db: Override cycle multiplier for Colin McRae PAL
[pcsx_rearmed.git] / plugins / dfsound / spu.c
CommitLineData
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1/***************************************************************************
2 spu.c - description
3 -------------------
4 begin : Wed May 15 2002
5 copyright : (C) 2002 by Pete Bernert
6 email : BlackDove@addcom.de
07a6dd2c 7
63a4f6b6 8 Portions (C) GraÅžvydas "notaz" Ignotas, 2010-2012,2014,2015
07a6dd2c 9
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10 ***************************************************************************/
11/***************************************************************************
12 * *
13 * This program is free software; you can redistribute it and/or modify *
14 * it under the terms of the GNU General Public License as published by *
15 * the Free Software Foundation; either version 2 of the License, or *
16 * (at your option) any later version. See also the license.txt file for *
17 * additional informations. *
18 * *
19 ***************************************************************************/
20
0de2ae23 21#include <assert.h>
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22#include "stdafx.h"
23
24#define _IN_SPU
25
26#include "externals.h"
3fc2a4c2 27#include "registers.h"
07c13dfd 28#include "out.h"
3154bfab 29#include "spu_config.h"
38b8a211 30#include "spu.h"
ef79bbde 31
de4a0279 32#ifdef __arm__
33#include "arm_features.h"
34#endif
35
8f2bb0cb 36#ifdef HAVE_ARMV7
1775933a 37 #define ssat32_to_16(v) \
38 asm("ssat %0,#16,%1" : "=r" (v) : "r" (v))
39#else
40 #define ssat32_to_16(v) do { \
41 if (v < -32768) v = -32768; \
42 else if (v > 32767) v = 32767; \
43 } while (0)
44#endif
45
fb552464 46#define PSXCLK 33868800 /* 33.8688 MHz */
47
650adfd2 48// intended to be ~1 frame
49#define IRQ_NEAR_BLOCKS 32
50
6d866bb7 51/*
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52#if defined (USEMACOSX)
53static char * libraryName = N_("Mac OS X Sound");
54#elif defined (USEALSA)
55static char * libraryName = N_("ALSA Sound");
56#elif defined (USEOSS)
57static char * libraryName = N_("OSS Sound");
58#elif defined (USESDL)
59static char * libraryName = N_("SDL Sound");
60#elif defined (USEPULSEAUDIO)
61static char * libraryName = N_("PulseAudio Sound");
62#else
63static char * libraryName = N_("NULL Sound");
64#endif
65
66static char * libraryInfo = N_("P.E.Op.S. Sound Driver V1.7\nCoded by Pete Bernert and the P.E.Op.S. team\n");
6d866bb7 67*/
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68
69// globals
70
3154bfab 71SPUInfo spu;
72SPUConfig spu_config;
ef79bbde 73
5514a050 74static int iFMod[NSSIZE];
05c7cec7 75static int RVB[NSSIZE * 2];
3154bfab 76int ChanBuf[NSSIZE];
ef79bbde 77
983a7cfd 78#define CDDA_BUFFER_SIZE (16384 * sizeof(uint32_t)) // must be power of 2
79
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80////////////////////////////////////////////////////////////////////////
81// CODE AREA
82////////////////////////////////////////////////////////////////////////
83
84// dirty inline func includes
85
86#include "reverb.c"
87#include "adsr.c"
88
89////////////////////////////////////////////////////////////////////////
90// helpers for simple interpolation
91
92//
93// easy interpolation on upsampling, no special filter, just "Pete's common sense" tm
94//
95// instead of having n equal sample values in a row like:
96// ____
97// |____
98//
99// we compare the current delta change with the next delta change.
100//
101// if curr_delta is positive,
102//
103// - and next delta is smaller (or changing direction):
104// \.
105// -__
106//
107// - and next delta significant (at least twice) bigger:
108// --_
109// \.
110//
111// - and next delta is nearly same:
112// \.
113// \.
114//
115//
116// if curr_delta is negative,
117//
118// - and next delta is smaller (or changing direction):
119// _--
120// /
121//
122// - and next delta significant (at least twice) bigger:
123// /
124// __-
125//
126// - and next delta is nearly same:
127// /
128// /
129//
130
38e4048f 131static void InterpolateUp(sample_buf *sb, int sinc)
ef79bbde 132{
38e4048f 133 int *SB = sb->SB;
134 if (sb->sinc_old != sinc)
135 {
136 sb->sinc_old = sinc;
137 SB[32] = 1;
138 }
011755d7 139 if(SB[32]==1) // flag == 1? calc step and set flag... and don't change the value in this pass
ef79bbde 140 {
011755d7 141 const int id1=SB[30]-SB[29]; // curr delta to next val
142 const int id2=SB[31]-SB[30]; // and next delta to next-next val :)
ef79bbde 143
011755d7 144 SB[32]=0;
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145
146 if(id1>0) // curr delta positive
147 {
148 if(id2<id1)
011755d7 149 {SB[28]=id1;SB[32]=2;}
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150 else
151 if(id2<(id1<<1))
011755d7 152 SB[28]=(id1*sinc)>>16;
ef79bbde 153 else
011755d7 154 SB[28]=(id1*sinc)>>17;
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155 }
156 else // curr delta negative
157 {
158 if(id2>id1)
011755d7 159 {SB[28]=id1;SB[32]=2;}
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160 else
161 if(id2>(id1<<1))
011755d7 162 SB[28]=(id1*sinc)>>16;
ef79bbde 163 else
011755d7 164 SB[28]=(id1*sinc)>>17;
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165 }
166 }
167 else
011755d7 168 if(SB[32]==2) // flag 1: calc step and set flag... and don't change the value in this pass
ef79bbde 169 {
011755d7 170 SB[32]=0;
ef79bbde 171
011755d7 172 SB[28]=(SB[28]*sinc)>>17;
173 //if(sinc<=0x8000)
174 // SB[29]=SB[30]-(SB[28]*((0x10000/sinc)-1));
76d1d09c 175 //else
011755d7 176 SB[29]+=SB[28];
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177 }
178 else // no flags? add bigger val (if possible), calc smaller step, set flag1
011755d7 179 SB[29]+=SB[28];
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180}
181
182//
183// even easier interpolation on downsampling, also no special filter, again just "Pete's common sense" tm
184//
185
38e4048f 186static void InterpolateDown(sample_buf *sb, int sinc)
ef79bbde 187{
38e4048f 188 int *SB = sb->SB;
011755d7 189 if(sinc>=0x20000L) // we would skip at least one val?
ef79bbde 190 {
011755d7 191 SB[29]+=(SB[30]-SB[29])/2; // add easy weight
192 if(sinc>=0x30000L) // we would skip even more vals?
193 SB[29]+=(SB[31]-SB[30])/2; // add additional next weight
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194 }
195}
196
197////////////////////////////////////////////////////////////////////////
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198
199#include "gauss_i.h"
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200#include "xa.c"
201
25f460ec 202static void do_irq(int cycles_after)
e4f075af 203{
25f460ec 204 if (spu.spuStat & STAT_IRQ)
205 log_unhandled("spu: missed irq?\n");
206 else
e4f075af 207 {
3154bfab 208 spu.spuStat |= STAT_IRQ; // asserted status?
25f460ec 209 if (spu.irqCallback)
210 spu.irqCallback(cycles_after);
e4f075af 211 }
212}
213
214static int check_irq(int ch, unsigned char *pos)
215{
a5ff8be2 216 if((spu.spuCtrl & (CTRL_ON|CTRL_IRQ)) == (CTRL_ON|CTRL_IRQ) && pos == spu.pSpuIrq)
e4f075af 217 {
32fbd56b 218 //printf("ch%d irq %04zx\n", ch, pos - spu.spuMemC);
25f460ec 219 do_irq(0);
e4f075af 220 return 1;
221 }
222 return 0;
223}
224
a5ff8be2 225void check_irq_io(unsigned int addr)
226{
227 unsigned int irq_addr = regAreaGet(H_SPUirqAddr) << 3;
228 //addr &= ~7; // ?
