rtc_tools/rtc_event_log_visualizer/analyze_audio.cc - src/ - Git at Google

 /*
  *  Copyright (c) 2020 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 "rtc_tools/rtc_event_log_visualizer/analyze_audio.h"

 #include <memory>
 #include <set>
 #include <utility>
 #include <vector>

 #include "modules/audio_coding/neteq/tools/audio_sink.h"
 #include "modules/audio_coding/neteq/tools/fake_decode_from_file.h"
 #include "modules/audio_coding/neteq/tools/neteq_delay_analyzer.h"
 #include "modules/audio_coding/neteq/tools/neteq_event_log_input.h"
 #include "modules/audio_coding/neteq/tools/neteq_replacement_input.h"
 #include "modules/audio_coding/neteq/tools/neteq_test.h"
 #include "modules/audio_coding/neteq/tools/resample_input_audio_file.h"

 namespace webrtc {

 void CreateAudioEncoderTargetBitrateGraph(const ParsedRtcEventLog& parsed_log,
                                           const AnalyzerConfig& config,
                                           Plot* plot) {
   TimeSeries time_series("Audio encoder target bitrate", LineStyle::kLine,
                          PointStyle::kHighlight);
   auto GetAnaBitrateBps = [](const LoggedAudioNetworkAdaptationEvent& ana_event)
       -> absl::optional<float> {
     if (ana_event.config.bitrate_bps)
       return absl::optional<float>(
           static_cast<float>(*ana_event.config.bitrate_bps));
     return absl::nullopt;
   };
   auto ToCallTime = [config](const LoggedAudioNetworkAdaptationEvent& packet) {
     return config.GetCallTimeSec(packet.log_time());
   };
   ProcessPoints<LoggedAudioNetworkAdaptationEvent>(
       ToCallTime, GetAnaBitrateBps,
       parsed_log.audio_network_adaptation_events(), &time_series);
   plot->AppendTimeSeries(std::move(time_series));
   plot->SetXAxis(config.CallBeginTimeSec(), config.CallEndTimeSec(), "Time (s)",
                  kLeftMargin, kRightMargin);
   plot->SetSuggestedYAxis(0, 1, "Bitrate (bps)", kBottomMargin, kTopMargin);
   plot->SetTitle("Reported audio encoder target bitrate");
 }

 void CreateAudioEncoderFrameLengthGraph(const ParsedRtcEventLog& parsed_log,
                                         const AnalyzerConfig& config,
                                         Plot* plot) {
   TimeSeries time_series("Audio encoder frame length", LineStyle::kLine,
                          PointStyle::kHighlight);
   auto GetAnaFrameLengthMs =
       [](const LoggedAudioNetworkAdaptationEvent& ana_event) {
         if (ana_event.config.frame_length_ms)
           return absl::optional<float>(
               static_cast<float>(*ana_event.config.frame_length_ms));
         return absl::optional<float>();
       };
   auto ToCallTime = [config](const LoggedAudioNetworkAdaptationEvent& packet) {
     return config.GetCallTimeSec(packet.log_time());
   };
   ProcessPoints<LoggedAudioNetworkAdaptationEvent>(
       ToCallTime, GetAnaFrameLengthMs,
       parsed_log.audio_network_adaptation_events(), &time_series);
   plot->AppendTimeSeries(std::move(time_series));
   plot->SetXAxis(config.CallBeginTimeSec(), config.CallEndTimeSec(), "Time (s)",
                  kLeftMargin, kRightMargin);
   plot->SetSuggestedYAxis(0, 1, "Frame length (ms)", kBottomMargin, kTopMargin);
   plot->SetTitle("Reported audio encoder frame length");
 }

 void CreateAudioEncoderPacketLossGraph(const ParsedRtcEventLog& parsed_log,
                                        const AnalyzerConfig& config,
                                        Plot* plot) {
   TimeSeries time_series("Audio encoder uplink packet loss fraction",
                          LineStyle::kLine, PointStyle::kHighlight);
   auto GetAnaPacketLoss =
       [](const LoggedAudioNetworkAdaptationEvent& ana_event) {
         if (ana_event.config.uplink_packet_loss_fraction)
           return absl::optional<float>(static_cast<float>(
               *ana_event.config.uplink_packet_loss_fraction));
         return absl::optional<float>();
       };
   auto ToCallTime = [config](const LoggedAudioNetworkAdaptationEvent& packet) {
     return config.GetCallTimeSec(packet.log_time());
   };
   ProcessPoints<LoggedAudioNetworkAdaptationEvent>(
       ToCallTime, GetAnaPacketLoss,
       parsed_log.audio_network_adaptation_events(), &time_series);
   plot->AppendTimeSeries(std::move(time_series));
   plot->SetXAxis(config.CallBeginTimeSec(), config.CallEndTimeSec(), "Time (s)",
                  kLeftMargin, kRightMargin);
   plot->SetSuggestedYAxis(0, 10, "Percent lost packets", kBottomMargin,
                           kTopMargin);
   plot->SetTitle("Reported audio encoder lost packets");
 }

