gecko-dev/dom/media/MediaFormatReader.cpp

3268 строки
99 KiB
C++

/* -*- Mode: C++; tab-width: 2; indent-tabs-mode: nil; c-basic-offset: 2 -*- */
/* vim:set ts=2 sw=2 sts=2 et cindent: */
/* This Source Code Form is subject to the terms of the Mozilla Public
* License, v. 2.0. If a copy of the MPL was not distributed with this
* file, You can obtain one at http://mozilla.org/MPL/2.0/. */
#include "MediaFormatReader.h"
#include "AutoTaskQueue.h"
#include "Layers.h"
#include "MediaData.h"
#include "MediaDecoderOwner.h"
#include "MediaInfo.h"
#include "MediaResource.h"
#include "VideoFrameContainer.h"
#include "VideoUtils.h"
#include "mozilla/AbstractThread.h"
#include "mozilla/CDMProxy.h"
#include "mozilla/ClearOnShutdown.h"
#include "mozilla/Preferences.h"
#include "mozilla/SharedThreadPool.h"
#include "mozilla/SyncRunnable.h"
#include "mozilla/Telemetry.h"
#include "mozilla/Unused.h"
#include "nsContentUtils.h"
#include "nsPrintfCString.h"
#include <algorithm>
#include <map>
#include <queue>
using namespace mozilla::media;
using mozilla::layers::Image;
using mozilla::layers::LayerManager;
using mozilla::layers::LayersBackend;
static mozilla::LazyLogModule sFormatDecoderLog("MediaFormatReader");
mozilla::LazyLogModule gMediaDemuxerLog("MediaDemuxer");
#define LOG(arg, ...) MOZ_LOG(sFormatDecoderLog, mozilla::LogLevel::Debug, ("MediaFormatReader(%p)::%s: " arg, this, __func__, ##__VA_ARGS__))
#define LOGV(arg, ...) MOZ_LOG(sFormatDecoderLog, mozilla::LogLevel::Verbose, ("MediaFormatReader(%p)::%s: " arg, this, __func__, ##__VA_ARGS__))
#define NS_DispatchToMainThread(...) CompileError_UseAbstractMainThreadInstead
namespace mozilla {
typedef void* MediaDataDecoderID;
/**
* This helper class is used to report telemetry of the time used to recover a
* decoder from GPU crash.
* It uses MediaDecoderOwnerID to identify which video we're dealing with.
* It uses MediaDataDecoderID to make sure that the old MediaDataDecoder has
* been deleted and we're already recovered.
* It reports two recovery times, one is calculated from GPU crashed (that is,
* the time when VideoDecoderChild::ActorDestory() is called) and the other is
* calculated from the MFR is notified with NS_ERROR_DOM_MEDIA_NEED_NEW_DECODER
* error.
*/
class GPUProcessCrashTelemetryLogger
{
struct GPUCrashData
{
GPUCrashData(MediaDataDecoderID aMediaDataDecoderID,
mozilla::TimeStamp aGPUCrashTime,
mozilla::TimeStamp aErrorNotifiedTime)
: mMediaDataDecoderID(aMediaDataDecoderID)
, mGPUCrashTime(aGPUCrashTime)
, mErrorNotifiedTime(aErrorNotifiedTime)
{
MOZ_ASSERT(mMediaDataDecoderID);
MOZ_ASSERT(!mGPUCrashTime.IsNull());
MOZ_ASSERT(!mErrorNotifiedTime.IsNull());
}
MediaDataDecoderID mMediaDataDecoderID;
mozilla::TimeStamp mGPUCrashTime;
mozilla::TimeStamp mErrorNotifiedTime;
};
public:
static void
RecordGPUCrashData(MediaDecoderOwnerID aMediaDecoderOwnerID,
MediaDataDecoderID aMediaDataDecoderID,
const TimeStamp& aGPUCrashTime,
const TimeStamp& aErrorNotifiedTime)
{
MOZ_ASSERT(aMediaDecoderOwnerID);
MOZ_ASSERT(aMediaDataDecoderID);
MOZ_ASSERT(!aGPUCrashTime.IsNull());
MOZ_ASSERT(!aErrorNotifiedTime.IsNull());
auto it = sGPUCrashDataMap.find(aMediaDecoderOwnerID);
if (it == sGPUCrashDataMap.end()) {
sGPUCrashDataMap.insert(std::make_pair(aMediaDecoderOwnerID,
GPUCrashData(aMediaDataDecoderID,
aGPUCrashTime,
aErrorNotifiedTime)));
}
}
static void
ReportTelemetry(MediaDecoderOwnerID aMediaDecoderOwnerID,
MediaDataDecoderID aMediaDataDecoderID)
{
MOZ_ASSERT(aMediaDecoderOwnerID);
MOZ_ASSERT(aMediaDataDecoderID);
auto it = sGPUCrashDataMap.find(aMediaDecoderOwnerID);
if (it != sGPUCrashDataMap.end() &&
it->second.mMediaDataDecoderID != aMediaDataDecoderID) {
Telemetry::AccumulateTimeDelta(
Telemetry::VIDEO_HW_DECODER_CRASH_RECOVERY_TIME_SINCE_GPU_CRASHED_MS,
it->second.mGPUCrashTime);
Telemetry::AccumulateTimeDelta(
Telemetry::VIDEO_HW_DECODER_CRASH_RECOVERY_TIME_SINCE_MFR_NOTIFIED_MS,
it->second.mErrorNotifiedTime);
sGPUCrashDataMap.erase(aMediaDecoderOwnerID);
}
}
private:
static std::map<MediaDecoderOwnerID, GPUCrashData> sGPUCrashDataMap;
};
std::map<MediaDecoderOwnerID, GPUProcessCrashTelemetryLogger::GPUCrashData>
GPUProcessCrashTelemetryLogger::sGPUCrashDataMap;
/**
* This is a singleton which controls the number of decoders that can be
* created concurrently. Before calling PDMFactory::CreateDecoder(), Alloc()
* must be called to get a token object as a permission to create a decoder.
* The token should stay alive until Shutdown() is called on the decoder.
* The destructor of the token will restore the decoder count so it is available
* for next calls of Alloc().
*/
class GlobalAllocPolicy
{
using TrackType = TrackInfo::TrackType;
public:
class Token
{
NS_INLINE_DECL_THREADSAFE_REFCOUNTING(Token)
protected:
virtual ~Token() {}
};
using Promise = MozPromise<RefPtr<Token>, bool, true>;
// Acquire a token for decoder creation. Thread-safe.
auto Alloc() -> RefPtr<Promise>;
// Called by ClearOnShutdown() to delete the singleton.
void operator=(decltype(nullptr));
// Get the singleton for the given track type. Thread-safe.
static GlobalAllocPolicy& Instance(TrackType aTrack);
private:
class AutoDeallocToken;
using PromisePrivate = Promise::Private;
GlobalAllocPolicy();
~GlobalAllocPolicy();
// Called by the destructor of TokenImpl to restore the decoder limit.
void Dealloc();
// Decrement the decoder limit and resolve a promise if available.
void ResolvePromise(ReentrantMonitorAutoEnter& aProofOfLock);
// Protect access to Instance().
static StaticMutex sMutex;
ReentrantMonitor mMonitor;
// The number of decoders available for creation.
int mDecoderLimit;
// Requests to acquire tokens.
std::queue<RefPtr<PromisePrivate>> mPromises;
};
StaticMutex GlobalAllocPolicy::sMutex;
class GlobalAllocPolicy::AutoDeallocToken : public Token
{
public:
explicit AutoDeallocToken(GlobalAllocPolicy& aPolicy) : mPolicy(aPolicy) { }
private:
~AutoDeallocToken()
{
mPolicy.Dealloc();
}
GlobalAllocPolicy& mPolicy; // reference to a singleton object.
};
GlobalAllocPolicy::GlobalAllocPolicy()
: mMonitor("DecoderAllocPolicy::mMonitor")
, mDecoderLimit(MediaPrefs::MediaDecoderLimit())
{
SystemGroup::Dispatch(
TaskCategory::Other,
NS_NewRunnableFunction("GlobalAllocPolicy::GlobalAllocPolicy", [this]() {
ClearOnShutdown(this, ShutdownPhase::ShutdownThreads);
}));
}
GlobalAllocPolicy::~GlobalAllocPolicy()
{
while (!mPromises.empty()) {
RefPtr<PromisePrivate> p = mPromises.front().forget();
mPromises.pop();
p->Reject(true, __func__);
}
}
GlobalAllocPolicy&
GlobalAllocPolicy::Instance(TrackType aTrack)
{
StaticMutexAutoLock lock(sMutex);
if (aTrack == TrackType::kAudioTrack) {
static auto sAudioPolicy = new GlobalAllocPolicy();
return *sAudioPolicy;
} else {
static auto sVideoPolicy = new GlobalAllocPolicy();
return *sVideoPolicy;
}
}
auto
GlobalAllocPolicy::Alloc() -> RefPtr<Promise>
{
// No decoder limit set.
if (mDecoderLimit < 0) {
return Promise::CreateAndResolve(new Token(), __func__);
}
ReentrantMonitorAutoEnter mon(mMonitor);
RefPtr<PromisePrivate> p = new PromisePrivate(__func__);
mPromises.push(p);
ResolvePromise(mon);
return p.forget();
}
void
GlobalAllocPolicy::Dealloc()
{
ReentrantMonitorAutoEnter mon(mMonitor);
++mDecoderLimit;
ResolvePromise(mon);
}
void
GlobalAllocPolicy::ResolvePromise(ReentrantMonitorAutoEnter& aProofOfLock)
{
MOZ_ASSERT(mDecoderLimit >= 0);
if (mDecoderLimit > 0 && !mPromises.empty()) {
--mDecoderLimit;
RefPtr<PromisePrivate> p = mPromises.front().forget();
mPromises.pop();
p->Resolve(new AutoDeallocToken(*this), __func__);
}
}
void
GlobalAllocPolicy::operator=(std::nullptr_t)
{
delete this;
}
/**
* This class addresses the concern of bug 1339310 comment 4 where the Widevine
* CDM doesn't support running multiple instances of a video decoder at once per
* CDM instance by sequencing the order of decoder creation and shutdown. Note
* this class addresses a different concern from that of GlobalAllocPolicy which
* controls a system-wide number of decoders while this class control a per-MFR
* number (which is one per CDM requirement).
*/
class LocalAllocPolicy
{
using TrackType = TrackInfo::TrackType;
using Promise = GlobalAllocPolicy::Promise;
using Token = GlobalAllocPolicy::Token;
NS_INLINE_DECL_THREADSAFE_REFCOUNTING(LocalAllocPolicy)
public:
LocalAllocPolicy(TrackType aTrack, TaskQueue* aOwnerThread)
: mTrack(aTrack)
, mOwnerThread(aOwnerThread)
{
}
// Acquire a token for decoder creation. Note the resolved token will
// aggregate a GlobalAllocPolicy token to comply to its policy. Note
// this function shouldn't be called again until the returned promise
// is resolved or rejected.
RefPtr<Promise> Alloc();
// Cancel the request to GlobalAllocPolicy and reject the current token
// request. Note this must happen before mOwnerThread->BeginShutdown().
void Cancel();
private:
/*
* An RAII class to manage LocalAllocPolicy::mDecoderLimit.
*/
class AutoDeallocToken : public Token
{
public:
explicit AutoDeallocToken(LocalAllocPolicy* aOwner)
: mOwner(aOwner)
{
MOZ_DIAGNOSTIC_ASSERT(mOwner->mDecoderLimit > 0);
--mOwner->mDecoderLimit;
}
// Aggregate a GlobalAllocPolicy token to present a single instance of
// Token to the client so the client doesn't have to deal with
// GlobalAllocPolicy and LocalAllocPolicy separately.
void Append(Token* aToken)
{
mToken = aToken;
}
private:
// Release tokens allocated from GlobalAllocPolicy and LocalAllocPolicy
// and process next token request if any.
~AutoDeallocToken()
{
mToken = nullptr; // Dealloc the global token.
++mOwner->mDecoderLimit; // Dealloc the local token.
mOwner->ProcessRequest(); // Process next pending request.
}
RefPtr<LocalAllocPolicy> mOwner;
RefPtr<Token> mToken;
};
~LocalAllocPolicy() { }
void ProcessRequest();
int mDecoderLimit = 1;
const TrackType mTrack;
RefPtr<TaskQueue> mOwnerThread;
MozPromiseHolder<Promise> mPendingPromise;
MozPromiseRequestHolder<Promise> mTokenRequest;
};
RefPtr<LocalAllocPolicy::Promise>
LocalAllocPolicy::Alloc()
{
MOZ_ASSERT(mOwnerThread->IsCurrentThreadIn());
MOZ_DIAGNOSTIC_ASSERT(mPendingPromise.IsEmpty());
RefPtr<Promise> p = mPendingPromise.Ensure(__func__);
if (mDecoderLimit > 0) {
ProcessRequest();
}
return p.forget();
}
void
LocalAllocPolicy::ProcessRequest()
{
MOZ_ASSERT(mOwnerThread->IsCurrentThreadIn());
MOZ_DIAGNOSTIC_ASSERT(mDecoderLimit > 0);
// No pending request.
if (mPendingPromise.IsEmpty()) {
return;
}
RefPtr<AutoDeallocToken> token = new AutoDeallocToken(this);
RefPtr<LocalAllocPolicy> self = this;
GlobalAllocPolicy::Instance(mTrack).Alloc()->Then(
mOwnerThread, __func__,
[self, token](RefPtr<Token> aToken) {
self->mTokenRequest.Complete();
token->Append(aToken);
self->mPendingPromise.Resolve(token, __func__);
},
[self, token]() {
self->mTokenRequest.Complete();
self->mPendingPromise.Reject(true, __func__);
})->Track(mTokenRequest);
}
void
LocalAllocPolicy::Cancel()
{
MOZ_ASSERT(mOwnerThread->IsCurrentThreadIn());
mPendingPromise.RejectIfExists(true, __func__);
mTokenRequest.DisconnectIfExists();
}
/**
* This class tracks shutdown promises to ensure all decoders are shut down
* completely before MFR continues the rest of the shutdown procedure.
*/
class MediaFormatReader::ShutdownPromisePool
{
public:
ShutdownPromisePool()
: mOnShutdownComplete(new ShutdownPromise::Private(__func__))
{
}
// Return a promise which will be resolved when all the tracking promises
// are resolved. Note no more promises should be added for tracking once
// this function is called.
