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|
//
// /home/ms/source/sidplay/libsidplay/emu/RCS/6581_.cpp,v
//
// Contributions:
//
// Noise generation algorithm is used courtesy of Asger Alstrup Nielsen.
// His original publication can be found on the SID home page.
//
// Noise table optimization proposed by Phillip Wooller. The output of
// each table does not differ.
//
// MOS-8580 R5 combined waveforms recorded by Dennis "Deadman" Lindroos.
// --------------------------------------------------------------------------
//
// --- MOS-6581 Emulator ---
//
// Copyright (c) 1994-1997 Michael Schwendt. All rights reserved.
//
// Redistribution and use in source and binary forms, either unchanged or
// modified, are permitted provided that the following conditions are met:
//
// (1) Redistributions of source code must retain the above copyright
// notice, this list of conditions and the following disclaimer.
//
// (2) Redistributions in binary form must reproduce the above copyright
// notice, this list of conditions and the following disclaimer in the
// documentation and/or other materials provided with the distribution.
//
// THIS SOFTWARE IS PROVIDED BY THE AUTHOR ``AS IS'' AND ANY EXPRESS OR
// IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED
// WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE
// DISCLAIMED. IN NO EVENT SHALL THE AUTHOR OR CONTRIBUTORS BE LIABLE FOR
// ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL
// DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS
// OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION)
// HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT,
// STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN
// ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE
// POSSIBILITY OF SUCH DAMAGE.
// --------------------------------------------------------------------------
#include "mytypes.h"
#include "myendian.h"
#include "sidtune.h"
#include "6510_.h"
#include "emucfg.h"
#include "envelope.h"
#include "opstruct.h"
#include "samples.h"
#include "wave6581.h"
#include "wave8580.h"
extern ubyte masterVolume;
extern uword masterVolumeAmplIndex;
sbyte* ampMod1x8;
sidOperator optr1, optr2, optr3;
// Voice 4 does not use a sidOperator structure.
uword voice4_gainLeft, voice4_gainRight;
static bool doAutoPanning;
static bool updateAutoPanning;
static uword apCount;
static const uword apSpeed = 0x4000;
bool filterEnabled = true;
filterfloat filterTable[0x800];
filterfloat bandPassParam[0x800];
filterfloat filterResTable[16];
static filterfloat filterDy, filterResDy;
#define lowPassParam filterTable
static ubyte filterType = 0;
static ubyte filterCurType = 0;
static uword filterValue;
static ubyte triangleTable[4096];
static ubyte sawtoothTable[4096];
static ubyte squareTable[2*4096];
static ubyte* waveform30;
static ubyte* waveform50;
static ubyte* waveform60;
static ubyte* waveform70;
#if defined(LARGE_NOISE_TABLE)
static ubyte noiseTableMSB[1<<8];
static ubyte noiseTableLSB[1L<<16];
#else
static ubyte noiseTableMSB[1<<8];
static ubyte noiseTableMID[1<<8];
static ubyte noiseTableLSB[1<<8];
#endif
static const udword noiseSeed = 0x7ffff8;
uword PCMfreq;
static udword PCMsid, PCMsidNoise;
// Song clock speed (PAL or NTSC). Does not affect pitch.
static udword sidtuneClockSpeed = 985248;
// Master clock speed. Affects pitch of SID and CIA samples.
udword C64_clockSpeed = 985248;
static float C64_fClockSpeed = 985248.4;
// -------------------------------------------------------------------- Speed
static uword calls = 50; // calls per second (here a default)
static uword fastForwardFactor = 128; // normal speed
#if defined(DIRECT_FIXPOINT)
cpuLword VALUES, VALUESadd, VALUESorg;
#else
uword VALUES, VALUESorg;
udword VALUESadd, VALUEScomma;
#endif
static uword defaultTimer, timer;
inline void calcValuesPerCall()
{
udword fastForwardFreq = PCMfreq;
if ( fastForwardFactor != 128 )
{
fastForwardFreq = (PCMfreq * fastForwardFactor) >> 7; // divide by 128
}
#if defined(DIRECT_FIXPOINT)
VALUES.l = ( VALUESorg.l = (((fastForwardFreq<<12)/calls)<<4) );
VALUESadd.l = 0;
#else
VALUES = (VALUESorg = (fastForwardFreq / calls));
VALUEScomma = ((fastForwardFreq % calls) * 65536UL) / calls;
VALUESadd = 0;
#endif
}
static void sidEmuChangeReplayingSpeed()
{
calcValuesPerCall();
}
// PAL: Clock speed: 985248.4 Hz
// CIA 1 Timer A: $4025 (60 Hz)
//
// NTSC: Clock speed: 1022727.14 Hz
// CIA 1 Timer A: $4295 (60 Hz)
