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-rw-r--r--server/mpm_fdqueue.c534
1 files changed, 534 insertions, 0 deletions
diff --git a/server/mpm_fdqueue.c b/server/mpm_fdqueue.c
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+/* Licensed to the Apache Software Foundation (ASF) under one or more
+ * contributor license agreements. See the NOTICE file distributed with
+ * this work for additional information regarding copyright ownership.
+ * The ASF licenses this file to You under the Apache License, Version 2.0
+ * (the "License"); you may not use this file except in compliance with
+ * the License. You may obtain a copy of the License at
+ *
+ * http://www.apache.org/licenses/LICENSE-2.0
+ *
+ * Unless required by applicable law or agreed to in writing, software
+ * distributed under the License is distributed on an "AS IS" BASIS,
+ * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
+ * See the License for the specific language governing permissions and
+ * limitations under the License.
+ */
+
+#include "mpm_fdqueue.h"
+
+#if APR_HAS_THREADS
+
+#include <apr_atomic.h>
+
+static const apr_uint32_t zero_pt = APR_UINT32_MAX/2;
+
+struct recycled_pool
+{
+ apr_pool_t *pool;
+ struct recycled_pool *next;
+};
+
+struct fd_queue_info_t
+{
+ apr_uint32_t volatile idlers; /**
+ * >= zero_pt: number of idle worker threads
+ * < zero_pt: number of threads blocked,
+ * waiting for an idle worker
+ */
+ apr_thread_mutex_t *idlers_mutex;
+ apr_thread_cond_t *wait_for_idler;
+ int terminated;
+ int max_idlers;
+ int max_recycled_pools;
+ apr_uint32_t recycled_pools_count;
+ struct recycled_pool *volatile recycled_pools;
+};
+
+struct fd_queue_elem_t
+{
+ apr_socket_t *sd;
+ void *sd_baton;
+ apr_pool_t *p;
+};
+
+static apr_status_t queue_info_cleanup(void *data_)
+{
+ fd_queue_info_t *qi = data_;
+ apr_thread_cond_destroy(qi->wait_for_idler);
+ apr_thread_mutex_destroy(qi->idlers_mutex);
+
+ /* Clean up any pools in the recycled list */
+ for (;;) {
+ struct recycled_pool *first_pool = qi->recycled_pools;
+ if (first_pool == NULL) {
+ break;
+ }
+ if (apr_atomic_casptr((void *)&qi->recycled_pools, first_pool->next,
+ first_pool) == first_pool) {
+ apr_pool_destroy(first_pool->pool);
+ }
+ }
+
+ return APR_SUCCESS;
+}
+
+apr_status_t ap_queue_info_create(fd_queue_info_t **queue_info,
+ apr_pool_t *pool, int max_idlers,
+ int max_recycled_pools)
+{
+ apr_status_t rv;
+ fd_queue_info_t *qi;
+
+ qi = apr_pcalloc(pool, sizeof(*qi));
+
+ rv = apr_thread_mutex_create(&qi->idlers_mutex, APR_THREAD_MUTEX_DEFAULT,
+ pool);
+ if (rv != APR_SUCCESS) {
+ return rv;
+ }
+ rv = apr_thread_cond_create(&qi->wait_for_idler, pool);
+ if (rv != APR_SUCCESS) {
+ return rv;
+ }
+ qi->recycled_pools = NULL;
+ qi->max_recycled_pools = max_recycled_pools;
+ qi->max_idlers = max_idlers;
+ qi->idlers = zero_pt;
+ apr_pool_cleanup_register(pool, qi, queue_info_cleanup,
+ apr_pool_cleanup_null);
+
+ *queue_info = qi;
+
+ return APR_SUCCESS;
+}
+
+apr_status_t ap_queue_info_set_idle(fd_queue_info_t *queue_info,
+ apr_pool_t *pool_to_recycle)
+{
+ apr_status_t rv;
+
+ ap_queue_info_push_pool(queue_info, pool_to_recycle);
+
+ /* If other threads are waiting on a worker, wake one up */
+ if (apr_atomic_inc32(&queue_info->idlers) < zero_pt) {
+ rv = apr_thread_mutex_lock(queue_info->idlers_mutex);
+ if (rv != APR_SUCCESS) {
+ AP_DEBUG_ASSERT(0);
+ return rv;
+ }
+ rv = apr_thread_cond_signal(queue_info->wait_for_idler);
+ if (rv != APR_SUCCESS) {
+ apr_thread_mutex_unlock(queue_info->idlers_mutex);
+ return rv;
+ }
+ rv = apr_thread_mutex_unlock(queue_info->idlers_mutex);
+ if (rv != APR_SUCCESS) {
+ return rv;
+ }
+ }
+
+ return APR_SUCCESS;
+}
+
+apr_status_t ap_queue_info_try_get_idler(fd_queue_info_t *queue_info)
+{
+ /* Don't block if there isn't any idle worker. */
+ for (;;) {
+ apr_uint32_t idlers = queue_info->idlers;
+ if (idlers <= zero_pt) {
+ return APR_EAGAIN;
+ }
+ if (apr_atomic_cas32(&queue_info->idlers, idlers - 1,
+ idlers) == idlers) {
+ return APR_SUCCESS;
+ }
+ }
+}
+
+apr_status_t ap_queue_info_wait_for_idler(fd_queue_info_t *queue_info,
+ int *had_to_block)
+{
+ apr_status_t rv;
+
+ /* Block if there isn't any idle worker.