RefPtr<ShutdownPromise> Shutdown();
// Track a shutdown promise.
void Track(RefPtr<ShutdownPromise> aPromise);
// Shut down a decoder and track its shutdown promise.
void ShutdownDecoder(already_AddRefed<MediaDataDecoder> aDecoder)
{
Track(RefPtr<MediaDataDecoder>(aDecoder)->Shutdown());
}
private:
bool mShutdown = false;
const RefPtr<ShutdownPromise::Private> mOnShutdownComplete;
nsTHashtable<nsRefPtrHashKey<ShutdownPromise>> mPromises;
};
RefPtr<ShutdownPromise>
MediaFormatReader::ShutdownPromisePool::Shutdown()
{
MOZ_DIAGNOSTIC_ASSERT(!mShutdown);
mShutdown = true;
if (mPromises.Count() == 0) {
mOnShutdownComplete->Resolve(true, __func__);
}
return mOnShutdownComplete;
}
void
MediaFormatReader::ShutdownPromisePool::Track(RefPtr<ShutdownPromise> aPromise)
{
MOZ_DIAGNOSTIC_ASSERT(!mShutdown);
MOZ_DIAGNOSTIC_ASSERT(!mPromises.Contains(aPromise));
mPromises.PutEntry(aPromise);
aPromise->Then(
AbstractThread::GetCurrent(), __func__,
[aPromise, this]() {
MOZ_DIAGNOSTIC_ASSERT(mPromises.Contains(aPromise));
mPromises.RemoveEntry(aPromise);
if (mShutdown && mPromises.Count() == 0) {
mOnShutdownComplete->Resolve(true, __func__);
}
});
}
void
MediaFormatReader::DecoderData::ShutdownDecoder()
{
MutexAutoLock lock(mMutex);
if (!mDecoder) {
// No decoder to shut down.
return;
}
if (mFlushing) {
// Flush is is in action. Shutdown will be initiated after flush completes.
MOZ_DIAGNOSTIC_ASSERT(mShutdownPromise);
mOwner->mShutdownPromisePool->Track(mShutdownPromise->Ensure(__func__));
// The order of decoder creation and shutdown is handled by LocalAllocPolicy
// and ShutdownPromisePool. MFR can now reset these members to a fresh state
// and be ready to create new decoders again without explicitly waiting for
// flush/shutdown to complete.
mShutdownPromise = nullptr;
mFlushing = false;
} else {
// No flush is in action. We can shut down the decoder now.
mOwner->mShutdownPromisePool->Track(mDecoder->Shutdown());
}
// mShutdownPromisePool will handle the order of decoder shutdown so
// we can forget mDecoder and be ready to create a new one.
mDecoder = nullptr;
mDescription = NS_LITERAL_CSTRING("shutdown");
mOwner->ScheduleUpdate(mType == MediaData::AUDIO_DATA
? TrackType::kAudioTrack
: TrackType::kVideoTrack);
}
void
MediaFormatReader::DecoderData::Flush()
{
if (mFlushing || mFlushed) {
// Flush still pending or already flushed, nothing more to do.
return;
}
mDecodeRequest.DisconnectIfExists();
mDrainRequest.DisconnectIfExists();
mDrainState = DrainState::None;
CancelWaitingForKey();
mOutput.Clear();
mNumSamplesInput = 0;
mNumSamplesOutput = 0;
mSizeOfQueue = 0;
if (mDecoder) {
TrackType type = mType == MediaData::AUDIO_DATA
? TrackType::kAudioTrack
: TrackType::kVideoTrack;
mFlushing = true;
MOZ_DIAGNOSTIC_ASSERT(!mShutdownPromise);
mShutdownPromise = new SharedShutdownPromiseHolder();
RefPtr<SharedShutdownPromiseHolder> p = mShutdownPromise;
RefPtr<MediaDataDecoder> d = mDecoder;
mDecoder->Flush()
->Then(mOwner->OwnerThread(), __func__,
[type, this, p, d]() {
if (!p->IsEmpty()) {
// Shutdown happened before flush completes. Let's continue to
// shut down the decoder. Note we don't access |this| because
// this decoder is no longer managed by MFR::DecoderData.
d->Shutdown()->ChainTo(p->Steal(), __func__);
return;
}
mFlushing = false;
mShutdownPromise = nullptr;
mOwner->ScheduleUpdate(type);
},
[type, this, p, d](const MediaResult& aError) {
if (!p->IsEmpty()) {
d->Shutdown()->ChainTo(p->Steal(), __func__);
return;
}
mFlushing = false;
mShutdownPromise = nullptr;
mOwner->NotifyError(type, aError);
});
}
mFlushed = true;
}
class MediaFormatReader::DecoderFactory
{
using InitPromise = MediaDataDecoder::InitPromise;
using TokenPromise = GlobalAllocPolicy::Promise;
using Token = GlobalAllocPolicy::Token;
public:
explicit DecoderFactory(MediaFormatReader* aOwner)
: mAudio(aOwner->mAudio, TrackInfo::kAudioTrack, aOwner->OwnerThread())
, mVideo(aOwner->mVideo, TrackInfo::kVideoTrack, aOwner->OwnerThread())
, mOwner(WrapNotNull(aOwner)) { }
void CreateDecoder(TrackType aTrack);
// Shutdown any decoder pending initialization and reset mAudio/mVideo to its
// pristine state so CreateDecoder() is ready to be called again immediately.
void ShutdownDecoder(TrackType aTrack)
{
MOZ_ASSERT(aTrack == TrackInfo::kAudioTrack ||
aTrack == TrackInfo::kVideoTrack);
auto& data = aTrack == TrackInfo::kAudioTrack ? mAudio : mVideo;
data.mPolicy->Cancel();
data.mTokenRequest.DisconnectIfExists();
data.mInitRequest.DisconnectIfExists();
if (data.mDecoder) {
mOwner->mShutdownPromisePool->ShutdownDecoder(data.mDecoder.forget());
}
data.mStage = Stage::None;
MOZ_ASSERT(!data.mToken);
}
private:
class Wrapper;
enum class Stage : int8_t
{
None,
WaitForToken,
CreateDecoder,
WaitForInit
};
struct Data
{
Data(DecoderData& aOwnerData, TrackType aTrack, TaskQueue* aThread)
: mOwnerData(aOwnerData)
, mTrack(aTrack)
, mPolicy(new LocalAllocPolicy(aTrack, aThread)) { }
DecoderData& mOwnerData;
const TrackType mTrack;
RefPtr<LocalAllocPolicy> mPolicy;
Stage mStage = Stage::None;
RefPtr<Token> mToken;
RefPtr<MediaDataDecoder> mDecoder;
MozPromiseRequestHolder<TokenPromise> mTokenRequest;
MozPromiseRequestHolder<InitPromise> mInitRequest;
} mAudio, mVideo;
void RunStage(Data& aData);
MediaResult DoCreateDecoder(Data& aData);
void DoInitDecoder(Data& aData);
// guaranteed to be valid by the owner.
const NotNull<MediaFormatReader*> mOwner;
};
void
MediaFormatReader::DecoderFactory::CreateDecoder(TrackType aTrack)
{
MOZ_ASSERT(aTrack == TrackInfo::kAudioTrack ||
aTrack == TrackInfo::kVideoTrack);
RunStage(aTrack == TrackInfo::kAudioTrack ? mAudio : mVideo);
}
class MediaFormatReader::DecoderFactory::Wrapper : public MediaDataDecoder
{
using Token = GlobalAllocPolicy::Token;
public:
Wrapper(already_AddRefed<MediaDataDecoder> aDecoder,
already_AddRefed<Token> aToken)
: mDecoder(aDecoder), mToken(aToken) {}
RefPtr<InitPromise> Init() override { return mDecoder->Init(); }
RefPtr<DecodePromise> Decode(MediaRawData* aSample) override
{
return mDecoder->Decode(aSample);
}
RefPtr<DecodePromise> Drain() override { return mDecoder->Drain(); }
RefPtr<FlushPromise> Flush() override { return mDecoder->Flush(); }
bool IsHardwareAccelerated(nsACString& aFailureReason) const override
{
return mDecoder->IsHardwareAccelerated(aFailureReason);
}
nsCString GetDescriptionName() const override
{
return mDecoder->GetDescriptionName();
}
void SetSeekThreshold(const TimeUnit& aTime) override
{
mDecoder->SetSeekThreshold(aTime);
}
bool SupportDecoderRecycling() const override
{
return mDecoder->SupportDecoderRecycling();
}
RefPtr<ShutdownPromise> Shutdown() override
{
RefPtr<MediaDataDecoder> decoder = mDecoder.forget();
RefPtr<Token> token = mToken.forget();
return decoder->Shutdown()->Then(
AbstractThread::GetCurrent(), __func__,
[token]() {
return ShutdownPromise::CreateAndResolve(true, __func__);
});
}
private:
RefPtr<MediaDataDecoder> mDecoder;
RefPtr<Token> mToken;
};
void
MediaFormatReader::DecoderFactory::RunStage(Data& aData)
{
switch (aData.mStage) {
case Stage::None: {
MOZ_ASSERT(!aData.mToken);
aData.mPolicy->Alloc()->Then(
mOwner->OwnerThread(), __func__,
[this, &aData] (RefPtr<Token> aToken) {
aData.mTokenRequest.Complete();
aData.mToken = aToken.forget();
aData.mStage = Stage::CreateDecoder;
RunStage(aData);
},
[&aData] () {
aData.mTokenRequest.Complete();
aData.mStage = Stage::None;
})->Track(aData.mTokenRequest);
aData.mStage = Stage::WaitForToken;
break;
}
case Stage::WaitForToken: {
MOZ_ASSERT(!aData.mToken);
MOZ_ASSERT(aData.mTokenRequest.Exists());
break;
}
case Stage::CreateDecoder: {
MOZ_ASSERT(aData.mToken);
MOZ_ASSERT(!aData.mDecoder);
MOZ_ASSERT(!aData.mInitRequest.Exists());
MediaResult rv = DoCreateDecoder(aData);
if (NS_FAILED(rv)) {
NS_WARNING("Error constructing decoders");
aData.mToken = nullptr;
aData.mStage = Stage::None;
mOwner->NotifyError(aData.mTrack, rv);
return;
}
aData.mDecoder = new Wrapper(aData.mDecoder.forget(), aData.mToken.forget());
DoInitDecoder(aData);
aData.mStage = Stage::WaitForInit;
break;
}
case Stage::WaitForInit: {
MOZ_ASSERT(aData.mDecoder);
MOZ_ASSERT(aData.mInitRequest.Exists());
break;
}
}
}
MediaResult
MediaFormatReader::DecoderFactory::DoCreateDecoder(Data& aData)
{
auto& ownerData = aData.mOwnerData;
auto decoderCreatingError = "error creating audio decoder";
MediaResult result =
MediaResult(NS_ERROR_DOM_MEDIA_FATAL_ERR, decoderCreatingError);
if (!mOwner->mPlatform) {
mOwner->mPlatform = new PDMFactory();
if (mOwner->IsEncrypted()) {
MOZ_ASSERT(mOwner->mCDMProxy);
mOwner->mPlatform->SetCDMProxy(mOwner->mCDMProxy);
}
}
switch (aData.mTrack) {
case TrackInfo::kAudioTrack: {
aData.mDecoder = mOwner->mPlatform->CreateDecoder({
ownerData.mInfo
? *ownerData.mInfo->GetAsAudioInfo()
: *ownerData.mOriginalInfo->GetAsAudioInfo(),
ownerData.mTaskQueue,
mOwner->mCrashHelper,
ownerData.mIsNullDecode,
&result,
TrackInfo::kAudioTrack,
&mOwner->OnTrackWaitingForKeyProducer()
});
break;
}
case TrackType::kVideoTrack: {
// Decoders use the layers backend to decide if they can use hardware decoding,
// so specify LAYERS_NONE if we want to forcibly disable it.
aData.mDecoder = mOwner->mPlatform->CreateDecoder({
ownerData.mInfo
? *ownerData.mInfo->GetAsVideoInfo()
: *ownerData.mOriginalInfo->GetAsVideoInfo(),
ownerData.mTaskQueue,
mOwner->mKnowsCompositor,
mOwner->GetImageContainer(),
mOwner->mCrashHelper,
ownerData.mIsNullDecode,
&result,
TrackType::kVideoTrack,
&mOwner->OnTrackWaitingForKeyProducer()
});
break;
}
default:
break;
}
if (aData.mDecoder) {
return NS_OK;
}
ownerData.mDescription = decoderCreatingError;
return result;
}
void
MediaFormatReader::DecoderFactory::DoInitDecoder(Data& aData)
{
auto& ownerData = aData.mOwnerData;
aData.mDecoder->Init()
->Then(mOwner->OwnerThread(), __func__,
[this, &aData, &ownerData](TrackType aTrack) {
aData.mInitRequest.Complete();
aData.mStage = Stage::None;
MutexAutoLock lock(ownerData.mMutex);
ownerData.mDecoder = aData.mDecoder.forget();
ownerData.mDescription = ownerData.mDecoder->GetDescriptionName();
mOwner->SetVideoDecodeThreshold();
mOwner->ScheduleUpdate(aTrack);
},
[this, &aData, &ownerData](const MediaResult& aError) {
aData.mInitRequest.Complete();
MOZ_RELEASE_ASSERT(!ownerData.mDecoder,
"Can't have a decoder already set");
aData.mStage = Stage::None;
mOwner->mShutdownPromisePool->ShutdownDecoder(aData.mDecoder.forget());
mOwner->NotifyError(aData.mTrack, aError);
})
->Track(aData.mInitRequest);
}
// DemuxerProxy ensures that the original main demuxer is only ever accessed
// via its own dedicated task queue.
