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zmusic/thirdparty/opnmidi/chips/gens/Ym2612.cpp

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Updated libOPNMIDI to 1.5.1 Changelog: * Added an ability to disable the automatical arpeggio * Updated the GENS chip emulator from the 2.10 into GS/II (thanks to @freq-mod for the help) * Added an ability to set number of loops * Added an ability to disable/enable playing of selected MIDI channels * Fixed memory damages and crashes while playing XMI files * Added the chip channels allocation mode option * Fixed the playback of multi-song XMI files * Added an ability to switch the XMI song on the fly And also: * Fixed the work on big endian processors * Fixed ARM64 build on some platforms * Improved support of the EA-MUS files (Thanks to [dashodanger](https://github.com/dashodanger)) * Fixed crash on attempt to change the volume of a blank note
2023-01-01 22:24:15 +00:00
/***************************************************************************
* libgens: Gens Emulation Library. *
* Ym2612.hpp: Yamaha YM2612 FM synthesis chip emulator. *
* *
* Copyright (c) 1999-2002 by Stéphane Dallongeville *
* Copyright (c) 2003-2004 by Stéphane Akhoun *
* Copyright (c) 2008-2010 by David Korth *
* *
* 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. *
* *
* 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. *
***************************************************************************/
/***********************************************************
* *
* YM2612.C : YM2612 emulator *
* *
* Almost constantes are taken from the MAME core *
* *
* This source is a part of Gens project *
* Written by Stéphane Dallongeville (gens@consolemul.com) *
* Copyright (c) 2002 by Stéphane Dallongeville *
* *
***********************************************************/
#include "Ym2612.hpp"
#include "Ym2612_p.hpp"
// C includes.
#include <stdint.h>
// C includes. (C++ namespace)
#include <cstdio>
#include <cmath>
#include <cstring>
#include <cassert>
/* Message logging. */
//#define LOG_MSG(...)
//#include "macros/log_msg.h"
#if 0
// Sound Manager.
#include "SoundMgr.hpp"
#include "Vdp/Vdp.hpp"
// TODO: Get rid of EmuContext.
#include "EmuContext/EmuContext.hpp"
#endif
namespace LibGens {
/** Ym2612Private **/
// Static variables.
bool Ym2612Private::isInit = false;
int *Ym2612Private::SIN_TAB[SIN_LENGTH]; // SINUS TABLE (pointer on TL TABLE)
int Ym2612Private::TL_TAB[TL_LENGTH * 2]; // TOTAL LEVEL TABLE (plus and minus)
unsigned int Ym2612Private::ENV_TAB[2 * ENV_LENGTH * 8]; // ENV CURVE TABLE (attack & decay)
//unsigned int Ym2612Private::ATTACK_TO_DECAY[ENV_LENGTH]; // Conversion from attack to decay phase
unsigned int Ym2612Private::DECAY_TO_ATTACK[ENV_LENGTH]; // Conversion from decay to attack phase
// libOPNMIDI: Fixed the compatibility with the error: "floating-point literal cannot appear in a constant-expression"
int Ym2612Private::LIMIT_CH_OUT = ((int) (((1 << OUT_BITS) * 1.5) - 1));
int Ym2612Private::PG_CUT_OFF = ((int) (78.0 / ENV_STEP));
int Ym2612Private::ENV_CUT_OFF = ((int) (68.0 / ENV_STEP));
int Ym2612Private::LFO_FMS_BASE = ((int) (0.05946309436 * 0.0338 * (double) (1 << LFO_FMS_LBITS)));
// Next Enveloppe phase functions pointer table
const Ym2612Private::Env_Event Ym2612Private::ENV_NEXT_EVENT[8] = {
Env_Attack_Next,
Env_Decay_Next,
Env_Substain_Next,
Env_Release_Next,
Env_NULL_Next,
Env_NULL_Next,
Env_NULL_Next,
Env_NULL_Next
};
// Default detune table.
// FD == F number
const uint8_t Ym2612Private::DT_DEF_TAB[4][32] = {
// FD = 0
{0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0,
0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0},
// FD = 1
{0, 0, 0, 0, 1, 1, 1, 1, 1, 1, 1, 1, 2, 2, 2, 2,
2, 3, 3, 3, 4, 4, 4, 5, 5, 6, 6, 7, 8, 8, 8, 8},
// FD = 2
{1, 1, 1, 1, 2, 2, 2, 2, 2, 3, 3, 3, 4, 4, 4, 5,
5, 6, 6, 7, 8, 8, 9, 10, 11, 12, 13, 14, 16, 16, 16, 16},
// FD = 3
{2, 2, 2, 2, 2, 3, 3, 3, 4, 4, 4, 5, 5, 6, 6, 7,
8, 8, 9, 10, 11, 12, 13, 14, 16, 17, 19, 20, 22, 22, 22, 22}
};
const uint8_t Ym2612Private::FKEY_TAB[16] = {
0, 0, 0, 0,
0, 0, 0, 1,
2, 3, 3, 3,
3, 3, 3, 3
};
const uint8_t Ym2612Private::LFO_AMS_TAB[4] = {
31, 4, 1, 0
};
const uint8_t Ym2612Private::LFO_FMS_TAB[8] = {
static_cast<uint8_t>(LFO_FMS_BASE * 0), static_cast<uint8_t>(LFO_FMS_BASE * 1),
static_cast<uint8_t>(LFO_FMS_BASE * 2), static_cast<uint8_t>(LFO_FMS_BASE * 3),
static_cast<uint8_t>(LFO_FMS_BASE * 4), static_cast<uint8_t>(LFO_FMS_BASE * 6),
static_cast<uint8_t>(LFO_FMS_BASE * 12), static_cast<uint8_t>(LFO_FMS_BASE * 24)
};
/*
* Pan law table
*/
static const unsigned short 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
};
unsigned int Ym2612Private::SL_TAB[16]; // Sustain level table. (STATIC)
unsigned int Ym2612Private::NULL_RATE[32]; // Table for NULL rate. (STATIC)
// LFO tables.
int Ym2612Private::LFO_ENV_TAB[LFO_LENGTH]; // LFO AMS TABLE (adjusted for 11.8 dB)
int Ym2612Private::LFO_FREQ_TAB[LFO_LENGTH]; // LFO FMS TABLE
// NOTE: INTER_TAB isn't used...
//int Ym2612::INTER_TAB[MAX_UPDATE_LENGTH]; // Interpolation table
/** Gens-specific **/
// TODO for LibGens
#if 0
#include "util/sound/gym.hpp"
#endif
/** end **/
Ym2612Private::Ym2612Private(Ym2612 *q)
: q(q)
{
if (!isInit) {
// Initialize the static tables.
isInit = true;
doStaticInit();
}
}
void Ym2612Private::doStaticInit(void)
{
// Sine table:
// SIN_TAB[x][y] = sin(x) * y;
// x = phase and y = volume
SIN_TAB[0] = SIN_TAB[SIN_LENGTH / 2] = &TL_TAB[(int)PG_CUT_OFF];
for (int i = 1; i <= SIN_LENGTH / 4; i++) {
double x = sin(2.0 * PI * (double) (i) / (double) (SIN_LENGTH)); // Sinus
x = 20 * log10(1 / x); // convert to dB
int j = (int)(x / ENV_STEP); // Get TL range
if (j > PG_CUT_OFF) {
j = (int) PG_CUT_OFF;
}
SIN_TAB[i] = SIN_TAB[(SIN_LENGTH / 2) - i] = &TL_TAB[j];
SIN_TAB[(SIN_LENGTH / 2) + i] = SIN_TAB[SIN_LENGTH - i] = &TL_TAB[TL_LENGTH + j];
// LOG_MSG(ym2612, LOG_MSG_LEVEL_DEBUG3,
// "SIN[%d][0] = %.8X SIN[%d][0] = %.8X SIN[%d][0] = %.8X SIN[%d][0] = %.8X",
// i, SIN_TAB[i][0], (SIN_LENGTH / 2) - i,
// SIN_TAB[(SIN_LENGTH / 2) - i][0], (SIN_LENGTH / 2) + i,
// SIN_TAB[(SIN_LENGTH / 2) + i][0], SIN_LENGTH - i,
// SIN_TAB[SIN_LENGTH - i][0]);
}
// LFO table:
for (int i = 0; i < LFO_LENGTH; i++) {
double x = sin (2.0 * PI * (double) (i) / (double) (LFO_LENGTH)); // Sinus
x += 1.0;
x /= 2.0; // positive only
x *= 11.8 / ENV_STEP; // adjusted to MAX envelope modulation
LFO_ENV_TAB[i] = (int) x;
x = sin(2.0 * PI * (double) (i) / (double) (LFO_LENGTH)); // Sinus
x *= (double) ((1 << (LFO_HBITS - 1)) - 1);
LFO_FREQ_TAB[i] = (int) x;
// LOG_MSG(ym2612, LOG_MSG_LEVEL_DEBUG3,
// "LFO[%d] = %.8X", i, LFO_ENV_TAB[i]);
}
// Envelope table:
// ENV_TAB[0] -> ENV_TAB[ENV_LENGTH - 1] = attack curve
// ENV_TAB[ENV_LENGTH] -> ENV_TAB[2 * ENV_LENGTH - 1] = decay curve
for (int i = 0; i < ENV_LENGTH; i++) {
// Attack curve (x^8 - music level 2 Vectorman 2)
double x = pow(((double)((ENV_LENGTH - 1) - i) / (double)(ENV_LENGTH)), 8);
x *= ENV_LENGTH;
ENV_TAB[i] = (int)x;
// Decay curve (just linear)
x = pow(((double) (i) / (double) (ENV_LENGTH)), 1);
x *= ENV_LENGTH;
ENV_TAB[ENV_LENGTH + i] = (int)x;
// LOG_MSG(ym2612, LOG_MSG_LEVEL_DEBUG3,
// "ATTACK[%d] = %d DECAY[%d] = %d",
// i, ENV_TAB[i], i, ENV_TAB[ENV_LENGTH + i]);
}
ENV_TAB[ENV_END >> ENV_LBITS] = ENV_LENGTH - 1; // for the stopped state
// Decay -> Attack table.
