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1 /*
2 * Copyright (c) 2000-2002 Apple Computer, Inc. All rights reserved.
3 *
4 * @APPLE_LICENSE_HEADER_START@
5 *
6 * The contents of this file constitute Original Code as defined in and
7 * are subject to the Apple Public Source License Version 1.1 (the
8 * "License"). You may not use this file except in compliance with the
9 * License. Please obtain a copy of the License at
10 * http://www.apple.com/publicsource and read it before using this file.
11 *
12 * This Original Code and all software distributed under the License are
13 * distributed on an "AS IS" basis, WITHOUT WARRANTY OF ANY KIND, EITHER
14 * EXPRESS OR IMPLIED, AND APPLE HEREBY DISCLAIMS ALL SUCH WARRANTIES,
15 * INCLUDING WITHOUT LIMITATION, ANY WARRANTIES OF MERCHANTABILITY,
16 * FITNESS FOR A PARTICULAR PURPOSE OR NON-INFRINGEMENT. Please see the
17 * License for the specific language governing rights and limitations
18 * under the License.
19 *
20 * @APPLE_LICENSE_HEADER_END@
21 */
22 /*
23 * @OSF_FREE_COPYRIGHT@
24 */
25 /*
26 * Mach Operating System
27 * Copyright (c) 1991,1990,1989,1988,1987 Carnegie Mellon University
28 * All Rights Reserved.
29 *
30 * Permission to use, copy, modify and distribute this software and its
31 * documentation is hereby granted, provided that both the copyright
32 * notice and this permission notice appear in all copies of the
33 * software, derivative works or modified versions, and any portions
34 * thereof, and that both notices appear in supporting documentation.
35 *
36 * CARNEGIE MELLON ALLOWS FREE USE OF THIS SOFTWARE IN ITS "AS IS"
37 * CONDITION. CARNEGIE MELLON DISCLAIMS ANY LIABILITY OF ANY KIND FOR
38 * ANY DAMAGES WHATSOEVER RESULTING FROM THE USE OF THIS SOFTWARE.
39 *
40 * Carnegie Mellon requests users of this software to return to
41 *
42 * Software Distribution Coordinator or Software.Distribution@CS.CMU.EDU
43 * School of Computer Science
44 * Carnegie Mellon University
45 * Pittsburgh PA 15213-3890
46 *
47 * any improvements or extensions that they make and grant Carnegie Mellon
48 * the rights to redistribute these changes.
49 */
50 /*
51 */
52 /*
53 * File: wait_queue.c (adapted from sched_prim.c)
54 * Author: Avadis Tevanian, Jr.
55 * Date: 1986
56 *
57 * Primitives for manipulating wait queues: either global
58 * ones from sched_prim.c, or private ones associated with
59 * particular structures(pots, semaphores, etc..).
60 */
61
62 #include <kern/kern_types.h>
63 #include <kern/simple_lock.h>
64 #include <kern/kalloc.h>
65 #include <kern/queue.h>
66 #include <kern/spl.h>
67 #include <mach/sync_policy.h>
68 #include <kern/sched_prim.h>
69
70 #include <kern/wait_queue.h>
71
72 /*
73 * Routine: wait_queue_init
74 * Purpose:
75 * Initialize a previously allocated wait queue.
76 * Returns:
77 * KERN_SUCCESS - The wait_queue_t was initialized
78 * KERN_INVALID_ARGUMENT - The policy parameter was invalid
79 */
80 kern_return_t
81 wait_queue_init(
82 wait_queue_t wq,
83 int policy)
84 {
85 if (!((policy & SYNC_POLICY_ORDER_MASK) == SYNC_POLICY_FIFO))
86 return KERN_INVALID_ARGUMENT;
87
88 wq->wq_fifo = TRUE;
89 wq->wq_type = _WAIT_QUEUE_inited;
90 queue_init(&wq->wq_queue);
91 hw_lock_init(&wq->wq_interlock);
92 return KERN_SUCCESS;
93 }
94
95 /*
96 * Routine: wait_queue_alloc
97 * Purpose:
98 * Allocate and initialize a wait queue for use outside of
99 * of the mach part of the kernel.
100 * Conditions:
101 * Nothing locked - can block.
102 * Returns:
103 * The allocated and initialized wait queue
104 * WAIT_QUEUE_NULL if there is a resource shortage
105 */
106 wait_queue_t
107 wait_queue_alloc(
108 int policy)
109 {
110 wait_queue_t wq;
111 kern_return_t ret;
112
113 wq = (wait_queue_t) kalloc(sizeof(struct wait_queue));
114 if (wq != WAIT_QUEUE_NULL) {
115 ret = wait_queue_init(wq, policy);
116 if (ret != KERN_SUCCESS) {
117 kfree((vm_offset_t)wq, sizeof(struct wait_queue));
118 wq = WAIT_QUEUE_NULL;
119 }
120 }
121 return wq;
122 }
123
124 /*
125 * Routine: wait_queue_free
126 * Purpose:
127 * Free an allocated wait queue.
128 * Conditions:
129 * May block.
130 */
131 kern_return_t
132 wait_queue_free(
133 wait_queue_t wq)
134 {
135 if (!wait_queue_is_queue(wq))
136 return KERN_INVALID_ARGUMENT;
137 if (!queue_empty(&wq->wq_queue))
138 return KERN_FAILURE;
139 kfree((vm_offset_t)wq, sizeof(struct wait_queue));
140 return KERN_SUCCESS;
141 }
142
143 /*
144 * Routine: wait_queue_set_init
145 * Purpose:
146 * Initialize a previously allocated wait queue set.
147 * Returns:
148 * KERN_SUCCESS - The wait_queue_set_t was initialized
149 * KERN_INVALID_ARGUMENT - The policy parameter was invalid
150 */
151 kern_return_t
152 wait_queue_set_init(
153 wait_queue_set_t wqset,
154 int policy)
155 {
156 kern_return_t ret;
157
158 ret = wait_queue_init(&wqset->wqs_wait_queue, policy);
159 if (ret != KERN_SUCCESS)
160 return ret;
161
162 wqset->wqs_wait_queue.wq_type = _WAIT_QUEUE_SET_inited;
163 if (policy & SYNC_POLICY_PREPOST)
164 wqset->wqs_wait_queue.wq_isprepost = TRUE;
165 else
166 wqset->wqs_wait_queue.wq_isprepost = FALSE;
167 queue_init(&wqset->wqs_setlinks);
168 wqset->wqs_refcount = 0;
169 return KERN_SUCCESS;
170 }
171
172 /* legacy API */
173 kern_return_t
174 wait_queue_sub_init(
175 wait_queue_set_t wqset,
176 int policy)
177 {
178 return wait_queue_set_init(wqset, policy);
179 }
180
181 /*
182 * Routine: wait_queue_set_alloc
183 * Purpose:
184 * Allocate and initialize a wait queue set for
185 * use outside of the mach part of the kernel.
186 * Conditions:
187 * May block.
