Genesis-Plus-GX/source/sound/fm.c

1941 lines
54 KiB
C

/*
**
** File: fm.c -- software implementation of Yamaha FM sound generator
**
** Copyright (C) 2001, 2002, 2003 Jarek Burczynski (bujar at mame dot net)
** Copyright (C) 1998 Tatsuyuki Satoh , MultiArcadeMachineEmulator development
**
** Version 1.4 (final beta)
**
*/
/*
** History:
**
** 2006-2008 Eke-Eke (Gamecube/Wii genesis plus port):
** - added DAC filtering
** - fixed internal FM timer emulation
** - removed unused multichip support and YMxxx support
** - fixed CH3 CSM mode (credits to Nemesis)
** - implemented PG overflow, aka "detune bug" (Ariel, Comix Zone, Shaq Fu, Spiderman,...), credits to Nemesis
** - fixed SSG-EG support, credits to Nemesis and additional fixes from Alone Coder
** - modified EG rates and frequency, tested by Nemesis on real hardware
** - fixed EG attenuation level on KEY ON (Ecco 2 splash sound)
** - fixed LFO phase update for CH3 special mode (Warlock, Alladin), thanks to AamirM
** - fixed Attack rate refresh (fix Batman&Robin introduction)
**
** 03-08-2003 Jarek Burczynski:
** - fixed YM2608 initial values (after the reset)
** - fixed flag and irqmask handling (YM2608)
** - fixed BUFRDY flag handling (YM2608)
**
** 14-06-2003 Jarek Burczynski:
** - implemented all of the YM2608 status register flags
** - implemented support for external memory read/write via YM2608
** - implemented support for deltat memory limit register in YM2608 emulation
**
** 22-05-2003 Jarek Burczynski:
** - fixed LFO PM calculations (copy&paste bugfix)
**
** 08-05-2003 Jarek Burczynski:
** - fixed SSG support
**
** 22-04-2003 Jarek Burczynski:
** - implemented 100% correct LFO generator (verified on real YM2610 and YM2608)
**
** 15-04-2003 Jarek Burczynski:
** - added support for YM2608's register 0x110 - status mask
**
** 01-12-2002 Jarek Burczynski:
** - fixed register addressing in YM2608, YM2610, YM2610B chips. (verified on real YM2608)
** The addressing patch used for early Neo-Geo games can be removed now.
**
** 26-11-2002 Jarek Burczynski, Nicola Salmoria:
** - recreated YM2608 ADPCM ROM using data from real YM2608's output which leads to:
** - added emulation of YM2608 drums.
** - output of YM2608 is two times lower now - same as YM2610 (verified on real YM2608)
**
** 16-08-2002 Jarek Burczynski:
** - binary exact Envelope Generator (verified on real YM2203);
** identical to YM2151
** - corrected 'off by one' error in feedback calculations (when feedback is off)
** - corrected connection (algorithm) calculation (verified on real YM2203 and YM2610)
**
** 18-12-2001 Jarek Burczynski:
** - added SSG-EG support (verified on real YM2203)
**
** 12-08-2001 Jarek Burczynski:
** - corrected sin_tab and tl_tab data (verified on real chip)
** - corrected feedback calculations (verified on real chip)
** - corrected phase generator calculations (verified on real chip)
** - corrected envelope generator calculations (verified on real chip)
** - corrected FM volume level (YM2610 and YM2610B).
** - changed YMxxxUpdateOne() functions (YM2203, YM2608, YM2610, YM2610B, YM2612) :
** this was needed to calculate YM2610 FM channels output correctly.
** (Each FM channel is calculated as in other chips, but the output of the channel
** gets shifted right by one *before* sending to accumulator. That was impossible to do
** with previous implementation).
**
** 23-07-2001 Jarek Burczynski, Nicola Salmoria:
** - corrected YM2610 ADPCM type A algorithm and tables (verified on real chip)
**
** 11-06-2001 Jarek Burczynski:
** - corrected end of sample bug in ADPCMA_calc_cha().
** Real YM2610 checks for equality between current and end addresses (only 20 LSB bits).
**
** 08-12-98 hiro-shi:
** rename ADPCMA -> ADPCMB, ADPCMB -> ADPCMA
** move ROM limit check.(CALC_CH? -> 2610Write1/2)
** test program (ADPCMB_TEST)
** move ADPCM A/B end check.
** ADPCMB repeat flag(no check)
** change ADPCM volume rate (8->16) (32->48).
**
** 09-12-98 hiro-shi:
** change ADPCM volume. (8->16, 48->64)
** replace ym2610 ch0/3 (YM-2610B)
** change ADPCM_SHIFT (10->8) missing bank change 0x4000-0xffff.
** add ADPCM_SHIFT_MASK
** change ADPCMA_DECODE_MIN/MAX.
*/
/************************************************************************/
/* comment of hiro-shi(Hiromitsu Shioya) */
/* YM2610(B) = OPN-B */
/* YM2610 : PSG:3ch FM:4ch ADPCM(18.5KHz):6ch DeltaT ADPCM:1ch */
/* YM2610B : PSG:3ch FM:6ch ADPCM(18.5KHz):6ch DeltaT ADPCM:1ch */
/************************************************************************/
#include <stdio.h>
#include <stdlib.h>
#include <string.h>
#include <stdarg.h>
#include <math.h>
#include "shared.h"
/* globals */
#define FREQ_SH 16 /* 16.16 fixed point (frequency calculations) */
#define EG_SH 16 /* 16.16 fixed point (envelope generator timing) */
#define LFO_SH 24 /* 8.24 fixed point (LFO calculations) */
#define TIMER_SH 16 /* 16.16 fixed point (timers calculations) */
#define FREQ_MASK ((1<<FREQ_SH)-1)
#define ENV_BITS 10
#define ENV_LEN (1<<ENV_BITS)
#define ENV_STEP (128.0/ENV_LEN)
#define MAX_ATT_INDEX (ENV_LEN-1) /* 1023 */
#define MIN_ATT_INDEX (0) /* 0 */
#define EG_ATT 4
#define EG_DEC 3
#define EG_SUS 2
#define EG_REL 1
#define EG_OFF 0
#define SIN_BITS 10
#define SIN_LEN (1<<SIN_BITS)
#define SIN_MASK (SIN_LEN-1)
#define TL_RES_LEN (256) /* 8 bits addressing (real chip) */
#define MAXOUT (+32767)
#define MINOUT (-32768)
/* TL_TAB_LEN is calculated as:
* 13 - sinus amplitude bits (Y axis)
* 2 - sinus sign bit (Y axis)
* TL_RES_LEN - sinus resolution (X axis)
*/
#define TL_TAB_LEN (13*2*TL_RES_LEN)
static signed int tl_tab[TL_TAB_LEN];
#define ENV_QUIET (TL_TAB_LEN>>3)
/* sin waveform table in 'decibel' scale */
