/* settings.ino - user settings for Sonoff-Tasmota Copyright (C) 2019 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 . */ #ifndef DOMOTICZ_UPDATE_TIMER #define DOMOTICZ_UPDATE_TIMER 0 // [DomoticzUpdateTimer] Send relay status (0 = disable, 1 - 3600 seconds) (Optional) #endif #ifndef EMULATION #define EMULATION EMUL_NONE // [Emulation] Select Belkin WeMo (single relay/light) or Hue Bridge emulation (multi relay/light) (EMUL_NONE, EMUL_WEMO or EMUL_HUE) #endif #ifndef MTX_ADDRESS1 // Add Display Support for up to eigth Matrices #define MTX_ADDRESS1 0 #endif #ifndef MTX_ADDRESS2 #define MTX_ADDRESS2 0 #endif #ifndef MTX_ADDRESS3 #define MTX_ADDRESS3 0 #endif #ifndef MTX_ADDRESS4 #define MTX_ADDRESS4 0 #endif #ifndef MTX_ADDRESS5 #define MTX_ADDRESS5 0 #endif #ifndef MTX_ADDRESS6 #define MTX_ADDRESS6 0 #endif #ifndef MTX_ADDRESS7 #define MTX_ADDRESS7 0 #endif #ifndef MTX_ADDRESS8 #define MTX_ADDRESS8 0 #endif #ifndef HOME_ASSISTANT_DISCOVERY_ENABLE #define HOME_ASSISTANT_DISCOVERY_ENABLE 0 #endif #ifndef LATITUDE #define LATITUDE 48.858360 // [Latitude] Your location to be used with sunrise and sunset #endif #ifndef LONGITUDE #define LONGITUDE 2.294442 // [Longitude] Your location to be used with sunrise and sunset #endif /*********************************************************************************************\ * RTC memory \*********************************************************************************************/ #define RTC_MEM_VALID 0xA55A uint32_t rtc_settings_crc = 0; uint32_t GetRtcSettingsCrc(void) { uint32_t crc = 0; uint8_t *bytes = (uint8_t*)&RtcSettings; for (uint16_t i = 0; i < sizeof(RTCMEM); i++) { crc += bytes[i]*(i+1); } return crc; } void RtcSettingsSave(void) { if (GetRtcSettingsCrc() != rtc_settings_crc) { RtcSettings.valid = RTC_MEM_VALID; ESP.rtcUserMemoryWrite(100, (uint32_t*)&RtcSettings, sizeof(RTCMEM)); rtc_settings_crc = GetRtcSettingsCrc(); } } void RtcSettingsLoad(void) { ESP.rtcUserMemoryRead(100, (uint32_t*)&RtcSettings, sizeof(RTCMEM)); // 0x290 if (RtcSettings.valid != RTC_MEM_VALID) { memset(&RtcSettings, 0, sizeof(RTCMEM)); RtcSettings.valid = RTC_MEM_VALID; RtcSettings.energy_kWhtoday = Settings.energy_kWhtoday; RtcSettings.energy_kWhtotal = Settings.energy_kWhtotal; for (uint8_t i = 0; i < MAX_COUNTERS; i++) { RtcSettings.pulse_counter[i] = Settings.pulse_counter[i]; } RtcSettings.power = Settings.power; RtcSettingsSave(); } rtc_settings_crc = GetRtcSettingsCrc(); } bool RtcSettingsValid(void) { return (RTC_MEM_VALID == RtcSettings.valid); } /********************************************************************************************/ uint32_t rtc_reboot_crc = 0; uint32_t GetRtcRebootCrc(void) { uint32_t crc = 0; uint8_t *bytes = (uint8_t*)&RtcReboot; for (uint16_t i = 0; i < sizeof(RTCRBT); i++) { crc += bytes[i]*(i+1); } return crc; } void RtcRebootSave(void) { if (GetRtcRebootCrc() != rtc_reboot_crc) { RtcReboot.valid = RTC_MEM_VALID; ESP.rtcUserMemoryWrite(100 - sizeof(RTCRBT), (uint32_t*)&RtcReboot, sizeof(RTCRBT)); rtc_reboot_crc = GetRtcRebootCrc(); } } void RtcRebootLoad(void) { ESP.rtcUserMemoryRead(100 - sizeof(RTCRBT), (uint32_t*)&RtcReboot, sizeof(RTCRBT)); // 0x280 if (RtcReboot.valid != RTC_MEM_VALID) { memset(&RtcReboot, 0, sizeof(RTCRBT)); RtcReboot.valid = RTC_MEM_VALID; // RtcReboot.fast_reboot_count = 0; // Explicit by memset RtcRebootSave(); } rtc_reboot_crc = GetRtcRebootCrc(); } bool RtcRebootValid(void) { return (RTC_MEM_VALID == RtcReboot.valid); } /*********************************************************************************************\ * Config - Flash \*********************************************************************************************/ extern "C" { #include "spi_flash.h" } #include "eboot_command.h" extern "C" uint32_t _SPIFFS_end; // From libraries/EEPROM/EEPROM.cpp EEPROMClass #define SPIFFS_END ((uint32_t)&_SPIFFS_end - 0x40200000) / SPI_FLASH_SEC_SIZE // Version 4.2 config = eeprom area #define SETTINGS_LOCATION SPIFFS_END // No need for SPIFFS as it uses EEPROM area // Version 5.2 allow for more flash space #define CFG_ROTATES 