Revert "[PATCH] paravirt: Add startup infrastructure for paravirtualization"
[pv_ops_mirror.git] / sound / isa / wavefront / wavefront_synth.c
blob78020d832e042ba089cae9c71f94833f988ec111
1 /* Copyright (C) by Paul Barton-Davis 1998-1999
3 * Some portions of this file are taken from work that is
4 * copyright (C) by Hannu Savolainen 1993-1996
6 * This program is distributed under the GNU GENERAL PUBLIC LICENSE (GPL)
7 * Version 2 (June 1991). See the "COPYING" file distributed with this software
8 * for more info.
9 */
11 /*
12 * An ALSA lowlevel driver for Turtle Beach ICS2115 wavetable synth
13 * (Maui, Tropez, Tropez Plus)
15 * This driver supports the onboard wavetable synthesizer (an ICS2115),
16 * including patch, sample and program loading and unloading, conversion
17 * of GUS patches during loading, and full user-level access to all
18 * WaveFront commands. It tries to provide semi-intelligent patch and
19 * sample management as well.
23 #include <sound/driver.h>
24 #include <asm/io.h>
25 #include <linux/interrupt.h>
26 #include <linux/init.h>
27 #include <linux/delay.h>
28 #include <linux/time.h>
29 #include <linux/wait.h>
30 #include <linux/moduleparam.h>
31 #include <sound/core.h>
32 #include <sound/snd_wavefront.h>
33 #include <sound/initval.h>
35 static int wf_raw = 0; /* we normally check for "raw state" to firmware
36 loading. if non-zero, then during driver loading, the
37 state of the board is ignored, and we reset the
38 board and load the firmware anyway.
41 static int fx_raw = 1; /* if this is zero, we'll leave the FX processor in
42 whatever state it is when the driver is loaded.
43 The default is to download the microprogram and
44 associated coefficients to set it up for "default"
45 operation, whatever that means.
48 static int debug_default = 0; /* you can set this to control debugging
49 during driver loading. it takes any combination
50 of the WF_DEBUG_* flags defined in
51 wavefront.h
54 /* XXX this needs to be made firmware and hardware version dependent */
56 static char *ospath = "/etc/sound/wavefront.os"; /* where to find a processed
57 version of the WaveFront OS
60 static int wait_usecs = 150; /* This magic number seems to give pretty optimal
61 throughput based on my limited experimentation.
62 If you want to play around with it and find a better
63 value, be my guest. Remember, the idea is to
64 get a number that causes us to just busy wait
65 for as many WaveFront commands as possible, without
66 coming up with a number so large that we hog the
67 whole CPU.
69 Specifically, with this number, out of about 134,000
70 status waits, only about 250 result in a sleep.
73 static int sleep_interval = 100; /* HZ/sleep_interval seconds per sleep */
74 static int sleep_tries = 50; /* number of times we'll try to sleep */
76 static int reset_time = 2; /* hundreths of a second we wait after a HW
77 reset for the expected interrupt.
80 static int ramcheck_time = 20; /* time in seconds to wait while ROM code
81 checks on-board RAM.
84 static int osrun_time = 10; /* time in seconds we wait for the OS to
85 start running.
87 module_param(wf_raw, int, 0444);
88 MODULE_PARM_DESC(wf_raw, "if non-zero, assume that we need to boot the OS");
89 module_param(fx_raw, int, 0444);
90 MODULE_PARM_DESC(fx_raw, "if non-zero, assume that the FX process needs help");
91 module_param(debug_default, int, 0444);
92 MODULE_PARM_DESC(debug_default, "debug parameters for card initialization");
93 module_param(wait_usecs, int, 0444);
94 MODULE_PARM_DESC(wait_usecs, "how long to wait without sleeping, usecs");
95 module_param(sleep_interval, int, 0444);
96 MODULE_PARM_DESC(sleep_interval, "how long to sleep when waiting for reply");
97 module_param(sleep_tries, int, 0444);
98 MODULE_PARM_DESC(sleep_tries, "how many times to try sleeping during a wait");
99 module_param(ospath, charp, 0444);
100 MODULE_PARM_DESC(ospath, "full pathname to processed ICS2115 OS firmware");
101 module_param(reset_time, int, 0444);
102 MODULE_PARM_DESC(reset_time, "how long to wait for a reset to take effect");
103 module_param(ramcheck_time, int, 0444);
104 MODULE_PARM_DESC(ramcheck_time, "how many seconds to wait for the RAM test");
105 module_param(osrun_time, int, 0444);
106 MODULE_PARM_DESC(osrun_time, "how many seconds to wait for the ICS2115 OS");
108 /* if WF_DEBUG not defined, no run-time debugging messages will
109 be available via the debug flag setting. Given the current
110 beta state of the driver, this will remain set until a future
111 version.
114 #define WF_DEBUG 1
116 #ifdef WF_DEBUG
118 #define DPRINT(cond, ...) \
119 if ((dev->debug & (cond)) == (cond)) { \
120 snd_printk (__VA_ARGS__); \
122 #else
123 #define DPRINT(cond, args...)
124 #endif /* WF_DEBUG */
126 #define LOGNAME "WaveFront: "
128 /* bitmasks for WaveFront status port value */
130 #define STAT_RINTR_ENABLED 0x01
131 #define STAT_CAN_READ 0x02
132 #define STAT_INTR_READ 0x04
133 #define STAT_WINTR_ENABLED 0x10
134 #define STAT_CAN_WRITE 0x20
135 #define STAT_INTR_WRITE 0x40
137 static int wavefront_delete_sample (snd_wavefront_t *, int sampnum);
138 static int wavefront_find_free_sample (snd_wavefront_t *);
140 struct wavefront_command {
141 int cmd;
142 char *action;
143 unsigned int read_cnt;
144 unsigned int write_cnt;
145 int need_ack;
148 static struct {
149 int errno;
150 const char *errstr;
151 } wavefront_errors[] = {
152 { 0x01, "Bad sample number" },
153 { 0x02, "Out of sample memory" },
154 { 0x03, "Bad patch number" },
155 { 0x04, "Error in number of voices" },
156 { 0x06, "Sample load already in progress" },
157 { 0x0B, "No sample load request pending" },
158 { 0x0E, "Bad MIDI channel number" },
159 { 0x10, "Download Record Error" },
160 { 0x80, "Success" },
161 { 0x0 }
164 #define NEEDS_ACK 1
166 static struct wavefront_command wavefront_commands[] = {
167 { WFC_SET_SYNTHVOL, "set synthesizer volume", 0, 1, NEEDS_ACK },
168 { WFC_GET_SYNTHVOL, "get synthesizer volume", 1, 0, 0},
169 { WFC_SET_NVOICES, "set number of voices", 0, 1, NEEDS_ACK },
170 { WFC_GET_NVOICES, "get number of voices", 1, 0, 0 },
171 { WFC_SET_TUNING, "set synthesizer tuning", 0, 2, NEEDS_ACK },
172 { WFC_GET_TUNING, "get synthesizer tuning", 2, 0, 0 },
173 { WFC_DISABLE_CHANNEL, "disable synth channel", 0, 1, NEEDS_ACK },
174 { WFC_ENABLE_CHANNEL, "enable synth channel", 0, 1, NEEDS_ACK },
175 { WFC_GET_CHANNEL_STATUS, "get synth channel status", 3, 0, 0 },
176 { WFC_MISYNTH_OFF, "disable midi-in to synth", 0, 0, NEEDS_ACK },
177 { WFC_MISYNTH_ON, "enable midi-in to synth", 0, 0, NEEDS_ACK },
178 { WFC_VMIDI_ON, "enable virtual midi mode", 0, 0, NEEDS_ACK },
179 { WFC_VMIDI_OFF, "disable virtual midi mode", 0, 0, NEEDS_ACK },
180 { WFC_MIDI_STATUS, "report midi status", 1, 0, 0 },
181 { WFC_FIRMWARE_VERSION, "report firmware version", 2, 0, 0 },
182 { WFC_HARDWARE_VERSION, "report hardware version", 2, 0, 0 },
183 { WFC_GET_NSAMPLES, "report number of samples", 2, 0, 0 },
184 { WFC_INSTOUT_LEVELS, "report instantaneous output levels", 7, 0, 0 },
185 { WFC_PEAKOUT_LEVELS, "report peak output levels", 7, 0, 0 },
186 { WFC_DOWNLOAD_SAMPLE, "download sample",
187 0, WF_SAMPLE_BYTES, NEEDS_ACK },
188 { WFC_DOWNLOAD_BLOCK, "download block", 0, 0, NEEDS_ACK},
189 { WFC_DOWNLOAD_SAMPLE_HEADER, "download sample header",
190 0, WF_SAMPLE_HDR_BYTES, NEEDS_ACK },
191 { WFC_UPLOAD_SAMPLE_HEADER, "upload sample header", 13, 2, 0 },
193 /* This command requires a variable number of bytes to be written.
