added software scaler

[picodrive.git] / Pico / sound / ym2612.c

/*\r
** This is a bunch of remains of original fm.c from MAME project. All stuff\r
** unrelated to ym2612 was removed, multiple chip support was removed,\r
** some parts of code were slightly rewritten and tied to the emulator.\r
**\r
** SSG-EG was also removed, because it's rarely used, Sega2.doc even does not\r
** document it ("proprietary") and tells to write 0 to SSG-EG control register.\r
*/\r
\r
/*\r
**\r
** File: fm.c -- software implementation of Yamaha FM sound generator\r
**\r
** Copyright (C) 2001, 2002, 2003 Jarek Burczynski (bujar at mame dot net)\r
** Copyright (C) 1998 Tatsuyuki Satoh , MultiArcadeMachineEmulator development\r
**\r
** Version 1.4 (final beta)\r
**\r
*/\r
\r
/*\r
** History:\r
**\r
** 03-08-2003 Jarek Burczynski:\r
**  - fixed YM2608 initial values (after the reset)\r
**  - fixed flag and irqmask handling (YM2608)\r
**  - fixed BUFRDY flag handling (YM2608)\r
**\r
** 14-06-2003 Jarek Burczynski:\r
**  - implemented all of the YM2608 status register flags\r
**  - implemented support for external memory read/write via YM2608\r
**  - implemented support for deltat memory limit register in YM2608 emulation\r
**\r
** 22-05-2003 Jarek Burczynski:\r
**  - fixed LFO PM calculations (copy&paste bugfix)\r
**\r
** 08-05-2003 Jarek Burczynski:\r
**  - fixed SSG support\r
**\r
** 22-04-2003 Jarek Burczynski:\r
**  - implemented 100% correct LFO generator (verified on real YM2610 and YM2608)\r
**\r
** 15-04-2003 Jarek Burczynski:\r
**  - added support for YM2608's register 0x110 - status mask\r
**\r
** 01-12-2002 Jarek Burczynski:\r
**  - fixed register addressing in YM2608, YM2610, YM2610B chips. (verified on real YM2608)\r
**    The addressing patch used for early Neo-Geo games can be removed now.\r
**\r
** 26-11-2002 Jarek Burczynski, Nicola Salmoria:\r
**  - recreated YM2608 ADPCM ROM using data from real YM2608's output which leads to:\r
**  - added emulation of YM2608 drums.\r
**  - output of YM2608 is two times lower now - same as YM2610 (verified on real YM2608)\r
**\r
** 16-08-2002 Jarek Burczynski:\r
**  - binary exact Envelope Generator (verified on real YM2203);\r
**    identical to YM2151\r
**  - corrected 'off by one' error in feedback calculations (when feedback is off)\r
**  - corrected connection (algorithm) calculation (verified on real YM2203 and YM2610)\r
**\r
** 18-12-2001 Jarek Burczynski:\r
**  - added SSG-EG support (verified on real YM2203)\r
**\r
** 12-08-2001 Jarek Burczynski:\r
**  - corrected ym_sin_tab and ym_tl_tab data (verified on real chip)\r
**  - corrected feedback calculations (verified on real chip)\r
**  - corrected phase generator calculations (verified on real chip)\r
**  - corrected envelope generator calculations (verified on real chip)\r
**  - corrected FM volume level (YM2610 and YM2610B).\r
**  - changed YMxxxUpdateOne() functions (YM2203, YM2608, YM2610, YM2610B, YM2612) :\r
**    this was needed to calculate YM2610 FM channels output correctly.\r
**    (Each FM channel is calculated as in other chips, but the output of the channel\r
**    gets shifted right by one *before* sending to accumulator. That was impossible to do\r
**    with previous implementation).\r
**\r
** 23-07-2001 Jarek Burczynski, Nicola Salmoria:\r
**  - corrected YM2610 ADPCM type A algorithm and tables (verified on real chip)\r
**\r
** 11-06-2001 Jarek Burczynski:\r
**  - corrected end of sample bug in ADPCMA_calc_cha().\r
**    Real YM2610 checks for equality between current and end addresses (only 20 LSB bits).\r
**\r
** 08-12-98 hiro-shi:\r
** rename ADPCMA -> ADPCMB, ADPCMB -> ADPCMA\r
** move ROM limit check.(CALC_CH? -> 2610Write1/2)\r
** test program (ADPCMB_TEST)\r
** move ADPCM A/B end check.\r
** ADPCMB repeat flag(no check)\r
** change ADPCM volume rate (8->16) (32->48).\r
**\r
** 09-12-98 hiro-shi:\r
** change ADPCM volume. (8->16, 48->64)\r
** replace ym2610 ch0/3 (YM-2610B)\r
** change ADPCM_SHIFT (10->8) missing bank change 0x4000-0xffff.\r
** add ADPCM_SHIFT_MASK\r
** change ADPCMA_DECODE_MIN/MAX.\r
*/\r
\r
\r
\r
\r
/************************************************************************/\r
/*    comment of hiro-shi(Hiromitsu Shioya)                             */\r
/*    YM2610(B) = OPN-B                                                 */\r
/*    YM2610  : PSG:3ch FM:4ch ADPCM(18.5KHz):6ch DeltaT ADPCM:1ch      */\r
/*    YM2610B : PSG:3ch FM:6ch ADPCM(18.5KHz):6ch DeltaT ADPCM:1ch      */\r
/************************************************************************/\r
\r
//#include <stdio.h>\r
\r
#include <string.h>\r
#include <math.h>\r
\r
#include "ym2612.h"\r
\r
#ifndef EXTERNAL_YM2612\r
#include <stdlib.h>\r
// let it be 1 global to simplify things\r
static YM2612 ym2612;\r
\r
#else\r
extern YM2612 *ym2612_940;\r
#define ym2612 (*ym2612_940)\r
\r
#endif\r
\r
void memset32(int *dest, int c, int count);\r
\r
\r
#ifndef __GNUC__\r
#pragma warning (disable:4100) // unreferenced formal parameter\r
#pragma warning (disable:4244)\r
#pragma warning (disable:4245) // signed/unsigned in conversion\r
#pragma warning (disable:4710)\r
#pragma warning (disable:4018) // signed/unsigned\r
#endif\r
\r
#ifndef INLINE\r
#define INLINE static __inline\r
#endif\r
\r
#ifndef M_PI\r
#define M_PI    3.14159265358979323846\r
#endif\r
\r
\r
/* globals */\r
\r
#define FREQ_SH			16  /* 16.16 fixed point (frequency calculations) */\r
#define EG_SH			16  /* 16.16 fixed point (envelope generator timing) */\r
#define LFO_SH			25  /*  7.25 fixed point (LFO calculations)       */\r
#define TIMER_SH		16  /* 16.16 fixed point (timers calculations)    */\r
\r
#define ENV_BITS		10\r
#define ENV_LEN			(1<<ENV_BITS)\r
#define ENV_STEP		(128.0/ENV_LEN)\r
\r
#define MAX_ATT_INDEX	(ENV_LEN-1) /* 1023 */\r
#define MIN_ATT_INDEX	(0)			/* 0 */\r
\r
#define EG_ATT			4\r
#define EG_DEC			3\r
#define EG_SUS			2\r
#define EG_REL			1\r
#define EG_OFF			0\r
\r
#define SIN_BITS		10\r
#define SIN_LEN			(1<<SIN_BITS)\r
#define SIN_MASK		(SIN_LEN-1)\r
\r
#define TL_RES_LEN		(256) /* 8 bits addressing (real chip) */\r
\r
#define EG_TIMER_OVERFLOW (3*(1<<EG_SH)) /* envelope generator timer overflows every 3 samples (on real chip) */\r
\r
#define MAXOUT		(+32767)\r
#define MINOUT		(-32768)\r
\r
/* limitter */\r
#define Limit(val, max,min) { \\r
	if ( val > max )      val = max; \\r
	else if ( val < min ) val = min; \\r
}\r
\r
\r
/*  TL_TAB_LEN is calculated as:\r
*   13 - sinus amplitude bits     (Y axis)\r
*   2  - sinus sign bit           (Y axis)\r
*   TL_RES_LEN - sinus resolution (X axis)\r
*/\r
//#define TL_TAB_LEN (13*2*TL_RES_LEN)\r
#define TL_TAB_LEN (13*TL_RES_LEN*256/8) // 106496*2\r
UINT16 ym_tl_tab[TL_TAB_LEN];\r
\r
