WLED/wled00/FX.h

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/*
WS2812FX.h - Library for WS2812 LED effects.
Harm Aldick - 2016
www.aldick.org
LICENSE
The MIT License (MIT)
Copyright (c) 2016 Harm Aldick
Permission is hereby granted, free of charge, to any person obtaining a copy
of this software and associated documentation files (the "Software"), to deal
in the Software without restriction, including without limitation the rights
to use, copy, modify, merge, publish, distribute, sublicense, and/or sell
copies of the Software, and to permit persons to whom the Software is
furnished to do so, subject to the following conditions:
The above copyright notice and this permission notice shall be included in
all copies or substantial portions of the Software.
THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE
AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER
LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM,
OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN
THE SOFTWARE.
Modified for WLED
*/
#ifndef WS2812FX_h
#define WS2812FX_h
#include <vector>
#include "const.h"
#define FASTLED_INTERNAL //remove annoying pragma messages
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#define USE_GET_MILLISECOND_TIMER
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#include "FastLED.h"
#define DEFAULT_BRIGHTNESS (uint8_t)127
#define DEFAULT_MODE (uint8_t)0
#define DEFAULT_SPEED (uint8_t)128
#define DEFAULT_INTENSITY (uint8_t)128
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#define DEFAULT_COLOR (uint32_t)0xFFAA00
#define DEFAULT_C1 (uint8_t)128
#define DEFAULT_C2 (uint8_t)128
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#define DEFAULT_C3 (uint8_t)16
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#ifndef MIN
#define MIN(a,b) ((a)<(b)?(a):(b))
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#endif
#ifndef MAX
#define MAX(a,b) ((a)>(b)?(a):(b))
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#endif
//color mangling macros
#ifndef RGBW32
#define RGBW32(r,g,b,w) (uint32_t((byte(w) << 24) | (byte(r) << 16) | (byte(g) << 8) | (byte(b))))
#endif
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/* Not used in all effects yet */
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#define WLED_FPS 42
#define FRAMETIME_FIXED (1000/WLED_FPS)
//#define FRAMETIME _frametime
#define FRAMETIME strip.getFrameTime()
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/* each segment uses 52 bytes of SRAM memory, so if you're application fails because of
insufficient memory, decreasing MAX_NUM_SEGMENTS may help */
#ifdef ESP8266
#define MAX_NUM_SEGMENTS 16
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/* How much data bytes all segments combined may allocate */
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#define MAX_SEGMENT_DATA 5120
#else
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#ifndef MAX_NUM_SEGMENTS
#define MAX_NUM_SEGMENTS 32
#endif
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#define MAX_SEGMENT_DATA 32767
#endif
/* How much data bytes each segment should max allocate to leave enough space for other segments,
assuming each segment uses the same amount of data. 256 for ESP8266, 640 for ESP32. */
#define FAIR_DATA_PER_SEG (MAX_SEGMENT_DATA / strip.getMaxSegments())
#define MIN_SHOW_DELAY (_frametime < 16 ? 8 : 15)
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#define NUM_COLORS 3 /* number of colors per segment */
#define SEGMENT strip._segments[strip.getCurrSegmentId()]
#define SEGENV strip._segments[strip.getCurrSegmentId()]
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//#define SEGCOLOR(x) strip._segments[strip.getCurrSegmentId()].currentColor(x, strip._segments[strip.getCurrSegmentId()].colors[x])
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//#define SEGLEN strip._segments[strip.getCurrSegmentId()].virtualLength()
#define SEGCOLOR(x) strip.segColor(x) /* saves us a few kbytes of code */
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#define SEGPALETTE strip._currentPalette
#define SEGLEN strip._virtualSegmentLength /* saves us a few kbytes of code */
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#define SPEED_FORMULA_L (5U + (50U*(255U - SEGMENT.speed))/SEGLEN)
// some common colors
#define RED (uint32_t)0xFF0000
#define GREEN (uint32_t)0x00FF00
#define BLUE (uint32_t)0x0000FF
#define WHITE (uint32_t)0xFFFFFF
#define BLACK (uint32_t)0x000000
#define YELLOW (uint32_t)0xFFFF00
#define CYAN (uint32_t)0x00FFFF
#define MAGENTA (uint32_t)0xFF00FF
