#if (defined(WIN32) && !defined(SDL))

 #   include "../win32/stdafx.h"

 #   include "../win32/VBA.h"

 #endif

 

 #include <cstring>

 #include <cassert>

 

 #include "GBASound.h"

 #include "../common/System.h" // SDL build needs this

 #include "../common/Util.h"

 #include "GBA.h"

 #include "GBAGlobals.h"

 

 #ifndef countof

 #define countof(a)  (sizeof(a) / sizeof(a[0]))

 #endif

 

 soundtick_t USE_TICKS_AS = 380; // (16777216.0/44100.0); // FIXME: (16777216.0/280896.0)(fps) vs 60.0fps?

 

 #define SOUND_MAGIC   0x60000000

 #define SOUND_MAGIC_2 0x30000000

 #define NOISE_MAGIC (2097152.0 / 44100.0)

 

 extern bool8 stopState;

 

 u8 soundWavePattern[4][32] = {

 	{ 0x01, 0x01, 0x01, 0x01,

 	  0xff, 0xff, 0xff, 0xff,

 	  0xff, 0xff, 0xff, 0xff,

 	  0xff, 0xff, 0xff, 0xff,

 	  0xff, 0xff, 0xff, 0xff,

 	  0xff, 0xff, 0xff, 0xff,

 	  0xff, 0xff, 0xff, 0xff,

 	  0xff, 0xff, 0xff, 0xff },

 	{ 0x01, 0x01, 0x01, 0x01,

 	  0x01, 0x01, 0x01, 0x01,

 	  0xff, 0xff, 0xff, 0xff,

 	  0xff, 0xff, 0xff, 0xff,

 	  0xff, 0xff, 0xff, 0xff,

 	  0xff, 0xff, 0xff, 0xff,

 	  0xff, 0xff, 0xff, 0xff,

 	  0xff, 0xff, 0xff, 0xff },

 	{ 0x01, 0x01, 0x01, 0x01,

 	  0x01, 0x01, 0x01, 0x01,

 	  0x01, 0x01, 0x01, 0x01,

 	  0x01, 0x01, 0x01, 0x01,

 	  0xff, 0xff, 0xff, 0xff,

 	  0xff, 0xff, 0xff, 0xff,

 	  0xff, 0xff, 0xff, 0xff,

 	  0xff, 0xff, 0xff, 0xff },

 	{ 0x01, 0x01, 0x01, 0x01,

 	  0x01, 0x01, 0x01, 0x01,

 	  0x01, 0x01, 0x01, 0x01,

 	  0x01, 0x01, 0x01, 0x01,

 	  0x01, 0x01, 0x01, 0x01,

 	  0x01, 0x01, 0x01, 0x01,

 	  0xff, 0xff, 0xff, 0xff,

 	  0xff, 0xff, 0xff, 0xff }

 };

 

 int32 soundFreqRatio[8] = {

 	1048576, // 0

 	524288, // 1

 	262144, // 2

 	174763, // 3

 	131072, // 4

 	104858, // 5

 	87381, // 6

 	74898  // 7

 };

 

 int32 soundShiftClock[16] = {

 	2,   // 0

 	4,   // 1

 	8,   // 2

 	16,  // 3

 	32,  // 4

 	64,  // 5

 	128, // 6

 	256, // 7

 	512, // 8

 	1024, // 9

 	2048, // 10

 	4096, // 11

 	8192, // 12

 	16384, // 13

 	1,   // 14

 	1    // 15

 };

 

 int32 soundVolume = 0;

 

 u8	soundBuffer[6][735];

 u16 soundFinalWave[1470];

 u16 soundFrameSound[735 * 30 * 2]; // for avi logging

 

 u32			soundBufferLen		= 1470;

 u32			soundBufferTotalLen = 14700;

 int32		soundQuality		= 2;

 int32		soundPaused			= 1;

 int32		soundPlay			= 0;

 soundtick_t soundTicks			= soundQuality * USE_TICKS_AS;

 soundtick_t SOUND_CLOCK_TICKS	= soundQuality * USE_TICKS_AS;

 u32			soundNextPosition	= 0;

 

 int32 soundLevel1 = 0;

 int32 soundLevel2 = 0;

 int32 soundBalance = 0;

 int32 soundMasterOn = 0;

 u32	  soundIndex = 0;

 u32	  soundBufferIndex		 = 0;

 int32 soundFrameSoundWritten = 0;

 int32 soundDebug			 = 0;

 bool8 soundOffFlag			 = false;

 

 int32 sound1On = 0;

 int32 sound1ATL = 0;

 int32 sound1Skip = 0;

 int32 sound1Index = 0;

 int32 sound1Continue = 0;

 int32 sound1EnvelopeVolume	  = 0;

 int32 sound1EnvelopeATL		  = 0;

 int32 sound1EnvelopeUpDown	  = 0;

 int32 sound1EnvelopeATLReload = 0;

 int32 sound1SweepATL		  = 0;

 int32 sound1SweepATLReload	  = 0;

 int32 sound1SweepSteps		  = 0;

 int32 sound1SweepUpDown		  = 0;

 int32 sound1SweepStep		  = 0;

 u8 *  sound1Wave			  = soundWavePattern[2];

 

 int32 sound2On = 0;

 int32 sound2ATL = 0;

 int32 sound2Skip = 0;

 int32 sound2Index = 0;

 int32 sound2Continue = 0;

 int32 sound2EnvelopeVolume	  = 0;

 int32 sound2EnvelopeATL		  = 0;

 int32 sound2EnvelopeUpDown	  = 0;

 int32 sound2EnvelopeATLReload = 0;

 u8 *  sound2Wave			  = soundWavePattern[2];

 

 int32 sound3On = 0;

 int32 sound3ATL			= 0;

 int32 sound3Skip		= 0;

 int32 sound3Index		= 0;

 int32 sound3Continue	= 0;

 int32 sound3OutputLevel = 0;

 int32 sound3Last		= 0;

 u8	  sound3WaveRam[0x20];

 int32 sound3Bank		 = 0;

 int32 sound3DataSize	 = 0;

 int32 sound3ForcedOutput = 0;

 

 int32 sound4On = 0;

 int32 sound4Clock = 0;

 int32 sound4ATL = 0;

 int32 sound4Skip = 0;

 int32 sound4Index = 0;

 int32 sound4ShiftRight		  = 0x7f;

 int32 sound4ShiftSkip		  = 0;

 int32 sound4ShiftIndex		  = 0;

 int32 sound4NSteps			  = 0;

 int32 sound4CountDown		  = 0;

 int32 sound4Continue		  = 0;

 int32 sound4EnvelopeVolume	  = 0;

 int32 sound4EnvelopeATL		  = 0;

 int32 sound4EnvelopeUpDown	  = 0;

 int32 sound4EnvelopeATLReload = 0;

