dosbox-wii/src/hardware/gus.cpp

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/*
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* Copyright (C) 2002-2019 The DOSBox 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.
*
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* 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.,
* 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301, USA.
*/
#include <string.h>
#include <iomanip>
#include <sstream>
#include "dosbox.h"
#include "inout.h"
#include "mixer.h"
#include "dma.h"
#include "pic.h"
#include "setup.h"
#include "shell.h"
#include "math.h"
#include "regs.h"
using namespace std;
//Extra bits of precision over normal gus
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#define WAVE_FRACT 9
#define WAVE_FRACT_MASK ((1 << WAVE_FRACT)-1)
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#define WAVE_MSWMASK ((1 << 16)-1)
#define WAVE_LSWMASK (0xffffffff ^ WAVE_MSWMASK)
//Amount of precision the volume has
#define RAMP_FRACT (10)
#define RAMP_FRACT_MASK ((1 << RAMP_FRACT)-1)
#define GUS_BASE myGUS.portbase
#define GUS_RATE myGUS.rate
#define LOG_GUS 0
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#define VOL_SHIFT 14
#define WCTRL_STOPPED 0x01
#define WCTRL_STOP 0x02
#define WCTRL_16BIT 0x04
#define WCTRL_LOOP 0x08
#define WCTRL_BIDIRECTIONAL 0x10
#define WCTRL_IRQENABLED 0x20
#define WCTRL_DECREASING 0x40
#define WCTRL_IRQPENDING 0x80
Bit8u adlib_commandreg;
static MixerChannel * gus_chan;
static Bit8u irqtable[8] = { 0, 2, 5, 3, 7, 11, 12, 15 };
static Bit8u dmatable[8] = { 0, 1, 3, 5, 6, 7, 0, 0 };
static Bit8u GUSRam[1024*1024]; // 1024K of GUS Ram
static Bit16u vol16bit[4096];
static Bit32u pantable[16];
class GUSChannels;
static void CheckVoiceIrq(void);
struct GFGus {
Bit8u gRegSelect;
Bit16u gRegData;
Bit32u gDramAddr;
Bit16u gCurChannel;
Bit8u DMAControl;
Bit16u dmaAddr;
Bit8u TimerControl;
Bit8u SampControl;
Bit8u mixControl;
Bit8u ActiveChannels;
Bit32u basefreq;
struct GusTimer {
Bit8u value;
bool reached;
bool raiseirq;
bool masked;
bool running;
float delay;
} timers[2];
Bit32u rate;
Bitu portbase;
Bit8u dma1;
Bit8u dma2;
Bit8u irq1;
Bit8u irq2;
bool irqenabled;
bool ChangeIRQDMA;
// IRQ status register values
Bit8u IRQStatus;
Bit32u ActiveMask;
Bit8u IRQChan;
Bit32u RampIRQ;
Bit32u WaveIRQ;
} myGUS;
Bitu DEBUG_EnableDebugger(void);
static void GUS_DMA_Callback(DmaChannel * chan,DMAEvent event);
class GUSChannels {
public:
Bit32u WaveStart;
Bit32u WaveEnd;
Bit32u WaveAddr;
Bit32u WaveAdd;
Bit8u WaveCtrl;
Bit16u WaveFreq;
Bit32u RampStart;
Bit32u RampEnd;
Bit32u RampVol;
Bit32u RampAdd;
Bit32u RampAddReal;
Bit8u RampRate;
Bit8u RampCtrl;
Bit8u PanPot;
Bit8u channum;
Bit32u irqmask;
Bit32u PanLeft;
Bit32u PanRight;
Bit32s VolLeft;
Bit32s VolRight;
GUSChannels(Bit8u num) {
channum = num;
irqmask = 1 << num;
WaveStart = 0;
WaveEnd = 0;
WaveAddr = 0;
WaveAdd = 0;
WaveFreq = 0;
WaveCtrl = 3;
RampRate = 0;
RampStart = 0;
RampEnd = 0;
RampCtrl = 3;
RampAdd = 0;
RampVol = 0;
VolLeft = 0;
VolRight = 0;
PanLeft = 0;
PanRight = 0;
PanPot = 0x7;
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}
// Returns a single 16-bit sample from the Gravis's RAM
INLINE Bit32s GetSample8() const {
Bit32u useAddr = WaveAddr >> WAVE_FRACT;
