/* xsns_62_MI_ESP32.ino - MI-BLE-sensors via ESP32 support for Tasmota Copyright (C) 2020 Christian Baars 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 . -------------------------------------------------------------------------------------------- Version yyyymmdd Action Description -------------------------------------------------------------------------------------------- 0.9.1.5 20201021 changed - HASS related ('null', hold back discovery), number of found sensors for RULES ------- 0.9.1.4 20201020 changed - use BearSSL for decryption, revert to old TELEPERIOD-cycle as default ------- 0.9.1.3 20200926 changed - Improve HA discovery, make key+MAC case insensitive ------- 0.9.1.3 20200916 changed - add ATC (custom FW for LYWSD03MMC), API adaption for NimBLE-Arduino 1.0.2 ------- 0.9.1.2 20200802 changed - add MHO-C303 ------- 0.9.1.1 20200715 changed - add MHO-C401, refactoring ------- 0.9.1.0 20200712 changed - add lights and yeerc, add pure passive mode with decryption, lots of refactoring ------- 0.9.0.1 20200706 changed - adapt to new NimBLE-API, tweak scan process ------- 0.9.0.0 20200413 started - initial development by Christian Baars forked - from arendst/tasmota - https://github.com/arendst/Tasmota */ #ifdef ESP32 // ESP32 only. Use define USE_HM10 for ESP8266 support #ifdef USE_MI_ESP32 #define XSNS_62 62 #define USE_MI_DECRYPTION #include #include #ifdef USE_MI_DECRYPTION #include #endif //USE_MI_DECRYPTION void MI32scanEndedCB(NimBLEScanResults results); void MI32notifyCB(NimBLERemoteCharacteristic* pRemoteCharacteristic, uint8_t* pData, size_t length, bool isNotify); struct { uint16_t perPage = 4; uint32_t period; // set manually in addition to TELE-period, is set to TELE-period after start union { struct { uint32_t init:1; uint32_t connected:1; uint32_t autoScan:1; uint32_t canScan:1; uint32_t runningScan:1; uint32_t canConnect:1; uint32_t willConnect:1; uint32_t readingDone:1; uint32_t shallSetTime:1; uint32_t willSetTime:1; uint32_t shallReadBatt:1; uint32_t willReadBatt:1; uint32_t shallSetUnit:1; uint32_t willSetUnit:1; uint32_t shallTriggerTele:1; uint32_t triggeredTele:1; uint32_t shallClearResults:1; // BLE scan results uint32_t shallShowStatusInfo:1; // react to amount of found sensors via RULES uint32_t firstAutodiscoveryDone:1; }; uint32_t all = 0; } mode; struct { uint8_t sensor; // points to to the number 0...255 } state; struct { uint32_t allwaysAggregate:1; // always show all known values of one sensor in brdigemode uint32_t noSummary:1; // no sensor values at TELE-period uint32_t directBridgeMode:1; // send every received BLE-packet as a MQTT-message in real-time uint32_t holdBackFirstAutodiscovery:1; // allows to trigger it later uint32_t showRSSI:1; uint32_t ignoreBogusBattery:1; uint32_t minimalSummary:1; // DEPRECATED!! } option; } MI32; #pragma pack(1) // byte-aligned structures to read the sensor data struct { uint16_t temp; uint8_t hum; uint16_t volt; // LYWSD03 only } LYWSD0x_HT; struct { uint8_t spare; uint16_t temp; uint16_t hum; } CGD1_HT; struct { uint16_t temp; uint8_t spare; uint32_t lux; uint8_t moist; uint16_t fert; } Flora_TLMF; // temperature, lux, moisture, fertility struct mi_beacon_t{ uint16_t frame; uint16_t productID; uint8_t counter; uint8_t MAC[6]; uint8_t spare; uint8_t type; uint8_t ten; uint8_t size; union { struct{ //0d uint16_t temp; uint16_t hum; }HT; uint8_t bat; //0a uint16_t temp; //04 uint16_t hum; //06 uint32_t lux; //07 uint8_t moist; //08 uint16_t fert; //09 uint32_t NMT; //17 struct{ //01 uint16_t num; uint8_t longPress; }Btn; }; uint8_t padding[12]; }; struct cg_packet_t { uint16_t frameID; uint8_t MAC[6]; uint16_t mode; union { struct { int16_t temp; // -9 - 59 °C uint16_t hum; }; uint8_t bat; }; }; struct encPacket_t{ // the packet is longer, but this part is enough to decrypt uint16_t PID; uint8_t frameCnt; uint8_t MAC[6]; uint8_t payload[16]; // only a pointer to the address, size is variable }; union mi_bindKey_t{ struct{ uint8_t key[16]; uint8_t MAC[6]; }; uint8_t buf[22]; }; struct ATCPacket_t{ uint8_t MAC[6]; int16_t temp; //sadly this is in wrong endianess uint8_t hum; uint8_t batPer; uint16_t batMV; uint8_t frameCnt; }; #pragma pack(0) struct mi_sensor_t{ uint8_t type; //Flora = 1; MI-HT_V1=2; LYWSD02=3; LYWSD03=4; CGG1=5; CGD1=6 uint8_t lastCnt; //device generated counter of the packet uint8_t shallSendMQTT; uint8_t MAC[6]; union { struct { uint32_t temp:1; uint32_t hum:1; uint32_t tempHum:1; //every hum sensor has temp too, easier to use Tasmota dew point functions uint32_t lux:1; uint32_t moist:1; uint32_t fert:1; uint32_t bat:1; uint32_t NMT:1; uint32_t PIR:1; uint32_t Btn:1; }; uint32_t raw; } feature; union { struct { uint32_t temp:1; uint32_t hum:1; uint32_t tempHum:1; //can be combined from the sensor uint32_t lux:1; uint32_t moist:1; uint32_t fert:1; uint32_t bat:1; uint32_t NMT:1; uint32_t motion:1; uint32_t noMotion:1; uint32_t Btn:1; }; uint32_t raw; } eventType; int rssi; uint32_t lastTime; uint32_t lux; float temp; //Flora, MJ_HT_V1, LYWSD0x, CGx union { struct { uint8_t moisture; uint16_t fertility; char firmware[6]; // actually only for FLORA but hopefully we can add for more devices }; // Flora struct { float hum; }; // MJ_HT_V1, LYWSD0x struct { uint16_t events; //"alarms" since boot uint32_t NMT; // no motion time in seconds for the MJYD2S }; uint16_t Btn; }; union { uint8_t bat; // many values seem to be hard-coded garbage (LYWSD0x, GCD1) }; }; std::vector MIBLEsensors; std::vector MIBLEbindKeys; static BLEScan* MI32Scan; /*********************************************************************************************\ * constants \*********************************************************************************************/ #define D_CMND_MI32 "MI32" const char S_JSON_MI32_COMMAND_NVALUE[] PROGMEM = "{\"" D_CMND_MI32 "%s\":%d}"; const char S_JSON_MI32_COMMAND[] PROGMEM = "{\"" D_CMND_MI32 "%s%s\"}"; const char kMI32_Commands[] PROGMEM = "Period|Time|Page|Battery|Unit|Key"; #define FLORA 1 #define MJ_HT_V1 2 #define LYWSD02 3 #define LYWSD03MMC 4 #define CGG1 5 #define CGD1 6 #define NLIGHT 7 #define MJYD2S 8 #define YEERC 9 #define MHOC401 10 #define MHOC303 11 #define ATC 12 #define MI32_TYPES 12 //count this manually const uint16_t kMI32DeviceID[MI32_TYPES]={ 0x0098, // Flora 0x01aa, // MJ_HT_V1 0x045b, // LYWSD02 0x055b, // LYWSD03 0x0347, // CGG1 0x0576, // CGD1 0x03dd, // NLIGHT 0x07f6, // MJYD2S 0x0153, // yee-rc 