 

 int32 soundControl = 0;

 

 int32 soundDSFifoAIndex		 = 0;

 int32 soundDSFifoACount		 = 0;

 int32 soundDSFifoAWriteIndex = 0;

 bool8 soundDSAEnabled		 = false;

 int32 soundDSATimer = 0;

 u8	  soundDSFifoA[32];

 u8	  soundDSAValue = 0;

 

 int32 soundDSFifoBIndex		 = 0;

 int32 soundDSFifoBCount		 = 0;

 int32 soundDSFifoBWriteIndex = 0;

 bool8 soundDSBEnabled		 = false;

 int32 soundDSBTimer = 0;

 u8	  soundDSFifoB[32];

 u8	  soundDSBValue = 0;

 

 int32 soundEnableFlag = 0x3ff;

 int32 soundMutedFlag  = 0;

 

 s16	  soundFilter[4000];

 s16	  soundRight[5] = { 0, 0, 0, 0, 0 };

 s16	  soundLeft[5] = { 0, 0, 0, 0, 0 };

 int32 soundEchoIndex = 0;

 bool8 soundEcho		 = false;

 bool8 soundLowPass	 = false;

 bool8 soundReverse	 = false;

 

 static int32  soundTicks_int32;

 static int32  SOUND_CLOCK_TICKS_int32;

 static int32  soundDSBValue_int32;

 variable_desc soundSaveStruct[] = {

 	{ &soundPaused,				sizeof(int32)					  },

 	{ &soundPlay,				sizeof(int32)					  },

 	{ &soundTicks_int32,		sizeof(int32)					  },

 	{ &SOUND_CLOCK_TICKS_int32, sizeof(int32)					  },

 	{ &soundLevel1,				sizeof(int32)					  },

 	{ &soundLevel2,				sizeof(int32)					  },

 	{ &soundBalance,			sizeof(int32)					  },

 	{ &soundMasterOn,			sizeof(int32)					  },

 	{ &soundIndex,				sizeof(int32)					  },

 	{ &sound1On,				sizeof(int32)					  },

 	{ &sound1ATL,				sizeof(int32)					  },

 	{ &sound1Skip,				sizeof(int32)					  },

 	{ &sound1Index,				sizeof(int32)					  },

 	{ &sound1Continue,			sizeof(int32)					  },

 	{ &sound1EnvelopeVolume,	sizeof(int32)					  },

 	{ &sound1EnvelopeATL,		sizeof(int32)					  },

 	{ &sound1EnvelopeATLReload, sizeof(int32)					  },

 	{ &sound1EnvelopeUpDown,	sizeof(int32)					  },

 	{ &sound1SweepATL,			sizeof(int32)					  },

 	{ &sound1SweepATLReload,	sizeof(int32)					  },

 	{ &sound1SweepSteps,		sizeof(int32)					  },

 	{ &sound1SweepUpDown,		sizeof(int32)					  },

 	{ &sound1SweepStep,			sizeof(int32)					  },

 	{ &sound2On,				sizeof(int32)					  },

 	{ &sound2ATL,				sizeof(int32)					  },

 	{ &sound2Skip,				sizeof(int32)					  },

 	{ &sound2Index,				sizeof(int32)					  },

 	{ &sound2Continue,			sizeof(int32)					  },

 	{ &sound2EnvelopeVolume,	sizeof(int32)					  },

 	{ &sound2EnvelopeATL,		sizeof(int32)					  },

 	{ &sound2EnvelopeATLReload, sizeof(int32)					  },

 	{ &sound2EnvelopeUpDown,	sizeof(int32)					  },

 	{ &sound3On,				sizeof(int32)					  },

 	{ &sound3ATL,				sizeof(int32)					  },

 	{ &sound3Skip,				sizeof(int32)					  },

 	{ &sound3Index,				sizeof(int32)					  },

 	{ &sound3Continue,			sizeof(int32)					  },

 	{ &sound3OutputLevel,		sizeof(int32)					  },

 	{ &sound4On,				sizeof(int32)					  },

 	{ &sound4ATL,				sizeof(int32)					  },

 	{ &sound4Skip,				sizeof(int32)					  },

 	{ &sound4Index,				sizeof(int32)					  },

 	{ &sound4Clock,				sizeof(int32)					  },

 	{ &sound4ShiftRight,		sizeof(int32)					  },

 	{ &sound4ShiftSkip,			sizeof(int32)					  },

 	{ &sound4ShiftIndex,		sizeof(int32)					  },

 	{ &sound4NSteps,			sizeof(int32)					  },

 	{ &sound4CountDown,			sizeof(int32)					  },

 	{ &sound4Continue,			sizeof(int32)					  },

 	{ &sound4EnvelopeVolume,	sizeof(int32)					  },

 	{ &sound4EnvelopeATL,		sizeof(int32)					  },

 	{ &sound4EnvelopeATLReload, sizeof(int32)					  },

 	{ &sound4EnvelopeUpDown,	sizeof(int32)					  },

 	{ &soundEnableFlag,			sizeof(int32)					  },

 	{ &soundControl,			sizeof(int32)					  },

 	{ &soundDSFifoAIndex,		sizeof(int32)					  },

 	{ &soundDSFifoACount,		sizeof(int32)					  },

 	{ &soundDSFifoAWriteIndex,	sizeof(int32)					  },

 	{ &soundDSAEnabled,			sizeof(bool8)					  },

 	{ &soundDSATimer,			sizeof(int32)					  },

 	{ &soundDSFifoA[0],			32								  },

 	{ &soundDSAValue,			sizeof(u8)						  },

 	{ &soundDSFifoBIndex,		sizeof(int32)					  },

 	{ &soundDSFifoBCount,		sizeof(int32)					  },

 	{ &soundDSFifoBWriteIndex,	sizeof(int32)					  },

 	{ &soundDSBEnabled,			sizeof(int32)					  },

 	{ &soundDSBTimer,			sizeof(int32)					  },

 	{ &soundDSFifoB[0],			32								  },

 	{ &soundDSBValue_int32,		sizeof(int32)					  }, // save as int32 because of a mistake of the past.