static void sidEmuSetClockSpeed(int clockMode)
{
switch (clockMode)
{
case SIDTUNE_CLOCK_NTSC:
{
C64_clockSpeed = 1022727;
C64_fClockSpeed = 1022727.14;
break;
}
case SIDTUNE_CLOCK_PAL:
default:
{
C64_clockSpeed = 985248;
C64_fClockSpeed = 985248.4;
break;
}
}
}
void sidEmuSetReplayingSpeed(int clockMode, uword callsPerSec)
{
switch (clockMode)
{
case SIDTUNE_CLOCK_NTSC:
{
sidtuneClockSpeed = 1022727;
timer = (defaultTimer = 0x4295);
break;
}
case SIDTUNE_CLOCK_PAL:
default:
{
sidtuneClockSpeed = 985248;
timer = (defaultTimer = 0x4025);
break;
}
}
switch (callsPerSec)
{
case SIDTUNE_SPEED_CIA_1A:
{
timer = readLEword(c64mem2+0xdc04);
if (timer < 16) // prevent overflow
{
timer = defaultTimer;
}
calls = sidtuneClockSpeed / timer;
break;
}
default:
{
calls = callsPerSec;
break;
}
}
calcValuesPerCall();
}
static void sidEmuUpdateReplayingSpeed()
{
if ( timer != readLEword(c64mem2+0xdc04) )
{
timer = readLEword(c64mem2+0xdc04);
// Prevent overflow
if ( timer < 16 )
timer = defaultTimer;
calls = sidtuneClockSpeed / timer;
calcValuesPerCall();
}
}
// --------------------------------------------------------------------------
inline void waveAdvance(struct sidOperator* pVoice)
{
#if defined(DIRECT_FIXPOINT)
pVoice->waveStep.l += pVoice->waveStepAdd.l;
pVoice->waveStep.w[HI] &= 4095;
#else
pVoice->waveStepPnt += pVoice->waveStepAddPnt;
pVoice->waveStep += ( pVoice->waveStepAdd + ( pVoice->waveStepPnt > 65535 ));
pVoice->waveStepPnt &= 0xFFFF;
pVoice->waveStep &= 4095;
#endif
}
inline void noiseAdvance(sidOperator* pVoice)
{
pVoice->noiseStep += pVoice->noiseStepAdd;
if (pVoice->noiseStep >= (1L<<20))
{
pVoice->noiseStep -= (1L<<20);
#if defined(DIRECT_FIXPOINT)
pVoice->noiseReg.l = (pVoice->noiseReg.l << 1) |
(((pVoice->noiseReg.l >> 22) ^ (pVoice->noiseReg.l >> 17)) & 1);
#else
pVoice->noiseReg = (pVoice->noiseReg << 1) |
(((pVoice->noiseReg >> 22) ^ (pVoice->noiseReg >> 17)) & 1);
#endif
#if defined(DIRECT_FIXPOINT) && defined(LARGE_NOISE_TABLE)
pVoice->noiseOutput = (noiseTableLSB[pVoice->noiseReg.w[LO]]
|noiseTableMSB[pVoice->noiseReg.w[HI]&0xff]);
#elif defined(DIRECT_FIXPOINT)
pVoice->noiseOutput = (noiseTableLSB[pVoice->noiseReg.b[LOLO]]
|noiseTableMID[pVoice->noiseReg.b[LOHI]]
|noiseTableMSB[pVoice->noiseReg.b[HILO]]);
#else
pVoice->noiseOutput = (noiseTableLSB[pVoice->noiseReg&0xff]
|noiseTableMID[pVoice->noiseReg>>8&0xff]
|noiseTableMSB[pVoice->noiseReg>>16&0xff]);
#endif
}
}
inline void noiseAdvanceHp(sidOperator* pVoice)
{
udword tmp = pVoice->noiseStepAdd;
while (tmp >= (1L<<20))
{
tmp -= (1L<<20);
#if defined(DIRECT_FIXPOINT)
pVoice->noiseReg.l = (pVoice->noiseReg.l << 1) |
(((pVoice->noiseReg.l >> 22) ^ (pVoice->noiseReg.l >> 17)) & 1);
#else
pVoice->noiseReg = (pVoice->noiseReg << 1) |
(((pVoice->noiseReg >> 22) ^ (pVoice->noiseReg >> 17)) & 1);
#endif
}
pVoice->noiseStep += tmp;
if (pVoice->noiseStep >= (1L<<20))
{
pVoice->noiseStep -= (1L<<20);
#if defined(DIRECT_FIXPOINT)
pVoice->noiseReg.l = (pVoice->noiseReg.l << 1) |
(((pVoice->noiseReg.l >> 22) ^ (pVoice->noiseReg.l >> 17)) & 1);
#else
pVoice->noiseReg = (pVoice->noiseReg << 1) |
(((pVoice->noiseReg >> 22) ^ (pVoice->noiseReg >> 17)) & 1);
#endif
}
#if defined(DIRECT_FIXPOINT) && defined(LARGE_NOISE_TABLE)
pVoice->noiseOutput = (noiseTableLSB[pVoice->noiseReg.w[LO]]
|noiseTableMSB[pVoice->noiseReg.w[HI]&0xff]);
#elif defined(DIRECT_FIXPOINT)
pVoice->noiseOutput = (noiseTableLSB[pVoice->noiseReg.b[LOLO]]
|noiseTableMID[pVoice->noiseReg.b[LOHI]]
|noiseTableMSB[pVoice->noiseReg.b[HILO]]);
#else
pVoice->noiseOutput = (noiseTableLSB[pVoice->noiseReg&0xff]
|noiseTableMID[pVoice->noiseReg>>8&0xff]
|noiseTableMSB[pVoice->noiseReg>>16&0xff]);
#endif
}
#if defined(DIRECT_FIXPOINT)
#define triangle triangleTable[pVoice->waveStep.w[HI]]
#define sawtooth sawtoothTable[pVoice->waveStep.w[HI]]
#define square squareTable[pVoice->waveStep.w[HI] + pVoice->pulseIndex]
#define triSaw waveform30[pVoice->waveStep.w[HI]]
#define triSquare waveform50[pVoice->waveStep.w[HI] + pVoice->SIDpulseWidth]
#define sawSquare waveform60[pVoice->waveStep.w[HI] + pVoice->SIDpulseWidth]
#define triSawSquare waveform70[pVoice->waveStep.w[HI] + pVoice->SIDpulseWidth]
#else
#define triangle triangleTable[pVoice->waveStep]
#define sawtooth sawtoothTable[pVoice->waveStep]
#define square squareTable[pVoice->waveStep + pVoice->pulseIndex]
#define triSaw waveform30[pVoice->waveStep]
#define triSquare waveform50[pVoice->waveStep + pVoice->SIDpulseWidth]
