Conversion from 1.5.4 to 2.1.1.



  • I am converting all my nodes to 2.1.1 because they are not visible in the Domoticz so I think I have re adjust them all. Is there a central place where the conversion is explained? I found already a lot of info on this forum. Now I have a questions what can I do with the row:
    gw.begin(incomingMessage, AUTO, true);
    I changed it already in
    begin(recieve,AUTO, true);
    But get an erro "begin was not declared in the scope.
    What must I do?


  • Hardware Contributor

    Not easy to say without your sketch..

    But I think that you may miss the "s" in

    #include <MySensors.h>  
    

    For more infos, you can take a look here:



  • @scalz thanks for the link, that was the one I used also. Perhaps you can do something with the whole script in the part void presentation (3rd row)

    // 2x binary switch + dallas temp example 
    // Connect button or door/window reed switch between 
    // digitial I/O pin 4,5 (BUTTON_PIN_4/BUTTON_PIN_5 below) and GND.
    // Connect dallas temp sensor to digital pin 3
    
    #include <MySensors.h>
    #include <SPI.h>
    #include <Bounce2.h>
    #include <DallasTemperature.h>
    #include <OneWire.h>
    #define DIGITAL_MOTION_SENSOR 2
    #define CHILD_ID_MOTION 6
    #define ONE_WIRE_BUS 3 // Pin where dallase sensor is connected 
    #define MAX_ATTACHED_DS18B20 16
    #define RELAY_ON 1                      // switch around for realy HIGH/LOW state
    #define RELAY_OFF 0
    
    Bounce motionsDebouncer = Bounce();
    
    int lastMOTION;
    unsigned long SLEEP_TIME = 420000;
    //unsigned long SLEEP_TIME = 3000;
    unsigned long blockMotionTimer = 0;
    
    
    OneWire oneWire(ONE_WIRE_BUS);
    DallasTemperature sensors(&oneWire);
    
    //#define noRelays 3
    //const int relayPin[] = {A1, A4, A5}; //  switch around pins to your desire
    //const int buttonPin[] = {6, 7, 8}; //  switch around pins to your desire
    #define noRelays 1
    const int relayPin[] = {A1}; //  switch around pins to your desire
    const int buttonPin[] = {6}; //  switch around pins to your desire
    
    class Relay             // relay class, store all relevant data (equivalent to struct)
    {
    public: 
      int buttonPin;                    // physical pin number of button
        int relayPin;                     // physical pin number of relay
      byte oldValue;                    // last Values for key (debounce)
      boolean relayState;               // relay status (also stored in EEPROM)
    };
    
    Relay Relays[noRelays];
    Bounce debouncerRELAY[noRelays];
    MyMessage msgRELAY[noRelays];
    
    
    float lastTemperature[MAX_ATTACHED_DS18B20];
    int numSensors=0;
    boolean receivedConfig = false;
    boolean metric = true; 
    MyMessage msg(0,V_TEMP);
    MyMessage msgMOTION(CHILD_ID_MOTION, V_TRIPPED);
    
    void presentation()  
    {  
      sensors.begin();
      begin(receive, AUTO, true);
      sendSketchInfo("Motion/Temp/relay", "1.0");
      numSensors = sensors.getDeviceCount();
      for (int i=0; i<numSensors && i<MAX_ATTACHED_DS18B20; i++) 
      {   
        present(i, S_TEMP);
      }
    
    
     
    pinMode(DIGITAL_MOTION_SENSOR, INPUT_PULLUP);      // sets the motion sensor digital pin as input
      motionsDebouncer.attach(DIGITAL_MOTION_SENSOR);
      motionsDebouncer.interval(400);
      // Register all sensors to gw (they will be created as child devices)
      present(CHILD_ID_MOTION, S_MOTION, "Motion needs presentation", true);
    
       for (int i = 0; i < noRelays; i++)
      {
        Relays[i].buttonPin = buttonPin[i];              // assign physical pins
        Relays[i].relayPin = relayPin[i];
        msgRELAY[i].sensor = i;                                   // initialize messages
        msgRELAY[i].type = V_LIGHT;
        debouncerRELAY[i] = Bounce();                        // initialize debouncer
        debouncerRELAY[i].attach(buttonPin[i]);
        debouncerRELAY[i].interval(5);
        pinMode(Relays[i].buttonPin, INPUT_PULLUP);
        pinMode(Relays[i].relayPin, OUTPUT);
        Relays[i].relayState = gw.loadState(i);                               // retrieve last values from EEPROM
        digitalWrite(Relays[i].relayPin, Relays[i].relayState ? RELAY_ON : RELAY_OFF); // and set relays accordingly
        send(msgRELAY[i].set(Relays[i].relayState ? true : false));                 // make controller aware of last status
        present(i, S_LIGHT);                               // present sensor to gateway
        delay(250);
    
