FastLED.cpp

#define FASTLED_INTERNAL
#include "FastLED.h"


#if defined(__SAM3X8E__)
volatile uint32_t fuckit;
#endif

FASTLED_NAMESPACE_BEGIN

void *pSmartMatrix = NULL;

CFastLED FastLED;

CLEDController *CLEDController::m_pHead = NULL;
CLEDController *CLEDController::m_pTail = NULL;
static uint32_t lastshow = 0;

// uint32_t CRGB::Squant = ((uint32_t)((__TIME__[4]-'0') * 28))<<16 | ((__TIME__[6]-'0')*50)<<8 | ((__TIME__[7]-'0')*28);

CFastLED::CFastLED() {
	// clear out the array of led controllers
	// m_nControllers = 0;
	m_Scale = 255;
	m_nFPS = 0;
	m_pPowerFunc = NULL;
	m_nPowerData = 0xFFFFFFFF;
}

CLEDController &CFastLED::addLeds(CLEDController *pLed,
									   struct CRGB *data,
									   int nLedsOrOffset, int nLedsIfOffset) {
	int nOffset = (nLedsIfOffset > 0) ? nLedsOrOffset : 0;
	int nLeds = (nLedsIfOffset > 0) ? nLedsIfOffset : nLedsOrOffset;

	pLed->init();
	pLed->setLeds(data + nOffset, nLeds);
	FastLED.setMaxRefreshRate(pLed->getMaxRefreshRate(),true);
	return *pLed;
}

void CFastLED::show(uint8_t scale) {
	// guard against showing too rapidly
	while(m_nMinMicros && ((micros()-lastshow) < m_nMinMicros));
	lastshow = micros();

	// If we have a function for computing power, use it!
	if(m_pPowerFunc) {
		scale = (*m_pPowerFunc)(scale, m_nPowerData);
	}

	CLEDController *pCur = CLEDController::head();
	while(pCur) {
		uint8_t d = pCur->getDither();
		if(m_nFPS < 100) { pCur->setDither(0); }
		pCur->showLeds(scale);
		pCur->setDither(d);
		pCur = pCur->next();
	}
	countFPS();
}

int CFastLED::count() {
    int x = 0;
	CLEDController *pCur = CLEDController::head();
	while( pCur) {
        x++;
		pCur = pCur->next();
	}
    return x;
}

CLEDController & CFastLED::operator[](int x) {
	CLEDController *pCur = CLEDController::head();
	while(x-- && pCur) {
		pCur = pCur->next();
	}
	if(pCur == NULL) {
		return *(CLEDController::head());
	} else {
		return *pCur;
	}
}

void CFastLED::showColor(const struct CRGB & color, uint8_t scale) {
	while(m_nMinMicros && ((micros()-lastshow) < m_nMinMicros));
	lastshow = micros();

	CLEDController *pCur = CLEDController::head();
	while(pCur) {
		uint8_t d = pCur->getDither();
		if(m_nFPS < 100) { pCur->setDither(0); }
		pCur->showColor(color, scale);
		pCur->setDither(d);
		pCur = pCur->next();
	}
	countFPS();
}

void CFastLED::clear(boolean writeData) {
	if(writeData) {
		showColor(CRGB(0,0,0), 0);
	}
    clearData();
}

void CFastLED::clearData() {
	CLEDController *pCur = CLEDController::head();
	while(pCur) {
		pCur->clearLedData();
		pCur = pCur->next();
	}
}

void CFastLED::delay(unsigned long ms) {
	unsigned long start = millis();
	while((millis()-start) < ms) {
#ifndef FASTLED_ACCURATE_CLOCK
		// make sure to allow at least one ms to pass to ensure the clock moves
		// forward
		::delay(1);
#endif
		show();
	}
}

void CFastLED::setTemperature(const struct CRGB & temp) {
	CLEDController *pCur = CLEDController::head();
	while(pCur) {
		pCur->setTemperature(temp);
		pCur = pCur->next();
	}
}

void CFastLED::setCorrection(const struct CRGB & correction) {
	CLEDController *pCur = CLEDController::head();
	while(pCur) {
		pCur->setCorrection(correction);
		pCur = pCur->next();
	}
}

void CFastLED::setDither(uint8_t ditherMode)  {
	CLEDController *pCur = CLEDController::head();
	while(pCur) {
		pCur->setDither(ditherMode);
		pCur = pCur->next();
	}
}

