/*
- * Copyright (c) 2000-2005 Apple Computer, Inc. All rights reserved.
+ * Copyright (c) 2000-2007 Apple Inc. All rights reserved.
*
- * @APPLE_LICENSE_OSREFERENCE_HEADER_START@
+ * @APPLE_OSREFERENCE_LICENSE_HEADER_START@
*
- * This file contains Original Code and/or Modifications of Original Code
- * as defined in and that are subject to the Apple Public Source License
- * Version 2.0 (the 'License'). You may not use this file except in
- * compliance with the License. The rights granted to you under the
- * License may not be used to create, or enable the creation or
- * redistribution of, unlawful or unlicensed copies of an Apple operating
- * system, or to circumvent, violate, or enable the circumvention or
- * violation of, any terms of an Apple operating system software license
- * agreement.
- *
- * Please obtain a copy of the License at
- * http://www.opensource.apple.com/apsl/ and read it before using this
- * file.
- *
- * The Original Code and all software distributed under the License are
- * distributed on an 'AS IS' basis, WITHOUT WARRANTY OF ANY KIND, EITHER
- * EXPRESS OR IMPLIED, AND APPLE HEREBY DISCLAIMS ALL SUCH WARRANTIES,
- * INCLUDING WITHOUT LIMITATION, ANY WARRANTIES OF MERCHANTABILITY,
- * FITNESS FOR A PARTICULAR PURPOSE, QUIET ENJOYMENT OR NON-INFRINGEMENT.
- * Please see the License for the specific language governing rights and
+ * This file contains Original Code and/or Modifications of Original Code
+ * as defined in and that are subject to the Apple Public Source License
+ * Version 2.0 (the 'License'). You may not use this file except in
+ * compliance with the License. The rights granted to you under the License
+ * may not be used to create, or enable the creation or redistribution of,
+ * unlawful or unlicensed copies of an Apple operating system, or to
+ * circumvent, violate, or enable the circumvention or violation of, any
+ * terms of an Apple operating system software license agreement.
+ *
+ * Please obtain a copy of the License at
+ * http://www.opensource.apple.com/apsl/ and read it before using this file.
+ *
+ * The Original Code and all software distributed under the License are
+ * distributed on an 'AS IS' basis, WITHOUT WARRANTY OF ANY KIND, EITHER
+ * EXPRESS OR IMPLIED, AND APPLE HEREBY DISCLAIMS ALL SUCH WARRANTIES,
+ * INCLUDING WITHOUT LIMITATION, ANY WARRANTIES OF MERCHANTABILITY,
+ * FITNESS FOR A PARTICULAR PURPOSE, QUIET ENJOYMENT OR NON-INFRINGEMENT.
+ * Please see the License for the specific language governing rights and
* limitations under the License.
- *
- * @APPLE_LICENSE_OSREFERENCE_HEADER_END@
+ *
+ * @APPLE_OSREFERENCE_LICENSE_HEADER_END@
*/
/*
* @OSF_FREE_COPYRIGHT@
#include <kern/kern_types.h>
#include <kern/simple_lock.h>
-#include <kern/kalloc.h>
+#include <kern/zalloc.h>
#include <kern/queue.h>
#include <kern/spl.h>
#include <mach/sync_policy.h>
+#include <kern/mach_param.h>
#include <kern/sched_prim.h>
#include <kern/wait_queue.h>
+#include <vm/vm_kern.h>
/* forward declarations */
static boolean_t wait_queue_member_locked(
wait_queue_t wq,
wait_queue_set_t wq_set);
-void wait_queue_unlink_one(
- wait_queue_t wq,
- wait_queue_set_t *wq_setp);
+static void wait_queues_init(void) __attribute__((section("__TEXT, initcode")));
-kern_return_t wait_queue_set_unlink_all_nofree(
- wait_queue_set_t wq_set);
+
+#define WAIT_QUEUE_MAX thread_max
+#define WAIT_QUEUE_SET_MAX task_max * 3
+#define WAIT_QUEUE_LINK_MAX PORT_MAX / 2 + (WAIT_QUEUE_MAX * WAIT_QUEUE_SET_MAX) / 64
+
+static zone_t _wait_queue_link_zone;
+static zone_t _wait_queue_set_zone;
+static zone_t _wait_queue_zone;
+
+/* see rdar://6737748&5561610; we need an unshadowed
+ * definition of a WaitQueueLink for debugging,
+ * but it needs to be used somewhere to wind up in
+ * the dSYM file. */
+volatile WaitQueueLink *unused_except_for_debugging;
+
+
+/*
+ * Waiting protocols and implementation:
+ *
+ * Each thread may be waiting for exactly one event; this event
+ * is set using assert_wait(). That thread may be awakened either
+ * by performing a thread_wakeup_prim() on its event,
+ * or by directly waking that thread up with clear_wait().