#define sawSquare waveform60[pVoice->waveStep + pVoice->SIDpulseWidth]
#define triSawSquare waveform70[pVoice->waveStep + pVoice->SIDpulseWidth]
#endif
static void sidMode00(struct sidOperator* pVoice) {
pVoice->output = (pVoice->filtIO-0x80);
waveAdvance(pVoice);
}
static void sidModeReal00(struct sidOperator* pVoice) {
pVoice->output = 0;
waveAdvance(pVoice);
}
static void sidMode10(struct sidOperator* pVoice) {
pVoice->output = triangle;
waveAdvance(pVoice);
}
static void sidMode20(struct sidOperator* pVoice) {
pVoice->output = sawtooth;
waveAdvance(pVoice);
}
static void sidMode30(struct sidOperator* pVoice) {
pVoice->output = triSaw;
waveAdvance(pVoice);
}
static void sidMode40(struct sidOperator* pVoice) {
pVoice->output = square;
waveAdvance(pVoice);
}
static void sidMode50(struct sidOperator* pVoice) {
pVoice->output = triSquare;
waveAdvance(pVoice);
}
static void sidMode60(struct sidOperator* pVoice) {
pVoice->output = sawSquare;
waveAdvance(pVoice);
}
static void sidMode70(struct sidOperator* pVoice) {
pVoice->output = triSawSquare;
waveAdvance(pVoice);
}
static void sidMode80(struct sidOperator* pVoice) {
pVoice->output = pVoice->noiseOutput;
waveAdvance(pVoice);
noiseAdvance(pVoice);
}
static void sidMode80hp(struct sidOperator* pVoice) {
pVoice->output = pVoice->noiseOutput;
waveAdvance(pVoice);
noiseAdvanceHp(pVoice);
}
static void sidModeLock(sidOperator* pVoice)
{
pVoice->noiseIsLocked = true;
pVoice->output = (pVoice->filtIO-0x80);
waveAdvance(pVoice);
}
//
//
//
static void sidMode14(struct sidOperator* pVoice)
{
#if defined(DIRECT_FIXPOINT)
if ( pVoice->modulator->waveStep.w[HI] < 2048 )
#else
if ( pVoice->modulator->waveStep < 2048 )
#endif
pVoice->output = triangle;
else
pVoice->output = 0xFF ^ triangle;
waveAdvance(pVoice);
}
static void sidMode34(struct sidOperator* pVoice) {
#if defined(DIRECT_FIXPOINT)
if ( pVoice->modulator->waveStep.w[HI] < 2048 )
#else
if ( pVoice->modulator->waveStep < 2048 )
#endif
pVoice->output = triSaw;
else
pVoice->output = 0xFF ^ triSaw;
waveAdvance(pVoice);
}
static void sidMode54(struct sidOperator* pVoice) {
#if defined(DIRECT_FIXPOINT)
if ( pVoice->modulator->waveStep.w[HI] < 2048 )
#else
if ( pVoice->modulator->waveStep < 2048 )
#endif
pVoice->output = triSquare;
else
pVoice->output = 0xFF ^ triSquare;
waveAdvance(pVoice);
}
static void sidMode74(struct sidOperator* pVoice) {
#if defined(DIRECT_FIXPOINT)
if ( pVoice->modulator->waveStep.w[HI] < 2048 )
#else
if ( pVoice->modulator->waveStep < 2048 )
#endif
pVoice->output = triSawSquare;
else
pVoice->output = 0xFF ^ triSawSquare;
waveAdvance(pVoice);
}
//
//
//
inline void waveCalcCycleLen(struct sidOperator* pVoice)
{
#if defined(DIRECT_FIXPOINT)
pVoice->cycleAddLen.w[HI] = 0;
pVoice->cycleAddLen.l += pVoice->cycleLen.l;
pVoice->cycleLenCount = pVoice->cycleAddLen.w[HI];
#else
pVoice->cycleAddLenPnt += pVoice->cycleLenPnt;
pVoice->cycleLenCount = pVoice->cycleLen + ( pVoice->cycleAddLenPnt > 65535 );
pVoice->cycleAddLenPnt &= 0xFFFF;
#endif
// If we keep the value cycleLen between 1 <= x <= 65535,
// the following check is not required.
// if ( pVoice->cycleLenCount == 0 )
// {
//#if defined(DIRECT_FIXPOINT)
// pVoice->waveStep.l = 0;
//#else
// pVoice->waveStep = (pVoice->waveStepPnt = 0);
//#endif
// pVoice->cycleLenCount = 0;
// }
// else
// {
#if defined(DIRECT_FIXPOINT)
register uword diff = pVoice->cycleLenCount - pVoice->cycleLen.w[HI];
#else
register uword diff = pVoice->cycleLenCount - pVoice->cycleLen;
#endif
if ( pVoice->wavePre[diff].len != pVoice->cycleLenCount )
{
pVoice->wavePre[diff].len = pVoice->cycleLenCount;
#if defined(DIRECT_FIXPOINT)
pVoice->wavePre[diff].stp = (pVoice->waveStepAdd.l = (4096UL*65536UL) / pVoice->cycleLenCount);
#else
pVoice->wavePre[diff].stp = (pVoice->waveStepAdd = 4096UL / pVoice->cycleLenCount);
pVoice->wavePre[diff].pnt = (pVoice->waveStepAddPnt = ((4096UL % pVoice->cycleLenCount) * 65536UL) / pVoice->cycleLenCount);
#endif
}
else
{
#if defined(DIRECT_FIXPOINT)
pVoice->waveStepAdd.l = pVoice->wavePre[diff].stp;
#else
pVoice->waveStepAdd = pVoice->wavePre[diff].stp;
pVoice->waveStepAddPnt = pVoice->wavePre[diff].pnt;
#endif
}
// } // see above (opening bracket)
}
inline void waveCalcFilter(struct sidOperator* pVoice)
{
if ( pVoice->filtEnabled )
{
if ( filterType != 0 )
{
if ( filterType == 0x20 )
{
pVoice->filtLow += ( pVoice->filtRef * filterDy );
filterfloat tmp = (filterfloat)pVoice->filtIO - pVoice->filtLow;
