mirror of
https://github.com/hyperion-project/hyperion.ng.git
synced 2023-10-10 13:36:59 +02:00
update adalight sketch (#299)
* rename platform rpi-pwm to rpi. remove original rpi platform install symlink to bin folder create effects folder for custom effects * fix osx jobs evaluation * - add rewrite time to serial leds - rework adalight sketch * add analog output * adalight: add analog mode: last led * tune adalight sketch to final state move refresh code to leddevice base class, so every leddevice can use it
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@ -1,117 +1,239 @@
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#include "FastLED.h"
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// How many leds in your strip?
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#define NUM_LEDS 240
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#define ANALOG_MODE_AVERAGE 0
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#define ANALOG_MODE_LAST_LED 1
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// For led chips like Neopixels, which have a data line, ground, and power, you just
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// need to define DATA_PIN. For led chipsets that are SPI based (four wires - data, clock,
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// ground, and power), like the LPD8806 define both DATA_PIN and CLOCK_PIN
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#define DATA_PIN 6
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/**************************************
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S E T U P
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set following values to your needs
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**************************************/
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// Number of leds in your strip. set to 1 and ANALOG_OUTPUT_ENABLED to true to activate analog only
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#define NUM_LEDS 100
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#define SPI_LEDS false // connection type. Set "true" for 4 wire and "false" for 3 Wire stripes.
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#define LED_TYPE WS2812B // type of your led controller, possible values, see below
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// 3 wire (pwm): NEOPIXEL BTM1829 TM1812 TM1809 TM1804 TM1803 UCS1903 UCS1903B UCS1904 UCS2903 WS2812 WS2852
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// S2812B SK6812 SK6822 APA106 PL9823 WS2811 WS2813 APA104 WS2811_40 GW6205 GW6205_40 LPD1886 LPD1886_8BIT
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// 4 wire (spi): LPD8806 WS2801 WS2803 SM16716 P9813 APA102 SK9822 DOTSTAR
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// For 3 wire led stripes line Neopixel/Ws2812, which have a data line, ground, and power, you just need to define DATA_PIN.
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// For led chipsets that are SPI based (four wires - data, clock, ground, and power), both defines DATA_PIN and CLOCK_PIN are needed
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#define DATA_PIN 6
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#define CLOCK_PIN 13
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#define COLOR_ORDER RGB
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#define COLOR_ORDER GRB // colororder of the stripe, set RGB in hyperion
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#define OFF_TIMEOUT 15000 // ms to switch off after no data was received, set 0 to deactivate
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// analog rgb uni color led stripe - using of hyperion smoothing is recommended
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// ATTENTION this pin config is default for atmega328 based arduinos, others might work to
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// if you have flickering analog leds this might be caused by unsynced pwm signals
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// try other pins is more or less the only thing that helps
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#define ANALOG_OUTPUT_ENABLED true
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#define ANALOG_MODE ANALOG_MODE_LAST_LED // use ANALOG_MODE_AVERAGE or ANALOG_MODE_LAST_LED
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#define ANALOG_GROUND_PIN 8 // additional ground pin to make wiring a bit easier
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#define ANALOG_RED_PIN 9
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#define ANALOG_GREEN_PIN 10
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#define ANALOG_BLUE_PIN 11
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// overall color adjustments
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#define ANALOG_BRIGHTNESS_RED 255 // maximum brightness for analog 0-255
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#define ANALOG_BRIGHTNESS_GREEN 255 // maximum brightness for analog 0-255
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#define ANALOG_BRIGHTNESS_BLUE 255 // maximum brightness for analog 0-255
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#define BRIGHTNESS 255 // maximum brightness 0-255
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#define DITHER_MODE BINARY_DITHER // BINARY_DITHER or DISABLE_DITHER
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#define COLOR_TEMPERATURE CRGB(255,255,255) // RGB value describing the color temperature
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#define COLOR_CORRECTION CRGB(255,255,255) // RGB value describing the color correction
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// Baudrate, higher rate allows faster refresh rate and more LEDs (defined in /etc/boblight.conf)
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#define serialRate 460800 // use 115200 for ftdi based boards
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/**************************************
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A D A L I G H T C O D E
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no user changes needed
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**************************************/
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// Adalight sends a "Magic Word" (defined in /etc/boblight.conf) before sending the pixel data
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uint8_t prefix[] = {'A', 'd', 'a'}, hi, lo, chk, i;
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// Baudrate, higher rate allows faster refresh rate and more LEDs (defined in /etc/boblight.conf)
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#define serialRate 460800
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unsigned long endTime;
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// Define the array of leds
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CRGB leds[NUM_LEDS];
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void setup() {
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// Uncomment/edit one of the following lines for your leds arrangement.
