Genesis-Plus-GX/source/sound/sn76489.c

/* 
    SN76489 emulation
    by Maxim in 2001 and 2002
    converted from my original Delphi implementation

    I'm a C newbie so I'm sure there are loads of stupid things
    in here which I'll come back to some day and redo

    Includes:
    - Super-high quality tone channel "oversampling" by calculating fractional positions on transitions
    - Noise output pattern reverse engineered from actual SMS output
    - Volume levels taken from actual SMS output

    07/08/04  Charles MacDonald
    Modified for use with SMS Plus:
    - Added support for multiple PSG chips.
    - Added reset/config/update routines.
    - Added context management routines.
    - Removed SN76489_GetValues().
    - Removed some unused variables.

   25/04/07 Eke-Eke
   Modified for use with GenesisPlus Gamecube's port:
   - made SN76489_Update outputs 16bits mono samples
   - replaced volume table with VGM plugin's one
*/

#include "sn76489.h"
#include <float.h> // for FLT_MIN
#include <string.h> // for memcpy

#define NoiseInitialState   0x8000  /* Initial state of shift register */
#define PSG_CUTOFF          0x6     /* Value below which PSG does not output */

static const int PSGVolumeValues[2][16] = {
  /* These values are taken from a real SMS2's output */
    {892,892,892,760,623,497,404,323,257,198,159,123,96,75,60,0}, /* I can't remember why 892... :P some scaling I did at some point */
  /* these values are true volumes for 2dB drops at each step (multiply previous by 10^-0.1), normalised at 760 */
	{1516,1205,957,760,603,479,381,303,240,191,152,120,96,76,60,0}
};

static SN76489_Context SN76489[MAX_SN76489];

void SN76489_Init(int which, int PSGClockValue, int SamplingRate)
{
    SN76489_Context *p = &SN76489[which];
    p->dClock=(float)PSGClockValue/16/SamplingRate;
    SN76489_Config(which, MUTE_ALLON, VOL_FULL, FB_SEGAVDP, SRW_SEGAVDP, 1);
    SN76489_Reset(which);
}

void SN76489_Reset(int which)
{
    SN76489_Context *p = &SN76489[which];
    int i;

    p->PSGStereo = 0xFF;

    for(i = 0; i <= 3; i++)
    {
        /* Initialise PSG state */
        p->Registers[2*i] = 1;         /* tone freq=1 */
        p->Registers[2*i+1] = 0xf;     /* vol=off */
        p->NoiseFreq = 0x10;

        /* Set counters to 0 */
        p->ToneFreqVals[i] = 0;

        /* Set flip-flops to 1 */
        p->ToneFreqPos[i] = 1;

        /* Set intermediate positions to do-not-use value */
        p->IntermediatePos[i] = FLT_MIN;

        /* Set panning to centre */
        p->panning[0]=127;
    }

    p->LatchedRegister=0;

    /* Initialise noise generator */
    p->NoiseShiftRegister=NoiseInitialState;

    /* Zero clock */
    p->Clock=0;

}

void SN76489_Shutdown(void)
{
}

void SN76489_Config(int which, int mute, int volume, int feedback, int sr_width, int boost_noise)
{
    SN76489_Context *p = &SN76489[which];

    p->Mute = mute;
    p->VolumeArray = volume;
    p->WhiteNoiseFeedback = feedback;
    p->SRWidth = sr_width;
    p->BoostNoise = boost_noise;
}

void SN76489_SetContext(int which, uint8 *data)
{
    memcpy(&SN76489[which], data, sizeof(SN76489_Context));
}

void SN76489_GetContext(int which, uint8 *data)
{
    memcpy(data, &SN76489[which], sizeof(SN76489_Context));
}

uint8 *SN76489_GetContextPtr(int which)
{
    return (uint8 *)&SN76489[which];
}

int SN76489_GetContextSize(void)
{
    return sizeof(SN76489_Context);
}

void SN76489_Write(int which, int data)
{
    SN76489_Context *p = &SN76489[which];