#define PURPLE (uint32_t)0x400080
#define ORANGE (uint32_t)0xFF3000
#define PINK (uint32_t)0xFF1493
#define ULTRAWHITE (uint32_t)0xFFFFFFFF
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#define DARKSLATEGRAY (uint32_t)0x2F4F4F
#define DARKSLATEGREY (uint32_t)0x2F4F4F
// options
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// bit 7: segment is in transition mode
// bits 4-6: TBD
// bit 3: mirror effect within segment
// bit 2: segment is on
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// bit 1: reverse segment
// bit 0: segment is selected
#define NO_OPTIONS (uint16_t)0x0000
#define TRANSPOSED (uint16_t)0x0400 // rotated 90deg & reversed
#define REVERSE_Y_2D (uint16_t)0x0200
#define MIRROR_Y_2D (uint16_t)0x0100
#define TRANSITIONAL (uint16_t)0x0080
#define MIRROR (uint16_t)0x0008
#define SEGMENT_ON (uint16_t)0x0004
#define REVERSE (uint16_t)0x0002
#define SELECTED (uint16_t)0x0001
#define FX_MODE_STATIC 0
#define FX_MODE_BLINK 1
#define FX_MODE_BREATH 2
#define FX_MODE_COLOR_WIPE 3
#define FX_MODE_COLOR_WIPE_RANDOM 4
#define FX_MODE_RANDOM_COLOR 5
#define FX_MODE_COLOR_SWEEP 6
#define FX_MODE_DYNAMIC 7
#define FX_MODE_RAINBOW 8
#define FX_MODE_RAINBOW_CYCLE 9
#define FX_MODE_SCAN 10
#define FX_MODE_DUAL_SCAN 11
#define FX_MODE_FADE 12
#define FX_MODE_THEATER_CHASE 13
#define FX_MODE_THEATER_CHASE_RAINBOW 14
#define FX_MODE_RUNNING_LIGHTS 15
#define FX_MODE_SAW 16
#define FX_MODE_TWINKLE 17
#define FX_MODE_DISSOLVE 18
#define FX_MODE_DISSOLVE_RANDOM 19
#define FX_MODE_SPARKLE 20
#define FX_MODE_FLASH_SPARKLE 21
#define FX_MODE_HYPER_SPARKLE 22
#define FX_MODE_STROBE 23
#define FX_MODE_STROBE_RAINBOW 24
#define FX_MODE_MULTI_STROBE 25
#define FX_MODE_BLINK_RAINBOW 26
#define FX_MODE_ANDROID 27
#define FX_MODE_CHASE_COLOR 28
#define FX_MODE_CHASE_RANDOM 29
#define FX_MODE_CHASE_RAINBOW 30
#define FX_MODE_CHASE_FLASH 31
#define FX_MODE_CHASE_FLASH_RANDOM 32
#define FX_MODE_CHASE_RAINBOW_WHITE 33
#define FX_MODE_COLORFUL 34
#define FX_MODE_TRAFFIC_LIGHT 35
#define FX_MODE_COLOR_SWEEP_RANDOM 36
#define FX_MODE_RUNNING_COLOR 37
#define FX_MODE_AURORA 38
#define FX_MODE_RUNNING_RANDOM 39
#define FX_MODE_LARSON_SCANNER 40
#define FX_MODE_COMET 41
#define FX_MODE_FIREWORKS 42
#define FX_MODE_RAIN 43
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#define FX_MODE_TETRIX 44 //was Merry Christmas prior to 0.12.0 (use "Chase 2" with Red/Green)
#define FX_MODE_FIRE_FLICKER 45
#define FX_MODE_GRADIENT 46
#define FX_MODE_LOADING 47
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//#define FX_MODE_POLICE 48 // candidate for removal (after below three)
#define FX_MODE_WAVESINS 48 // was Police prior to 0.14 (use Two Dots with Red/Blue)
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#define FX_MODE_FAIRY 49 //was Police All prior to 0.13.0-b6 (use "Two Dots" with Red/Blue and full intensity)
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#define FX_MODE_TWO_DOTS 50
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#define FX_MODE_FAIRYTWINKLE 51 //was Two Areas prior to 0.13.0-b6 (use "Two Dots" with full intensity)
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#define FX_MODE_RUNNING_DUAL 52
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//#define FX_MODE_HALLOWEEN 53 // candidate for removal
#define FX_MODE_PERLINMOVE 53 // was Halloween prior to 0.14 (use Cahse 2 with Purple/Orange)
#define FX_MODE_TRICOLOR_CHASE 54
#define FX_MODE_TRICOLOR_WIPE 55
#define FX_MODE_TRICOLOR_FADE 56
#define FX_MODE_LIGHTNING 57
#define FX_MODE_ICU 58
#define FX_MODE_MULTI_COMET 59
#define FX_MODE_DUAL_LARSON_SCANNER 60
#define FX_MODE_RANDOM_CHASE 61
#define FX_MODE_OSCILLATE 62
#define FX_MODE_PRIDE_2015 63
#define FX_MODE_JUGGLE 64
#define FX_MODE_PALETTE 65
#define FX_MODE_FIRE_2012 66
#define FX_MODE_COLORWAVES 67
#define FX_MODE_BPM 68
#define FX_MODE_FILLNOISE8 69
#define FX_MODE_NOISE16_1 70
#define FX_MODE_NOISE16_2 71
#define FX_MODE_NOISE16_3 72
#define FX_MODE_NOISE16_4 73
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#define FX_MODE_COLORTWINKLE 74
#define FX_MODE_LAKE 75
#define FX_MODE_METEOR 76
#define FX_MODE_METEOR_SMOOTH 77
#define FX_MODE_RAILWAY 78
#define FX_MODE_RIPPLE 79
#define FX_MODE_TWINKLEFOX 80
#define FX_MODE_TWINKLECAT 81
#define FX_MODE_HALLOWEEN_EYES 82
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#define FX_MODE_STATIC_PATTERN 83
#define FX_MODE_TRI_STATIC_PATTERN 84
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#define FX_MODE_SPOTS 85
#define FX_MODE_SPOTS_FADE 86