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// FastLED.addLeds<NEOPIXEL , DATA_PIN, RGB>(leds, NUM_LEDS);
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// FastLED.addLeds<BTM1829 , DATA_PIN, RGB>(leds, NUM_LEDS);
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// FastLED.addLeds<TM1812 , DATA_PIN, RGB>(leds, NUM_LEDS);
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// FastLED.addLeds<TM1809 , DATA_PIN, RGB>(leds, NUM_LEDS);
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// FastLED.addLeds<TM1804 , DATA_PIN, RGB>(leds, NUM_LEDS);
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// FastLED.addLeds<TM1803 , DATA_PIN, RGB>(leds, NUM_LEDS);
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// FastLED.addLeds<UCS1903 , DATA_PIN, RGB>(leds, NUM_LEDS);
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// FastLED.addLeds<UCS1903B , DATA_PIN, RGB>(leds, NUM_LEDS);
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// FastLED.addLeds<UCS1904 , DATA_PIN, RGB>(leds, NUM_LEDS);
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// FastLED.addLeds<UCS2903 , DATA_PIN, RGB>(leds, NUM_LEDS);
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// FastLED.addLeds<WS2812 , DATA_PIN, RGB>(leds, NUM_LEDS);
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// FastLED.addLeds<WS2852 , DATA_PIN, RGB>(leds, NUM_LEDS);
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FastLED.addLeds<WS2812B , DATA_PIN, RGB>(leds, NUM_LEDS);
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// FastLED.addLeds<SK6812 , DATA_PIN, RGB>(leds, NUM_LEDS);
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// FastLED.addLeds<SK6822 , DATA_PIN, RGB>(leds, NUM_LEDS);
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// FastLED.addLeds<APA106 , DATA_PIN, RGB>(leds, NUM_LEDS);
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// FastLED.addLeds<PL9823 , DATA_PIN, RGB>(leds, NUM_LEDS);
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// FastLED.addLeds<WS2811 , DATA_PIN, RGB>(leds, NUM_LEDS);
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// FastLED.addLeds<WS2813 , DATA_PIN, RGB>(leds, NUM_LEDS);
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// FastLED.addLeds<APA104 , DATA_PIN, RGB>(leds, NUM_LEDS);
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// FastLED.addLeds<WS2811_40 , DATA_PIN, RGB>(leds, NUM_LEDS);
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// FastLED.addLeds<GW6205 , DATA_PIN, RGB>(leds, NUM_LEDS);
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// FastLED.addLeds<GW6205_40 , DATA_PIN, RGB>(leds, NUM_LEDS);
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// FastLED.addLeds<LPD1886 , DATA_PIN, RGB>(leds, NUM_LEDS);
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// FastLED.addLeds<LPD1886_8BIT, DATA_PIN, RGB>(leds, NUM_LEDS);
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// set rgb to analog led stripe
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void showAnalogRGB(const CRGB& led) {
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if (ANALOG_OUTPUT_ENABLED) {
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byte r = map(led.r, 0,255,0,ANALOG_BRIGHTNESS_RED);
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byte g = map(led.g, 0,255,0,ANALOG_BRIGHTNESS_GREEN);
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byte b = map(led.b, 0,255,0,ANALOG_BRIGHTNESS_BLUE);
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analogWrite(ANALOG_RED_PIN , r);
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analogWrite(ANALOG_GREEN_PIN, g);
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analogWrite(ANALOG_BLUE_PIN , b);
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}
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}
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// FastLED.addLeds<LPD8806, DATA_PIN, CLOCK_PIN, RGB>(leds, NUM_LEDS);
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// FastLED.addLeds<WS2801 , DATA_PIN, CLOCK_PIN, RGB>(leds, NUM_LEDS);
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// FastLED.addLeds<WS2803 , DATA_PIN, CLOCK_PIN, RGB>(leds, NUM_LEDS);
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// FastLED.addLeds<SM16716, DATA_PIN, CLOCK_PIN, RGB>(leds, NUM_LEDS);
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// FastLED.addLeds<P9813 , DATA_PIN, CLOCK_PIN, RGB>(leds, NUM_LEDS);
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// FastLED.addLeds<APA102 , DATA_PIN, CLOCK_PIN, RGB>(leds, NUM_LEDS);
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// FastLED.addLeds<SK9822 , DATA_PIN, CLOCK_PIN, RGB>(leds, NUM_LEDS);
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// FastLED.addLeds<DOTSTAR, DATA_PIN, CLOCK_PIN, RGB>(leds, NUM_LEDS);
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// set color to all leds
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void showColor(const CRGB& led) {
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#if NUM_LEDS > 1 || ANALOG_OUTPUT_ENABLED == false
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LEDS.showColor(led);
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#endif
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showAnalogRGB(led);
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}
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// switch of digital and analog leds
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void switchOff() {
