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shaka-packager/packager/media/chunking/cue_alignment_handler.cc

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// Copyright 2018 Google Inc. All rights reserved.
//
// Use of this source code is governed by a BSD-style
// license that can be found in the LICENSE file or at
// https://developers.google.com/open-source/licenses/bsd
#include "packager/media/chunking/cue_alignment_handler.h"
#include "packager/status_macros.h"
namespace shaka {
namespace media {
namespace {
// The max number of samples that are allowed to be buffered before we shutdown
// because there is likely a problem with the content or how the pipeline was
// configured. This is about 20 seconds of buffer for audio with 48kHz.
const size_t kMaxBufferSize = 1000;
int64_t GetScaledTime(const StreamInfo& info, const StreamData& data) {
DCHECK(data.text_sample || data.media_sample);
if (data.text_sample) {
return data.text_sample->start_time();
}
if (info.stream_type() == kStreamText) {
// This class does not support splitting MediaSample at cue points, which is
// required for text stream. This class expects MediaSample to be converted
// to TextSample before passing to this class.
NOTREACHED()
<< "A text streams should use text samples, not media samples.";
}
if (info.stream_type() == kStreamAudio) {
// Return the mid-point for audio because if the portion of the sample
// after the cue point is bigger than the portion of the sample before
// the cue point, the sample is placed after the cue.
return data.media_sample->pts() + data.media_sample->duration() / 2;
}
DCHECK_EQ(info.stream_type(), kStreamVideo);
return data.media_sample->pts();
}
double TimeInSeconds(const StreamInfo& info, const StreamData& data) {
const int64_t scaled_time = GetScaledTime(info, data);
const uint32_t time_scale = info.time_scale();
return static_cast<double>(scaled_time) / time_scale;
}
Status GetNextCue(double hint,
SyncPointQueue* sync_points,
std::shared_ptr<const CueEvent>* out_cue) {
DCHECK(sync_points);
DCHECK(out_cue);
*out_cue = sync_points->GetNext(hint);
// |*out_cue| will only be null if the job was cancelled.
return *out_cue ? Status::OK
: Status(error::CANCELLED, "SyncPointQueue is cancelled.");
}
} // namespace
CueAlignmentHandler::CueAlignmentHandler(SyncPointQueue* sync_points)
: sync_points_(sync_points) {}
Status CueAlignmentHandler::InitializeInternal() {
sync_points_->AddThread();
stream_states_.resize(num_input_streams());
// Get the first hint for the stream. Use a negative hint so that if there is
// suppose to be a sync point at zero, we will still respect it.
hint_ = sync_points_->GetHint(-1);
return Status::OK;
}
Status CueAlignmentHandler::Process(std::unique_ptr<StreamData> data) {
switch (data->stream_data_type) {
case StreamDataType::kStreamInfo:
return OnStreamInfo(std::move(data));
case StreamDataType::kTextSample:
case StreamDataType::kMediaSample:
return OnSample(std::move(data));
default:
VLOG(3) << "Dropping unsupported data type "
<< static_cast<int>(data->stream_data_type);
return Status::OK;
}
}
Status CueAlignmentHandler::OnFlushRequest(size_t stream_index) {
stream_states_[stream_index].to_be_flushed = true;
// We need to wait for all stream to flush before we can flush each stream.
// This allows cached buffers to be cleared and cues to be properly
// synchronized and set on all streams.
for (const StreamState& stream_state : stream_states_) {
if (!stream_state.to_be_flushed) {
return Status::OK;
}
}
// Do a once over all the streams to ensure that their states are as we expect
// them. Video and non-video streams have different allowances here. Video
// should absolutely have no cues or samples where as non-video streams may
// have cues or samples.
for (StreamState& stream : stream_states_) {
DCHECK(stream.to_be_flushed);
if (stream.info->stream_type() == kStreamVideo) {
DCHECK_EQ(stream.samples.size(), 0u)
<< "Video streams should not store samples";
DCHECK_EQ(stream.cues.size(), 0u)
<< "Video streams should not store cues";
}
}
// It is possible that we did not get all the cues. |hint_| will get updated
// when we call |UseNextSyncPoint|.
while (sync_points_->HasMore(hint_)) {
std::shared_ptr<const CueEvent> next_cue;
RETURN_IF_ERROR(GetNextCue(hint_, sync_points_, &next_cue));
RETURN_IF_ERROR(UseNewSyncPoint(std::move(next_cue)));
}
// Now that there are new cues, it may be possible to dispatch some of the
// samples that may be left waiting.
for (StreamState& stream : stream_states_) {
RETURN_IF_ERROR(RunThroughSamples(&stream));
DCHECK_EQ(stream.samples.size(), 0u);
// It is possible for there to be cues that come after all the samples. Make
// sure to send them out too.
while (stream.cues.size()) {
RETURN_IF_ERROR(Dispatch(std::move(stream.cues.front())));
stream.cues.pop_front();
}
}
return FlushAllDownstreams();
}
Status CueAlignmentHandler::OnStreamInfo(std::unique_ptr<StreamData> data) {
StreamState& stream_state = stream_states_[data->stream_index];
// Keep a copy of the stream info so that we can check type and check
// timescale.