194 There is a hack in snd_wavefront_cmd() to support this. The actual
195 count is passed in as the read buffer ptr, cast appropriately.
196 Ugh.
199 { WFC_DOWNLOAD_MULTISAMPLE, "download multisample", 0, 0, NEEDS_ACK },
201 /* This one is a hack as well. We just read the first byte of the
202 response, don't fetch an ACK, and leave the rest to the
203 calling function. Ugly, ugly, ugly.
206 { WFC_UPLOAD_MULTISAMPLE, "upload multisample", 2, 1, 0 },
207 { WFC_DOWNLOAD_SAMPLE_ALIAS, "download sample alias",
208 0, WF_ALIAS_BYTES, NEEDS_ACK },
209 { WFC_UPLOAD_SAMPLE_ALIAS, "upload sample alias", WF_ALIAS_BYTES, 2, 0},
210 { WFC_DELETE_SAMPLE, "delete sample", 0, 2, NEEDS_ACK },
211 { WFC_IDENTIFY_SAMPLE_TYPE, "identify sample type", 5, 2, 0 },
212 { WFC_UPLOAD_SAMPLE_PARAMS, "upload sample parameters" },
213 { WFC_REPORT_FREE_MEMORY, "report free memory", 4, 0, 0 },
214 { WFC_DOWNLOAD_PATCH, "download patch", 0, 134, NEEDS_ACK },
215 { WFC_UPLOAD_PATCH, "upload patch", 132, 2, 0 },
216 { WFC_DOWNLOAD_PROGRAM, "download program", 0, 33, NEEDS_ACK },
217 { WFC_UPLOAD_PROGRAM, "upload program", 32, 1, 0 },
218 { WFC_DOWNLOAD_EDRUM_PROGRAM, "download enhanced drum program", 0, 9,
219 NEEDS_ACK},
220 { WFC_UPLOAD_EDRUM_PROGRAM, "upload enhanced drum program", 8, 1, 0},
221 { WFC_SET_EDRUM_CHANNEL, "set enhanced drum program channel",
222 0, 1, NEEDS_ACK },
223 { WFC_DISABLE_DRUM_PROGRAM, "disable drum program", 0, 1, NEEDS_ACK },
224 { WFC_REPORT_CHANNEL_PROGRAMS, "report channel program numbers",
225 32, 0, 0 },
226 { WFC_NOOP, "the no-op command", 0, 0, NEEDS_ACK },
227 { 0x00 }
230 static const char *
231 wavefront_errorstr (int errnum)
234 int i;
236 for (i = 0; wavefront_errors[i].errstr; i++) {
237 if (wavefront_errors[i].errno == errnum) {
238 return wavefront_errors[i].errstr;
242 return "Unknown WaveFront error";
245 static struct wavefront_command *
246 wavefront_get_command (int cmd)
249 int i;
251 for (i = 0; wavefront_commands[i].cmd != 0; i++) {
252 if (cmd == wavefront_commands[i].cmd) {
253 return &wavefront_commands[i];
257 return NULL;
260 static inline int
261 wavefront_status (snd_wavefront_t *dev)
264 return inb (dev->status_port);
267 static int
268 wavefront_sleep (int limit)
271 schedule_timeout_interruptible(limit);
273 return signal_pending(current);
276 static int
277 wavefront_wait (snd_wavefront_t *dev, int mask)
280 int i;
282 /* Spin for a short period of time, because >99% of all
283 requests to the WaveFront can be serviced inline like this.
286 for (i = 0; i < wait_usecs; i += 5) {
287 if (wavefront_status (dev) & mask) {
288 return 1;
290 udelay(5);
293 for (i = 0; i < sleep_tries; i++) {
295 if (wavefront_status (dev) & mask) {
296 return 1;
299 if (wavefront_sleep (HZ/sleep_interval)) {
300 return (0);
304 return (0);
307 static int
308 wavefront_read (snd_wavefront_t *dev)
311 if (wavefront_wait (dev, STAT_CAN_READ))
312 return inb (dev->data_port);
314 DPRINT (WF_DEBUG_DATA, "read timeout.\n");
316 return -1;
319 static int
320 wavefront_write (snd_wavefront_t *dev, unsigned char data)
323 if (wavefront_wait (dev, STAT_CAN_WRITE)) {
324 outb (data, dev->data_port);
325 return 0;
328 DPRINT (WF_DEBUG_DATA, "write timeout.\n");
330 return -1;
334 snd_wavefront_cmd (snd_wavefront_t *dev,
335 int cmd, unsigned char *rbuf, unsigned char *wbuf)
338 int ack;
339 unsigned int i;
340 int c;
341 struct wavefront_command *wfcmd;
343 if ((wfcmd = wavefront_get_command (cmd)) == NULL) {
344 snd_printk ("command 0x%x not supported.\n",
345 cmd);
346 return 1;
349 /* Hack to handle the one variable-size write command. See
350 wavefront_send_multisample() for the other half of this
351 gross and ugly strategy.
354 if (cmd == WFC_DOWNLOAD_MULTISAMPLE) {
355 wfcmd->write_cnt = (unsigned long) rbuf;
356 rbuf = NULL;
359 DPRINT (WF_DEBUG_CMD, "0x%x [%s] (%d,%d,%d)\n",
360 cmd, wfcmd->action, wfcmd->read_cnt,
361 wfcmd->write_cnt, wfcmd->need_ack);
363 if (wavefront_write (dev, cmd)) {
364 DPRINT ((WF_DEBUG_IO|WF_DEBUG_CMD), "cannot request "
365 "0x%x [%s].\n",
366 cmd, wfcmd->action);
367 return 1;
370 if (wfcmd->write_cnt > 0) {
371 DPRINT (WF_DEBUG_DATA, "writing %d bytes "
372 "for 0x%x\n",
373 wfcmd->write_cnt, cmd);
375 for (i = 0; i < wfcmd->write_cnt; i++) {
376 if (wavefront_write (dev, wbuf[i])) {
377 DPRINT (WF_DEBUG_IO, "bad write for byte "
378 "%d of 0x%x [%s].\n",
379 i, cmd, wfcmd->action);
380 return 1;
383 DPRINT (WF_DEBUG_DATA, "write[%d] = 0x%x\n",
384 i, wbuf[i]);
388 if (wfcmd->read_cnt > 0) {
389 DPRINT (WF_DEBUG_DATA, "reading %d ints "
390 "for 0x%x\n",
391 wfcmd->read_cnt, cmd);
393 for (i = 0; i < wfcmd->read_cnt; i++) {
395 if ((c = wavefront_read (dev)) == -1) {
396 DPRINT (WF_DEBUG_IO, "bad read for byte "
397 "%d of 0x%x [%s].\n",
398 i, cmd, wfcmd->action);
399 return 1;
402 /* Now handle errors. Lots of special cases here */
404 if (c == 0xff) {
405 if ((c = wavefront_read (dev)) == -1) {
406 DPRINT (WF_DEBUG_IO, "bad read for "
407 "error byte at "
408 "read byte %d "
409 "of 0x%x [%s].\n",
410 i, cmd,
411 wfcmd->action);
412 return 1;
415 /* Can you believe this madness ? */
417 if (c == 1 &&
418 wfcmd->cmd == WFC_IDENTIFY_SAMPLE_TYPE) {
419 rbuf[0] = WF_ST_EMPTY;
420 return (0);
422 } else if (c == 3 &&
423 wfcmd->cmd == WFC_UPLOAD_PATCH) {
425 return 3;
427 } else if (c == 1 &&
428 wfcmd->cmd == WFC_UPLOAD_PROGRAM) {
430 return 1;
432 } else {
434 DPRINT (WF_DEBUG_IO, "error %d (%s) "
435 "during "
436 "read for byte "
437 "%d of 0x%x "
438 "[%s].\n",
440 wavefront_errorstr (c),
441 i, cmd,
442 wfcmd->action);
443 return 1;
447 } else {
448 rbuf[i] = c;
451 DPRINT (WF_DEBUG_DATA, "read[%d] = 0x%x\n",i, rbuf[i]);
455 if ((wfcmd->read_cnt == 0 && wfcmd->write_cnt == 0) || wfcmd->need_ack) {
457 DPRINT (WF_DEBUG_CMD, "reading ACK for 0x%x\n", cmd);
459 /* Some commands need an ACK, but return zero instead
460 of the standard value.
