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Merge branch 'master' into dev 

Conflicts:
	CHANGELOG.md
	wled00/FX.cpp
	wled00/FX_fcn.cpp
	wled00/ntp.cpp
	wled00/wled.h
	wled00/wled_math.h
pull/2737/head
Blaz Kristan 2021-04-21 21:16:08 +02:00
rodzic 90516217e0 ff083daf31
commit 8608c45309
8 zmienionych plików z 155 dodań i 56 usunięć
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6
CHANGELOG.md
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@ -2,6 +2,12 @@
### Builds after release 0.12.0
#### Build 2104210
- Added `tb` to JSON state, allowing setting the timebase (set tb=0 to start e.g. wipe effect from the beginning). Receive only.
- Slightly raised Solid mode refresh rate to work with LEDs (TM1814) that require refresh rates of at least 2fps
- Added sunrise and sunset calculation to the backup JSON time source
#### Build 2104151
- `NUM_STRIPS` no longer required with compile-time strip defaults

2
usermods/PIR_sensor_switch/usermod_PIR_sensor_switch.h
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@ -372,7 +372,7 @@ after <input type=\"number\" min=\"1\" max=\"720\" value=\"";
JsonObject top = root.createNestedObject(F("PIRsensorSwitch"));
top[F("PIRenabled")] = m_PIRenabled;
top[F("PIRoffSec")] = m_switchOffDelay;
top[F("pin")] = PIRsensorPin;
top["pin"] = PIRsensorPin;
}
/**

135
wled00/FX.cpp
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@ -25,9 +25,6 @@
*/
#include "FX.h"
#ifndef WLED_DISABLE_FX_HIGH_FLASH_USE
#include "tv_colors.h"
#endif
#define IBN 5100
#define PALETTE_SOLID_WRAP (paletteBlend == 1 || paletteBlend == 3)
@ -37,7 +34,7 @@
*/
uint16_t WS2812FX::mode_static(void) {
fill(SEGCOLOR(0));
return (SEGMENT.getOption(SEG_OPTION_TRANSITIONAL)) ? FRAMETIME : 500; //update faster if in transition
return (SEGMENT.getOption(SEG_OPTION_TRANSITIONAL)) ? FRAMETIME : 380; //update faster if in transition
}
@ -3803,19 +3800,30 @@ uint16_t WS2812FX::mode_blends(void) {
return FRAMETIME;
}
#ifndef WLED_DISABLE_FX_HIGH_FLASH_USE
typedef struct TvSim {
uint32_t totalTime = 0;
uint32_t fadeTime = 0;
uint32_t startTime = 0;
uint32_t elapsed = 0;
uint32_t pixelNum = 0;
uint16_t sliderValues = 0;
uint32_t sceeneStart = 0;
uint32_t sceeneDuration = 0;
uint16_t sceeneColorHue = 0;
uint8_t sceeneColorSat = 0;
uint8_t sceeneColorBri = 0;
uint8_t actualColorR = 0;
uint8_t actualColorG = 0;
uint8_t actualColorB = 0;
uint16_t pr = 0; // Prev R, G, B
uint16_t pg = 0;
uint16_t pb = 0;
} tvSim;
#define numTVPixels (sizeof(tv_colors) / 2) // 2 bytes per Pixel (5/6/5)
#ifndef WLED_DISABLE_FX_HIGH_FLASH_USE
#include "tv_colors.h"
#define numTVPixels (sizeof(tv_colors) / 2) // 2 bytes per Pixel (5/6/5)
#endif
/*
