2 This file is part of PulseAudio.
4 Copyright 2004-2008 Lennart Poettering
5 Copyright 2006 Pierre Ossman <ossman@cendio.se> for Cendio AB
7 PulseAudio is free software; you can redistribute it and/or modify
8 it under the terms of the GNU Lesser General Public License as published
9 by the Free Software Foundation; either version 2.1 of the License,
10 or (at your option) any later version.
12 PulseAudio is distributed in the hope that it will be useful, but
13 WITHOUT ANY WARRANTY; without even the implied warranty of
14 MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
15 General Public License for more details.
17 You should have received a copy of the GNU Lesser General Public License
18 along with PulseAudio; if not, write to the Free Software
19 Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307
29 #include <asoundlib.h>
31 #ifdef HAVE_VALGRIND_MEMCHECK_H
32 #include <valgrind/memcheck.h>
35 #include <pulse/i18n.h>
36 #include <pulse/rtclock.h>
37 #include <pulse/timeval.h>
38 #include <pulse/util.h>
39 #include <pulse/xmalloc.h>
41 #include <pulsecore/core.h>
42 #include <pulsecore/module.h>
43 #include <pulsecore/memchunk.h>
44 #include <pulsecore/sink.h>
45 #include <pulsecore/modargs.h>
46 #include <pulsecore/core-rtclock.h>
47 #include <pulsecore/core-util.h>
48 #include <pulsecore/sample-util.h>
49 #include <pulsecore/log.h>
50 #include <pulsecore/macro.h>
51 #include <pulsecore/thread.h>
52 #include <pulsecore/core-error.h>
53 #include <pulsecore/thread-mq.h>
54 #include <pulsecore/rtpoll.h>
55 #include <pulsecore/time-smoother.h>
57 #include <modules/reserve-wrap.h>
59 #include "alsa-util.h"
60 #include "alsa-sink.h"
62 /* #define DEBUG_TIMING */
64 #define DEFAULT_DEVICE "default"
66 #define DEFAULT_TSCHED_BUFFER_USEC (2*PA_USEC_PER_SEC) /* 2s -- Overall buffer size */
67 #define DEFAULT_TSCHED_WATERMARK_USEC (20*PA_USEC_PER_MSEC) /* 20ms -- Fill up when only this much is left in the buffer */
69 #define TSCHED_WATERMARK_INC_STEP_USEC (10*PA_USEC_PER_MSEC) /* 10ms -- On underrun, increase watermark by this */
70 #define TSCHED_WATERMARK_DEC_STEP_USEC (5*PA_USEC_PER_MSEC) /* 5ms -- When everything's great, decrease watermark by this */
71 #define TSCHED_WATERMARK_VERIFY_AFTER_USEC (20*PA_USEC_PER_SEC) /* 20s -- How long after a drop out recheck if things are good now */
72 #define TSCHED_WATERMARK_INC_THRESHOLD_USEC (0*PA_USEC_PER_MSEC) /* 0ms -- If the buffer level ever below this theshold, increase the watermark */
73 #define TSCHED_WATERMARK_DEC_THRESHOLD_USEC (100*PA_USEC_PER_MSEC) /* 100ms -- If the buffer level didn't drop below this theshold in the verification time, decrease the watermark */
75 /* Note that TSCHED_WATERMARK_INC_THRESHOLD_USEC == 0 means tht we
76 * will increase the watermark only if we hit a real underrun. */
78 #define TSCHED_MIN_SLEEP_USEC (10*PA_USEC_PER_MSEC) /* 10ms -- Sleep at least 10ms on each iteration */
79 #define TSCHED_MIN_WAKEUP_USEC (4*PA_USEC_PER_MSEC) /* 4ms -- Wakeup at least this long before the buffer runs empty*/
81 #define SMOOTHER_MIN_INTERVAL (2*PA_USEC_PER_MSEC) /* 2ms -- min smoother update interval */
82 #define SMOOTHER_MAX_INTERVAL (200*PA_USEC_PER_MSEC) /* 200ms -- max smoother update inteval */
84 #define VOLUME_ACCURACY (PA_VOLUME_NORM/100) /* don't require volume adjustments to be perfectly correct. don't necessarily extend granularity in software unless the differences get greater than this level */
92 pa_thread_mq thread_mq
;
95 snd_pcm_t
*pcm_handle
;
97 pa_alsa_fdlist
*mixer_fdl
;
98 snd_mixer_t
*mixer_handle
;
99 pa_alsa_path_set
*mixer_path_set
;
100 pa_alsa_path
*mixer_path
;
102 pa_cvolume hardware_volume
;
114 watermark_inc_threshold
,
115 watermark_dec_threshold
;
117 pa_usec_t watermark_dec_not_before
;
119 pa_memchunk memchunk
;
121 char *device_name
; /* name of the PCM device */
122 char *control_device
; /* name of the control device */
124 pa_bool_t use_mmap
:1, use_tsched
:1;
126 pa_bool_t first
, after_rewind
;
128 pa_rtpoll_item
*alsa_rtpoll_item
;
130 snd_mixer_selem_channel_id_t mixer_map
[SND_MIXER_SCHN_LAST
];
132 pa_smoother
*smoother
;
133 uint64_t write_count
;
134 uint64_t since_start
;
135 pa_usec_t smoother_interval
;
136 pa_usec_t last_smoother_update
;
138 pa_reserve_wrapper
*reserve
;
139 pa_hook_slot
*reserve_slot
;
140 pa_reserve_monitor_wrapper
*monitor
;
141 pa_hook_slot
*monitor_slot
;
144 static void userdata_free(struct userdata
*u
);
146 static pa_hook_result_t
reserve_cb(pa_reserve_wrapper
*r
, void *forced
, struct userdata
*u
) {
150 if (pa_sink_suspend(u
->sink
, TRUE
, PA_SUSPEND_APPLICATION
) < 0)
151 return PA_HOOK_CANCEL
;
156 static void reserve_done(struct userdata
*u
) {
159 if (u
->reserve_slot
) {
160 pa_hook_slot_free(u
->reserve_slot
);
161 u
->reserve_slot
= NULL
;
165 pa_reserve_wrapper_unref(u
->reserve
);
170 static void reserve_update(struct userdata
*u
) {
171 const char *description
;
174 if (!u
->sink
|| !u
->reserve
)
177 if ((description
= pa_proplist_gets(u
->sink
->proplist
, PA_PROP_DEVICE_DESCRIPTION
)))
178 pa_reserve_wrapper_set_application_device_name(u
->reserve
, description
);
181 static int reserve_init(struct userdata
*u
, const char *dname
) {
190 if (pa_in_system_mode())
193 if (!(rname
= pa_alsa_get_reserve_name(dname
)))
196 /* We are resuming, try to lock the device */
197 u
->reserve
= pa_reserve_wrapper_get(u
->core
, rname
);
205 pa_assert(!u
->reserve_slot
);
206 u
->reserve_slot
= pa_hook_connect(pa_reserve_wrapper_hook(u
->reserve
), PA_HOOK_NORMAL
, (pa_hook_cb_t
) reserve_cb
, u
);
211 static pa_hook_result_t
monitor_cb(pa_reserve_monitor_wrapper
*w
, void* busy
, struct userdata
*u
) {
217 b
= PA_PTR_TO_UINT(busy
) && !u
->reserve
;
219 pa_sink_suspend(u
->sink
, b
, PA_SUSPEND_APPLICATION
);
223 static void monitor_done(struct userdata
*u
) {
226 if (u
->monitor_slot
) {
227 pa_hook_slot_free(u
->monitor_slot
);
228 u
->monitor_slot
= NULL
;
232 pa_reserve_monitor_wrapper_unref(u
->monitor
);
237 static int reserve_monitor_init(struct userdata
*u
, const char *dname
) {
243 if (pa_in_system_mode())
246 if (!(rname
= pa_alsa_get_reserve_name(dname
)))
249 u
->monitor
= pa_reserve_monitor_wrapper_get(u
->core
, rname
);
255 pa_assert(!u
->monitor_slot
);
256 u
->monitor_slot
= pa_hook_connect(pa_reserve_monitor_wrapper_hook(u
->monitor
), PA_HOOK_NORMAL
, (pa_hook_cb_t
) monitor_cb
, u
);
261 static void fix_min_sleep_wakeup(struct userdata
*u
