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-rw-r--r--dom/media/ogg/OggDemuxer.cpp2194
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diff --git a/dom/media/ogg/OggDemuxer.cpp b/dom/media/ogg/OggDemuxer.cpp
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+++ b/dom/media/ogg/OggDemuxer.cpp
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+ /* -*- 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 "nsError.h"
+#include "MediaDecoderStateMachine.h"
+#include "AbstractMediaDecoder.h"
+#include "OggDemuxer.h"
+#include "OggCodecState.h"
+#include "mozilla/Atomics.h"
+#include "mozilla/PodOperations.h"
+#include "mozilla/SharedThreadPool.h"
+#include "mozilla/Telemetry.h"
+#include "mozilla/TimeStamp.h"
+#include "MediaDataDemuxer.h"
+#include "nsAutoRef.h"
+#include "XiphExtradata.h"
+#include "MediaPrefs.h"
+
+#include <algorithm>
+
+extern mozilla::LazyLogModule gMediaDemuxerLog;
+#define OGG_DEBUG(arg, ...) MOZ_LOG(gMediaDemuxerLog, mozilla::LogLevel::Debug, ("OggDemuxer(%p)::%s: " arg, this, __func__, ##__VA_ARGS__))
+
+// Un-comment to enable logging of seek bisections.
+//#define SEEK_LOGGING
+#ifdef SEEK_LOGGING
+#define SEEK_LOG(type, msg) MOZ_LOG(gMediaDemuxerLog, type, msg)
+#else
+#define SEEK_LOG(type, msg)
+#endif
+
+namespace mozilla
+{
+
+using media::TimeUnit;
+using media::TimeInterval;
+using media::TimeIntervals;
+
+// The number of microseconds of "fuzz" we use in a bisection search over
+// HTTP. When we're seeking with fuzz, we'll stop the search if a bisection
+// lands between the seek target and OGG_SEEK_FUZZ_USECS microseconds before the
+// seek target. This is becaue it's usually quicker to just keep downloading
+// from an exisiting connection than to do another bisection inside that
+// small range, which would open a new HTTP connetion.
+static const uint32_t OGG_SEEK_FUZZ_USECS = 500000;
+
+// The number of microseconds of "pre-roll" we use for Opus streams.
+// The specification recommends 80 ms.
+static const int64_t OGG_SEEK_OPUS_PREROLL = 80 * USECS_PER_MS;
+
+static Atomic<uint32_t> sStreamSourceID(0u);
+
+class OggHeaders
+{
+public:
+ OggHeaders() {}
+ ~OggHeaders()
+ {
+ for (size_t i = 0; i < mHeaders.Length(); i++) {
+ delete[] mHeaders[i];
+ }
+ }
+
+ void AppendPacket(const ogg_packet* aPacket)
+ {
+ size_t packetSize = aPacket->bytes;
+ unsigned char* packetData = new unsigned char[packetSize];
+ memcpy(packetData, aPacket->packet, packetSize);
+ mHeaders.AppendElement(packetData);
+ mHeaderLens.AppendElement(packetSize);
+ }
+
+ nsTArray<const unsigned char*> mHeaders;
+ nsTArray<size_t> mHeaderLens;
+};
+
+// Return the corresponding category in aKind based on the following specs.
+// (https://www.whatwg.org/specs/web-apps/current-
+// work/multipage/embedded-content.html#dom-audiotrack-kind) &
+// (http://wiki.xiph.org/SkeletonHeaders)
+const nsString
+OggDemuxer::GetKind(const nsCString& aRole)
+{
+ if (aRole.Find("audio/main") != -1 || aRole.Find("video/main") != -1) {
+ return NS_LITERAL_STRING("main");
+ } else if (aRole.Find("audio/alternate") != -1 ||
+ aRole.Find("video/alternate") != -1) {
+ return NS_LITERAL_STRING("alternative");
+ } else if (aRole.Find("audio/audiodesc") != -1) {
+ return NS_LITERAL_STRING("descriptions");
+ } else if (aRole.Find("audio/described") != -1) {
+ return NS_LITERAL_STRING("main-desc");
+ } else if (aRole.Find("audio/dub") != -1) {
+ return NS_LITERAL_STRING("translation");
+ } else if (aRole.Find("audio/commentary") != -1) {
+ return NS_LITERAL_STRING("commentary");
+ } else if (aRole.Find("video/sign") != -1) {
+ return NS_LITERAL_STRING("sign");
+ } else if (aRole.Find("video/captioned") != -1) {
+ return NS_LITERAL_STRING("captions");
+ } else if (aRole.Find("video/subtitled") != -1) {
+ return NS_LITERAL_STRING("subtitles");
+ }
+ return EmptyString();
+}
+
+void
+OggDemuxer::InitTrack(MessageField* aMsgInfo,
+ TrackInfo* aInfo,
+ bool aEnable)
+{
+ MOZ_ASSERT(aMsgInfo);
+ MOZ_ASSERT(aInfo);
+
+ nsCString* sName = aMsgInfo->mValuesStore.Get(eName);
+ nsCString* sRole = aMsgInfo->mValuesStore.Get(eRole);
+ nsCString* sTitle = aMsgInfo->mValuesStore.Get(eTitle);
+ nsCString* sLanguage = aMsgInfo->mValuesStore.Get(eLanguage);
+ aInfo->Init(sName? NS_ConvertUTF8toUTF16(*sName):EmptyString(),
+ sRole? GetKind(*sRole):EmptyString(),
+ sTitle? NS_ConvertUTF8toUTF16(*sTitle):EmptyString(),
+ sLanguage? NS_ConvertUTF8toUTF16(*sLanguage):EmptyString(),
+ aEnable);
+}
+
+OggDemuxer::OggDemuxer(MediaResource* aResource)
+ : mTheoraState(nullptr)
+ , mVorbisState(nullptr)
+ , mOpusState(nullptr)
+ , mFlacState(nullptr)
+ , mOpusEnabled(MediaDecoder::IsOpusEnabled())
+ , mSkeletonState(nullptr)
+ , mAudioOggState(aResource)
+ , mVideoOggState(aResource)
+ , mVorbisSerial(0)
+ , mOpusSerial(0)
+ , mTheoraSerial(0)
+ , mFlacSerial(0)
+ , mOpusPreSkip(0)
+ , mIsChained(false)
+ , mTimedMetadataEvent(nullptr)
+ , mOnSeekableEvent(nullptr)
+{
+ MOZ_COUNT_CTOR(OggDemuxer);
+ PodZero(&mTheoraInfo);
+}
+
+OggDemuxer::~OggDemuxer()
+{
+ MOZ_COUNT_DTOR(OggDemuxer);
+ Reset(TrackInfo::kAudioTrack);
+ Reset(TrackInfo::kVideoTrack);
+ if (HasAudio() || HasVideo()) {
+ // If we were able to initialize our decoders, report whether we encountered
+ // a chained stream or not.
+ bool isChained = mIsChained;
+ void* ptr = this;
+ nsCOMPtr<nsIRunnable> task = NS_NewRunnableFunction([ptr, isChained]() -> void {
+ // We can't use OGG_DEBUG here because it implicitly refers to `this`,
+ // which we can't capture in this runnable.
+ MOZ_LOG(gMediaDemuxerLog, mozilla::LogLevel::Debug,
+ ("OggDemuxer(%p)::%s: Reporting telemetry MEDIA_OGG_LOADED_IS_CHAINED=%d",
+ ptr, __func__, isChained));
+ Telemetry::Accumulate(Telemetry::ID::MEDIA_OGG_LOADED_IS_CHAINED, isChained);
+ });
+ AbstractThread::MainThread()->Dispatch(task.forget());
+ }
+}
+
+void
+OggDemuxer::SetChainingEvents(TimedMetadataEventProducer* aMetadataEvent,
+ MediaEventProducer<void>* aOnSeekableEvent)
+{
+ mTimedMetadataEvent = aMetadataEvent;
+ mOnSeekableEvent = aOnSeekableEvent;
+}
+
+
+bool
+OggDemuxer::HasAudio()
+const
+{
+ return mVorbisState || mOpusState || mFlacState;
+}
+
+bool
+OggDemuxer::HasVideo()
+const
+{
+ return mTheoraState;
+}
+
+bool
+OggDemuxer::HaveStartTime()
+const
+{
+ return mStartTime.isSome();
+}
+
+int64_t
+OggDemuxer::StartTime() const
+{
+ return mStartTime.refOr(0);
+}
+
+bool
+OggDemuxer::HaveStartTime(TrackInfo::TrackType aType)
+{
+ return OggState(aType).mStartTime.isSome();
+}
+
+int64_t
+OggDemuxer::StartTime(TrackInfo::TrackType aType)
+{
+ return OggState(aType).mStartTime.refOr(TimeUnit::FromMicroseconds(0)).ToMicroseconds();
+}
+
+RefPtr<OggDemuxer::InitPromise>
+OggDemuxer::Init()
+{
+ int ret = ogg_sync_init(OggSyncState(TrackInfo::kAudioTrack));
+ if (ret != 0) {
+ return InitPromise::CreateAndReject(NS_ERROR_OUT_OF_MEMORY, __func__);
+ }
+ ret = ogg_sync_init(OggSyncState(TrackInfo::kVideoTrack));
+ if (ret != 0) {
+ return InitPromise::CreateAndReject(NS_ERROR_OUT_OF_MEMORY, __func__);
+ }
+ if (ReadMetadata() != NS_OK) {
+ return InitPromise::CreateAndReject(NS_ERROR_DOM_MEDIA_METADATA_ERR, __func__);
+ }
+
+ if (!GetNumberTracks(TrackInfo::kAudioTrack) &&
+ !GetNumberTracks(TrackInfo::kVideoTrack)) {
+ return InitPromise::CreateAndReject(NS_ERROR_DOM_MEDIA_METADATA_ERR, __func__);
+ }
+
+ return InitPromise::CreateAndResolve(NS_OK, __func__);
+}
+
+bool
+OggDemuxer::HasTrackType(TrackInfo::TrackType aType) const
+{
+ return !!GetNumberTracks(aType);
+}
+
+OggCodecState*
+OggDemuxer::GetTrackCodecState(TrackInfo::TrackType aType) const
+{
+ switch(aType) {
+ case TrackInfo::kAudioTrack:
+ if (mVorbisState) {
+ return mVorbisState;
+ } else if (mOpusState) {
+ return mOpusState;
+ } else {
+ return mFlacState;
+ }
+ case TrackInfo::kVideoTrack:
+ return mTheoraState;
+ default:
+ return 0;
+ }
+}
+
+TrackInfo::TrackType
+OggDemuxer::GetCodecStateType(OggCodecState* aState) const
+{
+ switch (aState->GetType()) {
+ case OggCodecState::TYPE_THEORA:
+ return TrackInfo::kVideoTrack;
+ case OggCodecState::TYPE_OPUS:
+ case OggCodecState::TYPE_VORBIS:
+ case OggCodecState::TYPE_FLAC:
+ return TrackInfo::kAudioTrack;
+ default:
+ return TrackInfo::kUndefinedTrack;
+ }
+}
+
+uint32_t
+OggDemuxer::GetNumberTracks(TrackInfo::TrackType aType) const
+{
+ switch(aType) {
+ case TrackInfo::kAudioTrack:
+ return HasAudio() ? 1 : 0;
+ case TrackInfo::kVideoTrack:
+ return HasVideo() ? 1 : 0;
+ default:
+ return 0;
+ }
+}
+
+UniquePtr<TrackInfo>
+OggDemuxer::GetTrackInfo(TrackInfo::TrackType aType, size_t aTrackNumber) const
+{
+ switch(aType) {
+ case TrackInfo::kAudioTrack:
+ return mInfo.mAudio.Clone();
+ case TrackInfo::kVideoTrack:
+ return mInfo.mVideo.Clone();
+ default:
+ return nullptr;
+ }
+}
+
+already_AddRefed<MediaTrackDemuxer>
+OggDemuxer::GetTrackDemuxer(TrackInfo::TrackType aType, uint32_t aTrackNumber)
+{
+ if (GetNumberTracks(aType) <= aTrackNumber) {
+ return nullptr;
+ }
+ RefPtr<OggTrackDemuxer> e = new OggTrackDemuxer(this, aType, aTrackNumber);
+ mDemuxers.AppendElement(e);
+
+ return e.forget();
+}
+
+nsresult
+OggDemuxer::Reset(TrackInfo::TrackType aType)
+{
+ // Discard any previously buffered packets/pages.
