/* * Copyright (c) 2017 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 #include #include #include #include #include "logging/rtc_event_log/encoder/rtc_event_log_encoder_legacy.h" #include "logging/rtc_event_log/encoder/rtc_event_log_encoder_new_format.h" #include "logging/rtc_event_log/encoder/rtc_event_log_encoder_v3.h" #include "logging/rtc_event_log/events/rtc_event_alr_state.h" #include "logging/rtc_event_log/events/rtc_event_audio_network_adaptation.h" #include "logging/rtc_event_log/events/rtc_event_audio_playout.h" #include "logging/rtc_event_log/events/rtc_event_audio_receive_stream_config.h" #include "logging/rtc_event_log/events/rtc_event_audio_send_stream_config.h" #include "logging/rtc_event_log/events/rtc_event_bwe_update_delay_based.h" #include "logging/rtc_event_log/events/rtc_event_bwe_update_loss_based.h" #include "logging/rtc_event_log/events/rtc_event_probe_cluster_created.h" #include "logging/rtc_event_log/events/rtc_event_probe_result_failure.h" #include "logging/rtc_event_log/events/rtc_event_probe_result_success.h" #include "logging/rtc_event_log/events/rtc_event_rtcp_packet_incoming.h" #include "logging/rtc_event_log/events/rtc_event_rtcp_packet_outgoing.h" #include "logging/rtc_event_log/events/rtc_event_rtp_packet_incoming.h" #include "logging/rtc_event_log/events/rtc_event_rtp_packet_outgoing.h" #include "logging/rtc_event_log/events/rtc_event_video_receive_stream_config.h" #include "logging/rtc_event_log/events/rtc_event_video_send_stream_config.h" #include "logging/rtc_event_log/rtc_event_log_parser.h" #include "logging/rtc_event_log/rtc_event_log_unittest_helper.h" #include "modules/audio_coding/audio_network_adaptor/include/audio_network_adaptor_config.h" #include "modules/rtp_rtcp/source/rtcp_packet/bye.h" #include "modules/rtp_rtcp/source/rtp_header_extensions.h" #include "rtc_base/fake_clock.h" #include "rtc_base/random.h" #include "test/gtest.h" namespace webrtc { class RtcEventLogEncoderTest : public ::testing::TestWithParam< std::tuple> { protected: RtcEventLogEncoderTest() : seed_(std::get<0>(GetParam())), prng_(seed_), encoding_type_(std::get<1>(GetParam())), event_count_(std::get<2>(GetParam())), force_repeated_fields_(std::get<3>(GetParam())), gen_(seed_ * 880001UL), verifier_(encoding_type_) { switch (encoding_type_) { case RtcEventLog::EncodingType::Legacy: encoder_ = std::make_unique(); break; case RtcEventLog::EncodingType::NewFormat: encoder_ = std::make_unique(); break; case RtcEventLog::EncodingType::ProtoFree: encoder_ = std::make_unique(); break; } encoded_ = encoder_->EncodeLogStart(rtc::TimeMillis(), rtc::TimeUTCMillis()); } ~RtcEventLogEncoderTest() override = default; // ANA events have some optional fields, so we want to make sure that we get // correct behavior both when all of the values are there, as well as when // only some. void TestRtcEventAudioNetworkAdaptation( const std::vector>&); template std::unique_ptr NewRtpPacket( uint32_t ssrc, const RtpHeaderExtensionMap& extension_map); template const std::vector* GetRtpPacketsBySsrc( const ParsedRtcEventLog* parsed_log, uint32_t ssrc); template void TestRtpPackets(); std::deque> history_; std::unique_ptr encoder_; ParsedRtcEventLog parsed_log_; const uint64_t seed_; Random prng_; const RtcEventLog::EncodingType encoding_type_; const size_t event_count_; const bool force_repeated_fields_; test::EventGenerator gen_; test::EventVerifier verifier_; std::string encoded_; }; void RtcEventLogEncoderTest::TestRtcEventAudioNetworkAdaptation( const std::vector>& events) { ASSERT_TRUE(history_.empty()) << "Function should be called once per test."; for (auto& event : events) { history_.push_back(event->Copy()); } encoded_ += encoder_->EncodeBatch(history_.begin(), history_.end()); ASSERT_TRUE(parsed_log_.ParseString(encoded_).ok()); const auto& ana_configs = parsed_log_.audio_network_adaptation_events(); ASSERT_EQ(ana_configs.size(), events.size()); for (size_t i = 0; i < events.size(); ++i) { verifier_.VerifyLoggedAudioNetworkAdaptationEvent(*events[i], ana_configs[i]); } } template <> std::unique_ptr RtcEventLogEncoderTest::NewRtpPacket( uint32_t ssrc, const RtpHeaderExtensionMap& extension_map) { return gen_.NewRtpPacketIncoming(ssrc, extension_map, false); } template <> std::unique_ptr RtcEventLogEncoderTest::NewRtpPacket( uint32_t ssrc, const RtpHeaderExtensionMap& extension_map) { return gen_.NewRtpPacketOutgoing(ssrc, extension_map, false); } template <> const std::vector* RtcEventLogEncoderTest::GetRtpPacketsBySsrc(const ParsedRtcEventLog* parsed_log, uint32_t ssrc) { const auto& incoming_streams = parsed_log->incoming_rtp_packets_by_ssrc(); for (const auto& stream : incoming_streams) { if (stream.ssrc == ssrc) { return &stream.incoming_packets; } } return nullptr; } template <> const std::vector* RtcEventLogEncoderTest::GetRtpPacketsBySsrc(const ParsedRtcEventLog* parsed_log, uint32_t ssrc) { const auto& outgoing_streams = parsed_log->outgoing_rtp_packets_by_ssrc(); for (const auto& stream : outgoing_streams) { if (stream.ssrc == ssrc) { return &stream.outgoing_packets; } } return nullptr; } template void RtcEventLogEncoderTest::TestRtpPackets() { // SSRCs will be randomly assigned out of this small pool, significant only // in that it also covers such edge