/* xdrv_20_hue.ino - Philips Hue support for Tasmota Copyright (C) 2020 Heiko Krupp and Theo Arends This program is free software: you can redistribute it and/or modify it under the terms of the GNU General Public License as published by the Free Software Foundation, either version 3 of the License, or (at your option) any later version. This program is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License for more details. You should have received a copy of the GNU General Public License along with this program. If not, see . */ #if defined(USE_WEBSERVER) && defined(USE_EMULATION) && defined(USE_EMULATION_HUE) && defined(USE_LIGHT) /*********************************************************************************************\ * Philips Hue bridge emulation * * Hue Bridge UPNP support routines * Need to send 3 response packets with varying ST and USN * * Using Espressif Inc Mac Address of 5C:CF:7F:00:00:00 * Philips Lighting is 00:17:88:00:00:00 \*********************************************************************************************/ #define XDRV_20 20 const char HUE_RESPONSE[] PROGMEM = "HTTP/1.1 200 OK\r\n" "HOST: 239.255.255.250:1900\r\n" "CACHE-CONTROL: max-age=100\r\n" "EXT:\r\n" "LOCATION: http://%s:80/description.xml\r\n" "SERVER: Linux/3.14.0 UPnP/1.0 IpBridge/1.24.0\r\n" // was 1.17 "hue-bridgeid: %s\r\n"; const char HUE_ST1[] PROGMEM = "ST: upnp:rootdevice\r\n" "USN: uuid:%s::upnp:rootdevice\r\n" "\r\n"; const char HUE_ST2[] PROGMEM = "ST: uuid:%s\r\n" "USN: uuid:%s\r\n" "\r\n"; const char HUE_ST3[] PROGMEM = "ST: urn:schemas-upnp-org:device:basic:1\r\n" "USN: uuid:%s\r\n" "\r\n"; String HueBridgeId(void) { String temp = WiFi.macAddress(); temp.replace(":", ""); String bridgeid = temp.substring(0, 6); bridgeid += "FFFE"; bridgeid += temp.substring(6); return bridgeid; // 5CCF7FFFFE139F3D } String HueSerialnumber(void) { String serial = WiFi.macAddress(); serial.replace(":", ""); serial.toLowerCase(); return serial; // 5ccf7f139f3d } String HueUuid(void) { String uuid = F("f6543a06-da50-11ba-8d8f-"); uuid += HueSerialnumber(); return uuid; // f6543a06-da50-11ba-8d8f-5ccf7f139f3d } void HueRespondToMSearch(void) { char message[TOPSZ]; TickerMSearch.detach(); if (PortUdp.beginPacket(udp_remote_ip, udp_remote_port)) { char response[320]; snprintf_P(response, sizeof(response), HUE_RESPONSE, WiFi.localIP().toString().c_str(), HueBridgeId().c_str()); int len = strlen(response); String uuid = HueUuid(); snprintf_P(response + len, sizeof(response) - len, HUE_ST1, uuid.c_str()); PortUdp.write(response); PortUdp.endPacket(); snprintf_P(response + len, sizeof(response) - len, HUE_ST2, uuid.c_str(), uuid.c_str()); PortUdp.write(response); PortUdp.endPacket(); snprintf_P(response + len, sizeof(response) - len, HUE_ST3, uuid.c_str()); PortUdp.write(response); PortUdp.endPacket(); snprintf_P(message, sizeof(message), PSTR(D_3_RESPONSE_PACKETS_SENT)); } else { snprintf_P(message, sizeof(message), PSTR(D_FAILED_TO_SEND_RESPONSE)); } // Do not use AddLog_P2 here (interrupt routine) if syslog or mqttlog is enabled. UDP/TCP will force exception 9 PrepLog_P2(LOG_LEVEL_DEBUG, PSTR(D_LOG_UPNP D_HUE " %s " D_TO " %s:%d"), message, udp_remote_ip.toString().c_str(), udp_remote_port); udp_response_mutex = false; } /*********************************************************************************************\ * Hue web server additions \*********************************************************************************************/ const char HUE_DESCRIPTION_XML[] PROGMEM = "" "" "" "1" "0" "" // "http://{x1/" "http://{x1:80/" "" "urn:schemas-upnp-org:device:Basic:1" "Amazon-Echo-HA-Bridge ({x1)" // "Philips hue ({x1)" "Royal Philips Electronics" "http://www.philips.com" "Philips hue Personal Wireless Lighting" "Philips hue bridge 2012" "929000226503" "{x3" "uuid:{x2" "" "\r\n" "\r\n"; const char HUE_LIGHTS_STATUS_JSON1_SUFFIX[] PROGMEM = "%s\"alert\":\"none\"," "\"effect\":\"none\"," "\"reachable\":true}"; const char HUE_LIGHTS_STATUS_JSON2[] PROGMEM = ",\"type\":\"Extended color light\"," "\"name\":\"%s\"," "\"modelid\":\"LCT007\"," "\"uniqueid\":\"%s\"," "\"swversion\":\"5.50.1.19085\"}"; const char HUE_GROUP0_STATUS_JSON[] PROGMEM = "{\"name\":\"Group 0\"," "\"lights\":[{l1]," "\"type\":\"LightGroup\"," "\"action\":"; // "\"scene\":\"none\","; const char HueConfigResponse_JSON[] PROGMEM = "{\"name\":\"Philips hue\"," "\"mac\":\"{ma\"," "\"dhcp\":true," "\"ipaddress\":\"{ip\"," "\"netmask\":\"{ms\"," "\"gateway\":\"{gw\"," "\"proxyaddress\":\"none\"," "\"proxyport\":0," "\"bridgeid\":\"{br\"," "\"UTC\":\"{dt\"," "\"whitelist\":{\"{id\":{" "\"last use date\":\"{dt\"," "\"create date\":\"{dt\"," "\"name\":\"Remote\"}}," "\"swversion\":\"01041302\"," "\"apiversion\":\"1.17.0\"," "\"swupdate\":{\"updatestate\":0,\"url\":\"\",\"text\":\"\",\"notify\": false}," "\"linkbutton\":false," "\"portalservices\":false" "}"; const char HUE_ERROR_JSON[] PROGMEM = "[{\"error\":{\"type\":901,\"address\":\"/\",\"description\":\"Internal Error\"}}]"; /********************************************************************************************/ String GetHueDeviceId(uint16_t id) { String deviceid = WiFi.macAddress(); deviceid += F(":00:11-"); deviceid += String(id); deviceid.toLowerCase(); return deviceid; // 5c:cf:7f:13:9f:3d:00:11-1 } String GetHueUserId(void) { char userid[7]; snprintf_P(userid, sizeof(userid), PSTR("%03x"), ESP.getChipId()); return String(userid); } void HandleUpnpSetupHue(void) { AddLog_P(LOG_LEVEL_DEBUG, S_LOG_HTTP, PSTR(D_HUE_BRIDGE_SETUP)); String description_xml = FPSTR(HUE_DESCRIPTION_XML); description_xml.replace("{x1", WiFi.localIP().toString()); description_xml.replace("{x2", HueUuid()); description_xml.replace("{x3", HueSerialnumber()); WSSend(200, CT_XML, description_xml); } void HueNotImplemented(String *path) { AddLog_P2(LOG_LEVEL_DEBUG_MORE, PSTR(D_LOG_HTTP D_HUE_API_NOT_IMPLEMENTED " (%s)"), path->c_str()); WSSend(200, CT_JSON, "{}"); } void HueConfigResponse(String *response) { *response += FPSTR(HueConfigResponse_JSON); response->replace("{ma", WiFi.macAddress()); response->replace("{ip", WiFi.localIP().toString()); response->replace("{ms", WiFi.subnetMask().toString()); response->replace("{gw", WiFi.gatewayIP().toString()); response->replace("{br", HueBridgeId()); response->replace("{dt", GetDateAndTime(DT_UTC)); response->replace("{id", GetHueUserId()); } void HueConfig(String *path) { String response = ""; HueConfigResponse(&response); WSSend(200, CT_JSON, response); } // device is forced to CT mode instead of HSB // only makes sense