blob: ceddc5fdc74a1e138ebdaea764b80017fcd7abfc [file] [log] [blame]
/*
* Copyright (c) 2013 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_rtcp_impl2.h"
#include <deque>
#include <map>
#include <memory>
#include <set>
#include <utility>
#include "absl/types/optional.h"
#include "api/field_trials_registry.h"
#include "api/units/time_delta.h"
#include "modules/rtp_rtcp/include/rtp_rtcp_defines.h"
#include "modules/rtp_rtcp/source/rtcp_packet.h"
#include "modules/rtp_rtcp/source/rtcp_packet/nack.h"
#include "modules/rtp_rtcp/source/rtp_packet_received.h"
#include "modules/rtp_rtcp/source/rtp_rtcp_interface.h"
#include "modules/rtp_rtcp/source/rtp_sender_video.h"
#include "rtc_base/logging.h"
#include "rtc_base/rate_limiter.h"
#include "rtc_base/strings/string_builder.h"
#include "test/explicit_key_value_config.h"
#include "test/gmock.h"
#include "test/gtest.h"
#include "test/rtcp_packet_parser.h"
#include "test/run_loop.h"
#include "test/time_controller/simulated_time_controller.h"
using ::testing::AllOf;
using ::testing::ElementsAre;
using ::testing::Eq;
using ::testing::Field;
using ::testing::Gt;
using ::testing::Not;
using ::testing::Optional;
using ::testing::SizeIs;
using webrtc::test::ExplicitKeyValueConfig;
namespace webrtc {
namespace {
constexpr uint32_t kSenderSsrc = 0x12345;
constexpr uint32_t kReceiverSsrc = 0x23456;
constexpr uint32_t kRtxSenderSsrc = 0x12346;
constexpr TimeDelta kOneWayNetworkDelay = TimeDelta::Millis(100);
constexpr uint8_t kBaseLayerTid = 0;
constexpr uint8_t kHigherLayerTid = 1;
constexpr uint16_t kSequenceNumber = 100;
constexpr uint8_t kPayloadType = 100;
constexpr uint8_t kRtxPayloadType = 98;
constexpr int kWidth = 320;
constexpr int kHeight = 100;
constexpr int kCaptureTimeMsToRtpTimestamp = 90; // 90 kHz clock.
constexpr TimeDelta kDefaultReportInterval = TimeDelta::Millis(1000);
// RTP header extension ids.
enum : int {
kAbsoluteSendTimeExtensionId = 1,
kTransportSequenceNumberExtensionId,
kTransmissionOffsetExtensionId,
};
class RtcpRttStatsTestImpl : public RtcpRttStats {
public:
RtcpRttStatsTestImpl() : rtt_ms_(0) {}
~RtcpRttStatsTestImpl() override = default;
void OnRttUpdate(int64_t rtt_ms) override { rtt_ms_ = rtt_ms; }
int64_t LastProcessedRtt() const override { return rtt_ms_; }
int64_t rtt_ms_;
};
// TODO(bugs.webrtc.org/11581): remove inheritance once the ModuleRtpRtcpImpl2
// Module/ProcessThread dependency is gone.
class SendTransport : public Transport,
public sim_time_impl::SimulatedSequenceRunner {
public:
SendTransport(TimeDelta delay, GlobalSimulatedTimeController* time_controller)
: receiver_(nullptr),
time_controller_(time_controller),
delay_(delay),
rtp_packets_sent_(0),
rtcp_packets_sent_(0),
last_packet_(&header_extensions_) {
time_controller_->Register(this);
}
~SendTransport() { time_controller_->Unregister(this); }
void SetRtpRtcpModule(ModuleRtpRtcpImpl2* receiver) { receiver_ = receiver; }
void SimulateNetworkDelay(TimeDelta delay) { delay_ = delay; }
bool SendRtp(const uint8_t* data,
size_t len,
const PacketOptions& options) override {
EXPECT_TRUE(last_packet_.Parse(data, len));
++rtp_packets_sent_;
return true;
}
bool SendRtcp(const uint8_t* data, size_t len) override {
test::RtcpPacketParser parser;
parser.Parse(data, len);
last_nack_list_ = parser.nack()->packet_ids();
Timestamp current_time = time_controller_->GetClock()->CurrentTime();
Timestamp delivery_time = current_time + delay_;
rtcp_packets_.push_back(
Packet{delivery_time, std::vector<uint8_t>(data, data + len)});
++rtcp_packets_sent_;
RunReady(current_time);
return true;
}
// sim_time_impl::SimulatedSequenceRunner
Timestamp GetNextRunTime() const override {
if (!rtcp_packets_.empty())
return rtcp_packets_.front().send_time;
return Timestamp::PlusInfinity();
}
void RunReady(Timestamp at_time) override {
while (!rtcp_packets_.empty() &&
rtcp_packets_.front().send_time <= at_time) {
Packet packet = std::move(rtcp_packets_.front());
rtcp_packets_.pop_front();
EXPECT_TRUE(receiver_);
receiver_->IncomingRtcpPacket(packet.data);
}
}
TaskQueueBase* GetAsTaskQueue() override {
return reinterpret_cast<TaskQueueBase*>(this);
}
size_t NumRtcpSent() { return rtcp_packets_sent_; }
ModuleRtpRtcpImpl2* receiver_;
GlobalSimulatedTimeController* const time_controller_;
TimeDelta delay_;
int rtp_packets_sent_;
size_t rtcp_packets_sent_;
std::vector<uint16_t> last_nack_list_;
RtpHeaderExtensionMap header_extensions_;
