/* * Copyright 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. */ #include "api/peer_connection_interface.h" #include #include #include #include #include #include #include #include "absl/strings/str_replace.h" #include "absl/types/optional.h" #include "api/audio/audio_mixer.h" #include "api/audio_codecs/audio_decoder_factory.h" #include "api/audio_codecs/audio_encoder_factory.h" #include "api/audio_codecs/builtin_audio_decoder_factory.h" #include "api/audio_codecs/builtin_audio_encoder_factory.h" #include "api/call/call_factory_interface.h" #include "api/create_peerconnection_factory.h" #include "api/data_channel_interface.h" #include "api/jsep.h" #include "api/jsep_session_description.h" #include "api/media_stream_interface.h" #include "api/media_types.h" #include "api/rtc_error.h" #include "api/rtc_event_log/rtc_event_log.h" #include "api/rtc_event_log/rtc_event_log_factory.h" #include "api/rtc_event_log_output.h" #include "api/rtc_event_log_output_file.h" #include "api/rtp_receiver_interface.h" #include "api/rtp_sender_interface.h" #include "api/rtp_transceiver_interface.h" #include "api/scoped_refptr.h" #include "api/task_queue/default_task_queue_factory.h" #include "api/video_codecs/builtin_video_decoder_factory.h" #include "api/video_codecs/builtin_video_encoder_factory.h" #include "api/video_codecs/video_decoder_factory.h" #include "api/video_codecs/video_encoder_factory.h" #include "media/base/codec.h" #include "media/base/media_config.h" #include "media/base/media_engine.h" #include "media/base/stream_params.h" #include "media/engine/webrtc_media_engine.h" #include "media/engine/webrtc_media_engine_defaults.h" #include "media/sctp/sctp_transport_internal.h" #include "modules/audio_device/include/audio_device.h" #include "modules/audio_processing/include/audio_processing.h" #include "p2p/base/fake_port_allocator.h" #include "p2p/base/p2p_constants.h" #include "p2p/base/port.h" #include "p2p/base/port_allocator.h" #include "p2p/base/transport_description.h" #include "p2p/base/transport_info.h" #include "pc/audio_track.h" #include "pc/media_session.h" #include "pc/media_stream.h" #include "pc/peer_connection.h" #include "pc/peer_connection_factory.h" #include "pc/rtc_stats_collector.h" #include "pc/rtp_sender.h" #include "pc/session_description.h" #include "pc/stream_collection.h" #include "pc/test/fake_audio_capture_module.h" #include "pc/test/fake_rtc_certificate_generator.h" #include "pc/test/fake_video_track_source.h" #include "pc/test/mock_peer_connection_observers.h" #include "pc/test/test_sdp_strings.h" #include "pc/video_track.h" #include "rtc_base/checks.h" #include "rtc_base/copy_on_write_buffer.h" #include "rtc_base/gunit.h" #include "rtc_base/ref_counted_object.h" #include "rtc_base/rtc_certificate_generator.h" #include "rtc_base/socket_address.h" #include "rtc_base/thread.h" #include "rtc_base/time_utils.h" #include "rtc_base/virtual_socket_server.h" #include "test/gmock.h" #include "test/gtest.h" #include "test/testsupport/file_utils.h" #ifdef WEBRTC_ANDROID #include "pc/test/android_test_initializer.h" #endif namespace webrtc { namespace { static const char kStreamId1[] = "local_stream_1"; static const char kStreamId2[] = "local_stream_2"; static const char kStreamId3[] = "local_stream_3"; static const int kDefaultStunPort = 3478; static const char kStunAddressOnly[] = "stun:address"; static const char kStunInvalidPort[] = "stun:address:-1"; static const char kStunAddressPortAndMore1[] = "stun:address:port:more"; static const char kStunAddressPortAndMore2[] = "stun:address:port more"; static const char kTurnIceServerUri[] = "turn:turn.example.org"; static const char kTurnUsername[] = "user"; static const char kTurnPassword[] = "password"; static const char kTurnHostname[] = "turn.example.org"; static const uint32_t kTimeout = 10000U; static const char kStreams[][8] = {"stream1", "stream2"}; static const char kAudioTracks[][32] = {"audiotrack0", "audiotrack1"}; static const char kVideoTracks[][32] = {"videotrack0", "videotrack1"}; static const char kRecvonly[] = "recvonly"; static const char kSendrecv[] = "sendrecv"; // Reference SDP with a MediaStream with label "stream1" and audio track with // id "audio_1" and a video track with id "video_1; static const char kSdpStringWithStream1PlanB[] = "v=0\r\n" "o=- 0 0 IN IP4 127.0.0.1\r\n" "s=-\r\n" "t=0 0\r\n" "m=audio 1 RTP/AVPF 103\r\n" "a=ice-ufrag:e5785931\r\n" "a=ice-pwd:36fb7878390db89481c1d46daa4278d8\r\n" "a=fingerprint:sha-256 58:AB:6E:F5:F1:E4:57:B7:E9:46:F4:86:04:28:F9:A7:ED:" "BD:AB:AE:40:EF:CE:9A:51:2C:2A:B1:9B:8B:78:84\r\n" "a=mid:audio\r\n" "a=sendrecv\r\n" "a=rtcp-mux\r\n" "a=rtpmap:103 ISAC/16000\r\n" "a=ssrc:1 cname:stream1\r\n" "a=ssrc:1 mslabel:stream1\r\n" "a=ssrc:1 label:audiotrack0\r\n" "m=video 1 RTP/AVPF 120\r\n" "a=ice-ufrag:e5785931\r\n" "a=ice-pwd:36fb7878390db89481c1d46daa4278d8\r\n" "a=fingerprint:sha-256 58:AB:6E:F5:F1:E4:57:B7:E9:46:F4:86:04:28:F9:A7:ED:" "BD:AB:AE:40:EF:CE:9A:51:2C:2A:B1:9B:8B:78:84\r\n" "a=mid:video\r\n" "a=sendrecv\r\n" "a=rtcp-mux\r\n" "a=rtpmap:120 VP8/90000\r\n" "a=ssrc:2 cname:stream1\r\n" "a=ssrc:2 mslabel:stream1\r\n" "a=ssrc:2 label:videotrack0\r\n"; // Same string as above but with the MID changed to the Unified Plan default. // This is needed so that this SDP can be used as an answer for a Unified Plan // offer. static const char kSdpStringWithStream1UnifiedPlan[] = "v=0\r\n" "o=- 0 0 IN IP4 127.0.0.1\r\n" "s=-\r\n" "t=0 0\r\n" "m=audio 1 RTP/AVPF 103\r\n" "a=ice-ufrag:e5785931\r\n" "a=ice-pwd:36fb7878390db89481c1d46daa4278d8\r\n" "a=fingerprint:sha-256 58:AB:6E:F5:F1:E4:57:B7:E9:46:F4:86:04:28:F9:A7:ED:" "BD:AB:AE:40:EF:CE:9A:51:2C:2A:B1:9B:8B:78:84\r\n" "a=mid:0\r\n" "a=sendrecv\r\n" "a=rtcp-mux\r\n" "a=rtpmap:103 ISAC/16000\r\n" "a=ssrc:1 cname:stream1\r\n" "a=ssrc:1 mslabel:stream1\r\n" "a=ssrc:1 label:audiotrack0\r\n" "m=video 1 RTP/AVPF 120\r\n" "a=ice-ufrag:e5785931\r\n" "a=ice-pwd:36fb7878390db89481c1d46daa4278d8\r\n" "a=fingerprint:sha-256 58:AB:6E:F5:F1:E4:57:B7:E9:46:F4:86:04:28:F9:A7:ED:" "BD:AB:AE:40:EF:CE:9A:51:2C:2A:B1:9B:8B:78:84\r\n" "a=mid:1\r\n" "a=sendrecv\r\n" "a=rtcp-mux\r\n" "a=rtpmap:120 VP8/90000\r\n" "a=ssrc:2 cname:stream1\r\n" "a=ssrc:2 mslabel:stream1\r\n" "a=ssrc:2 label:videotrack0\r\n"; // Reference SDP with a MediaStream with label "stream1" and audio track with // id "audio_1"; static const char kSdpStringWithStream1AudioTrackOnly[] = "v=0\r\n" "o=- 0 0 IN IP4 127.0.0.1\r\n" "s=-\r\n" "t=0 0\r\n" "m=audio 1 RTP/AVPF 103\r\n" "a=ice-ufrag:e5785931\r\n" "a=ice-pwd:36fb7878390db89481c1d46daa4278d8\r\n" "a=fingerprint:sha-256 58:AB:6E:F5:F1:E4:57:B7:E9:46:F4:86:04:28:F9:A7:ED:" "BD:AB:AE:40:EF:CE:9A:51:2C:2A:B1:9B:8B:78:84\r\n" "a=mid:audio\r\n" "a=sendrecv\r\n" "a=rtpmap:103 ISAC/16000\r\n" "a=ssrc:1 cname:stream1\r\n" "a=ssrc:1 mslabel:stream1\r\n" "a=ssrc:1 label:audiotrack0\r\n" "a=rtcp-mux\r\n"; // Reference SDP with two MediaStreams with label "stream1" and "stream2. Each // MediaStreams have one audio track and one video track. // This uses MSID. static const char kSdpStringWithStream1And2PlanB[] = "v=0\r\n" "o=- 0 0 IN IP4 127.0.0.1\r\n" "s=-\r\n" "t=0 0\r\n" "a=msid-semantic: WMS stream1 stream2\r\n" "m=audio 1 RTP/AVPF 103\r\n" "a=ice-ufrag:e5785931\r\n" "a=ice-pwd:36fb7878390db89481c1d46daa4278d8\r\n" "a=fingerprint:sha-256 58:AB:6E:F5:F1:E4:57:B7:E9:46:F4:86:04:28:F9:A7:ED:" "BD:AB:AE:40:EF:CE:9A:51:2C:2A:B1:9B:8B:78:84\r\n" "a=mid:audio\r\n" "a=sendrecv\r\n" "a=rtcp-mux\r\n" "a=rtpmap:103 ISAC/16000\r\n" "a=ssrc:1 cname:stream1\r\n" "a=ssrc:1 msid:stream1 audiotrack0\r\n" "a=ssrc:3 cname:stream2\r\n" "a=ssrc:3 msid:stream2 audiotrack1\r\n" "m=video 1 RTP/AVPF 120\r\n" "a=ice-ufrag:e5785931\r\n" "a=ice-pwd:36fb7878390db89481c1d46daa4278d8\r\n" "a=fingerprint:sha-256 58:AB:6E:F5:F1:E4:57:B7:E9:46:F4:86:04:28:F9:A7:ED:" "BD:AB:AE:40:EF:CE:9A:51:2C:2A:B1:9B:8B:78:84\r\n" "a=mid:video\r\n" "a=sendrecv\r\n" "a=rtcp-mux\r\n" "a=rtpmap:120 VP8/0\r\n" "a=ssrc:2 cname:stream1\r\n" "a=ssrc:2 msid:stream1 videotrack0\r\n" "a=ssrc:4 cname:stream2\r\n" "a=ssrc:4 msid:stream2 videotrack1\r\n"; static const char kSdpStringWithStream1And2UnifiedPlan[] = "v=0\r\n" "o=- 0 0 IN IP4 127.0.0.1\r\n" "s=-\r\n" "t=0 0\r\n" "a=msid-semantic: WMS stream1 stream2\r\n" "m=audio 1 RTP/AVPF 103\r\n" "a=ice-ufrag:e5785931\r\n" "a=ice-pwd:36fb7878390db89481c1d46daa4278d8\r\n" "a=fingerprint:sha-256 58:AB:6E:F5:F1:E4:57:B7:E9:46:F4:86:04:28:F9:A7:ED:" "BD:AB:AE:40:EF:CE:9A:51:2C:2A:B1:9B:8B:78:84\r\n" "a=mid:0\r\n" "a=sendrecv\r\n" "a=rtcp-mux\r\n" "a=rtpmap:103 ISAC/16000\r\n" "a=ssrc:1 cname:stream1\r\n" "a=ssrc:1 msid:stream1 audiotrack0\r\n" "m=video 1 RTP/AVPF 120\r\n" "a=ice-ufrag:e5785931\r\n" "a=ice-pwd:36fb7878390db89481c1d46daa4278d8\r\n" "a=fingerprint:sha-256 58:AB:6E:F5:F1:E4:57:B7:E9:46:F4:86:04:28:F9:A7:ED:" "BD:AB:AE:40:EF:CE:9A:51:2C:2A:B1:9B:8B:78:84\r\n" "a=mid:1\r\n" "a=sendrecv\r\n" "a=rtcp-mux\r\n" "a=rtpmap:120 VP8/0\r\n" "a=ssrc:2 cname:stream1\r\n" "a=ssrc:2 msid:stream1 videotrack0\r\n" "m=audio 1 RTP/AVPF 103\r\n" "a=ice-ufrag:e5785931\r\n" "a=ice-pwd:36fb7878390db89481c1d46daa4278d8\r\n" "a=fingerprint:sha-256 58:AB:6E:F5:F1:E4:57:B7:E9:46:F4:86:04:28:F9:A7:ED:" "BD:AB:AE:40:EF:CE:9A:51:2C:2A:B1:9B:8B:78:84\r\n" "a=mid:2\r\n" "a=sendrecv\r\n" "a=rtcp-mux\r\n" "a=rtpmap:103 ISAC/16000\r\n" "a=ssrc:3 cname:stream2\r\n" "a=ssrc:3 msid:stream2 audiotrack1\r\n" "m=video 1 RTP/AVPF 120\r\n" "a=ice-ufrag:e5785931\r\n" "a=ice-pwd:36fb7878390db89481c1d46daa4278d8\r\n" "a=fingerprint:sha-256 58:AB:6E:F5:F1:E4:57:B7:E9:46:F4:86:04:28:F9:A7:ED:" "BD:AB:AE:40:EF:CE:9A:51:2C:2A:B1:9B:8B:78:84\r\n" "a=mid:3\r\n" "a=sendrecv\r\n" "a=rtcp-mux\r\n" "a=rtpmap:120 VP8/0\r\n" "a=ssrc:4 cname:stream2\r\n" "a=ssrc:4 msid:stream2 videotrack1\r\n"; // Reference SDP without MediaStreams. Msid is not supported. static const char kSdpStringWithoutStreams[] = "v=0\r\n" "o=- 0 0 IN IP4 127.0.0.1\r\n" "s=-\r\n" "t=0 0\r\n" "m=audio 1 RTP/AVPF 103\r\n" "a=ice-ufrag:e5785931\r\n" "a=ice-pwd:36fb7878390db89481c1d46daa4278d8\r\n" "a=fingerprint:sha-256 58:AB:6E:F5:F1:E4:57:B7:E9:46:F4:86:04:28:F9:A7:ED:" "BD:AB:AE:40:EF:CE:9A:51:2C:2A:B1:9B:8B:78:84\r\n" "a=mid:audio\r\n" "a=sendrecv\r\n" "a=rtcp-mux\r\n" "a=rtpmap:103 ISAC/16000\r\n" "m=video 1 RTP/AVPF 120\r\n" "a=ice-ufrag:e5785931\r\n" "a=ice-pwd:36fb7878390db89481c1d46daa4278d8\r\n" "a=fingerprint:sha-256 58:AB:6E:F5:F1:E4:57:B7:E9:46:F4:86:04:28:F9:A7:ED:" "BD:AB:AE:40:EF:CE:9A:51:2C:2A:B1:9B:8B:78:84\r\n" "a=mid:video\r\n" "a=sendrecv\r\n" "a=rtcp-mux\r\n" "a=rtpmap:120 VP8/90000\r\n"; // Reference SDP without MediaStreams. Msid is supported. static const char kSdpStringWithMsidWithoutStreams[] = "v=0\r\n" "o=- 0 0 IN IP4 127.0.0.1\r\n" "s=-\r\n" "t=0 0\r\n" "a=msid-semantic: WMS\r\n" "m=audio 1 RTP/AVPF 103\r\n" "a=ice-ufrag:e5785931\r\n" "a=ice-pwd:36fb7878390db89481c1d46daa4278d8\r\n" "a=fingerprint:sha-256 58:AB:6E:F5:F1:E4:57:B7:E9:46:F4:86:04:28:F9:A7:ED:" "BD:AB:AE:40:EF:CE:9A:51:2C:2A:B1:9B:8B:78:84\r\n" "a=mid:audio\r\n" "a=sendrecv\r\n" "a=rtcp-mux\r\n" "a=rtpmap:103 ISAC/16000\r\n" "m=video 1 RTP/AVPF 120\r\n" "a=ice-ufrag:e5785931\r\n" "a=ice-pwd:36fb7878390db89481c1d46daa4278d8\r\n" "a=fingerprint:sha-256 58:AB:6E:F5:F1:E4:57:B7:E9:46:F4:86:04:28:F9:A7:ED:" "BD:AB:AE:40:EF:CE:9A:51:2C:2A:B1:9B:8B:78:84\r\n" "a=mid:video\r\n" "a=sendrecv\r\n" "a=rtcp-mux\r\n" "a=rtpmap:120 VP8/90000\r\n"; // Reference SDP without MediaStreams and audio only. static const char kSdpStringWithoutStreamsAudioOnly[] = "v=0\r\n" "o=- 0 0 IN IP4 127.0.0.1\r\n" "s=-\r\n" "t=0 0\r\n" "m=audio 1 RTP/AVPF 103\r\n" "a=ice-ufrag:e5785931\r\n" "a=ice-pwd:36fb7878390db89481c1d46daa4278d8\r\n" "a=fingerprint:sha-256 58:AB:6E:F5:F1:E4:57:B7:E9:46:F4:86:04:28:F9:A7:ED:" "BD:AB:AE:40:EF:CE:9A:51:2C:2A:B1:9B:8B:78:84\r\n" "a=mid:audio\r\n" "a=sendrecv\r\n" "a=rtcp-mux\r\n" "a=rtpmap:103 ISAC/16000\r\n"; // Reference SENDONLY SDP without MediaStreams. Msid is not supported. static const char kSdpStringSendOnlyWithoutStreams[] = "v=0\r\n" "o=- 0 0 IN IP4 127.0.0.1\r\n" "s=-\r\n" "t=0 0\r\n" "m=audio 1 RTP/AVPF 103\r\n" "a=ice-ufrag:e5785931\r\n" "a=ice-pwd:36fb7878390db89481c1d46daa4278d8\r\n" "a=fingerprint:sha-256 58:AB:6E:F5:F1:E4:57:B7:E9:46:F4:86:04:28:F9:A7:ED:" "BD:AB:AE:40:EF:CE:9A:51:2C:2A:B1:9B:8B:78:84\r\n" "a=mid:audio\r\n" "a=sendrecv\r\n" "a=sendonly\r\n" "a=rtcp-mux\r\n" "a=rtpmap:103 ISAC/16000\r\n" "m=video 1 RTP/AVPF 120\r\n" "a=ice-ufrag:e5785931\r\n" "a=ice-pwd:36fb7878390db89481c1d46daa4278d8\r\n" "a=fingerprint:sha-256 58:AB:6E:F5:F1:E4:57:B7:E9:46:F4:86:04:28:F9:A7:ED:" "BD:AB:AE:40:EF:CE:9A:51:2C:2A:B1:9B:8B:78:84\r\n" "a=mid:video\r\n" "a=sendrecv\r\n" "a=sendonly\r\n" "a=rtcp-mux\r\n" "a=rtpmap:120 VP8/90000\r\n"; static const char kSdpStringInit[] = "v=0\r\n" "o=- 0 0 IN IP4 127.0.0.1\r\n" "s=-\r\n" "t=0 0\r\n" "a=msid-semantic: WMS\r\n"; static const char kSdpStringAudio[] = "m=audio 1 RTP/AVPF 103\r\n" "a=ice-ufrag:e5785931\r\n" "a=ice-pwd:36fb7878390db89481c1d46daa4278d8\r\n" "a=fingerprint:sha-256 58:AB:6E:F5:F1:E4:57:B7:E9:46:F4:86:04:28:F9:A7:ED:" "BD:AB:AE:40:EF:CE:9A:51:2C:2A:B1:9B:8B:78:84\r\n" "a=mid:audio\r\n" "a=sendrecv\r\n" "a=rtcp-mux\r\n" "a=rtpmap:103 ISAC/16000\r\n"; static const char kSdpStringVideo[] = "m=video 1 RTP/AVPF 120\r\n" "a=ice-ufrag:e5785931\r\n" "a=ice-pwd:36fb7878390db89481c1d46daa4278d8\r\n" "a=fingerprint:sha-256 58:AB:6E:F5:F1:E4:57:B7:E9:46:F4:86:04:28:F9:A7:ED:" "BD:AB:AE:40:EF:CE:9A:51:2C:2A:B1:9B:8B:78:84\r\n" "a=mid:video\r\n" "a=sendrecv\r\n" "a=rtcp-mux\r\n" "a=rtpmap:120 VP8/90000\r\n"; static const char kSdpStringMs1Audio0[] = "a=ssrc:1 cname:stream1\r\n" "a=ssrc:1 msid:stream1 audiotrack0\r\n"; static const char kSdpStringMs1Video0[] = "a=ssrc:2 cname:stream1\r\n" "a=ssrc:2 msid:stream1 videotrack0\r\n"; static const char kSdpStringMs1Audio1[] = "a=ssrc:3 cname:stream1\r\n" "a=ssrc:3 msid:stream1 audiotrack1\r\n"; static const char kSdpStringMs1Video1[] = "a=ssrc:4 cname:stream1\r\n" "a=ssrc:4 msid:stream1 videotrack1\r\n"; static const char kDtlsSdesFallbackSdp[] = "v=0\r\n" "o=xxxxxx 7 2 IN IP4 0.0.0.0\r\n" "s=-\r\n" "c=IN IP4 0.0.0.0\r\n" "t=0 0\r\n" "a=group:BUNDLE audio\r\n" "a=msid-semantic: WMS\r\n" "m=audio 1 RTP/SAVPF 0\r\n" "a=sendrecv\r\n" "a=rtcp-mux\r\n" "a=mid:audio\r\n" "a=ssrc:1 cname:stream1\r\n" "a=ssrc:1 mslabel:stream1\r\n" "a=ssrc:1 label:audiotrack0\r\n" "a=ice-ufrag:e5785931\r\n" "a=ice-pwd:36fb7878390db89481c1d46daa4278d8\r\n" "a=rtpmap:0 pcmu/8000\r\n" "a=fingerprint:sha-1 " "4A:AD:B9:B1:3F:82:18:3B:54:02:12:DF:3E:5D:49:6B:19:E5:7C:AB\r\n" "a=setup:actpass\r\n" "a=crypto:0 AES_CM_128_HMAC_SHA1_80 " "inline:NzB4d1BINUAvLEw6UzF3WSJ+PSdFcGdUJShpX1Zj|2^20|1:32 " "dummy_session_params\r\n"; class RtcEventLogOutputNull final : public RtcEventLogOutput { public: bool IsActive() const override { return true; } bool Write(const std::string& output) override { return true; } }; using ::cricket::StreamParams; using ::testing::Exactly; using ::testing::Values; using RTCConfiguration = PeerConnectionInterface::RTCConfiguration; using RTCOfferAnswerOptions = PeerConnectionInterface::RTCOfferAnswerOptions; // Gets the first ssrc of given content type from the ContentInfo. bool GetFirstSsrc(const cricket::ContentInfo* content_info, int* ssrc) { if (!content_info || !ssrc) { return false; } const cricket::MediaContentDescription* media_desc = content_info->media_description(); if (!media_desc || media_desc->streams().empty()) { return false; } *ssrc = media_desc->streams().begin()->first_ssrc(); return true; } // Get the ufrags out of an SDP blob. Useful for testing ICE restart // behavior. std::vector GetUfrags( const webrtc::SessionDescriptionInterface* desc) { std::vector ufrags; for (const cricket::TransportInfo& info : desc->description()->transport_infos()) { ufrags.push_back(info.description.ice_ufrag); } return ufrags; } void SetSsrcToZero(std::string* sdp) { const char kSdpSsrcAtribute[] = "a=ssrc:"; const char kSdpSsrcAtributeZero[] = "a=ssrc:0"; size_t ssrc_pos = 0; while ((ssrc_pos = sdp->find(kSdpSsrcAtribute, ssrc_pos)) != std::string::npos) { size_t end_ssrc = sdp->find(" ", ssrc_pos); sdp->replace(ssrc_pos, end_ssrc - ssrc_pos, kSdpSsrcAtributeZero); ssrc_pos = end_ssrc; } } // Check if |streams| contains the specified track. bool ContainsTrack(const std::vector& streams, const std::string& stream_id, const std::string& track_id) { for (const cricket::StreamParams& params : streams) { if (params.first_stream_id() == stream_id && params.id == track_id) { return true; } } return false; } // Check if |senders| contains the specified sender, by id. bool ContainsSender( const std::vector>& senders, const std::string& id) { for (const auto& sender : senders) { if (sender->id() == id) { return true; } } return false; } // Check if |senders| contains the specified sender, by id and stream id. bool ContainsSender( const std::vector>& senders, const std::string& id, const std::string& stream_id) { for (const auto& sender : senders) { if (sender->id() == id && sender->stream_ids()[0] == stream_id) { return true; } } return false; } // Create a collection of streams. // CreateStreamCollection(1) creates a collection that // correspond to kSdpStringWithStream1. // CreateStreamCollection(2) correspond to kSdpStringWithStream1And2. rtc::scoped_refptr CreateStreamCollection( int number_of_streams, int tracks_per_stream) { rtc::scoped_refptr local_collection( StreamCollection::Create()); for (int i = 0; i < number_of_streams; ++i) { rtc::scoped_refptr stream( webrtc::MediaStream::Create(kStreams[i])); for (int j = 0; j < tracks_per_stream; ++j) { // Add a local audio track. rtc::scoped_refptr audio_track( webrtc::AudioTrack::Create(kAudioTracks[i * tracks_per_stream + j], nullptr)); stream->AddTrack(audio_track); // Add a local video track. rtc::scoped_refptr