      }
        
    }
    void loop() 
    {
    //process(); 
    
    for (byte i = 0; i < noRelays; i++)
      {
        debouncerRELAY[i].update();
        byte value = debouncerRELAY[i].read();
        if (value != Relays[i].oldValue && value == 0)
        {
          Relays[i].relayState = !Relays[i].relayState;
          digitalWrite(Relays[i].relayPin, Relays[i].relayState ? RELAY_ON : RELAY_OFF);
          send(msgRELAY[i].set(Relays[i].relayState ? true : false));
          saveState( i, Relays[i].relayState );
        }                 // save sensor state in EEPROM (location == sensor number)
    
        Relays[i].oldValue = value;
      }
      
      if (blockMotionTimer == 0) {
        if (motionsDebouncer.update()) {
            int value = motionsDebouncer.read();
            Serial.println( "PIR " + (String)value );
            send( msgMOTION.set( value ), true ); // Also it might need inverted value
            blockMotionTimer = (millis() + SLEEP_TIME);
       }
    } else {
            motionsDebouncer.update(); // dummy update to prevent false trigger after timer expires 
            if (blockMotionTimer < millis()) {
                blockMotionTimer = 0;
            }
    }
     
     
      
      updateTemperature(30);// update time in seconds
      
    }
    
    void updateTemperature(int frequency)
    {
      static unsigned long lastUpdateTime;
      if (millis() - lastUpdateTime >= frequency * 1000UL)
      {
        sensors.requestTemperatures(); 
        for (int i=0; i<numSensors && i< MAX_ATTACHED_DS18B20; i++) 
        {
          float temperature = static_cast<float>(static_cast<int>((getConfig().isMetric?sensors.getTempCByIndex(i):sensors.getTempFByIndex(i)) * 10.)) / 10.;
          if (lastTemperature[i] != temperature && temperature != -127.00) 
          {
            send(msg.setSensor(i).set(temperature,1));
            lastTemperature[i]=temperature;
          }
        }
        lastUpdateTime += frequency * 1000UL;
      }
    }
    
    //void incomingMessage(const MyMessage &message)
    
    void receive(const MyMessage &message){
    
      if (message.type == V_LIGHT)
      {
        if (message.sensor < noRelays)            // check if message is valid for relays..... previous line  [[[ if (message.sensor <=noRelays){ ]]]
        {
          Relays[message.sensor].relayState = message.getBool();
          digitalWrite(Relays[message.sensor].relayPin, Relays[message.sensor].relayState ? RELAY_ON : RELAY_OFF); // and set relays accordingly
          gw.saveState( message.sensor, Relays[message.sensor].relayState ); // save sensor state in EEPROM (location == sensor number)
        }
      }
    //gw.wait(50);
    
    }
    

  • Hardware Contributor

    you don't need to use begin() with 2.x. It's explained in the link above 😉 Take a look at the examples in case



  • @scalz That is a good idea, totaly forgotten🌀



  • @scalz I changed everything as mentioned before. I uploaded to my Nano but I see nothing in the serial monitor. I hope it is my last queation:
    the code is until now:

    In// 2x binary switch + dallas temp example 
    // Connect button or door/window reed switch between 
    // digitial I/O pin 4,5 (BUTTON_PIN_4/BUTTON_PIN_5 below) and GND.
    // Connect dallas temp sensor to digital pin 3
    
    #include <MySensors.h>
    #include <SPI.h>
    #include <Bounce2.h>
    #include <DallasTemperature.h>
    #include <OneWire.h>
    #define MY_RADIO_NRF24
    #define DIGITAL_MOTION_SENSOR 2
    #define CHILD_ID_MOTION 6
    #define ONE_WIRE_BUS 3 // Pin where dallase sensor is connected 
    #define MAX_ATTACHED_DS18B20 16
    #define RELAY_ON 1                      // switch around for realy HIGH/LOW state
    #define RELAY_OFF 0
    
