tedsound.cpp - emulators/yapesdl - Rivoreo Source Code Repositories

 #include "sound.h"
 #include "tedmem.h"
 #include "Sid.h"

 #define PRECISION 4
 #define OSCRELOADVAL (0x3FF << PRECISION)

 static int             Volume;
 static int             Snd1Status;
 static int             Snd2Status;
 static int             SndNoiseStatus;
 static int             DAStatus;
 static unsigned short  			  Freq1;
 static unsigned short  			  Freq2;
 static int             NoiseCounter;
 static int             FlipFlop[2];
 static int             oscCount1;
 static int             oscCount2;
 static int             OscReload[2];
 static int             oscStep;
 static unsigned char            noise[256]; // 0-8
 static unsigned int		MixingFreq;

 void ted_sound_init(unsigned int mixingFreq)
 {
 	//oscStep = (int) (( 2.0 * 110860.45 * (double) (1 << PRECISION)) / (double) (mixingFreq));
 	oscStep = (int) (( TED_SOUND_CLOCK * (double) (1 << PRECISION)) / (double) (mixingFreq) + 0.5);
     FlipFlop[0] = 0;
     FlipFlop[1] = 0;
     oscCount1 = 0;
     oscCount2 = 0;
     NoiseCounter = 0;
 	Freq1 = Freq2 = 0;
 	DAStatus = 0;
 	MixingFreq = mixingFreq;

 	/* initialise im with 0xa8 */
 	int im = 0xa8;
     for (int i=0; i<256; i++) {
 		noise[i] = im & 1;
 		im = (im<<1)+(1^((im>>7)&1)^((im>>5)&1)^((im>>4)&1)^((im>>1)&1));
     }
 }

 inline void render_ted_audio(Sint16 *buffer, unsigned int nrsamples)
 {
     // Rendering...
 	// Calculate the buffer...
 	if (DAStatus) {// digi?
 		short sample = 0;
 		if (Snd1Status) sample += Volume;
 		if (Snd2Status) sample += Volume;
 		for (;nrsamples--;) {
 			*buffer++ = sample;
 		}
 	} else {
 		unsigned int result1, result2;
 		for (;nrsamples--;) {
 			// Channel 1
 			if ((oscCount1 += oscStep) >= OSCRELOADVAL) {
 				if (OscReload[0] != (0x3FF << PRECISION))
 					FlipFlop[0] ^= 1;
 				oscCount1 = OscReload[0] + (oscCount1 - OSCRELOADVAL);
 			}
 			// Channel 2
 			if ((oscCount2 += oscStep) >= OSCRELOADVAL) {
 				if (OscReload[1] != (0x3FF << PRECISION)) {
 					FlipFlop[1] ^= 1;
 					if (NoiseCounter++==256)
 						NoiseCounter=0;
 				}
 				oscCount2 = OscReload[1] + (oscCount2 - OSCRELOADVAL);
 			}
 			result1 = (FlipFlop[0] && Snd1Status) ? Volume : 0;
 			if (Snd2Status) {
 				result2 = FlipFlop[1] ? Volume : 0;
 			} else if (SndNoiseStatus) {
 				result2 = noise[NoiseCounter] ? Volume : 0;
 			} else {
 				result2 = 0;
 			}
 			*buffer++ = result1 + result2;
 		}   // for
 	}
 }

 void render_audio(unsigned int nrsamples, short *buffer)
 {
     render_ted_audio(buffer, nrsamples);
     SIDsound *sid = theTed->getSidCard();

     if (sid != NULL) {
         short temp[SAMPLE_FREQ];
         int i = nrsamples - 1;
         //sid->calcSamplesLQ(temp, nrsamples);
 		sid->calcSamples(temp, nrsamples);
         do {
 			buffer[i] += temp[i];
 		} while(i--);
     }
 }

 inline void setFreq(unsigned int channel, int freq)
 {
 	if (freq == 0x3FF) {
 		freq = -1;
 	} else if (freq == 0x3FE) {
 		FlipFlop[channel] = 1;
 	}
 	OscReload[channel] = ((freq + 1)&0x3FF) << PRECISION;
 }

 void writeSoundReg(ClockCycle cycle, unsigned int reg, unsigned char value)
 {
 	flushBuffer(cycle, TED_SOUND_CLOCK);

 	switch (reg) {
 		case 0:
 			Freq1 = (Freq1 & 0x300) | value;
 			setFreq(0, Freq1);
 			break;
 		case 1:
 			Freq2 = (Freq2 & 0x300) | value;
 			setFreq(1, Freq2);
 			break;
 		case 2:
 			Freq2 = (Freq2 & 0xFF) | (value << 8);
 			setFreq(1, Freq2);
 			break;
 		case 3:
 			if ((DAStatus = (value & 0x80))) {
 				FlipFlop[0] = 1;
 				FlipFlop[1] = 1;
 				oscCount1 = OscReload[0];
 				oscCount2 = OscReload[1];
 				NoiseCounter = 0xFF;
 			}
 			Volume = value & 0x0F;
 			if (Volume > 8) Volume = 8;
 			Volume <<= 10;
 			Snd1Status = value & 0x10;
 			Snd2Status = value & 0x20;
 			SndNoiseStatus = value & 0x40;
 			break;
 		case 4:
 			Freq1 = (Freq1 & 0xFF) | (value << 8);
 			setFreq(0, Freq1);
 			break;
 	}
 }
	#include "sound.h"
	#include "tedmem.h"
	#include "Sid.h"