/* ~3K wasted but oh well */\r
UINT16 ym_tl_tab2[13*TL_RES_LEN];\r
\r
#define ENV_QUIET		(2*13*TL_RES_LEN/8)\r
\r
/* sin waveform table in 'decibel' scale (use only period/4 values) */\r
static UINT16 ym_sin_tab[256];\r
\r
/* sustain level table (3dB per step) */\r
/* bit0, bit1, bit2, bit3, bit4, bit5, bit6 */\r
/* 1,    2,    4,    8,    16,   32,   64   (value)*/\r
/* 0.75, 1.5,  3,    6,    12,   24,   48   (dB)*/\r
\r
/* 0 - 15: 0, 3, 6, 9,12,15,18,21,24,27,30,33,36,39,42,93 (dB)*/\r
#define SC(db) (UINT32) ( db * (4.0/ENV_STEP) )\r
static const UINT32 sl_table[16]={\r
 SC( 0),SC( 1),SC( 2),SC(3 ),SC(4 ),SC(5 ),SC(6 ),SC( 7),\r
 SC( 8),SC( 9),SC(10),SC(11),SC(12),SC(13),SC(14),SC(31)\r
};\r
#undef SC\r
\r
\r
#if 0\r
#define RATE_STEPS (8)\r
static const UINT8 eg_inc[19*RATE_STEPS]={\r
\r
/*cycle:0 1  2 3  4 5  6 7*/\r
\r
/* 0 */ 0,1, 0,1, 0,1, 0,1, /* rates 00..11 0 (increment by 0 or 1) */\r
/* 1 */ 0,1, 0,1, 1,1, 0,1, /* rates 00..11 1 */\r
/* 2 */ 0,1, 1,1, 0,1, 1,1, /* rates 00..11 2 */\r
/* 3 */ 0,1, 1,1, 1,1, 1,1, /* rates 00..11 3 */\r
\r
/* 4 */ 1,1, 1,1, 1,1, 1,1, /* rate 12 0 (increment by 1) */\r
/* 5 */ 1,1, 1,2, 1,1, 1,2, /* rate 12 1 */\r
/* 6 */ 1,2, 1,2, 1,2, 1,2, /* rate 12 2 */\r
/* 7 */ 1,2, 2,2, 1,2, 2,2, /* rate 12 3 */\r
\r
/* 8 */ 2,2, 2,2, 2,2, 2,2, /* rate 13 0 (increment by 2) */\r
/* 9 */ 2,2, 2,4, 2,2, 2,4, /* rate 13 1 */\r
/*10 */ 2,4, 2,4, 2,4, 2,4, /* rate 13 2 */\r
/*11 */ 2,4, 4,4, 2,4, 4,4, /* rate 13 3 */\r
\r
/*12 */ 4,4, 4,4, 4,4, 4,4, /* rate 14 0 (increment by 4) */\r
/*13 */ 4,4, 4,8, 4,4, 4,8, /* rate 14 1 */\r
/*14 */ 4,8, 4,8, 4,8, 4,8, /* rate 14 2 */\r
/*15 */ 4,8, 8,8, 4,8, 8,8, /* rate 14 3 */\r
\r
/*16 */ 8,8, 8,8, 8,8, 8,8, /* rates 15 0, 15 1, 15 2, 15 3 (increment by 8) */\r
/*17 */ 16,16,16,16,16,16,16,16, /* rates 15 2, 15 3 for attack */\r
/*18 */ 0,0, 0,0, 0,0, 0,0, /* infinity rates for attack and decay(s) */\r
};\r
#endif\r
\r
\r
#define PACK(a0,a1,a2,a3,a4,a5,a6,a7) ((a7<<21)|(a6<<18)|(a5<<15)|(a4<<12)|(a3<<9)|(a2<<6)|(a1<<3)|(a0<<0))\r
static const UINT32 eg_inc_pack[19] =\r
{\r
/* 0 */ PACK(0,1,0,1,0,1,0,1), /* rates 00..11 0 (increment by 0 or 1) */\r
/* 1 */ PACK(0,1,0,1,1,1,0,1), /* rates 00..11 1 */\r
/* 2 */ PACK(0,1,1,1,0,1,1,1), /* rates 00..11 2 */\r
/* 3 */ PACK(0,1,1,1,1,1,1,1), /* rates 00..11 3 */\r
\r
/* 4 */ PACK(1,1,1,1,1,1,1,1), /* rate 12 0 (increment by 1) */\r
/* 5 */ PACK(1,1,1,2,1,1,1,2), /* rate 12 1 */\r
/* 6 */ PACK(1,2,1,2,1,2,1,2), /* rate 12 2 */\r
/* 7 */ PACK(1,2,2,2,1,2,2,2), /* rate 12 3 */\r
\r
/* 8 */ PACK(2,2,2,2,2,2,2,2), /* rate 13 0 (increment by 2) */\r
/* 9 */ PACK(2,2,2,3,2,2,2,3), /* rate 13 1 */\r
/*10 */ PACK(2,3,2,3,2,3,2,3), /* rate 13 2 */\r
/*11 */ PACK(2,3,3,3,2,3,3,3), /* rate 13 3 */\r
\r
/*12 */ PACK(3,3,3,3,3,3,3,3), /* rate 14 0 (increment by 4) */\r
/*13 */ PACK(3,3,3,4,3,3,3,4), /* rate 14 1 */\r
/*14 */ PACK(3,4,3,4,3,4,3,4), /* rate 14 2 */\r
/*15 */ PACK(3,4,4,4,3,4,4,4), /* rate 14 3 */\r
\r
/*16 */ PACK(4,4,4,4,4,4,4,4), /* rates 15 0, 15 1, 15 2, 15 3 (increment by 8) */\r
/*17 */ PACK(5,5,5,5,5,5,5,5), /* rates 15 2, 15 3 for attack */\r
/*18 */ PACK(0,0,0,0,0,0,0,0), /* infinity rates for attack and decay(s) */\r
};\r
\r
\r
//#define O(a) (a*RATE_STEPS)\r
#define O(a) a\r
\r
/*note that there is no O(17) in this table - it's directly in the code */\r
static const UINT8 eg_rate_select[32+64+32]={	/* Envelope Generator rates (32 + 64 rates + 32 RKS) */\r
/* 32 infinite time rates */\r
O(18),O(18),O(18),O(18),O(18),O(18),O(18),O(18),\r
O(18),O(18),O(18),O(18),O(18),O(18),O(18),O(18),\r
O(18),O(18),O(18),O(18),O(18),O(18),O(18),O(18),\r
O(18),O(18),O(18),O(18),O(18),O(18),O(18),O(18),\r
\r
/* rates 00-11 */\r
O( 0),O( 1),O( 2),O( 3),\r
O( 0),O( 1),O( 2),O( 3),\r
O( 0),O( 1),O( 2),O( 3),\r
O( 0),O( 1),O( 2),O( 3),\r
O( 0),O( 1),O( 2),O( 3),\r
O( 0),O( 1),O( 2),O( 3),\r
O( 0),O( 1),O( 2),O( 3),\r
O( 0),O( 1),O( 2),O( 3),\r
O( 0),O( 1),O( 2),O( 3),\r
O( 0),O( 1),O( 2),O( 3),\r
O( 0),O( 1),O( 2),O( 3),\r
O( 0),O( 1),O( 2),O( 3),\r
\r
/* rate 12 */\r
O( 4),O( 5),O( 6),O( 7),\r
\r
/* rate 13 */\r
O( 8),O( 9),O(10),O(11),\r
\r
/* rate 14 */\r
O(12),O(13),O(14),O(15),\r
\r
/* rate 15 */\r
O(16),O(16),O(16),O(16),\r
\r
/* 32 dummy rates (same as 15 3) */\r
O(16),O(16),O(16),O(16),O(16),O(16),O(16),O(16),\r
O(16),O(16),O(16),O(16),O(16),O(16),O(16),O(16),\r
O(16),O(16),O(16),O(16),O(16),O(16),O(16),O(16),\r
O(16),O(16),O(16),O(16),O(16),O(16),O(16),O(16)\r
\r
};\r
#undef O\r
\r
/*rate  0,    1,    2,   3,   4,   5,  6,  7,  8,  9, 10, 11, 12, 13, 14, 15*/\r
/*shift 11,   10,   9,   8,   7,   6,  5,  4,  3,  2, 1,  0,  0,  0,  0,  0 */\r
/*mask  2047, 1023, 511, 255, 127, 63, 31, 15, 7,  3, 1,  0,  0,  0,  0,  0 */\r
\r
#define O(a) (a*1)\r
static const UINT8 eg_rate_shift[32+64+32]={	/* Envelope Generator counter shifts (32 + 64 rates + 32 RKS) */\r
/* 32 infinite time rates */\r
O(0),O(0),O(0),O(0),O(0),O(0),O(0),O(0),\r
O(0),O(0),O(0),O(0),O(0),O(0),O(0),O(0),\r
O(0),O(0),O(0),O(0),O(0),O(0),O(0),O(0),\r
O(0),O(0),O(0),O(0),O(0),O(0),O(0),O(0),\r
\r
/* rates 00-11 */\r
O(11),O(11),O(11),O(11),\r
O(10),O(10),O(10),O(10),\r
O( 9),O( 9),O( 9),O( 9),\r
O( 8),O( 8),O( 8),O( 8),\r
O( 7),O( 7),O( 7),O( 7),\r
O( 6),O( 6),O( 6),O( 6),\r
O( 5),O( 5),O( 5),O( 5),\r
O( 4),O( 4),O( 4),O( 4),\r
O( 3),O( 3),O( 3),O( 3),\r
O( 2),O( 2),O( 2),O( 2),\r
O( 1),O( 1),O( 1),O( 1),\r
O( 0),O( 0),O( 0),O( 0),\r
\r
/* rate 12 */\r
O( 0),O( 0),O( 0),O( 0),\r
\r
/* rate 13 */\r
O( 0),O( 0),O( 0),O( 0),\r
\r
/* rate 14 */\r
O( 0),O( 0),O( 0),O( 0),\r
\r
/* rate 15 */\r
O( 0),O( 0),O( 0),O( 0),\r
\r
/* 32 dummy rates (same as 15 3) */\r
O( 0),O( 0),O( 0),O( 0),O( 0),O( 0),O( 0),O( 0),\r
O( 0),O( 0),O( 0),O( 0),O( 0),O( 0),O( 0),O( 0),\r
O( 0),O( 0),O( 0),O( 0),O( 0),O( 0),O( 0),O( 0),\r
O( 0),O( 0),O( 0),O( 0),O( 0),O( 0),O( 0),O( 0)\r
\r
};\r
#undef O\r
\r
static const UINT8 dt_tab[4 * 32]={\r
/* this is YM2151 and YM2612 phase increment data (in 10.10 fixed point format)*/\r
/* FD=0 */\r
	0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0,\r
	0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0,\r
/* FD=1 */\r
	0, 0, 0, 0, 1, 1, 1, 1, 1, 1, 1, 1, 2, 2, 2, 2,\r
	2, 3, 3, 3, 4, 4, 4, 5, 5, 6, 6, 7, 8, 8, 8, 8,\r
/* FD=2 */\r
	1, 1, 1, 1, 2, 2, 2, 2, 2, 3, 3, 3, 4, 4, 4, 5,\r
	5, 6, 6, 7, 8, 8, 9,10,11,12,13,14,16,16,16,16,\r
/* FD=3 */\r
	2, 2, 2, 2, 2, 3, 3, 3, 4, 4, 4, 5, 5, 6, 6, 7,\r
	8 , 8, 9,10,11,12,13,14,16,17,19,20,22,22,22,22\r
};\r
\r
\r
/* OPN key frequency number -> key code follow table */\r
/* fnum higher 4bit -> keycode lower 2bit */\r
static const UINT8 opn_fktable[16] = {0,0,0,0,0,0,0,1,2,3,3,3,3,3,3,3};\r
\r
\r
/* 8 LFO speed parameters */\r
/* each value represents number of samples that one LFO level will last for */\r