 void CreateAudioEncoderEnableFecGraph(const ParsedRtcEventLog& parsed_log,
                                       const AnalyzerConfig& config,
                                       Plot* plot) {
   TimeSeries time_series("Audio encoder FEC", LineStyle::kLine,
                          PointStyle::kHighlight);
   auto GetAnaFecEnabled =
       [](const LoggedAudioNetworkAdaptationEvent& ana_event) {
         if (ana_event.config.enable_fec)
           return absl::optional<float>(
               static_cast<float>(*ana_event.config.enable_fec));
         return absl::optional<float>();
       };
   auto ToCallTime = [config](const LoggedAudioNetworkAdaptationEvent& packet) {
     return config.GetCallTimeSec(packet.log_time());
   };
   ProcessPoints<LoggedAudioNetworkAdaptationEvent>(
       ToCallTime, GetAnaFecEnabled,
       parsed_log.audio_network_adaptation_events(), &time_series);
   plot->AppendTimeSeries(std::move(time_series));
   plot->SetXAxis(config.CallBeginTimeSec(), config.CallEndTimeSec(), "Time (s)",
                  kLeftMargin, kRightMargin);
   plot->SetSuggestedYAxis(0, 1, "FEC (false/true)", kBottomMargin, kTopMargin);
   plot->SetTitle("Reported audio encoder FEC");
 }

 void CreateAudioEncoderEnableDtxGraph(const ParsedRtcEventLog& parsed_log,
                                       const AnalyzerConfig& config,
                                       Plot* plot) {
   TimeSeries time_series("Audio encoder DTX", LineStyle::kLine,
                          PointStyle::kHighlight);
   auto GetAnaDtxEnabled =
       [](const LoggedAudioNetworkAdaptationEvent& ana_event) {
         if (ana_event.config.enable_dtx)
           return absl::optional<float>(
               static_cast<float>(*ana_event.config.enable_dtx));
         return absl::optional<float>();
       };
   auto ToCallTime = [config](const LoggedAudioNetworkAdaptationEvent& packet) {
     return config.GetCallTimeSec(packet.log_time());
   };
   ProcessPoints<LoggedAudioNetworkAdaptationEvent>(
       ToCallTime, GetAnaDtxEnabled,
       parsed_log.audio_network_adaptation_events(), &time_series);
   plot->AppendTimeSeries(std::move(time_series));
   plot->SetXAxis(config.CallBeginTimeSec(), config.CallEndTimeSec(), "Time (s)",
                  kLeftMargin, kRightMargin);
   plot->SetSuggestedYAxis(0, 1, "DTX (false/true)", kBottomMargin, kTopMargin);
   plot->SetTitle("Reported audio encoder DTX");
 }

 void CreateAudioEncoderNumChannelsGraph(const ParsedRtcEventLog& parsed_log,
                                         const AnalyzerConfig& config,
                                         Plot* plot) {
   TimeSeries time_series("Audio encoder number of channels", LineStyle::kLine,
                          PointStyle::kHighlight);
   auto GetAnaNumChannels =
       [](const LoggedAudioNetworkAdaptationEvent& ana_event) {
         if (ana_event.config.num_channels)
           return absl::optional<float>(
               static_cast<float>(*ana_event.config.num_channels));
         return absl::optional<float>();
       };
   auto ToCallTime = [config](const LoggedAudioNetworkAdaptationEvent& packet) {
     return config.GetCallTimeSec(packet.log_time());
   };
   ProcessPoints<LoggedAudioNetworkAdaptationEvent>(
       ToCallTime, GetAnaNumChannels,
       parsed_log.audio_network_adaptation_events(), &time_series);
   plot->AppendTimeSeries(std::move(time_series));
   plot->SetXAxis(config.CallBeginTimeSec(), config.CallEndTimeSec(), "Time (s)",
                  kLeftMargin, kRightMargin);
   plot->SetSuggestedYAxis(0, 1, "Number of channels (1 (mono)/2 (stereo))",
                           kBottomMargin, kTopMargin);
   plot->SetTitle("Reported audio encoder number of channels");
 }

 namespace {

 // Factory to create a "replacement decoder" that produces the decoded audio
 // by reading from a file rather than from the encoded payloads.
 class ReplacementAudioDecoderFactory : public AudioDecoderFactory {
  public:
   ReplacementAudioDecoderFactory(const absl::string_view replacement_file_name,
                                  int file_sample_rate_hz)
       : replacement_file_name_(replacement_file_name),
         file_sample_rate_hz_(file_sample_rate_hz) {}

