x86/amd-iommu: Add per IOMMU reference counting
[linux/fpc-iii.git] / sound / oss / opl3.c
blob7781c13c147635b53b06756e31b0daae50b583c0
1 /*
2 * sound/oss/opl3.c
4 * A low level driver for Yamaha YM3812 and OPL-3 -chips
7 * Copyright (C) by Hannu Savolainen 1993-1997
9 * OSS/Free for Linux is distributed under the GNU GENERAL PUBLIC LICENSE (GPL)
10 * Version 2 (June 1991). See the "COPYING" file distributed with this software
11 * for more info.
14 * Changes
15 * Thomas Sailer ioctl code reworked (vmalloc/vfree removed)
16 * Alan Cox modularisation, fixed sound_mem allocs.
17 * Christoph Hellwig Adapted to module_init/module_exit
18 * Arnaldo C. de Melo get rid of check_region, use request_region for
19 * OPL4, release it on exit, some cleanups.
21 * Status
22 * Believed to work. Badly needs rewriting a bit to support multiple
23 * OPL3 devices.
26 #include <linux/init.h>
27 #include <linux/module.h>
28 #include <linux/delay.h>
31 * Major improvements to the FM handling 30AUG92 by Rob Hooft,
32 * hooft@chem.ruu.nl
35 #include "sound_config.h"
37 #include "opl3_hw.h"
39 #define MAX_VOICE 18
40 #define OFFS_4OP 11
42 struct voice_info
44 unsigned char keyon_byte;
45 long bender;
46 long bender_range;
47 unsigned long orig_freq;
48 unsigned long current_freq;
49 int volume;
50 int mode;
51 int panning; /* 0xffff means not set */
54 typedef struct opl_devinfo
56 int base;
57 int left_io, right_io;
58 int nr_voice;
59 int lv_map[MAX_VOICE];
61 struct voice_info voc[MAX_VOICE];
62 struct voice_alloc_info *v_alloc;
63 struct channel_info *chn_info;
65 struct sbi_instrument i_map[SBFM_MAXINSTR];
66 struct sbi_instrument *act_i[MAX_VOICE];
68 struct synth_info fm_info;
70 int busy;
71 int model;
72 unsigned char cmask;
74 int is_opl4;
75 } opl_devinfo;
77 static struct opl_devinfo *devc = NULL;
79 static int detected_model;
81 static int store_instr(int instr_no, struct sbi_instrument *instr);
82 static void freq_to_fnum(int freq, int *block, int *fnum);
83 static void opl3_command(int io_addr, unsigned int addr, unsigned int val);
84 static int opl3_kill_note(int dev, int voice, int note, int velocity);
86 static void enter_4op_mode(void)
88 int i;
89 static int v4op[MAX_VOICE] = {
90 0, 1, 2, 9, 10, 11, 6, 7, 8, 15, 16, 17
93 devc->cmask = 0x3f; /* Connect all possible 4 OP voice operators */
94 opl3_command(devc->right_io, CONNECTION_SELECT_REGISTER, 0x3f);
96 for (i = 0; i < 3; i++)
97 pv_map[i].voice_mode = 4;
98 for (i = 3; i < 6; i++)
99 pv_map[i].voice_mode = 0;
101 for (i = 9; i < 12; i++)
102 pv_map[i].voice_mode = 4;
103 for (i = 12; i < 15; i++)
104 pv_map[i].voice_mode = 0;
106 for (i = 0; i < 12; i++)
107 devc->lv_map[i] = v4op[i];
108 devc->v_alloc->max_voice = devc->nr_voice = 12;
111 static int opl3_ioctl(int dev, unsigned int cmd, void __user * arg)
113 struct sbi_instrument ins;
115 switch (cmd) {
116 case SNDCTL_FM_LOAD_INSTR:
117 printk(KERN_WARNING "Warning: Obsolete ioctl(SNDCTL_FM_LOAD_INSTR) used. Fix the program.\n");
118 if (copy_from_user(&ins, arg, sizeof(ins)))
119 return -EFAULT;
120 if (ins.channel < 0 || ins.channel >= SBFM_MAXINSTR) {
121 printk(KERN_WARNING "FM Error: Invalid instrument number %d\n", ins.channel);
122 return -EINVAL;
124 return store_instr(ins.channel, &ins);
126 case SNDCTL_SYNTH_INFO:
127 devc->fm_info.nr_voices = (devc->nr_voice == 12) ? 6 : devc->nr_voice;
128 if (copy_to_user(arg, &devc->fm_info, sizeof(devc->fm_info)))
129 return -EFAULT;
130 return 0;
132 case SNDCTL_SYNTH_MEMAVL:
133 return 0x7fffffff;
135 case SNDCTL_FM_4OP_ENABLE:
136 if (devc->model == 2)
137 enter_4op_mode();
138 return 0;
140 default:
141 return -EINVAL;
145 static int opl3_detect(int ioaddr)
148 * This function returns 1 if the FM chip is present at the given I/O port
149 * The detection algorithm plays with the timer built in the FM chip and
150 * looks for a change in the status register.
