/* xdrv_45_shelly_dimmer.ino - shelly dimmer support for Tasmota Copyright (C) 2021 James Turton 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 . */ #ifdef USE_LIGHT #ifdef USE_SHELLY_DIMMER /*********************************************************************************************\ * Shelly WiFi Dimmer v1 and v2 (ESP8266 w/ separate co-processor dimmer) * * {"NAME":"Shelly Dimmer 1","GPIO":[0,3200,0,3232,5568,5600,0,0,192,0,193,288,0,4736],"FLAG":0,"BASE":18} * {"NAME":"Shelly Dimmer 2","GPIO":[0,3200,0,3232,5568,5600,0,0,193,0,192,0,320,4736],"FLAG":0,"BASE":18} * * https://shelly.cloud/wifi-smart-home-automation-shelly-dimmer/ * https://shelly.cloud/products/shelly-dimmer-2-smart-home-light-controller/ \*********************************************************************************************/ #define XDRV_45 45 #define XNRG_31 31 // #define SHELLY_DIMMER_DEBUG // #define SHELLY_HW_DIMMING #define SHD_LOGNAME "SHD: " #ifdef SHELLY_CMDS #define D_PRFX_SHD "Shd" #define D_CMND_LEADINGEDGE "LeadingEdge" #define D_CMND_WARMUPBRIGHTNESS "WarmupBrightness" #define D_CMND_WARMUPTIME "WarmupTime" #endif // SHELLY_CMDS #define SHD_SWITCH_CMD 0x01 #define SHD_SWITCH_FADE_CMD 0x02 #define SHD_POLL_CMD 0x10 #define SHD_VERSION_CMD 0x11 #define SHD_SETTINGS_CMD 0x20 #define SHD_WARMUP_CMD 0x21 #define SHD_CALIBRATION1_CMD 0x30 #define SHD_CALIBRATION2_CMD 0x31 #define SHD_SWITCH_SIZE 2 #define SHD_SWITCH_FADE_SIZE 6 #define SHD_SETTINGS_SIZE 10 #define SHD_WARMUP_SIZE 4 #define SHD_CALIBRATION_SIZE 200 #define SHD_START_BYTE 0x01 #define SHD_END_BYTE 0x04 #define SHD_BUFFER_SIZE 256 #define SHD_ACK_TIMEOUT 200 // 200 ms ACK timeout #ifdef SHELLY_FW_UPGRADE #include #endif // SHELLY_FW_UPGRADE #include TasmotaSerial *ShdSerial = nullptr; typedef struct { uint8_t version_major = 0; uint8_t version_minor = 0; uint32_t brightness = 0; uint32_t power = 0; uint32_t fade_rate = 0; } SHD_DIMMER; struct SHD { SHD_DIMMER dimmer; uint8_t *buffer = nullptr; // Serial receive buffer int byte_counter = 0; // Index in serial receive buffer #ifdef USE_ENERGY_SENSOR uint32_t last_power_check = 0; // Time when last power was checked #endif // USE_ENERGY_SENSOR uint32_t start_time = 0; uint16_t req_brightness = 0; uint16_t req_fade_rate = 0; uint16_t leading_edge = 2; // Leading edge = 2 Trailing edge = 1 uint16_t warmup_brightness = 100; // 10% uint16_t warmup_time = 20; // 20ms uint8_t counter = 1; // Packet counter uint8_t hw_version = 0; // Dimmer 1 = 1 Dimmer 2 = 2 bool present = false; bool req_on = false; } Shd; /*********************************************************************************************\ * SHD firmware update Functions \*********************************************************************************************/ #ifdef SHELLY_FW_UPGRADE void ShdResetToDFUMode() { #ifdef SHELLY_DIMMER_DEBUG AddLog(LOG_LEVEL_DEBUG, PSTR(SHD_LOGNAME "Request co-processor reset in dfu mode")); #endif // SHELLY_DIMMER_DEBUG pinMode(Pin(GPIO_SHELLY_DIMMER_RST_INV), OUTPUT); digitalWrite(Pin(GPIO_SHELLY_DIMMER_RST_INV), LOW); pinMode(Pin(GPIO_SHELLY_DIMMER_BOOT0), OUTPUT); digitalWrite(Pin(GPIO_SHELLY_DIMMER_BOOT0), HIGH); delay(50); // clear