static const UINT32 lfo_samples_per_step[8] = {108, 77, 71, 67, 62, 44, 8, 5};\r
\r
\r
\r
/*There are 4 different LFO AM depths available, they are:\r
  0 dB, 1.4 dB, 5.9 dB, 11.8 dB\r
  Here is how it is generated (in EG steps):\r
\r
  11.8 dB = 0, 2, 4, 6, 8, 10,12,14,16...126,126,124,122,120,118,....4,2,0\r
   5.9 dB = 0, 1, 2, 3, 4, 5, 6, 7, 8....63, 63, 62, 61, 60, 59,.....2,1,0\r
   1.4 dB = 0, 0, 0, 0, 1, 1, 1, 1, 2,...15, 15, 15, 15, 14, 14,.....0,0,0\r
\r
  (1.4 dB is loosing precision as you can see)\r
\r
  It's implemented as generator from 0..126 with step 2 then a shift\r
  right N times, where N is:\r
    8 for 0 dB\r
    3 for 1.4 dB\r
    1 for 5.9 dB\r
    0 for 11.8 dB\r
*/\r
static const UINT8 lfo_ams_depth_shift[4] = {8, 3, 1, 0};\r
\r
\r
\r
/*There are 8 different LFO PM depths available, they are:\r
  0, 3.4, 6.7, 10, 14, 20, 40, 80 (cents)\r
\r
  Modulation level at each depth depends on F-NUMBER bits: 4,5,6,7,8,9,10\r
  (bits 8,9,10 = FNUM MSB from OCT/FNUM register)\r
\r
  Here we store only first quarter (positive one) of full waveform.\r
  Full table (lfo_pm_table) containing all 128 waveforms is build\r
  at run (init) time.\r
\r
  One value in table below represents 4 (four) basic LFO steps\r
  (1 PM step = 4 AM steps).\r
\r
  For example:\r
   at LFO SPEED=0 (which is 108 samples per basic LFO step)\r
   one value from "lfo_pm_output" table lasts for 432 consecutive\r
   samples (4*108=432) and one full LFO waveform cycle lasts for 13824\r
   samples (32*432=13824; 32 because we store only a quarter of whole\r
            waveform in the table below)\r
*/\r
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 */\r
/* FNUM BIT 4: 000 0001xxxx */\r
/* DEPTH 0 */ {0,   0,   0,   0,   0,   0,   0,   0},\r
/* DEPTH 1 */ {0,   0,   0,   0,   0,   0,   0,   0},\r
/* DEPTH 2 */ {0,   0,   0,   0,   0,   0,   0,   0},\r
/* DEPTH 3 */ {0,   0,   0,   0,   0,   0,   0,   0},\r
/* DEPTH 4 */ {0,   0,   0,   0,   0,   0,   0,   0},\r
/* DEPTH 5 */ {0,   0,   0,   0,   0,   0,   0,   0},\r
/* DEPTH 6 */ {0,   0,   0,   0,   0,   0,   0,   0},\r
/* DEPTH 7 */ {0,   0,   0,   0,   1,   1,   1,   1},\r
\r
/* FNUM BIT 5: 000 0010xxxx */\r
/* DEPTH 0 */ {0,   0,   0,   0,   0,   0,   0,   0},\r
/* DEPTH 1 */ {0,   0,   0,   0,   0,   0,   0,   0},\r
/* DEPTH 2 */ {0,   0,   0,   0,   0,   0,   0,   0},\r
/* DEPTH 3 */ {0,   0,   0,   0,   0,   0,   0,   0},\r
/* DEPTH 4 */ {0,   0,   0,   0,   0,   0,   0,   0},\r
/* DEPTH 5 */ {0,   0,   0,   0,   0,   0,   0,   0},\r
/* DEPTH 6 */ {0,   0,   0,   0,   1,   1,   1,   1},\r
/* DEPTH 7 */ {0,   0,   1,   1,   2,   2,   2,   3},\r
\r
/* FNUM BIT 6: 000 0100xxxx */\r
/* DEPTH 0 */ {0,   0,   0,   0,   0,   0,   0,   0},\r
/* DEPTH 1 */ {0,   0,   0,   0,   0,   0,   0,   0},\r
/* DEPTH 2 */ {0,   0,   0,   0,   0,   0,   0,   0},\r
/* DEPTH 3 */ {0,   0,   0,   0,   0,   0,   0,   0},\r
/* DEPTH 4 */ {0,   0,   0,   0,   0,   0,   0,   1},\r
/* DEPTH 5 */ {0,   0,   0,   0,   1,   1,   1,   1},\r
/* DEPTH 6 */ {0,   0,   1,   1,   2,   2,   2,   3},\r
/* DEPTH 7 */ {0,   0,   2,   3,   4,   4,   5,   6},\r
\r
/* FNUM BIT 7: 000 1000xxxx */\r
/* DEPTH 0 */ {0,   0,   0,   0,   0,   0,   0,   0},\r
/* DEPTH 1 */ {0,   0,   0,   0,   0,   0,   0,   0},\r
/* DEPTH 2 */ {0,   0,   0,   0,   0,   0,   1,   1},\r
/* DEPTH 3 */ {0,   0,   0,   0,   1,   1,   1,   1},\r
/* DEPTH 4 */ {0,   0,   0,   1,   1,   1,   1,   2},\r
/* DEPTH 5 */ {0,   0,   1,   1,   2,   2,   2,   3},\r
/* DEPTH 6 */ {0,   0,   2,   3,   4,   4,   5,   6},\r
/* DEPTH 7 */ {0,   0,   4,   6,   8,   8, 0xa, 0xc},\r
\r
/* FNUM BIT 8: 001 0000xxxx */\r
/* DEPTH 0 */ {0,   0,   0,   0,   0,   0,   0,   0},\r
/* DEPTH 1 */ {0,   0,   0,   0,   1,   1,   1,   1},\r
/* DEPTH 2 */ {0,   0,   0,   1,   1,   1,   2,   2},\r
/* DEPTH 3 */ {0,   0,   1,   1,   2,   2,   3,   3},\r
/* DEPTH 4 */ {0,   0,   1,   2,   2,   2,   3,   4},\r
/* DEPTH 5 */ {0,   0,   2,   3,   4,   4,   5,   6},\r
/* DEPTH 6 */ {0,   0,   4,   6,   8,   8, 0xa, 0xc},\r
/* DEPTH 7 */ {0,   0,   8, 0xc,0x10,0x10,0x14,0x18},\r
\r
/* FNUM BIT 9: 010 0000xxxx */\r
/* DEPTH 0 */ {0,   0,   0,   0,   0,   0,   0,   0},\r
/* DEPTH 1 */ {0,   0,   0,   0,   2,   2,   2,   2},\r
/* DEPTH 2 */ {0,   0,   0,   2,   2,   2,   4,   4},\r
/* DEPTH 3 */ {0,   0,   2,   2,   4,   4,   6,   6},\r
/* DEPTH 4 */ {0,   0,   2,   4,   4,   4,   6,   8},\r
/* DEPTH 5 */ {0,   0,   4,   6,   8,   8, 0xa, 0xc},\r
/* DEPTH 6 */ {0,   0,   8, 0xc,0x10,0x10,0x14,0x18},\r
/* DEPTH 7 */ {0,   0,0x10,0x18,0x20,0x20,0x28,0x30},\r
\r
/* FNUM BIT10: 100 0000xxxx */\r
/* DEPTH 0 */ {0,   0,   0,   0,   0,   0,   0,   0},\r
/* DEPTH 1 */ {0,   0,   0,   0,   4,   4,   4,   4},\r
/* DEPTH 2 */ {0,   0,   0,   4,   4,   4,   8,   8},\r
/* DEPTH 3 */ {0,   0,   4,   4,   8,   8, 0xc, 0xc},\r
/* DEPTH 4 */ {0,   0,   4,   8,   8,   8, 0xc,0x10},\r
/* DEPTH 5 */ {0,   0,   8, 0xc,0x10,0x10,0x14,0x18},\r
/* DEPTH 6 */ {0,   0,0x10,0x18,0x20,0x20,0x28,0x30},\r
/* DEPTH 7 */ {0,   0,0x20,0x30,0x40,0x40,0x50,0x60},\r
\r
};\r
\r
/* all 128 LFO PM waveforms */\r
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 */\r
\r
/* there are 2048 FNUMs that can be generated using FNUM/BLK registers\r
	but LFO works with one more bit of a precision so we really need 4096 elements */\r
static UINT32 fn_table[4096];	/* fnumber->increment counter */\r
\r
static int g_lfo_ampm = 0;\r
\r
/* register number to channel number , slot offset */\r
#define OPN_CHAN(N) (N&3)\r
#define OPN_SLOT(N) ((N>>2)&3)\r
\r
/* slot number */\r
#define SLOT1 0\r
#define SLOT2 2\r
#define SLOT3 1\r
#define SLOT4 3\r
\r
\r
/* OPN Mode Register Write */\r
INLINE void set_timers( int v )\r
{\r
	/* b7 = CSM MODE */\r
	/* b6 = 3 slot mode */\r
	/* b5 = reset b */\r
	/* b4 = reset a */\r
	/* b3 = timer enable b */\r
	/* b2 = timer enable a */\r
	/* b1 = load b */\r
	/* b0 = load a */\r
	ym2612.OPN.ST.mode = v;\r
\r
	/* reset Timer b flag */\r
	if( v & 0x20 )\r
		ym2612.OPN.ST.status &= ~2;\r
\r
	/* reset Timer a flag */\r
	if( v & 0x10 )\r
		ym2612.OPN.ST.status &= ~1;\r
}\r
\r
\r
INLINE void FM_KEYON(FM_CH *CH , int s )\r
{\r
	FM_SLOT *SLOT = &CH->SLOT[s];\r
	if( !SLOT->key )\r
	{\r
		SLOT->key = 1;\r
		SLOT->phase = 0;		/* restart Phase Generator */\r
		SLOT->state = EG_ATT;	/* phase -> Attack */\r
	}\r
}\r
\r
INLINE void FM_KEYOFF(FM_CH *CH , int s )\r
{\r
	FM_SLOT *SLOT = &CH->SLOT[s];\r
	if( SLOT->key )\r
	{\r
		SLOT->key = 0;\r
		if (SLOT->state>EG_REL)\r
			SLOT->state = EG_REL;/* phase -> Release */\r
	}\r
}\r
\r
\r
/* set detune & multiple */\r
INLINE void set_det_mul(FM_CH *CH, FM_SLOT *SLOT, int v)\r
{\r
	SLOT->mul = (v&0x0f)? (v&0x0f)*2 : 1;\r
	SLOT->DT  = ym2612.OPN.ST.dt_tab[(v>>4)&7];\r