188 * Returns:
189 * The allocated and initialized wait queue set
190 * WAIT_QUEUE_SET_NULL if there is a resource shortage
191 */
192 wait_queue_set_t
193 wait_queue_set_alloc(
194 int policy)
195 {
196 wait_queue_set_t wq_set;
197
198 wq_set = (wait_queue_set_t) kalloc(sizeof(struct wait_queue_set));
199 if (wq_set != WAIT_QUEUE_SET_NULL) {
200 kern_return_t ret;
201
202 ret = wait_queue_set_init(wq_set, policy);
203 if (ret != KERN_SUCCESS) {
204 kfree((vm_offset_t)wq_set, sizeof(struct wait_queue_set));
205 wq_set = WAIT_QUEUE_SET_NULL;
206 }
207 }
208 return wq_set;
209 }
210
211 /*
212 * Routine: wait_queue_set_free
213 * Purpose:
214 * Free an allocated wait queue set
215 * Conditions:
216 * May block.
217 */
218 kern_return_t
219 wait_queue_set_free(
220 wait_queue_set_t wq_set)
221 {
222 if (!wait_queue_is_set(wq_set))
223 return KERN_INVALID_ARGUMENT;
224
225 if (!queue_empty(&wq_set->wqs_wait_queue.wq_queue))
226 return KERN_FAILURE;
227
228 kfree((vm_offset_t)wq_set, sizeof(struct wait_queue_set));
229 return KERN_SUCCESS;
230 }
231
232 kern_return_t
233 wait_queue_sub_clearrefs(
234 wait_queue_set_t wq_set)
235 {
236 if (!wait_queue_is_set(wq_set))
237 return KERN_INVALID_ARGUMENT;
238
239 wqs_lock(wq_set);
240 wq_set->wqs_refcount = 0;
241 wqs_unlock(wq_set);
242 return KERN_SUCCESS;
243 }
244
245 /*
246 *
247 * Routine: wait_queue_set_size
248 * Routine: wait_queue_link_size
249 * Purpose:
250 * Return the size of opaque wait queue structures
251 */
252 unsigned int wait_queue_set_size(void) { return sizeof(WaitQueueSet); }
253 unsigned int wait_queue_link_size(void) { return sizeof(WaitQueueLink); }
254
255 /* declare a unique type for wait queue link structures */
256 static unsigned int _wait_queue_link;
257 static unsigned int _wait_queue_unlinked;
258
259 #define WAIT_QUEUE_LINK ((void *)&_wait_queue_link)
260 #define WAIT_QUEUE_UNLINKED ((void *)&_wait_queue_unlinked)
261
262 #define WAIT_QUEUE_ELEMENT_CHECK(wq, wqe) \
263 WQASSERT(((wqe)->wqe_queue == (wq) && \
264 queue_next(queue_prev((queue_t) (wqe))) == (queue_t)(wqe)), \
265 "wait queue element list corruption: wq=%#x, wqe=%#x", \
266 (wq), (wqe))
267
268 #define WQSPREV(wqs, wql) ((wait_queue_link_t)queue_prev( \
269 ((&(wqs)->wqs_setlinks == (queue_t)(wql)) ? \
270 (queue_t)(wql) : &(wql)->wql_setlinks)))
271
272 #define WQSNEXT(wqs, wql) ((wait_queue_link_t)queue_next( \
273 ((&(wqs)->wqs_setlinks == (queue_t)(wql)) ? \
274 (queue_t)(wql) : &(wql)->wql_setlinks)))
275
276 #define WAIT_QUEUE_SET_LINK_CHECK(wqs, wql) \
277 WQASSERT((((wql)->wql_type == WAIT_QUEUE_LINK) && \
278 ((wql)->wql_setqueue == (wqs)) && \
279 ((wql)->wql_queue->wq_type == _WAIT_QUEUE_inited) && \
280 (WQSNEXT((wqs), WQSPREV((wqs),(wql))) == (wql))), \
281 "wait queue set links corruption: wqs=%#x, wql=%#x", \
282 (wqs), (wql))
283
284 #if defined(_WAIT_QUEUE_DEBUG_)
285
286 #define WQASSERT(e, s, p0, p1) ((e) ? 0 : panic(s, p0, p1))
287
288 #define WAIT_QUEUE_CHECK(wq) \
289 MACRO_BEGIN \
290 queue_t q2 = &(wq)->wq_queue; \
291 wait_queue_element_t wqe2 = (wait_queue_element_t) queue_first(q2); \
292 while (!queue_end(q2, (queue_entry_t)wqe2)) { \
293 WAIT_QUEUE_ELEMENT_CHECK((wq), wqe2); \
294 wqe2 = (wait_queue_element_t) queue_next((queue_t) wqe2); \
295 } \
296 MACRO_END
297
298 #define WAIT_QUEUE_SET_CHECK(wqs) \
299 MACRO_BEGIN \
300 queue_t q2 = &(wqs)->wqs_setlinks; \
301 wait_queue_link_t wql2 = (wait_queue_link_t) queue_first(q2); \
302 while (!queue_end(q2, (queue_entry_t)wql2)) { \
303 WAIT_QUEUE_SET_LINK_CHECK((wqs), wql2); \
304 wql2 = (wait_queue_link_t) wql2->wql_setlinks.next; \
305 } \
306 MACRO_END
307
308 #else /* !_WAIT_QUEUE_DEBUG_ */
309
310 #define WQASSERT(e, s, p0, p1) assert(e)
311
312 #define WAIT_QUEUE_CHECK(wq)
313 #define WAIT_QUEUE_SET_CHECK(wqs)
314
315 #endif /* !_WAIT_QUEUE_DEBUG_ */
316
317 /*
318 * Routine: wait_queue_member_locked
319 * Purpose:
320 * Indicate if this set queue is a member of the queue
321 * Conditions:
322 * The wait queue is locked
323 * The set queue is just that, a set queue
324 */
325 __private_extern__ boolean_t
326 wait_queue_member_locked(
327 wait_queue_t wq,
328 wait_queue_set_t wq_set)
329 {
330 wait_queue_element_t wq_element;
331 queue_t q;
332
333 assert(wait_queue_held(wq));
334 assert(wait_queue_is_set(wq_set));
335
336 q = &wq->wq_queue;
337
338 wq_element = (wait_queue_element_t) queue_first(q);
339 while (!queue_end(q, (queue_entry_t)wq_element)) {
340 WAIT_QUEUE_ELEMENT_CHECK(wq, wq_element);
341 if ((wq_element->wqe_type == WAIT_QUEUE_LINK)) {
342 wait_queue_link_t wql = (wait_queue_link_t)wq_element;
343
344 if (wql->wql_setqueue == wq_set)
345 return TRUE;
346 }
347 wq_element = (wait_queue_element_t)
348 queue_next((queue_t) wq_element);
349 }
350 return FALSE;
351 }
352
353
354 /*
355 * Routine: wait_queue_member
356 * Purpose:
357 * Indicate if this set queue is a member of the queue
358 * Conditions:
359 * The set queue is just that, a set queue
360 */
361 boolean_t
362 wait_queue_member(
363 wait_queue_t wq,
364 wait_queue_set_t wq_set)
365 {
366 boolean_t ret;
367 spl_t s;
368
369 if (!wait_queue_is_set(wq_set))
370 return FALSE;
371
372 s = splsched();
373 wait_queue_lock(wq);
374 ret = wait_queue_member_locked(wq, wq_set);
375 wait_queue_unlock(wq);
376 splx(s);
377
378 return ret;
379 }
380
381
382 /*
383 * Routine: wait_queue_link_noalloc
384 * Purpose:
385 * Insert a set wait queue into a wait queue. This
386 * requires us to link the two together using a wait_queue_link
387 * structure that we allocate.