static unsigned int sin_tab[SIN_LEN];
/* sustain level table (3dB per step) */
/* bit0, bit1, bit2, bit3, bit4, bit5, bit6 */
/* 1, 2, 4, 8, 16, 32, 64 (value)*/
/* 0.75, 1.5, 3, 6, 12, 24, 48 (dB)*/
/* 0 - 15: 0, 3, 6, 9,12,15,18,21,24,27,30,33,36,39,42,93 (dB)*/
#define SC(db) (UINT32) ( db * (4.0/ENV_STEP) )
static const UINT32 sl_table[16]={
SC( 0),SC( 1),SC( 2),SC(3 ),SC(4 ),SC(5 ),SC(6 ),SC( 7),
SC( 8),SC( 9),SC(10),SC(11),SC(12),SC(13),SC(14),SC(31)
};
#undef SC
#define RATE_STEPS (8)
static const UINT8 eg_inc[19*RATE_STEPS]={
/*cycle:0 1 2 3 4 5 6 7*/
/* 0 */ 0,1, 0,1, 0,1, 0,1, /* rates 00..11 0 (increment by 0 or 1) */
/* 1 */ 0,1, 0,1, 1,1, 0,1, /* rates 00..11 1 */
/* 2 */ 0,1, 1,1, 0,1, 1,1, /* rates 00..11 2 */
/* 3 */ 0,1, 1,1, 1,1, 1,1, /* rates 00..11 3 */
/* 4 */ 1,1, 1,1, 1,1, 1,1, /* rate 12 0 (increment by 1) */
/* 5 */ 1,1, 1,2, 1,1, 1,2, /* rate 12 1 */
/* 6 */ 1,2, 1,2, 1,2, 1,2, /* rate 12 2 */
/* 7 */ 1,2, 2,2, 1,2, 2,2, /* rate 12 3 */
/* 8 */ 2,2, 2,2, 2,2, 2,2, /* rate 13 0 (increment by 2) */
/* 9 */ 2,2, 2,4, 2,2, 2,4, /* rate 13 1 */
/*10 */ 2,4, 2,4, 2,4, 2,4, /* rate 13 2 */
/*11 */ 2,4, 4,4, 2,4, 4,4, /* rate 13 3 */
/*12 */ 4,4, 4,4, 4,4, 4,4, /* rate 14 0 (increment by 4) */
/*13 */ 4,4, 4,8, 4,4, 4,8, /* rate 14 1 */
/*14 */ 4,8, 4,8, 4,8, 4,8, /* rate 14 2 */
/*15 */ 4,8, 8,8, 4,8, 8,8, /* rate 14 3 */
/*16 */ 8,8, 8,8, 8,8, 8,8, /* rates 15 0, 15 1, 15 2, 15 3 (increment by 8) */
/*17 */ 16,16,16,16,16,16,16,16, /* rates 15 2, 15 3 for attack */
/*18 */ 0,0, 0,0, 0,0, 0,0, /* infinity rates for attack and decay(s) */
};
#define O(a) (a*RATE_STEPS)
/*note that there is no O(17) in this table - it's directly in the code */
static const UINT8 eg_rate_select[32+64+32]={ /* Envelope Generator rates (32 + 64 rates + 32 RKS) */
/* 32 infinite time rates */
O(18),O(18),O(18),O(18),O(18),O(18),O(18),O(18),
O(18),O(18),O(18),O(18),O(18),O(18),O(18),O(18),
O(18),O(18),O(18),O(18),O(18),O(18),O(18),O(18),
O(18),O(18),O(18),O(18),O(18),O(18),O(18),O(18),
/* rates 00-11 */
/*
O( 0),O( 1),O( 2),O( 3),
O( 0),O( 1),O( 2),O( 3),
*/
O( 18),O( 18),O( 0),O( 0),
O( 0),O( 0),O( 2),O( 2), // Nemesis's tests
O( 0),O( 1),O( 2),O( 3),
O( 0),O( 1),O( 2),O( 3),
O( 0),O( 1),O( 2),O( 3),
O( 0),O( 1),O( 2),O( 3),
O( 0),O( 1),O( 2),O( 3),
O( 0),O( 1),O( 2),O( 3),
O( 0),O( 1),O( 2),O( 3),
O( 0),O( 1),O( 2),O( 3),
O( 0),O( 1),O( 2),O( 3),
O( 0),O( 1),O( 2),O( 3),
/* rate 12 */
O( 4),O( 5),O( 6),O( 7),
/* rate 13 */
O( 8),O( 9),O(10),O(11),
/* rate 14 */
O(12),O(13),O(14),O(15),
/* rate 15 */
O(16),O(16),O(16),O(16),
/* 32 dummy rates (same as 15 3) */
O(16),O(16),O(16),O(16),O(16),O(16),O(16),O(16),
O(16),O(16),O(16),O(16),O(16),O(16),O(16),O(16),
O(16),O(16),O(16),O(16),O(16),O(16),O(16),O(16),
O(16),O(16),O(16),O(16),O(16),O(16),O(16),O(16)
};
#undef O
/*rate 0, 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15*/
/*shift 11, 10, 9, 8, 7, 6, 5, 4, 3, 2, 1, 0, 0, 0, 0, 0 */
/*mask 2047, 1023, 511, 255, 127, 63, 31, 15, 7, 3, 1, 0, 0, 0, 0, 0 */
#define O(a) (a*1)
static const UINT8 eg_rate_shift[32+64+32]={ /* Envelope Generator counter shifts (32 + 64 rates + 32 RKS) */
/* 32 infinite time rates */
O(0),O(0),O(0),O(0),O(0),O(0),O(0),O(0),
O(0),O(0),O(0),O(0),O(0),O(0),O(0),O(0),
O(0),O(0),O(0),O(0),O(0),O(0),O(0),O(0),
O(0),O(0),O(0),O(0),O(0),O(0),O(0),O(0),
/* rates 00-11 */
O(11),O(11),O(11),O(11),
O(10),O(10),O(10),O(10),
O( 9),O( 9),O( 9),O( 9),
O( 8),O( 8),O( 8),O( 8),
O( 7),O( 7),O( 7),O( 7),
O( 6),O( 6),O( 6),O( 6),
O( 5),O( 5),O( 5),O( 5),
O( 4),O( 4),O( 4),O( 4),
O( 3),O( 3),O( 3),O( 3),
O( 2),O( 2),O( 2),O( 2),
O( 1),O( 1),O( 1),O( 1),
O( 0),O( 0),O( 0),O( 0),
/* rate 12 */
O( 0),O( 0),O( 0),O( 0),
/* rate 13 */
O( 0),O( 0),O( 0),O( 0),
/* rate 14 */
O( 0),O( 0),O( 0),O( 0),
/* rate 15 */
O( 0),O( 0),O( 0),O( 0),
/* 32 dummy rates (same as 15 3) */
O( 0),O( 0),O( 0),O( 0),O( 0),O( 0),O( 0),O( 0),
O( 0),O( 0),O( 0),O( 0),O( 0),O( 0),O( 0),O( 0),
O( 0),O( 0),O( 0),O( 0),O( 0),O( 0),O( 0),O( 0),
O( 0),O( 0),O( 0),O( 0),O( 0),O( 0),O( 0),O( 0)
};
#undef O
static const UINT8 dt_tab[4 * 32]={
/* this is YM2151 and YM2612 phase increment data (in 10.10 fixed point format)*/
/* 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
};
/* OPN key frequency number -> key code follow table */
/* fnum higher 4bit -> keycode lower 2bit */
static const UINT8 opn_fktable[16] = {0,0,0,0,0,0,0,1,2,3,3,3,3,3,3,3};
/* 8 LFO speed parameters */
/* each value represents number of samples that one LFO level will last for */
static const UINT32 lfo_samples_per_step[8] = {108, 77, 71, 67, 62, 44, 8, 5};
/*There are 4 different LFO AM depths available, they are:
0 dB, 1.4 dB, 5.9 dB, 11.8 dB
Here is how it is generated (in EG steps):
11.8 dB = 0, 2, 4, 6, 8, 10,12,14,16...126,126,124,122,120,118,....4,2,0
5.9 dB = 0, 1, 2, 3, 4, 5, 6, 7, 8....63, 63, 62, 61, 60, 59,.....2,1,0
1.4 dB = 0, 0, 0, 0, 1, 1, 1, 1, 2,...15, 15, 15, 15, 14, 14,.....0,0,0
(1.4 dB is loosing precision as you can see)
It's implemented as generator from 0..126 with step 2 then a shift
right N times, where N is:
8 for 0 dB
3 for 1.4 dB
1 for 5.9 dB
0 for 11.8 dB
*/
static const UINT8 lfo_ams_depth_shift[4] = {8, 3, 1, 0};
/*There are 8 different LFO PM depths available, they are:
0, 3.4, 6.7, 10, 14, 20, 40, 80 (cents)
Modulation level at each depth depends on F-NUMBER bits: 4,5,6,7,8,9,10
(bits 8,9,10 = FNUM MSB from OCT/FNUM register)
Here we store only first quarter (positive one) of full waveform.
Full table (lfo_pm_table) containing all 128 waveforms is build
at run (init) time.
One value in table below represents 4 (four) basic LFO steps
(1 PM step = 4 AM steps).