in the receive buffer while (Serial.available()) Serial.read(); digitalWrite(Pin(GPIO_SHELLY_DIMMER_RST_INV), HIGH); // pull out of reset delay(50); // wait 50ms fot the co-processor to come online } bool ShdUpdateFirmware(uint8_t* data, uint32_t size) { #ifdef SHELLY_DIMMER_DEBUG AddLog(LOG_LEVEL_DEBUG, PSTR(SHD_LOGNAME "Update firmware")); #endif // SHELLY_DIMMER_DEBUG bool ret = true; stm32_t *stm = stm32_init(&Serial, STREAM_SERIAL, 1); if (stm) { off_t offset = 0; uint8_t buffer[256]; unsigned int len; const uint8_t *p_st = data; uint32_t addr, start, end; stm32_err_t s_err; #ifdef SHELLY_DIMMER_DEBUG AddLog(LOG_LEVEL_DEBUG, PSTR(SHD_LOGNAME "STM32 erase memory")); #endif // SHELLY_DIMMER_DEBUG stm32_erase_memory(stm, 0, STM32_MASS_ERASE); addr = stm->dev->fl_start; end = addr + size; while(addr < end && offset < size) { uint32_t left = end - addr; len = sizeof(buffer) > left ? left : sizeof(buffer); len = len > size - offset ? size - offset : len; if (len == 0) { break; } memcpy(buffer, p_st, sizeof(buffer)); // We need 4-byte bounadry flash access p_st += sizeof(buffer); s_err = stm32_write_memory(stm, addr, buffer, len); if (s_err != STM32_ERR_OK) { ret = false; break; } addr += len; offset += len; } stm32_close(stm); } return ret; } bool ShdPresent(void) { return Shd.present; } uint32_t ShdFlash(uint8_t* data, size_t size) { #ifdef SHELLY_DIMMER_DEBUG AddLog(LOG_LEVEL_INFO, PSTR(SHD_LOGNAME "Updating firmware v%u.%u with %u bytes"), Shd.dimmer.version_major, Shd.dimmer.version_minor, size); #endif // SHELLY_DIMMER_DEBUG Serial.end(); Serial.begin(115200, SERIAL_8E1); ShdResetToDFUMode(); bool error = !ShdUpdateFirmware(data, size); // Allow flash access without ESP.flashRead Serial.end(); ShdResetToAppMode(); Serial.begin(115200, SERIAL_8N1); ShdSendVersion(); return error; } #endif // SHELLY_FW_UPGRADE /*********************************************************************************************\ * Helper Functions \*********************************************************************************************/ uint16_t checksum(uint8_t *buf, int len) { uint16_t chksm = 0; for (uint8_t i = 0; i < len; i++) chksm += buf[i]; return chksm; } int check_byte() { uint8_t index = Shd.byte_counter; uint8_t byte = Shd.buffer[index]; if (index == 0) return byte == SHD_START_BYTE; if (index < 4) return 1; uint8_t data_length = Shd.buffer[3]; if ((4 + data_length + 3) > SHD_BUFFER_SIZE) return 0; if (index < 4 + data_length + 1) return 1; if (index == 4 + data_length + 1) { uint16_t chksm = (Shd.buffer[index - 1] << 8 | Shd.buffer[index]); uint16_t chksm_calc = checksum(&Shd.buffer[1], 3 + data_length); if (chksm != chksm_calc) { #ifdef SHELLY_DIMMER_DEBUG AddLog(LOG_LEVEL_DEBUG, PSTR(SHD_LOGNAME "Checksum: %x calculated: %x"), chksm, chksm_calc); #endif // SHELLY_DIMMER_DEBUG return 0; } return 1; } if (index == 4 + data_length + 2 && byte == SHD_END_BYTE) return index; return 0; } /*********************************************************************************************\ * Internal Functions \*********************************************************************************************/ bool ShdSerialSend(const uint8_t data[] = nullptr, uint16_t len = 0) { int retries = 3; #ifdef SHELLY_DIMMER_DEBUG AddLog(LOG_LEVEL_DEBUG_MORE, PSTR(SHD_LOGNAME "Tx Packet %*_H"), len, (uint8_t*)data); #endif // SHELLY_DIMMER_DEBUG while (retries--) { ShdSerial->write(data, len); ShdSerial->flush(); // wait for any response uint32_t snd_time = millis(); while (TimePassedSince(snd_time) < SHD_ACK_TIMEOUT) { if (ShdSerialInput()) return true; delay(1); } // timeout AddLog(LOG_LEVEL_DEBUG_MORE, PSTR(SHD_LOGNAME "Serial send timeout")); } return false; } bool ShdSendCmd(uint8_t cmd, uint8_t *payload, uint8_t len) { uint8_t data[4 + 72 + 3]; // maximum payload for 0x30 packet is 72 uint16_t chksm; uint8_t pos = 0; data[0] = SHD_START_BYTE; data[1] = Shd.counter++; data[2] = cmd; data[3] = len; pos += 4; if (payload) { memcpy(data + 4, payload, len); pos += len; } // calculate checksum from id and onwards chksm = checksum(data + 1, 3 + len); data[pos++] = chksm >> 8; data[pos++] = chksm & 0xff; data[pos++] = SHD_END_BYTE; return ShdSerialSend(data, pos); } void ShdSetBrightness() { // Payload format: // [0-1] Brightness (%) * 10 uint8_t payload[SHD_SWITCH_SIZE]; payload[0] = Shd.req_brightness & 0xff; payload[1] = Shd.req_brightness >> 8; ShdSendCmd(SHD_SWITCH_CMD, payload, SHD_SWITCH_SIZE); } void ShdSetBrightnessFade() { uint16_t delta = 0; if (Shd.req_brightness > Shd.dimmer.brightness) delta = (Shd.req_brightness - Shd.dimmer.brightness) * 0.8; else delta = (Shd.dimmer.brightness - Shd.req_brightness) * 0.8; // Payload format: // [0-1] Brightness (%) * 10 // [2-3] Delta brightness (%) * 8 // [4-5] 0?? ToDo(jamesturton): Find out what this word is! uint8_t payload[SHD_SWITCH_FADE_SIZE]; payload[0] = Shd.req_brightness & 0xff; payload[1] = Shd.req_brightness >> 8; payload[2] = delta & 0xff; payload[3] = delta >> 8; payload[4] = 0; payload[5] = 0; ShdSendCmd(SHD_SWITCH_FADE_CMD, payload, SHD_SWITCH_FADE_SIZE); } void ShdSendSettings() { // as specified in STM32 assembly uint16_t fade_rate = Shd.req_fade_rate; if (fade_rate > 100) fade_rate = 100; // Payload format: // [0-1] Brightness (%) * 10 // [2-3] Leading / trailing edge (1=leading, 2=trailing) ToDo(jamesturton): Are there any other values this can take? // [4-5] Fade rate (units unknown) ToDo(jamesturton): Find fade rate units // [6-7] Warm up brightness (%) * 10 // [8-9] Warm up duration (ms) uint8_t payload[SHD_SETTINGS_SIZE]; payload[0] = Shd.req_brightness & 0xff; payload[1] = Shd.req_brightness >> 8; payload[2] = Shd.leading_edge & 0xff; payload[3] = Shd.leading_edge >> 8; payload[4] = fade_rate & 0xff; payload[5] = fade_rate >> 8; payload[6] = Shd.warmup_brightness & 0xff; payload[7] = Shd.warmup_brightness >> 8; payload[8] = Shd.warmup_time & 0xff; payload[9] = Shd.warmup_time >> 8; ShdSendCmd(SHD_SETTINGS_CMD, payload, SHD_SETTINGS_SIZE); } void ShdSendWarmup() { // Payload format: // [0-1] Warm up brightness (%) * 10 // [2-3] Warm up duration (ms) uint8_t payload[SHD_WARMUP_SIZE]; payload[0] = Shd.warmup_brightness & 0xff; payload[1] = Shd.warmup_brightness >> 