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raze-gles/libraries/game-music-emu/gme/Ym2612_Nuked.cpp
Christoph Oelckers 718112a8fe - added external libraries for music format playback and decompression from GZDoom. 
Currently none of these is being used, but eventually they will, once more code gets ported over.
So it's better to have them right away and avoid editing the project file too much, only to revert that later.
2019-09-22 08:59:48 +02:00

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// Game_Music_Emu https://bitbucket.org/mpyne/game-music-emu/
// Based on Nuked OPN2 ym3438.c and ym3438.h
#include "Ym2612_Nuked.h"
/*
* Copyright (C) 2017 Alexey Khokholov (Nuke.YKT)
*
* This library is free software; you can redistribute it and/or
* modify it under the terms of the GNU Lesser General Public
* License as published by the Free Software Foundation; either
* version 2.1 of the License, or (at your option) any later version.
*
* This library 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
* Lesser General Public License for more details.
*
* You should have received a copy of the GNU Lesser General Public
* License along with this library; if not, write to the Free Software
* Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA
*
*
* Nuked OPN2(Yamaha YM3438) emulator.
* Thanks:
* Silicon Pr0n:
* Yamaha YM3438 decap and die shot(digshadow).
* OPLx decapsulated(Matthew Gambrell, Olli Niemitalo):
* OPL2 ROMs.
*
* version: 1.0.7
*/
#include <stdint.h>
#include <string.h>
typedef uintptr_t Bitu;
typedef intptr_t Bits;
typedef uint64_t Bit64u;
typedef int64_t Bit64s;
typedef uint32_t Bit32u;
typedef int32_t Bit32s;
typedef uint16_t Bit16u;
typedef int16_t Bit16s;
typedef uint8_t Bit8u;
typedef int8_t Bit8s;
namespace Ym2612_NukedImpl
{
/*EXTRA*/
#define RSM_FRAC 10
#define OPN_WRITEBUF_SIZE 2048
#define OPN_WRITEBUF_DELAY 15
enum {
ym3438_type_discrete = 0, /* Discrete YM3438 (Teradrive) */
ym3438_type_asic = 1, /* ASIC YM3438 (MD1 VA7, MD2, MD3, etc) */
ym3438_type_ym2612 = 2 /* YM2612 (MD1, MD2 VA2) */
};
/*EXTRA*/
typedef struct _opn2_writebuf {
Bit64u time;
Bit8u port;
Bit8u data;
Bit8u reserved[6];
} opn2_writebuf;
typedef struct
{
Bit32u cycles;
Bit32u channel;
Bit16s mol, mor;
/* IO */
Bit16u write_data;
Bit8u write_a;
Bit8u write_d;
Bit8u write_a_en;
Bit8u write_d_en;
Bit8u write_busy;
Bit8u write_busy_cnt;
Bit8u write_fm_address;
Bit8u write_fm_data;
Bit8u write_fm_mode_a;
Bit16u address;
Bit8u data;
Bit8u pin_test_in;
Bit8u pin_irq;
Bit8u busy;
/* LFO */
Bit8u lfo_en;
Bit8u lfo_freq;
Bit8u lfo_pm;
Bit8u lfo_am;
Bit8u lfo_cnt;
Bit8u lfo_inc;
Bit8u lfo_quotient;
/* Phase generator */
Bit16u pg_fnum;
Bit8u pg_block;
Bit8u pg_kcode;
Bit32u pg_inc[24];
Bit32u pg_phase[24];
Bit8u pg_reset[24];
Bit32u pg_read;
/* Envelope generator */
Bit8u eg_cycle;
Bit8u eg_cycle_stop;
Bit8u eg_shift;
Bit8u eg_shift_lock;
Bit8u eg_timer_low_lock;
Bit16u eg_timer;
Bit8u eg_timer_inc;
Bit16u eg_quotient;
Bit8u eg_custom_timer;
Bit8u eg_rate;
Bit8u eg_ksv;
Bit8u eg_inc;
Bit8u eg_ratemax;
Bit8u eg_sl[2];
Bit8u eg_lfo_am;
Bit8u eg_tl[2];
Bit8u eg_state[24];
Bit16u eg_level[24];
Bit16u eg_out[24];
Bit8u eg_kon[24];
Bit8u eg_kon_csm[24];
Bit8u eg_kon_latch[24];
Bit8u eg_csm_mode[24];
Bit8u eg_ssg_enable[24];
Bit8u eg_ssg_pgrst_latch[24];
Bit8u eg_ssg_repeat_latch[24];
Bit8u eg_ssg_hold_up_latch[24];
Bit8u eg_ssg_dir[24];
Bit8u eg_ssg_inv[24];
Bit32u eg_read[2];
Bit8u eg_read_inc;
/* FM */
Bit16s fm_op1[6][2];
Bit16s fm_op2[6];
Bit16s fm_out[24];
Bit16u fm_mod[24];
/* Channel */
Bit16s ch_acc[6];
Bit16s ch_out[6];
Bit16s ch_lock;
Bit8u ch_lock_l;
Bit8u ch_lock_r;
Bit16s ch_read;
/* Timer */
Bit16u timer_a_cnt;
Bit16u timer_a_reg;
Bit8u timer_a_load_lock;
Bit8u timer_a_load;
Bit8u timer_a_enable;
Bit8u timer_a_reset;
Bit8u timer_a_load_latch;
Bit8u timer_a_overflow_flag;
Bit8u timer_a_overflow;
Bit16u timer_b_cnt;
Bit8u timer_b_subcnt;
Bit16u timer_b_reg;
Bit8u timer_b_load_lock;
Bit8u timer_b_load;
Bit8u timer_b_enable;
Bit8u timer_b_reset;
Bit8u timer_b_load_latch;
Bit8u timer_b_overflow_flag;
Bit8u timer_b_overflow;
/* Register set */
Bit8u mode_test_21[8];
Bit8u mode_test_2c[8];
Bit8u mode_ch3;
Bit8u mode_kon_channel;
Bit8u mode_kon_operator[4];
Bit8u mode_kon[24];
Bit8u mode_csm;
Bit8u mode_kon_csm;
Bit8u dacen;
Bit16s dacdata;
Bit8u ks[24];
Bit8u ar[24];
Bit8u sr[24];
Bit8u dt[24];
Bit8u multi[24];
Bit8u sl[24];
Bit8u rr[24];
Bit8u dr[24];
Bit8u am[24];
Bit8u tl[24];
Bit8u ssg_eg[24];
Bit16u fnum[6];
Bit8u block[6];
Bit8u kcode[6];
Bit16u fnum_3ch[6];
Bit8u block_3ch[6];
Bit8u kcode_3ch[6];
Bit8u reg_a4;
Bit8u reg_ac;
Bit8u connect[6];
Bit8u fb[6];
Bit8u pan_l[6], pan_r[6];
Bit8u ams[6];
Bit8u pms[6];
/*EXTRA*/
Bit32u mute[7];
Bit32s rateratio;
Bit32s samplecnt;
Bit32s oldsamples[2];
Bit32s samples[2];
Bit64u writebuf_samplecnt;
Bit32u writebuf_cur;
Bit32u writebuf_last;
Bit64u writebuf_lasttime;
opn2_writebuf writebuf[OPN_WRITEBUF_SIZE];
} ym3438_t;
/* EXTRA, original was "void OPN2_Reset(ym3438_t *chip)" */
void OPN2_Reset(ym3438_t *chip, Bit32u rate, Bit32u clock);
