tdesktop/Telegram/SourceFiles/media/audio/media_audio.cpp

1741 lines
48 KiB
C++

/*
This file is part of Telegram Desktop,
the official desktop application for the Telegram messaging service.
For license and copyright information please follow this link:
https://github.com/telegramdesktop/tdesktop/blob/master/LEGAL
*/
#include "media/audio/media_audio.h"
#include "media/audio/media_audio_ffmpeg_loader.h"
#include "media/audio/media_child_ffmpeg_loader.h"
#include "media/audio/media_audio_loaders.h"
#include "media/audio/media_audio_track.h"
#include "media/audio/media_openal_functions.h"
#include "media/streaming/media_streaming_utility.h"
#include "data/data_document.h"
#include "data/data_file_origin.h"
#include "data/data_session.h"
#include "platform/platform_audio.h"
#include "core/application.h"
#include "main/main_session.h"
#include "app.h"
#include <al.h>
#include <alc.h>
#include <numeric>
Q_DECLARE_METATYPE(AudioMsgId);
Q_DECLARE_METATYPE(VoiceWaveform);
namespace {
constexpr auto kSuppressRatioAll = 0.2;
constexpr auto kSuppressRatioSong = 0.05;
constexpr auto kWaveformCounterBufferSize = 256 * 1024;
QMutex AudioMutex;
ALCdevice *AudioDevice = nullptr;
ALCcontext *AudioContext = nullptr;
auto VolumeMultiplierAll = 1.;
auto VolumeMultiplierSong = 1.;
// Value for AL_PITCH_SHIFTER_COARSE_TUNE effect, 0.5 <= speed <= 2.
int CoarseTuneForSpeed(float64 speed) {
Expects(speed >= 0.5 && speed <= 2.);
constexpr auto kTuneSteps = 12;
const auto tuneRatio = std::log(speed) / std::log(2.);
return -int(std::round(kTuneSteps * tuneRatio));
}
} // namespace
namespace Media {
namespace Audio {
namespace {
Player::Mixer *MixerInstance = nullptr;
// Thread: Any.
bool ContextErrorHappened() {
ALenum errCode;
if ((errCode = alcGetError(AudioDevice)) != ALC_NO_ERROR) {
LOG(("Audio Context Error: %1, %2").arg(errCode).arg((const char *)alcGetString(AudioDevice, errCode)));
return true;
}
return false;
}
// Thread: Any.
bool PlaybackErrorHappened() {
ALenum errCode;
if ((errCode = alGetError()) != AL_NO_ERROR) {
LOG(("Audio Playback Error: %1, %2").arg(errCode).arg((const char *)alGetString(errCode)));
return true;
}
return false;
}
void EnumeratePlaybackDevices() {
auto deviceNames = QStringList();
auto devices = [&] {
if (alcIsExtensionPresent(nullptr, "ALC_ENUMERATE_ALL_EXT")) {
return alcGetString(nullptr, alcGetEnumValue(nullptr, "ALC_ALL_DEVICES_SPECIFIER"));
} else {
return alcGetString(nullptr, ALC_DEVICE_SPECIFIER);
}
}();
Assert(devices != nullptr);
while (*devices != 0) {
auto deviceName8Bit = QByteArray(devices);
auto deviceName = QString::fromUtf8(deviceName8Bit);
deviceNames.append(deviceName);
devices += deviceName8Bit.size() + 1;
}
LOG(("Audio Playback Devices: %1").arg(deviceNames.join(';')));
auto device = [&] {
if (alcIsExtensionPresent(nullptr, "ALC_ENUMERATE_ALL_EXT")) {
return alcGetString(nullptr, alcGetEnumValue(nullptr, "ALC_DEFAULT_ALL_DEVICES_SPECIFIER"));
} else {
return alcGetString(nullptr, ALC_DEFAULT_DEVICE_SPECIFIER);
}
}();
if (device) {
LOG(("Audio Playback Default Device: %1").arg(QString::fromUtf8(device)));
} else {
LOG(("Audio Playback Default Device: (null)"));
}
}
void EnumerateCaptureDevices() {
auto deviceNames = QStringList();
auto devices = alcGetString(nullptr, ALC_CAPTURE_DEVICE_SPECIFIER);
Assert(devices != nullptr);
while (*devices != 0) {
auto deviceName8Bit = QByteArray(devices);
auto deviceName = QString::fromUtf8(deviceName8Bit);
deviceNames.append(deviceName);
devices += deviceName8Bit.size() + 1;
}
LOG(("Audio Capture Devices: %1").arg(deviceNames.join(';')));
if (auto device = alcGetString(nullptr, ALC_CAPTURE_DEFAULT_DEVICE_SPECIFIER)) {
LOG(("Audio Capture Default Device: %1").arg(QString::fromUtf8(device)));
} else {
LOG(("Audio Capture Default Device: (null)"));
}
}
// Thread: Any. Must be locked: AudioMutex.
void DestroyPlaybackDevice() {
if (AudioContext) {
alcMakeContextCurrent(nullptr);
alcDestroyContext(AudioContext);
AudioContext = nullptr;
}
if (AudioDevice) {
alcCloseDevice(AudioDevice);
AudioDevice = nullptr;
}
}
// Thread: Any. Must be locked: AudioMutex.
bool CreatePlaybackDevice() {
if (AudioDevice) return true;
AudioDevice = alcOpenDevice(nullptr);
if (!AudioDevice) {
LOG(("Audio Error: Could not create default playback device, enumerating.."));
EnumeratePlaybackDevices();
return false;
}
AudioContext = alcCreateContext(AudioDevice, nullptr);
alcMakeContextCurrent(AudioContext);
if (ContextErrorHappened()) {
DestroyPlaybackDevice();
return false;
}
ALfloat v[] = { 0.f, 0.f, -1.f, 0.f, 1.f, 0.f };
alListener3f(AL_POSITION, 0.f, 0.f, 0.f);
alListener3f(AL_VELOCITY, 0.f, 0.f, 0.f);
alListenerfv(AL_ORIENTATION, v);
alDistanceModel(AL_NONE);
return true;
}
// Thread: Main. Must be locked: AudioMutex.
void ClosePlaybackDevice(not_null<Instance*> instance) {
if (!AudioDevice) return;
LOG(("Audio Info: Closing audio playback device."));
if (Player::mixer()) {
Player::mixer()->detachTracks();
}
instance->detachTracks();
DestroyPlaybackDevice();
}
} // namespace
// Thread: Main.
void Start(not_null<Instance*> instance) {
Assert(AudioDevice == nullptr);
qRegisterMetaType<AudioMsgId>();
qRegisterMetaType<VoiceWaveform>();
auto loglevel = getenv("ALSOFT_LOGLEVEL");
LOG(("OpenAL Logging Level: %1").arg(loglevel ? loglevel : "(not set)"));
OpenAL::LoadEFXExtension();
EnumeratePlaybackDevices();
EnumerateCaptureDevices();
MixerInstance = new Player::Mixer(instance);
Platform::Audio::Init();
}
// Thread: Main.
void Finish(not_null<Instance*> instance) {
Platform::Audio::DeInit();
// MixerInstance variable should be modified under AudioMutex protection.