 	{ &soundBuffer[0][0],		6 * 735							  },

 	{ &soundFinalWave[0],		2 * 735							  },

 	{ NULL,						0								  }

 };

 

 variable_desc soundSaveStructV2[] = {

 	{ &sound3WaveRam[0],   0x20							},

 	{ &sound3Bank,		   sizeof(int32)				},

 	{ &sound3DataSize,	   sizeof(int32)				},

 	{ &sound3ForcedOutput, sizeof(int32)				},

 	{ NULL,				   0							}

 };

 

 //variable_desc soundSaveStructV3[] = {

 //  { &soundTicks, sizeof(soundtick_t) },

 //  { &SOUND_CLOCK_TICKS, sizeof(soundtick_t) },

 //  { &USE_TICKS_AS, sizeof(soundtick_t) },

 //  { NULL, 0 }

 //};

 

 void soundEvent(u32 address, u8 data)

 {

 	int freq = 0;

 

 	switch (address)

 	{

 	case NR10:

 		data &= 0x7f;

 		sound1SweepATL	  = sound1SweepATLReload = 344 * ((data >> 4) & 7);

 		sound1SweepSteps  = data & 7;

 		sound1SweepUpDown = data & 0x08;

 		sound1SweepStep	  = 0;

 		ioMem[address]	  = data;

 		break;

 	case NR11:

 		sound1Wave	   = soundWavePattern[data >> 6];

 		sound1ATL	   = 172 * (64 - (data & 0x3f));

 		ioMem[address] = data;

 		break;

 	case NR12:

 		sound1EnvelopeUpDown	= data & 0x08;

 		sound1EnvelopeATLReload = 689 * (data & 7);

 		if ((data & 0xF8) == 0)

 			sound1EnvelopeVolume = 0;

 		ioMem[address] = data;

 		break;

 	case NR13:

 		freq	  = (((int)(ioMem[NR14] & 7)) << 8) | data;

 		sound1ATL = 172 * (64 - (ioMem[NR11] & 0x3f));

 		freq	  = 2048 - freq;

 		if (freq)

 		{

 			sound1Skip = SOUND_MAGIC / freq;

 		}

 		else

 			sound1Skip = 0;

 		ioMem[address] = data;

 		break;

 	case NR14:

 		data &= 0xC7;

 		freq = (((int)(data & 7) << 8) | ioMem[NR13]);

 		freq = 2048 - freq;

 		sound1ATL	   = 172 * (64 - (ioMem[NR11] & 0x3f));

 		sound1Continue = data & 0x40;

 		if (freq)

 		{

 			sound1Skip = SOUND_MAGIC / freq;

 		}

 		else

 			sound1Skip = 0;

 		if (data & 0x80)

 		{

 			ioMem[NR52] |= 1;

 			sound1EnvelopeVolume = ioMem[NR12] >> 4;

 			sound1EnvelopeUpDown = ioMem[NR12] & 0x08;

 			sound1ATL = 172 * (64 - (ioMem[NR11] & 0x3f));

 			sound1EnvelopeATLReload = sound1EnvelopeATL = 689 * (ioMem[NR12] & 7);

 			sound1SweepATL			= sound1SweepATLReload = 344 * ((ioMem[NR10] >> 4) & 7);

 			sound1SweepSteps		= ioMem[NR10] & 7;

 			sound1SweepUpDown		= ioMem[NR10] & 0x08;

 			sound1SweepStep			= 0;

 

 			sound1Index = 0;

 			sound1On	= 1;

 		}

 		ioMem[address] = data;

 		break;

 	case NR21:

 		sound2Wave	   = soundWavePattern[data >> 6];

 		sound2ATL	   = 172 * (64 - (data & 0x3f));

 		ioMem[address] = data;

 		break;

 	case NR22:

 		sound2EnvelopeUpDown	= data & 0x08;

 		sound2EnvelopeATLReload = 689 * (data & 7);

 		if ((data & 0xF8) == 0)

 			sound2EnvelopeVolume = 0;

 		ioMem[address] = data;

 		break;

 	case NR23:

 		freq	  = (((int)(ioMem[NR24] & 7)) << 8) | data;

 		sound2ATL = 172 * (64 - (ioMem[NR21] & 0x3f));

 		freq	  = 2048 - freq;

 		if (freq)

 		{

 			sound2Skip = SOUND_MAGIC / freq;

 		}

 		else

 			sound2Skip = 0;

 		ioMem[address] = data;

 		break;

 	case NR24:

 		data &= 0xC7;

 		freq = (((int)(data & 7) << 8) | ioMem[NR23]);

 		freq = 2048 - freq;

 		sound2ATL	   = 172 * (64 - (ioMem[NR21] & 0x3f));

 		sound2Continue = data & 0x40;

 		if (freq)

 		{

 			sound2Skip = SOUND_MAGIC / freq;

 		}

 		else

 			sound2Skip = 0;

 		if (data & 0x80)

 		{

 			ioMem[NR52] |= 2;

 			sound2EnvelopeVolume = ioMem[NR22] >> 4;

 			sound2EnvelopeUpDown = ioMem[NR22] & 0x08;

 			sound2ATL = 172 * (64 - (ioMem[NR21] & 0x3f));

 			sound2EnvelopeATLReload = sound2EnvelopeATL = 689 * (ioMem[NR22] & 7);

 

 			sound2Index = 0;

 			sound2On	= 1;

 		}

 		ioMem[address] = data;

 		break;

 	case NR30:

 		data &= 0xe0;

 		if (!(data & 0x80))

 		{

 			ioMem[NR52] &= 0xfb;

 			sound3On	 = 0;

 		}

 		if (((data >> 6) & 1) != sound3Bank)

 			memcpy(&ioMem[0x90], &sound3WaveRam[(((data >> 6) & 1) * 0x10) ^ 0x10],

 			       0x10);

 		sound3Bank	   = (data >> 6) & 1;

 		sound3DataSize = (data >> 5) & 1;

 		ioMem[address] = data;

 		break;

 	case NR31:

 		sound3ATL	   = 172 * (256 - data);

 		ioMem[address] = data;

 		break;

 	case NR32:

 		data &= 0xe0;

 		sound3OutputLevel  = (data >> 5) & 3;

 		sound3ForcedOutput = (data >> 7) & 1;

 		ioMem[address]	   = data;

 		break;

 	case NR33:

 		freq = 2048 - (((int)(ioMem[NR34] & 7) << 8) | data);

 		if (freq)

 		{

 			sound3Skip = SOUND_MAGIC_2 / freq;

 		}

 		else

 			sound3Skip = 0;

 		ioMem[address] = data;

 		break;

 	case NR34:

 		data &= 0xc7;

 		freq  = 2048 - (((data & 7) << 8) | (int)ioMem[NR33]);

 		if (freq)

 		{

 			sound3Skip = SOUND_MAGIC_2 / freq;

 		}

 		else

 		{

 			sound3Skip = 0;

