/* * Copyright (c) 2015 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. */ #ifdef ENABLE_RTC_EVENT_LOG #include #include #include #include "testing/gtest/include/gtest/gtest.h" #include "webrtc/base/buffer.h" #include "webrtc/base/checks.h" #include "webrtc/base/scoped_ptr.h" #include "webrtc/base/thread.h" #include "webrtc/call.h" #include "webrtc/call/rtc_event_log.h" #include "webrtc/modules/rtp_rtcp/source/rtp_sender.h" #include "webrtc/system_wrappers/include/clock.h" #include "webrtc/test/test_suite.h" #include "webrtc/test/testsupport/fileutils.h" #include "webrtc/test/testsupport/gtest_disable.h" // Files generated at build-time by the protobuf compiler. #ifdef WEBRTC_ANDROID_PLATFORM_BUILD #include "external/webrtc/webrtc/call/rtc_event_log.pb.h" #else #include "webrtc/call/rtc_event_log.pb.h" #endif namespace webrtc { namespace { const RTPExtensionType kExtensionTypes[] = { RTPExtensionType::kRtpExtensionTransmissionTimeOffset, RTPExtensionType::kRtpExtensionAudioLevel, RTPExtensionType::kRtpExtensionAbsoluteSendTime, RTPExtensionType::kRtpExtensionVideoRotation, RTPExtensionType::kRtpExtensionTransportSequenceNumber}; const char* kExtensionNames[] = {RtpExtension::kTOffset, RtpExtension::kAudioLevel, RtpExtension::kAbsSendTime, RtpExtension::kVideoRotation, RtpExtension::kTransportSequenceNumber}; const size_t kNumExtensions = 5; } // namespace // TODO(terelius): Place this definition with other parsing functions? MediaType GetRuntimeMediaType(rtclog::MediaType media_type) { switch (media_type) { case rtclog::MediaType::ANY: return MediaType::ANY; case rtclog::MediaType::AUDIO: return MediaType::AUDIO; case rtclog::MediaType::VIDEO: return MediaType::VIDEO; case rtclog::MediaType::DATA: return MediaType::DATA; } RTC_NOTREACHED(); return MediaType::ANY; } // Checks that the event has a timestamp, a type and exactly the data field // corresponding to the type. ::testing::AssertionResult IsValidBasicEvent(const rtclog::Event& event) { if (!event.has_timestamp_us()) return ::testing::AssertionFailure() << "Event has no timestamp"; if (!event.has_type()) return ::testing::AssertionFailure() << "Event has no event type"; rtclog::Event_EventType type = event.type(); if ((type == rtclog::Event::RTP_EVENT) != event.has_rtp_packet()) return ::testing::AssertionFailure() << "Event of type " << type << " has " << (event.has_rtp_packet() ? "" : "no ") << "RTP packet"; if ((type == rtclog::Event::RTCP_EVENT) != event.has_rtcp_packet()) return ::testing::AssertionFailure() << "Event of type " << type << " has " << (event.has_rtcp_packet() ? "" : "no ") << "RTCP packet"; if ((type == rtclog::Event::AUDIO_PLAYOUT_EVENT) != event.has_audio_playout_event()) return ::testing::AssertionFailure() << "Event of type " << type << " has " << (event.has_audio_playout_event() ? "" : "no ") << "audio_playout event"; if ((type == rtclog::Event::VIDEO_RECEIVER_CONFIG_EVENT) != event.has_video_receiver_config()) return ::testing::AssertionFailure() << "Event of type " << type << " has " << (event.has_video_receiver_config() ? "" : "no ") << "receiver config"; if ((type == rtclog::Event::VIDEO_SENDER_CONFIG_EVENT) != event.has_video_sender_config()) return ::testing::AssertionFailure() << "Event of type " << type << " has " << (event.has_video_sender_config() ? "" : "no ") << "sender config"; if ((type == rtclog::Event::AUDIO_RECEIVER_CONFIG_EVENT) != event.has_audio_receiver_config()) { return ::testing::AssertionFailure() << "Event of type " << type << " has " << (event.has_audio_receiver_config() ? "" : "no ") << "audio receiver config"; } if ((type == rtclog::Event::AUDIO_SENDER_CONFIG_EVENT) != event.has_audio_sender_config()) { return ::testing::AssertionFailure() << "Event of type " << type << " has " << (event.has_audio_sender_config() ? "" : "no ") << "audio sender config"; } return ::testing::AssertionSuccess(); } void VerifyReceiveStreamConfig(const rtclog::Event& event, const VideoReceiveStream::Config& config) { ASSERT_TRUE(IsValidBasicEvent(event)); ASSERT_EQ(rtclog::Event::VIDEO_RECEIVER_CONFIG_EVENT, event.type()); const rtclog::VideoReceiveConfig& receiver_config = event.video_receiver_config(); // Check SSRCs. ASSERT_TRUE(receiver_config.has_remote_ssrc()); EXPECT_EQ(config.rtp.remote_ssrc, receiver_config.remote_ssrc()); ASSERT_TRUE(receiver_config.has_local_ssrc()); EXPECT_EQ(config.rtp.local_ssrc, receiver_config.local_ssrc()); // Check RTCP settings. ASSERT_TRUE(receiver_config.has_rtcp_mode()); if (config.rtp.rtcp_mode == RtcpMode::kCompound) EXPECT_EQ(rtclog::VideoReceiveConfig::RTCP_COMPOUND, receiver_config.rtcp_mode()); else EXPECT_EQ(rtclog::VideoReceiveConfig::RTCP_REDUCEDSIZE, receiver_config.rtcp_mode()); ASSERT_TRUE(receiver_config.has_receiver_reference_time_report()); EXPECT_EQ(config.rtp.rtcp_xr.receiver_reference_time_report, receiver_config.receiver_reference_time_report()); ASSERT_TRUE(receiver_config.has_remb()); EXPECT_EQ(config.rtp.remb, receiver_config.remb()); // Check RTX map. ASSERT_EQ(static_cast(config.rtp.rtx.size()), receiver_config.rtx_map_size()); for (const rtclog::RtxMap& rtx_map : receiver_config.rtx_map()) { ASSERT_TRUE(rtx_map.has_payload_type()); ASSERT_TRUE(rtx_map.has_config()); EXPECT_EQ(1u, config.rtp.rtx.count(rtx_map.payload_type())); const rtclog::RtxConfig& rtx_config = rtx_map.config(); const VideoReceiveStream::Config::Rtp::Rtx& rtx = config.rtp.rtx.at(rtx_map.payload_type()); ASSERT_TRUE(rtx_config.has_rtx_ssrc()); ASSERT_TRUE(rtx_config.has_rtx_payload_type()); EXPECT_EQ(rtx.ssrc, rtx_config.rtx_ssrc()); EXPECT_EQ(rtx.payload_type, rtx_config.rtx_payload_type()); } // Check header extensions. ASSERT_EQ(static_cast(config.rtp.extensions.size()), receiver_config.header_extensions_size()); for (int i = 0; i < receiver_config.header_extensions_size(); i++) { ASSERT_TRUE(receiver_config.header_extensions(i).has_name()); ASSERT_TRUE(receiver_config.header_extensions(i).has_id()); const std::string& name = receiver_config.header_extensions(i).name(); int id = receiver_config.header_extensions(i).id(); EXPECT_EQ(config.rtp.extensions[i].id, id); EXPECT_EQ(config.rtp.extensions[i].name, name); } // Check decoders. ASSERT_EQ(static_cast(config.decoders.size()), receiver_config.decoders_size()); for (int i = 0; i < receiver_config.decoders_size(); i++) { ASSERT_TRUE(receiver_config.decoders(i).has_name()); ASSERT_TRUE(receiver_config.decoders(i).has_payload_type()); const std::string& decoder_name = receiver_config.decoders(i).name(); int decoder_type = receiver_config.decoders(i).payload_type(); EXPECT_EQ(config.decoders[i].payload_name, decoder_name); EXPECT_EQ(config.decoders[i].payload_type, decoder_type); } } void