// Module for interfacing with an MQTT broker #include "esp_log.h" #include "lauxlib.h" #include "lmem.h" #include "lnodeaux.h" #include "module.h" #include "platform.h" #include "task/task.h" #include #include "mqtt_client.h" #define MQTT_MAX_HOST_LEN 64 #define MQTT_MAX_CLIENT_LEN 32 #define MQTT_MAX_USERNAME_LEN 32 #define MQTT_MAX_PASSWORD_LEN 65 #define MQTT_MAX_LWT_TOPIC 32 #define MQTT_MAX_LWT_MSG 128 #define MQTT_METATABLE "mqtt.mt" #define TAG "MQTT" // mqtt_context struct contains information to wrap a esp_mqtt client in lua typedef struct { esp_mqtt_client_handle_t client; // handle to mqtt client char* client_id; // mqtt client ID char* username; // mqtt username char* password; // mqtt password char* lwt_topic; // mqtt last will/testament topic char* lwt_msg; // mqtt last will message int lwt_qos; // mqtt LWT qos level int lwt_retain; // mqtt LWT retain flag int keepalive; // keepalive ping period in seconds int disable_clean_session; // Whether to not clean the session on reconnect union { struct { lua_ref_t on_connect_cb; // maps to "connect" event lua_ref_t on_message_cb; // maps to "message" event lua_ref_t on_offline_cb; // maps to "offline" event lua_ref_t connected_ok_cb; lua_ref_t connected_nok_cb; lua_ref_t published_ok_cb; lua_ref_t subscribed_ok_cb; lua_ref_t unsubscribed_ok_cb; lua_ref_t self; lua_ref_t cert_pem; lua_ref_t client_cert_pem; lua_ref_t client_key_pem; }; lua_ref_t lua_refs[12]; }; } mqtt_context_t; // event_handler_t is the function signature for all events typedef void (*event_handler_t)(lua_State* L, mqtt_context_t* mqtt_context, esp_mqtt_event_handle_t event); // eventnames contains a list of the events that can be set in lua // with client:on(eventName, function) // The order is important, as they map directly to callbacks // in the union/struct above const char* const eventnames[] = {"connect", "message", "offline", NULL}; // nodemcu task handlers for receiving events task_handle_t event_handler_task_id = 0; // event_clone makes a copy of the mqtt event received so we can pass it on // and the mqtt library can discard it. static esp_mqtt_event_handle_t event_clone(esp_mqtt_event_handle_t ev) { // allocate memory for the copy esp_mqtt_event_handle_t ev1 = (esp_mqtt_event_handle_t)malloc(sizeof(esp_mqtt_event_t)); ESP_LOGD(TAG, "event_clone(): event %p, event id %d, msg %d", ev, ev->event_id, ev->msg_id); // make a shallow copy: *ev1 = *ev; // if the event carries data, make also a copy of it: if (ev->data != NULL) { if (ev->data_len > 0) { ev1->data = malloc(ev->data_len + 1); // null-terminate the data, useful for debugging memcpy(ev1->data, ev->data, ev->data_len); ev1->data[ev1->data_len] = '\0'; ESP_LOGD(TAG, "event_clone():malloc: event %p, msg %d, data %p, num %d", ev1, ev1->msg_id, ev1->data, ev1->data_len); } else { ev1->data = NULL; } } // if the event carries a topic, make also a copy of it: if (ev->topic != NULL) { if (ev->topic_len > 0) { ev1->topic = malloc(ev->topic_len + 1); // null-terminate the data, useful for debugging memcpy(ev1->topic, ev->topic, ev->topic_len); ev1->topic[ev1->topic_len] = '\0'; ESP_LOGD(TAG, "event_clone():malloc: event %p, msg %d, topic %p, num %d", ev1, ev1->msg_id, ev1->topic, ev1->topic_len); } else { ev1->topic = NULL; } } return ev1; } // event_free deallocates all the memory associated with a cloned event static void event_free(esp_mqtt_event_handle_t ev) { if (ev->data != NULL) { ESP_LOGD(TAG, "event_free():free: event %p, msg %d, data %p", ev, ev->msg_id, ev->data); free(ev->data); } if (ev->topic != NULL) { ESP_LOGD(TAG, "event_free():free: event %p, msg %d, topic %p", ev, ev->msg_id, ev->topic); free(ev->topic); } free(ev); } // event_connected is run when the mqtt client connected static void event_connected(lua_State* L, mqtt_context_t* mqtt_context, esp_mqtt_event_handle_t event) { // if the user set a one-shot connected callback, execute it: if (luaX_valid_ref(mqtt_context->connected_ok_cb)) { lua_rawgeti(L, LUA_REGISTRYINDEX, mqtt_context->connected_ok_cb); // push the callback function reference to the stack luaX_push_weak_ref(L, mqtt_context->self); // push a reference to the client (first parameter) ESP_LOGD(TAG, "CB:connect: calling registered one-shot connect callback"); int res = luaL_pcallx(L, 1, 0); //call the connect callback: function(client) if (res != 0) ESP_LOGD(TAG, "CB:connect: Error when calling one-shot connect callback - (%d) %s", res, luaL_checkstring(L, -1)); //after connecting ok, we clear _both_ the one-shot callbacks: luaX_unset_ref(L, &mqtt_context->connected_ok_cb); luaX_unset_ref(L, &mqtt_context->connected_nok_cb); } // now we check for the standard connect callback registered with 'mqtt:on()' if (luaX_valid_ref(mqtt_context->on_connect_cb)) { ESP_LOGD(TAG, "CB:connect: calling registered standard connect callback"); lua_rawgeti(L, LUA_REGISTRYINDEX, mqtt_context->on_connect_cb); // push the callback function reference to the stack luaX_push_weak_ref(L, mqtt_context->self); // push a reference to the client (first parameter) int res = luaL_pcallx(L, 1, 0); //call the connect callback: function(client) if (res != 0) ESP_LOGD(TAG, "CB:connect: Error when calling connect callback - (%d) %s", res, luaL_checkstring(L, -1)); } } // event_disconnected is run after a connection to the MQTT broker breaks. static void event_disconnected(lua_State* L, mqtt_context_t* mqtt_context, esp_mqtt_event_handle_t event) { if (mqtt_context->client == NULL) { ESP_LOGD(TAG, "MQTT Client was NULL on a disconnect event"); } // destroy the wrapped mqtt_client object esp_mqtt_client_destroy(mqtt_context->client); mqtt_context->client = NULL; // if the user set a one-shot connect error callback, execute it: if (luaX_valid_ref(mqtt_context->connected_nok_cb)) { lua_rawgeti(L, LUA_REGISTRYINDEX, mqtt_context->connected_nok_cb); // push the callback function reference to the stack luaX_push_weak_ref(L, mqtt_context->self); // push a reference to the client (first parameter) lua_pushinteger(L, -6); // esp sdk mqtt lib does not provide reason codes. Push "-6" to be backward compatible with ESP8266 API ESP_LOGD(TAG, "CB:disconnect: calling registered one-shot disconnect callback"); int res = luaL_pcallx(L, 2, 0); //call the disconnect callback with 2 parameters: function(client, reason) if (res != 0) ESP_LOGD(TAG, "CB:disconnect: Error when calling one-shot disconnect callback - (%d) %s", res, luaL_checkstring(L, -1)); //after connecting ok, we clear _both_ the one-shot callbacks luaX_unset_ref(L, &mqtt_context->connected_ok_cb); luaX_unset_ref(L, &mqtt_context->connected_nok_cb); } // now we check for the standard offline callback registered with 'mqtt:on()' if (luaX_valid_ref(mqtt_context->on_offline_cb)) { ESP_LOGD(TAG, "CB:disconnect: calling registered standard on_offline_cb