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|
/***
This file is part of PulseAudio.
Copyright 2004-2006 Lennart Poettering
Copyright 2006 Pierre Ossman <ossman@cendio.se> for Cendio AB
PulseAudio is free software; you can redistribute it and/or modify
it under the terms of the GNU Lesser General Public License as published
by the Free Software Foundation; either version 2.1 of the License,
or (at your option) any later version.
PulseAudio is distributed in the hope that it will be useful, but
WITHOUT ANY WARRANTY; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
General Public License for more details.
You should have received a copy of the GNU Lesser General Public License
along with PulseAudio; if not, write to the Free Software
Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307
USA.
***/
#ifdef HAVE_CONFIG_H
#include <config.h>
#endif
#include <stdio.h>
#include <stdlib.h>
#include <string.h>
#include <pulse/introspect.h>
#include <pulse/format.h>
#include <pulse/utf8.h>
#include <pulse/xmalloc.h>
#include <pulse/timeval.h>
#include <pulse/util.h>
#include <pulse/rtclock.h>
#include <pulse/internal.h>
#include <pulsecore/i18n.h>
#include <pulsecore/sink-input.h>
#include <pulsecore/namereg.h>
#include <pulsecore/core-util.h>
#include <pulsecore/sample-util.h>
#include <pulsecore/core-subscribe.h>
#include <pulsecore/log.h>
#include <pulsecore/macro.h>
#include <pulsecore/play-memblockq.h>
#include <pulsecore/flist.h>
#include "sink.h"
#define MAX_MIX_CHANNELS 32
#define MIX_BUFFER_LENGTH (PA_PAGE_SIZE)
#define ABSOLUTE_MIN_LATENCY (500)
#define ABSOLUTE_MAX_LATENCY (10*PA_USEC_PER_SEC)
#define DEFAULT_FIXED_LATENCY (250*PA_USEC_PER_MSEC)
PA_DEFINE_PUBLIC_CLASS(pa_sink, pa_msgobject);
struct pa_sink_volume_change {
pa_usec_t at;
pa_cvolume hw_volume;
PA_LLIST_FIELDS(pa_sink_volume_change);
};
struct sink_message_set_port {
pa_device_port *port;
int ret;
};
static void sink_free(pa_object *s);
static void pa_sink_volume_change_push(pa_sink *s);
static void pa_sink_volume_change_flush(pa_sink *s);
static void pa_sink_volume_change_rewind(pa_sink *s, size_t nbytes);
pa_sink_new_data* pa_sink_new_data_init(pa_sink_new_data *data) {
pa_assert(data);
pa_zero(*data);
data->proplist = pa_proplist_new();
return data;
}
void pa_sink_new_data_set_name(pa_sink_new_data *data, const char *name) {
pa_assert(data);
pa_xfree(data->name);
data->name = pa_xstrdup(name);
}
void pa_sink_new_data_set_sample_spec(pa_sink_new_data *data, const pa_sample_spec *spec) {
pa_assert(data);
if ((data->sample_spec_is_set = !!spec))
data->sample_spec = *spec;
}
void pa_sink_new_data_set_channel_map(pa_sink_new_data *data, const pa_channel_map *map) {
pa_assert(data);
if ((data->channel_map_is_set = !!map))
data->channel_map = *map;
}
void pa_sink_new_data_set_alternate_sample_rate(pa_sink_new_data *data, const uint32_t alternate_sample_rate) {
pa_assert(data);
data->alternate_sample_rate_is_set = TRUE;
data->alternate_sample_rate = alternate_sample_rate;
}
void pa_sink_new_data_set_volume(pa_sink_new_data *data, const pa_cvolume *volume) {
pa_assert(data);
if ((data->volume_is_set = !!volume))
data->volume = *volume;
}
void pa_sink_new_data_set_muted(pa_sink_new_data *data, pa_bool_t mute) {
pa_assert(data);
data->muted_is_set = TRUE;
data->muted = !!mute;
}
void pa_sink_new_data_set_port(pa_sink_new_data *data, const char *port) {
pa_assert(data);
pa_xfree(data->active_port);
data->active_port = pa_xstrdup(port);
}
void pa_sink_new_data_done(pa_sink_new_data *data) {
pa_assert(data);
pa_proplist_free(data->proplist);
if (data->ports)
pa_device_port_hashmap_free(data->ports);
pa_xfree(data->name);
pa_xfree(data->active_port);
}
/* Called from main context */
static void reset_callbacks(pa_sink *s) {
pa_assert(s);
s->set_state = NULL;
s->get_volume = NULL;
s->set_volume = NULL;
s->write_volume = NULL;
s->get_mute = NULL;
s->set_mute = NULL;
s->request_rewind = NULL;
s->update_requested_latency = NULL;
s->set_port = NULL;
s->get_formats = NULL;
s->set_formats = NULL;
s->update_rate = NULL;
}
/* Called from main context */
pa_sink* pa_sink_new(
pa_core *core,
pa_sink_new_data *data,
pa_sink_flags_t flags) {
pa_sink *s;
const char *name;
char st[PA_SAMPLE_SPEC_SNPRINT_MAX], cm[PA_CHANNEL_MAP_SNPRINT_MAX];
pa_source_new_data source_data;
const char *dn;
char *pt;
pa_assert(core);
pa_assert(data);
pa_assert(data->name);
pa_assert_ctl_context();
s = pa_msgobject_new(pa_sink);
if (!(name = pa_namereg_register(core, data->name, PA_NAMEREG_SINK, s, data->namereg_fail))) {
pa_log_debug("Failed to register name %s.", data->name);
pa_xfree(s);
return NULL;
}
pa_sink_new_data_set_name(data, name);
if (pa_hook_fire(&core->hooks[PA_CORE_HOOK_SINK_NEW], data) < 0) {
pa_xfree(s);
pa_namereg_unregister(core, name);
return NULL;
}
/* FIXME, need to free s here on failure */
pa_return_null_if_fail(!data->driver || pa_utf8_valid(data->driver));
pa_return_null_if_fail(data->name && pa_utf8_valid(data->name) && data->name[0]);
pa_return_null_if_fail(data->sample_spec_is_set && pa_sample_spec_valid(&data->sample_spec));
if (!data->channel_map_is_set)
pa_return_null_if_fail(pa_channel_map_init_auto(&data->channel_map, data->sample_spec.channels, PA_CHANNEL_MAP_DEFAULT));
pa_return_null_if_fail(pa_channel_map_valid(&data->channel_map));
pa_return_null_if_fail(data->channel_map.channels == data->sample_spec.channels);
/* FIXME: There should probably be a general function for checking whether
* the sink volume is allowed to be set, like there is for sink inputs. */
pa_assert(!data->volume_is_set || !(flags & PA_SINK_SHARE_VOLUME_WITH_MASTER));
if (!data->volume_is_set) {
pa_cvolume_reset(&data->volume, data->sample_spec.channels);
data->save_volume = FALSE;
}
pa_return_null_if_fail(pa_cvolume_valid(&data->volume));
pa_return_null_if_fail(pa_cvolume_compatible(&data->volume, &data->sample_spec));
if (!data->muted_is_set)
data->muted = FALSE;
if (data->card)
pa_proplist_update(data->proplist, PA_UPDATE_MERGE, data->card->proplist);
pa_device_init_description(data->proplist);
pa_device_init_icon(data->proplist, TRUE);
pa_device_init_intended_roles(data->proplist);
if (pa_hook_fire(&core->hooks[PA_CORE_HOOK_SINK_FIXATE], data) < 0) {
pa_xfree(s);
pa_namereg_unregister(core, name);
return NULL;
}
s->parent.parent.free = sink_free;
s->parent.process_msg = pa_sink_process_msg;
s->core = core;
s->state = PA_SINK_INIT;
s->flags = flags;
s->priority = 0;
s->suspend_cause = 0;
pa_sink_set_mixer_dirty(s, FALSE);
s->name = pa_xstrdup(name);
s->proplist = pa_proplist_copy(data->proplist);
s->driver = pa_xstrdup(pa_path_get_filename(data->driver));
s->module = data->module;
s->card = data->card;
s->priority = pa_device_init_priority(s->proplist);
s->sample_spec = data->sample_spec;
s->channel_map = data->channel_map;
s->default_sample_rate = s->sample_spec.rate;
if (data->alternate_sample_rate_is_set)
s->alternate_sample_rate = data->alternate_sample_rate;
else
s->alternate_sample_rate = s->core->alternate_sample_rate;
if (s->sample_spec.rate == s->alternate_sample_rate) {
pa_log_warn("Default and alternate sample rates are the same.");
s->alternate_sample_rate = 0;
}
s->inputs = pa_idxset_new(NULL, NULL);
s->n_corked = 0;
s->input_to_master = NULL;
s->reference_volume = s->real_volume = data->volume;
pa_cvolume_reset(&s->soft_volume, s->sample_spec.channels);
s->base_volume = PA_VOLUME_NORM;
s->n_volume_steps = PA_VOLUME_NORM+1;
s->muted = data->muted;
s->refresh_volume = s->refresh_muted = FALSE;
reset_callbacks(s);
s->userdata = NULL;
s->asyncmsgq = NULL;
/* As a minor optimization we just steal the list instead of
* copying it here */
s->ports = data->ports;
data->ports = NULL;
s->active_port = NULL;
s->save_port = FALSE;
if (data->active_port && s->ports)
if ((s->active_port = pa_hashmap_get(s->ports, data->active_port)))
s->save_port = data->save_port;
if (!s->active_port && s->ports) {
void *state;
pa_device_port *p;
PA_HASHMAP_FOREACH(p, s->ports, state)
if (!s->active_port || p->priority > s->active_port->priority)
s->active_port = p;
}
s->save_volume = data->save_volume;
s->save_muted = data->save_muted;
pa_silence_memchunk_get(
&core->silence_cache,
core->mempool,
&s->silence,
&s->sample_spec,
0);
s->thread_info.rtpoll = NULL;
s->thread_info.inputs = pa_hashmap_new(pa_idxset_trivial_hash_func, pa_idxset_trivial_compare_func);
s->thread_info.soft_volume = s->soft_volume;
s->thread_info.soft_muted = s->muted;
s->thread_info.state = s->state;
s->thread_info.rewind_nbytes = 0;
s->thread_info.rewind_requested = FALSE;
s->thread_info.max_rewind = 0;
s->thread_info.max_request = 0;
s->thread_info.requested_latency_valid = FALSE;
s->thread_info.requested_latency = 0;
s->thread_info.min_latency = ABSOLUTE_MIN_LATENCY;
s->thread_info.max_latency = ABSOLUTE_MAX_LATENCY;
s->thread_info.fixed_latency = flags & PA_SINK_DYNAMIC_LATENCY ? 0 : DEFAULT_FIXED_LATENCY;
PA_LLIST_HEAD_INIT(pa_sink_volume_change, s->thread_info.volume_changes);
s->thread_info.volume_changes_tail = NULL;
pa_sw_cvolume_multiply(&s->thread_info.current_hw_volume, &s->soft_volume, &s->real_volume);
s->thread_info.volume_change_safety_margin = core->deferred_volume_safety_margin_usec;
s->thread_info.volume_change_extra_delay = core->deferred_volume_extra_delay_usec;
/* FIXME: This should probably be moved to pa_sink_put() */
pa_assert_se(pa_idxset_put(core->sinks, s, &s->index) >= 0);
if (s->card)
pa_assert_se(pa_idxset_put(s->card->sinks, s, NULL) >= 0);
pt = pa_proplist_to_string_sep(s->proplist, "\n ");
pa_log_info("Created sink %u \"%s\" with sample spec %s and channel map %s\n %s",
s->index,
s->name,
pa_sample_spec_snprint(st, sizeof(st), &s->sample_spec),
pa_channel_map_snprint(cm, sizeof(cm), &s->channel_map),
pt);
pa_xfree(pt);
pa_source_new_data_init(&source_data);
pa_source_new_data_set_sample_spec(&source_data, &s->sample_spec);
pa_source_new_data_set_channel_map(&source_data, &s->channel_map);
pa_source_new_data_set_alternate_sample_rate(&source_data, s->alternate_sample_rate);
source_data.name = pa_sprintf_malloc("%s.monitor", name);
source_data.driver = data->driver;
source_data.module = data->module;
source_data.card = data->card;
dn = pa_proplist_gets(s->proplist, PA_PROP_DEVICE_DESCRIPTION);
pa_proplist_setf(source_data.proplist, PA_PROP_DEVICE_DESCRIPTION, "Monitor of %s", dn ? dn : s->name);
pa_proplist_sets(source_data.proplist, PA_PROP_DEVICE_CLASS, "monitor");
s->monitor_source = pa_source_new(core, &source_data,
((flags & PA_SINK_LATENCY) ? PA_SOURCE_LATENCY : 0) |
((flags & PA_SINK_DYNAMIC_LATENCY) ? PA_SOURCE_DYNAMIC_LATENCY : 0));
pa_source_new_data_done(&source_data);
if (!s->monitor_source) {
pa_sink_unlink(s);
pa_sink_unref(s);
return NULL;
}
s->monitor_source->monitor_of = s;
pa_source_set_latency_range(s->monitor_source, s->thread_info.min_latency, s->thread_info.max_latency);
pa_source_set_fixed_latency(s->monitor_source, s->thread_info.fixed_latency);
pa_source_set_max_rewind(s->monitor_source, s->thread_info.max_rewind);
return s;
}
/* Called from main context */
static int sink_set_state(pa_sink *s, pa_sink_state_t state) {
int ret;
pa_bool_t suspend_change;
pa_sink_state_t original_state;
pa_assert(s);
pa_assert_ctl_context();
if (s->state == state)
return 0;
original_state = s->state;
suspend_change =
(original_state == PA_SINK_SUSPENDED && PA_SINK_IS_OPENED(state)) ||
(PA_SINK_IS_OPENED(original_state) && state == PA_SINK_SUSPENDED);
if (s->set_state)
if ((ret = s->set_state(s, state)) < 0)
return ret;
if (s->asyncmsgq)
if ((ret = pa_asyncmsgq_send(s->asyncmsgq, PA_MSGOBJECT(s), PA_SINK_MESSAGE_SET_STATE, PA_UINT_TO_PTR(state), 0, NULL)) < 0) {
if (s->set_state)
s->set_state(s, original_state);
return ret;
}
s->state = state;
if (state != PA_SINK_UNLINKED) { /* if we enter UNLINKED state pa_sink_unlink() will fire the appropriate events */
pa_hook_fire(&s->core->hooks[PA_CORE_HOOK_SINK_STATE_CHANGED], s);
pa_subscription_post(s->core, PA_SUBSCRIPTION_EVENT_SINK | PA_SUBSCRIPTION_EVENT_CHANGE, s->index);
}
if (suspend_change) {
pa_sink_input *i;
uint32_t idx;
/* We're suspending or resuming, tell everyone about it */
PA_IDXSET_FOREACH(i, s->inputs, idx)
if (s->state == PA_SINK_SUSPENDED &&
(i->flags & PA_SINK_INPUT_KILL_ON_SUSPEND))
pa_sink_input_kill(i);
else if (i->suspend)
i->suspend(i, state == PA_SINK_SUSPENDED);
if (s->monitor_source)
pa_source_sync_suspend(s->monitor_source);
}
return 0;
}
void pa_sink_set_get_volume_callback(pa_sink *s, pa_sink_cb_t cb) {
pa_assert(s);
s->get_volume = cb;
}
void pa_sink_set_set_volume_callback(pa_sink *s, pa_sink_cb_t cb) {
pa_sink_flags_t flags;
pa_assert(s);
pa_assert(!s->write_volume || cb);
s->set_volume = cb;
/* Save the current flags so we can tell if they've changed */
flags = s->flags;
if (cb) {
/* The sink implementor is responsible for setting decibel volume support */
s->flags |= PA_SINK_HW_VOLUME_CTRL;
} else {
s->flags &= ~PA_SINK_HW_VOLUME_CTRL;
/* See note below in pa_sink_put() about volume sharing and decibel volumes */
pa_sink_enable_decibel_volume(s, !(s->flags & PA_SINK_SHARE_VOLUME_WITH_MASTER));
}
/* If the flags have changed after init, let any clients know via a change event */
if (s->state != PA_SINK_INIT && flags != s->flags)
pa_subscription_post(s->core, PA_SUBSCRIPTION_EVENT_SINK|PA_SUBSCRIPTION_EVENT_CHANGE, s->index);
}
void pa_sink_set_write_volume_callback(pa_sink *s, pa_sink_cb_t cb) {
pa_sink_flags_t flags;
pa_assert(s);
pa_assert(!cb || s->set_volume);
s->write_volume = cb;
/* Save the current flags so we can tell if they've changed */
flags = s->flags;
if (cb)
s->flags |= PA_SINK_DEFERRED_VOLUME;
else
s->flags &= ~PA_SINK_DEFERRED_VOLUME;
/* If the flags have changed after init, let any clients know via a change event */
if (s->state != PA_SINK_INIT && flags != s->flags)
pa_subscription_post(s->core, PA_SUBSCRIPTION_EVENT_SINK|PA_SUBSCRIPTION_EVENT_CHANGE, s->index);
}
void pa_sink_set_get_mute_callback(pa_sink *s, pa_sink_cb_t cb) {
pa_assert(s);
s->get_mute = cb;
}
void pa_sink_set_set_mute_callback(pa_sink *s, pa_sink_cb_t cb) {
pa_sink_flags_t flags;
pa_assert(s);
s->set_mute = cb;
/* Save the current flags so we can tell if they've changed */
flags = s->flags;
if (cb)
s->flags |= PA_SINK_HW_MUTE_CTRL;
else
s->flags &= ~PA_SINK_HW_MUTE_CTRL;
/* If the flags have changed after init, let any clients know via a change event */
if (s->state != PA_SINK_INIT && flags != s->flags)
pa_subscription_post(s->core, PA_SUBSCRIPTION_EVENT_SINK|PA_SUBSCRIPTION_EVENT_CHANGE, s->index);
}
static void enable_flat_volume(pa_sink *s, pa_bool_t enable) {
pa_sink_flags_t flags;
pa_assert(s);
/* Always follow the overall user preference here */
enable = enable && s->core->flat_volumes;
/* Save the current flags so we can tell if they've changed */
flags = s->flags;
if (enable)
s->flags |= PA_SINK_FLAT_VOLUME;
else
s->flags &= ~PA_SINK_FLAT_VOLUME;
/* If the flags have changed after init, let any clients know via a change event */
if (s->state != PA_SINK_INIT && flags != s->flags)
pa_subscription_post(s->core, PA_SUBSCRIPTION_EVENT_SINK|PA_SUBSCRIPTION_EVENT_CHANGE, s->index);
}
void pa_sink_enable_decibel_volume(pa_sink *s, pa_bool_t enable) {
pa_sink_flags_t flags;
pa_assert(s);
/* Save the current flags so we can tell if they've changed */
flags = s->flags;
if (enable) {
s->flags |= PA_SINK_DECIBEL_VOLUME;
enable_flat_volume(s, TRUE);
} else {
s->flags &= ~PA_SINK_DECIBEL_VOLUME;
enable_flat_volume(s, FALSE);
}
/* If the flags have changed after init, let any clients know via a change event */
if (s->state != PA_SINK_INIT && flags != s->flags)
pa_subscription_post(s->core, PA_SUBSCRIPTION_EVENT_SINK|PA_SUBSCRIPTION_EVENT_CHANGE, s->index);
}
/* Called from main context */
void pa_sink_put(pa_sink* s) {
pa_sink_assert_ref(s);
pa_assert_ctl_context();
pa_assert(s->state == PA_SINK_INIT);
pa_assert(!(s->flags & PA_SINK_SHARE_VOLUME_WITH_MASTER) || s->input_to_master);
/* The following fields must be initialized properly when calling _put() */
pa_assert(s->asyncmsgq);
pa_assert(s->thread_info.min_latency <= s->thread_info.max_latency);
/* Generally, flags should be initialized via pa_sink_new(). As a
* special exception we allow some volume related flags to be set
* between _new() and _put() by the callback setter functions above.
