modules/video_coding/codecs/test/videoprocessor.cc - src - Git at Google

 /*
  *  Copyright (c) 2012 The WebRTC project authors. All Rights Reserved.
  *
  *  Use of this source code is governed by a BSD-style license
  *  that can be found in the LICENSE file in the root of the source
  *  tree. An additional intellectual property rights grant can be found
  *  in the file PATENTS.  All contributing project authors may
  *  be found in the AUTHORS file in the root of the source tree.
  */

 #include "modules/video_coding/codecs/test/videoprocessor.h"

 #include <algorithm>
 #include <limits>
 #include <utility>

 #include "api/video/i420_buffer.h"
 #include "common_types.h"  // NOLINT(build/include)
 #include "common_video/h264/h264_common.h"
 #include "modules/video_coding/codecs/vp8/simulcast_rate_allocator.h"
 #include "modules/video_coding/include/video_codec_initializer.h"
 #include "modules/video_coding/utility/default_video_bitrate_allocator.h"
 #include "rtc_base/checks.h"
 #include "rtc_base/timeutils.h"
 #include "test/gtest.h"

 namespace webrtc {
 namespace test {

 namespace {

 const int kRtpClockRateHz = 90000;
 const int64_t kNoRenderTime = 0;

 std::unique_ptr<VideoBitrateAllocator> CreateBitrateAllocator(
     TestConfig* config) {
   std::unique_ptr<TemporalLayersFactory> tl_factory;
   if (config->codec_settings.codecType == VideoCodecType::kVideoCodecVP8) {
     tl_factory.reset(new TemporalLayersFactory());
     config->codec_settings.VP8()->tl_factory = tl_factory.get();
   }
   return std::unique_ptr<VideoBitrateAllocator>(
       VideoCodecInitializer::CreateBitrateAllocator(config->codec_settings,
                                                     std::move(tl_factory)));
 }

 rtc::Optional<size_t> GetMaxNaluLength(const EncodedImage& encoded_frame,
                                        const TestConfig& config) {
   if (config.codec_settings.codecType != kVideoCodecH264)
     return rtc::nullopt;

   std::vector<webrtc::H264::NaluIndex> nalu_indices =
       webrtc::H264::FindNaluIndices(encoded_frame._buffer,
                                     encoded_frame._length);

   RTC_CHECK(!nalu_indices.empty());

   size_t max_length = 0;
   for (const webrtc::H264::NaluIndex& index : nalu_indices)
     max_length = std::max(max_length, index.payload_size);

   return max_length;
 }

 int GetElapsedTimeMicroseconds(int64_t start_ns, int64_t stop_ns) {
   int64_t diff_us = (stop_ns - start_ns) / rtc::kNumNanosecsPerMicrosec;
   RTC_DCHECK_GE(diff_us, std::numeric_limits<int>::min());
   RTC_DCHECK_LE(diff_us, std::numeric_limits<int>::max());
   return static_cast<int>(diff_us);
 }

 void ExtractBufferWithSize(const VideoFrame& image,
                            int width,
                            int height,
                            rtc::Buffer* buffer) {
   if (image.width() != width || image.height() != height) {
     EXPECT_DOUBLE_EQ(static_cast<double>(width) / height,
                      static_cast<double>(image.width()) / image.height());
     // Same aspect ratio, no cropping needed.
     rtc::scoped_refptr<I420Buffer> scaled(I420Buffer::Create(width, height));
     scaled->ScaleFrom(*image.video_frame_buffer()->ToI420());

     size_t length =
         CalcBufferSize(VideoType::kI420, scaled->width(), scaled->height());
     buffer->SetSize(length);
     RTC_CHECK_NE(ExtractBuffer(scaled, length, buffer->data()), -1);
     return;
   }

   // No resize.
   size_t length =
       CalcBufferSize(VideoType::kI420, image.width(), image.height());
   buffer->SetSize(length);
   RTC_CHECK_NE(ExtractBuffer(image, length, buffer->data()), -1);
 }

