/* * Asterisk -- An open source telephony toolkit. * * Copyright (C) 2008, Digium, Inc. * * Russell Bryant * * See http://www.asterisk.org for more information about * the Asterisk project. Please do not directly contact * any of the maintainers of this project for assistance; * the project provides a web site, mailing lists and IRC * channels for your use. * * This program is free software, distributed under the terms of * the GNU General Public License Version 2. See the LICENSE file * at the top of the source tree. */ /*! * \file * \author Russell Bryant * * \brief pthread timing interface */ /*** MODULEINFO extended ***/ #include "asterisk.h" ASTERISK_FILE_VERSION(__FILE__, "$Revision$"); #include #include #include #include #include "asterisk/module.h" #include "asterisk/timing.h" #include "asterisk/utils.h" #include "asterisk/astobj2.h" #include "asterisk/time.h" #include "asterisk/lock.h" static void *timing_funcs_handle; static void *pthread_timer_open(void); static void pthread_timer_close(void *data); static int pthread_timer_set_rate(void *data, unsigned int rate); static int pthread_timer_ack(void *data, unsigned int quantity); static int pthread_timer_enable_continuous(void *data); static int pthread_timer_disable_continuous(void *data); static enum ast_timer_event pthread_timer_get_event(void *data); static unsigned int pthread_timer_get_max_rate(void *data); static int pthread_timer_fd(void *data); static struct ast_timing_interface pthread_timing = { .name = "pthread", .priority = 0, /* use this as a last resort */ .timer_open = pthread_timer_open, .timer_close = pthread_timer_close, .timer_set_rate = pthread_timer_set_rate, .timer_ack = pthread_timer_ack, .timer_enable_continuous = pthread_timer_enable_continuous, .timer_disable_continuous = pthread_timer_disable_continuous, .timer_get_event = pthread_timer_get_event, .timer_get_max_rate = pthread_timer_get_max_rate, .timer_fd = pthread_timer_fd, }; /* 1 tick / 10 ms */ #define MAX_RATE 100 static struct ao2_container *pthread_timers; #define PTHREAD_TIMER_BUCKETS 563 enum { PIPE_READ = 0, PIPE_WRITE = 1 }; enum pthread_timer_state { TIMER_STATE_IDLE, TIMER_STATE_TICKING, }; struct pthread_timer { int pipe[2]; enum pthread_timer_state state; unsigned int rate; /*! Interval in ms for current rate */ unsigned int interval; unsigned int tick_count; unsigned int pending_ticks; struct timeval start; bool continuous:1; bool pipe_signaled:1; }; static void pthread_timer_destructor(void *obj); static void signal_pipe(struct pthread_timer *timer); static void unsignal_pipe(struct pthread_timer *timer); static void ack_ticks(struct pthread_timer *timer, unsigned int num); /*! * \brief Data for the timing thread */ static struct { pthread_t thread; ast_mutex_t lock; ast_cond_t cond; unsigned int stop:1; } timing_thread; static void *pthread_timer_open(void) { struct pthread_timer *timer; if (!(timer = ao2_alloc(sizeof(*timer), pthread_timer_destructor))) { errno = ENOMEM; return NULL; } timer->pipe[PIPE_READ] = timer->pipe[PIPE_WRITE] = -1; timer->state = TIMER_STATE_IDLE; if (ast_pipe_nonblock(timer->pipe)) { ao2_ref(timer, -1); return NULL; } ao2_lock(pthread_timers); if (!ao2_container_count(pthread_timers)) { ast_mutex_lock(&timing_thread.lock); ast_cond_signal(&timing_thread.cond); ast_mutex_unlock(&timing_thread.lock); } ao2_link_flags(pthread_timers, timer, OBJ_NOLOCK); ao2_unlock(pthread_timers); return timer; } static void pthread_timer_close(void *data) { struct pthread_timer *timer = data; ao2_unlink(pthread_timers, timer); ao2_ref(timer, -1); } static int pthread_timer_set_rate(void *data, unsigned int rate) { struct pthread_timer *timer = data; if (rate > MAX_RATE) { ast_log(LOG_ERROR, "res_timing_pthread only supports timers at a " "max rate of %d / sec\n", MAX_RATE); errno = EINVAL; return -1; } ao2_lock(timer); if ((timer->rate = rate)) { timer->interval = roundf(1000.0 / ((float) rate)); timer->start = ast_tvnow(); timer->state = TIMER_STATE_TICKING; } else { timer->interval = 0; timer->start = ast_tv(0, 0); timer->state = TIMER_STATE_IDLE; } timer->tick_count = 0; ao2_unlock(timer); return 0; } static int pthread_timer_ack(void *data, unsigned int quantity) { struct pthread_timer *timer = data; ast_assert(quantity > 0); ao2_lock(timer); ack_ticks(timer, quantity); ao2_unlock(timer); return 0; } static int pthread_timer_enable_continuous(void *data) { struct pthread_timer *timer = data; ao2_lock(timer); if (!timer->continuous) { timer->continuous = true; signal_pipe(timer); } ao2_unlock(timer); return 0; } static int pthread_timer_disable_continuous(void *data) { struct pthread_timer *timer = data; ao2_lock(timer); if (timer->continuous) { timer->continuous = false; unsignal_pipe(timer); } ao2_unlock(timer); return 0; } static enum ast_timer_event pthread_timer_get_event(void *data) { struct