/* * Copyright 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 "api/audio_codecs/builtin_audio_decoder_factory.h" #include "api/audio_codecs/builtin_audio_encoder_factory.h" #include "api/jsep.h" #include "api/mediastreaminterface.h" #include "api/peerconnectioninterface.h" #include "api/umametrics.h" #include "api/video_codecs/builtin_video_decoder_factory.h" #include "api/video_codecs/builtin_video_encoder_factory.h" #include "pc/mediasession.h" #include "pc/mediastream.h" #include "pc/mediastreamtrack.h" #include "pc/peerconnectionwrapper.h" #include "pc/sdputils.h" #include "pc/test/fakeaudiocapturemodule.h" #include "pc/test/mockpeerconnectionobservers.h" #include "rtc_base/checks.h" #include "rtc_base/gunit.h" #include "rtc_base/ptr_util.h" #include "rtc_base/refcountedobject.h" #include "rtc_base/scoped_ref_ptr.h" #include "rtc_base/thread.h" #include "test/gmock.h" // This file contains tests for RTP Media API-related behavior of // |webrtc::PeerConnection|, see https://w3c.github.io/webrtc-pc/#rtp-media-api. namespace webrtc { using RTCConfiguration = PeerConnectionInterface::RTCConfiguration; using ::testing::ElementsAre; using ::testing::UnorderedElementsAre; using ::testing::Values; const uint32_t kDefaultTimeout = 10000u; template class OnSuccessObserver : public rtc::RefCountedObject< webrtc::SetRemoteDescriptionObserverInterface> { public: explicit OnSuccessObserver(MethodFunctor on_success) : on_success_(std::move(on_success)) {} // webrtc::SetRemoteDescriptionObserverInterface implementation. void OnSetRemoteDescriptionComplete(webrtc::RTCError error) override { RTC_CHECK(error.ok()); on_success_(); } private: MethodFunctor on_success_; }; class PeerConnectionRtpBaseTest : public testing::Test { public: explicit PeerConnectionRtpBaseTest(SdpSemantics sdp_semantics) : sdp_semantics_(sdp_semantics), pc_factory_( CreatePeerConnectionFactory(rtc::Thread::Current(), rtc::Thread::Current(), rtc::Thread::Current(), FakeAudioCaptureModule::Create(), CreateBuiltinAudioEncoderFactory(), CreateBuiltinAudioDecoderFactory(), CreateBuiltinVideoEncoderFactory(), CreateBuiltinVideoDecoderFactory(), nullptr /* audio_mixer */, nullptr /* audio_processing */)) {} std::unique_ptr CreatePeerConnection() { return CreatePeerConnection(RTCConfiguration()); } std::unique_ptr CreatePeerConnectionWithPlanB() { RTCConfiguration config; config.sdp_semantics = SdpSemantics::kPlanB; return CreatePeerConnectionInternal(config); } std::unique_ptr CreatePeerConnectionWithUnifiedPlan() { RTCConfiguration config; config.sdp_semantics = SdpSemantics::kUnifiedPlan; return CreatePeerConnectionInternal(config); } std::unique_ptr CreatePeerConnection( const RTCConfiguration& config) { RTCConfiguration modified_config = config; modified_config.sdp_semantics = sdp_semantics_; return CreatePeerConnectionInternal(modified_config); } protected: const SdpSemantics sdp_semantics_; rtc::scoped_refptr pc_factory_; private: // Private so that tests don't accidentally bypass the SdpSemantics // adjustment. std::unique_ptr CreatePeerConnectionInternal( const RTCConfiguration& config) { auto observer = rtc::MakeUnique(); auto pc = pc_factory_->CreatePeerConnection(config, nullptr, nullptr, observer.get()); return rtc::MakeUnique(pc_factory_, pc, std::move(observer)); } }; class PeerConnectionRtpTest : public PeerConnectionRtpBaseTest, public ::testing::WithParamInterface { protected: PeerConnectionRtpTest() : PeerConnectionRtpBaseTest(GetParam()) {} }; class PeerConnectionRtpTestPlanB : public PeerConnectionRtpBaseTest { protected: PeerConnectionRtpTestPlanB() : PeerConnectionRtpBaseTest(SdpSemantics::kPlanB) {} }; class PeerConnectionRtpTestUnifiedPlan : public PeerConnectionRtpBaseTest { protected: PeerConnectionRtpTestUnifiedPlan() : PeerConnectionRtpBaseTest(SdpSemantics::kUnifiedPlan) {} }; // These tests cover |webrtc::PeerConnectionObserver| callbacks firing upon // setting the remote description. TEST_P(PeerConnectionRtpTest, AddTrackWithoutStreamFiresOnAddTrack) { auto caller = CreatePeerConnection(); auto callee = CreatePeerConnection(); ASSERT_TRUE(caller->AddAudioTrack("audio_track")); ASSERT_TRUE(callee->SetRemoteDescription(caller->CreateOfferAndSetAsLocal())); ASSERT_EQ(callee->observer()->add_track_events_.size(), 1u); const auto& add_track_event = callee->observer()->add_track_events_[0]; EXPECT_EQ(add_track_event.streams, add_track_event.receiver->streams()); if (sdp_semantics_ == SdpSemantics::kPlanB) { // Since we are not supporting the no stream case with Plan B, there should // be a generated stream, even though we didn't set one with AddTrack. ASSERT_EQ(1u, add_track_event.streams.size()); EXPECT_TRUE(add_track_event.streams[0]->FindAudioTrack("audio_track")); } else { EXPECT_EQ(0u, add_track_event.streams.size()); } } TEST_P(PeerConnectionRtpTest, AddTrackWithStreamFiresOnAddTrack) { auto caller = CreatePeerConnection(); auto callee = CreatePeerConnection(); ASSERT_TRUE(caller->AddAudioTrack("audio_track", {"audio_stream"})); ASSERT_TRUE(callee->SetRemoteDescription(caller->CreateOfferAndSetAsLocal())); ASSERT_EQ(callee->observer()->add_track_events_.size(), 1u); auto& add_track_event = callee->observer()->add_track_events_[0]; ASSERT_EQ(add_track_event.streams.size(), 1u); EXPECT_EQ("audio_stream", add_track_event.streams[0]->id()); EXPECT_TRUE(add_track_event.streams[0]->FindAudioTrack("audio_track")); EXPECT_EQ(add_track_event.streams, add_track_event.receiver->streams()); } TEST_P(PeerConnectionRtpTest, RemoveTrackWithoutStreamFiresOnRemoveTrack) { auto caller = CreatePeerConnection(); auto callee = CreatePeerConnection(); auto sender = caller->AddAudioTrack("audio_track", {}); ASSERT_TRUE(callee->SetRemoteDescription(caller->CreateOfferAndSetAsLocal())); ASSERT_EQ(callee->observer()->add_track_events_.size(), 1u); ASSERT_TRUE( caller->SetRemoteDescription(callee->CreateAnswerAndSetAsLocal())); EXPECT_TRUE(caller->pc()->RemoveTrack(sender)); ASSERT_TRUE(callee->SetRemoteDescription(caller->CreateOfferAndSetAsLocal())); ASSERT_EQ(callee->observer()->add_track_events_.size(), 1u); EXPECT_EQ(callee->observer()->GetAddTrackReceivers(), callee->observer()->remove_track_events_); } TEST_P(PeerConnectionRtpTest, RemoveTrackWithStreamFiresOnRemoveTrack) { auto caller = CreatePeerConnection(); auto callee = CreatePeerConnection(); auto sender = caller->AddAudioTrack("audio_track", {"audio_stream"}); ASSERT_TRUE(callee->SetRemoteDescription(caller->CreateOfferAndSetAsLocal())); ASSERT_EQ(callee->observer()->add_track_events_.size(), 1u); ASSERT_TRUE( caller->SetRemoteDescription(callee->CreateAnswerAndSetAsLocal())); EXPECT_TRUE(caller->pc()->RemoveTrack(sender)); ASSERT_TRUE(callee->SetRemoteDescription(caller->CreateOfferAndSetAsLocal())); ASSERT_EQ(callee->observer()->add_track_events_.size(), 