video_track( webrtc::VideoTrack::Create(kVideoTracks[i * tracks_per_stream + j], webrtc::FakeVideoTrackSource::Create(), rtc::Thread::Current())); stream->AddTrack(video_track); } local_collection->AddStream(stream); } return local_collection; } // Check equality of StreamCollections. bool CompareStreamCollections(StreamCollectionInterface* s1, StreamCollectionInterface* s2) { if (s1 == nullptr || s2 == nullptr || s1->count() != s2->count()) { return false; } for (size_t i = 0; i != s1->count(); ++i) { if (s1->at(i)->id() != s2->at(i)->id()) { return false; } webrtc::AudioTrackVector audio_tracks1 = s1->at(i)->GetAudioTracks(); webrtc::AudioTrackVector audio_tracks2 = s2->at(i)->GetAudioTracks(); webrtc::VideoTrackVector video_tracks1 = s1->at(i)->GetVideoTracks(); webrtc::VideoTrackVector video_tracks2 = s2->at(i)->GetVideoTracks(); if (audio_tracks1.size() != audio_tracks2.size()) { return false; } for (size_t j = 0; j != audio_tracks1.size(); ++j) { if (audio_tracks1[j]->id() != audio_tracks2[j]->id()) { return false; } } if (video_tracks1.size() != video_tracks2.size()) { return false; } for (size_t j = 0; j != video_tracks1.size(); ++j) { if (video_tracks1[j]->id() != video_tracks2[j]->id()) { return false; } } } return true; } // Helper class to test Observer. class MockTrackObserver : public ObserverInterface { public: explicit MockTrackObserver(NotifierInterface* notifier) : notifier_(notifier) { notifier_->RegisterObserver(this); } ~MockTrackObserver() { Unregister(); } void Unregister() { if (notifier_) { notifier_->UnregisterObserver(this); notifier_ = nullptr; } } MOCK_METHOD(void, OnChanged, (), (override)); private: NotifierInterface* notifier_; }; // The PeerConnectionMediaConfig tests below verify that configuration and // constraints are propagated into the PeerConnection's MediaConfig. These // settings are intended for MediaChannel constructors, but that is not // exercised by these unittest. class PeerConnectionFactoryForTest : public webrtc::PeerConnectionFactory { public: static rtc::scoped_refptr CreatePeerConnectionFactoryForTest() { PeerConnectionFactoryDependencies dependencies; dependencies.worker_thread = rtc::Thread::Current(); dependencies.network_thread = rtc::Thread::Current(); dependencies.signaling_thread = rtc::Thread::Current(); dependencies.task_queue_factory = CreateDefaultTaskQueueFactory(); cricket::MediaEngineDependencies media_deps; media_deps.task_queue_factory = dependencies.task_queue_factory.get(); // Use fake audio device module since we're only testing the interface // level, and using a real one could make tests flaky when run in parallel. media_deps.adm = FakeAudioCaptureModule::Create(); SetMediaEngineDefaults(&media_deps); dependencies.media_engine = cricket::CreateMediaEngine(std::move(media_deps)); dependencies.call_factory = webrtc::CreateCallFactory(); dependencies.event_log_factory = std::make_unique( dependencies.task_queue_factory.get()); return new rtc::RefCountedObject( std::move(dependencies)); } using PeerConnectionFactory::PeerConnectionFactory; private: rtc::scoped_refptr fake_audio_capture_module_; }; // TODO(steveanton): Convert to use the new PeerConnectionWrapper. class PeerConnectionInterfaceBaseTest : public ::testing::Test { protected: explicit PeerConnectionInterfaceBaseTest(SdpSemantics sdp_semantics) : vss_(new rtc::VirtualSocketServer()), main_(vss_.get()), sdp_semantics_(sdp_semantics) { #ifdef WEBRTC_ANDROID webrtc::InitializeAndroidObjects(); #endif } virtual void SetUp() { // Use fake audio capture module since we're only testing the interface // level, and using a real one could make tests flaky when run in parallel. fake_audio_capture_module_ = FakeAudioCaptureModule::Create(); pc_factory_ = webrtc::CreatePeerConnectionFactory( rtc::Thread::Current(), rtc::Thread::Current(), rtc::Thread::Current(), rtc::scoped_refptr( fake_audio_capture_module_), webrtc::CreateBuiltinAudioEncoderFactory(), webrtc::CreateBuiltinAudioDecoderFactory(), webrtc::CreateBuiltinVideoEncoderFactory(), webrtc::CreateBuiltinVideoDecoderFactory(), nullptr /* audio_mixer */, nullptr /* audio_processing */); ASSERT_TRUE(pc_factory_); pc_factory_for_test_ = PeerConnectionFactoryForTest::CreatePeerConnectionFactoryForTest(); pc_factory_for_test_->Initialize(); } void CreatePeerConnection() { CreatePeerConnection(PeerConnectionInterface::RTCConfiguration()); } // DTLS does not work in a loopback call, so is disabled for most of the // tests in this file. void CreatePeerConnectionWithoutDtls() { RTCConfiguration config; config.enable_dtls_srtp = false; CreatePeerConnection(config); } void CreatePeerConnectionWithIceTransportsType( PeerConnectionInterface::IceTransportsType type) { PeerConnectionInterface::RTCConfiguration config; config.type = type; return CreatePeerConnection(config); } void CreatePeerConnectionWithIceServer(const std::string& uri, const std::string& username, const std::string& password) { PeerConnectionInterface::RTCConfiguration config; PeerConnectionInterface::IceServer server; server.uri = uri; server.username = username; server.password = password; config.servers.push_back(server); CreatePeerConnection(config); } void CreatePeerConnection(const RTCConfiguration& config) { std::unique_ptr port_allocator( new cricket::FakePortAllocator(rtc::Thread::Current(), nullptr)); port_allocator_ = port_allocator.get(); // Create certificate generator unless DTLS constraint is explicitly set to // false. std::unique_ptr cert_generator; if (config.enable_dtls_srtp.value_or(true)) { fake_certificate_generator_ = new FakeRTCCertificateGenerator(); cert_generator.reset(fake_certificate_generator_); } RTCConfiguration modified_config = config; modified_config.sdp_semantics = sdp_semantics_; pc_ = pc_factory_->CreatePeerConnection( modified_config, std::move(port_allocator), std::move(cert_generator), &observer_); ASSERT_TRUE(pc_.get() != NULL); observer_.SetPeerConnectionInterface(pc_.get()); EXPECT_EQ(PeerConnectionInterface::kStable, observer_.state_); } void CreatePeerConnectionExpectFail(const std::string& uri) { PeerConnectionInterface::RTCConfiguration config; PeerConnectionInterface::IceServer server; server.uri = uri; config.servers.push_back(server); config.sdp_semantics = sdp_semantics_; rtc::scoped_refptr pc = pc_factory_->CreatePeerConnection(config, nullptr, nullptr, &observer_); EXPECT_EQ(nullptr, pc); } void CreatePeerConnectionExpectFail( PeerConnectionInterface::RTCConfiguration config) { PeerConnectionInterface::IceServer server; server.uri = kTurnIceServerUri; server.password = kTurnPassword; config.servers.push_back(server); config.sdp_semantics = sdp_semantics_; rtc::scoped_refptr pc = pc_factory_->CreatePeerConnection(config, nullptr, nullptr, &observer_); EXPECT_EQ(nullptr, pc); } void CreatePeerConnectionWithDifferentConfigurations() { CreatePeerConnectionWithIceServer(kStunAddressOnly, "", ""); EXPECT_EQ(1u, port_allocator_->stun_servers().size()); EXPECT_EQ(0u, port_allocator_->turn_servers().size()); EXPECT_EQ("address", port_allocator_->stun_servers().begin()->hostname()); EXPECT_EQ(kDefaultStunPort, port_allocator_->stun_servers().begin()->port()); CreatePeerConnectionExpectFail(kStunInvalidPort); CreatePeerConnectionExpectFail(kStunAddressPortAndMore1); CreatePeerConnectionExpectFail(kStunAddressPortAndMore2); CreatePeerConnectionWithIceServer(kTurnIceServerUri, kTurnUsername, kTurnPassword); EXPECT_EQ(0u, port_allocator_->stun_servers().size()); EXPECT_EQ(1u, port_allocator_->turn_servers().size()); EXPECT_EQ(kTurnUsername, port_allocator_->turn_servers()[0].credentials.username); EXPECT_EQ(kTurnPassword, port_allocator_->turn_servers()[0].credentials.password); EXPECT_EQ(kTurnHostname, port_allocator_->turn_servers()[0].ports[0].address.hostname()); } void ReleasePeerConnection() { pc_ = NULL; observer_.SetPeerConnectionInterface(NULL); } rtc::scoped_refptr CreateVideoTrack( const std::string& label) { return pc_factory_->CreateVideoTrack(label, FakeVideoTrackSource::Create()); } void AddVideoTrack(const std::string& track_label, const std::vector& stream_ids = {}) { auto sender_or_error = pc_->AddTrack(CreateVideoTrack(track_label), stream_ids); ASSERT_EQ(RTCErrorType::NONE, sender_or_error.error().type()); } void AddVideoStream(const std::string& label) { rtc::scoped_refptr stream( pc_factory_->CreateLocalMediaStream(label)); stream->AddTrack(CreateVideoTrack(label + "v0")); ASSERT_TRUE(pc_->AddStream(stream)); } rtc::scoped_refptr CreateAudioTrack( const std::string& label) { return pc_factory_->CreateAudioTrack(label, nullptr); } void AddAudioTrack(const std::string& track_label, const std::vector& stream_ids = {}) { auto sender_or_error = pc_->AddTrack(CreateAudioTrack(track_label), stream_ids); ASSERT_EQ(RTCErrorType::NONE, sender_or_error.error().type()); } void AddAudioStream(const std::string& label) { rtc::scoped_refptr stream( pc_factory_->CreateLocalMediaStream(label)); stream->AddTrack(CreateAudioTrack(label + "a0")); ASSERT_TRUE(pc_->AddStream(stream)); } void AddAudioVideoStream(const std::string& stream_id, const std::string& audio_track_label, const std::string& video_track_label) { // Create a local stream. rtc::scoped_refptr stream( pc_factory_->CreateLocalMediaStream(stream_id)); stream->AddTrack(CreateAudioTrack(audio_track_label)); stream->AddTrack(CreateVideoTrack(video_track_label)); ASSERT_TRUE(pc_->AddStream(stream)); } rtc::scoped_refptr GetFirstReceiverOfType( cricket::MediaType media_type) { for (auto receiver : pc_->GetReceivers()) { if (receiver->media_type() == media_type) { return receiver; } } return nullptr; } bool DoCreateOfferAnswer(std::unique_ptr* desc, const RTCOfferAnswerOptions* options, bool offer) { rtc::scoped_refptr observer( new rtc::RefCountedObject()); if (offer) { pc_->CreateOffer(observer, options ? *options : RTCOfferAnswerOptions()); } else { pc_->CreateAnswer(observer, options ? *options : RTCOfferAnswerOptions()); } EXPECT_EQ_WAIT(true, observer->called(), kTimeout); *desc = observer->MoveDescription(); return observer->result(); } bool DoCreateOffer(std::unique_ptr* desc, const RTCOfferAnswerOptions* options) { return DoCreateOfferAnswer(desc, options, true); } bool DoCreateAnswer(std::unique_ptr* desc, const RTCOfferAnswerOptions* options) { return DoCreateOfferAnswer(desc, options, false); } bool DoSetSessionDescription( std::unique_ptr desc, bool local) { rtc::scoped_refptr observer( new rtc::RefCountedObject()); if (local) { pc_->SetLocalDescription(observer, desc.release()); } else { pc_->SetRemoteDescription(observer, desc.release()); } if (pc_->signaling_state() != PeerConnectionInterface::kClosed) { EXPECT_EQ_WAIT(true, observer->called(), kTimeout); } return observer->result(); } bool DoSetLocalDescription( std::unique_ptr desc) { return DoSetSessionDescription(std::move(desc), true); } bool DoSetRemoteDescription( std::unique_ptr desc) { return DoSetSessionDescription(std::move(desc), false); } // Calls PeerConnection::GetStats and check the return value. // It does not verify the values in the StatReports since a RTCP packet might // be required. bool DoGetStats(MediaStreamTrackInterface* track) { rtc::scoped_refptr observer( new rtc::RefCountedObject()); if (!pc_->GetStats(observer, track, PeerConnectionInterface::kStatsOutputLevelStandard)) return false; EXPECT_TRUE_WAIT(observer->called(), kTimeout); return observer->called(); } // Call the standards-compliant GetStats function. bool DoGetRTCStats() { rtc::scoped_refptr callback( new rtc::RefCountedObject()); pc_->GetStats(callback); EXPECT_TRUE_WAIT(callback->called(), kTimeout); return callback->called(); } void InitiateCall() { CreatePeerConnectionWithoutDtls(); // Create a local stream with audio&video tracks. if (sdp_semantics_ == SdpSemantics::kPlanB) { AddAudioVideoStream(kStreamId1, "audio_track", "video_track"); } else { // Unified Plan does not support AddStream, so just add an audio and video // track. AddAudioTrack(kAudioTracks[0], {kStreamId1}); AddVideoTrack(kVideoTracks[0], {kStreamId1}); } CreateOfferReceiveAnswer(); } // Verify that RTP Header extensions has been negotiated for audio and video. void VerifyRemoteRtpHeaderExtensions() { const cricket::MediaContentDescription* desc = cricket::GetFirstAudioContentDescription( pc_->remote_description()->description()); ASSERT_TRUE(desc != NULL); EXPECT_GT(desc->rtp_header_extensions().size(), 0u); desc = cricket::GetFirstVideoContentDescription( pc_->remote_description()->description()); ASSERT_TRUE(desc != NULL); EXPECT_GT(desc->rtp_header_extensions().size(), 0u); } void CreateOfferAsRemoteDescription() { std::unique_ptr offer; ASSERT_TRUE(DoCreateOffer(&offer, nullptr)); std::string sdp; EXPECT_TRUE(offer->ToString(&sdp)); std::unique_ptr remote_offer( webrtc::CreateSessionDescription(SdpType::kOffer, sdp)); EXPECT_TRUE(DoSetRemoteDescription(std::move(remote_offer))); EXPECT_EQ(PeerConnectionInterface::kHaveRemoteOffer, observer_.state_); } void CreateAndSetRemoteOffer(const std::string& sdp) { std::unique_ptr remote_offer( webrtc::CreateSessionDescription(SdpType::kOffer, sdp)); EXPECT_TRUE(DoSetRemoteDescription(std::move(remote_offer))); EXPECT_EQ(PeerConnectionInterface::kHaveRemoteOffer, observer_.state_); } void CreateAnswerAsLocalDescription() { std::unique_ptr answer; ASSERT_TRUE(DoCreateAnswer(&answer, nullptr)); // TODO(perkj): Currently SetLocalDescription fails if any parameters in an // audio codec change, even if the parameter has nothing to do with // receiving. Not all parameters are serialized to SDP. // Since CreatePrAnswerAsLocalDescription serialize/deserialize // the SessionDescription, it is necessary to do that here to in order to // get ReceiveOfferCreatePrAnswerAndAnswer and RenegotiateAudioOnly to pass. // https://code.google.com/p/webrtc/issues/detail?id=1356 std::string sdp; EXPECT_TRUE(answer->ToString(&sdp)); std::unique_ptr new_answer( webrtc::CreateSessionDescription(SdpType::kAnswer, sdp)); EXPECT_TRUE(DoSetLocalDescription(std::move(new_answer))); EXPECT_EQ(PeerConnectionInterface::kStable, observer_.state_); } void CreatePrAnswerAsLocalDescription() { std::unique_ptr answer; ASSERT_TRUE(DoCreateAnswer(&answer, nullptr)); std::string sdp; EXPECT_TRUE(answer->ToString(&sdp)); std::unique_ptr pr_answer( webrtc::CreateSessionDescription(SdpType::kPrAnswer, sdp)); EXPECT_TRUE(DoSetLocalDescription(std::move(pr_answer))); EXPECT_EQ(PeerConnectionInterface::kHaveLocalPrAnswer, observer_.state_); } void CreateOfferReceiveAnswer() { CreateOfferAsLocalDescription(); std::string sdp; EXPECT_TRUE(pc_->local_description()->ToString(&sdp)); CreateAnswerAsRemoteDescription(sdp); } void CreateOfferAsLocalDescription() { std::unique_ptr offer; ASSERT_TRUE(DoCreateOffer(&offer, nullptr)); // TODO(perkj): Currently SetLocalDescription fails if any parameters in an // audio codec change, even if the parameter has nothing to do with // receiving. Not all parameters are serialized to SDP. // Since CreatePrAnswerAsLocalDescription serialize/deserialize // the SessionDescription, it is necessary to do that here to in order to // get ReceiveOfferCreatePrAnswerAndAnswer and RenegotiateAudioOnly to pass. // https://code.google.com/p/webrtc/issues/detail?id=1356 std::string sdp; EXPECT_TRUE(offer->ToString(&sdp)); std::unique_ptr new_offer( webrtc::CreateSessionDescription(SdpType::kOffer, sdp)); EXPECT_TRUE(DoSetLocalDescription(std::move(new_offer))); EXPECT_EQ(PeerConnectionInterface::kHaveLocalOffer, observer_.state_); // Wait for the ice_complete message, so that SDP will have candidates. EXPECT_TRUE_WAIT(observer_.ice_gathering_complete_, kTimeout); } void CreateAnswerAsRemoteDescription(const std::string& sdp) { std::unique_ptr answer( webrtc::CreateSessionDescription(SdpType::kAnswer, sdp)); ASSERT_TRUE(answer); EXPECT_TRUE(DoSetRemoteDescription(std::move(answer))); EXPECT_EQ(PeerConnectionInterface::kStable, observer_.state_); } void CreatePrAnswerAndAnswerAsRemoteDescription(const std::string& sdp) { std::unique_ptr pr_answer( webrtc::CreateSessionDescription(SdpType::kPrAnswer, sdp)); ASSERT_TRUE(pr_answer); EXPECT_TRUE(DoSetRemoteDescription(std::move(pr_answer))); EXPECT_EQ(PeerConnectionInterface::kHaveRemotePrAnswer, observer_.state_); std::unique_ptr answer( webrtc::CreateSessionDescription(SdpType::kAnswer, sdp)); ASSERT_TRUE(answer); EXPECT_TRUE(DoSetRemoteDescription(std::move(answer))); EXPECT_EQ(PeerConnectionInterface::kStable, observer_.state_); } // Waits until a remote stream with the given id is signaled. This helper // function will verify both OnAddTrack and OnAddStream (Plan B only) are // called with the given stream id and expected number of tracks. void WaitAndVerifyOnAddStream(const std::string& stream_id, int expected_num_tracks) { // Verify that both OnAddStream and OnAddTrack are called. EXPECT_EQ_WAIT(stream_id, observer_.GetLastAddedStreamId(), kTimeout); EXPECT_EQ_WAIT(expected_num_tracks, observer_.CountAddTrackEventsForStream(stream_id), kTimeout); } // Creates an offer and applies it as a local session description. // Creates an answer with the same SDP an the offer but removes all lines // that start with a:ssrc" void CreateOfferReceiveAnswerWithoutSsrc() { CreateOfferAsLocalDescription(); std::string sdp; EXPECT_TRUE(pc_->local_description()->ToString(&sdp)); SetSsrcToZero(&sdp); CreateAnswerAsRemoteDescription(sdp); } // This function creates a MediaStream with label kStreams[0] and // |number_of_audio_tracks| and |number_of_video_tracks| tracks and the // corresponding SessionDescriptionInterface. The SessionDescriptionInterface // is returned and the MediaStream is stored in // |reference_collection_| std::unique_ptr CreateSessionDescriptionAndReference(size_t number_of_audio_tracks, size_t number_of_video_tracks) { EXPECT_LE(number_of_audio_tracks, 2u); EXPECT_LE(number_of_video_tracks, 2u); reference_collection_ = StreamCollection::Create(); std::string sdp_ms1 = std::string(kSdpStringInit); std::string mediastream_id = kStreams[0]; rtc::scoped_refptr stream( webrtc::MediaStream::Create(mediastream_id)); reference_collection_->AddStream(stream); if (number_of_audio_tracks > 0) { sdp_ms1 += std::string(kSdpStringAudio); sdp_ms1 += std::string(kSdpStringMs1Audio0); AddAudioTrack(kAudioTracks[0], stream); } if (number_of_audio_tracks > 1) { sdp_ms1 += kSdpStringMs1Audio1; AddAudioTrack(kAudioTracks[1], stream); } if (number_of_video_tracks > 0) { sdp_ms1 += std::string(kSdpStringVideo); sdp_ms1 += std::string(kSdpStringMs1Video0); AddVideoTrack(kVideoTracks[0], stream); } if (number_of_video_tracks > 1) { sdp_ms1 += kSdpStringMs1Video1; AddVideoTrack(kVideoTracks[1], stream); } return std::unique_ptr( webrtc::CreateSessionDescription(SdpType::kOffer, sdp_ms1)); } void AddAudioTrack(const std::string& track_id, MediaStreamInterface* stream) { rtc::scoped_refptr audio_track( webrtc::AudioTrack::Create(track_id, nullptr)); ASSERT_TRUE(stream->AddTrack(audio_track)); } void AddVideoTrack(const std::string& track_id, MediaStreamInterface* stream) { rtc::scoped_refptr video_track( webrtc::VideoTrack::Create(track_id, webrtc::FakeVideoTrackSource::Create(), rtc::Thread::Current())); ASSERT_TRUE(stream->AddTrack(video_track)); } std::unique_ptr CreateOfferWithOneAudioTrack() { CreatePeerConnectionWithoutDtls(); AddAudioTrack(kAudioTracks[0]); std::unique_ptr offer; EXPECT_TRUE(DoCreateOffer(&offer, nullptr)); return offer; } std::unique_ptr CreateOfferWithOneAudioStream() { CreatePeerConnectionWithoutDtls(); AddAudioStream(kStreamId1); std::unique_ptr offer; EXPECT_TRUE(DoCreateOffer(&offer, nullptr)); return offer; } std::unique_ptr CreateAnswerWithOneAudioTrack() { EXPECT_TRUE(DoSetRemoteDescription(CreateOfferWithOneAudioTrack())); std::unique_ptr answer; EXPECT_TRUE(DoCreateAnswer(&answer, nullptr)); return answer; } std::unique_ptr CreateAnswerWithOneAudioStream() { EXPECT_TRUE(DoSetRemoteDescription(CreateOfferWithOneAudioStream())); std::unique_ptr answer; EXPECT_TRUE(DoCreateAnswer(&answer, nullptr)); return answer; } const std::string& GetFirstAudioStreamCname( const SessionDescriptionInterface* desc) { const cricket::AudioContentDescription* audio_desc = cricket::GetFirstAudioContentDescription(desc->description()); return audio_desc->streams()[0].cname; } std::unique_ptr CreateOfferWithOptions( const RTCOfferAnswerOptions& offer_answer_options) { RTC_DCHECK(pc_); rtc::scoped_refptr observer( new rtc::RefCountedObject()); pc_->CreateOffer(observer, offer_answer_options); EXPECT_EQ_WAIT(true, observer->called(), kTimeout); return observer->MoveDescription(); } void CreateOfferWithOptionsAsRemoteDescription( std::unique_ptr* desc, const RTCOfferAnswerOptions& offer_answer_options) { *desc = CreateOfferWithOptions(offer_answer_options); ASSERT_TRUE(desc != nullptr); std::string sdp; EXPECT_TRUE((*desc)->ToString(&sdp)); std::unique_ptr remote_offer( webrtc::CreateSessionDescription(SdpType::kOffer, sdp)); EXPECT_TRUE(DoSetRemoteDescription(std::move(remote_offer))); EXPECT_EQ(PeerConnectionInterface::kHaveRemoteOffer, observer_.state_); } void CreateOfferWithOptionsAsLocalDescription( std::unique_ptr* desc, const RTCOfferAnswerOptions& offer_answer_options) { *desc = CreateOfferWithOptions(offer_answer_options); ASSERT_TRUE(desc != nullptr); std::string sdp; EXPECT_TRUE((*desc)->ToString(&sdp)); std::unique_ptr new_offer( webrtc::CreateSessionDescription(SdpType::kOffer, sdp)); EXPECT_TRUE(DoSetLocalDescription(std::move(new_offer))); EXPECT_EQ(PeerConnectionInterface::kHaveLocalOffer, observer_.state_); } bool HasCNCodecs(const cricket::ContentInfo* content) { RTC_DCHECK(content); RTC_DCHECK(content->media_description()); for (const cricket::AudioCodec& codec : content->media_description()->as_audio()->codecs()) { if (codec.name == "CN") { return true; } } return false; } const char* GetSdpStringWithStream1() const { if (sdp_semantics_ == SdpSemantics::kPlanB) { return kSdpStringWithStream1PlanB; } else { return kSdpStringWithStream1UnifiedPlan; } } const char* GetSdpStringWithStream1And2() const { if (sdp_semantics_ == SdpSemantics::kPlanB) { return kSdpStringWithStream1And2PlanB; } else { return kSdpStringWithStream1And2UnifiedPlan; } } std::unique_ptr vss_; rtc::AutoSocketServerThread main_; rtc::scoped_refptr fake_audio_capture_module_; cricket::FakePortAllocator* port_allocator_ = nullptr; FakeRTCCertificateGenerator* fake_certificate_generator_ = nullptr; rtc::scoped_refptr pc_factory_; rtc::scoped_refptr pc_factory_for_test_; rtc::scoped_refptr pc_; MockPeerConnectionObserver observer_; rtc::scoped_refptr reference_collection_; const SdpSemantics sdp_semantics_; }; class PeerConnectionInterfaceTest : public PeerConnectionInterfaceBaseTest, public ::testing::WithParamInterface { protected: PeerConnectionInterfaceTest() : PeerConnectionInterfaceBaseTest(GetParam()) {} }; class PeerConnectionInterfaceTestPlanB : public PeerConnectionInterfaceBaseTest { protected: PeerConnectionInterfaceTestPlanB() : PeerConnectionInterfaceBaseTest(SdpSemantics::kPlanB) {} }; // Generate different CNAMEs when PeerConnections are created. // The CNAMEs are expected to be generated randomly. It is possible // that the test fails, though the possibility is very low. TEST_P(PeerConnectionInterfaceTest, CnameGenerationInOffer) { std::unique_ptr offer1 = CreateOfferWithOneAudioTrack(); std::unique_ptr offer2 = CreateOfferWithOneAudioTrack(); EXPECT_NE(GetFirstAudioStreamCname(offer1.get()), GetFirstAudioStreamCname(offer2.get())); } TEST_P(PeerConnectionInterfaceTest, CnameGenerationInAnswer) { std::unique_ptr answer1 = CreateAnswerWithOneAudioTrack(); std::unique_ptr answer2 = CreateAnswerWithOneAudioTrack(); EXPECT_NE(GetFirstAudioStreamCname(answer1.get()), GetFirstAudioStreamCname(answer2.get())); } TEST_P(PeerConnectionInterfaceTest, CreatePeerConnectionWithDifferentConfigurations) { CreatePeerConnectionWithDifferentConfigurations(); } TEST_P(PeerConnectionInterfaceTest, CreatePeerConnectionWithDifferentIceTransportsTypes) { CreatePeerConnectionWithIceTransportsType(PeerConnectionInterface::kNone); EXPECT_EQ(cricket::CF_NONE, port_allocator_->candidate_filter()); CreatePeerConnectionWithIceTransportsType(PeerConnectionInterface::kRelay); EXPECT_EQ(cricket::CF_RELAY, port_allocator_->candidate_filter()); CreatePeerConnectionWithIceTransportsType(PeerConnectionInterface::kNoHost); EXPECT_EQ(cricket::CF_ALL & ~cricket::CF_HOST, port_allocator_->candidate_filter()); CreatePeerConnectionWithIceTransportsType(PeerConnectionInterface::kAll); EXPECT_EQ(cricket::CF_ALL, port_allocator_->candidate_filter()); } // Test that when a PeerConnection is created with a nonzero candidate pool // size, the pooled PortAllocatorSession is created with all the attributes // in the RTCConfiguration. TEST_P(PeerConnectionInterfaceTest, CreatePeerConnectionWithPooledCandidates) { PeerConnectionInterface::RTCConfiguration config; PeerConnectionInterface::IceServer server; server.uri = kStunAddressOnly; config.servers.push_back(server); config.type = PeerConnectionInterface::kRelay; config.disable_ipv6 = true; config.tcp_candidate_policy = PeerConnectionInterface::kTcpCandidatePolicyDisabled; config.candidate_network_policy = PeerConnectionInterface::kCandidateNetworkPolicyLowCost; config.ice_candidate_pool_size = 1; CreatePeerConnection(config); const cricket::FakePortAllocatorSession* session = static_cast( port_allocator_->GetPooledSession()); ASSERT_NE(nullptr, session); EXPECT_EQ(1UL, session->stun_servers().size()); EXPECT_EQ(0U, session->flags() & cricket::PORTALLOCATOR_ENABLE_IPV6); EXPECT_LT(0U, session->flags() & cricket::PORTALLOCATOR_DISABLE_TCP); EXPECT_LT(0U, session->flags() & cricket::PORTALLOCATOR_DISABLE_COSTLY_NETWORKS); } // Test that network-related RTCConfiguration members are applied to the // PortAllocator when CreatePeerConnection is called. Specifically: // - disable_ipv6_on_wifi // - max_ipv6_networks // - tcp_candidate_policy // - candidate_network_policy // - prune_turn_ports // // Note that the candidate filter (RTCConfiguration::type) is already tested // above. TEST_P(PeerConnectionInterfaceTest, CreatePeerConnectionAppliesNetworkConfigToPortAllocator) { // Create fake port allocator. std::unique_ptr port_allocator( new cricket::FakePortAllocator(rtc::Thread::Current(), nullptr)); cricket::FakePortAllocator* raw_port_allocator = port_allocator.get(); // Create RTCConfiguration with some network-related fields relevant to // PortAllocator populated. PeerConnectionInterface::RTCConfiguration config; config.disable_ipv6_on_wifi = true; config.max_ipv6_networks = 10; config.tcp_candidate_policy = PeerConnectionInterface::kTcpCandidatePolicyDisabled; config.candidate_network_policy = PeerConnectionInterface::kCandidateNetworkPolicyLowCost; config.prune_turn_ports = true; // Create the PC factory and PC with the above config. rtc::scoped_refptr pc_factory( webrtc::CreatePeerConnectionFactory( rtc::Thread::Current(), rtc::Thread::Current(), rtc::Thread::Current(), fake_audio_capture_module_, webrtc::CreateBuiltinAudioEncoderFactory(), webrtc::CreateBuiltinAudioDecoderFactory(), webrtc::CreateBuiltinVideoEncoderFactory(), webrtc::CreateBuiltinVideoDecoderFactory(), nullptr /* audio_mixer */, nullptr /* audio_processing */)); rtc::scoped_refptr pc( pc_factory->CreatePeerConnection(config, std::move(port_allocator), nullptr, &observer_)); EXPECT_TRUE(pc.get()); observer_.SetPeerConnectionInterface(pc.get()); // Now validate that the config fields set above were applied to the // PortAllocator, as flags or otherwise. EXPECT_FALSE(raw_port_allocator->flags() & cricket::PORTALLOCATOR_ENABLE_IPV6_ON_WIFI); EXPECT_EQ(10, raw_port_allocator->max_ipv6_networks()); EXPECT_TRUE(raw_port_allocator->flags() & cricket::PORTALLOCATOR_DISABLE_TCP); EXPECT_TRUE(raw_port_allocator->flags() & cricket::PORTALLOCATOR_DISABLE_COSTLY_NETWORKS); EXPECT_EQ(webrtc::PRUNE_BASED_ON_PRIORITY, raw_port_allocator->turn_port_prune_policy()); } // Check that GetConfiguration returns the configuration the PeerConnection was // constructed with, before SetConfiguration is called. TEST_P(PeerConnectionInterfaceTest, GetConfigurationAfterCreatePeerConnection) { PeerConnectionInterface::RTCConfiguration config; config.type = PeerConnectionInterface::kRelay; CreatePeerConnection(config); PeerConnectionInterface::RTCConfiguration returned_config = pc_->GetConfiguration(); EXPECT_EQ(PeerConnectionInterface::kRelay, returned_config.type); } // Check that GetConfiguration returns the last configuration passed into // SetConfiguration. TEST_P(PeerConnectionInterfaceTest, GetConfigurationAfterSetConfiguration) { PeerConnectionInterface::RTCConfiguration starting_config; starting_config.bundle_policy = webrtc::PeerConnection::kBundlePolicyMaxBundle; CreatePeerConnection(starting_config); PeerConnectionInterface::RTCConfiguration config = pc_->GetConfiguration(); config.type = PeerConnectionInterface::kRelay; EXPECT_TRUE(pc_->SetConfiguration(config).ok()); PeerConnectionInterface::RTCConfiguration returned_config = pc_->GetConfiguration(); EXPECT_EQ(PeerConnectionInterface::kRelay, returned_config.type); } TEST_P(PeerConnectionInterfaceTest, SetConfigurationFailsAfterClose) { CreatePeerConnection(); pc_->Close(); EXPECT_FALSE( pc_->SetConfiguration(PeerConnectionInterface::RTCConfiguration()).ok()); } TEST_F(PeerConnectionInterfaceTestPlanB, AddStreams) { CreatePeerConnectionWithoutDtls(); AddVideoStream(kStreamId1); AddAudioStream(kStreamId2); ASSERT_EQ(2u, pc_->local_streams()->count()); // Test we can add multiple local streams to one peerconnection. rtc::scoped_refptr stream( pc_factory_->CreateLocalMediaStream(kStreamId3)); rtc::scoped_refptr audio_track( pc_factory_->CreateAudioTrack(kStreamId3, static_cast(NULL))); stream->AddTrack(audio_track.get()); EXPECT_TRUE(pc_->AddStream(stream)); EXPECT_EQ(3u, pc_->local_streams()->count()); // Remove the third stream. pc_->RemoveStream(pc_->local_streams()->at(2)); EXPECT_EQ(2u, pc_->local_streams()->count()); // Remove the second stream. pc_->RemoveStream(pc_->local_streams()->at(1)); EXPECT_EQ(1u, pc_->local_streams()->count()); // Remove the first stream. pc_->RemoveStream(pc_->local_streams()->at(0)); EXPECT_EQ(0u, pc_->local_streams()->count()); } // Test that the created offer includes streams we added. // Don't run under Unified Plan since the stream API is not available. TEST_F(PeerConnectionInterfaceTestPlanB, AddedStreamsPresentInOffer) { CreatePeerConnectionWithoutDtls(); AddAudioVideoStream(kStreamId1, "audio_track", "video_track"); std::unique_ptr offer; ASSERT_TRUE(DoCreateOffer(&offer, nullptr)); const cricket::AudioContentDescription* audio_desc = cricket::GetFirstAudioContentDescription(offer->description()); EXPECT_TRUE(ContainsTrack(audio_desc->streams(), kStreamId1, "audio_track")); const cricket::VideoContentDescription* video_desc = cricket::GetFirstVideoContentDescription(offer->description()); EXPECT_TRUE(ContainsTrack(video_desc->streams(), kStreamId1, "video_track")); // Add another stream and ensure the offer includes both the old and new // streams. AddAudioVideoStream(kStreamId2, "audio_track2", "video_track2"); ASSERT_TRUE(DoCreateOffer(&offer, nullptr)); audio_desc = cricket::GetFirstAudioContentDescription(offer->description()); EXPECT_TRUE(ContainsTrack(audio_desc->streams(), kStreamId1, "audio_track")); EXPECT_TRUE(ContainsTrack(audio_desc->streams(), kStreamId2, "audio_track2")); video_desc = cricket::GetFirstVideoContentDescription(offer->description()); EXPECT_TRUE(ContainsTrack(video_desc->streams(), kStreamId1, "video_track")); EXPECT_TRUE(ContainsTrack(video_desc->streams(), kStreamId2, "video_track2")); } // Don't run under Unified Plan since the stream API is not available. TEST_F(PeerConnectionInterfaceTestPlanB, RemoveStream) { CreatePeerConnectionWithoutDtls(); AddVideoStream(kStreamId1); ASSERT_EQ(1u, pc_->local_streams()->count()); pc_->RemoveStream(pc_->local_streams()->at(0)); EXPECT_EQ(0u, pc_->local_streams()->count()); } // Test for AddTrack and RemoveTrack methods. // Tests that the created offer includes tracks we added, // and that the RtpSenders are created correctly. // Also tests that RemoveTrack removes the tracks from subsequent offers. // Only tested with Plan B since Unified Plan is covered in more detail by tests // in peerconnection_jsep_unittests.cc TEST_F(PeerConnectionInterfaceTestPlanB, AddTrackRemoveTrack) { CreatePeerConnectionWithoutDtls(); rtc::scoped_refptr audio_track( CreateAudioTrack("audio_track")); rtc::scoped_refptr video_track( CreateVideoTrack("video_track")); auto audio_sender = pc_->AddTrack(audio_track, {kStreamId1}).MoveValue(); auto video_sender = pc_->AddTrack(video_track, {kStreamId1}).MoveValue(); EXPECT_EQ(1UL, audio_sender->stream_ids().size()); EXPECT_EQ(kStreamId1, audio_sender->stream_ids()[0]); EXPECT_EQ("audio_track", audio_sender->id()); EXPECT_EQ(audio_track, audio_sender->track()); EXPECT_EQ(1UL, video_sender->stream_ids().size()); EXPECT_EQ(kStreamId1, video_sender->stream_ids()[0]); EXPECT_EQ("video_track", video_sender->id()); EXPECT_EQ(video_track, video_sender->track()); // Now create an offer and check for the senders. std::unique_ptr offer; ASSERT_TRUE(DoCreateOffer(&offer, nullptr)); const cricket::ContentInfo* audio_content = cricket::GetFirstAudioContent(offer->description()); EXPECT_TRUE(ContainsTrack(audio_content->media_description()->streams(), kStreamId1, "audio_track")); const cricket::ContentInfo* video_content = cricket::GetFirstVideoContent(offer->description()); EXPECT_TRUE(ContainsTrack(video_content->media_description()->streams(), kStreamId1, "video_track")); EXPECT_TRUE(DoSetLocalDescription(std::move(offer))); // Now try removing the tracks. EXPECT_TRUE(pc_->RemoveTrack(audio_sender)); EXPECT_TRUE(pc_->RemoveTrack(video_sender)); // Create a new offer and ensure it doesn't contain the removed senders. ASSERT_TRUE(DoCreateOffer(&offer, nullptr)); audio_content = cricket::GetFirstAudioContent(offer->description()); EXPECT_FALSE(ContainsTrack(audio_content->media_description()->streams(), kStreamId1, "audio_track")); video_content = cricket::GetFirstVideoContent(offer->description()); EXPECT_FALSE(ContainsTrack(video_content->media_description()->streams(), kStreamId1, "video_track")); EXPECT_TRUE(DoSetLocalDescription(std::move(offer))); // Calling RemoveTrack on a sender no longer attached to a PeerConnection // should return false. EXPECT_FALSE(pc_->RemoveTrack(audio_sender)); EXPECT_FALSE(pc_->RemoveTrack(video_sender)); } // Test creating senders without a stream specified, // expecting a random stream ID to be generated. TEST_P(PeerConnectionInterfaceTest, AddTrackWithoutStream) { CreatePeerConnectionWithoutDtls(); rtc::scoped_refptr audio_track( CreateAudioTrack("audio_track")); rtc::scoped_refptr video_track( CreateVideoTrack("video_track")); auto audio_sender = pc_->AddTrack(audio_track, std::vector()).MoveValue(); auto video_sender = pc_->AddTrack(video_track, std::vector()).MoveValue(); EXPECT_EQ("audio_track", audio_sender->id()); EXPECT_EQ(audio_track, audio_sender->track()); EXPECT_EQ("video_track", video_sender->id()); EXPECT_EQ(video_track, video_sender->track()); if (sdp_semantics_ == SdpSemantics::kPlanB) { // If the ID is truly a random GUID, it should be infinitely unlikely they // will be the same. EXPECT_NE(video_sender->stream_ids(), audio_sender->stream_ids()); } else { // We allows creating tracks without stream ids under Unified Plan // semantics. EXPECT_EQ(0u, video_sender->stream_ids().size()); EXPECT_EQ(0u, audio_sender->stream_ids().size()); } } // Test that we can call GetStats() after AddTrack but before connecting // the PeerConnection to a