pcsx2/plugins/SPU2null/Src/SPU2.cpp

/*  SPU2null
 *  Copyright (C) 2002-2005  SPU2null Team
 *
 *  This program is free software; you can redistribute it and/or modify
 *  it under the terms of the GNU General Public License as published by
 *  the Free Software Foundation; either version 2 of the License, or
 *  (at your option) any later version.
 *
 *  This program is distributed in the hope that it will be useful,
 *  but WITHOUT ANY WARRANTY; without even the implied warranty of
 *  MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
 *  GNU General Public License for more details.
 *
 *  You should have received a copy of the GNU General Public License
 *  along with this program; if not, write to the Free Software
 *  Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA  02111-1307  USA
 */

#include "SPU2.h"

#include <assert.h>
#include <stdlib.h>

const unsigned char version  = PS2E_SPU2_VERSION;
const unsigned char revision = 0;
const unsigned char build    = 7;    // increase that with each version
const unsigned int minor = 1;    // increase that with each version

// ADSR constants
#define ATTACK_MS      494L
#define DECAYHALF_MS   286L
#define DECAY_MS       572L
#define SUSTAIN_MS     441L
#define RELEASE_MS     437L

#ifdef _DEBUG
static char *libraryName      = "SPU2null (Debug)";
#else
static char *libraryName      = "SPU2null ";
#endif

FILE *spu2Log;
Config conf;

ADMA Adma4;
ADMA Adma7;

u32 MemAddr[2];
u32 g_nSpuInit = 0;
unsigned short interrupt = 0;
s8 *spu2regs = NULL;
u16* spu2mem = NULL;
u16* pSpuIrq[2] = {NULL};
u32 dwEndChannel2[2] = {0}; // keeps track of what channels have ended
unsigned long   dwNoiseVal=1;                          // global noise generator

int SPUCycles = 0, SPUWorkerCycles = 0;
int SPUStartCycle[2];
int SPUTargetCycle[2];

int ADMAS4Write();
int ADMAS7Write();

void InitADSR();

void (*irqCallbackSPU2)();                  // func of main emu, called on spu irq
void (*irqCallbackDMA4)()=0;                  // func of main emu, called on spu irq
void (*irqCallbackDMA7)()=0;                  // func of main emu, called on spu irq

const int f[5][2] = {   {    0,  0  },
                        {   60,  0  },
                        {  115, -52 },
                        {   98, -55 },
                        {  122, -60 } };

u32 RateTable[160];

// channels and voices
VOICE_PROCESSED voices[SPU_NUMBER_VOICES+1]; // +1 for modulation

u32 CALLBACK PS2EgetLibType() {
	return PS2E_LT_SPU2;
}

char* CALLBACK PS2EgetLibName() {
	return libraryName;
}

u32 CALLBACK PS2EgetLibVersion2(u32 type) {
	return (version<<16)|(revision<<8)|build|(minor<<24);
}

void __Log(char *fmt, ...) {
	va_list list;

	if (!conf.Log || spu2Log == NULL) return;

	va_start(list, fmt);
	vfprintf(spu2Log, fmt, list);
	va_end(list);
}

s32 CALLBACK SPU2init() {
#ifdef SPU2_LOG
	spu2Log = fopen("logs/spu2.txt", "w");
	if (spu2Log) setvbuf(spu2Log, NULL,  _IONBF, 0);
	SPU2_LOG("Spu2 null version %d,%d\n",revision,build);  
	SPU2_LOG("SPU2init\n");
#endif
	spu2regs = (s8*)malloc(0x10000);
	if (spu2regs == NULL) {
		SysMessage("Error allocating Memory\n"); return -1;
	}
    memset(spu2regs, 0, 0x10000);

    spu2mem = (u16*)malloc(0x200000); // 2Mb
    if (spu2mem == NULL) {
		SysMessage("Error allocating Memory\n"); return -1;
	}
    memset(spu2mem, 0, 0x200000);
    memset(dwEndChannel2, 0, sizeof(dwEndChannel2));

    InitADSR();

    memset(voices, 0, sizeof(voices));
    // last 24 channels have higher mem offset
    for(int i = 0; i < 24; ++i)
        voices[i+24].memoffset = 0x400;

    // init each channel
    for(u32 i = 0; i < ARRAYSIZE(voices); ++i) {

        voices[i].pLoop = voices[i].pStart = voices[i].pCurr = (u8*)spu2mem;

        voices[i].pvoice = (_SPU_VOICE*)((u8*)spu2regs+voices[i].memoffset)+(i%24);
        voices[i].ADSRX.SustainLevel = 1024;                // -> init sustain
    }
	
	return 0;
}

s32 CALLBACK SPU2open(void *pDsp) {
    LoadConfig();
    SPUCycles = SPUWorkerCycles = 0;
    interrupt = 0;
    SPUStartCycle[0] = SPUStartCycle[1] = 0;
    SPUTargetCycle[0] = SPUTargetCycle[1] = 0;
    g_nSpuInit = 1;
    return 0;
}

void CALLBACK SPU2close() {
    g_nSpuInit = 0;
}

void CALLBACK SPU2shutdown() {
	free(spu2regs); spu2regs = NULL;
    free(spu2mem); spu2mem = NULL;
#ifdef SPU2_LOG
	if (spu2Log) fclose(spu2Log);
#endif
}

// simulate SPU2 for 1ms
void SPU2Worker();

#define CYCLES_PER_MS (36864000/1000)

void CALLBACK SPU2async(u32 cycle)
{
    SPUCycles += cycle;
	if(interrupt & (1<<2)){
		if(SPUCycles - SPUStartCycle[1] >= SPUTargetCycle[1]){
			interrupt &= ~(1<<2);
			irqCallbackDMA7();
		}
		
