Wave and feed code help

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Posts: 206
Joined: Sat Oct 10, 2015 9:17 pm
PostPosted: Mon Mar 07, 2016 4:07 pm
New coding help I need add a few things need dc pump mode for a adjustable amount of hours maybe time can be different but would like it to switch from sine , and short pulse , and when leaving feed mode to be in nutrient expor mode for a adjustable about of time and to have a max setting for adjustable nighttime

So I would like to adjust the hours inbetween switchING modes
Adjustable time for leaving feed mode for length of nutrient mode
Adjustable limitING speed and when it starts and ends night mode

then other for my return pump to delay adjustable mins after leaving feed mode (I currently useing delay on but it also effects waterchange and I don't want delay in water change mode)


also I want to add on/off/auto over idea in the menu for if my router stops I can manually switch relay on or off.

and last want to add my ato on cycle code to be in memory so i can edit the time on the url memory location where it says 3 in this code
Code: Select all
    ReefAngel.SingleATO(true, Port7, InternalMemory.ATOExtendedTimeout_read(), 3);



Code: Select all
#include <ReefAngel_Features.h>
    #include <Globals.h>
    #include <RA_Wifi.h>
    #include <Wire.h>
    #include <OneWire.h>
    #include <Time.h>
    #include <DS1307RTC.h>
    #include <InternalEEPROM.h>
    #include <RA_NokiaLCD.h>
    #include <RA_ATO.h>
    #include <RA_Joystick.h>
    #include <LED.h>
    #include <RA_TempSensor.h>
    #include <Relay.h>
    #include <RA_PWM.h>
    #include <Timer.h>
    #include <Memory.h>
    #include <RA_Colors.h>
    #include <RA_CustomColors.h>
    #include <ReefAngel.h>
    #include <SunLocation.h>
    #include <Tide.h>
    #include <DCPump.h>
    #include <WiFiAlert.h>
    #include <DCPump.h>

    // Won't compile without this...
    // ReefAngel.DCPump.UseMemory=true;
    // Custom menus
    #include <avr/pgmspace.h>
    prog_char menu1_label[] PROGMEM = "Feeding Mode";
    prog_char menu2_label[] PROGMEM = "Water Change";
    prog_char menu3_label[] PROGMEM = "ATO Clear";
    prog_char menu4_label[] PROGMEM = "Overheat Clear";
    prog_char menu5_label[] PROGMEM = "PH Calibration";
    prog_char menu6_label[] PROGMEM = "Date / Time";

    // Group the menu entries together
    PROGMEM const char *menu_items[] = {
    menu1_label, menu2_label, menu3_label,
    menu4_label, menu5_label, menu6_label
    };

    // Define Custom Memory Locations
    #define Mem_I_Latitude        108
    #define Mem_I_Longitude       110
    #define Mem_B_AcclRiseOffset  112
    #define Mem_B_AcclSetOffset   113
    #define Mem_B_AcclDay         114
    #define Mem_B_LightMode       160
    #define Mem_B_LightOffset     161
    #define Mem_I_RiseOffset      162
    #define Mem_I_SetOffset       164
    #define Mem_B_AcclActinicOffset     166
    #define Mem_B_AcclDaylightOffset    167
    #define Mem_B_LightsOffPerc   171

    #define Mem_B_PrintDebug      198
    #define Mem_B_ResetMemory     199

    void init_memory() {
      // Initialize Custom Memory Locations
      InternalMemory.write_int(Mem_I_Latitude,-21);
      InternalMemory.write_int(Mem_I_Longitude,-147);
      InternalMemory.write(Mem_B_AcclRiseOffset,11);
      InternalMemory.write(Mem_B_AcclSetOffset,11);
      InternalMemory.write(Mem_B_AcclDay,0);
      InternalMemory.write(Mem_B_LightOffset,30);
      InternalMemory.write(Mem_B_LightMode,1);
      InternalMemory.write_int(Mem_I_RiseOffset,21);
      InternalMemory.write_int(Mem_I_SetOffset,21);
      InternalMemory.write(Mem_B_AcclActinicOffset,166);
      InternalMemory.write(Mem_B_AcclDaylightOffset,66);
      InternalMemory.write(Mem_B_LightsOffPerc,1);

      InternalMemory.write(Mem_B_ResetMemory,false);
    }

    #define NUMBERS_8x16


    // Define Relay Ports by Name
    #define Return             1
    #define Heater             2
    #define WhiteLeft          3
    #define BlueLeft           4
    #define WhiteRight         5
    #define BlueRight          6
    #define Autotopoff         7
    #define Skimmer            8

    ////// Place global variable code below here

    // Custom classes
    SunLocation sun;
    Tide tide;

    // For Cloud and preset code
    int DaylightPWMValue=0;
    int ActinicPWMValue=0;
    int DaylightPWMValue0=0;        // For cloud code, channel 0
    int DaylightPWMValue2=0;        // For cloud code, chennel 2
    int ActinicPWMValue1=0;        // For cloud code, channel 0
    int ActinicPWMValue3=0;        // For cloud code, chennel 2