 }  // namespace

 VideoProcessor::VideoProcessor(webrtc::VideoEncoder* encoder,
                                webrtc::VideoDecoder* decoder,
                                FrameReader* analysis_frame_reader,
                                PacketManipulator* packet_manipulator,
                                const TestConfig& config,
                                Stats* stats,
                                IvfFileWriter* encoded_frame_writer,
                                FrameWriter* decoded_frame_writer)
     : config_(config),
       encoder_(encoder),
       decoder_(decoder),
       bitrate_allocator_(CreateBitrateAllocator(&config_)),
       encode_callback_(this),
       decode_callback_(this),
       packet_manipulator_(packet_manipulator),
       analysis_frame_reader_(analysis_frame_reader),
       encoded_frame_writer_(encoded_frame_writer),
       decoded_frame_writer_(decoded_frame_writer),
       last_inputed_frame_num_(-1),
       last_encoded_frame_num_(-1),
       last_decoded_frame_num_(-1),
       first_key_frame_has_been_excluded_(false),
       last_decoded_frame_buffer_(analysis_frame_reader->FrameLength()),
       stats_(stats),
       rate_update_index_(-1) {
   RTC_DCHECK(encoder);
   RTC_DCHECK(decoder);
   RTC_DCHECK(packet_manipulator);
   RTC_DCHECK(analysis_frame_reader);
   RTC_DCHECK(stats);

   // Setup required callbacks for the encoder and decoder.
   RTC_CHECK_EQ(encoder_->RegisterEncodeCompleteCallback(&encode_callback_),
                WEBRTC_VIDEO_CODEC_OK);
   RTC_CHECK_EQ(decoder_->RegisterDecodeCompleteCallback(&decode_callback_),
                WEBRTC_VIDEO_CODEC_OK);

   // Initialize the encoder and decoder.
   RTC_CHECK_EQ(
       encoder_->InitEncode(&config_.codec_settings, config_.NumberOfCores(),
                            config_.networking_config.max_payload_size_in_bytes),
       WEBRTC_VIDEO_CODEC_OK);
   RTC_CHECK_EQ(
       decoder_->InitDecode(&config_.codec_settings, config_.NumberOfCores()),
       WEBRTC_VIDEO_CODEC_OK);
 }

 VideoProcessor::~VideoProcessor() {
   RTC_DCHECK_CALLED_SEQUENTIALLY(&sequence_checker_);

   RTC_CHECK_EQ(encoder_->Release(), WEBRTC_VIDEO_CODEC_OK);
   RTC_CHECK_EQ(decoder_->Release(), WEBRTC_VIDEO_CODEC_OK);

   encoder_->RegisterEncodeCompleteCallback(nullptr);
   decoder_->RegisterDecodeCompleteCallback(nullptr);
 }

 void VideoProcessor::ProcessFrame() {
   RTC_DCHECK_CALLED_SEQUENTIALLY(&sequence_checker_);
   const int frame_number = ++last_inputed_frame_num_;

   // Get frame from file.
   rtc::scoped_refptr<I420BufferInterface> buffer(
       analysis_frame_reader_->ReadFrame());
   RTC_CHECK(buffer) << "Tried to read too many frames from the file.";
   // Use the frame number as the basis for timestamp to identify frames. Let the
   // first timestamp be non-zero, to not make the IvfFileWriter believe that we
   // want to use capture timestamps in the IVF files.
   const uint32_t rtp_timestamp = (frame_number + 1) * kRtpClockRateHz /
                                  config_.codec_settings.maxFramerate;
   rtp_timestamp_to_frame_num_[rtp_timestamp] = frame_number;
   input_frames_[frame_number] = rtc::MakeUnique<VideoFrame>(
       buffer, rtp_timestamp, kNoRenderTime, webrtc::kVideoRotation_0);

   std::vector<FrameType> frame_types = config_.FrameTypeForFrame(frame_number);

   // Create frame statistics object used for aggregation at end of test run.
   FrameStatistic* frame_stat = stats_->AddFrame();

