/* * Copyright (c) 2017 The WebRTC project authors. All Rights Reserved. * * Use of this source code is governed by a BSD-style license * that can be found in the LICENSE file in the root of the source * tree. An additional intellectual property rights grant can be found * in the file PATENTS. All contributing project authors may * be found in the AUTHORS file in the root of the source tree. */ #include "modules/rtp_rtcp/source/rtcp_transceiver.h" #include #include #include "api/units/time_delta.h" #include "api/units/timestamp.h" #include "modules/rtp_rtcp/source/rtcp_packet/remote_estimate.h" #include "modules/rtp_rtcp/source/rtcp_packet/sender_report.h" #include "modules/rtp_rtcp/source/rtcp_packet/transport_feedback.h" #include "rtc_base/event.h" #include "rtc_base/task_queue_for_test.h" #include "system_wrappers/include/clock.h" #include "test/gmock.h" #include "test/gtest.h" #include "test/mock_transport.h" #include "test/rtcp_packet_parser.h" namespace { using ::testing::_; using ::testing::AtLeast; using ::testing::Invoke; using ::testing::InvokeWithoutArgs; using ::testing::IsNull; using ::testing::NiceMock; using ::webrtc::MockTransport; using ::webrtc::RtcpTransceiver; using ::webrtc::RtcpTransceiverConfig; using ::webrtc::SimulatedClock; using ::webrtc::TaskQueueForTest; using ::webrtc::Timestamp; using ::webrtc::rtcp::RemoteEstimate; using ::webrtc::rtcp::RtcpPacket; using ::webrtc::rtcp::TransportFeedback; using ::webrtc::test::RtcpPacketParser; class MockMediaReceiverRtcpObserver : public webrtc::MediaReceiverRtcpObserver { public: MOCK_METHOD(void, OnSenderReport, (uint32_t, webrtc::NtpTime, uint32_t), (override)); }; constexpr webrtc::TimeDelta kTimeout = webrtc::TimeDelta::Seconds(1); void WaitPostedTasks(TaskQueueForTest* queue) { rtc::Event done; queue->PostTask([&done] { done.Set(); }); ASSERT_TRUE(done.Wait(kTimeout)); } TEST(RtcpTransceiverTest, SendsRtcpOnTaskQueueWhenCreatedOffTaskQueue) { SimulatedClock clock(0); MockTransport outgoing_transport; TaskQueueForTest queue("rtcp"); RtcpTransceiverConfig config; config.clock = &clock; config.outgoing_transport = &outgoing_transport; config.task_queue = queue.Get(); EXPECT_CALL(outgoing_transport, SendRtcp(_, _)) .WillRepeatedly(InvokeWithoutArgs([&] { EXPECT_TRUE(queue.IsCurrent()); return true; })); RtcpTransceiver rtcp_transceiver(config); rtcp_transceiver.SendCompoundPacket(); WaitPostedTasks(&queue); } TEST(RtcpTransceiverTest, SendsRtcpOnTaskQueueWhenCreatedOnTaskQueue) { SimulatedClock clock(0); MockTransport outgoing_transport; TaskQueueForTest queue("rtcp"); RtcpTransceiverConfig config; config.clock = &clock; config.outgoing_transport = &outgoing_transport; config.task_queue = queue.Get(); EXPECT_CALL(outgoing_transport, SendRtcp(_, _)) .WillRepeatedly(InvokeWithoutArgs([&] { EXPECT_TRUE(queue.IsCurrent()); return true; })); std::unique_ptr rtcp_transceiver; queue.PostTask([&] { rtcp_transceiver = std::make_unique(config); rtcp_transceiver->SendCompoundPacket(); }); WaitPostedTasks(&queue); } TEST(RtcpTransceiverTest, CanBeDestroyedOnTaskQueue) { SimulatedClock clock(0); NiceMock outgoing_transport; TaskQueueForTest queue("rtcp"); RtcpTransceiverConfig config; config.clock = &clock; config.outgoing_transport = &outgoing_transport; config.task_queue = queue.Get(); auto rtcp_transceiver = std::make_unique(config); queue.PostTask([&] { // Insert a packet just before destruction to test for races. rtcp_transceiver->SendCompoundPacket(); rtcp_transceiver.reset(); }); WaitPostedTasks(&queue); } TEST(RtcpTransceiverTest, CanBeDestroyedWithoutBlocking) { SimulatedClock clock(0); TaskQueueForTest queue("rtcp"); NiceMock outgoing_transport; RtcpTransceiverConfig config; config.clock = &clock; config.outgoing_transport = &outgoing_transport; config.task_queue = queue.Get(); auto* rtcp_transceiver = new RtcpTransceiver(config); rtcp_transceiver->SendCompoundPacket(); rtc::Event done; rtc::Event heavy_task; queue.PostTask([&] { EXPECT_TRUE(heavy_task.Wait(kTimeout)); done.Set(); }); delete rtcp_transceiver; heavy_task.Set(); EXPECT_TRUE(done.Wait(kTimeout)); } TEST(RtcpTransceiverTest, MaySendPacketsAfterDestructor) { // i.e. Be careful! SimulatedClock clock(0); NiceMock outgoing_transport; // Must outlive queue below. TaskQueueForTest queue("rtcp"); RtcpTransceiverConfig config; config.clock = &clock; config.outgoing_transport = &outgoing_transport; config.task_queue = queue.Get(); auto* rtcp_transceiver = new RtcpTransceiver(config); rtc::Event heavy_task; queue.PostTask([&] { EXPECT_TRUE(heavy_task.Wait(kTimeout)); }); rtcp_transceiver->SendCompoundPacket(); delete rtcp_transceiver; EXPECT_CALL(outgoing_transport, SendRtcp); heavy_task.Set(); WaitPostedTasks(&queue); } // Use rtp timestamp to distinguish different incoming sender reports. rtc::CopyOnWriteBuffer CreateSenderReport(uint32_t ssrc, uint32_t rtp_time) { webrtc::rtcp::SenderReport sr; sr.SetSenderSsrc(ssrc); sr.SetRtpTimestamp(rtp_time); rtc::Buffer buffer = sr.Build(); // Switch to an efficient way creating CopyOnWriteBuffer from RtcpPacket when // there is one. Until then do not worry about extra memcpy in test. return rtc::CopyOnWriteBuffer(buffer.data(), buffer.size()); } TEST(RtcpTransceiverTest, DoesntPostToRtcpObserverAfterCallToRemove) { const uint32_t kRemoteSsrc = 1234; SimulatedClock clock(0); MockTransport null_transport; TaskQueueForTest queue("rtcp"); RtcpTransceiverConfig config; config.clock = &clock; config.outgoing_transport = &null_transport; config.task_queue = queue.Get(); RtcpTransceiver rtcp_transceiver(config); rtc::Event observer_deleted; auto observer = std::make_unique(); EXPECT_CALL(*observer, OnSenderReport(kRemoteSsrc, _, 1)); EXPECT_CALL(*observer, OnSenderReport(kRemoteSsrc, _, 2)).Times(0); rtcp_transceiver.AddMediaReceiverRtcpObserver(kRemoteSsrc, observer.get()); rtcp_transceiver.ReceivePacket(CreateSenderReport(kRemoteSsrc, 1)); rtcp_transceiver.RemoveMediaReceiverRtcpObserver(kRemoteSsrc, observer.get(), /*on_removed=*/[&] { observer.reset(); observer_deleted.Set(); }); rtcp_transceiver.ReceivePacket(CreateSenderReport(kRemoteSsrc, 2)); EXPECT_TRUE(observer_deleted.Wait(kTimeout)); WaitPostedTasks(&queue); } TEST(RtcpTransceiverTest, RemoveMediaReceiverRtcpObserverIsNonBlocking) { const uint32_t kRemoteSsrc = 1234; SimulatedClock clock(0); MockTransport null_transport; TaskQueueForTest queue("rtcp"); RtcpTransceiverConfig config; config.clock = &clock; config.outgoing_transport = &null_transport; config.task_queue = queue.Get(); RtcpTransceiver rtcp_transceiver(config); auto observer = std::make_unique(); rtcp_transceiver.AddMediaReceiverRtcpObserver(kRemoteSsrc, observer.get()); rtc::Event queue_blocker; rtc::Event observer_deleted; queue.PostTask([&] { EXPECT_TRUE(queue_blocker.Wait(kTimeout)); }); rtcp_transceiver.RemoveMediaReceiverRtcpObserver(kRemoteSsrc, observer.get(), /*on_removed=*/[&] { observer.reset(); observer_deleted.Set(); }); EXPECT_THAT(observer, Not(IsNull())); queue_blocker.Set(); EXPECT_TRUE(observer_deleted.Wait(kTimeout)); } TEST(RtcpTransceiverTest, CanCallSendCompoundPacketFromAnyThread) { SimulatedClock clock(0); MockTransport outgoing_transport; TaskQueueForTest queue("rtcp"); RtcpTransceiverConfig config; config.clock = &clock; config.outgoing_transport = &outgoing_transport; config.task_queue = queue.Get(); EXPECT_CALL(outgoing_transport, SendRtcp(_, _)) // If test is slow, a periodic task may send an extra packet. .Times(AtLeast(3)) .WillRepeatedly(InvokeWithoutArgs([&] { EXPECT_TRUE(queue.IsCurrent()); return