/* * Copyright (c) 2012 The WebRTC project authors. All Rights Reserved. * * Use of this source code is governed by a BSD-style license * that can be found in the LICENSE file in the root of the source * tree. An additional intellectual property rights grant can be found * in the file PATENTS. All contributing project authors may * be found in the AUTHORS file in the root of the source tree. */ /* * This file includes unit tests for the RTPSender. */ #include "testing/gmock/include/gmock/gmock.h" #include "testing/gtest/include/gtest/gtest.h" #include "webrtc/base/buffer.h" #include "webrtc/base/scoped_ptr.h" #include "webrtc/modules/rtp_rtcp/interface/rtp_cvo.h" #include "webrtc/modules/rtp_rtcp/interface/rtp_header_parser.h" #include "webrtc/modules/rtp_rtcp/interface/rtp_rtcp_defines.h" #include "webrtc/modules/rtp_rtcp/source/rtp_format_video_generic.h" #include "webrtc/modules/rtp_rtcp/source/rtp_header_extension.h" #include "webrtc/modules/rtp_rtcp/source/rtp_sender.h" #include "webrtc/modules/rtp_rtcp/source/rtp_sender_video.h" #include "webrtc/system_wrappers/include/stl_util.h" #include "webrtc/modules/rtp_rtcp/source/rtp_utility.h" #include "webrtc/test/mock_transport.h" #include "webrtc/typedefs.h" namespace webrtc { namespace { const int kTransmissionTimeOffsetExtensionId = 1; const int kAbsoluteSendTimeExtensionId = 14; const int kTransportSequenceNumberExtensionId = 13; const int kPayload = 100; const int kRtxPayload = 98; const uint32_t kTimestamp = 10; const uint16_t kSeqNum = 33; const int kTimeOffset = 22222; const int kMaxPacketLength = 1500; const uint32_t kAbsoluteSendTime = 0x00aabbcc; const uint8_t kAudioLevel = 0x5a; const uint16_t kTransportSequenceNumber = 0xaabbu; const uint8_t kAudioLevelExtensionId = 9; const int kAudioPayload = 103; const uint64_t kStartTime = 123456789; const size_t kMaxPaddingSize = 224u; const int kVideoRotationExtensionId = 5; const VideoRotation kRotation = kVideoRotation_270; using testing::_; const uint8_t* GetPayloadData(const RTPHeader& rtp_header, const uint8_t* packet) { return packet + rtp_header.headerLength; } size_t GetPayloadDataLength(const RTPHeader& rtp_header, const size_t packet_length) { return packet_length - rtp_header.headerLength - rtp_header.paddingLength; } uint64_t ConvertMsToAbsSendTime(int64_t time_ms) { return (((time_ms << 18) + 500) / 1000) & 0x00ffffff; } class LoopbackTransportTest : public webrtc::Transport { public: LoopbackTransportTest() : packets_sent_(0), last_sent_packet_len_(0), total_bytes_sent_(0), last_sent_packet_(nullptr) {} ~LoopbackTransportTest() { STLDeleteContainerPointers(sent_packets_.begin(), sent_packets_.end()); } bool SendRtp(const uint8_t* data, size_t len, const PacketOptions& options) override { packets_sent_++; rtc::Buffer* buffer = new rtc::Buffer(reinterpret_cast(data), len); last_sent_packet_ = buffer->data(); last_sent_packet_len_ = len; total_bytes_sent_ += len; sent_packets_.push_back(buffer); return true; } bool SendRtcp(const uint8_t* data, size_t len) override { return false; } int packets_sent_; size_t last_sent_packet_len_; size_t total_bytes_sent_; uint8_t* last_sent_packet_; std::vector sent_packets_; }; } // namespace class MockRtpPacketSender : public RtpPacketSender { public: MockRtpPacketSender() {} virtual ~MockRtpPacketSender() {} MOCK_METHOD6(InsertPacket, void(Priority priority, uint32_t ssrc, uint16_t sequence_number, int64_t capture_time_ms, size_t bytes, bool retransmission)); }; class RtpSenderTest : public ::testing::Test { protected: RtpSenderTest() : fake_clock_(kStartTime), mock_paced_sender_(), rtp_sender_(), payload_(kPayload), transport_(), kMarkerBit(true) { EXPECT_CALL(mock_paced_sender_, InsertPacket(_, _, _, _, _, _)) .WillRepeatedly(testing::Return()); } void SetUp() override { SetUpRtpSender(true); } void SetUpRtpSender(bool pacer) { rtp_sender_.reset(new RTPSender(false, &fake_clock_, &transport_, nullptr, pacer ? &mock_paced_sender_ : nullptr, nullptr, nullptr, nullptr, nullptr, nullptr)); rtp_sender_->SetSequenceNumber(kSeqNum); } SimulatedClock fake_clock_; MockRtpPacketSender mock_paced_sender_; rtc::scoped_ptr rtp_sender_; int payload_; LoopbackTransportTest transport_; const bool kMarkerBit; uint8_t packet_[kMaxPacketLength]; void VerifyRTPHeaderCommon(const RTPHeader& rtp_header) { VerifyRTPHeaderCommon(rtp_header, kMarkerBit); } void VerifyRTPHeaderCommon(const RTPHeader& rtp_header, bool marker_bit) { EXPECT_EQ(marker_bit, rtp_header.markerBit); EXPECT_EQ(payload_, rtp_header.payloadType); EXPECT_EQ(kSeqNum, rtp_header.sequenceNumber); EXPECT_EQ(kTimestamp, rtp_header.timestamp); EXPECT_EQ(rtp_sender_->SSRC(), rtp_header.ssrc); EXPECT_EQ(0, rtp_header.numCSRCs); EXPECT_EQ(0U, rtp_header.paddingLength); } void SendPacket(int64_t capture_time_ms, int payload_length) { uint32_t timestamp = capture_time_ms * 90; int32_t rtp_length = rtp_sender_->BuildRTPheader(packet_, kPayload, kMarkerBit, timestamp, capture_time_ms); ASSERT_GE(rtp_length, 0); // Packet should be stored in a send bucket. EXPECT_EQ(0, rtp_sender_->SendToNetwork( packet_, payload_length, rtp_length, capture_time_ms, kAllowRetransmission, RtpPacketSender::kNormalPriority)); } }; // TODO(pbos): Move tests over from WithoutPacer to RtpSenderTest as this is our // default code path. class RtpSenderTestWithoutPacer : public RtpSenderTest { public: void SetUp() override { SetUpRtpSender(false); } }; class RtpSenderVideoTest : public RtpSenderTest { protected: virtual void SetUp() override { // TODO(pbos): Set up to use pacer. SetUpRtpSender(false); rtp_sender_video_.reset( new RTPSenderVideo(&fake_clock_, rtp_sender_.get())); } rtc::scoped_ptr rtp_sender_video_; void VerifyCVOPacket(uint8_t* data, size_t len, bool expect_cvo, RtpHeaderExtensionMap* map, uint16_t seq_num, VideoRotation rotation) { webrtc::RtpUtility::RtpHeaderParser rtp_parser(data, len); webrtc::RTPHeader rtp_header; size_t length = static_cast(rtp_sender_->BuildRTPheader( packet_, kPayload, expect_cvo /* marker_bit */, kTimestamp, 0)); if (expect_cvo) { ASSERT_EQ(kRtpHeaderSize + rtp_sender_->RtpHeaderExtensionTotalLength(), length); } else { ASSERT_EQ(kRtpHeaderSize, length); } ASSERT_TRUE(rtp_parser.Parse(rtp_header, map)); ASSERT_FALSE(rtp_parser.RTCP()); EXPECT_EQ(payload_, rtp_header.payloadType); EXPECT_EQ(seq_num, rtp_header.sequenceNumber); EXPECT_EQ(kTimestamp, rtp_header.timestamp); EXPECT_EQ(rtp_sender_->SSRC(), rtp_header.ssrc); EXPECT_EQ(0, rtp_header.numCSRCs); EXPECT_EQ(0U, rtp_header.paddingLength); EXPECT_EQ(ConvertVideoRotationToCVOByte(rotation), rtp_header.extension.videoRotation); } }; TEST_F(RtpSenderTestWithoutPacer, RegisterRtpTransmissionTimeOffsetHeaderExtension) { EXPECT_EQ(0u, rtp_sender_->RtpHeaderExtensionTotalLength()); EXPECT_EQ(0, rtp_sender_->RegisterRtpHeaderExtension( kRtpExtensionTransmissionTimeOffset, kTransmissionTimeOffsetExtensionId)); EXPECT_EQ(kRtpOneByteHeaderLength + kTransmissionTimeOffsetLength, rtp_sender_->RtpHeaderExtensionTotalLength()); EXPECT_EQ(0, rtp_sender_->DeregisterRtpHeaderExtension( kRtpExtensionTransmissionTimeOffset)); EXPECT_EQ(0u, rtp_sender_->RtpHeaderExtensionTotalLength()); } TEST_F(RtpSenderTestWithoutPacer, RegisterRtpAbsoluteSendTimeHeaderExtension) { EXPECT_EQ(0u, rtp_sender_->RtpHeaderExtensionTotalLength()); EXPECT_EQ(0, rtp_sender_->RegisterRtpHeaderExtension( kRtpExtensionAbsoluteSendTime, kAbsoluteSendTimeExtensionId)); EXPECT_EQ(RtpUtility::Word32Align(kRtpOneByteHeaderLength + kAbsoluteSendTimeLength), rtp_sender_->RtpHeaderExtensionTotalLength()); EXPECT_EQ(0, rtp_sender_->DeregisterRtpHeaderExtension( kRtpExtensionAbsoluteSendTime)); EXPECT_EQ(0u, rtp_sender_->RtpHeaderExtensionTotalLength()); } TEST_F(RtpSenderTestWithoutPacer, RegisterRtpAudioLevelHeaderExtension) { EXPECT_EQ(0u, rtp_sender_->RtpHeaderExtensionTotalLength()); EXPECT_EQ(0, rtp_sender_->RegisterRtpHeaderExtension( kRtpExtensionAudioLevel, kAudioLevelExtensionId)); EXPECT_EQ( RtpUtility::Word32Align(kRtpOneByteHeaderLength + kAudioLevelLength), rtp_sender_->RtpHeaderExtensionTotalLength()); EXPECT_EQ(0, rtp_sender_->DeregisterRtpHeaderExtension( kRtpExtensionAudioLevel)); EXPECT_EQ(0u, rtp_sender_->RtpHeaderExtensionTotalLength()); } TEST_F(RtpSenderTestWithoutPacer, RegisterRtpHeaderExtensions) { EXPECT_EQ(0u, rtp_sender_->RtpHeaderExtensionTotalLength()); EXPECT_EQ(0, rtp_sender_->RegisterRtpHeaderExtension( kRtpExtensionTransmissionTimeOffset, kTransmissionTimeOffsetExtensionId)); EXPECT_EQ(RtpUtility::Word32Align(kRtpOneByteHeaderLength + kTransmissionTimeOffsetLength), rtp_sender_->RtpHeaderExtensionTotalLength()); EXPECT_EQ(0, rtp_sender_->RegisterRtpHeaderExtension( kRtpExtensionAbsoluteSendTime, kAbsoluteSendTimeExtensionId)); EXPECT_EQ(RtpUtility::Word32Align(kRtpOneByteHeaderLength + kTransmissionTimeOffsetLength + kAbsoluteSendTimeLength), rtp_sender_->RtpHeaderExtensionTotalLength()); EXPECT_EQ(0, rtp_sender_->RegisterRtpHeaderExtension( kRtpExtensionAudioLevel, kAudioLevelExtensionId)); EXPECT_EQ(RtpUtility::Word32Align( kRtpOneByteHeaderLength + kTransmissionTimeOffsetLength + kAbsoluteSendTimeLength + kAudioLevelLength), rtp_sender_->RtpHeaderExtensionTotalLength()); EXPECT_EQ(0, rtp_sender_->RegisterRtpHeaderExtension( kRtpExtensionVideoRotation, kVideoRotationExtensionId)); EXPECT_TRUE(rtp_sender_->ActivateCVORtpHeaderExtension()); EXPECT_EQ(RtpUtility::Word32Align(kRtpOneByteHeaderLength + kTransmissionTimeOffsetLength + kAbsoluteSendTimeLength + kAudioLevelLength + kVideoRotationLength), rtp_sender_->RtpHeaderExtensionTotalLength()); // Deregister starts. EXPECT_EQ(0, rtp_sender_->DeregisterRtpHeaderExtension( kRtpExtensionTransmissionTimeOffset)); EXPECT_EQ(RtpUtility::Word32Align(kRtpOneByteHeaderLength + kAbsoluteSendTimeLength + kAudioLevelLength + kVideoRotationLength), rtp_sender_->RtpHeaderExtensionTotalLength()); EXPECT_EQ(0, rtp_sender_->DeregisterRtpHeaderExtension( kRtpExtensionAbsoluteSendTime)); EXPECT_EQ(RtpUtility::Word32Align(kRtpOneByteHeaderLength + kAudioLevelLength + kVideoRotationLength), rtp_sender_->RtpHeaderExtensionTotalLength()); EXPECT_EQ(0, rtp_sender_->DeregisterRtpHeaderExtension( kRtpExtensionAudioLevel)); EXPECT_EQ( RtpUtility::Word32Align(kRtpOneByteHeaderLength + kVideoRotationLength), rtp_sender_->RtpHeaderExtensionTotalLength()); EXPECT_EQ( 0, rtp_sender_->DeregisterRtpHeaderExtension(kRtpExtensionVideoRotation)); EXPECT_EQ(0u, rtp_sender_->RtpHeaderExtensionTotalLength()); } TEST_F(RtpSenderTestWithoutPacer, RegisterRtpVideoRotationHeaderExtension) { EXPECT_EQ(0u, rtp_sender_->RtpHeaderExtensionTotalLength()); EXPECT_EQ(0, rtp_sender_->RegisterRtpHeaderExtension( kRtpExtensionVideoRotation, kVideoRotationExtensionId)); EXPECT_EQ(0u, rtp_sender_->RtpHeaderExtensionTotalLength()); EXPECT_TRUE(rtp_sender_->ActivateCVORtpHeaderExtension()); EXPECT_EQ( RtpUtility::Word32Align(kRtpOneByteHeaderLength + kVideoRotationLength), rtp_sender_->RtpHeaderExtensionTotalLength()); EXPECT_EQ( 0, rtp_sender_->DeregisterRtpHeaderExtension(kRtpExtensionVideoRotation)); EXPECT_EQ(0u, rtp_sender_->RtpHeaderExtensionTotalLength()); } TEST_F(RtpSenderTestWithoutPacer, BuildRTPPacket) { size_t length = static_cast(rtp_sender_->BuildRTPheader( packet_, kPayload, kMarkerBit, kTimestamp, 0)); ASSERT_EQ(kRtpHeaderSize, length); // Verify webrtc::RtpUtility::RtpHeaderParser rtp_parser(packet_, length); webrtc::RTPHeader rtp_header; const bool valid_rtp_header = rtp_parser.Parse(rtp_header, nullptr); ASSERT_TRUE(valid_rtp_header); ASSERT_FALSE(rtp_parser.RTCP()); VerifyRTPHeaderCommon(rtp_header); EXPECT_EQ(length, rtp_header.headerLength); EXPECT_FALSE(rtp_header.extension.hasTransmissionTimeOffset); EXPECT_FALSE(rtp_header.extension.hasAbsoluteSendTime); EXPECT_FALSE(rtp_header.extension.hasAudioLevel); EXPECT_EQ(0, rtp_header.extension.transmissionTimeOffset); EXPECT_EQ(0u, rtp_header.extension.absoluteSendTime); EXPECT_FALSE(rtp_header.extension.voiceActivity); EXPECT_EQ(0u, rtp_header.extension.audioLevel); EXPECT_EQ(0u, rtp_header.extension.videoRotation); } TEST_F(RtpSenderTestWithoutPacer, BuildRTPPacketWithTransmissionOffsetExtension) { EXPECT_EQ(0, rtp_sender_->SetTransmissionTimeOffset(kTimeOffset)); EXPECT_EQ(0, rtp_sender_->RegisterRtpHeaderExtension( kRtpExtensionTransmissionTimeOffset, kTransmissionTimeOffsetExtensionId)); size_t length = static_cast(rtp_sender_->BuildRTPheader( packet_, kPayload, kMarkerBit, kTimestamp, 0)); ASSERT_EQ(kRtpHeaderSize + rtp_sender_->RtpHeaderExtensionTotalLength(), length); // Verify webrtc::RtpUtility::RtpHeaderParser rtp_parser(packet_, length); webrtc::RTPHeader rtp_header; RtpHeaderExtensionMap map; map.Register(kRtpExtensionTransmissionTimeOffset, kTransmissionTimeOffsetExtensionId); const bool valid_rtp_header = rtp_parser.Parse(rtp_header, &map); ASSERT_TRUE(valid_rtp_header); ASSERT_FALSE(rtp_parser.RTCP()); VerifyRTPHeaderCommon(rtp_header); EXPECT_EQ(length, rtp_header.headerLength); EXPECT_TRUE(rtp_header.extension.hasTransmissionTimeOffset); EXPECT_EQ(kTimeOffset, rtp_header.extension.transmissionTimeOffset); // Parse without map extension webrtc::RTPHeader rtp_header2; const bool valid_rtp_header2 = rtp_parser.Parse(rtp_header2, nullptr); ASSERT_TRUE(valid_rtp_header2); VerifyRTPHeaderCommon(rtp_header2); EXPECT_EQ(length, rtp_header2.headerLength); EXPECT_FALSE(rtp_header2.extension.hasTransmissionTimeOffset); EXPECT_EQ(0, rtp_header2.extension.transmissionTimeOffset); } TEST_F(RtpSenderTestWithoutPacer, BuildRTPPacketWithNegativeTransmissionOffsetExtension) { const int kNegTimeOffset = -500; EXPECT_EQ(0, rtp_sender_->SetTransmissionTimeOffset(kNegTimeOffset)); EXPECT_EQ(0, rtp_sender_->RegisterRtpHeaderExtension( kRtpExtensionTransmissionTimeOffset, kTransmissionTimeOffsetExtensionId)); size_t length = static_cast(rtp_sender_->BuildRTPheader( packet_, kPayload, kMarkerBit, kTimestamp, 0)); ASSERT_EQ(kRtpHeaderSize + rtp_sender_->RtpHeaderExtensionTotalLength(), length); // Verify webrtc::RtpUtility::RtpHeaderParser rtp_parser(packet_, length); webrtc::RTPHeader rtp_header; RtpHeaderExtensionMap map; map.Register(kRtpExtensionTransmissionTimeOffset, kTransmissionTimeOffsetExtensionId); const bool valid_rtp_header = rtp_parser.Parse(rtp_header, &map); ASSERT_TRUE(valid_rtp_header); ASSERT_FALSE(rtp_parser.RTCP()); VerifyRTPHeaderCommon(rtp_header); EXPECT_EQ(length, rtp_header.headerLength); EXPECT_TRUE(rtp_header.extension.hasTransmissionTimeOffset); EXPECT_EQ(kNegTimeOffset, rtp_header.extension.transmissionTimeOffset); } TEST_F(RtpSenderTestWithoutPacer, BuildRTPPacketWithAbsoluteSendTimeExtension) { EXPECT_EQ(0, rtp_sender_->SetAbsoluteSendTime(kAbsoluteSendTime)); EXPECT_EQ(0, rtp_sender_->RegisterRtpHeaderExtension( kRtpExtensionAbsoluteSendTime, kAbsoluteSendTimeExtensionId)); size_t length = static_cast(rtp_sender_->BuildRTPheader( packet_, kPayload, kMarkerBit, kTimestamp, 0)); ASSERT_EQ(kRtpHeaderSize + rtp_sender_->RtpHeaderExtensionTotalLength(), length); // Verify webrtc::RtpUtility::RtpHeaderParser rtp_parser(packet_, length); webrtc::RTPHeader rtp_header; RtpHeaderExtensionMap map; map.Register(kRtpExtensionAbsoluteSendTime, kAbsoluteSendTimeExtensionId); const bool valid_rtp_header = rtp_parser.Parse(rtp_header, &map); ASSERT_TRUE(valid_rtp_header); ASSERT_FALSE(rtp_parser.RTCP()); VerifyRTPHeaderCommon(rtp_header); EXPECT_EQ(length, rtp_header.headerLength); EXPECT_TRUE(rtp_header.extension.hasAbsoluteSendTime); EXPECT_EQ(kAbsoluteSendTime, rtp_header.extension.absoluteSendTime); // Parse without map extension webrtc::RTPHeader rtp_header2; const bool valid_rtp_header2 = rtp_parser.Parse(rtp_header2, nullptr); ASSERT_TRUE(valid_rtp_header2); VerifyRTPHeaderCommon(rtp_header2); EXPECT_EQ(length, rtp_header2.headerLength); EXPECT_FALSE(rtp_header2.extension.hasAbsoluteSendTime); EXPECT_EQ(0u, rtp_header2.extension.absoluteSendTime); } // Test CVO header extension is only set when marker bit is true. TEST_F(RtpSenderTestWithoutPacer, BuildRTPPacketWithVideoRotation_MarkerBit) { rtp_sender_->SetVideoRotation(kRotation); EXPECT_EQ(0, rtp_sender_->RegisterRtpHeaderExtension( kRtpExtensionVideoRotation, kVideoRotationExtensionId)); EXPECT_TRUE(rtp_sender_->ActivateCVORtpHeaderExtension()); RtpHeaderExtensionMap map; map.Register(kRtpExtensionVideoRotation, kVideoRotationExtensionId); size_t length = static_cast( rtp_sender_->BuildRTPheader(packet_, kPayload, true, kTimestamp, 0)); ASSERT_EQ(kRtpHeaderSize + rtp_sender_->RtpHeaderExtensionTotalLength(), length); // Verify webrtc::RtpUtility::RtpHeaderParser rtp_parser(packet_, length); webrtc::RTPHeader rtp_header; ASSERT_TRUE(rtp_parser.Parse(rtp_header, &map)); ASSERT_FALSE(rtp_parser.RTCP()); VerifyRTPHeaderCommon(rtp_header); EXPECT_EQ(length, rtp_header.headerLength); EXPECT_TRUE(rtp_header.extension.hasVideoRotation); EXPECT_EQ(ConvertVideoRotationToCVOByte(kRotation), rtp_header.extension.videoRotation); } // Test CVO header extension is not set when marker bit is false. TEST_F(RtpSenderTestWithoutPacer, DISABLED_BuildRTPPacketWithVideoRotation_NoMarkerBit) { rtp_sender_->SetVideoRotation(kRotation); EXPECT_EQ(0, rtp_sender_->RegisterRtpHeaderExtension( kRtpExtensionVideoRotation, kVideoRotationExtensionId)); EXPECT_TRUE(rtp_sender_->ActivateCVORtpHeaderExtension()); RtpHeaderExtensionMap map; map.Register(kRtpExtensionVideoRotation, kVideoRotationExtensionId); size_t length = static_cast( rtp_sender_->BuildRTPheader(packet_, kPayload, false, kTimestamp, 0)); ASSERT_EQ(kRtpHeaderSize, length); // Verify webrtc::RtpUtility::RtpHeaderParser rtp_parser(packet_, length); webrtc::RTPHeader rtp_header; ASSERT_TRUE(rtp_parser.Parse(rtp_header, &map)); ASSERT_FALSE(rtp_parser.RTCP()); VerifyRTPHeaderCommon(rtp_header, false); EXPECT_EQ(length, rtp_header.headerLength); EXPECT_FALSE(rtp_header.extension.hasVideoRotation); } TEST_F(RtpSenderTestWithoutPacer, BuildRTPPacketWithAudioLevelExtension) { EXPECT_EQ(0, rtp_sender_->RegisterRtpHeaderExtension( kRtpExtensionAudioLevel, kAudioLevelExtensionId)); size_t length = static_cast(rtp_sender_->BuildRTPheader( packet_, kPayload, kMarkerBit, kTimestamp, 0)); ASSERT_EQ(kRtpHeaderSize + rtp_sender_->RtpHeaderExtensionTotalLength(), length); // Verify webrtc::RtpUtility::RtpHeaderParser rtp_parser(packet_, length); webrtc::RTPHeader rtp_header; // Updating audio level is done in RTPSenderAudio, so simulate it here. rtp_parser.Parse(rtp_header); rtp_sender_->UpdateAudioLevel(packet_, length, rtp_header, true, kAudioLevel); RtpHeaderExtensionMap map; map.Register(kRtpExtensionAudioLevel, kAudioLevelExtensionId); const bool valid_rtp_header = rtp_parser.Parse(rtp_header, &map); ASSERT_TRUE(valid_rtp_header); ASSERT_FALSE(rtp_parser.RTCP()); VerifyRTPHeaderCommon(rtp_header); EXPECT_EQ(length, rtp_header.headerLength); EXPECT_TRUE(rtp_header.extension.hasAudioLevel); EXPECT_TRUE(rtp_header.extension.voiceActivity); EXPECT_EQ(kAudioLevel, rtp_header.extension.audioLevel); // Parse without map extension webrtc::RTPHeader rtp_header2; const bool valid_rtp_header2 = rtp_parser.Parse(rtp_header2, nullptr); ASSERT_TRUE(valid_rtp_header2); VerifyRTPHeaderCommon(rtp_header2); EXPECT_EQ(length, rtp_header2.headerLength); EXPECT_FALSE(rtp_header2.extension.hasAudioLevel); EXPECT_FALSE(rtp_header2.extension.voiceActivity); EXPECT_EQ(0u, rtp_header2.extension.audioLevel); } TEST_F(RtpSenderTestWithoutPacer, BuildRTPPacketWithHeaderExtensions) { EXPECT_EQ(0, rtp_sender_->SetTransmissionTimeOffset(kTimeOffset)); EXPECT_EQ(0, rtp_sender_->SetAbsoluteSendTime(kAbsoluteSendTime)); EXPECT_EQ(0, rtp_sender_->SetTransportSequenceNumber(kTransportSequenceNumber)); EXPECT_EQ(0, rtp_sender_->RegisterRtpHeaderExtension( kRtpExtensionTransmissionTimeOffset, kTransmissionTimeOffsetExtensionId)); EXPECT_EQ(0, rtp_sender_->RegisterRtpHeaderExtension( kRtpExtensionAbsoluteSendTime, kAbsoluteSendTimeExtensionId)); EXPECT_EQ(0, rtp_sender_->RegisterRtpHeaderExtension( kRtpExtensionAudioLevel, kAudioLevelExtensionId)); EXPECT_EQ(0, rtp_sender_->RegisterRtpHeaderExtension( kRtpExtensionTransportSequenceNumber, kTransportSequenceNumberExtensionId)); size_t length = static_cast(rtp_sender_->BuildRTPheader( packet_, kPayload, kMarkerBit, kTimestamp, 0)); ASSERT_EQ(kRtpHeaderSize + rtp_sender_->RtpHeaderExtensionTotalLength(), length); // Verify webrtc::RtpUtility::RtpHeaderParser rtp_parser(packet_, length); webrtc::RTPHeader rtp_header; // Updating audio level is done in RTPSenderAudio, so simulate it here. rtp_parser.Parse(rtp_header); rtp_sender_->UpdateAudioLevel(packet_, length, rtp_header, true, kAudioLevel); RtpHeaderExtensionMap map; map.Register(kRtpExtensionTransmissionTimeOffset, kTransmissionTimeOffsetExtensionId); map.Register(kRtpExtensionAbsoluteSendTime, kAbsoluteSendTimeExtensionId); map.Register(kRtpExtensionAudioLevel, kAudioLevelExtensionId); map.Register(kRtpExtensionTransportSequenceNumber, kTransportSequenceNumberExtensionId); const bool valid_rtp_header = rtp_parser.Parse(rtp_header, &map); ASSERT_TRUE(valid_rtp_header); ASSERT_FALSE(rtp_parser.RTCP()); VerifyRTPHeaderCommon(rtp_header); EXPECT_EQ(length, rtp_header.headerLength); EXPECT_TRUE(rtp_header.extension.hasTransmissionTimeOffset); EXPECT_TRUE(rtp_header.extension.hasAbsoluteSendTime); EXPECT_TRUE(rtp_header.extension.hasAudioLevel); EXPECT_TRUE(rtp_header.extension.hasTransportSequenceNumber); EXPECT_EQ(kTimeOffset, rtp_header.extension.transmissionTimeOffset); EXPECT_EQ(kAbsoluteSendTime, rtp_header.extension.absoluteSendTime); EXPECT_TRUE(rtp_header.extension.voiceActivity); EXPECT_EQ(kAudioLevel, rtp_header.extension.audioLevel); EXPECT_EQ(kTransportSequenceNumber, rtp_header.extension.transportSequenceNumber); // Parse without map extension webrtc::RTPHeader rtp_header2; const bool valid_rtp_header2 = rtp_parser.Parse(rtp_header2, nullptr); ASSERT_TRUE(valid_rtp_header2); VerifyRTPHeaderCommon(rtp_header2); EXPECT_EQ(length, rtp_header2.headerLength); EXPECT_FALSE(rtp_header2.extension.hasTransmissionTimeOffset); EXPECT_FALSE(rtp_header2.extension.hasAbsoluteSendTime); EXPECT_FALSE(rtp_header2.extension.hasAudioLevel); EXPECT_FALSE(rtp_header2.extension.hasTransportSequenceNumber); EXPECT_EQ(0, rtp_header2.extension.transmissionTimeOffset); EXPECT_EQ(0u, rtp_header2.extension.absoluteSendTime); EXPECT_FALSE(rtp_header2.extension.voiceActivity); EXPECT_EQ(0u, rtp_header2.extension.audioLevel); EXPECT_EQ(0u, rtp_header2.extension.transportSequenceNumber); } TEST_F(RtpSenderTest, TrafficSmoothingWithExtensions) { EXPECT_CALL(mock_paced_sender_, InsertPacket(RtpPacketSender::kNormalPriority, _, kSeqNum, _, _, _)) .WillRepeatedly(testing::Return()); rtp_sender_->SetStorePacketsStatus(true, 10); EXPECT_EQ(0, rtp_sender_->RegisterRtpHeaderExtension( kRtpExtensionTransmissionTimeOffset, kTransmissionTimeOffsetExtensionId)); EXPECT_EQ(0, rtp_sender_->RegisterRtpHeaderExtension( kRtpExtensionAbsoluteSendTime, kAbsoluteSendTimeExtensionId)); rtp_sender_->SetTargetBitrate(300000); int64_t capture_time_ms = fake_clock_.TimeInMilliseconds(); int rtp_length_int = rtp_sender_->BuildRTPheader( packet_, kPayload, kMarkerBit, kTimestamp, capture_time_ms); ASSERT_NE(-1, rtp_length_int); size_t rtp_length = static_cast(rtp_length_int); // Packet should be stored in a send bucket. EXPECT_EQ(0, rtp_sender_->SendToNetwork(packet_, 0, rtp_length, capture_time_ms, kAllowRetransmission, RtpPacketSender::kNormalPriority)); EXPECT_EQ(0, transport_.packets_sent_); const int kStoredTimeInMs = 100; fake_clock_.AdvanceTimeMilliseconds(kStoredTimeInMs); rtp_sender_->TimeToSendPacket(kSeqNum, capture_time_ms, false); // Process send bucket. Packet should now be sent. EXPECT_EQ(1, transport_.packets_sent_); EXPECT_EQ(rtp_length, transport_.last_sent_packet_len_); // Parse sent packet. webrtc::RtpUtility::RtpHeaderParser rtp_parser(transport_.last_sent_packet_, rtp_length); webrtc::RTPHeader rtp_header; RtpHeaderExtensionMap map; map.Register(kRtpExtensionTransmissionTimeOffset, kTransmissionTimeOffsetExtensionId); map.Register(kRtpExtensionAbsoluteSendTime, kAbsoluteSendTimeExtensionId); const bool valid_rtp_header = rtp_parser.Parse(rtp_header, &map); ASSERT_TRUE(valid_rtp_header); // Verify transmission time offset. EXPECT_EQ(kStoredTimeInMs * 90, rtp_header.extension.transmissionTimeOffset); uint64_t expected_send_time = ConvertMsToAbsSendTime(fake_clock_.TimeInMilliseconds()); EXPECT_EQ(expected_send_time, rtp_header.extension.absoluteSendTime); } TEST_F(RtpSenderTest, TrafficSmoothingRetransmits) { EXPECT_CALL(mock_paced_sender_, InsertPacket(RtpPacketSender::kNormalPriority, _, kSeqNum, _, _, _)) .WillRepeatedly(testing::Return()); rtp_sender_->SetStorePacketsStatus(true, 10); EXPECT_EQ(0, rtp_sender_->RegisterRtpHeaderExtension( kRtpExtensionTransmissionTimeOffset, kTransmissionTimeOffsetExtensionId)); EXPECT_EQ(0, rtp_sender_->RegisterRtpHeaderExtension( kRtpExtensionAbsoluteSendTime, kAbsoluteSendTimeExtensionId)); rtp_sender_->SetTargetBitrate(300000); int64_t capture_time_ms = fake_clock_.TimeInMilliseconds(); int rtp_length_int = rtp_sender_->BuildRTPheader( packet_, kPayload, kMarkerBit, kTimestamp, capture_time_ms); ASSERT_NE(-1, rtp_length_int); size_t rtp_length = static_cast(rtp_length_int); // Packet should be stored in a send bucket. EXPECT_EQ(0, rtp_sender_->SendToNetwork(packet_, 0, rtp_length, capture_time_ms, kAllowRetransmission, RtpPacketSender::kNormalPriority)); EXPECT_EQ(0, transport_.packets_sent_); EXPECT_CALL(mock_paced_sender_, InsertPacket(RtpPacketSender::kHighPriority, _, kSeqNum, _, _, _)) .WillRepeatedly(testing::Return()); const int kStoredTimeInMs = 100; fake_clock_.AdvanceTimeMilliseconds(kStoredTimeInMs); EXPECT_EQ(rtp_length_int, rtp_sender_->ReSendPacket(kSeqNum)); EXPECT_EQ(0, transport_.packets_sent_); rtp_sender_->TimeToSendPacket(kSeqNum, capture_time_ms, false); // Process