   std::vector<AudioCodecSpec> GetSupportedDecoders() override {
     RTC_DCHECK_NOTREACHED();
     return {};
   }

   bool IsSupportedDecoder(const SdpAudioFormat& format) override {
     return true;
   }

   std::unique_ptr<AudioDecoder> MakeAudioDecoder(
       const SdpAudioFormat& format,
       absl::optional<AudioCodecPairId> codec_pair_id) override {
     auto replacement_file = std::make_unique<test::ResampleInputAudioFile>(
         replacement_file_name_, file_sample_rate_hz_);
     replacement_file->set_output_rate_hz(48000);
     return std::make_unique<test::FakeDecodeFromFile>(
         std::move(replacement_file), 48000, false);
   }

  private:
   const std::string replacement_file_name_;
   const int file_sample_rate_hz_;
 };

 // Creates a NetEq test object and all necessary input and output helpers. Runs
 // the test and returns the NetEqDelayAnalyzer object that was used to
 // instrument the test.
 std::unique_ptr<test::NetEqStatsGetter> CreateNetEqTestAndRun(
     ParsedRtcEventLog parsed_log,
     uint32_t ssrc,
     const std::string& replacement_file_name,
     int file_sample_rate_hz) {
   std::unique_ptr<test::NetEqInput> input =
       test::CreateNetEqEventLogInput(parsed_log, ssrc);
   if (!input) {
     return nullptr;
   }

   constexpr int kReplacementPt = 127;
   std::set<uint8_t> cn_types;
   std::set<uint8_t> forbidden_types;
   input.reset(new test::NetEqReplacementInput(std::move(input), kReplacementPt,
                                               cn_types, forbidden_types));

   std::unique_ptr<test::VoidAudioSink> output(new test::VoidAudioSink());

   rtc::scoped_refptr<AudioDecoderFactory> decoder_factory =
       rtc::make_ref_counted<ReplacementAudioDecoderFactory>(
           replacement_file_name, file_sample_rate_hz);

   test::NetEqTest::DecoderMap codecs = {
       {kReplacementPt, SdpAudioFormat("l16", 48000, 1)}};

   std::unique_ptr<test::NetEqDelayAnalyzer> delay_cb(
       new test::NetEqDelayAnalyzer);
   std::unique_ptr<test::NetEqStatsGetter> neteq_stats_getter(
       new test::NetEqStatsGetter(std::move(delay_cb)));
   test::DefaultNetEqTestErrorCallback error_cb;
   test::NetEqTest::Callbacks callbacks;
   callbacks.error_callback = &error_cb;
   callbacks.post_insert_packet = neteq_stats_getter->delay_analyzer();
   callbacks.get_audio_callback = neteq_stats_getter.get();

   NetEq::Config config;
   test::NetEqTest test(config, decoder_factory, codecs, /*text_log=*/nullptr,
                        /*factory=*/nullptr, std::move(input), std::move(output),
                        callbacks);
   test.Run();
   return neteq_stats_getter;
 }
 }  // namespace

 NetEqStatsGetterMap SimulateNetEq(const ParsedRtcEventLog& parsed_log,
                                   const AnalyzerConfig& config,
                                   const std::string& replacement_file_name,
                                   int file_sample_rate_hz) {
   NetEqStatsGetterMap neteq_stats;
   for (uint32_t ssrc : parsed_log.incoming_audio_ssrcs()) {
     std::unique_ptr<test::NetEqStatsGetter> stats = CreateNetEqTestAndRun(
         parsed_log, ssrc, replacement_file_name, file_sample_rate_hz);
     if (stats) {
       neteq_stats[ssrc] = std::move(stats);
     }
   }
   return neteq_stats;
 }

 // Given a NetEqStatsGetter and the SSRC that the NetEqStatsGetter was created
 // for, this method generates a plot for the jitter buffer delay profile.
 void CreateAudioJitterBufferGraph(const ParsedRtcEventLog& parsed_log,
                                   const AnalyzerConfig& config,
                                   uint32_t ssrc,
                                   const test::NetEqStatsGetter* stats_getter,
                                   Plot* plot) {
   test::NetEqDelayAnalyzer::Delays arrival_delay_ms;
   test::NetEqDelayAnalyzer::Delays corrected_arrival_delay_ms;
   test::NetEqDelayAnalyzer::Delays playout_delay_ms;
   test::NetEqDelayAnalyzer::Delays target_delay_ms;

   stats_getter->delay_analyzer()->CreateGraphs(
       &arrival_delay_ms, &corrected_arrival_delay_ms, &playout_delay_ms,
       &target_delay_ms);

