/* * Asterisk -- An open source telephony toolkit. * * Copyright (C) 1999 - 2008, Digium, Inc. * * Mark Spencer * 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 * * \brief Device state management * * \author Mark Spencer * \author Russell Bryant * * \arg \ref AstExtState */ /*! \page AstExtState Extension and device states in Asterisk * * (Note that these descriptions of device states and extension * states have not been updated to the way things work * in Asterisk 1.6.) * * Asterisk has an internal system that reports states * for an extension. By using the dialplan priority -1, * also called a \b hint, a connection can be made from an * extension to one or many devices. The state of the extension * now depends on the combined state of the devices. * * The device state is basically based on the current calls. * If the devicestate engine can find a call from or to the * device, it's in use. * * Some channel drivers implement a callback function for * a better level of reporting device states. The SIP channel * has a complicated system for this, which is improved * by adding call limits to the configuration. * * Functions that want to check the status of an extension * register themself as a \b watcher. * Watchers in this system can subscribe either to all extensions * or just a specific extensions. * * For non-device related states, there's an API called * devicestate providers. This is an extendible system for * delivering state information from outside sources or * functions within Asterisk. Currently we have providers * for app_meetme.c - the conference bridge - and call * parking (metermaids). * * There are manly three subscribers to extension states * within Asterisk: * - AMI, the manager interface * - app_queue.c - the Queue dialplan application * - SIP subscriptions, a.k.a. "blinking lamps" or * "buddy lists" * * The CLI command "show hints" show last known state * * \note None of these handle user states, like an IM presence * system. res_xmpp.c can subscribe and watch such states * in jabber/xmpp based systems. * * \section AstDevStateArch Architecture for devicestates * * When a channel driver or asterisk app changes state for * a watched object, it alerts the core. The core queues * a change. When the change is processed, there's a query * sent to the channel driver/provider if there's a function * to handle that, otherwise a channel walk is issued to find * a channel that involves the object. * * The changes are queued and processed by a separate thread. * This thread calls the watchers subscribing to status * changes for the object. For manager, this results * in events. For SIP, NOTIFY requests. * * - Device states * \arg \ref devicestate.c * \arg \ref devicestate.h * * \section AstExtStateArch Architecture for extension states * * Hints are connected to extension. If an extension changes state * it checks the hint devices. If there is a hint, the callbacks into * device states are checked. The aggregated state is set for the hint * and reported back. * * - Extension states * \arg \ref AstENUM ast_extension_states * \arg \ref pbx.c * \arg \ref pbx.h * - Structures * - \ref ast_state_cb struct. Callbacks for watchers * - Callback ast_state_cb_type * - \ref ast_hint struct. * - Functions * - ast_extension_state_add() * - ast_extension_state_del() * - ast_get_hint() * */ /*** MODULEINFO core ***/ /*** DOCUMENTATION Raised when a device state changes The device whose state has changed The new state of the device This differs from the ExtensionStatus event because this event is raised for all device state changes, not only for changes that affect dialplan hints.

ExtensionStatus

