {
826
827 dev_dbg(xpc_chan, "XPC_IPI_CLOSEREPLY received from partid=%d,"
828 " channel=%d\n", ch->partid, ch->number);
829
830 if (ch->flags & XPC_C_DISCONNECTED) {
831 DBUG_ON(part->act_state != XPC_P_DEACTIVATING);
832 spin_unlock_irqrestore(&ch->lock, irq_flags);
833 return;
834 }
835
836 DBUG_ON(!(ch->flags & XPC_C_CLOSEREQUEST));
837 DBUG_ON(!(ch->flags & XPC_C_RCLOSEREQUEST));
838
839 ch->flags |= XPC_C_RCLOSEREPLY;
840
841 if (ch->flags & XPC_C_CLOSEREPLY) {
842 /* both sides have finished disconnecting */
843 xpc_process_disconnect(ch, &irq_flags);
844 }
845 }
846
847
848 if (IPI_flags & XPC_IPI_OPENREQUEST) {
849
850 dev_dbg(xpc_chan, "XPC_IPI_OPENREQUEST (msg_size=%d, "
851 "local_nentries=%d) received from partid=%d, "
852 "channel=%d\n", args->msg_size, args->local_nentries,
853 ch->partid, ch->number);
854
855 if ((ch->flags & XPC_C_DISCONNECTING) ||
856 part->act_state == XPC_P_DEACTIVATING) {
857 spin_unlock_irqrestore(&ch->lock, irq_flags);
858 return;
859 }
860 DBUG_ON(!(ch->flags & (XPC_C_DISCONNECTED |
861 XPC_C_OPENREQUEST)));
862 DBUG_ON(ch->flags & (XPC_C_ROPENREQUEST | XPC_C_ROPENREPLY |
863 XPC_C_OPENREPLY | XPC_C_CONNECTED));
864
865 /*
866 * The meaningful OPENREQUEST connection state fields are:
867 * msg_size = size of channel's messages in bytes
868 * local_nentries = remote partition's local_nentries
869 */
870 DBUG_ON(args->msg_size == 0);
871 DBUG_ON(args->local_nentries == 0);
872
873 ch->flags |= (XPC_C_ROPENREQUEST | XPC_C_CONNECTING);
874 ch->remote_nentries = args->local_nentries;
875
876
877 if (ch->flags & XPC_C_OPENREQUEST) {
878 if (args->msg_size != ch->msg_size) {
879 XPC_DISCONNECT_CHANNEL(ch, xpcUnequalMsgSizes,
880 &irq_flags);
881 spin_unlock_irqrestore(&ch->lock, irq_flags);
882 return;
883 }
884 } else {
885 ch->msg_size = args->msg_size;
886
887 XPC_SET_REASON(ch, 0, 0);
888 ch->flags &= ~XPC_C_DISCONNECTED;
889
890 atomic_inc(&part->nchannels_active);
891 }
892
893 xpc_process_connect(ch, &irq_flags);
894 }
895
896
897 if (IPI_flags & XPC_IPI_OPENREPLY) {
898
899 dev_dbg(xpc_chan, "XPC_IPI_OPENREPLY (local_msgqueue_pa=0x%lx, "
900 "local_nentries=%d, remote_nentries=%d) received from "
901 "partid=%d, channel=%d\n", args->local_msgqueue_pa,
902 args->local_nentries, args->remote_nentries,
903 ch->partid, ch->number);
904
905 if (ch->flags & (XPC_C_DISCONNECTING | XPC_C_DISCONNECTED)) {
906 spin_unlock_irqrestore(&ch->lock, irq_flags);
907 return;
908 }
909 DBUG_ON(!(ch->flags & XPC_C_OPENREQUEST));
910 DBUG_ON(!(ch->flags & XPC_C_ROPENREQUEST));
911 DBUG_ON(ch->flags & XPC_C_CONNECTED);
912
913 /*
914 * The meaningful OPENREPLY connection state fields are:
915 * local_msgqueue_pa = physical address of remote
916 * partition's local_msgqueue
917 * local_nentries = remote partition's local_nentries
918 * remote_nentries = remote partition's remote_nentries
919 */
920 DBUG_ON(args->local_msgqueue_pa == 0);
921 DBUG_ON(args->local_nentries == 0);
922 DBUG_ON(args->remote_nentries == 0);
923
924 ch->flags |= XPC_C_ROPENREPLY;
925 ch->remote_msgqueue_pa = args->local_msgqueue_pa;
926
927 if (args->local_nentries < ch->remote_nentries) {
928 dev_dbg(xpc_chan, "XPC_IPI_OPENREPLY: new "
929 "remote_nentries=%d, old remote_nentries=%d, "
930 "partid=%d, channel=%d\n",
931 args->local_nentries, ch->remote_nentries,
932 ch->partid, ch->number);
933
934 ch->remote_nentries = args->local_nentries;
935 }
936 if (args->remote_nentries < ch->local_nentries) {
937 dev_dbg(xpc_chan, "XPC_IPI_OPENREPLY: new "
938 "local_nentries=%d, old local_nentries=%d, "
939 "partid=%d, channel=%d\n",
940 args->remote_nentries, ch->local_nentries,
941 ch->partid, ch->number);
942
943 ch->local_nentries = args->remote_nentries;
944 }
945
946 xpc_process_connect(ch, &irq_flags);
947 }
948
949 spin_unlock_irqrestore(&ch->lock, irq_flags);
950}
951
952
953/*
954 * Attempt to establish a channel connection to a remote partition.
955 */
956static enum xpc_retval
957xpc_connect_channel(struct xpc_channel *ch)
958{
959 unsigned long irq_flags;
960 struct xpc_registration *registration = &xpc_registrations[ch->number];
961
962
963 if (down_interruptible(&registration->sema) != 0) {
964 return xpcInterrupted;
965 }
966
967 if (!XPC_CHANNEL_REGISTERED(ch->number)) {
968 up(&registration->sema);
969 return xpcUnregistered;
970 }
971
972 spin_lock_irqsave(&ch->lock, irq_flags);
973
974 DBUG_ON(ch->flags & XPC_C_CONNECTED);
975 DBUG_ON(ch->flags & XPC_C_OPENREQUEST);
976
977 if (ch->flags & XPC_C_DISCONNECTING) {
978 spin_unlock_irqrestore(&ch->lock, irq_flags);
979 up(&registration->sema);
980 return ch->reason;
981 }
982
983
984 /* add info from the channel connect registration to the channel */
985
986 ch->kthreads_assigned_limit = registration->assigned_limit;
987 ch->kthreads_idle_limit = registration->idle_limit;
988 DBUG_ON(atomic_read(&ch->kthreads_assigned) != 0);
989 DBUG_ON(atomic_read(&ch->kthreads_idle) != 0);
990 DBUG_ON(atomic_read(&ch->kthreads_active) != 0);
991
992 ch->func = registration->func;
993 DBUG_ON(registration->func == NULL);
994 ch->key = registration->key;
995
996 ch->local_nentries = registration->nentries;
997
998 if (ch->flags & XPC_C_ROPENREQUEST) {
999 if (registration->msg_size != ch->msg_size) {
1000 /* the local and remote sides aren't the same */
1001
1002 /*
1003 * Because XPC_DISCONNECT_CHANNEL() can block we're
1004 * forced to up the registration sema before we unlock
1005 * the channel lock. But that's okay here because we're
1006 * done with the part that required the registration
1007 * sema. XPC_DISCONNECT_CHANNEL() requires that the
1008 * channel lock be locked and will unlock and relock
1009 * the channel lock as needed.
1010 */
1011 up(&registration->sema);
1012 XPC_DISCONNECT_CHANNEL(ch, xpcUnequalMsgSizes,
1013 &irq_flags);
1014 spin_unlock_irqrestore(&ch->lock, irq_flags);
1015 return xpcUnequalMsgSizes;
1016 }
1017 } else {
1018 ch->msg_size = registration->msg_size;
1019
1020 XPC_SET_REASON(ch, 0, 0);
1021 ch->flags &= ~XPC_C_DISCONNECTED;
1022
1023 atomic_inc(&xpc_partitions[ch->partid].nchannels_active);
1024 }
1025
1026 up(&registration->sema);
1027
1028
1029 /* initiate the connection */
1030
1031 ch->flags |= (XPC_C_OPENREQUEST | XPC_C_CONNECTING);
1032 xpc_IPI_send_openrequest(ch, &irq_flags);
1033
1034 xpc_process_connect(ch, &irq_flags);
1035
1036 spin_unlock_irqrestore(&ch->lock, irq_flags);
1037
1038 return xpcSuccess;
1039}
1040
1041
1042/*
1043 * Notify those who wanted to be notified upon delivery of their message.
1044 */
1045static void
1046xpc_notify_senders(struct xpc_channel *ch, enum xpc_retval reason, s64 put)
1047{
1048 struct xpc_notify *notify;
1049 u8 notify_type;
1050 s64 get = ch->w_remote_GP.get - 1;
1051
1052
1053 while (++get < put && atomic_read(&ch->n_to_notify) > 0) {
1054
1055 notify = &ch->notify_queue[get % ch->local_nentries];
1056
1057 /*
1058 * See if the notify entry indicates it was associated with
1059 * a message who's sender wants to be notified. It is possible
1060 * that it is, but someone else is doing or has done the
1061 * notification.
1062 */
1063 notify_type = notify->type;
1064 if (notify_type == 0 ||
1065 cmpxchg(&notify->type, notify_type, 0) !=
1066 notify_type) {
1067 continue;
1068 }
1069
1070 DBUG_ON(notify_type != XPC_N_CALL);
1071
1072 atomic_dec(&ch->n_to_notify);
1073
1074 if (notify->func != NULL) {
1075 dev_dbg(xpc_chan, "notify->func() called, notify=0x%p, "
1076 "msg_number=%ld, partid=%d, channel=%d\n",
1077 (void *) notify, get, ch->partid, ch->number);
1078
1079 notify->func(reason, ch->partid, ch->number,
1080 notify->key);
1081
1082 dev_dbg(xpc_chan, "notify->func() returned, "
1083 "notify=0x%p, msg_number=%ld, partid=%d, "
1084 "channel=%d\n", (void *) notify, get,
1085 ch->partid, ch->number);
1086 }
1087 }
1088}
1089
1090
1091/*
1092 * Clear some of the msg flags in the local message queue.
1093 */
1094static inline void
1095xpc_clear_local_msgqueue_flags(struct xpc_channel *ch)
1096{
1097 struct xpc_msg *msg;
1098 s64 get;
1099
1100
1101 get = ch->w_remote_GP.get;
1102 do {
1103 msg = (struct xpc_msg *) ((u64) ch->local_msgqueue +
1104 (get % ch->local_nentries) * ch->msg_size);
1105 msg->flags = 0;
1106 } while (++get < (volatile s64) ch->remote_GP.get);
1107}
1108
1109
1110/*
1111 * Clear some of the msg flags in the remote message queue.
1112 */
1113static inline void
1114xpc_clear_remote_msgqueue_flags(struct xpc_channel *ch)
1115{
1116 struct xpc_msg *msg;
1117 s64 put;
1118
1119
1120 put = ch->w_remote_GP.put;
1121 do {
1122 msg = (struct xpc_msg *) ((u64) ch->remote_msgqueue +
1123 (put % ch->remote_nentries) * ch->msg_size);
1124 msg->flags = 0;
1125 } while (++put < (volatile s64) ch->remote_GP.put);
1126}
1127
1128
1129static void
1130xpc_process_msg_IPI(struct xpc_partition *part, int ch_number)
1131{
1132 struct xpc_channel *ch = &part->channels[ch_number];
1133 int nmsgs_sent;
1134
1135
1136 ch->remote_GP = part->remote_GPs[ch_number];
1137
1138
1139 /* See what, if anything, has changed for each connected channel */
1140
1141 xpc_msgqueue_ref(ch);
1142
1143 if (ch->w_remote_GP.get == ch->remote_GP.get &&
1144 ch->w_remote_GP.put == ch->remote_GP.put) {
1145 /* nothing changed since GPs were last pulled */
1146 xpc_msgqueue_deref(ch);
1147 return;
1148 }
1149
1150 if (!(ch->flags & XPC_C_CONNECTED)){
1151 xpc_msgqueue_deref(ch);
1152 return;
1153 }
1154
1155
1156 /*
1157 * First check to see if messages recently sent by us have been
1158 * received by the other side. (The remote GET value will have
1159 * changed since we last looked at it.)
1160 */
1161
1162 if (ch->w_remote_GP.get != ch->remote_GP.get) {
1163
1164 /*
1165 * We need to notify any senders that want to be notified
1166 * that their sent messages have been received by their
1167 * intended recipients. We need to do this before updating
1168 * w_remote_GP.get so that we don't allocate the same message
1169 * queue entries prematurely (see xpc_allocate_msg()).
1170 */
1171 if (atomic_read(&ch->n_to_notify) > 0) {
1172 /*
1173 * Notify senders that messages sent have been
1174 * received and delivered by the other side.
1175 */
1176 xpc_notify_senders(ch, xpcMsgDelivered,
1177 ch->remote_GP.get);
1178 }
1179
1180 /*
1181 * Clear msg->flags in previously sent messages, so that
1182 * they're ready for xpc_allocate_msg().
1183 */
1184 xpc_clear_local_msgqueue_flags(ch);
1185
1186 (volatile s64) ch->w_remote_GP.get = ch->remote_GP.get;
1187
1188 dev_dbg(xpc_chan, "w_remote_GP.get changed to %ld, partid=%d, "
1189 "channel=%d\n", ch->w_remote_GP.get, ch->partid,
1190 ch->number);
1191
1192 /*
1193 * If anyone was waiting for message queue entries to become
1194 * available, wake them up.
1195 */
1196 if (atomic_read(&ch->n_on_msg_allocate_wq) > 0) {
1197 wake_up(&ch->msg_allocate_wq);
1198 }
1199 }
1200
1201
1202 /*
1203 * Now check for newly sent messages by the other side. (The remote
1204 * PUT value will have changed since we last looked at it.)
1205 */
1206
1207 if (ch->w_remote_GP.put != ch->remote_GP.put) {
1208 /*
1209 * Clear msg->flags in previously received messages, so that
1210 * they're ready for xpc_get_deliverable_msg().
1211 */
1212 xpc_clear_remote_msgqueue_flags(ch);
1213
1214 (volatile s64) ch->w_remote_GP.put = ch->remote_GP.put;
1215
1216 dev_dbg(xpc_chan, "w_remote_GP.put changed to %ld, partid=%d, "
1217 "channel=%d\n", ch->w_remote_GP.put, ch->partid,
1218 ch->number);
1219
1220 nmsgs_sent = ch->w_remote_GP.put - ch->w_local_GP.get;
1221 if (nmsgs_sent > 0) {
1222 dev_dbg(xpc_chan, "msgs waiting to be copied and "
1223 "delivered=%d, partid=%d, channel=%d\n",
1224 nmsgs_sent, ch->partid, ch->number);
1225
1226 if (ch->flags & XPC_C_CONNECTCALLOUT) {
1227 xpc_activate_kthreads(ch, nmsgs_sent);
1228 }
1229 }
1230 }
1231
1232 xpc_msgqueue_deref(ch);
1233}
1234
1235
1236void
1237xpc_process_channel_activity(struct xpc_partition *part)
1238{
1239 unsigned long irq_flags;
1240 u64 IPI_amo, IPI_flags;
1241 struct xpc_channel *ch;
1242 int ch_number;
1243
1244
1245 IPI_amo = xpc_get_IPI_flags(part);
1246
1247 /*
1248 * Initiate channel connections for registered channels.