stream_state.info = data->stream_info;
return Dispatch(std::move(data));
}
Status CueAlignmentHandler::OnVideoSample(std::unique_ptr<StreamData> sample) {
DCHECK(sample);
DCHECK(sample->media_sample);
const size_t stream_index = sample->stream_index;
StreamState& stream = stream_states_[stream_index];
const double sample_time = TimeInSeconds(*stream.info, *sample);
const bool is_key_frame = sample->media_sample->is_key_frame();
if (is_key_frame && sample_time >= hint_) {
auto next_sync = sync_points_->PromoteAt(sample_time);
if (!next_sync) {
LOG(ERROR) << "Failed to promote sync point at " << sample_time
<< ". This happens only if video streams are not GOP-aligned.";
return Status(error::INVALID_ARGUMENT,
"Streams are not properly GOP-aligned.");
}
RETURN_IF_ERROR(UseNewSyncPoint(std::move(next_sync)));
DCHECK_EQ(stream.cues.size(), 1u);
RETURN_IF_ERROR(Dispatch(std::move(stream.cues.front())));
stream.cues.pop_front();
}
return Dispatch(std::move(sample));
}
Status CueAlignmentHandler::OnNonVideoSample(
std::unique_ptr<StreamData> sample) {
DCHECK(sample);
DCHECK(sample->media_sample || sample->text_sample);
const size_t stream_index = sample->stream_index;
StreamState& stream_state = stream_states_[stream_index];
// Accept the sample. This will output it if it comes before the hint point or
// will cache it if it comes after the hint point.
RETURN_IF_ERROR(AcceptSample(std::move(sample), &stream_state));
// If all the streams are waiting on a hint, it means that none has next sync
// point determined. It also means that there are no video streams and we need
// to wait for all streams to converge on a hint so that we can get the next
// sync point.
if (EveryoneWaitingAtHint()) {
std::shared_ptr<const CueEvent> next_sync;
RETURN_IF_ERROR(GetNextCue(hint_, sync_points_, &next_sync));
RETURN_IF_ERROR(UseNewSyncPoint(next_sync));
}
return Status::OK;
}
Status CueAlignmentHandler::OnSample(std::unique_ptr<StreamData> sample) {
// There are two modes:
// 1. There is a video input.
// 2. There are no video inputs.
//
// When there is a video input, we rely on the video input get the next sync
// point and release all the samples.
//
// When there are no video inputs, we rely on the sync point queue to block
// us until there is a sync point.
const size_t stream_index = sample->stream_index;
const StreamType stream_type =
stream_states_[stream_index].info->stream_type();
const bool is_video = stream_type == kStreamVideo;
return is_video ? OnVideoSample(std::move(sample))
: OnNonVideoSample(std::move(sample));
}
Status CueAlignmentHandler::UseNewSyncPoint(
std::shared_ptr<const CueEvent> new_sync) {
hint_ = sync_points_->GetHint(new_sync->time_in_seconds);
DCHECK_GT(hint_, new_sync->time_in_seconds);
for (size_t stream_index = 0; stream_index < stream_states_.size();
stream_index++) {
StreamState& stream = stream_states_[stream_index];
stream.cues.push_back(StreamData::FromCueEvent(stream_index, new_sync));
RETURN_IF_ERROR(RunThroughSamples(&stream));
}
return Status::OK;
}
bool CueAlignmentHandler::EveryoneWaitingAtHint() const {
for (const StreamState& stream_state : stream_states_) {
if (stream_state.samples.empty()) {
return false;
}
}
return true;
}
Status CueAlignmentHandler::AcceptSample(std::unique_ptr<StreamData> sample,
StreamState* stream) {
DCHECK(sample);
DCHECK(sample->media_sample || sample->text_sample);
DCHECK(stream);
// Need to cache the stream index as we will lose the pointer when we add
// the sample to the queue.
const size_t stream_index = sample->stream_index;
stream->samples.push_back(std::move(sample));
if (stream->samples.size() > kMaxBufferSize) {
LOG(ERROR) << "Stream " << stream_index << " has buffered "
<< stream->samples.size() << " when the max is "
<< kMaxBufferSize;
return Status(error::INVALID_ARGUMENT,
"Streams are not properly multiplexed.");
}
return RunThroughSamples(stream);
}
Status CueAlignmentHandler::RunThroughSamples(StreamState* stream) {
// Step through all our samples until we find where we can insert the cue.
// Think of this as a merge sort.
while (stream->cues.size() && stream->samples.size()) {
const double cue_time = stream->cues.front()->cue_event->time_in_seconds;
const double sample_time =
TimeInSeconds(*stream->info, *stream->samples.front());
if (sample_time < cue_time) {
RETURN_IF_ERROR(Dispatch(std::move(stream->samples.front())));
stream->samples.pop_front();
} else {
RETURN_IF_ERROR(Dispatch(std::move(stream->cues.front())));
stream->cues.pop_front();
}
}
// If we still have samples, then it means that we sent out the cue and can
// now work up to the hint. So now send all samples that come before the hint
// downstream.
while (stream->samples.size() &&
TimeInSeconds(*stream->info, *stream->samples.front()) < hint_) {
RETURN_IF_ERROR(Dispatch(std::move(stream->samples.front())));
stream->samples.pop_front();
}
return Status::OK;
}
} // namespace media
} // namespace shaka
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