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|
/*
Sega/Yamaha AICA emulation
By ElSemi, kingshriek, and R. Belmont
This is effectively a 64-voice SCSP, with the following differences:
- No FM mode
- A third sample format (ADPCM) has been added
- Some minor other tweeks
*/
#include <math.h>
#include <string.h>
#include "ao.h"
#include "cpuintrf.h"
#include "aica.h"
#include "aicadsp.h"
#include "dc_hw.h"
#define ICLIP16(x) (x<-32768)?-32768:((x>32767)?32767:x)
#define SHIFT 12
#define FIX(v) ((UINT32) ((float) (1<<SHIFT)*(v)))
#define EG_SHIFT 16
#define USEDSP
// include the LFO handling code
#include "aicalfo.c"
/*
AICA features 64 programmable slots
that can generate PCM and ADPCM (from ROM/RAM) sound
*/
//SLOT PARAMETERS
#define KEYONEX(slot) ((slot->udata.data[0x0]>>0x0)&0x8000)
#define KEYONB(slot) ((slot->udata.data[0x0]>>0x0)&0x4000)
#define SSCTL(slot) ((slot->udata.data[0x0]>>0xA)&0x0001)
#define LPCTL(slot) ((slot->udata.data[0x0]>>0x9)&0x0001)
#define PCMS(slot) ((slot->udata.data[0x0]>>0x7)&0x0003)
#define SA(slot) (((slot->udata.data[0x0]&0x7F)<<16)|(slot->udata.data[0x4/2]))
#define LSA(slot) (slot->udata.data[0x8/2])
#define LEA(slot) (slot->udata.data[0xc/2])
#define D2R(slot) ((slot->udata.data[0x10/2]>>0xB)&0x001F)
#define D1R(slot) ((slot->udata.data[0x10/2]>>0x6)&0x001F)
#define AR(slot) ((slot->udata.data[0x10/2]>>0x0)&0x001F)
#define LPSLNK(slot) ((slot->udata.data[0x14/2]>>0x0)&0x4000)
#define KRS(slot) ((slot->udata.data[0x14/2]>>0xA)&0x000F)
#define DL(slot) ((slot->udata.data[0x14/2]>>0x5)&0x001F)
#define RR(slot) ((slot->udata.data[0x14/2]>>0x0)&0x001F)
#define TL(slot) ((slot->udata.data[0x28/2]>>0x8)&0x00FF)
#define OCT(slot) ((slot->udata.data[0x18/2]>>0xB)&0x000F)
#define FNS(slot) ((slot->udata.data[0x18/2]>>0x0)&0x03FF)
#define LFORE(slot) ((slot->udata.data[0x1c/2]>>0x0)&0x8000)
#define LFOF(slot) ((slot->udata.data[0x1c/2]>>0xA)&0x001F)
#define PLFOWS(slot) ((slot->udata.data[0x1c/2]>>0x8)&0x0003)
#define PLFOS(slot) ((slot->udata.data[0x1c/2]>>0x5)&0x0007)
#define ALFOWS(slot) ((slot->udata.data[0x1c/2]>>0x3)&0x0003)
#define ALFOS(slot) ((slot->udata.data[0x1c/2]>>0x0)&0x0007)
#define ISEL(slot) ((slot->udata.data[0x20/2]>>0x0)&0x000F)
#define IMXL(slot) ((slot->udata.data[0x20/2]>>0x4)&0x000F)
#define DISDL(slot) ((slot->udata.data[0x24/2]>>0x8)&0x000F)
#define DIPAN(slot) ((slot->udata.data[0x24/2]>>0x0)&0x001F)
#define EFSDL(slot) ((AICA->EFSPAN[slot*4]>>8)&0x000f)
#define EFPAN(slot) ((AICA->EFSPAN[slot*4]>>0)&0x001f)
//Envelope times in ms
static const double ARTimes[64]={100000/*infinity*/,100000/*infinity*/,8100.0,6900.0,6000.0,4800.0,4000.0,3400.0,3000.0,2400.0,2000.0,1700.0,1500.0,
1200.0,1000.0,860.0,760.0,600.0,500.0,430.0,380.0,300.0,250.0,220.0,190.0,150.0,130.0,110.0,95.0,
76.0,63.0,55.0,47.0,38.0,31.0,27.0,24.0,19.0,15.0,13.0,12.0,9.4,7.9,6.8,6.0,4.7,3.8,3.4,3.0,2.4,
2.0,1.8,1.6,1.3,1.1,0.93,0.85,0.65,0.53,0.44,0.40,0.35,0.0,0.0};
static const double DRTimes[64]={100000/*infinity*/,100000/*infinity*/,118200.0,101300.0,88600.0,70900.0,59100.0,50700.0,44300.0,35500.0,29600.0,25300.0,22200.0,17700.0,
14800.0,12700.0,11100.0,8900.0,7400.0,6300.0,5500.0,4400.0,3700.0,3200.0,2800.0,2200.0,1800.0,1600.0,1400.0,1100.0,
920.0,790.0,690.0,550.0,460.0,390.0,340.0,270.0,230.0,200.0,170.0,140.0,110.0,98.0,85.0,68.0,57.0,49.0,43.0,34.0,
28.0,25.0,22.0,18.0,14.0,12.0,11.0,8.5,7.1,6.1,5.4,4.3,3.6,3.1};
static UINT32 FNS_Table[0x400];
static INT32 EG_TABLE[0x400];
typedef enum {ATTACK,DECAY1,DECAY2,RELEASE} _STATE;
struct _EG
{
int volume; //
_STATE state;
int step;
//step vals
int AR; //Attack
int D1R; //Decay1
int D2R; //Decay2
int RR; //Release
int DL; //Decay level
UINT8 LPLINK;
};
struct _SLOT
{
union
{
UINT16 data[0x40]; //only 0x1a bytes used
UINT8 datab[0x80];
} udata;
UINT8 active; //this slot is currently playing
UINT8 *base; //samples base address
UINT32 prv_addr; // previous play address (for ADPCM)
UINT32 cur_addr; //current play address (24.8)
UINT32 nxt_addr; //next play address
UINT32 step; //pitch step (24.8)
UINT8 Backwards; //the wave is playing backwards
struct _EG EG; //Envelope
struct _EG FEG; //filter envelope
struct _LFO PLFO; //Phase LFO
struct _LFO ALFO; //Amplitude LFO
int slot;
int cur_sample; //current ADPCM sample
int cur_quant; //current ADPCM step
int curstep;
int cur_lpquant, cur_lpsample, cur_lpstep;
UINT8 *adbase, *adlpbase;
UINT8 mslc; // monitored?