1249 *
1250 * For each connected channel that has pending messages activate idle
1251 * kthreads and/or create new kthreads as needed.
1252 */
1253
1254 for (ch_number = 0; ch_number < part->nchannels; ch_number++) {
1255 ch = &part->channels[ch_number];
1256
1257
1258 /*
1259 * Process any open or close related IPI flags, and then deal
1260 * with connecting or disconnecting the channel as required.
1261 */
1262
1263 IPI_flags = XPC_GET_IPI_FLAGS(IPI_amo, ch_number);
1264
1265 if (XPC_ANY_OPENCLOSE_IPI_FLAGS_SET(IPI_flags)) {
1266 xpc_process_openclose_IPI(part, ch_number, IPI_flags);
1267 }
1268
1269
1270 if (ch->flags & XPC_C_DISCONNECTING) {
1271 spin_lock_irqsave(&ch->lock, irq_flags);
1272 xpc_process_disconnect(ch, &irq_flags);
1273 spin_unlock_irqrestore(&ch->lock, irq_flags);
1274 continue;
1275 }
1276
1277 if (part->act_state == XPC_P_DEACTIVATING) {
1278 continue;
1279 }
1280
1281 if (!(ch->flags & XPC_C_CONNECTED)) {
1282 if (!(ch->flags & XPC_C_OPENREQUEST)) {
1283 DBUG_ON(ch->flags & XPC_C_SETUP);
1284 (void) xpc_connect_channel(ch);
1285 } else {
1286 spin_lock_irqsave(&ch->lock, irq_flags);
1287 xpc_process_connect(ch, &irq_flags);
1288 spin_unlock_irqrestore(&ch->lock, irq_flags);
1289 }
1290 continue;
1291 }
1292
1293
1294 /*
1295 * Process any message related IPI flags, this may involve the
1296 * activation of kthreads to deliver any pending messages sent
1297 * from the other partition.
1298 */
1299
1300 if (XPC_ANY_MSG_IPI_FLAGS_SET(IPI_flags)) {
1301 xpc_process_msg_IPI(part, ch_number);
1302 }
1303 }
1304}
1305
1306
1307/*
1308 * XPC's heartbeat code calls this function to inform XPC that a partition has
1309 * gone down. XPC responds by tearing down the XPartition Communication
1310 * infrastructure used for the just downed partition.
1311 *
1312 * XPC's heartbeat code will never call this function and xpc_partition_up()
1313 * at the same time. Nor will it ever make multiple calls to either function
1314 * at the same time.
1315 */
1316void
1317xpc_partition_down(struct xpc_partition *part, enum xpc_retval reason)
1318{
1319 unsigned long irq_flags;
1320 int ch_number;
1321 struct xpc_channel *ch;
1322
1323
1324 dev_dbg(xpc_chan, "deactivating partition %d, reason=%d\n",
1325 XPC_PARTID(part), reason);
1326
1327 if (!xpc_part_ref(part)) {
1328 /* infrastructure for this partition isn't currently set up */
1329 return;
1330 }
1331
1332
1333 /* disconnect all channels associated with the downed partition */
1334
1335 for (ch_number = 0; ch_number < part->nchannels; ch_number++) {
1336 ch = &part->channels[ch_number];
1337
1338
1339 xpc_msgqueue_ref(ch);
1340 spin_lock_irqsave(&ch->lock, irq_flags);
1341
1342 XPC_DISCONNECT_CHANNEL(ch, reason, &irq_flags);
1343
1344 spin_unlock_irqrestore(&ch->lock, irq_flags);
1345 xpc_msgqueue_deref(ch);
1346 }
1347
1348 xpc_wakeup_channel_mgr(part);
1349
1350 xpc_part_deref(part);
1351}
1352
1353
1354/*
1355 * Teardown the infrastructure necessary to support XPartition Communication
1356 * between the specified remote partition and the local one.
1357 */
1358void
1359xpc_teardown_infrastructure(struct xpc_partition *part)
1360{
1361 partid_t partid = XPC_PARTID(part);
1362
1363
1364 /*
1365 * We start off by making this partition inaccessible to local
1366 * processes by marking it as no longer setup. Then we make it
1367 * inaccessible to remote processes by clearing the XPC per partition
1368 * specific variable's magic # (which indicates that these variables
1369 * are no longer valid) and by ignoring all XPC notify IPIs sent to
1370 * this partition.
1371 */
1372
1373 DBUG_ON(atomic_read(&part->nchannels_active) != 0);
1374 DBUG_ON(part->setup_state != XPC_P_SETUP);
1375 part->setup_state = XPC_P_WTEARDOWN;
1376
1377 xpc_vars_part[partid].magic = 0;
1378
1379
1380 free_irq(SGI_XPC_NOTIFY, (void *) (u64) partid);
1381
1382
1383 /*
1384 * Before proceding with the teardown we have to wait until all
1385 * existing references cease.
1386 */
1387 wait_event(part->teardown_wq, (atomic_read(&part->references) == 0));
1388
1389
1390 /* now we can begin tearing down the infrastructure */
1391
1392 part->setup_state = XPC_P_TORNDOWN;
1393
1394 /* in case we've still got outstanding timers registered... */
1395 del_timer_sync(&part->dropped_IPI_timer);
1396
1397 kfree(part->remote_openclose_args_base);
1398 part->remote_openclose_args = NULL;
1399 kfree(part->local_openclose_args_base);
1400 part->local_openclose_args = NULL;
1401 kfree(part->remote_GPs_base);
1402 part->remote_GPs = NULL;
1403 kfree(part->local_GPs_base);
1404 part->local_GPs = NULL;
1405 kfree(part->channels);
1406 part->channels = NULL;
1407 part->local_IPI_amo_va = NULL;
1408}
1409
1410
1411/*
1412 * Called by XP at the time of channel connection registration to cause
1413 * XPC to establish connections to all currently active partitions.
1414 */
1415void
1416xpc_initiate_connect(int ch_number)
1417{
1418 partid_t partid;
1419 struct xpc_partition *part;
1420 struct xpc_channel *ch;
1421
1422
1423 DBUG_ON(ch_number < 0 || ch_number >= XPC_NCHANNELS);
1424
1425 for (partid = 1; partid < XP_MAX_PARTITIONS; partid++) {
1426 part = &xpc_partitions[partid];
1427
1428 if (xpc_part_ref(part)) {
1429 ch = &part->channels[ch_number];
1430
1431 if (!(ch->flags & XPC_C_DISCONNECTING)) {
1432 DBUG_ON(ch->flags & XPC_C_OPENREQUEST);
1433 DBUG_ON(ch->flags & XPC_C_CONNECTED);
1434 DBUG_ON(ch->flags & XPC_C_SETUP);
1435
1436 /*
1437 * Initiate the establishment of a connection
1438 * on the newly registered channel to the
1439 * remote partition.
1440 */
1441 xpc_wakeup_channel_mgr(part);
1442 }
1443
1444 xpc_part_deref(part);
1445 }
1446 }
1447}
1448
1449
1450void
1451xpc_connected_callout(struct xpc_channel *ch)
1452{
1453 unsigned long irq_flags;
1454
1455
1456 /* let the registerer know that a connection has been established */
1457
1458 if (ch->func != NULL) {
1459 dev_dbg(xpc_chan, "ch->func() called, reason=xpcConnected, "
1460 "partid=%d, channel=%d\n", ch->partid, ch->number);
1461
1462 ch->func(xpcConnected, ch->partid, ch->number,
1463 (void *) (u64) ch->local_nentries, ch->key);
1464
1465 dev_dbg(xpc_chan, "ch->func() returned, reason=xpcConnected, "
1466 "partid=%d, channel=%d\n", ch->partid, ch->number);
1467 }
1468
1469 spin_lock_irqsave(&ch->lock, irq_flags);
1470 ch->flags |= XPC_C_CONNECTCALLOUT;
1471 spin_unlock_irqrestore(&ch->lock, irq_flags);
1472}
1473
1474
1475/*
1476 * Called by XP at the time of channel connection unregistration to cause
1477 * XPC to teardown all current connections for the specified channel.
1478 *
1479 * Before returning xpc_initiate_disconnect() will wait until all connections
1480 * on the specified channel have been closed/torndown. So the caller can be
1481 * assured that they will not be receiving any more callouts from XPC to the
1482 * function they registered via xpc_connect().
1483 *
1484 * Arguments:
1485 *
1486 * ch_number - channel # to unregister.
1487 */
1488void
1489xpc_initiate_disconnect(int ch_number)
1490{
1491 unsigned long irq_flags;
1492 partid_t partid;
1493 struct xpc_partition *part;
1494 struct xpc_channel *ch;
1495
1496
1497 DBUG_ON(ch_number < 0 || ch_number >= XPC_NCHANNELS);
1498
1499 /* initiate the channel disconnect for every active partition */
1500 for (partid = 1; partid < XP_MAX_PARTITIONS; partid++) {
1501 part = &xpc_partitions[partid];
1502
1503 if (xpc_part_ref(part)) {
1504 ch = &part->channels[ch_number];
1505 xpc_msgqueue_ref(ch);
1506
1507 spin_lock_irqsave(&ch->lock, irq_flags);
1508
1509 XPC_DISCONNECT_CHANNEL(ch, xpcUnregistering,
1510 &irq_flags);
1511
1512 spin_unlock_irqrestore(&ch->lock, irq_flags);
1513
1514 xpc_msgqueue_deref(ch);
1515 xpc_part_deref(part);
1516 }
1517 }
1518
1519 xpc_disconnect_wait(ch_number);
1520}
1521
1522
1523/*
1524 * To disconnect a channel, and reflect it back to all who may be waiting.
1525 *
1526 * >>> An OPEN is not allowed until XPC_C_DISCONNECTING is cleared by
1527 * >>> xpc_free_msgqueues().
1528 *
1529 * THE CHANNEL IS TO BE LOCKED BY THE CALLER AND WILL REMAIN LOCKED UPON RETURN.
1530 */
1531void
1532xpc_disconnect_channel(const int line, struct xpc_channel *ch,
1533 enum xpc_retval reason, unsigned long *irq_flags)
1534{
1535 u32 flags;
1536
1537
1538 DBUG_ON(!spin_is_locked(&ch->lock));
1539
1540 if (ch->flags & (XPC_C_DISCONNECTING | XPC_C_DISCONNECTED)) {
1541 return;
1542 }
1543 DBUG_ON(!(ch->flags & (XPC_C_CONNECTING | XPC_C_CONNECTED)));
1544
1545 dev_dbg(xpc_chan, "reason=%d, line=%d, partid=%d, channel=%d\n",
1546 reason, line, ch->partid, ch->number);
1547
1548 XPC_SET_REASON(ch, reason, line);
1549
1550 flags = ch->flags;
1551 /* some of these may not have been set */
1552 ch->flags &= ~(XPC_C_OPENREQUEST | XPC_C_OPENREPLY |
1553 XPC_C_ROPENREQUEST | XPC_C_ROPENREPLY |
1554 XPC_C_CONNECTING | XPC_C_CONNECTED);
1555
1556 ch->flags |= (XPC_C_CLOSEREQUEST | XPC_C_DISCONNECTING);
1557 xpc_IPI_send_closerequest(ch, irq_flags);
1558
1559 if (flags & XPC_C_CONNECTED) {
1560 ch->flags |= XPC_C_WASCONNECTED;
1561 }
1562
1563 if (atomic_read(&ch->kthreads_idle) > 0) {
1564 /* wake all idle kthreads so they can exit */
1565 wake_up_all(&ch->idle_wq);
1566 }
1567
1568 spin_unlock_irqrestore(&ch->lock, *irq_flags);
1569
1570
1571 /* wake those waiting to allocate an entry from the local msg queue */
1572
1573 if (atomic_read(&ch->n_on_msg_allocate_wq) > 0) {
1574 wake_up(&ch->msg_allocate_wq);
1575 }
1576
1577 /* wake those waiting for notify completion */
1578
1579 if (atomic_read(&ch->n_to_notify) > 0) {
1580 xpc_notify_senders(ch, reason, ch->w_local_GP.put);
1581 }
1582
1583 spin_lock_irqsave(&ch->lock, *irq_flags);
1584}
1585
1586
1587void
1588xpc_disconnected_callout(struct xpc_channel *ch)
1589{
1590 /*
1591 * Let the channel's registerer know that the channel is now
1592 * disconnected. We don't want to do this if the registerer was never
1593 * informed of a connection being made, unless the disconnect was for
1594 * abnormal reasons.
1595 */
1596
1597 if (ch->func != NULL) {
1598 dev_dbg(xpc_chan, "ch->func() called, reason=%d, partid=%d, "
1599 "channel=%d\n", ch->reason, ch->partid, ch->number);
1600
1601 ch->func(ch->reason, ch->partid, ch->number, NULL, ch->key);
1602
1603 dev_dbg(xpc_chan, "ch->func() returned, reason=%d, partid=%d, "
1604 "channel=%d\n", ch->reason, ch->partid, ch->number);
1605 }
1606}
1607
1608
1609/*
1610 * Wait for a message entry to become available for the specified channel,
1611 * but don't wait any longer than 1 jiffy.
1612 */
1613static enum xpc_retval
1614xpc_allocate_msg_wait(struct xpc_channel *ch)
1615{
1616 enum xpc_retval ret;
1617
1618
1619 if (ch->flags & XPC_C_DISCONNECTING) {
1620 DBUG_ON(ch->reason == xpcInterrupted); // >>> Is this true?
1621 return ch->reason;
1622 }
1623
1624 atomic_inc(&ch->n_on_msg_allocate_wq);
1625 ret = interruptible_sleep_on_timeout(&ch->msg_allocate_wq, 1);
1626 atomic_dec(&ch->n_on_msg_allocate_wq);
1627
1628 if (ch->flags & XPC_C_DISCONNECTING) {
1629 ret = ch->reason;
1630 DBUG_ON(ch->reason == xpcInterrupted); // >>> Is this true?
1631 } else if (ret == 0) {
1632 ret = xpcTimeout;
1633 } else {
1634 ret = xpcInterrupted;
1635 }
1636
1637 return ret;
1638}
1639
1640
1641/*
1642 * Allocate an entry for a message from the message queue associated with the
1643 * specified channel.
1644 */
1645static enum xpc_retval
1646xpc_allocate_msg(struct xpc_channel *ch, u32 flags,
1647 struct xpc_msg **address_of_msg)
1648{
1649 struct xpc_msg *msg;
1650 enum xpc_retval ret;
1651 s64 put;
1652
1653
1654 /* this reference will be dropped in xpc_send_msg() */
1655 xpc_msgqueue_ref(ch);
1656
1657 if (ch->flags & XPC_C_DISCONNECTING) {
1658 xpc_msgqueue_deref(ch);
1659 return ch->reason;
1660 }
1661 if (!(ch->flags & XPC_C_CONNECTED)) {
1662 xpc_msgqueue_deref(ch);
1663 return xpcNotConnected;
1664 }
1665
1666
1667 /*
1668 * Get the next available message entry from the local message queue.
1669 * If none are available, we'll make sure that we grab the latest
1670 * GP values.
1671 */
1672 ret = xpcTimeout;
1673
1674 while (1) {
1675
1676 put = (volatile s64) ch->w_local_GP.put;
1677 if (put - (volatile s64) ch->w_remote_GP.get <
1678 ch->local_nentries) {
1679
1680 /* There are available message entries. We need to try
1681 * to secure one for ourselves. We'll do this by trying
1682 * to increment w_local_GP.put as long as someone else
1683 * doesn't beat us to it. If they do, we'll have to
1684 * try again.