// So it is modified in the ~Mixer() destructor after all tracks are cleared.
delete MixerInstance;
// No sync required already.
ClosePlaybackDevice(instance);
}
// Thread: Main. Locks: AudioMutex.
bool IsAttachedToDevice() {
QMutexLocker lock(&AudioMutex);
return (AudioDevice != nullptr);
}
// Thread: Any. Must be locked: AudioMutex.
bool AttachToDevice() {
if (AudioDevice) {
return true;
}
LOG(("Audio Info: recreating audio device and reattaching the tracks"));
CreatePlaybackDevice();
if (!AudioDevice) {
return false;
}
if (auto m = Player::mixer()) {
m->reattachTracks();
emit m->faderOnTimer();
}
crl::on_main([] {
if (!App::quitting()) {
Current().reattachTracks();
}
});
return true;
}
void ScheduleDetachFromDeviceSafe() {
crl::on_main([] {
if (!App::quitting()) {
Current().scheduleDetachFromDevice();
}
});
}
void ScheduleDetachIfNotUsedSafe() {
crl::on_main([] {
if (!App::quitting()) {
Current().scheduleDetachIfNotUsed();
}
});
}
void StopDetachIfNotUsedSafe() {
crl::on_main([] {
if (!App::quitting()) {
Current().stopDetachIfNotUsed();
}
});
}
bool SupportsSpeedControl() {
return OpenAL::HasEFXExtension();
}
} // namespace Audio
namespace Player {
namespace {
constexpr auto kVolumeRound = 10000;
constexpr auto kPreloadSamples = 2LL * kDefaultFrequency; // preload next part if less than 2 seconds remains
constexpr auto kFadeDuration = crl::time(500);
constexpr auto kCheckPlaybackPositionTimeout = crl::time(100); // 100ms per check audio position
constexpr auto kCheckPlaybackPositionDelta = 2400LL; // update position called each 2400 samples
constexpr auto kCheckFadingTimeout = crl::time(7); // 7ms
base::Observable<AudioMsgId> UpdatedObservable;
} // namespace
base::Observable<AudioMsgId> &Updated() {
return UpdatedObservable;
}
// Thread: Any. Must be locked: AudioMutex.
float64 ComputeVolume(AudioMsgId::Type type) {
switch (type) {
case AudioMsgId::Type::Voice: return VolumeMultiplierAll;
case AudioMsgId::Type::Song: return VolumeMultiplierSong * mixer()->getSongVolume();
case AudioMsgId::Type::Video: return mixer()->getVideoVolume();
}
return 1.;
}
Mixer *mixer() {
return Audio::MixerInstance;
}
void Mixer::Track::createStream(AudioMsgId::Type type) {
alGenSources(1, &stream.source);
alSourcef(stream.source, AL_PITCH, 1.f);
alSource3f(stream.source, AL_POSITION, 0, 0, 0);
alSource3f(stream.source, AL_VELOCITY, 0, 0, 0);
alSourcei(stream.source, AL_LOOPING, 0);
alSourcei(stream.source, AL_SOURCE_RELATIVE, 1);
alSourcei(stream.source, AL_ROLLOFF_FACTOR, 0);
alGenBuffers(3, stream.buffers);
if (speedEffect) {
applySourceSpeedEffect();
} else {
removeSourceSpeedEffect();
}
}
void Mixer::Track::removeSourceSpeedEffect() {
if (!Audio::SupportsSpeedControl()) {
return;
}
alSource3i(stream.source, alGetEnumValue("AL_AUXILIARY_SEND_FILTER"), alGetEnumValue("AL_EFFECTSLOT_NULL"), 0, 0);
alSourcei(stream.source, alGetEnumValue("AL_DIRECT_FILTER"), alGetEnumValue("AL_FILTER_NULL"));
alSourcef(stream.source, AL_PITCH, 1.f);
}
void Mixer::Track::applySourceSpeedEffect() {
if (!Audio::SupportsSpeedControl()) {
return;
}
Expects(speedEffect != nullptr);
if (!speedEffect->effect || !OpenAL::alIsEffect(speedEffect->effect)) {
OpenAL::alGenAuxiliaryEffectSlots(1, &speedEffect->effectSlot);
OpenAL::alGenEffects(1, &speedEffect->effect);
OpenAL::alGenFilters(1, &speedEffect->filter);
OpenAL::alEffecti(speedEffect->effect, alGetEnumValue("AL_EFFECT_TYPE"), alGetEnumValue("AL_EFFECT_PITCH_SHIFTER"));
OpenAL::alFilteri(speedEffect->filter, alGetEnumValue("AL_FILTER_TYPE"), alGetEnumValue("AL_FILTER_LOWPASS"));
OpenAL::alFilterf(speedEffect->filter, alGetEnumValue("AL_LOWPASS_GAIN"), 0.f);
}
OpenAL::alEffecti(speedEffect->effect, alGetEnumValue("AL_PITCH_SHIFTER_COARSE_TUNE"), speedEffect->coarseTune);
OpenAL::alAuxiliaryEffectSloti(speedEffect->effectSlot, alGetEnumValue("AL_EFFECTSLOT_EFFECT"), speedEffect->effect);
alSourcef(stream.source, AL_PITCH, speedEffect->speed);
alSource3i(stream.source, alGetEnumValue("AL_AUXILIARY_SEND_FILTER"), speedEffect->effectSlot, 0, 0);
alSourcei(stream.source, alGetEnumValue("AL_DIRECT_FILTER"), speedEffect->filter);
}
void Mixer::Track::destroyStream() {
if (isStreamCreated()) {
alDeleteBuffers(3, stream.buffers);
alDeleteSources(1, &stream.source);
}
stream.source = 0;
for (auto i = 0; i != 3; ++i) {
stream.buffers[i] = 0;
}
resetSpeedEffect();
}
void Mixer::Track::resetSpeedEffect() {
if (!Audio::SupportsSpeedControl()) {
return;
}
if (!speedEffect) {
return;
} else if (speedEffect->effect && OpenAL::alIsEffect(speedEffect->effect)) {
if (isStreamCreated()) {
removeSourceSpeedEffect();
}
OpenAL::alDeleteEffects(1, &speedEffect->effect);
OpenAL::alDeleteAuxiliaryEffectSlots(1, &speedEffect->effectSlot);
OpenAL::alDeleteFilters(1, &speedEffect->filter);
}
speedEffect->effect = speedEffect->effectSlot = speedEffect->filter = 0;
}
void Mixer::Track::reattach(AudioMsgId::Type type) {
if (isStreamCreated()
|| (!samplesCount[0] && !state.id.externalPlayId())) {
return;
}
createStream(type);
for (auto i = 0; i != kBuffersCount; ++i) {
if (!samplesCount[i]) {
break;
}
alBufferData(stream.buffers[i], format, bufferSamples[i].constData(), bufferSamples[i].size(), frequency);
alSourceQueueBuffers(stream.source, 1, stream.buffers + i);
}
alSourcei(stream.source, AL_SAMPLE_OFFSET, qMax(state.position - bufferedPosition, 0LL));
if (!IsStopped(state.state)
&& (state.state != State::PausedAtEnd)
&& !state.waitingForData) {
alSourcef(stream.source, AL_GAIN, ComputeVolume(type));
alSourcePlay(stream.source);
if (IsPaused(state.state)) {
// We must always start the source if we want the AL_SAMPLE_OFFSET to be applied.