) {
262 size_t max_use
, max_use_2
;
265 pa_assert(u
->use_tsched
);
267 max_use
= u
->hwbuf_size
- u
->hwbuf_unused
;
268 max_use_2
= pa_frame_align(max_use
/2, &u
->sink
->sample_spec
);
270 u
->min_sleep
= pa_usec_to_bytes(TSCHED_MIN_SLEEP_USEC
, &u
->sink
->sample_spec
);
271 u
->min_sleep
= PA_CLAMP(u
->min_sleep
, u
->frame_size
, max_use_2
);
273 u
->min_wakeup
= pa_usec_to_bytes(TSCHED_MIN_WAKEUP_USEC
, &u
->sink
->sample_spec
);
274 u
->min_wakeup
= PA_CLAMP(u
->min_wakeup
, u
->frame_size
, max_use_2
);
277 static void fix_tsched_watermark(struct userdata
*u
) {
280 pa_assert(u
->use_tsched
);
282 max_use
= u
->hwbuf_size
- u
->hwbuf_unused
;
284 if (u
->tsched_watermark
> max_use
- u
->min_sleep
)
285 u
->tsched_watermark
= max_use
- u
->min_sleep
;
287 if (u
->tsched_watermark
< u
->min_wakeup
)
288 u
->tsched_watermark
= u
->min_wakeup
;
291 static void increase_watermark(struct userdata
*u
) {
292 size_t old_watermark
;
293 pa_usec_t old_min_latency
, new_min_latency
;
296 pa_assert(u
->use_tsched
);
298 /* First, just try to increase the watermark */
299 old_watermark
= u
->tsched_watermark
;
300 u
->tsched_watermark
= PA_MIN(u
->tsched_watermark
* 2, u
->tsched_watermark
+ u
->watermark_inc_step
);
301 fix_tsched_watermark(u
);
303 if (old_watermark
!= u
->tsched_watermark
) {
304 pa_log_info("Increasing wakeup watermark to %0.2f ms",
305 (double) pa_bytes_to_usec(u
->tsched_watermark
, &u
->sink
->sample_spec
) / PA_USEC_PER_MSEC
);
309 /* Hmm, we cannot increase the watermark any further, hence let's raise the latency */
310 old_min_latency
= u
->sink
->thread_info
.min_latency
;
311 new_min_latency
= PA_MIN(old_min_latency
* 2, old_min_latency
+ TSCHED_WATERMARK_INC_STEP_USEC
);
312 new_min_latency
= PA_MIN(new_min_latency
, u
->sink
->thread_info
.max_latency
);
314 if (old_min_latency
!= new_min_latency
) {
315 pa_log_info("Increasing minimal latency to %0.2f ms",
316 (double) new_min_latency
/ PA_USEC_PER_MSEC
);
318 pa_sink_set_latency_range_within_thread(u
->sink
, new_min_latency
, u
->sink
->thread_info
.max_latency
);
321 /* When we reach this we're officialy fucked! */
324 static void decrease_watermark(struct userdata
*u
) {
325 size_t old_watermark
;
329 pa_assert(u
->use_tsched
);
331 now
= pa_rtclock_now();
333 if (u
->watermark_dec_not_before
<= 0)
336 if (u
->watermark_dec_not_before
> now
)
339 old_watermark
= u
->tsched_watermark
;
341 if (u
->tsched_watermark
< u
->watermark_dec_step
)
342 u
->tsched_watermark
= u
->tsched_watermark
/ 2;
344 u
->tsched_watermark
= PA_MAX(u
->tsched_watermark
/ 2, u
->tsched_watermark
- u
->watermark_dec_step
);
346 fix_tsched_watermark(u
);
348 if (old_watermark
!= u
->tsched_watermark
)
349 pa_log_info("Decreasing wakeup watermark to %0.2f ms",
350 (double) pa_bytes_to_usec(u
->tsched_watermark
, &u
->sink
->sample_spec
) / PA_USEC_PER_MSEC
);
352 /* We don't change the latency range*/
355 u
->watermark_dec_not_before
= now
+ TSCHED_WATERMARK_VERIFY_AFTER_USEC
;
358 static void hw_sleep_time(struct userdata
*u
, pa_usec_t
*sleep_usec
, pa_usec_t
*process_usec
) {
361 pa_assert(sleep_usec
);
362 pa_assert(process_usec
);
365 pa_assert(u
->use_tsched
);
367 usec
= pa_sink_get_requested_latency_within_thread(u
->sink
);
369 if (usec
== (pa_usec_t
) -1)
370 usec
= pa_bytes_to_usec(u
->hwbuf_size
, &u
->sink
->sample_spec
);
372 wm
= pa_bytes_to_usec(u
->tsched_watermark
, &u
->sink
->sample_spec
);
377 *sleep_usec
= usec
- wm
;
381 pa_log_debug("Buffer time: %lu ms; Sleep time: %lu ms; Process time: %lu ms",
382 (unsigned long) (usec
/ PA_USEC_PER_MSEC
),
383 (unsigned long) (*sleep_usec
/ PA_USEC_PER_MSEC
),
384 (unsigned long) (*process_usec
/ PA_USEC_PER_MSEC
));
388 static int try_recover(struct userdata
*u
, const char *call
, int err
) {
393 pa_log_debug("%s: %s", call
, pa_alsa_strerror(err
));
395 pa_assert(err
!= -EAGAIN
);
398 pa_log_debug("%s: Buffer underrun!", call
);
400 if (err
== -ESTRPIPE
)
401 pa_log_debug("%s: System suspended!", call
);
403 if ((err
= snd_pcm_recover(u
->pcm_handle
, err
, 1)) < 0) {
404 pa_log("%s: %s", call
, pa_alsa_strerror(err
));
413 static size_t check_left_to_play(struct userdata
*u
, size_t n_bytes
, pa_bool_t on_timeout
) {
415 pa_bool_t underrun
= FALSE
;
417 /* We use <= instead of < for this check here because an underrun
418 * only happens after the last sample was processed, not already when
419 * it is removed from the buffer. This is particularly important
420 * when block transfer is used. */
422 if (n_bytes
<= u
->hwbuf_size
)
423 left_to_play
= u
->hwbuf_size
- n_bytes
;
426 /* We got a dropout. What a mess! */
434 if (!u
->first
&& !u
->after_rewind
)
435 if (pa_log_ratelimit())
436 pa_log_info("Underrun!");
440 pa_log_debug("%0.2f ms left to play; inc threshold = %0.2f ms; dec threshold = %0.2f ms",
441 (double) pa_bytes_to_usec(left_to_play
, &u
->sink
->sample_spec
) / PA_USEC_PER_MSEC
,
442 (double) pa_bytes_to_usec(u
->watermark_inc_threshold
, &u
->sink
->sample_spec
) / PA_USEC_PER_MSEC
,
443 (double) pa_bytes_to_usec(u
->watermark_dec_threshold
, &u
->sink
->sample_spec
) / PA_USEC_PER_MSEC
);
447 pa_bool_t reset_not_before
= TRUE
;
449 if (!u
->first
&& !u
->after_rewind
) {
450 if (underrun
|| left_to_play
< u
->watermark_inc_threshold
)
451 increase_watermark(u
);
452 else if (left_to_play
> u
->watermark_dec_threshold
) {
453 reset_not_before
= FALSE
;
455 /* We decrease the watermark only if have actually
456 * been woken up by a timeout. If something else woke
457 * us up it's too easy to fulfill the deadlines... */
460 decrease_watermark(u
);
464 if (reset_not_before
)
465 u
->watermark_dec_not_before
= 0;
471 static int mmap_write(struct userdata
*u
, pa_usec_t
*sleep_usec
, pa_bool_t polled
, pa_bool_t on_timeout
) {
472 pa_bool_t work_done
= TRUE
;
473 pa_usec_t max_sleep_usec
= 0, process_usec
= 0;
478 pa_sink_assert_ref(u
->sink
);
481 hw_sleep_time(u
, &max_sleep_usec
, &process_usec
);
487 pa_bool_t after_avail
= TRUE
;
489 /* First we determine how many samples are missing to fill the
490 * buffer up to 100% */
492 if (PA_UNLIKELY((n
= pa_alsa_safe_avail(u
->pcm_handle
, u
->hwbuf_size
, &u
->sink
->sample_spec
)) < 0)) {
494 if ((r
= try_recover(u
, "snd_pcm_avail", (int) n
)) == 0)
500 n_bytes
= (size_t) n
* u
->frame_size
;
503 pa_log_debug("avail: %lu", (unsigned long) n_bytes
);
506 left_to_play
= check_left_to_play(u
, n_bytes
, on_timeout
);