if (WaveAdd >= (1 << WAVE_FRACT)) {
Bit32s tmpsmall = (Bit8s)GUSRam[useAddr];
return tmpsmall << 8;
}
else {
Bit32u nextAddr = (useAddr + 1) & ( 1024 * 1024 - 1 );
// Interpolate
Bit32s w1 = ((Bit8s)GUSRam[useAddr]) << 8;
Bit32s w2 = ((Bit8s)GUSRam[nextAddr]) << 8;
Bit32s diff = w2 - w1;
Bit32s scale = (Bit32s)(WaveAddr&WAVE_FRACT_MASK);
return (w1 + ((diff*scale) >> WAVE_FRACT));
}
}
INLINE Bit32s GetSample16() const {
Bit32u useAddr = WaveAddr >> WAVE_FRACT;
// Formula used to convert addresses for use with 16-bit samples
Bit32u holdAddr = useAddr & 0xc0000L;
useAddr = useAddr & 0x1ffffL;
useAddr = useAddr << 1;
useAddr = (holdAddr | useAddr);
if (WaveAdd >= (1 << WAVE_FRACT)) {
return (GUSRam[useAddr + 0] | (((Bit8s)GUSRam[useAddr + 1]) << 8));
}
else {
// Interpolate
Bit32s w1 = (GUSRam[useAddr + 0] | (((Bit8s)GUSRam[useAddr + 1]) << 8));
Bit32s w2 = (GUSRam[useAddr + 2] | (((Bit8s)GUSRam[useAddr + 3]) << 8));
Bit32s diff = w2 - w1;
Bit32s scale = (Bit32s)(WaveAddr&WAVE_FRACT_MASK);
return (w1 + ((diff*scale) >> WAVE_FRACT));
}
}
void WriteWaveFreq(Bit16u val) {
WaveFreq = val;
double frameadd = double(val >> 1)/512.0; //Samples / original gus frame
double realadd = (frameadd*(double)myGUS.basefreq/(double)GUS_RATE) * (double)(1 << WAVE_FRACT);
WaveAdd = (Bit32u)realadd;
}
void WriteWaveCtrl(Bit8u val) {
Bit32u oldirq=myGUS.WaveIRQ;
WaveCtrl = val & 0x7f;
if ((val & 0xa0)==0xa0) myGUS.WaveIRQ|=irqmask;
else myGUS.WaveIRQ&=~irqmask;
if (oldirq != myGUS.WaveIRQ)
CheckVoiceIrq();
}
INLINE Bit8u ReadWaveCtrl(void) {
Bit8u ret=WaveCtrl;
if (myGUS.WaveIRQ & irqmask) ret|=0x80;
return ret;
}
void UpdateWaveRamp(void) {
WriteWaveFreq(WaveFreq);
WriteRampRate(RampRate);
}
void WritePanPot(Bit8u val) {
PanPot = val;
PanLeft = pantable[0x0f-(val & 0xf)];
PanRight = pantable[(val & 0xf)];
UpdateVolumes();
}
Bit8u ReadPanPot(void) {
return PanPot;
}
void WriteRampCtrl(Bit8u val) {
Bit32u old=myGUS.RampIRQ;
RampCtrl = val & 0x7f;
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//Manually set the irq
if ((val & 0xa0)==0xa0)
myGUS.RampIRQ|=irqmask;
else
myGUS.RampIRQ&=~irqmask;
if (old != myGUS.RampIRQ)
CheckVoiceIrq();
}
INLINE Bit8u ReadRampCtrl(void) {
Bit8u ret=RampCtrl;
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if (myGUS.RampIRQ & irqmask) ret |= 0x80;
return ret;
}
void WriteRampRate(Bit8u val) {
RampRate = val;
double frameadd = (double)(RampRate & 63)/(double)(1 << (3*(val >> 6)));
double realadd = (frameadd*(double)myGUS.basefreq/(double)GUS_RATE) * (double)(1 << RAMP_FRACT);
RampAdd = (Bit32u)realadd;
}
INLINE void WaveUpdate(void) {
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if (WaveCtrl & ( WCTRL_STOP | WCTRL_STOPPED)) return;
Bit32s WaveLeft;
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if (WaveCtrl & WCTRL_DECREASING) {
WaveAddr -= WaveAdd;
WaveLeft = WaveStart-WaveAddr;
} else {
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WaveAddr += WaveAdd;
WaveLeft = WaveAddr-WaveEnd;
}
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//Not yet reaching a boundary
if (WaveLeft<0)
return;
/* Generate an IRQ if needed */
if (WaveCtrl & 0x20) {
myGUS.WaveIRQ|=irqmask;
}
/* Check for not being in PCM operation */
if (RampCtrl & 0x04) return;
/* Check for looping */