152 * Note! The timers of the FM chip are not connected to AdLib (and compatible)
153 * boards.
155 * Note2! The chip is initialized if detected.
158 unsigned char stat1, signature;
159 int i;
161 if (devc != NULL)
163 printk(KERN_ERR "opl3: Only one OPL3 supported.\n");
164 return 0;
167 devc = kzalloc(sizeof(*devc), GFP_KERNEL);
169 if (devc == NULL)
171 printk(KERN_ERR "opl3: Can't allocate memory for the device control "
172 "structure \n ");
173 return 0;
176 strcpy(devc->fm_info.name, "OPL2");
178 if (!request_region(ioaddr, 4, devc->fm_info.name)) {
179 printk(KERN_WARNING "opl3: I/O port 0x%x already in use\n", ioaddr);
180 goto cleanup_devc;
183 devc->base = ioaddr;
185 /* Reset timers 1 and 2 */
186 opl3_command(ioaddr, TIMER_CONTROL_REGISTER, TIMER1_MASK | TIMER2_MASK);
188 /* Reset the IRQ of the FM chip */
189 opl3_command(ioaddr, TIMER_CONTROL_REGISTER, IRQ_RESET);
191 signature = stat1 = inb(ioaddr); /* Status register */
193 if (signature != 0x00 && signature != 0x06 && signature != 0x02 &&
194 signature != 0x0f)
196 MDB(printk(KERN_INFO "OPL3 not detected %x\n", signature));
197 goto cleanup_region;
200 if (signature == 0x06) /* OPL2 */
202 detected_model = 2;
204 else if (signature == 0x00 || signature == 0x0f) /* OPL3 or OPL4 */
206 unsigned char tmp;
208 detected_model = 3;
211 * Detect availability of OPL4 (_experimental_). Works probably
212 * only after a cold boot. In addition the OPL4 port
213 * of the chip may not be connected to the PC bus at all.
216 opl3_command(ioaddr + 2, OPL3_MODE_REGISTER, 0x00);
217 opl3_command(ioaddr + 2, OPL3_MODE_REGISTER, OPL3_ENABLE | OPL4_ENABLE);
219 if ((tmp = inb(ioaddr)) == 0x02) /* Have a OPL4 */
221 detected_model = 4;
224 if (request_region(ioaddr - 8, 2, "OPL4")) /* OPL4 port was free */
226 int tmp;
228 outb((0x02), ioaddr - 8); /* Select OPL4 ID register */
229 udelay(10);
230 tmp = inb(ioaddr - 7); /* Read it */
231 udelay(10);
233 if (tmp == 0x20) /* OPL4 should return 0x20 here */
235 detected_model = 4;
236 outb((0xF8), ioaddr - 8); /* Select OPL4 FM mixer control */
237 udelay(10);
238 outb((0x1B), ioaddr - 7); /* Write value */
239 udelay(10);
241 else
242 { /* release OPL4 port */
243 release_region(ioaddr - 8, 2);
244 detected_model = 3;
247 opl3_command(ioaddr + 2, OPL3_MODE_REGISTER, 0);
249 for (i = 0; i < 9; i++)
250 opl3_command(ioaddr, KEYON_BLOCK + i, 0); /*
251 * Note off
254 opl3_command(ioaddr, TEST_REGISTER, ENABLE_WAVE_SELECT);
255 opl3_command(ioaddr, PERCOSSION_REGISTER, 0x00); /*
256 * Melodic mode.
