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zmusic/thirdparty/opnmidi/chips/np2/fmgen_opna.cpp
Wohlstand 72c23d98a3 Update libOPNMIDI library to 1.5.0 
## 1.5.0   2020-09-28
 * Drum note length expanding is now supported in real-time mode (Thanks to [Jean Pierre Cimalando](https://github.com/jpcima) for a work!)
 * Added support for OPNA chip with Neko Project II Kai YM2602 emulator usage (Thanks to [Jean Pierre Cimalando](https://github.com/jpcima) for a work!)
 * Added VGM file dumper which allows to output OPN2 commands into VGM file. (A new MIDI to VGM tool is now created with basing on libOPNMIDI)
 * Fixed an incorrect work of CC-121 (See https://github.com/Wohlstand/libADLMIDI/issues/227 for details)
 * Internality has been refactored and improved
2020-10-04 08:03:44 +02:00

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// ---------------------------------------------------------------------------
// OPN/A/B interface with ADPCM support
// Copyright (C) cisc 1998, 2001.
// ---------------------------------------------------------------------------
// $Id: opna.cpp,v 1.68 2003/06/12 14:03:44 cisc Exp $
#include "fmgen_types.h"
#include "fmgen_headers.h"
#include "fmgen_misc.h"
#include "fmgen_opna.h"
#include "fmgen_fmgeninl.h"
#define BUILD_OPN
#define BUILD_OPNA
#define BUILD_OPNB
// TOFIX:
// OPN ch3 <20><><EFBFBD><EFBFBD><EFBFBD>Prepare<72>̑ΏۂƂȂ<C682><C882>Ă<EFBFBD><C482>܂<EFBFBD><DC82><EFBFBD>Q
// ---------------------------------------------------------------------------
// OPNA: ADPCM <20>f<EFBFBD>[<5B>^<5E>̊i<CC8A>[<5B><><EFBFBD><EFBFBD><EFBFBD>̈Ⴂ (8bit/1bit) <20><><EFBFBD>G<EFBFBD>~<7E><><EFBFBD><EFBFBD><EFBFBD>[<5B>g<EFBFBD><67><EFBFBD>Ȃ<EFBFBD>
// <09><><EFBFBD>̃I<CC83>v<EFBFBD>V<EFBFBD><56><EFBFBD><EFBFBD><EFBFBD><EFBFBD>L<EFBFBD><4C><EFBFBD>ɂ<EFBFBD><C982><EFBFBD><EFBFBD> ADPCM <20><><EFBFBD><EFBFBD><EFBFBD><EFBFBD><EFBFBD>ւ̃A<CC83>N<EFBFBD>Z<EFBFBD>X(<28><><EFBFBD><EFBFBD> 8bit <20><><EFBFBD>[<5B>h)<29><>
// <09><><EFBFBD><EFBFBD><EFBFBD>y<EFBFBD><79><EFBFBD>Ȃ邩<C882><E982A9>
//
//#define NO_BITTYPE_EMULATION
#ifdef BUILD_OPNA
#include "fmgen_file.h"
#endif
namespace FM
{
// ---------------------------------------------------------------------------
// OPNBase
#if defined(BUILD_OPN) || defined(BUILD_OPNA) || defined (BUILD_OPNB)
uint32 OPNBase::lfotable[8]; // OPNA/B <20>p
OPNBase::OPNBase()
{
prescale = 0;
}
// <09>p<EFBFBD><70><EFBFBD><EFBFBD><EFBFBD>[<5B>^<5E>Z<EFBFBD>b<EFBFBD>g
void OPNBase::SetParameter(Channel4* ch, uint addr, uint data)
{
const static uint slottable[4] = { 0, 2, 1, 3 };
const static uint8 sltable[16] =
{
0, 4, 8, 12, 16, 20, 24, 28,
32, 36, 40, 44, 48, 52, 56, 124,
};
if ((addr & 3) < 3)
{
uint slot = slottable[(addr >> 2) & 3];
Operator* op = &ch->op[slot];
switch ((addr >> 4) & 15)
{
case 3: // 30-3E DT/MULTI
op->SetDT((data >> 4) & 0x07);
op->SetMULTI(data & 0x0f);
break;
case 4: // 40-4E TL
op->SetTL(data & 0x7f, (regtc & 0x80) && (csmch == ch));
break;
case 5: // 50-5E KS/AR
op->SetKS((data >> 6) & 3);
op->SetAR((data & 0x1f) * 2);
break;
case 6: // 60-6E DR/AMON
op->SetDR((data & 0x1f) * 2);
op->SetAMON((data & 0x80) != 0);
break;
case 7: // 70-7E SR
op->SetSR((data & 0x1f) * 2);
break;
case 8: // 80-8E SL/RR
op->SetSL(sltable[(data >> 4) & 15]);
op->SetRR((data & 0x0f) * 4 + 2);
break;
case 9: // 90-9E SSG-EC
op->SetSSGEC(data & 0x0f);
break;
}
}
}
// <09><><EFBFBD>Z<EFBFBD>b<EFBFBD>g
void OPNBase::Reset()
{
status = 0;
SetPrescaler(0);
Timer::Reset();
psg.Reset();
}
// <09>v<EFBFBD><76><EFBFBD>X<EFBFBD>P<EFBFBD>[<5B><><EFBFBD>ݒ<EFBFBD>
void OPNBase::SetPrescaler(uint p)
{
static const char table[3][2] = { { 6, 4 }, { 3, 2 }, { 2, 1 } };
static const uint8 table2[8] = { 108, 77, 71, 67, 62, 44, 8, 5 };
// 512
if (prescale != p)
{
prescale = p;
/*warning: comparison is always true due to limited range of data type [-Wtype-limits]*/
// assert(0 <= prescale && prescale < 3);
assert(prescale < 3);
uint fmclock = clock / table[p][0] / 12;
rate = psgrate;
// <20><><EFBFBD><EFBFBD><EFBFBD><EFBFBD><EFBFBD>g<EFBFBD><67><EFBFBD>Əo<C68F>͎<EFBFBD><CD8E>g<EFBFBD><67><EFBFBD>̔<EFBFBD>
assert(fmclock < (0x80000000 >> FM_RATIOBITS));
uint ratio = ((fmclock << FM_RATIOBITS) + rate/2) / rate;
SetTimerBase(fmclock);
// MakeTimeTable(ratio);
chip.SetRatio(ratio);
psg.SetClock(clock / table[p][1], psgrate);
for (int i=0; i<8; i++)
{
lfotable[i] = (ratio << (2+FM_LFOCBITS-FM_RATIOBITS)) / table2[i];
}
}
}
// <09><><EFBFBD><EFBFBD><EFBFBD><EFBFBD>
bool OPNBase::Init(uint c, uint r)
{
clock = c;
psgrate = r;
return true;
}
// <09><><EFBFBD>ʐݒ<CA90>
void OPNBase::SetVolumeFM(int db)
{
db = Min(db, 20);
if (db > -192)
fmvolume = int(16384.0 * pow(10.0, db / 40.0));
else
fmvolume = 0;
}
// <09>^<5E>C<EFBFBD>}<7D>[<5B><><EFBFBD>ԏ<EFBFBD><D48F><EFBFBD>
void OPNBase::TimerA()
{
if (regtc & 0x80)
{
csmch->KeyControl(0x00);
csmch->KeyControl(0x0f);
}
}
void OPNBase::DataSave(struct OPNBaseData* data) {
Timer::DataSave(&data->timer);
data->fmvolume = fmvolume;
data->clock = clock;
data->rate = rate;
data->psgrate = psgrate;
data->status = status;
data->prescale = prescale;
chip.DataSave(&data->chip);
psg.DataSave(&data->psg);
}
void OPNBase::DataLoad(struct OPNBaseData* data) {
Timer::DataLoad(&data->timer);
fmvolume = data->fmvolume;
clock = data->clock;
rate = data->rate;
psgrate = data->psgrate;
status = data->status;
prescale = data->prescale;
chip.DataLoad(&data->chip);
psg.DataLoad(&data->psg);
}
#endif // defined(BUILD_OPN) || defined(BUILD_OPNA) || defined (BUILD_OPNB)
// ---------------------------------------------------------------------------
// YM2203
//
#ifdef BUILD_OPN
OPN::OPN()
{
SetVolumeFM(0);
SetVolumePSG(0);
csmch = &ch[2];
for (int i=0; i<3; i++)
{
ch[i].SetChip(&chip);
ch[i].SetType(typeN);
}
}
// <09><><EFBFBD><EFBFBD><EFBFBD><EFBFBD>
