WLED/wled00/wled11_ol.ino

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#ifdef USEOVERLAYS
void _nixieDisplay(int num[], int dur[], int pausedur[], int cnt)
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{
strip.setRange(overlayMin, overlayMax, 0);
if (num[nixieClockI] >= 0 && !nixiePause)
{
strip.setIndividual(num[nixieClockI],((uint32_t)white << 24)| ((uint32_t)col_t[0] << 16) | ((uint32_t)col_t[1] << 8) | col_t[2]);
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strip.unlock(num[nixieClockI]);
}
if (!nixiePause)
{
overlayRefreshMs = dur[nixieClockI];
} else
{
overlayRefreshMs = pausedur[nixieClockI];
}
if (pausedur[nixieClockI] > 0 && !nixiePause)
{
nixiePause = true;
} else {
if (nixieClockI < cnt -1)
{
nixieClockI++;
} else
{
nixieClockI = -1;
}
nixiePause = false;
}
}
void _nixieNumber(int number, int dur)
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{
if (nixieClockI < 0)
{
DEBUG_PRINT(number);
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int digitCnt = -1;
int digits[4];
digits[3] = number/1000;
digits[2] = (number/100)%10;
digits[1] = (number/10)%10;
digits[0] = number%10;
if (number > 999) //four digits
{
digitCnt = 4;
} else if (number > 99) //three digits
{
digitCnt = 3;
} else if (number > 9) //two digits
{
digitCnt = 2;
} else { //single digit
digitCnt = 1;
}
DEBUG_PRINT(" ");
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for (int i = 0; i < digitCnt; i++)
{
DEBUG_PRINT(digits[i]);
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overlayArr[digitCnt-1-i] = digits[i];
overlayDur[digitCnt-1-i] = ((dur/4)*3)/digitCnt;
overlayPauseDur[digitCnt-1-i] = 0;
}
DEBUG_PRINTLN(" ");
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for (int i = 1; i < digitCnt; i++)
{
if (overlayArr[i] == overlayArr[i-1])
{
overlayPauseDur[i-1] = dur/12;
overlayDur[i-1] = overlayDur[i-1]-dur/12;
}
}
for (int i = digitCnt; i < 6; i++)
{
overlayArr[i] = -1;
overlayDur[i] = 0;
overlayPauseDur[i] = 0;
}
overlayPauseDur[5] = dur/4;
for (int i = 0; i < 6; i++)
{
if (overlayArr[i] != -1)
{
overlayArr[i] = overlayArr[i] + overlayMin;
if (overlayReverse)
overlayArr[i] = overlayMax - overlayArr[i];
}
}
for (int i = 0; i <6; i++)
{
DEBUG_PRINT(overlayArr[i]);
DEBUG_PRINT(" ");
DEBUG_PRINT(overlayDur[i]);
DEBUG_PRINT(" ");
DEBUG_PRINT(overlayPauseDur[i]);
DEBUG_PRINT(" ");
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}
DEBUG_PRINTLN(" ");
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nixieClockI = 0;
} else {
_nixieDisplay(overlayArr, overlayDur, overlayPauseDur, 6);
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}
}
void handleOverlays()
{
//properties: range, (color)
//0 no overlay
//1 solid color (NI)
//2 analog clock
//3 digital nixie-style clock one digit
//4 just static hour (NI)
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//5 analog countdown
//6 digital one digit countdown
if (millis() - overlayRefreshedTime > overlayRefreshMs)
{
overlayRefreshedTime = millis();
switch (overlayCurrent)
{
case 2: _overlayAnalogClock(); break;//2 analog clock
case 3: _overlayNixieClock(); break;//nixie 1-digit
case 5: _overlayAnalogCountdown(); break;//a.countdown
case 6: _overlayNixieCountdown(); break;//d.