// Otherwise it won't be read by alGetSource and we'll get a corrupt position.
// So in case of a paused source we start it and then immediately pause it.
alSourcePause(stream.source);
}
}
}
void Mixer::Track::detach() {
getNotQueuedBufferIndex();
resetStream();
destroyStream();
}
void Mixer::Track::clear() {
detach();
state = TrackState();
file = FileLocation();
data = QByteArray();
bufferedPosition = 0;
bufferedLength = 0;
loading = false;
loaded = false;
fadeStartPosition = 0;
format = 0;
frequency = kDefaultFrequency;
for (int i = 0; i != kBuffersCount; ++i) {
samplesCount[i] = 0;
bufferSamples[i] = QByteArray();
}
setExternalData(nullptr);
lastUpdateWhen = 0;
lastUpdatePosition = 0;
}
void Mixer::Track::started() {
resetStream();
bufferedPosition = 0;
bufferedLength = 0;
loaded = false;
fadeStartPosition = 0;
format = 0;
frequency = kDefaultFrequency;
for (auto i = 0; i != kBuffersCount; ++i) {
samplesCount[i] = 0;
bufferSamples[i] = QByteArray();
}
}
bool Mixer::Track::isStreamCreated() const {
return alIsSource(stream.source);
}
void Mixer::Track::ensureStreamCreated(AudioMsgId::Type type) {
if (!isStreamCreated()) {
createStream(type);
}
}
int Mixer::Track::getNotQueuedBufferIndex() {
// See if there are no free buffers right now.
while (samplesCount[kBuffersCount - 1] != 0) {
// Try to unqueue some buffer.
ALint processed = 0;
alGetSourcei(stream.source, AL_BUFFERS_PROCESSED, &processed);
if (processed < 1) { // No processed buffers, wait.
return -1;
}
// Unqueue some processed buffer.
ALuint buffer = 0;
alSourceUnqueueBuffers(stream.source, 1, &buffer);
// Find it in the list and clear it.
bool found = false;
for (auto i = 0; i != kBuffersCount; ++i) {
if (stream.buffers[i] == buffer) {
auto samplesInBuffer = samplesCount[i];
bufferedPosition += samplesInBuffer;
bufferedLength -= samplesInBuffer;
for (auto j = i + 1; j != kBuffersCount; ++j) {
samplesCount[j - 1] = samplesCount[j];
stream.buffers[j - 1] = stream.buffers[j];
bufferSamples[j - 1] = bufferSamples[j];
}
samplesCount[kBuffersCount - 1] = 0;
stream.buffers[kBuffersCount - 1] = buffer;
bufferSamples[kBuffersCount - 1] = QByteArray();
found = true;
break;
}
}
if (!found) {
LOG(("Audio Error: Could not find the unqueued buffer! Buffer %1 in source %2 with processed count %3").arg(buffer).arg(stream.source).arg(processed));
return -1;
}
}
for (auto i = 0; i != kBuffersCount; ++i) {
if (!samplesCount[i]) {
return i;
}
}
return -1;
}
void Mixer::Track::setExternalData(
std::unique_ptr<ExternalSoundData> data) {
changeSpeedEffect(data ? data->speed : 1.);
externalData = std::move(data);
}
void Mixer::Track::changeSpeedEffect(float64 speed) {
if (!Audio::SupportsSpeedControl()) {
return;
}
if (speed != 1.) {
if (!speedEffect) {
speedEffect = std::make_unique<SpeedEffect>();
}
speedEffect->speed = speed;
speedEffect->coarseTune = CoarseTuneForSpeed(speed);
if (isStreamCreated()) {
applySourceSpeedEffect();
}
} else if (speedEffect) {
resetSpeedEffect();
speedEffect = nullptr;
}
}
void Mixer::Track::resetStream() {
if (isStreamCreated()) {
alSourceStop(stream.source);
alSourcei(stream.source, AL_BUFFER, AL_NONE);
}
}
Mixer::Track::~Track() = default;
Mixer::Mixer(not_null<Audio::Instance*> instance)
: _instance(instance)
, _volumeVideo(kVolumeRound)
, _volumeSong(kVolumeRound)
, _fader(new Fader(&_faderThread))
, _loader(new Loaders(&_loaderThread)) {
connect(this, SIGNAL(faderOnTimer()), _fader, SLOT(onTimer()), Qt::QueuedConnection);
connect(this, SIGNAL(suppressSong()), _fader, SLOT(onSuppressSong()));
connect(this, SIGNAL(unsuppressSong()), _fader, SLOT(onUnsuppressSong()));
connect(this, SIGNAL(suppressAll(qint64)), _fader, SLOT(onSuppressAll(qint64)));
Core::App().settings().songVolumeChanges(
) | rpl::start_with_next([=] {
QMetaObject::invokeMethod(_fader, "onSongVolumeChanged");
}, _lifetime);
Core::App().settings().videoVolumeChanges(
) | rpl::start_with_next([=] {
QMetaObject::invokeMethod(_fader, "onVideoVolumeChanged");
}, _lifetime);
connect(this, SIGNAL(loaderOnStart(const AudioMsgId&, qint64)), _loader, SLOT(onStart(const AudioMsgId&, qint64)));
connect(this, SIGNAL(loaderOnCancel(const AudioMsgId&)), _loader, SLOT(onCancel(const AudioMsgId&)));
connect(_loader, SIGNAL(needToCheck()), _fader, SLOT(onTimer()));
connect(_loader, SIGNAL(error(const AudioMsgId&)), this, SLOT(onError(const AudioMsgId&)));
connect(_fader, SIGNAL(needToPreload(const AudioMsgId&)), _loader, SLOT(onLoad(const AudioMsgId&)));
connect(_fader, SIGNAL(playPositionUpdated(const AudioMsgId&)), this, SIGNAL(updated(const AudioMsgId&)));
connect(_fader, SIGNAL(audioStopped(const AudioMsgId&)), this, SLOT(onStopped(const AudioMsgId&)));
connect(_fader, SIGNAL(error(const AudioMsgId&)), this, SLOT(onError(const AudioMsgId&)));
connect(this, SIGNAL(stoppedOnError(const AudioMsgId&)), this, SIGNAL(updated(const AudioMsgId&)), Qt::QueuedConnection);
connect(this, SIGNAL(updated(const AudioMsgId&)), this, SLOT(onUpdated(const AudioMsgId&)));
_loaderThread.start();
_faderThread.start();
}
// Thread: Main. Locks: AudioMutex.