@ -3823,45 +3831,109 @@ typedef struct TvSim {
Modified and adapted to WLED by Def3nder, based on "Fake TV Light for Engineers" by Phillip Burgess https://learn.adafruit.com/fake-tv-light-for-engineers/arduino-sketch
*/
uint16_t WS2812FX::mode_tv_simulator(void) {
#ifdef WLED_DISABLE_FX_HIGH_FLASH_USE
return mode_static();
#else
uint16_t nr, ng, nb, r, g, b, i;
uint8_t hi, lo, r8, g8, b8;
uint16_t nr, ng, nb, r, g, b, i, hue;
uint8_t hi, lo, r8, g8, b8, sat, bri, j;
if (!SEGENV.allocateData(sizeof(tvSim))) return mode_static(); //allocation failed
TvSim* tvSimulator = reinterpret_cast<TvSim*>(SEGENV.data);
// initialize start of the TV-Colors
if (SEGENV.call == 0) {
tvSimulator->pixelNum = ((uint8_t)random(18)) * numTVPixels / 18; // Begin at random movie (18 in total)
uint8_t colorSpeed = map(SEGMENT.speed, 0, UINT8_MAX, 1, 20);
uint8_t colorIntensity = map(SEGMENT.intensity, 0, UINT8_MAX, 10, 30);
i = SEGMENT.speed << 8 | SEGMENT.intensity;
if (i != tvSimulator->sliderValues) {
tvSimulator->sliderValues = i;
SEGENV.aux1 = 0;
}
// Read next 16-bit (5/6/5) color
hi = pgm_read_byte(&tv_colors[tvSimulator->pixelNum * 2 ]);
lo = pgm_read_byte(&tv_colors[tvSimulator->pixelNum * 2 + 1]);
#ifndef WLED_DISABLE_FX_HIGH_FLASH_USE
/*
* this code uses the real color data from tv_colos.h
*/
// Expand to 24-bit (8/8/8)
r8 = (hi & 0xF8) | (hi >> 5);
g8 = ((hi << 5) & 0xff) | ((lo & 0xE0) >> 3) | ((hi & 0x06) >> 1);
b8 = ((lo << 3) & 0xff) | ((lo & 0x1F) >> 2);
// initialize start of the TV-Colors
if (SEGENV.aux1 == 0) {
tvSimulator->pixelNum = ((uint8_t)random8(18)) * numTVPixels / 18; // Begin at random movie (18 in total)
SEGENV.aux1 = 1;
}
// Read next 16-bit (5/6/5) color
hi = pgm_read_byte(&tv_colors[tvSimulator->pixelNum * 2 ]);
lo = pgm_read_byte(&tv_colors[tvSimulator->pixelNum * 2 + 1]);
// Expand to 24-bit (8/8/8)
r8 = (hi & 0xF8) | (hi >> 5);
g8 = ((hi << 5) & 0xff) | ((lo & 0xE0) >> 3) | ((hi & 0x06) >> 1);
b8 = ((lo << 3) & 0xff) | ((lo & 0x1F) >> 2);
// Apply gamma correction, further expand to 16/16/16
nr = (uint8_t)gamma8(r8) * 257; // New R/G/B
ng = (uint8_t)gamma8(g8) * 257;
nb = (uint8_t)gamma8(b8) * 257;
// Apply gamma correction, further expand to 16/16/16
nr = (uint8_t)gamma8(r8) * 257; // New R/G/B
ng = (uint8_t)gamma8(g8) * 257;
nb = (uint8_t)gamma8(b8) * 257;
#else
/*
* this code calculates the color to be used and save 18k of flash memory
*/
// create a new sceene
if (((millis() - tvSimulator->sceeneStart) >= tvSimulator->sceeneDuration) || SEGENV.aux1 == 0) {
tvSimulator->sceeneStart = millis(); // remember the start of the new sceene
tvSimulator->sceeneDuration = random16(60* 250* colorSpeed, 60* 750 * colorSpeed); // duration of a "movie sceene" which has similar colors (5 to 15 minutes with max speed slider)