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#define FX_MODE_GLITTER 87
#define FX_MODE_CANDLE 88
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#define FX_MODE_STARBURST 89
#define FX_MODE_EXPLODING_FIREWORKS 90
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#define FX_MODE_BOUNCINGBALLS 91
#define FX_MODE_SINELON 92
#define FX_MODE_SINELON_DUAL 93
#define FX_MODE_SINELON_RAINBOW 94
#define FX_MODE_POPCORN 95
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#define FX_MODE_DRIP 96
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#define FX_MODE_PLASMA 97
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#define FX_MODE_PERCENT 98
#define FX_MODE_RIPPLE_RAINBOW 99
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#define FX_MODE_HEARTBEAT 100
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#define FX_MODE_PACIFICA 101
#define FX_MODE_CANDLE_MULTI 102
#define FX_MODE_SOLID_GLITTER 103
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#define FX_MODE_SUNRISE 104
#define FX_MODE_PHASED 105
#define FX_MODE_TWINKLEUP 106
#define FX_MODE_NOISEPAL 107
#define FX_MODE_SINEWAVE 108
#define FX_MODE_PHASEDNOISE 109
#define FX_MODE_FLOW 110
#define FX_MODE_CHUNCHUN 111
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#define FX_MODE_DANCING_SHADOWS 112
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#define FX_MODE_WASHING_MACHINE 113
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//#define FX_MODE_CANDY_CANE 114 // candidate for removal
#define FX_MODE_FLOWSTRIPE 114 // was Cany Cane prior to 0.14 (use Cahse 2 with Red/White)
#define FX_MODE_BLENDS 115
#define FX_MODE_TV_SIMULATOR 116
#define FX_MODE_DYNAMIC_SMOOTH 117
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#ifndef WLED_DISABLE_2D
// new 2D effects
#define FX_MODE_2DSPACESHIPS 118
#define FX_MODE_2DCRAZYBEES 119
#define FX_MODE_2DGHOSTRIDER 120
#define FX_MODE_2DBLOBS 121
#define FX_MODE_2DSCROLLTEXT 122
#define FX_MODE_2DDRIFTROSE 123
// WLED-SR effects (non SR compatible IDs)
#define FX_MODE_2DBLACKHOLE 124 // non audio
#define FX_MODE_2DDNASPIRAL 125 // non audio
#define FX_MODE_2DHIPHOTIC 126 // non audio
#define FX_MODE_2DPLASMABALL 127 // non audio
#define FX_MODE_2DSINDOTS 128 // non audio
#define FX_MODE_2DFRIZZLES 129 // non audio
#define FX_MODE_2DLISSAJOUS 130 // non audio
#define FX_MODE_2DPOLARLIGHTS 131 // non audio
#define FX_MODE_2DTARTAN 132 // non audio
#define FX_MODE_2DGAMEOFLIFE 133 // non audio
#define FX_MODE_2DJULIA 134 // non audio
#define FX_MODE_2DCOLOREDBURSTS 135 // non audio
#define FX_MODE_2DSUNRADIATION 136 // non audio
#define FX_MODE_2DNOISE 137 // non audio
#define FX_MODE_2DFIRENOISE 138 // non audio
#define FX_MODE_2DSQUAREDSWIRL 139 // non audio
#define FX_MODE_2DDNA 140 // non audio
#define FX_MODE_2DMATRIX 141 // non audio
#define FX_MODE_2DMETABALLS 142 // non audio
#define FX_MODE_2DPULSER 143 // non audio
#define FX_MODE_2DDRIFT 144 // non audio
#endif
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#ifndef WLED_DISABLE_AUDIO
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#ifndef WLED_DISABLE_2D
#define FX_MODE_2DWAVERLY 145 // audio enhanced
#define FX_MODE_2DSWIRL 146 // audio enhanced
#define FX_MODE_2DAKEMI 147 // audio enhanced
// 148 & 149 reserved
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#endif
#define FX_MODE_PIXELWAVE 150 // audio enhanced
#define FX_MODE_JUGGLES 151 // audio enhanced
#define FX_MODE_MATRIPIX 152 // audio enhanced
#define FX_MODE_GRAVIMETER 153 // audio enhanced
#define FX_MODE_PLASMOID 154 // audio enhanced
#define FX_MODE_PUDDLES 155 // audio enhanced
#define FX_MODE_MIDNOISE 156 // audio enhanced
#define FX_MODE_NOISEMETER 157 // audio enhanced
#define FX_MODE_NOISEFIRE 158 // audio enhanced
#define FX_MODE_PUDDLEPEAK 159 // audio enhanced
#define FX_MODE_RIPPLEPEAK 160 // audio enhanced
#define FX_MODE_GRAVCENTER 161 // audio enhanced
#define FX_MODE_GRAVCENTRIC 162 // audio enhanced
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#endif
#ifndef USERMOD_AUDIOREACTIVE
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#ifndef WLED_DISABLE_AUDIO
#define MODE_COUNT 163
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#else
#ifndef WLED_DISABLE_2D
#define MODE_COUNT 145
#else
#define MODE_COUNT 118
#endif
#endif
#else
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#ifdef WLED_DISABLE_AUDIO
#error Incompatible options: WLED_DISABLE_AUDIO and USERMOD_AUDIOREACTIVE
#endif
#ifdef WLED_DISABLE_2D
#error AUDIOREACTIVE usermod requires 2D support.