Mixer::~Mixer() {
{
QMutexLocker lock(&AudioMutex);
for (auto i = 0; i != kTogetherLimit; ++i) {
trackForType(AudioMsgId::Type::Voice, i)->clear();
trackForType(AudioMsgId::Type::Song, i)->clear();
}
_videoTrack.clear();
Audio::ClosePlaybackDevice(_instance);
Audio::MixerInstance = nullptr;
}
_faderThread.quit();
_loaderThread.quit();
_faderThread.wait();
_loaderThread.wait();
}
void Mixer::onUpdated(const AudioMsgId &audio) {
if (audio.externalPlayId()) {
externalSoundProgress(audio);
}
Media::Player::Updated().notify(audio);
}
void Mixer::onError(const AudioMsgId &audio) {
emit stoppedOnError(audio);
QMutexLocker lock(&AudioMutex);
auto type = audio.type();
if (type == AudioMsgId::Type::Voice) {
if (auto current = trackForType(type)) {
if (current->state.id == audio) {
emit unsuppressSong();
}
}
}
}
void Mixer::onStopped(const AudioMsgId &audio) {
emit updated(audio);
QMutexLocker lock(&AudioMutex);
auto type = audio.type();
if (type == AudioMsgId::Type::Voice) {
if (auto current = trackForType(type)) {
if (current->state.id == audio) {
emit unsuppressSong();
}
}
}
}
Mixer::Track *Mixer::trackForType(AudioMsgId::Type type, int index) {
if (index < 0) {
if (auto indexPtr = currentIndex(type)) {
index = *indexPtr;
} else {
return nullptr;
}
}
switch (type) {
case AudioMsgId::Type::Voice: return &_audioTracks[index];
case AudioMsgId::Type::Song: return &_songTracks[index];
case AudioMsgId::Type::Video: return &_videoTrack;
}
return nullptr;
}
const Mixer::Track *Mixer::trackForType(AudioMsgId::Type type, int index) const {
return const_cast<Mixer*>(this)->trackForType(type, index);
}
int *Mixer::currentIndex(AudioMsgId::Type type) {
switch (type) {
case AudioMsgId::Type::Voice: return &_audioCurrent;
case AudioMsgId::Type::Song: return &_songCurrent;
case AudioMsgId::Type::Video: { static int videoIndex = 0; return &videoIndex; }
}
return nullptr;
}
const int *Mixer::currentIndex(AudioMsgId::Type type) const {
return const_cast<Mixer*>(this)->currentIndex(type);
}
void Mixer::resetFadeStartPosition(AudioMsgId::Type type, int positionInBuffered) {
auto track = trackForType(type);
if (!track) return;
if (positionInBuffered < 0) {
Audio::AttachToDevice();
if (track->isStreamCreated()) {
ALint alSampleOffset = 0;
ALint alState = AL_INITIAL;
alGetSourcei(track->stream.source, AL_SAMPLE_OFFSET, &alSampleOffset);
alGetSourcei(track->stream.source, AL_SOURCE_STATE, &alState);
if (Audio::PlaybackErrorHappened()) {
setStoppedState(track, State::StoppedAtError);
onError(track->state.id);
return;
} else if ((alState == AL_STOPPED)
&& (alSampleOffset == 0)
&& !internal::CheckAudioDeviceConnected()) {
track->fadeStartPosition = track->state.position;
return;
}
const auto stoppedAtEnd = track->state.waitingForData
|| ((alState == AL_STOPPED)
&& (!IsStopped(track->state.state)
|| IsStoppedAtEnd(track->state.state)));
positionInBuffered = stoppedAtEnd
? track->bufferedLength
: alSampleOffset;
} else {
positionInBuffered = 0;
}
}
auto fullPosition = track->samplesCount[0]
? (track->bufferedPosition + positionInBuffered)
: track->state.position;
track->state.position = fullPosition;
track->fadeStartPosition = fullPosition;
}
bool Mixer::fadedStop(AudioMsgId::Type type, bool *fadedStart) {
auto current = trackForType(type);
if (!current) return false;
switch (current->state.state) {
case State::Starting:
case State::Resuming:
case State::Playing: {
current->state.state = State::Stopping;
resetFadeStartPosition(type);
if (fadedStart) *fadedStart = true;
} break;
case State::Pausing: {
current->state.state = State::Stopping;
if (fadedStart) *fadedStart = true;
} break;
case State::Paused:
case State::PausedAtEnd: {
setStoppedState(current);
} return true;
}
return false;
}
void Mixer::play(
const AudioMsgId &audio,
std::unique_ptr<ExternalSoundData> externalData,
crl::time positionMs) {
Expects(externalData != nullptr);
Expects(audio.externalPlayId() != 0);
setSongVolume(Core::App().settings().songVolume());
setVideoVolume(Core::App().settings().videoVolume());
auto type = audio.type();
AudioMsgId stopped;
{
QMutexLocker lock(&AudioMutex);
Audio::AttachToDevice();
if (!AudioDevice) return;
auto fadedStart = false;
auto current = trackForType(type);
if (!current) return;
if (current->state.id != audio) {
if (fadedStop(type, &fadedStart)) {
stopped = current->state.id;
}
if (current->state.id) {
emit loaderOnCancel(current->state.id);
emit faderOnTimer();
}
if (type != AudioMsgId::Type::Video) {
auto foundCurrent = currentIndex(type);
auto index = 0;
for (; index != kTogetherLimit; ++index) {
if (trackForType(type, index)->state.id == audio) {
*foundCurrent = index;
break;
}
}
if (index == kTogetherLimit && ++*foundCurrent >= kTogetherLimit) {
*foundCurrent -= kTogetherLimit;
}
current = trackForType(type);
}
}
current->clear(); // Clear all previous state.