// This ensure that the reader's taskqueue will never blocked while a demuxer
// is itself blocked attempting to access the MediaCache or the MediaResource.
class MediaFormatReader::DemuxerProxy
{
using TrackType = TrackInfo::TrackType;
class Wrapper;
public:
explicit DemuxerProxy(MediaDataDemuxer* aDemuxer)
: mTaskQueue(new AutoTaskQueue(
GetMediaThreadPool(MediaThreadType::PLATFORM_DECODER),
"DemuxerProxy::mTaskQueue"))
, mData(new Data(aDemuxer))
{
MOZ_COUNT_CTOR(DemuxerProxy);
}
~DemuxerProxy()
{
MOZ_COUNT_DTOR(DemuxerProxy);
}
RefPtr<ShutdownPromise> Shutdown()
{
RefPtr<Data> data = mData.forget();
return InvokeAsync(mTaskQueue, __func__, [data]() {
// We need to clear our reference to the demuxer now. So that in the event
// the init promise wasn't resolved, such as what can happen with the
// mediasource demuxer that is waiting on more data, it will force the
// init promise to be rejected.
data->mDemuxer = nullptr;
data->mAudioDemuxer = nullptr;
data->mVideoDemuxer = nullptr;
return ShutdownPromise::CreateAndResolve(true, __func__);
});
}
RefPtr<MediaDataDemuxer::InitPromise> Init();
Wrapper*
GetTrackDemuxer(TrackType aTrack, uint32_t aTrackNumber)
{
MOZ_RELEASE_ASSERT(mData && mData->mInitDone);
switch (aTrack) {
case TrackInfo::kAudioTrack:
return mData->mAudioDemuxer;
case TrackInfo::kVideoTrack:
return mData->mVideoDemuxer;
default:
return nullptr;
}
}
uint32_t GetNumberTracks(TrackType aTrack) const
{
MOZ_RELEASE_ASSERT(mData && mData->mInitDone);
switch (aTrack) {
case TrackInfo::kAudioTrack:
return mData->mNumAudioTrack;
case TrackInfo::kVideoTrack:
return mData->mNumVideoTrack;
default:
return 0;
}
}
bool IsSeekable() const
{
MOZ_RELEASE_ASSERT(mData && mData->mInitDone);
return mData->mSeekable;
}
bool IsSeekableOnlyInBufferedRanges() const
{
MOZ_RELEASE_ASSERT(mData && mData->mInitDone);
return mData->mSeekableOnlyInBufferedRange;
}
UniquePtr<EncryptionInfo> GetCrypto() const
{
MOZ_RELEASE_ASSERT(mData && mData->mInitDone);
if (!mData->mCrypto) {
return nullptr;
}
auto crypto = MakeUnique<EncryptionInfo>();
*crypto = *mData->mCrypto;
return crypto;
}
RefPtr<NotifyDataArrivedPromise> NotifyDataArrived();
bool ShouldComputeStartTime() const
{
MOZ_RELEASE_ASSERT(mData && mData->mInitDone);
return mData->mShouldComputeStartTime;
}
private:
const RefPtr<AutoTaskQueue> mTaskQueue;
struct Data
{
NS_INLINE_DECL_THREADSAFE_REFCOUNTING(Data)
explicit Data(MediaDataDemuxer* aDemuxer)
: mInitDone(false)
, mDemuxer(aDemuxer)
{
}
Atomic<bool> mInitDone;
// Only ever accessed over mTaskQueue once.
RefPtr<MediaDataDemuxer> mDemuxer;
// Only accessed once InitPromise has been resolved and immutable after.
// So we can safely access them without the use of the mutex.
uint32_t mNumAudioTrack = 0;
RefPtr<Wrapper> mAudioDemuxer;
uint32_t mNumVideoTrack = 0;
RefPtr<Wrapper> mVideoDemuxer;
bool mSeekable = false;
bool mSeekableOnlyInBufferedRange = false;
bool mShouldComputeStartTime = true;
UniquePtr<EncryptionInfo> mCrypto;
private:
~Data() { }
};
RefPtr<Data> mData;
};
class MediaFormatReader::DemuxerProxy::Wrapper : public MediaTrackDemuxer
{
public:
Wrapper(MediaTrackDemuxer* aTrackDemuxer, AutoTaskQueue* aTaskQueue)
: mMutex("TrackDemuxer Mutex")
, mTaskQueue(aTaskQueue)
, mGetSamplesMayBlock(aTrackDemuxer->GetSamplesMayBlock())
, mInfo(aTrackDemuxer->GetInfo())
, mTrackDemuxer(aTrackDemuxer)
{
}
UniquePtr<TrackInfo> GetInfo() const override
{
if (!mInfo) {
return nullptr;
}
return mInfo->Clone();
}
RefPtr<SeekPromise> Seek(const TimeUnit& aTime) override
{
RefPtr<Wrapper> self = this;
return InvokeAsync(
mTaskQueue, __func__,
[self, aTime]() { return self->mTrackDemuxer->Seek(aTime); })
->Then(mTaskQueue, __func__,
[self](const TimeUnit& aTime) {
self->UpdateRandomAccessPoint();
return SeekPromise::CreateAndResolve(aTime, __func__);
},
[self](const MediaResult& aError) {
self->UpdateRandomAccessPoint();
return SeekPromise::CreateAndReject(aError, __func__);
});
}
RefPtr<SamplesPromise> GetSamples(int32_t aNumSamples) override
{
RefPtr<Wrapper> self = this;
return InvokeAsync(mTaskQueue, __func__,
[self, aNumSamples]() {
return self->mTrackDemuxer->GetSamples(aNumSamples);
})
->Then(mTaskQueue, __func__,
[self](RefPtr<SamplesHolder> aSamples) {
self->UpdateRandomAccessPoint();
return SamplesPromise::CreateAndResolve(aSamples.forget(), __func__);
},
[self](const MediaResult& aError) {
self->UpdateRandomAccessPoint();
return SamplesPromise::CreateAndReject(aError, __func__);
});
}
bool GetSamplesMayBlock() const override
{
return mGetSamplesMayBlock;
}
void Reset() override
{
RefPtr<Wrapper> self = this;
mTaskQueue->Dispatch(
NS_NewRunnableFunction("MediaFormatReader::DemuxerProxy::Wrapper::Reset",
[self]() { self->mTrackDemuxer->Reset(); }));
}
nsresult GetNextRandomAccessPoint(TimeUnit* aTime) override
{
MutexAutoLock lock(mMutex);
if (NS_SUCCEEDED(mNextRandomAccessPointResult)) {
*aTime = mNextRandomAccessPoint;
}
return mNextRandomAccessPointResult;
}
RefPtr<SkipAccessPointPromise>
SkipToNextRandomAccessPoint(const TimeUnit& aTimeThreshold) override
{
RefPtr<Wrapper> self = this;
return InvokeAsync(
mTaskQueue, __func__,
[self, aTimeThreshold]() {
return self->mTrackDemuxer->SkipToNextRandomAccessPoint(
aTimeThreshold);
})
->Then(mTaskQueue, __func__,
[self](uint32_t aVal) {
self->UpdateRandomAccessPoint();
return SkipAccessPointPromise::CreateAndResolve(aVal, __func__);
},
[self](const SkipFailureHolder& aError) {
self->UpdateRandomAccessPoint();
return SkipAccessPointPromise::CreateAndReject(aError, __func__);
});
}
TimeIntervals GetBuffered() override
{
MutexAutoLock lock(mMutex);
return mBuffered;
}
void BreakCycles() override { }
private:
Mutex mMutex;
const RefPtr<AutoTaskQueue> mTaskQueue;
const bool mGetSamplesMayBlock;
const UniquePtr<TrackInfo> mInfo;
// mTrackDemuxer is only ever accessed on demuxer's task queue.
RefPtr<MediaTrackDemuxer> mTrackDemuxer;
// All following members are protected by mMutex
nsresult mNextRandomAccessPointResult = NS_OK;
TimeUnit mNextRandomAccessPoint;
TimeIntervals mBuffered;
friend class DemuxerProxy;
~Wrapper()
{
RefPtr<MediaTrackDemuxer> trackDemuxer = mTrackDemuxer.forget();
mTaskQueue->Dispatch(NS_NewRunnableFunction(
"MediaFormatReader::DemuxerProxy::Wrapper::~Wrapper",
[trackDemuxer]() { trackDemuxer->BreakCycles(); }));
}
void UpdateRandomAccessPoint()
{
MOZ_ASSERT(mTaskQueue->IsCurrentThreadIn());
if (!mTrackDemuxer) {
// Detached.
return;
}
MutexAutoLock lock(mMutex);
mNextRandomAccessPointResult =
mTrackDemuxer->GetNextRandomAccessPoint(&mNextRandomAccessPoint);
}
void UpdateBuffered()
{
MOZ_ASSERT(mTaskQueue->IsCurrentThreadIn());
if (!mTrackDemuxer) {
// Detached.
return;
}
MutexAutoLock lock(mMutex);
mBuffered = mTrackDemuxer->GetBuffered();
}
};
RefPtr<MediaDataDemuxer::InitPromise>
MediaFormatReader::DemuxerProxy::Init()
{
using InitPromise = MediaDataDemuxer::InitPromise;
RefPtr<Data> data = mData;
RefPtr<AutoTaskQueue> taskQueue = mTaskQueue;
return InvokeAsync(mTaskQueue, __func__,
[data, taskQueue]() {
if (!data->mDemuxer) {
return InitPromise::CreateAndReject(
NS_ERROR_DOM_MEDIA_CANCELED, __func__);
}
return data->mDemuxer->Init();
})
->Then(taskQueue, __func__,
[data, taskQueue]() {
if (!data->mDemuxer) { // Was shutdown.
return InitPromise::CreateAndReject(
NS_ERROR_DOM_MEDIA_CANCELED, __func__);
}
data->mNumAudioTrack =
data->mDemuxer->GetNumberTracks(TrackInfo::kAudioTrack);
if (data->mNumAudioTrack) {
RefPtr<MediaTrackDemuxer> d =
data->mDemuxer->GetTrackDemuxer(TrackInfo::kAudioTrack, 0);
if (d) {
RefPtr<Wrapper> wrapper =
new DemuxerProxy::Wrapper(d, taskQueue);
wrapper->UpdateBuffered();
data->mAudioDemuxer = wrapper;
}
}
data->mNumVideoTrack =
data->mDemuxer->GetNumberTracks(TrackInfo::kVideoTrack);
if (data->mNumVideoTrack) {
RefPtr<MediaTrackDemuxer> d =
data->mDemuxer->GetTrackDemuxer(TrackInfo::kVideoTrack, 0);
if (d) {
RefPtr<Wrapper> wrapper =
new DemuxerProxy::Wrapper(d, taskQueue);
wrapper->UpdateBuffered();
data->mVideoDemuxer = wrapper;
}
}
data->mCrypto = data->mDemuxer->GetCrypto();
data->mSeekable = data->mDemuxer->IsSeekable();
data->mSeekableOnlyInBufferedRange =
data->mDemuxer->IsSeekableOnlyInBufferedRanges();
data->mShouldComputeStartTime =
data->mDemuxer->ShouldComputeStartTime();
data->mInitDone = true;
return InitPromise::CreateAndResolve(NS_OK, __func__);
},
[](const MediaResult& aError) {
return InitPromise::CreateAndReject(aError, __func__);
});
}
RefPtr<MediaFormatReader::NotifyDataArrivedPromise>
MediaFormatReader::DemuxerProxy::NotifyDataArrived()
{
RefPtr<Data> data = mData;
return InvokeAsync(mTaskQueue, __func__, [data]() {
if (!data->mDemuxer) {
// Was shutdown.
return NotifyDataArrivedPromise::CreateAndReject(
NS_ERROR_DOM_MEDIA_CANCELED, __func__);
}
data->mDemuxer->NotifyDataArrived();
if (data->mAudioDemuxer) {
data->mAudioDemuxer->UpdateBuffered();
}
if (data->mVideoDemuxer) {
data->mVideoDemuxer->UpdateBuffered();
}
return NotifyDataArrivedPromise::CreateAndResolve(true, __func__);
});
}
MediaFormatReader::MediaFormatReader(MediaFormatReaderInit& aInit,
MediaDataDemuxer* aDemuxer)
: mTaskQueue(new TaskQueue(GetMediaThreadPool(MediaThreadType::PLAYBACK),
"MediaFormatReader::mTaskQueue",
/* aSupportsTailDispatch = */ true))
, mAudio(this, MediaData::AUDIO_DATA, MediaPrefs::MaxAudioDecodeError())
, mVideo(this, MediaData::VIDEO_DATA, MediaPrefs::MaxVideoDecodeError())
, mDemuxer(new DemuxerProxy(aDemuxer))
, mDemuxerInitDone(false)
, mPendingNotifyDataArrived(false)
, mLastReportedNumDecodedFrames(0)
, mPreviousDecodedKeyframeTime_us(sNoPreviousDecodedKeyframe)
, mKnowsCompositor(aInit.mKnowsCompositor)
, mInitDone(false)
, mTrackDemuxersMayBlock(false)
, mSeekScheduled(false)
, mVideoFrameContainer(aInit.mVideoFrameContainer)
, mCrashHelper(aInit.mCrashHelper)
, mDecoderFactory(new DecoderFactory(this))
, mShutdownPromisePool(new ShutdownPromisePool())
, mBuffered(mTaskQueue,
TimeIntervals(),
"MediaFormatReader::mBuffered (Canonical)")
, mFrameStats(aInit.mFrameStats)
, mMediaDecoderOwnerID(aInit.mMediaDecoderOwnerID)
{
MOZ_ASSERT(aDemuxer);
MOZ_COUNT_CTOR(MediaFormatReader);
mOnTrackWaitingForKeyListener = OnTrackWaitingForKey().Connect(
mTaskQueue, this, &MediaFormatReader::NotifyWaitingForKey);
}
MediaFormatReader::~MediaFormatReader()
{
MOZ_COUNT_DTOR(MediaFormatReader);
MOZ_ASSERT(mShutdown);
}
RefPtr<ShutdownPromise>
MediaFormatReader::Shutdown()
{
MOZ_ASSERT(OnTaskQueue());
LOG("");
mDemuxerInitRequest.DisconnectIfExists();
mNotifyDataArrivedPromise.DisconnectIfExists();
mMetadataPromise.RejectIfExists(NS_ERROR_DOM_MEDIA_CANCELED, __func__);
mSeekPromise.RejectIfExists(NS_ERROR_DOM_MEDIA_CANCELED, __func__);
mSkipRequest.DisconnectIfExists();
if (mAudio.HasPromise()) {
mAudio.RejectPromise(NS_ERROR_DOM_MEDIA_CANCELED, __func__);
}
if (mVideo.HasPromise()) {
mVideo.RejectPromise(NS_ERROR_DOM_MEDIA_CANCELED, __func__);
}
if (HasAudio()) {
mAudio.ResetDemuxer();
mAudio.mTrackDemuxer->BreakCycles();
mAudio.mTrackDemuxer = nullptr;
mAudio.ResetState();
ShutdownDecoder(TrackInfo::kAudioTrack);
}
if (HasVideo()) {
mVideo.ResetDemuxer();
mVideo.mTrackDemuxer->BreakCycles();
mVideo.mTrackDemuxer = nullptr;
mVideo.ResetState();
ShutdownDecoder(TrackInfo::kVideoTrack);
}
mShutdownPromisePool->Track(mDemuxer->Shutdown());
mDemuxer = nullptr;
mOnTrackWaitingForKeyListener.Disconnect();
mShutdown = true;
return mShutdownPromisePool->Shutdown()
->Then(OwnerThread(), __func__, this,
&MediaFormatReader::TearDownDecoders,
&MediaFormatReader::TearDownDecoders);
}
void
MediaFormatReader::ShutdownDecoder(TrackType aTrack)
{
LOGV("%s", TrackTypeToStr(aTrack));
// Shut down the pending decoder if any.
