| /* |
| * Copyright (c) 2016 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/event_log_visualizer/analyzer.h" |
| |
| #include <algorithm> |
| #include <cmath> |
| #include <limits> |
| #include <map> |
| #include <string> |
| #include <utility> |
| |
| #include "absl/memory/memory.h" |
| #include "absl/strings/string_view.h" |
| #include "api/transport/field_trial_based_config.h" |
| #include "api/transport/goog_cc_factory.h" |
| #include "call/audio_receive_stream.h" |
| #include "call/audio_send_stream.h" |
| #include "call/call.h" |
| #include "call/video_receive_stream.h" |
| #include "call/video_send_stream.h" |
| #include "common_types.h" // NOLINT(build/include) |
| #include "logging/rtc_event_log/rtc_stream_config.h" |
| #include "modules/audio_coding/audio_network_adaptor/include/audio_network_adaptor.h" |
| #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_replacement_input.h" |
| #include "modules/audio_coding/neteq/tools/neteq_test.h" |
| #include "modules/audio_coding/neteq/tools/resample_input_audio_file.h" |
| #include "modules/congestion_controller/goog_cc/acknowledged_bitrate_estimator.h" |
| #include "modules/congestion_controller/goog_cc/bitrate_estimator.h" |
| #include "modules/congestion_controller/goog_cc/delay_based_bwe.h" |
| #include "modules/congestion_controller/include/receive_side_congestion_controller.h" |
| #include "modules/congestion_controller/rtp/transport_feedback_adapter.h" |
| #include "modules/pacing/packet_router.h" |
| #include "modules/remote_bitrate_estimator/include/bwe_defines.h" |
| #include "modules/rtp_rtcp/include/rtp_rtcp.h" |
| #include "modules/rtp_rtcp/include/rtp_rtcp_defines.h" |
| #include "modules/rtp_rtcp/source/rtcp_packet.h" |
| #include "modules/rtp_rtcp/source/rtcp_packet/common_header.h" |
| #include "modules/rtp_rtcp/source/rtcp_packet/receiver_report.h" |
| #include "modules/rtp_rtcp/source/rtcp_packet/remb.h" |
| #include "modules/rtp_rtcp/source/rtcp_packet/sender_report.h" |
| #include "modules/rtp_rtcp/source/rtcp_packet/transport_feedback.h" |
| #include "modules/rtp_rtcp/source/rtp_header_extensions.h" |
| #include "modules/rtp_rtcp/source/rtp_utility.h" |
| #include "rtc_base/checks.h" |
| #include "rtc_base/format_macros.h" |
| #include "rtc_base/function_view.h" |
| #include "rtc_base/logging.h" |
| #include "rtc_base/numerics/sequence_number_util.h" |
| #include "rtc_base/rate_statistics.h" |
| #include "rtc_base/strings/string_builder.h" |
| |
| #ifndef BWE_TEST_LOGGING_COMPILE_TIME_ENABLE |
| #define BWE_TEST_LOGGING_COMPILE_TIME_ENABLE 0 |
| #endif // BWE_TEST_LOGGING_COMPILE_TIME_ENABLE |
| |
| namespace webrtc { |
| |
| namespace { |
| |
| const int kNumMicrosecsPerSec = 1000000; |
| |
| void SortPacketFeedbackVector(std::vector<PacketFeedback>* vec) { |
| auto pred = [](const PacketFeedback& packet_feedback) { |
| return packet_feedback.arrival_time_ms == PacketFeedback::kNotReceived; |
| }; |
| vec->erase(std::remove_if(vec->begin(), vec->end(), pred), vec->end()); |
| std::sort(vec->begin(), vec->end(), PacketFeedbackComparator()); |
| } |
| |
| std::string SsrcToString(uint32_t ssrc) { |
| rtc::StringBuilder ss; |
| ss << "SSRC " << ssrc; |
| return ss.Release(); |
| } |
| |
| // Checks whether an SSRC is contained in the list of desired SSRCs. |
| // Note that an empty SSRC list matches every SSRC. |
| bool MatchingSsrc(uint32_t ssrc, const std::vector<uint32_t>& desired_ssrc) { |
| if (desired_ssrc.size() == 0) |
| return true; |
| return std::find(desired_ssrc.begin(), desired_ssrc.end(), ssrc) != |
| desired_ssrc.end(); |
| } |
| |
| double AbsSendTimeToMicroseconds(int64_t abs_send_time) { |
| // The timestamp is a fixed point representation with 6 bits for seconds |
| // and 18 bits for fractions of a second. Thus, we divide by 2^18 to get the |
| // time in seconds and then multiply by kNumMicrosecsPerSec to convert to |
| // microseconds. |
| static constexpr double kTimestampToMicroSec = |
| static_cast<double>(kNumMicrosecsPerSec) / static_cast<double>(1ul << 18); |
| return abs_send_time * kTimestampToMicroSec; |
| } |
| |
| // Computes the difference |later| - |earlier| where |later| and |earlier| |
| // are counters that wrap at |modulus|. The difference is chosen to have the |
| // least absolute value. For example if |modulus| is 8, then the difference will |
| // be chosen in the range [-3, 4]. If |modulus| is 9, then the difference will |
| // be in [-4, 4]. |
| int64_t WrappingDifference(uint32_t later, uint32_t earlier, int64_t modulus) { |
| RTC_DCHECK_LE(1, modulus); |
| RTC_DCHECK_LT(later, modulus); |
| RTC_DCHECK_LT(earlier, modulus); |
| int64_t difference = |
| static_cast<int64_t>(later) - static_cast<int64_t>(earlier); |
| int64_t max_difference = modulus / 2; |
| int64_t min_difference = max_difference - modulus + 1; |
| if (difference > max_difference) { |
| difference -= modulus; |
| } |
| if (difference < min_difference) { |
| difference += modulus; |
| } |
| if (difference > max_difference / 2 || difference < min_difference / 2) { |
| RTC_LOG(LS_WARNING) << "Difference between" << later << " and " << earlier |
| << " expected to be in the range (" |
| << min_difference / 2 << "," << max_difference / 2 |
| << ") but is " << difference |
| << ". Correct unwrapping is uncertain."; |
| } |
| return difference; |
| } |
| |
| // This is much more reliable for outgoing streams than for incoming streams. |
| template <typename RtpPacketContainer> |
| absl::optional<uint32_t> EstimateRtpClockFrequency( |
| const RtpPacketContainer& packets, |
| int64_t end_time_us) { |
| RTC_CHECK(packets.size() >= 2); |
| SeqNumUnwrapper<uint32_t> unwrapper; |
| uint64_t first_rtp_timestamp = |
| unwrapper.Unwrap(packets[0].rtp.header.timestamp); |
| int64_t first_log_timestamp = packets[0].log_time_us(); |
| uint64_t last_rtp_timestamp = first_rtp_timestamp; |
| int64_t last_log_timestamp = first_log_timestamp; |
| for (size_t i = 1; i < packets.size(); i++) { |
| if (packets[i].log_time_us() > end_time_us) |
| break; |
| last_rtp_timestamp = unwrapper.Unwrap(packets[i].rtp.header.timestamp); |
| last_log_timestamp = packets[i].log_time_us(); |
| } |
| if (last_log_timestamp - first_log_timestamp < kNumMicrosecsPerSec) { |
| RTC_LOG(LS_WARNING) |
| << "Failed to estimate RTP clock frequency: Stream too short. (" |
| << packets.size() << " packets, " |
| << last_log_timestamp - first_log_timestamp << " us)"; |
| return absl::nullopt; |
| } |
| double duration = |
| static_cast<double>(last_log_timestamp - first_log_timestamp) / |
| kNumMicrosecsPerSec; |
| double estimated_frequency = |
| (last_rtp_timestamp - first_rtp_timestamp) / duration; |
| for (uint32_t f : {8000, 16000, 32000, 48000, 90000}) { |
| if (std::fabs(estimated_frequency - f) < 0.05 * f) { |
| return f; |
| } |
| } |
| RTC_LOG(LS_WARNING) << "Failed to estimate RTP clock frequency: Estimate " |
| << estimated_frequency |
| << "not close to any stardard RTP frequency."; |
| return absl::nullopt; |
| } |
| |
| constexpr float kLeftMargin = 0.01f; |
| constexpr float kRightMargin = 0.02f; |
| constexpr float kBottomMargin = 0.02f; |
| constexpr float kTopMargin = 0.05f; |
| |
| absl::optional<double> NetworkDelayDiff_AbsSendTime( |
| const LoggedRtpPacketIncoming& old_packet, |
| const LoggedRtpPacketIncoming& new_packet) { |
| if (old_packet.rtp.header.extension.hasAbsoluteSendTime && |
| new_packet.rtp.header.extension.hasAbsoluteSendTime) { |
| int64_t send_time_diff = WrappingDifference( |
| new_packet.rtp.header.extension.absoluteSendTime, |
| old_packet.rtp.header.extension.absoluteSendTime, 1ul << 24); |
| int64_t recv_time_diff = |
| new_packet.log_time_us() - old_packet.log_time_us(); |
| double delay_change_us = |
| recv_time_diff - AbsSendTimeToMicroseconds(send_time_diff); |
| return delay_change_us / 1000; |
| } else { |
| return absl::nullopt; |
| } |
| } |
| |
| absl::optional<double> NetworkDelayDiff_CaptureTime( |
| const LoggedRtpPacketIncoming& old_packet, |
| const LoggedRtpPacketIncoming& new_packet, |
| const double sample_rate) { |
| int64_t send_time_diff = |
| WrappingDifference(new_packet.rtp.header.timestamp, |
| old_packet.rtp.header.timestamp, 1ull << 32); |
| int64_t recv_time_diff = new_packet.log_time_us() - old_packet.log_time_us(); |
| |
| double delay_change = |
| static_cast<double>(recv_time_diff) / 1000 - |
| static_cast<double>(send_time_diff) / sample_rate * 1000; |
| if (delay_change < -10000 || 10000 < delay_change) { |
| RTC_LOG(LS_WARNING) << "Very large delay change. Timestamps correct?"; |
| RTC_LOG(LS_WARNING) << "Old capture time " |
| << old_packet.rtp.header.timestamp << ", received time " |
| << old_packet.log_time_us(); |
| RTC_LOG(LS_WARNING) << "New capture time " |
| << new_packet.rtp.header.timestamp << ", received time " |
| << new_packet.log_time_us(); |
| RTC_LOG(LS_WARNING) << "Receive time difference " << recv_time_diff << " = " |
| << static_cast<double>(recv_time_diff) / |
| kNumMicrosecsPerSec |
| << "s"; |
| RTC_LOG(LS_WARNING) << "Send time difference " << send_time_diff << " = " |
| << static_cast<double>(send_time_diff) / sample_rate |
| << "s"; |
| } |
| return delay_change; |
| } |
| |
| // For each element in data_view, use |f()| to extract a y-coordinate and |
| // store the result in a TimeSeries. |
| template <typename DataType, typename IterableType> |
| void ProcessPoints(rtc::FunctionView<float(const DataType&)> fx, |
| rtc::FunctionView<absl::optional<float>(const DataType&)> fy, |
| const IterableType& data_view, |
| TimeSeries* result) { |
| for (size_t i = 0; i < data_view.size(); i++) { |
| const DataType& elem = data_view[i]; |
| float x = fx(elem); |
| absl::optional<float> y = fy(elem); |
| if (y) |
| result->points.emplace_back(x, *y); |
| } |
| } |
| |
| // For each pair of adjacent elements in |data|, use |f()| to extract a |
| // y-coordinate and store the result in a TimeSeries. Note that the x-coordinate |
| // will be the time of the second element in the pair. |
| template <typename DataType, typename ResultType, typename IterableType> |
| void ProcessPairs( |
| rtc::FunctionView<float(const DataType&)> fx, |
| rtc::FunctionView<absl::optional<ResultType>(const DataType&, |
| const DataType&)> fy, |
| const IterableType& data, |
| TimeSeries* result) { |
| for (size_t i = 1; i < data.size(); i++) { |
| float x = fx(data[i]); |
| absl::optional<ResultType> y = fy(data[i - 1], data[i]); |
| if (y) |
