third_party/chromium/media/cast/test/fake_media_source.cc - cobalt - Git at Google

 // Copyright 2014 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/cast/test/fake_media_source.h"

 #include <memory>
 #include <utility>

 #include "base/bind.h"
 #include "base/files/scoped_file.h"
 #include "base/logging.h"
 #include "base/rand_util.h"
 #include "base/strings/string_number_conversions.h"
 #include "build/build_config.h"
 #include "media/base/audio_buffer.h"
 #include "media/base/audio_bus.h"
 #include "media/base/audio_fifo.h"
 #include "media/base/audio_timestamp_helper.h"
 #include "media/base/media.h"
 #include "media/base/video_frame.h"
 #include "media/base/video_util.h"
 #include "media/cast/cast_sender.h"
 #include "media/cast/test/utility/audio_utility.h"
 #include "media/cast/test/utility/video_utility.h"
 #include "ui/gfx/geometry/size.h"

 // TODO(miu): Figure out why _mkdir() and _rmdir() are missing when compiling
 // third_party/ffmpeg/libavformat/os_support.h (lines 182, 183).
 // http://crbug.com/572986
 #if defined(OS_WIN)
 #include <direct.h>
 #endif  // defined(OS_WIN)
 #include "media/ffmpeg/ffmpeg_common.h"
 #include "media/ffmpeg/ffmpeg_decoding_loop.h"
 #include "media/ffmpeg/ffmpeg_deleters.h"
 #include "media/filters/ffmpeg_glue.h"
 #include "media/filters/in_memory_url_protocol.h"

 namespace {

 static const int kSoundFrequency = 440;  // Frequency of sinusoid wave.
 static const float kSoundVolume = 0.10f;
 static const int kAudioFrameMs = 10;  // Each audio frame is exactly 10ms.
 static const int kAudioPacketsPerSecond = 1000 / kAudioFrameMs;

 // Bounds for variable frame size mode.
 static const int kMinFakeFrameWidth = 60;
 static const int kMinFakeFrameHeight = 34;
 static const int kStartingFakeFrameWidth = 854;
 static const int kStartingFakeFrameHeight = 480;
 static const int kMaxFakeFrameWidth = 1280;
 static const int kMaxFakeFrameHeight = 720;
 static const int kMaxFrameSizeChangeMillis = 5000;

 void AVFreeFrame(AVFrame* frame) {
   av_frame_free(&frame);
 }

 base::TimeDelta PtsToTimeDelta(int64_t pts, const AVRational& time_base) {
   return pts * base::Seconds(1) * time_base.num / time_base.den;
 }

 int64_t TimeDeltaToPts(base::TimeDelta delta, const AVRational& time_base) {
   return static_cast<int64_t>(
       delta.InSecondsF() * time_base.den / time_base.num + 0.5 /* rounding */);
 }

 }  // namespace

 namespace media {
 namespace cast {

 FakeMediaSource::FakeMediaSource(
     scoped_refptr<base::SingleThreadTaskRunner> task_runner,
     const base::TickClock* clock,
     const FrameSenderConfig& audio_config,
     const FrameSenderConfig& video_config,
     bool keep_frames)
     : task_runner_(task_runner),
       output_audio_params_(AudioParameters::AUDIO_PCM_LINEAR,
                            media::GuessChannelLayout(audio_config.channels),
                            audio_config.rtp_timebase,
                            audio_config.rtp_timebase / kAudioPacketsPerSecond),
       video_config_(video_config),
       keep_frames_(keep_frames),
       variable_frame_size_mode_(false),
       synthetic_count_(0),
       clock_(clock),
       audio_frame_count_(0),
       video_frame_count_(0),
       av_format_context_(nullptr),
       audio_stream_index_(-1),
       playback_rate_(1.0),
       video_stream_index_(-1),
       video_frame_rate_numerator_(video_config.max_frame_rate),
       video_frame_rate_denominator_(1),
       audio_algo_(&media_log_),
       video_first_pts_(0),
       video_first_pts_set_(false) {
   CHECK(output_audio_params_.IsValid());
   audio_bus_factory_ = std::make_unique<TestAudioBusFactory>(
       audio_config.channels, audio_config.rtp_timebase, kSoundFrequency,
       kSoundVolume);
 }

 FakeMediaSource::~FakeMediaSource() = default;

 void FakeMediaSource::SetSourceFile(const base::FilePath& video_file,
                                     int final_fps) {
   DCHECK(!video_file.empty());

   LOG(INFO) << "Source: " << video_file.value();
   if (!file_data_.Initialize(video_file)) {
     LOG(ERROR) << "Cannot load file.";
     return;
   }
   protocol_ = std::make_unique<InMemoryUrlProtocol>(file_data_.data(),
                                                     file_data_.length(), false);
   glue_ = std::make_unique<FFmpegGlue>(protocol_.get());

   if (!glue_->OpenContext()) {
     LOG(ERROR) << "Cannot open file.";
     return;
   }

   // AVFormatContext is owned by the glue.
   av_format_context_ = glue_->format_context();
   if (avformat_find_stream_info(av_format_context_, NULL) < 0) {
     LOG(ERROR) << "Cannot find stream information.";
     return;
   }

   // Prepare FFmpeg decoders.
   for (unsigned int i = 0; i < av_format_context_->nb_streams; ++i) {
     AVStream* av_stream = av_format_context_->streams[i];
     std::unique_ptr<AVCodecContext, ScopedPtrAVFreeContext> av_codec_context(
         AVStreamToAVCodecContext(av_stream));
     if (!av_codec_context) {
       LOG(ERROR) << "Cannot get a codec context for the codec: "
                  << av_stream->codecpar->codec_id;
       continue;
     }

     const AVCodec* av_codec = avcodec_find_decoder(av_codec_context->codec_id);

     if (!av_codec) {
       LOG(ERROR) << "Cannot find decoder for the codec: "
                  << av_codec_context->codec_id;
       continue;
     }