1u); EXPECT_EQ(callee->observer()->GetAddTrackReceivers(), callee->observer()->remove_track_events_); EXPECT_EQ(0u, callee->observer()->remote_streams()->count()); } TEST_P(PeerConnectionRtpTest, RemoveTrackWithSharedStreamFiresOnRemoveTrack) { auto caller = CreatePeerConnection(); auto callee = CreatePeerConnection(); const char kSharedStreamId[] = "shared_audio_stream"; auto sender1 = caller->AddAudioTrack("audio_track1", {kSharedStreamId}); auto sender2 = caller->AddAudioTrack("audio_track2", {kSharedStreamId}); ASSERT_TRUE(callee->SetRemoteDescription(caller->CreateOfferAndSetAsLocal())); ASSERT_EQ(callee->observer()->add_track_events_.size(), 2u); ASSERT_TRUE( caller->SetRemoteDescription(callee->CreateAnswerAndSetAsLocal())); // Remove "audio_track1". EXPECT_TRUE(caller->pc()->RemoveTrack(sender1)); ASSERT_TRUE(callee->SetRemoteDescription(caller->CreateOfferAndSetAsLocal())); ASSERT_EQ(callee->observer()->add_track_events_.size(), 2u); EXPECT_EQ( std::vector>{ callee->observer()->add_track_events_[0].receiver}, callee->observer()->remove_track_events_); ASSERT_EQ(1u, callee->observer()->remote_streams()->count()); ASSERT_TRUE( caller->SetRemoteDescription(callee->CreateAnswerAndSetAsLocal())); // Remove "audio_track2". EXPECT_TRUE(caller->pc()->RemoveTrack(sender2)); ASSERT_TRUE(callee->SetRemoteDescription(caller->CreateOfferAndSetAsLocal())); ASSERT_EQ(callee->observer()->add_track_events_.size(), 2u); EXPECT_EQ(callee->observer()->GetAddTrackReceivers(), callee->observer()->remove_track_events_); EXPECT_EQ(0u, callee->observer()->remote_streams()->count()); } // Tests the edge case that if a stream ID changes for a given track that both // OnRemoveTrack and OnAddTrack is fired. TEST_F(PeerConnectionRtpTestPlanB, RemoteStreamIdChangesFiresOnRemoveAndOnAddTrack) { auto caller = CreatePeerConnection(); auto callee = CreatePeerConnection(); const char kStreamId1[] = "stream1"; const char kStreamId2[] = "stream2"; caller->AddAudioTrack("audio_track1", {kStreamId1}); ASSERT_TRUE(callee->SetRemoteDescription(caller->CreateOfferAndSetAsLocal())); EXPECT_EQ(callee->observer()->add_track_events_.size(), 1u); // Change the stream ID of the sender in the session description. auto offer = caller->CreateOfferAndSetAsLocal(); auto* audio_desc = cricket::GetFirstAudioContentDescription(offer->description()); ASSERT_EQ(audio_desc->mutable_streams().size(), 1u); audio_desc->mutable_streams()[0].set_stream_ids({kStreamId2}); ASSERT_TRUE(callee->SetRemoteDescription(std::move(offer))); ASSERT_EQ(callee->observer()->add_track_events_.size(), 2u); EXPECT_EQ(callee->observer()->add_track_events_[1].streams[0]->id(), kStreamId2); ASSERT_EQ(callee->observer()->remove_track_events_.size(), 1u); EXPECT_EQ(callee->observer()->remove_track_events_[0]->streams()[0]->id(), kStreamId1); } // Tests that setting a remote description with sending transceivers will fire // the OnTrack callback for each transceiver and setting a remote description // with receive only transceivers will not call OnTrack. One transceiver is // created without any stream_ids, while the other is created with multiple // stream_ids. TEST_F(PeerConnectionRtpTestUnifiedPlan, AddTransceiverCallsOnTrack) { const std::string kStreamId1 = "video_stream1"; const std::string kStreamId2 = "video_stream2"; auto caller = CreatePeerConnection(); auto callee = CreatePeerConnection(); auto audio_transceiver = caller->AddTransceiver(cricket::MEDIA_TYPE_AUDIO); RtpTransceiverInit video_transceiver_init; video_transceiver_init.stream_ids = {kStreamId1, kStreamId2}; auto video_transceiver = caller->AddTransceiver(cricket::MEDIA_TYPE_VIDEO, video_transceiver_init); ASSERT_TRUE(caller->ExchangeOfferAnswerWith(callee.get())); ASSERT_EQ(0u, caller->observer()->on_track_transceivers_.size()); ASSERT_EQ(2u, callee->observer()->on_track_transceivers_.size()); EXPECT_EQ(audio_transceiver->mid(), callee->pc()->GetTransceivers()[0]->mid()); EXPECT_EQ(video_transceiver->mid(), callee->pc()->GetTransceivers()[1]->mid()); std::vector> audio_streams = callee->pc()->GetTransceivers()[0]->receiver()->streams(); std::vector> video_streams = callee->pc()->GetTransceivers()[1]->receiver()->streams(); ASSERT_EQ(0u, audio_streams.size()); ASSERT_EQ(2u, video_streams.size()); EXPECT_EQ(kStreamId1, video_streams[0]->id()); EXPECT_EQ(kStreamId2, video_streams[1]->id()); } // Test that doing additional offer/answer exchanges with no changes to tracks // will cause no additional OnTrack calls after the tracks have been negotiated. TEST_F(PeerConnectionRtpTestUnifiedPlan, ReofferDoesNotCallOnTrack) { auto caller = CreatePeerConnection(); auto callee = CreatePeerConnection(); caller->AddAudioTrack("audio"); callee->AddAudioTrack("audio"); ASSERT_TRUE(caller->ExchangeOfferAnswerWith(callee.get())); EXPECT_EQ(1u, caller->observer()->on_track_transceivers_.size()); EXPECT_EQ(1u, callee->observer()->on_track_transceivers_.size()); // If caller reoffers with no changes expect no additional OnTrack calls. ASSERT_TRUE(caller->ExchangeOfferAnswerWith(callee.get())); EXPECT_EQ(1u, caller->observer()->on_track_transceivers_.size()); EXPECT_EQ(1u, callee->observer()->on_track_transceivers_.size()); // Also if callee reoffers with no changes expect no additional OnTrack calls. ASSERT_TRUE(callee->ExchangeOfferAnswerWith(caller.get())); EXPECT_EQ(1u, caller->observer()->on_track_transceivers_.size()); EXPECT_EQ(1u, callee->observer()->on_track_transceivers_.size()); } // Test that OnTrack is called when the transceiver direction changes to send // the track. TEST_F(PeerConnectionRtpTestUnifiedPlan, SetDirectionCallsOnTrack) { auto caller = CreatePeerConnection(); auto callee = CreatePeerConnection(); auto transceiver = caller->AddTransceiver(cricket::MEDIA_TYPE_AUDIO); transceiver->SetDirection(RtpTransceiverDirection::kInactive); ASSERT_TRUE(caller->ExchangeOfferAnswerWith(callee.get())); EXPECT_EQ(0u, caller->observer()->on_track_transceivers_.size()); EXPECT_EQ(0u, callee->observer()->on_track_transceivers_.size()); transceiver->SetDirection(RtpTransceiverDirection::kSendOnly); ASSERT_TRUE(caller->ExchangeOfferAnswerWith(callee.get())); EXPECT_EQ(0u, caller->observer()->on_track_transceivers_.size()); EXPECT_EQ(1u, callee->observer()->on_track_transceivers_.size()); // If the direction changes but it is still receiving on the remote side, then // OnTrack should not be fired again. transceiver->SetDirection(RtpTransceiverDirection::kSendRecv); ASSERT_TRUE(caller->ExchangeOfferAnswerWith(callee.get())); EXPECT_EQ(0u, caller->observer()->on_track_transceivers_.size()); EXPECT_EQ(1u, callee->observer()->on_track_transceivers_.size()); } // Test that OnTrack is called twice when a sendrecv call is started, the callee // changes the direction to inactive, then changes it back to