WLED/wled00/overlay.cpp
2020-04-10 12:30:08 +02:00

377 lines
12 KiB
C++

#include "wled.h"
/*
* Used to draw clock overlays over the strip
*/
void initCronixie()
{
if (overlayCurrent == 3 && !cronixieInit)
{
setCronixie();
strip.getSegment(0).grouping = 10; //10 LEDs per digit
cronixieInit = true;
} else if (cronixieInit && overlayCurrent != 3)
{
strip.getSegment(0).grouping = 1;
cronixieInit = false;
}
}
void handleOverlays()
{
if (millis() - overlayRefreshedTime > overlayRefreshMs)
{
initCronixie();
updateLocalTime();
checkTimers();
checkCountdown();
if (overlayCurrent == 3) _overlayCronixie();//Diamex cronixie clock kit
overlayRefreshedTime = millis();
}
}
void _overlayAnalogClock()
{
int overlaySize = overlayMax - overlayMin +1;
if (countdownMode)
{
_overlayAnalogCountdown(); return;
}
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(analogClock12pixel + overlaySize*hourP);
if (hourPixel > overlayMax) hourPixel = overlayMin -1 + hourPixel - overlayMax;
int minutePixel = floor(analogClock12pixel + overlaySize*minuteP);
if (minutePixel > overlayMax) minutePixel = overlayMin -1 + minutePixel - overlayMax;
int secondPixel = floor(analogClock12pixel + overlaySize*secondP);
if (secondPixel > overlayMax) secondPixel = overlayMin -1 + secondPixel - overlayMax;
if (analogClockSecondsTrail)
{
if (secondPixel < analogClock12pixel)
{
strip.setRange(analogClock12pixel, overlayMax, 0xFF0000);
strip.setRange(overlayMin, secondPixel, 0xFF0000);
} else
{
strip.setRange(analogClock12pixel, secondPixel, 0xFF0000);
}
}
if (analogClock5MinuteMarks)
{
int pix;
for (int i = 0; i <= 12; i++)
{
pix = analogClock12pixel + round((overlaySize / 12.0) *i);
if (pix > overlayMax) pix -= overlaySize;
strip.setPixelColor(pix, 0x00FFAA);
}
}
if (!analogClockSecondsTrail) strip.setPixelColor(secondPixel, 0xFF0000);
strip.setPixelColor(minutePixel, 0x00FF00);
strip.setPixelColor(hourPixel, 0x0000FF);
overlayRefreshMs = 998;
}
void _overlayAnalogCountdown()
{
if (now() < countdownTime)
{
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;
byte pixelCnt = perc*overlaySize;
if (analogClock12pixel + pixelCnt > overlayMax)
{
strip.setRange(analogClock12pixel, overlayMax, ((uint32_t)colSec[3] << 24)| ((uint32_t)colSec[0] << 16) | ((uint32_t)colSec[1] << 8) | colSec[2]);
strip.setRange(overlayMin, overlayMin +pixelCnt -(1+ overlayMax -analogClock12pixel), ((uint32_t)colSec[3] << 24)| ((uint32_t)colSec[0] << 16) | ((uint32_t)colSec[1] << 8) | colSec[2]);
} else
{
strip.setRange(analogClock12pixel, analogClock12pixel + pixelCnt, ((uint32_t)colSec[3] << 24)| ((uint32_t)colSec[0] << 16) | ((uint32_t)colSec[1] << 8) | colSec[2]);
}
}
overlayRefreshMs = 998;
}
void handleOverlayDraw() {
if (!overlayCurrent) return;
switch (overlayCurrent)
{
case 1: _overlayAnalogClock(); break;
case 3: _drawOverlayCronixie(); break;
}
}
/*
* Support for the Cronixie clock
*/
#ifndef WLED_DISABLE_CRONIXIE
byte _digitOut[6] = {10,10,10,10,10,10};
byte getSameCodeLength(char code, int index, char const cronixieDisplay[])
{
byte counter = 0;
for (int i = index+1; i < 6; i++)
{
if (cronixieDisplay[i] == code)
{
counter++;
} else {
return counter;
}
}
return counter;
}
void setCronixie()
{
/*
* digit purpose index
* 0-9 | 0-9 (incl. random)
* 10 | blank
* 11 | blank, bg off
* 12 | test upw.
* 13 | test dnw.