pthread_timer *timer = data; enum ast_timer_event res = AST_TIMING_EVENT_EXPIRED; ao2_lock(timer); if (timer->continuous) { res = AST_TIMING_EVENT_CONTINUOUS; } ao2_unlock(timer); return res; } static unsigned int pthread_timer_get_max_rate(void *data) { return MAX_RATE; } static int pthread_timer_fd(void *data) { struct pthread_timer *timer = data; return timer->pipe[PIPE_READ]; } static void pthread_timer_destructor(void *obj) { struct pthread_timer *timer = obj; if (timer->pipe[PIPE_READ] > -1) { close(timer->pipe[PIPE_READ]); timer->pipe[PIPE_READ] = -1; } if (timer->pipe[PIPE_WRITE] > -1) { close(timer->pipe[PIPE_WRITE]); timer->pipe[PIPE_WRITE] = -1; } } /*! * \note only PIPE_READ is guaranteed valid */ static int pthread_timer_hash(const void *obj, const int flags) { const struct pthread_timer *timer = obj; return timer->pipe[PIPE_READ]; } /*! * \note only PIPE_READ is guaranteed valid */ static int pthread_timer_cmp(void *obj, void *arg, int flags) { struct pthread_timer *timer1 = obj, *timer2 = arg; return (timer1->pipe[PIPE_READ] == timer2->pipe[PIPE_READ]) ? CMP_MATCH | CMP_STOP : 0; } /*! * \retval 0 no timer tick needed * \retval non-zero write to the timing pipe needed */ static int check_timer(struct pthread_timer *timer) { struct timeval now; if (timer->state == TIMER_STATE_IDLE) { return 0; } now = ast_tvnow(); if (timer->tick_count < (ast_tvdiff_ms(now, timer->start) / timer->interval)) { timer->tick_count++; if (!timer->tick_count) { /* Handle overflow. */ timer->start = now; } return 1; } return 0; } /*! * \internal * \pre timer is locked */ static void ack_ticks(struct pthread_timer *timer, unsigned int quantity) { int pending_ticks = timer->pending_ticks; ast_assert(quantity); if (quantity > pending_ticks) { quantity = pending_ticks; } if (!quantity) { return; } timer->pending_ticks -= quantity; if ((0 == timer->pending_ticks) && !timer->continuous) { unsignal_pipe(timer); } } /*! * \internal * \pre timer is locked */ static void signal_pipe(struct pthread_timer *timer) { ssize_t res; unsigned char x = 42; if (timer->pipe_signaled) { return; } res = write(timer->pipe[PIPE_WRITE], &x, 1); if (-1 == res) { ast_log(LOG_ERROR, "Error writing to timing pipe: %s\n", strerror(errno)); } else { timer->pipe_signaled = true; } } /*! * \internal * \pre timer is locked */ static void unsignal_pipe(struct pthread_timer *timer) { ssize_t res; unsigned long buffer; if (!timer->pipe_signaled) { return; } res = read(timer->pipe[PIPE_READ], &buffer, sizeof(buffer)); if (-1 == res) { ast_log(LOG_ERROR, "Error reading from pipe: %s\n", strerror(errno)); } else { timer->pipe_signaled = false; } } static int run_timer(void *obj, void *arg, int flags) { struct pthread_timer *timer = obj; if (timer->state == TIMER_STATE_IDLE) { return 0; } ao2_lock(timer); if (check_timer(timer)) { timer->pending_ticks++; signal_pipe(timer); } ao2_unlock(timer); return 0; } static void *do_timing(void *arg) { struct timeval next_wakeup = ast_tvnow(); while (!timing_thread.stop) { struct timespec ts = { 0, }; ao2_callback(pthread_timers, OBJ_NODATA, run_timer, NULL); next_wakeup = ast_tvadd(next_wakeup, ast_tv(0, 5000)); ts.tv_sec = next_wakeup.tv_sec; ts.tv_nsec = next_wakeup.tv_usec * 1000; ast_mutex_lock(&timing_thread.lock); if (!timing_thread.stop) { if (ao2_container_count(pthread_timers)) { ast_cond_timedwait(&timing_thread.cond, &timing_thread.lock, &ts); } else { ast_cond_wait(&timing_thread.cond, &timing_thread.lock); } } ast_mutex_unlock(&timing_thread.lock); } return NULL; } static int init_timing_thread(void) { ast_mutex_init(&timing_thread.lock); ast_cond_init(&timing_thread.cond, NULL); if (ast_pthread_create_background(&timing_thread.thread, NULL, do_timing, NULL)) { ast_log(LOG_ERROR, "Unable to start timing thread.\n"); return -1; } return 0; } static int load_module(void) { pthread_timers = ao2_container_alloc_hash(AO2_ALLOC_OPT_LOCK_MUTEX, 0, PTHREAD_TIMER_BUCKETS, pthread_timer_hash, NULL, pthread_timer_cmp); if (!pthread_timers) { return AST_MODULE_LOAD_DECLINE; } if (init_timing_thread()) { ao2_ref(pthread_timers, -1); pthread_timers = NULL; return AST_MODULE_LOAD_DECLINE; } return (timing_funcs_handle = ast_register_timing_interface(&pthread_timing)) ? AST_MODULE_LOAD_SUCCESS : AST_MODULE_LOAD_DECLINE; } static int unload_module(void) { int res; ast_mutex_lock(&timing_thread.lock); timing_thread.stop = 1; ast_cond_signal(&timing_thread.cond); ast_mutex_unlock(&timing_thread.lock); pthread_join(timing_thread.thread, NULL); if (!(res = ast_unregister_timing_interface(timing_funcs_handle))) { ao2_ref(pthread_timers, -1); pthread_timers = NULL; } return res; } AST_MODULE_INFO(ASTERISK_GPL_KEY, AST_MODFLAG_LOAD_ORDER, "pthread Timing Interface", .support_level = AST_MODULE_SUPPORT_EXTENDED, .load = load_module, .unload = unload_module, .load_pri = AST_MODPRI_TIMING, );