sendrecv. TEST_F(PeerConnectionRtpTestUnifiedPlan, SetDirectionHoldCallsOnTrackTwice) { auto caller = CreatePeerConnection(); auto callee = CreatePeerConnection(); auto transceiver = caller->AddTransceiver(cricket::MEDIA_TYPE_AUDIO); ASSERT_TRUE(caller->ExchangeOfferAnswerWith(callee.get())); EXPECT_EQ(0u, caller->observer()->on_track_transceivers_.size()); EXPECT_EQ(1u, callee->observer()->on_track_transceivers_.size()); // Put the call on hold by no longer receiving the track. callee->pc()->GetTransceivers()[0]->SetDirection( RtpTransceiverDirection::kInactive); ASSERT_TRUE(callee->ExchangeOfferAnswerWith(caller.get())); EXPECT_EQ(0u, caller->observer()->on_track_transceivers_.size()); EXPECT_EQ(1u, callee->observer()->on_track_transceivers_.size()); // Resume the call by changing the direction to recvonly. This should call // OnTrack again on the callee side. callee->pc()->GetTransceivers()[0]->SetDirection( RtpTransceiverDirection::kRecvOnly); ASSERT_TRUE(callee->ExchangeOfferAnswerWith(caller.get())); EXPECT_EQ(0u, caller->observer()->on_track_transceivers_.size()); EXPECT_EQ(2u, callee->observer()->on_track_transceivers_.size()); } // Test that setting a remote offer twice with no answer in the middle results // in OnAddTrack being fired twice, once for each SetRemoteDescription. This // happens since the RtpTransceiver's current_direction is only updated when // setting the answer. // TODO(bugs.webrtc.org/9236): This is spec-compliant but strange behavior. TEST_F(PeerConnectionRtpTestUnifiedPlan, ApplyTwoOffersWithNoAnswerResultsInTwoAddTrackEvents) { auto caller = CreatePeerConnection(); auto callee = CreatePeerConnection(); caller->AddAudioTrack("audio_track", {}); ASSERT_TRUE(callee->SetRemoteDescription(caller->CreateOffer())); ASSERT_EQ(1u, callee->observer()->add_track_events_.size()); ASSERT_TRUE(callee->SetRemoteDescription(caller->CreateOffer())); EXPECT_EQ(2u, callee->observer()->add_track_events_.size()); } // Test that setting a remote offer twice with no answer in the middle and the // track being removed between the two offers results in OnAddTrack being called // once the first time and OnRemoveTrack never getting called. This happens // since the RtpTransceiver's current_direction is only updated when setting the // answer. // TODO(bugs.webrtc.org/9236): This is spec-compliant but strange behavior. TEST_F(PeerConnectionRtpTestUnifiedPlan, ApplyTwoOffersWithNoAnswerAndTrackRemovedResultsInNoRemoveTrackEvents) { auto caller = CreatePeerConnection(); auto callee = CreatePeerConnection(); auto sender = caller->AddAudioTrack("audio_track", {}); ASSERT_TRUE(callee->SetRemoteDescription(caller->CreateOffer())); ASSERT_EQ(1u, callee->observer()->add_track_events_.size()); caller->pc()->RemoveTrack(sender); ASSERT_TRUE(callee->SetRemoteDescription(caller->CreateOffer())); EXPECT_EQ(1u, callee->observer()->add_track_events_.size()); EXPECT_EQ(0u, callee->observer()->remove_track_events_.size()); } // These tests examine the state of the peer connection as a result of // performing SetRemoteDescription(). TEST_P(PeerConnectionRtpTest, AddTrackWithoutStreamAddsReceiver) { auto caller = CreatePeerConnection(); auto callee = CreatePeerConnection(); ASSERT_TRUE(caller->AddAudioTrack("audio_track", {})); ASSERT_TRUE(callee->SetRemoteDescription(caller->CreateOfferAndSetAsLocal())); EXPECT_EQ(callee->pc()->GetReceivers().size(), 1u); auto receiver_added = callee->pc()->GetReceivers()[0]; EXPECT_EQ("audio_track", receiver_added->track()->id()); if (sdp_semantics_ == SdpSemantics::kPlanB) { // Since we are not supporting the no stream case with Plan B, there should // be a generated stream, even though we didn't set one with AddTrack. ASSERT_EQ(1u, receiver_added->streams().size()); EXPECT_TRUE(receiver_added->streams()[0]->FindAudioTrack("audio_track")); } else { EXPECT_EQ(0u, receiver_added->streams().size()); } } TEST_P(PeerConnectionRtpTest, AddTrackWithStreamAddsReceiver) { auto caller = CreatePeerConnection(); auto callee = CreatePeerConnection(); ASSERT_TRUE(caller->AddAudioTrack("audio_track", {"audio_stream"})); ASSERT_TRUE(callee->SetRemoteDescription(caller->CreateOfferAndSetAsLocal())); EXPECT_EQ(callee->pc()->GetReceivers().size(), 1u); auto receiver_added = callee->pc()->GetReceivers()[0]; EXPECT_EQ("audio_track", receiver_added->track()->id()); EXPECT_EQ(receiver_added->streams().size(), 1u); EXPECT_EQ("audio_stream", receiver_added->streams()[0]->id()); EXPECT_TRUE(receiver_added->streams()[0]->FindAudioTrack("audio_track")); } TEST_P(PeerConnectionRtpTest, RemoveTrackWithoutStreamRemovesReceiver) { auto caller = CreatePeerConnection(); auto callee = CreatePeerConnection(); auto sender = caller->AddAudioTrack("audio_track", {}); ASSERT_TRUE(sender); ASSERT_TRUE(caller->ExchangeOfferAnswerWith(callee.get())); ASSERT_EQ(callee->pc()->GetReceivers().size(), 1u); auto receiver = callee->pc()->GetReceivers()[0]; ASSERT_TRUE(caller->pc()->RemoveTrack(sender)); ASSERT_TRUE(caller->ExchangeOfferAnswerWith(callee.get())); if (sdp_semantics_ == SdpSemantics::kUnifiedPlan) { // With Unified Plan the receiver stays but the transceiver transitions to // inactive. ASSERT_EQ(1u, callee->pc()->GetReceivers().size()); EXPECT_EQ(RtpTransceiverDirection::kInactive, callee->pc()->GetTransceivers()[0]->current_direction()); } else { // With Plan B the receiver is removed. ASSERT_EQ(0u, callee->pc()->GetReceivers().size()); } } TEST_P(PeerConnectionRtpTest, RemoveTrackWithStreamRemovesReceiver) { auto caller = CreatePeerConnection(); auto callee = CreatePeerConnection(); auto sender = caller->AddAudioTrack("audio_track", {"audio_stream"}); ASSERT_TRUE(sender); ASSERT_TRUE(caller->ExchangeOfferAnswerWith(callee.get())); ASSERT_EQ(callee->pc()->GetReceivers().size(), 1u); auto receiver = callee->pc()->GetReceivers()[0]; ASSERT_TRUE(caller->pc()->RemoveTrack(sender)); ASSERT_TRUE(caller->ExchangeOfferAnswerWith(callee.get())); if (sdp_semantics_ == SdpSemantics::kUnifiedPlan) { // With Unified Plan the receiver stays but the transceiver transitions to // inactive. EXPECT_EQ(1u, callee->pc()->GetReceivers().size()); EXPECT_EQ(RtpTransceiverDirection::kInactive, callee->pc()->GetTransceivers()[0]->current_direction()); } else { // With Plan B the receiver is removed. EXPECT_EQ(0u, callee->pc()->GetReceivers().size()); } } TEST_P(PeerConnectionRtpTest, RemoveTrackWithSharedStreamRemovesReceiver) { auto caller = CreatePeerConnection(); auto callee = CreatePeerConnection(); const char kSharedStreamId[] = "shared_audio_stream"; auto sender1 = caller->AddAudioTrack("audio_track1", {kSharedStreamId}); auto sender2 = caller->AddAudioTrack("audio_track2", {kSharedStreamId}); ASSERT_TRUE(caller->ExchangeOfferAnswerWith(callee.get())); ASSERT_EQ(2u, callee->pc()->GetReceivers().size()); // Remove "audio_track1". EXPECT_TRUE(caller->pc()->RemoveTrack(sender1)); ASSERT_TRUE(caller->ExchangeOfferAnswerWith(callee.get())); if (sdp_semantics_ == SdpSemantics::kUnifiedPlan) { // With Unified Plan the receiver stays but the transceiver transitions to // inactive. ASSERT_EQ(2u, callee->pc()->GetReceivers().size()); auto transceiver = callee->pc()->GetTransceivers()[0]; EXPECT_EQ("audio_track1", transceiver->receiver()->track()->id()); EXPECT_EQ(RtpTransceiverDirection::kInactive, transceiver->current_direction()); } else { // With Plan B the receiver is removed. ASSERT_EQ(1u, callee->pc()->GetReceivers().size()); EXPECT_EQ("audio_track2", callee->pc()->GetReceivers()[0]->track()->id()); } // Remove "audio_track2". EXPECT_TRUE(caller->pc()->RemoveTrack(sender2)); ASSERT_TRUE(caller->ExchangeOfferAnswerWith(callee.get())); if (sdp_semantics_ == SdpSemantics::kUnifiedPlan) { // With Unified Plan the receiver stays but the transceiver transitions to // inactive. ASSERT_EQ(2u, callee->pc()->GetReceivers().size()); auto transceiver = callee->pc()->GetTransceivers()[1]; EXPECT_EQ("audio_track2", transceiver->receiver()->track()->id()); EXPECT_EQ(RtpTransceiverDirection::kInactive, transceiver->current_direction()); } else { // With Plan B the receiver is removed. ASSERT_EQ(0u, callee->pc()->GetReceivers().size()); } } // Invokes SetRemoteDescription() twice in a row without synchronizing the two // calls and examine the state of the peer connection inside the callbacks to // ensure that the second call does not occur prematurely, contaminating the // state of the peer connection of the first callback. TEST_F(PeerConnectionRtpTestPlanB, StatesCorrelateWithSetRemoteDescriptionCall) { auto caller = CreatePeerConnection(); auto callee = CreatePeerConnection(); // Create SDP for adding a track and for removing it. This will be used in the // first and second SetRemoteDescription() calls. auto sender = caller->AddAudioTrack("audio_track", {}); auto srd1_sdp = caller->CreateOfferAndSetAsLocal(); EXPECT_TRUE(caller->pc()->RemoveTrack(sender)); auto srd2_sdp = caller->CreateOfferAndSetAsLocal(); // In the first SetRemoteDescription() callback, check that we have a // receiver for the track. auto pc = callee->pc(); bool srd1_callback_called = false; auto srd1_callback = [&srd1_callback_called, &pc]() { EXPECT_EQ(pc->GetReceivers().size(), 1u); srd1_callback_called = true; }; // In the second SetRemoteDescription() callback, check that the receiver has // been removed. // TODO(hbos): When we implement Unified Plan, receivers will not be removed. // Instead, the transceiver owning the receiver will become inactive. // https://crbug.com/webrtc/7600 bool srd2_callback_called = false; auto srd2_callback = [&srd2_callback_called, &pc]() { EXPECT_TRUE(pc->GetReceivers().empty()); srd2_callback_called = true; }; // Invoke SetRemoteDescription() twice in a row without synchronizing the two // calls. The callbacks verify that the two calls are synchronized, as in, the // effects of the second SetRemoteDescription() call must not have happened by // the time the first callback is invoked. If it has then the receiver that is // added as a result of the first SetRemoteDescription() call will already // have been removed as a result of the second SetRemoteDescription() call // when the first callback is invoked. callee->pc()->SetRemoteDescription( std::move(srd1_sdp), new OnSuccessObserver(srd1_callback)); callee->pc()->SetRemoteDescription( std::move(srd2_sdp), new OnSuccessObserver(srd2_callback)); EXPECT_TRUE_WAIT(srd1_callback_called, kDefaultTimeout); EXPECT_TRUE_WAIT(srd2_callback_called, kDefaultTimeout); } // Tests that a remote track is created with the signaled MSIDs when they are // communicated with a=msid and no SSRCs are signaled at all (i.e., no a=ssrc // lines). TEST_F(PeerConnectionRtpTestUnifiedPlan, UnsignaledSsrcCreatesReceiverStreams) { auto caller = CreatePeerConnection(); auto callee = CreatePeerConnection(); const char kStreamId1[] = "stream1"; const char kStreamId2[] = "stream2"; caller->AddTrack(caller->CreateAudioTrack("audio_track1"), {kStreamId1, kStreamId2}); auto offer = caller->CreateOfferAndSetAsLocal(); // Munge the offer to take out everything but the stream_ids. auto contents = offer->description()->contents(); ASSERT_TRUE(!contents.empty()); ASSERT_TRUE(!contents[0].media_description()->streams().empty()); std::vector stream_ids = contents[0].media_description()->streams()[0].stream_ids(); contents[0].media_description()->mutable_streams().clear(); cricket::StreamParams new_stream; new_stream.set_stream_ids(stream_ids); contents[0].media_description()->AddStream(new_stream); // Set the remote description and verify that the streams were added to the // receiver correctly. ASSERT_TRUE( callee->SetRemoteDescription(CloneSessionDescription(offer.get()))); auto receivers = callee->pc()->GetReceivers(); ASSERT_EQ(receivers.size(), 1u); ASSERT_EQ(receivers[0]->streams().size(), 2u); EXPECT_EQ(receivers[0]->streams()[0]->id(), kStreamId1); EXPECT_EQ(receivers[0]->streams()[1]->id(), kStreamId2); } // Tests that with Unified Plan if the the stream id changes for a track when // when setting a new remote description, that the media stream is updated // appropriately for the receiver. TEST_F(PeerConnectionRtpTestUnifiedPlan, RemoteStreamIdChangesUpdatesReceiver) { auto caller = CreatePeerConnection(); auto callee = CreatePeerConnection(); const char kStreamId1[] = "stream1"; const char kStreamId2[] = "stream2"; caller->AddTrack(caller->CreateAudioTrack("audio_track1"), {kStreamId1}); ASSERT_TRUE(callee->SetRemoteDescription(caller->CreateOfferAndSetAsLocal())); EXPECT_EQ(callee->observer()->add_track_events_.size(), 1u); // Change the stream id of the sender in the session description. auto offer = caller->CreateOfferAndSetAsLocal(); auto contents = offer->description()->contents(); ASSERT_EQ(contents.size(), 1u); ASSERT_EQ(contents[0].media_description()->mutable_streams().size(), 1u); contents[0].media_description()->mutable_streams()[0].set_stream_ids( {kStreamId2}); // Set the remote description and verify that the stream was updated properly. ASSERT_TRUE( callee->SetRemoteDescription(CloneSessionDescription(offer.get()))); auto receivers = callee->pc()->GetReceivers(); ASSERT_EQ(receivers.size(), 1u); ASSERT_EQ(receivers[0]->streams().size(), 1u); EXPECT_EQ(receivers[0]->streams()[0]->id(), kStreamId2); } // This tests a regression caught by a downstream client, that occured when // applying a remote description with a SessionDescription object that // contained StreamParams that didn't have ids. Although there were multiple // remote audio senders, FindSenderInfo didn't find them as unique, because // it looked up by StreamParam.id, which none had. This meant only one // AudioRtpReceiver was created, as opposed to one for each