+ *
+ * The implementation of wait events uses a hash table. Each
+ * bucket is queue of threads having the same hash function
+ * value; the chain for the queue (linked list) is the run queue
+ * field. [It is not possible to be waiting and runnable at the
+ * same time.]
+ *
+ * Locks on both the thread and on the hash buckets govern the
+ * wait event field and the queue chain field. Because wakeup
+ * operations only have the event as an argument, the event hash
+ * bucket must be locked before any thread.
+ *
+ * Scheduling operations may also occur at interrupt level; therefore,
+ * interrupts below splsched() must be prevented when holding
+ * thread or hash bucket locks.
+ *
+ * The wait event hash table declarations are as follows:
+ */
+
+struct wait_queue boot_wait_queue[1];
+__private_extern__ struct wait_queue *wait_queues = &boot_wait_queue[0];
+
+__private_extern__ uint32_t num_wait_queues = 1;
+
+static uint32_t
+compute_wait_hash_size(__unused unsigned cpu_count, __unused uint64_t memsize) {
+ uint32_t hsize = (uint32_t)round_page_64((thread_max / 11) * sizeof(struct wait_queue));
+ uint32_t bhsize;
+
+ if (PE_parse_boot_argn("wqsize", &bhsize, sizeof(bhsize)))
+ hsize = bhsize;
+
+ return hsize;
+}
+
+static void
+wait_queues_init(void)
+{
+ uint32_t i, whsize;
+ kern_return_t kret;
+
+ whsize = compute_wait_hash_size(processor_avail_count, machine_info.max_mem);
+ num_wait_queues = (whsize / ((uint32_t)sizeof(struct wait_queue))) - 1;
+
+ kret = kernel_memory_allocate(kernel_map, (vm_offset_t *) &wait_queues, whsize, 0, KMA_KOBJECT|KMA_NOPAGEWAIT);
+
+ if (kret != KERN_SUCCESS || wait_queues == NULL)
+ panic("kernel_memory_allocate() failed to allocate wait queues, error: %d, whsize: 0x%x", kret, whsize);
+
+ for (i = 0; i < num_wait_queues; i++) {
+ wait_queue_init(&wait_queues[i], SYNC_POLICY_FIFO);
+ }
+}
+
+void
+wait_queue_bootstrap(void)
+{
+ wait_queues_init();
+ _wait_queue_zone = zinit(sizeof(struct wait_queue),
+ WAIT_QUEUE_MAX * sizeof(struct wait_queue),
+ sizeof(struct wait_queue),
+ "wait queues");
+ _wait_queue_set_zone = zinit(sizeof(struct wait_queue_set),
+ WAIT_QUEUE_SET_MAX * sizeof(struct wait_queue_set),
+ sizeof(struct wait_queue_set),
+ "wait queue sets");
+ _wait_queue_link_zone = zinit(sizeof(struct _wait_queue_link),
+ WAIT_QUEUE_LINK_MAX * sizeof(struct _wait_queue_link),
+ sizeof(struct _wait_queue_link),
+ "wait queue links");
+}
/*
* Routine: wait_queue_init
wait_queue_t wq,
int policy)
{
- if (!((policy & SYNC_POLICY_ORDER_MASK) == SYNC_POLICY_FIFO))
+ /* only FIFO and LIFO for now */
+ if ((policy & SYNC_POLICY_FIXED_PRIORITY) != 0)
return KERN_INVALID_ARGUMENT;
- wq->wq_fifo = TRUE;
+ wq->wq_fifo = ((policy & SYNC_POLICY_REVERSED) == 0);
wq->wq_type = _WAIT_QUEUE_inited;
queue_init(&wq->wq_queue);
hw_lock_init(&wq->wq_interlock);
wait_queue_t wq;
kern_return_t ret;
- wq = (wait_queue_t) kalloc(sizeof(struct wait_queue));
+ wq = (wait_queue_t) zalloc(_wait_queue_zone);
if (wq != WAIT_QUEUE_NULL) {
ret = wait_queue_init(wq, policy);
if (ret != KERN_SUCCESS) {
- kfree(wq, sizeof(struct wait_queue));
+ zfree(_wait_queue_zone, wq);
wq = WAIT_QUEUE_NULL;
}
}
return KERN_INVALID_ARGUMENT;
if (!queue_empty(&wq->wq_queue))
