/* * Copyright (c) 2019 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/rtp_packetizer_av1.h" #include #include #include #include #include #include "api/array_view.h" #include "api/scoped_refptr.h" #include "api/video/encoded_image.h" #include "modules/rtp_rtcp/source/rtp_packet_to_send.h" #include "modules/rtp_rtcp/source/rtp_packetizer_av1_test_helper.h" #include "modules/rtp_rtcp/source/video_rtp_depacketizer_av1.h" #include "test/gmock.h" #include "test/gtest.h" namespace webrtc { namespace { using ::testing::Each; using ::testing::ElementsAre; using ::testing::ElementsAreArray; using ::testing::Le; using ::testing::SizeIs; constexpr uint8_t kNewCodedVideoSequenceBit = 0b00'00'1000; // Wrapper around rtp_packet to make it look like container of payload bytes. struct RtpPayload { using value_type = rtc::ArrayView::value_type; using const_iterator = rtc::ArrayView::const_iterator; RtpPayload() : rtp_packet(/*extensions=*/nullptr) {} RtpPayload& operator=(RtpPayload&&) = default; RtpPayload(RtpPayload&&) = default; const_iterator begin() const { return rtp_packet.payload().begin(); } const_iterator end() const { return rtp_packet.payload().end(); } const uint8_t* data() const { return rtp_packet.payload().data(); } size_t size() const { return rtp_packet.payload().size(); } uint8_t aggregation_header() const { return rtp_packet.payload()[0]; } RtpPacketToSend rtp_packet; }; // Wrapper around frame pointer to make it look like container of bytes with // nullptr frame look like empty container. class Av1Frame { public: using value_type = uint8_t; using const_iterator = const uint8_t*; explicit Av1Frame(rtc::scoped_refptr frame) : frame_(std::move(frame)) {} const_iterator begin() const { return frame_ ? frame_->data() : nullptr; } const_iterator end() const { return frame_ ? (frame_->data() + frame_->size()) : nullptr; } private: rtc::scoped_refptr frame_; }; std::vector Packetize( rtc::ArrayView payload, RtpPacketizer::PayloadSizeLimits limits, VideoFrameType frame_type = VideoFrameType::kVideoFrameDelta, bool is_last_frame_in_picture = true) { // Run code under test. RtpPacketizerAv1 packetizer(payload, limits, frame_type, is_last_frame_in_picture); // Convert result into structure that is easier to run expectation against. std::vector result(packetizer.NumPackets()); for (RtpPayload& rtp_payload : result) { EXPECT_TRUE(packetizer.NextPacket(&rtp_payload.rtp_packet)); } return result; } Av1Frame ReassembleFrame(rtc::ArrayView rtp_payloads) { std::vector> payloads(rtp_payloads.size()); for (size_t i = 0; i < rtp_payloads.size(); ++i) { payloads[i] = rtp_payloads[i]; } return Av1Frame(VideoRtpDepacketizerAv1().AssembleFrame(payloads)); } TEST(RtpPacketizerAv1Test, PacketizeOneObuWithoutSizeAndExtension) { auto kFrame = BuildAv1Frame({Av1Obu(kAv1ObuTypeFrame) .WithoutSize() .WithPayload({1, 2, 3, 4, 5, 6, 7})}); EXPECT_THAT(Packetize(kFrame, {}), ElementsAre(ElementsAre(0b00'01'0000, // aggregation header