blob: 7604de6fba4e2165a79fbb49fe3872912eec6de0 [file] [log] [blame]
/*
* Copyright (c) 2015 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/pacing/packet_router.h"
#include <cstddef>
#include <cstdint>
#include <memory>
#include <utility>
#include "api/units/time_delta.h"
#include "modules/rtp_rtcp/include/rtp_header_extension_map.h"
#include "modules/rtp_rtcp/mocks/mock_rtp_rtcp.h"
#include "modules/rtp_rtcp/source/rtcp_packet/transport_feedback.h"
#include "rtc_base/checks.h"
#include "rtc_base/fake_clock.h"
#include "test/gmock.h"
#include "test/gtest.h"
namespace webrtc {
// TODO(eladalon): Restructure and/or replace the existing monolithic tests
// (only some of the test are monolithic) according to the new
// guidelines - small tests for one thing at a time.
// (I'm not removing any tests during CL, so as to demonstrate no regressions.)
namespace {
using ::testing::_;
using ::testing::AnyNumber;
using ::testing::AtLeast;
using ::testing::ElementsAreArray;
using ::testing::Field;
using ::testing::Gt;
using ::testing::Le;
using ::testing::NiceMock;
using ::testing::Pointee;
using ::testing::Property;
using ::testing::Return;
using ::testing::SaveArg;
constexpr int kProbeMinProbes = 5;
constexpr int kProbeMinBytes = 1000;
} // namespace
class PacketRouterTest : public ::testing::Test {
public:
PacketRouterTest() {
extension_manager.Register<TransportSequenceNumber>(/*id=*/1);
}
protected:
std::unique_ptr<RtpPacketToSend> BuildRtpPacket(uint32_t ssrc) {
std::unique_ptr<RtpPacketToSend> packet =
std::make_unique<RtpPacketToSend>(&extension_manager);
packet->SetSsrc(ssrc);
return packet;
}
PacketRouter packet_router_;
RtpHeaderExtensionMap extension_manager;
};
TEST_F(PacketRouterTest, Sanity_NoModuleRegistered_GeneratePadding) {
constexpr DataSize bytes = DataSize::Bytes(300);
const PacedPacketInfo paced_info(1, kProbeMinProbes, kProbeMinBytes);
EXPECT_TRUE(packet_router_.GeneratePadding(bytes).empty());
}
TEST_F(PacketRouterTest, Sanity_NoModuleRegistered_SendRemb) {
const std::vector<uint32_t> ssrcs = {1, 2, 3};
constexpr uint32_t bitrate_bps = 10000;
// Expect not to crash
packet_router_.SendRemb(bitrate_bps, ssrcs);
}
TEST_F(PacketRouterTest, Sanity_NoModuleRegistered_SendTransportFeedback) {
std::vector<std::unique_ptr<rtcp::RtcpPacket>> feedback;
feedback.push_back(std::make_unique<rtcp::TransportFeedback>());
// Expect not to crash
packet_router_.SendCombinedRtcpPacket(std::move(feedback));
}
TEST_F(PacketRouterTest, GeneratePaddingPrioritizesRtx) {
// Two RTP modules. The first (prioritized due to rtx) isn't sending media so
// should not be called.
const uint16_t kSsrc1 = 1234;
const uint16_t kSsrc2 = 4567;
NiceMock<MockRtpRtcpInterface> rtp_1;
ON_CALL(rtp_1, RtxSendStatus()).WillByDefault(Return(kRtxRedundantPayloads));
ON_CALL(rtp_1, SSRC()).WillByDefault(Return(kSsrc1));
ON_CALL(rtp_1, SupportsPadding).WillByDefault(Return(false));
NiceMock<MockRtpRtcpInterface> rtp_2;
ON_CALL(rtp_2, RtxSendStatus()).WillByDefault(Return(kRtxOff));
ON_CALL(rtp_2, SSRC()).WillByDefault(Return(kSsrc2));
ON_CALL(rtp_2, SupportsPadding).WillByDefault(Return(true));
packet_router_.AddSendRtpModule(&rtp_1, false);
packet_router_.AddSendRtpModule(&rtp_2, false);
const size_t kPaddingSize = 123;
const size_t kExpectedPaddingPackets = 1;
EXPECT_CALL(rtp_1, GeneratePadding(_)).Times(0);
EXPECT_CALL(rtp_2, GeneratePadding(kPaddingSize))
.WillOnce([&](size_t padding_size) {
return std::vector<std::unique_ptr<RtpPacketToSend>>(
kExpectedPaddingPackets);
});
auto generated_padding =
packet_router_.GeneratePadding(DataSize::Bytes(kPaddingSize));
EXPECT_EQ(generated_padding.size(), kExpectedPaddingPackets);
packet_router_.RemoveSendRtpModule(&rtp_1);
packet_router_.RemoveSendRtpModule(&rtp_2);
}
TEST_F(PacketRouterTest, GeneratePaddingPrioritizesVideo) {
// Two RTP modules. Neither support RTX, both support padding,
// but the first one is for audio and second for video.