	}

	if(interrupt & (1<<1)){
		if(SPUCycles - SPUStartCycle[0] >= SPUTargetCycle[0]){
			interrupt &= ~(1<<1);
			irqCallbackDMA4();
		}
	}

    if( g_nSpuInit ) {

        while( SPUCycles-SPUWorkerCycles > 0 && CYCLES_PER_MS < SPUCycles-SPUWorkerCycles ) {
            SPU2Worker();
            SPUWorkerCycles += CYCLES_PER_MS;
        }
    }
}

void InitADSR()                                    // INIT ADSR
{
    unsigned long r,rs,rd;
    int i;
    memset(RateTable,0,sizeof(unsigned long)*160);        // build the rate table according to Neill's rules (see at bottom of file)

    r=3;rs=1;rd=0;

    for(i=32;i<160;i++)                                   // we start at pos 32 with the real values... everything before is 0
    {
        if(r<0x3FFFFFFF)
        {
            r+=rs;
            rd++;if(rd==5) {rd=1;rs*=2;}
        }
        if(r>0x3FFFFFFF) r=0x3FFFFFFF;

        RateTable[i]=r;
    }
}

int MixADSR(VOICE_PROCESSED* pvoice)                             // MIX ADSR
{    
    if(pvoice->bStop)                                  // should be stopped:
    {                      
        if(pvoice->bIgnoreLoop==0){
            pvoice->ADSRX.EnvelopeVol=0;
            pvoice->bOn=false;
            pvoice->pStart= (u8*)(spu2mem+pvoice->iStartAddr);
            pvoice->pLoop= (u8*)(spu2mem+pvoice->iStartAddr);
            pvoice->pCurr= (u8*)(spu2mem+pvoice->iStartAddr);
            pvoice->bStop=true;
            pvoice->bIgnoreLoop=false;
            return 0;
        }
        if(pvoice->ADSRX.ReleaseModeExp)// do release
        {
            switch((pvoice->ADSRX.EnvelopeVol>>28)&0x7)
            {
                case 0: pvoice->ADSRX.EnvelopeVol-=RateTable[(4*(pvoice->ADSRX.ReleaseRate^0x1F))-0x18 +0 + 32]; break;
                case 1: pvoice->ADSRX.EnvelopeVol-=RateTable[(4*(pvoice->ADSRX.ReleaseRate^0x1F))-0x18 +4 + 32]; break;
                case 2: pvoice->ADSRX.EnvelopeVol-=RateTable[(4*(pvoice->ADSRX.ReleaseRate^0x1F))-0x18 +6 + 32]; break;
                case 3: pvoice->ADSRX.EnvelopeVol-=RateTable[(4*(pvoice->ADSRX.ReleaseRate^0x1F))-0x18 +8 + 32]; break;
                case 4: pvoice->ADSRX.EnvelopeVol-=RateTable[(4*(pvoice->ADSRX.ReleaseRate^0x1F))-0x18 +9 + 32]; break;
                case 5: pvoice->ADSRX.EnvelopeVol-=RateTable[(4*(pvoice->ADSRX.ReleaseRate^0x1F))-0x18 +10+ 32]; break;
                case 6: pvoice->ADSRX.EnvelopeVol-=RateTable[(4*(pvoice->ADSRX.ReleaseRate^0x1F))-0x18 +11+ 32]; break;
                case 7: pvoice->ADSRX.EnvelopeVol-=RateTable[(4*(pvoice->ADSRX.ReleaseRate^0x1F))-0x18 +12+ 32]; break;
            }
        }
        else
        {
            pvoice->ADSRX.EnvelopeVol-=RateTable[(4*(pvoice->ADSRX.ReleaseRate^0x1F))-0x0C + 32];
        }

        if(pvoice->ADSRX.EnvelopeVol<0) 
        {
            pvoice->ADSRX.EnvelopeVol=0;
            pvoice->bOn=false;
            pvoice->pStart= (u8*)(spu2mem+pvoice->iStartAddr);
            pvoice->pLoop= (u8*)(spu2mem+pvoice->iStartAddr);
            pvoice->pCurr= (u8*)(spu2mem+pvoice->iStartAddr);
            pvoice->bStop=true;
            pvoice->bIgnoreLoop=false;
            //pvoice->bReverb=0;
            //pvoice->bNoise=0;
        }

        pvoice->ADSRX.lVolume=pvoice->ADSRX.EnvelopeVol>>21;
        pvoice->ADSRX.lVolume=pvoice->ADSRX.EnvelopeVol>>21;
        return pvoice->ADSRX.lVolume;
    }
    else                                                  // not stopped yet?
    {
        if(pvoice->ADSRX.State==0)                       // -> attack
        {
            if(pvoice->ADSRX.AttackModeExp)
            {
                if(pvoice->ADSRX.EnvelopeVol<0x60000000) 
                    pvoice->ADSRX.EnvelopeVol+=RateTable[(pvoice->ADSRX.AttackRate^0x7F)-0x10 + 32];
                else
                    pvoice->ADSRX.EnvelopeVol+=RateTable[(pvoice->ADSRX.AttackRate^0x7F)-0x18 + 32];
            }
            else
            {
                pvoice->ADSRX.EnvelopeVol+=RateTable[(pvoice->ADSRX.AttackRate^0x7F)-0x10 + 32];
            }

            if(pvoice->ADSRX.EnvelopeVol<0) 
            {
                pvoice->ADSRX.EnvelopeVol=0x7FFFFFFF;
                pvoice->ADSRX.State=1;
            }