     // Number of threads for decoding.
     av_codec_context->thread_count = 2;
     av_codec_context->error_concealment = FF_EC_GUESS_MVS | FF_EC_DEBLOCK;
     av_codec_context->request_sample_fmt = AV_SAMPLE_FMT_S16;

     if (avcodec_open2(av_codec_context.get(), av_codec, nullptr) < 0) {
       LOG(ERROR) << "Cannot open AVCodecContext for the codec: "
                  << av_codec_context->codec_id;
       return;
     }

     if (av_codec->type == AVMEDIA_TYPE_AUDIO) {
       if (av_codec_context->sample_fmt == AV_SAMPLE_FMT_S16P) {
         LOG(ERROR) << "Audio format not supported.";
         continue;
       }
       ChannelLayout layout = ChannelLayoutToChromeChannelLayout(
           av_codec_context->channel_layout,
           av_codec_context->channels);
       if (layout == CHANNEL_LAYOUT_UNSUPPORTED) {
         LOG(ERROR) << "Unsupported audio channels layout.";
         continue;
       }
       if (audio_stream_index_ != -1) {
         LOG(WARNING) << "Found multiple audio streams.";
       }
       audio_stream_index_ = static_cast<int>(i);
       av_audio_context_ = std::move(av_codec_context);
       source_audio_params_.Reset(
           AudioParameters::AUDIO_PCM_LINEAR, layout,
           av_audio_context_->sample_rate,
           av_audio_context_->sample_rate / kAudioPacketsPerSecond);
       source_audio_params_.set_channels_for_discrete(
           av_audio_context_->channels);
       CHECK(source_audio_params_.IsValid());
       LOG(INFO) << "Source file has audio.";
       audio_decoding_loop_ =
           std::make_unique<FFmpegDecodingLoop>(av_audio_context_.get());
     } else if (av_codec->type == AVMEDIA_TYPE_VIDEO) {
       VideoPixelFormat format =
           AVPixelFormatToVideoPixelFormat(av_codec_context->pix_fmt);
       if (format != PIXEL_FORMAT_I420) {
         LOG(ERROR) << "Cannot handle non YV12 video format: " << format;
         continue;
       }
       if (video_stream_index_ != -1) {
         LOG(WARNING) << "Found multiple video streams.";
       }
       video_stream_index_ = static_cast<int>(i);
       av_video_context_ = std::move(av_codec_context);
       video_decoding_loop_ =
           std::make_unique<FFmpegDecodingLoop>(av_video_context_.get());
       if (final_fps > 0) {
         // If video is played at a manual speed audio needs to match.
         playback_rate_ = 1.0 * final_fps *
             av_stream->r_frame_rate.den / av_stream->r_frame_rate.num;
         video_frame_rate_numerator_ = final_fps;
         video_frame_rate_denominator_ = 1;
       } else {
         playback_rate_ = 1.0;
         video_frame_rate_numerator_ = av_stream->r_frame_rate.num;
         video_frame_rate_denominator_ = av_stream->r_frame_rate.den;
       }
       LOG(INFO) << "Source file has video.";
     } else {
       LOG(ERROR) << "Unknown stream type; ignore.";
     }
   }

   Rewind();
 }

 void FakeMediaSource::SetVariableFrameSizeMode(bool enabled) {
   variable_frame_size_mode_ = enabled;
 }

 void FakeMediaSource::Start(scoped_refptr<AudioFrameInput> audio_frame_input,
                             scoped_refptr<VideoFrameInput> video_frame_input) {
   audio_frame_input_ = audio_frame_input;
   video_frame_input_ = video_frame_input;

   LOG(INFO) << "Max Frame rate: " << video_config_.max_frame_rate;
   LOG(INFO) << "Source Frame rate: "
             << video_frame_rate_numerator_ << "/"
             << video_frame_rate_denominator_ << " fps.";
   LOG(INFO) << "Audio playback rate: " << playback_rate_;

   if (start_time_.is_null())
     start_time_ = clock_->NowTicks();

   if (!is_transcoding_audio() && !is_transcoding_video()) {
     // Send fake patterns.
     task_runner_->PostTask(FROM_HERE,
                            base::BindOnce(&FakeMediaSource::SendNextFakeFrame,
                                           weak_factory_.GetWeakPtr()));
     return;
   }

   // Send transcoding streams.
   bool is_encrypted = false;
   audio_algo_.Initialize(source_audio_params_, is_encrypted);
   audio_algo_.FlushBuffers();
   audio_fifo_input_bus_ = AudioBus::Create(
       source_audio_params_.channels(),
       source_audio_params_.frames_per_buffer());
   // Audio FIFO can carry all data fron AudioRendererAlgorithm.
   audio_fifo_ = std::make_unique<AudioFifo>(source_audio_params_.channels(),
                                             audio_algo_.QueueCapacity());
   audio_converter_ = std::make_unique<media::AudioConverter>(
       source_audio_params_, output_audio_params_, true);
   audio_converter_->AddInput(this);
   task_runner_->PostTask(FROM_HERE,
                          base::BindOnce(&FakeMediaSource::SendNextFrame,
                                         weak_factory_.GetWeakPtr()));
 }

 void FakeMediaSource::SendNextFakeFrame() {
   UpdateNextFrameSize();
   scoped_refptr<VideoFrame> video_frame =
       VideoFrame::CreateBlackFrame(current_frame_size_);
   PopulateVideoFrame(video_frame.get(), synthetic_count_);
   ++synthetic_count_;

   const base::TimeTicks now = clock_->NowTicks();

   base::TimeDelta video_time = VideoFrameTime(++video_frame_count_);
   video_frame->set_timestamp(video_time);
   if (keep_frames_)
     inserted_video_frame_queue_.push(video_frame);
   video_frame_input_->InsertRawVideoFrame(video_frame,
                                           start_time_ + video_time);

   // Send just enough audio data to match next video frame's time.
   base::TimeDelta audio_time = AudioFrameTime(audio_frame_count_);
   while (audio_time < video_time) {
     if (is_transcoding_audio()) {
       Decode(true);
       CHECK(!audio_bus_queue_.empty()) << "No audio decoded.";
       std::unique_ptr<AudioBus> bus(audio_bus_queue_.front());
       audio_bus_queue_.pop();
       audio_frame_input_->InsertAudio(std::move(bus), start_time_ + audio_time);
     } else {
       audio_frame_input_->InsertAudio(
           audio_bus_factory_->NextAudioBus(base::Milliseconds(kAudioFrameMs)),
           start_time_ + audio_time);
     }
     audio_time = AudioFrameTime(++audio_frame_count_);
   }