tvSimulator->sceeneColorHue = random16( 0, 768); // random start color-tone for the sceene
tvSimulator->sceeneColorSat = random8 ( 100, 130 + colorIntensity); // random start color-saturation for the sceene
tvSimulator->sceeneColorBri = random8 ( 200, 240); // random start color-brightness for the sceene
SEGENV.aux1 = 1;
SEGENV.aux0 = 0;
}
// slightly change the color-tone in this sceene
if ( SEGENV.aux0 == 0) {
// hue change in both directions
j = random8(4 * colorIntensity);
hue = (random8() < 128) ? ((j < tvSimulator->sceeneColorHue) ? tvSimulator->sceeneColorHue - j : 767 - tvSimulator->sceeneColorHue - j) : // negative
((j + tvSimulator->sceeneColorHue) < 767 ? tvSimulator->sceeneColorHue + j : tvSimulator->sceeneColorHue + j - 767) ; // positive
// saturation
j = random8(2 * colorIntensity);
sat = (tvSimulator->sceeneColorSat - j) < 0 ? 0 : tvSimulator->sceeneColorSat - j;
// brightness
j = random8(100);
bri = (tvSimulator->sceeneColorBri - j) < 0 ? 0 : tvSimulator->sceeneColorBri - j;
// calculate R,G,B from HSV
// Source: https://blog.adafruit.com/2012/03/14/constant-brightness-hsb-to-rgb-algorithm/
{ // just to create a local scope for the variables
uint8_t temp[5], n = (hue >> 8) % 3;
uint8_t x = ((((hue & 255) * sat) >> 8) * bri) >> 8;
uint8_t s = ( (256 - sat) * bri) >> 8;
temp[0] = temp[3] = s;
temp[1] = temp[4] = x + s;
temp[2] = bri - x;
tvSimulator->actualColorR = temp[n + 2];
tvSimulator->actualColorG = temp[n + 1];
tvSimulator->actualColorB = temp[n ];
}
}
// Apply gamma correction, further expand to 16/16/16
nr = (uint8_t)gamma8(tvSimulator->actualColorR) * 257; // New R/G/B
ng = (uint8_t)gamma8(tvSimulator->actualColorG) * 257;
nb = (uint8_t)gamma8(tvSimulator->actualColorB) * 257;
#endif
if (SEGENV.aux0 == 0) { // initialize next iteration
SEGENV.aux0 = 1;
// increase color-index for next loop
tvSimulator->pixelNum++;
if (tvSimulator->pixelNum >= numTVPixels) tvSimulator->pixelNum = 0;
#ifndef WLED_DISABLE_FX_HIGH_FLASH_USE
// increase color-index for next loop
tvSimulator->pixelNum++;
if (tvSimulator->pixelNum >= numTVPixels) tvSimulator->pixelNum = 0;
#endif
// randomize total duration and fade duration for the actual color
tvSimulator->totalTime = random(250, 2500); // Semi-random pixel-to-pixel time
tvSimulator->fadeTime = random(0, tvSimulator->totalTime); // Pixel-to-pixel transition time
if (random(10) < 3) tvSimulator->fadeTime = 0; // Force scene cut 30% of time
tvSimulator->totalTime = random16(250, 2500); // Semi-random pixel-to-pixel time
tvSimulator->fadeTime = random16(0, tvSimulator->totalTime); // Pixel-to-pixel transition time