| result->points.emplace_back(x, static_cast<float>(*y)); |
| } |
| } |
| |
| // For each pair of adjacent elements in |data|, use |f()| to extract a |
| // y-coordinate and store the result in a TimeSeries. Note that the x-coordinate |
| // will be the time of the second element in the pair. |
| template <typename DataType, typename ResultType, typename IterableType> |
| void AccumulatePairs( |
| rtc::FunctionView<float(const DataType&)> fx, |
| rtc::FunctionView<absl::optional<ResultType>(const DataType&, |
| const DataType&)> fy, |
| const IterableType& data, |
| TimeSeries* result) { |
| ResultType sum = 0; |
| for (size_t i = 1; i < data.size(); i++) { |
| float x = fx(data[i]); |
| absl::optional<ResultType> y = fy(data[i - 1], data[i]); |
| if (y) { |
| sum += *y; |
| result->points.emplace_back(x, static_cast<float>(sum)); |
| } |
| } |
| } |
| |
| // Calculates a moving average of |data| and stores the result in a TimeSeries. |
| // A data point is generated every |step| microseconds from |begin_time| |
| // to |end_time|. The value of each data point is the average of the data |
| // during the preceeding |window_duration_us| microseconds. |
| template <typename DataType, typename ResultType, typename IterableType> |
| void MovingAverage( |
| rtc::FunctionView<float(int64_t)> fx, |
| rtc::FunctionView<absl::optional<ResultType>(const DataType&)> fy, |
| const IterableType& data_view, |
| int64_t begin_time, |
| int64_t end_time, |
| int64_t window_duration_us, |
| int64_t step, |
| TimeSeries* result) { |
| size_t window_index_begin = 0; |
| size_t window_index_end = 0; |
| ResultType sum_in_window = 0; |
| |
| for (int64_t t = begin_time; t < end_time + step; t += step) { |
| while (window_index_end < data_view.size() && |
| data_view[window_index_end].log_time_us() < t) { |
| absl::optional<ResultType> value = fy(data_view[window_index_end]); |
| if (value) |
| sum_in_window += *value; |
| ++window_index_end; |
| } |
| while (window_index_begin < data_view.size() && |
| data_view[window_index_begin].log_time_us() < |
| t - window_duration_us) { |
| absl::optional<ResultType> value = fy(data_view[window_index_begin]); |
| if (value) |
| sum_in_window -= *value; |
| ++window_index_begin; |
| } |
| float window_duration_s = |
| static_cast<float>(window_duration_us) / kNumMicrosecsPerSec; |
| float x = fx(t); |
| float y = sum_in_window / window_duration_s; |
| result->points.emplace_back(x, y); |
| } |
| } |
| |
| const char kUnknownEnumValue[] = "unknown"; |
| |
| const char kIceCandidateTypeLocal[] = "local"; |
| const char kIceCandidateTypeStun[] = "stun"; |
| const char kIceCandidateTypePrflx[] = "prflx"; |
| const char kIceCandidateTypeRelay[] = "relay"; |
| |
| const char kProtocolUdp[] = "udp"; |
| const char kProtocolTcp[] = "tcp"; |
| const char kProtocolSsltcp[] = "ssltcp"; |
| const char kProtocolTls[] = "tls"; |
| |
| const char kAddressFamilyIpv4[] = "ipv4"; |
| const char kAddressFamilyIpv6[] = "ipv6"; |
| |
| const char kNetworkTypeEthernet[] = "ethernet"; |
| const char kNetworkTypeLoopback[] = "loopback"; |
| const char kNetworkTypeWifi[] = "wifi"; |
| const char kNetworkTypeVpn[] = "vpn"; |
| const char kNetworkTypeCellular[] = "cellular"; |
| |
| std::string GetIceCandidateTypeAsString(webrtc::IceCandidateType type) { |
| switch (type) { |
| case webrtc::IceCandidateType::kLocal: |
| return kIceCandidateTypeLocal; |
| case webrtc::IceCandidateType::kStun: |
| return kIceCandidateTypeStun; |
| case webrtc::IceCandidateType::kPrflx: |
| return kIceCandidateTypePrflx; |
| case webrtc::IceCandidateType::kRelay: |
| return kIceCandidateTypeRelay; |
| default: |
| return kUnknownEnumValue; |
| } |
| } |
| |
| std::string GetProtocolAsString(webrtc::IceCandidatePairProtocol protocol) { |
| switch (protocol) { |
| case webrtc::IceCandidatePairProtocol::kUdp: |
| return kProtocolUdp; |
| case webrtc::IceCandidatePairProtocol::kTcp: |
| return kProtocolTcp; |
| case webrtc::IceCandidatePairProtocol::kSsltcp: |
| return kProtocolSsltcp; |
| case webrtc::IceCandidatePairProtocol::kTls: |
| return kProtocolTls; |
| default: |
| return kUnknownEnumValue; |
| } |
| } |
| |
| std::string GetAddressFamilyAsString( |
| webrtc::IceCandidatePairAddressFamily family) { |
| switch (family) { |
| case webrtc::IceCandidatePairAddressFamily::kIpv4: |
| return kAddressFamilyIpv4; |
| case webrtc::IceCandidatePairAddressFamily::kIpv6: |
| return kAddressFamilyIpv6; |
| default: |
| return kUnknownEnumValue; |
| } |
| } |
| |
| std::string GetNetworkTypeAsString(webrtc::IceCandidateNetworkType type) { |
| switch (type) { |
| case webrtc::IceCandidateNetworkType::kEthernet: |
| return kNetworkTypeEthernet; |
| case webrtc::IceCandidateNetworkType::kLoopback: |
| return kNetworkTypeLoopback; |
| case webrtc::IceCandidateNetworkType::kWifi: |
| return kNetworkTypeWifi; |
| case webrtc::IceCandidateNetworkType::kVpn: |
| return kNetworkTypeVpn; |
| case webrtc::IceCandidateNetworkType::kCellular: |
| return kNetworkTypeCellular; |
| default: |
| return kUnknownEnumValue; |
| } |
| } |
| |
| std::string GetCandidatePairLogDescriptionAsString( |
| const LoggedIceCandidatePairConfig& config) { |
| // Example: stun:wifi->relay(tcp):cellular@udp:ipv4 |
| // represents a pair of a local server-reflexive candidate on a WiFi network |
| // and a remote relay candidate using TCP as the relay protocol on a cell |
| // network, when the candidate pair communicates over UDP using IPv4. |
| rtc::StringBuilder ss; |
| std::string local_candidate_type = |
| GetIceCandidateTypeAsString(config.local_candidate_type); |
| std::string remote_candidate_type = |
| GetIceCandidateTypeAsString(config.remote_candidate_type); |
| if (config.local_candidate_type == webrtc::IceCandidateType::kRelay) { |
| local_candidate_type += |
| "(" + GetProtocolAsString(config.local_relay_protocol) + ")"; |
| } |
| ss << local_candidate_type << ":" |
| << GetNetworkTypeAsString(config.local_network_type) << ":" |
| << GetAddressFamilyAsString(config.local_address_family) << "->" |
| << remote_candidate_type << ":" |
| << GetAddressFamilyAsString(config.remote_address_family) << "@" |
| << GetProtocolAsString(config.candidate_pair_protocol); |
| return ss.Release(); |
| } |
| |
| std::string GetDirectionAsString(PacketDirection direction) { |
| if (direction == kIncomingPacket) { |
| return "Incoming"; |
| } else { |
| return "Outgoing"; |
| } |
| } |
| |
| std::string GetDirectionAsShortString(PacketDirection direction) { |
| if (direction == kIncomingPacket) { |
| return "In"; |
| } else { |
| return "Out"; |
| } |
| } |
| |
| } // namespace |
| |
| EventLogAnalyzer::EventLogAnalyzer(const ParsedRtcEventLog& log, |
| bool normalize_time) |
| : parsed_log_(log), |
| window_duration_(250000), |
| step_(10000), |
| normalize_time_(normalize_time) { |
| begin_time_ = parsed_log_.first_timestamp(); |
| end_time_ = parsed_log_.last_timestamp(); |
| if (end_time_ < begin_time_) { |
| RTC_LOG(LS_WARNING) << "No useful events in the log."; |
| begin_time_ = end_time_ = 0; |
| } |
| call_duration_s_ = ToCallTimeSec(end_time_); |
| |
| const auto& log_start_events = parsed_log_.start_log_events(); |
| const auto& log_end_events = parsed_log_.stop_log_events(); |
| auto start_iter = log_start_events.begin(); |
| auto end_iter = log_end_events.begin(); |
| while (start_iter != log_start_events.end()) { |
| int64_t start = start_iter->log_time_us(); |
| ++start_iter; |
| absl::optional<int64_t> next_start; |
| if (start_iter != log_start_events.end()) |
| next_start.emplace(start_iter->log_time_us()); |
| if (end_iter != log_end_events.end() && |
| end_iter->log_time_us() <= |
| next_start.value_or(std::numeric_limits<int64_t>::max())) { |
| int64_t end = end_iter->log_time_us(); |
| RTC_DCHECK_LE(start, end); |
| log_segments_.push_back(std::make_pair(start, end)); |
| ++end_iter; |
| } else { |
| // we're missing an end event. Assume that it occurred just before the |
| // next start. |
| log_segments_.push_back( |
| std::make_pair(start, next_start.value_or(end_time_))); |
| } |
| } |
| RTC_LOG(LS_INFO) << "Found " << log_segments_.size() |
| << " (LOG_START, LOG_END) segments in log."; |
| } |
| |
| class BitrateObserver : public RemoteBitrateObserver { |
| public: |
| BitrateObserver() : last_bitrate_bps_(0), bitrate_updated_(false) {} |
| |
| void Update(NetworkControlUpdate update) { |
| if (update.target_rate) { |
| last_bitrate_bps_ = update.target_rate->target_rate.bps(); |
| bitrate_updated_ = true; |
| } |
| } |
| |
| void OnReceiveBitrateChanged(const std::vector<uint32_t>& ssrcs, |
| uint32_t bitrate) override {} |
| |
| uint32_t last_bitrate_bps() const { return last_bitrate_bps_; } |
| bool GetAndResetBitrateUpdated() { |
| bool bitrate_updated = bitrate_updated_; |
| bitrate_updated_ = false; |
| return bitrate_updated; |
| } |
| |
| private: |
| uint32_t last_bitrate_bps_; |
| bool bitrate_updated_; |
| }; |
| |
| int64_t EventLogAnalyzer::ToCallTimeUs(int64_t timestamp) const { |
| int64_t begin_time = 0; |
| if (normalize_time_) { |
| begin_time = begin_time_; |
| } |
| return timestamp - begin_time; |
| } |
| |
| float EventLogAnalyzer::ToCallTimeSec(int64_t timestamp) const { |
| return static_cast<float>(ToCallTimeUs(timestamp)) / kNumMicrosecsPerSec; |
| } |
| |
| void EventLogAnalyzer::CreatePacketGraph(PacketDirection direction, |
| Plot* plot) { |
| for (const auto& stream : parsed_log_.rtp_packets_by_ssrc(direction)) { |
| // Filter on SSRC. |
| if (!MatchingSsrc(stream.ssrc, desired_ssrc_)) { |
| continue; |
| } |
| |
| TimeSeries time_series(GetStreamName(direction, stream.ssrc), |
| LineStyle::kBar); |
| auto GetPacketSize = [](const LoggedRtpPacket& packet) { |
| return absl::optional<float>(packet.total_length); |
| }; |
| auto ToCallTime = [this](const LoggedRtpPacket& packet) { |
| return this->ToCallTimeSec(packet.log_time_us()); |
| }; |
| ProcessPoints<LoggedRtpPacket>(ToCallTime, GetPacketSize, |
| stream.packet_view, &time_series); |
| plot->AppendTimeSeries(std::move(time_series)); |
| } |
| |
| plot->SetXAxis(ToCallTimeSec(begin_time_), call_duration_s_, "Time (s)", |
| kLeftMargin, kRightMargin); |
| plot->SetSuggestedYAxis(0, 1, "Packet size (bytes)", kBottomMargin, |
| kTopMargin); |
| plot->SetTitle(GetDirectionAsString(direction) + " RTP packets"); |
| } |
| |
| template <typename IterableType> |
| void EventLogAnalyzer::CreateAccumulatedPacketsTimeSeries( |