463 if ((ack = wavefront_read (dev)) == 0) {
464 ack = WF_ACK;
467 if (ack != WF_ACK) {
468 if (ack == -1) {
469 DPRINT (WF_DEBUG_IO, "cannot read ack for "
470 "0x%x [%s].\n",
471 cmd, wfcmd->action);
472 return 1;
474 } else {
475 int err = -1; /* something unknown */
477 if (ack == 0xff) { /* explicit error */
479 if ((err = wavefront_read (dev)) == -1) {
480 DPRINT (WF_DEBUG_DATA,
481 "cannot read err "
482 "for 0x%x [%s].\n",
483 cmd, wfcmd->action);
487 DPRINT (WF_DEBUG_IO, "0x%x [%s] "
488 "failed (0x%x, 0x%x, %s)\n",
489 cmd, wfcmd->action, ack, err,
490 wavefront_errorstr (err));
492 return -err;
496 DPRINT (WF_DEBUG_DATA, "ack received "
497 "for 0x%x [%s]\n",
498 cmd, wfcmd->action);
499 } else {
501 DPRINT (WF_DEBUG_CMD, "0x%x [%s] does not need "
502 "ACK (%d,%d,%d)\n",
503 cmd, wfcmd->action, wfcmd->read_cnt,
504 wfcmd->write_cnt, wfcmd->need_ack);
507 return 0;
511 /***********************************************************************
512 WaveFront data munging
514 Things here are weird. All data written to the board cannot
515 have its most significant bit set. Any data item with values
516 potentially > 0x7F (127) must be split across multiple bytes.
518 Sometimes, we need to munge numeric values that are represented on
519 the x86 side as 8-32 bit values. Sometimes, we need to munge data
520 that is represented on the x86 side as an array of bytes. The most
521 efficient approach to handling both cases seems to be to use 2
522 different functions for munging and 2 for de-munging. This avoids
523 weird casting and worrying about bit-level offsets.
525 **********************************************************************/
527 static unsigned char *
528 munge_int32 (unsigned int src,
529 unsigned char *dst,
530 unsigned int dst_size)
532 unsigned int i;
534 for (i = 0; i < dst_size; i++) {
535 *dst = src & 0x7F; /* Mask high bit of LSB */
536 src = src >> 7; /* Rotate Right 7 bits */
537 /* Note: we leave the upper bits in place */
539 dst++;
541 return dst;
544 static int
545 demunge_int32 (unsigned char* src, int src_size)
548 int i;
549 int outval = 0;
551 for (i = src_size - 1; i >= 0; i--) {
552 outval=(outval<<7)+src[i];
555 return outval;
558 static
559 unsigned char *
560 munge_buf (unsigned char *src, unsigned char *dst, unsigned int dst_size)
563 unsigned int i;
564 unsigned int last = dst_size / 2;
566 for (i = 0; i < last; i++) {
567 *dst++ = src[i] & 0x7f;
568 *dst++ = src[i] >> 7;
570 return dst;
573 static
574 unsigned char *
575 demunge_buf (unsigned char *src, unsigned char *dst, unsigned int src_bytes)
578 int i;
579 unsigned char *end = src + src_bytes;
581 end = src + src_bytes;
583 /* NOTE: src and dst *CAN* point to the same address */
585 for (i = 0; src != end; i++) {
586 dst[i] = *src++;
587 dst[i] |= (*src++)<<7;
590 return dst;
593 /***********************************************************************
594 WaveFront: sample, patch and program management.
595 ***********************************************************************/
597 static int
598 wavefront_delete_sample (snd_wavefront_t *dev, int sample_num)
601 unsigned char wbuf[2];
602 int x;
604 wbuf[0] = sample_num & 0x7f;
605 wbuf[1] = sample_num >> 7;
607 if ((x = snd_wavefront_cmd (dev, WFC_DELETE_SAMPLE, NULL, wbuf)) == 0) {
608 dev->sample_status[sample_num] = WF_ST_EMPTY;
611 return x;
614 static int
615 wavefront_get_sample_status (snd_wavefront_t *dev, int assume_rom)
618 int i;
619 unsigned char rbuf[32], wbuf[32];
620 unsigned int sc_real, sc_alias, sc_multi;
622 /* check sample status */
624 if (snd_wavefront_cmd (dev, WFC_GET_NSAMPLES, rbuf, wbuf)) {
625 snd_printk ("cannot request sample count.\n");
626 return -1;
629 sc_real = sc_alias = sc_multi = dev->samples_used = 0;
631 for (i = 0; i < WF_MAX_SAMPLE; i++) {
633 wbuf[0] = i & 0x7f;
634 wbuf[1] = i >> 7;
636 if (snd_wavefront_cmd (dev, WFC_IDENTIFY_SAMPLE_TYPE, rbuf, wbuf)) {
637 snd_printk("cannot identify sample "
638 "type of slot %d\n", i);
639 dev->sample_status[i] = WF_ST_EMPTY;
640 continue;
643 dev->sample_status[i] = (WF_SLOT_FILLED|rbuf[0]);
645 if (assume_rom) {
646 dev->sample_status[i] |= WF_SLOT_ROM;
649 switch (rbuf[0] & WF_ST_MASK) {
650 case WF_ST_SAMPLE:
651 sc_real++;
652 break;
653 case WF_ST_MULTISAMPLE:
654 sc_multi++;
655 break;
656 case WF_ST_ALIAS:
657 sc_alias++;
658 break;
659 case WF_ST_EMPTY:
660 break;
662 default:
663 snd_printk ("unknown sample type for "
664 "slot %d (0x%x)\n",
665 i, rbuf[0]);
668 if (rbuf[0] != WF_ST_EMPTY) {
669 dev->samples_used++;
673 snd_printk ("%d samples used (%d real, %d aliases, %d multi), "
674 "%d empty\n", dev->samples_used, sc_real, sc_alias, sc_multi,
675 WF_MAX_SAMPLE - dev->samples_used);
678 return (0);
682 static int
683 wavefront_get_patch_status (snd_wavefront_t *dev)
686 unsigned char patchbuf[WF_PATCH_BYTES];
687 unsigned char patchnum[2];
688 wavefront_patch *p;
689 int i, x, cnt, cnt2;
691 for (i = 0; i < WF_MAX_PATCH; i++) {
692 patchnum[0] = i & 0x7f;
693 patchnum[1] = i >> 7;
695 if ((x = snd_wavefront_cmd (dev, WFC_UPLOAD_PATCH, patchbuf,
696 patchnum)) == 0) {
698 dev->patch_status[i] |= WF_SLOT_FILLED;
699 p = (wavefront_patch *) patchbuf;
700 dev->sample_status
701 [p->sample_number|(p->sample_msb<<7)] |=
702 WF_SLOT_USED;
704 } else if (x == 3) { /* Bad patch number */
705 dev->patch_status[i] = 0;
706 } else {
707 snd_printk ("upload patch "
708 "error 0x%x\n", x);
709 dev->patch_status[i] = 0;
710 return 1;
714 /* program status has already filled in slot_used bits */
716 for (i = 0, cnt = 0, cnt2 = 0; i < WF_MAX_PATCH; i++) {
717 if (dev->patch_status[i] & WF_SLOT_FILLED) {
718 cnt++;
720 if (dev->patch_status[i] & WF_SLOT_USED) {
721 cnt2++;
725 snd_printk ("%d patch slots filled, %d in use\n", cnt, cnt2);
727 return (0);
730 static int
731 wavefront_get_program_status (snd_wavefront_t *dev)
734 unsigned char progbuf[WF_PROGRAM_BYTES];
735 wavefront_program prog;
736 unsigned char prognum;
737 int i, x, l, cnt;
739 for (i = 0; i < WF_MAX_PROGRAM; i++) {
740 prognum = i;
742 if ((x = snd_wavefront_cmd (dev, WFC_UPLOAD_PROGRAM, progbuf,
743 &prognum)) == 0) {
745 dev->prog_status[i] |= WF_SLOT_USED;
747 demunge_buf (progbuf, (unsigned char *) &prog,
748 WF_PROGRAM_BYTES);
750 for (l = 0; l < WF_NUM_LAYERS; l++) {
751 if (prog.layer[l].mute) {
752 dev->patch_status
753 [prog.layer[l].patch_number] |=
754 WF_SLOT_USED;
757 } else if (x == 1) { /* Bad program number */
758 dev->prog_status[i] = 0;
759 } else {
760 snd_printk ("upload program "
761 "error 0x%x\n", x);
762 dev->prog_status[i] = 0;
766 for (i = 0, cnt = 0; i < WF_MAX_PROGRAM; i++) {
767 if (dev->prog_status[i]) {
768 cnt++;
772 snd_printk ("%d programs slots in use\n", cnt);
774 return (0);
777 static int
778 wavefront_send_patch (snd_wavefront_t *dev, wavefront_patch_info *header)
781 unsigned char buf[WF_PATCH_BYTES+2];
782 unsigned char *bptr;
784 DPRINT (WF_DEBUG_LOAD_PATCH, "downloading patch %d\n",
785 header->number);
787 dev->patch_status[header->number] |= WF_SLOT_FILLED;
789 bptr = buf;
790 bptr = munge_int32 (header->number, buf, 2);
791 munge_buf ((unsigned char *)&header->hdr.p, bptr, WF_PATCH_BYTES);
793 if (snd_wavefront_cmd (dev, WFC_DOWNLOAD_PATCH, NULL, buf)) {
794 snd_printk ("download patch failed\n");
795 return -(EIO);
798 return (0);
801 static int
802 wavefront_send_program (snd_wavefront_t *dev, wavefront_patch_info *header)
805 unsigned char buf[WF_PROGRAM_BYTES+1];
806 int i;
808 DPRINT (WF_DEBUG_LOAD_PATCH, "downloading program %d\n",
809 header->number);
811 dev->prog_status[header->number] = WF_SLOT_USED;
813 /* XXX need to zero existing SLOT_USED bit for program_status[i]
814 where `i' is the program that's being (potentially) overwritten.