remote sender. TEST_F(PeerConnectionRtpTestPlanB, MultipleRemoteSendersWithoutStreamParamIdAddsMultipleReceivers) { auto caller = CreatePeerConnection(); auto callee = CreatePeerConnection(); const char kStreamId1[] = "stream1"; const char kStreamId2[] = "stream2"; caller->AddAudioTrack("audio_track1", {kStreamId1}); caller->AddAudioTrack("audio_track2", {kStreamId2}); auto offer = caller->CreateOfferAndSetAsLocal(); auto mutable_streams = cricket::GetFirstAudioContentDescription(offer->description()) ->mutable_streams(); ASSERT_EQ(mutable_streams.size(), 2u); // Clear the IDs in the StreamParams. mutable_streams[0].id.clear(); mutable_streams[1].id.clear(); ASSERT_TRUE( callee->SetRemoteDescription(CloneSessionDescription(offer.get()))); auto receivers = callee->pc()->GetReceivers(); ASSERT_EQ(receivers.size(), 2u); ASSERT_EQ(receivers[0]->streams().size(), 1u); EXPECT_EQ(kStreamId1, receivers[0]->streams()[0]->id()); ASSERT_EQ(receivers[1]->streams().size(), 1u); EXPECT_EQ(kStreamId2, receivers[1]->streams()[0]->id()); } // Tests for the legacy SetRemoteDescription() function signature. // Sanity test making sure the callback is invoked. TEST_P(PeerConnectionRtpTest, LegacyObserverOnSuccess) { auto caller = CreatePeerConnection(); auto callee = CreatePeerConnection(); std::string error; ASSERT_TRUE( callee->SetRemoteDescription(caller->CreateOfferAndSetAsLocal(), &error)); } // Verifies legacy behavior: The observer is not called if if the peer // connection is destroyed because the asynchronous callback is executed in the // peer connection's message handler. TEST_P(PeerConnectionRtpTest, LegacyObserverNotCalledIfPeerConnectionDereferenced) { auto caller = CreatePeerConnection(); auto callee = CreatePeerConnection(); rtc::scoped_refptr observer = new rtc::RefCountedObject(); auto offer = caller->CreateOfferAndSetAsLocal(); callee->pc()->SetRemoteDescription(observer, offer.release()); callee = nullptr; rtc::Thread::Current()->ProcessMessages(0); EXPECT_FALSE(observer->called()); } // RtpTransceiver Tests. // Test that by default there are no transceivers with Unified Plan. TEST_F(PeerConnectionRtpTestUnifiedPlan, PeerConnectionHasNoTransceivers) { auto caller = CreatePeerConnection(); EXPECT_THAT(caller->pc()->GetTransceivers(), ElementsAre()); } // Test that a transceiver created with the audio kind has the correct initial // properties. TEST_F(PeerConnectionRtpTestUnifiedPlan, AddTransceiverHasCorrectInitProperties) { auto caller = CreatePeerConnection(); auto transceiver = caller->AddTransceiver(cricket::MEDIA_TYPE_AUDIO); EXPECT_EQ(rtc::nullopt, transceiver->mid()); EXPECT_FALSE(transceiver->stopped()); EXPECT_EQ(RtpTransceiverDirection::kSendRecv, transceiver->direction()); EXPECT_EQ(rtc::nullopt, transceiver->current_direction()); } // Test that adding a transceiver with the audio kind creates an audio sender // and audio receiver with the receiver having a live audio track. TEST_F(PeerConnectionRtpTestUnifiedPlan, AddAudioTransceiverCreatesAudioSenderAndReceiver) { auto caller = CreatePeerConnection(); auto transceiver = caller->AddTransceiver(cricket::MEDIA_TYPE_AUDIO); EXPECT_EQ(cricket::MEDIA_TYPE_AUDIO, transceiver->media_type()); ASSERT_TRUE(transceiver->sender()); EXPECT_EQ(cricket::MEDIA_TYPE_AUDIO, transceiver->sender()->media_type()); ASSERT_TRUE(transceiver->receiver()); EXPECT_EQ(cricket::MEDIA_TYPE_AUDIO, transceiver->receiver()->media_type()); auto track = transceiver->receiver()->track(); ASSERT_TRUE(track); EXPECT_EQ(MediaStreamTrackInterface::kAudioKind, track->kind()); EXPECT_EQ(MediaStreamTrackInterface::TrackState::kLive, track->state()); } // Test that adding a transceiver with the video kind creates an video sender // and video receiver with the receiver having a live video track. TEST_F(PeerConnectionRtpTestUnifiedPlan, AddAudioTransceiverCreatesVideoSenderAndReceiver) { auto caller = CreatePeerConnection(); auto transceiver = caller->AddTransceiver(cricket::MEDIA_TYPE_VIDEO); EXPECT_EQ(cricket::MEDIA_TYPE_VIDEO, transceiver->media_type()); ASSERT_TRUE(transceiver->sender()); EXPECT_EQ(cricket::MEDIA_TYPE_VIDEO, transceiver->sender()->media_type()); ASSERT_TRUE(transceiver->receiver()); EXPECT_EQ(cricket::MEDIA_TYPE_VIDEO, transceiver->receiver()->media_type()); auto track = transceiver->receiver()->track(); ASSERT_TRUE(track); EXPECT_EQ(MediaStreamTrackInterface::kVideoKind, track->kind()); EXPECT_EQ(MediaStreamTrackInterface::TrackState::kLive, track->state()); } // Test that after a call to AddTransceiver, the transceiver shows in // GetTransceivers(), the transceiver's sender shows in GetSenders(), and the // transceiver's receiver shows in GetReceivers(). TEST_F(PeerConnectionRtpTestUnifiedPlan, AddTransceiverShowsInLists) { auto caller = CreatePeerConnection(); auto transceiver = caller->AddTransceiver(cricket::MEDIA_TYPE_AUDIO); EXPECT_EQ( std::vector>{transceiver}, caller->pc()->GetTransceivers()); EXPECT_EQ( std::vector>{ transceiver->sender()}, caller->pc()->GetSenders()); EXPECT_EQ( std::vector>{ transceiver->receiver()}, caller->pc()->GetReceivers()); } // Test that the direction passed in through the AddTransceiver init parameter // is set in the returned transceiver. TEST_F(PeerConnectionRtpTestUnifiedPlan, AddTransceiverWithDirectionIsReflected) { auto caller = CreatePeerConnection(); RtpTransceiverInit init; init.direction = RtpTransceiverDirection::kSendOnly; auto transceiver = caller->AddTransceiver(cricket::MEDIA_TYPE_AUDIO, init); EXPECT_EQ(RtpTransceiverDirection::kSendOnly, transceiver->direction()); } // Test that calling AddTransceiver with a track creates a transceiver which has // its sender's track set to the passed-in track. TEST_F(PeerConnectionRtpTestUnifiedPlan, AddTransceiverWithTrackCreatesSenderWithTrack) { auto caller = CreatePeerConnection(); auto audio_track = caller->CreateAudioTrack("audio track"); auto transceiver = caller->AddTransceiver(audio_track); auto sender = transceiver->sender(); ASSERT_TRUE(sender->track()); EXPECT_EQ(audio_track, sender->track()); auto receiver = transceiver->receiver(); ASSERT_TRUE(receiver->track()); EXPECT_EQ(MediaStreamTrackInterface::kAudioKind, receiver->track()->kind()); EXPECT_EQ(MediaStreamTrackInterface::TrackState::kLive, receiver->track()->state()); } // Test that calling AddTransceiver twice with the same track creates distinct // transceivers, senders with the same track. TEST_F(PeerConnectionRtpTestUnifiedPlan, AddTransceiverTwiceWithSameTrackCreatesMultipleTransceivers) { auto caller = CreatePeerConnection(); auto audio_track = caller->CreateAudioTrack("audio track"); auto transceiver1 = caller->AddTransceiver(audio_track); auto transceiver2 = caller->AddTransceiver(audio_track); EXPECT_NE(transceiver1, transceiver2); auto sender1 = transceiver1->sender(); auto sender2 = transceiver2->sender(); EXPECT_NE(sender1, sender2); EXPECT_EQ(audio_track, sender1->track()); EXPECT_EQ(audio_track, sender2->track()); EXPECT_THAT(caller->pc()->GetTransceivers(), UnorderedElementsAre(transceiver1, transceiver2)); EXPECT_THAT(caller->pc()->GetSenders(), UnorderedElementsAre(sender1, sender2)); } // RtpTransceiver error handling tests. TEST_F(PeerConnectionRtpTestUnifiedPlan, AddTransceiverWithInvalidKindReturnsError) { auto caller = CreatePeerConnection(); auto result = caller->pc()->AddTransceiver(cricket::MEDIA_TYPE_DATA); EXPECT_EQ(RTCErrorType::INVALID_PARAMETER, result.error().type()); } TEST_F(PeerConnectionRtpTestUnifiedPlan, CanClosePeerConnectionWithoutCrashing) { auto caller = CreatePeerConnection(); caller->pc()->Close(); } // Unified Plan AddTrack tests. // Test that adding an audio track creates a new audio RtpSender with the given // track. TEST_F(PeerConnectionRtpTestUnifiedPlan, AddAudioTrackCreatesAudioSender) { auto caller = CreatePeerConnection(); auto audio_track = caller->CreateAudioTrack("a"); auto sender = caller->AddTrack(audio_track); ASSERT_TRUE(sender); EXPECT_EQ(cricket::MEDIA_TYPE_AUDIO, sender->media_type()); EXPECT_EQ(audio_track, sender->track()); } // Test that adding a video track creates a new video RtpSender with the given // track. TEST_F(PeerConnectionRtpTestUnifiedPlan, AddVideoTrackCreatesVideoSender) { auto caller = CreatePeerConnection(); auto video_track = caller->CreateVideoTrack("a"); auto sender = caller->AddTrack(video_track); ASSERT_TRUE(sender); EXPECT_EQ(cricket::MEDIA_TYPE_VIDEO, sender->media_type()); EXPECT_EQ(video_track, sender->track()); } // Test that adding a track to a new PeerConnection creates an RtpTransceiver // with the sender that AddTrack returns and in the sendrecv direction. TEST_F(PeerConnectionRtpTestUnifiedPlan, AddFirstTrackCreatesTransceiver) { auto caller = CreatePeerConnection(); auto sender = caller->AddAudioTrack("a"); ASSERT_TRUE(sender); auto transceivers = caller->pc()->GetTransceivers(); ASSERT_EQ(1u, transceivers.size()); EXPECT_EQ(sender, transceivers[0]->sender()); EXPECT_EQ(RtpTransceiverDirection::kSendRecv, transceivers[0]->direction()); } // Test that if a transceiver of the same type but no track had been added to // the PeerConnection and later a call to AddTrack is made, the resulting sender // is the transceiver's sender and the sender's track is the newly-added track. TEST_F(PeerConnectionRtpTestUnifiedPlan, AddTrackReusesTransceiver) { auto caller = CreatePeerConnection(); auto transceiver = caller->AddTransceiver(cricket::MEDIA_TYPE_AUDIO); auto audio_track = caller->CreateAudioTrack("a"); auto sender = caller->AddTrack(audio_track); ASSERT_TRUE(sender); auto transceivers = caller->pc()->GetTransceivers(); ASSERT_EQ(1u, transceivers.size()); EXPECT_EQ(transceiver, transceivers[0]); EXPECT_EQ(sender, transceiver->sender()); EXPECT_EQ(audio_track, sender->track()); } // Test that adding two tracks to a new PeerConnection creates two // RtpTransceivers in the same order. TEST_F(PeerConnectionRtpTestUnifiedPlan, TwoAddTrackCreatesTwoTransceivers) { auto caller = CreatePeerConnection(); auto sender1 = caller->AddAudioTrack("a"); auto sender2 = caller->AddVideoTrack("v"); ASSERT_TRUE(sender2); auto transceivers = caller->pc()->GetTransceivers(); ASSERT_EQ(2u, transceivers.size()); EXPECT_EQ(sender1, transceivers[0]->sender()); EXPECT_EQ(sender2, transceivers[1]->sender()); } // Test that if there are multiple transceivers with no sending track then a // later call to AddTrack will use the one of the same type as the newly-added // track. TEST_F(PeerConnectionRtpTestUnifiedPlan, AddTrackReusesTransceiverOfType) { auto caller = CreatePeerConnection(); auto audio_transceiver = caller->AddTransceiver(cricket::MEDIA_TYPE_AUDIO); auto video_transceiver = caller->AddTransceiver(cricket::MEDIA_TYPE_VIDEO); auto sender = caller->AddVideoTrack("v"); ASSERT_EQ(2u, caller->pc()->GetTransceivers().size()); EXPECT_NE(sender, audio_transceiver->sender()); EXPECT_EQ(sender, video_transceiver->sender()); } // Test that if the only transceivers that do not have a sending track have a // different type from the added track, then AddTrack will create a new // transceiver for the track. TEST_F(PeerConnectionRtpTestUnifiedPlan, AddTrackDoesNotReuseTransceiverOfWrongType) { auto caller = CreatePeerConnection(); caller->AddTransceiver(cricket::MEDIA_TYPE_AUDIO); auto sender = caller->AddVideoTrack("v"); auto transceivers = caller->pc()->GetTransceivers(); ASSERT_EQ(2u, transceivers.size()); EXPECT_NE(sender, transceivers[0]->sender()); EXPECT_EQ(sender, transceivers[1]->sender()); } // Test that the first available transceiver is reused by AddTrack when multiple // are available. TEST_F(PeerConnectionRtpTestUnifiedPlan, AddTrackReusesFirstMatchingTransceiver) { auto caller = CreatePeerConnection(); caller->AddTransceiver(cricket::MEDIA_TYPE_AUDIO); caller->AddTransceiver(cricket::MEDIA_TYPE_AUDIO); auto sender = caller->AddAudioTrack("a"); auto transceivers = caller->pc()->GetTransceivers(); ASSERT_EQ(2u, transceivers.size()); EXPECT_EQ(sender, transceivers[0]->sender()); EXPECT_NE(sender, transceivers[1]->sender()); } // Test that a call to AddTrack that reuses a transceiver will change the // direction from inactive to sendonly. TEST_F(PeerConnectionRtpTestUnifiedPlan, AddTrackChangesDirectionFromInactiveToSendOnly) { auto caller = CreatePeerConnection(); RtpTransceiverInit init; init.direction = RtpTransceiverDirection::kInactive; auto transceiver = caller->AddTransceiver(cricket::MEDIA_TYPE_AUDIO, init); caller->observer()->clear_negotiation_needed(); ASSERT_TRUE(caller->AddAudioTrack("a")); EXPECT_TRUE(caller->observer()->negotiation_needed()); EXPECT_EQ(RtpTransceiverDirection::kSendOnly, transceiver->direction()); } // Test that a call to AddTrack that reuses a transceiver will change the // direction from recvonly to sendrecv. TEST_F(PeerConnectionRtpTestUnifiedPlan, AddTrackChangesDirectionFromRecvOnlyToSendRecv) { auto caller = CreatePeerConnection(); RtpTransceiverInit init; init.direction = RtpTransceiverDirection::kRecvOnly; auto transceiver = caller->AddTransceiver(cricket::MEDIA_TYPE_AUDIO, init); caller->observer()->clear_negotiation_needed(); ASSERT_TRUE(caller->AddAudioTrack("a")); EXPECT_TRUE(caller->observer()->negotiation_needed()); EXPECT_EQ(RtpTransceiverDirection::kSendRecv, transceiver->direction()); } TEST_F(PeerConnectionRtpTestUnifiedPlan, AddTrackCreatesSenderWithTrackId) { const std::string kTrackId = "audio_track"; auto caller = CreatePeerConnection(); auto audio_track = caller->CreateAudioTrack(kTrackId); auto sender = caller->AddTrack(audio_track); EXPECT_EQ(kTrackId, sender->id()); } // Unified Plan AddTrack error handling. TEST_F(PeerConnectionRtpTestUnifiedPlan, AddTrackErrorIfClosed) { auto