};
#define MEM4B(aica) ((aica->udata.data[0]>>0x0)&0x0200)
#define DAC18B(aica) ((aica->udata.data[0]>>0x0)&0x0100)
#define MVOL(aica) ((aica->udata.data[0]>>0x0)&0x000F)
#define RBL(aica) ((aica->udata.data[2]>>0xD)&0x0003)
#define RBP(aica) ((aica->udata.data[2]>>0x0)&0x0fff)
#define MOFULL(aica) ((aica->udata.data[4]>>0x0)&0x1000)
#define MOEMPTY(aica) ((aica->udata.data[4]>>0x0)&0x0800)
#define MIOVF(aica) ((aica->udata.data[4]>>0x0)&0x0400)
#define MIFULL(aica) ((aica->udata.data[4]>>0x0)&0x0200)
#define MIEMPTY(aica) ((aica->udata.data[4]>>0x0)&0x0100)
#define AFSEL(aica) ((aica->udata.data[6]>>0x0)&0x4000)
#define MSLC(aica) ((aica->udata.data[6]>>0x8)&0x3F)
#define SCILV0(aica) ((aica->udata.data[0xa8/2]>>0x0)&0xff)
#define SCILV1(aica) ((aica->udata.data[0xac/2]>>0x0)&0xff)
#define SCILV2(aica) ((aica->udata.data[0xb0/2]>>0x0)&0xff)
#define SCIEX0 0
#define SCIEX1 1
#define SCIEX2 2
#define SCIMID 3
#define SCIDMA 4
#define SCIIRQ 5
#define SCITMA 6
#define SCITMB 7
struct _AICA
{
union
{
UINT16 data[0xc0/2];
UINT8 datab[0xc0];
} udata;
UINT16 IRQL, IRQR;
UINT16 EFSPAN[0x48];
struct _SLOT Slots[64];
signed short RINGBUF[64];
unsigned char BUFPTR;
unsigned char *AICARAM;
UINT32 AICARAM_LENGTH;
char Master;
void (*IntARMCB)(struct sARM7 *cpu, int irq);
INT32 *buffertmpl, *buffertmpr;
UINT32 IrqTimA;
UINT32 IrqTimBC;
UINT32 IrqMidi;
UINT8 MidiOutW,MidiOutR;
UINT8 MidiStack[16];
UINT8 MidiW,MidiR;
int LPANTABLE[0x20000];
int RPANTABLE[0x20000];
int TimPris[3];
int TimCnt[3];
// DMA stuff
UINT32 aica_dmea;
UINT16 aica_drga;
UINT16 aica_dtlg;
int ARTABLE[64], DRTABLE[64];
struct _AICADSP DSP;
struct sARM7 *cpu;
INT16 *bufferl;
INT16 *bufferr;
int length;
signed short *RBUFDST; //this points to where the sample will be stored in the RingBuf
};
//static struct _AICA *AllocedAICA;
static const float SDLT[16]={-1000000.0,-42.0,-39.0,-36.0,-33.0,-30.0,-27.0,-24.0,-21.0,-18.0,-15.0,-12.0,-9.0,-6.0,-3.0,0.0};
static unsigned char DecodeSCI(struct _AICA *AICA, unsigned char irq)
{
unsigned char SCI=0;
unsigned char v;
v=(SCILV0((AICA))&(1<<irq))?1:0;
SCI|=v;
v=(SCILV1((AICA))&(1<<irq))?1:0;
SCI|=v<<1;
v=(SCILV2((AICA))&(1<<irq))?1:0;
SCI|=v<<2;
return SCI;
}
static void ResetInterrupts(struct _AICA *AICA)
{
#if 0
UINT32 reset = AICA->udata.data[0xa4/2];
if (reset & 0x40)
AICA->IntARMCB(-AICA->IrqTimA);
if (reset & 0x180)
AICA->IntARMCB(-AICA->IrqTimBC);
#endif
}
static void CheckPendingIRQ(struct _AICA *AICA)
{
UINT32 pend=AICA->udata.data[0xa0/2];
UINT32 en=AICA->udata.data[0x9c/2];
if(AICA->MidiW!=AICA->MidiR)
{
AICA->IRQL = AICA->IrqMidi;
AICA->IntARMCB(AICA->cpu, 1);
return;
}
if(!pend)
return;
if(pend&0x40)
if(en&0x40)
{
AICA->IRQL = AICA->IrqTimA;
AICA->IntARMCB(AICA->cpu, 1);
return;
}
if(pend&0x80)
if(en&0x80)
{
AICA->IRQL = AICA->IrqTimBC;
AICA->IntARMCB(AICA->cpu, 1);
return;
}
if(pend&0x100)
if(en&0x100)
{
AICA->IRQL = AICA->IrqTimBC;
AICA->IntARMCB(AICA->cpu, 1);
return;
}
}
static int Get_AR(struct _AICA *AICA,int base,int R)
{
int Rate=base+(R<<1);
if(Rate>63) Rate=63;
if(Rate<0) Rate=0;
return AICA->ARTABLE[Rate];
}
static int Get_DR(struct _AICA *AICA,int base,int R)
{
int Rate=base+(R<<1);
if(Rate>63) Rate=63;
if(Rate<0) Rate=0;
return AICA->DRTABLE[Rate];
}
static int Get_RR(struct _AICA *AICA,int base,int R)
{
int Rate=base+(R<<1);
if(Rate>63) Rate=63;
if(Rate<0) Rate=0;
return AICA->DRTABLE[Rate];
}
static void Compute_EG(struct _AICA *AICA,struct _SLOT *slot)
{
int octave=OCT(slot);
int rate;
if(octave&8) octave=octave-16;
if(KRS(slot)!=0xf)
rate=octave+2*KRS(slot)+((FNS(slot)>>9)&1);