// NOTE: There used to be an Attack -> Decay table,
// but it wasn't implemented as of the original
// port of Gens for Linux...
for (int i = 0, j = ENV_LENGTH - 1; i < ENV_LENGTH; i++) {
while (j && (ENV_TAB[j] < (unsigned) i))
j--;
DECAY_TO_ATTACK[i] = j << ENV_LBITS;
}
// Sustain Level table:
for (int i = 0; i < 15; i++) {
double x = i * 3; // 3 and not 6 (Mickey Mania first music for test)
x /= ENV_STEP;
int j = (int)x;
j <<= ENV_LBITS;
SL_TAB[i] = j + ENV_DECAY;
}
int j = ENV_LENGTH - 1; // special case : volume off
j <<= ENV_LBITS;
SL_TAB[15] = j + ENV_DECAY;
// TL table:
// [0 - 4095] = +output [4095 - ...] = +output overflow (fill with 0)
// [12288 - 16383] = -output [16384 - ...] = -output overflow (fill with 0)
for (int i = 0; i < TL_LENGTH; i++) {
if (i >= PG_CUT_OFF) {
// YM2612 cut off sound after 78 dB (14 bits output ?)
TL_TAB[TL_LENGTH + i] = TL_TAB[i] = 0;
} else {
double x = MAX_OUT; // Max output
x /= pow(10, (ENV_STEP * i) / 20); // Decibel -> Voltage
TL_TAB[i] = (int) x;
TL_TAB[TL_LENGTH + i] = -TL_TAB[i];
}
// LOG_MSG(ym2612, LOG_MSG_LEVEL_DEBUG3,
// "TL_TAB[%d] = %.8X TL_TAB[%d] = %.8X",
// i, TL_TAB[i], TL_LENGTH + i, TL_TAB[TL_LENGTH + i]);
}
// NULL frequency rate table.
// It's always 0.
memset(NULL_RATE, 0, sizeof(NULL_RATE));
}
/*****************************************
* Functions for calculating parameters. *
*****************************************/
inline void Ym2612Private::CALC_FINC_SL(slot_t *SL, int finc, int kc)
{
int ksr;
SL->Finc = (finc + SL->DT[kc]) * SL->MUL;
ksr = kc >> SL->KSR_S; // keycode atténuation
// LOG_MSG(ym2612, LOG_MSG_LEVEL_DEBUG2,
// "FINC = %d SL->Finc = %d", finc, SL->Finc);
if (SL->KSR != ksr) {
// si le KSR a changé alors
// les différents taux pour l'enveloppe sont mis à jour
SL->KSR = ksr;
SL->EincA = SL->AR[ksr];
SL->EincD = SL->DR[ksr];
SL->EincS = SL->SR[ksr];
SL->EincR = SL->RR[ksr];
if (SL->Ecurp == ATTACK) {
SL->Einc = SL->EincA;
} else if (SL->Ecurp == DECAY) {
SL->Einc = SL->EincD;
} else if (SL->Ecnt < ENV_END) {
if (SL->Ecurp == SUSTAIN)
SL->Einc = SL->EincS;
else if (SL->Ecurp == RELEASE)
SL->Einc = SL->EincR;
}
// LOG_MSG(ym2612, LOG_MSG_LEVEL_DEBUG2,
// "KSR = %.4X EincA = %.8X EincD = %.8X EincS = %.8X EincR = %.8X",
// ksr, SL->EincA, SL->EincD, SL->EincS, SL->EincR);
}
}
inline void Ym2612Private::CALC_FINC_CH(channel_t *CH)
{
int finc, kc;
finc = FINC_TAB[CH->FNUM[0]] >> (7 - CH->FOCT[0]);
kc = CH->KC[0];
CALC_FINC_SL(&CH->_SLOT[0], finc, kc);
CALC_FINC_SL(&CH->_SLOT[1], finc, kc);
CALC_FINC_SL(&CH->_SLOT[2], finc, kc);
CALC_FINC_SL(&CH->_SLOT[3], finc, kc);
}
/*********************************
* Functions for setting values. *
*********************************/
/**
* KEY_ON event.
* @param ch Channel.
* @param nsl Slot number.
*/
void Ym2612Private::KEY_ON(channel_t *CH, int nsl)
{
slot_t *SL = &(CH->_SLOT[nsl]); // on recupère le bon pointeur de slot
// la touche est-elle relâchée ?
if (SL->Ecurp == RELEASE) {
SL->Fcnt = 0;
// Fix Ecco 2 splash sound
SL->Ecnt = (DECAY_TO_ATTACK[ENV_TAB[SL->Ecnt >> ENV_LBITS]] + ENV_ATTACK) & SL->ChgEnM;
SL->ChgEnM = ~0;
/*
SL->Ecnt = DECAY_TO_ATTACK[ENV_TAB[SL->Ecnt >> ENV_LBITS]] + ENV_ATTACK;
SL->Ecnt = 0;
*/
SL->Einc = SL->EincA;
SL->Ecmp = ENV_DECAY;
SL->Ecurp = ATTACK;
}
}
/**
* KEY_OFF event.
* @param ch Channel.
* @param nsl Slot number.
*/
void Ym2612Private::KEY_OFF(channel_t *CH, int nsl)
{
slot_t *SL = &(CH->_SLOT[nsl]); // on recupère le bon pointeur de slot
// la touche est-elle appuyée ?
if (SL->Ecurp != RELEASE) {
// attack phase ?
if (SL->Ecnt < ENV_DECAY) {
SL->Ecnt = (ENV_TAB[SL->Ecnt >> ENV_LBITS] << ENV_LBITS) + ENV_DECAY;
}
SL->Einc = SL->EincR;
SL->Ecmp = ENV_END;
SL->Ecurp = RELEASE;
}
}
inline void Ym2612Private::CSM_Key_Control(void)
{
KEY_ON(&state.CHANNEL[2], 0);
KEY_ON(&state.CHANNEL[2], 1);
KEY_ON(&state.CHANNEL[2], 2);
KEY_ON(&state.CHANNEL[2], 3);
}
/**
* Set a value for a slot.
* @param address Register address.
* @param data Data.
*/
int Ym2612Private::SLOT_SET(int address, uint8_t data)
{
int nch = address & 3;
if (nch == 3)
return 1;
if (address & 0x100)
nch += 3;
channel_t *CH = &state.CHANNEL[nch];
const int nsl = (address >> 2) & 3;
slot_t *SL = &CH->_SLOT[nsl];
switch (address & 0xF0) {
case 0x30:
if ((SL->MUL = (data & 0x0F)) != 0) {
SL->MUL <<= 1;
} else {
SL->MUL = 1;
}
SL->DT = DT_TAB[(data >> 4) & 7];
CH->_SLOT[0].Finc = -1;
// LOG_MSG(ym2612, LOG_MSG_LEVEL_DEBUG2,
// "CHANNEL[%d], SLOT[%d] DTMUL = %.2X", nch, nsl, data & 0x7F);
break;
case 0x40:
SL->TL = data & 0x7F;
// SOR2 do a lot of TL adjustement and this fix R.Shinobi jump sound...
q->specialUpdate();
#if ((ENV_HBITS - 7) < 0)
SL->TLL = SL->TL >> (7 - ENV_HBITS);
#else
SL->TLL = SL->TL << (ENV_HBITS - 7);
#endif
// LOG_MSG(ym2612, LOG_MSG_LEVEL_DEBUG2,
// "CHANNEL[%d], SLOT[%d] TL = %.2X", nch, nsl, SL->TL);
break;
case 0x50:
SL->KSR_S = 3 - (data >> 6);
CH->_SLOT[0].Finc = -1;
if (data &= 0x1F) {
SL->AR = &AR_TAB[data << 1];
} else {
SL->AR = &NULL_RATE[0];
}
SL->EincA = SL->AR[SL->KSR];
if (SL->Ecurp == ATTACK)
SL->Einc = SL->EincA;
// LOG_MSG(ym2612, LOG_MSG_LEVEL_DEBUG2,
// "CHANNEL[%d], SLOT[%d] AR = %.2X EincA = %.6X", nch, nsl, data, SL->EincA);
break;
case 0x60:
if ((SL->AMSon = (data & 0x80))) {
SL->AMS = CH->AMS;
} else {
SL->AMS = 31;
}
if (data &= 0x1F) {
SL->DR = &DR_TAB[data << 1];
} else {
SL->DR = &NULL_RATE[0];
}
SL->EincD = SL->DR[SL->KSR];
if (SL->Ecurp == DECAY)
SL->Einc = SL->EincD;
// LOG_MSG(ym2612, LOG_MSG_LEVEL_DEBUG2,
// "CHANNEL[%d], SLOT[%d] AMS = %d DR = %.2X EincD = %.6X",
// nch, nsl, SL->AMSon, data, SL->EincD);
break;
case 0x70:
if (data &= 0x1F) {
SL->SR = &DR_TAB[data << 1];
} else {
SL->SR = &NULL_RATE[0];
}
SL->EincS = SL->SR[SL->KSR];
if ((SL->Ecurp == SUSTAIN) && (SL->Ecnt < ENV_END))
SL->Einc = SL->EincS;
// LOG_MSG(ym2612, LOG_MSG_LEVEL_DEBUG2,
// "CHANNEL[%d], SLOT[%d] SR = %.2X EincS = %.6X",
// nch, nsl, data, SL->EincS);
break;
case 0x80:
SL->SLL = SL_TAB[data >> 4];
SL->RR = &DR_TAB[((data & 0xF) << 2) + 2];
SL->EincR = SL->RR[SL->KSR];
if ((SL->Ecurp == RELEASE) && (SL->Ecnt < ENV_END))
SL->Einc = SL->EincR;
// LOG_MSG(ym2612, LOG_MSG_LEVEL_DEBUG2,
// "CHANNEL[%d], SLOT[%d] SL = %.8X", nch, nsl, SL->SLL);
// LOG_MSG(ym2612, LOG_MSG_LEVEL_DEBUG2,
// "CHANNEL[%d], SLOT[%d] RR = %.2X EincR = %.2X",
// nch, nsl, ((data & 0xF) << 1) | 2, SL->EincR);
break;
case 0x90:
// SSG-EG envelope shapes:
/*
E At Al H
1 0 0 0 \\\\
1 0 0 1 \___
1 0 1 0 \/\/
1 0 1 1 \
1 1 0 0 ////
1 1 0 1 /
1 1 1 0 /\/\
1 1 1 1 /___
E = SSG-EG enable
At = Start negate
Al = Altern
H = Hold
*/
if (data & 0x08) {
SL->SEG = data & 0x0F;
} else {
SL->SEG = 0;
}
// LOG_MSG(ym2612, LOG_MSG_LEVEL_DEBUG2,
// "CHANNEL[%d], SLOT[%d] SSG-EG = %.2X", nch, nsl, data);
break;
}
return 0;
}
/**
* Set a value for a channel.