void OPN2_SetChipType(Bit32u type);
void OPN2_Clock(ym3438_t *chip, Bit16s *buffer);
void OPN2_Write(ym3438_t *chip, Bit32u port, Bit8u data);
void OPN2_SetTestPin(ym3438_t *chip, Bit32u value);
Bit32u OPN2_ReadTestPin(ym3438_t *chip);
Bit32u OPN2_ReadIRQPin(ym3438_t *chip);
Bit8u OPN2_Read(ym3438_t *chip, Bit32u port);
/*EXTRA*/
void OPN2_WriteBuffered(ym3438_t *chip, Bit32u port, Bit8u data);
void OPN2_Generate(ym3438_t *chip, Bit16s *buf);
void OPN2_GenerateResampled(ym3438_t *chip, Bit16s *buf);
void OPN2_GenerateStream(ym3438_t *chip, Bit16s *output, Bit32u numsamples);
void OPN2_GenerateStreamMix(ym3438_t *chip, Bit16s *output, Bit32u numsamples);
void OPN2_SetOptions(Bit8u flags);
void OPN2_SetMute(ym3438_t *chip, Bit32u mute);
enum {
eg_num_attack = 0,
eg_num_decay = 1,
eg_num_sustain = 2,
eg_num_release = 3
};
/* logsin table */
static const Bit16u logsinrom[256] = {
0x859, 0x6c3, 0x607, 0x58b, 0x52e, 0x4e4, 0x4a6, 0x471,
0x443, 0x41a, 0x3f5, 0x3d3, 0x3b5, 0x398, 0x37e, 0x365,
0x34e, 0x339, 0x324, 0x311, 0x2ff, 0x2ed, 0x2dc, 0x2cd,
0x2bd, 0x2af, 0x2a0, 0x293, 0x286, 0x279, 0x26d, 0x261,
0x256, 0x24b, 0x240, 0x236, 0x22c, 0x222, 0x218, 0x20f,
0x206, 0x1fd, 0x1f5, 0x1ec, 0x1e4, 0x1dc, 0x1d4, 0x1cd,
0x1c5, 0x1be, 0x1b7, 0x1b0, 0x1a9, 0x1a2, 0x19b, 0x195,
0x18f, 0x188, 0x182, 0x17c, 0x177, 0x171, 0x16b, 0x166,
0x160, 0x15b, 0x155, 0x150, 0x14b, 0x146, 0x141, 0x13c,
0x137, 0x133, 0x12e, 0x129, 0x125, 0x121, 0x11c, 0x118,
0x114, 0x10f, 0x10b, 0x107, 0x103, 0x0ff, 0x0fb, 0x0f8,
0x0f4, 0x0f0, 0x0ec, 0x0e9, 0x0e5, 0x0e2, 0x0de, 0x0db,
0x0d7, 0x0d4, 0x0d1, 0x0cd, 0x0ca, 0x0c7, 0x0c4, 0x0c1,
0x0be, 0x0bb, 0x0b8, 0x0b5, 0x0b2, 0x0af, 0x0ac, 0x0a9,
0x0a7, 0x0a4, 0x0a1, 0x09f, 0x09c, 0x099, 0x097, 0x094,
0x092, 0x08f, 0x08d, 0x08a, 0x088, 0x086, 0x083, 0x081,
0x07f, 0x07d, 0x07a, 0x078, 0x076, 0x074, 0x072, 0x070,
0x06e, 0x06c, 0x06a, 0x068, 0x066, 0x064, 0x062, 0x060,
0x05e, 0x05c, 0x05b, 0x059, 0x057, 0x055, 0x053, 0x052,
0x050, 0x04e, 0x04d, 0x04b, 0x04a, 0x048, 0x046, 0x045,
0x043, 0x042, 0x040, 0x03f, 0x03e, 0x03c, 0x03b, 0x039,
0x038, 0x037, 0x035, 0x034, 0x033, 0x031, 0x030, 0x02f,
0x02e, 0x02d, 0x02b, 0x02a, 0x029, 0x028, 0x027, 0x026,
0x025, 0x024, 0x023, 0x022, 0x021, 0x020, 0x01f, 0x01e,
0x01d, 0x01c, 0x01b, 0x01a, 0x019, 0x018, 0x017, 0x017,
0x016, 0x015, 0x014, 0x014, 0x013, 0x012, 0x011, 0x011,
0x010, 0x00f, 0x00f, 0x00e, 0x00d, 0x00d, 0x00c, 0x00c,
0x00b, 0x00a, 0x00a, 0x009, 0x009, 0x008, 0x008, 0x007,
0x007, 0x007, 0x006, 0x006, 0x005, 0x005, 0x005, 0x004,
0x004, 0x004, 0x003, 0x003, 0x003, 0x002, 0x002, 0x002,
0x002, 0x001, 0x001, 0x001, 0x001, 0x001, 0x001, 0x001,
0x000, 0x000, 0x000, 0x000, 0x000, 0x000, 0x000, 0x000
};
/* exp table */
static const Bit16u exprom[256] = {
0x000, 0x003, 0x006, 0x008, 0x00b, 0x00e, 0x011, 0x014,
0x016, 0x019, 0x01c, 0x01f, 0x022, 0x025, 0x028, 0x02a,
0x02d, 0x030, 0x033, 0x036, 0x039, 0x03c, 0x03f, 0x042,
0x045, 0x048, 0x04b, 0x04e, 0x051, 0x054, 0x057, 0x05a,
0x05d, 0x060, 0x063, 0x066, 0x069, 0x06c, 0x06f, 0x072,
0x075, 0x078, 0x07b, 0x07e, 0x082, 0x085, 0x088, 0x08b,
0x08e, 0x091, 0x094, 0x098, 0x09b, 0x09e, 0x0a1, 0x0a4,
0x0a8, 0x0ab, 0x0ae, 0x0b1, 0x0b5, 0x0b8, 0x0bb, 0x0be,
0x0c2, 0x0c5, 0x0c8, 0x0cc, 0x0cf, 0x0d2, 0x0d6, 0x0d9,
0x0dc, 0x0e0, 0x0e3, 0x0e7, 0x0ea, 0x0ed, 0x0f1, 0x0f4,
0x0f8, 0x0fb, 0x0ff, 0x102, 0x106, 0x109, 0x10c, 0x110,
0x114, 0x117, 0x11b, 0x11e, 0x122, 0x125, 0x129, 0x12c,
0x130, 0x134, 0x137, 0x13b, 0x13e, 0x142, 0x146, 0x149,
0x14d, 0x151, 0x154, 0x158, 0x15c, 0x160, 0x163, 0x167,
0x16b, 0x16f, 0x172, 0x176, 0x17a, 0x17e, 0x181, 0x185,
0x189, 0x18d, 0x191, 0x195, 0x199, 0x19c, 0x1a0, 0x1a4,
0x1a8, 0x1ac, 0x1b0, 0x1b4, 0x1b8, 0x1bc, 0x1c0, 0x1c4,
0x1c8, 0x1cc, 0x1d0, 0x1d4, 0x1d8, 0x1dc, 0x1e0, 0x1e4,
0x1e8, 0x1ec, 0x1f0, 0x1f5, 0x1f9, 0x1fd, 0x201, 0x205,
0x209, 0x20e, 0x212, 0x216, 0x21a, 0x21e, 0x223, 0x227,
0x22b, 0x230, 0x234, 0x238, 0x23c, 0x241, 0x245, 0x249,
0x24e, 0x252, 0x257, 0x25b, 0x25f, 0x264, 0x268, 0x26d,
0x271, 0x276, 0x27a, 0x27f, 0x283, 0x288, 0x28c, 0x291,
0x295, 0x29a, 0x29e, 0x2a3, 0x2a8, 0x2ac, 0x2b1, 0x2b5,
0x2ba, 0x2bf, 0x2c4, 0x2c8, 0x2cd, 0x2d2, 0x2d6, 0x2db,
0x2e0, 0x2e5, 0x2e9, 0x2ee, 0x2f3, 0x2f8, 0x2fd, 0x302,
0x306, 0x30b, 0x310, 0x315, 0x31a, 0x31f, 0x324, 0x329,
0x32e, 0x333, 0x338, 0x33d, 0x342, 0x347, 0x34c, 0x351,
0x356, 0x35b, 0x360, 0x365, 0x36a, 0x370, 0x375, 0x37a,
0x37f, 0x384, 0x38a, 0x38f, 0x394, 0x399, 0x39f, 0x3a4,
0x3a9, 0x3ae, 0x3b4, 0x3b9, 0x3bf, 0x3c4, 0x3c9, 0x3cf,
0x3d4, 0x3da, 0x3df, 0x3e4, 0x3ea, 0x3ef, 0x3f5, 0x3fa
};
/* Note table */
static const Bit32u fn_note[16] = {
0, 0, 0, 0, 0, 0, 0, 1, 2, 3, 3, 3, 3, 3, 3, 3
};
/* Envelope generator */
static const Bit32u eg_stephi[4][4] = {
{ 0, 0, 0, 0 },
{ 1, 0, 0, 0 },
{ 1, 0, 1, 0 },
{ 1, 1, 1, 0 }
};
static const Bit8u eg_am_shift[4] = {
7, 3, 1, 0
};
/* Phase generator */
static const Bit32u pg_detune[8] = { 16, 17, 19, 20, 22, 24, 27, 29 };
static const Bit32u pg_lfo_sh1[8][8] = {
{ 7, 7, 7, 7, 7, 7, 7, 7 },
{ 7, 7, 7, 7, 7, 7, 7, 7 },
{ 7, 7, 7, 7, 7, 7, 1, 1 },
{ 7, 7, 7, 7, 1, 1, 1, 1 },