For example:
at LFO SPEED=0 (which is 108 samples per basic LFO step)
one value from "lfo_pm_output" table lasts for 432 consecutive
samples (4*108=432) and one full LFO waveform cycle lasts for 13824
samples (32*432=13824; 32 because we store only a quarter of whole
waveform in the table below)
*/
static const UINT8 lfo_pm_output[7*8][8]={ /* 7 bits meaningful (of F-NUMBER), 8 LFO output levels per one depth (out of 32), 8 LFO depths */
/* FNUM BIT 4: 000 0001xxxx */
/* DEPTH 0 */ {0, 0, 0, 0, 0, 0, 0, 0},
/* DEPTH 1 */ {0, 0, 0, 0, 0, 0, 0, 0},
/* DEPTH 2 */ {0, 0, 0, 0, 0, 0, 0, 0},
/* DEPTH 3 */ {0, 0, 0, 0, 0, 0, 0, 0},
/* DEPTH 4 */ {0, 0, 0, 0, 0, 0, 0, 0},
/* DEPTH 5 */ {0, 0, 0, 0, 0, 0, 0, 0},
/* DEPTH 6 */ {0, 0, 0, 0, 0, 0, 0, 0},
/* DEPTH 7 */ {0, 0, 0, 0, 1, 1, 1, 1},
/* FNUM BIT 5: 000 0010xxxx */
/* DEPTH 0 */ {0, 0, 0, 0, 0, 0, 0, 0},
/* DEPTH 1 */ {0, 0, 0, 0, 0, 0, 0, 0},
/* DEPTH 2 */ {0, 0, 0, 0, 0, 0, 0, 0},
/* DEPTH 3 */ {0, 0, 0, 0, 0, 0, 0, 0},
/* DEPTH 4 */ {0, 0, 0, 0, 0, 0, 0, 0},
/* DEPTH 5 */ {0, 0, 0, 0, 0, 0, 0, 0},
/* DEPTH 6 */ {0, 0, 0, 0, 1, 1, 1, 1},
/* DEPTH 7 */ {0, 0, 1, 1, 2, 2, 2, 3},
/* FNUM BIT 6: 000 0100xxxx */
/* DEPTH 0 */ {0, 0, 0, 0, 0, 0, 0, 0},
/* DEPTH 1 */ {0, 0, 0, 0, 0, 0, 0, 0},
/* DEPTH 2 */ {0, 0, 0, 0, 0, 0, 0, 0},
/* DEPTH 3 */ {0, 0, 0, 0, 0, 0, 0, 0},
/* DEPTH 4 */ {0, 0, 0, 0, 0, 0, 0, 1},
/* DEPTH 5 */ {0, 0, 0, 0, 1, 1, 1, 1},
/* DEPTH 6 */ {0, 0, 1, 1, 2, 2, 2, 3},
/* DEPTH 7 */ {0, 0, 2, 3, 4, 4, 5, 6},
/* FNUM BIT 7: 000 1000xxxx */
/* DEPTH 0 */ {0, 0, 0, 0, 0, 0, 0, 0},
/* DEPTH 1 */ {0, 0, 0, 0, 0, 0, 0, 0},
/* DEPTH 2 */ {0, 0, 0, 0, 0, 0, 1, 1},
/* DEPTH 3 */ {0, 0, 0, 0, 1, 1, 1, 1},
/* DEPTH 4 */ {0, 0, 0, 1, 1, 1, 1, 2},
/* DEPTH 5 */ {0, 0, 1, 1, 2, 2, 2, 3},
/* DEPTH 6 */ {0, 0, 2, 3, 4, 4, 5, 6},
/* DEPTH 7 */ {0, 0, 4, 6, 8, 8, 0xa, 0xc},
/* FNUM BIT 8: 001 0000xxxx */
/* DEPTH 0 */ {0, 0, 0, 0, 0, 0, 0, 0},
/* DEPTH 1 */ {0, 0, 0, 0, 1, 1, 1, 1},
/* DEPTH 2 */ {0, 0, 0, 1, 1, 1, 2, 2},
/* DEPTH 3 */ {0, 0, 1, 1, 2, 2, 3, 3},
/* DEPTH 4 */ {0, 0, 1, 2, 2, 2, 3, 4},
/* DEPTH 5 */ {0, 0, 2, 3, 4, 4, 5, 6},
/* DEPTH 6 */ {0, 0, 4, 6, 8, 8, 0xa, 0xc},
/* DEPTH 7 */ {0, 0, 8, 0xc,0x10,0x10,0x14,0x18},
/* FNUM BIT 9: 010 0000xxxx */
/* DEPTH 0 */ {0, 0, 0, 0, 0, 0, 0, 0},
/* DEPTH 1 */ {0, 0, 0, 0, 2, 2, 2, 2},
/* DEPTH 2 */ {0, 0, 0, 2, 2, 2, 4, 4},
/* DEPTH 3 */ {0, 0, 2, 2, 4, 4, 6, 6},
/* DEPTH 4 */ {0, 0, 2, 4, 4, 4, 6, 8},
/* DEPTH 5 */ {0, 0, 4, 6, 8, 8, 0xa, 0xc},
/* DEPTH 6 */ {0, 0, 8, 0xc,0x10,0x10,0x14,0x18},
/* DEPTH 7 */ {0, 0,0x10,0x18,0x20,0x20,0x28,0x30},
/* FNUM BIT10: 100 0000xxxx */
/* DEPTH 0 */ {0, 0, 0, 0, 0, 0, 0, 0},
/* DEPTH 1 */ {0, 0, 0, 0, 4, 4, 4, 4},
/* DEPTH 2 */ {0, 0, 0, 4, 4, 4, 8, 8},
/* DEPTH 3 */ {0, 0, 4, 4, 8, 8, 0xc, 0xc},
/* DEPTH 4 */ {0, 0, 4, 8, 8, 8, 0xc,0x10},
/* DEPTH 5 */ {0, 0, 8, 0xc,0x10,0x10,0x14,0x18},
/* DEPTH 6 */ {0, 0,0x10,0x18,0x20,0x20,0x28,0x30},
/* DEPTH 7 */ {0, 0,0x20,0x30,0x40,0x40,0x50,0x60},
};
/* all 128 LFO PM waveforms */
static INT32 lfo_pm_table[128*8*32]; /* 128 combinations of 7 bits meaningful (of F-NUMBER), 8 LFO depths, 32 LFO output levels per one depth */
/* register number to channel number , slot offset */
#define OPN_CHAN(N) (N&3)
#define OPN_SLOT(N) ((N>>2)&3)
/* slot number */
#define SLOT1 0
#define SLOT2 2
#define SLOT3 1
#define SLOT4 3
/* struct describing a single operator (SLOT) */
typedef struct
{
INT32 *DT; /* detune :dt_tab[DT] */
UINT8 KSR; /* key scale rate :3-KSR */
UINT32 ar; /* attack rate */
UINT32 d1r; /* decay rate */
UINT32 d2r; /* sustain rate */
UINT32 rr; /* release rate */
UINT8 ksr; /* key scale rate :kcode>>(3-KSR) */
UINT32 mul; /* multiple :ML_TABLE[ML] */
/* Phase Generator */
UINT32 phase; /* phase counter */
INT32 Incr; /* phase step */
/* Envelope Generator */
UINT8 state; /* phase type */
UINT32 tl; /* total level: TL << 3 */
INT32 volume; /* envelope counter */
UINT32 sl; /* sustain level:sl_table[SL] */
UINT32 vol_out; /* current output from EG circuit (without AM from LFO) */
UINT8 eg_sh_ar; /* (attack state) */
UINT8 eg_sel_ar; /* (attack state) */
UINT8 eg_sh_d1r; /* (decay state) */
UINT8 eg_sel_d1r; /* (decay state) */
UINT8 eg_sh_d2r; /* (sustain state) */
UINT8 eg_sel_d2r; /* (sustain state) */
UINT8 eg_sh_rr; /* (release state) */
UINT8 eg_sel_rr; /* (release state) */
UINT8 ssg; /* SSG-EG waveform */
UINT8 ssgn; /* SSG-EG negated output */
UINT32 key; /* 0=last key was KEY OFF, 1=KEY ON */
/* LFO */
UINT32 AMmask; /* AM enable flag */
} FM_SLOT;
typedef struct
{
FM_SLOT SLOT[4]; /* four SLOTs (operators) */
UINT8 ALGO; /* algorithm */
UINT8 FB; /* feedback shift */
INT32 op1_out[2]; /* op1 output for feedback */
INT32 *connect1; /* SLOT1 output pointer */
INT32 *connect3; /* SLOT3 output pointer */
INT32 *connect2; /* SLOT2 output pointer */
INT32 *connect4; /* SLOT4 output pointer */
INT32 *mem_connect;/* where to put the delayed sample (MEM) */
INT32 mem_value; /* delayed sample (MEM) value */
INT32 pms; /* channel PMS */
UINT8 ams; /* channel AMS */
UINT32 fc; /* fnum,blk:adjusted to sample rate */
UINT8 kcode; /* key code: */
UINT32 block_fnum; /* current blk/fnum value for this slot (can be different betweeen slots of one channel in 3slot mode) */
} FM_CH;
typedef struct
{
int clock; /* master clock (Hz) */
int rate; /* sampling rate (Hz) */
double freqbase; /* frequency base */
int TimerBase; /* Timer base time */
UINT8 address[2]; /* address register */
UINT8 status; /* status flag */
UINT32 mode; /* mode CSM / 3SLOT */
UINT8 fn_h; /* freq latch */
int TA; /* timer a value */
double TAL; /* timer a base */
double TAC; /* timer a counter */
int TB; /* timer b */
double TBL; /* timer b base */
double TBC; /* timer b counter */
/* local time tables */
INT32 dt_tab[8][32];/* DeTune table */
} FM_ST;
/***********************************************************/
/* OPN unit */
/***********************************************************/
/* OPN 3slot struct */
typedef struct
{
UINT32 fc[3]; /* fnum3,blk3: calculated */
UINT8 fn_h; /* freq3 latch */
UINT8 kcode[3]; /* key code */
UINT32 block_fnum[3]; /* current fnum value for this slot (can be different betweeen slots of one channel in 3slot mode) */