511 /* We won't fill up the playback buffer before at least
512 * half the sleep time is over because otherwise we might
513 * ask for more data from the clients then they expect. We
514 * need to guarantee that clients only have to keep around
515 * a single hw buffer length. */
518 pa_bytes_to_usec(left_to_play
, &u
->sink
->sample_spec
) > process_usec
+max_sleep_usec
/2) {
520 pa_log_debug("Not filling up, because too early.");
525 if (PA_UNLIKELY(n_bytes
<= u
->hwbuf_unused
)) {
529 char *dn
= pa_alsa_get_driver_name_by_pcm(u
->pcm_handle
);
530 pa_log(_("ALSA woke us up to write new data to the device, but there was actually nothing to write!\n"
531 "Most likely this is a bug in the ALSA driver '%s'. Please report this issue to the ALSA developers.\n"
532 "We were woken up with POLLOUT set -- however a subsequent snd_pcm_avail() returned 0 or another value < min_avail."),
538 pa_log_debug("Not filling up, because not necessary.");
546 pa_log_debug("Not filling up, because already too many iterations.");
552 n_bytes
-= u
->hwbuf_unused
;
556 pa_log_debug("Filling up");
563 const snd_pcm_channel_area_t
*areas
;
564 snd_pcm_uframes_t offset
, frames
;
565 snd_pcm_sframes_t sframes
;
567 frames
= (snd_pcm_uframes_t
) (n_bytes
/ u
->frame_size
);
568 /* pa_log_debug("%lu frames to write", (unsigned long) frames); */
570 if (PA_UNLIKELY((err
= pa_alsa_safe_mmap_begin(u
->pcm_handle
, &areas
, &offset
, &frames
, u
->hwbuf_size
, &u
->sink
->sample_spec
)) < 0)) {
572 if (!after_avail
&& err
== -EAGAIN
)
575 if ((r
= try_recover(u
, "snd_pcm_mmap_begin", err
)) == 0)
581 /* Make sure that if these memblocks need to be copied they will fit into one slot */
582 if (frames
> pa_mempool_block_size_max(u
->sink
->core
->mempool
)/u
->frame_size
)
583 frames
= pa_mempool_block_size_max(u
->sink
->core
->mempool
)/u
->frame_size
;
585 if (!after_avail
&& frames
== 0)
588 pa_assert(frames
> 0);
591 /* Check these are multiples of 8 bit */
592 pa_assert((areas
[0].first
& 7) == 0);
593 pa_assert((areas
[0].step
& 7)== 0);
595 /* We assume a single interleaved memory buffer */
596 pa_assert((areas
[0].first
>> 3) == 0);
597 pa_assert((areas
[0].step
>> 3) == u
->frame_size
);
599 p
= (uint8_t*) areas
[0].addr
+ (offset
* u
->frame_size
);
601 chunk
.memblock
= pa_memblock_new_fixed(u
->core
->mempool
, p
, frames
* u
->frame_size
, TRUE
);
602 chunk
.length
= pa_memblock_get_length(chunk
.memblock
);
605 pa_sink_render_into_full(u
->sink
, &chunk
);
606 pa_memblock_unref_fixed(chunk
.memblock
);
608 if (PA_UNLIKELY((sframes
= snd_pcm_mmap_commit(u
->pcm_handle
, offset
, frames
)) < 0)) {
610 if ((r
= try_recover(u
, "snd_pcm_mmap_commit", (int) sframes
)) == 0)
618 u
->write_count
+= frames
* u
->frame_size
;
619 u
->since_start
+= frames
* u
->frame_size
;
622 pa_log_debug("Wrote %lu bytes (of possible %lu bytes)", (unsigned long) (frames
* u
->frame_size
), (unsigned long) n_bytes
);
625 if ((size_t) frames
* u
->frame_size
>= n_bytes
)
628 n_bytes
-= (size_t) frames
* u
->frame_size
;
632 *sleep_usec
= pa_bytes_to_usec(left_to_play
, &u
->sink
->sample_spec
);
634 if (*sleep_usec
> process_usec
)
635 *sleep_usec
-= process_usec
;
639 return work_done
? 1 : 0;
642 static int unix_write(struct userdata
*u
, pa_usec_t
*sleep_usec
, pa_bool_t polled
, pa_bool_t on_timeout
) {
643 pa_bool_t work_done
= FALSE
;
644 pa_usec_t max_sleep_usec
= 0, process_usec
= 0;
649 pa_sink_assert_ref(u
->sink
);
652 hw_sleep_time(u
, &max_sleep_usec
, &process_usec
);
658 pa_bool_t after_avail
= TRUE
;
660 if (PA_UNLIKELY((n
= pa_alsa_safe_avail(u
->pcm_handle
, u
->hwbuf_size
, &u
->sink
->sample_spec
)) < 0)) {
662 if ((r
= try_recover(u
, "snd_pcm_avail", (int) n
)) == 0)
668 n_bytes
= (size_t) n
* u
->frame_size
;
669 left_to_play
= check_left_to_play(u
, n_bytes
, on_timeout
);
674 /* We won't fill up the playback buffer before at least
675 * half the sleep time is over because otherwise we might
676 * ask for more data from the clients then they expect. We
677 * need to guarantee that clients only have to keep around
678 * a single hw buffer length. */
681 pa_bytes_to_usec(left_to_play
, &u
->sink
->sample_spec
) > process_usec
+max_sleep_usec
/2)
684 if (PA_UNLIKELY(n_bytes
<= u
->hwbuf_unused
)) {
688 char *dn
= pa_alsa_get_driver_name_by_pcm(u
->pcm_handle
);
689 pa_log(_("ALSA woke us up to write new data to the device, but there was actually nothing to write!\n"
690 "Most likely this is a bug in the ALSA driver '%s'. Please report this issue to the ALSA developers.\n"
691 "We were woken up with POLLOUT set -- however a subsequent snd_pcm_avail() returned 0 or another value < min_avail."),
701 pa_log_debug("Not filling up, because already too many iterations.");
707 n_bytes
-= u
->hwbuf_unused
;
711 snd_pcm_sframes_t frames
;
714 /* pa_log_debug("%lu frames to write", (unsigned long) frames); */
716 if (u
->memchunk
.length
<= 0)
717 pa_sink_render(u
->sink
, n_bytes
, &u
->memchunk
);
719 pa_assert(u
->memchunk
.length
> 0);
721 frames
= (snd_pcm_sframes_t
) (u
->memchunk
.length
/ u
->frame_size
);
723 if (frames
> (snd_pcm_sframes_t
) (n_bytes
/u
->frame_size
))
724 frames
= (snd_pcm_sframes_t
) (n_bytes
/u
->frame_size
);
726 p
= pa_memblock_acquire(u
->memchunk
.memblock
);
727 frames
= snd_pcm_writei(u
->pcm_handle
, (const uint8_t*) p
+ u
->memchunk
.index
, (snd_pcm_uframes_t
) frames
);
728 pa_memblock_release(u
->memchunk
.memblock
);
730 if (PA_UNLIKELY(frames
< 0)) {
732 if (!after_avail
&& (int) frames
== -EAGAIN
)
735 if ((r
= try_recover(u
, "snd_pcm_writei", (int) frames
)) == 0)
741 if (!after_avail
&& frames
== 0)
744 pa_assert(frames
> 0);
747 u
->memchunk
.index
+= (size_t) frames
* u
->frame_size
;
748 u
->memchunk
.length
-= (size_t) frames
* u
->frame_size
;
750 if (u
->memchunk
.length
<= 0) {
751 pa_memblock_unref(u
->memchunk
.memblock
);
752 pa_memchunk_reset(&u
->memchunk
);
757 u
->write_count
+= frames
* u
->frame_size
;
758 u
->since_start
+= frames
* u
->frame_size
;
760 /* pa_log_debug("wrote %lu frames", (unsigned long) frames); */
762 if ((size_t) frames
* u
->frame_size
>= n_bytes
)
765 n_bytes
-= (size_t) frames
* u
->frame_size
;
769 *sleep_usec
= pa_bytes_to_usec(left_to_play
, &u
->sink
->sample_spec
);
771 if (*sleep_usec
> process_usec
)
772 *sleep_usec
-= process_usec
;
776 return work_done
? 1 : 0;
779 static void update_smoother(struct userdata
*u
) {
780 snd_pcm_sframes_t delay
= 0;
783 pa_usec_t now1
= 0, now2