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#endif
#define FX_MODE_2DGEQ 148
#define FX_MODE_2DFUNKYPLANK 149
#define FX_MODE_PIXELS 163
#define FX_MODE_FREQWAVE 164
#define FX_MODE_FREQMATRIX 165
#define FX_MODE_WATERFALL 166
#define FX_MODE_FREQPIXELS 167
#define FX_MODE_BINMAP 168
#define FX_MODE_NOISEMOVE 169
#define FX_MODE_FREQMAP 170
#define FX_MODE_GRAVFREQ 171
#define FX_MODE_DJLIGHT 172
#define FX_MODE_BLURZ 173
#define FX_MODE_ROCKTAVES 174
//#define FX_MODE_CUSTOMEFFECT 175 //WLEDSR Custom Effects
#define MODE_COUNT 175
#endif
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typedef enum mapping1D2D {
M12_Pixels = 0,
M12_VerticalBar = 1,
M12_Circle = 2,
M12_Block = 3
} mapping1D2D_t;
// segment, 68 (92 in memory) bytes
typedef struct Segment {
public:
uint16_t start; // start index / start X coordinate 2D (left)
uint16_t stop; // stop index / stop X coordinate 2D (right); segment is invalid if stop == 0
uint16_t offset;
uint8_t speed;
uint8_t intensity;
uint8_t palette;
uint8_t mode;
union {
uint16_t options; //bit pattern: msb first: [transposed mirrorY reverseY] transitional (tbd) paused needspixelstate mirrored on reverse selected
struct {
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bool selected : 1; // 0 : selected
bool reverse : 1; // 1 : reversed
bool on : 1; // 2 : is On
bool mirror : 1; // 3 : mirrored
bool pxs : 1; // 4 : indicates that the effect does not use FRAMETIME or needs getPixelColor (?)
bool freeze : 1; // 5 : paused/frozen
bool reset : 1; // 6 : indicates that Segment runtime requires reset
bool transitional: 1; // 7 : transitional (there is transition occuring)
bool reverse_y : 1; // 8 : reversed Y (2D)
bool mirror_y : 1; // 9 : mirrored Y (2D)
bool transpose : 1; // 10 : transposed (2D, swapped X & Y)
uint8_t map1D2D : 2; // 11-12 : mapping for 1D effect on 2D (0-strip, 1-expand vertically, 2-circular, 3-rectangular)
uint8_t soundSim : 3; // 13-15 : 0-7 sound simulation types
};
};
uint8_t grouping, spacing;
uint8_t opacity;
uint32_t colors[NUM_COLORS];
uint8_t cct; //0==1900K, 255==10091K
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uint8_t custom1, custom2; // custom FX parameters/sliders
struct {
uint8_t custom3 : 5; // reduced range slider (0-31)
bool check1 : 1; // checkmark 1
bool check2 : 1; // checkmark 2
bool check3 : 1; // checkmark 3
};
uint16_t startY; // start Y coodrinate 2D (top)
uint16_t stopY; // stop Y coordinate 2D (bottom)
char *name;
// runtime data
unsigned long next_time; // millis() of next update
uint32_t step; // custom "step" var
uint32_t call; // call counter
uint16_t aux0; // custom var
uint16_t aux1; // custom var
byte* data;
CRGB* leds;
static CRGB *_globalLeds;
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private:
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union {
uint8_t _capabilities;
struct {
bool _isRGB : 1;
bool _hasW : 1;
bool _isCCT : 1;
bool _manualW : 1;
uint8_t _reserved : 4;
};
};
uint16_t _dataLen;
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static uint16_t _usedSegmentData;
// transition data, valid only if transitional==true, holds values during transition
struct Transition {
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uint32_t _colorT[NUM_COLORS];
uint8_t _briT; // temporary brightness
uint8_t _cctT; // temporary CCT
CRGBPalette16 _palT; // temporary palette
uint8_t _modeP; // previous mode/effect
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uint32_t _start;
uint16_t _dur;
Transition(uint16_t dur=750) : _briT(255), _cctT(127), _palT(CRGBPalette16(CRGB::Black)), _modeP(FX_MODE_STATIC), _start(millis()), _dur(dur) {}
Transition(uint16_t d, uint8_t b, uint8_t c, const uint32_t *o) : _briT(b), _cctT(c), _palT(CRGBPalette16(CRGB::Black)), _modeP(FX_MODE_STATIC), _start(millis()), _dur(d) {
for (size_t i=0; i<NUM_COLORS; i++) _colorT[i] = o[i];
}
} *_t; // this struct will bootloop ESP
public:
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Segment(uint16_t sStart=0, uint16_t sStop=30) :
start(sStart),
stop(sStop),
offset(0),
speed(DEFAULT_SPEED),
intensity(DEFAULT_INTENSITY),
palette(0),
mode(DEFAULT_MODE),
options(SELECTED | SEGMENT_ON),
grouping(1),
spacing(0),
opacity(255),
colors{DEFAULT_COLOR,BLACK,BLACK},
cct(127),
custom1(DEFAULT_C1),
custom2(DEFAULT_C2),
custom3(DEFAULT_C3),
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check1(false),
check2(false),
check3(false),
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startY(0),
stopY(1),
name(nullptr),
next_time(0),
step(0),
call(0),
aux0(0),
aux1(0),
data(nullptr),
leds(nullptr),
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_capabilities(0),
_dataLen(0),
_t(nullptr)
{
refreshLightCapabilities();
}
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Segment(uint16_t sStartX, uint16_t sStopX, uint16_t sStartY, uint16_t sStopY) : Segment(sStartX, sStopX) {