current->state.id = audio;
current->lastUpdateWhen = 0;
current->lastUpdatePosition = 0;
current->setExternalData(std::move(externalData));
current->state.position = (positionMs * current->state.frequency)
/ 1000LL;
current->state.state = current->externalData
? State::Paused
: fadedStart
? State::Starting
: State::Playing;
current->loading = true;
emit loaderOnStart(current->state.id, positionMs);
if (type == AudioMsgId::Type::Voice) {
emit suppressSong();
}
}
if (stopped) {
emit updated(stopped);
}
}
void Mixer::feedFromExternal(ExternalSoundPart &&part) {
_loader->feedFromExternal(std::move(part));
}
void Mixer::forceToBufferExternal(const AudioMsgId &audioId) {
_loader->forceToBufferExternal(audioId);
}
void Mixer::setSpeedFromExternal(const AudioMsgId &audioId, float64 speed) {
QMutexLocker lock(&AudioMutex);
const auto track = trackForType(audioId.type());
if (track->state.id == audioId) {
track->changeSpeedEffect(speed);
}
}
Streaming::TimePoint Mixer::getExternalSyncTimePoint(
const AudioMsgId &audio) const {
Expects(audio.externalPlayId() != 0);
auto result = Streaming::TimePoint();
const auto type = audio.type();
QMutexLocker lock(&AudioMutex);
const auto track = trackForType(type);
if (track && track->state.id == audio && track->lastUpdateWhen > 0) {
result.trackTime = track->lastUpdatePosition;
result.worldTime = track->lastUpdateWhen;
}
return result;
}
crl::time Mixer::getExternalCorrectedTime(const AudioMsgId &audio, crl::time frameMs, crl::time systemMs) {
auto result = frameMs;
const auto type = audio.type();
QMutexLocker lock(&AudioMutex);
const auto track = trackForType(type);
if (track && track->state.id == audio && track->lastUpdateWhen > 0) {
result = static_cast<crl::time>(track->lastUpdatePosition);
if (systemMs > track->lastUpdateWhen) {
result += (systemMs - track->lastUpdateWhen);
}
}
return result;
}
void Mixer::externalSoundProgress(const AudioMsgId &audio) {
const auto type = audio.type();
QMutexLocker lock(&AudioMutex);
const auto current = trackForType(type);
if (current && current->state.length && current->state.frequency) {
if (current->state.id == audio && current->state.state == State::Playing) {
current->lastUpdateWhen = crl::now();
current->lastUpdatePosition = (current->state.position * 1000ULL) / current->state.frequency;
}
}
}
bool Mixer::checkCurrentALError(AudioMsgId::Type type) {
if (!Audio::PlaybackErrorHappened()) return true;
const auto data = trackForType(type);
if (!data) {
setStoppedState(data, State::StoppedAtError);
onError(data->state.id);
}
return false;
}
void Mixer::pause(const AudioMsgId &audio, bool fast) {
AudioMsgId current;
{
QMutexLocker lock(&AudioMutex);
auto type = audio.type();
auto track = trackForType(type);
if (!track || track->state.id != audio) {
return;
}
current = track->state.id;
switch (track->state.state) {
case State::Starting:
case State::Resuming:
case State::Playing: {
track->state.state = fast ? State::Paused : State::Pausing;
resetFadeStartPosition(type);
if (type == AudioMsgId::Type::Voice) {
emit unsuppressSong();
}
} break;
case State::Pausing:
case State::Stopping: {
track->state.state = fast ? State::Paused : State::Pausing;
} break;
}
if (fast && track->isStreamCreated()) {
ALint state = AL_INITIAL;
alGetSourcei(track->stream.source, AL_SOURCE_STATE, &state);
if (!checkCurrentALError(type)) return;
if (state == AL_PLAYING) {
alSourcePause(track->stream.source);
if (!checkCurrentALError(type)) return;
}
}
emit faderOnTimer();
track->lastUpdateWhen = 0;
track->lastUpdatePosition = 0;
}
if (current) emit updated(current);
}
void Mixer::resume(const AudioMsgId &audio, bool fast) {
AudioMsgId current;
{
QMutexLocker lock(&AudioMutex);
auto type = audio.type();
auto track = trackForType(type);
if (!track || track->state.id != audio) {
return;
}
current = track->state.id;
switch (track->state.state) {
case State::Pausing:
case State::Paused:
case State::PausedAtEnd: {
if (track->state.state == State::Paused) {
// This calls Audio::AttachToDevice().
resetFadeStartPosition(type);
} else {
Audio::AttachToDevice();
}
track->state.state = fast ? State::Playing : State::Resuming;
if (track->isStreamCreated()) {
// When starting the video audio is in paused state and
// gets resumed before the stream is created with any data.
ALint state = AL_INITIAL;
alGetSourcei(track->stream.source, AL_SOURCE_STATE, &state);
if (!checkCurrentALError(type)) return;
if (state != AL_PLAYING) {
if (state == AL_STOPPED && !internal::CheckAudioDeviceConnected()) {
return;
}
alSourcef(track->stream.source, AL_GAIN, ComputeVolume(type));
if (!checkCurrentALError(type)) return;
if (state == AL_STOPPED) {
alSourcei(track->stream.source, AL_SAMPLE_OFFSET, qMax(track->state.position - track->bufferedPosition, 0LL));
if (!checkCurrentALError(type)) return;
}
alSourcePlay(track->stream.source);
if (!checkCurrentALError(type)) return;
}
if (type == AudioMsgId::Type::Voice) {
emit suppressSong();
}
}
} break;
}
emit faderOnTimer();
}
if (current) emit updated(current);
}
//
// Right now all the music is played in the streaming player.
//
//void Mixer::seek(AudioMsgId::Type type, crl::time positionMs) {
// QMutexLocker lock(&AudioMutex);
//
// const auto current = trackForType(type);
// const auto audio = current->state.id;
//
// Audio::AttachToDevice();
// const auto streamCreated = current->isStreamCreated();
// const auto position = (positionMs * current->frequency) / 1000LL;
// const auto fastSeek = [&] {
// const auto loadedStart = current->bufferedPosition;
// const auto loadedLength = current->bufferedLength;
// const auto skipBack = (current->loaded ? 0 : kDefaultFrequency);
// const auto availableEnd = loadedStart + loadedLength - skipBack;
// if (position < loadedStart) {
// return false;
// } else if (position >= availableEnd) {
// return false;
// } else if (!streamCreated) {
// return false;
// } else if (IsStoppedOrStopping(current->state.state)) {
// return false;
// }
// return true;
// }();
// if (fastSeek) {
// alSourcei(current->stream.source, AL_SAMPLE_OFFSET, position - current->bufferedPosition);
// if (!checkCurrentALError(type)) return;
//
// alSourcef(current->stream.source, AL_GAIN, ComputeVolume(type));
// if (!checkCurrentALError(type)) return;
//
// resetFadeStartPosition(type, position - current->bufferedPosition);
// } else {
// setStoppedState(current);
// }
// switch (current->state.state) {
// case State::Pausing:
// case State::Paused:
// case State::PausedAtEnd: {
// if (current->state.state == State::PausedAtEnd) {
// current->state.state = State::Paused;
// }
// lock.unlock();
// return resume(audio, true);
// } break;
// case State::Starting:
// case State::Resuming:
// case State::Playing: {
// current->state.state = State::Pausing;
// resetFadeStartPosition(type);
// if (type == AudioMsgId::Type::Voice) {
// emit unsuppressSong();
// }
// } break;
// case State::Stopping:
// case State::Stopped:
// case State::StoppedAtEnd:
// case State::StoppedAtError:
// case State::StoppedAtStart: {
// lock.unlock();
// } return play(audio, positionMs);
// }
// emit faderOnTimer();
//}
void Mixer::stop(const AudioMsgId &audio) {
AudioMsgId current;
{
QMutexLocker lock(&AudioMutex);
auto type = audio.type();
auto track = trackForType(type);
if (!track || track->state.id != audio) {
return;
}
current = audio;
fadedStop(type);
if (type == AudioMsgId::Type::Voice) {
emit unsuppressSong();
} else if (type == AudioMsgId::Type::Video) {
track->clear();
emit loaderOnCancel(audio);
}
}
if (current) emit updated(current);
}
void Mixer::stop(const AudioMsgId &audio, State state) {
Expects(IsStopped(state));
AudioMsgId current;
{
QMutexLocker lock(&AudioMutex);
auto type = audio.type();
auto track = trackForType(type);
if (!track
|| track->state.id != audio
|| IsStopped(track->state.state)) {
return;
}
current = audio;
setStoppedState(track, state);
if (type == AudioMsgId::Type::Voice) {
emit unsuppressSong();
} else if (type == AudioMsgId::Type::Video) {
track->clear();
}
}
if (current) emit updated(current);
}
void Mixer::stopAndClear() {
Track *current_audio = nullptr, *current_song = nullptr;
{
QMutexLocker lock(&AudioMutex);
if ((current_audio = trackForType(AudioMsgId::Type::Voice))) {
setStoppedState(current_audio);
}
if ((current_song = trackForType(AudioMsgId::Type::Song))) {
setStoppedState(current_song);
}
}
if (current_song) {
emit updated(current_song->state.id);
}
if (current_audio) {
emit updated(current_audio->state.id);
}
{
QMutexLocker lock(&AudioMutex);
auto clearAndCancel = [this](AudioMsgId::Type type, int index) {
auto track = trackForType(type, index);
if (track->state.id) {
emit loaderOnCancel(track->state.id);
}
track->clear();
};
for (auto index = 0; index != kTogetherLimit; ++index) {
clearAndCancel(AudioMsgId::Type::Voice, index);
clearAndCancel(AudioMsgId::Type::Song, index);
}
_videoTrack.clear();
}
}
TrackState Mixer::currentState(AudioMsgId::Type type) {
QMutexLocker lock(&AudioMutex);
auto current = trackForType(type);
if (!current) {
return TrackState();
}
return current->state;
}
void Mixer::setStoppedState(Track *current, State state) {
current->state.state = state;
current->state.position = 0;
if (current->isStreamCreated()) {
alSourceStop(current->stream.source);
alSourcef(current->stream.source, AL_GAIN, 1);
}
if (current->state.id) {
emit loaderOnCancel(current->state.id);
}
}
// Thread: Main. Must be locked: AudioMutex.