258 return 1;
259 cleanup_region:
260 release_region(ioaddr, 4);
261 cleanup_devc:
262 kfree(devc);
263 devc = NULL;
264 return 0;
267 static int opl3_kill_note (int devno, int voice, int note, int velocity)
269 struct physical_voice_info *map;
271 if (voice < 0 || voice >= devc->nr_voice)
272 return 0;
274 devc->v_alloc->map[voice] = 0;
276 map = &pv_map[devc->lv_map[voice]];
277 DEB(printk("Kill note %d\n", voice));
279 if (map->voice_mode == 0)
280 return 0;
282 opl3_command(map->ioaddr, KEYON_BLOCK + map->voice_num, devc->voc[voice].keyon_byte & ~0x20);
283 devc->voc[voice].keyon_byte = 0;
284 devc->voc[voice].bender = 0;
285 devc->voc[voice].volume = 64;
286 devc->voc[voice].panning = 0xffff; /* Not set */
287 devc->voc[voice].bender_range = 200;
288 devc->voc[voice].orig_freq = 0;
289 devc->voc[voice].current_freq = 0;
290 devc->voc[voice].mode = 0;
291 return 0;
294 #define HIHAT 0
295 #define CYMBAL 1
296 #define TOMTOM 2
297 #define SNARE 3
298 #define BDRUM 4
299 #define UNDEFINED TOMTOM
300 #define DEFAULT TOMTOM
302 static int store_instr(int instr_no, struct sbi_instrument *instr)
304 if (instr->key != FM_PATCH && (instr->key != OPL3_PATCH || devc->model != 2))
305 printk(KERN_WARNING "FM warning: Invalid patch format field (key) 0x%x\n", instr->key);
306 memcpy((char *) &(devc->i_map[instr_no]), (char *) instr, sizeof(*instr));
307 return 0;
310 static int opl3_set_instr (int dev, int voice, int instr_no)
312 if (voice < 0 || voice >= devc->nr_voice)
313 return 0;
314 if (instr_no < 0 || instr_no >= SBFM_MAXINSTR)
315 instr_no = 0; /* Acoustic piano (usually) */
317 devc->act_i[voice] = &devc->i_map[instr_no];
318 return 0;
322 * The next table looks magical, but it certainly is not. Its values have
323 * been calculated as table[i]=8*log(i/64)/log(2) with an obvious exception
324 * for i=0. This log-table converts a linear volume-scaling (0..127) to a
325 * logarithmic scaling as present in the FM-synthesizer chips. so : Volume
326 * 64 = 0 db = relative volume 0 and: Volume 32 = -6 db = relative
327 * volume -8 it was implemented as a table because it is only 128 bytes and
328 * it saves a lot of log() calculations. (RH)
331 static char fm_volume_table[128] =
333 -64, -48, -40, -35, -32, -29, -27, -26,
334 -24, -23, -21, -20, -19, -18, -18, -17,
335 -16, -15, -15, -14, -13, -13, -12, -12,
336 -11, -11, -10, -10, -10, -9, -9, -8,
337 -8, -8, -7, -7, -7, -6, -6, -6,
338 -5, -5, -5, -5, -4, -4, -4, -4,
339 -3, -3, -3, -3, -2, -2, -2, -2,
340 -2, -1, -1, -1, -1, 0, 0, 0,
341 0, 0, 0, 1, 1, 1, 1, 1,
342 1, 2, 2, 2, 2, 2, 2, 2,
343 3, 3, 3, 3, 3, 3, 3, 4,
344 4, 4, 4, 4, 4, 4, 4, 5,
345 5, 5, 5, 5, 5, 5, 5, 5,
346 6, 6, 6, 6, 6, 6, 6, 6,
347 6, 7, 7, 7, 7, 7, 7, 7,
348 7, 7, 7, 8, 8, 8, 8, 8
351 static void calc_vol(unsigned char *regbyte, int volume, int main_vol)
353 int level = (~*regbyte & 0x3f);
355 if (main_vol > 127)
356 main_vol = 127;
357 volume = (volume * main_vol) / 127;
359 if (level)
360 level += fm_volume_table[volume];
362 if (level > 0x3f)
363 level = 0x3f;
364 if (level < 0)
365 level = 0;
367 *regbyte = (*regbyte & 0xc0) | (~level & 0x3f);
370 static void set_voice_volume(int voice, int volume, int main_vol)
372 unsigned char vol1, vol2, vol3, vol4;
373 struct sbi_instrument *instr;
374 struct physical_voice_info *map;
376 if (voice < 0 || voice >= devc->nr_voice)
377 return;
379 map = &pv_map[devc->lv_map[voice]];
380 instr = devc->act_i[voice];
382 if (!instr)
383 instr = &devc->i_map[0];