tmp -= pVoice->filtRef * filterResDy;
pVoice->filtRef += ( tmp * (filterDy) );
pVoice->filtIO = (sbyte)(pVoice->filtRef-pVoice->filtLow/4);
}
else if (filterType == 0x40)
{
pVoice->filtLow += ( pVoice->filtRef * filterDy * 0.1 );
filterfloat tmp = (filterfloat)pVoice->filtIO - pVoice->filtLow;
tmp -= pVoice->filtRef * filterResDy;
pVoice->filtRef += ( tmp * (filterDy) );
filterfloat tmp2 = pVoice->filtRef - pVoice->filtIO/8;
if (tmp2 < -128)
tmp2 = -128;
if (tmp2 > 127)
tmp2 = 127;
pVoice->filtIO = (sbyte)tmp2;
}
else
{
pVoice->filtLow += ( pVoice->filtRef * filterDy );
filterfloat sample = pVoice->filtIO;
filterfloat sample2 = sample - pVoice->filtLow;
int tmp = (int)sample2;
sample2 -= pVoice->filtRef * filterResDy;
pVoice->filtRef += ( sample2 * filterDy );
if ( filterType == 0x10 )
{
pVoice->filtIO = (sbyte)pVoice->filtLow;
}
else if ( filterType == 0x30 )
{
pVoice->filtIO = (sbyte)pVoice->filtLow;
}
else if ( filterType == 0x50 )
{
pVoice->filtIO = (sbyte)(sample - (tmp >> 1));
}
else if ( filterType == 0x60 )
{
pVoice->filtIO = (sbyte)tmp;
}
else if ( filterType == 0x70 )
{
pVoice->filtIO = (sbyte)(sample - (tmp >> 1));
}
}
}
else // filterType == 0x00
{
pVoice->filtIO = 0;
}
}
}
sbyte waveCalcMute(struct sidOperator* pVoice)
{
(*pVoice->ADSRproc)(pVoice); // just process envelope
return pVoice->filtIO&pVoice->outputMask;
}
sbyte waveCalcNormal(struct sidOperator* pVoice)
{
if ( pVoice->cycleLenCount <= 0 )
{
waveCalcCycleLen(pVoice);
if (( pVoice->SIDctrl & 0x40 ) == 0x40 )
{
pVoice->pulseIndex = pVoice->newPulseIndex;
if ( pVoice->pulseIndex > 2048 )
{
#if defined(DIRECT_FIXPOINT)
pVoice->waveStep.w[HI] = 0;
#else
pVoice->waveStep = 0;
#endif
}
}
}
(*pVoice->waveProc)(pVoice);
pVoice->filtIO = ampMod1x8[(*pVoice->ADSRproc)(pVoice)|pVoice->output];
waveCalcFilter(pVoice);
return pVoice->filtIO&pVoice->outputMask;
}
sbyte waveCalcRangeCheck(struct sidOperator* pVoice)
{
#if defined(DIRECT_FIXPOINT)
pVoice->waveStepOld = pVoice->waveStep.w[HI];
(*pVoice->waveProc)(pVoice);
if (pVoice->waveStep.w[HI] < pVoice->waveStepOld)
#else
pVoice->waveStepOld = pVoice->waveStep;
(*pVoice->waveProc)(pVoice);
if (pVoice->waveStep < pVoice->waveStepOld)
#endif
{
// Next step switch back to normal calculation.
pVoice->cycleLenCount = 0;
pVoice->outProc = &waveCalcNormal;
#if defined(DIRECT_FIXPOINT)
pVoice->waveStep.w[HI] = 4095;
#else
pVoice->waveStep = 4095;
#endif
}
pVoice->filtIO = ampMod1x8[(*pVoice->ADSRproc)(pVoice)|pVoice->output];
waveCalcFilter(pVoice);
return pVoice->filtIO&pVoice->outputMask;
}
// -------------------------------------------------- Operator frame set-up 1
inline void sidEmuSet(struct sidOperator* pVoice, uword sidIndex)
{
pVoice->SIDfreq = readLEword(c64mem2+sidIndex);
pVoice->SIDpulseWidth = (readLEword(c64mem2+sidIndex+2) & 0x0FFF);
pVoice->newPulseIndex = 4096 - pVoice->SIDpulseWidth;
#if defined(DIRECT_FIXPOINT)
if ( ((pVoice->waveStep.w[HI] + pVoice->pulseIndex) >= 0x1000)
&& ((pVoice->waveStep.w[HI] + pVoice->newPulseIndex) >= 0x1000) )
{
pVoice->pulseIndex = pVoice->newPulseIndex;
}
else if ( ((pVoice->waveStep.w[HI] + pVoice->pulseIndex) < 0x1000)
&& ((pVoice->waveStep.w[HI] + pVoice->newPulseIndex) < 0x1000) )
{
pVoice->pulseIndex = pVoice->newPulseIndex;
}
#else
if ( ((pVoice->waveStep + pVoice->pulseIndex) >= 0x1000)
&& ((pVoice->waveStep + pVoice->newPulseIndex) >= 0x1000) )
{
pVoice->pulseIndex = pVoice->newPulseIndex;
}
else if ( ((pVoice->waveStep + pVoice->pulseIndex) < 0x1000)
&& ((pVoice->waveStep + pVoice->newPulseIndex) < 0x1000) )
{
pVoice->pulseIndex = pVoice->newPulseIndex;
}
#endif
ubyte enveTemp, newWave, oldWave;
oldWave = pVoice->SIDctrl;
enveTemp = pVoice->ADSRctrl;
pVoice->SIDctrl = (newWave = c64mem2[sidIndex +4]);
if (( newWave & 1 ) ==0 )
{
if (( oldWave & 1 ) !=0 )
enveTemp = ENVE_STARTRELEASE;
// else if ( pVoice->gateOnCtrl )
// {
// enveTemp = ENVE_STARTSHORTATTACK;
// }
}
else if ( pVoice->gateOffCtrl || ((oldWave&1)==0) )
{
enveTemp = ENVE_STARTATTACK;
if (doAutoPanning && updateAutoPanning)
{
// Swap source/destination position.
uword tmp = pVoice->gainSource;
pVoice->gainSource = pVoice->gainDest;
pVoice->gainDest = tmp;
if ((pVoice->gainDest^pVoice->gainSource) == 0)
{
// Mute voice.
pVoice->gainLeft = (pVoice->gainRight = 0x0000+0x80);
}
else
{
// Start from middle position.
pVoice->gainLeft = pVoice->gainLeftCentered;
pVoice->gainRight = pVoice->gainRightCentered;
}
// Determine direction.