kAv1ObuTypeFrame, 1, 2, 3, 4, 5, 6, 7))); } TEST(RtpPacketizerAv1Test, PacketizeOneObuWithoutSizeWithExtension) { auto kFrame = BuildAv1Frame({Av1Obu(kAv1ObuTypeFrame) .WithoutSize() .WithExtension(kAv1ObuExtensionS1T1) .WithPayload({2, 3, 4, 5, 6, 7})}); EXPECT_THAT( Packetize(kFrame, {}), ElementsAre(ElementsAre(0b00'01'0000, // aggregation header kAv1ObuTypeFrame | kAv1ObuExtensionPresentBit, kAv1ObuExtensionS1T1, 2, 3, 4, 5, 6, 7))); } TEST(RtpPacketizerAv1Test, RemovesObuSizeFieldWithoutExtension) { auto kFrame = BuildAv1Frame( {Av1Obu(kAv1ObuTypeFrame).WithPayload({11, 12, 13, 14, 15, 16, 17})}); EXPECT_THAT( Packetize(kFrame, {}), ElementsAre(ElementsAre(0b00'01'0000, // aggregation header kAv1ObuTypeFrame, 11, 12, 13, 14, 15, 16, 17))); } TEST(RtpPacketizerAv1Test, RemovesObuSizeFieldWithExtension) { auto kFrame = BuildAv1Frame({Av1Obu(kAv1ObuTypeFrame) .WithExtension(kAv1ObuExtensionS1T1) .WithPayload({1, 2, 3, 4, 5, 6, 7})}); EXPECT_THAT( Packetize(kFrame, {}), ElementsAre(ElementsAre(0b00'01'0000, // aggregation header kAv1ObuTypeFrame | kAv1ObuExtensionPresentBit, kAv1ObuExtensionS1T1, 1, 2, 3, 4, 5, 6, 7))); } TEST(RtpPacketizerAv1Test, OmitsSizeForLastObuWhenThreeObusFitsIntoThePacket) { auto kFrame = BuildAv1Frame( {Av1Obu(kAv1ObuTypeSequenceHeader).WithPayload({1, 2, 3, 4, 5, 6}), Av1Obu(kAv1ObuTypeMetadata).WithPayload({11, 12, 13, 14}), Av1Obu(kAv1ObuTypeFrame).WithPayload({21, 22, 23, 24, 25, 26})}); EXPECT_THAT(Packetize(kFrame, {}), ElementsAre(ElementsAre( 0b00'11'0000, // aggregation header 7, kAv1ObuTypeSequenceHeader, 1, 2, 3, 4, 5, 6, // 5, kAv1ObuTypeMetadata, 11, 12, 13, 14, // kAv1ObuTypeFrame, 21, 22, 23, 24, 25, 26))); } TEST(RtpPacketizerAv1Test, UseSizeForAllObusWhenFourObusFitsIntoThePacket) { auto kFrame = BuildAv1Frame( {Av1Obu(kAv1ObuTypeSequenceHeader).WithPayload({1, 2, 3, 4, 5, 6}), Av1Obu(kAv1ObuTypeMetadata).WithPayload({11, 12, 13, 14}), Av1Obu(kAv1ObuTypeFrameHeader).WithPayload({21, 22, 23}), Av1Obu(kAv1ObuTypeTileGroup).WithPayload({31, 32, 33, 34, 35, 36})}); EXPECT_THAT(Packetize(kFrame, {}), ElementsAre(ElementsAre( 0b00'00'0000, // aggregation header 7, kAv1ObuTypeSequenceHeader, 1, 2, 3, 4, 5, 6, // 5, kAv1ObuTypeMetadata, 11, 12, 13, 14, // 4, kAv1ObuTypeFrameHeader, 21, 22, 23, // 7, kAv1ObuTypeTileGroup, 31, 32, 33, 34, 35, 36))); } TEST(RtpPacketizerAv1Test, DiscardsTemporalDelimiterAndTileListObu) { auto kFrame = BuildAv1Frame( {Av1Obu(kAv1ObuTypeTemporalDelimiter), Av1Obu(kAv1ObuTypeMetadata), Av1Obu(kAv1ObuTypeTileList).WithPayload({1, 2, 3, 4, 5, 6}), Av1Obu(kAv1ObuTypeFrameHeader).WithPayload({21, 22, 23}), Av1Obu(kAv1ObuTypeTileGroup).WithPayload({31, 32, 33, 34, 35, 36})}); EXPECT_THAT( Packetize(kFrame, {}), ElementsAre(ElementsAre(0b00'11'0000, // aggregation header 1, kAv1ObuTypeMetadata, // 4, kAv1ObuTypeFrameHeader, 21, 22, 23, // kAv1ObuTypeTileGroup, 31, 32, 33, 34, 35, 36))); } TEST(RtpPacketizerAv1Test, SplitTwoObusIntoTwoPacketForceSplitObuHeader) { // Craft