	CH->SLOT[SLOT1].Incr=-1;\r
}\r
\r
/* set total level */\r
INLINE void set_tl(FM_SLOT *SLOT, int v)\r
{\r
	SLOT->tl = (v&0x7f)<<(ENV_BITS-7); /* 7bit TL */\r
}\r
\r
/* set attack rate & key scale  */\r
INLINE void set_ar_ksr(FM_CH *CH, FM_SLOT *SLOT, int v)\r
{\r
	UINT8 old_KSR = SLOT->KSR;\r
\r
	SLOT->ar = (v&0x1f) ? 32 + ((v&0x1f)<<1) : 0;\r
\r
	SLOT->KSR = 3-(v>>6);\r
	if (SLOT->KSR != old_KSR)\r
	{\r
		CH->SLOT[SLOT1].Incr=-1;\r
	}\r
	else\r
	{\r
		int eg_sh_ar, eg_sel_ar;\r
\r
		/* refresh Attack rate */\r
		if ((SLOT->ar + SLOT->ksr) < 32+62)\r
		{\r
			eg_sh_ar  = eg_rate_shift [SLOT->ar  + SLOT->ksr ];\r
			eg_sel_ar = eg_rate_select[SLOT->ar  + SLOT->ksr ];\r
		}\r
		else\r
		{\r
			eg_sh_ar  = 0;\r
			eg_sel_ar = 17;\r
		}\r
\r
		SLOT->eg_pack_ar = eg_inc_pack[eg_sel_ar] | (eg_sh_ar<<24);\r
	}\r
}\r
\r
/* set decay rate */\r
INLINE void set_dr(FM_SLOT *SLOT, int v)\r
{\r
	int eg_sh_d1r, eg_sel_d1r;\r
\r
	SLOT->d1r = (v&0x1f) ? 32 + ((v&0x1f)<<1) : 0;\r
\r
	eg_sh_d1r = eg_rate_shift [SLOT->d1r + SLOT->ksr];\r
	eg_sel_d1r= eg_rate_select[SLOT->d1r + SLOT->ksr];\r
\r
	SLOT->eg_pack_d1r = eg_inc_pack[eg_sel_d1r] | (eg_sh_d1r<<24);\r
}\r
\r
/* set sustain rate */\r
INLINE void set_sr(FM_SLOT *SLOT, int v)\r
{\r
	int eg_sh_d2r, eg_sel_d2r;\r
\r
	SLOT->d2r = (v&0x1f) ? 32 + ((v&0x1f)<<1) : 0;\r
\r
	eg_sh_d2r = eg_rate_shift [SLOT->d2r + SLOT->ksr];\r
	eg_sel_d2r= eg_rate_select[SLOT->d2r + SLOT->ksr];\r
\r
	SLOT->eg_pack_d2r = eg_inc_pack[eg_sel_d2r] | (eg_sh_d2r<<24);\r
}\r
\r
/* set release rate */\r
INLINE void set_sl_rr(FM_SLOT *SLOT, int v)\r
{\r
	int eg_sh_rr, eg_sel_rr;\r
\r
	SLOT->sl = sl_table[ v>>4 ];\r
\r
	SLOT->rr  = 34 + ((v&0x0f)<<2);\r
\r
	eg_sh_rr  = eg_rate_shift [SLOT->rr  + SLOT->ksr];\r
	eg_sel_rr = eg_rate_select[SLOT->rr  + SLOT->ksr];\r
\r
	SLOT->eg_pack_rr = eg_inc_pack[eg_sel_rr] | (eg_sh_rr<<24);\r
}\r
\r
\r
\r
INLINE signed int op_calc(UINT32 phase, unsigned int env, signed int pm)\r
{\r
	int ret, sin = (phase>>16) + (pm>>1);\r
	int neg = sin & 0x200;\r
	if (sin & 0x100) sin ^= 0xff;\r
	sin&=0xff;\r
	env&=~1;\r
\r
	// this was already checked\r
	// if (env >= ENV_QUIET) // 384\r
	//	return 0;\r
\r
	ret = ym_tl_tab[sin | (env<<7)];\r
\r
	return neg ? -ret : ret;\r
}\r
\r
INLINE signed int op_calc1(UINT32 phase, unsigned int env, signed int pm)\r
{\r
	int ret, sin = (phase+pm)>>16;\r
	int neg = sin & 0x200;\r
	if (sin & 0x100) sin ^= 0xff;\r
	sin&=0xff;\r
	env&=~1;\r
\r
	// if (env >= ENV_QUIET) // 384\r
	//	return 0;\r
\r
	ret = ym_tl_tab[sin | (env<<7)];\r
\r
	return neg ? -ret : ret;\r
}\r
\r
#if !defined(_ASM_YM2612_C) || defined(EXTERNAL_YM2612)\r
/* advance LFO to next sample */\r
INLINE int advance_lfo(int lfo_ampm, UINT32 lfo_cnt_old, UINT32 lfo_cnt)\r
{\r
	UINT8 pos;\r
	UINT8 prev_pos;\r
\r
	prev_pos = (lfo_cnt_old >> LFO_SH) & 127;\r
\r
	pos = (lfo_cnt >> LFO_SH) & 127;\r
\r
	/* update AM when LFO output changes */\r
\r
	if (prev_pos != pos)\r
	{\r
		lfo_ampm &= 0xff;\r
		/* triangle */\r
		/* AM: 0 to 126 step +2, 126 to 0 step -2 */\r
		if (pos<64)\r
			lfo_ampm |= ((pos&63) * 2) << 8;           /* 0 - 126 */\r
		else\r
			lfo_ampm |= (126 - (pos&63)*2) << 8;\r
	}\r
	else\r
	{\r
		return lfo_ampm;\r
	}\r
\r
	/* PM works with 4 times slower clock */\r
	prev_pos >>= 2;\r
	pos >>= 2;\r
	/* update PM when LFO output changes */\r
	if (prev_pos != pos)\r
	{\r
		lfo_ampm &= ~0xff;\r
		lfo_ampm |= pos; /* 0 - 32 */\r
	}\r
	return lfo_ampm;\r
}\r
\r
#define EG_INC_VAL() \\r
	((1 << ((pack >> ((eg_cnt>>shift)&7)*3)&7)) >> 1)\r
\r
INLINE UINT32 update_eg_phase(FM_SLOT *SLOT, UINT32 eg_cnt)\r
{\r
	INT32 volume = SLOT->volume;\r
\r
	switch(SLOT->state)\r
	{\r
		case EG_ATT:		/* attack phase */\r
		{\r
			UINT32 pack = SLOT->eg_pack_ar;\r
			UINT32 shift = pack>>24;\r
			if ( !(eg_cnt & ((1<<shift)-1) ) )\r
			{\r
				volume += ( ~volume * EG_INC_VAL() ) >>4;\r
\r
				if (volume <= MIN_ATT_INDEX)\r
				{\r
					volume = MIN_ATT_INDEX;\r
					SLOT->state = EG_DEC;\r
				}\r
			}\r
			break;\r
		}\r
\r
		case EG_DEC:	/* decay phase */\r
		{\r
			UINT32 pack = SLOT->eg_pack_d1r;\r
			UINT32 shift = pack>>24;\r
			if ( !(eg_cnt & ((1<<shift)-1) ) )\r
			{\r
				volume += EG_INC_VAL();\r
\r
				if ( volume >= (INT32) SLOT->sl )\r
					SLOT->state = EG_SUS;\r
			}\r
			break;\r
		}\r
\r
		case EG_SUS:	/* sustain phase */\r
		{\r
			UINT32 pack = SLOT->eg_pack_d2r;\r
			UINT32 shift = pack>>24;\r
			if ( !(eg_cnt & ((1<<shift)-1) ) )\r
			{\r
				volume += EG_INC_VAL();\r
\r
				if ( volume >= MAX_ATT_INDEX )\r
				{\r
					volume = MAX_ATT_INDEX;\r
					/* do not change SLOT->state (verified on real chip) */\r
				}\r
			}\r
			break;\r
		}\r
\r
		case EG_REL:	/* release phase */\r
		{\r
			UINT32 pack = SLOT->eg_pack_rr;\r
			UINT32 shift = pack>>24;\r
			if ( !(eg_cnt & ((1<<shift)-1) ) )\r
			{\r
				volume += EG_INC_VAL();\r
\r
				if ( volume >= MAX_ATT_INDEX )\r
				{\r
					volume = MAX_ATT_INDEX;\r
					SLOT->state = EG_OFF;\r
				}\r
			}\r
			break;\r
		}\r
	}\r
\r
	SLOT->volume = volume;\r
	return SLOT->tl + ((UINT32)volume); /* tl is 7bit<<3, volume 0-1023 (0-2039 total) */\r
}\r
#endif\r
\r
\r
typedef struct\r
{\r
	UINT16 vol_out1; /* 00: current output from EG circuit (without AM from LFO) */\r
	UINT16 vol_out2;\r
	UINT16 vol_out3;\r
	UINT16 vol_out4;\r
	UINT32 pad[2];\r
	UINT32 phase1;   /* 10 */\r
	UINT32 phase2;\r
	UINT32 phase3;\r
	UINT32 phase4;\r
	UINT32 incr1;    /* 20: phase step */\r
	UINT32 incr2;\r
	UINT32 incr3;\r
	UINT32 incr4;\r
	UINT32 lfo_cnt;  /* 30 */\r
	UINT32 lfo_inc;\r
	INT32  mem;      /* one sample delay memory */\r
	UINT32 eg_cnt;   /* envelope generator counter */\r
	FM_CH  *CH;      /* 40: envelope generator counter */\r
	UINT32 eg_timer;\r
	UINT32 eg_timer_add;\r
	UINT32 pack;     // 4c: stereo, lastchan, disabled, lfo_enabled | pan_r, pan_l, ams[2] | AMmasks[4] | FB[4] | lfo_ampm[16]\r
	UINT32 algo;     /* 50: algo[3], was_update */\r
	INT32  op1_out;\r
} chan_rend_context;\r
\r
\r
#if !defined(_ASM_YM2612_C) || defined(EXTERNAL_YM2612)\r
static void chan_render_loop(chan_rend_context *ct, int *buffer, int length)\r
{\r
	int scounter;					/* sample counter */\r
\r
	/* sample generating loop */\r
	for (scounter = 0; scounter < length; scounter++)\r
	{\r
		int smp = 0;		/* produced sample */\r
		unsigned int eg_out, eg_out2, eg_out4;\r
\r
		if (ct->pack & 8) { /* LFO enabled ? (test Earthworm Jim in between demo 1 and 2) */\r
			ct->pack = (ct->pack&0xffff) | (advance_lfo(ct->pack >> 16, ct->lfo_cnt, ct->lfo_cnt + ct->lfo_inc) << 16);\r
			ct->lfo_cnt += ct->lfo_inc;\r
		}\r
\r
		ct->eg_timer += ct->eg_timer_add;\r
		while (ct->eg_timer >= EG_TIMER_OVERFLOW)\r
		{\r
			ct->eg_timer -= EG_TIMER_OVERFLOW;\r
			ct->eg_cnt++;\r
\r