}
}
}
void _overlayAnalogClock()
{
int overlaySize = overlayMax - overlayMin +1;
strip.unlockAll();
local = TZ.toLocal(now(), &tcr);
double hourP = ((double)(hour(local)%12))/12;
double minuteP = ((double)minute(local))/60;
hourP = hourP + minuteP/12;
double secondP = ((double)second(local))/60;
int hourPixel = floor(overlayMin + analogClock12pixel + overlaySize*hourP);
if (hourPixel > overlayMax) hourPixel = hourPixel - overlayMax;
int minutePixel = floor(overlayMin + analogClock12pixel + overlaySize*minuteP);
if (minutePixel > overlayMax) minutePixel = minutePixel - overlayMax;
int secondPixel = floor(overlayMin + analogClock12pixel + overlaySize*secondP);
if (secondPixel > overlayMax) secondPixel = secondPixel - overlayMax;
if (analogClock5MinuteMarks)
{
int pix;
for (int i = 0; i <= 12; i++)
{
pix = overlayMin + analogClock12pixel + (overlaySize/12)*i;
if (pix > overlayMax) pix = pix - overlayMax;
strip.setIndividual(pix, 0xAAAAAA);
}
}
if (analogClockSecondsTrail)
{
strip.setRange(analogClock12pixel, secondPixel, 0x0000FF);
} else
{
strip.setIndividual(secondPixel, 0x0000FF);
}
strip.setIndividual(minutePixel, 0x00FF00);
strip.setIndividual(hourPixel, 0xFF0000);
overlayRefreshMs = 998;
}
void _overlayNixieClock()
{
if (nixieClockI < 0)
{
local = TZ.toLocal(now(), &tcr);
overlayArr[0] = hour(local);
if (nixieClock12HourFormat && overlayArr[0] > 12)
{
overlayArr[0] = overlayArr[0]%12;
}
overlayArr[1] = -1;
if (overlayArr[0] > 9)
{
overlayArr[1] = overlayArr[0]%10;
overlayArr[0] = overlayArr[0]/10;
}
overlayArr[2] = minute(local);
overlayArr[3] = overlayArr[2]%10;
overlayArr[2] = overlayArr[2]/10;
overlayArr[4] = -1;
overlayArr[5] = -1;
if (nixieClockDisplaySeconds)
{
overlayArr[4] = second(local);
overlayArr[5] = overlayArr[4]%10;
overlayArr[4] = overlayArr[4]/10;
}
for (int i = 0; i < 6; i++)
{
if (overlayArr[i] != -1)
{
overlayArr[i] = overlayArr[i] + overlayMin;
if (overlayReverse)
overlayArr[i] = overlayMax - overlayArr[i];
}
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}
overlayDur[0] = 12 + 12*(255 - overlaySpeed);
if (overlayArr[1] == overlayArr[0])
{
overlayPauseDur[0] = 3 + 3*(255 - overlaySpeed);
} else
{
overlayPauseDur[0] = 0;
}
if (overlayArr[1] == -1)
{
overlayDur[1] = 0;
} else
{
overlayDur[1] = 12 + 12*(255 - overlaySpeed);
}
overlayPauseDur[1] = 9 + 9*(255 - overlaySpeed);
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overlayDur[2] = 12 + 12*(255 - overlaySpeed);
if (overlayArr[2] == overlayArr[3])
{
overlayPauseDur[2] = 3 + 3*(255 - overlaySpeed);
} else
{
overlayPauseDur[2] = 0;
}
overlayDur[3] = 12 + 12*(255 - overlaySpeed);
overlayPauseDur[3] = 9 + 9*(255 - overlaySpeed);
if (overlayArr[4] == -1)
{
overlayDur[4] = 0;
overlayPauseDur[4] = 0;
overlayDur[5] = 0;
} else
{
overlayDur[4] = 12 + 12*(255 - overlaySpeed);
if (overlayArr[5] == overlayArr[4])
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{
overlayPauseDur[4] = 3 + 3*(255 - overlaySpeed);
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} else
{
overlayPauseDur[4] = 0;
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}
overlayDur[5] = 12 + 12*(255 - overlaySpeed);
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}
overlayPauseDur[5] = 22 + 22*(255 - overlaySpeed);
nixieClockI = 0;
} else
{
_nixieDisplay(overlayArr, overlayDur, overlayPauseDur, 6);
}
}
void _overlayAnalogCountdown()
{
strip.unlockAll();
if (now() >= countdownTime)
{
//what to do if countdown finished
} else
{
long diff = countdownTime - now();
double pval = 60;
if (diff > 31557600L) //display in years if more than 365 days
{
pval = 315576000L; //10 years
} else if (diff > 2592000L) //display in months if more than a month
{
pval = 31557600L; //1 year
} else if (diff > 604800) //display in weeks if more than a week
{
pval = 2592000L; //1 month
} else if (diff > 86400) //display in days if more than 24 hours
{
pval = 604800; //1 week
} else if (diff > 3600) //display in hours if more than 60 minutes
{
pval = 86400; //1 day
} else if (diff > 60) //display in minutes if more than 60 seconds
{
pval = 3600; //1 hour
}
int overlaySize = overlayMax - overlayMin +1;
double perc = (pval-(double)diff)/pval;
if (perc > 1.0) perc = 1.0;
uint8_t pixelCnt = perc*overlaySize;
if (analogClock12pixel + pixelCnt > overlayMax)
{
strip.setRange(analogClock12pixel, overlayMax, ((uint32_t)white_sec << 24)| ((uint32_t)col_sec[0] << 16) | ((uint32_t)col_sec[1] << 8) | col_sec[2]);
strip.setRange(overlayMin, overlayMin +pixelCnt -(1+ overlayMax -analogClock12pixel), ((uint32_t)white_sec << 24)| ((uint32_t)col_sec[0] << 16) | ((uint32_t)col_sec[1] << 8) | col_sec[2]);
} else
{
strip.setRange(analogClock12pixel, analogClock12pixel + pixelCnt, ((uint32_t)white_sec << 24)| ((uint32_t)col_sec[0] << 16) | ((uint32_t)col_sec[1] << 8) | col_sec[2]);
}
}
overlayRefreshMs = 998;
}
void _overlayNixieCountdown()
{
if (now() >= countdownTime)
{
if (effectCurrent != 8){
effectCurrent = 8;
strip.setMode(8);
strip.setSpeed(255);
}
_nixieNumber(2018, 2018);
} else
{
long diff = countdownTime - now();
if (diff > 86313600L) //display in years if more than 999 days
{
diff = diff/31557600L;
} else if (diff > 3596400) //display in days if more than 999 hours
{
diff = diff/86400;
} else if (diff > 59940) //display in hours if more than 999 minutes
{
diff = diff/1440;
} else if (diff > 999) //display in minutes if more than 999 seconds
{
diff = diff/60;
}
_nixieNumber(diff, 800);
}
}
#endif