    // Needs to be global for DrawCustomGraph()
    int ScreenID=1;
    ////// Place global variable code above here

    // Setup on controller startup/reset
    void setup()
    {
      // This must be the first line
      ReefAngel.Init();  //Initialize controller
      ReefAngel.InitMenu(pgm_read_word(&(menu_items[0])),SIZE(menu_items)); // Initialize Menu
     
      // Ports toggled in Feeding Mode
      ReefAngel.FeedingModePorts = Port1Bit | Port2Bit ;
      // Ports toggled in Water Change Mode
      ReefAngel.WaterChangePorts = Port1Bit | Port2Bit  | Port7Bit  | Port8Bit;
      // Ports toggled when Lights On / Off menu entry selected
      ReefAngel.LightsOnPorts = Port3Bit | Port4Bit | Port5Bit | Port6Bit;
      // Ports turned off when Overheat temperature exceeded
      ReefAngel.OverheatShutoffPorts = Port2Bit;
      // Use T1 probe as temperature and overheat functions
      ReefAngel.TempProbe = T1_PROBE;
      ReefAngel.OverheatProbe = T1_PROBE;
     
      // Feeeding and Water Change mode speed
      ReefAngel.DCPump.FeedingSpeed=0;
      ReefAngel.DCPump.WaterChangeSpeed=0;
     
       // Ports that are always on
    ReefAngel.Relay.On( Port1 ); // Return Pump
     
       
      ////// Place additional initialization code below here
   
       
      if (InternalMemory.read(Mem_B_ResetMemory))
        init_memory();
     ////// Place additional initialization code above here
    }

    void loop()
    {
    ReefAngel.Relay.DelayedOn( Port1 ); // Return Pump
    ReefAngel.SingleATO(true, Port7, InternalMemory.ATOExtendedTimeout_read(), 3); // ato cycle once every 3 hour
    ReefAngel.Relay.Set(Port8, ReefAngel.HighATO.IsActive()); // Skimmer no time out
    ReefAngel.DCPump.ExpansionChannel[4] = Sync; // Left Jebao RW4
    ReefAngel.DCPump.ExpansionChannel[5] = Sync; // jebao rw4
    ReefAngel.StandardHeater(Heater);
     
      ////// Place your custom code below here
     
      // Lighting and Flow
      SetSun();               // Setup Sun rise/set lighting
      AcclimateLED();         // Apply acclimation dimming
      LEDPresets();
      CheckCloud();           //  Check for cloud and lightning.
      UpdateLED();
     
     
      ////// Place your custom code above here

      // This should always be the last line
       ReefAngel.Portal( "troylong45" );
    ReefAngel.DDNS( "1" ); // Your DDNS is troylong45-1.myreefangel.com
    ReefAngel.ShowInterface();
    }

   

    void SetSun() {
      // Start acclimation routine
      int acclRiseOffset=InternalMemory.read(Mem_B_AcclRiseOffset)*60;
      int acclSetOffset=InternalMemory.read(Mem_B_AcclSetOffset)*60;
      byte acclDay=InternalMemory.read(Mem_B_AcclDay);
     
      // See if we are acclimating corals and decrease the countdown each day
      static boolean acclCounterReady=false;
      if (now()%SECS_PER_DAY!=0) acclCounterReady=true;
      if (now()%SECS_PER_DAY==0 && acclCounterReady && acclDay>0) {
        acclDay--;
        acclCounterReady=false;
        InternalMemory.write(Mem_B_AcclDay,acclDay);
      }
      // End acclimation

      // Add some customizable offsets
      sun.Init(InternalMemory.read_int(Mem_I_Latitude), InternalMemory.read_int(Mem_I_Longitude));
      int riseOffset=InternalMemory.read_int(Mem_I_RiseOffset);
      int setOffset=InternalMemory.read_int(Mem_I_SetOffset);
     
      sun.SetOffset(riseOffset,(acclDay*acclRiseOffset),setOffset,(-acclDay*acclSetOffset)); // Bahamas
      sun.CheckAndUpdate(); // Calculate today's Sunrise / Sunset

      byte lightOffset=InternalMemory.read(Mem_B_LightOffset); // left right separation
      byte actinicOffset=InternalMemory.ActinicOffset_read();
     
      // Make sure light resets to zero at night.
      for(int i=0;i<4;i++) { ReefAngel.PWM.SetChannel(i,0); }
     