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if (WaveCtrl & WCTRL_LOOP) {
/* Bi-directional looping */
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if (WaveCtrl & WCTRL_BIDIRECTIONAL) WaveCtrl^= WCTRL_DECREASING;
WaveAddr = (WaveCtrl & WCTRL_DECREASING) ? (WaveEnd-WaveLeft) : (WaveStart+WaveLeft);
} else {
WaveCtrl|=1; //Stop the channel
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WaveAddr = (WaveCtrl & WCTRL_DECREASING) ? WaveStart : WaveEnd;
}
}
INLINE void UpdateVolumes(void) {
Bit32s templeft=RampVol - PanLeft;
templeft&=~(templeft >> 31);
Bit32s tempright=RampVol - PanRight;
tempright&=~(tempright >> 31);
VolLeft=vol16bit[templeft >> RAMP_FRACT];
VolRight=vol16bit[tempright >> RAMP_FRACT];
}
INLINE void RampUpdate(void) {
/* Check if ramping enabled */
if (RampCtrl & 0x3) return;
Bit32s RampLeft;
if (RampCtrl & 0x40) {
RampVol-=RampAdd;
RampLeft=RampStart-RampVol;
} else {
RampVol+=RampAdd;
RampLeft=RampVol-RampEnd;
}
if (RampLeft<0) {
UpdateVolumes();
return;
}
/* Generate an IRQ if needed */
if (RampCtrl & 0x20) {
myGUS.RampIRQ|=irqmask;
}
/* Check for looping */
if (RampCtrl & 0x08) {
/* Bi-directional looping */
if (RampCtrl & 0x10) RampCtrl^=0x40;
RampVol = (RampCtrl & 0x40) ? (RampEnd-RampLeft) : (RampStart+RampLeft);
} else {
RampCtrl|=1; //Stop the channel
RampVol = (RampCtrl & 0x40) ? RampStart : RampEnd;
}
UpdateVolumes();
}
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void generateSamples(Bit32s * stream,Bit32u len) {
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//Disabled channel
if (RampCtrl & WaveCtrl & 3) return;
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if (WaveCtrl & WCTRL_16BIT) {
for (int i = 0; i < (int)len; i++) {
// Get sample
Bit32s tmpsamp = GetSample16();
// Output stereo sample
stream[i << 1] += tmpsamp * VolLeft;
stream[(i << 1) + 1] += tmpsamp * VolRight;
WaveUpdate();
RampUpdate();
}
}
else {
for (int i = 0; i < (int)len; i++) {
// Get sample
Bit32s tmpsamp = GetSample8();
// Output stereo sample
stream[i << 1] += tmpsamp * VolLeft;
stream[(i << 1) + 1] += tmpsamp * VolRight;
WaveUpdate();
RampUpdate();
}
}
}
};
static GUSChannels *guschan[32];
static GUSChannels *curchan;
static void GUSReset(void) {
if((myGUS.gRegData & 0x1) == 0x1) {
// Reset
adlib_commandreg = 85;
myGUS.IRQStatus = 0;
myGUS.timers[0].raiseirq = false;
myGUS.timers[1].raiseirq = false;
myGUS.timers[0].reached = false;
myGUS.timers[1].reached = false;
myGUS.timers[0].running = false;
myGUS.timers[1].running = false;
myGUS.timers[0].value = 0xff;
myGUS.timers[1].value = 0xff;
myGUS.timers[0].delay = 0.080f;
myGUS.timers[1].delay = 0.320f;
myGUS.ChangeIRQDMA = false;
myGUS.mixControl = 0x0b; // latches enabled by default LINEs disabled
// Stop all channels
int i;
for(i=0;i<32;i++) {
guschan[i]->RampVol=0;
guschan[i]->WriteWaveCtrl(0x1);
guschan[i]->WriteRampCtrl(0x1);
guschan[i]->WritePanPot(0x7);
}
myGUS.IRQChan = 0;
}
if ((myGUS.gRegData & 0x4) != 0) {
myGUS.irqenabled = true;
} else {
myGUS.irqenabled = false;
}
}
static INLINE void GUS_CheckIRQ(void) {
if (myGUS.IRQStatus && (myGUS.mixControl & 0x08))
PIC_ActivateIRQ(myGUS.irq1);
}
static void CheckVoiceIrq(void) {
myGUS.IRQStatus&=0x9f;
Bitu totalmask=(myGUS.RampIRQ|myGUS.WaveIRQ) & myGUS.ActiveMask;
if (!totalmask) return;