void Mixer::detachTracks() {
for (auto i = 0; i != kTogetherLimit; ++i) {
trackForType(AudioMsgId::Type::Voice, i)->detach();
trackForType(AudioMsgId::Type::Song, i)->detach();
}
_videoTrack.detach();
}
// Thread: Main. Must be locked: AudioMutex.
void Mixer::reattachIfNeeded() {
Audio::Current().stopDetachIfNotUsed();
auto reattachNeeded = [this] {
auto isPlayingState = [](const Track &track) {
auto state = track.state.state;
return (state == State::Playing) || IsFading(state);
};
for (auto i = 0; i != kTogetherLimit; ++i) {
if (isPlayingState(*trackForType(AudioMsgId::Type::Voice, i))
|| isPlayingState(*trackForType(AudioMsgId::Type::Song, i))) {
return true;
}
}
return isPlayingState(_videoTrack);
};
if (reattachNeeded() || Audio::Current().hasActiveTracks()) {
Audio::AttachToDevice();
}
}
// Thread: Any. Must be locked: AudioMutex.
void Mixer::reattachTracks() {
for (auto i = 0; i != kTogetherLimit; ++i) {
trackForType(AudioMsgId::Type::Voice, i)->reattach(AudioMsgId::Type::Voice);
trackForType(AudioMsgId::Type::Song, i)->reattach(AudioMsgId::Type::Song);
}
_videoTrack.reattach(AudioMsgId::Type::Video);
}
void Mixer::setSongVolume(float64 volume) {
_volumeSong.storeRelease(qRound(volume * kVolumeRound));
}
float64 Mixer::getSongVolume() const {
return float64(_volumeSong.loadAcquire()) / kVolumeRound;
}
void Mixer::setVideoVolume(float64 volume) {
_volumeVideo.storeRelease(qRound(volume * kVolumeRound));
}
float64 Mixer::getVideoVolume() const {
return float64(_volumeVideo.loadAcquire()) / kVolumeRound;
}
Fader::Fader(QThread *thread) : QObject()
, _timer(this)
, _suppressVolumeAll(1., 1.)
, _suppressVolumeSong(1., 1.) {
moveToThread(thread);
_timer.moveToThread(thread);
connect(thread, SIGNAL(started()), this, SLOT(onInit()));
connect(thread, SIGNAL(finished()), this, SLOT(deleteLater()));
_timer.setSingleShot(true);
connect(&_timer, SIGNAL(timeout()), this, SLOT(onTimer()));
}
void Fader::onInit() {
}
void Fader::onTimer() {
QMutexLocker lock(&AudioMutex);
if (!mixer()) return;
auto volumeChangedAll = false;
auto volumeChangedSong = false;
if (_suppressAll || _suppressSongAnim) {
auto ms = crl::now();
if (_suppressAll) {
if (ms >= _suppressAllEnd || ms < _suppressAllStart) {
_suppressAll = _suppressAllAnim = false;
_suppressVolumeAll = anim::value(1., 1.);
} else if (ms > _suppressAllEnd - kFadeDuration) {
if (_suppressVolumeAll.to() != 1.) _suppressVolumeAll.start(1.);
_suppressVolumeAll.update(1. - ((_suppressAllEnd - ms) / float64(kFadeDuration)), anim::linear);
} else if (ms >= _suppressAllStart + st::mediaPlayerSuppressDuration) {
if (_suppressAllAnim) {
_suppressVolumeAll.finish();
_suppressAllAnim = false;
}
} else if (ms > _suppressAllStart) {
_suppressVolumeAll.update((ms - _suppressAllStart) / float64(st::mediaPlayerSuppressDuration), anim::linear);
}
auto wasVolumeMultiplierAll = VolumeMultiplierAll;
VolumeMultiplierAll = _suppressVolumeAll.current();
volumeChangedAll = (VolumeMultiplierAll != wasVolumeMultiplierAll);
}
if (_suppressSongAnim) {
if (ms >= _suppressSongStart + kFadeDuration) {
_suppressVolumeSong.finish();
_suppressSongAnim = false;
} else {
_suppressVolumeSong.update((ms - _suppressSongStart) / float64(kFadeDuration), anim::linear);
}
}
auto wasVolumeMultiplierSong = VolumeMultiplierSong;
VolumeMultiplierSong = _suppressVolumeSong.current();
accumulate_min(VolumeMultiplierSong, VolumeMultiplierAll);
volumeChangedSong = (VolumeMultiplierSong != wasVolumeMultiplierSong);
}
auto hasFading = (_suppressAll || _suppressSongAnim);
auto hasPlaying = false;
auto updatePlayback = [this, &hasPlaying, &hasFading](AudioMsgId::Type type, int index, float64 volumeMultiplier, bool suppressGainChanged) {
auto track = mixer()->trackForType(type, index);
if (IsStopped(track->state.state) || track->state.state == State::Paused || !track->isStreamCreated()) return;
auto emitSignals = updateOnePlayback(track, hasPlaying, hasFading, volumeMultiplier, suppressGainChanged);
if (emitSignals & EmitError) emit error(track->state.id);
if (emitSignals & EmitStopped) emit audioStopped(track->state.id);
if (emitSignals & EmitPositionUpdated) emit playPositionUpdated(track->state.id);
if (emitSignals & EmitNeedToPreload) emit needToPreload(track->state.id);
};
auto suppressGainForMusic = ComputeVolume(AudioMsgId::Type::Song);
auto suppressGainForMusicChanged = volumeChangedSong || _volumeChangedSong;
for (auto i = 0; i != kTogetherLimit; ++i) {
updatePlayback(AudioMsgId::Type::Voice, i, VolumeMultiplierAll, volumeChangedAll);
updatePlayback(AudioMsgId::Type::Song, i, suppressGainForMusic, suppressGainForMusicChanged);
}
auto suppressGainForVideo = ComputeVolume(AudioMsgId::Type::Video);
auto suppressGainForVideoChanged = volumeChangedAll || _volumeChangedVideo;
updatePlayback(AudioMsgId::Type::Video, 0, suppressGainForVideo, suppressGainForVideoChanged);
_volumeChangedSong = _volumeChangedVideo = false;
