/** \addtogroup Controller * @{ * * @file main.cpp * @author Ollo * @brief PlantControl * @version 0.1 * @date 2020-05-01 * * @copyright Copyright (c) 2020 */ /****************************************************************************** * INCLUDES ******************************************************************************/ #include "PlantCtrl.h" #include "ControllerConfiguration.h" #include "HomieConfiguration.h" #include "DallasTemperature.h" #include #include "time.h" #include "esp_sleep.h" #include "RunningMedian.h" #include "WakeReason.h" #include #include #include #include "DS2438.h" #include "soc/soc.h" #include "soc/rtc_cntl_reg.h" /****************************************************************************** * DEFINES ******************************************************************************/ #define AMOUNT_SENOR_QUERYS 8 #define MAX_TANK_DEPTH 1000 #define TEST_TOPIC "roundtrip\0" #define BACKUP_TOPIC "$implementation/config/backup/set\0" #define BACKUP_STATUS_TOPIC "$implementation/config/backup\0" #define getTopic(test, topic) \ char *topic = new char[strlen(Homie.getConfiguration().mqtt.baseTopic) + strlen(Homie.getConfiguration().deviceId) + 1 + strlen(test) + 1]; \ strcpy(topic, Homie.getConfiguration().mqtt.baseTopic); \ strcat(topic, Homie.getConfiguration().deviceId); \ strcat(topic, "/"); \ strcat(topic, test); /****************************************************************************** * FUNCTION PROTOTYPES ******************************************************************************/ int determineNextPump(); void plantcontrol(boolean withHomie); void readPowerSwitchedSensors(); /****************************************************************************** * NON VOLATILE VARIABLES in DEEP SLEEP ******************************************************************************/ RTC_SLOW_ATTR int lastPumpRunning = -1; /**< store last successfully waterd plant */ RTC_SLOW_ATTR long lastWaterValue = 0; /**< to calculate the used water per plant */ RTC_SLOW_ATTR long rtcLastWateringPlant[MAX_PLANTS] = {0}; /****************************************************************************** * LOCAL VARIABLES ******************************************************************************/ bool volatile mDownloadMode = false; /**< Controller must not sleep */ bool volatile mSensorsRead = false; /**< Sensors are read without Wifi or MQTT */ bool volatile mAliveWasRead = false; bool volatile mMQTTReady = false; bool mConfigured = false; long nextBlink = 0; /**< Time needed in main loop to support expected blink code */ RunningMedian waterRawSensor = RunningMedian(5); float mSolarVoltage = 0.0f; /**< Voltage from solar panels */ unsigned long setupFinishedTimestamp; /*************************** Hardware abstraction *****************************/ OneWire oneWire(SENSOR_ONEWIRE); DallasTemperature sensors(&oneWire); DS2438 battery(&oneWire, 0.0333333f, AMOUNT_SENOR_QUERYS); Plant mPlants[MAX_PLANTS] = { Plant(SENSOR_PLANT0, OUTPUT_PUMP0, 0, &plant0, &mSetting0), Plant(SENSOR_PLANT1, OUTPUT_PUMP1, 1, &plant1, &mSetting1), Plant(SENSOR_PLANT2, OUTPUT_PUMP2, 2, &plant2, &mSetting2), Plant(SENSOR_PLANT3, OUTPUT_PUMP3, 3, &plant3, &mSetting3), Plant(SENSOR_PLANT4, OUTPUT_PUMP4, 4, &plant4, &mSetting4), Plant(SENSOR_PLANT5, OUTPUT_PUMP5, 5, &plant5, &mSetting5), Plant(SENSOR_PLANT6, OUTPUT_PUMP6, 6, &plant6, &mSetting6)}; /****************************************************************************** * LOCAL FUNCTIONS ******************************************************************************/ long getCurrentTime() { struct