callback"); lua_rawgeti(L, LUA_REGISTRYINDEX, mqtt_context->on_offline_cb); // push the callback function reference to the stack luaX_push_weak_ref(L, mqtt_context->self); // push a reference to the client (first parameter) int res = luaL_pcallx(L, 1, 0); //call the offline callback: function(client) if (res != 0) ESP_LOGD(TAG, "CB:disconnect: Error when calling offline callback - (%d) %s", res, luaL_checkstring(L, -1)); } } // event_subscribed is called when the last subscribe call is successful static void event_subscribed(lua_State* L, mqtt_context_t* mqtt_context, esp_mqtt_event_handle_t event) { if (!luaX_valid_ref(mqtt_context->subscribed_ok_cb)) return; ESP_LOGD(TAG, "CB:subscribe: calling registered one-shot subscribe callback"); lua_rawgeti(L, LUA_REGISTRYINDEX, mqtt_context->subscribed_ok_cb); // push the function reference on the stack luaX_push_weak_ref(L, mqtt_context->self); // push the client object on the stack luaX_unset_ref(L, &mqtt_context->subscribed_ok_cb); // forget the callback since it is one-shot int res = luaL_pcallx(L, 1, 0); //call the connect callback with one parameter: function(client) if (res != 0) ESP_LOGD(TAG, "CB:subscribe: Error when calling one-shot subscribe callback - (%d) %s", res, luaL_checkstring(L, -1)); } //event_published is called when a publish operation completes static void event_published(lua_State* L, mqtt_context_t* mqtt_context, esp_mqtt_event_handle_t event) { if (!luaX_valid_ref(mqtt_context->published_ok_cb)) return; ESP_LOGD(TAG, "CB:publish: calling registered one-shot publish callback"); lua_rawgeti(L, LUA_REGISTRYINDEX, mqtt_context->published_ok_cb); // push the callback function reference to the stack luaX_push_weak_ref(L, mqtt_context->self); // push the client reference to the stack luaX_unset_ref(L, &mqtt_context->published_ok_cb); // forget this callback since it is one-shot int res = luaL_pcallx(L, 1, 0); //call the connect callback with 1 parameter: function(client) if (res != 0) ESP_LOGD(TAG, "CB:publish: Error when calling one-shot publish callback - (%d) %s", res, luaL_checkstring(L, -1)); } // event_unsubscribed is called when a subscription is successful static void event_unsubscribed(lua_State* L, mqtt_context_t* mqtt_context, esp_mqtt_event_handle_t event) { if (!luaX_valid_ref(mqtt_context->unsubscribed_ok_cb)) return; ESP_LOGD(TAG, "CB:unsubscribe: calling registered one-shot unsubscribe callback"); lua_rawgeti(L, LUA_REGISTRYINDEX, mqtt_context->unsubscribed_ok_cb); // push callback function reference on the stack luaX_push_weak_ref(L, mqtt_context->self); // push a reference to the client luaX_unset_ref(L, &mqtt_context->unsubscribed_ok_cb); // forget callback as it is one-shot int res = luaL_pcallx(L, 1, 0); //call the connect callback with one parameter: function(client) if (res != 0) ESP_LOGD(TAG, "CB:unsubscribe: Error when calling one-shot unsubscribe callback - (%d) %s", res, luaL_checkstring(L, -1)); } //event_data_received is called when data is received on a subscribed topic static void event_data_received(lua_State* L, mqtt_context_t* mqtt_context, esp_mqtt_event_handle_t event) { if (!luaX_valid_ref(mqtt_context->on_message_cb)) return; lua_rawgeti(L, LUA_REGISTRYINDEX, mqtt_context->on_message_cb); int numArg = 2; luaX_push_weak_ref(L, mqtt_context->self); lua_pushlstring(L, event->topic, event->topic_len); if (event->data != NULL) { lua_pushlstring(L, event->data, event->data_len); numArg++; } int