+ ogg_sync_reset(OggSyncState(aType));
+ OggCodecState* trackState = GetTrackCodecState(aType);
+ if (trackState) {
+ return trackState->Reset();
+ }
+ OggState(aType).mNeedKeyframe = true;
+ return NS_OK;
+}
+
+bool
+OggDemuxer::ReadHeaders(TrackInfo::TrackType aType,
+ OggCodecState* aState,
+ OggHeaders& aHeaders)
+{
+ while (!aState->DoneReadingHeaders()) {
+ DemuxUntilPacketAvailable(aType, aState);
+ ogg_packet* packet = aState->PacketOut();
+ if (!packet) {
+ OGG_DEBUG("Ran out of header packets early; deactivating stream %ld", aState->mSerial);
+ aState->Deactivate();
+ return false;
+ }
+
+ // Save a copy of the header packet for the decoder to use later;
+ // OggCodecState::DecodeHeader will free it when processing locally.
+ aHeaders.AppendPacket(packet);
+
+ // Local OggCodecState needs to decode headers in order to process
+ // packet granulepos -> time mappings, etc.
+ if (!aState->DecodeHeader(packet)) {
+ OGG_DEBUG("Failed to decode ogg header packet; deactivating stream %ld", aState->mSerial);
+ aState->Deactivate();
+ return false;
+ }
+ }
+
+ return aState->Init();
+}
+
+void
+OggDemuxer::BuildSerialList(nsTArray<uint32_t>& aTracks)
+{
+ // Obtaining seek index information for currently active bitstreams.
+ if (HasVideo()) {
+ aTracks.AppendElement(mTheoraState->mSerial);
+ }
+ if (HasAudio()) {
+ if (mVorbisState) {
+ aTracks.AppendElement(mVorbisState->mSerial);
+ } else if (mOpusState) {
+ aTracks.AppendElement(mOpusState->mSerial);
+ }
+ }
+}
+
+void
+OggDemuxer::SetupTargetTheora(TheoraState* aTheoraState, OggHeaders& aHeaders)
+{
+ if (mTheoraState) {
+ mTheoraState->Reset();
+ }
+
+ nsIntRect picture = nsIntRect(aTheoraState->mInfo.pic_x,
+ aTheoraState->mInfo.pic_y,
+ aTheoraState->mInfo.pic_width,
+ aTheoraState->mInfo.pic_height);
+
+ nsIntSize displaySize = nsIntSize(aTheoraState->mInfo.pic_width,
+ aTheoraState->mInfo.pic_height);
+
+ // Apply the aspect ratio to produce the intrinsic display size we report
+ // to the element.
+ ScaleDisplayByAspectRatio(displaySize, aTheoraState->mPixelAspectRatio);
+
+ nsIntSize frameSize(aTheoraState->mInfo.frame_width,
+ aTheoraState->mInfo.frame_height);
+ if (IsValidVideoRegion(frameSize, picture, displaySize)) {
+ // Video track's frame sizes will not overflow. Activate the video track.
+ mInfo.mVideo.mMimeType = "video/theora";
+ mInfo.mVideo.mDisplay = displaySize;
+ mInfo.mVideo.mImage = frameSize;
+ mInfo.mVideo.SetImageRect(picture);
+
+ // Copy Theora info data for time computations on other threads.
+ memcpy(&mTheoraInfo, &aTheoraState->mInfo, sizeof(mTheoraInfo));
+
+ // Save header packets for the decoder
+ if (!XiphHeadersToExtradata(mInfo.mVideo.mCodecSpecificConfig,
+ aHeaders.mHeaders, aHeaders.mHeaderLens)) {
+ return;
+ }
+
+ mTheoraState = aTheoraState;
+ mTheoraSerial = aTheoraState->mSerial;
+ }
+}
+
+void
+OggDemuxer::SetupTargetVorbis(VorbisState* aVorbisState, OggHeaders& aHeaders)
+{
+ if (mVorbisState) {
+ mVorbisState->Reset();
+ }
+
+ // Copy Vorbis info data for time computations on other threads.
+ memcpy(&mVorbisInfo, &aVorbisState->mInfo, sizeof(mVorbisInfo));
+ mVorbisInfo.codec_setup = nullptr;
+
+ mInfo.mAudio.mMimeType = "audio/vorbis";
+ mInfo.mAudio.mRate = aVorbisState->mInfo.rate;
+ mInfo.mAudio.mChannels = aVorbisState->mInfo.channels;
+
+ // Save header packets for the decoder
+ if (!XiphHeadersToExtradata(mInfo.mAudio.mCodecSpecificConfig,
+ aHeaders.mHeaders, aHeaders.mHeaderLens)) {
+ return;
+ }
+
+ mVorbisState = aVorbisState;
+ mVorbisSerial = aVorbisState->mSerial;
+}
+
+void
+OggDemuxer::SetupTargetOpus(OpusState* aOpusState, OggHeaders& aHeaders)
+{
+ if (mOpusState) {
+ mOpusState->Reset();
+ }
+
+ mInfo.mAudio.mMimeType = "audio/opus";
+ mInfo.mAudio.mRate = aOpusState->mRate;
+ mInfo.mAudio.mChannels = aOpusState->mChannels;
+
+ // Save preskip & the first header packet for the Opus decoder
+ uint64_t preSkip = aOpusState->Time(0, aOpusState->mPreSkip);
+ uint8_t c[sizeof(preSkip)];
+ BigEndian::writeUint64(&c[0], preSkip);
+ mInfo.mAudio.mCodecSpecificConfig->AppendElements(&c[0], sizeof(preSkip));
+ mInfo.mAudio.mCodecSpecificConfig->AppendElements(aHeaders.mHeaders[0],
+ aHeaders.mHeaderLens[0]);
+
+ mOpusState = aOpusState;
+ mOpusSerial = aOpusState->mSerial;
+ mOpusPreSkip = aOpusState->mPreSkip;
+}
+
+void
+OggDemuxer::SetupTargetFlac(FlacState* aFlacState, OggHeaders& aHeaders)
+{
+ if (mFlacState) {
+ mFlacState->Reset();
+ }
+
+ mInfo.mAudio = aFlacState->Info();
+ mFlacState = aFlacState;
+ mFlacSerial = aFlacState->mSerial;
+}
+
+void
+OggDemuxer::SetupTargetSkeleton()
+{
+ // Setup skeleton related information after mVorbisState & mTheroState
+ // being set (if they exist).
+ if (mSkeletonState) {
+ OggHeaders headers;
+ if (!HasAudio() && !HasVideo()) {
+ // We have a skeleton track, but no audio or video, may as well disable
+ // the skeleton, we can't do anything useful with this media.
+ OGG_DEBUG("Deactivating skeleton stream %ld", mSkeletonState->mSerial);
+ mSkeletonState->Deactivate();
+ } else if (ReadHeaders(TrackInfo::kAudioTrack, mSkeletonState, headers) &&
+ mSkeletonState->HasIndex()) {
+ // We don't particularly care about which track we are currently using
+ // as both MediaResource points to the same content.
+ // Extract the duration info out of the index, so we don't need to seek to
+ // the end of resource to get it.
+ nsTArray<uint32_t> tracks;
+ BuildSerialList(tracks);
+ int64_t duration = 0;
+ if (NS_SUCCEEDED(mSkeletonState->GetDuration(tracks, duration))) {
+ OGG_DEBUG("Got duration from Skeleton index %lld", duration);
+ mInfo.mMetadataDuration.emplace(TimeUnit::FromMicroseconds(duration));
+ }
+ }
+ }
+}
+
+void
+OggDemuxer::SetupMediaTracksInfo(const nsTArray<uint32_t>& aSerials)
+{
+ // For each serial number
+ // 1. Retrieve a codecState from mCodecStore by this serial number.
+ // 2. Retrieve a message field from mMsgFieldStore by this serial number.
+ // 3. For now, skip if the serial number refers to a non-primary bitstream.
+ // 4. Setup track and other audio/video related information per different types.