*
* Thus we implement a couple safeguards here which ensure the above
* setters were used (or at least the implementor made manual changes
* in a compatible way).
*
* Note: All of these flags set here can change over the life time
* of the sink. */
pa_assert(!(s->flags & PA_SINK_HW_VOLUME_CTRL) || s->set_volume);
pa_assert(!(s->flags & PA_SINK_DEFERRED_VOLUME) || s->write_volume);
pa_assert(!(s->flags & PA_SINK_HW_MUTE_CTRL) || s->set_mute);
/* XXX: Currently decibel volume is disabled for all sinks that use volume
* sharing. When the master sink supports decibel volume, it would be good
* to have the flag also in the filter sink, but currently we don't do that
* so that the flags of the filter sink never change when it's moved from
* a master sink to another. One solution for this problem would be to
* remove user-visible volume altogether from filter sinks when volume
* sharing is used, but the current approach was easier to implement... */
/* We always support decibel volumes in software, otherwise we leave it to
* the sink implementor to set this flag as needed.
*
* Note: This flag can also change over the life time of the sink. */
if (!(s->flags & PA_SINK_HW_VOLUME_CTRL) && !(s->flags & PA_SINK_SHARE_VOLUME_WITH_MASTER))
pa_sink_enable_decibel_volume(s, TRUE);
/* If the sink implementor support DB volumes by itself, we should always
* try and enable flat volumes too */
if ((s->flags & PA_SINK_DECIBEL_VOLUME))
enable_flat_volume(s, TRUE);
if (s->flags & PA_SINK_SHARE_VOLUME_WITH_MASTER) {
pa_sink *root_sink = pa_sink_get_master(s);
pa_assert(root_sink);
s->reference_volume = root_sink->reference_volume;
pa_cvolume_remap(&s->reference_volume, &root_sink->channel_map, &s->channel_map);
s->real_volume = root_sink->real_volume;
pa_cvolume_remap(&s->real_volume, &root_sink->channel_map, &s->channel_map);
} else
/* We assume that if the sink implementor changed the default
* volume he did so in real_volume, because that is the usual
* place where he is supposed to place his changes. */
s->reference_volume = s->real_volume;
s->thread_info.soft_volume = s->soft_volume;
s->thread_info.soft_muted = s->muted;
pa_sw_cvolume_multiply(&s->thread_info.current_hw_volume, &s->soft_volume, &s->real_volume);
pa_assert((s->flags & PA_SINK_HW_VOLUME_CTRL)
|| (s->base_volume == PA_VOLUME_NORM
&& ((s->flags & PA_SINK_DECIBEL_VOLUME || (s->flags & PA_SINK_SHARE_VOLUME_WITH_MASTER)))));
pa_assert(!(s->flags & PA_SINK_DECIBEL_VOLUME) || s->n_volume_steps == PA_VOLUME_NORM+1);
pa_assert(!(s->flags & PA_SINK_DYNAMIC_LATENCY) == (s->thread_info.fixed_latency != 0));
pa_assert(!(s->flags & PA_SINK_LATENCY) == !(s->monitor_source->flags & PA_SOURCE_LATENCY));
pa_assert(!(s->flags & PA_SINK_DYNAMIC_LATENCY) == !(s->monitor_source->flags & PA_SOURCE_DYNAMIC_LATENCY));
pa_assert(s->monitor_source->thread_info.fixed_latency == s->thread_info.fixed_latency);
pa_assert(s->monitor_source->thread_info.min_latency == s->thread_info.min_latency);
pa_assert(s->monitor_source->thread_info.max_latency == s->thread_info.max_latency);
pa_assert_se(sink_set_state(s, PA_SINK_IDLE) == 0);
pa_source_put(s->monitor_source);
pa_subscription_post(s->core, PA_SUBSCRIPTION_EVENT_SINK | PA_SUBSCRIPTION_EVENT_NEW, s->index);
pa_hook_fire(&s->core->hooks[PA_CORE_HOOK_SINK_PUT], s);
}
/* Called from main context */
void pa_sink_unlink(pa_sink* s) {
pa_bool_t linked;
pa_sink_input *i, *j = NULL;
pa_assert(s);
pa_assert_ctl_context();
/* Please note that pa_sink_unlink() does more than simply
* reversing pa_sink_put(). It also undoes the registrations
* already done in pa_sink_new()! */
/* All operations here shall be idempotent, i.e. pa_sink_unlink()
* may be called multiple times on the same sink without bad
* effects. */
linked = PA_SINK_IS_LINKED(s->state);
if (linked)
pa_hook_fire(&s->core->hooks[PA_CORE_HOOK_SINK_UNLINK], s);
if (s->state != PA_SINK_UNLINKED)
pa_namereg_unregister(s->core, s->name);
pa_idxset_remove_by_data(s->core->sinks, s, NULL);
if (s->card)
pa_idxset_remove_by_data(s->card->sinks, s, NULL);
while ((i = pa_idxset_first(s->inputs, NULL))) {
pa_assert(i != j);
pa_sink_input_kill(i);
j = i;
}
if (linked)
sink_set_state(s, PA_SINK_UNLINKED);
else
s->state = PA_SINK_UNLINKED;
reset_callbacks(s);
if (s->monitor_source)
pa_source_unlink(s->monitor_source);
if (linked) {
pa_subscription_post(s->core, PA_SUBSCRIPTION_EVENT_SINK | PA_SUBSCRIPTION_EVENT_REMOVE, s->index);
pa_hook_fire(&s->core->hooks[PA_CORE_HOOK_SINK_UNLINK_POST], s);
}
}
/* Called from main context */
static void sink_free(pa_object *o) {
pa_sink *s = PA_SINK(o);
pa_sink_input *i;
pa_assert(s);
pa_assert_ctl_context();
pa_assert(pa_sink_refcnt(s) == 0);
if (PA_SINK_IS_LINKED(s->state))
pa_sink_unlink(s);
pa_log_info("Freeing sink %u \"%s\"", s->index, s->name);
if (s->monitor_source) {
pa_source_unref(s->monitor_source);
s->monitor_source = NULL;
}
pa_idxset_free(s->inputs, NULL, NULL);
while ((i = pa_hashmap_steal_first(s->thread_info.inputs)))
pa_sink_input_unref(i);
pa_hashmap_free(s->thread_info.inputs, NULL, NULL);
if (s->silence.memblock)
pa_memblock_unref(s->silence.memblock);
pa_xfree(s->name);
pa_xfree(s->driver);
if (s->proplist)
pa_proplist_free(s->proplist);
if (s->ports)
pa_device_port_hashmap_free(s->ports);
pa_xfree(s);
}
/* Called from main context, and not while the IO thread is active, please */
void pa_sink_set_asyncmsgq(pa_sink *s, pa_asyncmsgq *q) {
pa_sink_assert_ref(s);
pa_assert_ctl_context();
s->asyncmsgq = q;
if (s->monitor_source)
pa_source_set_asyncmsgq(s->monitor_source, q);
}
/* Called from main context, and not while the IO thread is active, please */
void pa_sink_update_flags(pa_sink *s, pa_sink_flags_t mask, pa_sink_flags_t value) {
pa_sink_assert_ref(s);
pa_assert_ctl_context();
if (mask == 0)
return;
/* For now, allow only a minimal set of flags to be changed. */
pa_assert((mask & ~(PA_SINK_DYNAMIC_LATENCY|PA_SINK_LATENCY)) == 0);
s->flags = (s->flags & ~mask) | (value & mask);
pa_source_update_flags(s->monitor_source,
((mask & PA_SINK_LATENCY) ? PA_SOURCE_LATENCY : 0) |
((mask & PA_SINK_DYNAMIC_LATENCY) ? PA_SOURCE_DYNAMIC_LATENCY : 0),
((value & PA_SINK_LATENCY) ? PA_SOURCE_LATENCY : 0) |
((value & PA_SINK_DYNAMIC_LATENCY) ? PA_SINK_DYNAMIC_LATENCY : 0));
}
/* Called from IO context, or before _put() from main context */
void pa_sink_set_rtpoll(pa_sink *s, pa_rtpoll *p) {
pa_sink_assert_ref(s);
pa_sink_assert_io_context(s);
s->thread_info.rtpoll = p;
if (s->monitor_source)
pa_source_set_rtpoll(s->monitor_source, p);
}
/* Called from main context */
int pa_sink_update_status(pa_sink*s) {
pa_sink_assert_ref(s);
pa_assert_ctl_context();
pa_assert(PA_SINK_IS_LINKED(s->state));
if (s->state == PA_SINK_SUSPENDED)
return 0;
return sink_set_state(s, pa_sink_used_by(s) ? PA_SINK_RUNNING : PA_SINK_IDLE);
}
/* Called from any context - must be threadsafe */
void pa_sink_set_mixer_dirty(pa_sink *s, pa_bool_t is_dirty)
{
pa_atomic_store(&s->mixer_dirty, is_dirty ? 1 : 0);
}
/* Called from main context */
int pa_sink_suspend(pa_sink *s, pa_bool_t suspend, pa_suspend_cause_t cause) {
pa_sink_assert_ref(s);
pa_assert_ctl_context();
pa_assert(PA_SINK_IS_LINKED(s->state));
pa_assert(cause != 0);
if (suspend) {
s->suspend_cause |= cause;
s->monitor_source->suspend_cause |= cause;
} else {
s->suspend_cause &= ~cause;
s->monitor_source->suspend_cause &= ~cause;
}
if (!(s->suspend_cause & PA_SUSPEND_SESSION) && (pa_atomic_load(&s->mixer_dirty) != 0)) {
/* This might look racy but isn't: If somebody sets mixer_dirty exactly here,
it'll be handled just fine. */
pa_sink_set_mixer_dirty(s, FALSE);
pa_log_debug("Mixer is now accessible. Updating alsa mixer settings.");
if (s->active_port && s->set_port) {
if (s->flags & PA_SINK_DEFERRED_VOLUME) {
struct sink_message_set_port msg = { .port = s->active_port, .ret = 0 };
pa_assert_se(pa_asyncmsgq_send(s->asyncmsgq, PA_MSGOBJECT(s), PA_SINK_MESSAGE_SET_PORT, &msg, 0, NULL) == 0);
}
else
s->set_port(s, s->active_port);
}
else {
if (s->set_mute)
s->set_mute(s);
if (s->set_volume)
s->set_volume(s);
}
}
if ((pa_sink_get_state(s) == PA_SINK_SUSPENDED) == !!s->suspend_cause)
return 0;
pa_log_debug("Suspend cause of sink %s is 0x%04x, %s", s->name, s->suspend_cause, s->suspend_cause ? "suspending" : "resuming");
if (s->suspend_cause)
return sink_set_state(s, PA_SINK_SUSPENDED);
else
return sink_set_state(s, pa_sink_used_by(s) ? PA_SINK_RUNNING : PA_SINK_IDLE);
}
/* Called from main context */
pa_queue *pa_sink_move_all_start(pa_sink *s, pa_queue *q) {
pa_sink_input *i, *n;
uint32_t idx;
pa_sink_assert_ref(s);
pa_assert_ctl_context();
pa_assert(PA_SINK_IS_LINKED(s->state));
if (!q)
q = pa_queue_new();
for (i = PA_SINK_INPUT(pa_idxset_first(s->inputs, &idx)); i; i = n) {
n = PA_SINK_INPUT(pa_idxset_next(s->inputs, &idx));
pa_sink_input_ref(i);
if (pa_sink_input_start_move(i) >= 0)
pa_queue_push(q, i);
else
pa_sink_input_unref(i);
}
return q;
}
/* Called from main context */
void pa_sink_move_all_finish(pa_sink *s, pa_queue *q, pa_bool_t save) {
pa_sink_input *i;
pa_sink_assert_ref(s);
pa_assert_ctl_context();
pa_assert(PA_SINK_IS_LINKED(s->state));
pa_assert(q);
while ((i = PA_SINK_INPUT(pa_queue_pop(q)))) {
if (pa_sink_input_finish_move(i, s, save) < 0)
pa_sink_input_fail_move(i);
pa_sink_input_unref(i);
}
pa_queue_free(q, NULL);
}
/* Called from main context */
void pa_sink_move_all_fail(pa_queue *q) {
pa_sink_input *i;
pa_assert_ctl_context();
pa_assert(q);
while ((i = PA_SINK_INPUT(pa_queue_pop(q)))) {
pa_sink_input_fail_move(i);
pa_sink_input_unref(i);
}
pa_queue_free(q, NULL);
}
/* Called from IO thread context */
void pa_sink_process_rewind(pa_sink *s, size_t nbytes) {
pa_sink_input *i;
void *state = NULL;
pa_sink_assert_ref(s);
pa_sink_assert_io_context(s);
pa_assert(PA_SINK_IS_LINKED(s->thread_info.state));
/* If nobody requested this and this is actually no real rewind
* then we can short cut this. Please note that this means that
* not all rewind requests triggered upstream will always be
* translated in actual requests! */
if (!s->thread_info.rewind_requested && nbytes <= 0)
return;
s->thread_info.rewind_nbytes = 0;
s->thread_info.rewind_requested = FALSE;
if (s->thread_info.state == PA_SINK_SUSPENDED)
return;
if (nbytes > 0) {
pa_log_debug("Processing rewind...");
if (s->flags & PA_SINK_DEFERRED_VOLUME)
pa_sink_volume_change_rewind(s, nbytes);
}
PA_HASHMAP_FOREACH(i, s->thread_info.inputs, state) {
pa_sink_input_assert_ref(i);
pa_sink_input_process_rewind(i, nbytes);
}
if (nbytes > 0) {
if (s->monitor_source && PA_SOURCE_IS_LINKED(s->monitor_source->thread_info.state))
pa_source_process_rewind(s->monitor_source, nbytes);
}
}
/* Called from IO thread context */
static unsigned fill_mix_info(pa_sink *s, size_t *length, pa_mix_info *info, unsigned maxinfo) {
pa_sink_input *i;
unsigned n = 0;
void *state = NULL;
size_t mixlength = *length;
pa_sink_assert_ref(s);
pa_sink_assert_io_context(s);
pa_assert(info);
while ((i = pa_hashmap_iterate(s->thread_info.inputs, &state, NULL)) && maxinfo > 0) {
pa_sink_input_assert_ref(i);
pa_sink_input_peek(i, *length, &info->chunk, &info->volume);
if (mixlength == 0 || info->chunk.length < mixlength)