;
784 snd_pcm_status_t
*status
;
786 snd_pcm_status_alloca(&status
);
789 pa_assert(u
->pcm_handle
);
791 /* Let's update the time smoother */
793 if (PA_UNLIKELY((err
= pa_alsa_safe_delay(u
->pcm_handle
, &delay
, u
->hwbuf_size
, &u
->sink
->sample_spec
)) < 0)) {
794 pa_log_warn("Failed to query DSP status data: %s", pa_alsa_strerror(err
));
798 if (PA_UNLIKELY((err
= snd_pcm_status(u
->pcm_handle
, status
)) < 0))
799 pa_log_warn("Failed to get timestamp: %s", pa_alsa_strerror(err
));
801 snd_htimestamp_t htstamp
= { 0, 0 };
802 snd_pcm_status_get_htstamp(status
, &htstamp
);
803 now1
= pa_timespec_load(&htstamp
);
806 /* Hmm, if the timestamp is 0, then it wasn't set and we take the current time */
808 now1
= pa_rtclock_now();
810 /* check if the time since the last update is bigger than the interval */
811 if (u
->last_smoother_update
> 0)
812 if (u
->last_smoother_update
+ u
->smoother_interval
> now1
)
815 position
= (int64_t) u
->write_count
- ((int64_t) delay
* (int64_t) u
->frame_size
);
817 if (PA_UNLIKELY(position
< 0))
820 now2
= pa_bytes_to_usec((uint64_t) position
, &u
->sink
->sample_spec
);
822 pa_smoother_put(u
->smoother
, now1
, now2
);
824 u
->last_smoother_update
= now1
;
825 /* exponentially increase the update interval up to the MAX limit */
826 u
->smoother_interval
= PA_MIN (u
->smoother_interval
* 2, SMOOTHER_MAX_INTERVAL
);
829 static pa_usec_t
sink_get_latency(struct userdata
*u
) {
832 pa_usec_t now1
, now2
;
836 now1
= pa_rtclock_now();
837 now2
= pa_smoother_get(u
->smoother
, now1
);
839 delay
= (int64_t) pa_bytes_to_usec(u
->write_count
, &u
->sink
->sample_spec
) - (int64_t) now2
;
841 r
= delay
>= 0 ? (pa_usec_t
) delay
: 0;
843 if (u
->memchunk
.memblock
)
844 r
+= pa_bytes_to_usec(u
->memchunk
.length
, &u
->sink
->sample_spec
);
849 static int build_pollfd(struct userdata
*u
) {
851 pa_assert(u
->pcm_handle
);
853 if (u
->alsa_rtpoll_item
)
854 pa_rtpoll_item_free(u
->alsa_rtpoll_item
);
856 if (!(u
->alsa_rtpoll_item
= pa_alsa_build_pollfd(u
->pcm_handle
, u
->rtpoll
)))
862 /* Called from IO context */
863 static int suspend(struct userdata
*u
) {
865 pa_assert(u
->pcm_handle
);
867 pa_smoother_pause(u
->smoother
, pa_rtclock_now());
869 /* Let's suspend -- we don't call snd_pcm_drain() here since that might
870 * take awfully long with our long buffer sizes today. */
871 snd_pcm_close(u
->pcm_handle
);
872 u
->pcm_handle
= NULL
;
874 if (u
->alsa_rtpoll_item
) {
875 pa_rtpoll_item_free(u
->alsa_rtpoll_item
);
876 u
->alsa_rtpoll_item
= NULL
;
879 pa_log_info("Device suspended...");
884 /* Called from IO context */
885 static int update_sw_params(struct userdata
*u
) {
886 snd_pcm_uframes_t avail_min
;
891 /* Use the full buffer if noone asked us for anything specific */
897 if ((latency
= pa_sink_get_requested_latency_within_thread(u
->sink
)) != (pa_usec_t
) -1) {
900 pa_log_debug("Latency set to %0.2fms", (double) latency
/ PA_USEC_PER_MSEC
);
902 b
= pa_usec_to_bytes(latency
, &u
->sink
->sample_spec
);
904 /* We need at least one sample in our buffer */
906 if (PA_UNLIKELY(b
< u
->frame_size
))
909 u
->hwbuf_unused
= PA_LIKELY(b
< u
->hwbuf_size
) ? (u
->hwbuf_size
- b
) : 0;
912 fix_min_sleep_wakeup(u
);
913 fix_tsched_watermark(u
);
916 pa_log_debug("hwbuf_unused=%lu", (unsigned long) u
->hwbuf_unused
);
918 /* We need at last one frame in the used part of the buffer */
919 avail_min
= (snd_pcm_uframes_t
) u
->hwbuf_unused
/ u
->frame_size
+ 1;
922 pa_usec_t sleep_usec
, process_usec
;
924 hw_sleep_time(u
, &sleep_usec
, &process_usec
);
925 avail_min
+= pa_usec_to_bytes(sleep_usec
, &u
->sink
->sample_spec
) / u
->frame_size
;
928 pa_log_debug("setting avail_min=%lu", (unsigned long) avail_min
);
930 if ((err
= pa_alsa_set_sw_params(u
->pcm_handle
, avail_min
, !u
->use_tsched
)) < 0) {
931 pa_log("Failed to set software parameters: %s", pa_alsa_strerror(err
));
935 pa_sink_set_max_request_within_thread(u
->sink
, u
->hwbuf_size
- u
->hwbuf_unused
);
940 /* Called from IO context */
941 static int unsuspend(struct userdata
*u
) {
945 snd_pcm_uframes_t period_size
, buffer_size
;
948 pa_assert(!u
->pcm_handle
);
950 pa_log_info("Trying resume...");
952 if ((err
= snd_pcm_open(&u
->pcm_handle
, u
->device_name
, SND_PCM_STREAM_PLAYBACK
,
954 SND_PCM_NO_AUTO_RESAMPLE
|
955 SND_PCM_NO_AUTO_CHANNELS
|
956 SND_PCM_NO_AUTO_FORMAT
)) < 0) {
957 pa_log("Error opening PCM device %s: %s", u
->device_name
, pa_alsa_strerror(err
));
961 ss
= u
->sink
->sample_spec
;
962 period_size
= u
->fragment_size
/ u
->frame_size
;
963 buffer_size
= u
->hwbuf_size
/ u
->frame_size
;
967 if ((err
= pa_alsa_set_hw_params(u
->pcm_handle
, &ss
, &period_size
, &buffer_size
, 0, &b
, &d
, TRUE
)) < 0) {
968 pa_log("Failed to set hardware parameters: %s", pa_alsa_strerror(err
));
972 if (b
!= u
->use_mmap
|| d
!= u
->use_tsched
) {
973 pa_log_warn("Resume failed, couldn't get original access mode.");
977 if (!pa_sample_spec_equal(&ss
, &u
->sink
->sample_spec
)) {
978 pa_log_warn("Resume failed, couldn't restore original sample settings.");
982 if (period_size
*u
->frame_size
!= u
->fragment_size
||
983 buffer_size
*u
->frame_size
!= u
->hwbuf_size
) {
984 pa_log_warn("Resume failed, couldn't restore original fragment settings. (Old: %lu/%lu, New %lu/%lu)",
985 (unsigned long) u
->hwbuf_size
, (unsigned long) u
->fragment_size
,
986 (unsigned long) (buffer_size
*u
->fragment_size
), (unsigned long) (period_size
*u
->frame_size
));
990 if (update_sw_params(u
) < 0)
993 if (build_pollfd(u
) < 0)
997 pa_smoother_reset(u
->smoother
, pa_rtclock_now(), TRUE
);
998 u
->smoother_interval
= SMOOTHER_MIN_INTERVAL
;
999 u
->last_smoother_update
= 0;
1004 pa_log_info("Resumed successfully...");
1009 if (u
->pcm_handle
) {
1010 snd_pcm_close(u
->pcm_handle
);
1011 u
->pcm_handle
= NULL
;
1017 /* Called from IO context */
1018 static int sink_process_msg(pa_msgobject
*o
, int code
, void *data
, int64_t offset
, pa_memchunk
*chunk
) {
1019 struct userdata
*u
= PA_SINK(o
)->userdata
;
1023 case PA_SINK_MESSAGE_GET_LATENCY
: {
1027 r
= sink_get_latency(u
);
1029 *((pa_usec_t
*) data
) = r
;
1034 case PA_SINK_MESSAGE_SET_STATE
:
1036 switch ((pa_sink_state_t
) PA_PTR_TO_UINT(data
)) {
1038 case PA_SINK_SUSPENDED
: {
1041 pa_assert(PA_SINK_IS_OPENED(u
->sink
->thread_info
.state
));
1043 if ((r
= suspend(u
)) < 0)
1050 case PA_SINK_RUNNING
: {
1053 if (u
->sink
->thread_info
.state
== PA_SINK_INIT
) {
