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#ifndef __INC_DMX_H
#define __INC_DMX_H
#ifdef DmxSimple_h
#include<DmxSimple.h>
#define HAS_DMX_SIMPLE
// note - dmx simple must be included before FastSPI for this code to be enabled
template <uint8_t DATA_PIN, EOrder RGB_ORDER = RGB> class DMXSimpleController : public CLEDController {
public:
// initialize the LED controller
virtual void init() { DmxSimple.usePin(DATA_PIN); }
// clear out/zero out the given number of leds.
virtual void clearLeds(int nLeds) {
int count = min(nLeds * 3, DMX_SIZE);
for(int iChannel = 1; iChannel <= count; iChannel++) { DmxSimple.write(iChannel, 0); }
}
protected:
// set all the leds on the controller to a given color
virtual void showColor(const struct CRGB & data, int nLeds, CRGB scale) {
int count = min(nLeds, DMX_SIZE / 3);
int iChannel = 1;
for(int i = 0; i < count; i++) {
DmxSimple.write(iChannel++, scale8(data[RGB_BYTE0(RGB_ORDER)], scale.raw[RGB_BYTE0(RGB_ORDER)]));
DmxSimple.write(iChannel++, scale8(data[RGB_BYTE1(RGB_ORDER)], scale.raw[RGB_BYTE1(RGB_ORDER)]));
DmxSimple.write(iChannel++, scale8(data[RGB_BYTE2(RGB_ORDER)], scale.raw[RGB_BYTE2(RGB_ORDER)]));
}
}
// note that the uint8_ts will be in the order that you want them sent out to the device.
// nLeds is the number of RGB leds being written to
virtual void show(const struct CRGB *data, int nLeds, CRGB scale) {
int count = min(nLeds, DMX_SIZE / 3);
int iChannel = 1;
for(int i = 0; i < count; i++) {
DmxSimple.write(iChannel++, scale8(data[i][RGB_BYTE0(RGB_ORDER)], scale.raw[RGB_BYTE0(RGB_ORDER)]));
DmxSimple.write(iChannel++, scale8(data[i][RGB_BYTE1(RGB_ORDER)], scale.raw[RGB_BYTE1(RGB_ORDER)]));
DmxSimple.write(iChannel++, scale8(data[i][RGB_BYTE2(RGB_ORDER)], scale.raw[RGB_BYTE2(RGB_ORDER)]));
}
}
#ifdef SUPPORT_ARGB
// as above, but every 4th uint8_t is assumed to be alpha channel data, and will be skipped
virtual void show(const struct CARGB *data, int nLeds, uint8_t scale = 255) = 0;
#endif
};
#endif
#ifdef DmxSerial_h
#include<DMXSerial.h>
template <EOrder RGB_ORDER = RGB> class DMXSerialController : public CLEDController {
public:
// initialize the LED controller
virtual void init() { DMXSerial.init(DMXController); }
// clear out/zero out the given number of leds.
virtual void clearLeds(int nLeds) {
int count = min(nLeds * 3, DMXSERIAL_MAX);
for(int iChannel = 0; iChannel < count; iChannel++) { DMXSerial.write(iChannel, 0); }
}
// set all the leds on the controller to a given color
virtual void showColor(const struct CRGB & data, int nLeds, CRGB scale) {
int count = min(nLeds, DMXSERIAL_MAX / 3);
int iChannel = 0;
for(int i = 0; i < count; i++) {
DMXSerial.write(iChannel++, scale8(data[RGB_BYTE0(RGB_ORDER)], scale.raw[RGB_BYTE0(RGB_ORDER)]));
DMXSerial.write(iChannel++, scale8(data[RGB_BYTE1(RGB_ORDER)], scale.raw[RGB_BYTE1(RGB_ORDER)]));
DMXSerial.write(iChannel++, scale8(data[RGB_BYTE2(RGB_ORDER)], scale.raw[RGB_BYTE2(RGB_ORDER)]));
}
}
// note that the uint8_ts will be in the order that you want them sent out to the device.
// nLeds is the number of RGB leds being written to
virtual void show(const struct CRGB *data, int nLeds, CRGB scale) {
int count = min(nLeds, DMXSERIAL_MAX / 3);
int iChannel = 0;
for(int i = 0; i < count; i++) {
DMXSerial.write(iChannel++, scale8(data[i][RGB_BYTE0(RGB_ORDER)], scale.raw[RGB_BYTE0(RGB_ORDER)]));
DMXSerial.write(iChannel++, scale8(data[i][RGB_BYTE1(RGB_ORDER)], scale.raw[RGB_BYTE1(RGB_ORDER)]));
DMXSerial.write(iChannel++, scale8(data[i][RGB_BYTE2(RGB_ORDER)], scale.raw[RGB_BYTE2(RGB_ORDER)]));
}
}
#ifdef SUPPORT_ARGB
// as above, but every 4th uint8_t is assumed to be alpha channel data, and will be skipped
virtual void show(const struct CARGB *data, int nLeds, uint8_t scale = 255) = 0;
#endif
};
#define HAS_DMX_SERIAL
#endif
#endif
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