mixlength = info->chunk.length;
if (pa_memblock_is_silence(info->chunk.memblock)) {
pa_memblock_unref(info->chunk.memblock);
continue;
}
info->userdata = pa_sink_input_ref(i);
pa_assert(info->chunk.memblock);
pa_assert(info->chunk.length > 0);
info++;
n++;
maxinfo--;
}
if (mixlength > 0)
*length = mixlength;
return n;
}
/* Called from IO thread context */
static void inputs_drop(pa_sink *s, pa_mix_info *info, unsigned n, pa_memchunk *result) {
pa_sink_input *i;
void *state;
unsigned p = 0;
unsigned n_unreffed = 0;
pa_sink_assert_ref(s);
pa_sink_assert_io_context(s);
pa_assert(result);
pa_assert(result->memblock);
pa_assert(result->length > 0);
/* We optimize for the case where the order of the inputs has not changed */
PA_HASHMAP_FOREACH(i, s->thread_info.inputs, state) {
unsigned j;
pa_mix_info* m = NULL;
pa_sink_input_assert_ref(i);
/* Let's try to find the matching entry info the pa_mix_info array */
for (j = 0; j < n; j ++) {
if (info[p].userdata == i) {
m = info + p;
break;
}
p++;
if (p >= n)
p = 0;
}
/* Drop read data */
pa_sink_input_drop(i, result->length);
if (s->monitor_source && PA_SOURCE_IS_LINKED(s->monitor_source->thread_info.state)) {
if (pa_hashmap_size(i->thread_info.direct_outputs) > 0) {
void *ostate = NULL;
pa_source_output *o;
pa_memchunk c;
if (m && m->chunk.memblock) {
c = m->chunk;
pa_memblock_ref(c.memblock);
pa_assert(result->length <= c.length);
c.length = result->length;
pa_memchunk_make_writable(&c, 0);
pa_volume_memchunk(&c, &s->sample_spec, &m->volume);
} else {
c = s->silence;
pa_memblock_ref(c.memblock);
pa_assert(result->length <= c.length);
c.length = result->length;
}
while ((o = pa_hashmap_iterate(i->thread_info.direct_outputs, &ostate, NULL))) {
pa_source_output_assert_ref(o);
pa_assert(o->direct_on_input == i);
pa_source_post_direct(s->monitor_source, o, &c);
}
pa_memblock_unref(c.memblock);
}
}
if (m) {
if (m->chunk.memblock)
pa_memblock_unref(m->chunk.memblock);
pa_memchunk_reset(&m->chunk);
pa_sink_input_unref(m->userdata);
m->userdata = NULL;
n_unreffed += 1;
}
}
/* Now drop references to entries that are included in the
* pa_mix_info array but don't exist anymore */
if (n_unreffed < n) {
for (; n > 0; info++, n--) {
if (info->userdata)
pa_sink_input_unref(info->userdata);
if (info->chunk.memblock)
pa_memblock_unref(info->chunk.memblock);
}
}
if (s->monitor_source && PA_SOURCE_IS_LINKED(s->monitor_source->thread_info.state))
pa_source_post(s->monitor_source, result);
}
/* Called from IO thread context */
void pa_sink_render(pa_sink*s, size_t length, pa_memchunk *result) {
pa_mix_info info[MAX_MIX_CHANNELS];
unsigned n;
size_t block_size_max;
pa_sink_assert_ref(s);
pa_sink_assert_io_context(s);
pa_assert(PA_SINK_IS_LINKED(s->thread_info.state));
pa_assert(pa_frame_aligned(length, &s->sample_spec));
pa_assert(result);
pa_assert(!s->thread_info.rewind_requested);
pa_assert(s->thread_info.rewind_nbytes == 0);
if (s->thread_info.state == PA_SINK_SUSPENDED) {
result->memblock = pa_memblock_ref(s->silence.memblock);
result->index = s->silence.index;
result->length = PA_MIN(s->silence.length, length);
return;
}
pa_sink_ref(s);
if (length <= 0)
length = pa_frame_align(MIX_BUFFER_LENGTH, &s->sample_spec);
block_size_max = pa_mempool_block_size_max(s->core->mempool);
if (length > block_size_max)
length = pa_frame_align(block_size_max, &s->sample_spec);
pa_assert(length > 0);
n = fill_mix_info(s, &length, info, MAX_MIX_CHANNELS);
if (n == 0) {
*result = s->silence;
pa_memblock_ref(result->memblock);
if (result->length > length)
result->length = length;
} else if (n == 1) {
pa_cvolume volume;
*result = info[0].chunk;
pa_memblock_ref(result->memblock);
if (result->length > length)
result->length = length;
pa_sw_cvolume_multiply(&volume, &s->thread_info.soft_volume, &info[0].volume);
if (s->thread_info.soft_muted || pa_cvolume_is_muted(&volume)) {
pa_memblock_unref(result->memblock);
pa_silence_memchunk_get(&s->core->silence_cache,
s->core->mempool,
result,
&s->sample_spec,
result->length);
} else if (!pa_cvolume_is_norm(&volume)) {
pa_memchunk_make_writable(result, 0);
pa_volume_memchunk(result, &s->sample_spec, &volume);
}
} else {
void *ptr;
result->memblock = pa_memblock_new(s->core->mempool, length);
ptr = pa_memblock_acquire(result->memblock);
result->length = pa_mix(info, n,
ptr, length,
&s->sample_spec,
&s->thread_info.soft_volume,
s->thread_info.soft_muted);
pa_memblock_release(result->memblock);
result->index = 0;
}
inputs_drop(s, info, n, result);
pa_sink_unref(s);
}
/* Called from IO thread context */
void pa_sink_render_into(pa_sink*s, pa_memchunk *target) {
pa_mix_info info[MAX_MIX_CHANNELS];
unsigned n;
size_t length, block_size_max;
pa_sink_assert_ref(s);
pa_sink_assert_io_context(s);
pa_assert(PA_SINK_IS_LINKED(s->thread_info.state));
pa_assert(target);
pa_assert(target->memblock);
pa_assert(target->length > 0);
pa_assert(pa_frame_aligned(target->length, &s->sample_spec));
pa_assert(!s->thread_info.rewind_requested);
pa_assert(s->thread_info.rewind_nbytes == 0);
if (s->thread_info.state == PA_SINK_SUSPENDED) {
pa_silence_memchunk(target, &s->sample_spec);
return;
}
pa_sink_ref(s);
length = target->length;
block_size_max = pa_mempool_block_size_max(s->core->mempool);
if (length > block_size_max)
length = pa_frame_align(block_size_max, &s->sample_spec);
pa_assert(length > 0);
n = fill_mix_info(s, &length, info, MAX_MIX_CHANNELS);
if (n == 0) {
if (target->length > length)
target->length = length;
pa_silence_memchunk(target, &s->sample_spec);
} else if (n == 1) {
pa_cvolume volume;
if (target->length > length)
target->length = length;
pa_sw_cvolume_multiply(&volume, &s->thread_info.soft_volume, &info[0].volume);
if (s->thread_info.soft_muted || pa_cvolume_is_muted(&volume))
pa_silence_memchunk(target, &s->sample_spec);
else {
pa_memchunk vchunk;
vchunk = info[0].chunk;
pa_memblock_ref(vchunk.memblock);
if (vchunk.length > length)
vchunk.length = length;
if (!pa_cvolume_is_norm(&volume)) {
pa_memchunk_make_writable(&vchunk, 0);
pa_volume_memchunk(&vchunk, &s->sample_spec, &volume);
}
pa_memchunk_memcpy(target, &vchunk);
pa_memblock_unref(vchunk.memblock);
}
} else {
void *ptr;
ptr = pa_memblock_acquire(target->memblock);
target->length = pa_mix(info, n,
(uint8_t*) ptr + target->index, length,
&s->sample_spec,
&s->thread_info.soft_volume,
s->thread_info.soft_muted);
pa_memblock_release(target->memblock);
}
inputs_drop(s, info, n, target);
pa_sink_unref(s);
}
/* Called from IO thread context */
void pa_sink_render_into_full(pa_sink *s, pa_memchunk *target) {
pa_memchunk chunk;
size_t l, d;
pa_sink_assert_ref(s);
pa_sink_assert_io_context(s);
pa_assert(PA_SINK_IS_LINKED(s->thread_info.state));
pa_assert(target);
pa_assert(target->memblock);
pa_assert(target->length > 0);
pa_assert(pa_frame_aligned(target->length, &s->sample_spec));
pa_assert(!s->thread_info.rewind_requested);
pa_assert(s->thread_info.rewind_nbytes == 0);
if (s->thread_info.state == PA_SINK_SUSPENDED) {
pa_silence_memchunk(target, &s->sample_spec);
return;
}
pa_sink_ref(s);
l = target->length;
d = 0;
while (l > 0) {
chunk = *target;
chunk.index += d;
chunk.length -= d;
pa_sink_render_into(s, &chunk);
d += chunk.length;
l -= chunk.length;
}
pa_sink_unref(s);
}
/* Called from IO thread context */
void pa_sink_render_full(pa_sink *s, size_t length, pa_memchunk *result) {
pa_sink_assert_ref(s);
pa_sink_assert_io_context(s);
pa_assert(PA_SINK_IS_LINKED(s->thread_info.state));
pa_assert(length > 0);
pa_assert(pa_frame_aligned(length, &s->sample_spec));
pa_assert(result);
pa_assert(!s->thread_info.rewind_requested);
pa_assert(s->thread_info.rewind_nbytes == 0);
pa_sink_ref(s);
pa_sink_render(s, length, result);
if (result->length < length) {
pa_memchunk chunk;
pa_memchunk_make_writable(result, length);
chunk.memblock = result->memblock;
chunk.index = result->index + result->length;
chunk.length = length - result->length;
pa_sink_render_into_full(s, &chunk);
result->length = length;
}
pa_sink_unref(s);
}
/* Called from main thread */
pa_bool_t pa_sink_update_rate(pa_sink *s, uint32_t rate, pa_bool_t passthrough)
{
if (s->update_rate) {
uint32_t desired_rate = rate;
uint32_t default_rate = s->default_sample_rate;
uint32_t alternate_rate = s->alternate_sample_rate;
uint32_t idx;
pa_sink_input *i;
pa_bool_t use_alternate = FALSE;
if (PA_UNLIKELY(default_rate == alternate_rate)) {
pa_log_warn("Default and alternate sample rates are the same.");
return FALSE;
}
if (PA_SINK_IS_RUNNING(s->state)) {
pa_log_info("Cannot update rate, SINK_IS_RUNNING, will keep using %u Hz",
s->sample_spec.rate);
return FALSE;
}
if (s->monitor_source) {
if (PA_SOURCE_IS_RUNNING(s->monitor_source->state) == TRUE) {
pa_log_info("Cannot update rate, monitor source is RUNNING");
return FALSE;
}
}
if (PA_UNLIKELY (desired_rate < 8000 ||
desired_rate > PA_RATE_MAX))
return FALSE;
if (!passthrough) {
pa_assert(default_rate % 4000 || default_rate % 11025);
pa_assert(alternate_rate % 4000 || alternate_rate % 11025);
if (default_rate % 4000) {
/* default is a 11025 multiple */
if ((alternate_rate % 4000 == 0) && (desired_rate % 4000 == 0))
use_alternate=TRUE;
} else {
/* default is 4000 multiple */
if ((alternate_rate % 11025 == 0) && (desired_rate % 11025 == 0))
use_alternate=TRUE;
}
if (use_alternate)
desired_rate = alternate_rate;
else
desired_rate = default_rate;
} else {
desired_rate = rate; /* use stream sampling rate, discard default/alternate settings */
}
if (!passthrough && pa_sink_used_by(s) > 0)
return FALSE;
pa_sink_suspend(s, TRUE, PA_SUSPEND_IDLE); /* needed before rate update, will be resumed automatically */
if (s->update_rate(s, desired_rate) == TRUE) {
/* update monitor source as well */
if (s->monitor_source && !passthrough)
pa_source_update_rate(s->monitor_source, desired_rate, FALSE);
pa_log_info("Changed sampling rate successfully");
PA_IDXSET_FOREACH(i, s->inputs, idx) {
if (i->state == PA_SINK_INPUT_CORKED)
pa_sink_input_update_rate(i);
}
return TRUE;
}
}
return FALSE;
}
/* Called from main thread */
pa_usec_t pa_sink_get_latency(pa_sink *s) {
pa_usec_t usec = 0;
pa_sink_assert_ref(s);
pa_assert_ctl_context();
pa_assert(PA_SINK_IS_LINKED(s->state));
/* The returned value is supposed to be in the time domain of the sound card! */
if (s->state == PA_SINK_SUSPENDED)
return 0;
if (!(s->flags & PA_SINK_LATENCY))
return 0;
pa_assert_se(pa_asyncmsgq_send(s->asyncmsgq, PA_MSGOBJECT(s), PA_SINK_MESSAGE_GET_LATENCY, &usec, 0, NULL) == 0);
return usec;
}
/* Called from IO thread */
pa_usec_t pa_sink_get_latency_within_thread(pa_sink *s) {
pa_usec_t usec = 0;
pa_msgobject *o;
pa_sink_assert_ref(s);
pa_sink_assert_io_context(s);
pa_assert(PA_SINK_IS_LINKED(s->thread_info.state));
/* The returned value is supposed to be in the time domain of the sound card! */
if (s->thread_info.state == PA_SINK_SUSPENDED)
return 0;
if (!(s->flags & PA_SINK_LATENCY))
return 0;
o = PA_MSGOBJECT(s);
/* FIXME: We probably should make this a proper vtable callback instead of going through process_msg() */
if (o->process_msg(o, PA_SINK_MESSAGE_GET_LATENCY, &usec, 0, NULL) < 0)
return -1;
return usec;
}
/* Called from the main thread (and also from the IO thread while the main
* thread is waiting).