// true = L > R : L down, R up
// false = L < R : L up, R down
pVoice->gainDirec = (pVoice->gainLeft > pVoice->gainDest);
}
}
if (doAutoPanning && updateAutoPanning && (enveTemp!=ENVE_STARTATTACK))
{
if (pVoice->gainDirec)
{
if (pVoice->gainLeft > pVoice->gainDest)
{
pVoice->gainLeft -= 0x0100;
pVoice->gainRight += 0x0100;
}
else
{
// Swap source/destination position.
uword tmp = pVoice->gainSource;
pVoice->gainSource = pVoice->gainDest;
pVoice->gainDest = tmp;
// Inverse direction.
pVoice->gainDirec = false;
}
}
else
{
if (pVoice->gainRight > pVoice->gainSource)
{
pVoice->gainLeft += 0x0100;
pVoice->gainRight -= 0x0100;
}
else
{
pVoice->gainDirec = true;
// Swap source/destination position.
uword tmp = pVoice->gainSource;
pVoice->gainSource = pVoice->gainDest;
// Inverse direction.
pVoice->gainDest = tmp;
}
}
}
if ((( oldWave ^ newWave ) & 0xF0 ) != 0 )
{
pVoice->cycleLenCount = 0;
}
ubyte ADtemp = c64mem2[sidIndex +5];
ubyte SRtemp = c64mem2[sidIndex +6];
if ( pVoice->SIDAD != ADtemp )
{
enveTemp |= ENVE_ALTER;
}
else if ( pVoice->SIDSR != SRtemp )
{
enveTemp |= ENVE_ALTER;
}
pVoice->SIDAD = ADtemp;
pVoice->SIDSR = SRtemp;
extern const ubyte masterVolumeLevels[16]; // -> envelope.cpp
ubyte tmpSusVol = masterVolumeLevels[SRtemp >> 4];
if (pVoice->ADSRctrl != ENVE_SUSTAIN) // !!!
{
pVoice->enveSusVol = tmpSusVol;
}
else
{
if ( pVoice->enveSusVol > pVoice->enveVol )
pVoice->enveSusVol = 0;
else
pVoice->enveSusVol = tmpSusVol;
}
extern ptr2sidUwordFunc enveModeTable[]; // -> envelope.cpp
pVoice->ADSRproc = enveModeTable[enveTemp>>1]; // shifting out the KEY-bit
pVoice->ADSRctrl = enveTemp & (255-ENVE_ALTER-1);
if ( filterEnabled )
{
if (( c64mem2[0xd417] & pVoice->filtVoiceMask ) != 0 )
{
pVoice->filtEnabled = true;
}
else
{
pVoice->filtEnabled = false;
}
}
else
{
pVoice->filtEnabled = false;
}
}
// -------------------------------------------------- Operator frame set-up 2
// MOS-8580, MOS-6581 (no 70)
static ptr2sidVoidFunc sidModeNormalTable[16] =
{
sidMode00, sidMode10, sidMode20, sidMode30, sidMode40, sidMode50, sidMode60, sidMode70,
sidMode80, sidModeLock, sidModeLock, sidModeLock, sidModeLock, sidModeLock, sidModeLock, sidModeLock
};
// MOS-8580, MOS-6581 (no 74)
static ptr2sidVoidFunc sidModeRingTable[16] =
{
sidMode00, sidMode14, sidMode00, sidMode34, sidMode00, sidMode54, sidMode00, sidMode74,
sidModeLock, sidModeLock, sidModeLock, sidModeLock, sidModeLock, sidModeLock, sidModeLock, sidModeLock
};
inline void sidEmuSet2(struct sidOperator* pVoice)
{
pVoice->outProc = &waveCalcNormal;
pVoice->sync = false;
if ( (pVoice->SIDfreq < 16)
|| ((pVoice->SIDctrl & 8) != 0) )
{
pVoice->outProc = &waveCalcMute;
if (pVoice->SIDfreq == 0)
{
#if defined(DIRECT_FIXPOINT)
pVoice->cycleLen.l = (pVoice->cycleAddLen.l = 0);
pVoice->waveStep.l = 0;
#else
pVoice->cycleLen = (pVoice->cycleLenPnt = 0);
pVoice->cycleAddLenPnt = 0;
pVoice->waveStep = 0;
pVoice->waveStepPnt = 0;
#endif
pVoice->curSIDfreq = (pVoice->curNoiseFreq = 0);
pVoice->noiseStepAdd = 0;
pVoice->cycleLenCount = 0;
}
if ((pVoice->SIDctrl & 8) != 0)
{
if (pVoice->noiseIsLocked)
{
pVoice->noiseIsLocked = false;
#if defined(DIRECT_FIXPOINT)
pVoice->noiseReg.l = noiseSeed;
#else
pVoice->noiseReg = noiseSeed;
#endif
}
}
}
else
{
if ( pVoice->curSIDfreq != pVoice->SIDfreq )
{
pVoice->curSIDfreq = pVoice->SIDfreq;
// We keep the value cycleLen between 1 <= x <= 65535.
// This makes a range-check in waveCalcCycleLen() unrequired.