229 if((spu.spuCtrl & (CTRL_ON|CTRL_IRQ)) == (CTRL_ON|CTRL_IRQ) && addr == irq_addr)
230 {
231 //printf("io irq %04x\n", irq_addr);
25f460ec 232 do_irq(0);
233 }
234}
235
236void do_irq_io(int cycles_after)
237{
238 if ((spu.spuCtrl & (CTRL_ON|CTRL_IRQ)) == (CTRL_ON|CTRL_IRQ))
239 {
240 do_irq(cycles_after);
a5ff8be2 241 }
242}
243
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244////////////////////////////////////////////////////////////////////////
245// START SOUND... called by main thread to setup a new sound on a channel
246////////////////////////////////////////////////////////////////////////
247
38e4048f 248static void ResetInterpolation(sample_buf *sb)
ef79bbde 249{
38e4048f 250 memset(&sb->interp, 0, sizeof(sb->interp));
251 sb->sinc_old = -1;
252}
ef79bbde 253
38e4048f 254static void StartSoundSB(sample_buf *sb)
255{
256 sb->SB[26] = 0; // init mixing vars
257 sb->SB[27] = 0;
258 ResetInterpolation(sb);
3bd31caf 259}
260
261static void StartSoundMain(int ch)
262{
263 SPUCHAN *s_chan = &spu.s_chan[ch];
264
265 StartADSR(ch);
266 StartREVERB(ch);
267
d358733b 268 s_chan->prevflags = 2;
269 s_chan->iSBPos = 27;
270 s_chan->spos = 0;
271 s_chan->bStarting = 1;
ef79bbde 272
5fdcf5cd 273 s_chan->pCurr = spu.spuMemC + ((regAreaGetCh(ch, 6) & ~1) << 3);
16f3ca66 274
3154bfab 275 spu.dwNewChannel&=~(1<<ch); // clear new channel bit
4ccd0fb2 276 spu.dwChannelDead&=~(1<<ch);
1d5d35bc 277 spu.dwChannelsAudible|=1<<ch;
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278}
279
3bd31caf 280static void StartSound(int ch)
281{
282 StartSoundMain(ch);
38e4048f 283 StartSoundSB(&spu.sb[ch]);
3bd31caf 284}
285
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286////////////////////////////////////////////////////////////////////////
287// ALL KIND OF HELPERS
288////////////////////////////////////////////////////////////////////////
289
0de2ae23 290INLINE int FModChangeFrequency(int pitch, int ns, int *fmod_buf)
ef79bbde 291{
5aa9f158 292 pitch = (signed short)pitch;
0de2ae23 293 pitch = ((32768 + fmod_buf[ns]) * pitch) >> 15;
5aa9f158 294 pitch &= 0xffff;
295 if (pitch > 0x3fff)
296 pitch = 0x3fff;
ef79bbde 297
0de2ae23 298 fmod_buf[ns] = 0;
ef79bbde 299
5aa9f158 300 return pitch << 4;
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301}
302
38e4048f 303INLINE void StoreInterpolationGaussCubic(sample_buf *sb, int fa)
ef79bbde 304{
38e4048f 305 int gpos = sb->interp.gauss.pos & 3;
306 sb->interp.gauss.val[gpos++] = fa;
307 sb->interp.gauss.pos = gpos & 3;
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308}
309
38e4048f 310#define gval(x) (int)sb->interp.gauss.val[(gpos + x) & 3]
ef79bbde 311
38e4048f 312INLINE int GetInterpolationCubic(const sample_buf *sb, int spos)
ef79bbde 313{
38e4048f 314 int gpos = sb->interp.gauss.pos;
315 int xd = (spos >> 1) + 1;
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316 int fa;
317
38e4048f 318 fa = gval(3) - 3*gval(2) + 3*gval(1) - gval(0);
319 fa *= (xd - (2<<15)) / 6;
320 fa >>= 15;
321 fa += gval(2) - gval(1) - gval(1) + gval(0);
322 fa *= (xd - (1<<15)) >> 1;
323 fa >>= 15;
324 fa += gval(1) - gval(0);
325 fa *= xd;
326 fa >>= 15;
327 fa = fa + gval(0);
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328 return fa;
329}
330
38e4048f 331INLINE int GetInterpolationGauss(const sample_buf *sb, int spos)
332{
333 int gpos = sb->interp.gauss.pos;
334 int vl = (spos >> 6) & ~3;
335 int vr;
336 vr = (gauss[vl+0] * gval(0)) >> 15;
337 vr += (gauss[vl+1] * gval(1)) >> 15;
338 vr += (gauss[vl+2] * gval(2)) >> 15;
339 vr += (gauss[vl+3] * gval(3)) >> 15;
340 return vr;
341}
342
381ea103 343static void decode_block_data(int *dest, const unsigned char *src, int predict_nr, int shift_factor)
344{
5514a050 345 static const int f[16][2] = {
346 { 0, 0 },
347 { 60, 0 },
348 { 115, -52 },
349 { 98, -55 },
350 { 122, -60 }
351 };
381ea103 352 int nSample;
353 int fa, s_1, s_2, d, s;
354
355 s_1 = dest[27];
356 s_2 = dest[26];
357
358 for (nSample = 0; nSample < 28; src++)
359 {
360 d = (int)*src;
361 s = (int)(signed short)((d & 0x0f) << 12);
362
5aa9f158 363 fa = s >> shift_factor;
381ea103 364 fa += ((s_1 * f[predict_nr][0])>>6) + ((s_2 * f[predict_nr][1])>>6);
5aa9f158 365 ssat32_to_16(fa);
366 s_2 = s_1; s_1 = fa;
381ea103 367
368 dest[nSample++] = fa;
369
370 s = (int)(signed short)((d & 0xf0) << 8);
5aa9f158 371 fa = s >> shift_factor;
381ea103 372 fa += ((s_1 * f[predict_nr][0])>>6) + ((s_2 * f[predict_nr][1])>>6);
5aa9f158 373 ssat32_to_16(fa);
374 s_2 = s_1; s_1 = fa;
381ea103 375
376 dest[nSample++] = fa;
377 }
378}
379
3bd31caf 380static int decode_block(void *unused, int ch, int *SB)
e11ae5c5 381{
5514a050 382 SPUCHAN *s_chan = &spu.s_chan[ch];
e11ae5c5 383 unsigned char *start;
215ff9e6 384 int predict_nr, shift_factor, flags;
e11ae5c5 385 int ret = 0;
386
5514a050 387 start = s_chan->pCurr; // set up the current pos
d358733b 388 if (start - spu.spuMemC < 0x1000) { // ?
389 //log_unhandled("ch%02d plays decode bufs @%05lx\n",
390 // ch, (long)(start - spu.spuMemC));
215ff9e6 391 ret = 1;
d358733b 392 }
e11ae5c5 393
5514a050 394 if (s_chan->prevflags & 1) // 1: stop/loop
3fc2a4c2 395 {
5514a050 396 if (!(s_chan->prevflags & 2))
215ff9e6 397 ret = 1;
e4f075af 398
5514a050 399 start = s_chan->pLoop;
3fc2a4c2 400 }
3113a160 401
402 check_irq(ch, start);
e11ae5c5 403
5514a050 404 predict_nr = start[0];
215ff9e6 405 shift_factor = predict_nr & 0xf;
e11ae5c5 406 predict_nr >>= 4;
e11ae5c5 407
011755d7 408 decode_block_data(SB, start + 2, predict_nr, shift_factor);
e11ae5c5 409
215ff9e6 410 flags = start[1];
3113a160 411 if (flags & 4 && !s_chan->bIgnoreLoop)
5514a050 412 s_chan->pLoop = start; // loop adress
e11ae5c5 413
215ff9e6 414 start += 16;
3fc2a4c2 415
5514a050 416 s_chan->pCurr = start; // store values for next cycle
417 s_chan->prevflags = flags;
d358733b 418 s_chan->bStarting = 0;
e11ae5c5 419
420 return ret;
421}
422
07a6dd2c 423// do block, but ignore sample data
424static int skip_block(int ch)
425{
5514a050 426 SPUCHAN *s_chan = &spu.s_chan[ch];
427 unsigned char *start = s_chan->pCurr;
215ff9e6 428 int flags;
429 int ret = 0;
430
5514a050 431 if (s_chan->prevflags & 1) {
432 if (!(s_chan->prevflags & 2))
215ff9e6 433 ret = 1;
07a6dd2c 434
5514a050 435 start = s_chan->pLoop;
215ff9e6 436 }
3113a160 437
438 check_irq(ch, start);
07a6dd2c 439
215ff9e6 440 flags = start[1];
3113a160 441 if (flags & 4 && !s_chan->bIgnoreLoop)
5514a050 442 s_chan->pLoop = start;
07a6dd2c 443
e4f075af 444 start += 16;
07a6dd2c 445
5514a050 446 s_chan->pCurr = start;
447 s_chan->prevflags = flags;
d358733b 448 s_chan->bStarting = 0;
e4f075af 449
89cb2058 450 return ret;
07a6dd2c 451}
452
650adfd2 453// if irq is going to trigger sooner than in upd_samples, set upd_samples
454static void scan_for_irq(int ch, unsigned int *upd_samples)
455{
5514a050 456 SPUCHAN *s_chan = &spu.s_chan[ch];
650adfd2 457 int pos, sinc, sinc_inv, end;
458 unsigned char *block;
459 int flags;
460
5514a050 461 block = s_chan->pCurr;
462 pos = s_chan->spos;
463 sinc = s_chan->sinc;
650adfd2 464 end = pos + *upd_samples * sinc;
e099a4a8 465 if (s_chan->prevflags & 1) // 1: stop/loop
466 block = s_chan->pLoop;
650adfd2 467
5514a050 468 pos += (28 - s_chan->iSBPos) << 16;
650adfd2 469 while (pos < end)
470 {
3154bfab 471 if (block == spu.pSpuIrq)
650adfd2 472 break;
473 flags = block[1];
474 block += 16;
475 if (flags & 1) { // 1: stop/loop
5514a050 476 block = s_chan->pLoop;
650adfd2 477 }
478 pos += 28 << 16;
479 }
480
481 if (pos < end)
482 {
5514a050 483 sinc_inv = s_chan->sinc_inv;
650adfd2 484 if (sinc_inv == 0)
5514a050 485 sinc_inv = s_chan->sinc_inv = (0x80000000u / (uint32_t)sinc) << 1;
650adfd2 486
5514a050 487 pos -= s_chan->spos;
650adfd2 488 *upd_samples = (((uint64_t)pos * sinc_inv) >> 32) + 1;
489 //xprintf("ch%02d: irq sched: %3d %03d\n",
490 // ch, *upd_samples, *upd_samples * 60 * 263 / 44100);
491 }
492}
493
38e4048f 494#define make_do_samples(name, fmod_code, interp_start, interp_store, interp_get, interp_end) \