817 for (i = 0; i < WF_NUM_LAYERS; i++) {
818 if (header->hdr.pr.layer[i].mute) {
819 dev->patch_status[header->hdr.pr.layer[i].patch_number] |=
820 WF_SLOT_USED;
822 /* XXX need to mark SLOT_USED for sample used by
823 patch_number, but this means we have to load it. Ick.
828 buf[0] = header->number;
829 munge_buf ((unsigned char *)&header->hdr.pr, &buf[1], WF_PROGRAM_BYTES);
831 if (snd_wavefront_cmd (dev, WFC_DOWNLOAD_PROGRAM, NULL, buf)) {
832 snd_printk ("download patch failed\n");
833 return -(EIO);
836 return (0);
839 static int
840 wavefront_freemem (snd_wavefront_t *dev)
843 char rbuf[8];
845 if (snd_wavefront_cmd (dev, WFC_REPORT_FREE_MEMORY, rbuf, NULL)) {
846 snd_printk ("can't get memory stats.\n");
847 return -1;
848 } else {
849 return demunge_int32 (rbuf, 4);
853 static int
854 wavefront_send_sample (snd_wavefront_t *dev,
855 wavefront_patch_info *header,
856 u16 __user *dataptr,
857 int data_is_unsigned)
860 /* samples are downloaded via a 16-bit wide i/o port
861 (you could think of it as 2 adjacent 8-bit wide ports
862 but its less efficient that way). therefore, all
863 the blocksizes and so forth listed in the documentation,
864 and used conventionally to refer to sample sizes,
865 which are given in 8-bit units (bytes), need to be
866 divided by 2.
869 u16 sample_short = 0;
870 u32 length;
871 u16 __user *data_end = NULL;
872 unsigned int i;
873 const unsigned int max_blksize = 4096/2;
874 unsigned int written;
875 unsigned int blocksize;
876 int dma_ack;
877 int blocknum;
878 unsigned char sample_hdr[WF_SAMPLE_HDR_BYTES];
879 unsigned char *shptr;
880 int skip = 0;
881 int initial_skip = 0;
883 DPRINT (WF_DEBUG_LOAD_PATCH, "sample %sdownload for slot %d, "
884 "type %d, %d bytes from 0x%lx\n",
885 header->size ? "" : "header ",
886 header->number, header->subkey,
887 header->size,
888 (unsigned long) header->dataptr);
890 if (header->number == WAVEFRONT_FIND_FREE_SAMPLE_SLOT) {
891 int x;
893 if ((x = wavefront_find_free_sample (dev)) < 0) {
894 return -ENOMEM;
896 snd_printk ("unspecified sample => %d\n", x);
897 header->number = x;
900 if (header->size) {
902 /* XXX it's a debatable point whether or not RDONLY semantics
903 on the ROM samples should cover just the sample data or
904 the sample header. For now, it only covers the sample data,
905 so anyone is free at all times to rewrite sample headers.
907 My reason for this is that we have the sample headers
908 available in the WFB file for General MIDI, and so these
909 can always be reset if needed. The sample data, however,
910 cannot be recovered without a complete reset and firmware
911 reload of the ICS2115, which is a very expensive operation.
913 So, doing things this way allows us to honor the notion of
914 "RESETSAMPLES" reasonably cheaply. Note however, that this
915 is done purely at user level: there is no WFB parser in
916 this driver, and so a complete reset (back to General MIDI,
917 or theoretically some other configuration) is the
918 responsibility of the user level library.
920 To try to do this in the kernel would be a little
921 crazy: we'd need 158K of kernel space just to hold
922 a copy of the patch/program/sample header data.
925 if (dev->rom_samples_rdonly) {
926 if (dev->sample_status[header->number] & WF_SLOT_ROM) {
927 snd_printk ("sample slot %d "
928 "write protected\n",
929 header->number);
930 return -EACCES;
934 wavefront_delete_sample (dev, header->number);
937 if (header->size) {
938 dev->freemem = wavefront_freemem (dev);
940 if (dev->freemem < (int)header->size) {
941 snd_printk ("insufficient memory to "
942 "load %d byte sample.\n",
943 header->size);
944 return -ENOMEM;
949 skip = WF_GET_CHANNEL(&header->hdr.s);
951 if (skip > 0 && header->hdr.s.SampleResolution != LINEAR_16BIT) {
952 snd_printk ("channel selection only "
953 "possible on 16-bit samples");
954 return -(EINVAL);
957 switch (skip) {
958 case 0:
959 initial_skip = 0;
960 skip = 1;
961 break;
962 case 1:
963 initial_skip = 0;
964 skip = 2;
965 break;
966 case 2:
967 initial_skip = 1;
968 skip = 2;
969 break;
970 case 3:
971 initial_skip = 2;
972 skip = 3;
973 break;
974 case 4:
975 initial_skip = 3;
976 skip = 4;
977 break;
978 case 5:
979 initial_skip = 4;
980 skip = 5;
981 break;
982 case 6:
983 initial_skip = 5;
984 skip = 6;
985 break;
988 DPRINT (WF_DEBUG_LOAD_PATCH, "channel selection: %d => "
989 "initial skip = %d, skip = %d\n",
990 WF_GET_CHANNEL (&header->hdr.s),
991 initial_skip, skip);
993 /* Be safe, and zero the "Unused" bits ... */
995 WF_SET_CHANNEL(&header->hdr.s, 0);
997 /* adjust size for 16 bit samples by dividing by two. We always
998 send 16 bits per write, even for 8 bit samples, so the length
999 is always half the size of the sample data in bytes.
1002 length = header->size / 2;
1004 /* the data we're sent has not been munged, and in fact, the
1005 header we have to send isn't just a munged copy either.
1006 so, build the sample header right here.
1009 shptr = &sample_hdr[0];
1011 shptr = munge_int32 (header->number, shptr, 2);
1013 if (header->size) {
1014 shptr = munge_int32 (length, shptr, 4);
1017 /* Yes, a 4 byte result doesn't contain all of the offset bits,
1018 but the offset only uses 24 bits.
1021 shptr = munge_int32 (*((u32 *) &header->hdr.s.sampleStartOffset),
1022 shptr, 4);
1023 shptr = munge_int32 (*((u32 *) &header->hdr.s.loopStartOffset),
1024 shptr, 4);
1025 shptr = munge_int32 (*((u32 *) &header->hdr.s.loopEndOffset),
1026 shptr, 4);
1027 shptr = munge_int32 (*((u32 *) &header->hdr.s.sampleEndOffset),
1028 shptr, 4);
1030 /* This one is truly weird. What kind of weirdo decided that in
1031 a system dominated by 16 and 32 bit integers, they would use
1032 a just 12 bits ?
1035 shptr = munge_int32 (header->hdr.s.FrequencyBias, shptr, 3);
1037 /* Why is this nybblified, when the MSB is *always* zero ?
1038 Anyway, we can't take address of bitfield, so make a
1039 good-faith guess at where it starts.
1042 shptr = munge_int32 (*(&header->hdr.s.FrequencyBias+1),
1043 shptr, 2);
1045 if (snd_wavefront_cmd (dev,
1046 header->size ?
1047 WFC_DOWNLOAD_SAMPLE : WFC_DOWNLOAD_SAMPLE_HEADER,
1048 NULL, sample_hdr)) {
1049 snd_printk ("sample %sdownload refused.\n",
1050 header->size ? "" : "header ");
1051 return -(EIO);
1054 if (header->size == 0) {
1055 goto sent; /* Sorry. Just had to have one somewhere */
1058 data_end = dataptr + length;
1060 /* Do any initial skip over an unused channel's data */
1062 dataptr += initial_skip;
1064 for (written = 0, blocknum = 0;
1065 written < length; written += max_blksize, blocknum++) {
1067 if ((length - written) > max_blksize) {
1068 blocksize = max_blksize;
1069 } else {
1070 /* round to nearest 16-byte value */
1071 blocksize = ALIGN(length - written, 8);
1074 if (snd_wavefront_cmd (dev, WFC_DOWNLOAD_BLOCK, NULL, NULL)) {
1075 snd_printk ("download block "
1076 "request refused.\n");
1077 return -(EIO);
1080 for (i = 0; i < blocksize; i++) {
1082 if (dataptr < data_end) {
1084 __get_user (sample_short, dataptr);
1085 dataptr += skip;
1087 if (data_is_unsigned) { /* GUS ? */
1089 if (WF_SAMPLE_IS_8BIT(&header->hdr.s)) {
1091 /* 8 bit sample
1092 resolution, sign
1093 extend both bytes.