   // This is the time since FakeMediaSource was started.
   const base::TimeDelta elapsed_time = now - start_time_;

   // Handle the case when frame generation cannot keep up.
   // Move the time ahead to match the next frame.
   while (video_time < elapsed_time) {
     LOG(WARNING) << "Skipping one frame.";
     video_time = VideoFrameTime(++video_frame_count_);
   }

   task_runner_->PostDelayedTask(
       FROM_HERE,
       base::BindOnce(&FakeMediaSource::SendNextFakeFrame,
                      weak_factory_.GetWeakPtr()),
       video_time - elapsed_time);
 }

 void FakeMediaSource::UpdateNextFrameSize() {
   if (variable_frame_size_mode_) {
     bool update_size_change_time = false;
     if (current_frame_size_.IsEmpty()) {
       current_frame_size_ = gfx::Size(kStartingFakeFrameWidth,
                                       kStartingFakeFrameHeight);
       update_size_change_time = true;
     } else if (clock_->NowTicks() >= next_frame_size_change_time_) {
       current_frame_size_ = gfx::Size(
           base::RandInt(kMinFakeFrameWidth, kMaxFakeFrameWidth),
           base::RandInt(kMinFakeFrameHeight, kMaxFakeFrameHeight));
       update_size_change_time = true;
     }

     if (update_size_change_time) {
       next_frame_size_change_time_ =
           clock_->NowTicks() +
           base::Milliseconds(base::RandDouble() * kMaxFrameSizeChangeMillis);
     }
   } else {
     current_frame_size_ = gfx::Size(kStartingFakeFrameWidth,
                                     kStartingFakeFrameHeight);
     next_frame_size_change_time_ = base::TimeTicks();
   }
 }

 bool FakeMediaSource::SendNextTranscodedVideo(base::TimeDelta elapsed_time) {
   if (!is_transcoding_video())
     return false;

   Decode(false);
   if (video_frame_queue_.empty())
     return false;

   const scoped_refptr<VideoFrame> video_frame = video_frame_queue_.front();
   if (elapsed_time < video_frame->timestamp())
     return false;
   video_frame_queue_.pop();

   // Use the timestamp from the file if we're transcoding.
   video_frame->set_timestamp(ScaleTimestamp(video_frame->timestamp()));
   if (keep_frames_)
     inserted_video_frame_queue_.push(video_frame);
   video_frame_input_->InsertRawVideoFrame(
       video_frame, start_time_ + video_frame->timestamp());

   // Make sure queue is not empty.
   Decode(false);
   return true;
 }

 bool FakeMediaSource::SendNextTranscodedAudio(base::TimeDelta elapsed_time) {
   if (!is_transcoding_audio())
     return false;

   Decode(true);
   if (audio_bus_queue_.empty())
     return false;

   base::TimeDelta audio_time = audio_sent_ts_->GetTimestamp();
   if (elapsed_time < audio_time)
     return false;
   std::unique_ptr<AudioBus> bus(audio_bus_queue_.front());
   audio_bus_queue_.pop();
   audio_sent_ts_->AddFrames(bus->frames());
   audio_frame_input_->InsertAudio(std::move(bus), start_time_ + audio_time);

   // Make sure queue is not empty.
   Decode(true);
   return true;
 }

 void FakeMediaSource::SendNextFrame() {
   // Send as much as possible. Audio is sent according to
   // system time.
   while (SendNextTranscodedAudio(clock_->NowTicks() - start_time_)) {
   }

   // Video is sync'ed to audio.
   while (SendNextTranscodedVideo(audio_sent_ts_->GetTimestamp())) {
   }

   if (audio_bus_queue_.empty() && video_frame_queue_.empty()) {
     // Both queues are empty can only mean that we have reached
     // the end of the stream.
     LOG(INFO) << "Rewind.";
     Rewind();
   }

   // Send next send.
   task_runner_->PostDelayedTask(FROM_HERE,
                                 base::BindOnce(&FakeMediaSource::SendNextFrame,
                                                weak_factory_.GetWeakPtr()),
                                 base::Milliseconds(kAudioFrameMs));
 }

 base::TimeDelta FakeMediaSource::VideoFrameTime(int frame_number) {
   return frame_number * base::Seconds(1) * video_frame_rate_denominator_ /
          video_frame_rate_numerator_;
 }

 base::TimeDelta FakeMediaSource::ScaleTimestamp(base::TimeDelta timestamp) {
   return timestamp / playback_rate_;
 }

 base::TimeDelta FakeMediaSource::AudioFrameTime(int frame_number) {
   return frame_number * base::Milliseconds(kAudioFrameMs);
 }

 void FakeMediaSource::Rewind() {
   CHECK(av_seek_frame(av_format_context_, -1, 0, AVSEEK_FLAG_BACKWARD) >= 0)
       << "Failed to rewind to the beginning.";
 }

 ScopedAVPacket FakeMediaSource::DemuxOnePacket(bool* audio) {
   ScopedAVPacket packet = MakeScopedAVPacket();
   if (av_read_frame(av_format_context_, packet.get()) < 0) {
     VLOG(1) << "Failed to read one AVPacket.";
     packet.reset();
     return packet;
   }

   int stream_index = static_cast<int>(packet->stream_index);
   if (stream_index == audio_stream_index_) {
     *audio = true;
   } else if (stream_index == video_stream_index_) {
     *audio = false;
   } else {
     // Ignore unknown packet.
     LOG(INFO) << "Unknown packet.";
     packet.reset();
   }
   return packet;
 }

 void FakeMediaSource::DecodeAudio(ScopedAVPacket packet) {
   auto result = audio_decoding_loop_->DecodePacket(
       packet.get(), base::BindRepeating(&FakeMediaSource::OnNewAudioFrame,
                                         base::Unretained(this)));
   CHECK_EQ(result, FFmpegDecodingLoop::DecodeStatus::kOkay)
       << "Failed to decode audio.";

   const int frames_needed_to_scale =
       playback_rate_ * av_audio_context_->sample_rate / kAudioPacketsPerSecond;
   while (frames_needed_to_scale <= audio_algo_.BufferedFrames()) {
     if (!audio_algo_.FillBuffer(audio_fifo_input_bus_.get(), 0,
                                 audio_fifo_input_bus_->frames(),
                                 playback_rate_)) {
       // Nothing can be scaled. Decode some more.
       return;
     }