res = luaL_pcallx(L, numArg, 0); //call the messagecallback if (res != 0) ESP_LOGD(TAG, "CB:data: Error when calling message callback - (%d) %s", res, luaL_checkstring(L, -1)); } // event_task_handler takes a nodemcu task message and dispatches it to the appropriate event_xxx callback above. static void event_task_handler(task_param_t param, task_prio_t prio) { // extract the event data out of the task param esp_mqtt_event_handle_t event = (esp_mqtt_event_handle_t)param; // recover the mqtt context from the event user_context field: mqtt_context_t* mqtt_context = (mqtt_context_t*)event->user_context; // Check if this event is about an object that is in the process of garbage collection: if (!luaX_valid_ref(mqtt_context->self)) { ESP_LOGW(TAG, "caught stray event: %d", event->event_id); // this can happen if the userdata object is dereferenced while attempting to connect goto task_handler_end; // free resources and abort } lua_State* L = lua_getstate(); //returns main Lua state if (L == NULL) { goto task_handler_end; // free resources and abort } ESP_LOGD(TAG, "event_task_handler: event_id: %d state %p, settings %p, stack top %d", event->event_id, L, mqtt_context, lua_gettop(L)); event_handler_t eventhandler = NULL; switch (event->event_id) { case MQTT_EVENT_DATA: eventhandler = event_data_received; break; case MQTT_EVENT_CONNECTED: eventhandler = event_connected; break; case MQTT_EVENT_DISCONNECTED: eventhandler = event_disconnected; break; case MQTT_EVENT_SUBSCRIBED: eventhandler = event_subscribed; break; case MQTT_EVENT_UNSUBSCRIBED: eventhandler = event_unsubscribed; break; case MQTT_EVENT_PUBLISHED: eventhandler = event_published; break; default: goto task_handler_end; // free resources and abort } int top = lua_gettop(L); // save the stack status to restore it later lua_checkstack(L, 5); // make sure there are at least 5 slots available // pin our object by putting a reference on the stack, // so it can't be garbage collected during user callback execution. luaX_push_weak_ref(L, mqtt_context->self); eventhandler(L, mqtt_context, event); lua_settop(L, top); // leave the stack as it was task_handler_end: event_free(event); // free the event copy memory } // mqtt_event_handler receives all events from the esp mqtt library and converts them // to a task message static esp_err_t mqtt_event_handler(esp_mqtt_event_handle_t event) { task_post_medium(event_handler_task_id, (task_param_t)event_clone(event)); return ESP_OK; } // Lua: on() // mqtt_on allows to set the callback associated to mqtt events static int mqtt_on(lua_State* L) { if (!lua_isfunction(L, 3)) //check whether we are passed a callback function return 0; int event = luaL_checkoption(L, 2, "message", eventnames); // map passed event name to an index in the eventnames array mqtt_context_t* mqtt_context = (mqtt_context_t*)luaL_checkudata(L, 1, MQTT_METATABLE); //retrieve the mqtt_context luaX_set_ref(L, 3, &mqtt_context->lua_refs[event]); // set the callback reference return 0; } // Lua: mqtt:connect(host[, port[, secure[, autoreconnect]]][, function(client)[, function(client, reason)]]) // mqtt_connect starts a connection with the mqtt broker static int mqtt_connect(lua_State* L) { mqtt_context_t* mqtt_context = (mqtt_context_t*)luaL_checkudata(L, 1, MQTT_METATABLE); //retrieve the mqtt context if (mqtt_context->client) { // destroy existing client. This