RtpPacketReceived last_packet_;
struct Packet {
Timestamp send_time;
std::vector<uint8_t> data;
};
std::deque<Packet> rtcp_packets_;
};
class RtpRtcpModule : public RtcpPacketTypeCounterObserver,
public SendPacketObserver {
public:
struct SentPacket {
SentPacket(uint16_t packet_id, int64_t capture_time_ms, uint32_t ssrc)
: packet_id(packet_id), capture_time_ms(capture_time_ms), ssrc(ssrc) {}
uint16_t packet_id;
int64_t capture_time_ms;
uint32_t ssrc;
};
RtpRtcpModule(GlobalSimulatedTimeController* time_controller,
bool is_sender,
const FieldTrialsRegistry& trials)
: time_controller_(time_controller),
is_sender_(is_sender),
trials_(trials),
receive_statistics_(
ReceiveStatistics::Create(time_controller->GetClock())),
transport_(kOneWayNetworkDelay, time_controller) {
CreateModuleImpl();
}
TimeController* const time_controller_;
const bool is_sender_;
const FieldTrialsRegistry& trials_;
RtcpPacketTypeCounter packets_sent_;
RtcpPacketTypeCounter packets_received_;
std::unique_ptr<ReceiveStatistics> receive_statistics_;
SendTransport transport_;
RtcpRttStatsTestImpl rtt_stats_;
std::unique_ptr<ModuleRtpRtcpImpl2> impl_;
void RtcpPacketTypesCounterUpdated(
uint32_t ssrc,
const RtcpPacketTypeCounter& packet_counter) override {
counter_map_[ssrc] = packet_counter;
}
void OnSendPacket(uint16_t packet_id,
int64_t capture_time_ms,
uint32_t ssrc) override {
last_sent_packet_.emplace(packet_id, capture_time_ms, ssrc);
}
absl::optional<SentPacket> last_sent_packet() const {
return last_sent_packet_;
}
RtcpPacketTypeCounter RtcpSent() {
// RTCP counters for remote SSRC.
return counter_map_[is_sender_ ? kReceiverSsrc : kSenderSsrc];
}
RtcpPacketTypeCounter RtcpReceived() {
// Received RTCP stats for (own) local SSRC.
return counter_map_[impl_->SSRC()];
}
int RtpSent() { return transport_.rtp_packets_sent_; }
uint16_t LastRtpSequenceNumber() { return last_packet().SequenceNumber(); }
std::vector<uint16_t> LastNackListSent() {
return transport_.last_nack_list_;
}
void SetRtcpReportIntervalAndReset(TimeDelta rtcp_report_interval) {
rtcp_report_interval_ = rtcp_report_interval;
CreateModuleImpl();
}
const RtpPacketReceived& last_packet() { return transport_.last_packet_; }
void RegisterHeaderExtension(absl::string_view uri, int id) {
impl_->RegisterRtpHeaderExtension(uri, id);
transport_.header_extensions_.RegisterByUri(id, uri);
transport_.last_packet_.IdentifyExtensions(transport_.header_extensions_);
}
void ReinintWithFec(VideoFecGenerator* fec_generator) {
fec_generator_ = fec_generator;
CreateModuleImpl();
}
void CreateModuleImpl() {
RtpRtcpInterface::Configuration config;
config.audio = false;
config.clock = time_controller_->GetClock();
config.outgoing_transport = &transport_;
config.receive_statistics = receive_statistics_.get();
config.rtcp_packet_type_counter_observer = this;
config.rtt_stats = &rtt_stats_;
config.rtcp_report_interval_ms = rtcp_report_interval_.ms();
config.local_media_ssrc = is_sender_ ? kSenderSsrc : kReceiverSsrc;
config.rtx_send_ssrc =
is_sender_ ? absl::make_optional(kRtxSenderSsrc) : absl::nullopt;
config.need_rtp_packet_infos = true;
config.non_sender_rtt_measurement = true;
config.field_trials = &trials_;
config.send_packet_observer = this;
config.fec_generator = fec_generator_;
impl_.reset(new ModuleRtpRtcpImpl2(config));
impl_->SetRemoteSSRC(is_sender_ ? kReceiverSsrc : kSenderSsrc);
impl_->SetRTCPStatus(RtcpMode::kCompound);
}
private:
std::map<uint32_t, RtcpPacketTypeCounter> counter_map_;
absl::optional<SentPacket> last_sent_packet_;
VideoFecGenerator* fec_generator_ = nullptr;
TimeDelta rtcp_report_interval_ = kDefaultReportInterval;
};
} // namespace
class RtpRtcpImpl2Test : public ::testing::Test {
protected:
RtpRtcpImpl2Test()
: time_controller_(Timestamp::Micros(133590000000000)),
field_trials_(""),
sender_(&time_controller_,
/*is_sender=*/true,
field_trials_),
receiver_(&time_controller_,
/*is_sender=*/false,
field_trials_) {}
void SetUp() override {
// Send module.
EXPECT_EQ(0, sender_.impl_->SetSendingStatus(true));
sender_.impl_->SetSendingMediaStatus(true);
sender_.impl_->SetSequenceNumber(kSequenceNumber);
sender_.impl_->SetStorePacketsStatus(true, 100);
RTPSenderVideo::Config video_config;
video_config.clock = time_controller_.GetClock();
video_config.rtp_sender = sender_.impl_->RtpSender();
video_config.field_trials = &field_trials_;
sender_video_ = std::make_unique<RTPSenderVideo>(video_config);
// Receive module.