return KERN_FAILURE;
- kfree(wq, sizeof(struct wait_queue));
+ zfree(_wait_queue_zone, wq);
return KERN_SUCCESS;
}
wqset->wqs_wait_queue.wq_type = _WAIT_QUEUE_SET_inited;
if (policy & SYNC_POLICY_PREPOST)
- wqset->wqs_wait_queue.wq_isprepost = TRUE;
+ wqset->wqs_wait_queue.wq_prepost = TRUE;
else
- wqset->wqs_wait_queue.wq_isprepost = FALSE;
+ wqset->wqs_wait_queue.wq_prepost = FALSE;
queue_init(&wqset->wqs_setlinks);
- wqset->wqs_refcount = 0;
+ queue_init(&wqset->wqs_preposts);
return KERN_SUCCESS;
}
wait_queue_sub_clearrefs(
wait_queue_set_t wq_set)
{
+ wait_queue_link_t wql;
+ queue_t q;
+ spl_t s;
+
if (!wait_queue_is_set(wq_set))
return KERN_INVALID_ARGUMENT;
+ s = splsched();
wqs_lock(wq_set);
- wq_set->wqs_refcount = 0;
+ q = &wq_set->wqs_preposts;
+ while (!queue_empty(q)) {
+ queue_remove_first(q, wql, wait_queue_link_t, wql_preposts);
+ assert(!wql_is_preposted(wql));
+ }
wqs_unlock(wq_set);
+ splx(s);
return KERN_SUCCESS;
}
{
wait_queue_set_t wq_set;
- wq_set = (wait_queue_set_t) kalloc(sizeof(struct wait_queue_set));
+ wq_set = (wait_queue_set_t) zalloc(_wait_queue_set_zone);
if (wq_set != WAIT_QUEUE_SET_NULL) {
kern_return_t ret;
ret = wait_queue_set_init(wq_set, policy);
if (ret != KERN_SUCCESS) {
- kfree(wq_set, sizeof(struct wait_queue_set));
+ zfree(_wait_queue_set_zone, wq_set);
wq_set = WAIT_QUEUE_SET_NULL;
}
}
if (!queue_empty(&wq_set->wqs_wait_queue.wq_queue))
return KERN_FAILURE;
- kfree(wq_set, sizeof(struct wait_queue_set));
+ zfree(_wait_queue_set_zone, wq_set);
return KERN_SUCCESS;
}
/* declare a unique type for wait queue link structures */
static unsigned int _wait_queue_link;
+static unsigned int _wait_queue_link_noalloc;
static unsigned int _wait_queue_unlinked;
#define WAIT_QUEUE_LINK ((void *)&_wait_queue_link)
+#define WAIT_QUEUE_LINK_NOALLOC ((void *)&_wait_queue_link_noalloc)
#define WAIT_QUEUE_UNLINKED ((void *)&_wait_queue_unlinked)
#define WAIT_QUEUE_ELEMENT_CHECK(wq, wqe) \
(queue_t)(wql) : &(wql)->wql_setlinks)))
#define WAIT_QUEUE_SET_LINK_CHECK(wqs, wql) \
- WQASSERT((((wql)->wql_type == WAIT_QUEUE_LINK) && \
+ WQASSERT(((((wql)->wql_type == WAIT_QUEUE_LINK) || \
+ ((wql)->wql_type == WAIT_QUEUE_LINK_NOALLOC)) && \
((wql)->wql_setqueue == (wqs)) && \
- ((wql)->wql_queue->wq_type == _WAIT_QUEUE_inited) && \
+ (((wql)->wql_queue->wq_type == _WAIT_QUEUE_inited) || \
+ ((wql)->wql_queue->wq_type == _WAIT_QUEUE_SET_inited)) && \
(WQSNEXT((wqs), WQSPREV((wqs),(wql))) == (wql))), \
"wait queue set links corruption: wqs=%#x, wql=%#x", \
- (wqs), (wql))
+ (wqs), (wql))
#if defined(_WAIT_QUEUE_DEBUG_)
wq_element = (wait_queue_element_t) queue_first(q);
while (!queue_end(q, (queue_entry_t)wq_element)) {
WAIT_QUEUE_ELEMENT_CHECK(wq, wq_element);
- if ((wq_element->wqe_type == WAIT_QUEUE_LINK)) {
+ if ((wq_element->wqe_type == WAIT_QUEUE_LINK) ||
+ (wq_element->wqe_type == WAIT_QUEUE_LINK_NOALLOC)) {
wait_queue_link_t wql = (wait_queue_link_t)wq_element;
if (wql->wql_setqueue == wq_set)
/*
- * Routine: wait_queue_link_noalloc
+ * Routine: wait_queue_link_internal
* Purpose:
* Insert a set wait queue into a wait queue. This
* requires us to link the two together using a wait_queue_link
- * structure that we allocate.
+ * structure that was provided.