* @param address Register address.
* @param data Data.
*/
int Ym2612Private::CHANNEL_SET(int address, uint8_t data)
{
int nch = address & 3;
if (nch == 3)
return 1;
if (address & 0x100)
nch += 3;
channel_t *CH = &state.CHANNEL[nch];
switch (address & 0xFC) {
case 0xA0:
q->specialUpdate();
CH->FNUM[0] = (CH->FNUM[0] & 0x700) + data;
CH->KC[0] = (CH->FOCT[0] << 2) | FKEY_TAB[CH->FNUM[0] >> 7];
CH->_SLOT[0].Finc = -1;
// LOG_MSG(ym2612, LOG_MSG_LEVEL_DEBUG2,
// "CHANNEL[%d] part1 FNUM = %d KC = %d",
// nch, CH->FNUM[0], CH->KC[0]);
break;
case 0xA4:
q->specialUpdate();
CH->FNUM[0] = (CH->FNUM[0] & 0x0FF) + ((int) (data & 0x07) << 8);
CH->FOCT[0] = (data & 0x38) >> 3;
CH->KC[0] = (CH->FOCT[0] << 2) | FKEY_TAB[CH->FNUM[0] >> 7];
CH->_SLOT[0].Finc = -1;
// LOG_MSG(ym2612, LOG_MSG_LEVEL_DEBUG2,
// "CHANNEL[%d] part2 FNUM = %d FOCT = %d KC = %d",
// nch, CH->FNUM[0], CH->FOCT[0], CH->KC[0]);
break;
case 0xA8:
if (address < 0x100) {
// Channel 3: Specific slot operator.
const int nsl = nch + 1;
q->specialUpdate();
state.CHANNEL[2].FNUM[nsl] = (state.CHANNEL[2].FNUM[nsl] & 0x700) + data;
state.CHANNEL[2].KC[nsl] = (state.CHANNEL[2].FOCT[nsl] << 2) |
FKEY_TAB[state.CHANNEL[2].FNUM[nsl] >> 7];
state.CHANNEL[2]._SLOT[0].Finc = -1;
// LOG_MSG(ym2612, LOG_MSG_LEVEL_DEBUG2,
// "CHANNEL[2] part1 FNUM[%d] = %d KC[%d] = %d",
// nsl, state.CHANNEL[2].FNUM[nsl],
// nsl, state.CHANNEL[2].KC[nsl]);
}
break;
case 0xAC:
if (address < 0x100) {
// Channel 3: Specific slot operator.
const int nsl = nch + 1;
q->specialUpdate();
state.CHANNEL[2].FNUM[nsl] = (state.CHANNEL[2].FNUM[nsl] & 0x0FF) +
((int) (data & 0x07) << 8);
state.CHANNEL[2].FOCT[nsl] = (data & 0x38) >> 3;
state.CHANNEL[2].KC[nsl] = (state.CHANNEL[2].FOCT[nsl] << 2) |
FKEY_TAB[state.CHANNEL[2].FNUM[nsl] >> 7];
state.CHANNEL[2]._SLOT[0].Finc = -1;
// LOG_MSG(ym2612, LOG_MSG_LEVEL_DEBUG2,
// "CHANNEL[2] part2 FNUM[%d] = %d FOCT[%d] = %d KC[%d] = %d",
// nsl, state.CHANNEL[2].FNUM[nsl],
// nsl, state.CHANNEL[2].FOCT[nsl],
// nsl, state.CHANNEL[2].KC[nsl]);
}
break;
case 0xB0:
if (CH->ALGO != (data & 7)) {
// Fix VectorMan 2 heli sound (level 1)
q->specialUpdate();
CH->ALGO = data & 7;
CH->_SLOT[0].ChgEnM = 0;
CH->_SLOT[1].ChgEnM = 0;
CH->_SLOT[2].ChgEnM = 0;
CH->_SLOT[3].ChgEnM = 0;
}
CH->FB = 9 - ((data >> 3) & 7); // Real thing ?
/*if (CH->FB = ((data >> 3) & 7)) {
// Thunder force 4 (music stage 8), Gynoug, Aladdin bug sound...
CH->FB = 9 - CH->FB;
} else {
CH->FB = 31;
}*/
// LOG_MSG(ym2612, LOG_MSG_LEVEL_DEBUG2,
// "CHANNEL[%d] ALGO = %d FB = %d", nch, CH->ALGO, CH->FB);
break;
case 0xB4:
q->specialUpdate();
// -1 = 0xFFFFFFFF. Useful trick from game-music-emu.
CH->LEFT = 0 - ((data >> 7) & 1);
CH->RIGHT = 0 - ((data >> 6) & 1);
CH->AMS = LFO_AMS_TAB[(data >> 4) & 3];
CH->FMS = LFO_FMS_TAB[data & 7];
for (int i = 0; i < 3; i++) {
slot_t *SL = &CH->_SLOT[i];
SL->AMS = (SL->AMSon ? CH->AMS : 31);
}
// LOG_MSG(ym2612, LOG_MSG_LEVEL_DEBUG1,
// "CHANNEL[%d] AMS = %d FMS = %d", nch, CH->AMS, CH->FMS);
break;
}
return 0;
}
/**
* Set a value for the entire device.
* @param address Register address.
* @param data Data.
*/
int Ym2612Private::YM_SET(int address, uint8_t data)
{
switch (address) {
case 0x22:
// LFO enable
if (data & 8) {
// Cool Spot music 1, LFO modified severals time which
// distord the sound, have to check that on a real genesis...
state.LFOinc = LFO_INC_TAB[data & 7];
// LOG_MSG(ym2612, LOG_MSG_LEVEL_DEBUG1,
// "LFO Enable, LFOinc = %.8X %d", state.LFOinc, data & 7);
} else {
state.LFOinc = state.LFOcnt = 0;
// LOG_MSG(ym2612, LOG_MSG_LEVEL_DEBUG1,
// "LFO Disable");
}
break;
case 0x24:
state.TimerA = (state.TimerA & 0x003) | (((int)data) << 2);
if (state.TimerAL != (1024 - state.TimerA) << 12) {
state.TimerAcnt = state.TimerAL = (1024 - state.TimerA) << 12;
// LOG_MSG(ym2612, LOG_MSG_LEVEL_DEBUG2,
// "Timer A Set = %.8X", state.TimerAcnt);
}
break;
case 0x25:
state.TimerA = (state.TimerA & 0x3FC) | (data & 3);
if (state.TimerAL != (1024 - state.TimerA) << 12) {
state.TimerAcnt = state.TimerAL = (1024 - state.TimerA) << 12;
// LOG_MSG(ym2612, LOG_MSG_LEVEL_DEBUG2,
// "Timer A Set = %.8X", state.TimerAcnt);
}
break;
case 0x26:
state.TimerB = data;
if (state.TimerBL != (256 - state.TimerB) << (4 + 12)) {
state.TimerBcnt = state.TimerBL = (256 - state.TimerB) << (4 + 12);
// LOG_MSG(ym2612, LOG_MSG_LEVEL_DEBUG2,
// "Timer B Set = %.8X", state.TimerBcnt);
}
break;
case 0x27:
// Paramètre divers
// b7 = CSM MODE
// b6 = 3 slot mode
// b5 = reset b
// b4 = reset a
// b3 = timer enable b
// b2 = timer enable a
// b1 = load b
// b0 = load a
if ((data ^ state.Mode) & 0x40) {
// We changed the channel 2 mode, so recalculate phase step
// This fix the punch sound in Street of Rage 2
q->specialUpdate();
state.CHANNEL[2]._SLOT[0].Finc = -1; // recalculate phase step
}
/*
if ((data & 2) && (YM2612.Status & 2))
YM2612.TimerBcnt = YM2612.TimerBL;
if ((data & 1) && (YM2612.Status & 1))
YM2612.TimerAcnt = YM2612.TimerAL;
*/
//YM2612.Status &= (~data >> 4); // Reset du Status au cas ou c'est demandé
state.status &= (~data >> 4) & (data >> 2); // Reset Status
state.Mode = data;
// LOG_MSG(ym2612, LOG_MSG_LEVEL_DEBUG1,
// "Mode reg = %.2X", data);
break;
case 0x28: {
int nch = data & 3;
if (nch == 3)
return 1;
if (data & 4)
nch += 3;
channel_t *CH = &state.CHANNEL[nch];
q->specialUpdate();
// KEY_ON or KEY_OFF the selected operator(s).
if (data & 0x10)
KEY_ON(CH, S0); // On appuie sur la touche pour le slot 1
else
KEY_OFF(CH, S0); // On relâche la touche pour le slot 1
if (data & 0x20)
KEY_ON(CH, S1); // On appuie sur la touche pour le slot 3
else
KEY_OFF(CH, S1); // On relâche la touche pour le slot 3
if (data & 0x40)
KEY_ON(CH, S2); // On appuie sur la touche pour le slot 2
else
KEY_OFF(CH, S2); // On relâche la touche pour le slot 2
if (data & 0x80)
KEY_ON(CH, S3); // On appuie sur la touche pour le slot 4
else
KEY_OFF(CH, S3); // On relâche la touche pour le slot 4
// LOG_MSG(ym2612, LOG_MSG_LEVEL_DEBUG1,
// "CHANNEL[%d] KEY %.1X", nch, ((data & 0xF0) >> 4));
break;
}
case 0x2A:
// Set the DAC value.
state.DACdata = ((int)data - 0x80) << 7; // donnée du DAC
break;
case 0x2B:
if (state.DAC ^ (data & 0x80))
q->specialUpdate();
// Enable/disable the DAC.
state.DAC = data & 0x80; // Activate / Deactivate the DAC.
break;
}
return 0;
}
/***********************************************
* fonctions de génération *
***********************************************/
void Ym2612Private::Env_NULL_Next(slot_t *SL)
{
// Mark SL as unused.