VerifySendStreamConfig(const rtclog::Event& event, const VideoSendStream::Config& config) { ASSERT_TRUE(IsValidBasicEvent(event)); ASSERT_EQ(rtclog::Event::VIDEO_SENDER_CONFIG_EVENT, event.type()); const rtclog::VideoSendConfig& sender_config = event.video_sender_config(); // Check SSRCs. ASSERT_EQ(static_cast(config.rtp.ssrcs.size()), sender_config.ssrcs_size()); for (int i = 0; i < sender_config.ssrcs_size(); i++) { EXPECT_EQ(config.rtp.ssrcs[i], sender_config.ssrcs(i)); } // Check header extensions. ASSERT_EQ(static_cast(config.rtp.extensions.size()), sender_config.header_extensions_size()); for (int i = 0; i < sender_config.header_extensions_size(); i++) { ASSERT_TRUE(sender_config.header_extensions(i).has_name()); ASSERT_TRUE(sender_config.header_extensions(i).has_id()); const std::string& name = sender_config.header_extensions(i).name(); int id = sender_config.header_extensions(i).id(); EXPECT_EQ(config.rtp.extensions[i].id, id); EXPECT_EQ(config.rtp.extensions[i].name, name); } // Check RTX settings. ASSERT_EQ(static_cast(config.rtp.rtx.ssrcs.size()), sender_config.rtx_ssrcs_size()); for (int i = 0; i < sender_config.rtx_ssrcs_size(); i++) { EXPECT_EQ(config.rtp.rtx.ssrcs[i], sender_config.rtx_ssrcs(i)); } if (sender_config.rtx_ssrcs_size() > 0) { ASSERT_TRUE(sender_config.has_rtx_payload_type()); EXPECT_EQ(config.rtp.rtx.payload_type, sender_config.rtx_payload_type()); } // Check CNAME. ASSERT_TRUE(sender_config.has_c_name()); EXPECT_EQ(config.rtp.c_name, sender_config.c_name()); // Check encoder. ASSERT_TRUE(sender_config.has_encoder()); ASSERT_TRUE(sender_config.encoder().has_name()); ASSERT_TRUE(sender_config.encoder().has_payload_type()); EXPECT_EQ(config.encoder_settings.payload_name, sender_config.encoder().name()); EXPECT_EQ(config.encoder_settings.payload_type, sender_config.encoder().payload_type()); } void VerifyRtpEvent(const rtclog::Event& event, bool incoming, MediaType media_type, uint8_t* header, size_t header_size, size_t total_size) { ASSERT_TRUE(IsValidBasicEvent(event)); ASSERT_EQ(rtclog::Event::RTP_EVENT, event.type()); const rtclog::RtpPacket& rtp_packet = event.rtp_packet(); ASSERT_TRUE(rtp_packet.has_incoming()); EXPECT_EQ(incoming, rtp_packet.incoming()); ASSERT_TRUE(rtp_packet.has_type()); EXPECT_EQ(media_type, GetRuntimeMediaType(rtp_packet.type())); ASSERT_TRUE(rtp_packet.has_packet_length()); EXPECT_EQ(total_size, rtp_packet.packet_length()); ASSERT_TRUE(rtp_packet.has_header()); ASSERT_EQ(header_size, rtp_packet.header().size()); for (size_t i = 0; i < header_size; i++) { EXPECT_EQ(header[i], static_cast(rtp_packet.header()[i])); } } void VerifyRtcpEvent(const rtclog::Event& event, bool incoming, MediaType media_type, uint8_t* packet, size_t total_size) { ASSERT_TRUE(IsValidBasicEvent(event)); ASSERT_EQ(rtclog::Event::RTCP_EVENT, event.type()); const rtclog::RtcpPacket& rtcp_packet = event.rtcp_packet(); ASSERT_TRUE(rtcp_packet.has_incoming()); EXPECT_EQ(incoming, rtcp_packet.incoming()); ASSERT_TRUE(rtcp_packet.has_type()); EXPECT_EQ(media_type, GetRuntimeMediaType(rtcp_packet.type())); ASSERT_TRUE(rtcp_packet.has_packet_data()); ASSERT_EQ(total_size, rtcp_packet.packet_data().size()); for (size_t i = 0; i < total_size; i++) { EXPECT_EQ(packet[i], static_cast(rtcp_packet.packet_data()[i])); } } void VerifyPlayoutEvent(const rtclog::Event& event, uint32_t