			if (ct->CH->SLOT[SLOT1].state != EG_OFF) ct->vol_out1 = update_eg_phase(&ct->CH->SLOT[SLOT1], ct->eg_cnt);\r
			if (ct->CH->SLOT[SLOT2].state != EG_OFF) ct->vol_out2 = update_eg_phase(&ct->CH->SLOT[SLOT2], ct->eg_cnt);\r
			if (ct->CH->SLOT[SLOT3].state != EG_OFF) ct->vol_out3 = update_eg_phase(&ct->CH->SLOT[SLOT3], ct->eg_cnt);\r
			if (ct->CH->SLOT[SLOT4].state != EG_OFF) ct->vol_out4 = update_eg_phase(&ct->CH->SLOT[SLOT4], ct->eg_cnt);\r
		}\r
\r
		if (ct->pack & 4) continue; /* output disabled */\r
\r
		/* calculate channel sample */\r
		eg_out = ct->vol_out1;\r
		if ( (ct->pack & 8) && (ct->pack&(1<<(SLOT1+8))) ) eg_out += ct->pack >> (((ct->pack&0xc0)>>6)+24);\r
\r
		if( eg_out < ENV_QUIET )	/* SLOT 1 */\r
		{\r
			int out = 0;\r
\r
			if (ct->pack&0xf000) out = ((ct->op1_out>>16) + (ct->op1_out<<16>>16)) << ((ct->pack&0xf000)>>12); /* op1_out0 + op1_out1 */\r
			ct->op1_out <<= 16;\r
			ct->op1_out |= (unsigned short)op_calc1(ct->phase1, eg_out, out);\r
		} else {\r
			ct->op1_out <<= 16; /* op1_out0 = op1_out1; op1_out1 = 0; */\r
		}\r
\r
		eg_out  = ct->vol_out3; // volume_calc(&CH->SLOT[SLOT3]);\r
		eg_out2 = ct->vol_out2; // volume_calc(&CH->SLOT[SLOT2]);\r
		eg_out4 = ct->vol_out4; // volume_calc(&CH->SLOT[SLOT4]);\r
\r
		if (ct->pack & 8) {\r
			unsigned int add = ct->pack >> (((ct->pack&0xc0)>>6)+24);\r
			if (ct->pack & (1<<(SLOT3+8))) eg_out  += add;\r
			if (ct->pack & (1<<(SLOT2+8))) eg_out2 += add;\r
			if (ct->pack & (1<<(SLOT4+8))) eg_out4 += add;\r
		}\r
\r
		switch( ct->CH->ALGO )\r
		{\r
#if 0\r
			case 0: smp = upd_algo0(ct); break;\r
			case 1: smp = upd_algo1(ct); break;\r
			case 2: smp = upd_algo2(ct); break;\r
			case 3: smp = upd_algo3(ct); break;\r
			case 4: smp = upd_algo4(ct); break;\r
			case 5: smp = upd_algo5(ct); break;\r
			case 6: smp = upd_algo6(ct); break;\r
			case 7: smp = upd_algo7(ct); break;\r
#else\r
			case 0:\r
			{\r
				/* M1---C1---MEM---M2---C2---OUT */\r
				int m2,c1,c2=0;	/* Phase Modulation input for operators 2,3,4 */\r
				m2 = ct->mem;\r
				c1 = ct->op1_out>>16;\r
				if( eg_out  < ENV_QUIET ) {		/* SLOT 3 */\r
					c2  = op_calc(ct->phase3, eg_out,  m2);\r
				}\r
				if( eg_out2 < ENV_QUIET ) {		/* SLOT 2 */\r
					ct->mem = op_calc(ct->phase2, eg_out2, c1);\r
				}\r
				else ct->mem = 0;\r
				if( eg_out4 < ENV_QUIET ) {		/* SLOT 4 */\r
					smp = op_calc(ct->phase4, eg_out4, c2);\r
				}\r
				break;\r
			}\r
			case 1:\r
			{\r
				/* M1------+-MEM---M2---C2---OUT */\r
				/*      C1-+                     */\r
				int m2,c2=0;\r
				m2 = ct->mem;\r
				ct->mem = ct->op1_out>>16;\r
				if( eg_out  < ENV_QUIET ) {		/* SLOT 3 */\r
					c2  = op_calc(ct->phase3, eg_out,  m2);\r
				}\r
				if( eg_out2 < ENV_QUIET ) {		/* SLOT 2 */\r
					ct->mem+= op_calc(ct->phase2, eg_out2, 0);\r
				}\r
				if( eg_out4 < ENV_QUIET ) {		/* SLOT 4 */\r
					smp = op_calc(ct->phase4, eg_out4, c2);\r
				}\r
				break;\r
			}\r
			case 2:\r
			{\r
				/* M1-----------------+-C2---OUT */\r
				/*      C1---MEM---M2-+          */\r
				int m2,c2;\r
				m2 = ct->mem;\r
				c2 = ct->op1_out>>16;\r
				if( eg_out  < ENV_QUIET ) {		/* SLOT 3 */\r
					c2 += op_calc(ct->phase3, eg_out,  m2);\r
				}\r
				if( eg_out2 < ENV_QUIET ) {		/* SLOT 2 */\r
					ct->mem = op_calc(ct->phase2, eg_out2, 0);\r
				}\r
				else ct->mem = 0;\r
				if( eg_out4 < ENV_QUIET ) {		/* SLOT 4 */\r
					smp = op_calc(ct->phase4, eg_out4, c2);\r
				}\r
				break;\r
			}\r
			case 3:\r
			{\r
				/* M1---C1---MEM------+-C2---OUT */\r
				/*                 M2-+          */\r
				int c1,c2;\r
				c2 = ct->mem;\r
				c1 = ct->op1_out>>16;\r
				if( eg_out  < ENV_QUIET ) {		/* SLOT 3 */\r
					c2 += op_calc(ct->phase3, eg_out,  0);\r
				}\r
				if( eg_out2 < ENV_QUIET ) {		/* SLOT 2 */\r
					ct->mem = op_calc(ct->phase2, eg_out2, c1);\r
				}\r
				else ct->mem = 0;\r
				if( eg_out4 < ENV_QUIET ) {		/* SLOT 4 */\r
					smp = op_calc(ct->phase4, eg_out4, c2);\r
				}\r
				break;\r
			}\r
			case 4:\r
			{\r
				/* M1---C1-+-OUT */\r
				/* M2---C2-+     */\r
				/* MEM: not used */\r
				int c1,c2=0;\r
				c1 = ct->op1_out>>16;\r
				if( eg_out  < ENV_QUIET ) {		/* SLOT 3 */\r
					c2  = op_calc(ct->phase3, eg_out,  0);\r
				}\r
				if( eg_out2 < ENV_QUIET ) {		/* SLOT 2 */\r
					smp = op_calc(ct->phase2, eg_out2, c1);\r
				}\r
				if( eg_out4 < ENV_QUIET ) {		/* SLOT 4 */\r
					smp+= op_calc(ct->phase4, eg_out4, c2);\r
				}\r
				break;\r
			}\r
			case 5:\r
			{\r
				/*    +----C1----+     */\r
				/* M1-+-MEM---M2-+-OUT */\r
				/*    +----C2----+     */\r
				int m2,c1,c2;\r
				m2 = ct->mem;\r
				ct->mem = c1 = c2 = ct->op1_out>>16;\r
				if( eg_out < ENV_QUIET ) {		/* SLOT 3 */\r
					smp = op_calc(ct->phase3, eg_out, m2);\r
				}\r
				if( eg_out2 < ENV_QUIET ) {		/* SLOT 2 */\r
					smp+= op_calc(ct->phase2, eg_out2, c1);\r
				}\r
				if( eg_out4 < ENV_QUIET ) {		/* SLOT 4 */\r
					smp+= op_calc(ct->phase4, eg_out4, c2);\r
				}\r
				break;\r
			}\r
			case 6:\r
			{\r
				/* M1---C1-+     */\r
				/*      M2-+-OUT */\r
				/*      C2-+     */\r
				/* MEM: not used */\r
				int c1;\r
				c1 = ct->op1_out>>16;\r
				if( eg_out < ENV_QUIET ) {		/* SLOT 3 */\r
					smp = op_calc(ct->phase3, eg_out,  0);\r
				}\r
				if( eg_out2 < ENV_QUIET ) {		/* SLOT 2 */\r
					smp+= op_calc(ct->phase2, eg_out2, c1);\r
				}\r
				if( eg_out4 < ENV_QUIET ) {		/* SLOT 4 */\r
					smp+= op_calc(ct->phase4, eg_out4, 0);\r
				}\r
				break;\r
			}\r
			case 7:\r
			{\r
				/* M1-+     */\r
				/* C1-+-OUT */\r
				/* M2-+     */\r
				/* C2-+     */\r
				/* MEM: not used*/\r
				smp = ct->op1_out>>16;\r
				if( eg_out < ENV_QUIET ) {		/* SLOT 3 */\r
					smp += op_calc(ct->phase3, eg_out,  0);\r
				}\r
				if( eg_out2 < ENV_QUIET ) {		/* SLOT 2 */\r
					smp += op_calc(ct->phase2, eg_out2, 0);\r
				}\r
				if( eg_out4 < ENV_QUIET ) {		/* SLOT 4 */\r
					smp += op_calc(ct->phase4, eg_out4, 0);\r
				}\r
				break;\r
			}\r
#endif\r
		}\r
		/* done calculating channel sample */\r
\r
		/* mix sample to output buffer */\r
		if (smp) {\r
			if (ct->pack & 1) { /* stereo */\r
				if (ct->pack & 0x20) /* L */ /* TODO: check correctness */\r
					buffer[scounter*2] += smp;\r
				if (ct->pack & 0x10) /* R */\r
					buffer[scounter*2+1] += smp;\r
			} else {\r
				buffer[scounter] += smp;\r
			}\r
			ct->algo = 8; // algo is only used in asm, here only bit3 is used\r
		}\r
\r
		/* update phase counters AFTER output calculations */\r
		ct->phase1 += ct->incr1;\r
		ct->phase2 += ct->incr2;\r
		ct->phase3 += ct->incr3;\r
		ct->phase4 += ct->incr4;\r
	}\r
}\r
#else\r
void chan_render_loop(chan_rend_context *ct, int *buffer, unsigned short length);\r
#endif\r
\r
\r