   // For the highest measurement accuracy of the encode time, the start/stop
   // time recordings should wrap the Encode call as tightly as possible.
   frame_stat->encode_start_ns = rtc::TimeNanos();
   frame_stat->encode_return_code =
       encoder_->Encode(*input_frames_[frame_number], nullptr, &frame_types);
 }

 void VideoProcessor::SetRates(int bitrate_kbps, int framerate_fps) {
   RTC_DCHECK_CALLED_SEQUENTIALLY(&sequence_checker_);
   config_.codec_settings.maxFramerate = framerate_fps;
   int set_rates_result = encoder_->SetRateAllocation(
       bitrate_allocator_->GetAllocation(bitrate_kbps * 1000, framerate_fps),
       framerate_fps);
   RTC_DCHECK_GE(set_rates_result, 0)
       << "Failed to update encoder with new rate " << bitrate_kbps << ".";
   ++rate_update_index_;
   num_dropped_frames_.push_back(0);
   num_spatial_resizes_.push_back(0);
 }

 std::vector<int> VideoProcessor::NumberDroppedFramesPerRateUpdate() const {
   RTC_DCHECK_CALLED_SEQUENTIALLY(&sequence_checker_);
   return num_dropped_frames_;
 }

 std::vector<int> VideoProcessor::NumberSpatialResizesPerRateUpdate() const {
   RTC_DCHECK_CALLED_SEQUENTIALLY(&sequence_checker_);
   return num_spatial_resizes_;
 }

 void VideoProcessor::FrameEncoded(webrtc::VideoCodecType codec,
                                   const EncodedImage& encoded_image) {
   RTC_DCHECK_CALLED_SEQUENTIALLY(&sequence_checker_);

   // For the highest measurement accuracy of the encode time, the start/stop
   // time recordings should wrap the Encode call as tightly as possible.
   int64_t encode_stop_ns = rtc::TimeNanos();

   if (config_.encoded_frame_checker) {
     config_.encoded_frame_checker->CheckEncodedFrame(codec, encoded_image);
   }

   const int frame_number =
       rtp_timestamp_to_frame_num_[encoded_image._timeStamp];

   // Ensure strict monotonicity.
   RTC_CHECK_GT(frame_number, last_encoded_frame_num_);

   // Check for dropped frames.
   bool last_frame_missing = false;
   if (frame_number > 0) {
     int num_dropped_from_last_encode =
         frame_number - last_encoded_frame_num_ - 1;
     RTC_DCHECK_GE(num_dropped_from_last_encode, 0);
     RTC_CHECK_GE(rate_update_index_, 0);
     num_dropped_frames_[rate_update_index_] += num_dropped_from_last_encode;
     const FrameStatistic* last_encoded_frame_stat =
         stats_->GetFrame(last_encoded_frame_num_);
     last_frame_missing = (last_encoded_frame_stat->manipulated_length == 0);
   }
   last_encoded_frame_num_ = frame_number;

   // Update frame statistics.
   FrameStatistic* frame_stat = stats_->GetFrame(frame_number);
   frame_stat->encode_time_us =
       GetElapsedTimeMicroseconds(frame_stat->encode_start_ns, encode_stop_ns);
   frame_stat->encoding_successful = true;
   frame_stat->encoded_frame_size_bytes = encoded_image._length;
   frame_stat->frame_type = encoded_image._frameType;
   frame_stat->qp = encoded_image.qp_;
   frame_stat->bitrate_kbps = static_cast<int>(
       encoded_image._length * config_.codec_settings.maxFramerate * 8 / 1000);
   frame_stat->total_packets =
       encoded_image._length / config_.networking_config.packet_size_in_bytes +
       1;
   frame_stat->max_nalu_length = GetMaxNaluLength(encoded_image, config_);

   // Make a raw copy of |encoded_image| to feed to the decoder.
   size_t copied_buffer_size = encoded_image._length +
                               EncodedImage::GetBufferPaddingBytes(codec);
   std::unique_ptr<uint8_t[]> copied_buffer(new uint8_t[copied_buffer_size]);
   memcpy(copied_buffer.get(), encoded_image._buffer, encoded_image._length);
   EncodedImage copied_image = encoded_image;
   copied_image._size = copied_buffer_size;
   copied_image._buffer = copied_buffer.get();

   // Simulate packet loss.
   if (!ExcludeFrame(copied_image)) {
     frame_stat->packets_dropped =
         packet_manipulator_->ManipulatePackets(&copied_image);
   }
   frame_stat->manipulated_length = copied_image._length;