+ for (size_t i = 0; i < aSerials.Length(); i++) {
+ uint32_t serial = aSerials[i];
+ OggCodecState* codecState = mCodecStore.Get(serial);
+
+ MessageField* msgInfo = nullptr;
+ if (mSkeletonState && mSkeletonState->mMsgFieldStore.Contains(serial)) {
+ mSkeletonState->mMsgFieldStore.Get(serial, &msgInfo);
+ }
+
+ if (codecState->GetType() == OggCodecState::TYPE_THEORA) {
+ TheoraState* theoraState = static_cast<TheoraState*>(codecState);
+ if (!(mTheoraState && mTheoraState->mSerial == theoraState->mSerial)) {
+ continue;
+ }
+
+ if (msgInfo) {
+ InitTrack(msgInfo, &mInfo.mVideo, mTheoraState == theoraState);
+ }
+
+ nsIntRect picture = nsIntRect(theoraState->mInfo.pic_x,
+ theoraState->mInfo.pic_y,
+ theoraState->mInfo.pic_width,
+ theoraState->mInfo.pic_height);
+ nsIntSize displaySize = nsIntSize(theoraState->mInfo.pic_width,
+ theoraState->mInfo.pic_height);
+ nsIntSize frameSize(theoraState->mInfo.frame_width,
+ theoraState->mInfo.frame_height);
+ ScaleDisplayByAspectRatio(displaySize, theoraState->mPixelAspectRatio);
+ if (IsValidVideoRegion(frameSize, picture, displaySize)) {
+ mInfo.mVideo.mDisplay = displaySize;
+ }
+ } else if (codecState->GetType() == OggCodecState::TYPE_VORBIS) {
+ VorbisState* vorbisState = static_cast<VorbisState*>(codecState);
+ if (!(mVorbisState && mVorbisState->mSerial == vorbisState->mSerial)) {
+ continue;
+ }
+
+ if (msgInfo) {
+ InitTrack(msgInfo,
+ &mInfo.mAudio,
+ mVorbisState == vorbisState);
+ }
+
+ mInfo.mAudio.mRate = vorbisState->mInfo.rate;
+ mInfo.mAudio.mChannels = vorbisState->mInfo.channels;
+ FillTags(&mInfo.mAudio, vorbisState->GetTags());
+ } else if (codecState->GetType() == OggCodecState::TYPE_OPUS) {
+ OpusState* opusState = static_cast<OpusState*>(codecState);
+ if (!(mOpusState && mOpusState->mSerial == opusState->mSerial)) {
+ continue;
+ }
+
+ if (msgInfo) {
+ InitTrack(msgInfo, &mInfo.mAudio, mOpusState == opusState);
+ }
+
+ mInfo.mAudio.mRate = opusState->mRate;
+ mInfo.mAudio.mChannels = opusState->mChannels;
+ FillTags(&mInfo.mAudio, opusState->GetTags());
+ } else if (codecState->GetType() == OggCodecState::TYPE_FLAC) {
+ FlacState* flacState = static_cast<FlacState*>(codecState);
+ if (!(mFlacState && mFlacState->mSerial == flacState->mSerial)) {
+ continue;
+ }
+
+ if (msgInfo) {
+ InitTrack(msgInfo, &mInfo.mAudio, mFlacState == flacState);
+ }
+
+ mInfo.mAudio = flacState->Info();
+ FillTags(&mInfo.mAudio, flacState->GetTags());
+ }
+ }
+}
+
+void
+OggDemuxer::FillTags(TrackInfo* aInfo, MetadataTags* aTags)
+{
+ if (!aTags) {
+ return;
+ }
+ nsAutoPtr<MetadataTags> tags(aTags);
+ for (auto iter = aTags->Iter(); !iter.Done(); iter.Next()) {
+ aInfo->mTags.AppendElement(MetadataTag(iter.Key(), iter.Data()));
+ }
+}
+
+nsresult
+OggDemuxer::ReadMetadata()
+{
+ OGG_DEBUG("OggDemuxer::ReadMetadata called!");
+
+ // We read packets until all bitstreams have read all their header packets.
+ // We record the offset of the first non-header page so that we know
+ // what page to seek to when seeking to the media start.
+
+ // @FIXME we have to read all the header packets on all the streams
+ // and THEN we can run SetupTarget*
+ // @fixme fixme
+
+ TrackInfo::TrackType tracks[2] =
+ { TrackInfo::kAudioTrack, TrackInfo::kVideoTrack };
+
+ nsTArray<OggCodecState*> bitstreams;
+ nsTArray<uint32_t> serials;
+
+ for (uint32_t i = 0; i < ArrayLength(tracks); i++) {
+ ogg_page page;
+ bool readAllBOS = false;
+ while (!readAllBOS) {
+ if (!ReadOggPage(tracks[i], &page)) {
+ // Some kind of error...
+ OGG_DEBUG("OggDemuxer::ReadOggPage failed? leaving ReadMetadata...");
+ return NS_ERROR_FAILURE;
+ }
+
+ int serial = ogg_page_serialno(&page);
+
+ if (!ogg_page_bos(&page)) {
+ // We've encountered a non Beginning Of Stream page. No more BOS pages
+ // can follow in this Ogg segment, so there will be no other bitstreams
+ // in the Ogg (unless it's invalid).
+ readAllBOS = true;
+ } else if (!mCodecStore.Contains(serial)) {
+ // We've not encountered a stream with this serial number before. Create
+ // an OggCodecState to demux it, and map that to the OggCodecState
+ // in mCodecStates.
+ OggCodecState* codecState = OggCodecState::Create(&page);
+ mCodecStore.Add(serial, codecState);
+ bitstreams.AppendElement(codecState);
+ serials.AppendElement(serial);
+ }
+ if (NS_FAILED(DemuxOggPage(tracks[i], &page))) {
+ return NS_ERROR_FAILURE;
+ }
+ }
+ }
+
+ // We've read all BOS pages, so we know the streams contained in the media.
+ // 1. Find the first encountered Theora/Vorbis/Opus bitstream, and configure
+ // it as the target A/V bitstream.
+ // 2. Deactivate the rest of bitstreams for now, until we have MediaInfo
+ // support multiple track infos.
+ for (uint32_t i = 0; i < bitstreams.Length(); ++i) {
+ OggCodecState* s = bitstreams[i];
+ if (s) {
+ OggHeaders headers;
+ if (s->GetType() == OggCodecState::TYPE_THEORA &&
+ ReadHeaders(TrackInfo::kVideoTrack, s, headers)) {
+ if (!mTheoraState) {
+ TheoraState* theoraState = static_cast<TheoraState*>(s);
+ SetupTargetTheora(theoraState, headers);
+ } else {
+ s->Deactivate();
+ }
+ } else if (s->GetType() == OggCodecState::TYPE_VORBIS &&
+ ReadHeaders(TrackInfo::kAudioTrack, s, headers)) {
+ if (!mVorbisState) {
+ VorbisState* vorbisState = static_cast<VorbisState*>(s);
+ SetupTargetVorbis(vorbisState, headers);
+ } else {
+ s->Deactivate();
+ }
+ } else if (s->GetType() == OggCodecState::TYPE_OPUS &&
+ ReadHeaders(TrackInfo::kAudioTrack, s, headers)) {
+ if (mOpusEnabled) {
+ if (!mOpusState) {
+ OpusState* opusState = static_cast<OpusState*>(s);
+ SetupTargetOpus(opusState, headers);
+ } else {
+ s->Deactivate();
+ }
+ } else {
+ NS_WARNING("Opus decoding disabled."
+ " See media.opus.enabled in about:config");
+ }
+ } else if (MediaPrefs::FlacInOgg() &&
+ s->GetType() == OggCodecState::TYPE_FLAC &&
+ ReadHeaders(TrackInfo::kAudioTrack, s, headers)) {
+ if (!mFlacState) {
+ FlacState* flacState = static_cast<FlacState*>(s);
+ SetupTargetFlac(flacState, headers);
+ } else {
+ s->Deactivate();
+ }
+ } else if (s->GetType() == OggCodecState::TYPE_SKELETON && !mSkeletonState) {
+ mSkeletonState = static_cast<SkeletonState*>(s);
+ } else {
+ // Deactivate any non-primary bitstreams.
+ s->Deactivate();
+ }
+ }
+ }
+
+ SetupTargetSkeleton();
+ SetupMediaTracksInfo(serials);
+
+ if (HasAudio() || HasVideo()) {
+ int64_t startTime = -1;
+ FindStartTime(startTime);
+ if (startTime >= 0) {
+ OGG_DEBUG("Detected stream start time %lld", startTime);
+ mStartTime.emplace(startTime);
+ }
+
+ if (mInfo.mMetadataDuration.isNothing() &&
+ Resource(TrackInfo::kAudioTrack)->GetLength() >= 0) {
+ // We didn't get a duration from the index or a Content-Duration header.
+ // Seek to the end of file to find the end time.
+ int64_t length = Resource(TrackInfo::kAudioTrack)->GetLength();
+
+ NS_ASSERTION(length > 0, "Must have a content length to get end time");
+
+ int64_t endTime = RangeEndTime(TrackInfo::kAudioTrack, length);
+
+ if (endTime != -1) {
+ mInfo.mUnadjustedMetadataEndTime.emplace(TimeUnit::FromMicroseconds(endTime));
+ mInfo.mMetadataDuration.emplace(TimeUnit::FromMicroseconds(endTime - mStartTime.refOr(0)));
+ OGG_DEBUG("Got Ogg duration from seeking to end %lld", endTime);
+ }
+ }
+ if (mInfo.mMetadataDuration.isNothing()) {
+ mInfo.mMetadataDuration.emplace(TimeUnit::FromInfinity());
+ }
+ if (HasAudio()) {
+ mInfo.mAudio.mDuration = mInfo.mMetadataDuration->ToMicroseconds();
+ }
+ if (HasVideo()) {
+ mInfo.mVideo.mDuration = mInfo.mMetadataDuration->ToMicroseconds();
+ }
+ } else {
+ OGG_DEBUG("no audio or video tracks");
+ return NS_ERROR_FAILURE;
+ }
+
+ OGG_DEBUG("success?!");
+ return NS_OK;
+}
+
+void
+OggDemuxer::SetChained() {
+ {
+ if (mIsChained) {
+ return;
+ }
+ mIsChained = true;
+ }
+ if (mOnSeekableEvent) {
+ mOnSeekableEvent->Notify();
+ }
+}
+
+bool
+OggDemuxer::ReadOggChain(const media::TimeUnit& aLastEndTime)
+{
+ bool chained = false;
+ OpusState* newOpusState = nullptr;
+ VorbisState* newVorbisState = nullptr;
+ FlacState* newFlacState = nullptr;
+ nsAutoPtr<MetadataTags> tags;
+
+ if (HasVideo() || HasSkeleton() || !HasAudio()) {
+ return false;
+ }
+
+ ogg_page page;
+ if (!ReadOggPage(TrackInfo::kAudioTrack, &page) || !ogg_page_bos(&page)) {
+ // Chaining is only supported for audio only ogg files.