const uint16_t kSsrc1 = 1234;
const uint16_t kSsrc2 = 4567;
const size_t kPaddingSize = 123;
const size_t kExpectedPaddingPackets = 1;
auto generate_padding = [&](size_t padding_size) {
return std::vector<std::unique_ptr<RtpPacketToSend>>(
kExpectedPaddingPackets);
};
NiceMock<MockRtpRtcpInterface> audio_module;
ON_CALL(audio_module, RtxSendStatus()).WillByDefault(Return(kRtxOff));
ON_CALL(audio_module, SSRC()).WillByDefault(Return(kSsrc1));
ON_CALL(audio_module, SupportsPadding).WillByDefault(Return(true));
ON_CALL(audio_module, IsAudioConfigured).WillByDefault(Return(true));
NiceMock<MockRtpRtcpInterface> video_module;
ON_CALL(video_module, RtxSendStatus()).WillByDefault(Return(kRtxOff));
ON_CALL(video_module, SSRC()).WillByDefault(Return(kSsrc2));
ON_CALL(video_module, SupportsPadding).WillByDefault(Return(true));
ON_CALL(video_module, IsAudioConfigured).WillByDefault(Return(false));
// First add only the audio module. Since this is the only choice we have,
// padding should be sent on the audio ssrc.
packet_router_.AddSendRtpModule(&audio_module, false);
EXPECT_CALL(audio_module, GeneratePadding(kPaddingSize))
.WillOnce(generate_padding);
packet_router_.GeneratePadding(DataSize::Bytes(kPaddingSize));
// Add the video module, this should now be prioritized since we cannot
// guarantee that audio packets will be included in the BWE.
packet_router_.AddSendRtpModule(&video_module, false);
EXPECT_CALL(audio_module, GeneratePadding).Times(0);
EXPECT_CALL(video_module, GeneratePadding(kPaddingSize))
.WillOnce(generate_padding);
packet_router_.GeneratePadding(DataSize::Bytes(kPaddingSize));
// Remove and the add audio module again. Module order shouldn't matter;
// video should still be prioritized.
packet_router_.RemoveSendRtpModule(&audio_module);
packet_router_.AddSendRtpModule(&audio_module, false);
EXPECT_CALL(audio_module, GeneratePadding).Times(0);
EXPECT_CALL(video_module, GeneratePadding(kPaddingSize))
.WillOnce(generate_padding);
packet_router_.GeneratePadding(DataSize::Bytes(kPaddingSize));
// Remove and the video module, we should fall back to padding on the
// audio module again.
packet_router_.RemoveSendRtpModule(&video_module);
EXPECT_CALL(audio_module, GeneratePadding(kPaddingSize))
.WillOnce(generate_padding);
packet_router_.GeneratePadding(DataSize::Bytes(kPaddingSize));
packet_router_.RemoveSendRtpModule(&audio_module);
}
TEST_F(PacketRouterTest, PadsOnLastActiveMediaStream) {
const uint16_t kSsrc1 = 1234;
const uint16_t kSsrc2 = 4567;
const uint16_t kSsrc3 = 8901;
// First two rtp modules send media and have rtx.