* Conditions:
* The wait queue being inserted must be inited as a set queue
+ * The wait_queue_link structure must already be properly typed
*/
+static
kern_return_t
-wait_queue_link_noalloc(
+wait_queue_link_internal(
wait_queue_t wq,
wait_queue_set_t wq_set,
wait_queue_link_t wql)
queue_t q;
spl_t s;
- if (!wait_queue_is_queue(wq) || !wait_queue_is_set(wq_set))
+ if (!wait_queue_is_valid(wq) || !wait_queue_is_set(wq_set))
return KERN_INVALID_ARGUMENT;
/*
- * There are probably less threads and sets associated with
- * the wait queue, then there are wait queues associated with
- * the set. So lets validate it that way.
+ * There are probably fewer threads and sets associated with
+ * the wait queue than there are wait queues associated with
+ * the set. So let's validate it that way.
*/
s = splsched();
wait_queue_lock(wq);
wq_element = (wait_queue_element_t) queue_first(q);
while (!queue_end(q, (queue_entry_t)wq_element)) {
WAIT_QUEUE_ELEMENT_CHECK(wq, wq_element);
- if (wq_element->wqe_type == WAIT_QUEUE_LINK &&
+ if ((wq_element->wqe_type == WAIT_QUEUE_LINK ||
+ wq_element->wqe_type == WAIT_QUEUE_LINK_NOALLOC) &&
((wait_queue_link_t)wq_element)->wql_setqueue == wq_set) {
wait_queue_unlock(wq);
splx(s);
WAIT_QUEUE_SET_CHECK(wq_set);
+ assert(wql->wql_type == WAIT_QUEUE_LINK ||
+ wql->wql_type == WAIT_QUEUE_LINK_NOALLOC);
+
wql->wql_queue = wq;
+ wql_clear_prepost(wql);
queue_enter(&wq->wq_queue, wql, wait_queue_link_t, wql_links);
wql->wql_setqueue = wq_set;
queue_enter(&wq_set->wqs_setlinks, wql, wait_queue_link_t, wql_setlinks);
- wql->wql_type = WAIT_QUEUE_LINK;
wqs_unlock(wq_set);
wait_queue_unlock(wq);
return KERN_SUCCESS;
}
+/*
+ * Routine: wait_queue_link_noalloc
+ * Purpose:
+ * Insert a set wait queue into a wait queue. This
+ * requires us to link the two together using a wait_queue_link
+ * structure that we allocate.
+ * Conditions:
+ * The wait queue being inserted must be inited as a set queue
+ */
+kern_return_t
+wait_queue_link_noalloc(
+ wait_queue_t wq,
+ wait_queue_set_t wq_set,
+ wait_queue_link_t wql)
+{
+ wql->wql_type = WAIT_QUEUE_LINK_NOALLOC;
+ return wait_queue_link_internal(wq, wq_set, wql);
+}
+
/*
* Routine: wait_queue_link
* Purpose:
wait_queue_link_t wql;
kern_return_t ret;
- wql = (wait_queue_link_t) kalloc(sizeof(struct wait_queue_link));
+ wql = (wait_queue_link_t) zalloc(_wait_queue_link_zone);
if (wql == WAIT_QUEUE_LINK_NULL)
return KERN_RESOURCE_SHORTAGE;
- ret = wait_queue_link_noalloc(wq, wq_set, wql);
+ wql->wql_type = WAIT_QUEUE_LINK;
+ ret = wait_queue_link_internal(wq, wq_set, wql);
if (ret != KERN_SUCCESS)
- kfree(wql, sizeof(struct wait_queue_link));
+ zfree(_wait_queue_link_zone, wql);
return ret;
}
/*
- * Routine: wait_queue_unlink_nofree
+ * Routine: wait_queue_unlink_locked
* Purpose:
* Undo the linkage between a wait queue and a set.
*/
queue_remove(&wq->wq_queue, wql, wait_queue_link_t, wql_links);
wql->wql_setqueue = WAIT_QUEUE_SET_NULL;
queue_remove(&wq_set->wqs_setlinks, wql, wait_queue_link_t, wql_setlinks);
+ if (wql_is_preposted(wql)) {
+ queue_t ppq = &wq_set->wqs_preposts;
+ queue_remove(ppq, wql, wait_queue_link_t, wql_preposts);
+ }
wql->wql_type = WAIT_QUEUE_UNLINKED;
WAIT_QUEUE_CHECK(wq);
queue_t q;
spl_t s;
- if (!wait_queue_is_queue(wq) || !wait_queue_is_set(wq_set)) {
+ if (!wait_queue_is_valid(wq) || !wait_queue_is_set(wq_set)) {
return KERN_INVALID_ARGUMENT;
}
s = splsched();
wq_element = (wait_queue_element_t) queue_first(q);
while (!queue_end(q, (queue_entry_t)wq_element)) {
WAIT_QUEUE_ELEMENT_CHECK(wq, wq_element);
- if (wq_element->wqe_type == WAIT_QUEUE_LINK) {
+ if (wq_element->wqe_type == WAIT_QUEUE_LINK ||
+ wq_element->wqe_type == WAIT_QUEUE_LINK_NOALLOC) {
+
wql = (wait_queue_link_t)wq_element;
if (wql->wql_setqueue == wq_set) {
+ boolean_t alloced;
+
+ alloced = (wql->wql_type == WAIT_QUEUE_LINK);
wqs_lock(wq_set);
wait_queue_unlink_locked(wq, wq_set, wql);
wqs_unlock(wq_set);
wait_queue_unlock(wq);
splx(s);
- kfree(wql, sizeof(struct wait_queue_link));
+ if (alloced)
+ zfree(_wait_queue_link_zone, wql);
return KERN_SUCCESS;
}
}
return KERN_NOT_IN_SET;
}
-
-/*
- * Routine: wait_queue_unlinkall_nofree
- * Purpose:
- * Remove the linkage between a wait queue and all its
- * sets. The caller is responsible for freeing
- * the wait queue link structures.