bool OPN::Init(uint c, uint r, bool ip, const char*)
{
if (!SetRate(c, r, ip))
return false;
Reset();
SetVolumeFM(0);
SetVolumePSG(0);
SetChannelMask(0);
return true;
}
// <09>T<EFBFBD><54><EFBFBD>v<EFBFBD><76><EFBFBD><EFBFBD><EFBFBD>O<EFBFBD><4F><EFBFBD>[<5B>g<EFBFBD>ύX
bool OPN::SetRate(uint c, uint r, bool)
{
OPNBase::Init(c, r);
RebuildTimeTable();
return true;
}
// <09><><EFBFBD>Z<EFBFBD>b<EFBFBD>g
void OPN::Reset()
{
int i;
for (i=0x20; i<0x28; i++) SetReg(i, 0);
for (i=0x30; i<0xc0; i++) SetReg(i, 0);
OPNBase::Reset();
ch[0].Reset();
ch[1].Reset();
ch[2].Reset();
}
// <09><><EFBFBD>W<EFBFBD>X<EFBFBD>^<5E>ǂݍ<C782><DD8D><EFBFBD>
uint OPN::GetReg(uint addr)
{
if (addr < 0x10)
return psg.GetReg(addr);
else
return 0;
}
// <09><><EFBFBD>W<EFBFBD>X<EFBFBD>^<5E>A<EFBFBD><41><EFBFBD>C<EFBFBD>Ƀf<C983>[<5B>^<5E><>ݒ<EFBFBD>
void OPN::SetReg(uint addr, uint data)
{
// LOG2("reg[%.2x] <- %.2x\n", addr, data);
if (addr >= 0x100)
return;
int c = addr & 3;
switch (addr)
{
case 0: case 1: case 2: case 3: case 4: case 5: case 6: case 7:
case 8: case 9: case 10: case 11: case 12: case 13: case 14: case 15:
psg.SetReg(addr, data);
break;
case 0x24: case 0x25:
SetTimerA(addr, data);
break;
case 0x26:
SetTimerB(data);
break;
case 0x27:
SetTimerControl(data);
break;
case 0x28: // Key On/Off
if ((data & 3) < 3)
ch[data & 3].KeyControl(data >> 4);
break;
case 0x2d: case 0x2e: case 0x2f:
SetPrescaler(addr-0x2d);
break;
// F-Number
case 0xa0: case 0xa1: case 0xa2:
fnum[c] = data + fnum2[c] * 0x100;
break;
case 0xa4: case 0xa5: case 0xa6:
fnum2[c] = uint8(data);
break;
case 0xa8: case 0xa9: case 0xaa:
fnum3[c] = data + fnum2[c+3] * 0x100;
break;
case 0xac: case 0xad: case 0xae:
fnum2[c+3] = uint8(data);
break;
case 0xb0: case 0xb1: case 0xb2:
ch[c].SetFB((data >> 3) & 7);
ch[c].SetAlgorithm(data & 7);
break;
default:
if (c < 3)
{
if ((addr & 0xf0) == 0x60)
data &= 0x1f;
OPNBase::SetParameter(&ch[c], addr, data);
}
break;
}
}
// <09>X<EFBFBD>e<EFBFBD>[<5B>^<5E>X<EFBFBD>t<EFBFBD><74><EFBFBD>O<EFBFBD>ݒ<EFBFBD>
void OPN::SetStatus(uint bits)
{
if (!(status & bits))
{
status |= bits;
Intr(true);
}
}
void OPN::ResetStatus(uint bit)
{
status &= ~bit;
if (!status)
Intr(false);
}
// <09>}<7D>X<EFBFBD>N<EFBFBD>ݒ<EFBFBD>
void OPN::SetChannelMask(uint mask)
{
for (int i=0; i<3; i++)
ch[i].Mute(!!(mask & (1 << i)));
psg.SetChannelMask(mask >> 6);
}
void OPN::DataSave(struct OPNData* data) {
OPNBase::DataSave(&data->opnbase);
memcpy(data->fnum, fnum, sizeof(uint) * 3);
memcpy(data->fnum3, fnum3, sizeof(uint) * 3);
memcpy(data->fnum2, fnum2, 6);
for(int i = 0; i < 3; i++) {
ch[i].DataSave(&data->ch[i]);
}
}
void OPN::DataLoad(struct OPNData* data) {
OPNBase::DataLoad(&data->opnbase);
memcpy(fnum, data->fnum, sizeof(uint) * 3);
memcpy(fnum3, data->fnum3, sizeof(uint) * 3);
memcpy(fnum2, data->fnum2, 6);
for(int i = 0; i < 3; i++) {
ch[i].DataLoad(&data->ch[i]);
}
csmch = &ch[2];
for (int i=0; i<3; i++)
{
ch[i].SetChip(&chip);
ch[i].SetType(typeN);
}
}
// <09><><EFBFBD><EFBFBD>(2ch)
void OPN::Mix(Sample* buffer, int nsamples)
{
//printf("M:%d\n",nsamples);
#define IStoSample(s) ((Limit(s, 0x7fff, -0x8000) * fmvolume) >> 14)
psg.Mix(buffer, nsamples);
// Set F-Number
ch[0].SetFNum(fnum[0]);
ch[1].SetFNum(fnum[1]);
if (!(regtc & 0xc0))
ch[2].SetFNum(fnum[2]);
else
{ // <20><><EFBFBD>ʉ<EFBFBD>
ch[2].op[0].SetFNum(fnum3[1]);
ch[2].op[1].SetFNum(fnum3[2]);
ch[2].op[2].SetFNum(fnum3[0]);
ch[2].op[3].SetFNum(fnum[2]);
}
int actch = (((ch[2].Prepare() << 2) | ch[1].Prepare()) << 2) | ch[0].Prepare();
//printf("a %X\n",actch);
if (actch & 0x15)
{
Sample* limit = buffer + nsamples * 2;
for (Sample* dest = buffer; dest < limit; dest+=2)
{
ISample s = 0;
if (actch & 0x01) s = ch[0].Calc();
if (actch & 0x04) s += ch[1].Calc();
if (actch & 0x10) s += ch[2].Calc();
s = IStoSample(s);
StoreSample(dest[0], s);
StoreSample(dest[1], s);
//printf("%08X,%08X\n",dest[0],dest[1]);
}
}
#undef IStoSample
}
#endif // BUILD_OPN
// ---------------------------------------------------------------------------
// YM2608/2610 common part
// ---------------------------------------------------------------------------
#if defined(BUILD_OPNA) || defined(BUILD_OPNB)
int OPNABase::amtable[FM_LFOENTS] = { -1, };
int OPNABase::pmtable[FM_LFOENTS];
int32 OPNABase::tltable[FM_TLENTS+FM_TLPOS];
bool OPNABase::tablehasmade = false;
OPNABase::OPNABase()
{
adpcmbuf = 0;
memaddr = 0;
startaddr = 0;
deltan = 256;
adpcmvol = 0;
control2 = 0;
MakeTable2();
BuildLFOTable();
for (int i=0; i<6; i++)
{
ch[i].SetChip(&chip);
ch[i].SetType(typeN);
}
}
OPNABase::~OPNABase()
{
}
// ---------------------------------------------------------------------------
// <09><><EFBFBD><EFBFBD><EFBFBD><EFBFBD>
//
bool OPNABase::Init(uint, uint, bool)
{
RebuildTimeTable();
Reset();
SetVolumeFM(0);
SetVolumePSG(0);
SetChannelMask(0);
return true;
}
// ---------------------------------------------------------------------------
// <09>e<EFBFBD>[<5B>u<EFBFBD><75><EFBFBD>
//
void OPNABase::MakeTable2()
{
if (!tablehasmade)
{
for (int i=-FM_TLPOS; i<FM_TLENTS; i++)
{
tltable[i+FM_TLPOS] = uint(65536. * pow(2.0, i * -16. / FM_TLENTS))-1;
}
tablehasmade = true;
}
}
// libOPNMIDI: soft panning
static const uint16 panlawtable[] =
{
65535, 65529, 65514, 65489, 65454, 65409, 65354, 65289,
65214, 65129, 65034, 64929, 64814, 64689, 64554, 64410,
64255, 64091, 63917, 63733, 63540, 63336, 63123, 62901,
62668, 62426, 62175, 61914, 61644, 61364, 61075, 60776,
60468, 60151, 59825, 59489, 59145, 58791, 58428, 58057,
57676, 57287, 56889, 56482, 56067, 55643, 55211, 54770,
54320, 53863, 53397, 52923, 52441, 51951, 51453, 50947,
50433, 49912, 49383, 48846, 48302, 47750, 47191,
46340, /* Center left */
46340, /* Center right */
45472, 44885, 44291, 43690, 43083, 42469, 41848, 41221,
40588, 39948, 39303, 38651, 37994, 37330, 36661, 35986,
35306, 34621, 33930, 33234, 32533, 31827, 31116, 30400,