#if defined(DIRECT_FIXPOINT)
pVoice->cycleLen.l = ((PCMsid << 12) / pVoice->SIDfreq) << 4;
if (pVoice->cycleLenCount > 0)
{
waveCalcCycleLen(pVoice);
pVoice->outProc = &waveCalcRangeCheck;
}
#else
pVoice->cycleLen = PCMsid / pVoice->SIDfreq;
pVoice->cycleLenPnt = (( PCMsid % pVoice->SIDfreq ) * 65536UL ) / pVoice->SIDfreq;
if (pVoice->cycleLenCount > 0)
{
waveCalcCycleLen(pVoice);
pVoice->outProc = &waveCalcRangeCheck;
}
#endif
}
if ((( pVoice->SIDctrl & 0x80 ) == 0x80 ) && ( pVoice->curNoiseFreq != pVoice->SIDfreq ))
{
pVoice->curNoiseFreq = pVoice->SIDfreq;
pVoice->noiseStepAdd = (PCMsidNoise * pVoice->SIDfreq) >> 8;
if (pVoice->noiseStepAdd >= (1L<<21))
sidModeNormalTable[8] = sidMode80hp;
else
sidModeNormalTable[8] = sidMode80;
}
if (( pVoice->SIDctrl & 2 ) != 0 )
{
if ( ( pVoice->modulator->SIDfreq == 0 ) || (( pVoice->modulator->SIDctrl & 8 ) != 0 ) )
{
;
}
else if ( (( pVoice->carrier->SIDctrl & 2 ) != 0 ) &&
( pVoice->modulator->SIDfreq >= ( pVoice->SIDfreq << 1 )) )
{
;
}
else
{
pVoice->sync = true;
}
}
if ((( pVoice->SIDctrl & 0x14 ) == 0x14 ) && ( pVoice->modulator->SIDfreq != 0 ))
pVoice->waveProc = sidModeRingTable[pVoice->SIDctrl >> 4];
else
pVoice->waveProc = sidModeNormalTable[pVoice->SIDctrl >> 4];
}
}
// -------------------------------------------------------------- Buffer fill
static uword toFill;
ubyte bufferScale;
ubyte playRamRom;
#if defined(SIDEMU_TIME_COUNT)
static udword prevBufferLen; // need for fast_forward time count
static udword scaledBufferLen;
#endif
void* fill8bitMono(void*, udword); // only need one fill()-prototype here
void* (*sidEmuFillFunc)(void*, udword) = &fill8bitMono; // default
void sidEmuFillBuffer( emuEngine& thisEmu,
sidTune& thisTune,
void* buffer, udword bufferLen )
{
// Ensure a sane status of the whole emulator.
if ( thisEmu.isReady && thisTune.getStatus() )
{
// Both, 16-bit and stereo samples take more memory.
// Hence fewer samples fit into the buffer.
bufferLen >>= bufferScale;
// Split sample buffer into pieces for # voices:
// splitBufferLen * bytesPerSample * voices = bufferLen
if ( thisEmu.config.volumeControl == SIDEMU_HWMIXING )
{
bufferLen >>= 2; // or /4
extern udword splitBufferLen;
splitBufferLen = bufferLen;
}
#if defined(SIDEMU_TIME_COUNT)
if (prevBufferLen != bufferLen)
{
prevBufferLen = bufferLen;
scaledBufferLen = (bufferLen<<7) / fastForwardFactor;
}
thisEmu.bytesCount += scaledBufferLen;
while (thisEmu.bytesCount >= thisEmu.config.frequency)
{
thisEmu.bytesCount -= thisEmu.config.frequency;
thisEmu.secondsThisSong++;
thisEmu.secondsTotal++;
}
#endif
while ( bufferLen > 0 )
{
if ( toFill > bufferLen )
{
buffer = (*sidEmuFillFunc)(buffer, bufferLen);
toFill -= bufferLen;
bufferLen = 0;
}
else if ( toFill > 0 )
{
buffer = (*sidEmuFillFunc)(buffer, toFill);
bufferLen -= toFill;
toFill = 0;
}
if ( toFill == 0 )
{
optr3readWave = optr3.output;
optr3readEnve = optr3.enveVol;
uword replayPC = thisTune.getPlayAddr();
// playRamRom was set by external player interface.
if ( replayPC == 0 )
{
playRamRom = c64mem1[1];
if ((playRamRom & 2) != 0) // isKernal ?
{
replayPC = readLEword(c64mem1+0x0314); // IRQ
}
else
{
replayPC = readLEword(c64mem1+0xfffe); // NMI
}
}
//bool retcode =
interpreter(replayPC, playRamRom, 0, 0, 0);
if (thisTune.getSongSpeed() == SIDTUNE_SPEED_CIA_1A)
{
sidEmuUpdateReplayingSpeed();
}
masterVolume = ( c64mem2[0xd418] & 15 );
masterVolumeAmplIndex = masterVolume << 8;
if (c64mem2[0xd418]&0x80)
optr3.outputMask = 0; // off
else
optr3.outputMask = 0xff; // on
optr1.gateOnCtrl = sidKeysOn[4];
optr1.gateOffCtrl = sidKeysOff[4];
sidEmuSet( &optr1, 0xd400 );
optr2.gateOnCtrl = sidKeysOn[4+7];
optr2.gateOffCtrl = sidKeysOff[4+7];
sidEmuSet( &optr2, 0xd407 );
optr3.gateOnCtrl = sidKeysOn[4+14];
optr3.gateOffCtrl = sidKeysOff[4+14];
sidEmuSet( &optr3, 0xd40e );
filterType = c64mem2[0xd418] & 0x70;
if (filterType != filterCurType)
{
filterCurType = filterType;
optr1.filtLow = (optr1.filtRef = 0);
optr2.filtLow = (optr2.filtRef = 0);
optr3.filtLow = (optr3.filtRef = 0);
}
if ( filterEnabled )
{
filterValue = 0x7ff & ( (c64mem2[0xd415]&7) | ( (uword)c64mem2[0xd416] << 3 ));
if (filterType == 0x20)
filterDy = bandPassParam[filterValue];
else
filterDy = lowPassParam[filterValue];
filterResDy = filterResTable[c64mem2[0xd417] >> 4] - filterDy;
if ( filterResDy < 1.0 )
filterResDy = 1.0;
}
sidEmuSet2( &optr1 );
sidEmuSet2( &optr2 );
sidEmuSet2( &optr3 );
sampleEmuCheckForInit();
#if defined(DIRECT_FIXPOINT)
VALUESadd.w[HI] = 0;
VALUESadd.l += VALUES.l;
toFill = VALUESadd.w[HI];
#else
udword temp = (VALUESadd + VALUEScomma);
VALUESadd = temp & 0xFFFF;
toFill = VALUES + (temp > 65535);
#endif
// Decide whether to update/start auto-panning.
if ((apCount += timer) >= apSpeed)
{
apCount -= apSpeed;
updateAutoPanning = true;
}
else
{
updateAutoPanning = false;
}
}
} // end while bufferLen
} // end if status
}
bool sidEmuFastForwardReplay( int percent )
{
if (( percent < 1 ) || ( percent > 100 ))
{
return false;
}
else
{
fastForwardFactor = (percent<<7)/100; // we use 2^7 as divider
#if defined(SIDEMU_TIME_COUNT)
scaledBufferLen = (prevBufferLen<<7)/fastForwardFactor;
#endif
calcValuesPerCall();
// Ensure that we calculate at least a single sample per player call.