1096 ((unsigned char*)
1097 &sample_short)[0] += 0x7f;
1098 ((unsigned char*)
1099 &sample_short)[1] += 0x7f;
1101 } else {
1103 /* 16 bit sample
1104 resolution, sign
1105 extend the MSB.
1108 sample_short += 0x7fff;
1112 } else {
1114 /* In padding section of final block:
1116 Don't fetch unsupplied data from
1117 user space, just continue with
1118 whatever the final value was.
1122 if (i < blocksize - 1) {
1123 outw (sample_short, dev->block_port);
1124 } else {
1125 outw (sample_short, dev->last_block_port);
1129 /* Get "DMA page acknowledge", even though its really
1130 nothing to do with DMA at all.
1133 if ((dma_ack = wavefront_read (dev)) != WF_DMA_ACK) {
1134 if (dma_ack == -1) {
1135 snd_printk ("upload sample "
1136 "DMA ack timeout\n");
1137 return -(EIO);
1138 } else {
1139 snd_printk ("upload sample "
1140 "DMA ack error 0x%x\n",
1141 dma_ack);
1142 return -(EIO);
1147 dev->sample_status[header->number] = (WF_SLOT_FILLED|WF_ST_SAMPLE);
1149 /* Note, label is here because sending the sample header shouldn't
1150 alter the sample_status info at all.
1153 sent:
1154 return (0);
1157 static int
1158 wavefront_send_alias (snd_wavefront_t *dev, wavefront_patch_info *header)
1161 unsigned char alias_hdr[WF_ALIAS_BYTES];
1163 DPRINT (WF_DEBUG_LOAD_PATCH, "download alias, %d is "
1164 "alias for %d\n",
1165 header->number,
1166 header->hdr.a.OriginalSample);
1168 munge_int32 (header->number, &alias_hdr[0], 2);
1169 munge_int32 (header->hdr.a.OriginalSample, &alias_hdr[2], 2);
1170 munge_int32 (*((unsigned int *)&header->hdr.a.sampleStartOffset),
1171 &alias_hdr[4], 4);
1172 munge_int32 (*((unsigned int *)&header->hdr.a.loopStartOffset),
1173 &alias_hdr[8], 4);
1174 munge_int32 (*((unsigned int *)&header->hdr.a.loopEndOffset),
1175 &alias_hdr[12], 4);
1176 munge_int32 (*((unsigned int *)&header->hdr.a.sampleEndOffset),
1177 &alias_hdr[16], 4);
1178 munge_int32 (header->hdr.a.FrequencyBias, &alias_hdr[20], 3);
1179 munge_int32 (*(&header->hdr.a.FrequencyBias+1), &alias_hdr[23], 2);
1181 if (snd_wavefront_cmd (dev, WFC_DOWNLOAD_SAMPLE_ALIAS, NULL, alias_hdr)) {
1182 snd_printk ("download alias failed.\n");
1183 return -(EIO);
1186 dev->sample_status[header->number] = (WF_SLOT_FILLED|WF_ST_ALIAS);
1188 return (0);
1191 static int
1192 wavefront_send_multisample (snd_wavefront_t *dev, wavefront_patch_info *header)
1194 int i;
1195 int num_samples;
1196 unsigned char *msample_hdr;
1198 msample_hdr = kmalloc(sizeof(WF_MSAMPLE_BYTES), GFP_KERNEL);
1199 if (! msample_hdr)
1200 return -ENOMEM;
1202 munge_int32 (header->number, &msample_hdr[0], 2);
1204 /* You'll recall at this point that the "number of samples" value
1205 in a wavefront_multisample struct is actually the log2 of the
1206 real number of samples.
1209 num_samples = (1<<(header->hdr.ms.NumberOfSamples&7));
1210 msample_hdr[2] = (unsigned char) header->hdr.ms.NumberOfSamples;
1212 DPRINT (WF_DEBUG_LOAD_PATCH, "multi %d with %d=%d samples\n",
1213 header->number,
1214 header->hdr.ms.NumberOfSamples,
1215 num_samples);
1217 for (i = 0; i < num_samples; i++) {
1218 DPRINT(WF_DEBUG_LOAD_PATCH|WF_DEBUG_DATA, "sample[%d] = %d\n",
1219 i, header->hdr.ms.SampleNumber[i]);
1220 munge_int32 (header->hdr.ms.SampleNumber[i],
1221 &msample_hdr[3+(i*2)], 2);
1224 /* Need a hack here to pass in the number of bytes
1225 to be written to the synth. This is ugly, and perhaps
1226 one day, I'll fix it.
1229 if (snd_wavefront_cmd (dev, WFC_DOWNLOAD_MULTISAMPLE,
1230 (unsigned char *) (long) ((num_samples*2)+3),
1231 msample_hdr)) {
1232 snd_printk ("download of multisample failed.\n");
1233 kfree(msample_hdr);
1234 return -(EIO);
1237 dev->sample_status[header->number] = (WF_SLOT_FILLED|WF_ST_MULTISAMPLE);
1239 kfree(msample_hdr);
1240 return (0);
1243 static int
1244 wavefront_fetch_multisample (snd_wavefront_t *dev,
1245 wavefront_patch_info *header)
1247 int i;
1248 unsigned char log_ns[1];
1249 unsigned char number[2];
1250 int num_samples;
1252 munge_int32 (header->number, number, 2);
1254 if (snd_wavefront_cmd (dev, WFC_UPLOAD_MULTISAMPLE, log_ns, number)) {
1255 snd_printk ("upload multisample failed.\n");
1256 return -(EIO);
1259 DPRINT (WF_DEBUG_DATA, "msample %d has %d samples\n",
1260 header->number, log_ns[0]);
1262 header->hdr.ms.NumberOfSamples = log_ns[0];
1264 /* get the number of samples ... */
1266 num_samples = (1 << log_ns[0]);
1268 for (i = 0; i < num_samples; i++) {
1269 char d[2];
1270 int val;
1272 if ((val = wavefront_read (dev)) == -1) {
1273 snd_printk ("upload multisample failed "
1274 "during sample loop.\n");
1275 return -(EIO);
1277 d[0] = val;
1279 if ((val = wavefront_read (dev)) == -1) {
1280 snd_printk ("upload multisample failed "
1281 "during sample loop.\n");
1282 return -(EIO);
1284 d[1] = val;
1286 header->hdr.ms.SampleNumber[i] =
1287 demunge_int32 ((unsigned char *) d, 2);
1289 DPRINT (WF_DEBUG_DATA, "msample sample[%d] = %d\n",
1290 i, header->hdr.ms.SampleNumber[i]);
1293 return (0);
1297 static int
1298 wavefront_send_drum (snd_wavefront_t *dev, wavefront_patch_info *header)
1301 unsigned char drumbuf[WF_DRUM_BYTES];
1302 wavefront_drum *drum = &header->hdr.d;
1303 int i;
1305 DPRINT (WF_DEBUG_LOAD_PATCH, "downloading edrum for MIDI "
1306 "note %d, patch = %d\n",
1307 header->number, drum->PatchNumber);
1309 drumbuf[0] = header->number & 0x7f;
1311 for (i = 0; i < 4; i++) {
1312 munge_int32 (((unsigned char *)drum)[i], &drumbuf[1+(i*2)], 2);
1315 if (snd_wavefront_cmd (dev, WFC_DOWNLOAD_EDRUM_PROGRAM, NULL, drumbuf)) {
1316 snd_printk ("download drum failed.\n");
1317 return -(EIO);
1320 return (0);
1323 static int
1324 wavefront_find_free_sample (snd_wavefront_t *dev)
1327 int i;
1329 for (i = 0; i < WF_MAX_SAMPLE; i++) {
1330 if (!(dev->sample_status[i] & WF_SLOT_FILLED)) {
1331 return i;
1334 snd_printk ("no free sample slots!\n");
1335 return -1;
1338 #if 0
1339 static int