	if (data&0x80) {
        /* Latch/data byte  %1 cc t dddd */
        p->LatchedRegister=((data>>4)&0x07);
        p->Registers[p->LatchedRegister]=
            (p->Registers[p->LatchedRegister] & 0x3f0)    /* zero low 4 bits */
            | (data&0xf);                           /* and replace with data */
	} else {
        /* Data byte        %0 - dddddd */
        if (!(p->LatchedRegister%2)&&(p->LatchedRegister<5))
            /* Tone register */
            p->Registers[p->LatchedRegister]=
                (p->Registers[p->LatchedRegister] & 0x00f)    /* zero high 6 bits */
                | ((data&0x3f)<<4);                     /* and replace with data */
		else
            /* Other register */
            p->Registers[p->LatchedRegister]=data&0x0f;       /* Replace with data */
    }
    switch (p->LatchedRegister) {
	case 0:
	case 2:
    case 4: /* Tone channels */
        if (p->Registers[p->LatchedRegister]==0) p->Registers[p->LatchedRegister]=1;    /* Zero frequency changed to 1 to avoid div/0 */
		break;
    case 6: /* Noise */
        p->NoiseShiftRegister=NoiseInitialState;   /* reset shift register */
        p->NoiseFreq=0x10<<(p->Registers[6]&0x3);     /* set noise signal generator frequency */
		break;
    }
}

void SN76489_GGStereoWrite(int which, int data)
{
    SN76489_Context *p = &SN76489[which];
    p->PSGStereo=data;
}

void SN76489_Update(int which, INT16 *buffer, int length)
{
    SN76489_Context *p = &SN76489[which];
    int i, j;

    for(j = 0; j < length; j++)
    {
        for (i=0;i<=2;++i)
            if (p->IntermediatePos[i]!=FLT_MIN)
                p->Channels[i]=(short)((p->Mute >> i & 0x1)*PSGVolumeValues[p->VolumeArray][p->Registers[2*i+1]]*p->IntermediatePos[i]);
            else
                p->Channels[i]=(p->Mute >> i & 0x1)*PSGVolumeValues[p->VolumeArray][p->Registers[2*i+1]]*p->ToneFreqPos[i];
    
        p->Channels[3]=(short)((p->Mute >> 3 & 0x1)*PSGVolumeValues[p->VolumeArray][p->Registers[7]]*(p->NoiseShiftRegister & 0x1));
    
        if (p->BoostNoise) p->Channels[3]<<=1; /* double noise volume */
    
        buffer[j] =0;
        for (i=0;i<=3;++i) buffer[j] += p->Channels[i];
    
        p->Clock+=p->dClock;
        p->NumClocksForSample=(int)p->Clock;  /* truncates */
        p->Clock-=p->NumClocksForSample;  /* remove integer part */
        /* Looks nicer in Delphi... */
        /*  Clock:=Clock+p->dClock; */
        /*  NumClocksForSample:=Trunc(Clock); */
        /*  Clock:=Frac(Clock); */
    
        /* Decrement tone channel counters */
        for (i=0;i<=2;++i)
            p->ToneFreqVals[i]-=p->NumClocksForSample;
     
        /* Noise channel: match to tone2 or decrement its counter */
        if (p->NoiseFreq==0x80) p->ToneFreqVals[3]=p->ToneFreqVals[2];
        else p->ToneFreqVals[3]-=p->NumClocksForSample;
    
        /* Tone channels: */
        for (i=0;i<=2;++i) {
            if (p->ToneFreqVals[i]<=0) {   /* If it gets below 0... */
                if (p->Registers[i*2]>PSG_CUTOFF) {
                    /* Calculate how much of the sample is + and how much is - */
                    /* Go to floating point and include the clock fraction for extreme accuracy :D */
                    /* Store as long int, maybe it's faster? I'm not very good at this */
                    p->IntermediatePos[i]=(p->NumClocksForSample-p->Clock+2*p->ToneFreqVals[i])*p->ToneFreqPos[i]/(p->NumClocksForSample+p->Clock);
                    p->ToneFreqPos[i]=-p->ToneFreqPos[i]; /* Flip the flip-flop */
                } else {
                    p->ToneFreqPos[i]=1;   /* stuck value */
                    p->IntermediatePos[i]=FLT_MIN;
                }
                p->ToneFreqVals[i]+=p->Registers[i*2]*(p->NumClocksForSample/p->Registers[i*2]+1);
            } else p->IntermediatePos[i]=FLT_MIN;
        }
    