// TODO: Write a macro to do this!
((void)SL);
}
void Ym2612Private::Env_Attack_Next(slot_t *SL)
{
// Verified with Gynoug even in HQ (explode SFX)
SL->Ecnt = ENV_DECAY;
SL->Einc = SL->EincD;
SL->Ecmp = SL->SLL;
SL->Ecurp = DECAY;
}
void Ym2612Private::Env_Decay_Next(slot_t *SL)
{
// Verified with Gynoug even in HQ (explode SFX)
SL->Ecnt = SL->SLL;
SL->Einc = SL->EincS;
SL->Ecmp = ENV_END;
SL->Ecurp = SUSTAIN;
}
void Ym2612Private::Env_Substain_Next(slot_t *SL)
{
if (SL->SEG & 8) {
// SSG-EG is enabled.
if (SL->SEG & 1) {
SL->Ecnt = ENV_END;
SL->Einc = 0;
SL->Ecmp = ENV_END + 1;
} else {
// re KEY ON
// SL->Fcnt = 0;
// SL->ChgEnM = 0xFFFFFFFF;
SL->Ecnt = 0;
SL->Einc = SL->EincA;
SL->Ecmp = ENV_DECAY;
SL->Ecurp = ATTACK;
}
SL->SEG ^= (SL->SEG & 2) << 1;
} else {
// SSG-EG is disabled.
SL->Ecnt = ENV_END;
SL->Einc = 0;
SL->Ecmp = ENV_END + 1;
}
}
void Ym2612Private::Env_Release_Next(slot_t *SL)
{
SL->Ecnt = ENV_END;
SL->Einc = 0;
SL->Ecmp = ENV_END + 1;
}
#define GET_CURRENT_PHASE() do { \
in0 = CH->_SLOT[S0].Fcnt; \
in1 = CH->_SLOT[S1].Fcnt; \
in2 = CH->_SLOT[S2].Fcnt; \
in3 = CH->_SLOT[S3].Fcnt; \
} while (0)
#define UPDATE_PHASE() do { \
CH->_SLOT[S0].Fcnt += CH->_SLOT[S0].Finc; \
CH->_SLOT[S1].Fcnt += CH->_SLOT[S1].Finc; \
CH->_SLOT[S2].Fcnt += CH->_SLOT[S2].Finc; \
CH->_SLOT[S3].Fcnt += CH->_SLOT[S3].Finc; \
} while (0)
#define UPDATE_PHASE_LFO() do { \
if ((freq_LFO = (CH->FMS * LFO_FREQ_UP[i]) >> (LFO_HBITS - 1))) \
{ \
CH->_SLOT[S0].Fcnt += CH->_SLOT[S0].Finc + ((CH->_SLOT[S0].Finc * freq_LFO) >> LFO_FMS_LBITS); \
CH->_SLOT[S1].Fcnt += CH->_SLOT[S1].Finc + ((CH->_SLOT[S1].Finc * freq_LFO) >> LFO_FMS_LBITS); \
CH->_SLOT[S2].Fcnt += CH->_SLOT[S2].Finc + ((CH->_SLOT[S2].Finc * freq_LFO) >> LFO_FMS_LBITS); \
CH->_SLOT[S3].Fcnt += CH->_SLOT[S3].Finc + ((CH->_SLOT[S3].Finc * freq_LFO) >> LFO_FMS_LBITS); \
} \
else \
{ \
CH->_SLOT[S0].Fcnt += CH->_SLOT[S0].Finc; \
CH->_SLOT[S1].Fcnt += CH->_SLOT[S1].Finc; \
CH->_SLOT[S2].Fcnt += CH->_SLOT[S2].Finc; \
CH->_SLOT[S3].Fcnt += CH->_SLOT[S3].Finc; \
} \
} while (0)
// Commented out from Gens Rerecording
/*
#define GET_CURRENT_ENV \
if (CH->_SLOT[S0].SEG & 4) \
{ \
if ((en0 = ENV_TAB[(CH->_SLOT[S0].Ecnt >> ENV_LBITS)] + CH->_SLOT[S0].TLL) > ENV_MASK) en0 = 0; \
else en0 ^= ENV_MASK; \
} \
else en0 = ENV_TAB[(CH->_SLOT[S0].Ecnt >> ENV_LBITS)] + CH->_SLOT[S0].TLL; \
if (CH->_SLOT[S1].SEG & 4) \
{ \
if ((en1 = ENV_TAB[(CH->_SLOT[S1].Ecnt >> ENV_LBITS)] + CH->_SLOT[S1].TLL) > ENV_MASK) en1 = 0; \
else en1 ^= ENV_MASK; \
} \
else en1 = ENV_TAB[(CH->_SLOT[S1].Ecnt >> ENV_LBITS)] + CH->_SLOT[S1].TLL; \
if (CH->_SLOT[S2].SEG & 4) \
{ \
if ((en2 = ENV_TAB[(CH->_SLOT[S2].Ecnt >> ENV_LBITS)] + CH->_SLOT[S2].TLL) > ENV_MASK) en2 = 0; \
else en2 ^= ENV_MASK; \
} \
else en2 = ENV_TAB[(CH->_SLOT[S2].Ecnt >> ENV_LBITS)] + CH->_SLOT[S2].TLL; \
if (CH->_SLOT[S3].SEG & 4) \
{ \
if ((en3 = ENV_TAB[(CH->_SLOT[S3].Ecnt >> ENV_LBITS)] + CH->_SLOT[S3].TLL) > ENV_MASK) en3 = 0; \
else en3 ^= ENV_MASK; \
} \
else en3 = ENV_TAB[(CH->_SLOT[S3].Ecnt >> ENV_LBITS)] + CH->_SLOT[S3].TLL;
*/
// New version from Gens Rerecording
#define GET_CURRENT_ENV() do { \
en0 = ENV_TAB[(CH->_SLOT[S0].Ecnt >> ENV_LBITS)] + CH->_SLOT[S0].TLL; \
en1 = ENV_TAB[(CH->_SLOT[S1].Ecnt >> ENV_LBITS)] + CH->_SLOT[S1].TLL; \
en2 = ENV_TAB[(CH->_SLOT[S2].Ecnt >> ENV_LBITS)] + CH->_SLOT[S2].TLL; \
en3 = ENV_TAB[(CH->_SLOT[S3].Ecnt >> ENV_LBITS)] + CH->_SLOT[S3].TLL; \
} while (0)
// Commented out from Gens Rerecording
/*
#define GET_CURRENT_ENV_LFO \
env_LFO = LFO_ENV_UP[i]; \
\
if (CH->_SLOT[S0].SEG & 4) \
{ \
if ((en0 = ENV_TAB[(CH->_SLOT[S0].Ecnt >> ENV_LBITS)] + CH->_SLOT[S0].TLL) > ENV_MASK) en0 = 0; \
else en0 = (en0 ^ ENV_MASK) + (env_LFO >> CH->_SLOT[S0].AMS); \
} \
else en0 = ENV_TAB[(CH->_SLOT[S0].Ecnt >> ENV_LBITS)] + CH->_SLOT[S0].TLL + (env_LFO >> CH->_SLOT[S0].AMS); \
if (CH->_SLOT[S1].SEG & 4) \
{ \
if ((en1 = ENV_TAB[(CH->_SLOT[S1].Ecnt >> ENV_LBITS)] + CH->_SLOT[S1].TLL) > ENV_MASK) en1 = 0; \
else en1 = (en1 ^ ENV_MASK) + (env_LFO >> CH->_SLOT[S1].AMS); \
} \
else en1 = ENV_TAB[(CH->_SLOT[S1].Ecnt >> ENV_LBITS)] + CH->_SLOT[S1].TLL + (env_LFO >> CH->_SLOT[S1].AMS); \
if (CH->_SLOT[S2].SEG & 4) \
{ \
if ((en2 = ENV_TAB[(CH->_SLOT[S2].Ecnt >> ENV_LBITS)] + CH->_SLOT[S2].TLL) > ENV_MASK) en2 = 0; \
else en2 = (en2 ^ ENV_MASK) + (env_LFO >> CH->_SLOT[S2].AMS); \
} \
else en2 = ENV_TAB[(CH->_SLOT[S2].Ecnt >> ENV_LBITS)] + CH->_SLOT[S2].TLL + (env_LFO >> CH->_SLOT[S2].AMS); \
if (CH->_SLOT[S3].SEG & 4) \
{ \
if ((en3 = ENV_TAB[(CH->_SLOT[S3].Ecnt >> ENV_LBITS)] + CH->_SLOT[S3].TLL) > ENV_MASK) en3 = 0; \
else en3 = (en3 ^ ENV_MASK) + (env_LFO >> CH->_SLOT[S3].AMS); \
} \
else en3 = ENV_TAB[(CH->_SLOT[S3].Ecnt >> ENV_LBITS)] + CH->_SLOT[S3].TLL + (env_LFO >> CH->_SLOT[S3].AMS);
*/
// New version from Gens Rerecording
#define GET_CURRENT_ENV_LFO() do { \
env_LFO = LFO_ENV_UP[i]; \
en0 = ENV_TAB[(CH->_SLOT[S0].Ecnt >> ENV_LBITS)] + CH->_SLOT[S0].TLL + (env_LFO >> CH->_SLOT[S0].AMS); \
en1 = ENV_TAB[(CH->_SLOT[S1].Ecnt >> ENV_LBITS)] + CH->_SLOT[S1].TLL + (env_LFO >> CH->_SLOT[S1].AMS); \
en2 = ENV_TAB[(CH->_SLOT[S2].Ecnt >> ENV_LBITS)] + CH->_SLOT[S2].TLL + (env_LFO >> CH->_SLOT[S2].AMS); \
en3 = ENV_TAB[(CH->_SLOT[S3].Ecnt >> ENV_LBITS)] + CH->_SLOT[S3].TLL + (env_LFO >> CH->_SLOT[S3].AMS); \
} while (0)
#define UPDATE_ENV() do { \
if ((CH->_SLOT[S0].Ecnt += CH->_SLOT[S0].Einc) >= CH->_SLOT[S0].Ecmp) \