| Plot* plot, |
| const IterableType& packets, |
| const std::string& label) { |
| TimeSeries time_series(label, LineStyle::kStep); |
| for (size_t i = 0; i < packets.size(); i++) { |
| float x = ToCallTimeSec(packets[i].log_time_us()); |
| time_series.points.emplace_back(x, i + 1); |
| } |
| plot->AppendTimeSeries(std::move(time_series)); |
| } |
| |
| void EventLogAnalyzer::CreateAccumulatedPacketsGraph(PacketDirection direction, |
| Plot* plot) { |
| for (const auto& stream : parsed_log_.rtp_packets_by_ssrc(direction)) { |
| if (!MatchingSsrc(stream.ssrc, desired_ssrc_)) |
| continue; |
| std::string label = |
| std::string("RTP ") + GetStreamName(direction, stream.ssrc); |
| CreateAccumulatedPacketsTimeSeries(plot, stream.packet_view, label); |
| } |
| std::string label = |
| std::string("RTCP ") + "(" + GetDirectionAsShortString(direction) + ")"; |
| if (direction == kIncomingPacket) { |
| CreateAccumulatedPacketsTimeSeries( |
| plot, parsed_log_.incoming_rtcp_packets(), label); |
| } else { |
| CreateAccumulatedPacketsTimeSeries( |
| plot, parsed_log_.outgoing_rtcp_packets(), label); |
| } |
| |
| plot->SetXAxis(ToCallTimeSec(begin_time_), call_duration_s_, "Time (s)", |
| kLeftMargin, kRightMargin); |
| plot->SetSuggestedYAxis(0, 1, "Received Packets", kBottomMargin, kTopMargin); |
| plot->SetTitle(std::string("Accumulated ") + GetDirectionAsString(direction) + |
| " RTP/RTCP packets"); |
| } |
| |
| // For each SSRC, plot the time between the consecutive playouts. |
| void EventLogAnalyzer::CreatePlayoutGraph(Plot* plot) { |
| for (const auto& playout_stream : parsed_log_.audio_playout_events()) { |
| uint32_t ssrc = playout_stream.first; |
| if (!MatchingSsrc(ssrc, desired_ssrc_)) |
| continue; |
| absl::optional<int64_t> last_playout_ms; |
| TimeSeries time_series(SsrcToString(ssrc), LineStyle::kBar); |
| for (const auto& playout_event : playout_stream.second) { |
| float x = ToCallTimeSec(playout_event.log_time_us()); |
| int64_t playout_time_ms = playout_event.log_time_ms(); |
| // If there were no previous playouts, place the point on the x-axis. |
| float y = playout_time_ms - last_playout_ms.value_or(playout_time_ms); |
| time_series.points.push_back(TimeSeriesPoint(x, y)); |
| last_playout_ms.emplace(playout_time_ms); |
| } |
| plot->AppendTimeSeries(std::move(time_series)); |
| } |
| |
| plot->SetXAxis(ToCallTimeSec(begin_time_), call_duration_s_, "Time (s)", |
| kLeftMargin, kRightMargin); |
| plot->SetSuggestedYAxis(0, 1, "Time since last playout (ms)", kBottomMargin, |
| kTopMargin); |
| plot->SetTitle("Audio playout"); |
| } |
| |
| // For audio SSRCs, plot the audio level. |
| void EventLogAnalyzer::CreateAudioLevelGraph(PacketDirection direction, |
| Plot* plot) { |
| for (const auto& stream : parsed_log_.rtp_packets_by_ssrc(direction)) { |
| if (!IsAudioSsrc(direction, stream.ssrc)) |
| continue; |
| TimeSeries time_series(GetStreamName(direction, stream.ssrc), |
| LineStyle::kLine); |
| for (auto& packet : stream.packet_view) { |
| if (packet.header.extension.hasAudioLevel) { |
| float x = ToCallTimeSec(packet.log_time_us()); |
| // The audio level is stored in -dBov (so e.g. -10 dBov is stored as 10) |
| // Here we convert it to dBov. |
| float y = static_cast<float>(-packet.header.extension.audioLevel); |
| time_series.points.emplace_back(TimeSeriesPoint(x, y)); |
| } |
| } |
| plot->AppendTimeSeries(std::move(time_series)); |
| } |
| |
| plot->SetXAxis(ToCallTimeSec(begin_time_), call_duration_s_, "Time (s)", |
| kLeftMargin, kRightMargin); |
| plot->SetYAxis(-127, 0, "Audio level (dBov)", kBottomMargin, kTopMargin); |
| plot->SetTitle(GetDirectionAsString(direction) + " audio level"); |
| } |
| |
| // For each SSRC, plot the time between the consecutive playouts. |
| void EventLogAnalyzer::CreateSequenceNumberGraph(Plot* plot) { |
| for (const auto& stream : parsed_log_.incoming_rtp_packets_by_ssrc()) { |
| // Filter on SSRC. |
| if (!MatchingSsrc(stream.ssrc, desired_ssrc_)) { |
| continue; |
| } |
| |
| TimeSeries time_series(GetStreamName(kIncomingPacket, stream.ssrc), |
| LineStyle::kBar); |
| auto GetSequenceNumberDiff = [](const LoggedRtpPacketIncoming& old_packet, |
| const LoggedRtpPacketIncoming& new_packet) { |
| int64_t diff = |
| WrappingDifference(new_packet.rtp.header.sequenceNumber, |
| old_packet.rtp.header.sequenceNumber, 1ul << 16); |
| return diff; |
| }; |
| auto ToCallTime = [this](const LoggedRtpPacketIncoming& packet) { |
| return this->ToCallTimeSec(packet.log_time_us()); |
| }; |
| ProcessPairs<LoggedRtpPacketIncoming, float>( |
| ToCallTime, GetSequenceNumberDiff, stream.incoming_packets, |
| &time_series); |
| plot->AppendTimeSeries(std::move(time_series)); |
| } |
| |
| plot->SetXAxis(ToCallTimeSec(begin_time_), call_duration_s_, "Time (s)", |
| kLeftMargin, kRightMargin); |
| plot->SetSuggestedYAxis(0, 1, "Difference since last packet", kBottomMargin, |
| kTopMargin); |
| plot->SetTitle("Sequence number"); |
| } |
| |
| void EventLogAnalyzer::CreateIncomingPacketLossGraph(Plot* plot) { |
| for (const auto& stream : parsed_log_.incoming_rtp_packets_by_ssrc()) { |
| const std::vector<LoggedRtpPacketIncoming>& packets = |
| stream.incoming_packets; |
| // Filter on SSRC. |
| if (!MatchingSsrc(stream.ssrc, desired_ssrc_) || packets.size() == 0) { |
| continue; |
| } |
| |
| TimeSeries time_series(GetStreamName(kIncomingPacket, stream.ssrc), |
| LineStyle::kLine, PointStyle::kHighlight); |
| // TODO(terelius): Should the window and step size be read from the class |
| // instead? |
| const int64_t kWindowUs = 1000000; |
| const int64_t kStep = 1000000; |
| SeqNumUnwrapper<uint16_t> unwrapper_; |
| SeqNumUnwrapper<uint16_t> prior_unwrapper_; |
| size_t window_index_begin = 0; |
| size_t window_index_end = 0; |
| uint64_t highest_seq_number = |
| unwrapper_.Unwrap(packets[0].rtp.header.sequenceNumber) - 1; |
| uint64_t highest_prior_seq_number = |
| prior_unwrapper_.Unwrap(packets[0].rtp.header.sequenceNumber) - 1; |
| |
| for (int64_t t = begin_time_; t < end_time_ + kStep; t += kStep) { |
| while (window_index_end < packets.size() && |
| packets[window_index_end].rtp.log_time_us() < t) { |
| uint64_t sequence_number = unwrapper_.Unwrap( |
| packets[window_index_end].rtp.header.sequenceNumber); |
| highest_seq_number = std::max(highest_seq_number, sequence_number); |
| ++window_index_end; |
| } |
| while (window_index_begin < packets.size() && |
| packets[window_index_begin].rtp.log_time_us() < t - kWindowUs) { |
| uint64_t sequence_number = prior_unwrapper_.Unwrap( |
| packets[window_index_begin].rtp.header.sequenceNumber); |
| highest_prior_seq_number = |
| std::max(highest_prior_seq_number, sequence_number); |
| ++window_index_begin; |
| } |
| float x = ToCallTimeSec(t); |
| uint64_t expected_packets = highest_seq_number - highest_prior_seq_number; |
| if (expected_packets > 0) { |
| int64_t received_packets = window_index_end - window_index_begin; |
| int64_t lost_packets = expected_packets - received_packets; |
| float y = static_cast<float>(lost_packets) / expected_packets * 100; |
| time_series.points.emplace_back(x, y); |
| } |
| } |
| plot->AppendTimeSeries(std::move(time_series)); |
| } |
| |
| plot->SetXAxis(ToCallTimeSec(begin_time_), call_duration_s_, "Time (s)", |
| kLeftMargin, kRightMargin); |
| plot->SetSuggestedYAxis(0, 1, "Estimated loss rate (%)", kBottomMargin, |
| kTopMargin); |
| plot->SetTitle("Estimated incoming loss rate"); |
| } |
| |
| void EventLogAnalyzer::CreateIncomingDelayGraph(Plot* plot) { |
| for (const auto& stream : parsed_log_.incoming_rtp_packets_by_ssrc()) { |
| // Filter on SSRC. |
| if (!MatchingSsrc(stream.ssrc, desired_ssrc_) || |
| IsRtxSsrc(kIncomingPacket, stream.ssrc)) { |
| continue; |
| } |
| |
| const std::vector<LoggedRtpPacketIncoming>& packets = |
| stream.incoming_packets; |
| if (packets.size() < 100) { |
| RTC_LOG(LS_WARNING) << "Can't estimate the RTP clock frequency with " |
| << packets.size() << " packets in the stream."; |
| continue; |
| } |
| int64_t end_time_us = log_segments_.empty() |
| ? std::numeric_limits<int64_t>::max() |
| : log_segments_.front().second; |
| absl::optional<uint32_t> estimated_frequency = |
| EstimateRtpClockFrequency(packets, end_time_us); |
| if (!estimated_frequency) |
| continue; |
| const double frequency_hz = *estimated_frequency; |
| if (IsVideoSsrc(kIncomingPacket, stream.ssrc) && frequency_hz != 90000) { |
| RTC_LOG(LS_WARNING) |
| << "Video stream should use a 90 kHz clock but appears to use " |
| << frequency_hz / 1000 << ". Discarding."; |
| continue; |
| } |
| |
| auto ToCallTime = [this](const LoggedRtpPacketIncoming& packet) { |
| return this->ToCallTimeSec(packet.log_time_us()); |
| }; |
| auto ToNetworkDelay = [frequency_hz]( |
| const LoggedRtpPacketIncoming& old_packet, |
| const LoggedRtpPacketIncoming& new_packet) { |
| return NetworkDelayDiff_CaptureTime(old_packet, new_packet, frequency_hz); |
| }; |
| |
| TimeSeries capture_time_data( |
| GetStreamName(kIncomingPacket, stream.ssrc) + " capture-time", |
| LineStyle::kLine); |
| AccumulatePairs<LoggedRtpPacketIncoming, double>( |
| ToCallTime, ToNetworkDelay, packets, &capture_time_data); |
| plot->AppendTimeSeries(std::move(capture_time_data)); |
| |
| TimeSeries send_time_data( |
| GetStreamName(kIncomingPacket, stream.ssrc) + " abs-send-time", |
| LineStyle::kLine); |
| AccumulatePairs<LoggedRtpPacketIncoming, double>( |
| ToCallTime, NetworkDelayDiff_AbsSendTime, packets, &send_time_data); |
| plot->AppendTimeSeriesIfNotEmpty(std::move(send_time_data)); |
| } |
| |
| plot->SetXAxis(ToCallTimeSec(begin_time_), call_duration_s_, "Time (s)", |
| kLeftMargin, kRightMargin); |
| plot->SetSuggestedYAxis(0, 1, "Delay (ms)", kBottomMargin, kTopMargin); |
| plot->SetTitle("Incoming network delay (relative to first packet)"); |
| } |
| |
| // Plot the fraction of packets lost (as perceived by the loss-based BWE). |
| void EventLogAnalyzer::CreateFractionLossGraph(Plot* plot) { |
| TimeSeries time_series("Fraction lost", LineStyle::kLine, |
| PointStyle::kHighlight); |
| for (auto& bwe_update : parsed_log_.bwe_loss_updates()) { |
| float x = ToCallTimeSec(bwe_update.log_time_us()); |
| float y = static_cast<float>(bwe_update.fraction_lost) / 255 * 100; |
| time_series.points.emplace_back(x, y); |
| } |
| |
| plot->AppendTimeSeries(std::move(time_series)); |
| plot->SetXAxis(ToCallTimeSec(begin_time_), call_duration_s_, "Time (s)", |
| kLeftMargin, kRightMargin); |