        /* Noise channel */
        if (p->ToneFreqVals[3]<=0) {   /* If it gets below 0... */
            p->ToneFreqPos[3]=-p->ToneFreqPos[3]; /* Flip the flip-flop */
            if (p->NoiseFreq!=0x80)            /* If not matching tone2, decrement counter */
                p->ToneFreqVals[3]+=p->NoiseFreq*(p->NumClocksForSample/p->NoiseFreq+1);
            if (p->ToneFreqPos[3]==1) {    /* Only once per cycle... */
                int Feedback;
                if (p->Registers[6]&0x4) { /* White noise */
                    /* Calculate parity of fed-back bits for feedback */
                    switch (p->WhiteNoiseFeedback) {
                        /* Do some optimised calculations for common (known) feedback values */
                    case 0x0003:    /* SC-3000, BBC %00000011 */
                    case 0x0009:    /* SMS, GG, MD  %00001001 */
                        /* If two bits fed back, I can do Feedback=(nsr & fb) && (nsr & fb ^ fb) */
                        /* since that's (one or more bits set) && (not all bits set) */
                        Feedback=((p->NoiseShiftRegister&p->WhiteNoiseFeedback) && ((p->NoiseShiftRegister&p->WhiteNoiseFeedback)^p->WhiteNoiseFeedback));
                        break;
                    default:        /* Default handler for all other feedback values */
                        Feedback=p->NoiseShiftRegister&p->WhiteNoiseFeedback;
                        Feedback^=Feedback>>8;
                        Feedback^=Feedback>>4;
                        Feedback^=Feedback>>2;
                        Feedback^=Feedback>>1;
                        Feedback&=1;
                        break;
                    }
                } else      /* Periodic noise */
                    Feedback=p->NoiseShiftRegister&1;
    
                p->NoiseShiftRegister=(p->NoiseShiftRegister>>1) | (Feedback << (p->SRWidth-1));
    
    /* Original code: */
    /*          p->NoiseShiftRegister=(p->NoiseShiftRegister>>1) | ((p->Registers[6]&0x4?((p->NoiseShiftRegister&0x9) && (p->NoiseShiftRegister&0x9^0x9)):p->NoiseShiftRegister&1)<<15); */
            }
        }
    }
}

/*void SN76489_UpdateOne(int which, int *l, int *r)
{
  INT16 tl,tr;
  INT16 *buff[2]={&tl,&tr};
  SN76489_Update(which,buff,1);
  *l=tl;
  *r=tr;
}*/

int  SN76489_GetMute(int which)
{
  return SN76489[which].Mute;
}

void SN76489_SetMute(int which, int val)
{
  SN76489[which].Mute=val;
}

int  SN76489_GetVolType(int which)
{
  return SN76489[which].VolumeArray;
}

void SN76489_SetVolType(int which, int val)
{
  SN76489[which].VolumeArray=val;
}

void SN76489_SetPanning(int which, int ch0, int ch1, int ch2, int ch3)
{
  SN76489[which].panning[0]=ch0;
  SN76489[which].panning[1]=ch1;
  SN76489[which].panning[2]=ch2;
  SN76489[which].panning[3]=ch3;
}
2007-08-10 22:34:06 +02:00			`/*`
			`SN76489 emulation`
			`by Maxim in 2001 and 2002`
			`converted from my original Delphi implementation`

			`I'm a C newbie so I'm sure there are loads of stupid things`
			`in here which I'll come back to some day and redo`

			`Includes:`
			`- Super-high quality tone channel "oversampling" by calculating fractional positions on transitions`
			`- Noise output pattern reverse engineered from actual SMS output`
			`- Volume levels taken from actual SMS output`