mDecoderFactory->ShutdownDecoder(aTrack);
auto& decoder = GetDecoderData(aTrack);
// Flush the decoder if necessary.
decoder.Flush();
// Shut down the decoder if any.
decoder.ShutdownDecoder();
}
RefPtr<ShutdownPromise>
MediaFormatReader::TearDownDecoders()
{
if (mAudio.mTaskQueue) {
mAudio.mTaskQueue->BeginShutdown();
mAudio.mTaskQueue->AwaitShutdownAndIdle();
mAudio.mTaskQueue = nullptr;
}
if (mVideo.mTaskQueue) {
mVideo.mTaskQueue->BeginShutdown();
mVideo.mTaskQueue->AwaitShutdownAndIdle();
mVideo.mTaskQueue = nullptr;
}
mDecoderFactory = nullptr;
mPlatform = nullptr;
mVideoFrameContainer = nullptr;
ReleaseResources();
mBuffered.DisconnectAll();
return mTaskQueue->BeginShutdown();
}
nsresult
MediaFormatReader::Init()
{
MOZ_ASSERT(NS_IsMainThread(), "Must be on main thread.");
mAudio.mTaskQueue = new TaskQueue(
GetMediaThreadPool(MediaThreadType::PLATFORM_DECODER),
"MFR::mAudio::mTaskQueue");
mVideo.mTaskQueue = new TaskQueue(
GetMediaThreadPool(MediaThreadType::PLATFORM_DECODER),
"MFR::mVideo::mTaskQueue");
return NS_OK;
}
void
MediaFormatReader::SetCDMProxy(CDMProxy* aProxy)
{
RefPtr<CDMProxy> proxy = aProxy;
RefPtr<MediaFormatReader> self = this;
nsCOMPtr<nsIRunnable> r =
NS_NewRunnableFunction("MediaFormatReader::SetCDMProxy", [=]() {
MOZ_ASSERT(self->OnTaskQueue());
self->mCDMProxy = proxy;
if (HasAudio()) {
self->ScheduleUpdate(TrackInfo::kAudioTrack);
}
if (HasVideo()) {
self->ScheduleUpdate(TrackInfo::kVideoTrack);
}
});
OwnerThread()->Dispatch(r.forget());
}
bool
MediaFormatReader::IsWaitingOnCDMResource()
{
MOZ_ASSERT(OnTaskQueue());
return IsEncrypted() && !mCDMProxy;
}
RefPtr<MediaFormatReader::MetadataPromise>
MediaFormatReader::AsyncReadMetadata()
{
MOZ_ASSERT(OnTaskQueue());
MOZ_DIAGNOSTIC_ASSERT(mMetadataPromise.IsEmpty());
if (mInitDone) {
// We are returning from dormant.
MetadataHolder metadata;
metadata.mInfo = MakeUnique<MediaInfo>(mInfo);
return MetadataPromise::CreateAndResolve(Move(metadata), __func__);
}
RefPtr<MetadataPromise> p = mMetadataPromise.Ensure(__func__);
mDemuxer->Init()
->Then(OwnerThread(), __func__, this,
&MediaFormatReader::OnDemuxerInitDone,
&MediaFormatReader::OnDemuxerInitFailed)
->Track(mDemuxerInitRequest);
return p;
}
void
MediaFormatReader::OnDemuxerInitDone(const MediaResult& aResult)
{
MOZ_ASSERT(OnTaskQueue());
mDemuxerInitRequest.Complete();
if (NS_FAILED(aResult) && MediaPrefs::MediaWarningsAsErrors()) {
mMetadataPromise.Reject(aResult, __func__);
return;
}
mDemuxerInitDone = true;
UniquePtr<MetadataTags> tags(MakeUnique<MetadataTags>());
RefPtr<PDMFactory> platform;
if (!IsWaitingOnCDMResource()) {
platform = new PDMFactory();
}
// To decode, we need valid video and a place to put it.
bool videoActive =
!!mDemuxer->GetNumberTracks(TrackInfo::kVideoTrack) && GetImageContainer();
if (videoActive) {
// We currently only handle the first video track.
mVideo.mTrackDemuxer = mDemuxer->GetTrackDemuxer(TrackInfo::kVideoTrack, 0);
if (!mVideo.mTrackDemuxer) {
mMetadataPromise.Reject(NS_ERROR_DOM_MEDIA_METADATA_ERR, __func__);
return;
}
UniquePtr<TrackInfo> videoInfo = mVideo.mTrackDemuxer->GetInfo();
videoActive = videoInfo && videoInfo->IsValid();
if (videoActive) {
if (platform &&
!platform->SupportsMimeType(videoInfo->mMimeType, nullptr)) {
// We have no decoder for this track. Error.
mMetadataPromise.Reject(NS_ERROR_DOM_MEDIA_METADATA_ERR, __func__);
return;
}
{
MutexAutoLock lock(mVideo.mMutex);
mInfo.mVideo = *videoInfo->GetAsVideoInfo();
}
for (const MetadataTag& tag : videoInfo->mTags) {
tags->Put(tag.mKey, tag.mValue);
}
mVideo.mOriginalInfo = Move(videoInfo);
mTrackDemuxersMayBlock |= mVideo.mTrackDemuxer->GetSamplesMayBlock();
} else {
mVideo.mTrackDemuxer->BreakCycles();
mVideo.mTrackDemuxer = nullptr;
}
}
bool audioActive = !!mDemuxer->GetNumberTracks(TrackInfo::kAudioTrack);
if (audioActive) {
mAudio.mTrackDemuxer = mDemuxer->GetTrackDemuxer(TrackInfo::kAudioTrack, 0);
if (!mAudio.mTrackDemuxer) {
mMetadataPromise.Reject(NS_ERROR_DOM_MEDIA_METADATA_ERR, __func__);
return;
}
UniquePtr<TrackInfo> audioInfo = mAudio.mTrackDemuxer->GetInfo();
// We actively ignore audio tracks that we know we can't play.
audioActive =
audioInfo && audioInfo->IsValid() &&
(!platform || platform->SupportsMimeType(audioInfo->mMimeType, nullptr));
if (audioActive) {
{
MutexAutoLock lock(mAudio.mMutex);
mInfo.mAudio = *audioInfo->GetAsAudioInfo();
}
for (const MetadataTag& tag : audioInfo->mTags) {
tags->Put(tag.mKey, tag.mValue);
}
mAudio.mOriginalInfo = Move(audioInfo);
mTrackDemuxersMayBlock |= mAudio.mTrackDemuxer->GetSamplesMayBlock();
} else {
mAudio.mTrackDemuxer->BreakCycles();
mAudio.mTrackDemuxer = nullptr;
}
}
UniquePtr<EncryptionInfo> crypto = mDemuxer->GetCrypto();
if (crypto && crypto->IsEncrypted()) {
// Try and dispatch 'encrypted'. Won't go if ready state still HAVE_NOTHING.
for (uint32_t i = 0; i < crypto->mInitDatas.Length(); i++) {
mOnEncrypted.Notify(crypto->mInitDatas[i].mInitData,
crypto->mInitDatas[i].mType);
}
mInfo.mCrypto = *crypto;
}
auto videoDuration = HasVideo() ? mInfo.mVideo.mDuration : TimeUnit::Zero();
auto audioDuration = HasAudio() ? mInfo.mAudio.mDuration : TimeUnit::Zero();
auto duration = std::max(videoDuration, audioDuration);
if (duration.IsPositive()) {
mInfo.mMetadataDuration = Some(duration);
}
mInfo.mMediaSeekable = mDemuxer->IsSeekable();
mInfo.mMediaSeekableOnlyInBufferedRanges =
mDemuxer->IsSeekableOnlyInBufferedRanges();
if (!videoActive && !audioActive) {
mMetadataPromise.Reject(NS_ERROR_DOM_MEDIA_METADATA_ERR, __func__);
return;
}
mTags = Move(tags);
mInitDone = true;
// Try to get the start time.
// For MSE case, the start time of each track is assumed to be 0.
// For others, we must demux the first sample to know the start time for each
// track.
if (!mDemuxer->ShouldComputeStartTime()) {
mAudio.mFirstDemuxedSampleTime.emplace(TimeUnit::Zero());
mVideo.mFirstDemuxedSampleTime.emplace(TimeUnit::Zero());
} else {
if (HasAudio()) {
RequestDemuxSamples(TrackInfo::kAudioTrack);
}
if (HasVideo()) {
RequestDemuxSamples(TrackInfo::kVideoTrack);
}
}
if (aResult != NS_OK) {
mOnDecodeWarning.Notify(aResult);
}
MaybeResolveMetadataPromise();
}
void
MediaFormatReader::MaybeResolveMetadataPromise()
{
MOZ_ASSERT(OnTaskQueue());
if ((HasAudio() && mAudio.mFirstDemuxedSampleTime.isNothing()) ||
(HasVideo() && mVideo.mFirstDemuxedSampleTime.isNothing())) {
return;
}
TimeUnit startTime =
std::min(mAudio.mFirstDemuxedSampleTime.refOr(TimeUnit::FromInfinity()),
mVideo.mFirstDemuxedSampleTime.refOr(TimeUnit::FromInfinity()));
if (!startTime.IsInfinite()) {
mInfo.mStartTime = startTime; // mInfo.mStartTime is initialized to 0.
}
MetadataHolder metadata;
metadata.mInfo = MakeUnique<MediaInfo>(mInfo);
metadata.mTags = mTags->Count() ? Move(mTags) : nullptr;
// We now have all the informations required to calculate the initial buffered
// range.
mHasStartTime = true;
UpdateBuffered();
mMetadataPromise.Resolve(Move(metadata), __func__);
}
bool
MediaFormatReader::IsEncrypted() const
{
return (HasAudio() && mInfo.mAudio.mCrypto.mValid) ||
(HasVideo() && mInfo.mVideo.mCrypto.mValid);
}
void
MediaFormatReader::OnDemuxerInitFailed(const MediaResult& aError)
{
mDemuxerInitRequest.Complete();
mMetadataPromise.Reject(aError, __func__);
}
void
MediaFormatReader::ReadUpdatedMetadata(MediaInfo* aInfo)
{
*aInfo = mInfo;
}
MediaFormatReader::DecoderData&
MediaFormatReader::GetDecoderData(TrackType aTrack)
{
MOZ_ASSERT(aTrack == TrackInfo::kAudioTrack ||
aTrack == TrackInfo::kVideoTrack);
if (aTrack == TrackInfo::kAudioTrack) {
return mAudio;
}
return mVideo;
}
bool
MediaFormatReader::ShouldSkip(TimeUnit aTimeThreshold)
{
MOZ_ASSERT(HasVideo());
if (!MediaPrefs::MFRSkipToNextKeyFrameEnabled()) {
return false;
}
TimeUnit nextKeyframe;
nsresult rv = mVideo.mTrackDemuxer->GetNextRandomAccessPoint(&nextKeyframe);
if (NS_FAILED(rv)) {
// Only OggTrackDemuxer with video type gets into here.
// We don't support skip-to-next-frame for this case.
return false;
}
return (nextKeyframe <= aTimeThreshold ||
(mVideo.mTimeThreshold &&
mVideo.mTimeThreshold.ref().EndTime() < aTimeThreshold)) &&
nextKeyframe.ToMicroseconds() >= 0 && !nextKeyframe.IsInfinite();
}
RefPtr<MediaFormatReader::VideoDataPromise>
MediaFormatReader::RequestVideoData(const TimeUnit& aTimeThreshold)
{
MOZ_ASSERT(OnTaskQueue());
MOZ_DIAGNOSTIC_ASSERT(mSeekPromise.IsEmpty(),
"No sample requests allowed while seeking");
MOZ_DIAGNOSTIC_ASSERT(!mVideo.HasPromise(), "No duplicate sample requests");
MOZ_DIAGNOSTIC_ASSERT(!mVideo.mSeekRequest.Exists() ||
mVideo.mTimeThreshold.isSome());
MOZ_DIAGNOSTIC_ASSERT(!IsSeeking(), "called mid-seek");
LOGV("RequestVideoData(%" PRId64 ")", aTimeThreshold.ToMicroseconds());
if (!HasVideo()) {
LOG("called with no video track");
return VideoDataPromise::CreateAndReject(NS_ERROR_DOM_MEDIA_FATAL_ERR,
__func__);
}
if (IsSeeking()) {
LOG("called mid-seek. Rejecting.");
return VideoDataPromise::CreateAndReject(NS_ERROR_DOM_MEDIA_CANCELED,
__func__);
}
if (mShutdown) {
NS_WARNING("RequestVideoData on shutdown MediaFormatReader!");
return VideoDataPromise::CreateAndReject(NS_ERROR_DOM_MEDIA_CANCELED,
__func__);
}
// Ensure we have no pending seek going as ShouldSkip could return out of date
// information.