NiceMock<MockRtpRtcpInterface> rtp_1;
EXPECT_CALL(rtp_1, SSRC()).WillRepeatedly(Return(kSsrc1));
EXPECT_CALL(rtp_1, SupportsPadding).WillRepeatedly(Return(true));
EXPECT_CALL(rtp_1, SupportsRtxPayloadPadding).WillRepeatedly(Return(true));
EXPECT_CALL(rtp_1, TrySendPacket).WillRepeatedly(Return(false));
EXPECT_CALL(rtp_1, TrySendPacket(
Pointee(Property(&RtpPacketToSend::Ssrc, kSsrc1)), _))
.WillRepeatedly(Return(true));
NiceMock<MockRtpRtcpInterface> rtp_2;
EXPECT_CALL(rtp_2, SSRC()).WillRepeatedly(Return(kSsrc2));
EXPECT_CALL(rtp_2, SupportsPadding).WillRepeatedly(Return(true));
EXPECT_CALL(rtp_2, SupportsRtxPayloadPadding).WillRepeatedly(Return(true));
EXPECT_CALL(rtp_2, TrySendPacket).WillRepeatedly(Return(false));
EXPECT_CALL(rtp_2, TrySendPacket(
Pointee(Property(&RtpPacketToSend::Ssrc, kSsrc2)), _))
.WillRepeatedly(Return(true));
// Third module is sending media, but does not support rtx.
NiceMock<MockRtpRtcpInterface> rtp_3;
EXPECT_CALL(rtp_3, SSRC()).WillRepeatedly(Return(kSsrc3));
EXPECT_CALL(rtp_3, SupportsPadding).WillRepeatedly(Return(true));
EXPECT_CALL(rtp_3, SupportsRtxPayloadPadding).WillRepeatedly(Return(false));
EXPECT_CALL(rtp_3, TrySendPacket).WillRepeatedly(Return(false));
EXPECT_CALL(rtp_3, TrySendPacket(
Pointee(Property(&RtpPacketToSend::Ssrc, kSsrc3)), _))
.WillRepeatedly(Return(true));
packet_router_.AddSendRtpModule(&rtp_1, false);
packet_router_.AddSendRtpModule(&rtp_2, false);
packet_router_.AddSendRtpModule(&rtp_3, false);
const size_t kPaddingBytes = 100;
// Initially, padding will be sent on last added rtp module that sends media
// and supports rtx.
EXPECT_CALL(rtp_2, GeneratePadding(kPaddingBytes))
.Times(1)
.WillOnce([&](size_t target_size_bytes) {
std::vector<std::unique_ptr<RtpPacketToSend>> packets;
packets.push_back(BuildRtpPacket(kSsrc2));
return packets;
});
packet_router_.GeneratePadding(DataSize::Bytes(kPaddingBytes));
// Send media on first module. Padding should be sent on that module.
packet_router_.SendPacket(BuildRtpPacket(kSsrc1), PacedPacketInfo());
EXPECT_CALL(rtp_1, GeneratePadding(kPaddingBytes))
.Times(1)
.WillOnce([&](size_t target_size_bytes) {
std::vector<std::unique_ptr<RtpPacketToSend>> packets;
packets.push_back(BuildRtpPacket(kSsrc1));
return packets;
});
packet_router_.GeneratePadding(DataSize::Bytes(kPaddingBytes));
// Send media on second module. Padding should be sent there.
packet_router_.SendPacket(BuildRtpPacket(kSsrc2), PacedPacketInfo());
// If the last active module is removed, and no module sends media before
// the next padding request, and arbitrary module will be selected.
packet_router_.OnBatchComplete();
packet_router_.RemoveSendRtpModule(&rtp_2);
// Send on and then remove all remaining modules.
