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2026-02-06 16:49:21 +01:00 · 2026-02-06 16:49:21 +01:00 · bd09b9d570
commit bd09b9d570
3 changed files with 445 additions and 0 deletions
--- a/.vscode/extensions.json
+++ b/.vscode/extensions.json
@ -0,0 +1,10 @@
 {
    // See http://go.microsoft.com/fwlink/?LinkId=827846
    // for the documentation about the extensions.json format
    "recommendations": [
        "platformio.platformio-ide"
    ],
    "unwantedRecommendations": [
        "ms-vscode.cpptools-extension-pack"
    ]
 }
--- a/platformio.ini
+++ b/platformio.ini
@ -0,0 +1,34 @@
 ; PlatformIO Project Configuration File
 ;
 ;   Build options: build flags, source filter
 ;   Upload options: custom upload port, speed and extra flags
 ;   Library options: dependencies, extra library storages
 ;   Advanced options: extra scripting
 ;
 ; Please visit documentation for the other options and examples
 ; https://docs.platformio.org/page/projectconf.html
 [env:esp32dev]
 platform = espressif32
 board = esp32dev
 framework = arduino
 # Libraries hier eintragen:
 lib_deps = 
    knolleary/PubSubClient @ ^2.8
    arduino-libraries/NTPClient @ ^3.2.1
    bblanchon/ArduinoJson @ ^6.21.3
 # SERIAL MONITOR EINSTELLUNGEN:
 monitor_speed = 115200          # Baudrate
 monitor_port = COM9             # Port festlegen
 monitor_filters =               # Filter aktivieren
    colorize                    # Farbige Ausgabe
    esp32_exception_decoder     # ESP32 Fehler dekodieren
    log2file                    # In Datei speichern
    time                        # Zeitstempel
    default                     # Standardfilter
 monitor_rts = 0                 # RTS deaktivieren
 monitor_dtr = 0                 # DTR deaktivieren
 monitor_echo = yes              # Eingaben anzeigen
 monitor_raw = no                # Raw-Mode
 monitor_encoding = utf8         # Encoding
 monitor_rx_timeout = 3          # Timeout in Sekunden
--- a/src/main.cpp
+++ b/src/main.cpp
@ -0,0 +1,401 @@
 #include <WiFi.h>
 #include <PubSubClient.h>
 #include <NTPClient.h>
 #include <WiFiUdp.h>
 #include <ArduinoJson.h>
 #include <EEPROM.h>
 #include <esp_task_wdt.h>
 // =================== HARDWARE KONFIGURATION ===================
 // WICHTIG: Dein KY-025 ist INVERTIERT (HIGH bei Magnet, LOW ohne Magnet)
 #define REED_PIN 4        // GPIO4 (funktioniert gut mit Pullup)
 const float PULSES_PER_M3 = 100.0; // Anpassen: Wie viele Impulse pro m³?
 // =================== NETZWERK KONFIGURATION ===================
 const char* SSID = "pipanet";
 const char* PASS = "passatvr6";
 // =================== MQTT KONFIGURATION ===================
 const char* MQTT_SERVER = "192.168.2.173";
 const char* STATE_TOPIC = "homeassistant/sensor/gaszahler/state";
 const char* COMMAND_TOPIC = "homeassistant/sensor/gaszahler/set";
 const char* CONFIG_TOPIC = "homeassistant/sensor/gaszahler/config";
 const char* AVAILABILITY_TOPIC = "homeassistant/sensor/gaszahler/status";
 // =================== GLOBALE VARIABLEN ===================
 // volatile für Interrupt-Sicherheit
 volatile unsigned long totalPulses = 0;
 volatile unsigned long dailyPulses = 0;
 volatile bool lastReedState = false;
 volatile unsigned long lastPulseTime = 0;
 volatile bool pulseFlag = false;  // Für sichere Hauptschleife-Verarbeitung
 const unsigned long DEBOUNCE_MS = 50;    // Entprellzeit
 const unsigned long MIN_PULSE_GAP = 100; // Minimaler Impulsabstand (ms)
 const int EEPROM_SIZE = 128;
 // =================== OBJEKTE ===================