else
rate=0; //rate=((FNS(slot)>>9)&1);
slot->EG.volume=0x17f<<EG_SHIFT;
slot->EG.AR=Get_AR(AICA,rate,AR(slot));
slot->EG.D1R=Get_DR(AICA,rate,D1R(slot));
slot->EG.D2R=Get_DR(AICA,rate,D2R(slot));
slot->EG.RR=Get_RR(AICA,rate,RR(slot));
slot->EG.DL=0x1f-DL(slot);
}
static void AICA_StopSlot(struct _SLOT *slot,int keyoff);
static int EG_Update(struct _SLOT *slot)
{
switch(slot->EG.state)
{
case ATTACK:
slot->EG.volume+=slot->EG.AR;
if(slot->EG.volume>=(0x3ff<<EG_SHIFT))
{
if (!LPSLNK(slot))
{
slot->EG.state=DECAY1;
if(slot->EG.D1R>=(1024<<EG_SHIFT)) //Skip DECAY1, go directly to DECAY2
slot->EG.state=DECAY2;
}
slot->EG.volume=0x3ff<<EG_SHIFT;
}
break;
case DECAY1:
slot->EG.volume-=slot->EG.D1R;
if(slot->EG.volume<=0)
slot->EG.volume=0;
if(slot->EG.volume>>(EG_SHIFT+5)<slot->EG.DL)
slot->EG.state=DECAY2;
break;
case DECAY2:
if(D2R(slot)==0)
return (slot->EG.volume>>EG_SHIFT)<<(SHIFT-10);
slot->EG.volume-=slot->EG.D2R;
if(slot->EG.volume<=0)
slot->EG.volume=0;
break;
case RELEASE:
slot->EG.volume-=slot->EG.RR;
if(slot->EG.volume<=0)
{
slot->EG.volume=0;
AICA_StopSlot(slot,0);
// slot->EG.volume=0x17f<<EG_SHIFT;
// slot->EG.state=ATTACK;
}
break;
default:
return 1<<SHIFT;
}
return (slot->EG.volume>>EG_SHIFT)<<(SHIFT-10);
}
static UINT32 AICA_Step(struct _SLOT *slot)
{
int octave=OCT(slot);
UINT32 Fn;
Fn=(FNS_Table[FNS(slot)]); //24.8
if(octave&8)
Fn>>=(16-octave);
else
Fn<<=octave;
return Fn/(44100);
}
static void Compute_LFO(struct _SLOT *slot)
{
if(PLFOS(slot)!=0)
AICALFO_ComputeStep(&(slot->PLFO),LFOF(slot),PLFOWS(slot),PLFOS(slot),0);
if(ALFOS(slot)!=0)
AICALFO_ComputeStep(&(slot->ALFO),LFOF(slot),ALFOWS(slot),ALFOS(slot),1);
}
#define ADPCMSHIFT 8
#define ADFIX(f) (int) ((float) f*(float) (1<<ADPCMSHIFT))
const int TableQuant[8]={ADFIX(0.8984375),ADFIX(0.8984375),ADFIX(0.8984375),ADFIX(0.8984375),ADFIX(1.19921875),ADFIX(1.59765625),ADFIX(2.0),ADFIX(2.3984375)};
const int quant_mul[16]= { 1, 3, 5, 7, 9, 11, 13, 15, -1, -3, -5, -7, -9, -11, -13, -15};
void InitADPCM(int *PrevSignal, int *PrevQuant)
{
*PrevSignal=0;
*PrevQuant=0x7f;
}
INLINE signed short DecodeADPCM(int *PrevSignal, unsigned char Delta, int *PrevQuant)
{
int x = *PrevQuant * quant_mul [Delta & 15];
x = *PrevSignal + ((int)(x + ((UINT32)x >> 29)) >> 3);
*PrevSignal=ICLIP16(x);
*PrevQuant=(*PrevQuant*TableQuant[Delta&7])>>ADPCMSHIFT;
*PrevQuant=(*PrevQuant<0x7f)?0x7f:((*PrevQuant>0x6000)?0x6000:*PrevQuant);
return *PrevSignal;
}
static void AICA_StartSlot(struct _AICA *AICA, struct _SLOT *slot)
{
UINT64 start_offset;
slot->active=1;
slot->Backwards=0;
slot->cur_addr=0; slot->nxt_addr=1<<SHIFT; slot->prv_addr=-1;
start_offset = SA(slot); // AICA can play 16-bit samples from any boundry
slot->base=&AICA->AICARAM[start_offset];
slot->step=AICA_Step(slot);
Compute_EG(AICA,slot);
slot->EG.state=ATTACK;
slot->EG.volume=0x17f<<EG_SHIFT;
Compute_LFO(slot);
if (PCMS(slot) >= 2)
{
UINT8 *base;
UINT32 curstep, steps_to_go;
slot->curstep = 0;
slot->adbase = (unsigned char *) (AICA->AICARAM+((SA(slot))&0x7fffff));
InitADPCM(&(slot->cur_sample), &(slot->cur_quant));
InitADPCM(&(slot->cur_lpsample), &(slot->cur_lpquant));
// walk to the ADPCM state at LSA
curstep = 0;
base = slot->adbase;
steps_to_go = LSA(slot);
while (curstep < steps_to_go)
{
int shift1, delta1;
shift1 = 4*((curstep&1));
delta1 = (*base>>shift1)&0xf;
DecodeADPCM(&(slot->cur_lpsample),delta1,&(slot->cur_lpquant));
curstep++;
if (!(curstep & 1))
{
base++;
}
}
slot->cur_lpstep = curstep;
slot->adlpbase = base;
// on real hardware this creates undefined behavior.