RtpRtcpInterface* last_send_module;
EXPECT_CALL(rtp_1, GeneratePadding(kPaddingBytes))
.Times(1)
.WillOnce([&](size_t target_size_bytes) {
last_send_module = &rtp_1;
std::vector<std::unique_ptr<RtpPacketToSend>> packets;
packets.push_back(BuildRtpPacket(kSsrc1));
return packets;
});
EXPECT_CALL(rtp_3, GeneratePadding(kPaddingBytes))
.Times(1)
.WillOnce([&](size_t target_size_bytes) {
last_send_module = &rtp_3;
std::vector<std::unique_ptr<RtpPacketToSend>> packets;
packets.push_back(BuildRtpPacket(kSsrc3));
return packets;
});
for (int i = 0; i < 2; ++i) {
last_send_module = nullptr;
packet_router_.GeneratePadding(DataSize::Bytes(kPaddingBytes));
EXPECT_NE(last_send_module, nullptr);
packet_router_.RemoveSendRtpModule(last_send_module);
}
}
TEST_F(PacketRouterTest, AllocatesTransportSequenceNumbers) {
const uint16_t kStartSeq = 0xFFF0;
const size_t kNumPackets = 32;
const uint16_t kSsrc1 = 1234;
PacketRouter packet_router(kStartSeq - 1);
NiceMock<MockRtpRtcpInterface> rtp_1;
EXPECT_CALL(rtp_1, SSRC()).WillRepeatedly(Return(kSsrc1));
EXPECT_CALL(rtp_1, TrySendPacket).WillRepeatedly(Return(true));
packet_router.AddSendRtpModule(&rtp_1, false);
for (size_t i = 0; i < kNumPackets; ++i) {
auto packet = BuildRtpPacket(kSsrc1);
EXPECT_TRUE(packet->ReserveExtension<TransportSequenceNumber>());
packet_router.SendPacket(std::move(packet), PacedPacketInfo());
uint32_t expected_unwrapped_seq = static_cast<uint32_t>(kStartSeq) + i;
EXPECT_EQ(static_cast<uint16_t>(expected_unwrapped_seq & 0xFFFF),
packet_router.CurrentTransportSequenceNumber());
}
packet_router.OnBatchComplete();
packet_router.RemoveSendRtpModule(&rtp_1);
}
TEST_F(PacketRouterTest, SendTransportFeedback) {
NiceMock<MockRtpRtcpInterface> rtp_1;
NiceMock<MockRtpRtcpInterface> rtp_2;
ON_CALL(rtp_1, RTCP()).WillByDefault(Return(RtcpMode::kCompound));
ON_CALL(rtp_2, RTCP()).WillByDefault(Return(RtcpMode::kCompound));
packet_router_.AddSendRtpModule(&rtp_1, false);
packet_router_.AddReceiveRtpModule(&rtp_2, false);
std::vector<std::unique_ptr<rtcp::RtcpPacket>> feedback;
feedback.push_back(std::make_unique<rtcp::TransportFeedback>());
EXPECT_CALL(rtp_1, SendCombinedRtcpPacket);
packet_router_.SendCombinedRtcpPacket(std::move(feedback));
packet_router_.RemoveSendRtpModule(&rtp_1);
EXPECT_CALL(rtp_2, SendCombinedRtcpPacket);
std::vector<std::unique_ptr<rtcp::RtcpPacket>> new_feedback;
new_feedback.push_back(std::make_unique<rtcp::TransportFeedback>());
packet_router_.SendCombinedRtcpPacket(std::move(new_feedback));
packet_router_.RemoveReceiveRtpModule(&rtp_2);
}
TEST_F(PacketRouterTest, SendPacketWithoutTransportSequenceNumbers) {
const uint16_t kSsrc1 = 1234;
NiceMock<MockRtpRtcpInterface> rtp_1;
ON_CALL(rtp_1, SendingMedia).WillByDefault(Return(true));
ON_CALL(rtp_1, SSRC).WillByDefault(Return(kSsrc1));
packet_router_.AddSendRtpModule(&rtp_1, false);
// Send a packet without TransportSequenceNumber extension registered,
// packets sent should not have the extension set.
RtpHeaderExtensionMap extension_manager;
auto packet = std::make_unique<RtpPacketToSend>(&extension_manager);
packet->SetSsrc(kSsrc1);
EXPECT_CALL(
rtp_1,
TrySendPacket(
Pointee(Property(
&RtpPacketToSend::HasExtension<TransportSequenceNumber>, false)),
_))
.WillOnce(Return(true));
packet_router_.SendPacket(std::move(packet), PacedPacketInfo());
packet_router_.OnBatchComplete();
packet_router_.RemoveSendRtpModule(&rtp_1);
}
TEST_F(PacketRouterTest, SendPacketAssignsTransportSequenceNumbers) {
NiceMock<MockRtpRtcpInterface> rtp_1;
NiceMock<MockRtpRtcpInterface> rtp_2;
const uint16_t kSsrc1 = 1234;
const uint16_t kSsrc2 = 2345;
ON_CALL(rtp_1, SSRC).WillByDefault(Return(kSsrc1));
ON_CALL(rtp_2, SSRC).WillByDefault(Return(kSsrc2));
packet_router_.AddSendRtpModule(&rtp_1, false);
packet_router_.AddSendRtpModule(&rtp_2, false);
// Transport sequence numbers start at 1, for historical reasons.