EXPECT_EQ(0, receiver_.impl_->SetSendingStatus(false));
receiver_.impl_->SetSendingMediaStatus(false);
// Transport settings.
sender_.transport_.SetRtpRtcpModule(receiver_.impl_.get());
receiver_.transport_.SetRtpRtcpModule(sender_.impl_.get());
}
void AdvanceTime(TimeDelta duration) {
time_controller_.AdvanceTime(duration);
}
void ReinitWithFec(VideoFecGenerator* fec_generator,
absl::optional<int> red_payload_type) {
sender_.ReinintWithFec(fec_generator);
EXPECT_EQ(0, sender_.impl_->SetSendingStatus(true));
sender_.impl_->SetSendingMediaStatus(true);
sender_.impl_->SetSequenceNumber(kSequenceNumber);
sender_.impl_->SetStorePacketsStatus(true, 100);
receiver_.transport_.SetRtpRtcpModule(sender_.impl_.get());
RTPSenderVideo::Config video_config;
video_config.clock = time_controller_.GetClock();
video_config.rtp_sender = sender_.impl_->RtpSender();
video_config.field_trials = &field_trials_;
video_config.fec_overhead_bytes = fec_generator->MaxPacketOverhead();
video_config.fec_type = fec_generator->GetFecType();
video_config.red_payload_type = red_payload_type;
sender_video_ = std::make_unique<RTPSenderVideo>(video_config);
}
GlobalSimulatedTimeController time_controller_;
test::ExplicitKeyValueConfig field_trials_;
RtpRtcpModule sender_;
std::unique_ptr<RTPSenderVideo> sender_video_;
RtpRtcpModule receiver_;
bool SendFrame(const RtpRtcpModule* module,
RTPSenderVideo* sender,
uint8_t tid) {
int64_t now_ms = time_controller_.GetClock()->TimeInMilliseconds();
return SendFrame(
module, sender, tid,
static_cast<uint32_t>(now_ms * kCaptureTimeMsToRtpTimestamp), now_ms);
}
bool SendFrame(const RtpRtcpModule* module,
RTPSenderVideo* sender,
uint8_t tid,
uint32_t rtp_timestamp,
int64_t capture_time_ms) {
RTPVideoHeaderVP8 vp8_header = {};
vp8_header.temporalIdx = tid;
RTPVideoHeader rtp_video_header;
rtp_video_header.frame_type = VideoFrameType::kVideoFrameKey;
rtp_video_header.width = kWidth;
rtp_video_header.height = kHeight;
rtp_video_header.rotation = kVideoRotation_0;
rtp_video_header.content_type = VideoContentType::UNSPECIFIED;
rtp_video_header.playout_delay = {-1, -1};
rtp_video_header.is_first_packet_in_frame = true;
rtp_video_header.simulcastIdx = 0;
rtp_video_header.codec = kVideoCodecVP8;
rtp_video_header.video_type_header = vp8_header;
rtp_video_header.video_timing = {0u, 0u, 0u, 0u, 0u, 0u, false};
const uint8_t payload[100] = {0};
bool success = module->impl_->OnSendingRtpFrame(0, 0, kPayloadType, true);
success &= sender->SendVideo(kPayloadType, VideoCodecType::kVideoCodecVP8,
rtp_timestamp, capture_time_ms, payload,
rtp_video_header, 0, {});
return success;
}
void IncomingRtcpNack(const RtpRtcpModule* module, uint16_t sequence_number) {
bool sender = module->impl_->SSRC() == kSenderSsrc;
rtcp::Nack nack;
uint16_t list[1];
list[0] = sequence_number;
const uint16_t kListLength = sizeof(list) / sizeof(list[0]);
nack.SetSenderSsrc(sender ? kReceiverSsrc : kSenderSsrc);
nack.SetMediaSsrc(sender ? kSenderSsrc : kReceiverSsrc);
nack.SetPacketIds(list, kListLength);
rtc::Buffer packet = nack.Build();
module->impl_->IncomingRtcpPacket(packet);
}
};
TEST_F(RtpRtcpImpl2Test, RetransmitsAllLayers) {
// Send frames.
EXPECT_EQ(0, sender_.RtpSent());
EXPECT_TRUE(SendFrame(&sender_, sender_video_.get(),
kBaseLayerTid)); // kSequenceNumber
EXPECT_TRUE(SendFrame(&sender_, sender_video_.get(),
kHigherLayerTid)); // kSequenceNumber + 1
EXPECT_TRUE(SendFrame(&sender_, sender_video_.get(),
kNoTemporalIdx)); // kSequenceNumber + 2
EXPECT_EQ(3, sender_.RtpSent());
EXPECT_EQ(kSequenceNumber + 2, sender_.LastRtpSequenceNumber());
// Min required delay until retransmit = 5 + RTT ms (RTT = 0).
AdvanceTime(TimeDelta::Millis(5));
// Frame with kBaseLayerTid re-sent.
IncomingRtcpNack(&sender_, kSequenceNumber);
EXPECT_EQ(4, sender_.RtpSent());
EXPECT_EQ(kSequenceNumber, sender_.LastRtpSequenceNumber());
// Frame with kHigherLayerTid re-sent.