29680, 28955, 28225, 27492, 26754, 26012, 25266, 24516,
23762, 23005, 22244, 21480, 20713, 19942, 19169, 18392,
17613, 16831, 16046, 15259, 14469, 13678, 12884, 12088,
11291, 10492, 9691, 8888, 8085, 7280, 6473, 5666,
4858, 4050, 3240, 2431, 1620, 810, 0
};
// ---------------------------------------------------------------------------
// <09><><EFBFBD>Z<EFBFBD>b<EFBFBD>g
//
void OPNABase::Reset()
{
int i;
OPNBase::Reset();
for (i=0x20; i<0x28; i++) SetReg(i, 0);
for (i=0x30; i<0xc0; i++) SetReg(i, 0);
for (i=0x130; i<0x1c0; i++) SetReg(i, 0);
for (i=0x100; i<0x110; i++) SetReg(i, 0);
for (i=0x10; i<0x20; i++) SetReg(i, 0);
for (i=0; i<6; i++)
{
pan[i] = 3;
panvolume_l[i] = panvolume_r[i] = panlawtable[64];
ch[i].Reset();
}
stmask = ~0x1c;
statusnext = 0;
memaddr = 0;
adpcmd = 127;
adpcmx = 0;
lfocount = 0;
adpcmplay = false;
adplc = 0;
adpld = 0x100;
status = 0;
UpdateStatus();
}
// ---------------------------------------------------------------------------
// <09>T<EFBFBD><54><EFBFBD>v<EFBFBD><76><EFBFBD><EFBFBD><EFBFBD>O<EFBFBD><4F><EFBFBD>[<5B>g<EFBFBD>ύX
//
bool OPNABase::SetRate(uint c, uint r, bool)
{
c /= 2; // <20>]<5D><><EFBFBD>łƂ̌݊<CC8C><DD8A><EFBFBD><EFBFBD><EFBFBD><EFBFBD>d<EFBFBD><64><EFBFBD><EFBFBD><EFBFBD><EFBFBD><EFBFBD><EFBFBD><EFBFBD><EFBFBD><EFBFBD>R<EFBFBD><52><EFBFBD><EFBFBD><EFBFBD>g<EFBFBD>A<EFBFBD>E<EFBFBD>g<EFBFBD><67><EFBFBD>
OPNBase::Init(c, r);
adplbase = int(8192. * (clock/72.) / r);
adpld = deltan * adplbase >> 16;
RebuildTimeTable();
lfodcount = reg22 & 0x08 ? lfotable[reg22 & 7] : 0;
return true;
}
// ---------------------------------------------------------------------------
// <09>`<60><><EFBFBD><EFBFBD><EFBFBD>l<EFBFBD><6C><EFBFBD>}<7D>X<EFBFBD>N<EFBFBD>̐ݒ<CC90>
//
void OPNABase::SetChannelMask(uint mask)
{
for (int i=0; i<6; i++)
ch[i].Mute(!!(mask & (1 << i)));
psg.SetChannelMask(mask >> 6);
adpcmmask_ = (mask & (1 << 9)) != 0;
rhythmmask_ = (mask >> 10) & ((1 << 6) - 1);
}
void OPNABase::SetPan(uint c, uint8 p)
{
panvolume_l[c] = panlawtable[p & 0x7f];
panvolume_r[c] = panlawtable[0x7f - (p & 0x7f)];
}
// ---------------------------------------------------------------------------
void OPNABase::DataSave(struct OPNABaseData* data) {
OPNBase::DataSave(&data->opnbase);
memcpy(data->pan, pan, 6);
memcpy(data->panvolume_l, panvolume_l, sizeof(uint16) * 6);
memcpy(data->panvolume_r, panvolume_r, sizeof(uint16) * 6);
memcpy(data->fnum2, fnum2, 9);
data->reg22 = reg22;
data->reg29 = reg29;
data->stmask = stmask;
data->statusnext = statusnext;
data->lfocount = lfocount;
data->lfodcount = lfodcount;
memcpy(data->fnum, fnum, sizeof(uint) * 6);
memcpy(data->fnum3, fnum3, sizeof(uint) * 3);
data->is_adpcmbuf = 0;
if(adpcmbuf) {
data->is_adpcmbuf = 1;
memcpy(data->adpcmbuf, adpcmbuf, 0x40000);
}
data->adpcmmask = adpcmmask;
data->adpcmnotice = adpcmnotice;
data->startaddr = startaddr;
data->stopaddr = stopaddr;
data->memaddr = memaddr;
data->limitaddr = limitaddr;
data->adpcmlevel = adpcmlevel;
data->adpcmvolume = adpcmvolume;
data->adpcmvol = adpcmvol;
data->deltan = deltan;
data->adplc = adplc;
data->adpld = adpld;
data->adplbase = adplbase;
data->adpcmx = adpcmx;
data->adpcmd = adpcmd;
data->adpcmout = adpcmout;
data->apout0 = apout0;
data->apout1 = apout1;
data->adpcmreadbuf = adpcmreadbuf;
data->adpcmplay = adpcmplay;
data->granuality = granuality;
data->control1 = control1;
data->control2 = control2;
memcpy(data->adpcmreg, adpcmreg, 8);
data->rhythmmask_ = rhythmmask_;
for(int i = 0; i < 6; i++) {
ch[i].DataSave(&data->ch[i]);
}
}
// ---------------------------------------------------------------------------
void OPNABase::DataLoad(struct OPNABaseData* data) {
OPNBase::DataLoad(&data->opnbase);
memcpy(pan, data->pan, 6);
memcpy(panvolume_l, data->panvolume_l, sizeof(uint16) * 6);
memcpy(panvolume_r, data->panvolume_r, sizeof(uint16) * 6);
memcpy(fnum2, data->fnum2, 9);
reg22 = data->reg22;
reg29 = data->reg29;
stmask = data->stmask;
statusnext = data->statusnext;
lfocount = data->lfocount;
lfodcount = data->lfodcount;
memcpy(fnum, data->fnum, sizeof(uint) * 6);
memcpy(fnum3, data->fnum3, sizeof(uint) * 3);
if(data->is_adpcmbuf) {
if(!adpcmbuf)
adpcmbuf = new uint8[0x40000];
memcpy(adpcmbuf, data->adpcmbuf, 0x40000);
}
adpcmmask = data->adpcmmask;
adpcmnotice = data->adpcmnotice;
startaddr = data->startaddr;
stopaddr = data->stopaddr;
memaddr = data->memaddr;
limitaddr = data->limitaddr;
adpcmlevel = data->adpcmlevel;
adpcmvolume = data->adpcmvolume;
adpcmvol = data->adpcmvol;
deltan = data->deltan;
adplc = data->adplc;
adpld = data->adpld;
adplbase = data->adplbase;
adpcmx = data->adpcmx;
adpcmd = data->adpcmd;
adpcmout = data->adpcmout;
apout0 = data->apout0;
apout1 = data->apout1;
adpcmreadbuf = data->adpcmreadbuf;
adpcmplay = data->adpcmplay;
granuality = data->granuality;
control1 = data->control1;
control2 = data->control2;
memcpy(adpcmreg, data->adpcmreg, 8);
rhythmmask_ = data->rhythmmask_;
for(int i = 0; i < 6; i++) {
ch[i].DataLoad(&data->ch[i]);
ch[i].SetChip(&chip);
}
}
// ---------------------------------------------------------------------------
// <09><><EFBFBD>W<EFBFBD>X<EFBFBD>^<5E>A<EFBFBD><41><EFBFBD>C<EFBFBD>Ƀf<C983>[<5B>^<5E><>ݒ<EFBFBD>
//
void OPNABase::SetReg(uint addr, uint data)
{
int c = addr & 3;
switch (addr)
{
uint modified;
// Timer -----------------------------------------------------------------
case 0x24: case 0x25:
SetTimerA(addr, data);
break;
case 0x26:
SetTimerB(data);
break;
case 0x27:
SetTimerControl(data);
break;
// Misc ------------------------------------------------------------------
case 0x28: // Key On/Off
if ((data & 3) < 3)
{
c = (data & 3) + (data & 4 ? 3 : 0);
ch[c].KeyControl(data >> 4);
}
break;
// Status Mask -----------------------------------------------------------
case 0x29:
reg29 = data;
// UpdateStatus(); //?