   TimeSeries time_series_packet_arrival("packet arrival delay",
                                         LineStyle::kLine);
   TimeSeries time_series_relative_packet_arrival(
       "Relative packet arrival delay", LineStyle::kLine);
   TimeSeries time_series_play_time("Playout delay", LineStyle::kLine);
   TimeSeries time_series_target_time("Target delay", LineStyle::kLine,
                                      PointStyle::kHighlight);

   for (const auto& data : arrival_delay_ms) {
     const float x = config.GetCallTimeSec(Timestamp::Millis(data.first));
     const float y = data.second;
     time_series_packet_arrival.points.emplace_back(TimeSeriesPoint(x, y));
   }
   for (const auto& data : corrected_arrival_delay_ms) {
     const float x = config.GetCallTimeSec(Timestamp::Millis(data.first));
     const float y = data.second;
     time_series_relative_packet_arrival.points.emplace_back(
         TimeSeriesPoint(x, y));
   }
   for (const auto& data : playout_delay_ms) {
     const float x = config.GetCallTimeSec(Timestamp::Millis(data.first));
     const float y = data.second;
     time_series_play_time.points.emplace_back(TimeSeriesPoint(x, y));
   }
   for (const auto& data : target_delay_ms) {
     const float x = config.GetCallTimeSec(Timestamp::Millis(data.first));
     const float y = data.second;
     time_series_target_time.points.emplace_back(TimeSeriesPoint(x, y));
   }

   plot->AppendTimeSeries(std::move(time_series_packet_arrival));
   plot->AppendTimeSeries(std::move(time_series_relative_packet_arrival));
   plot->AppendTimeSeries(std::move(time_series_play_time));
   plot->AppendTimeSeries(std::move(time_series_target_time));

   plot->SetXAxis(config.CallBeginTimeSec(), config.CallEndTimeSec(), "Time (s)",
                  kLeftMargin, kRightMargin);
   plot->SetSuggestedYAxis(0, 1, "Relative delay (ms)", kBottomMargin,
                           kTopMargin);
   plot->SetTitle("NetEq timing for " +
                  GetStreamName(parsed_log, kIncomingPacket, ssrc));
 }

 template <typename NetEqStatsType>
 void CreateNetEqStatsGraphInternal(
     const ParsedRtcEventLog& parsed_log,
     const AnalyzerConfig& config,
     const NetEqStatsGetterMap& neteq_stats,
     rtc::FunctionView<const std::vector<std::pair<int64_t, NetEqStatsType>>*(
         const test::NetEqStatsGetter*)> data_extractor,
     rtc::FunctionView<float(const NetEqStatsType&)> stats_extractor,
     const std::string& plot_name,
     Plot* plot) {
   std::map<uint32_t, TimeSeries> time_series;

   for (const auto& st : neteq_stats) {
     const uint32_t ssrc = st.first;
     const std::vector<std::pair<int64_t, NetEqStatsType>>* data_vector =
         data_extractor(st.second.get());
     for (const auto& data : *data_vector) {
       const float time = config.GetCallTimeSec(Timestamp::Millis(data.first));
       const float value = stats_extractor(data.second);
       time_series[ssrc].points.emplace_back(TimeSeriesPoint(time, value));
     }
   }

   for (auto& series : time_series) {
     series.second.label =
         GetStreamName(parsed_log, kIncomingPacket, series.first);
     series.second.line_style = LineStyle::kLine;
     plot->AppendTimeSeries(std::move(series.second));
   }

   plot->SetXAxis(config.CallBeginTimeSec(), config.CallEndTimeSec(), "Time (s)",
                  kLeftMargin, kRightMargin);
   plot->SetSuggestedYAxis(0, 1, plot_name, kBottomMargin, kTopMargin);
   plot->SetTitle(plot_name);
 }

 void CreateNetEqNetworkStatsGraph(
     const ParsedRtcEventLog& parsed_log,
     const AnalyzerConfig& config,
     const NetEqStatsGetterMap& neteq_stats,
     rtc::FunctionView<float(const NetEqNetworkStatistics&)> stats_extractor,
     const std::string& plot_name,
     Plot* plot) {
   CreateNetEqStatsGraphInternal<NetEqNetworkStatistics>(
       parsed_log, config, neteq_stats,
       [](const test::NetEqStatsGetter* stats_getter) {
         return stats_getter->stats();
       },
       stats_extractor, plot_name, plot);
 }

 void CreateNetEqLifetimeStatsGraph(
     const ParsedRtcEventLog& parsed_log,
     const AnalyzerConfig& config,
     const NetEqStatsGetterMap& neteq_stats,
     rtc::FunctionView<float(const NetEqLifetimeStatistics&)> stats_extractor,
     const std::string& plot_name,
     Plot* plot) {
   CreateNetEqStatsGraphInternal<NetEqLifetimeStatistics>(
       parsed_log, config, neteq_stats,
       [](const test::NetEqStatsGetter* stats_getter) {
         return stats_getter->lifetime_stats();
       },
       stats_extractor, plot_name, plot);
 }