	#define PRECISION 4
	#define OSCRELOADVAL (0x3FF << PRECISION)

	static int Volume;
	static int Snd1Status;
	static int Snd2Status;
	static int SndNoiseStatus;
	static int DAStatus;
	static unsigned short Freq1;
	static unsigned short Freq2;
	static int NoiseCounter;
	static int FlipFlop[2];
	static int oscCount1;
	static int oscCount2;
	static int OscReload[2];
	static int oscStep;
	static unsigned char noise[256]; // 0-8
	static unsigned int MixingFreq;

	void ted_sound_init(unsigned int mixingFreq)
	{
	//oscStep = (int) (( 2.0 * 110860.45 * (double) (1 << PRECISION)) / (double) (mixingFreq));
	oscStep = (int) (( TED_SOUND_CLOCK * (double) (1 << PRECISION)) / (double) (mixingFreq) + 0.5);
	FlipFlop[0] = 0;
	FlipFlop[1] = 0;
	oscCount1 = 0;
	oscCount2 = 0;
	NoiseCounter = 0;
	Freq1 = Freq2 = 0;
	DAStatus = 0;
	MixingFreq = mixingFreq;

	/* initialise im with 0xa8 */
	int im = 0xa8;
	for (int i=0; i<256; i++) {
	noise[i] = im & 1;
	im = (im<<1)+(1^((im>>7)&1)^((im>>5)&1)^((im>>4)&1)^((im>>1)&1));
	}
	}

	inline void render_ted_audio(Sint16 *buffer, unsigned int nrsamples)
	{
	// Rendering...
	// Calculate the buffer...
	if (DAStatus) {// digi?
	short sample = 0;
	if (Snd1Status) sample += Volume;
	if (Snd2Status) sample += Volume;
	for (;nrsamples--;) {
	*buffer++ = sample;
	}
	} else {
	unsigned int result1, result2;
	for (;nrsamples--;) {
	// Channel 1
	if ((oscCount1 += oscStep) >= OSCRELOADVAL) {
	if (OscReload[0] != (0x3FF << PRECISION))
	FlipFlop[0] ^= 1;
	oscCount1 = OscReload[0] + (oscCount1 - OSCRELOADVAL);
	}
	// Channel 2
	if ((oscCount2 += oscStep) >= OSCRELOADVAL) {
	if (OscReload[1] != (0x3FF << PRECISION)) {
	FlipFlop[1] ^= 1;
	if (NoiseCounter++==256)
	NoiseCounter=0;
	}
	oscCount2 = OscReload[1] + (oscCount2 - OSCRELOADVAL);
	}
	result1 = (FlipFlop[0] && Snd1Status) ? Volume : 0;
	if (Snd2Status) {
	result2 = FlipFlop[1] ? Volume : 0;
	} else if (SndNoiseStatus) {
	result2 = noise[NoiseCounter] ? Volume : 0;
	} else {
	result2 = 0;
	}
	*buffer++ = result1 + result2;
	} // for
	}
	}

	void render_audio(unsigned int nrsamples, short *buffer)
	{
	render_ted_audio(buffer, nrsamples);
	SIDsound *sid = theTed->getSidCard();

	if (sid != NULL) {
	short temp[SAMPLE_FREQ];
	int i = nrsamples - 1;
	//sid->calcSamplesLQ(temp, nrsamples);
	sid->calcSamples(temp, nrsamples);
	do {
	buffer[i] += temp[i];
	} while(i--);
	}
	}

	inline void setFreq(unsigned int channel, int freq)
	{
	if (freq == 0x3FF) {
	freq = -1;
	} else if (freq == 0x3FE) {
	FlipFlop[channel] = 1;
	}
	OscReload[channel] = ((freq + 1)&0x3FF) << PRECISION;
	}

	void writeSoundReg(ClockCycle cycle, unsigned int reg, unsigned char value)
	{
	flushBuffer(cycle, TED_SOUND_CLOCK);

	switch (reg) {
	case 0:
	Freq1 = (Freq1 & 0x300) \| value;
	setFreq(0, Freq1);
	break;
	case 1:
	Freq2 = (Freq2 & 0x300) \| value;
	setFreq(1, Freq2);
	break;
	case 2:
	Freq2 = (Freq2 & 0xFF) \| (value << 8);
	setFreq(1, Freq2);
	break;
	case 3:
	if ((DAStatus = (value & 0x80))) {
	FlipFlop[0] = 1;
	FlipFlop[1] = 1;
	oscCount1 = OscReload[0];
	oscCount2 = OscReload[1];
	NoiseCounter = 0xFF;
	}
	Volume = value & 0x0F;
	if (Volume > 8) Volume = 8;
	Volume <<= 10;
	Snd1Status = value & 0x10;
	Snd2Status = value & 0x20;
	SndNoiseStatus = value & 0x40;
	break;
	case 4:
	Freq1 = (Freq1 & 0xFF) \| (value << 8);
	setFreq(0, Freq1);
	break;
	}
	}