ssrc) { ASSERT_TRUE(IsValidBasicEvent(event)); ASSERT_EQ(rtclog::Event::AUDIO_PLAYOUT_EVENT, event.type()); const rtclog::AudioPlayoutEvent& playout_event = event.audio_playout_event(); ASSERT_TRUE(playout_event.has_local_ssrc()); EXPECT_EQ(ssrc, playout_event.local_ssrc()); } void VerifyLogStartEvent(const rtclog::Event& event) { ASSERT_TRUE(IsValidBasicEvent(event)); EXPECT_EQ(rtclog::Event::LOG_START, event.type()); } /* * Bit number i of extension_bitvector is set to indicate the * presence of extension number i from kExtensionTypes / kExtensionNames. * The least significant bit extension_bitvector has number 0. */ size_t GenerateRtpPacket(uint32_t extensions_bitvector, uint32_t csrcs_count, uint8_t* packet, size_t packet_size) { RTC_CHECK_GE(packet_size, 16 + 4 * csrcs_count + 4 * kNumExtensions); Clock* clock = Clock::GetRealTimeClock(); RTPSender rtp_sender(false, // bool audio clock, // Clock* clock nullptr, // Transport* nullptr, // RtpAudioFeedback* nullptr, // PacedSender* nullptr, // PacketRouter* nullptr, // SendTimeObserver* nullptr, // BitrateStatisticsObserver* nullptr, // FrameCountObserver* nullptr); // SendSideDelayObserver* std::vector csrcs; for (unsigned i = 0; i < csrcs_count; i++) { csrcs.push_back(rand()); } rtp_sender.SetCsrcs(csrcs); rtp_sender.SetSSRC(rand()); rtp_sender.SetStartTimestamp(rand(), true); rtp_sender.SetSequenceNumber(rand()); for (unsigned i = 0; i < kNumExtensions; i++) { if (extensions_bitvector & (1u << i)) { rtp_sender.RegisterRtpHeaderExtension(kExtensionTypes[i], i + 1); } } int8_t payload_type = rand() % 128; bool marker_bit = (rand() % 2 == 1); uint32_t capture_timestamp = rand(); int64_t capture_time_ms = rand(); bool timestamp_provided = (rand() % 2 == 1); bool inc_sequence_number = (rand() % 2 == 1); size_t header_size = rtp_sender.BuildRTPheader( packet, payload_type, marker_bit, capture_timestamp, capture_time_ms, timestamp_provided, inc_sequence_number); for (size_t i = header_size; i < packet_size; i++) { packet[i] = rand(); } return header_size; } void GenerateRtcpPacket(uint8_t* packet, size_t packet_size) { for (size_t i = 0; i < packet_size; i++) { packet[i] = rand(); } } void GenerateVideoReceiveConfig(uint32_t extensions_bitvector, VideoReceiveStream::Config* config) { // Create a map from a payload type to an encoder name. VideoReceiveStream::Decoder decoder; decoder.payload_type = rand(); decoder.payload_name = (rand() % 2 ? "VP8" : "H264"); config->decoders.push_back(decoder); // Add SSRCs for the stream. config->rtp.remote_ssrc = rand(); config->rtp.local_ssrc = rand(); // Add extensions and settings for RTCP. config->rtp.rtcp_mode = rand() % 2 ? RtcpMode::kCompound : RtcpMode::kReducedSize; config->rtp.rtcp_xr.receiver_reference_time_report = (rand() % 2 == 1); config->rtp.remb = (rand() % 2 == 1); // Add a map from a payload type to a new ssrc and a new payload type for RTX. VideoReceiveStream::Config::Rtp::Rtx rtx_pair; rtx_pair.ssrc = rand(); rtx_pair.payload_type = rand(); config->rtp.rtx.insert(std::make_pair(rand(), rtx_pair)); // Add header extensions. for (unsigned i = 0; i < kNumExtensions; i++) { if (extensions_bitvector & (1u << i)) { config->rtp.extensions.push_back( RtpExtension(kExtensionNames[i], rand())); } } } void GenerateVideoSendConfig(uint32_t extensions_bitvector, VideoSendStream::Config* config) { // Create