    Bounce motionsDebouncer = Bounce();
    
    int lastMOTION;
    unsigned long SLEEP_TIME = 420000;
    //unsigned long SLEEP_TIME = 3000;
    unsigned long blockMotionTimer = 0;
    
    
    OneWire oneWire(ONE_WIRE_BUS);
    DallasTemperature sensors(&oneWire);
    
    //#define noRelays 3
    //const int relayPin[] = {A1, A4, A5}; //  switch around pins to your desire
    //const int buttonPin[] = {6, 7, 8}; //  switch around pins to your desire
    #define noRelays 1
    const int relayPin[] = {A1}; //  switch around pins to your desire
    const int buttonPin[] = {6}; //  switch around pins to your desire
    
    class Relay             // relay class, store all relevant data (equivalent to struct)
    {
    public: 
      int buttonPin;                    // physical pin number of button
        int relayPin;                     // physical pin number of relay
      byte oldValue;                    // last Values for key (debounce)
      boolean relayState;               // relay status (also stored in EEPROM)
    };
    
    Relay Relays[noRelays];
    Bounce debouncerRELAY[noRelays];
    MyMessage msgRELAY[noRelays];
    
    
    float lastTemperature[MAX_ATTACHED_DS18B20];
    int numSensors=0;
    boolean receivedConfig = false;
    boolean metric = true; 
    MyMessage msg(0,V_TEMP);
    MyMessage msgMOTION(CHILD_ID_MOTION, V_TRIPPED);
    
    void presentation()  
    {  
      //sensors.begin();
      //begin receive, AUTO, true;
      sendSketchInfo("Motion/Temp/relay", "1.0");
      numSensors = sensors.getDeviceCount();
      for (int i=0; i<numSensors && i<MAX_ATTACHED_DS18B20; i++) 
      {   
        present(i, S_TEMP);
      }
    
    
     
    pinMode(DIGITAL_MOTION_SENSOR, INPUT_PULLUP);      // sets the motion sensor digital pin as input
      motionsDebouncer.attach(DIGITAL_MOTION_SENSOR);
      motionsDebouncer.interval(400);
      // Register all sensors to gw (they will be created as child devices)
      present(CHILD_ID_MOTION, S_MOTION, "Motion needs presentation", true);
    
       for (int i = 0; i < noRelays; i++)
      {
        Relays[i].buttonPin = buttonPin[i];              // assign physical pins
        Relays[i].relayPin = relayPin[i];
        msgRELAY[i].sensor = i;                                   // initialize messages
        msgRELAY[i].type = V_LIGHT;
        debouncerRELAY[i] = Bounce();                        // initialize debouncer
        debouncerRELAY[i].attach(buttonPin[i]);
        debouncerRELAY[i].interval(5);
        pinMode(Relays[i].buttonPin, INPUT_PULLUP);
        pinMode(Relays[i].relayPin, OUTPUT);
        Relays[i].relayState = loadState(i);                               // retrieve last values from EEPROM
        digitalWrite(Relays[i].relayPin, Relays[i].relayState ? RELAY_ON : RELAY_OFF); // and set relays accordingly
        send(msgRELAY[i].set(Relays[i].relayState ? true : false));                 // make controller aware of last status
        present(i, S_LIGHT);                               // present sensor to gateway
        delay(250);
    
      }
        
    }
    void loop() 
    {
    
    
    for (byte i = 0; i < noRelays; i++)
      {
        debouncerRELAY[i].update();
        byte value = debouncerRELAY[i].read();
        if (value != Relays[i].oldValue && value == 0)
        {
          Relays[i].relayState = !Relays[i].relayState;
          digitalWrite(Relays[i].relayPin, Relays[i].relayState ? RELAY_ON : RELAY_OFF);
          send(msgRELAY[i].set(Relays[i].relayState ? true : false));
          saveState( i, Relays[i].relayState );
        }                 // save sensor state in EEPROM (location == sensor number)
    
        Relays[i].oldValue = value;
      }
      
      if (blockMotionTimer == 0) {
        if (motionsDebouncer.update()) {
            int value = motionsDebouncer.read();
            Serial.println( "PIR " + (String)value );
            send( msgMOTION.set( value ), true ); // Also it might need inverted value
            blockMotionTimer = (millis() + SLEEP_TIME);
       }
    } else {
            motionsDebouncer.update(); // dummy update to prevent false trigger after timer expires 
            if (blockMotionTimer < millis()) {
                blockMotionTimer = 0;
            }
    }
     