IncomingRtcpNack(&sender_, kSequenceNumber + 1);
EXPECT_EQ(5, sender_.RtpSent());
EXPECT_EQ(kSequenceNumber + 1, sender_.LastRtpSequenceNumber());
// Frame with kNoTemporalIdx re-sent.
IncomingRtcpNack(&sender_, kSequenceNumber + 2);
EXPECT_EQ(6, sender_.RtpSent());
EXPECT_EQ(kSequenceNumber + 2, sender_.LastRtpSequenceNumber());
}
TEST_F(RtpRtcpImpl2Test, Rtt) {
RtpPacketReceived packet;
packet.SetTimestamp(1);
packet.SetSequenceNumber(123);
packet.SetSsrc(kSenderSsrc);
packet.AllocatePayload(100 - 12);
receiver_.receive_statistics_->OnRtpPacket(packet);
// Send Frame before sending an SR.
EXPECT_TRUE(SendFrame(&sender_, sender_video_.get(), kBaseLayerTid));
// Sender module should send an SR.
EXPECT_EQ(0, sender_.impl_->SendRTCP(kRtcpReport));
AdvanceTime(kOneWayNetworkDelay);
// Receiver module should send a RR with a response to the last received SR.
EXPECT_EQ(0, receiver_.impl_->SendRTCP(kRtcpReport));
AdvanceTime(kOneWayNetworkDelay);
// Verify RTT.
int64_t rtt;
int64_t avg_rtt;
int64_t min_rtt;
int64_t max_rtt;
EXPECT_EQ(
0, sender_.impl_->RTT(kReceiverSsrc, &rtt, &avg_rtt, &min_rtt, &max_rtt));
EXPECT_NEAR(2 * kOneWayNetworkDelay.ms(), rtt, 1);
EXPECT_NEAR(2 * kOneWayNetworkDelay.ms(), avg_rtt, 1);
EXPECT_NEAR(2 * kOneWayNetworkDelay.ms(), min_rtt, 1);
EXPECT_NEAR(2 * kOneWayNetworkDelay.ms(), max_rtt, 1);
// No RTT from other ssrc.
EXPECT_EQ(-1, sender_.impl_->RTT(kReceiverSsrc + 1, &rtt, &avg_rtt, &min_rtt,
&max_rtt));
// Verify RTT from rtt_stats config.
EXPECT_EQ(0, sender_.rtt_stats_.LastProcessedRtt());
EXPECT_EQ(0, sender_.impl_->rtt_ms());
AdvanceTime(TimeDelta::Millis(1000));
EXPECT_NEAR(2 * kOneWayNetworkDelay.ms(),
sender_.rtt_stats_.LastProcessedRtt(), 1);
EXPECT_NEAR(2 * kOneWayNetworkDelay.ms(), sender_.impl_->rtt_ms(), 1);
}
TEST_F(RtpRtcpImpl2Test, RttForReceiverOnly) {
// Receiver module should send a Receiver time reference report (RTRR).
EXPECT_EQ(0, receiver_.impl_->SendRTCP(kRtcpReport));
// Sender module should send a response to the last received RTRR (DLRR).
AdvanceTime(TimeDelta::Millis(1000));
// Send Frame before sending a SR.
EXPECT_TRUE(SendFrame(&sender_, sender_video_.get(), kBaseLayerTid));
EXPECT_EQ(0, sender_.impl_->SendRTCP(kRtcpReport));
// Verify RTT.
EXPECT_EQ(0, receiver_.rtt_stats_.LastProcessedRtt());
EXPECT_EQ(0, receiver_.impl_->rtt_ms());
AdvanceTime(TimeDelta::Millis(1000));
EXPECT_NEAR(2 * kOneWayNetworkDelay.ms(),
receiver_.rtt_stats_.LastProcessedRtt(), 1);
EXPECT_NEAR(2 * kOneWayNetworkDelay.ms(), receiver_.impl_->rtt_ms(), 1);
}
TEST_F(RtpRtcpImpl2Test, NoSrBeforeMedia) {
// Ignore fake transport delays in this test.
sender_.transport_.SimulateNetworkDelay(TimeDelta::Zero());
receiver_.transport_.SimulateNetworkDelay(TimeDelta::Zero());
// Move ahead to the instant a rtcp is expected.
// Verify no SR is sent before media has been sent, RR should still be sent
// from the receiving module though.
AdvanceTime(kDefaultReportInterval / 2);
EXPECT_EQ(sender_.transport_.NumRtcpSent(), 0u);
EXPECT_EQ(receiver_.transport_.NumRtcpSent(), 1u);
// RTCP should be triggered by the RTP send.
EXPECT_TRUE(SendFrame(&sender_, sender_video_.get(), kBaseLayerTid));
EXPECT_EQ(sender_.transport_.NumRtcpSent(), 1u);
}
TEST_F(RtpRtcpImpl2Test, RtcpPacketTypeCounter_Nack) {
EXPECT_EQ(0U, sender_.RtcpReceived().nack_packets);
EXPECT_EQ(0U, receiver_.RtcpSent().nack_packets);
// Receive module sends a NACK.
const uint16_t kNackLength = 1;
uint16_t nack_list[kNackLength] = {123};
EXPECT_EQ(0, receiver_.impl_->SendNACK(nack_list, kNackLength));
AdvanceTime(kOneWayNetworkDelay);
EXPECT_EQ(1U, receiver_.RtcpSent().nack_packets);
// Send module receives the NACK.