1685 */
1686 if (cmpxchg(&ch->w_local_GP.put, put, put + 1) ==
1687 put) {
1688 /* we got the entry referenced by put */
1689 break;
1690 }
1691 continue; /* try again */
1692 }
1693
1694
1695 /*
1696 * There aren't any available msg entries at this time.
1697 *
1698 * In waiting for a message entry to become available,
1699 * we set a timeout in case the other side is not
1700 * sending completion IPIs. This lets us fake an IPI
1701 * that will cause the IPI handler to fetch the latest
1702 * GP values as if an IPI was sent by the other side.
1703 */
1704 if (ret == xpcTimeout) {
1705 xpc_IPI_send_local_msgrequest(ch);
1706 }
1707
1708 if (flags & XPC_NOWAIT) {
1709 xpc_msgqueue_deref(ch);
1710 return xpcNoWait;
1711 }
1712
1713 ret = xpc_allocate_msg_wait(ch);
1714 if (ret != xpcInterrupted && ret != xpcTimeout) {
1715 xpc_msgqueue_deref(ch);
1716 return ret;
1717 }
1718 }
1719
1720
1721 /* get the message's address and initialize it */
1722 msg = (struct xpc_msg *) ((u64) ch->local_msgqueue +
1723 (put % ch->local_nentries) * ch->msg_size);
1724
1725
1726 DBUG_ON(msg->flags != 0);
1727 msg->number = put;
1728
1729 dev_dbg(xpc_chan, "w_local_GP.put changed to %ld; msg=0x%p, "
1730 "msg_number=%ld, partid=%d, channel=%d\n", put + 1,
1731 (void *) msg, msg->number, ch->partid, ch->number);
1732
1733 *address_of_msg = msg;
1734
1735 return xpcSuccess;
1736}
1737
1738
1739/*
1740 * Allocate an entry for a message from the message queue associated with the
1741 * specified channel. NOTE that this routine can sleep waiting for a message
1742 * entry to become available. To not sleep, pass in the XPC_NOWAIT flag.
1743 *
1744 * Arguments:
1745 *
1746 * partid - ID of partition to which the channel is connected.
1747 * ch_number - channel #.
1748 * flags - see xpc.h for valid flags.
1749 * payload - address of the allocated payload area pointer (filled in on
1750 * return) in which the user-defined message is constructed.
1751 */
1752enum xpc_retval
1753xpc_initiate_allocate(partid_t partid, int ch_number, u32 flags, void **payload)
1754{
1755 struct xpc_partition *part = &xpc_partitions[partid];
1756 enum xpc_retval ret = xpcUnknownReason;
1757 struct xpc_msg *msg;
1758
1759
1760 DBUG_ON(partid <= 0 || partid >= XP_MAX_PARTITIONS);
1761 DBUG_ON(ch_number < 0 || ch_number >= part->nchannels);
1762
1763 *payload = NULL;
1764
1765 if (xpc_part_ref(part)) {
1766 ret = xpc_allocate_msg(&part->channels[ch_number], flags, &msg);
1767 xpc_part_deref(part);
1768
1769 if (msg != NULL) {
1770 *payload = &msg->payload;
1771 }
1772 }
1773
1774 return ret;
1775}
1776
1777
1778/*
1779 * Now we actually send the messages that are ready to be sent by advancing
1780 * the local message queue's Put value and then send an IPI to the recipient
1781 * partition.
1782 */
1783static void
1784xpc_send_msgs(struct xpc_channel *ch, s64 initial_put)
1785{
1786 struct xpc_msg *msg;
1787 s64 put = initial_put + 1;
1788 int send_IPI = 0;
1789
1790
1791 while (1) {
1792
1793 while (1) {
1794 if (put == (volatile s64) ch->w_local_GP.put) {
1795 break;
1796 }
1797
1798 msg = (struct xpc_msg *) ((u64) ch->local_msgqueue +
1799 (put % ch->local_nentries) * ch->msg_size);
1800
1801 if (!(msg->flags & XPC_M_READY)) {
1802 break;
1803 }
1804
1805 put++;
1806 }
1807
1808 if (put == initial_put) {
1809 /* nothing's changed */
1810 break;
1811 }
1812
1813 if (cmpxchg_rel(&ch->local_GP->put, initial_put, put) !=
1814 initial_put) {
1815 /* someone else beat us to it */
1816 DBUG_ON((volatile s64) ch->local_GP->put < initial_put);
1817 break;
1818 }
1819
1820 /* we just set the new value of local_GP->put */
1821
1822 dev_dbg(xpc_chan, "local_GP->put changed to %ld, partid=%d, "
1823 "channel=%d\n", put, ch->partid, ch->number);
1824
1825 send_IPI = 1;
1826
1827 /*
1828 * We need to ensure that the message referenced by
1829 * local_GP->put is not XPC_M_READY or that local_GP->put
1830 * equals w_local_GP.put, so we'll go have a look.
1831 */
1832 initial_put = put;
1833 }
1834
1835 if (send_IPI) {
1836 xpc_IPI_send_msgrequest(ch);
1837 }
1838}
1839
1840
1841/*
1842 * Common code that does the actual sending of the message by advancing the
1843 * local message queue's Put value and sends an IPI to the partition the
1844 * message is being sent to.
1845 */
1846static enum xpc_retval
1847xpc_send_msg(struct xpc_channel *ch, struct xpc_msg *msg, u8 notify_type,
1848 xpc_notify_func func, void *key)
1849{
1850 enum xpc_retval ret = xpcSuccess;
1851 struct xpc_notify *notify = NULL; // >>> to keep the compiler happy!!
1852 s64 put, msg_number = msg->number;
1853
1854
1855 DBUG_ON(notify_type == XPC_N_CALL && func == NULL);
1856 DBUG_ON((((u64) msg - (u64) ch->local_msgqueue) / ch->msg_size) !=
1857 msg_number % ch->local_nentries);
1858 DBUG_ON(msg->flags & XPC_M_READY);
1859
1860 if (ch->flags & XPC_C_DISCONNECTING) {
1861 /* drop the reference grabbed in xpc_allocate_msg() */
1862 xpc_msgqueue_deref(ch);
1863 return ch->reason;
1864 }
1865
1866 if (notify_type != 0) {
1867 /*
1868 * Tell the remote side to send an ACK interrupt when the
1869 * message has been delivered.
1870 */
1871 msg->flags |= XPC_M_INTERRUPT;
1872
1873 atomic_inc(&ch->n_to_notify);
1874
1875 notify = &ch->notify_queue[msg_number % ch->local_nentries];
1876 notify->func = func;
1877 notify->key = key;
1878 (volatile u8) notify->type = notify_type;
1879
1880 // >>> is a mb() needed here?
1881
1882 if (ch->flags & XPC_C_DISCONNECTING) {
1883 /*
1884 * An error occurred between our last error check and
1885 * this one. We will try to clear the type field from
1886 * the notify entry. If we succeed then
1887 * xpc_disconnect_channel() didn't already process
1888 * the notify entry.
1889 */
1890 if (cmpxchg(&notify->type, notify_type, 0) ==
1891 notify_type) {
1892 atomic_dec(&ch->n_to_notify);
1893 ret = ch->reason;
1894 }
1895
1896 /* drop the reference grabbed in xpc_allocate_msg() */
1897 xpc_msgqueue_deref(ch);
1898 return ret;
1899 }
1900 }
1901
1902 msg->flags |= XPC_M_READY;
1903
1904 /*
1905 * The preceding store of msg->flags must occur before the following
1906 * load of ch->local_GP->put.
1907 */
1908 mb();
1909
1910 /* see if the message is next in line to be sent, if so send it */
1911
1912 put = ch->local_GP->put;
1913 if (put == msg_number) {
1914 xpc_send_msgs(ch, put);
1915 }
1916
1917 /* drop the reference grabbed in xpc_allocate_msg() */
1918 xpc_msgqueue_deref(ch);
1919 return ret;
1920}
1921
1922
1923/*
1924 * Send a message previously allocated using xpc_initiate_allocate() on the
1925 * specified channel connected to the specified partition.
1926 *
1927 * This routine will not wait for the message to be received, nor will
1928 * notification be given when it does happen. Once this routine has returned
1929 * the message entry allocated via xpc_initiate_allocate() is no longer
1930 * accessable to the caller.
1931 *
1932 * This routine, although called by users, does not call xpc_part_ref() to
1933 * ensure that the partition infrastructure is in place. It relies on the
1934 * fact that we called xpc_msgqueue_ref() in xpc_allocate_msg().
1935 *
1936 * Arguments:
1937 *
1938 * partid - ID of partition to which the channel is connected.
1939 * ch_number - channel # to send message on.
1940 * payload - pointer to the payload area allocated via
1941 * xpc_initiate_allocate().
1942 */
1943enum xpc_retval
1944xpc_initiate_send(partid_t partid, int ch_number, void *payload)
1945{
1946 struct xpc_partition *part = &xpc_partitions[partid];
1947 struct xpc_msg *msg = XPC_MSG_ADDRESS(payload);
1948 enum xpc_retval ret;
1949
1950
1951 dev_dbg(xpc_chan, "msg=0x%p, partid=%d, channel=%d\n", (void *) msg,
1952 partid, ch_number);
1953
1954 DBUG_ON(partid <= 0 || partid >= XP_MAX_PARTITIONS);
1955 DBUG_ON(ch_number < 0 || ch_number >= part->nchannels);
1956 DBUG_ON(msg == NULL);
1957
1958 ret = xpc_send_msg(&part->channels[ch_number], msg, 0, NULL, NULL);
1959
1960 return ret;
1961}
1962
1963
1964/*
1965 * Send a message previously allocated using xpc_initiate_allocate on the
1966 * specified channel connected to the specified partition.
1967 *
1968 * This routine will not wait for the message to be sent. Once this routine
1969 * has returned the message entry allocated via xpc_initiate_allocate() is no
1970 * longer accessable to the caller.
1971 *
1972 * Once the remote end of the channel has received the message, the function
1973 * passed as an argument to xpc_initiate_send_notify() will be called. This
1974 * allows the sender to free up or re-use any buffers referenced by the
1975 * message, but does NOT mean the message has been processed at the remote
1976 * end by a receiver.
1977 *
1978 * If this routine returns an error, the caller's function will NOT be called.
1979 *
1980 * This routine, although called by users, does not call xpc_part_ref() to
1981 * ensure that the partition infrastructure is in place. It relies on the
1982 * fact that we called xpc_msgqueue_ref() in xpc_allocate_msg().
1983 *
1984 * Arguments:
1985 *
1986 * partid - ID of partition to which the channel is connected.
1987 * ch_number - channel # to send message on.
1988 * payload - pointer to the payload area allocated via
1989 * xpc_initiate_allocate().
1990 * func - function to call with asynchronous notification of message
1991 * receipt. THIS FUNCTION MUST BE NON-BLOCKING.
1992 * key - user-defined key to be passed to the function when it's called.
1993 */
1994enum xpc_retval
1995xpc_initiate_send_notify(partid_t partid, int ch_number, void *payload,
1996 xpc_notify_func func, void *key)
1997{
1998 struct xpc_partition *part = &xpc_partitions[partid];
1999 struct xpc_msg *msg = XPC_MSG_ADDRESS(payload);
2000 enum xpc_retval ret;
2001
2002
2003 dev_dbg(xpc_chan, "msg=0x%p, partid=%d, channel=%d\n", (void *) msg,
2004 partid, ch_number);
2005
2006 DBUG_ON(partid <= 0 || partid >= XP_MAX_PARTITIONS);
2007 DBUG_ON(ch_number < 0 || ch_number >= part->nchannels);
2008 DBUG_ON(msg == NULL);
2009 DBUG_ON(func == NULL);
2010
2011 ret = xpc_send_msg(&part->channels[ch_number], msg, XPC_N_CALL,
2012 func, key);
2013 return ret;
2014}
2015
2016
2017static struct xpc_msg *
2018xpc_pull_remote_msg(struct xpc_channel *ch, s64 get)
2019{
2020 struct xpc_partition *part = &xpc_partitions[ch->partid];
2021 struct xpc_msg *remote_msg, *msg;
2022 u32 msg_index, nmsgs;
2023 u64 msg_offset;
2024 enum xpc_retval ret;
2025
2026
2027 if (down_interruptible(&ch->msg_to_pull_sema) != 0) {
2028 /* we were interrupted by a signal */
2029 return NULL;
2030 }
2031
2032 while (get >= ch->next_msg_to_pull) {
2033
2034 /* pull as many messages as are ready and able to be pulled */
2035
2036 msg_index = ch->next_msg_to_pull % ch->remote_nentries;
2037
2038 DBUG_ON(ch->next_msg_to_pull >=
2039 (volatile s64) ch->w_remote_GP.put);
2040 nmsgs = (volatile s64) ch->w_remote_GP.put -
2041 ch->next_msg_to_pull;
2042 if (msg_index + nmsgs > ch->remote_nentries) {
2043 /* ignore the ones that wrap the msg queue for now */
2044 nmsgs = ch->remote_nentries - msg_index;
2045 }
2046
2047 msg_offset = msg_index * ch->msg_size;
2048 msg = (struct xpc_msg *) ((u64) ch->remote_msgqueue +
2049 msg_offset);
2050 remote_msg = (struct xpc_msg *) (ch->remote_msgqueue_pa +
2051 msg_offset);
2052
2053 if ((ret = xpc_pull_remote_cachelines(part, msg, remote_msg,
2054 nmsgs * ch->msg_size)) != xpcSuccess) {
2055
2056 dev_dbg(xpc_chan, "failed to pull %d msgs starting with"
2057 " msg %ld from partition %d, channel=%d, "
2058 "ret=%d\n", nmsgs, ch->next_msg_to_pull,
2059 ch->partid, ch->number, ret);
2060
2061 XPC_DEACTIVATE_PARTITION(part, ret);
2062
2063 up(&ch->msg_to_pull_sema);
2064 return NULL;
2065 }
2066
2067 mb(); /* >>> this may not be needed, we're not sure */
2068
2069 ch->next_msg_to_pull += nmsgs;
2070 }
2071
2072 up(&ch->msg_to_pull_sema);
2073
2074 /* return the message we were looking for */
2075 msg_offset = (get % ch->remote_nentries) * ch->msg_size;
2076 msg = (struct xpc_msg *) ((u64) ch->remote_msgqueue + msg_offset);
2077
2078 return msg;
2079}
2080
2081
2082/*
2083 * Get a message to be delivered.
2084 */
2085static struct xpc_msg *
2086xpc_get_deliverable_msg(struct xpc_channel *ch)
2087{
2088 struct xpc_msg *msg = NULL;
2089 s64 get;
2090
2091
2092 do {
2093 if ((volatile u32) ch->flags & XPC_C_DISCONNECTING) {
2094 break;
2095 }
2096
2097 get = (volatile s64) ch->w_local_GP.get;
2098 if (get == (volatile s64) ch->w_remote_GP.put) {
2099 break;
2100 }
2101
2102 /* There are messages waiting to be pulled and delivered.
2103 * We need to try to secure one for ourselves. We'll do this
2104 * by trying to increment w_local_GP.get and hope that no one
2105 * else beats us to it. If they do, we'll we'll simply have
2106 * to try again for the next one.