break;
// Prescaler -------------------------------------------------------------
case 0x2d: case 0x2e: case 0x2f:
SetPrescaler(addr-0x2d);
break;
// F-Number --------------------------------------------------------------
case 0x1a0: case 0x1a1: case 0x1a2:
c += 3;
// fall through
case 0xa0: case 0xa1: case 0xa2:
fnum[c] = data + fnum2[c] * 0x100;
ch[c].SetFNum(fnum[c]);
break;
case 0x1a4: case 0x1a5: case 0x1a6:
c += 3;
// fall through
case 0xa4 : case 0xa5: case 0xa6:
fnum2[c] = uint8(data);
break;
case 0xa8: case 0xa9: case 0xaa:
fnum3[c] = data + fnum2[c+6] * 0x100;
break;
case 0xac : case 0xad: case 0xae:
fnum2[c+6] = uint8(data);
break;
// Algorithm -------------------------------------------------------------
case 0x1b0: case 0x1b1: case 0x1b2:
c += 3;
// fall through
case 0xb0: case 0xb1: case 0xb2:
ch[c].SetFB((data >> 3) & 7);
ch[c].SetAlgorithm(data & 7);
break;
case 0x1b4: case 0x1b5: case 0x1b6:
c += 3;
// fall through
case 0xb4: case 0xb5: case 0xb6:
pan[c] = (data >> 6) & 3;
ch[c].SetMS(data);
break;
// LFO -------------------------------------------------------------------
case 0x22:
modified = reg22 ^ data;
reg22 = data;
if (modified & 0x8)
lfocount = 0;
lfodcount = reg22 & 8 ? lfotable[reg22 & 7] : 0;
break;
// PSG -------------------------------------------------------------------
case 0: case 1: case 2: case 3: case 4: case 5: case 6: case 7:
case 8: case 9: case 10: case 11: case 12: case 13: case 14: case 15:
psg.SetReg(addr, data);
break;
// <20><><EFBFBD>F ------------------------------------------------------------------
default:
if (c < 3)
{
if (addr & 0x100)
c += 3;
OPNBase::SetParameter(&ch[c], addr, data);
}
break;
}
}
// ---------------------------------------------------------------------------
// ADPCM B
//
void OPNABase::SetADPCMBReg(uint addr, uint data)
{
switch (addr)
{
case 0x00: // Control Register 1
if ((data & 0x80) && !adpcmplay)
{
adpcmplay = true;
memaddr = startaddr;
adpcmx = 0, adpcmd = 127;
adplc = 0;
}
if (data & 1)
{
adpcmplay = false;
}
control1 = data;
break;
case 0x01: // Control Register 2
control2 = data;
granuality = control2 & 2 ? 1 : 4;
break;
case 0x02: // Start Address L
case 0x03: // Start Address H
adpcmreg[addr - 0x02 + 0] = data;
startaddr = (adpcmreg[1]*256+adpcmreg[0]) << 6;
memaddr = startaddr;
// LOG1(" startaddr %.6x", startaddr);
break;
case 0x04: // Stop Address L
case 0x05: // Stop Address H
adpcmreg[addr - 0x04 + 2] = data;
stopaddr = (adpcmreg[3]*256+adpcmreg[2] + 1) << 6;
// LOG1(" stopaddr %.6x", stopaddr);
break;
case 0x08: // ADPCM data
if ((control1 & 0x60) == 0x60)
{
// LOG2(" Wr [0x%.5x] = %.2x", memaddr, data);
WriteRAM(data);
}
break;
case 0x09: // delta-N L
case 0x0a: // delta-N H
adpcmreg[addr - 0x09 + 4] = data;
deltan = adpcmreg[5]*256+adpcmreg[4];
deltan = Max(256, deltan);
adpld = deltan * adplbase >> 16;
break;
case 0x0b: // Level Control
adpcmlevel = data;
adpcmvolume = (adpcmvol * adpcmlevel) >> 12;
break;
case 0x0c: // Limit Address L
case 0x0d: // Limit Address H
adpcmreg[addr - 0x0c + 6] = data;
limitaddr = (adpcmreg[7]*256+adpcmreg[6] + 1) << 6;
// LOG1(" limitaddr %.6x", limitaddr);
break;
case 0x10: // Flag Control
if (data & 0x80)
{
status = 0;
UpdateStatus();
}
else
{
stmask = ~(data & 0x1f);
// UpdateStatus(); //???
}
break;
}
}
// ---------------------------------------------------------------------------
// <09><><EFBFBD>W<EFBFBD>X<EFBFBD>^<5E>
//
uint OPNA::GetReg(uint addr)
{
if (addr < 0x10)
return psg.GetReg(addr);
if (addr == 0x108)
{
// LOG1("%d:reg[108] -> ", Diag::GetCPUTick());
uint data = adpcmreadbuf & 0xff;
adpcmreadbuf >>= 8;
if ((control1 & 0x60) == 0x20)
{
adpcmreadbuf |= ReadRAM() << 8;
// LOG2("Rd [0x%.6x:%.2x] ", memaddr, adpcmreadbuf >> 8);
}
// LOG0("%.2x\n");
return data;
}
if (addr == 0xff)
return 1;
return 0;
}
// ---------------------------------------------------------------------------
// <09>X<EFBFBD>e<EFBFBD>[<5B>^<5E>X<EFBFBD>t<EFBFBD><74><EFBFBD>O<EFBFBD>ݒ<EFBFBD>
//
void OPNABase::SetStatus(uint bits)
{
if (!(status & bits))
{
// LOG2("SetStatus(%.2x %.2x)\n", bits, stmask);
status |= bits & stmask;
UpdateStatus();
}
// else
// LOG1("SetStatus(%.2x) - ignored\n", bits);
}
void OPNABase::ResetStatus(uint bits)
{
status &= ~bits;
// LOG1("ResetStatus(%.2x)\n", bits);
UpdateStatus();
}
inline void OPNABase::UpdateStatus()
{
// LOG2("%d:INT = %d\n", Diag::GetCPUTick(), (status & stmask & reg29) != 0);
Intr((status & stmask & reg29) != 0);
}
// ---------------------------------------------------------------------------
// ADPCM RAM <20>ւ̏<D682><CC8F><EFBFBD><EFBFBD>ݑ<EFBFBD><DD91><EFBFBD>
//
void OPNABase::WriteRAM(uint data)
{
#ifndef NO_BITTYPE_EMULATION
if (!(control2 & 2))
{
// 1 bit mode
adpcmbuf[(memaddr >> 4) & 0x3ffff] = data;
memaddr += 16;
}
else
{
// 8 bit mode
uint8* p = &adpcmbuf[(memaddr >> 4) & 0x7fff];
uint bank = (memaddr >> 1) & 7;
uint8 mask = 1 << bank;
data <<= bank;
p[0x00000] = (p[0x00000] & ~mask) | (uint8(data) & mask); data >>= 1;
p[0x08000] = (p[0x08000] & ~mask) | (uint8(data) & mask); data >>= 1;
p[0x10000] = (p[0x10000] & ~mask) | (uint8(data) & mask); data >>= 1;
p[0x18000] = (p[0x18000] & ~mask) | (uint8(data) & mask); data >>= 1;
p[0x20000] = (p[0x20000] & ~mask) | (uint8(data) & mask); data >>= 1;
p[0x28000] = (p[0x28000] & ~mask) | (uint8(data) & mask); data >>= 1;
p[0x30000] = (p[0x30000] & ~mask) | (uint8(data) & mask); data >>= 1;
p[0x38000] = (p[0x38000] & ~mask) | (uint8(data) & mask);
memaddr += 2;
}
#else
adpcmbuf[(memaddr >> granuality) & 0x3ffff] = data;
memaddr += 1 << granuality;
#endif
if (memaddr == stopaddr)
{
SetStatus(4);
statusnext = 0x04; // EOS
memaddr &= 0x3fffff;
}
if (memaddr == limitaddr)
{
// LOG1("Limit ! (%.8x)\n", limitaddr);
memaddr = 0;
}
SetStatus(8);
}
// ---------------------------------------------------------------------------
// ADPCM RAM <20><><EFBFBD><EFBFBD>̓ǂݍ<C782><DD8D>ݑ<EFBFBD><DD91><EFBFBD>
//
uint OPNABase::ReadRAM()