0de2ae23 495static noinline int name(int *dst, \
3bd31caf 496 int (*decode_f)(void *context, int ch, int *SB), void *ctx, \
38e4048f 497 int ch, int ns_to, sample_buf *sb, int sinc, int *spos, int *sbpos) \
07a6dd2c 498{ \
215ff9e6 499 int ns, d, fa; \
500 int ret = ns_to; \
07a6dd2c 501 interp_start; \
502 \
215ff9e6 503 for (ns = 0; ns < ns_to; ns++) \
07a6dd2c 504 { \
505 fmod_code; \
506 \
63a4f6b6 507 *spos += sinc; \
508 while (*spos >= 0x10000) \
07a6dd2c 509 { \
38e4048f 510 fa = sb->SB[(*sbpos)++]; \
63a4f6b6 511 if (*sbpos >= 28) \
07a6dd2c 512 { \
63a4f6b6 513 *sbpos = 0; \
38e4048f 514 d = decode_f(ctx, ch, sb->SB); \
215ff9e6 515 if (d && ns < ret) \
516 ret = ns; \
07a6dd2c 517 } \
518 \
38e4048f 519 interp_store; \
63a4f6b6 520 *spos -= 0x10000; \
07a6dd2c 521 } \
522 \
38e4048f 523 interp_get; \
07a6dd2c 524 } \
525 \
07a6dd2c 526 interp_end; \
527 \
528 return ret; \
529}
530
38e4048f 531// helpers for simple linear interpolation: delay real val for two slots,
532// and calc the two deltas, for a 'look at the future behaviour'
07a6dd2c 533#define simple_interp_store \
38e4048f 534 sb->SB[28] = 0; \
535 sb->SB[29] = sb->SB[30]; \
536 sb->SB[30] = sb->SB[31]; \
537 sb->SB[31] = fa; \
538 sb->SB[32] = 1
07a6dd2c 539
540#define simple_interp_get \
011755d7 541 if(sinc<0x10000) /* -> upsampling? */ \
38e4048f 542 InterpolateUp(sb, sinc); /* --> interpolate up */ \
543 else InterpolateDown(sb, sinc); /* --> else down */ \
0de2ae23 544 dst[ns] = sb->SB[29]
07a6dd2c 545
38e4048f 546make_do_samples(do_samples_nointerp, , fa = sb->SB[29],
0de2ae23 547 , dst[ns] = fa, sb->SB[29] = fa)
38e4048f 548make_do_samples(do_samples_simple, , ,
07a6dd2c 549 simple_interp_store, simple_interp_get, )
38e4048f 550make_do_samples(do_samples_gauss, , ,
551 StoreInterpolationGaussCubic(sb, fa),
0de2ae23 552 dst[ns] = GetInterpolationGauss(sb, *spos), )
38e4048f 553make_do_samples(do_samples_cubic, , ,
554 StoreInterpolationGaussCubic(sb, fa),
0de2ae23 555 dst[ns] = GetInterpolationCubic(sb, *spos), )
38e4048f 556make_do_samples(do_samples_fmod,
0de2ae23 557 sinc = FModChangeFrequency(spu.s_chan[ch].iRawPitch, ns, iFMod), ,
38e4048f 558 StoreInterpolationGaussCubic(sb, fa),
0de2ae23 559 dst[ns] = GetInterpolationGauss(sb, *spos), )
38e4048f 560
0de2ae23 561INLINE int do_samples_adpcm(int *dst,
38e4048f 562 int (*decode_f)(void *context, int ch, int *SB), void *ctx,
563 int ch, int ns_to, int fmod, sample_buf *sb, int sinc, int *spos, int *sbpos)
564{
565 int interp = spu.interpolation;
566 if (fmod == 1)
0de2ae23 567 return do_samples_fmod(dst, decode_f, ctx, ch, ns_to, sb, sinc, spos, sbpos);
38e4048f 568 if (fmod)
569 interp = 2;
570 switch (interp) {
571 case 0:
0de2ae23 572 return do_samples_nointerp(dst, decode_f, ctx, ch, ns_to, sb, sinc, spos, sbpos);
38e4048f 573 case 1:
0de2ae23 574 return do_samples_simple (dst, decode_f, ctx, ch, ns_to, sb, sinc, spos, sbpos);
38e4048f 575 default:
0de2ae23 576 return do_samples_gauss (dst, decode_f, ctx, ch, ns_to, sb, sinc, spos, sbpos);
38e4048f 577 case 3:
0de2ae23 578 return do_samples_cubic (dst, decode_f, ctx, ch, ns_to, sb, sinc, spos, sbpos);
38e4048f 579 }
580}
07a6dd2c 581
215ff9e6 582static int do_samples_skip(int ch, int ns_to)
07a6dd2c 583{
5514a050 584 SPUCHAN *s_chan = &spu.s_chan[ch];
8f5f2dd5 585 int spos = s_chan->spos;
586 int sinc = s_chan->sinc;
215ff9e6 587 int ret = ns_to, ns, d;
b1094d0e 588
8f5f2dd5 589 spos += s_chan->iSBPos << 16;
215ff9e6 590
591 for (ns = 0; ns < ns_to; ns++)
07a6dd2c 592 {
8f5f2dd5 593 spos += sinc;
594 while (spos >= 28*0x10000)
215ff9e6 595 {
596 d = skip_block(ch);
597 if (d && ns < ret)
598 ret = ns;
8f5f2dd5 599 spos -= 28*0x10000;
215ff9e6 600 }
07a6dd2c 601 }
602
8f5f2dd5 603 s_chan->iSBPos = spos >> 16;
604 s_chan->spos = spos & 0xffff;
215ff9e6 605
606 return ret;
607}
608
0de2ae23 609static int do_samples_skip_fmod(int ch, int ns_to, int *fmod_buf)
610{
611 SPUCHAN *s_chan = &spu.s_chan[ch];
612 int spos = s_chan->spos;
613 int ret = ns_to, ns, d;
614
615 spos += s_chan->iSBPos << 16;
616
617 for (ns = 0; ns < ns_to; ns++)
618 {
619 spos += FModChangeFrequency(s_chan->iRawPitch, ns, fmod_buf);
620 while (spos >= 28*0x10000)
621 {
622 d = skip_block(ch);
623 if (d && ns < ret)
624 ret = ns;
625 spos -= 28*0x10000;
626 }
627 }
628
629 s_chan->iSBPos = spos >> 16;
630 s_chan->spos = spos & 0xffff;
631
632 return ret;
633}
634
635static void do_lsfr_samples(int *dst, int ns_to, int ctrl,
215ff9e6 636 unsigned int *dwNoiseCount, unsigned int *dwNoiseVal)
637{
638 unsigned int counter = *dwNoiseCount;
639 unsigned int val = *dwNoiseVal;
640 unsigned int level, shift, bit;
641 int ns;
642
b1094d0e 643 // modified from DrHell/shalma, no fraction
215ff9e6 644 level = (ctrl >> 10) & 0x0f;
b1094d0e 645 level = 0x8000 >> level;
646
215ff9e6 647 for (ns = 0; ns < ns_to; ns++)
b1094d0e 648 {
215ff9e6 649 counter += 2;
650 if (counter >= level)
b1094d0e 651 {
215ff9e6 652 counter -= level;
653 shift = (val >> 10) & 0x1f;
b1094d0e 654 bit = (0x69696969 >> shift) & 1;
215ff9e6 655 bit ^= (val >> 15) & 1;
656 val = (val << 1) | bit;
b1094d0e 657 }
658
0de2ae23 659 dst[ns] = (signed short)val;
b1094d0e 660 }
07a6dd2c 661
215ff9e6 662 *dwNoiseCount = counter;
663 *dwNoiseVal = val;
664}
665
0de2ae23 666static int do_samples_noise(int *dst, int ch, int ns_to)
215ff9e6 667{
668 int ret;
669
670 ret = do_samples_skip(ch, ns_to);
671
0de2ae23 672 do_lsfr_samples(dst, ns_to, spu.spuCtrl, &spu.dwNoiseCount, &spu.dwNoiseVal);
215ff9e6 673
89cb2058 674 return ret;
07a6dd2c 675}
676
665f33e1 677#ifdef HAVE_ARMV5
3a721c1f 678// asm code; lv and rv must be 0-3fff
3bd31caf 679extern void mix_chan(int *SSumLR, int count, int lv, int rv);
680extern void mix_chan_rvb(int *SSumLR, int count, int lv, int rv, int *rvb);
b17618c0 681#else
3bd31caf 682static void mix_chan(int *SSumLR, int count, int lv, int rv)
b17618c0 683{
3bd31caf 684 const int *src = ChanBuf;
b17618c0 685 int l, r;
686
687 while (count--)
688 {
689 int sval = *src++;
690
691 l = (sval * lv) >> 14;
692 r = (sval * rv) >> 14;
3bd31caf 693 *SSumLR++ += l;
694 *SSumLR++ += r;
b17618c0 695 }
696}
697
3bd31caf 698static void mix_chan_rvb(int *SSumLR, int count, int lv, int rv, int *rvb)
b17618c0 699{
3bd31caf 700 const int *src = ChanBuf;
701 int *dst = SSumLR;
702 int *drvb = rvb;
b17618c0 703 int l, r;
704
705 while (count--)
706 {
707 int sval = *src++;
708
709 l = (sval * lv) >> 14;
710 r = (sval * rv) >> 14;
711 *dst++ += l;
712 *dst++ += r;
713 *drvb++ += l;
714 *drvb++ += r;
715 }
716}
717#endif
718
b72f17a1 719// 0x0800-0x0bff Voice 1
720// 0x0c00-0x0fff Voice 3
215ff9e6 721static noinline void do_decode_bufs(unsigned short *mem, int which,
722 int count, int decode_pos)
b72f17a1 723{
215ff9e6 724 unsigned short *dst = &mem[0x800/2 + which*0x400/2];
725 const int *src = ChanBuf;
726 int cursor = decode_pos;
b72f17a1 727
728 while (count-- > 0)
729 {
ee9afdbd 730 cursor &= 0x1ff;
b72f17a1 731 dst[cursor] = *src++;
ee9afdbd 732 cursor++;
b72f17a1 733 }
734
735 // decode_pos is updated and irqs are checked later, after voice loop
736}
737
215ff9e6 738static void do_silent_chans(int ns_to, int silentch)
739{
5514a050 740 unsigned int mask;
741 SPUCHAN *s_chan;
215ff9e6 742 int ch;
743
5514a050 744 mask = silentch & 0xffffff;
745 for (ch = 0; mask != 0; ch++, mask >>= 1)
215ff9e6 746 {
5514a050 747 if (!(mask & 1)) continue;
215ff9e6 748 if (spu.dwChannelDead & (1<<ch)) continue;
5514a050 749
750 s_chan = &spu.s_chan[ch];
751 if (s_chan->pCurr > spu.pSpuIrq && s_chan->pLoop > spu.pSpuIrq)
215ff9e6 752 continue;
753
5514a050 754 s_chan->spos += s_chan->iSBPos << 16;
755 s_chan->iSBPos = 0;
215ff9e6 756
5514a050 757 s_chan->spos += s_chan->sinc * ns_to;
758 while (s_chan->spos >= 28 * 0x10000)
215ff9e6 759 {
5514a050 760 unsigned char *start = s_chan->pCurr;
215ff9e6 761
762 skip_block(ch);
5514a050 763 if (start == s_chan->pCurr || start - spu.spuMemC < 0x1000)
215ff9e6 764 {
765 // looping on self or stopped(?)