{ 7, 7, 7, 1, 1, 1, 1, 0 },
{ 7, 7, 1, 1, 0, 0, 0, 0 },
{ 7, 7, 1, 1, 0, 0, 0, 0 },
{ 7, 7, 1, 1, 0, 0, 0, 0 }
};
static const Bit32u pg_lfo_sh2[8][8] = {
{ 7, 7, 7, 7, 7, 7, 7, 7 },
{ 7, 7, 7, 7, 2, 2, 2, 2 },
{ 7, 7, 7, 2, 2, 2, 7, 7 },
{ 7, 7, 2, 2, 7, 7, 2, 2 },
{ 7, 7, 2, 7, 7, 7, 2, 7 },
{ 7, 7, 7, 2, 7, 7, 2, 1 },
{ 7, 7, 7, 2, 7, 7, 2, 1 },
{ 7, 7, 7, 2, 7, 7, 2, 1 }
};
/* Address decoder */
static const Bit32u op_offset[12] = {
0x000, /* Ch1 OP1/OP2 */
0x001, /* Ch2 OP1/OP2 */
0x002, /* Ch3 OP1/OP2 */
0x100, /* Ch4 OP1/OP2 */
0x101, /* Ch5 OP1/OP2 */
0x102, /* Ch6 OP1/OP2 */
0x004, /* Ch1 OP3/OP4 */
0x005, /* Ch2 OP3/OP4 */
0x006, /* Ch3 OP3/OP4 */
0x104, /* Ch4 OP3/OP4 */
0x105, /* Ch5 OP3/OP4 */
0x106 /* Ch6 OP3/OP4 */
};
static const Bit32u ch_offset[6] = {
0x000, /* Ch1 */
0x001, /* Ch2 */
0x002, /* Ch3 */
0x100, /* Ch4 */
0x101, /* Ch5 */
0x102 /* Ch6 */
};
/* LFO */
static const Bit32u lfo_cycles[8] = {
108, 77, 71, 67, 62, 44, 8, 5
};
/* FM algorithm */
static const Bit32u fm_algorithm[4][6][8] = {
{
{ 1, 1, 1, 1, 1, 1, 1, 1 }, /* OP1_0 */
{ 1, 1, 1, 1, 1, 1, 1, 1 }, /* OP1_1 */
{ 0, 0, 0, 0, 0, 0, 0, 0 }, /* OP2 */
{ 0, 0, 0, 0, 0, 0, 0, 0 }, /* Last operator */
{ 0, 0, 0, 0, 0, 0, 0, 0 }, /* Last operator */
{ 0, 0, 0, 0, 0, 0, 0, 1 } /* Out */
},
{
{ 0, 1, 0, 0, 0, 1, 0, 0 }, /* OP1_0 */
{ 0, 0, 0, 0, 0, 0, 0, 0 }, /* OP1_1 */
{ 1, 1, 1, 0, 0, 0, 0, 0 }, /* OP2 */
{ 0, 0, 0, 0, 0, 0, 0, 0 }, /* Last operator */
{ 0, 0, 0, 0, 0, 0, 0, 0 }, /* Last operator */
{ 0, 0, 0, 0, 0, 1, 1, 1 } /* Out */
},
{
{ 0, 0, 0, 0, 0, 0, 0, 0 }, /* OP1_0 */
{ 0, 0, 0, 0, 0, 0, 0, 0 }, /* OP1_1 */
{ 0, 0, 0, 0, 0, 0, 0, 0 }, /* OP2 */
{ 1, 0, 0, 1, 1, 1, 1, 0 }, /* Last operator */
{ 0, 0, 0, 0, 0, 0, 0, 0 }, /* Last operator */
{ 0, 0, 0, 0, 1, 1, 1, 1 } /* Out */
},
{
{ 0, 0, 1, 0, 0, 1, 0, 0 }, /* OP1_0 */
{ 0, 0, 0, 0, 0, 0, 0, 0 }, /* OP1_1 */
{ 0, 0, 0, 1, 0, 0, 0, 0 }, /* OP2 */
{ 1, 1, 0, 1, 1, 0, 0, 0 }, /* Last operator */
{ 0, 0, 1, 0, 0, 0, 0, 0 }, /* Last operator */
{ 1, 1, 1, 1, 1, 1, 1, 1 } /* Out */
}
};
static Bit32u chip_type = ym3438_type_discrete;
void OPN2_DoIO(ym3438_t *chip)
{
/* Write signal check */
chip->write_a_en = (chip->write_a & 0x03) == 0x01;
chip->write_d_en = (chip->write_d & 0x03) == 0x01;
chip->write_a <<= 1;
chip->write_d <<= 1;
/* Busy counter */
chip->busy = chip->write_busy;
chip->write_busy_cnt += chip->write_busy;
chip->write_busy = (chip->write_busy && !(chip->write_busy_cnt >> 5)) || chip->write_d_en;
chip->write_busy_cnt &= 0x1f;
}
void OPN2_DoRegWrite(ym3438_t *chip)
{
Bit32u i;
Bit32u slot = chip->cycles % 12;
Bit32u address;
Bit32u channel = chip->channel;
/* Update registers */
if (chip->write_fm_data)
{
/* Slot */
if (op_offset[slot] == (chip->address & 0x107))
{
if (chip->address & 0x08)
{
/* OP2, OP4 */
slot += 12;
}
address = chip->address & 0xf0;
switch (address)
{
case 0x30: /* DT, MULTI */
chip->multi[slot] = chip->data & 0x0f;
if (!chip->multi[slot])
{
chip->multi[slot] = 1;
}
else
{
chip->multi[slot] <<= 1;
}
chip->dt[slot] = (chip->data >> 4) & 0x07;
break;
case 0x40: /* TL */
chip->tl[slot] = chip->data & 0x7f;
break;
case 0x50: /* KS, AR */
chip->ar[slot] = chip->data & 0x1f;
chip->ks[slot] = (chip->data >> 6) & 0x03;
break;
case 0x60: /* AM, DR */
chip->dr[slot] = chip->data & 0x1f;
chip->am[slot] = (chip->data >> 7) & 0x01;
break;
case 0x70: /* SR */
chip->sr[slot] = chip->data & 0x1f;
break;
case 0x80: /* SL, RR */
chip->rr[slot] = chip->data & 0x0f;
chip->sl[slot] = (chip->data >> 4) & 0x0f;
chip->sl[slot] |= (chip->sl[slot] + 1) & 0x10;
break;
case 0x90: /* SSG-EG */
chip->ssg_eg[slot] = chip->data & 0x0f;
break;
default:
break;
}
}
/* Channel */
if (ch_offset[channel] == (chip->address & 0x103))
{
address = chip->address & 0xfc;
switch (address)
{
case 0xa0:
chip->fnum[channel] = (chip->data & 0xff) | ((chip->reg_a4 & 0x07) << 8);
chip->block[channel] = (chip->reg_a4 >> 3) & 0x07;
chip->kcode[channel] = (chip->block[channel] << 2) | fn_note[chip->fnum[channel] >> 7];
break;
case 0xa4:
chip->reg_a4 = chip->data & 0xff;
break;
case 0xa8:
chip->fnum_3ch[channel] = (chip->data & 0xff) | ((chip->reg_ac & 0x07) << 8);
chip->block_3ch[channel] = (chip->reg_ac >> 3) & 0x07;
chip->kcode_3ch[channel] = (chip->block_3ch[channel] << 2) | fn_note[chip->fnum_3ch[channel] >> 7];
break;
case 0xac:
chip->reg_ac = chip->data & 0xff;
break;
case 0xb0:
chip->connect[channel] = chip->data & 0x07;
chip->fb[channel] = (chip->data >> 3) & 0x07;
break;
case 0xb4:
chip->pms[channel] = chip->data & 0x07;
chip->ams[channel] = (chip->data >> 4) & 0x03;
chip->pan_l[channel] = (chip->data >> 7) & 0x01;
chip->pan_r[channel] = (chip->data >> 6) & 0x01;
break;
default:
break;
}
}
}
if (chip->write_a_en || chip->write_d_en)
{
/* Data */
if (chip->write_a_en)
{
chip->write_fm_data = 0;
}
if (chip->write_fm_address && chip->write_d_en)
{
chip->write_fm_data = 1;
}
/* Address */
if (chip->write_a_en)
{
if ((chip->write_data & 0xf0) != 0x00)
{
/* FM Write */
chip->address = chip->write_data;
chip->write_fm_address = 1;
}
else
{