385 if (instr->channel < 0)
386 return;
388 if (devc->voc[voice].mode == 0)
389 return;
391 if (devc->voc[voice].mode == 2)
393 vol1 = instr->operators[2];
394 vol2 = instr->operators[3];
395 if ((instr->operators[10] & 0x01))
397 calc_vol(&vol1, volume, main_vol);
398 calc_vol(&vol2, volume, main_vol);
400 else
402 calc_vol(&vol2, volume, main_vol);
404 opl3_command(map->ioaddr, KSL_LEVEL + map->op[0], vol1);
405 opl3_command(map->ioaddr, KSL_LEVEL + map->op[1], vol2);
407 else
408 { /*
409 * 4 OP voice
411 int connection;
413 vol1 = instr->operators[2];
414 vol2 = instr->operators[3];
415 vol3 = instr->operators[OFFS_4OP + 2];
416 vol4 = instr->operators[OFFS_4OP + 3];
419 * The connection method for 4 OP devc->voc is defined by the rightmost
420 * bits at the offsets 10 and 10+OFFS_4OP
423 connection = ((instr->operators[10] & 0x01) << 1) | (instr->operators[10 + OFFS_4OP] & 0x01);
425 switch (connection)
427 case 0:
428 calc_vol(&vol4, volume, main_vol);
429 break;
431 case 1:
432 calc_vol(&vol2, volume, main_vol);
433 calc_vol(&vol4, volume, main_vol);
434 break;
436 case 2:
437 calc_vol(&vol1, volume, main_vol);
438 calc_vol(&vol4, volume, main_vol);
439 break;
441 case 3:
442 calc_vol(&vol1, volume, main_vol);
443 calc_vol(&vol3, volume, main_vol);
444 calc_vol(&vol4, volume, main_vol);
445 break;
447 default:
450 opl3_command(map->ioaddr, KSL_LEVEL + map->op[0], vol1);
451 opl3_command(map->ioaddr, KSL_LEVEL + map->op[1], vol2);
452 opl3_command(map->ioaddr, KSL_LEVEL + map->op[2], vol3);
453 opl3_command(map->ioaddr, KSL_LEVEL + map->op[3], vol4);
457 static int opl3_start_note (int dev, int voice, int note, int volume)
459 unsigned char data, fpc;
460 int block, fnum, freq, voice_mode, pan;
461 struct sbi_instrument *instr;
462 struct physical_voice_info *map;
464 if (voice < 0 || voice >= devc->nr_voice)
465 return 0;
467 map = &pv_map[devc->lv_map[voice]];
468 pan = devc->voc[voice].panning;
470 if (map->voice_mode == 0)
471 return 0;
473 if (note == 255) /*
474 * Just change the volume
477 set_voice_volume(voice, volume, devc->voc[voice].volume);
478 return 0;
482 * Kill previous note before playing
485 opl3_command(map->ioaddr, KSL_LEVEL + map->op[1], 0xff); /*
486 * Carrier
487 * volume to
488 * min
490 opl3_command(map->ioaddr, KSL_LEVEL + map->op[0], 0xff); /*
491 * Modulator
492 * volume to
495 if (map->voice_mode == 4)
497 opl3_command(map->ioaddr, KSL_LEVEL + map->op[2], 0xff);
498 opl3_command(map->ioaddr, KSL_LEVEL + map->op[3], 0xff);
501 opl3_command(map->ioaddr, KEYON_BLOCK + map->voice_num, 0x00); /*
502 * Note
503 * off
506 instr = devc->act_i[voice];
508 if (!instr)
509 instr = &devc->i_map[0];
511 if (instr->channel < 0)
513 printk(KERN_WARNING "opl3: Initializing voice %d with undefined instrument\n", voice);
514 return 0;
517 if (map->voice_mode == 2 && instr->key == OPL3_PATCH)
518 return 0; /*
519 * Cannot play
522 voice_mode = map->voice_mode;
524 if (voice_mode == 4)
526 int voice_shift;
528 voice_shift = (map->ioaddr == devc->left_io) ? 0 : 3;
529 voice_shift += map->voice_num;
531 if (instr->key != OPL3_PATCH) /*
532 * Just 2 OP patch
535 voice_mode = 2;
536 devc->cmask &= ~(1 << voice_shift);
538 else
540 devc->cmask |= (1 << voice_shift);
543 opl3_command(devc->right_io, CONNECTION_SELECT_REGISTER, devc->cmask);
547 * Set Sound Characteristics
550 opl3_command(map->ioaddr, AM_VIB + map->op[0], instr->operators[0]);
551 opl3_command(map->ioaddr, AM_VIB + map->op[1], instr->operators[1]);