peer. TEST_P(PeerConnectionInterfaceTest, AddTrackBeforeConnecting) { CreatePeerConnectionWithoutDtls(); rtc::scoped_refptr audio_track( CreateAudioTrack("audio_track")); rtc::scoped_refptr video_track( CreateVideoTrack("video_track")); auto audio_sender = pc_->AddTrack(audio_track, std::vector()); auto video_sender = pc_->AddTrack(video_track, std::vector()); EXPECT_TRUE(DoGetStats(nullptr)); } TEST_P(PeerConnectionInterfaceTest, AttachmentIdIsSetOnAddTrack) { CreatePeerConnectionWithoutDtls(); rtc::scoped_refptr audio_track( CreateAudioTrack("audio_track")); rtc::scoped_refptr video_track( CreateVideoTrack("video_track")); auto audio_sender = pc_->AddTrack(audio_track, std::vector()); ASSERT_TRUE(audio_sender.ok()); auto* audio_sender_proxy = static_cast*>( audio_sender.value().get()); EXPECT_NE(0, audio_sender_proxy->internal()->AttachmentId()); auto video_sender = pc_->AddTrack(video_track, std::vector()); ASSERT_TRUE(video_sender.ok()); auto* video_sender_proxy = static_cast*>( video_sender.value().get()); EXPECT_NE(0, video_sender_proxy->internal()->AttachmentId()); } // Don't run under Unified Plan since the stream API is not available. TEST_F(PeerConnectionInterfaceTestPlanB, AttachmentIdIsSetOnAddStream) { CreatePeerConnectionWithoutDtls(); AddVideoStream(kStreamId1); auto senders = pc_->GetSenders(); ASSERT_EQ(1u, senders.size()); auto* sender_proxy = static_cast*>( senders[0].get()); EXPECT_NE(0, sender_proxy->internal()->AttachmentId()); } TEST_P(PeerConnectionInterfaceTest, CreateOfferReceiveAnswer) { InitiateCall(); WaitAndVerifyOnAddStream(kStreamId1, 2); VerifyRemoteRtpHeaderExtensions(); } TEST_P(PeerConnectionInterfaceTest, CreateOfferReceivePrAnswerAndAnswer) { CreatePeerConnectionWithoutDtls(); AddVideoTrack(kVideoTracks[0], {kStreamId1}); CreateOfferAsLocalDescription(); std::string offer; EXPECT_TRUE(pc_->local_description()->ToString(&offer)); CreatePrAnswerAndAnswerAsRemoteDescription(offer); WaitAndVerifyOnAddStream(kStreamId1, 1); } TEST_P(PeerConnectionInterfaceTest, ReceiveOfferCreateAnswer) { CreatePeerConnectionWithoutDtls(); AddVideoTrack(kVideoTracks[0], {kStreamId1}); CreateOfferAsRemoteDescription(); CreateAnswerAsLocalDescription(); WaitAndVerifyOnAddStream(kStreamId1, 1); } TEST_P(PeerConnectionInterfaceTest, ReceiveOfferCreatePrAnswerAndAnswer) { CreatePeerConnectionWithoutDtls(); AddVideoTrack(kVideoTracks[0], {kStreamId1}); CreateOfferAsRemoteDescription(); CreatePrAnswerAsLocalDescription(); CreateAnswerAsLocalDescription(); WaitAndVerifyOnAddStream(kStreamId1, 1); } // Don't run under Unified Plan since the stream API is not available. TEST_F(PeerConnectionInterfaceTestPlanB, Renegotiate) { InitiateCall(); ASSERT_EQ(1u, pc_->remote_streams()->count()); pc_->RemoveStream(pc_->local_streams()->at(0)); CreateOfferReceiveAnswer(); EXPECT_EQ(0u, pc_->remote_streams()->count()); AddVideoStream(kStreamId1); CreateOfferReceiveAnswer(); } // Tests that after negotiating an audio only call, the respondent can perform a // renegotiation that removes the audio stream. TEST_F(PeerConnectionInterfaceTestPlanB, RenegotiateAudioOnly) { CreatePeerConnectionWithoutDtls(); AddAudioStream(kStreamId1); CreateOfferAsRemoteDescription(); CreateAnswerAsLocalDescription(); ASSERT_EQ(1u, pc_->remote_streams()->count()); pc_->RemoveStream(pc_->local_streams()->at(0)); CreateOfferReceiveAnswer(); EXPECT_EQ(0u, pc_->remote_streams()->count()); } // Test that candidates are generated and that we can parse our own candidates. TEST_P(PeerConnectionInterfaceTest, IceCandidates) { CreatePeerConnectionWithoutDtls(); EXPECT_FALSE(pc_->AddIceCandidate(observer_.last_candidate())); // SetRemoteDescription takes ownership of offer. std::unique_ptr offer; AddVideoTrack(kVideoTracks[0]); EXPECT_TRUE(DoCreateOffer(&offer, nullptr)); EXPECT_TRUE(DoSetRemoteDescription(std::move(offer))); // SetLocalDescription takes ownership of answer. std::unique_ptr answer; EXPECT_TRUE(DoCreateAnswer(&answer, nullptr)); EXPECT_TRUE(DoSetLocalDescription(std::move(answer))); EXPECT_TRUE_WAIT(observer_.last_candidate() != nullptr, kTimeout); EXPECT_TRUE_WAIT(observer_.ice_gathering_complete_, kTimeout); EXPECT_TRUE(pc_->AddIceCandidate(observer_.last_candidate())); } // Test that CreateOffer and CreateAnswer will fail if the track labels are // not unique. TEST_F(PeerConnectionInterfaceTestPlanB, CreateOfferAnswerWithInvalidStream) { CreatePeerConnectionWithoutDtls(); // Create a regular offer for the CreateAnswer test later. std::unique_ptr offer; EXPECT_TRUE(DoCreateOffer(&offer, nullptr)); EXPECT_TRUE(offer); offer.reset(); // Create a local stream with audio&video tracks having same label. AddAudioTrack("track_label", {kStreamId1}); AddVideoTrack("track_label", {kStreamId1}); // Test CreateOffer EXPECT_FALSE(DoCreateOffer(&offer, nullptr)); // Test CreateAnswer std::unique_ptr answer; EXPECT_FALSE(DoCreateAnswer(&answer, nullptr)); } // Test that we will get different SSRCs for each tracks in the offer and answer // we created. TEST_P(PeerConnectionInterfaceTest, SsrcInOfferAnswer) { CreatePeerConnectionWithoutDtls(); // Create a local stream with audio&video tracks having different labels. AddAudioTrack(kAudioTracks[0], {kStreamId1}); AddVideoTrack(kVideoTracks[0], {kStreamId1}); // Test CreateOffer std::unique_ptr offer; ASSERT_TRUE(DoCreateOffer(&offer, nullptr)); int audio_ssrc = 0; int video_ssrc = 0; EXPECT_TRUE( GetFirstSsrc(GetFirstAudioContent(offer->description()), &audio_ssrc)); EXPECT_TRUE( GetFirstSsrc(GetFirstVideoContent(offer->description()), &video_ssrc)); EXPECT_NE(audio_ssrc, video_ssrc); // Test CreateAnswer EXPECT_TRUE(DoSetRemoteDescription(std::move(offer))); std::unique_ptr answer; ASSERT_TRUE(DoCreateAnswer(&answer, nullptr)); audio_ssrc = 0; video_ssrc = 0; EXPECT_TRUE( GetFirstSsrc(GetFirstAudioContent(answer->description()), &audio_ssrc)); EXPECT_TRUE( GetFirstSsrc(GetFirstVideoContent(answer->description()), &video_ssrc)); EXPECT_NE(audio_ssrc, video_ssrc); } // Test that it's possible to call AddTrack on a MediaStream after adding // the stream to a PeerConnection. // TODO(deadbeef): Remove this test once this behavior is no longer supported. // Don't run under Unified Plan since the stream API is not available. TEST_F(PeerConnectionInterfaceTestPlanB, AddTrackAfterAddStream) { CreatePeerConnectionWithoutDtls(); // Create audio stream and add to PeerConnection. AddAudioStream(kStreamId1); MediaStreamInterface* stream = pc_->local_streams()->at(0); // Add video track to the audio-only stream. rtc::scoped_refptr video_track( CreateVideoTrack("video_label")); stream->AddTrack(video_track.get()); std::unique_ptr offer; ASSERT_TRUE(DoCreateOffer(&offer, nullptr)); const cricket::MediaContentDescription* video_desc = cricket::GetFirstVideoContentDescription(offer->description()); EXPECT_TRUE(video_desc != nullptr); } // Test that it's possible to call RemoveTrack on a MediaStream after adding // the stream to a PeerConnection. // TODO(deadbeef): Remove this test once this behavior is no longer supported. // Don't run under Unified Plan since the stream API is not available. TEST_F(PeerConnectionInterfaceTestPlanB, RemoveTrackAfterAddStream) { CreatePeerConnectionWithoutDtls(); // Create audio/video stream and add to PeerConnection. AddAudioVideoStream(kStreamId1, "audio_label", "video_label"); MediaStreamInterface* stream = pc_->local_streams()->at(0); // Remove the video track. stream->RemoveTrack(stream->GetVideoTracks()[0]); std::unique_ptr offer; ASSERT_TRUE(DoCreateOffer(&offer, nullptr)); const cricket::MediaContentDescription* video_desc = cricket::GetFirstVideoContentDescription(offer->description()); EXPECT_TRUE(video_desc == nullptr); } // Test creating a sender with a stream ID, and ensure the ID is populated // in the offer. // Don't run under Unified Plan since the stream API is not available. TEST_F(PeerConnectionInterfaceTestPlanB, CreateSenderWithStream) { CreatePeerConnectionWithoutDtls(); pc_->CreateSender("video", kStreamId1); std::unique_ptr offer; ASSERT_TRUE(DoCreateOffer(&offer, nullptr)); const cricket::MediaContentDescription* video_desc = cricket::GetFirstVideoContentDescription(offer->description()); ASSERT_TRUE(video_desc != nullptr); ASSERT_EQ(1u, video_desc->streams().size()); EXPECT_EQ(kStreamId1, video_desc->streams()[0].first_stream_id()); } // Test that we can specify a certain track that we want statistics about. TEST_P(PeerConnectionInterfaceTest, GetStatsForSpecificTrack) { InitiateCall(); ASSERT_LT(0u, pc_->GetSenders().size()); ASSERT_LT(0u, pc_->GetReceivers().size()); rtc::scoped_refptr remote_audio = pc_->GetReceivers()[0]->track(); EXPECT_TRUE(DoGetStats(remote_audio)); // Remove the stream. Since we are sending to our selves the local // and the remote stream is the same. pc_->RemoveTrack(pc_->GetSenders()[0]); // Do a re-negotiation. CreateOfferReceiveAnswer(); // Test that we still can get statistics for the old track. Even if it is not // sent any longer. EXPECT_TRUE(DoGetStats(remote_audio)); } // Test that we can get stats on a video track. TEST_P(PeerConnectionInterfaceTest, GetStatsForVideoTrack) { InitiateCall(); auto video_receiver = GetFirstReceiverOfType(cricket::MEDIA_TYPE_VIDEO); ASSERT_TRUE(video_receiver); EXPECT_TRUE(DoGetStats(video_receiver->track())); } // Test that we don't get statistics for an invalid track. TEST_P(PeerConnectionInterfaceTest, GetStatsForInvalidTrack) { InitiateCall(); rtc::scoped_refptr unknown_audio_track( pc_factory_->CreateAudioTrack("unknown track", NULL)); EXPECT_FALSE(DoGetStats(unknown_audio_track)); } TEST_P(PeerConnectionInterfaceTest, GetRTCStatsBeforeAndAfterCalling) { CreatePeerConnectionWithoutDtls(); EXPECT_TRUE(DoGetRTCStats()); // Clearing stats cache is needed now, but should be temporary. // https://bugs.chromium.org/p/webrtc/issues/detail?id=8693 pc_->ClearStatsCache(); AddAudioTrack(kAudioTracks[0], {kStreamId1}); AddVideoTrack(kVideoTracks[0], {kStreamId1}); EXPECT_TRUE(DoGetRTCStats()); pc_->ClearStatsCache(); CreateOfferReceiveAnswer(); EXPECT_TRUE(DoGetRTCStats()); } // This test setup two RTP data channels in loop back. TEST_P(PeerConnectionInterfaceTest, TestDataChannel) { RTCConfiguration config; config.enable_rtp_data_channel = true; config.enable_dtls_srtp = false; CreatePeerConnection(config); rtc::scoped_refptr data1 = pc_->CreateDataChannel("test1", NULL); rtc::scoped_refptr data2 = pc_->CreateDataChannel("test2", NULL); ASSERT_TRUE(data1 != NULL); std::unique_ptr observer1( new MockDataChannelObserver(data1)); std::unique_ptr observer2( new MockDataChannelObserver(data2)); EXPECT_EQ(DataChannelInterface::kConnecting, data1->state()); EXPECT_EQ(DataChannelInterface::kConnecting, data2->state()); std::string data_to_send1 = "testing testing"; std::string data_to_send2 = "testing something else"; EXPECT_FALSE(data1->Send(DataBuffer(data_to_send1))); CreateOfferReceiveAnswer(); EXPECT_TRUE_WAIT(observer1->IsOpen(), kTimeout); EXPECT_TRUE_WAIT(observer2->IsOpen(), kTimeout); EXPECT_EQ(DataChannelInterface::kOpen, data1->state()); EXPECT_EQ(DataChannelInterface::kOpen, data2->state()); EXPECT_TRUE(data1->Send(DataBuffer(data_to_send1))); EXPECT_TRUE(data2->Send(DataBuffer(data_to_send2))); EXPECT_EQ_WAIT(data_to_send1, observer1->last_message(), kTimeout); EXPECT_EQ_WAIT(data_to_send2, observer2->last_message(), kTimeout); data1->Close(); EXPECT_EQ(DataChannelInterface::kClosing, data1->state()); CreateOfferReceiveAnswer(); EXPECT_FALSE(observer1->IsOpen()); EXPECT_EQ(DataChannelInterface::kClosed, data1->state()); EXPECT_TRUE(observer2->IsOpen()); data_to_send2 = "testing something else again"; EXPECT_TRUE(data2->Send(DataBuffer(data_to_send2))); EXPECT_EQ_WAIT(data_to_send2, observer2->last_message(), kTimeout); } // This test verifies that sendnig binary data over RTP data channels should // fail. TEST_P(PeerConnectionInterfaceTest, TestSendBinaryOnRtpDataChannel) { RTCConfiguration config; config.enable_rtp_data_channel = true; config.enable_dtls_srtp = false; CreatePeerConnection(config); rtc::scoped_refptr data1 = pc_->CreateDataChannel("test1", NULL); rtc::scoped_refptr data2 = pc_->CreateDataChannel("test2", NULL); ASSERT_TRUE(data1 != NULL); std::unique_ptr observer1( new MockDataChannelObserver(data1)); std::unique_ptr observer2( new MockDataChannelObserver(data2)); EXPECT_EQ(DataChannelInterface::kConnecting, data1->state()); EXPECT_EQ(DataChannelInterface::kConnecting, data2->state()); CreateOfferReceiveAnswer(); EXPECT_TRUE_WAIT(observer1->IsOpen(), kTimeout); EXPECT_TRUE_WAIT(observer2->IsOpen(), kTimeout); EXPECT_EQ(DataChannelInterface::kOpen, data1->state()); EXPECT_EQ(DataChannelInterface::kOpen, data2->state()); rtc::CopyOnWriteBuffer buffer("test", 4); EXPECT_FALSE(data1->Send(DataBuffer(buffer, true))); } // This test setup a RTP data channels in loop back and test that a channel is // opened even if the remote end answer with a zero SSRC. TEST_P(PeerConnectionInterfaceTest, TestSendOnlyDataChannel) { RTCConfiguration config; config.enable_rtp_data_channel = true; config.enable_dtls_srtp = false; CreatePeerConnection(config); rtc::scoped_refptr data1 = pc_->CreateDataChannel("test1", NULL); std::unique_ptr observer1( new MockDataChannelObserver(data1)); CreateOfferReceiveAnswerWithoutSsrc(); EXPECT_TRUE_WAIT(observer1->IsOpen(), kTimeout); data1->Close(); EXPECT_EQ(DataChannelInterface::kClosing, data1->state()); CreateOfferReceiveAnswerWithoutSsrc(); EXPECT_EQ(DataChannelInterface::kClosed, data1->state()); EXPECT_FALSE(observer1->IsOpen()); } // This test that if a data channel is added in an answer a receive only channel // channel is created. TEST_P(PeerConnectionInterfaceTest, TestReceiveOnlyDataChannel) { RTCConfiguration config; config.enable_rtp_data_channel = true; config.enable_dtls_srtp = false; CreatePeerConnection(config); std::string offer_label = "offer_channel"; rtc::scoped_refptr offer_channel = pc_->CreateDataChannel(offer_label, NULL); CreateOfferAsLocalDescription(); // Replace the data channel label in the offer and apply it as an answer. std::string receive_label = "answer_channel"; std::string sdp; EXPECT_TRUE(pc_->local_description()->ToString(&sdp)); absl::StrReplaceAll({{offer_label, receive_label}}, &sdp); CreateAnswerAsRemoteDescription(sdp); // Verify that a new incoming data channel has been created and that // it is open but can't we written to. ASSERT_TRUE(observer_.last_datachannel_ != NULL); DataChannelInterface* received_channel = observer_.last_datachannel_; EXPECT_EQ(DataChannelInterface::kConnecting, received_channel->state()); EXPECT_EQ(receive_label, received_channel->label()); EXPECT_FALSE(received_channel->Send(DataBuffer("something"))); // Verify that the channel we initially offered has been rejected. EXPECT_EQ(DataChannelInterface::kClosed, offer_channel->state()); // Do another offer / answer exchange and verify that the data channel is // opened. CreateOfferReceiveAnswer(); EXPECT_EQ_WAIT(DataChannelInterface::kOpen, received_channel->state(), kTimeout); } // This test that no data channel is returned if a reliable channel is // requested. // TODO(perkj): Remove this test once reliable channels are implemented. TEST_P(PeerConnectionInterfaceTest, CreateReliableRtpDataChannelShouldFail) { RTCConfiguration rtc_config; rtc_config.enable_rtp_data_channel = true; CreatePeerConnection(rtc_config); std::string label = "test"; webrtc::DataChannelInit config; config.reliable = true; rtc::scoped_refptr channel = pc_->CreateDataChannel(label, &config); EXPECT_TRUE(channel == NULL); } // Verifies that duplicated label is not allowed for RTP data channel. TEST_P(PeerConnectionInterfaceTest, RtpDuplicatedLabelNotAllowed) { RTCConfiguration config; config.enable_rtp_data_channel = true; CreatePeerConnection(config); std::string label = "test"; rtc::scoped_refptr channel = pc_->CreateDataChannel(label, nullptr); EXPECT_NE(channel, nullptr); rtc::scoped_refptr dup_channel = pc_->CreateDataChannel(label, nullptr); EXPECT_EQ(dup_channel, nullptr); } // This tests that a SCTP data channel is returned using different // DataChannelInit configurations. TEST_P(PeerConnectionInterfaceTest, CreateSctpDataChannel) { RTCConfiguration rtc_config; rtc_config.enable_dtls_srtp = true; CreatePeerConnection(rtc_config); webrtc::DataChannelInit config; rtc::scoped_refptr channel = pc_->CreateDataChannel("1", &config); EXPECT_TRUE(channel != NULL); EXPECT_TRUE(channel->reliable()); EXPECT_TRUE(observer_.renegotiation_needed_); observer_.renegotiation_needed_ = false; config.ordered = false; channel = pc_->CreateDataChannel("2", &config); EXPECT_TRUE(channel != NULL); EXPECT_TRUE(channel->reliable()); EXPECT_FALSE(observer_.renegotiation_needed_); config.ordered = true; config.maxRetransmits = 0; channel = pc_->CreateDataChannel("3", &config); EXPECT_TRUE(channel != NULL); EXPECT_FALSE(channel->reliable()); EXPECT_FALSE(observer_.renegotiation_needed_); config.maxRetransmits = absl::nullopt; config.maxRetransmitTime = 0; channel = pc_->CreateDataChannel("4", &config); EXPECT_TRUE(channel != NULL); EXPECT_FALSE(channel->reliable()); EXPECT_FALSE(observer_.renegotiation_needed_); } // For backwards compatibility, we want people who "unset" maxRetransmits // and maxRetransmitTime by setting them to -1 to get what they want. TEST_P(PeerConnectionInterfaceTest, CreateSctpDataChannelWithMinusOne) { RTCConfiguration rtc_config; rtc_config.enable_dtls_srtp = true; CreatePeerConnection(rtc_config); webrtc::DataChannelInit config; config.maxRetransmitTime = -1; config.maxRetransmits = -1; rtc::scoped_refptr channel = pc_->CreateDataChannel("1", &config); EXPECT_TRUE(channel != NULL); } // This tests that no data channel is returned if both maxRetransmits and // maxRetransmitTime are set for SCTP data channels. TEST_P(PeerConnectionInterfaceTest, CreateSctpDataChannelShouldFailForInvalidConfig) { RTCConfiguration