if (hasFading) {
_timer.start(kCheckFadingTimeout);
Audio::StopDetachIfNotUsedSafe();
} else if (hasPlaying) {
_timer.start(kCheckPlaybackPositionTimeout);
Audio::StopDetachIfNotUsedSafe();
} else {
Audio::ScheduleDetachIfNotUsedSafe();
}
}
int32 Fader::updateOnePlayback(Mixer::Track *track, bool &hasPlaying, bool &hasFading, float64 volumeMultiplier, bool volumeChanged) {
const auto errorHappened = [&] {
if (Audio::PlaybackErrorHappened()) {
setStoppedState(track, State::StoppedAtError);
return true;
}
return false;
};
ALint alSampleOffset = 0;
ALint alState = AL_INITIAL;
alGetSourcei(track->stream.source, AL_SAMPLE_OFFSET, &alSampleOffset);
alGetSourcei(track->stream.source, AL_SOURCE_STATE, &alState);
if (errorHappened()) {
return EmitError;
} else if ((alState == AL_STOPPED)
&& (alSampleOffset == 0)
&& !internal::CheckAudioDeviceConnected()) {
return 0;
}
int32 emitSignals = 0;
const auto stoppedAtEnd = track->state.waitingForData
|| ((alState == AL_STOPPED)
&& (!IsStopped(track->state.state)
|| IsStoppedAtEnd(track->state.state)));
const auto positionInBuffered = stoppedAtEnd
? track->bufferedLength
: alSampleOffset;
const auto waitingForDataOld = track->state.waitingForData;
track->state.waitingForData = stoppedAtEnd
&& (track->state.state != State::Stopping);
const auto fullPosition = track->bufferedPosition + positionInBuffered;
auto playing = (track->state.state == State::Playing);
auto fading = IsFading(track->state.state);
if (alState != AL_PLAYING && !track->loading) {
if (fading || playing) {
fading = false;
playing = false;
if (track->state.state == State::Pausing) {
setStoppedState(track, State::PausedAtEnd);
} else if (track->state.state == State::Stopping) {
setStoppedState(track, State::Stopped);
} else {
setStoppedState(track, State::StoppedAtEnd);
}
if (errorHappened()) return EmitError;
emitSignals |= EmitStopped;
}
} else if (fading && alState == AL_PLAYING) {
auto fadingForSamplesCount = (fullPosition - track->fadeStartPosition);
if (crl::time(1000) * fadingForSamplesCount >= kFadeDuration * track->state.frequency) {
fading = false;
alSourcef(track->stream.source, AL_GAIN, 1. * volumeMultiplier);
if (errorHappened()) return EmitError;
switch (track->state.state) {
case State::Stopping: {
setStoppedState(track);
alState = AL_STOPPED;
} break;
case State::Pausing: {
alSourcePause(track->stream.source);
if (errorHappened()) return EmitError;
track->state.state = State::Paused;
} break;
case State::Starting:
case State::Resuming: {
track->state.state = State::Playing;
playing = true;
} break;
}
} else {
auto newGain = crl::time(1000) * fadingForSamplesCount / float64(kFadeDuration * track->state.frequency);
if (track->state.state == State::Pausing || track->state.state == State::Stopping) {
newGain = 1. - newGain;
}
alSourcef(track->stream.source, AL_GAIN, newGain * volumeMultiplier);
if (errorHappened()) return EmitError;
}
} else if (playing && alState == AL_PLAYING) {
if (volumeChanged) {
alSourcef(track->stream.source, AL_GAIN, 1. * volumeMultiplier);
if (errorHappened()) return EmitError;
}
}
if (alState == AL_PLAYING && fullPosition >= track->state.position + kCheckPlaybackPositionDelta) {
track->state.position = fullPosition;
emitSignals |= EmitPositionUpdated;
} else if (track->state.waitingForData && !waitingForDataOld) {
if (fullPosition > track->state.position) {
track->state.position = fullPosition;
}
// When stopped because of insufficient data while streaming,
// inform the player about the last position we were at.
emitSignals |= EmitPositionUpdated;
}
if (playing || track->state.state == State::Starting || track->state.state == State::Resuming) {
if (!track->loaded && !track->loading) {
auto needPreload = (track->state.position + kPreloadSamples > track->bufferedPosition + track->bufferedLength);
if (needPreload) {
track->loading = true;
emitSignals |= EmitNeedToPreload;
}
}
}
if (playing) hasPlaying = true;
if (fading) hasFading = true;
return emitSignals;
}
void Fader::setStoppedState(Mixer::Track *track, State state) {
mixer()->setStoppedState(track, state);
}
void Fader::onSuppressSong() {
if (!_suppressSong) {
_suppressSong = true;
_suppressSongAnim = true;
_suppressSongStart = crl::now();
_suppressVolumeSong.start(kSuppressRatioSong);
onTimer();
}
}
void Fader::onUnsuppressSong() {
if (_suppressSong) {
_suppressSong = false;
_suppressSongAnim = true;
_suppressSongStart = crl::now();
_suppressVolumeSong.start(1.);
onTimer();
}
}
void Fader::onSuppressAll(qint64 duration) {
_suppressAll = true;
auto now = crl::now();
if (_suppressAllEnd < now + kFadeDuration) {
_suppressAllStart = now;
}
_suppressAllEnd = now + duration;
_suppressVolumeAll.start(kSuppressRatioAll);
onTimer();
}
void Fader::onSongVolumeChanged() {
_volumeChangedSong = true;
onTimer();
}
void Fader::onVideoVolumeChanged() {
_volumeChangedVideo = true;
onTimer();
}
namespace internal {
// Thread: Any.