if (myGUS.RampIRQ) myGUS.IRQStatus|=0x40;
if (myGUS.WaveIRQ) myGUS.IRQStatus|=0x20;
GUS_CheckIRQ();
for (;;) {
Bit32u check=(1 << myGUS.IRQChan);
if (totalmask & check) return;
myGUS.IRQChan++;
if (myGUS.IRQChan>=myGUS.ActiveChannels) myGUS.IRQChan=0;
}
}
static Bit16u ExecuteReadRegister(void) {
Bit8u tmpreg;
// LOG_MSG("Read global reg %x",myGUS.gRegSelect);
switch (myGUS.gRegSelect) {
case 0x41: // Dma control register - read acknowledges DMA IRQ
tmpreg = myGUS.DMAControl & 0xbf;
tmpreg |= (myGUS.IRQStatus & 0x80) >> 1;
myGUS.IRQStatus&=0x7f;
return (Bit16u)(tmpreg << 8);
case 0x42: // Dma address register
return myGUS.dmaAddr;
case 0x45: // Timer control register. Identical in operation to Adlib's timer
return (Bit16u)(myGUS.TimerControl << 8);
break;
case 0x49: // Dma sample register
tmpreg = myGUS.DMAControl & 0xbf;
tmpreg |= (myGUS.IRQStatus & 0x80) >> 1;
return (Bit16u)(tmpreg << 8);
case 0x80: // Channel voice control read register
if (curchan) return curchan->ReadWaveCtrl() << 8;
else return 0x0300;
case 0x82: // Channel MSB start address register
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if (curchan) return (Bit16u)(curchan->WaveStart >> 16);
else return 0x0000;
case 0x83: // Channel LSW start address register
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if (curchan) return (Bit16u)(curchan->WaveStart );
else return 0x0000;
case 0x89: // Channel volume register
if (curchan) return (Bit16u)((curchan->RampVol >> RAMP_FRACT) << 4);
else return 0x0000;
case 0x8a: // Channel MSB current address register
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if (curchan) return (Bit16u)(curchan->WaveAddr >> 16);
else return 0x0000;
case 0x8b: // Channel LSW current address register
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if (curchan) return (Bit16u)(curchan->WaveAddr );
else return 0x0000;
case 0x8d: // Channel volume control register
if (curchan) return curchan->ReadRampCtrl() << 8;
else return 0x0300;
case 0x8f: // General channel IRQ status register
tmpreg=myGUS.IRQChan|0x20;
Bit32u mask;
mask=1 << myGUS.IRQChan;
if (!(myGUS.RampIRQ & mask)) tmpreg|=0x40;
if (!(myGUS.WaveIRQ & mask)) tmpreg|=0x80;
myGUS.RampIRQ&=~mask;
myGUS.WaveIRQ&=~mask;
CheckVoiceIrq();
return (Bit16u)(tmpreg << 8);
default:
#if LOG_GUS
LOG_MSG("Read Register num 0x%x", myGUS.gRegSelect);
#endif
return myGUS.gRegData;
}
}
static void GUS_TimerEvent(Bitu val) {
if (!myGUS.timers[val].masked) myGUS.timers[val].reached=true;
if (myGUS.timers[val].raiseirq) {
myGUS.IRQStatus|=0x4 << val;
GUS_CheckIRQ();
}
if (myGUS.timers[val].running)
PIC_AddEvent(GUS_TimerEvent,myGUS.timers[val].delay,val);
}
static void ExecuteGlobRegister(void) {
int i;
// if (myGUS.gRegSelect|1!=0x44) LOG_MSG("write global register %x with %x", myGUS.gRegSelect, myGUS.gRegData);
switch(myGUS.gRegSelect) {
case 0x0: // Channel voice control register
if(curchan) curchan->WriteWaveCtrl((Bit16u)myGUS.gRegData>>8);
break;
case 0x1: // Channel frequency control register
if(curchan) curchan->WriteWaveFreq(myGUS.gRegData);
break;
case 0x2: // Channel MSW start address register
if (curchan) {
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Bit32u tmpaddr = (Bit32u)((myGUS.gRegData & 0x1fff) << 16);
curchan->WaveStart = (curchan->WaveStart & WAVE_MSWMASK) | tmpaddr;