| plot->SetSuggestedYAxis(0, 10, "Percent lost packets", kBottomMargin, |
| kTopMargin); |
| plot->SetTitle("Reported packet loss"); |
| } |
| |
| // Plot the total bandwidth used by all RTP streams. |
| void EventLogAnalyzer::CreateTotalIncomingBitrateGraph(Plot* plot) { |
| // TODO(terelius): This could be provided by the parser. |
| std::multimap<int64_t, size_t> packets_in_order; |
| for (const auto& stream : parsed_log_.incoming_rtp_packets_by_ssrc()) { |
| for (const LoggedRtpPacketIncoming& packet : stream.incoming_packets) |
| packets_in_order.insert( |
| std::make_pair(packet.rtp.log_time_us(), packet.rtp.total_length)); |
| } |
| |
| auto window_begin = packets_in_order.begin(); |
| auto window_end = packets_in_order.begin(); |
| size_t bytes_in_window = 0; |
| |
| // Calculate a moving average of the bitrate and store in a TimeSeries. |
| TimeSeries bitrate_series("Bitrate", LineStyle::kLine); |
| for (int64_t time = begin_time_; time < end_time_ + step_; time += step_) { |
| while (window_end != packets_in_order.end() && window_end->first < time) { |
| bytes_in_window += window_end->second; |
| ++window_end; |
| } |
| while (window_begin != packets_in_order.end() && |
| window_begin->first < time - window_duration_) { |
| RTC_DCHECK_LE(window_begin->second, bytes_in_window); |
| bytes_in_window -= window_begin->second; |
| ++window_begin; |
| } |
| float window_duration_in_seconds = |
| static_cast<float>(window_duration_) / kNumMicrosecsPerSec; |
| float x = ToCallTimeSec(time); |
| float y = bytes_in_window * 8 / window_duration_in_seconds / 1000; |
| bitrate_series.points.emplace_back(x, y); |
| } |
| plot->AppendTimeSeries(std::move(bitrate_series)); |
| |
| // Overlay the outgoing REMB over incoming bitrate. |
| TimeSeries remb_series("Remb", LineStyle::kStep); |
| for (const auto& rtcp : parsed_log_.rembs(kOutgoingPacket)) { |
| float x = ToCallTimeSec(rtcp.log_time_us()); |
| float y = static_cast<float>(rtcp.remb.bitrate_bps()) / 1000; |
| remb_series.points.emplace_back(x, y); |
| } |
| plot->AppendTimeSeriesIfNotEmpty(std::move(remb_series)); |
| |
| plot->SetXAxis(ToCallTimeSec(begin_time_), call_duration_s_, "Time (s)", |
| kLeftMargin, kRightMargin); |
| plot->SetSuggestedYAxis(0, 1, "Bitrate (kbps)", kBottomMargin, kTopMargin); |
| plot->SetTitle("Incoming RTP bitrate"); |
| } |
| |
| // Plot the total bandwidth used by all RTP streams. |
| void EventLogAnalyzer::CreateTotalOutgoingBitrateGraph(Plot* plot, |
| bool show_detector_state, |
| bool show_alr_state) { |
| // TODO(terelius): This could be provided by the parser. |
| std::multimap<int64_t, size_t> packets_in_order; |
| for (const auto& stream : parsed_log_.outgoing_rtp_packets_by_ssrc()) { |
| for (const LoggedRtpPacketOutgoing& packet : stream.outgoing_packets) |
| packets_in_order.insert( |
| std::make_pair(packet.rtp.log_time_us(), packet.rtp.total_length)); |
| } |
| |
| auto window_begin = packets_in_order.begin(); |
| auto window_end = packets_in_order.begin(); |
| size_t bytes_in_window = 0; |
| |
| // Calculate a moving average of the bitrate and store in a TimeSeries. |
| TimeSeries bitrate_series("Bitrate", LineStyle::kLine); |
| for (int64_t time = begin_time_; time < end_time_ + step_; time += step_) { |
| while (window_end != packets_in_order.end() && window_end->first < time) { |
| bytes_in_window += window_end->second; |
| ++window_end; |
| } |
| while (window_begin != packets_in_order.end() && |
| window_begin->first < time - window_duration_) { |
| RTC_DCHECK_LE(window_begin->second, bytes_in_window); |
| bytes_in_window -= window_begin->second; |
| ++window_begin; |
| } |
| float window_duration_in_seconds = |
| static_cast<float>(window_duration_) / kNumMicrosecsPerSec; |
| float x = ToCallTimeSec(time); |
| float y = bytes_in_window * 8 / window_duration_in_seconds / 1000; |
| bitrate_series.points.emplace_back(x, y); |
| } |
| plot->AppendTimeSeries(std::move(bitrate_series)); |
| |
| // Overlay the send-side bandwidth estimate over the outgoing bitrate. |
| TimeSeries loss_series("Loss-based estimate", LineStyle::kStep); |
| for (auto& loss_update : parsed_log_.bwe_loss_updates()) { |
| float x = ToCallTimeSec(loss_update.log_time_us()); |
| float y = static_cast<float>(loss_update.bitrate_bps) / 1000; |
| loss_series.points.emplace_back(x, y); |
| } |
| |
| TimeSeries delay_series("Delay-based estimate", LineStyle::kStep); |
| IntervalSeries overusing_series("Overusing", "#ff8e82", |
| IntervalSeries::kHorizontal); |
| IntervalSeries underusing_series("Underusing", "#5092fc", |
| IntervalSeries::kHorizontal); |
| IntervalSeries normal_series("Normal", "#c4ffc4", |
| IntervalSeries::kHorizontal); |
| IntervalSeries* last_series = &normal_series; |
| double last_detector_switch = 0.0; |
| |
| BandwidthUsage last_detector_state = BandwidthUsage::kBwNormal; |
| |
| for (auto& delay_update : parsed_log_.bwe_delay_updates()) { |
| float x = ToCallTimeSec(delay_update.log_time_us()); |
| float y = static_cast<float>(delay_update.bitrate_bps) / 1000; |
| |
| if (last_detector_state != delay_update.detector_state) { |
| last_series->intervals.emplace_back(last_detector_switch, x); |
| last_detector_state = delay_update.detector_state; |
| last_detector_switch = x; |
| |
| switch (delay_update.detector_state) { |
| case BandwidthUsage::kBwNormal: |
| last_series = &normal_series; |
| break; |
| case BandwidthUsage::kBwUnderusing: |
| last_series = &underusing_series; |
| break; |
| case BandwidthUsage::kBwOverusing: |
| last_series = &overusing_series; |
| break; |
| case BandwidthUsage::kLast: |
| RTC_NOTREACHED(); |
| } |
| } |
| |
| delay_series.points.emplace_back(x, y); |
| } |
| |
| RTC_CHECK(last_series); |
| last_series->intervals.emplace_back(last_detector_switch, end_time_); |
| |
| TimeSeries created_series("Probe cluster created.", LineStyle::kNone, |
| PointStyle::kHighlight); |
| for (auto& cluster : parsed_log_.bwe_probe_cluster_created_events()) { |
| float x = ToCallTimeSec(cluster.log_time_us()); |
| float y = static_cast<float>(cluster.bitrate_bps) / 1000; |
| created_series.points.emplace_back(x, y); |
| } |
| |
| TimeSeries result_series("Probing results.", LineStyle::kNone, |
| PointStyle::kHighlight); |
| for (auto& result : parsed_log_.bwe_probe_success_events()) { |
| float x = ToCallTimeSec(result.log_time_us()); |
| float y = static_cast<float>(result.bitrate_bps) / 1000; |
| result_series.points.emplace_back(x, y); |
| } |
| |
| TimeSeries probe_failures_series("Probe failed", LineStyle::kNone, |
| PointStyle::kHighlight); |
| for (auto& failure : parsed_log_.bwe_probe_failure_events()) { |
| float x = ToCallTimeSec(failure.log_time_us()); |
| probe_failures_series.points.emplace_back(x, 0); |
| } |
| |
| IntervalSeries alr_state("ALR", "#555555", IntervalSeries::kHorizontal); |
| bool previously_in_alr = false; |
| int64_t alr_start = 0; |
| for (auto& alr : parsed_log_.alr_state_events()) { |
| float y = ToCallTimeSec(alr.log_time_us()); |
| if (!previously_in_alr && alr.in_alr) { |
| alr_start = alr.log_time_us(); |
| previously_in_alr = true; |
| } else if (previously_in_alr && !alr.in_alr) { |
| float x = ToCallTimeSec(alr_start); |
| alr_state.intervals.emplace_back(x, y); |
| previously_in_alr = false; |
| } |
| } |
| |
| if (previously_in_alr) { |
| float x = ToCallTimeSec(alr_start); |
| float y = ToCallTimeSec(end_time_); |
| alr_state.intervals.emplace_back(x, y); |
| } |
| |
| if (show_detector_state) { |
| plot->AppendIntervalSeries(std::move(overusing_series)); |
| plot->AppendIntervalSeries(std::move(underusing_series)); |
| plot->AppendIntervalSeries(std::move(normal_series)); |
| } |
| |
| if (show_alr_state) { |
| plot->AppendIntervalSeries(std::move(alr_state)); |
| } |
| plot->AppendTimeSeries(std::move(loss_series)); |
| plot->AppendTimeSeriesIfNotEmpty(std::move(probe_failures_series)); |
| plot->AppendTimeSeries(std::move(delay_series)); |
| plot->AppendTimeSeries(std::move(created_series)); |
| plot->AppendTimeSeries(std::move(result_series)); |
| |
| // Overlay the incoming REMB over the outgoing bitrate. |
| TimeSeries remb_series("Remb", LineStyle::kStep); |
| for (const auto& rtcp : parsed_log_.rembs(kIncomingPacket)) { |
| float x = ToCallTimeSec(rtcp.log_time_us()); |
| float y = static_cast<float>(rtcp.remb.bitrate_bps()) / 1000; |
| remb_series.points.emplace_back(x, y); |
| } |
| plot->AppendTimeSeriesIfNotEmpty(std::move(remb_series)); |
| |
| plot->SetXAxis(ToCallTimeSec(begin_time_), call_duration_s_, "Time (s)", |
| kLeftMargin, kRightMargin); |
| plot->SetSuggestedYAxis(0, 1, "Bitrate (kbps)", kBottomMargin, kTopMargin); |
| plot->SetTitle("Outgoing RTP bitrate"); |
| } |
| |
| // For each SSRC, plot the bandwidth used by that stream. |
| void EventLogAnalyzer::CreateStreamBitrateGraph(PacketDirection direction, |
| Plot* plot) { |
| for (const auto& stream : parsed_log_.rtp_packets_by_ssrc(direction)) { |
| // Filter on SSRC. |
| if (!MatchingSsrc(stream.ssrc, desired_ssrc_)) { |
| continue; |
| } |
| |
| TimeSeries time_series(GetStreamName(direction, stream.ssrc), |
| LineStyle::kLine); |
| auto GetPacketSizeKilobits = [](const LoggedRtpPacket& packet) { |
| return packet.total_length * 8.0 / 1000.0; |
| }; |
| auto ToCallTime = [this](int64_t time) { |
| return this->ToCallTimeSec(time); |
| }; |
| MovingAverage<LoggedRtpPacket, double>( |
| ToCallTime, GetPacketSizeKilobits, stream.packet_view, begin_time_, |
| end_time_, window_duration_, step_, &time_series); |
| plot->AppendTimeSeries(std::move(time_series)); |
| } |
| |
| plot->SetXAxis(ToCallTimeSec(begin_time_), call_duration_s_, "Time (s)", |
| kLeftMargin, kRightMargin); |
| plot->SetSuggestedYAxis(0, 1, "Bitrate (kbps)", kBottomMargin, kTopMargin); |
| plot->SetTitle(GetDirectionAsString(direction) + " bitrate per stream"); |
| } |
| |
| void EventLogAnalyzer::CreateSendSideBweSimulationGraph(Plot* plot) { |
| using RtpPacketType = LoggedRtpPacketOutgoing; |
| using TransportFeedbackType = LoggedRtcpPacketTransportFeedback; |
| |
| // TODO(terelius): This could be provided by the parser. |
| std::multimap<int64_t, const RtpPacketType*> outgoing_rtp; |
| for (const auto& stream : parsed_log_.outgoing_rtp_packets_by_ssrc()) { |
| for (const RtpPacketType& rtp_packet : stream.outgoing_packets) |
| outgoing_rtp.insert( |
| std::make_pair(rtp_packet.rtp.log_time_us(), &rtp_packet)); |
| } |
| |
| const std::vector<TransportFeedbackType>& incoming_rtcp = |
