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// Copyright 2015 The Chromium Authors. All rights reserved.
// Use of this source code is governed by a BSD-style license that can be
// found in the LICENSE file.
#include "media/base/android/video_media_codec_decoder.h"
#include <utility>
#include "base/bind.h"
#include "base/logging.h"
#include "media/base/android/media_statistics.h"
#include "media/base/android/sdk_media_codec_bridge.h"
#include "media/base/demuxer_stream.h"
#include "media/base/timestamp_constants.h"
namespace media {
namespace {
const int kDelayForStandAloneEOS = 2; // milliseconds
}
VideoMediaCodecDecoder::VideoMediaCodecDecoder(
const scoped_refptr<base::SingleThreadTaskRunner>& media_task_runner,
FrameStatistics* frame_statistics,
const base::Closure& request_data_cb,
const base::Closure& starvation_cb,
const base::Closure& decoder_drained_cb,
const base::Closure& stop_done_cb,
const base::Closure& waiting_for_decryption_key_cb,
const base::Closure& error_cb,
const SetTimeCallback& update_current_time_cb,
const VideoSizeChangedCallback& video_size_changed_cb)
: MediaCodecDecoder("VideoDecoder",
media_task_runner,
frame_statistics,
request_data_cb,
starvation_cb,
decoder_drained_cb,
stop_done_cb,
waiting_for_decryption_key_cb,
error_cb),
is_protected_surface_required_(false),
update_current_time_cb_(update_current_time_cb),
video_size_changed_cb_(video_size_changed_cb) {}
VideoMediaCodecDecoder::~VideoMediaCodecDecoder() {
DCHECK(media_task_runner_->BelongsToCurrentThread());
DVLOG(1) << "VideoDecoder::~VideoDecoder()";
ReleaseDecoderResources();
}
const char* VideoMediaCodecDecoder::class_name() const {
return "VideoDecoder";
}
bool VideoMediaCodecDecoder::HasStream() const {
DCHECK(media_task_runner_->BelongsToCurrentThread());
return configs_.video_codec != kUnknownVideoCodec;
}
void VideoMediaCodecDecoder::SetDemuxerConfigs(const DemuxerConfigs& configs) {
DVLOG(1) << class_name() << "::" << __FUNCTION__ << " " << configs;
configs_ = configs;
if (video_size_.IsEmpty()) {
video_size_ = configs_.video_size;
media_task_runner_->PostTask(
FROM_HERE, base::Bind(video_size_changed_cb_, video_size_));
}
}
bool VideoMediaCodecDecoder::IsContentEncrypted() const {
// Make sure SetDemuxerConfigs() as been called.
DCHECK(configs_.video_codec != kUnknownVideoCodec);
return configs_.is_video_encrypted;
}
void VideoMediaCodecDecoder::ReleaseDecoderResources() {
DCHECK(media_task_runner_->BelongsToCurrentThread());
DVLOG(1) << class_name() << "::" << __FUNCTION__;
DoEmergencyStop();
ReleaseMediaCodec();
surface_ = gfx::ScopedJavaSurface();
}
void VideoMediaCodecDecoder::ReleaseMediaCodec() {
DCHECK(media_task_runner_->BelongsToCurrentThread());
MediaCodecDecoder::ReleaseMediaCodec();
delayed_buffers_.clear();
}
void VideoMediaCodecDecoder::SetVideoSurface(gfx::ScopedJavaSurface surface) {
DCHECK(media_task_runner_->BelongsToCurrentThread());
DVLOG(1) << class_name() << "::" << __FUNCTION__
<< (surface.IsEmpty() ? " empty" : " non-empty");
surface_ = std::move(surface);
needs_reconfigure_ = true;
}
bool VideoMediaCodecDecoder::HasVideoSurface() const {
DCHECK(media_task_runner_->BelongsToCurrentThread());
return !surface_.IsEmpty();
}
void VideoMediaCodecDecoder::SetProtectedSurfaceRequired(bool value) {
DCHECK(media_task_runner_->BelongsToCurrentThread());
is_protected_surface_required_ = value;
}
bool VideoMediaCodecDecoder::IsProtectedSurfaceRequired() const {
DCHECK(media_task_runner_->BelongsToCurrentThread());
return is_protected_surface_required_;
}
bool VideoMediaCodecDecoder::IsCodecReconfigureNeeded(
const DemuxerConfigs& next) const {
if (always_reconfigure_for_tests_)
return true;
if (configs_.video_codec != next.video_codec ||
configs_.is_video_encrypted != next.is_video_encrypted) {
return true;
}
// Only size changes below this point
if (configs_.video_size.width() == next.video_size.width() &&
configs_.video_size.height() == next.video_size.height()) {
return false; // i.e. configs_ == next
}
return !static_cast<VideoCodecBridge*>(media_codec_bridge_.get())
->IsAdaptivePlaybackSupported(next.video_size.width(),
next.video_size.height());
}
MediaCodecDecoder::ConfigStatus VideoMediaCodecDecoder::ConfigureInternal(
jobject media_crypto) {
DCHECK(media_task_runner_->BelongsToCurrentThread());
DVLOG(1) << class_name() << "::" << __FUNCTION__;
// If we cannot find a key frame in cache, the browser seek is needed.