      switch(InternalMemory.read(Mem_B_LightMode)) {   
        case 0: {
          // Daylights
          ReefAngel.PWM.Channel0PWMSlope(lightOffset,0);
          ReefAngel.PWM.Channel2PWMSlope(0,lightOffset);
          // Actinics
          ReefAngel.PWM.Channel1PWMSlope(actinicOffset+lightOffset,actinicOffset);
          ReefAngel.PWM.Channel3PWMSlope(actinicOffset,actinicOffset+lightOffset);
          break;
        }
        case 1: {
          // Daylights
          ReefAngel.PWM.Channel0PWMParabola(lightOffset,0);
          ReefAngel.PWM.Channel2PWMParabola(0,lightOffset);
          // Actinics
          ReefAngel.PWM.Channel1PWMParabola(actinicOffset+lightOffset,actinicOffset);
          ReefAngel.PWM.Channel3PWMParabola(actinicOffset,actinicOffset+lightOffset);
          break;
        }
      case 2: {
          // Daylights
          ReefAngel.PWM.Channel0PWMSmoothRamp(lightOffset,0);
          ReefAngel.PWM.Channel2PWMSmoothRamp(0,lightOffset);
          // Actinics
          ReefAngel.PWM.Channel1PWMSmoothRamp(actinicOffset+lightOffset,actinicOffset);
          ReefAngel.PWM.Channel3PWMSmoothRamp(actinicOffset,actinicOffset+lightOffset);
          break;
        }
      case 3: {
          // Daylights
          ReefAngel.PWM.Channel0PWMSigmoid(lightOffset,0);
          ReefAngel.PWM.Channel2PWMSigmoid(0,lightOffset);
          // Actinics
          ReefAngel.PWM.Channel1PWMSigmoid(actinicOffset+lightOffset,actinicOffset);
          ReefAngel.PWM.Channel3PWMSigmoid(actinicOffset,actinicOffset+lightOffset);
          break;
        }
      case 4: { // Reverse the actinics in the morning
          // Daylights
          ReefAngel.PWM.Channel0PWMParabola(lightOffset+actinicOffset,0);
          ReefAngel.PWM.Channel2PWMParabola(actinicOffset,lightOffset);
          // Actinics
          ReefAngel.PWM.Channel1PWMParabola(lightOffset,actinicOffset);
          ReefAngel.PWM.Channel3PWMParabola(0,actinicOffset+lightOffset);
          break;
        }
      }
    }


    void AcclimateLED() {
      byte acclDay=InternalMemory.read(Mem_B_AcclDay);
     
      if (acclDay > 0) {
        float acclActinicOffset=acclDay*(40.95*(((float)InternalMemory.read(Mem_B_AcclActinicOffset)/100)));
        float acclDaylightOffset=acclDay*(40.95*((float)InternalMemory.read(Mem_B_AcclDaylightOffset)/100));
        float endPerc;
     
        endPerc=40.95*InternalMemory.PWMSlopeEnd1_read();
        ReefAngel.PWM.SetChannelRaw(1,map(ReefAngel.PWM.GetChannelValueRaw(1),0,endPerc,0,endPerc-acclActinicOffset));
        endPerc=40.95*InternalMemory.PWMSlopeEnd3_read();
        ReefAngel.PWM.SetChannelRaw(3,map(ReefAngel.PWM.GetChannelValueRaw(3),0,endPerc,0,endPerc-acclActinicOffset));
        endPerc=40.95*InternalMemory.PWMSlopeEnd0_read();
        ReefAngel.PWM.SetChannelRaw(0,map(ReefAngel.PWM.GetChannelValueRaw(0),0,endPerc,0,endPerc-acclDaylightOffset));
        endPerc=40.95*InternalMemory.PWMSlopeEnd2_read();
        ReefAngel.PWM.SetChannelRaw(2,map(ReefAngel.PWM.GetChannelValueRaw(2),0,endPerc,0,endPerc-acclDaylightOffset));
      }
    }

    #define LED_1to1  Box1_Port1
    #define LED_2to1  Box1_Port2
    #define LED_3to1  Box1_Port3
    #define LED_4to1  Box1_Port4
    #define LED_BLUE  Box1_Port5
    #define LED_WHITE Box1_Port6
    #define LED_STORM Box1_Port8

    void resetRelayBox(byte ID) {
      // toggle all relays except for the one selected
      for (int i=Box1_Port1;i<=Box1_Port4;i++) {
        if (i!=ID) ReefAngel.Relay.Auto(i);
      }
    }

    void LEDPresets() {
      static byte lastPreset=0;
     
      DaylightPWMValue0=ReefAngel.PWM.GetChannelValueRaw(0);
      ActinicPWMValue1=ReefAngel.PWM.GetChannelValueRaw(1);
      DaylightPWMValue2=ReefAngel.PWM.GetChannelValueRaw(2);
      ActinicPWMValue3=ReefAngel.PWM.GetChannelValueRaw(3);
      DaylightPWMValue=ReefAngel.PWM.GetDaylightValueRaw();
      ActinicPWMValue=ReefAngel.PWM.GetActinicValueRaw();

      if (ReefAngel.Relay.isMaskOn(LED_1to1)) {
        if (lastPreset!=1) resetRelayBox(LED_1to1);
        DaylightPWMValue0=90*40.95;
        ActinicPWMValue1=10*40.95;
        DaylightPWMValue2=90*40.95;
        ActinicPWMValue3=10*40.95;
        lastPreset=1;
      }
     