 }  // namespace webrtc
	/*
	* Copyright (c) 2020 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 "rtc_tools/rtc_event_log_visualizer/analyze_audio.h"

	#include <memory>
	#include <set>
	#include <utility>
	#include <vector>

	#include "modules/audio_coding/neteq/tools/audio_sink.h"
	#include "modules/audio_coding/neteq/tools/fake_decode_from_file.h"
	#include "modules/audio_coding/neteq/tools/neteq_delay_analyzer.h"
	#include "modules/audio_coding/neteq/tools/neteq_event_log_input.h"
	#include "modules/audio_coding/neteq/tools/neteq_replacement_input.h"
	#include "modules/audio_coding/neteq/tools/neteq_test.h"
	#include "modules/audio_coding/neteq/tools/resample_input_audio_file.h"

	namespace webrtc {

	void CreateAudioEncoderTargetBitrateGraph(const ParsedRtcEventLog& parsed_log,
	const AnalyzerConfig& config,
	Plot* plot) {
	TimeSeries time_series("Audio encoder target bitrate", LineStyle::kLine,
	PointStyle::kHighlight);
	auto GetAnaBitrateBps = [](const LoggedAudioNetworkAdaptationEvent& ana_event)
	-> absl::optional<float> {
	if (ana_event.config.bitrate_bps)
	return absl::optional<float>(
	static_cast<float>(*ana_event.config.bitrate_bps));
	return absl::nullopt;
	};
	auto ToCallTime = [config](const LoggedAudioNetworkAdaptationEvent& packet) {
	return config.GetCallTimeSec(packet.log_time());
	};
	ProcessPoints<LoggedAudioNetworkAdaptationEvent>(
	ToCallTime, GetAnaBitrateBps,
	parsed_log.audio_network_adaptation_events(), &time_series);
	plot->AppendTimeSeries(std::move(time_series));
	plot->SetXAxis(config.CallBeginTimeSec(), config.CallEndTimeSec(), "Time (s)",
	kLeftMargin, kRightMargin);
	plot->SetSuggestedYAxis(0, 1, "Bitrate (bps)", kBottomMargin, kTopMargin);
	plot->SetTitle("Reported audio encoder target bitrate");
	}

	void CreateAudioEncoderFrameLengthGraph(const ParsedRtcEventLog& parsed_log,
	const AnalyzerConfig& config,
	Plot* plot) {
	TimeSeries time_series("Audio encoder frame length", LineStyle::kLine,
	PointStyle::kHighlight);
	auto GetAnaFrameLengthMs =
	[](const LoggedAudioNetworkAdaptationEvent& ana_event) {
	if (ana_event.config.frame_length_ms)
	return absl::optional<float>(
	static_cast<float>(*ana_event.config.frame_length_ms));
	return absl::optional<float>();
	};
	auto ToCallTime = [config](const LoggedAudioNetworkAdaptationEvent& packet) {
	return config.GetCallTimeSec(packet.log_time());
	};
	ProcessPoints<LoggedAudioNetworkAdaptationEvent>(
	ToCallTime, GetAnaFrameLengthMs,
	parsed_log.audio_network_adaptation_events(), &time_series);
	plot->AppendTimeSeries(std::move(time_series));
	plot->SetXAxis(config.CallBeginTimeSec(), config.CallEndTimeSec(), "Time (s)",
	kLeftMargin, kRightMargin);
	plot->SetSuggestedYAxis(0, 1, "Frame length (ms)", kBottomMargin, kTopMargin);
	plot->SetTitle("Reported audio encoder frame length");
	}

	void CreateAudioEncoderPacketLossGraph(const ParsedRtcEventLog& parsed_log,
	const AnalyzerConfig& config,
	Plot* plot) {
	TimeSeries time_series("Audio encoder uplink packet loss fraction",
	LineStyle::kLine, PointStyle::kHighlight);
	auto GetAnaPacketLoss =
	[](const LoggedAudioNetworkAdaptationEvent& ana_event) {
	if (ana_event.config.uplink_packet_loss_fraction)
	return absl::optional<float>(static_cast<float>(
	*ana_event.config.uplink_packet_loss_fraction));
	return absl::optional<float>();
	};
	auto ToCallTime = [config](const LoggedAudioNetworkAdaptationEvent& packet) {
	return config.GetCallTimeSec(packet.log_time());
	};
	ProcessPoints<LoggedAudioNetworkAdaptationEvent>(
	ToCallTime, GetAnaPacketLoss,
	parsed_log.audio_network_adaptation_events(), &time_series);
	plot->AppendTimeSeries(std::move(time_series));
	plot->SetXAxis(config.CallBeginTimeSec(), config.CallEndTimeSec(), "Time (s)",
	kLeftMargin, kRightMargin);
	plot->SetSuggestedYAxis(0, 10, "Percent lost packets", kBottomMargin,
	kTopMargin);
	plot->SetTitle("Reported audio encoder lost packets");
	}

