/* * FreeSWITCH Modular Media Switching Software Library / Soft-Switch Application * Copyright (C) 2005/2006, Anthony Minessale II * * Version: MPL 1.1 * * The contents of this file are subject to the Mozilla Public License Version * 1.1 (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.mozilla.org/MPL/ * * Software distributed under the License is distributed on an "AS IS" basis, * WITHOUT WARRANTY OF ANY KIND, either express or implied. See the License * for the specific language governing rights and limitations under the * License. * * The Original Code is FreeSWITCH Modular Media Switching Software Library / Soft-Switch Application * * The Initial Developer of the Original Code is * Anthony Minessale II * Portions created by the Initial Developer are Copyright (C) * the Initial Developer. All Rights Reserved. * * Contributor(s): * * Anthony Minessale II * Michael Jerris * Paul D. Tinsley * * * switch_event.c -- Event System * */ #include #include static char hostname[128] = ""; static char guess_ip_v4[80] = ""; static char guess_ip_v6[80] = ""; static switch_event_node_t *EVENT_NODES[SWITCH_EVENT_ALL + 1] = { NULL }; static switch_mutex_t *BLOCK = NULL; static switch_mutex_t *POOL_LOCK = NULL; static switch_mutex_t *EVENT_QUEUE_MUTEX = NULL; static switch_mutex_t *EVENT_QUEUE_HAVEMORE_MUTEX = NULL; static switch_thread_cond_t *EVENT_QUEUE_CONDITIONAL = NULL; static switch_memory_pool_t *RUNTIME_POOL = NULL; /* static switch_memory_pool_t *APOOL = NULL; */ /* static switch_memory_pool_t *BPOOL = NULL; */ static switch_memory_pool_t *THRUNTIME_POOL = NULL; static switch_queue_t *EVENT_QUEUE[3] = { 0, 0, 0 }; static int POOL_COUNT_MAX = SWITCH_CORE_QUEUE_LEN; static switch_hash_t *CUSTOM_HASH = NULL; static int THREAD_RUNNING = 0; static int EVENT_QUEUE_HAVEMORE = 0; static switch_queue_t *EVENT_RECYCLE_QUEUE = NULL; static switch_queue_t *EVENT_HEADER_RECYCLE_QUEUE = NULL; #if 0 static void *locked_alloc(switch_size_t len) { void *mem; switch_mutex_lock(POOL_LOCK); /* ----------------------------------------------- */ mem = switch_core_alloc(THRUNTIME_POOL, len); switch_mutex_unlock(POOL_LOCK); /* ---------------------------------------------- */ return mem; } static void *locked_dup(char *str) { char *dup; switch_mutex_lock(POOL_LOCK); /* ----------------------------------------------- */ dup = switch_core_strdup(THRUNTIME_POOL, str); switch_mutex_unlock(POOL_LOCK); /* ---------------------------------------------- */ return dup; } #define ALLOC(size) locked_alloc(size) #define DUP(str) locked_dup(str) #endif static char *my_dup (const char *s) { size_t len = strlen (s) + 1; void *new = malloc (len); switch_assert(new); return (char *) memcpy (new, s, len); } #ifndef ALLOC #define ALLOC(size) malloc(size) #endif #ifndef DUP #define DUP(str) my_dup(str) #endif #ifndef FREE #define FREE(ptr) switch_safe_free(ptr) #endif /* make sure this is synced with the switch_event_types_t enum in switch_types.h also never put any new ones before EVENT_ALL */ static char *EVENT_NAMES[] = { "CUSTOM", "CHANNEL_CREATE", "CHANNEL_DESTROY", "CHANNEL_STATE", "CHANNEL_ANSWER", "CHANNEL_HANGUP", "CHANNEL_EXECUTE", "CHANNEL_EXECUTE_COMPLETE", "CHANNEL_BRIDGE", "CHANNEL_UNBRIDGE", "CHANNEL_PROGRESS", "CHANNEL_OUTGOING", "CHANNEL_PARK", "CHANNEL_UNPARK", "CHANNEL_APPLICATION", "CHANNEL_ORIGINATE", "API", "LOG", "INBOUND_CHAN", "OUTBOUND_CHAN", "STARTUP", "SHUTDOWN", "PUBLISH", "UNPUBLISH", "TALK", "NOTALK", "SESSION_CRASH", "MODULE_LOAD", "MODULE_UNLOAD", "DTMF", "MESSAGE", "PRESENCE_IN", "PRESENCE_OUT", "PRESENCE_PROBE", "MESSAGE_WAITING", "MESSAGE_QUERY", "ROSTER", "CODEC", "BACKGROUND_JOB", "DETECTED_SPEECH", "DETECTED_TONE", "PRIVATE_COMMAND", "HEARTBEAT", "TRAP", "ADD_SCHEDULE", "DEL_SCHEDULE", "EXE_SCHEDULE", "RE_SCHEDULE", "ALL" }; static int switch_events_match(switch_event_t *event, switch_event_node_t *node) { int match = 0; if (node->event_id == SWITCH_EVENT_ALL) { match++; if (!node->subclass) { return match; } } if (match || event->event_id == node->event_id) { if (event->subclass && node->subclass) { if (!strncasecmp(node->subclass->name, "file:", 5)) { char *file_header; if ((file_header = switch_event_get_header(event, "file")) != 0) { match = strstr(node->subclass->name + 5, file_header) ? 1 : 0; } } else if (!strncasecmp(node->subclass->name, "func:", 5)) { char *func_header; if ((func_header = switch_event_get_header(event, "function")) != 0) { match = strstr(node->subclass->name + 5, func_header) ? 1 : 0; } } else { match = strstr(event->subclass->name, node->subclass->name) ? 1 : 0; } } else if ((event->subclass && !node->subclass) || (!event->subclass && !node->subclass)) { match = 1; } else { match = 0; } } return match; } static void *SWITCH_THREAD_FUNC switch_event_thread(switch_thread_t * thread, void *obj) { switch_event_t *out_event = NULL; switch_queue_t *queue = NULL; switch_queue_t *queues[3] = { 0, 0, 0 }; void *pop; int i, len[3] = { 0, 0, 0 }; switch_assert(thread != NULL); switch_assert(obj == NULL); switch_assert(POOL_LOCK != NULL); switch_assert(RUNTIME_POOL != NULL); switch_assert(EVENT_QUEUE_MUTEX != NULL); switch_assert(EVENT_QUEUE_HAVEMORE_MUTEX != NULL); switch_assert(EVENT_QUEUE_CONDITIONAL != NULL); THREAD_RUNNING = 1; queues[0] = EVENT_QUEUE[SWITCH_PRIORITY_HIGH]; queues[1] = EVENT_QUEUE[SWITCH_PRIORITY_NORMAL]; queues[2] = EVENT_QUEUE[SWITCH_PRIORITY_LOW]; switch_mutex_lock(EVENT_QUEUE_MUTEX); for (;;) { int any; len[1] = switch_queue_size(EVENT_QUEUE[SWITCH_PRIORITY_NORMAL]); len[2] = switch_queue_size(EVENT_QUEUE[SWITCH_PRIORITY_LOW]); len[0] = switch_queue_size(EVENT_QUEUE[SWITCH_PRIORITY_HIGH]); any = len[1] + len[2] + len[0]; if (!any) { /* lock on havemore so we are the only ones poking at it while we check it * see if we saw anything in the queues or have a check again flag */ switch_mutex_lock(EVENT_QUEUE_HAVEMORE_MUTEX); if (!EVENT_QUEUE_HAVEMORE) { /* See if we need to quit */ if (THREAD_RUNNING != 1) { /* give up our lock */ switch_mutex_unlock(EVENT_QUEUE_HAVEMORE_MUTEX); /* game over */ break; } /* give up our lock */ switch_mutex_unlock(EVENT_QUEUE_HAVEMORE_MUTEX); /* wait until someone tells us we have something to do */ switch_thread_cond_wait(EVENT_QUEUE_CONDITIONAL, EVENT_QUEUE_MUTEX); } else { /* Caught a race, one of the queues was updated after we looked at it * reset our flag */ EVENT_QUEUE_HAVEMORE = 0; /* give up our lock */ switch_mutex_unlock(EVENT_QUEUE_HAVEMORE_MUTEX); } /* go grab some events */ continue; } for (i = 0; i < 