timeval tv_now; gettimeofday(&tv_now, NULL); return tv_now.tv_sec; } int getCurrentHour() { struct tm info; time_t now; time(&now); localtime_r(&now, &info); return info.tm_hour; } void espDeepSleepFor(long seconds, bool activatePump, bool withHomieShutdown) { if (mDownloadMode) { Serial << "abort deepsleep, DownloadMode active" << endl; return; } if (withHomieShutdown) { for (int i = 0; i < 10; i++) { long cTime = getCurrentTime(); if (cTime < 100000) { Serial << "Wait for ntp" << endl; delay(100); } else { break; } } } esp_sleep_pd_config(ESP_PD_DOMAIN_RTC_PERIPH, ESP_PD_OPTION_OFF); esp_sleep_pd_config(ESP_PD_DOMAIN_RTC_SLOW_MEM, ESP_PD_OPTION_ON); esp_sleep_pd_config(ESP_PD_DOMAIN_RTC_FAST_MEM, ESP_PD_OPTION_OFF); if (activatePump) { esp_sleep_pd_config(ESP_PD_DOMAIN_XTAL, ESP_PD_OPTION_ON); gpio_deep_sleep_hold_en(); gpio_hold_en(OUTPUT_ENABLE_PUMP); //pump pwr } else { gpio_hold_dis(OUTPUT_ENABLE_PUMP); //pump pwr gpio_deep_sleep_hold_dis(); digitalWrite(OUTPUT_ENABLE_PUMP, LOW); digitalWrite(OUTPUT_ENABLE_SENSOR, LOW); for (int i = 0; i < MAX_PLANTS; i++) { mPlants[i].deactivatePump(); } } gpio_hold_en(OUTPUT_PUMP0); gpio_hold_en(OUTPUT_PUMP1); gpio_hold_en(OUTPUT_PUMP2); gpio_hold_en(OUTPUT_PUMP3); gpio_hold_en(OUTPUT_PUMP4); gpio_hold_en(OUTPUT_PUMP5); gpio_hold_en(OUTPUT_PUMP6); //FIXME fix for outher outputs Serial.print("Trying to sleep for "); Serial.print(seconds); Serial.println(" seconds"); esp_sleep_enable_timer_wakeup((seconds * 1000U * 1000U)); Serial.flush(); if (withHomieShutdown) { Homie.prepareToSleep(); } else { Serial << "Bye offline mode" << endl; Serial.flush(); esp_deep_sleep_start(); } } //requires homie being started void readOneWireSensors(bool withMQTT) { int sensorCount = sensors.getDS18Count(); Serial << "Read OneWire" << endl; Serial.flush(); for (uint8_t i = 0; i < sensorCount; i++) { DeviceAddress ds18b20Address; sensors.getAddress(ds18b20Address, i); bool valid = false; float temp = -127; for (int retry = 0; retry < AMOUNT_SENOR_QUERYS && !valid; retry++) { temp = sensors.getTempC(ds18b20Address); if (temp != -127) { valid = true; } } //TODO is -127 bus error? if so add retry code char buf[sizeof(DeviceAddress) * 2]; snprintf(buf, sizeof(buf), "%.2X%.2X%.2X%.2X%.2X%.2X%.2X%.2X", ds18b20Address[0], ds18b20Address[1], ds18b20Address[2], ds18b20Address[3], ds18b20Address[4], ds18b20Address[5], ds18b20Address[6], ds18b20Address[7]); if (valid) { Serial << "OneWire sensor " << String(buf) << " has value " << temp << endl; if (String(lipoSensorAddr.get()).compareTo(String(buf))) { if (withMQTT) { sensorTemp.setProperty(TEMPERATUR_SENSOR_LIPO).send(String(temp)); } Serial << "Lipo Temperatur " << temp << " °C " << endl; } else if (String(waterSensorAddr.get()).compareTo(String(buf))) { if (withMQTT) { sensorTemp.setProperty(TEMPERATUR_SENSOR_WATER).send(String(temp)); } Serial << "Water Temperatur " << temp << " °C " << endl; } /* Always send the sensor address with the temperatur value */ if (withMQTT) { sensorTemp.setProperty(String(buf)).send(String(temp)); } Serial << "Temperatur " << String(buf) << " : " << temp << " °C " << endl; } else { Serial << "OneWire sensor " << String(buf) << " could not be read " << temp << endl; } } battery.update(); mSolarVoltage = battery.getVoltage(BATTSENSOR_INDEX_SOLAR) * SOLAR_VOLT_FACTOR; Serial.flush(); } /** * @brief Sensors, that are connected to GPIOs, mandatory for WIFI. * These sensors (ADC2) can only be read when no Wifi is used. */ void readPowerSwitchedSensors() { digitalWrite(OUTPUT_ENABLE_SENSOR, HIGH); delay(10); for (int readCnt = 