/* SSG write */
chip->write_fm_address = 0;
}
}
/* FM Mode */
/* Data */
if (chip->write_d_en && (chip->write_data & 0x100) == 0)
{
switch (chip->address)
{
case 0x21: /* LSI test 1 */
for (i = 0; i < 8; i++)
{
chip->mode_test_21[i] = (chip->write_data >> i) & 0x01;
}
break;
case 0x22: /* LFO control */
if ((chip->write_data >> 3) & 0x01)
{
chip->lfo_en = 0x7f;
}
else
{
chip->lfo_en = 0;
}
chip->lfo_freq = chip->write_data & 0x07;
break;
case 0x24: /* Timer A */
chip->timer_a_reg &= 0x03;
chip->timer_a_reg |= (chip->write_data & 0xff) << 2;
break;
case 0x25:
chip->timer_a_reg &= 0x3fc;
chip->timer_a_reg |= chip->write_data & 0x03;
break;
case 0x26: /* Timer B */
chip->timer_b_reg = chip->write_data & 0xff;
break;
case 0x27: /* CSM, Timer control */
chip->mode_ch3 = (chip->write_data & 0xc0) >> 6;
chip->mode_csm = chip->mode_ch3 == 2;
chip->timer_a_load = chip->write_data & 0x01;
chip->timer_a_enable = (chip->write_data >> 2) & 0x01;
chip->timer_a_reset = (chip->write_data >> 4) & 0x01;
chip->timer_b_load = (chip->write_data >> 1) & 0x01;
chip->timer_b_enable = (chip->write_data >> 3) & 0x01;
chip->timer_b_reset = (chip->write_data >> 5) & 0x01;
break;
case 0x28: /* Key on/off */
for (i = 0; i < 4; i++)
{
chip->mode_kon_operator[i] = (chip->write_data >> (4 + i)) & 0x01;
}
if ((chip->write_data & 0x03) == 0x03)
{
/* Invalid address */
chip->mode_kon_channel = 0xff;
}
else
{
chip->mode_kon_channel = (chip->write_data & 0x03) + ((chip->write_data >> 2) & 1) * 3;
}
break;
case 0x2a: /* DAC data */
chip->dacdata &= 0x01;
chip->dacdata |= (chip->write_data ^ 0x80) << 1;
break;
case 0x2b: /* DAC enable */
chip->dacen = chip->write_data >> 7;
break;
case 0x2c: /* LSI test 2 */
for (i = 0; i < 8; i++)
{
chip->mode_test_2c[i] = (chip->write_data >> i) & 0x01;
}
chip->dacdata &= 0x1fe;
chip->dacdata |= chip->mode_test_2c[3];
chip->eg_custom_timer = !chip->mode_test_2c[7] && chip->mode_test_2c[6];
break;
default:
break;
}
}
/* Address */
if (chip->write_a_en)
{
chip->write_fm_mode_a = chip->write_data & 0xff;
}
}
if (chip->write_fm_data)
{
chip->data = chip->write_data & 0xff;
}
}
void OPN2_PhaseCalcIncrement(ym3438_t *chip)
{
Bit32u chan = chip->channel;
Bit32u slot = chip->cycles;
Bit32u fnum = chip->pg_fnum;
Bit32u fnum_h = fnum >> 4;
Bit32u fm;
Bit32u basefreq;
Bit8u lfo = chip->lfo_pm;
Bit8u lfo_l = lfo & 0x0f;
Bit8u pms = chip->pms[chan];
Bit8u dt = chip->dt[slot];
Bit8u dt_l = dt & 0x03;
Bit8u detune = 0;
Bit8u block, note;
Bit8u sum, sum_h, sum_l;
Bit8u kcode = chip->pg_kcode;
fnum <<= 1;
/* Apply LFO */
if (lfo_l & 0x08)
{
lfo_l ^= 0x0f;
}
fm = (fnum_h >> pg_lfo_sh1[pms][lfo_l]) + (fnum_h >> pg_lfo_sh2[pms][lfo_l]);
if (pms > 5)
{
fm <<= pms - 5;
}
fm >>= 2;
if (lfo & 0x10)
{
fnum -= fm;
}
else
{
fnum += fm;
}
fnum &= 0xfff;
basefreq = (fnum << chip->pg_block) >> 2;
/* Apply detune */
if (dt_l)
{
if (kcode > 0x1c)
{
kcode = 0x1c;
}
block = kcode >> 2;
note = kcode & 0x03;
sum = block + 9 + ((dt_l == 3) | (dt_l & 0x02));
sum_h = sum >> 1;
sum_l = sum & 0x01;
detune = pg_detune[(sum_l << 2) | note] >> (9 - sum_h);
}
if (dt & 0x04)
{
basefreq -= detune;
}
else
{
basefreq += detune;
}
basefreq &= 0x1ffff;
chip->pg_inc[slot] = (basefreq * chip->multi[slot]) >> 1;
chip->pg_inc[slot] &= 0xfffff;
}
void OPN2_PhaseGenerate(ym3438_t *chip)
{
Bit32u slot;
/* Mask increment */
slot = (chip->cycles + 20) % 24;
if (chip->pg_reset[slot])
{
chip->pg_inc[slot] = 0;
}
/* Phase step */
slot = (chip->cycles + 19) % 24;
chip->pg_phase[slot] += chip->pg_inc[slot];
chip->pg_phase[slot] &= 0xfffff;
if (chip->pg_reset[slot] || chip->mode_test_21[3])
{
chip->pg_phase[slot] = 0;
}
}
void OPN2_EnvelopeSSGEG(ym3438_t *chip)
{
Bit32u slot = chip->cycles;
Bit8u direction = 0;
chip->eg_ssg_pgrst_latch[slot] = 0;
chip->eg_ssg_repeat_latch[slot] = 0;
chip->eg_ssg_hold_up_latch[slot] = 0;
chip->eg_ssg_inv[slot] = 0;
if (chip->ssg_eg[slot] & 0x08)
{
direction = chip->eg_ssg_dir[slot];
if (chip->eg_level[slot] & 0x200)
{
/* Reset */
if ((chip->ssg_eg[slot] & 0x03) == 0x00)
{
chip->eg_ssg_pgrst_latch[slot] = 1;
}
/* Repeat */
if ((chip->ssg_eg[slot] & 0x01) == 0x00)
{
chip->eg_ssg_repeat_latch[slot] = 1;
}
/* Inverse */
if ((chip->ssg_eg[slot] & 0x03) == 0x02)
{
direction ^= 1;
}
if ((chip->ssg_eg[slot] & 0x03) == 0x03)
{
direction = 1;
}
}
/* Hold up */
if (chip->eg_kon_latch[slot]
&& ((chip->ssg_eg[slot] & 0x07) == 0x05 || (chip->ssg_eg[slot] & 0x07) == 0x03))
{
chip->eg_ssg_hold_up_latch[slot] = 1;
}
direction &= chip->eg_kon[slot];
chip->eg_ssg_inv[slot] = (chip->eg_ssg_dir[slot] ^ ((chip->ssg_eg[slot] >> 2) & 0x01))
& chip->eg_kon[slot];
}
chip->eg_ssg_dir[slot] = direction;
chip->eg_ssg_enable[slot] = (chip->ssg_eg[slot] >> 3) & 0x01;
}
void OPN2_EnvelopeADSR(ym3438_t *chip)
{
Bit32u slot = (chip->cycles + 22) % 24;
Bit8u nkon = chip->eg_kon_latch[slot];
Bit8u okon = chip->eg_kon[slot];
Bit8u kon_event;
Bit8u koff_event;
Bit8u eg_off;
Bit16s level;
Bit16s nextlevel = 0;
Bit16s ssg_level;
Bit8u nextstate = chip->eg_state[slot];
Bit16s inc = 0;
chip->eg_read[0] = chip->eg_read_inc;
chip->eg_read_inc = chip->eg_inc > 0;