	void CreateAudioEncoderEnableFecGraph(const ParsedRtcEventLog& parsed_log,
	const AnalyzerConfig& config,
	Plot* plot) {
	TimeSeries time_series("Audio encoder FEC", LineStyle::kLine,
	PointStyle::kHighlight);
	auto GetAnaFecEnabled =
	[](const LoggedAudioNetworkAdaptationEvent& ana_event) {
	if (ana_event.config.enable_fec)
	return absl::optional<float>(
	static_cast<float>(*ana_event.config.enable_fec));
	return absl::optional<float>();
	};
	auto ToCallTime = [config](const LoggedAudioNetworkAdaptationEvent& packet) {
	return config.GetCallTimeSec(packet.log_time());
	};
	ProcessPoints<LoggedAudioNetworkAdaptationEvent>(
	ToCallTime, GetAnaFecEnabled,
	parsed_log.audio_network_adaptation_events(), &time_series);
	plot->AppendTimeSeries(std::move(time_series));
	plot->SetXAxis(config.CallBeginTimeSec(), config.CallEndTimeSec(), "Time (s)",
	kLeftMargin, kRightMargin);
	plot->SetSuggestedYAxis(0, 1, "FEC (false/true)", kBottomMargin, kTopMargin);
	plot->SetTitle("Reported audio encoder FEC");
	}

	void CreateAudioEncoderEnableDtxGraph(const ParsedRtcEventLog& parsed_log,
	const AnalyzerConfig& config,
	Plot* plot) {
	TimeSeries time_series("Audio encoder DTX", LineStyle::kLine,
	PointStyle::kHighlight);
	auto GetAnaDtxEnabled =
	[](const LoggedAudioNetworkAdaptationEvent& ana_event) {
	if (ana_event.config.enable_dtx)
	return absl::optional<float>(
	static_cast<float>(*ana_event.config.enable_dtx));
	return absl::optional<float>();
	};
	auto ToCallTime = [config](const LoggedAudioNetworkAdaptationEvent& packet) {
	return config.GetCallTimeSec(packet.log_time());
	};
	ProcessPoints<LoggedAudioNetworkAdaptationEvent>(
	ToCallTime, GetAnaDtxEnabled,
	parsed_log.audio_network_adaptation_events(), &time_series);
	plot->AppendTimeSeries(std::move(time_series));
	plot->SetXAxis(config.CallBeginTimeSec(), config.CallEndTimeSec(), "Time (s)",
	kLeftMargin, kRightMargin);
	plot->SetSuggestedYAxis(0, 1, "DTX (false/true)", kBottomMargin, kTopMargin);
	plot->SetTitle("Reported audio encoder DTX");
	}

	void CreateAudioEncoderNumChannelsGraph(const ParsedRtcEventLog& parsed_log,
	const AnalyzerConfig& config,
	Plot* plot) {
	TimeSeries time_series("Audio encoder number of channels", LineStyle::kLine,
	PointStyle::kHighlight);
	auto GetAnaNumChannels =
	[](const LoggedAudioNetworkAdaptationEvent& ana_event) {
	if (ana_event.config.num_channels)
	return absl::optional<float>(
	static_cast<float>(*ana_event.config.num_channels));
	return absl::optional<float>();
	};
	auto ToCallTime = [config](const LoggedAudioNetworkAdaptationEvent& packet) {
	return config.GetCallTimeSec(packet.log_time());
	};
	ProcessPoints<LoggedAudioNetworkAdaptationEvent>(
	ToCallTime, GetAnaNumChannels,
	parsed_log.audio_network_adaptation_events(), &time_series);
	plot->AppendTimeSeries(std::move(time_series));
	plot->SetXAxis(config.CallBeginTimeSec(), config.CallEndTimeSec(), "Time (s)",
	kLeftMargin, kRightMargin);
	plot->SetSuggestedYAxis(0, 1, "Number of channels (1 (mono)/2 (stereo))",
	kBottomMargin, kTopMargin);
	plot->SetTitle("Reported audio encoder number of channels");
	}

	namespace {

	// Factory to create a "replacement decoder" that produces the decoded audio
	// by reading from a file rather than from the encoded payloads.
	class ReplacementAudioDecoderFactory : public AudioDecoderFactory {
	public:
	ReplacementAudioDecoderFactory(const absl::string_view replacement_file_name,
	int file_sample_rate_hz)
	: replacement_file_name_(replacement_file_name),
	file_sample_rate_hz_(file_sample_rate_hz) {}