1054 if (build_pollfd(u
) < 0)
1058 if (u
->sink
->thread_info
.state
== PA_SINK_SUSPENDED
) {
1059 if ((r
= unsuspend(u
)) < 0)
1066 case PA_SINK_UNLINKED
:
1068 case PA_SINK_INVALID_STATE
:
1075 return pa_sink_process_msg(o
, code
, data
, offset
, chunk
);
1078 /* Called from main context */
1079 static int sink_set_state_cb(pa_sink
*s
, pa_sink_state_t new_state
) {
1080 pa_sink_state_t old_state
;
1083 pa_sink_assert_ref(s
);
1084 pa_assert_se(u
= s
->userdata
);
1086 old_state
= pa_sink_get_state(u
->sink
);
1088 if (PA_SINK_IS_OPENED(old_state
) && new_state
== PA_SINK_SUSPENDED
)
1090 else if (old_state
== PA_SINK_SUSPENDED
&& PA_SINK_IS_OPENED(new_state
))
1091 if (reserve_init(u
, u
->device_name
) < 0)
1092 return -PA_ERR_BUSY
;
1097 static int mixer_callback(snd_mixer_elem_t
*elem
, unsigned int mask
) {
1098 struct userdata
*u
= snd_mixer_elem_get_callback_private(elem
);
1101 pa_assert(u
->mixer_handle
);
1103 if (mask
== SND_CTL_EVENT_MASK_REMOVE
)
1106 if (mask
& SND_CTL_EVENT_MASK_VALUE
) {
1107 pa_sink_get_volume(u
->sink
, TRUE
);
1108 pa_sink_get_mute(u
->sink
, TRUE
);
1114 static void sink_get_volume_cb(pa_sink
*s
) {
1115 struct userdata
*u
= s
->userdata
;
1117 char t
[PA_CVOLUME_SNPRINT_MAX
];
1120 pa_assert(u
->mixer_path
);
1121 pa_assert(u
->mixer_handle
);
1123 if (pa_alsa_path_get_volume(u
->mixer_path
, u
->mixer_handle
, &s
->channel_map
, &r
) < 0)
1126 /* Shift down by the base volume, so that 0dB becomes maximum volume */
1127 pa_sw_cvolume_multiply_scalar(&r
, &r
, s
->base_volume
);
1129 pa_log_debug("Read hardware volume: %s", pa_cvolume_snprint(t
, sizeof(t
), &r
));
1131 if (pa_cvolume_equal(&u
->hardware_volume
, &r
))
1134 s
->real_volume
= u
->hardware_volume
= r
;
1136 /* Hmm, so the hardware volume changed, let's reset our software volume */
1137 if (u
->mixer_path
->has_dB
)
1138 pa_sink_set_soft_volume(s
, NULL
);
1141 static void sink_set_volume_cb(pa_sink
*s
) {
1142 struct userdata
*u
= s
->userdata
;
1144 char t
[PA_CVOLUME_SNPRINT_MAX
];
1147 pa_assert(u
->mixer_path
);
1148 pa_assert(u
->mixer_handle
);
1150 /* Shift up by the base volume */
1151 pa_sw_cvolume_divide_scalar(&r
, &s
->real_volume
, s
->base_volume
);
1153 if (pa_alsa_path_set_volume(u
->mixer_path
, u
->mixer_handle
, &s
->channel_map
, &r
) < 0)
1156 /* Shift down by the base volume, so that 0dB becomes maximum volume */
1157 pa_sw_cvolume_multiply_scalar(&r
, &r
, s
->base_volume
);
1159 u
->hardware_volume
= r
;
1161 if (u
->mixer_path
->has_dB
) {
1162 pa_cvolume new_soft_volume
;
1163 pa_bool_t accurate_enough
;
1165 /* Match exactly what the user requested by software */
1166 pa_sw_cvolume_divide(&new_soft_volume
, &s
->real_volume
, &u
->hardware_volume
);
1168 /* If the adjustment to do in software is only minimal we
1169 * can skip it. That saves us CPU at the expense of a bit of
1172 (pa_cvolume_min(&new_soft_volume
) >= (PA_VOLUME_NORM
- VOLUME_ACCURACY
)) &&
1173 (pa_cvolume_max(&new_soft_volume
) <= (PA_VOLUME_NORM
+ VOLUME_ACCURACY
));
1175 pa_log_debug("Requested volume: %s", pa_cvolume_snprint(t
, sizeof(t
), &s
->real_volume
));
1176 pa_log_debug("Got hardware volume: %s", pa_cvolume_snprint(t
, sizeof(t
), &u
->hardware_volume
));
1177 pa_log_debug("Calculated software volume: %s (accurate-enough=%s)", pa_cvolume_snprint(t
, sizeof(t
), &new_soft_volume
),
1178 pa_yes_no(accurate_enough
));
1180 if (!accurate_enough
)
1181 s
->soft_volume
= new_soft_volume
;
1184 pa_log_debug("Wrote hardware volume: %s", pa_cvolume_snprint(t
, sizeof(t
), &r
));
1186 /* We can't match exactly what the user requested, hence let's
1187 * at least tell the user about it */
1193 static void sink_get_mute_cb(pa_sink
*s
) {
1194 struct userdata
*u
= s
->userdata
;
1198 pa_assert(u
->mixer_path
);
1199 pa_assert(u
->mixer_handle
);
1201 if (pa_alsa_path_get_mute(u
->mixer_path
, u
->mixer_handle
, &b
) < 0)
1207 static void sink_set_mute_cb(pa_sink
*s
) {
1208 struct userdata
*u
= s
->userdata
;
1211 pa_assert(u
->mixer_path
);
1212 pa_assert(u
->mixer_handle
);
1214 pa_alsa_path_set_mute(u
->mixer_path
, u
->mixer_handle
, s
->muted
);
1217 static int sink_set_port_cb(pa_sink
*s
, pa_device_port
*p
) {
1218 struct userdata
*u
= s
->userdata
;
1219 pa_alsa_port_data
*data
;
1223 pa_assert(u
->mixer_handle
);
1225 data
= PA_DEVICE_PORT_DATA(p
);
1227 pa_assert_se(u
->mixer_path
= data
->path
);
1228 pa_alsa_path_select(u
->mixer_path
, u
->mixer_handle
);
1230 if (u
->mixer_path
->has_volume
&& u
->mixer_path
->has_dB
) {
1231 s
->base_volume
= pa_sw_volume_from_dB(-u
->mixer_path
->max_dB
);
1232 s
->n_volume_steps
= PA_VOLUME_NORM
+1;
1234 if (u
->mixer_path
->max_dB
> 0.0)
1235 pa_log_info("Fixing base volume to %0.2f dB", pa_sw_volume_to_dB(s
->base_volume
));
1237 pa_log_info("No particular base volume set, fixing to 0 dB");
1239 s
->base_volume
= PA_VOLUME_NORM
;
1240 s
->n_volume_steps
= u
->mixer_path
->max_volume
- u
->mixer_path
->min_volume
+ 1;
1244 pa_alsa_setting_select(data
->setting
, u
->mixer_handle
);
1254 static void sink_update_requested_latency_cb(pa_sink
*s
) {
1255 struct userdata
*u
= s
->userdata
;
1262 before
= u
->hwbuf_unused
;
1263 update_sw_params(u
);
1265 /* Let's check whether we now use only a smaller part of the
1266 buffer then before. If so, we need to make sure that subsequent
1267 rewinds are relative to the new maximum fill level and not to the
1268 current fill level. Thus, let's do a full rewind once, to clear
1271 if (u
->hwbuf_unused
> before
) {
1272 pa_log_debug("Requesting rewind due to latency change.");
1273 pa_sink_request_rewind(s
, (size_t) -1);
1277 static int process_rewind(struct userdata
*u
) {
1278 snd_pcm_sframes_t unused
;
1279 size_t rewind_nbytes
, unused_nbytes
, limit_nbytes
;
1282 /* Figure out how much we shall rewind and reset the counter */
1283 rewind_nbytes
= u
->sink
->thread_info
.rewind_nbytes
;
1285 pa_log_debug("Requested to rewind %lu bytes.", (unsigned long) rewind_nbytes
);
1287 if (PA_UNLIKELY((unused
= pa_alsa_safe_avail(u
->pcm_handle
, u
->hwbuf_size
, &u
->sink
->sample_spec
)) < 0)) {
1288 pa_log("snd_pcm_avail() failed: %s", pa_alsa_strerror((int) unused
));
1292 unused_nbytes
= u
->tsched_watermark
+ (size_t) unused
* u
->frame_size
;
1294 if (u
->hwbuf_size
> unused_nbytes
)
1295 limit_nbytes
= u
->hwbuf_size
- unused_nbytes
;
1299 if (rewind_nbytes
> limit_nbytes
)
1300 rewind_nbytes
= limit_nbytes
;
1302 if (rewind_nbytes