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#if ANALOG_ONLY == false
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memset(leds, 0, NUM_LEDS * sizeof(struct CRGB));
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FastLED.show();
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#endif
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showAnalogRGB(leds[0]);
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}
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// function to check if serial data is available
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// if timeout occured leds switch of, if configured
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bool checkIncommingData() {
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boolean dataAvailable = true;
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while (!Serial.available()) {
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if ( OFF_TIMEOUT > 0 && endTime < millis()) {
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switchOff();
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dataAvailable = false;
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endTime = millis() + OFF_TIMEOUT;
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}
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}
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return dataAvailable;
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}
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// main function that setups and runs the code
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void setup() {
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// additional ground pin to make wiring a bit easier
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pinMode(ANALOG_GROUND_PIN, OUTPUT);
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digitalWrite(ANALOG_GROUND_PIN, LOW);
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// analog output
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if (ANALOG_OUTPUT_ENABLED) {
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pinMode(ANALOG_BLUE_PIN , OUTPUT);
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pinMode(ANALOG_RED_PIN , OUTPUT);
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pinMode(ANALOG_GREEN_PIN, OUTPUT);
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}
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// Uncomment/edit one of the following lines for your leds arrangement.
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int ledCount = NUM_LEDS;
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if (ANALOG_MODE == ANALOG_MODE_LAST_LED) {
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ledCount--;
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}
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#if NUM_LEDS > 1 || ANALOG_OUTPUT_ENABLED == false
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#if SPI_LEDS == true
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FastLED.addLeds<LED_TYPE, DATA_PIN, CLOCK_PIN, COLOR_ORDER>(leds, ledCount);
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#else
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FastLED.addLeds<LED_TYPE, DATA_PIN, COLOR_ORDER>(leds, ledCount);
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#endif
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#endif
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// color adjustments
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FastLED.setBrightness ( BRIGHTNESS );
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FastLED.setTemperature( COLOR_TEMPERATURE );
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FastLED.setCorrection ( COLOR_CORRECTION );
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FastLED.setDither ( DITHER_MODE );
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// initial RGB flash
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LEDS.showColor(CRGB(255, 0, 0));
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delay(250);
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LEDS.showColor(CRGB(0, 255, 0));
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delay(250);
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LEDS.showColor(CRGB(0, 0, 255));
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delay(250);
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LEDS.showColor(CRGB(0, 0, 0));
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showColor(CRGB(255, 0, 0)); delay(400);
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showColor(CRGB(0, 255, 0)); delay(400);
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showColor(CRGB(0, 0, 255)); delay(400);
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showColor(CRGB(0, 0, 0));
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Serial.begin(serialRate);
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Serial.print("Ada\n"); // Send "Magic Word" string to host
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}
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boolean transmissionSuccess;
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unsigned long sum_r, sum_g, sum_b;
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// loop() is avoided as even that small bit of function overhead
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// has a measurable impact on this code's overall throughput.