rtc_config; rtc_config.enable_dtls_srtp = true; CreatePeerConnection(rtc_config); std::string label = "test"; webrtc::DataChannelInit config; config.maxRetransmits = 0; config.maxRetransmitTime = 0; rtc::scoped_refptr channel = pc_->CreateDataChannel(label, &config); EXPECT_TRUE(channel == NULL); } // The test verifies that creating a SCTP data channel with an id already in use // or out of range should fail. TEST_P(PeerConnectionInterfaceTest, CreateSctpDataChannelWithInvalidIdShouldFail) { RTCConfiguration rtc_config; rtc_config.enable_dtls_srtp = true; CreatePeerConnection(rtc_config); webrtc::DataChannelInit config; rtc::scoped_refptr channel; config.id = 1; config.negotiated = true; channel = pc_->CreateDataChannel("1", &config); EXPECT_TRUE(channel != NULL); EXPECT_EQ(1, channel->id()); channel = pc_->CreateDataChannel("x", &config); EXPECT_TRUE(channel == NULL); config.id = cricket::kMaxSctpSid; config.negotiated = true; channel = pc_->CreateDataChannel("max", &config); EXPECT_TRUE(channel != NULL); EXPECT_EQ(config.id, channel->id()); config.id = cricket::kMaxSctpSid + 1; config.negotiated = true; channel = pc_->CreateDataChannel("x", &config); EXPECT_TRUE(channel == NULL); } // Verifies that duplicated label is allowed for SCTP data channel. TEST_P(PeerConnectionInterfaceTest, SctpDuplicatedLabelAllowed) { RTCConfiguration rtc_config; rtc_config.enable_dtls_srtp = true; CreatePeerConnection(rtc_config); std::string label = "test"; rtc::scoped_refptr channel = pc_->CreateDataChannel(label, nullptr); EXPECT_NE(channel, nullptr); rtc::scoped_refptr dup_channel = pc_->CreateDataChannel(label, nullptr); EXPECT_NE(dup_channel, nullptr); } // This test verifies that OnRenegotiationNeeded is fired for every new RTP // DataChannel. TEST_P(PeerConnectionInterfaceTest, RenegotiationNeededForNewRtpDataChannel) { RTCConfiguration rtc_config; rtc_config.enable_rtp_data_channel = true; rtc_config.enable_dtls_srtp = false; CreatePeerConnection(rtc_config); rtc::scoped_refptr dc1 = pc_->CreateDataChannel("test1", NULL); EXPECT_TRUE(observer_.renegotiation_needed_); observer_.renegotiation_needed_ = false; CreateOfferReceiveAnswer(); rtc::scoped_refptr dc2 = pc_->CreateDataChannel("test2", NULL); EXPECT_EQ(observer_.renegotiation_needed_, GetParam() == SdpSemantics::kPlanB); } // This test that a data channel closes when a PeerConnection is deleted/closed. TEST_P(PeerConnectionInterfaceTest, DataChannelCloseWhenPeerConnectionClose) { RTCConfiguration rtc_config; rtc_config.enable_rtp_data_channel = true; rtc_config.enable_dtls_srtp = false; CreatePeerConnection(rtc_config); rtc::scoped_refptr data1 = pc_->CreateDataChannel("test1", NULL); rtc::scoped_refptr data2 = pc_->CreateDataChannel("test2", NULL); ASSERT_TRUE(data1 != NULL); std::unique_ptr observer1( new MockDataChannelObserver(data1)); std::unique_ptr observer2( new MockDataChannelObserver(data2)); CreateOfferReceiveAnswer(); EXPECT_TRUE_WAIT(observer1->IsOpen(), kTimeout); EXPECT_TRUE_WAIT(observer2->IsOpen(), kTimeout); ReleasePeerConnection(); EXPECT_EQ(DataChannelInterface::kClosed, data1->state()); EXPECT_EQ(DataChannelInterface::kClosed, data2->state()); } // This tests that RTP data channels can be rejected in an answer. TEST_P(PeerConnectionInterfaceTest, TestRejectRtpDataChannelInAnswer) { RTCConfiguration rtc_config; rtc_config.enable_rtp_data_channel = true; rtc_config.enable_dtls_srtp = false; CreatePeerConnection(rtc_config); rtc::scoped_refptr offer_channel( pc_->CreateDataChannel("offer_channel", NULL)); CreateOfferAsLocalDescription(); // Create an answer where the m-line for data channels are rejected. std::string sdp; EXPECT_TRUE(pc_->local_description()->ToString(&sdp)); std::unique_ptr answer( webrtc::CreateSessionDescription(SdpType::kAnswer, sdp)); ASSERT_TRUE(answer); cricket::ContentInfo* data_info = cricket::GetFirstDataContent(answer->description()); data_info->rejected = true; DoSetRemoteDescription(std::move(answer)); EXPECT_EQ(DataChannelInterface::kClosed, offer_channel->state()); } #ifdef HAVE_SCTP // This tests that SCTP data channels can be rejected in an answer. TEST_P(PeerConnectionInterfaceTest, TestRejectSctpDataChannelInAnswer) #else TEST_P(PeerConnectionInterfaceTest, DISABLED_TestRejectSctpDataChannelInAnswer) #endif { RTCConfiguration rtc_config; CreatePeerConnection(rtc_config); rtc::scoped_refptr offer_channel( pc_->CreateDataChannel("offer_channel", NULL)); CreateOfferAsLocalDescription(); // Create an answer where the m-line for data channels are rejected. std::string sdp; EXPECT_TRUE(pc_->local_description()->ToString(&sdp)); std::unique_ptr answer( webrtc::CreateSessionDescription(SdpType::kAnswer, sdp)); ASSERT_TRUE(answer); cricket::ContentInfo* data_info = cricket::GetFirstDataContent(answer->description()); data_info->rejected = true; DoSetRemoteDescription(std::move(answer)); EXPECT_EQ(DataChannelInterface::kClosed, offer_channel->state()); } // Test that we can create a session description from an SDP string from // FireFox, use it as a remote session description, generate an answer and use // the answer as a local description. TEST_P(PeerConnectionInterfaceTest, ReceiveFireFoxOffer) { RTCConfiguration rtc_config; rtc_config.enable_dtls_srtp = true; CreatePeerConnection(rtc_config); AddAudioTrack("audio_label"); AddVideoTrack("video_label"); std::unique_ptr desc( webrtc::CreateSessionDescription(SdpType::kOffer, webrtc::kFireFoxSdpOffer, nullptr)); EXPECT_TRUE(DoSetSessionDescription(std::move(desc), false)); CreateAnswerAsLocalDescription(); ASSERT_TRUE(pc_->local_description() != NULL); ASSERT_TRUE(pc_->remote_description() != NULL); const cricket::ContentInfo* content = cricket::GetFirstAudioContent(pc_->local_description()->description()); ASSERT_TRUE(content != NULL); EXPECT_FALSE(content->rejected); content = cricket::GetFirstVideoContent(pc_->local_description()->description()); ASSERT_TRUE(content != NULL); EXPECT_FALSE(content->rejected); #ifdef HAVE_SCTP content = cricket::GetFirstDataContent(pc_->local_description()->description()); ASSERT_TRUE(content != NULL); EXPECT_FALSE(content->rejected); #endif } // Test that fallback from DTLS to SDES is not supported. // The fallback was previously supported but was removed to simplify the code // and because it's non-standard. TEST_P(PeerConnectionInterfaceTest, DtlsSdesFallbackNotSupported) { RTCConfiguration rtc_config; rtc_config.enable_dtls_srtp = true; CreatePeerConnection(rtc_config); // Wait for fake certificate to be generated. Previously, this is what caused // the "a=crypto" lines to be rejected. AddAudioTrack("audio_label"); AddVideoTrack("video_label"); ASSERT_NE(nullptr, fake_certificate_generator_); EXPECT_EQ_WAIT(1, fake_certificate_generator_->generated_certificates(), kTimeout); std::unique_ptr desc( webrtc::CreateSessionDescription(SdpType::kOffer, kDtlsSdesFallbackSdp, nullptr)); EXPECT_FALSE(DoSetSessionDescription(std::move(desc), /*local=*/false)); } // Test that we can create an audio only offer and receive an answer with a // limited set of audio codecs and receive an updated offer with more audio // codecs, where the added codecs are not supported. TEST_P(PeerConnectionInterfaceTest, ReceiveUpdatedAudioOfferWithBadCodecs) { CreatePeerConnectionWithoutDtls(); AddAudioTrack("audio_label"); CreateOfferAsLocalDescription(); const char* answer_sdp = (sdp_semantics_ == SdpSemantics::kPlanB ? webrtc::kAudioSdpPlanB : webrtc::kAudioSdpUnifiedPlan); std::unique_ptr answer( webrtc::CreateSessionDescription(SdpType::kAnswer, answer_sdp, nullptr)); EXPECT_TRUE(DoSetSessionDescription(std::move(answer), false)); const char* reoffer_sdp = (sdp_semantics_ == SdpSemantics::kPlanB ? webrtc::kAudioSdpWithUnsupportedCodecsPlanB : webrtc::kAudioSdpWithUnsupportedCodecsUnifiedPlan); std::unique_ptr updated_offer( webrtc::CreateSessionDescription(SdpType::kOffer, reoffer_sdp, nullptr)); EXPECT_TRUE(DoSetSessionDescription(std::move(updated_offer), false)); CreateAnswerAsLocalDescription(); } // Test that if we're receiving (but not sending) a track, subsequent offers // will have m-lines with a=recvonly. TEST_P(PeerConnectionInterfaceTest, CreateSubsequentRecvOnlyOffer) { RTCConfiguration rtc_config; rtc_config.enable_dtls_srtp = true; CreatePeerConnection(rtc_config); CreateAndSetRemoteOffer(GetSdpStringWithStream1()); CreateAnswerAsLocalDescription(); // At this point we should be receiving stream 1, but not sending anything. // A new offer should be recvonly. std::unique_ptr offer; DoCreateOffer(&offer, nullptr); const cricket::ContentInfo* video_content = cricket::GetFirstVideoContent(offer->description()); ASSERT_EQ(RtpTransceiverDirection::kRecvOnly, video_content->media_description()->direction()); const cricket::ContentInfo* audio_content = cricket::GetFirstAudioContent(offer->description()); ASSERT_EQ(RtpTransceiverDirection::kRecvOnly, audio_content->media_description()->direction()); } // Test that if we're receiving (but not sending) a track, and the // offerToReceiveVideo/offerToReceiveAudio constraints are explicitly set to // false, the generated m-lines will be a=inactive. TEST_P(PeerConnectionInterfaceTest, CreateSubsequentInactiveOffer) { RTCConfiguration rtc_config; rtc_config.enable_dtls_srtp = true; CreatePeerConnection(rtc_config); CreateAndSetRemoteOffer(GetSdpStringWithStream1()); CreateAnswerAsLocalDescription(); // At this point we should be receiving stream 1, but not sending anything. // A new offer would be recvonly, but we'll set the "no receive" constraints // to make it inactive. std::unique_ptr offer; RTCOfferAnswerOptions options; options.offer_to_receive_audio = 0; options.offer_to_receive_video = 0; DoCreateOffer(&offer, &options); const cricket::ContentInfo* video_content = cricket::GetFirstVideoContent(offer->description()); ASSERT_EQ(RtpTransceiverDirection::kInactive, video_content->media_description()->direction()); const cricket::ContentInfo* audio_content = cricket::GetFirstAudioContent(offer->description()); ASSERT_EQ(RtpTransceiverDirection::kInactive, audio_content->media_description()->direction()); } // Test that we can use SetConfiguration to change the ICE servers of the // PortAllocator. TEST_P(PeerConnectionInterfaceTest, SetConfigurationChangesIceServers) { CreatePeerConnection(); PeerConnectionInterface::RTCConfiguration config = pc_->GetConfiguration(); PeerConnectionInterface::IceServer server; server.uri = "stun:test_hostname"; config.servers.push_back(server); EXPECT_TRUE(pc_->SetConfiguration(config).ok()); EXPECT_EQ(1u, port_allocator_->stun_servers().size()); EXPECT_EQ("test_hostname", port_allocator_->stun_servers().begin()->hostname()); } TEST_P(PeerConnectionInterfaceTest, SetConfigurationChangesCandidateFilter) { CreatePeerConnection(); PeerConnectionInterface::RTCConfiguration config = pc_->GetConfiguration(); config.type = PeerConnectionInterface::kRelay; EXPECT_TRUE(pc_->SetConfiguration(config).ok()); EXPECT_EQ(cricket::CF_RELAY, port_allocator_->candidate_filter()); } TEST_P(PeerConnectionInterfaceTest, SetConfigurationChangesPruneTurnPortsFlag) { PeerConnectionInterface::RTCConfiguration config; config.prune_turn_ports = false; CreatePeerConnection(config); config = pc_->GetConfiguration(); EXPECT_EQ(webrtc::NO_PRUNE, port_allocator_->turn_port_prune_policy()); config.prune_turn_ports = true; EXPECT_TRUE(pc_->SetConfiguration(config).ok()); EXPECT_EQ(webrtc::PRUNE_BASED_ON_PRIORITY, port_allocator_->turn_port_prune_policy()); } // Test that the ice check interval can be changed. This does not verify that // the setting makes it all the way to P2PTransportChannel, as that would // require a very complex set of mocks. TEST_P(PeerConnectionInterfaceTest, SetConfigurationChangesIceCheckInterval) { PeerConnectionInterface::RTCConfiguration config; config.ice_check_min_interval = absl::nullopt; CreatePeerConnection(config); config = pc_->GetConfiguration(); config.ice_check_min_interval = 100; EXPECT_TRUE(pc_->SetConfiguration(config).ok()); config = pc_->GetConfiguration(); EXPECT_EQ(config.ice_check_min_interval, 100); } TEST_P(PeerConnectionInterfaceTest, SetConfigurationChangesSurfaceIceCandidatesOnIceTransportTypeChanged) { PeerConnectionInterface::RTCConfiguration config; config.surface_ice_candidates_on_ice_transport_type_changed = false; CreatePeerConnection(config); config = pc_->GetConfiguration(); EXPECT_FALSE(config.surface_ice_candidates_on_ice_transport_type_changed); config.surface_ice_candidates_on_ice_transport_type_changed = true; EXPECT_TRUE(pc_->SetConfiguration(config).ok()); config = pc_->GetConfiguration(); EXPECT_TRUE(config.surface_ice_candidates_on_ice_transport_type_changed); } // Test that when SetConfiguration changes both the pool size and other // attributes, the pooled session is created with the updated attributes. TEST_P(PeerConnectionInterfaceTest, SetConfigurationCreatesPooledSessionCorrectly) { CreatePeerConnection(); PeerConnectionInterface::RTCConfiguration config = pc_->GetConfiguration(); config.ice_candidate_pool_size = 1; PeerConnectionInterface::IceServer server; server.uri = kStunAddressOnly; config.servers.push_back(server); config.type = PeerConnectionInterface::kRelay; EXPECT_TRUE(pc_->SetConfiguration(config).ok()); const cricket::FakePortAllocatorSession* session = static_cast( port_allocator_->GetPooledSession()); ASSERT_NE(nullptr, session); EXPECT_EQ(1UL, session->stun_servers().size()); } // Test that after SetLocalDescription, changing the pool size is not allowed, // and an invalid modification error is returned. TEST_P(PeerConnectionInterfaceTest, CantChangePoolSizeAfterSetLocalDescription) { CreatePeerConnection(); // Start by setting a size of 1. PeerConnectionInterface::RTCConfiguration config = pc_->GetConfiguration(); config.ice_candidate_pool_size = 1; EXPECT_TRUE(pc_->SetConfiguration(config).ok()); // Set remote offer; can still change pool size at this point. CreateOfferAsRemoteDescription(); config.ice_candidate_pool_size = 2; EXPECT_TRUE(pc_->SetConfiguration(config).ok()); // Set local answer; now it's too late. CreateAnswerAsLocalDescription(); config.ice_candidate_pool_size = 3; RTCError error = pc_->SetConfiguration(config); EXPECT_EQ(RTCErrorType::INVALID_MODIFICATION, error.type()); } // Test that after setting an answer, extra pooled sessions are discarded. The // ICE candidate pool is only intended to be used for the first offer/answer. TEST_P(PeerConnectionInterfaceTest, ExtraPooledSessionsDiscardedAfterApplyingAnswer) { CreatePeerConnection(); // Set a larger-than-necessary size. PeerConnectionInterface::RTCConfiguration config = pc_->GetConfiguration(); config.ice_candidate_pool_size = 4; EXPECT_TRUE(pc_->SetConfiguration(config).ok()); // Do offer/answer. CreateOfferAsRemoteDescription(); CreateAnswerAsLocalDescription(); // Expect no pooled sessions to be left. const cricket::PortAllocatorSession* session = port_allocator_->GetPooledSession(); EXPECT_EQ(nullptr, session); } // After Close is called, pooled candidates should be discarded so as to not // waste network resources. TEST_P(PeerConnectionInterfaceTest, PooledSessionsDiscardedAfterClose) { CreatePeerConnection(); PeerConnectionInterface::RTCConfiguration config = pc_->GetConfiguration(); config.ice_candidate_pool_size = 3; EXPECT_TRUE(pc_->SetConfiguration(config).ok()); pc_->Close(); // Expect no pooled sessions to be left. const cricket::PortAllocatorSession* session = port_allocator_->GetPooledSession(); EXPECT_EQ(nullptr, session); } // Test that SetConfiguration returns an invalid modification error if // modifying a field in the configuration that isn't allowed to be modified. TEST_P(PeerConnectionInterfaceTest, SetConfigurationReturnsInvalidModificationError) { PeerConnectionInterface::RTCConfiguration config; config.bundle_policy = PeerConnectionInterface::kBundlePolicyBalanced; config.rtcp_mux_policy = PeerConnectionInterface::kRtcpMuxPolicyNegotiate; config.continual_gathering_policy = PeerConnectionInterface::GATHER_ONCE; CreatePeerConnection(config); PeerConnectionInterface::RTCConfiguration modified_config = pc_->GetConfiguration(); modified_config.bundle_policy = PeerConnectionInterface::kBundlePolicyMaxBundle; RTCError error = pc_->SetConfiguration(modified_config); EXPECT_EQ(RTCErrorType::INVALID_MODIFICATION, error.type()); modified_config = pc_->GetConfiguration(); modified_config.rtcp_mux_policy = PeerConnectionInterface::kRtcpMuxPolicyRequire; error = pc_->SetConfiguration(modified_config); EXPECT_EQ(RTCErrorType::INVALID_MODIFICATION, error.type()); modified_config = pc_->GetConfiguration(); modified_config.continual_gathering_policy = PeerConnectionInterface::GATHER_CONTINUALLY; error = pc_->SetConfiguration(modified_config); EXPECT_EQ(RTCErrorType::INVALID_MODIFICATION, error.type()); } // Test that SetConfiguration returns a range error if the candidate pool size // is negative or larger than allowed by the spec. TEST_P(PeerConnectionInterfaceTest, SetConfigurationReturnsRangeErrorForBadCandidatePoolSize) { PeerConnectionInterface::RTCConfiguration config; CreatePeerConnection(config); config = pc_->GetConfiguration(); config.ice_candidate_pool_size = -1; RTCError error = pc_->SetConfiguration(config); EXPECT_EQ(RTCErrorType::INVALID_RANGE, error.type()); config.ice_candidate_pool_size = INT_MAX; error = pc_->SetConfiguration(config); EXPECT_EQ(RTCErrorType::INVALID_RANGE, error.type()); } // Test that SetConfiguration returns a syntax error if parsing an ICE server // URL failed. TEST_P(PeerConnectionInterfaceTest, SetConfigurationReturnsSyntaxErrorFromBadIceUrls) { PeerConnectionInterface::RTCConfiguration config; CreatePeerConnection(config); config = pc_->GetConfiguration(); PeerConnectionInterface::IceServer bad_server; bad_server.uri = "stunn:www.example.com"; config.servers.push_back(bad_server); RTCError error = pc_->SetConfiguration(config); EXPECT_EQ(RTCErrorType::SYNTAX_ERROR, error.type()); } // Test that SetConfiguration returns an invalid parameter error if a TURN // IceServer is missing a username or password. TEST_P(PeerConnectionInterfaceTest, SetConfigurationReturnsInvalidParameterIfCredentialsMissing) { PeerConnectionInterface::RTCConfiguration config; CreatePeerConnection(config); config = pc_->GetConfiguration(); PeerConnectionInterface::IceServer bad_server; bad_server.uri = "turn:www.example.com"; // Missing password. bad_server.username = "foo"; config.servers.push_back(bad_server); RTCError error; EXPECT_EQ(pc_->SetConfiguration(config).type(), RTCErrorType::INVALID_PARAMETER); } // Test that PeerConnection::Close changes the states to closed and all remote // tracks change state to ended. TEST_P(PeerConnectionInterfaceTest, CloseAndTestStreamsAndStates) { // Initialize a PeerConnection and negotiate local and remote session // description. InitiateCall(); // With Plan B, verify the stream count. The analog with Unified Plan is the // RtpTransceiver count. if (sdp_semantics_ == SdpSemantics::kPlanB) { ASSERT_EQ(1u, pc_->local_streams()->count()); ASSERT_EQ(1u, pc_->remote_streams()->count()); } else { ASSERT_EQ(2u, pc_->GetTransceivers().size()); } pc_->Close(); EXPECT_EQ(PeerConnectionInterface::kClosed, pc_->signaling_state()); EXPECT_EQ(PeerConnectionInterface::kIceConnectionClosed, pc_->ice_connection_state()); EXPECT_EQ(PeerConnectionInterface::kIceGatheringComplete, pc_->ice_gathering_state()); if (sdp_semantics_ == SdpSemantics::kPlanB) { EXPECT_EQ(1u, pc_->local_streams()->count()); EXPECT_EQ(1u, pc_->remote_streams()->count()); } else { // Verify that the RtpTransceivers are still present but all stopped. EXPECT_EQ(2u, pc_->GetTransceivers().size()); for (const auto& transceiver : pc_->GetTransceivers()) { EXPECT_TRUE(transceiver->stopped()); } } auto audio_receiver = GetFirstReceiverOfType(cricket::MEDIA_TYPE_AUDIO); ASSERT_TRUE(audio_receiver); auto video_receiver = GetFirstReceiverOfType(cricket::MEDIA_TYPE_VIDEO); ASSERT_TRUE(video_receiver); // Track state may be updated asynchronously. EXPECT_EQ_WAIT(MediaStreamTrackInterface::kEnded, audio_receiver->track()->state(), kTimeout); EXPECT_EQ_WAIT(MediaStreamTrackInterface::kEnded, video_receiver->track()->state(), kTimeout); } // Test that PeerConnection methods fails gracefully after // PeerConnection::Close has been called. // Don't run under Unified Plan since the stream API is not available. TEST_F(PeerConnectionInterfaceTestPlanB, CloseAndTestMethods) { CreatePeerConnectionWithoutDtls(); AddAudioVideoStream(kStreamId1, "audio_label", "video_label"); CreateOfferAsRemoteDescription(); CreateAnswerAsLocalDescription(); ASSERT_EQ(1u, pc_->local_streams()->count()); rtc::scoped_refptr local_stream = pc_->local_streams()->at(0); pc_->Close(); pc_->RemoveStream(local_stream); EXPECT_FALSE(pc_->AddStream(local_stream)); EXPECT_TRUE(pc_->CreateDataChannel("test", NULL) == NULL); EXPECT_TRUE(pc_->local_description() != NULL); EXPECT_TRUE(pc_->remote_description() != NULL); std::unique_ptr offer; EXPECT_FALSE(DoCreateOffer(&offer, nullptr)); std::unique_ptr answer; EXPECT_FALSE(DoCreateAnswer(&answer, nullptr)); std::string sdp; ASSERT_TRUE(pc_->remote_description()->ToString(&sdp)); std::unique_ptr remote_offer( webrtc::CreateSessionDescription(SdpType::kOffer, sdp)); EXPECT_FALSE(DoSetRemoteDescription(std::move(remote_offer))); ASSERT_TRUE(pc_->local_description()->ToString(&sdp)); std::unique_ptr local_offer( webrtc::CreateSessionDescription(SdpType::kOffer, sdp)); EXPECT_FALSE(DoSetLocalDescription(std::move(local_offer))); } // Test that GetStats can still be called after PeerConnection::Close. TEST_P(PeerConnectionInterfaceTest, CloseAndGetStats) { InitiateCall(); pc_->Close(); DoGetStats(NULL); } // NOTE: The series of tests below come from what used to be // mediastreamsignaling_unittest.cc, and are mostly aimed at testing that // setting a remote or local description has the expected effects. // This test verifies that the remote MediaStreams corresponding to a received // SDP string is created. In this test the two separate MediaStreams are // signaled. TEST_P(PeerConnectionInterfaceTest, UpdateRemoteStreams) { RTCConfiguration config; config.enable_dtls_srtp = true; CreatePeerConnection(config); CreateAndSetRemoteOffer(GetSdpStringWithStream1()); rtc::scoped_refptr reference(CreateStreamCollection(1, 1)); EXPECT_TRUE( CompareStreamCollections(observer_.remote_streams(), reference.get())); MediaStreamInterface* remote_stream = observer_.remote_streams()->at(0); EXPECT_TRUE(remote_stream->GetVideoTracks()[0]->GetSource() != nullptr); // Create a session description based on another SDP with another // MediaStream. CreateAndSetRemoteOffer(GetSdpStringWithStream1And2()); rtc::scoped_refptr reference2(CreateStreamCollection(2, 1)); EXPECT_TRUE( CompareStreamCollections(observer_.remote_streams(), reference2.get())); } // This test verifies that when remote tracks are added/removed from SDP, the // created remote streams are updated appropriately. // Don't run under Unified Plan since this test uses Plan B SDP to test Plan B // specific behavior. TEST_F(PeerConnectionInterfaceTestPlanB, AddRemoveTrackFromExistingRemoteMediaStream) { RTCConfiguration config; config.enable_dtls_srtp = true; CreatePeerConnection(config); std::unique_ptr desc_ms1 = CreateSessionDescriptionAndReference(1, 1); EXPECT_TRUE(DoSetRemoteDescription(std::move(desc_ms1))); EXPECT_TRUE(CompareStreamCollections(observer_.remote_streams(), reference_collection_)); // Add extra audio and video tracks to the same MediaStream. std::unique_ptr desc_ms1_two_tracks = CreateSessionDescriptionAndReference(2, 2); EXPECT_TRUE(DoSetRemoteDescription(std::move(desc_ms1_two_tracks))); EXPECT_TRUE(CompareStreamCollections(observer_.remote_streams(), reference_collection_)); rtc::scoped_refptr audio_track2 = observer_.remote_streams()->at(0)->GetAudioTracks()[1]; EXPECT_EQ(webrtc::MediaStreamTrackInterface::kLive, audio_track2->state()); rtc::scoped_refptr video_track2 = observer_.remote_streams()->at(0)->GetVideoTracks()[1]; EXPECT_EQ(webrtc::MediaStreamTrackInterface::kLive, video_track2->state()); // Remove the extra audio and video tracks. std::unique_ptr desc_ms2 = CreateSessionDescriptionAndReference(1, 1); MockTrackObserver audio_track_observer(audio_track2); MockTrackObserver video_track_observer(video_track2); EXPECT_CALL(audio_track_observer, OnChanged()).Times(Exactly(1)); EXPECT_CALL(video_track_observer, OnChanged()).Times(Exactly(1)); EXPECT_TRUE(DoSetRemoteDescription(std::move(desc_ms2))); EXPECT_TRUE(CompareStreamCollections(observer_.remote_streams(), reference_collection_)); // Track state may be updated asynchronously. EXPECT_EQ_WAIT(webrtc::MediaStreamTrackInterface::kEnded, audio_track2->state(), kTimeout); EXPECT_EQ_WAIT(webrtc::MediaStreamTrackInterface::kEnded, video_track2->state(), kTimeout); } // This tests that remote tracks are ended if a local session description is set // that rejects the media content type. TEST_P(PeerConnectionInterfaceTest, RejectMediaContent) { RTCConfiguration config; config.enable_dtls_srtp = true; CreatePeerConnection(config); // First create and set a remote offer, then reject its video content in our // answer. CreateAndSetRemoteOffer(kSdpStringWithStream1PlanB); auto audio_receiver = GetFirstReceiverOfType(cricket::MEDIA_TYPE_AUDIO); ASSERT_TRUE(audio_receiver); auto video_receiver = GetFirstReceiverOfType(cricket::MEDIA_TYPE_VIDEO); ASSERT_TRUE(video_receiver); rtc::scoped_refptr remote_audio = audio_receiver->track(); EXPECT_EQ(webrtc::MediaStreamTrackInterface::kLive, remote_audio->state()); rtc::scoped_refptr remote_video = video_receiver->track(); EXPECT_EQ(MediaStreamTrackInterface::kLive, remote_video->state()); std::unique_ptr local_answer; EXPECT_TRUE(DoCreateAnswer(&local_answer, nullptr)); cricket::ContentInfo* video_info = local_answer->description()->GetContentByName("video"); video_info->rejected = true; EXPECT_TRUE(DoSetLocalDescription(std::move(local_answer))); EXPECT_EQ(MediaStreamTrackInterface::kEnded, remote_video->state()); EXPECT_EQ(MediaStreamTrackInterface::kLive, remote_audio->state()); // Now create an offer where we reject both video and audio. std::unique_ptr local_offer; EXPECT_TRUE(DoCreateOffer(&local_offer, nullptr)); video_info = local_offer->description()->GetContentByName("video"); ASSERT_TRUE(video_info != nullptr); video_info->rejected = true; cricket::ContentInfo* audio_info = local_offer->description()->GetContentByName("audio"); ASSERT_TRUE(audio_info != nullptr); audio_info->rejected = true; EXPECT_TRUE(DoSetLocalDescription(std::move(local_offer))); // Track state may be updated asynchronously. EXPECT_EQ_WAIT(MediaStreamTrackInterface::kEnded, remote_audio->state(), kTimeout); EXPECT_EQ_WAIT(MediaStreamTrackInterface::kEnded, remote_video->state(), kTimeout); } // This tests that we won't crash if the remote track has been removed outside // of PeerConnection and then PeerConnection tries to reject the track. // Don't run under Unified Plan since the stream API is not available. TEST_F(PeerConnectionInterfaceTestPlanB, RemoveTrackThenRejectMediaContent) { RTCConfiguration config; config.enable_dtls_srtp = true; CreatePeerConnection(config); CreateAndSetRemoteOffer(GetSdpStringWithStream1()); MediaStreamInterface* remote_stream = observer_.remote_streams()->at(0); remote_stream->RemoveTrack(remote_stream->GetVideoTracks()[0]); remote_stream->RemoveTrack(remote_stream->GetAudioTracks()[0]); std::unique_ptr local_answer( webrtc::CreateSessionDescription(SdpType::kAnswer, GetSdpStringWithStream1(), nullptr)); cricket::ContentInfo* video_info = local_answer->description()->GetContentByName("video"); video_info->rejected = true; cricket::ContentInfo* audio_info = local_answer->description()->GetContentByName("audio"); audio_info->rejected = true; EXPECT_TRUE(DoSetLocalDescription(std::move(local_answer))); // No crash is a pass. } // This tests that if a recvonly remote description is set, no remote streams // will be created, even if the description contains SSRCs/MSIDs. // See: https://code.google.com/p/webrtc/issues/detail?id=5054 TEST_P(PeerConnectionInterfaceTest, RecvonlyDescriptionDoesntCreateStream) { RTCConfiguration config; config.enable_dtls_srtp = true; CreatePeerConnection(config); std::string recvonly_offer = GetSdpStringWithStream1(); absl::StrReplaceAll({{kSendrecv, kRecvonly}}, &recvonly_offer); CreateAndSetRemoteOffer(recvonly_offer); EXPECT_EQ(0u, observer_.remote_streams()->count()); } // This tests that a default MediaStream is created if a remote session // description doesn't contain any streams and no MSID support. // It also tests that the default stream is updated if a video m-line is added // in a subsequent session description. // Don't run under Unified Plan since this behavior is Plan B specific. TEST_F(PeerConnectionInterfaceTestPlanB, SdpWithoutMsidCreatesDefaultStream) { RTCConfiguration config; config.enable_dtls_srtp = true; CreatePeerConnection(config); CreateAndSetRemoteOffer(kSdpStringWithoutStreamsAudioOnly); ASSERT_EQ(1u, observer_.remote_streams()->count()); MediaStreamInterface* remote_stream = observer_.remote_streams()->at(0); EXPECT_EQ(1u, remote_stream->GetAudioTracks().size()); EXPECT_EQ(0u, remote_stream->GetVideoTracks().size()); EXPECT_EQ("default", remote_stream->id()); CreateAndSetRemoteOffer(kSdpStringWithoutStreams); ASSERT_EQ(1u, observer_.remote_streams()->count()); ASSERT_EQ(1u, remote_stream->GetAudioTracks().size()); EXPECT_EQ("defaulta0", remote_stream->GetAudioTracks()[0]->id()); EXPECT_EQ(MediaStreamTrackInterface::kLive, remote_stream->GetAudioTracks()[0]->state()); ASSERT_EQ(1u, remote_stream->GetVideoTracks().size()); EXPECT_EQ("defaultv0", remote_stream->GetVideoTracks()[0]->id()); EXPECT_EQ(MediaStreamTrackInterface::kLive, remote_stream->GetVideoTracks()[0]->state()); } // This tests that a default MediaStream is created if a remote session // description doesn't contain any streams and media direction is send only. // Don't run under Unified Plan since this behavior is Plan B specific. TEST_F(PeerConnectionInterfaceTestPlanB, SendOnlySdpWithoutMsidCreatesDefaultStream) { RTCConfiguration config; config.enable_dtls_srtp = true; CreatePeerConnection(config); CreateAndSetRemoteOffer(kSdpStringSendOnlyWithoutStreams); ASSERT_EQ(1u, observer_.remote_streams()->count()); MediaStreamInterface* remote_stream = observer_.remote_streams()->at(0); EXPECT_EQ(1u, remote_stream->GetAudioTracks().size()); EXPECT_EQ(1u, remote_stream->GetVideoTracks().size()); EXPECT_EQ("default", remote_stream->id()); } // This tests that it won't crash when PeerConnection tries to remove // a remote track that as already been removed from the MediaStream. // Don't run under Unified Plan since this behavior is Plan B specific. TEST_F(PeerConnectionInterfaceTestPlanB, RemoveAlreadyGoneRemoteStream) { RTCConfiguration config; config.enable_dtls_srtp = true; CreatePeerConnection(config); CreateAndSetRemoteOffer(GetSdpStringWithStream1()); MediaStreamInterface* remote_stream = observer_.remote_streams()->at(0); remote_stream->RemoveTrack(remote_stream->GetAudioTracks()[0]); remote_stream->RemoveTrack(remote_stream->GetVideoTracks()[0]); CreateAndSetRemoteOffer(kSdpStringWithoutStreams); // No crash is a pass. } // This tests that a default MediaStream is created if the remote session // description doesn't contain any streams and don't contain an indication if // MSID is supported. // Don't run under Unified Plan since this behavior is Plan B specific. TEST_F(PeerConnectionInterfaceTestPlanB, SdpWithoutMsidAndStreamsCreatesDefaultStream) { RTCConfiguration config; config.enable_dtls_srtp = true; CreatePeerConnection(config); CreateAndSetRemoteOffer(kSdpStringWithoutStreams); ASSERT_EQ(1u, observer_.remote_streams()->count()); MediaStreamInterface* remote_stream = observer_.remote_streams()->at(0); EXPECT_EQ(1u, remote_stream->GetAudioTracks().size()); EXPECT_EQ(1u, remote_stream->GetVideoTracks().size()); } // This tests that a default MediaStream is not created if the remote session // description doesn't contain any streams but does support MSID. // Don't run under Unified Plan since this behavior is Plan B specific. TEST_F(PeerConnectionInterfaceTestPlanB, SdpWithMsidDontCreatesDefaultStream) { RTCConfiguration config; config.enable_dtls_srtp = true; CreatePeerConnection(config); CreateAndSetRemoteOffer(kSdpStringWithMsidWithoutStreams); EXPECT_EQ(0u, observer_.remote_streams()->count()); } // This tests that when setting a new description, the old default tracks are // not destroyed and recreated. // See: https://bugs.chromium.org/p/webrtc/issues/detail?id=5250 // Don't run under Unified Plan since this behavior is Plan B specific. TEST_F(PeerConnectionInterfaceTestPlanB, DefaultTracksNotDestroyedAndRecreated) { RTCConfiguration config; config.enable_dtls_srtp = true; CreatePeerConnection(config); CreateAndSetRemoteOffer(kSdpStringWithoutStreamsAudioOnly); ASSERT_EQ(1u, observer_.remote_streams()->count()); MediaStreamInterface* remote_stream = observer_.remote_streams()->at(0); ASSERT_EQ(1u, remote_stream->GetAudioTracks().size()); // Set the track to "disabled", then set a new description and ensure the // track is still disabled, which ensures it hasn't been recreated. remote_stream->GetAudioTracks()[0]->set_enabled(false); CreateAndSetRemoteOffer(kSdpStringWithoutStreamsAudioOnly); ASSERT_EQ(1u, remote_stream->GetAudioTracks().size()); EXPECT_FALSE(remote_stream->GetAudioTracks()[0]->enabled()); } // This tests that a default MediaStream is not created if a remote session // description is updated to not have any MediaStreams. // Don't run under Unified Plan since this behavior is Plan B specific. TEST_F(PeerConnectionInterfaceTestPlanB, VerifyDefaultStreamIsNotCreated) { RTCConfiguration config; config.enable_dtls_srtp = true; CreatePeerConnection(config); CreateAndSetRemoteOffer(GetSdpStringWithStream1()); rtc::scoped_refptr reference(CreateStreamCollection(1, 1)); EXPECT_TRUE( CompareStreamCollections(observer_.remote_streams(), reference.get())); CreateAndSetRemoteOffer(kSdpStringWithoutStreams); EXPECT_EQ(0u, observer_.remote_streams()->count()); } // This tests that a default MediaStream is created if a remote SDP comes from // an endpoint that doesn't signal SSRCs, but signals media stream IDs. TEST_F(PeerConnectionInterfaceTestPlanB, SdpWithMsidWithoutSsrcCreatesDefaultStream) { RTCConfiguration config; config.enable_dtls_srtp = true; CreatePeerConnection(config); std::string sdp_string = kSdpStringWithoutStreamsAudioOnly; // Add a=msid lines to simulate a Unified Plan endpoint that only // signals stream IDs with a=msid lines. sdp_string.append("a=msid:audio_stream_id audio_track_id\n"); CreateAndSetRemoteOffer(sdp_string); ASSERT_EQ(1u, observer_.remote_streams()->count()); MediaStreamInterface* remote_stream = observer_.remote_streams()->at(0); EXPECT_EQ("default", remote_stream->id()); ASSERT_EQ(1u, remote_stream->GetAudioTracks().size()); } // This tests that when a Plan B endpoint receives an SDP that signals no media // stream IDs indicated by the special character "-" in the a=msid line, that // a default stream ID will be used for the MediaStream ID. This can occur // when a Unified Plan endpoint signals no media stream IDs, but signals both // a=ssrc msid and a=msid lines for interop signaling with Plan B. TEST_F(PeerConnectionInterfaceTestPlanB, SdpWithEmptyMsidAndSsrcCreatesDefaultStreamId) { RTCConfiguration config; config.enable_dtls_srtp = true; CreatePeerConnection(config); // Add a a=msid line to the SDP. This is prioritized when parsing the SDP, so // the sender's stream ID will be interpreted as no stream IDs. std::string