| parsed_log_.transport_feedbacks(kIncomingPacket); |
| |
| SimulatedClock clock(0); |
| BitrateObserver observer; |
| RtcEventLogNullImpl null_event_log; |
| PacketRouter packet_router; |
| PacedSender pacer(&clock, &packet_router, &null_event_log); |
| TransportFeedbackAdapter transport_feedback; |
| auto factory = GoogCcNetworkControllerFactory(&null_event_log); |
| TimeDelta process_interval = factory.GetProcessInterval(); |
| // TODO(holmer): Log the call config and use that here instead. |
| static const uint32_t kDefaultStartBitrateBps = 300000; |
| NetworkControllerConfig cc_config; |
| cc_config.constraints.at_time = Timestamp::us(clock.TimeInMicroseconds()); |
| cc_config.constraints.starting_rate = DataRate::bps(kDefaultStartBitrateBps); |
| auto goog_cc = factory.Create(cc_config); |
| |
| TimeSeries time_series("Delay-based estimate", LineStyle::kStep, |
| PointStyle::kHighlight); |
| TimeSeries acked_time_series("Acked bitrate", LineStyle::kLine, |
| PointStyle::kHighlight); |
| TimeSeries acked_estimate_time_series( |
| "Acked bitrate estimate", LineStyle::kLine, PointStyle::kHighlight); |
| |
| auto rtp_iterator = outgoing_rtp.begin(); |
| auto rtcp_iterator = incoming_rtcp.begin(); |
| |
| auto NextRtpTime = [&]() { |
| if (rtp_iterator != outgoing_rtp.end()) |
| return static_cast<int64_t>(rtp_iterator->first); |
| return std::numeric_limits<int64_t>::max(); |
| }; |
| |
| auto NextRtcpTime = [&]() { |
| if (rtcp_iterator != incoming_rtcp.end()) |
| return static_cast<int64_t>(rtcp_iterator->log_time_us()); |
| return std::numeric_limits<int64_t>::max(); |
| }; |
| int64_t next_process_time_us_ = std::min({NextRtpTime(), NextRtcpTime()}); |
| |
| auto NextProcessTime = [&]() { |
| if (rtcp_iterator != incoming_rtcp.end() || |
| rtp_iterator != outgoing_rtp.end()) { |
| return next_process_time_us_; |
| } |
| return std::numeric_limits<int64_t>::max(); |
| }; |
| |
| RateStatistics acked_bitrate(250, 8000); |
| #if !(BWE_TEST_LOGGING_COMPILE_TIME_ENABLE) |
| FieldTrialBasedConfig field_trial_config_; |
| // The event_log_visualizer should normally not be compiled with |
| // BWE_TEST_LOGGING_COMPILE_TIME_ENABLE since the normal plots won't work. |
| // However, compiling with BWE_TEST_LOGGING, runnning with --plot_sendside_bwe |
| // and piping the output to plot_dynamics.py can be used as a hack to get the |
| // internal state of various BWE components. In this case, it is important |
| // we don't instantiate the AcknowledgedBitrateEstimator both here and in |
| // SendSideCongestionController since that would lead to duplicate outputs. |
| AcknowledgedBitrateEstimator acknowledged_bitrate_estimator( |
| &field_trial_config_, |
| absl::make_unique<BitrateEstimator>(&field_trial_config_)); |
| #endif // !(BWE_TEST_LOGGING_COMPILE_TIME_ENABLE) |
| int64_t time_us = |
| std::min({NextRtpTime(), NextRtcpTime(), NextProcessTime()}); |
| int64_t last_update_us = 0; |
| while (time_us != std::numeric_limits<int64_t>::max()) { |
| clock.AdvanceTimeMicroseconds(time_us - clock.TimeInMicroseconds()); |
| if (clock.TimeInMicroseconds() >= NextRtpTime()) { |
| RTC_DCHECK_EQ(clock.TimeInMicroseconds(), NextRtpTime()); |
| const RtpPacketType& rtp_packet = *rtp_iterator->second; |
| if (rtp_packet.rtp.header.extension.hasTransportSequenceNumber) { |
| RTC_DCHECK(rtp_packet.rtp.header.extension.hasTransportSequenceNumber); |
| transport_feedback.AddPacket( |
| rtp_packet.rtp.header.ssrc, |
| rtp_packet.rtp.header.extension.transportSequenceNumber, |
| rtp_packet.rtp.total_length, PacedPacketInfo(), |
| Timestamp::us(rtp_packet.rtp.log_time_us())); |
| rtc::SentPacket sent_packet( |
| rtp_packet.rtp.header.extension.transportSequenceNumber, |
| rtp_packet.rtp.log_time_us() / 1000); |
| auto sent_msg = transport_feedback.ProcessSentPacket(sent_packet); |
| if (sent_msg) |
| observer.Update(goog_cc->OnSentPacket(*sent_msg)); |
| } |
| ++rtp_iterator; |
| } |
| if (clock.TimeInMicroseconds() >= NextRtcpTime()) { |
| RTC_DCHECK_EQ(clock.TimeInMicroseconds(), NextRtcpTime()); |
| |
| auto feedback_msg = transport_feedback.ProcessTransportFeedback( |
| rtcp_iterator->transport_feedback, |
| Timestamp::ms(clock.TimeInMilliseconds())); |
| absl::optional<uint32_t> bitrate_bps; |
| if (feedback_msg) { |
| observer.Update(goog_cc->OnTransportPacketsFeedback(*feedback_msg)); |
| std::vector<PacketFeedback> feedback = |
| transport_feedback.GetTransportFeedbackVector(); |
| SortPacketFeedbackVector(&feedback); |
| if (!feedback.empty()) { |
| #if !(BWE_TEST_LOGGING_COMPILE_TIME_ENABLE) |
| acknowledged_bitrate_estimator.IncomingPacketFeedbackVector(feedback); |
| #endif // !(BWE_TEST_LOGGING_COMPILE_TIME_ENABLE) |
| for (const PacketFeedback& packet : feedback) |
| acked_bitrate.Update(packet.payload_size, packet.arrival_time_ms); |
| bitrate_bps = acked_bitrate.Rate(feedback.back().arrival_time_ms); |
| } |
| } |
| |
| float x = ToCallTimeSec(clock.TimeInMicroseconds()); |
| float y = bitrate_bps.value_or(0) / 1000; |
| acked_time_series.points.emplace_back(x, y); |
| #if !(BWE_TEST_LOGGING_COMPILE_TIME_ENABLE) |
| y = acknowledged_bitrate_estimator.bitrate_bps().value_or(0) / 1000; |
| acked_estimate_time_series.points.emplace_back(x, y); |
| #endif // !(BWE_TEST_LOGGING_COMPILE_TIME_ENABLE) |
| ++rtcp_iterator; |
| } |
| if (clock.TimeInMicroseconds() >= NextProcessTime()) { |
| RTC_DCHECK_EQ(clock.TimeInMicroseconds(), NextProcessTime()); |
| ProcessInterval msg; |
| msg.at_time = Timestamp::us(clock.TimeInMicroseconds()); |
| observer.Update(goog_cc->OnProcessInterval(msg)); |
| next_process_time_us_ += process_interval.us(); |
| } |
| if (observer.GetAndResetBitrateUpdated() || |
| time_us - last_update_us >= 1e6) { |
| uint32_t y = observer.last_bitrate_bps() / 1000; |
| float x = ToCallTimeSec(clock.TimeInMicroseconds()); |
| time_series.points.emplace_back(x, y); |
| last_update_us = time_us; |
| } |
| time_us = std::min({NextRtpTime(), NextRtcpTime(), NextProcessTime()}); |
| } |
| // Add the data set to the plot. |
| plot->AppendTimeSeries(std::move(time_series)); |
| plot->AppendTimeSeries(std::move(acked_time_series)); |
| plot->AppendTimeSeriesIfNotEmpty(std::move(acked_estimate_time_series)); |
| |
| plot->SetXAxis(ToCallTimeSec(begin_time_), call_duration_s_, "Time (s)", |
| kLeftMargin, kRightMargin); |
| plot->SetSuggestedYAxis(0, 10, "Bitrate (kbps)", kBottomMargin, kTopMargin); |
| plot->SetTitle("Simulated send-side BWE behavior"); |
| } |
| |
| void EventLogAnalyzer::CreateReceiveSideBweSimulationGraph(Plot* plot) { |
| using RtpPacketType = LoggedRtpPacketIncoming; |
| class RembInterceptingPacketRouter : public PacketRouter { |
| public: |
| void OnReceiveBitrateChanged(const std::vector<uint32_t>& ssrcs, |
| uint32_t bitrate_bps) override { |
| last_bitrate_bps_ = bitrate_bps; |
| bitrate_updated_ = true; |
| PacketRouter::OnReceiveBitrateChanged(ssrcs, bitrate_bps); |
| } |
| uint32_t last_bitrate_bps() const { return last_bitrate_bps_; } |
| bool GetAndResetBitrateUpdated() { |
| bool bitrate_updated = bitrate_updated_; |
| bitrate_updated_ = false; |
| return bitrate_updated; |
| } |
| |
| private: |
| uint32_t last_bitrate_bps_; |
| bool bitrate_updated_; |
| }; |
| |
| std::multimap<int64_t, const RtpPacketType*> incoming_rtp; |
| |
| for (const auto& stream : parsed_log_.incoming_rtp_packets_by_ssrc()) { |
| if (IsVideoSsrc(kIncomingPacket, stream.ssrc)) { |
| for (const auto& rtp_packet : stream.incoming_packets) |
| incoming_rtp.insert( |
| std::make_pair(rtp_packet.rtp.log_time_us(), &rtp_packet)); |
| } |
| } |
| |
| SimulatedClock clock(0); |
| RembInterceptingPacketRouter packet_router; |
| // TODO(terelius): The PacketRouter is used as the RemoteBitrateObserver. |
| // Is this intentional? |
| ReceiveSideCongestionController rscc(&clock, &packet_router); |
| // TODO(holmer): Log the call config and use that here instead. |
| // static const uint32_t kDefaultStartBitrateBps = 300000; |
| // rscc.SetBweBitrates(0, kDefaultStartBitrateBps, -1); |
| |
| TimeSeries time_series("Receive side estimate", LineStyle::kLine, |
| PointStyle::kHighlight); |
| TimeSeries acked_time_series("Received bitrate", LineStyle::kLine); |
| |
| RateStatistics acked_bitrate(250, 8000); |
| int64_t last_update_us = 0; |
| for (const auto& kv : incoming_rtp) { |
| const RtpPacketType& packet = *kv.second; |
| int64_t arrival_time_ms = packet.rtp.log_time_us() / 1000; |
| size_t payload = packet.rtp.total_length; /*Should subtract header?*/ |
| clock.AdvanceTimeMicroseconds(packet.rtp.log_time_us() - |
| clock.TimeInMicroseconds()); |
| rscc.OnReceivedPacket(arrival_time_ms, payload, packet.rtp.header); |
| acked_bitrate.Update(payload, arrival_time_ms); |
| absl::optional<uint32_t> bitrate_bps = acked_bitrate.Rate(arrival_time_ms); |
| if (bitrate_bps) { |
| uint32_t y = *bitrate_bps / 1000; |
| float x = ToCallTimeSec(clock.TimeInMicroseconds()); |
| acked_time_series.points.emplace_back(x, y); |
| } |
| if (packet_router.GetAndResetBitrateUpdated() || |
| clock.TimeInMicroseconds() - last_update_us >= 1e6) { |
| uint32_t y = packet_router.last_bitrate_bps() / 1000; |
| float x = ToCallTimeSec(clock.TimeInMicroseconds()); |
| time_series.points.emplace_back(x, y); |
| last_update_us = clock.TimeInMicroseconds(); |
| } |
| } |
| // Add the data set to the plot. |
| plot->AppendTimeSeries(std::move(time_series)); |
| plot->AppendTimeSeries(std::move(acked_time_series)); |
| |
| plot->SetXAxis(ToCallTimeSec(begin_time_), call_duration_s_, "Time (s)", |
| kLeftMargin, kRightMargin); |
| plot->SetSuggestedYAxis(0, 10, "Bitrate (kbps)", kBottomMargin, kTopMargin); |
| plot->SetTitle("Simulated receive-side BWE behavior"); |
| } |
| |
| void EventLogAnalyzer::CreateNetworkDelayFeedbackGraph(Plot* plot) { |
| TimeSeries late_feedback_series("Late feedback results.", LineStyle::kNone, |
| PointStyle::kHighlight); |
| TimeSeries time_series("Network delay", LineStyle::kLine, |
| PointStyle::kHighlight); |
| int64_t min_send_receive_diff_ms = std::numeric_limits<int64_t>::max(); |
| int64_t min_rtt_ms = std::numeric_limits<int64_t>::max(); |
| |
| int64_t prev_y = 0; |
| for (auto packet : GetNetworkTrace(parsed_log_)) { |
| if (packet.arrival_time_ms == PacketFeedback::kNotReceived) |
| continue; |
| float x = ToCallTimeSec(1000 * packet.feedback_arrival_time_ms); |
| if (packet.send_time_ms == PacketFeedback::kNoSendTime) { |