     // Prevent overflow of audio data in the FIFO.
     if (audio_fifo_input_bus_->frames() + audio_fifo_->frames() <=
         audio_fifo_->max_frames()) {
       audio_fifo_->Push(audio_fifo_input_bus_.get());
     } else {
       LOG(WARNING) << "Audio FIFO full; dropping samples.";
     }

     // Make sure there's enough data to resample audio.
     if (audio_fifo_->frames() <
         2 * source_audio_params_.sample_rate() / kAudioPacketsPerSecond) {
       continue;
     }

     std::unique_ptr<media::AudioBus> resampled_bus(media::AudioBus::Create(
         output_audio_params_.channels(),
         output_audio_params_.sample_rate() / kAudioPacketsPerSecond));
     audio_converter_->Convert(resampled_bus.get());
     audio_bus_queue_.push(resampled_bus.release());
   }
 }

 bool FakeMediaSource::OnNewAudioFrame(AVFrame* frame) {
   int frames_read = frame->nb_samples;
   if (frames_read < 0)
     return false;

   if (!audio_sent_ts_) {
     // Initialize the base time to the first packet in the file. This is set to
     // the frequency we send to the receiver. Not the frequency of the source
     // file. This is because we increment the frame count by samples we sent.
     audio_sent_ts_ = std::make_unique<AudioTimestampHelper>(
         output_audio_params_.sample_rate());
     // For some files this is an invalid value.
     base::TimeDelta base_ts;
     audio_sent_ts_->SetBaseTimestamp(base_ts);
   }

   scoped_refptr<AudioBuffer> buffer = AudioBuffer::CopyFrom(
       AVSampleFormatToSampleFormat(av_audio_context_->sample_fmt,
                                    av_audio_context_->codec_id),
       ChannelLayoutToChromeChannelLayout(av_audio_context_->channel_layout,
                                          av_audio_context_->channels),
       av_audio_context_->channels, av_audio_context_->sample_rate, frames_read,
       &frame->data[0],
       PtsToTimeDelta(frame->pts, av_audio_stream()->time_base));
   audio_algo_.EnqueueBuffer(buffer);
   return true;
 }

 void FakeMediaSource::DecodeVideo(ScopedAVPacket packet) {
   auto result = video_decoding_loop_->DecodePacket(
       packet.get(), base::BindRepeating(&FakeMediaSource::OnNewVideoFrame,
                                         base::Unretained(this)));
   CHECK_EQ(result, FFmpegDecodingLoop::DecodeStatus::kOkay)
       << "Failed to decode video.";
 }

 bool FakeMediaSource::OnNewVideoFrame(AVFrame* frame) {
   gfx::Size size(av_video_context_->width, av_video_context_->height);

   if (!video_first_pts_set_) {
     video_first_pts_ = frame->pts;
     video_first_pts_set_ = true;
   }
   const AVRational& time_base = av_video_stream()->time_base;
   base::TimeDelta timestamp =
       PtsToTimeDelta(frame->pts - video_first_pts_, time_base);
   if (timestamp < last_video_frame_timestamp_) {
     // Stream has rewound.  Rebase |video_first_pts_|.
     const AVRational& frame_rate = av_video_stream()->r_frame_rate;
     timestamp = last_video_frame_timestamp_ +
                 (base::Seconds(1) * frame_rate.den / frame_rate.num);
     const int64_t adjustment_pts = TimeDeltaToPts(timestamp, time_base);
     video_first_pts_ = frame->pts - adjustment_pts;
   }

   AVFrame* shallow_copy = av_frame_clone(frame);
   scoped_refptr<media::VideoFrame> video_frame =
       VideoFrame::WrapExternalYuvData(
           media::PIXEL_FORMAT_I420, size, gfx::Rect(size), size,
           shallow_copy->linesize[0], shallow_copy->linesize[1],
           shallow_copy->linesize[2], shallow_copy->data[0],
           shallow_copy->data[1], shallow_copy->data[2], timestamp);
   if (!video_frame)
     return false;
   video_frame_queue_.push(video_frame);
   video_frame_queue_.back()->AddDestructionObserver(
       base::BindOnce(&AVFreeFrame, shallow_copy));
   last_video_frame_timestamp_ = timestamp;
   return true;
 }

 void FakeMediaSource::Decode(bool decode_audio) {
   // Read the stream until one video frame can be decoded.
   while (true) {
     if (decode_audio && !audio_bus_queue_.empty())
       return;
     if (!decode_audio && !video_frame_queue_.empty())
       return;

     bool audio_packet = false;
     ScopedAVPacket packet = DemuxOnePacket(&audio_packet);
     if (!packet) {
       VLOG(1) << "End of stream.";
       return;
     }

     if (audio_packet)
       DecodeAudio(std::move(packet));
     else
       DecodeVideo(std::move(packet));
   }
 }

 double FakeMediaSource::ProvideInput(media::AudioBus* output_bus,
                                      uint32_t frames_delayed) {
   if (audio_fifo_->frames() >= output_bus->frames()) {
     audio_fifo_->Consume(output_bus, 0, output_bus->frames());
     return 1.0;
   } else {
     LOG(WARNING) << "Not enough audio data for resampling.";
     output_bus->Zero();
     return 0.0;
   }
 }

 scoped_refptr<media::VideoFrame>
 FakeMediaSource::PopOldestInsertedVideoFrame() {
   CHECK(!inserted_video_frame_queue_.empty());
   scoped_refptr<media::VideoFrame> video_frame =
       inserted_video_frame_queue_.front();
   inserted_video_frame_queue_.pop();
   return video_frame;
 }

 AVStream* FakeMediaSource::av_audio_stream() {
   return av_format_context_->streams[audio_stream_index_];
 }

 AVStream* FakeMediaSource::av_video_stream() {
   return av_format_context_->streams[video_stream_index_];
 }