uint16_t transport_sequence_number = 1;
auto packet = BuildRtpPacket(kSsrc1);
EXPECT_TRUE(packet->ReserveExtension<TransportSequenceNumber>());
EXPECT_CALL(
rtp_1,
TrySendPacket(Pointee(Property(
&RtpPacketToSend::GetExtension<TransportSequenceNumber>,
transport_sequence_number)),
_))
.WillOnce(Return(true));
packet_router_.SendPacket(std::move(packet), PacedPacketInfo());
++transport_sequence_number;
packet = BuildRtpPacket(kSsrc2);
EXPECT_TRUE(packet->ReserveExtension<TransportSequenceNumber>());
EXPECT_CALL(
rtp_2,
TrySendPacket(Pointee(Property(
&RtpPacketToSend::GetExtension<TransportSequenceNumber>,
transport_sequence_number)),
_))
.WillOnce(Return(true));
packet_router_.SendPacket(std::move(packet), PacedPacketInfo());
packet_router_.OnBatchComplete();
packet_router_.RemoveSendRtpModule(&rtp_1);
packet_router_.RemoveSendRtpModule(&rtp_2);
}
TEST_F(PacketRouterTest, DoesNotIncrementTransportSequenceNumberOnSendFailure) {
NiceMock<MockRtpRtcpInterface> rtp;
constexpr uint32_t kSsrc = 1234;
ON_CALL(rtp, SSRC).WillByDefault(Return(kSsrc));
packet_router_.AddSendRtpModule(&rtp, false);
// Transport sequence numbers start at 1, for historical reasons.
const uint16_t kStartTransportSequenceNumber = 1;
// Build and send a packet - it should be assigned the start sequence number.
// Return failure status code to make sure sequence number is not incremented.
auto packet = BuildRtpPacket(kSsrc);
EXPECT_TRUE(packet->ReserveExtension<TransportSequenceNumber>());
EXPECT_CALL(
rtp,
TrySendPacket(Pointee(Property(
&RtpPacketToSend::GetExtension<TransportSequenceNumber>,
kStartTransportSequenceNumber)),
_))
.WillOnce(Return(false));
packet_router_.SendPacket(std::move(packet), PacedPacketInfo());
// Send another packet, verify transport sequence number is still at the
// start state.
packet = BuildRtpPacket(kSsrc);
EXPECT_TRUE(packet->ReserveExtension<TransportSequenceNumber>());
EXPECT_CALL(
rtp,
TrySendPacket(Pointee(Property(
&RtpPacketToSend::GetExtension<TransportSequenceNumber>,
kStartTransportSequenceNumber)),
_))
.WillOnce(Return(true));
packet_router_.SendPacket(std::move(packet), PacedPacketInfo());
packet_router_.OnBatchComplete();
packet_router_.RemoveSendRtpModule(&rtp);
}
TEST_F(PacketRouterTest, ForwardsAbortedRetransmissions) {
NiceMock<MockRtpRtcpInterface> rtp_1;
NiceMock<MockRtpRtcpInterface> rtp_2;
const uint32_t kSsrc1 = 1234;
const uint32_t kSsrc2 = 2345;
const uint32_t kInvalidSsrc = 3456;
ON_CALL(rtp_1, SSRC).WillByDefault(Return(kSsrc1));
ON_CALL(rtp_2, SSRC).WillByDefault(Return(kSsrc2));
packet_router_.AddSendRtpModule(&rtp_1, false);
packet_router_.AddSendRtpModule(&rtp_2, false);
// Sets of retransmission sequence numbers we wish to abort, per ssrc.
const uint16_t kAbortedRetransmissionsOnSsrc1[] = {17, 42};
const uint16_t kAbortedRetransmissionsOnSsrc2[] = {1337, 4711};
const uint16_t kAbortedRetransmissionsOnSsrc3[] = {123};
EXPECT_CALL(rtp_1, OnAbortedRetransmissions(
ElementsAreArray(kAbortedRetransmissionsOnSsrc1)));
EXPECT_CALL(rtp_2, OnAbortedRetransmissions(
ElementsAreArray(kAbortedRetransmissionsOnSsrc2)));
packet_router_.OnAbortedRetransmissions(kSsrc1,
kAbortedRetransmissionsOnSsrc1);
packet_router_.OnAbortedRetransmissions(kSsrc2,
kAbortedRetransmissionsOnSsrc2);
// Should be noop and not cause any issues.