+ * apr_atomic_add32(x, -1) does the same as dec32(x), except
+ * that it returns the previous value (unlike dec32's bool).
+ */
+ if (apr_atomic_add32(&queue_info->idlers, -1) <= zero_pt) {
+ rv = apr_thread_mutex_lock(queue_info->idlers_mutex);
+ if (rv != APR_SUCCESS) {
+ AP_DEBUG_ASSERT(0);
+ apr_atomic_inc32(&(queue_info->idlers)); /* back out dec */
+ return rv;
+ }
+ /* Re-check the idle worker count to guard against a
+ * race condition. Now that we're in the mutex-protected
+ * region, one of two things may have happened:
+ * - If the idle worker count is still negative, the
+ * workers are all still busy, so it's safe to
+ * block on a condition variable.
+ * - If the idle worker count is non-negative, then a
+ * worker has become idle since the first check
+ * of queue_info->idlers above. It's possible
+ * that the worker has also signaled the condition
+ * variable--and if so, the listener missed it
+ * because it wasn't yet blocked on the condition
+ * variable. But if the idle worker count is
+ * now non-negative, it's safe for this function to
+ * return immediately.
+ *
+ * A "negative value" (relative to zero_pt) in
+ * queue_info->idlers tells how many
+ * threads are waiting on an idle worker.
+ */
+ if (queue_info->idlers < zero_pt) {
+ if (had_to_block) {
+ *had_to_block = 1;
+ }
+ rv = apr_thread_cond_wait(queue_info->wait_for_idler,
+ queue_info->idlers_mutex);
+ if (rv != APR_SUCCESS) {
+ AP_DEBUG_ASSERT(0);
+ apr_thread_mutex_unlock(queue_info->idlers_mutex);
+ return rv;
+ }
+ }
+ rv = apr_thread_mutex_unlock(queue_info->idlers_mutex);
+ if (rv != APR_SUCCESS) {
+ return rv;
+ }
+ }
+
+ if (queue_info->terminated) {
+ return APR_EOF;
+ }
+ else {
+ return APR_SUCCESS;
+ }
+}
+
+apr_uint32_t ap_queue_info_num_idlers(fd_queue_info_t *queue_info)
+{
+ apr_uint32_t val;
+ val = apr_atomic_read32(&queue_info->idlers);
+ return (val > zero_pt) ? val - zero_pt : 0;
+}
+
+void ap_queue_info_push_pool(fd_queue_info_t *queue_info,
+ apr_pool_t *pool_to_recycle)
+{
+ struct recycled_pool *new_recycle;
+ /* If we have been given a pool to recycle, atomically link
+ * it into the queue_info's list of recycled pools
+ */
+ if (!pool_to_recycle)
+ return;
+
+ if (queue_info->max_recycled_pools >= 0) {
+ apr_uint32_t n = apr_atomic_read32(&queue_info->recycled_pools_count);
+ if (n >= queue_info->max_recycled_pools) {
+ apr_pool_destroy(pool_to_recycle);
+ return;
+ }
+ apr_atomic_inc32(&queue_info->recycled_pools_count);
+ }
+
+ apr_pool_clear(pool_to_recycle);
+ new_recycle = apr_palloc(pool_to_recycle, sizeof *new_recycle);
+ new_recycle->pool = pool_to_recycle;
+ for (;;) {
+ /*
+ * Save queue_info->recycled_pool in local variable next because
+ * new_recycle->next can be changed after apr_atomic_casptr
+ * function call. For gory details see PR 44402.
+ */
+ struct recycled_pool *next = queue_info->recycled_pools;
+ new_recycle->next = next;
+ if (apr_atomic_casptr((void *)&queue_info->recycled_pools,
+ new_recycle, next) == next)
+ break;
+ }
+}
+
+void ap_queue_info_pop_pool(fd_queue_info_t *queue_info,
+ apr_pool_t **recycled_pool)
+{
+ /* Atomically pop a pool from the recycled list */
+
+ /* This function is safe only as long as it is single threaded because
+ * it reaches into the queue and accesses "next" which can change.