 }  // namespace cast
 }  // namespace media
	// Copyright 2014 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/cast/test/fake_media_source.h"

	#include <memory>
	#include <utility>

	#include "base/bind.h"
	#include "base/files/scoped_file.h"
	#include "base/logging.h"
	#include "base/rand_util.h"
	#include "base/strings/string_number_conversions.h"
	#include "build/build_config.h"
	#include "media/base/audio_buffer.h"
	#include "media/base/audio_bus.h"
	#include "media/base/audio_fifo.h"
	#include "media/base/audio_timestamp_helper.h"
	#include "media/base/media.h"
	#include "media/base/video_frame.h"
	#include "media/base/video_util.h"
	#include "media/cast/cast_sender.h"
	#include "media/cast/test/utility/audio_utility.h"
	#include "media/cast/test/utility/video_utility.h"
	#include "ui/gfx/geometry/size.h"

	// TODO(miu): Figure out why _mkdir() and _rmdir() are missing when compiling
	// third_party/ffmpeg/libavformat/os_support.h (lines 182, 183).
	// http://crbug.com/572986
	#if defined(OS_WIN)
	#include <direct.h>
	#endif // defined(OS_WIN)
	#include "media/ffmpeg/ffmpeg_common.h"
	#include "media/ffmpeg/ffmpeg_decoding_loop.h"
	#include "media/ffmpeg/ffmpeg_deleters.h"
	#include "media/filters/ffmpeg_glue.h"
	#include "media/filters/in_memory_url_protocol.h"

	namespace {

	static const int kSoundFrequency = 440; // Frequency of sinusoid wave.
	static const float kSoundVolume = 0.10f;
	static const int kAudioFrameMs = 10; // Each audio frame is exactly 10ms.
	static const int kAudioPacketsPerSecond = 1000 / kAudioFrameMs;

	// Bounds for variable frame size mode.
	static const int kMinFakeFrameWidth = 60;
	static const int kMinFakeFrameHeight = 34;
	static const int kStartingFakeFrameWidth = 854;
	static const int kStartingFakeFrameHeight = 480;
	static const int kMaxFakeFrameWidth = 1280;
	static const int kMaxFakeFrameHeight = 720;
	static const int kMaxFrameSizeChangeMillis = 5000;

	void AVFreeFrame(AVFrame* frame) {
	av_frame_free(&frame);
	}

	base::TimeDelta PtsToTimeDelta(int64_t pts, const AVRational& time_base) {
	return pts * base::Seconds(1) * time_base.num / time_base.den;
	}

	int64_t TimeDeltaToPts(base::TimeDelta delta, const AVRational& time_base) {
	return static_cast<int64_t>(
	delta.InSecondsF() * time_base.den / time_base.num + 0.5 /* rounding */);
	}

	} // namespace

	namespace media {
	namespace cast {

	FakeMediaSource::FakeMediaSource(
	scoped_refptr<base::SingleThreadTaskRunner> task_runner,
	const base::TickClock* clock,
	const FrameSenderConfig& audio_config,
	const FrameSenderConfig& video_config,
	bool keep_frames)
	: task_runner_(task_runner),
	output_audio_params_(AudioParameters::AUDIO_PCM_LINEAR,
	media::GuessChannelLayout(audio_config.channels),
	audio_config.rtp_timebase,
	audio_config.rtp_timebase / kAudioPacketsPerSecond),
	video_config_(video_config),
	keep_frames_(keep_frames),
	variable_frame_size_mode_(false),
	synthetic_count_(0),
	clock_(clock),
	audio_frame_count_(0),
	video_frame_count_(0),
	av_format_context_(nullptr),
	audio_stream_index_(-1),
	playback_rate_(1.0),
	video_stream_index_(-1),
	video_frame_rate_numerator_(video_config.max_frame_rate),
	video_frame_rate_denominator_(1),
	audio_algo_(&media_log_),
	video_first_pts_(0),
	video_first_pts_set_(false) {
	CHECK(output_audio_params_.IsValid());
	audio_bus_factory_ = std::make_unique<TestAudioBusFactory>(
	audio_config.channels, audio_config.rtp_timebase, kSoundFrequency,
	kSoundVolume);
	}

	FakeMediaSource::~FakeMediaSource() = default;

	void FakeMediaSource::SetSourceFile(const base::FilePath& video_file,
	int final_fps) {
	DCHECK(!video_file.empty());

	LOG(INFO) << "Source: " << video_file.value();
	if (!file_data_.Initialize(video_file)) {
	LOG(ERROR) << "Cannot load file.";
	return;
	}
	protocol_ = std::make_unique<InMemoryUrlProtocol>(file_data_.data(),
	file_data_.length(), false);
	glue_ = std::make_unique<FFmpegGlue>(protocol_.get());

	if (!glue_->OpenContext()) {
	LOG(ERROR) << "Cannot open file.";
	return;
	}

	// AVFormatContext is owned by the glue.
	av_format_context_ = glue_->format_context();
	if (avformat_find_stream_info(av_format_context_, NULL) < 0) {
	LOG(ERROR) << "Cannot find stream information.";
	return;
	}

	// Prepare FFmpeg decoders.
	for (unsigned int i = 0; i < av_format_context_->nb_streams; ++i) {
	AVStream* av_stream = av_format_context_->streams[i];
	std::unique_ptr<AVCodecContext, ScopedPtrAVFreeContext> av_codec_context(
	AVStreamToAVCodecContext(av_stream));
	if (!av_codec_context) {
	LOG(ERROR) << "Cannot get a codec context for the codec: "
	<< av_stream->codecpar->codec_id;
	continue;
	}

	const AVCodec* av_codec = avcodec_find_decoder(av_codec_context->codec_id);

	if (!av_codec) {
	LOG(ERROR) << "Cannot find decoder for the codec: "
	<< av_codec_context->codec_id;
	continue;
	}

