mpd/src/output/Thread.cxx

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/*
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* Copyright 2003-2018 The Music Player Daemon Project
* http://www.musicpd.org
*
* This program is free software; you can redistribute it and/or modify
* it under the terms of the GNU General Public License as published by
* the Free Software Foundation; either version 2 of the License, or
* (at your option) any later version.
*
* This program 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 General Public License along
* with this program; if not, write to the Free Software Foundation, Inc.,
* 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA.
*/
#include "Control.hxx"
#include "Filtered.hxx"
#include "Client.hxx"
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#include "Domain.hxx"
#include "mixer/MixerInternal.hxx"
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#include "thread/Util.hxx"
#include "thread/Slack.hxx"
#include "thread/Name.hxx"
#include "util/StringBuffer.hxx"
#include "util/ScopeExit.hxx"
#include "util/RuntimeError.hxx"
#include "Log.hxx"
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#include <assert.h>
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#include <string.h>
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void
AudioOutputControl::CommandFinished() noexcept
{
assert(command != Command::NONE);
command = Command::NONE;
client_cond.notify_one();
}
inline void
AudioOutputControl::InternalOpen2(const AudioFormat in_audio_format)
{
assert(in_audio_format.IsValid());
const auto cf = in_audio_format.WithMask(output->config_audio_format);
if (open && cf != output->filter_audio_format)
/* if the filter's output format changes, the output
must be reopened as well */
InternalCloseOutput(true);
output->filter_audio_format = cf;
if (!open) {
{
const ScopeUnlock unlock(mutex);
output->OpenOutputAndConvert(output->filter_audio_format);
}
open = true;
} else if (in_audio_format != output->out_audio_format) {
/* reconfigure the final ConvertFilter for its new
input AudioFormat */
try {
output->ConfigureConvertFilter();
} catch (...) {
open = false;
{
const ScopeUnlock unlock(mutex);
output->CloseOutput(false);
}
throw;
}
}
{
const ScopeUnlock unlock(mutex);
output->OpenSoftwareMixer();
}
}
inline bool
AudioOutputControl::InternalEnable() noexcept
{
if (really_enabled)
/* already enabled */
return true;
last_error = nullptr;
try {
{
const ScopeUnlock unlock(mutex);
output->Enable();
}
really_enabled = true;
return true;
} catch (...) {
LogError(std::current_exception());
Failure(std::current_exception());
return false;
}
}
inline void
AudioOutputControl::InternalDisable() noexcept
{
if (!really_enabled)
return;
InternalCheckClose(false);
really_enabled = false;
const ScopeUnlock unlock(mutex);
output->Disable();
}
inline void
AudioOutputControl::InternalOpen(const AudioFormat in_audio_format,
const MusicPipe &pipe) noexcept
{
/* enable the device (just in case the last enable has failed) */
if (!InternalEnable())
return;
last_error = nullptr;
fail_timer.Reset();
skip_delay = true;
AudioFormat f;
try {
try {
f = source.Open(in_audio_format, pipe,
output->prepared_replay_gain_filter.get(),
output->prepared_other_replay_gain_filter.get(),
*output->prepared_filter);
} catch (...) {
std::throw_with_nested(FormatRuntimeError("Failed to open filter for %s",
GetLogName()));
}
try {
InternalOpen2(f);
} catch (...) {
source.Close();
throw;
}
} catch (...) {
LogError(std::current_exception());
Failure(std::current_exception());
}
if (f != in_audio_format || f != output->out_audio_format)
FormatDebug(output_domain, "converting in=%s -> f=%s -> out=%s",
ToString(in_audio_format).c_str(),
ToString(f).c_str(),
ToString(output->out_audio_format).c_str());
}
inline void
AudioOutputControl::InternalCloseOutput(bool drain) noexcept
{
assert(IsOpen());
open = false;
const ScopeUnlock unlock(mutex);
output->CloseOutput(drain);
}
inline void
AudioOutputControl::InternalClose(bool drain) noexcept
{
assert(IsOpen());
open = false;
{
const ScopeUnlock unlock(mutex);
output->Close(drain);
}
source.Close();
}
inline void
AudioOutputControl::InternalCheckClose(bool drain) noexcept
{
if (IsOpen())
InternalClose(drain);
}
/**
* Wait until the output's delay reaches zero.