a map from a payload type to an encoder name. config->encoder_settings.payload_type = rand(); config->encoder_settings.payload_name = (rand() % 2 ? "VP8" : "H264"); // Add SSRCs for the stream. config->rtp.ssrcs.push_back(rand()); // Add a map from a payload type to new ssrcs and a new payload type for RTX. config->rtp.rtx.ssrcs.push_back(rand()); config->rtp.rtx.payload_type = rand(); // Add a CNAME. config->rtp.c_name = "some.user@some.host"; // Add header extensions. for (unsigned i = 0; i < kNumExtensions; i++) { if (extensions_bitvector & (1u << i)) { config->rtp.extensions.push_back( RtpExtension(kExtensionNames[i], rand())); } } } // Test for the RtcEventLog class. Dumps some RTP packets and other events // to disk, then reads them back to see if they match. void LogSessionAndReadBack(size_t rtp_count, size_t rtcp_count, size_t playout_count, uint32_t extensions_bitvector, uint32_t csrcs_count, unsigned int random_seed) { ASSERT_LE(rtcp_count, rtp_count); ASSERT_LE(playout_count, rtp_count); std::vector rtp_packets; std::vector rtcp_packets; std::vector rtp_header_sizes; std::vector playout_ssrcs; VideoReceiveStream::Config receiver_config(nullptr); VideoSendStream::Config sender_config(nullptr); srand(random_seed); // Create rtp_count RTP packets containing random data. for (size_t i = 0; i < rtp_count; i++) { size_t packet_size = 1000 + rand() % 64; rtp_packets.push_back(rtc::Buffer(packet_size)); size_t header_size = GenerateRtpPacket(extensions_bitvector, csrcs_count, rtp_packets[i].data(), packet_size); rtp_header_sizes.push_back(header_size); } // Create rtcp_count RTCP packets containing random data. for (size_t i = 0; i < rtcp_count; i++) { size_t packet_size = 1000 + rand() % 64; rtcp_packets.push_back(rtc::Buffer(packet_size)); GenerateRtcpPacket(rtcp_packets[i].data(), packet_size); } // Create playout_count random SSRCs to use when logging AudioPlayout events. for (size_t i = 0; i < playout_count; i++) { playout_ssrcs.push_back(static_cast(rand())); } // Create configurations for the video streams. GenerateVideoReceiveConfig(extensions_bitvector, &receiver_config); GenerateVideoSendConfig(extensions_bitvector, &sender_config); const int config_count = 2; // Find the name of the current test, in order to use it as a temporary // filename. auto test_info = ::testing::UnitTest::GetInstance()->current_test_info(); const std::string temp_filename = test::OutputPath() + test_info->test_case_name() + test_info->name(); // When log_dumper goes out of scope, it causes the log file to be flushed // to disk. { rtc::scoped_ptr log_dumper(RtcEventLog::Create()); log_dumper->LogVideoReceiveStreamConfig(receiver_config); log_dumper->LogVideoSendStreamConfig(sender_config); size_t rtcp_index = 1, playout_index = 1; for (size_t i = 1; i <= rtp_count; i++) { log_dumper->LogRtpHeader( (i % 2 == 0), // Every second packet is incoming. (i % 3 == 0) ? MediaType::AUDIO : MediaType::VIDEO, rtp_packets[i - 1].data(), rtp_packets[i - 1].size()); if (i * rtcp_count >= rtcp_index * rtp_count) { log_dumper->LogRtcpPacket( rtcp_index % 2 == 0, // Every second packet is incoming rtcp_index % 3 == 0 ? MediaType::AUDIO : MediaType::VIDEO, rtcp_packets[rtcp_index - 1].data(), rtcp_packets[rtcp_index - 1].size()); rtcp_index++; } if (i * playout_count >= playout_index * rtp_count) { log_dumper->LogAudioPlayout(playout_ssrcs[playout_index - 1]); playout_index++; } if (i == rtp_count / 2) { log_dumper->StartLogging(temp_filename, 10000000); } } } // Read the generated file from disk. rtclog::EventStream parsed_stream; ASSERT_TRUE(RtcEventLog::ParseRtcEventLog(temp_filename, &parsed_stream)); // Verify that what we read back from the event log is the same as // what we wrote down. For RTCP we log the full packets, but for // RTP we should only log the header. const int event_count = config_count + playout_count + rtcp_count + rtp_count + 1; EXPECT_EQ(event_count, parsed_stream.stream_size()); VerifyReceiveStreamConfig(parsed_stream.stream(0), receiver_config); VerifySendStreamConfig(parsed_stream.stream(1), sender_config); size_t event_index = config_count, rtcp_index = 1, playout_index = 1; for (size_t i = 1; i <= rtp_count; i++) { VerifyRtpEvent(parsed_stream.stream(event_index), (i % 2 == 0), // Every second packet is incoming. (i % 3 == 0) ? MediaType::AUDIO : MediaType::VIDEO, rtp_packets[i - 1].data(), rtp_header_sizes[i - 1], rtp_packets[i - 1].size()); event_index++; if (i * rtcp_count >= rtcp_index * rtp_count) { VerifyRtcpEvent(parsed_stream.stream(event_index), rtcp_index % 2 == 0, // Every second packet is incoming. rtcp_index % 3 == 0 ? MediaType::AUDIO : MediaType::VIDEO, rtcp_packets[rtcp_index - 1].data(), rtcp_packets[rtcp_index - 1].size()); event_index++; rtcp_index++; } if (i * playout_count >= playout_index * rtp_count) { VerifyPlayoutEvent(parsed_stream.stream(event_index), playout_ssrcs[playout_index - 1]); event_index++; playout_index++; } if (i == rtp_count / 2) { VerifyLogStartEvent(parsed_stream.stream(event_index)); event_index++; } } // Clean up temporary file - can be pretty slow. remove(temp_filename.c_str()); } TEST(RtcEventLogTest, LogSessionAndReadBack) { // Log 5 RTP, 2 RTCP, and 0 playout events with no header extensions or CSRCS. LogSessionAndReadBack(5, 2, 0, 0, 0, 321); // Enable AbsSendTime and TransportSequenceNumbers uint32_t extensions = 0; for (uint32_t i = 0; i < kNumExtensions; i++) { if (kExtensionTypes[i] == RTPExtensionType::kRtpExtensionAbsoluteSendTime || kExtensionTypes[i] == RTPExtensionType::kRtpExtensionTransportSequenceNumber) { extensions |= 1u << i; } } LogSessionAndReadBack(8, 2, 0, extensions, 0, 3141592653u); extensions = (1u << kNumExtensions) - 1; // Enable all header extensions LogSessionAndReadBack(9, 2, 3, extensions, 2, 2718281828u); // Try all combinations of header extensions and up to 2 CSRCS. for (extensions = 0; extensions < (1u << kNumExtensions); extensions++) { for (uint32_t csrcs_count = 0; csrcs_count < 3; csrcs_count++) { LogSessionAndReadBack(5 + extensions, // Number of RTP packets. 2 + csrcs_count, // Number of RTCP packets. 3 + csrcs_count, // Number of playout events extensions, // Bit vector choosing extensions csrcs_count, // Number of contributing sources rand()); } } } // Tests that the event queue works correctly, i.e. drops old RTP, RTCP and // debug events, but keeps config events even if they are older than the limit. void DropOldEvents(uint32_t extensions_bitvector, uint32_t csrcs_count, unsigned int random_seed) { rtc::Buffer old_rtp_packet; rtc::Buffer recent_rtp_packet; rtc::Buffer old_rtcp_packet; rtc::Buffer recent_rtcp_packet; VideoReceiveStream::Config