startY = sStartY;
stopY = sStopY;
}
Segment(const Segment &orig); // copy constructor
Segment(Segment &&orig) noexcept; // move constructor
~Segment() {
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#ifdef WLED_DEBUG
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Serial.print(F("Destroying segment:"));
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if (name) Serial.printf(" %s (%p)", name, name);
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if (data) Serial.printf(" %d (%p)", (int)_dataLen, data);
if (leds) Serial.printf(" [%u]", length()*sizeof(CRGB));
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Serial.println();
#endif
if (!Segment::_globalLeds && leds) free(leds);
if (name) delete[] name;
if (_t) delete _t;
deallocateData();
}
Segment& operator= (const Segment &orig); // copy assignment
Segment& operator= (Segment &&orig) noexcept; // move assignment
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#ifdef WLED_DEBUG
size_t getSize() { return sizeof(Segment) + (data?_dataLen:0) + (name?strlen(name):0) + (_t?sizeof(Transition):0) + (!Segment::_globalLeds && leds?sizeof(CRGB)*length():0); }
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#endif
inline bool getOption(uint8_t n) { return ((options >> n) & 0x01); }
inline bool isSelected(void) { return selected; }
inline bool isActive(void) { return stop > start; }
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inline bool is2D(void) { return !(startY == 0 && stopY == 1); }
inline uint16_t width(void) { return stop - start; } // segment width in physical pixels (length if 1D)
inline uint16_t height(void) { return stopY - startY; } // segment height (if 2D) in physical pixels
inline uint16_t length(void) { return width() * height(); } // segment length (count) in physical pixels
inline uint16_t groupLength(void) { return grouping + spacing; }
inline uint8_t getLightCapabilities(void) { return _capabilities; }
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static uint16_t getUsedSegmentData(void) { return _usedSegmentData; }
static void addUsedSegmentData(int len) { _usedSegmentData += len; }
bool setColor(uint8_t slot, uint32_t c); //returns true if changed
void setCCT(uint16_t k);
void setOpacity(uint8_t o);
void setOption(uint8_t n, bool val);
uint8_t differs(Segment& b);
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void refreshLightCapabilities(void);
// runtime data functions
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inline uint16_t dataSize(void) { return _dataLen; }
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bool allocateData(size_t len);
void deallocateData(void);
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void resetIfRequired(void);
/**
* Flags that before the next effect is calculated,
* the internal segment state should be reset.
* Call resetIfRequired before calling the next effect function.
* Safe to call from interrupts and network requests.
*/
inline void markForReset(void) { reset = true; } // setOption(SEG_OPTION_RESET, true)
//inline void setUpLeds() { if (!leds) leds = (CRGB*)malloc(sizeof(CRGB)*length()); }
void setUpLeds(void);
// transition functions
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void startTransition(uint16_t dur); // transition has to start before actual segment values change
void handleTransition(void);
uint16_t progress(void); //transition progression between 0-65535
uint8_t currentBri(uint8_t briNew, bool useCct = false);
uint8_t currentMode(uint8_t modeNew);
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uint32_t currentColor(uint8_t slot, uint32_t colorNew);
CRGBPalette16 &loadPalette(CRGBPalette16 &tgt, uint8_t pal);
CRGBPalette16 &currentPalette(CRGBPalette16 &tgt, uint8_t paletteID);
// 1D strip
uint16_t virtualLength(void);
void setPixelColor(int n, uint32_t c); // set relative pixel within segment with color
void setPixelColor(int n, byte r, byte g, byte b, byte w = 0) { setPixelColor(n, RGBW32(r,g,b,w)); } // automatically inline
void setPixelColor(int n, CRGB c) { setPixelColor(n, RGBW32(c.r,c.g,c.b,0)); } // automatically inline
void setPixelColor(float i, uint32_t c, bool aa = true);
void setPixelColor(float i, uint8_t r, uint8_t g, uint8_t b, uint8_t w = 0, bool aa = true) { setPixelColor(i, RGBW32(r,g,b,w), aa); }
void setPixelColor(float i, CRGB c, bool aa = true) { setPixelColor(i, RGBW32(c.r,c.g,c.b,0), aa); }
uint32_t getPixelColor(uint16_t i);
// 1D support functions (some implement 2D as well)
void blur(uint8_t);
void fill(uint32_t c);
void fade_out(uint8_t r);
void fadeToBlackBy(uint8_t fadeBy);
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void blendPixelColor(int n, uint32_t color, uint8_t blend);
void blendPixelColor(int n, CRGB c, uint8_t blend) { blendPixelColor(n, RGBW32(c.r,c.g,c.b,0), blend); }
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void addPixelColor(int n, uint32_t color);