 		}

 		sound3Continue = data & 0x40;

 		if ((data & 0x80) && (ioMem[NR30] & 0x80))

 		{

 			ioMem[NR52] |= 4;

 			sound3ATL	 = 172 * (256 - ioMem[NR31]);

 			sound3Index	 = 0;

 			sound3On	 = 1;

 		}

 		ioMem[address] = data;

 		break;

 	case NR41:

 		data &= 0x3f;

 		sound4ATL	   = 172 * (64 - (data & 0x3f));

 		ioMem[address] = data;

 		break;

 	case NR42:

 		sound4EnvelopeUpDown	= data & 0x08;

 		sound4EnvelopeATLReload = 689 * (data & 7);

 		if ((data & 0xF8) == 0)

 			sound4EnvelopeVolume = 0;

 		ioMem[address] = data;

 		break;

 	case NR43:

 		freq		 = soundFreqRatio[data & 7];

 		sound4NSteps = data & 0x08;

 

 		sound4Skip = freq * NOISE_MAGIC;

 

 		sound4Clock = data >> 4;

 

 		freq = freq / soundShiftClock[sound4Clock];

 

 		sound4ShiftSkip = freq * NOISE_MAGIC;

 		ioMem[address]	= data;

 		break;

 	case NR44:

 		data &= 0xc0;

 		sound4Continue = data & 0x40;

 		if (data & 0x80)

 		{

 			ioMem[NR52] |= 8;

 			sound4EnvelopeVolume = ioMem[NR42] >> 4;

 			sound4EnvelopeUpDown = ioMem[NR42] & 0x08;

 			sound4ATL = 172 * (64 - (ioMem[NR41] & 0x3f));

 			sound4EnvelopeATLReload = sound4EnvelopeATL = 689 * (ioMem[NR42] & 7);

 

 			sound4On = 1;

 

 			sound4Index		 = 0;

 			sound4ShiftIndex = 0;

 

 			freq = soundFreqRatio[ioMem[NR43] & 7];

 

 			sound4Skip = freq * NOISE_MAGIC;

 

 			sound4NSteps = ioMem[NR43] & 0x08;

 

 			freq = freq / soundShiftClock[ioMem[NR43] >> 4];

 

 			sound4ShiftSkip = freq * NOISE_MAGIC;

 			if (sound4NSteps)

 				sound4ShiftRight = 0x7f;

 			else

 				sound4ShiftRight = 0x7fff;

 		}

 		ioMem[address] = data;

 		break;

 	case NR50:

 		data &= 0x77;

 		soundLevel1	   = data & 7;

 		soundLevel2	   = (data >> 4) & 7;

 		ioMem[address] = data;

 		break;

 	case NR51:

 		soundBalance   = (data & soundEnableFlag);

 		ioMem[address] = data;

 		break;

 	case NR52:

 		data &= 0x80;

 		data |= ioMem[NR52] & 15;

 		soundMasterOn = data & 0x80;

 		if (!(data & 0x80))

 		{

 			sound1On = 0;

 			sound2On = 0;

 			sound3On = 0;

 			sound4On = 0;

 		}

 		ioMem[address] = data;

 		break;

 	case 0x90:

 	case 0x91:

 	case 0x92:

 	case 0x93:

 	case 0x94:

 	case 0x95:

 	case 0x96:

 	case 0x97:

 	case 0x98:

 	case 0x99:

 	case 0x9a:

 	case 0x9b:

 	case 0x9c:

 	case 0x9d:

 	case 0x9e:

 	case 0x9f:

 		sound3WaveRam[(sound3Bank * 0x10) ^ 0x10 + (address & 15)] = data;

 		break;

 	}

 }

 

 void soundEvent(u32 address, u16 data)

 {

 	switch (address)

 	{

 	case SGCNT0_H:

 		data		&= 0xFF0F;

 		soundControl = data & 0x770F;;

 		if (data & 0x0800)

 		{

 			soundDSFifoAWriteIndex = 0;

 			soundDSFifoAIndex	   = 0;

 			soundDSFifoACount	   = 0;

 			soundDSAValue = 0;

 			memset(soundDSFifoA, 0, 32);

 		}

 		soundDSAEnabled = (data & 0x0300) ? true : false;

 		soundDSATimer	= (data & 0x0400) ? 1 : 0;

 		if (data & 0x8000)

 		{

 			soundDSFifoBWriteIndex = 0;

 			soundDSFifoBIndex	   = 0;

 			soundDSFifoBCount	   = 0;

 			soundDSBValue = 0;

 			memset(soundDSFifoB, 0, 32);

 		}

 		soundDSBEnabled = (data & 0x3000) ? true : false;

 		soundDSBTimer	= (data & 0x4000) ? 1 : 0;

 		*((u16 *)&ioMem[address]) = data;

 		break;

 	case FIFOA_L:

 	case FIFOA_H:

 		soundDSFifoA[soundDSFifoAWriteIndex++] = data & 0xFF;

 		soundDSFifoA[soundDSFifoAWriteIndex++] = data >> 8;

 		soundDSFifoACount		 += 2;

 		soundDSFifoAWriteIndex	 &= 31;

 		*((u16 *)&ioMem[address]) = data;

 		break;

 	case FIFOB_L:

 	case FIFOB_H:

 		soundDSFifoB[soundDSFifoBWriteIndex++] = data & 0xFF;

 		soundDSFifoB[soundDSFifoBWriteIndex++] = data >> 8;

 		soundDSFifoBCount		 += 2;

 		soundDSFifoBWriteIndex	 &= 31;

 		*((u16 *)&ioMem[address]) = data;

 		break;

 	case 0x88:

 		data &= 0xC3FF;

 		*((u16 *)&ioMem[address]) = data;

 		break;

 	case 0x90:

 	case 0x92:

 	case 0x94:

 	case 0x96:

 	case 0x98:

 	case 0x9a:

 	case 0x9c:

 	case 0x9e:

 		*((u16 *)&sound3WaveRam[(sound3Bank * 0x10) ^ 0x10 + (address & 14)]) = data;

 		*((u16 *)&ioMem[address]) = data;

 		break;

 	}

 }

 

 void soundChannel1()

 {

 	int vol = sound1EnvelopeVolume;

 

 	int freq  = 0;

 	int value = 0;

 

 	if (sound1On && (sound1ATL || !sound1Continue))

 	{

 		sound1Index += soundQuality * sound1Skip;

 		sound1Index &= 0x1fffffff;

 

 		value = ((s8)sound1Wave[sound1Index >> 24]) * vol;

 	}

 

 	soundBuffer[0][soundIndex] = value;