if (LSA(slot) > LEA(slot))
{
slot->udata.data[0xc/2] = 0xffff;
}
}
}
static void AICA_StopSlot(struct _SLOT *slot,int keyoff)
{
if(keyoff /*&& slot->EG.state!=RELEASE*/)
{
slot->EG.state=RELEASE;
}
else
{
slot->active=0;
}
slot->udata.data[0]&=~0x4000;
}
#define log_base_2(n) (log((float) n)/log((float) 2))
static void AICA_Init(struct _AICA *AICA, const struct AICAinterface *intf)
{
printf ("AICA_Init(cpu=%p)\n", intf->cpu);
int i=0;
AICA->IrqTimA = AICA->IrqTimBC = AICA->IrqMidi = 0;
AICA->MidiR=AICA->MidiW=0;
AICA->MidiOutR=AICA->MidiOutW=0;
// get AICA RAM
{
memset(AICA,0,sizeof(*AICA));
if (!i)
{
AICA->Master=1;
}
else
{
AICA->Master=0;
}
if (intf->region)
{
AICA->AICARAM = &intf->cpu->dc_ram[0];
AICA->AICARAM_LENGTH = 2*1024*1024;
AICA->DSP.AICARAM = (UINT16 *)AICA->AICARAM;
AICA->DSP.AICARAM_LENGTH = (2*1024*1024)/2;
AICA->cpu = intf->cpu;
}
}
for(i=0;i<0x400;++i)
{
float fcent=(double) 1200.0*log_base_2((double)(((double) 1024.0+(double)i)/(double)1024.0));
fcent=(double) 44100.0*pow(2.0,fcent/1200.0);
FNS_Table[i]=(float) (1<<SHIFT) *fcent;
}
for(i=0;i<0x400;++i)
{
float envDB=((float)(3*(i-0x3ff)))/32.0;
float scale=(float)(1<<SHIFT);
EG_TABLE[i]=(INT32)(pow(10.0,envDB/20.0)*scale);
}
for(i=0;i<0x20000;++i)
{
int iTL =(i>>0x0)&0xff;
int iPAN=(i>>0x8)&0x1f;
int iSDL=(i>>0xD)&0x0F;
float TL=1.0;
float SegaDB=0;
float fSDL=1.0;
float PAN=1.0;
float LPAN,RPAN;
if(iTL&0x01) SegaDB-=0.4;
if(iTL&0x02) SegaDB-=0.8;
if(iTL&0x04) SegaDB-=1.5;
if(iTL&0x08) SegaDB-=3;
if(iTL&0x10) SegaDB-=6;
if(iTL&0x20) SegaDB-=12;
if(iTL&0x40) SegaDB-=24;
if(iTL&0x80) SegaDB-=48;
TL=pow(10.0,SegaDB/20.0);
SegaDB=0;
if(iPAN&0x1) SegaDB-=3;
if(iPAN&0x2) SegaDB-=6;
if(iPAN&0x4) SegaDB-=12;
if(iPAN&0x8) SegaDB-=24;
if((iPAN&0xf)==0xf) PAN=0.0;
else PAN=pow(10.0,SegaDB/20.0);
if(iPAN<0x10)
{
LPAN=PAN;
RPAN=1.0;
}
else
{
RPAN=PAN;
LPAN=1.0;
}
if(iSDL)
fSDL=pow(10.0,(SDLT[iSDL])/20.0);
else
fSDL=0.0;
AICA->LPANTABLE[i]=FIX((4.0*LPAN*TL*fSDL));
AICA->RPANTABLE[i]=FIX((4.0*RPAN*TL*fSDL));
}
AICA->ARTABLE[0]=AICA->DRTABLE[0]=0; //Infinite time
AICA->ARTABLE[1]=AICA->DRTABLE[1]=0; //Infinite time
for(i=2;i<64;++i)
{
double t,step,scale;
t=ARTimes[i]; //In ms
if(t!=0.0)
{
step=(1023*1000.0)/((float) 44100.0f*t);
scale=(double) (1<<EG_SHIFT);
AICA->ARTABLE[i]=(int) (step*scale);
}
else
AICA->ARTABLE[i]=1024<<EG_SHIFT;
t=DRTimes[i]; //In ms
step=(1023*1000.0)/((float) 44100.0f*t);
scale=(double) (1<<EG_SHIFT);
AICA->DRTABLE[i]=(int) (step*scale);
}
// make sure all the slots are off
for(i=0;i<64;++i)
{
AICA->Slots[i].slot=i;
AICA->Slots[i].active=0;
AICA->Slots[i].base=NULL;
AICA->Slots[i].EG.state=RELEASE;
AICA->Slots[i].mslc=0;
}
AICALFO_Init();
AICA->buffertmpl=(signed int*) malloc(44100*sizeof(signed int));
AICA->buffertmpr=(signed int*) malloc(44100*sizeof(signed int));
memset(AICA->buffertmpl,0,44100*sizeof(signed int));
memset(AICA->buffertmpr,0,44100*sizeof(signed int));
// no "pend"
AICA[0].udata.data[0xa0/2] = 0;
//AICA[1].udata.data[0x20/2] = 0;
AICA->TimCnt[0] = 0xffff;
AICA->TimCnt[1] = 0xffff;
AICA->TimCnt[2] = 0xffff;
}
static void AICA_UpdateSlotReg(struct _AICA *AICA,int s,int r)
{
struct _SLOT *slot=AICA->Slots+s;
int sl;