   // For the highest measurement accuracy of the decode time, the start/stop
   // time recordings should wrap the Decode call as tightly as possible.
   frame_stat->decode_start_ns = rtc::TimeNanos();
   frame_stat->decode_return_code =
       decoder_->Decode(copied_image, last_frame_missing, nullptr);

   if (encoded_frame_writer_) {
     RTC_CHECK(encoded_frame_writer_->WriteFrame(encoded_image, codec));
   }
 }

 void VideoProcessor::FrameDecoded(const VideoFrame& decoded_frame) {
   RTC_DCHECK_CALLED_SEQUENTIALLY(&sequence_checker_);

   // For the highest measurement accuracy of the decode time, the start/stop
   // time recordings should wrap the Decode call as tightly as possible.
   int64_t decode_stop_ns = rtc::TimeNanos();

   // Update frame statistics.
   const int frame_number =
       rtp_timestamp_to_frame_num_[decoded_frame.timestamp()];
   FrameStatistic* frame_stat = stats_->GetFrame(frame_number);
   frame_stat->decoded_width = decoded_frame.width();
   frame_stat->decoded_height = decoded_frame.height();
   frame_stat->decode_time_us =
       GetElapsedTimeMicroseconds(frame_stat->decode_start_ns, decode_stop_ns);
   frame_stat->decoding_successful = true;

   // Ensure strict monotonicity.
   RTC_CHECK_GT(frame_number, last_decoded_frame_num_);

   // Check if the codecs have resized the frame since previously decoded frame.
   if (frame_number > 0) {
     if (decoded_frame_writer_ && last_decoded_frame_num_ >= 0) {
       // For dropped/lost frames, write out the last decoded frame to make it
       // look like a freeze at playback.
       const int num_dropped_frames = frame_number - last_decoded_frame_num_;
       for (int i = 0; i < num_dropped_frames; i++) {
         WriteDecodedFrameToFile(&last_decoded_frame_buffer_);
       }
     }
     // TODO(ssilkin): move to FrameEncoded when webm:1474 is implemented.
     const FrameStatistic* last_decoded_frame_stat =
         stats_->GetFrame(last_decoded_frame_num_);
     if (decoded_frame.width() != last_decoded_frame_stat->decoded_width ||
         decoded_frame.height() != last_decoded_frame_stat->decoded_height) {
       RTC_CHECK_GE(rate_update_index_, 0);
       ++num_spatial_resizes_[rate_update_index_];
     }
   }
   last_decoded_frame_num_ = frame_number;

   // Skip quality metrics calculation to not affect CPU usage.
   if (!config_.measure_cpu) {
     frame_stat->psnr =
         I420PSNR(input_frames_[frame_number].get(), &decoded_frame);
     frame_stat->ssim =
         I420SSIM(input_frames_[frame_number].get(), &decoded_frame);
   }

   // Delay erasing of input frames by one frame. The current frame might
   // still be needed for other simulcast stream or spatial layer.
   const int frame_number_to_erase = frame_number - 1;
   if (frame_number_to_erase >= 0) {
     auto input_frame_erase_to =
         input_frames_.lower_bound(frame_number_to_erase);
     input_frames_.erase(input_frames_.begin(), input_frame_erase_to);
   }

   if (decoded_frame_writer_) {
     ExtractBufferWithSize(decoded_frame, config_.codec_settings.width,
                           config_.codec_settings.height,
                           &last_decoded_frame_buffer_);
     WriteDecodedFrameToFile(&last_decoded_frame_buffer_);
   }
 }

 void VideoProcessor::WriteDecodedFrameToFile(rtc::Buffer* buffer) {
   RTC_DCHECK_EQ(buffer->size(), decoded_frame_writer_->FrameLength());
   RTC_CHECK(decoded_frame_writer_->WriteFrame(buffer->data()));
 }

 bool VideoProcessor::ExcludeFrame(const EncodedImage& encoded_image) {
   RTC_DCHECK_CALLED_SEQUENTIALLY(&sequence_checker_);
   if (encoded_image._frameType != kVideoFrameKey) {
     return false;
   }
   bool exclude_frame = false;
   switch (config_.exclude_frame_types) {
     case kExcludeOnlyFirstKeyFrame:
       if (!first_key_frame_has_been_excluded_) {
         first_key_frame_has_been_excluded_ = true;
         exclude_frame = true;
       }
       break;
     case kExcludeAllKeyFrames:
       exclude_frame = true;
       break;
     default:
       RTC_NOTREACHED();
   }
   return exclude_frame;
 }