      if (ReefAngel.Relay.isMaskOff(LED_1to1)) {
        if (lastPreset!=2) resetRelayBox(LED_1to1);
        DaylightPWMValue0=10*40.95;
        ActinicPWMValue1=90*40.95;
        DaylightPWMValue2=10*40.95;
        ActinicPWMValue3=90*40.95;
        lastPreset=2;
      }
     
      if (ReefAngel.Relay.isMaskOn(LED_2to1)) {
        if (lastPreset!=3) resetRelayBox(LED_2to1);
        DaylightPWMValue0=60*40.95;
        ActinicPWMValue1=40*40.95;
        DaylightPWMValue2=60*40.95;
        ActinicPWMValue3=40*40.95;
        lastPreset=3;
      }

      if (ReefAngel.Relay.isMaskOff(LED_2to1)) {
        if (lastPreset!=4) resetRelayBox(LED_2to1);
        DaylightPWMValue0=40*40.95;
        ActinicPWMValue1=60*40.95;
        DaylightPWMValue2=40*40.95;
        ActinicPWMValue3=60*40.95;
        lastPreset=4;
      }

      if (ReefAngel.Relay.isMaskOn(LED_3to1)) {
        if (lastPreset!=5) resetRelayBox(LED_3to1);
        DaylightPWMValue0=75*40.95;
        ActinicPWMValue1=25*40.95;
        DaylightPWMValue2=75*40.95;
        ActinicPWMValue3=25*40.95;
        lastPreset=5;
      }

      if (ReefAngel.Relay.isMaskOff(LED_3to1)) {
        if (lastPreset!=6) resetRelayBox(LED_3to1);
        DaylightPWMValue0=25*40.95;
        ActinicPWMValue1=75*40.95;
        DaylightPWMValue2=25*40.95;
        ActinicPWMValue3=75*40.95;
        lastPreset=6;
      }

      if (ReefAngel.Relay.isMaskOn(LED_4to1)) {
        if (lastPreset!=7) resetRelayBox(LED_4to1);
        DaylightPWMValue0=80*40.95;
        ActinicPWMValue1=20*40.95;
        DaylightPWMValue2=80*40.95;
        ActinicPWMValue3=20*40.95;
        lastPreset=7;
      }

      if (ReefAngel.Relay.isMaskOff(LED_4to1)) {
        if (lastPreset!=8) resetRelayBox(LED_4to1);
        DaylightPWMValue0=20*40.95;
        ActinicPWMValue1=80*40.95;
        DaylightPWMValue2=20*40.95;
        ActinicPWMValue3=80*40.95;
        lastPreset=8;
      }

      if (ReefAngel.Relay.isMaskOn(LED_BLUE)) {
        if (lastPreset!=9) resetRelayBox(LED_BLUE);
        DaylightPWMValue0=0;
        ActinicPWMValue1=80*40.95;
        DaylightPWMValue2=0;
        ActinicPWMValue3=80*40.95;
        lastPreset=9;
      }

      if (ReefAngel.Relay.isMaskOff(LED_BLUE)) {
        if (lastPreset!=10) resetRelayBox(LED_BLUE);
        ActinicPWMValue1=0;
        ActinicPWMValue3=0;
        lastPreset=10;
      }   
     
      if (ReefAngel.Relay.isMaskOn(LED_WHITE)) {
        if (lastPreset!=11) resetRelayBox(LED_WHITE);
        DaylightPWMValue0=80*40.95;
        ActinicPWMValue1=0;
        DaylightPWMValue2=80*40.95;
        ActinicPWMValue3=0;
        lastPreset=11;
      }

      if (ReefAngel.Relay.isMaskOff(LED_WHITE)) {
        if (lastPreset!=12) resetRelayBox(LED_WHITE);
        DaylightPWMValue0=0;
        DaylightPWMValue2=0;
        lastPreset=12;
      } 
      }

    // Write updated values to the channels
    void UpdateLED() {
      ReefAngel.PWM.SetChannelRaw(0,DaylightPWMValue0);
      ReefAngel.PWM.SetChannelRaw(1,ActinicPWMValue1);
      ReefAngel.PWM.SetChannelRaw(2,DaylightPWMValue2);
      ReefAngel.PWM.SetChannelRaw(3,ActinicPWMValue3);
      ReefAngel.PWM.SetDaylightRaw(DaylightPWMValue);   
      ReefAngel.PWM.SetActinicRaw(ActinicPWMValue);

      byte LightsOffPerc=40.95*InternalMemory.read(Mem_B_LightsOffPerc);
     
      if (ReefAngel.PWM.GetChannelValueRaw(0)>=LightsOffPerc) ReefAngel.Relay.On(WhiteLeft); else ReefAngel.Relay.Off(WhiteLeft);
      if (ReefAngel.PWM.GetChannelValueRaw(1)>=LightsOffPerc) ReefAngel.Relay.On(BlueLeft); else ReefAngel.Relay.Off(BlueLeft);
      if (ReefAngel.PWM.GetChannelValueRaw(2)>=LightsOffPerc) ReefAngel.Relay.On(WhiteRight); else ReefAngel.Relay.Off(WhiteRight);
      if (ReefAngel.PWM.GetChannelValueRaw(3)>=LightsOffPerc) ReefAngel.Relay.On(BlueRight); else ReefAngel.Relay.Off(BlueRight);
    }