            pvoice->ADSRX.lVolume=pvoice->ADSRX.EnvelopeVol>>21;
            return pvoice->ADSRX.lVolume;
        }
        //--------------------------------------------------//
        if(pvoice->ADSRX.State==1)                       // -> decay
        {
            switch((pvoice->ADSRX.EnvelopeVol>>28)&0x7)
            {
            case 0: pvoice->ADSRX.EnvelopeVol-=RateTable[(4*(pvoice->ADSRX.DecayRate^0x1F))-0x18+0 + 32]; break;
            case 1: pvoice->ADSRX.EnvelopeVol-=RateTable[(4*(pvoice->ADSRX.DecayRate^0x1F))-0x18+4 + 32]; break;
            case 2: pvoice->ADSRX.EnvelopeVol-=RateTable[(4*(pvoice->ADSRX.DecayRate^0x1F))-0x18+6 + 32]; break;
            case 3: pvoice->ADSRX.EnvelopeVol-=RateTable[(4*(pvoice->ADSRX.DecayRate^0x1F))-0x18+8 + 32]; break;
            case 4: pvoice->ADSRX.EnvelopeVol-=RateTable[(4*(pvoice->ADSRX.DecayRate^0x1F))-0x18+9 + 32]; break;
            case 5: pvoice->ADSRX.EnvelopeVol-=RateTable[(4*(pvoice->ADSRX.DecayRate^0x1F))-0x18+10+ 32]; break;
            case 6: pvoice->ADSRX.EnvelopeVol-=RateTable[(4*(pvoice->ADSRX.DecayRate^0x1F))-0x18+11+ 32]; break;
            case 7: pvoice->ADSRX.EnvelopeVol-=RateTable[(4*(pvoice->ADSRX.DecayRate^0x1F))-0x18+12+ 32]; break;
            }

            if(pvoice->ADSRX.EnvelopeVol<0) pvoice->ADSRX.EnvelopeVol=0;
            if(((pvoice->ADSRX.EnvelopeVol>>27)&0xF) <= pvoice->ADSRX.SustainLevel)
            {
                pvoice->ADSRX.State=2;
            }

            pvoice->ADSRX.lVolume=pvoice->ADSRX.EnvelopeVol>>21;
            return pvoice->ADSRX.lVolume;
        }
        //--------------------------------------------------//
        if(pvoice->ADSRX.State==2)                       // -> sustain
        {
            if(pvoice->ADSRX.SustainIncrease)
            {
                if(pvoice->ADSRX.SustainModeExp)
                {
                    if(pvoice->ADSRX.EnvelopeVol<0x60000000) 
                        pvoice->ADSRX.EnvelopeVol+=RateTable[(pvoice->ADSRX.SustainRate^0x7F)-0x10 + 32];
                    else
                        pvoice->ADSRX.EnvelopeVol+=RateTable[(pvoice->ADSRX.SustainRate^0x7F)-0x18 + 32];
                }
                else
                {
                    pvoice->ADSRX.EnvelopeVol+=RateTable[(pvoice->ADSRX.SustainRate^0x7F)-0x10 + 32];
                }

                if(pvoice->ADSRX.EnvelopeVol<0) 
                {
                    pvoice->ADSRX.EnvelopeVol=0x7FFFFFFF;
                }
            }
            else
            {
                if(pvoice->ADSRX.SustainModeExp)
                {
                    switch((pvoice->ADSRX.EnvelopeVol>>28)&0x7)
                    {
                    case 0: pvoice->ADSRX.EnvelopeVol-=RateTable[((pvoice->ADSRX.SustainRate^0x7F))-0x1B +0 + 32];break;
                    case 1: pvoice->ADSRX.EnvelopeVol-=RateTable[((pvoice->ADSRX.SustainRate^0x7F))-0x1B +4 + 32];break;
                    case 2: pvoice->ADSRX.EnvelopeVol-=RateTable[((pvoice->ADSRX.SustainRate^0x7F))-0x1B +6 + 32];break;
                    case 3: pvoice->ADSRX.EnvelopeVol-=RateTable[((pvoice->ADSRX.SustainRate^0x7F))-0x1B +8 + 32];break;
                    case 4: pvoice->ADSRX.EnvelopeVol-=RateTable[((pvoice->ADSRX.SustainRate^0x7F))-0x1B +9 + 32];break;
                    case 5: pvoice->ADSRX.EnvelopeVol-=RateTable[((pvoice->ADSRX.SustainRate^0x7F))-0x1B +10+ 32];break;
                    case 6: pvoice->ADSRX.EnvelopeVol-=RateTable[((pvoice->ADSRX.SustainRate^0x7F))-0x1B +11+ 32];break;
                    case 7: pvoice->ADSRX.EnvelopeVol-=RateTable[((pvoice->ADSRX.SustainRate^0x7F))-0x1B +12+ 32];break;
                    }
                }
                else
                {
                    pvoice->ADSRX.EnvelopeVol-=RateTable[((pvoice->ADSRX.SustainRate^0x7F))-0x0F + 32];
                }

                if(pvoice->ADSRX.EnvelopeVol<0) 
                {
                    pvoice->ADSRX.EnvelopeVol=0;
                }
            }
            pvoice->ADSRX.lVolume=pvoice->ADSRX.EnvelopeVol>>21;
            return pvoice->ADSRX.lVolume;
        }
    }
    return 0;
}

// simulate SPU2 for 1ms
void SPU2Worker()
{
    u8* start;
    int ch,flags;
    
    VOICE_PROCESSED* pChannel=voices;
    for(ch=0;ch<SPU_NUMBER_VOICES;ch++,pChannel++)              // loop em all... we will collect 1 ms of sound of each playing channel
    {
        if(pChannel->bNew) {
            pChannel->StartSound();                         // start new sound
            dwEndChannel2[ch/24]&=~(1<<(ch%24));                  // clear end channel bit
        }

        if(!pChannel->bOn)
        {
            // fill buffer with empty data
            continue;
        }

        if(pChannel->iActFreq!=pChannel->iUsedFreq)     // new psx frequency?
            pChannel->VoiceChangeFrequency();

        // loop until 1 ms of data is reached
        int ns = 0;
        while(ns<NSSIZE)
        {
            while(pChannel->spos >= 0x10000 )
            {
                if(pChannel->iSBPos==28)            // 28 reached?
                {
                    start=pChannel->pCurr;          // set up the current pos

                    // special "stop" sign
                    if( start == (u8*)-1 ) //!pChannel->bOn 
                    {
                        pChannel->bOn=false;                        // -> turn everything off
                        pChannel->ADSRX.lVolume=0;
                        pChannel->ADSRX.EnvelopeVol=0;
                        goto ENDX;                              // -> and done for this channel
                    }

                    pChannel->iSBPos=0;