 }  // namespace test
 }  // namespace webrtc
	/*
	* Copyright (c) 2012 The WebRTC project authors. All Rights Reserved.
	*
	* Use of this source code is governed by a BSD-style license
	* that can be found in the LICENSE file in the root of the source
	* tree. An additional intellectual property rights grant can be found
	* in the file PATENTS. All contributing project authors may
	* be found in the AUTHORS file in the root of the source tree.
	*/

	#include "modules/video_coding/codecs/test/videoprocessor.h"

	#include <algorithm>
	#include <limits>
	#include <utility>

	#include "api/video/i420_buffer.h"
	#include "common_types.h" // NOLINT(build/include)
	#include "common_video/h264/h264_common.h"
	#include "modules/video_coding/codecs/vp8/simulcast_rate_allocator.h"
	#include "modules/video_coding/include/video_codec_initializer.h"
	#include "modules/video_coding/utility/default_video_bitrate_allocator.h"
	#include "rtc_base/checks.h"
	#include "rtc_base/timeutils.h"
	#include "test/gtest.h"

	namespace webrtc {
	namespace test {

	namespace {

	const int kRtpClockRateHz = 90000;
	const int64_t kNoRenderTime = 0;

	std::unique_ptr<VideoBitrateAllocator> CreateBitrateAllocator(
	TestConfig* config) {
	std::unique_ptr<TemporalLayersFactory> tl_factory;
	if (config->codec_settings.codecType == VideoCodecType::kVideoCodecVP8) {
	tl_factory.reset(new TemporalLayersFactory());
	config->codec_settings.VP8()->tl_factory = tl_factory.get();
	}
	return std::unique_ptr<VideoBitrateAllocator>(
	VideoCodecInitializer::CreateBitrateAllocator(config->codec_settings,
	std::move(tl_factory)));
	}

	rtc::Optional<size_t> GetMaxNaluLength(const EncodedImage& encoded_frame,
	const TestConfig& config) {
	if (config.codec_settings.codecType != kVideoCodecH264)
	return rtc::nullopt;

	std::vector<webrtc::H264::NaluIndex> nalu_indices =
	webrtc::H264::FindNaluIndices(encoded_frame._buffer,
	encoded_frame._length);

	RTC_CHECK(!nalu_indices.empty());

	size_t max_length = 0;
	for (const webrtc::H264::NaluIndex& index : nalu_indices)
	max_length = std::max(max_length, index.payload_size);

	return max_length;
	}

	int GetElapsedTimeMicroseconds(int64_t start_ns, int64_t stop_ns) {
	int64_t diff_us = (stop_ns - start_ns) / rtc::kNumNanosecsPerMicrosec;
	RTC_DCHECK_GE(diff_us, std::numeric_limits<int>::min());
	RTC_DCHECK_LE(diff_us, std::numeric_limits<int>::max());
	return static_cast<int>(diff_us);
	}

	void ExtractBufferWithSize(const VideoFrame& image,
	int width,
	int height,
	rtc::Buffer* buffer) {
	if (image.width() != width \|\| image.height() != height) {
	EXPECT_DOUBLE_EQ(static_cast<double>(width) / height,
	static_cast<double>(image.width()) / image.height());
	// Same aspect ratio, no cropping needed.
	rtc::scoped_refptr<I420Buffer> scaled(I420Buffer::Create(width, height));
	scaled->ScaleFrom(*image.video_frame_buffer()->ToI420());

	size_t length =
	CalcBufferSize(VideoType::kI420, scaled->width(), scaled->height());
	buffer->SetSize(length);
	RTC_CHECK_NE(ExtractBuffer(scaled, length, buffer->data()), -1);
	return;
	}

	// No resize.
	size_t length =
	CalcBufferSize(VideoType::kI420, image.width(), image.height());
	buffer->SetSize(length);
	RTC_CHECK_NE(ExtractBuffer(image, length, buffer->data()), -1);
	}