for LST_COLDWARM, LST_RGBW and LST_RGBCW bool g_gotct = false; // store previously set values from the Alexa app // it allows to correct slight deviations from value set by the app // The Alexa app is very sensitive to exact values uint16_t prev_hue = 0; uint8_t prev_sat = 0; uint8_t prev_bri = 254; uint16_t prev_ct = 254; char prev_x_str[24] = "\0"; // store previously set xy by Alexa app char prev_y_str[24] = "\0"; uint8_t getLocalLightSubtype(uint8_t device) { if (light_type) { if (device >= Light.device) { if (Settings.flag3.pwm_multi_channels) { // SetOption68 - Enable multi-channels PWM instead of Color PWM return LST_SINGLE; // If SetOption68, each channel acts like a dimmer } else { return Light.subtype; // the actual light } } else { return LST_NONE; // relays } } else { return LST_NONE; } } void HueLightStatus1(uint8_t device, String *response) { uint16_t ct = 0; uint8_t color_mode; String light_status = ""; uint16_t hue = 0; uint8_t sat = 0; uint8_t bri = 254; uint32_t echo_gen = findEchoGeneration(); // 1 for 1st gen =+ Echo Dot 2nd gen, 2 for 2nd gen and above // local_light_subtype simulates the Light.subtype for 'device' // For relays LST_NONE, for dimmers LST_SINGLE uint8_t local_light_subtype = getLocalLightSubtype(device); bri = LightGetBri(device); // get Dimmer corrected with SetOption68 if (bri > 254) bri = 254; // Philips Hue bri is between 1 and 254 if (bri < 1) bri = 1; #ifdef USE_SHUTTER if (ShutterState(device)) { bri = (float)((Settings.shutter_options[device-1] & 1) ? 100 - Settings.shutter_position[device-1] : Settings.shutter_position[device-1]) / 100; } #endif if (light_type) { light_state.getHSB(&hue, &sat, nullptr); if ((bri > prev_bri ? bri - prev_bri : prev_bri - bri) < 1) bri = prev_bri; if (sat > 254) sat = 254; // Philips Hue only accepts 254 as max hue if ((sat > prev_sat ? sat - prev_sat : prev_sat - sat) < 1) { sat = prev_sat; } else { // if sat was changed outside of Alexa, reset xy prev_x_str[0] = prev_y_str[0] = 0; } hue = changeUIntScale(hue, 0, 359, 0, 65535); if ((hue > prev_hue ? hue - prev_hue : prev_hue - hue) < 400) { hue = prev_hue; } else { // if hue was changed outside of Alexa, reset xy prev_x_str[0] = prev_y_str[0] = 0; } color_mode = light_state.getColorMode(); ct = light_state.getCT(); if (LCM_RGB == color_mode) { g_gotct = false; } if (LCM_CT == color_mode) { g_gotct = true; } // If LCM_BOTH == color_mode, leave g_gotct unchanged // re-adjust ct if close to command value if ((ct > prev_ct ? ct - prev_ct : prev_ct - ct) < 1) ct = prev_ct; //AddLog_P2(LOG_LEVEL_DEBUG_MORE, PSTR("HueLightStatus1 HSB (%d, %d, %d) Prev_HSB (%d, %d, %d)"), // hue, sat, bri, prev_hue, prev_sat, prev_bri); } const size_t buf_size = 256; char * buf = (char*) malloc(buf_size); // temp buffer for strings, avoid stack snprintf_P(buf, buf_size, PSTR("{\"on\":%s,"), (power & (1 << (device-1))) ? "true" : "false"); // Brightness for all devices with PWM if ((1 == echo_gen) || (LST_SINGLE <= local_light_subtype)) { // force dimmer for 1st gen Echo snprintf_P(buf, buf_size, PSTR("%s\"bri\":%d,"), buf, bri); } if (LST_COLDWARM <= local_light_subtype) { snprintf_P(buf, buf_size, PSTR("%s\"colormode\":\"%s\","), buf, g_gotct ? "ct" : "hs"); } if (LST_RGB <= local_light_subtype) { // colors if (prev_x_str[0] && prev_y_str[0]) { snprintf_P(buf, buf_size, PSTR("%s\"xy\":[%s,%s],"), buf, prev_x_str, prev_y_str); } else { float x, y; light_state.getXY(&x, &y); snprintf_P(buf, buf_size, PSTR("%s\"xy\":[%s,%s],"), buf, String(x, 5).c_str(), String(y, 5).c_str()); } snprintf_P(buf, buf_size, PSTR("%s\"hue\":%d,\"sat\":%d,"), buf, hue, sat); } if (LST_COLDWARM == local_light_subtype || LST_RGBW <= local_light_subtype) { // white temp snprintf_P(buf, buf_size, PSTR("%s\"ct\":%d,"), buf, ct > 0 ? ct : 284); } snprintf_P(buf, buf_size, HUE_LIGHTS_STATUS_JSON1_SUFFIX, buf); *response += buf; free(buf); } // Check whether this device should be reported to Alexa or considered hidden. // Any device whose friendly name start with "$" is considered hidden bool HueActive(uint8_t device) { if (device > MAX_FRIENDLYNAMES) { device = MAX_FRIENDLYNAMES; } return '$' != *SettingsText(SET_FRIENDLYNAME1 +device -1); } void HueLightStatus2(uint8_t device, String *response) { const size_t buf_size = 192; char * buf = (char*) malloc(buf_size); const size_t max_name_len = 32; char fname[max_name_len + 1]; strlcpy(fname, SettingsText(device <= MAX_FRIENDLYNAMES ? SET_FRIENDLYNAME1 + device -1 : SET_FRIENDLYNAME1 + MAX_FRIENDLYNAMES -1), max_name_len + 1); if (device > MAX_FRIENDLYNAMES) { uint32_t fname_len = strlen(fname); if (fname_len > max_name_len - 2) { fname_len = max_name_len - 2; } fname[fname_len++] = '-'; if (device - MAX_FRIENDLYNAMES < 10) { fname[fname_len++] = '0' + device - MAX_FRIENDLYNAMES; } else { fname[fname_len++] = 'A' + device - MAX_FRIENDLYNAMES - 10; } fname[fname_len] = 0x00; } snprintf_P(buf, buf_size, HUE_LIGHTS_STATUS_JSON2, fname, GetHueDeviceId(device).c_str()); *response += buf; free(buf); } // generate a unique lightId mixing local IP address and device number // it is limited to 32 devices. // last 24 bits of Mac address + 4 bits of local light + high bit for relays 16-31, relay 32 is mapped to 0 // Zigbee extension: bit 29 = 1, and last 16 bits = short address of Zigbee device #ifndef USE_ZIGBEE uint32_t EncodeLightId(uint8_t relay_id) #else uint32_t EncodeLightId(uint8_t relay_id, uint16_t z_shortaddr = 0) #endif { uint8_t mac[6]; WiFi.macAddress(mac); uint32_t id = (mac[3] << 20) | (mac[4] << 12) | (mac[5] << 4); if (relay_id >= 32) { // for Relay #32, we encode as 0 relay_id = 0; } if (relay_id > 15) { id |= (1 << 28); } id |= (relay_id & 0xF); #ifdef USE_ZIGBEE if ((z_shortaddr) && (!relay_id)) { // fror Zigbee devices, we have relay_id == 0 and shortaddr != 0 id = (1 << 29) | z_shortaddr; } #endif return id; } // get hue_id and decode the relay_id // 4 LSB decode to 1-15, if bit 28 is set, it encodes 16-31, if 0 then 32 // Zigbee: // If the Id encodes a Zigbee device (meaning bit 29 is set) // it returns 0 and sets the 'shortaddr' to the device short address #ifndef USE_ZIGBEE uint32_t DecodeLightId(uint32_t hue_id) #else uint32_t DecodeLightId(uint32_t hue_id, uint16_t * shortaddr = nullptr) #endif { uint8_t relay_id = hue_id & 0xF; if (hue_id & (1 << 28)) { // check if bit 25 is set, if so we have relay_id += 16; } if (0 == relay_id) { // special value 0 is actually relay #32 relay_id = 32; } #ifdef USE_ZIGBEE if (hue_id & (1 << 29)) { // this is actually a Zigbee ID if (shortaddr) { *shortaddr = hue_id & 