***/ #include "asterisk.h" #include "asterisk/_private.h" #include "asterisk/channel.h" #include "asterisk/utils.h" #include "asterisk/lock.h" #include "asterisk/linkedlists.h" #include "asterisk/devicestate.h" #include "asterisk/pbx.h" #include "asterisk/app.h" #include "asterisk/astobj2.h" #include "asterisk/stasis.h" #include "asterisk/devicestate.h" #define DEVSTATE_TOPIC_BUCKETS 57 /*! \brief Device state strings for printing */ static const char * const devstatestring[][2] = { { /* 0 AST_DEVICE_UNKNOWN */ "Unknown", "UNKNOWN" }, /*!< Valid, but unknown state */ { /* 1 AST_DEVICE_NOT_INUSE */ "Not in use", "NOT_INUSE" }, /*!< Not used */ { /* 2 AST_DEVICE IN USE */ "In use", "INUSE" }, /*!< In use */ { /* 3 AST_DEVICE_BUSY */ "Busy", "BUSY" }, /*!< Busy */ { /* 4 AST_DEVICE_INVALID */ "Invalid", "INVALID" }, /*!< Invalid - not known to Asterisk */ { /* 5 AST_DEVICE_UNAVAILABLE */ "Unavailable", "UNAVAILABLE" }, /*!< Unavailable (not registered) */ { /* 6 AST_DEVICE_RINGING */ "Ringing", "RINGING" }, /*!< Ring, ring, ring */ { /* 7 AST_DEVICE_RINGINUSE */ "Ring+Inuse", "RINGINUSE" }, /*!< Ring and in use */ { /* 8 AST_DEVICE_ONHOLD */ "On Hold", "ONHOLD" }, /*!< On Hold */ }; /*!\brief Mapping for channel states to device states */ static const struct chan2dev { enum ast_channel_state chan; enum ast_device_state dev; } chan2dev[] = { { AST_STATE_DOWN, AST_DEVICE_NOT_INUSE }, { AST_STATE_RESERVED, AST_DEVICE_INUSE }, { AST_STATE_OFFHOOK, AST_DEVICE_INUSE }, { AST_STATE_DIALING, AST_DEVICE_INUSE }, { AST_STATE_RING, AST_DEVICE_INUSE }, { AST_STATE_RINGING, AST_DEVICE_RINGING }, { AST_STATE_UP, AST_DEVICE_INUSE }, { AST_STATE_BUSY, AST_DEVICE_BUSY }, { AST_STATE_DIALING_OFFHOOK, AST_DEVICE_INUSE }, { AST_STATE_PRERING, AST_DEVICE_RINGING }, }; /*! \brief A device state provider (not a channel) */ struct devstate_prov { char label[40]; ast_devstate_prov_cb_type callback; AST_RWLIST_ENTRY(devstate_prov) list; }; /*! \brief A list of providers */ static AST_RWLIST_HEAD_STATIC(devstate_provs, devstate_prov); struct state_change { AST_LIST_ENTRY(state_change) list; enum ast_devstate_cache cachable; char device[1]; }; /*! \brief The state change queue. State changes are queued for processing by a separate thread */ static AST_LIST_HEAD_STATIC(state_changes, state_change); /*! \brief The device state change notification thread */ static pthread_t change_thread = AST_PTHREADT_NULL; /*! \brief Flag for the queue */ static ast_cond_t change_pending; static volatile int shuttingdown; struct stasis_subscription *devstate_message_sub; static struct stasis_topic *device_state_topic_all; static struct stasis_cache *device_state_cache; static struct stasis_caching_topic *device_state_topic_cached; static struct stasis_topic_pool *device_state_topic_pool; static struct ast_manager_event_blob *devstate_to_ami(struct stasis_message *msg); static struct ast_event *devstate_to_event(struct stasis_message *msg); STASIS_MESSAGE_TYPE_DEFN(ast_device_state_message_type, .to_ami = devstate_to_ami, .to_event = devstate_to_event, ); /* Forward declarations */ static int getproviderstate(const char *provider, const char *address); /*! \brief Find devicestate as text message for output */ const char *ast_devstate2str(enum ast_device_state devstate) { return devstatestring[devstate][0]; } enum ast_device_state ast_state_chan2dev(enum ast_channel_state chanstate) { int i; chanstate &= 0xFFFF; for (i = 0; i < ARRAY_LEN(chan2dev); i++) { if (chan2dev[i].chan == chanstate) { return chan2dev[i].dev; } } return AST_DEVICE_UNKNOWN; } /* Parseable */ const char *ast_devstate_str(enum ast_device_state state) { return devstatestring[state][1]; } enum ast_device_state ast_devstate_val(const char *val) { if (!strcasecmp(val, "NOT_INUSE")) return AST_DEVICE_NOT_INUSE; else