	} // namespace

	VideoProcessor::VideoProcessor(webrtc::VideoEncoder* encoder,
	webrtc::VideoDecoder* decoder,
	FrameReader* analysis_frame_reader,
	PacketManipulator* packet_manipulator,
	const TestConfig& config,
	Stats* stats,
	IvfFileWriter* encoded_frame_writer,
	FrameWriter* decoded_frame_writer)
	: config_(config),
	encoder_(encoder),
	decoder_(decoder),
	bitrate_allocator_(CreateBitrateAllocator(&config_)),
	encode_callback_(this),
	decode_callback_(this),
	packet_manipulator_(packet_manipulator),
	analysis_frame_reader_(analysis_frame_reader),
	encoded_frame_writer_(encoded_frame_writer),
	decoded_frame_writer_(decoded_frame_writer),
	last_inputed_frame_num_(-1),
	last_encoded_frame_num_(-1),
	last_decoded_frame_num_(-1),
	first_key_frame_has_been_excluded_(false),
	last_decoded_frame_buffer_(analysis_frame_reader->FrameLength()),
	stats_(stats),
	rate_update_index_(-1) {
	RTC_DCHECK(encoder);
	RTC_DCHECK(decoder);
	RTC_DCHECK(packet_manipulator);
	RTC_DCHECK(analysis_frame_reader);
	RTC_DCHECK(stats);

	// Setup required callbacks for the encoder and decoder.
	RTC_CHECK_EQ(encoder_->RegisterEncodeCompleteCallback(&encode_callback_),
	WEBRTC_VIDEO_CODEC_OK);
	RTC_CHECK_EQ(decoder_->RegisterDecodeCompleteCallback(&decode_callback_),
	WEBRTC_VIDEO_CODEC_OK);

	// Initialize the encoder and decoder.
	RTC_CHECK_EQ(
	encoder_->InitEncode(&config_.codec_settings, config_.NumberOfCores(),
	config_.networking_config.max_payload_size_in_bytes),
	WEBRTC_VIDEO_CODEC_OK);
	RTC_CHECK_EQ(
	decoder_->InitDecode(&config_.codec_settings, config_.NumberOfCores()),
	WEBRTC_VIDEO_CODEC_OK);
	}

	VideoProcessor::~VideoProcessor() {
	RTC_DCHECK_CALLED_SEQUENTIALLY(&sequence_checker_);

	RTC_CHECK_EQ(encoder_->Release(), WEBRTC_VIDEO_CODEC_OK);
	RTC_CHECK_EQ(decoder_->Release(), WEBRTC_VIDEO_CODEC_OK);

	encoder_->RegisterEncodeCompleteCallback(nullptr);
	decoder_->RegisterDecodeCompleteCallback(nullptr);
	}

	void VideoProcessor::ProcessFrame() {
	RTC_DCHECK_CALLED_SEQUENTIALLY(&sequence_checker_);
	const int frame_number = ++last_inputed_frame_num_;

	// Get frame from file.
	rtc::scoped_refptr<I420BufferInterface> buffer(
	analysis_frame_reader_->ReadFrame());
	RTC_CHECK(buffer) << "Tried to read too many frames from the file.";
	// Use the frame number as the basis for timestamp to identify frames. Let the
	// first timestamp be non-zero, to not make the IvfFileWriter believe that we
	// want to use capture timestamps in the IVF files.
	const uint32_t rtp_timestamp = (frame_number + 1) * kRtpClockRateHz /
	config_.codec_settings.maxFramerate;
	rtp_timestamp_to_frame_num_[rtp_timestamp] = frame_number;
	input_frames_[frame_number] = rtc::MakeUnique<VideoFrame>(
	buffer, rtp_timestamp, kNoRenderTime, webrtc::kVideoRotation_0);

	std::vector<FrameType> frame_types = config_.FrameTypeForFrame(frame_number);

	// Create frame statistics object used for aggregation at end of test run.
	FrameStatistic* frame_stat = stats_->AddFrame();