1340 wavefront_find_free_patch (snd_wavefront_t *dev)
1343 int i;
1345 for (i = 0; i < WF_MAX_PATCH; i++) {
1346 if (!(dev->patch_status[i] & WF_SLOT_FILLED)) {
1347 return i;
1350 snd_printk ("no free patch slots!\n");
1351 return -1;
1353 #endif
1355 static int
1356 wavefront_load_patch (snd_wavefront_t *dev, const char __user *addr)
1358 wavefront_patch_info *header;
1359 int err;
1361 header = kmalloc(sizeof(*header), GFP_KERNEL);
1362 if (! header)
1363 return -ENOMEM;
1365 if (copy_from_user (header, addr, sizeof(wavefront_patch_info) -
1366 sizeof(wavefront_any))) {
1367 snd_printk ("bad address for load patch.\n");
1368 err = -EFAULT;
1369 goto __error;
1372 DPRINT (WF_DEBUG_LOAD_PATCH, "download "
1373 "Sample type: %d "
1374 "Sample number: %d "
1375 "Sample size: %d\n",
1376 header->subkey,
1377 header->number,
1378 header->size);
1380 switch (header->subkey) {
1381 case WF_ST_SAMPLE: /* sample or sample_header, based on patch->size */
1383 if (copy_from_user (&header->hdr.s, header->hdrptr,
1384 sizeof (wavefront_sample))) {
1385 err = -EFAULT;
1386 break;
1389 err = wavefront_send_sample (dev, header, header->dataptr, 0);
1390 break;
1392 case WF_ST_MULTISAMPLE:
1394 if (copy_from_user (&header->hdr.s, header->hdrptr,
1395 sizeof (wavefront_multisample))) {
1396 err = -EFAULT;
1397 break;
1400 err = wavefront_send_multisample (dev, header);
1401 break;
1403 case WF_ST_ALIAS:
1405 if (copy_from_user (&header->hdr.a, header->hdrptr,
1406 sizeof (wavefront_alias))) {
1407 err = -EFAULT;
1408 break;
1411 err = wavefront_send_alias (dev, header);
1412 break;
1414 case WF_ST_DRUM:
1415 if (copy_from_user (&header->hdr.d, header->hdrptr,
1416 sizeof (wavefront_drum))) {
1417 err = -EFAULT;
1418 break;
1421 err = wavefront_send_drum (dev, header);
1422 break;
1424 case WF_ST_PATCH:
1425 if (copy_from_user (&header->hdr.p, header->hdrptr,
1426 sizeof (wavefront_patch))) {
1427 err = -EFAULT;
1428 break;
1431 err = wavefront_send_patch (dev, header);
1432 break;
1434 case WF_ST_PROGRAM:
1435 if (copy_from_user (&header->hdr.pr, header->hdrptr,
1436 sizeof (wavefront_program))) {
1437 err = -EFAULT;
1438 break;
1441 err = wavefront_send_program (dev, header);
1442 break;
1444 default:
1445 snd_printk ("unknown patch type %d.\n",
1446 header->subkey);
1447 err = -EINVAL;
1448 break;
1451 __error:
1452 kfree(header);
1453 return err;
1456 /***********************************************************************
1457 WaveFront: hardware-dependent interface
1458 ***********************************************************************/
1460 static void
1461 process_sample_hdr (u8 *buf)
1464 wavefront_sample s;
1465 u8 *ptr;
1467 ptr = buf;
1469 /* The board doesn't send us an exact copy of a "wavefront_sample"
1470 in response to an Upload Sample Header command. Instead, we
1471 have to convert the data format back into our data structure,
1472 just as in the Download Sample command, where we have to do
1473 something very similar in the reverse direction.
1476 *((u32 *) &s.sampleStartOffset) = demunge_int32 (ptr, 4); ptr += 4;
1477 *((u32 *) &s.loopStartOffset) = demunge_int32 (ptr, 4); ptr += 4;
1478 *((u32 *) &s.loopEndOffset) = demunge_int32 (ptr, 4); ptr += 4;
1479 *((u32 *) &s.sampleEndOffset) = demunge_int32 (ptr, 4); ptr += 4;
1480 *((u32 *) &s.FrequencyBias) = demunge_int32 (ptr, 3); ptr += 3;
1482 s.SampleResolution = *ptr & 0x3;
1483 s.Loop = *ptr & 0x8;
1484 s.Bidirectional = *ptr & 0x10;
1485 s.Reverse = *ptr & 0x40;
1487 /* Now copy it back to where it came from */
1489 memcpy (buf, (unsigned char *) &s, sizeof (wavefront_sample));
1492 static int
1493 wavefront_synth_control (snd_wavefront_card_t *acard,
1494 wavefront_control *wc)
1497 snd_wavefront_t *dev = &acard->wavefront;
1498 unsigned char patchnumbuf[2];
1499 int i;
1501 DPRINT (WF_DEBUG_CMD, "synth control with "
1502 "cmd 0x%x\n", wc->cmd);
1504 /* Pre-handling of or for various commands */
1506 switch (wc->cmd) {
1508 case WFC_DISABLE_INTERRUPTS:
1509 snd_printk ("interrupts disabled.\n");
1510 outb (0x80|0x20, dev->control_port);
1511 dev->interrupts_are_midi = 1;
1512 return 0;
1514 case WFC_ENABLE_INTERRUPTS:
1515 snd_printk ("interrupts enabled.\n");
1516 outb (0x80|0x40|0x20, dev->control_port);
1517 dev->interrupts_are_midi = 1;
1518 return 0;
1520 case WFC_INTERRUPT_STATUS:
1521 wc->rbuf[0] = dev->interrupts_are_midi;
1522 return 0;
1524 case WFC_ROMSAMPLES_RDONLY:
1525 dev->rom_samples_rdonly = wc->wbuf[0];
1526 wc->status = 0;
1527 return 0;
1529 case WFC_IDENTIFY_SLOT_TYPE:
1530 i = wc->wbuf[0] | (wc->wbuf[1] << 7);
1531 if (i <0 || i >= WF_MAX_SAMPLE) {
1532 snd_printk ("invalid slot ID %d\n",
1534 wc->status = EINVAL;
1535 return -EINVAL;
1537 wc->rbuf[0] = dev->sample_status[i];
1538 wc->status = 0;
1539 return 0;
1541 case WFC_DEBUG_DRIVER:
1542 dev->debug = wc->wbuf[0];
1543 snd_printk ("debug = 0x%x\n", dev->debug);
1544 return 0;
1546 case WFC_UPLOAD_PATCH:
1547 munge_int32 (*((u32 *) wc->wbuf), patchnumbuf, 2);
1548 memcpy (wc->wbuf, patchnumbuf, 2);
1549 break;
1551 case WFC_UPLOAD_MULTISAMPLE:
1552 /* multisamples have to be handled differently, and
1553 cannot be dealt with properly by snd_wavefront_cmd() alone.
1555 wc->status = wavefront_fetch_multisample
1556 (dev, (wavefront_patch_info *) wc->rbuf);
1557 return 0;
1559 case WFC_UPLOAD_SAMPLE_ALIAS:
1560 snd_printk ("support for sample alias upload "
1561 "being considered.\n");
1562 wc->status = EINVAL;
1563 return -EINVAL;
1566 wc->status = snd_wavefront_cmd (dev, wc->cmd, wc->rbuf, wc->wbuf);
1568 /* Post-handling of certain commands.
1570 In particular, if the command was an upload, demunge the data
1571 so that the user-level doesn't have to think about it.
1574 if (wc->status == 0) {
1575 switch (wc->cmd) {
1576 /* intercept any freemem requests so that we know
1577 we are always current with the user-level view
1578 of things.