} FM_3SLOT;
/* OPN/A/B common state */
typedef struct
{
FM_ST ST; /* general state */
FM_3SLOT SL3; /* 3 slot mode state */
unsigned int pan[6*2]; /* fm channels output masks (0xffffffff = enable) */
UINT32 eg_cnt; /* global envelope generator counter */
UINT32 eg_timer; /* global envelope generator counter works at frequency = chipclock/64/3 */
UINT32 eg_timer_add; /* step of eg_timer */
UINT32 eg_timer_overflow;/* envelope generator timer overlfows every 3 samples (on real chip) */
/* there are 2048 FNUMs that can be generated using FNUM/BLK registers
but LFO works with one more bit of a precision so we really need 4096 elements */
UINT32 fn_table[4096]; /* fnumber->increment counter */
/* LFO */
UINT32 lfo_cnt;
UINT32 lfo_inc;
UINT32 lfo_freq[8]; /* LFO FREQ table */
} FM_OPN;
typedef struct
{
FM_CH CH[6]; /* channel state */
UINT8 dacen; /* DAC mode */
INT32 dacout; /* DAC output */
FM_OPN OPN; /* OPN state */
} YM2612;
static YM2612 ym2612;
/* current chip state */
static INT32 m2,c1,c2; /* Phase Modulation input for operators 2,3,4 */
static INT32 mem; /* one sample delay memory */
static INT32 out_fm[8]; /* outputs of working channels */
static UINT32 LFO_AM; /* runtime LFO calculations helper */
static INT32 LFO_PM; /* runtime LFO calculations helper */
static int fn_max; /* maximal phase increment (used for phase overflow) */
/* limitter */
#define Limit(val, max,min) { \
if ( val > max ) val = max; \
else if ( val < min ) val = min; \
}
/* OPN Mode Register Write */
INLINE void set_timers(int v )
{
/* 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 ((ym2612.OPN.ST.mode ^ v) & 0xC0) ym2612.CH[2].SLOT[SLOT1].Incr=-1; /* recalculate phase (from gens) */
/* reload Timers */
if ((v&1) & !(ym2612.OPN.ST.mode&1)) ym2612.OPN.ST.TAC = ym2612.OPN.ST.TAL;
if ((v&2) & !(ym2612.OPN.ST.mode&2)) ym2612.OPN.ST.TBC = ym2612.OPN.ST.TBL;
/* reset Timers flags */
ym2612.OPN.ST.status &= (~v >> 4);
ym2612.OPN.ST.mode = v;
}
INLINE void FM_KEYON(FM_CH *CH , int s )
{
FM_SLOT *SLOT = &CH->SLOT[s];
//if( !SLOT->key )
if(SLOT->state <= EG_REL)
{
//SLOT->key = 1;
SLOT->phase = 0; /* restart Phase Generator */
SLOT->ssgn = (SLOT->ssg & 0x04) >> 1;
if ((SLOT->ar + SLOT->ksr) < 94 /*32+62*/)
{
SLOT->state = EG_ATT; /* phase -> Attack */
SLOT->volume = MAX_ATT_INDEX; /* fix Ecco 2 splash sound */
}
else
{
/* Attack Rate is maximal: directly switch to Decay */
SLOT->state = EG_DEC;
SLOT->volume = MIN_ATT_INDEX;
}
}
}
INLINE void FM_KEYOFF(FM_CH *CH , int s )
{
FM_SLOT *SLOT = &CH->SLOT[s];
//if( SLOT->key )
//{
//SLOT->key = 0;
if (SLOT->state>EG_REL)
{
SLOT->state = EG_REL; /* phase -> Release */
SLOT->ssgn = 0; /* reset Invert Flag (from Nemesis) */
}
// }
}
/* set algorithm connection */
static void setup_connection( FM_CH *CH, int ch )
{
INT32 *carrier = &out_fm[ch];
INT32 **om1 = &CH->connect1;
INT32 **om2 = &CH->connect3;
INT32 **oc1 = &CH->connect2;
INT32 **memc = &CH->mem_connect;
switch( CH->ALGO ){
case 0:
/* M1---C1---MEM---M2---C2---OUT */
*om1 = &c1;
*oc1 = &mem;
*om2 = &c2;
*memc= &m2;
break;
case 1:
/* M1------+-MEM---M2---C2---OUT */
/* C1-+ */
*om1 = &mem;
*oc1 = &mem;
*om2 = &c2;
*memc= &m2;
break;
case 2:
/* M1-----------------+-C2---OUT */
/* C1---MEM---M2-+ */
*om1 = &c2;
*oc1 = &mem;
*om2 = &c2;
*memc= &m2;
break;
case 3:
/* M1---C1---MEM------+-C2---OUT */
/* M2-+ */
*om1 = &c1;
*oc1 = &mem;
*om2 = &c2;
*memc= &c2;
break;
case 4:
/* M1---C1-+-OUT */
/* M2---C2-+ */
/* MEM: not used */
*om1 = &c1;
*oc1 = carrier;
*om2 = &c2;
*memc= &mem; /* store it anywhere where it will not be used */
break;
case 5:
/* +----C1----+ */
/* M1-+-MEM---M2-+-OUT */
/* +----C2----+ */
*om1 = 0; /* special mark */
*oc1 = carrier;
*om2 = carrier;
*memc= &m2;
break;
case 6:
/* M1---C1-+ */
/* M2-+-OUT */
/* C2-+ */
/* MEM: not used */
*om1 = &c1;
*oc1 = carrier;
*om2 = carrier;
*memc= &mem; /* store it anywhere where it will not be used */
break;
case 7:
/* M1-+ */
/* C1-+-OUT */
/* M2-+ */
/* C2-+ */
/* MEM: not used*/
*om1 = carrier;
*oc1 = carrier;
*om2 = carrier;
*memc= &mem; /* store it anywhere where it will not be used */
break;
}
CH->connect4 = carrier;
}
/* set detune & multiple */
INLINE void set_det_mul(FM_CH *CH,FM_SLOT *SLOT,int v)
{
SLOT->mul = (v&0x0f)? (v&0x0f)*2 : 1;
SLOT->DT = ym2612.OPN.ST.dt_tab[(v>>4)&7];
CH->SLOT[SLOT1].Incr=-1;
}
/* set total level */
INLINE void set_tl(FM_CH *CH,FM_SLOT *SLOT , int v)
{
SLOT->tl = (v&0x7f)<<(ENV_BITS-7); /* 7bit TL */
}
/* set attack rate & key scale */
INLINE void set_ar_ksr(FM_CH *CH,FM_SLOT *SLOT,int v)
{
SLOT->ar = (v&0x1f) ? (32 + ((v&0x1f)<<1)) : 0;
SLOT->KSR = 3-(v>>6);
CH->SLOT[SLOT1].Incr=-1;
}
/* set decay rate */
INLINE void set_dr(FM_SLOT *SLOT,int v)
{
SLOT->d1r = (v&0x1f) ? (32 + ((v&0x1f)<<1)) : 0;
SLOT->eg_sh_d1r = eg_rate_shift [SLOT->d1r + SLOT->ksr];
SLOT->eg_sel_d1r= eg_rate_select[SLOT->d1r + SLOT->ksr];
}
/* set sustain rate */
INLINE void set_sr(FM_SLOT *SLOT,int v)
{
SLOT->d2r = (v&0x1f) ? (32 + ((v&0x1f)<<1)) : 0;
SLOT->eg_sh_d2r = eg_rate_shift [SLOT->d2r + SLOT->ksr];
SLOT->eg_sel_d2r= eg_rate_select[SLOT->d2r + SLOT->ksr];
}
/* set release rate */
INLINE void set_sl_rr(FM_SLOT *SLOT,int v)
{
SLOT->sl = sl_table[ v>>4 ];
SLOT->rr = 34 + ((v&0x0f)<<2);
SLOT->eg_sh_rr = eg_rate_shift [SLOT->rr + SLOT->ksr];
SLOT->eg_sel_rr = eg_rate_select[SLOT->rr + SLOT->ksr];
}
INLINE signed int op_calc(UINT32 phase, unsigned int env, signed int pm)
{
UINT32 p;
p = (env<<3) + sin_tab[ ( ((signed int)((phase & ~FREQ_MASK) + (pm<<15))) >> FREQ_SH ) & SIN_MASK ];
if (p >= TL_TAB_LEN)
return 0;
return tl_tab[p];
}
INLINE signed int op_calc1(UINT32 phase, unsigned int env, signed int pm)
{
UINT32 p;
p = (env<<3) + sin_tab[ ( ((signed int)((phase & ~FREQ_MASK) + pm )) >> FREQ_SH ) & SIN_MASK ];
if (p >= TL_TAB_LEN)
return 0;
return tl_tab[p];
}
/* advance LFO to next sample */
INLINE void advance_lfo()
{
UINT8 pos;
UINT8 prev_pos;
if (ym2612.OPN.lfo_inc) /* LFO enabled ? */
{
prev_pos = ym2612.OPN.lfo_cnt>>LFO_SH & 127;
ym2612.OPN.lfo_cnt += ym2612.OPN.lfo_inc;
pos = ( ym2612.OPN.lfo_cnt >> LFO_SH) & 127;
/* update AM when LFO output changes */