+ return false;
+ }
+
+ int serial = ogg_page_serialno(&page);
+ if (mCodecStore.Contains(serial)) {
+ return false;
+ }
+
+ nsAutoPtr<OggCodecState> codecState;
+ codecState = OggCodecState::Create(&page);
+ if (!codecState) {
+ return false;
+ }
+
+ if (mVorbisState && (codecState->GetType() == OggCodecState::TYPE_VORBIS)) {
+ newVorbisState = static_cast<VorbisState*>(codecState.get());
+ } else if (mOpusState && (codecState->GetType() == OggCodecState::TYPE_OPUS)) {
+ newOpusState = static_cast<OpusState*>(codecState.get());
+ } else if (mFlacState && (codecState->GetType() == OggCodecState::TYPE_FLAC)) {
+ newFlacState = static_cast<FlacState*>(codecState.get());
+ } else {
+ return false;
+ }
+
+ OggCodecState* state;
+
+ mCodecStore.Add(serial, codecState.forget());
+ state = mCodecStore.Get(serial);
+
+ NS_ENSURE_TRUE(state != nullptr, false);
+
+ if (NS_FAILED(state->PageIn(&page))) {
+ return false;
+ }
+
+ MessageField* msgInfo = nullptr;
+ if (mSkeletonState && mSkeletonState->mMsgFieldStore.Contains(serial)) {
+ mSkeletonState->mMsgFieldStore.Get(serial, &msgInfo);
+ }
+
+ OggHeaders vorbisHeaders;
+ if ((newVorbisState &&
+ ReadHeaders(TrackInfo::kAudioTrack, newVorbisState, vorbisHeaders)) &&
+ (mVorbisState->mInfo.rate == newVorbisState->mInfo.rate) &&
+ (mVorbisState->mInfo.channels == newVorbisState->mInfo.channels)) {
+
+ SetupTargetVorbis(newVorbisState, vorbisHeaders);
+ LOG(LogLevel::Debug, ("New vorbis ogg link, serial=%d\n", mVorbisSerial));
+
+ if (msgInfo) {
+ InitTrack(msgInfo, &mInfo.mAudio, true);
+ }
+ mInfo.mAudio.mMimeType = NS_LITERAL_CSTRING("audio/vorbis");
+ mInfo.mAudio.mRate = newVorbisState->mInfo.rate;
+ mInfo.mAudio.mChannels = newVorbisState->mInfo.channels;
+
+ chained = true;
+ tags = newVorbisState->GetTags();
+ }
+
+ OggHeaders opusHeaders;
+ if ((newOpusState &&
+ ReadHeaders(TrackInfo::kAudioTrack, newOpusState, opusHeaders)) &&
+ (mOpusState->mRate == newOpusState->mRate) &&
+ (mOpusState->mChannels == newOpusState->mChannels)) {
+
+ SetupTargetOpus(newOpusState, opusHeaders);
+
+ if (msgInfo) {
+ InitTrack(msgInfo, &mInfo.mAudio, true);
+ }
+ mInfo.mAudio.mMimeType = NS_LITERAL_CSTRING("audio/opus");
+ mInfo.mAudio.mRate = newOpusState->mRate;
+ mInfo.mAudio.mChannels = newOpusState->mChannels;
+
+ chained = true;
+ tags = newOpusState->GetTags();
+ }
+
+ OggHeaders flacHeaders;
+ if ((newFlacState &&
+ ReadHeaders(TrackInfo::kAudioTrack, newFlacState, flacHeaders)) &&
+ (mFlacState->Info().mRate == newFlacState->Info().mRate) &&
+ (mFlacState->Info().mChannels == newFlacState->Info().mChannels)) {
+
+ SetupTargetFlac(newFlacState, flacHeaders);
+ LOG(LogLevel::Debug, ("New flac ogg link, serial=%d\n", mFlacSerial));
+
+ if (msgInfo) {
+ InitTrack(msgInfo, &mInfo.mAudio, true);
+ }
+
+ mInfo.mAudio = newFlacState->Info();
+ chained = true;
+ tags = newFlacState->GetTags();
+ }
+
+ if (chained) {
+ SetChained();
+ mInfo.mMediaSeekable = false;
+ mDecodedAudioDuration += aLastEndTime;
+ if (mTimedMetadataEvent) {
+ mTimedMetadataEvent->Notify(
+ TimedMetadata(mDecodedAudioDuration,
+ Move(tags),
+ nsAutoPtr<MediaInfo>(new MediaInfo(mInfo))));
+ }
+ // Setup a new TrackInfo so that the MediaFormatReader will flush the
+ // current decoder.
+ mSharedAudioTrackInfo = new SharedTrackInfo(mInfo.mAudio, ++sStreamSourceID);
+ return true;
+ }
+
+ return false;
+}
+
+OggDemuxer::OggStateContext&
+OggDemuxer::OggState(TrackInfo::TrackType aType)
+{
+ if (aType == TrackInfo::kVideoTrack) {
+ return mVideoOggState;
+ }
+ return mAudioOggState;
+}
+
+ogg_sync_state*
+OggDemuxer::OggSyncState(TrackInfo::TrackType aType)
+{
+ return &OggState(aType).mOggState.mState;
+}
+
+MediaResourceIndex*
+OggDemuxer::Resource(TrackInfo::TrackType aType)
+{
+ return &OggState(aType).mResource;
+}
+
+MediaResourceIndex*
+OggDemuxer::CommonResource()
+{
+ return &mAudioOggState.mResource;
+}
+
+bool
+OggDemuxer::ReadOggPage(TrackInfo::TrackType aType, ogg_page* aPage)
+{
+ int ret = 0;
+ while((ret = ogg_sync_pageseek(OggSyncState(aType), aPage)) <= 0) {
+ if (ret < 0) {
+ // Lost page sync, have to skip up to next page.
+ continue;
+ }
+ // Returns a buffer that can be written too
+ // with the given size. This buffer is stored
+ // in the ogg synchronisation structure.
+ char* buffer = ogg_sync_buffer(OggSyncState(aType), 4096);
+ NS_ASSERTION(buffer, "ogg_sync_buffer failed");
+
+ // Read from the resource into the buffer
+ uint32_t bytesRead = 0;
+
+ nsresult rv = Resource(aType)->Read(buffer, 4096, &bytesRead);
+ if (NS_FAILED(rv) || !bytesRead) {
+ // End of file or error.
+ return false;
+ }
+
+ // Update the synchronisation layer with the number
+ // of bytes written to the buffer
+ ret = ogg_sync_wrote(OggSyncState(aType), bytesRead);
+ NS_ENSURE_TRUE(ret == 0, false);
+ }
+
+ return true;
+}
+
+nsresult
+OggDemuxer::DemuxOggPage(TrackInfo::TrackType aType, ogg_page* aPage)
+{
+ int serial = ogg_page_serialno(aPage);
+ OggCodecState* codecState = mCodecStore.Get(serial);
+ if (codecState == nullptr) {
+ OGG_DEBUG("encountered packet for unrecognized codecState");
+ return NS_ERROR_FAILURE;
+ }
+ if (GetCodecStateType(codecState) != aType &&
+ codecState->GetType() != OggCodecState::TYPE_SKELETON) {
+ // Not a page we're interested in.
+ return NS_OK;
+ }
+ if (NS_FAILED(codecState->PageIn(aPage))) {
+ OGG_DEBUG("codecState->PageIn failed");
+ return NS_ERROR_FAILURE;
+ }
+ return NS_OK;
+}
+
+bool
+OggDemuxer::IsSeekable() const
+{
+ if (mIsChained) {
+ return false;
+ }
+ return true;
+}
+
+UniquePtr<EncryptionInfo>
+OggDemuxer::GetCrypto()
+{
+ return nullptr;
+}
+
+ogg_packet*
+OggDemuxer::GetNextPacket(TrackInfo::TrackType aType)
+{
+ OggCodecState* state = GetTrackCodecState(aType);
+ ogg_packet* packet = nullptr;
+ OggStateContext& context = OggState(aType);
+
+ while (true) {
+ if (packet) {
+ OggCodecState::ReleasePacket(state->PacketOut());
+ }
+ DemuxUntilPacketAvailable(aType, state);
+
+ packet = state->PacketPeek();
+ if (!packet) {
+ break;
+ }
+ if (state->IsHeader(packet)) {
+ continue;
+ }
+ if (context.mNeedKeyframe && !state->IsKeyframe(packet)) {
+ continue;
+ }
+ context.mNeedKeyframe = false;
+ break;
+ }
+
+ return packet;
+}
+
+void
+OggDemuxer::DemuxUntilPacketAvailable(TrackInfo::TrackType aType,
+ OggCodecState* aState)
+{
+ while (!aState->IsPacketReady()) {
+ OGG_DEBUG("no packet yet, reading some more");
+ ogg_page page;
+ if (!ReadOggPage(aType, &page)) {
+ OGG_DEBUG("no more pages to read in resource?");
+ return;
+ }
+ DemuxOggPage(aType, &page);
+ }
+}
+
+TimeIntervals
+OggDemuxer::GetBuffered(TrackInfo::TrackType aType)
+{
+ if (!HaveStartTime(aType)) {
+ return TimeIntervals();
+ }
+ if (mIsChained) {
+ return TimeIntervals::Invalid();
+ }
+ TimeIntervals buffered;
+ // HasAudio and HasVideo are not used here as they take a lock and cause
+ // a deadlock. Accessing mInfo doesn't require a lock - it doesn't change
+ // after metadata is read.
+ if (!mInfo.HasValidMedia()) {
+ // No need to search through the file if there are no audio or video tracks
+ return buffered;
+ }
+
+ AutoPinned<MediaResource> resource(Resource(aType)->GetResource());
+ MediaByteRangeSet ranges;
+ nsresult res = resource->GetCachedRanges(ranges);
+ NS_ENSURE_SUCCESS(res, TimeIntervals::Invalid());
+
+ // Traverse across the buffered byte ranges, determining the time ranges
+ // they contain. MediaResource::GetNextCachedData(offset) returns -1 when
+ // offset is after the end of the media resource, or there's no more cached
+ // data after the offset. This loop will run until we've checked every
+ // buffered range in the media, in increasing order of offset.
+ nsAutoOggSyncState sync;
+ for (uint32_t index = 0; index < ranges.Length(); index++) {
+ // Ensure the offsets are after the header pages.
+ int64_t startOffset = ranges[index].mStart;
+ int64_t endOffset = ranges[index].mEnd;
+
+ // Because the granulepos time is actually the end time of the page,
+ // we special-case (startOffset == 0) so that the first
+ // buffered range always appears to be buffered from the media start
+ // time, rather than from the end-time of the first page.
+ int64_t startTime = (startOffset == 0) ? StartTime() : -1;
+
+ // Find the start time of the range. Read pages until we find one with a
+ // granulepos which we can convert into a timestamp to use as the time of
+ // the start of the buffered range.
+ ogg_sync_reset(&sync.mState);
+ while (startTime == -1) {
+ ogg_page page;
+ int32_t discard;
+ PageSyncResult pageSyncResult = PageSync(Resource(aType),
+ &sync.mState,
+ true,
+ startOffset,
+ endOffset,
+ &page,
+ discard);
+ if (pageSyncResult == PAGE_SYNC_ERROR) {
+ return TimeIntervals::Invalid();
+ } else if (pageSyncResult == PAGE_SYNC_END_OF_RANGE) {
+ // Hit the end of range without reading a page, give up trying to
+ // find a start time for this buffered range, skip onto the next one.
+ break;
+ }
+
+ int64_t granulepos = ogg_page_granulepos(&page);
+ if (granulepos == -1) {
+ // Page doesn't have an end time, advance to the next page
+ // until we find one.
+ startOffset += page.header_len + page.body_len;
+ continue;
+ }
+
+ uint32_t serial = ogg_page_serialno(&page);
+ if (aType == TrackInfo::kAudioTrack && mVorbisState &&
+ serial == mVorbisSerial) {
+ startTime = VorbisState::Time(&mVorbisInfo, granulepos);
+ NS_ASSERTION(startTime > 0, "Must have positive start time");
+ } else if (aType == TrackInfo::kAudioTrack && mOpusState &&
+ serial == mOpusSerial) {
+ startTime = OpusState::Time(mOpusPreSkip, granulepos);
+ NS_ASSERTION(startTime > 0, "Must have positive start time");
+ } else if (aType == TrackInfo::kAudioTrack && mFlacState &&
+ serial == mFlacSerial) {
+ startTime = mFlacState->Time(granulepos);
+ NS_ASSERTION(startTime > 0, "Must have positive start time");
+ } else if (aType == TrackInfo::kVideoTrack && mTheoraState &&
+ serial == mTheoraSerial) {
+ startTime = TheoraState::Time(&mTheoraInfo, granulepos);
+ NS_ASSERTION(startTime > 0, "Must have positive start time");
+ } else if (mCodecStore.Contains(serial)) {
+ // Stream is not the theora or vorbis stream we're playing,
+ // but is one that we have header data for.