if (random8(10) < 3) tvSimulator->fadeTime = 0; // Force scene cut 30% of time
tvSimulator->startTime = millis();
} // end of initialization
@ -3894,7 +3966,6 @@ uint16_t WS2812FX::mode_tv_simulator(void) {
}
return FRAMETIME;
#endif
}
/*

2
wled00/FX_fcn.cpp
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@ -43,7 +43,7 @@
19, 18, 17, 16, 15, 20, 21, 22, 23, 24, 29, 28, 27, 26, 25]}
*/
//factory defaults LED setup (for multistrip boards)
//factory defaults LED setup
//#define PIXEL_COUNTS 30, 30, 30, 30
//#define DATA_PINS 16, 1, 3, 4
//#define DEFAULT_LED_TYPE TYPE_WS2812_RGB

48
wled00/bus_wrapper.h
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@ -28,7 +28,7 @@
#define I_8266_U1_400_3 10
#define I_8266_DM_400_3 11
#define I_8266_BB_400_3 12
//TM1418 (RGBW)
//TM1814 (RGBW)
#define I_8266_U0_TM1_4 13
#define I_8266_U1_TM1_4 14
#define I_8266_DM_TM1_4 15
@ -68,7 +68,7 @@
#define I_32_R7_400_3 44
#define I_32_I0_400_3 45
#define I_32_I1_400_3 46
//TM1418 (RGBW)
//TM1814 (RGBW)
#define I_32_R0_TM1_4 47
#define I_32_R1_TM1_4 48
#define I_32_R2_TM1_4 49
@ -117,7 +117,7 @@
#define B_8266_U1_400_3 NeoPixelBrightnessBus<NeoGrbFeature, NeoEsp8266Uart1400KbpsMethod> //3 chan, esp8266, gpio2
#define B_8266_DM_400_3 NeoPixelBrightnessBus<NeoGrbFeature, NeoEsp8266Dma400KbpsMethod> //3 chan, esp8266, gpio3
#define B_8266_BB_400_3 NeoPixelBrightnessBus<NeoGrbFeature, NeoEsp8266BitBang400KbpsMethod> //3 chan, esp8266, bb (any pin)
//TM1418 (RGBW)
//TM1814 (RGBW)
#define B_8266_U0_TM1_4 NeoPixelBrightnessBus<NeoWrgbTm1814Feature, NeoEsp8266Uart0Tm1814Method>
#define B_8266_U1_TM1_4 NeoPixelBrightnessBus<NeoWrgbTm1814Feature, NeoEsp8266Uart1Tm1814Method>
#define B_8266_DM_TM1_4 NeoPixelBrightnessBus<NeoWrgbTm1814Feature, NeoEsp8266DmaTm1814Method>
@ -159,7 +159,7 @@
#define B_32_R7_400_3 NeoPixelBrightnessBus<NeoGrbFeature, NeoEsp32Rmt7400KbpsMethod>
#define B_32_I0_400_3 NeoPixelBrightnessBus<NeoGrbFeature, NeoEsp32I2s0400KbpsMethod>
#define B_32_I1_400_3 NeoPixelBrightnessBus<NeoGrbFeature, NeoEsp32I2s1400KbpsMethod>
//TM1418 (RGBW)
//TM1814 (RGBW)
#define B_32_R0_TM1_4 NeoPixelBrightnessBus<NeoWrgbTm1814Feature, NeoEsp32Rmt0Tm1814Method>
#define B_32_R1_TM1_4 NeoPixelBrightnessBus<NeoWrgbTm1814Feature, NeoEsp32Rmt1Tm1814Method>
#define B_32_R2_TM1_4 NeoPixelBrightnessBus<NeoWrgbTm1814Feature, NeoEsp32Rmt2Tm1814Method>
@ -198,6 +198,14 @@
//handles pointer type conversion for all possible bus types
class PolyBus {
public:
// Begin & initialize the PixelSettings for TM1814 strips.
template <class T>
static void beginTM1814(void* busPtr) {
T tm1814_strip = static_cast<T>(busPtr);
tm1814_strip->Begin();
// Max current for each LED (22.5 mA).