}
break;
case 0x3: // Channel LSW start address register
if(curchan != NULL) {
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Bit32u tmpaddr = (Bit32u)(myGUS.gRegData);
curchan->WaveStart = (curchan->WaveStart & WAVE_LSWMASK) | tmpaddr;
}
break;
case 0x4: // Channel MSW end address register
if(curchan != NULL) {
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Bit32u tmpaddr = (Bit32u)(myGUS.gRegData & 0x1fff) << 16;
curchan->WaveEnd = (curchan->WaveEnd & WAVE_MSWMASK) | tmpaddr;
}
break;
case 0x5: // Channel MSW end address register
if(curchan != NULL) {
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Bit32u tmpaddr = (Bit32u)(myGUS.gRegData);
curchan->WaveEnd = (curchan->WaveEnd & WAVE_LSWMASK) | tmpaddr;
}
break;
case 0x6: // Channel volume ramp rate register
if(curchan != NULL) {
Bit8u tmpdata = (Bit16u)myGUS.gRegData>>8;
curchan->WriteRampRate(tmpdata);
}
break;
case 0x7: // Channel volume ramp start register EEEEMMMM
if(curchan != NULL) {
Bit8u tmpdata = (Bit16u)myGUS.gRegData >> 8;
curchan->RampStart = tmpdata << (4+RAMP_FRACT);
}
break;
case 0x8: // Channel volume ramp end register EEEEMMMM
if(curchan != NULL) {
Bit8u tmpdata = (Bit16u)myGUS.gRegData >> 8;
curchan->RampEnd = tmpdata << (4+RAMP_FRACT);
}
break;
case 0x9: // Channel current volume register
if(curchan != NULL) {
Bit16u tmpdata = (Bit16u)myGUS.gRegData >> 4;
curchan->RampVol = tmpdata << RAMP_FRACT;
curchan->UpdateVolumes();
}
break;
case 0xA: // Channel MSW current address register
if(curchan != NULL) {
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Bit32u tmpaddr = (Bit32u)(myGUS.gRegData & 0x1fff) << 16;
curchan->WaveAddr = (curchan->WaveAddr & WAVE_MSWMASK) | tmpaddr;
}
break;
case 0xB: // Channel LSW current address register
if(curchan != NULL) {
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Bit32u tmpaddr = (Bit32u)(myGUS.gRegData);
curchan->WaveAddr = (curchan->WaveAddr & WAVE_LSWMASK) | tmpaddr;
}
break;
case 0xC: // Channel pan pot register
if(curchan) curchan->WritePanPot((Bit16u)myGUS.gRegData>>8);
break;
case 0xD: // Channel volume control register
if(curchan) curchan->WriteRampCtrl((Bit16u)myGUS.gRegData>>8);
break;
case 0xE: // Set active channel register
myGUS.gRegSelect = myGUS.gRegData>>8; //JAZZ Jackrabbit seems to assume this?
myGUS.ActiveChannels = 1+((myGUS.gRegData>>8) & 63);
if(myGUS.ActiveChannels < 14) myGUS.ActiveChannels = 14;
if(myGUS.ActiveChannels > 32) myGUS.ActiveChannels = 32;
myGUS.ActiveMask=0xffffffffU >> (32-myGUS.ActiveChannels);
gus_chan->Enable(true);
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myGUS.basefreq = (Bit32u)(0.5 + 1000000.0/(1.619695497*(double)(myGUS.ActiveChannels)));
#if LOG_GUS
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LOG_MSG("GUS set to %d channels, freq %d", myGUS.ActiveChannels, myGUS.basefreq);
#endif
for (i=0;i<myGUS.ActiveChannels;i++) guschan[i]->UpdateWaveRamp();
break;
case 0x10: // Undocumented register used in Fast Tracker 2
break;
case 0x41: // Dma control register
myGUS.DMAControl = (Bit8u)(myGUS.gRegData>>8);
GetDMAChannel(myGUS.dma1)->Register_Callback(
(myGUS.DMAControl & 0x1) ? GUS_DMA_Callback : 0);
break;
case 0x42: // Gravis DRAM DMA address register
myGUS.dmaAddr = myGUS.gRegData;
break;