1581 case WFC_REPORT_FREE_MEMORY:
1582 dev->freemem = demunge_int32 (wc->rbuf, 4);
1583 break;
1585 case WFC_UPLOAD_PATCH:
1586 demunge_buf (wc->rbuf, wc->rbuf, WF_PATCH_BYTES);
1587 break;
1589 case WFC_UPLOAD_PROGRAM:
1590 demunge_buf (wc->rbuf, wc->rbuf, WF_PROGRAM_BYTES);
1591 break;
1593 case WFC_UPLOAD_EDRUM_PROGRAM:
1594 demunge_buf (wc->rbuf, wc->rbuf, WF_DRUM_BYTES - 1);
1595 break;
1597 case WFC_UPLOAD_SAMPLE_HEADER:
1598 process_sample_hdr (wc->rbuf);
1599 break;
1601 case WFC_UPLOAD_SAMPLE_ALIAS:
1602 snd_printk ("support for "
1603 "sample aliases still "
1604 "being considered.\n");
1605 break;
1607 case WFC_VMIDI_OFF:
1608 snd_wavefront_midi_disable_virtual (acard);
1609 break;
1611 case WFC_VMIDI_ON:
1612 snd_wavefront_midi_enable_virtual (acard);
1613 break;
1617 return 0;
1620 int
1621 snd_wavefront_synth_open (struct snd_hwdep *hw, struct file *file)
1624 if (!try_module_get(hw->card->module))
1625 return -EFAULT;
1626 file->private_data = hw;
1627 return 0;
1630 int
1631 snd_wavefront_synth_release (struct snd_hwdep *hw, struct file *file)
1634 module_put(hw->card->module);
1635 return 0;
1639 snd_wavefront_synth_ioctl (struct snd_hwdep *hw, struct file *file,
1640 unsigned int cmd, unsigned long arg)
1643 struct snd_card *card;
1644 snd_wavefront_t *dev;
1645 snd_wavefront_card_t *acard;
1646 wavefront_control *wc;
1647 void __user *argp = (void __user *)arg;
1648 int err;
1650 card = (struct snd_card *) hw->card;
1652 snd_assert(card != NULL, return -ENODEV);
1654 snd_assert(card->private_data != NULL, return -ENODEV);
1656 acard = card->private_data;
1657 dev = &acard->wavefront;
1659 switch (cmd) {
1660 case WFCTL_LOAD_SPP:
1661 if (wavefront_load_patch (dev, argp) != 0) {
1662 return -EIO;
1664 break;
1666 case WFCTL_WFCMD:
1667 wc = kmalloc(sizeof(*wc), GFP_KERNEL);
1668 if (! wc)
1669 return -ENOMEM;
1670 if (copy_from_user (wc, argp, sizeof (*wc)))
1671 err = -EFAULT;
1672 else if (wavefront_synth_control (acard, wc) < 0)
1673 err = -EIO;
1674 else if (copy_to_user (argp, wc, sizeof (*wc)))
1675 err = -EFAULT;
1676 else
1677 err = 0;
1678 kfree(wc);
1679 return err;
1681 default:
1682 return -EINVAL;
1685 return 0;
1689 /***********************************************************************/
1690 /* WaveFront: interface for card-level wavefront module */
1691 /***********************************************************************/
1693 void
1694 snd_wavefront_internal_interrupt (snd_wavefront_card_t *card)
1696 snd_wavefront_t *dev = &card->wavefront;
1699 Some comments on interrupts. I attempted a version of this
1700 driver that used interrupts throughout the code instead of
1701 doing busy and/or sleep-waiting. Alas, it appears that once
1702 the Motorola firmware is downloaded, the card *never*
1703 generates an RX interrupt. These are successfully generated
1704 during firmware loading, and after that wavefront_status()
1705 reports that an interrupt is pending on the card from time
1706 to time, but it never seems to be delivered to this
1707 driver. Note also that wavefront_status() continues to
1708 report that RX interrupts are enabled, suggesting that I
1709 didn't goof up and disable them by mistake.
1711 Thus, I stepped back to a prior version of
1712 wavefront_wait(), the only place where this really
1713 matters. Its sad, but I've looked through the code to check
1714 on things, and I really feel certain that the Motorola
1715 firmware prevents RX-ready interrupts.
1718 if ((wavefront_status(dev) & (STAT_INTR_READ|STAT_INTR_WRITE)) == 0) {
1719 return;
1722 spin_lock(&dev->irq_lock);
1723 dev->irq_ok = 1;
1724 dev->irq_cnt++;
1725 spin_unlock(&dev->irq_lock);
1726 wake_up(&dev->interrupt_sleeper);
1729 /* STATUS REGISTER
1731 0 Host Rx Interrupt Enable (1=Enabled)
1732 1 Host Rx Register Full (1=Full)
1733 2 Host Rx Interrupt Pending (1=Interrupt)
1734 3 Unused
1735 4 Host Tx Interrupt (1=Enabled)
1736 5 Host Tx Register empty (1=Empty)
1737 6 Host Tx Interrupt Pending (1=Interrupt)
1738 7 Unused
1741 static int __devinit
1742 snd_wavefront_interrupt_bits (int irq)
1745 int bits;
1747 switch (irq) {
1748 case 9:
1749 bits = 0x00;
1750 break;
1751 case 5:
1752 bits = 0x08;
1753 break;
1754 case 12:
1755 bits = 0x10;
1756 break;
1757 case 15:
1758 bits = 0x18;
1759 break;
1761 default:
1762 snd_printk ("invalid IRQ %d\n", irq);
1763 bits = -1;
1766 return bits;
1769 static void __devinit
1770 wavefront_should_cause_interrupt (snd_wavefront_t *dev,
1771 int val, int port, int timeout)
1774 wait_queue_t wait;
1776 init_waitqueue_entry(&wait, current);
1777 spin_lock_irq(&dev->irq_lock);
1778 add_wait_queue(&dev->interrupt_sleeper, &wait);
1779 dev->irq_ok = 0;
1780 outb (val,port);
1781 spin_unlock_irq(&dev->irq_lock);
1782 while (1) {
1783 if ((timeout = schedule_timeout_interruptible(timeout)) == 0)
1784 return;
1785 if (dev->irq_ok)
1786 return;
1790 static int __devinit
1791 wavefront_reset_to_cleanliness (snd_wavefront_t *dev)
1794 int bits;
1795 int hwv[2];
1797 /* IRQ already checked */
1799 bits = snd_wavefront_interrupt_bits (dev->irq);
1801 /* try reset of port */
1803 outb (0x0, dev->control_port);
1805 /* At this point, the board is in reset, and the H/W initialization
1806 register is accessed at the same address as the data port.
1808 Bit 7 - Enable IRQ Driver
1809 0 - Tri-state the Wave-Board drivers for the PC Bus IRQs
1810 1 - Enable IRQ selected by bits 5:3 to be driven onto the PC Bus.
1812 Bit 6 - MIDI Interface Select
1814 0 - Use the MIDI Input from the 26-pin WaveBlaster
1815 compatible header as the serial MIDI source
1816 1 - Use the MIDI Input from the 9-pin D connector as the
1817 serial MIDI source.
1819 Bits 5:3 - IRQ Selection
1820 0 0 0 - IRQ 2/9
1821 0 0 1 - IRQ 5
1822 0 1 0 - IRQ 12
1823 0 1 1 - IRQ 15
1824 1 0 0 - Reserved
1825 1 0 1 - Reserved
1826 1 1 0 - Reserved
1827 1 1 1 - Reserved
1829 Bits 2:1 - Reserved
1830 Bit 0 - Disable Boot ROM
1831 0 - memory accesses to 03FC30-03FFFFH utilize the internal Boot ROM
1832 1 - memory accesses to 03FC30-03FFFFH are directed to external
1833 storage.
1837 /* configure hardware: IRQ, enable interrupts,
1838 plus external 9-pin MIDI interface selected
1841 outb (0x80 | 0x40 | bits, dev->data_port);
1843 /* CONTROL REGISTER
1845 0 Host Rx Interrupt Enable (1=Enabled) 0x1
1846 1 Unused 0x2
1847 2 Unused 0x4
1848 3 Unused 0x8
1849 4 Host Tx Interrupt Enable 0x10
1850 5 Mute (0=Mute; 1=Play) 0x20
1851 6 Master Interrupt Enable (1=Enabled) 0x40
1852 7 Master Reset (0=Reset; 1=Run) 0x80
1854 Take us out of reset, mute output, master + TX + RX interrupts on.
1856 We'll get an interrupt presumably to tell us that the TX
1857 register is clear.
1860 wavefront_should_cause_interrupt(dev, 0x80|0x40|0x10|0x1,
1861 dev->control_port,
1862 (reset_time*HZ)/100);
1864 /* Note: data port is now the data port, not the h/w initialization
1865 port.
1868 if (!dev->irq_ok) {
1869 snd_printk ("intr not received after h/w un-reset.\n");
1870 goto gone_bad;
1873 /* Note: data port is now the data port, not the h/w initialization
1874 port.
1876 At this point, only "HW VERSION" or "DOWNLOAD OS" commands
1877 will work. So, issue one of them, and wait for TX
1878 interrupt. This can take a *long* time after a cold boot,
1879 while the ISC ROM does its RAM test. The SDK says up to 4
1880 seconds - with 12MB of RAM on a Tropez+, it takes a lot
1881 longer than that (~16secs). Note that the card understands
1882 the difference between a warm and a cold boot, so
1883 subsequent ISC2115 reboots (say, caused by module
1884 reloading) will get through this much faster.
1886 XXX Interesting question: why is no RX interrupt received first ?
1889 wavefront_should_cause_interrupt(dev, WFC_HARDWARE_VERSION,
1890 dev->data_port, ramcheck_time*HZ);
1892 if (!dev->irq_ok) {
1893 snd_printk ("post-RAM-check interrupt not received.\n");
1894 goto gone_bad;
1897 if (!wavefront_wait (dev, STAT_CAN_READ)) {
1898 snd_printk ("no response to HW version cmd.\n");
1899 goto gone_bad;
1902 if ((hwv[0] = wavefront_read (dev)) == -1) {
1903 snd_printk ("board not responding correctly.\n");
1904 goto gone_bad;
1907 if (hwv[0] == 0xFF) { /* NAK */
1909 /* Board's RAM test failed. Try to read error code,
1910 and tell us about it either way.