| late_feedback_series.points.emplace_back(x, prev_y); |
| continue; |
| } |
| int64_t y = packet.arrival_time_ms - packet.send_time_ms; |
| prev_y = y; |
| int64_t rtt_ms = packet.feedback_arrival_time_ms - packet.send_time_ms; |
| min_rtt_ms = std::min(rtt_ms, min_rtt_ms); |
| min_send_receive_diff_ms = std::min(y, min_send_receive_diff_ms); |
| time_series.points.emplace_back(x, y); |
| } |
| |
| // We assume that the base network delay (w/o queues) is equal to half |
| // the minimum RTT. Therefore rescale the delays by subtracting the minimum |
| // observed 1-ways delay and add half the minumum RTT. |
| const int64_t estimated_clock_offset_ms = |
| min_send_receive_diff_ms - min_rtt_ms / 2; |
| for (TimeSeriesPoint& point : time_series.points) |
| point.y -= estimated_clock_offset_ms; |
| for (TimeSeriesPoint& point : late_feedback_series.points) |
| point.y -= estimated_clock_offset_ms; |
| |
| // Add the data set to the plot. |
| plot->AppendTimeSeriesIfNotEmpty(std::move(time_series)); |
| plot->AppendTimeSeriesIfNotEmpty(std::move(late_feedback_series)); |
| |
| plot->SetXAxis(ToCallTimeSec(begin_time_), call_duration_s_, "Time (s)", |
| kLeftMargin, kRightMargin); |
| plot->SetSuggestedYAxis(0, 10, "Delay (ms)", kBottomMargin, kTopMargin); |
| plot->SetTitle("Outgoing network delay (based on per-packet feedback)"); |
| } |
| |
| void EventLogAnalyzer::CreatePacerDelayGraph(Plot* plot) { |
| for (const auto& stream : parsed_log_.outgoing_rtp_packets_by_ssrc()) { |
| const std::vector<LoggedRtpPacketOutgoing>& packets = |
| stream.outgoing_packets; |
| |
| if (packets.size() < 2) { |
| RTC_LOG(LS_WARNING) |
| << "Can't estimate a the RTP clock frequency or the " |
| "pacer delay with less than 2 packets in the stream"; |
| continue; |
| } |
| int64_t end_time_us = log_segments_.empty() |
| ? std::numeric_limits<int64_t>::max() |
| : log_segments_.front().second; |
| absl::optional<uint32_t> estimated_frequency = |
| EstimateRtpClockFrequency(packets, end_time_us); |
| if (!estimated_frequency) |
| continue; |
| if (IsVideoSsrc(kOutgoingPacket, stream.ssrc) && |
| *estimated_frequency != 90000) { |
| RTC_LOG(LS_WARNING) |
| << "Video stream should use a 90 kHz clock but appears to use " |
| << *estimated_frequency / 1000 << ". Discarding."; |
| continue; |
| } |
| |
| TimeSeries pacer_delay_series( |
| GetStreamName(kOutgoingPacket, stream.ssrc) + "(" + |
| std::to_string(*estimated_frequency / 1000) + " kHz)", |
| LineStyle::kLine, PointStyle::kHighlight); |
| SeqNumUnwrapper<uint32_t> timestamp_unwrapper; |
| uint64_t first_capture_timestamp = |
| timestamp_unwrapper.Unwrap(packets.front().rtp.header.timestamp); |
| uint64_t first_send_timestamp = packets.front().rtp.log_time_us(); |
| for (const auto& packet : packets) { |
| double capture_time_ms = (static_cast<double>(timestamp_unwrapper.Unwrap( |
| packet.rtp.header.timestamp)) - |
| first_capture_timestamp) / |
| *estimated_frequency * 1000; |
| double send_time_ms = |
| static_cast<double>(packet.rtp.log_time_us() - first_send_timestamp) / |
| 1000; |
| float x = ToCallTimeSec(packet.rtp.log_time_us()); |
| float y = send_time_ms - capture_time_ms; |
| pacer_delay_series.points.emplace_back(x, y); |
| } |
| plot->AppendTimeSeries(std::move(pacer_delay_series)); |
| } |
| |
| plot->SetXAxis(ToCallTimeSec(begin_time_), call_duration_s_, "Time (s)", |
| kLeftMargin, kRightMargin); |
| plot->SetSuggestedYAxis(0, 10, "Pacer delay (ms)", kBottomMargin, kTopMargin); |
| plot->SetTitle( |
| "Delay from capture to send time. (First packet normalized to 0.)"); |
| } |
| |
| void EventLogAnalyzer::CreateTimestampGraph(PacketDirection direction, |
| Plot* plot) { |
| for (const auto& stream : parsed_log_.rtp_packets_by_ssrc(direction)) { |
| TimeSeries rtp_timestamps( |
| GetStreamName(direction, stream.ssrc) + " capture-time", |
| LineStyle::kLine, PointStyle::kHighlight); |
| for (const auto& packet : stream.packet_view) { |
| float x = ToCallTimeSec(packet.log_time_us()); |
| float y = packet.header.timestamp; |
| rtp_timestamps.points.emplace_back(x, y); |
| } |
| plot->AppendTimeSeries(std::move(rtp_timestamps)); |
| |
| TimeSeries rtcp_timestamps( |
| GetStreamName(direction, stream.ssrc) + " rtcp capture-time", |
| LineStyle::kLine, PointStyle::kHighlight); |
| // TODO(terelius): Why only sender reports? |
| const auto& sender_reports = parsed_log_.sender_reports(direction); |
| for (const auto& rtcp : sender_reports) { |
| if (rtcp.sr.sender_ssrc() != stream.ssrc) |
| continue; |
| float x = ToCallTimeSec(rtcp.log_time_us()); |
| float y = rtcp.sr.rtp_timestamp(); |
| rtcp_timestamps.points.emplace_back(x, y); |
| } |
| plot->AppendTimeSeriesIfNotEmpty(std::move(rtcp_timestamps)); |
| } |
| |
| plot->SetXAxis(ToCallTimeSec(begin_time_), call_duration_s_, "Time (s)", |
| kLeftMargin, kRightMargin); |
| plot->SetSuggestedYAxis(0, 1, "RTP timestamp", kBottomMargin, kTopMargin); |
| plot->SetTitle(GetDirectionAsString(direction) + " timestamps"); |
| } |
| |
| void EventLogAnalyzer::CreateSenderAndReceiverReportPlot( |
| PacketDirection direction, |
| rtc::FunctionView<float(const rtcp::ReportBlock&)> fy, |
| std::string title, |
| std::string yaxis_label, |
| Plot* plot) { |
| std::map<uint32_t, TimeSeries> sr_reports_by_ssrc; |
| const auto& sender_reports = parsed_log_.sender_reports(direction); |
| for (const auto& rtcp : sender_reports) { |
| float x = ToCallTimeSec(rtcp.log_time_us()); |
| uint32_t ssrc = rtcp.sr.sender_ssrc(); |
| for (const auto& block : rtcp.sr.report_blocks()) { |
| float y = fy(block); |
| auto sr_report_it = sr_reports_by_ssrc.find(ssrc); |
| bool inserted; |
| if (sr_report_it == sr_reports_by_ssrc.end()) { |
| std::tie(sr_report_it, inserted) = sr_reports_by_ssrc.emplace( |
| ssrc, TimeSeries(GetStreamName(direction, ssrc) + " Sender Reports", |
| LineStyle::kLine, PointStyle::kHighlight)); |
| } |
| sr_report_it->second.points.emplace_back(x, y); |
| } |
| } |
| for (auto& kv : sr_reports_by_ssrc) { |
| plot->AppendTimeSeries(std::move(kv.second)); |
| } |
| |
| std::map<uint32_t, TimeSeries> rr_reports_by_ssrc; |
| const auto& receiver_reports = parsed_log_.receiver_reports(direction); |
| for (const auto& rtcp : receiver_reports) { |
| float x = ToCallTimeSec(rtcp.log_time_us()); |
| uint32_t ssrc = rtcp.rr.sender_ssrc(); |
| for (const auto& block : rtcp.rr.report_blocks()) { |
| float y = fy(block); |
| auto rr_report_it = rr_reports_by_ssrc.find(ssrc); |
| bool inserted; |
| if (rr_report_it == rr_reports_by_ssrc.end()) { |
| std::tie(rr_report_it, inserted) = rr_reports_by_ssrc.emplace( |
| ssrc, |
| TimeSeries(GetStreamName(direction, ssrc) + " Receiver Reports", |
| LineStyle::kLine, PointStyle::kHighlight)); |
| } |
| rr_report_it->second.points.emplace_back(x, y); |
| } |
| } |
| for (auto& kv : rr_reports_by_ssrc) { |
| plot->AppendTimeSeries(std::move(kv.second)); |
| } |
| |
| plot->SetXAxis(ToCallTimeSec(begin_time_), call_duration_s_, "Time (s)", |
| kLeftMargin, kRightMargin); |
| plot->SetSuggestedYAxis(0, 1, yaxis_label, kBottomMargin, kTopMargin); |
| plot->SetTitle(title); |
| } |
| |
| void EventLogAnalyzer::CreateAudioEncoderTargetBitrateGraph(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 = [this](const LoggedAudioNetworkAdaptationEvent& packet) { |
| return this->ToCallTimeSec(packet.log_time_us()); |
| }; |
| ProcessPoints<LoggedAudioNetworkAdaptationEvent>( |
| ToCallTime, GetAnaBitrateBps, |
| parsed_log_.audio_network_adaptation_events(), &time_series); |
| plot->AppendTimeSeries(std::move(time_series)); |
| plot->SetXAxis(ToCallTimeSec(begin_time_), call_duration_s_, "Time (s)", |
| kLeftMargin, kRightMargin); |
| plot->SetSuggestedYAxis(0, 1, "Bitrate (bps)", kBottomMargin, kTopMargin); |
| plot->SetTitle("Reported audio encoder target bitrate"); |
| } |
| |
| void EventLogAnalyzer::CreateAudioEncoderFrameLengthGraph(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 = [this](const LoggedAudioNetworkAdaptationEvent& packet) { |
| return this->ToCallTimeSec(packet.log_time_us()); |
| }; |
| ProcessPoints<LoggedAudioNetworkAdaptationEvent>( |
| ToCallTime, GetAnaFrameLengthMs, |
| parsed_log_.audio_network_adaptation_events(), &time_series); |
| plot->AppendTimeSeries(std::move(time_series)); |
| plot->SetXAxis(ToCallTimeSec(begin_time_), call_duration_s_, "Time (s)", |
| kLeftMargin, kRightMargin); |
| plot->SetSuggestedYAxis(0, 1, "Frame length (ms)", kBottomMargin, kTopMargin); |
| plot->SetTitle("Reported audio encoder frame length"); |
| } |
| |
| void EventLogAnalyzer::CreateAudioEncoderPacketLossGraph(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 = [this](const LoggedAudioNetworkAdaptationEvent& packet) { |
| return this->ToCallTimeSec(packet.log_time_us()); |
| }; |
| ProcessPoints<LoggedAudioNetworkAdaptationEvent>( |
| ToCallTime, GetAnaPacketLoss, |
| parsed_log_.audio_network_adaptation_events(), &time_series); |
| plot->AppendTimeSeries(std::move(time_series)); |
| plot->SetXAxis(ToCallTimeSec(begin_time_), call_duration_s_, "Time (s)", |
| kLeftMargin, kRightMargin); |
| plot->SetSuggestedYAxis(0, 10, "Percent lost packets", kBottomMargin, |
| kTopMargin); |
| plot->SetTitle("Reported audio encoder lost packets"); |
| } |
| |
| void EventLogAnalyzer::CreateAudioEncoderEnableFecGraph(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 = [this](const LoggedAudioNetworkAdaptationEvent& packet) { |
| return this->ToCallTimeSec(packet.log_time_us()); |
| }; |
| ProcessPoints<LoggedAudioNetworkAdaptationEvent>( |
| ToCallTime, GetAnaFecEnabled, |
| parsed_log_.audio_network_adaptation_events(), &time_series); |
| plot->AppendTimeSeries(std::move(time_series)); |
| plot->SetXAxis(ToCallTimeSec(begin_time_), call_duration_s_, "Time (s)", |
| kLeftMargin, kRightMargin); |
| plot->SetSuggestedYAxis(0, 1, "FEC (false/true)", kBottomMargin, kTopMargin); |
| plot->SetTitle("Reported audio encoder FEC"); |
| } |
| |
| void EventLogAnalyzer::CreateAudioEncoderEnableDtxGraph(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 = [this](const LoggedAudioNetworkAdaptationEvent& packet) { |
| return this->ToCallTimeSec(packet.log_time_us()); |
| }; |
| ProcessPoints<LoggedAudioNetworkAdaptationEvent>( |
| ToCallTime, GetAnaDtxEnabled, |
| parsed_log_.audio_network_adaptation_events(), &time_series); |
| plot->AppendTimeSeries(std::move(time_series)); |
| plot->SetXAxis(ToCallTimeSec(begin_time_), call_duration_s_, "Time (s)", |