static int chan_render(int *buffer, int length, FM_CH *CH, UINT32 flags) // flags: stereo, lastchan, disabled, ?, pan_r, pan_l\r
{\r
	chan_rend_context ct;\r
\r
	ct.CH = CH;\r
	ct.mem = CH->mem_value;		/* one sample delay memory */\r
	ct.lfo_cnt = ym2612.OPN.lfo_cnt;\r
	ct.lfo_inc = ym2612.OPN.lfo_inc;\r
\r
	flags &= 0x37;\r
\r
	if (ct.lfo_inc) {\r
		flags |= 8;\r
		flags |= g_lfo_ampm << 16;\r
		flags |= CH->AMmasks << 8;\r
		if (CH->ams == 8) // no ams\r
			 flags &= ~0xf00;\r
		else flags |= (CH->ams&3)<<6;\r
	}\r
	flags |= (CH->FB&0xf)<<12;				/* feedback shift */\r
	ct.pack = flags;\r
\r
	ct.eg_cnt = ym2612.OPN.eg_cnt;			/* envelope generator counter */\r
	ct.eg_timer = ym2612.OPN.eg_timer;\r
	ct.eg_timer_add = ym2612.OPN.eg_timer_add;\r
\r
	/* precalculate phase modulation incr */\r
	ct.phase1 = CH->SLOT[SLOT1].phase;\r
	ct.phase2 = CH->SLOT[SLOT2].phase;\r
	ct.phase3 = CH->SLOT[SLOT3].phase;\r
	ct.phase4 = CH->SLOT[SLOT4].phase;\r
\r
	/* current output from EG circuit (without AM from LFO) */\r
	ct.vol_out1 = CH->SLOT[SLOT1].tl + ((UINT32)CH->SLOT[SLOT1].volume);\r
	ct.vol_out2 = CH->SLOT[SLOT2].tl + ((UINT32)CH->SLOT[SLOT2].volume);\r
	ct.vol_out3 = CH->SLOT[SLOT3].tl + ((UINT32)CH->SLOT[SLOT3].volume);\r
	ct.vol_out4 = CH->SLOT[SLOT4].tl + ((UINT32)CH->SLOT[SLOT4].volume);\r
\r
	ct.op1_out = CH->op1_out;\r
	ct.algo = CH->ALGO & 7;\r
\r
	if(CH->pms)\r
	{\r
		/* add support for 3 slot mode */\r
		UINT32 block_fnum = CH->block_fnum;\r
\r
		UINT32 fnum_lfo   = ((block_fnum & 0x7f0) >> 4) * 32 * 8;\r
		INT32  lfo_fn_table_index_offset = lfo_pm_table[ fnum_lfo + CH->pms + ((ct.pack>>16)&0xff) ];\r
\r
		if (lfo_fn_table_index_offset)	/* LFO phase modulation active */\r
		{\r
			UINT8  blk;\r
			UINT32 fn;\r
			int kc,fc;\r
\r
			block_fnum = block_fnum*2 + lfo_fn_table_index_offset;\r
\r
			blk = (block_fnum&0x7000) >> 12;\r
			fn  = block_fnum & 0xfff;\r
\r
			/* keyscale code */\r
			kc = (blk<<2) | opn_fktable[fn >> 8];\r
			/* phase increment counter */\r
			fc = fn_table[fn]>>(7-blk);\r
\r
			ct.incr1 = ((fc+CH->SLOT[SLOT1].DT[kc])*CH->SLOT[SLOT1].mul) >> 1;\r
			ct.incr2 = ((fc+CH->SLOT[SLOT2].DT[kc])*CH->SLOT[SLOT2].mul) >> 1;\r
			ct.incr3 = ((fc+CH->SLOT[SLOT3].DT[kc])*CH->SLOT[SLOT3].mul) >> 1;\r
			ct.incr4 = ((fc+CH->SLOT[SLOT4].DT[kc])*CH->SLOT[SLOT4].mul) >> 1;\r
		}\r
		else	/* LFO phase modulation  = zero */\r
		{\r
			ct.incr1 = CH->SLOT[SLOT1].Incr;\r
			ct.incr2 = CH->SLOT[SLOT2].Incr;\r
			ct.incr3 = CH->SLOT[SLOT3].Incr;\r
			ct.incr4 = CH->SLOT[SLOT4].Incr;\r
		}\r
	}\r
	else	/* no LFO phase modulation */\r
	{\r
		ct.incr1 = CH->SLOT[SLOT1].Incr;\r
		ct.incr2 = CH->SLOT[SLOT2].Incr;\r
		ct.incr3 = CH->SLOT[SLOT3].Incr;\r
		ct.incr4 = CH->SLOT[SLOT4].Incr;\r
	}\r
\r
	chan_render_loop(&ct, buffer, length);\r
\r
	// write back persistent stuff:\r
	if (flags & 2) { /* last channel */\r
		ym2612.OPN.eg_cnt = ct.eg_cnt;\r
		ym2612.OPN.eg_timer = ct.eg_timer;\r
		g_lfo_ampm = ct.pack >> 16;\r
		ym2612.OPN.lfo_cnt = ct.lfo_cnt;\r
	}\r
\r
	CH->op1_out = ct.op1_out;\r
	CH->SLOT[SLOT1].phase = ct.phase1;\r
	CH->SLOT[SLOT2].phase = ct.phase2;\r
	CH->SLOT[SLOT3].phase = ct.phase3;\r
	CH->SLOT[SLOT4].phase = ct.phase4;\r
	CH->mem_value = ct.mem;\r
\r
	return (ct.algo & 8) >> 3; // had output\r
}\r
\r
/* update phase increment and envelope generator */\r
INLINE void refresh_fc_eg_slot(FM_SLOT *SLOT, int fc, int kc)\r
{\r
	int ksr;\r
\r
	/* (frequency) phase increment counter */\r
	SLOT->Incr = ((fc+SLOT->DT[kc])*SLOT->mul) >> 1;\r
\r
	ksr = kc >> SLOT->KSR;\r
	if( SLOT->ksr != ksr )\r
	{\r
		int eg_sh, eg_sel;\r
		SLOT->ksr = ksr;\r
\r
		/* calculate envelope generator rates */\r
		if ((SLOT->ar + SLOT->ksr) < 32+62)\r
		{\r
			eg_sh  = eg_rate_shift [SLOT->ar  + SLOT->ksr ];\r
			eg_sel = eg_rate_select[SLOT->ar  + SLOT->ksr ];\r
		}\r
		else\r
		{\r
			eg_sh  = 0;\r
			eg_sel = 17;\r
		}\r
\r
		SLOT->eg_pack_ar = eg_inc_pack[eg_sel] | (eg_sh<<24);\r
\r
		eg_sh  = eg_rate_shift [SLOT->d1r + SLOT->ksr];\r
		eg_sel = eg_rate_select[SLOT->d1r + SLOT->ksr];\r
\r
		SLOT->eg_pack_d1r = eg_inc_pack[eg_sel] | (eg_sh<<24);\r
\r
		eg_sh  = eg_rate_shift [SLOT->d2r + SLOT->ksr];\r
		eg_sel = eg_rate_select[SLOT->d2r + SLOT->ksr];\r
\r
		SLOT->eg_pack_d2r = eg_inc_pack[eg_sel] | (eg_sh<<24);\r
\r
		eg_sh  = eg_rate_shift [SLOT->rr  + SLOT->ksr];\r
		eg_sel = eg_rate_select[SLOT->rr  + SLOT->ksr];\r
\r
		SLOT->eg_pack_rr = eg_inc_pack[eg_sel] | (eg_sh<<24);\r
	}\r
}\r
\r
/* update phase increment counters */\r
INLINE void refresh_fc_eg_chan(FM_CH *CH)\r
{\r
	if( CH->SLOT[SLOT1].Incr==-1){\r
		int fc = CH->fc;\r
		int kc = CH->kcode;\r
		refresh_fc_eg_slot(&CH->SLOT[SLOT1] , fc , kc );\r
		refresh_fc_eg_slot(&CH->SLOT[SLOT2] , fc , kc );\r
		refresh_fc_eg_slot(&CH->SLOT[SLOT3] , fc , kc );\r
		refresh_fc_eg_slot(&CH->SLOT[SLOT4] , fc , kc );\r
	}\r
}\r
\r
/* initialize time tables */\r
static void init_timetables(const UINT8 *dttable)\r
{\r
	int i,d;\r
	double rate;\r
\r
	/* DeTune table */\r
	for (d = 0;d <= 3;d++){\r
		for (i = 0;i <= 31;i++){\r
			rate = ((double)dttable[d*32 + i]) * SIN_LEN  * ym2612.OPN.ST.freqbase  * (1<<FREQ_SH) / ((double)(1<<20));\r
			ym2612.OPN.ST.dt_tab[d][i]   = (INT32) rate;\r
			ym2612.OPN.ST.dt_tab[d+4][i] = -ym2612.OPN.ST.dt_tab[d][i];\r
		}\r
	}\r
}\r
\r
\r
static void reset_channels(FM_CH *CH, int num)\r
{\r
	int c,s;\r
\r
	ym2612.OPN.ST.mode   = 0;	/* normal mode */\r
	ym2612.OPN.ST.TA     = 0;\r
	ym2612.OPN.ST.TAC    = 0;\r
	ym2612.OPN.ST.TB     = 0;\r
	ym2612.OPN.ST.TBC    = 0;\r
\r
	for( c = 0 ; c < num ; c++ )\r
	{\r
		CH[c].fc = 0;\r
		for(s = 0 ; s < 4 ; s++ )\r
		{\r
			CH[c].SLOT[s].state= EG_OFF;\r
			CH[c].SLOT[s].volume = MAX_ATT_INDEX;\r
		}\r
	}\r
}\r
\r
/* initialize generic tables */\r
static void init_tables(void)\r
{\r
	signed int i,x,y,p;\r
	signed int n;\r
	double o,m;\r
\r
	for (i=0; i < 256; i++)\r
	{\r
		/* non-standard sinus */\r
		m = sin( ((i*2)+1) * M_PI / SIN_LEN ); /* checked against the real chip */\r
\r
		/* we never reach zero here due to ((i*2)+1) */\r
\r
		if (m>0.0)\r
			o = 8*log(1.0/m)/log(2);	/* convert to 'decibels' */\r
		else\r
			o = 8*log(-1.0/m)/log(2);	/* convert to 'decibels' */\r
\r
		o = o / (ENV_STEP/4);\r
\r
		n = (int)(2.0*o);\r
		if (n&1)						/* round to nearest */\r
			n = (n>>1)+1;\r
		else\r
			n = n>>1;\r
\r
		ym_sin_tab[ i ] = n;\r
		//dprintf("FM.C: sin [%4i]= %4i", i, ym_sin_tab[i]);\r
	}\r
\r
	//dprintf("FM.C: ENV_QUIET= %08x", ENV_QUIET );\r
\r
\r
	for (x=0; x < TL_RES_LEN; x++)\r
	{\r
		m = (1<<16) / pow(2, (x+1) * (ENV_STEP/4.0) / 8.0);\r
		m = floor(m);\r
\r
		/* we never reach (1<<16) here due to the (x+1) */\r
		/* result fits within 16 bits at maximum */\r
\r
		n = (int)m;		/* 16 bits here */\r
		n >>= 4;		/* 12 bits here */\r
		if (n&1)		/* round to nearest */\r