> 0) {
1303 snd_pcm_sframes_t in_frames
, out_frames
;
1305 pa_log_debug("Limited to %lu bytes.", (unsigned long) rewind_nbytes
);
1307 in_frames
= (snd_pcm_sframes_t
) (rewind_nbytes
/ u
->frame_size
);
1308 pa_log_debug("before: %lu", (unsigned long) in_frames
);
1309 if ((out_frames
= snd_pcm_rewind(u
->pcm_handle
, (snd_pcm_uframes_t
) in_frames
)) < 0) {
1310 pa_log("snd_pcm_rewind() failed: %s", pa_alsa_strerror((int) out_frames
));
1311 if (try_recover(u
, "process_rewind", out_frames
) < 0)
1316 pa_log_debug("after: %lu", (unsigned long) out_frames
);
1318 rewind_nbytes
= (size_t) out_frames
* u
->frame_size
;
1320 if (rewind_nbytes
<= 0)
1321 pa_log_info("Tried rewind, but was apparently not possible.");
1323 u
->write_count
-= rewind_nbytes
;
1324 pa_log_debug("Rewound %lu bytes.", (unsigned long) rewind_nbytes
);
1325 pa_sink_process_rewind(u
->sink
, rewind_nbytes
);
1327 u
->after_rewind
= TRUE
;
1331 pa_log_debug("Mhmm, actually there is nothing to rewind.");
1333 pa_sink_process_rewind(u
->sink
, 0);
1337 static void thread_func(void *userdata
) {
1338 struct userdata
*u
= userdata
;
1339 unsigned short revents
= 0;
1343 pa_log_debug("Thread starting up");
1345 if (u
->core
->realtime_scheduling
)
1346 pa_make_realtime(u
->core
->realtime_priority
);
1348 pa_thread_mq_install(&u
->thread_mq
);
1354 pa_log_debug("Loop");
1357 /* Render some data and write it to the dsp */
1358 if (PA_SINK_IS_OPENED(u
->sink
->thread_info
.state
)) {
1360 pa_usec_t sleep_usec
= 0;
1361 pa_bool_t on_timeout
= pa_rtpoll_timer_elapsed(u
->rtpoll
);
1363 if (PA_UNLIKELY(u
->sink
->thread_info
.rewind_requested
))
1364 if (process_rewind(u
) < 0)
1368 work_done
= mmap_write(u
, &sleep_usec
, revents
& POLLOUT
, on_timeout
);
1370 work_done
= unix_write(u
, &sleep_usec
, revents
& POLLOUT
, on_timeout
);
1375 /* pa_log_debug("work_done = %i", work_done); */
1380 pa_log_info("Starting playback.");
1381 snd_pcm_start(u
->pcm_handle
);
1383 pa_smoother_resume(u
->smoother
, pa_rtclock_now(), TRUE
);
1389 if (u
->use_tsched
) {
1392 if (u
->since_start
<= u
->hwbuf_size
) {
1394 /* USB devices on ALSA seem to hit a buffer
1395 * underrun during the first iterations much
1396 * quicker then we calculate here, probably due to
1397 * the transport latency. To accommodate for that
1398 * we artificially decrease the sleep time until
1399 * we have filled the buffer at least once
1402 if (pa_log_ratelimit())
1403 pa_log_debug("Cutting sleep time for the initial iterations by half.");
1407 /* OK, the playback buffer is now full, let's
1408 * calculate when to wake up next */
1409 /* pa_log_debug("Waking up in %0.2fms (sound card clock).", (double) sleep_usec / PA_USEC_PER_MSEC); */
1411 /* Convert from the sound card time domain to the
1412 * system time domain */
1413 cusec
= pa_smoother_translate(u
->smoother
, pa_rtclock_now(), sleep_usec
);
1415 /* pa_log_debug("Waking up in %0.2fms (system clock).", (double) cusec / PA_USEC_PER_MSEC); */
1417 /* We don't trust the conversion, so we wake up whatever comes first */
1418 pa_rtpoll_set_timer_relative(u
->rtpoll
, PA_MIN(sleep_usec
, cusec
));
1422 u
->after_rewind
= FALSE
;
1424 } else if (u
->use_tsched
)
1426 /* OK, we're in an invalid state, let's disable our timers */
1427 pa_rtpoll_set_timer_disabled(u
->rtpoll
);
1429 /* Hmm, nothing to do. Let's sleep */
1430 if ((ret
= pa_rtpoll_run(u
->rtpoll
, TRUE
)) < 0)
1436 /* Tell ALSA about this and process its response */
1437 if (PA_SINK_IS_OPENED(u
->sink
->thread_info
.state
)) {
1438 struct pollfd
*pollfd
;
1442 pollfd
= pa_rtpoll_item_get_pollfd(u
->alsa_rtpoll_item
, &n
);
1444 if ((err
= snd_pcm_poll_descriptors_revents(u
->pcm_handle
, pollfd
, n
, &revents
)) < 0) {
1445 pa_log("snd_pcm_poll_descriptors_revents() failed: %s", pa_alsa_strerror(err
));
1449 if (revents
& ~POLLOUT
) {
1450 if (pa_alsa_recover_from_poll(u
->pcm_handle
, revents
) < 0)
1455 } else if (revents
&& u
->use_tsched
&& pa_log_ratelimit())
1456 pa_log_debug("Wakeup from ALSA!");
1463 /* If this was no regular exit from the loop we have to continue
1464 * processing messages until we received PA_MESSAGE_SHUTDOWN */
1465 pa_asyncmsgq_post(u
->thread_mq
.outq
, PA_MSGOBJECT(u
->core
), PA_CORE_MESSAGE_UNLOAD_MODULE
, u
->module
, 0, NULL
, NULL
);
1466 pa_asyncmsgq_wait_for(u
->thread_mq
.inq
, PA_MESSAGE_SHUTDOWN
);
1469 pa_log_debug("Thread shutting down");
1472 static void set_sink_name(pa_sink_new_data
*data
, pa_modargs
*ma
, const char *device_id
, const char *device_name
, pa_alsa_mapping
*mapping
) {
1478 pa_assert(device_name
);
1480 if ((n
= pa_modargs_get_value(ma
, "sink_name", NULL
))) {
1481 pa_sink_new_data_set_name(data
, n
);
1482 data
->namereg_fail
= TRUE
;
1486 if ((n
= pa_modargs_get_value(ma
, "name", NULL
)))
1487 data
->namereg_fail
= TRUE
;
1489 n
= device_id
? device_id
: device_name
;
1490 data
->namereg_fail
= FALSE
;
1494 t
= pa_sprintf_malloc("alsa_output.%s.%s", n
, mapping
->name
);
1496 t
= pa_sprintf_malloc("alsa_output.%s", n
);
1498 pa_sink_new_data_set_name(data
, t
);
1502 static void find_mixer(struct userdata
*u
, pa_alsa_mapping
*mapping
, const char *element
, pa_bool_t ignore_dB
) {
1504 if (!mapping
&& !element
)
1507 if (!(u
->mixer_handle
= pa_alsa_open_mixer_for_pcm(u
->pcm_handle
, &u
->control_device
))) {
1508 pa_log_info("Failed to find a working mixer device.");
1514 if (!(u
->mixer_path
= pa_alsa_path_synthesize(element
, PA_ALSA_DIRECTION_OUTPUT
)))
1517 if (pa_alsa_path_probe(u
->mixer_path
, u
->mixer_handle
, ignore_dB
) < 0)
1520 pa_log_debug("Probed mixer path %s:", u
->mixer_path
->name
);
1521 pa_alsa_path_dump(u
->mixer_path
);
1524 if (!(u
->mixer_path_set
= pa_alsa_path_set_new(mapping
, PA_ALSA_DIRECTION_OUTPUT
)))
1527 pa_alsa_path_set_probe(u
->mixer_path_set
, u
->mixer_handle
, ignore_dB
);
1529 pa_log_debug("Probed mixer paths:");
1530 pa_alsa_path_set_dump(u
->mixer_path_set
);
1537 if (u
->mixer_path_set
) {
1538 pa_alsa_path_set_free(u
->mixer_path_set
);
1539 u
->mixer_path_set
= NULL
;
1540 } else if (u
->mixer_path
) {
1541 pa_alsa_path_free(u
->mixer_path
);
1542 u
->mixer_path
= NULL
;
1545 if (u
->mixer_handle
) {
1546 snd_mixer_close(u
->mixer_handle
);
1547 u
->mixer_handle
= NULL
;
1551 static int setup_mixer(struct userdata
*u
, pa_bool_t ignore_dB
) {
1554 if (!u
->mixer_handle
)
1557 if (u
->sink
->active_port
) {
1558 pa_alsa_port_data
*data
;