QMutex *audioPlayerMutex() {
return &AudioMutex;
}
// Thread: Any.
bool audioCheckError() {
return !Audio::PlaybackErrorHappened();
}
// Thread: Any. Must be locked: AudioMutex.
bool audioDeviceIsConnected() {
if (!AudioDevice) {
return false;
}
// always connected in the basic OpenAL, disconnect status is an extension
auto isConnected = ALint(1);
if (alcIsExtensionPresent(nullptr, "ALC_EXT_disconnect")) {
alcGetIntegerv(AudioDevice, alcGetEnumValue(nullptr, "ALC_CONNECTED"), 1, &isConnected);
}
if (Audio::ContextErrorHappened()) {
return false;
}
return (isConnected != 0);
}
// Thread: Any. Must be locked: AudioMutex.
bool CheckAudioDeviceConnected() {
if (audioDeviceIsConnected()) {
return true;
}
Audio::ScheduleDetachFromDeviceSafe();
return false;
}
// Thread: Main. Locks: AudioMutex.
void DetachFromDevice(not_null<Audio::Instance*> instance) {
QMutexLocker lock(&AudioMutex);
Audio::ClosePlaybackDevice(instance);
if (mixer()) {
mixer()->reattachIfNeeded();
}
}
} // namespace internal
} // namespace Player
class FFMpegAttributesReader : public AbstractFFMpegLoader {
public:
FFMpegAttributesReader(const FileLocation &file, const QByteArray &data)
: AbstractFFMpegLoader(file, data, bytes::vector()) {
}
bool open(crl::time positionMs) override {
if (!AbstractFFMpegLoader::open(positionMs)) {
return false;
}
int res = 0;
char err[AV_ERROR_MAX_STRING_SIZE] = { 0 };
int videoStreamId = av_find_best_stream(fmtContext, AVMEDIA_TYPE_VIDEO, -1, -1, &codec, 0);
if (videoStreamId >= 0) {
DEBUG_LOG(("Audio Read Error: Found video stream in file '%1', data size '%2', error %3, %4").arg(_file.name()).arg(_data.size()).arg(videoStreamId).arg(av_make_error_string(err, sizeof(err), streamId)));
return false;
}
for (int32 i = 0, l = fmtContext->nb_streams; i < l; ++i) {
const auto stream = fmtContext->streams[i];
if (stream->disposition & AV_DISPOSITION_ATTACHED_PIC) {
const auto &packet = stream->attached_pic;
if (packet.size) {
const auto coverBytes = QByteArray(
(const char*)packet.data,
packet.size);
auto format = QByteArray();
auto animated = false;
_cover = App::readImage(
coverBytes,
&format,
true,
&animated);
if (!_cover.isNull()) {
_coverBytes = coverBytes;
_coverFormat = format;
break;
}
}
}
}
extractMetaData(fmtContext->streams[streamId]->metadata);
extractMetaData(fmtContext->metadata);
return true;
}
void trySet(QString &to, AVDictionary *dict, const char *key) {
if (!to.isEmpty()) return;
if (AVDictionaryEntry* tag = av_dict_get(dict, key, nullptr, 0)) {
to = QString::fromUtf8(tag->value);
}
}
void extractMetaData(AVDictionary *dict) {
trySet(_title, dict, "title");
trySet(_performer, dict, "artist");
trySet(_performer, dict, "performer");
trySet(_performer, dict, "album_artist");
//for (AVDictionaryEntry *tag = av_dict_get(dict, "", 0, AV_DICT_IGNORE_SUFFIX); tag; tag = av_dict_get(dict, "", tag, AV_DICT_IGNORE_SUFFIX)) {
// const char *key = tag->key;
// const char *value = tag->value;
// QString tmp = QString::fromUtf8(value);
//}
}
int format() override {
return 0;
}
QString title() {
return _title;
}
QString performer() {
return _performer;
}
QImage cover() {
return _cover;
}
QByteArray coverBytes() {
return _coverBytes;
}
QByteArray coverFormat() {
return _coverFormat;
}
ReadResult readMore(QByteArray &result, int64 &samplesAdded) override {
DEBUG_LOG(("Audio Read Error: should not call this"));
return ReadResult::Error;
}
~FFMpegAttributesReader() {
}
private:
QString _title, _performer;
QImage _cover;
QByteArray _coverBytes, _coverFormat;
};
namespace Player {
FileMediaInformation::Song PrepareForSending(const QString &fname, const QByteArray &data) {
auto result = FileMediaInformation::Song();
FFMpegAttributesReader reader(FileLocation(fname), data);
const auto positionMs = crl::time(0);
if (reader.open(positionMs) && reader.samplesCount() > 0) {
result.duration = reader.samplesCount() / reader.samplesFrequency();
result.title = reader.title();
result.performer = reader.performer();
result.cover = reader.cover();
}
return result;
}
} // namespace Player
class FFMpegWaveformCounter : public FFMpegLoader {
public:
FFMpegWaveformCounter(const FileLocation &file, const QByteArray &data) : FFMpegLoader(file, data, bytes::vector()) {
}
bool open(crl::time positionMs) override {
if (!FFMpegLoader::open(positionMs)) {
return false;
}
QByteArray buffer;
buffer.reserve(kWaveformCounterBufferSize);
int64 countbytes = sampleSize() * samplesCount();
int64 processed = 0;
int64 sumbytes = 0;
if (samplesCount() < Media::Player::kWaveformSamplesCount) {
return false;
}
QVector<uint16> peaks;
peaks.reserve(Media::Player::kWaveformSamplesCount);
auto fmt = format();
auto peak = uint16(0);
auto callback = [&](uint16 sample) {
accumulate_max(peak, sample);
sumbytes += Media::Player::kWaveformSamplesCount;
if (sumbytes >= countbytes) {
sumbytes -= countbytes;
peaks.push_back(peak);
peak = 0;
}
};
while (processed < countbytes) {
buffer.resize(0);
int64 samples = 0;
auto res = readMore(buffer, samples);
if (res == ReadResult::Error || res == ReadResult::EndOfFile) {
break;
}
if (buffer.isEmpty()) {
continue;
}
auto sampleBytes = bytes::make_span(buffer);
if (fmt == AL_FORMAT_MONO8 || fmt == AL_FORMAT_STEREO8) {
Media::Audio::IterateSamples<uchar>(sampleBytes, callback);
} else if (fmt == AL_FORMAT_MONO16 || fmt == AL_FORMAT_STEREO16) {
Media::Audio::IterateSamples<int16>(sampleBytes, callback);
}
processed += sampleSize() * samples;
}
if (sumbytes > 0 && peaks.size() < Media::Player::kWaveformSamplesCount) {
peaks.push_back(peak);
}
if (peaks.isEmpty()) {
return false;
}
auto sum = std::accumulate(peaks.cbegin(), peaks.cend(), 0LL);
peak = qMax(int32(sum * 1.8 / peaks.size()), 2500);
result.resize(peaks.size());
for (int32 i = 0, l = peaks.size(); i != l; ++i) {
result[i] = char(qMin(31U, uint32(qMin(peaks.at(i), peak)) * 31 / peak));
}
return true;
}
const VoiceWaveform &waveform() const {
return result;
}
~FFMpegWaveformCounter() {
}
private:
VoiceWaveform result;
};
} // namespace Media
VoiceWaveform audioCountWaveform(
const FileLocation &file,
const QByteArray &data) {
Media::FFMpegWaveformCounter counter(file, data);
const auto positionMs = crl::time(0);
if (counter.open(positionMs)) {
return counter.waveform();
}
return VoiceWaveform();
}