switch(r&0x7f)
{
case 0:
case 1:
if(KEYONEX(slot))
{
for(sl=0;sl<64;++sl)
{
struct _SLOT *s2=AICA->Slots+sl;
{
if(KEYONB(s2) && s2->EG.state==RELEASE/*&& !s2->active*/)
{
if(s2->mslc) AICA->udata.data[0x10] &= 0x7FFF; // reset LP at KEY_ON
AICA_StartSlot(AICA, s2);
#if 0
printf("StartSlot[%02X]: SSCTL %01X SA %06X LSA %04X LEA %04X PCMS %01X LPCTL %01X\n",sl,SSCTL(s2),SA(s2),LSA(s2),LEA(s2),PCMS(s2),LPCTL(s2));
printf(" AR %02X D1R %02X D2R %02X RR %02X DL %02X KRS %01X LPSLNK %01X\n",AR(s2),D1R(s2),D2R(s2),RR(s2),DL(s2),KRS(s2),LPSLNK(s2)>>14);
printf(" TL %02X OCT %01X FNS %03X\n",TL(s2),OCT(s2),FNS(s2));
printf(" LFORE %01X LFOF %02X ALFOWS %01X ALFOS %01X PLFOWS %01X PLFOS %01X\n",LFORE(s2),LFOF(s2),ALFOWS(s2),ALFOS(s2),PLFOWS(s2),PLFOS(s2));
printf(" IMXL %01X ISEL %01X DISDL %01X DIPAN %02X\n",IMXL(s2),ISEL(s2),DISDL(s2),DIPAN(s2));
printf("\n");
fflush(stdout);
#endif
}
if(!KEYONB(s2) /*&& s2->active*/)
{
AICA_StopSlot(s2,1);
}
}
}
slot->udata.data[0]&=~0x8000;
}
break;
case 0x18:
case 0x19:
slot->step=AICA_Step(slot);
break;
case 0x14:
case 0x15:
slot->EG.RR=Get_RR(AICA,0,RR(slot));
slot->EG.DL=0x1f-DL(slot);
break;
case 0x1c:
case 0x1d:
Compute_LFO(slot);
break;
case 0x24:
// printf("[%02d]: %x to DISDL/DIPAN (PC=%x)\n", s, slot->udata.data[0x24/2], arm7_get_register(15));
break;
}
}
static void AICA_UpdateReg(struct _AICA *AICA, int reg)
{
switch(reg&0xff)
{
case 0x4:
case 0x5:
{
unsigned int v=RBL(AICA);
AICA->DSP.RBP=RBP(AICA);
if(v==0)
AICA->DSP.RBL=8*1024;
else if(v==1)
AICA->DSP.RBL=16*1024;
else if(v==2)
AICA->DSP.RBL=32*1024;
else if(v==3)
AICA->DSP.RBL=64*1024;
}
break;
case 0x8:
case 0x9:
AICA_MidiIn(AICA, 0, AICA->udata.data[0x8/2]&0xff, 0);
break;
case 0x12:
case 0x13:
case 0x14:
case 0x15:
case 0x16:
case 0x17:
break;
case 0x90:
case 0x91:
if(AICA->Master)
{
AICA->TimPris[0]=1<<((AICA->udata.data[0x90/2]>>8)&0x7);
AICA->TimCnt[0]=(AICA->udata.data[0x90/2]&0xff)<<8;
}
break;
case 0x94:
case 0x95:
if(AICA->Master)
{
AICA->TimPris[1]=1<<((AICA->udata.data[0x94/2]>>8)&0x7);
AICA->TimCnt[1]=(AICA->udata.data[0x94/2]&0xff)<<8;
}
break;
case 0x98:
case 0x99:
if(AICA->Master)
{
AICA->TimPris[2]=1<<((AICA->udata.data[0x98/2]>>8)&0x7);
AICA->TimCnt[2]=(AICA->udata.data[0x98/2]&0xff)<<8;
}
break;
case 0xa4: //SCIRE
case 0xa5:
if(AICA->Master)
{
AICA->udata.data[0xa0/2] &= ~AICA->udata.data[0xa4/2];
ResetInterrupts(AICA);
// behavior from real hardware (SCSP, assumed to carry over): if you SCIRE a timer that's expired,
// it'll immediately pop up again
if (AICA->TimCnt[0] >= 0xff00)
{
AICA->udata.data[0xa0/2] |= 0x40;
}
if (AICA->TimCnt[1] >= 0xff00)
{
AICA->udata.data[0xa0/2] |= 0x80;
}
if (AICA->TimCnt[2] >= 0xff00)
{
AICA->udata.data[0xa0/2] |= 0x100;
}
}
break;
case 0xa8:
case 0xa9:
case 0xac:
case 0xad:
case 0xb0:
case 0xb1:
if(AICA->Master)
{
AICA->IrqTimA=DecodeSCI(AICA,SCITMA);
AICA->IrqTimBC=DecodeSCI(AICA,SCITMB);
AICA->IrqMidi=DecodeSCI(AICA,SCIMID);
}
break;
}
}
static void AICA_UpdateSlotRegR(struct _AICA *AICA, int slot,int reg)
{
}
static void AICA_UpdateRegR(struct _AICA *AICA, int reg)
{
switch(reg&0xff)
{
case 8:
case 9:
{
unsigned short v=AICA->udata.data[0x8/2];
v&=0xff00;