case 0x43: // MSB Peek/poke DRAM position
myGUS.gDramAddr = (0xff0000 & myGUS.gDramAddr) | ((Bit32u)myGUS.gRegData);
break;
case 0x44: // LSW Peek/poke DRAM position
myGUS.gDramAddr = (0xffff & myGUS.gDramAddr) | ((Bit32u)myGUS.gRegData>>8) << 16;
break;
case 0x45: // Timer control register. Identical in operation to Adlib's timer
myGUS.TimerControl = (Bit8u)(myGUS.gRegData>>8);
myGUS.timers[0].raiseirq=(myGUS.TimerControl & 0x04)>0;
if (!myGUS.timers[0].raiseirq) myGUS.IRQStatus&=~0x04;
myGUS.timers[1].raiseirq=(myGUS.TimerControl & 0x08)>0;
if (!myGUS.timers[1].raiseirq) myGUS.IRQStatus&=~0x08;
break;
case 0x46: // Timer 1 control
myGUS.timers[0].value = (Bit8u)(myGUS.gRegData>>8);
myGUS.timers[0].delay = (0x100 - myGUS.timers[0].value) * 0.080f;
break;
case 0x47: // Timer 2 control
myGUS.timers[1].value = (Bit8u)(myGUS.gRegData>>8);
myGUS.timers[1].delay = (0x100 - myGUS.timers[1].value) * 0.320f;
break;
case 0x49: // DMA sampling control register
myGUS.SampControl = (Bit8u)(myGUS.gRegData>>8);
GetDMAChannel(myGUS.dma1)->Register_Callback(
(myGUS.SampControl & 0x1) ? GUS_DMA_Callback : 0);
break;
case 0x4c: // GUS reset register
GUSReset();
break;
default:
#if LOG_GUS
LOG_MSG("Unimplemented global register %x -- %x", myGUS.gRegSelect, myGUS.gRegData);
#endif
break;
}
return;
}
static Bitu read_gus(Bitu port,Bitu iolen) {
// LOG_MSG("read from gus port %x",port);
switch(port - GUS_BASE) {
case 0x206:
return myGUS.IRQStatus;
case 0x208:
Bit8u tmptime;
tmptime = 0;
if (myGUS.timers[0].reached) tmptime |= (1 << 6);
if (myGUS.timers[1].reached) tmptime |= (1 << 5);
if (tmptime & 0x60) tmptime |= (1 << 7);
if (myGUS.IRQStatus & 0x04) tmptime|=(1 << 2);
if (myGUS.IRQStatus & 0x08) tmptime|=(1 << 1);
return tmptime;
case 0x20a:
return adlib_commandreg;
case 0x302:
return (Bit8u)myGUS.gCurChannel;
case 0x303:
return myGUS.gRegSelect;
case 0x304:
if (iolen==2) return ExecuteReadRegister() & 0xffff;
else return ExecuteReadRegister() & 0xff;
case 0x305:
return ExecuteReadRegister() >> 8;
case 0x307:
if(myGUS.gDramAddr < sizeof(GUSRam)) {
return GUSRam[myGUS.gDramAddr];
} else {
return 0;
}
default:
#if LOG_GUS
LOG_MSG("Read GUS at port 0x%x", port);
#endif
break;
}
return 0xff;
}
static void write_gus(Bitu port,Bitu val,Bitu iolen) {
// LOG_MSG("Write gus port %x val %x",port,val);
switch(port - GUS_BASE) {
case 0x200:
myGUS.mixControl = (Bit8u)val;
myGUS.ChangeIRQDMA = true;
return;
case 0x208:
adlib_commandreg = (Bit8u)val;
break;
case 0x209:
//TODO adlib_commandreg should be 4 for this to work else it should just latch the value
if (val & 0x80) {
myGUS.timers[0].reached=false;
myGUS.timers[1].reached=false;
return;
}
myGUS.timers[0].masked=(val & 0x40)>0;
myGUS.timers[1].masked=(val & 0x20)>0;
if (val & 0x1) {
if (!myGUS.timers[0].running) {
PIC_AddEvent(GUS_TimerEvent,myGUS.timers[0].delay,0);
myGUS.timers[0].running=true;
}
} else myGUS.timers[0].running=false;
if (val & 0x2) {
if (!myGUS.timers[1].running) {
PIC_AddEvent(GUS_TimerEvent,myGUS.timers[1].delay,1);
myGUS.timers[1].running=true;
}
} else myGUS.timers[1].running=false;
break;
//TODO Check if 0x20a register is also available on the gus like on the interwave
case 0x20b:
if (!myGUS.ChangeIRQDMA) break;
myGUS.ChangeIRQDMA=false;
if (myGUS.mixControl & 0x40) {