EXPECT_EQ(1U, sender_.RtcpReceived().nack_packets);
}
TEST_F(RtpRtcpImpl2Test, AddStreamDataCounters) {
StreamDataCounters rtp;
const int64_t kStartTimeMs = 1;
rtp.first_packet_time_ms = kStartTimeMs;
rtp.transmitted.packets = 1;
rtp.transmitted.payload_bytes = 1;
rtp.transmitted.header_bytes = 2;
rtp.transmitted.padding_bytes = 3;
EXPECT_EQ(rtp.transmitted.TotalBytes(), rtp.transmitted.payload_bytes +
rtp.transmitted.header_bytes +
rtp.transmitted.padding_bytes);
StreamDataCounters rtp2;
rtp2.first_packet_time_ms = -1;
rtp2.transmitted.packets = 10;
rtp2.transmitted.payload_bytes = 10;
rtp2.retransmitted.header_bytes = 4;
rtp2.retransmitted.payload_bytes = 5;
rtp2.retransmitted.padding_bytes = 6;
rtp2.retransmitted.packets = 7;
rtp2.fec.packets = 8;
StreamDataCounters sum = rtp;
sum.Add(rtp2);
EXPECT_EQ(kStartTimeMs, sum.first_packet_time_ms);
EXPECT_EQ(11U, sum.transmitted.packets);
EXPECT_EQ(11U, sum.transmitted.payload_bytes);
EXPECT_EQ(2U, sum.transmitted.header_bytes);
EXPECT_EQ(3U, sum.transmitted.padding_bytes);
EXPECT_EQ(4U, sum.retransmitted.header_bytes);
EXPECT_EQ(5U, sum.retransmitted.payload_bytes);
EXPECT_EQ(6U, sum.retransmitted.padding_bytes);
EXPECT_EQ(7U, sum.retransmitted.packets);
EXPECT_EQ(8U, sum.fec.packets);
EXPECT_EQ(sum.transmitted.TotalBytes(),
rtp.transmitted.TotalBytes() + rtp2.transmitted.TotalBytes());
StreamDataCounters rtp3;
rtp3.first_packet_time_ms = kStartTimeMs + 10;
sum.Add(rtp3);
EXPECT_EQ(kStartTimeMs, sum.first_packet_time_ms); // Holds oldest time.
}
TEST_F(RtpRtcpImpl2Test, SendsInitialNackList) {
// Send module sends a NACK.
const uint16_t kNackLength = 1;
uint16_t nack_list[kNackLength] = {123};
EXPECT_EQ(0U, sender_.RtcpSent().nack_packets);
// Send Frame before sending a compound RTCP that starts with SR.
EXPECT_TRUE(SendFrame(&sender_, sender_video_.get(), kBaseLayerTid));
EXPECT_EQ(0, sender_.impl_->SendNACK(nack_list, kNackLength));
EXPECT_EQ(1U, sender_.RtcpSent().nack_packets);
EXPECT_THAT(sender_.LastNackListSent(), ElementsAre(123));
}
TEST_F(RtpRtcpImpl2Test, SendsExtendedNackList) {
// Send module sends a NACK.
const uint16_t kNackLength = 1;
uint16_t nack_list[kNackLength] = {123};
EXPECT_EQ(0U, sender_.RtcpSent().nack_packets);
// Send Frame before sending a compound RTCP that starts with SR.
EXPECT_TRUE(SendFrame(&sender_, sender_video_.get(), kBaseLayerTid));
EXPECT_EQ(0, sender_.impl_->SendNACK(nack_list, kNackLength));
EXPECT_EQ(1U, sender_.RtcpSent().nack_packets);
EXPECT_THAT(sender_.LastNackListSent(), ElementsAre(123));
// Same list not re-send.
EXPECT_EQ(0, sender_.impl_->SendNACK(nack_list, kNackLength));
EXPECT_EQ(1U, sender_.RtcpSent().nack_packets);
EXPECT_THAT(sender_.LastNackListSent(), ElementsAre(123));
// Only extended list sent.
const uint16_t kNackExtLength = 2;
uint16_t nack_list_ext[kNackExtLength] = {123, 124};
EXPECT_EQ(0, sender_.impl_->SendNACK(nack_list_ext, kNackExtLength));
EXPECT_EQ(2U, sender_.RtcpSent().nack_packets);
EXPECT_THAT(sender_.LastNackListSent(), ElementsAre(124));
}
TEST_F(RtpRtcpImpl2Test, ReSendsNackListAfterRttMs) {
sender_.transport_.SimulateNetworkDelay(TimeDelta::Zero());
// Send module sends a NACK.
const uint16_t kNackLength = 2;
uint16_t nack_list[kNackLength] = {123, 125};
EXPECT_EQ(0U, sender_.RtcpSent().nack_packets);
// Send Frame before sending a compound RTCP that starts with SR.
EXPECT_TRUE(SendFrame(&sender_, sender_video_.get(), kBaseLayerTid));
EXPECT_EQ(0, sender_.impl_->SendNACK(nack_list, kNackLength));
EXPECT_EQ(1U, sender_.RtcpSent().nack_packets);
EXPECT_THAT(sender_.LastNackListSent(), ElementsAre(123, 125));
// Same list not re-send, rtt interval has not passed.
const TimeDelta kStartupRtt = TimeDelta::Millis(100);
AdvanceTime(kStartupRtt);
EXPECT_EQ(0, sender_.impl_->SendNACK(nack_list, kNackLength));
EXPECT_EQ(1U, sender_.RtcpSent().nack_packets);
// Rtt interval passed, full list sent.