     
      
      updateTemperature(30);// update time in seconds
      
    }
    
    void updateTemperature(int frequency)
    {
      static unsigned long lastUpdateTime;
      if (millis() - lastUpdateTime >= frequency * 1000UL)
      {
        sensors.requestTemperatures(); 
        for (int i=0; i<numSensors && i< MAX_ATTACHED_DS18B20; i++) 
        {
          float temperature = static_cast<float>(static_cast<int>((getControllerConfig().isMetric?sensors.getTempCByIndex(i):sensors.getTempFByIndex(i)) * 10.)) / 10.;
          if (lastTemperature[i] != temperature && temperature != -127.00) 
          {
            send(msg.setSensor(i).set(temperature,1));
            lastTemperature[i]=temperature;
          }
        }
        lastUpdateTime += frequency * 1000UL;
      }
    }
    
    //void incomingMessage(const MyMessage &message)
    
    void receive(const MyMessage &message){
    
      if (message.type == V_LIGHT)
      {
        if (message.sensor < noRelays)            // check if message is valid for relays..... previous line  [[[ if (message.sensor <=noRelays){ ]]]
        {
          Relays[message.sensor].relayState = message.getBool();
          digitalWrite(Relays[message.sensor].relayPin, Relays[message.sensor].relayState ? RELAY_ON : RELAY_OFF); // and set relays accordingly
          saveState( message.sensor, Relays[message.sensor].relayState ); // save sensor state in EEPROM (location == sensor number)
        }
      }
    //gw.wait(50);
    
    }
    `

  • Hardware Contributor

    in the link i provided above, at the 2nd line..

    "It is important to do these defines before including MySensors.h, otherwise they will go unnoticed when the library evaluates which parts to include."



  • @Dick I hope it is the last time to keep you involved, still nothing in the serial Monitor. For a test I loaded an Example and that showed up in the monitor. Any idea?

    In// 2x binary switch + dallas temp example
    // Connect button or door/window reed switch between
    // digitial I/O pin 4,5 (BUTTON_PIN_4/BUTTON_PIN_5 below) and GND.
    // Connect dallas temp sensor to digital pin 3
    
    #define MY_RADIO_NRF24
    #define DIGITAL_MOTION_SENSOR 2
    #define CHILD_ID_MOTION 6
    #define ONE_WIRE_BUS 3 // Pin where dallase sensor is connected 
    #define MAX_ATTACHED_DS18B20 16
    #define noRelays 1
    #define RELAY_ON 1                      // switch around for realy HIGH/LOW state
    #define RELAY_OFF 0
    
    #include <MySensors.h>
    #include <SPI.h>
    #include <Bounce2.h>
    #include <DallasTemperature.h>
    #include <OneWire.h>
    
    Bounce motionsDebouncer = Bounce();
    
    int lastMOTION;
    unsigned long SLEEP_TIME = 420000;
    //unsigned long SLEEP_TIME = 3000;
    unsigned long blockMotionTimer = 0;
    
    
    OneWire oneWire(ONE_WIRE_BUS);
    DallasTemperature sensors(&oneWire);
    
    //#define noRelays 3
    //const int relayPin[] = {A1, A4, A5}; //  switch around pins to your desire
    //const int buttonPin[] = {6, 7, 8}; //  switch around pins to your desire
    const int relayPin[] = {A1}; //  switch around pins to your desire
    const int buttonPin[] = {6}; //  switch around pins to your desire
    
    class Relay             // relay class, store all relevant data (equivalent to struct)
    {
      public:
        int buttonPin;                    // physical pin number of button
        int relayPin;                     // physical pin number of relay
        byte oldValue;                    // last Values for key (debounce)
        boolean relayState;               // relay status (also stored in EEPROM)
    };
    
    Relay Relays[noRelays];
    Bounce debouncerRELAY[noRelays];
    MyMessage msgRELAY[noRelays];
    
    
    float lastTemperature[MAX_ATTACHED_DS18B20];
    int numSensors = 0;
    boolean receivedConfig = false;
    boolean metric = true;
    MyMessage msg(0, V_TEMP);
    MyMessage msgMOTION(CHILD_ID_MOTION, V_TRIPPED);
    
    void presentation()
    {
      //sensors.begin();
      //begin receive, AUTO, true;
      sendSketchInfo("Motion/Temp/relay", "1.0");
      numSensors = sensors.getDeviceCount();
      for (int i = 0; i < numSensors && i < MAX_ATTACHED_DS18B20; i++)
      {
        present(i, S_TEMP);
      }
    