                    // decode the 16 byte packet

                    flags=(int)start[1];
                    start += 16;

                    // some callback and irq active?
                    if(pChannel->GetCtrl()->irq) {
                        // if irq address reached or irq on looping addr, when stop/loop flag is set 
                        u8* pirq = (u8*)pSpuIrq[ch>=24];
                        if( (pirq > start-16  && pirq <= start)
                            || ((flags&1) && (pirq >  pChannel->pLoop-16 && pirq <= pChannel->pLoop)))
                        {
                            IRQINFO |= 4<<(int)(ch>=24);
                            irqCallbackSPU2();
                        }
                    }

                    // flag handler
                    if((flags&4) && (!pChannel->bIgnoreLoop))
                        pChannel->pLoop=start-16;                // loop adress

                    if(flags&1)                               // 1: stop/loop
                    {
                        // We play this block out first...
                        dwEndChannel2[ch/24]|=(1<<(ch%24));
                        //if(!(flags&2))                          // 1+2: do loop... otherwise: stop
                        if(flags!=3 || pChannel->pLoop==NULL)   // PETE: if we don't check exactly for 3, loop hang ups will happen (DQ4, for example)
                        {                                      // and checking if pLoop is set avoids crashes, yeah
                            start = (u8*)-1;
                            pChannel->bStop = true;
                            pChannel->bIgnoreLoop = false;
                        }
                        else
                        {
                            start = pChannel->pLoop;
                        }
                    }

                    pChannel->pCurr=start;                    // store values for next cycle
                }

                pChannel->iSBPos++;        // get sample data
                pChannel->spos -= 0x10000;
            }

            MixADSR(pChannel);

            // go to the next packet
            ns++;
            pChannel->spos += pChannel->sinc;
        }
ENDX:
        ;
    }

    // mix all channels
    if( (spu2Ru16(REG_C0_MMIX) & 0xC0) && (spu2Ru16(REG_C0_ADMAS) & 0x1) && !(spu2Ru16(REG_C0_CTRL) & 0x30)) {
        for(int ns=0;ns<NSSIZE;ns++) { 
		    Adma4.Index +=1;

		    if(Adma4.Index == 128 || Adma4.Index == 384)
		    {
			    if(ADMAS4Write())
			    {
				    spu2Ru16(REG_C0_SPUSTAT)&=~0x80;
				    irqCallbackDMA4();
			    }
			    else MemAddr[0] += 1024;
		    }
        	
		    if(Adma4.Index == 512){
			    Adma4.Index = 0;
		    }
	    }
    }


    if( (spu2Ru16(REG_C1_MMIX) & 0xC0) && (spu2Ru16(REG_C1_ADMAS) & 0x2) && !(spu2Ru16(REG_C1_CTRL) & 0x30)) {
        for(int ns=0;ns<NSSIZE;ns++) { 
		    Adma7.Index +=1;
        	
		    if(Adma7.Index == 128 || Adma7.Index == 384)
		    {
			    if(ADMAS7Write())
			    {
				    spu2Ru16(REG_C1_SPUSTAT)&=~0x80;
				    irqCallbackDMA7();
			    }
                else MemAddr[1] += 1024;
		    }

		    if(Adma7.Index == 512)	Adma7.Index = 0;
	    }
    }
}

void CALLBACK SPU2readDMA4Mem(u16 *pMem, int size)
{
    u32 spuaddr = C0_SPUADDR;
    int i;

#ifdef SPU2_LOG
    SPU2_LOG("SPU2 readDMA4Mem size %x, addr: %x\n", size, pMem);
#endif

    for(i=0;i<size;i++)
    {
        *pMem++ = *(u16*)(spu2mem+spuaddr);
        if((spu2Rs16(REG_C0_CTRL)&0x40) && C0_IRQA == spuaddr){
            spu2Ru16(SPDIF_OUT) |= 0x4;
            C0_SPUADDR_SET(spuaddr);
            IRQINFO |= 4;
            irqCallbackSPU2();
        }

        spuaddr++;           // inc spu addr
        if(spuaddr>0x0fffff) // wrap at 2Mb
            spuaddr=0;             // wrap
    }

    spuaddr+=19; //Transfer Local To Host TSAH/L + Data Size + 20 (already +1'd)
    C0_SPUADDR_SET(spuaddr);

    // got from J.F. and Kanodin... is it needed?
    spu2Ru16(REG_C0_SPUSTAT) &=~0x80;                                     // DMA complete
    SPUStartCycle[0] = SPUCycles;
    SPUTargetCycle[0] = size;
    interrupt |= (1<<1);
}

void CALLBACK SPU2readDMA7Mem(u16* pMem, int size)
{
    u32 spuaddr = C1_SPUADDR;
    int i;

#ifdef SPU2_LOG
    SPU2_LOG("SPU2 readDMA7Mem size %x, addr: %x\n", size, pMem);
#endif

    for(i=0;i<size;i++)
    {
        *pMem++ = *(u16*)(spu2mem+spuaddr);
        if((spu2Rs16(REG_C1_CTRL)&0x40) && C1_IRQA == spuaddr ){
           spu2Ru16(SPDIF_OUT) |= 0x8;
           C1_SPUADDR_SET(spuaddr);
           IRQINFO |= 8;
           irqCallbackSPU2();
        }
        spuaddr++;                            // inc spu addr
        if(spuaddr>0x0fffff) // wrap at 2Mb
            spuaddr=0;             // wrap
    }

    spuaddr+=19; //Transfer Local To Host TSAH/L + Data Size + 20 (already +1'd)
    C1_SPUADDR_SET(spuaddr);

    // got from J.F. and Kanodin... is it needed?
    spu2Ru16(REG_C1_SPUSTAT)&=~0x80;                                     // DMA complete
    SPUStartCycle[1] = SPUCycles;
    SPUTargetCycle[1] = size;
    interrupt |= (1<<2);
}