*
* When a sink uses volume sharing, it never has the PA_SINK_FLAT_VOLUME flag
* set. Instead, flat volume mode is detected by checking whether the root sink
* has the flag set. */
pa_bool_t pa_sink_flat_volume_enabled(pa_sink *s) {
pa_sink_assert_ref(s);
s = pa_sink_get_master(s);
if (PA_LIKELY(s))
return (s->flags & PA_SINK_FLAT_VOLUME);
else
return FALSE;
}
/* Called from the main thread (and also from the IO thread while the main
* thread is waiting). */
pa_sink *pa_sink_get_master(pa_sink *s) {
pa_sink_assert_ref(s);
while (s && (s->flags & PA_SINK_SHARE_VOLUME_WITH_MASTER)) {
if (PA_UNLIKELY(!s->input_to_master))
return NULL;
s = s->input_to_master->sink;
}
return s;
}
/* Called from main context */
pa_bool_t pa_sink_is_passthrough(pa_sink *s) {
pa_sink_input *alt_i;
uint32_t idx;
pa_sink_assert_ref(s);
/* one and only one PASSTHROUGH input can possibly be connected */
if (pa_idxset_size(s->inputs) == 1) {
alt_i = pa_idxset_first(s->inputs, &idx);
if (pa_sink_input_is_passthrough(alt_i))
return TRUE;
}
return FALSE;
}
/* Called from main context */
void pa_sink_enter_passthrough(pa_sink *s) {
pa_cvolume volume;
/* disable the monitor in passthrough mode */
if (s->monitor_source)
pa_source_suspend(s->monitor_source, TRUE, PA_SUSPEND_PASSTHROUGH);
/* set the volume to NORM */
s->saved_volume = *pa_sink_get_volume(s, TRUE);
s->saved_save_volume = s->save_volume;
pa_cvolume_set(&volume, s->sample_spec.channels, PA_MIN(s->base_volume, PA_VOLUME_NORM));
pa_sink_set_volume(s, &volume, TRUE, FALSE);
}
/* Called from main context */
void pa_sink_leave_passthrough(pa_sink *s) {
/* Unsuspend monitor */
if (s->monitor_source)
pa_source_suspend(s->monitor_source, FALSE, PA_SUSPEND_PASSTHROUGH);
/* Restore sink volume to what it was before we entered passthrough mode */
pa_sink_set_volume(s, &s->saved_volume, TRUE, s->saved_save_volume);
pa_cvolume_init(&s->saved_volume);
s->saved_save_volume = FALSE;
}
/* Called from main context. */
static void compute_reference_ratio(pa_sink_input *i) {
unsigned c = 0;
pa_cvolume remapped;
pa_assert(i);
pa_assert(pa_sink_flat_volume_enabled(i->sink));
/*
* Calculates the reference ratio from the sink's reference
* volume. This basically calculates:
*
* i->reference_ratio = i->volume / i->sink->reference_volume
*/
remapped = i->sink->reference_volume;
pa_cvolume_remap(&remapped, &i->sink->channel_map, &i->channel_map);
i->reference_ratio.channels = i->sample_spec.channels;
for (c = 0; c < i->sample_spec.channels; c++) {
/* We don't update when the sink volume is 0 anyway */
if (remapped.values[c] <= PA_VOLUME_MUTED)
continue;
/* Don't update the reference ratio unless necessary */
if (pa_sw_volume_multiply(
i->reference_ratio.values[c],
remapped.values[c]) == i->volume.values[c])
continue;
i->reference_ratio.values[c] = pa_sw_volume_divide(
i->volume.values[c],
remapped.values[c]);
}
}
/* Called from main context. Only called for the root sink in volume sharing
* cases, except for internal recursive calls. */
static void compute_reference_ratios(pa_sink *s) {
uint32_t idx;
pa_sink_input *i;
pa_sink_assert_ref(s);
pa_assert_ctl_context();
pa_assert(PA_SINK_IS_LINKED(s->state));
pa_assert(pa_sink_flat_volume_enabled(s));
PA_IDXSET_FOREACH(i, s->inputs, idx) {
compute_reference_ratio(i);
if (i->origin_sink && (i->origin_sink->flags & PA_SINK_SHARE_VOLUME_WITH_MASTER))
compute_reference_ratios(i->origin_sink);
}
}
/* Called from main context. Only called for the root sink in volume sharing
* cases, except for internal recursive calls. */
static void compute_real_ratios(pa_sink *s) {
pa_sink_input *i;
uint32_t idx;
pa_sink_assert_ref(s);
pa_assert_ctl_context();
pa_assert(PA_SINK_IS_LINKED(s->state));
pa_assert(pa_sink_flat_volume_enabled(s));
PA_IDXSET_FOREACH(i, s->inputs, idx) {
unsigned c;
pa_cvolume remapped;
if (i->origin_sink && (i->origin_sink->flags & PA_SINK_SHARE_VOLUME_WITH_MASTER)) {
/* The origin sink uses volume sharing, so this input's real ratio
* is handled as a special case - the real ratio must be 0 dB, and
* as a result i->soft_volume must equal i->volume_factor. */
pa_cvolume_reset(&i->real_ratio, i->real_ratio.channels);
i->soft_volume = i->volume_factor;
compute_real_ratios(i->origin_sink);
continue;
}
/*
* This basically calculates:
*
* i->real_ratio := i->volume / s->real_volume
* i->soft_volume := i->real_ratio * i->volume_factor
*/
remapped = s->real_volume;
pa_cvolume_remap(&remapped, &s->channel_map, &i->channel_map);
i->real_ratio.channels = i->sample_spec.channels;
i->soft_volume.channels = i->sample_spec.channels;
for (c = 0; c < i->sample_spec.channels; c++) {
if (remapped.values[c] <= PA_VOLUME_MUTED) {
/* We leave i->real_ratio untouched */
i->soft_volume.values[c] = PA_VOLUME_MUTED;
continue;
}
/* Don't lose accuracy unless necessary */
if (pa_sw_volume_multiply(
i->real_ratio.values[c],
remapped.values[c]) != i->volume.values[c])
i->real_ratio.values[c] = pa_sw_volume_divide(
i->volume.values[c],
remapped.values[c]);
i->soft_volume.values[c] = pa_sw_volume_multiply(
i->real_ratio.values[c],
i->volume_factor.values[c]);
}
/* We don't copy the soft_volume to the thread_info data
* here. That must be done by the caller */
}
}
static pa_cvolume *cvolume_remap_minimal_impact(
pa_cvolume *v,
const pa_cvolume *template,
const pa_channel_map *from,
const pa_channel_map *to) {
pa_cvolume t;
pa_assert(v);
pa_assert(template);
pa_assert(from);
pa_assert(to);
pa_assert(pa_cvolume_compatible_with_channel_map(v, from));
pa_assert(pa_cvolume_compatible_with_channel_map(template, to));
/* Much like pa_cvolume_remap(), but tries to minimize impact when
* mapping from sink input to sink volumes:
*
* If template is a possible remapping from v it is used instead
* of remapping anew.
*
* If the channel maps don't match we set an all-channel volume on
* the sink to ensure that changing a volume on one stream has no
* effect that cannot be compensated for in another stream that
* does not have the same channel map as the sink. */
if (pa_channel_map_equal(from, to))
return v;
t = *template;
if (pa_cvolume_equal(pa_cvolume_remap(&t, to, from), v)) {
*v = *template;
return v;
}
pa_cvolume_set(v, to->channels, pa_cvolume_max(v));
return v;
}
/* Called from main thread. Only called for the root sink in volume sharing
* cases, except for internal recursive calls. */
static void get_maximum_input_volume(pa_sink *s, pa_cvolume *max_volume, const pa_channel_map *channel_map) {
pa_sink_input *i;
uint32_t idx;
pa_sink_assert_ref(s);
pa_assert(max_volume);
pa_assert(channel_map);
pa_assert(pa_sink_flat_volume_enabled(s));
PA_IDXSET_FOREACH(i, s->inputs, idx) {
pa_cvolume remapped;
if (i->origin_sink && (i->origin_sink->flags & PA_SINK_SHARE_VOLUME_WITH_MASTER)) {
get_maximum_input_volume(i->origin_sink, max_volume, channel_map);
/* Ignore this input. The origin sink uses volume sharing, so this
* input's volume will be set to be equal to the root sink's real
* volume. Obviously this input's current volume must not then
* affect what the root sink's real volume will be. */
continue;
}
remapped = i->volume;
cvolume_remap_minimal_impact(&remapped, max_volume, &i->channel_map, channel_map);
pa_cvolume_merge(max_volume, max_volume, &remapped);
}
}
/* Called from main thread. Only called for the root sink in volume sharing
* cases, except for internal recursive calls. */
static pa_bool_t has_inputs(pa_sink *s) {
pa_sink_input *i;
uint32_t idx;
pa_sink_assert_ref(s);
PA_IDXSET_FOREACH(i, s->inputs, idx) {
if (!i->origin_sink || !(i->origin_sink->flags & PA_SINK_SHARE_VOLUME_WITH_MASTER) || has_inputs(i->origin_sink))
return TRUE;
}
return FALSE;
}
/* Called from main thread. Only called for the root sink in volume sharing
* cases, except for internal recursive calls. */
static void update_real_volume(pa_sink *s, const pa_cvolume *new_volume, pa_channel_map *channel_map) {
pa_sink_input *i;
uint32_t idx;
pa_sink_assert_ref(s);
pa_assert(new_volume);
pa_assert(channel_map);
s->real_volume = *new_volume;
pa_cvolume_remap(&s->real_volume, channel_map, &s->channel_map);
PA_IDXSET_FOREACH(i, s->inputs, idx) {
if (i->origin_sink && (i->origin_sink->flags & PA_SINK_SHARE_VOLUME_WITH_MASTER)) {
if (pa_sink_flat_volume_enabled(s)) {
pa_cvolume old_volume = i->volume;
/* Follow the root sink's real volume. */
i->volume = *new_volume;
pa_cvolume_remap(&i->volume, channel_map, &i->channel_map);
compute_reference_ratio(i);
/* The volume changed, let's tell people so */
if (!pa_cvolume_equal(&old_volume, &i->volume)) {
if (i->volume_changed)
i->volume_changed(i);
pa_subscription_post(i->core, PA_SUBSCRIPTION_EVENT_SINK_INPUT|PA_SUBSCRIPTION_EVENT_CHANGE, i->index);
}
}
update_real_volume(i->origin_sink, new_volume, channel_map);
}
}
}
/* Called from main thread. Only called for the root sink in shared volume
* cases. */
static void compute_real_volume(pa_sink *s) {
pa_sink_assert_ref(s);
pa_assert_ctl_context();
pa_assert(PA_SINK_IS_LINKED(s->state));
pa_assert(pa_sink_flat_volume_enabled(s));
pa_assert(!(s->flags & PA_SINK_SHARE_VOLUME_WITH_MASTER));
/* This determines the maximum volume of all streams and sets
* s->real_volume accordingly. */
if (!has_inputs(s)) {
/* In the special case that we have no sink inputs we leave the
* volume unmodified. */
update_real_volume(s, &s->reference_volume, &s->channel_map);
return;
}
pa_cvolume_mute(&s->real_volume, s->channel_map.channels);
/* First let's determine the new maximum volume of all inputs
* connected to this sink */
get_maximum_input_volume(s, &s->real_volume, &s->channel_map);
update_real_volume(s, &s->real_volume, &s->channel_map);
/* Then, let's update the real ratios/soft volumes of all inputs
* connected to this sink */
compute_real_ratios(s);
}
/* Called from main thread. Only called for the root sink in shared volume
* cases, except for internal recursive calls. */
static void propagate_reference_volume(pa_sink *s) {
pa_sink_input *i;
uint32_t idx;
pa_sink_assert_ref(s);
pa_assert_ctl_context();
pa_assert(PA_SINK_IS_LINKED(s->state));
pa_assert(pa_sink_flat_volume_enabled(s));
/* This is called whenever the sink volume changes that is not
* caused by a sink input volume change. We need to fix up the
* sink input volumes accordingly */
PA_IDXSET_FOREACH(i, s->inputs, idx) {
pa_cvolume old_volume;
if (i->origin_sink && (i->origin_sink->flags & PA_SINK_SHARE_VOLUME_WITH_MASTER)) {
propagate_reference_volume(i->origin_sink);
/* Since the origin sink uses volume sharing, this input's volume
* needs to be updated to match the root sink's real volume, but
* that will be done later in update_shared_real_volume(). */
continue;
}
old_volume = i->volume;
/* This basically calculates:
*
* i->volume := s->reference_volume * i->reference_ratio */
i->volume = s->reference_volume;
pa_cvolume_remap(&i->volume, &s->channel_map, &i->channel_map);
pa_sw_cvolume_multiply(&i->volume, &i->volume, &i->reference_ratio);
/* The volume changed, let's tell people so */
if (!pa_cvolume_equal(&old_volume, &i->volume)) {
if (i->volume_changed)
i->volume_changed(i);
pa_subscription_post(i->core, PA_SUBSCRIPTION_EVENT_SINK_INPUT|PA_SUBSCRIPTION_EVENT_CHANGE, i->index);
}
}
}
/* Called from main thread. Only called for the root sink in volume sharing
* cases, except for internal recursive calls. The return value indicates
* whether any reference volume actually changed. */
static pa_bool_t update_reference_volume(pa_sink *s, const pa_cvolume *v, const pa_channel_map *channel_map, pa_bool_t save) {
pa_cvolume volume;
pa_bool_t reference_volume_changed;
pa_sink_input *i;
uint32_t idx;
pa_sink_assert_ref(s);
pa_assert(PA_SINK_IS_LINKED(s->state));
pa_assert(v);
pa_assert(channel_map);
pa_assert(pa_cvolume_valid(v));
volume = *v;
pa_cvolume_remap(&volume, channel_map, &s->channel_map);
reference_volume_changed = !pa_cvolume_equal(&volume, &s->reference_volume);
s->reference_volume = volume;
s->save_volume = (!reference_volume_changed && s->save_volume) || save;
if (reference_volume_changed)
pa_subscription_post(s->core, PA_SUBSCRIPTION_EVENT_SINK|PA_SUBSCRIPTION_EVENT_CHANGE, s->index);
else if (!(s->flags & PA_SINK_SHARE_VOLUME_WITH_MASTER))
/* If the root sink's volume doesn't change, then there can't be any
* changes in the other sinks in the sink tree either.
*
* It's probably theoretically possible that even if the root sink's
* volume changes slightly, some filter sink doesn't change its volume
* due to rounding errors. If that happens, we still want to propagate
* the changed root sink volume to the sinks connected to the
* intermediate sink that didn't change its volume. This theoretical
* possibility is the reason why we have that !(s->flags &
* PA_SINK_SHARE_VOLUME_WITH_MASTER) condition. Probably nobody would
* notice even if we returned here FALSE always if
* reference_volume_changed is FALSE. */
return FALSE;
PA_IDXSET_FOREACH(i, s->inputs, idx) {
if (i->origin_sink && (i->origin_sink->flags & PA_SINK_SHARE_VOLUME_WITH_MASTER))
update_reference_volume(i->origin_sink, v, channel_map, FALSE);
}
return TRUE;
}
/* Called from main thread */
void pa_sink_set_volume(
pa_sink *s,
const pa_cvolume *volume,
pa_bool_t send_msg,
pa_bool_t save) {
pa_cvolume new_reference_volume;
pa_sink *root_sink;
pa_sink_assert_ref(s);
pa_assert_ctl_context();
pa_assert(PA_SINK_IS_LINKED(s->state));
pa_assert(!volume || pa_cvolume_valid(volume));
pa_assert(volume || pa_sink_flat_volume_enabled(s));
pa_assert(!volume || volume->channels == 1 || pa_cvolume_compatible(volume, &s->sample_spec));
/* make sure we don't change the volume when a PASSTHROUGH input is connected ...