void addPixelColor(int n, byte r, byte g, byte b, byte w = 0) { addPixelColor(n, RGBW32(r,g,b,w)); } // automatically inline
void addPixelColor(int n, CRGB c) { addPixelColor(n, RGBW32(c.r,c.g,c.b,0)); } // automatically inline
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void fadePixelColor(uint16_t n, uint8_t fade);
uint8_t get_random_wheel_index(uint8_t pos);
uint32_t color_from_palette(uint16_t, bool mapping, bool wrap, uint8_t mcol, uint8_t pbri = 255);
uint32_t color_wheel(uint8_t pos);
// 2D matrix
uint16_t virtualWidth(void);
uint16_t virtualHeight(void);
#ifndef WLED_DISABLE_2D
uint16_t XY(uint16_t x, uint16_t y); // support function to get relative index within segment (for leds[])
void setPixelColorXY(int x, int y, uint32_t c); // set relative pixel within segment with color
void setPixelColorXY(int x, int y, byte r, byte g, byte b, byte w = 0) { setPixelColorXY(x, y, RGBW32(r,g,b,w)); } // automatically inline
void setPixelColorXY(int x, int y, CRGB c) { setPixelColorXY(x, y, RGBW32(c.r,c.g,c.b,0)); } // automatically inline
void setPixelColorXY(float x, float y, uint32_t c, bool aa = true);
void setPixelColorXY(float x, float y, byte r, byte g, byte b, byte w = 0, bool aa = true) { setPixelColorXY(x, y, RGBW32(r,g,b,w), aa); }
void setPixelColorXY(float x, float y, CRGB c, bool aa = true) { setPixelColorXY(x, y, RGBW32(c.r,c.g,c.b,0), aa); }
uint32_t getPixelColorXY(uint16_t x, uint16_t y);
// 2D support functions
void blendPixelColorXY(uint16_t x, uint16_t y, uint32_t color, uint8_t blend);
void blendPixelColorXY(uint16_t x, uint16_t y, CRGB c, uint8_t blend) { blendPixelColorXY(x, y, RGBW32(c.r,c.g,c.b,0), blend); }
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void addPixelColorXY(int x, int y, uint32_t color);
void addPixelColorXY(int x, int y, byte r, byte g, byte b, byte w = 0) { addPixelColorXY(x, y, RGBW32(r,g,b,w)); } // automatically inline
void addPixelColorXY(int x, int y, CRGB c) { addPixelColorXY(x, y, RGBW32(c.r,c.g,c.b,0)); }
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void fadePixelColorXY(uint16_t x, uint16_t y, uint8_t fade);
void box_blur(uint16_t i, bool vertical, fract8 blur_amount); // 1D box blur (with weight)
void blurRow(uint16_t row, fract8 blur_amount);
void blurCol(uint16_t col, fract8 blur_amount);
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void moveX(int8_t delta);
void moveY(int8_t delta);
void move(uint8_t dir, uint8_t delta);
void fill_circle(uint16_t cx, uint16_t cy, uint8_t radius, CRGB c);
void drawLine(uint16_t x0, uint16_t y0, uint16_t x1, uint16_t y1, uint32_t c);
void drawLine(uint16_t x0, uint16_t y0, uint16_t x1, uint16_t y1, CRGB c) { drawLine(x0, y0, x1, y1, RGBW32(c.r,c.g,c.b,0)); } // automatic inline
void drawCharacter(unsigned char chr, int16_t x, int16_t y, uint8_t w, uint8_t h, uint32_t color);
void drawCharacter(unsigned char chr, int16_t x, int16_t y, uint8_t w, uint8_t h, CRGB c) { drawCharacter(chr, x, y, w, h, RGBW32(c.r,c.g,c.b,0)); } // automatic inline
void wu_pixel(uint32_t x, uint32_t y, CRGB c);
void blur1d(fract8 blur_amount); // blur all rows in 1 dimension
void blur2d(fract8 blur_amount) { blur(blur_amount); }
void fill_solid(CRGB c) { fill(RGBW32(c.r,c.g,c.b,0)); }
void nscale8(uint8_t scale);
#else
uint16_t XY(uint16_t x, uint16_t y) { return x; }
void setPixelColorXY(int x, int y, uint32_t c) { setPixelColor(x, c); }
void setPixelColorXY(int x, int y, byte r, byte g, byte b, byte w = 0) { setPixelColor(x, RGBW32(r,g,b,w)); }
void setPixelColorXY(int x, int y, CRGB c) { setPixelColor(x, RGBW32(c.r,c.g,c.b,0)); }
void setPixelColorXY(float x, float y, uint32_t c, bool aa = true) { setPixelColor(x, c, aa); }
void setPixelColorXY(float x, float y, byte r, byte g, byte b, byte w = 0, bool aa = true) { setPixelColor(x, RGBW32(r,g,b,w), aa); }
void setPixelColorXY(float x, float y, CRGB c, bool aa = true) { setPixelColor(x, RGBW32(c.r,c.g,c.b,0), aa); }
uint32_t getPixelColorXY(uint16_t x, uint16_t y) { return getPixelColor(x); }
void blendPixelColorXY(uint16_t x, uint16_t y, uint32_t c, uint8_t blend) { blendPixelColor(x, c, blend); }
void blendPixelColorXY(uint16_t x, uint16_t y, CRGB c, uint8_t blend) { blendPixelColor(x, RGBW32(c.r,c.g,c.b,0), blend); }
void addPixelColorXY(int x, int y, uint32_t color) { addPixelColor(x, color); }
void addPixelColorXY(int x, int y, byte r, byte g, byte b, byte w = 0) { addPixelColor(x, RGBW32(r,g,b,w)); }
void addPixelColorXY(int x, int y, CRGB c) { addPixelColor(x, RGBW32(c.r,c.g,c.b,0)); }
void fadePixelColorXY(uint16_t x, uint16_t y, uint8_t fade) { fadePixelColor(x, fade); }
void box_blur(uint16_t i, bool vertical, fract8 blur_amount) {}
void blurRow(uint16_t row, fract8 blur_amount) {}
void blurCol(uint16_t col, fract8 blur_amount) {}
void moveX(int8_t delta) {}
void moveY(int8_t delta) {}
void move(uint8_t dir, uint8_t delta) {}
