LEDstoffroehre/esp-deckenlicht.ino

#include <Homie.h>
#include <ArduinoOTA.h>

#define PIN_LIGHT    D5
#define PIN_LIGHT1   D6
#define PIN_LIGHT2   D7
#define PIN_LIGHT3   D8
#define PIN_SENSOR   D0

#define FULL 255
#define LOWER 50
#define MINIMUM 1
#define OFF 0
int timeout = (1000-50);

#define FW_NAME "esp-deckenlicht"
#define FW_VERSION "1.0.1"
int w0;
int w1;
int w2;
int w3;
int w0b, w1b, w2b, w3b;
int step = 0;
int strobo = 1;
bool disco = false;
int lastEvent = 0;

//Fluorescent effect
int fluorescentSet=0;
bool fluorescentActive=false;
long fluorescentLastActivated=0;
#define FLUORESCENT_TIMEDIVIDE 10
int fluorescentTemp=0;
#define FLUORESCENTUPDATEINTERVAL 20
long fluorescentLastUpdated=0;
int fluorescentCurrentBrightness=0; //current brightness for effect duration
#define FLUORESCENTTEMPMAX 400

bool lastSensorValue = false;

HomieNode lightNode("strip", "strip");
HomieNode sensorNode("sensor", "sensor");
Bounce debouncer = Bounce();

bool speedHandler(const HomieRange& range, const String& value) {
  Homie.getLogger() << "speed " << ": " << value << endl;
  timeout = value.toInt();
  lightNode.setProperty("speed").send(value);
  return true;
}

bool stroboToggleHandler(const HomieRange& range, const String& value) {
  Homie.getLogger() << "stroboToggle " << ": " << value << endl;
  lightNode.setProperty("stroboToggle").send(value);
  strobo *= -1;
  if (strobo == 1)
  {
    w0 = w1 = w2 = w3 = FULL;
  }
  else
  {
    w0 = w1 = w2 = w3 = OFF;
  }
  output();
}

bool beatHandler(const HomieRange& range, const String& value) {
  Homie.getLogger() << "beat " << ": " << value << endl;
  lightNode.setProperty("beat").send(value);
  if (step >= 4) {
    step = 0;
  }
  // Cycle each light from 255 to 50 to 1 to off
  switch (step)
  {
    case 0:
      w0 = FULL;
      w1 = OFF;
      w2 = MINIMUM;
      w3 = LOWER;
      break;
    case 1:
      w1 = FULL;
      w2 = OFF;
      w3 = MINIMUM;
      w0 = LOWER;
      break;
    case 2:
      w2 = FULL;
      w3 = OFF;
      w0 = MINIMUM;
      w1 = LOWER;
      break;
    case 3:
      w3 = FULL;
      w0 = OFF;
      w1 = MINIMUM;
      w2 = LOWER;
      break;
    default:
      w0 = w1 = w2 = w3 = 0;
      break;
  }
  output();
  step++;
}

bool discoHandler(const HomieRange& range, const String& value) {
  Homie.getLogger() << "disco " << ": " << value << endl;
  lightNode.setProperty("disco").send(value);
  if (value.toInt() == 0)
  {
    disco = false;
    // Return to previous state
    w0 = w0b;
    w1 = w1b;
    w2 = w2b;
    w3 = w3b;
    output();
  } else
  {
    step = 0;
    w0b = w0;
    w1b = w1;
    w2b = w2;
    w3b = w3;
    disco = true;
  }
  return true;
}


bool fluorescentHandler(const HomieRange& range, const String& value) {
  Homie.getLogger() << "fluorescent " << ": " << value << endl;
  lightNode.setProperty("fluorescent").send(value);
  fluorescentSet=value.toInt();
  disco = false;
  if (fluorescentSet==0){ // turned off
    fluorescentActive=false; //set effect off
    w0 = 0;
    w1 = 0;
    w2 = 0;
    w3 = 0;
  }else{ //turned on
    if (w0==0 && w1==0 && w2==0 && w3==0){ //turned on and was off before
      //Initialization
      fluorescentActive=true;  //start effect
      fluorescentLastActivated=millis();
      fluorescentLastUpdated=millis();
      fluorescentTemp=0; //"temperature" for warmup
      fluorescentCurrentBrightness=0; //brightness for effect duration
    }
  }
  output();
  return true;
}

bool lightHandler(const HomieRange& range, const String& value) {
  Homie.getLogger() << "light " << ": " << value << endl;
  disco = false;
  w0 = value.toInt();
  w1 = value.toInt();
  w2 = value.toInt();
  w3 = value.toInt();
  lightNode.setProperty("light").send(value);
  output();
  return true;
}

bool light0Handler(const HomieRange& range, const String& value) {
  Homie.getLogger() << "light0 " << ": " << value << endl;
  w0 = value.toInt();
  disco = false;
  lightNode.setProperty("light0").send(value);
  output();
  return true;
}

bool light1Handler(const HomieRange& range, const String& value) {
  Homie.getLogger() << "light1 " << ": " << value << endl;
  w1 = value.toInt();
  disco = false;
  lightNode.setProperty("light1").send(value);
  output();
  return true;
}

bool light2Handler(const HomieRange& range, const String& value) {
  Homie.getLogger() << "light2 " << ": " << value << endl;
  w2 = value.toInt();
  disco = false;
  lightNode.setProperty("light2").send(value);
  output();
  return true;
}