 WiFiUDP ntpUDP;
 NTPClient timeClient(ntpUDP, "pool.ntp.org", 3600, 60000); // UTC+1, Update alle 60s
 WiFiClient wifiClient;
 PubSubClient mqtt(wifiClient);
 // =================== EEPROM FUNKTIONEN ===================
 void saveToEEPROM() {
  EEPROM.begin(EEPROM_SIZE);
  // Magic Number zum Erkennen von gültigen Daten
  EEPROM.put(0, 0xABCD1234);
  // Daten speichern
  EEPROM.put(4, totalPulses);
  EEPROM.put(8, dailyPulses);
  // CRC-Prüfsumme
  uint32_t crc = totalPulses ^ dailyPulses ^ 0x55AA55AA;
  EEPROM.put(12, crc);
  EEPROM.commit();
  EEPROM.end();
  Serial.printf("EEPROM gespeichert: Total=%lu, Daily=%lu\n", totalPulses, dailyPulses);
 }
 void loadFromEEPROM() {
  EEPROM.begin(EEPROM_SIZE);
  // Magic Number prüfen
  uint32_t magic;
  EEPROM.get(0, magic);
  if (magic == 0xABCD1234) {
    // Daten laden
    EEPROM.get(4, totalPulses);
    EEPROM.get(8, dailyPulses);
    // CRC prüfen
    uint32_t storedCRC, calculatedCRC;
    EEPROM.get(12, storedCRC);
    calculatedCRC = totalPulses ^ dailyPulses ^ 0x55AA55AA;
    if (storedCRC == calculatedCRC) {
      Serial.printf("EEPROM geladen: Total=%lu (%.2f m³), Daily=%lu (%.2f m³)\n", 
                    totalPulses, totalPulses / PULSES_PER_M3,
                    dailyPulses, dailyPulses / PULSES_PER_M3);
    } else {
      Serial.println("EEPROM CRC Fehler - Reset auf 0");
      totalPulses = 0;
      dailyPulses = 0;
    }
  } else {
    Serial.println("Keine gültigen EEPROM-Daten gefunden");
    totalPulses = 0;
    dailyPulses = 0;
  }
  EEPROM.end();
 }
 // =================== INTERRUPT HANDLER ===================
 void IRAM_ATTR handleReedInterrupt() {
  unsigned long now = millis();
  // Hardware-Entprellung und Mindestabstand
  if (now - lastPulseTime < MIN_PULSE_GAP) {
    return; // Zu schnelle Impulse ignorieren
  }
  bool currentState = digitalRead(REED_PIN);
  // WICHTIG: Dein Sensor ist INVERTIERT!
  // HIGH = Magnet vorhanden (Zähler im Ruhezustand)
  // LOW  = Magnet weg (Zähler bewegt sich -> Impuls)
  if (currentState == LOW && lastReedState == HIGH) {
    // Flanke von HIGH nach LOW = Magnet wurde entfernt = Zähler bewegt sich
    pulseFlag = true;  // Für Hauptschleife
    lastPulseTime = now;
  }
  lastReedState = currentState;
 }
 // =================== MQTT FUNKTIONEN ===================
 void sendHAConfig() {
  StaticJsonDocument<512> config;
  // Gerätekonfiguration
  JsonObject device = config.createNestedObject("device");
  device["identifiers"][0] = String("gasmeter_") + String((uint32_t)ESP.getEfuseMac(), HEX);
  device["name"] = "Gas Zähler";
  device["manufacturer"] = "DIY";
  device["model"] = "ESP32 + KY-025";
  device["sw_version"] = "2.0";
  // Totale Gasmenge
  config["name"] = "Gas Verbrauch Total";
  config["unique_id"] = String("gasmeter_total_") + String((uint32_t)ESP.getEfuseMac(), HEX);
  config["state_topic"] = STATE_TOPIC;
  config["unit_of_meas"] = "m³";
  config["device_class"] = "gas";
  config["state_class"] = "total_increasing";
  config["value_template"] = "{{ value_json.total_m3 }}";
  config["availability_topic"] = AVAILABILITY_TOPIC;
  config["payload_available"] = "online";
  config["payload_not_available"] = "offline";
  config["json_attributes_topic"] = STATE_TOPIC;
  char buffer[512];
  serializeJson(config, buffer);
  mqtt.publish(CONFIG_TOPIC, buffer, true);
  Serial.println("Home Assistant Config gesendet");
 }
 void sendMQTTData() {
  StaticJsonDocument<256> doc;
  // Berechnungen