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while (true) {
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// wait for first byte of Magic Word
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for (i = 0; i < sizeof prefix; ++i) {
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// If next byte is not in Magic Word, the start over
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if (!checkIncommingData() || prefix[i] != Serial.read()) {
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i = 0;
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}
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}
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// Hi, Lo, Checksum
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if (!checkIncommingData()) continue;
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hi = Serial.read();
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if (!checkIncommingData()) continue;
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lo = Serial.read();
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if (!checkIncommingData()) continue;
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chk = Serial.read();
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// if checksum does not match go back to wait
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if (chk != (hi ^ lo ^ 0x55)) continue;
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memset(leds, 0, NUM_LEDS * sizeof(struct CRGB));
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transmissionSuccess = true;
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sum_r = 0;
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sum_g = 0;
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sum_b = 0;
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// read the transmission data and set LED values
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for (uint8_t idx = 0; idx < NUM_LEDS; idx++) {
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byte r, g, b;
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if (!checkIncommingData()) {
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transmissionSuccess = false;
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break;
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}
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r = Serial.read();
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if (!checkIncommingData()) {
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transmissionSuccess = false;
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break;
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}
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g = Serial.read();
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if (!checkIncommingData()) {
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transmissionSuccess = false;
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break;
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}
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b = Serial.read();
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leds[idx].r = r;
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leds[idx].g = g;
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leds[idx].b = b;
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#if ANALOG_OUTPUT_ENABLED == true && ANALOG_MODE == ANALOG_MODE_AVERAGE
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sum_r += r;
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sum_g += g;
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sum_b += b;
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#endif
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}
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// shows new values
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if (transmissionSuccess) {
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endTime = millis() + OFF_TIMEOUT;
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#if NUM_LEDS > 1 || ANALOG_OUTPUT_ENABLED == false
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FastLED.show();
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#endif
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#if ANALOG_OUTPUT_ENABLED == true
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#if ANALOG_MODE == ANALOG_MODE_LAST_LED
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showAnalogRGB(leds[NUM_LEDS-1]);
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#else
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showAnalogRGB(CRGB(sum_r/NUM_LEDS, sum_g/NUM_LEDS, sum_b/NUM_LEDS));
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#endif
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#endif
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}
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}
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} // end of setup
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void loop() {
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// wait for first byte of Magic Word
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for (i = 0; i < sizeof prefix; ++i) {
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waitLoop: while (!Serial.available()) ;;
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// Check next byte in Magic Word
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if (prefix[i] == Serial.read()) continue;
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// otherwise, start over
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i = 0;
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goto waitLoop;
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}
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// Hi, Lo, Checksum
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while (!Serial.available()) ;;
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hi = Serial.read();
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while (!Serial.available()) ;;
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lo = Serial.read();
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while (!Serial.available()) ;;
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chk = Serial.read();
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// if checksum does not match go back to wait
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if (chk != (hi ^ lo ^ 0x55))
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{
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i = 0;
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goto waitLoop;
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}
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memset(leds, 0, NUM_LEDS * sizeof(struct CRGB));
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// read the transmission data and set LED values
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for (uint8_t i = 0; i < NUM_LEDS; i++) {
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byte r, g, b;
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while (!Serial.available());
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r = Serial.read();
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while (!Serial.available());
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g = Serial.read();
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while (!Serial.available());
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b = Serial.read();
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leds[i].r = r;
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leds[i].g = g;
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leds[i].b = b;
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}
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// shows new values
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FastLED.show();
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// Not used. See note in setup() function.