sdp_string = kSdpStringWithStream1AudioTrackOnly; sdp_string.append("a=msid:- audiotrack0\n"); CreateAndSetRemoteOffer(sdp_string); ASSERT_EQ(1u, observer_.remote_streams()->count()); // Because SSRCs are signaled the track ID will be what was signaled in the // a=msid line. EXPECT_EQ("audiotrack0", observer_.last_added_track_label_); MediaStreamInterface* remote_stream = observer_.remote_streams()->at(0); EXPECT_EQ("default", remote_stream->id()); ASSERT_EQ(1u, remote_stream->GetAudioTracks().size()); // Previously a bug ocurred when setting the remote description a second time. // This is because we checked equality of the remote StreamParams stream ID // (empty), and the previously set stream ID for the remote sender // ("default"). This cause a track to be removed, then added, when really // nothing should occur because it is the same track. CreateAndSetRemoteOffer(sdp_string); EXPECT_EQ(0u, observer_.remove_track_events_.size()); EXPECT_EQ(1u, observer_.add_track_events_.size()); EXPECT_EQ("audiotrack0", observer_.last_added_track_label_); remote_stream = observer_.remote_streams()->at(0); EXPECT_EQ("default", remote_stream->id()); ASSERT_EQ(1u, remote_stream->GetAudioTracks().size()); } // This tests that an RtpSender is created when the local description is set // after adding a local stream. // TODO(deadbeef): This test and the one below it need to be updated when // an RtpSender's lifetime isn't determined by when a local description is set. // Don't run under Unified Plan since this behavior is Plan B specific. TEST_F(PeerConnectionInterfaceTestPlanB, LocalDescriptionChanged) { RTCConfiguration config; config.enable_dtls_srtp = true; CreatePeerConnection(config); // Create an offer with 1 stream with 2 tracks of each type. rtc::scoped_refptr stream_collection = CreateStreamCollection(1, 2); pc_->AddStream(stream_collection->at(0)); std::unique_ptr offer; ASSERT_TRUE(DoCreateOffer(&offer, nullptr)); EXPECT_TRUE(DoSetLocalDescription(std::move(offer))); auto senders = pc_->GetSenders(); EXPECT_EQ(4u, senders.size()); EXPECT_TRUE(ContainsSender(senders, kAudioTracks[0])); EXPECT_TRUE(ContainsSender(senders, kVideoTracks[0])); EXPECT_TRUE(ContainsSender(senders, kAudioTracks[1])); EXPECT_TRUE(ContainsSender(senders, kVideoTracks[1])); // Remove an audio and video track. pc_->RemoveStream(stream_collection->at(0)); stream_collection = CreateStreamCollection(1, 1); pc_->AddStream(stream_collection->at(0)); ASSERT_TRUE(DoCreateOffer(&offer, nullptr)); EXPECT_TRUE(DoSetLocalDescription(std::move(offer))); senders = pc_->GetSenders(); EXPECT_EQ(2u, senders.size()); EXPECT_TRUE(ContainsSender(senders, kAudioTracks[0])); EXPECT_TRUE(ContainsSender(senders, kVideoTracks[0])); EXPECT_FALSE(ContainsSender(senders, kAudioTracks[1])); EXPECT_FALSE(ContainsSender(senders, kVideoTracks[1])); } // This tests that an RtpSender is created when the local description is set // before adding a local stream. // Don't run under Unified Plan since this behavior is Plan B specific. TEST_F(PeerConnectionInterfaceTestPlanB, AddLocalStreamAfterLocalDescriptionChanged) { RTCConfiguration config; config.enable_dtls_srtp = true; CreatePeerConnection(config); rtc::scoped_refptr stream_collection = CreateStreamCollection(1, 2); // Add a stream to create the offer, but remove it afterwards. pc_->AddStream(stream_collection->at(0)); std::unique_ptr offer; ASSERT_TRUE(DoCreateOffer(&offer, nullptr)); pc_->RemoveStream(stream_collection->at(0)); EXPECT_TRUE(DoSetLocalDescription(std::move(offer))); auto senders = pc_->GetSenders(); EXPECT_EQ(0u, senders.size()); pc_->AddStream(stream_collection->at(0)); senders = pc_->GetSenders(); EXPECT_EQ(4u, senders.size()); EXPECT_TRUE(ContainsSender(senders, kAudioTracks[0])); EXPECT_TRUE(ContainsSender(senders, kVideoTracks[0])); EXPECT_TRUE(ContainsSender(senders, kAudioTracks[1])); EXPECT_TRUE(ContainsSender(senders, kVideoTracks[1])); } // This tests that the expected behavior occurs if the SSRC on a local track is // changed when SetLocalDescription is called. TEST_P(PeerConnectionInterfaceTest, ChangeSsrcOnTrackInLocalSessionDescription) { RTCConfiguration config; config.enable_dtls_srtp = true; CreatePeerConnection(config); AddAudioTrack(kAudioTracks[0]); AddVideoTrack(kVideoTracks[0]); std::unique_ptr offer; ASSERT_TRUE(DoCreateOffer(&offer, nullptr)); // Grab a copy of the offer before it gets passed into the PC. std::unique_ptr modified_offer = webrtc::CreateSessionDescription( webrtc::SdpType::kOffer, offer->session_id(), offer->session_version(), offer->description()->Clone()); EXPECT_TRUE(DoSetLocalDescription(std::move(offer))); auto senders = pc_->GetSenders(); EXPECT_EQ(2u, senders.size()); EXPECT_TRUE(ContainsSender(senders, kAudioTracks[0])); EXPECT_TRUE(ContainsSender(senders, kVideoTracks[0])); // Change the ssrc of the audio and video track. cricket::MediaContentDescription* desc = cricket::GetFirstAudioContentDescription(modified_offer->description()); ASSERT_TRUE(desc != NULL); for (StreamParams& stream : desc->mutable_streams()) { for (unsigned int& ssrc : stream.ssrcs) { ++ssrc; } } desc = cricket::GetFirstVideoContentDescription(modified_offer->description()); ASSERT_TRUE(desc != NULL); for (StreamParams& stream : desc->mutable_streams()) { for (unsigned int& ssrc : stream.ssrcs) { ++ssrc; } } EXPECT_TRUE(DoSetLocalDescription(std::move(modified_offer))); senders = pc_->GetSenders(); EXPECT_EQ(2u, senders.size()); EXPECT_TRUE(ContainsSender(senders, kAudioTracks[0])); EXPECT_TRUE(ContainsSender(senders, kVideoTracks[0])); // TODO(deadbeef): Once RtpSenders expose parameters, check that the SSRC // changed. } // This tests that the expected behavior occurs if a new session description is // set with the same tracks, but on a different MediaStream. // Don't run under Unified Plan since the stream API is not available. TEST_F(PeerConnectionInterfaceTestPlanB, SignalSameTracksInSeparateMediaStream) { RTCConfiguration config; config.enable_dtls_srtp = true; CreatePeerConnection(config); rtc::scoped_refptr stream_collection = CreateStreamCollection(2, 1); pc_->AddStream(stream_collection->at(0)); std::unique_ptr offer; ASSERT_TRUE(DoCreateOffer(&offer, nullptr)); EXPECT_TRUE(DoSetLocalDescription(std::move(offer))); auto senders = pc_->GetSenders(); EXPECT_EQ(2u, senders.size()); EXPECT_TRUE(ContainsSender(senders, kAudioTracks[0], kStreams[0])); EXPECT_TRUE(ContainsSender(senders, kVideoTracks[0], kStreams[0])); // Add a new MediaStream but with the same tracks as in the first stream. rtc::scoped_refptr stream_1( webrtc::MediaStream::Create(kStreams[1])); stream_1->AddTrack(stream_collection->at(0)->GetVideoTracks()[0]); stream_1->AddTrack(stream_collection->at(0)->GetAudioTracks()[0]); pc_->AddStream(stream_1); ASSERT_TRUE(DoCreateOffer(&offer, nullptr)); EXPECT_TRUE(DoSetLocalDescription(std::move(offer))); auto new_senders = pc_->GetSenders(); // Should be the same senders as before, but with updated stream id. // Note that this behavior is subject to change in the future. // We may decide the PC should ignore existing tracks in AddStream. EXPECT_EQ(senders, new_senders); EXPECT_TRUE(ContainsSender(new_senders, kAudioTracks[0], kStreams[1])); EXPECT_TRUE(ContainsSender(new_senders, kVideoTracks[0], kStreams[1])); } // This tests that PeerConnectionObserver::OnAddTrack is correctly called. TEST_P(PeerConnectionInterfaceTest, OnAddTrackCallback) { RTCConfiguration config; config.enable_dtls_srtp = true; CreatePeerConnection(config); CreateAndSetRemoteOffer(kSdpStringWithStream1AudioTrackOnly); EXPECT_EQ(observer_.num_added_tracks_, 1); EXPECT_EQ(observer_.last_added_track_label_, kAudioTracks[0]); // Create and set the updated remote SDP. CreateAndSetRemoteOffer(kSdpStringWithStream1PlanB); EXPECT_EQ(observer_.num_added_tracks_, 2); EXPECT_EQ(observer_.last_added_track_label_, kVideoTracks[0]); } // Test that when SetConfiguration is called and the configuration is // changing, the next offer causes an ICE restart. TEST_P(PeerConnectionInterfaceTest, SetConfigurationCausingIceRestart) { PeerConnectionInterface::RTCConfiguration config; config.type = PeerConnectionInterface::kRelay; CreatePeerConnection(config); config = pc_->GetConfiguration(); AddAudioTrack(kAudioTracks[0], {kStreamId1}); AddVideoTrack(kVideoTracks[0], {kStreamId1}); // Do initial offer/answer so there's something to restart. CreateOfferAsLocalDescription(); CreateAnswerAsRemoteDescription(GetSdpStringWithStream1()); // Grab the ufrags. std::vector initial_ufrags = GetUfrags(pc_->local_description()); // Change ICE policy, which should trigger an ICE restart on the next offer. config.type = PeerConnectionInterface::kAll; EXPECT_TRUE(pc_->SetConfiguration(config).ok()); CreateOfferAsLocalDescription(); // Grab the new ufrags. std::vector subsequent_ufrags = GetUfrags(pc_->local_description()); // Sanity check. EXPECT_EQ(initial_ufrags.size(), subsequent_ufrags.size()); // Check that each ufrag is different. for (int i = 0; i < static_cast(initial_ufrags.size()); ++i) { EXPECT_NE(initial_ufrags[i], subsequent_ufrags[i]); } } // Test that when SetConfiguration is called and the configuration *isn't* // changing, the next offer does *not* cause an ICE restart. TEST_P(PeerConnectionInterfaceTest, SetConfigurationNotCausingIceRestart) { PeerConnectionInterface::RTCConfiguration config; config.type = PeerConnectionInterface::kRelay; CreatePeerConnection(config); config = pc_->GetConfiguration(); AddAudioTrack(kAudioTracks[0]); AddVideoTrack(kVideoTracks[0]); // Do initial offer/answer so there's something to restart. CreateOfferAsLocalDescription(); CreateAnswerAsRemoteDescription(GetSdpStringWithStream1()); // Grab the ufrags. std::vector initial_ufrags = GetUfrags(pc_->local_description()); // Call SetConfiguration with a config identical to what the PC was // constructed with. EXPECT_TRUE(pc_->SetConfiguration(config).ok()); CreateOfferAsLocalDescription(); // Grab the new ufrags. std::vector subsequent_ufrags = GetUfrags(pc_->local_description()); EXPECT_EQ(initial_ufrags, subsequent_ufrags); } // Test for a weird corner case scenario: // 1. Audio/video session established. // 2. SetConfiguration changes ICE config; ICE restart needed. // 3. ICE restart initiated by remote peer, but only for one m= section. // 4. Next createOffer should initiate an ICE restart, but only for the other // m= section; it would be pointless to do an ICE restart for the m= section // that was already restarted. TEST_P(PeerConnectionInterfaceTest, SetConfigurationCausingPartialIceRestart) { PeerConnectionInterface::RTCConfiguration config; config.type = PeerConnectionInterface::kRelay; CreatePeerConnection(config); config = pc_->GetConfiguration(); AddAudioTrack(kAudioTracks[0], {kStreamId1}); AddVideoTrack(kVideoTracks[0], {kStreamId1}); // Do initial offer/answer so there's something to restart. CreateOfferAsLocalDescription(); CreateAnswerAsRemoteDescription(GetSdpStringWithStream1()); // Change ICE policy, which should set the "needs-ice-restart" flag. config.type = PeerConnectionInterface::kAll; EXPECT_TRUE(pc_->SetConfiguration(config).ok()); // Do ICE restart for the first m= section, initiated by remote peer. std::unique_ptr remote_offer( webrtc::CreateSessionDescription(SdpType::kOffer, GetSdpStringWithStream1(), nullptr)); ASSERT_TRUE(remote_offer); remote_offer->description()->transport_infos()[0].description.ice_ufrag = "modified"; EXPECT_TRUE(DoSetRemoteDescription(std::move(remote_offer))); CreateAnswerAsLocalDescription(); // Grab the ufrags. std::vector initial_ufrags = GetUfrags(pc_->local_description()); ASSERT_EQ(2U, initial_ufrags.size()); // Create offer and grab the new ufrags. CreateOfferAsLocalDescription(); std::vector subsequent_ufrags = GetUfrags(pc_->local_description()); ASSERT_EQ(2U, subsequent_ufrags.size()); // Ensure that only the ufrag for the second m= section changed. EXPECT_EQ(initial_ufrags[0], subsequent_ufrags[0]); EXPECT_NE(initial_ufrags[1], subsequent_ufrags[1]); } // Tests that the methods to return current/pending descriptions work as // expected at different points in the offer/answer exchange. This test does // one offer/answer exchange as the offerer, then another as the answerer. TEST_P(PeerConnectionInterfaceTest, CurrentAndPendingDescriptions) { // This disables DTLS so we can apply an answer to ourselves. CreatePeerConnection(); // Create initial local offer and get SDP (which will also be used as // answer/pranswer); std::unique_ptr local_offer; ASSERT_TRUE(DoCreateOffer(&local_offer, nullptr)); std::string sdp; EXPECT_TRUE(local_offer->ToString(&sdp)); // Set local offer. SessionDescriptionInterface* local_offer_ptr = local_offer.get(); EXPECT_TRUE(DoSetLocalDescription(std::move(local_offer))); EXPECT_EQ(local_offer_ptr, pc_->pending_local_description()); EXPECT_EQ(nullptr, pc_->pending_remote_description()); EXPECT_EQ(nullptr, pc_->current_local_description()); EXPECT_EQ(nullptr, pc_->current_remote_description()); // Set remote pranswer. std::unique_ptr remote_pranswer( webrtc::CreateSessionDescription(SdpType::kPrAnswer, sdp)); SessionDescriptionInterface* remote_pranswer_ptr = remote_pranswer.get(); EXPECT_TRUE(DoSetRemoteDescription(std::move(remote_pranswer))); EXPECT_EQ(local_offer_ptr, pc_->pending_local_description()); EXPECT_EQ(remote_pranswer_ptr, pc_->pending_remote_description()); EXPECT_EQ(nullptr, pc_->current_local_description()); EXPECT_EQ(nullptr, pc_->current_remote_description()); // Set remote answer. std::unique_ptr remote_answer( webrtc::CreateSessionDescription(SdpType::kAnswer, sdp)); SessionDescriptionInterface* remote_answer_ptr = remote_answer.get(); EXPECT_TRUE(DoSetRemoteDescription(std::move(remote_answer))); EXPECT_EQ(nullptr, pc_->pending_local_description()); EXPECT_EQ(nullptr, pc_->pending_remote_description()); EXPECT_EQ(local_offer_ptr, pc_->current_local_description()); EXPECT_EQ(remote_answer_ptr, pc_->current_remote_description()); // Set remote offer. std::unique_ptr remote_offer( webrtc::CreateSessionDescription(SdpType::kOffer, sdp)); SessionDescriptionInterface* remote_offer_ptr = remote_offer.get(); EXPECT_TRUE(DoSetRemoteDescription(std::move(remote_offer))); EXPECT_EQ(remote_offer_ptr, pc_->pending_remote_description()); EXPECT_EQ(nullptr, pc_->pending_local_description()); EXPECT_EQ(local_offer_ptr, pc_->current_local_description()); EXPECT_EQ(remote_answer_ptr, pc_->current_remote_description()); // Set local pranswer. std::unique_ptr local_pranswer( webrtc::CreateSessionDescription(SdpType::kPrAnswer, sdp)); SessionDescriptionInterface* local_pranswer_ptr = local_pranswer.get(); EXPECT_TRUE(DoSetLocalDescription(std::move(local_pranswer))); EXPECT_EQ(remote_offer_ptr, pc_->pending_remote_description()); EXPECT_EQ(local_pranswer_ptr, pc_->pending_local_description()); EXPECT_EQ(local_offer_ptr, pc_->current_local_description()); EXPECT_EQ(remote_answer_ptr, pc_->current_remote_description()); // Set local answer. std::unique_ptr local_answer( webrtc::CreateSessionDescription(SdpType::kAnswer, sdp)); SessionDescriptionInterface* local_answer_ptr = local_answer.get(); EXPECT_TRUE(DoSetLocalDescription(std::move(local_answer))); EXPECT_EQ(nullptr, pc_->pending_remote_description()); EXPECT_EQ(nullptr, pc_->pending_local_description()); EXPECT_EQ(remote_offer_ptr, pc_->current_remote_description()); EXPECT_EQ(local_answer_ptr, pc_->current_local_description()); } // Tests that it won't crash when calling StartRtcEventLog or StopRtcEventLog // after the PeerConnection is closed. // This version tests the StartRtcEventLog version that receives an object // of type |RtcEventLogOutput|. TEST_P(PeerConnectionInterfaceTest, StartAndStopLoggingToOutputAfterPeerConnectionClosed) { CreatePeerConnection(); // The RtcEventLog will be reset when the PeerConnection is closed. pc_->Close(); EXPECT_FALSE( pc_->StartRtcEventLog(std::make_unique(), webrtc::RtcEventLog::kImmediateOutput)); pc_->StopRtcEventLog(); } // Test that generated offers/answers include "ice-option:trickle". TEST_P(PeerConnectionInterfaceTest, OffersAndAnswersHaveTrickleIceOption) { CreatePeerConnection(); // First, create an offer with audio/video. RTCOfferAnswerOptions options; options.offer_to_receive_audio = 1; options.offer_to_receive_video = 1; std::unique_ptr offer; ASSERT_TRUE(DoCreateOffer(&offer, &options)); cricket::SessionDescription* desc = offer->description(); ASSERT_EQ(2u, desc->transport_infos().size()); EXPECT_TRUE(desc->transport_infos()[0].description.HasOption("trickle")); EXPECT_TRUE(desc->transport_infos()[1].description.HasOption("trickle")); // Apply the offer as a remote description, then create an answer. EXPECT_FALSE(pc_->can_trickle_ice_candidates()); EXPECT_TRUE(DoSetRemoteDescription(std::move(offer))); ASSERT_TRUE(pc_->can_trickle_ice_candidates()); EXPECT_TRUE(*(pc_->can_trickle_ice_candidates())); std::unique_ptr answer; ASSERT_TRUE(DoCreateAnswer(&answer, &options)); desc = answer->description(); ASSERT_EQ(2u, desc->transport_infos().size()); EXPECT_TRUE(desc->transport_infos()[0].description.HasOption("trickle")); EXPECT_TRUE(desc->transport_infos()[1].description.HasOption("trickle")); } // Test that ICE renomination isn't offered if it's not enabled in the PC's // RTCConfiguration. TEST_P(PeerConnectionInterfaceTest, IceRenominationNotOffered) { PeerConnectionInterface::RTCConfiguration config; config.enable_ice_renomination = false; CreatePeerConnection(config); AddAudioTrack("foo"); std::unique_ptr offer; ASSERT_TRUE(DoCreateOffer(&offer, nullptr)); cricket::SessionDescription* desc = offer->description(); EXPECT_EQ(1u, desc->transport_infos().size()); EXPECT_FALSE( desc->transport_infos()[0].description.GetIceParameters().renomination); } // Test that the ICE renomination option is present in generated offers/answers // if it's enabled in the PC's