send bucket. Packet should now be sent. EXPECT_EQ(1, transport_.packets_sent_); EXPECT_EQ(rtp_length, transport_.last_sent_packet_len_); // Parse sent packet. webrtc::RtpUtility::RtpHeaderParser rtp_parser(transport_.last_sent_packet_, rtp_length); webrtc::RTPHeader rtp_header; RtpHeaderExtensionMap map; map.Register(kRtpExtensionTransmissionTimeOffset, kTransmissionTimeOffsetExtensionId); map.Register(kRtpExtensionAbsoluteSendTime, kAbsoluteSendTimeExtensionId); const bool valid_rtp_header = rtp_parser.Parse(rtp_header, &map); ASSERT_TRUE(valid_rtp_header); // Verify transmission time offset. EXPECT_EQ(kStoredTimeInMs * 90, rtp_header.extension.transmissionTimeOffset); uint64_t expected_send_time = ConvertMsToAbsSendTime(fake_clock_.TimeInMilliseconds()); EXPECT_EQ(expected_send_time, rtp_header.extension.absoluteSendTime); } // This test sends 1 regular video packet, then 4 padding packets, and then // 1 more regular packet. TEST_F(RtpSenderTest, SendPadding) { // Make all (non-padding) packets go to send queue. EXPECT_CALL(mock_paced_sender_, InsertPacket(RtpPacketSender::kNormalPriority, _, _, _, _, _)) .WillRepeatedly(testing::Return()); uint16_t seq_num = kSeqNum; uint32_t timestamp = kTimestamp; rtp_sender_->SetStorePacketsStatus(true, 10); size_t rtp_header_len = kRtpHeaderSize; EXPECT_EQ(0, rtp_sender_->RegisterRtpHeaderExtension( kRtpExtensionTransmissionTimeOffset, kTransmissionTimeOffsetExtensionId)); rtp_header_len += 4; // 4 bytes extension. EXPECT_EQ(0, rtp_sender_->RegisterRtpHeaderExtension( kRtpExtensionAbsoluteSendTime, kAbsoluteSendTimeExtensionId)); rtp_header_len += 4; // 4 bytes extension. rtp_header_len += 4; // 4 extra bytes common to all extension headers. // Create and set up parser. rtc::scoped_ptr rtp_parser( webrtc::RtpHeaderParser::Create()); ASSERT_TRUE(rtp_parser.get() != nullptr); rtp_parser->RegisterRtpHeaderExtension(kRtpExtensionTransmissionTimeOffset, kTransmissionTimeOffsetExtensionId); rtp_parser->RegisterRtpHeaderExtension(kRtpExtensionAbsoluteSendTime, kAbsoluteSendTimeExtensionId); webrtc::RTPHeader rtp_header; rtp_sender_->SetTargetBitrate(300000); int64_t capture_time_ms = fake_clock_.TimeInMilliseconds(); int rtp_length_int = rtp_sender_->BuildRTPheader( packet_, kPayload, kMarkerBit, timestamp, capture_time_ms); const uint32_t media_packet_timestamp = timestamp; ASSERT_NE(-1, rtp_length_int); size_t rtp_length = static_cast(rtp_length_int); // Packet should be stored in a send bucket. EXPECT_EQ(0, rtp_sender_->SendToNetwork(packet_, 0, rtp_length, capture_time_ms, kAllowRetransmission, RtpPacketSender::kNormalPriority)); int total_packets_sent = 0; EXPECT_EQ(total_packets_sent, transport_.packets_sent_); const int kStoredTimeInMs = 100; fake_clock_.AdvanceTimeMilliseconds(kStoredTimeInMs); rtp_sender_->TimeToSendPacket(seq_num++, capture_time_ms, false); // Packet should now be sent. This test doesn't verify the regular video // packet, since it is tested in another test. EXPECT_EQ(++total_packets_sent, transport_.packets_sent_); timestamp += 90 * kStoredTimeInMs; // Send padding 4 times, waiting 50 ms between each. for (int i = 0; i < 4; ++i) { const int kPaddingPeriodMs = 50; const size_t kPaddingBytes = 100; const size_t kMaxPaddingLength = 224; // Value taken from rtp_sender.cc. // Padding will be forced to full packets. EXPECT_EQ(kMaxPaddingLength, rtp_sender_->TimeToSendPadding(kPaddingBytes)); // Process send bucket. Padding should now be sent. EXPECT_EQ(++total_packets_sent, transport_.packets_sent_); EXPECT_EQ(kMaxPaddingLength + rtp_header_len, transport_.last_sent_packet_len_); // Parse sent packet. ASSERT_TRUE(rtp_parser->Parse(transport_.last_sent_packet_, transport_.last_sent_packet_len_, &rtp_header)); EXPECT_EQ(kMaxPaddingLength, rtp_header.paddingLength); // Verify sequence number and timestamp. The timestamp should be the same // as the last media packet. EXPECT_EQ(seq_num++, rtp_header.sequenceNumber); EXPECT_EQ(media_packet_timestamp, rtp_header.timestamp); // Verify transmission time offset. int offset = timestamp - media_packet_timestamp; EXPECT_EQ(offset, rtp_header.extension.transmissionTimeOffset); uint64_t expected_send_time = ConvertMsToAbsSendTime(fake_clock_.TimeInMilliseconds()); EXPECT_EQ(expected_send_time, rtp_header.extension.absoluteSendTime); fake_clock_.AdvanceTimeMilliseconds(kPaddingPeriodMs); timestamp += 90 * kPaddingPeriodMs; } // Send a regular video packet again. capture_time_ms = fake_clock_.TimeInMilliseconds(); rtp_length_int = rtp_sender_->BuildRTPheader( packet_, kPayload, kMarkerBit, timestamp, capture_time_ms); ASSERT_NE(-1, rtp_length_int); rtp_length = static_cast(rtp_length_int); // Packet should be stored in a send bucket. EXPECT_EQ(0, rtp_sender_->SendToNetwork(packet_, 0, rtp_length, capture_time_ms, kAllowRetransmission, RtpPacketSender::kNormalPriority)); rtp_sender_->TimeToSendPacket(seq_num, capture_time_ms, false); // Process send bucket. EXPECT_EQ(++total_packets_sent, transport_.packets_sent_); EXPECT_EQ(rtp_length, transport_.last_sent_packet_len_); // Parse sent packet. ASSERT_TRUE(rtp_parser->Parse(transport_.last_sent_packet_, rtp_length, &rtp_header)); // Verify sequence number and timestamp. EXPECT_EQ(seq_num, rtp_header.sequenceNumber); EXPECT_EQ(timestamp, rtp_header.timestamp); // Verify transmission time offset. This packet is sent without delay. EXPECT_EQ(0, rtp_header.extension.transmissionTimeOffset); uint64_t expected_send_time = ConvertMsToAbsSendTime(fake_clock_.TimeInMilliseconds()); EXPECT_EQ(expected_send_time, rtp_header.extension.absoluteSendTime); } TEST_F(RtpSenderTest, SendRedundantPayloads) { MockTransport transport; rtp_sender_.reset(new RTPSender(false, &fake_clock_, &transport, nullptr, &mock_paced_sender_, nullptr, nullptr, nullptr, nullptr, nullptr)); rtp_sender_->SetSequenceNumber(kSeqNum); rtp_sender_->SetRtxPayloadType(kRtxPayload, kPayload); // Make all packets go through the pacer. EXPECT_CALL(mock_paced_sender_, InsertPacket(RtpPacketSender::kNormalPriority, _, _, _, _, _)) .WillRepeatedly(testing::Return()); uint16_t seq_num = kSeqNum; rtp_sender_->SetStorePacketsStatus(true, 10); int32_t rtp_header_len = kRtpHeaderSize; EXPECT_EQ(0, rtp_sender_->RegisterRtpHeaderExtension( kRtpExtensionAbsoluteSendTime, kAbsoluteSendTimeExtensionId)); rtp_header_len += 4; // 4 bytes extension. rtp_header_len += 4; // 4 extra bytes common to all extension headers. rtp_sender_->SetRtxStatus(kRtxRetransmitted | kRtxRedundantPayloads); rtp_sender_->SetRtxSsrc(1234); // Create and set up parser. rtc::scoped_ptr rtp_parser( webrtc::RtpHeaderParser::Create()); ASSERT_TRUE(rtp_parser.get() != nullptr); rtp_parser->RegisterRtpHeaderExtension(kRtpExtensionTransmissionTimeOffset, kTransmissionTimeOffsetExtensionId); rtp_parser->RegisterRtpHeaderExtension(kRtpExtensionAbsoluteSendTime, kAbsoluteSendTimeExtensionId); rtp_sender_->SetTargetBitrate(300000); const size_t kNumPayloadSizes = 10; const size_t kPayloadSizes[kNumPayloadSizes] = {500, 550, 600, 650, 700, 750, 800, 850, 900, 950}; // Send 10 packets of increasing size. for (size_t i = 0; i < kNumPayloadSizes; ++i) { int64_t capture_time_ms = fake_clock_.TimeInMilliseconds(); EXPECT_CALL(transport, SendRtp(_, _, _)).WillOnce(testing::Return(true)); SendPacket(capture_time_ms, kPayloadSizes[i]); rtp_sender_->TimeToSendPacket(seq_num++, capture_time_ms, false); fake_clock_.AdvanceTimeMilliseconds(33); } // The amount of padding to send it too small to send a payload packet. EXPECT_CALL(transport, SendRtp(_, kMaxPaddingSize + rtp_header_len, _)) .WillOnce(testing::Return(true)); EXPECT_EQ(kMaxPaddingSize, rtp_sender_->TimeToSendPadding(49)); EXPECT_CALL(transport, SendRtp(_, kPayloadSizes[0] + rtp_header_len + kRtxHeaderSize, _)) .WillOnce(testing::Return(true)); EXPECT_EQ(kPayloadSizes[0], rtp_sender_->TimeToSendPadding(500)); EXPECT_CALL(transport, SendRtp(_, kPayloadSizes[kNumPayloadSizes - 1] + rtp_header_len + kRtxHeaderSize, _)) .WillOnce(testing::Return(true)); EXPECT_CALL(transport, SendRtp(_, kMaxPaddingSize + rtp_header_len, _)) .WillOnce(testing::Return(true)); EXPECT_EQ(kPayloadSizes[kNumPayloadSizes - 1] + kMaxPaddingSize, rtp_sender_->TimeToSendPadding(999)); } TEST_F(RtpSenderTestWithoutPacer, SendGenericVideo) { char payload_name[RTP_PAYLOAD_NAME_SIZE] = "GENERIC"; const uint8_t payload_type = 127; ASSERT_EQ(0, rtp_sender_->RegisterPayload(payload_name, payload_type, 90000, 0, 1500)); uint8_t payload[] = {47, 11, 32, 93, 89}; // Send keyframe ASSERT_EQ( 0, rtp_sender_->SendOutgoingData(kVideoFrameKey, payload_type, 1234, 4321, payload, sizeof(payload), nullptr)); RtpUtility::RtpHeaderParser rtp_parser(transport_.last_sent_packet_, transport_.last_sent_packet_len_); webrtc::RTPHeader rtp_header; ASSERT_TRUE(rtp_parser.Parse(rtp_header)); const uint8_t* payload_data = GetPayloadData(rtp_header, transport_.last_sent_packet_); uint8_t generic_header = *payload_data++; ASSERT_EQ(sizeof(payload) + sizeof(generic_header), GetPayloadDataLength(rtp_header, transport_.last_sent_packet_len_)); EXPECT_TRUE(generic_header & RtpFormatVideoGeneric::kKeyFrameBit); EXPECT_TRUE(generic_header & RtpFormatVideoGeneric::kFirstPacketBit); EXPECT_EQ(0, memcmp(payload, payload_data, sizeof(payload))); // Send delta frame payload[0] = 13; payload[1] = 42; payload[4] = 13; ASSERT_EQ(0, rtp_sender_->SendOutgoingData(kVideoFrameDelta, payload_type, 1234, 4321, payload, sizeof(payload), nullptr)); RtpUtility::RtpHeaderParser rtp_parser2(transport_.last_sent_packet_, transport_.last_sent_packet_len_); ASSERT_TRUE(rtp_parser.Parse(rtp_header)); payload_data = GetPayloadData(rtp_header, transport_.last_sent_packet_); generic_header = *payload_data++; EXPECT_FALSE(generic_header & RtpFormatVideoGeneric::kKeyFrameBit); EXPECT_TRUE(generic_header & RtpFormatVideoGeneric::kFirstPacketBit); ASSERT_EQ(sizeof(payload) + sizeof(generic_header), GetPayloadDataLength(rtp_header, transport_.last_sent_packet_len_)); EXPECT_EQ(0, memcmp(payload, payload_data, sizeof(payload))); } TEST_F(RtpSenderTest, FrameCountCallbacks) { class TestCallback : public FrameCountObserver { public: TestCallback() : FrameCountObserver(), num_calls_(0), ssrc_(0) {} virtual ~TestCallback() {} void FrameCountUpdated(const FrameCounts& frame_counts, uint32_t ssrc) override { ++num_calls_; ssrc_ = ssrc; frame_counts_ = frame_counts; } uint32_t num_calls_; uint32_t ssrc_; FrameCounts frame_counts_; } callback; rtp_sender_.reset(new RTPSender(false, &fake_clock_, &transport_, nullptr, &mock_paced_sender_, nullptr, nullptr, nullptr, &callback, nullptr)); char payload_name[RTP_PAYLOAD_NAME_SIZE] = "GENERIC"; const uint8_t payload_type = 127; ASSERT_EQ(0, rtp_sender_->RegisterPayload(payload_name, payload_type, 90000, 0, 1500)); uint8_t payload[] = {47, 11, 32, 93, 89}; rtp_sender_->SetStorePacketsStatus(true, 1); uint32_t ssrc = rtp_sender_->SSRC(); ASSERT_EQ( 0, rtp_sender_->SendOutgoingData(kVideoFrameKey, payload_type, 1234, 4321, payload, sizeof(payload), nullptr)); EXPECT_EQ(1U, callback.num_calls_); EXPECT_EQ(ssrc, callback.ssrc_); EXPECT_EQ(1, callback.frame_counts_.key_frames); EXPECT_EQ(0, callback.frame_counts_.delta_frames); ASSERT_EQ(0, rtp_sender_->SendOutgoingData(kVideoFrameDelta, payload_type, 1234, 4321, payload, sizeof(payload), nullptr)); EXPECT_EQ(2U, callback.num_calls_); EXPECT_EQ(ssrc, callback.ssrc_); EXPECT_EQ(1, callback.frame_counts_.key_frames); EXPECT_EQ(1, callback.frame_counts_.delta_frames); rtp_sender_.reset(); } TEST_F(RtpSenderTest, BitrateCallbacks) { class TestCallback : public BitrateStatisticsObserver { public: TestCallback() : BitrateStatisticsObserver(), num_calls_(0), ssrc_(0) {} virtual ~TestCallback() {} void Notify(const BitrateStatistics& total_stats, const BitrateStatistics& retransmit_stats, uint32_t ssrc) override { ++num_calls_; ssrc_ = ssrc; total_stats_ = total_stats; retransmit_stats_ = retransmit_stats; } uint32_t num_calls_; uint32_t ssrc_; BitrateStatistics total_stats_; BitrateStatistics retransmit_stats_; } callback; rtp_sender_.reset(new RTPSender(false, &fake_clock_, &transport_, nullptr, nullptr, nullptr, nullptr, &callback, nullptr, nullptr)); // Simulate kNumPackets sent with kPacketInterval ms intervals. const uint32_t kNumPackets = 15; const uint32_t kPacketInterval = 20; // Overhead = 12 bytes RTP header + 1 byte generic header. const uint32_t kPacketOverhead = 13; char payload_name[RTP_PAYLOAD_NAME_SIZE] = "GENERIC"; const uint8_t payload_type = 127; ASSERT_EQ( 0, rtp_sender_->RegisterPayload(payload_name, payload_type, 90000, 0, 1500)); uint8_t payload[] = {47, 11, 32, 93, 89}; rtp_sender_->SetStorePacketsStatus(true, 1); uint32_t ssrc = rtp_sender_->SSRC(); // Initial process call so we get a new time window. rtp_sender_->ProcessBitrate(); uint64_t start_time = fake_clock_.CurrentNtpInMilliseconds(); // Send a few frames. for (uint32_t i = 0; i < kNumPackets; ++i) { ASSERT_EQ(0, rtp_sender_->SendOutgoingData(kVideoFrameKey, payload_type, 1234, 4321, payload, sizeof(payload), 0)); fake_clock_.AdvanceTimeMilliseconds(kPacketInterval); } rtp_sender_->ProcessBitrate(); const uint32_t expected_packet_rate = 1000 / kPacketInterval; // We get one call for every stats updated, thus two calls since both the // stream stats and the retransmit stats are updated once. EXPECT_EQ(2u, callback.num_calls_); EXPECT_EQ(ssrc, callback.ssrc_); EXPECT_EQ(start_time + (kNumPackets * kPacketInterval), callback.total_stats_.timestamp_ms); EXPECT_EQ(expected_packet_rate, callback.total_stats_.packet_rate); EXPECT_EQ((kPacketOverhead + sizeof(payload)) * 8 * expected_packet_rate, callback.total_stats_.bitrate_bps); rtp_sender_.reset(); } class RtpSenderAudioTest : public RtpSenderTest { protected: RtpSenderAudioTest() {} void SetUp() override { payload_ = kAudioPayload; rtp_sender_.reset(new RTPSender(true, &fake_clock_, &transport_, nullptr, nullptr, nullptr, nullptr, nullptr, nullptr, nullptr)); rtp_sender_->SetSequenceNumber(kSeqNum); } }; TEST_F(RtpSenderTestWithoutPacer, StreamDataCountersCallbacks) { class TestCallback : public StreamDataCountersCallback { public: TestCallback() : StreamDataCountersCallback(), ssrc_(0), counters_() {} virtual ~TestCallback() {} void DataCountersUpdated(const StreamDataCounters& counters, uint32_t ssrc) override { ssrc_ = ssrc; counters_ = counters; } uint32_t ssrc_; StreamDataCounters counters_; void MatchPacketCounter(const RtpPacketCounter& expected, const RtpPacketCounter& actual) { EXPECT_EQ(expected.payload_bytes, actual.payload_bytes); EXPECT_EQ(expected.header_bytes, actual.header_bytes); EXPECT_EQ(expected.padding_bytes, actual.padding_bytes); EXPECT_EQ(expected.packets, actual.packets); } void Matches(uint32_t ssrc, const StreamDataCounters& counters) { EXPECT_EQ(ssrc, ssrc_); MatchPacketCounter(counters.transmitted, counters_.transmitted); MatchPacketCounter(counters.retransmitted, counters_.retransmitted); EXPECT_EQ(counters.fec.packets, counters_.fec.packets); } } callback; const uint8_t kRedPayloadType = 96; const uint8_t kUlpfecPayloadType = 97; char payload_name[RTP_PAYLOAD_NAME_SIZE] = "GENERIC"; const uint8_t payload_type = 127; ASSERT_EQ(0, rtp_sender_->RegisterPayload(payload_name, payload_type, 90000, 0, 1500)); uint8_t payload[] = {47, 11, 32, 93, 89}; rtp_sender_->SetStorePacketsStatus(true, 1); uint32_t ssrc = rtp_sender_->SSRC(); rtp_sender_->RegisterRtpStatisticsCallback(&callback); // Send a frame. ASSERT_EQ( 0, rtp_sender_->SendOutgoingData(kVideoFrameKey, payload_type, 1234, 4321, payload, sizeof(payload), nullptr)); StreamDataCounters expected; expected.transmitted.payload_bytes = 6; expected.transmitted.header_bytes = 12; expected.transmitted.padding_bytes = 0; expected.transmitted.packets = 1; expected.retransmitted.payload_bytes = 0; expected.retransmitted.header_bytes = 0; expected.retransmitted.padding_bytes = 0; expected.retransmitted.packets = 0; expected.fec.packets = 0; callback.Matches(ssrc, expected); // Retransmit a frame. uint16_t seqno = rtp_sender_->SequenceNumber() - 1; rtp_sender_->ReSendPacket(seqno, 0); expected.transmitted.payload_bytes = 12; expected.transmitted.header_bytes = 24; expected.transmitted.packets = 2; expected.retransmitted.payload_bytes = 6; expected.retransmitted.header_bytes = 12; expected.retransmitted.padding_bytes = 0; expected.retransmitted.packets = 1; callback.Matches(ssrc, expected); // Send padding. rtp_sender_->TimeToSendPadding(kMaxPaddingSize); expected.transmitted.payload_bytes = 12; expected.transmitted.header_bytes = 36; expected.transmitted.padding_bytes = kMaxPaddingSize; expected.transmitted.packets = 3; callback.Matches(ssrc, expected); // Send FEC. rtp_sender_->SetGenericFECStatus(true, kRedPayloadType, kUlpfecPayloadType); FecProtectionParams fec_params; fec_params.fec_mask_type = kFecMaskRandom; fec_params.fec_rate = 1; fec_params.max_fec_frames = 1; fec_params.use_uep_protection = false; rtp_sender_->SetFecParameters(&fec_params, &fec_params); ASSERT_EQ(0, rtp_sender_->SendOutgoingData(kVideoFrameDelta, payload_type, 1234, 4321, payload, sizeof(payload), nullptr)); expected.transmitted.payload_bytes = 40; expected.transmitted.header_bytes = 60; expected.transmitted.packets = 5; expected.fec.packets = 1; callback.Matches(ssrc, expected); rtp_sender_->RegisterRtpStatisticsCallback(nullptr); } TEST_F(RtpSenderAudioTest, SendAudio) { char payload_name[RTP_PAYLOAD_NAME_SIZE] = "PAYLOAD_NAME"; const uint8_t payload_type = 127; ASSERT_EQ(0, rtp_sender_->RegisterPayload(payload_name, payload_type, 48000, 0, 1500)); uint8_t payload[] = {47, 11, 32, 93, 89}; ASSERT_EQ( 0, rtp_sender_->SendOutgoingData(kAudioFrameCN, payload_type, 1234, 4321, payload, sizeof(payload), nullptr)); RtpUtility::RtpHeaderParser rtp_parser(transport_.last_sent_packet_, transport_.last_sent_packet_len_); webrtc::RTPHeader rtp_header; ASSERT_TRUE(rtp_parser.Parse(rtp_header)); const uint8_t* payload_data = GetPayloadData(rtp_header, transport_.last_sent_packet_); ASSERT_EQ(sizeof(payload), GetPayloadDataLength(rtp_header, transport_.last_sent_packet_len_)); EXPECT_EQ(0, memcmp(payload, payload_data, sizeof(payload))); } TEST_F(RtpSenderAudioTest, SendAudioWithAudioLevelExtension) { EXPECT_EQ(0, rtp_sender_->SetAudioLevel(kAudioLevel)); EXPECT_EQ(0, rtp_sender_->RegisterRtpHeaderExtension( kRtpExtensionAudioLevel, kAudioLevelExtensionId)); char payload_name[RTP_PAYLOAD_NAME_SIZE] = "PAYLOAD_NAME"; const uint8_t payload_type = 127; ASSERT_EQ(0, rtp_sender_->RegisterPayload(payload_name, payload_type, 48000, 0, 1500)); uint8_t payload[] = {47, 11, 32, 93, 89}; ASSERT_EQ( 0, rtp_sender_->SendOutgoingData(kAudioFrameCN, payload_type, 1234, 4321, payload, sizeof(payload), nullptr)); RtpUtility::RtpHeaderParser rtp_parser(transport_.last_sent_packet_, transport_.last_sent_packet_len_); webrtc::RTPHeader rtp_header; ASSERT_TRUE(rtp_parser.Parse(rtp_header)); const uint8_t* payload_data = GetPayloadData(rtp_header, transport_.last_sent_packet_); ASSERT_EQ(sizeof(payload), GetPayloadDataLength(rtp_header, transport_.last_sent_packet_len_)); EXPECT_EQ(0, memcmp(payload, payload_data, sizeof(payload))); uint8_t extension[] = { 0xbe, 0xde, 0x00, 0x01, (kAudioLevelExtensionId << 4) + 0, // ID + length. kAudioLevel, // Data. 0x00, 0x00 // Padding. }; EXPECT_EQ(0, memcmp(extension, payload_data - sizeof(extension), sizeof(extension))); } // As RFC4733, named telephone events are carried as part of the audio stream // and must use the same sequence number and timestamp base as the regular // audio channel. // This test checks the marker bit for the first packet and the consequent // packets of the same telephone event. Since it is specifically for DTMF // events, ignoring audio packets and sending kEmptyFrame instead of those. TEST_F(RtpSenderAudioTest, CheckMarkerBitForTelephoneEvents) { char payload_name[RTP_PAYLOAD_NAME_SIZE] = "telephone-event"; uint8_t payload_type = 126; ASSERT_EQ(0, rtp_sender_->RegisterPayload(payload_name, payload_type, 0, 0, 0)); // For Telephone events, payload is not added to the registered payload list, // it will register only the payload used for audio stream. // Registering the payload again for audio stream with different payload name. strcpy(payload_name, "payload_name"); ASSERT_EQ(0, rtp_sender_->RegisterPayload(payload_name, payload_type, 8000, 1, 0)); int64_t capture_time_ms = fake_clock_.TimeInMilliseconds(); // DTMF event key=9, duration=500 and attenuationdB=10 rtp_sender_->SendTelephoneEvent(9, 500, 10); // During start, it takes the starting timestamp as last sent timestamp. // The duration is calculated as the difference of current and last sent // timestamp. So for first call it will skip since the duration is zero. ASSERT_EQ(0, rtp_sender_->SendOutgoingData(kEmptyFrame, payload_type, capture_time_ms, 0, nullptr, 0, nullptr)); // DTMF Sample Length is (Frequency/1000) * Duration. // So in this case, it is (8000/1000) * 500 = 4000. // Sending it as two packets. ASSERT_EQ(0, rtp_sender_->SendOutgoingData(kEmptyFrame, payload_type, capture_time_ms + 2000, 0, nullptr, 0, nullptr)); rtc::scoped_ptr rtp_parser( webrtc::RtpHeaderParser::Create()); ASSERT_TRUE(rtp_parser.get() != nullptr); webrtc::RTPHeader rtp_header; ASSERT_TRUE(rtp_parser->Parse(transport_.last_sent_packet_, transport_.last_sent_packet_len_, &rtp_header)); // Marker Bit should be set to 1 for first packet. EXPECT_TRUE(rtp_header.markerBit); ASSERT_EQ(0, rtp_sender_->SendOutgoingData(kEmptyFrame, payload_type, capture_time_ms + 4000, 0, nullptr, 0, nullptr)); ASSERT_TRUE(rtp_parser->Parse(transport_.last_sent_packet_, transport_.last_sent_packet_len_, &rtp_header)); // Marker Bit should be set to 0 for rest of the packets. EXPECT_FALSE(rtp_header.markerBit); } TEST_F(RtpSenderTestWithoutPacer, BytesReportedCorrectly) { const char* kPayloadName = "GENERIC"; const uint8_t kPayloadType = 127; rtp_sender_->SetSSRC(1234); rtp_sender_->SetRtxSsrc(4321); rtp_sender_->SetRtxPayloadType(kPayloadType - 1, kPayloadType); rtp_sender_->SetRtxStatus(kRtxRetransmitted | kRtxRedundantPayloads); ASSERT_EQ( 0, rtp_sender_->RegisterPayload(kPayloadName, kPayloadType, 90000, 0, 1500)); uint8_t payload[] = {47, 11, 32, 93, 89}; ASSERT_EQ(0, rtp_sender_->SendOutgoingData(kVideoFrameKey, kPayloadType, 1234, 4321, payload, sizeof(payload), 0)); // Will send 2 full-size padding packets. rtp_sender_->TimeToSendPadding(1); rtp_sender_->TimeToSendPadding(1); StreamDataCounters rtp_stats; StreamDataCounters rtx_stats; rtp_sender_->GetDataCounters(&rtp_stats, &rtx_stats); // Payload + 1-byte generic header. EXPECT_GT(rtp_stats.first_packet_time_ms, -1); EXPECT_EQ(rtp_stats.transmitted.payload_bytes, sizeof(payload) + 1); EXPECT_EQ(rtp_stats.transmitted.header_bytes, 12u); EXPECT_EQ(rtp_stats.transmitted.padding_bytes, 0u); EXPECT_EQ(rtx_stats.transmitted.payload_bytes, 0u); EXPECT_EQ(rtx_stats.transmitted.header_bytes, 24u); EXPECT_EQ(rtx_stats.transmitted.padding_bytes, 2 * kMaxPaddingSize); EXPECT_EQ(rtp_stats.transmitted.TotalBytes(), rtp_stats.transmitted.payload_bytes + rtp_stats.transmitted.header_bytes + rtp_stats.transmitted.padding_bytes); EXPECT_EQ(rtx_stats.transmitted.TotalBytes(), rtx_stats.transmitted.payload_bytes + rtx_stats.transmitted.header_bytes + rtx_stats.transmitted.padding_bytes); EXPECT_EQ(transport_.total_bytes_sent_, rtp_stats.transmitted.TotalBytes() + rtx_stats.transmitted.TotalBytes()); } TEST_F(RtpSenderTestWithoutPacer, RespectsNackBitrateLimit) { const int32_t kPacketSize = 1400; const int32_t kNumPackets = 30; rtp_sender_->SetStorePacketsStatus(true, kNumPackets); // Set bitrate (in kbps) to fit kNumPackets รก kPacketSize bytes in one second. rtp_sender_->SetTargetBitrate(kNumPackets * kPacketSize * 8); const uint16_t kStartSequenceNumber = rtp_sender_->SequenceNumber(); std::list sequence_numbers; for (int32_t i = 0; i < kNumPackets; ++i) { sequence_numbers.push_back(kStartSequenceNumber + i); fake_clock_.AdvanceTimeMilliseconds(1); SendPacket(fake_clock_.TimeInMilliseconds(), kPacketSize); } EXPECT_EQ(kNumPackets, transport_.packets_sent_); fake_clock_.AdvanceTimeMilliseconds(1000 - kNumPackets); // Resending should work - brings the bandwidth up to the limit. // NACK bitrate is capped to the same bitrate as the encoder, since the max // protection overhead is 50% (see MediaOptimization::SetTargetRates). rtp_sender_->OnReceivedNACK(sequence_numbers, 0); EXPECT_EQ(kNumPackets * 2, transport_.packets_sent_); // Resending should not work, bandwidth exceeded. rtp_sender_->OnReceivedNACK(sequence_numbers, 0); EXPECT_EQ(kNumPackets * 2, transport_.packets_sent_); } // Verify that all packets of a frame have CVO byte set. TEST_F(RtpSenderVideoTest, SendVideoWithCVO) { RTPVideoHeader hdr = {0}; hdr.rotation = kVideoRotation_90; EXPECT_EQ(0, rtp_sender_->RegisterRtpHeaderExtension( kRtpExtensionVideoRotation, kVideoRotationExtensionId)); EXPECT_TRUE(rtp_sender_->ActivateCVORtpHeaderExtension()); EXPECT_EQ( RtpUtility::Word32Align(kRtpOneByteHeaderLength + kVideoRotationLength), rtp_sender_->RtpHeaderExtensionTotalLength()); rtp_sender_video_->SendVideo(kRtpVideoGeneric, kVideoFrameKey, kPayload, kTimestamp, 0, packet_, sizeof(packet_), nullptr, &hdr); RtpHeaderExtensionMap map; map.Register(kRtpExtensionVideoRotation, kVideoRotationExtensionId); // Verify that this packet does have CVO byte. VerifyCVOPacket( reinterpret_cast(transport_.sent_packets_[0]->data()), transport_.sent_packets_[0]->size(), true, &map, kSeqNum, hdr.rotation); // Verify that this packet does have CVO byte. VerifyCVOPacket( reinterpret_cast(transport_.sent_packets_[1]->data()), transport_.sent_packets_[1]->size(), true, &map, kSeqNum + 1, hdr.rotation); } } // namespace webrtc