| blob | 7ac6e6705fd18d81fa0c21b09469b8d08a5a1814 |
1 /* DirectSound
2 *
3 * Copyright 1998 Marcus Meissner
4 * Copyright 1998 Rob Riggs
5 * Copyright 2000-2002 TransGaming Technologies, Inc.
6 * Copyright 2007 Peter Dons Tychsen
7 * Copyright 2007 Maarten Lankhorst
8 *
9 * This library is free software; you can redistribute it and/or
10 * modify it under the terms of the GNU Lesser General Public
11 * License as published by the Free Software Foundation; either
12 * version 2.1 of the License, or (at your option) any later version.
13 *
14 * This library is distributed in the hope that it will be useful,
15 * but WITHOUT ANY WARRANTY; without even the implied warranty of
16 * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
17 * Lesser General Public License for more details.
18 *
19 * You should have received a copy of the GNU Lesser General Public
20 * License along with this library; if not, write to the Free Software
21 * Foundation, Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301, USA
22 */
24 #include <assert.h>
25 #include <stdarg.h>
28 #define NONAMELESSSTRUCT
29 #define NONAMELESSUNION
42 {
47 /* the AmpFactors are expressed in 16.16 fixed point */
49 /* FIXME: dwPan{Left|Right}AmpFactor */
51 /* FIXME: use calculated vol and pan ampfactors */
58 }
61 {
68 else
72 else
75 {
78 }
79 else
80 {
83 }
91 }
93 /** Convert a primary buffer position to a pointer position for device->mix_buffer
94 * device: DirectSoundDevice for which to calculate
95 * pos: Primary buffer position to converts
96 * Returns: Offset for mix_buffer
97 */
99 {
104 }
106 /* NOTE: Not all secpos have to always be mapped to a bufpos, other way around is always the case
107 * DWORD64 is used here because a single DWORD wouldn't be big enough to fit the freqAcc for big buffers
108 */
109 /** This function converts a 'native' sample pointer to a resampled pointer that fits for primary
110 * secmixpos is used to decide which freqAcc is needed
111 * overshot tells what the 'actual' secpos is now (optional)
112 */
113 DWORD DSOUND_secpos_to_bufpos(const IDirectSoundBufferImpl *dsb, DWORD secpos, DWORD secmixpos, DWORD* overshot)
114 {
125 {
131 }
133 }
135 /** Convert a resampled pointer that fits for primary to a 'native' sample pointer
136 * freqAccNext is used here rather than freqAcc: In case the app wants to fill up to
137 * the play position it won't overwrite it
138 */
140 {
142 DWORD64 framelen;
143 DWORD64 acc;
150 /* Because of differences between freqAcc and freqAccNext, this might happen */
154 }
156 /**
157 * Move freqAccNext to freqAcc, and find new values for buffer length and freqAccNext
158 */
160 {
165 }
167 /**
168 * Recalculate the size for temporary buffer, and new writelead
169 * Should be called when one of the following things occur:
170 * - Primary buffer format is changed
171 * - This buffer format (frequency) is changed
172 *
173 * After this, DSOUND_MixToTemporary(dsb, 0, dsb->buflen) should
174 * be called to refill the temporary buffer with data.
175 */
177 {
183 /* calculate the 10ms write lead */
194 dsb->convert = convertbpp[dsb->pwfx->wBitsPerSample/8 - 1][dsb->device->pwfx->wBitsPerSample/8 - 1];
199 {
202 else
205 if ((dsb->max_buffer_len <= dsb->device->buflen || dsb->max_buffer_len < ds_snd_shadow_maxsize * 1024 * 1024) && ds_snd_shadow_maxsize >= 0)
208 FillMemory(dsb->tmp_buffer, dsb->tmp_buffer_len, dsb->device->pwfx->wBitsPerSample == 8 ? 128 : 0);
209 else
211 }
214 }
216 /**
217 * Check for application callback requests for when the play position
218 * reaches certain points.
219 *
220 * The offsets that will be triggered will be those between the recorded
221 * "last played" position for the buffer (i.e. dsb->playpos) and "len" bytes
222 * beyond that position.
223 */
225 {
227 DWORD offset;
228 LPDSBPOSITIONNOTIFY event;
241 /* DSBPN_OFFSETSTOP has to be the last element. So this is */
242 /* OK. [Inside DirectX, p274] */
243 /* */
244 /* This also means we can't sort the entries by offset, */
245 /* because DSBPN_OFFSETSTOP == -1 */
253 }
259 }
264 }
265 }
266 }
267 }
269 /**
270 * Copy a single frame from the given input buffer to the given output buffer.
271 * Translate 8 <-> 16 bits and mono <-> stereo
272 */
274 {
282 }
285 {
287 }
290 {
293 }
294 }
296 /**
297 * Calculate the distance between two buffer offsets, taking wraparound
298 * into account.
299 */
301 {
302 /* If these asserts fail, the problem is not here, but in the underlying code */
309 }
310 }
311 /**
312 * Mix at most the given amount of data into the allocated temporary buffer
313 * of the given secondary buffer, starting from the dsb's first currently
314 * unsampled frame (writepos), translating frequency (pitch), stereo/mono
315 * and bits-per-sample so that it is ideal for the primary buffer.