554 * Set Attack/Decay
557 opl3_command(map->ioaddr, ATTACK_DECAY + map->op[0], instr->operators[4]);
558 opl3_command(map->ioaddr, ATTACK_DECAY + map->op[1], instr->operators[5]);
561 * Set Sustain/Release
564 opl3_command(map->ioaddr, SUSTAIN_RELEASE + map->op[0], instr->operators[6]);
565 opl3_command(map->ioaddr, SUSTAIN_RELEASE + map->op[1], instr->operators[7]);
568 * Set Wave Select
571 opl3_command(map->ioaddr, WAVE_SELECT + map->op[0], instr->operators[8]);
572 opl3_command(map->ioaddr, WAVE_SELECT + map->op[1], instr->operators[9]);
575 * Set Feedback/Connection
578 fpc = instr->operators[10];
580 if (pan != 0xffff)
582 fpc &= ~STEREO_BITS;
583 if (pan < -64)
584 fpc |= VOICE_TO_LEFT;
585 else
586 if (pan > 64)
587 fpc |= VOICE_TO_RIGHT;
588 else
589 fpc |= (VOICE_TO_LEFT | VOICE_TO_RIGHT);
592 if (!(fpc & 0x30))
593 fpc |= 0x30; /*
594 * Ensure that at least one chn is enabled
596 opl3_command(map->ioaddr, FEEDBACK_CONNECTION + map->voice_num, fpc);
599 * If the voice is a 4 OP one, initialize the operators 3 and 4 also
602 if (voice_mode == 4)
605 * Set Sound Characteristics
608 opl3_command(map->ioaddr, AM_VIB + map->op[2], instr->operators[OFFS_4OP + 0]);
609 opl3_command(map->ioaddr, AM_VIB + map->op[3], instr->operators[OFFS_4OP + 1]);
612 * Set Attack/Decay
615 opl3_command(map->ioaddr, ATTACK_DECAY + map->op[2], instr->operators[OFFS_4OP + 4]);
616 opl3_command(map->ioaddr, ATTACK_DECAY + map->op[3], instr->operators[OFFS_4OP + 5]);
619 * Set Sustain/Release
622 opl3_command(map->ioaddr, SUSTAIN_RELEASE + map->op[2], instr->operators[OFFS_4OP + 6]);
623 opl3_command(map->ioaddr, SUSTAIN_RELEASE + map->op[3], instr->operators[OFFS_4OP + 7]);
626 * Set Wave Select
629 opl3_command(map->ioaddr, WAVE_SELECT + map->op[2], instr->operators[OFFS_4OP + 8]);
630 opl3_command(map->ioaddr, WAVE_SELECT + map->op[3], instr->operators[OFFS_4OP + 9]);
633 * Set Feedback/Connection
636 fpc = instr->operators[OFFS_4OP + 10];
637 if (!(fpc & 0x30))
638 fpc |= 0x30; /*
639 * Ensure that at least one chn is enabled
641 opl3_command(map->ioaddr, FEEDBACK_CONNECTION + map->voice_num + 3, fpc);
644 devc->voc[voice].mode = voice_mode;
645 set_voice_volume(voice, volume, devc->voc[voice].volume);
647 freq = devc->voc[voice].orig_freq = note_to_freq(note) / 1000;
650 * Since the pitch bender may have been set before playing the note, we
651 * have to calculate the bending now.
654 freq = compute_finetune(devc->voc[voice].orig_freq, devc->voc[voice].bender, devc->voc[voice].bender_range, 0);
655 devc->voc[voice].current_freq = freq;
657 freq_to_fnum(freq, &block, &fnum);
660 * Play note
663 data = fnum & 0xff; /*
664 * Least significant bits of fnumber
666 opl3_command(map->ioaddr, FNUM_LOW + map->voice_num, data);
668 data = 0x20 | ((block & 0x7) << 2) | ((fnum >> 8) & 0x3);
669 devc->voc[voice].keyon_byte = data;
670 opl3_command(map->ioaddr, KEYON_BLOCK + map->voice_num, data);
671 if (voice_mode == 4)
672 opl3_command(map->ioaddr, KEYON_BLOCK + map->voice_num + 3, data);
674 return 0;
677 static void freq_to_fnum (int freq, int *block, int *fnum)
679 int f, octave;
682 * Converts the note frequency to block and fnum values for the FM chip
685 * First try to compute the block -value (octave) where the note belongs
688 f = freq;
690 octave = 5;
692 if (f == 0)
693 octave = 0;
694 else if (f < 261)
696 while (f < 261)
698 octave--;
699 f <<= 1;
702 else if (f > 493)
704 while (f > 493)
706 octave++;
707 f >>= 1;
711 if (octave > 7)