expected payloads so that there is only one way to split original // frame into two packets. const uint8_t kExpectPayload1[6] = { 0b01'10'0000, // aggregation_header 3, kAv1ObuTypeFrameHeader | kAv1ObuExtensionPresentBit, kAv1ObuExtensionS1T1, 21, // kAv1ObuTypeTileGroup | kAv1ObuExtensionPresentBit}; const uint8_t kExpectPayload2[6] = {0b10'01'0000, // aggregation_header kAv1ObuExtensionS1T1, 11, 12, 13, 14}; auto kFrame = BuildAv1Frame({Av1Obu(kAv1ObuTypeFrameHeader) .WithExtension(kAv1ObuExtensionS1T1) .WithPayload({21}), Av1Obu(kAv1ObuTypeTileGroup) .WithExtension(kAv1ObuExtensionS1T1) .WithPayload({11, 12, 13, 14})}); RtpPacketizer::PayloadSizeLimits limits; limits.max_payload_len = 6; auto payloads = Packetize(kFrame, limits); EXPECT_THAT(payloads, ElementsAre(ElementsAreArray(kExpectPayload1), ElementsAreArray(kExpectPayload2))); } TEST(RtpPacketizerAv1Test, SetsNbitAtTheFirstPacketOfAKeyFrameWithSequenceHeader) { auto kFrame = BuildAv1Frame( {Av1Obu(kAv1ObuTypeSequenceHeader).WithPayload({1, 2, 3, 4, 5, 6, 7})}); RtpPacketizer::PayloadSizeLimits limits; limits.max_payload_len = 6; auto packets = Packetize(kFrame, limits, VideoFrameType::kVideoFrameKey); ASSERT_THAT(packets, SizeIs(2)); EXPECT_TRUE(packets[0].aggregation_header() & kNewCodedVideoSequenceBit); EXPECT_FALSE(packets[1].aggregation_header() & kNewCodedVideoSequenceBit); } TEST(RtpPacketizerAv1Test, DoesntSetNbitAtThePacketsOfAKeyFrameWithoutSequenceHeader) { auto kFrame = BuildAv1Frame( {Av1Obu(kAv1ObuTypeFrame).WithPayload({1, 2, 3, 4, 5, 6, 7})}); RtpPacketizer::PayloadSizeLimits limits; limits.max_payload_len = 6; auto packets = Packetize(kFrame, limits, VideoFrameType::kVideoFrameKey); ASSERT_THAT(packets, SizeIs(2)); EXPECT_FALSE(packets[0].aggregation_header() & kNewCodedVideoSequenceBit); EXPECT_FALSE(packets[1].aggregation_header() & kNewCodedVideoSequenceBit); } TEST(RtpPacketizerAv1Test, DoesntSetNbitAtThePacketsOfADeltaFrame) { // Even when that delta frame starts with a (redundant) sequence header. auto kFrame = BuildAv1Frame( {Av1Obu(kAv1ObuTypeSequenceHeader).WithPayload({1, 2, 3, 4, 5, 6, 7})}); RtpPacketizer::PayloadSizeLimits limits; limits.max_payload_len = 6; auto packets = Packetize(kFrame, limits, VideoFrameType::kVideoFrameDelta); ASSERT_THAT(packets, SizeIs(2)); EXPECT_FALSE(packets[0].aggregation_header() & kNewCodedVideoSequenceBit); EXPECT_FALSE(packets[1].aggregation_header() & kNewCodedVideoSequenceBit); } // There are multiple valid reasonable ways to split payload into multiple // packets, do not validate current choice, instead use RtpDepacketizer // to validate frame is reconstracted to the same one. Note: since // RtpDepacketizer always inserts obu_size fields in the output, use frame where // each obu has obu_size fields for more streight forward validation. TEST(RtpPacketizerAv1Test, SplitSingleObuIntoTwoPackets) { auto kFrame = BuildAv1Frame({Av1Obu(kAv1ObuTypeFrame) .WithPayload({11, 12, 13, 14, 15, 16, 