766 spu.dwChannelDead |= 1<<ch;
5514a050 767 s_chan->spos = 0;
215ff9e6 768 break;
769 }
770
5514a050 771 s_chan->spos -= 28 * 0x10000;
215ff9e6 772 }
773 }
774}
775
776static void do_channels(int ns_to)
777{
778 unsigned int mask;
05c7cec7 779 int do_rvb, ch, d;
5514a050 780 SPUCHAN *s_chan;
38e4048f 781
782 if (unlikely(spu.interpolation != spu_config.iUseInterpolation))
783 {
784 spu.interpolation = spu_config.iUseInterpolation;
785 mask = spu.dwChannelsAudible & 0xffffff;
786 for (ch = 0; mask != 0; ch++, mask >>= 1)
787 if (mask & 1)
788 ResetInterpolation(&spu.sb[ch]);
789 }
215ff9e6 790
05c7cec7 791 do_rvb = spu.rvb->StartAddr && spu_config.iUseReverb;
792 if (do_rvb)
793 memset(RVB, 0, ns_to * sizeof(RVB[0]) * 2);
3bd31caf 794
795 mask = spu.dwNewChannel & 0xffffff;
796 for (ch = 0; mask != 0; ch++, mask >>= 1) {
797 if (mask & 1)
798 StartSound(ch);
799 }
215ff9e6 800
5aa94fa0 801 mask = spu.dwChannelsAudible & 0xffffff;
215ff9e6 802 for (ch = 0; mask != 0; ch++, mask >>= 1) // loop em all...
803 {
804 if (!(mask & 1)) continue; // channel not playing? next
805
5514a050 806 s_chan = &spu.s_chan[ch];
5514a050 807 if (s_chan->bNoise)
0de2ae23 808 d = do_samples_noise(ChanBuf, ch, ns_to);
215ff9e6 809 else
0de2ae23 810 d = do_samples_adpcm(ChanBuf, decode_block, NULL, ch, ns_to, s_chan->bFMod,
38e4048f 811 &spu.sb[ch], s_chan->sinc, &s_chan->spos, &s_chan->iSBPos);
215ff9e6 812
d358733b 813 if (!s_chan->bStarting) {
0de2ae23 814 d = MixADSR(ChanBuf, &s_chan->ADSRX, d);
d358733b 815 if (d < ns_to) {
816 spu.dwChannelsAudible &= ~(1 << ch);
817 s_chan->ADSRX.State = ADSR_RELEASE;
818 s_chan->ADSRX.EnvelopeVol = 0;
819 memset(&ChanBuf[d], 0, (ns_to - d) * sizeof(ChanBuf[0]));
820 }
215ff9e6 821 }
822
823 if (ch == 1 || ch == 3)
824 {
825 do_decode_bufs(spu.spuMem, ch/2, ns_to, spu.decode_pos);
826 spu.decode_dirty_ch |= 1 << ch;
827 }
828
5514a050 829 if (s_chan->bFMod == 2) // fmod freq channel
215ff9e6 830 memcpy(iFMod, &ChanBuf, ns_to * sizeof(iFMod[0]));
9bcccb91 831 if (!(spu.spuCtrl & CTRL_MUTE))
832 ;
833 else if (s_chan->bRVBActive && do_rvb)
05c7cec7 834 mix_chan_rvb(spu.SSumLR, ns_to, s_chan->iLeftVolume, s_chan->iRightVolume, RVB);
215ff9e6 835 else
3bd31caf 836 mix_chan(spu.SSumLR, ns_to, s_chan->iLeftVolume, s_chan->iRightVolume);
215ff9e6 837 }
05c7cec7 838
38b8a211 839 MixCD(spu.SSumLR, RVB, ns_to, spu.decode_pos);
73d2a903 840
05c7cec7 841 if (spu.rvb->StartAddr) {
7b2c4897 842 if (do_rvb)
05c7cec7 843 REVERBDo(spu.SSumLR, RVB, ns_to, spu.rvb->CurrAddr);
05c7cec7 844
845 spu.rvb->CurrAddr += ns_to / 2;
846 while (spu.rvb->CurrAddr >= 0x40000)
847 spu.rvb->CurrAddr -= 0x40000 - spu.rvb->StartAddr;
848 }
215ff9e6 849}
850
05c7cec7 851static void do_samples_finish(int *SSumLR, int ns_to,
3bd31caf 852 int silentch, int decode_pos);
63a4f6b6 853
854// optional worker thread handling
855
9165d434 856#if P_HAVE_PTHREAD || defined(WANT_THREAD_CODE)
63a4f6b6 857
3bd31caf 858// worker thread state
859static struct spu_worker {
860 union {
861 struct {
8fb79cd1 862 unsigned char exit_thread;
863 unsigned char prev_work_in_thread;
864 unsigned char pad[2];
3bd31caf 865 unsigned int i_ready;
866 unsigned int i_reaped;
05c7cec7 867 unsigned int last_boot_cnt; // dsp
0c1151fe 868 unsigned int ram_dirty;
8fb79cd1 869 unsigned int channels_last;
3bd31caf 870 };
871 // aligning for C64X_DSP
872 unsigned int _pad0[128/4];
873 };
874 union {
875 struct {
876 unsigned int i_done;
877 unsigned int active; // dsp
878 unsigned int boot_cnt;
879 };
880 unsigned int _pad1[128/4];
881 };
882 struct work_item {
883 int ns_to;
884 int ctrl;
885 int decode_pos;
05c7cec7 886 int rvb_addr;
3bd31caf 887 unsigned int channels_new;
888 unsigned int channels_on;
889 unsigned int channels_silent;
890 struct {
891 int spos;
892 int sbpos;
893 int sinc;
894 int start;
895 int loop;
05c7cec7 896 short vol_l;
897 short vol_r;
53d4b74d 898 unsigned short ns_to;
899 unsigned short bNoise:1;
900 unsigned short bFMod:2;
901 unsigned short bRVBActive:1;
0de2ae23 902 unsigned short bStarting:1;
3bd31caf 903 ADSRInfoEx adsr;
3bd31caf 904 } ch[24];
3bd31caf 905 int SSumLR[NSSIZE * 2];
906 } i[4];
907} *worker;
908
909#define WORK_MAXCNT (sizeof(worker->i) / sizeof(worker->i[0]))
910#define WORK_I_MASK (WORK_MAXCNT - 1)
911
5514a050 912static void thread_work_start(void);
3bd31caf 913static void thread_work_wait_sync(struct work_item *work, int force);
05c7cec7 914static void thread_sync_caches(void);
3bd31caf 915static int thread_get_i_done(void);
916
917static int decode_block_work(void *context, int ch, int *SB)
918{
919 const unsigned char *ram = spu.spuMemC;
920 int predict_nr, shift_factor, flags;
921 struct work_item *work = context;
922 int start = work->ch[ch].start;
923 int loop = work->ch[ch].loop;
924
925 predict_nr = ram[start];
926 shift_factor = predict_nr & 0xf;
927 predict_nr >>= 4;
928
929 decode_block_data(SB, ram + start + 2, predict_nr, shift_factor);
930
931 flags = ram[start + 1];
932 if (flags & 4)
933 loop = start; // loop adress
934
935 start += 16;
936
937 if (flags & 1) // 1: stop/loop
938 start = loop;
939
940 work->ch[ch].start = start & 0x7ffff;
941 work->ch[ch].loop = loop;
942
943 return 0;
944}
5514a050 945
3bd31caf 946static void queue_channel_work(int ns_to, unsigned int silentch)
63a4f6b6 947{
0de2ae23 948 int tmpFMod[NSSIZE];
3bd31caf 949 struct work_item *work;
950 SPUCHAN *s_chan;
63a4f6b6 951 unsigned int mask;
3bd31caf 952 int ch, d;
63a4f6b6 953
3bd31caf 954 work = &worker->i[worker->i_ready & WORK_I_MASK];
955 work->ns_to = ns_to;
956 work->ctrl = spu.spuCtrl;
957 work->decode_pos = spu.decode_pos;
958 work->channels_silent = silentch;
959
8fb79cd1 960 if (!worker->prev_work_in_thread) {
961 // copy adpcm and interpolation state to sb_thread
962 worker->prev_work_in_thread = 1;
963 mask = spu.dwChannelsAudible & ~spu.dwNewChannel & 0xffffff;
964 for (ch = 0; mask != 0; ch++, mask >>= 1) {
965 if (mask & 1)
966 memcpy(spu.sb_thread[ch].SB, spu.sb[ch].SB, sizeof(spu.sb_thread[ch].SB));
967 }
968 }
969
3bd31caf 970 mask = work->channels_new = spu.dwNewChannel & 0xffffff;
971 for (ch = 0; mask != 0; ch++, mask >>= 1) {
972 if (mask & 1)
0de2ae23 973 StartSound(ch);
3bd31caf 974 }
975
5aa94fa0 976 mask = work->channels_on = spu.dwChannelsAudible & 0xffffff;
8fb79cd1 977 worker->channels_last = mask;
3bd31caf 978 spu.decode_dirty_ch |= mask & 0x0a;
63a4f6b6 979
63a4f6b6 980 for (ch = 0; mask != 0; ch++, mask >>= 1)
981 {
982 if (!(mask & 1)) continue;
983
5514a050 984 s_chan = &spu.s_chan[ch];
3bd31caf 985 work->ch[ch].spos = s_chan->spos;