if (!strcasecmp(val, "INUSE")) return AST_DEVICE_INUSE; else if (!strcasecmp(val, "BUSY")) return AST_DEVICE_BUSY; else if (!strcasecmp(val, "INVALID")) return AST_DEVICE_INVALID; else if (!strcasecmp(val, "UNAVAILABLE")) return AST_DEVICE_UNAVAILABLE; else if (!strcasecmp(val, "RINGING")) return AST_DEVICE_RINGING; else if (!strcasecmp(val, "RINGINUSE")) return AST_DEVICE_RINGINUSE; else if (!strcasecmp(val, "ONHOLD")) return AST_DEVICE_ONHOLD; return AST_DEVICE_UNKNOWN; } /*! \brief Find out if device is active in a call or not \note find channels with the device's name in it This function is only used for channels that does not implement devicestate natively */ enum ast_device_state ast_parse_device_state(const char *device) { struct ast_channel *chan; char match[AST_CHANNEL_NAME]; enum ast_device_state res; snprintf(match, sizeof(match), "%s-", device); if (!(chan = ast_channel_get_by_name_prefix(match, strlen(match)))) { return AST_DEVICE_UNKNOWN; } if (ast_channel_hold_state(chan) == AST_CONTROL_HOLD) { res = AST_DEVICE_ONHOLD; } else { res = ast_state_chan2dev(ast_channel_state(chan)); } ast_channel_unref(chan); return res; } static enum ast_device_state devstate_cached(const char *device) { struct stasis_message *cached_msg; struct ast_device_state_message *device_state; enum ast_device_state state; cached_msg = stasis_cache_get_by_eid(ast_device_state_cache(), ast_device_state_message_type(), device, NULL); if (!cached_msg) { return AST_DEVICE_UNKNOWN; } device_state = stasis_message_data(cached_msg); state = device_state->state; ao2_cleanup(cached_msg); return state; } /*! \brief Check device state through channel specific function or generic function */ static enum ast_device_state _ast_device_state(const char *device, int check_cache) { char *number; const struct ast_channel_tech *chan_tech; enum ast_device_state res; /*! \brief Channel driver that provides device state */ char *tech; /* If the last known state is cached, just return that */ if (check_cache) { res = devstate_cached(device); if (res != AST_DEVICE_UNKNOWN) { return res; } } number = ast_strdupa(device); tech = strsep(&number, "/"); if (!number) { /*! \brief Another provider of device state */ char *provider; provider = strsep(&tech, ":"); if (!tech) { return AST_DEVICE_INVALID; } /* We have a provider */ number = tech; ast_debug(3, "Checking if I can find provider for \"%s\" - number: %s\n", provider, number); return getproviderstate(provider, number); } ast_debug(4, "No provider found, checking channel drivers for %s - %s\n", tech, number); chan_tech = ast_get_channel_tech(tech); if (!chan_tech) { return AST_DEVICE_INVALID; } /* Does the channel driver support device state notification? */ if (!chan_tech->devicestate) { /* No, try the generic function */ return ast_parse_device_state(device); } res = chan_tech->devicestate(number); if (res == AST_DEVICE_UNKNOWN) { res = ast_parse_device_state(device); } return res; } enum ast_device_state ast_device_state(const char *device) { /* This function is called from elsewhere in the code to find out the * current state of a device. Check the cache, first. */ return _ast_device_state(device, 1); } /*! \brief Add device state provider */ int ast_devstate_prov_add(const char *label, ast_devstate_prov_cb_type callback) { struct devstate_prov *devcb; struct devstate_prov *devprov; if (!callback || !