AdvanceTime(TimeDelta::Millis(1));
EXPECT_EQ(0, sender_.impl_->SendNACK(nack_list, kNackLength));
EXPECT_EQ(2U, sender_.RtcpSent().nack_packets);
EXPECT_THAT(sender_.LastNackListSent(), ElementsAre(123, 125));
}
TEST_F(RtpRtcpImpl2Test, UniqueNackRequests) {
receiver_.transport_.SimulateNetworkDelay(TimeDelta::Zero());
EXPECT_EQ(0U, receiver_.RtcpSent().nack_packets);
EXPECT_EQ(0U, receiver_.RtcpSent().nack_requests);
EXPECT_EQ(0U, receiver_.RtcpSent().unique_nack_requests);
EXPECT_EQ(0, receiver_.RtcpSent().UniqueNackRequestsInPercent());
// Receive module sends NACK request.
const uint16_t kNackLength = 4;
uint16_t nack_list[kNackLength] = {10, 11, 13, 18};
EXPECT_EQ(0, receiver_.impl_->SendNACK(nack_list, kNackLength));
EXPECT_EQ(1U, receiver_.RtcpSent().nack_packets);
EXPECT_EQ(4U, receiver_.RtcpSent().nack_requests);
EXPECT_EQ(4U, receiver_.RtcpSent().unique_nack_requests);
EXPECT_THAT(receiver_.LastNackListSent(), ElementsAre(10, 11, 13, 18));
// Send module receives the request.
EXPECT_EQ(1U, sender_.RtcpReceived().nack_packets);
EXPECT_EQ(4U, sender_.RtcpReceived().nack_requests);
EXPECT_EQ(4U, sender_.RtcpReceived().unique_nack_requests);
EXPECT_EQ(100, sender_.RtcpReceived().UniqueNackRequestsInPercent());
// Receive module sends new request with duplicated packets.
const TimeDelta kStartupRtt = TimeDelta::Millis(100);
AdvanceTime(kStartupRtt + TimeDelta::Millis(1));
const uint16_t kNackLength2 = 4;
uint16_t nack_list2[kNackLength2] = {11, 18, 20, 21};
EXPECT_EQ(0, receiver_.impl_->SendNACK(nack_list2, kNackLength2));
EXPECT_EQ(2U, receiver_.RtcpSent().nack_packets);
EXPECT_EQ(8U, receiver_.RtcpSent().nack_requests);
EXPECT_EQ(6U, receiver_.RtcpSent().unique_nack_requests);
EXPECT_THAT(receiver_.LastNackListSent(), ElementsAre(11, 18, 20, 21));
// Send module receives the request.
EXPECT_EQ(2U, sender_.RtcpReceived().nack_packets);
EXPECT_EQ(8U, sender_.RtcpReceived().nack_requests);
EXPECT_EQ(6U, sender_.RtcpReceived().unique_nack_requests);
EXPECT_EQ(75, sender_.RtcpReceived().UniqueNackRequestsInPercent());
}
TEST_F(RtpRtcpImpl2Test, ConfigurableRtcpReportInterval) {
const TimeDelta kVideoReportInterval = TimeDelta::Millis(3000);
// Recreate sender impl with new configuration, and redo setup.
sender_.SetRtcpReportIntervalAndReset(kVideoReportInterval);
SetUp();
EXPECT_TRUE(SendFrame(&sender_, sender_video_.get(), kBaseLayerTid));
// Initial state
EXPECT_EQ(0u, sender_.transport_.NumRtcpSent());
// Move ahead to the last ms before a rtcp is expected, no action.
AdvanceTime(kVideoReportInterval / 2 - TimeDelta::Millis(1));
EXPECT_EQ(sender_.transport_.NumRtcpSent(), 0u);
// Move ahead to the first rtcp. Send RTCP.
AdvanceTime(TimeDelta::Millis(1));
EXPECT_EQ(sender_.transport_.NumRtcpSent(), 1u);
EXPECT_TRUE(SendFrame(&sender_, sender_video_.get(), kBaseLayerTid));
// Move ahead to the last possible second before second rtcp is expected.
AdvanceTime(kVideoReportInterval * 1 / 2 - TimeDelta::Millis(1));
EXPECT_EQ(sender_.transport_.NumRtcpSent(), 1u);
// Move ahead into the range of second rtcp, the second rtcp may be sent.
AdvanceTime(TimeDelta::Millis(1));
EXPECT_GE(sender_.transport_.NumRtcpSent(), 1u);
AdvanceTime(kVideoReportInterval / 2);
EXPECT_GE(sender_.transport_.NumRtcpSent(), 1u);
// Move out the range of second rtcp, the second rtcp must have been sent.