// WRITE

// AutoDMA's are used to transfer to the DIRECT INPUT area of the spu2 memory
// Left and Right channels are always interleaved together in the transfer so 
// the AutoDMA's deinterleaves them and transfers them. An interrupt is
// generated when half of the buffer (256 short-words for left and 256 
// short-words for right ) has been transferred. Another interrupt occurs at 
// the end of the transfer.
int ADMAS4Write()
{
    u32 spuaddr;
    if(interrupt & 0x2) return 0;
    if(Adma4.AmountLeft <= 0) return 1;

    spuaddr = C0_SPUADDR;
    // SPU2 Deinterleaves the Left and Right Channels
    memcpy((short*)(spu2mem + spuaddr + 0x2000),(short*)Adma4.MemAddr,512);
    Adma4.MemAddr += 256;
    memcpy((short*)(spu2mem + spuaddr + 0x2200),(short*)Adma4.MemAddr,512);
    Adma4.MemAddr += 256;
    spuaddr = (spuaddr + 256) & 511;
    C0_SPUADDR_SET(spuaddr);

    Adma4.AmountLeft-=512;
    if(Adma4.AmountLeft == 0) 
    {
        SPUStartCycle[0] = SPUCycles;
        SPUTargetCycle[0] = 1;//512*48000;
        spu2Ru16(REG_C0_SPUSTAT)&=~0x80;
        interrupt |= (1<<1);
    }
    return 0;
}

int ADMAS7Write()
{
    u32 spuaddr;
    if(interrupt & 0x4) return 0;
    if(Adma7.AmountLeft <= 0) return 1;

    spuaddr = C1_SPUADDR;
    // SPU2 Deinterleaves the Left and Right Channels
    memcpy((short*)(spu2mem + spuaddr + 0x2400),(short*)Adma7.MemAddr,512);
    Adma7.MemAddr += 256;
    memcpy((short*)(spu2mem + spuaddr + 0x2600),(short*)Adma7.MemAddr,512);
    Adma7.MemAddr += 256;
    spuaddr = (spuaddr + 256) & 511;
    C1_SPUADDR_SET(spuaddr);

    Adma7.AmountLeft-=512;
    if(Adma7.AmountLeft == 0) 
    {
        SPUStartCycle[1] = SPUCycles;
        SPUTargetCycle[1] = 1;//512*48000;
        spu2Ru16(REG_C1_SPUSTAT)&=~0x80;
        interrupt |= (1<<2);
    }
    return 0;
}

void CALLBACK SPU2writeDMA4Mem(u16* pMem, int size)
{
    u32 spuaddr;

#ifdef SPU2_LOG
    SPU2_LOG("SPU2 writeDMA4Mem size %x, addr: %x\n", size, pMem);
#endif
    if((spu2Ru16(REG_C0_ADMAS) & 0x1) && (spu2Ru16(REG_C0_CTRL) & 0x30) == 0 && size)
    {
        //fwrite(pMem,iSize<<1,1,LogFile);
        memset(&Adma4,0,sizeof(ADMA));
        C0_SPUADDR_SET(0);
        Adma4.MemAddr = pMem;
        Adma4.AmountLeft = size;
        ADMAS4Write();
        return;
    }

    spuaddr = C0_SPUADDR;
    memcpy((unsigned char*)(spu2mem + spuaddr),(unsigned char*)pMem,size<<1);
    spuaddr += size;
    C0_SPUADDR_SET(spuaddr);
    
    if( (spu2Ru16(REG_C0_CTRL)&0x40) && C0_IRQA == spuaddr){
        spu2Ru16(SPDIF_OUT) |= 0x4;
        IRQINFO |= 4;
        irqCallbackSPU2();
    }
    if(spuaddr>0xFFFFE)
        spuaddr = 0x2800;
    C0_SPUADDR_SET(spuaddr);

    MemAddr[0] += size<<1;
    spu2Ru16(REG_C0_SPUSTAT)&=~0x80;
    SPUStartCycle[0] = SPUCycles;
    SPUTargetCycle[0] = 1;//iSize;
    interrupt |= (1<<1);
}

void CALLBACK SPU2writeDMA7Mem(u16* pMem, int size)
{
    u32 spuaddr;

#ifdef SPU2_LOG
    SPU2_LOG("SPU2 writeDMA7Mem size %x, addr: %x\n", size, pMem);
#endif
    if((spu2Ru16(REG_C1_ADMAS) & 0x2) && (spu2Ru16(REG_C1_CTRL) & 0x30) == 0 && size)
    {
        //fwrite(pMem,iSize<<1,1,LogFile);
        memset(&Adma7,0,sizeof(ADMA));
        C1_SPUADDR_SET(0);
        Adma7.MemAddr = pMem;
        Adma7.AmountLeft = size;
        ADMAS7Write();
        return;
    }

    spuaddr = C1_SPUADDR;
    memcpy((unsigned char*)(spu2mem + spuaddr),(unsigned char*)pMem,size<<1);
    spuaddr += size;
    C1_SPUADDR_SET(spuaddr);
    
    if( (spu2Ru16(REG_C1_CTRL)&0x40) && C1_IRQA == spuaddr){
        spu2Ru16(SPDIF_OUT) |= 0x8;
        IRQINFO |= 8;
        irqCallbackSPU2();
    }
    if(spuaddr>0xFFFFE)
        spuaddr = 0x2800;
    C1_SPUADDR_SET(spuaddr);