0; readCnt < AMOUNT_SENOR_QUERYS; readCnt++) { for (int i = 0; i < MAX_PLANTS; i++) { mPlants[i].addSenseValue(); } delay(2); } /* Read the distance and give the temperature sensors some time */ { for (int i = 0; i < AMOUNT_SENOR_QUERYS; i++) { unsigned long duration = 0; digitalWrite(SENSOR_TANK_TRG, HIGH); delayMicroseconds(20); cli(); digitalWrite(SENSOR_TANK_TRG, LOW); //10ms is > 2m tank depth duration = pulseIn(SENSOR_TANK_ECHO, HIGH, 10); sei(); int mmDis = duration * 0.3432 / 2; if (mmDis > MAX_TANK_DEPTH) { waterRawSensor.add(0); } else { waterRawSensor.add(mmDis); } } } Serial << "Distance sensor " << waterRawSensor.getAverage() << " cm" << endl; /* deactivate the sensors */ digitalWrite(OUTPUT_ENABLE_SENSOR, LOW); } bool copyFile(const char *source, const char *target) { Serial << "copy started " << source << " -> " << target << endl; byte buffer[512]; if (!SPIFFS.begin()) { return false; } File file = SPIFFS.open(source, FILE_READ); File file2 = SPIFFS.open(target, FILE_WRITE); Serial.flush(); if (!file) { Serial << "There was an error opening " << source << " for reading" << endl; SPIFFS.end(); return false; } if (!file2) { Serial << "There was an error opening " << target << " for reading" << endl; file.close(); SPIFFS.end(); return false; } while (file.available()) { int read = file.read(buffer, 512); if (read < 0) { Serial << "copy file is fucked" << endl; file.close(); file2.close(); SPIFFS.end(); return false; } else { file.write(buffer, read); } } file2.flush(); Serial << "copy finished " << source << " -> " << target << endl; file.close(); file2.close(); SPIFFS.end(); return true; } void onMessage(char *incoming, char *payload, AsyncMqttClientMessageProperties properties, size_t len, size_t index, size_t total) { getTopic(TEST_TOPIC, testTopic); if (strcmp(incoming, testTopic) == 0) { mAliveWasRead = true; } delete testTopic; getTopic(BACKUP_TOPIC, backupTopic); if (strcmp(incoming, backupTopic) == 0) { bool backupSucessful = copyFile("/homie/config.json", "/homie/config.old"); getTopic(BACKUP_STATUS_TOPIC, backupStatusTopic); Homie.getMqttClient().publish(backupStatusTopic, 2, true, backupSucessful ? "true" : "false"); delete backupStatusTopic; } delete backupTopic; } void onHomieEvent(const HomieEvent &event) { switch (event.type) { case HomieEventType::READY_TO_SLEEP: Serial << "Bye homie mode" << endl; Serial.flush(); esp_deep_sleep_start(); break; case HomieEventType::SENDING_STATISTICS: break; case HomieEventType::MQTT_READY: if (mSensorsRead) { Serial.printf("Timeout occured... too late!\r\n"); return; } mSensorsRead = true; // MQTT is working, deactivate timeout logic Serial.printf("NTP Setup with server %s\r\n", ntpServer.get()); configTime(0, 0, ntpServer.get()); Serial << "publish plants mqtt" << endl; for (int i = 0; i < MAX_PLANTS; i++) { mPlants[i].postMQTTconnection(); } { getTopic(TEST_TOPIC, testopic) Homie.getMqttClient() .subscribe(testopic, 2); Homie.getMqttClient().publish(testopic, 2, false, "ping"); Homie.getMqttClient().onMessage(onMessage); getTopic(BACKUP_TOPIC, backupTopic) Homie.getMqttClient() .subscribe(backupTopic, 2); } mMQTTReady = true; break; case HomieEventType::OTA_STARTED: Homie.getLogger() << "OTA started" << endl; for (int i = 0; i < MAX_PLANTS; i++) { mPlants[i].deactivatePump(); } WRITE_PERI_REG(RTC_CNTL_BROWN_OUT_REG, 0); digitalWrite(OUTPUT_ENABLE_PUMP, HIGH); delay(100); WRITE_PERI_REG(RTC_CNTL_BROWN_OUT_REG, 1); mDownloadMode = true; break; case HomieEventType::OTA_SUCCESSFUL: Homie.getLogger() << "OTA