ENV_NEXT_EVENT[CH->_SLOT[S0].Ecurp](&(CH->_SLOT[S0])); \
if ((CH->_SLOT[S1].Ecnt += CH->_SLOT[S1].Einc) >= CH->_SLOT[S1].Ecmp) \
ENV_NEXT_EVENT[CH->_SLOT[S1].Ecurp](&(CH->_SLOT[S1])); \
if ((CH->_SLOT[S2].Ecnt += CH->_SLOT[S2].Einc) >= CH->_SLOT[S2].Ecmp) \
ENV_NEXT_EVENT[CH->_SLOT[S2].Ecurp](&(CH->_SLOT[S2])); \
if ((CH->_SLOT[S3].Ecnt += CH->_SLOT[S3].Einc) >= CH->_SLOT[S3].Ecmp) \
ENV_NEXT_EVENT[CH->_SLOT[S3].Ecurp](&(CH->_SLOT[S3])); \
} while (0)
#define DO_LIMIT() do { \
if (CH->OUTd > LIMIT_CH_OUT) \
CH->OUTd = LIMIT_CH_OUT; \
else if (CH->OUTd < -LIMIT_CH_OUT) \
CH->OUTd = -LIMIT_CH_OUT; \
} while (0)
#define DO_FEEDBACK0() do { \
in0 += CH->S0_OUT[0] >> CH->FB; \
CH->S0_OUT[0] = SIN_TAB[(in0 >> SIN_LBITS) & SIN_MASK][en0]; \
} while (0)
#define DO_FEEDBACK() do { \
in0 += (CH->S0_OUT[0] + CH->S0_OUT[1]) >> CH->FB; \
CH->S0_OUT[1] = CH->S0_OUT[0]; \
CH->S0_OUT[0] = SIN_TAB[(in0 >> SIN_LBITS) & SIN_MASK][en0]; \
} while (0)
#define DO_FEEDBACK2() do { \
in0 += (CH->S0_OUT[0] + (CH->S0_OUT[0] >> 2) + CH->S0_OUT[1]) >> CH->FB; \
CH->S0_OUT[1] = CH->S0_OUT[0] >> 2; \
CH->S0_OUT[0] = SIN_TAB[(in0 >> SIN_LBITS) & SIN_MASK][en0]; \
} while (0)
#define DO_FEEDBACK3() do { \
in0 += (CH->S0_OUT[0] + CH->S0_OUT[1] + CH->S0_OUT[2] + CH->S0_OUT[3]) >> CH->FB; \
CH->S0_OUT[3] = CH->S0_OUT[2] >> 1; \
CH->S0_OUT[2] = CH->S0_OUT[1] >> 1; \
CH->S0_OUT[1] = CH->S0_OUT[0] >> 1; \
CH->S0_OUT[0] = SIN_TAB[(in0 >> SIN_LBITS) & SIN_MASK][en0]; \
} while (0)
#define DO_ALGO_0() do { \
DO_FEEDBACK(); \
in1 += CH->S0_OUT[0]; \
in2 += SIN_TAB[(in1 >> SIN_LBITS) & SIN_MASK][en1]; \
in3 += SIN_TAB[(in2 >> SIN_LBITS) & SIN_MASK][en2]; \
CH->OUTd = (SIN_TAB[(in3 >> SIN_LBITS) & SIN_MASK][en3]) >> OUT_SHIFT; \
} while (0)
#define DO_ALGO_1() do { \
DO_FEEDBACK(); \
in2 += CH->S0_OUT[0] + SIN_TAB[(in1 >> SIN_LBITS) & SIN_MASK][en1]; \
in3 += SIN_TAB[(in2 >> SIN_LBITS) & SIN_MASK][en2]; \
CH->OUTd = (SIN_TAB[(in3 >> SIN_LBITS) & SIN_MASK][en3]) >> OUT_SHIFT; \
} while (0)
#define DO_ALGO_2() do { \
DO_FEEDBACK(); \
in2 += SIN_TAB[(in1 >> SIN_LBITS) & SIN_MASK][en1]; \
in3 += CH->S0_OUT[0] + SIN_TAB[(in2 >> SIN_LBITS) & SIN_MASK][en2]; \
CH->OUTd = (SIN_TAB[(in3 >> SIN_LBITS) & SIN_MASK][en3]) >> OUT_SHIFT; \
} while (0)
#define DO_ALGO_3() do { \
DO_FEEDBACK(); \
in1 += CH->S0_OUT[0]; \
in3 += SIN_TAB[(in1 >> SIN_LBITS) & SIN_MASK][en1] + \
SIN_TAB[(in2 >> SIN_LBITS) & SIN_MASK][en2]; \
CH->OUTd = (SIN_TAB[(in3 >> SIN_LBITS) & SIN_MASK][en3]) >> OUT_SHIFT; \
} while (0)
#define DO_ALGO_4() do { \
DO_FEEDBACK(); \
in1 += CH->S0_OUT[0]; \
in3 += SIN_TAB[(in2 >> SIN_LBITS) & SIN_MASK][en2]; \
CH->OUTd = ((int)SIN_TAB[(in3 >> SIN_LBITS) & SIN_MASK][en3] + \
(int)SIN_TAB[(in1 >> SIN_LBITS) & SIN_MASK][en1]) >> OUT_SHIFT; \
DO_LIMIT(); \
} while (0)
#define DO_ALGO_5() do { \
DO_FEEDBACK(); \
in1 += CH->S0_OUT[0]; \
in2 += CH->S0_OUT[0]; \
in3 += CH->S0_OUT[0]; \
CH->OUTd = ((int)SIN_TAB[(in3 >> SIN_LBITS) & SIN_MASK][en3] + \
(int)SIN_TAB[(in1 >> SIN_LBITS) & SIN_MASK][en1] + \
(int)SIN_TAB[(in2 >> SIN_LBITS) & SIN_MASK][en2]) >> OUT_SHIFT; \
DO_LIMIT(); \
} while (0)
#define DO_ALGO_6() do { \
DO_FEEDBACK(); \
in1 += CH->S0_OUT[0]; \
CH->OUTd = ((int)SIN_TAB[(in3 >> SIN_LBITS) & SIN_MASK][en3] + \
(int)SIN_TAB[(in1 >> SIN_LBITS) & SIN_MASK][en1] + \
(int)SIN_TAB[(in2 >> SIN_LBITS) & SIN_MASK][en2]) >> OUT_SHIFT; \
DO_LIMIT(); \
} while (0)
#define DO_ALGO_7() do { \
DO_FEEDBACK(); \
CH->OUTd = ((int)SIN_TAB[(in3 >> SIN_LBITS) & SIN_MASK][en3] + \
(int)SIN_TAB[(in1 >> SIN_LBITS) & SIN_MASK][en1] + \
(int)SIN_TAB[(in2 >> SIN_LBITS) & SIN_MASK][en2] + \
CH->S0_OUT[0]) >> OUT_SHIFT; \
DO_LIMIT(); \
} while (0)
#define DO_OUTPUT() do { \
bufL[i] += (int)((CH->OUTd * CH->PANVolumeL / 65535) & CH->LEFT); \
bufR[i] += (int)((CH->OUTd * CH->PANVolumeR / 65535) & CH->RIGHT); \
} while (0)
#define DO_OUTPUT_INT0() do { \
if ((int_cnt += state.Inter_Step) & 0x04000) { \
int_cnt &= 0x3FFF; \
bufL[i] += (int)((CH->OUTd * CH->PANVolumeL / 65535) & CH->LEFT); \
bufR[i] += (int)((CH->OUTd * CH->PANVolumeR / 65535) & CH->RIGHT); \
} else { \
i--; \
} \
} while (0)
#define DO_OUTPUT_INT1() do { \
CH->Old_OUTd = (CH->OUTd + CH->Old_OUTd) >> 1; \
if ((int_cnt += state.Inter_Step) & 0x04000) { \
int_cnt &= 0x3FFF; \
bufL[i] += (int)((CH->Old_OUTd * CH->PANVolumeL / 65535) & CH->LEFT); \
bufR[i] += (int)((CH->Old_OUTd * CH->PANVolumeR / 65535) & CH->RIGHT); \
} else { \
i--; \
} \
} while (0)
#define DO_OUTPUT_INT2() do { \
if ((int_cnt += state.Inter_Step) & 0x04000) { \
int_cnt &= 0x3FFF; \
CH->Old_OUTd = (CH->OUTd + CH->Old_OUTd) >> 1; \
bufL[i] += (int)((CH->Old_OUTd * CH->PANVolumeL / 65535) & CH->LEFT); \
bufR[i] += (int)((CH->Old_OUTd * CH->PANVolumeR / 65535) & CH->RIGHT); \
} else { \
i--; \
} \ \
CH->Old_OUTd = CH->OUTd; \
} while (0)
#define DO_OUTPUT_INT() do { \
if ((int_cnt += state.Inter_Step) & 0x04000) { \
int_cnt &= 0x3FFF; \
CH->Old_OUTd = (((int_cnt ^ 0x3FFF) * CH->OUTd) + \
(int_cnt * CH->Old_OUTd)) >> 14; \
bufL[i] += (int)((CH->Old_OUTd * CH->PANVolumeL / 65535) & CH->LEFT); \
bufR[i] += (int)((CH->Old_OUTd * CH->PANVolumeR / 65535) & CH->RIGHT); \
} else { \
i--; \
} \
CH->Old_OUTd = CH->OUTd; \
} while (0)
template<int algo>
inline void Ym2612Private::T_Update_Chan(channel_t *CH, int32_t *bufL, int32_t *bufR, int length)
{
// Check if the channel has reached the end of the update.
{
int not_end = (CH->_SLOT[S3].Ecnt - ENV_END);
// Special cases.