/* Reset phase generator */
chip->pg_reset[slot] = (nkon && !okon) || chip->eg_ssg_pgrst_latch[slot];
/* KeyOn/Off */
kon_event = (nkon && !okon) || (okon && chip->eg_ssg_repeat_latch[slot]);
koff_event = okon && !nkon;
ssg_level = level = (Bit16s)chip->eg_level[slot];
if (chip->eg_ssg_inv[slot])
{
/* Inverse */
ssg_level = 512 - level;
ssg_level &= 0x3ff;
}
if (koff_event)
{
level = ssg_level;
}
if (chip->eg_ssg_enable[slot])
{
eg_off = level >> 9;
}
else
{
eg_off = (level & 0x3f0) == 0x3f0;
}
nextlevel = level;
if (kon_event)
{
nextstate = eg_num_attack;
/* Instant attack */
if (chip->eg_ratemax)
{
nextlevel = 0;
}
else if (chip->eg_state[slot] == eg_num_attack && level != 0 && chip->eg_inc && nkon)
{
inc = (~level << chip->eg_inc) >> 5;
}
}
else
{
switch (chip->eg_state[slot])
{
case eg_num_attack:
if (level == 0)
{
nextstate = eg_num_decay;
}
else if(chip->eg_inc && !chip->eg_ratemax && nkon)
{
inc = (~level << chip->eg_inc) >> 5;
}
break;
case eg_num_decay:
if ((level >> 5) == chip->eg_sl[1])
{
nextstate = eg_num_sustain;
}
else if (!eg_off && chip->eg_inc)
{
inc = 1 << (chip->eg_inc - 1);
if (chip->eg_ssg_enable[slot])
{
inc <<= 2;
}
}
break;
case eg_num_sustain:
case eg_num_release:
if (!eg_off && chip->eg_inc)
{
inc = 1 << (chip->eg_inc - 1);
if (chip->eg_ssg_enable[slot])
{
inc <<= 2;
}
}
break;
default:
break;
}
if (!nkon)
{
nextstate = eg_num_release;
}
}
if (chip->eg_kon_csm[slot])
{
nextlevel |= chip->eg_tl[1] << 3;
}
/* Envelope off */
if (!kon_event && !chip->eg_ssg_hold_up_latch[slot] && chip->eg_state[slot] != eg_num_attack && eg_off)
{
nextstate = eg_num_release;
nextlevel = 0x3ff;
}
nextlevel += inc;
chip->eg_kon[slot] = chip->eg_kon_latch[slot];
chip->eg_level[slot] = (Bit16u)nextlevel & 0x3ff;
chip->eg_state[slot] = nextstate;
}
void OPN2_EnvelopePrepare(ym3438_t *chip)
{
Bit8u rate;
Bit8u sum;
Bit8u inc = 0;
Bit32u slot = chip->cycles;
Bit8u rate_sel;
/* Prepare increment */
rate = (chip->eg_rate << 1) + chip->eg_ksv;
if (rate > 0x3f)
{
rate = 0x3f;
}
sum = ((rate >> 2) + chip->eg_shift_lock) & 0x0f;
if (chip->eg_rate != 0 && chip->eg_quotient == 2)
{
if (rate < 48)
{
switch (sum)
{
case 12:
inc = 1;
break;
case 13:
inc = (rate >> 1) & 0x01;
break;
case 14:
inc = rate & 0x01;
break;
default:
break;
}
}
else
{
inc = eg_stephi[rate & 0x03][chip->eg_timer_low_lock] + (rate >> 2) - 11;
if (inc > 4)
{
inc = 4;
}
}
}
chip->eg_inc = inc;
chip->eg_ratemax = (rate >> 1) == 0x1f;
/* Prepare rate & ksv */
rate_sel = chip->eg_state[slot];
if ((chip->eg_kon[slot] && chip->eg_ssg_repeat_latch[slot])
|| (!chip->eg_kon[slot] && chip->eg_kon_latch[slot]))
{
rate_sel = eg_num_attack;
}
switch (rate_sel)
{
case eg_num_attack:
chip->eg_rate = chip->ar[slot];
break;
case eg_num_decay:
chip->eg_rate = chip->dr[slot];
break;
case eg_num_sustain:
chip->eg_rate = chip->sr[slot];
break;
case eg_num_release:
chip->eg_rate = (chip->rr[slot] << 1) | 0x01;
break;
default:
break;
}
chip->eg_ksv = chip->pg_kcode >> (chip->ks[slot] ^ 0x03);
if (chip->am[slot])
{
chip->eg_lfo_am = chip->lfo_am >> eg_am_shift[chip->ams[chip->channel]];
}
else
{
chip->eg_lfo_am = 0;
}
/* Delay TL & SL value */
chip->eg_tl[1] = chip->eg_tl[0];
chip->eg_tl[0] = chip->tl[slot];
chip->eg_sl[1] = chip->eg_sl[0];
chip->eg_sl[0] = chip->sl[slot];
}
void OPN2_EnvelopeGenerate(ym3438_t *chip)
{
Bit32u slot = (chip->cycles + 23) % 24;
Bit16u level;
level = chip->eg_level[slot];
if (chip->eg_ssg_inv[slot])
{
/* Inverse */
level = 512 - level;
}
if (chip->mode_test_21[5])
{
level = 0;
}
level &= 0x3ff;
/* Apply AM LFO */
level += chip->eg_lfo_am;
/* Apply TL */
if (!(chip->mode_csm && chip->channel == 2 + 1))
{
level += chip->eg_tl[0] << 3;
}
if (level > 0x3ff)
{
level = 0x3ff;
}
chip->eg_out[slot] = level;
}
void OPN2_UpdateLFO(ym3438_t *chip)
{
if ((chip->lfo_quotient & lfo_cycles[chip->lfo_freq]) == lfo_cycles[chip->lfo_freq])
{
chip->lfo_quotient = 0;
chip->lfo_cnt++;
}
else
{
chip->lfo_quotient += chip->lfo_inc;
}
chip->lfo_cnt &= chip->lfo_en;
}
void OPN2_FMPrepare(ym3438_t *chip)
{
Bit32u slot = (chip->cycles + 6) % 24;
Bit32u channel = chip->channel;
Bit16s mod, mod1, mod2;
Bit32u op = slot / 6;
Bit8u connect = chip->connect[channel];
Bit32u prevslot = (chip->cycles + 18) % 24;
/* Calculate modulation */
mod1 = mod2 = 0;
if (fm_algorithm[op][0][connect])
{
mod2 |= chip->fm_op1[channel][0];
}
if (fm_algorithm[op][1][connect])
{
mod1 |= chip->fm_op1[channel][1];
}
if (fm_algorithm[op][2][connect])
{
mod1 |= chip->fm_op2[channel];
}
if (fm_algorithm[op][3][connect])
{
mod2 |= chip->fm_out[prevslot];
}
if (fm_algorithm[op][4][connect])
{
mod1 |= chip->fm_out[prevslot];
}
mod = mod1 + mod2;
if (op == 0)
{
/* Feedback */
mod = mod >> (10 - chip->fb[channel]);
if (!chip->fb[channel])
{
mod = 0;
}
}
else
{
mod >>= 1;
}
chip->fm_mod[slot] = mod;
slot = (chip->cycles + 18) % 24;
/* OP1 */
if (slot / 6 == 0)
{
chip->fm_op1[channel][1] = chip->fm_op1[channel][0];
chip->fm_op1[channel][0] = chip->fm_out[slot];
}
/* OP2 */
if (slot / 6 == 2)
{
chip->fm_op2[channel] = chip->fm_out[slot];
}
}