+ * We are OK today because it is only called from the listener thread.
+ * cas-based pushes do not have the same limitation - any number can
+ * happen concurrently with a single cas-based pop.
+ */
+
+ *recycled_pool = NULL;
+
+
+ /* Atomically pop a pool from the recycled list */
+ for (;;) {
+ struct recycled_pool *first_pool = queue_info->recycled_pools;
+ if (first_pool == NULL) {
+ break;
+ }
+ if (apr_atomic_casptr((void *)&queue_info->recycled_pools,
+ first_pool->next, first_pool) == first_pool) {
+ *recycled_pool = first_pool->pool;
+ if (queue_info->max_recycled_pools >= 0)
+ apr_atomic_dec32(&queue_info->recycled_pools_count);
+ break;
+ }
+ }
+}
+
+void ap_queue_info_free_idle_pools(fd_queue_info_t *queue_info)
+{
+ apr_pool_t *p;
+
+ queue_info->max_recycled_pools = 0;
+ for (;;) {
+ ap_queue_info_pop_pool(queue_info, &p);
+ if (p == NULL)
+ break;
+ apr_pool_destroy(p);
+ }
+ apr_atomic_set32(&queue_info->recycled_pools_count, 0);
+}
+
+
+apr_status_t ap_queue_info_term(fd_queue_info_t *queue_info)
+{
+ apr_status_t rv;
+
+ rv = apr_thread_mutex_lock(queue_info->idlers_mutex);
+ if (rv != APR_SUCCESS) {
+ return rv;
+ }
+
+ queue_info->terminated = 1;
+ apr_thread_cond_broadcast(queue_info->wait_for_idler);
+
+ return apr_thread_mutex_unlock(queue_info->idlers_mutex);
+}
+
+/**
+ * Detects when the fd_queue_t is full. This utility function is expected
+ * to be called from within critical sections, and is not threadsafe.
+ */
+#define ap_queue_full(queue) ((queue)->nelts == (queue)->bounds)
+
+/**
+ * Detects when the fd_queue_t is empty. This utility function is expected
+ * to be called from within critical sections, and is not threadsafe.
+ */
+#define ap_queue_empty(queue) ((queue)->nelts == 0 && \
+ APR_RING_EMPTY(&queue->timers, \
+ timer_event_t, link))
+
+/**
+ * Callback routine that is called to destroy this
+ * fd_queue_t when its pool is destroyed.
+ */
+static apr_status_t ap_queue_destroy(void *data)
+{
+ fd_queue_t *queue = data;
+
+ /* Ignore errors here, we can't do anything about them anyway.
+ * XXX: We should at least try to signal an error here, it is
+ * indicative of a programmer error. -aaron */
+ apr_thread_cond_destroy(queue->not_empty);
+ apr_thread_mutex_destroy(queue->one_big_mutex);
+
+ return APR_SUCCESS;
+}
+
+/**
+ * Initialize the fd_queue_t.
+ */
+apr_status_t ap_queue_create(fd_queue_t **pqueue, int capacity, apr_pool_t *p)
+{
+ apr_status_t rv;
+ fd_queue_t *queue;
+
+ queue = apr_pcalloc(p, sizeof *queue);
+
+ if ((rv = apr_thread_mutex_create(&queue->one_big_mutex,
+ APR_THREAD_MUTEX_DEFAULT,
+ p)) != APR_SUCCESS) {
+ return rv;
+ }
+ if ((rv = apr_thread_cond_create(&queue->not_empty, p)) != APR_SUCCESS) {
+ return rv;
+ }
+
+ APR_RING_INIT(&queue->timers, timer_event_t, link);
+
+ queue->data = apr_pcalloc(p, capacity * sizeof(fd_queue_elem_t));
+ queue->bounds = capacity;
+
+ apr_pool_cleanup_register(p, queue, ap_queue_destroy,
+ apr_pool_cleanup_null);
+ *pqueue = queue;
+
+ return APR_SUCCESS;
+}
+
+/**
+ * Push a new socket onto the queue.