	// Number of threads for decoding.
	av_codec_context->thread_count = 2;
	av_codec_context->error_concealment = FF_EC_GUESS_MVS \| FF_EC_DEBLOCK;
	av_codec_context->request_sample_fmt = AV_SAMPLE_FMT_S16;

	if (avcodec_open2(av_codec_context.get(), av_codec, nullptr) < 0) {
	LOG(ERROR) << "Cannot open AVCodecContext for the codec: "
	<< av_codec_context->codec_id;
	return;
	}

	if (av_codec->type == AVMEDIA_TYPE_AUDIO) {
	if (av_codec_context->sample_fmt == AV_SAMPLE_FMT_S16P) {
	LOG(ERROR) << "Audio format not supported.";
	continue;
	}
	ChannelLayout layout = ChannelLayoutToChromeChannelLayout(
	av_codec_context->channel_layout,
	av_codec_context->channels);
	if (layout == CHANNEL_LAYOUT_UNSUPPORTED) {
	LOG(ERROR) << "Unsupported audio channels layout.";
	continue;
	}
	if (audio_stream_index_ != -1) {
	LOG(WARNING) << "Found multiple audio streams.";
	}
	audio_stream_index_ = static_cast<int>(i);
	av_audio_context_ = std::move(av_codec_context);
	source_audio_params_.Reset(
	AudioParameters::AUDIO_PCM_LINEAR, layout,
	av_audio_context_->sample_rate,
	av_audio_context_->sample_rate / kAudioPacketsPerSecond);
	source_audio_params_.set_channels_for_discrete(
	av_audio_context_->channels);
	CHECK(source_audio_params_.IsValid());
	LOG(INFO) << "Source file has audio.";
	audio_decoding_loop_ =
	std::make_unique<FFmpegDecodingLoop>(av_audio_context_.get());
	} else if (av_codec->type == AVMEDIA_TYPE_VIDEO) {
	VideoPixelFormat format =
	AVPixelFormatToVideoPixelFormat(av_codec_context->pix_fmt);
	if (format != PIXEL_FORMAT_I420) {
	LOG(ERROR) << "Cannot handle non YV12 video format: " << format;
	continue;
	}
	if (video_stream_index_ != -1) {
	LOG(WARNING) << "Found multiple video streams.";
	}
	video_stream_index_ = static_cast<int>(i);
	av_video_context_ = std::move(av_codec_context);
	video_decoding_loop_ =
	std::make_unique<FFmpegDecodingLoop>(av_video_context_.get());
	if (final_fps > 0) {
	// If video is played at a manual speed audio needs to match.
	playback_rate_ = 1.0 * final_fps *
	av_stream->r_frame_rate.den / av_stream->r_frame_rate.num;
	video_frame_rate_numerator_ = final_fps;
	video_frame_rate_denominator_ = 1;
	} else {
	playback_rate_ = 1.0;
	video_frame_rate_numerator_ = av_stream->r_frame_rate.num;
	video_frame_rate_denominator_ = av_stream->r_frame_rate.den;
	}
	LOG(INFO) << "Source file has video.";
	} else {
	LOG(ERROR) << "Unknown stream type; ignore.";
	}
	}

	Rewind();
	}

	void FakeMediaSource::SetVariableFrameSizeMode(bool enabled) {
	variable_frame_size_mode_ = enabled;
	}

	void FakeMediaSource::Start(scoped_refptr<AudioFrameInput> audio_frame_input,
	scoped_refptr<VideoFrameInput> video_frame_input) {
	audio_frame_input_ = audio_frame_input;
	video_frame_input_ = video_frame_input;

	LOG(INFO) << "Max Frame rate: " << video_config_.max_frame_rate;
	LOG(INFO) << "Source Frame rate: "
	<< video_frame_rate_numerator_ << "/"
	<< video_frame_rate_denominator_ << " fps.";
	LOG(INFO) << "Audio playback rate: " << playback_rate_;

	if (start_time_.is_null())
	start_time_ = clock_->NowTicks();

	if (!is_transcoding_audio() && !is_transcoding_video()) {
	// Send fake patterns.
	task_runner_->PostTask(FROM_HERE,
	base::BindOnce(&FakeMediaSource::SendNextFakeFrame,
	weak_factory_.GetWeakPtr()));
	return;
	}

	// Send transcoding streams.
	bool is_encrypted = false;
	audio_algo_.Initialize(source_audio_params_, is_encrypted);
	audio_algo_.FlushBuffers();
	audio_fifo_input_bus_ = AudioBus::Create(
	source_audio_params_.channels(),
	source_audio_params_.frames_per_buffer());
	// Audio FIFO can carry all data fron AudioRendererAlgorithm.
	audio_fifo_ = std::make_unique<AudioFifo>(source_audio_params_.channels(),
	audio_algo_.QueueCapacity());
	audio_converter_ = std::make_unique<media::AudioConverter>(
	source_audio_params_, output_audio_params_, true);
	audio_converter_->AddInput(this);
	task_runner_->PostTask(FROM_HERE,
	base::BindOnce(&FakeMediaSource::SendNextFrame,
	weak_factory_.GetWeakPtr()));
	}

	void FakeMediaSource::SendNextFakeFrame() {
	UpdateNextFrameSize();
	scoped_refptr<VideoFrame> video_frame =
	VideoFrame::CreateBlackFrame(current_frame_size_);
	PopulateVideoFrame(video_frame.get(), synthetic_count_);
	++synthetic_count_;

	const base::TimeTicks now = clock_->NowTicks();

	base::TimeDelta video_time = VideoFrameTime(++video_frame_count_);
	video_frame->set_timestamp(video_time);
	if (keep_frames_)
	inserted_video_frame_queue_.push(video_frame);
	video_frame_input_->InsertRawVideoFrame(video_frame,
	start_time_ + video_time);

	// Send just enough audio data to match next video frame's time.
	base::TimeDelta audio_time = AudioFrameTime(audio_frame_count_);
	while (audio_time < video_time) {
	if (is_transcoding_audio()) {
	Decode(true);
	CHECK(!audio_bus_queue_.empty()) << "No audio decoded.";
	std::unique_ptr<AudioBus> bus(audio_bus_queue_.front());
	audio_bus_queue_.pop();
	audio_frame_input_->InsertAudio(std::move(bus), start_time_ + audio_time);
	} else {
	audio_frame_input_->InsertAudio(
	audio_bus_factory_->NextAudioBus(base::Milliseconds(kAudioFrameMs)),
	start_time_ + audio_time);
	}
	audio_time = AudioFrameTime(++audio_frame_count_);
	}