void OPN2_ChGenerate(ym3438_t *chip)
{
Bit32u slot = (chip->cycles + 18) % 24;
Bit32u channel = chip->channel;
Bit32u op = slot / 6;
Bit32u test_dac = chip->mode_test_2c[5];
Bit16s acc = chip->ch_acc[channel];
Bit16s add = test_dac;
Bit16s sum = 0;
if (op == 0 && !test_dac)
{
acc = 0;
}
if (fm_algorithm[op][5][chip->connect[channel]] && !test_dac)
{
add += chip->fm_out[slot] >> 5;
}
sum = acc + add;
/* Clamp */
if (sum > 255)
{
sum = 255;
}
else if(sum < -256)
{
sum = -256;
}
if (op == 0 || test_dac)
{
chip->ch_out[channel] = chip->ch_acc[channel];
}
chip->ch_acc[channel] = sum;
}
void OPN2_ChOutput(ym3438_t *chip)
{
Bit32u cycles = chip->cycles;
Bit32u slot = chip->cycles;
Bit32u channel = chip->channel;
Bit32u test_dac = chip->mode_test_2c[5];
Bit16s out;
Bit16s sign;
Bit32u out_en;
chip->ch_read = chip->ch_lock;
if (slot < 12)
{
/* Ch 4,5,6 */
channel++;
}
if ((cycles & 3) == 0)
{
if (!test_dac)
{
/* Lock value */
chip->ch_lock = chip->ch_out[channel];
}
chip->ch_lock_l = chip->pan_l[channel];
chip->ch_lock_r = chip->pan_r[channel];
}
/* Ch 6 */
if (((cycles >> 2) == 1 && chip->dacen) || test_dac)
{
out = (Bit16s)chip->dacdata;
out <<= 7;
out >>= 7;
}
else
{
out = chip->ch_lock;
}
chip->mol = 0;
chip->mor = 0;
if (chip_type == ym3438_type_ym2612)
{
out_en = ((cycles & 3) == 3) || test_dac;
/* YM2612 DAC emulation(not verified) */
sign = out >> 8;
if (out >= 0)
{
out++;
sign++;
}
if (chip->ch_lock_l && out_en)
{
chip->mol = out;
}
else
{
chip->mol = sign;
}
if (chip->ch_lock_r && out_en)
{
chip->mor = out;
}
else
{
chip->mor = sign;
}
/* Amplify signal */
chip->mol *= 3;
chip->mor *= 3;
}
else
{
out_en = ((cycles & 3) != 0) || test_dac;
/* Discrete YM3438 seems has the ladder effect too */
if (out >= 0 && chip_type == ym3438_type_discrete)
{
out++;
}
if (chip->ch_lock_l && out_en)
{
chip->mol = out;
}
if (chip->ch_lock_r && out_en)
{
chip->mor = out;
}
}
}
void OPN2_FMGenerate(ym3438_t *chip)
{
Bit32u slot = (chip->cycles + 19) % 24;
/* Calculate phase */
Bit16u phase = (chip->fm_mod[slot] + (chip->pg_phase[slot] >> 10)) & 0x3ff;
Bit16u quarter;
Bit16u level;
Bit16s output;
if (phase & 0x100)
{
quarter = (phase ^ 0xff) & 0xff;
}
else
{
quarter = phase & 0xff;
}
level = logsinrom[quarter];
/* Apply envelope */
level += chip->eg_out[slot] << 2;
/* Transform */
if (level > 0x1fff)
{
level = 0x1fff;
}
output = ((exprom[(level & 0xff) ^ 0xff] | 0x400) << 2) >> (level >> 8);
if (phase & 0x200)
{
output = ((~output) ^ (chip->mode_test_21[4] << 13)) + 1;
}
else
{
output = output ^ (chip->mode_test_21[4] << 13);
}
output <<= 2;
output >>= 2;
chip->fm_out[slot] = output;
}
void OPN2_DoTimerA(ym3438_t *chip)
{
Bit16u time;
Bit8u load;
load = chip->timer_a_overflow;
if (chip->cycles == 2)
{
/* Lock load value */
load |= (!chip->timer_a_load_lock && chip->timer_a_load);
chip->timer_a_load_lock = chip->timer_a_load;
if (chip->mode_csm)
{
/* CSM KeyOn */
chip->mode_kon_csm = load;
}
else
{
chip->mode_kon_csm = 0;
}
}
/* Load counter */
if (chip->timer_a_load_latch)
{
time = chip->timer_a_reg;
}
else
{
time = chip->timer_a_cnt;
}
chip->timer_a_load_latch = load;
/* Increase counter */
if ((chip->cycles == 1 && chip->timer_a_load_lock) || chip->mode_test_21[2])
{
time++;
}
/* Set overflow flag */
if (chip->timer_a_reset)
{
chip->timer_a_reset = 0;
chip->timer_a_overflow_flag = 0;
}
else
{
chip->timer_a_overflow_flag |= chip->timer_a_overflow & chip->timer_a_enable;
}
chip->timer_a_overflow = (time >> 10);
chip->timer_a_cnt = time & 0x3ff;
}
void OPN2_DoTimerB(ym3438_t *chip)
{
Bit16u time;
Bit8u load;
load = chip->timer_b_overflow;
if (chip->cycles == 2)
{
/* Lock load value */
load |= (!chip->timer_b_load_lock && chip->timer_b_load);
chip->timer_b_load_lock = chip->timer_b_load;
}
/* Load counter */
if (chip->timer_b_load_latch)
{
time = chip->timer_b_reg;
}
else
{
time = chip->timer_b_cnt;
}
chip->timer_b_load_latch = load;
/* Increase counter */
if (chip->cycles == 1)
{
chip->timer_b_subcnt++;
}
if ((chip->timer_b_subcnt == 0x10 && chip->timer_b_load_lock) || chip->mode_test_21[2])
{
time++;
}
chip->timer_b_subcnt &= 0x0f;
/* Set overflow flag */
if (chip->timer_b_reset)
{
chip->timer_b_reset = 0;
chip->timer_b_overflow_flag = 0;
}
else
{
chip->timer_b_overflow_flag |= chip->timer_b_overflow & chip->timer_b_enable;
}
chip->timer_b_overflow = (time >> 8);
chip->timer_b_cnt = time & 0xff;
}
void OPN2_KeyOn(ym3438_t*chip)
{
Bit32u slot = chip->cycles;
Bit32u chan = chip->channel;
/* Key On */
chip->eg_kon_latch[slot] = chip->mode_kon[slot];
chip->eg_kon_csm[slot] = 0;
if (chip->channel == 2 && chip->mode_kon_csm)
{
/* CSM Key On */
chip->eg_kon_latch[slot] = 1;
chip->eg_kon_csm[slot] = 1;
}
if (chip->cycles == chip->mode_kon_channel)
{
/* OP1 */
chip->mode_kon[chan] = chip->mode_kon_operator[0];
/* OP2 */
chip->mode_kon[chan + 12] = chip->mode_kon_operator[1];
/* OP3 */
chip->mode_kon[chan + 6] = chip->mode_kon_operator[2];
/* OP4 */
chip->mode_kon[chan + 18] = chip->mode_kon_operator[3];
}
}
void OPN2_Reset(ym3438_t *chip, Bit32u rate, Bit32u clock)
{
Bit32u i, rateratio;
rateratio = (Bit32u)chip->rateratio;