if (!au_queue_.RewindToLastKeyFrame()) {
DVLOG(1) << class_name() << "::" << __FUNCTION__ << " key frame required";
return kConfigKeyFrameRequired;
}
if (configs_.video_codec == kUnknownVideoCodec) {
DVLOG(0) << class_name() << "::" << __FUNCTION__
<< ": configuration parameters are required";
return kConfigFailure;
}
if (surface_.IsEmpty()) {
DVLOG(0) << class_name() << "::" << __FUNCTION__ << ": surface is required";
return kConfigFailure;
}
bool is_secure = IsContentEncrypted() && is_protected_surface_required_;
media_codec_bridge_.reset(VideoCodecBridge::CreateDecoder(
configs_.video_codec, is_secure, configs_.video_size,
surface_.j_surface().obj(), media_crypto));
if (!media_codec_bridge_) {
DVLOG(0) << class_name() << "::" << __FUNCTION__
<< " failed: cannot create video codec";
return kConfigFailure;
}
DVLOG(0) << class_name() << "::" << __FUNCTION__ << " succeeded";
if (!codec_created_for_tests_cb_.is_null())
media_task_runner_->PostTask(FROM_HERE, codec_created_for_tests_cb_);
return kConfigOk;
}
void VideoMediaCodecDecoder::AssociateCurrentTimeWithPTS(base::TimeDelta pts) {
DCHECK(media_task_runner_->BelongsToCurrentThread());
DVLOG(1) << class_name() << "::" << __FUNCTION__ << " pts:" << pts;
start_time_ticks_ = base::TimeTicks::Now();
start_pts_ = pts;
last_seen_pts_ = pts;
}
void VideoMediaCodecDecoder::DissociatePTSFromTime() {
DCHECK(media_task_runner_->BelongsToCurrentThread());
start_pts_ = last_seen_pts_ = kNoTimestamp();
}
void VideoMediaCodecDecoder::OnOutputFormatChanged() {
DCHECK(decoder_thread_.task_runner()->BelongsToCurrentThread());
gfx::Size prev_size = video_size_;
// See b/18224769. The values reported from MediaCodecBridge::GetOutputSize
// correspond to the actual video frame size, but this is not necessarily the
// size that should be output.
video_size_ = configs_.video_size;
if (video_size_ != prev_size) {
media_task_runner_->PostTask(
FROM_HERE, base::Bind(video_size_changed_cb_, video_size_));
}
}
void VideoMediaCodecDecoder::Render(int buffer_index,
size_t offset,
size_t size,
RenderMode render_mode,
base::TimeDelta pts,
bool eos_encountered) {
DCHECK(decoder_thread_.task_runner()->BelongsToCurrentThread());
DVLOG(2) << class_name() << "::" << __FUNCTION__ << " pts:" << pts
<< (eos_encountered ? " EOS " : " ") << AsString(render_mode);
// Normally EOS comes as a separate access unit that does not have data,
// the corresponding |size| will be 0.