388 * Conditions:
389 * The wait queue being inserted must be inited as a set queue
390 */
391 kern_return_t
392 wait_queue_link_noalloc(
393 wait_queue_t wq,
394 wait_queue_set_t wq_set,
395 wait_queue_link_t wql)
396 {
397 wait_queue_element_t wq_element;
398 queue_t q;
399 spl_t s;
400
401 if (!wait_queue_is_queue(wq) || !wait_queue_is_set(wq_set))
402 return KERN_INVALID_ARGUMENT;
403
404 /*
405 * There are probably less threads and sets associated with
406 * the wait queue, then there are wait queues associated with
407 * the set. So lets validate it that way.
408 */
409 s = splsched();
410 wait_queue_lock(wq);
411 q = &wq->wq_queue;
412 wq_element = (wait_queue_element_t) queue_first(q);
413 while (!queue_end(q, (queue_entry_t)wq_element)) {
414 WAIT_QUEUE_ELEMENT_CHECK(wq, wq_element);
415 if (wq_element->wqe_type == WAIT_QUEUE_LINK &&
416 ((wait_queue_link_t)wq_element)->wql_setqueue == wq_set) {
417 wait_queue_unlock(wq);
418 splx(s);
419 return KERN_ALREADY_IN_SET;
420 }
421 wq_element = (wait_queue_element_t)
422 queue_next((queue_t) wq_element);
423 }
424
425 /*
426 * Not already a member, so we can add it.
427 */
428 wqs_lock(wq_set);
429
430 WAIT_QUEUE_SET_CHECK(wq_set);
431
432 wql->wql_queue = wq;
433 queue_enter(&wq->wq_queue, wql, wait_queue_link_t, wql_links);
434 wql->wql_setqueue = wq_set;
435 queue_enter(&wq_set->wqs_setlinks, wql, wait_queue_link_t, wql_setlinks);
436 wql->wql_type = WAIT_QUEUE_LINK;
437
438 wqs_unlock(wq_set);
439 wait_queue_unlock(wq);
440 splx(s);
441
442 return KERN_SUCCESS;
443 }
444
445 /*
446 * Routine: wait_queue_link
447 * Purpose:
448 * Insert a set wait queue into a wait queue. This
449 * requires us to link the two together using a wait_queue_link
450 * structure that we allocate.
451 * Conditions:
452 * The wait queue being inserted must be inited as a set queue
453 */
454 kern_return_t
455 wait_queue_link(
456 wait_queue_t wq,
457 wait_queue_set_t wq_set)
458 {
459 wait_queue_link_t wql;
460 kern_return_t ret;
461
462 wql = (wait_queue_link_t) kalloc(sizeof(struct wait_queue_link));
463 if (wql == WAIT_QUEUE_LINK_NULL)
464 return KERN_RESOURCE_SHORTAGE;
465
466 ret = wait_queue_link_noalloc(wq, wq_set, wql);
467 if (ret != KERN_SUCCESS)
468 kfree((vm_offset_t)wql, sizeof(struct wait_queue_link));
469
470 return ret;
471 }
472
473
474 /*
475 * Routine: wait_queue_unlink_nofree
476 * Purpose:
477 * Undo the linkage between a wait queue and a set.
478 */
479 static void
480 wait_queue_unlink_locked(
481 wait_queue_t wq,
482 wait_queue_set_t wq_set,
483 wait_queue_link_t wql)
484 {
485 assert(wait_queue_held(wq));
486 assert(wait_queue_held(&wq_set->wqs_wait_queue));
487
488 wql->wql_queue = WAIT_QUEUE_NULL;
489 queue_remove(&wq->wq_queue, wql, wait_queue_link_t, wql_links);
490 wql->wql_setqueue = WAIT_QUEUE_SET_NULL;
491 queue_remove(&wq_set->wqs_setlinks, wql, wait_queue_link_t, wql_setlinks);
492 wql->wql_type = WAIT_QUEUE_UNLINKED;
493
494 WAIT_QUEUE_CHECK(wq);
495 WAIT_QUEUE_SET_CHECK(wq_set);
496 }
497
498 /*
499 * Routine: wait_queue_unlink
500 * Purpose:
501 * Remove the linkage between a wait queue and a set,
502 * freeing the linkage structure.
503 * Conditions:
504 * The wait queue being must be a member set queue
505 */
506 kern_return_t
507 wait_queue_unlink(
508 wait_queue_t wq,
509 wait_queue_set_t wq_set)
510 {
511 wait_queue_element_t wq_element;
512 wait_queue_link_t wql;
513 queue_t q;
514 spl_t s;
515
516 if (!wait_queue_is_queue(wq) || !wait_queue_is_set(wq_set)) {
517 return KERN_INVALID_ARGUMENT;
518 }
519 s = splsched();
520 wait_queue_lock(wq);
521
522 q = &wq->wq_queue;
523 wq_element = (wait_queue_element_t) queue_first(q);
524 while (!queue_end(q, (queue_entry_t)wq_element)) {
525 WAIT_QUEUE_ELEMENT_CHECK(wq, wq_element);
526 if (wq_element->wqe_type == WAIT_QUEUE_LINK) {
527 wql = (wait_queue_link_t)wq_element;
528
529 if (wql->wql_setqueue == wq_set) {
530 wqs_lock(wq_set);
531 wait_queue_unlink_locked(wq, wq_set, wql);
532 wqs_unlock(wq_set);
533 wait_queue_unlock(wq);
534 splx(s);
535 kfree((vm_offset_t)wql, sizeof(struct wait_queue_link));
536 return KERN_SUCCESS;
537 }
538 }
539 wq_element = (wait_queue_element_t)
540 queue_next((queue_t) wq_element);
541 }
542 wait_queue_unlock(wq);
543 splx(s);
544 return KERN_NOT_IN_SET;
545 }
546
547
548 /*
549 * Routine: wait_queue_unlinkall_nofree
550 * Purpose:
551 * Remove the linkage between a wait queue and all its
552 * sets. The caller is responsible for freeing
553 * the wait queue link structures.
554 */
555
556 kern_return_t
557 wait_queue_unlinkall_nofree(
558 wait_queue_t wq)
559 {
560 wait_queue_element_t wq_element;
561 wait_queue_element_t wq_next_element;
562 wait_queue_set_t wq_set;
563 wait_queue_link_t wql;
564 queue_head_t links_queue_head;
565 queue_t links = &links_queue_head;
566 queue_t q;
567 spl_t s;
568
569 if (!wait_queue_is_queue(wq)) {
570 return KERN_INVALID_ARGUMENT;
571 }
572
573 queue_init(links);
574
575 s = splsched();
576 wait_queue_lock(wq);
577
578 q = &wq->wq_queue;
579
580 wq_element = (wait_queue_element_t) queue_first(q);
581 while (!queue_end(q, (queue_entry_t)wq_element)) {
582 WAIT_QUEUE_ELEMENT_CHECK(wq, wq_element);
583 wq_next_element = (wait_queue_element_t)
584 queue_next((queue_t) wq_element);
585
586 if (wq_element->wqe_type == WAIT_QUEUE_LINK) {
587 wql = (wait_queue_link_t)wq_element;
588 wq_set = wql->wql_setqueue;
589 wqs_lock(wq_set);
590 wait_queue_unlink_locked(wq, wq_set, wql);
591 wqs_unlock(wq_set);
592 }
593 wq_element = wq_next_element;
594 }
595 wait_queue_unlock(wq);
596 splx(s);
597 return(KERN_SUCCESS);
598 }
599
600
601 /*
602 * Routine: wait_queue_unlink_all
603 * Purpose:
604 * Remove the linkage between a wait queue and all its sets.