- */
-
-kern_return_t
-wait_queue_unlinkall_nofree(
- wait_queue_t wq)
-{
- wait_queue_element_t wq_element;
- wait_queue_element_t wq_next_element;
- wait_queue_set_t wq_set;
- wait_queue_link_t wql;
- queue_head_t links_queue_head;
- queue_t links = &links_queue_head;
- queue_t q;
- spl_t s;
-
- if (!wait_queue_is_queue(wq)) {
- return KERN_INVALID_ARGUMENT;
- }
-
- queue_init(links);
-
- s = splsched();
- wait_queue_lock(wq);
-
- q = &wq->wq_queue;
-
- wq_element = (wait_queue_element_t) queue_first(q);
- while (!queue_end(q, (queue_entry_t)wq_element)) {
- WAIT_QUEUE_ELEMENT_CHECK(wq, wq_element);
- wq_next_element = (wait_queue_element_t)
- queue_next((queue_t) wq_element);
-
- if (wq_element->wqe_type == WAIT_QUEUE_LINK) {
- wql = (wait_queue_link_t)wq_element;
- wq_set = wql->wql_setqueue;
- wqs_lock(wq_set);
- wait_queue_unlink_locked(wq, wq_set, wql);
- wqs_unlock(wq_set);
- }
- wq_element = wq_next_element;
- }
- wait_queue_unlock(wq);
- splx(s);
- return(KERN_SUCCESS);
-}
-
-
/*
* Routine: wait_queue_unlink_all
* Purpose:
- * Remove the linkage between a wait queue and all its sets.
- * All the linkage structures are freed.
+ * Remove the linkage between a wait queue and all its sets.
+ * All the linkage structures that were allocated internally
+ * are freed. The others are the caller's responsibility.
* Conditions:
* Nothing of interest locked.
*/
queue_t q;
spl_t s;
- if (!wait_queue_is_queue(wq)) {
+ if (!wait_queue_is_valid(wq)) {
return KERN_INVALID_ARGUMENT;
}
wq_element = (wait_queue_element_t) queue_first(q);
while (!queue_end(q, (queue_entry_t)wq_element)) {
+ boolean_t alloced;
+
WAIT_QUEUE_ELEMENT_CHECK(wq, wq_element);
wq_next_element = (wait_queue_element_t)
queue_next((queue_t) wq_element);
- if (wq_element->wqe_type == WAIT_QUEUE_LINK) {
+ alloced = (wq_element->wqe_type == WAIT_QUEUE_LINK);
+ if (alloced || wq_element->wqe_type == WAIT_QUEUE_LINK_NOALLOC) {
wql = (wait_queue_link_t)wq_element;
wq_set = wql->wql_setqueue;
wqs_lock(wq_set);
wait_queue_unlink_locked(wq, wq_set, wql);
wqs_unlock(wq_set);
- enqueue(links, &wql->wql_links);
+ if (alloced)
+ enqueue(links, &wql->wql_links);
}
wq_element = wq_next_element;
}
while(!queue_empty(links)) {
wql = (wait_queue_link_t) dequeue(links);
- kfree(wql, sizeof(struct wait_queue_link));
- }
-
- return(KERN_SUCCESS);
-}
-
-/*
- * Routine: wait_queue_set_unlink_all_nofree
- * Purpose:
- * Remove the linkage between a set wait queue and all its
- * member wait queues. The link structures are not freed, nor
- * returned. It is the caller's responsibility to track and free
- * them.