{
uint data;
#ifndef NO_BITTYPE_EMULATION
if (!(control2 & 2))
{
// 1 bit mode
data = adpcmbuf[(memaddr >> 4) & 0x3ffff];
memaddr += 16;
}
else
{
// 8 bit mode
uint8* p = &adpcmbuf[(memaddr >> 4) & 0x7fff];
uint bank = (memaddr >> 1) & 7;
uint8 mask = 1 << bank;
data = (p[0x38000] & mask);
data = data * 2 + (p[0x30000] & mask);
data = data * 2 + (p[0x28000] & mask);
data = data * 2 + (p[0x20000] & mask);
data = data * 2 + (p[0x18000] & mask);
data = data * 2 + (p[0x10000] & mask);
data = data * 2 + (p[0x08000] & mask);
data = data * 2 + (p[0x00000] & mask);
data >>= bank;
memaddr += 2;
}
#else
data = adpcmbuf[(memaddr >> granuality) & 0x3ffff];
memaddr += 1 << granuality;
#endif
if (memaddr == stopaddr)
{
SetStatus(4);
statusnext = 0x04; // EOS
memaddr &= 0x3fffff;
}
if (memaddr == limitaddr)
{
// LOG1("Limit ! (%.8x)\n", limitaddr);
memaddr = 0;
}
if (memaddr < stopaddr)
SetStatus(8);
return data;
}
inline int OPNABase::DecodeADPCMBSample(uint data)
{
static const int table1[16] =
{
1, 3, 5, 7, 9, 11, 13, 15,
-1, -3, -5, -7, -9, -11, -13, -15,
};
static const int table2[16] =
{
57, 57, 57, 57, 77, 102, 128, 153,
57, 57, 57, 57, 77, 102, 128, 153,
};
adpcmx = Limit(adpcmx + table1[data] * adpcmd / 8, 32767, -32768);
adpcmd = Limit(adpcmd * table2[data] / 64, 24576, 127);
return adpcmx;
}
// ---------------------------------------------------------------------------
// ADPCM RAM <20><><EFBFBD><EFBFBD><EFBFBD> nibble <20>ǂݍ<C782><DD8D>݋y<DD8B><79> ADPCM <20>W<EFBFBD>J
//
int OPNABase::ReadRAMN()
{
uint data;
if (granuality > 0)
{
#ifndef NO_BITTYPE_EMULATION
if (!(control2 & 2))
{
data = adpcmbuf[(memaddr >> 4) & 0x3ffff];
memaddr += 8;
if (memaddr & 8)
return DecodeADPCMBSample(data >> 4);
data &= 0x0f;
}
else
{
uint8* p = &adpcmbuf[(memaddr >> 4) & 0x7fff] + ((~memaddr & 1) << 17);
uint bank = (memaddr >> 1) & 7;
uint8 mask = 1 << bank;
data = (p[0x18000] & mask);
data = data * 2 + (p[0x10000] & mask);
data = data * 2 + (p[0x08000] & mask);
data = data * 2 + (p[0x00000] & mask);
data >>= bank;
memaddr ++;
if (memaddr & 1)
return DecodeADPCMBSample(data);
}
#else
data = adpcmbuf[(memaddr >> granuality) & adpcmmask];
memaddr += 1 << (granuality-1);
if (memaddr & (1 << (granuality-1)))
return DecodeADPCMBSample(data >> 4);
data &= 0x0f;
#endif
}
else
{
data = adpcmbuf[(memaddr >> 1) & adpcmmask];
++memaddr;
if (memaddr & 1)
return DecodeADPCMBSample(data >> 4);
data &= 0x0f;
}
DecodeADPCMBSample(data);
// check
if (memaddr == stopaddr)
{
if (control1 & 0x10)
{
memaddr = startaddr;
data = adpcmx;
adpcmx = 0, adpcmd = 127;
return data;
}
else
{
memaddr &= adpcmmask; //0x3fffff;
SetStatus(adpcmnotice);
adpcmplay = false;
}
}
if (memaddr == limitaddr)
memaddr = 0;
return adpcmx;
}
// ---------------------------------------------------------------------------
// <09>g<EFBFBD><67><EFBFBD>X<EFBFBD>e<EFBFBD>[<5B>^<5E>X<EFBFBD><58>ǂ݂<C782><DD82><EFBFBD>
//
uint OPNABase::ReadStatusEx()
{
uint r = ((status | 8) & stmask) | (adpcmplay ? 0x20 : 0);
status |= statusnext;
statusnext = 0;
return r;
}
// ---------------------------------------------------------------------------
// ADPCM <20>W<EFBFBD>J
//
inline void OPNABase::DecodeADPCMB()
{
apout0 = apout1;
int n = (ReadRAMN() * adpcmvolume) >> 13;
apout1 = adpcmout + n;
adpcmout = n;
}
// ---------------------------------------------------------------------------
// ADPCM <20><><EFBFBD><EFBFBD>
//
void OPNABase::ADPCMBMix(Sample* dest, uint count)
{
uint maskl = control2 & 0x80 ? -1 : 0;
uint maskr = control2 & 0x40 ? -1 : 0;
if (adpcmmask_)
{
maskl = maskr = 0;
}
if (adpcmplay)
{
// LOG2("ADPCM Play: %d DeltaN: %d\n", adpld, deltan);
if (adpld <= 8192) // fplay < fsamp
{
for (; count>0; count--)
{
if (adplc < 0)
{
adplc += 8192;
DecodeADPCMB();
if (!adpcmplay)
break;
}
int s = (adplc * apout0 + (8192-adplc) * apout1) >> 13;
StoreSample(dest[0], s & maskl);
StoreSample(dest[1], s & maskr);
dest += 2;
adplc -= adpld;
}
for (; count>0 && apout0; count--)
{
if (adplc < 0)
{
apout0 = apout1, apout1 = 0;
adplc += 8192;
}
int s = (adplc * apout1) >> 13;
StoreSample(dest[0], s & maskl);
StoreSample(dest[1], s & maskr);
dest += 2;
adplc -= adpld;
}
}
else // fplay > fsamp (adpld = fplay/famp*8192)
{
int t = (-8192*8192)/adpld;
for (; count>0; count--)
{
int s = apout0 * (8192+adplc);
while (adplc < 0)
{
DecodeADPCMB();
if (!adpcmplay)
goto stop;
s -= apout0 * Max(adplc, t);
adplc -= t;
}
adplc -= 8192;
s >>= 13;
StoreSample(dest[0], s & maskl);
StoreSample(dest[1], s & maskr);
dest += 2;
}
stop:
;
}
}
if (!adpcmplay)
{
apout0 = apout1 = adpcmout = 0;
adplc = 0;
}
}
// ---------------------------------------------------------------------------
// <09><><EFBFBD><EFBFBD>
// in: buffer <09><><EFBFBD><EFBFBD><EFBFBD><EFBFBD>
// nsamples <09><><EFBFBD><EFBFBD><EFBFBD>T<EFBFBD><54><EFBFBD>v<EFBFBD><76><EFBFBD><EFBFBD>
//
void OPNABase::FMMix(Sample* buffer, int nsamples)
{
if (fmvolume > 0)
{
// <20><><EFBFBD><EFBFBD>
// Set F-Number
if (!(regtc & 0xc0))
csmch->SetFNum(fnum[csmch-ch]);
else
{
// <20><><EFBFBD>ʉ<EFBFBD><CA89><EFBFBD><EFBFBD>[<5B>h
csmch->op[0].SetFNum(fnum3[1]); csmch->op[1].SetFNum(fnum3[2]);
csmch->op[2].SetFNum(fnum3[0]); csmch->op[3].SetFNum(fnum[2]);
}
int act = (((ch[2].Prepare() << 2) | ch[1].Prepare()) << 2) | ch[0].Prepare();
if (reg29 & 0x80)
act |= (ch[3].Prepare() | ((ch[4].Prepare() | (ch[5].Prepare() << 2)) << 2)) << 6;
if (!(reg22 & 0x08))
act &= 0x555;
if (act & 0x555)
{
Mix6(buffer, nsamples, act);
}
}
}
// ---------------------------------------------------------------------------
void OPNABase::MixSubSL(int activech, ISample** dest)
{
if (activech & 0x001) (*dest[0] = ch[0].CalcL());
if (activech & 0x004) (*dest[1] += ch[1].CalcL());
if (activech & 0x010) (*dest[2] += ch[2].CalcL());
if (activech & 0x040) (*dest[3] += ch[3].CalcL());
if (activech & 0x100) (*dest[4] += ch[4].CalcL());
if (activech & 0x400) (*dest[5] += ch[5].CalcL());
}