	std::vector<AudioCodecSpec> GetSupportedDecoders() override {
	RTC_DCHECK_NOTREACHED();
	return {};
	}

	bool IsSupportedDecoder(const SdpAudioFormat& format) override {
	return true;
	}

	std::unique_ptr<AudioDecoder> MakeAudioDecoder(
	const SdpAudioFormat& format,
	absl::optional<AudioCodecPairId> codec_pair_id) override {
	auto replacement_file = std::make_unique<test::ResampleInputAudioFile>(
	replacement_file_name_, file_sample_rate_hz_);
	replacement_file->set_output_rate_hz(48000);
	return std::make_unique<test::FakeDecodeFromFile>(
	std::move(replacement_file), 48000, false);
	}

	private:
	const std::string replacement_file_name_;
	const int file_sample_rate_hz_;
	};

	// Creates a NetEq test object and all necessary input and output helpers. Runs
	// the test and returns the NetEqDelayAnalyzer object that was used to
	// instrument the test.
	std::unique_ptr<test::NetEqStatsGetter> CreateNetEqTestAndRun(
	ParsedRtcEventLog parsed_log,
	uint32_t ssrc,
	const std::string& replacement_file_name,
	int file_sample_rate_hz) {
	std::unique_ptr<test::NetEqInput> input =
	test::CreateNetEqEventLogInput(parsed_log, ssrc);
	if (!input) {
	return nullptr;
	}

	constexpr int kReplacementPt = 127;
	std::set<uint8_t> cn_types;
	std::set<uint8_t> forbidden_types;
	input.reset(new test::NetEqReplacementInput(std::move(input), kReplacementPt,
	cn_types, forbidden_types));

	std::unique_ptr<test::VoidAudioSink> output(new test::VoidAudioSink());

	rtc::scoped_refptr<AudioDecoderFactory> decoder_factory =
	rtc::make_ref_counted<ReplacementAudioDecoderFactory>(
	replacement_file_name, file_sample_rate_hz);

	test::NetEqTest::DecoderMap codecs = {
	{kReplacementPt, SdpAudioFormat("l16", 48000, 1)}};

	std::unique_ptr<test::NetEqDelayAnalyzer> delay_cb(
	new test::NetEqDelayAnalyzer);
	std::unique_ptr<test::NetEqStatsGetter> neteq_stats_getter(
	new test::NetEqStatsGetter(std::move(delay_cb)));
	test::DefaultNetEqTestErrorCallback error_cb;
	test::NetEqTest::Callbacks callbacks;
	callbacks.error_callback = &error_cb;
	callbacks.post_insert_packet = neteq_stats_getter->delay_analyzer();
	callbacks.get_audio_callback = neteq_stats_getter.get();

	NetEq::Config config;
	test::NetEqTest test(config, decoder_factory, codecs, /text_log=/nullptr,
	/factory=/nullptr, std::move(input), std::move(output),
	callbacks);
	test.Run();
	return neteq_stats_getter;
	}
	} // namespace

	NetEqStatsGetterMap SimulateNetEq(const ParsedRtcEventLog& parsed_log,
	const AnalyzerConfig& config,
	const std::string& replacement_file_name,
	int file_sample_rate_hz) {
	NetEqStatsGetterMap neteq_stats;
	for (uint32_t ssrc : parsed_log.incoming_audio_ssrcs()) {
	std::unique_ptr<test::NetEqStatsGetter> stats = CreateNetEqTestAndRun(
	parsed_log, ssrc, replacement_file_name, file_sample_rate_hz);
	if (stats) {
	neteq_stats[ssrc] = std::move(stats);
	}
	}
	return neteq_stats;
	}

	// Given a NetEqStatsGetter and the SSRC that the NetEqStatsGetter was created
	// for, this method generates a plot for the jitter buffer delay profile.
	void CreateAudioJitterBufferGraph(const ParsedRtcEventLog& parsed_log,
	const AnalyzerConfig& config,
	uint32_t ssrc,
	const test::NetEqStatsGetter* stats_getter,
	Plot* plot) {
	test::NetEqDelayAnalyzer::Delays arrival_delay_ms;
	test::NetEqDelayAnalyzer::Delays corrected_arrival_delay_ms;
	test::NetEqDelayAnalyzer::Delays playout_delay_ms;
	test::NetEqDelayAnalyzer::Delays target_delay_ms;

	stats_getter->delay_analyzer()->CreateGraphs(
	&arrival_delay_ms, &corrected_arrival_delay_ms, &playout_delay_ms,
	&target_delay_ms);