memset(chip, 0, sizeof(ym3438_t));
for (i = 0; i < 24; i++)
{
chip->eg_out[i] = 0x3ff;
chip->eg_level[i] = 0x3ff;
chip->eg_state[i] = eg_num_release;
chip->multi[i] = 1;
}
for (i = 0; i < 6; i++)
{
chip->pan_l[i] = 1;
chip->pan_r[i] = 1;
}
if (rate != 0)
{
chip->rateratio = (Bit32s)(Bit32u)((((Bit64u)144 * rate) << RSM_FRAC) / clock);
}
else
{
chip->rateratio = (Bit32s)rateratio;
}
}
void OPN2_SetChipType(Bit32u type)
{
chip_type = type;
}
void OPN2_Clock(ym3438_t *chip, Bit16s *buffer)
{
Bit32u slot = chip->cycles;
chip->lfo_inc = chip->mode_test_21[1];
chip->pg_read >>= 1;
chip->eg_read[1] >>= 1;
chip->eg_cycle++;
/* Lock envelope generator timer value */
if (chip->cycles == 1 && chip->eg_quotient == 2)
{
if (chip->eg_cycle_stop)
{
chip->eg_shift_lock = 0;
}
else
{
chip->eg_shift_lock = chip->eg_shift + 1;
}
chip->eg_timer_low_lock = chip->eg_timer & 0x03;
}
/* Cycle specific functions */
switch (chip->cycles)
{
case 0:
chip->lfo_pm = chip->lfo_cnt >> 2;
if (chip->lfo_cnt & 0x40)
{
chip->lfo_am = chip->lfo_cnt & 0x3f;
}
else
{
chip->lfo_am = chip->lfo_cnt ^ 0x3f;
}
chip->lfo_am <<= 1;
break;
case 1:
chip->eg_quotient++;
chip->eg_quotient %= 3;
chip->eg_cycle = 0;
chip->eg_cycle_stop = 1;
chip->eg_shift = 0;
chip->eg_timer_inc |= chip->eg_quotient >> 1;
chip->eg_timer = chip->eg_timer + chip->eg_timer_inc;
chip->eg_timer_inc = chip->eg_timer >> 12;
chip->eg_timer &= 0xfff;
break;
case 2:
chip->pg_read = chip->pg_phase[21] & 0x3ff;
chip->eg_read[1] = chip->eg_out[0];
break;
case 13:
chip->eg_cycle = 0;
chip->eg_cycle_stop = 1;
chip->eg_shift = 0;
chip->eg_timer = chip->eg_timer + chip->eg_timer_inc;
chip->eg_timer_inc = chip->eg_timer >> 12;
chip->eg_timer &= 0xfff;
break;
case 23:
chip->lfo_inc |= 1;
break;
}
chip->eg_timer &= ~(chip->mode_test_21[5] << chip->eg_cycle);
if (((chip->eg_timer >> chip->eg_cycle) | (chip->pin_test_in & chip->eg_custom_timer)) & chip->eg_cycle_stop)
{
chip->eg_shift = chip->eg_cycle;
chip->eg_cycle_stop = 0;
}
OPN2_DoIO(chip);
OPN2_DoTimerA(chip);
OPN2_DoTimerB(chip);
OPN2_KeyOn(chip);
OPN2_ChOutput(chip);
OPN2_ChGenerate(chip);
OPN2_FMPrepare(chip);
OPN2_FMGenerate(chip);
OPN2_PhaseGenerate(chip);
OPN2_PhaseCalcIncrement(chip);
OPN2_EnvelopeADSR(chip);
OPN2_EnvelopeGenerate(chip);
OPN2_EnvelopeSSGEG(chip);
OPN2_EnvelopePrepare(chip);
/* Prepare fnum & block */
if (chip->mode_ch3)
{
/* Channel 3 special mode */
switch (slot)
{
case 1: /* OP1 */
chip->pg_fnum = chip->fnum_3ch[1];
chip->pg_block = chip->block_3ch[1];
chip->pg_kcode = chip->kcode_3ch[1];
break;
case 7: /* OP3 */
chip->pg_fnum = chip->fnum_3ch[0];
chip->pg_block = chip->block_3ch[0];
chip->pg_kcode = chip->kcode_3ch[0];
break;
case 13: /* OP2 */
chip->pg_fnum = chip->fnum_3ch[2];
chip->pg_block = chip->block_3ch[2];
chip->pg_kcode = chip->kcode_3ch[2];
break;
case 19: /* OP4 */
default:
chip->pg_fnum = chip->fnum[(chip->channel + 1) % 6];
chip->pg_block = chip->block[(chip->channel + 1) % 6];
chip->pg_kcode = chip->kcode[(chip->channel + 1) % 6];
break;
}
}
else
{
chip->pg_fnum = chip->fnum[(chip->channel + 1) % 6];
chip->pg_block = chip->block[(chip->channel + 1) % 6];
chip->pg_kcode = chip->kcode[(chip->channel + 1) % 6];
}
OPN2_UpdateLFO(chip);
OPN2_DoRegWrite(chip);
chip->cycles = (chip->cycles + 1) % 24;
chip->channel = chip->cycles % 6;
buffer[0] = chip->mol;
buffer[1] = chip->mor;
}
void OPN2_Write(ym3438_t *chip, Bit32u port, Bit8u data)
{
port &= 3;
chip->write_data = ((port << 7) & 0x100) | data;
if (port & 1)
{
/* Data */
chip->write_d |= 1;
}
else
{
/* Address */
chip->write_a |= 1;
}
}
void OPN2_SetTestPin(ym3438_t *chip, Bit32u value)
{
chip->pin_test_in = value & 1;
}
Bit32u OPN2_ReadTestPin(ym3438_t *chip)
{
if (!chip->mode_test_2c[7])
{
return 0;
}
return chip->cycles == 23;
}
Bit32u OPN2_ReadIRQPin(ym3438_t *chip)
{
return chip->timer_a_overflow_flag | chip->timer_b_overflow_flag;
}
Bit8u OPN2_Read(ym3438_t *chip, Bit32u port)
{
if ((port & 3) == 0 || chip_type == ym3438_type_asic)
{
if (chip->mode_test_21[6])
{
/* Read test data */
Bit32u slot = (chip->cycles + 18) % 24;
Bit16u testdata = ((chip->pg_read & 0x01) << 15)
| ((chip->eg_read[chip->mode_test_21[0]] & 0x01) << 14);
if (chip->mode_test_2c[4])
{
testdata |= chip->ch_read & 0x1ff;
}
else
{
testdata |= chip->fm_out[slot] & 0x3fff;
}
if (chip->mode_test_21[7])
{
return testdata & 0xff;
}
else
{
return testdata >> 8;
}
}
else
{
return (Bit8u)(chip->busy << 7) | (Bit8u)(chip->timer_b_overflow_flag << 1)
| (Bit8u)chip->timer_a_overflow_flag;
}
}
return 0;
}
void OPN2_WriteBuffered(ym3438_t *chip, Bit32u port, Bit8u data)
{
Bit64u time1, time2;
Bit16s buffer[2];
Bit64u skip;
if (chip->writebuf[chip->writebuf_last].port & 0x04)
{
OPN2_Write(chip, chip->writebuf[chip->writebuf_last].port & 0X03,
chip->writebuf[chip->writebuf_last].data);
chip->writebuf_cur = (chip->writebuf_last + 1) % OPN_WRITEBUF_SIZE;
skip = chip->writebuf[chip->writebuf_last].time - chip->writebuf_samplecnt;
chip->writebuf_samplecnt = chip->writebuf[chip->writebuf_last].time;
while (skip--)
{
OPN2_Clock(chip, buffer);
}
}
