extern "C" void loop() { Actor::eventLoop(); if (WiFi.status() != WL_CONNECTED) { Serial.print("Connecting to "); Serial.print(WIFI_SSID); Serial.println("..."); WiFi.begin(WIFI_SSID, WIFI_PSWD); if (WiFi.waitForConnectResult() != WL_CONNECTED) { LOGF(" still connecting "); return; } LOGF("WiFi connected"); } if (WiFi.status() == WL_CONNECTED) { // if (wifi.connected()) { if (!client.connected()) { mdns.onWifiConnected(Header(INIT)); IPAddress server = mdns.query("mqtt"); client.set_server(server,1883); if (client.connect("wibo1", prefix + "system/alive", 1, 0, "false")) { client.publish(prefix + "system/alive", "true"); client.set_callback(callback); client.subscribe(subscribe_topic); Log.setOutput(udpLog); LOGF(" mqtt client connected "); } else { LOGF(" mqtt connect failed ") } } if (client.connected()) client.loop(); }
void loop() { ArduinoOTA.handle(); // -- MQTT connect if (!client.connected()) { error_path += thisDevicePath; error_path += "/"; error_path += "errors/"; error_path += thisDeviceName; if (client.connect(MQTT::Connect(thisDeviceName).set_will(error_path, "disconnected"))) { Serial.println("MQTT connected"); client.set_callback(callback); client.subscribe(MQTT::Subscribe() .add_topic("/deviceInfo/#") .add_topic("/global/#") .add_topic(subscribe_path) ); // notify persistence of device IP String persistence_ip_path = "/persistence/control/"; persistence_ip_path += thisDeviceName; persistence_ip_path += "/ip"; client.publish(MQTT::Publish(persistence_ip_path, local_ip_str).set_qos(2)); // ask persistence/control/device_name/chipID "request states" -- do you have any states with my device_name or chipID String persistence_path = "/persistence/control/"; persistence_path += thisDeviceName; persistence_path += "/"; persistence_path += chip_id; client.publish(MQTT::Publish(persistence_path, "request states").set_qos(2)); Serial.println("request states sent"); } } if (client.connected()) { client.loop(); } // -- NeoPixel continuous update for(int i=0; i<PixelCount; i++) { strip.SetPixelColor(i, RgbColor (redValue, greenValue, blueValue)); } strip.Show(); yield(); }
mqtt_result PubSub::loop() { mqtt_result result; if(!client.connected()) { long now = millis(); if(now - lastConnectionAttempt > 5000) { lastConnectionAttempt = now; mqtt_result connectResult = this->connect(); if(connectResult == E_MQTT_OK) { lastConnectionAttempt = 0; } result = connectResult; } else { result = E_MQTT_WAITING; } } else { result = E_MQTT_OK; client.loop(); } resolver.loop(); return result; }
void loop() { ArduinoOTA.handle(); // -- MQTT connect if (!client.connected()) { error_path += thisDevicePath; error_path += "/"; error_path += "errors/"; error_path += thisDeviceName; if (client.connect(MQTT::Connect(thisDeviceName).set_will(error_path, "disconnected"))) { Serial.println("MQTT connected"); client.set_callback(callback); client.subscribe(MQTT::Subscribe() .add_topic("/deviceInfo/#") .add_topic("/global/#") .add_topic(subscribe_path) ); // notify persistence of device IP String persistence_ip_path = "/persistence/control/"; persistence_ip_path += thisDeviceName; persistence_ip_path += "/ip"; client.publish(MQTT::Publish(persistence_ip_path, local_ip_str).set_qos(2)); // ask persistence/control/device_name/chipID "request states" -- do you have any states with my device_name or chipID String persistence_path = "/persistence/control/"; persistence_path += thisDeviceName; persistence_path += "/"; persistence_path += chip_id; client.publish(MQTT::Publish(persistence_path, "request states").set_qos(2)); Serial.println("request states sent"); } } if (client.connected()) { client.loop(); } /* // -- Device Request Response if (sendJSON) { buildDeviceJson(); // flag set to false inside function } */ /* // -- Confirm Messages if (sendConfirm) { client.publish(MQTT::Publish(confirmPath, confirmPayload).set_qos(2)); sendConfirm = false; } */ /* // -- NeoPixel updates if (neoPixelChange) { for(int i=0; i<PixelCount; i++) { strip.SetPixelColor(i, RgbColor (redValue, greenValue, blueValue)); } strip.Show(); neoPixelChange = false; } */ // -- NeoPixel continuous update for(int i=0; i<PixelCount; i++) { strip.SetPixelColor(i, RgbColor (redValue, greenValue, blueValue)); } strip.Show(); /* // -- NeoPixel Sunrise Alarm Code if (millis() - lastcheck > alarmcheck) { DateTime now = RTC.now(); lastcheck = millis(); if (alarmminute == now.minute() && alarmhour == now.hour()) { sunrise(4000); sunrise(400); sunrise(40); sunrise(40); sunrise(40); sunrise(40); sunrise(40); sunrise(20); sunrise(20); black(); } } */ // Do things every NTPLimit seconds if ( millis() - tick > NTPlimit) { tick = millis(); /* // -- get server and send NTP packet //get a random server from the pool WiFi.hostByName(ntpServerName, timeServerIP); sendNTPpacket(timeServerIP); // send an NTP packet to a time server // wait to see if a reply is available delay(1000); int cb = udp.parsePacket(); if (!cb) { Serial.println("no packet yet"); } else { //Serial.print("packet received, length="); //Serial.println(cb); udp.read(packetBuffer, NTP_PACKET_SIZE); // read the packet into the buffer unsigned long highWord = word(packetBuffer[40], packetBuffer[41]); unsigned long lowWord = word(packetBuffer[42], packetBuffer[43]); // combine the four bytes (two words) into a long integer // this is NTP time (seconds since Jan 1 1900): unsigned long secsSince1900 = highWord << 16 | lowWord; const unsigned long seventyYears = 2208988800UL; unsigned long epoch = secsSince1900 - seventyYears; int UTChour = (epoch % 86400L) / 3600; // (86400 equals secs per day) int UTCmin = (epoch % 3600) / 60; // (3600 equals secs per minute) //Serial.println(UTChour); Serial.print(year(epoch)); Serial.print('-'); Serial.print(month(epoch)); Serial.print('-'); Serial.println(day(epoch)); Serial.print("The UTC time is "); // UTC is the time at Greenwich Meridian (GMT) Serial.print(UTChour); Serial.print(':'); if ( ((epoch % 3600) / 60) < 10 ) { Serial.print('0'); } Serial.print(UTCmin); Serial.print(':'); if ( (epoch % 60) < 10 ) { Serial.print('0'); } Serial.println(epoch % 60); // print the second } */ /* // -- begin neropixel test delay(1000); Serial.println("Colors R, G, B, W..."); // set the colors, // if they don't match in order, you need to use NeoGrbFeature feature strip.SetPixelColor(0, RgbColor (128, 0, 0)); strip.SetPixelColor(1, green); strip.SetPixelColor(2, blue); strip.SetPixelColor(3, white); // the following line demonstrates rgbw color support // if the NeoPixels are rgbw types the following line will compile // if the NeoPixels are anything else, the following line will give an error //strip.SetPixelColor(3, RgbwColor(colorSaturation)); strip.Show(); delay(1000); Serial.println("Off ..."); // turn off the pixels strip.SetPixelColor(0, black); strip.SetPixelColor(1, black); strip.SetPixelColor(2, black); strip.SetPixelColor(3, black); strip.Show(); delay(1000); Serial.println("HSL Colors R, G, B, W..."); // set the colors, // if they don't match in order, you may need to use NeoGrbFeature feature strip.SetPixelColor(0, hslRed); strip.SetPixelColor(1, hslGreen); strip.SetPixelColor(2, hslBlue); strip.SetPixelColor(3, hslWhite); strip.Show(); delay(1000); Serial.println("Off again..."); // turn off the pixels strip.SetPixelColor(0, hslBlack); strip.SetPixelColor(1, hslBlack); strip.SetPixelColor(2, hslBlack); strip.SetPixelColor(3, hslBlack); strip.Show(); */ // -- neopixel sunrise test //sunrise(40); //offblack(); /* // -- print IP address Serial.println(WiFi.localIP()); //Serial.println(".."); */ } yield(); }