+ *
+ * precondition: ap_queue_info_wait_for_idler has already been called
+ * to reserve an idle worker thread
+ */
+apr_status_t ap_queue_push_socket(fd_queue_t *queue,
+ apr_socket_t *sd, void *sd_baton,
+ apr_pool_t *p)
+{
+ fd_queue_elem_t *elem;
+ apr_status_t rv;
+
+ if ((rv = apr_thread_mutex_lock(queue->one_big_mutex)) != APR_SUCCESS) {
+ return rv;
+ }
+
+ AP_DEBUG_ASSERT(!queue->terminated);
+ AP_DEBUG_ASSERT(!ap_queue_full(queue));
+
+ elem = &queue->data[queue->in++];
+ if (queue->in >= queue->bounds)
+ queue->in -= queue->bounds;
+ elem->sd = sd;
+ elem->sd_baton = sd_baton;
+ elem->p = p;
+ queue->nelts++;
+
+ apr_thread_cond_signal(queue->not_empty);
+
+ return apr_thread_mutex_unlock(queue->one_big_mutex);
+}
+
+apr_status_t ap_queue_push_timer(fd_queue_t *queue, timer_event_t *te)
+{
+ apr_status_t rv;
+
+ if ((rv = apr_thread_mutex_lock(queue->one_big_mutex)) != APR_SUCCESS) {
+ return rv;
+ }
+
+ AP_DEBUG_ASSERT(!queue->terminated);
+
+ APR_RING_INSERT_TAIL(&queue->timers, te, timer_event_t, link);
+
+ apr_thread_cond_signal(queue->not_empty);
+
+ return apr_thread_mutex_unlock(queue->one_big_mutex);
+}
+
+/**
+ * Retrieves the next available socket from the queue. If there are no
+ * sockets available, it will block until one becomes available.
+ * Once retrieved, the socket is placed into the address specified by
+ * 'sd'.
+ */
+apr_status_t ap_queue_pop_something(fd_queue_t *queue,
+ apr_socket_t **sd, void **sd_baton,
+ apr_pool_t **p, timer_event_t **te_out)
+{
+ fd_queue_elem_t *elem;
+ timer_event_t *te;
+ apr_status_t rv;
+
+ if ((rv = apr_thread_mutex_lock(queue->one_big_mutex)) != APR_SUCCESS) {
+ return rv;
+ }
+
+ /* Keep waiting until we wake up and find that the queue is not empty. */
+ if (ap_queue_empty(queue)) {
+ if (!queue->terminated) {
+ apr_thread_cond_wait(queue->not_empty, queue->one_big_mutex);
+ }
+ /* If we wake up and it's still empty, then we were interrupted */
+ if (ap_queue_empty(queue)) {
+ rv = apr_thread_mutex_unlock(queue->one_big_mutex);
+ if (rv != APR_SUCCESS) {
+ return rv;
+ }
+ if (queue->terminated) {
+ return APR_EOF; /* no more elements ever again */
+ }
+ else {
+ return APR_EINTR;
+ }
+ }
+ }
+
+ te = NULL;
+ if (te_out) {
+ if (!APR_RING_EMPTY(&queue->timers, timer_event_t, link)) {
+ te = APR_RING_FIRST(&queue->timers);
+ APR_RING_REMOVE(te, link);
+ }
+ *te_out = te;
+ }
+ if (!te) {
+ elem = &queue->data[queue->out++];
+ if (queue->out >= queue->bounds)
+ queue->out -= queue->bounds;
+ queue->nelts--;
+
+ *sd = elem->sd;
+ if (sd_baton) {
+ *sd_baton = elem->sd_baton;
+ }
+ *p = elem->p;
+#ifdef AP_DEBUG
+ elem->sd = NULL;
+ elem->p = NULL;
+#endif /* AP_DEBUG */
+ }
+
+ return apr_thread_mutex_unlock(queue->one_big_mutex);
+}
+
+static apr_status_t queue_interrupt(fd_queue_t *queue, int all, int term)
+{
+ apr_status_t rv;
+
+ if (queue->terminated) {
+ return APR_EOF;
+ }
+
+ if ((rv = apr_thread_mutex_lock(queue->one_big_mutex)) != APR_SUCCESS) {
+ return rv;
+ }
+
+ /* we must hold one_big_mutex when setting this... otherwise,
+ * we could end up setting it and waking everybody up just after a
+ * would-be popper checks it but right before they block
+ */
+ if (term) {
+ queue->terminated = 1;
+ }
+ if (all)
+ apr_thread_cond_broadcast(queue->not_empty);
+ else
+ apr_thread_cond_signal(queue->not_empty);
+
+ return apr_thread_mutex_unlock(queue->one_big_mutex);
+}
+
+apr_status_t ap_queue_interrupt_all(fd_queue_t *queue)
+{
+ return queue_interrupt(queue, 1, 0);
+}
+
+apr_status_t ap_queue_interrupt_one(fd_queue_t *queue)
+{
+ return queue_interrupt(queue, 0, 0);
+}
+
+apr_status_t ap_queue_term(fd_queue_t *queue)
+{
+ return queue_interrupt(queue, 1, 1);
+}
+
+#endif /* APR_HAS_THREADS */