inline void OPNABase::MixSubS(int activech, ISample** dest)
{
if (activech & 0x001) (*dest[0] = ch[0].Calc());
if (activech & 0x004) (*dest[1] += ch[1].Calc());
if (activech & 0x010) (*dest[2] += ch[2].Calc());
if (activech & 0x040) (*dest[3] += ch[3].Calc());
if (activech & 0x100) (*dest[4] += ch[4].Calc());
if (activech & 0x400) (*dest[5] += ch[5].Calc());
}
// ---------------------------------------------------------------------------
void OPNABase::BuildLFOTable()
{
if (amtable[0] == -1)
{
for (int c=0; c<256; c++)
{
int v;
if (c < 0x40) v = c * 2 + 0x80;
else if (c < 0xc0) v = 0x7f - (c - 0x40) * 2 + 0x80;
else v = (c - 0xc0) * 2;
pmtable[c] = c;
if (c < 0x80) v = 0xff - c * 2;
else v = (c - 0x80) * 2;
amtable[c] = v & ~3;
}
}
}
// ---------------------------------------------------------------------------
inline void OPNABase::LFO()
{
// LOG3("%4d - %8d, %8d\n", c, lfocount, lfodcount);
// Operator::SetPML(pmtable[(lfocount >> (FM_LFOCBITS+1)) & 0xff]);
// Operator::SetAML(amtable[(lfocount >> (FM_LFOCBITS+1)) & 0xff]);
chip.SetPML(pmtable[(lfocount >> (FM_LFOCBITS+1)) & 0xff]);
chip.SetAML(amtable[(lfocount >> (FM_LFOCBITS+1)) & 0xff]);
lfocount += lfodcount;
}
// ---------------------------------------------------------------------------
// <09><><EFBFBD><EFBFBD>
//
#define IStoSample(s) ((Limit(s, 0x7fff, -0x8000) * fmvolume) >> 14)
void OPNABase::Mix6(Sample* buffer, int nsamples, int activech)
{
// Mix
// libOPNMIDI: rewrite for panning support
const uint activechmask[6] = {0x001, 0x004, 0x010, 0x040, 0x100, 0x400};
Sample* limit = buffer + nsamples * 2;
for (Sample* dest = buffer; dest < limit; dest+=2)
{
ISample out[6];
if (activech & 0xaaa)
{
LFO();
for (uint c = 0; c<6; ++c)
out[c] = (activechmask[c] & activech) ? ch[c].CalcL() : 0;
}
else
{
for (uint c = 0; c<6; ++c)
out[c] = (activechmask[c] & activech) ? ch[c].Calc() : 0;
}
int lrouts[2] = {0, 0};
for (uint c = 0; c<6; ++c)
{
int panl = panvolume_l[c];
int panr = panvolume_r[c];
panl = (pan[c] & 2) ? panl : 0;
panr = (pan[c] & 1) ? panr : 0;
lrouts[0] += out[c] * panl / 65535;
lrouts[1] += out[c] * panr / 65535;
}
StoreSample(dest[0], lrouts[0]);
StoreSample(dest[1], lrouts[1]);
}
}
#endif // defined(BUILD_OPNA) || defined(BUILD_OPNB)
// ---------------------------------------------------------------------------
// YM2608(OPNA)
// ---------------------------------------------------------------------------
#ifdef BUILD_OPNA
// ---------------------------------------------------------------------------
// <09>\<5C>z
//
OPNA::OPNA()
{
for (int i=0; i<6; i++)
{
rhythm[i].sample = 0;
rhythm[i].pos = 0;
rhythm[i].size = 0;
rhythm[i].volume = 0;
}
rhythmtvol = 0;
adpcmmask = 0x3ffff;
adpcmnotice = 4;
csmch = &ch[2];
}
// ---------------------------------------------------------------------------
OPNA::~OPNA()
{
delete[] adpcmbuf;
for (int i=0; i<6; i++)
delete[] rhythm[i].sample;
}
// ---------------------------------------------------------------------------
// <09><><EFBFBD><EFBFBD><EFBFBD><EFBFBD>
//
bool OPNA::Init(uint c, uint r, bool ipflag, const char* path)
{
rate = 8000;
LoadRhythmSample(path);
if (!adpcmbuf)
adpcmbuf = new uint8[0x40000];
if (!adpcmbuf)
return false;
if (!SetRate(c, r, ipflag))
return false;
if (!OPNABase::Init(c, r, ipflag))
return false;
Reset();
SetVolumeADPCM(0);
SetVolumeRhythmTotal(0);
for (int i=0; i<6; i++)
SetVolumeRhythm(0, 0);
return true;
}
// ---------------------------------------------------------------------------
// <09><><EFBFBD>Z<EFBFBD>b<EFBFBD>g
//
void OPNA::Reset()
{
reg29 = 0x1f;
rhythmkey = 0;
limitaddr = 0x3ffff;
OPNABase::Reset();
}
// ---------------------------------------------------------------------------
// <09>T<EFBFBD><54><EFBFBD>v<EFBFBD><76><EFBFBD><EFBFBD><EFBFBD>O<EFBFBD><4F><EFBFBD>[<5B>g<EFBFBD>ύX
//
bool OPNA::SetRate(uint c, uint r, bool ipflag)
{
if (!OPNABase::SetRate(c, r, ipflag))
return false;
for (int i=0; i<6; i++)
{
rhythm[i].step = rhythm[i].rate * 1024 / r;
}
return true;
}
// ---------------------------------------------------------------------------
// <09><><EFBFBD>Y<EFBFBD><59><EFBFBD><EFBFBD><EFBFBD><EFBFBD>ǂ݂<C782><DD82><EFBFBD>
//
bool OPNA::LoadRhythmSample(const char* path)
{
static const char* rhythmname[6] =
{
"bd", "sd", "top", "hh", "tom", "rim",
};
int i;
for (i=0; i<6; i++)
rhythm[i].pos = ~0u;
for (i=0; i<6; i++)
{
FileIO file;
uint32 fsize;
char buf[MAX_PATH + 1] = "";
if (path)
strncpy(buf, path, MAX_PATH);
strncat(buf, "2608_", MAX_PATH);
strncat(buf, rhythmname[i], MAX_PATH);
strncat(buf, ".wav", MAX_PATH);
if (!file.Open(buf, FileIO::readonly))
{
if (i != 5)
break;
if (path)
strncpy(buf, path, MAX_PATH);
strncpy(buf, "2608_rym.wav", MAX_PATH);
if (!file.Open(buf, FileIO::readonly))
break;
}
struct
{
uint32 chunksize;
uint16 tag;
uint16 nch;
uint32 rate;
uint32 avgbytes;
uint16 align;
uint16 bps;
uint16 size;
} whdr;
file.Seek(0x10, FileIO::begin);
file.Read(&whdr, sizeof(whdr));
uint8 subchunkname[4];
fsize = 4 + whdr.chunksize - sizeof(whdr);
do
{
file.Seek(fsize, FileIO::current);
file.Read(&subchunkname, 4);
file.Read(&fsize, 4);
} while (memcmp("data", subchunkname, 4));
fsize /= 2;
if (fsize >= 0x100000 || whdr.tag != 1 || whdr.nch != 1)
break;
fsize = Max(fsize, (1<<31)/1024);
if(!rhythm[i].sample)
delete rhythm[i].sample;
rhythm[i].sample = new int16[fsize];
if (!rhythm[i].sample)
break;
file.Read(rhythm[i].sample, fsize * 2);
rhythm[i].rate = whdr.rate;
rhythm[i].step = rhythm[i].rate * 1024 / rate;
rhythm[i].pos = rhythm[i].size = fsize * 1024;
}
if (i != 6)
{
for (i=0; i<6; i++)
{
delete[] rhythm[i].sample;
rhythm[i].sample = 0;
}
return false;
}
return true;
}
// ---------------------------------------------------------------------------
// <09><><EFBFBD>W<EFBFBD>X<EFBFBD>^<5E>A<EFBFBD><41><EFBFBD>C<EFBFBD>Ƀf<C983>[<5B>^<5E><>ݒ<EFBFBD>
//
void OPNA::SetReg(uint addr, uint data)
{
addr &= 0x1ff;
switch (addr)
{
case 0x29:
reg29 = data;
// UpdateStatus(); //?