0x0387, // MHO-C401 0x06d3, // MHO-C303 0x0a1c // ATC -> this is a fake ID }; const char kMI32DeviceType1[] PROGMEM = "Flora"; const char kMI32DeviceType2[] PROGMEM = "MJ_HT_V1"; const char kMI32DeviceType3[] PROGMEM = "LYWSD02"; const char kMI32DeviceType4[] PROGMEM = "LYWSD03"; const char kMI32DeviceType5[] PROGMEM = "CGG1"; const char kMI32DeviceType6[] PROGMEM = "CGD1"; const char kMI32DeviceType7[] PROGMEM = "NLIGHT"; const char kMI32DeviceType8[] PROGMEM = "MJYD2S"; const char kMI32DeviceType9[] PROGMEM = "YEERC"; const char kMI32DeviceType10[] PROGMEM ="MHOC401"; const char kMI32DeviceType11[] PROGMEM ="MHOC303"; const char kMI32DeviceType12[] PROGMEM ="ATC"; const char * kMI32DeviceType[] PROGMEM = {kMI32DeviceType1,kMI32DeviceType2,kMI32DeviceType3,kMI32DeviceType4,kMI32DeviceType5,kMI32DeviceType6,kMI32DeviceType7,kMI32DeviceType8,kMI32DeviceType9,kMI32DeviceType10,kMI32DeviceType11,kMI32DeviceType12}; /*********************************************************************************************\ * enumerations \*********************************************************************************************/ enum MI32_Commands { // commands useable in console or rules CMND_MI32_PERIOD, // set period like TELE-period in seconds between read-cycles CMND_MI32_TIME, // set LYWSD02-Time from ESP8266-time CMND_MI32_PAGE, // sensor entries per web page, which will be shown alternated CMND_MI32_BATTERY, // read all battery levels CMND_MI32_UNIT, // toggles the displayed unit between C/F (LYWSD02) CMND_MI32_KEY // add bind key to a mac for packet decryption }; enum MI32_TASK { MI32_TASK_SCAN = 0, MI32_TASK_CONN = 1, MI32_TASK_TIME = 2, MI32_TASK_BATT = 3, MI32_TASK_UNIT = 4, }; /*********************************************************************************************\ * Classes \*********************************************************************************************/ class MI32SensorCallback : public NimBLEClientCallbacks { void onConnect(NimBLEClient* pclient) { AddLog_P2(LOG_LEVEL_DEBUG,PSTR("connected %s"), kMI32DeviceType[(MIBLEsensors[MI32.state.sensor].type)-1]); MI32.mode.willConnect = 0; MI32.mode.connected = 1; } void onDisconnect(NimBLEClient* pclient) { MI32.mode.connected = 0; AddLog_P2(LOG_LEVEL_DEBUG,PSTR("disconnected %s"), kMI32DeviceType[(MIBLEsensors[MI32.state.sensor].type)-1]); } bool onConnParamsUpdateRequest(NimBLEClient* MI32Client, const ble_gap_upd_params* params) { if(params->itvl_min < 24) { /** 1.25ms units */ return false; } else if(params->itvl_max > 40) { /** 1.25ms units */ return false; } else if(params->latency > 2) { /** Number of intervals allowed to skip */ return false; } else if(params->supervision_timeout > 100) { /** 10ms units */ return false; } return true; } }; class MI32AdvCallbacks: public NimBLEAdvertisedDeviceCallbacks { void onResult(NimBLEAdvertisedDevice* advertisedDevice) { // AddLog_P2(LOG_LEVEL_DEBUG,PSTR("Advertised Device: %s Buffer: %u"),advertisedDevice->getAddress().toString().c_str(),advertisedDevice->getServiceData(0).length()); if (advertisedDevice->getServiceDataCount() == 0) { // AddLog_P2(LOG_LEVEL_DEBUG,PSTR("No Xiaomi Device: %s Buffer: %u"),advertisedDevice->getAddress().toString().c_str(),advertisedDevice->getServiceData(0).length()); MI32Scan->erase(advertisedDevice->getAddress()); return; } uint16_t uuid = advertisedDevice->getServiceDataUUID(0).getNative()->u16.value; // AddLog_P2(LOG_LEVEL_DEBUG,PSTR("UUID: %x"),uuid); uint8_t addr[6]; memcpy(addr,advertisedDevice->getAddress().getNative(),6); MI32_ReverseMAC(addr); int rssi = 0xffff; if(advertisedDevice->haveRSSI()) { rssi = advertisedDevice->getRSSI(); } // AddLog_P2(LOG_LEVEL_DEBUG,PSTR("RSSI: %d"),rssi); // actually i never got a 0xffff if(uuid==0xfe95) { MI32ParseResponse((char*)advertisedDevice->getServiceData(0).data(),advertisedDevice->getServiceData(0).length(), addr, rssi); } else if(uuid==0xfdcd) { MI32parseCGD1Packet((char*)advertisedDevice->getServiceData(0).data(),advertisedDevice->getServiceData(0).length(), addr, rssi); } else if(uuid==0x181a) { //ATC MI32ParseATCPacket((char*)advertisedDevice->getServiceData(0).data(),advertisedDevice->getServiceData(0).length(), addr, rssi); } else { // AddLog_P2(LOG_LEVEL_DEBUG,PSTR("No Xiaomi Device: %x: %s Buffer: %u"), uuid, advertisedDevice->getAddress().toString().c_str(),advertisedDevice->getServiceData(0).length()); MI32Scan->erase(advertisedDevice->getAddress()); } }; }; static MI32AdvCallbacks MI32ScanCallbacks; static MI32SensorCallback MI32SensorCB; static NimBLEClient* MI32Client; /*********************************************************************************************\ * BLE callback functions \*********************************************************************************************/ void MI32scanEndedCB(NimBLEScanResults results){ AddLog_P2(LOG_LEVEL_DEBUG,PSTR("Scan ended")); MI32.mode.runningScan = 0; } void MI32notifyCB(NimBLERemoteCharacteristic* pRemoteCharacteristic, uint8_t* pData, size_t length, bool isNotify){ AddLog_P2(LOG_LEVEL_DEBUG,PSTR("Notified length: %u"),length); switch(MIBLEsensors[MI32.state.sensor].type){ case LYWSD03MMC: case LYWSD02: case MHOC401: MI32readHT_LY((char*)pData); MI32.mode.readingDone = 1; break; default: MI32.mode.readingDone = 1; break; } } /*********************************************************************************************\ * Helper functions \*********************************************************************************************/ void MI32_ReverseMAC(uint8_t _mac[]){ uint8_t _reversedMAC[6]; for (uint8_t i=0; i<6; i++){ _reversedMAC[5-i] = _mac[i]; } memcpy(_mac,_reversedMAC, sizeof(_reversedMAC)); } #ifdef USE_MI_DECRYPTION void MI32AddKey(char* payload){ mi_bindKey_t keyMAC; memset(keyMAC.buf,0,sizeof(keyMAC)); UpperCase(payload,payload); MI32KeyMACStringToBytes(payload,keyMAC.buf); bool unknownKey = true; for(uint32_t i=0; i= '0' && c <= '9') value = (c - '0'); else if (c >= 'A' && c <= 'F') value = (10 + (c - 'A')); _keyMAC[(index/2)] += value << (((index + 1) % 2) * 4); index++; } // AddLog_P2(LOG_LEVEL_DEBUG,PSTR("MI32: %s to:"),_string); // AddLog_P2(LOG_LEVEL_DEBUG,PSTR("MI32: key-array: %02X%02X%02X%02X%02X%02X%02X%02X%02X%02X%02X%02X%02X%02X%02X%02X"),_keyMAC[0],_keyMAC[1],_keyMAC[2],_keyMAC[3],_keyMAC[4],_keyMAC[5],_keyMAC[6],_keyMAC[7],_keyMAC[8],_keyMAC[9],_keyMAC[10],_keyMAC[11],_string,_keyMAC[12],_keyMAC[13],_keyMAC[14],_keyMAC[15]); // AddLog_P2(LOG_LEVEL_DEBUG,PSTR("MI32: MAC-array: %02X%02X%02X%02X%02X%02X"),_keyMAC[16],_keyMAC[17],_keyMAC[18],_keyMAC[19],_keyMAC[20],_keyMAC[21]); } /** * @brief Decrypts payload in place * * @param _buf - pointer to the buffer at position of PID * @param _bufSize - buffersize (last position is two bytes behind last byte of TAG) * @param _type - sensor type * @return int - error code, 0 for success */ int MI32_decryptPacket(char *_buf, uint16_t _bufSize, uint32_t _type){ encPacket_t *packet = (encPacket_t*)_buf; uint8_t payload[8]; size_t data_len = _bufSize - 9 - 4 - 3 - 1 - 1 ; // _bufsize - header - tag - ext.counter - RSSI - spare(?) int ret = 0; uint8_t nonce[12]; uint32_t tag; const unsigned char authData[1] = {0x11}; // AddLog_P2(LOG_LEVEL_DEBUG,PSTR("Decrypt Size of Buffer: %u, payload length: %u"), _bufSize, data_len); // AddLogBuffer(LOG_LEVEL_DEBUG,(uint8_t*)_buf, _bufSize); // nonce: device MAC, device type, frame cnt, ext. cnt for (uint32_t i = 0; i<6; i++){ nonce[i] = packet->MAC[i]; } memcpy((uint8_t*)&nonce+6,(uint8_t*)&packet->PID,2); nonce[8] = packet->frameCnt; memcpy((uint8_t*)&nonce+9,(uint8_t*)&_buf[_bufSize-9],3); // AddLog_P2(LOG_LEVEL_DEBUG,PSTR("nonceCnt1 and 2: %02x %02x %02x"),nonce[9],nonce[10],nonce[11]); memcpy((uint8_t*)&tag,(uint8_t*)&_buf[_bufSize-6],4); // AddLog_P2(LOG_LEVEL_DEBUG,PSTR("tag: %02x %02x %02x %02x"),tag[0],tag[1],tag[2],tag[3]); MI32_ReverseMAC(packet->MAC); uint8_t _bindkey[16] = {0x0}; bool foundNoKey = true; AddLog_P2(LOG_LEVEL_DEBUG,PSTR("MI32: search key for MAC: %02x %02x %02x %02x %02x %02x"), packet->MAC[0], packet->MAC[1], packet->MAC[2], packet->MAC[3], packet->MAC[4], packet->MAC[5]); for(uint32_t i=0; iMAC,MIBLEbindKeys[i].MAC,sizeof(packet->MAC))==0){ memcpy(_bindkey,MIBLEbindKeys[i].key,sizeof(_bindkey)); AddLog_P2(LOG_LEVEL_DEBUG,PSTR("MI32: decryption Key found")); foundNoKey = false; break; } } if(foundNoKey){ AddLog_P2(LOG_LEVEL_DEBUG,PSTR("MI32: no Key found !!")); return -2; } br_aes_small_ctrcbc_keys keyCtx; br_aes_small_ctrcbc_init(&keyCtx, _bindkey, sizeof(_bindkey)); br_ccm_context ctx; br_ccm_init(&ctx, &keyCtx.vtable); br_ccm_reset(&ctx, nonce, sizeof(nonce), sizeof(authData), data_len, sizeof(tag)); br_ccm_aad_inject(&ctx, authData, sizeof(authData)); br_ccm_flip(&ctx); memcpy(payload,packet->payload,data_len); //we want to be sure about 4-byte alignement br_ccm_run(&ctx, 0, payload, data_len); memcpy((uint8_t*)packet->payload+1,payload,data_len); //back to the packet // br_ccm_get_tag(&ctx, &checkTag); ret = br_ccm_check_tag(&ctx, &tag); // AddLog_P2(LOG_LEVEL_DEBUG,PSTR("packetTag: %08x"),tag); // AddLog_P2(LOG_LEVEL_DEBUG,PSTR("computedTag: %08x"),checkTag); AddLog_P2(LOG_LEVEL_DEBUG,PSTR("MI32: Err:%i, Decrypted : %02x %02x %02x %02x %02x "), ret, packet->payload[1],packet->payload[2],packet->payload[3],packet->payload[4],packet->payload[5]); return ret-1; } #endif // USE_MI_DECRYPTION #ifdef USE_HOME_ASSISTANT /** * @brief For HASS only, changes last entry of JSON in mqtt_data to 'null' */ void MI32nullifyEndOfMQTT_DATA(){ char *p = mqtt_data + strlen(mqtt_data); while(true){ *p--; if(p[0]==':'){ p[1] = 0; break; } } ResponseAppend_P(PSTR("null")); } #endif // USE_HOME_ASSISTANT /*********************************************************************************************\ * common functions \*********************************************************************************************/ /** * @brief Return the slot number of a known sensor or return create new sensor slot * * @param _MAC BLE address of the sensor * @param _type Type number of the sensor * @return uint32_t Known or new slot in the sensors-vector */ uint32_t MIBLEgetSensorSlot(uint8_t (&_MAC)[6], uint16_t _type, uint8_t counter){ DEBUG_SENSOR_LOG(PSTR("%s: will test ID-type: %x"),D_CMND_MI32, _type); bool _success = false; for (uint32_t i=0;i= NIMBLE_MAX_CONNECTIONS) { MI32.mode.willConnect = 0; DEBUG_SENSOR_LOG(PSTR("%s: max connection already reached"),D_CMND_MI32); return false; } if(!MI32Client) { // AddLog_P2(LOG_LEVEL_DEBUG,PSTR("%s: will create client"),D_CMND_MI32); MI32Client = NimBLEDevice::createClient(); MI32Client->setClientCallbacks(&MI32SensorCB , false); MI32Client->setConnectionParams(12,12,0,48); MI32Client->setConnectTimeout(30); // AddLog_P2(LOG_LEVEL_DEBUG,PSTR("%s: did create new client"),D_CMND_MI32); } vTaskDelay(300/ portTICK_PERIOD_MS); if (!MI32Client->connect(_address,false)) { MI32.mode.willConnect = 0; // NimBLEDevice::deleteClient(MI32Client); // AddLog_P2(LOG_LEVEL_DEBUG,PSTR("%s: did not connect client"),D_CMND_MI32); return false; } return true; // } } void MI32StartScanTask(){ if (MI32.mode.connected) return; MI32.mode.runningScan = 1; xTaskCreatePinnedToCore( MI32ScanTask, /* Function to implement the task */ "MI32ScanTask", /* Name of the task */ 4096, /* Stack size in words */ NULL, /* Task input parameter */ 0, /* Priority of the task */ NULL, /* Task handle. */ 0); /* Core where the task should run */ AddLog_P2(LOG_LEVEL_DEBUG,PSTR("%s: Start scanning"),D_CMND_MI32); } void MI32ScanTask(void *pvParameters){ if (MI32Scan == nullptr) MI32Scan = NimBLEDevice::getScan(); // DEBUG_SENSOR_LOG(PSTR("%s: Scan Cache Length: %u"),D_CMND_MI32, MI32Scan->getResults().getCount()); MI32Scan->setInterval(70); MI32Scan->setWindow(50); MI32Scan->setAdvertisedDeviceCallbacks(&MI32ScanCallbacks,true); MI32Scan->setActiveScan(false); MI32Scan->start(0, MI32scanEndedCB, true); // never stop scanning, will pause automatically while connecting uint32_t timer = 0; for(;;){ if(MI32.mode.shallClearResults){ MI32Scan->clearResults(); MI32.mode.shallClearResults=0; } vTaskDelay(10000/ portTICK_PERIOD_MS); } vTaskDelete( NULL ); } void MI32StartSensorTask(){ MI32.mode.willConnect = 1; switch(MIBLEsensors[MI32.state.sensor].type){ case LYWSD03MMC: case MHOC401: break; default: MI32.mode.willConnect = 0; return; } xTaskCreatePinnedToCore( MI32SensorTask, /* Function to implement the task */ "MI32SensorTask", /* Name of the task */ 4096, /* Stack size in words */ NULL, /* Task input parameter */ 15, /* Priority of the task */ NULL, /* Task handle. */ 0); /* Core where the task should run */ AddLog_P2(LOG_LEVEL_DEBUG,PSTR("%s: Start sensor connections"),D_CMND_MI32); AddLog_P2(LOG_LEVEL_DEBUG,PSTR("%s: with sensor: %u"),D_CMND_MI32, MI32.state.sensor); } void MI32SensorTask(void *pvParameters){ if (MI32ConnectActiveSensor()){ uint32_t timer = 0; while (MI32.mode.connected == 0){ if (timer>1000){ MI32Client->disconnect(); // NimBLEDevice::deleteClient(MI32Client); MI32.mode.willConnect = 0; MI32.mode.willReadBatt = 0; //could be a "battery task" for LYWSD03MMC or MHO-C401 vTaskDelay(100/ portTICK_PERIOD_MS); vTaskDelete( NULL ); } timer++; vTaskDelay(10/ portTICK_PERIOD_MS); } timer = 150; switch(MIBLEsensors[MI32.state.sensor].type){ case LYWSD03MMC: case MHOC401: MI32.mode.readingDone = 0; if(MI32connectLYWSD03forNotification()) timer=0; break; default: break; } while (!MI32.mode.readingDone){ if (timer>150){ break; } timer++; vTaskDelay(100/ portTICK_PERIOD_MS); } MI32Client->disconnect(); DEBUG_SENSOR_LOG(PSTR("%s: requested disconnect"),D_CMND_MI32); } MI32.mode.connected = 0; vTaskDelete( NULL ); } bool MI32connectLYWSD03forNotification(){ NimBLERemoteService* pSvc = nullptr; NimBLERemoteCharacteristic* pChr = nullptr; static BLEUUID serviceUUID(0xebe0ccb0,0x7a0a,0x4b0c,0x8a1a6ff2997da3a6); static BLEUUID charUUID(0xebe0ccc1,0x7a0a,0x4b0c,0x8a1a6ff2997da3a6); pSvc = MI32Client->getService(serviceUUID); if(pSvc) { pChr = pSvc->getCharacteristic(charUUID); } if (pChr){ if(pChr->canNotify()) { if(pChr->subscribe(true,MI32notifyCB,false)) { return true; } } } return false; } void MI32StartTimeTask(){ MI32.mode.willConnect = 1; xTaskCreatePinnedToCore( MI32TimeTask, /* Function to implement the task */ "MI32TimeTask", /* Name of the task */ 4096, /* Stack size in words */ NULL, /* Task input parameter */ 15, /* Priority of the task */ NULL, /* Task handle. */ 0); /* Core where the task should run */ // AddLog_P2(LOG_LEVEL_DEBUG,PSTR("%s: Start time set"),D_CMND_MI32); // AddLog_P2(LOG_LEVEL_DEBUG,PSTR("%s: with sensor: %u"),D_CMND_MI32, MI32.state.sensor); } void MI32TimeTask(void *pvParameters){ if (MIBLEsensors[MI32.state.sensor].type != LYWSD02 && MIBLEsensors[MI32.state.sensor].type != MHOC303) { MI32.mode.shallSetTime = 0; vTaskDelete( NULL ); } if(MI32ConnectActiveSensor()){ uint32_t timer = 0; while (MI32.mode.connected == 0){ if (timer>1000){ break; } timer++; vTaskDelay(10/ portTICK_PERIOD_MS); } NimBLERemoteService* pSvc = nullptr; NimBLERemoteCharacteristic* pChr = nullptr; static BLEUUID serviceUUID(0xEBE0CCB0,0x7A0A,0x4B0C,0x8A1A6FF2997DA3A6); static BLEUUID charUUID(0xEBE0CCB7,0x7A0A,0x4B0C,0x8A1A6FF2997DA3A6); pSvc = MI32Client->getService(serviceUUID); if(pSvc) { pChr = pSvc->getCharacteristic(charUUID); } if (pChr){ if(pChr->canWrite()) { union { uint8_t buf[5]; uint32_t time; } _utc; _utc.time = Rtc.utc_time; _utc.buf[4] = Rtc.time_timezone / 60; if(!pChr->writeValue(_utc.buf,sizeof(_utc.buf),true)) { // true is important ! MI32.mode.willConnect = 0; MI32Client->disconnect(); } else { MI32.mode.shallSetTime = 0; MI32.mode.willSetTime = 0; } } } MI32Client->disconnect(); } MI32.mode.connected = 0; MI32.mode.canScan = 1; vTaskDelete( NULL ); } void MI32StartUnitTask(){ MI32.mode.willConnect = 1; xTaskCreatePinnedToCore( MI32UnitTask, /* Function to implement the task */ "MI32UnitTask", /* Name of the task */ 4096, /* Stack size in words */ NULL, /* Task input parameter */ 15, /* Priority of the task */ NULL, /* Task handle. */ 0); /* Core where the task should run */ // AddLog_P2(LOG_LEVEL_DEBUG,PSTR("%s: Start unit set"),D_CMND_MI32); // AddLog_P2(LOG_LEVEL_DEBUG,PSTR("%s: with sensor: %u"),D_CMND_MI32, MI32.state.sensor); } void MI32UnitTask(void *pvParameters){ if (MIBLEsensors[MI32.state.sensor].type != LYWSD02 && MIBLEsensors[MI32.state.sensor].type != MHOC303) { MI32.mode.shallSetUnit = 0; vTaskDelete( NULL ); } if(MI32ConnectActiveSensor()){ uint32_t timer = 0; while (MI32.mode.connected == 0){ if (timer>1000){ break; } timer++; vTaskDelay(10/ portTICK_PERIOD_MS); } NimBLERemoteService* pSvc = nullptr; NimBLERemoteCharacteristic* pChr = nullptr; static BLEUUID serviceUUID(0xEBE0CCB0,0x7A0A,0x4B0C,0x8A1A6FF2997DA3A6); static BLEUUID charUUID(0xEBE0CCBE,0x7A0A,0x4B0C,0x8A1A6FF2997DA3A6); pSvc = MI32Client->getService(serviceUUID); if(pSvc) { pChr = pSvc->getCharacteristic(charUUID); } if(pChr->canRead()){ uint8_t curUnit; const char *buf = pChr->readValue().c_str(); if( buf[0] != 0 && buf[0]<101 ){ curUnit = buf[0]; } if(pChr->canWrite()) { curUnit = curUnit == 0x01?0xFF:0x01; // C/F if(!pChr->writeValue(&curUnit,sizeof(curUnit),true)) { // true is important ! MI32.mode.willConnect = 0; MI32Client->disconnect(); } else { MI32.mode.shallSetUnit = 0; MI32.mode.willSetUnit = 0; } } } MI32Client->disconnect(); } MI32.mode.connected = 0; MI32.mode.canScan = 1; vTaskDelete( NULL ); } void MI32StartBatteryTask(){ if (MI32.mode.connected) return; MI32.mode.willReadBatt = 1; MI32.mode.willConnect = 1; MI32.mode.canScan = 0; switch (MIBLEsensors[MI32.state.sensor].type){ case LYWSD03MMC: case MJ_HT_V1: case CGG1: case NLIGHT: case MJYD2S: case YEERC: case MHOC401: MI32.mode.willConnect = 0; MI32.mode.willReadBatt = 0; return; } xTaskCreatePinnedToCore( MI32BatteryTask, /* Function to implement the task */ "MI32BatteryTask", /* Name of the task */ 4096, /* Stack size in words */ NULL, /* Task input parameter */ 15, /* Priority of the task */ NULL, /* Task handle. */ 0); /* Core where the task should run */ } void MI32BatteryTask(void *pvParameters){ // all reported battery values are probably crap, but we allow the reading on demand MI32.mode.connected = 0; if(MI32ConnectActiveSensor()){ uint32_t timer = 0; while (MI32.mode.connected == 0){ if (timer>1000){ break; } timer++; vTaskDelay(30/ portTICK_PERIOD_MS); } switch(MIBLEsensors[MI32.state.sensor].type){ case FLORA: case LYWSD02: case CGD1: MI32batteryRead(MIBLEsensors[MI32.state.sensor].type); break; } MI32Client->disconnect(); } MI32.mode.willReadBatt = 0; MI32.mode.connected = 0; vTaskDelete( NULL ); } void MI32batteryRead(uint32_t _type){ uint32_t timer = 0; while (!MI32.mode.connected){ if (timer>1000){ break; } timer++; vTaskDelay(10/ portTICK_PERIOD_MS); } DEBUG_SENSOR_LOG(PSTR("%s connected for battery"),kMI32DeviceType[MIBLEsensors[MI32.state.sensor].type-1] ); NimBLERemoteService* pSvc = nullptr; NimBLERemoteCharacteristic* pChr = nullptr; switch(_type){ case FLORA: { static BLEUUID _serviceUUID(0x00001204,0x0000,0x1000,0x800000805f9b34fb); static BLEUUID _charUUID(0x00001a02,0x0000,0x1000,0x800000805f9b34fb); pSvc = MI32Client->getService(_serviceUUID); if(pSvc) { pChr = pSvc->getCharacteristic(_charUUID); } } break; case LYWSD02: { static BLEUUID _serviceUUID(0xEBE0CCB0,0x7A0A,0x4B0C,0x8A1A6FF2997DA3A6); static BLEUUID _charUUID(0xEBE0CCC4,0x7A0A,0x4B0C,0x8A1A6FF2997DA3A6); pSvc = MI32Client->getService(_serviceUUID); if(pSvc) { pChr = pSvc->getCharacteristic(_charUUID); } } break; case CGD1: { static BLEUUID _serviceUUID((uint16_t)0x180F); static BLEUUID _charUUID((uint16_t)0x2A19); pSvc = MI32Client->getService(_serviceUUID); if(pSvc) { pChr = pSvc->getCharacteristic(_charUUID); } } break; } if (pChr){ DEBUG_SENSOR_LOG(PSTR("%s: got %s char %s"),D_CMND_MI32, kMI32DeviceType[MIBLEsensors[MI32.state.sensor].type-1], pChr->getUUID().toString().c_str()); if(pChr->canRead()) { const char *buf = pChr->readValue().c_str(); MI32readBat((char*)buf); } } MI32.mode.readingDone = 1; } /*********************************************************************************************\ * parse the response from advertisements \*********************************************************************************************/ void MI32parseMiBeacon(char * _buf, uint32_t _slot, uint16_t _bufSize){ float _tempFloat; mi_beacon_t _beacon; if (MIBLEsensors[_slot].type==MJ_HT_V1 || MIBLEsensors[_slot].type==CGG1 || MIBLEsensors[_slot].type==YEERC){ memcpy((uint8_t*)&_beacon+1,(uint8_t*)_buf, sizeof(_beacon)-1); // shift by one byte for the MJ_HT_V1 DANGER!!! memcpy((uint8_t*)&_beacon.MAC,(uint8_t*)&_beacon.MAC+1,6); // but shift back the MAC _beacon.counter = _buf[4]; // restore the counter } else{ memcpy((char *)&_beacon, _buf, _bufSize); } MIBLEsensors[_slot].lastCnt = _beacon.counter; #ifdef USE_MI_DECRYPTION int decryptRet = 0; switch(MIBLEsensors[_slot].type){ case LYWSD03MMC: case MHOC401: if (_beacon.frame == 0x5858){ decryptRet = MI32_decryptPacket((char*)&_beacon.productID,_bufSize, LYWSD03MMC); //start with PID // AddLogBuffer(LOG_LEVEL_DEBUG,(uint8_t*)&_beacon.productID,_bufSize); } break; case MJYD2S: AddLog_P2(LOG_LEVEL_DEBUG,PSTR("MJYD2S: %x"),_beacon.frame); if (_beacon.frame == 0x5948){ // Now let's build/recreate a special MiBeacon memmove((uint8_t*)&_beacon.MAC+6,(uint8_t*)&_beacon.MAC, _bufSize); // shift payload by the size of the MAC = 6 bytes memcpy((uint8_t*)&_beacon.MAC,MIBLEsensors[_slot].MAC,6); // now insert the real MAC from our internal vector _bufSize+=6; // the packet has grown MI32_ReverseMAC(_beacon.MAC); // payload MAC is always reversed AddLog_P2(LOG_LEVEL_DEBUG,PSTR("MJYD2S: special packet")); } if (_beacon.frame != 0x5910){ decryptRet = MI32_decryptPacket((char*)&_beacon.productID,_bufSize,MJYD2S); //start with PID } else{ // This seems to be some kind of wake-up packet only, as it shows up before all kinds of messages, not only motion // if(millis()-MIBLEsensors[_slot].lastTime>120000){ // MIBLEsensors[_slot].eventType = 1; // MIBLEsensors[_slot].events++; // MIBLEsensors[_slot].shallSendMQTT = 1; // MIBLEsensors[_slot].lastTime = millis(); // AddLog_P2(LOG_LEVEL_DEBUG,PSTR("MI32: MJYD2S secondary PIR")); // MIBLEsensors[_slot].NMT = 0; // MI32.mode.shallTriggerTele = 1; // } } break; } if(decryptRet!=0){ AddLog_P2(LOG_LEVEL_DEBUG,PSTR("MI32: decryption failed with error: %d"),decryptRet); return; } #endif //USE_MI_DECRYPTION if(MIBLEsensors[_slot].type==6){ DEBUG_SENSOR_LOG(PSTR("CGD1 no support for MiBeacon, type %u"),MIBLEsensors[_slot].type); return; } AddLog_P2(LOG_LEVEL_DEBUG,PSTR("%s at slot %u with payload type: %02x"), kMI32DeviceType[MIBLEsensors[_slot].type-1],_slot,_beacon.type); switch(_beacon.type){ case 0x01: MIBLEsensors[_slot].Btn=_beacon.Btn.num + (_beacon.Btn.longPress/2)*6; MIBLEsensors[_slot].eventType.Btn = 1; MI32.mode.shallTriggerTele = 1; // AddLog_P2(LOG_LEVEL_DEBUG,PSTR("Mode 1: U16: %u Button"), MIBLEsensors[_slot].Btn ); break; case 0x04: _tempFloat=(float)(_beacon.temp)/10.0f; if(_tempFloat<60){ MIBLEsensors[_slot].temp=_tempFloat; MIBLEsensors[_slot].eventType.temp = 1; DEBUG_SENSOR_LOG(PSTR("Mode 4: temp updated")); } // AddLog_P2(LOG_LEVEL_DEBUG,PSTR("Mode 4: U16: %u Temp"), _beacon.temp ); break; case 0x06: _tempFloat=(float)(_beacon.hum)/10.0f; if(_tempFloat<101){ MIBLEsensors[_slot].hum=_tempFloat; MIBLEsensors[_slot].eventType.hum = 1; DEBUG_SENSOR_LOG(PSTR("Mode 6: hum updated")); } // AddLog_P2(LOG_LEVEL_DEBUG,PSTR("Mode 6: U16: %u Hum"), _beacon.hum); break; case 0x07: MIBLEsensors[_slot].lux=_beacon.lux & 0x00ffffff; if(MIBLEsensors[_slot].type==MJYD2S){ MIBLEsensors[_slot].eventType.noMotion = 1; } MIBLEsensors[_slot].eventType.lux = 1; // AddLog_P2(LOG_LEVEL_DEBUG,PSTR("Mode 7: U24: %u Lux"), _beacon.lux & 0x00ffffff); break; case 0x08: MIBLEsensors[_slot].moisture=_beacon.moist; MIBLEsensors[_slot].eventType.moist = 1; DEBUG_SENSOR_LOG(PSTR("Mode 8: moisture updated")); // AddLog_P2(LOG_LEVEL_DEBUG,PSTR("Mode 8: U8: %u Moisture"), _beacon.moist); break; case 0x09: MIBLEsensors[_slot].fertility=_beacon.fert; MIBLEsensors[_slot].eventType.fert = 1; DEBUG_SENSOR_LOG(PSTR("Mode 9: fertility updated")); // AddLog_P2(LOG_LEVEL_DEBUG,PSTR("Mode 9: U16: %u Fertility"), _beacon.fert); break; case 0x0a: if(MI32.option.ignoreBogusBattery){ if(MIBLEsensors[_slot].type==LYWSD03MMC || MIBLEsensors[_slot].type==MHOC401){ break; } } if(_beacon.bat<101){ MIBLEsensors[_slot].bat = _beacon.bat; MIBLEsensors[_slot].eventType.bat = 1; DEBUG_SENSOR_LOG(PSTR("Mode a: bat updated")); } // AddLog_P2(LOG_LEVEL_DEBUG,PSTR("Mode a: U8: %u %%"), _beacon.bat); break; case 0x0d: _tempFloat=(float)(_beacon.HT.temp)/10.0f; if(_tempFloat<60){ MIBLEsensors[_slot].temp = _tempFloat; DEBUG_SENSOR_LOG(PSTR("Mode d: temp updated")); } _tempFloat=(float)(_beacon.HT.hum)/10.0f; if(_tempFloat<100){ MIBLEsensors[_slot].hum = _tempFloat; DEBUG_SENSOR_LOG(PSTR("Mode d: hum updated")); } MIBLEsensors[_slot].eventType.tempHum = 1; // AddLog_P2(LOG_LEVEL_DEBUG,PSTR("Mode d: U16: %x Temp U16: %x Hum"), _beacon.HT.temp, _beacon.HT.hum); break; #ifdef USE_MI_DECRYPTION case 0x0f: if (_beacon.ten!