712 octave = 7;
714 *fnum = freq * (1 << (20 - octave)) / 49716;
715 *block = octave;
718 static void opl3_command (int io_addr, unsigned int addr, unsigned int val)
720 int i;
723 * The original 2-OP synth requires a quite long delay after writing to a
724 * register. The OPL-3 survives with just two INBs
727 outb(((unsigned char) (addr & 0xff)), io_addr);
729 if (devc->model != 2)
730 udelay(10);
731 else
732 for (i = 0; i < 2; i++)
733 inb(io_addr);
735 outb(((unsigned char) (val & 0xff)), io_addr + 1);
737 if (devc->model != 2)
738 udelay(30);
739 else
740 for (i = 0; i < 2; i++)
741 inb(io_addr);
744 static void opl3_reset(int devno)
746 int i;
748 for (i = 0; i < 18; i++)
749 devc->lv_map[i] = i;
751 for (i = 0; i < devc->nr_voice; i++)
753 opl3_command(pv_map[devc->lv_map[i]].ioaddr,
754 KSL_LEVEL + pv_map[devc->lv_map[i]].op[0], 0xff);
756 opl3_command(pv_map[devc->lv_map[i]].ioaddr,
757 KSL_LEVEL + pv_map[devc->lv_map[i]].op[1], 0xff);
759 if (pv_map[devc->lv_map[i]].voice_mode == 4)
761 opl3_command(pv_map[devc->lv_map[i]].ioaddr,
762 KSL_LEVEL + pv_map[devc->lv_map[i]].op[2], 0xff);
764 opl3_command(pv_map[devc->lv_map[i]].ioaddr,
765 KSL_LEVEL + pv_map[devc->lv_map[i]].op[3], 0xff);
768 opl3_kill_note(devno, i, 0, 64);
771 if (devc->model == 2)
773 devc->v_alloc->max_voice = devc->nr_voice = 18;
775 for (i = 0; i < 18; i++)
776 pv_map[i].voice_mode = 2;
781 static int opl3_open(int dev, int mode)
783 int i;
785 if (devc->busy)
786 return -EBUSY;
787 devc->busy = 1;
789 devc->v_alloc->max_voice = devc->nr_voice = (devc->model == 2) ? 18 : 9;
790 devc->v_alloc->timestamp = 0;
792 for (i = 0; i < 18; i++)
794 devc->v_alloc->map[i] = 0;
795 devc->v_alloc->alloc_times[i] = 0;
798 devc->cmask = 0x00; /*
799 * Just 2 OP mode
801 if (devc->model == 2)
802 opl3_command(devc->right_io, CONNECTION_SELECT_REGISTER, devc->cmask);
803 return 0;
806 static void opl3_close(int dev)
808 devc->busy = 0;
809 devc->v_alloc->max_voice = devc->nr_voice = (devc->model == 2) ? 18 : 9;
811 devc->fm_info.nr_drums = 0;
812 devc->fm_info.perc_mode = 0;
814 opl3_reset(dev);
817 static void opl3_hw_control(int dev, unsigned char *event)
821 static int opl3_load_patch(int dev, int format, const char __user *addr,
822 int offs, int count, int pmgr_flag)
824 struct sbi_instrument ins;
826 if (count <sizeof(ins))
828 printk(KERN_WARNING "FM Error: Patch record too short\n");
829 return -EINVAL;
833 * What the fuck is going on here? We leave junk in the beginning
834 * of ins and then check the field pretty close to that beginning?
836 if(copy_from_user(&((char *) &ins)[offs], addr + offs, sizeof(ins) - offs))
837 return -EFAULT;
839 if (ins.channel < 0 || ins.channel >= SBFM_MAXINSTR)
841 printk(KERN_WARNING "FM Error: Invalid instrument number %d\n", ins.channel);
842 return -EINVAL;
844 ins.key = format;
846 return store_instr(ins.channel, &ins);
849 static void opl3_panning(int dev, int voice, int value)
851 devc->voc[voice].panning = value;
854 static void opl3_volume_method(int dev, int mode)
858 #define SET_VIBRATO(cell) { \
859 tmp = instr->operators[(cell-1)+(((cell-1)/2)*OFFS_4OP)]; \
860 if (pressure > 110) \
861 tmp |= 0x40; /* Vibrato on */ \
862 opl3_command (map->ioaddr, AM_VIB + map->op[cell-1], tmp);}
864 static void opl3_aftertouch(int dev, int voice, int pressure)
866 int tmp;
867 struct sbi_instrument *instr;
868 struct physical_voice_info *map;
870 if (voice < 0 || voice >= devc->nr_voice)
871 return;
873 map = &pv_map[devc->lv_map[voice]];