packet_router_.OnAbortedRetransmissions(kInvalidSsrc,
kAbortedRetransmissionsOnSsrc3);
packet_router_.RemoveSendRtpModule(&rtp_1);
packet_router_.RemoveSendRtpModule(&rtp_2);
}
TEST_F(PacketRouterTest, ReportsRtxSsrc) {
NiceMock<MockRtpRtcpInterface> rtp_1;
NiceMock<MockRtpRtcpInterface> rtp_2;
const uint32_t kSsrc1 = 1234;
const uint32_t kRtxSsrc1 = 1235;
const uint32_t kSsrc2 = 2345;
const uint32_t kInvalidSsrc = 3456;
ON_CALL(rtp_1, SSRC).WillByDefault(Return(kSsrc1));
ON_CALL(rtp_1, RtxSsrc).WillByDefault(Return(kRtxSsrc1));
ON_CALL(rtp_2, SSRC).WillByDefault(Return(kSsrc2));
packet_router_.AddSendRtpModule(&rtp_1, false);
packet_router_.AddSendRtpModule(&rtp_2, false);
EXPECT_EQ(packet_router_.GetRtxSsrcForMedia(kSsrc1), kRtxSsrc1);
EXPECT_EQ(packet_router_.GetRtxSsrcForMedia(kRtxSsrc1), absl::nullopt);
EXPECT_EQ(packet_router_.GetRtxSsrcForMedia(kSsrc2), absl::nullopt);
EXPECT_EQ(packet_router_.GetRtxSsrcForMedia(kInvalidSsrc), absl::nullopt);
packet_router_.RemoveSendRtpModule(&rtp_1);
packet_router_.RemoveSendRtpModule(&rtp_2);
}
TEST_F(PacketRouterTest, RoutesBatchCompleteToActiveModules) {
NiceMock<MockRtpRtcpInterface> rtp_1;
NiceMock<MockRtpRtcpInterface> rtp_2;
constexpr uint32_t kSsrc1 = 4711;
constexpr uint32_t kSsrc2 = 1234;
ON_CALL(rtp_1, SSRC).WillByDefault(Return(kSsrc1));
ON_CALL(rtp_2, SSRC).WillByDefault(Return(kSsrc2));
packet_router_.AddSendRtpModule(&rtp_1, false);
packet_router_.AddSendRtpModule(&rtp_2, false);
EXPECT_CALL(rtp_1, TrySendPacket).WillOnce(Return(true));
packet_router_.SendPacket(BuildRtpPacket(kSsrc1), PacedPacketInfo());
EXPECT_CALL(rtp_1, OnBatchComplete);
EXPECT_CALL(rtp_2, OnBatchComplete).Times(0);
packet_router_.OnBatchComplete();
packet_router_.RemoveSendRtpModule(&rtp_1);
packet_router_.RemoveSendRtpModule(&rtp_2);
}
#if RTC_DCHECK_IS_ON && GTEST_HAS_DEATH_TEST && !defined(WEBRTC_ANDROID)
using PacketRouterDeathTest = PacketRouterTest;
TEST_F(PacketRouterDeathTest, DoubleRegistrationOfSendModuleDisallowed) {
NiceMock<MockRtpRtcpInterface> module;
constexpr bool remb_candidate = false; // Value irrelevant.
packet_router_.AddSendRtpModule(&module, remb_candidate);
EXPECT_DEATH(packet_router_.AddSendRtpModule(&module, remb_candidate), "");
// Test tear-down
packet_router_.RemoveSendRtpModule(&module);
}
TEST_F(PacketRouterDeathTest, DoubleRegistrationOfReceiveModuleDisallowed) {
NiceMock<MockRtpRtcpInterface> module;
constexpr bool remb_candidate = false; // Value irrelevant.