986 work->ch[ch].sbpos = s_chan->iSBPos;
987 work->ch[ch].sinc = s_chan->sinc;
988 work->ch[ch].adsr = s_chan->ADSRX;
05c7cec7 989 work->ch[ch].vol_l = s_chan->iLeftVolume;
990 work->ch[ch].vol_r = s_chan->iRightVolume;
3bd31caf 991 work->ch[ch].start = s_chan->pCurr - spu.spuMemC;
992 work->ch[ch].loop = s_chan->pLoop - spu.spuMemC;
53d4b74d 993 work->ch[ch].bNoise = s_chan->bNoise;
994 work->ch[ch].bFMod = s_chan->bFMod;
995 work->ch[ch].bRVBActive = s_chan->bRVBActive;
0de2ae23 996 work->ch[ch].bStarting = s_chan->bStarting;
5514a050 997 if (s_chan->prevflags & 1)
3bd31caf 998 work->ch[ch].start = work->ch[ch].loop;
63a4f6b6 999
0de2ae23 1000 if (unlikely(s_chan->bFMod == 2))
1001 {
1002 // sucks, have to do double work
ee98433b 1003 if (s_chan->bNoise)
1004 d = do_samples_noise(tmpFMod, ch, ns_to);
1005 else
1006 d = do_samples_gauss(tmpFMod, decode_block, NULL, ch, ns_to,
0de2ae23 1007 &spu.sb[ch], s_chan->sinc, &s_chan->spos, &s_chan->iSBPos);
1008 if (!s_chan->bStarting) {
1009 d = MixADSR(tmpFMod, &s_chan->ADSRX, d);
1010 if (d < ns_to) {
1011 spu.dwChannelsAudible &= ~(1 << ch);
1012 s_chan->ADSRX.State = ADSR_RELEASE;
1013 s_chan->ADSRX.EnvelopeVol = 0;
1014 }
1015 }
1016 memset(&tmpFMod[d], 0, (ns_to - d) * sizeof(tmpFMod[d]));
1017 work->ch[ch].ns_to = d;
1018 continue;
1019 }
1020 if (unlikely(s_chan->bFMod))
1021 d = do_samples_skip_fmod(ch, ns_to, tmpFMod);
1022 else
1023 d = do_samples_skip(ch, ns_to);
3bd31caf 1024 work->ch[ch].ns_to = d;
1025
d358733b 1026 if (!s_chan->bStarting) {
1027 // note: d is not accurate on skip
1028 d = SkipADSR(&s_chan->ADSRX, d);
1029 if (d < ns_to) {
1030 spu.dwChannelsAudible &= ~(1 << ch);
1031 s_chan->ADSRX.State = ADSR_RELEASE;
1032 s_chan->ADSRX.EnvelopeVol = 0;
1033 }
3bd31caf 1034 }
0de2ae23 1035 } // for (ch;;)
63a4f6b6 1036
05c7cec7 1037 work->rvb_addr = 0;
1038 if (spu.rvb->StartAddr) {
7b2c4897 1039 if (spu_config.iUseReverb)
05c7cec7 1040 work->rvb_addr = spu.rvb->CurrAddr;
05c7cec7 1041
1042 spu.rvb->CurrAddr += ns_to / 2;
1043 while (spu.rvb->CurrAddr >= 0x40000)
1044 spu.rvb->CurrAddr -= 0x40000 - spu.rvb->StartAddr;
1045 }
1046
3bd31caf 1047 worker->i_ready++;
5514a050 1048 thread_work_start();
63a4f6b6 1049}
1050
3bd31caf 1051static void do_channel_work(struct work_item *work)
63a4f6b6 1052{
3bd31caf 1053 unsigned int mask;
38e4048f 1054 int spos, sbpos;
63a4f6b6 1055 int d, ch, ns_to;
1056
3bd31caf 1057 ns_to = work->ns_to;
05c7cec7 1058
38e4048f 1059 if (unlikely(spu.interpolation != spu_config.iUseInterpolation))
1060 {
1061 spu.interpolation = spu_config.iUseInterpolation;
0de2ae23 1062 mask = work->channels_on;
38e4048f 1063 for (ch = 0; mask != 0; ch++, mask >>= 1)
1064 if (mask & 1)
0de2ae23 1065 ResetInterpolation(&spu.sb_thread[ch]);
38e4048f 1066 }
1067
05c7cec7 1068 if (work->rvb_addr)
1069 memset(RVB, 0, ns_to * sizeof(RVB[0]) * 2);
63a4f6b6 1070
3bd31caf 1071 mask = work->channels_new;
1072 for (ch = 0; mask != 0; ch++, mask >>= 1) {
1073 if (mask & 1)
0de2ae23 1074 StartSoundSB(&spu.sb_thread[ch]);
3bd31caf 1075 }
1076
1077 mask = work->channels_on;
63a4f6b6 1078 for (ch = 0; mask != 0; ch++, mask >>= 1)
1079 {
1080 if (!(mask & 1)) continue;
1081
3bd31caf 1082 d = work->ch[ch].ns_to;
1083 spos = work->ch[ch].spos;
1084 sbpos = work->ch[ch].sbpos;
5514a050 1085
53d4b74d 1086 if (work->ch[ch].bNoise)
0de2ae23 1087 do_lsfr_samples(ChanBuf, d, work->ctrl, &spu.dwNoiseCount, &spu.dwNoiseVal);
63a4f6b6 1088 else
0de2ae23 1089 do_samples_adpcm(ChanBuf, decode_block_work, work, ch, d, work->ch[ch].bFMod,
1090 &spu.sb_thread[ch], work->ch[ch].sinc, &spos, &sbpos);
63a4f6b6 1091
0de2ae23 1092 d = MixADSR(ChanBuf, &work->ch[ch].adsr, d);
63a4f6b6 1093 if (d < ns_to) {
3bd31caf 1094 work->ch[ch].adsr.EnvelopeVol = 0;
63a4f6b6 1095 memset(&ChanBuf[d], 0, (ns_to - d) * sizeof(ChanBuf[0]));
1096 }
1097
1098 if (ch == 1 || ch == 3)
53d4b74d 1099 do_decode_bufs(spu.spuMem, ch/2, ns_to, work->decode_pos);
63a4f6b6 1100
53d4b74d 1101 if (work->ch[ch].bFMod == 2) // fmod freq channel
63a4f6b6 1102 memcpy(iFMod, &ChanBuf, ns_to * sizeof(iFMod[0]));
53d4b74d 1103 if (work->ch[ch].bRVBActive && work->rvb_addr)
3bd31caf 1104 mix_chan_rvb(work->SSumLR, ns_to,
05c7cec7 1105 work->ch[ch].vol_l, work->ch[ch].vol_r, RVB);
63a4f6b6 1106 else
05c7cec7 1107 mix_chan(work->SSumLR, ns_to, work->ch[ch].vol_l, work->ch[ch].vol_r);
63a4f6b6 1108 }
05c7cec7 1109
1110 if (work->rvb_addr)
1111 REVERBDo(work->SSumLR, RVB, ns_to, work->rvb_addr);
63a4f6b6 1112}
1113
8fb79cd1 1114static void sync_worker_thread(int force_no_thread)
63a4f6b6 1115{
8fb79cd1 1116 int force = force_no_thread;
3bd31caf 1117 struct work_item *work;
1118 int done, used_space;
63a4f6b6 1119
7b2c4897 1120 // rvb offsets will change, thread may be using them
1121 force |= spu.rvb->dirty && spu.rvb->StartAddr;
1122
3bd31caf 1123 done = thread_get_i_done() - worker->i_reaped;
1124 used_space = worker->i_ready - worker->i_reaped;
0c1151fe 1125
3bd31caf 1126 //printf("done: %d use: %d dsp: %u/%u\n", done, used_space,
1127 // worker->boot_cnt, worker->i_done);
63a4f6b6 1128
3bd31caf 1129 while ((force && used_space > 0) || used_space >= WORK_MAXCNT || done > 0) {
1130 work = &worker->i[worker->i_reaped & WORK_I_MASK];
1131 thread_work_wait_sync(work, force);
63a4f6b6 1132
38b8a211 1133 MixCD(work->SSumLR, RVB, work->ns_to, work->decode_pos);
05c7cec7 1134 do_samples_finish(work->SSumLR, work->ns_to,
3bd31caf 1135 work->channels_silent, work->decode_pos);
63a4f6b6 1136
3bd31caf 1137 worker->i_reaped++;
1138 done = thread_get_i_done() - worker->i_reaped;
1139 used_space = worker->i_ready - worker->i_reaped;
63a4f6b6 1140 }
8fb79cd1 1141 if (force_no_thread && worker->prev_work_in_thread) {
1142 unsigned int ch, mask = worker->channels_last;
1143 worker->prev_work_in_thread = 0;
05c7cec7 1144 thread_sync_caches();
8fb79cd1 1145 for (ch = 0; mask != 0; ch++, mask >>= 1) {
1146 if (mask & 1)
1147 memcpy(spu.sb[ch].SB, spu.sb_thread[ch].SB, sizeof(spu.sb_thread[ch].SB));
1148 }
1149 }
63a4f6b6 1150}
1151
1152#else
1153
1154static void queue_channel_work(int ns_to, int silentch) {}
8fb79cd1 1155static void sync_worker_thread(int force_no_thread) {}
3bd31caf 1156
1157static const void * const worker = NULL;
63a4f6b6 1158
9165d434 1159#endif // P_HAVE_PTHREAD || defined(WANT_THREAD_CODE)
63a4f6b6 1160
ef79bbde
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1161////////////////////////////////////////////////////////////////////////
1162// MAIN SPU FUNCTION
6d75977b 1163// here is the main job handler...