AdvanceTime(kVideoReportInterval / 2);
EXPECT_EQ(sender_.transport_.NumRtcpSent(), 2u);
}
TEST_F(RtpRtcpImpl2Test, RtpSenderEgressTimestampOffset) {
// RTP timestamp offset not explicitly set, default to random value.
uint16_t seqno = sender_.impl_->GetRtpState().sequence_number;
uint32_t media_rtp_ts = 1001;
uint32_t rtp_ts = media_rtp_ts + sender_.impl_->StartTimestamp();
EXPECT_TRUE(SendFrame(&sender_, sender_video_.get(), kBaseLayerTid, rtp_ts,
/*capture_time_ms=*/0));
AdvanceTime(kOneWayNetworkDelay);
EXPECT_THAT(
sender_.impl_->GetSentRtpPacketInfos(std::vector<uint16_t>{seqno}),
ElementsAre(Field(&RtpSequenceNumberMap::Info::timestamp, media_rtp_ts)));
RtpState saved_rtp_state = sender_.impl_->GetRtpState();
// Change RTP timestamp offset.
sender_.impl_->SetStartTimestamp(2000);
// Restores RtpState and make sure the old timestamp offset is in place.
sender_.impl_->SetRtpState(saved_rtp_state);
seqno = sender_.impl_->GetRtpState().sequence_number;
media_rtp_ts = 1031;
rtp_ts = media_rtp_ts + sender_.impl_->StartTimestamp();
EXPECT_TRUE(SendFrame(&sender_, sender_video_.get(), kBaseLayerTid, rtp_ts,
/*capture_time_ms=*/0));
AdvanceTime(kOneWayNetworkDelay);
EXPECT_THAT(
sender_.impl_->GetSentRtpPacketInfos(std::vector<uint16_t>{seqno}),
ElementsAre(Field(&RtpSequenceNumberMap::Info::timestamp, media_rtp_ts)));
}
TEST_F(RtpRtcpImpl2Test, StoresPacketInfoForSentPackets) {
const uint32_t kStartTimestamp = 1u;
SetUp();
sender_.impl_->SetStartTimestamp(kStartTimestamp);
sender_.impl_->SetSequenceNumber(1);
PacedPacketInfo pacing_info;
RtpPacketToSend packet(nullptr);
packet.set_packet_type(RtpPacketToSend::Type::kVideo);
packet.SetSsrc(kSenderSsrc);
// Single-packet frame.
packet.SetTimestamp(1);
packet.set_first_packet_of_frame(true);
packet.SetMarker(true);
sender_.impl_->TrySendPacket(&packet, pacing_info);
AdvanceTime(TimeDelta::Millis(1));
std::vector<RtpSequenceNumberMap::Info> seqno_info =
sender_.impl_->GetSentRtpPacketInfos(std::vector<uint16_t>{1});
EXPECT_THAT(seqno_info, ElementsAre(RtpSequenceNumberMap::Info(
/*timestamp=*/1 - kStartTimestamp,
/*is_first=*/1,
/*is_last=*/1)));
// Three-packet frame.
packet.SetTimestamp(2);
packet.set_first_packet_of_frame(true);
packet.SetMarker(false);
sender_.impl_->TrySendPacket(&packet, pacing_info);
packet.set_first_packet_of_frame(false);
sender_.impl_->TrySendPacket(&packet, pacing_info);
packet.SetMarker(true);
sender_.impl_->TrySendPacket(&packet, pacing_info);
AdvanceTime(TimeDelta::Millis(1));
seqno_info =
sender_.impl_->GetSentRtpPacketInfos(std::vector<uint16_t>{2, 3, 4});
EXPECT_THAT(seqno_info, ElementsAre(RtpSequenceNumberMap::Info(
/*timestamp=*/2 - kStartTimestamp,
/*is_first=*/1,
/*is_last=*/0),
RtpSequenceNumberMap::Info(
/*timestamp=*/2 - kStartTimestamp,
/*is_first=*/0,
/*is_last=*/0),
RtpSequenceNumberMap::Info(
/*timestamp=*/2 - kStartTimestamp,
/*is_first=*/0,
/*is_last=*/1)));
}
// Checks that the sender report stats are not available if no RTCP SR was sent.
TEST_F(RtpRtcpImpl2Test, SenderReportStatsNotAvailable) {
EXPECT_THAT(receiver_.impl_->GetSenderReportStats(), Eq(absl::nullopt));
}
// Checks that the sender report stats are available if an RTCP SR was sent.
TEST_F(RtpRtcpImpl2Test, SenderReportStatsAvailable) {
// Send a frame in order to send an SR.
EXPECT_TRUE(SendFrame(&sender_, sender_video_.get(), kBaseLayerTid));
// Send an SR.
ASSERT_THAT(sender_.impl_->SendRTCP(kRtcpReport), Eq(0));
AdvanceTime(kOneWayNetworkDelay);
EXPECT_THAT(receiver_.impl_->GetSenderReportStats(), Not(Eq(absl::nullopt)));
}
// Checks that the sender report stats are not available if an RTCP SR with an
// unexpected SSRC is received.
TEST_F(RtpRtcpImpl2Test, SenderReportStatsNotUpdatedWithUnexpectedSsrc) {
constexpr uint32_t kUnexpectedSenderSsrc = 0x87654321;
static_assert(kUnexpectedSenderSsrc != kSenderSsrc, "");
// Forge a sender report and pass it to the receiver as if an RTCP SR were
// sent by an unexpected sender.
rtcp::SenderReport sr;
sr.SetSenderSsrc(kUnexpectedSenderSsrc);
sr.SetNtp({/*seconds=*/1u, /*fractions=*/1u << 31});
sr.SetPacketCount(123u);
sr.SetOctetCount(456u);
auto raw_packet = sr.Build();
receiver_.impl_->IncomingRtcpPacket(raw_packet);
EXPECT_THAT(receiver_.impl_->GetSenderReportStats(), Eq(absl::nullopt));
}
// Checks the stats derived from the last received RTCP SR are set correctly.