tm1814_strip->SetPixelSettings(NeoTm1814Settings(/*R*/225, /*G*/225, /*B*/225, /*W*/225));
}
static void begin(void* busPtr, uint8_t busType, uint8_t* pins) {
switch (busType) {
case I_NONE: break;
@ -214,10 +222,10 @@ class PolyBus {
case I_8266_U1_400_3: (static_cast<B_8266_U1_400_3*>(busPtr))->Begin(); break;
case I_8266_DM_400_3: (static_cast<B_8266_DM_400_3*>(busPtr))->Begin(); break;
case I_8266_BB_400_3: (static_cast<B_8266_BB_400_3*>(busPtr))->Begin(); break;
case I_8266_U0_TM1_4: (static_cast<B_8266_U0_TM1_4*>(busPtr))->Begin(); break;
case I_8266_U1_TM1_4: (static_cast<B_8266_U1_TM1_4*>(busPtr))->Begin(); break;
case I_8266_DM_TM1_4: (static_cast<B_8266_DM_TM1_4*>(busPtr))->Begin(); break;
case I_8266_BB_TM1_4: (static_cast<B_8266_BB_TM1_4*>(busPtr))->Begin(); break;
case I_8266_U0_TM1_4: beginTM1814<B_8266_U0_TM1_4*>(busPtr); break;
case I_8266_U1_TM1_4: beginTM1814<B_8266_U1_TM1_4*>(busPtr); break;
case I_8266_DM_TM1_4: beginTM1814<B_8266_DM_TM1_4*>(busPtr); break;
case I_8266_BB_TM1_4: beginTM1814<B_8266_BB_TM1_4*>(busPtr); break;
case I_HS_DOT_3: (static_cast<B_HS_DOT_3*>(busPtr))->Begin(); break;
case I_HS_DOT_4: (static_cast<B_HS_DOT_4*>(busPtr))->Begin(); break;
case I_HS_LPD_3: (static_cast<B_HS_LPD_3*>(busPtr))->Begin(); break;
@ -255,16 +263,16 @@ class PolyBus {
case I_32_R7_400_3: (static_cast<B_32_R7_400_3*>(busPtr))->Begin(); break;
case I_32_I0_400_3: (static_cast<B_32_I0_400_3*>(busPtr))->Begin(); break;
case I_32_I1_400_3: (static_cast<B_32_I1_400_3*>(busPtr))->Begin(); break;
case I_32_R0_TM1_4: (static_cast<B_32_R0_TM1_4*>(busPtr))->Begin(); break;
case I_32_R1_TM1_4: (static_cast<B_32_R1_TM1_4*>(busPtr))->Begin(); break;
case I_32_R2_TM1_4: (static_cast<B_32_R2_TM1_4*>(busPtr))->Begin(); break;
case I_32_R3_TM1_4: (static_cast<B_32_R3_TM1_4*>(busPtr))->Begin(); break;
case I_32_R4_TM1_4: (static_cast<B_32_R4_TM1_4*>(busPtr))->Begin(); break;
case I_32_R5_TM1_4: (static_cast<B_32_R5_TM1_4*>(busPtr))->Begin(); break;
case I_32_R6_TM1_4: (static_cast<B_32_R6_TM1_4*>(busPtr))->Begin(); break;
case I_32_R7_TM1_4: (static_cast<B_32_R7_TM1_4*>(busPtr))->Begin(); break;
case I_32_I0_TM1_4: (static_cast<B_32_I0_TM1_4*>(busPtr))->Begin(); break;
case I_32_I1_TM1_4: (static_cast<B_32_I1_TM1_4*>(busPtr))->Begin(); break;
case I_32_R0_TM1_4: beginTM1814<B_32_R0_TM1_4*>(busPtr); break;
case I_32_R1_TM1_4: beginTM1814<B_32_R1_TM1_4*>(busPtr); break;
case I_32_R2_TM1_4: beginTM1814<B_32_R2_TM1_4*>(busPtr); break;
case I_32_R3_TM1_4: beginTM1814<B_32_R3_TM1_4*>(busPtr); break;
case I_32_R4_TM1_4: beginTM1814<B_32_R4_TM1_4*>(busPtr); break;
case I_32_R5_TM1_4: beginTM1814<B_32_R5_TM1_4*>(busPtr); break;
case I_32_R6_TM1_4: beginTM1814<B_32_R6_TM1_4*>(busPtr); break;
case I_32_R7_TM1_4: beginTM1814<B_32_R7_TM1_4*>(busPtr); break;