  float total_m3 = totalPulses / PULSES_PER_M3;
  float daily_m3 = dailyPulses / PULSES_PER_M3;
  float hourly_m3 = daily_m3 / 24.0;  // Vereinfachte Annahme
  // Hauptwerte
  doc["total_m3"] = total_m3;
  doc["daily_m3"] = daily_m3;
  doc["hourly_m3"] = hourly_m3;
  doc["total_pulses"] = totalPulses;
  // Zusätzliche Info
  doc["pulses_per_m3"] = PULSES_PER_M3;
  doc["timestamp"] = timeClient.getFormattedTime();
  doc["uptime"] = millis() / 1000;
  doc["rssi"] = WiFi.RSSI();
  char output[256];
  serializeJson(doc, output);
  if (mqtt.publish(STATE_TOPIC, output, true)) {
    Serial.printf("MQTT gesendet: %.3f m³ total, %.3f m³ heute\n", total_m3, daily_m3);
  } else {
    Serial.println("MQTT Sendefehler!");
  }
 }
 void mqttCallback(char* topic, byte* payload, unsigned int length) {
  char message[length + 1];
  memcpy(message, payload, length);
  message[length] = '\0';
  Serial.printf("MQTT Callback: Topic=%s, Message=%s\n", topic, message);
  if (String(topic) == COMMAND_TOPIC) {
    if (strcmp(message, "reset_total") == 0) {
      totalPulses = 0;
      saveToEEPROM();
      Serial.println("Totalzähler zurückgesetzt");
    } 
    else if (strcmp(message, "reset_daily") == 0) {
      dailyPulses = 0;
      saveToEEPROM();
      Serial.println("Tageszähler zurückgesetzt");
    }
    else if (strcmp(message, "restart") == 0) {
      Serial.println("Neustart via MQTT...");
      ESP.restart();
    }
    // Sofortige Bestätigung senden
    sendMQTTData();
  }
 }
 void reconnectMQTT() {
  static unsigned long lastAttempt = 0;
  if (!mqtt.connected()) {
    if (millis() - lastAttempt > 5000) {
      Serial.print("Verbinde mit MQTT...");
      // Client ID mit MAC-Adresse für Eindeutigkeit
      String clientId = "GasMeter-" + String((uint32_t)ESP.getEfuseMac(), HEX);
      if (mqtt.connect(clientId.c_str(), AVAILABILITY_TOPIC, 1, true, "offline")) {
        Serial.println("verbunden!");
        // Verfügbarkeit melden
        mqtt.publish(AVAILABILITY_TOPIC, "online", true);
        // Topics abonnieren
        mqtt.subscribe(COMMAND_TOPIC);
        // Config an HA senden
        sendHAConfig();
        // Sofort Daten senden
        sendMQTTData();
      } else {
        Serial.printf("fehlgeschlagen, rc=%d\n", mqtt.state());
      }
      lastAttempt = millis();
    }
  }
 }
 // =================== TAGESRESET ===================
 void checkDailyReset() {
  static int lastDay = -1;
  timeClient.update();
  int currentDay = timeClient.getDay();
  if (lastDay != -1 && currentDay != lastDay) {
    Serial.println("Neuer Tag - Tageszähler wird zurückgesetzt");
    dailyPulses = 0;
    saveToEEPROM();
    // Sofort MQTT Update
    if (mqtt.connected()) {
      sendMQTTData();
    }
  }
  lastDay = currentDay;
 }
 // =================== WATCHDOG & ÜBERWACHUNG ===================
 void setupWatchdog() {
  // Task Watchdog für Hauptschleife (5 Sekunden)
  esp_task_wdt_init(5, true);
  esp_task_wdt_add(NULL);
 }
 // =================== SETUP ===================
 void setup() {
  Serial.begin(115200);
  delay(1000);
  Serial.println("\n=================================");
  Serial.println("     ESP32 Gaszähler v2.0");
  Serial.println("=================================");
  Serial.printf("Chip-ID: %08X\n", (uint32_t)ESP.getEfuseMac());
  Serial.printf("Free Heap: %d bytes\n", ESP.getFreeHeap());
  // EEPROM Daten laden
  loadFromEEPROM();
  // Reed-Sensor initialisieren
  pinMode(REED_PIN, INPUT_PULLUP);
  // Initialen Zustand lesen (INVERTIERT!)