/*if (prev_pos != pos)*/
/* actually I can't optimize is this way without rewritting chan_calc()
to use chip->lfo_am instead of global lfo_am */
{
/* triangle */
/* AM: 0 to 126 step +2, 126 to 0 step -2 */
if (pos<64)
LFO_AM = (pos&63) * 2;
else
LFO_AM = 126 - ((pos&63) * 2);
}
/* PM works with 4 times slower clock */
prev_pos >>= 2;
pos >>= 2;
/* update PM when LFO output changes */
/*if (prev_pos != pos)*/ /* can't use global lfo_pm for this optimization, must be chip->lfo_pm instead*/
{
LFO_PM = pos;
}
}
else
{
LFO_AM = 0;
LFO_PM = 0;
}
}
INLINE void advance_eg_channel(FM_SLOT *SLOT)
{
unsigned int out;
unsigned int swap_flag = 0;
unsigned int i;
i = 4; /* four operators per channel */
do
{
/* reset swap_flag (EkeEke) */
swap_flag = 0;
switch(SLOT->state)
{
case EG_ATT: /* attack phase */
if (!(ym2612.OPN.eg_cnt & ((1<<SLOT->eg_sh_ar)-1)))
{
SLOT->volume += (~SLOT->volume *
(eg_inc[SLOT->eg_sel_ar + ((ym2612.OPN.eg_cnt>>SLOT->eg_sh_ar)&7)])
)>>4;
if (SLOT->volume <= MIN_ATT_INDEX)
{
SLOT->volume = MIN_ATT_INDEX;
SLOT->state = EG_DEC;
}
}
break;
case EG_DEC: /* decay phase */
if (SLOT->ssg&0x08) /* SSG EG type envelope selected */
{
if ( !(ym2612.OPN.eg_cnt & ((1<<SLOT->eg_sh_d1r)-1) ) )
{
//SLOT->volume += 4 * eg_inc[SLOT->eg_sel_d1r + ((ym2612.OPN.eg_cnt>>SLOT->eg_sh_d1r)&7)];
SLOT->volume += 6 * eg_inc[SLOT->eg_sel_d1r + ((ym2612.OPN.eg_cnt>>SLOT->eg_sh_d1r)&7)]; /* from Nemesis */
if ( SLOT->volume >= (INT32)(SLOT->sl) )
SLOT->state = EG_SUS;
}
}
else
{
if ( !(ym2612.OPN.eg_cnt & ((1<<SLOT->eg_sh_d1r)-1) ) )
{
SLOT->volume += eg_inc[SLOT->eg_sel_d1r + ((ym2612.OPN.eg_cnt>>SLOT->eg_sh_d1r)&7)];
if ( SLOT->volume >= (INT32)(SLOT->sl) )
SLOT->state = EG_SUS;
}
}
break;
case EG_SUS: /* sustain phase */
if (SLOT->ssg&0x08) /* SSG EG type envelope selected */
{
if ( !(ym2612.OPN.eg_cnt & ((1<<SLOT->eg_sh_d2r)-1) ) )
{
//SLOT->volume += 4 * eg_inc[SLOT->eg_sel_d2r + ((ym2612.OPN.eg_cnt>>SLOT->eg_sh_d2r)&7)];
SLOT->volume += 6 * eg_inc[SLOT->eg_sel_d2r + ((ym2612.OPN.eg_cnt>>SLOT->eg_sh_d2r)&7)]; /* from Nemesis */
if ( SLOT->volume >= MAX_ATT_INDEX)
{
SLOT->volume = MAX_ATT_INDEX;
if (SLOT->ssg&0x01) /* bit 0 = hold */
{
if (SLOT->ssgn&1) /* have we swapped once ??? */
{
/* yes, so do nothing, just hold current level */
}
else
swap_flag = (SLOT->ssg&0x02) | 1 ; /* bit 1 = alternate */
}
else
{
/* same as KEY-ON operation */
/* restart of the Phase Generator should be here */
SLOT->phase = 0;
if ((SLOT->ar + SLOT->ksr) < 94 /*32+62*/)
{
SLOT->state = EG_ATT; /* phase -> Attack */
SLOT->volume = MAX_ATT_INDEX;
}
else
{
/* Attack Rate is maximal: directly switch to Decay */
SLOT->state = EG_DEC;
SLOT->volume = MIN_ATT_INDEX;
}
swap_flag = (SLOT->ssg&0x02); /* bit 1 = alternate */
}
}
}
}
else
{
if ( !(ym2612.OPN.eg_cnt & ((1<<SLOT->eg_sh_d2r)-1) ) )
{
SLOT->volume += eg_inc[SLOT->eg_sel_d2r + ((ym2612.OPN.eg_cnt>>SLOT->eg_sh_d2r)&7)];
if ( SLOT->volume >= MAX_ATT_INDEX )
{
SLOT->volume = MAX_ATT_INDEX;
/* do not change SLOT->state (verified on real chip) */
}
}
}
break;
case EG_REL: /* release phase */
if ( !(ym2612.OPN.eg_cnt & ((1<<SLOT->eg_sh_rr)-1) ) )
{
if (SLOT->ssg&0x08)
{
SLOT->volume += 6 * eg_inc[SLOT->eg_sel_rr + ((ym2612.OPN.eg_cnt>>SLOT->eg_sh_rr)&7)]; /* from Nemesis */
}
else
{
SLOT->volume += eg_inc[SLOT->eg_sel_rr + ((ym2612.OPN.eg_cnt>>SLOT->eg_sh_rr)&7)];
}
if ( SLOT->volume >= MAX_ATT_INDEX )
{
SLOT->volume = MAX_ATT_INDEX;
SLOT->state = EG_OFF;
}
}
break;
}
out = /*SLOT->tl +*/ ((UINT32)SLOT->volume);
/* negate output (changes come from alternate bit, init comes from attack bit) */
if ((SLOT->ssg&0x08) && (SLOT->ssgn&2))
out ^= MAX_ATT_INDEX;
/* we need to store the result here because we are going to change ssgn
in next instruction */
SLOT->vol_out = out + SLOT->tl;
/* reverse SLOT inversion flag if required */
SLOT->ssgn ^= swap_flag;
SLOT++;
i--;
} while (i);
}
#define volume_calc(OP) ((OP)->vol_out + (AM & (OP)->AMmask))
INLINE void update_phase_lfo_slot(FM_SLOT *SLOT , INT32 pms, UINT32 block_fnum)
{
UINT32 fnum_lfo = ((block_fnum & 0x7f0) >> 4) * 32 * 8;
INT32 lfo_fn_table_index_offset = lfo_pm_table[ fnum_lfo + pms + LFO_PM ];
if (lfo_fn_table_index_offset) /* LFO phase modulation active */
{
block_fnum = block_fnum*2 + lfo_fn_table_index_offset;
UINT8 blk = (block_fnum&0x7000) >> 12;
UINT32 fn = block_fnum & 0xfff;
/* keyscale code */
int kc = (blk<<2) | opn_fktable[fn >> 8];
/* phase increment counter */
int fc = (ym2612.OPN.fn_table[fn]>>(7-blk)) + SLOT->DT[kc];
/* detects frequency overflow (credits to Nemesis) */
if (fc < 0) fc += fn_max;
/* update phase */
SLOT->phase += (fc * SLOT->mul) >> 1;
}
else /* LFO phase modulation = zero */
{
SLOT->phase += SLOT->Incr;
}
}
INLINE void update_phase_lfo_channel(FM_CH *CH)
{
UINT32 block_fnum = CH->block_fnum;
UINT32 fnum_lfo = ((block_fnum & 0x7f0) >> 4) * 32 * 8;
INT32 lfo_fn_table_index_offset = lfo_pm_table[ fnum_lfo + CH->pms + LFO_PM ];
if (lfo_fn_table_index_offset) /* LFO phase modulation active */
{
block_fnum = block_fnum*2 + lfo_fn_table_index_offset;
UINT8 blk = (block_fnum&0x7000) >> 12;
UINT32 fn = block_fnum & 0xfff;
/* keyscale code */
int kc = (blk<<2) | opn_fktable[fn >> 8];
/* phase increment counter */
int fc = (ym2612.OPN.fn_table[fn]>>(7-blk));
/* detects frequency overflow (credits to Nemesis) */
int finc = fc + CH->SLOT[SLOT1].DT[kc];
if (finc < 0) finc += fn_max;
CH->SLOT[SLOT1].phase += (finc*CH->SLOT[SLOT1].mul) >> 1;
finc = fc + CH->SLOT[SLOT2].DT[kc];
if (finc < 0) finc += fn_max;
CH->SLOT[SLOT2].phase += (finc*CH->SLOT[SLOT2].mul) >> 1;
finc = fc + CH->SLOT[SLOT3].DT[kc];
if (finc < 0) finc += fn_max;
CH->SLOT[SLOT3].phase += (finc*CH->SLOT[SLOT3].mul) >> 1;
finc = fc + CH->SLOT[SLOT4].DT[kc];
if (finc < 0) finc += fn_max;
CH->SLOT[SLOT4].phase += (finc*CH->SLOT[SLOT4].mul) >> 1;
}
else /* LFO phase modulation = zero */
{
CH->SLOT[SLOT1].phase += CH->SLOT[SLOT1].Incr;
CH->SLOT[SLOT2].phase += CH->SLOT[SLOT2].Incr;
CH->SLOT[SLOT3].phase += CH->SLOT[SLOT3].Incr;
CH->SLOT[SLOT4].phase += CH->SLOT[SLOT4].Incr;
}
}
INLINE void chan_calc(FM_CH *CH)
{
unsigned int eg_out;
UINT32 AM = LFO_AM >> CH->ams;
m2 = c1 = c2 = mem = 0;