ef79bbde
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1164////////////////////////////////////////////////////////////////////////
1165
8fb79cd1 1166void do_samples(unsigned int cycles_to, int force_no_thread)
ef79bbde 1167{
3bd31caf 1168 unsigned int silentch;
650adfd2 1169 int cycle_diff;
3bd31caf 1170 int ns_to;
ef79bbde 1171
3154bfab 1172 cycle_diff = cycles_to - spu.cycles_played;
650adfd2 1173 if (cycle_diff < -2*1048576 || cycle_diff > 2*1048576)
1174 {
20ed712f 1175 log_unhandled("desync %u %d\n", cycles_to, cycle_diff);
3154bfab 1176 spu.cycles_played = cycles_to;
650adfd2 1177 return;
1178 }
e34a4bd3 1179
5aa94fa0 1180 silentch = ~(spu.dwChannelsAudible | spu.dwNewChannel) & 0xffffff;
3bd31caf 1181
8fb79cd1 1182 force_no_thread |= (silentch == 0xffffff);
de4a0279 1183 if (worker != NULL)
8fb79cd1 1184 sync_worker_thread(force_no_thread);
de4a0279 1185
650adfd2 1186 if (cycle_diff < 2 * 768)
1187 return;
e34a4bd3 1188
650adfd2 1189 ns_to = (cycle_diff / 768 + 1) & ~1;
1190 if (ns_to > NSSIZE) {
1191 // should never happen
20ed712f 1192 log_unhandled("ns_to oflow %d %d\n", ns_to, NSSIZE);
650adfd2 1193 ns_to = NSSIZE;
1194 }
1195
1196 //////////////////////////////////////////////////////
1197 // special irq handling in the decode buffers (0x0000-0x1000)
1198 // we know:
1199 // the decode buffers are located in spu memory in the following way:
1200 // 0x0000-0x03ff CD audio left
1201 // 0x0400-0x07ff CD audio right
1202 // 0x0800-0x0bff Voice 1
1203 // 0x0c00-0x0fff Voice 3
1204 // and decoded data is 16 bit for one sample
1205 // we assume:
1206 // even if voices 1/3 are off or no cd audio is playing, the internal
1207 // play positions will move on and wrap after 0x400 bytes.
1208 // Therefore: we just need a pointer from spumem+0 to spumem+3ff, and
1209 // increase this pointer on each sample by 2 bytes. If this pointer
1210 // (or 0x400 offsets of this pointer) hits the spuirq address, we generate
1211 // an IRQ.
1212
3154bfab 1213 if (unlikely((spu.spuCtrl & CTRL_IRQ)
c4c66b22 1214 && spu.pSpuIrq < spu.spuMemC+0x1000))
650adfd2 1215 {
3154bfab 1216 int irq_pos = (spu.pSpuIrq - spu.spuMemC) / 2 & 0x1ff;
1217 int left = (irq_pos - spu.decode_pos) & 0x1ff;
650adfd2 1218 if (0 < left && left <= ns_to)
1219 {
3154bfab 1220 //xprintf("decoder irq %x\n", spu.decode_pos);
25f460ec 1221 do_irq(0);
650adfd2 1222 }
1223 }
3c7a8977 1224 if (!spu.cycles_dma_end || (int)(spu.cycles_dma_end - cycles_to) < 0) {
1225 spu.cycles_dma_end = 0;
1226 check_irq_io(spu.spuAddr);
1227 }
650adfd2 1228
7b2c4897 1229 if (unlikely(spu.rvb->dirty))
1230 REVERBPrep();
1231
8fb79cd1 1232 if (force_no_thread || worker == NULL || !spu_config.iUseThread) {
3bd31caf 1233 do_channels(ns_to);
05c7cec7 1234 do_samples_finish(spu.SSumLR, ns_to, silentch, spu.decode_pos);
63a4f6b6 1235 }
215ff9e6 1236 else {
3bd31caf 1237 queue_channel_work(ns_to, silentch);
53d4b74d 1238 //sync_worker_thread(1); // uncomment for debug
215ff9e6 1239 }
ef79bbde 1240
215ff9e6 1241 // advance "stopped" channels that can cause irqs
1242 // (all chans are always playing on the real thing..)