	// This is the time since FakeMediaSource was started.
	const base::TimeDelta elapsed_time = now - start_time_;

	// Handle the case when frame generation cannot keep up.
	// Move the time ahead to match the next frame.
	while (video_time < elapsed_time) {
	LOG(WARNING) << "Skipping one frame.";
	video_time = VideoFrameTime(++video_frame_count_);
	}

	task_runner_->PostDelayedTask(
	FROM_HERE,
	base::BindOnce(&FakeMediaSource::SendNextFakeFrame,
	weak_factory_.GetWeakPtr()),
	video_time - elapsed_time);
	}

	void FakeMediaSource::UpdateNextFrameSize() {
	if (variable_frame_size_mode_) {
	bool update_size_change_time = false;
	if (current_frame_size_.IsEmpty()) {
	current_frame_size_ = gfx::Size(kStartingFakeFrameWidth,
	kStartingFakeFrameHeight);
	update_size_change_time = true;
	} else if (clock_->NowTicks() >= next_frame_size_change_time_) {
	current_frame_size_ = gfx::Size(
	base::RandInt(kMinFakeFrameWidth, kMaxFakeFrameWidth),
	base::RandInt(kMinFakeFrameHeight, kMaxFakeFrameHeight));
	update_size_change_time = true;
	}

	if (update_size_change_time) {
	next_frame_size_change_time_ =
	clock_->NowTicks() +
	base::Milliseconds(base::RandDouble() * kMaxFrameSizeChangeMillis);
	}
	} else {
	current_frame_size_ = gfx::Size(kStartingFakeFrameWidth,
	kStartingFakeFrameHeight);
	next_frame_size_change_time_ = base::TimeTicks();
	}
	}

	bool FakeMediaSource::SendNextTranscodedVideo(base::TimeDelta elapsed_time) {
	if (!is_transcoding_video())
	return false;

	Decode(false);
	if (video_frame_queue_.empty())
	return false;

	const scoped_refptr<VideoFrame> video_frame = video_frame_queue_.front();
	if (elapsed_time < video_frame->timestamp())
	return false;
	video_frame_queue_.pop();

	// Use the timestamp from the file if we're transcoding.
	video_frame->set_timestamp(ScaleTimestamp(video_frame->timestamp()));
	if (keep_frames_)
	inserted_video_frame_queue_.push(video_frame);
	video_frame_input_->InsertRawVideoFrame(
	video_frame, start_time_ + video_frame->timestamp());

	// Make sure queue is not empty.
	Decode(false);
	return true;
	}

	bool FakeMediaSource::SendNextTranscodedAudio(base::TimeDelta elapsed_time) {
	if (!is_transcoding_audio())
	return false;

	Decode(true);
	if (audio_bus_queue_.empty())
	return false;

	base::TimeDelta audio_time = audio_sent_ts_->GetTimestamp();
	if (elapsed_time < audio_time)
	return false;
	std::unique_ptr<AudioBus> bus(audio_bus_queue_.front());
	audio_bus_queue_.pop();
	audio_sent_ts_->AddFrames(bus->frames());
	audio_frame_input_->InsertAudio(std::move(bus), start_time_ + audio_time);

	// Make sure queue is not empty.
	Decode(true);
	return true;
	}

	void FakeMediaSource::SendNextFrame() {
	// Send as much as possible. Audio is sent according to
	// system time.
	while (SendNextTranscodedAudio(clock_->NowTicks() - start_time_)) {
	}

	// Video is sync'ed to audio.
	while (SendNextTranscodedVideo(audio_sent_ts_->GetTimestamp())) {
	}

	if (audio_bus_queue_.empty() && video_frame_queue_.empty()) {
	// Both queues are empty can only mean that we have reached
	// the end of the stream.
	LOG(INFO) << "Rewind.";
	Rewind();
	}

	// Send next send.
	task_runner_->PostDelayedTask(FROM_HERE,
	base::BindOnce(&FakeMediaSource::SendNextFrame,
	weak_factory_.GetWeakPtr()),
	base::Milliseconds(kAudioFrameMs));
	}

	base::TimeDelta FakeMediaSource::VideoFrameTime(int frame_number) {
	return frame_number * base::Seconds(1) * video_frame_rate_denominator_ /
	video_frame_rate_numerator_;
	}

	base::TimeDelta FakeMediaSource::ScaleTimestamp(base::TimeDelta timestamp) {
	return timestamp / playback_rate_;
	}

	base::TimeDelta FakeMediaSource::AudioFrameTime(int frame_number) {
	return frame_number * base::Milliseconds(kAudioFrameMs);
	}

	void FakeMediaSource::Rewind() {
	CHECK(av_seek_frame(av_format_context_, -1, 0, AVSEEK_FLAG_BACKWARD) >= 0)
	<< "Failed to rewind to the beginning.";
	}

	ScopedAVPacket FakeMediaSource::DemuxOnePacket(bool* audio) {
	ScopedAVPacket packet = MakeScopedAVPacket();
	if (av_read_frame(av_format_context_, packet.get()) < 0) {
	VLOG(1) << "Failed to read one AVPacket.";
	packet.reset();
	return packet;
	}

	int stream_index = static_cast<int>(packet->stream_index);
	if (stream_index == audio_stream_index_) {
	*audio = true;
	} else if (stream_index == video_stream_index_) {
	*audio = false;
	} else {
	// Ignore unknown packet.
	LOG(INFO) << "Unknown packet.";
	packet.reset();
	}
	return packet;
	}

	void FakeMediaSource::DecodeAudio(ScopedAVPacket packet) {
	auto result = audio_decoding_loop_->DecodePacket(
	packet.get(), base::BindRepeating(&FakeMediaSource::OnNewAudioFrame,
	base::Unretained(this)));
	CHECK_EQ(result, FFmpegDecodingLoop::DecodeStatus::kOkay)
	<< "Failed to decode audio.";

	const int frames_needed_to_scale =
	playback_rate_ * av_audio_context_->sample_rate / kAudioPacketsPerSecond;
	while (frames_needed_to_scale <= audio_algo_.BufferedFrames()) {
	if (!audio_algo_.FillBuffer(audio_fifo_input_bus_.get(), 0,
	audio_fifo_input_bus_->frames(),
	playback_rate_)) {
	// Nothing can be scaled. Decode some more.
	return;
	}