* ... *except* if we're being invoked to reset the volume to ensure 0 dB gain */
if (pa_sink_is_passthrough(s) && (!volume || !pa_cvolume_is_norm(volume))) {
pa_log_warn("Cannot change volume, Sink is connected to PASSTHROUGH input");
return;
}
/* In case of volume sharing, the volume is set for the root sink first,
* from which it's then propagated to the sharing sinks. */
root_sink = pa_sink_get_master(s);
if (PA_UNLIKELY(!root_sink))
return;
/* As a special exception we accept mono volumes on all sinks --
* even on those with more complex channel maps */
if (volume) {
if (pa_cvolume_compatible(volume, &s->sample_spec))
new_reference_volume = *volume;
else {
new_reference_volume = s->reference_volume;
pa_cvolume_scale(&new_reference_volume, pa_cvolume_max(volume));
}
pa_cvolume_remap(&new_reference_volume, &s->channel_map, &root_sink->channel_map);
if (update_reference_volume(root_sink, &new_reference_volume, &root_sink->channel_map, save)) {
if (pa_sink_flat_volume_enabled(root_sink)) {
/* OK, propagate this volume change back to the inputs */
propagate_reference_volume(root_sink);
/* And now recalculate the real volume */
compute_real_volume(root_sink);
} else
update_real_volume(root_sink, &root_sink->reference_volume, &root_sink->channel_map);
}
} else {
/* If volume is NULL we synchronize the sink's real and
* reference volumes with the stream volumes. */
pa_assert(pa_sink_flat_volume_enabled(root_sink));
/* Ok, let's determine the new real volume */
compute_real_volume(root_sink);
/* Let's 'push' the reference volume if necessary */
pa_cvolume_merge(&new_reference_volume, &s->reference_volume, &root_sink->real_volume);
/* If the sink and it's root don't have the same number of channels, we need to remap */
if (s != root_sink && !pa_channel_map_equal(&s->channel_map, &root_sink->channel_map))
pa_cvolume_remap(&new_reference_volume, &s->channel_map, &root_sink->channel_map);
update_reference_volume(root_sink, &new_reference_volume, &root_sink->channel_map, save);
/* Now that the reference volume is updated, we can update the streams'
* reference ratios. */
compute_reference_ratios(root_sink);
}
if (root_sink->set_volume) {
/* If we have a function set_volume(), then we do not apply a
* soft volume by default. However, set_volume() is free to
* apply one to root_sink->soft_volume */
pa_cvolume_reset(&root_sink->soft_volume, root_sink->sample_spec.channels);
if (!(root_sink->flags & PA_SINK_DEFERRED_VOLUME))
root_sink->set_volume(root_sink);
} else
/* If we have no function set_volume(), then the soft volume
* becomes the real volume */
root_sink->soft_volume = root_sink->real_volume;
/* This tells the sink that soft volume and/or real volume changed */
if (send_msg)
pa_assert_se(pa_asyncmsgq_send(root_sink->asyncmsgq, PA_MSGOBJECT(root_sink), PA_SINK_MESSAGE_SET_SHARED_VOLUME, NULL, 0, NULL) == 0);
}
/* Called from the io thread if sync volume is used, otherwise from the main thread.
* Only to be called by sink implementor */
void pa_sink_set_soft_volume(pa_sink *s, const pa_cvolume *volume) {
pa_sink_assert_ref(s);
pa_assert(!(s->flags & PA_SINK_SHARE_VOLUME_WITH_MASTER));
if (s->flags & PA_SINK_DEFERRED_VOLUME)
pa_sink_assert_io_context(s);
else
pa_assert_ctl_context();
if (!volume)
pa_cvolume_reset(&s->soft_volume, s->sample_spec.channels);
else
s->soft_volume = *volume;
if (PA_SINK_IS_LINKED(s->state) && !(s->flags & PA_SINK_DEFERRED_VOLUME))
pa_assert_se(pa_asyncmsgq_send(s->asyncmsgq, PA_MSGOBJECT(s), PA_SINK_MESSAGE_SET_VOLUME, NULL, 0, NULL) == 0);
else
s->thread_info.soft_volume = s->soft_volume;
}
/* Called from the main thread. Only called for the root sink in volume sharing
* cases, except for internal recursive calls. */
static void propagate_real_volume(pa_sink *s, const pa_cvolume *old_real_volume) {
pa_sink_input *i;
uint32_t idx;
pa_sink_assert_ref(s);
pa_assert(old_real_volume);
pa_assert_ctl_context();
pa_assert(PA_SINK_IS_LINKED(s->state));
/* This is called when the hardware's real volume changes due to
* some external event. We copy the real volume into our
* reference volume and then rebuild the stream volumes based on
* i->real_ratio which should stay fixed. */
if (!(s->flags & PA_SINK_SHARE_VOLUME_WITH_MASTER)) {
if (pa_cvolume_equal(old_real_volume, &s->real_volume))
return;
/* 1. Make the real volume the reference volume */
update_reference_volume(s, &s->real_volume, &s->channel_map, TRUE);
}
if (pa_sink_flat_volume_enabled(s)) {
PA_IDXSET_FOREACH(i, s->inputs, idx) {
pa_cvolume old_volume = i->volume;
/* 2. Since the sink's reference and real volumes are equal
* now our ratios should be too. */
i->reference_ratio = i->real_ratio;
/* 3. Recalculate the new stream reference volume based on the
* reference ratio and the sink's reference volume.
*
* This basically calculates:
*
* i->volume = s->reference_volume * i->reference_ratio
*
* This is identical to propagate_reference_volume() */
i->volume = s->reference_volume;
pa_cvolume_remap(&i->volume, &s->channel_map, &i->channel_map);
pa_sw_cvolume_multiply(&i->volume, &i->volume, &i->reference_ratio);
/* Notify if something changed */
if (!pa_cvolume_equal(&old_volume, &i->volume)) {
if (i->volume_changed)
i->volume_changed(i);
pa_subscription_post(i->core, PA_SUBSCRIPTION_EVENT_SINK_INPUT|PA_SUBSCRIPTION_EVENT_CHANGE, i->index);
}
if (i->origin_sink && (i->origin_sink->flags & PA_SINK_SHARE_VOLUME_WITH_MASTER))
propagate_real_volume(i->origin_sink, old_real_volume);
}
}
/* Something got changed in the hardware. It probably makes sense
* to save changed hw settings given that hw volume changes not
* triggered by PA are almost certainly done by the user. */
if (!(s->flags & PA_SINK_SHARE_VOLUME_WITH_MASTER))
s->save_volume = TRUE;
}
/* Called from io thread */
void pa_sink_update_volume_and_mute(pa_sink *s) {
pa_assert(s);
pa_sink_assert_io_context(s);
pa_asyncmsgq_post(pa_thread_mq_get()->outq, PA_MSGOBJECT(s), PA_SINK_MESSAGE_UPDATE_VOLUME_AND_MUTE, NULL, 0, NULL, NULL);
}
/* Called from main thread */
const pa_cvolume *pa_sink_get_volume(pa_sink *s, pa_bool_t force_refresh) {
pa_sink_assert_ref(s);
pa_assert_ctl_context();
pa_assert(PA_SINK_IS_LINKED(s->state));
if (s->refresh_volume || force_refresh) {
struct pa_cvolume old_real_volume;
pa_assert(!(s->flags & PA_SINK_SHARE_VOLUME_WITH_MASTER));
old_real_volume = s->real_volume;
if (!(s->flags & PA_SINK_DEFERRED_VOLUME) && s->get_volume)
s->get_volume(s);
pa_assert_se(pa_asyncmsgq_send(s->asyncmsgq, PA_MSGOBJECT(s), PA_SINK_MESSAGE_GET_VOLUME, NULL, 0, NULL) == 0);
update_real_volume(s, &s->real_volume, &s->channel_map);
propagate_real_volume(s, &old_real_volume);
}
return &s->reference_volume;
}
/* Called from main thread. In volume sharing cases, only the root sink may
* call this. */
void pa_sink_volume_changed(pa_sink *s, const pa_cvolume *new_real_volume) {
pa_cvolume old_real_volume;
pa_sink_assert_ref(s);
pa_assert_ctl_context();
pa_assert(PA_SINK_IS_LINKED(s->state));
pa_assert(!(s->flags & PA_SINK_SHARE_VOLUME_WITH_MASTER));
/* The sink implementor may call this if the volume changed to make sure everyone is notified */
old_real_volume = s->real_volume;
update_real_volume(s, new_real_volume, &s->channel_map);
propagate_real_volume(s, &old_real_volume);
}
/* Called from main thread */
void pa_sink_set_mute(pa_sink *s, pa_bool_t mute, pa_bool_t save) {
pa_bool_t old_muted;
pa_sink_assert_ref(s);
pa_assert_ctl_context();
pa_assert(PA_SINK_IS_LINKED(s->state));
old_muted = s->muted;
s->muted = mute;
s->save_muted = (old_muted == s->muted && s->save_muted) || save;
if (!(s->flags & PA_SINK_DEFERRED_VOLUME) && s->set_mute)
s->set_mute(s);
pa_assert_se(pa_asyncmsgq_send(s->asyncmsgq, PA_MSGOBJECT(s), PA_SINK_MESSAGE_SET_MUTE, NULL, 0, NULL) == 0);
if (old_muted != s->muted)
pa_subscription_post(s->core, PA_SUBSCRIPTION_EVENT_SINK|PA_SUBSCRIPTION_EVENT_CHANGE, s->index);
}
/* Called from main thread */
pa_bool_t pa_sink_get_mute(pa_sink *s, pa_bool_t force_refresh) {
pa_sink_assert_ref(s);
pa_assert_ctl_context();
pa_assert(PA_SINK_IS_LINKED(s->state));
if (s->refresh_muted || force_refresh) {
pa_bool_t old_muted = s->muted;
if (!(s->flags & PA_SINK_DEFERRED_VOLUME) && s->get_mute)
s->get_mute(s);
pa_assert_se(pa_asyncmsgq_send(s->asyncmsgq, PA_MSGOBJECT(s), PA_SINK_MESSAGE_GET_MUTE, NULL, 0, NULL) == 0);
if (old_muted != s->muted) {
s->save_muted = TRUE;
pa_subscription_post(s->core, PA_SUBSCRIPTION_EVENT_SINK|PA_SUBSCRIPTION_EVENT_CHANGE, s->index);
/* Make sure the soft mute status stays in sync */
pa_assert_se(pa_asyncmsgq_send(s->asyncmsgq, PA_MSGOBJECT(s), PA_SINK_MESSAGE_SET_MUTE, NULL, 0, NULL) == 0);
}
}
return s->muted;
}
/* Called from main thread */
void pa_sink_mute_changed(pa_sink *s, pa_bool_t new_muted) {
pa_sink_assert_ref(s);
pa_assert_ctl_context();
pa_assert(PA_SINK_IS_LINKED(s->state));
/* The sink implementor may call this if the volume changed to make sure everyone is notified */
if (s->muted == new_muted)
return;
s->muted = new_muted;
s->save_muted = TRUE;
pa_subscription_post(s->core, PA_SUBSCRIPTION_EVENT_SINK|PA_SUBSCRIPTION_EVENT_CHANGE, s->index);
}
/* Called from main thread */
pa_bool_t pa_sink_update_proplist(pa_sink *s, pa_update_mode_t mode, pa_proplist *p) {
pa_sink_assert_ref(s);
pa_assert_ctl_context();
if (p)
pa_proplist_update(s->proplist, mode, p);
if (PA_SINK_IS_LINKED(s->state)) {
pa_hook_fire(&s->core->hooks[PA_CORE_HOOK_SINK_PROPLIST_CHANGED], s);
pa_subscription_post(s->core, PA_SUBSCRIPTION_EVENT_SINK|PA_SUBSCRIPTION_EVENT_CHANGE, s->index);
}
return TRUE;
}
/* Called from main thread */
/* FIXME -- this should be dropped and be merged into pa_sink_update_proplist() */
void pa_sink_set_description(pa_sink *s, const char *description) {
const char *old;
pa_sink_assert_ref(s);
pa_assert_ctl_context();
if (!description && !pa_proplist_contains(s->proplist, PA_PROP_DEVICE_DESCRIPTION))
return;
old = pa_proplist_gets(s->proplist, PA_PROP_DEVICE_DESCRIPTION);
if (old && description && pa_streq(old, description))
return;
if (description)
pa_proplist_sets(s->proplist, PA_PROP_DEVICE_DESCRIPTION, description);
else
pa_proplist_unset(s->proplist, PA_PROP_DEVICE_DESCRIPTION);
if (s->monitor_source) {
char *n;
n = pa_sprintf_malloc("Monitor Source of %s", description ? description : s->name);
pa_source_set_description(s->monitor_source, n);
pa_xfree(n);
}
if (PA_SINK_IS_LINKED(s->state)) {
pa_subscription_post(s->core, PA_SUBSCRIPTION_EVENT_SINK|PA_SUBSCRIPTION_EVENT_CHANGE, s->index);
pa_hook_fire(&s->core->hooks[PA_CORE_HOOK_SINK_PROPLIST_CHANGED], s);
}
}
/* Called from main thread */
unsigned pa_sink_linked_by(pa_sink *s) {
unsigned ret;
pa_sink_assert_ref(s);
pa_assert_ctl_context();
pa_assert(PA_SINK_IS_LINKED(s->state));
ret = pa_idxset_size(s->inputs);
/* We add in the number of streams connected to us here. Please
* note the asymmetry to pa_sink_used_by()! */
if (s->monitor_source)
ret += pa_source_linked_by(s->monitor_source);
return ret;
}
/* Called from main thread */
unsigned pa_sink_used_by(pa_sink *s) {
unsigned ret;
pa_sink_assert_ref(s);
pa_assert_ctl_context();
pa_assert(PA_SINK_IS_LINKED(s->state));
ret = pa_idxset_size(s->inputs);
pa_assert(ret >= s->n_corked);
/* Streams connected to our monitor source do not matter for
* pa_sink_used_by()!.*/
return ret - s->n_corked;
}
/* Called from main thread */
unsigned pa_sink_check_suspend(pa_sink *s) {
unsigned ret;
pa_sink_input *i;
uint32_t idx;
pa_sink_assert_ref(s);
pa_assert_ctl_context();
if (!PA_SINK_IS_LINKED(s->state))
return 0;
ret = 0;
PA_IDXSET_FOREACH(i, s->inputs, idx) {
pa_sink_input_state_t st;
st = pa_sink_input_get_state(i);
/* We do not assert here. It is perfectly valid for a sink input to
* be in the INIT state (i.e. created, marked done but not yet put)
* and we should not care if it's unlinked as it won't contribute
* towards our busy status.