605 * All the linkage structures are freed.
606 * Conditions:
607 * Nothing of interest locked.
608 */
609
610 kern_return_t
611 wait_queue_unlink_all(
612 wait_queue_t wq)
613 {
614 wait_queue_element_t wq_element;
615 wait_queue_element_t wq_next_element;
616 wait_queue_set_t wq_set;
617 wait_queue_link_t wql;
618 queue_head_t links_queue_head;
619 queue_t links = &links_queue_head;
620 queue_t q;
621 spl_t s;
622
623 if (!wait_queue_is_queue(wq)) {
624 return KERN_INVALID_ARGUMENT;
625 }
626
627 queue_init(links);
628
629 s = splsched();
630 wait_queue_lock(wq);
631
632 q = &wq->wq_queue;
633
634 wq_element = (wait_queue_element_t) queue_first(q);
635 while (!queue_end(q, (queue_entry_t)wq_element)) {
636 WAIT_QUEUE_ELEMENT_CHECK(wq, wq_element);
637 wq_next_element = (wait_queue_element_t)
638 queue_next((queue_t) wq_element);
639
640 if (wq_element->wqe_type == WAIT_QUEUE_LINK) {
641 wql = (wait_queue_link_t)wq_element;
642 wq_set = wql->wql_setqueue;
643 wqs_lock(wq_set);
644 wait_queue_unlink_locked(wq, wq_set, wql);
645 wqs_unlock(wq_set);
646 enqueue(links, &wql->wql_links);
647 }
648 wq_element = wq_next_element;
649 }
650 wait_queue_unlock(wq);
651 splx(s);
652
653 while(!queue_empty(links)) {
654 wql = (wait_queue_link_t) dequeue(links);
655 kfree((vm_offset_t) wql, sizeof(struct wait_queue_link));
656 }
657
658 return(KERN_SUCCESS);
659 }
660
661 /*
662 * Routine: wait_queue_set_unlink_all_nofree
663 * Purpose:
664 * Remove the linkage between a set wait queue and all its
665 * member wait queues. The link structures are not freed, nor
666 * returned. It is the caller's responsibility to track and free
667 * them.
668 * Conditions:
669 * The wait queue being must be a member set queue
670 */
671 kern_return_t
672 wait_queue_set_unlink_all_nofree(
673 wait_queue_set_t wq_set)
674 {
675 wait_queue_link_t wql;
676 wait_queue_t wq;
677 queue_t q;
678 kern_return_t kret;
679 spl_t s;
680
681 if (!wait_queue_is_set(wq_set)) {
682 return KERN_INVALID_ARGUMENT;
683 }
684
685 retry:
686 s = splsched();
687 wqs_lock(wq_set);
688
689 q = &wq_set->wqs_setlinks;
690
691 wql = (wait_queue_link_t)queue_first(q);
692 while (!queue_end(q, (queue_entry_t)wql)) {
693 WAIT_QUEUE_SET_LINK_CHECK(wq_set, wql);
694 wq = wql->wql_queue;
695 if (wait_queue_lock_try(wq)) {
696 wait_queue_unlink_locked(wq, wq_set, wql);
697 wait_queue_unlock(wq);
698 wql = (wait_queue_link_t)queue_first(q);
699 } else {
700 wqs_unlock(wq_set);
701 splx(s);
702 delay(1);
703 goto retry;
704 }
705 }
706 wqs_unlock(wq_set);
707 splx(s);
708
709 return(KERN_SUCCESS);
710 }
711
712 /* legacy interface naming */
713 kern_return_t
714 wait_subqueue_unlink_all(
715 wait_queue_set_t wq_set)
716 {
717 return wait_queue_set_unlink_all_nofree(wq_set);
718 }
719
720
721 /*
722 * Routine: wait_queue_set_unlink_all
723 * Purpose:
724 * Remove the linkage between a set wait queue and all its
725 * member wait queues. The link structures are freed.
726 * Conditions:
727 * The wait queue must be a set
728 */
729 kern_return_t
730 wait_queue_set_unlink_all(
731 wait_queue_set_t wq_set)
732 {
733 wait_queue_link_t wql;
734 wait_queue_t wq;
735 queue_t q;
736 queue_head_t links_queue_head;
737 queue_t links = &links_queue_head;
738 kern_return_t kret;
739 spl_t s;
740
741 if (!wait_queue_is_set(wq_set)) {
742 return KERN_INVALID_ARGUMENT;
743 }
744
745 queue_init(links);
746
747 retry:
748 s = splsched();
749 wqs_lock(wq_set);
750
751 q = &wq_set->wqs_setlinks;
752
753 wql = (wait_queue_link_t)queue_first(q);
754 while (!queue_end(q, (queue_entry_t)wql)) {
755 WAIT_QUEUE_SET_LINK_CHECK(wq_set, wql);
756 wq = wql->wql_queue;
757 if (wait_queue_lock_try(wq)) {
758 wait_queue_unlink_locked(wq, wq_set, wql);
759 wait_queue_unlock(wq);
760 enqueue(links, &wql->wql_links);
761 wql = (wait_queue_link_t)queue_first(q);
762 } else {
763 wqs_unlock(wq_set);
764 splx(s);
765 delay(1);
766 goto retry;
767 }
768 }
769 wqs_unlock(wq_set);
770 splx(s);
771
772 while (!queue_empty (links)) {
773 wql = (wait_queue_link_t) dequeue(links);
774 kfree((vm_offset_t)wql, sizeof(struct wait_queue_link));
775 }
776 return(KERN_SUCCESS);
777 }
778
779
780 /*
781 * Routine: wait_queue_unlink_one
782 * Purpose:
783 * Find and unlink one set wait queue
784 * Conditions:
785 * Nothing of interest locked.
786 */
787 void
788 wait_queue_unlink_one(
789 wait_queue_t wq,
790 wait_queue_set_t *wq_setp)
791 {
792 wait_queue_element_t wq_element;
793 queue_t q;
794 spl_t s;
795
796 s = splsched();
797 wait_queue_lock(wq);
798
799 q = &wq->wq_queue;
800
801 wq_element = (wait_queue_element_t) queue_first(q);
802 while (!queue_end(q, (queue_entry_t)wq_element)) {
803
804 if (wq_element->wqe_type == WAIT_QUEUE_LINK) {
805 wait_queue_link_t wql = (wait_queue_link_t)wq_element;
806 wait_queue_set_t wq_set = wql->wql_setqueue;
807
808 wqs_lock(wq_set);
809 wait_queue_unlink_locked(wq, wq_set, wql);
810 wqs_unlock(wq_set);
811 wait_queue_unlock(wq);
812 splx(s);
813 kfree((vm_offset_t)wql,sizeof(struct wait_queue_link));
814 *wq_setp = wq_set;
815 return;
816 }
817
818 wq_element = (wait_queue_element_t)
819 queue_next((queue_t) wq_element);
820 }
821 wait_queue_unlock(wq);
822 splx(s);
823 *wq_setp = WAIT_QUEUE_SET_NULL;
824 }
825
826
827 /*
828 * Routine: wait_queue_assert_wait64_locked
829 * Purpose:
830 * Insert the current thread into the supplied wait queue
831 * waiting for a particular event to be posted to that queue.