	// Prevent overflow of audio data in the FIFO.
	if (audio_fifo_input_bus_->frames() + audio_fifo_->frames() <=
	audio_fifo_->max_frames()) {
	audio_fifo_->Push(audio_fifo_input_bus_.get());
	} else {
	LOG(WARNING) << "Audio FIFO full; dropping samples.";
	}

	// Make sure there's enough data to resample audio.
	if (audio_fifo_->frames() <
	2 * source_audio_params_.sample_rate() / kAudioPacketsPerSecond) {
	continue;
	}

	std::unique_ptr<media::AudioBus> resampled_bus(media::AudioBus::Create(
	output_audio_params_.channels(),
	output_audio_params_.sample_rate() / kAudioPacketsPerSecond));
	audio_converter_->Convert(resampled_bus.get());
	audio_bus_queue_.push(resampled_bus.release());
	}
	}

	bool FakeMediaSource::OnNewAudioFrame(AVFrame* frame) {
	int frames_read = frame->nb_samples;
	if (frames_read < 0)
	return false;

	if (!audio_sent_ts_) {
	// Initialize the base time to the first packet in the file. This is set to
	// the frequency we send to the receiver. Not the frequency of the source
	// file. This is because we increment the frame count by samples we sent.
	audio_sent_ts_ = std::make_unique<AudioTimestampHelper>(
	output_audio_params_.sample_rate());
	// For some files this is an invalid value.
	base::TimeDelta base_ts;
	audio_sent_ts_->SetBaseTimestamp(base_ts);
	}

	scoped_refptr<AudioBuffer> buffer = AudioBuffer::CopyFrom(
	AVSampleFormatToSampleFormat(av_audio_context_->sample_fmt,
	av_audio_context_->codec_id),
	ChannelLayoutToChromeChannelLayout(av_audio_context_->channel_layout,
	av_audio_context_->channels),
	av_audio_context_->channels, av_audio_context_->sample_rate, frames_read,
	&frame->data[0],
	PtsToTimeDelta(frame->pts, av_audio_stream()->time_base));
	audio_algo_.EnqueueBuffer(buffer);
	return true;
	}

	void FakeMediaSource::DecodeVideo(ScopedAVPacket packet) {
	auto result = video_decoding_loop_->DecodePacket(
	packet.get(), base::BindRepeating(&FakeMediaSource::OnNewVideoFrame,
	base::Unretained(this)));
	CHECK_EQ(result, FFmpegDecodingLoop::DecodeStatus::kOkay)
	<< "Failed to decode video.";
	}

	bool FakeMediaSource::OnNewVideoFrame(AVFrame* frame) {
	gfx::Size size(av_video_context_->width, av_video_context_->height);

	if (!video_first_pts_set_) {
	video_first_pts_ = frame->pts;
	video_first_pts_set_ = true;
	}
	const AVRational& time_base = av_video_stream()->time_base;
	base::TimeDelta timestamp =
	PtsToTimeDelta(frame->pts - video_first_pts_, time_base);
	if (timestamp < last_video_frame_timestamp_) {
	// Stream has rewound. Rebase \|video_first_pts_\|.
	const AVRational& frame_rate = av_video_stream()->r_frame_rate;
	timestamp = last_video_frame_timestamp_ +
	(base::Seconds(1) * frame_rate.den / frame_rate.num);
	const int64_t adjustment_pts = TimeDeltaToPts(timestamp, time_base);
	video_first_pts_ = frame->pts - adjustment_pts;
	}

	AVFrame* shallow_copy = av_frame_clone(frame);
	scoped_refptr<media::VideoFrame> video_frame =
	VideoFrame::WrapExternalYuvData(
	media::PIXEL_FORMAT_I420, size, gfx::Rect(size), size,
	shallow_copy->linesize[0], shallow_copy->linesize[1],
	shallow_copy->linesize[2], shallow_copy->data[0],
	shallow_copy->data[1], shallow_copy->data[2], timestamp);
	if (!video_frame)
	return false;
	video_frame_queue_.push(video_frame);
	video_frame_queue_.back()->AddDestructionObserver(
	base::BindOnce(&AVFreeFrame, shallow_copy));
	last_video_frame_timestamp_ = timestamp;
	return true;
	}

	void FakeMediaSource::Decode(bool decode_audio) {
	// Read the stream until one video frame can be decoded.
	while (true) {
	if (decode_audio && !audio_bus_queue_.empty())
	return;
	if (!decode_audio && !video_frame_queue_.empty())
	return;

	bool audio_packet = false;
	ScopedAVPacket packet = DemuxOnePacket(&audio_packet);
	if (!packet) {
	VLOG(1) << "End of stream.";
	return;
	}

	if (audio_packet)
	DecodeAudio(std::move(packet));
	else
	DecodeVideo(std::move(packet));
	}
	}

	double FakeMediaSource::ProvideInput(media::AudioBus* output_bus,
	uint32_t frames_delayed) {
	if (audio_fifo_->frames() >= output_bus->frames()) {
	audio_fifo_->Consume(output_bus, 0, output_bus->frames());
	return 1.0;
	} else {
	LOG(WARNING) << "Not enough audio data for resampling.";
	output_bus->Zero();
	return 0.0;
	}
	}

	scoped_refptr<media::VideoFrame>
	FakeMediaSource::PopOldestInsertedVideoFrame() {
	CHECK(!inserted_video_frame_queue_.empty());
	scoped_refptr<media::VideoFrame> video_frame =
	inserted_video_frame_queue_.front();
	inserted_video_frame_queue_.pop();
	return video_frame;
	}

	AVStream* FakeMediaSource::av_audio_stream() {
	return av_format_context_->streams[audio_stream_index_];
	}

	AVStream* FakeMediaSource::av_video_stream() {
	return av_format_context_->streams[video_stream_index_];
	}

	} // namespace cast
	} // namespace media