0xFFFF; } relay_id = 0; } #endif // USE_ZIGBEE return relay_id; } static const char * FIRST_GEN_UA[] = { // list of User-Agents signature "AEOBC", // Echo Dot 2ng Generation }; // Check if the Echo device is of 1st generation, which triggers different results uint32_t findEchoGeneration(void) { // result is 1 for 1st gen, 2 for 2nd gen and further String user_agent = WebServer->header("User-Agent"); uint32_t gen = 2; for (uint32_t i = 0; i < sizeof(FIRST_GEN_UA)/sizeof(char*); i++) { if (user_agent.indexOf(FIRST_GEN_UA[i]) >= 0) { // found gen = 1; break; } } if (0 == user_agent.length()) { gen = 1; // if no user-agent, also revert to gen v1 } AddLog_P2(LOG_LEVEL_DEBUG_MORE, D_LOG_HTTP D_HUE " User-Agent: %s, gen=%d", user_agent.c_str(), gen); // Header collection is set in xdrv_01_webserver.ino, in StartWebserver() return gen; } void HueGlobalConfig(String *path) { String response; path->remove(0,1); // cut leading / to get response = F("{\"lights\":{"); bool appending = false; // do we need to add a comma to append CheckHue(&response, appending); #ifdef USE_ZIGBEE ZigbeeCheckHue(&response, appending); #endif // USE_ZIGBEE response += F("},\"groups\":{},\"schedules\":{},\"config\":"); HueConfigResponse(&response); response += "}"; WSSend(200, CT_JSON, response); } void HueAuthentication(String *path) { char response[38]; snprintf_P(response, sizeof(response), PSTR("[{\"success\":{\"username\":\"%s\"}}]"), GetHueUserId().c_str()); WSSend(200, CT_JSON, response); AddLog_P2(LOG_LEVEL_DEBUG_MORE, PSTR(D_LOG_HTTP D_HUE " Authentication Result (%s)"), response); } // refactored to remove code duplicates void CheckHue(String * response, bool &appending) { uint8_t maxhue = (devices_present > MAX_HUE_DEVICES) ? MAX_HUE_DEVICES : devices_present; for (uint32_t i = 1; i <= maxhue; i++) { if (HueActive(i)) { if (appending) { *response += ","; } *response += "\""; *response += EncodeLightId(i); *response += F("\":{\"state\":"); HueLightStatus1(i, response); HueLightStatus2(i, response); appending = true; } } } void HueLightsCommand(uint8_t device, uint32_t device_id, String &response) { uint16_t tmp = 0; uint16_t hue = 0; uint8_t sat = 0; uint8_t bri = 254; uint16_t ct = 0; bool on = false; bool resp = false; // is the response non null (add comma between parameters) bool change = false; // need to change a parameter to the light uint8_t local_light_subtype = getLocalLightSubtype(device); // get the subtype for this device const size_t buf_size = 100; char * buf = (char*) malloc(buf_size); if (WebServer->args()) { response = "["; StaticJsonBuffer<300> jsonBuffer; JsonObject &hue_json = jsonBuffer.parseObject(WebServer->arg((WebServer->args())-1)); if (hue_json.containsKey("on")) { on = hue_json["on"]; snprintf_P(buf, buf_size, PSTR("{\"success\":{\"/lights/%d/state/on\":%s}}"), device_id, on ? "true" : "false"); #ifdef USE_SHUTTER if (ShutterState(device)) { if (!change) { bri = on ? 