875 DEB(printk("Aftertouch %d\n", voice));
877 if (map->voice_mode == 0)
878 return;
881 * Adjust the amount of vibrato depending the pressure
884 instr = devc->act_i[voice];
886 if (!instr)
887 instr = &devc->i_map[0];
889 if (devc->voc[voice].mode == 4)
891 int connection = ((instr->operators[10] & 0x01) << 1) | (instr->operators[10 + OFFS_4OP] & 0x01);
893 switch (connection)
895 case 0:
896 SET_VIBRATO(4);
897 break;
899 case 1:
900 SET_VIBRATO(2);
901 SET_VIBRATO(4);
902 break;
904 case 2:
905 SET_VIBRATO(1);
906 SET_VIBRATO(4);
907 break;
909 case 3:
910 SET_VIBRATO(1);
911 SET_VIBRATO(3);
912 SET_VIBRATO(4);
913 break;
917 * Not implemented yet
920 else
922 SET_VIBRATO(1);
924 if ((instr->operators[10] & 0x01)) /*
925 * Additive synthesis
927 SET_VIBRATO(2);
931 #undef SET_VIBRATO
933 static void bend_pitch(int dev, int voice, int value)
935 unsigned char data;
936 int block, fnum, freq;
937 struct physical_voice_info *map;
939 map = &pv_map[devc->lv_map[voice]];
941 if (map->voice_mode == 0)
942 return;
944 devc->voc[voice].bender = value;
945 if (!value)
946 return;
947 if (!(devc->voc[voice].keyon_byte & 0x20))
948 return; /*
949 * Not keyed on
952 freq = compute_finetune(devc->voc[voice].orig_freq, devc->voc[voice].bender, devc->voc[voice].bender_range, 0);
953 devc->voc[voice].current_freq = freq;
955 freq_to_fnum(freq, &block, &fnum);
957 data = fnum & 0xff; /*
958 * Least significant bits of fnumber
960 opl3_command(map->ioaddr, FNUM_LOW + map->voice_num, data);
962 data = 0x20 | ((block & 0x7) << 2) | ((fnum >> 8) & 0x3);
963 devc->voc[voice].keyon_byte = data;
964 opl3_command(map->ioaddr, KEYON_BLOCK + map->voice_num, data);
967 static void opl3_controller (int dev, int voice, int ctrl_num, int value)
969 if (voice < 0 || voice >= devc->nr_voice)
970 return;
972 switch (ctrl_num)
974 case CTRL_PITCH_BENDER:
975 bend_pitch(dev, voice, value);
976 break;
978 case CTRL_PITCH_BENDER_RANGE:
979 devc->voc[voice].bender_range = value;
980 break;
982 case CTL_MAIN_VOLUME:
983 devc->voc[voice].volume = value / 128;
984 break;
986 case CTL_PAN:
987 devc->voc[voice].panning = (value * 2) - 128;
988 break;
992 static void opl3_bender(int dev, int voice, int value)
994 if (voice < 0 || voice >= devc->nr_voice)
995 return;
997 bend_pitch(dev, voice, value - 8192);
1000 static int opl3_alloc_voice(int dev, int chn, int note, struct voice_alloc_info *alloc)
1002 int i, p, best, first, avail, best_time = 0x7fffffff;
1003 struct sbi_instrument *instr;
1004 int is4op;
1005 int instr_no;
1007 if (chn < 0 || chn > 15)
1008 instr_no = 0;
1009 else
1010 instr_no = devc->chn_info[chn].pgm_num;
1012 instr = &devc->i_map[instr_no];
1013 if (instr->channel < 0 || /* Instrument not loaded */
1014 devc->nr_voice != 12) /* Not in 4 OP mode */
1015 is4op = 0;
1016 else if (devc->nr_voice == 12) /* 4 OP mode */
1017 is4op = (instr->key == OPL3_PATCH);
1018 else
1019 is4op = 0;
1021 if (is4op)
1023 first = p = 0;
1024 avail = 6;
1026 else
1028 if (devc->nr_voice == 12) /* 4 OP mode. Use the '2 OP only' operators first */
1029 first = p = 6;
1030 else
1031 first = p = 0;
1032 avail = devc->nr_voice;
1036 * Now try to find a free voice
1038 best = first;
1040 for (i = 0; i < avail; i++)
1042 if (alloc->map[p] == 0)
1044 return p;
1046 if (alloc->alloc_times[p] < best_time) /* Find oldest playing note */
1048 best_time = alloc->alloc_times[p];
1049 best = p;
1051 p = (p + 1) % avail;
1055 * Insert some kind of priority mechanism here.