caller = CreatePeerConnection(); auto audio_track = caller->CreateAudioTrack("a"); caller->pc()->Close(); caller->observer()->clear_negotiation_needed(); auto result = caller->pc() ->AddTrack(audio_track, std::vector()); EXPECT_EQ(RTCErrorType::INVALID_STATE, result.error().type()); EXPECT_FALSE(caller->observer()->negotiation_needed()); } TEST_F(PeerConnectionRtpTestUnifiedPlan, AddTrackErrorIfTrackAlreadyHasSender) { auto caller = CreatePeerConnection(); auto audio_track = caller->CreateAudioTrack("a"); ASSERT_TRUE(caller->AddTrack(audio_track)); caller->observer()->clear_negotiation_needed(); auto result = caller->pc() ->AddTrack(audio_track, std::vector()); EXPECT_EQ(RTCErrorType::INVALID_PARAMETER, result.error().type()); EXPECT_FALSE(caller->observer()->negotiation_needed()); } // Unified Plan RemoveTrack tests. // Test that calling RemoveTrack on a sender with a previously-added track // clears the sender's track. TEST_F(PeerConnectionRtpTestUnifiedPlan, RemoveTrackClearsSenderTrack) { auto caller = CreatePeerConnection(); auto sender = caller->AddAudioTrack("a"); ASSERT_TRUE(caller->pc()->RemoveTrack(sender)); EXPECT_FALSE(sender->track()); } // Test that calling RemoveTrack on a sender where the transceiver is configured // in the sendrecv direction changes the transceiver's direction to recvonly. TEST_F(PeerConnectionRtpTestUnifiedPlan, RemoveTrackChangesDirectionFromSendRecvToRecvOnly) { auto caller = CreatePeerConnection(); RtpTransceiverInit init; init.direction = RtpTransceiverDirection::kSendRecv; auto transceiver = caller->AddTransceiver(caller->CreateAudioTrack("a"), init); caller->observer()->clear_negotiation_needed(); ASSERT_TRUE(caller->pc()->RemoveTrack(transceiver->sender())); EXPECT_TRUE(caller->observer()->negotiation_needed()); EXPECT_EQ(RtpTransceiverDirection::kRecvOnly, transceiver->direction()); EXPECT_TRUE(caller->observer()->renegotiation_needed_); } // Test that calling RemoveTrack on a sender where the transceiver is configured // in the sendonly direction changes the transceiver's direction to inactive. TEST_F(PeerConnectionRtpTestUnifiedPlan, RemoveTrackChangesDirectionFromSendOnlyToInactive) { auto caller = CreatePeerConnection(); RtpTransceiverInit init; init.direction = RtpTransceiverDirection::kSendOnly; auto transceiver = caller->AddTransceiver(caller->CreateAudioTrack("a"), init); caller->observer()->clear_negotiation_needed(); ASSERT_TRUE(caller->pc()->RemoveTrack(transceiver->sender())); EXPECT_TRUE(caller->observer()->negotiation_needed()); EXPECT_EQ(RtpTransceiverDirection::kInactive, transceiver->direction()); } // Test that calling RemoveTrack with a sender that has a null track results in // no change in state. TEST_F(PeerConnectionRtpTestUnifiedPlan, RemoveTrackWithNullSenderTrackIsNoOp) { auto caller = CreatePeerConnection(); auto sender = caller->AddAudioTrack("a"); auto transceiver = caller->pc()->GetTransceivers()[0]; ASSERT_TRUE(sender->SetTrack(nullptr)); caller->observer()->clear_negotiation_needed(); ASSERT_TRUE(caller->pc()->RemoveTrack(sender)); EXPECT_FALSE(caller->observer()->negotiation_needed()); EXPECT_EQ(RtpTransceiverDirection::kSendRecv, transceiver->direction()); } // Unified Plan RemoveTrack error handling. TEST_F(PeerConnectionRtpTestUnifiedPlan, RemoveTrackErrorIfClosed) { auto caller = CreatePeerConnection(); auto sender = caller->AddAudioTrack("a"); caller->pc()->Close(); caller->observer()->clear_negotiation_needed(); EXPECT_FALSE(caller->pc()->RemoveTrack(sender)); EXPECT_FALSE(caller->observer()->negotiation_needed()); } TEST_F(PeerConnectionRtpTestUnifiedPlan, RemoveTrackNoErrorIfTrackAlreadyRemoved) { auto caller = CreatePeerConnection(); auto sender = caller->AddAudioTrack("a"); ASSERT_TRUE(caller->pc()->RemoveTrack(sender)); caller->observer()->clear_negotiation_needed(); EXPECT_TRUE(caller->pc()->RemoveTrack(sender)); EXPECT_FALSE(caller->observer()->negotiation_needed()); } // Test that OnRenegotiationNeeded is fired if SetDirection is called on an // active RtpTransceiver with a new direction. TEST_F(PeerConnectionRtpTestUnifiedPlan, RenegotiationNeededAfterTransceiverSetDirection) { auto caller = CreatePeerConnection(); auto transceiver = caller->AddTransceiver(cricket::MEDIA_TYPE_AUDIO); caller->observer()->clear_negotiation_needed(); transceiver->SetDirection(RtpTransceiverDirection::kInactive); EXPECT_TRUE(caller->observer()->negotiation_needed()); } // Test that OnRenegotiationNeeded is not fired if SetDirection is called on an // active RtpTransceiver with current direction. TEST_F(PeerConnectionRtpTestUnifiedPlan, NoRenegotiationNeededAfterTransceiverSetSameDirection) { auto caller = CreatePeerConnection(); auto transceiver = caller->AddTransceiver(cricket::MEDIA_TYPE_AUDIO); caller->observer()->clear_negotiation_needed(); transceiver->SetDirection(transceiver->direction()); EXPECT_FALSE(caller->observer()->negotiation_needed()); } // Test that OnRenegotiationNeeded is not fired if SetDirection is called on a // stopped RtpTransceiver. TEST_F(PeerConnectionRtpTestUnifiedPlan, NoRenegotiationNeededAfterSetDirectionOnStoppedTransceiver) { auto caller = CreatePeerConnection(); auto transceiver = caller->AddTransceiver(cricket::MEDIA_TYPE_AUDIO); transceiver->Stop(); caller->observer()->clear_negotiation_needed(); transceiver->SetDirection(RtpTransceiverDirection::kInactive); EXPECT_FALSE(caller->observer()->negotiation_needed()); } // Test MSID signaling between Unified Plan and Plan B endpoints. There are two // options for this kind of signaling: media section based (a=msid) and ssrc // based (a=ssrc MSID). While JSEP only specifies media section MSID signaling, // we want to ensure compatibility with older Plan B endpoints that might expect // ssrc based MSID signaling. Thus we test here that Unified Plan offers both // types but answers with the same type as the offer. class PeerConnectionMsidSignalingTest : public PeerConnectionRtpTestUnifiedPlan {}; TEST_F(PeerConnectionMsidSignalingTest, UnifiedPlanTalkingToOurself) { auto caller = CreatePeerConnectionWithUnifiedPlan(); caller->AddAudioTrack("caller_audio"); auto callee = CreatePeerConnectionWithUnifiedPlan(); callee->AddAudioTrack("callee_audio"); auto caller_observer = caller->RegisterFakeMetricsObserver(); ASSERT_TRUE(caller->ExchangeOfferAnswerWith(callee.get())); // Offer should have had both a=msid and a=ssrc MSID lines. auto* offer = callee->pc()->remote_description(); EXPECT_EQ((cricket::kMsidSignalingMediaSection | cricket::kMsidSignalingSsrcAttribute), offer->description()->msid_signaling()); // Answer should have had only a=msid lines. auto* answer = caller->pc()->remote_description(); EXPECT_EQ(cricket::kMsidSignalingMediaSection, answer->description()->msid_signaling()); // Check that this is counted correctly