void fill_circle(uint16_t cx, uint16_t cy, uint8_t radius, CRGB c) {}
void drawLine(uint16_t x0, uint16_t y0, uint16_t x1, uint16_t y1, uint32_t c) {}
void drawLine(uint16_t x0, uint16_t y0, uint16_t x1, uint16_t y1, CRGB c) {}
void drawCharacter(unsigned char chr, int16_t x, int16_t y, uint8_t w, uint8_t h, uint32_t color) {}
void drawCharacter(unsigned char chr, int16_t x, int16_t y, uint8_t w, uint8_t h, CRGB color) {}
void wu_pixel(uint32_t x, uint32_t y, CRGB c) {}
#endif
} segment;
//static int i = sizeof(Segment);
// main "strip" class
class WS2812FX { // 96 bytes
typedef uint16_t (*mode_ptr)(void); // pointer to mode function
typedef void (*show_callback)(void); // pre show callback
typedef struct ModeData {
uint8_t _id; // mode (effect) id
mode_ptr _fcn; // mode (effect) function
const char *_data; // mode (effect) name and its UI control data
ModeData(uint8_t id, uint16_t (*fcn)(void), const char *data) : _id(id), _fcn(fcn), _data(data) {}
} mode_data_t;
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static WS2812FX* instance;
public:
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WS2812FX() :
gammaCorrectBri(false),
gammaCorrectCol(true),
paletteFade(0),
paletteBlend(0),
milliampsPerLed(55),
cctBlending(0),
ablMilliampsMax(ABL_MILLIAMPS_DEFAULT),
currentMilliamps(0),
now(millis()),
timebase(0),
isMatrix(false),
#ifndef WLED_DISABLE_2D
hPanels(1),
vPanels(1),
panelH(8),
panelW(8),
matrixWidth(DEFAULT_LED_COUNT),
matrixHeight(1),
matrix{0,0,0,0},
panel{{0,0,0,0}},
#endif
// semi-private (just obscured) used in effect functions through macros
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_currentPalette(CRGBPalette16(CRGB::Black)),
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_colors_t{0,0,0},
_virtualSegmentLength(0),
// true private variables
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_length(DEFAULT_LED_COUNT),
_brightness(DEFAULT_BRIGHTNESS),
_transitionDur(750),
_targetFps(WLED_FPS),
_frametime(FRAMETIME_FIXED),
_cumulativeFps(2),
_isServicing(false),
_isOffRefreshRequired(false),
_hasWhiteChannel(false),
_triggered(false),
_modeCount(MODE_COUNT),
_callback(nullptr),
customMappingTable(nullptr),
customMappingSize(0),
_lastShow(0),
_segment_index(0),
_mainSegment(0)
{
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WS2812FX::instance = this;
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_mode.reserve(_modeCount); // allocate memory to prevent initial fragmentation (does not increase size())
_modeData.reserve(_modeCount); // allocate memory to prevent initial fragmentation (does not increase size())
if (_mode.capacity() <= 1 || _modeData.capacity() <= 1) _modeCount = 1; // memory allocation failed only show Solid
else setupEffectData();
}
~WS2812FX() {
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if (customMappingTable) delete[] customMappingTable;
_mode.clear();
_modeData.clear();
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_segments.clear();
customPalettes.clear();
if (useLedsArray && Segment::_globalLeds) free(Segment::_globalLeds);
}
static WS2812FX* getInstance(void) { return instance; }
void
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#ifdef WLED_DEBUG
printSize(),
#endif
finalizeInit(),
service(void),
setMode(uint8_t segid, uint8_t m),
setColor(uint8_t slot, uint8_t r, uint8_t g, uint8_t b, uint8_t w = 0),
setColor(uint8_t slot, uint32_t c),
setCCT(uint16_t k),
setBrightness(uint8_t b, bool direct = false),
setRange(uint16_t i, uint16_t i2, uint32_t col),
setTransitionMode(bool t),
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purgeSegments(bool force = false),
setSegment(uint8_t n, uint16_t start, uint16_t stop, uint8_t grouping = 1, uint8_t spacing = 0, uint16_t offset = UINT16_MAX, uint16_t startY=0, uint16_t stopY=1),
setMainSegmentId(uint8_t n),
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restartRuntime(),
resetSegments(),
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makeAutoSegments(bool forceReset = false),
fixInvalidSegments(),
setPixelColor(int n, uint32_t c),
show(void),
setTargetFps(uint8_t fps),
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deserializeMap(uint8_t n=0);
void fill(uint32_t c) { for (int i = 0; i < _length; i++) setPixelColor(i, c); } // fill whole strip with color (inline)
void addEffect(uint8_t id, mode_ptr mode_fn, const char *mode_name); // add effect to the list; defined in FX.cpp
void setupEffectData(void); // add default effects to the list; defined in FX.cpp
// outsmart the compiler :) by correctly overloading
inline void setPixelColor(int n, uint8_t r, uint8_t g, uint8_t b, uint8_t w = 0) { setPixelColor(n, RGBW32(r,g,b,w)); }
inline void setPixelColor(int n, CRGB c) { setPixelColor(n, c.red, c.green, c.blue); }
inline void trigger(void) { _triggered = true; } // Forces the next frame to be computed on all active segments.