* 14 | binary AM/PM
* 15 | BB upper +50 for no trailing 0
* 16 | BBB
* 17 | BBBB
* 18 | BBBBB
* 19 | BBBBBB
* 20 | H
* 21 | HH
* 22 | HHH
* 23 | HHHH
* 24 | M
* 25 | MM
* 26 | MMM
* 27 | MMMM
* 28 | MMMMM
* 29 | MMMMMM
* 30 | S
* 31 | SS
* 32 | SSS
* 33 | SSSS
* 34 | SSSSS
* 35 | SSSSSS
* 36 | Y
* 37 | YY
* 38 | YYYY
* 39 | I
* 40 | II
* 41 | W
* 42 | WW
* 43 | D
* 44 | DD
* 45 | DDD
* 46 | V
* 47 | VV
* 48 | VVV
* 49 | VVVV
* 50 | VVVVV
* 51 | VVVVVV
* 52 | v
* 53 | vv
* 54 | vvv
* 55 | vvvv
* 56 | vvvvv
* 57 | vvvvvv
*/
//H HourLower | HH - Hour 24. | AH - Hour 12. | HHH Hour of Month | HHHH Hour of Year
//M MinuteUpper | MM Minute of Hour | MMM Minute of 12h | MMMM Minute of Day | MMMMM Minute of Month | MMMMMM Minute of Year
//S SecondUpper | SS Second of Minute | SSS Second of 10 Minute | SSSS Second of Hour | SSSSS Second of Day | SSSSSS Second of Week
//B AM/PM | BB 0-6/6-12/12-18/18-24 | BBB 0-3... | BBBB 0-1.5... | BBBBB 0-1 | BBBBBB 0-0.5
//Y YearLower | YY - Year LU | YYYY - Std.
//I MonthLower | II - Month of Year
//W Week of Month | WW Week of Year
//D Day of Week | DD Day Of Month | DDD Day Of Year
DEBUG_PRINT("cset ");
DEBUG_PRINTLN(cronixieDisplay);
overlayRefreshMs = 1997; //Only refresh every 2secs if no seconds are displayed
for (int i = 0; i < 6; i++)
{
dP[i] = 10;
switch (cronixieDisplay[i])
{
case '_': dP[i] = 10; break;
case '-': dP[i] = 11; break;
case 'r': dP[i] = random(1,7); break; //random btw. 1-6
case 'R': dP[i] = random(0,10); break; //random btw. 0-9
//case 't': break; //Test upw.
//case 'T': break; //Test dnw.
case 'b': dP[i] = 14 + getSameCodeLength('b',i,cronixieDisplay); i = i+dP[i]-14; break;
case 'B': dP[i] = 14 + getSameCodeLength('B',i,cronixieDisplay); i = i+dP[i]-14; break;
case 'h': dP[i] = 70 + getSameCodeLength('h',i,cronixieDisplay); i = i+dP[i]-70; break;
case 'H': dP[i] = 20 + getSameCodeLength('H',i,cronixieDisplay); i = i+dP[i]-20; break;
case 'A': dP[i] = 108; i++; break;
case 'a': dP[i] = 58; i++; break;
case 'm': dP[i] = 74 + getSameCodeLength('m',i,cronixieDisplay); i = i+dP[i]-74; break;
case 'M': dP[i] = 24 + getSameCodeLength('M',i,cronixieDisplay); i = i+dP[i]-24; break;
case 's': dP[i] = 80 + getSameCodeLength('s',i,cronixieDisplay); i = i+dP[i]-80; overlayRefreshMs = 497; break; //refresh more often bc. of secs
case 'S': dP[i] = 30 + getSameCodeLength('S',i,cronixieDisplay); i = i+dP[i]-30; overlayRefreshMs = 497; break;
case 'Y': dP[i] = 36 + getSameCodeLength('Y',i,cronixieDisplay); i = i+dP[i]-36; break;
case 'y': dP[i] = 86 + getSameCodeLength('y',i,cronixieDisplay); i = i+dP[i]-86; break;
case 'I': dP[i] = 39 + getSameCodeLength('I',i,cronixieDisplay); i = i+dP[i]-39; break; //Month. Don't ask me why month and minute both start with M.