	// For the highest measurement accuracy of the encode time, the start/stop
	// time recordings should wrap the Encode call as tightly as possible.
	frame_stat->encode_start_ns = rtc::TimeNanos();
	frame_stat->encode_return_code =
	encoder_->Encode(*input_frames_[frame_number], nullptr, &frame_types);
	}

	void VideoProcessor::SetRates(int bitrate_kbps, int framerate_fps) {
	RTC_DCHECK_CALLED_SEQUENTIALLY(&sequence_checker_);
	config_.codec_settings.maxFramerate = framerate_fps;
	int set_rates_result = encoder_->SetRateAllocation(
	bitrate_allocator_->GetAllocation(bitrate_kbps * 1000, framerate_fps),
	framerate_fps);
	RTC_DCHECK_GE(set_rates_result, 0)
	<< "Failed to update encoder with new rate " << bitrate_kbps << ".";
	++rate_update_index_;
	num_dropped_frames_.push_back(0);
	num_spatial_resizes_.push_back(0);
	}

	std::vector<int> VideoProcessor::NumberDroppedFramesPerRateUpdate() const {
	RTC_DCHECK_CALLED_SEQUENTIALLY(&sequence_checker_);
	return num_dropped_frames_;
	}

	std::vector<int> VideoProcessor::NumberSpatialResizesPerRateUpdate() const {
	RTC_DCHECK_CALLED_SEQUENTIALLY(&sequence_checker_);
	return num_spatial_resizes_;
	}

	void VideoProcessor::FrameEncoded(webrtc::VideoCodecType codec,
	const EncodedImage& encoded_image) {
	RTC_DCHECK_CALLED_SEQUENTIALLY(&sequence_checker_);

	// For the highest measurement accuracy of the encode time, the start/stop
	// time recordings should wrap the Encode call as tightly as possible.
	int64_t encode_stop_ns = rtc::TimeNanos();

	if (config_.encoded_frame_checker) {
	config_.encoded_frame_checker->CheckEncodedFrame(codec, encoded_image);
	}

	const int frame_number =
	rtp_timestamp_to_frame_num_[encoded_image._timeStamp];

	// Ensure strict monotonicity.
	RTC_CHECK_GT(frame_number, last_encoded_frame_num_);

	// Check for dropped frames.
	bool last_frame_missing = false;
	if (frame_number > 0) {
	int num_dropped_from_last_encode =
	frame_number - last_encoded_frame_num_ - 1;
	RTC_DCHECK_GE(num_dropped_from_last_encode, 0);
	RTC_CHECK_GE(rate_update_index_, 0);
	num_dropped_frames_[rate_update_index_] += num_dropped_from_last_encode;
	const FrameStatistic* last_encoded_frame_stat =
	stats_->GetFrame(last_encoded_frame_num_);
	last_frame_missing = (last_encoded_frame_stat->manipulated_length == 0);
	}
	last_encoded_frame_num_ = frame_number;

	// Update frame statistics.
	FrameStatistic* frame_stat = stats_->GetFrame(frame_number);
	frame_stat->encode_time_us =
	GetElapsedTimeMicroseconds(frame_stat->encode_start_ns, encode_stop_ns);
	frame_stat->encoding_successful = true;
	frame_stat->encoded_frame_size_bytes = encoded_image._length;
	frame_stat->frame_type = encoded_image._frameType;
	frame_stat->qp = encoded_image.qp_;
	frame_stat->bitrate_kbps = static_cast<int>(
	encoded_image._length * config_.codec_settings.maxFramerate * 8 / 1000);
	frame_stat->total_packets =
	encoded_image._length / config_.networking_config.packet_size_in_bytes +
	1;
	frame_stat->max_nalu_length = GetMaxNaluLength(encoded_image, config_);

	// Make a raw copy of \|encoded_image\| to feed to the decoder.
	size_t copied_buffer_size = encoded_image._length +
	EncodedImage::GetBufferPaddingBytes(codec);
	std::unique_ptr<uint8_t[]> copied_buffer(new uint8_t[copied_buffer_size]);
	memcpy(copied_buffer.get(), encoded_image._buffer, encoded_image._length);
	EncodedImage copied_image = encoded_image;
	copied_image._size = copied_buffer_size;
	copied_image._buffer = copied_buffer.get();

	// Simulate packet loss.
	if (!ExcludeFrame(copied_image)) {
	frame_stat->packets_dropped =
	packet_manipulator_->ManipulatePackets(&copied_image);
	}
	frame_stat->manipulated_length = copied_image._length;

	// For the highest measurement accuracy of the decode time, the start/stop
	// time recordings should wrap the Decode call as tightly as possible.
	frame_stat->decode_start_ns = rtc::TimeNanos();
	frame_stat->decode_return_code =
	decoder_->Decode(copied_image, last_frame_missing, nullptr);

	if (encoded_frame_writer_) {
	RTC_CHECK(encoded_frame_writer_->WriteFrame(encoded_image, codec));
	}
	}

	void VideoProcessor::FrameDecoded(const VideoFrame& decoded_frame) {
	RTC_DCHECK_CALLED_SEQUENTIALLY(&sequence_checker_);