| kLeftMargin, kRightMargin); |
| plot->SetSuggestedYAxis(0, 1, "DTX (false/true)", kBottomMargin, kTopMargin); |
| plot->SetTitle("Reported audio encoder DTX"); |
| } |
| |
| void EventLogAnalyzer::CreateAudioEncoderNumChannelsGraph(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 = [this](const LoggedAudioNetworkAdaptationEvent& packet) { |
| return this->ToCallTimeSec(packet.log_time_us()); |
| }; |
| ProcessPoints<LoggedAudioNetworkAdaptationEvent>( |
| ToCallTime, GetAnaNumChannels, |
| parsed_log_.audio_network_adaptation_events(), &time_series); |
| plot->AppendTimeSeries(std::move(time_series)); |
| plot->SetXAxis(ToCallTimeSec(begin_time_), call_duration_s_, "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"); |
| } |
| |
| class NetEqStreamInput : public test::NetEqInput { |
| public: |
| // Does not take any ownership, and all pointers must refer to valid objects |
| // that outlive the one constructed. |
| NetEqStreamInput(const std::vector<LoggedRtpPacketIncoming>* packet_stream, |
| const std::vector<LoggedAudioPlayoutEvent>* output_events, |
| absl::optional<int64_t> end_time_ms) |
| : packet_stream_(*packet_stream), |
| packet_stream_it_(packet_stream_.begin()), |
| output_events_it_(output_events->begin()), |
| output_events_end_(output_events->end()), |
| end_time_ms_(end_time_ms) { |
| RTC_DCHECK(packet_stream); |
| RTC_DCHECK(output_events); |
| } |
| |
| absl::optional<int64_t> NextPacketTime() const override { |
| if (packet_stream_it_ == packet_stream_.end()) { |
| return absl::nullopt; |
| } |
| if (end_time_ms_ && packet_stream_it_->rtp.log_time_ms() > *end_time_ms_) { |
| return absl::nullopt; |
| } |
| return packet_stream_it_->rtp.log_time_ms(); |
| } |
| |
| absl::optional<int64_t> NextOutputEventTime() const override { |
| if (output_events_it_ == output_events_end_) { |
| return absl::nullopt; |
| } |
| if (end_time_ms_ && output_events_it_->log_time_ms() > *end_time_ms_) { |
| return absl::nullopt; |
| } |
| return output_events_it_->log_time_ms(); |
| } |
| |
| std::unique_ptr<PacketData> PopPacket() override { |
| if (packet_stream_it_ == packet_stream_.end()) { |
| return std::unique_ptr<PacketData>(); |
| } |
| std::unique_ptr<PacketData> packet_data(new PacketData()); |
| packet_data->header = packet_stream_it_->rtp.header; |
| packet_data->time_ms = packet_stream_it_->rtp.log_time_ms(); |
| |
| // This is a header-only "dummy" packet. Set the payload to all zeros, with |
| // length according to the virtual length. |
| packet_data->payload.SetSize(packet_stream_it_->rtp.total_length - |
| packet_stream_it_->rtp.header_length); |
| std::fill_n(packet_data->payload.data(), packet_data->payload.size(), 0); |
| |
| ++packet_stream_it_; |
| return packet_data; |
| } |
| |
| void AdvanceOutputEvent() override { |
| if (output_events_it_ != output_events_end_) { |
| ++output_events_it_; |
| } |
| } |
| |
| bool ended() const override { return !NextEventTime(); } |
| |
| absl::optional<RTPHeader> NextHeader() const override { |
| if (packet_stream_it_ == packet_stream_.end()) { |
| return absl::nullopt; |
| } |
| return packet_stream_it_->rtp.header; |
| } |
| |
| private: |
| const std::vector<LoggedRtpPacketIncoming>& packet_stream_; |
| std::vector<LoggedRtpPacketIncoming>::const_iterator packet_stream_it_; |
| std::vector<LoggedAudioPlayoutEvent>::const_iterator output_events_it_; |
| const std::vector<LoggedAudioPlayoutEvent>::const_iterator output_events_end_; |
| const absl::optional<int64_t> end_time_ms_; |
| }; |
| |
| 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_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 = absl::make_unique<test::ResampleInputAudioFile>( |
| replacement_file_name_, file_sample_rate_hz_); |
| replacement_file->set_output_rate_hz(48000); |
| return absl::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( |
| const std::vector<LoggedRtpPacketIncoming>* packet_stream, |
| const std::vector<LoggedAudioPlayoutEvent>* output_events, |
| absl::optional<int64_t> end_time_ms, |
| const std::string& replacement_file_name, |
| int file_sample_rate_hz) { |
| std::unique_ptr<test::NetEqInput> input( |
| new NetEqStreamInput(packet_stream, output_events, end_time_ms)); |
| |
| 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)); |
| |
| NetEq::Config config; |
| config.max_packets_in_buffer = 200; |
| config.enable_fast_accelerate = true; |
| |
| std::unique_ptr<test::VoidAudioSink> output(new test::VoidAudioSink()); |
| |
| rtc::scoped_refptr<AudioDecoderFactory> decoder_factory = |
| new rtc::RefCountedObject<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(); |
| |
| test::NetEqTest test(config, decoder_factory, codecs, nullptr, |
| std::move(input), std::move(output), callbacks); |
| test.Run(); |
| return neteq_stats_getter; |
| } |
| } // namespace |
| |
| EventLogAnalyzer::NetEqStatsGetterMap EventLogAnalyzer::SimulateNetEq( |
| const std::string& replacement_file_name, |
| int file_sample_rate_hz) const { |
| NetEqStatsGetterMap neteq_stats; |
| |
| for (const auto& stream : parsed_log_.incoming_rtp_packets_by_ssrc()) { |
| const uint32_t ssrc = stream.ssrc; |
| if (!IsAudioSsrc(kIncomingPacket, ssrc)) |
| continue; |
| const std::vector<LoggedRtpPacketIncoming>* audio_packets = |
| &stream.incoming_packets; |
| if (audio_packets == nullptr) { |
| // No incoming audio stream found. |
| continue; |
| } |
| |
| RTC_DCHECK(neteq_stats.find(ssrc) == neteq_stats.end()); |
| |
| std::map<uint32_t, std::vector<LoggedAudioPlayoutEvent>>::const_iterator |
| output_events_it = parsed_log_.audio_playout_events().find(ssrc); |
| if (output_events_it == parsed_log_.audio_playout_events().end()) { |
| // Could not find output events with SSRC matching the input audio stream. |
| // Using the first available stream of output events. |
| output_events_it = parsed_log_.audio_playout_events().cbegin(); |
| } |
| |
| absl::optional<int64_t> end_time_ms = |
| log_segments_.empty() |
| ? absl::nullopt |
| : absl::optional<int64_t>(log_segments_.front().second / 1000); |
| |
| neteq_stats[ssrc] = CreateNetEqTestAndRun( |
| audio_packets, &output_events_it->second, end_time_ms, |
| replacement_file_name, file_sample_rate_hz); |
| } |
| |
| 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 EventLogAnalyzer::CreateAudioJitterBufferGraph( |
| uint32_t ssrc, |
| const test::NetEqStatsGetter* stats_getter, |
| Plot* plot) const { |
| 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 = ToCallTimeSec(data.first * 1000); // ms to us. |
| 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 = ToCallTimeSec(data.first * 1000); // ms to us. |
| 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 = ToCallTimeSec(data.first * 1000); // ms to us. |
| 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 = ToCallTimeSec(data.first * 1000); // ms to us. |
| 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(ToCallTimeSec(begin_time_), call_duration_s_, "Time (s)", |
| kLeftMargin, kRightMargin); |
| plot->SetSuggestedYAxis(0, 1, "Relative delay (ms)", kBottomMargin, |
| kTopMargin); |
| plot->SetTitle("NetEq timing for " + GetStreamName(kIncomingPacket, ssrc)); |
| } |
| |
| template <typename NetEqStatsType> |
| void EventLogAnalyzer::CreateNetEqStatsGraphInternal( |
| 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) const { |
| 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 = ToCallTimeSec(data.first * 1000); // ms to us. |
| 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(kIncomingPacket, series.first); |
| series.second.line_style = LineStyle::kLine; |
| plot->AppendTimeSeries(std::move(series.second)); |
| } |
| |
| plot->SetXAxis(ToCallTimeSec(begin_time_), call_duration_s_, "Time (s)", |
| kLeftMargin, kRightMargin); |
| plot->SetSuggestedYAxis(0, 1, plot_name, kBottomMargin, kTopMargin); |
| plot->SetTitle(plot_name); |
| } |
| |
| void EventLogAnalyzer::CreateNetEqNetworkStatsGraph( |
| const NetEqStatsGetterMap& neteq_stats, |
| rtc::FunctionView<float(const NetEqNetworkStatistics&)> stats_extractor, |
| const std::string& plot_name, |
| Plot* plot) const { |
| CreateNetEqStatsGraphInternal<NetEqNetworkStatistics>( |
| neteq_stats, |
| [](const test::NetEqStatsGetter* stats_getter) { |
| return stats_getter->stats(); |
| }, |
| stats_extractor, plot_name, plot); |
| } |
| |
| void EventLogAnalyzer::CreateNetEqLifetimeStatsGraph( |
| const NetEqStatsGetterMap& neteq_stats, |
| rtc::FunctionView<float(const NetEqLifetimeStatistics&)> stats_extractor, |
| const std::string& plot_name, |
| Plot* plot) const { |
| CreateNetEqStatsGraphInternal<NetEqLifetimeStatistics>( |
| neteq_stats, |
| [](const test::NetEqStatsGetter* stats_getter) { |
| return stats_getter->lifetime_stats(); |
| }, |
| stats_extractor, plot_name, plot); |
| } |
| |
| void EventLogAnalyzer::CreateIceCandidatePairConfigGraph(Plot* plot) { |
| std::map<uint32_t, TimeSeries> configs_by_cp_id; |
| for (const auto& config : parsed_log_.ice_candidate_pair_configs()) { |
| if (configs_by_cp_id.find(config.candidate_pair_id) == |
| configs_by_cp_id.end()) { |
| const std::string candidate_pair_desc = |
| GetCandidatePairLogDescriptionAsString(config); |
| configs_by_cp_id[config.candidate_pair_id] = |
| TimeSeries("[" + std::to_string(config.candidate_pair_id) + "]" + |
| candidate_pair_desc, |
| LineStyle::kNone, PointStyle::kHighlight); |
| candidate_pair_desc_by_id_[config.candidate_pair_id] = |
| candidate_pair_desc; |
| } |
| float x = ToCallTimeSec(config.log_time_us()); |
| float y = static_cast<float>(config.type); |
| configs_by_cp_id[config.candidate_pair_id].points.emplace_back(x, y); |
| } |
| |
| // TODO(qingsi): There can be a large number of candidate pairs generated by |
| // certain calls and the frontend cannot render the chart in this case due to |
| // the failure of generating a palette with the same number of colors. |
| for (auto& kv : configs_by_cp_id) { |
| plot->AppendTimeSeries(std::move(kv.second)); |
| } |
| |
| plot->SetXAxis(ToCallTimeSec(begin_time_), call_duration_s_, "Time (s)", |
| kLeftMargin, kRightMargin); |
| plot->SetSuggestedYAxis(0, 3, "Numeric Config Type", kBottomMargin, |
| kTopMargin); |
| plot->SetTitle("[IceEventLog] ICE candidate pair configs"); |
| } |
| |
| std::string EventLogAnalyzer::GetCandidatePairLogDescriptionFromId( |
| uint32_t candidate_pair_id) { |
| if (candidate_pair_desc_by_id_.find(candidate_pair_id) != |
| candidate_pair_desc_by_id_.end()) { |