832 *
833 * Conditions:
834 * The wait queue is assumed locked.
835 *
836 */
837 __private_extern__ wait_result_t
838 wait_queue_assert_wait64_locked(
839 wait_queue_t wq,
840 event64_t event,
841 wait_interrupt_t interruptible,
842 boolean_t unlock)
843 {
844 thread_t thread;
845 wait_result_t wait_result;
846
847 if (wq->wq_type == _WAIT_QUEUE_SET_inited) {
848 wait_queue_set_t wqs = (wait_queue_set_t)wq;
849 if (wqs->wqs_isprepost && wqs->wqs_refcount > 0) {
850 if (unlock)
851 wait_queue_unlock(wq);
852 return(THREAD_AWAKENED);
853 }
854 }
855
856 /*
857 * This is the extent to which we currently take scheduling attributes
858 * into account. If the thread is vm priviledged, we stick it at
859 * the front of the queue. Later, these queues will honor the policy
860 * value set at wait_queue_init time.
861 */
862 thread = current_thread();
863 thread_lock(thread);
864 wait_result = thread_mark_wait_locked(thread, interruptible);
865 if (wait_result == THREAD_WAITING) {
866 if (thread->vm_privilege)
867 enqueue_head(&wq->wq_queue, (queue_entry_t) thread);
868 else
869 enqueue_tail(&wq->wq_queue, (queue_entry_t) thread);
870 thread->wait_event = event;
871 thread->wait_queue = wq;
872 }
873 thread_unlock(thread);
874 if (unlock)
875 wait_queue_unlock(wq);
876 return(wait_result);
877 }
878
879 /*
880 * Routine: wait_queue_assert_wait
881 * Purpose:
882 * Insert the current thread into the supplied wait queue
883 * waiting for a particular event to be posted to that queue.
884 *
885 * Conditions:
886 * nothing of interest locked.
887 */
888 wait_result_t
889 wait_queue_assert_wait(
890 wait_queue_t wq,
891 event_t event,
892 wait_interrupt_t interruptible)
893 {
894 spl_t s;
895 wait_result_t ret;
896
897 /* If it is an invalid wait queue, you can't wait on it */
898 if (!wait_queue_is_valid(wq)) {
899 thread_t thread = current_thread();
900 return (thread->wait_result = THREAD_RESTART);
901 }
902
903 s = splsched();
904 wait_queue_lock(wq);
905 ret = wait_queue_assert_wait64_locked(
906 wq, (event64_t)((uint32_t)event),
907 interruptible, TRUE);
908 /* wait queue unlocked */
909 splx(s);
910 return(ret);
911 }
912
913 /*
914 * Routine: wait_queue_assert_wait64
915 * Purpose:
916 * Insert the current thread into the supplied wait queue
917 * waiting for a particular event to be posted to that queue.
918 * Conditions:
919 * nothing of interest locked.
920 */
921 wait_result_t
922 wait_queue_assert_wait64(
923 wait_queue_t wq,
924 event64_t event,
925 wait_interrupt_t interruptible)
926 {
927 spl_t s;
928 wait_result_t ret;
929
930 /* If it is an invalid wait queue, you cant wait on it */
931 if (!wait_queue_is_valid(wq)) {
932 thread_t thread = current_thread();
933 return (thread->wait_result = THREAD_RESTART);
934 }
935
936 s = splsched();
937 wait_queue_lock(wq);
938 ret = wait_queue_assert_wait64_locked(wq, event, interruptible, TRUE);
939 /* wait queue unlocked */
940 splx(s);
941 return(ret);
942 }
943
944
945 /*
946 * Routine: _wait_queue_select64_all
947 * Purpose:
948 * Select all threads off a wait queue that meet the
949 * supplied criteria.
950 * Conditions:
951 * at splsched
952 * wait queue locked
953 * wake_queue initialized and ready for insertion
954 * possibly recursive
955 * Returns:
956 * a queue of locked threads
957 */
958 static void
959 _wait_queue_select64_all(
960 wait_queue_t wq,
961 event64_t event,
962 queue_t wake_queue)
963 {
964 wait_queue_element_t wq_element;
965 wait_queue_element_t wqe_next;
966 queue_t q;
967
968 q = &wq->wq_queue;
969
970 wq_element = (wait_queue_element_t) queue_first(q);
971 while (!queue_end(q, (queue_entry_t)wq_element)) {
972 WAIT_QUEUE_ELEMENT_CHECK(wq, wq_element);
973 wqe_next = (wait_queue_element_t)
974 queue_next((queue_t) wq_element);
975
976 /*
977 * We may have to recurse if this is a compound wait queue.
978 */
979 if (wq_element->wqe_type == WAIT_QUEUE_LINK) {
980 wait_queue_link_t wql = (wait_queue_link_t)wq_element;
981 wait_queue_t set_queue;
982
983 /*
984 * We have to check the set wait queue.
985 */
986 set_queue = (wait_queue_t)wql->wql_setqueue;
987 wait_queue_lock(set_queue);
988 if (set_queue->wq_isprepost) {
989 wait_queue_set_t wqs = (wait_queue_set_t)set_queue;
990
991 /*
992 * Preposting is only for sets and wait queue
993 * is the first element of set
994 */
995 wqs->wqs_refcount++;
996 }
997 if (! wait_queue_empty(set_queue))
998 _wait_queue_select64_all(set_queue, event, wake_queue);
999 wait_queue_unlock(set_queue);
1000 } else {
1001
1002 /*
1003 * Otherwise, its a thread. If it is waiting on
1004 * the event we are posting to this queue, pull
1005 * it off the queue and stick it in out wake_queue.
1006 */
1007 thread_t t = (thread_t)wq_element;
1008
1009 if (t->wait_event == event) {
1010 thread_lock(t);
1011 remqueue(q, (queue_entry_t) t);
1012 enqueue (wake_queue, (queue_entry_t) t);
1013 t->wait_queue = WAIT_QUEUE_NULL;
1014 t->wait_event = NO_EVENT64;
1015 t->at_safe_point = FALSE;
1016 /* returned locked */
1017 }
1018 }
1019 wq_element = wqe_next;
1020 }
1021 }
1022
1023 /*
1024 * Routine: wait_queue_wakeup64_all_locked
1025 * Purpose:
1026 * Wakeup some number of threads that are in the specified
1027 * wait queue and waiting on the specified event.
1028 * Conditions:
1029 * wait queue already locked (may be released).
1030 * Returns:
1031 * KERN_SUCCESS - Threads were woken up
1032 * KERN_NOT_WAITING - No threads were waiting <wq,event> pair
1033 */
1034 __private_extern__ kern_return_t
1035 wait_queue_wakeup64_all_locked(
1036 wait_queue_t wq,
1037 event64_t event,
1038 wait_result_t result,
1039 boolean_t unlock)
1040 {
1041 queue_head_t wake_queue_head;
1042 queue_t q = &wake_queue_head;
1043 kern_return_t res;
1044
1045 assert(wait_queue_held(wq));
1046 queue_init(q);
1047
1048 /*
1049 * Select the threads that we will wake up. The threads
1050 * are returned to us locked and cleanly removed from the
1051 * wait queue.