- * Conditions:
- * The wait queue being must be a member set queue
- */
-kern_return_t
-wait_queue_set_unlink_all_nofree(
- wait_queue_set_t wq_set)
-{
- wait_queue_link_t wql;
- wait_queue_t wq;
- queue_t q;
- spl_t s;
-
- if (!wait_queue_is_set(wq_set)) {
- return KERN_INVALID_ARGUMENT;
- }
-
-retry:
- s = splsched();
- wqs_lock(wq_set);
-
- q = &wq_set->wqs_setlinks;
-
- wql = (wait_queue_link_t)queue_first(q);
- while (!queue_end(q, (queue_entry_t)wql)) {
- WAIT_QUEUE_SET_LINK_CHECK(wq_set, wql);
- wq = wql->wql_queue;
- if (wait_queue_lock_try(wq)) {
- wait_queue_unlink_locked(wq, wq_set, wql);
- wait_queue_unlock(wq);
- wql = (wait_queue_link_t)queue_first(q);
- } else {
- wqs_unlock(wq_set);
- splx(s);
- delay(1);
- goto retry;
- }
+ zfree(_wait_queue_link_zone, wql);
}
- wqs_unlock(wq_set);
- splx(s);
return(KERN_SUCCESS);
}
wait_subqueue_unlink_all(
wait_queue_set_t wq_set)
{
- return wait_queue_set_unlink_all_nofree(wq_set);
+ return wait_queue_set_unlink_all(wq_set);
}
* Routine: wait_queue_set_unlink_all
* Purpose:
* Remove the linkage between a set wait queue and all its
- * member wait queues. The link structures are freed.
+ * member wait queues. The link structures are freed for those
+ * links which were dynamically allocated.
* Conditions:
* The wait queue must be a set
*/
WAIT_QUEUE_SET_LINK_CHECK(wq_set, wql);
wq = wql->wql_queue;
if (wait_queue_lock_try(wq)) {
+ boolean_t alloced;
+
+ alloced = (wql->wql_type == WAIT_QUEUE_LINK);
wait_queue_unlink_locked(wq, wq_set, wql);
wait_queue_unlock(wq);
- enqueue(links, &wql->wql_links);
+ if (alloced)
+ enqueue(links, &wql->wql_links);
wql = (wait_queue_link_t)queue_first(q);
} else {
wqs_unlock(wq_set);
while (!queue_empty (links)) {
wql = (wait_queue_link_t) dequeue(links);
- kfree(wql, sizeof(struct wait_queue_link));
+ zfree(_wait_queue_link_zone, wql);
}
return(KERN_SUCCESS);
}
-
-/*
- * Routine: wait_queue_unlink_one
- * Purpose:
- * Find and unlink one set wait queue
- * Conditions:
- * Nothing of interest locked.
- */
-void
-wait_queue_unlink_one(
- wait_queue_t wq,
- wait_queue_set_t *wq_setp)
-{
- wait_queue_element_t wq_element;
- queue_t q;
- spl_t s;
-
- s = splsched();
- wait_queue_lock(wq);
-
- q = &wq->wq_queue;
-
- wq_element = (wait_queue_element_t) queue_first(q);
- while (!queue_end(q, (queue_entry_t)wq_element)) {
-
- if (wq_element->wqe_type == WAIT_QUEUE_LINK) {
- wait_queue_link_t wql = (wait_queue_link_t)wq_element;
- wait_queue_set_t wq_set = wql->wql_setqueue;
-
- wqs_lock(wq_set);
- wait_queue_unlink_locked(wq, wq_set, wql);
- wqs_unlock(wq_set);
- wait_queue_unlock(wq);
- splx(s);
- kfree(wql,sizeof(struct wait_queue_link));
- *wq_setp = wq_set;
- return;
- }
-
- wq_element = (wait_queue_element_t)
- queue_next((queue_t) wq_element);
- }
- wait_queue_unlock(wq);
- splx(s);
- *wq_setp = WAIT_QUEUE_SET_NULL;
-}
-
-
/*
* Routine: wait_queue_assert_wait64_locked
* Purpose:
if (wq->wq_type == _WAIT_QUEUE_SET_inited) {
wait_queue_set_t wqs = (wait_queue_set_t)wq;
- if (wqs->wqs_isprepost && wqs->wqs_refcount > 0)
+ if (event == NO_EVENT64 && wqs_is_preposted(wqs))
return(THREAD_AWAKENED);
}
*/
wait_result = thread_mark_wait_locked(thread, interruptible);
if (wait_result == THREAD_WAITING) {
- if (thread->options & TH_OPT_VMPRIV)
+ if (!wq->wq_fifo || thread->options & TH_OPT_VMPRIV)
enqueue_head(&wq->wq_queue, (queue_entry_t) thread);
else
enqueue_tail(&wq->wq_queue, (queue_entry_t) thread);
s = splsched();
wait_queue_lock(wq);
thread_lock(thread);
- ret = wait_queue_assert_wait64_locked(wq, (event64_t)((uint32_t)event),
+ ret = wait_queue_assert_wait64_locked(wq, CAST_DOWN(event64_t,event),
interruptible, deadline, thread);
thread_unlock(thread);
wait_queue_unlock(wq);
/*
* We may have to recurse if this is a compound wait queue.