  lastReedState = digitalRead(REED_PIN);
  Serial.printf("Startzustand Reed-Pin: %s\n", 
                lastReedState ? "HIGH (Magnet vorhanden)" : "LOW (kein Magnet)");
  // Interrupt konfigurieren
  attachInterrupt(digitalPinToInterrupt(REED_PIN), handleReedInterrupt, CHANGE);
  Serial.println("Interrupt aktiviert (CHANGE)");
  // WiFi verbinden
  Serial.print("Verbinde mit WiFi");
  WiFi.begin(SSID, PASS);
  WiFi.setSleep(false); // Bessere Stabilität
  unsigned long wifiTimeout = millis() + 30000;
  while (WiFi.status() != WL_CONNECTED && millis() < wifiTimeout) {
    delay(500);
    Serial.print(".");
  }
  if (WiFi.status() == WL_CONNECTED) {
    Serial.println("\nWiFi verbunden!");
    Serial.printf("IP: %s, RSSI: %d dBm\n", 
                  WiFi.localIP().toString().c_str(), WiFi.RSSI());
  } else {
    Serial.println("\nWiFi Fehler - im Offline-Modus");
  }
  // NTP Client
  timeClient.begin();
  timeClient.update();
  Serial.printf("NTP Zeit: %s\n", timeClient.getFormattedTime().c_str());
  // MQTT Client
  mqtt.setServer(MQTT_SERVER, 1883);
  mqtt.setCallback(mqttCallback);
  mqtt.setBufferSize(512);
  mqtt.setKeepAlive(30);
  // Watchdog
  setupWatchdog();
  Serial.println("Setup abgeschlossen!");
  Serial.println("=================================\n");
 }
 // =================== HAUPTLOOP ===================
 void loop() {
  static unsigned long lastMQTTSend = 0;
  static unsigned long lastSerialOutput = 0;
  static unsigned long lastStateCheck = 0;
  // Watchdog füttern
  esp_task_wdt_reset();
  // Impulse in Hauptschleife verarbeiten (thread-sicher)
  if (pulseFlag) {
    // Warte kurze Zeit für Stabilität
    delay(1);
    // Nochmal prüfen (Entprellung)
    if (digitalRead(REED_PIN) == LOW) {
      totalPulses++;
      dailyPulses++;
      Serial.printf("[IMPULS] Total: %lu (%.3f m³), Heute: %lu (%.3f m³)\n",
                    totalPulses, totalPulses / PULSES_PER_M3,
                    dailyPulses, dailyPulses / PULSES_PER_M3);
      // Bei jedem Impuls speichern (für maximale Datenintegrität)
      saveToEEPROM();
      // Sofort MQTT Update bei aktivem Impuls
      if (mqtt.connected() && (millis() - lastMQTTSend > 1000)) {
        sendMQTTData();
        lastMQTTSend = millis();
      }
    }
    pulseFlag = false;
  }
  // Netzwerk Updates
  if (WiFi.status() == WL_CONNECTED) {
    timeClient.update();
    mqtt.loop();
    reconnectMQTT();
    checkDailyReset();
  }
  // Regelmäßiges MQTT Update (alle 30 Sekunden)
  if (mqtt.connected() && (millis() - lastMQTTSend > 30000)) {
    sendMQTTData();
    lastMQTTSend = millis();
  }
  // Serieller Status (alle 60 Sekunden)
  if (millis() - lastSerialOutput > 60000) {
    Serial.printf("[STATUS] Heap: %d, Uptime: %lu s, RSSI: %d dBm\n",
                  ESP.getFreeHeap(), millis() / 1000, WiFi.RSSI());
    lastSerialOutput = millis();
  }
  // Reed-Pin Status prüfen (Debug, alle 10s)
  if (millis() - lastStateCheck > 10000) {
    bool currentState = digitalRead(REED_PIN);
    Serial.printf("[SENSOR] Pin: %s\n", 
                  currentState ? "HIGH (Magnet da)" : "LOW (Magnet weg)");
    lastStateCheck = millis();
  }
  delay(10); // Kleine Pause für Stabilität
 }