	// For the highest measurement accuracy of the decode time, the start/stop
	// time recordings should wrap the Decode call as tightly as possible.
	int64_t decode_stop_ns = rtc::TimeNanos();

	// Update frame statistics.
	const int frame_number =
	rtp_timestamp_to_frame_num_[decoded_frame.timestamp()];
	FrameStatistic* frame_stat = stats_->GetFrame(frame_number);
	frame_stat->decoded_width = decoded_frame.width();
	frame_stat->decoded_height = decoded_frame.height();
	frame_stat->decode_time_us =
	GetElapsedTimeMicroseconds(frame_stat->decode_start_ns, decode_stop_ns);
	frame_stat->decoding_successful = true;

	// Ensure strict monotonicity.
	RTC_CHECK_GT(frame_number, last_decoded_frame_num_);

	// Check if the codecs have resized the frame since previously decoded frame.
	if (frame_number > 0) {
	if (decoded_frame_writer_ && last_decoded_frame_num_ >= 0) {
	// For dropped/lost frames, write out the last decoded frame to make it
	// look like a freeze at playback.
	const int num_dropped_frames = frame_number - last_decoded_frame_num_;
	for (int i = 0; i < num_dropped_frames; i++) {
	WriteDecodedFrameToFile(&last_decoded_frame_buffer_);
	}
	}
	// TODO(ssilkin): move to FrameEncoded when webm:1474 is implemented.
	const FrameStatistic* last_decoded_frame_stat =
	stats_->GetFrame(last_decoded_frame_num_);
	if (decoded_frame.width() != last_decoded_frame_stat->decoded_width \|\|
	decoded_frame.height() != last_decoded_frame_stat->decoded_height) {
	RTC_CHECK_GE(rate_update_index_, 0);
	++num_spatial_resizes_[rate_update_index_];
	}
	}
	last_decoded_frame_num_ = frame_number;

	// Skip quality metrics calculation to not affect CPU usage.
	if (!config_.measure_cpu) {
	frame_stat->psnr =
	I420PSNR(input_frames_[frame_number].get(), &decoded_frame);
	frame_stat->ssim =
	I420SSIM(input_frames_[frame_number].get(), &decoded_frame);
	}

	// Delay erasing of input frames by one frame. The current frame might
	// still be needed for other simulcast stream or spatial layer.
	const int frame_number_to_erase = frame_number - 1;
	if (frame_number_to_erase >= 0) {
	auto input_frame_erase_to =
	input_frames_.lower_bound(frame_number_to_erase);
	input_frames_.erase(input_frames_.begin(), input_frame_erase_to);
	}

	if (decoded_frame_writer_) {
	ExtractBufferWithSize(decoded_frame, config_.codec_settings.width,
	config_.codec_settings.height,
	&last_decoded_frame_buffer_);
	WriteDecodedFrameToFile(&last_decoded_frame_buffer_);
	}
	}

	void VideoProcessor::WriteDecodedFrameToFile(rtc::Buffer* buffer) {
	RTC_DCHECK_EQ(buffer->size(), decoded_frame_writer_->FrameLength());
	RTC_CHECK(decoded_frame_writer_->WriteFrame(buffer->data()));
	}

	bool VideoProcessor::ExcludeFrame(const EncodedImage& encoded_image) {
	RTC_DCHECK_CALLED_SEQUENTIALLY(&sequence_checker_);
	if (encoded_image._frameType != kVideoFrameKey) {
	return false;
	}
	bool exclude_frame = false;
	switch (config_.exclude_frame_types) {
	case kExcludeOnlyFirstKeyFrame:
	if (!first_key_frame_has_been_excluded_) {
	first_key_frame_has_been_excluded_ = true;
	exclude_frame = true;
	}
	break;
	case kExcludeAllKeyFrames:
	exclude_frame = true;
	break;
	default:
	RTC_NOTREACHED();
	}
	return exclude_frame;
	}

	} // namespace test
	} // namespace webrtc