#include "fdqueue.h"
#include "apr_atomic.h"
typedef struct recycled_pool
{
apr_pool_t *pool;
struct recycled_pool *next;
} recycled_pool;
struct fd_queue_info_t
{
apr_int32_t idlers;
apr_thread_mutex_t *idlers_mutex;
apr_thread_cond_t *wait_for_idler;
int terminated;
int max_idlers;
recycled_pool *recycled_pools;
};
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);
for (;;) {
struct recycled_pool *first_pool = qi->recycled_pools;
if (first_pool == NULL) {
break;
}
if (apr_atomic_casptr
((volatile 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)
{
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_idlers = max_idlers;
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;
int prev_idlers;
ap_push_pool(queue_info, pool_to_recycle);
prev_idlers = apr_atomic_inc32(&(queue_info->idlers));
if (prev_idlers < 0) {
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_wait_for_idler(fd_queue_info_t * queue_info)
{
apr_status_t rv;
int prev_idlers;
prev_idlers = apr_atomic_add32(&(queue_info->idlers), -1);
if (prev_idlers <= 0) {
rv = apr_thread_mutex_lock(queue_info->idlers_mutex);
if (rv != APR_SUCCESS) {
AP_DEBUG_ASSERT(0);
apr_atomic_inc32(&(queue_info->idlers));
return rv;
}
if (queue_info->idlers < 0) {
rv = apr_thread_cond_wait(queue_info->wait_for_idler,
queue_info->idlers_mutex);
if (rv != APR_SUCCESS) {
apr_status_t rv2;
AP_DEBUG_ASSERT(0);
rv2 = apr_thread_mutex_unlock(queue_info->idlers_mutex);
if (rv2 != APR_SUCCESS) {
return rv2;
}
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;
}
}
void ap_push_pool(fd_queue_info_t * queue_info,
apr_pool_t * pool_to_recycle)
{
if (pool_to_recycle) {
struct recycled_pool *new_recycle;
new_recycle = (struct recycled_pool *) apr_palloc(pool_to_recycle,
sizeof
(*new_recycle));
new_recycle->pool = pool_to_recycle;
for (;;) {
struct recycled_pool *next = queue_info->recycled_pools;
new_recycle->next = next;
if (apr_atomic_casptr
((volatile void **) &(queue_info->recycled_pools),
new_recycle, next) == next) {
break;
}
}
}
}
void ap_pop_pool(apr_pool_t ** recycled_pool, fd_queue_info_t * queue_info)
{
*recycled_pool = NULL;
for (;;) {
struct recycled_pool *first_pool = queue_info->recycled_pools;
if (first_pool == NULL) {
break;
}
if (apr_atomic_casptr
((volatile void **) &(queue_info->recycled_pools),
first_pool->next, first_pool) == first_pool) {
*recycled_pool = first_pool->pool;
break;
}
}
}
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);
}
#define ap_queue_full(queue) ((queue)->nelts == (queue)->bounds)
#define ap_queue_empty(queue) ((queue)->nelts == 0)
static apr_status_t ap_queue_destroy(void *data)
{
fd_queue_t *queue = data;
apr_thread_cond_destroy(queue->not_empty);
apr_thread_mutex_destroy(queue->one_big_mutex);
return APR_SUCCESS;
}
apr_status_t ap_queue_init(fd_queue_t * queue, int queue_capacity,
apr_pool_t * a)
{
int i;
apr_status_t rv;
if ((rv = apr_thread_mutex_create(&queue->one_big_mutex,
APR_THREAD_MUTEX_DEFAULT,
a)) != APR_SUCCESS) {
return rv;
}
if ((rv = apr_thread_cond_create(&queue->not_empty, a)) != APR_SUCCESS) {
return rv;
}
queue->data = apr_palloc(a, queue_capacity * sizeof(fd_queue_elem_t));
queue->bounds = queue_capacity;
queue->nelts = 0;
for (i = 0; i < queue_capacity; ++i)
queue->data[i].sd = NULL;
apr_pool_cleanup_register(a, queue, ap_queue_destroy,
apr_pool_cleanup_null);
return APR_SUCCESS;
}
apr_status_t ap_queue_push(fd_queue_t * queue, apr_socket_t * sd,
conn_state_t * cs, 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->nelts];
elem->sd = sd;
elem->cs = cs;
elem->p = p;
queue->nelts++;
apr_thread_cond_signal(queue->not_empty);
if ((rv = apr_thread_mutex_unlock(queue->one_big_mutex)) != APR_SUCCESS) {
return rv;
}
return APR_SUCCESS;
}
apr_status_t ap_queue_pop(fd_queue_t * queue, apr_socket_t ** sd,
conn_state_t ** cs, 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;
}
if (ap_queue_empty(queue)) {
if (!queue->terminated) {
apr_thread_cond_wait(queue->not_empty, queue->one_big_mutex);
}
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;
}
else {
return APR_EINTR;
}
}
}
elem = &queue->data[--queue->nelts];
*sd = elem->sd;
*cs = elem->cs;
*p = elem->p;
#ifdef AP_DEBUG
elem->sd = NULL;
elem->p = NULL;
#endif
rv = apr_thread_mutex_unlock(queue->one_big_mutex);
return rv;
}
apr_status_t ap_queue_interrupt_all(fd_queue_t * queue)
{
apr_status_t rv;
if ((rv = apr_thread_mutex_lock(queue->one_big_mutex)) != APR_SUCCESS) {
return rv;
}
apr_thread_cond_broadcast(queue->not_empty);
return apr_thread_mutex_unlock(queue->one_big_mutex);
}
apr_status_t ap_queue_term(fd_queue_t * queue)
{
apr_status_t rv;
if ((rv = apr_thread_mutex_lock(queue->one_big_mutex)) != APR_SUCCESS) {
return rv;
}
queue->terminated = 1;
if ((rv = apr_thread_mutex_unlock(queue->one_big_mutex)) != APR_SUCCESS) {
return rv;
}
return ap_queue_interrupt_all(queue);
}