8 // Number of flash sectors used (handles uploads) /*********************************************************************************************\ * EEPROM support based on EEPROM library and tuned for Tasmota \*********************************************************************************************/ uint32_t eeprom_sector = SPIFFS_END; uint8_t* eeprom_data = 0; size_t eeprom_size = 0; bool eeprom_dirty = false; void EepromBegin(size_t size) { if (size <= 0) { return; } if (size > SPI_FLASH_SEC_SIZE - sizeof(Settings) -4) { size = SPI_FLASH_SEC_SIZE - sizeof(Settings) -4; } size = (size + 3) & (~3); // In case begin() is called a 2nd+ time, don't reallocate if size is the same if (eeprom_data && size != eeprom_size) { delete[] eeprom_data; eeprom_data = new uint8_t[size]; } else if (!eeprom_data) { eeprom_data = new uint8_t[size]; } eeprom_size = size; size_t flash_offset = SPI_FLASH_SEC_SIZE - eeprom_size; uint8_t* flash_buffer; flash_buffer = new uint8_t[SPI_FLASH_SEC_SIZE]; noInterrupts(); spi_flash_read(eeprom_sector * SPI_FLASH_SEC_SIZE, reinterpret_cast(flash_buffer), SPI_FLASH_SEC_SIZE); interrupts(); memcpy(eeprom_data, flash_buffer + flash_offset, eeprom_size); delete[] flash_buffer; eeprom_dirty = false; // make sure dirty is cleared in case begin() is called 2nd+ time } size_t EepromLength(void) { return eeprom_size; } uint8_t EepromRead(int const address) { if (address < 0 || (size_t)address >= eeprom_size) { return 0; } if (!eeprom_data) { return 0; } return eeprom_data[address]; } // Prototype needed for Arduino IDE - https://forum.arduino.cc/index.php?topic=406509.0 template T EepromGet(int const address, T &t); template T EepromGet(int const address, T &t) { if (address < 0 || address + sizeof(T) > eeprom_size) { return t; } if (!eeprom_data) { return 0; } memcpy((uint8_t*) &t, eeprom_data + address, sizeof(T)); return t; } void EepromWrite(int const address, uint8_t const value) { if (address < 0 || (size_t)address >= eeprom_size) { return; } if (!eeprom_data) { return; } // Optimise eeprom_dirty. Only flagged if data written is different. uint8_t* pData = &eeprom_data[address]; if (*pData != value) { *pData = value; eeprom_dirty = true; } } // Prototype needed for Arduino IDE - https://forum.arduino.cc/index.php?topic=406509.0 template void EepromPut(int const address, const T &t); template void EepromPut(int const address, const T &t) { if (address < 0 || address + sizeof(T) > eeprom_size) { return; } if (!eeprom_data) { return; } // Optimise eeprom_dirty. Only flagged if data written is different. if (memcmp(eeprom_data + address, (const uint8_t*)&t, sizeof(T)) != 0) { eeprom_dirty = true; memcpy(eeprom_data + address, (const uint8_t*)&t, sizeof(T)); } } bool EepromCommit(void) { bool ret = false; if (!eeprom_size) { return false; } if (!eeprom_dirty) { return true; } if (!eeprom_data) { return false; } size_t flash_offset = SPI_FLASH_SEC_SIZE - eeprom_size; uint8_t* flash_buffer; flash_buffer = new uint8_t[SPI_FLASH_SEC_SIZE]; noInterrupts(); spi_flash_read(eeprom_sector * SPI_FLASH_SEC_SIZE, reinterpret_cast(flash_buffer), SPI_FLASH_SEC_SIZE); memcpy(flash_buffer + flash_offset, eeprom_data, eeprom_size); if (spi_flash_erase_sector(eeprom_sector) == SPI_FLASH_RESULT_OK) { if (spi_flash_write(eeprom_sector * SPI_FLASH_SEC_SIZE, reinterpret_cast(flash_buffer), SPI_FLASH_SEC_SIZE) == SPI_FLASH_RESULT_OK) { eeprom_dirty = false; ret = true; } } interrupts(); delete[] flash_buffer; return ret; } uint8_t * EepromGetDataPtr() { eeprom_dirty = true; return &eeprom_data[0]; } void EepromEnd(void) { if (!eeprom_size) { return; } EepromCommit(); if (eeprom_data) { delete[] eeprom_data; } eeprom_data = 0; eeprom_size = 0; eeprom_dirty = false; } /********************************************************************************************/ uint16_t settings_crc = 0; uint32_t settings_location = SETTINGS_LOCATION; uint8_t *settings_buffer = nullptr; /********************************************************************************************/ /* * Based on cores/esp8266/Updater.cpp */ void SetFlashModeDout(void) { uint8_t *_buffer; uint32_t address; eboot_command ebcmd; eboot_command_read(&ebcmd); address = ebcmd.args[0]; _buffer = new uint8_t[FLASH_SECTOR_SIZE]; if (ESP.flashRead(address, (uint32_t*)_buffer, FLASH_SECTOR_SIZE)) { if (_buffer[2] != 3) { // DOUT _buffer[2] = 3; if (ESP.flashEraseSector(address / FLASH_SECTOR_SIZE)) ESP.flashWrite(address, (uint32_t*)_buffer, FLASH_SECTOR_SIZE); } } delete[] _buffer; } void SettingsBufferFree(void) { if (settings_buffer != nullptr) { free(settings_buffer); settings_buffer = nullptr; } } bool SettingsBufferAlloc(void) { SettingsBufferFree(); if (!