 

 	if (sound1On)

 	{

 		if (sound1ATL)

 		{

 			sound1ATL -= soundQuality;

 

 			if (sound1ATL <= 0 && sound1Continue)

 			{

 				ioMem[NR52] &= 0xfe;

 				sound1On	 = 0;

 			}

 		}

 

 		if (sound1EnvelopeATL)

 		{

 			sound1EnvelopeATL -= soundQuality;

 

 			if (sound1EnvelopeATL <= 0)

 			{

 				if (sound1EnvelopeUpDown)

 				{

 					if (sound1EnvelopeVolume < 15)

 						sound1EnvelopeVolume++;

 				}

 				else

 				{

 					if (sound1EnvelopeVolume)

 						sound1EnvelopeVolume--;

 				}

 

 				sound1EnvelopeATL += sound1EnvelopeATLReload;

 			}

 		}

 

 		if (sound1SweepATL)

 		{

 			sound1SweepATL -= soundQuality;

 

 			if (sound1SweepATL <= 0)

 			{

 				freq = (((int)(ioMem[NR14] & 7) << 8) | ioMem[NR13]);

 

 				int updown = 1;

 

 				if (sound1SweepUpDown)

 					updown = -1;

 

 				int newfreq = 0;

 				if (sound1SweepSteps)

 				{

 					newfreq = freq + updown * freq / (1 << sound1SweepSteps);

 					if (newfreq == freq)

 						newfreq = 0;

 				}

 				else

 					newfreq = freq;

 

 				if (newfreq < 0)

 				{

 					sound1SweepATL += sound1SweepATLReload;

 				}

 				else if (newfreq > 2047)

 				{

 					sound1SweepATL = 0;

 					sound1On	   = 0;

 					ioMem[NR52]	  &= 0xfe;

 				}

 				else

 				{

 					sound1SweepATL += sound1SweepATLReload;

 					sound1Skip		= SOUND_MAGIC / (2048 - newfreq);

 

 					ioMem[NR13] = newfreq & 0xff;

 					ioMem[NR14] = (ioMem[NR14] & 0xf8) | ((newfreq >> 8) & 7);

 				}

 			}

 		}

 	}

 }

 

 void soundChannel2()

 {

 	//  int freq = 0;

 	int vol = sound2EnvelopeVolume;

 

 	int value = 0;

 

 	if (sound2On && (sound2ATL || !sound2Continue))

 	{

 		sound2Index += soundQuality * sound2Skip;

 		sound2Index &= 0x1fffffff;

 

 		value = ((s8)sound2Wave[sound2Index >> 24]) * vol;

 	}

 

 	soundBuffer[1][soundIndex] = value;

 

 	if (sound2On)

 	{

 		if (sound2ATL)

 		{

 			sound2ATL -= soundQuality;

 

 			if (sound2ATL <= 0 && sound2Continue)

 			{

 				ioMem[NR52] &= 0xfd;

 				sound2On	 = 0;

 			}

 		}

 

 		if (sound2EnvelopeATL)

 		{

 			sound2EnvelopeATL -= soundQuality;

 

 			if (sound2EnvelopeATL <= 0)

 			{

 				if (sound2EnvelopeUpDown)

 				{

 					if (sound2EnvelopeVolume < 15)

 						sound2EnvelopeVolume++;

 				}

 				else

 				{

 					if (sound2EnvelopeVolume)

 						sound2EnvelopeVolume--;

 				}

 				sound2EnvelopeATL += sound2EnvelopeATLReload;

 			}

 		}

 	}

 }

 

 void soundChannel3()

 {

 	int value = sound3Last;

 

 	if (sound3On && (sound3ATL || !sound3Continue))

 	{

 		sound3Index += soundQuality * sound3Skip;

 		if (sound3DataSize)

 		{

 			sound3Index &= 0x3fffffff;

 			value		 = sound3WaveRam[sound3Index >> 25];

 		}

 		else

 		{

 			sound3Index &= 0x1fffffff;

 			value		 = sound3WaveRam[sound3Bank * 0x10 + (sound3Index >> 25)];

 		}

 

 		if ((sound3Index & 0x01000000))

 		{

 			value &= 0x0f;

 		}

 		else

 		{

 			value >>= 4;

 		}

 

 		value -= 8;

 		value *= 2;

 

 		if (sound3ForcedOutput)

 		{

 			value = ((value >> 1) + value) >> 1;

 		}

 		else

 		{

 			switch (sound3OutputLevel)

 			{

 			case 0:

 				value = 0;

 				break;

 			case 1:

 				break;

 			case 2:

 				value = (value >> 1);

 				break;

 			case 3:

 				value = (value >> 2);

 				break;

 			}

 		}

 		//value += 1;

 		sound3Last = value;

 	}

 

 	soundBuffer[2][soundIndex] = value;

 

 	if (sound3On)

 	{

 		if (sound3ATL)

 		{

 			sound3ATL -= soundQuality;

 

 			if (sound3ATL <= 0 && sound3Continue)

 			{

 				ioMem[NR52] &= 0xfb;

 				sound3On	 = 0;

 			}

 		}

 	}

 }

 

 void soundChannel4()

 {

 	int vol = sound4EnvelopeVolume;

 

 	int value = 0;

 

 	if (sound4Clock <= 0x0c)

 	{

 		if (sound4On && (sound4ATL || !sound4Continue))

 		{

 	  #define NOISE_ONE_SAMP_SCALE  0x200000

 

 			sound4Index		 += soundQuality * sound4Skip;

 			sound4ShiftIndex += soundQuality * sound4ShiftSkip;

 

 			if (sound4NSteps)

 			{

 				while (sound4ShiftIndex >= NOISE_ONE_SAMP_SCALE)

 				{

 					sound4ShiftRight = (((sound4ShiftRight << 6) ^

 					                     (sound4ShiftRight << 5)) & 0x40) |

 					                   (sound4ShiftRight >> 1);

 					sound4ShiftIndex -= NOISE_ONE_SAMP_SCALE;

 				}

 			}

 			else

 			{

 				while (sound4ShiftIndex >= NOISE_ONE_SAMP_SCALE)

 				{

 					sound4ShiftRight = (((sound4ShiftRight << 14) ^

 					                     (sound4ShiftRight << 13)) & 0x4000) |

 					                   (sound4ShiftRight >> 1);

 

 					sound4ShiftIndex -= NOISE_ONE_SAMP_SCALE;

 				}

 			}

 

 			sound4Index		 %= NOISE_ONE_SAMP_SCALE;

 			sound4ShiftIndex %= NOISE_ONE_SAMP_SCALE;