bool light3Handler(const HomieRange& range, const String& value) {
  Homie.getLogger() << "light3 " << ": " << value << endl;
  w3 = value.toInt();
  disco = false;
  lightNode.setProperty("light3").send(value);
  output();
  return true;
}

void output() {
  // * 4 to scale the input up for ESP Arduino default 10 bit PWM
  if (w0 == FULL) 
  {
      analogWrite(PIN_LIGHT, 1023);
  } else  {   
      analogWrite(PIN_LIGHT, w0*4);
  }
  if (w1 == FULL) 
  {
      analogWrite(PIN_LIGHT1, 1023);
  } else  {   
      analogWrite(PIN_LIGHT1, w1*4);
  }
  if (w2 == FULL) 
  {
      analogWrite(PIN_LIGHT2, 1023);
  } else  {   
      analogWrite(PIN_LIGHT2, w2*4);
  }
  if (w3 == FULL)
  {
      analogWrite(PIN_LIGHT3, 1023);
  } else  {   
      analogWrite(PIN_LIGHT3, w3*4);
  }
}

void loopHandler()
{
  if (disco)
  {
    if (millis() - lastEvent >= (1000-timeout) || lastEvent == 0) {
      lastEvent = millis();
      if (step >= 4) {
        step = 0;
      }
      // Cycle each light from 255 to 50 to 1 to off
      switch (step)
      {
        case 0:
          w0 = FULL;
          w1 = OFF;
          w2 = MINIMUM;
          w3 = LOWER;
          break;
        case 1:
          w1 = FULL;
          w2 = OFF;
          w3 = MINIMUM;
          w0 = LOWER;
          break;
        case 2:
          w2 = FULL;
          w3 = OFF;
          w0 = MINIMUM;
          w1 = LOWER;
          break;
        case 3:
          w3 = FULL;
          w0 = OFF;
          w1 = MINIMUM;
          w2 = LOWER;
          break;
        default:
          w0 = w1 = w2 = w3 = 0;
          break;
      }
      output();
      step++;
    }
  }
  if (fluorescentActive){
    long _time=millis()-fluorescentLastActivated; //time since activated


    //mosquitto_pub -h raum.ctdo.de -t "homie/esp-deckenlicht/strip/fluorescent/set" -m "255"

    if (millis() > fluorescentLastUpdated+FLUORESCENTUPDATEINTERVAL){ //Update values
      fluorescentTemp+=random(0, 5); //min (inclusive), max (exclusive)
      fluorescentLastUpdated=millis();

      if (random(0,256)<fluorescentTemp*1.0/FLUORESCENTTEMPMAX*256){ //the warmer, the more often
        if (random(0,10)==0){ //ignite
          fluorescentCurrentBrightness=fluorescentSet*0.9;
        }
      }
      if (random(0,256)>fluorescentTemp*1.0/FLUORESCENTTEMPMAX*256){ //the colder, the more often
        if (fluorescentCurrentBrightness<5){ //not on
          if (random(0,20)==0){ //ignite
            fluorescentCurrentBrightness=fluorescentSet*0.9;
          }
        }
        fluorescentCurrentBrightness-=50;
      }

    
      if (fluorescentTemp>=FLUORESCENTTEMPMAX){ //finished
        fluorescentActive=false;
        fluorescentCurrentBrightness=fluorescentSet; //set disired value
      }
      
      if (fluorescentCurrentBrightness<0){
        fluorescentCurrentBrightness=0;
      }else if (fluorescentCurrentBrightness>255){
        fluorescentCurrentBrightness=255;
      }
      w0 = w1 = w2 = w3 = fluorescentCurrentBrightness;
      output();
    }
  }
  bool sensorValue = debouncer.read();
  if (Homie.isConfigured() && Homie.isConnected() && sensorValue != lastSensorValue) {
      sensorNode.setProperty("motion").send(sensorValue ? "true" : "false");
      lastSensorValue = sensorValue;
  }

}

void setup() {
  Serial.begin(115200);
  Serial << endl << endl;

  pinMode(PIN_LIGHT, OUTPUT);
  pinMode(PIN_LIGHT1, OUTPUT);
  pinMode(PIN_LIGHT2, OUTPUT);
  pinMode(PIN_LIGHT3, OUTPUT);
  
  debouncer.attach(PIN_SENSOR,INPUT);
  debouncer.interval(50);


  Homie_setFirmware(FW_NAME, FW_VERSION);
  Homie_setBrand(FW_NAME);
  Homie.setLoopFunction(loopHandler);

  lightNode.advertise("speed").settable(speedHandler);
  lightNode.advertise("disco").settable(discoHandler);
  lightNode.advertise("beat").settable(beatHandler);
  lightNode.advertise("light").settable(lightHandler);
  lightNode.advertise("light0").settable(light0Handler);
  lightNode.advertise("light1").settable(light1Handler);
  lightNode.advertise("light2").settable(light2Handler);
  lightNode.advertise("light3").settable(light3Handler);
  lightNode.advertise("fluorescent").settable(fluorescentHandler);
  
  sensorNode.advertise("motion");

  // Activate other PWM frequency. 1000 (1 KHz) is default
  analogWriteFreq(30000);

  // Restore last state
  output();

  Homie.setup();

  ArduinoOTA.setHostname(Homie.getConfiguration().deviceId);
  ArduinoOTA.begin();
}

void loop() {
  Homie.loop();
  debouncer.update();
  ArduinoOTA.handle();
}