    // Menu Code
    void MenuEntry1() {
      ReefAngel.FeedingModeStart();
    }
    void MenuEntry2() {
      ReefAngel.WaterChangeModeStart();
    }
    void MenuEntry3() {
      ReefAngel.ATOClear();
      ReefAngel.DisplayMenuEntry("Clear ATO Timeout");
    }
    void MenuEntry4() {
      ReefAngel.OverheatClear();
      ReefAngel.DisplayMenuEntry("Clear Overheat");
    }
    void MenuEntry5() {
      ReefAngel.SetupCalibratePH();
    }
    void MenuEntry6() {
      ReefAngel.SetupDateTime();
    }
    // Custom Main Screen
    void DrawCustomMain() {
      const int NumScreens=4;
      static boolean drawGraph=true;
     
      // Main Header
      // ReefAngel.LCD.DrawText(DefaultFGColor, DefaultBGColor, 35, 2,"Troy's Reef");
      ReefAngel.LCD.DrawDate(5,2);
      ReefAngel.LCD.Clear(COLOR_BLACK, 1, 11, 128, 11);

      // Param Header
      DrawParams(5,14);
     
      switch (ScreenID) {
        case 0:
        {
          if (drawGraph) { ReefAngel.LCD.DrawGraph(5,40); drawGraph=false; }
          break;
        }
        case 1: { DrawStatus(5,40); break; }
        case 2: { DrawSunMoon(5,40); break; }


      }
     
      // Draw Relays
      DrawRelays(12,94);
     
      // Date+Time
      // ReefAngel.LCD.DrawDate(5,122);
     
      if (ReefAngel.Joystick.IsLeft()) {
        ReefAngel.ClearScreen(DefaultBGColor);
        ScreenID--; drawGraph=true;
      }
      if (ReefAngel.Joystick.IsRight()) {
        ReefAngel.ClearScreen(DefaultBGColor);
        ScreenID++; drawGraph=true;
      }
      if (ScreenID<0) ScreenID=NumScreens-1;
      if (ScreenID>=NumScreens) ScreenID=0;
     
    }

    void DrawCustomGraph() {
      if (ScreenID==0)
        ReefAngel.LCD.DrawGraph(5, 40);
    }

    void DrawParams(int x, int y) {
      char buf[16];

      ReefAngel.LCD.DrawText(COLOR_BLACK,DefaultBGColor,x+5,y,"Temp:");
      ReefAngel.LCD.DrawText(COLOR_BLACK,DefaultBGColor,x+80, y, "PH:");
      // Temp and PH
      y+=2;
      ConvertNumToString(buf, ReefAngel.Params.Temp[T2_PROBE], 10);
      ReefAngel.LCD.DrawText(T2TempColor, DefaultBGColor, x+45, y, buf);
      y+=6;
      ConvertNumToString(buf, ReefAngel.Params.Temp[T1_PROBE], 10);
      ReefAngel.LCD.DrawLargeText(T1TempColor, DefaultBGColor, x+5, y, buf, Num8x16);
      ConvertNumToString(buf, ReefAngel.Params.PH, 100);
      ReefAngel.LCD.DrawLargeText(PHColor, DefaultBGColor, x+80, y, buf, Num8x16);
      y+=5;
      ConvertNumToString(buf, ReefAngel.Params.Temp[T3_PROBE], 10);
      ReefAngel.LCD.DrawText(T3TempColor, DefaultBGColor, x+45, y, buf);
    }

    void DrawStatus(int x, int y) {
      int t=x;
     
      ReefAngel.LCD.DrawLargeText(COLOR_INDIGO,DefaultBGColor,15,y,"High",Font8x16);
      ReefAngel.LCD.DrawLargeText(COLOR_INDIGO,DefaultBGColor,85,y,"Low",Font8x16);
     
      if (ReefAngel.HighATO.IsActive()) {
        ReefAngel.LCD.FillCircle(55,y+3,5,COLOR_GREEN);
      } else {
        ReefAngel.LCD.FillCircle(55,y+3,5,COLOR_RED);
      }
     
      if (ReefAngel.LowATO.IsActive()) {
        ReefAngel.LCD.FillCircle(70,y+3,5,COLOR_GREEN);
      } else {
        ReefAngel.LCD.FillCircle(70,y+3,5,COLOR_RED);
      }
      y+=12;
     