if (!size && eos_encountered) {
// Stand-alone EOS
// Discard the PTS that comes with it and ensure it is released last.
pts = last_seen_pts_ +
base::TimeDelta::FromMilliseconds(kDelayForStandAloneEOS);
} else {
// Keep track of last seen PTS
last_seen_pts_ = pts;
}
// Do not update time for stand-alone EOS.
const bool update_time = !(eos_encountered && size == 0u);
// For video we simplify the preroll operation and render the first frame
// after preroll during the preroll phase, i.e. without waiting for audio
// stream to finish prerolling.
switch (render_mode) {
case kRenderSkip:
ReleaseOutputBuffer(buffer_index, pts, false, false, eos_encountered);
return;
case kRenderAfterPreroll:
// We get here in the preroll phase. Render now as explained above.
// |start_pts_| is not set yet, thus we cannot calculate |time_to_render|.
ReleaseOutputBuffer(buffer_index, pts, (size > 0), update_time,
eos_encountered);
return;
case kRenderNow:
break;
}
DCHECK_EQ(kRenderNow, render_mode);
DCHECK_NE(kNoTimestamp(), start_pts_); // start_pts_ must be set
base::TimeDelta time_to_render =
pts - (base::TimeTicks::Now() - start_time_ticks_ + start_pts_);
DVLOG(2) << class_name() << "::" << __FUNCTION__ << " pts:" << pts
<< " ticks delta:" << (base::TimeTicks::Now() - start_time_ticks_)
<< " time_to_render:" << time_to_render;
const bool render = (size > 0);
if (render)
frame_statistics_->IncrementFrameCount();
if (time_to_render < base::TimeDelta()) {
if (render) {
DVLOG(2) << class_name() << "::" << __FUNCTION__
<< " LATE FRAME delay:" << (-1) * time_to_render;
frame_statistics_->IncrementLateFrameCount();
}
// Render late frames immediately.
ReleaseOutputBuffer(buffer_index, pts, render, update_time,
eos_encountered);
return;
}
delayed_buffers_.insert(buffer_index);
decoder_thread_.task_runner()->PostDelayedTask(
FROM_HERE, base::Bind(&VideoMediaCodecDecoder::ReleaseOutputBuffer,
base::Unretained(this), buffer_index, pts, render,
update_time, eos_encountered),
time_to_render);
}
int VideoMediaCodecDecoder::NumDelayedRenderTasks() const {
DCHECK(decoder_thread_.task_runner()->BelongsToCurrentThread());
return delayed_buffers_.size();
}
void VideoMediaCodecDecoder::ReleaseDelayedBuffers() {
// Media thread
// Called when there is no decoder thread
for (int index : delayed_buffers_)
media_codec_bridge_->ReleaseOutputBuffer(index, false);
delayed_buffers_.clear();
}
#ifndef NDEBUG
void VideoMediaCodecDecoder::VerifyUnitIsKeyFrame(
const AccessUnit* unit) const {
// The first video frame in a sequence must be a key frame or stand-alone EOS.
DCHECK(unit);
bool stand_alone_eos = unit->is_end_of_stream && unit->data.empty();
DCHECK(stand_alone_eos || unit->is_key_frame);
}
#endif
void VideoMediaCodecDecoder::ReleaseOutputBuffer(int buffer_index,
base::TimeDelta pts,
bool render,
bool update_time,
bool eos_encountered) {
DCHECK(decoder_thread_.task_runner()->BelongsToCurrentThread());
DVLOG(2) << class_name() << "::" << __FUNCTION__ << " pts:" << pts;
// Do not render if we are in emergency stop, there might be no surface.
if (InEmergencyStop())
render = false;
media_codec_bridge_->ReleaseOutputBuffer(buffer_index, render);
delayed_buffers_.erase(buffer_index);
CheckLastFrame(eos_encountered, !delayed_buffers_.empty());
// |update_current_time_cb_| might be null if there is audio stream.
// Do not update current time for stand-alone EOS frames.
if (!update_current_time_cb_.is_null() && update_time) {
media_task_runner_->PostTask(
FROM_HERE, base::Bind(update_current_time_cb_, pts, pts, false));
}
}
} // namespace media
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