 

 			value = ((sound4ShiftRight & 1) * 2 - 1) * vol;

 		}

 		else

 		{

 			value = 0;

 		}

 	}

 

 	soundBuffer[3][soundIndex] = value;

 

 	if (sound4On)

 	{

 		if (sound4ATL)

 		{

 			sound4ATL -= soundQuality;

 

 			if (sound4ATL <= 0 && sound4Continue)

 			{

 				ioMem[NR52] &= 0xfd;

 				sound4On	 = 0;

 			}

 		}

 

 		if (sound4EnvelopeATL)

 		{

 			sound4EnvelopeATL -= soundQuality;

 

 			if (sound4EnvelopeATL <= 0)

 			{

 				if (sound4EnvelopeUpDown)

 				{

 					if (sound4EnvelopeVolume < 15)

 						sound4EnvelopeVolume++;

 				}

 				else

 				{

 					if (sound4EnvelopeVolume)

 						sound4EnvelopeVolume--;

 				}

 				sound4EnvelopeATL += sound4EnvelopeATLReload;

 			}

 		}

 	}

 }

 

 void soundDirectSoundA()

 {

 	soundBuffer[4][soundIndex] = soundDSAValue;

 }

 

 void soundDirectSoundATimer()

 {

 	if (soundDSAEnabled)

 	{

 		if (soundDSFifoACount <= 16)

 		{

 			CPUCheckDMA(3, 2);

 			if (soundDSFifoACount <= 16)

 			{

 				soundEvent(FIFOA_L, (u16)0);

 				soundEvent(FIFOA_H, (u16)0);

 				soundEvent(FIFOA_L, (u16)0);

 				soundEvent(FIFOA_H, (u16)0);

 				soundEvent(FIFOA_L, (u16)0);

 				soundEvent(FIFOA_H, (u16)0);

 				soundEvent(FIFOA_L, (u16)0);

 				soundEvent(FIFOA_H, (u16)0);

 			}

 		}

 

 		soundDSAValue	  = (soundDSFifoA[soundDSFifoAIndex]);

 		soundDSFifoAIndex = (++soundDSFifoAIndex) & 31;

 		soundDSFifoACount--;

 	}

 	else

 		soundDSAValue = 0;

 }

 

 void soundDirectSoundB()

 {

 	soundBuffer[5][soundIndex] = soundDSBValue;

 }

 

 void soundDirectSoundBTimer()

 {

 	if (soundDSBEnabled)

 	{

 		if (soundDSFifoBCount <= 16)

 		{

 			CPUCheckDMA(3, 4);

 			if (soundDSFifoBCount <= 16)

 			{

 				soundEvent(FIFOB_L, (u16)0);

 				soundEvent(FIFOB_H, (u16)0);

 				soundEvent(FIFOB_L, (u16)0);

 				soundEvent(FIFOB_H, (u16)0);

 				soundEvent(FIFOB_L, (u16)0);

 				soundEvent(FIFOB_H, (u16)0);

 				soundEvent(FIFOB_L, (u16)0);

 				soundEvent(FIFOB_H, (u16)0);

 			}

 		}

 

 		soundDSBValue	  = (soundDSFifoB[soundDSFifoBIndex]);

 		soundDSFifoBIndex = (++soundDSFifoBIndex) & 31;

 		soundDSFifoBCount--;

 	}

 	else

 	{

 		soundDSBValue = 0;

 	}

 }

 

 void soundTimerOverflow(int timer)

 {

 	if (soundDSAEnabled && (soundDSATimer == timer))

 	{

 		soundDirectSoundATimer();

 	}

 	if (soundDSBEnabled && (soundDSBTimer == timer))

 	{

 		soundDirectSoundBTimer();

 	}

 }

 

 void soundMix()

 {

 	int res		 = 0;

 	int cgbRes	 = 0;

 	int ratio	 = ioMem[0x82] & 3;

 	int dsaRatio = ioMem[0x82] & 4;

 	int dsbRatio = ioMem[0x82] & 8;

 

 	if (ioMem)

 		soundBalance = (ioMem[NR51] & soundEnableFlag & ~soundMutedFlag);

 

 	if (soundBalance & 16)

 	{

 		cgbRes = ((s8)soundBuffer[0][soundIndex]);

 	}

 	if (soundBalance & 32)

 	{

 		cgbRes += ((s8)soundBuffer[1][soundIndex]);

 	}

 	if (soundBalance & 64)

 	{

 		cgbRes += ((s8)soundBuffer[2][soundIndex]);

 	}

 	if (soundBalance & 128)

 	{

 		cgbRes += ((s8)soundBuffer[3][soundIndex]);

 	}

 

 	if ((soundControl & 0x0200) && (soundEnableFlag & 0x100))

 	{

 		if (!dsaRatio)

 			res = ((s8)soundBuffer[4][soundIndex]) >> 1;

 		else

 			res = ((s8)soundBuffer[4][soundIndex]);

 	}

 

 	if ((soundControl & 0x2000) && (soundEnableFlag & 0x200))

 	{

 		if (!dsbRatio)

 			res += ((s8)soundBuffer[5][soundIndex]) >> 1;

 		else

 			res += ((s8)soundBuffer[5][soundIndex]);

 	}

 

 	res	   = (res * 170);

 	cgbRes = (cgbRes * 52 * soundLevel1);

 

 	switch (ratio)

 	{

 	case 0:

 	case 3: // prohibited, but 25%

 		cgbRes >>= 2;

 		break;

 	case 1:

 		cgbRes >>= 1;

 		break;

 	case 2:

 		break;

 	}

 

 	res += cgbRes;

 

 	if (soundEcho)

 	{

 		res *= 2;

 		res += soundFilter[soundEchoIndex];

 		res /= 2;

 		soundFilter[soundEchoIndex++] = res;

 	}

 

 	if (soundLowPass)

 	{

 		soundLeft[4] = soundLeft[3];

 		soundLeft[3] = soundLeft[2];

 		soundLeft[2] = soundLeft[1];

 		soundLeft[1] = soundLeft[0];

 		soundLeft[0] = res;

 		res = (soundLeft[4] + 2 * soundLeft[3] + 8 * soundLeft[2] + 2 * soundLeft[1] +

 		       soundLeft[0]) / 14;

 	}

 

 	bool noSpecialEffects = false;

 #if (defined(WIN32) && !defined(SDL))

 	if (theApp.soundRecording || theApp.aviRecording || theApp.nvAudioLog)

 		noSpecialEffects = true;

 #endif

 

 	if (!noSpecialEffects)

 	{

 		switch (soundVolume)