     
      // Display Acclimation timer
      byte acclDay=InternalMemory.read(Mem_B_AcclDay);
     
      if (acclDay > 0) {
        ReefAngel.LCD.DrawText(DefaultFGColor,DefaultBGColor,x,y,"Acclimation Day:"); x+=100;
        ReefAngel.LCD.DrawSingleMonitor(acclDay,DefaultFGColor,x,y,1);
      } else {
        ReefAngel.LCD.Clear(DefaultBGColor,x,y,128,y+8);
      }
    }

    void DrawSunMoon(int x, int y) {
      char buf[16];
      int t=x;

      y+=2;
      /// Display Sunrise / Sunset
      sprintf(buf, "%02d:%02d", sun.GetRiseHour(), sun.GetRiseMinute());
      ReefAngel.LCD.DrawText(COLOR_BLACK,DefaultBGColor,x,y,"Rise:"); x+=31;
      ReefAngel.LCD.DrawText(COLOR_RED,DefaultBGColor,x,y,buf);
      sprintf(buf, "%02d:%02d", sun.GetSetHour(), sun.GetSetMinute()); x+=36;
      ReefAngel.LCD.DrawText(COLOR_BLACK,DefaultBGColor,x,y,"Set:"); x+=25;
      ReefAngel.LCD.DrawText(COLOR_RED,DefaultBGColor,x,y,buf);
      y+=15; x=t;
     
    }

    void DrawRelays(int x, int y) {
      // Draw Relays
      byte TempRelay = ReefAngel.Relay.RelayData;
      TempRelay &= ReefAngel.Relay.RelayMaskOff;
      TempRelay |= ReefAngel.Relay.RelayMaskOn;
      ReefAngel.LCD.DrawOutletBox(x, y, TempRelay);
    }

    void DelayedOnModes(byte relay) {
      static unsigned long startTime=now();

      if ( (startTime==LastStart) && ReefAngel.HighATO.IsActive()) {
        ReefAngel.Relay.On(relay);
      } else {
        ReefAngel.Relay.DelayedOn(relay);
      }
    }

     void CheckCloud()
        {
          // ------------------------------------------------------------
          // Change the values below to customize your cloud/storm effect

          // Frequency in days based on the day of the month - number 2 means every 2 days, for example (day 2,4,6 etc)
          // For testing purposes, you can use 1 and cause the cloud to occur everyday
        #define Clouds_Every_X_Days 1

          // Percentage chance of a cloud happening today
          // For testing purposes, you can use 100 and cause the cloud to have 100% chance of happening
        #define Cloud_Chance_per_Day 45

          // Minimum number of minutes for cloud duration.  Don't use max duration of less than 6
        #define Min_Cloud_Duration 1

          // Maximum number of minutes for the cloud duration. Don't use max duration of more than 255
        #define Max_Cloud_Duration 5

          // Minimum number of clouds that can happen per day
        #define Min_Clouds_per_Day 2

          // Maximum number of clouds that can happen per day
        #define Max_Clouds_per_Day 30

          // Only start the cloud effect after this setting
          // In this example, start cloud after noon
        #define Start_Cloud_After NumMins(10,00)

          // Always end the cloud effect before this setting
          // In this example, end cloud before 9:00pm
        #define End_Cloud_Before NumMins(18,00)

          // Percentage chance of a lightning happen for every cloud
          // For testing purposes, you can use 100 and cause the lightning to have 100% chance of happening
        #define Lightning_Change_per_Cloud 25

          // Note: Make sure to choose correct values that will work within your PWMSLope settings.
          // For example, in our case, we could have a max of 5 clouds per day and they could last for 50 minutes.
          // Which could mean 250 minutes of clouds. We need to make sure the PWMSlope can accomodate 250 minutes
          // of effects or unforseen result could happen.
          // Also, make sure that you can fit double those minutes between Start_Cloud_After and End_Cloud_Before.
          // In our example, we have 510 minutes between Start_Cloud_After and End_Cloud_Before, so double the
          // 250 minutes (or 500 minutes) can fit in that 510 minutes window.
          // It's a tight fit, but it did.

          //#define printdebug // Uncomment this for debug print on Serial Monitor window
        #define forcecloudcalculation // Uncomment this to force the cloud calculation to happen in the boot process.

          // Add Random Lightning modes
        #define Calm 0    // No lightning
        #define Slow 1    // 5 seconds of slow lightning in the middle of a cloud for ELN style (slow response) drivers
        #define Fast 2    // 5 seconds of fast lightning in the middle of a cloud for LDD style (fast response) drivers
        #define Mega 3    // Lightning throughout the cloud, higher chance as it gets darker
        #define Mega2 4   // Like Mega, but with more lightning
          // Set which modes you want to use
          // Example:  { Calm, Fast, Mega, Mega2 } to randomize all four modes.
          // { Mega2 } for just Mega2.  { Mega, Mega, Fast} for Mega and Fast, with twice the chance of Mega.
          byte LightningModes[] = { Calm, Slow };

          // Change the values above to customize your cloud/storm effect
          // ------------------------------------------------------------
          // Do not change anything below here

          static byte cloudchance=255;
          static byte cloudduration=0;
          static int cloudstart=0;
          static byte numclouds=0;
          static byte lightningchance=0;
          static byte cloudindex=0;
          static byte lightningstatus=0;
          static int LastNumMins=0;
          static byte lightningMode=0;
          static boolean chooseLightning=true;

          static time_t DelayCounter=millis();    // Variable for lightning timing.
          static int DelayTime=random(1000);      // Variable for lightning timimg.