+ startOffset += page.header_len + page.body_len;
+ continue;
+ } else {
+ // Page is for a stream we don't know about (possibly a chained
+ // ogg), return OK to abort the finding any further ranges. This
+ // prevents us searching through the rest of the media when we
+ // may not be able to extract timestamps from it.
+ SetChained();
+ return buffered;
+ }
+ }
+
+ if (startTime != -1) {
+ // We were able to find a start time for that range, see if we can
+ // find an end time.
+ int64_t endTime = RangeEndTime(aType, startOffset, endOffset, true);
+ if (endTime > startTime) {
+ buffered += TimeInterval(
+ TimeUnit::FromMicroseconds(startTime - StartTime()),
+ TimeUnit::FromMicroseconds(endTime - StartTime()));
+ }
+ }
+ }
+
+ return buffered;
+}
+
+void
+OggDemuxer::FindStartTime(int64_t& aOutStartTime)
+{
+ // Extract the start times of the bitstreams in order to calculate
+ // the duration.
+ int64_t videoStartTime = INT64_MAX;
+ int64_t audioStartTime = INT64_MAX;
+
+ if (HasVideo()) {
+ FindStartTime(TrackInfo::kVideoTrack, videoStartTime);
+ if (videoStartTime != INT64_MAX) {
+ OGG_DEBUG("OggDemuxer::FindStartTime() video=%lld", videoStartTime);
+ mVideoOggState.mStartTime =
+ Some(TimeUnit::FromMicroseconds(videoStartTime));
+ }
+ }
+ if (HasAudio()) {
+ FindStartTime(TrackInfo::kAudioTrack, audioStartTime);
+ if (audioStartTime != INT64_MAX) {
+ OGG_DEBUG("OggDemuxer::FindStartTime() audio=%lld", audioStartTime);
+ mAudioOggState.mStartTime =
+ Some(TimeUnit::FromMicroseconds(audioStartTime));
+ }
+ }
+
+ int64_t startTime = std::min(videoStartTime, audioStartTime);
+ if (startTime != INT64_MAX) {
+ aOutStartTime = startTime;
+ }
+}
+
+void
+OggDemuxer::FindStartTime(TrackInfo::TrackType aType, int64_t& aOutStartTime)
+{
+ int64_t startTime = INT64_MAX;
+
+ OggCodecState* state = GetTrackCodecState(aType);
+ ogg_packet* pkt = GetNextPacket(aType);
+ if (pkt) {
+ startTime = state->PacketStartTime(pkt);
+ }
+
+ if (startTime != INT64_MAX) {
+ aOutStartTime = startTime;
+ }
+}
+
+nsresult
+OggDemuxer::SeekInternal(TrackInfo::TrackType aType, const TimeUnit& aTarget)
+{
+ int64_t target = aTarget.ToMicroseconds();
+ OGG_DEBUG("About to seek to %lld", target);
+ nsresult res;
+ int64_t adjustedTarget = target;
+ int64_t startTime = StartTime(aType);
+ int64_t endTime = mInfo.mMetadataDuration->ToMicroseconds();
+ if (aType == TrackInfo::kAudioTrack && mOpusState){
+ adjustedTarget = std::max(startTime, target - OGG_SEEK_OPUS_PREROLL);
+ }
+
+ if (!HaveStartTime(aType) || adjustedTarget == startTime) {
+ // We've seeked to the media start or we can't seek.
+ // Just seek to the offset of the first content page.
+ res = Resource(aType)->Seek(nsISeekableStream::NS_SEEK_SET, 0);
+ NS_ENSURE_SUCCESS(res,res);
+
+ res = Reset(aType);
+ NS_ENSURE_SUCCESS(res,res);
+ } else {
+ // TODO: This may seek back unnecessarily far in the video, but we don't
+ // have a way of asking Skeleton to seek to a different target for each
+ // stream yet. Using adjustedTarget here is at least correct, if slow.
+ IndexedSeekResult sres = SeekToKeyframeUsingIndex(aType, adjustedTarget);
+ NS_ENSURE_TRUE(sres != SEEK_FATAL_ERROR, NS_ERROR_FAILURE);
+ if (sres == SEEK_INDEX_FAIL) {
+ // No index or other non-fatal index-related failure. Try to seek
+ // using a bisection search. Determine the already downloaded data
+ // in the media cache, so we can try to seek in the cached data first.
+ AutoTArray<SeekRange, 16> ranges;
+ res = GetSeekRanges(aType, ranges);
+ NS_ENSURE_SUCCESS(res,res);
+
+ // Figure out if the seek target lies in a buffered range.
+ SeekRange r = SelectSeekRange(aType, ranges, target, startTime, endTime, true);
+
+ if (!r.IsNull()) {
+ // We know the buffered range in which the seek target lies, do a
+ // bisection search in that buffered range.
+ res = SeekInBufferedRange(aType, target, adjustedTarget, startTime, endTime, ranges, r);
+ NS_ENSURE_SUCCESS(res,res);
+ } else {
+ // The target doesn't lie in a buffered range. Perform a bisection
+ // search over the whole media, using the known buffered ranges to
+ // reduce the search space.
+ res = SeekInUnbuffered(aType, target, startTime, endTime, ranges);
+ NS_ENSURE_SUCCESS(res,res);
+ }
+ }
+ }
+
+ // Demux forwards until we find the first keyframe prior the target.
+ // there may be non-keyframes in the page before the keyframe.
+ // Additionally, we may have seeked to the first page referenced by the
+ // page index which may be quite far off the target.
+ // When doing fastSeek we display the first frame after the seek, so
+ // we need to advance the decode to the keyframe otherwise we'll get
+ // visual artifacts in the first frame output after the seek.
+ OggCodecState* state = GetTrackCodecState(aType);
+ OggPacketQueue tempPackets;
+ bool foundKeyframe = false;
+ while (true) {
+ DemuxUntilPacketAvailable(aType, state);
+ ogg_packet* packet = state->PacketPeek();
+ if (packet == nullptr) {
+ OGG_DEBUG("End of stream reached before keyframe found in indexed seek");
+ break;
+ }
+ int64_t startTstamp = state->PacketStartTime(packet);
+ if (foundKeyframe && startTstamp > adjustedTarget) {
+ break;
+ }
+ if (state->IsKeyframe(packet)) {
+ OGG_DEBUG("keyframe found after seeking at %lld", startTstamp);
+ tempPackets.Erase();
+ foundKeyframe = true;
+ }
+ if (foundKeyframe && startTstamp == adjustedTarget) {
+ break;
+ }
+ ogg_packet* releaseMe = state->PacketOut();
+ if (foundKeyframe) {
+ tempPackets.Append(releaseMe);
+ } else {
+ // Discard video packets before the first keyframe.
+ OggCodecState::ReleasePacket(releaseMe);
+ }
+ }
+ // Re-add all packet into the codec state in order.
+ state->PushFront(Move(tempPackets));
+
+ return NS_OK;
+}
+
+OggDemuxer::IndexedSeekResult
+OggDemuxer::RollbackIndexedSeek(TrackInfo::TrackType aType, int64_t aOffset)
+{
+ if (mSkeletonState) {
+ mSkeletonState->Deactivate();
+ }
+ nsresult res = Resource(aType)->Seek(nsISeekableStream::NS_SEEK_SET, aOffset);
+ NS_ENSURE_SUCCESS(res, SEEK_FATAL_ERROR);
+ return SEEK_INDEX_FAIL;
+}
+
+OggDemuxer::IndexedSeekResult
+OggDemuxer::SeekToKeyframeUsingIndex(TrackInfo::TrackType aType, int64_t aTarget)
+{
+ if (!HasSkeleton() || !mSkeletonState->HasIndex()) {
+ return SEEK_INDEX_FAIL;
+ }
+ // We have an index from the Skeleton track, try to use it to seek.
+ AutoTArray<uint32_t, 2> tracks;
+ BuildSerialList(tracks);
+ SkeletonState::nsSeekTarget keyframe;
+ if (NS_FAILED(mSkeletonState->IndexedSeekTarget(aTarget,
+ tracks,
+ keyframe))) {
+ // Could not locate a keypoint for the target in the index.
+ return SEEK_INDEX_FAIL;
+ }
+
+ // Remember original resource read cursor position so we can rollback on failure.
+ int64_t tell = Resource(aType)->Tell();
+
+ // Seek to the keypoint returned by the index.
+ if (keyframe.mKeyPoint.mOffset > Resource(aType)->GetLength() ||
+ keyframe.mKeyPoint.mOffset < 0) {
+ // Index must be invalid.
+ return RollbackIndexedSeek(aType, tell);
+ }
+ LOG(LogLevel::Debug, ("Seeking using index to keyframe at offset %lld\n",
+ keyframe.mKeyPoint.mOffset));
+ nsresult res = Resource(aType)->Seek(nsISeekableStream::NS_SEEK_SET,
+ keyframe.mKeyPoint.mOffset);
+ NS_ENSURE_SUCCESS(res, SEEK_FATAL_ERROR);
+
+ // We've moved the read set, so reset decode.
+ res = Reset(aType);
+ NS_ENSURE_SUCCESS(res, SEEK_FATAL_ERROR);
+
+ // Check that the page the index thinks is exactly here is actually exactly
+ // here. If not, the index is invalid.
+ ogg_page page;
+ int skippedBytes = 0;
+ PageSyncResult syncres = PageSync(Resource(aType),
+ OggSyncState(aType),
+ false,
+ keyframe.mKeyPoint.mOffset,
+ Resource(aType)->GetLength(),
+ &page,
+ skippedBytes);
+ NS_ENSURE_TRUE(syncres != PAGE_SYNC_ERROR, SEEK_FATAL_ERROR);
+ if (syncres != PAGE_SYNC_OK || skippedBytes != 0) {
+ LOG(LogLevel::Debug, ("Indexed-seek failure: Ogg Skeleton Index is invalid "
+ "or sync error after seek"));
+ return RollbackIndexedSeek(aType, tell);
+ }
+ uint32_t serial = ogg_page_serialno(&page);
+ if (serial != keyframe.mSerial) {
+ // Serialno of page at offset isn't what the index told us to expect.
+ // Assume the index is invalid.
+ return RollbackIndexedSeek(aType, tell);
+ }
+ OggCodecState* codecState = mCodecStore.Get(serial);
+ if (codecState && codecState->mActive &&
+ ogg_stream_pagein(&codecState->mState, &page) != 0) {
+ // Couldn't insert page into the ogg resource, or somehow the resource
+ // is no longer active.