	TimeSeries time_series_packet_arrival("packet arrival delay",
	LineStyle::kLine);
	TimeSeries time_series_relative_packet_arrival(
	"Relative packet arrival delay", LineStyle::kLine);
	TimeSeries time_series_play_time("Playout delay", LineStyle::kLine);
	TimeSeries time_series_target_time("Target delay", LineStyle::kLine,
	PointStyle::kHighlight);

	for (const auto& data : arrival_delay_ms) {
	const float x = config.GetCallTimeSec(Timestamp::Millis(data.first));
	const float y = data.second;
	time_series_packet_arrival.points.emplace_back(TimeSeriesPoint(x, y));
	}
	for (const auto& data : corrected_arrival_delay_ms) {
	const float x = config.GetCallTimeSec(Timestamp::Millis(data.first));
	const float y = data.second;
	time_series_relative_packet_arrival.points.emplace_back(
	TimeSeriesPoint(x, y));
	}
	for (const auto& data : playout_delay_ms) {
	const float x = config.GetCallTimeSec(Timestamp::Millis(data.first));
	const float y = data.second;
	time_series_play_time.points.emplace_back(TimeSeriesPoint(x, y));
	}
	for (const auto& data : target_delay_ms) {
	const float x = config.GetCallTimeSec(Timestamp::Millis(data.first));
	const float y = data.second;
	time_series_target_time.points.emplace_back(TimeSeriesPoint(x, y));
	}

	plot->AppendTimeSeries(std::move(time_series_packet_arrival));
	plot->AppendTimeSeries(std::move(time_series_relative_packet_arrival));
	plot->AppendTimeSeries(std::move(time_series_play_time));
	plot->AppendTimeSeries(std::move(time_series_target_time));

	plot->SetXAxis(config.CallBeginTimeSec(), config.CallEndTimeSec(), "Time (s)",
	kLeftMargin, kRightMargin);
	plot->SetSuggestedYAxis(0, 1, "Relative delay (ms)", kBottomMargin,
	kTopMargin);
	plot->SetTitle("NetEq timing for " +
	GetStreamName(parsed_log, kIncomingPacket, ssrc));
	}

	template <typename NetEqStatsType>
	void CreateNetEqStatsGraphInternal(
	const ParsedRtcEventLog& parsed_log,
	const AnalyzerConfig& config,
	const NetEqStatsGetterMap& neteq_stats,
	rtc::FunctionView<const std::vector<std::pair<int64_t, NetEqStatsType>>*(
	const test::NetEqStatsGetter*)> data_extractor,
	rtc::FunctionView<float(const NetEqStatsType&)> stats_extractor,
	const std::string& plot_name,
	Plot* plot) {
	std::map<uint32_t, TimeSeries> time_series;

	for (const auto& st : neteq_stats) {
	const uint32_t ssrc = st.first;
	const std::vector<std::pair<int64_t, NetEqStatsType>>* data_vector =
	data_extractor(st.second.get());
	for (const auto& data : *data_vector) {
	const float time = config.GetCallTimeSec(Timestamp::Millis(data.first));
	const float value = stats_extractor(data.second);
	time_series[ssrc].points.emplace_back(TimeSeriesPoint(time, value));
	}
	}

	for (auto& series : time_series) {
	series.second.label =
	GetStreamName(parsed_log, kIncomingPacket, series.first);
	series.second.line_style = LineStyle::kLine;
	plot->AppendTimeSeries(std::move(series.second));
	}

	plot->SetXAxis(config.CallBeginTimeSec(), config.CallEndTimeSec(), "Time (s)",
	kLeftMargin, kRightMargin);
	plot->SetSuggestedYAxis(0, 1, plot_name, kBottomMargin, kTopMargin);
	plot->SetTitle(plot_name);
	}

	void CreateNetEqNetworkStatsGraph(
	const ParsedRtcEventLog& parsed_log,
	const AnalyzerConfig& config,
	const NetEqStatsGetterMap& neteq_stats,
	rtc::FunctionView<float(const NetEqNetworkStatistics&)> stats_extractor,
	const std::string& plot_name,
	Plot* plot) {
	CreateNetEqStatsGraphInternal<NetEqNetworkStatistics>(
	parsed_log, config, neteq_stats,
	[](const test::NetEqStatsGetter* stats_getter) {
	return stats_getter->stats();
	},
	stats_extractor, plot_name, plot);
	}

	void CreateNetEqLifetimeStatsGraph(
	const ParsedRtcEventLog& parsed_log,
	const AnalyzerConfig& config,
	const NetEqStatsGetterMap& neteq_stats,
	rtc::FunctionView<float(const NetEqLifetimeStatistics&)> stats_extractor,
	const std::string& plot_name,
	Plot* plot) {
	CreateNetEqStatsGraphInternal<NetEqLifetimeStatistics>(
	parsed_log, config, neteq_stats,
	[](const test::NetEqStatsGetter* stats_getter) {
	return stats_getter->lifetime_stats();
	},
	stats_extractor, plot_name, plot);
	}

	} // namespace webrtc