v|=AICA->MidiStack[AICA->MidiR];
AICA->IntARMCB(AICA->cpu, 0); // cancel the IRQ
if(AICA->MidiR!=AICA->MidiW)
{
++AICA->MidiR;
AICA->MidiR&=15;
}
AICA->udata.data[0x8/2]=v;
}
break;
case 0x10: // LP check
case 0x11:
{
//int MSLC = (AICA->udata.data[0xc/2]>>8) & 0x3f; // which slot are we monitoring?
}
break;
case 0x14: // CA (slot address)
case 0x15:
{
int MSLC = (AICA->udata.data[0xc/2]>>8) & 0x3f; // which slot are we monitoring?
unsigned int CA = AICA->Slots[MSLC].cur_addr>>(SHIFT+12);
AICA->udata.data[0x14/2] = CA;
}
break;
}
}
static void AICA_w16(struct _AICA *AICA,unsigned int addr,unsigned short val)
{
addr&=0xffff;
if(addr<0x2000)
{
int slot=addr/0x80;
addr&=0x7f;
// printf("%x to slot %d offset %x\n", val, slot, addr);
*((unsigned short *) (AICA->Slots[slot].udata.datab+(addr))) = val;
AICA_UpdateSlotReg(AICA,slot,addr&0x7f);
}
else if (addr < 0x2800)
{
if (addr <= 0x2044)
{
// printf("%x to EFSxx slot %d (addr %x)\n", val, (addr-0x2000)/4, addr&0x7f);
AICA->EFSPAN[addr&0x7f] = val;
}
}
else if(addr<0x3000)
{
if (addr < 0x28be)
{
// printf("%x to AICA global @ %x\n", val, addr & 0xff);
*((unsigned short *) (AICA->udata.datab+((addr&0xff)))) = val;
AICA_UpdateReg(AICA, addr&0xff);
}
else if (addr == 0x2d00)
{
AICA->IRQL = val;
}
else if (addr == 0x2d04)
{
AICA->IRQR = val;
if (val)
{
AICA->IntARMCB(AICA->cpu, 0);
}
}
}
else
{
//DSP
if(addr<0x3200) //COEF
*((unsigned short *) (AICA->DSP.COEF+(addr-0x3000)/2))=val;
else if(addr<0x3400)
*((unsigned short *) (AICA->DSP.MADRS+(addr-0x3200)/2))=val;
else if(addr<0x3c00)
{
*((unsigned short *) (AICA->DSP.MPRO+(addr-0x3400)/2))=val;
if (addr == 0x3bfe)
{
AICADSP_Start(&AICA->DSP);
}
}
}
}
static unsigned short AICA_r16(struct _AICA *AICA, unsigned int addr)
{
unsigned short v=0;
addr&=0xffff;
if(addr<0x2000)
{
int slot=addr/0x80;
addr&=0x7f;
AICA_UpdateSlotRegR(AICA, slot,addr&0x7f);
v=*((unsigned short *) (AICA->Slots[slot].udata.datab+(addr)));
}
else if(addr<0x3000)
{
if (addr <= 0x2044)
{
v = AICA->EFSPAN[addr&0x7f];
}
else if (addr < 0x28be)
{
AICA_UpdateRegR(AICA, addr&0xff);
v= *((unsigned short *) (AICA->udata.datab+((addr&0xff))));
if((addr&0xfe)==0x10) AICA->udata.data[0x10/2] &= 0x7FFF; // reset LP on read
}
else if (addr == 0x2d00)
{
return AICA->IRQL;
}
else if (addr == 0x2d04)
{
return AICA->IRQR;
}
}
// else if (addr<0x700)
// v=AICA->RINGBUF[(addr-0x600)/2];
return v;
}
#define REVSIGN(v) ((~v)+1)
void AICA_TimersAddTicks(struct _AICA *AICA, int ticks)
{
if(AICA->TimCnt[0]<=0xff00)
{
AICA->TimCnt[0] += ticks << (8-((AICA->udata.data[0x90/2]>>8)&0x7));
if (AICA->TimCnt[0] >= 0xFF00)
{
AICA->TimCnt[0] = 0xFFFF;
AICA->udata.data[0xa0/2]|=0x40;
}
AICA->udata.data[0x90/2]&=0xff00;
AICA->udata.data[0x90/2]|=AICA->TimCnt[0]>>8;
}
if(AICA->TimCnt[1]<=0xff00)
{
AICA->TimCnt[1] += ticks << (8-((AICA->udata.data[0x94/2]>>8)&0x7));
if (AICA->TimCnt[1] >= 0xFF00)
{
AICA->TimCnt[1] = 0xFFFF;
AICA->udata.data[0xa0/2]|=0x80;
}
AICA->udata.data[0x94/2]&=0xff00;
AICA->udata.data[0x94/2]|=AICA->TimCnt[1]>>8;
}
if(AICA->TimCnt[2]<=0xff00)
{
AICA->TimCnt[2] += ticks << (8-((AICA->udata.data[0x98/2]>>8)&0x7));
if (AICA->TimCnt[2] >= 0xFF00)
{
AICA->TimCnt[2] = 0xFFFF;