+ return RollbackIndexedSeek(aType, tell);
+ }
+ return SEEK_OK;
+}
+
+// Reads a page from the media resource.
+OggDemuxer::PageSyncResult
+OggDemuxer::PageSync(MediaResourceIndex* aResource,
+ ogg_sync_state* aState,
+ bool aCachedDataOnly,
+ int64_t aOffset,
+ int64_t aEndOffset,
+ ogg_page* aPage,
+ int& aSkippedBytes)
+{
+ aSkippedBytes = 0;
+ // Sync to the next page.
+ int ret = 0;
+ uint32_t bytesRead = 0;
+ int64_t readHead = aOffset;
+ while (ret <= 0) {
+ ret = ogg_sync_pageseek(aState, aPage);
+ if (ret == 0) {
+ char* buffer = ogg_sync_buffer(aState, PAGE_STEP);
+ NS_ASSERTION(buffer, "Must have a buffer");
+
+ // Read from the file into the buffer
+ int64_t bytesToRead = std::min(static_cast<int64_t>(PAGE_STEP),
+ aEndOffset - readHead);
+ NS_ASSERTION(bytesToRead <= UINT32_MAX, "bytesToRead range check");
+ if (bytesToRead <= 0) {
+ return PAGE_SYNC_END_OF_RANGE;
+ }
+ nsresult rv = NS_OK;
+ if (aCachedDataOnly) {
+ rv = aResource->GetResource()->ReadFromCache(buffer, readHead,
+ static_cast<uint32_t>(bytesToRead));
+ NS_ENSURE_SUCCESS(rv,PAGE_SYNC_ERROR);
+ bytesRead = static_cast<uint32_t>(bytesToRead);
+ } else {
+ rv = aResource->Seek(nsISeekableStream::NS_SEEK_SET, readHead);
+ NS_ENSURE_SUCCESS(rv,PAGE_SYNC_ERROR);
+ rv = aResource->Read(buffer,
+ static_cast<uint32_t>(bytesToRead),
+ &bytesRead);
+ NS_ENSURE_SUCCESS(rv,PAGE_SYNC_ERROR);
+ }
+ if (bytesRead == 0 && NS_SUCCEEDED(rv)) {
+ // End of file.
+ return PAGE_SYNC_END_OF_RANGE;
+ }
+ readHead += bytesRead;
+
+ // Update the synchronisation layer with the number
+ // of bytes written to the buffer
+ ret = ogg_sync_wrote(aState, bytesRead);
+ NS_ENSURE_TRUE(ret == 0, PAGE_SYNC_ERROR);
+ continue;
+ }
+
+ if (ret < 0) {
+ NS_ASSERTION(aSkippedBytes >= 0, "Offset >= 0");
+ aSkippedBytes += -ret;
+ NS_ASSERTION(aSkippedBytes >= 0, "Offset >= 0");
+ continue;
+ }
+ }
+
+ return PAGE_SYNC_OK;
+}
+
+//OggTrackDemuxer
+OggTrackDemuxer::OggTrackDemuxer(OggDemuxer* aParent,
+ TrackInfo::TrackType aType,
+ uint32_t aTrackNumber)
+ : mParent(aParent)
+ , mType(aType)
+{
+ mInfo = mParent->GetTrackInfo(aType, aTrackNumber);
+ MOZ_ASSERT(mInfo);
+}
+
+OggTrackDemuxer::~OggTrackDemuxer()
+{
+}
+
+UniquePtr<TrackInfo>
+OggTrackDemuxer::GetInfo() const
+{
+ return mInfo->Clone();
+}
+
+RefPtr<OggTrackDemuxer::SeekPromise>
+OggTrackDemuxer::Seek(TimeUnit aTime)
+{
+ // Seeks to aTime. Upon success, SeekPromise will be resolved with the
+ // actual time seeked to. Typically the random access point time
+ mQueuedSample = nullptr;
+ TimeUnit seekTime = aTime;
+ if (mParent->SeekInternal(mType, aTime) == NS_OK) {
+ RefPtr<MediaRawData> sample(NextSample());
+
+ // Check what time we actually seeked to.
+ if (sample != nullptr) {
+ seekTime = TimeUnit::FromMicroseconds(sample->mTime);
+ OGG_DEBUG("%p seeked to time %lld", this, seekTime.ToMicroseconds());
+ }
+ mQueuedSample = sample;
+
+ return SeekPromise::CreateAndResolve(seekTime, __func__);
+ } else {
+ return SeekPromise::CreateAndReject(NS_ERROR_DOM_MEDIA_DEMUXER_ERR, __func__);
+ }
+}
+
+RefPtr<MediaRawData>
+OggTrackDemuxer::NextSample()
+{
+ if (mQueuedSample) {
+ RefPtr<MediaRawData> nextSample = mQueuedSample;
+ mQueuedSample = nullptr;
+ if (mType == TrackInfo::kAudioTrack) {
+ nextSample->mTrackInfo = mParent->mSharedAudioTrackInfo;
+ }
+ return nextSample;
+ }
+ ogg_packet* packet = mParent->GetNextPacket(mType);
+ if (!packet) {
+ return nullptr;
+ }
+ // Check the eos state in case we need to look for chained streams.
+ bool eos = packet->e_o_s;
+ OggCodecState* state = mParent->GetTrackCodecState(mType);
+ RefPtr<MediaRawData> data = state->PacketOutAsMediaRawData();
+ if (!data) {
+ return nullptr;
+ }
+ if (mType == TrackInfo::kAudioTrack) {
+ data->mTrackInfo = mParent->mSharedAudioTrackInfo;
+ }
+ if (eos) {
+ // We've encountered an end of bitstream packet; check for a chained
+ // bitstream following this one.
+ // This will also update mSharedAudioTrackInfo.
+ mParent->ReadOggChain(TimeUnit::FromMicroseconds(data->GetEndTime()));
+ }
+ return data;
+}
+
+RefPtr<OggTrackDemuxer::SamplesPromise>
+OggTrackDemuxer::GetSamples(int32_t aNumSamples)
+{
+ RefPtr<SamplesHolder> samples = new SamplesHolder;
+ if (!aNumSamples) {
+ return SamplesPromise::CreateAndReject(NS_ERROR_DOM_MEDIA_DEMUXER_ERR, __func__);
+ }
+
+ while (aNumSamples) {
+ RefPtr<MediaRawData> sample(NextSample());
+ if (!sample) {
+ break;
+ }
+ samples->mSamples.AppendElement(sample);
+ aNumSamples--;
+ }
+
+ if (samples->mSamples.IsEmpty()) {
+ return SamplesPromise::CreateAndReject(NS_ERROR_DOM_MEDIA_END_OF_STREAM, __func__);
+ } else {
+ return SamplesPromise::CreateAndResolve(samples, __func__);
+ }
+}
+
+void
+OggTrackDemuxer::Reset()
+{
+ mParent->Reset(mType);
+ mQueuedSample = nullptr;
+}
+
+RefPtr<OggTrackDemuxer::SkipAccessPointPromise>
+OggTrackDemuxer::SkipToNextRandomAccessPoint(TimeUnit aTimeThreshold)
+{
+ uint32_t parsed = 0;
+ bool found = false;
+ RefPtr<MediaRawData> sample;
+
+ OGG_DEBUG("TimeThreshold: %f", aTimeThreshold.ToSeconds());
+ while (!found && (sample = NextSample())) {
+ parsed++;
+ if (sample->mKeyframe && sample->mTime >= aTimeThreshold.ToMicroseconds()) {
+ found = true;
+ mQueuedSample = sample;
+ }
+ }
+ if (found) {
+ OGG_DEBUG("next sample: %f (parsed: %d)",
+ TimeUnit::FromMicroseconds(sample->mTime).ToSeconds(),
+ parsed);
+ return SkipAccessPointPromise::CreateAndResolve(parsed, __func__);
+ } else {
+ SkipFailureHolder failure(NS_ERROR_DOM_MEDIA_END_OF_STREAM, parsed);
+ return SkipAccessPointPromise::CreateAndReject(Move(failure), __func__);
+ }
+}
+
+TimeIntervals
+OggTrackDemuxer::GetBuffered()
+{
+ return mParent->GetBuffered(mType);
+}
+
+void
+OggTrackDemuxer::BreakCycles()
+{
+ mParent = nullptr;
+}
+
+
+// Returns an ogg page's checksum.
+ogg_uint32_t
+OggDemuxer::GetPageChecksum(ogg_page* page)
+{
+ if (page == 0 || page->header == 0 || page->header_len < 25) {
+ return 0;
+ }
+ const unsigned char* p = page->header + 22;
+ uint32_t c = p[0] + (p[1] << 8) + (p[2] << 16) + (p[3] << 24);
+ return c;
+}
+
+int64_t
+OggDemuxer::RangeStartTime(TrackInfo::TrackType aType, int64_t aOffset)
+{
+ int64_t position = Resource(aType)->Tell();
+ nsresult res = Resource(aType)->Seek(nsISeekableStream::NS_SEEK_SET, aOffset);
+ NS_ENSURE_SUCCESS(res, 0);
+ int64_t startTime = 0;
+ FindStartTime(aType, startTime);
+ res = Resource(aType)->Seek(nsISeekableStream::NS_SEEK_SET, position);
+ NS_ENSURE_SUCCESS(res, -1);
+ return startTime;
+}
+
+struct nsDemuxerAutoOggSyncState
+{
+ nsDemuxerAutoOggSyncState()
+ {
+ ogg_sync_init(&mState);
+ }
+ ~nsDemuxerAutoOggSyncState()
+ {
+ ogg_sync_clear(&mState);
+ }
+ ogg_sync_state mState;
+};
+
+int64_t
+OggDemuxer::RangeEndTime(TrackInfo::TrackType aType, int64_t aEndOffset)
+{
+ int64_t position = Resource(aType)->Tell();
+ int64_t endTime = RangeEndTime(aType, 0, aEndOffset, false);
+ nsresult res = Resource(aType)->Seek(nsISeekableStream::NS_SEEK_SET, position);
+ NS_ENSURE_SUCCESS(res, -1);
+ return endTime;
+}
+
+int64_t
+OggDemuxer::RangeEndTime(TrackInfo::TrackType aType,
+ int64_t aStartOffset,
+ int64_t aEndOffset,
+ bool aCachedDataOnly)
+{
+ nsDemuxerAutoOggSyncState sync;
+
+ // We need to find the last page which ends before aEndOffset that
+ // has a granulepos that we can convert to a timestamp. We do this by
+ // backing off from aEndOffset until we encounter a page on which we can
+ // interpret the granulepos. If while backing off we encounter a page which
+ // we've previously encountered before, we'll either backoff again if we
+ // haven't found an end time yet, or return the last end time found.