1560 /* We have a list of supported paths, so let's activate the
1561 * one that has been chosen as active */
1563 data
= PA_DEVICE_PORT_DATA(u
->sink
->active_port
);
1564 u
->mixer_path
= data
->path
;
1566 pa_alsa_path_select(data
->path
, u
->mixer_handle
);
1569 pa_alsa_setting_select(data
->setting
, u
->mixer_handle
);
1573 if (!u
->mixer_path
&& u
->mixer_path_set
)
1574 u
->mixer_path
= u
->mixer_path_set
->paths
;
1576 if (u
->mixer_path
) {
1577 /* Hmm, we have only a single path, then let's activate it */
1579 pa_alsa_path_select(u
->mixer_path
, u
->mixer_handle
);
1581 if (u
->mixer_path
->settings
)
1582 pa_alsa_setting_select(u
->mixer_path
->settings
, u
->mixer_handle
);
1587 if (!u
->mixer_path
->has_volume
)
1588 pa_log_info("Driver does not support hardware volume control, falling back to software volume control.");
1591 if (u
->mixer_path
->has_dB
) {
1592 pa_log_info("Hardware volume ranges from %0.2f dB to %0.2f dB.", u
->mixer_path
->min_dB
, u
->mixer_path
->max_dB
);
1594 u
->sink
->base_volume
= pa_sw_volume_from_dB(-u
->mixer_path
->max_dB
);
1595 u
->sink
->n_volume_steps
= PA_VOLUME_NORM
+1;
1597 if (u
->mixer_path
->max_dB
> 0.0)
1598 pa_log_info("Fixing base volume to %0.2f dB", pa_sw_volume_to_dB(u
->sink
->base_volume
));
1600 pa_log_info("No particular base volume set, fixing to 0 dB");
1603 pa_log_info("Hardware volume ranges from %li to %li.", u
->mixer_path
->min_volume
, u
->mixer_path
->max_volume
);
1604 u
->sink
->base_volume
= PA_VOLUME_NORM
;
1605 u
->sink
->n_volume_steps
= u
->mixer_path
->max_volume
- u
->mixer_path
->min_volume
+ 1;
1608 u
->sink
->get_volume
= sink_get_volume_cb
;
1609 u
->sink
->set_volume
= sink_set_volume_cb
;
1611 u
->sink
->flags
|= PA_SINK_HW_VOLUME_CTRL
| (u
->mixer_path
->has_dB
? PA_SINK_DECIBEL_VOLUME
: 0);
1612 pa_log_info("Using hardware volume control. Hardware dB scale %s.", u
->mixer_path
->has_dB
? "supported" : "not supported");
1615 if (!u
->mixer_path
->has_mute
) {
1616 pa_log_info("Driver does not support hardware mute control, falling back to software mute control.");
1618 u
->sink
->get_mute
= sink_get_mute_cb
;
1619 u
->sink
->set_mute
= sink_set_mute_cb
;
1620 u
->sink
->flags
|= PA_SINK_HW_MUTE_CTRL
;
1621 pa_log_info("Using hardware mute control.");
1624 u
->mixer_fdl
= pa_alsa_fdlist_new();
1626 if (pa_alsa_fdlist_set_mixer(u
->mixer_fdl
, u
->mixer_handle
, u
->core
->mainloop
) < 0) {
1627 pa_log("Failed to initialize file descriptor monitoring");
1631 if (u
->mixer_path_set
)
1632 pa_alsa_path_set_set_callback(u
->mixer_path_set
, u
->mixer_handle
, mixer_callback
, u
);
1634 pa_alsa_path_set_callback(u
->mixer_path
, u
->mixer_handle
, mixer_callback
, u
);
1639 pa_sink
*pa_alsa_sink_new(pa_module
*m
, pa_modargs
*ma
, const char*driver
, pa_card
*card
, pa_alsa_mapping
*mapping
) {
1641 struct userdata
*u
= NULL
;
1642 const char *dev_id
= NULL
;
1643 pa_sample_spec ss
, requested_ss
;
1645 uint32_t nfrags
, frag_size
, buffer_size
, tsched_size
, tsched_watermark
;
1646 snd_pcm_uframes_t period_frames
, buffer_frames
, tsched_frames
;
1648 pa_bool_t use_mmap
= TRUE
, b
, use_tsched
= TRUE
, d
, ignore_dB
= FALSE
;
1649 pa_sink_new_data data
;
1650 pa_alsa_profile_set
*profile_set
= NULL
;
1655 ss
= m
->core
->default_sample_spec
;
1656 map
= m
->core
->default_channel_map
;
1657 if (pa_modargs_get_sample_spec_and_channel_map(ma
, &ss
, &map
, PA_CHANNEL_MAP_ALSA
) < 0) {
1658 pa_log("Failed to parse sample specification and channel map");
1663 frame_size
= pa_frame_size(&ss
);
1665 nfrags
= m
->core
->default_n_fragments
;
1666 frag_size
= (uint32_t) pa_usec_to_bytes(m
->core
->default_fragment_size_msec
*PA_USEC_PER_MSEC
, &ss
);
1668 frag_size
= (uint32_t) frame_size
;
1669 tsched_size
= (uint32_t) pa_usec_to_bytes(DEFAULT_TSCHED_BUFFER_USEC
, &ss
);
1670 tsched_watermark
= (uint32_t) pa_usec_to_bytes(DEFAULT_TSCHED_WATERMARK_USEC
, &ss
);
1672 if (pa_modargs_get_value_u32(ma
, "fragments", &nfrags
) < 0 ||
1673 pa_modargs_get_value_u32(ma
, "fragment_size", &frag_size
) < 0 ||
1674 pa_modargs_get_value_u32(ma
, "tsched_buffer_size", &tsched_size
) < 0 ||
1675 pa_modargs_get_value_u32(ma
, "tsched_buffer_watermark", &tsched_watermark
) < 0) {
1676 pa_log("Failed to parse buffer metrics");
1680 buffer_size
= nfrags
* frag_size
;
1682 period_frames
= frag_size
/frame_size
;
1683 buffer_frames
= buffer_size
/frame_size
;
1684 tsched_frames
= tsched_size
/frame_size
;
1686 if (pa_modargs_get_value_boolean(ma
, "mmap", &use_mmap
) < 0) {
1687 pa_log("Failed to parse mmap argument.");
1691 if (pa_modargs_get_value_boolean(ma
, "tsched", &use_tsched
) < 0) {
1692 pa_log("Failed to parse tsched argument.");
1696 if (pa_modargs_get_value_boolean(ma
, "ignore_dB", &ignore_dB
) < 0) {
1697 pa_log("Failed to parse ignore_dB argument.");
1701 if (use_tsched
&& !pa_rtclock_hrtimer()) {
1702 pa_log_notice("Disabling timer-based scheduling because high-resolution timers are not available from the kernel.");
1706 u
= pa_xnew0(struct userdata
, 1);
1709 u
->use_mmap
= use_mmap
;
1710 u
->use_tsched
= use_tsched
;
1712 u
->rtpoll
= pa_rtpoll_new();
1713 pa_thread_mq_init(&u
->thread_mq
, m
->core
->mainloop
, u
->rtpoll
);
1715 u
->smoother
= pa_smoother_new(
1716 DEFAULT_TSCHED_BUFFER_USEC
*2,
1717 DEFAULT_TSCHED_BUFFER_USEC
*2,
1723 u
->smoother_interval
= SMOOTHER_MIN_INTERVAL
;
1725 dev_id
= pa_modargs_get_value(
1727 pa_modargs_get_value(ma
, "device", DEFAULT_DEVICE
));
1729 if (reserve_init(u
, dev_id
) < 0)
1732 if (reserve_monitor_init(u
, dev_id
) < 0)
1740 if (!(dev_id
= pa_modargs_get_value(ma
, "device_id", NULL
))) {
1741 pa_log("device_id= not set");
1745 if (!(u
->pcm_handle
= pa_alsa_open_by_device_id_mapping(
1749 SND_PCM_STREAM_PLAYBACK
,
1750 &period_frames
, &buffer_frames
, tsched_frames
,
1755 } else if ((dev_id
= pa_modargs_get_value(ma
, "device_id", NULL
))) {
1757 if (!(profile_set
= pa_alsa_profile_set_new(NULL
, &map
)))
1760 if (!(u
->pcm_handle
= pa_alsa_open_by_device_id_auto(
1764 SND_PCM_STREAM_PLAYBACK
,
1765 &period_frames
, &buffer_frames
, tsched_frames
,
1766 &b
, &d
, profile_set
, &mapping
)))
1772 if (!(u
->pcm_handle
= pa_alsa_open_by_device_string(
1773 pa_modargs_get_value(ma
, "device", DEFAULT_DEVICE
),
1776 SND_PCM_STREAM_PLAYBACK
,
1777 &period_frames
, &buffer_frames
, tsched_frames
,
1782 pa_assert(u
->device_name
);
1783 pa_log_info("Successfully opened device %s.", u
->device_name
);
1785 if (pa_alsa_pcm_is_modem(u