*/
- if (wq_element->wqe_type == WAIT_QUEUE_LINK) {
+ if (wq_element->wqe_type == WAIT_QUEUE_LINK ||
+ wq_element->wqe_type == WAIT_QUEUE_LINK_NOALLOC) {
wait_queue_link_t wql = (wait_queue_link_t)wq_element;
- wait_queue_t set_queue;
+ wait_queue_set_t set_queue = wql->wql_setqueue;
/*
- * We have to check the set wait queue.
+ * We have to check the set wait queue. If it is marked
+ * as pre-post, and it is the "generic event" then mark
+ * it pre-posted now (if not already).
*/
- set_queue = (wait_queue_t)wql->wql_setqueue;
- wait_queue_lock(set_queue);
- if (set_queue->wq_isprepost) {
- wait_queue_set_t wqs = (wait_queue_set_t)set_queue;
-
- /*
- * Preposting is only for sets and wait queue
- * is the first element of set
- */
- wqs->wqs_refcount++;
+ wqs_lock(set_queue);
+ if (event == NO_EVENT64 && set_queue->wqs_prepost && !wql_is_preposted(wql)) {
+ queue_t ppq = &set_queue->wqs_preposts;
+ queue_enter(ppq, wql, wait_queue_link_t, wql_preposts);
}
- if (! wait_queue_empty(set_queue))
- _wait_queue_select64_all(set_queue, event, wake_queue);
- wait_queue_unlock(set_queue);
+ if (! wait_queue_empty(&set_queue->wqs_wait_queue))
+ _wait_queue_select64_all(&set_queue->wqs_wait_queue, event, wake_queue);
+ wqs_unlock(set_queue);
} else {
/*
queue_t q = &wake_queue_head;
kern_return_t res;
- assert(wait_queue_held(wq));
+// assert(wait_queue_held(wq));
+// if(!wq->wq_interlock.lock_data) { /* (BRINGUP */
+// panic("wait_queue_wakeup64_all_locked: lock not held on %p\n", wq); /* (BRINGUP) */
+// }
+
queue_init(q);
/*
s = splsched();
wait_queue_lock(wq);
+// if(!wq->wq_interlock.lock_data) { /* (BRINGUP */
+// panic("wait_queue_wakeup_all: we did not get the lock on %p\n", wq); /* (BRINGUP) */
+// }
ret = wait_queue_wakeup64_all_locked(
- wq, (event64_t)((uint32_t)event),
+ wq, CAST_DOWN(event64_t,event),
result, TRUE);
/* lock released */
splx(s);
* a locked thread - if one found
* Note:
* This is where the sync policy of the wait queue comes
- * into effect. For now, we just assume FIFO.
+ * into effect. For now, we just assume FIFO/LIFO.
*/
static thread_t
_wait_queue_select64_one(
thread_t t = THREAD_NULL;
queue_t q;
- assert(wq->wq_fifo);
-
q = &wq->wq_queue;
wq_element = (wait_queue_element_t) queue_first(q);
/*
* We may have to recurse if this is a compound wait queue.
*/
- if (wq_element->wqe_type == WAIT_QUEUE_LINK) {
+ if (wq_element->wqe_type == WAIT_QUEUE_LINK ||
+ wq_element->wqe_type == WAIT_QUEUE_LINK_NOALLOC) {
wait_queue_link_t wql = (wait_queue_link_t)wq_element;
- wait_queue_t set_queue;
+ wait_queue_set_t set_queue = wql->wql_setqueue;
/*
- * We have to check the set wait queue.
+ * We have to check the set wait queue. If the set
+ * supports pre-posting, it isn't already preposted,
+ * and we didn't find a thread in the set, then mark it.
+ *
+ * If we later find a thread, there may be a spurious
+ * pre-post here on this set. The wait side has to check
+ * for that either pre- or post-wait.
*/
- set_queue = (wait_queue_t)wql->wql_setqueue;
- wait_queue_lock(set_queue);
- if (! wait_queue_empty(set_queue)) {
- t = _wait_queue_select64_one(set_queue, event);
+ wqs_lock(set_queue);
+ if (! wait_queue_empty(&set_queue->wqs_wait_queue)) {
+ t = _wait_queue_select64_one(&set_queue->wqs_wait_queue, event);
}
- wait_queue_unlock(set_queue);
- if (t != THREAD_NULL)
+ if (t != THREAD_NULL) {
+ wqs_unlock(set_queue);
return t;
+ }
+ if (event == NO_EVENT64 && set_queue->wqs_prepost && !wql_is_preposted(wql)) {
+ queue_t ppq = &set_queue->wqs_preposts;
+ queue_enter(ppq, wql, wait_queue_link_t, wql_preposts);
+ }
+ wqs_unlock(set_queue);
+
} else {
/*
return THREAD_NULL;
}
-/*
- * Routine: wait_queue_peek64_locked
- * Purpose:
- * Select the best thread from a wait queue that meet the
- * supplied criteria, but leave it on the queue it was
- * found on. The thread, and the actual wait_queue the
- * thread was found on are identified.