3; i++) { if (len[i]) { queue = queues[i]; while (queue) { if (switch_queue_trypop(queue, &pop) == SWITCH_STATUS_SUCCESS) { out_event = pop; switch_event_deliver(&out_event); } else { break; } } } } if (THREAD_RUNNING < 0) { THREAD_RUNNING--; } } THREAD_RUNNING = 0; return NULL; } SWITCH_DECLARE(void) switch_event_deliver(switch_event_t **event) { switch_event_types_t e; switch_event_node_t *node; for (e = (*event)->event_id;; e = SWITCH_EVENT_ALL) { for (node = EVENT_NODES[e]; node; node = node->next) { if (switch_events_match(*event, node)) { (*event)->bind_user_data = node->user_data; node->callback(*event); } } if (e == SWITCH_EVENT_ALL) { break; } } switch_event_destroy(event); } SWITCH_DECLARE(switch_status_t) switch_event_running(void) { return THREAD_RUNNING ? SWITCH_STATUS_SUCCESS : SWITCH_STATUS_FALSE; } SWITCH_DECLARE(char *) switch_event_name(switch_event_types_t event) { switch_assert(BLOCK != NULL); switch_assert(RUNTIME_POOL != NULL); return EVENT_NAMES[event]; } SWITCH_DECLARE(switch_status_t) switch_name_event(char *name, switch_event_types_t *type) { switch_event_types_t x; switch_assert(BLOCK != NULL); switch_assert(RUNTIME_POOL != NULL); for (x = 0; x <= SWITCH_EVENT_ALL; x++) { if ((strlen(name) > 13 && !strcasecmp(name + 13, EVENT_NAMES[x])) || !strcasecmp(name, EVENT_NAMES[x])) { *type = x; return SWITCH_STATUS_SUCCESS; } } return SWITCH_STATUS_FALSE; } SWITCH_DECLARE(switch_status_t) switch_event_reserve_subclass_detailed(char *owner, char *subclass_name) { switch_event_subclass_t *subclass; switch_assert(RUNTIME_POOL != NULL); switch_assert(CUSTOM_HASH != NULL); if (switch_core_hash_find(CUSTOM_HASH, subclass_name)) { return SWITCH_STATUS_INUSE; } if ((subclass = switch_core_alloc(RUNTIME_POOL, sizeof(*subclass))) == 0) { return SWITCH_STATUS_MEMERR; } subclass->owner = switch_core_strdup(RUNTIME_POOL, owner); subclass->name = switch_core_strdup(RUNTIME_POOL, subclass_name); switch_core_hash_insert(CUSTOM_HASH, subclass->name, subclass); return SWITCH_STATUS_SUCCESS; } SWITCH_DECLARE(void) switch_core_memory_reclaim_events(void) { void *pop; int size; size = switch_queue_size(EVENT_RECYCLE_QUEUE); switch_log_printf(SWITCH_CHANNEL_LOG, SWITCH_LOG_CONSOLE, "Returning %d recycled event(s) %d bytes\n", size, (int) sizeof(switch_event_t) * size); size = switch_queue_size(EVENT_HEADER_RECYCLE_QUEUE); switch_log_printf(SWITCH_CHANNEL_LOG, SWITCH_LOG_CONSOLE, "Returning %d recycled event header(s) %d bytes\n", size, (int) sizeof(switch_event_header_t) * size); while (switch_queue_trypop(EVENT_HEADER_RECYCLE_QUEUE, &pop) == SWITCH_STATUS_SUCCESS) { free(pop); } while (switch_queue_trypop(EVENT_RECYCLE_QUEUE, &pop) == SWITCH_STATUS_SUCCESS) { free(pop); } } SWITCH_DECLARE(switch_status_t) switch_event_shutdown(void) { int x = 0, last = 0; if (THREAD_RUNNING > 0) { THREAD_RUNNING = -1; /* lock on havemore to make sure he event thread, if currently running * doesn't check the HAVEMORE flag before we set it */ switch_mutex_lock(EVENT_QUEUE_HAVEMORE_MUTEX); /* see if the event thread is sitting */ if (switch_mutex_trylock(EVENT_QUEUE_MUTEX) == SWITCH_STATUS_SUCCESS) { /* we don't need havemore anymore, the thread was sitting already */ switch_mutex_unlock(EVENT_QUEUE_HAVEMORE_MUTEX); /* wake