          // Every day at midnight, we check for chance of cloud happening today
          if (hour()==0 && minute()==0 && second()==0) cloudchance=255;

        #ifdef forcecloudcalculation
          if (cloudchance==255)
        #else
            if (hour()==0 && minute()==0 && second()==1 && cloudchance==255)
        #endif
            {
              randomSeed(millis());    // Seed the random number generator
              //Pick a random number between 0 and 99
              cloudchance=random(100);
              // if picked number is greater than Cloud_Chance_per_Day, we will not have clouds today
              if (cloudchance>Cloud_Chance_per_Day) cloudchance=0;
              // Check if today is day for clouds.
              if ((day()%Clouds_Every_X_Days)!=0) cloudchance=0;
              // If we have cloud today
              if (cloudchance)
              {
                // pick a random number for number of clouds between Min_Clouds_per_Day and Max_Clouds_per_Day
                numclouds=random(Min_Clouds_per_Day,Max_Clouds_per_Day);
                // pick the time that the first cloud will start
                // the range is calculated between Start_Cloud_After and the even distribuition of clouds on this day.
                cloudstart=random(Start_Cloud_After,Start_Cloud_After+((End_Cloud_Before-Start_Cloud_After)/(numclouds*2)));
                // pick a random number for the cloud duration of first cloud.
                cloudduration=random(Min_Cloud_Duration,Max_Cloud_Duration);
                //Pick a random number between 0 and 99
                lightningchance=random(100);
                // if picked number is greater than Lightning_Change_per_Cloud, we will not have lightning today
                if (lightningchance>Lightning_Change_per_Cloud) lightningchance=0;
              }
            }
          // Now that we have all the parameters for the cloud, let's create the effect


          if (cloudchance)
          {
            //is it time for cloud yet?
            if (NumMins(hour(),minute())>=cloudstart && NumMins(hour(),minute())<(cloudstart+cloudduration))
            {
              DaylightPWMValue=ReversePWMSlope(cloudstart,cloudstart+cloudduration,DaylightPWMValue/40.95,0,180)*40.95;
              if (chooseLightning)
              {
                lightningMode=LightningModes[random(100)%sizeof(LightningModes)];
                chooseLightning=false;
              }
              switch (lightningMode)
              {
              case Calm:
                break;
              case Mega:
                // Lightning chance from beginning of cloud through the end.  Chance increases with darkness of cloud.
                if (lightningchance && random(ReversePWMSlope(cloudstart,cloudstart+cloudduration,100,0,180))<1 && (millis()-DelayCounter)>DelayTime)
                {
                  // Send the trigger
                  Strike();
                  DelayCounter=millis();    // If we just had a round of flashes, then lets put in a longer delay
                  DelayTime=random(1000);   // of up to a second for dramatic effect before we do another round.
                }
                break;
              case Mega2:
                // Higher lightning chance from beginning of cloud through the end.  Chance increases with darkness of cloud.
                if (lightningchance && random(ReversePWMSlope(cloudstart,cloudstart+cloudduration,100,0,180))<2)
                {
                  Strike();
                }
                break;
              case Fast:
                // 5 seconds of lightning in the middle of the cloud
                if (lightningchance && (NumMins(hour(),minute())==(cloudstart+(cloudduration/2))) && second()<5 && (millis()-DelayCounter)>DelayTime)
                {
                  Strike();

                  DelayCounter=millis();    // If we just had a round of flashes, then lets put in a longer delay
                  DelayTime=random(1000);   // of up to a second for dramatic effect before we do another round.
                }
                break;
              case Slow:
                // Slow lightning for 5 seconds in the middle of the cloud.  Suitable for slower ELN style drivers
                if (lightningchance && (NumMins(hour(),minute())==(cloudstart+(cloudduration/2))) && second()<5)
                {
                  if (random(100)<20) lightningstatus=1;
                  else lightningstatus=0;
                  if (lightningstatus)
                  {
                    DaylightPWMValue=4095;
                  }
                  else
                  {
                    DaylightPWMValue=0;
                  }
                  delay(1);
                }
                break;
              default:
                break;
              }
            }
            else
            {
              chooseLightning=true; // Reset the flag to choose a new lightning type
            }

            if (NumMins(hour(),minute())>(cloudstart+cloudduration))
            {
              cloudindex++;
              if (cloudindex < numclouds)
              {
                cloudstart=random(Start_Cloud_After+(((End_Cloud_Before-Start_Cloud_After)/(numclouds*2))*cloudindex*2),(Start_Cloud_After+(((End_Cloud_Before-Start_Cloud_After)/(numclouds*2))*cloudindex*2))+((End_Cloud_Before-Start_Cloud_After)/(numclouds*2)));
                // pick a random number for the cloud duration of first cloud.
                cloudduration=random(Min_Cloud_Duration,Max_Cloud_Duration);
                //Pick a random number between 0 and 99
                lightningchance=random(100);
                // if picked number is greater than Lightning_Change_per_Cloud, we will not have lightning today
                if (lightningchance>Lightning_Change_per_Cloud) lightningchance=0;
              }
            }
          }