case I_32_I0_TM1_4: beginTM1814<B_32_I0_TM1_4*>(busPtr); break;
case I_32_I1_TM1_4: beginTM1814<B_32_I1_TM1_4*>(busPtr); break;
// ESP32 can (and should, to avoid inadvertantly driving the chip select signal) specify the pins used for SPI, but only in begin()
case I_HS_DOT_3: (static_cast<B_HS_DOT_3*>(busPtr))->Begin(pins[1], -1, pins[0], -1); break;
case I_HS_DOT_4: (static_cast<B_HS_DOT_4*>(busPtr))->Begin(pins[1], -1, pins[0], -1); break;
@ -878,6 +886,8 @@ class PolyBus {
return (rgbwOverride ? I_8266_U0_NEO_4 : I_8266_U0_NEO_3) + offset;
case TYPE_WS2811_400KHZ:
return I_8266_U0_400_3 + offset;
case TYPE_TM1814:
return I_8266_U0_TM1_4 + offset;
}
#else //ESP32
uint8_t offset = num; //RMT bus # == bus index in BusManager
@ -890,6 +900,8 @@ class PolyBus {
return (rgbwOverride ? I_32_R0_NEO_4 : I_32_R0_NEO_3) + offset;
case TYPE_WS2811_400KHZ:
return I_32_R0_400_3 + offset;
case TYPE_TM1814:
return I_32_R0_TM1_4 + offset;
}
#endif
}

14
wled00/json.cpp
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@ -214,6 +214,9 @@ bool deserializeState(JsonObject root)
jsonTransitionOnce = true;
}
strip.setTransition(transitionDelayTemp);
tr = root[F("tb")] | -1;
if (tr >= 0) strip.timebase = ((uint32_t)tr) - millis();
int cy = root[F("pl")] | -2;
if (cy > -2) presetCyclingEnabled = (cy >= 0);
@ -235,9 +238,16 @@ bool deserializeState(JsonObject root)
receiveNotifications = udpn["recv"] | receiveNotifications;
bool noNotification = udpn[F("nn")]; //send no notification just for this request
unsigned long timein = root[F("time")] | UINT32_MAX;
unsigned long timein = root[F("time")] | UINT32_MAX; //backup time source if NTP not synced
if (timein != UINT32_MAX) {
if (millis() - ntpLastSyncTime > 50000000L) setTime(timein);
time_t prev = now();
if (millis() - ntpLastSyncTime > 50000000L) {
setTime(timein);
if (abs(now() - prev) > 60L) {
updateLocalTime();
calculateSunriseAndSunset();
}
}
if (presetsModifiedTime == 0) presetsModifiedTime = timein;
}

2
wled00/ntp.cpp
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@ -330,7 +330,7 @@ int getSunriseUTC(int year, int month, int day, float lat, float lon, bool sunse
float M = (0.9856f * t) - 3.289f;
//4. calculate the Sun's true longitude
float L = fmod_t(M + (1.916f * sin_t(DEG_TO_RAD*M)) + (0.020f * sin_t(2*DEG_TO_RAD*M)) + 282.634f, 360.0f);
float L = fmod_t(M + (1.916f * sin_t(DEG_TO_RAD*M)) + (0.02f * sin_t(2*DEG_TO_RAD*M)) + 282.634f, 360.0f);
//5a. calculate the Sun's right ascension
float RA = fmod_t(RAD_TO_DEG*atan_t(0.91764f * tan_t(DEG_TO_RAD*L)), 360.0f);

2
wled00/wled.h
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@ -8,7 +8,7 @@
*/
// version code in format yymmddb (b = daily build)
#define VERSION 2104191
#define VERSION 2104210
//uncomment this if you have a "my_config.h" file you'd like to use
//#define WLED_USE_MY_CONFIG