1052 */
1053 _wait_queue_select64_all(wq, event, q);
1054 if (unlock)
1055 wait_queue_unlock(wq);
1056
1057 /*
1058 * For each thread, set it running.
1059 */
1060 res = KERN_NOT_WAITING;
1061 while (!queue_empty (q)) {
1062 thread_t thread = (thread_t) dequeue(q);
1063 res = thread_go_locked(thread, result);
1064 assert(res == KERN_SUCCESS);
1065 thread_unlock(thread);
1066 }
1067 return res;
1068 }
1069
1070
1071 /*
1072 * Routine: wait_queue_wakeup_all
1073 * Purpose:
1074 * Wakeup some number of threads that are in the specified
1075 * wait queue and waiting on the specified event.
1076 * Conditions:
1077 * Nothing locked
1078 * Returns:
1079 * KERN_SUCCESS - Threads were woken up
1080 * KERN_NOT_WAITING - No threads were waiting <wq,event> pair
1081 */
1082 kern_return_t
1083 wait_queue_wakeup_all(
1084 wait_queue_t wq,
1085 event_t event,
1086 wait_result_t result)
1087 {
1088 kern_return_t ret;
1089 spl_t s;
1090
1091 if (!wait_queue_is_valid(wq)) {
1092 return KERN_INVALID_ARGUMENT;
1093 }
1094
1095 s = splsched();
1096 wait_queue_lock(wq);
1097 ret = wait_queue_wakeup64_all_locked(
1098 wq, (event64_t)((uint32_t)event),
1099 result, TRUE);
1100 /* lock released */
1101 splx(s);
1102 return ret;
1103 }
1104
1105 /*
1106 * Routine: wait_queue_wakeup64_all
1107 * Purpose:
1108 * Wakeup some number of threads that are in the specified
1109 * wait queue and waiting on the specified event.
1110 * Conditions:
1111 * Nothing locked
1112 * Returns:
1113 * KERN_SUCCESS - Threads were woken up
1114 * KERN_NOT_WAITING - No threads were waiting <wq,event> pair
1115 */
1116 kern_return_t
1117 wait_queue_wakeup64_all(
1118 wait_queue_t wq,
1119 event64_t event,
1120 wait_result_t result)
1121 {
1122 kern_return_t ret;
1123 spl_t s;
1124
1125 if (!wait_queue_is_valid(wq)) {
1126 return KERN_INVALID_ARGUMENT;
1127 }
1128
1129 s = splsched();
1130 wait_queue_lock(wq);
1131 ret = wait_queue_wakeup64_all_locked(wq, event, result, TRUE);
1132 /* lock released */
1133 splx(s);
1134 return ret;
1135 }
1136
1137 /*
1138 * Routine: _wait_queue_select64_one
1139 * Purpose:
1140 * Select the best thread off a wait queue that meet the
1141 * supplied criteria.
1142 * Conditions:
1143 * at splsched
1144 * wait queue locked
1145 * possibly recursive
1146 * Returns:
1147 * a locked thread - if one found
1148 * Note:
1149 * This is where the sync policy of the wait queue comes
1150 * into effect. For now, we just assume FIFO.
1151 */
1152 static thread_t
1153 _wait_queue_select64_one(
1154 wait_queue_t wq,
1155 event64_t event)
1156 {
1157 wait_queue_element_t wq_element;
1158 wait_queue_element_t wqe_next;
1159 thread_t t = THREAD_NULL;
1160 queue_t q;
1161
1162 assert(wq->wq_fifo);
1163
1164 q = &wq->wq_queue;
1165
1166 wq_element = (wait_queue_element_t) queue_first(q);
1167 while (!queue_end(q, (queue_entry_t)wq_element)) {
1168 WAIT_QUEUE_ELEMENT_CHECK(wq, wq_element);
1169 wqe_next = (wait_queue_element_t)
1170 queue_next((queue_t) wq_element);
1171
1172 /*
1173 * We may have to recurse if this is a compound wait queue.
1174 */
1175 if (wq_element->wqe_type == WAIT_QUEUE_LINK) {
1176 wait_queue_link_t wql = (wait_queue_link_t)wq_element;
1177 wait_queue_t set_queue;
1178
1179 /*
1180 * We have to check the set wait queue.
1181 */
1182 set_queue = (wait_queue_t)wql->wql_setqueue;
1183 wait_queue_lock(set_queue);
1184 if (! wait_queue_empty(set_queue)) {
1185 t = _wait_queue_select64_one(set_queue, event);
1186 }
1187 wait_queue_unlock(set_queue);
1188 if (t != THREAD_NULL)
1189 return t;
1190 } else {
1191
1192 /*
1193 * Otherwise, its a thread. If it is waiting on
1194 * the event we are posting to this queue, pull
1195 * it off the queue and stick it in out wake_queue.
1196 */
1197 thread_t t = (thread_t)wq_element;
1198
1199 if (t->wait_event == event) {
1200 thread_lock(t);
1201 remqueue(q, (queue_entry_t) t);
1202 t->wait_queue = WAIT_QUEUE_NULL;
1203 t->wait_event = NO_EVENT64;
1204 t->at_safe_point = FALSE;
1205 return t; /* still locked */
1206 }
1207 }
1208 wq_element = wqe_next;
1209 }
1210 return THREAD_NULL;
1211 }
1212
1213 /*
1214 * Routine: wait_queue_peek64_locked
1215 * Purpose:
1216 * Select the best thread from a wait queue that meet the
1217 * supplied criteria, but leave it on the queue it was
1218 * found on. The thread, and the actual wait_queue the
1219 * thread was found on are identified.
1220 * Conditions:
1221 * at splsched
1222 * wait queue locked
1223 * possibly recursive
1224 * Returns:
1225 * a locked thread - if one found
1226 * a locked waitq - the one the thread was found on
1227 * Note:
1228 * Both the waitq the thread was actually found on, and
1229 * the supplied wait queue, are locked after this.
1230 */
1231 __private_extern__ void
1232 wait_queue_peek64_locked(
1233 wait_queue_t wq,
1234 event64_t event,
1235 thread_t *tp,
1236 wait_queue_t *wqp)
1237 {
1238 wait_queue_element_t wq_element;
1239 wait_queue_element_t wqe_next;
1240 thread_t t;
1241 queue_t q;
1242
1243 assert(wq->wq_fifo);
1244
1245 *tp = THREAD_NULL;
1246
1247 q = &wq->wq_queue;
1248
1249 wq_element = (wait_queue_element_t) queue_first(q);
1250 while (!queue_end(q, (queue_entry_t)wq_element)) {
1251 WAIT_QUEUE_ELEMENT_CHECK(wq, wq_element);
1252 wqe_next = (wait_queue_element_t)
1253 queue_next((queue_t) wq_element);
1254
1255 /*
1256 * We may have to recurse if this is a compound wait queue.
1257 */
1258 if (wq_element->wqe_type == WAIT_QUEUE_LINK) {
1259 wait_queue_link_t wql = (wait_queue_link_t)wq_element;
1260 wait_queue_t set_queue;
1261
1262 /*
1263 * We have to check the set wait queue.