17, 18, 19})}); RtpPacketizer::PayloadSizeLimits limits; limits.max_payload_len = 8; auto payloads = Packetize(kFrame, limits); EXPECT_THAT(payloads, ElementsAre(SizeIs(Le(8u)), SizeIs(Le(8u)))); // Use RtpDepacketizer to validate the split. EXPECT_THAT(ReassembleFrame(payloads), ElementsAreArray(kFrame)); } TEST(RtpPacketizerAv1Test, SplitSingleObuIntoManyPackets) { auto kFrame = BuildAv1Frame( {Av1Obu(kAv1ObuTypeFrame).WithPayload(std::vector(1200, 27))}); RtpPacketizer::PayloadSizeLimits limits; limits.max_payload_len = 100; auto payloads = Packetize(kFrame, limits); EXPECT_THAT(payloads, SizeIs(13u)); EXPECT_THAT(payloads, Each(SizeIs(Le(100u)))); // Use RtpDepacketizer to validate the split. EXPECT_THAT(ReassembleFrame(payloads), ElementsAreArray(kFrame)); } TEST(RtpPacketizerAv1Test, SetMarkerBitForLastPacketInEndOfPictureFrame) { auto kFrame = BuildAv1Frame( {Av1Obu(kAv1ObuTypeFrame).WithPayload(std::vector(200, 27))}); RtpPacketizer::PayloadSizeLimits limits; limits.max_payload_len = 100; auto payloads = Packetize(kFrame, limits, VideoFrameType::kVideoFrameDelta, /*is_last_frame_in_picture=*/true); ASSERT_THAT(payloads, SizeIs(3u)); EXPECT_FALSE(payloads[0].rtp_packet.Marker()); EXPECT_FALSE(payloads[1].rtp_packet.Marker()); EXPECT_TRUE(payloads[2].rtp_packet.Marker()); } TEST(RtpPacketizerAv1Test, DoesntSetMarkerBitForPacketsNotInEndOfPictureFrame) { auto kFrame = BuildAv1Frame( {Av1Obu(kAv1ObuTypeFrame).WithPayload(std::vector(200, 27))}); RtpPacketizer::PayloadSizeLimits limits; limits.max_payload_len = 100; auto payloads = Packetize(kFrame, limits, VideoFrameType::kVideoFrameDelta, /*is_last_frame_in_picture=*/false); ASSERT_THAT(payloads, SizeIs(3u)); EXPECT_FALSE(payloads[0].rtp_packet.Marker()); EXPECT_FALSE(payloads[1].rtp_packet.Marker()); EXPECT_FALSE(payloads[2].rtp_packet.Marker()); } TEST(RtpPacketizerAv1Test, SplitTwoObusIntoTwoPackets) { // 2nd OBU is too large to fit into one packet, so its head would be in the // same packet as the 1st OBU. auto kFrame = BuildAv1Frame( {Av1Obu(kAv1ObuTypeSequenceHeader).WithPayload({11, 12}), Av1Obu(kAv1ObuTypeFrame).WithPayload({1, 2, 3, 4, 5, 6, 7, 8, 9})}); RtpPacketizer::PayloadSizeLimits limits; limits.max_payload_len = 8; auto payloads = Packetize(kFrame, limits); EXPECT_THAT(payloads, ElementsAre(SizeIs(Le(8u)), SizeIs(Le(8u)))); // Use RtpDepacketizer to validate the split. EXPECT_THAT(ReassembleFrame(payloads), ElementsAreArray(kFrame)); } TEST(RtpPacketizerAv1Test, SplitSingleObuIntoTwoPacketsBecauseOfSinglePacketLimit) { auto kFrame = BuildAv1Frame({Av1Obu(kAv1ObuTypeFrame) .WithPayload({11, 12, 13, 14, 15, 16, 17, 18, 19})}); RtpPacketizer::PayloadSizeLimits limits; limits.max_payload_len = 10; limits.single_packet_reduction_len = 8; auto payloads = Packetize(kFrame, limits); EXPECT_THAT(payloads, ElementsAre(SizeIs(Le(10u)), SizeIs(Le(10u)))); EXPECT_THAT(ReassembleFrame(payloads), ElementsAreArray(kFrame)); } } // namespace } // namespace webrtc