cases as SSRC = 0 and SSRC = 0xffffffff. // The pool is intentionally small, so as to produce collisions. const std::vector kSsrcPool = {0x00000000, 0x12345678, 0xabcdef01, 0xffffffff, 0x20171024, 0x19840730, 0x19831230}; // TODO(terelius): Test extensions for legacy encoding, too. RtpHeaderExtensionMap extension_map; if (encoding_type_ != RtcEventLog::EncodingType::Legacy) { extension_map = gen_.NewRtpHeaderExtensionMap(true); } // Simulate `event_count_` RTP packets, with SSRCs assigned randomly // out of the small pool above. std::map>> events_by_ssrc; for (size_t i = 0; i < event_count_; ++i) { const uint32_t ssrc = kSsrcPool[prng_.Rand(kSsrcPool.size() - 1)]; std::unique_ptr event = (events_by_ssrc[ssrc].empty() || !force_repeated_fields_) ? NewRtpPacket(ssrc, extension_map) : events_by_ssrc[ssrc][0]->Copy(); history_.push_back(event->Copy()); events_by_ssrc[ssrc].emplace_back(std::move(event)); } // Encode and parse. encoded_ += encoder_->EncodeBatch(history_.begin(), history_.end()); ASSERT_TRUE(parsed_log_.ParseString(encoded_).ok()); // For each SSRC, make sure the RTP packets associated with it to have been // correctly encoded and parsed. for (auto it = events_by_ssrc.begin(); it != events_by_ssrc.end(); ++it) { const uint32_t ssrc = it->first; const auto& original_packets = it->second; const std::vector* parsed_rtp_packets = GetRtpPacketsBySsrc(&parsed_log_, ssrc); ASSERT_NE(parsed_rtp_packets, nullptr); ASSERT_EQ(original_packets.size(), parsed_rtp_packets->size()); for (size_t i = 0; i < original_packets.size(); ++i) { verifier_.VerifyLoggedRtpPacket( *original_packets[i], (*parsed_rtp_packets)[i]); } } } TEST_P(RtcEventLogEncoderTest, RtcEventAlrState) { std::vector> events(event_count_); for (size_t i = 0; i < event_count_; ++i) { events[i] = (i == 0 || !force_repeated_fields_) ? gen_.NewAlrState() : events[0]->Copy(); history_.push_back(events[i]->Copy()); } encoded_ += encoder_->EncodeBatch(history_.begin(), history_.end()); ASSERT_TRUE(parsed_log_.ParseString(encoded_).ok()); const auto& alr_state_events = parsed_log_.alr_state_events(); ASSERT_EQ(alr_state_events.size(), event_count_); for (size_t i = 0; i < event_count_; ++i) { verifier_.VerifyLoggedAlrStateEvent(*events[i], alr_state_events[i]); } } TEST_P(RtcEventLogEncoderTest, RtcEventRouteChange) { if (encoding_type_ == RtcEventLog::EncodingType::Legacy) { return; } std::vector> events(event_count_); for (size_t i = 0; i < event_count_; ++i) { events[i] = (i == 0 || !force_repeated_fields_) ? gen_.NewRouteChange() : events[0]->Copy(); history_.push_back(events[i]->Copy()); } encoded_ += encoder_->EncodeBatch(history_.begin(), history_.end()); ASSERT_TRUE(parsed_log_.ParseString(encoded_).ok()); const auto& route_change_events = parsed_log_.route_change_events(); ASSERT_EQ(route_change_events.size(), event_count_); for (size_t i = 0; i < event_count_; ++i) { verifier_.VerifyLoggedRouteChangeEvent(*events[i], route_change_events[i]); } } TEST_P(RtcEventLogEncoderTest, RtcEventRemoteEstimate) { std::vector> events(event_count_); for (size_t i = 0; i < event_count_; ++i) { events[i] = (i == 0 || !force_repeated_fields_) ? gen_.NewRemoteEstimate() : std::make_unique(*events[0]); history_.push_back(std::make_unique(*events[i])); } encoded_ += encoder_->EncodeBatch(history_.begin(), history_.end()); ASSERT_TRUE(parsed_log_.ParseString(encoded_).ok()); const auto& parsed_events = parsed_log_.remote_estimate_events(); ASSERT_EQ(parsed_events.size(), event_count_); for (size_t i = 0; i < event_count_; ++i) { verifier_.VerifyLoggedRemoteEstimateEvent(*events[i], parsed_events[i]); } } TEST_P(RtcEventLogEncoderTest, RtcEventAudioNetworkAdaptationBitrate) { std::vector> events( event_count_); for (size_t i = 0; i < event_count_; ++i) { if (i == 0 || !force_repeated_fields_) { auto runtime_config = std::make_unique(); const int bitrate_bps = rtc::checked_cast( prng_.Rand(0, std::numeric_limits::max())); runtime_config->bitrate_bps = bitrate_bps; events[i] = std::make_unique( std::move(runtime_config)); } else { events[i] = events[0]->Copy(); } } TestRtcEventAudioNetworkAdaptation(events); } TEST_P(RtcEventLogEncoderTest, RtcEventAudioNetworkAdaptationFrameLength) { std::vector> events( event_count_); for (size_t i = 0; i < event_count_; ++i) { if (i == 0 || !force_repeated_fields_) { auto runtime_config = std::make_unique(); const int frame_length_ms = prng_.Rand(1, 1000); runtime_config->frame_length_ms = frame_length_ms; events[i] = std::make_unique( std::move(runtime_config)); } else { events[i] = events[0]->Copy(); } } TestRtcEventAudioNetworkAdaptation(events); } TEST_P(RtcEventLogEncoderTest, RtcEventAudioNetworkAdaptationPacketLoss) { std::vector> events( event_count_); for (size_t i = 0; i < event_count_; ++i) { if (i == 0 || !force_repeated_fields_) { // To simplify the test, we just check powers of two. const float plr = std::pow(0.5f, prng_.Rand(1, 8)); auto runtime_config = std::make_unique(); runtime_config->uplink_packet_loss_fraction = plr; events[i] = std::make_unique( std::move(runtime_config)); } else { events[i] = events[0]->Copy(); } } TestRtcEventAudioNetworkAdaptation(events); } TEST_P(RtcEventLogEncoderTest, RtcEventAudioNetworkAdaptationFec) { std::vector> events( event_count_); for (size_t i = 0; i < event_count_; ++i) { if (i == 0 || !force_repeated_fields_) { auto runtime_config = std::make_unique(); runtime_config->enable_fec = prng_.Rand(); events[i] = std::make_unique( std::move(runtime_config)); } else { events[i] = events[0]->Copy(); } } TestRtcEventAudioNetworkAdaptation(events); } TEST_P(RtcEventLogEncoderTest, RtcEventAudioNetworkAdaptationDtx) { std::vector> events( event_count_); for (size_t i = 0; i < event_count_; ++i) { if (i == 0 || !force_repeated_fields_) { auto runtime_config = std::make_unique(); runtime_config->enable_dtx = prng_.Rand(); events[i] = std::make_unique( std::move(runtime_config)); } else { events[i] = events[0]->Copy(); } } TestRtcEventAudioNetworkAdaptation(events); } TEST_P(RtcEventLogEncoderTest, RtcEventAudioNetworkAdaptationChannels) { std::vector> events( event_count_); for (size_t i = 0; i < event_count_; ++i) { if (i == 0 || !force_repeated_fields_) { auto runtime_config = std::make_unique(); runtime_config->num_channels = prng_.Rand(1, 2); events[i] = std::make_unique( std::move(runtime_config)); } else { events[i] = events[0]->Copy(); } } TestRtcEventAudioNetworkAdaptation(events); } TEST_P(RtcEventLogEncoderTest, RtcEventAudioNetworkAdaptationAll) { std::vector> events( event_count_); for (size_t i = 0; i < event_count_; ++i) { if (i == 0 || !force_repeated_fields_) { auto runtime_config = std::make_unique(); runtime_config->bitrate_bps = rtc::checked_cast( prng_.Rand(0, std::numeric_limits::max())); runtime_config->frame_length_ms = prng_.Rand(1, 1000); runtime_config->uplink_packet_loss_fraction = std::pow(0.5f, prng_.Rand(1, 8)); runtime_config->enable_fec = prng_.Rand(); runtime_config->enable_dtx = prng_.Rand(); runtime_config->num_channels = prng_.Rand(1, 2); events[i] = std::make_unique( std::move(runtime_config)); } else { events[i] = events[0]->Copy(); } } TestRtcEventAudioNetworkAdaptation(events); } TEST_P(RtcEventLogEncoderTest, RtcEventAudioPlayout) { // SSRCs will be randomly assigned out of this small pool, significant only // in that it also covers such edge cases as SSRC = 0 and SSRC = 0xffffffff. // The pool is intentionally small, so as to produce collisions. const std::vector kSsrcPool = {0x00000000, 0x12345678, 0xabcdef01, 0xffffffff, 0x20171024, 0x19840730, 0x19831230}; std::map>> original_events_by_ssrc; for (size_t i = 0; i < event_count_; ++i) { const uint32_t ssrc = kSsrcPool[prng_.Rand(kSsrcPool.size() - 1)]; std::unique_ptr event = (original_events_by_ssrc[ssrc].empty() || !force_repeated_fields_) ? gen_.NewAudioPlayout(ssrc) : original_events_by_ssrc[ssrc][0]->Copy(); history_.push_back(event->Copy()); original_events_by_ssrc[ssrc].push_back(std::move(event)); } encoded_ += encoder_->EncodeBatch(history_.begin(), history_.end()); ASSERT_TRUE(parsed_log_.ParseString(encoded_).ok()); const auto& parsed_playout_events_by_ssrc = parsed_log_.audio_playout_events(); // Same number of distinct SSRCs. ASSERT_EQ(parsed_playout_events_by_ssrc.size(), original_events_by_ssrc.size()); for (auto& original_event_it : original_events_by_ssrc) { const uint32_t ssrc = original_event_it.first; const auto& original_playout_events = original_event_it.second; const auto& parsed_event_it = parsed_playout_events_by_ssrc.find(ssrc); ASSERT_TRUE(parsed_event_it != parsed_playout_events_by_ssrc.end()); const auto& parsed_playout_events = parsed_event_it->second; // Same number playout events for the SSRC under examination. ASSERT_EQ(original_playout_events.size(), parsed_playout_events.size()); for (size_t i = 0; i < original_playout_events.size(); ++i) { verifier_.VerifyLoggedAudioPlayoutEvent(*original_playout_events[i], parsed_playout_events[i]); } } } // TODO(eladalon/terelius): Test with multiple events in the batch. TEST_P(RtcEventLogEncoderTest, RtcEventAudioReceiveStreamConfig) { uint32_t ssrc = prng_.Rand(); RtpHeaderExtensionMap extensions = gen_.NewRtpHeaderExtensionMap(); std::unique_ptr event = gen_.NewAudioReceiveStreamConfig(ssrc, extensions); history_.push_back(event->Copy()); encoded_ += encoder_->EncodeBatch(history_.begin(), history_.end()); ASSERT_TRUE(parsed_log_.ParseString(encoded_).ok()); const auto& audio_recv_configs = parsed_log_.audio_recv_configs(); ASSERT_EQ(audio_recv_configs.size(), 1u); verifier_.VerifyLoggedAudioRecvConfig(*event, audio_recv_configs[0]); } // TODO(eladalon/terelius): Test with multiple events in the batch. TEST_P(RtcEventLogEncoderTest, RtcEventAudioSendStreamConfig) { uint32_t ssrc = prng_.Rand(); RtpHeaderExtensionMap extensions = gen_.NewRtpHeaderExtensionMap(); std::unique_ptr event = gen_.NewAudioSendStreamConfig(ssrc, extensions); history_.push_back(event->Copy()); encoded_ += encoder_->EncodeBatch(history_.begin(), history_.end()); ASSERT_TRUE(parsed_log_.ParseString(encoded_).ok()); const auto& audio_send_configs = parsed_log_.audio_send_configs(); ASSERT_EQ(audio_send_configs.size(), 1u); verifier_.VerifyLoggedAudioSendConfig(*event, audio_send_configs[0]); } TEST_P(RtcEventLogEncoderTest, RtcEventBweUpdateDelayBased) { std::vector> events( event_count_); for (size_t i = 0; i < event_count_; ++i) { events[i] = (i == 0 || !force_repeated_fields_) ? gen_.NewBweUpdateDelayBased() : events[0]->Copy(); history_.push_back(events[i]->Copy()); } encoded_ += encoder_->EncodeBatch(history_.begin(), history_.end()); ASSERT_TRUE(parsed_log_.ParseString(encoded_).ok()); const auto& bwe_delay_updates = parsed_log_.bwe_delay_updates(); ASSERT_EQ(bwe_delay_updates.size(), event_count_); for (size_t i = 0; i < event_count_; ++i) { verifier_.VerifyLoggedBweDelayBasedUpdate(*events[i], bwe_delay_updates[i]); } } TEST_P(RtcEventLogEncoderTest, RtcEventBweUpdateLossBased) { std::vector> events(event_count_); for (size_t i = 0; i < event_count_; ++i) { events[i] = (i == 0 || !force_repeated_fields_) ? gen_.NewBweUpdateLossBased() : events[0]->Copy(); history_.push_back(events[i]->Copy()); } encoded_ += encoder_->EncodeBatch(history_.begin(), history_.end()); ASSERT_TRUE(parsed_log_.ParseString(encoded_).ok()); const auto& bwe_loss_updates = parsed_log_.bwe_loss_updates(); ASSERT_EQ(bwe_loss_updates.size(), event_count_); for (size_t i = 0; i < event_count_; ++i) { verifier_.VerifyLoggedBweLossBasedUpdate(*events[i], bwe_loss_updates[i]); } } TEST_P(RtcEventLogEncoderTest, RtcEventGenericPacketReceived) { if (encoding_type_ == RtcEventLog::EncodingType::Legacy) { return; } std::vector> events( event_count_); for (size_t i = 0; i < event_count_; ++i) { events[i] = (i == 0 || !force_repeated_fields_) ? gen_.NewGenericPacketReceived() : events[0]->Copy(); history_.push_back(events[i]->Copy()); } encoded_ += encoder_->EncodeBatch(history_.begin(), history_.end()); ASSERT_TRUE(parsed_log_.ParseString(encoded_).ok()); const auto& packets_received = parsed_log_.generic_packets_received(); ASSERT_EQ(packets_received.size(), event_count_); for (size_t i = 0; i < event_count_; ++i) { verifier_.VerifyLoggedGenericPacketReceived(*events[i], packets_received[i]); } } TEST_P(RtcEventLogEncoderTest, RtcEventGenericPacketSent) { if (encoding_type_ == RtcEventLog::EncodingType::Legacy) { return; } std::vector> events(event_count_); for (size_t i = 0; i < event_count_; ++i) { events[i] = (i == 0 || !force_repeated_fields_) ? gen_.NewGenericPacketSent() : events[0]->Copy(); history_.push_back(events[i]->Copy()); } encoded_ += encoder_->EncodeBatch(history_.begin(), history_.end()); ASSERT_TRUE(parsed_log_.ParseString(encoded_).ok()); const auto& packets_sent = parsed_log_.generic_packets_sent(); ASSERT_EQ(packets_sent.size(), event_count_); for (size_t i = 0; i < event_count_; ++i) { verifier_.VerifyLoggedGenericPacketSent(*events[i], packets_sent[i]); } } TEST_P(RtcEventLogEncoderTest, RtcEventGenericAcksReceived) { if (encoding_type_ == RtcEventLog::EncodingType::Legacy) { return; } std::vector> events(event_count_); for (size_t i = 0; i < event_count_; ++i) { events[i] = (i == 0 || !force_repeated_fields_) ? gen_.NewGenericAckReceived() : events[0]->Copy(); history_.push_back(events[i]->Copy()); } encoded_ += encoder_->EncodeBatch(history_.begin(), history_.end()); ASSERT_TRUE(parsed_log_.ParseString(encoded_).ok()); const auto& decoded_events = parsed_log_.generic_acks_received(); ASSERT_EQ(decoded_events.size(), event_count_); for (size_t i = 0; i < event_count_; ++i) { verifier_.VerifyLoggedGenericAckReceived(*events[i], decoded_events[i]); } } TEST_P(RtcEventLogEncoderTest, RtcEventDtlsTransportState) { std::vector> events(event_count_); for (size_t i = 0; i < event_count_; ++i) { events[i] = (i == 0 || !force_repeated_fields_) ? gen_.NewDtlsTransportState() : events[0]->Copy(); history_.push_back(events[i]->Copy()); } encoded_ += encoder_->EncodeBatch(history_.begin(), history_.end()); ASSERT_TRUE(parsed_log_.ParseString(encoded_).ok()); const auto& dtls_transport_states = parsed_log_.dtls_transport_states(); if (encoding_type_ == RtcEventLog::EncodingType::Legacy) { ASSERT_EQ(dtls_transport_states.size(), 0u); return; } ASSERT_EQ(dtls_transport_states.size(), event_count_); for (size_t i = 0; i < event_count_; ++i) { verifier_.VerifyLoggedDtlsTransportState(*events[i], dtls_transport_states[i]); } } TEST_P(RtcEventLogEncoderTest, RtcEventDtlsWritableState) { std::vector> events(event_count_); for (size_t i = 0; i < event_count_; ++i) { events[i] = (i == 0 || !force_repeated_fields_) ? gen_.NewDtlsWritableState() : events[0]->Copy(); history_.push_back(events[i]->Copy()); } encoded_ += encoder_->EncodeBatch(history_.begin(), history_.end()); ASSERT_TRUE(parsed_log_.ParseString(encoded_).ok()); const auto& dtls_writable_states = parsed_log_.dtls_writable_states(); if (encoding_type_ == RtcEventLog::EncodingType::Legacy) { ASSERT_EQ(dtls_writable_states.size(), 0u); return; } ASSERT_EQ(dtls_writable_states.size(), event_count_); for (size_t i = 0; i < event_count_; ++i) { verifier_.VerifyLoggedDtlsWritableState(*events[i], dtls_writable_states[i]); } } TEST_P(RtcEventLogEncoderTest, RtcEventFrameDecoded) { // SSRCs will be randomly assigned out of this small pool, significant only // in that it also covers such edge cases as SSRC = 0 and SSRC = 0xffffffff. // The pool is intentionally small, so as to produce collisions. const std::vector kSsrcPool = {0x00000000, 0x12345678, 0xabcdef01, 0xffffffff, 0x20171024, 0x19840730, 0x19831230}; std::map>> original_events_by_ssrc; for (size_t i = 0; i < event_count_; ++i) { const uint32_t ssrc = kSsrcPool[prng_.Rand(kSsrcPool.size() - 1)]; std::unique_ptr event = (original_events_by_ssrc[ssrc].empty() || !force_repeated_fields_) ? gen_.NewFrameDecodedEvent(ssrc) : original_events_by_ssrc[ssrc][0]->Copy(); history_.push_back(event->Copy()); original_events_by_ssrc[ssrc].push_back(std::move(event)); } encoded_ += encoder_->EncodeBatch(history_.begin(), history_.end()); auto status = parsed_log_.ParseString(encoded_); if (!status.ok()) RTC_LOG(LS_ERROR) << status.message(); ASSERT_TRUE(status.ok()); const auto& decoded_frames_by_ssrc = parsed_log_.decoded_frames(); if (encoding_type_ == RtcEventLog::EncodingType::Legacy) { ASSERT_EQ(decoded_frames_by_ssrc.size(), 0u); return; } // Same number of distinct SSRCs. ASSERT_EQ(decoded_frames_by_ssrc.size(), original_events_by_ssrc.size()); for (const auto& original_event_it : original_events_by_ssrc) { const uint32_t ssrc = original_event_it.first; const std::vector>& original_frames = original_event_it.second; const auto& parsed_event_it = decoded_frames_by_ssrc.find(ssrc); ASSERT_TRUE(parsed_event_it != decoded_frames_by_ssrc.end()); const std::vector& parsed_frames = parsed_event_it->second; // Same number events for the SSRC under examination. ASSERT_EQ(original_frames.size(), parsed_frames.size()); for (size_t i = 0; i < original_frames.size(); ++i) { verifier_.VerifyLoggedFrameDecoded(*original_frames[i], parsed_frames[i]); } } } // TODO(eladalon/terelius): Test with multiple events in the batch. TEST_P(RtcEventLogEncoderTest, RtcEventIceCandidatePairConfig) { std::unique_ptr event = gen_.NewIceCandidatePairConfig(); history_.push_back(event->Copy()); encoded_ += encoder_->EncodeBatch(history_.begin(), history_.end()); ASSERT_TRUE(parsed_log_.ParseString(encoded_).ok()); const auto& ice_candidate_pair_configs = parsed_log_.ice_candidate_pair_configs(); ASSERT_EQ(ice_candidate_pair_configs.size(), 1u); verifier_.VerifyLoggedIceCandidatePairConfig(*event, ice_candidate_pair_configs[0]); } // TODO(eladalon/terelius): Test with multiple events in the batch. TEST_P(RtcEventLogEncoderTest, RtcEventIceCandidatePair) { std::unique_ptr event = gen_.NewIceCandidatePair(); history_.push_back(event->Copy()); encoded_ += encoder_->EncodeBatch(history_.begin(), history_.end()); ASSERT_TRUE(parsed_log_.ParseString(encoded_).ok()); const auto& ice_candidate_pair_events = parsed_log_.ice_candidate_pair_events(); ASSERT_EQ(ice_candidate_pair_events.size(), 1u); verifier_.VerifyLoggedIceCandidatePairEvent(*event, ice_candidate_pair_events[0]); } TEST_P(RtcEventLogEncoderTest, RtcEventLoggingStarted) { const int64_t timestamp_ms = prng_.Rand(1'000'000'000); const int64_t utc_time_ms = prng_.Rand(1'000'000'000); // Overwrite the previously encoded LogStart event. encoded_ = encoder_->EncodeLogStart(timestamp_ms * 1000, utc_time_ms * 1000); ASSERT_TRUE(parsed_log_.ParseString(encoded_).ok()); const auto& start_log_events = parsed_log_.start_log_events(); ASSERT_EQ(start_log_events.size(), 1u); verifier_.VerifyLoggedStartEvent(timestamp_ms * 1000, utc_time_ms * 1000, start_log_events[0]); } TEST_P(RtcEventLogEncoderTest, RtcEventLoggingStopped) { const int64_t start_timestamp_ms = prng_.Rand(1'000'000'000); const int64_t start_utc_time_ms = prng_.Rand(1'000'000'000); // Overwrite the previously encoded LogStart event. encoded_ = encoder_->EncodeLogStart(start_timestamp_ms * 1000, start_utc_time_ms * 1000); const int64_t stop_timestamp_ms = prng_.Rand(start_timestamp_ms, 2'000'000'000); encoded_ += encoder_->EncodeLogEnd(stop_timestamp_ms * 1000); ASSERT_TRUE(parsed_log_.ParseString(encoded_).ok()); const auto& stop_log_events = parsed_log_.stop_log_events(); ASSERT_EQ(stop_log_events.size(), 1u); verifier_.VerifyLoggedStopEvent(stop_timestamp_ms * 1000, stop_log_events[0]); } // TODO(eladalon/terelius): Test with multiple events in the batch. TEST_P(RtcEventLogEncoderTest, RtcEventProbeClusterCreated) { std::unique_ptr event = gen_.NewProbeClusterCreated(); history_.push_back(event->Copy()); encoded_ += encoder_->EncodeBatch(history_.begin(), history_.end()); ASSERT_TRUE(parsed_log_.ParseString(encoded_).ok()); const auto& bwe_probe_cluster_created_events = parsed_log_.bwe_probe_cluster_created_events(); ASSERT_EQ(bwe_probe_cluster_created_events.size(), 1u); verifier_.VerifyLoggedBweProbeClusterCreatedEvent( *event, bwe_probe_cluster_created_events[0]); } // TODO(eladalon/terelius): Test with multiple events in the batch. TEST_P(RtcEventLogEncoderTest, RtcEventProbeResultFailure) { std::unique_ptr event = gen_.NewProbeResultFailure(); history_.push_back(event->Copy()); encoded_ += encoder_->EncodeBatch(history_.begin(), history_.end()); ASSERT_TRUE(parsed_log_.ParseString(encoded_).ok()); const auto& bwe_probe_failure_events = parsed_log_.bwe_probe_failure_events(); ASSERT_EQ(bwe_probe_failure_events.size(), 1u); verifier_.VerifyLoggedBweProbeFailureEvent(*event, bwe_probe_failure_events[0]); } // TODO(eladalon/terelius): Test with multiple events in the batch. TEST_P(RtcEventLogEncoderTest, RtcEventProbeResultSuccess) { std::unique_ptr event = gen_.NewProbeResultSuccess(); history_.push_back(event->Copy()); encoded_ += encoder_->EncodeBatch(history_.begin(), history_.end()); ASSERT_TRUE(parsed_log_.ParseString(encoded_).ok()); const auto& bwe_probe_success_events = parsed_log_.bwe_probe_success_events(); ASSERT_EQ(bwe_probe_success_events.size(), 