1264 */
1265 set_queue = (wait_queue_t)wql->wql_setqueue;
1266 wait_queue_lock(set_queue);
1267 if (! wait_queue_empty(set_queue)) {
1268 wait_queue_peek64_locked(set_queue, event, tp, wqp);
1269 }
1270 if (*tp != THREAD_NULL) {
1271 if (*wqp != set_queue)
1272 wait_queue_unlock(set_queue);
1273 return; /* thread and its waitq locked */
1274 }
1275
1276 wait_queue_unlock(set_queue);
1277 } else {
1278
1279 /*
1280 * Otherwise, its a thread. If it is waiting on
1281 * the event we are posting to this queue, return
1282 * it locked, but leave it on the queue.
1283 */
1284 thread_t t = (thread_t)wq_element;
1285
1286 if (t->wait_event == event) {
1287 thread_lock(t);
1288 *tp = t;
1289 *wqp = wq;
1290 return;
1291 }
1292 }
1293 wq_element = wqe_next;
1294 }
1295 }
1296
1297 /*
1298 * Routine: wait_queue_pull_thread_locked
1299 * Purpose:
1300 * Pull a thread that was previously "peeked" off the wait
1301 * queue and (possibly) unlock the waitq.
1302 * Conditions:
1303 * at splsched
1304 * wait queue locked
1305 * thread locked
1306 * Returns:
1307 * with the thread still locked.
1308 */
1309 void
1310 wait_queue_pull_thread_locked(
1311 wait_queue_t waitq,
1312 thread_t thread,
1313 boolean_t unlock)
1314 {
1315
1316 assert(thread->wait_queue == waitq);
1317
1318 remqueue(&waitq->wq_queue, (queue_entry_t)thread );
1319 thread->wait_queue = WAIT_QUEUE_NULL;
1320 thread->wait_event = NO_EVENT64;
1321 thread->at_safe_point = FALSE;
1322 if (unlock)
1323 wait_queue_unlock(waitq);
1324 }
1325
1326
1327 /*
1328 * Routine: wait_queue_select64_thread
1329 * Purpose:
1330 * Look for a thread and remove it from the queues, if
1331 * (and only if) the thread is waiting on the supplied
1332 * <wait_queue, event> pair.
1333 * Conditions:
1334 * at splsched
1335 * wait queue locked
1336 * possibly recursive
1337 * Returns:
1338 * KERN_NOT_WAITING: Thread is not waiting here.
1339 * KERN_SUCCESS: It was, and is now removed (returned locked)
1340 */
1341 static kern_return_t
1342 _wait_queue_select64_thread(
1343 wait_queue_t wq,
1344 event64_t event,
1345 thread_t thread)
1346 {
1347 wait_queue_element_t wq_element;
1348 wait_queue_element_t wqe_next;
1349 kern_return_t res = KERN_NOT_WAITING;
1350 queue_t q = &wq->wq_queue;
1351
1352 thread_lock(thread);
1353 if ((thread->wait_queue == wq) && (thread->wait_event == event)) {
1354 remqueue(q, (queue_entry_t) thread);
1355 thread->at_safe_point = FALSE;
1356 thread->wait_event = NO_EVENT64;
1357 thread->wait_queue = WAIT_QUEUE_NULL;
1358 /* thread still locked */
1359 return KERN_SUCCESS;
1360 }
1361 thread_unlock(thread);
1362
1363 /*
1364 * The wait_queue associated with the thread may be one of this
1365 * wait queue's sets. Go see. If so, removing it from
1366 * there is like removing it from here.
1367 */
1368 wq_element = (wait_queue_element_t) queue_first(q);
1369 while (!queue_end(q, (queue_entry_t)wq_element)) {
1370 WAIT_QUEUE_ELEMENT_CHECK(wq, wq_element);
1371 wqe_next = (wait_queue_element_t)
1372 queue_next((queue_t) wq_element);
1373
1374 if (wq_element->wqe_type == WAIT_QUEUE_LINK) {
1375 wait_queue_link_t wql = (wait_queue_link_t)wq_element;
1376 wait_queue_t set_queue;
1377
1378 set_queue = (wait_queue_t)wql->wql_setqueue;
1379 wait_queue_lock(set_queue);
1380 if (! wait_queue_empty(set_queue)) {
1381 res = _wait_queue_select64_thread(set_queue,
1382 event,
1383 thread);
1384 }
1385 wait_queue_unlock(set_queue);
1386 if (res == KERN_SUCCESS)
1387 return KERN_SUCCESS;
1388 }
1389 wq_element = wqe_next;
1390 }
1391 return res;
1392 }
1393
1394
1395 /*
1396 * Routine: wait_queue_wakeup64_identity_locked
1397 * Purpose:
1398 * Select a single thread that is most-eligible to run and set
1399 * set it running. But return the thread locked.
1400 *
1401 * Conditions:
1402 * at splsched
1403 * wait queue locked
1404 * possibly recursive
1405 * Returns:
1406 * a pointer to the locked thread that was awakened
1407 */
1408 __private_extern__ thread_t
1409 wait_queue_wakeup64_identity_locked(
1410 wait_queue_t wq,
1411 event64_t event,
1412 wait_result_t result,
1413 boolean_t unlock)
1414 {
1415 kern_return_t res;
1416 thread_t thread;
1417
1418 assert(wait_queue_held(wq));
1419
1420
1421 thread = _wait_queue_select64_one(wq, event);
1422 if (unlock)
1423 wait_queue_unlock(wq);
1424
1425 if (thread) {
1426 res = thread_go_locked(thread, result);
1427 assert(res == KERN_SUCCESS);
1428 }
1429 return thread; /* still locked if not NULL */
1430 }
1431
1432
1433 /*
1434 * Routine: wait_queue_wakeup64_one_locked
1435 * Purpose:
1436 * Select a single thread that is most-eligible to run and set
1437 * set it runnings.
1438 *
1439 * Conditions:
1440 * at splsched
1441 * wait queue locked
1442 * possibly recursive
1443 * Returns:
1444 * KERN_SUCCESS: It was, and is, now removed.
1445 * KERN_NOT_WAITING - No thread was waiting <wq,event> pair
1446 */
1447 __private_extern__ kern_return_t
1448 wait_queue_wakeup64_one_locked(
1449 wait_queue_t wq,
1450 event64_t event,
1451 wait_result_t result,
1452 boolean_t unlock)
1453 {
1454 thread_t thread;
1455
1456 assert(wait_queue_held(wq));
1457
1458 thread = _wait_queue_select64_one(wq, event);
1459 if (unlock)
1460 wait_queue_unlock(wq);
1461
1462 if (thread) {
1463 kern_return_t res;
1464
1465 res = thread_go_locked(thread, result);
1466 assert(res == KERN_SUCCESS);
1467 thread_unlock(thread);
1468 return res;
1469 }
1470
1471 return KERN_NOT_WAITING;
1472 }
1473
1474 /*
1475 * Routine: wait_queue_wakeup_one
1476 * Purpose:
1477 * Wakeup the most appropriate thread that is in the specified
1478 * wait queue for the specified event.