*CH->mem_connect = CH->mem_value; /* restore delayed sample (MEM) value to m2 or c2 */
eg_out = volume_calc(&CH->SLOT[SLOT1]);
{
INT32 out = CH->op1_out[0] + CH->op1_out[1];
CH->op1_out[0] = CH->op1_out[1];
if( !CH->connect1 ){
/* algorithm 5 */
mem = c1 = c2 = CH->op1_out[0];
}else{
/* other algorithms */
*CH->connect1 += CH->op1_out[0];
}
CH->op1_out[1] = 0;
if( eg_out < ENV_QUIET ) /* SLOT 1 */
{
if (!CH->FB)
out=0;
CH->op1_out[1] = op_calc1(CH->SLOT[SLOT1].phase, eg_out, (out<<CH->FB) );
}
}
eg_out = volume_calc(&CH->SLOT[SLOT3]);
if( eg_out < ENV_QUIET ) /* SLOT 3 */
*CH->connect3 += op_calc(CH->SLOT[SLOT3].phase, eg_out, m2);
eg_out = volume_calc(&CH->SLOT[SLOT2]);
if( eg_out < ENV_QUIET ) /* SLOT 2 */
*CH->connect2 += op_calc(CH->SLOT[SLOT2].phase, eg_out, c1);
eg_out = volume_calc(&CH->SLOT[SLOT4]);
if( eg_out < ENV_QUIET ) /* SLOT 4 */
*CH->connect4 += op_calc(CH->SLOT[SLOT4].phase, eg_out, c2);
/* store current MEM */
CH->mem_value = mem;
/* update phase counters AFTER output calculations */
if(CH->pms)
{
/* add support for 3 slot mode */
if ((ym2612.OPN.ST.mode & 0xC0) && (CH == &ym2612.CH[2]))
{
update_phase_lfo_slot(&ym2612.CH[2].SLOT[SLOT1], ym2612.CH[2].pms, ym2612.OPN.SL3.block_fnum[1]);
update_phase_lfo_slot(&ym2612.CH[2].SLOT[SLOT2], ym2612.CH[2].pms, ym2612.OPN.SL3.block_fnum[2]);
update_phase_lfo_slot(&ym2612.CH[2].SLOT[SLOT3], ym2612.CH[2].pms, ym2612.OPN.SL3.block_fnum[0]);
update_phase_lfo_slot(&ym2612.CH[2].SLOT[SLOT4], ym2612.CH[2].pms, ym2612.CH[2].block_fnum);
}
else update_phase_lfo_channel(CH);
}
else /* no LFO phase modulation */
{
CH->SLOT[SLOT1].phase += CH->SLOT[SLOT1].Incr;
CH->SLOT[SLOT2].phase += CH->SLOT[SLOT2].Incr;
CH->SLOT[SLOT3].phase += CH->SLOT[SLOT3].Incr;
CH->SLOT[SLOT4].phase += CH->SLOT[SLOT4].Incr;
}
}
/* update phase increment and envelope generator */
INLINE void refresh_fc_eg_slot(FM_SLOT *SLOT , int fc , int kc )
{
int ksr = kc >> SLOT->KSR;
fc += SLOT->DT[kc];
/* detects frequency overflow (credits to Nemesis) */
if (fc < 0) fc += fn_max;
/* (frequency) phase increment counter */
SLOT->Incr = (fc * SLOT->mul) >> 1;
if( SLOT->ksr != ksr )
{
SLOT->ksr = ksr;
/* recalculate envelope generator rates */
if ((SLOT->ar + SLOT->ksr) < 94 /*32+62*/)
{
SLOT->eg_sh_ar = eg_rate_shift [SLOT->ar + SLOT->ksr ];
SLOT->eg_sel_ar = eg_rate_select[SLOT->ar + SLOT->ksr ];
}
else
{
SLOT->eg_sh_ar = 0;
SLOT->eg_sel_ar = 17*RATE_STEPS;
}
SLOT->eg_sh_d1r = eg_rate_shift [SLOT->d1r + SLOT->ksr];
SLOT->eg_sel_d1r= eg_rate_select[SLOT->d1r + SLOT->ksr];
SLOT->eg_sh_d2r = eg_rate_shift [SLOT->d2r + SLOT->ksr];
SLOT->eg_sel_d2r= eg_rate_select[SLOT->d2r + SLOT->ksr];
SLOT->eg_sh_rr = eg_rate_shift [SLOT->rr + SLOT->ksr];
SLOT->eg_sel_rr = eg_rate_select[SLOT->rr + SLOT->ksr];
}
}
/* update phase increment counters */
INLINE void refresh_fc_eg_chan(FM_CH *CH )
{
if( CH->SLOT[SLOT1].Incr==-1){
int fc = CH->fc;
int kc = CH->kcode;
refresh_fc_eg_slot(&CH->SLOT[SLOT1] , fc , kc );
refresh_fc_eg_slot(&CH->SLOT[SLOT2] , fc , kc );
refresh_fc_eg_slot(&CH->SLOT[SLOT3] , fc , kc );
refresh_fc_eg_slot(&CH->SLOT[SLOT4] , fc , kc );
}
}
/* initialize time tables */
static void init_timetables(const UINT8 *dttable )
{
int i,d;
double rate;
/* DeTune table */
for (d = 0;d <= 3;d++)
{
for (i = 0;i <= 31;i++)
{
rate = ((double)dttable[d*32 + i]) * SIN_LEN * ym2612.OPN.ST.freqbase * (1<<FREQ_SH) / ((double)(1<<20));
ym2612.OPN.ST.dt_tab[d][i] = (INT32) rate;
ym2612.OPN.ST.dt_tab[d+4][i] = -ym2612.OPN.ST.dt_tab[d][i];
}
}
}
static void reset_channels(FM_CH *CH , int num )
{
int c,s;
for( c = 0 ; c < num ; c++ )
{
CH[c].fc = 0;
for(s = 0 ; s < 4 ; s++ )
{
CH[c].SLOT[s].ssg = 0;
CH[c].SLOT[s].ssgn = 0;
CH[c].SLOT[s].state= EG_OFF;
CH[c].SLOT[s].volume = MAX_ATT_INDEX;
CH[c].SLOT[s].vol_out= MAX_ATT_INDEX;
}
}
}
/* initialize generic tables */
static int init_tables(void)
{
signed int i,x;
signed int n;
double o,m;
for (x=0; x<TL_RES_LEN; x++)
{
m = (1<<16) / pow(2, (x+1) * (ENV_STEP/4.0) / 8.0);
m = floor(m);
/* we never reach (1<<16) here due to the (x+1) */
/* result fits within 16 bits at maximum */
n = (int)m; /* 16 bits here */
n >>= 4; /* 12 bits here */
if (n&1) /* round to nearest */
n = (n>>1)+1;
else
n = n>>1;
/* 11 bits here (rounded) */
n <<= 2; /* 13 bits here (as in real chip) */
tl_tab[ x*2 + 0 ] = n;
tl_tab[ x*2 + 1 ] = -tl_tab[ x*2 + 0 ];
for (i=1; i<13; i++)
{
tl_tab[ x*2+0 + i*2*TL_RES_LEN ] = tl_tab[ x*2+0 ]>>i;
tl_tab[ x*2+1 + i*2*TL_RES_LEN ] = -tl_tab[ x*2+0 + i*2*TL_RES_LEN ];
}
}
for (i=0; i<SIN_LEN; i++)
{
/* non-standard sinus */
m = sin( ((i*2)+1) * M_PI / SIN_LEN ); /* checked against the real chip */
/* we never reach zero here due to ((i*2)+1) */
if (m>0.0)
o = 8*log(1.0/m)/log(2); /* convert to 'decibels' */
else
o = 8*log(-1.0/m)/log(2); /* convert to 'decibels' */
o = o / (ENV_STEP/4);
n = (int)(2.0*o);
if (n&1) /* round to nearest */
n = (n>>1)+1;
else
n = n>>1;
sin_tab[ i ] = n*2 + (m>=0.0? 0: 1 );
}
/* build LFO PM modulation table */
for(i = 0; i < 8; i++) /* 8 PM depths */
{
UINT8 fnum;
for (fnum=0; fnum<128; fnum++) /* 7 bits meaningful of F-NUMBER */
{
UINT8 value;
UINT8 step;
UINT32 offset_depth = i;
UINT32 offset_fnum_bit;
UINT32 bit_tmp;
for (step=0; step<8; step++)
{
value = 0;
for (bit_tmp=0; bit_tmp<7; bit_tmp++) /* 7 bits */
{
if (fnum & (1<<bit_tmp)) /* only if bit "bit_tmp" is set */
{
offset_fnum_bit = bit_tmp * 8;
value += lfo_pm_output[offset_fnum_bit + offset_depth][step];
}
}
lfo_pm_table[(fnum*32*8) + (i*32) + step + 0] = value;
lfo_pm_table[(fnum*32*8) + (i*32) +(step^7)+ 8] = value;
lfo_pm_table[(fnum*32*8) + (i*32) + step +16] = -value;
lfo_pm_table[(fnum*32*8) + (i*32) +(step^7)+24] = -value;
}
}
}
return 1;
}
/* CSM Key Controll */
INLINE void CSMKeyControll(FM_CH *CH)
{
/* correct implementation (credits to Nemesis) */
/* all key on */
FM_KEYON(CH,SLOT1);
FM_KEYON(CH,SLOT2);
FM_KEYON(CH,SLOT3);
FM_KEYON(CH,SLOT4);
/* all key off */
FM_KEYOFF(CH,SLOT1);
FM_KEYOFF(CH,SLOT2);
FM_KEYOFF(CH,SLOT3);
FM_KEYOFF(CH,SLOT4);
}
static void INTERNAL_TIMER_A()
{
if (ym2612.OPN.ST.mode & 0x01)
{
if ((ym2612.OPN.ST.TAC -= ym2612.OPN.ST.TimerBase) <= 0)
{
/* set status (if enabled) */
if (ym2612.OPN.ST.mode & 0x04) ym2612.OPN.ST.status |= 0x01;