inline void setShowCallback(show_callback cb) { _callback = cb; }
inline void setTransition(uint16_t t) { _transitionDur = t; }
inline void appendSegment(const Segment &seg = Segment()) { _segments.push_back(seg); }
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bool
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gammaCorrectBri,
gammaCorrectCol,
checkSegmentAlignment(void),
hasRGBWBus(void),
hasCCTBus(void),
// return true if the strip is being sent pixel updates
isUpdating(void),
useLedsArray = false;
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inline bool isServicing(void) { return _isServicing; }
inline bool hasWhiteChannel(void) {return _hasWhiteChannel;}
inline bool isOffRefreshRequired(void) {return _isOffRefreshRequired;}
uint8_t
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paletteFade,
paletteBlend,
milliampsPerLed,
cctBlending,
getActiveSegmentsNum(void),
getFirstSelectedSegId(void),
getLastActiveSegmentId(void),
setPixelSegment(uint8_t n);
inline uint8_t getBrightness(void) { return _brightness; }
inline uint8_t getMaxSegments(void) { return MAX_NUM_SEGMENTS; } // returns maximum number of supported segments (fixed value)
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inline uint8_t getSegmentsNum(void) { return _segments.size(); } // returns currently present segments
inline uint8_t getCurrSegmentId(void) { return _segment_index; }
inline uint8_t getMainSegmentId(void) { return _mainSegment; }
inline uint8_t getPaletteCount() { return 13 + GRADIENT_PALETTE_COUNT; }
inline uint8_t getTargetFps() { return _targetFps; }
inline uint8_t getModeCount() { return _modeCount; }
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uint16_t
ablMilliampsMax,
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currentMilliamps,
getLengthPhysical(void),
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getFps();
inline uint16_t getFrameTime(void) { return _frametime; }
inline uint16_t getMinShowDelay(void) { return MIN_SHOW_DELAY; }
inline uint16_t getLengthTotal(void) { return _length; }
inline uint16_t getTransition(void) { return _transitionDur; }
uint32_t
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now,
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timebase,
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currentColor(uint32_t colorNew, uint8_t tNr),
getPixelColor(uint16_t);
inline uint32_t getLastShow(void) { return _lastShow; }
inline uint32_t segColor(uint8_t i) { return _colors_t[i]; }
const char *
getModeData(uint8_t id = 0) { return (id && id<_modeCount) ? _modeData[id] : PSTR("Solid"); }
const char **
getModeDataSrc(void) { return &(_modeData[0]); } // vectors use arrays for underlying data
Segment& getSegment(uint8_t id);
inline Segment& getFirstSelectedSeg(void) { return _segments[getFirstSelectedSegId()]; }
inline Segment& getMainSegment(void) { return _segments[getMainSegmentId()]; }
inline Segment* getSegments(void) { return &(_segments[0]); }
// 2D support (panels)
bool
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isMatrix;
#ifndef WLED_DISABLE_2D
#define WLED_MAX_PANELS 64
uint8_t
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hPanels,
vPanels;
uint16_t
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panelH,
panelW,
matrixWidth,
matrixHeight;
typedef struct panel_bitfield_t {
bool bottomStart : 1; // starts at bottom?
bool rightStart : 1; // starts on right?
bool vertical : 1; // is vertical?
bool serpentine : 1; // is serpentine?
} Panel;
Panel
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matrix,
panel[WLED_MAX_PANELS];
#endif
void
setUpMatrix(),
setPixelColorXY(int x, int y, uint32_t c);
// outsmart the compiler :) by correctly overloading
inline void setPixelColorXY(int x, int y, byte r, byte g, byte b, byte w = 0) { setPixelColorXY(x, y, RGBW32(r,g,b,w)); } // automatically inline
inline void setPixelColorXY(int x, int y, CRGB c) { setPixelColorXY(x, y, RGBW32(c.r,c.g,c.b,0)); }
uint32_t
getPixelColorXY(uint16_t, uint16_t);
// end 2D support
void loadCustomPalettes(void); // loads custom palettes from JSON
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CRGBPalette16 _currentPalette; // palette used for current effect (includes transition)
std::vector<CRGBPalette16> customPalettes; // TODO: move custom palettes out of WS2812FX class
// using public variables to reduce code size increase due to inline function getSegment() (with bounds checking)
// and color transitions
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uint32_t _colors_t[3]; // color used for effect (includes transition)
uint16_t _virtualSegmentLength;
std::vector<segment> _segments;
friend class Segment;
private:
uint16_t _length;
uint8_t _brightness;
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uint16_t _transitionDur;
uint8_t _targetFps;
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uint16_t _frametime;
uint16_t _cumulativeFps;
// will require only 1 byte
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struct {
bool _isServicing : 1;
bool _isOffRefreshRequired : 1; //periodic refresh is required for the strip to remain off.
bool _hasWhiteChannel : 1;
bool _triggered : 1;
};
uint8_t _modeCount;
std::vector<mode_ptr> _mode; // SRAM footprint: 4 bytes per element
std::vector<const char*> _modeData; // mode (effect) name and its slider control data array
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show_callback _callback;
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uint16_t* customMappingTable;
uint16_t customMappingSize;
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uint32_t _lastShow;
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uint8_t _segment_index;
uint8_t _mainSegment;
void
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estimateCurrentAndLimitBri(void);
};
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extern const char JSON_mode_names[];
extern const char JSON_palette_names[];
#endif