1243 if (spu.spuCtrl & CTRL_IRQ)
1244 do_silent_chans(ns_to, silentch);
1245
1246 spu.cycles_played += ns_to * 768;
1247 spu.decode_pos = (spu.decode_pos + ns_to) & 0x1ff;
3047daea 1248 spu.spuStat = (spu.spuStat & ~0x800) | ((spu.decode_pos << 3) & 0x800);
d358733b 1249#if 0
1250 static int ccount; static time_t ctime; ccount++;
1251 if (time(NULL) != ctime)
1252 { printf("%d\n", ccount); ccount = 0; ctime = time(NULL); }
1253#endif
215ff9e6 1254}
1255
05c7cec7 1256static void do_samples_finish(int *SSumLR, int ns_to,
3bd31caf 1257 int silentch, int decode_pos)
215ff9e6 1258{
5fdcf5cd 1259 int vol_l = ((int)regAreaGet(H_SPUmvolL) << 17) >> 17;
1260 int vol_r = ((int)regAreaGet(H_SPUmvolR) << 17) >> 17;
215ff9e6 1261 int ns;
1262 int d;
78c60846 1263
3bd31caf 1264 // must clear silent channel decode buffers
1265 if(unlikely(silentch & spu.decode_dirty_ch & (1<<1)))
b72f17a1 1266 {
3154bfab 1267 memset(&spu.spuMem[0x800/2], 0, 0x400);
1268 spu.decode_dirty_ch &= ~(1<<1);
b72f17a1 1269 }
3154bfab 1270 if(unlikely(silentch & spu.decode_dirty_ch & (1<<3)))
b72f17a1 1271 {
3154bfab 1272 memset(&spu.spuMem[0xc00/2], 0, 0x400);
1273 spu.decode_dirty_ch &= ~(1<<3);
b72f17a1 1274 }
8680e822 1275
5fdcf5cd 1276 vol_l = vol_l * spu_config.iVolume >> 10;
1277 vol_r = vol_r * spu_config.iVolume >> 10;
1278
9bcccb91 1279 if (!(vol_l | vol_r))
1775933a 1280 {
5fdcf5cd 1281 // muted? (rare)
3154bfab 1282 memset(spu.pS, 0, ns_to * 2 * sizeof(spu.pS[0]));
5fdcf5cd 1283 memset(SSumLR, 0, ns_to * 2 * sizeof(SSumLR[0]));
3154bfab 1284 spu.pS += ns_to * 2;
1775933a 1285 }
1286 else
650adfd2 1287 for (ns = 0; ns < ns_to * 2; )
ef79bbde 1288 {
9e7a7352 1289 d = SSumLR[ns]; SSumLR[ns] = 0;
eaa5336d 1290 d = d * vol_l >> 14;
1775933a 1291 ssat32_to_16(d);
3154bfab 1292 *spu.pS++ = d;
97ea4077 1293 ns++;
ef79bbde 1294
9e7a7352 1295 d = SSumLR[ns]; SSumLR[ns] = 0;
eaa5336d 1296 d = d * vol_r >> 14;
1775933a 1297 ssat32_to_16(d);
3154bfab 1298 *spu.pS++ = d;
97ea4077 1299 ns++;
ef79bbde 1300 }
650adfd2 1301}
ef79bbde 1302
650adfd2 1303void schedule_next_irq(void)
1304{
1305 unsigned int upd_samples;
1306 int ch;
ef79bbde 1307
3154bfab 1308 if (spu.scheduleCallback == NULL)
650adfd2 1309 return;
e34a4bd3 1310
650adfd2 1311 upd_samples = 44100 / 50;
e34a4bd3 1312
650adfd2 1313 for (ch = 0; ch < MAXCHAN; ch++)
1314 {
3154bfab 1315 if (spu.dwChannelDead & (1 << ch))
650adfd2 1316 continue;
5514a050 1317 if ((unsigned long)(spu.pSpuIrq - spu.s_chan[ch].pCurr) > IRQ_NEAR_BLOCKS * 16
1318 && (unsigned long)(spu.pSpuIrq - spu.s_chan[ch].pLoop) > IRQ_NEAR_BLOCKS * 16)
650adfd2 1319 continue;
f3fa20c2 1320 if (spu.s_chan[ch].sinc == 0)
1321 continue;
16187bfb 1322
650adfd2 1323 scan_for_irq(ch, &upd_samples);
ef79bbde
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1324 }
1325
3154bfab 1326 if (unlikely(spu.pSpuIrq < spu.spuMemC + 0x1000))
650adfd2 1327 {
3154bfab 1328 int irq_pos = (spu.pSpuIrq - spu.spuMemC) / 2 & 0x1ff;
1329 int left = (irq_pos - spu.decode_pos) & 0x1ff;
650adfd2 1330 if (0 < left && left < upd_samples) {
3154bfab 1331 //xprintf("decode: %3d (%3d/%3d)\n", left, spu.decode_pos, irq_pos);
650adfd2 1332 upd_samples = left;
1333 }
1334 }
16187bfb 1335
650adfd2 1336 if (upd_samples < 44100 / 50)
3154bfab 1337 spu.scheduleCallback(upd_samples * 768);
ef79bbde
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1338}
1339
1340// SPU ASYNC... even newer epsxe func
1341// 1 time every 'cycle' cycles... harhar
1342
650adfd2 1343// rearmed: called dynamically now
554a2220 1344
650adfd2 1345void CALLBACK SPUasync(unsigned int cycle, unsigned int flags)
ef79bbde 1346{
b34d6a80 1347 do_samples(cycle, 0);
fb552464 1348
3154bfab 1349 if (spu.spuCtrl & CTRL_IRQ)
650adfd2 1350 schedule_next_irq();
f8edb5bc 1351
650adfd2 1352 if (flags & 1) {
3154bfab 1353 out_current->feed(spu.pSpuBuffer, (unsigned char *)spu.pS - spu.pSpuBuffer);
1354 spu.pS = (short *)spu.pSpuBuffer;
fb552464 1355
3154bfab 1356 if (spu_config.iTempo) {
650adfd2 1357 if (!out_current->busy())
1358 // cause more samples to be generated
1359 // (and break some games because of bad sync)
3154bfab 1360 spu.cycles_played -= 44100 / 60 / 2 * 768;
ef79bbde 1361 }
650adfd2 1362 }
ef79bbde
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1363}
1364
1365// SPU UPDATE... new epsxe func
1366// 1 time every 32 hsync lines
1367// (312/32)x50 in pal
1368// (262/32)x60 in ntsc
1369
1370// since epsxe 1.5.2 (linux) uses SPUupdate, not SPUasync, I will
1371// leave that func in the linux port, until epsxe linux is using
1372// the async function as well
1373
1374void CALLBACK SPUupdate(void)
1375{
ef79bbde
P
1376}
1377
1378// XA AUDIO
1379
38b8a211 1380void CALLBACK SPUplayADPCMchannel(xa_decode_t *xap, unsigned int cycle, int is_start)
ef79bbde
P
1381{
1382 if(!xap) return;
9cf79034 1383 if(!xap->freq) return; // no xa freq ? bye
ef79bbde 1384
38b8a211 1385 if (is_start)
1386 spu.XAPlay = spu.XAFeed = spu.XAStart;
5c5e6c0c 1387 if (spu.XAPlay == spu.XAFeed)
9cf79034 1388 do_samples(cycle, 1); // catch up to prevent source underflows later
1389
1390 FeedXA(xap); // call main XA feeder
b34d6a80 1391 spu.xapGlobal = xap; // store info for save states
67c020ee 1392 spu.cdClearSamples = 512;
ef79bbde
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1393}
1394
1395// CDDA AUDIO
5c5e6c0c 1396int CALLBACK SPUplayCDDAchannel(short *pcm, int nbytes, unsigned int cycle, int unused)
ef79bbde 1397{
983a7cfd 1398 if (!pcm) return -1;
1399 if (nbytes<=0) return -1;
ef79bbde 1400
5c5e6c0c 1401 if (spu.CDDAPlay == spu.CDDAFeed)
9cf79034 1402 do_samples(cycle, 1); // catch up to prevent source underflows later
1403
b34d6a80 1404 FeedCDDA((unsigned char *)pcm, nbytes);
67c020ee 1405 spu.cdClearSamples = 512;
b34d6a80 1406 return 0;
ef79bbde
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1407}
1408
38b8a211 1409void CALLBACK SPUsetCDvol(unsigned char ll, unsigned char lr,
1410 unsigned char rl, unsigned char rr, unsigned int cycle)
1411{
1412 if (spu.XAPlay != spu.XAFeed || spu.CDDAPlay != spu.CDDAFeed)
1413 do_samples(cycle, 1);
1414 spu.cdv.ll = ll;
1415 spu.cdv.lr = lr;
1416 spu.cdv.rl = rl;
1417 spu.cdv.rr = rr;
1418}
1419
6d75977b 1420// to be called after state load
1421void ClearWorkingState(void)
ef79bbde 1422{
5514a050 1423 memset(iFMod, 0, sizeof(iFMod));
3154bfab 1424 spu.pS=(short *)spu.pSpuBuffer; // setup soundbuffer pointer
ef79bbde
P
1425}
1426
1427// SETUPSTREAMS: init most of the spu buffers
05c7cec7 1428static void SetupStreams(void)
ef79bbde 1429{
3154bfab 1430 spu.pSpuBuffer = (unsigned char *)malloc(32768); // alloc mixing buffer
3bd31caf 1431 spu.SSumLR = calloc(NSSIZE * 2, sizeof(spu.SSumLR[0]));
ef79bbde 1432
33788798 1433 spu.XAStart = malloc(44100 * sizeof(uint32_t)); // alloc xa buffer
3154bfab 1434 spu.XAEnd = spu.XAStart + 44100;
1435 spu.XAPlay = spu.XAStart;
1436 spu.XAFeed = spu.XAStart;
ef79bbde 1437
33788798 1438 spu.CDDAStart = malloc(CDDA_BUFFER_SIZE); // alloc cdda buffer
b34d6a80 1439 spu.CDDAEnd = spu.CDDAStart + CDDA_BUFFER_SIZE / sizeof(uint32_t);
3154bfab 1440 spu.CDDAPlay = spu.CDDAStart;
1441 spu.CDDAFeed = spu.CDDAStart;
ef79bbde 1442
6d75977b 1443 ClearWorkingState();
ef79bbde
P
1444}
1445
1446// REMOVESTREAMS: free most buffer
05c7cec7 1447static void RemoveStreams(void)
ef79bbde 1448{
3154bfab 1449 free(spu.pSpuBuffer); // free mixing buffer
1450 spu.pSpuBuffer = NULL;