+ const int step = 5000;
+ const int maxOggPageSize = 65306;
+ int64_t readStartOffset = aEndOffset;
+ int64_t readLimitOffset = aEndOffset;
+ int64_t readHead = aEndOffset;
+ int64_t endTime = -1;
+ uint32_t checksumAfterSeek = 0;
+ uint32_t prevChecksumAfterSeek = 0;
+ bool mustBackOff = false;
+ while (true) {
+ ogg_page page;
+ int ret = ogg_sync_pageseek(&sync.mState, &page);
+ if (ret == 0) {
+ // We need more data if we've not encountered a page we've seen before,
+ // or we've read to the end of file.
+ if (mustBackOff || readHead == aEndOffset || readHead == aStartOffset) {
+ if (endTime != -1 || readStartOffset == 0) {
+ // We have encountered a page before, or we're at the end of file.
+ break;
+ }
+ mustBackOff = false;
+ prevChecksumAfterSeek = checksumAfterSeek;
+ checksumAfterSeek = 0;
+ ogg_sync_reset(&sync.mState);
+ readStartOffset = std::max(static_cast<int64_t>(0), readStartOffset - step);
+ // There's no point reading more than the maximum size of
+ // an Ogg page into data we've previously scanned. Any data
+ // between readLimitOffset and aEndOffset must be garbage
+ // and we can ignore it thereafter.
+ readLimitOffset = std::min(readLimitOffset,
+ readStartOffset + maxOggPageSize);
+ readHead = std::max(aStartOffset, readStartOffset);
+ }
+
+ int64_t limit = std::min(static_cast<int64_t>(UINT32_MAX),
+ aEndOffset - readHead);
+ limit = std::max(static_cast<int64_t>(0), limit);
+ limit = std::min(limit, static_cast<int64_t>(step));
+ uint32_t bytesToRead = static_cast<uint32_t>(limit);
+ uint32_t bytesRead = 0;
+ char* buffer = ogg_sync_buffer(&sync.mState, bytesToRead);
+ NS_ASSERTION(buffer, "Must have buffer");
+ nsresult res;
+ if (aCachedDataOnly) {
+ res = Resource(aType)->GetResource()->ReadFromCache(buffer, readHead, bytesToRead);
+ NS_ENSURE_SUCCESS(res, -1);
+ bytesRead = bytesToRead;
+ } else {
+ NS_ASSERTION(readHead < aEndOffset,
+ "resource pos must be before range end");
+ res = Resource(aType)->Seek(nsISeekableStream::NS_SEEK_SET, readHead);
+ NS_ENSURE_SUCCESS(res, -1);
+ res = Resource(aType)->Read(buffer, bytesToRead, &bytesRead);
+ NS_ENSURE_SUCCESS(res, -1);
+ }
+ readHead += bytesRead;
+ if (readHead > readLimitOffset) {
+ mustBackOff = true;
+ }
+
+ // Update the synchronisation layer with the number
+ // of bytes written to the buffer
+ ret = ogg_sync_wrote(&sync.mState, bytesRead);
+ if (ret != 0) {
+ endTime = -1;
+ break;
+ }
+ continue;
+ }
+
+ if (ret < 0 || ogg_page_granulepos(&page) < 0) {
+ continue;
+ }
+
+ uint32_t checksum = GetPageChecksum(&page);
+ if (checksumAfterSeek == 0) {
+ // This is the first page we've decoded after a backoff/seek. Remember
+ // the page checksum. If we backoff further and encounter this page
+ // again, we'll know that we won't find a page with an end time after
+ // this one, so we'll know to back off again.
+ checksumAfterSeek = checksum;
+ }
+ if (checksum == prevChecksumAfterSeek) {
+ // This page has the same checksum as the first page we encountered
+ // after the last backoff/seek. Since we've already scanned after this
+ // page and failed to find an end time, we may as well backoff again and
+ // try to find an end time from an earlier page.
+ mustBackOff = true;
+ continue;
+ }
+
+ int64_t granulepos = ogg_page_granulepos(&page);
+ int serial = ogg_page_serialno(&page);
+
+ OggCodecState* codecState = nullptr;
+ codecState = mCodecStore.Get(serial);
+ if (!codecState) {
+ // This page is from a bitstream which we haven't encountered yet.
+ // It's probably from a new "link" in a "chained" ogg. Don't
+ // bother even trying to find a duration...
+ SetChained();
+ endTime = -1;
+ break;
+ }
+
+ int64_t t = codecState->Time(granulepos);
+ if (t != -1) {
+ endTime = t;
+ }
+ }
+
+ return endTime;
+}
+
+nsresult
+OggDemuxer::GetSeekRanges(TrackInfo::TrackType aType,
+ nsTArray<SeekRange>& aRanges)
+{
+ AutoPinned<MediaResource> resource(Resource(aType)->GetResource());
+ MediaByteRangeSet cached;
+ nsresult res = resource->GetCachedRanges(cached);
+ NS_ENSURE_SUCCESS(res, res);
+
+ for (uint32_t index = 0; index < cached.Length(); index++) {
+ auto& range = cached[index];
+ int64_t startTime = -1;
+ int64_t endTime = -1;
+ if (NS_FAILED(Reset(aType))) {
+ return NS_ERROR_FAILURE;
+ }
+ int64_t startOffset = range.mStart;
+ int64_t endOffset = range.mEnd;
+ startTime = RangeStartTime(aType, startOffset);
+ if (startTime != -1 &&
+ ((endTime = RangeEndTime(aType, endOffset)) != -1)) {
+ NS_WARNING_ASSERTION(startTime < endTime,
+ "Start time must be before end time");
+ aRanges.AppendElement(SeekRange(startOffset,
+ endOffset,
+ startTime,
+ endTime));
+ }
+ }
+ if (NS_FAILED(Reset(aType))) {
+ return NS_ERROR_FAILURE;
+ }
+ return NS_OK;
+}
+
+OggDemuxer::SeekRange
+OggDemuxer::SelectSeekRange(TrackInfo::TrackType aType,
+ const nsTArray<SeekRange>& ranges,
+ int64_t aTarget,
+ int64_t aStartTime,
+ int64_t aEndTime,
+ bool aExact)
+{
+ int64_t so = 0;
+ int64_t eo = Resource(aType)->GetLength();
+ int64_t st = aStartTime;
+ int64_t et = aEndTime;
+ for (uint32_t i = 0; i < ranges.Length(); i++) {
+ const SeekRange& r = ranges[i];
+ if (r.mTimeStart < aTarget) {
+ so = r.mOffsetStart;
+ st = r.mTimeStart;
+ }
+ if (r.mTimeEnd >= aTarget && r.mTimeEnd < et) {
+ eo = r.mOffsetEnd;
+ et = r.mTimeEnd;
+ }
+
+ if (r.mTimeStart < aTarget && aTarget <= r.mTimeEnd) {
+ // Target lies exactly in this range.
+ return ranges[i];
+ }
+ }
+ if (aExact || eo == -1) {
+ return SeekRange();
+ }
+ return SeekRange(so, eo, st, et);
+}
+
+
+nsresult
+OggDemuxer::SeekInBufferedRange(TrackInfo::TrackType aType,
+ int64_t aTarget,
+ int64_t aAdjustedTarget,
+ int64_t aStartTime,
+ int64_t aEndTime,
+ const nsTArray<SeekRange>& aRanges,
+ const SeekRange& aRange)
+{
+ OGG_DEBUG("Seeking in buffered data to %lld using bisection search", aTarget);
+ if (aType == TrackInfo::kVideoTrack || aAdjustedTarget >= aTarget) {
+ // We know the exact byte range in which the target must lie. It must
+ // be buffered in the media cache. Seek there.
+ nsresult res = SeekBisection(aType, aTarget, aRange, 0);
+ if (NS_FAILED(res) || aType != TrackInfo::kVideoTrack) {
+ return res;
+ }
+
+ // We have an active Theora bitstream. Peek the next Theora frame, and
+ // extract its keyframe's time.
+ DemuxUntilPacketAvailable(aType, mTheoraState);
+ ogg_packet* packet = mTheoraState->PacketPeek();
+ if (packet && !mTheoraState->IsKeyframe(packet)) {
+ // First post-seek frame isn't a keyframe, seek back to previous keyframe,
+ // otherwise we'll get visual artifacts.
+ NS_ASSERTION(packet->granulepos != -1, "Must have a granulepos");
+ int shift = mTheoraState->mInfo.keyframe_granule_shift;
+ int64_t keyframeGranulepos = (packet->granulepos >> shift) << shift;
+ int64_t keyframeTime = mTheoraState->StartTime(keyframeGranulepos);
+ SEEK_LOG(LogLevel::Debug, ("Keyframe for %lld is at %lld, seeking back to it",
+ frameTime, keyframeTime));
+ aAdjustedTarget = std::min(aAdjustedTarget, keyframeTime);
+ }
+ }
+
+ nsresult res = NS_OK;
+ if (aAdjustedTarget < aTarget) {
+ SeekRange k = SelectSeekRange(aType,
+ aRanges,
+ aAdjustedTarget,
+ aStartTime,
+ aEndTime,
+ false);
+ res = SeekBisection(aType, aAdjustedTarget, k, OGG_SEEK_FUZZ_USECS);
+ }
+ return res;
+}
+
+nsresult
+OggDemuxer::SeekInUnbuffered(TrackInfo::TrackType aType,
+ int64_t aTarget,
+ int64_t aStartTime,
+ int64_t aEndTime,
+ const nsTArray<SeekRange>& aRanges)
+{
+ OGG_DEBUG("Seeking in unbuffered data to %lld using bisection search", aTarget);
+
+ // If we've got an active Theora bitstream, determine the maximum possible
+ // time in usecs which a keyframe could be before a given interframe. We
+ // subtract this from our seek target, seek to the new target, and then
+ // will decode forward to the original seek target. We should encounter a
+ // keyframe in that interval. This prevents us from needing to run two
+ // bisections; one for the seek target frame, and another to find its
+ // keyframe. It's usually faster to just download this extra data, rather
+ // tham perform two bisections to find the seek target's keyframe. We
+ // don't do this offsetting when seeking in a buffered range,
+ // as the extra decoding causes a noticeable speed hit when all the data
+ // is buffered (compared to just doing a bisection to exactly find the
+ // keyframe).
+ int64_t keyframeOffsetMs = 0;
+ if (aType == TrackInfo::kVideoTrack && mTheoraState) {
+ keyframeOffsetMs = mTheoraState->MaxKeyframeOffset();
+ }
+ // Add in the Opus pre-roll if necessary, as well.
+ if (aType == TrackInfo::kAudioTrack && mOpusState) {
+ keyframeOffsetMs = std::max(keyframeOffsetMs, OGG_SEEK_OPUS_PREROLL);
+ }
+ int64_t seekTarget = std::max(aStartTime, aTarget - keyframeOffsetMs);
+ // Minimize the bisection search space using the known timestamps from the
+ // buffered ranges.