// Copied from Game_Music_Emu v0.5.2.
if (algo == 7)
not_end |= (CH->_SLOT[S0].Ecnt - ENV_END);
if (algo >= 5)
not_end |= (CH->_SLOT[S2].Ecnt - ENV_END);
if (algo >= 4)
not_end |= (CH->_SLOT[S1].Ecnt - ENV_END);
if (not_end == 0)
return;
}
// LOG_MSG(ym2612, LOG_MSG_LEVEL_DEBUG2,
// "Algo %d len = %d", algo, length);
for (int i = 0; i < length; i++) {
int in0, in1, in2, in3; // current phase calculation
int en0, en1, en2, en3; // current envelope calculation
GET_CURRENT_PHASE();
UPDATE_PHASE();
GET_CURRENT_ENV();
UPDATE_ENV();
assert(algo >= 0 && algo <= 7);
switch (algo) {
case 0:
DO_ALGO_0();
break;
case 1:
DO_ALGO_1();
break;
case 2:
DO_ALGO_2();
break;
case 3:
DO_ALGO_3();
break;
case 4:
DO_ALGO_4();
break;
case 5:
DO_ALGO_5();
break;
case 6:
DO_ALGO_6();
break;
case 7:
DO_ALGO_7();
break;
default:
break;
}
DO_OUTPUT();
}
}
template<int algo>
inline void Ym2612Private::T_Update_Chan_LFO(channel_t *CH, int32_t *bufL, int32_t *bufR, int length)
{
// Check if the channel has reached the end of the update.
{
int not_end = (CH->_SLOT[S3].Ecnt - ENV_END);
// Special cases.
// Copied from Game_Music_Emu v0.5.2.
if (algo == 7)
not_end |= (CH->_SLOT[S0].Ecnt - ENV_END);
if (algo >= 5)
not_end |= (CH->_SLOT[S2].Ecnt - ENV_END);
if (algo >= 4)
not_end |= (CH->_SLOT[S1].Ecnt - ENV_END);
if (not_end == 0)
return;
}
int env_LFO, freq_LFO;
// LOG_MSG(ym2612, LOG_MSG_LEVEL_DEBUG2,
// "Algo %d LFO len = %d", algo, length);
for (int i = 0; i < length; i++) {
int in0, in1, in2, in3; // current phase calculation
int en0, en1, en2, en3; // current envelope calculation
GET_CURRENT_PHASE();
UPDATE_PHASE_LFO();
GET_CURRENT_ENV_LFO();
UPDATE_ENV();
assert(algo >= 0 && algo <= 7);
switch (algo) {
case 0:
DO_ALGO_0();
break;
case 1:
DO_ALGO_1();
break;
case 2:
DO_ALGO_2();
break;
case 3:
DO_ALGO_3();
break;
case 4:
DO_ALGO_4();
break;
case 5:
DO_ALGO_5();
break;
case 6:
DO_ALGO_6();
break;
case 7:
DO_ALGO_7();
break;
default:
break;
}
DO_OUTPUT();
}
}
/******************************************************
* Interpolated output *
*****************************************************/
template<int algo>
inline void Ym2612Private::T_Update_Chan_Int(channel_t *CH, int32_t *bufL, int32_t *bufR, int length)
{
// Check if the channel has reached the end of the update.
{
int not_end = (CH->_SLOT[S3].Ecnt - ENV_END);
// Special cases.
// Copied from Game_Music_Emu v0.5.2.
if (algo == 7)
not_end |= (CH->_SLOT[S0].Ecnt - ENV_END);
if (algo >= 5)
not_end |= (CH->_SLOT[S2].Ecnt - ENV_END);
if (algo >= 4)
not_end |= (CH->_SLOT[S1].Ecnt - ENV_END);
if (not_end == 0)
return;
}
// LOG_MSG(ym2612, LOG_MSG_LEVEL_DEBUG2,
// "Algo %d Int len = %d", algo, length);
int_cnt = state.Inter_Cnt;
for (int i = 0; i < length; i++) {
int in0, in1, in2, in3; // current phase calculation
int en0, en1, en2, en3; // current envelope calculation
GET_CURRENT_PHASE();
UPDATE_PHASE();
GET_CURRENT_ENV();
UPDATE_ENV();
assert(algo >= 0 && algo <= 7);
switch (algo) {
case 0:
DO_ALGO_0();
break;
case 1:
DO_ALGO_1();
break;
case 2:
DO_ALGO_2();
break;
case 3:
DO_ALGO_3();
break;
case 4:
DO_ALGO_4();
break;
case 5:
DO_ALGO_5();
break;
case 6:
DO_ALGO_6();
break;
case 7:
DO_ALGO_7();
break;
default:
break;
}
DO_OUTPUT_INT();
}
}
template<int algo>
inline void Ym2612Private::T_Update_Chan_LFO_Int(channel_t *CH, int32_t *bufL, int32_t *bufR, int length)
{
// Check if the channel has reached the end of the update.
{
int not_end = (CH->_SLOT[S3].Ecnt - ENV_END);
// Special cases.
// Copied from Game_Music_Emu v0.5.2.
if (algo == 7)
not_end |= (CH->_SLOT[S0].Ecnt - ENV_END);
if (algo >= 5)
not_end |= (CH->_SLOT[S2].Ecnt - ENV_END);
if (algo >= 4)
not_end |= (CH->_SLOT[S1].Ecnt - ENV_END);
if (not_end == 0)
return;
}
int_cnt = state.Inter_Cnt;
int env_LFO, freq_LFO;
// LOG_MSG(ym2612, LOG_MSG_LEVEL_DEBUG2,
// "Algo %d LFO Int len = %d", algo, length);
for (int i = 0; i < length; i++) {
int in0, in1, in2, in3; // current phase calculation
int en0, en1, en2, en3; // current envelope calculation
GET_CURRENT_PHASE();
UPDATE_PHASE_LFO();
GET_CURRENT_ENV_LFO();
UPDATE_ENV();
assert(algo >= 0 && algo <= 7);
switch (algo) {
case 0:
DO_ALGO_0();
break;
case 1:
DO_ALGO_1();
break;
case 2:
DO_ALGO_2();
break;
case 3:
DO_ALGO_3();
break;
case 4:
DO_ALGO_4();
break;
case 5:
DO_ALGO_5();
break;
case 6:
DO_ALGO_6();
break;
case 7:
DO_ALGO_7();
break;
default:
break;
}
DO_OUTPUT_INT();
}
}
/**
* Update Channel function.
* Replaces the UPDATE_CHAN function pointer table.
* NOTE: This will probably be slower than the function pointer table.
* TODO: Figure out how to optimize it!
*/
void Ym2612Private::Update_Chan(int algo_type, channel_t *CH, int32_t *bufL, int32_t *bufR, int length)
{
switch (algo_type & 0x1F) {
case 0x00: T_Update_Chan<0>(CH, bufL, bufR, length); break;
case 0x01: T_Update_Chan<1>(CH, bufL, bufR, length); break;
case 0x02: T_Update_Chan<2>(CH, bufL, bufR, length); break;
case 0x03: T_Update_Chan<3>(CH, bufL, bufR, length); break;
case 0x04: T_Update_Chan<4>(CH, bufL, bufR, length); break;
case 0x05: T_Update_Chan<5>(CH, bufL, bufR, length); break;
case 0x06: T_Update_Chan<6>(CH, bufL, bufR, length); break;
case 0x07: T_Update_Chan<7>(CH, bufL, bufR, length); break;
case 0x08: T_Update_Chan_LFO<0>(CH, bufL, bufR, length); break;
case 0x09: T_Update_Chan_LFO<1>(CH, bufL, bufR, length); break;
case 0x0A: T_Update_Chan_LFO<2>(CH, bufL, bufR, length); break;
case 0x0B: T_Update_Chan_LFO<3>(CH, bufL, bufR, length); break;
case 0x0C: T_Update_Chan_LFO<4>(CH, bufL, bufR, length); break;
case 0x0D: T_Update_Chan_LFO<5>(CH, bufL, bufR, length); break;
case 0x0E: T_Update_Chan_LFO<6>(CH, bufL, bufR, length); break;
case 0x0F: T_Update_Chan_LFO<7>(CH, bufL, bufR, length); break;
case 0x10: T_Update_Chan_Int<0>(CH, bufL, bufR, length); break;
case 0x11: T_Update_Chan_Int<1>(CH, bufL, bufR, length); break;
case 0x12: T_Update_Chan_Int<2>(CH, bufL, bufR, length); break;
case 0x13: T_Update_Chan_Int<3>(CH, bufL, bufR, length); break;
case 0x14: T_Update_Chan_Int<4>(CH, bufL, bufR, length); break;
case 0x15: T_Update_Chan_Int<5>(CH, bufL, bufR, length); break;
case 0x16: T_Update_Chan_Int<6>(CH, bufL, bufR, length); break;
case 0x17: T_Update_Chan_Int<7>(CH, bufL, bufR, length); break;
case 0x18: T_Update_Chan_LFO_Int<0>(CH, bufL, bufR, length); break;
case 0x19: T_Update_Chan_LFO_Int<1>(CH, bufL, bufR, length); break;
case 0x1A: T_Update_Chan_LFO_Int<2>(CH, bufL, bufR, length); break;
case 0x1B: T_Update_Chan_LFO_Int<3>(CH, bufL, bufR, length); break;
case 0x1C: T_Update_Chan_LFO_Int<4>(CH, bufL, bufR, length); break;
case 0x1D: T_Update_Chan_LFO_Int<5>(CH, bufL, bufR, length); break;
case 0x1E: T_Update_Chan_LFO_Int<6>(CH, bufL, bufR, length); break;
case 0x1F: T_Update_Chan_LFO_Int<7>(CH, bufL, bufR, length); break;
default:
break;
}
}
/***********************************************
* Public functions. *
***********************************************/
/** Ym2612 **/
Ym2612::Ym2612()
: d(new Ym2612Private(this))
{
// TODO: Some initialization should go here!
m_writeLen = 0;
m_enabled = true; // TODO: Make this customizable.
m_dacEnabled = true; // TODO: Make this customizable.
m_improved = true; // TODO: Make this customizable.
}
Ym2612::Ym2612(int clock, int rate)
: d(new Ym2612Private(this))
{
// TODO: Some initialization should go here!
m_writeLen = 0;
m_enabled = true; // TODO: Make this customizable.
m_dacEnabled = true; // TODO: Make this customizable.
m_improved = true; // TODO: Make this customizable.
reInit(clock, rate);
}
Ym2612::~Ym2612()
{
delete d;
}
/**
* (Re-)Initialize the YM2612.