| return candidate_pair_desc_by_id_[candidate_pair_id]; |
| } |
| for (const auto& config : parsed_log_.ice_candidate_pair_configs()) { |
| // TODO(qingsi): Add the handling of the "Updated" config event after the |
| // visualization of property change for candidate pairs is introduced. |
| if (candidate_pair_desc_by_id_.find(config.candidate_pair_id) == |
| candidate_pair_desc_by_id_.end()) { |
| const std::string candidate_pair_desc = |
| GetCandidatePairLogDescriptionAsString(config); |
| candidate_pair_desc_by_id_[config.candidate_pair_id] = |
| candidate_pair_desc; |
| } |
| } |
| return candidate_pair_desc_by_id_[candidate_pair_id]; |
| } |
| |
| void EventLogAnalyzer::CreateIceConnectivityCheckGraph(Plot* plot) { |
| std::map<uint32_t, TimeSeries> checks_by_cp_id; |
| for (const auto& event : parsed_log_.ice_candidate_pair_events()) { |
| if (checks_by_cp_id.find(event.candidate_pair_id) == |
| checks_by_cp_id.end()) { |
| checks_by_cp_id[event.candidate_pair_id] = TimeSeries( |
| "[" + std::to_string(event.candidate_pair_id) + "]" + |
| GetCandidatePairLogDescriptionFromId(event.candidate_pair_id), |
| LineStyle::kNone, PointStyle::kHighlight); |
| } |
| float x = ToCallTimeSec(event.log_time_us()); |
| constexpr int kIceCandidatePairEventTypeOffset = |
| static_cast<int>(IceCandidatePairConfigType::kNumValues); |
| float y = static_cast<float>(event.type) + kIceCandidatePairEventTypeOffset; |
| checks_by_cp_id[event.candidate_pair_id].points.emplace_back(x, y); |
| } |
| |
| // TODO(qingsi): The same issue as in CreateIceCandidatePairConfigGraph. |
| for (auto& kv : checks_by_cp_id) { |
| plot->AppendTimeSeries(std::move(kv.second)); |
| } |
| |
| plot->SetXAxis(ToCallTimeSec(begin_time_), call_duration_s_, "Time (s)", |
| kLeftMargin, kRightMargin); |
| plot->SetSuggestedYAxis(0, 4, "Numeric Connectivity State", kBottomMargin, |
| kTopMargin); |
| plot->SetTitle("[IceEventLog] ICE connectivity checks"); |
| } |
| |
| void EventLogAnalyzer::CreateDtlsTransportStateGraph(Plot* plot) { |
| TimeSeries states("DTLS Transport State", LineStyle::kNone, |
| PointStyle::kHighlight); |
| for (const auto& event : parsed_log_.dtls_transport_states()) { |
| float x = ToCallTimeSec(event.log_time_us()); |
| float y = static_cast<float>(event.dtls_transport_state); |
| states.points.emplace_back(x, y); |
| } |
| plot->AppendTimeSeries(std::move(states)); |
| plot->SetXAxis(ToCallTimeSec(begin_time_), call_duration_s_, "Time (s)", |
| kLeftMargin, kRightMargin); |
| plot->SetSuggestedYAxis(0, static_cast<float>(DtlsTransportState::kNumValues), |
| "Numeric Transport State", kBottomMargin, kTopMargin); |
| plot->SetTitle("DTLS Transport State"); |
| } |
| |
| void EventLogAnalyzer::CreateDtlsWritableStateGraph(Plot* plot) { |
| TimeSeries writable("DTLS Writable", LineStyle::kNone, |
| PointStyle::kHighlight); |
| for (const auto& event : parsed_log_.dtls_writable_states()) { |
| float x = ToCallTimeSec(event.log_time_us()); |
| float y = static_cast<float>(event.writable); |
| writable.points.emplace_back(x, y); |
| } |
| plot->AppendTimeSeries(std::move(writable)); |
| plot->SetXAxis(ToCallTimeSec(begin_time_), call_duration_s_, "Time (s)", |
| kLeftMargin, kRightMargin); |
| plot->SetSuggestedYAxis(0, 1, "Writable", kBottomMargin, kTopMargin); |
| plot->SetTitle("DTLS Writable State"); |
| } |
| |
| void EventLogAnalyzer::PrintNotifications(FILE* file) { |
| fprintf(file, "========== TRIAGE NOTIFICATIONS ==========\n"); |
| for (const auto& alert : incoming_rtp_recv_time_gaps_) { |
| fprintf(file, "%3.3lf s : %s\n", alert.Time(), alert.ToString().c_str()); |
| } |
| for (const auto& alert : incoming_rtcp_recv_time_gaps_) { |
| fprintf(file, "%3.3lf s : %s\n", alert.Time(), alert.ToString().c_str()); |
| } |
| for (const auto& alert : outgoing_rtp_send_time_gaps_) { |
| fprintf(file, "%3.3lf s : %s\n", alert.Time(), alert.ToString().c_str()); |
| } |
| for (const auto& alert : outgoing_rtcp_send_time_gaps_) { |
| fprintf(file, "%3.3lf s : %s\n", alert.Time(), alert.ToString().c_str()); |
| } |
| for (const auto& alert : incoming_seq_num_jumps_) { |
| fprintf(file, "%3.3lf s : %s\n", alert.Time(), alert.ToString().c_str()); |
| } |
| for (const auto& alert : incoming_capture_time_jumps_) { |
| fprintf(file, "%3.3lf s : %s\n", alert.Time(), alert.ToString().c_str()); |
| } |
| for (const auto& alert : outgoing_seq_num_jumps_) { |
| fprintf(file, "%3.3lf s : %s\n", alert.Time(), alert.ToString().c_str()); |
| } |
| for (const auto& alert : outgoing_capture_time_jumps_) { |
| fprintf(file, "%3.3lf s : %s\n", alert.Time(), alert.ToString().c_str()); |
| } |
| for (const auto& alert : outgoing_high_loss_alerts_) { |
| fprintf(file, " : %s\n", alert.ToString().c_str()); |
| } |
| fprintf(file, "========== END TRIAGE NOTIFICATIONS ==========\n"); |
| } |
| |
| void EventLogAnalyzer::CreateStreamGapAlerts(PacketDirection direction) { |
| // With 100 packets/s (~800kbps), false positives would require 10 s without |
| // data. |
| constexpr int64_t kMaxSeqNumJump = 1000; |
| // With a 90 kHz clock, false positives would require 10 s without data. |
| constexpr int64_t kMaxCaptureTimeJump = 900000; |
| |
| int64_t end_time_us = log_segments_.empty() |
| ? std::numeric_limits<int64_t>::max() |
| : log_segments_.front().second; |
| |
| SeqNumUnwrapper<uint16_t> seq_num_unwrapper; |
| absl::optional<int64_t> last_seq_num; |
| SeqNumUnwrapper<uint32_t> capture_time_unwrapper; |
| absl::optional<int64_t> last_capture_time; |
| // Check for gaps in sequence numbers and capture timestamps. |
| for (const auto& stream : parsed_log_.rtp_packets_by_ssrc(direction)) { |
| for (const auto& packet : stream.packet_view) { |
| if (packet.log_time_us() > end_time_us) { |
| // Only process the first (LOG_START, LOG_END) segment. |
| break; |
| } |
| |
| int64_t seq_num = seq_num_unwrapper.Unwrap(packet.header.sequenceNumber); |
| if (last_seq_num.has_value() && |
| std::abs(seq_num - last_seq_num.value()) > kMaxSeqNumJump) { |
| Alert_SeqNumJump(direction, ToCallTimeSec(packet.log_time_us()), |
| packet.header.ssrc); |
| } |
| last_seq_num.emplace(seq_num); |
| |
| int64_t capture_time = |
| capture_time_unwrapper.Unwrap(packet.header.timestamp); |
| if (last_capture_time.has_value() && |
| std::abs(capture_time - last_capture_time.value()) > |
| kMaxCaptureTimeJump) { |
| Alert_CaptureTimeJump(direction, ToCallTimeSec(packet.log_time_us()), |
| packet.header.ssrc); |
| } |
| last_capture_time.emplace(capture_time); |
| } |
| } |
| } |
| |
| void EventLogAnalyzer::CreateTransmissionGapAlerts(PacketDirection direction) { |
| constexpr int64_t kMaxRtpTransmissionGap = 500000; |
| constexpr int64_t kMaxRtcpTransmissionGap = 2000000; |
| int64_t end_time_us = log_segments_.empty() |
| ? std::numeric_limits<int64_t>::max() |
| : log_segments_.front().second; |
| |
| // TODO(terelius): The parser could provide a list of all packets, ordered |
| // by time, for each direction. |
| std::multimap<int64_t, const LoggedRtpPacket*> rtp_in_direction; |
| for (const auto& stream : parsed_log_.rtp_packets_by_ssrc(direction)) { |
| for (const LoggedRtpPacket& rtp_packet : stream.packet_view) |
| rtp_in_direction.emplace(rtp_packet.log_time_us(), &rtp_packet); |
| } |
| absl::optional<int64_t> last_rtp_time; |
| for (const auto& kv : rtp_in_direction) { |
| int64_t timestamp = kv.first; |
| if (timestamp > end_time_us) { |
| // Only process the first (LOG_START, LOG_END) segment. |
| break; |
| } |
| int64_t duration = timestamp - last_rtp_time.value_or(0); |
| if (last_rtp_time.has_value() && duration > kMaxRtpTransmissionGap) { |
| // No packet sent/received for more than 500 ms. |
| Alert_RtpLogTimeGap(direction, ToCallTimeSec(timestamp), duration / 1000); |
| } |
| last_rtp_time.emplace(timestamp); |
| } |
| |
| absl::optional<int64_t> last_rtcp_time; |
| if (direction == kIncomingPacket) { |
| for (const auto& rtcp : parsed_log_.incoming_rtcp_packets()) { |
| if (rtcp.log_time_us() > end_time_us) { |
| // Only process the first (LOG_START, LOG_END) segment. |
| break; |
| } |
| int64_t duration = rtcp.log_time_us() - last_rtcp_time.value_or(0); |
| if (last_rtcp_time.has_value() && duration > kMaxRtcpTransmissionGap) { |
| // No feedback sent/received for more than 2000 ms. |
| Alert_RtcpLogTimeGap(direction, ToCallTimeSec(rtcp.log_time_us()), |
| duration / 1000); |
| } |
| last_rtcp_time.emplace(rtcp.log_time_us()); |
| } |
| } else { |
| for (const auto& rtcp : parsed_log_.outgoing_rtcp_packets()) { |
| if (rtcp.log_time_us() > end_time_us) { |
| // Only process the first (LOG_START, LOG_END) segment. |
| break; |
| } |
| int64_t duration = rtcp.log_time_us() - last_rtcp_time.value_or(0); |
| if (last_rtcp_time.has_value() && duration > kMaxRtcpTransmissionGap) { |
| // No feedback sent/received for more than 2000 ms. |
| Alert_RtcpLogTimeGap(direction, ToCallTimeSec(rtcp.log_time_us()), |
| duration / 1000); |
| } |
| last_rtcp_time.emplace(rtcp.log_time_us()); |
| } |
| } |
| } |
| |
| // TODO(terelius): Notifications could possibly be generated by the same code |
| // that produces the graphs. There is some code duplication that could be |
| // avoided, but that might be solved anyway when we move functionality from the |
| // analyzer to the parser. |
| void EventLogAnalyzer::CreateTriageNotifications() { |
| CreateStreamGapAlerts(kIncomingPacket); |
| CreateStreamGapAlerts(kOutgoingPacket); |
| CreateTransmissionGapAlerts(kIncomingPacket); |
| CreateTransmissionGapAlerts(kOutgoingPacket); |
| |
| int64_t end_time_us = log_segments_.empty() |
| ? std::numeric_limits<int64_t>::max() |
| : log_segments_.front().second; |
| |
| constexpr double kMaxLossFraction = 0.05; |
| // Loss feedback |
| int64_t total_lost_packets = 0; |
| int64_t total_expected_packets = 0; |
| for (auto& bwe_update : parsed_log_.bwe_loss_updates()) { |
| if (bwe_update.log_time_us() > end_time_us) { |
| // Only process the first (LOG_START, LOG_END) segment. |
| break; |
| } |
| int64_t lost_packets = static_cast<double>(bwe_update.fraction_lost) / 255 * |
| bwe_update.expected_packets; |
| total_lost_packets += lost_packets; |
| total_expected_packets += bwe_update.expected_packets; |
| } |
| double avg_outgoing_loss = |
| static_cast<double>(total_lost_packets) / total_expected_packets; |
| if (avg_outgoing_loss > kMaxLossFraction) { |
| Alert_OutgoingHighLoss(avg_outgoing_loss); |
| } |
| } |
| |
| } // namespace webrtc |