AICA->udata.data[0xa0/2]|=0x100;
}
AICA->udata.data[0x98/2]&=0xff00;
AICA->udata.data[0x98/2]|=AICA->TimCnt[2]>>8;
}
}
INLINE INT32 AICA_UpdateSlot(struct _AICA *AICA, struct _SLOT *slot)
{
INT32 sample, fpart;
int cur_sample; //current sample
int nxt_sample; //next sample
int step=slot->step;
UINT32 addr1,addr2; // current and next sample addresses
if(SSCTL(slot)!=0) //no FM or noise yet
return 0;
if(PLFOS(slot)!=0)
{
step=step*AICAPLFO_Step(&(slot->PLFO));
step>>=SHIFT;
}
if(PCMS(slot) == 0)
{
addr1=(slot->cur_addr>>(SHIFT-1))&0x7ffffe;
addr2=(slot->nxt_addr>>(SHIFT-1))&0x7ffffe;
}
else
{
addr1=slot->cur_addr>>SHIFT;
addr2=slot->nxt_addr>>SHIFT;
}
if(PCMS(slot) == 1) // 8-bit signed
{
INT8 *p1=(signed char *) (AICA->AICARAM+(((SA(slot)+addr1))&0x7fffff));
INT8 *p2=(signed char *) (AICA->AICARAM+(((SA(slot)+addr2))&0x7fffff));
cur_sample = p1[0] << 8;
nxt_sample = p2[0] << 8;
}
else if (PCMS(slot) == 0) //16 bit signed
{
INT16 *p1=(signed short *) (AICA->AICARAM+((SA(slot)+addr1)&0x7fffff));
INT16 *p2=(signed short *) (AICA->AICARAM+((SA(slot)+addr2)&0x7fffff));
cur_sample = LE16(p1[0]);
nxt_sample = LE16(p2[0]);
}
else // 4-bit ADPCM
{
UINT8 *base= slot->adbase;
UINT32 steps_to_go = addr2, curstep = slot->curstep;
if (base)
{
cur_sample = slot->cur_sample; // may already contains current decoded sample
// seek to the interpolation sample
while (curstep < steps_to_go)
{
int shift1, delta1;
shift1 = 4*((curstep&1));
delta1 = (*base>>shift1)&0xf;
DecodeADPCM(&(slot->cur_sample),delta1,&(slot->cur_quant));
curstep++;
if (!(curstep & 1))
{
base++;
}
if (curstep == addr1)
cur_sample = slot->cur_sample;
}
nxt_sample = slot->cur_sample;
slot->adbase = base;
slot->curstep = curstep;
}
else
{
cur_sample = nxt_sample = 0;
}
}
fpart = slot->cur_addr & ((1<<SHIFT)-1);
sample=cur_sample*((1<<SHIFT)-fpart)+nxt_sample*fpart;
sample>>=SHIFT;
slot->prv_addr=slot->cur_addr;
slot->cur_addr+=step;
slot->nxt_addr=slot->cur_addr+(1<<SHIFT);
addr1=slot->cur_addr>>SHIFT;
addr2=slot->nxt_addr>>SHIFT;
if(addr1>=LSA(slot))
{
if(LPSLNK(slot) && slot->EG.state==ATTACK)
slot->EG.state = DECAY1;
}
switch(LPCTL(slot))
{
case 0: //no loop
if(addr2>=LSA(slot) && addr2>=LEA(slot)) // if next sample exceed then current must exceed too
{
//slot->active=0;
if(slot->mslc) AICA->udata.data[8] |= 0x8000;
AICA_StopSlot(slot,0);
}
break;
case 1: //normal loop
if(addr2>=LEA(slot))
{
INT32 rem_addr;
if(slot->mslc) AICA->udata.data[8] |= 0x8000;
rem_addr = slot->nxt_addr - (LEA(slot)<<SHIFT);
slot->nxt_addr = (LSA(slot)<<SHIFT) + rem_addr;
if(addr1>=LEA(slot))
{
rem_addr = slot->cur_addr - (LEA(slot)<<SHIFT);
slot->cur_addr = (LSA(slot)<<SHIFT) + rem_addr;
}
if(PCMS(slot)>=2)
{
// restore the state @ LSA - the sampler will naturally walk to (LSA + remainder)
slot->adbase = &AICA->AICARAM[SA(slot)+(LSA(slot)/2)];
slot->curstep = LSA(slot);
if (PCMS(slot) == 2)
{
slot->cur_sample = slot->cur_lpsample;
slot->cur_quant = slot->cur_lpquant;
}
//printf("Looping: slot_addr %x LSA %x LEA %x step %x base %x\n", slot->cur_addr>>SHIFT, LSA(slot), LEA(slot), slot->curstep, slot->adbase);
}
}
break;
}
if(ALFOS(slot)!=0)
{
sample=sample*AICAALFO_Step(&(slot->ALFO));
sample>>=SHIFT;
}