2107 */
2108
2109 if (cmpxchg(&ch->w_local_GP.get, get, get + 1) == get) {
2110 /* we got the entry referenced by get */
2111
2112 dev_dbg(xpc_chan, "w_local_GP.get changed to %ld, "
2113 "partid=%d, channel=%d\n", get + 1,
2114 ch->partid, ch->number);
2115
2116 /* pull the message from the remote partition */
2117
2118 msg = xpc_pull_remote_msg(ch, get);
2119
2120 DBUG_ON(msg != NULL && msg->number != get);
2121 DBUG_ON(msg != NULL && (msg->flags & XPC_M_DONE));
2122 DBUG_ON(msg != NULL && !(msg->flags & XPC_M_READY));
2123
2124 break;
2125 }
2126
2127 } while (1);
2128
2129 return msg;
2130}
2131
2132
2133/*
2134 * Deliver a message to its intended recipient.
2135 */
2136void
2137xpc_deliver_msg(struct xpc_channel *ch)
2138{
2139 struct xpc_msg *msg;
2140
2141
2142 if ((msg = xpc_get_deliverable_msg(ch)) != NULL) {
2143
2144 /*
2145 * This ref is taken to protect the payload itself from being
2146 * freed before the user is finished with it, which the user
2147 * indicates by calling xpc_initiate_received().
2148 */
2149 xpc_msgqueue_ref(ch);
2150
2151 atomic_inc(&ch->kthreads_active);
2152
2153 if (ch->func != NULL) {
2154 dev_dbg(xpc_chan, "ch->func() called, msg=0x%p, "
2155 "msg_number=%ld, partid=%d, channel=%d\n",
2156 (void *) msg, msg->number, ch->partid,
2157 ch->number);
2158
2159 /* deliver the message to its intended recipient */
2160 ch->func(xpcMsgReceived, ch->partid, ch->number,
2161 &msg->payload, ch->key);
2162
2163 dev_dbg(xpc_chan, "ch->func() returned, msg=0x%p, "
2164 "msg_number=%ld, partid=%d, channel=%d\n",
2165 (void *) msg, msg->number, ch->partid,
2166 ch->number);
2167 }
2168
2169 atomic_dec(&ch->kthreads_active);
2170 }
2171}
2172
2173
2174/*
2175 * Now we actually acknowledge the messages that have been delivered and ack'd
2176 * by advancing the cached remote message queue's Get value and if requested
2177 * send an IPI to the message sender's partition.
2178 */
2179static void
2180xpc_acknowledge_msgs(struct xpc_channel *ch, s64 initial_get, u8 msg_flags)
2181{
2182 struct xpc_msg *msg;
2183 s64 get = initial_get + 1;
2184 int send_IPI = 0;
2185
2186
2187 while (1) {
2188
2189 while (1) {
2190 if (get == (volatile s64) ch->w_local_GP.get) {
2191 break;
2192 }
2193
2194 msg = (struct xpc_msg *) ((u64) ch->remote_msgqueue +
2195 (get % ch->remote_nentries) * ch->msg_size);
2196
2197 if (!(msg->flags & XPC_M_DONE)) {
2198 break;
2199 }
2200
2201 msg_flags |= msg->flags;
2202 get++;
2203 }
2204
2205 if (get == initial_get) {
2206 /* nothing's changed */
2207 break;
2208 }
2209
2210 if (cmpxchg_rel(&ch->local_GP->get, initial_get, get) !=
2211 initial_get) {
2212 /* someone else beat us to it */
2213 DBUG_ON((volatile s64) ch->local_GP->get <=
2214 initial_get);
2215 break;
2216 }
2217
2218 /* we just set the new value of local_GP->get */
2219
2220 dev_dbg(xpc_chan, "local_GP->get changed to %ld, partid=%d, "
2221 "channel=%d\n", get, ch->partid, ch->number);
2222
2223 send_IPI = (msg_flags & XPC_M_INTERRUPT);
2224
2225 /*
2226 * We need to ensure that the message referenced by
2227 * local_GP->get is not XPC_M_DONE or that local_GP->get
2228 * equals w_local_GP.get, so we'll go have a look.
2229 */
2230 initial_get = get;
2231 }
2232
2233 if (send_IPI) {
2234 xpc_IPI_send_msgrequest(ch);
2235 }
2236}
2237
2238
2239/*
2240 * Acknowledge receipt of a delivered message.
2241 *
2242 * If a message has XPC_M_INTERRUPT set, send an interrupt to the partition
2243 * that sent the message.
2244 *
2245 * This function, although called by users, does not call xpc_part_ref() to
2246 * ensure that the partition infrastructure is in place. It relies on the
2247 * fact that we called xpc_msgqueue_ref() in xpc_deliver_msg().
2248 *
2249 * Arguments:
2250 *
2251 * partid - ID of partition to which the channel is connected.
2252 * ch_number - channel # message received on.
2253 * payload - pointer to the payload area allocated via
2254 * xpc_initiate_allocate().
2255 */
2256void
2257xpc_initiate_received(partid_t partid, int ch_number, void *payload)
2258{
2259 struct xpc_partition *part = &xpc_partitions[partid];
2260 struct xpc_channel *ch;
2261 struct xpc_msg *msg = XPC_MSG_ADDRESS(payload);
2262 s64 get, msg_number = msg->number;
2263
2264
2265 DBUG_ON(partid <= 0 || partid >= XP_MAX_PARTITIONS);
2266 DBUG_ON(ch_number < 0 || ch_number >= part->nchannels);
2267
2268 ch = &part->channels[ch_number];
2269
2270 dev_dbg(xpc_chan, "msg=0x%p, msg_number=%ld, partid=%d, channel=%d\n",
2271 (void *) msg, msg_number, ch->partid, ch->number);
2272
2273 DBUG_ON((((u64) msg - (u64) ch->remote_msgqueue) / ch->msg_size) !=
2274 msg_number % ch->remote_nentries);
2275 DBUG_ON(msg->flags & XPC_M_DONE);
2276
2277 msg->flags |= XPC_M_DONE;
2278
2279 /*
2280 * The preceding store of msg->flags must occur before the following
2281 * load of ch->local_GP->get.
2282 */
2283 mb();
2284
2285 /*
2286 * See if this message is next in line to be acknowledged as having
2287 * been delivered.
2288 */
2289 get = ch->local_GP->get;
2290 if (get == msg_number) {
2291 xpc_acknowledge_msgs(ch, get, msg->flags);
2292 }
2293
2294 /* the call to xpc_msgqueue_ref() was done by xpc_deliver_msg() */
2295 xpc_msgqueue_deref(ch);
2296}
2297
diff --git a/arch/ia64/sn/kernel/xpc_main.c b/arch/ia64/sn/kernel/xpc_main.c
new file mode 100644
index 000000000000..177ddb748ebe
--- /dev/null
+++ b/arch/ia64/sn/kernel/xpc_main.c
@@ -0,0 +1,1064 @@
1/*
2 * This file is subject to the terms and conditions of the GNU General Public
3 * License. See the file "COPYING" in the main directory of this archive
4 * for more details.
5 *
6 * Copyright (c) 2004-2005 Silicon Graphics, Inc. All Rights Reserved.
7 */
8
9
10/*
11 * Cross Partition Communication (XPC) support - standard version.
12 *
13 * XPC provides a message passing capability that crosses partition
14 * boundaries. This module is made up of two parts:
15 *
16 * partition This part detects the presence/absence of other
17 * partitions. It provides a heartbeat and monitors
18 * the heartbeats of other partitions.
19 *
20 * channel This part manages the channels and sends/receives
21 * messages across them to/from other partitions.
22 *
23 * There are a couple of additional functions residing in XP, which
24 * provide an interface to XPC for its users.
25 *
26 *
27 * Caveats:
28 *
29 * . We currently have no way to determine which nasid an IPI came
30 * from. Thus, xpc_IPI_send() does a remote AMO write followed by
31 * an IPI. The AMO indicates where data is to be pulled from, so
32 * after the IPI arrives, the remote partition checks the AMO word.
33 * The IPI can actually arrive before the AMO however, so other code
34 * must periodically check for this case. Also, remote AMO operations
35 * do not reliably time out. Thus we do a remote PIO read solely to
36 * know whether the remote partition is down and whether we should
37 * stop sending IPIs to it. This remote PIO read operation is set up
38 * in a special nofault region so SAL knows to ignore (and cleanup)
39 * any errors due to the remote AMO write, PIO read, and/or PIO
40 * write operations.
41 *
42 * If/when new hardware solves this IPI problem, we should abandon
43 * the current approach.
44 *
45 */
46
47
48#include <linux/kernel.h>
49#include <linux/module.h>
50#include <linux/init.h>
51#include <linux/sched.h>
52#include <linux/syscalls.h>
53#include <linux/cache.h>
54#include <linux/interrupt.h>
55#include <linux/slab.h>
56#include <asm/sn/intr.h>
57#include <asm/sn/sn_sal.h>
58#include <asm/uaccess.h>
59#include "xpc.h"
60
61
62/* define two XPC debug device structures to be used with dev_dbg() et al */
63
64struct device_driver xpc_dbg_name = {
65 .name = "xpc"
66};
67
68struct device xpc_part_dbg_subname = {
69 .bus_id = {0}, /* set to "part" at xpc_init() time */
70 .driver = &xpc_dbg_name
71};
72
73struct device xpc_chan_dbg_subname = {
74 .bus_id = {0}, /* set to "chan" at xpc_init() time */
75 .driver = &xpc_dbg_name
76};
77
78struct device *xpc_part = &xpc_part_dbg_subname;
79struct device *xpc_chan = &xpc_chan_dbg_subname;
80
81
82/* systune related variables for /proc/sys directories */
83
84static int xpc_hb_min = 1;
85static int xpc_hb_max = 10;
86
87static int xpc_hb_check_min = 10;
88static int xpc_hb_check_max = 120;
89
90static ctl_table xpc_sys_xpc_hb_dir[] = {
91 {
92 1,
93 "hb_interval",
94 &xpc_hb_interval,
95 sizeof(int),
96 0644,
97 NULL,
98 &proc_dointvec_minmax,
99 &sysctl_intvec,
100 NULL,
101 &xpc_hb_min, &xpc_hb_max
102 },
103 {
104 2,
105 "hb_check_interval",
106 &xpc_hb_check_interval,
107 sizeof(int),
108 0644,
109 NULL,
110 &proc_dointvec_minmax,
111 &sysctl_intvec,
112 NULL,
113 &xpc_hb_check_min, &xpc_hb_check_max
114 },
115 {0}
116};
117static ctl_table xpc_sys_xpc_dir[] = {
118 {
119 1,
120 "hb",
121 NULL,
122 0,
123 0555,
124 xpc_sys_xpc_hb_dir
125 },
126 {0}
127};
128static ctl_table xpc_sys_dir[] = {
129 {
130 1,
131 "xpc",
132 NULL,
133 0,
134 0555,
135 xpc_sys_xpc_dir
136 },
137 {0}
138};
139static struct ctl_table_header *xpc_sysctl;
140
141
142/* #of IRQs received */
143static atomic_t xpc_act_IRQ_rcvd;
144
145/* IRQ handler notifies this wait queue on receipt of an IRQ */
146static DECLARE_WAIT_QUEUE_HEAD(xpc_act_IRQ_wq);
147
148static unsigned long xpc_hb_check_timeout;
149
150/* xpc_hb_checker thread exited notification */
151static DECLARE_MUTEX_LOCKED(xpc_hb_checker_exited);
152
153/* xpc_discovery thread exited notification */
154static DECLARE_MUTEX_LOCKED(xpc_discovery_exited);
155
156
157static struct timer_list xpc_hb_timer;
158
159
160static void xpc_kthread_waitmsgs(struct xpc_partition *, struct xpc_channel *);
161
162
163/*
164 * Notify the heartbeat check thread that an IRQ has been received.
165 */
166static irqreturn_t
167xpc_act_IRQ_handler(int irq, void *dev_id, struct pt_regs *regs)
168{
169 atomic_inc(&xpc_act_IRQ_rcvd);
170 wake_up_interruptible(&xpc_act_IRQ_wq);
171 return IRQ_HANDLED;
172}
173
174
175/*
176 * Timer to produce the heartbeat. The timer structures function is
177 * already set when this is initially called. A tunable is used to
178 * specify when the next timeout should occur.
179 */
180static void
181xpc_hb_beater(unsigned long dummy)
182{
183 xpc_vars->heartbeat++;
184
185 if (jiffies >= xpc_hb_check_timeout) {
186 wake_up_interruptible(&xpc_act_IRQ_wq);
187 }
188
189 xpc_hb_timer.expires = jiffies + (xpc_hb_interval * HZ);
190 add_timer(&xpc_hb_timer);
191}
192
193
194/*
195 * This thread is responsible for nearly all of the partition
196 * activation/deactivation.
197 */
198static int
199xpc_hb_checker(void *ignore)
200{
201 int last_IRQ_count = 0;
202 int new_IRQ_count;
203 int force_IRQ=0;
204
205
206 /* this thread was marked active by xpc_hb_init() */
207
208 daemonize(XPC_HB_CHECK_THREAD_NAME);
209
210 set_cpus_allowed(current, cpumask_of_cpu(XPC_HB_CHECK_CPU));
211
212 xpc_hb_check_timeout = jiffies + (xpc_hb_check_interval * HZ);
213
214 while (!(volatile int) xpc_exiting) {
215
216 /* wait for IRQ or timeout */
217 (void) wait_event_interruptible(xpc_act_IRQ_wq,
218 (last_IRQ_count < atomic_read(&xpc_act_IRQ_rcvd) ||
219 jiffies >= xpc_hb_check_timeout ||
220 (volatile int) xpc_exiting));
221
222 dev_dbg(xpc_part, "woke up with %d ticks rem; %d IRQs have "
223 "been received\n",
224 (int) (xpc_hb_check_timeout - jiffies),
225 atomic_read(&xpc_act_IRQ_rcvd) - last_IRQ_count);
226
227
228 /* checking of remote heartbeats is skewed by IRQ handling */
229 if (jiffies >= xpc_hb_check_timeout) {
230 dev_dbg(xpc_part, "checking remote heartbeats\n");
231 xpc_check_remote_hb();
232
233 /*
234 * We need to periodically recheck to ensure no
235 * IPI/AMO pairs have been missed. That check
236 * must always reset xpc_hb_check_timeout.
237 */
238 force_IRQ = 1;
239 }
240
241
242 new_IRQ_count = atomic_read(&xpc_act_IRQ_rcvd);
243 if (last_IRQ_count < new_IRQ_count || force_IRQ != 0) {
244 force_IRQ = 0;
245
246 dev_dbg(xpc_part, "found an IRQ to process; will be "
247 "resetting xpc_hb_check_timeout\n");
248
249 last_IRQ_count += xpc_identify_act_IRQ_sender();
250 if (last_IRQ_count < new_IRQ_count) {
251 /* retry once to help avoid missing AMO */
252 (void) xpc_identify_act_IRQ_sender();
253 }
254 last_IRQ_count = new_IRQ_count;
255
256 xpc_hb_check_timeout = jiffies +
257 (xpc_hb_check_interval * HZ);
258 }
259 }
260
261 dev_dbg(xpc_part, "heartbeat checker is exiting\n");
262
263
264 /* mark this thread as inactive */
265 up(&xpc_hb_checker_exited);
266 return 0;
267}
268
269
270/*
271 * This thread will attempt to discover other partitions to activate
272 * based on info provided by SAL. This new thread is short lived and
273 * will exit once discovery is complete.