*/
if (!PA_SINK_INPUT_IS_LINKED(st))
continue;
if (st == PA_SINK_INPUT_CORKED)
continue;
if (i->flags & PA_SINK_INPUT_DONT_INHIBIT_AUTO_SUSPEND)
continue;
ret ++;
}
if (s->monitor_source)
ret += pa_source_check_suspend(s->monitor_source);
return ret;
}
/* Called from the IO thread */
static void sync_input_volumes_within_thread(pa_sink *s) {
pa_sink_input *i;
void *state = NULL;
pa_sink_assert_ref(s);
pa_sink_assert_io_context(s);
PA_HASHMAP_FOREACH(i, s->thread_info.inputs, state) {
if (pa_cvolume_equal(&i->thread_info.soft_volume, &i->soft_volume))
continue;
i->thread_info.soft_volume = i->soft_volume;
pa_sink_input_request_rewind(i, 0, TRUE, FALSE, FALSE);
}
}
/* Called from the IO thread. Only called for the root sink in volume sharing
* cases, except for internal recursive calls. */
static void set_shared_volume_within_thread(pa_sink *s) {
pa_sink_input *i = NULL;
void *state = NULL;
pa_sink_assert_ref(s);
PA_MSGOBJECT(s)->process_msg(PA_MSGOBJECT(s), PA_SINK_MESSAGE_SET_VOLUME_SYNCED, NULL, 0, NULL);
PA_HASHMAP_FOREACH(i, s->thread_info.inputs, state) {
if (i->origin_sink && (i->origin_sink->flags & PA_SINK_SHARE_VOLUME_WITH_MASTER))
set_shared_volume_within_thread(i->origin_sink);
}
}
/* Called from IO thread, except when it is not */
int pa_sink_process_msg(pa_msgobject *o, int code, void *userdata, int64_t offset, pa_memchunk *chunk) {
pa_sink *s = PA_SINK(o);
pa_sink_assert_ref(s);
switch ((pa_sink_message_t) code) {
case PA_SINK_MESSAGE_ADD_INPUT: {
pa_sink_input *i = PA_SINK_INPUT(userdata);
/* If you change anything here, make sure to change the
* sink input handling a few lines down at
* PA_SINK_MESSAGE_FINISH_MOVE, too. */
pa_hashmap_put(s->thread_info.inputs, PA_UINT32_TO_PTR(i->index), pa_sink_input_ref(i));
/* Since the caller sleeps in pa_sink_input_put(), we can
* safely access data outside of thread_info even though
* it is mutable */
if ((i->thread_info.sync_prev = i->sync_prev)) {
pa_assert(i->sink == i->thread_info.sync_prev->sink);
pa_assert(i->sync_prev->sync_next == i);
i->thread_info.sync_prev->thread_info.sync_next = i;
}
if ((i->thread_info.sync_next = i->sync_next)) {
pa_assert(i->sink == i->thread_info.sync_next->sink);
pa_assert(i->sync_next->sync_prev == i);
i->thread_info.sync_next->thread_info.sync_prev = i;
}
pa_assert(!i->thread_info.attached);
i->thread_info.attached = TRUE;
if (i->attach)
i->attach(i);
pa_sink_input_set_state_within_thread(i, i->state);
/* The requested latency of the sink input needs to be
* fixed up and then configured on the sink */
if (i->thread_info.requested_sink_latency != (pa_usec_t) -1)
pa_sink_input_set_requested_latency_within_thread(i, i->thread_info.requested_sink_latency);
pa_sink_input_update_max_rewind(i, s->thread_info.max_rewind);
pa_sink_input_update_max_request(i, s->thread_info.max_request);
/* We don't rewind here automatically. This is left to the
* sink input implementor because some sink inputs need a
* slow start, i.e. need some time to buffer client
* samples before beginning streaming. */
/* FIXME: Actually rewinding should be requested before
* updating the sink requested latency, because updating
* the requested latency updates also max_rewind of the
* sink. Now consider this: a sink has a 10 s buffer and
* nobody has requested anything less. Then a new stream
* appears while the sink buffer is full. The new stream
* requests e.g. 100 ms latency. That request is forwarded
* to the sink, so now max_rewind is 100 ms. When a rewind
* is requested, the sink will only rewind 100 ms, and the
* new stream will have to wait about 10 seconds before it
* becomes audible. */
/* In flat volume mode we need to update the volume as
* well */
return o->process_msg(o, PA_SINK_MESSAGE_SET_SHARED_VOLUME, NULL, 0, NULL);
}
case PA_SINK_MESSAGE_REMOVE_INPUT: {
pa_sink_input *i = PA_SINK_INPUT(userdata);
/* If you change anything here, make sure to change the
* sink input handling a few lines down at
* PA_SINK_MESSAGE_START_MOVE, too. */
if (i->detach)
i->detach(i);
pa_sink_input_set_state_within_thread(i, i->state);
pa_assert(i->thread_info.attached);
i->thread_info.attached = FALSE;
/* Since the caller sleeps in pa_sink_input_unlink(),
* we can safely access data outside of thread_info even
* though it is mutable */
pa_assert(!i->sync_prev);
pa_assert(!i->sync_next);
if (i->thread_info.sync_prev) {
i->thread_info.sync_prev->thread_info.sync_next = i->thread_info.sync_prev->sync_next;
i->thread_info.sync_prev = NULL;
}
if (i->thread_info.sync_next) {
i->thread_info.sync_next->thread_info.sync_prev = i->thread_info.sync_next->sync_prev;
i->thread_info.sync_next = NULL;
}
if (pa_hashmap_remove(s->thread_info.inputs, PA_UINT32_TO_PTR(i->index)))
pa_sink_input_unref(i);
pa_sink_invalidate_requested_latency(s, TRUE);
pa_sink_request_rewind(s, (size_t) -1);
/* In flat volume mode we need to update the volume as
* well */
return o->process_msg(o, PA_SINK_MESSAGE_SET_SHARED_VOLUME, NULL, 0, NULL);
}
case PA_SINK_MESSAGE_START_MOVE: {
pa_sink_input *i = PA_SINK_INPUT(userdata);
/* We don't support moving synchronized streams. */
pa_assert(!i->sync_prev);
pa_assert(!i->sync_next);
pa_assert(!i->thread_info.sync_next);
pa_assert(!i->thread_info.sync_prev);
if (i->thread_info.state != PA_SINK_INPUT_CORKED) {
pa_usec_t usec = 0;
size_t sink_nbytes, total_nbytes;
/* The old sink probably has some audio from this
* stream in its buffer. We want to "take it back" as
* much as possible and play it to the new sink. We
* don't know at this point how much the old sink can
* rewind. We have to pick something, and that
* something is the full latency of the old sink here.
* So we rewind the stream buffer by the sink latency
* amount, which may be more than what we should
* rewind. This can result in a chunk of audio being
* played both to the old sink and the new sink.
*
* FIXME: Fix this code so that we don't have to make
* guesses about how much the sink will actually be
* able to rewind. If someone comes up with a solution
* for this, something to note is that the part of the
* latency that the old sink couldn't rewind should
* ideally be compensated after the stream has moved
* to the new sink by adding silence. The new sink
* most likely can't start playing the moved stream
* immediately, and that gap should be removed from
* the "compensation silence" (at least at the time of
* writing this, the move finish code will actually
* already take care of dropping the new sink's
* unrewindable latency, so taking into account the
* unrewindable latency of the old sink is the only
* problem).
*
* The render_memblockq contents are discarded,
* because when the sink changes, the format of the
* audio stored in the render_memblockq may change
* too, making the stored audio invalid. FIXME:
* However, the read and write indices are moved back
* the same amount, so if they are not the same now,
* they won't be the same after the rewind either. If
* the write index of the render_memblockq is ahead of
* the read index, then the render_memblockq will feed
* the new sink some silence first, which it shouldn't
* do. The write index should be flushed to be the
* same as the read index. */
/* Get the latency of the sink */
usec = pa_sink_get_latency_within_thread(s);
sink_nbytes = pa_usec_to_bytes(usec, &s->sample_spec);
total_nbytes = sink_nbytes + pa_memblockq_get_length(i->thread_info.render_memblockq);
if (total_nbytes > 0) {
i->thread_info.rewrite_nbytes = i->thread_info.resampler ? pa_resampler_request(i->thread_info.resampler, total_nbytes) : total_nbytes;
i->thread_info.rewrite_flush = TRUE;
pa_sink_input_process_rewind(i, sink_nbytes);
}
}
if (i->detach)
i->detach(i);
pa_assert(i->thread_info.attached);
i->thread_info.attached = FALSE;
/* Let's remove the sink input ...*/
if (pa_hashmap_remove(s->thread_info.inputs, PA_UINT32_TO_PTR(i->index)))
pa_sink_input_unref(i);
pa_sink_invalidate_requested_latency(s, TRUE);
pa_log_debug("Requesting rewind due to started move");
pa_sink_request_rewind(s, (size_t) -1);
/* In flat volume mode we need to update the volume as
* well */
return o->process_msg(o, PA_SINK_MESSAGE_SET_SHARED_VOLUME, NULL, 0, NULL);
}
case PA_SINK_MESSAGE_FINISH_MOVE: {
pa_sink_input *i = PA_SINK_INPUT(userdata);
/* We don't support moving synchronized streams. */
pa_assert(!i->sync_prev);
pa_assert(!i->sync_next);
pa_assert(!i->thread_info.sync_next);
pa_assert(!i->thread_info.sync_prev);
pa_hashmap_put(s->thread_info.inputs, PA_UINT32_TO_PTR(i->index), pa_sink_input_ref(i));
pa_assert(!i->thread_info.attached);
i->thread_info.attached = TRUE;
if (i->attach)
i->attach(i);
if (i->thread_info.state != PA_SINK_INPUT_CORKED) {
pa_usec_t usec = 0;
size_t nbytes;
/* In the ideal case the new sink would start playing
* the stream immediately. That requires the sink to
* be able to rewind all of its latency, which usually
* isn't possible, so there will probably be some gap
* before the moved stream becomes audible. We then
* have two possibilities: 1) start playing the stream
* from where it is now, or 2) drop the unrewindable
* latency of the sink from the stream. With option 1
* we won't lose any audio but the stream will have a
* pause. With option 2 we may lose some audio but the
* stream time will be somewhat in sync with the wall
* clock. Lennart seems to have chosen option 2 (one
* of the reasons might have been that option 1 is
* actually much harder to implement), so we drop the
* latency of the new sink from the moved stream and
* hope that the sink will undo most of that in the
* rewind. */
/* Get the latency of the sink */
usec = pa_sink_get_latency_within_thread(s);
nbytes = pa_usec_to_bytes(usec, &s->sample_spec);
if (nbytes > 0)
pa_sink_input_drop(i, nbytes);
pa_log_debug("Requesting rewind due to finished move");
pa_sink_request_rewind(s, nbytes);
}
/* Updating the requested sink latency has to be done
* after the sink rewind request, not before, because
* otherwise the sink may limit the rewind amount
* needlessly. */
if (i->thread_info.requested_sink_latency != (pa_usec_t) -1)
pa_sink_input_set_requested_latency_within_thread(i, i->thread_info.requested_sink_latency);
pa_sink_input_update_max_rewind(i, s->thread_info.max_rewind);
pa_sink_input_update_max_request(i, s->thread_info.max_request);
return o->process_msg(o, PA_SINK_MESSAGE_SET_SHARED_VOLUME, NULL, 0, NULL);
}
case PA_SINK_MESSAGE_SET_SHARED_VOLUME: {
pa_sink *root_sink = pa_sink_get_master(s);
if (PA_LIKELY(root_sink))
set_shared_volume_within_thread(root_sink);
return 0;
}
case PA_SINK_MESSAGE_SET_VOLUME_SYNCED:
if (s->flags & PA_SINK_DEFERRED_VOLUME) {
s->set_volume(s);
pa_sink_volume_change_push(s);
}
/* Fall through ... */
case PA_SINK_MESSAGE_SET_VOLUME:
if (!pa_cvolume_equal(&s->thread_info.soft_volume, &s->soft_volume)) {
s->thread_info.soft_volume = s->soft_volume;
pa_sink_request_rewind(s, (size_t) -1);
}
/* Fall through ... */
case PA_SINK_MESSAGE_SYNC_VOLUMES:
sync_input_volumes_within_thread(s);
return 0;
case PA_SINK_MESSAGE_GET_VOLUME:
if ((s->flags & PA_SINK_DEFERRED_VOLUME) && s->get_volume) {
s->get_volume(s);
pa_sink_volume_change_flush(s);
pa_sw_cvolume_divide(&s->thread_info.current_hw_volume, &s->real_volume, &s->soft_volume);
}
/* In case sink implementor reset SW volume. */
if (!pa_cvolume_equal(&s->thread_info.soft_volume, &s->soft_volume)) {
s->thread_info.soft_volume = s->soft_volume;
pa_sink_request_rewind(s, (size_t) -1);
}
return 0;
case PA_SINK_MESSAGE_SET_MUTE:
if (s->thread_info.soft_muted != s->muted) {
s->thread_info.soft_muted = s->muted;
pa_sink_request_rewind(s, (size_t) -1);
}
if (s->flags & PA_SINK_DEFERRED_VOLUME && s->set_mute)
s->set_mute(s);
return 0;
case PA_SINK_MESSAGE_GET_MUTE:
if (s->flags & PA_SINK_DEFERRED_VOLUME && s->get_mute)
s->get_mute(s);
return 0;
case PA_SINK_MESSAGE_SET_STATE: {
pa_bool_t suspend_change =
(s->thread_info.state == PA_SINK_SUSPENDED && PA_SINK_IS_OPENED(PA_PTR_TO_UINT(userdata))) ||
(PA_SINK_IS_OPENED(s->thread_info.state) && PA_PTR_TO_UINT(userdata) == PA_SINK_SUSPENDED);
s->thread_info.state = PA_PTR_TO_UINT(userdata);
if (s->thread_info.state == PA_SINK_SUSPENDED) {
s->thread_info.rewind_nbytes = 0;
s->thread_info.rewind_requested = FALSE;
}
if (suspend_change) {
pa_sink_input *i;
void *state = NULL;
while ((i = pa_hashmap_iterate(s->thread_info.inputs, &state, NULL)))
if (i->suspend_within_thread)
i->suspend_within_thread(i, s->thread_info.state == PA_SINK_SUSPENDED);
}
return 0;
}
case PA_SINK_MESSAGE_DETACH:
/* Detach all streams */
pa_sink_detach_within_thread(s);
return 0;
case PA_SINK_MESSAGE_ATTACH:
/* Reattach all streams */
pa_sink_attach_within_thread(s);
return 0;
case PA_SINK_MESSAGE_GET_REQUESTED_LATENCY: {
pa_usec_t *usec = userdata;
*usec = pa_sink_get_requested_latency_within_thread(s);
/* Yes, that's right, the IO thread will see -1 when no
* explicit requested latency is configured, the main
* thread will see max_latency */
if (*usec == (pa_usec_t) -1)
*usec = s->thread_info.max_latency;
return 0;
}
case PA_SINK_MESSAGE_SET_LATENCY_RANGE: {
pa_usec_t *r = userdata;
pa_sink_set_latency_range_within_thread(s, r[0], r[1]);
return 0;
}
case PA_SINK_MESSAGE_GET_LATENCY_RANGE: {
pa_usec_t *r = userdata;
r[0] = s->thread_info.min_latency;
r[1] = s->thread_info.max_latency;
return 0;
}
case PA_SINK_MESSAGE_GET_FIXED_LATENCY:
*((pa_usec_t*) userdata) = s->thread_info.fixed_latency;
return 0;
case PA_SINK_MESSAGE_SET_FIXED_LATENCY:
pa_sink_set_fixed_latency_within_thread(s, (pa_usec_t) offset);
return 0;
case PA_SINK_MESSAGE_GET_MAX_REWIND:
*((size_t*) userdata) = s->thread_info.max_rewind;
return 0;
case PA_SINK_MESSAGE_GET_MAX_REQUEST:
*((size_t*) userdata) = s->thread_info.max_request;
return 0;
case PA_SINK_MESSAGE_SET_MAX_REWIND:
pa_sink_set_max_rewind_within_thread(s, (size_t) offset);
return 0;