=0) break; MIBLEsensors[_slot].eventType.motion = 1; MIBLEsensors[_slot].lastTime = millis(); MIBLEsensors[_slot].events++; MIBLEsensors[_slot].lux = _beacon.lux; MIBLEsensors[_slot].eventType.lux = 1; MIBLEsensors[_slot].NMT = 0; MI32.mode.shallTriggerTele = 1; // AddLog_P2(LOG_LEVEL_DEBUG,PSTR("PIR: primary"),MIBLEsensors[_slot].lux ); break; case 0x17: MIBLEsensors[_slot].NMT = _beacon.NMT; MIBLEsensors[_slot].eventType.NMT = 1; MI32.mode.shallTriggerTele = 1; // AddLog_P2(LOG_LEVEL_DEBUG,PSTR("Mode 17: NMT: %u seconds"), _beacon.NMT); break; #endif //USE_MI_DECRYPTION default: if (MIBLEsensors[_slot].type==NLIGHT){ MIBLEsensors[_slot].eventType.motion = 1; //PIR MIBLEsensors[_slot].events++; MIBLEsensors[_slot].NMT = 0; MIBLEsensors[_slot].lastTime = millis(); MI32.mode.shallTriggerTele = 1; // AddLog_P2(LOG_LEVEL_DEBUG,PSTR("PIR: primary"),MIBLEsensors[_slot].lux ); } else{ AddLogBuffer(LOG_LEVEL_DEBUG,(uint8_t*)_buf,_bufSize); } break; } if(MIBLEsensors[_slot].eventType.raw == 0) return; MIBLEsensors[_slot].shallSendMQTT = 1; if(MI32.option.directBridgeMode) MI32.mode.shallTriggerTele = 1; } void MI32ParseATCPacket(char * _buf, uint32_t length, uint8_t addr[6], int rssi){ ATCPacket_t *_packet = (ATCPacket_t*)_buf; uint32_t _slot = MIBLEgetSensorSlot(_packet->MAC, 0x0a1c, _packet->frameCnt); // This must be a hard-coded fake ID AddLog_P2(LOG_LEVEL_DEBUG,PSTR("%s at slot %u"), kMI32DeviceType[MIBLEsensors[_slot].type-1],_slot); if(_slot==0xff) return; MIBLEsensors[_slot].rssi=rssi; MIBLEsensors.at(_slot).temp = (float)(__builtin_bswap16(_packet->temp))/10.0f; MIBLEsensors.at(_slot).hum = (float)_packet->hum; MIBLEsensors[_slot].eventType.tempHum = 1; MIBLEsensors.at(_slot).bat = _packet->batPer; MIBLEsensors[_slot].eventType.bat = 1; MIBLEsensors[_slot].shallSendMQTT = 1; if(MI32.option.directBridgeMode) MI32.mode.shallTriggerTele = 1; } void MI32parseCGD1Packet(char * _buf, uint32_t length, uint8_t addr[6], int rssi){ // no MiBeacon uint8_t _addr[6]; memcpy(_addr,addr,6); uint32_t _slot = MIBLEgetSensorSlot(_addr, 0x0576, 0); // This must be hard-coded, no object-id in Cleargrass-packet, we have no packet counter too AddLog_P2(LOG_LEVEL_DEBUG,PSTR("%s at slot %u"), kMI32DeviceType[MIBLEsensors[_slot].type-1],_slot); if(_slot==0xff) return; MIBLEsensors[_slot].rssi=rssi; cg_packet_t _packet; memcpy((char*)&_packet,_buf,sizeof(_packet)); switch (_packet.mode){ case 0x0401: float _tempFloat; _tempFloat=(float)(_packet.temp)/10.0f; if(_tempFloat<60){ MIBLEsensors.at(_slot).temp = _tempFloat; MIBLEsensors[_slot].eventType.temp = 1; DEBUG_SENSOR_LOG(PSTR("CGD1: temp updated")); } _tempFloat=(float)(_packet.hum)/10.0f; if(_tempFloat<100){ MIBLEsensors.at(_slot).hum = _tempFloat; MIBLEsensors[_slot].eventType.hum = 1; DEBUG_SENSOR_LOG(PSTR("CGD1: hum updated")); } DEBUG_SENSOR_LOG(PSTR("CGD1: U16: %x Temp U16: %x Hum"), _packet.temp, _packet.hum); break; case 0x0102: if(_packet.bat<101){ MIBLEsensors.at(_slot).bat = _packet.bat; MIBLEsensors[_slot].eventType.bat = 1; DEBUG_SENSOR_LOG(PSTR("Mode a: bat updated")); } break; default: DEBUG_SENSOR_LOG(PSTR("MI32: unexpected CGD1-packet")); } if(MIBLEsensors[_slot].eventType.raw == 0) return; MIBLEsensors[_slot].shallSendMQTT = 1; if(MI32.option.directBridgeMode) MI32.mode.shallTriggerTele = 1; } void MI32ParseResponse(char *buf, uint16_t bufsize, uint8_t addr[6], int rssi) { if(bufsize<9) { //9 is from the NLIGHT return; } uint16_t _type= buf[3]*256 + buf[2]; // AddLog_P2(LOG_LEVEL_INFO, PSTR("%02x %02x %02x %02x"),(uint8_t)buf[0], (uint8_t)buf[1],(uint8_t)buf[2],(uint8_t)buf[3]); uint8_t _addr[6]; memcpy(_addr,addr,6); uint16_t _slot = MIBLEgetSensorSlot(_addr, _type, buf[4]); if(_slot!=0xff) { MIBLEsensors[_slot].rssi=rssi; MI32parseMiBeacon(buf,_slot,bufsize); } } /***********************************************************************\ * Read data from connections \***********************************************************************/ void MI32readHT_LY(char *_buf){ DEBUG_SENSOR_LOG(PSTR("%s: raw data: %x%x%x%x%x%x%x"),D_CMND_MI32,_buf[0],_buf[1],_buf[2],_buf[3],_buf[4],_buf[5],_buf[6]); if(_buf[0] != 0 && _buf[1] != 0){ memcpy(&LYWSD0x_HT,(void *)_buf,sizeof(LYWSD0x_HT)); AddLog_P2(LOG_LEVEL_DEBUG, PSTR("%s: T * 100: %u, H: %u, V: %u"),D_CMND_MI32,LYWSD0x_HT.temp,LYWSD0x_HT.hum, LYWSD0x_HT.volt); uint32_t _slot = MI32.state.sensor; DEBUG_SENSOR_LOG(PSTR("MIBLE: Sensor slot: %u"), _slot); static float _tempFloat; _tempFloat=(float)(LYWSD0x_HT.temp)/100.0f; if(_tempFloat<60){ MIBLEsensors[_slot].temp=_tempFloat; // MIBLEsensors[_slot].showedUp=255; // this sensor is real } _tempFloat=(float)LYWSD0x_HT.hum; if(_tempFloat<100){ MIBLEsensors[_slot].hum = _tempFloat; DEBUG_SENSOR_LOG(PSTR("LYWSD0x: hum updated")); } MIBLEsensors[_slot].eventType.tempHum = 1; if (MIBLEsensors[_slot].type == LYWSD03MMC || MIBLEsensors[_slot].type == MHOC401){ MIBLEsensors[_slot].bat = ((float)LYWSD0x_HT.volt-2100.0f)/12.0f; MI32.mode.willReadBatt = 0; MIBLEsensors[_slot].eventType.bat = 1; } MIBLEsensors[_slot].shallSendMQTT = 1; MI32.mode.shallTriggerTele = 1; } } bool MI32readBat(char *_buf){ DEBUG_SENSOR_LOG(PSTR("%s: raw data: %x%x%x%x%x%x%x"),D_CMND_MI32,_buf[0],_buf[1],_buf[2],_buf[3],_buf[4],_buf[5],_buf[6]); if(_buf[0] != 0){ AddLog_P2(LOG_LEVEL_DEBUG,PSTR("%s: Battery: %u"),D_CMND_MI32,_buf[0]); uint32_t _slot = MI32.state.sensor; DEBUG_SENSOR_LOG(PSTR("MIBLE: Sensor slot: %u"), _slot); if(_buf[0]<101){ MIBLEsensors[_slot].bat=_buf[0]; if(MIBLEsensors[_slot].type==FLORA){ memcpy(MIBLEsensors[_slot].firmware, _buf+2, 5); MIBLEsensors[_slot].firmware[5] = '\0'; AddLog_P2(LOG_LEVEL_DEBUG,PSTR("%s: Firmware: %s"),D_CMND_MI32,MIBLEsensors[_slot].firmware); } MIBLEsensors[_slot].eventType.bat = 1; MIBLEsensors[_slot].shallSendMQTT = 1; MI32.mode.shallTriggerTele = 1; return true; } } return false; } /** * @brief Launch functions from Core 1 to make race conditions less likely * */ void MI32Every50mSecond(){ if(MI32.mode.shallTriggerTele){ MI32.mode.shallTriggerTele = 0; MI32triggerTele(); } } /** * @brief Main loop of the driver, "high level"-loop * */ void MI32EverySecond(bool restart){ static uint32_t _counter = MI32.period - 15; static uint32_t _nextSensorSlot = 0; for (uint32_t i = 0; i < MIBLEsensors.size(); i++) { if(MIBLEsensors[i].type==NLIGHT || MIBLEsensors[i].type==MJYD2S){ MIBLEsensors[i].NMT++; } } if(MI32.mode.shallShowStatusInfo == 1){ MI32StatusInfo(); } if(restart){ _counter = 0; MI32.mode.canScan = 0; MI32.mode.canConnect = 1; MI32.mode.willReadBatt = 0; MI32.mode.willConnect = 0; return; } if (MI32.mode.shallSetTime) { MI32.mode.canScan = 0; MI32.mode.canConnect = 0; if (MI32.mode.willSetTime == 0){ MI32.mode.willSetTime = 1; MI32StartTask(MI32_TASK_TIME); } } if (MI32.mode.shallSetUnit) { MI32.mode.canScan = 0; MI32.mode.canConnect = 0; if (MI32.mode.willSetUnit == 0){ MI32.mode.willSetUnit = 1; MI32StartTask(MI32_TASK_UNIT); } } if (MI32.mode.willReadBatt) return; if (_counter>MI32.period) { _counter = 0; MI32.mode.canScan = 0; MI32.mode.canConnect = 1; } if(MI32.mode.connected == 1 || MI32.mode.willConnect == 1) return; if(MIBLEsensors.size()==0) { if (MI32.mode.runningScan == 0 && MI32.mode.canScan == 1) MI32StartTask(MI32_TASK_SCAN); return; } if(_counter==0) { MI32.state.sensor = _nextSensorSlot; AddLog_P2(LOG_LEVEL_DEBUG,PSTR("%s: active sensor now: %u of %u"),D_CMND_MI32, MI32.state.sensor, MIBLEsensors.size()-1); MI32.mode.canScan = 0; // if (MI32.mode.runningScan|| MI32.mode.connected || MI32.mode.willConnect) return; if (MI32.mode.connected || MI32.mode.willConnect) return; _nextSensorSlot++; MI32.mode.canConnect = 1; if(MI32.mode.connected == 0) { AddLog_P2(LOG_LEVEL_DEBUG, PSTR("will connect to %s"),kMI32DeviceType[MIBLEsensors[MI32.state.sensor].type-1] ); if (MI32.mode.shallReadBatt) { MI32StartTask(MI32_TASK_BATT); } #ifndef USE_MI_DECRYPTION // turn off connections, because we only listen to advertisements else{ MI32StartTask(MI32_TASK_CONN); } #endif //USE_MI_DECRYPTION } if (_nextSensorSlot>(MIBLEsensors.size()-1)) { _nextSensorSlot= 0; _counter++; if (MI32.mode.shallReadBatt){ MI32.mode.shallReadBatt = 0; } MI32.mode.canConnect = 0; MI32.mode.canScan = 1; } } else _counter++; if (MI32.state.sensor>MIBLEsensors.size()-1) { _nextSensorSlot = 0; MI32.mode.canScan = 1; } MI32StartTask(MI32_TASK_SCAN); } /*********************************************************************************************\ * Commands \*********************************************************************************************/ bool MI32Cmd(void) { char command[CMDSZ]; bool serviced = true; uint8_t disp_len = strlen(D_CMND_MI32); if (!strncasecmp_P(XdrvMailbox.topic, PSTR(D_CMND_MI32), disp_len)) { // prefix uint32_t command_code = GetCommandCode(command, sizeof(command), XdrvMailbox.topic + disp_len, kMI32_Commands); switch (command_code) { case CMND_MI32_PERIOD: if (XdrvMailbox.data_len > 0) { if (XdrvMailbox.payload==1) { MI32EverySecond(true); XdrvMailbox.payload = MI32.period; } else { MI32.period = XdrvMailbox.payload; } } else { XdrvMailbox.payload = MI32.period; } Response_P(S_JSON_MI32_COMMAND_NVALUE, command, XdrvMailbox.payload); break; case CMND_MI32_TIME: if (XdrvMailbox.data_len > 0) { if(MIBLEsensors.size()>XdrvMailbox.payload){ if(MIBLEsensors[XdrvMailbox.payload].type == LYWSD02 || MIBLEsensors[XdrvMailbox.payload].type == MHOC303){ AddLog_P2(LOG_LEVEL_DEBUG,PSTR("%s: will set Time"),D_CMND_MI32); MI32.state.sensor = XdrvMailbox.payload; MI32.mode.canScan = 0; MI32.mode.canConnect = 0; MI32.mode.shallSetTime = 1; MI32.mode.willSetTime = 0; } } } Response_P(S_JSON_MI32_COMMAND_NVALUE, command, XdrvMailbox.payload); break; case CMND_MI32_UNIT: if (XdrvMailbox.data_len > 0) { if(MIBLEsensors.size()>XdrvMailbox.payload){ if(MIBLEsensors[XdrvMailbox.payload].type == LYWSD02 || MIBLEsensors[XdrvMailbox.payload].type == MHOC303){ AddLog_P2(LOG_LEVEL_DEBUG,PSTR("%s: will set Unit"),D_CMND_MI32); MI32.state.sensor = XdrvMailbox.payload; MI32.mode.canScan = 0; MI32.mode.canConnect = 0; MI32.mode.shallSetUnit = 1; MI32.mode.willSetUnit = 0; } } } Response_P(S_JSON_MI32_COMMAND_NVALUE, command, XdrvMailbox.payload); break; case CMND_MI32_PAGE: if (XdrvMailbox.data_len > 0) { if (XdrvMailbox.payload == 0) XdrvMailbox.payload = MI32.perPage; // ignore 0 MI32.perPage = XdrvMailbox.payload; } else XdrvMailbox.payload = MI32.perPage; Response_P(S_JSON_MI32_COMMAND_NVALUE, command, XdrvMailbox.payload); break; case CMND_MI32_BATTERY: MI32EverySecond(true); MI32.mode.shallReadBatt = 1; MI32.mode.canConnect = 1; XdrvMailbox.payload = MI32.period; Response_P(S_JSON_MI32_COMMAND, command, ""); break; #ifdef USE_MI_DECRYPTION case CMND_MI32_KEY: if (XdrvMailbox.data_len==44){ // a KEY-MAC-string MI32AddKey(XdrvMailbox.data); Response_P(S_JSON_MI32_COMMAND, command, XdrvMailbox.data); } break; #endif //USE_MI_DECRYPTION default: // else for Unknown command serviced = false; break; } } else { return false; } return serviced; } /*********************************************************************************************\ * Presentation \*********************************************************************************************/ const char HTTP_MI32[] PROGMEM = "{s}MI ESP32 v0.9.1.5{m}%u%s / %u{e}"; const char HTTP_MI32_MAC[] PROGMEM = "{s}%s %s{m}%s{e}"; const char HTTP_RSSI[] PROGMEM = "{s}%s " D_RSSI "{m}%d dBm{e}"; const char HTTP_BATTERY[] PROGMEM = "{s}%s" " Battery" "{m}%u %%{e}"; const char HTTP_LASTBUTTON[] PROGMEM = "{s}%s Last Button{m}%u {e}"; const char HTTP_EVENTS[] PROGMEM = "{s}%s Events{m}%u {e}"; const char HTTP_NMT[] PROGMEM = "{s}%s No motion{m}> %u seconds{e}"; const char HTTP_MI32_FLORA_DATA[] PROGMEM = "{s}%s" " Fertility" "{m}%u us/cm{e}"; const char HTTP_MI32_HL[] PROGMEM = "{s}
{m}
{e}"; void MI32Show(bool json) { if (json) { #ifdef USE_HOME_ASSISTANT bool _noSummarySave = MI32.option.noSummary; bool _minimalSummarySave = MI32.option.minimalSummary; if(hass_mode==2){ if(MI32.option.holdBackFirstAutodiscovery){ if(!MI32.mode.firstAutodiscoveryDone){ MI32.mode.firstAutodiscoveryDone = 1; return; } } MI32.option.noSummary = false; MI32.option.minimalSummary = false; } #endif //USE_HOME_ASSISTANT if(!MI32.mode.triggeredTele){ MI32.mode.shallClearResults=1; if(MI32.option.noSummary) return; // no message at TELEPERIOD } for (uint32_t i = 0; i < MIBLEsensors.size(); i++) { if(MI32.mode.triggeredTele && MIBLEsensors[i].eventType.raw == 0) continue; if(MI32.mode.triggeredTele && MIBLEsensors[i].shallSendMQTT==0) continue; ResponseAppend_P(PSTR(",\"%s-%02x%02x%02x\":"), // do not add the '{' now ... kMI32DeviceType[MIBLEsensors[i].type-1], MIBLEsensors[i].MAC[3], MIBLEsensors[i].MAC[4], MIBLEsensors[i].MAC[5]); uint32_t _positionCurlyBracket = strlen(mqtt_data); // ... this will be a ',' first, but later be replaced if((!MI32.mode.triggeredTele && !MI32.option.minimalSummary)||MI32.mode.triggeredTele){ bool tempHumSended = false; if(MIBLEsensors[i].feature.tempHum){ if(MIBLEsensors[i].eventType.tempHum || !MI32.mode.triggeredTele || MI32.option.allwaysAggregate){ if (!isnan(MIBLEsensors[i].hum) && !isnan(MIBLEsensors[i].temp) #ifdef USE_HOME_ASSISTANT ||(hass_mode!=-1) #endif //USE_HOME_ASSISTANT ) { ResponseAppend_P(PSTR(",")); ResponseAppendTHD(MIBLEsensors[i].temp, MIBLEsensors[i].hum); tempHumSended = true; } } } if(MIBLEsensors[i].feature.temp && !tempHumSended){ if(MIBLEsensors[i].eventType.temp || !MI32.mode.triggeredTele || MI32.option.allwaysAggregate) { if (!isnan(MIBLEsensors[i].temp) #ifdef USE_HOME_ASSISTANT ||(hass_mode!