up the event thread */ switch_thread_cond_signal(EVENT_QUEUE_CONDITIONAL); /* give up our lock */ switch_mutex_unlock(EVENT_QUEUE_MUTEX); } else { /* it wasn't waiting which means we might have updated a queue it already looked at * set a flag so it knows to read the queues again */ EVENT_QUEUE_HAVEMORE = 1; /* variable updated, give up the mutex */ switch_mutex_unlock(EVENT_QUEUE_HAVEMORE_MUTEX); } while (x < 100 && THREAD_RUNNING) { switch_yield(1000); if (THREAD_RUNNING == last) { x++; } last = THREAD_RUNNING; } } switch_core_hash_destroy(&CUSTOM_HASH); switch_core_memory_reclaim_events(); return SWITCH_STATUS_SUCCESS; } SWITCH_DECLARE(switch_status_t) switch_event_init(switch_memory_pool_t *pool) { switch_thread_t *thread; switch_threadattr_t *thd_attr;; switch_threadattr_create(&thd_attr, pool); switch_threadattr_detach_set(thd_attr, 1); gethostname(hostname, sizeof(hostname)); switch_find_local_ip(guess_ip_v4, sizeof(guess_ip_v4), AF_INET); switch_find_local_ip(guess_ip_v6, sizeof(guess_ip_v6), AF_INET6); switch_assert(pool != NULL); THRUNTIME_POOL = RUNTIME_POOL = pool; /* if (switch_core_new_memory_pool(&THRUNTIME_POOL) != SWITCH_STATUS_SUCCESS) { switch_log_printf(SWITCH_CHANNEL_LOG, SWITCH_LOG_CRIT, "Could not allocate memory pool\n"); return SWITCH_STATUS_MEMERR; } */ /* if (switch_core_new_memory_pool(&BPOOL) != SWITCH_STATUS_SUCCESS) { switch_log_printf(SWITCH_CHANNEL_LOG, SWITCH_LOG_DEBUG, "Could not allocate memory pool\n"); return SWITCH_STATUS_MEMERR; } */ /* THRUNTIME_POOL = APOOL; */ switch_queue_create(&EVENT_QUEUE[0], POOL_COUNT_MAX + 10, THRUNTIME_POOL); switch_queue_create(&EVENT_QUEUE[1], POOL_COUNT_MAX + 10, THRUNTIME_POOL); switch_queue_create(&EVENT_QUEUE[2], POOL_COUNT_MAX + 10, THRUNTIME_POOL); switch_queue_create(&EVENT_RECYCLE_QUEUE, SWITCH_CORE_QUEUE_LEN, THRUNTIME_POOL); switch_queue_create(&EVENT_HEADER_RECYCLE_QUEUE, SWITCH_CORE_QUEUE_LEN, THRUNTIME_POOL); switch_log_printf(SWITCH_CHANNEL_LOG, SWITCH_LOG_INFO, "Activate Eventing Engine.\n"); switch_mutex_init(&BLOCK, SWITCH_MUTEX_NESTED, RUNTIME_POOL); switch_mutex_init(&POOL_LOCK, SWITCH_MUTEX_NESTED, RUNTIME_POOL); switch_mutex_init(&EVENT_QUEUE_MUTEX, SWITCH_MUTEX_NESTED, RUNTIME_POOL); switch_mutex_init(&EVENT_QUEUE_HAVEMORE_MUTEX, SWITCH_MUTEX_NESTED, RUNTIME_POOL); switch_thread_cond_create(&EVENT_QUEUE_CONDITIONAL, RUNTIME_POOL); switch_core_hash_init(&CUSTOM_HASH, RUNTIME_POOL); switch_threadattr_stacksize_set(thd_attr, SWITCH_THREAD_STACKSIZE); switch_thread_create(&thread, thd_attr, switch_event_thread, NULL, RUNTIME_POOL); while (!THREAD_RUNNING) { switch_yield(1000); } return SWITCH_STATUS_SUCCESS; } SWITCH_DECLARE(switch_status_t) switch_event_create_subclass(switch_event_t **event, switch_event_types_t event_id, const char *subclass_name) { void *pop; if (event_id != SWITCH_EVENT_CUSTOM && subclass_name) { return SWITCH_STATUS_GENERR; } if (switch_queue_trypop(EVENT_RECYCLE_QUEUE, &pop) == SWITCH_STATUS_SUCCESS) { *event = (switch_event_t *) pop; } else { *event = ALLOC(sizeof(switch_event_t)); switch_assert(*event); } memset(*event, 0, sizeof(switch_event_t)); (*event)->event_id = event_id; if (subclass_name) { if (!