          // Write the times of the next cloud, next lightning, and cloud duration to the screen and into some customvars for the Portal.
          if (LastNumMins!=NumMins(hour(),minute()))
          {
            LastNumMins=NumMins(hour(),minute());
            /*ReefAngel.LCD.Clear(255,0,120,132,132);
             ReefAngel.LCD.DrawText(0,255,5,120,"C");
             ReefAngel.LCD.DrawText(0,255,11,120,"00:00");
             ReefAngel.LCD.DrawText(0,255,45,120,"L");
             ReefAngel.LCD.DrawText(0,255,51,120,"00:00"); */
            if (cloudchance && (NumMins(hour(),minute())<cloudstart))
            {
              int x=0;
              if ((cloudstart/60)>=10) x=11;
              else x=17;
              //ReefAngel.LCD.DrawText(0,255,x,120,(cloudstart/60));
              ReefAngel.CustomVar[3]=cloudstart/60; // Write the hour of the next cloud to custom variable for Portal reporting
              if ((cloudstart%60)>=10) x=29;
              else x=35;
              //ReefAngel.LCD.DrawText(0,255,x,120,(cloudstart%60));
              ReefAngel.CustomVar[4]=cloudstart%60; // Write the minute of the next cloud to custom variable for Portal reporting

            }
            //ReefAngel.LCD.DrawText(0,255,90,120,cloudduration);
            ReefAngel.CustomVar[7]=(cloudduration);    // Put the duration of the next cloud in a custom var for the portal
            if (lightningchance)
            {
              int x=0;
              if (((cloudstart+(cloudduration/2))/60)>=10) x=51;
              else x=57;
              //ReefAngel.LCD.DrawText(0,255,x,120,((cloudstart+(cloudduration/2))/60));
              ReefAngel.CustomVar[5]=(cloudstart+(cloudduration/2))/60;    // Write the hour of the next lightning to a custom variable for the Portal
              if (((cloudstart+(cloudduration/2))%60)>=10) x=69;
              else x=75;
              //ReefAngel.LCD.DrawText(0,255,x,120,((cloudstart+(cloudduration/2))%60)); // Write the minute of the next lightning to a custom variable for the Portal
                ReefAngel.CustomVar[6]=(cloudstart+(cloudduration/2))%60;
            }
          }   
        }

        void Strike()
        {
          int a=random(1,5);    // Pick a number of consecutive flashes from 1 to 4.
          for (int i=0; i<a; i++)
          {
            // Flash on
            int newdata=4095;
            Wire.beginTransmission(0x40);      // Address of the dimming expansion module
            Wire.write(0x8+(4*0));             // 0x8 is channel 0, 0x12 is channel 1, etc.  I'm using channel 1.
            Wire.write(newdata&0xff);          // Send the data 8 bits at a time.  This sends the LSB
            Wire.write(newdata>>8);            // This sends the MSB
            Wire.endTransmission();
           
            Wire.beginTransmission(0x40);      // Address of the dimming expansion module
            Wire.write(0x8+(4*2));             // 0x8 is channel 0, 0x12 is channel 1, etc.  I'm using channel 1.
            Wire.write(newdata&0xff);          // Send the data 8 bits at a time.  This sends the LSB
            Wire.write(newdata>>8);            // This sends the MSB
            Wire.endTransmission();
           
            int randy=random(20,80);    // Random number for a delay
            if (randy>71) randy=((randy-70)/2)*100;    // Small chance of a longer delay
            delay(randy);                // Wait from 20 to 69 ms, or 100-400 ms
           
            // Flash off.  Return to baseline.
            newdata=ReefAngel.PWM.GetChannelValueRaw(0);   // Use the channel number you're flashing here
            Wire.beginTransmission(0x40);    // Same as above
            Wire.write(0x8+(4*0));
            Wire.write(newdata&0xff);
            Wire.write(newdata>>8);
            Wire.endTransmission();
           
            newdata=ReefAngel.PWM.GetChannelValueRaw(0);   // Use the channel number you're flashing here
            Wire.beginTransmission(0x40);    // Same as above
            Wire.write(0x8+(4*2));
            Wire.write(newdata&0xff);
            Wire.write(newdata>>8);
            Wire.endTransmission();
           
            delay(random(30,50));                // Wait from 30 to 49 ms
            wdt_reset();    // Reset watchdog timer to avoid re-boots
          }
        }

        byte ReversePWMSlope(long cstart,long cend,byte PWMStart,byte PWMEnd, byte clength)
        {
          long n=elapsedSecsToday(now());
          cstart*=60;
          cend*=60;
          if (n<cstart) return PWMStart;
          if (n>=cstart && n<=(cstart+clength)) return map(n,cstart,cstart+clength,PWMStart,PWMEnd);
          if (n>(cstart+clength) && n<(cend-clength)) return PWMEnd;
          if (n>=(cend-clength) && n<=cend) return map(n,cend-clength,cend,PWMEnd,PWMStart);
          if (n>cend) return (int) PWMStart;
        }
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