case PA_SINK_MESSAGE_SET_MAX_REQUEST:
pa_sink_set_max_request_within_thread(s, (size_t) offset);
return 0;
case PA_SINK_MESSAGE_SET_PORT:
pa_assert(userdata);
if (s->set_port) {
struct sink_message_set_port *msg_data = userdata;
msg_data->ret = s->set_port(s, msg_data->port);
}
return 0;
case PA_SINK_MESSAGE_UPDATE_VOLUME_AND_MUTE:
/* This message is sent from IO-thread and handled in main thread. */
pa_assert_ctl_context();
/* Make sure we're not messing with main thread when no longer linked */
if (!PA_SINK_IS_LINKED(s->state))
return 0;
pa_sink_get_volume(s, TRUE);
pa_sink_get_mute(s, TRUE);
return 0;
case PA_SINK_MESSAGE_GET_LATENCY:
case PA_SINK_MESSAGE_MAX:
;
}
return -1;
}
/* Called from main thread */
int pa_sink_suspend_all(pa_core *c, pa_bool_t suspend, pa_suspend_cause_t cause) {
pa_sink *sink;
uint32_t idx;
int ret = 0;
pa_core_assert_ref(c);
pa_assert_ctl_context();
pa_assert(cause != 0);
PA_IDXSET_FOREACH(sink, c->sinks, idx) {
int r;
if ((r = pa_sink_suspend(sink, suspend, cause)) < 0)
ret = r;
}
return ret;
}
/* Called from main thread */
void pa_sink_detach(pa_sink *s) {
pa_sink_assert_ref(s);
pa_assert_ctl_context();
pa_assert(PA_SINK_IS_LINKED(s->state));
pa_assert_se(pa_asyncmsgq_send(s->asyncmsgq, PA_MSGOBJECT(s), PA_SINK_MESSAGE_DETACH, NULL, 0, NULL) == 0);
}
/* Called from main thread */
void pa_sink_attach(pa_sink *s) {
pa_sink_assert_ref(s);
pa_assert_ctl_context();
pa_assert(PA_SINK_IS_LINKED(s->state));
pa_assert_se(pa_asyncmsgq_send(s->asyncmsgq, PA_MSGOBJECT(s), PA_SINK_MESSAGE_ATTACH, NULL, 0, NULL) == 0);
}
/* Called from IO thread */
void pa_sink_detach_within_thread(pa_sink *s) {
pa_sink_input *i;
void *state = NULL;
pa_sink_assert_ref(s);
pa_sink_assert_io_context(s);
pa_assert(PA_SINK_IS_LINKED(s->thread_info.state));
PA_HASHMAP_FOREACH(i, s->thread_info.inputs, state)
if (i->detach)
i->detach(i);
if (s->monitor_source)
pa_source_detach_within_thread(s->monitor_source);
}
/* Called from IO thread */
void pa_sink_attach_within_thread(pa_sink *s) {
pa_sink_input *i;
void *state = NULL;
pa_sink_assert_ref(s);
pa_sink_assert_io_context(s);
pa_assert(PA_SINK_IS_LINKED(s->thread_info.state));
PA_HASHMAP_FOREACH(i, s->thread_info.inputs, state)
if (i->attach)
i->attach(i);
if (s->monitor_source)
pa_source_attach_within_thread(s->monitor_source);
}
/* Called from IO thread */
void pa_sink_request_rewind(pa_sink*s, size_t nbytes) {
pa_sink_assert_ref(s);
pa_sink_assert_io_context(s);
pa_assert(PA_SINK_IS_LINKED(s->thread_info.state));
if (s->thread_info.state == PA_SINK_SUSPENDED)
return;
if (nbytes == (size_t) -1)
nbytes = s->thread_info.max_rewind;
nbytes = PA_MIN(nbytes, s->thread_info.max_rewind);
if (s->thread_info.rewind_requested &&
nbytes <= s->thread_info.rewind_nbytes)
return;
s->thread_info.rewind_nbytes = nbytes;
s->thread_info.rewind_requested = TRUE;
if (s->request_rewind)
s->request_rewind(s);
}
/* Called from IO thread */
pa_usec_t pa_sink_get_requested_latency_within_thread(pa_sink *s) {
pa_usec_t result = (pa_usec_t) -1;
pa_sink_input *i;
void *state = NULL;
pa_usec_t monitor_latency;
pa_sink_assert_ref(s);
pa_sink_assert_io_context(s);
if (!(s->flags & PA_SINK_DYNAMIC_LATENCY))
return PA_CLAMP(s->thread_info.fixed_latency, s->thread_info.min_latency, s->thread_info.max_latency);
if (s->thread_info.requested_latency_valid)
return s->thread_info.requested_latency;
PA_HASHMAP_FOREACH(i, s->thread_info.inputs, state)
if (i->thread_info.requested_sink_latency != (pa_usec_t) -1 &&
(result == (pa_usec_t) -1 || result > i->thread_info.requested_sink_latency))
result = i->thread_info.requested_sink_latency;
monitor_latency = pa_source_get_requested_latency_within_thread(s->monitor_source);
if (monitor_latency != (pa_usec_t) -1 &&
(result == (pa_usec_t) -1 || result > monitor_latency))
result = monitor_latency;
if (result != (pa_usec_t) -1)
result = PA_CLAMP(result, s->thread_info.min_latency, s->thread_info.max_latency);
if (PA_SINK_IS_LINKED(s->thread_info.state)) {
/* Only cache if properly initialized */
s->thread_info.requested_latency = result;
s->thread_info.requested_latency_valid = TRUE;
}
return result;
}
/* Called from main thread */
pa_usec_t pa_sink_get_requested_latency(pa_sink *s) {
pa_usec_t usec = 0;
pa_sink_assert_ref(s);
pa_assert_ctl_context();
pa_assert(PA_SINK_IS_LINKED(s->state));
if (s->state == PA_SINK_SUSPENDED)
return 0;
pa_assert_se(pa_asyncmsgq_send(s->asyncmsgq, PA_MSGOBJECT(s), PA_SINK_MESSAGE_GET_REQUESTED_LATENCY, &usec, 0, NULL) == 0);
return usec;
}
/* Called from IO as well as the main thread -- the latter only before the IO thread started up */
void pa_sink_set_max_rewind_within_thread(pa_sink *s, size_t max_rewind) {
pa_sink_input *i;
void *state = NULL;
pa_sink_assert_ref(s);
pa_sink_assert_io_context(s);
if (max_rewind == s->thread_info.max_rewind)
return;
s->thread_info.max_rewind = max_rewind;
if (PA_SINK_IS_LINKED(s->thread_info.state))
PA_HASHMAP_FOREACH(i, s->thread_info.inputs, state)
pa_sink_input_update_max_rewind(i, s->thread_info.max_rewind);
if (s->monitor_source)
pa_source_set_max_rewind_within_thread(s->monitor_source, s->thread_info.max_rewind);
}
/* Called from main thread */
void pa_sink_set_max_rewind(pa_sink *s, size_t max_rewind) {
pa_sink_assert_ref(s);
pa_assert_ctl_context();
if (PA_SINK_IS_LINKED(s->state))
pa_assert_se(pa_asyncmsgq_send(s->asyncmsgq, PA_MSGOBJECT(s), PA_SINK_MESSAGE_SET_MAX_REWIND, NULL, max_rewind, NULL) == 0);
else
pa_sink_set_max_rewind_within_thread(s, max_rewind);
}
/* Called from IO as well as the main thread -- the latter only before the IO thread started up */
void pa_sink_set_max_request_within_thread(pa_sink *s, size_t max_request) {
void *state = NULL;
pa_sink_assert_ref(s);
pa_sink_assert_io_context(s);
if (max_request == s->thread_info.max_request)
return;
s->thread_info.max_request = max_request;
if (PA_SINK_IS_LINKED(s->thread_info.state)) {
pa_sink_input *i;
PA_HASHMAP_FOREACH(i, s->thread_info.inputs, state)
pa_sink_input_update_max_request(i, s->thread_info.max_request);
}
}
/* Called from main thread */
void pa_sink_set_max_request(pa_sink *s, size_t max_request) {
pa_sink_assert_ref(s);
pa_assert_ctl_context();
if (PA_SINK_IS_LINKED(s->state))
pa_assert_se(pa_asyncmsgq_send(s->asyncmsgq, PA_MSGOBJECT(s), PA_SINK_MESSAGE_SET_MAX_REQUEST, NULL, max_request, NULL) == 0);
else
pa_sink_set_max_request_within_thread(s, max_request);
}
/* Called from IO thread */
void pa_sink_invalidate_requested_latency(pa_sink *s, pa_bool_t dynamic) {
pa_sink_input *i;
void *state = NULL;
pa_sink_assert_ref(s);
pa_sink_assert_io_context(s);
if ((s->flags & PA_SINK_DYNAMIC_LATENCY))
s->thread_info.requested_latency_valid = FALSE;
else if (dynamic)
return;
if (PA_SINK_IS_LINKED(s->thread_info.state)) {
if (s->update_requested_latency)
s->update_requested_latency(s);
PA_HASHMAP_FOREACH(i, s->thread_info.inputs, state)
if (i->update_sink_requested_latency)
i->update_sink_requested_latency(i);
}
}
/* Called from main thread */
void pa_sink_set_latency_range(pa_sink *s, pa_usec_t min_latency, pa_usec_t max_latency) {
pa_sink_assert_ref(s);
pa_assert_ctl_context();
/* min_latency == 0: no limit
* min_latency anything else: specified limit
*
* Similar for max_latency */
if (min_latency < ABSOLUTE_MIN_LATENCY)
min_latency = ABSOLUTE_MIN_LATENCY;
if (max_latency <= 0 ||
max_latency > ABSOLUTE_MAX_LATENCY)
max_latency = ABSOLUTE_MAX_LATENCY;
pa_assert(min_latency <= max_latency);
/* Hmm, let's see if someone forgot to set PA_SINK_DYNAMIC_LATENCY here... */
pa_assert((min_latency == ABSOLUTE_MIN_LATENCY &&
max_latency == ABSOLUTE_MAX_LATENCY) ||
(s->flags & PA_SINK_DYNAMIC_LATENCY));
if (PA_SINK_IS_LINKED(s->state)) {
pa_usec_t r[2];
r[0] = min_latency;
r[1] = max_latency;
pa_assert_se(pa_asyncmsgq_send(s->asyncmsgq, PA_MSGOBJECT(s), PA_SINK_MESSAGE_SET_LATENCY_RANGE, r, 0, NULL) == 0);
} else
pa_sink_set_latency_range_within_thread(s, min_latency, max_latency);
}
/* Called from main thread */
void pa_sink_get_latency_range(pa_sink *s, pa_usec_t *min_latency, pa_usec_t *max_latency) {
pa_sink_assert_ref(s);
pa_assert_ctl_context();
pa_assert(min_latency);
pa_assert(max_latency);
if (PA_SINK_IS_LINKED(s->state)) {
pa_usec_t r[2] = { 0, 0 };
pa_assert_se(pa_asyncmsgq_send(s->asyncmsgq, PA_MSGOBJECT(s), PA_SINK_MESSAGE_GET_LATENCY_RANGE, r, 0, NULL) == 0);
*min_latency = r[0];
*max_latency = r[1];
} else {
*min_latency = s->thread_info.min_latency;
*max_latency = s->thread_info.max_latency;
}
}
/* Called from IO thread */
void pa_sink_set_latency_range_within_thread(pa_sink *s, pa_usec_t min_latency, pa_usec_t max_latency) {
pa_sink_assert_ref(s);
pa_sink_assert_io_context(s);
pa_assert(min_latency >= ABSOLUTE_MIN_LATENCY);
pa_assert(max_latency <= ABSOLUTE_MAX_LATENCY);
pa_assert(min_latency <= max_latency);
/* Hmm, let's see if someone forgot to set PA_SINK_DYNAMIC_LATENCY here... */
pa_assert((min_latency == ABSOLUTE_MIN_LATENCY &&
max_latency == ABSOLUTE_MAX_LATENCY) ||
(s->flags & PA_SINK_DYNAMIC_LATENCY));
if (s->thread_info.min_latency == min_latency &&
s->thread_info.max_latency == max_latency)
return;
s->thread_info.min_latency = min_latency;
s->thread_info.max_latency = max_latency;
if (PA_SINK_IS_LINKED(s->thread_info.state)) {
pa_sink_input *i;
void *state = NULL;
PA_HASHMAP_FOREACH(i, s->thread_info.inputs, state)
if (i->update_sink_latency_range)
i->update_sink_latency_range(i);
}
pa_sink_invalidate_requested_latency(s, FALSE);
pa_source_set_latency_range_within_thread(s->monitor_source, min_latency, max_latency);
}
/* Called from main thread */
void pa_sink_set_fixed_latency(pa_sink *s, pa_usec_t latency) {
pa_sink_assert_ref(s);
pa_assert_ctl_context();
if (s->flags & PA_SINK_DYNAMIC_LATENCY) {
pa_assert(latency == 0);
return;
}
if (latency < ABSOLUTE_MIN_LATENCY)
latency = ABSOLUTE_MIN_LATENCY;
if (latency > ABSOLUTE_MAX_LATENCY)
latency = ABSOLUTE_MAX_LATENCY;
if (PA_SINK_IS_LINKED(s->state))
pa_assert_se(pa_asyncmsgq_send(s->asyncmsgq, PA_MSGOBJECT(s), PA_SINK_MESSAGE_SET_FIXED_LATENCY, NULL, (int64_t) latency, NULL) == 0);
else
s->thread_info.fixed_latency = latency;
pa_source_set_fixed_latency(s->monitor_source, latency);
}
/* Called from main thread */
pa_usec_t pa_sink_get_fixed_latency(pa_sink *s) {
pa_usec_t latency;
pa_sink_assert_ref(s);
pa_assert_ctl_context();
if (s->flags & PA_SINK_DYNAMIC_LATENCY)
return 0;
if (PA_SINK_IS_LINKED(s->state))
pa_assert_se(pa_asyncmsgq_send(s->asyncmsgq, PA_MSGOBJECT(s), PA_SINK_MESSAGE_GET_FIXED_LATENCY, &latency, 0, NULL) == 0);
else
latency = s->thread_info.fixed_latency;
return latency;
}
/* Called from IO thread */
void pa_sink_set_fixed_latency_within_thread(pa_sink *s, pa_usec_t latency) {
pa_sink_assert_ref(s);
pa_sink_assert_io_context(s);
if (s->flags & PA_SINK_DYNAMIC_LATENCY) {
pa_assert(latency == 0);
return;
}
pa_assert(latency >= ABSOLUTE_MIN_LATENCY);
pa_assert(latency <= ABSOLUTE_MAX_LATENCY);
if (s->thread_info.fixed_latency == latency)
return;
s->thread_info.fixed_latency = latency;
if (PA_SINK_IS_LINKED(s->thread_info.state)) {
pa_sink_input *i;
void *state = NULL;
PA_HASHMAP_FOREACH(i, s->thread_info.inputs, state)
if (i->update_sink_fixed_latency)
i->update_sink_fixed_latency(i);
}
pa_sink_invalidate_requested_latency(s, FALSE);
pa_source_set_fixed_latency_within_thread(s->monitor_source, latency);
}
/* Called from main context */
size_t pa_sink_get_max_rewind(pa_sink *s) {
size_t r;
pa_assert_ctl_context();
pa_sink_assert_ref(s);
if (!PA_SINK_IS_LINKED(s->state))
return s->thread_info.max_rewind;
pa_assert_se(pa_asyncmsgq_send(s->asyncmsgq, PA_MSGOBJECT(s), PA_SINK_MESSAGE_GET_MAX_REWIND, &r, 0, NULL) == 0);
return r;
}
/* Called from main context */
size_t pa_sink_get_max_request(pa_sink *s) {
size_t r;
pa_sink_assert_ref(s);
pa_assert_ctl_context();
if (!PA_SINK_IS_LINKED(s->state))
return s->thread_info.max_request;
pa_assert_se(pa_asyncmsgq_send(s->asyncmsgq, PA_MSGOBJECT(s), PA_SINK_MESSAGE_GET_MAX_REQUEST, &r, 0, NULL) == 0);
return r;
}
/* Called from main context */
int pa_sink_set_port(pa_sink *s, const char *name, pa_bool_t save) {
pa_device_port *port;
int ret;
pa_sink_assert_ref(s);
pa_assert_ctl_context();
if (!s->set_port) {
pa_log_debug("set_port() operation not implemented for sink %u \"%s\"", s->index, s->name);
return -PA_ERR_NOTIMPLEMENTED;
}
if (!s->ports || !name)
return -PA_ERR_NOENTITY;
if (!(port = pa_hashmap_get(s->ports, name)))
return -PA_ERR_NOENTITY;
if (s->active_port == port) {
s->save_port = s->save_port || save;
return 0;
}
if (s->flags & PA_SINK_DEFERRED_VOLUME) {
struct sink_message_set_port msg = { .port = port, .ret = 0 };
pa_assert_se(pa_asyncmsgq_send(s->asyncmsgq, PA_MSGOBJECT(s), PA_SINK_MESSAGE_SET_PORT, &msg, 0, NULL) == 0);
ret = msg.ret;
}
else
ret = s->set_port(s, port);
if (ret < 0)
return -PA_ERR_NOENTITY;
pa_subscription_post(s->core, PA_SUBSCRIPTION_EVENT_SINK|PA_SUBSCRIPTION_EVENT_CHANGE, s->index);
pa_log_info("Changed port of sink %u \"%s\" to %s", s->index, s->name, port->name);
s->active_port = port;
s->save_port = save;
pa_hook_fire(&s->core->hooks[PA_CORE_HOOK_SINK_PORT_CHANGED], s);
return 0;
}
pa_bool_t pa_device_init_icon(pa_proplist *p, pa_bool_t is_sink) {
const char *ff, *c, *t = NULL, *s = "", *profile, *bus;
pa_assert(p);
if (pa_proplist_contains(p, PA_PROP_DEVICE_ICON_NAME))
return TRUE;
if ((ff = pa_proplist_gets(p, PA_PROP_DEVICE_FORM_FACTOR))) {
if (pa_streq(ff, "microphone"))
t = "audio-input-microphone";
else if (pa_streq(ff, "webcam"))
t = "camera-web";
else if (pa_streq(ff, "computer"))
t = "computer";
else if (pa_streq(ff, "handset"))
t = "phone";
else if (pa_streq(ff, "portable"))
t = "multimedia-player";
else if (pa_streq(ff, "tv"))
t = "video-display";
/*
* The following icons are not part of the icon naming spec,
* because Rodney Dawes sucks as the maintainer of that spec.