RTCConfiguration. TEST_P(PeerConnectionInterfaceTest, IceRenominationOptionInOfferAndAnswer) { PeerConnectionInterface::RTCConfiguration config; config.enable_ice_renomination = true; CreatePeerConnection(config); AddAudioTrack("foo"); std::unique_ptr offer; ASSERT_TRUE(DoCreateOffer(&offer, nullptr)); cricket::SessionDescription* desc = offer->description(); EXPECT_EQ(1u, desc->transport_infos().size()); EXPECT_TRUE( desc->transport_infos()[0].description.GetIceParameters().renomination); // Set the offer as a remote description, then create an answer and ensure it // has the renomination flag too. EXPECT_TRUE(DoSetRemoteDescription(std::move(offer))); std::unique_ptr answer; ASSERT_TRUE(DoCreateAnswer(&answer, nullptr)); desc = answer->description(); EXPECT_EQ(1u, desc->transport_infos().size()); EXPECT_TRUE( desc->transport_infos()[0].description.GetIceParameters().renomination); } // Test that if CreateOffer is called with the deprecated "offer to receive // audio/video" constraints, they're processed and result in an offer with // audio/video sections just as if RTCOfferAnswerOptions had been used. TEST_P(PeerConnectionInterfaceTest, CreateOfferWithOfferToReceiveConstraints) { CreatePeerConnection(); RTCOfferAnswerOptions options; options.offer_to_receive_audio = 1; options.offer_to_receive_video = 1; std::unique_ptr offer; ASSERT_TRUE(DoCreateOffer(&offer, &options)); cricket::SessionDescription* desc = offer->description(); const cricket::ContentInfo* audio = cricket::GetFirstAudioContent(desc); const cricket::ContentInfo* video = cricket::GetFirstVideoContent(desc); ASSERT_NE(nullptr, audio); ASSERT_NE(nullptr, video); EXPECT_FALSE(audio->rejected); EXPECT_FALSE(video->rejected); } // Test that if CreateAnswer is called with the deprecated "offer to receive // audio/video" constraints, they're processed and can be used to reject an // offered m= section just as can be done with RTCOfferAnswerOptions; // Don't run under Unified Plan since this behavior is not supported. TEST_F(PeerConnectionInterfaceTestPlanB, CreateAnswerWithOfferToReceiveConstraints) { CreatePeerConnection(); // First, create an offer with audio/video and apply it as a remote // description. RTCOfferAnswerOptions options; options.offer_to_receive_audio = 1; options.offer_to_receive_video = 1; std::unique_ptr offer; ASSERT_TRUE(DoCreateOffer(&offer, &options)); EXPECT_TRUE(DoSetRemoteDescription(std::move(offer))); // Now create answer that rejects audio/video. options.offer_to_receive_audio = 0; options.offer_to_receive_video = 0; std::unique_ptr answer; ASSERT_TRUE(DoCreateAnswer(&answer, &options)); cricket::SessionDescription* desc = answer->description(); const cricket::ContentInfo* audio = cricket::GetFirstAudioContent(desc); const cricket::ContentInfo* video = cricket::GetFirstVideoContent(desc); ASSERT_NE(nullptr, audio); ASSERT_NE(nullptr, video); EXPECT_TRUE(audio->rejected); EXPECT_TRUE(video->rejected); } // Test that negotiation can succeed with a data channel only, and with the max // bundle policy. Previously there was a bug that prevented this. #ifdef HAVE_SCTP TEST_P(PeerConnectionInterfaceTest, DataChannelOnlyOfferWithMaxBundlePolicy) { #else TEST_P(PeerConnectionInterfaceTest, DISABLED_DataChannelOnlyOfferWithMaxBundlePolicy) { #endif // HAVE_SCTP PeerConnectionInterface::RTCConfiguration config; config.bundle_policy = PeerConnectionInterface::kBundlePolicyMaxBundle; CreatePeerConnection(config); // First, create an offer with only a data channel and apply it as a remote // description. pc_->CreateDataChannel("test", nullptr); std::unique_ptr offer; ASSERT_TRUE(DoCreateOffer(&offer, nullptr)); EXPECT_TRUE(DoSetRemoteDescription(std::move(offer))); // Create and set answer as well. std::unique_ptr answer; ASSERT_TRUE(DoCreateAnswer(&answer, nullptr)); EXPECT_TRUE(DoSetLocalDescription(std::move(answer))); } TEST_P(PeerConnectionInterfaceTest, SetBitrateWithoutMinSucceeds) { CreatePeerConnection(); BitrateSettings bitrate; bitrate.start_bitrate_bps = 100000; EXPECT_TRUE(pc_->SetBitrate(bitrate).ok()); } TEST_P(PeerConnectionInterfaceTest, SetBitrateNegativeMinFails) { CreatePeerConnection(); BitrateSettings bitrate; bitrate.min_bitrate_bps = -1; EXPECT_FALSE(pc_->SetBitrate(bitrate).ok()); } TEST_P(PeerConnectionInterfaceTest, SetBitrateCurrentLessThanMinFails) { CreatePeerConnection(); BitrateSettings bitrate; bitrate.min_bitrate_bps = 5; bitrate.start_bitrate_bps = 3; EXPECT_FALSE(pc_->SetBitrate(bitrate).ok()); } TEST_P(PeerConnectionInterfaceTest, SetBitrateCurrentNegativeFails) { CreatePeerConnection(); BitrateSettings bitrate; bitrate.start_bitrate_bps = -1; EXPECT_FALSE(pc_->SetBitrate(bitrate).ok()); } TEST_P(PeerConnectionInterfaceTest, SetBitrateMaxLessThanCurrentFails) { CreatePeerConnection(); BitrateSettings bitrate; bitrate.start_bitrate_bps = 10; bitrate.max_bitrate_bps = 8; EXPECT_FALSE(pc_->SetBitrate(bitrate).ok()); } TEST_P(PeerConnectionInterfaceTest, SetBitrateMaxLessThanMinFails) { CreatePeerConnection(); BitrateSettings bitrate; bitrate.min_bitrate_bps = 10; bitrate.max_bitrate_bps = 8; EXPECT_FALSE(pc_->SetBitrate(bitrate).ok()); } TEST_P(PeerConnectionInterfaceTest, SetBitrateMaxNegativeFails) { CreatePeerConnection(); BitrateSettings bitrate; bitrate.max_bitrate_bps = -1; EXPECT_FALSE(pc_->SetBitrate(bitrate).ok()); } // The current bitrate from BitrateSettings is currently clamped // by Call's BitrateConstraints, which comes from the SDP or a default value. // This test checks that a call to SetBitrate with a current bitrate that will // be clamped succeeds. TEST_P(PeerConnectionInterfaceTest, SetBitrateCurrentLessThanImplicitMin) { CreatePeerConnection(); BitrateSettings bitrate; bitrate.start_bitrate_bps = 1; EXPECT_TRUE(pc_->SetBitrate(bitrate).ok()); } // The following tests verify that the offer can be created correctly. TEST_P(PeerConnectionInterfaceTest, CreateOfferFailsWithInvalidOfferToReceiveAudio) { RTCOfferAnswerOptions rtc_options; // Setting offer_to_receive_audio to a value lower than kUndefined or greater // than kMaxOfferToReceiveMedia should be treated as invalid. rtc_options.offer_to_receive_audio = RTCOfferAnswerOptions::kUndefined - 1; CreatePeerConnection(); EXPECT_FALSE(CreateOfferWithOptions(rtc_options)); rtc_options.offer_to_receive_audio = RTCOfferAnswerOptions::kMaxOfferToReceiveMedia + 1; EXPECT_FALSE(CreateOfferWithOptions(rtc_options)); } TEST_P(PeerConnectionInterfaceTest, CreateOfferFailsWithInvalidOfferToReceiveVideo) { RTCOfferAnswerOptions rtc_options; // Setting offer_to_receive_video to a value lower than kUndefined or greater // than kMaxOfferToReceiveMedia should be treated as invalid. rtc_options.offer_to_receive_video = RTCOfferAnswerOptions::kUndefined - 1; CreatePeerConnection(); EXPECT_FALSE(CreateOfferWithOptions(rtc_options)); rtc_options.offer_to_receive_video = RTCOfferAnswerOptions::kMaxOfferToReceiveMedia + 1; EXPECT_FALSE(CreateOfferWithOptions(rtc_options)); } // Test that the audio and video content will be added to an offer if both // |offer_to_receive_audio| and |offer_to_receive_video| options are 1. TEST_P(PeerConnectionInterfaceTest, CreateOfferWithAudioVideoOptions) { RTCOfferAnswerOptions rtc_options; rtc_options.offer_to_receive_audio = 1; rtc_options.offer_to_receive_video = 1; std::unique_ptr offer; CreatePeerConnection(); offer = CreateOfferWithOptions(rtc_options); ASSERT_TRUE(offer); EXPECT_NE(nullptr, GetFirstAudioContent(offer->description())); EXPECT_NE(nullptr, GetFirstVideoContent(offer->description())); } // Test that only audio content will be added to the offer if only // |offer_to_receive_audio| options is 1. TEST_P(PeerConnectionInterfaceTest, CreateOfferWithAudioOnlyOptions) { RTCOfferAnswerOptions rtc_options; rtc_options.offer_to_receive_audio = 1; rtc_options.offer_to_receive_video = 0; std::unique_ptr offer; CreatePeerConnection(); offer = CreateOfferWithOptions(rtc_options); ASSERT_TRUE(offer); EXPECT_NE(nullptr, GetFirstAudioContent(offer->description())); EXPECT_EQ(nullptr, GetFirstVideoContent(offer->description())); } // Test that only video content will be added if only |offer_to_receive_video| // options is 1. TEST_P(PeerConnectionInterfaceTest, CreateOfferWithVideoOnlyOptions) { RTCOfferAnswerOptions rtc_options; rtc_options.offer_to_receive_audio = 0; rtc_options.offer_to_receive_video = 1; std::unique_ptr offer; CreatePeerConnection(); offer = CreateOfferWithOptions(rtc_options); ASSERT_TRUE(offer); EXPECT_EQ(nullptr, GetFirstAudioContent(offer->description())); EXPECT_NE(nullptr, GetFirstVideoContent(offer->description())); } // Test that no media content will be added to the offer if using default // RTCOfferAnswerOptions. TEST_P(PeerConnectionInterfaceTest, CreateOfferWithDefaultOfferAnswerOptions) { RTCOfferAnswerOptions rtc_options; std::unique_ptr offer; CreatePeerConnection(); offer = CreateOfferWithOptions(rtc_options); ASSERT_TRUE(offer); EXPECT_EQ(nullptr, GetFirstAudioContent(offer->description())); EXPECT_EQ(nullptr, GetFirstVideoContent(offer->description())); } // Test that if |ice_restart| is true, the ufrag/pwd will change, otherwise // ufrag/pwd will be the same in the new offer. TEST_P(PeerConnectionInterfaceTest, CreateOfferWithIceRestart) { CreatePeerConnection(); RTCOfferAnswerOptions rtc_options; rtc_options.ice_restart = false; rtc_options.offer_to_receive_audio = 1; std::unique_ptr offer; CreateOfferWithOptionsAsLocalDescription(&offer, rtc_options); std::string mid = cricket::GetFirstAudioContent(offer->description())->name; auto ufrag1 = offer->description()->GetTransportInfoByName(mid)->description.ice_ufrag; auto pwd1 = offer->description()->GetTransportInfoByName(mid)->description.ice_pwd; // |ice_restart| is false, the ufrag/pwd shouldn't change. CreateOfferWithOptionsAsLocalDescription(&offer, rtc_options); auto ufrag2 = offer->description()->GetTransportInfoByName(mid)->description.ice_ufrag; auto pwd2 = offer->description()->GetTransportInfoByName(mid)->description.ice_pwd; // |ice_restart| is true, the ufrag/pwd should change. rtc_options.ice_restart = true; CreateOfferWithOptionsAsLocalDescription(&offer, rtc_options); auto ufrag3 = offer->description()->GetTransportInfoByName(mid)->description.ice_ufrag; auto pwd3 = offer->description()->GetTransportInfoByName(mid)->description.ice_pwd; EXPECT_EQ(ufrag1, ufrag2); EXPECT_EQ(pwd1, pwd2); EXPECT_NE(ufrag2, ufrag3); EXPECT_NE(pwd2, pwd3); } // Test that if |use_rtp_mux| is true, the bundling will be enabled in the // offer; if it is false, there won't be any bundle group in the offer. TEST_P(PeerConnectionInterfaceTest, CreateOfferWithRtpMux) { RTCOfferAnswerOptions rtc_options; rtc_options.offer_to_receive_audio = 1; rtc_options.offer_to_receive_video = 1; std::unique_ptr offer; CreatePeerConnection(); rtc_options.use_rtp_mux = true; offer = CreateOfferWithOptions(rtc_options); ASSERT_TRUE(offer); EXPECT_NE(nullptr, GetFirstAudioContent(offer->description())); EXPECT_NE(nullptr, GetFirstVideoContent(offer->description())); EXPECT_TRUE(offer->description()->HasGroup(cricket::GROUP_TYPE_BUNDLE)); rtc_options.use_rtp_mux = false; offer = CreateOfferWithOptions(rtc_options); ASSERT_TRUE(offer); EXPECT_NE(nullptr, GetFirstAudioContent(offer->description())); EXPECT_NE(nullptr, GetFirstVideoContent(offer->description())); EXPECT_FALSE(offer->description()->HasGroup(cricket::GROUP_TYPE_BUNDLE)); } // This test ensures OnRenegotiationNeeded is called when we add track with // MediaStream -> AddTrack in the same way it is called when we add track with // PeerConnection -> AddTrack. // The test can be removed once addStream is rewritten in terms of addTrack // https://bugs.chromium.org/p/webrtc/issues/detail?id=7815 // Don't run under Unified Plan since the stream API is not available. TEST_F(PeerConnectionInterfaceTestPlanB, MediaStreamAddTrackRemoveTrackRenegotiate) { CreatePeerConnectionWithoutDtls(); rtc::scoped_refptr stream( pc_factory_->CreateLocalMediaStream(kStreamId1)); pc_->AddStream(stream); rtc::scoped_refptr audio_track( CreateAudioTrack("audio_track")); rtc::scoped_refptr video_track( CreateVideoTrack("video_track")); stream->AddTrack(audio_track); EXPECT_TRUE_WAIT(observer_.renegotiation_needed_, kTimeout); observer_.renegotiation_needed_ = false; CreateOfferReceiveAnswer(); stream->AddTrack(video_track); EXPECT_TRUE_WAIT(observer_.renegotiation_needed_, kTimeout); observer_.renegotiation_needed_ = false; CreateOfferReceiveAnswer(); stream->RemoveTrack(audio_track); EXPECT_TRUE_WAIT(observer_.renegotiation_needed_, kTimeout); observer_.renegotiation_needed_ = false; CreateOfferReceiveAnswer(); stream->RemoveTrack(video_track); EXPECT_TRUE_WAIT(observer_.renegotiation_needed_, kTimeout); observer_.renegotiation_needed_ = false; } // Tests that an error is returned if a description is applied that has fewer // media sections than the existing description. TEST_P(PeerConnectionInterfaceTest, MediaSectionCountEnforcedForSubsequentOffer) { CreatePeerConnection(); AddAudioTrack("audio_label"); AddVideoTrack("video_label"); std::unique_ptr offer; ASSERT_TRUE(DoCreateOffer(&offer, nullptr)); EXPECT_TRUE(DoSetRemoteDescription(std::move(offer))); // A remote offer with fewer media sections should be rejected. ASSERT_TRUE(DoCreateOffer(&offer, nullptr)); offer->description()->contents().pop_back(); offer->description()->contents().pop_back(); ASSERT_TRUE(offer->description()->contents().empty()); EXPECT_FALSE(DoSetRemoteDescription(std::move(offer))); std::unique_ptr answer; ASSERT_TRUE(DoCreateAnswer(&answer, nullptr)); EXPECT_TRUE(DoSetLocalDescription(std::move(answer))); // A subsequent local offer with fewer media sections should be rejected. ASSERT_TRUE(DoCreateOffer(&offer, nullptr)); offer->description()->contents().pop_back(); offer->description()->contents().pop_back(); ASSERT_TRUE(offer->description()->contents().empty()); EXPECT_FALSE(DoSetLocalDescription(std::move(offer))); } TEST_P(PeerConnectionInterfaceTest, ExtmapAllowMixedIsConfigurable) { RTCConfiguration config; // Default behavior is false. CreatePeerConnection(config); std::unique_ptr offer; ASSERT_TRUE(DoCreateOffer(&offer, nullptr)); EXPECT_FALSE(offer->description()->extmap_allow_mixed()); // Possible to set to true. config.offer_extmap_allow_mixed = true; CreatePeerConnection(config); offer.release(); ASSERT_TRUE(DoCreateOffer(&offer, nullptr)); EXPECT_TRUE(offer->description()->extmap_allow_mixed()); } INSTANTIATE_TEST_SUITE_P(PeerConnectionInterfaceTest, PeerConnectionInterfaceTest, Values(SdpSemantics::kPlanB, SdpSemantics::kUnifiedPlan)); class PeerConnectionMediaConfigTest : public ::testing::Test { protected: void SetUp() override { pcf_ = PeerConnectionFactoryForTest::CreatePeerConnectionFactoryForTest(); pcf_->Initialize(); } const cricket::MediaConfig TestCreatePeerConnection( const RTCConfiguration& config) { rtc::scoped_refptr pc( pcf_->CreatePeerConnection(config, nullptr, nullptr, &observer_)); EXPECT_TRUE(pc.get()); observer_.SetPeerConnectionInterface(pc.get()); return pc->GetConfiguration().media_config; } rtc::scoped_refptr pcf_; MockPeerConnectionObserver observer_; }; // This sanity check validates the test infrastructure itself. TEST_F(PeerConnectionMediaConfigTest, TestCreateAndClose) { PeerConnectionInterface::RTCConfiguration config; rtc::scoped_refptr pc( pcf_->CreatePeerConnection(config, nullptr, nullptr, &observer_)); EXPECT_TRUE(pc.get()); observer_.SetPeerConnectionInterface(pc.get()); // Required. pc->Close(); // No abort -> ok. SUCCEED(); } // This test verifies the default behaviour with no constraints and a // default RTCConfiguration. TEST_F(PeerConnectionMediaConfigTest, TestDefaults) { PeerConnectionInterface::RTCConfiguration config; const cricket::MediaConfig& media_config = TestCreatePeerConnection(config); EXPECT_FALSE(media_config.enable_dscp); EXPECT_TRUE(media_config.video.enable_cpu_adaptation); EXPECT_TRUE(media_config.video.enable_prerenderer_smoothing); EXPECT_FALSE(media_config.video.suspend_below_min_bitrate); EXPECT_FALSE(media_config.video.experiment_cpu_load_estimator); } // This test verifies that the enable_prerenderer_smoothing flag is // propagated from RTCConfiguration to the PeerConnection. TEST_F(PeerConnectionMediaConfigTest, TestDisablePrerendererSmoothingTrue) { PeerConnectionInterface::RTCConfiguration config; config.set_prerenderer_smoothing(false); const cricket::MediaConfig& media_config = TestCreatePeerConnection(config); EXPECT_FALSE(media_config.video.enable_prerenderer_smoothing); } // This test verifies that the experiment_cpu_load_estimator flag is // propagated from RTCConfiguration to the PeerConnection. TEST_F(PeerConnectionMediaConfigTest, TestEnableExperimentCpuLoadEstimator) { PeerConnectionInterface::RTCConfiguration config; config.set_experiment_cpu_load_estimator(true); const cricket::MediaConfig& media_config = TestCreatePeerConnection(config); EXPECT_TRUE(media_config.video.experiment_cpu_load_estimator); } // Tests a few random fields being different. TEST(RTCConfigurationTest, ComparisonOperators) { PeerConnectionInterface::RTCConfiguration a; PeerConnectionInterface::RTCConfiguration b; EXPECT_EQ(a, b); PeerConnectionInterface::RTCConfiguration c; c.servers.push_back(PeerConnectionInterface::IceServer()); EXPECT_NE(a, c); PeerConnectionInterface::RTCConfiguration d; d.type = PeerConnectionInterface::kRelay; EXPECT_NE(a, d); PeerConnectionInterface::RTCConfiguration e; e.audio_jitter_buffer_max_packets = 5; EXPECT_NE(a, e); PeerConnectionInterface::RTCConfiguration f; f.ice_connection_receiving_timeout = 1337; EXPECT_NE(a, f); PeerConnectionInterface::RTCConfiguration g; g.disable_ipv6 = true; EXPECT_NE(a, g); PeerConnectionInterface::RTCConfiguration h( PeerConnectionInterface::RTCConfigurationType::kAggressive); EXPECT_NE(a, h); } } // namespace } // namespace webrtc