			`07/08/04 Charles MacDonald`
			`Modified for use with SMS Plus:`
			`- Added support for multiple PSG chips.`
			`- Added reset/config/update routines.`
			`- Added context management routines.`
			`- Removed SN76489_GetValues().`
			`- Removed some unused variables.`

			`25/04/07 Eke-Eke`
			`Modified for use with GenesisPlus Gamecube's port:`
			`- made SN76489_Update outputs 16bits mono samples`
			`- replaced volume table with VGM plugin's one`
			`*/`

			`#include "sn76489.h"`
			`#include <float.h> // for FLT_MIN`
			`#include <string.h> // for memcpy`

			`#define NoiseInitialState 0x8000 /* Initial state of shift register */`
			`#define PSG_CUTOFF 0x6 /* Value below which PSG does not output */`

			`static const int PSGVolumeValues[2][16] = {`
			`/* These values are taken from a real SMS2's output */`
			`{892,892,892,760,623,497,404,323,257,198,159,123,96,75,60,0}, /* I can't remember why 892... :P some scaling I did at some point */`
			`/* these values are true volumes for 2dB drops at each step (multiply previous by 10^-0.1), normalised at 760 */`
			`{1516,1205,957,760,603,479,381,303,240,191,152,120,96,76,60,0}`
			`};`

			`static SN76489_Context SN76489[MAX_SN76489];`

			`void SN76489_Init(int which, int PSGClockValue, int SamplingRate)`
			`{`
			`SN76489_Context *p = &SN76489[which];`
			`p->dClock=(float)PSGClockValue/16/SamplingRate;`
			`SN76489_Config(which, MUTE_ALLON, VOL_FULL, FB_SEGAVDP, SRW_SEGAVDP, 1);`
			`SN76489_Reset(which);`
			`}`

			`void SN76489_Reset(int which)`
			`{`
			`SN76489_Context *p = &SN76489[which];`
			`int i;`

			`p->PSGStereo = 0xFF;`

			`for(i = 0; i <= 3; i++)`
			`{`
			`/* Initialise PSG state */`
			`p->Registers[2i] = 1; / tone freq=1 */`
			`p->Registers[2i+1] = 0xf; / vol=off */`
			`p->NoiseFreq = 0x10;`

			`/* Set counters to 0 */`
			`p->ToneFreqVals[i] = 0;`

			`/* Set flip-flops to 1 */`
			`p->ToneFreqPos[i] = 1;`

			`/* Set intermediate positions to do-not-use value */`
			`p->IntermediatePos[i] = FLT_MIN;`

			`/* Set panning to centre */`
			`p->panning[0]=127;`
			`}`

			`p->LatchedRegister=0;`

			`/* Initialise noise generator */`
			`p->NoiseShiftRegister=NoiseInitialState;`

			`/* Zero clock */`
			`p->Clock=0;`

			`}`

			`void SN76489_Shutdown(void)`
			`{`
			`}`

			`void SN76489_Config(int which, int mute, int volume, int feedback, int sr_width, int boost_noise)`
			`{`
			`SN76489_Context *p = &SN76489[which];`

			`p->Mute = mute;`
			`p->VolumeArray = volume;`
			`p->WhiteNoiseFeedback = feedback;`
			`p->SRWidth = sr_width;`
			`p->BoostNoise = boost_noise;`
			`}`

			`void SN76489_SetContext(int which, uint8 *data)`
			`{`
			`memcpy(&SN76489[which], data, sizeof(SN76489_Context));`
			`}`

			`void SN76489_GetContext(int which, uint8 *data)`
			`{`
			`memcpy(data, &SN76489[which], sizeof(SN76489_Context));`
			`}`

			`uint8 *SN76489_GetContextPtr(int which)`
			`{`
			`return (uint8 *)&SN76489[which];`
			`}`

			`int SN76489_GetContextSize(void)`
			`{`
			`return sizeof(SN76489_Context);`
			`}`

			`void SN76489_Write(int which, int data)`
			`{`
			`SN76489_Context *p = &SN76489[which];`