			n = (n>>1)+1;\r
		else\r
			n = n>>1;\r
						/* 11 bits here (rounded) */\r
		n <<= 2;		/* 13 bits here (as in real chip) */\r
		ym_tl_tab2[ x ] = n;\r
\r
		for (i=1; i < 13; i++)\r
		{\r
			ym_tl_tab2[ x + i*TL_RES_LEN ] = n >> i;\r
		}\r
	}\r
\r
	for (x=0; x < 256; x++)\r
	{\r
		int sin = ym_sin_tab[ x ];\r
\r
		for (y=0; y < 2*13*TL_RES_LEN/8; y+=2)\r
		{\r
			p = (y<<2) + sin;\r
			if (p >= 13*TL_RES_LEN)\r
				 ym_tl_tab[(y<<7) | x] = 0;\r
			else ym_tl_tab[(y<<7) | x] = ym_tl_tab2[p];\r
		}\r
	}\r
\r
\r
	/* build LFO PM modulation table */\r
	for(i = 0; i < 8; i++) /* 8 PM depths */\r
	{\r
		UINT8 fnum;\r
		for (fnum=0; fnum<128; fnum++) /* 7 bits meaningful of F-NUMBER */\r
		{\r
			UINT8 value;\r
			UINT8 step;\r
			UINT32 offset_depth = i;\r
			UINT32 offset_fnum_bit;\r
			UINT32 bit_tmp;\r
\r
			for (step=0; step<8; step++)\r
			{\r
				value = 0;\r
				for (bit_tmp=0; bit_tmp<7; bit_tmp++) /* 7 bits */\r
				{\r
					if (fnum & (1<<bit_tmp)) /* only if bit "bit_tmp" is set */\r
					{\r
						offset_fnum_bit = bit_tmp * 8;\r
						value += lfo_pm_output[offset_fnum_bit + offset_depth][step];\r
					}\r
				}\r
				lfo_pm_table[(fnum*32*8) + (i*32) + step   + 0] = value;\r
				lfo_pm_table[(fnum*32*8) + (i*32) +(step^7)+ 8] = value;\r
				lfo_pm_table[(fnum*32*8) + (i*32) + step   +16] = -value;\r
				lfo_pm_table[(fnum*32*8) + (i*32) +(step^7)+24] = -value;\r
			}\r
		}\r
	}\r
}\r
\r
\r
/* CSM Key Controll */\r
INLINE void CSMKeyControll(FM_CH *CH)\r
{\r
	/* this is wrong, atm */\r
\r
	/* all key on */\r
	FM_KEYON(CH,SLOT1);\r
	FM_KEYON(CH,SLOT2);\r
	FM_KEYON(CH,SLOT3);\r
	FM_KEYON(CH,SLOT4);\r
}\r
\r
\r
/* prescaler set (and make time tables) */\r
static void OPNSetPres(int pres)\r
{\r
	int i;\r
\r
	/* frequency base */\r
	ym2612.OPN.ST.freqbase = (ym2612.OPN.ST.rate) ? ((double)ym2612.OPN.ST.clock / ym2612.OPN.ST.rate) / pres : 0;\r
\r
	ym2612.OPN.eg_timer_add  = (1<<EG_SH) * ym2612.OPN.ST.freqbase;\r
\r
\r
	/* make time tables */\r
	init_timetables( dt_tab );\r
\r
	/* there are 2048 FNUMs that can be generated using FNUM/BLK registers\r
        but LFO works with one more bit of a precision so we really need 4096 elements */\r
	/* calculate fnumber -> increment counter table */\r
	for(i = 0; i < 4096; i++)\r
	{\r
		/* freq table for octave 7 */\r
		/* OPN phase increment counter = 20bit */\r
		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 */\r
	}\r
\r
	/* LFO freq. table */\r
	for(i = 0; i < 8; i++)\r
	{\r
		/* Amplitude modulation: 64 output levels (triangle waveform); 1 level lasts for one of "lfo_samples_per_step" samples */\r
		/* Phase modulation: one entry from lfo_pm_output lasts for one of 4 * "lfo_samples_per_step" samples  */\r
		ym2612.OPN.lfo_freq[i] = (1.0 / lfo_samples_per_step[i]) * (1<<LFO_SH) * ym2612.OPN.ST.freqbase;\r
	}\r
}\r
\r
\r
/* write a OPN register (0x30-0xff) */\r
static int OPNWriteReg(int r, int v)\r
{\r
	int ret = 1;\r
	FM_CH *CH;\r
	FM_SLOT *SLOT;\r
\r
	UINT8 c = OPN_CHAN(r);\r
\r
	if (c == 3) return 0; /* 0xX3,0xX7,0xXB,0xXF */\r
\r
	if (r >= 0x100) c+=3;\r
\r
	CH = &ym2612.CH[c];\r
\r
	SLOT = &(CH->SLOT[OPN_SLOT(r)]);\r
\r
	switch( r & 0xf0 ) {\r
	case 0x30:	/* DET , MUL */\r
		set_det_mul(CH,SLOT,v);\r
		break;\r
\r
	case 0x40:	/* TL */\r
		set_tl(SLOT,v);\r
		break;\r
\r
	case 0x50:	/* KS, AR */\r
		set_ar_ksr(CH,SLOT,v);\r
		break;\r
\r
	case 0x60:	/* bit7 = AM ENABLE, DR */\r
		set_dr(SLOT,v);\r
		if(v&0x80) CH->AMmasks |=   1<<OPN_SLOT(r);\r
		else       CH->AMmasks &= ~(1<<OPN_SLOT(r));\r
		break;\r
\r
	case 0x70:	/*     SR */\r
		set_sr(SLOT,v);\r
		break;\r
\r
	case 0x80:	/* SL, RR */\r
		set_sl_rr(SLOT,v);\r
		break;\r
\r
	case 0x90:	/* SSG-EG */\r
		// removed.\r
		ret = 0;\r
		break;\r
\r
	case 0xa0:\r
		switch( OPN_SLOT(r) ){\r
		case 0:		/* 0xa0-0xa2 : FNUM1 */\r
			{\r
				UINT32 fn = (((UINT32)( (ym2612.OPN.ST.fn_h)&7))<<8) + v;\r
				UINT8 blk = ym2612.OPN.ST.fn_h>>3;\r
				/* keyscale code */\r
				CH->kcode = (blk<<2) | opn_fktable[fn >> 7];\r
				/* phase increment counter */\r
				CH->fc = fn_table[fn*2]>>(7-blk);\r
\r
				/* store fnum in clear form for LFO PM calculations */\r
				CH->block_fnum = (blk<<11) | fn;\r
\r
				CH->SLOT[SLOT1].Incr=-1;\r
			}\r
			break;\r
		case 1:		/* 0xa4-0xa6 : FNUM2,BLK */\r
			ym2612.OPN.ST.fn_h = v&0x3f;\r
			ret = 0;\r
			break;\r
		case 2:		/* 0xa8-0xaa : 3CH FNUM1 */\r
			if(r < 0x100)\r
			{\r
				UINT32 fn = (((UINT32)(ym2612.OPN.SL3.fn_h&7))<<8) + v;\r
				UINT8 blk = ym2612.OPN.SL3.fn_h>>3;\r
				/* keyscale code */\r
				ym2612.OPN.SL3.kcode[c]= (blk<<2) | opn_fktable[fn >> 7];\r
				/* phase increment counter */\r
				ym2612.OPN.SL3.fc[c] = fn_table[fn*2]>>(7-blk);\r
				ym2612.OPN.SL3.block_fnum[c] = fn;\r
				ym2612.CH[2].SLOT[SLOT1].Incr=-1;\r
			}\r
			break;\r
		case 3:		/* 0xac-0xae : 3CH FNUM2,BLK */\r
			if(r < 0x100)\r
				ym2612.OPN.SL3.fn_h = v&0x3f;\r
			ret = 0;\r
			break;\r
		default:\r
			ret = 0;\r
			break;\r
		}\r
		break;\r
\r
	case 0xb0:\r
		switch( OPN_SLOT(r) ){\r
		case 0:		/* 0xb0-0xb2 : FB,ALGO */\r
			{\r
				int feedback = (v>>3)&7;\r
				CH->ALGO = v&7;\r
				CH->FB   = feedback ? feedback+6 : 0;\r
			}\r
			break;\r
		case 1:		/* 0xb4-0xb6 : L , R , AMS , PMS (YM2612/YM2610B/YM2610/YM2608) */\r
			{\r
				int panshift = c<<1;\r
\r
				/* b0-2 PMS */\r
				CH->pms = (v & 7) * 32; /* CH->pms = PM depth * 32 (index in lfo_pm_table) */\r
\r
				/* b4-5 AMS */\r
				CH->ams = lfo_ams_depth_shift[(v>>4) & 3];\r
\r
				/* PAN :  b7 = L, b6 = R */\r
				ym2612.OPN.pan &= ~(3<<panshift);\r
				ym2612.OPN.pan |= ((v & 0xc0) >> 6) << panshift; // ..LRLR\r
			}\r
			break;\r
		default:\r
			ret = 0;\r
			break;\r
		}\r
		break;\r
	default:\r
		ret = 0;\r
		break;\r
	}\r
\r
	return ret;\r
}\r
\r
\r
/*******************************************************************************/\r
/*      YM2612 local section                                                   */\r
/*******************************************************************************/\r
\r
int   *ym2612_dacen;\r
INT32 *ym2612_dacout;\r
\r
\r
/* Generate samples for YM2612 */\r
int YM2612UpdateOne_(int *buffer, int length, int stereo, int is_buf_empty)\r
{\r
	int pan;\r
	int active_chs = 0;\r
\r
	// if !is_buf_empty, it means it has valid samples to mix with, else it may contain trash\r
	if (is_buf_empty) memset32(buffer, 0, length<<stereo);\r
\r
	/* refresh PG and EG */\r
	refresh_fc_eg_chan( &ym2612.CH[0] );\r
	refresh_fc_eg_chan( &ym2612.CH[1] );\r
	if( (ym2612.OPN.ST.mode & 0xc0) )\r
	{\r
		/* 3SLOT MODE */\r
		if( ym2612.CH[2].SLOT[SLOT1].Incr==-1)\r
		{\r
			refresh_fc_eg_slot(&ym2612.CH[2].SLOT[SLOT1], ym2612.OPN.SL3.fc[1], ym2612.OPN.SL3.kcode[1] );\r