274 */
275static int
276xpc_initiate_discovery(void *ignore)
277{
278 daemonize(XPC_DISCOVERY_THREAD_NAME);
279
280 xpc_discovery();
281
282 dev_dbg(xpc_part, "discovery thread is exiting\n");
283
284 /* mark this thread as inactive */
285 up(&xpc_discovery_exited);
286 return 0;
287}
288
289
290/*
291 * Establish first contact with the remote partititon. This involves pulling
292 * the XPC per partition variables from the remote partition and waiting for
293 * the remote partition to pull ours.
294 */
295static enum xpc_retval
296xpc_make_first_contact(struct xpc_partition *part)
297{
298 enum xpc_retval ret;
299
300
301 while ((ret = xpc_pull_remote_vars_part(part)) != xpcSuccess) {
302 if (ret != xpcRetry) {
303 XPC_DEACTIVATE_PARTITION(part, ret);
304 return ret;
305 }
306
307 dev_dbg(xpc_chan, "waiting to make first contact with "
308 "partition %d\n", XPC_PARTID(part));
309
310 /* wait a 1/4 of a second or so */
311 set_current_state(TASK_INTERRUPTIBLE);
312 (void) schedule_timeout(0.25 * HZ);
313
314 if (part->act_state == XPC_P_DEACTIVATING) {
315 return part->reason;
316 }
317 }
318
319 return xpc_mark_partition_active(part);
320}
321
322
323/*
324 * The first kthread assigned to a newly activated partition is the one
325 * created by XPC HB with which it calls xpc_partition_up(). XPC hangs on to
326 * that kthread until the partition is brought down, at which time that kthread
327 * returns back to XPC HB. (The return of that kthread will signify to XPC HB
328 * that XPC has dismantled all communication infrastructure for the associated
329 * partition.) This kthread becomes the channel manager for that partition.
330 *
331 * Each active partition has a channel manager, who, besides connecting and
332 * disconnecting channels, will ensure that each of the partition's connected
333 * channels has the required number of assigned kthreads to get the work done.
334 */
335static void
336xpc_channel_mgr(struct xpc_partition *part)
337{
338 while (part->act_state != XPC_P_DEACTIVATING ||
339 atomic_read(&part->nchannels_active) > 0) {
340
341 xpc_process_channel_activity(part);
342
343
344 /*
345 * Wait until we've been requested to activate kthreads or
346 * all of the channel's message queues have been torn down or
347 * a signal is pending.
348 *
349 * The channel_mgr_requests is set to 1 after being awakened,
350 * This is done to prevent the channel mgr from making one pass
351 * through the loop for each request, since he will
352 * be servicing all the requests in one pass. The reason it's
353 * set to 1 instead of 0 is so that other kthreads will know
354 * that the channel mgr is running and won't bother trying to
355 * wake him up.
356 */
357 atomic_dec(&part->channel_mgr_requests);
358 (void) wait_event_interruptible(part->channel_mgr_wq,
359 (atomic_read(&part->channel_mgr_requests) > 0 ||
360 (volatile u64) part->local_IPI_amo != 0 ||
361 ((volatile u8) part->act_state ==
362 XPC_P_DEACTIVATING &&
363 atomic_read(&part->nchannels_active) == 0)));
364 atomic_set(&part->channel_mgr_requests, 1);
365
366 // >>> Does it need to wakeup periodically as well? In case we
367 // >>> miscalculated the #of kthreads to wakeup or create?
368 }
369}
370
371
372/*
373 * When XPC HB determines that a partition has come up, it will create a new
374 * kthread and that kthread will call this function to attempt to set up the
375 * basic infrastructure used for Cross Partition Communication with the newly
376 * upped partition.
377 *
378 * The kthread that was created by XPC HB and which setup the XPC
379 * infrastructure will remain assigned to the partition until the partition
380 * goes down. At which time the kthread will teardown the XPC infrastructure
381 * and then exit.
382 *
383 * XPC HB will put the remote partition's XPC per partition specific variables
384 * physical address into xpc_partitions[partid].remote_vars_part_pa prior to
385 * calling xpc_partition_up().
386 */
387static void
388xpc_partition_up(struct xpc_partition *part)
389{
390 DBUG_ON(part->channels != NULL);
391
392 dev_dbg(xpc_chan, "activating partition %d\n", XPC_PARTID(part));
393
394 if (xpc_setup_infrastructure(part) != xpcSuccess) {
395 return;
396 }
397
398 /*
399 * The kthread that XPC HB called us with will become the
400 * channel manager for this partition. It will not return
401 * back to XPC HB until the partition's XPC infrastructure
402 * has been dismantled.
403 */
404
405 (void) xpc_part_ref(part); /* this will always succeed */
406
407 if (xpc_make_first_contact(part) == xpcSuccess) {
408 xpc_channel_mgr(part);
409 }
410
411 xpc_part_deref(part);
412
413 xpc_teardown_infrastructure(part);
414}
415
416
417static int
418xpc_activating(void *__partid)
419{
420 partid_t partid = (u64) __partid;
421 struct xpc_partition *part = &xpc_partitions[partid];
422 unsigned long irq_flags;
423 struct sched_param param = { sched_priority: MAX_USER_RT_PRIO - 1 };
424 int ret;
425
426
427 DBUG_ON(partid <= 0 || partid >= XP_MAX_PARTITIONS);
428
429 spin_lock_irqsave(&part->act_lock, irq_flags);
430
431 if (part->act_state == XPC_P_DEACTIVATING) {
432 part->act_state = XPC_P_INACTIVE;
433 spin_unlock_irqrestore(&part->act_lock, irq_flags);
434 part->remote_rp_pa = 0;
435 return 0;
436 }
437
438 /* indicate the thread is activating */
439 DBUG_ON(part->act_state != XPC_P_ACTIVATION_REQ);
440 part->act_state = XPC_P_ACTIVATING;
441
442 XPC_SET_REASON(part, 0, 0);
443 spin_unlock_irqrestore(&part->act_lock, irq_flags);
444
445 dev_dbg(xpc_part, "bringing partition %d up\n", partid);
446
447 daemonize("xpc%02d", partid);
448
449 /*
450 * This thread needs to run at a realtime priority to prevent a
451 * significant performance degradation.
452 */
453 ret = sched_setscheduler(current, SCHED_FIFO, &param);
454 if (ret != 0) {
455 dev_warn(xpc_part, "unable to set pid %d to a realtime "
456 "priority, ret=%d\n", current->pid, ret);
457 }
458
459 /* allow this thread and its children to run on any CPU */
460 set_cpus_allowed(current, CPU_MASK_ALL);
461
462 /*
463 * Register the remote partition's AMOs with SAL so it can handle
464 * and cleanup errors within that address range should the remote
465 * partition go down. We don't unregister this range because it is
466 * difficult to tell when outstanding writes to the remote partition
467 * are finished and thus when it is safe to unregister. This should
468 * not result in wasted space in the SAL xp_addr_region table because
469 * we should get the same page for remote_amos_page_pa after module
470 * reloads and system reboots.
471 */
472 if (sn_register_xp_addr_region(part->remote_amos_page_pa,
473 PAGE_SIZE, 1) < 0) {
474 dev_warn(xpc_part, "xpc_partition_up(%d) failed to register "
475 "xp_addr region\n", partid);
476
477 spin_lock_irqsave(&part->act_lock, irq_flags);
478 part->act_state = XPC_P_INACTIVE;
479 XPC_SET_REASON(part, xpcPhysAddrRegFailed, __LINE__);
480 spin_unlock_irqrestore(&part->act_lock, irq_flags);
481 part->remote_rp_pa = 0;
482 return 0;
483 }
484
485 XPC_ALLOW_HB(partid, xpc_vars);
486 xpc_IPI_send_activated(part);
487
488
489 /*
490 * xpc_partition_up() holds this thread and marks this partition as
491 * XPC_P_ACTIVE by calling xpc_hb_mark_active().
492 */
493 (void) xpc_partition_up(part);
494
495 xpc_mark_partition_inactive(part);
496
497 if (part->reason == xpcReactivating) {
498 /* interrupting ourselves results in activating partition */
499 xpc_IPI_send_reactivate(part);
500 }
501
502 return 0;
503}
504
505
506void
507xpc_activate_partition(struct xpc_partition *part)
508{
509 partid_t partid = XPC_PARTID(part);
510 unsigned long irq_flags;
511 pid_t pid;
512
513
514 spin_lock_irqsave(&part->act_lock, irq_flags);
515
516 pid = kernel_thread(xpc_activating, (void *) ((u64) partid), 0);
517
518 DBUG_ON(part->act_state != XPC_P_INACTIVE);
519
520 if (pid > 0) {
521 part->act_state = XPC_P_ACTIVATION_REQ;
522 XPC_SET_REASON(part, xpcCloneKThread, __LINE__);
523 } else {
524 XPC_SET_REASON(part, xpcCloneKThreadFailed, __LINE__);
525 }
526
527 spin_unlock_irqrestore(&part->act_lock, irq_flags);
528}
529
530
531/*
532 * Handle the receipt of a SGI_XPC_NOTIFY IRQ by seeing whether the specified
533 * partition actually sent it. Since SGI_XPC_NOTIFY IRQs may be shared by more
534 * than one partition, we use an AMO_t structure per partition to indicate
535 * whether a partition has sent an IPI or not. >>> If it has, then wake up the
536 * associated kthread to handle it.
537 *
538 * All SGI_XPC_NOTIFY IRQs received by XPC are the result of IPIs sent by XPC
539 * running on other partitions.
540 *
541 * Noteworthy Arguments:
542 *
543 * irq - Interrupt ReQuest number. NOT USED.
544 *
545 * dev_id - partid of IPI's potential sender.
546 *
547 * regs - processor's context before the processor entered
548 * interrupt code. NOT USED.
549 */
550irqreturn_t
551xpc_notify_IRQ_handler(int irq, void *dev_id, struct pt_regs *regs)
552{
553 partid_t partid = (partid_t) (u64) dev_id;
554 struct xpc_partition *part = &xpc_partitions[partid];
555
556
557 DBUG_ON(partid <= 0 || partid >= XP_MAX_PARTITIONS);
558
559 if (xpc_part_ref(part)) {
560 xpc_check_for_channel_activity(part);
561
562 xpc_part_deref(part);
563 }
564 return IRQ_HANDLED;
565}
566
567
568/*
569 * Check to see if xpc_notify_IRQ_handler() dropped any IPIs on the floor
570 * because the write to their associated IPI amo completed after the IRQ/IPI
571 * was received.
572 */
573void
574xpc_dropped_IPI_check(struct xpc_partition *part)
575{
576 if (xpc_part_ref(part)) {
577 xpc_check_for_channel_activity(part);
578
579 part->dropped_IPI_timer.expires = jiffies +
580 XPC_P_DROPPED_IPI_WAIT;
581 add_timer(&part->dropped_IPI_timer);
582 xpc_part_deref(part);
583 }
584}
585
586
587void
588xpc_activate_kthreads(struct xpc_channel *ch, int needed)
589{
590 int idle = atomic_read(&ch->kthreads_idle);
591 int assigned = atomic_read(&ch->kthreads_assigned);
592 int wakeup;
593
594
595 DBUG_ON(needed <= 0);
596
597 if (idle > 0) {
598 wakeup = (needed > idle) ? idle : needed;
599 needed -= wakeup;
600
601 dev_dbg(xpc_chan, "wakeup %d idle kthreads, partid=%d, "
602 "channel=%d\n", wakeup, ch->partid, ch->number);
603
604 /* only wakeup the requested number of kthreads */
605 wake_up_nr(&ch->idle_wq, wakeup);
606 }
607
608 if (needed <= 0) {
609 return;
610 }
611
612 if (needed + assigned > ch->kthreads_assigned_limit) {
613 needed = ch->kthreads_assigned_limit - assigned;
614 // >>>should never be less than 0
615 if (needed <= 0) {
616 return;
617 }
618 }
619
620 dev_dbg(xpc_chan, "create %d new kthreads, partid=%d, channel=%d\n",
621 needed, ch->partid, ch->number);
622
623 xpc_create_kthreads(ch, needed);
624}
625
626
627/*
628 * This function is where XPC's kthreads wait for messages to deliver.
629 */
630static void
631xpc_kthread_waitmsgs(struct xpc_partition *part, struct xpc_channel *ch)
632{
633 do {
634 /* deliver messages to their intended recipients */
635
636 while ((volatile s64) ch->w_local_GP.get <
637 (volatile s64) ch->w_remote_GP.put &&
638 !((volatile u32) ch->flags &
639 XPC_C_DISCONNECTING)) {
640 xpc_deliver_msg(ch);
641 }
642
643 if (atomic_inc_return(&ch->kthreads_idle) >
644 ch->kthreads_idle_limit) {
645 /* too many idle kthreads on this channel */
646 atomic_dec(&ch->kthreads_idle);
647 break;
648 }
649
650 dev_dbg(xpc_chan, "idle kthread calling "
651 "wait_event_interruptible_exclusive()\n");
652
653 (void) wait_event_interruptible_exclusive(ch->idle_wq,
654 ((volatile s64) ch->w_local_GP.get <
655 (volatile s64) ch->w_remote_GP.put ||
656 ((volatile u32) ch->flags &
657 XPC_C_DISCONNECTING)));
658
659 atomic_dec(&ch->kthreads_idle);
660
661 } while (!((volatile u32) ch->flags & XPC_C_DISCONNECTING));
662}
663
664
665static int
666xpc_daemonize_kthread(void *args)
667{
668 partid_t partid = XPC_UNPACK_ARG1(args);
669 u16 ch_number = XPC_UNPACK_ARG2(args);
670 struct xpc_partition *part = &xpc_partitions[partid];
671 struct xpc_channel *ch;
672 int n_needed;
673
674
675 daemonize("xpc%02dc%d", partid, ch_number);
676
677 dev_dbg(xpc_chan, "kthread starting, partid=%d, channel=%d\n",
678 partid, ch_number);
679
680 ch = &part->channels[ch_number];
681
682 if (!(ch->flags & XPC_C_DISCONNECTING)) {
683 DBUG_ON(!(ch->flags & XPC_C_CONNECTED));
684
685 /* let registerer know that connection has been established */
686
687 if (atomic_read(&ch->kthreads_assigned) == 1) {
688 xpc_connected_callout(ch);
689
690 /*
691 * It is possible that while the callout was being
692 * made that the remote partition sent some messages.
693 * If that is the case, we may need to activate
694 * additional kthreads to help deliver them. We only
695 * need one less than total #of messages to deliver.
696 */
697 n_needed = ch->w_remote_GP.put - ch->w_local_GP.get - 1;
698 if (n_needed > 0 &&
699 !(ch->flags & XPC_C_DISCONNECTING)) {
700 xpc_activate_kthreads(ch, n_needed);
701 }
702 }
703
704 xpc_kthread_waitmsgs(part, ch);
705 }
706
707 if (atomic_dec_return(&ch->kthreads_assigned) == 0 &&
708 ((ch->flags & XPC_C_CONNECTCALLOUT) ||
709 (ch->reason != xpcUnregistering &&
710 ch->reason != xpcOtherUnregistering))) {
711 xpc_disconnected_callout(ch);
712 }
713
714
715 xpc_msgqueue_deref(ch);
716
717 dev_dbg(xpc_chan, "kthread exiting, partid=%d, channel=%d\n",
718 partid, ch_number);
719
720 xpc_part_deref(part);
721 return 0;
722}
723
724
725/*
726 * For each partition that XPC has established communications with, there is
727 * a minimum of one kernel thread assigned to perform any operation that
728 * may potentially sleep or block (basically the callouts to the asynchronous
729 * functions registered via xpc_connect()).