+ SeekRange k =
+ SelectSeekRange(aType, aRanges, seekTarget, aStartTime, aEndTime, false);
+ return SeekBisection(aType, seekTarget, k, OGG_SEEK_FUZZ_USECS);
+}
+
+nsresult
+OggDemuxer::SeekBisection(TrackInfo::TrackType aType,
+ int64_t aTarget,
+ const SeekRange& aRange,
+ uint32_t aFuzz)
+{
+ nsresult res;
+
+ if (aTarget <= aRange.mTimeStart) {
+ if (NS_FAILED(Reset(aType))) {
+ return NS_ERROR_FAILURE;
+ }
+ res = Resource(aType)->Seek(nsISeekableStream::NS_SEEK_SET, 0);
+ NS_ENSURE_SUCCESS(res,res);
+ return NS_OK;
+ }
+
+ // Bisection search, find start offset of last page with end time less than
+ // the seek target.
+ ogg_int64_t startOffset = aRange.mOffsetStart;
+ ogg_int64_t startTime = aRange.mTimeStart;
+ ogg_int64_t startLength = 0; // Length of the page at startOffset.
+ ogg_int64_t endOffset = aRange.mOffsetEnd;
+ ogg_int64_t endTime = aRange.mTimeEnd;
+
+ ogg_int64_t seekTarget = aTarget;
+ int64_t seekLowerBound = std::max(static_cast<int64_t>(0), aTarget - aFuzz);
+ int hops = 0;
+ DebugOnly<ogg_int64_t> previousGuess = -1;
+ int backsteps = 0;
+ const int maxBackStep = 10;
+ NS_ASSERTION(static_cast<uint64_t>(PAGE_STEP) * pow(2.0, maxBackStep) < INT32_MAX,
+ "Backstep calculation must not overflow");
+
+ // Seek via bisection search. Loop until we find the offset where the page
+ // before the offset is before the seek target, and the page after the offset
+ // is after the seek target.
+ while (true) {
+ ogg_int64_t duration = 0;
+ double target = 0;
+ ogg_int64_t interval = 0;
+ ogg_int64_t guess = 0;
+ ogg_page page;
+ int skippedBytes = 0;
+ ogg_int64_t pageOffset = 0;
+ ogg_int64_t pageLength = 0;
+ ogg_int64_t granuleTime = -1;
+ bool mustBackoff = false;
+
+ // Guess where we should bisect to, based on the bit rate and the time
+ // remaining in the interval. Loop until we can determine the time at
+ // the guess offset.
+ while (true) {
+
+ // Discard any previously buffered packets/pages.
+ if (NS_FAILED(Reset(aType))) {
+ return NS_ERROR_FAILURE;
+ }
+
+ interval = endOffset - startOffset - startLength;
+ if (interval == 0) {
+ // Our interval is empty, we've found the optimal seek point, as the
+ // page at the start offset is before the seek target, and the page
+ // at the end offset is after the seek target.
+ SEEK_LOG(LogLevel::Debug, ("Interval narrowed, terminating bisection."));
+ break;
+ }
+
+ // Guess bisection point.
+ duration = endTime - startTime;
+ target = (double)(seekTarget - startTime) / (double)duration;
+ guess = startOffset + startLength +
+ static_cast<ogg_int64_t>((double)interval * target);
+ guess = std::min(guess, endOffset - PAGE_STEP);
+ if (mustBackoff) {
+ // We previously failed to determine the time at the guess offset,
+ // probably because we ran out of data to decode. This usually happens
+ // when we guess very close to the end offset. So reduce the guess
+ // offset using an exponential backoff until we determine the time.
+ SEEK_LOG(LogLevel::Debug, ("Backing off %d bytes, backsteps=%d",
+ static_cast<int32_t>(PAGE_STEP * pow(2.0, backsteps)), backsteps));
+ guess -= PAGE_STEP * static_cast<ogg_int64_t>(pow(2.0, backsteps));
+
+ if (guess <= startOffset) {
+ // We've tried to backoff to before the start offset of our seek
+ // range. This means we couldn't find a seek termination position
+ // near the end of the seek range, so just set the seek termination
+ // condition, and break out of the bisection loop. We'll begin
+ // decoding from the start of the seek range.
+ interval = 0;
+ break;
+ }
+
+ backsteps = std::min(backsteps + 1, maxBackStep);
+ // We reset mustBackoff. If we still need to backoff further, it will
+ // be set to true again.
+ mustBackoff = false;
+ } else {
+ backsteps = 0;
+ }
+ guess = std::max(guess, startOffset + startLength);
+
+ SEEK_LOG(LogLevel::Debug, ("Seek loop start[o=%lld..%lld t=%lld] "
+ "end[o=%lld t=%lld] "
+ "interval=%lld target=%lf guess=%lld",
+ startOffset, (startOffset+startLength), startTime,
+ endOffset, endTime, interval, target, guess));
+
+ NS_ASSERTION(guess >= startOffset + startLength, "Guess must be after range start");
+ NS_ASSERTION(guess < endOffset, "Guess must be before range end");
+ NS_ASSERTION(guess != previousGuess, "Guess should be different to previous");
+ previousGuess = guess;
+
+ hops++;
+
+ // Locate the next page after our seek guess, and then figure out the
+ // granule time of the audio and video bitstreams there. We can then
+ // make a bisection decision based on our location in the media.
+ PageSyncResult pageSyncResult = PageSync(Resource(aType),
+ OggSyncState(aType),
+ false,
+ guess,
+ endOffset,
+ &page,
+ skippedBytes);
+ NS_ENSURE_TRUE(pageSyncResult != PAGE_SYNC_ERROR, NS_ERROR_FAILURE);
+
+ if (pageSyncResult == PAGE_SYNC_END_OF_RANGE) {
+ // Our guess was too close to the end, we've ended up reading the end
+ // page. Backoff exponentially from the end point, in case the last
+ // page/frame/sample is huge.
+ mustBackoff = true;
+ SEEK_LOG(LogLevel::Debug, ("Hit the end of range, backing off"));
+ continue;
+ }
+
+ // We've located a page of length |ret| at |guess + skippedBytes|.
+ // Remember where the page is located.
+ pageOffset = guess + skippedBytes;
+ pageLength = page.header_len + page.body_len;
+
+ // Read pages until we can determine the granule time of the audio and
+ // video bitstream.
+ ogg_int64_t audioTime = -1;
+ ogg_int64_t videoTime = -1;
+ do {
+ // Add the page to its codec state, determine its granule time.
+ uint32_t serial = ogg_page_serialno(&page);
+ OggCodecState* codecState = mCodecStore.Get(serial);
+ if (codecState && GetCodecStateType(codecState) == aType) {
+ if (codecState->mActive) {
+ int ret = ogg_stream_pagein(&codecState->mState, &page);
+ NS_ENSURE_TRUE(ret == 0, NS_ERROR_FAILURE);
+ }
+
+ ogg_int64_t granulepos = ogg_page_granulepos(&page);
+
+ if (aType == TrackInfo::kAudioTrack &&
+ granulepos > 0 && audioTime == -1) {
+ if (mVorbisState && serial == mVorbisState->mSerial) {
+ audioTime = mVorbisState->Time(granulepos);
+ } else if (mOpusState && serial == mOpusState->mSerial) {
+ audioTime = mOpusState->Time(granulepos);
+ } else if (mFlacState && serial == mFlacState->mSerial) {
+ audioTime = mFlacState->Time(granulepos);
+ }
+ }
+
+ if (aType == TrackInfo::kVideoTrack &&
+ granulepos > 0 && serial == mTheoraState->mSerial &&
+ videoTime == -1) {
+ videoTime = mTheoraState->Time(granulepos);
+ }
+
+ if (pageOffset + pageLength >= endOffset) {
+ // Hit end of readable data.
+ break;
+ }
+ }
+ if (!ReadOggPage(aType, &page)) {
+ break;
+ }
+
+ } while ((aType == TrackInfo::kAudioTrack && audioTime == -1) ||
+ (aType == TrackInfo::kVideoTrack && videoTime == -1));
+
+
+ if ((aType == TrackInfo::kAudioTrack && audioTime == -1) ||
+ (aType == TrackInfo::kVideoTrack && videoTime == -1)) {
+ // We don't have timestamps for all active tracks...
+ if (pageOffset == startOffset + startLength &&
+ pageOffset + pageLength >= endOffset) {
+ // We read the entire interval without finding timestamps for all
+ // active tracks. We know the interval start offset is before the seek
+ // target, and the interval end is after the seek target, and we can't
+ // terminate inside the interval, so we terminate the seek at the
+ // start of the interval.
+ interval = 0;
+ break;
+ }
+
+ // We should backoff; cause the guess to back off from the end, so
+ // that we've got more room to capture.
+ mustBackoff = true;
+ continue;
+ }
+
+ // We've found appropriate time stamps here. Proceed to bisect
+ // the search space.
+ granuleTime = aType == TrackInfo::kAudioTrack ? audioTime : videoTime;
+ NS_ASSERTION(granuleTime > 0, "Must get a granuletime");
+ break;
+ } // End of "until we determine time at guess offset" loop.
+
+ if (interval == 0) {
+ // Seek termination condition; we've found the page boundary of the
+ // last page before the target, and the first page after the target.
+ SEEK_LOG(LogLevel::Debug, ("Terminating seek at offset=%lld", startOffset));
+ NS_ASSERTION(startTime < aTarget, "Start time must always be less than target");
+ res = Resource(aType)->Seek(nsISeekableStream::NS_SEEK_SET, startOffset);
+ NS_ENSURE_SUCCESS(res,res);
+ if (NS_FAILED(Reset(aType))) {
+ return NS_ERROR_FAILURE;
+ }
+ break;
+ }
+
+ SEEK_LOG(LogLevel::Debug, ("Time at offset %lld is %lld", guess, granuleTime));
+ if (granuleTime < seekTarget && granuleTime > seekLowerBound) {
+ // We're within the fuzzy region in which we want to terminate the search.
+ res = Resource(aType)->Seek(nsISeekableStream::NS_SEEK_SET, pageOffset);
+ NS_ENSURE_SUCCESS(res,res);
+ if (NS_FAILED(Reset(aType))) {
+ return NS_ERROR_FAILURE;
+ }
+ SEEK_LOG(LogLevel::Debug, ("Terminating seek at offset=%lld", pageOffset));
+ break;
+ }
+
+ if (granuleTime >= seekTarget) {
+ // We've landed after the seek target.
+ NS_ASSERTION(pageOffset < endOffset, "offset_end must decrease");
+ endOffset = pageOffset;
+ endTime = granuleTime;
+ } else if (granuleTime < seekTarget) {
+ // Landed before seek target.
+ NS_ASSERTION(pageOffset >= startOffset + startLength,
+ "Bisection point should be at or after end of first page in interval");
+ startOffset = pageOffset;
+ startLength = pageLength;
+ startTime = granuleTime;
+ }
+ NS_ASSERTION(startTime <= seekTarget, "Must be before seek target");
+ NS_ASSERTION(endTime >= seekTarget, "End must be after seek target");
+ }
+
+ SEEK_LOG(LogLevel::Debug, ("Seek complete in %d bisections.", hops));
+
+ return NS_OK;
+}
+
+#undef OGG_DEBUG
+#undef SEEK_DEBUG
+} // namespace mozilla