break;
// Rhythm ----------------------------------------------------------------
case 0x10: // DM/KEYON
if (!(data & 0x80)) // KEY ON
{
rhythmkey |= data & 0x3f;
if (data & 0x01) rhythm[0].pos = 0;
if (data & 0x02) rhythm[1].pos = 0;
if (data & 0x04) rhythm[2].pos = 0;
if (data & 0x08) rhythm[3].pos = 0;
if (data & 0x10) rhythm[4].pos = 0;
if (data & 0x20) rhythm[5].pos = 0;
}
else
{ // DUMP
rhythmkey &= ~data;
}
break;
case 0x11:
rhythmtl = ~data & 63;
break;
case 0x18: // Bass Drum
case 0x19: // Snare Drum
case 0x1a: // Top Cymbal
case 0x1b: // Hihat
case 0x1c: // Tom-tom
case 0x1d: // Rim shot
rhythm[addr & 7].pan = (data >> 6) & 3;
rhythm[addr & 7].level = ~data & 31;
break;
case 0x100: case 0x101:
case 0x102: case 0x103:
case 0x104: case 0x105:
case 0x108: case 0x109:
case 0x10a: case 0x10b:
case 0x10c: case 0x10d:
case 0x110:
OPNABase::SetADPCMBReg(addr - 0x100, data);
break;
default:
OPNABase::SetReg(addr, data);
break;
}
}
// ---------------------------------------------------------------------------
void OPNA::DataSave(struct OPNAData* data) {
OPNABase::DataSave(&data->opnabase);
memcpy(data->rhythm, rhythm, sizeof(Rhythm) * 6);
data->rhythmtl = rhythmtl;
data->rhythmtvol = rhythmtvol;
data->rhythmkey = rhythmkey;
}
// ---------------------------------------------------------------------------
void OPNA::DataLoad(struct OPNAData* data) {
OPNABase::DataLoad(&data->opnabase);
memcpy(rhythm, data->rhythm, sizeof(Rhythm) * 6);
rhythmtl = data->rhythmtl;
rhythmtvol = data->rhythmtvol;
rhythmkey = data->rhythmkey;
csmch = &ch[2];
}
// ---------------------------------------------------------------------------
// <09><><EFBFBD>Y<EFBFBD><59><EFBFBD><EFBFBD><EFBFBD><EFBFBD>
//
void OPNA::RhythmMix(Sample* buffer, uint count)
{
if (rhythmtvol < 128 && rhythm[0].sample && (rhythmkey & 0x3f))
{
Sample* limit = buffer + count * 2;
for (int i=0; i<6; i++)
{
Rhythm& r = rhythm[i];
if ((rhythmkey & (1 << i)) /*&& r.level < 128*/) // libOPNMIDI: Useless condition, signed int 8t has 127 max
{
int db = Limit(rhythmtl+rhythmtvol+r.level+r.volume, 127, -31);
int vol = tltable[FM_TLPOS+(db << (FM_TLBITS-7))] >> 4;
int maskl = -((r.pan >> 1) & 1);
int maskr = -(r.pan & 1);
if (rhythmmask_ & (1 << i))
{
maskl = maskr = 0;
}
for (Sample* dest = buffer; dest<limit && r.pos < r.size; dest+=2)
{
int sample = (r.sample[r.pos / 1024] * vol) >> 12;
r.pos += r.step;
StoreSample(dest[0], sample & maskl);
StoreSample(dest[1], sample & maskr);
}
}
}
}
}
// ---------------------------------------------------------------------------
// <09><><EFBFBD>ʐݒ<CA90>
//
void OPNA::SetVolumeRhythmTotal(int db)
{
db = Min(db, 20);
rhythmtvol = -(db * 2 / 3);
}
void OPNA::SetVolumeRhythm(int index, int db)
{
db = Min(db, 20);
rhythm[index].volume = -(db * 2 / 3);
}
void OPNA::SetVolumeADPCM(int db)
{
db = Min(db, 20);
if (db > -192)
adpcmvol = int(65536.0 * pow(10.0, db / 40.0));
else
adpcmvol = 0;
adpcmvolume = (adpcmvol * adpcmlevel) >> 12;
}
// ---------------------------------------------------------------------------
// <09><><EFBFBD><EFBFBD>
// in: buffer <09><><EFBFBD><EFBFBD><EFBFBD><EFBFBD>
// nsamples <09><><EFBFBD><EFBFBD><EFBFBD>T<EFBFBD><54><EFBFBD>v<EFBFBD><76><EFBFBD><EFBFBD>
//
void OPNA::Mix(Sample* buffer, int nsamples)
{
FMMix(buffer, nsamples);
psg.Mix(buffer, nsamples);
ADPCMBMix(buffer, nsamples);
RhythmMix(buffer, nsamples);
}
#endif // BUILD_OPNA
// ---------------------------------------------------------------------------
// YM2610(OPNB)
// ---------------------------------------------------------------------------
#ifdef BUILD_OPNB
// ---------------------------------------------------------------------------
// <09>\<5C>z
//
OPNB::OPNB()
{
adpcmabuf = 0;
adpcmasize = 0;
for (int i=0; i<6; i++)
{
adpcma[i].pan = 0;
adpcma[i].level = 0;
adpcma[i].volume = 0;
adpcma[i].pos = 0;
adpcma[i].step = 0;
adpcma[i].volume = 0;
adpcma[i].start = 0;
adpcma[i].stop = 0;
adpcma[i].adpcmx = 0;
adpcma[i].adpcmd = 0;
}
adpcmatl = 0;
adpcmakey = 0;
adpcmatvol = 0;
adpcmmask = 0;
adpcmnotice = 0x8000;
granuality = -1;
csmch = &ch[2];
InitADPCMATable();
}
OPNB::~OPNB()
{
}
// ---------------------------------------------------------------------------
// <09><><EFBFBD><EFBFBD><EFBFBD><EFBFBD>
//
bool OPNB::Init(uint c, uint r, bool ipflag,
uint8 *_adpcma, int _adpcma_size,
uint8 *_adpcmb, int _adpcmb_size)
{
int i;
if (!SetRate(c, r, ipflag))
return false;
if (!OPNABase::Init(c, r, ipflag))
return false;
adpcmabuf = _adpcma;
adpcmasize = _adpcma_size;
adpcmbuf = _adpcmb;
for (i=0; i<=24; i++) // max 16M bytes
{
if (_adpcmb_size <= (1 << i))
{
adpcmmask = (1 << i) - 1;
break;
}
}
// adpcmmask = _adpcmb_size - 1;
limitaddr = adpcmmask;
Reset();
SetVolumeFM(0);
SetVolumePSG(0);
SetVolumeADPCMB(0);
SetVolumeADPCMATotal(0);
for (i=0; i<6; i++)
SetVolumeADPCMA(0, 0);
SetChannelMask(0);
return true;
}
// ---------------------------------------------------------------------------
// <09><><EFBFBD>Z<EFBFBD>b<EFBFBD>g
//
void OPNB::Reset()
{
OPNABase::Reset();
stmask = ~0;
adpcmakey = 0;
reg29 = ~0;
for (int i=0; i<6; i++)
{
adpcma[i].pan = 0;
adpcma[i].level = 0;
adpcma[i].volume = 0;
adpcma[i].pos = 0;
adpcma[i].step = 0;
adpcma[i].volume = 0;
adpcma[i].start = 0;
adpcma[i].stop = 0;
adpcma[i].adpcmx = 0;
adpcma[i].adpcmd = 0;
}
}
// ---------------------------------------------------------------------------
// <09>T<EFBFBD><54><EFBFBD>v<EFBFBD><76><EFBFBD><EFBFBD><EFBFBD>O<EFBFBD><4F><EFBFBD>[<5B>g<EFBFBD>ύX
//
bool OPNB::SetRate(uint c, uint r, bool ipflag)
{
if (!OPNABase::SetRate(c, r, ipflag))
return false;
adpcmastep = int(double(c) / 54 * 8192 / r);
return true;
}
// ---------------------------------------------------------------------------
// <09><><EFBFBD>W<EFBFBD>X<EFBFBD>^<5E>A<EFBFBD><41><EFBFBD>C<EFBFBD>Ƀf<C983>[<5B>^<5E><>ݒ<EFBFBD>
//
void OPNB::SetReg(uint addr, uint data)
{
addr &= 0x1ff;
switch (addr)
{
// omitted registers
case 0x29:
case 0x2d: case 0x2e: case 0x2f:
break;
// ADPCM A ---------------------------------------------------------------
case 0x100: // DM/KEYON
if (!(data & 0x80)) // KEY ON
{
adpcmakey |= data & 0x3f;
for (int c=0; c<6; c++)
{
if (data & (1<<c))
{
ResetStatus(0x100 << c);
adpcma[c].pos = adpcma[c].start;
// adpcma[c].step = 0x10000 - adpcma[c].step;
adpcma[c].step = 0;
adpcma[c].adpcmx = 0;
adpcma[c].adpcmd = 0;
adpcma[c].nibble = 0;
}
}
}
else
{ // DUMP
adpcmakey &= ~data;