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}
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#include <map>
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#include <algorithm>
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#include <QTimer>
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// Utility includes
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#include <utils/ColorRgb.h>
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#include <utils/ColorRgbw.h>
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@ -81,4 +83,15 @@ protected:
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static int _ledCount;
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static int _ledRGBCount;
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static int _ledRGBWCount;
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/// Timer object which makes sure that led data is written at a minimum rate
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/// e.g. Adalight device will switch off when it does not receive data at least every 15 seconds
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QTimer _refresh_timer;
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protected slots:
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/// Write the last data to the leds again
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int rewriteLeds();
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private:
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std::vector<ColorRgb> _ledValues;
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};
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@ -17,9 +17,14 @@ LedDevice::LedDevice()
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, _log(Logger::getInstance("LedDevice"))
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, _ledBuffer(0)
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, _deviceReady(true)
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, _refresh_timer()
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{
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LedDevice::getLedDeviceSchemas();
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// setup timer
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_refresh_timer.setSingleShot(false);
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_refresh_timer.setInterval(0);
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connect(&_refresh_timer, SIGNAL(timeout()), this, SLOT(rewriteLeds()));
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}
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// dummy implemention
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@ -103,7 +108,17 @@ QJsonObject LedDevice::getLedDeviceSchemas()
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int LedDevice::setLedValues(const std::vector<ColorRgb>& ledValues)
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{
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return _deviceReady ? write(ledValues) : -1;
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if (!_deviceReady)
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return -1;
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_ledValues = ledValues;
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// restart the timer
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if (_refresh_timer.interval() > 0)
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{
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_refresh_timer.start();
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}
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return write(ledValues);
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}
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int LedDevice::switchOff()
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@ -118,3 +133,8 @@ void LedDevice::setLedCount(int ledCount)
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_ledRGBCount = _ledCount * sizeof(ColorRgb);
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_ledRGBWCount = _ledCount * sizeof(ColorRgbw);
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}
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int LedDevice::rewriteLeds()
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{
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return write(_ledValues);
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}
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@ -2,7 +2,6 @@
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LedDeviceAdalight::LedDeviceAdalight(const QJsonObject &deviceConfig)
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: ProviderRs232()
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{
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_deviceReady = init(deviceConfig);
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}
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@ -17,16 +17,7 @@ ProviderRs232::ProviderRs232()
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, _bytesWritten(0)