      pinMode(DIGITAL_MOTION_SENSOR, INPUT_PULLUP);      // sets the motion sensor digital pin as input
      motionsDebouncer.attach(DIGITAL_MOTION_SENSOR);
      motionsDebouncer.interval(400);
      // Register all sensors to gw (they will be created as child devices)
      present(CHILD_ID_MOTION, S_MOTION, "Motion needs presentation", true);
    
      for (int i = 0; i < noRelays; i++)
      {
        Relays[i].buttonPin = buttonPin[i];              // assign physical pins
        Relays[i].relayPin = relayPin[i];
        msgRELAY[i].sensor = i;                                   // initialize messages
        msgRELAY[i].type = V_LIGHT;
        debouncerRELAY[i] = Bounce();                        // initialize debouncer
        debouncerRELAY[i].attach(buttonPin[i]);
        debouncerRELAY[i].interval(5);
        pinMode(Relays[i].buttonPin, INPUT_PULLUP);
        pinMode(Relays[i].relayPin, OUTPUT);
        Relays[i].relayState = loadState(i);                               // retrieve last values from EEPROM
        digitalWrite(Relays[i].relayPin, Relays[i].relayState ? RELAY_ON : RELAY_OFF); // and set relays accordingly
        send(msgRELAY[i].set(Relays[i].relayState ? true : false));                 // make controller aware of last status
        present(i, S_LIGHT);                               // present sensor to gateway
        delay(250);
    
      }
    
    }
    void loop()
    {
    
    
      for (byte i = 0; i < noRelays; i++)
      {
        debouncerRELAY[i].update();
        byte value = debouncerRELAY[i].read();
        if (value != Relays[i].oldValue && value == 0)
        {
          Relays[i].relayState = !Relays[i].relayState;
          digitalWrite(Relays[i].relayPin, Relays[i].relayState ? RELAY_ON : RELAY_OFF);
          send(msgRELAY[i].set(Relays[i].relayState ? true : false));
          saveState( i, Relays[i].relayState );
        }                 // save sensor state in EEPROM (location == sensor number)
    
        Relays[i].oldValue = value;
      }
    
      if (blockMotionTimer == 0) {
        if (motionsDebouncer.update()) {
          int value = motionsDebouncer.read();
          Serial.println( "PIR " + (String)value );
          send( msgMOTION.set( value ), true ); // Also it might need inverted value
          blockMotionTimer = (millis() + SLEEP_TIME);
        }
      } else {
        motionsDebouncer.update(); // dummy update to prevent false trigger after timer expires
        if (blockMotionTimer < millis()) {
          blockMotionTimer = 0;
        }
      }
    
    
    
      updateTemperature(30);// update time in seconds
    
    }
    
    void updateTemperature(int frequency)
    {
      static unsigned long lastUpdateTime;
      if (millis() - lastUpdateTime >= frequency * 1000UL)
      {
        sensors.requestTemperatures();
        for (int i = 0; i < numSensors && i < MAX_ATTACHED_DS18B20; i++)
        {
          float temperature = static_cast<float>(static_cast<int>((getControllerConfig().isMetric ? sensors.getTempCByIndex(i) : sensors.getTempFByIndex(i)) * 10.)) / 10.;
          if (lastTemperature[i] != temperature && temperature != -127.00)
          {
            send(msg.setSensor(i).set(temperature, 1));
            lastTemperature[i] = temperature;
          }
        }
        lastUpdateTime += frequency * 1000UL;
      }
    }
    
    //void incomingMessage(const MyMessage &message)
    
    void receive(const MyMessage &message) {
    
      if (message.type == V_LIGHT)
      {
        if (message.sensor < noRelays)            // check if message is valid for relays..... previous line  [[[ if (message.sensor <=noRelays){ ]]]
        {
          Relays[message.sensor].relayState = message.getBool();
          digitalWrite(Relays[message.sensor].relayPin, Relays[message.sensor].relayState ? RELAY_ON : RELAY_OFF); // and set relays accordingly
          saveState( message.sensor, Relays[message.sensor].relayState ); // save sensor state in EEPROM (location == sensor number)
        }
      }
      //gw.wait(50);
    
    }
    `

  • Hero Member

    @Dick Add the following to the beginning of your sketch to enable serial print:

    #define MY_DEBUG
    


  • @korttoma That is easy,Thanks for the solution.


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