receiver_config(nullptr); VideoSendStream::Config sender_config(nullptr); srand(random_seed); // Create two RTP packets containing random data. size_t packet_size = 1000 + rand() % 64; old_rtp_packet.SetSize(packet_size); GenerateRtpPacket(extensions_bitvector, csrcs_count, old_rtp_packet.data(), packet_size); packet_size = 1000 + rand() % 64; recent_rtp_packet.SetSize(packet_size); size_t recent_header_size = GenerateRtpPacket( extensions_bitvector, csrcs_count, recent_rtp_packet.data(), packet_size); // Create two RTCP packets containing random data. packet_size = 1000 + rand() % 64; old_rtcp_packet.SetSize(packet_size); GenerateRtcpPacket(old_rtcp_packet.data(), packet_size); packet_size = 1000 + rand() % 64; recent_rtcp_packet.SetSize(packet_size); GenerateRtcpPacket(recent_rtcp_packet.data(), packet_size); // Create configurations for the video streams. GenerateVideoReceiveConfig(extensions_bitvector, &receiver_config); GenerateVideoSendConfig(extensions_bitvector, &sender_config); // Find the name of the current test, in order to use it as a temporary // filename. auto test_info = ::testing::UnitTest::GetInstance()->current_test_info(); const std::string temp_filename = test::OutputPath() + test_info->test_case_name() + test_info->name(); // The log file will be flushed to disk when the log_dumper goes out of scope. { rtc::scoped_ptr log_dumper(RtcEventLog::Create()); // Reduce the time old events are stored to 50 ms. log_dumper->SetBufferDuration(50000); log_dumper->LogVideoReceiveStreamConfig(receiver_config); log_dumper->LogVideoSendStreamConfig(sender_config); log_dumper->LogRtpHeader(false, MediaType::AUDIO, old_rtp_packet.data(), old_rtp_packet.size()); log_dumper->LogRtcpPacket(true, MediaType::AUDIO, old_rtcp_packet.data(), old_rtcp_packet.size()); // Sleep 55 ms to let old events be removed from the queue. rtc::Thread::SleepMs(55); log_dumper->StartLogging(temp_filename, 10000000); log_dumper->LogRtpHeader(true, MediaType::VIDEO, recent_rtp_packet.data(), recent_rtp_packet.size()); log_dumper->LogRtcpPacket(false, MediaType::VIDEO, recent_rtcp_packet.data(), recent_rtcp_packet.size()); } // Read the generated file from disk. rtclog::EventStream parsed_stream; ASSERT_TRUE(RtcEventLog::ParseRtcEventLog(temp_filename, &parsed_stream)); // Verify that what we read back from the event log is the same as // what we wrote. Old RTP and RTCP events should have been discarded, // but old configuration events should still be available. EXPECT_EQ(5, parsed_stream.stream_size()); VerifyReceiveStreamConfig(parsed_stream.stream(0), receiver_config); VerifySendStreamConfig(parsed_stream.stream(1), sender_config); VerifyLogStartEvent(parsed_stream.stream(2)); VerifyRtpEvent(parsed_stream.stream(3), true, MediaType::VIDEO, recent_rtp_packet.data(), recent_header_size, recent_rtp_packet.size()); VerifyRtcpEvent(parsed_stream.stream(4), false, MediaType::VIDEO, recent_rtcp_packet.data(), recent_rtcp_packet.size()); // Clean up temporary file - can be pretty slow. remove(temp_filename.c_str()); } TEST(RtcEventLogTest, DropOldEvents) { // Enable all header extensions uint32_t extensions = (1u << kNumExtensions) - 1; uint32_t csrcs_count = 2; DropOldEvents(extensions, csrcs_count, 141421356); DropOldEvents(extensions, csrcs_count, 173205080); } } // namespace webrtc #endif // ENABLE_RTC_EVENT_LOG