730 *
731 * Additional kthreads are created and destroyed by XPC as the workload
732 * demands.
733 *
734 * A kthread is assigned to one of the active channels that exists for a given
735 * partition.
736 */
737void
738xpc_create_kthreads(struct xpc_channel *ch, int needed)
739{
740 unsigned long irq_flags;
741 pid_t pid;
742 u64 args = XPC_PACK_ARGS(ch->partid, ch->number);
743
744
745 while (needed-- > 0) {
746 pid = kernel_thread(xpc_daemonize_kthread, (void *) args, 0);
747 if (pid < 0) {
748 /* the fork failed */
749
750 if (atomic_read(&ch->kthreads_assigned) <
751 ch->kthreads_idle_limit) {
752 /*
753 * Flag this as an error only if we have an
754 * insufficient #of kthreads for the channel
755 * to function.
756 *
757 * No xpc_msgqueue_ref() is needed here since
758 * the channel mgr is doing this.
759 */
760 spin_lock_irqsave(&ch->lock, irq_flags);
761 XPC_DISCONNECT_CHANNEL(ch, xpcLackOfResources,
762 &irq_flags);
763 spin_unlock_irqrestore(&ch->lock, irq_flags);
764 }
765 break;
766 }
767
768 /*
769 * The following is done on behalf of the newly created
770 * kthread. That kthread is responsible for doing the
771 * counterpart to the following before it exits.
772 */
773 (void) xpc_part_ref(&xpc_partitions[ch->partid]);
774 xpc_msgqueue_ref(ch);
775 atomic_inc(&ch->kthreads_assigned);
776 ch->kthreads_created++; // >>> temporary debug only!!!
777 }
778}
779
780
781void
782xpc_disconnect_wait(int ch_number)
783{
784 partid_t partid;
785 struct xpc_partition *part;
786 struct xpc_channel *ch;
787
788
789 /* now wait for all callouts to the caller's function to cease */
790 for (partid = 1; partid < XP_MAX_PARTITIONS; partid++) {
791 part = &xpc_partitions[partid];
792
793 if (xpc_part_ref(part)) {
794 ch = &part->channels[ch_number];
795
796// >>> how do we keep from falling into the window between our check and going
797// >>> down and coming back up where sema is re-inited?
798 if (ch->flags & XPC_C_SETUP) {
799 (void) down(&ch->teardown_sema);
800 }
801
802 xpc_part_deref(part);
803 }
804 }
805}
806
807
808static void
809xpc_do_exit(void)
810{
811 partid_t partid;
812 int active_part_count;
813 struct xpc_partition *part;
814
815
816 /* now it's time to eliminate our heartbeat */
817 del_timer_sync(&xpc_hb_timer);
818 xpc_vars->heartbeating_to_mask = 0;
819
820 /* indicate to others that our reserved page is uninitialized */
821 xpc_rsvd_page->vars_pa = 0;
822
823 /*
824 * Ignore all incoming interrupts. Without interupts the heartbeat
825 * checker won't activate any new partitions that may come up.
826 */
827 free_irq(SGI_XPC_ACTIVATE, NULL);
828
829 /*
830 * Cause the heartbeat checker and the discovery threads to exit.
831 * We don't want them attempting to activate new partitions as we
832 * try to deactivate the existing ones.
833 */
834 xpc_exiting = 1;
835 wake_up_interruptible(&xpc_act_IRQ_wq);
836
837 /* wait for the heartbeat checker thread to mark itself inactive */
838 down(&xpc_hb_checker_exited);
839
840 /* wait for the discovery thread to mark itself inactive */
841 down(&xpc_discovery_exited);
842
843
844 set_current_state(TASK_INTERRUPTIBLE);
845 schedule_timeout(0.3 * HZ);
846 set_current_state(TASK_RUNNING);
847
848
849 /* wait for all partitions to become inactive */
850
851 do {
852 active_part_count = 0;
853
854 for (partid = 1; partid < XP_MAX_PARTITIONS; partid++) {
855 part = &xpc_partitions[partid];
856 if (part->act_state != XPC_P_INACTIVE) {
857 active_part_count++;
858
859 XPC_DEACTIVATE_PARTITION(part, xpcUnloading);
860 }
861 }
862
863 if (active_part_count) {
864 set_current_state(TASK_INTERRUPTIBLE);
865 schedule_timeout(0.3 * HZ);
866 set_current_state(TASK_RUNNING);
867 }
868
869 } while (active_part_count > 0);
870
871
872 /* close down protections for IPI operations */
873 xpc_restrict_IPI_ops();
874
875
876 /* clear the interface to XPC's functions */
877 xpc_clear_interface();
878
879 if (xpc_sysctl) {
880 unregister_sysctl_table(xpc_sysctl);
881 }
882}
883
884
885int __init
886xpc_init(void)
887{
888 int ret;
889 partid_t partid;
890 struct xpc_partition *part;
891 pid_t pid;
892
893
894 /*
895 * xpc_remote_copy_buffer is used as a temporary buffer for bte_copy'ng
896 * both a partition's reserved page and its XPC variables. Its size was
897 * based on the size of a reserved page. So we need to ensure that the
898 * XPC variables will fit as well.
899 */
900 if (XPC_VARS_ALIGNED_SIZE > XPC_RSVD_PAGE_ALIGNED_SIZE) {
901 dev_err(xpc_part, "xpc_remote_copy_buffer is not big enough\n");
902 return -EPERM;
903 }
904 DBUG_ON((u64) xpc_remote_copy_buffer !=
905 L1_CACHE_ALIGN((u64) xpc_remote_copy_buffer));
906
907 snprintf(xpc_part->bus_id, BUS_ID_SIZE, "part");
908 snprintf(xpc_chan->bus_id, BUS_ID_SIZE, "chan");
909
910 xpc_sysctl = register_sysctl_table(xpc_sys_dir, 1);
911
912 /*
913 * The first few fields of each entry of xpc_partitions[] need to
914 * be initialized now so that calls to xpc_connect() and
915 * xpc_disconnect() can be made prior to the activation of any remote
916 * partition. NOTE THAT NONE OF THE OTHER FIELDS BELONGING TO THESE
917 * ENTRIES ARE MEANINGFUL UNTIL AFTER AN ENTRY'S CORRESPONDING
918 * PARTITION HAS BEEN ACTIVATED.
919 */
920 for (partid = 1; partid < XP_MAX_PARTITIONS; partid++) {
921 part = &xpc_partitions[partid];
922
923 DBUG_ON((u64) part != L1_CACHE_ALIGN((u64) part));
924
925 part->act_IRQ_rcvd = 0;
926 spin_lock_init(&part->act_lock);
927 part->act_state = XPC_P_INACTIVE;
928 XPC_SET_REASON(part, 0, 0);
929 part->setup_state = XPC_P_UNSET;
930 init_waitqueue_head(&part->teardown_wq);
931 atomic_set(&part->references, 0);
932 }
933
934 /*
935 * Open up protections for IPI operations (and AMO operations on
936 * Shub 1.1 systems).
937 */
938 xpc_allow_IPI_ops();
939
940 /*
941 * Interrupts being processed will increment this atomic variable and
942 * awaken the heartbeat thread which will process the interrupts.
943 */
944 atomic_set(&xpc_act_IRQ_rcvd, 0);
945
946 /*
947 * This is safe to do before the xpc_hb_checker thread has started
948 * because the handler releases a wait queue. If an interrupt is
949 * received before the thread is waiting, it will not go to sleep,
950 * but rather immediately process the interrupt.
951 */
952 ret = request_irq(SGI_XPC_ACTIVATE, xpc_act_IRQ_handler, 0,
953 "xpc hb", NULL);
954 if (ret != 0) {
955 dev_err(xpc_part, "can't register ACTIVATE IRQ handler, "
956 "errno=%d\n", -ret);
957
958 xpc_restrict_IPI_ops();
959
960 if (xpc_sysctl) {
961 unregister_sysctl_table(xpc_sysctl);
962 }
963 return -EBUSY;
964 }
965
966 /*
967 * Fill the partition reserved page with the information needed by
968 * other partitions to discover we are alive and establish initial
969 * communications.
970 */
971 xpc_rsvd_page = xpc_rsvd_page_init();
972 if (xpc_rsvd_page == NULL) {
973 dev_err(xpc_part, "could not setup our reserved page\n");
974
975 free_irq(SGI_XPC_ACTIVATE, NULL);
976 xpc_restrict_IPI_ops();
977
978 if (xpc_sysctl) {
979 unregister_sysctl_table(xpc_sysctl);
980 }
981 return -EBUSY;
982 }
983
984
985 /*
986 * Set the beating to other partitions into motion. This is
987 * the last requirement for other partitions' discovery to
988 * initiate communications with us.
989 */
990 init_timer(&xpc_hb_timer);
991 xpc_hb_timer.function = xpc_hb_beater;
992 xpc_hb_beater(0);
993
994
995 /*
996 * The real work-horse behind xpc. This processes incoming
997 * interrupts and monitors remote heartbeats.
998 */
999 pid = kernel_thread(xpc_hb_checker, NULL, 0);
1000 if (pid < 0) {
1001 dev_err(xpc_part, "failed while forking hb check thread\n");
1002
1003 /* indicate to others that our reserved page is uninitialized */
1004 xpc_rsvd_page->vars_pa = 0;
1005
1006 del_timer_sync(&xpc_hb_timer);
1007 free_irq(SGI_XPC_ACTIVATE, NULL);
1008 xpc_restrict_IPI_ops();
1009
1010 if (xpc_sysctl) {
1011 unregister_sysctl_table(xpc_sysctl);
1012 }
1013 return -EBUSY;
1014 }
1015
1016
1017 /*
1018 * Startup a thread that will attempt to discover other partitions to
1019 * activate based on info provided by SAL. This new thread is short
1020 * lived and will exit once discovery is complete.
1021 */
1022 pid = kernel_thread(xpc_initiate_discovery, NULL, 0);
1023 if (pid < 0) {
1024 dev_err(xpc_part, "failed while forking discovery thread\n");
1025
1026 /* mark this new thread as a non-starter */
1027 up(&xpc_discovery_exited);
1028
1029 xpc_do_exit();
1030 return -EBUSY;
1031 }
1032
1033
1034 /* set the interface to point at XPC's functions */
1035 xpc_set_interface(xpc_initiate_connect, xpc_initiate_disconnect,
1036 xpc_initiate_allocate, xpc_initiate_send,
1037 xpc_initiate_send_notify, xpc_initiate_received,
1038 xpc_initiate_partid_to_nasids);
1039
1040 return 0;
1041}
1042module_init(xpc_init);
1043
1044
1045void __exit
1046xpc_exit(void)
1047{
1048 xpc_do_exit();
1049}
1050module_exit(xpc_exit);
1051
1052
1053MODULE_AUTHOR("Silicon Graphics, Inc.");
1054MODULE_DESCRIPTION("Cross Partition Communication (XPC) support");
1055MODULE_LICENSE("GPL");
1056
1057module_param(xpc_hb_interval, int, 0);
1058MODULE_PARM_DESC(xpc_hb_interval, "Number of seconds between "
1059 "heartbeat increments.");
1060
1061module_param(xpc_hb_check_interval, int, 0);
1062MODULE_PARM_DESC(xpc_hb_check_interval, "Number of seconds between "
1063 "heartbeat checks.");
1064
diff --git a/arch/ia64/sn/kernel/xpc_partition.c b/arch/ia64/sn/kernel/xpc_partition.c
new file mode 100644
index 000000000000..b31d9988a37a
--- /dev/null
+++ b/arch/ia64/sn/kernel/xpc_partition.c
@@ -0,0 +1,971 @@
1/*
2 * This file is subject to the terms and conditions of the GNU General Public
3 * License. See the file "COPYING" in the main directory of this archive
4 * for more details.
5 *
6 * Copyright (c) 2004-2005 Silicon Graphics, Inc. All Rights Reserved.
7 */
8
9
10/*
11 * Cross Partition Communication (XPC) partition support.
12 *
13 * This is the part of XPC that detects the presence/absence of
14 * other partitions. It provides a heartbeat and monitors the
15 * heartbeats of other partitions.
16 *
17 */
18
19
20#include <linux/kernel.h>
21#include <linux/sysctl.h>
22#include <linux/cache.h>
23#include <linux/mmzone.h>
24#include <linux/nodemask.h>
25#include <asm/sn/bte.h>
26#include <asm/sn/intr.h>
27#include <asm/sn/sn_sal.h>
28#include <asm/sn/nodepda.h>
29#include <asm/sn/addrs.h>
30#include "xpc.h"
31
32
33/* XPC is exiting flag */
34int xpc_exiting;
35
36
37/* SH_IPI_ACCESS shub register value on startup */
38static u64 xpc_sh1_IPI_access;
39static u64 xpc_sh2_IPI_access0;
40static u64 xpc_sh2_IPI_access1;
41static u64 xpc_sh2_IPI_access2;
42static u64 xpc_sh2_IPI_access3;
43
44
45/* original protection values for each node */
46u64 xpc_prot_vec[MAX_COMPACT_NODES];
47
48
49/* this partition's reserved page */
50struct xpc_rsvd_page *xpc_rsvd_page;
51
52/* this partition's XPC variables (within the reserved page) */
53struct xpc_vars *xpc_vars;
54struct xpc_vars_part *xpc_vars_part;
55
56
57/*
58 * For performance reasons, each entry of xpc_partitions[] is cacheline
59 * aligned. And xpc_partitions[] is padded with an additional entry at the
60 * end so that the last legitimate entry doesn't share its cacheline with
61 * another variable.
62 */
63struct xpc_partition xpc_partitions[XP_MAX_PARTITIONS + 1];
64
65
66/*
67 * Generic buffer used to store a local copy of the remote partitions
68 * reserved page or XPC variables.
69 *
70 * xpc_discovery runs only once and is a seperate thread that is
71 * very likely going to be processing in parallel with receiving
72 * interrupts.
73 */
74char ____cacheline_aligned
75 xpc_remote_copy_buffer[XPC_RSVD_PAGE_ALIGNED_SIZE];
76
77
78/* systune related variables */
79int xpc_hb_interval = XPC_HB_DEFAULT_INTERVAL;
80int xpc_hb_check_interval = XPC_HB_CHECK_DEFAULT_TIMEOUT;
81
82
83/*
84 * Given a nasid, get the physical address of the partition's reserved page
85 * for that nasid. This function returns 0 on any error.
86 */
87static u64
88xpc_get_rsvd_page_pa(int nasid, u64 buf, u64 buf_size)
89{
90 bte_result_t bte_res;
91 s64 status;
92 u64 cookie = 0;
93 u64 rp_pa = nasid; /* seed with nasid */
94 u64 len = 0;
95
96
97 while (1) {
98
99 status = sn_partition_reserved_page_pa(buf, &cookie, &rp_pa,
100 &len);
101
102 dev_dbg(xpc_part, "SAL returned with status=%li, cookie="
103 "0x%016lx, address=0x%016lx, len=0x%016lx\n",
104 status, cookie, rp_pa, len);
105
106 if (status != SALRET_MORE_PASSES) {
107 break;
108 }
109
110 if (len > buf_size) {
111 dev_err(xpc_part, "len (=0x%016lx) > buf_size\n", len);
112 status = SALRET_ERROR;
113 break;
114 }
115
116 bte_res = xp_bte_copy(rp_pa, ia64_tpa(buf), buf_size,
117 (BTE_NOTIFY | BTE_WACQUIRE), NULL);
118 if (bte_res != BTE_SUCCESS) {
119 dev_dbg(xpc_part, "xp_bte_copy failed %i\n", bte_res);
120 status = SALRET_ERROR;
121 break;
122 }
123 }
124
125 if (status != SALRET_OK) {
126 rp_pa = 0;
127 }
128 dev_dbg(xpc_part, "reserved page at phys address 0x%016lx\n", rp_pa);
129 return rp_pa;
130}
131
132
133/*
134 * Fill the partition reserved page with the information needed by
135 * other partitions to discover we are alive and establish initial
136 * communications.