8; payload[2] = Shd.warmup_time & 0xff; payload[3] = Shd.warmup_time >> 8; ShdSendCmd(SHD_WARMUP_CMD, payload, SHD_WARMUP_SIZE); } void ShdSendCalibration(uint16_t brightness, uint16_t func, uint16_t fade_rate) { // Payload format: // ??? ToDo(jamesturton): Find calibration payload format! uint8_t payload[SHD_CALIBRATION_SIZE]; memset(payload, 0, sizeof(payload)); ShdSendCmd(SHD_CALIBRATION1_CMD, payload, SHD_CALIBRATION_SIZE); ShdSendCmd(SHD_CALIBRATION2_CMD, payload, SHD_CALIBRATION_SIZE); } bool ShdSyncState() { #ifdef SHELLY_DIMMER_DEBUG AddLog(LOG_LEVEL_DEBUG, PSTR(SHD_LOGNAME "Serial %p"), ShdSerial); AddLog(LOG_LEVEL_DEBUG, PSTR(SHD_LOGNAME "Set Brightness Want %d, Is %d"), Shd.req_brightness, Shd.dimmer.brightness); AddLog(LOG_LEVEL_DEBUG, PSTR(SHD_LOGNAME "Set Fade Want %d, Is %d"), Settings->light_speed, Shd.dimmer.fade_rate); #endif // SHELLY_DIMMER_DEBUG if (!ShdSerial) return false; #ifdef SHELLY_HW_DIMMING // TODO(jamesturton): HW dimming seems to conflict with SW dimming. See how // we can disbale SW dimming when using HW dimming. if (Settings->light_speed != Shd.dimmer.fade_rate) { ShdSetBrightnessFade(); ShdDebugState(); } else #endif // SHELLY_HW_DIMMING if (Shd.req_brightness != Shd.dimmer.brightness) { ShdSetBrightness(); ShdDebugState(); } return true; } void ShdDebugState() { #ifdef SHELLY_DIMMER_DEBUG AddLog(LOG_LEVEL_DEBUG, PSTR(SHD_LOGNAME "MCU v%d.%d, Brightness:%d(%d%%), Power:%d, Fade:%d"), Shd.dimmer.version_major, Shd.dimmer.version_minor, Shd.dimmer.brightness, changeUIntScale(Shd.dimmer.brightness, 0, 1000, 0, 100), Shd.dimmer.power, Shd.dimmer.fade_rate); #endif // SHELLY_DIMMER_DEBUG } bool ShdPacketProcess(void) { uint8_t pos = 0; uint8_t id, cmd, len; bool ret = false; if (Shd.buffer[pos++] != SHD_START_BYTE) return false; id = Shd.buffer[pos++]; cmd = Shd.buffer[pos++]; len = Shd.buffer[pos++]; switch (cmd) { case SHD_POLL_CMD: { // 1 when returning fade_rate, 0 when returning wattage, brightness? uint8_t hw_version_raw = Shd.buffer[pos + 0]; uint16_t unknown_0 = Shd.buffer[pos + 1]; uint16_t brightness = Shd.buffer[pos + 3] << 8 | Shd.buffer[pos + 2]; uint32_t wattage_raw = Shd.buffer[pos + 7] << 24 | Shd.buffer[pos + 6] << 16 | Shd.buffer[pos + 5] << 8 | Shd.buffer[pos + 4]; uint32_t voltage_raw = Shd.buffer[pos + 11] << 24 | Shd.buffer[pos + 10] << 16 | Shd.buffer[pos + 9] << 8 | Shd.buffer[pos + 8]; uint32_t current_raw = Shd.buffer[pos + 15] << 24 | Shd.buffer[pos + 14] << 16 | Shd.buffer[pos + 13] << 8 | Shd.buffer[pos + 12]; uint32_t fade_rate = Shd.buffer[pos + 16]; float wattage = 0; if (wattage_raw > 0) wattage = 880373 / (float)wattage_raw; float voltage = 0; if (voltage_raw > 0) voltage = 347800 / (float)voltage_raw; float current = 0; if (current_raw > 0) current = 1448 / (float)current_raw; if (hw_version_raw == 0) Shd.hw_version = 1; else if (hw_version_raw == 1) Shd.hw_version = 2; #ifdef USE_ENERGY_SENSOR if (Shd.hw_version == 2) { Energy->current_available = true; Energy->voltage_available = true; } Energy->active_power[0] = wattage; Energy->voltage[0] = voltage; Energy->current[0] = current; if (Shd.last_power_check > 10 && Energy->active_power[0] > 