// IRQ configuration, only use low bits for irq 1
if (irqtable[val & 0x7]) myGUS.irq1=irqtable[val & 0x7];
#if LOG_GUS
LOG_MSG("Assigned GUS to IRQ %d", myGUS.irq1);
#endif
} else {
// DMA configuration, only use low bits for dma 1
if (dmatable[val & 0x7]) myGUS.dma1=dmatable[val & 0x7];
#if LOG_GUS
LOG_MSG("Assigned GUS to DMA %d", myGUS.dma1);
#endif
}
break;
case 0x302:
myGUS.gCurChannel = val & 31 ;
curchan = guschan[myGUS.gCurChannel];
break;
case 0x303:
myGUS.gRegSelect = (Bit8u)val;
myGUS.gRegData = 0;
break;
case 0x304:
if (iolen==2) {
myGUS.gRegData=(Bit16u)val;
ExecuteGlobRegister();
} else myGUS.gRegData = (Bit16u)val;
break;
case 0x305:
myGUS.gRegData = (Bit16u)((0x00ff & myGUS.gRegData) | val << 8);
ExecuteGlobRegister();
break;
case 0x307:
if(myGUS.gDramAddr < sizeof(GUSRam)) GUSRam[myGUS.gDramAddr] = (Bit8u)val;
break;
default:
#if LOG_GUS
LOG_MSG("Write GUS at port 0x%x with %x", port, val);
#endif
break;
}
}
static void GUS_DMA_Callback(DmaChannel * chan,DMAEvent event) {
if (event!=DMA_UNMASKED) return;
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Bitu dmaaddr;
//Calculate the dma address
//DMA transfers can't cross 256k boundaries, so you should be safe to just determine the start once and go from there
//Bit 2 - 0 = if DMA channel is an 8 bit channel(0 - 3).
if (myGUS.DMAControl & 0x4)
dmaaddr = (((myGUS.dmaAddr & 0x1fff) << 1) | (myGUS.dmaAddr & 0xc000)) << 4;
else
dmaaddr = myGUS.dmaAddr << 4;
//Reading from dma?
if((myGUS.DMAControl & 0x2) == 0) {
Bitu read=chan->Read(chan->currcnt+1,&GUSRam[dmaaddr]);
//Check for 16 or 8bit channel
read*=(chan->DMA16+1);
if((myGUS.DMAControl & 0x80) != 0) {
//Invert the MSB to convert twos compliment form
Bitu i;
if((myGUS.DMAControl & 0x40) == 0) {
// 8-bit data
for(i=dmaaddr;i<(dmaaddr+read);i++) GUSRam[i] ^= 0x80;
} else {
// 16-bit data
for(i=dmaaddr+1;i<(dmaaddr+read);i+=2) GUSRam[i] ^= 0x80;
}
}
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//Writing to dma
} else {
chan->Write(chan->currcnt+1,&GUSRam[dmaaddr]);
}
/* Raise the TC irq if needed */
if((myGUS.DMAControl & 0x20) != 0) {
myGUS.IRQStatus |= 0x80;
GUS_CheckIRQ();
}
chan->Register_Callback(0);
}
static void GUS_CallBack(Bitu len) {
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Bit32s buffer[MIXER_BUFSIZE][2];
memset(buffer, 0, len * sizeof(buffer[0]));
for (Bitu i = 0; i < myGUS.ActiveChannels; i++) {
guschan[i]->generateSamples(buffer[0], len);
}
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for (Bitu i = 0; i < len; i++) {
buffer[i][0] >>= VOL_SHIFT;
buffer[i][1] >>= VOL_SHIFT;
}
gus_chan->AddSamples_s32(len, buffer[0]);
CheckVoiceIrq();
}
// Generate logarithmic to linear volume conversion tables
static void MakeTables(void) {
int i;
double out = (double)(1 << 13);
for (i=4095;i>=0;i--) {
vol16bit[i]=(Bit16s)out;
out/=1.002709201; /* 0.0235 dB Steps */
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//Original amplification routine in the hardware
//vol16bit[i] = ((256 + i & 0xff) << VOL_SHIFT) / (1 << (24 - (i >> 8)));
}
pantable[0] = 4095 << RAMP_FRACT;
for (i=1;i<16;i++) {
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pantable[i]=(Bit32u)(0.5-128.0*(log((double)i/15.0)/log(2.0))*(double)(1 << RAMP_FRACT));
}
}
class GUS:public Module_base{
private:
IO_ReadHandleObject ReadHandler[8];
IO_WriteHandleObject WriteHandler[9];
AutoexecObject autoexecline[2];
MixerObject MixerChan;
public:
GUS(Section* configuration):Module_base(configuration){
if(!IS_EGAVGA_ARCH) return;
Section_prop * section=static_cast<Section_prop *>(configuration);
if(!section->Get_bool("gus")) return;
memset(&myGUS,0,sizeof(myGUS));
memset(GUSRam,0,1024*1024);
myGUS.rate=section->Get_int("gusrate");
myGUS.portbase = section->Get_hex("gusbase") - 0x200;
int dma_val = section->Get_int("gusdma");
if ((dma_val<0) || (dma_val>255)) dma_val = 3; // sensible default
int irq_val = section->Get_int("gusirq");
if ((irq_val<0) || (irq_val>255)) irq_val = 5; // sensible default
myGUS.dma1 = (Bit8u)dma_val;
myGUS.dma2 = (Bit8u)dma_val;
myGUS.irq1 = (Bit8u)irq_val;
myGUS.irq2 = (Bit8u)irq_val;
// We'll leave the MIDI interface to the MPU-401
// Ditto for the Joystick
// GF1 Synthesizer
ReadHandler[0].Install(0x302 + GUS_BASE,read_gus,IO_MB);
WriteHandler[0].Install(0x302 + GUS_BASE,write_gus,IO_MB);
WriteHandler[1].Install(0x303 + GUS_BASE,write_gus,IO_MB);
ReadHandler[1].Install(0x303 + GUS_BASE,read_gus,IO_MB);
WriteHandler[2].Install(0x304 + GUS_BASE,write_gus,IO_MB|IO_MW);
ReadHandler[2].Install(0x304 + GUS_BASE,read_gus,IO_MB|IO_MW);
WriteHandler[3].Install(0x305 + GUS_BASE,write_gus,IO_MB);
ReadHandler[3].Install(0x305 + GUS_BASE,read_gus,IO_MB);
ReadHandler[4].Install(0x206 + GUS_BASE,read_gus,IO_MB);
WriteHandler[4].Install(0x208 + GUS_BASE,write_gus,IO_MB);
ReadHandler[5].Install(0x208 + GUS_BASE,read_gus,IO_MB);
WriteHandler[5].Install(0x209 + GUS_BASE,write_gus,IO_MB);
WriteHandler[6].Install(0x307 + GUS_BASE,write_gus,IO_MB);
ReadHandler[6].Install(0x307 + GUS_BASE,read_gus,IO_MB);
// Board Only
WriteHandler[7].Install(0x200 + GUS_BASE,write_gus,IO_MB);
ReadHandler[7].Install(0x20A + GUS_BASE,read_gus,IO_MB);
WriteHandler[8].Install(0x20B + GUS_BASE,write_gus,IO_MB);
// DmaChannels[myGUS.dma1]->Register_TC_Callback(GUS_DMA_TC_Callback);
MakeTables();
for (Bit8u chan_ct=0; chan_ct<32; chan_ct++) {
guschan[chan_ct] = new GUSChannels(chan_ct);
}
// Register the Mixer CallBack
gus_chan=MixerChan.Install(GUS_CallBack,GUS_RATE,"GUS");
myGUS.gRegData=0x1;
GUSReset();
myGUS.gRegData=0x0;
int portat = 0x200+GUS_BASE;
// ULTRASND=Port,DMA1,DMA2,IRQ1,IRQ2
// [GUS port], [GUS DMA (recording)], [GUS DMA (playback)], [GUS IRQ (playback)], [GUS IRQ (MIDI)]
ostringstream temp;
temp << "SET ULTRASND=" << hex << setw(3) << portat << ","
<< dec << (Bitu)myGUS.dma1 << "," << (Bitu)myGUS.dma2 << ","
<< (Bitu)myGUS.irq1 << "," << (Bitu)myGUS.irq2 << ends;
// Create autoexec.bat lines
autoexecline[0].Install(temp.str());
autoexecline[1].Install(std::string("SET ULTRADIR=") + section->Get_string("ultradir"));
}
~GUS() {
if(!IS_EGAVGA_ARCH) return;
Section_prop * section=static_cast<Section_prop *>(m_configuration);
if(!section->Get_bool("gus")) return;
myGUS.gRegData=0x1;
GUSReset();
myGUS.gRegData=0x0;
for(Bitu i=0;i<32;i++) {
delete guschan[i];
}
memset(&myGUS,0,sizeof(myGUS));
memset(GUSRam,0,1024*1024);
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}
};
static GUS* test;
void GUS_ShutDown(Section* /*sec*/) {
delete test;
}
void GUS_Init(Section* sec) {
test = new GUS(sec);
sec->AddDestroyFunction(&GUS_ShutDown,true);
}