/* reload the counter */
ym2612.OPN.ST.TAC += ym2612.OPN.ST.TAL;
/* CSM mode total level latch and auto key on */
if ((ym2612.OPN.ST.mode & 0xC0) == 0x80) CSMKeyControll (&(ym2612.CH[2]));
}
}
}
static void INTERNAL_TIMER_B(int step)
{
if (ym2612.OPN.ST.mode & 0x02)
{
if ((ym2612.OPN.ST.TBC -= (ym2612.OPN.ST.TimerBase * (double)step)) <= 0)
{
/* set status (if enabled) */
if (ym2612.OPN.ST.mode & 0x08) ym2612.OPN.ST.status |= 0x02;
/* reload the counter */
ym2612.OPN.ST.TBC += ym2612.OPN.ST.TBL;
}
}
}
/* prescaler set (and make time tables) */
static void OPNSetPres(int pres)
{
int i;
if (config.hq_fm)
{
ym2612.OPN.ST.rate = ym2612.OPN.ST.clock / pres;
}
/* frequency base */
ym2612.OPN.ST.freqbase = ((double) ym2612.OPN.ST.clock / (double) ym2612.OPN.ST.rate) / ((double) pres);
/* timer increment in usecs (timers are incremented after each updated samples) */
ym2612.OPN.ST.TimerBase = 1000000.0 / (double)ym2612.OPN.ST.rate;
ym2612.OPN.eg_timer_add = (UINT32)((1<<EG_SH) * ym2612.OPN.ST.freqbase);
//ym2612.OPN.eg_timer_overflow = ( 3 ) * (1<<EG_SH);
ym2612.OPN.eg_timer_overflow = (351 * (1<<EG_SH)) / 144; /* correct frequency (Nemesis: tested on real HW) */
/* make time tables */
init_timetables(dt_tab);
/* there are 2048 FNUMs that can be generated using FNUM/BLK registers
but LFO works with one more bit of a precision so we really need 4096 elements */
/* calculate fnumber -> increment counter table */
for(i = 0; i < 4096; i++)
{
/* freq table for octave 7 */
/* OPN phase increment counter = 20bit */
ym2612.OPN.fn_table[i] = (UINT32)( (double)i * 32 * ym2612.OPN.ST.freqbase * (1<<(FREQ_SH-10)) ); /* -10 because chip works with 10.10 fixed point, while we use 16.16 */
}
/* maximal frequency, used for overflow, best setting with BLOCK=5 (notaz) */
fn_max = ((UINT32)((double)ym2612.OPN.fn_table[0x7ff*2] / ym2612.OPN.ST.freqbase) >> 2);
/* LFO freq. table */
for(i = 0; i < 8; i++)
{
/* Amplitude modulation: 64 output levels (triangle waveform); 1 level lasts for one of "lfo_samples_per_step" samples */
/* Phase modulation: one entry from lfo_pm_output lasts for one of 4 * "lfo_samples_per_step" samples */
ym2612.OPN.lfo_freq[i] = (UINT32)((1.0 / lfo_samples_per_step[i]) * (1<<LFO_SH) * ym2612.OPN.ST.freqbase);
}
}
/* write a OPN mode register 0x20-0x2f */
static void OPNWriteMode(int r, int v)
{
UINT8 c;
FM_CH *CH;
switch(r){
case 0x21: /* Test */
break;
case 0x22: /* LFO FREQ (YM2608/YM2610/YM2610B/ym2612) */
if (v&0x08) /* LFO enabled ? */
{
ym2612.OPN.lfo_inc = ym2612.OPN.lfo_freq[v&7];
}
else
{
ym2612.OPN.lfo_inc = 0;
}
break;
case 0x24: /* timer A High 8*/
ym2612.OPN.ST.TA = (ym2612.OPN.ST.TA & 0x03)|(((int)v)<<2);
ym2612.OPN.ST.TAL = fm_timera_tab[ym2612.OPN.ST.TA];
break;
case 0x25: /* timer A Low 2*/
ym2612.OPN.ST.TA = (ym2612.OPN.ST.TA & 0x3fc)|(v&3);
ym2612.OPN.ST.TAL = fm_timera_tab[ym2612.OPN.ST.TA];
break;
case 0x26: /* timer B */
ym2612.OPN.ST.TB = v;
ym2612.OPN.ST.TBL = fm_timerb_tab[ym2612.OPN.ST.TB];
break;
case 0x27: /* mode, timer control */
set_timers(v);
break;
case 0x28: /* key on / off */
c = v & 0x03;
if( c == 3 ) break;
if (v&0x04) c+=3; /* CH 4-6 */
CH = &ym2612.CH[c];
if (v&0x10) FM_KEYON(CH,SLOT1); else FM_KEYOFF(CH,SLOT1);
if (v&0x20) FM_KEYON(CH,SLOT2); else FM_KEYOFF(CH,SLOT2);
if (v&0x40) FM_KEYON(CH,SLOT3); else FM_KEYOFF(CH,SLOT3);
if (v&0x80) FM_KEYON(CH,SLOT4); else FM_KEYOFF(CH,SLOT4);
break;
}
}
/* write a OPN register (0x30-0xff) */
static void OPNWriteReg(int r, int v)
{
FM_CH *CH;
FM_SLOT *SLOT;
UINT8 c = OPN_CHAN(r);
if (c == 3) return; /* 0xX3,0xX7,0xXB,0xXF */
if (r >= 0x100) c+=3;
CH = &ym2612.CH[c];
SLOT = &(CH->SLOT[OPN_SLOT(r)]);
switch( r & 0xf0 ) {
case 0x30: /* DET , MUL */
set_det_mul(CH,SLOT,v);
break;
case 0x40: /* TL */
set_tl(CH,SLOT,v);
break;
case 0x50: /* KS, AR */
set_ar_ksr(CH,SLOT,v);
break;
case 0x60: /* bit7 = AM ENABLE, DR */
set_dr(SLOT,v);
SLOT->AMmask = (v&0x80) ? ~0 : 0;
break;
case 0x70: /* SR */
set_sr(SLOT,v);
break;
case 0x80: /* SL, RR */
set_sl_rr(SLOT,v);
break;
case 0x90: /* SSG-EG */
SLOT->ssg = v&0x0f;
SLOT->ssgn = (v&0x04)>>1; /* bit 1 in ssgn = attack */
/* SSG-EG envelope shapes :
E AtAlH
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
The shapes are generated using Attack, Decay and Sustain phases.
Each single character in the diagrams above represents this whole
sequence:
- when KEY-ON = 1, normal Attack phase is generated (*without* any
difference when compared to normal mode),
- later, when envelope level reaches minimum level (max volume),
the EG switches to Decay phase (which works with bigger steps
when compared to normal mode - see below),
- later when envelope level passes the SL level,
the EG swithes to Sustain phase (which works with bigger steps
when compared to normal mode - see below),
- finally when envelope level reaches maximum level (min volume),
the EG switches to Attack phase again (depends on actual waveform).
Important is that when switch to Attack phase occurs, the phase counter
of that operator will be zeroed-out (as in normal KEY-ON) but not always.
(I havent found the rule for that - perhaps only when the output level is low)
The difference (when compared to normal Envelope Generator mode) is
that the resolution in Decay and Sustain phases is 4 times lower;
this results in only 256 steps instead of normal 1024.
In other words:
when SSG-EG is disabled, the step inside of the EG is one,
when SSG-EG is enabled, the step is four (in Decay and Sustain phases).
Times between the level changes are the same in both modes.
Important:
Decay 1 Level (so called SL) is compared to actual SSG-EG output, so
it is the same in both SSG and no-SSG modes, with this exception:
when the SSG-EG is enabled and is generating raising levels
(when the EG output is inverted) the SL will be found at wrong level !!!
For example, when SL=02:
0 -6 = -6dB in non-inverted EG output
96-6 = -90dB in inverted EG output
Which means that EG compares its level to SL as usual, and that the
output is simply inverted afterall.
The Yamaha's manuals say that AR should be set to 0x1f (max speed).
That is not necessary, but then EG will be generating Attack phase.