packet_router_.AddReceiveRtpModule(&module, remb_candidate);
EXPECT_DEATH(packet_router_.AddReceiveRtpModule(&module, remb_candidate), "");
// Test tear-down
packet_router_.RemoveReceiveRtpModule(&module);
}
TEST_F(PacketRouterDeathTest, RemovalOfNeverAddedSendModuleDisallowed) {
NiceMock<MockRtpRtcpInterface> module;
EXPECT_DEATH(packet_router_.RemoveSendRtpModule(&module), "");
}
TEST_F(PacketRouterDeathTest, RemovalOfNeverAddedReceiveModuleDisallowed) {
NiceMock<MockRtpRtcpInterface> module;
EXPECT_DEATH(packet_router_.RemoveReceiveRtpModule(&module), "");
}
#endif // RTC_DCHECK_IS_ON && GTEST_HAS_DEATH_TEST && !defined(WEBRTC_ANDROID)
TEST(PacketRouterRembTest, ChangeSendRtpModuleChangeRembSender) {
rtc::ScopedFakeClock clock;
NiceMock<MockRtpRtcpInterface> rtp_send;
NiceMock<MockRtpRtcpInterface> rtp_recv;
PacketRouter packet_router;
packet_router.AddSendRtpModule(&rtp_send, true);
packet_router.AddReceiveRtpModule(&rtp_recv, true);
uint32_t bitrate_estimate = 456;
std::vector<uint32_t> ssrcs = {1234, 5678};
EXPECT_CALL(rtp_send, SetRemb(bitrate_estimate, ssrcs));
packet_router.SendRemb(bitrate_estimate, ssrcs);
// Remove the sending module -> should get remb on the second module.
packet_router.RemoveSendRtpModule(&rtp_send);
EXPECT_CALL(rtp_recv, SetRemb(bitrate_estimate, ssrcs));
packet_router.SendRemb(bitrate_estimate, ssrcs);
packet_router.RemoveReceiveRtpModule(&rtp_recv);
}
// Only register receiving modules and make sure we fallback to trigger a REMB
// packet on this one.
TEST(PacketRouterRembTest, NoSendingRtpModule) {
rtc::ScopedFakeClock clock;
NiceMock<MockRtpRtcpInterface> rtp;
PacketRouter packet_router;
packet_router.AddReceiveRtpModule(&rtp, true);
uint32_t bitrate_estimate = 456;
const std::vector<uint32_t> ssrcs = {1234};
EXPECT_CALL(rtp, SetRemb(bitrate_estimate, ssrcs));
packet_router.SendRemb(bitrate_estimate, ssrcs);
// Lower the estimate to trigger a new packet REMB packet.
EXPECT_CALL(rtp, SetRemb(bitrate_estimate, ssrcs));
packet_router.SendRemb(bitrate_estimate, ssrcs);
EXPECT_CALL(rtp, UnsetRemb());
packet_router.RemoveReceiveRtpModule(&rtp);
}
TEST(PacketRouterRembTest, NonCandidateSendRtpModuleNotUsedForRemb) {
rtc::ScopedFakeClock clock;
PacketRouter packet_router;
NiceMock<MockRtpRtcpInterface> module;
constexpr bool remb_candidate = false;
packet_router.AddSendRtpModule(&module, remb_candidate);
constexpr uint32_t bitrate_estimate = 456;
const std::vector<uint32_t> ssrcs = {1234};
EXPECT_CALL(module, SetRemb(_, _)).Times(0);
packet_router.SendRemb(bitrate_estimate, ssrcs);
// Test tear-down
packet_router.RemoveSendRtpModule(&module);
}
TEST(PacketRouterRembTest, CandidateSendRtpModuleUsedForRemb) {
rtc::ScopedFakeClock clock;
PacketRouter packet_router;
NiceMock<MockRtpRtcpInterface> module;
constexpr bool remb_candidate = true;
packet_router.AddSendRtpModule(&module, remb_candidate);
constexpr uint32_t bitrate_estimate = 456;
const std::vector<uint32_t> ssrcs = {1234};
EXPECT_CALL(module, SetRemb(bitrate_estimate, ssrcs));
packet_router.SendRemb(bitrate_estimate, ssrcs);
// Test tear-down
packet_router.RemoveSendRtpModule(&module);
}
TEST(PacketRouterRembTest, NonCandidateReceiveRtpModuleNotUsedForRemb) {
rtc::ScopedFakeClock clock;
PacketRouter packet_router;
NiceMock<MockRtpRtcpInterface> module;
constexpr bool remb_candidate = false;
packet_router.AddReceiveRtpModule(&module, remb_candidate);
constexpr uint32_t bitrate_estimate = 456;