1u); verifier_.VerifyLoggedBweProbeSuccessEvent(*event, bwe_probe_success_events[0]); } TEST_P(RtcEventLogEncoderTest, RtcEventRtcpPacketIncoming) { if (force_repeated_fields_) { // RTCP packets maybe delivered twice (once for audio and once for video). // As a work around, we're removing duplicates in the parser. return; } std::vector> events(event_count_); for (size_t i = 0; i < event_count_; ++i) { events[i] = (i == 0 || !force_repeated_fields_) ? gen_.NewRtcpPacketIncoming() : events[0]->Copy(); history_.push_back(events[i]->Copy()); } encoded_ += encoder_->EncodeBatch(history_.begin(), history_.end()); ASSERT_TRUE(parsed_log_.ParseString(encoded_).ok()); const auto& incoming_rtcp_packets = parsed_log_.incoming_rtcp_packets(); ASSERT_EQ(incoming_rtcp_packets.size(), event_count_); for (size_t i = 0; i < event_count_; ++i) { verifier_.VerifyLoggedRtcpPacketIncoming(*events[i], incoming_rtcp_packets[i]); } } TEST_P(RtcEventLogEncoderTest, RtcEventRtcpPacketOutgoing) { std::vector> events(event_count_); for (size_t i = 0; i < event_count_; ++i) { events[i] = (i == 0 || !force_repeated_fields_) ? gen_.NewRtcpPacketOutgoing() : events[0]->Copy(); history_.push_back(events[i]->Copy()); } encoded_ += encoder_->EncodeBatch(history_.begin(), history_.end()); ASSERT_TRUE(parsed_log_.ParseString(encoded_).ok()); const auto& outgoing_rtcp_packets = parsed_log_.outgoing_rtcp_packets(); ASSERT_EQ(outgoing_rtcp_packets.size(), event_count_); for (size_t i = 0; i < event_count_; ++i) { verifier_.VerifyLoggedRtcpPacketOutgoing(*events[i], outgoing_rtcp_packets[i]); } } TEST_P(RtcEventLogEncoderTest, RtcEventRtcpReceiverReport) { if (force_repeated_fields_) { return; } rtc::ScopedFakeClock fake_clock; fake_clock.SetTime(Timestamp::Millis(prng_.Rand())); for (auto direction : {kIncomingPacket, kOutgoingPacket}) { std::vector events(event_count_); std::vector timestamps_ms(event_count_); for (size_t i = 0; i < event_count_; ++i) { timestamps_ms[i] = rtc::TimeMillis(); events[i] = gen_.NewReceiverReport(); rtc::Buffer buffer = events[i].Build(); if (direction == kIncomingPacket) { history_.push_back( std::make_unique(buffer)); } else { history_.push_back( std::make_unique(buffer)); } fake_clock.AdvanceTime(TimeDelta::Millis(prng_.Rand(0, 1000))); } encoded_ += encoder_->EncodeBatch(history_.begin(), history_.end()); ASSERT_TRUE(parsed_log_.ParseString(encoded_).ok()); const auto& receiver_reports = parsed_log_.receiver_reports(direction); ASSERT_EQ(receiver_reports.size(), event_count_); for (size_t i = 0; i < event_count_; ++i) { verifier_.VerifyLoggedReceiverReport(timestamps_ms[i], events[i], receiver_reports[i]); } } } TEST_P(RtcEventLogEncoderTest, RtcEventRtcpSenderReport) { if (force_repeated_fields_) { return; } rtc::ScopedFakeClock fake_clock; fake_clock.SetTime(Timestamp::Millis(prng_.Rand())); for (auto direction : {kIncomingPacket, kOutgoingPacket}) { std::vector events(event_count_); std::vector timestamps_ms(event_count_); for (size_t i = 0; i < event_count_; ++i) { timestamps_ms[i] = rtc::TimeMillis(); events[i] = gen_.NewSenderReport(); rtc::Buffer buffer = events[i].Build(); if (direction == kIncomingPacket) { history_.push_back( std::make_unique(buffer)); } else { history_.push_back( std::make_unique(buffer)); } fake_clock.AdvanceTime(TimeDelta::Millis(prng_.Rand(0, 1000))); } encoded_ += encoder_->EncodeBatch(history_.begin(), history_.end()); ASSERT_TRUE(parsed_log_.ParseString(encoded_).ok()); const auto& sender_reports = parsed_log_.sender_reports(direction); ASSERT_EQ(sender_reports.size(), event_count_); for (size_t i = 0; i < event_count_; ++i) { verifier_.VerifyLoggedSenderReport(timestamps_ms[i], events[i], sender_reports[i]); } } } TEST_P(RtcEventLogEncoderTest, RtcEventRtcpExtendedReports) { if (force_repeated_fields_) { return; } rtc::ScopedFakeClock fake_clock; fake_clock.SetTime(Timestamp::Millis(prng_.Rand())); for (auto direction : {kIncomingPacket, kOutgoingPacket}) { std::vector events(event_count_); std::vector timestamps_ms(event_count_); for (size_t i = 0; i < event_count_; ++i) { timestamps_ms[i] = rtc::TimeMillis(); events[i] = gen_.NewExtendedReports(); rtc::Buffer buffer = events[i].Build(); if (direction == kIncomingPacket) { history_.push_back( std::make_unique(buffer)); } else { history_.push_back( std::make_unique(buffer)); } fake_clock.AdvanceTime(TimeDelta::Millis(prng_.Rand(0, 1000))); } encoded_ += encoder_->EncodeBatch(history_.begin(), history_.end()); ASSERT_TRUE(parsed_log_.ParseString(encoded_).ok()); const auto& extended_reports = parsed_log_.extended_reports(direction); ASSERT_EQ(extended_reports.size(), event_count_); for (size_t i = 0; i < event_count_; ++i) { verifier_.VerifyLoggedExtendedReports(timestamps_ms[i], events[i], extended_reports[i]); } } } TEST_P(RtcEventLogEncoderTest, RtcEventRtcpFir) { if (force_repeated_fields_) { return; } rtc::ScopedFakeClock fake_clock; fake_clock.SetTime(Timestamp::Millis(prng_.Rand())); for (auto direction : {kIncomingPacket, kOutgoingPacket}) { std::vector events(event_count_); std::vector timestamps_ms(event_count_); for (size_t i = 0; i < event_count_; ++i) { timestamps_ms[i] = rtc::TimeMillis(); events[i] = gen_.NewFir(); rtc::Buffer buffer = events[i].Build(); if (direction == kIncomingPacket) { history_.push_back( std::make_unique(buffer)); } else { history_.push_back( std::make_unique(buffer)); } fake_clock.AdvanceTime(TimeDelta::Millis(prng_.Rand(0, 1000))); } encoded_ += encoder_->EncodeBatch(history_.begin(), history_.end()); ASSERT_TRUE(parsed_log_.ParseString(encoded_).ok()); const auto& firs = parsed_log_.firs(direction); ASSERT_EQ(firs.size(), event_count_); for (size_t i = 0; i < event_count_; ++i) { verifier_.VerifyLoggedFir(timestamps_ms[i], events[i], firs[i]); } } } TEST_P(RtcEventLogEncoderTest, RtcEventRtcpPli) { if (force_repeated_fields_) { return; } rtc::ScopedFakeClock fake_clock; fake_clock.SetTime(Timestamp::Millis(prng_.Rand())); for (auto direction : {kIncomingPacket, kOutgoingPacket}) { std::vector events(event_count_); std::vector timestamps_ms(event_count_); for (size_t i = 0; i < event_count_; ++i) { timestamps_ms[i] = rtc::TimeMillis(); events[i] = gen_.NewPli(); rtc::Buffer buffer = events[i].Build(); if (direction == kIncomingPacket) { history_.push_back( std::make_unique(buffer)); } else { history_.push_back( std::make_unique(buffer)); } fake_clock.AdvanceTime(TimeDelta::Millis(prng_.Rand(0, 1000))); } encoded_ += encoder_->EncodeBatch(history_.begin(), history_.end()); ASSERT_TRUE(parsed_log_.ParseString(encoded_).ok()); const auto& plis = parsed_log_.plis(direction); ASSERT_EQ(plis.size(), event_count_); for (size_t i = 0; i < event_count_; ++i) { verifier_.VerifyLoggedPli(timestamps_ms[i], events[i], plis[i]); } } } TEST_P(RtcEventLogEncoderTest, RtcEventRtcpBye) { if (force_repeated_fields_) { return; } rtc::ScopedFakeClock fake_clock; fake_clock.SetTime(Timestamp::Millis(prng_.Rand())); for (auto direction : {kIncomingPacket, kOutgoingPacket}) { std::vector events(event_count_); std::vector timestamps_ms(event_count_); for (size_t i = 0; i < event_count_; ++i) { timestamps_ms[i] = rtc::TimeMillis(); events[i] = gen_.NewBye(); rtc::Buffer buffer = events[i].Build(); if (direction == kIncomingPacket) { history_.push_back( std::make_unique(buffer)); } else { history_.push_back( std::make_unique(buffer)); } fake_clock.AdvanceTime(TimeDelta::Millis(prng_.Rand(0, 1000))); } encoded_ += encoder_->EncodeBatch(history_.begin(), history_.end()); ASSERT_TRUE(parsed_log_.ParseString(encoded_).ok()); const auto& byes = parsed_log_.byes(direction); ASSERT_EQ(byes.size(), event_count_); for (size_t i = 0; i < event_count_; ++i) { verifier_.VerifyLoggedBye(timestamps_ms[i], events[i], byes[i]); } } } TEST_P(RtcEventLogEncoderTest, RtcEventRtcpNack) { if (force_repeated_fields_) { return; } rtc::ScopedFakeClock fake_clock; fake_clock.SetTime(Timestamp::Millis(prng_.Rand())); for (auto direction : {kIncomingPacket, kOutgoingPacket}) { std::vector events(event_count_); std::vector timestamps_ms(event_count_); for (size_t i = 0; i < event_count_; ++i) { timestamps_ms[i] = rtc::TimeMillis(); events[i] = gen_.NewNack(); rtc::Buffer buffer = events[i].Build(); if (direction == kIncomingPacket) { history_.push_back( std::make_unique(buffer)); } else { history_.push_back( std::make_unique(buffer)); } fake_clock.AdvanceTime(TimeDelta::Millis(prng_.Rand(0, 1000))); } encoded_ += encoder_->EncodeBatch(history_.begin(), history_.end()); ASSERT_TRUE(parsed_log_.ParseString(encoded_).ok()); const auto& nacks = parsed_log_.nacks(direction); ASSERT_EQ(nacks.size(), event_count_); for (size_t i = 0; i < event_count_; ++i) { verifier_.VerifyLoggedNack(timestamps_ms[i], events[i], nacks[i]); } } } TEST_P(RtcEventLogEncoderTest, RtcEventRtcpRemb) { if (force_repeated_fields_) { return; } rtc::ScopedFakeClock fake_clock; fake_clock.SetTime(Timestamp::Millis(prng_.Rand())); for (auto direction : {kIncomingPacket, kOutgoingPacket}) { std::vector events(event_count_); std::vector timestamps_ms(event_count_); for (size_t i = 0; i < event_count_; ++i) { timestamps_ms[i] = rtc::TimeMillis(); events[i] = gen_.NewRemb(); rtc::Buffer buffer = events[i].Build(); if (direction == kIncomingPacket) { history_.push_back( std::make_unique(buffer)); } else { history_.push_back( std::make_unique(buffer)); } fake_clock.AdvanceTime(TimeDelta::Millis(prng_.Rand(0, 1000))); } encoded_ += encoder_->EncodeBatch(history_.begin(), history_.end()); ASSERT_TRUE(parsed_log_.ParseString(encoded_).ok()); const auto& rembs = parsed_log_.rembs(direction); ASSERT_EQ(rembs.size(), event_count_); for (size_t i = 0; i < event_count_; ++i) { verifier_.VerifyLoggedRemb(timestamps_ms[i], events[i], rembs[i]); } } } TEST_P(RtcEventLogEncoderTest, RtcEventRtcpTransportFeedback) { if (force_repeated_fields_) { return; } rtc::ScopedFakeClock fake_clock; fake_clock.SetTime(Timestamp::Millis(prng_.Rand())); for (auto direction : {kIncomingPacket, kOutgoingPacket}) { std::vector events; events.reserve(event_count_); std::vector timestamps_ms(event_count_); for (size_t i = 0; i < event_count_; ++i) { timestamps_ms[i] = rtc::TimeMillis(); events.emplace_back(gen_.NewTransportFeedback()); rtc::Buffer buffer = events[i].Build(); if (direction == kIncomingPacket) { history_.push_back( std::make_unique(buffer)); } else { history_.push_back( std::make_unique(buffer)); } fake_clock.AdvanceTime(TimeDelta::Millis(prng_.Rand(0, 1000))); } encoded_ += encoder_->EncodeBatch(history_.begin(), history_.end()); ASSERT_TRUE(parsed_log_.ParseString(encoded_).ok()); const auto& transport_feedbacks = parsed_log_.transport_feedbacks(direction); ASSERT_EQ(transport_feedbacks.size(), event_count_); for (size_t i = 0; i < event_count_; ++i) { verifier_.VerifyLoggedTransportFeedback(timestamps_ms[i], events[i], transport_feedbacks[i]); } } } TEST_P(RtcEventLogEncoderTest, RtcEventRtcpLossNotification) { if (force_repeated_fields_) { return; } rtc::ScopedFakeClock fake_clock; fake_clock.SetTime(Timestamp::Millis(prng_.Rand())); for (auto direction : {kIncomingPacket, kOutgoingPacket}) { std::vector events; events.reserve(event_count_); std::vector timestamps_ms(event_count_); for (size_t i = 0; i < event_count_; ++i) { timestamps_ms[i] = rtc::TimeMillis(); events.emplace_back(gen_.NewLossNotification()); rtc::Buffer buffer = events[i].Build(); if (direction == kIncomingPacket) { history_.push_back( std::make_unique(buffer)); } else { history_.push_back( std::make_unique(buffer)); } fake_clock.AdvanceTime(TimeDelta::Millis(prng_.Rand(0, 1000))); } encoded_ += encoder_->EncodeBatch(history_.begin(), history_.end()); ASSERT_TRUE(parsed_log_.ParseString(encoded_).ok()); const auto& loss_notifications = parsed_log_.loss_notifications(direction); ASSERT_EQ(loss_notifications.size(), event_count_); for (size_t i = 0; i < event_count_; ++i) { verifier_.VerifyLoggedLossNotification(timestamps_ms[i], events[i], loss_notifications[i]); } } } TEST_P(RtcEventLogEncoderTest, RtcEventRtpPacketIncoming) { TestRtpPackets(); } TEST_P(RtcEventLogEncoderTest, RtcEventRtpPacketOutgoing) { TestRtpPackets(); } // TODO(eladalon/terelius): Test with multiple events in the batch. TEST_P(RtcEventLogEncoderTest, RtcEventVideoReceiveStreamConfig) { uint32_t ssrc = prng_.Rand(); RtpHeaderExtensionMap extensions = gen_.NewRtpHeaderExtensionMap(); std::unique_ptr event = gen_.NewVideoReceiveStreamConfig(ssrc, extensions); history_.push_back(event->Copy()); encoded_ += encoder_->EncodeBatch(history_.begin(), history_.end()); ASSERT_TRUE(parsed_log_.ParseString(encoded_).ok()); const auto& video_recv_configs = parsed_log_.video_recv_configs(); ASSERT_EQ(video_recv_configs.size(), 1u); verifier_.VerifyLoggedVideoRecvConfig(*event, video_recv_configs[0]); } // TODO(eladalon/terelius): Test with multiple events in the batch. TEST_P(RtcEventLogEncoderTest, RtcEventVideoSendStreamConfig) { uint32_t ssrc = prng_.Rand(); RtpHeaderExtensionMap extensions = gen_.NewRtpHeaderExtensionMap(); std::unique_ptr event = gen_.NewVideoSendStreamConfig(ssrc, extensions); history_.push_back(event->Copy()); encoded_ += encoder_->EncodeBatch(history_.begin(), history_.end()); ASSERT_TRUE(parsed_log_.ParseString(encoded_).ok()); const auto& video_send_configs = parsed_log_.video_send_configs(); ASSERT_EQ(video_send_configs.size(), 1u); verifier_.VerifyLoggedVideoSendConfig(*event, video_send_configs[0]); } INSTANTIATE_TEST_SUITE_P( RandomSeeds, RtcEventLogEncoderTest, ::testing::Combine(/* Random seed*: */ ::testing::Values(1, 2, 3, 4, 5), /* Encoding: */ ::testing::Values(RtcEventLog::EncodingType::Legacy, RtcEventLog::EncodingType::NewFormat), /* Event count: */ ::testing::Values(1, 2, 10, 100), /* Repeated fields: */ ::testing::Bool())); class RtcEventLogEncoderSimpleTest : public ::testing::TestWithParam { protected: RtcEventLogEncoderSimpleTest() : encoding_type_(GetParam()) { switch (encoding_type_) { case RtcEventLog::EncodingType::Legacy: encoder_ = std::make_unique(); break; case RtcEventLog::EncodingType::NewFormat: encoder_ = std::make_unique(); break; case RtcEventLog::EncodingType::ProtoFree: encoder_ = std::make_unique(); break; } encoded_ = encoder_->EncodeLogStart(rtc::TimeMillis(), rtc::TimeUTCMillis()); } ~RtcEventLogEncoderSimpleTest() override = default; std::deque> history_; std::unique_ptr encoder_; ParsedRtcEventLog parsed_log_; const RtcEventLog::EncodingType encoding_type_; std::string encoded_; }; TEST_P(RtcEventLogEncoderSimpleTest, RtcEventLargeCompoundRtcpPacketIncoming) { // Create a compound packet containing multiple Bye messages. rtc::Buffer packet; size_t index = 0; for (int i = 0; i < 8; i++) { rtcp::Bye bye; std::string reason(255, 'a'); // Add some arbitrary data. bye.SetReason(reason); bye.SetSenderSsrc(0x12345678); packet.SetSize(packet.size() + bye.BlockLength()); bool created = bye.Create(packet.data(), &index, packet.capacity(), nullptr); ASSERT_TRUE(created); ASSERT_EQ(index, packet.size()); } EXPECT_GT(packet.size(), static_cast(IP_PACKET_SIZE)); auto event = std::make_unique(packet); history_.push_back(event->Copy()); encoded_ += encoder_->EncodeBatch(history_.begin(), history_.end()); ParsedRtcEventLog::ParseStatus status = parsed_log_.ParseString(encoded_); ASSERT_TRUE(status.ok()) << status.message(); const auto& incoming_rtcp_packets = parsed_log_.incoming_rtcp_packets(); ASSERT_EQ(incoming_rtcp_packets.size(), 1u); ASSERT_EQ(incoming_rtcp_packets[0].rtcp.raw_data.size(), packet.size()); EXPECT_EQ(memcmp(incoming_rtcp_packets[0].rtcp.raw_data.data(), packet.data(), packet.size()), 0); } INSTANTIATE_TEST_SUITE_P( LargeCompoundRtcp, RtcEventLogEncoderSimpleTest, ::testing::Values(RtcEventLog::EncodingType::Legacy, RtcEventLog::EncodingType::NewFormat)); } // namespace webrtc