- * Conditions:
- * at splsched
- * wait queue locked
- * possibly recursive
- * Returns:
- * a locked thread - if one found
- * a locked waitq - the one the thread was found on
- * Note:
- * Both the waitq the thread was actually found on, and
- * the supplied wait queue, are locked after this.
- */
-__private_extern__ void
-wait_queue_peek64_locked(
- wait_queue_t wq,
- event64_t event,
- thread_t *tp,
- wait_queue_t *wqp)
-{
- wait_queue_element_t wq_element;
- wait_queue_element_t wqe_next;
- queue_t q;
-
- assert(wq->wq_fifo);
-
- *tp = THREAD_NULL;
-
- q = &wq->wq_queue;
-
- wq_element = (wait_queue_element_t) queue_first(q);
- while (!queue_end(q, (queue_entry_t)wq_element)) {
- WAIT_QUEUE_ELEMENT_CHECK(wq, wq_element);
- wqe_next = (wait_queue_element_t)
- queue_next((queue_t) wq_element);
-
- /*
- * We may have to recurse if this is a compound wait queue.
- */
- if (wq_element->wqe_type == WAIT_QUEUE_LINK) {
- wait_queue_link_t wql = (wait_queue_link_t)wq_element;
- wait_queue_t set_queue;
-
- /*
- * We have to check the set wait queue.
- */
- set_queue = (wait_queue_t)wql->wql_setqueue;
- wait_queue_lock(set_queue);
- if (! wait_queue_empty(set_queue)) {
- wait_queue_peek64_locked(set_queue, event, tp, wqp);
- }
- if (*tp != THREAD_NULL) {
- if (*wqp != set_queue)
- wait_queue_unlock(set_queue);
- return; /* thread and its waitq locked */
- }
-
- wait_queue_unlock(set_queue);
- } else {
-
- /*
- * Otherwise, its a thread. If it is waiting on
- * the event we are posting to this queue, return
- * it locked, but leave it on the queue.
- */
- thread_t t = (thread_t)wq_element;
-
- if (t->wait_event == event) {
- thread_lock(t);
- *tp = t;
- *wqp = wq;
- return;
- }
- }
- wq_element = wqe_next;
- }
-}
/*
* Routine: wait_queue_pull_thread_locked
* Purpose:
- * Pull a thread that was previously "peeked" off the wait
- * queue and (possibly) unlock the waitq.
+ * Pull a thread off its wait queue and (possibly) unlock
+ * the waitq.
* Conditions:
* at splsched
* wait queue locked
wqe_next = (wait_queue_element_t)
queue_next((queue_t) wq_element);
- if (wq_element->wqe_type == WAIT_QUEUE_LINK) {
+ if (wq_element->wqe_type == WAIT_QUEUE_LINK ||
+ wq_element->wqe_type == WAIT_QUEUE_LINK_NOALLOC) {
wait_queue_link_t wql = (wait_queue_link_t)wq_element;
- wait_queue_t set_queue;
+ wait_queue_set_t set_queue = wql->wql_setqueue;
- set_queue = (wait_queue_t)wql->wql_setqueue;
- wait_queue_lock(set_queue);
- if (! wait_queue_empty(set_queue)) {
- res = _wait_queue_select64_thread(set_queue,
+ wqs_lock(set_queue);
+ if (! wait_queue_empty(&set_queue->wqs_wait_queue)) {
+ res = _wait_queue_select64_thread(&set_queue->wqs_wait_queue,
event,
thread);
}
- wait_queue_unlock(set_queue);
+ wqs_unlock(set_queue);
if (res == KERN_SUCCESS)
return KERN_SUCCESS;
}
assert(wait_queue_held(wq));
-
thread = _wait_queue_select64_one(wq, event);
if (unlock)
wait_queue_unlock(wq);
s = splsched();
wait_queue_lock(wq);
- thread = _wait_queue_select64_one(wq, (event64_t)((uint32_t)event));
+ thread = _wait_queue_select64_one(wq, CAST_DOWN(event64_t,event));
wait_queue_unlock(wq);
if (thread) {
s = splsched();
wait_queue_lock(wq);
- res = _wait_queue_select64_thread(wq, (event64_t)((uint32_t)event), thread);
+ res = _wait_queue_select64_thread(wq, CAST_DOWN(event64_t,event), thread);
wait_queue_unlock(wq);
if (res == KERN_SUCCESS) {
projects / apple / xnu.git / blobdiff