const std::vector<uint32_t> ssrcs = {1234};
EXPECT_CALL(module, SetRemb(_, _)).Times(0);
packet_router.SendRemb(bitrate_estimate, ssrcs);
// Test tear-down
packet_router.RemoveReceiveRtpModule(&module);
}
TEST(PacketRouterRembTest, CandidateReceiveRtpModuleUsedForRemb) {
rtc::ScopedFakeClock clock;
PacketRouter packet_router;
NiceMock<MockRtpRtcpInterface> module;
constexpr bool remb_candidate = true;
packet_router.AddReceiveRtpModule(&module, remb_candidate);
constexpr uint32_t bitrate_estimate = 456;
const std::vector<uint32_t> ssrcs = {1234};
EXPECT_CALL(module, SetRemb(bitrate_estimate, ssrcs));
packet_router.SendRemb(bitrate_estimate, ssrcs);
// Test tear-down
packet_router.RemoveReceiveRtpModule(&module);
}
TEST(PacketRouterRembTest,
SendCandidatePreferredOverReceiveCandidate_SendModuleAddedFirst) {
rtc::ScopedFakeClock clock;
PacketRouter packet_router;
NiceMock<MockRtpRtcpInterface> send_module;
NiceMock<MockRtpRtcpInterface> receive_module;
constexpr bool remb_candidate = true;
// Send module added - activated.
packet_router.AddSendRtpModule(&send_module, remb_candidate);
// Receive module added - the send module remains the active one.
packet_router.AddReceiveRtpModule(&receive_module, remb_candidate);
constexpr uint32_t bitrate_estimate = 456;
const std::vector<uint32_t> ssrcs = {1234};
EXPECT_CALL(send_module, SetRemb(bitrate_estimate, ssrcs));
EXPECT_CALL(receive_module, SetRemb(_, _)).Times(0);
packet_router.SendRemb(bitrate_estimate, ssrcs);
// Test tear-down
packet_router.RemoveReceiveRtpModule(&receive_module);
packet_router.RemoveSendRtpModule(&send_module);
}
TEST(PacketRouterRembTest,
SendCandidatePreferredOverReceiveCandidate_ReceiveModuleAddedFirst) {
rtc::ScopedFakeClock clock;
PacketRouter packet_router;
NiceMock<MockRtpRtcpInterface> send_module;
NiceMock<MockRtpRtcpInterface> receive_module;
constexpr bool remb_candidate = true;
// Receive module added - activated.
packet_router.AddReceiveRtpModule(&receive_module, remb_candidate);
// Send module added - replaces receive module as active.
packet_router.AddSendRtpModule(&send_module, remb_candidate);
constexpr uint32_t bitrate_estimate = 456;
const std::vector<uint32_t> ssrcs = {1234};
EXPECT_CALL(send_module, SetRemb(bitrate_estimate, ssrcs));
EXPECT_CALL(receive_module, SetRemb(_, _)).Times(0);
clock.AdvanceTime(TimeDelta::Millis(1000));
packet_router.SendRemb(bitrate_estimate, ssrcs);
// Test tear-down
packet_router.RemoveReceiveRtpModule(&receive_module);
packet_router.RemoveSendRtpModule(&send_module);
}
TEST(PacketRouterRembTest, ReceiveModuleTakesOverWhenLastSendModuleRemoved) {
rtc::ScopedFakeClock clock;
PacketRouter packet_router;
NiceMock<MockRtpRtcpInterface> send_module;
NiceMock<MockRtpRtcpInterface> receive_module;
constexpr bool remb_candidate = true;
// Send module active, receive module inactive.
packet_router.AddSendRtpModule(&send_module, remb_candidate);
packet_router.AddReceiveRtpModule(&receive_module, remb_candidate);
// Send module removed - receive module becomes active.
packet_router.RemoveSendRtpModule(&send_module);
constexpr uint32_t bitrate_estimate = 456;
const std::vector<uint32_t> ssrcs = {1234};
EXPECT_CALL(send_module, SetRemb(_, _)).Times(0);
EXPECT_CALL(receive_module, SetRemb(bitrate_estimate, ssrcs));
packet_router.SendRemb(bitrate_estimate, ssrcs);
// Test tear-down
packet_router.RemoveReceiveRtpModule(&receive_module);
}
} // namespace webrtc