3bd31caf 1451 free(spu.SSumLR);
1452 spu.SSumLR = NULL;
3154bfab 1453 free(spu.XAStart); // free XA buffer
1454 spu.XAStart = NULL;
1455 free(spu.CDDAStart); // free CDDA buffer
1456 spu.CDDAStart = NULL;
ef79bbde
P
1457}
1458
5514a050 1459#if defined(C64X_DSP)
1460
1461/* special code for TI C64x DSP */
1462#include "spu_c64x.c"
1463
9165d434 1464#elif P_HAVE_PTHREAD
5514a050 1465
1466#include <pthread.h>
1467#include <semaphore.h>
1468#include <unistd.h>
1469
1470static struct {
1471 pthread_t thread;
1472 sem_t sem_avail;
1473 sem_t sem_done;
1474} t;
1475
1476/* generic pthread implementation */
1477
1478static void thread_work_start(void)
1479{
1480 sem_post(&t.sem_avail);
1481}
1482
3bd31caf 1483static void thread_work_wait_sync(struct work_item *work, int force)
5514a050 1484{
1485 sem_wait(&t.sem_done);
1486}
63a4f6b6 1487
3bd31caf 1488static int thread_get_i_done(void)
de4a0279 1489{
3bd31caf 1490 return worker->i_done;
de4a0279 1491}
1492
05c7cec7 1493static void thread_sync_caches(void)
1494{
1495}
1496
63a4f6b6 1497static void *spu_worker_thread(void *unused)
1498{
3bd31caf 1499 struct work_item *work;
1500
63a4f6b6 1501 while (1) {
5514a050 1502 sem_wait(&t.sem_avail);
63a4f6b6 1503 if (worker->exit_thread)
1504 break;
1505
3bd31caf 1506 work = &worker->i[worker->i_done & WORK_I_MASK];
1507 do_channel_work(work);
1508 worker->i_done++;
63a4f6b6 1509
5514a050 1510 sem_post(&t.sem_done);
63a4f6b6 1511 }
1512
1513 return NULL;
1514}
1515
1516static void init_spu_thread(void)
1517{
1518 int ret;
1519
42dde520 1520 spu.sb_thread = spu.sb_thread_;
1521
63a4f6b6 1522 if (sysconf(_SC_NPROCESSORS_ONLN) <= 1)
1523 return;
1524
1525 worker = calloc(1, sizeof(*worker));
1526 if (worker == NULL)
1527 return;
5514a050 1528 ret = sem_init(&t.sem_avail, 0, 0);
63a4f6b6 1529 if (ret != 0)
1530 goto fail_sem_avail;
5514a050 1531 ret = sem_init(&t.sem_done, 0, 0);
63a4f6b6 1532 if (ret != 0)
1533 goto fail_sem_done;
1534
5514a050 1535 ret = pthread_create(&t.thread, NULL, spu_worker_thread, NULL);
63a4f6b6 1536 if (ret != 0)
1537 goto fail_thread;
1538
3bd31caf 1539 spu_config.iThreadAvail = 1;
63a4f6b6 1540 return;
1541
1542fail_thread:
5514a050 1543 sem_destroy(&t.sem_done);
63a4f6b6 1544fail_sem_done:
5514a050 1545 sem_destroy(&t.sem_avail);
63a4f6b6 1546fail_sem_avail:
1547 free(worker);
1548 worker = NULL;
3bd31caf 1549 spu_config.iThreadAvail = 0;
63a4f6b6 1550}
1551
1552static void exit_spu_thread(void)
1553{
1554 if (worker == NULL)
1555 return;
1556 worker->exit_thread = 1;
5514a050 1557 sem_post(&t.sem_avail);
1558 pthread_join(t.thread, NULL);
1559 sem_destroy(&t.sem_done);
1560 sem_destroy(&t.sem_avail);
63a4f6b6 1561 free(worker);
1562 worker = NULL;
1563}
1564
9165d434 1565#else // if !P_HAVE_PTHREAD
63a4f6b6 1566
1567static void init_spu_thread(void)
1568{
1569}
1570
1571static void exit_spu_thread(void)
1572{
1573}
1574
1575#endif
ef79bbde
P
1576
1577// SPUINIT: this func will be called first by the main emu
1578long CALLBACK SPUinit(void)
1579{
05c7cec7 1580 int i;
1581
66cc6abb 1582 memset(&spu, 0, sizeof(spu));
f05ce78e 1583 spu.spuMemC = calloc(1, 512 * 1024 + 16);
1584 // a guard for runaway channels - End+Mute
1585 spu.spuMemC[512 * 1024 + 1] = 1;
1586
ef79bbde
P
1587 InitADSR();
1588
5514a050 1589 spu.s_chan = calloc(MAXCHAN+1, sizeof(spu.s_chan[0])); // channel + 1 infos (1 is security for fmod handling)
05c7cec7 1590 spu.rvb = calloc(1, sizeof(REVERBInfo));
5514a050 1591
1592 spu.spuAddr = 0;
3154bfab 1593 spu.decode_pos = 0;
c4c66b22 1594 spu.pSpuIrq = spu.spuMemC;
ef79bbde 1595
ef79bbde
P
1596 SetupStreams(); // prepare streaming
1597
3154bfab 1598 if (spu_config.iVolume == 0)
1599 spu_config.iVolume = 768; // 1024 is 1.0
1600
63a4f6b6 1601 init_spu_thread();
1602
05c7cec7 1603 for (i = 0; i < MAXCHAN; i++) // loop sound channels
1604 {
1605 spu.s_chan[i].ADSRX.SustainLevel = 0xf; // -> init sustain
1606 spu.s_chan[i].ADSRX.SustainIncrease = 1;
1607 spu.s_chan[i].pLoop = spu.spuMemC;
1608 spu.s_chan[i].pCurr = spu.spuMemC;
16f3ca66 1609 spu.s_chan[i].bIgnoreLoop = 0;
05c7cec7 1610 }
1611
1612 spu.bSpuInit=1; // flag: we are inited
1613
ef79bbde
P
1614 return 0;
1615}
1616
1617// SPUOPEN: called by main emu after init
1618long CALLBACK SPUopen(void)
1619{
3154bfab 1620 if (spu.bSPUIsOpen) return 0; // security for some stupid main emus
ef79bbde
P
1621
1622 SetupSound(); // setup sound (before init!)
ef79bbde 1623
3154bfab 1624 spu.bSPUIsOpen = 1;
ef79bbde
P
1625
1626 return PSE_SPU_ERR_SUCCESS;
1627}
1628
1629// SPUCLOSE: called before shutdown
1630long CALLBACK SPUclose(void)
1631{
3154bfab 1632 if (!spu.bSPUIsOpen) return 0; // some security
ef79bbde 1633
3154bfab 1634 spu.bSPUIsOpen = 0; // no more open
ef79bbde 1635
07c13dfd 1636 out_current->finish(); // no more sound handling
ef79bbde
P
1637
1638 return 0;
1639}
1640
1641// SPUSHUTDOWN: called by main emu on final exit
1642long CALLBACK SPUshutdown(void)
1643{
1644 SPUclose();
ef79bbde 1645
63a4f6b6 1646 exit_spu_thread();
1647
5514a050 1648 free(spu.spuMemC);
1649 spu.spuMemC = NULL;
1650 free(spu.s_chan);
1651 spu.s_chan = NULL;
05c7cec7 1652 free(spu.rvb);
1653 spu.rvb = NULL;
5514a050 1654
1655 RemoveStreams(); // no more streaming
1656 spu.bSpuInit=0;
1657
ef79bbde
P
1658 return 0;
1659}
1660
ef79bbde
P
1661// SETUP CALLBACKS
1662// this functions will be called once,
1663// passes a callback that should be called on SPU-IRQ/cdda volume change
c2eee46b 1664void CALLBACK SPUregisterCallback(void (CALLBACK *callback)(int))
ef79bbde 1665{
3154bfab 1666 spu.irqCallback = callback;
ef79bbde
P
1667}
1668
b64fb891 1669void CALLBACK SPUregisterCDDAVolume(void (CALLBACK *CDDAVcallback)(short, short))
ef79bbde 1670{
7285d7ad 1671 //spu.cddavCallback = CDDAVcallback;
ef79bbde
P
1672}
1673
2b30c129 1674void CALLBACK SPUregisterScheduleCb(void (CALLBACK *callback)(unsigned int))
1675{
3154bfab 1676 spu.scheduleCallback = callback;
2b30c129 1677}
1678
ef79bbde 1679// COMMON PLUGIN INFO FUNCS
e906c010 1680/*
ef79bbde
P
1681char * CALLBACK PSEgetLibName(void)
1682{
1683 return _(libraryName);
1684}
1685
1686unsigned long CALLBACK PSEgetLibType(void)
1687{
1688 return PSE_LT_SPU;
1689}
1690
1691unsigned long CALLBACK PSEgetLibVersion(void)
1692{
1693 return (1 << 16) | (6 << 8);
1694}
1695
1696char * SPUgetLibInfos(void)
1697{
1698 return _(libraryInfo);
1699}
e906c010 1700*/
6d866bb7 1701
90f1d26c 1702// debug
174c454a 1703void spu_get_debug_info(int *chans_out, int *run_chans, int *fmod_chans_out, int *noise_chans_out)
90f1d26c 1704{
174c454a 1705 int ch = 0, fmod_chans = 0, noise_chans = 0, irq_chans = 0;
90f1d26c 1706
5514a050 1707 if (spu.s_chan == NULL)
1708 return;
1709
90f1d26c 1710 for(;ch<MAXCHAN;ch++)
1711 {
5aa94fa0 1712 if (!(spu.dwChannelsAudible & (1<<ch)))
90f1d26c 1713 continue;
5514a050 1714 if (spu.s_chan[ch].bFMod == 2)
90f1d26c 1715 fmod_chans |= 1 << ch;
5514a050 1716 if (spu.s_chan[ch].bNoise)
90f1d26c 1717 noise_chans |= 1 << ch;
5514a050 1718 if((spu.spuCtrl&CTRL_IRQ) && spu.s_chan[ch].pCurr <= spu.pSpuIrq && spu.s_chan[ch].pLoop <= spu.pSpuIrq)
174c454a 1719 irq_chans |= 1 << ch;
90f1d26c 1720 }
1721
5aa94fa0 1722 *chans_out = spu.dwChannelsAudible;
1723 *run_chans = ~spu.dwChannelsAudible & ~spu.dwChannelDead & irq_chans;
90f1d26c 1724 *fmod_chans_out = fmod_chans;
1725 *noise_chans_out = noise_chans;
1726}
1727
6d866bb7 1728// vim:shiftwidth=1:expandtab