			`if (data&0x80) {`
			`/* Latch/data byte %1 cc t dddd */`
			`p->LatchedRegister=((data>>4)&0x07);`
			`p->Registers[p->LatchedRegister]=`
			`(p->Registers[p->LatchedRegister] & 0x3f0) /* zero low 4 bits */`
			`\| (data&0xf); /* and replace with data */`
			`} else {`
			`/* Data byte %0 - dddddd */`
			`if (!(p->LatchedRegister%2)&&(p->LatchedRegister<5))`
			`/* Tone register */`
			`p->Registers[p->LatchedRegister]=`
			`(p->Registers[p->LatchedRegister] & 0x00f) /* zero high 6 bits */`
			`\| ((data&0x3f)<<4); /* and replace with data */`
			`else`
			`/* Other register */`
			`p->Registers[p->LatchedRegister]=data&0x0f; /* Replace with data */`
			`}`
			`switch (p->LatchedRegister) {`
			`case 0:`
			`case 2:`
			`case 4: /* Tone channels */`
			`if (p->Registers[p->LatchedRegister]==0) p->Registers[p->LatchedRegister]=1; /* Zero frequency changed to 1 to avoid div/0 */`
			`break;`
			`case 6: /* Noise */`
			`p->NoiseShiftRegister=NoiseInitialState; /* reset shift register */`
			`p->NoiseFreq=0x10<<(p->Registers[6]&0x3); /* set noise signal generator frequency */`
			`break;`
			`}`
			`}`

			`void SN76489_GGStereoWrite(int which, int data)`
			`{`
			`SN76489_Context *p = &SN76489[which];`
			`p->PSGStereo=data;`
			`}`

			`void SN76489_Update(int which, INT16 *buffer, int length)`
			`{`
			`SN76489_Context *p = &SN76489[which];`
			`int i, j;`

			`for(j = 0; j < length; j++)`
			`{`
			`for (i=0;i<=2;++i)`
			`if (p->IntermediatePos[i]!=FLT_MIN)`
			`p->Channels[i]=(short)((p->Mute >> i & 0x1)PSGVolumeValues[p->VolumeArray][p->Registers[2i+1]]*p->IntermediatePos[i]);`
			`else`
			`p->Channels[i]=(p->Mute >> i & 0x1)PSGVolumeValues[p->VolumeArray][p->Registers[2i+1]]*p->ToneFreqPos[i];`

			`p->Channels[3]=(short)((p->Mute >> 3 & 0x1)PSGVolumeValues[p->VolumeArray][p->Registers[7]](p->NoiseShiftRegister & 0x1));`

			`if (p->BoostNoise) p->Channels[3]<<=1; /* double noise volume */`

			`buffer[j] =0;`
			`for (i=0;i<=3;++i) buffer[j] += p->Channels[i];`

			`p->Clock+=p->dClock;`
			`p->NumClocksForSample=(int)p->Clock; /* truncates */`
			`p->Clock-=p->NumClocksForSample; /* remove integer part */`
			`/* Looks nicer in Delphi... */`
			`/* Clock:=Clock+p->dClock; */`
			`/* NumClocksForSample:=Trunc(Clock); */`
			`/* Clock:=Frac(Clock); */`

			`/* Decrement tone channel counters */`
			`for (i=0;i<=2;++i)`
			`p->ToneFreqVals[i]-=p->NumClocksForSample;`

			`/* Noise channel: match to tone2 or decrement its counter */`
			`if (p->NoiseFreq==0x80) p->ToneFreqVals[3]=p->ToneFreqVals[2];`
			`else p->ToneFreqVals[3]-=p->NumClocksForSample;`