137 */
138struct xpc_rsvd_page *
139xpc_rsvd_page_init(void)
140{
141 struct xpc_rsvd_page *rp;
142 AMO_t *amos_page;
143 u64 rp_pa, next_cl, nasid_array = 0;
144 int i, ret;
145
146
147 /* get the local reserved page's address */
148
149 rp_pa = xpc_get_rsvd_page_pa(cnodeid_to_nasid(0),
150 (u64) xpc_remote_copy_buffer,
151 XPC_RSVD_PAGE_ALIGNED_SIZE);
152 if (rp_pa == 0) {
153 dev_err(xpc_part, "SAL failed to locate the reserved page\n");
154 return NULL;
155 }
156 rp = (struct xpc_rsvd_page *) __va(rp_pa);
157
158 if (rp->partid != sn_partition_id) {
159 dev_err(xpc_part, "the reserved page's partid of %d should be "
160 "%d\n", rp->partid, sn_partition_id);
161 return NULL;
162 }
163
164 rp->version = XPC_RP_VERSION;
165
166 /*
167 * Place the XPC variables on the cache line following the
168 * reserved page structure.
169 */
170 next_cl = (u64) rp + XPC_RSVD_PAGE_ALIGNED_SIZE;
171 xpc_vars = (struct xpc_vars *) next_cl;
172
173 /*
174 * Before clearing xpc_vars, see if a page of AMOs had been previously
175 * allocated. If not we'll need to allocate one and set permissions
176 * so that cross-partition AMOs are allowed.
177 *
178 * The allocated AMO page needs MCA reporting to remain disabled after
179 * XPC has unloaded. To make this work, we keep a copy of the pointer
180 * to this page (i.e., amos_page) in the struct xpc_vars structure,
181 * which is pointed to by the reserved page, and re-use that saved copy
182 * on subsequent loads of XPC. This AMO page is never freed, and its
183 * memory protections are never restricted.
184 */
185 if ((amos_page = xpc_vars->amos_page) == NULL) {
186 amos_page = (AMO_t *) mspec_kalloc_page(0);
187 if (amos_page == NULL) {
188 dev_err(xpc_part, "can't allocate page of AMOs\n");
189 return NULL;
190 }
191
192 /*
193 * Open up AMO-R/W to cpu. This is done for Shub 1.1 systems
194 * when xpc_allow_IPI_ops() is called via xpc_hb_init().
195 */
196 if (!enable_shub_wars_1_1()) {
197 ret = sn_change_memprotect(ia64_tpa((u64) amos_page),
198 PAGE_SIZE, SN_MEMPROT_ACCESS_CLASS_1,
199 &nasid_array);
200 if (ret != 0) {
201 dev_err(xpc_part, "can't change memory "
202 "protections\n");
203 mspec_kfree_page((unsigned long) amos_page);
204 return NULL;
205 }
206 }
207 }
208
209 memset(xpc_vars, 0, sizeof(struct xpc_vars));
210
211 /*
212 * Place the XPC per partition specific variables on the cache line
213 * following the XPC variables structure.
214 */
215 next_cl += XPC_VARS_ALIGNED_SIZE;
216 memset((u64 *) next_cl, 0, sizeof(struct xpc_vars_part) *
217 XP_MAX_PARTITIONS);
218 xpc_vars_part = (struct xpc_vars_part *) next_cl;
219 xpc_vars->vars_part_pa = __pa(next_cl);
220
221 xpc_vars->version = XPC_V_VERSION;
222 xpc_vars->act_nasid = cpuid_to_nasid(0);
223 xpc_vars->act_phys_cpuid = cpu_physical_id(0);
224 xpc_vars->amos_page = amos_page; /* save for next load of XPC */
225
226
227 /*
228 * Initialize the activation related AMO variables.
229 */
230 xpc_vars->act_amos = xpc_IPI_init(XP_MAX_PARTITIONS);
231 for (i = 1; i < XP_NASID_MASK_WORDS; i++) {
232 xpc_IPI_init(i + XP_MAX_PARTITIONS);
233 }
234 /* export AMO page's physical address to other partitions */
235 xpc_vars->amos_page_pa = ia64_tpa((u64) xpc_vars->amos_page);
236
237 /*
238 * This signifies to the remote partition that our reserved
239 * page is initialized.
240 */
241 (volatile u64) rp->vars_pa = __pa(xpc_vars);
242
243 return rp;
244}
245
246
247/*
248 * Change protections to allow IPI operations (and AMO operations on
249 * Shub 1.1 systems).
250 */
251void
252xpc_allow_IPI_ops(void)
253{
254 int node;
255 int nasid;
256
257
258 // >>> Change SH_IPI_ACCESS code to use SAL call once it is available.
259
260 if (is_shub2()) {
261 xpc_sh2_IPI_access0 =
262 (u64) HUB_L((u64 *) LOCAL_MMR_ADDR(SH2_IPI_ACCESS0));
263 xpc_sh2_IPI_access1 =
264 (u64) HUB_L((u64 *) LOCAL_MMR_ADDR(SH2_IPI_ACCESS1));
265 xpc_sh2_IPI_access2 =
266 (u64) HUB_L((u64 *) LOCAL_MMR_ADDR(SH2_IPI_ACCESS2));
267 xpc_sh2_IPI_access3 =
268 (u64) HUB_L((u64 *) LOCAL_MMR_ADDR(SH2_IPI_ACCESS3));
269
270 for_each_online_node(node) {
271 nasid = cnodeid_to_nasid(node);
272 HUB_S((u64 *) GLOBAL_MMR_ADDR(nasid, SH2_IPI_ACCESS0),
273 -1UL);
274 HUB_S((u64 *) GLOBAL_MMR_ADDR(nasid, SH2_IPI_ACCESS1),
275 -1UL);
276 HUB_S((u64 *) GLOBAL_MMR_ADDR(nasid, SH2_IPI_ACCESS2),
277 -1UL);
278 HUB_S((u64 *) GLOBAL_MMR_ADDR(nasid, SH2_IPI_ACCESS3),
279 -1UL);
280 }
281
282 } else {
283 xpc_sh1_IPI_access =
284 (u64) HUB_L((u64 *) LOCAL_MMR_ADDR(SH1_IPI_ACCESS));
285
286 for_each_online_node(node) {
287 nasid = cnodeid_to_nasid(node);
288 HUB_S((u64 *) GLOBAL_MMR_ADDR(nasid, SH1_IPI_ACCESS),
289 -1UL);
290
291 /*
292 * Since the BIST collides with memory operations on
293 * SHUB 1.1 sn_change_memprotect() cannot be used.
294 */
295 if (enable_shub_wars_1_1()) {
296 /* open up everything */
297 xpc_prot_vec[node] = (u64) HUB_L((u64 *)
298 GLOBAL_MMR_ADDR(nasid,
299 SH1_MD_DQLP_MMR_DIR_PRIVEC0));
300 HUB_S((u64 *) GLOBAL_MMR_ADDR(nasid,
301 SH1_MD_DQLP_MMR_DIR_PRIVEC0),
302 -1UL);
303 HUB_S((u64 *) GLOBAL_MMR_ADDR(nasid,
304 SH1_MD_DQRP_MMR_DIR_PRIVEC0),
305 -1UL);
306 }
307 }
308 }
309}
310
311
312/*
313 * Restrict protections to disallow IPI operations (and AMO operations on
314 * Shub 1.1 systems).
315 */
316void
317xpc_restrict_IPI_ops(void)
318{
319 int node;
320 int nasid;
321
322
323 // >>> Change SH_IPI_ACCESS code to use SAL call once it is available.
324
325 if (is_shub2()) {
326
327 for_each_online_node(node) {
328 nasid = cnodeid_to_nasid(node);
329 HUB_S((u64 *) GLOBAL_MMR_ADDR(nasid, SH2_IPI_ACCESS0),
330 xpc_sh2_IPI_access0);
331 HUB_S((u64 *) GLOBAL_MMR_ADDR(nasid, SH2_IPI_ACCESS1),
332 xpc_sh2_IPI_access1);
333 HUB_S((u64 *) GLOBAL_MMR_ADDR(nasid, SH2_IPI_ACCESS2),
334 xpc_sh2_IPI_access2);
335 HUB_S((u64 *) GLOBAL_MMR_ADDR(nasid, SH2_IPI_ACCESS3),
336 xpc_sh2_IPI_access3);
337 }
338
339 } else {
340
341 for_each_online_node(node) {
342 nasid = cnodeid_to_nasid(node);
343 HUB_S((u64 *) GLOBAL_MMR_ADDR(nasid, SH1_IPI_ACCESS),
344 xpc_sh1_IPI_access);
345
346 if (enable_shub_wars_1_1()) {
347 HUB_S((u64 *) GLOBAL_MMR_ADDR(nasid,
348 SH1_MD_DQLP_MMR_DIR_PRIVEC0),
349 xpc_prot_vec[node]);
350 HUB_S((u64 *) GLOBAL_MMR_ADDR(nasid,
351 SH1_MD_DQRP_MMR_DIR_PRIVEC0),
352 xpc_prot_vec[node]);
353 }
354 }
355 }
356}
357
358
359/*
360 * At periodic intervals, scan through all active partitions and ensure
361 * their heartbeat is still active. If not, the partition is deactivated.
362 */
363void
364xpc_check_remote_hb(void)
365{
366 struct xpc_vars *remote_vars;
367 struct xpc_partition *part;
368 partid_t partid;
369 bte_result_t bres;
370
371
372 remote_vars = (struct xpc_vars *) xpc_remote_copy_buffer;
373
374 for (partid = 1; partid < XP_MAX_PARTITIONS; partid++) {
375 if (partid == sn_partition_id) {
376 continue;
377 }
378
379 part = &xpc_partitions[partid];
380
381 if (part->act_state == XPC_P_INACTIVE ||
382 part->act_state == XPC_P_DEACTIVATING) {
383 continue;
384 }
385
386 /* pull the remote_hb cache line */
387 bres = xp_bte_copy(part->remote_vars_pa,
388 ia64_tpa((u64) remote_vars),
389 XPC_VARS_ALIGNED_SIZE,
390 (BTE_NOTIFY | BTE_WACQUIRE), NULL);
391 if (bres != BTE_SUCCESS) {
392 XPC_DEACTIVATE_PARTITION(part,
393 xpc_map_bte_errors(bres));
394 continue;
395 }
396
397 dev_dbg(xpc_part, "partid = %d, heartbeat = %ld, last_heartbeat"
398 " = %ld, kdb_status = %ld, HB_mask = 0x%lx\n", partid,
399 remote_vars->heartbeat, part->last_heartbeat,
400 remote_vars->kdb_status,
401 remote_vars->heartbeating_to_mask);
402
403 if (((remote_vars->heartbeat == part->last_heartbeat) &&
404 (remote_vars->kdb_status == 0)) ||
405 !XPC_HB_ALLOWED(sn_partition_id, remote_vars)) {
406
407 XPC_DEACTIVATE_PARTITION(part, xpcNoHeartbeat);
408 continue;
409 }
410
411 part->last_heartbeat = remote_vars->heartbeat;
412 }
413}
414
415
416/*
417 * Get a copy of the remote partition's rsvd page.
418 *
419 * remote_rp points to a buffer that is cacheline aligned for BTE copies and
420 * assumed to be of size XPC_RSVD_PAGE_ALIGNED_SIZE.
421 */
422static enum xpc_retval
423xpc_get_remote_rp(int nasid, u64 *discovered_nasids,
424 struct xpc_rsvd_page *remote_rp, u64 *remote_rsvd_page_pa)
425{
426 int bres, i;
427
428
429 /* get the reserved page's physical address */
430
431 *remote_rsvd_page_pa = xpc_get_rsvd_page_pa(nasid, (u64) remote_rp,
432 XPC_RSVD_PAGE_ALIGNED_SIZE);
433 if (*remote_rsvd_page_pa == 0) {
434 return xpcNoRsvdPageAddr;
435 }
436
437
438 /* pull over the reserved page structure */
439
440 bres = xp_bte_copy(*remote_rsvd_page_pa, ia64_tpa((u64) remote_rp),
441 XPC_RSVD_PAGE_ALIGNED_SIZE,
442 (BTE_NOTIFY | BTE_WACQUIRE), NULL);
443 if (bres != BTE_SUCCESS) {
444 return xpc_map_bte_errors(bres);
445 }
446
447
448 if (discovered_nasids != NULL) {
449 for (i = 0; i < XP_NASID_MASK_WORDS; i++) {
450 discovered_nasids[i] |= remote_rp->part_nasids[i];
451 }
452 }
453
454
455 /* check that the partid is for another partition */
456
457 if (remote_rp->partid < 1 ||
458 remote_rp->partid > (XP_MAX_PARTITIONS - 1)) {
459 return xpcInvalidPartid;
460 }
461
462 if (remote_rp->partid == sn_partition_id) {
463 return xpcLocalPartid;
464 }
465
466
467 if (XPC_VERSION_MAJOR(remote_rp->version) !=
468 XPC_VERSION_MAJOR(XPC_RP_VERSION)) {
469 return xpcBadVersion;
470 }
471
472 return xpcSuccess;
473}
474
475
476/*
477 * Get a copy of the remote partition's XPC variables.
478 *
479 * remote_vars points to a buffer that is cacheline aligned for BTE copies and
480 * assumed to be of size XPC_VARS_ALIGNED_SIZE.
481 */
482static enum xpc_retval
483xpc_get_remote_vars(u64 remote_vars_pa, struct xpc_vars *remote_vars)
484{
485 int bres;
486
487
488 if (remote_vars_pa == 0) {
489 return xpcVarsNotSet;
490 }
491
492
493 /* pull over the cross partition variables */
494
495 bres = xp_bte_copy(remote_vars_pa, ia64_tpa((u64) remote_vars),
496 XPC_VARS_ALIGNED_SIZE,
497 (BTE_NOTIFY | BTE_WACQUIRE), NULL);
498 if (bres != BTE_SUCCESS) {
499 return xpc_map_bte_errors(bres);
500 }
501
502 if (XPC_VERSION_MAJOR(remote_vars->version) !=
503 XPC_VERSION_MAJOR(XPC_V_VERSION)) {
504 return xpcBadVersion;
505 }
506
507 return xpcSuccess;
508}
509
510
511/*
512 * Prior code has determine the nasid which generated an IPI. Inspect
513 * that nasid to determine if its partition needs to be activated or
514 * deactivated.
515 *
516 * A partition is consider "awaiting activation" if our partition
517 * flags indicate it is not active and it has a heartbeat. A
518 * partition is considered "awaiting deactivation" if our partition
519 * flags indicate it is active but it has no heartbeat or it is not
520 * sending its heartbeat to us.