0) { uint32_t time_passed = abs(TimePassedSince(Shd.last_power_check)); // Time passed in milliseconds uint32_t deca_microWh = (uint32_t)(Energy->active_power[0] * time_passed) / 36; #ifdef SHELLY_DIMMER_DEBUG AddLog(LOG_LEVEL_DEBUG, PSTR(SHD_LOGNAME "%4_f W is %u dmWh during %u ms"), &Energy->active_power[0], deca_microWh, time_passed); #endif // SHELLY_DIMMER_DEBUG Energy->kWhtoday_delta[0] += deca_microWh; EnergyUpdateToday(); } Shd.last_power_check = millis(); #endif // USE_ENERGY_SENSOR #ifdef SHELLY_DIMMER_DEBUG AddLog(LOG_LEVEL_DEBUG, PSTR(SHD_LOGNAME "ShdPacketProcess: Dimmer %d Brightness:%d Power:%lu Voltage:%lu Current:%lu Fade:%d"), Shd.hw_version, brightness, wattage_raw, voltage_raw, current_raw, fade_rate); #endif // SHELLY_DIMMER_DEBUG Shd.dimmer.brightness = brightness; Shd.dimmer.power = wattage_raw; Shd.dimmer.fade_rate = fade_rate; } break; case SHD_VERSION_CMD: { #ifdef SHELLY_DIMMER_DEBUG AddLog(LOG_LEVEL_DEBUG, PSTR(SHD_LOGNAME "ShdPacketProcess: Version: %u.%u"), Shd.buffer[pos + 1], Shd.buffer[pos]); #endif // SHELLY_DIMMER_DEBUG Shd.dimmer.version_minor = Shd.buffer[pos]; Shd.dimmer.version_major = Shd.buffer[pos + 1]; } break; case SHD_SWITCH_CMD: case SHD_SWITCH_FADE_CMD: case SHD_SETTINGS_CMD: case SHD_WARMUP_CMD: case SHD_CALIBRATION1_CMD: case SHD_CALIBRATION2_CMD: { ret = (Shd.buffer[pos] == 0x01); } break; } return ret; } void ShdResetToAppMode() { #ifdef SHELLY_DIMMER_DEBUG AddLog(LOG_LEVEL_DEBUG, PSTR(SHD_LOGNAME "Request co-processor reset in app mode")); #endif // SHELLY_DIMMER_DEBUG pinMode(Pin(GPIO_SHELLY_DIMMER_RST_INV), OUTPUT); digitalWrite(Pin(GPIO_SHELLY_DIMMER_RST_INV), LOW); pinMode(Pin(GPIO_SHELLY_DIMMER_BOOT0), OUTPUT); digitalWrite(Pin(GPIO_SHELLY_DIMMER_BOOT0), LOW); delay(50); // clear in the receive buffer while (Serial.available()) Serial.read(); digitalWrite(Pin(GPIO_SHELLY_DIMMER_RST_INV), HIGH); // pull out of reset delay(50); // wait 50ms fot the co-processor to come online } void ShdPoll(void) { #ifdef SHELLY_DIMMER_DEBUG AddLog(LOG_LEVEL_DEBUG, PSTR(SHD_LOGNAME "Poll")); #endif // SHELLY_DIMMER_DEBUG if (!ShdSerial) return; ShdSendCmd(SHD_POLL_CMD, 0, 0); ShdSyncState(); } bool ShdSendVersion(void) { #ifdef SHELLY_DIMMER_DEBUG AddLog(LOG_LEVEL_INFO, PSTR(SHD_LOGNAME "Sending version command")); #endif // SHELLY_DIMMER_DEBUG return ShdSendCmd(SHD_VERSION_CMD, 0, 0); } void ShdGetSettings(void) { char parameters[32]; // Shd.req_brightness = 0; Shd.leading_edge = 0; // Shd.req_fade_rate = 0; Shd.warmup_brightness = 0; Shd.warmup_time = 0; if (strstr(SettingsText(SET_SHD_PARAM), ",") != nullptr) { #ifdef SHELLY_DIMMER_DEBUG AddLog(LOG_LEVEL_INFO, PSTR(SHD_LOGNAME "Loading params: %s"), SettingsText(SET_SHD_PARAM)); #endif // SHELLY_DIMMER_DEBUG // Shd.req_brightness = atoi(subStr(parameters, SettingsText(SET_SHD_PARAM), ",", 1)); Shd.leading_edge = atoi(subStr(parameters, SettingsText(SET_SHD_PARAM), ",", 2)); // Shd.req_fade_rate = atoi(subStr(parameters, SettingsText(SET_SHD_PARAM), ",", 3)); Shd.warmup_brightness = atoi(subStr(parameters, SettingsText(SET_SHD_PARAM), ",", 4)); Shd.warmup_time = atoi(subStr(parameters, SettingsText(SET_SHD_PARAM), ",", 5)); } } void ShdSaveSettings(void) { char parameters[32]; snprintf_P(parameters, sizeof(parameters), PSTR("%d,%d,%d,%d,%d"), Shd.req_brightness, Shd.leading_edge, Shd.req_fade_rate, Shd.warmup_brightness, Shd.warmup_time); SettingsUpdateText(SET_SHD_PARAM, parameters); } void ShdInit(void) { #ifdef SHELLY_DIMMER_DEBUG AddLog(LOG_LEVEL_INFO, PSTR(SHD_LOGNAME "Shelly Dimmer Driver Starting Tx %d Rx %d"), Pin(GPIO_TXD), Pin(GPIO_RXD)); #endif // SHELLY_DIMMER_DEBUG Shd.buffer = (uint8_t *)malloc(SHD_BUFFER_SIZE); if (Shd.buffer != nullptr) { ShdSerial = new TasmotaSerial(Pin(GPIO_RXD), Pin(GPIO_TXD), 2, 0, SHD_BUFFER_SIZE); if (ShdSerial->begin(115200)) { if (ShdSerial->hardwareSerial()) ClaimSerial(); ShdSerial->flush(); ShdResetToAppMode(); bool got_version = ShdSendVersion(); AddLog(LOG_LEVEL_INFO, PSTR(SHD_LOGNAME "Shelly Dimmer Co-processor Version v%u.%u"), Shd.dimmer.version_major, Shd.dimmer.version_minor); ShdGetSettings(); ShdSaveSettings(); ShdSendSettings(); ShdSyncState(); } } } bool ShdSerialInput(void) { while (ShdSerial->available()) { yield(); uint8_t serial_in_byte = ShdSerial->read(); Shd.buffer[Shd.byte_counter] = serial_in_byte; int check = check_byte(); if (check > 1) { // finished #ifdef SHELLY_DIMMER_DEBUG Shd.byte_counter++; AddLog(LOG_LEVEL_DEBUG_MORE, PSTR(SHD_LOGNAME "Rx Packet %*_H"), Shd.byte_counter, Shd.buffer); #endif // SHELLY_DIMMER_DEBUG Shd.byte_counter = 0; ShdPacketProcess(); return true; } else if (check == 0) { // wrong data #ifdef SHELLY_DIMMER_DEBUG AddLog(LOG_LEVEL_DEBUG, PSTR(SHD_LOGNAME "Byte %i of received data frame is invalid. Rx Packet %*_H"), Shd.byte_counter, Shd.byte_counter +1, Shd.buffer); #endif // SHELLY_DIMMER_DEBUG Shd.byte_counter = 0; } else { Shd.byte_counter++; } } return false; } /*********************************************************************************************\ * API Functions \*********************************************************************************************/ bool ShdModuleSelected(void) { if (PinUsed(GPIO_SHELLY_DIMMER_BOOT0) && PinUsed(GPIO_SHELLY_DIMMER_RST_INV)) { UpdateDevicesPresent(1); TasmotaGlobal.light_type = LT_SERIAL1; Shd.present = true; } return Shd.present; } bool ShdSetChannels(void) { #ifdef SHELLY_DIMMER_DEBUG AddLog(LOG_LEVEL_DEBUG_MORE, PSTR(SHD_LOGNAME "SetChannels %*_H"), XdrvMailbox.data_len, (uint8_t *)XdrvMailbox.data); #endif // SHELLY_DIMMER_DEBUG uint16_t brightness = ((uint32_t *)XdrvMailbox.data)[0]; // Use dimmer_hw_min and dimmer_hw_max to constrain our values if the light should be on if (brightness > 0) brightness = changeUIntScale(brightness, 0, 255, Settings->dimmer_hw_min * 10, Settings->dimmer_hw_max * 10); Shd.req_brightness = brightness; ShdDebugState(); return ShdSyncState(); } bool ShdSetPower(void) { #ifdef SHELLY_DIMMER_DEBUG AddLog(LOG_LEVEL_INFO, PSTR(SHD_LOGNAME "Set Power, Power 0x%02x"), XdrvMailbox.index); #endif // SHELLY_DIMMER_DEBUG Shd.req_on = (bool)XdrvMailbox.index; return ShdSyncState(); } /*********************************************************************************************\ * Commands \*********************************************************************************************/ #ifdef SHELLY_CMDS const char kShdCommands[] PROGMEM = D_PRFX_SHD "|" // Prefix D_CMND_LEADINGEDGE "|" D_CMND_WARMUPBRIGHTNESS "|" D_CMND_WARMUPTIME; void (* const ShdCommand[])(void) PROGMEM = { &CmndShdLeadingEdge, &CmndShdWarmupBrightness, &CmndShdWarmupTime }; void CmndShdLeadingEdge(void) { if (XdrvMailbox.payload == 0 || XdrvMailbox.payload == 1) { Shd.leading_edge = 2 - XdrvMailbox.payload; Settings->shd_leading_edge = XdrvMailbox.payload; #ifdef SHELLY_DIMMER_DEBUG if (Shd.leading_edge == 1) AddLog(LOG_LEVEL_DEBUG, PSTR(SHD_LOGNAME "Set to trailing edge")); else AddLog(LOG_LEVEL_DEBUG, PSTR(SHD_LOGNAME "Set to leading edge")); #endif // SHELLY_DIMMER_DEBUG ShdSendSettings(); } ShdSaveSettings(); ResponseCmndNumber(Settings->shd_leading_edge); } void CmndShdWarmupBrightness(void) { if ((10 <= XdrvMailbox.payload) && (XdrvMailbox.payload <= 100)) { Shd.warmup_brightness = XdrvMailbox.payload * 10; Settings->shd_warmup_brightness = XdrvMailbox.payload; #ifdef SHELLY_DIMMER_DEBUG AddLog(LOG_LEVEL_DEBUG, PSTR(SHD_LOGNAME "Set warmup brightness to %d%%"), XdrvMailbox.payload); #endif // SHELLY_DIMMER_DEBUG ShdSendSettings(); } ShdSaveSettings(); ResponseCmndNumber(Settings->shd_warmup_brightness); } void CmndShdWarmupTime(void) { if ((20 <= XdrvMailbox.payload) && (XdrvMailbox.payload <= 200)) { Shd.warmup_time = XdrvMailbox.payload; Settings->shd_warmup_time = XdrvMailbox.payload; #ifdef SHELLY_DIMMER_DEBUG AddLog(LOG_LEVEL_DEBUG, PSTR(SHD_LOGNAME "Set warmup time to %dms"), XdrvMailbox.payload); #endif // SHELLY_DIMMER_DEBUG ShdSendSettings(); } ShdSaveSettings(); ResponseCmndNumber(Settings->shd_warmup_time); } #endif // SHELLY_CMDS /*********************************************************************************************\ * Energy Interface \*********************************************************************************************/ #ifdef USE_ENERGY_SENSOR bool Xnrg31(uint32_t function) { bool result = false; if (Shd.present) { if (FUNC_PRE_INIT == function) { #ifndef SHELLY_VOLTAGE_MON Energy->current_available = false; Energy->voltage_available = false; #endif // SHELLY_VOLTAGE_MON Energy->use_overtemp = true; // Use global temperature for overtemp detection TasmotaGlobal.energy_driver = XNRG_31; } } return result; } #endif // USE_ENERGY_SENSOR /*********************************************************************************************\ * Driver Interface \*********************************************************************************************/ bool Xdrv45(uint32_t function) { bool result = false; if (FUNC_MODULE_INIT == function) { result = ShdModuleSelected(); } else if (Shd.present) { switch (function) { case FUNC_EVERY_SECOND: ShdPoll(); break; case FUNC_INIT: ShdInit(); break; case FUNC_SET_DEVICE_POWER: result = ShdSetPower(); break; case FUNC_SET_CHANNELS: result = ShdSetChannels(); break; #ifdef SHELLY_CMDS case FUNC_COMMAND: result = DecodeCommand(kShdCommands, ShdCommand); break; #endif // SHELLY_CMDS } } return result; } #endif // USE_SHELLY_DIMMER #endif // USE_LIGHT