}
break;
case 0x101:
adpcmatl = ~data & 63;
break;
case 0x108: case 0x109: case 0x10a:
case 0x10b: case 0x10c: case 0x10d:
adpcma[addr & 7].pan = (data >> 6) & 3;
adpcma[addr & 7].level = ~data & 31;
break;
case 0x110: case 0x111: case 0x112: // START ADDRESS (L)
case 0x113: case 0x114: case 0x115:
case 0x118: case 0x119: case 0x11a: // START ADDRESS (H)
case 0x11b: case 0x11c: case 0x11d:
adpcmareg[addr - 0x110] = data;
adpcma[addr & 7].pos = adpcma[addr & 7].start =
(adpcmareg[(addr&7)+8]*256+adpcmareg[addr&7]) << 9;
break;
case 0x120: case 0x121: case 0x122: // END ADDRESS (L)
case 0x123: case 0x124: case 0x125:
case 0x128: case 0x129: case 0x12a: // END ADDRESS (H)
case 0x12b: case 0x12c: case 0x12d:
adpcmareg[addr - 0x110] = data;
adpcma[addr & 7].stop =
(adpcmareg[(addr&7)+24]*256+adpcmareg[(addr&7)+16] + 1) << 9;
break;
// ADPCMB -----------------------------------------------------------------
case 0x10:
if ((data & 0x80) && !adpcmplay)
{
adpcmplay = true;
memaddr = startaddr;
adpcmx = 0, adpcmd = 127;
adplc = 0;
}
if (data & 1)
adpcmplay = false;
control1 = data & 0x91;
break;
case 0x11: // Control Register 2
control2 = data & 0xc0;
break;
case 0x12: // Start Address L
case 0x13: // Start Address H
adpcmreg[addr - 0x12 + 0] = data;
startaddr = (adpcmreg[1]*256+adpcmreg[0]) << 9;
memaddr = startaddr;
break;
case 0x14: // Stop Address L
case 0x15: // Stop Address H
adpcmreg[addr - 0x14 + 2] = data;
stopaddr = (adpcmreg[3]*256+adpcmreg[2] + 1) << 9;
// LOG1(" stopaddr %.6x", stopaddr);
break;
case 0x19: // delta-N L
case 0x1a: // delta-N H
adpcmreg[addr - 0x19 + 4] = data;
deltan = adpcmreg[5]*256+adpcmreg[4];
deltan = Max(256, deltan);
adpld = deltan * adplbase >> 16;
break;
case 0x1b: // Level Control
adpcmlevel = data;
adpcmvolume = (adpcmvol * adpcmlevel) >> 12;
break;
case 0x1c: // Flag Control
stmask = ~((data & 0xbf) << 8);
status &= stmask;
UpdateStatus();
break;
default:
OPNABase::SetReg(addr, data);
break;
}
// LOG0("\n");
}
// ---------------------------------------------------------------------------
// <09><><EFBFBD>W<EFBFBD>X<EFBFBD>^<5E>
//
uint OPNB::GetReg(uint addr)
{
if (addr < 0x10)
return psg.GetReg(addr);
return 0;
}
// ---------------------------------------------------------------------------
// <09>g<EFBFBD><67><EFBFBD>X<EFBFBD>e<EFBFBD>[<5B>^<5E>X<EFBFBD><58>ǂ݂<C782><DD82><EFBFBD>
//
uint OPNB::ReadStatusEx()
{
return (status & stmask) >> 8;
}
// ---------------------------------------------------------------------------
// YM2610
//
int OPNB::jedi_table[(48+1)*16];
void OPNB::InitADPCMATable()
{
const static int8 table2[] =
{
1, 3, 5, 7, 9, 11, 13, 15,
-1, -3, -5, -7, -9,-11,-13,-15,
};
for (int i=0; i<=48; i++)
{
int s = int(16.0 * pow (1.1, i) * 3);
for (int j=0; j<16; j++)
{
jedi_table[i*16+j] = s * table2[j] / 8;
}
}
}
// ---------------------------------------------------------------------------
// ADPCMA <20><><EFBFBD><EFBFBD>
//
void OPNB::ADPCMAMix(Sample* buffer, uint count)
{
const static int decode_tableA1[16] =
{
-1*16, -1*16, -1*16, -1*16, 2*16, 5*16, 7*16, 9*16,
-1*16, -1*16, -1*16, -1*16, 2*16, 5*16, 7*16, 9*16
};
if (adpcmatvol < 128 && (adpcmakey & 0x3f))
{
Sample* limit = buffer + count * 2;
for (int i=0; i<6; i++)
{
ADPCMA& r = adpcma[i];
if ((adpcmakey & (1 << i))/* && r.level < 128*/) // libOPNMIDI: Useless condition, signed int 8t has 127 max
{
uint maskl = r.pan & 2 ? -1 : 0;
uint maskr = r.pan & 1 ? -1 : 0;
if (rhythmmask_ & (1 << i))
{
maskl = maskr = 0;
}
int db = Limit(adpcmatl+adpcmatvol+r.level+r.volume, 127, -31);
int vol = tltable[FM_TLPOS+(db << (FM_TLBITS-7))] >> 4;
Sample* dest = buffer;
for ( ; dest<limit; dest+=2)
{
r.step += adpcmastep;
if (r.pos >= r.stop)
{
SetStatus(0x100 << i);
adpcmakey &= ~(1<<i);
break;
}
for (; r.step > 0x10000; r.step -= 0x10000)
{
int data;
if (!(r.pos & 1))
{
r.nibble = adpcmabuf[r.pos>>1];
data = r.nibble >> 4;
}
else
{
data = r.nibble & 0x0f;
}
r.pos++;
r.adpcmx += jedi_table[r.adpcmd + data];
r.adpcmx = Limit(r.adpcmx, 2048*3-1, -2048*3);
r.adpcmd += decode_tableA1[data];
r.adpcmd = Limit(r.adpcmd, 48*16, 0);
}
int sample = (r.adpcmx * vol) >> 10;
StoreSample(dest[0], sample & maskl);
StoreSample(dest[1], sample & maskr);
}
}
}
}
}
// ---------------------------------------------------------------------------
// <09><><EFBFBD>ʐݒ<CA90>
//
void OPNB::SetVolumeADPCMATotal(int db)
{
db = Min(db, 20);
adpcmatvol = -(db * 2 / 3);
}
void OPNB::SetVolumeADPCMA(int index, int db)
{
db = Min(db, 20);
adpcma[index].volume = -(db * 2 / 3);
}
void OPNB::SetVolumeADPCMB(int db)
{
db = Min(db, 20);
if (db > -192)
adpcmvol = int(65536.0 * pow(10, db / 40.0));
else
adpcmvol = 0;
}
// ---------------------------------------------------------------------------
void OPNB::DataSave(struct OPNBData* data, void* adpcmadata) {
OPNABase::DataSave(&data->opnabase);
if(adpcmasize) {
adpcmadata = malloc(adpcmasize);
memcpy(adpcmadata, adpcmabuf, adpcmasize);
}
data->adpcmasize = adpcmasize;
memcpy(data->adpcma, adpcma, sizeof(ADPCMA) * 6);
data->adpcmatl = adpcmatl;
data->adpcmatvol = adpcmatvol;
data->adpcmakey = adpcmakey;
data->adpcmastep = adpcmastep;
memcpy(data->adpcmareg, adpcmareg, 32);
for(int i = 0; i < 6; i++) {
ch[i].DataSave(&data->ch[i]);
}
}
// ---------------------------------------------------------------------------
void OPNB::DataLoad(struct OPNBData* data, void* adpcmadata) {
OPNABase::DataLoad(&data->opnabase); // libOPNMIDI: bugfix DataLoad (was DataSave here)
if(data->adpcmasize) {
adpcmabuf = (uint8*)malloc(data->adpcmasize);
memcpy(adpcmabuf, adpcmadata, data->adpcmasize);
}
adpcmasize = data->adpcmasize;
memcpy(adpcma, data->adpcma, sizeof(ADPCMA) * 6);
adpcmatl = data->adpcmatl;
adpcmatvol = data->adpcmatvol;
adpcmakey = data->adpcmakey;
adpcmastep = data->adpcmastep;
memcpy(adpcmareg, data->adpcmareg, 32);
for(int i = 0; i < 6; i++) {
ch[i].DataLoad(&data->ch[i]);
}
csmch = &ch[2];
}
// ---------------------------------------------------------------------------
// <09><><EFBFBD><EFBFBD>
// in: buffer <09><><EFBFBD><EFBFBD><EFBFBD><EFBFBD>
// nsamples <09><><EFBFBD><EFBFBD><EFBFBD>T<EFBFBD><54><EFBFBD>v<EFBFBD><76><EFBFBD><EFBFBD>
//
void OPNB::Mix(Sample* buffer, int nsamples)
{
FMMix(buffer, nsamples);
psg.Mix(buffer, nsamples);
ADPCMBMix(buffer, nsamples);
ADPCMAMix(buffer, nsamples);
}
#endif // BUILD_OPNB
} // namespace FM
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