if(slot->EG.state==ATTACK)
sample=(sample*EG_Update(slot))>>SHIFT;
else
sample=(sample*EG_TABLE[EG_Update(slot)>>(SHIFT-10)])>>SHIFT;
if(slot->mslc)
{
AICA->udata.data[0x14/2] = addr1;
if (!(AFSEL(AICA)))
{
UINT16 res;
AICA->udata.data[0x10/2] |= slot->EG.state<<13;
res = 0x3FF - (slot->EG.volume>>EG_SHIFT);
res *= 959;
res /= 1024;
if (res > 959) res = 959;
AICA->udata.data[0x10/2] = res;
//AICA->udata.data[0x10/2] |= 0x3FF - (slot->EG.volume>>EG_SHIFT);
}
}
return sample;
}
static void AICA_DoMasterSamples(struct _AICA *AICA, int nsamples)
{
INT16 *bufr,*bufl;
int sl, s, i;
bufr=AICA->bufferr;
bufl=AICA->bufferl;
for(s=0;s<nsamples;++s)
{
INT32 smpl, smpr;
smpl = smpr = 0;
// mix slots' direct output
for(sl=0;sl<64;++sl)
{
struct _SLOT *slot=AICA->Slots+sl;
slot->mslc = (MSLC(AICA)==sl);
AICA->RBUFDST=AICA->RINGBUF+AICA->BUFPTR;
if(AICA->Slots[sl].active)
{
unsigned int Enc;
signed int sample;
sample=AICA_UpdateSlot(AICA, slot);
Enc=((TL(slot))<<0x0)|((IMXL(slot))<<0xd);
AICADSP_SetSample(&AICA->DSP,(sample*AICA->LPANTABLE[Enc])>>(SHIFT-2),ISEL(slot),IMXL(slot));
Enc=((TL(slot))<<0x0)|((DIPAN(slot))<<0x8)|((DISDL(slot))<<0xd);
{
smpl+=(sample*AICA->LPANTABLE[Enc])>>SHIFT;
smpr+=(sample*AICA->RPANTABLE[Enc])>>SHIFT;
}
}
AICA->BUFPTR&=63;
}
// process the DSP
AICADSP_Step(&AICA->DSP);
// mix DSP output
for(i=0;i<16;++i)
{
if(EFSDL(i))
{
unsigned int Enc=((EFPAN(i))<<0x8)|((EFSDL(i))<<0xd);
smpl+=(AICA->DSP.EFREG[i]*AICA->LPANTABLE[Enc])>>SHIFT;
smpr+=(AICA->DSP.EFREG[i]*AICA->RPANTABLE[Enc])>>SHIFT;
}
}
*bufl++ = ICLIP16(smpl>>3);
*bufr++ = ICLIP16(smpr>>3);
AICA_TimersAddTicks(AICA, 1);
CheckPendingIRQ(AICA);
}
}
int AICA_IRQCB(void *param)
{
CheckPendingIRQ(param);
return -1;
}
void AICA_Update(struct _AICA *AICA, void *param, INT16 **inputs, INT16 **buf, int samples)
{
AICA->bufferl = buf[0];
AICA->bufferr = buf[1];
AICA->length = samples;
AICA_DoMasterSamples(AICA, samples);
}
void *aica_start(const void *config)
{
const struct AICAinterface *intf;
struct _AICA *AICA;
AICA = malloc(sizeof(*AICA));
memset(AICA, 0, sizeof(*AICA));
intf = config;
// init the emulation
AICA_Init(AICA, intf);
// set up the IRQ callbacks
{
AICA->IntARMCB = intf->irq_callback[0];
// AICA->stream = stream_create(0, 2, 44100, AICA, AICA_Update);
}
return AICA;
}
void aica_stop(struct _AICA *AICA)
{
if (AICA->buffertmpl) {
free (AICA->buffertmpl);
}
if (AICA->buffertmpr) {
free (AICA->buffertmpr);
}
free(AICA);
}
void AICA_set_ram_base(struct _AICA *AICA, int which, void *base)
{
if (AICA)
{
AICA->AICARAM = base;
AICA->DSP.AICARAM = base;
}
}
READ16_HANDLER( AICA_0_r )
{
UINT16 res = AICA_r16(AICA, offset*2);
// printf("Read AICA @ %x => %x (PC=%x, R5=%x)\n", offset*2, res, arm7_get_register(15), arm7_get_register(5));
return res;
}
extern UINT32* stv_scu;
WRITE16_HANDLER( AICA_0_w )
{
UINT16 tmp;
tmp = AICA_r16(AICA, offset*2);
COMBINE_DATA(&tmp);
AICA_w16(AICA,offset*2, tmp);
}
WRITE16_HANDLER( AICA_MidiIn )
{
AICA->MidiStack[AICA->MidiW++]=data;
AICA->MidiW &= 15;
}
READ16_HANDLER( AICA_MidiOutR )
{
unsigned char val;
val=AICA->MidiStack[AICA->MidiR++];
AICA->MidiR&=7;
return val;
}
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