true; })); RtcpTransceiver rtcp_transceiver(config); // Call from the construction thread. rtcp_transceiver.SendCompoundPacket(); // Call from the same queue transceiver use for processing. queue.PostTask([&] { rtcp_transceiver.SendCompoundPacket(); }); // Call from unrelated task queue. TaskQueueForTest queue_send("send_packet"); queue_send.PostTask([&] { rtcp_transceiver.SendCompoundPacket(); }); WaitPostedTasks(&queue_send); WaitPostedTasks(&queue); } TEST(RtcpTransceiverTest, DoesntSendPacketsAfterStopCallback) { SimulatedClock clock(0); NiceMock outgoing_transport; TaskQueueForTest queue("rtcp"); RtcpTransceiverConfig config; config.clock = &clock; config.outgoing_transport = &outgoing_transport; config.task_queue = queue.Get(); config.schedule_periodic_compound_packets = true; auto rtcp_transceiver = std::make_unique(config); rtc::Event done; rtcp_transceiver->SendCompoundPacket(); rtcp_transceiver->Stop([&] { EXPECT_CALL(outgoing_transport, SendRtcp).Times(0); done.Set(); }); rtcp_transceiver = nullptr; EXPECT_TRUE(done.Wait(kTimeout)); } TEST(RtcpTransceiverTest, SendsCombinedRtcpPacketOnTaskQueue) { static constexpr uint32_t kSenderSsrc = 12345; SimulatedClock clock(0); MockTransport outgoing_transport; TaskQueueForTest queue("rtcp"); RtcpTransceiverConfig config; config.clock = &clock; config.feedback_ssrc = kSenderSsrc; config.outgoing_transport = &outgoing_transport; config.task_queue = queue.Get(); config.schedule_periodic_compound_packets = false; RtcpTransceiver rtcp_transceiver(config); EXPECT_CALL(outgoing_transport, SendRtcp) .WillOnce([&](const uint8_t* buffer, size_t size) { EXPECT_TRUE(queue.IsCurrent()); RtcpPacketParser rtcp_parser; rtcp_parser.Parse(buffer, size); EXPECT_EQ(rtcp_parser.transport_feedback()->num_packets(), 1); EXPECT_EQ(rtcp_parser.transport_feedback()->sender_ssrc(), kSenderSsrc); EXPECT_EQ(rtcp_parser.app()->num_packets(), 1); EXPECT_EQ(rtcp_parser.app()->sender_ssrc(), kSenderSsrc); return true; }); // Create minimalistic transport feedback packet. std::vector> packets; auto transport_feedback = std::make_unique(); transport_feedback->AddReceivedPacket(321, Timestamp::Millis(10)); packets.push_back(std::move(transport_feedback)); auto remote_estimate = std::make_unique(); packets.push_back(std::move(remote_estimate)); rtcp_transceiver.SendCombinedRtcpPacket(std::move(packets)); WaitPostedTasks(&queue); } TEST(RtcpTransceiverTest, SendFrameIntraRequestDefaultsToNewRequest) { static constexpr uint32_t kSenderSsrc = 12345; SimulatedClock clock(0); MockTransport outgoing_transport; TaskQueueForTest queue("rtcp"); RtcpTransceiverConfig config; config.clock = &clock; config.feedback_ssrc = kSenderSsrc; config.outgoing_transport = &outgoing_transport; config.task_queue = queue.Get(); config.schedule_periodic_compound_packets = false; RtcpTransceiver rtcp_transceiver(config); uint8_t first_seq_nr; EXPECT_CALL(outgoing_transport, SendRtcp) .WillOnce([&](const uint8_t* buffer, size_t size) { EXPECT_TRUE(queue.IsCurrent()); RtcpPacketParser rtcp_parser; rtcp_parser.Parse(buffer, size); EXPECT_EQ(rtcp_parser.fir()->requests()[0].ssrc, kSenderSsrc); first_seq_nr = rtcp_parser.fir()->requests()[0].seq_nr; return true; }) .WillOnce([&](const uint8_t* buffer, size_t size) { EXPECT_TRUE(queue.IsCurrent()); RtcpPacketParser rtcp_parser; rtcp_parser.Parse(buffer, size); EXPECT_EQ(rtcp_parser.fir()->requests()[0].ssrc, kSenderSsrc); EXPECT_EQ(rtcp_parser.fir()->requests()[0].seq_nr, first_seq_nr + 1); return true; }); // Send 2 FIR packets because the sequence numbers are incremented after, // sending. One wouldn't be able to differentiate the new_request. rtcp_transceiver.SendFullIntraRequest({kSenderSsrc}); rtcp_transceiver.SendFullIntraRequest({kSenderSsrc}); WaitPostedTasks(&queue); } } // namespace