// Still possible would be also (0 < x < 1.0).
// Else (x = 0) this would cause a deadlock in the buffer fill loop.
#if defined(DIRECT_FIXPOINT)
if (VALUES.w[HI] < 1)
{
VALUES.l = (VALUESorg.l = 0);
VALUES.w[HI] = (VALUESorg.w[HI] = 1);
}
#else
if (VALUES < 1)
{
VALUES = (VALUESorg = 1);
VALUEScomma = 0;
}
#endif
return true;
}
}
// --------------------------------------------------------------------- Init
void initWaveformTables(bool isNewSID)
{
int i,j;
uword k;
k = 0;
for ( i = 0; i < 256; i++ )
for ( j = 0; j < 8; j++ )
triangleTable[k++] = i;
for ( i = 255; i >= 0; i-- )
for ( j = 0; j < 8; j++ )
triangleTable[k++] = i;
k = 0;
for ( i = 0; i < 256; i++ )
for ( j = 0; j < 16; j++ )
sawtoothTable[k++] = i;
k = 0;
for ( i = 0; i < 4096; i++ )
squareTable[k++] = 0;
for ( i = 0; i < 4096; i++ )
squareTable[k++] = 255;
if ( isNewSID )
{
waveform30 = waveform30_8580;
waveform50 = waveform50_8580;
waveform60 = waveform60_8580;
waveform70 = waveform70_8580;
}
else
{
waveform30 = waveform30_6581;
waveform50 = waveform50_6581;
waveform60 = waveform60_6581;
waveform70 = waveform70_6581; // really audible?
}
for ( i = 4096; i < 8192; i++ )
{
waveform50[i] = 0;
waveform60[i] = 0;
waveform70[i] = 0;
}
if ( isNewSID )
{
sidModeNormalTable[3] = sidMode30;
sidModeNormalTable[6] = sidMode60;
sidModeNormalTable[7] = sidMode70;
sidModeRingTable[7] = sidMode74;
}
else
{
sidModeNormalTable[3] = sidMode30;
sidModeNormalTable[6] = sidMode60;
sidModeNormalTable[7] = sidMode00; // really audible?
sidModeRingTable[7] = sidMode00; //
}
#if defined(LARGE_NOISE_TABLE)
udword ni;
for (ni = 0; ni < sizeof(noiseTableLSB); ni++)
{
noiseTableLSB[ni] = (ubyte)
(((ni >> (13-4)) & 0x10) |
((ni >> (11-3)) & 0x08) |
((ni >> (7-2)) & 0x04) |
((ni >> (4-1)) & 0x02) |
((ni >> (2-0)) & 0x01));
}
for (ni = 0; ni < sizeof(noiseTableMSB); ni++)
{
noiseTableMSB[ni] = (ubyte)
(((ni << (7-(22-16))) & 0x80) |
((ni << (6-(20-16))) & 0x40) |
((ni << (5-(16-16))) & 0x20));
}
#else
udword ni;
for (ni = 0; ni < sizeof(noiseTableLSB); ni++)
{
noiseTableLSB[ni] = (ubyte)
(((ni >> (7-2)) & 0x04) |
((ni >> (4-1)) & 0x02) |
((ni >> (2-0)) & 0x01));
}
for (ni = 0; ni < sizeof(noiseTableMID); ni++)
{
noiseTableMID[ni] = (ubyte)
(((ni >> (13-8-4)) & 0x10) |
((ni << (3-(11-8))) & 0x08));
}
for (ni = 0; ni < sizeof(noiseTableMSB); ni++)
{
noiseTableMSB[ni] = (ubyte)
(((ni << (7-(22-16))) & 0x80) |
((ni << (6-(20-16))) & 0x40) |
((ni << (5-(16-16))) & 0x20));
}
#endif
}
void sidEmuConfigure(udword PCMfrequency, bool measuredEnveValues,
bool isNewSID, bool emulateFilter, int clockSpeed)
{
sidEmuSetClockSpeed(clockSpeed); // set clock speed
PCMfreq = PCMfrequency;
PCMsid = (udword)(PCMfrequency * (16777216.0 / C64_fClockSpeed));
PCMsidNoise = (udword)((C64_fClockSpeed*256.0)/PCMfrequency);
sidEmuChangeReplayingSpeed(); // depends on frequency
sampleEmuInit(); // depends on clock speed + frequency
filterEnabled = emulateFilter;
initWaveformTables(isNewSID);
extern void enveEmuInit(udword updateFreq, bool measuredValues);
enveEmuInit(PCMfreq,measuredEnveValues);
}
// Reset.
bool sidEmuReset()
{
void clearSidOperator( struct sidOperator* );
extern void enveEmuResetOperator(sidOperator* pVoice);
clearSidOperator( &optr1 );
enveEmuResetOperator( &optr1 );
clearSidOperator( &optr2 );
enveEmuResetOperator( &optr2 );
clearSidOperator( &optr3 );
enveEmuResetOperator( &optr3 );
optr1.modulator = &optr3;
optr3.carrier = &optr1;
optr1.filtVoiceMask = 1;
optr2.modulator = &optr1;
optr1.carrier = &optr2;
optr2.filtVoiceMask = 2;
optr3.modulator = &optr2;
optr2.carrier = &optr3;
optr3.filtVoiceMask = 4;
// Used for detecting changes of the GATE-bit (aka KEY-bit).