1479 * Conditions:
1480 * Nothing locked
1481 * Returns:
1482 * KERN_SUCCESS - Thread was woken up
1483 * KERN_NOT_WAITING - No thread was waiting <wq,event> pair
1484 */
1485 kern_return_t
1486 wait_queue_wakeup_one(
1487 wait_queue_t wq,
1488 event_t event,
1489 wait_result_t result)
1490 {
1491 thread_t thread;
1492 spl_t s;
1493
1494 if (!wait_queue_is_valid(wq)) {
1495 return KERN_INVALID_ARGUMENT;
1496 }
1497
1498 s = splsched();
1499 wait_queue_lock(wq);
1500 thread = _wait_queue_select64_one(wq, (event64_t)((uint32_t)event));
1501 wait_queue_unlock(wq);
1502
1503 if (thread) {
1504 kern_return_t res;
1505
1506 res = thread_go_locked(thread, result);
1507 assert(res == KERN_SUCCESS);
1508 thread_unlock(thread);
1509 splx(s);
1510 return res;
1511 }
1512
1513 splx(s);
1514 return KERN_NOT_WAITING;
1515 }
1516
1517 /*
1518 * Routine: wait_queue_wakeup64_one
1519 * Purpose:
1520 * Wakeup the most appropriate thread that is in the specified
1521 * wait queue for the specified event.
1522 * Conditions:
1523 * Nothing locked
1524 * Returns:
1525 * KERN_SUCCESS - Thread was woken up
1526 * KERN_NOT_WAITING - No thread was waiting <wq,event> pair
1527 */
1528 kern_return_t
1529 wait_queue_wakeup64_one(
1530 wait_queue_t wq,
1531 event64_t event,
1532 wait_result_t result)
1533 {
1534 thread_t thread;
1535 spl_t s;
1536
1537 if (!wait_queue_is_valid(wq)) {
1538 return KERN_INVALID_ARGUMENT;
1539 }
1540 s = splsched();
1541 wait_queue_lock(wq);
1542 thread = _wait_queue_select64_one(wq, event);
1543 wait_queue_unlock(wq);
1544
1545 if (thread) {
1546 kern_return_t res;
1547
1548 res = thread_go_locked(thread, result);
1549 assert(res == KERN_SUCCESS);
1550 thread_unlock(thread);
1551 splx(s);
1552 return res;
1553 }
1554
1555 splx(s);
1556 return KERN_NOT_WAITING;
1557 }
1558
1559
1560 /*
1561 * Routine: wait_queue_wakeup64_thread_locked
1562 * Purpose:
1563 * Wakeup the particular thread that was specified if and only
1564 * it was in this wait queue (or one of it's set queues)
1565 * and waiting on the specified event.
1566 *
1567 * This is much safer than just removing the thread from
1568 * whatever wait queue it happens to be on. For instance, it
1569 * may have already been awoken from the wait you intended to
1570 * interrupt and waited on something else (like another
1571 * semaphore).
1572 * Conditions:
1573 * at splsched
1574 * wait queue already locked (may be released).
1575 * Returns:
1576 * KERN_SUCCESS - the thread was found waiting and awakened
1577 * KERN_NOT_WAITING - the thread was not waiting here
1578 */
1579 __private_extern__ kern_return_t
1580 wait_queue_wakeup64_thread_locked(
1581 wait_queue_t wq,
1582 event64_t event,
1583 thread_t thread,
1584 wait_result_t result,
1585 boolean_t unlock)
1586 {
1587 kern_return_t res;
1588
1589 assert(wait_queue_held(wq));
1590
1591 /*
1592 * See if the thread was still waiting there. If so, it got
1593 * dequeued and returned locked.
1594 */
1595 res = _wait_queue_select64_thread(wq, event, thread);
1596 if (unlock)
1597 wait_queue_unlock(wq);
1598
1599 if (res != KERN_SUCCESS)
1600 return KERN_NOT_WAITING;
1601
1602 res = thread_go_locked(thread, result);
1603 assert(res == KERN_SUCCESS);
1604 thread_unlock(thread);
1605 return res;
1606 }
1607
1608 /*
1609 * Routine: wait_queue_wakeup_thread
1610 * Purpose:
1611 * Wakeup the particular thread that was specified if and only
1612 * it was in this wait queue (or one of it's set queues)
1613 * and waiting on the specified event.
1614 *
1615 * This is much safer than just removing the thread from
1616 * whatever wait queue it happens to be on. For instance, it
1617 * may have already been awoken from the wait you intended to
1618 * interrupt and waited on something else (like another
1619 * semaphore).
1620 * Conditions:
1621 * nothing of interest locked
1622 * we need to assume spl needs to be raised
1623 * Returns:
1624 * KERN_SUCCESS - the thread was found waiting and awakened
1625 * KERN_NOT_WAITING - the thread was not waiting here
1626 */
1627 kern_return_t
1628 wait_queue_wakeup_thread(
1629 wait_queue_t wq,
1630 event_t event,
1631 thread_t thread,
1632 wait_result_t result)
1633 {
1634 kern_return_t res;
1635 spl_t s;
1636
1637 if (!wait_queue_is_valid(wq)) {
1638 return KERN_INVALID_ARGUMENT;
1639 }
1640
1641 s = splsched();
1642 wait_queue_lock(wq);
1643 res = _wait_queue_select64_thread(wq, (event64_t)((uint32_t)event), thread);
1644 wait_queue_unlock(wq);
1645
1646 if (res == KERN_SUCCESS) {
1647 res = thread_go_locked(thread, result);
1648 assert(res == KERN_SUCCESS);
1649 thread_unlock(thread);
1650 splx(s);
1651 return res;
1652 }
1653 splx(s);
1654 return KERN_NOT_WAITING;
1655 }
1656
1657 /*
1658 * Routine: wait_queue_wakeup64_thread
1659 * Purpose:
1660 * Wakeup the particular thread that was specified if and only
1661 * it was in this wait queue (or one of it's set's queues)
1662 * and waiting on the specified event.
1663 *
1664 * This is much safer than just removing the thread from
1665 * whatever wait queue it happens to be on. For instance, it
1666 * may have already been awoken from the wait you intended to
1667 * interrupt and waited on something else (like another
1668 * semaphore).
1669 * Conditions:
1670 * nothing of interest locked
1671 * we need to assume spl needs to be raised
1672 * Returns:
1673 * KERN_SUCCESS - the thread was found waiting and awakened
1674 * KERN_NOT_WAITING - the thread was not waiting here
1675 */
1676 kern_return_t
1677 wait_queue_wakeup64_thread(
1678 wait_queue_t wq,
1679 event64_t event,
1680 thread_t thread,
1681 wait_result_t result)
1682 {
1683 kern_return_t res;
1684 spl_t s;
1685
1686 if (!wait_queue_is_valid(wq)) {
1687 return KERN_INVALID_ARGUMENT;
1688 }
1689
1690 s = splsched();
1691 wait_queue_lock(wq);
1692 res = _wait_queue_select64_thread(wq, event, thread);
1693 wait_queue_unlock(wq);
1694
1695 if (res == KERN_SUCCESS) {
1696 res = thread_go_locked(thread, result);
1697 assert(res == KERN_SUCCESS);
1698 thread_unlock(thread);
1699 splx(s);
1700 return res;
1701 }
1702 splx(s);
1703 return KERN_NOT_WAITING;
1704 }