->pcm_handle
)) {
1786 pa_log_notice("Device %s is modem, refusing further initialization.", u
->device_name
);
1791 pa_log_info("Selected mapping '%s' (%s).", mapping
->description
, mapping
->name
);
1793 if (use_mmap
&& !b
) {
1794 pa_log_info("Device doesn't support mmap(), falling back to UNIX read/write mode.");
1795 u
->use_mmap
= use_mmap
= FALSE
;
1798 if (use_tsched
&& (!b
|| !d
)) {
1799 pa_log_info("Cannot enable timer-based scheduling, falling back to sound IRQ scheduling.");
1800 u
->use_tsched
= use_tsched
= FALSE
;
1804 pa_log_info("Successfully enabled mmap() mode.");
1807 pa_log_info("Successfully enabled timer-based scheduling mode.");
1809 /* ALSA might tweak the sample spec, so recalculate the frame size */
1810 frame_size
= pa_frame_size(&ss
);
1812 find_mixer(u
, mapping
, pa_modargs_get_value(ma
, "control", NULL
), ignore_dB
);
1814 pa_sink_new_data_init(&data
);
1815 data
.driver
= driver
;
1818 set_sink_name(&data
, ma
, dev_id
, u
->device_name
, mapping
);
1819 pa_sink_new_data_set_sample_spec(&data
, &ss
);
1820 pa_sink_new_data_set_channel_map(&data
, &map
);
1822 pa_alsa_init_proplist_pcm(m
->core
, data
.proplist
, u
->pcm_handle
);
1823 pa_proplist_sets(data
.proplist
, PA_PROP_DEVICE_STRING
, u
->device_name
);
1824 pa_proplist_setf(data
.proplist
, PA_PROP_DEVICE_BUFFERING_BUFFER_SIZE
, "%lu", (unsigned long) (buffer_frames
* frame_size
));
1825 pa_proplist_setf(data
.proplist
, PA_PROP_DEVICE_BUFFERING_FRAGMENT_SIZE
, "%lu", (unsigned long) (period_frames
* frame_size
));
1826 pa_proplist_sets(data
.proplist
, PA_PROP_DEVICE_ACCESS_MODE
, u
->use_tsched
? "mmap+timer" : (u
->use_mmap
? "mmap" : "serial"));
1829 pa_proplist_sets(data
.proplist
, PA_PROP_DEVICE_PROFILE_NAME
, mapping
->name
);
1830 pa_proplist_sets(data
.proplist
, PA_PROP_DEVICE_PROFILE_DESCRIPTION
, mapping
->description
);
1833 pa_alsa_init_description(data
.proplist
);
1835 if (u
->control_device
)
1836 pa_alsa_init_proplist_ctl(data
.proplist
, u
->control_device
);
1838 if (pa_modargs_get_proplist(ma
, "sink_properties", data
.proplist
, PA_UPDATE_REPLACE
) < 0) {
1839 pa_log("Invalid properties");
1840 pa_sink_new_data_done(&data
);
1844 if (u
->mixer_path_set
)
1845 pa_alsa_add_ports(&data
.ports
, u
->mixer_path_set
);
1847 u
->sink
= pa_sink_new(m
->core
, &data
, PA_SINK_HARDWARE
|PA_SINK_LATENCY
|(u
->use_tsched
? PA_SINK_DYNAMIC_LATENCY
: 0));
1848 pa_sink_new_data_done(&data
);
1851 pa_log("Failed to create sink object");
1855 u
->sink
->parent
.process_msg
= sink_process_msg
;
1856 u
->sink
->update_requested_latency
= sink_update_requested_latency_cb
;
1857 u
->sink
->set_state
= sink_set_state_cb
;
1858 u
->sink
->set_port
= sink_set_port_cb
;
1859 u
->sink
->userdata
= u
;
1861 pa_sink_set_asyncmsgq(u
->sink
, u
->thread_mq
.inq
);
1862 pa_sink_set_rtpoll(u
->sink
, u
->rtpoll
);
1864 u
->frame_size
= frame_size
;
1865 u
->fragment_size
= frag_size
= (size_t) (period_frames
* frame_size
);
1866 u
->hwbuf_size
= buffer_size
= (size_t) (buffer_frames
* frame_size
);
1867 pa_cvolume_mute(&u
->hardware_volume
, u
->sink
->sample_spec
.channels
);
1869 pa_log_info("Using %0.1f fragments of size %lu bytes (%0.2fms), buffer size is %lu bytes (%0.2fms)",
1870 (double) u
->hwbuf_size
/ (double) u
->fragment_size
,
1871 (long unsigned) u
->fragment_size
,
1872 (double) pa_bytes_to_usec(u
->fragment_size
, &ss
) / PA_USEC_PER_MSEC
,
1873 (long unsigned) u
->hwbuf_size
,
1874 (double) pa_bytes_to_usec(u
->hwbuf_size
, &ss
) / PA_USEC_PER_MSEC
);
1876 pa_sink_set_max_request(u
->sink
, u
->hwbuf_size
);
1877 pa_sink_set_max_rewind(u
->sink
, u
->hwbuf_size
);
1879 if (u
->use_tsched
) {
1880 u
->tsched_watermark
= pa_usec_to_bytes_round_up(pa_bytes_to_usec_round_up(tsched_watermark
, &requested_ss
), &u
->sink
->sample_spec
);
1882 u
->watermark_inc_step
= pa_usec_to_bytes(TSCHED_WATERMARK_INC_STEP_USEC
, &u
->sink
->sample_spec
);
1883 u
->watermark_dec_step
= pa_usec_to_bytes(TSCHED_WATERMARK_DEC_STEP_USEC
, &u
->sink
->sample_spec
);
1885 u
->watermark_inc_threshold
= pa_usec_to_bytes_round_up(TSCHED_WATERMARK_INC_THRESHOLD_USEC
, &u
->sink
->sample_spec
);
1886 u
->watermark_dec_threshold
= pa_usec_to_bytes_round_up(TSCHED_WATERMARK_DEC_THRESHOLD_USEC
, &u
->sink
->sample_spec
);
1888 fix_min_sleep_wakeup(u
);
1889 fix_tsched_watermark(u
);
1891 pa_sink_set_latency_range(u
->sink
,
1893 pa_bytes_to_usec(u
->hwbuf_size
, &ss
));
1895 pa_log_info("Time scheduling watermark is %0.2fms",
1896 (double) pa_bytes_to_usec(u
->tsched_watermark
, &ss
) / PA_USEC_PER_MSEC
);
1898 pa_sink_set_fixed_latency(u
->sink
, pa_bytes_to_usec(u
->hwbuf_size
, &ss
));
1903 if (update_sw_params(u
) < 0)
1906 if (setup_mixer(u
, ignore_dB
) < 0)
1909 pa_alsa_dump(PA_LOG_DEBUG
, u
->pcm_handle
);
1911 if (!(u
->thread
= pa_thread_new(thread_func
, u
))) {
1912 pa_log("Failed to create thread.");
1916 /* Get initial mixer settings */
1917 if (data
.volume_is_set
) {
1918 if (u
->sink
->set_volume
)
1919 u
->sink
->set_volume(u
->sink
);
1921 if (u
->sink
->get_volume
)
1922 u
->sink
->get_volume(u
->sink
);
1925 if (data
.muted_is_set
) {
1926 if (u
->sink
->set_mute
)
1927 u
->sink
->set_mute(u
->sink
);
1929 if (u
->sink
->get_mute
)
1930 u
->sink
->get_mute(u
->sink
);
1933 pa_sink_put(u
->sink
);
1936 pa_alsa_profile_set_free(profile_set
);
1946 pa_alsa_profile_set_free(profile_set
);
1951 static void userdata_free(struct userdata
*u
) {
1955 pa_sink_unlink(u
->sink
);
1958 pa_asyncmsgq_send(u
->thread_mq
.inq
, NULL
, PA_MESSAGE_SHUTDOWN
, NULL
, 0, NULL
);
1959 pa_thread_free(u
->thread
);
1962 pa_thread_mq_done(&u
->thread_mq
);
1965 pa_sink_unref(u
->sink
);
1967 if (u
->memchunk
.memblock
)
1968 pa_memblock_unref(u
->memchunk
.memblock
);
1970 if (u
->alsa_rtpoll_item
)
1971 pa_rtpoll_item_free(u
->alsa_rtpoll_item
);
1974 pa_rtpoll_free(u
->rtpoll
);
1976 if (u
->pcm_handle
) {
1977 snd_pcm_drop(u
->pcm_handle
);
1978 snd_pcm_close(u
->pcm_handle
);
1982 pa_alsa_fdlist_free(u
->mixer_fdl
);
1984 if (u
->mixer_path_set
)
1985 pa_alsa_path_set_free(u
->mixer_path_set
);
1986 else if (u
->mixer_path
)
1987 pa_alsa_path_free(u
->mixer_path
);
1989 if (u
->mixer_handle
)
1990 snd_mixer_close(u
->mixer_handle
);
1993 pa_smoother_free(u
->smoother
);
1998 pa_xfree(u
->device_name
);
1999 pa_xfree(u
->control_device
);
2003 void pa_alsa_sink_free(pa_sink
*s
) {
2006 pa_sink_assert_ref(s
);
2007 pa_assert_se(u
= s
->userdata
);