    MemAddr[1] += size<<1;
    spu2Ru16(REG_C1_SPUSTAT)&=~0x80;
    SPUStartCycle[1] = SPUCycles;
    SPUTargetCycle[1] = 1;//iSize;
    interrupt |= (1<<2);
}

void CALLBACK SPU2interruptDMA4()
{
#ifdef SPU2_LOG
	SPU2_LOG("SPU2 interruptDMA4\n");
#endif
//	spu2Rs16(REG_C0_CTRL)&= ~0x30;
//	spu2Rs16(REG__1B0) = 0;
//	spu2Rs16(SPU2_STATX_WRDY_M)|= 0x80;
    spu2Rs16(REG_C0_CTRL)&=~0x30;
	spu2Ru16(REG_C0_SPUSTAT)|=0x80;
}

void CALLBACK SPU2interruptDMA7()
{
#ifdef SPU2_LOG
	SPU2_LOG("SPU2 interruptDMA7\n");
#endif
//	spu2Rs16(REG_C1_CTRL)&= ~0x30;
//	//spu2Rs16(REG__5B0) = 0;
//	spu2Rs16(SPU2_STATX_DREQ)|= 0x80;
    spu2Rs16(REG_C1_CTRL)&=~0x30;
	spu2Ru16(REG_C1_SPUSTAT)|=0x80;
}

// turn channels on
void SoundOn(int start,int end,unsigned short val)     // SOUND ON PSX COMAND
{
    for(int ch=start;ch<end;ch++,val>>=1)                     // loop channels
    {
        if((val&1) && voices[ch].pStart)                    // mmm... start has to be set before key on !?!
        {
            voices[ch].bNew=true;
            voices[ch].bIgnoreLoop = false;
        }
    }
}

// turn channels off
void SoundOff(int start,int end,unsigned short val)    // SOUND OFF PSX COMMAND
{
    for(int ch=start;ch<end;ch++,val>>=1)                     // loop channels
    {
        if(val&1)                                           // && s_chan[i].bOn)  mmm...
            voices[ch].bStop=true;                                               
    }
}

void FModOn(int start,int end,unsigned short val)      // FMOD ON PSX COMMAND
{
    int ch;

    for(ch=start;ch<end;ch++,val>>=1)                     // loop channels
    {
        if(val&1)                                           // -> fmod on/off
        {
            if(ch>0) {
            }
        }
        else {
            // turn fmod off
        }
    }
}

void CALLBACK SPU2write(u32 mem, u16 value)
{
    u32 spuaddr;
#ifdef SPU2_LOG
	SPU2_LOG("SPU2 write mem %x value %x\n", mem, value);
#endif

    assert( C0_SPUADDR < 0x100000);
    assert( C1_SPUADDR < 0x100000);

    spu2Ru16(mem) = value;
    u32 r = mem&0xffff;

    // channel info
    if((r>=0x0000 && r<0x0180)||(r>=0x0400 && r<0x0580))  // some channel info?
    {
        int ch=0;
        if(r>=0x400) ch=((r-0x400)>>4)+24;
        else ch=(r>>4);

        VOICE_PROCESSED* pvoice = &voices[ch];

        switch(r&0x0f)
        {
            case 0:
            case 2:
                pvoice->SetVolume(mem&0x2);
                break;
            case 4:
            {
                int NP;
                if(value>0x3fff) NP=0x3fff;                             // get pitch val
                else           NP=value;

                pvoice->pvoice->pitch = NP;

                NP=(44100L*NP)/4096L;                                 // calc frequency
                if(NP<1) NP=1;                                        // some security
                pvoice->iActFreq=NP;                               // store frequency
                break;
            }
            case 6:
            {
                pvoice->ADSRX.AttackModeExp=(value&0x8000)?1:0; 
                pvoice->ADSRX.AttackRate = ((value>>8) & 0x007f);
                pvoice->ADSRX.DecayRate = (((value>>4) & 0x000f));
                pvoice->ADSRX.SustainLevel = (value & 0x000f);
                break;
            }
            case 8:
                pvoice->ADSRX.SustainModeExp = (value&0x8000)?1:0;
                pvoice->ADSRX.SustainIncrease= (value&0x4000)?0:1;
                pvoice->ADSRX.SustainRate = ((value>>6) & 0x007f);
                pvoice->ADSRX.ReleaseModeExp = (value&0x0020)?1:0;
                pvoice->ADSRX.ReleaseRate = ((value & 0x001f));
                break;
        }

        return;
    }
    
    // more channel info
    if((r>=0x01c0 && r<=0x02E0)||(r>=0x05c0 && r<=0x06E0))
    {
        int ch=0;
        unsigned long rx=r;
        if(rx>=0x400)
        {
            ch=24;
            rx-=0x400;
        }

        ch+=((rx-0x1c0)/12);
        rx-=(ch%24)*12;
        VOICE_PROCESSED* pvoice = &voices[ch];

        switch(rx)
        {
            case 0x1C0:
                pvoice->iStartAddr=(((unsigned long)value&0x3f)<<16)|(pvoice->iStartAddr&0xFFFF);
                pvoice->pStart=(u8*)(spu2mem+pvoice->iStartAddr);
                break;
            case 0x1C2:
                pvoice->iStartAddr=(pvoice->iStartAddr & 0x3f0000) | (value & 0xFFFF);
                pvoice->pStart=(u8*)(spu2mem+pvoice->iStartAddr);
                break;
            case 0x1C4:
                pvoice->iLoopAddr =(((unsigned long)value&0x3f)<<16)|(pvoice->iLoopAddr&0xFFFF);
                pvoice->pLoop=(u8*)(spu2mem+pvoice->iLoopAddr);
                pvoice->bIgnoreLoop=pvoice->iLoopAddr>0;
                break;
            case 0x1C6:
                pvoice->iLoopAddr=(pvoice->iLoopAddr& 0x3f0000) | (value & 0xFFFF);
                pvoice->pLoop=(u8*)(spu2mem+pvoice->iLoopAddr);
                pvoice->bIgnoreLoop=pvoice->iLoopAddr>0;
                break;
            case 0x1C8:
                // unused... check if it gets written as well
                pvoice->iNextAddr=(((unsigned long)value&0x3f)<<16)|(pvoice->iNextAddr&0xFFFF);
                break;
            case 0x1CA:
                // unused... check if it gets written as well
                pvoice->iNextAddr=(pvoice->iNextAddr & 0x3f0000) | (value & 0xFFFF);
                break;
        }