316 * Doesn't perform any mixing - this is a straight copy/convert operation.
317 *
318 * dsb = the secondary buffer
319 * writepos = Starting position of changed buffer
320 * len = number of bytes to resample from writepos
321 *
322 * NOTE: writepos + len <= buflen. When called by mixer, MixOne makes sure of this.
323 */
324 void DSOUND_MixToTemporary(const IDirectSoundBufferImpl *dsb, DWORD writepos, DWORD len, BOOL inmixer)
325 {
332 /* We resample only when needed */
333 if ((dsb->tmp_buffer && inmixer) || (!dsb->tmp_buffer && !inmixer) || dsb->resampleinmixer != inmixer)
346 {
350 else
353 }
354 else
359 /* Check for same sample rate */
371 }
373 }
375 /* Mix in different sample rates */
376 TRACE("(%p) Adjusting frequency: %d -> %d\n", dsb, dsb->freq, dsb->device->pwfx->nSamplesPerSec);
382 {
392 }
398 /* FIXME: Small problem here when we're overwriting buf_mixpos, it then STILL uses old freqAcc, not sure if it matters or not */
408 }
409 }
410 }
412 /** Apply volume to the given soundbuffer from (primary) position writepos and length len
413 * Returns: NULL if no volume needs to be applied
414 * or else a memory handle that holds 'len' volume adjusted buffer */
416 {
417 INT i;
437 {
440 }
443 {
446 }
449 {
450 /* If we just resampled in DSOUND_MixToTemporary, we shouldn't need to resize here */
455 else
457 }
465 else
470 /* 8-bit WAV is unsigned, but we need to operate */
471 /* on signed data for this to work properly */
475 }
480 /* 16-bit WAV is signed -- much better */
484 }
488 }
490 }
492 /**
493 * Mix (at most) the given number of bytes into the given position of the
494 * device buffer, from the secondary buffer "dsb" (starting at the current
495 * mix position for that buffer).
496 *
497 * Returns the number of bytes actually mixed into the device buffer. This
498 * will match fraglen unless the end of the secondary buffer is reached
499 * (and it is not looping).
500 *
501 * dsb = the secondary buffer to mix from
502 * writepos = position (offset) in device buffer to write at
503 * fraglen = number of bytes to mix
504 */
506 {
508 BYTE *ibuf = (dsb->tmp_buffer ? dsb->tmp_buffer : dsb->buffer->memory) + dsb->buf_mixpos, *volbuf;
511 TRACE("buf_mixpos=%d/%d sec_mixpos=%d/%d\n", dsb->buf_mixpos, dsb->tmp_buffer_len, dsb->sec_mixpos, dsb->buflen);
520 }
522 /* Resample buffer to temporary buffer specifically allocated for this purpose, if needed */
523 DSOUND_MixToTemporary(dsb, dsb->sec_mixpos, DSOUND_bufpos_to_secpos(dsb, dsb->buf_mixpos+len) - dsb->sec_mixpos, TRUE);
527 /* Apply volume if needed */
533 /* Now mix the temporary buffer into the devices main buffer */
536 else
537 {
541 }
554 }
556 }
560 /* check for notification positions */
564 }
566 /* increase mix position */
571 }
573 /**
574 * Mix some frames from the given secondary buffer "dsb" into the device
575 * primary buffer.
576 *
577 * dsb = the secondary buffer
578 * playpos = the current play position in the device buffer (primary buffer)
579 * writepos = the current safe-to-write position in the device buffer
580 * mixlen = the maximum number of bytes in the primary buffer to mix, from the
581 * current writepos.
582 *
583 * Returns: the number of bytes beyond the writepos that were mixed.
584 */
586 {
587 /* The buffer's primary_mixpos may be before or after the device
588 * buffer's mixpos, but both must be ahead of writepos. */
589 DWORD primary_done;
592 TRACE("writepos=%d, buf_mixpos=%d, primary_mixpos=%d, mixlen=%d\n", writepos, dsb->buf_mixpos, dsb->primary_mixpos, mixlen);
595 /* If leading in, only mix about 20 ms, and 'skip' mixing the rest, for more fluid pointer advancement */
597 {
599 {
602 }
603 }
606 /* calculate how much pre-buffering has already been done for this buffer */
609 /* sanity */
611 {
612 /* Should *NEVER* happen */
613 ERR("Fatal error. Under/Overflow? primary_done=%d, mixpos=%d/%d (%d/%d), primary_mixpos=%d, writepos=%d, mixlen=%d\n", primary_done,dsb->buf_mixpos,dsb->tmp_buffer_len,dsb->sec_mixpos, dsb->buflen, dsb->primary_mixpos, writepos, mixlen);
615 }
617 /* take into account already mixed data */
625 /* First try to mix to the end of the buffer if possible
626 * Theoretically it would allow for better optimization
627 */
629 {
636 {
640 }
641 }
644 /* re-calculate the primary done */
649 /* Report back the total prebuffered amount for this buffer */
651 }
653 /**
654 * For a DirectSoundDevice, go through all the currently playing buffers and
655 * mix them in to the device buffer.