 		{

 		case 0:

 		case 1:

 		case 2:

 		case 3:

 			res *= (soundVolume + 1);

 			break;

 		case 4:

 			res >>= 2;

 			break;

 		case 5:

 			res >>= 1;

 			break;

 		}

 	}

 

 	if (res > 32767)

 		res = 32767;

 	if (res < -32768)

 		res = -32768;

 

 	if (soundReverse && !noSpecialEffects)

 	{

 		soundFinalWave[++soundBufferIndex] = res;

 		if ((soundFrameSoundWritten + 1) >= countof(soundFrameSound))

 			/*assert(false)*/;

 		else

 			soundFrameSound[++soundFrameSoundWritten] = res;

 	}

 	else

 	{

 		soundFinalWave[soundBufferIndex++] = res;

 		if (soundFrameSoundWritten >= countof(soundFrameSound))

 			/*assert(false)*/;

 		else

 			soundFrameSound[soundFrameSoundWritten++] = res;

 	}

 

 	res	   = 0;

 	cgbRes = 0;

 

 	if (soundBalance & 1)

 	{

 		cgbRes = ((s8)soundBuffer[0][soundIndex]);

 	}

 	if (soundBalance & 2)

 	{

 		cgbRes += ((s8)soundBuffer[1][soundIndex]);

 	}

 	if (soundBalance & 4)

 	{

 		cgbRes += ((s8)soundBuffer[2][soundIndex]);

 	}

 	if (soundBalance & 8)

 	{

 		cgbRes += ((s8)soundBuffer[3][soundIndex]);

 	}

 

 	if ((soundControl & 0x0100) && (soundEnableFlag & 0x100))

 	{

 		if (!dsaRatio)

 			res = ((s8)soundBuffer[4][soundIndex]) >> 1;

 		else

 			res = ((s8)soundBuffer[4][soundIndex]);

 	}

 

 	if ((soundControl & 0x1000) && (soundEnableFlag & 0x200))

 	{

 		if (!dsbRatio)

 			res += ((s8)soundBuffer[5][soundIndex]) >> 1;

 		else

 			res += ((s8)soundBuffer[5][soundIndex]);

 	}

 

 	res	   = (res * 170);

 	cgbRes = (cgbRes * 52 * soundLevel1);

 

 	switch (ratio)

 	{

 	case 0:

 	case 3: // prohibited, but 25%

 		cgbRes >>= 2;

 		break;

 	case 1:

 		cgbRes >>= 1;

 		break;

 	case 2:

 		break;

 	}

 

 	res += cgbRes;

 

 	if (soundEcho)

 	{

 		res *= 2;

 		res += soundFilter[soundEchoIndex];

 		res /= 2;

 		soundFilter[soundEchoIndex++] = res;

 

 		if (soundEchoIndex >= 4000)

 			soundEchoIndex = 0;

 	}

 

 	if (soundLowPass)

 	{

 		soundRight[4] = soundRight[3];

 		soundRight[3] = soundRight[2];

 		soundRight[2] = soundRight[1];

 		soundRight[1] = soundRight[0];

 		soundRight[0] = res;

 		res = (soundRight[4] + 2 * soundRight[3] + 8 * soundRight[2] + 2 * soundRight[1] +

 		       soundRight[0]) / 14;

 	}

 

 	if (!noSpecialEffects)

 	{

 		switch (soundVolume)

 		{

 		case 0:

 		case 1:

 		case 2:

 		case 3:

 			res *= (soundVolume + 1);

 			break;

 		case 4:

 			res >>= 2;

 			break;

 		case 5:

 			res >>= 1;

 			break;

 		}

 	}

 

 	if (res > 32767)

 		res = 32767;

 	if (res < -32768)

 		res = -32768;

 

 	if (soundReverse && !noSpecialEffects)

 	{

 		soundFinalWave[-1 + soundBufferIndex++]		   = res;

 		if ((soundFrameSoundWritten) >= countof(soundFrameSound))

 			/*assert(false)*/;

 		else

 			soundFrameSound[-1 + soundFrameSoundWritten++] = res;

 	}

 	else

 	{

 		soundFinalWave[soundBufferIndex++]			  = res;

 		if ((soundFrameSoundWritten + 1) >= countof(soundFrameSound))

 			/*assert(false)*/;

 		else

 			soundFrameSound[soundFrameSoundWritten++] = res;

 	}

 }

 

 void soundTick()

 {

 	if (systemSoundOn)

 	{

 		if (soundMasterOn && !stopState)

 		{

 			soundChannel1();

 			soundChannel2();

 			soundChannel3();

 			soundChannel4();

 			soundDirectSoundA();

 			soundDirectSoundB();

 			soundMix();

 		}

 		else

 		{

 			soundFinalWave[soundBufferIndex++] = 0;

 			soundFinalWave[soundBufferIndex++] = 0;

 			if ((soundFrameSoundWritten + 1) >= countof(soundFrameSound))

 				/*assert(false)*/;

 			else

 			{

 				soundFrameSound[soundFrameSoundWritten++] = 0;

 				soundFrameSound[soundFrameSoundWritten++] = 0;

 			}

 		}

 

 		soundIndex++;

 

 		if (2 * soundBufferIndex >= soundBufferLen)

 		{

 			if (systemSoundOn)

 			{

 				if (soundPaused)

 				{

 					soundResume();

 				}

 

 				systemSoundWriteToBuffer();

 			}

 			soundIndex		 = 0;

 			soundBufferIndex = 0;

 		}

 	}

 }

 

 void soundShutdown()

 {

 	systemSoundShutdown();

 }

 

 void soundPause()

 {

 	systemSoundPause();

 }

 

 void soundResume()

 {

 	systemSoundResume();

 }

 

 void soundEnableChannels(int channels)

 {

 	int c = (channels & 0x0f) << 4;

 	soundEnableFlag |= ((channels & 0x30f) | c);

 }

 

 void soundDisableChannels(int channels)

 {

 	int c = (channels & 0x0f) << 4;

 	soundEnableFlag &= ~((channels & 0x30f) | c);

 }

 

 int soundGetEnabledChannels()

 {

 	return (soundEnableFlag & 0x30f);

 }

 

 #if 0

 // unused

 void soundMuteChannels(int channels)

 {

 	soundMutedFlag |= channels & 0x30f;

 }

 

 void soundUnmuteChannels(int channels)

 {

 	soundMutedFlag &= ~(channels & 0x30f);

 }

 

 int soundGetMutedChannels()

 {

 	return (soundMutedFlag & 0x30f);

 }

 #endif

 

 void soundReset()

 {

 	systemSoundReset();