if (!mVideo.HasInternalSeekPending() && ShouldSkip(aTimeThreshold)) {
RefPtr<VideoDataPromise> p = mVideo.EnsurePromise(__func__);
SkipVideoDemuxToNextKeyFrame(aTimeThreshold);
return p;
}
RefPtr<VideoDataPromise> p = mVideo.EnsurePromise(__func__);
ScheduleUpdate(TrackInfo::kVideoTrack);
return p;
}
void
MediaFormatReader::OnDemuxFailed(TrackType aTrack, const MediaResult& aError)
{
MOZ_ASSERT(OnTaskQueue());
LOG("Failed to demux %s, failure:%" PRIu32,
aTrack == TrackType::kVideoTrack ? "video" : "audio",
static_cast<uint32_t>(aError.Code()));
auto& decoder = GetDecoderData(aTrack);
decoder.mDemuxRequest.Complete();
switch (aError.Code()) {
case NS_ERROR_DOM_MEDIA_END_OF_STREAM:
if (!decoder.mWaitingForData) {
decoder.RequestDrain();
}
NotifyEndOfStream(aTrack);
break;
case NS_ERROR_DOM_MEDIA_WAITING_FOR_DATA:
if (!decoder.mWaitingForData) {
decoder.RequestDrain();
}
NotifyWaitingForData(aTrack);
break;
case NS_ERROR_DOM_MEDIA_CANCELED:
if (decoder.HasPromise()) {
decoder.RejectPromise(NS_ERROR_DOM_MEDIA_CANCELED, __func__);
}
break;
default:
NotifyError(aTrack, aError);
break;
}
}
void
MediaFormatReader::DoDemuxVideo()
{
using SamplesPromise = MediaTrackDemuxer::SamplesPromise;
auto p = mVideo.mTrackDemuxer->GetSamples(1);
if (mVideo.mFirstDemuxedSampleTime.isNothing()) {
RefPtr<MediaFormatReader> self = this;
p = p->Then(OwnerThread(), __func__,
[self] (RefPtr<MediaTrackDemuxer::SamplesHolder> aSamples) {
self->OnFirstDemuxCompleted(TrackInfo::kVideoTrack, aSamples);
return SamplesPromise::CreateAndResolve(aSamples.forget(), __func__);
},
[self] (const MediaResult& aError) {
self->OnFirstDemuxFailed(TrackInfo::kVideoTrack, aError);
return SamplesPromise::CreateAndReject(aError, __func__);
});
}
p->Then(OwnerThread(), __func__, this,
&MediaFormatReader::OnVideoDemuxCompleted,
&MediaFormatReader::OnVideoDemuxFailed)
->Track(mVideo.mDemuxRequest);
}
void
MediaFormatReader::OnVideoDemuxCompleted(
RefPtr<MediaTrackDemuxer::SamplesHolder> aSamples)
{
LOGV("%zu video samples demuxed (sid:%d)",
aSamples->mSamples.Length(),
aSamples->mSamples[0]->mTrackInfo
? aSamples->mSamples[0]->mTrackInfo->GetID()
: 0);
mVideo.mDemuxRequest.Complete();
mVideo.mQueuedSamples.AppendElements(aSamples->mSamples);
ScheduleUpdate(TrackInfo::kVideoTrack);
}
RefPtr<MediaFormatReader::AudioDataPromise>
MediaFormatReader::RequestAudioData()
{
MOZ_ASSERT(OnTaskQueue());
MOZ_DIAGNOSTIC_ASSERT(!mAudio.HasPromise(), "No duplicate sample requests");
MOZ_DIAGNOSTIC_ASSERT(IsVideoSeeking() || mSeekPromise.IsEmpty(),
"No sample requests allowed while seeking");
MOZ_DIAGNOSTIC_ASSERT(IsVideoSeeking() || !mAudio.mSeekRequest.Exists() ||
mAudio.mTimeThreshold.isSome());
MOZ_DIAGNOSTIC_ASSERT(IsVideoSeeking() || !IsSeeking(), "called mid-seek");
LOGV("");
if (!HasAudio()) {
LOG("called with no audio track");
return AudioDataPromise::CreateAndReject(NS_ERROR_DOM_MEDIA_FATAL_ERR,
__func__);
}
if (IsSeeking()) {
LOG("called mid-seek. Rejecting.");
return AudioDataPromise::CreateAndReject(NS_ERROR_DOM_MEDIA_CANCELED,
__func__);
}
if (mShutdown) {
NS_WARNING("RequestAudioData on shutdown MediaFormatReader!");
return AudioDataPromise::CreateAndReject(NS_ERROR_DOM_MEDIA_CANCELED,
__func__);
}
RefPtr<AudioDataPromise> p = mAudio.EnsurePromise(__func__);
ScheduleUpdate(TrackInfo::kAudioTrack);
return p;
}
void
MediaFormatReader::DoDemuxAudio()
{
using SamplesPromise = MediaTrackDemuxer::SamplesPromise;
auto p = mAudio.mTrackDemuxer->GetSamples(1);
if (mAudio.mFirstDemuxedSampleTime.isNothing()) {
RefPtr<MediaFormatReader> self = this;
p = p->Then(OwnerThread(), __func__,
[self] (RefPtr<MediaTrackDemuxer::SamplesHolder> aSamples) {
self->OnFirstDemuxCompleted(TrackInfo::kAudioTrack, aSamples);
return SamplesPromise::CreateAndResolve(aSamples.forget(), __func__);
},
[self] (const MediaResult& aError) {
self->OnFirstDemuxFailed(TrackInfo::kAudioTrack, aError);
return SamplesPromise::CreateAndReject(aError, __func__);
});
}
p->Then(OwnerThread(), __func__, this,
&MediaFormatReader::OnAudioDemuxCompleted,
&MediaFormatReader::OnAudioDemuxFailed)
->Track(mAudio.mDemuxRequest);
}
void
MediaFormatReader::OnAudioDemuxCompleted(
RefPtr<MediaTrackDemuxer::SamplesHolder> aSamples)
{
LOGV("%zu audio samples demuxed (sid:%d)",
aSamples->mSamples.Length(),
aSamples->mSamples[0]->mTrackInfo
? aSamples->mSamples[0]->mTrackInfo->GetID()
: 0);
mAudio.mDemuxRequest.Complete();
mAudio.mQueuedSamples.AppendElements(aSamples->mSamples);
ScheduleUpdate(TrackInfo::kAudioTrack);
}
void
MediaFormatReader::NotifyNewOutput(
TrackType aTrack, const MediaDataDecoder::DecodedData& aResults)
{
MOZ_ASSERT(OnTaskQueue());
auto& decoder = GetDecoderData(aTrack);
for (auto& sample : aResults) {
LOGV("Received new %s sample time:%" PRId64 " duration:%" PRId64,
TrackTypeToStr(aTrack), sample->mTime.ToMicroseconds(),
sample->mDuration.ToMicroseconds());
decoder.mOutput.AppendElement(sample);
decoder.mNumSamplesOutput++;
decoder.mNumOfConsecutiveError = 0;
}
LOG("Done processing new %s samples", TrackTypeToStr(aTrack));
if (!aResults.IsEmpty()) {
// We have decoded our first frame, we can now starts to skip future errors.
decoder.mFirstFrameTime.reset();
}
ScheduleUpdate(aTrack);
}
void
MediaFormatReader::NotifyError(TrackType aTrack, const MediaResult& aError)
{
MOZ_ASSERT(OnTaskQueue());
NS_WARNING(aError.Description().get());
LOGV("%s Decoding error", TrackTypeToStr(aTrack));
auto& decoder = GetDecoderData(aTrack);
decoder.mError = decoder.HasFatalError() ? decoder.mError : Some(aError);
// The GPU process had crashed and we receive a
// NS_ERROR_DOM_MEDIA_NEED_NEW_DECODER because we were doing HW decoding.
// Now, save the related data and we will report the recovery time when a new
// decoder is ready.
if (aTrack == TrackType::kVideoTrack &&
aError == NS_ERROR_DOM_MEDIA_NEED_NEW_DECODER &&
!aError.GPUCrashTimeStamp().IsNull()) {
GPUProcessCrashTelemetryLogger::RecordGPUCrashData(mMediaDecoderOwnerID,
&decoder,
aError.GPUCrashTimeStamp(),
TimeStamp::Now());
}
ScheduleUpdate(aTrack);
}
void
MediaFormatReader::NotifyWaitingForData(TrackType aTrack)
{
MOZ_ASSERT(OnTaskQueue());
auto& decoder = GetDecoderData(aTrack);
decoder.mWaitingForData = true;
if (decoder.mTimeThreshold) {
decoder.mTimeThreshold.ref().mWaiting = true;
}
ScheduleUpdate(aTrack);
}
void
MediaFormatReader::NotifyWaitingForKey(TrackType aTrack)
{
MOZ_ASSERT(OnTaskQueue());
auto& decoder = GetDecoderData(aTrack);
mOnWaitingForKey.Notify();
if (!decoder.mDecodeRequest.Exists()) {
LOGV("WaitingForKey received while no pending decode. Ignoring");
return;
}
decoder.mWaitingForKey = true;
ScheduleUpdate(aTrack);
}
void
MediaFormatReader::NotifyEndOfStream(TrackType aTrack)
{
MOZ_ASSERT(OnTaskQueue());
auto& decoder = GetDecoderData(aTrack);
decoder.mDemuxEOS = true;
ScheduleUpdate(aTrack);
}
bool
MediaFormatReader::NeedInput(DecoderData& aDecoder)
{
// The decoder will not be fed a new raw sample until the current decoding
// requests has completed.
return
(aDecoder.HasPromise() || aDecoder.mTimeThreshold.isSome()) &&
!aDecoder.HasPendingDrain() &&
!aDecoder.HasFatalError() &&
!aDecoder.mDemuxRequest.Exists() &&
!aDecoder.mOutput.Length() &&
!aDecoder.HasInternalSeekPending() &&
!aDecoder.mDecodeRequest.Exists();
}
void
MediaFormatReader::ScheduleUpdate(TrackType aTrack)
{
MOZ_ASSERT(OnTaskQueue());
if (mShutdown) {
return;
}
auto& decoder = GetDecoderData(aTrack);
if (decoder.mUpdateScheduled) {
return;
}
LOGV("SchedulingUpdate(%s)", TrackTypeToStr(aTrack));
decoder.mUpdateScheduled = true;
RefPtr<nsIRunnable> task(NewRunnableMethod<TrackType>(
"MediaFormatReader::Update", this, &MediaFormatReader::Update, aTrack));
OwnerThread()->Dispatch(task.forget());
}
bool
MediaFormatReader::UpdateReceivedNewData(TrackType aTrack)
{
MOZ_ASSERT(OnTaskQueue());
auto& decoder = GetDecoderData(aTrack);
if (!decoder.mReceivedNewData) {
return false;
}
// We do not want to clear mWaitingForData while there are pending
// demuxing or seeking operations that could affect the value of this flag.
// This is in order to ensure that we will retry once they complete as we may
// now have new data that could potentially allow those operations to
// successfully complete if tried again.
if (decoder.mSeekRequest.Exists()) {
// Nothing more to do until this operation complete.
return true;
}
if (aTrack == TrackType::kVideoTrack && mSkipRequest.Exists()) {
LOGV("Skipping in progress, nothing more to do");
return true;
}
if (decoder.mDemuxRequest.Exists()) {
// We may have pending operations to process, so we want to continue
// after UpdateReceivedNewData returns.
return false;
}
if (decoder.HasPendingDrain()) {
// We do not want to clear mWaitingForData or mDemuxEOS while
// a drain is in progress in order to properly complete the operation.
return false;
}
decoder.mReceivedNewData = false;
if (decoder.mTimeThreshold) {
decoder.mTimeThreshold.ref().mWaiting = false;
}
decoder.mWaitingForData = false;
if (decoder.HasFatalError()) {
return false;
}
if (!mSeekPromise.IsEmpty() &&
(!IsVideoSeeking() || aTrack == TrackInfo::kVideoTrack)) {
MOZ_ASSERT(!decoder.HasPromise());
MOZ_DIAGNOSTIC_ASSERT(
(IsVideoSeeking() || !mAudio.mTimeThreshold) && !mVideo.mTimeThreshold,
"InternalSeek must have been aborted when Seek was first called");
MOZ_DIAGNOSTIC_ASSERT(
(IsVideoSeeking() || !mAudio.HasWaitingPromise()) &&
!mVideo.HasWaitingPromise(),
"Waiting promises must have been rejected when Seek was first called");
if (mVideo.mSeekRequest.Exists() ||
(!IsVideoSeeking() && mAudio.mSeekRequest.Exists())) {
// Already waiting for a seek to complete. Nothing more to do.
return true;
}
LOG("Attempting Seek");
ScheduleSeek();
return true;
}
if (decoder.HasInternalSeekPending() || decoder.HasWaitingPromise()) {
if (decoder.HasInternalSeekPending()) {
LOG("Attempting Internal Seek");
InternalSeek(aTrack, decoder.mTimeThreshold.ref());
}
if (decoder.HasWaitingPromise() && !decoder.IsWaiting()) {
MOZ_ASSERT(!decoder.HasPromise());
LOG("We have new data. Resolving WaitingPromise");
decoder.mWaitingPromise.Resolve(decoder.mType, __func__);
}
return true;
}
return false;
}
void
MediaFormatReader::RequestDemuxSamples(TrackType aTrack)
{
MOZ_ASSERT(OnTaskQueue());
auto& decoder = GetDecoderData(aTrack);
MOZ_ASSERT(!decoder.mDemuxRequest.Exists());
if (!decoder.mQueuedSamples.IsEmpty()) {
// No need to demux new samples.
return;
}
if (decoder.mDemuxEOS) {
// Nothing left to demux.
// We do not want to attempt to demux while in waiting for data mode
// as it would retrigger an unecessary drain.
return;
}
LOGV("Requesting extra demux %s", TrackTypeToStr(aTrack));
if (aTrack == TrackInfo::kVideoTrack) {
DoDemuxVideo();
} else {
DoDemuxAudio();
}
}
void
MediaFormatReader::DecodeDemuxedSamples(TrackType aTrack,
MediaRawData* aSample)
{
MOZ_ASSERT(OnTaskQueue());
auto& decoder = GetDecoderData(aTrack);
RefPtr<MediaFormatReader> self = this;
decoder.mFlushed = false;
decoder.mDecoder->Decode(aSample)
->Then(mTaskQueue, __func__,
[self, this, aTrack, &decoder]
(const MediaDataDecoder::DecodedData& aResults) {
decoder.mDecodeRequest.Complete();
NotifyNewOutput(aTrack, aResults);
// When we recovered from a GPU crash and get the first decoded
// frame, report the recovery time telemetry.
if (aTrack == TrackType::kVideoTrack) {
GPUProcessCrashTelemetryLogger::ReportTelemetry(
mMediaDecoderOwnerID, &decoder);
}
},
[self, this, aTrack, &decoder](const MediaResult& aError) {
decoder.mDecodeRequest.Complete();
NotifyError(aTrack, aError);
})
->Track(decoder.mDecodeRequest);
}
void
MediaFormatReader::HandleDemuxedSamples(
TrackType aTrack, FrameStatistics::AutoNotifyDecoded& aA)
{
MOZ_ASSERT(OnTaskQueue());
auto& decoder = GetDecoderData(aTrack);
if (decoder.mFlushing) {
LOGV("Decoder operation in progress, let it complete.");
return;
}
if (decoder.mQueuedSamples.IsEmpty()) {
return;
}
if (!decoder.mDecoder) {
mDecoderFactory->CreateDecoder(aTrack);
return;
}
LOGV("Giving %s input to decoder", TrackTypeToStr(aTrack));
// Decode all our demuxed frames.
while (decoder.mQueuedSamples.Length()) {
RefPtr<MediaRawData> sample = decoder.mQueuedSamples[0];
RefPtr<TrackInfoSharedPtr> info = sample->mTrackInfo;
if (info && decoder.mLastStreamSourceID != info->GetID()) {
bool recyclable = MediaPrefs::MediaDecoderCheckRecycling() &&
decoder.mDecoder->SupportDecoderRecycling();
if (!recyclable && decoder.mTimeThreshold.isNothing() &&
(decoder.mNextStreamSourceID.isNothing() ||
decoder.mNextStreamSourceID.ref() != info->GetID())) {
LOG("%s stream id has changed from:%d to:%d, draining decoder.",
TrackTypeToStr(aTrack),
decoder.mLastStreamSourceID,
info->GetID());
decoder.RequestDrain();
decoder.mNextStreamSourceID = Some(info->GetID());
ScheduleUpdate(aTrack);
return;
}
LOG("%s stream id has changed from:%d to:%d.",
TrackTypeToStr(aTrack), decoder.mLastStreamSourceID,
info->GetID());
decoder.mLastStreamSourceID = info->GetID();
decoder.mNextStreamSourceID.reset();
if (!recyclable) {
LOG("Decoder does not support recycling, recreate decoder.");
// If flushing is required, it will clear our array of queued samples.