EXPECT_TRUE(caller_observer->ExpectOnlySingleEnumCount( kEnumCounterSdpSemanticNegotiated, kSdpSemanticNegotiatedUnifiedPlan)); } TEST_F(PeerConnectionMsidSignalingTest, PlanBOfferToUnifiedPlanAnswer) { auto caller = CreatePeerConnectionWithPlanB(); caller->AddAudioTrack("caller_audio"); auto callee = CreatePeerConnectionWithUnifiedPlan(); callee->AddAudioTrack("callee_audio"); ASSERT_TRUE(caller->ExchangeOfferAnswerWith(callee.get())); // Offer should have only a=ssrc MSID lines. auto* offer = callee->pc()->remote_description(); EXPECT_EQ(cricket::kMsidSignalingSsrcAttribute, offer->description()->msid_signaling()); // Answer should have only a=ssrc MSID lines to match the offer. auto* answer = caller->pc()->remote_description(); EXPECT_EQ(cricket::kMsidSignalingSsrcAttribute, answer->description()->msid_signaling()); } // This tests that a Plan B endpoint appropriately sets the remote description // from a Unified Plan offer. When the Unified Plan offer contains a=msid lines // that signal no stream ids or multiple stream ids we expect that the Plan B // endpoint always has exactly one media stream per track. TEST_F(PeerConnectionMsidSignalingTest, UnifiedPlanToPlanBAnswer) { const std::string kStreamId1 = "audio_stream_1"; const std::string kStreamId2 = "audio_stream_2"; auto caller = CreatePeerConnectionWithUnifiedPlan(); caller->AddAudioTrack("caller_audio", {kStreamId1, kStreamId2}); caller->AddVideoTrack("caller_video", {}); auto callee = CreatePeerConnectionWithPlanB(); callee->AddAudioTrack("callee_audio"); caller->AddVideoTrack("callee_video"); ASSERT_TRUE(caller->ExchangeOfferAnswerWith(callee.get())); // Offer should have had both a=msid and a=ssrc MSID lines. auto* offer = callee->pc()->remote_description(); EXPECT_EQ((cricket::kMsidSignalingMediaSection | cricket::kMsidSignalingSsrcAttribute), offer->description()->msid_signaling()); // Callee should always have 1 stream for all of it's receivers. const auto& track_events = callee->observer()->add_track_events_; ASSERT_EQ(2u, track_events.size()); ASSERT_EQ(1u, track_events[0].streams.size()); EXPECT_EQ(kStreamId1, track_events[0].streams[0]->id()); ASSERT_EQ(1u, track_events[1].streams.size()); // This autogenerated a stream id for the empty one signalled. EXPECT_FALSE(track_events[1].streams[0]->id().empty()); } TEST_F(PeerConnectionMsidSignalingTest, PureUnifiedPlanToUs) { auto caller = CreatePeerConnectionWithUnifiedPlan(); caller->AddAudioTrack("caller_audio"); auto callee = CreatePeerConnectionWithUnifiedPlan(); callee->AddAudioTrack("callee_audio"); auto offer = caller->CreateOffer(); // Simulate a pure Unified Plan offerer by setting the MSID signaling to media // section only. offer->description()->set_msid_signaling(cricket::kMsidSignalingMediaSection); ASSERT_TRUE( caller->SetLocalDescription(CloneSessionDescription(offer.get()))); ASSERT_TRUE(callee->SetRemoteDescription(std::move(offer))); // Answer should have only a=msid to match the offer. auto answer = callee->CreateAnswer(); EXPECT_EQ(cricket::kMsidSignalingMediaSection, answer->description()->msid_signaling()); } // Test that the correct UMA metrics are reported for simple/complex SDP. class SdpFormatReceivedTest : public PeerConnectionRtpTestUnifiedPlan {}; #ifdef HAVE_SCTP TEST_F(SdpFormatReceivedTest, DataChannelOnlyIsReportedAsNoTracks) { auto caller = CreatePeerConnectionWithUnifiedPlan(); caller->CreateDataChannel("dc"); auto callee = CreatePeerConnectionWithUnifiedPlan(); auto callee_metrics = callee->RegisterFakeMetricsObserver(); ASSERT_TRUE(callee->SetRemoteDescription(caller->CreateOffer())); EXPECT_TRUE(callee_metrics->ExpectOnlySingleEnumCount( kEnumCounterSdpFormatReceived, kSdpFormatReceivedNoTracks)); } #endif // HAVE_SCTP TEST_F(SdpFormatReceivedTest, SimpleUnifiedPlanIsReportedAsSimple) { auto caller = CreatePeerConnectionWithUnifiedPlan(); caller->AddAudioTrack("audio"); caller->AddVideoTrack("video"); auto callee = CreatePeerConnectionWithPlanB(); auto callee_metrics = callee->RegisterFakeMetricsObserver(); ASSERT_TRUE(callee->SetRemoteDescription(caller->CreateOffer())); EXPECT_TRUE(callee_metrics->ExpectOnlySingleEnumCount( kEnumCounterSdpFormatReceived, kSdpFormatReceivedSimple)); } TEST_F(SdpFormatReceivedTest, SimplePlanBIsReportedAsSimple) { auto caller = CreatePeerConnectionWithPlanB(); caller->AddVideoTrack("video"); // Video only. auto callee = CreatePeerConnectionWithUnifiedPlan(); auto callee_metrics = callee->RegisterFakeMetricsObserver(); ASSERT_TRUE(callee->SetRemoteDescription(caller->CreateOffer())); EXPECT_TRUE(callee_metrics->ExpectOnlySingleEnumCount( kEnumCounterSdpFormatReceived, kSdpFormatReceivedSimple)); } TEST_F(SdpFormatReceivedTest, ComplexUnifiedIsReportedAsComplexUnifiedPlan) { auto caller = CreatePeerConnectionWithUnifiedPlan(); caller->AddAudioTrack("audio1"); caller->AddAudioTrack("audio2"); caller->AddVideoTrack("video"); auto callee = CreatePeerConnectionWithPlanB(); auto callee_metrics = callee->RegisterFakeMetricsObserver(); ASSERT_TRUE(callee->SetRemoteDescription(caller->CreateOffer())); EXPECT_TRUE(callee_metrics->ExpectOnlySingleEnumCount( kEnumCounterSdpFormatReceived, kSdpFormatReceivedComplexUnifiedPlan)); } TEST_F(SdpFormatReceivedTest, ComplexPlanBIsReportedAsComplexPlanB) { auto caller = CreatePeerConnectionWithPlanB(); caller->AddVideoTrack("video1"); caller->AddVideoTrack("video2"); auto callee = CreatePeerConnectionWithUnifiedPlan(); auto callee_metrics = callee->RegisterFakeMetricsObserver(); // This fails since Unified Plan cannot set a session description with // multiple "Plan B tracks" in the same media section. But we still expect the // SDP Format to be recorded. ASSERT_FALSE(callee->SetRemoteDescription(caller->CreateOffer())); EXPECT_TRUE(callee_metrics->ExpectOnlySingleEnumCount( kEnumCounterSdpFormatReceived, kSdpFormatReceivedComplexPlanB)); } // Sender setups in a call. TEST_P(PeerConnectionRtpTest, CreateTwoSendersWithSameTrack) { auto caller = CreatePeerConnection(); auto callee = CreatePeerConnection(); auto track = caller->CreateAudioTrack("audio_track"); auto sender1 = caller->AddTrack(track); ASSERT_TRUE(sender1); // We need to temporarily reset the track for the subsequent AddTrack() to // succeed. EXPECT_TRUE(sender1->SetTrack(nullptr)); auto sender2 = caller->AddTrack(track); EXPECT_TRUE(sender2); EXPECT_TRUE(sender1->SetTrack(track)); if (sdp_semantics_ == SdpSemantics::kPlanB) { // TODO(hbos): When https://crbug.com/webrtc/8734 is resolved, this should // return true, and doing |callee->SetRemoteDescription()| should work. EXPECT_FALSE(caller->CreateOfferAndSetAsLocal()); } else { EXPECT_TRUE(caller->CreateOfferAndSetAsLocal()); } } INSTANTIATE_TEST_CASE_P(PeerConnectionRtpTest, PeerConnectionRtpTest, Values(SdpSemantics::kPlanB, SdpSemantics::kUnifiedPlan)); } // namespace webrtc