case 'i': dP[i] = 89 + getSameCodeLength('i',i,cronixieDisplay); i = i+dP[i]-89; break;
//case 'W': break;
//case 'w': break;
case 'D': dP[i] = 43 + getSameCodeLength('D',i,cronixieDisplay); i = i+dP[i]-43; break;
case 'd': dP[i] = 93 + getSameCodeLength('d',i,cronixieDisplay); i = i+dP[i]-93; break;
case '0': dP[i] = 0; break;
case '1': dP[i] = 1; break;
case '2': dP[i] = 2; break;
case '3': dP[i] = 3; break;
case '4': dP[i] = 4; break;
case '5': dP[i] = 5; break;
case '6': dP[i] = 6; break;
case '7': dP[i] = 7; break;
case '8': dP[i] = 8; break;
case '9': dP[i] = 9; break;
//case 'V': break; //user var0
//case 'v': break; //user var1
}
}
DEBUG_PRINT("result ");
for (int i = 0; i < 5; i++)
{
DEBUG_PRINT((int)dP[i]);
DEBUG_PRINT(" ");
}
DEBUG_PRINTLN((int)dP[5]);
_overlayCronixie(); //refresh
}
void _overlayCronixie()
{
byte h = hour(local);
byte h0 = h;
byte m = minute(local);
byte s = second(local);
byte d = day(local);
byte mi = month(local);
int y = year(local);
//this has to be changed in time for 22nd century
y -= 2000; if (y<0) y += 30; //makes countdown work
if (useAMPM && !countdownMode)
{
if (h>12) h-=12;
else if (h==0) h+=12;
}
for (int i = 0; i < 6; i++)
{
if (dP[i] < 12) _digitOut[i] = dP[i];
else {
if (dP[i] < 65)
{
switch(dP[i])
{
case 21: _digitOut[i] = h/10; _digitOut[i+1] = h- _digitOut[i]*10; i++; break; //HH
case 25: _digitOut[i] = m/10; _digitOut[i+1] = m- _digitOut[i]*10; i++; break; //MM
case 31: _digitOut[i] = s/10; _digitOut[i+1] = s- _digitOut[i]*10; i++; break; //SS
case 20: _digitOut[i] = h- (h/10)*10; break; //H
case 24: _digitOut[i] = m/10; break; //M
case 30: _digitOut[i] = s/10; break; //S
case 43: _digitOut[i] = weekday(local); _digitOut[i]--; if (_digitOut[i]<1) _digitOut[i]= 7; break; //D
case 44: _digitOut[i] = d/10; _digitOut[i+1] = d- _digitOut[i]*10; i++; break; //DD
case 40: _digitOut[i] = mi/10; _digitOut[i+1] = mi- _digitOut[i]*10; i++; break; //II
case 37: _digitOut[i] = y/10; _digitOut[i+1] = y- _digitOut[i]*10; i++; break; //YY
case 39: _digitOut[i] = 2; _digitOut[i+1] = 0; _digitOut[i+2] = y/10; _digitOut[i+3] = y- _digitOut[i+2]*10; i+=3; break; //YYYY
//case 16: _digitOut[i+2] = ((h0/3)&1)?1:0; i++; //BBB (BBBB NI)
//case 15: _digitOut[i+1] = (h0>17 || (h0>5 && h0<12))?1:0; i++; //BB
case 14: _digitOut[i] = (h0>11)?1:0; break; //B
}
} else
{
switch(dP[i])
{
case 71: _digitOut[i] = h/10; _digitOut[i+1] = h- _digitOut[i]*10; if(_digitOut[i] == 0) _digitOut[i]=10; i++; break; //hh
case 75: _digitOut[i] = m/10; _digitOut[i+1] = m- _digitOut[i]*10; if(_digitOut[i] == 0) _digitOut[i]=10; i++; break; //mm
case 81: _digitOut[i] = s/10; _digitOut[i+1] = s- _digitOut[i]*10; if(_digitOut[i] == 0) _digitOut[i]=10; i++; break; //ss
//case 66: _digitOut[i+2] = ((h0/3)&1)?1:10; i++; //bbb (bbbb NI)
//case 65: _digitOut[i+1] = (h0>17 || (h0>5 && h0<12))?1:10; i++; //bb
case 64: _digitOut[i] = (h0>11)?1:10; break; //b
case 93: _digitOut[i] = weekday(local); _digitOut[i]--; if (_digitOut[i]<1) _digitOut[i]= 7; break; //d
case 94: _digitOut[i] = d/10; _digitOut[i+1] = d- _digitOut[i]*10; if(_digitOut[i] == 0) _digitOut[i]=10; i++; break; //dd
case 90: _digitOut[i] = mi/10; _digitOut[i+1] = mi- _digitOut[i]*10; if(_digitOut[i] == 0) _digitOut[i]=10; i++; break; //ii
case 87: _digitOut[i] = y/10; _digitOut[i+1] = y- _digitOut[i]*10; i++; break; //yy
case 89: _digitOut[i] = 2; _digitOut[i+1] = 0; _digitOut[i+2] = y/10; _digitOut[i+3] = y- _digitOut[i+2]*10; i+=3; break; //yyyy
}
}
}
}
}
void _drawOverlayCronixie()
{
byte offsets[] = {5, 0, 6, 1, 7, 2, 8, 3, 9, 4};
for (uint16_t i = 0; i < 6; i++)
{
byte o = 10*i;
byte excl = 10;
if(_digitOut[i] < 10) excl = offsets[_digitOut[i]];
excl += o;
if (cronixieBacklight && _digitOut[i] <11)
{
uint32_t col = strip.gamma32(strip.getSegment(0).colors[1]);
for (uint16_t j=o; j< o+10; j++) {
if (j != excl) strip.setPixelColor(j, col);
}
} else
{
for (uint16_t j=o; j< o+10; j++) {
if (j != excl) strip.setPixelColor(j, 0);
}
}
}
}
#else // WLED_DISABLE_CRONIXIE
byte getSameCodeLength(char code, int index, char const cronixieDisplay[]) {}
void setCronixie() {}
void _overlayCronixie() {}
void _drawOverlayCronixie() {}
#endif