521 *
522 * To determine the heartbeat, the remote nasid must have a properly
523 * initialized reserved page.
524 */
525static void
526xpc_identify_act_IRQ_req(int nasid)
527{
528 struct xpc_rsvd_page *remote_rp;
529 struct xpc_vars *remote_vars;
530 u64 remote_rsvd_page_pa;
531 u64 remote_vars_pa;
532 partid_t partid;
533 struct xpc_partition *part;
534 enum xpc_retval ret;
535
536
537 /* pull over the reserved page structure */
538
539 remote_rp = (struct xpc_rsvd_page *) xpc_remote_copy_buffer;
540
541 ret = xpc_get_remote_rp(nasid, NULL, remote_rp, &remote_rsvd_page_pa);
542 if (ret != xpcSuccess) {
543 dev_warn(xpc_part, "unable to get reserved page from nasid %d, "
544 "which sent interrupt, reason=%d\n", nasid, ret);
545 return;
546 }
547
548 remote_vars_pa = remote_rp->vars_pa;
549 partid = remote_rp->partid;
550 part = &xpc_partitions[partid];
551
552
553 /* pull over the cross partition variables */
554
555 remote_vars = (struct xpc_vars *) xpc_remote_copy_buffer;
556
557 ret = xpc_get_remote_vars(remote_vars_pa, remote_vars);
558 if (ret != xpcSuccess) {
559
560 dev_warn(xpc_part, "unable to get XPC variables from nasid %d, "
561 "which sent interrupt, reason=%d\n", nasid, ret);
562
563 XPC_DEACTIVATE_PARTITION(part, ret);
564 return;
565 }
566
567
568 part->act_IRQ_rcvd++;
569
570 dev_dbg(xpc_part, "partid for nasid %d is %d; IRQs = %d; HB = "
571 "%ld:0x%lx\n", (int) nasid, (int) partid, part->act_IRQ_rcvd,
572 remote_vars->heartbeat, remote_vars->heartbeating_to_mask);
573
574
575 if (part->act_state == XPC_P_INACTIVE) {
576
577 part->remote_rp_pa = remote_rsvd_page_pa;
578 dev_dbg(xpc_part, " remote_rp_pa = 0x%016lx\n",
579 part->remote_rp_pa);
580
581 part->remote_vars_pa = remote_vars_pa;
582 dev_dbg(xpc_part, " remote_vars_pa = 0x%016lx\n",
583 part->remote_vars_pa);
584
585 part->last_heartbeat = remote_vars->heartbeat;
586 dev_dbg(xpc_part, " last_heartbeat = 0x%016lx\n",
587 part->last_heartbeat);
588
589 part->remote_vars_part_pa = remote_vars->vars_part_pa;
590 dev_dbg(xpc_part, " remote_vars_part_pa = 0x%016lx\n",
591 part->remote_vars_part_pa);
592
593 part->remote_act_nasid = remote_vars->act_nasid;
594 dev_dbg(xpc_part, " remote_act_nasid = 0x%x\n",
595 part->remote_act_nasid);
596
597 part->remote_act_phys_cpuid = remote_vars->act_phys_cpuid;
598 dev_dbg(xpc_part, " remote_act_phys_cpuid = 0x%x\n",
599 part->remote_act_phys_cpuid);
600
601 part->remote_amos_page_pa = remote_vars->amos_page_pa;
602 dev_dbg(xpc_part, " remote_amos_page_pa = 0x%lx\n",
603 part->remote_amos_page_pa);
604
605 xpc_activate_partition(part);
606
607 } else if (part->remote_amos_page_pa != remote_vars->amos_page_pa ||
608 !XPC_HB_ALLOWED(sn_partition_id, remote_vars)) {
609
610 part->reactivate_nasid = nasid;
611 XPC_DEACTIVATE_PARTITION(part, xpcReactivating);
612 }
613}
614
615
616/*
617 * Loop through the activation AMO variables and process any bits
618 * which are set. Each bit indicates a nasid sending a partition
619 * activation or deactivation request.
620 *
621 * Return #of IRQs detected.
622 */
623int
624xpc_identify_act_IRQ_sender(void)
625{
626 int word, bit;
627 u64 nasid_mask;
628 u64 nasid; /* remote nasid */
629 int n_IRQs_detected = 0;
630 AMO_t *act_amos;
631 struct xpc_rsvd_page *rp = (struct xpc_rsvd_page *) xpc_rsvd_page;
632
633
634 act_amos = xpc_vars->act_amos;
635
636
637 /* scan through act AMO variable looking for non-zero entries */
638 for (word = 0; word < XP_NASID_MASK_WORDS; word++) {
639
640 nasid_mask = xpc_IPI_receive(&act_amos[word]);
641 if (nasid_mask == 0) {
642 /* no IRQs from nasids in this variable */
643 continue;
644 }
645
646 dev_dbg(xpc_part, "AMO[%d] gave back 0x%lx\n", word,
647 nasid_mask);
648
649
650 /*
651 * If this nasid has been added to the machine since
652 * our partition was reset, this will retain the
653 * remote nasid in our reserved pages machine mask.
654 * This is used in the event of module reload.
655 */
656 rp->mach_nasids[word] |= nasid_mask;
657
658
659 /* locate the nasid(s) which sent interrupts */
660
661 for (bit = 0; bit < (8 * sizeof(u64)); bit++) {
662 if (nasid_mask & (1UL << bit)) {
663 n_IRQs_detected++;
664 nasid = XPC_NASID_FROM_W_B(word, bit);
665 dev_dbg(xpc_part, "interrupt from nasid %ld\n",
666 nasid);
667 xpc_identify_act_IRQ_req(nasid);
668 }
669 }
670 }
671 return n_IRQs_detected;
672}
673
674
675/*
676 * Mark specified partition as active.
677 */
678enum xpc_retval
679xpc_mark_partition_active(struct xpc_partition *part)
680{
681 unsigned long irq_flags;
682 enum xpc_retval ret;
683
684
685 dev_dbg(xpc_part, "setting partition %d to ACTIVE\n", XPC_PARTID(part));
686
687 spin_lock_irqsave(&part->act_lock, irq_flags);
688 if (part->act_state == XPC_P_ACTIVATING) {
689 part->act_state = XPC_P_ACTIVE;
690 ret = xpcSuccess;
691 } else {
692 DBUG_ON(part->reason == xpcSuccess);
693 ret = part->reason;
694 }
695 spin_unlock_irqrestore(&part->act_lock, irq_flags);
696
697 return ret;
698}
699
700
701/*
702 * Notify XPC that the partition is down.
703 */
704void
705xpc_deactivate_partition(const int line, struct xpc_partition *part,
706 enum xpc_retval reason)
707{
708 unsigned long irq_flags;
709 partid_t partid = XPC_PARTID(part);
710
711
712 spin_lock_irqsave(&part->act_lock, irq_flags);
713
714 if (part->act_state == XPC_P_INACTIVE) {
715 XPC_SET_REASON(part, reason, line);
716 spin_unlock_irqrestore(&part->act_lock, irq_flags);
717 if (reason == xpcReactivating) {
718 /* we interrupt ourselves to reactivate partition */
719 xpc_IPI_send_reactivate(part);
720 }
721 return;
722 }
723 if (part->act_state == XPC_P_DEACTIVATING) {
724 if ((part->reason == xpcUnloading && reason != xpcUnloading) ||
725 reason == xpcReactivating) {
726 XPC_SET_REASON(part, reason, line);
727 }
728 spin_unlock_irqrestore(&part->act_lock, irq_flags);
729 return;
730 }
731
732 part->act_state = XPC_P_DEACTIVATING;
733 XPC_SET_REASON(part, reason, line);
734
735 spin_unlock_irqrestore(&part->act_lock, irq_flags);
736
737 XPC_DISALLOW_HB(partid, xpc_vars);
738
739 dev_dbg(xpc_part, "bringing partition %d down, reason = %d\n", partid,
740 reason);
741
742 xpc_partition_down(part, reason);
743}
744
745
746/*
747 * Mark specified partition as active.
748 */
749void
750xpc_mark_partition_inactive(struct xpc_partition *part)
751{
752 unsigned long irq_flags;
753
754
755 dev_dbg(xpc_part, "setting partition %d to INACTIVE\n",
756 XPC_PARTID(part));
757
758 spin_lock_irqsave(&part->act_lock, irq_flags);
759 part->act_state = XPC_P_INACTIVE;
760 spin_unlock_irqrestore(&part->act_lock, irq_flags);
761 part->remote_rp_pa = 0;
762}
763
764
765/*
766 * SAL has provided a partition and machine mask. The partition mask
767 * contains a bit for each even nasid in our partition. The machine
768 * mask contains a bit for each even nasid in the entire machine.
769 *
770 * Using those two bit arrays, we can determine which nasids are
771 * known in the machine. Each should also have a reserved page
772 * initialized if they are available for partitioning.
773 */
774void
775xpc_discovery(void)
776{
777 void *remote_rp_base;
778 struct xpc_rsvd_page *remote_rp;
779 struct xpc_vars *remote_vars;
780 u64 remote_rsvd_page_pa;
781 u64 remote_vars_pa;
782 int region;
783 int max_regions;
784 int nasid;
785 struct xpc_rsvd_page *rp;
786 partid_t partid;
787 struct xpc_partition *part;
788 u64 *discovered_nasids;
789 enum xpc_retval ret;
790
791
792 remote_rp = xpc_kmalloc_cacheline_aligned(XPC_RSVD_PAGE_ALIGNED_SIZE,
793 GFP_KERNEL, &remote_rp_base);
794 if (remote_rp == NULL) {
795 return;
796 }
797 remote_vars = (struct xpc_vars *) remote_rp;
798
799
800 discovered_nasids = kmalloc(sizeof(u64) * XP_NASID_MASK_WORDS,
801 GFP_KERNEL);
802 if (discovered_nasids == NULL) {
803 kfree(remote_rp_base);
804 return;
805 }
806 memset(discovered_nasids, 0, sizeof(u64) * XP_NASID_MASK_WORDS);
807
808 rp = (struct xpc_rsvd_page *) xpc_rsvd_page;
809
810 /*
811 * The term 'region' in this context refers to the minimum number of
812 * nodes that can comprise an access protection grouping. The access
813 * protection is in regards to memory, IOI and IPI.
814 */
815//>>> move the next two #defines into either include/asm-ia64/sn/arch.h or
816//>>> include/asm-ia64/sn/addrs.h
817#define SH1_MAX_REGIONS 64
818#define SH2_MAX_REGIONS 256
819 max_regions = is_shub2() ? SH2_MAX_REGIONS : SH1_MAX_REGIONS;
820
821 for (region = 0; region < max_regions; region++) {
822
823 if ((volatile int) xpc_exiting) {
824 break;
825 }
826
827 dev_dbg(xpc_part, "searching region %d\n", region);
828
829 for (nasid = (region * sn_region_size * 2);
830 nasid < ((region + 1) * sn_region_size * 2);
831 nasid += 2) {
832
833 if ((volatile int) xpc_exiting) {
834 break;
835 }
836
837 dev_dbg(xpc_part, "checking nasid %d\n", nasid);
838
839
840 if (XPC_NASID_IN_ARRAY(nasid, rp->part_nasids)) {
841 dev_dbg(xpc_part, "PROM indicates Nasid %d is "
842 "part of the local partition; skipping "
843 "region\n", nasid);
844 break;
845 }
846
847 if (!(XPC_NASID_IN_ARRAY(nasid, rp->mach_nasids))) {
848 dev_dbg(xpc_part, "PROM indicates Nasid %d was "
849 "not on Numa-Link network at reset\n",
850 nasid);
851 continue;
852 }
853
854 if (XPC_NASID_IN_ARRAY(nasid, discovered_nasids)) {
855 dev_dbg(xpc_part, "Nasid %d is part of a "
856 "partition which was previously "
857 "discovered\n", nasid);
858 continue;
859 }
860
861
862 /* pull over the reserved page structure */
863
864 ret = xpc_get_remote_rp(nasid, discovered_nasids,
865 remote_rp, &remote_rsvd_page_pa);
866 if (ret != xpcSuccess) {
867 dev_dbg(xpc_part, "unable to get reserved page "
868 "from nasid %d, reason=%d\n", nasid,
869 ret);
870
871 if (ret == xpcLocalPartid) {
872 break;
873 }
874 continue;
875 }
876
877 remote_vars_pa = remote_rp->vars_pa;
878
879 partid = remote_rp->partid;
880 part = &xpc_partitions[partid];
881
882
883 /* pull over the cross partition variables */
884
885 ret = xpc_get_remote_vars(remote_vars_pa, remote_vars);
886 if (ret != xpcSuccess) {
887 dev_dbg(xpc_part, "unable to get XPC variables "
888 "from nasid %d, reason=%d\n", nasid,
889 ret);
890
891 XPC_DEACTIVATE_PARTITION(part, ret);
892 continue;
893 }
894
895 if (part->act_state != XPC_P_INACTIVE) {
896 dev_dbg(xpc_part, "partition %d on nasid %d is "
897 "already activating\n", partid, nasid);
898 break;
899 }
900
901 /*
902 * Register the remote partition's AMOs with SAL so it
903 * can handle and cleanup errors within that address
904 * range should the remote partition go down. We don't
905 * unregister this range because it is difficult to
906 * tell when outstanding writes to the remote partition
907 * are finished and thus when it is thus safe to
908 * unregister. This should not result in wasted space
909 * in the SAL xp_addr_region table because we should
910 * get the same page for remote_act_amos_pa after
911 * module reloads and system reboots.
912 */
913 if (sn_register_xp_addr_region(
914 remote_vars->amos_page_pa,
915 PAGE_SIZE, 1) < 0) {
916 dev_dbg(xpc_part, "partition %d failed to "
917 "register xp_addr region 0x%016lx\n",
918 partid, remote_vars->amos_page_pa);
919
920 XPC_SET_REASON(part, xpcPhysAddrRegFailed,
921 __LINE__);
922 break;
923 }
924
925 /*
926 * The remote nasid is valid and available.
927 * Send an interrupt to that nasid to notify
928 * it that we are ready to begin activation.
929 */
930 dev_dbg(xpc_part, "sending an interrupt to AMO 0x%lx, "
931 "nasid %d, phys_cpuid 0x%x\n",
932 remote_vars->amos_page_pa,
933 remote_vars->act_nasid,
934 remote_vars->act_phys_cpuid);
935
936 xpc_IPI_send_activate(remote_vars);
937 }
938 }
939
940 kfree(discovered_nasids);
941 kfree(remote_rp_base);
942}
943
944
945/*
946 * Given a partid, get the nasids owned by that partition from the
947 * remote partitions reserved page.
948 */
949enum xpc_retval
950xpc_initiate_partid_to_nasids(partid_t partid, void *nasid_mask)
951{
952 struct xpc_partition *part;
953 u64 part_nasid_pa;
954 int bte_res;
955
956
957 part = &xpc_partitions[partid];
958 if (part->remote_rp_pa == 0) {
959 return xpcPartitionDown;
960 }
961
962 part_nasid_pa = part->remote_rp_pa +
963 (u64) &((struct xpc_rsvd_page *) 0)->part_nasids;
964
965 bte_res = xp_bte_copy(part_nasid_pa, ia64_tpa((u64) nasid_mask),
966 L1_CACHE_ALIGN(XP_NASID_MASK_BYTES),
967 (BTE_NOTIFY | BTE_WACQUIRE), NULL);
968
969 return xpc_map_bte_errors(bte_res);
970}
971