			`/* Tone channels: */`
			`for (i=0;i<=2;++i) {`
			`if (p->ToneFreqVals[i]<=0) { /* If it gets below 0... */`
			`if (p->Registers[i*2]>PSG_CUTOFF) {`
			`/* Calculate how much of the sample is + and how much is - */`
			`/* Go to floating point and include the clock fraction for extreme accuracy :D */`
			`/* Store as long int, maybe it's faster? I'm not very good at this */`
			`p->IntermediatePos[i]=(p->NumClocksForSample-p->Clock+2p->ToneFreqVals[i])p->ToneFreqPos[i]/(p->NumClocksForSample+p->Clock);`
			`p->ToneFreqPos[i]=-p->ToneFreqPos[i]; /* Flip the flip-flop */`
			`} else {`
			`p->ToneFreqPos[i]=1; /* stuck value */`
			`p->IntermediatePos[i]=FLT_MIN;`
			`}`
			`p->ToneFreqVals[i]+=p->Registers[i2](p->NumClocksForSample/p->Registers[i*2]+1);`
			`} else p->IntermediatePos[i]=FLT_MIN;`
			`}`

			`/* Noise channel */`
			`if (p->ToneFreqVals[3]<=0) { /* If it gets below 0... */`
			`p->ToneFreqPos[3]=-p->ToneFreqPos[3]; /* Flip the flip-flop */`
			`if (p->NoiseFreq!=0x80) /* If not matching tone2, decrement counter */`
			`p->ToneFreqVals[3]+=p->NoiseFreq*(p->NumClocksForSample/p->NoiseFreq+1);`
			`if (p->ToneFreqPos[3]==1) { /* Only once per cycle... */`
			`int Feedback;`
			`if (p->Registers[6]&0x4) { /* White noise */`
			`/* Calculate parity of fed-back bits for feedback */`
			`switch (p->WhiteNoiseFeedback) {`
			`/* Do some optimised calculations for common (known) feedback values */`
			`case 0x0003: /* SC-3000, BBC %00000011 */`
			`case 0x0009: /* SMS, GG, MD %00001001 */`
			`/* If two bits fed back, I can do Feedback=(nsr & fb) && (nsr & fb ^ fb) */`
			`/* since that's (one or more bits set) && (not all bits set) */`
			`Feedback=((p->NoiseShiftRegister&p->WhiteNoiseFeedback) && ((p->NoiseShiftRegister&p->WhiteNoiseFeedback)^p->WhiteNoiseFeedback));`
			`break;`
			`default: /* Default handler for all other feedback values */`
			`Feedback=p->NoiseShiftRegister&p->WhiteNoiseFeedback;`
			`Feedback^=Feedback>>8;`
			`Feedback^=Feedback>>4;`
			`Feedback^=Feedback>>2;`
			`Feedback^=Feedback>>1;`
			`Feedback&=1;`
			`break;`
			`}`
			`} else /* Periodic noise */`
			`Feedback=p->NoiseShiftRegister&1;`

			`p->NoiseShiftRegister=(p->NoiseShiftRegister>>1) \| (Feedback << (p->SRWidth-1));`

			`/* Original code: */`
			`/* p->NoiseShiftRegister=(p->NoiseShiftRegister>>1) \| ((p->Registers[6]&0x4?((p->NoiseShiftRegister&0x9) && (p->NoiseShiftRegister&0x9^0x9)):p->NoiseShiftRegister&1)<<15); */`
			`}`
			`}`
			`}`
			`}`

			`/void SN76489_UpdateOne(int which, int l, int *r)`
			`{`
			`INT16 tl,tr;`
			`INT16 *buff[2]={&tl,&tr};`
			`SN76489_Update(which,buff,1);`
			`*l=tl;`
			`*r=tr;`
			`}*/`

			`int SN76489_GetMute(int which)`
			`{`
			`return SN76489[which].Mute;`
			`}`

			`void SN76489_SetMute(int which, int val)`
			`{`
			`SN76489[which].Mute=val;`
			`}`

			`int SN76489_GetVolType(int which)`
			`{`
			`return SN76489[which].VolumeArray;`
			`}`

			`void SN76489_SetVolType(int which, int val)`
			`{`
			`SN76489[which].VolumeArray=val;`
			`}`

			`void SN76489_SetPanning(int which, int ch0, int ch1, int ch2, int ch3)`
			`{`
			`SN76489[which].panning[0]=ch0;`
			`SN76489[which].panning[1]=ch1;`
			`SN76489[which].panning[2]=ch2;`
			`SN76489[which].panning[3]=ch3;`
			`}`