=-1) #endif //USE_HOME_ASSISTANT ) { char temperature[FLOATSZ]; dtostrfd(MIBLEsensors[i].temp, Settings.flag2.temperature_resolution, temperature); ResponseAppend_P(PSTR(",\"" D_JSON_TEMPERATURE "\":%s"), temperature); } } } if(MIBLEsensors[i].feature.hum && !tempHumSended){ if(MIBLEsensors[i].eventType.hum || !MI32.mode.triggeredTele || MI32.option.allwaysAggregate) { if (!isnan(MIBLEsensors[i].hum) #ifdef USE_HOME_ASSISTANT ||(hass_mode!=-1) #endif //USE_HOME_ASSISTANT ) { char hum[FLOATSZ]; dtostrfd(MIBLEsensors[i].hum, Settings.flag2.humidity_resolution, hum); ResponseAppend_P(PSTR(",\"" D_JSON_HUMIDITY "\":%s"), hum); } } } if (MIBLEsensors[i].feature.lux){ if(MIBLEsensors[i].eventType.lux || !MI32.mode.triggeredTele || MI32.option.allwaysAggregate){ if (MIBLEsensors[i].lux!=0x0ffffff #ifdef USE_HOME_ASSISTANT ||(hass_mode!=-1) #endif //USE_HOME_ASSISTANT ) { // this is the error code -> no lux ResponseAppend_P(PSTR(",\"" D_JSON_ILLUMINANCE "\":%u"), MIBLEsensors[i].lux); #ifdef USE_HOME_ASSISTANT if (MIBLEsensors[i].lux==0x0ffffff) MI32nullifyEndOfMQTT_DATA(); #endif //USE_HOME_ASSISTANT } } } if (MIBLEsensors[i].feature.moist){ if(MIBLEsensors[i].eventType.moist || !MI32.mode.triggeredTele || MI32.option.allwaysAggregate){ if (MIBLEsensors[i].moisture!=0xff #ifdef USE_HOME_ASSISTANT ||(hass_mode!=-1) #endif //USE_HOME_ASSISTANT ) { ResponseAppend_P(PSTR(",\"" D_JSON_MOISTURE "\":%u"), MIBLEsensors[i].moisture); #ifdef USE_HOME_ASSISTANT if (MIBLEsensors[i].moisture==0xff) MI32nullifyEndOfMQTT_DATA(); #endif //USE_HOME_ASSISTANT } } } if (MIBLEsensors[i].feature.fert){ if(MIBLEsensors[i].eventType.fert || !MI32.mode.triggeredTele || MI32.option.allwaysAggregate){ if (MIBLEsensors[i].fertility!=0xffff #ifdef USE_HOME_ASSISTANT ||(hass_mode!=-1) #endif //USE_HOME_ASSISTANT ) { ResponseAppend_P(PSTR(",\"Fertility\":%u"), MIBLEsensors[i].fertility); #ifdef USE_HOME_ASSISTANT if (MIBLEsensors[i].fertility==0xffff) MI32nullifyEndOfMQTT_DATA(); #endif //USE_HOME_ASSISTANT } } } if (MIBLEsensors[i].feature.Btn){ if(MIBLEsensors[i].eventType.Btn #ifdef USE_HOME_ASSISTANT ||(hass_mode==2) #endif //USE_HOME_ASSISTANT ){ ResponseAppend_P(PSTR(",\"Btn\":%u"),MIBLEsensors[i].Btn); } } } // minimal summary if (MIBLEsensors[i].feature.PIR){ if(MIBLEsensors[i].eventType.motion || !MI32.mode.triggeredTele){ if(MI32.mode.triggeredTele) ResponseAppend_P(PSTR(",\"PIR\":1")); // only real-time ResponseAppend_P(PSTR(",\"Events\":%u"),MIBLEsensors[i].events); } else if(MIBLEsensors[i].eventType.noMotion && MI32.mode.triggeredTele){ ResponseAppend_P(PSTR(",\"PIR\":0")); } } if (MIBLEsensors[i].type == FLORA && !MI32.mode.triggeredTele) { if (MIBLEsensors[i].firmware[0] != '\0') { // this is the error code -> no firmware ResponseAppend_P(PSTR(",\"Firmware\":\"%s\""), MIBLEsensors[i].firmware); } } if (MIBLEsensors[i].feature.NMT || !MI32.mode.triggeredTele){ if(MIBLEsensors[i].eventType.NMT){ ResponseAppend_P(PSTR(",\"NMT\":%u"), MIBLEsensors[i].NMT); } } if (MIBLEsensors[i].feature.bat){ if(MIBLEsensors[i].eventType.bat || !MI32.mode.triggeredTele || MI32.option.allwaysAggregate){ if (MIBLEsensors[i].bat != 0x00 #ifdef USE_HOME_ASSISTANT ||(hass_mode!=-1) #endif //USE_HOME_ASSISTANT ) { // this is the error code -> no battery ResponseAppend_P(PSTR(",\"Battery\":%u"), MIBLEsensors[i].bat); #ifdef USE_HOME_ASSISTANT if (MIBLEsensors[i].bat == 0x00) MI32nullifyEndOfMQTT_DATA(); #endif //USE_HOME_ASSISTANT } } } if (MI32.option.showRSSI && MI32.mode.triggeredTele) ResponseAppend_P(PSTR(",\"RSSI\":%d"), MIBLEsensors[i].rssi); if(_positionCurlyBracket==strlen(mqtt_data)) ResponseAppend_P(PSTR(",")); // write some random char, to be overwritten in the next step ResponseAppend_P(PSTR("}")); mqtt_data[_positionCurlyBracket] = '{'; MIBLEsensors[i].eventType.raw = 0; if(MIBLEsensors[i].shallSendMQTT==1){ MIBLEsensors[i].shallSendMQTT = 0; continue; } } MI32.mode.triggeredTele = 0; #ifdef USE_HOME_ASSISTANT if(hass_mode==2){ MI32.option.noSummary = _noSummarySave; MI32.option.minimalSummary = _minimalSummarySave; } #endif //USE_HOME_ASSISTANT #ifdef USE_WEBSERVER } else { static uint16_t _page = 0; static uint16_t _counter = 0; int32_t i = _page * MI32.perPage; uint32_t j = i + MI32.perPage; if (j+1>MIBLEsensors.size()){ j = MIBLEsensors.size(); } char stemp[5] ={0}; if (MIBLEsensors.size()-(_page*MI32.perPage)>1 && MI32.perPage!=1) { sprintf_P(stemp,"-%u",j); } if (MIBLEsensors.size()==0) i=-1; // only for the GUI WSContentSend_PD(HTTP_MI32, i+1,stemp,MIBLEsensors.size()); for (i; iFLORA) { // everything "above" Flora if (!isnan(MIBLEsensors[i].hum) && !isnan(MIBLEsensors[i].temp)) { WSContentSend_THD(kMI32DeviceType[MIBLEsensors[i].type-1], MIBLEsensors[i].temp, MIBLEsensors[i].hum); } } #ifdef USE_MI_DECRYPTION if (MIBLEsensors[i].type==NLIGHT || MIBLEsensors[i].type==MJYD2S) { #else if (MIBLEsensors[i].type==NLIGHT) { #endif //USE_MI_DECRYPTION WSContentSend_PD(HTTP_EVENTS, kMI32DeviceType[MIBLEsensors[i].type-1], MIBLEsensors[i].events); if(MIBLEsensors[i].NMT>0) WSContentSend_PD(HTTP_NMT, kMI32DeviceType[MIBLEsensors[i].type-1], MIBLEsensors[i].NMT); } if (MIBLEsensors[i].lux!=0x00ffffff) { // this is the error code -> no valid value WSContentSend_PD(HTTP_SNS_ILLUMINANCE, kMI32DeviceType[MIBLEsensors[i].type-1], MIBLEsensors[i].lux); } if(MIBLEsensors[i].bat!=0x00){ WSContentSend_PD(HTTP_BATTERY, kMI32DeviceType[MIBLEsensors[i].type-1], MIBLEsensors[i].bat); } if (MIBLEsensors[i].type==YEERC){ WSContentSend_PD(HTTP_LASTBUTTON, kMI32DeviceType[MIBLEsensors[i].type-1], MIBLEsensors[i].Btn); } } _counter++; if(_counter>3) { _page++; _counter=0; } if (MIBLEsensors.size()%MI32.perPage==0 && _page==MIBLEsensors.size()/MI32.perPage) { _page = 0; } if (_page>MIBLEsensors.size()/MI32.perPage) { _page = 0; } #endif // USE_WEBSERVER } } /*********************************************************************************************\ * Interface \*********************************************************************************************/ bool Xsns62(uint8_t function) { bool result = false; if (FUNC_INIT == function){ MI32Init(); } if (MI32.mode.init) { switch (function) { case FUNC_EVERY_50_MSECOND: MI32Every50mSecond(); break; case FUNC_EVERY_SECOND: MI32EverySecond(false); break; case FUNC_COMMAND: result = MI32Cmd(); break; case FUNC_JSON_APPEND: MI32Show(1); break; #ifdef USE_WEBSERVER case FUNC_WEB_SENSOR: MI32Show(0); break; #endif // USE_WEBSERVER } } return result; } #endif // USE_MI_ESP32 #endif // ESP32