        return;
    }

    // process non-channel data
    switch(mem&0xffff) {
        case REG_C0_SPUDATA:
            spuaddr = C0_SPUADDR;
            spu2mem[spuaddr] = value;
            spuaddr++;
            if( (spu2Ru16(REG_C0_CTRL)&0x40) && C0_IRQA == spuaddr){
                spu2Ru16(SPDIF_OUT) |= 0x4;
                IRQINFO |= 4;
                irqCallbackSPU2();
            }
            if(spuaddr>0xFFFFE)
                spuaddr = 0x2800;
            C0_SPUADDR_SET(spuaddr);
            spu2Ru16(REG_C0_SPUSTAT)&=~0x80;
            spu2Ru16(REG_C0_CTRL)&=~0x30;
            break;
        case REG_C1_SPUDATA:
            spuaddr = C1_SPUADDR;
            spu2mem[spuaddr] = value;
            spuaddr++;
            if( (spu2Ru16(REG_C1_CTRL)&0x40) && C1_IRQA == spuaddr){
                spu2Ru16(SPDIF_OUT) |= 0x8;
                IRQINFO |= 8;
                irqCallbackSPU2();
            }
            if(spuaddr>0xFFFFE)
                spuaddr = 0x2800;
            C1_SPUADDR_SET(spuaddr);
            spu2Ru16(REG_C1_SPUSTAT)&=~0x80;
            spu2Ru16(REG_C1_CTRL)&=~0x30;
            break;
        case REG_C0_IRQA_HI:
        case REG_C0_IRQA_LO:
            pSpuIrq[0]=spu2mem+(C0_IRQA<<1);
            break;
        case REG_C1_IRQA_HI:
        case REG_C1_IRQA_LO:
            pSpuIrq[1]=spu2mem+(C1_IRQA<<1);
            break;

        case REG_C0_SPUADDR_HI:
        case REG_C1_SPUADDR_HI:
            spu2Ru16(mem) = value&0xf;
            break;

        case REG_C0_SPUON1: SoundOn(0,16,value); break;
        case REG_C0_SPUON2: SoundOn(16,24,value); break;
        case REG_C1_SPUON1: SoundOn(24,40,value); break;
        case REG_C1_SPUON2: SoundOn(40,48,value); break;
        case REG_C0_SPUOFF1: SoundOff(0,16,value); break;
        case REG_C0_SPUOFF2: SoundOff(16,24,value); break;
        case REG_C1_SPUOFF1: SoundOff(24,40,value); break;
        case REG_C1_SPUOFF2: SoundOff(40,48,value); break;

        // According to manual all bits are cleared by writing an arbitary value
        case REG_C0_END1: dwEndChannel2[0] = 0; break;
        case REG_C0_END2: dwEndChannel2[0] = 0; break;
        case REG_C1_END1: dwEndChannel2[1] = 0; break;
        case REG_C1_END2: dwEndChannel2[1] = 0; break;
        case REG_C0_FMOD1: FModOn(0,16,value); break;
        case REG_C0_FMOD2: FModOn(16,24,value); break;
        case REG_C1_FMOD1: FModOn(24,40,value); break;
        case REG_C1_FMOD2: FModOn(40,48,value); break;
   }

    assert( C0_SPUADDR < 0x100000);
    assert( C1_SPUADDR < 0x100000);
}

u16  CALLBACK SPU2read(u32 mem)
{
    u32 spuaddr;
	u16 ret;
    u32 r = mem&0xffff;

    if((r>=0x0000 && r<=0x0180)||(r>=0x0400 && r<=0x0580))  // some channel info?
    {
        int ch=0;
        if(r>=0x400) ch=((r-0x400)>>4)+24;
        else ch=(r>>4);

        VOICE_PROCESSED* pvoice = &voices[ch];
                
        switch(r&0x0f) {
            case 10: return (unsigned short)(pvoice->ADSRX.EnvelopeVol>>16);
        }
    }

    if((r>0x01c0 && r<=0x02E0)||(r>0x05c0 && r<=0x06E0))  // some channel info?
    {
        int ch=0;
        unsigned long rx=r;
        if(rx>=0x400)
        {
            ch=24;
            rx-=0x400;
        }

        ch+=((rx-0x1c0)/12);
        rx-=(ch%24)*12;
        VOICE_PROCESSED* pvoice = &voices[ch];

        switch(rx) {
            case 0x1C0: return (u16)(((pvoice->pStart-(u8*)spu2mem)>>17)&0x3F);
            case 0x1C2: return (u16)(((pvoice->pStart-(u8*)spu2mem)>>1)&0xFFFF);
            case 0x1C4: return (u16)(((pvoice->pLoop-(u8*)spu2mem)>>17)&0x3F);
            case 0x1C6: return (u16)(((pvoice->pLoop-(u8*)spu2mem)>>1)&0xFFFF);
            case 0x1C8: return (u16)(((pvoice->pCurr-(u8*)spu2mem)>>17)&0x3F);
            case 0x1CA: return (u16)(((pvoice->pCurr-(u8*)spu2mem)>>1)&0xFFFF);
        }
    }

	switch(mem&0xffff) {
        case REG_C0_SPUDATA:
            spuaddr = C0_SPUADDR;
            ret =spu2mem[spuaddr];
            spuaddr++;
            if(spuaddr>0xfffff)
                spuaddr=0;
            C0_SPUADDR_SET(spuaddr);
            break;
        case REG_C1_SPUDATA:
            spuaddr = C1_SPUADDR;
            ret = spu2mem[spuaddr];
            spuaddr++;
            if(spuaddr>0xfffff)
                spuaddr=0;
            C1_SPUADDR_SET(spuaddr);
            break;

        case REG_C0_END1: return (dwEndChannel2[0]&0xffff);
        case REG_C0_END2: return (dwEndChannel2[0]>>16);
        case REG_C1_END1: return (dwEndChannel2[1]&0xffff);
        case REG_C1_END2: return (dwEndChannel2[1]>>16);

        case REG_IRQINFO:
            ret = IRQINFO;
            IRQINFO = 0;
            break;
		default:
			ret = spu2Ru16(mem);
	}
#ifdef SPU2_LOG
	SPU2_LOG("SPU2 read mem %x: %x\n", mem, ret);
#endif	

	return ret;
}

void CALLBACK SPU2WriteMemAddr(int core, u32 value)
{
	MemAddr[core] = value;
}

u32 CALLBACK SPU2ReadMemAddr(int core)
{
	return MemAddr[core];
}

void CALLBACK SPU2irqCallback(void (*SPU2callback)(),void (*DMA4callback)(),void (*DMA7callback)())
{
    irqCallbackSPU2 = SPU2callback;
    irqCallbackDMA4 = DMA4callback;
    irqCallbackDMA7 = DMA7callback;
}