656 *
657 * writepos = the current safe-to-write position in the primary buffer
658 * mixlen = the maximum amount to mix into the primary buffer
659 * (beyond the current writepos)
660 * mustlock = Do we have to fight for lock because we otherwise risk an underrun?
661 * recover = true if the sound device may have been reset and the write
662 * position in the device buffer changed
663 * all_stopped = reports back if all buffers have stopped
664 *
665 * Returns: the length beyond the writepos that was mixed to.
666 */
668 static DWORD DSOUND_MixToPrimary(const DirectSoundDevice *device, DWORD writepos, DWORD mixlen, BOOL mustlock, BOOL recover, BOOL *all_stopped)
669 {
675 /* unless we find a running buffer, all have stopped */
687 {
690 }
691 /* if buffer is stopping it is stopped now */
697 /* if recovering, reset the mix position */
700 }
702 /* if the buffer was starting, it must be playing now */
706 /* mix next buffer into the main buffer */
711 /* record the minimum length mixed from all buffers */
712 /* we only want to return the length which *all* buffers have mixed */
716 }
718 }
719 }
724 }
726 /**
727 * Add buffers to the emulated wave device system.
728 *
729 * device = The current dsound playback device
730 * force = If TRUE, the function will buffer up as many frags as possible,
731 * even though and will ignore the actual state of the primary buffer.
732 *
733 * Returns: None
734 */
737 {
741 /* calculate the current wave frag position */
744 /* calculate the current wave write position */
751 {
752 /* check remaining prebuffered frags */
761 }
762 else
763 /* buffer the maximum amount of frags */
766 /* limit to the queue we have left */
772 /* adjust queue */
775 /* get out of CS when calling the wave system */
777 /* **** */
779 /* queue up the new buffers */
783 wave_fragpos++;
785 }
787 /* **** */
791 }
793 /**
794 * Perform mixing for a Direct Sound device. That is, go through all the
795 * secondary buffers (the sound bites currently playing) and mix them in
796 * to the primary buffer (the device buffer).
797 */
799 {
802 /* **** */
807 DWORD playpos, writepos, writelead, maxq, frag, prebuff_max, prebuff_left, size1, size2, mixplaypos, mixplaypos2;
813 /* the sound of silence */
816 /* get the position in the primary buffer */
820 }
828 /* wipe out just-played sound data */
837 IDsDriverBuffer_Lock(device->hwbuf, &buf1, &size1, &buf2, &size2, device->playpos, size1+size2, 0);
840 FIXME("%d: (%d, %d)=>(%d, %d) There should be an additional buffer here!!\n", __LINE__, device->playpos, device->mixpos, playpos, writepos);
851 IDsDriverBuffer_Lock(device->hwbuf, &buf1, &size1, &buf2, &size2, device->playpos, size1+size2, 0);
854 {
857 }
860 }
863 /* calc maximum prebuff */
868 /* check how close we are to an underrun. It occurs when the writepos overtakes the mixpos */
872 /* find the maximum we can prebuffer from current write position */
878 /* check for underrun. underrun occurs when the write position passes the mix position */
879 if((prebuff_left > prebuff_max) || (device->state == STATE_STOPPED) || (device->state == STATE_STARTING)){
884 /* recover mixing for all buffers */
887 /* reset mix position to write position */
889 }
891 /* Do we risk an 'underrun' if we don't advance pointer? */
898 /* do the mixing */
902 {
904 device->normfunction(device->mix_buffer + DSOUND_bufpos_to_mixpos(device, writepos), device->buffer + writepos, todo);
906 }
907 else
908 device->normfunction(device->mix_buffer + DSOUND_bufpos_to_mixpos(device, writepos), device->buffer + writepos, frag);
910 /* update the mix position, taking wrap-around into account */
915 {
919 {
922 }
924 }
926 /* update prebuff left */
929 /* check if have a whole fragment */
932 /* update the wave queue if using wave system */
936 /* buffers are full. start playing if applicable */
941 }
943 /* we are playing now */
945 }
946 }
948 /* buffers are full. start stopping if applicable */
953 }
955 /* start stopping again. as soon as there is no more data, it will stop */
957 }
958 }
959 }
961 /* if device was stopping, its for sure stopped when all buffers have stopped */
966 /* stop the primary buffer now */
968 }
972 /* update the wave queue if using wave system */
975 else
976 /* Keep alsa happy, which needs GetPosition called once every 10 ms */
979 /* in the DSSCL_WRITEPRIMARY mode, the app is totally in charge... */
983 else
985 }
989 else
991 }
992 }
995 /* **** */
996 }
1000 {
1003 DWORD end_time;
1012 }
1023 }
1026 {
1033 /* check if packet completed from wave driver */
1036 /* **** */
1041 /* update playpos */
1045 /* sanity */
1048 }
1050 /* update queue */
1054 /* **** */
1055 }
1057 }