*
* @return true if playback should be continued, false if a command
* was issued
*/
inline bool
AudioOutputControl::WaitForDelay(std::unique_lock<Mutex> &lock) noexcept
{
while (true) {
const auto delay = output->Delay();
if (delay <= std::chrono::steady_clock::duration::zero())
return true;
(void)wake_cond.wait_for(lock, delay);
if (command != Command::NONE)
return false;
}
}
bool
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AudioOutputControl::FillSourceOrClose() noexcept
try {
return source.Fill(mutex);
} catch (...) {
FormatError(std::current_exception(),
"Failed to filter for %s", GetLogName());
InternalCloseError(std::current_exception());
return false;
}
inline bool
AudioOutputControl::PlayChunk(std::unique_lock<Mutex> &lock) noexcept
{
// ensure pending tags are flushed in all cases
const auto *tag = source.ReadTag();
if (tags && tag != nullptr) {
const ScopeUnlock unlock(mutex);
try {
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output->SendTag(*tag);
} catch (...) {
FormatError(std::current_exception(),
"Failed to send tag to %s",
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GetLogName());
}
}
while (command == Command::NONE) {
const auto data = source.PeekData();
if (data.empty())
break;
if (skip_delay)
skip_delay = false;
else if (!WaitForDelay(lock))
break;
size_t nbytes;
try {
const ScopeUnlock unlock(mutex);
nbytes = output->Play(data.data, data.size);
assert(nbytes > 0);
assert(nbytes <= data.size);
} catch (...) {
FormatError(std::current_exception(),
"Failed to play on %s", GetLogName());
InternalCloseError(std::current_exception());
return false;
}
assert(nbytes % output->out_audio_format.GetFrameSize() == 0);
source.ConsumeData(nbytes);
}
return true;
}
inline bool
AudioOutputControl::InternalPlay(std::unique_lock<Mutex> &lock) noexcept
{
if (!FillSourceOrClose())
/* no chunk available */
return false;
assert(!in_playback_loop);
in_playback_loop = true;
AtScopeExit(this) {
assert(in_playback_loop);
in_playback_loop = false;
};
unsigned n = 0;
do {
if (command != Command::NONE)
return true;
if (++n >= 64) {
/* wake up the player every now and then to
give it a chance to refill the pipe before
it runs empty */
const ScopeUnlock unlock(mutex);
client.ChunksConsumed();
n = 0;
}
if (!PlayChunk(lock))
break;
} while (FillSourceOrClose());
const ScopeUnlock unlock(mutex);
client.ChunksConsumed();
return true;
}
inline void
AudioOutputControl::InternalPause(std::unique_lock<Mutex> &lock) noexcept
{
{
const ScopeUnlock unlock(mutex);
output->BeginPause();
}
pause = true;
CommandFinished();
do {
if (!WaitForDelay(lock))
break;
bool success;
{
const ScopeUnlock unlock(mutex);
success = output->IteratePause();
}
if (!success) {
InternalClose(false);
break;
}
} while (command == Command::NONE);
pause = false;
{
const ScopeUnlock unlock(mutex);
output->EndPause();
}
skip_delay = true;
}
static void
PlayFull(FilteredAudioOutput &output, ConstBuffer<void> _buffer)
{
auto buffer = ConstBuffer<uint8_t>::FromVoid(_buffer);
while (!buffer.empty()) {
size_t nbytes = output.Play(buffer.data, buffer.size);
assert(nbytes > 0);
buffer.skip_front(nbytes);
}
}
inline void
AudioOutputControl::InternalDrain() noexcept
{
try {
/* flush the filter and play its remaining output */
const ScopeUnlock unlock(mutex);
while (true) {
auto buffer = source.Flush();
if (buffer.IsNull())
break;
PlayFull(*output, buffer);
}
output->Drain();
} catch (...) {
FormatError(std::current_exception(),
"Failed to flush filter on %s", GetLogName());
InternalCloseError(std::current_exception());
return;
}
}
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void
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AudioOutputControl::Task() noexcept
{
FormatThreadName("output:%s", GetName());
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try {
SetThreadRealtime();
} catch (...) {
LogError(std::current_exception(),
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"OutputThread could not get realtime scheduling, continuing anyway");
}
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SetThreadTimerSlackUS(100);
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std::unique_lock<Mutex> lock(mutex);
while (true) {
switch (command) {
case Command::NONE:
break;
case Command::ENABLE:
InternalEnable();
CommandFinished();
break;
case Command::DISABLE:
InternalDisable();
CommandFinished();
break;
case Command::OPEN:
InternalOpen(request.audio_format, *request.pipe);
CommandFinished();
break;
case Command::CLOSE:
InternalCheckClose(false);
CommandFinished();
break;
case Command::PAUSE:
if (!open) {
/* the output has failed after
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the PAUSE command was submitted; bail
out */
CommandFinished();
break;
}
InternalPause(lock);
/* don't "break" here: this might cause
Play() to be called when command==CLOSE
ends the paused state - "continue" checks
the new command first */
continue;
case Command::RELEASE:
if (!open) {
/* the output has failed after
the PAUSE command was submitted; bail
out */
CommandFinished();
break;
}
if (always_on) {
/* in "always_on" mode, the output is
paused instead of being closed;
however we need to flush the
AudioOutputSource because its data
have been invalidated by stopping
the actual playback */
source.Cancel();
InternalPause(lock);
} else {
InternalClose(false);
CommandFinished();
}
/* don't "break" here: this might cause
Play() to be called when command==CLOSE
ends the paused state - "continue" checks
the new command first */
continue;
case Command::DRAIN:
if (open)
InternalDrain();
CommandFinished();
continue;
case Command::CANCEL:
source.Cancel();
if (open) {
const ScopeUnlock unlock(mutex);
output->Cancel();
}
CommandFinished();
continue;
case Command::KILL:
InternalDisable();
source.Cancel();
CommandFinished();
return;
}
if (open && allow_play && InternalPlay(lock))
/* don't wait for an event if there are more
chunks in the pipe */
continue;
if (command == Command::NONE) {
woken_for_play = false;
wake_cond.wait(lock);
}
}
}
void
AudioOutputControl::StartThread()
{
assert(command == Command::NONE);
const ScopeUnlock unlock(mutex);
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thread.Start();
}