disconnects an existing connection using this object esp_mqtt_client_destroy(mqtt_context->client); mqtt_context->client = NULL; } // initialize a mqtt config structure set to zero esp_mqtt_client_config_t config; memset(&config, 0, sizeof(esp_mqtt_client_config_t)); // process function parameters populating the mqtt config structure config.host = luaL_checkstring(L, 2); // set defaults: int secure = 0; int reconnect = 0; int port = 1883; int n = 3; const char * cert_pem = NULL; const char * client_cert_pem = NULL; const char * client_key_pem = NULL; if (lua_isnumber(L, n)) { port = luaL_checknumber(L, n); n++; } if (lua_isnumber(L, n)) { secure = !!luaL_checkinteger(L, n); n++; } else { if (lua_istable(L, n)) { secure = true; lua_getfield(L, n, "ca_cert"); if ((cert_pem = luaL_optstring(L, -1, NULL)) != NULL) { luaX_set_ref(L, -1, &mqtt_context->cert_pem); } lua_pop(L, 1); // lua_getfield(L, n, "client_cert"); if ((client_cert_pem = luaL_optstring(L, -1, NULL)) != NULL) { luaX_set_ref(L, -1, &mqtt_context->client_cert_pem); } lua_pop(L, 1); // lua_getfield(L, n, "client_key"); if ((client_key_pem = luaL_optstring(L, -1, NULL)) != NULL) { luaX_set_ref(L, -1, &mqtt_context->client_key_pem); } lua_pop(L, 1); // n++; } } if (lua_isnumber(L, n)) { reconnect = !!luaL_checkinteger(L, n); n++; } if (lua_isfunction(L, n)) { luaX_set_ref(L, n, &mqtt_context->connected_ok_cb); n++; } if (lua_isfunction(L, n)) { luaX_set_ref(L, n, &mqtt_context->connected_nok_cb); n++; } ESP_LOGD(TAG, "connect: mqtt_context*: %p", mqtt_context); config.user_context = mqtt_context; // store a pointer to our context in the mqtt client user context field // this will be useful to identify to which instance events belong to config.event_handle = mqtt_event_handler; // set the function that will be called by the mqtt client everytime something // happens config.client_id = mqtt_context->client_id; config.lwt_msg = mqtt_context->lwt_msg; config.lwt_topic = mqtt_context->lwt_topic; config.username = mqtt_context->username; config.password = mqtt_context->password; config.keepalive = mqtt_context->keepalive; config.disable_clean_session = mqtt_context->disable_clean_session; config.port = port; config.disable_auto_reconnect = (reconnect == 0); config.transport = secure ? MQTT_TRANSPORT_OVER_SSL : MQTT_TRANSPORT_OVER_TCP; config.cert_pem = cert_pem; config.client_cert_pem = client_cert_pem; config.client_key_pem = client_key_pem; // create a mqtt client instance mqtt_context->client = esp_mqtt_client_init(&config); if (mqtt_context->client == NULL) { luaL_error(L, "MQTT library failed to start"); return 0; } // actually start the mqtt client and connect esp_err_t err = esp_mqtt_client_start(mqtt_context->client); if (err != ESP_OK) { luaL_error(L, "Error starting mqtt client"); } lua_pushboolean(L, true); // return true (ok) return 1; } // Lua: mqtt:close() // mqtt_close terminates the current connection static int mqtt_close(lua_State* L) { mqtt_context_t* mqtt_context = (mqtt_context_t*)luaL_checkudata(L, 1, MQTT_METATABLE); if (mqtt_context->client == NULL) return 0; ESP_LOGD(TAG, "Closing MQTT client %p", mqtt_context->client); esp_mqtt_client_destroy(mqtt_context->client); mqtt_context->client = NULL; return 0; } // Lua: mqtt:lwt(topic, message[, qos[, retain]]) // mqtt_lwt sets last will / testament topic and message // must be called before connecting static int