// So make a copy now.
nsTArray<RefPtr<MediaRawData>> samples{ Move(decoder.mQueuedSamples) };
ShutdownDecoder(aTrack);
if (sample->mKeyframe) {
decoder.mQueuedSamples.AppendElements(Move(samples));
}
} else if (decoder.HasWaitingPromise()) {
decoder.Flush();
}
decoder.mInfo = info;
if (sample->mKeyframe) {
ScheduleUpdate(aTrack);
} else {
auto time = TimeInterval(sample->mTime, sample->GetEndTime());
InternalSeekTarget seekTarget =
decoder.mTimeThreshold.refOr(InternalSeekTarget(time, false));
LOG("Stream change occurred on a non-keyframe. Seeking to:%" PRId64,
sample->mTime.ToMicroseconds());
InternalSeek(aTrack, seekTarget);
}
return;
}
LOGV("Input:%" PRId64 " (dts:%" PRId64 " kf:%d)",
sample->mTime.ToMicroseconds(), sample->mTimecode.ToMicroseconds(),
sample->mKeyframe);
decoder.mNumSamplesInput++;
decoder.mSizeOfQueue++;
if (aTrack == TrackInfo::kVideoTrack) {
aA.mStats.mParsedFrames++;
}
DecodeDemuxedSamples(aTrack, sample);
decoder.mQueuedSamples.RemoveElementAt(0);
break;
}
}
void
MediaFormatReader::InternalSeek(TrackType aTrack,
const InternalSeekTarget& aTarget)
{
MOZ_ASSERT(OnTaskQueue());
LOG("%s internal seek to %f",
TrackTypeToStr(aTrack), aTarget.Time().ToSeconds());
auto& decoder = GetDecoderData(aTrack);
decoder.Flush();
decoder.ResetDemuxer();
decoder.mTimeThreshold = Some(aTarget);
RefPtr<MediaFormatReader> self = this;
decoder.mTrackDemuxer->Seek(decoder.mTimeThreshold.ref().Time())
->Then(OwnerThread(), __func__,
[self, aTrack] (TimeUnit aTime) {
auto& decoder = self->GetDecoderData(aTrack);
decoder.mSeekRequest.Complete();
MOZ_ASSERT(
decoder.mTimeThreshold,
"Seek promise must be disconnected when timethreshold is reset");
decoder.mTimeThreshold.ref().mHasSeeked = true;
self->SetVideoDecodeThreshold();
self->ScheduleUpdate(aTrack);
},
[self, aTrack] (const MediaResult& aError) {
auto& decoder = self->GetDecoderData(aTrack);
decoder.mSeekRequest.Complete();
switch (aError.Code()) {
case NS_ERROR_DOM_MEDIA_WAITING_FOR_DATA:
self->NotifyWaitingForData(aTrack);
break;
case NS_ERROR_DOM_MEDIA_END_OF_STREAM:
decoder.mTimeThreshold.reset();
self->NotifyEndOfStream(aTrack);
break;
case NS_ERROR_DOM_MEDIA_CANCELED:
decoder.mTimeThreshold.reset();
break;
default:
decoder.mTimeThreshold.reset();
self->NotifyError(aTrack, aError);
break;
}
})
->Track(decoder.mSeekRequest);
}
void
MediaFormatReader::DrainDecoder(TrackType aTrack)
{
MOZ_ASSERT(OnTaskQueue());
auto& decoder = GetDecoderData(aTrack);
if (decoder.mDrainState == DrainState::Draining) {
return;
}
if (!decoder.mDecoder ||
(decoder.mDrainState != DrainState::PartialDrainPending &&
decoder.mNumSamplesInput == decoder.mNumSamplesOutput)) {
// No frames to drain.
LOGV("Draining %s with nothing to drain", TrackTypeToStr(aTrack));
decoder.mDrainState = DrainState::DrainAborted;
ScheduleUpdate(aTrack);
return;
}
decoder.mDrainState = DrainState::Draining;
RefPtr<MediaFormatReader> self = this;
decoder.mDecoder->Drain()
->Then(mTaskQueue, __func__,
[self, this, aTrack, &decoder]
(const MediaDataDecoder::DecodedData& aResults) {
decoder.mDrainRequest.Complete();
if (aResults.IsEmpty()) {
decoder.mDrainState = DrainState::DrainCompleted;
} else {
NotifyNewOutput(aTrack, aResults);
// Let's see if we have any more data available to drain.
decoder.mDrainState = DrainState::PartialDrainPending;
}
ScheduleUpdate(aTrack);
},
[self, this, aTrack, &decoder](const MediaResult& aError) {
decoder.mDrainRequest.Complete();
NotifyError(aTrack, aError);
})
->Track(decoder.mDrainRequest);
LOG("Requesting %s decoder to drain", TrackTypeToStr(aTrack));
}
void
MediaFormatReader::Update(TrackType aTrack)
{
MOZ_ASSERT(OnTaskQueue());
if (mShutdown) {
return;
}
LOGV("Processing update for %s", TrackTypeToStr(aTrack));
bool needOutput = false;
auto& decoder = GetDecoderData(aTrack);
decoder.mUpdateScheduled = false;
if (!mInitDone) {
return;
}
if (aTrack == TrackType::kVideoTrack && mSkipRequest.Exists()) {
LOGV("Skipping in progress, nothing more to do");
return;
}
if (UpdateReceivedNewData(aTrack)) {
LOGV("Nothing more to do");
return;
}
if (decoder.mSeekRequest.Exists()) {
LOGV("Seeking hasn't completed, nothing more to do");
return;
}
MOZ_DIAGNOSTIC_ASSERT(
!decoder.HasInternalSeekPending() ||
(!decoder.mOutput.Length() && !decoder.mQueuedSamples.Length()),
"No frames can be demuxed or decoded while an internal seek is pending");
// Record number of frames decoded and parsed. Automatically update the
// stats counters using the AutoNotifyDecoded stack-based class.
FrameStatistics::AutoNotifyDecoded a(mFrameStats);
// Drop any frames found prior our internal seek target.
while (decoder.mTimeThreshold && decoder.mOutput.Length()) {
RefPtr<MediaData>& output = decoder.mOutput[0];
InternalSeekTarget target = decoder.mTimeThreshold.ref();
auto time = output->mTime;
if (time >= target.Time()) {
// We have reached our internal seek target.
decoder.mTimeThreshold.reset();
// We might have dropped some keyframes.
mPreviousDecodedKeyframeTime_us = sNoPreviousDecodedKeyframe;
}
if (time < target.Time() || (target.mDropTarget && target.Contains(time))) {
LOGV("Internal Seeking: Dropping %s frame time:%f wanted:%f (kf:%d)",
TrackTypeToStr(aTrack),
output->mTime.ToSeconds(),
target.Time().ToSeconds(),
output->mKeyframe);
decoder.mOutput.RemoveElementAt(0);
decoder.mSizeOfQueue -= 1;
}
}
while (decoder.mOutput.Length() &&
decoder.mOutput[0]->mType == MediaData::NULL_DATA) {
LOGV("Dropping null data. Time: %" PRId64,
decoder.mOutput[0]->mTime.ToMicroseconds());
decoder.mOutput.RemoveElementAt(0);
decoder.mSizeOfQueue -= 1;
}
if (decoder.HasPromise()) {
needOutput = true;
if (decoder.mOutput.Length()) {
RefPtr<MediaData> output = decoder.mOutput[0];
decoder.mOutput.RemoveElementAt(0);
decoder.mSizeOfQueue -= 1;
decoder.mLastDecodedSampleTime =
Some(TimeInterval(output->mTime, output->GetEndTime()));
decoder.mNumSamplesOutputTotal++;
ReturnOutput(output, aTrack);
// We have a decoded sample ready to be returned.
if (aTrack == TrackType::kVideoTrack) {
uint64_t delta =
decoder.mNumSamplesOutputTotal - mLastReportedNumDecodedFrames;
a.mStats.mDecodedFrames = static_cast<uint32_t>(delta);
mLastReportedNumDecodedFrames = decoder.mNumSamplesOutputTotal;
if (output->mKeyframe) {
if (mPreviousDecodedKeyframeTime_us < output->mTime.ToMicroseconds()) {
// There is a previous keyframe -> Record inter-keyframe stats.
uint64_t segment_us =
output->mTime.ToMicroseconds() - mPreviousDecodedKeyframeTime_us;
a.mStats.mInterKeyframeSum_us += segment_us;
a.mStats.mInterKeyframeCount += 1;
if (a.mStats.mInterKeyFrameMax_us < segment_us) {
a.mStats.mInterKeyFrameMax_us = segment_us;
}
}
mPreviousDecodedKeyframeTime_us = output->mTime.ToMicroseconds();
}
nsCString error;
mVideo.mIsHardwareAccelerated =
mVideo.mDecoder && mVideo.mDecoder->IsHardwareAccelerated(error);
#ifdef XP_WIN
// D3D11_YCBCR_IMAGE images are GPU based, we try to limit the amount
// of GPU RAM used.
VideoData* videoData = static_cast<VideoData*>(output.get());
mVideo.mIsHardwareAccelerated =
mVideo.mIsHardwareAccelerated ||
(videoData->mImage &&
videoData->mImage->GetFormat() == ImageFormat::D3D11_YCBCR_IMAGE);
#endif
}
} else if (decoder.HasFatalError()) {
LOG("Rejecting %s promise: DECODE_ERROR", TrackTypeToStr(aTrack));
decoder.RejectPromise(decoder.mError.ref(), __func__);
return;
} else if (decoder.HasCompletedDrain()) {
if (decoder.mDemuxEOS) {
LOG("Rejecting %s promise: EOS", TrackTypeToStr(aTrack));
decoder.RejectPromise(NS_ERROR_DOM_MEDIA_END_OF_STREAM, __func__);
} else if (decoder.mWaitingForData) {
if (decoder.mDrainState == DrainState::DrainCompleted &&
decoder.mLastDecodedSampleTime &&
!decoder.mNextStreamSourceID) {
// We have completed draining the decoder following WaitingForData.
// Set up the internal seek machinery to be able to resume from the
// last sample decoded.
LOG("Seeking to last sample time: %" PRId64,
decoder.mLastDecodedSampleTime.ref().mStart.ToMicroseconds());
InternalSeek(aTrack,
InternalSeekTarget(decoder.mLastDecodedSampleTime.ref(), true));
}
if (!decoder.mReceivedNewData) {
LOG("Rejecting %s promise: WAITING_FOR_DATA", TrackTypeToStr(aTrack));
decoder.RejectPromise(NS_ERROR_DOM_MEDIA_WAITING_FOR_DATA, __func__);
}
}
decoder.mDrainState = DrainState::None;
// Now that draining has completed, we check if we have received
// new data again as the result may now be different from the earlier
// run.
if (UpdateReceivedNewData(aTrack) || decoder.mSeekRequest.Exists()) {
LOGV("Nothing more to do");
return;
}
} else if (decoder.mDemuxEOS &&
!decoder.HasPendingDrain() &&
decoder.mQueuedSamples.IsEmpty()) {
// It is possible to transition from WAITING_FOR_DATA directly to EOS
// state during the internal seek; in which case no draining would occur.
// There is no more samples left to be decoded and we are already in
// EOS state. We can immediately reject the data promise.
LOG("Rejecting %s promise: EOS", TrackTypeToStr(aTrack));
decoder.RejectPromise(NS_ERROR_DOM_MEDIA_END_OF_STREAM, __func__);
} else if (decoder.mWaitingForKey) {
LOG("Rejecting %s promise: WAITING_FOR_DATA due to waiting for key",
TrackTypeToStr(aTrack));
decoder.RejectPromise(NS_ERROR_DOM_MEDIA_WAITING_FOR_DATA, __func__);
}
}
if (decoder.mDrainState == DrainState::DrainRequested ||
decoder.mDrainState == DrainState::PartialDrainPending) {
if (decoder.mOutput.IsEmpty()) {
DrainDecoder(aTrack);
}
return;
}
if (decoder.mError && !decoder.HasFatalError()) {
MOZ_RELEASE_ASSERT(!decoder.HasInternalSeekPending(),
"No error can occur while an internal seek is pending");
bool needsNewDecoder =
decoder.mError.ref() == NS_ERROR_DOM_MEDIA_NEED_NEW_DECODER;
if (!needsNewDecoder &&
++decoder.mNumOfConsecutiveError > decoder.mMaxConsecutiveError) {
NotifyError(aTrack, decoder.mError.ref());
return;
}
decoder.mError.reset();
LOG("%s decoded error count %d", TrackTypeToStr(aTrack),
decoder.mNumOfConsecutiveError);
if (needsNewDecoder) {
LOG("Error: Need new decoder");
ShutdownDecoder(aTrack);
}
if (decoder.mFirstFrameTime) {
TimeInterval seekInterval = TimeInterval(decoder.mFirstFrameTime.ref(),
decoder.mFirstFrameTime.ref());
InternalSeek(aTrack, InternalSeekTarget(seekInterval, false));
return;
}
TimeUnit nextKeyframe;
if (aTrack == TrackType::kVideoTrack &&
NS_SUCCEEDED(
decoder.mTrackDemuxer->GetNextRandomAccessPoint(&nextKeyframe)) &&
!nextKeyframe.IsInfinite()) {
SkipVideoDemuxToNextKeyFrame(
decoder.mLastDecodedSampleTime.refOr(TimeInterval()).Length());
} else if (aTrack == TrackType::kAudioTrack) {
decoder.Flush();
} else {
// We can't recover from this error.