* @param clock YM2612 clock frequency.
* @param rate Sound rate.
* @return 0 on success; non-zero on error.
*/
// Initialisation de l'émulateur YM2612
int Ym2612::reInit(int clock, int rate)
{
assert(rate > 0);
assert(clock > rate);
if (rate <= 0 || clock <= rate)
return -1;
// Clear the state struct.
memset(&d->state, 0, sizeof(d->state));
d->state.Clock = clock;
d->state.Rate = rate;
// 144 = 12 * (prescale * 2) = 12 * 6 * 2
// prescale set to 6 by default
d->state.Frequence = ((double)(d->state.Clock) / (double)(d->state.Rate)) / 144.0;
d->state.TimerBase = (int)(d->state.Frequence * 4096.0);
if (m_improved && (d->state.Frequence > 1.0)) {
d->state.Inter_Step = (unsigned int)((1.0 / d->state.Frequence) * (double)(0x4000));
d->state.Inter_Cnt = 0;
// We recalculate rate and frequence after interpolation
d->state.Rate = (int)(d->state.Clock / 144.0);
d->state.Frequence = 1.0;
} else {
// No interpolation.
d->state.Inter_Step = 0x4000;
d->state.Inter_Cnt = 0;
}
// LOG_MSG(ym2612, LOG_MSG_LEVEL_DEBUG2,
// "YM2612 frequency = %g, rate = %d, interp step = %.8X",
// d->state.Frequence, d->state.Rate, d->state.Inter_Step);
// Frequency Step table.
for (int i = 0; i < 2048; i++) {
double x = (double)(i) * d->state.Frequence;
#if ((SIN_LBITS + SIN_HBITS - (21 - 7)) < 0)
x /= (double) (1 << ((21 - 7) - SIN_LBITS - SIN_HBITS));
#else
x *= (double) (1 << (SIN_LBITS + SIN_HBITS - (21 - 7)));
#endif
x /= 2.0; // because MUL = value * 2
d->FINC_TAB[i] = (unsigned int)x;
}
// Attack and Decay Rate tables.
// Entries 0-3 are always 0.
for (int i = 0; i < 4; i++) {
d->AR_TAB[i] = 0;
d->DR_TAB[i] = 0;
}
// Attack and Decay Rate tables.
// Calculate entries 32-63.
for (int i = 0; i < 60; i++) {
double x = d->state.Frequence;
x *= 1.0 + ((i & 3) * 0.25); // bits 0-1 : x1.00, x1.25, x1.50, x1.75
x *= (double) (1 << ((i >> 2))); // bits 2-5 : shift bits (x2^0 - x2^15)
x *= (double) (d->ENV_LENGTH << ENV_LBITS); // on ajuste pour le tableau ENV_TAB
d->AR_TAB[i + 4] = (unsigned int) (x / d->AR_RATE);
d->DR_TAB[i + 4] = (unsigned int) (x / d->DR_RATE);
}
// Attack and Decay Rate tables.
// Entries 64-95 are copies of entry 63.
for (int i = 64; i < 96; i++) {
d->AR_TAB[i] = d->AR_TAB[63];
d->DR_TAB[i] = d->DR_TAB[63];
}
// Detune table.
for (int i = 0; i < 4; i++) {
for (int j = 0; j < 32; j++) {
double x;
#if ((SIN_LBITS + SIN_HBITS - 21) < 0)
x = (double)d->DT_DEF_TAB[i][j] * d->state.Frequence /
(double)(1 << (21 - SIN_LBITS - SIN_HBITS));
#else
x = (double)d->DT_DEF_TAB[i][j] * d->state.Frequence *
(double)(1 << (SIN_LBITS + SIN_HBITS - 21));
#endif
d->DT_TAB[i + 0][j] = (int) x;
d->DT_TAB[i + 4][j] = (int) -x;
}
}
// LFO step table.
// TODO: Move to a static class variable?
static const double LFO_BITS[8] = {
3.98, 5.56, 6.02, 6.37, 6.88, 9.63, 48.1, 72.2
};
double j = (d->state.Rate * d->state.Inter_Step) / 0x4000;
for (int i = 0; i < 8; i++) {
d->LFO_INC_TAB[i] = (unsigned int) (LFO_BITS[i] * (double) (1 << (LFO_HBITS + LFO_LBITS)) / j);
}
// Reset the YM2612.
reset();
return 0;
}
void Ym2612::write_pan(int channel, int data)
{
d->state.CHANNEL[channel].PANVolumeL = panlawtable[data & 0x7F];
d->state.CHANNEL[channel].PANVolumeR = panlawtable[0x7F - (data & 0x7F)];
}
/**
* Reset the YM2612.
*/
void Ym2612::reset(void)
{
// LOG_MSG(ym2612, LOG_MSG_LEVEL_DEBUG1,
// "Starting reseting YM2612 ...");
d->state.LFOcnt = 0;
d->state.TimerA = 0;
d->state.TimerAL = 0;
d->state.TimerAcnt = 0;
d->state.TimerB = 0;
d->state.TimerBL = 0;
d->state.TimerBcnt = 0;
d->state.DAC = 0;
d->state.DACdata = 0;
d->state.status = 0;
d->state.OPNAadr = 0;
d->state.OPNBadr = 0;
d->state.Inter_Cnt = 0;
for (int i = 0; i < 6; i++) {
d->state.CHANNEL[i].Old_OUTd = 0;
d->state.CHANNEL[i].OUTd = 0;
d->state.CHANNEL[i].LEFT = 0xFFFFFFFF;
d->state.CHANNEL[i].RIGHT = 0xFFFFFFFF;
d->state.CHANNEL[i].ALGO = 0;;
d->state.CHANNEL[i].FB = 31;
d->state.CHANNEL[i].FMS = 0;
d->state.CHANNEL[i].AMS = 0;
d->state.CHANNEL[i].PANVolumeL = 46340;
d->state.CHANNEL[i].PANVolumeR = 46340;
for (int j = 0; j < 4; j++) {
d->state.CHANNEL[i].S0_OUT[j] = 0;
d->state.CHANNEL[i].FNUM[j] = 0;
d->state.CHANNEL[i].FOCT[j] = 0;
d->state.CHANNEL[i].KC[j] = 0;
d->state.CHANNEL[i]._SLOT[j].Fcnt = 0;
d->state.CHANNEL[i]._SLOT[j].Finc = 0;
d->state.CHANNEL[i]._SLOT[j].Ecnt = d->ENV_END; // Put it at the end of Decay phase...
d->state.CHANNEL[i]._SLOT[j].Einc = 0;
d->state.CHANNEL[i]._SLOT[j].Ecmp = 0;
d->state.CHANNEL[i]._SLOT[j].Ecurp = d->RELEASE;
d->state.CHANNEL[i]._SLOT[j].ChgEnM = 0;
}
}
// Initialize registers to 0xFF.
memset(d->state.REG, 0xFF, sizeof(d->state.REG));
// Initialize other registers to 0xC0.
for (int i = 0xB6; i >= 0xB4; i--) {
this->write(0, (uint8_t)i);
this->write(2, (uint8_t)i);
this->write(1, 0xC0);
this->write(3, 0xC0);
}
// Initialize more registers to 0x00.
for (int i = 0xB2; i >= 0x22; i--) {
this->write(0, (uint8_t)i);
this->write(2, (uint8_t)i);
this->write(1, 0x00);
this->write(3, 0x00);
}
// Initialize DAC to 0x80. (silence)
this->write(0, 0x2A);
this->write(1, 0x80);
// LOG_MSG(ym2612, LOG_MSG_LEVEL_DEBUG1,
// "Finishing reseting YM2612 ...");
}
/**
* Read the YM2612 status register.
* @return YM2612 status register.
*/
uint8_t Ym2612::read(void) const
{
#if 0
static int cnt = 0;
if (cnt++ == 50)
{
cnt = 0;
return YM2612.Status;
}
else return YM2612.Status | 0x80;
#endif
/**
* READ DATA is the same for all four addresses.
* Format: [BUSY X X X X X OVRA OVRB]
* BUSY: If 1, YM2612 is busy and cannot accept new data.
* OVRA: If 1, timer A has overflowed.
* OVRB: If 1, timer B has overflowed.
*/
return (uint8_t)d->state.status;
}
/**
* Write to a YM2612 register.
* @param address Address.
* @param data Data.
* @return 0 on success; non-zero on error. (TODO: This isn't used by anything!)
*/
int Ym2612::write(unsigned int address, uint8_t data)
{
/**
* Possible addresses:
* - 0: Bank 0 register number.
* - 1: Bank 0 data.
* - 2: Bank 1 register number.
* - 3: Bank 1 data.
*/
int reg_num;
switch (address & 0x03) {
case 0:
d->state.OPNAadr = data;
break;
case 1:
// Trivial optimization for DAC.
if (d->state.OPNAadr == 0x2A) {
d->state.DACdata = ((int)data - 0x80) << 7;
return 0;
}
reg_num = d->state.OPNAadr & 0xF0;
if (reg_num >= 0x30) {
if (d->state.REG[0][d->state.OPNAadr] == data) {
// Don't bother doing anything if the
// register has the same value.
// TODO: Is this correct?
return 2;
}
d->state.REG[0][d->state.OPNAadr] = data;
if (reg_num < 0xA0) {
d->SLOT_SET(d->state.OPNAadr, data);
} else {
d->CHANNEL_SET(d->state.OPNAadr, data);
}
} else {
// YM2612 control registers.
d->state.REG[0][d->state.OPNAadr] = data;
/* TODO: Reimplement GYM dumping support in LibGens.
if ((GYM_Dumping) &&
((d->state.OPNAadr == 0x22) ||
(d->state.OPNAadr == 0x27) ||
(d->state.OPNAadr == 0x28)))
{
gym_dump_update(1, (uint8_t)d->state.OPNAadr, data);
}
*/
d->YM_SET(d->state.OPNAadr, data);
}
break;
case 2:
d->state.OPNBadr = data;
break;
case 3:
reg_num = d->state.OPNBadr & 0xF0;
if (reg_num >= 0x30) {
if (d->state.REG[1][d->state.OPNBadr] == data) {
// Don't bother doing anything if the
// register has the same value.