*/
break;
case 0xa0:
switch( OPN_SLOT(r) ){
case 0: /* 0xa0-0xa2 : FNUM1 */
{
UINT32 fn = (((UINT32)((ym2612.OPN.ST.fn_h)&7))<<8) + v;
UINT8 blk = ym2612.OPN.ST.fn_h>>3;
/* keyscale code */
CH->kcode = (blk<<2) | opn_fktable[fn >> 7];
/* phase increment counter */
CH->fc = ym2612.OPN.fn_table[fn*2]>>(7-blk);
/* store fnum in clear form for LFO PM calculations */
CH->block_fnum = (blk<<11) | fn;
CH->SLOT[SLOT1].Incr=-1;
}
break;
case 1: /* 0xa4-0xa6 : FNUM2,BLK */
ym2612.OPN.ST.fn_h = v&0x3f;
break;
case 2: /* 0xa8-0xaa : 3CH FNUM1 */
if(r < 0x100)
{
UINT32 fn = (((UINT32)(ym2612.OPN.SL3.fn_h&7))<<8) + v;
UINT8 blk = ym2612.OPN.SL3.fn_h>>3;
/* keyscale code */
ym2612.OPN.SL3.kcode[c]= (blk<<2) | opn_fktable[fn >> 7];
/* phase increment counter */
ym2612.OPN.SL3.fc[c] = ym2612.OPN.fn_table[fn*2]>>(7-blk);
ym2612.OPN.SL3.block_fnum[c] = (blk<<11) | fn; //fn;
ym2612.CH[2].SLOT[SLOT1].Incr=-1;
}
break;
case 3: /* 0xac-0xae : 3CH FNUM2,BLK */
if(r < 0x100)
ym2612.OPN.SL3.fn_h = v&0x3f;
break;
}
break;
case 0xb0:
switch( OPN_SLOT(r) ){
case 0: /* 0xb0-0xb2 : FB,ALGO */
{
int feedback = (v>>3)&7;
CH->ALGO = v&7;
CH->FB = feedback ? feedback+6 : 0;
setup_connection( CH, c );
}
break;
case 1: /* 0xb4-0xb6 : L , R , AMS , PMS (ym2612/YM2610B/YM2610/YM2608) */
/* b0-2 PMS */
CH->pms = (v & 7) * 32; /* CH->pms = PM depth * 32 (index in lfo_pm_table) */
/* b4-5 AMS */
CH->ams = lfo_ams_depth_shift[(v>>4) & 0x03];
/* PAN : b7 = L, b6 = R */
ym2612.OPN.pan[ c*2 ] = (v & 0x80) ? ~0 : 0;
ym2612.OPN.pan[ c*2+1 ] = (v & 0x40) ? ~0 : 0;
break;
}
break;
}
}
/* Generate 32bits samples for ym2612 */
void YM2612UpdateOne(int **buffer, int length)
{
int i;
int *bufL,*bufR;
int lt,rt;
/* set buffer */
bufL = buffer[0];
bufR = buffer[1];
/* refresh PG and EG */
refresh_fc_eg_chan(&ym2612.CH[0]);
refresh_fc_eg_chan(&ym2612.CH[1]);
if (ym2612.OPN.ST.mode & 0xC0)
{
/* 3SLOT MODE (operator order is 0,1,3,2) */
if(ym2612.CH[2].SLOT[SLOT1].Incr==-1)
{
refresh_fc_eg_slot(&ym2612.CH[2].SLOT[SLOT1] , ym2612.OPN.SL3.fc[1] , ym2612.OPN.SL3.kcode[1] );
refresh_fc_eg_slot(&ym2612.CH[2].SLOT[SLOT2] , ym2612.OPN.SL3.fc[2] , ym2612.OPN.SL3.kcode[2] );
refresh_fc_eg_slot(&ym2612.CH[2].SLOT[SLOT3] , ym2612.OPN.SL3.fc[0] , ym2612.OPN.SL3.kcode[0] );
refresh_fc_eg_slot(&ym2612.CH[2].SLOT[SLOT4] , ym2612.CH[2].fc , ym2612.CH[2].kcode );
}
}
else refresh_fc_eg_chan(&ym2612.CH[2]);
refresh_fc_eg_chan(&ym2612.CH[3]);
refresh_fc_eg_chan(&ym2612.CH[4]);
refresh_fc_eg_chan(&ym2612.CH[5]);
/* buffering */
for(i=0; i < length ; i++)
{
advance_lfo();
/* clear outputs */
out_fm[0] = 0;
out_fm[1] = 0;
out_fm[2] = 0;
out_fm[3] = 0;
out_fm[4] = 0;
out_fm[5] = 0;
/* advance envelope generator */
ym2612.OPN.eg_timer += ym2612.OPN.eg_timer_add;
while (ym2612.OPN.eg_timer >= ym2612.OPN.eg_timer_overflow)
{
ym2612.OPN.eg_timer -= ym2612.OPN.eg_timer_overflow;
ym2612.OPN.eg_cnt++;
advance_eg_channel(&ym2612.CH[0].SLOT[SLOT1]);
advance_eg_channel(&ym2612.CH[1].SLOT[SLOT1]);
advance_eg_channel(&ym2612.CH[2].SLOT[SLOT1]);
advance_eg_channel(&ym2612.CH[3].SLOT[SLOT1]);
advance_eg_channel(&ym2612.CH[4].SLOT[SLOT1]);
advance_eg_channel(&ym2612.CH[5].SLOT[SLOT1]);
}
/* calculate FM */
chan_calc(&ym2612.CH[0]);
chan_calc(&ym2612.CH[1]);
chan_calc(&ym2612.CH[2]);
chan_calc(&ym2612.CH[3]);
chan_calc(&ym2612.CH[4]);
/* DAC Mode */
if (ym2612.dacen)
{
*(ym2612.CH[5].connect4) += ym2612.dacout;
}
else chan_calc(&ym2612.CH[5]);
lt = ((out_fm[0]>>0) & ym2612.OPN.pan[0]);
rt = ((out_fm[0]>>0) & ym2612.OPN.pan[1]);
lt += ((out_fm[1]>>0) & ym2612.OPN.pan[2]);
rt += ((out_fm[1]>>0) & ym2612.OPN.pan[3]);
lt += ((out_fm[2]>>0) & ym2612.OPN.pan[4]);
rt += ((out_fm[2]>>0) & ym2612.OPN.pan[5]);
lt += ((out_fm[3]>>0) & ym2612.OPN.pan[6]);
rt += ((out_fm[3]>>0) & ym2612.OPN.pan[7]);
lt += ((out_fm[4]>>0) & ym2612.OPN.pan[8]);
rt += ((out_fm[4]>>0) & ym2612.OPN.pan[9]);
lt += ((out_fm[5]>>0) & ym2612.OPN.pan[10]);
rt += ((out_fm[5]>>0) & ym2612.OPN.pan[11]);
/* limiter */
Limit(lt,MAXOUT,MINOUT);
Limit(rt,MAXOUT,MINOUT);
/* buffering */
bufL[i] = lt;
bufR[i] = rt;
/* timer A control */
INTERNAL_TIMER_A();
}
INTERNAL_TIMER_B(length);
}
/* initialize ym2612 emulator(s) */
int YM2612Init(int clock, int rate)
{
memset(&ym2612,0,sizeof(YM2612));
init_tables();
ym2612.OPN.ST.clock = clock;
ym2612.OPN.ST.rate = rate;
YM2612ResetChip();
return 0;
}
/* reset */
int YM2612ResetChip(void)
{
int i;
OPNSetPres(6*24);
OPNWriteMode(0x27,0x30); /* mode 0 , timer reset */
ym2612.OPN.eg_timer = 0;
ym2612.OPN.eg_cnt = 0;
ym2612.OPN.ST.status = 0;
ym2612.OPN.ST.mode = 0;
ym2612.OPN.ST.TA = 0;
ym2612.OPN.ST.TAL = 0;
ym2612.OPN.ST.TAC = 0;
ym2612.OPN.ST.TB = 0;
ym2612.OPN.ST.TBL = 0;
ym2612.OPN.ST.TBC = 0;
reset_channels(&ym2612.CH[0] , 6 );
for(i = 0xb6 ; i >= 0xb4 ; i-- )
{
OPNWriteReg(i ,0xc0);
OPNWriteReg(i|0x100,0xc0);
}
for(i = 0xb2 ; i >= 0x30 ; i-- )
{
OPNWriteReg(i ,0);
OPNWriteReg(i|0x100,0);
}
for(i = 0x26 ; i >= 0x20 ; i-- ) OPNWriteReg(i,0);
/* DAC mode clear */
ym2612.dacen = 0;
ym2612.dacout = 0;
return 0;
}
/* ym2612 write */
/* n = number */
/* a = address */
/* v = value */
int YM2612Write(unsigned char a, unsigned char v)
{
int addr;
//v &= 0xff; /* adjust to 8 bit bus */
switch( a&3 )
{
case 0: /* address port 0 */
ym2612.OPN.ST.address[0] = v;
break;
case 1: /* data port 0 */
addr = ym2612.OPN.ST.address[0];
fm_reg[0][addr] = v;
switch( addr & 0xf0 )
{
case 0x20: /* 0x20-0x2f Mode */
switch( addr )
{
case 0x2a: /* DAC data (ym2612) */
ym2612.dacout = ((int)v - 0x80) << 6; /* level unknown (5 is too low, 8 is too loud) */
break;
case 0x2b: /* DAC Sel (ym2612) */
/* b7 = dac enable */
ym2612.dacen = v & 0x80;
break;
default: /* OPN section */
/* write register */
OPNWriteMode(addr,v);
}
break;
default: /* 0x30-0xff OPN section */
/* write register */
OPNWriteReg(addr,v);
}
break;
case 2: /* address port 1 */
ym2612.OPN.ST.address[1] = v;
break;
case 3: /* data port 1 */
addr = ym2612.OPN.ST.address[1];
fm_reg[1][addr] = v;
OPNWriteReg(addr | 0x100,v);
break;
}
return 0;
}
int YM2612Read(void)
{
return ym2612.OPN.ST.status;
}