*
* http://lists.freedesktop.org/archives/xdg/2009-May/010397.html
*/
else if (pa_streq(ff, "headset"))
t = "audio-headset";
else if (pa_streq(ff, "headphone"))
t = "audio-headphones";
else if (pa_streq(ff, "speaker"))
t = "audio-speakers";
else if (pa_streq(ff, "hands-free"))
t = "audio-handsfree";
}
if (!t)
if ((c = pa_proplist_gets(p, PA_PROP_DEVICE_CLASS)))
if (pa_streq(c, "modem"))
t = "modem";
if (!t) {
if (is_sink)
t = "audio-card";
else
t = "audio-input-microphone";
}
if ((profile = pa_proplist_gets(p, PA_PROP_DEVICE_PROFILE_NAME))) {
if (strstr(profile, "analog"))
s = "-analog";
else if (strstr(profile, "iec958"))
s = "-iec958";
else if (strstr(profile, "hdmi"))
s = "-hdmi";
}
bus = pa_proplist_gets(p, PA_PROP_DEVICE_BUS);
pa_proplist_setf(p, PA_PROP_DEVICE_ICON_NAME, "%s%s%s%s", t, pa_strempty(s), bus ? "-" : "", pa_strempty(bus));
return TRUE;
}
pa_bool_t pa_device_init_description(pa_proplist *p) {
const char *s, *d = NULL, *k;
pa_assert(p);
if (pa_proplist_contains(p, PA_PROP_DEVICE_DESCRIPTION))
return TRUE;
if ((s = pa_proplist_gets(p, PA_PROP_DEVICE_FORM_FACTOR)))
if (pa_streq(s, "internal"))
d = _("Built-in Audio");
if (!d)
if ((s = pa_proplist_gets(p, PA_PROP_DEVICE_CLASS)))
if (pa_streq(s, "modem"))
d = _("Modem");
if (!d)
d = pa_proplist_gets(p, PA_PROP_DEVICE_PRODUCT_NAME);
if (!d)
return FALSE;
k = pa_proplist_gets(p, PA_PROP_DEVICE_PROFILE_DESCRIPTION);
if (d && k)
pa_proplist_setf(p, PA_PROP_DEVICE_DESCRIPTION, "%s %s", d, k);
else if (d)
pa_proplist_sets(p, PA_PROP_DEVICE_DESCRIPTION, d);
return TRUE;
}
pa_bool_t pa_device_init_intended_roles(pa_proplist *p) {
const char *s;
pa_assert(p);
if (pa_proplist_contains(p, PA_PROP_DEVICE_INTENDED_ROLES))
return TRUE;
if ((s = pa_proplist_gets(p, PA_PROP_DEVICE_FORM_FACTOR)))
if (pa_streq(s, "handset") || pa_streq(s, "hands-free")
|| pa_streq(s, "headset")) {
pa_proplist_sets(p, PA_PROP_DEVICE_INTENDED_ROLES, "phone");
return TRUE;
}
return FALSE;
}
unsigned pa_device_init_priority(pa_proplist *p) {
const char *s;
unsigned priority = 0;
pa_assert(p);
if ((s = pa_proplist_gets(p, PA_PROP_DEVICE_CLASS))) {
if (pa_streq(s, "sound"))
priority += 9000;
else if (!pa_streq(s, "modem"))
priority += 1000;
}
if ((s = pa_proplist_gets(p, PA_PROP_DEVICE_FORM_FACTOR))) {
if (pa_streq(s, "internal"))
priority += 900;
else if (pa_streq(s, "speaker"))
priority += 500;
else if (pa_streq(s, "headphone"))
priority += 400;
}
if ((s = pa_proplist_gets(p, PA_PROP_DEVICE_BUS))) {
if (pa_streq(s, "pci"))
priority += 50;
else if (pa_streq(s, "usb"))
priority += 40;
else if (pa_streq(s, "bluetooth"))
priority += 30;
}
if ((s = pa_proplist_gets(p, PA_PROP_DEVICE_PROFILE_NAME))) {
if (pa_startswith(s, "analog-"))
priority += 9;
else if (pa_startswith(s, "iec958-"))
priority += 8;
}
return priority;
}
PA_STATIC_FLIST_DECLARE(pa_sink_volume_change, 0, pa_xfree);
/* Called from the IO thread. */
static pa_sink_volume_change *pa_sink_volume_change_new(pa_sink *s) {
pa_sink_volume_change *c;
if (!(c = pa_flist_pop(PA_STATIC_FLIST_GET(pa_sink_volume_change))))
c = pa_xnew(pa_sink_volume_change, 1);
PA_LLIST_INIT(pa_sink_volume_change, c);
c->at = 0;
pa_cvolume_reset(&c->hw_volume, s->sample_spec.channels);
return c;
}
/* Called from the IO thread. */
static void pa_sink_volume_change_free(pa_sink_volume_change *c) {
pa_assert(c);
if (pa_flist_push(PA_STATIC_FLIST_GET(pa_sink_volume_change), c) < 0)
pa_xfree(c);
}
/* Called from the IO thread. */
void pa_sink_volume_change_push(pa_sink *s) {
pa_sink_volume_change *c = NULL;
pa_sink_volume_change *nc = NULL;
uint32_t safety_margin = s->thread_info.volume_change_safety_margin;
const char *direction = NULL;
pa_assert(s);
nc = pa_sink_volume_change_new(s);
/* NOTE: There is already more different volumes in pa_sink that I can remember.
* Adding one more volume for HW would get us rid of this, but I am trying
* to survive with the ones we already have. */
pa_sw_cvolume_divide(&nc->hw_volume, &s->real_volume, &s->soft_volume);
if (!s->thread_info.volume_changes && pa_cvolume_equal(&nc->hw_volume, &s->thread_info.current_hw_volume)) {
pa_log_debug("Volume not changing");
pa_sink_volume_change_free(nc);
return;
}
nc->at = pa_sink_get_latency_within_thread(s);
nc->at += pa_rtclock_now() + s->thread_info.volume_change_extra_delay;
if (s->thread_info.volume_changes_tail) {
for (c = s->thread_info.volume_changes_tail; c; c = c->prev) {
/* If volume is going up let's do it a bit late. If it is going
* down let's do it a bit early. */
if (pa_cvolume_avg(&nc->hw_volume) > pa_cvolume_avg(&c->hw_volume)) {
if (nc->at + safety_margin > c->at) {
nc->at += safety_margin;
direction = "up";
break;
}
}
else if (nc->at - safety_margin > c->at) {
nc->at -= safety_margin;
direction = "down";
break;
}
}
}
if (c == NULL) {
if (pa_cvolume_avg(&nc->hw_volume) > pa_cvolume_avg(&s->thread_info.current_hw_volume)) {
nc->at += safety_margin;
direction = "up";
} else {
nc->at -= safety_margin;
direction = "down";
}
PA_LLIST_PREPEND(pa_sink_volume_change, s->thread_info.volume_changes, nc);
}
else {
PA_LLIST_INSERT_AFTER(pa_sink_volume_change, s->thread_info.volume_changes, c, nc);
}
pa_log_debug("Volume going %s to %d at %llu", direction, pa_cvolume_avg(&nc->hw_volume), (long long unsigned) nc->at);
/* We can ignore volume events that came earlier but should happen later than this. */
PA_LLIST_FOREACH(c, nc->next) {
pa_log_debug("Volume change to %d at %llu was dropped", pa_cvolume_avg(&c->hw_volume), (long long unsigned) c->at);
pa_sink_volume_change_free(c);
}
nc->next = NULL;
s->thread_info.volume_changes_tail = nc;
}
/* Called from the IO thread. */
static void pa_sink_volume_change_flush(pa_sink *s) {
pa_sink_volume_change *c = s->thread_info.volume_changes;
pa_assert(s);
s->thread_info.volume_changes = NULL;
s->thread_info.volume_changes_tail = NULL;
while (c) {
pa_sink_volume_change *next = c->next;
pa_sink_volume_change_free(c);
c = next;
}
}
/* Called from the IO thread. */
pa_bool_t pa_sink_volume_change_apply(pa_sink *s, pa_usec_t *usec_to_next) {
pa_usec_t now;
pa_bool_t ret = FALSE;
pa_assert(s);
if (!s->thread_info.volume_changes || !PA_SINK_IS_LINKED(s->state)) {
if (usec_to_next)
*usec_to_next = 0;
return ret;
}
pa_assert(s->write_volume);
now = pa_rtclock_now();
while (s->thread_info.volume_changes && now >= s->thread_info.volume_changes->at) {
pa_sink_volume_change *c = s->thread_info.volume_changes;
PA_LLIST_REMOVE(pa_sink_volume_change, s->thread_info.volume_changes, c);
pa_log_debug("Volume change to %d at %llu was written %llu usec late",
pa_cvolume_avg(&c->hw_volume), (long long unsigned) c->at, (long long unsigned) (now - c->at));
ret = TRUE;
s->thread_info.current_hw_volume = c->hw_volume;
pa_sink_volume_change_free(c);
}
if (ret)
s->write_volume(s);
if (s->thread_info.volume_changes) {
if (usec_to_next)
*usec_to_next = s->thread_info.volume_changes->at - now;
if (pa_log_ratelimit(PA_LOG_DEBUG))
pa_log_debug("Next volume change in %lld usec", (long long) (s->thread_info.volume_changes->at - now));
}
else {
if (usec_to_next)
*usec_to_next = 0;
s->thread_info.volume_changes_tail = NULL;
}
return ret;
}
/* Called from the IO thread. */
static void pa_sink_volume_change_rewind(pa_sink *s, size_t nbytes) {
/* All the queued volume events later than current latency are shifted to happen earlier. */
pa_sink_volume_change *c;
pa_volume_t prev_vol = pa_cvolume_avg(&s->thread_info.current_hw_volume);
pa_usec_t rewound = pa_bytes_to_usec(nbytes, &s->sample_spec);
pa_usec_t limit = pa_sink_get_latency_within_thread(s);
pa_log_debug("latency = %lld", (long long) limit);
limit += pa_rtclock_now() + s->thread_info.volume_change_extra_delay;
PA_LLIST_FOREACH(c, s->thread_info.volume_changes) {
pa_usec_t modified_limit = limit;
if (prev_vol > pa_cvolume_avg(&c->hw_volume))
modified_limit -= s->thread_info.volume_change_safety_margin;
else
modified_limit += s->thread_info.volume_change_safety_margin;
if (c->at > modified_limit) {
c->at -= rewound;
if (c->at < modified_limit)
c->at = modified_limit;
}
prev_vol = pa_cvolume_avg(&c->hw_volume);
}
pa_sink_volume_change_apply(s, NULL);
}
/* Called from the main thread */
/* Gets the list of formats supported by the sink. The members and idxset must
* be freed by the caller. */
pa_idxset* pa_sink_get_formats(pa_sink *s) {
pa_idxset *ret;
pa_assert(s);
if (s->get_formats) {
/* Sink supports format query, all is good */
ret = s->get_formats(s);
} else {
/* Sink doesn't support format query, so assume it does PCM */
pa_format_info *f = pa_format_info_new();
f->encoding = PA_ENCODING_PCM;
ret = pa_idxset_new(NULL, NULL);
pa_idxset_put(ret, f, NULL);
}
return ret;
}
/* Called from the main thread */
/* Allows an external source to set what formats a sink supports if the sink
* permits this. The function makes a copy of the formats on success. */
pa_bool_t pa_sink_set_formats(pa_sink *s, pa_idxset *formats) {
pa_assert(s);
pa_assert(formats);
if (s->set_formats)
/* Sink supports setting formats -- let's give it a shot */
return s->set_formats(s, formats);
else
/* Sink doesn't support setting this -- bail out */
return FALSE;
}
/* Called from the main thread */
/* Checks if the sink can accept this format */
pa_bool_t pa_sink_check_format(pa_sink *s, pa_format_info *f)
{
pa_idxset *formats = NULL;
pa_bool_t ret = FALSE;
pa_assert(s);
pa_assert(f);
formats = pa_sink_get_formats(s);
if (formats) {
pa_format_info *finfo_device;
uint32_t i;
PA_IDXSET_FOREACH(finfo_device, formats, i) {
if (pa_format_info_is_compatible(finfo_device, f)) {
ret = TRUE;
break;
}
}
pa_idxset_free(formats, (pa_free2_cb_t) pa_format_info_free2, NULL);
}
return ret;
}
/* Called from the main thread */
/* Calculates the intersection between formats supported by the sink and
* in_formats, and returns these, in the order of the sink's formats. */
pa_idxset* pa_sink_check_formats(pa_sink *s, pa_idxset *in_formats) {
pa_idxset *out_formats = pa_idxset_new(NULL, NULL), *sink_formats = NULL;
pa_format_info *f_sink, *f_in;
uint32_t i, j;
pa_assert(s);
if (!in_formats || pa_idxset_isempty(in_formats))
goto done;
sink_formats = pa_sink_get_formats(s);
PA_IDXSET_FOREACH(f_sink, sink_formats, i) {
PA_IDXSET_FOREACH(f_in, in_formats, j) {
if (pa_format_info_is_compatible(f_sink, f_in))
pa_idxset_put(out_formats, pa_format_info_copy(f_in), NULL);
}
}
done:
if (sink_formats)
pa_idxset_free(sink_formats, (pa_free2_cb_t) pa_format_info_free2, NULL);
return out_formats;
}
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