NotifyError(aTrack, NS_ERROR_DOM_MEDIA_FATAL_ERR);
}
return;
}
bool needInput = NeedInput(decoder);
LOGV("Update(%s) ni=%d no=%d in:%" PRIu64 " out:%" PRIu64
" qs=%u decoding:%d flushing:%d desc:%s pending:%u waiting:%d eos:%d "
"ds:%d sid:%u",
TrackTypeToStr(aTrack),
needInput,
needOutput,
decoder.mNumSamplesInput,
decoder.mNumSamplesOutput,
uint32_t(size_t(decoder.mSizeOfQueue)),
decoder.mDecodeRequest.Exists(),
decoder.mFlushing,
decoder.mDescription.get(),
uint32_t(decoder.mOutput.Length()),
decoder.mWaitingForData,
decoder.mDemuxEOS,
int32_t(decoder.mDrainState),
decoder.mLastStreamSourceID);
if (IsWaitingOnCDMResource()) {
// If the content is encrypted, MFR won't start to create decoder until
// CDMProxy is set.
return;
}
if ((decoder.mWaitingForData &&
(!decoder.mTimeThreshold || decoder.mTimeThreshold.ref().mWaiting)) ||
(decoder.mWaitingForKey && decoder.mDecodeRequest.Exists())) {
// Nothing more we can do at present.
LOGV("Still waiting for data or key.");
return;
}
if (decoder.CancelWaitingForKey()) {
LOGV("No longer waiting for key. Resolving waiting promise");
return;
}
if (!needInput) {
LOGV("No need for additional input (pending:%u)",
uint32_t(decoder.mOutput.Length()));
return;
}
// Demux samples if we don't have some.
RequestDemuxSamples(aTrack);
HandleDemuxedSamples(aTrack, a);
}
void
MediaFormatReader::ReturnOutput(MediaData* aData, TrackType aTrack)
{
MOZ_ASSERT(GetDecoderData(aTrack).HasPromise());
MOZ_DIAGNOSTIC_ASSERT(aData->mType != MediaData::NULL_DATA);
LOG("Resolved data promise for %s [%" PRId64 ", %" PRId64 "]",
TrackTypeToStr(aTrack),
aData->mTime.ToMicroseconds(),
aData->GetEndTime().ToMicroseconds());
if (aTrack == TrackInfo::kAudioTrack) {
AudioData* audioData = static_cast<AudioData*>(aData);
if (audioData->mChannels != mInfo.mAudio.mChannels ||
audioData->mRate != mInfo.mAudio.mRate) {
LOG("change of audio format (rate:%d->%d). "
"This is an unsupported configuration",
mInfo.mAudio.mRate,
audioData->mRate);
mInfo.mAudio.mRate = audioData->mRate;
mInfo.mAudio.mChannels = audioData->mChannels;
}
mAudio.ResolvePromise(audioData, __func__);
} else if (aTrack == TrackInfo::kVideoTrack) {
VideoData* videoData = static_cast<VideoData*>(aData);
if (videoData->mDisplay != mInfo.mVideo.mDisplay) {
LOG("change of video display size (%dx%d->%dx%d)",
mInfo.mVideo.mDisplay.width, mInfo.mVideo.mDisplay.height,
videoData->mDisplay.width, videoData->mDisplay.height);
mInfo.mVideo.mDisplay = videoData->mDisplay;
}
TimeUnit nextKeyframe;
if (!mVideo.HasInternalSeekPending() &&
NS_SUCCEEDED(
mVideo.mTrackDemuxer->GetNextRandomAccessPoint(&nextKeyframe))) {
videoData->SetNextKeyFrameTime(nextKeyframe);
}
mVideo.ResolvePromise(videoData, __func__);
}
}
size_t
MediaFormatReader::SizeOfVideoQueueInFrames()
{
return SizeOfQueue(TrackInfo::kVideoTrack);
}
size_t
MediaFormatReader::SizeOfAudioQueueInFrames()
{
return SizeOfQueue(TrackInfo::kAudioTrack);
}
size_t
MediaFormatReader::SizeOfQueue(TrackType aTrack)
{
auto& decoder = GetDecoderData(aTrack);
return decoder.mSizeOfQueue;
}
RefPtr<MediaFormatReader::WaitForDataPromise>
MediaFormatReader::WaitForData(MediaData::Type aType)
{
MOZ_ASSERT(OnTaskQueue());
TrackType trackType = aType == MediaData::VIDEO_DATA ?
TrackType::kVideoTrack : TrackType::kAudioTrack;
auto& decoder = GetDecoderData(trackType);
if (!decoder.IsWaiting()) {
// We aren't waiting for anything.
return WaitForDataPromise::CreateAndResolve(decoder.mType, __func__);
}
RefPtr<WaitForDataPromise> p = decoder.mWaitingPromise.Ensure(__func__);
ScheduleUpdate(trackType);
return p;
}
nsresult
MediaFormatReader::ResetDecode(TrackSet aTracks)
{
MOZ_ASSERT(OnTaskQueue());
LOGV("");
mSeekPromise.RejectIfExists(NS_OK, __func__);
mSkipRequest.DisconnectIfExists();
// Do the same for any data wait promises.
if (aTracks.contains(TrackInfo::kAudioTrack)) {
mAudio.mWaitingPromise.RejectIfExists(
WaitForDataRejectValue(MediaData::AUDIO_DATA,
WaitForDataRejectValue::CANCELED), __func__);
}
if (aTracks.contains(TrackInfo::kVideoTrack)) {
mVideo.mWaitingPromise.RejectIfExists(
WaitForDataRejectValue(MediaData::VIDEO_DATA,
WaitForDataRejectValue::CANCELED), __func__);
}
// Reset miscellaneous seeking state.
mPendingSeekTime.reset();
if (HasVideo() && aTracks.contains(TrackInfo::kVideoTrack)) {
mVideo.ResetDemuxer();
mVideo.mFirstFrameTime = Some(media::TimeUnit::Zero());
Reset(TrackInfo::kVideoTrack);
if (mVideo.HasPromise()) {
mVideo.RejectPromise(NS_ERROR_DOM_MEDIA_CANCELED, __func__);
}
}
if (HasAudio() && aTracks.contains(TrackInfo::kAudioTrack)) {
mAudio.ResetDemuxer();
mVideo.mFirstFrameTime = Some(media::TimeUnit::Zero());
Reset(TrackInfo::kAudioTrack);
if (mAudio.HasPromise()) {
mAudio.RejectPromise(NS_ERROR_DOM_MEDIA_CANCELED, __func__);
}
}
return NS_OK;
}
void
MediaFormatReader::Reset(TrackType aTrack)
{
MOZ_ASSERT(OnTaskQueue());
LOG("Reset(%s) BEGIN", TrackTypeToStr(aTrack));
auto& decoder = GetDecoderData(aTrack);
decoder.ResetState();
decoder.Flush();
LOG("Reset(%s) END", TrackTypeToStr(aTrack));
}
void
MediaFormatReader::DropDecodedSamples(TrackType aTrack)
{
MOZ_ASSERT(OnTaskQueue());
auto& decoder = GetDecoderData(aTrack);
size_t lengthDecodedQueue = decoder.mOutput.Length();
if (lengthDecodedQueue && decoder.mTimeThreshold.isSome()) {
auto time = decoder.mOutput.LastElement()->mTime;
if (time >= decoder.mTimeThreshold.ref().Time()) {
// We would have reached our internal seek target.
decoder.mTimeThreshold.reset();
}
}
decoder.mOutput.Clear();
decoder.mSizeOfQueue -= lengthDecodedQueue;
if (aTrack == TrackInfo::kVideoTrack && mFrameStats) {
mFrameStats->NotifyDecodedFrames({ 0, 0, lengthDecodedQueue });
}
}
void
MediaFormatReader::SkipVideoDemuxToNextKeyFrame(TimeUnit aTimeThreshold)
{
MOZ_ASSERT(OnTaskQueue());
LOG("Skipping up to %" PRId64, aTimeThreshold.ToMicroseconds());
// We've reached SkipVideoDemuxToNextKeyFrame when our decoding is late.
// As such we can drop all already decoded samples and discard all pending
// samples.
DropDecodedSamples(TrackInfo::kVideoTrack);
mVideo.mTrackDemuxer->SkipToNextRandomAccessPoint(aTimeThreshold)
->Then(OwnerThread(), __func__, this,
&MediaFormatReader::OnVideoSkipCompleted,
&MediaFormatReader::OnVideoSkipFailed)
->Track(mSkipRequest);
}
void
MediaFormatReader::VideoSkipReset(uint32_t aSkipped)
{
MOZ_ASSERT(OnTaskQueue());
// Some frames may have been output by the decoder since we initiated the
// videoskip process and we know they would be late.
DropDecodedSamples(TrackInfo::kVideoTrack);
// Report the pending frames as dropped.
if (mFrameStats) {
mFrameStats->NotifyDecodedFrames({ 0, 0, SizeOfVideoQueueInFrames() });
}
// Cancel any pending demux request and pending demuxed samples.
mVideo.mDemuxRequest.DisconnectIfExists();
Reset(TrackType::kVideoTrack);
if (mFrameStats) {
mFrameStats->NotifyDecodedFrames({ aSkipped, 0, aSkipped });
}
mVideo.mNumSamplesSkippedTotal += aSkipped;
}
void
MediaFormatReader::OnVideoSkipCompleted(uint32_t aSkipped)
{
MOZ_ASSERT(OnTaskQueue());
LOG("Skipping succeeded, skipped %u frames", aSkipped);
mSkipRequest.Complete();
VideoSkipReset(aSkipped);
ScheduleUpdate(TrackInfo::kVideoTrack);
}
void
MediaFormatReader::OnVideoSkipFailed(
MediaTrackDemuxer::SkipFailureHolder aFailure)
{
MOZ_ASSERT(OnTaskQueue());
LOG("Skipping failed, skipped %u frames", aFailure.mSkipped);
mSkipRequest.Complete();
switch (aFailure.mFailure.Code()) {
case NS_ERROR_DOM_MEDIA_END_OF_STREAM:
case NS_ERROR_DOM_MEDIA_WAITING_FOR_DATA:
// Some frames may have been output by the decoder since we initiated the
// videoskip process and we know they would be late.
DropDecodedSamples(TrackInfo::kVideoTrack);
// We can't complete the skip operation, will just service a video frame
// normally.
ScheduleUpdate(TrackInfo::kVideoTrack);
break;
case NS_ERROR_DOM_MEDIA_CANCELED:
if (mVideo.HasPromise()) {
mVideo.RejectPromise(aFailure.mFailure, __func__);
}
break;
default:
NotifyError(TrackType::kVideoTrack, aFailure.mFailure);
break;
}
}
RefPtr<MediaFormatReader::SeekPromise>
MediaFormatReader::Seek(const SeekTarget& aTarget)
{
MOZ_ASSERT(OnTaskQueue());
LOG("aTarget=(%" PRId64 ")", aTarget.GetTime().ToMicroseconds());
MOZ_DIAGNOSTIC_ASSERT(mSeekPromise.IsEmpty());
MOZ_DIAGNOSTIC_ASSERT(!mVideo.HasPromise());
MOZ_DIAGNOSTIC_ASSERT(aTarget.IsVideoOnly() || !mAudio.HasPromise());
MOZ_DIAGNOSTIC_ASSERT(mPendingSeekTime.isNothing());
MOZ_DIAGNOSTIC_ASSERT(mVideo.mTimeThreshold.isNothing());
MOZ_DIAGNOSTIC_ASSERT(aTarget.IsVideoOnly() ||
mAudio.mTimeThreshold.isNothing());
if (!mInfo.mMediaSeekable && !mInfo.mMediaSeekableOnlyInBufferedRanges) {
LOG("Seek() END (Unseekable)");
return SeekPromise::CreateAndReject(NS_ERROR_FAILURE, __func__);
}
if (mShutdown) {
return SeekPromise::CreateAndReject(NS_ERROR_FAILURE, __func__);
}
SetSeekTarget(aTarget);
RefPtr<SeekPromise> p = mSeekPromise.Ensure(__func__);
ScheduleSeek();
return p;
}
void
MediaFormatReader::SetSeekTarget(const SeekTarget& aTarget)
{
MOZ_ASSERT(OnTaskQueue());
mOriginalSeekTarget = aTarget;
mFallbackSeekTime = mPendingSeekTime = Some(aTarget.GetTime());
}
void
MediaFormatReader::ScheduleSeek()
{
if (mSeekScheduled) {
return;
}
mSeekScheduled = true;
OwnerThread()->Dispatch(NewRunnableMethod(
"MediaFormatReader::AttemptSeek", this, &MediaFormatReader::AttemptSeek));
}
void
MediaFormatReader::AttemptSeek()
{
MOZ_ASSERT(OnTaskQueue());
mSeekScheduled = false;
if (mPendingSeekTime.isNothing()) {
return;
}
if (HasVideo()) {
mVideo.ResetDemuxer();
mVideo.ResetState();
}
// Don't reset the audio demuxer not state when seeking video only
// as it will cause the audio to seek back to the beginning
// resulting in out-of-sync audio from video.
if (HasAudio() && !mOriginalSeekTarget.IsVideoOnly()) {
mAudio.ResetDemuxer();
mAudio.ResetState();
}
if (HasVideo()) {
DoVideoSeek();
} else if (HasAudio()) {
DoAudioSeek();
} else {
MOZ_CRASH();
}
}
void
MediaFormatReader::OnSeekFailed(TrackType aTrack, const MediaResult& aError)
{
MOZ_ASSERT(OnTaskQueue());
LOGV("%s failure:%" PRIu32, TrackTypeToStr(aTrack), static_cast<uint32_t>(aError.Code()));
if (aTrack == TrackType::kVideoTrack) {
mVideo.mSeekRequest.Complete();
} else {
mAudio.mSeekRequest.Complete();
}
if (aError == NS_ERROR_DOM_MEDIA_WAITING_FOR_DATA) {
if (HasVideo() &&
aTrack == TrackType::kAudioTrack &&
mFallbackSeekTime.isSome() &&
mPendingSeekTime.ref() != mFallbackSeekTime.ref()) {
// We have failed to seek audio where video seeked to earlier.
// Attempt to seek instead to the closest point that we know we have in
// order to limit A/V sync discrepency.
// Ensure we have the most up to date buffered ranges.