chip->writebuf[chip->writebuf_last].port = (port & 0x03) | 0x04;
chip->writebuf[chip->writebuf_last].data = data;
time1 = chip->writebuf_lasttime + OPN_WRITEBUF_DELAY;
time2 = chip->writebuf_samplecnt;
if (time1 < time2)
{
time1 = time2;
}
chip->writebuf[chip->writebuf_last].time = time1;
chip->writebuf_lasttime = time1;
chip->writebuf_last = (chip->writebuf_last + 1) % OPN_WRITEBUF_SIZE;
}
void OPN2_Generate(ym3438_t *chip, Bit16s *buf)
{
Bit32u i;
Bit16s buffer[2];
Bit32u mute;
buf[0] = 0;
buf[1] = 0;
for (i = 0; i < 24; i++)
{
switch (chip->cycles >> 2)
{
case 0: /* Ch 2 */
mute = chip->mute[1];
break;
case 1: /* Ch 6, DAC */
mute = chip->mute[5 + chip->dacen];
break;
case 2: /* Ch 4 */
mute = chip->mute[3];
break;
case 3: /* Ch 1 */
mute = chip->mute[0];
break;
case 4: /* Ch 5 */
mute = chip->mute[4];
break;
case 5: /* Ch 3 */
mute = chip->mute[2];
break;
default:
mute = 0;
break;
}
OPN2_Clock(chip, buffer);
if (!mute)
{
buf[0] += buffer[0];
buf[1] += buffer[1];
}
while (chip->writebuf[chip->writebuf_cur].time <= chip->writebuf_samplecnt)
{
if (!(chip->writebuf[chip->writebuf_cur].port & 0x04))
{
break;
}
chip->writebuf[chip->writebuf_cur].port &= 0x03;
OPN2_Write(chip, chip->writebuf[chip->writebuf_cur].port,
chip->writebuf[chip->writebuf_cur].data);
chip->writebuf_cur = (chip->writebuf_cur + 1) % OPN_WRITEBUF_SIZE;
}
chip->writebuf_samplecnt++;
}
}
void OPN2_GenerateResampled(ym3438_t *chip, Bit16s *buf)
{
Bit16s buffer[2];
while (chip->samplecnt >= chip->rateratio)
{
chip->oldsamples[0] = chip->samples[0];
chip->oldsamples[1] = chip->samples[1];
OPN2_Generate(chip, buffer);
chip->samples[0] = buffer[0] * 11;
chip->samples[1] = buffer[1] * 11;
chip->samplecnt -= chip->rateratio;
}
buf[0] = (Bit16s)(((chip->oldsamples[0] * (chip->rateratio - chip->samplecnt)
+ chip->samples[0] * chip->samplecnt) / chip->rateratio)>>1);
buf[1] = (Bit16s)(((chip->oldsamples[1] * (chip->rateratio - chip->samplecnt)
+ chip->samples[1] * chip->samplecnt) / chip->rateratio)>>1);
chip->samplecnt += 1 << RSM_FRAC;
}
void OPN2_GenerateStream(ym3438_t *chip, Bit16s *output, Bit32u numsamples)
{
Bit32u i;
Bit16s buffer[2];
for (i = 0; i < numsamples; i++)
{
OPN2_GenerateResampled(chip, buffer);
*output++ = buffer[0];
*output++ = buffer[1];
}
}
void OPN2_GenerateStreamMix(ym3438_t *chip, Bit16s *output, Bit32u numsamples)
{
Bit32u i;
Bit16s buffer[2];
for (i = 0; i < numsamples; i++)
{
OPN2_GenerateResampled(chip, buffer);
*output++ += buffer[0];
*output++ += buffer[1];
}
}
void OPN2_SetOptions(Bit8u flags)
{
switch ((flags >> 3) & 0x03)
{
case 0x00: /* YM2612 */
default:
OPN2_SetChipType(ym3438_type_ym2612);
break;
case 0x01: /* ASIC YM3438 */
OPN2_SetChipType(ym3438_type_asic);
break;
case 0x02: /* Discrete YM3438 */
OPN2_SetChipType(ym3438_type_discrete);
break;
}
}
void OPN2_SetMute(ym3438_t *chip, Bit32u mute)
{
Bit32u i;
for (i = 0; i < 7; i++)
{
chip->mute[i] = (mute >> i) & 0x01;
}
}
} // Ym2612_NukedImpl
Ym2612_Nuked_Emu::Ym2612_Nuked_Emu()
{
Ym2612_NukedImpl::OPN2_SetChipType( Ym2612_NukedImpl::ym3438_type_asic );
impl = new Ym2612_NukedImpl::ym3438_t;
}
Ym2612_Nuked_Emu::~Ym2612_Nuked_Emu()
{
Ym2612_NukedImpl::ym3438_t *chip_r = reinterpret_cast<Ym2612_NukedImpl::ym3438_t*>(impl);
if ( chip_r ) delete chip_r;
}
const char *Ym2612_Nuked_Emu::set_rate(double sample_rate, double clock_rate)
{
Ym2612_NukedImpl::ym3438_t *chip_r = reinterpret_cast<Ym2612_NukedImpl::ym3438_t*>(impl);
if ( !chip_r )
return "Out of memory";
prev_sample_rate = sample_rate;
prev_clock_rate = clock_rate;
Ym2612_NukedImpl::OPN2_Reset( chip_r, static_cast<Bit32u>(sample_rate), static_cast<Bit32u>(clock_rate) );
return 0;
}
void Ym2612_Nuked_Emu::reset()
{
Ym2612_NukedImpl::ym3438_t *chip_r = reinterpret_cast<Ym2612_NukedImpl::ym3438_t*>(impl);
if ( !chip_r ) Ym2612_NukedImpl::OPN2_Reset( chip_r, static_cast<Bit32u>(prev_sample_rate), static_cast<Bit32u>(prev_clock_rate) );
}
void Ym2612_Nuked_Emu::mute_voices(int mask)
{
Ym2612_NukedImpl::ym3438_t *chip_r = reinterpret_cast<Ym2612_NukedImpl::ym3438_t*>(impl);
if ( chip_r ) Ym2612_NukedImpl::OPN2_SetMute( chip_r, mask );
}
void Ym2612_Nuked_Emu::write0(int addr, int data)
{
Ym2612_NukedImpl::ym3438_t *chip_r = reinterpret_cast<Ym2612_NukedImpl::ym3438_t*>(impl);
if ( !chip_r ) return;
Ym2612_NukedImpl::OPN2_WriteBuffered( chip_r, 0, static_cast<Bit8u>(addr) );
Ym2612_NukedImpl::OPN2_WriteBuffered( chip_r, 1, static_cast<Bit8u>(data) );
}
void Ym2612_Nuked_Emu::write1(int addr, int data)
{
Ym2612_NukedImpl::ym3438_t *chip_r = reinterpret_cast<Ym2612_NukedImpl::ym3438_t*>(impl);
if ( !chip_r ) return;
Ym2612_NukedImpl::OPN2_WriteBuffered( chip_r, 0 + 2, static_cast<Bit8u>(addr) );
Ym2612_NukedImpl::OPN2_WriteBuffered( chip_r, 1 + 2, static_cast<Bit8u>(data) );
}
void Ym2612_Nuked_Emu::run(int pair_count, Ym2612_Nuked_Emu::sample_t *out)
{
Ym2612_NukedImpl::ym3438_t *chip_r = reinterpret_cast<Ym2612_NukedImpl::ym3438_t*>(impl);
if ( !chip_r ) return;
Ym2612_NukedImpl::OPN2_GenerateStream(chip_r, out, pair_count);
}
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