// 6510-interpreter clears these before each call.
sidKeysOff[4] = (sidKeysOff[4+7] = (sidKeysOff[4+14] = false));
sidKeysOn[4] = (sidKeysOn[4+7] = (sidKeysOn[4+14] = false));
sampleEmuReset();
filterType = (filterCurType = 0);
filterValue = 0;
filterDy = (filterResDy = 0);
toFill = 0;
#if defined(SIDEMU_TIME_COUNT)
prevBufferLen = (scaledBufferLen = 0);
#endif
return true;
}
void clearSidOperator( struct sidOperator* pVoice )
{
pVoice->SIDfreq = 0;
pVoice->SIDctrl = 0;
pVoice->SIDAD = 0;
pVoice->SIDSR = 0;
pVoice->sync = false;
pVoice->pulseIndex = (pVoice->newPulseIndex = (pVoice->SIDpulseWidth = 0));
pVoice->curSIDfreq = (pVoice->curNoiseFreq = 0);
pVoice->output = (pVoice->noiseOutput = 0);
pVoice->outputMask = 0xff; // on
pVoice->filtIO = 0;
pVoice->filtEnabled = false;
pVoice->filtLow = (pVoice->filtRef = 0);
pVoice->cycleLenCount = 0;
#if defined(DIRECT_FIXPOINT)
pVoice->cycleLen.l = (pVoice->cycleAddLen.l = 0);
#else
pVoice->cycleLen = (pVoice->cycleLenPnt = 0);
pVoice->cycleAddLenPnt = 0;
#endif
extern sbyte waveCalcMute(struct sidOperator*);
pVoice->outProc = &waveCalcMute;
#if defined(DIRECT_FIXPOINT)
pVoice->waveStepAdd.l = (pVoice->waveStep.l = 0);
pVoice->wavePre[0].len = (pVoice->wavePre[0].stp = 0);
pVoice->wavePre[1].len = (pVoice->wavePre[1].stp = 0);
#else
pVoice->waveStepAdd = (pVoice->waveStepAddPnt = 0);
pVoice->waveStep = (pVoice->waveStepPnt = 0);
pVoice->wavePre[0].len = 0;
pVoice->wavePre[0].stp = (pVoice->wavePre[0].pnt = 0);
pVoice->wavePre[1].len = 0;
pVoice->wavePre[1].stp = (pVoice->wavePre[1].pnt = 0);
#endif
pVoice->waveStepOld = 0;
#if defined(DIRECT_FIXPOINT)
pVoice->noiseReg.l = noiseSeed;
#else
pVoice->noiseReg = noiseSeed;
#endif
pVoice->noiseStepAdd = (pVoice->noiseStep = 0);
pVoice->noiseIsLocked = false;
}
void sidEmuResetAutoPanning(int autoPanning)
{
doAutoPanning = (autoPanning!=SIDEMU_NONE);
updateAutoPanning = false;
apCount = 0;
// Auto-panning see sidEmuSet(). Reset volume levels to default.
if (doAutoPanning)
{
optr1.gainLeft = (optr1.gainSource = 0xa080);
optr1.gainRight = (optr1.gainDest = 0x2080);
optr1.gainDirec = (optr1.gainLeft > optr1.gainRight);
optr1.gainLeftCentered = 0x8080; // middle
optr1.gainRightCentered = 0x7f80;
optr2.gainLeft = (optr2.gainSource = 0x2080); // this one mirrored
optr2.gainRight = (optr2.gainDest = 0xa080);
optr2.gainDirec = (optr2.gainLeft > optr2.gainRight);
optr2.gainLeftCentered = 0x8080; // middle
optr2.gainRightCentered = 0x7f80;
optr3.gainLeft = (optr3.gainSource = 0xa080);
optr3.gainRight = (optr3.gainDest = 0x2080);
optr3.gainDirec = (optr3.gainLeft > optr3.gainRight);
optr3.gainLeftCentered = 0x8080; // middle
optr3.gainRightCentered = 0x7f80;
voice4_gainLeft = 0x8080; // middle, not moving
voice4_gainRight = 0x7f80;
}
}
void sidEmuSetVoiceVolume(int voice, uword leftLevel, uword rightLevel, uword total)
{
leftLevel *= total;
leftLevel >>= 8;
rightLevel *= total;
rightLevel >>= 8;
uword centeredLeftLevel = (0x80*total)>>8;
uword centeredRightLevel = (0x7f*total)>>8;
// Signed 8-bit samples will be added to base array index.
// So middle must be 0x80.
// [-80,-81,...,-FE,-FF,0,1,...,7E,7F]
uword leftIndex = 0x0080 + (leftLevel<<8);
uword rightIndex = 0x0080 + (rightLevel<<8);
uword gainLeftCentered = 0x0080 + (centeredLeftLevel<<8);
uword gainRightCentered = 0x0080 + (centeredRightLevel<<8);
switch ( voice )
{
case 1:
{
optr1.gainLeft = leftIndex;
optr1.gainRight = rightIndex;
//
optr1.gainSource = leftIndex;
optr1.gainDest = rightIndex;
optr1.gainLeftCentered = gainLeftCentered;
optr1.gainRightCentered = gainRightCentered;
optr1.gainDirec = (optr1.gainLeft > optr1.gainDest);
break;
}
case 2:
{
optr2.gainLeft = leftIndex;
optr2.gainRight = rightIndex;
//
optr2.gainSource = leftIndex;
optr2.gainDest = rightIndex;
optr2.gainLeftCentered = gainLeftCentered;
optr2.gainRightCentered = gainRightCentered;
optr2.gainDirec = (optr2.gainLeft > optr2.gainDest);
break;
}
case 3:
{
optr3.gainLeft = leftIndex;
optr3.gainRight = rightIndex;
//
optr3.gainSource = leftIndex;
optr3.gainDest = rightIndex;
optr3.gainLeftCentered = gainLeftCentered;
optr3.gainRightCentered = gainRightCentered;
optr3.gainDirec = (optr3.gainLeft > optr3.gainDest);
break;
}
case 4:
{
voice4_gainLeft = leftIndex;
voice4_gainRight = rightIndex;
break;
}
default:
{
break;
}
}
}
uword sidEmuReturnVoiceVolume( int voice )
{
uword left = 0;
uword right = 0;
switch ( voice )
{
case 1:
{
left = optr1.gainLeft;
right = optr1.gainRight;
break;
}
case 2:
{
left = optr2.gainLeft;
right = optr2.gainRight;
break;
}
case 3:
{
left = optr3.gainLeft;
right = optr3.gainRight;
break;
}
case 4:
{
left = voice4_gainLeft;
right = voice4_gainRight;
break;
}
default:
{
break;
}
}
return (left&0xff00)|(right>>8);
}
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