 

 	soundPaused		  = 1;

 	soundPlay		  = 0;

 	SOUND_CLOCK_TICKS = soundQuality * USE_TICKS_AS;

 	soundTicks		  = SOUND_CLOCK_TICKS;

 	soundNextPosition = 0;

 	soundMasterOn	  = 1;

 	soundIndex		  = 0;

 	soundBufferIndex  = 0;

 	soundLevel1		  = 7;

 	soundLevel2		  = 7;

 

 	sound1On = 0;

 	sound1ATL = 0;

 	sound1Skip = 0;

 	sound1Index = 0;

 	sound1Continue = 0;

 	sound1EnvelopeVolume	= 0;

 	sound1EnvelopeATL		= 0;

 	sound1EnvelopeUpDown	= 0;

 	sound1EnvelopeATLReload = 0;

 	sound1SweepATL			= 0;

 	sound1SweepATLReload	= 0;

 	sound1SweepSteps		= 0;

 	sound1SweepUpDown		= 0;

 	sound1SweepStep			= 0;

 	sound1Wave				= soundWavePattern[2];

 

 	sound2On = 0;

 	sound2ATL = 0;

 	sound2Skip = 0;

 	sound2Index = 0;

 	sound2Continue = 0;

 	sound2EnvelopeVolume	= 0;

 	sound2EnvelopeATL		= 0;

 	sound2EnvelopeUpDown	= 0;

 	sound2EnvelopeATLReload = 0;

 	sound2Wave				= soundWavePattern[2];

 

 	sound3On = 0;

 	sound3ATL = 0;

 	sound3Skip		   = 0;

 	sound3Index		   = 0;

 	sound3Continue	   = 0;

 	sound3OutputLevel  = 0;

 	sound3Last		   = 0;

 	sound3Bank		   = 0;

 	sound3DataSize	   = 0;

 	sound3ForcedOutput = 0;

 

 	sound4On = 0;

 	sound4Clock = 0;

 	sound4ATL = 0;

 	sound4Skip = 0;

 	sound4Index = 0;

 	sound4ShiftRight		= 0x7f;

 	sound4NSteps			= 0;

 	sound4CountDown			= 0;

 	sound4Continue			= 0;

 	sound4EnvelopeVolume	= 0;

 	sound4EnvelopeATL		= 0;

 	sound4EnvelopeUpDown	= 0;

 	sound4EnvelopeATLReload = 0;

 

 	sound1On = 0;

 	sound2On = 0;

 	sound3On = 0;

 	sound4On = 0;

 

 	int addr = 0x90;

 

 	while (addr < 0xA0)

 	{

 		ioMem[addr++] = 0x00;

 		ioMem[addr++] = 0xff;

 	}

 

 	addr = 0;

 	while (addr < 0x20)

 	{

 		sound3WaveRam[addr++] = 0x00;

 		sound3WaveRam[addr++] = 0xff;

 	}

 

 	memset(soundFinalWave, 0, soundBufferLen);

 

 	memset(soundFilter, 0, sizeof(soundFilter));

 	soundEchoIndex = 0;

 }

 

 bool soundInit()

 {

 	if (systemSoundInit())

 	{

 		memset(soundBuffer[0], 0, 735 * 2);

 		memset(soundBuffer[1], 0, 735 * 2);

 		memset(soundBuffer[2], 0, 735 * 2);

 		memset(soundBuffer[3], 0, 735 * 2);

 

 		memset(soundFinalWave, 0, soundBufferLen);

 

 		soundPaused = 1;

 		return true;

 	}

 	return false;

 }

 

 void soundSetQuality(int quality)

 {

 	if (soundQuality != quality && systemSoundCanChangeQuality())

 	{

 		if (!soundOffFlag)

 			soundShutdown();

 		soundQuality	  = quality;

 		soundNextPosition = 0;

 		if (!soundOffFlag)

 			soundInit();

 		SOUND_CLOCK_TICKS = USE_TICKS_AS * soundQuality;

 		soundIndex		  = 0;

 		soundBufferIndex  = 0;

 	}

 	else if (soundQuality != quality)

 	{

 		soundNextPosition = 0;

 		SOUND_CLOCK_TICKS = USE_TICKS_AS * soundQuality;

 		soundIndex		  = 0;

 		soundBufferIndex  = 0;

 	}

 }

 

 void soundSaveGame(gzFile gzFile)

 {

 	soundTicks_int32		= (int32) soundTicks;

 	SOUND_CLOCK_TICKS_int32 = (int32) SOUND_CLOCK_TICKS;

 	soundDSBValue_int32		= (int32) soundDSBValue;

 

 	utilWriteData(gzFile, soundSaveStruct);

 	utilWriteData(gzFile, soundSaveStructV2);

 

 	utilGzWrite(gzFile, &soundQuality, sizeof(int32));

 	//utilWriteData(gzFile, soundSaveStructV3);

 }

 

 void soundReadGame(gzFile gzFile, int version)

 {

 	int32 oldSoundPaused = soundPaused;

 	int32 oldSoundEnableFlag = soundEnableFlag;

 	utilReadData(gzFile, soundSaveStruct);

 	soundPaused = oldSoundPaused;

 	soundEnableFlag = oldSoundEnableFlag;

 

 	if (version >= SAVE_GAME_VERSION_3)

 	{

 		utilReadData(gzFile, soundSaveStructV2);

 	}

 	else

 	{

 		sound3Bank		   = (ioMem[NR30] >> 6) & 1;

 		sound3DataSize	   = (ioMem[NR30] >> 5) & 1;

 		sound3ForcedOutput = (ioMem[NR32] >> 7) & 1;

 		// nothing better to do here...

 		memcpy(&sound3WaveRam[0x00], &ioMem[0x90], 0x10);

 		memcpy(&sound3WaveRam[0x10], &ioMem[0x90], 0x10);

 	}

 	soundBufferIndex = soundIndex * 2;

 

 	int quality = 1;

 	utilGzRead(gzFile, &quality, sizeof(int32));

 	soundSetQuality(quality);

 

 	sound1Wave = soundWavePattern[ioMem[NR11] >> 6];

 	sound2Wave = soundWavePattern[ioMem[NR21] >> 6];

 

 	//if(version >= SAVE_GAME_VERSION_14) {

 	//  utilReadData(gzFile, soundSaveStructV3);

 	//}

 	//else {

 	soundTicks		  = (soundtick_t) soundTicks_int32;

 	SOUND_CLOCK_TICKS = (soundtick_t) SOUND_CLOCK_TICKS_int32;

 	//}

 	soundDSBValue = (u8) (soundDSBValue_int32 & 0xff);

 }