successful" << endl; digitalWrite(OUTPUT_ENABLE_SENSOR, LOW); digitalWrite(OUTPUT_ENABLE_PUMP, LOW); ESP.restart(); break; default: break; } } int determineNextPump() { bool isLowLight = (mSolarVoltage < SOLAR_CHARGE_MIN_VOLTAGE); int pumpToUse = -1; for (int i = 0; i < MAX_PLANTS; i++) { Plant plant = mPlants[i]; if (!plant.isPumpTriggerActive()) { Serial.printf("%d Skip deactivated pump\r\n", i); continue; } if ((rtcLastWateringPlant[i] > 0) && ((rtcLastWateringPlant[i] + plant.getCooldownInSeconds()) < getCurrentTime())) { Serial.printf("%d Skipping due to cooldown %ld / %ld \r\n", i, rtcLastWateringPlant[i], plant.getCooldownInSeconds()); continue; } if (!isLowLight && plant.isAllowedOnlyAtLowLight()) { Serial.printf("%d No pump required: due to light\r\n", i); continue; } if (plant.getCurrentMoisture() == MISSING_SENSOR) { Serial.printf("%d No pump possible: missing sensor \r\n", i); continue; } if (plant.isPumpRequired()) { /* Handle e.g. start = 21, end = 8 */ if (((plant.getHoursStart() > plant.getHoursEnd()) && (getCurrentHour() >= plant.getHoursStart() || getCurrentHour() <= plant.getHoursEnd())) || /* Handle e.g. start = 8, end = 21 */ ((plant.getHoursStart() < plant.getHoursEnd()) && (getCurrentHour() >= plant.getHoursStart() && getCurrentHour() <= plant.getHoursEnd())) || /* no time from NTP received */ (getCurrentTime() < 10000)) { Serial.printf("%d Requested pumping\r\n", i); pumpToUse = i; } else { Serial.printf("%d ignored due to time boundary: %d to %d (current %d)\r\n", i, plant.getHoursStart(), plant.getHoursEnd(), getCurrentHour()); } continue; } else { Serial.printf("%d No pump required: moisture acceptable %f / %ld\r\n", i, plant.getCurrentMoisture(), plant.getSettingsMoisture()); } } return pumpToUse; } /** * @brief Handle Mqtt commands to keep controller alive * * @param range multiple transmitted values (not used for this function) * @param value single value * @return true when the command was parsed and executed succuessfully * @return false on errors when parsing the request */ bool aliveHandler(const HomieRange &range, const String &value) { if (range.isRange) return false; // only one controller is present Serial.println("aliuve handler"); Serial.flush(); if (value.equals("ON") || value.equals("On") || value.equals("1")) { mDownloadMode = true; } else { if (mDownloadMode) { esp_restart(); } mDownloadMode = false; } return true; } bool notStarted = true; void homieLoop() { if (mMQTTReady && mAliveWasRead && notStarted) { Serial.println("received alive & mqtt is ready"); notStarted = false; plantcontrol(true); } } /** * @brief Startup function * Is called once, the controller is started */ void setup() { /* reduce power consumption */ setCpuFrequencyMhz(80); Serial.begin(115200); Serial << "Wifi mode set to " << WIFI_OFF << " to allow analog2 useage " << endl; WiFi.mode(WIFI_OFF); Serial.flush(); /* Intialize Plant */ for (int i = 0; i < MAX_PLANTS; i++) { mPlants[i].init(); } Serial.println("plants init"); Serial.flush(); // read button pinMode(BUTTON, INPUT); // Power pins pinMode(OUTPUT_ENABLE_PUMP, OUTPUT); digitalWrite(OUTPUT_ENABLE_PUMP, LOW); pinMode(OUTPUT_ENABLE_SENSOR, OUTPUT); if (HomieInternals::MAX_CONFIG_SETTING_SIZE < MAX_CONFIG_SETTING_ITEMS) { //increase the config settings to 50 and the json to 3000 Serial << "Limits.hpp is not adjusted, please search for this string and increase" << endl; return; } /************************* Start One-Wire bus ***************/ int tempInitStartTime = millis(); uint8_t sensorCount = 0U; /* Required to read the temperature at least once */ while ((sensorCount == 0 || !battery.isFound()) && millis() < tempInitStartTime + TEMPERATUR_TIMEOUT) { sensors.begin(); battery.begin(); sensorCount = sensors.getDS18Count(); delay(50); } Serial << "One wire count: " << sensorCount << " found in " << (millis() - tempInitStartTime) << "ms" << endl; Serial.flush(); /* Measure temperature TODO idea: move this into setup */ if (sensorCount > 0) { sensors.setResolution(DS18B20_RESOLUTION); sensors.requestTemperatures(); } Serial << "Reading sensors start" << endl; Serial.flush(); readPowerSwitchedSensors(); Serial << "Reading sensors end" << endl; Serial.flush(); /************************* Start Homie Framework ***************/ Homie_setFirmware("PlantControl", FIRMWARE_VERSION); // Set default values //in seconds deepSleepTime.setDefaultValue(600).setValidator([](long candidate) { return (candidate > 0) && (candidate < (60 * 60 * 2) /** 2h max sleep */); }); deepSleepNightTime.setDefaultValue(600); wateringDeepSleep.setDefaultValue(5); ntpServer.setDefaultValue("pool.ntp.org"); /* waterLevelMax 1000 */ /* 100cm in mm */ waterLevelMin.setDefaultValue(50); /* 5cm in mm */ waterLevelWarn.setDefaultValue(500); /* 50cm in mm */ waterLevelVol.setDefaultValue(5000); /* 5l in ml */ lipoSensorAddr.setDefaultValue(""); waterSensorAddr.setDefaultValue(""); Homie.setLoopFunction(homieLoop); Homie.onEvent(onHomieEvent); //Homie.disableLogging(); Homie.setup(); mConfigured = Homie.isConfigured(); if (mConfigured) { Serial << "Wifi mode set to " << WIFI_STA << endl; WiFi.mode(WIFI_STA); for (int i = 0; i < MAX_PLANTS; i++) { mPlants[i].advertise(); } sensorTemp.advertise(TEMPERATUR_SENSOR_LIPO) .setName(TEMPERATURE_NAME) .setDatatype(NUMBER_TYPE) .setUnit(TEMPERATURE_UNIT); sensorTemp.advertise(TEMPERATUR_SENSOR_WATER) .setName(TEMPERATURE_NAME) .setDatatype(NUMBER_TYPE) .setUnit(TEMPERATURE_UNIT); sensorTemp.advertise(TEMPERATUR_SENSOR_CHIP) .setName(TEMPERATURE_NAME) .setDatatype(NUMBER_TYPE) .setUnit(TEMPERATURE_UNIT); sensorLipo.advertise("percent") .setName("Percent") .setDatatype(NUMBER_TYPE) .setUnit("%"); sensorLipo.advertise("volt") .setName("Volt") .setDatatype(NUMBER_TYPE) .setUnit("V"); sensorSolar.advertise("percent") .setName("Percent") .setDatatype(NUMBER_TYPE) .setUnit("%"); sensorSolar.advertise("volt") .setName("Volt") .setDatatype(NUMBER_TYPE) .setUnit("V"); sensorWater.advertise("remaining").setDatatype(NUMBER_TYPE).setUnit("%"); } else { readOneWireSensors(false); digitalWrite(OUTPUT_ENABLE_PUMP, HIGH); delay(100); Serial << "Wifi mode set to " << WIFI_AP_STA << endl; WiFi.mode(WIFI_AP_STA); Serial.println("Initial Setup. Start Accesspoint..."); mDownloadMode = true; } stayAlive.advertise("alive").setName("Alive").setDatatype(NUMBER_TYPE).settable(aliveHandler); setupFinishedTimestamp = millis(); } /** * @brief Cyclic call * Executs the Homie base functionallity or triggers sleeping, if requested. */ void loop() { Homie.loop(); /* Toggel Senor LED to visualize mode 3 */ if (mDownloadMode) { if (nextBlink < millis()) { digitalWrite(OUTPUT_ENABLE_SENSOR, !digitalRead(OUTPUT_ENABLE_SENSOR)); if (mConfigured) { nextBlink = millis() + 500; } else { if (lastPumpRunning >= 0 && lastPumpRunning < MAX_PLANTS) { mPlants[lastPumpRunning].deactivatePump(); } if (lastPumpRunning >= MAX_PLANTS) { digitalWrite(OUTPUT_ENABLE_PUMP, LOW); nextBlink = millis() + 500; } else { lastPumpRunning++; nextBlink = millis() + 5000; } if (lastPumpRunning < MAX_PLANTS) { mPlants[lastPumpRunning].activatePump(); } } } } else { unsigned long timeSinceSetup = millis() - setupFinishedTimestamp; if ((timeSinceSetup > MQTT_TIMEOUT) && (!mSensorsRead)) { mSensorsRead = true; /* Disable Wifi and put modem into sleep mode */ WiFi.mode(WIFI_OFF); Serial << "Wifi mode set to " << WIFI_OFF << " mqqt was no reached within " << timeSinceSetup << "ms , fallback to offline mode " << endl; Serial.flush(); plantcontrol(false); } } /** Timeout always stopping the ESP -> no endless power consumption */ if (millis() > 60000 && !mDownloadMode) { Serial << (millis() / 1000) << "not terminated watchdog reset" << endl; Serial.flush(); esp_restart(); } } /*** * @fn plantcontrol * Main function, doing the logic */ void plantcontrol(bool withHomie) { if (lastPumpRunning != -1) { long waterDiff = waterRawSensor.getAverage() - lastWaterValue; mPlants[lastPumpRunning].setProperty("waterusage").send(String(waterDiff)); /* TODO convert diff into volume (milli liter) */ Serial << "Plant" << lastPumpRunning << ": Water diff " << waterDiff << " mm" << endl; } readOneWireSensors(true); for (int i = 0; i < MAX_PLANTS; i++) { long raw = mPlants[i].getCurrentMoisture(); long pct = 100 - map(raw, MOIST_SENSOR_MIN_ADC, MOIST_SENSOR_MAX_ADC, 0, 100); if (raw == MISSING_SENSOR) { pct = 0; } if (pct < 0) { pct = 0; } if (pct > 100) { pct = 100; } mPlants[i].setProperty("moist").send(String(pct)); mPlants[i].setProperty("moistraw").send(String(raw)); } Serial << "W : " << waterRawSensor.getAverage() << " cm (" << String(waterLevelMax.get() - waterRawSensor.getAverage()) << "%)" << endl; lastWaterValue = waterRawSensor.getAverage(); float batteryVoltage = battery.getVoltage(BATTSENSOR_INDEX_BATTERY); float chipTemp = battery.getTemperature(); Serial << "Chip Temperatur " << chipTemp << " °C " << endl; if (withHomie) { sensorWater.setProperty("remaining").send(String(waterLevelMax.get() - waterRawSensor.getAverage())); sensorLipo.setProperty("percent").send(String(100 * batteryVoltage / VOLT_MAX_BATT)); sensorLipo.setProperty("volt").send(String(batteryVoltage)); sensorLipo.setProperty("current").send(String(battery.getCurrent())); sensorLipo.setProperty("Ah").send(String(battery.getAh())); sensorLipo.setProperty("ICA").send(String(battery.getICA())); sensorLipo.setProperty("DCA").send(String(battery.getDCA())); sensorLipo.setProperty("CCA").send(String(battery.getCCA())); sensorSolar.setProperty("volt").send(String(mSolarVoltage)); sensorTemp.setProperty(TEMPERATUR_SENSOR_CHIP).send(String(chipTemp)); } else { Serial.println("Skipping MQTT, offline mode"); Serial.flush(); } bool hasWater = true; //FIXMEmWaterGone > waterLevelMin.get(); //FIXME no water warning message lastPumpRunning = determineNextPump(); if (lastPumpRunning != -1 && !hasWater) { Serial.println("Want to pump but no water"); } else if (lastPumpRunning != -1 && hasWater) { if (mDownloadMode) { Serial.println("Mode 3 active, ignoring pump request"); } else { //prevent BOD to be paranoid WRITE_PERI_REG(RTC_CNTL_BROWN_OUT_REG, 0); digitalWrite(OUTPUT_ENABLE_PUMP, HIGH); delay(100); WRITE_PERI_REG(RTC_CNTL_BROWN_OUT_REG, 1); rtcLastWateringPlant[lastPumpRunning] = getCurrentTime(); mPlants[lastPumpRunning].activatePump(); } } /* Always handle one of the deep sleep duration */ if (lastPumpRunning == -1 || !hasWater) { if (mSolarVoltage < SOLAR_CHARGE_MIN_VOLTAGE) { Serial.print(mSolarVoltage); Serial.println("V! No pumps to activate and low light, deepSleepNight"); espDeepSleepFor(deepSleepNightTime.get(), false, withHomie); } else { Serial.println("No pumps to activate, deepSleep"); espDeepSleepFor(deepSleepTime.get(), false, withHomie); } } else { Serial.println("Running pump, watering deepsleep"); espDeepSleepFor(wateringDeepSleep.get(), true, withHomie); } } /** @}*/