mqtt_lwt(lua_State* L) { mqtt_context_t* mqtt_context = (mqtt_context_t*)luaL_checkudata(L, 1, MQTT_METATABLE); // free previous topic and messasge, if any. luaX_free_string(L, mqtt_context->lwt_topic); luaX_free_string(L, mqtt_context->lwt_msg); // save a copy of topic and message to pass to the client // when connecting mqtt_context->lwt_topic = luaX_alloc_string(L, 2, MQTT_MAX_LWT_TOPIC); mqtt_context->lwt_msg = luaX_alloc_string(L, 3, MQTT_MAX_LWT_MSG); //process optional parameters int n = 4; if (lua_isnumber(L, n)) { mqtt_context->lwt_qos = (int)lua_tonumber(L, n); n++; } if (lua_isnumber(L, n)) { mqtt_context->lwt_retain = (int)lua_tonumber(L, n); n++; } ESP_LOGD(TAG, "Set LWT topic '%s', qos %d, retain %d", mqtt_context->lwt_topic, mqtt_context->lwt_qos, mqtt_context->lwt_retain); return 0; } //Lua: mqtt:publish(topic, payload, qos, retain[, function(client)]) // returns true on success, false otherwise // mqtt_publish publishes a message on the given topic static int mqtt_publish(lua_State* L) { mqtt_context_t* mqtt_context = (mqtt_context_t*)luaL_checkudata(L, 1, MQTT_METATABLE); esp_mqtt_client_handle_t client = mqtt_context->client; if (client == NULL) { lua_pushboolean(L, false); // return false (error) return 1; } const char* topic = luaL_checkstring(L, 2); size_t data_size; const char* data = luaL_checklstring(L, 3, &data_size); int qos = luaL_checkint(L, 4); int retain = luaL_checkint(L, 5); if (lua_isfunction(L, 6)) { // set one-shot on publish callback luaX_set_ref(L, 6, &mqtt_context->published_ok_cb); } ESP_LOGD(TAG, "MQTT publish client %p, topic %s, %d bytes", client, topic, data_size); int msg_id = esp_mqtt_client_publish(client, topic, data, data_size, qos, retain); lua_pushboolean(L, msg_id >= 0); // if msg_id < 0 there was an error. return 1; } // Lua: mqtt:subscribe(topic, qos[, function(client)]) OR mqtt:subscribe(table[, function(client)]) // returns true on success, false otherwise // mqtt_subscribe subscribes to the given topic static int mqtt_subscribe(lua_State* L) { mqtt_context_t* mqtt_context = (mqtt_context_t*)luaL_checkudata(L, 1, MQTT_METATABLE); esp_mqtt_client_handle_t client = mqtt_context->client; if (client == NULL) { lua_pushboolean(L, false); // return false (error) return 1; } const char* topic = luaL_checkstring(L, 2); int qos = luaL_checkint(L, 3); if (lua_isfunction(L, 4)) // if a callback is provided, set it. luaX_set_ref(L, 4, &mqtt_context->subscribed_ok_cb); ESP_LOGD(TAG, "MQTT subscribe client %p, topic %s", client, topic); esp_err_t err = esp_mqtt_client_subscribe(client, topic, qos); lua_pushboolean(L, err == ESP_OK); return 1; // one value returned, true on success, false on error. } // Lua: mqtt:unsubscribe(topic[, function(client)]) // TODO: accept also mqtt:unsubscribe(table[, function(client)]) // returns true on success, false otherwise // mqtt_unsubscribe unsubscribes from the given topic static int mqtt_unsubscribe(lua_State* L) { mqtt_context_t* mqtt_context = (mqtt_context_t*)luaL_checkudata(L, 1, MQTT_METATABLE); esp_mqtt_client_handle_t client = mqtt_context->client; if (client == NULL) { lua_pushboolean(L, false); // return false (error) return 1; } const char* topic = luaL_checkstring(L, 2); if (lua_isfunction(L, 3)) luaX_set_ref(L, 3, &mqtt_context->unsubscribed_ok_cb); ESP_LOGD(TAG, "MQTT unsubscribe client %p, topic %s", client, topic); esp_err_t err = esp_mqtt_client_unsubscribe(client, topic); lua_pushboolean(L, err == ESP_OK); return 1; // return 1 value: true OK, false error. } // mqtt_deleted is called on garbage collection static int mqtt_delete(lua_State* L) { mqtt_context_t* mqtt_context = (mqtt_context_t*)luaL_checkudata(L, 1, MQTT_METATABLE); // forget all callbacks for (int i = 0; i < sizeof(mqtt_context->lua_refs) / sizeof(lua_ref_t); i++) { luaX_unset_ref(L, &mqtt_context->lua_refs[i]); } // if there is a client active, shut it down. if (mqtt_context->client != NULL) { ESP_LOGD(TAG, "stopping MQTT client %p;", mqtt_context); // destroy the client. This is a blocking call. // If a connection request was ongoing this will block and // a disconnect callback could be fired before coming back here. esp_mqtt_client_destroy(mqtt_context->client); } // free all dynamic strings luaX_free_string(L, mqtt_context->client_id); luaX_free_string(L, mqtt_context->username); luaX_free_string(L, mqtt_context->password); luaX_free_string(L, mqtt_context->lwt_msg); luaX_free_string(L, mqtt_context->lwt_topic); ESP_LOGD(TAG, "MQTT client garbage collected"); return 0; } // Lua: mqtt.Client(clientid, keepalive[, username, password, cleansession]) // mqtt_new creates a new instance of our mqtt userdata lua object static int mqtt_new(lua_State* L) { //create a new lua userdata object and initialize to 0. mqtt_context_t* mqtt_context = (mqtt_context_t*)lua_newuserdata(L, sizeof(mqtt_context_t)); memset(mqtt_context, 0, sizeof(mqtt_context_t)); // initialize all callbacks to LUA_NOREF, indicating they're unset. for (int i = 0; i < sizeof(mqtt_context->lua_refs) / sizeof(lua_ref_t); i++) { mqtt_context->lua_refs[i] = LUA_NOREF; } // keep a weak reference to our userdata object so we can pass it as a parameter to user callbacks lua_pushvalue(L, -1); mqtt_context->self = luaX_weak_ref(L); // store the parameters passed: mqtt_context->client_id = luaX_alloc_string(L, 1, MQTT_MAX_CLIENT_LEN); ESP_LOGD(TAG, "MQTT client id %s", mqtt_context->client_id); mqtt_context->keepalive = luaL_checkinteger(L, 2); int n = 2; if (lua_isstring(L, 3)) { mqtt_context->username = luaX_alloc_string(L, 3, MQTT_MAX_USERNAME_LEN); n++; } if (lua_isstring(L, 4)) { mqtt_context->password = luaX_alloc_string(L, 4, MQTT_MAX_PASSWORD_LEN); n++; } if (lua_isnumber(L, 5)) { mqtt_context->disable_clean_session = (luaL_checknumber(L, 5) == 0); n++; } luaL_getmetatable(L, MQTT_METATABLE); lua_setmetatable(L, -2); if (event_handler_task_id == 0) { // if this is the first time, create nodemcu tasks for every event type event_handler_task_id = task_get_id(event_task_handler); } return 1; //one object returned, the mqtt context wrapped in a lua userdata object } // map client methods to functions: LROT_BEGIN(mqtt_metatable, NULL, 0) LROT_FUNCENTRY(__gc, mqtt_delete) LROT_TABENTRY(__index, mqtt_metatable) LROT_FUNCENTRY(connect, mqtt_connect) LROT_FUNCENTRY(close, mqtt_close) LROT_FUNCENTRY(lwt, mqtt_lwt) LROT_FUNCENTRY(publish, mqtt_publish) LROT_FUNCENTRY(subscribe, mqtt_subscribe) LROT_FUNCENTRY(unsubscribe, mqtt_unsubscribe) LROT_FUNCENTRY(on, mqtt_on) LROT_END(mqtt_metatable, NULL, 0) // Module function map LROT_BEGIN(mqtt, NULL, 0) LROT_FUNCENTRY(Client, mqtt_new) LROT_END(mqtt, NULL, 0) int luaopen_mqtt(lua_State* L) { luaL_rometatable(L, MQTT_METATABLE, LROT_TABLEREF(mqtt_metatable)); // create metatable for mqtt return 0; } NODEMCU_MODULE(MQTT, "mqtt", mqtt, luaopen_mqtt);