1058 if (best < 0)
1059 best = 0;
1060 if (best > devc->nr_voice)
1061 best -= devc->nr_voice;
1063 return best; /* All devc->voc in use. Select the first one. */
1066 static void opl3_setup_voice(int dev, int voice, int chn)
1068 struct channel_info *info =
1069 &synth_devs[dev]->chn_info[chn];
1071 opl3_set_instr(dev, voice, info->pgm_num);
1073 devc->voc[voice].bender = 0;
1074 devc->voc[voice].bender_range = info->bender_range;
1075 devc->voc[voice].volume = info->controllers[CTL_MAIN_VOLUME];
1076 devc->voc[voice].panning = (info->controllers[CTL_PAN] * 2) - 128;
1079 static struct synth_operations opl3_operations =
1081 .owner = THIS_MODULE,
1082 .id = "OPL",
1083 .info = NULL,
1084 .midi_dev = 0,
1085 .synth_type = SYNTH_TYPE_FM,
1086 .synth_subtype = FM_TYPE_ADLIB,
1087 .open = opl3_open,
1088 .close = opl3_close,
1089 .ioctl = opl3_ioctl,
1090 .kill_note = opl3_kill_note,
1091 .start_note = opl3_start_note,
1092 .set_instr = opl3_set_instr,
1093 .reset = opl3_reset,
1094 .hw_control = opl3_hw_control,
1095 .load_patch = opl3_load_patch,
1096 .aftertouch = opl3_aftertouch,
1097 .controller = opl3_controller,
1098 .panning = opl3_panning,
1099 .volume_method = opl3_volume_method,
1100 .bender = opl3_bender,
1101 .alloc_voice = opl3_alloc_voice,
1102 .setup_voice = opl3_setup_voice
1105 static int opl3_init(int ioaddr, struct module *owner)
1107 int i;
1108 int me;
1110 if (devc == NULL)
1112 printk(KERN_ERR "opl3: Device control structure not initialized.\n");
1113 return -1;
1116 if ((me = sound_alloc_synthdev()) == -1)
1118 printk(KERN_WARNING "opl3: Too many synthesizers\n");
1119 return -1;
1122 devc->nr_voice = 9;
1124 devc->fm_info.device = 0;
1125 devc->fm_info.synth_type = SYNTH_TYPE_FM;
1126 devc->fm_info.synth_subtype = FM_TYPE_ADLIB;
1127 devc->fm_info.perc_mode = 0;
1128 devc->fm_info.nr_voices = 9;
1129 devc->fm_info.nr_drums = 0;
1130 devc->fm_info.instr_bank_size = SBFM_MAXINSTR;
1131 devc->fm_info.capabilities = 0;
1132 devc->left_io = ioaddr;
1133 devc->right_io = ioaddr + 2;
1135 if (detected_model <= 2)
1136 devc->model = 1;
1137 else
1139 devc->model = 2;
1140 if (detected_model == 4)
1141 devc->is_opl4 = 1;
1144 opl3_operations.info = &devc->fm_info;
1146 synth_devs[me] = &opl3_operations;
1148 if (owner)
1149 synth_devs[me]->owner = owner;
1151 sequencer_init();
1152 devc->v_alloc = &opl3_operations.alloc;
1153 devc->chn_info = &opl3_operations.chn_info[0];
1155 if (devc->model == 2)
1157 if (devc->is_opl4)
1158 strcpy(devc->fm_info.name, "Yamaha OPL4/OPL3 FM");
1159 else
1160 strcpy(devc->fm_info.name, "Yamaha OPL3");
1162 devc->v_alloc->max_voice = devc->nr_voice = 18;
1163 devc->fm_info.nr_drums = 0;
1164 devc->fm_info.synth_subtype = FM_TYPE_OPL3;
1165 devc->fm_info.capabilities |= SYNTH_CAP_OPL3;
1167 for (i = 0; i < 18; i++)
1169 if (pv_map[i].ioaddr == USE_LEFT)
1170 pv_map[i].ioaddr = devc->left_io;
1171 else
1172 pv_map[i].ioaddr = devc->right_io;
1174 opl3_command(devc->right_io, OPL3_MODE_REGISTER, OPL3_ENABLE);
1175 opl3_command(devc->right_io, CONNECTION_SELECT_REGISTER, 0x00);
1177 else
1179 strcpy(devc->fm_info.name, "Yamaha OPL2");
1180 devc->v_alloc->max_voice = devc->nr_voice = 9;
1181 devc->fm_info.nr_drums = 0;
1183 for (i = 0; i < 18; i++)
1184 pv_map[i].ioaddr = devc->left_io;
1186 conf_printf2(devc->fm_info.name, ioaddr, 0, -1, -1);
1188 for (i = 0; i < SBFM_MAXINSTR; i++)
1189 devc->i_map[i].channel = -1;
1191 return me;
1194 static int me;
1196 static int io = -1;
1198 module_param(io, int, 0);
1200 static int __init init_opl3 (void)
1202 printk(KERN_INFO "YM3812 and OPL-3 driver Copyright (C) by Hannu Savolainen, Rob Hooft 1993-1996\n");
1204 if (io != -1) /* User loading pure OPL3 module */
1206 if (!opl3_detect(io))
1208 return -ENODEV;
1211 me = opl3_init(io, THIS_MODULE);
1214 return 0;
1217 static void __exit cleanup_opl3(void)
1219 if (devc && io != -1)
1221 if (devc->base) {
1222 release_region(devc->base,4);
1223 if (devc->is_opl4)
1224 release_region(devc->base - 8, 2);
1226 kfree(devc);
1227 devc = NULL;
1228 sound_unload_synthdev(me);
1232 module_init(init_opl3);
1233 module_exit(cleanup_opl3);
1235 #ifndef MODULE
1236 static int __init setup_opl3(char *str)
1238 /* io */
1239 int ints[2];
1241 str = get_options(str, ARRAY_SIZE(ints), ints);
1243 io = ints[1];
1245 return 1;
1248 __setup("opl3=", setup_opl3);
1249 #endif
1250 MODULE_LICENSE("GPL");