1913 if ((hwv[0] = wavefront_read (dev)) == -1) {
1914 snd_printk ("on-board RAM test failed "
1915 "(bad error code).\n");
1916 } else {
1917 snd_printk ("on-board RAM test failed "
1918 "(error code: 0x%x).\n",
1919 hwv[0]);
1921 goto gone_bad;
1924 /* We're OK, just get the next byte of the HW version response */
1926 if ((hwv[1] = wavefront_read (dev)) == -1) {
1927 snd_printk ("incorrect h/w response.\n");
1928 goto gone_bad;
1931 snd_printk ("hardware version %d.%d\n",
1932 hwv[0], hwv[1]);
1934 return 0;
1937 gone_bad:
1938 return (1);
1941 #include <linux/fs.h>
1942 #include <linux/mm.h>
1943 #include <linux/slab.h>
1944 #include <linux/unistd.h>
1945 #include <linux/syscalls.h>
1946 #include <asm/uaccess.h>
1949 static int __devinit
1950 wavefront_download_firmware (snd_wavefront_t *dev, char *path)
1953 unsigned char section[WF_SECTION_MAX];
1954 signed char section_length; /* yes, just a char; max value is WF_SECTION_MAX */
1955 int section_cnt_downloaded = 0;
1956 int fd;
1957 int c;
1958 int i;
1959 mm_segment_t fs;
1961 /* This tries to be a bit cleverer than the stuff Alan Cox did for
1962 the generic sound firmware, in that it actually knows
1963 something about the structure of the Motorola firmware. In
1964 particular, it uses a version that has been stripped of the
1965 20K of useless header information, and had section lengths
1966 added, making it possible to load the entire OS without any
1967 [kv]malloc() activity, since the longest entity we ever read is
1968 42 bytes (well, WF_SECTION_MAX) long.
1971 fs = get_fs();
1972 set_fs (get_ds());
1974 if ((fd = sys_open ((char __user *) path, 0, 0)) < 0) {
1975 snd_printk ("Unable to load \"%s\".\n",
1976 path);
1977 return 1;
1980 while (1) {
1981 int x;
1983 if ((x = sys_read (fd, (char __user *) &section_length, sizeof (section_length))) !=
1984 sizeof (section_length)) {
1985 snd_printk ("firmware read error.\n");
1986 goto failure;
1989 if (section_length == 0) {
1990 break;
1993 if (section_length < 0 || section_length > WF_SECTION_MAX) {
1994 snd_printk ("invalid firmware section length %d\n",
1995 section_length);
1996 goto failure;
1999 if (sys_read (fd, (char __user *) section, section_length) != section_length) {
2000 snd_printk ("firmware section "
2001 "read error.\n");
2002 goto failure;
2005 /* Send command */
2007 if (wavefront_write (dev, WFC_DOWNLOAD_OS)) {
2008 goto failure;
2011 for (i = 0; i < section_length; i++) {
2012 if (wavefront_write (dev, section[i])) {
2013 goto failure;
2017 /* get ACK */
2019 if (wavefront_wait (dev, STAT_CAN_READ)) {
2021 if ((c = inb (dev->data_port)) != WF_ACK) {
2023 snd_printk ("download "
2024 "of section #%d not "
2025 "acknowledged, ack = 0x%x\n",
2026 section_cnt_downloaded + 1, c);
2027 goto failure;
2031 } else {
2032 snd_printk ("time out for firmware ACK.\n");
2033 goto failure;
2038 sys_close (fd);
2039 set_fs (fs);
2040 return 0;
2042 failure:
2043 sys_close (fd);
2044 set_fs (fs);
2045 snd_printk ("firmware download failed!!!\n");
2046 return 1;
2050 static int __devinit
2051 wavefront_do_reset (snd_wavefront_t *dev)
2054 char voices[1];
2056 if (wavefront_reset_to_cleanliness (dev)) {
2057 snd_printk ("hw reset failed.\n");
2058 goto gone_bad;
2061 if (dev->israw) {
2062 if (wavefront_download_firmware (dev, ospath)) {
2063 goto gone_bad;
2066 dev->israw = 0;
2068 /* Wait for the OS to get running. The protocol for
2069 this is non-obvious, and was determined by
2070 using port-IO tracing in DOSemu and some
2071 experimentation here.
2073 Rather than using timed waits, use interrupts creatively.
2076 wavefront_should_cause_interrupt (dev, WFC_NOOP,
2077 dev->data_port,
2078 (osrun_time*HZ));
2080 if (!dev->irq_ok) {
2081 snd_printk ("no post-OS interrupt.\n");
2082 goto gone_bad;
2085 /* Now, do it again ! */
2087 wavefront_should_cause_interrupt (dev, WFC_NOOP,
2088 dev->data_port, (10*HZ));
2090 if (!dev->irq_ok) {
2091 snd_printk ("no post-OS interrupt(2).\n");
2092 goto gone_bad;
2095 /* OK, no (RX/TX) interrupts any more, but leave mute
2096 in effect.
2099 outb (0x80|0x40, dev->control_port);
2102 /* SETUPSND.EXE asks for sample memory config here, but since i
2103 have no idea how to interpret the result, we'll forget
2104 about it.
2107 if ((dev->freemem = wavefront_freemem (dev)) < 0) {
2108 goto gone_bad;
2111 snd_printk ("available DRAM %dk\n", dev->freemem / 1024);
2113 if (wavefront_write (dev, 0xf0) ||
2114 wavefront_write (dev, 1) ||
2115 (wavefront_read (dev) < 0)) {
2116 dev->debug = 0;
2117 snd_printk ("MPU emulation mode not set.\n");
2118 goto gone_bad;
2121 voices[0] = 32;
2123 if (snd_wavefront_cmd (dev, WFC_SET_NVOICES, NULL, voices)) {
2124 snd_printk ("cannot set number of voices to 32.\n");
2125 goto gone_bad;
2129 return 0;
2131 gone_bad:
2132 /* reset that sucker so that it doesn't bother us. */
2134 outb (0x0, dev->control_port);
2135 dev->interrupts_are_midi = 0;
2136 return 1;
2139 int __devinit
2140 snd_wavefront_start (snd_wavefront_t *dev)
2143 int samples_are_from_rom;
2145 /* IMPORTANT: assumes that snd_wavefront_detect() and/or
2146 wavefront_reset_to_cleanliness() has already been called
2149 if (dev->israw) {
2150 samples_are_from_rom = 1;
2151 } else {
2152 /* XXX is this always true ? */
2153 samples_are_from_rom = 0;
2156 if (dev->israw || fx_raw) {
2157 if (wavefront_do_reset (dev)) {
2158 return -1;
2161 /* Check for FX device, present only on Tropez+ */
2163 dev->has_fx = (snd_wavefront_fx_detect (dev) == 0);
2165 if (dev->has_fx && fx_raw) {
2166 snd_wavefront_fx_start (dev);
2169 wavefront_get_sample_status (dev, samples_are_from_rom);
2170 wavefront_get_program_status (dev);
2171 wavefront_get_patch_status (dev);
2173 /* Start normal operation: unreset, master interrupt enabled, no mute
2176 outb (0x80|0x40|0x20, dev->control_port);
2178 return (0);
2181 int __devinit
2182 snd_wavefront_detect (snd_wavefront_card_t *card)
2185 unsigned char rbuf[4], wbuf[4];
2186 snd_wavefront_t *dev = &card->wavefront;
2188 /* returns zero if a WaveFront card is successfully detected.
2189 negative otherwise.
2192 dev->israw = 0;
2193 dev->has_fx = 0;
2194 dev->debug = debug_default;
2195 dev->interrupts_are_midi = 0;
2196 dev->irq_cnt = 0;
2197 dev->rom_samples_rdonly = 1;
2199 if (snd_wavefront_cmd (dev, WFC_FIRMWARE_VERSION, rbuf, wbuf) == 0) {
2201 dev->fw_version[0] = rbuf[0];
2202 dev->fw_version[1] = rbuf[1];
2204 snd_printk ("firmware %d.%d already loaded.\n",
2205 rbuf[0], rbuf[1]);
2207 /* check that a command actually works */
2209 if (snd_wavefront_cmd (dev, WFC_HARDWARE_VERSION,
2210 rbuf, wbuf) == 0) {
2211 dev->hw_version[0] = rbuf[0];
2212 dev->hw_version[1] = rbuf[1];
2213 } else {
2214 snd_printk ("not raw, but no "
2215 "hardware version!\n");
2216 return -1;
2219 if (!wf_raw) {
2220 return 0;
2221 } else {
2222 snd_printk ("reloading firmware as you requested.\n");
2223 dev->israw = 1;
2226 } else {
2228 dev->israw = 1;
2229 snd_printk ("no response to firmware probe, assume raw.\n");
2233 return 0;