UpdateReceivedNewData(TrackType::kAudioTrack);
Maybe<TimeUnit> nextSeekTime;
// Find closest buffered time found after video seeked time.
for (const auto& timeRange : mAudio.mTimeRanges) {
if (timeRange.mStart >= mPendingSeekTime.ref()) {
nextSeekTime.emplace(timeRange.mStart);
break;
}
}
if (nextSeekTime.isNothing() ||
nextSeekTime.ref() > mFallbackSeekTime.ref()) {
nextSeekTime = Some(mFallbackSeekTime.ref());
LOG("Unable to seek audio to video seek time. A/V sync may be broken");
} else {
mFallbackSeekTime.reset();
}
mPendingSeekTime = nextSeekTime;
DoAudioSeek();
return;
}
NotifyWaitingForData(aTrack);
}
MOZ_ASSERT(!mVideo.mSeekRequest.Exists() && !mAudio.mSeekRequest.Exists());
mPendingSeekTime.reset();
auto type = aTrack == TrackType::kAudioTrack ? MediaData::AUDIO_DATA
: MediaData::VIDEO_DATA;
mSeekPromise.Reject(SeekRejectValue(type, aError), __func__);
}
void
MediaFormatReader::DoVideoSeek()
{
MOZ_ASSERT(mPendingSeekTime.isSome());
LOGV("Seeking video to %" PRId64, mPendingSeekTime.ref().ToMicroseconds());
auto seekTime = mPendingSeekTime.ref();
mVideo.mTrackDemuxer->Seek(seekTime)
->Then(OwnerThread(), __func__, this,
&MediaFormatReader::OnVideoSeekCompleted,
&MediaFormatReader::OnVideoSeekFailed)
->Track(mVideo.mSeekRequest);
}
void
MediaFormatReader::OnVideoSeekCompleted(TimeUnit aTime)
{
MOZ_ASSERT(OnTaskQueue());
LOGV("Video seeked to %" PRId64, aTime.ToMicroseconds());
mVideo.mSeekRequest.Complete();
mVideo.mFirstFrameTime = Some(aTime);
mPreviousDecodedKeyframeTime_us = sNoPreviousDecodedKeyframe;
SetVideoDecodeThreshold();
if (HasAudio() && !mOriginalSeekTarget.IsVideoOnly()) {
MOZ_ASSERT(mPendingSeekTime.isSome());
if (mOriginalSeekTarget.IsFast()) {
// We are performing a fast seek. We need to seek audio to where the
// video seeked to, to ensure proper A/V sync once playback resume.
mPendingSeekTime = Some(aTime);
}
DoAudioSeek();
} else {
mPendingSeekTime.reset();
mSeekPromise.Resolve(aTime, __func__);
}
}
void
MediaFormatReader::OnVideoSeekFailed(const MediaResult& aError)
{
mPreviousDecodedKeyframeTime_us = sNoPreviousDecodedKeyframe;
OnSeekFailed(TrackType::kVideoTrack, aError);
}
void
MediaFormatReader::SetVideoDecodeThreshold()
{
MOZ_ASSERT(OnTaskQueue());
if (!HasVideo() || !mVideo.mDecoder) {
return;
}
if (!mVideo.mTimeThreshold && !IsSeeking()) {
return;
}
TimeUnit threshold;
if (mVideo.mTimeThreshold) {
// For internalSeek.
threshold = mVideo.mTimeThreshold.ref().Time();
} else if (IsSeeking()) {
// If IsSeeking() is true, then video seek must have completed already.
TimeUnit keyframe;
if (NS_FAILED(mVideo.mTrackDemuxer->GetNextRandomAccessPoint(&keyframe))) {
return;
}
// If the key frame is invalid/infinite, it means the target position is
// closing to end of stream. We don't want to skip any frame at this point.
if (!keyframe.IsValid() || keyframe.IsInfinite()) {
return;
}
threshold = mOriginalSeekTarget.GetTime();
} else {
return;
}
LOG("Set seek threshold to %" PRId64, threshold.ToMicroseconds());
mVideo.mDecoder->SetSeekThreshold(threshold);
}
void
MediaFormatReader::DoAudioSeek()
{
MOZ_ASSERT(mPendingSeekTime.isSome());
LOGV("Seeking audio to %" PRId64, mPendingSeekTime.ref().ToMicroseconds());
auto seekTime = mPendingSeekTime.ref();
mAudio.mTrackDemuxer->Seek(seekTime)
->Then(OwnerThread(), __func__, this,
&MediaFormatReader::OnAudioSeekCompleted,
&MediaFormatReader::OnAudioSeekFailed)
->Track(mAudio.mSeekRequest);
}
void
MediaFormatReader::OnAudioSeekCompleted(TimeUnit aTime)
{
MOZ_ASSERT(OnTaskQueue());
LOGV("Audio seeked to %" PRId64, aTime.ToMicroseconds());
mAudio.mSeekRequest.Complete();
mAudio.mFirstFrameTime = Some(aTime);
mPendingSeekTime.reset();
mSeekPromise.Resolve(aTime, __func__);
}
void
MediaFormatReader::OnAudioSeekFailed(const MediaResult& aError)
{
OnSeekFailed(TrackType::kAudioTrack, aError);
}
void MediaFormatReader::ReleaseResources()
{
LOGV("");
if (mShutdown) {
return;
}
ShutdownDecoder(TrackInfo::kAudioTrack);
ShutdownDecoder(TrackInfo::kVideoTrack);
}
bool
MediaFormatReader::VideoIsHardwareAccelerated() const
{
return mVideo.mIsHardwareAccelerated;
}
void
MediaFormatReader::NotifyTrackDemuxers()
{
MOZ_ASSERT(OnTaskQueue());
LOGV("");
if (!mInitDone) {
return;
}
if (HasVideo()) {
mVideo.mReceivedNewData = true;
ScheduleUpdate(TrackType::kVideoTrack);
}
if (HasAudio()) {
mAudio.mReceivedNewData = true;
ScheduleUpdate(TrackType::kAudioTrack);
}
}
void
MediaFormatReader::NotifyDataArrived()
{
MOZ_ASSERT(OnTaskQueue());
if (mShutdown || !mDemuxer || !mDemuxerInitDone) {
return;
}
if (mNotifyDataArrivedPromise.Exists()) {
// Already one in progress. Set the dirty flag so we can process it later.
mPendingNotifyDataArrived = true;
return;
}
RefPtr<MediaFormatReader> self = this;
mDemuxer->NotifyDataArrived()
->Then(OwnerThread(), __func__,
[self]() {
self->mNotifyDataArrivedPromise.Complete();
self->UpdateBuffered();
self->NotifyTrackDemuxers();
if (self->mPendingNotifyDataArrived) {
self->mPendingNotifyDataArrived = false;
self->NotifyDataArrived();
}
},
[self]() { self->mNotifyDataArrivedPromise.Complete(); })
->Track(mNotifyDataArrivedPromise);
}
void
MediaFormatReader::UpdateBuffered()
{
MOZ_ASSERT(OnTaskQueue());
if (mShutdown) {
return;
}
if (!mInitDone || !mHasStartTime) {
mBuffered = TimeIntervals();
return;
}
if (HasVideo()) {
mVideo.mTimeRanges = mVideo.mTrackDemuxer->GetBuffered();
bool hasLastEnd;
auto lastEnd = mVideo.mTimeRanges.GetEnd(&hasLastEnd);
if (hasLastEnd) {
if (mVideo.mLastTimeRangesEnd &&
mVideo.mLastTimeRangesEnd.ref() < lastEnd) {
// New data was added after our previous end, we can clear the EOS flag.
mVideo.mDemuxEOS = false;
ScheduleUpdate(TrackInfo::kVideoTrack);
}
mVideo.mLastTimeRangesEnd = Some(lastEnd);
}
}
if (HasAudio()) {
mAudio.mTimeRanges = mAudio.mTrackDemuxer->GetBuffered();
bool hasLastEnd;
auto lastEnd = mAudio.mTimeRanges.GetEnd(&hasLastEnd);
if (hasLastEnd) {
if (mAudio.mLastTimeRangesEnd &&
mAudio.mLastTimeRangesEnd.ref() < lastEnd) {
// New data was added after our previous end, we can clear the EOS flag.
mAudio.mDemuxEOS = false;
ScheduleUpdate(TrackInfo::kAudioTrack);
}
mAudio.mLastTimeRangesEnd = Some(lastEnd);
}
}
media::TimeIntervals intervals;
if (HasAudio() && HasVideo()) {
intervals = media::Intersection(mVideo.mTimeRanges, mAudio.mTimeRanges);
} else if (HasAudio()) {
intervals = mAudio.mTimeRanges;
} else if (HasVideo()) {
intervals = mVideo.mTimeRanges;
}
if (!intervals.Length() || intervals.GetStart() == TimeUnit::Zero()) {
// IntervalSet already starts at 0 or is empty, nothing to shift.
mBuffered = intervals;
} else {
mBuffered =
intervals.Shift(TimeUnit::Zero() - mInfo.mStartTime);
}
}
layers::ImageContainer*
MediaFormatReader::GetImageContainer()
{
return mVideoFrameContainer ? mVideoFrameContainer->GetImageContainer()
: nullptr;
}
void
MediaFormatReader::GetMozDebugReaderData(nsACString& aString)
{
nsCString result;
nsAutoCString audioDecoderName("unavailable");
nsAutoCString videoDecoderName = audioDecoderName;
nsAutoCString audioType("none");
nsAutoCString videoType("none");
if (HasAudio()) {
MutexAutoLock lock(mAudio.mMutex);
audioDecoderName = mAudio.mDescription;
audioType = mInfo.mAudio.mMimeType;
}
if (HasVideo()) {
MutexAutoLock mon(mVideo.mMutex);
videoDecoderName = mVideo.mDescription;
videoType = mInfo.mVideo.mMimeType;
}
result += nsPrintfCString(
"Audio Decoder(%s): %s\n", audioType.get(), audioDecoderName.get());
result += nsPrintfCString("Audio Frames Decoded: %" PRIu64 "\n",
mAudio.mNumSamplesOutputTotal);
if (HasAudio()) {
result += nsPrintfCString(
"Audio State: ni=%d no=%d wp=%d demuxr=%d demuxq=%u decoder=%d tt=%.1f "
"tths=%d in=%" PRIu64 " out=%" PRIu64
" qs=%u pending=%u wfd=%d eos=%d ds=%d wfk=%d sid=%u\n",
NeedInput(mAudio),
mAudio.HasPromise(),
!mAudio.mWaitingPromise.IsEmpty(),
mAudio.mDemuxRequest.Exists(),
uint32_t(mAudio.mQueuedSamples.Length()),
mAudio.mDecodeRequest.Exists(),
mAudio.mTimeThreshold ? mAudio.mTimeThreshold.ref().Time().ToSeconds()
: -1.0,
mAudio.mTimeThreshold ? mAudio.mTimeThreshold.ref().mHasSeeked : -1,
mAudio.mNumSamplesInput,
mAudio.mNumSamplesOutput,
unsigned(size_t(mAudio.mSizeOfQueue)),
unsigned(mAudio.mOutput.Length()),
mAudio.mWaitingForData,
mAudio.mDemuxEOS,
int32_t(mAudio.mDrainState),
mAudio.mWaitingForKey,
mAudio.mLastStreamSourceID);
}
result += nsPrintfCString(
"Video Decoder(%s): %s\n", videoType.get(), videoDecoderName.get());
result +=
nsPrintfCString("Hardware Video Decoding: %s\n",
VideoIsHardwareAccelerated() ? "enabled" : "disabled");
result +=
nsPrintfCString("Video Frames Decoded: %" PRIu64 " (skipped=%" PRIu64 ")\n",
mVideo.mNumSamplesOutputTotal,
mVideo.mNumSamplesSkippedTotal);
if (HasVideo()) {
result += nsPrintfCString(
"Video State: ni=%d no=%d wp=%d demuxr=%d demuxq=%u decoder=%d tt=%.1f "
"tths=%d in=%" PRIu64 " out=%" PRIu64
" qs=%u pending:%u wfd=%d eos=%d ds=%d wfk=%d sid=%u\n",
NeedInput(mVideo),
mVideo.HasPromise(),
!mVideo.mWaitingPromise.IsEmpty(),
mVideo.mDemuxRequest.Exists(),
uint32_t(mVideo.mQueuedSamples.Length()),
mVideo.mDecodeRequest.Exists(),
mVideo.mTimeThreshold ? mVideo.mTimeThreshold.ref().Time().ToSeconds()
: -1.0,
mVideo.mTimeThreshold ? mVideo.mTimeThreshold.ref().mHasSeeked : -1,
mVideo.mNumSamplesInput,
mVideo.mNumSamplesOutput,
unsigned(size_t(mVideo.mSizeOfQueue)),
unsigned(mVideo.mOutput.Length()),
mVideo.mWaitingForData,
mVideo.mDemuxEOS,
int32_t(mVideo.mDrainState),
mVideo.mWaitingForKey,
mVideo.mLastStreamSourceID);
}
aString += result;
}
void
MediaFormatReader::SetVideoNullDecode(bool aIsNullDecode)
{
MOZ_ASSERT(OnTaskQueue());
return SetNullDecode(TrackType::kVideoTrack, aIsNullDecode);
}
void
MediaFormatReader::UpdateCompositor(
already_AddRefed<layers::KnowsCompositor> aCompositor)
{
MOZ_ASSERT(OnTaskQueue());
mKnowsCompositor = aCompositor;
}
void
MediaFormatReader::SetNullDecode(TrackType aTrack, bool aIsNullDecode)
{
MOZ_ASSERT(OnTaskQueue());
auto& decoder = GetDecoderData(aTrack);
if (decoder.mIsNullDecode == aIsNullDecode) {
return;
}
LOG("%s, decoder.mIsNullDecode = %d => aIsNullDecode = %d",
TrackTypeToStr(aTrack), decoder.mIsNullDecode, aIsNullDecode);
decoder.mIsNullDecode = aIsNullDecode;
ShutdownDecoder(aTrack);
}
void
MediaFormatReader::OnFirstDemuxCompleted(
TrackInfo::TrackType aType, RefPtr<MediaTrackDemuxer::SamplesHolder> aSamples)
{
MOZ_ASSERT(OnTaskQueue());
if (mShutdown) {
return;
}
auto& decoder = GetDecoderData(aType);
MOZ_ASSERT(decoder.mFirstDemuxedSampleTime.isNothing());
decoder.mFirstDemuxedSampleTime.emplace(aSamples->mSamples[0]->mTime);
MaybeResolveMetadataPromise();
}
void
MediaFormatReader::OnFirstDemuxFailed(TrackInfo::TrackType aType,
const MediaResult& aError)
{
MOZ_ASSERT(OnTaskQueue());
if (mShutdown) {
return;
}
auto& decoder = GetDecoderData(aType);
MOZ_ASSERT(decoder.mFirstDemuxedSampleTime.isNothing());
decoder.mFirstDemuxedSampleTime.emplace(TimeUnit::FromInfinity());
MaybeResolveMetadataPromise();
}
} // namespace mozilla
#undef NS_DispatchToMainThread