(devprov = ast_calloc(1, sizeof(*devprov)))) return -1; devprov->callback = callback; ast_copy_string(devprov->label, label, sizeof(devprov->label)); AST_RWLIST_WRLOCK(&devstate_provs); AST_RWLIST_TRAVERSE(&devstate_provs, devcb, list) { if (!strcasecmp(devcb->label, label)) { ast_log(LOG_WARNING, "Device state provider '%s' already registered\n", label); ast_free(devprov); AST_RWLIST_UNLOCK(&devstate_provs); return -1; } } AST_RWLIST_INSERT_HEAD(&devstate_provs, devprov, list); AST_RWLIST_UNLOCK(&devstate_provs); return 0; } /*! \brief Remove device state provider */ int ast_devstate_prov_del(const char *label) { struct devstate_prov *devcb; int res = -1; AST_RWLIST_WRLOCK(&devstate_provs); AST_RWLIST_TRAVERSE_SAFE_BEGIN(&devstate_provs, devcb, list) { if (!strcasecmp(devcb->label, label)) { AST_RWLIST_REMOVE_CURRENT(list); ast_free(devcb); res = 0; break; } } AST_RWLIST_TRAVERSE_SAFE_END; AST_RWLIST_UNLOCK(&devstate_provs); return res; } /*! \brief Get provider device state */ static int getproviderstate(const char *provider, const char *address) { struct devstate_prov *devprov; int res = AST_DEVICE_INVALID; AST_RWLIST_RDLOCK(&devstate_provs); AST_RWLIST_TRAVERSE(&devstate_provs, devprov, list) { ast_debug(5, "Checking provider %s with %s\n", devprov->label, provider); if (!strcasecmp(devprov->label, provider)) { res = devprov->callback(address); break; } } AST_RWLIST_UNLOCK(&devstate_provs); return res; } /*! Called by the state change thread to find out what the state is, and then * to queue up the state change event */ static void do_state_change(const char *device, enum ast_devstate_cache cachable) { enum ast_device_state state; state = _ast_device_state(device, 0); ast_debug(3, "Changing state for %s - state %u (%s)\n", device, state, ast_devstate2str(state)); ast_publish_device_state(device, state, cachable); } int ast_devstate_changed_literal(enum ast_device_state state, enum ast_devstate_cache cachable, const char *device) { struct state_change *change; /* * If we know the state change (how nice of the caller of this function!) * then we can just generate a device state event. * * Otherwise, we do the following: * - Queue an event up to another thread that the state has changed * - In the processing thread, it calls the callback provided by the * device state provider (which may or may not be a channel driver) * to determine the state. * - If the device state provider does not know the state, or this is * for a channel and the channel driver does not implement a device * state callback, then we will look through the channel list to * see if we can determine a state based on active calls. * - Once a state has been determined, a device state event is generated. */ if (state != AST_DEVICE_UNKNOWN) { ast_publish_device_state(device, state, cachable); } else if (change_thread == AST_PTHREADT_NULL || !(change = ast_calloc(1, sizeof(*change) + strlen(device)))) { /* we could not allocate a change struct, or */ /* there is no background thread, so process the change now */ do_state_change(device, cachable); } else { /* queue the change */ strcpy(change->device, device); change->cachable = cachable; AST_LIST_LOCK(&state_changes); AST_LIST_INSERT_TAIL(&state_changes, change, list); ast_cond_signal(&change_pending); AST_LIST_UNLOCK(&state_changes); } return 0; } int ast_devstate_changed(enum ast_device_state state, enum ast_devstate_cache cachable, const char *fmt, ...) { char buf[AST_MAX_EXTENSION]; va_list ap; va_start(ap, fmt); vsnprintf(buf, sizeof(buf), fmt, ap); va_end(ap); return ast_devstate_changed_literal(state, cachable, buf); } /*! \brief Go through the dev state change queue and update changes in the dev state thread */ static void *do_devstate_changes(void *data) { struct state_change *next, *current; while (!shuttingdown) { /* This basically pops off any state change entries, resets the list back to NULL, unlocks, and processes each state change */ AST_LIST_LOCK(&state_changes); if (AST_LIST_EMPTY(&state_changes)) ast_cond_wait(&change_pending, &state_changes.lock); next = AST_LIST_FIRST(&state_changes); AST_LIST_HEAD_INIT_NOLOCK(&state_changes); AST_LIST_UNLOCK(&state_changes); /* Process each state change */ while ((current = next)) { next = AST_LIST_NEXT(current, list); do_state_change(current->device, current->cachable); ast_free(current); } } return NULL; } static struct ast_device_state_message *device_state_alloc(const char *device, enum ast_device_state state, enum ast_devstate_cache cachable, const struct ast_eid *eid) { struct ast_device_state_message *new_device_state; char *pos; size_t stuff_len; ast_assert(!ast_strlen_zero(device)); stuff_len = strlen(device) + 1; if (eid) { stuff_len += sizeof(*eid); } new_device_state = ao2_alloc_options(sizeof(*new_device_state) + stuff_len, NULL, AO2_ALLOC_OPT_LOCK_NOLOCK); if (!new_device_state) { return NULL; } if (eid) { /* non-aggregate device state. */ new_device_state->stuff[0] = *eid; new_device_state->eid = &new_device_state->stuff[0]; pos = (char *) &new_device_state->stuff[1]; } else { pos = (char *) &new_device_state->stuff[0]; } strcpy(pos, device);/* Safe */ new_device_state->device = pos; new_device_state->state = state; new_device_state->cachable = cachable; return new_device_state; } static void devstate_change_cb(void *data, struct stasis_subscription *sub, struct stasis_message *msg) { struct ast_device_state_message *device_state; if (ast_device_state_message_type() != stasis_message_type(msg)) { return; } device_state = stasis_message_data(msg); if (device_state->cachable == AST_DEVSTATE_CACHABLE || !device_state->eid) { /* Ignore cacheable and aggregate messages. */ return; } /* * Non-cacheable device state aggregates are just the * device state republished as the aggregate. */ ast_publish_device_state_full(device_state->device, device_state->state, device_state->cachable, NULL); } static void device_state_engine_cleanup(void) { shuttingdown = 1; AST_LIST_LOCK(&state_changes); ast_cond_signal(&change_pending); AST_LIST_UNLOCK(&state_changes); if (change_thread != AST_PTHREADT_NULL) { pthread_join(change_thread, NULL); } } /*! \brief Initialize the device state engine in separate thread */ int ast_device_state_engine_init(void) { ast_cond_init(&change_pending, NULL); if (ast_pthread_create_background(&change_thread, NULL, do_devstate_changes, NULL) < 0) { ast_log(LOG_ERROR, "Unable to start device state change thread.\n"); return -1; } ast_register_cleanup(device_state_engine_cleanup); return 0; } void ast_devstate_aggregate_init(struct ast_devstate_aggregate *agg) { memset(agg, 0, sizeof(*agg)); agg->state = AST_DEVICE_INVALID; } void ast_devstate_aggregate_add(struct ast_devstate_aggregate *agg, enum ast_device_state state) { static enum ast_device_state state_order[] = { 1, /* AST_DEVICE_UNKNOWN */ 3, /* AST_DEVICE_NOT_INUSE */ 6, /* AST_DEVICE_INUSE */ 7, /* AST_DEVICE_BUSY */ 0, /* AST_DEVICE_INVALID */ 2, /* AST_DEVICE_UNAVAILABLE */ 5, /* AST_DEVICE_RINGING */ 8, /* AST_DEVICE_RINGINUSE */ 4, /* AST_DEVICE_ONHOLD */ }; if (state == AST_DEVICE_RINGING) { agg->ringing = 1; } else if (state == AST_DEVICE_INUSE || state == AST_DEVICE_ONHOLD || state == AST_DEVICE_BUSY) { agg->inuse = 1; } if (agg->ringing && agg->inuse) { agg->state = AST_DEVICE_RINGINUSE; } else if (state_order[state] > state_order[agg->state]) { agg->state = state; } } enum ast_device_state ast_devstate_aggregate_result(struct ast_devstate_aggregate *agg) { return agg->state; } struct stasis_topic *ast_device_state_topic_all(void) { return device_state_topic_all; } struct stasis_cache *ast_device_state_cache(void) { return device_state_cache; } struct stasis_topic *ast_device_state_topic_cached(void) { return stasis_caching_get_topic(device_state_topic_cached); } struct stasis_topic *ast_device_state_topic(const char *device) { return stasis_topic_pool_get_topic(device_state_topic_pool, device); } int ast_device_state_clear_cache(const char *device) { struct stasis_message *cached_msg; struct stasis_message *msg; cached_msg = stasis_cache_get_by_eid(ast_device_state_cache(), ast_device_state_message_type(), device, &ast_eid_default); if (!cached_msg) { /* nothing to clear */ return -1; } msg = stasis_cache_clear_create(cached_msg); if (msg) { stasis_publish(ast_device_state_topic(device), msg); } ao2_cleanup(msg); ao2_cleanup(cached_msg); return 0; } int ast_publish_device_state_full( const char *device, enum ast_device_state state, enum ast_devstate_cache cachable, struct ast_eid *eid) { RAII_VAR(struct ast_device_state_message *, device_state, NULL, ao2_cleanup); RAII_VAR(struct stasis_message *, message, NULL, ao2_cleanup); struct stasis_topic *device_specific_topic; ast_assert(!ast_strlen_zero(device)); if (!ast_device_state_message_type()) { return -1; } device_state = device_state_alloc(device, state, cachable, eid); if (!device_state) { return -1; } message = stasis_message_create_full(ast_device_state_message_type(), device_state, eid); if (!message) { return -1; } device_specific_topic = ast_device_state_topic(device); if (!device_specific_topic) { return -1; } stasis_publish(device_specific_topic, message); return 0; } static const char *device_state_get_id(struct stasis_message *message) { struct ast_device_state_message *device_state; if (ast_device_state_message_type() != stasis_message_type(message)) { return NULL; } device_state = stasis_message_data(message); if (device_state->cachable == AST_DEVSTATE_NOT_CACHABLE) { return NULL; } return device_state->device; } /*! * \internal * \brief Callback to publish the aggregate device state cache entry message. * \since 12.2.0 * * \param cache_topic Caching topic the aggregate message may be published over. * \param aggregate The aggregate shapshot message to publish. * * \return Nothing */ static void device_state_aggregate_publish(struct stasis_topic *cache_topic, struct stasis_message *aggregate) { const char *device; struct stasis_topic *device_specific_topic; device = device_state_get_id(aggregate); if (!device) { return; } device_specific_topic = ast_device_state_topic(device); if (!device_specific_topic) { return; } stasis_publish(device_specific_topic, aggregate); } /*! * \internal * \brief Callback to calculate the aggregate device state cache entry. * \since 12.2.0 * * \param entry Cache entry to calculate a new aggregate snapshot. * \param new_snapshot The shapshot that is being updated. * * \note Return a ref bumped pointer from stasis_cache_entry_get_aggregate() * if a new aggregate could not be calculated because of error. * * \return New aggregate-snapshot calculated on success. * Caller has a reference on return. */ static struct stasis_message *device_state_aggregate_calc(struct stasis_cache_entry *entry, struct stasis_message *new_snapshot) { struct stasis_message *aggregate_snapshot; struct stasis_message *snapshot; struct ast_device_state_message *device_state; const char *device = NULL; struct ast_devstate_aggregate aggregate; int idx; if (!ast_device_state_message_type()) { return NULL; } /* Determine the new aggregate device state. */ ast_devstate_aggregate_init(&aggregate); snapshot = stasis_cache_entry_get_local(entry); if (snapshot) { device_state = stasis_message_data(snapshot); device = device_state->device; ast_devstate_aggregate_add(&aggregate, device_state->state); } for (idx = 0; ; ++idx) { snapshot = stasis_cache_entry_get_remote(entry, idx); if (!snapshot) { break; } device_state = stasis_message_data(snapshot); device = device_state->device; ast_devstate_aggregate_add(&aggregate, device_state->state); } if (!device) { /* There are no device states cached. Delete the aggregate. */ return NULL; } snapshot = stasis_cache_entry_get_aggregate(entry); if (snapshot) { device_state = stasis_message_data(snapshot); if (device_state->state == ast_devstate_aggregate_result(&aggregate)) { /* Aggregate device state did not change. */ return ao2_bump(snapshot); } } device_state = device_state_alloc(device, ast_devstate_aggregate_result(&aggregate), AST_DEVSTATE_CACHABLE, NULL); if (!device_state) { /* Bummer. We have to keep the old aggregate snapshot. */ return ao2_bump(snapshot); } aggregate_snapshot = stasis_message_create_full(ast_device_state_message_type(), device_state, NULL); ao2_cleanup(device_state); if (!aggregate_snapshot) { /* Bummer. We have to keep the old aggregate snapshot. */ return ao2_bump(snapshot); } return aggregate_snapshot; } static void devstate_cleanup(void) { devstate_message_sub = stasis_unsubscribe_and_join(devstate_message_sub); device_state_topic_cached = stasis_caching_unsubscribe_and_join(device_state_topic_cached); ao2_cleanup(device_state_cache); device_state_cache = NULL; ao2_cleanup(device_state_topic_pool); device_state_topic_pool = NULL; ao2_cleanup(device_state_topic_all); device_state_topic_all = NULL; STASIS_MESSAGE_TYPE_CLEANUP(ast_device_state_message_type); } int devstate_init(void) { ast_register_cleanup(devstate_cleanup); if (STASIS_MESSAGE_TYPE_INIT(ast_device_state_message_type) != 0) { return -1; } device_state_topic_all = stasis_topic_create("ast_device_state_topic"); if (!device_state_topic_all) { return -1; } device_state_topic_pool = stasis_topic_pool_create(ast_device_state_topic_all()); if (!device_state_topic_pool) { return -1; } device_state_cache = stasis_cache_create_full(device_state_get_id, device_state_aggregate_calc, device_state_aggregate_publish); if (!device_state_cache) { return -1; } device_state_topic_cached = stasis_caching_topic_create(ast_device_state_topic_all(), device_state_cache); if (!device_state_topic_cached) { return -1; } devstate_message_sub = stasis_subscribe(ast_device_state_topic_all(), devstate_change_cb, NULL); if (!devstate_message_sub) { ast_log(LOG_ERROR, "Failed to create subscription creating uncached device state aggregate events.\n"); return -1; } return 0; } static struct ast_manager_event_blob *devstate_to_ami(struct stasis_message *msg) { struct ast_device_state_message *dev_state; dev_state = stasis_message_data(msg); /* Ignore non-aggregate states */ if (dev_state->eid) { return NULL; } return ast_manager_event_blob_create(EVENT_FLAG_CALL, "DeviceStateChange", "Device: %s\r\n" "State: %s\r\n", dev_state->device, ast_devstate_str(dev_state->state)); } /*! \brief Convert a \ref stasis_message to a \ref ast_event */ static struct ast_event *devstate_to_event(struct stasis_message *message) { struct ast_event *event; struct ast_device_state_message *device_state; if (!message) { return NULL; } device_state = stasis_message_data(message); if (device_state->eid) { event = ast_event_new(AST_EVENT_DEVICE_STATE_CHANGE, AST_EVENT_IE_DEVICE, AST_EVENT_IE_PLTYPE_STR, device_state->device, AST_EVENT_IE_STATE, AST_EVENT_IE_PLTYPE_UINT, device_state->state, AST_EVENT_IE_CACHABLE, AST_EVENT_IE_PLTYPE_UINT, device_state->cachable, AST_EVENT_IE_EID, AST_EVENT_IE_PLTYPE_RAW, device_state->eid, sizeof(*device_state->eid), AST_EVENT_IE_END); } else { event = ast_event_new(AST_EVENT_DEVICE_STATE, AST_EVENT_IE_DEVICE, AST_EVENT_IE_PLTYPE_STR, device_state->device, AST_EVENT_IE_STATE, AST_EVENT_IE_PLTYPE_UINT, device_state->state, AST_EVENT_IE_CACHABLE, AST_EVENT_IE_PLTYPE_UINT, device_state->cachable, AST_EVENT_IE_END); } return event; }