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, _frameDropCounter(0)
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, _lastError(QSerialPort::NoError)
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, _timer()
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{
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// setup timer
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_timer.setSingleShot(false);
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_timer.setInterval(1000);
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connect(&_timer, SIGNAL(timeout()), this, SLOT(rewriteLeds()));
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// start the timer
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_timer.start();
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connect(&_rs232Port, SIGNAL(error(QSerialPort::SerialPortError)), this, SLOT(error(QSerialPort::SerialPortError)));
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connect(&_rs232Port, SIGNAL(bytesWritten(qint64)), this, SLOT(bytesWritten(qint64)));
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connect(&_rs232Port, SIGNAL(readyRead()), this, SLOT(readyRead()));
|
||||
@ -38,7 +29,7 @@ bool ProviderRs232::init(const QJsonObject &deviceConfig)
|
||||
_deviceName = deviceConfig["output"].toString().toStdString();
|
||||
_baudRate_Hz = deviceConfig["rate"].toInt();
|
||||
_delayAfterConnect_ms = deviceConfig["delayAfterConnect"].toInt(250);
|
||||
_timer.setInterval ( deviceConfig["rewriteTime"].toInt(5000) );
|
||||
_refresh_timer.setInterval( deviceConfig["rewriteTime"].toInt(5000) );
|
||||
|
||||
return true;
|
||||
}
|
||||
@ -157,8 +148,6 @@ bool ProviderRs232::tryOpen(const int delayAfterConnect_ms)
|
||||
|
||||
int ProviderRs232::writeBytes(const qint64 size, const uint8_t * data)
|
||||
{
|
||||
// restart the timer
|
||||
_timer.start();
|
||||
if (! _blockedForDelay)
|
||||
{
|
||||
if (!_rs232Port.isOpen())
|
||||
|
@ -46,15 +46,12 @@ protected:
|
||||
* @param[in[ size The length of the data
|
||||
* @param[in] data The data
|
||||
*
|
||||
* @return Zero on succes else negative
|
||||
* @return Zero on success else negative
|
||||
*/
|
||||
int writeBytes(const qint64 size, const uint8_t *data);
|
||||
|
||||
void closeDevice();
|
||||
|
||||
/// The RS232 serial-device
|
||||
QSerialPort _rs232Port;
|
||||
|
||||
private slots:
|
||||
/// Write the last data to the leds again
|
||||
int rewriteLeds();
|
||||
@ -79,7 +76,7 @@ protected:
|
||||
int _delayAfterConnect_ms;
|
||||
|
||||
/// The RS232 serial-device
|
||||
// QSerialPort _rs232Port;
|
||||
QSerialPort _rs232Port;
|
||||
|
||||
bool _blockedForDelay;
|
||||
|
||||
@ -89,9 +86,4 @@ protected:
|
||||
qint64 _bytesWritten;
|
||||
qint64 _frameDropCounter;
|
||||
QSerialPort::SerialPortError _lastError;
|
||||
|
||||
/// Timer object which makes sure that led data is written at a minimum rate
|
||||
/// e.g. Adalight device will switch off when it does not receive data at least
|
||||
/// every 15 seconds
|
||||
QTimer _timer;
|
||||
};
|
||||
|
@ -19,6 +19,13 @@
|
||||
"default": 250,
|
||||
"append" : "ms",
|
||||
"propertyOrder" : 3
|
||||
},
|
||||
"rewriteTime": {
|
||||
"type": "integer",
|
||||
"title":"refresh time",
|
||||
"default": 5000,
|
||||
"append" : "ms",
|
||||
"propertyOrder" : 4
|
||||
}
|
||||
},
|
||||
"additionalProperties": true
|
||||
|
@ -19,6 +19,13 @@
|
||||
"default": 250,
|
||||
"append" : "ms",
|
||||
"propertyOrder" : 3
|
||||
},
|
||||
"rewriteTime": {
|
||||
"type": "integer",
|
||||
"title":"refresh time",
|
||||
"default": 5000,
|
||||
"append" : "ms",
|
||||
"propertyOrder" : 4
|
||||
}
|
||||
},
|
||||
"additionalProperties": true
|
||||
|
@ -19,6 +19,13 @@
|
||||
"default": 250,
|
||||
"append" : "ms",
|
||||
"propertyOrder" : 3
|
||||
},
|
||||
"rewriteTime": {
|
||||
"type": "integer",
|
||||
"title":"refresh time",
|
||||
"default": 5000,
|
||||
"append" : "ms",
|
||||
"propertyOrder" : 4
|
||||
}
|
||||
},
|
||||
"additionalProperties": true
|
||||
|
@ -23,6 +23,13 @@
|
||||
"title":"Delay after connect",
|
||||
"default": 250,
|
||||
"propertyOrder" : 3
|
||||
},
|
||||
"rewriteTime": {
|
||||
"type": "integer",
|
||||
"title":"refresh time",
|
||||
"default": 5000,
|
||||
"append" : "ms",
|
||||
"propertyOrder" : 4
|
||||
}
|
||||
},
|
||||
"additionalProperties": true
|
||||
|
@ -18,6 +18,13 @@
|
||||
"title":"Delay after connect",
|
||||
"default": 250,
|
||||
"propertyOrder" : 3
|
||||
},
|
||||
"rewriteTime": {
|
||||
"type": "integer",
|
||||
"title":"refresh time",
|
||||
"default": 5000,
|
||||
"append" : "ms",
|
||||
"propertyOrder" : 4
|
||||
}
|
||||
},
|
||||
"additionalProperties": true
|
||||
|
@ -18,6 +18,13 @@
|
||||
"title":"Delay after connect",
|
||||
"default": 250,
|
||||
"propertyOrder" : 3
|
||||
},
|
||||
"rewriteTime": {
|
||||
"type": "integer",
|
||||
"title":"refresh time",
|
||||
"default": 5000,
|
||||
"append" : "ms",
|
||||
"propertyOrder" : 4
|
||||
}
|
||||
},
|
||||
"additionalProperties": true
|
||||
|
Loading…
Reference in New Issue
Block a user