((*event)->subclass = switch_core_hash_find(CUSTOM_HASH, subclass_name))) { switch_event_reserve_subclass((char *)subclass_name); (*event)->subclass = switch_core_hash_find(CUSTOM_HASH, subclass_name); } switch_event_add_header(*event, SWITCH_STACK_BOTTOM, "Event-Subclass", "%s", subclass_name); } return SWITCH_STATUS_SUCCESS; } SWITCH_DECLARE(switch_status_t) switch_event_set_priority(switch_event_t *event, switch_priority_t priority) { event->priority = priority; switch_event_add_header(event, SWITCH_STACK_TOP, "priority", "%s", switch_priority_name(priority)); return SWITCH_STATUS_SUCCESS; } SWITCH_DECLARE(char *) switch_event_get_header(switch_event_t *event, char *header_name) { switch_event_header_t *hp; if (header_name) { for (hp = event->headers; hp; hp = hp->next) { if (!strcasecmp(hp->name, header_name)) { return hp->value; } } } return NULL; } SWITCH_DECLARE(char *) switch_event_get_body(switch_event_t *event) { if (event) { return event->body; } return NULL; } SWITCH_DECLARE(switch_status_t) switch_event_del_header(switch_event_t *event, const char *header_name) { switch_event_header_t *hp, *lp = NULL; switch_status_t status = SWITCH_STATUS_FALSE; for (hp = event->headers; hp; hp = hp->next) { if (!strcmp(header_name, hp->name)) { if (lp) { lp->next = hp->next; } else { event->headers = hp->next; } FREE(hp->name); FREE(hp->value); if (switch_queue_trypush(EVENT_HEADER_RECYCLE_QUEUE, hp) != SWITCH_STATUS_SUCCESS) { FREE(hp); } status = SWITCH_STATUS_SUCCESS; break; } lp = hp; } return status; } SWITCH_DECLARE(switch_status_t) switch_event_add_header(switch_event_t *event, switch_stack_t stack, const char *header_name, const char *fmt, ...) { int ret = 0; char *data; va_list ap; va_start(ap, fmt); ret = switch_vasprintf(&data, fmt, ap); va_end(ap); if (ret == -1) { return SWITCH_STATUS_MEMERR; } else { switch_event_header_t *header, *hp; void *pop; if (switch_queue_trypop(EVENT_HEADER_RECYCLE_QUEUE, &pop) == SWITCH_STATUS_SUCCESS) { header = (switch_event_header_t *) pop; } else { header = ALLOC(sizeof(*header)); switch_assert(header); } memset(header, 0, sizeof(*header)); header->name = DUP(header_name); header->value = data; if (stack == SWITCH_STACK_TOP) { header->next = event->headers; event->headers = header; } else { for (hp = event->headers; hp && hp->next; hp = hp->next); if (hp) { hp->next = header; } else { event->headers = header; } } return SWITCH_STATUS_SUCCESS; } } SWITCH_DECLARE(switch_status_t) switch_event_add_body(switch_event_t *event, const char *fmt, ...) { int ret = 0; char *data; va_list ap; if (fmt) { va_start(ap, fmt); ret = switch_vasprintf(&data, fmt, ap); va_end(ap); if (ret == -1) { return SWITCH_STATUS_GENERR; } else { event->body = data; return SWITCH_STATUS_SUCCESS; } } else { return SWITCH_STATUS_GENERR; } } SWITCH_DECLARE(void) switch_event_destroy(switch_event_t **event) { switch_event_t *ep = *event; switch_event_header_t *hp, *this; if (ep) { for (hp = ep->headers; hp;) { this = hp; hp = hp->next; FREE(this->name); FREE(this->value); if (switch_queue_trypush(EVENT_HEADER_RECYCLE_QUEUE, this) != SWITCH_STATUS_SUCCESS) { FREE(this); } } FREE(ep->body); if (switch_queue_trypush(EVENT_RECYCLE_QUEUE, ep) != SWITCH_STATUS_SUCCESS) { FREE(ep); } } *event = NULL; } SWITCH_DECLARE(switch_status_t) switch_event_dup(switch_event_t **event, switch_event_t *todup) { switch_event_header_t *header, *hp, *hp2, *last = NULL; if (switch_event_create_subclass(event, todup->event_id, todup->subclass ? todup->subclass->name : NULL) != SWITCH_STATUS_SUCCESS) { return SWITCH_STATUS_GENERR; } (*event)->subclass = todup->subclass; (*event)->event_user_data = todup->event_user_data; (*event)->bind_user_data = todup->bind_user_data; hp2 = (*event)->headers; for (hp = todup->headers; hp; hp = hp->next) { if ((header = ALLOC(sizeof(*header))) == 0) { return SWITCH_STATUS_MEMERR; } memset(header, 0, sizeof(*header)); header->name = DUP(hp->name); header->value = DUP(hp->value); if (last) { last->next = header; } else { (*event)->headers = header; } last = header; } if (todup->body) { (*event)->body = DUP(todup->body); } (*event)->key = todup->key; return SWITCH_STATUS_SUCCESS; } SWITCH_DECLARE(switch_status_t) switch_event_serialize(switch_event_t *event, char **str, switch_bool_t encode) { switch_size_t len = 0; switch_event_header_t *hp; switch_size_t llen = 0, dlen = 0, blocksize = 512, encode_len = 1536, new_len = 0; char *buf; char *encode_buf = NULL; /* used for url encoding of variables to make sure unsafe things stay out of the serialzed copy */ *str = NULL; dlen = blocksize * 2; if (!(buf = malloc(dlen))) { return SWITCH_STATUS_MEMERR; } /* go ahead and give ourselves some space to work with, should save a few reallocs */ if (!(encode_buf = malloc(encode_len))) { return SWITCH_STATUS_MEMERR; } /* switch_log_printf(SWITCH_CHANNEL_LOG, SWITCH_LOG_INFO, "hit serialze!.\n"); */ for (hp = event->headers; hp; hp = hp->next) { /* * grab enough memory to store 3x the string (url encode takes one char and turns it into %XX) * so we could end up with a string that is 3 times the original's length, unlikely but rather * be safe than destroy the string, also add one for the null. And try to be smart about using * the memory, allocate and only reallocate if we need more. This avoids an alloc, free CPU * destroying loop. */ new_len = (strlen(hp->value) * 3) + 1; if (encode_len < new_len) { char *tmp; /* switch_log_printf(SWITCH_CHANNEL_LOG, SWITCH_LOG_INFO, "Allocing %d was %d.\n", ((strlen(hp->value) * 3) + 1), encode_len); */ /* we can use realloc for initial alloc as well, if encode_buf is zero it treats it as a malloc */ /* keep track of the size of our allocation */ encode_len = new_len; if (!(tmp = realloc(encode_buf, encode_len))) { /* oh boy, ram's gone, give back what little we grabbed and bail */ switch_safe_free(buf); switch_safe_free(encode_buf); return SWITCH_STATUS_MEMERR; } encode_buf = tmp; } /* handle any bad things in the string like newlines : etc that screw up the serialized format */ if (encode) { switch_url_encode(hp->value, encode_buf, encode_len - 1); } else { snprintf(encode_buf, encode_len, "[%s]", hp->value); } llen = strlen(hp->name) + strlen(encode_buf) + 8; if ((len + llen) > dlen) { char *m; dlen += (blocksize + (len + llen)); if ((m = realloc(buf, dlen))) { buf = m; } else { /* we seem to be out of memory trying to resize the serialize string, give back what we already have and give up */ switch_safe_free(buf); switch_safe_free(encode_buf); return SWITCH_STATUS_MEMERR; } } snprintf(buf + len, dlen - len, "%s: %s\n", hp->name, switch_strlen_zero(encode_buf) ? "_undef_" : encode_buf); len = strlen(buf); } /* we are done with the memory we used for encoding, give it back */ switch_safe_free(encode_buf); if (event->body) { int blen = (int) strlen(event->body); llen = blen; if (blen) { llen += 25; } else { llen += 5; } if ((len + llen) > dlen) { char *m; dlen += (blocksize + (len + llen)); if ((m = realloc(buf, dlen))) { buf = m; } else { switch_safe_free(buf); return SWITCH_STATUS_MEMERR; } } if (blen) { snprintf(buf + len, dlen - len, "Content-Length: %d\n\n%s", blen, event->body); } else { snprintf(buf + len, dlen - len, "\n"); } } else { snprintf(buf + len, dlen - len, "\n"); } *str = buf; return SWITCH_STATUS_SUCCESS; } static switch_xml_t add_xml_header(switch_xml_t xml, char *name, char *value, int offset) { switch_xml_t header = NULL; if ((header = switch_xml_add_child_d(xml, "header", offset))) { switch_xml_set_attr_d(header, "name", name); switch_xml_set_attr_d(header, "value", value); } return header; } SWITCH_DECLARE(switch_xml_t) switch_event_xmlize(switch_event_t *event, const char *fmt,...) { switch_event_header_t *hp; char *data = NULL, *body = NULL; int ret = 0; switch_xml_t xml = NULL; uint32_t off = 0; va_list ap; if (!(xml = switch_xml_new("event"))) { return xml; } if (fmt) { va_start(ap, fmt); #ifdef HAVE_VASPRINTF ret = vasprintf(&data, fmt, ap); #else data = (char *) malloc(2048); switch_assert(data); ret = vsnprintf(data, 2048, fmt, ap); #endif va_end(ap); if (ret == -1) { return NULL; } } for (hp = event->headers; hp; hp = hp->next) { add_xml_header(xml, hp->name, hp->value, off++); } if (data) { body = data; } else if (event->body) { body = event->body; } if (body) { int blen = (int) strlen(body); char blena[25]; snprintf(blena, sizeof(blena), "%d", blen); if (blen) { switch_xml_t xbody = NULL; add_xml_header(xml, "Content-Length", blena, off++); if ((xbody = switch_xml_add_child_d(xml, "body", off++))) { switch_xml_set_txt_d(xbody, body); } } } if (data) { free(data); } return xml; } SWITCH_DECLARE(switch_status_t) switch_event_fire_detailed(char *file, char *func, int line, switch_event_t **event, void *user_data) { switch_time_exp_t tm; char date[80] = ""; switch_size_t retsize; switch_time_t ts = switch_timestamp_now(); switch_assert(BLOCK != NULL); switch_assert(RUNTIME_POOL != NULL); switch_assert(EVENT_QUEUE_HAVEMORE_MUTEX != NULL); switch_assert(EVENT_QUEUE_MUTEX != NULL); switch_assert(EVENT_QUEUE_CONDITIONAL != NULL); switch_assert(RUNTIME_POOL != NULL); if (THREAD_RUNNING <= 0) { /* sorry we're closed */ switch_event_destroy(event); return SWITCH_STATUS_FALSE; } switch_event_add_header(*event, SWITCH_STACK_BOTTOM, "Event-Name", "%s", switch_event_name((*event)->event_id)); switch_event_add_header(*event, SWITCH_STACK_BOTTOM, "Core-UUID", "%s", switch_core_get_uuid()); switch_event_add_header(*event, SWITCH_STACK_BOTTOM, "FreeSWITCH-Hostname", "%s", hostname); switch_event_add_header(*event, SWITCH_STACK_BOTTOM, "FreeSWITCH-IPv4", "%s", guess_ip_v4); switch_event_add_header(*event, SWITCH_STACK_BOTTOM, "FreeSWITCH-IPv6", "%s", guess_ip_v6); switch_time_exp_lt(&tm, ts); switch_strftime(date, &retsize, sizeof(date), "%Y-%m-%d %T", &tm); switch_event_add_header(*event, SWITCH_STACK_BOTTOM, "Event-Date-Local", "%s", date); switch_rfc822_date(date, ts); switch_event_add_header(*event, SWITCH_STACK_BOTTOM, "Event-Date-GMT", "%s", date); switch_event_add_header(*event, SWITCH_STACK_BOTTOM, "Event-Date-timestamp", "%"SWITCH_UINT64_T_FMT, (uint64_t)ts); switch_event_add_header(*event, SWITCH_STACK_BOTTOM, "Event-Calling-File", "%s", switch_cut_path(file)); switch_event_add_header(*event, SWITCH_STACK_BOTTOM, "Event-Calling-Function", "%s", func); switch_event_add_header(*event, SWITCH_STACK_BOTTOM, "Event-Calling-Line-Number", "%d", line); if ((*event)->subclass) { switch_event_add_header(*event, SWITCH_STACK_BOTTOM, "Event-Subclass", "%s", (*event)->subclass->name); switch_event_add_header(*event, SWITCH_STACK_BOTTOM, "Event-Subclass-Owner", "%s", (*event)->subclass->owner); } if (user_data) { (*event)->event_user_data = user_data; } switch_queue_push(EVENT_QUEUE[(*event)->priority], *event); /* lock on havemore to make sure he event thread, if currently running * doesn't check the HAVEMORE flag before we set it */ switch_mutex_lock(EVENT_QUEUE_HAVEMORE_MUTEX); /* see if the event thread is sitting */ if (switch_mutex_trylock(EVENT_QUEUE_MUTEX) == SWITCH_STATUS_SUCCESS) { /* we don't need havemore anymore, the thread was sitting already */ switch_mutex_unlock(EVENT_QUEUE_HAVEMORE_MUTEX); /* wake up the event thread */ switch_thread_cond_signal(EVENT_QUEUE_CONDITIONAL); /* give up our lock */ switch_mutex_unlock(EVENT_QUEUE_MUTEX); } else { /* it wasn't waiting which means we might have updated a queue it already looked at * set a flag so it knows to read the queues again */ EVENT_QUEUE_HAVEMORE = 1; /* variable updated, give up the mutex */ switch_mutex_unlock(EVENT_QUEUE_HAVEMORE_MUTEX); } *event = NULL; return SWITCH_STATUS_SUCCESS; } SWITCH_DECLARE(switch_status_t) switch_event_bind(const char *id, switch_event_types_t event, char *subclass_name, switch_event_callback_t callback, void *user_data) { switch_event_node_t *event_node; switch_event_subclass_t *subclass = NULL; switch_assert(BLOCK != NULL); switch_assert(RUNTIME_POOL != NULL); if (subclass_name) { if ((subclass = switch_core_hash_find(CUSTOM_HASH, subclass_name)) == 0) { if ((subclass = switch_core_alloc(RUNTIME_POOL, sizeof(*subclass))) == 0) { return SWITCH_STATUS_MEMERR; } else { subclass->owner = switch_core_strdup(RUNTIME_POOL, id); subclass->name = switch_core_strdup(RUNTIME_POOL, subclass_name); } } } if (event <= SWITCH_EVENT_ALL && (event_node = switch_core_alloc(RUNTIME_POOL, sizeof(switch_event_node_t))) != 0) { switch_mutex_lock(BLOCK); /* ----------------------------------------------- */ event_node->id = switch_core_strdup(RUNTIME_POOL, id); event_node->event_id = event; event_node->subclass = subclass; event_node->callback = callback; event_node->user_data = user_data; if (EVENT_NODES[event]) { event_node->next = EVENT_NODES[event]; } EVENT_NODES[event] = event_node; switch_mutex_unlock(BLOCK); /* ----------------------------------------------- */ return SWITCH_STATUS_SUCCESS; } return SWITCH_STATUS_MEMERR; } /* For Emacs: * Local Variables: * mode:c * indent-tabs-mode:t * tab-width:4 * c-basic-offset:4 * End: * For VIM: * vim:set softtabstop=4 shiftwidth=4 tabstop=4 expandtab: */