// TODO: Is this correct?
return 2;
}
d->state.REG[1][d->state.OPNBadr] = data;
/* TODO: Reimplement GYM dumping support in LibGens.
if (GYM_Dumping)
gym_dump_update(2, (uint8_t)d->state.OPNBadr, data);
*/
if (reg_num < 0xA0) {
d->SLOT_SET(d->state.OPNBadr + 0x100, data);
} else {
d->CHANNEL_SET(d->state.OPNBadr + 0x100, data);
}
} else {
// Invalid register.
// TODO: Save the value anyway?
return 1;
}
break;
}
return 0;
}
/**
* Update the YM2612 audio output.
* @param bufL Left audio buffer. (16-bit; int32_t is used for saturation.)
* @param bufR Right audio buffer. (16-bit; int32_t is used for saturation.)
* @param length Length to write.
*/
void Ym2612::update(int32_t *bufL, int32_t *bufR, int length)
{
// LOG_MSG(ym2612, LOG_MSG_LEVEL_DEBUG4,
// "Starting generating sound...");
// Mise à jour des pas des compteurs-fréquences s'ils ont été modifiés
if (d->state.CHANNEL[0]._SLOT[0].Finc == -1) {
d->CALC_FINC_CH(&d->state.CHANNEL[0]);
}
if (d->state.CHANNEL[1]._SLOT[0].Finc == -1) {
d->CALC_FINC_CH(&d->state.CHANNEL[1]);
}
if (d->state.CHANNEL[2]._SLOT[0].Finc == -1) {
if (d->state.Mode & 0x40) {
d->CALC_FINC_SL(&(d->state.CHANNEL[2]._SLOT[d->S0]),
d->FINC_TAB[d->state.CHANNEL[2].FNUM[2]] >> (7 - d->state.CHANNEL[2].FOCT[2]),
d->state.CHANNEL[2].KC[2]);
d->CALC_FINC_SL(&(d->state.CHANNEL[2]._SLOT[d->S1]),
d->FINC_TAB[d->state.CHANNEL[2].FNUM[3]] >> (7 - d->state.CHANNEL[2].FOCT[3]),
d->state.CHANNEL[2].KC[3]);
d->CALC_FINC_SL(&(d->state.CHANNEL[2]._SLOT[d->S2]),
d->FINC_TAB[d->state.CHANNEL[2].FNUM[1]] >> (7 - d->state.CHANNEL[2].FOCT[1]),
d->state.CHANNEL[2].KC[1]);
d->CALC_FINC_SL(&(d->state.CHANNEL[2]._SLOT[d->S3]),
d->FINC_TAB[d->state.CHANNEL[2].FNUM[0]] >> (7 - d->state.CHANNEL[2].FOCT[0]),
d->state.CHANNEL[2].KC[0]);
} else {
d->CALC_FINC_CH(&d->state.CHANNEL[2]);
}
}
if (d->state.CHANNEL[3]._SLOT[0].Finc == -1) {
d->CALC_FINC_CH(&d->state.CHANNEL[3]);
}
if (d->state.CHANNEL[4]._SLOT[0].Finc == -1) {
d->CALC_FINC_CH(&d->state.CHANNEL[4]);
}
if (d->state.CHANNEL[5]._SLOT[0].Finc == -1) {
d->CALC_FINC_CH(&d->state.CHANNEL[5]);
}
/*
d->CALC_FINC_CH(&d->state.CHANNEL[0]);
d->CALC_FINC_CH(&d->state.CHANNEL[1]);
if (d->state.Mode & 0x40) {
d->CALC_FINC_SL(&(d->state.CHANNEL[2].SLOT[0]), d->FINC_TAB[d->state.CHANNEL[2].FNUM[2]] >> (7 - d->state.CHANNEL[2].FOCT[2]), YM2612.CHANNEL[2].KC[2]);
d->CALC_FINC_SL(&(d->state.CHANNEL[2].SLOT[1]), d->FINC_TAB[d->state.CHANNEL[2].FNUM[3]] >> (7 - d->state.CHANNEL[2].FOCT[3]), YM2612.CHANNEL[2].KC[3]);
d->CALC_FINC_SL(&(d->state.CHANNEL[2].SLOT[2]), d->FINC_TAB[d->state.CHANNEL[2].FNUM[1]] >> (7 - d->state.CHANNEL[2].FOCT[1]), YM2612.CHANNEL[2].KC[1]);
d->CALC_FINC_SL(&(d->state.CHANNEL[2].SLOT[3]), d->FINC_TAB[d->state.CHANNEL[2].FNUM[0]] >> (7 - d->state.CHANNEL[2].FOCT[0]), d->state.CHANNEL[2].KC[0]);
} else {
d->CALC_FINC_CH(&d->state.CHANNEL[2]);
}
d->CALC_FINC_CH(&d->state.CHANNEL[3]);
d->CALC_FINC_CH(&d->state.CHANNEL[4]);
d->CALC_FINC_CH(&d->state.CHANNEL[5]);
*/
// Determine the algorithm type.
int algo_type;
if (d->state.Inter_Step & 0x04000) {
algo_type = 0;
} else {
algo_type = 16;
}
if (d->state.LFOinc) {
// Precalculate LFO wav
for (int i = 0; i < length; i++) {
int j = ((d->state.LFOcnt += d->state.LFOinc) >> LFO_LBITS) & d->LFO_MASK;
d->LFO_ENV_UP[i] = d->LFO_ENV_TAB[j];
d->LFO_FREQ_UP[i] = d->LFO_FREQ_TAB[j];
// LOG_MSG(ym2612, LOG_MSG_LEVEL_DEBUG4,
// "LFO_ENV_UP[%d] = %d LFO_FREQ_UP[%d] = %d",
// i, d->LFO_ENV_UP[i], i, d->LFO_FREQ_UP[i]);
}
algo_type |= 8;
}
d->Update_Chan((d->state.CHANNEL[0].ALGO + algo_type), &(d->state.CHANNEL[0]), bufL, bufR, length);
d->Update_Chan((d->state.CHANNEL[1].ALGO + algo_type), &(d->state.CHANNEL[1]), bufL, bufR, length);
d->Update_Chan((d->state.CHANNEL[2].ALGO + algo_type), &(d->state.CHANNEL[2]), bufL, bufR, length);
d->Update_Chan((d->state.CHANNEL[3].ALGO + algo_type), &(d->state.CHANNEL[3]), bufL, bufR, length);
d->Update_Chan((d->state.CHANNEL[4].ALGO + algo_type), &(d->state.CHANNEL[4]), bufL, bufR, length);
if (!(d->state.DAC)) {
// Update channel 6 only if DAC is disabled.
d->Update_Chan((d->state.CHANNEL[5].ALGO + algo_type), &(d->state.CHANNEL[5]), bufL, bufR, length);
}
d->state.Inter_Cnt = d->int_cnt;
// LOG_MSG(ym2612, LOG_MSG_LEVEL_DEBUG4,
// "Finishing generating sound...");
}
/**
* Update the YM2612 DAC output and timers.
* @param bufL Left audio buffer. (16-bit; int32_t is used for saturation.)
* @param bufR Right audio buffer. (16-bit; int32_t is used for saturation.)
* @param length Length of the output buffer.
*/
void Ym2612::updateDacAndTimers(int32_t *bufL, int32_t *bufR, int length)
{
// Update DAC.
if (d->state.DAC && d->state.DACdata && m_dacEnabled) {
for (int i = 0; i < length; i++) {
bufL[i] += (d->state.DACdata & d->state.CHANNEL[5].LEFT);
bufR[i] += (d->state.DACdata & d->state.CHANNEL[5].RIGHT);
}
}
// Update timers.
int i = d->state.TimerBase * length;
if (d->state.Mode & 1) {
// Timer A is ON.
//if ((YM2612.TimerAcnt -= 14073) <= 0) // 13879=NTSC (old: 14475=NTSC 14586=PAL)
if ((d->state.TimerAcnt -= i) <= 0) {
d->state.status |= (d->state.Mode & 0x04) >> 2;
d->state.TimerAcnt += d->state.TimerAL;
// LOG_MSG(ym2612, LOG_MSG_LEVEL_DEBUG1,
// "Counter A overflow");
if (d->state.Mode & 0x80) {
d->CSM_Key_Control();
}
}
}
if (d->state.Mode & 2) {
// Timer B is ON.
//if ((d->state.TimerBcnt -= 14073) <= 0) // 13879=NTSC (old: 14475=NTSC 14586=PAL)
if ((d->state.TimerBcnt -= i) <= 0) {
d->state.status |= (d->state.Mode & 0x08) >> 2;
d->state.TimerBcnt += d->state.TimerBL;
// LOG_MSG(ym2612, LOG_MSG_LEVEL_DEBUG1,
// "Counter B overflow");
}
}
}
/**
* Update the YM2612 buffer.
*/
void Ym2612::specialUpdate(void)
{
if (!(m_writeLen > 0 && m_enabled))
return;
// Update the sound buffer.
update(m_bufPtrL, m_bufPtrR, m_writeLen);
m_writeLen = 0;
#if 0
// TODO: Don't use EmuContext here...
int line_num = 1;
EmuContext *context = EmuContext::Instance();
if (context != nullptr)
line_num = (context->m_vdp->VDP_Lines.currentLine + 1);
// Determine the new starting position.
int writePos = SoundMgr::GetWritePos(line_num);
// Update the PSG buffer pointers.
m_bufPtrL = &SoundMgr::ms_SegBufL[writePos];
m_bufPtrR = &SoundMgr::ms_SegBufR[writePos];
#endif
}
/**
* Get the value of a register.
* @param regID Register ID.
* @return Value of the register.
*/
int Ym2612::getReg(int regID) const
{
if (regID < 0 || regID >= 0x200)
return -1;
return d->state.REG[(regID >> 8) & 1][regID & 0xFF];
}
/**
* Reset the YM2612 buffer pointers.
*/
void Ym2612::resetBufferPtrs(int32_t *bufPtrL, int32_t *bufPtrR)
{
m_bufPtrL = bufPtrL;
m_bufPtrR = bufPtrR;
}
/* end */
}
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