1.0f : 0.0f; // when bri is not part of this request then calculate it change = true; resp = true; response += buf; // actually publish the state } } else { #endif switch(on) { case false : ExecuteCommandPower(device, POWER_OFF, SRC_HUE); break; case true : ExecuteCommandPower(device, POWER_ON, SRC_HUE); break; } response += buf; resp = true; #ifdef USE_SHUTTER } #endif // USE_SHUTTER } if (light_type && (local_light_subtype >= LST_SINGLE)) { if (!Settings.flag3.pwm_multi_channels) { // SetOption68 - Enable multi-channels PWM instead of Color PWM light_state.getHSB(&hue, &sat, nullptr); bri = light_state.getBri(); // get the combined bri for CT and RGB, not only the RGB one ct = light_state.getCT(); uint8_t color_mode = light_state.getColorMode(); if (LCM_RGB == color_mode) { g_gotct = false; } if (LCM_CT == color_mode) { g_gotct = true; } // If LCM_BOTH == color_mode, leave g_gotct unchanged } else { // treat each channel as simple dimmer bri = LightGetBri(device); } } prev_x_str[0] = prev_y_str[0] = 0; // reset xy string if (hue_json.containsKey("bri")) { // Brightness is a scale from 1 (the minimum the light is capable of) to 254 (the maximum). Note: a brightness of 1 is not off. bri = hue_json["bri"]; prev_bri = bri; // store command value if (resp) { response += ","; } snprintf_P(buf, buf_size, PSTR("{\"success\":{\"/lights/%d/state/%s\":%d}}"), device_id, "bri", bri); response += buf; if (LST_SINGLE <= Light.subtype) { // extend bri value if set to max if (254 <= bri) { bri = 255; } change = true; } resp = true; } // handle xy before Hue/Sat // If the request contains both XY and HS, we wan't to give priority to HS if (hue_json.containsKey("xy")) { float x = hue_json["xy"][0]; float y = hue_json["xy"][1]; const String &x_str = hue_json["xy"][0]; const String &y_str = hue_json["xy"][1]; x_str.toCharArray(prev_x_str, sizeof(prev_x_str)); y_str.toCharArray(prev_y_str, sizeof(prev_y_str)); uint8_t rr,gg,bb; LightStateClass::XyToRgb(x, y, &rr, &gg, &bb); LightStateClass::RgbToHsb(rr, gg, bb, &hue, &sat, nullptr); prev_hue = changeUIntScale(hue, 0, 359, 0, 65535); // calculate back prev_hue prev_sat = (sat > 254 ? 254 : sat); //AddLog_P2(LOG_LEVEL_DEBUG_MORE, "XY RGB (%d %d %d) HS (%d %d)", rr,gg,bb,hue,sat); if (resp) { response += ","; } snprintf_P(buf, buf_size, PSTR("{\"success\":{\"/lights/%d/state/xy\":[%s,%s]}}"), device_id, prev_x_str, prev_y_str); response += buf; g_gotct = false; resp = true; change = true; } if (hue_json.containsKey("hue")) { // The hue value is a wrapping value between 0 and 65535. Both 0 and 65535 are red, 25500 is green and 46920 is blue. hue = hue_json["hue"]; prev_hue = hue; if (resp) { response += ","; } snprintf_P(buf, buf_size, PSTR("{\"success\":{\"/lights/%d/state/%s\":%d}}"), device_id, "hue", hue); response += buf; if (LST_RGB <= Light.subtype) { // change range from 0..65535 to 0..359 hue = changeUIntScale(hue, 0, 65535, 0, 359); g_gotct = false; change = true; } resp = true; } if (hue_json.containsKey("sat")) { // Saturation of the light. 254 is the most saturated (colored) and 0 is the least saturated (white). sat = hue_json["sat"]; prev_sat = sat; // store command value if (resp) { response += ","; } snprintf_P(buf, buf_size, PSTR("{\"success\":{\"/lights/%d/state/%s\":%d}}"), device_id, "sat", sat); response += buf; if (LST_RGB <= Light.subtype) { // extend sat value if set to max if (254 <= sat) { sat = 255; } g_gotct = false; change = true; } resp = true; } if (hue_json.containsKey("ct")) { // Color temperature 153 (Cold) to 500 (Warm) ct = hue_json["ct"]; prev_ct = ct; // store commande value if (resp) { response += ","; } snprintf_P(buf, buf_size, PSTR("{\"success\":{\"/lights/%d/state/%s\":%d}}"), device_id, "ct", ct); response += buf; if ((LST_COLDWARM == Light.subtype) || (LST_RGBW <= Light.subtype)) { g_gotct = true; change = true; } resp = true; } if (change) { #ifdef USE_SHUTTER if (ShutterState(device)) { AddLog_P2(LOG_LEVEL_DEBUG, PSTR("Settings.shutter_invert: %d"), Settings.shutter_options[device-1] & 1); ShutterSetPosition(device, bri * 100.0f ); } else #endif if (light_type && (local_light_subtype > LST_NONE)) { // not relay if (!Settings.flag3.pwm_multi_channels) { // SetOption68 - Enable multi-channels PWM instead of Color PWM if (g_gotct) { light_controller.changeCTB(ct, bri); } else { light_controller.changeHSB(hue, sat, bri); } LightPreparePower(); } else { // SetOption68 On, each channel is a dimmer LightSetBri(device, bri); } if (LST_COLDWARM <= local_light_subtype) { MqttPublishPrefixTopic_P(RESULT_OR_STAT, PSTR(D_CMND_COLOR)); } else { MqttPublishPrefixTopic_P(RESULT_OR_STAT, PSTR(D_CMND_DIMMER)); } XdrvRulesProcess(); } change = false; } response += "]"; if (2 == response.length()) { response = FPSTR(HUE_ERROR_JSON); } } else { response = FPSTR(HUE_ERROR_JSON); } free(buf); } void HueLights(String *path) { /* * http://tasmota/api/username/lights/1/state?1={"on":true,"hue":56100,"sat":254,"bri":254,"alert":"none","transitiontime":40} */ String response; int code = 200; uint8_t device = 1; uint32_t device_id; // the raw device_id used by Hue emulation uint8_t maxhue = (devices_present > MAX_HUE_DEVICES) ? MAX_HUE_DEVICES : devices_present; path->remove(0,path->indexOf("/lights")); // Remove until /lights if (path->endsWith("/lights")) { // Got /lights response = "{"; bool appending = false; CheckHue(&response, appending); #ifdef USE_ZIGBEE ZigbeeCheckHue(&response, appending); #endif // USE_ZIGBEE #ifdef USE_SCRIPT_HUE Script_Check_Hue(&response); #endif response += "}"; } else if (path->endsWith("/state")) { // Got ID/state path->remove(0,8); // Remove /lights/ path->remove(path->indexOf("/state")); // Remove /state device_id = atoi(path->c_str()); device = DecodeLightId(device_id); #ifdef USE_ZIGBEE uint16_t shortaddr; device = DecodeLightId(device_id, &shortaddr); if (shortaddr) { return ZigbeeHandleHue(shortaddr, device_id, response); } #endif // USE_ZIGBEE #ifdef USE_SCRIPT_HUE if (device > devices_present) { return Script_Handle_Hue(path); } #endif if ((device >= 1) || (device <= maxhue)) { HueLightsCommand(device, device_id, response); } } else if(path->indexOf("/lights/") >= 0) { // Got /lights/ID AddLog_P2(LOG_LEVEL_DEBUG_MORE, "/lights path=%s", path->c_str()); path->remove(0,8); // Remove /lights/ device_id = atoi(path->c_str()); device = DecodeLightId(device_id); #ifdef USE_ZIGBEE uint16_t shortaddr; device = DecodeLightId(device_id, &shortaddr); if (shortaddr) { ZigbeeHueStatus(&response, shortaddr); goto exit; } #endif // USE_ZIGBEE #ifdef USE_SCRIPT_HUE if (device > devices_present) { Script_HueStatus(&response, device-devices_present - 1); goto exit; } #endif if ((device < 1) || (device > maxhue)) { device = 1; } response += F("{\"state\":"); HueLightStatus1(device, &response); HueLightStatus2(device, &response); } else { response = "{}"; code = 406; } exit: AddLog_P2(LOG_LEVEL_DEBUG_MORE, PSTR(D_LOG_HTTP D_HUE " Result (%s)"), response.c_str()); WSSend(code, CT_JSON, response); } void HueGroups(String *path) { /* * http://tasmota/api/username/groups?1={"name":"Woonkamer","lights":[],"type":"Room","class":"Living room"}) */ String response = "{}"; uint8_t maxhue = (devices_present > MAX_HUE_DEVICES) ? MAX_HUE_DEVICES : devices_present; //AddLog_P2(LOG_LEVEL_DEBUG_MORE, PSTR(D_LOG_HTTP D_HUE " HueGroups (%s)"), path->c_str()); if (path->endsWith("/0")) { response = FPSTR(HUE_GROUP0_STATUS_JSON); String lights = F("\"1\""); for (uint32_t i = 2; i <= maxhue; i++) { lights += ",\""; lights += EncodeLightId(i); lights += "\""; } #ifdef USE_ZIGBEE ZigbeeHueGroups(&response); #endif // USE_ZIGBEE response.replace("{l1", lights); HueLightStatus1(1, &response); response += F("}"); } AddLog_P2(LOG_LEVEL_DEBUG_MORE, PSTR(D_LOG_HTTP D_HUE " HueGroups Result (%s)"), path->c_str()); WSSend(200, CT_JSON, response); } void HandleHueApi(String *path) { /* HUE API uses /api// syntax. The userid is created by the echo device and * on original HUE the pressed button allows for creation of this user. We simply ignore the * user part and allow every caller as with Web or WeMo. * * (c) Heiko Krupp, 2017 * * Hue URL * http://tasmota/api/username/lights/1/state with post data {"on":true,"hue":56100,"sat":254,"bri":254,"alert":"none","transitiontime":40} * is converted by webserver to * http://tasmota/api/username/lights/1/state with arg plain={"on":true,"hue":56100,"sat":254,"bri":254,"alert":"none","transitiontime":40} */ uint8_t args = 0; path->remove(0, 4); // remove /api uint16_t apilen = path->length(); AddLog_P2(LOG_LEVEL_DEBUG_MORE, PSTR(D_LOG_HTTP D_HUE_API " (%s)"), path->c_str()); // HTP: Hue API (//lights/1/state for (args = 0; args < WebServer->args(); args++) { String json = WebServer->arg(args); AddLog_P2(LOG_LEVEL_DEBUG_MORE, PSTR(D_LOG_HTTP D_HUE_POST_ARGS " (%s)"), json.c_str()); // HTP: Hue POST args ({"on":false}) } if (path->endsWith(F("/invalid/"))) {} // Just ignore else if (!apilen) HueAuthentication(path); // New HUE App setup else if (path->endsWith(F("/"))) HueAuthentication(path); // New HUE App setup else if (path->endsWith(F("/config"))) HueConfig(path); else if (path->indexOf(F("/lights")) >= 0) HueLights(path); else if (path->indexOf(F("/groups")) >= 0) HueGroups(path); else if (path->endsWith(F("/schedules"))) HueNotImplemented(path); else if (path->endsWith(F("/sensors"))) HueNotImplemented(path); else if (path->endsWith(F("/scenes"))) HueNotImplemented(path); else if (path->endsWith(F("/rules"))) HueNotImplemented(path); else if (path->endsWith(F("/resourcelinks"))) HueNotImplemented(path); else HueGlobalConfig(path); } /*********************************************************************************************\ * Interface \*********************************************************************************************/ bool Xdrv20(uint8_t function) { bool result = false; #if defined(USE_SCRIPT_HUE) || defined(USE_ZIGBEE) if ((EMUL_HUE == Settings.flag2.emulation)) { #else if (devices_present && (EMUL_HUE == Settings.flag2.emulation)) { #endif switch (function) { case FUNC_WEB_ADD_HANDLER: WebServer->on(F("/description.xml"), HandleUpnpSetupHue); break; } } return result; } #endif // USE_WEBSERVER && USE_EMULATION && USE_EMULATION_HUE