// VOICE_PROCESSED definitions
SPU_CONTROL_* VOICE_PROCESSED::GetCtrl()
{
    return ((SPU_CONTROL_*)(spu2regs+memoffset+REG_C0_CTRL));
}

void VOICE_PROCESSED::SetVolume(int iProcessRight)
{
    u16 vol = iProcessRight ? pvoice->right.word : pvoice->left.word;

    if(vol&0x8000) // sweep not working
    {
        short sInc=1;                                       // -> sweep up?
        if(vol&0x2000) sInc=-1;                             // -> or down?
        if(vol&0x1000) vol^=0xffff;                         // -> mmm... phase inverted? have to investigate this
        vol=((vol&0x7f)+1)/2;                               // -> sweep: 0..127 -> 0..64
        vol+=vol/(2*sInc);                                  // -> HACK: we don't sweep right now, so we just raise/lower the volume by the half!
        vol*=128;
    }
    else                                                  // no sweep:
    {
        if(vol&0x4000)                                      // -> mmm... phase inverted? have to investigate this
        vol=0x3fff-(vol&0x3fff);
    }

    vol&=0x3fff;
    // set volume
    //if( iProcessRight ) right = vol;
    //else left = vol;
}

void VOICE_PROCESSED::StartSound()
{
    ADSRX.lVolume=1; // and init some adsr vars
    ADSRX.State=0;
    ADSRX.EnvelopeVol=0;
                            
    if(bReverb && GetCtrl()->reverb )
    {
        // setup the reverb effects
    }
    
    pCurr=pStart;   // set sample start
    iSBPos=28;

    bNew=false;         // init channel flags
    bStop=false;
    bOn=true;
    spos=0x10000L;
}

void VOICE_PROCESSED::VoiceChangeFrequency()
{
    iUsedFreq=iActFreq;               // -> take it and calc steps
    sinc=(u32)pvoice->pitch<<4;
    if(!sinc)
        sinc=1;
}

void VOICE_PROCESSED::Stop()
{
}

// GUI Routines
s32 CALLBACK SPU2test() {
	return 0;
}

typedef struct {
    u32 version;
	u8 spu2regs[0x10000];
} SPU2freezeData;

s32  CALLBACK SPU2freeze(int mode, freezeData *data){
	SPU2freezeData *spud;

	if (mode == FREEZE_LOAD) {
		spud = (SPU2freezeData*)data->data;
        if( spud->version == 0x11223344 ) {
		    memcpy(spu2regs, spud->spu2regs, 0x10000);
        }
        else printf("SPU2null wrong format\n");
	} else
	if (mode == FREEZE_SAVE) {
		spud = (SPU2freezeData*)data->data;
        spud->version = 0x11223344;
		memcpy(spud->spu2regs, spu2regs, 0x10000);
	} else
	if (mode == FREEZE_SIZE) {
		data->size = sizeof(SPU2freezeData);
	}

	return 0;
}

#ifndef _WIN32

GtkWidget *MsgDlg;

void OnMsg_Ok() {
	gtk_widget_destroy(MsgDlg);
	gtk_main_quit();
}

void SysMessage(char *fmt, ...) {
	GtkWidget *Ok,*Txt;
	GtkWidget *Box,*Box1;
	va_list list;
	char msg[512];

	va_start(list, fmt);
	vsprintf(msg, fmt, list);
	va_end(list);

	if (msg[strlen(msg)-1] == '\n') msg[strlen(msg)-1] = 0;
    
	MsgDlg = gtk_window_new (GTK_WINDOW_POPUP);
	gtk_window_set_position(GTK_WINDOW(MsgDlg), GTK_WIN_POS_CENTER);
	gtk_window_set_title(GTK_WINDOW(MsgDlg), "SPU2null Msg");
	gtk_container_set_border_width(GTK_CONTAINER(MsgDlg), 5);

	Box = gtk_vbox_new(5, 0);
	gtk_container_add(GTK_CONTAINER(MsgDlg), Box);
	gtk_widget_show(Box);

	Txt = gtk_label_new(msg);
	
	gtk_box_pack_start(GTK_BOX(Box), Txt, FALSE, FALSE, 5);
	gtk_widget_show(Txt);

	Box1 = gtk_hbutton_box_new();
	gtk_box_pack_start(GTK_BOX(Box), Box1, FALSE, FALSE, 0);
	gtk_widget_show(Box1);

	Ok = gtk_button_new_with_label("Ok");
	gtk_signal_connect (GTK_OBJECT(Ok), "clicked", GTK_SIGNAL_FUNC(OnMsg_Ok), NULL);
	gtk_container_add(GTK_CONTAINER(Box1), Ok);
	GTK_WIDGET_SET_FLAGS(Ok, GTK_CAN_DEFAULT);
	gtk_widget_show(Ok);

	gtk_widget_show(MsgDlg);	

	gtk_main();
}

void CALLBACK SPU2configure() {
	SysMessage("Nothing to Configure");
}

void CALLBACK SPU2about() {
	SysMessage("%s %d.%d", libraryName, version, build);
}

void LoadConfig()
{
}

#endif