			refresh_fc_eg_slot(&ym2612.CH[2].SLOT[SLOT2], ym2612.OPN.SL3.fc[2], ym2612.OPN.SL3.kcode[2] );\r
			refresh_fc_eg_slot(&ym2612.CH[2].SLOT[SLOT3], ym2612.OPN.SL3.fc[0], ym2612.OPN.SL3.kcode[0] );\r
			refresh_fc_eg_slot(&ym2612.CH[2].SLOT[SLOT4], ym2612.CH[2].fc , ym2612.CH[2].kcode );\r
		}\r
	} else refresh_fc_eg_chan( &ym2612.CH[2] );\r
	refresh_fc_eg_chan( &ym2612.CH[3] );\r
	refresh_fc_eg_chan( &ym2612.CH[4] );\r
	refresh_fc_eg_chan( &ym2612.CH[5] );\r
\r
	pan = ym2612.OPN.pan;\r
	if (stereo) stereo = 1;\r
\r
	/* mix to 32bit dest */\r
	// flags: stereo, lastchan, disabled, ?, pan_r, pan_l\r
	active_chs |= chan_render(buffer, length, &ym2612.CH[0], stereo|((pan&0x003)<<4)) << 0;\r
	active_chs |= chan_render(buffer, length, &ym2612.CH[1], stereo|((pan&0x00c)<<2)) << 1;\r
	active_chs |= chan_render(buffer, length, &ym2612.CH[2], stereo|((pan&0x030)   )) << 2;\r
	active_chs |= chan_render(buffer, length, &ym2612.CH[3], stereo|((pan&0x0c0)>>2)) << 3;\r
	active_chs |= chan_render(buffer, length, &ym2612.CH[4], stereo|((pan&0x300)>>4)) << 4;\r
	active_chs |= chan_render(buffer, length, &ym2612.CH[5], stereo|((pan&0xc00)>>6)|(ym2612.dacen<<2)|2) << 5;\r
\r
	return active_chs; // 1 if buffer updated\r
}\r
\r
\r
/* initialize YM2612 emulator */\r
void YM2612Init_(int clock, int rate)\r
{\r
	// notaz\r
	ym2612_dacen = &ym2612.dacen;\r
	ym2612_dacout = &ym2612.dacout;\r
\r
	/* clear everything but the regs */\r
	memset(ym2612.CH, 0, sizeof(ym2612)-sizeof(ym2612.REGS)-4);\r
	init_tables();\r
\r
	ym2612.OPN.ST.clock = clock;\r
	ym2612.OPN.ST.rate = rate;\r
\r
	/* Extend handler */\r
	YM2612ResetChip_();\r
}\r
\r
\r
/* reset */\r
void YM2612ResetChip_(void)\r
{\r
	int i;\r
\r
	OPNSetPres( 6*24 );\r
	set_timers( 0x30 ); /* mode 0 , timer reset */\r
\r
	ym2612.OPN.eg_timer = 0;\r
	ym2612.OPN.eg_cnt   = 0;\r
	ym2612.OPN.ST.status = 0;\r
\r
	reset_channels( &ym2612.CH[0] , 6 );\r
	for(i = 0xb6 ; i >= 0xb4 ; i-- )\r
	{\r
		OPNWriteReg(i      ,0xc0);\r
		OPNWriteReg(i|0x100,0xc0);\r
	}\r
	for(i = 0xb2 ; i >= 0x30 ; i-- )\r
	{\r
		OPNWriteReg(i      ,0);\r
		OPNWriteReg(i|0x100,0);\r
	}\r
	for(i = 0x26 ; i >= 0x20 ; i-- ) OPNWriteReg(i,0);\r
	/* DAC mode clear */\r
	ym2612.dacen = 0;\r
}\r
\r
\r
/* YM2612 write */\r
/* a = address */\r
/* v = value   */\r
/* returns 1 if sample affecting state changed */\r
int YM2612Write_(unsigned int a, unsigned int v)\r
{\r
	int addr, ret=1;\r
\r
	v &= 0xff;	/* adjust to 8 bit bus */\r
\r
	switch( a&3){\r
	case 0:	/* address port 0 */\r
		ym2612.OPN.ST.address = v;\r
		ym2612.addr_A1 = 0;\r
		ret=0;\r
		break;\r
\r
	case 1:	/* data port 0    */\r
		if (ym2612.addr_A1 != 0) {\r
			ret=0;\r
			break;	/* verified on real YM2608 */\r
		}\r
\r
		addr = ym2612.OPN.ST.address;\r
		ym2612.REGS[addr] = v;\r
\r
		switch( addr & 0xf0 )\r
		{\r
		case 0x20:	/* 0x20-0x2f Mode */\r
			switch( addr )\r
			{\r
			case 0x22:	/* LFO FREQ (YM2608/YM2610/YM2610B/YM2612) */\r
				if (v&0x08) /* LFO enabled ? */\r
				{\r
					ym2612.OPN.lfo_inc = ym2612.OPN.lfo_freq[v&7];\r
				}\r
				else\r
				{\r
					ym2612.OPN.lfo_inc = 0;\r
				}\r
				break;\r
			case 0x24: { // timer A High 8\r
					int TAnew = (ym2612.OPN.ST.TA & 0x03)|(((int)v)<<2);\r
					if(ym2612.OPN.ST.TA != TAnew) {\r
						// we should reset ticker only if new value is written. Outrun requires this.\r
						ym2612.OPN.ST.TA = TAnew;\r
						ym2612.OPN.ST.TAC = (1024-TAnew)*18;\r
						ym2612.OPN.ST.TAT = 0;\r
					}\r
				}\r
				ret=0;\r
				break;\r
			case 0x25: { // timer A Low 2\r
					int TAnew = (ym2612.OPN.ST.TA & 0x3fc)|(v&3);\r
					if(ym2612.OPN.ST.TA != TAnew) {\r
						ym2612.OPN.ST.TA = TAnew;\r
						ym2612.OPN.ST.TAC = (1024-TAnew)*18;\r
						ym2612.OPN.ST.TAT = 0;\r
					}\r
				}\r
				ret=0;\r
				break;\r
			case 0x26: // timer B\r
				if(ym2612.OPN.ST.TB != v) {\r
					ym2612.OPN.ST.TB = v;\r
					ym2612.OPN.ST.TBC  = (256-v)<<4;\r
					ym2612.OPN.ST.TBC *= 18;\r
					ym2612.OPN.ST.TBT  = 0;\r
				}\r
				ret=0;\r
				break;\r
			case 0x27:	/* mode, timer control */\r
				set_timers( v );\r
				ret=0;\r
				break;\r
			case 0x28:	/* key on / off */\r
				{\r
					UINT8 c;\r
					FM_CH *CH;\r
\r
					c = v & 0x03;\r
					if( c == 3 ) { ret=0; break; }\r
					if( v&0x04 ) c+=3;\r
					CH = &ym2612.CH[c];\r
					if(v&0x10) FM_KEYON(CH,SLOT1); else FM_KEYOFF(CH,SLOT1);\r
					if(v&0x20) FM_KEYON(CH,SLOT2); else FM_KEYOFF(CH,SLOT2);\r
					if(v&0x40) FM_KEYON(CH,SLOT3); else FM_KEYOFF(CH,SLOT3);\r
					if(v&0x80) FM_KEYON(CH,SLOT4); else FM_KEYOFF(CH,SLOT4);\r
					break;\r
				}\r
			case 0x2a:	/* DAC data (YM2612) */\r
				ym2612.dacout = ((int)v - 0x80) << 6;	/* level unknown (notaz: 8 seems to be too much) */\r
				ret=0;\r
				break;\r
			case 0x2b:	/* DAC Sel  (YM2612) */\r
				/* b7 = dac enable */\r
				ym2612.dacen = v & 0x80;\r
				ret=0;\r
				break;\r
			default:\r
				break;\r
			}\r
			break;\r
		default:	/* 0x30-0xff OPN section */\r
			/* write register */\r
			ret = OPNWriteReg(addr,v);\r
		}\r
		break;\r
\r
	case 2:	/* address port 1 */\r
		ym2612.OPN.ST.address = v;\r
		ym2612.addr_A1 = 1;\r
		ret=0;\r
		break;\r
\r
	case 3:	/* data port 1    */\r
		if (ym2612.addr_A1 != 1) {\r
			ret=0;\r
			break;	/* verified on real YM2608 */\r
		}\r
\r
		addr = ym2612.OPN.ST.address | 0x100;\r
		ym2612.REGS[addr] = v;\r
\r
		ret = OPNWriteReg(addr, v);\r
		break;\r
	}\r
/*\r
	if(ret) {\r
		extern int Scanline;\r
		dprintf("ymw [%i]", Scanline);\r
	}\r
*/\r
	return ret;\r
}\r
\r
UINT8 YM2612Read_(void)\r
{\r
	return ym2612.OPN.ST.status;\r
}\r
\r
\r
int YM2612PicoTick_(int n)\r
{\r
	int ret = 0;\r
\r
	// timer A\r
	if(ym2612.OPN.ST.mode & 0x01 && (ym2612.OPN.ST.TAT+=64*n) >= ym2612.OPN.ST.TAC) {\r
		ym2612.OPN.ST.TAT -= ym2612.OPN.ST.TAC;\r
		if(ym2612.OPN.ST.mode & 0x04) ym2612.OPN.ST.status |= 1;\r
		// CSM mode total level latch and auto key on\r
		if(ym2612.OPN.ST.mode & 0x80) {\r
			CSMKeyControll( &(ym2612.CH[2]) ); // Vectorman2, etc.\r
			ret = 1;\r
		}\r
	}\r
\r
	// timer B\r
	if(ym2612.OPN.ST.mode & 0x02 && (ym2612.OPN.ST.TBT+=64*n) >= ym2612.OPN.ST.TBC) {\r
		ym2612.OPN.ST.TBT -= ym2612.OPN.ST.TBC;\r
		if(ym2612.OPN.ST.mode & 0x08) ym2612.OPN.ST.status |= 2;\r
	}\r
\r
	return ret;\r
}\r
\r
\r
void YM2612PicoStateLoad_(void)\r
{\r
#ifndef EXTERNAL_YM2612\r
	int i, old_A1 = ym2612.addr_A1;\r
\r
	reset_channels( &ym2612.CH[0], 6 );\r
\r
	// feed all the registers and update internal state\r
	for(i = 0; i < 0x100; i++) {\r
		YM2612Write_(0, i);\r
		YM2612Write_(1, ym2612.REGS[i]);\r
	}\r
	for(i = 0; i < 0x100; i++) {\r
		YM2612Write_(2, i);\r
		YM2612Write_(3, ym2612.REGS[i|0x100]);\r
	}\r
\r
	ym2612.addr_A1 = old_A1;\r
#else\r
	reset_channels( &ym2612.CH[0], 6 );\r
#endif\r
}\r
\r
\r
void *YM2612GetRegs(void)\r
{\r
	return ym2612.REGS;\r
}\r