(settings_buffer = (uint8_t *)malloc(sizeof(Settings)))) { AddLog_P(LOG_LEVEL_DEBUG, PSTR(D_LOG_APPLICATION D_UPLOAD_ERR_2)); // Not enough (memory) space return false; } return true; } uint16_t GetSettingsCrc(void) { uint16_t crc = 0; uint8_t *bytes = (uint8_t*)&Settings; for (uint16_t i = 0; i < sizeof(SYSCFG); i++) { if ((i < 14) || (i > 15)) { crc += bytes[i]*(i+1); } // Skip crc } return crc; } void SettingsSaveAll(void) { if (Settings.flag.save_state) { Settings.power = power; } else { Settings.power = 0; } XsnsCall(FUNC_SAVE_BEFORE_RESTART); EepromCommit(); SettingsSave(0); } /*********************************************************************************************\ * Config Save - Save parameters to Flash ONLY if any parameter has changed \*********************************************************************************************/ uint32_t GetSettingsAddress(void) { return settings_location * SPI_FLASH_SEC_SIZE; } void SettingsSave(uint8_t rotate) { /* Save configuration in eeprom or one of 7 slots below * * rotate 0 = Save in next flash slot * rotate 1 = Save only in eeprom flash slot until SetOption12 0 or restart * rotate 2 = Save in eeprom flash slot, erase next flash slots and continue depending on stop_flash_rotate * stop_flash_rotate 0 = Allow flash slot rotation (SetOption12 0) * stop_flash_rotate 1 = Allow only eeprom flash slot use (SetOption12 1) */ #ifndef FIRMWARE_MINIMAL if ((GetSettingsCrc() != settings_crc) || rotate) { if (1 == rotate) { // Use eeprom flash slot only and disable flash rotate from now on (upgrade) stop_flash_rotate = 1; } if (2 == rotate) { // Use eeprom flash slot and erase next flash slots if stop_flash_rotate is off (default) settings_location = SETTINGS_LOCATION +1; } if (stop_flash_rotate) { settings_location = SETTINGS_LOCATION; } else { settings_location--; if (settings_location <= (SETTINGS_LOCATION - CFG_ROTATES)) { settings_location = SETTINGS_LOCATION; } } Settings.save_flag++; Settings.cfg_size = sizeof(SYSCFG); Settings.cfg_crc = GetSettingsCrc(); if (SPIFFS_END == settings_location) { uint8_t* flash_buffer; flash_buffer = new uint8_t[SPI_FLASH_SEC_SIZE]; if (eeprom_data && eeprom_size) { size_t flash_offset = SPI_FLASH_SEC_SIZE - eeprom_size; memcpy(flash_buffer + flash_offset, eeprom_data, eeprom_size); // Write dirty EEPROM data } else { ESP.flashRead(settings_location * SPI_FLASH_SEC_SIZE, (uint32*)flash_buffer, SPI_FLASH_SEC_SIZE); // Read EEPROM area } memcpy(flash_buffer, &Settings, sizeof(Settings)); ESP.flashEraseSector(settings_location); ESP.flashWrite(settings_location * SPI_FLASH_SEC_SIZE, (uint32*)flash_buffer, SPI_FLASH_SEC_SIZE); delete[] flash_buffer; } else { ESP.flashEraseSector(settings_location); ESP.flashWrite(settings_location * SPI_FLASH_SEC_SIZE, (uint32*)&Settings, sizeof(SYSCFG)); } if (!stop_flash_rotate && rotate) { for (uint8_t i = 1; i < CFG_ROTATES; i++) { ESP.flashEraseSector(settings_location -i); // Delete previous configurations by resetting to 0xFF delay(1); } } AddLog_P2(LOG_LEVEL_DEBUG, PSTR(D_LOG_CONFIG D_SAVED_TO_FLASH_AT " %X, " D_COUNT " %d, " D_BYTES " %d"), settings_location, Settings.save_flag, sizeof(SYSCFG)); settings_crc = Settings.cfg_crc; } #endif // FIRMWARE_MINIMAL RtcSettingsSave(); } void SettingsLoad(void) { // Load configuration from eeprom or one of 7 slots below if first valid load does not stop_flash_rotate struct SYSCFGH { uint16_t cfg_holder; // 000 uint16_t cfg_size; // 002 unsigned long save_flag; // 004 } _SettingsH; unsigned long save_flag = 0; settings_location = 0; uint32_t flash_location = SETTINGS_LOCATION +1; for (uint8_t i = 0; i < CFG_ROTATES; i++) { flash_location--; ESP.flashRead(flash_location * SPI_FLASH_SEC_SIZE, (uint32*)&Settings, sizeof(SYSCFG)); bool valid = false; if (Settings.version > 0x06000000) { valid = (Settings.cfg_crc == GetSettingsCrc()); } else { ESP.flashRead((flash_location -1) * SPI_FLASH_SEC_SIZE, (uint32*)&_SettingsH, sizeof(SYSCFGH)); valid = (Settings.cfg_holder == _SettingsH.cfg_holder); } if (valid) { if (Settings.save_flag > save_flag) { save_flag = Settings.save_flag; settings_location = flash_location; if (Settings.flag.stop_flash_rotate && (0 == i)) { // Stop only if eeprom area should be used and it is valid break; } } } delay(1); } if (settings_location > 0) { ESP.flashRead(settings_location * SPI_FLASH_SEC_SIZE, (uint32*)&Settings, sizeof(SYSCFG)); AddLog_P2(LOG_LEVEL_DEBUG, PSTR(D_LOG_CONFIG D_LOADED_FROM_FLASH_AT " %X, " D_COUNT " %d"), settings_location, Settings.save_flag); } #ifndef FIRMWARE_MINIMAL if (!settings_location || (Settings.cfg_holder != (uint16_t)CFG_HOLDER)) { // Init defaults if cfg_holder differs from user settings in my_user_config.h SettingsDefault(); } settings_crc = GetSettingsCrc(); #endif // FIRMWARE_MINIMAL RtcSettingsLoad(); } void SettingsErase(uint8_t type) { /* 0 = Erase from program end until end of physical flash 1 = Erase SDK parameter area at end of linker memory model (0x0FDxxx - 0x0FFFFF) solving possible wifi errors */ #ifndef FIRMWARE_MINIMAL bool result; uint32_t _sectorStart = (ESP.getSketchSize() / SPI_FLASH_SEC_SIZE) + 1; uint32_t _sectorEnd = ESP.getFlashChipRealSize() / SPI_FLASH_SEC_SIZE; if (1 == type) { _sectorStart = SETTINGS_LOCATION +2; // SDK parameter area above EEPROM area (0x0FDxxx - 0x0FFFFF) _sectorEnd = SETTINGS_LOCATION +5; } bool _serialoutput = (LOG_LEVEL_DEBUG_MORE <= seriallog_level); AddLog_P2(LOG_LEVEL_DEBUG, PSTR(D_LOG_APPLICATION D_ERASE " %d " D_UNIT_SECTORS), _sectorEnd - _sectorStart); for (uint32_t _sector = _sectorStart; _sector < _sectorEnd; _sector++) { result = ESP.flashEraseSector(_sector); if (_serialoutput) { Serial.print(F(D_LOG_APPLICATION D_ERASED_SECTOR " ")); Serial.print(_sector); if (result) { Serial.println(F(" " D_OK)); } else { Serial.println(F(" " D_ERROR)); } delay(10); } OsWatchLoop(); } #endif // FIRMWARE_MINIMAL } // Copied from 2.4.0 as 2.3.0 is incomplete bool SettingsEraseConfig(void) { const size_t cfgSize = 0x4000; size_t cfgAddr = ESP.getFlashChipSize() - cfgSize; for (size_t offset = 0; offset < cfgSize; offset += SPI_FLASH_SEC_SIZE) { if (!ESP.flashEraseSector((cfgAddr + offset) / SPI_FLASH_SEC_SIZE)) { return false; } } return true; } void SettingsSdkErase(void) { WiFi.disconnect(true); // Delete SDK wifi config SettingsErase(1); SettingsEraseConfig(); delay(1000); } /********************************************************************************************/ void SettingsDefault(void) { AddLog_P(LOG_LEVEL_NONE, PSTR(D_LOG_CONFIG D_USE_DEFAULTS)); SettingsDefaultSet1(); SettingsDefaultSet2(); SettingsSave(2); } void SettingsDefaultSet1(void) { memset(&Settings, 0x00, sizeof(SYSCFG)); Settings.cfg_holder = (uint16_t)CFG_HOLDER; Settings.cfg_size = sizeof(SYSCFG); // Settings.save_flag = 0; Settings.version = VERSION; // Settings.bootcount = 0; // Settings.cfg_crc = 0; } void SettingsDefaultSet2(void) { memset((char*)&Settings +16, 0x00, sizeof(SYSCFG) -16); // Settings.flag.value_units = 0; // Settings.flag.stop_flash_rotate = 0; Settings.save_data = SAVE_DATA; Settings.param[P_BOOT_LOOP_OFFSET] = BOOT_LOOP_OFFSET; Settings.param[P_RGB_REMAP] = RGB_REMAP_RGBW; Settings.sleep = APP_SLEEP; if (Settings.sleep < 50) { Settings.sleep = 50; // Default to 50 for sleep, for now } // Module // Settings.flag.interlock = 0; Settings.interlock[0] = 0xFF; // Legacy support using all relays in one interlock group Settings.module = MODULE; ModuleDefault(WEMOS); // for (uint8_t i = 0; i < sizeof(Settings.my_gp); i++) { Settings.my_gp.io[i] = GPIO_NONE; } strlcpy(Settings.friendlyname[0], FRIENDLY_NAME, sizeof(Settings.friendlyname[0])); strlcpy(Settings.friendlyname[1], FRIENDLY_NAME"2", sizeof(Settings.friendlyname[1])); strlcpy(Settings.friendlyname[2], FRIENDLY_NAME"3", sizeof(Settings.friendlyname[2])); strlcpy(Settings.friendlyname[3], FRIENDLY_NAME"4", sizeof(Settings.friendlyname[3])); strlcpy(Settings.ota_url, OTA_URL, sizeof(Settings.ota_url)); // Power Settings.flag.save_state = SAVE_STATE; Settings.power = APP_POWER; Settings.poweronstate = APP_POWERON_STATE; Settings.blinktime = APP_BLINKTIME; Settings.blinkcount = APP_BLINKCOUNT; Settings.ledstate = APP_LEDSTATE; Settings.pulse_timer[0] = APP_PULSETIME; // for (uint8_t i = 1; i < MAX_PULSETIMERS; i++) { Settings.pulse_timer[i] = 0; } // Serial Settings.baudrate = APP_BAUDRATE / 1200; Settings.sbaudrate = SOFT_BAUDRATE / 1200; Settings.serial_delimiter = 0xff; Settings.seriallog_level = SERIAL_LOG_LEVEL; // Wifi ParseIp(&Settings.ip_address[0], WIFI_IP_ADDRESS); ParseIp(&Settings.ip_address[1], WIFI_GATEWAY); ParseIp(&Settings.ip_address[2], WIFI_SUBNETMASK); ParseIp(&Settings.ip_address[3], WIFI_DNS); Settings.sta_config = WIFI_CONFIG_TOOL; // Settings.sta_active = 0; strlcpy(Settings.sta_ssid[0], STA_SSID1, sizeof(Settings.sta_ssid[0])); strlcpy(Settings.sta_pwd[0], STA_PASS1, sizeof(Settings.sta_pwd[0])); strlcpy(Settings.sta_ssid[1], STA_SSID2, sizeof(Settings.sta_ssid[1])); strlcpy(Settings.sta_pwd[1], STA_PASS2, sizeof(Settings.sta_pwd[1])); strlcpy(Settings.hostname, WIFI_HOSTNAME, sizeof(Settings.hostname)); // Syslog strlcpy(Settings.syslog_host, SYS_LOG_HOST, sizeof(Settings.syslog_host)); Settings.syslog_port = SYS_LOG_PORT; Settings.syslog_level = SYS_LOG_LEVEL; // Webserver Settings.flag2.emulation = EMULATION; Settings.webserver = WEB_SERVER; Settings.weblog_level = WEB_LOG_LEVEL; strlcpy(Settings.web_password, WEB_PASSWORD, sizeof(Settings.web_password)); Settings.flag3.mdns_enabled = MDNS_ENABLED; // Button // Settings.flag.button_restrict = 0; // Settings.flag.button_swap = 0; // Settings.flag.button_single = 0; Settings.param[P_HOLD_TIME] = KEY_HOLD_TIME; // Default 4 seconds hold time // Switch for (uint8_t i = 0; i < MAX_SWITCHES; i++) { Settings.switchmode[i] = SWITCH_MODE; } // MQTT Settings.flag.mqtt_enabled = MQTT_USE; // Settings.flag.mqtt_response = 0; Settings.flag.mqtt_power_retain = MQTT_POWER_RETAIN; Settings.flag.mqtt_button_retain = MQTT_BUTTON_RETAIN; Settings.flag.mqtt_switch_retain = MQTT_SWITCH_RETAIN; Settings.flag3.button_switch_force_local = MQTT_BUTTON_SWITCH_FORCE_LOCAL; Settings.flag3.hass_tele_on_power = TELE_ON_POWER; // Settings.flag.mqtt_sensor_retain = 0; // Settings.flag.mqtt_offline = 0; // Settings.flag.mqtt_serial = 0; // Settings.flag.device_index_enable = 0; strlcpy(Settings.mqtt_host, MQTT_HOST, sizeof(Settings.mqtt_host)); Settings.mqtt_port = MQTT_PORT; strlcpy(Settings.mqtt_client, MQTT_CLIENT_ID, sizeof(Settings.mqtt_client)); strlcpy(Settings.mqtt_user, MQTT_USER, sizeof(Settings.mqtt_user)); strlcpy(Settings.mqtt_pwd, MQTT_PASS, sizeof(Settings.mqtt_pwd)); strlcpy(Settings.mqtt_topic, MQTT_TOPIC, sizeof(Settings.mqtt_topic)); strlcpy(Settings.button_topic, MQTT_BUTTON_TOPIC, sizeof(Settings.button_topic)); strlcpy(Settings.switch_topic, MQTT_SWITCH_TOPIC, sizeof(Settings.switch_topic)); strlcpy(Settings.mqtt_grptopic, MQTT_GRPTOPIC, sizeof(Settings.mqtt_grptopic)); strlcpy(Settings.mqtt_fulltopic, MQTT_FULLTOPIC, sizeof(Settings.mqtt_fulltopic)); Settings.mqtt_retry = MQTT_RETRY_SECS; strlcpy(Settings.mqtt_prefix[0], SUB_PREFIX, sizeof(Settings.mqtt_prefix[0])); strlcpy(Settings.mqtt_prefix[1], PUB_PREFIX, sizeof(Settings.mqtt_prefix[1])); strlcpy(Settings.mqtt_prefix[2], PUB_PREFIX2, sizeof(Settings.mqtt_prefix[2])); strlcpy(Settings.state_text[0], MQTT_STATUS_OFF, sizeof(Settings.state_text[0])); strlcpy(Settings.state_text[1], MQTT_STATUS_ON, sizeof(Settings.state_text[1])); strlcpy(Settings.state_text[2], MQTT_CMND_TOGGLE, sizeof(Settings.state_text[2])); strlcpy(Settings.state_text[3], MQTT_CMND_HOLD, sizeof(Settings.state_text[3])); char fingerprint[60]; strlcpy(fingerprint, MQTT_FINGERPRINT1, sizeof(fingerprint)); char *p = fingerprint; for (uint8_t i = 0; i < 20; i++) { Settings.mqtt_fingerprint[0][i] = strtol(p, &p, 16); } strlcpy(fingerprint, MQTT_FINGERPRINT2, sizeof(fingerprint)); p = fingerprint; for (uint8_t i = 0; i < 20; i++) { Settings.mqtt_fingerprint[1][i] = strtol(p, &p, 16); } Settings.tele_period = TELE_PERIOD; // Energy Settings.flag2.current_resolution = 3; // Settings.flag2.voltage_resolution = 0; // Settings.flag2.wattage_resolution = 0; Settings.flag2.energy_resolution = ENERGY_RESOLUTION; Settings.param[P_MAX_POWER_RETRY] = MAX_POWER_RETRY; Settings.energy_power_delta = DEFAULT_POWER_DELTA; Settings.energy_power_calibration = HLW_PREF_PULSE; Settings.energy_voltage_calibration = HLW_UREF_PULSE; Settings.energy_current_calibration = HLW_IREF_PULSE; // Settings.energy_kWhtoday = 0; // Settings.energy_kWhyesterday = 0; // Settings.energy_kWhdoy = 0; // Settings.energy_min_power = 0; // Settings.energy_max_power = 0; // Settings.energy_min_voltage = 0; // Settings.energy_max_voltage = 0; // Settings.energy_min_current = 0; // Settings.energy_max_current = 0; // Settings.energy_max_power_limit = 0; // MaxPowerLimit Settings.energy_max_power_limit_hold = MAX_POWER_HOLD; Settings.energy_max_power_limit_window = MAX_POWER_WINDOW; // Settings.energy_max_power_safe_limit = 0; // MaxSafePowerLimit Settings.energy_max_power_safe_limit_hold = SAFE_POWER_HOLD; Settings.energy_max_power_safe_limit_window = SAFE_POWER_WINDOW; // Settings.energy_max_energy = 0; // MaxEnergy // Settings.energy_max_energy_start = 0; // MaxEnergyStart // Settings.energy_kWhtotal = 0; RtcSettings.energy_kWhtotal = 0; // RF Bridge // for (uint8_t i = 0; i < 17; i++) { Settings.rf_code[i][0] = 0; } memcpy_P(Settings.rf_code[0], kDefaultRfCode, 9); // Domoticz Settings.domoticz_update_timer = DOMOTICZ_UPDATE_TIMER; // for (uint8_t i = 0; i < MAX_DOMOTICZ_IDX; i++) { // Settings.domoticz_relay_idx[i] = 0; // Settings.domoticz_key_idx[i] = 0; // Settings.domoticz_switch_idx[i] = 0; // } // for (uint8_t i = 0; i < MAX_DOMOTICZ_SNS_IDX; i++) { // Settings.domoticz_sensor_idx[i] = 0; // } // Sensor Settings.flag.temperature_conversion = TEMP_CONVERSION; Settings.flag.pressure_conversion = PRESSURE_CONVERSION; Settings.flag2.pressure_resolution = PRESSURE_RESOLUTION; Settings.flag2.humidity_resolution = HUMIDITY_RESOLUTION; Settings.flag2.temperature_resolution = TEMP_RESOLUTION; // Settings.altitude = 0; // Rules // Settings.rule_enabled = 0; // Settings.rule_once = 0; // for (uint8_t i = 1; i < MAX_RULE_SETS; i++) { Settings.rules[i][0] = '\0'; } Settings.flag2.calc_resolution = CALC_RESOLUTION; // Home Assistant Settings.flag.hass_discovery = HOME_ASSISTANT_DISCOVERY_ENABLE; // Knx // Settings.flag.knx_enabled = 0; // Settings.flag.knx_enable_enhancement = 0; // Light Settings.flag.pwm_control = 1; //Settings.flag.ws_clock_reverse = 0; //Settings.flag.light_signal = 0; //Settings.flag.not_power_linked = 0; //Settings.flag.decimal_text = 0; Settings.pwm_frequency = PWM_FREQ; Settings.pwm_range = PWM_RANGE; for (uint8_t i = 0; i < MAX_PWMS; i++) { Settings.light_color[i] = 255; // Settings.pwm_value[i] = 0; } // Settings.light_correction = 0; Settings.light_dimmer = 10; // Settings.light_fade = 0; Settings.light_speed = 1; // Settings.light_scheme = 0; Settings.light_width = 1; // Settings.light_wakeup = 0; Settings.light_pixels = WS2812_LEDS; // Settings.light_rotation = 0; SettingsDefaultSet_5_8_1(); // Clock color // Display SettingsDefaultSet_5_10_1(); // Display settings // Time if (((APP_TIMEZONE > -14) && (APP_TIMEZONE < 15)) || (99 == APP_TIMEZONE)) { Settings.timezone = APP_TIMEZONE; Settings.timezone_minutes = 0; } else { Settings.timezone = APP_TIMEZONE / 60; Settings.timezone_minutes = abs(APP_TIMEZONE % 60); } strlcpy(Settings.ntp_server[0], NTP_SERVER1, sizeof(Settings.ntp_server[0])); strlcpy(Settings.ntp_server[1], NTP_SERVER2, sizeof(Settings.ntp_server[1])); strlcpy(Settings.ntp_server[2], NTP_SERVER3, sizeof(Settings.ntp_server[2])); for (uint8_t j = 0; j < 3; j++) { for (uint8_t i = 0; i < strlen(Settings.ntp_server[j]); i++) { if (Settings.ntp_server[j][i] == ',') { Settings.ntp_server[j][i] = '.'; } } } Settings.latitude = (int)((double)LATITUDE * 1000000); Settings.longitude = (int)((double)LONGITUDE * 1000000); SettingsDefaultSet_5_13_1c(); // Time STD/DST settings Settings.button_debounce = KEY_DEBOUNCE_TIME; Settings.switch_debounce = SWITCH_DEBOUNCE_TIME; for (uint8_t j = 0; j < 5; j++) { Settings.rgbwwTable[j] = 255; } Settings.novasds_period = WORKING_PERIOD; memset(&Settings.drivers, 0xFF, 32); // Enable all possible monitors, displays, drivers and sensors } /********************************************************************************************/ void SettingsDefaultSet_5_8_1(void) { // Settings.flag.ws_clock_reverse = 0; Settings.ws_width[WS_SECOND] = 1; Settings.ws_color[WS_SECOND][WS_RED] = 255; Settings.ws_color[WS_SECOND][WS_GREEN] = 0; Settings.ws_color[WS_SECOND][WS_BLUE] = 255; Settings.ws_width[WS_MINUTE] = 3; Settings.ws_color[WS_MINUTE][WS_RED] = 0; Settings.ws_color[WS_MINUTE][WS_GREEN] = 255; Settings.ws_color[WS_MINUTE][WS_BLUE] = 0; Settings.ws_width[WS_HOUR] = 5; Settings.ws_color[WS_HOUR][WS_RED] = 255; Settings.ws_color[WS_HOUR][WS_GREEN] = 0; Settings.ws_color[WS_HOUR][WS_BLUE] = 0; } void SettingsDefaultSet_5_10_1(void) { Settings.display_model = 0; Settings.display_mode = 1; Settings.display_refresh = 2; Settings.display_rows = 2; Settings.display_cols[0] = 16; Settings.display_cols[1] = 8; Settings.display_dimmer = 1; Settings.display_size = 1; Settings.display_font = 1; Settings.display_rotate = 0; Settings.display_address[0] = MTX_ADDRESS1; Settings.display_address[1] = MTX_ADDRESS2; Settings.display_address[2] = MTX_ADDRESS3; Settings.display_address[3] = MTX_ADDRESS4; Settings.display_address[4] = MTX_ADDRESS5; Settings.display_address[5] = MTX_ADDRESS6; Settings.display_address[6] = MTX_ADDRESS7; Settings.display_address[7] = MTX_ADDRESS8; } void SettingsResetStd(void) { Settings.tflag[0].hemis = TIME_STD_HEMISPHERE; Settings.tflag[0].week = TIME_STD_WEEK; Settings.tflag[0].dow = TIME_STD_DAY; Settings.tflag[0].month = TIME_STD_MONTH; Settings.tflag[0].hour = TIME_STD_HOUR; Settings.toffset[0] = TIME_STD_OFFSET; } void SettingsResetDst(void) { Settings.tflag[1].hemis = TIME_DST_HEMISPHERE; Settings.tflag[1].week = TIME_DST_WEEK; Settings.tflag[1].dow = TIME_DST_DAY; Settings.tflag[1].month = TIME_DST_MONTH; Settings.tflag[1].hour = TIME_DST_HOUR; Settings.toffset[1] = TIME_DST_OFFSET; } void SettingsDefaultSet_5_13_1c(void) { SettingsResetStd(); SettingsResetDst(); } /********************************************************************************************/ void SettingsDelta(void) { if (Settings.version != VERSION) { // Fix version dependent changes if (Settings.version < 0x05050000) { for (uint8_t i = 0; i < 17; i++) { Settings.rf_code[i][0] = 0; } memcpy_P(Settings.rf_code[0], kDefaultRfCode, 9); } if (Settings.version < 0x05080000) { Settings.light_pixels = WS2812_LEDS; Settings.light_width = 1; Settings.light_color[0] = 255; Settings.light_color[1] = 0; Settings.light_color[2] = 0; Settings.light_dimmer = 10; Settings.light_correction = 0; Settings.light_fade = 0; Settings.light_speed = 1; Settings.light_scheme = 0; Settings.light_width = 1; Settings.light_wakeup = 0; } if (Settings.version < 0x0508000A) { Settings.power = 0; Settings.altitude = 0; } if (Settings.version < 0x0508000B) { for (uint8_t i = 0; i < sizeof(Settings.my_gp); i++) { // Move GPIO_LEDs if ((Settings.my_gp.io[i] >= 25) && (Settings.my_gp.io[i] <= 32)) { // Was GPIO_LED1 Settings.my_gp.io[i] += 23; // Move GPIO_LED1 } } for (uint8_t i = 0; i < MAX_PWMS; i++) { // Move pwm_value and reset additional pulse_timerrs Settings.pwm_value[i] = Settings.pulse_timer[4 +i]; Settings.pulse_timer[4 +i] = 0; } } if (Settings.version < 0x0508000D) { Settings.pwm_frequency = PWM_FREQ; Settings.pwm_range = PWM_RANGE; } if (Settings.version < 0x0508000E) { SettingsDefaultSet_5_8_1(); } if (Settings.version < 0x05090102) { Settings.flag2.data = Settings.flag.data; Settings.flag2.data &= 0xFFE80000; Settings.flag2.voltage_resolution = Settings.flag.not_power_linked; Settings.flag2.current_resolution = 3; Settings.ina219_mode = 0; } if (Settings.version < 0x050A0009) { SettingsDefaultSet_5_10_1(); } if (Settings.version < 0x050B0107) { Settings.flag.not_power_linked = 0; } if (Settings.version < 0x050C0005) { Settings.light_rotation = 0; Settings.energy_power_delta = DEFAULT_POWER_DELTA; char fingerprint[60]; memcpy(fingerprint, Settings.mqtt_fingerprint, sizeof(fingerprint)); char *p = fingerprint; for (uint8_t i = 0; i < 20; i++) { Settings.mqtt_fingerprint[0][i] = strtol(p, &p, 16); Settings.mqtt_fingerprint[1][i] = Settings.mqtt_fingerprint[0][i]; } } if (Settings.version < 0x050C0007) { Settings.baudrate = APP_BAUDRATE / 1200; } if (Settings.version < 0x050C0008) { Settings.sbaudrate = SOFT_BAUDRATE / 1200; Settings.serial_delimiter = 0xff; } if (Settings.version < 0x050C000A) { Settings.latitude = (int)((double)LATITUDE * 1000000); Settings.longitude = (int)((double)LONGITUDE * 1000000); } if (Settings.version < 0x050C000B) { Settings.rules[0][0] = '\0'; } if (Settings.version < 0x050C000D) { memmove(Settings.rules, Settings.rules -256, sizeof(Settings.rules)); // move rules up by 256 bytes memset(&Settings.timer, 0x00, sizeof(Timer) * MAX_TIMERS); // Reset timers as layout has changed from v5.12.0i Settings.knx_GA_registered = 0; Settings.knx_CB_registered = 0; memset(&Settings.knx_physsical_addr, 0x00, 0x800 - 0x6b8); // Reset until 0x800 for future use } if (Settings.version < 0x050C000F) { Settings.energy_kWhtoday /= 1000; Settings.energy_kWhyesterday /= 1000; RtcSettings.energy_kWhtoday /= 1000; } if (Settings.version < 0x050D0103) { SettingsDefaultSet_5_13_1c(); } if (Settings.version < 0x050E0002) { for (uint8_t i = 1; i < MAX_RULE_SETS; i++) { Settings.rules[i][0] = '\0'; } Settings.rule_enabled = Settings.flag.mqtt_serial_raw; // Was rules_enabled until 5.14.0b Settings.rule_once = Settings.flag.pressure_conversion; // Was rules_once until 5.14.0b } if (Settings.version < 0x06000000) { Settings.cfg_size = sizeof(SYSCFG); Settings.cfg_crc = GetSettingsCrc(); } if (Settings.version < 0x06000002) { for (uint8_t i = 0; i < MAX_SWITCHES; i++) { if (i < 4) { Settings.switchmode[i] = Settings.interlock[i]; } else { Settings.switchmode[i] = SWITCH_MODE; } } for (uint8_t i = 0; i < sizeof(Settings.my_gp); i++) { if (Settings.my_gp.io[i] >= GPIO_SWT5) { // Move up from GPIO_SWT5 to GPIO_KEY1 Settings.my_gp.io[i] += 4; } } } if (Settings.version < 0x06000003) { Settings.flag.mqtt_serial_raw = 0; // Was rules_enabled until 5.14.0b Settings.flag.pressure_conversion = 0; // Was rules_once until 5.14.0b Settings.flag3.data = 0; } if (Settings.version < 0x06010103) { Settings.flag3.timers_enable = 1; } if (Settings.version < 0x0601010C) { Settings.button_debounce = KEY_DEBOUNCE_TIME; Settings.switch_debounce = SWITCH_DEBOUNCE_TIME; } if (Settings.version < 0x0602010A) { for (uint8_t j = 0; j < 5; j++) { Settings.rgbwwTable[j] = 255; } } if (Settings.version < 0x06030002) { Settings.timezone_minutes = 0; } if (Settings.version < 0x06030004) { memset(&Settings.drivers, 0xFF, 32); // Enable all possible monitors, displays, drivers and sensors } if (Settings.version < 0x0603000E) { Settings.flag2.calc_resolution = CALC_RESOLUTION; } if (Settings.version < 0x0603000F) { if (Settings.sleep < 50) { Settings.sleep = 50; // Default to 50 for sleep, for now } } if (Settings.version < 0x06040105) { Settings.flag3.mdns_enabled = MDNS_ENABLED; Settings.param[P_MDNS_DELAYED_START] = 0; } if (Settings.version < 0x0604010B) { Settings.interlock[0] = 0xFF; // Legacy support using all relays in one interlock group for (uint8_t i = 1; i < MAX_INTERLOCKS; i++) { Settings.interlock[i] = 0; } } if (Settings.version < 0x0604010D) { Settings.param[P_BOOT_LOOP_OFFSET] = BOOT_LOOP_OFFSET; } if (Settings.version < 0x06040110) { ModuleDefault(WEMOS); } if (Settings.version < 0x06040113) { Settings.param[P_RGB_REMAP] = RGB_REMAP_RGBW; } if (Settings.version < 0x06050003) { Settings.novasds_period = WORKING_PERIOD; } Settings.version = VERSION; SettingsSave(1); } }