//
// template<int m, int n> void transpose8(unsigned char A[8], unsigned char B[8]) {
// 	uint32_t x, y, t;
//
// 	// Load the array and pack it into x and y.
//   	y = *(unsigned int*)(A);
// 	x = *(unsigned int*)(A+4);
//
// 	// x = (A[0]<<24)   | (A[m]<<16)   | (A[2*m]<<8) | A[3*m];
// 	// y = (A[4*m]<<24) | (A[5*m]<<16) | (A[6*m]<<8) | A[7*m];
//
        // // pre-transform x
        // t = (x ^ (x >> 7)) & 0x00AA00AA;  x = x ^ t ^ (t << 7);
        // t = (x ^ (x >>14)) & 0x0000CCCC;  x = x ^ t ^ (t <<14);
				//
        // // pre-transform y
        // t = (y ^ (y >> 7)) & 0x00AA00AA;  y = y ^ t ^ (t << 7);
        // t = (y ^ (y >>14)) & 0x0000CCCC;  y = y ^ t ^ (t <<14);
				//
        // // final transform
        // t = (x & 0xF0F0F0F0) | ((y >> 4) & 0x0F0F0F0F);
        // y = ((x << 4) & 0xF0F0F0F0) | (y & 0x0F0F0F0F);
        // x = t;
//
// 	B[7*n] = y; y >>= 8;
// 	B[6*n] = y; y >>= 8;
// 	B[5*n] = y; y >>= 8;
// 	B[4*n] = y;
//
//   B[3*n] = x; x >>= 8;
// 	B[2*n] = x; x >>= 8;
// 	B[n] = x; x >>= 8;
// 	B[0] = x;
// 	// B[0]=x>>24;    B[n]=x>>16;    B[2*n]=x>>8;  B[3*n]=x>>0;
// 	// B[4*n]=y>>24;  B[5*n]=y>>16;  B[6*n]=y>>8;  B[7*n]=y>>0;
// }
//
// void transposeLines(Lines & out, Lines & in) {
// 	transpose8<1,2>(in.bytes, out.bytes);
// 	transpose8<1,2>(in.bytes + 8, out.bytes + 1);
// }

extern int noise_min;
extern int noise_max;

void CFastLED::countFPS(int nFrames) {
  static int br = 0;
  static uint32_t lastframe = 0; // millis();

  if(br++ >= nFrames) {
		uint32_t now = millis();
		now -= lastframe;
		m_nFPS = (br * 1000) / now;
    br = 0;
    lastframe = millis();
  }
}

void CFastLED::setMaxRefreshRate(uint16_t refresh, bool constrain) {
  if(constrain) {
    // if we're constraining, the new value of m_nMinMicros _must_ be higher than previously (because we're only
    // allowed to slow things down if constraining)
    if(refresh > 0) {
      m_nMinMicros = ( (1000000/refresh) >  m_nMinMicros) ? (1000000/refresh) : m_nMinMicros;
    }
  } else if(refresh > 0) {
    m_nMinMicros = 1000000 / refresh;
  } else {
    m_nMinMicros = 0;
  }
}

extern "C" int atexit(void (* /*func*/ )()) { return 0; }

#ifdef NEED_CXX_BITS
namespace __cxxabiv1
{
	extern "C" void __cxa_pure_virtual (void) {}
	/* guard variables */

	/* The ABI requires a 64-bit type.  */
	__extension__ typedef int __guard __attribute__((mode(__DI__)));

	extern "C" int __cxa_guard_acquire (__guard *);
	extern "C" void __cxa_guard_release (__guard *);
	extern "C" void __cxa_guard_abort (__guard *);

	extern "C" int __cxa_guard_acquire (__guard *g)
	{
		return !*(char *)(g);
	}

	extern "C" void __cxa_guard_release (__guard *g)
	{
		*(char *)g = 1;
	}

	extern "C" void __cxa_guard_abort (__guard *)
	{

	}
}
#endif

FASTLED_NAMESPACE_END