TEST_F(RtpRtcpImpl2Test, SenderReportStatsCheckStatsFromLastReport) {
using SenderReportStats = RtpRtcpInterface::SenderReportStats;
const NtpTime ntp(/*seconds=*/1u, /*fractions=*/1u << 31);
constexpr uint32_t kPacketCount = 123u;
constexpr uint32_t kOctetCount = 456u;
// Forge a sender report and pass it to the receiver as if an RTCP SR were
// sent by the sender.
rtcp::SenderReport sr;
sr.SetSenderSsrc(kSenderSsrc);
sr.SetNtp(ntp);
sr.SetPacketCount(kPacketCount);
sr.SetOctetCount(kOctetCount);
auto raw_packet = sr.Build();
receiver_.impl_->IncomingRtcpPacket(raw_packet);
EXPECT_THAT(
receiver_.impl_->GetSenderReportStats(),
Optional(AllOf(Field(&SenderReportStats::last_remote_timestamp, Eq(ntp)),
Field(&SenderReportStats::packets_sent, Eq(kPacketCount)),
Field(&SenderReportStats::bytes_sent, Eq(kOctetCount)))));
}
// Checks that the sender report stats count equals the number of sent RTCP SRs.
TEST_F(RtpRtcpImpl2Test, SenderReportStatsCount) {
using SenderReportStats = RtpRtcpInterface::SenderReportStats;
// Send a frame in order to send an SR.
EXPECT_TRUE(SendFrame(&sender_, sender_video_.get(), kBaseLayerTid));
// Send the first SR.
ASSERT_THAT(sender_.impl_->SendRTCP(kRtcpReport), Eq(0));
AdvanceTime(kOneWayNetworkDelay);
EXPECT_THAT(receiver_.impl_->GetSenderReportStats(),
Optional(Field(&SenderReportStats::reports_count, Eq(1u))));
// Send the second SR.
ASSERT_THAT(sender_.impl_->SendRTCP(kRtcpReport), Eq(0));
AdvanceTime(kOneWayNetworkDelay);
EXPECT_THAT(receiver_.impl_->GetSenderReportStats(),
Optional(Field(&SenderReportStats::reports_count, Eq(2u))));
}
// Checks that the sender report stats include a valid arrival time if an RTCP
// SR was sent.
TEST_F(RtpRtcpImpl2Test, SenderReportStatsArrivalTimestampSet) {
// Send a frame in order to send an SR.
EXPECT_TRUE(SendFrame(&sender_, sender_video_.get(), kBaseLayerTid));
// Send an SR.
ASSERT_THAT(sender_.impl_->SendRTCP(kRtcpReport), Eq(0));
AdvanceTime(kOneWayNetworkDelay);
auto stats = receiver_.impl_->GetSenderReportStats();
ASSERT_THAT(stats, Not(Eq(absl::nullopt)));
EXPECT_TRUE(stats->last_arrival_timestamp.Valid());
}
// Checks that the packet and byte counters from an RTCP SR are not zero once
// a frame is sent.
TEST_F(RtpRtcpImpl2Test, SenderReportStatsPacketByteCounters) {
using SenderReportStats = RtpRtcpInterface::SenderReportStats;
// Send a frame in order to send an SR.
EXPECT_TRUE(SendFrame(&sender_, sender_video_.get(), kBaseLayerTid));
ASSERT_THAT(sender_.transport_.rtp_packets_sent_, Gt(0));
// Advance time otherwise the RTCP SR report will not include any packets
// generated by `SendFrame()`.
AdvanceTime(TimeDelta::Millis(1));
// Send an SR.
ASSERT_THAT(sender_.impl_->SendRTCP(kRtcpReport), Eq(0));
AdvanceTime(kOneWayNetworkDelay);
EXPECT_THAT(receiver_.impl_->GetSenderReportStats(),
Optional(AllOf(Field(&SenderReportStats::packets_sent, Gt(0u)),
Field(&SenderReportStats::bytes_sent, Gt(0u)))));
}
TEST_F(RtpRtcpImpl2Test, SendingVideoAdvancesSequenceNumber) {
const uint16_t sequence_number = sender_.impl_->SequenceNumber();
EXPECT_TRUE(SendFrame(&sender_, sender_video_.get(), kBaseLayerTid));
ASSERT_THAT(sender_.transport_.rtp_packets_sent_, Gt(0));
EXPECT_EQ(sequence_number + 1, sender_.impl_->SequenceNumber());
}
TEST_F(RtpRtcpImpl2Test, SequenceNumberNotAdvancedWhenNotSending) {
const uint16_t sequence_number = sender_.impl_->SequenceNumber();
sender_.impl_->SetSendingMediaStatus(false);
EXPECT_FALSE(SendFrame(&sender_, sender_video_.get(), kBaseLayerTid));
ASSERT_THAT(sender_.transport_.rtp_packets_sent_, Eq(0));
EXPECT_EQ(sequence_number, sender_.impl_->SequenceNumber());
}
TEST_F(RtpRtcpImpl2Test, PaddingNotAllowedInMiddleOfFrame) {
constexpr size_t kPaddingSize = 100;
// Can't send padding before media.
EXPECT_THAT(sender_.impl_->GeneratePadding(kPaddingSize), SizeIs(0u));
EXPECT_TRUE(SendFrame(&sender_, sender_video_.get(), kBaseLayerTid));
// Padding is now ok.
EXPECT_THAT(sender_.impl_->GeneratePadding(kPaddingSize), SizeIs(Gt(0u)));
// Send half a video frame.
PacedPacketInfo pacing_info;
std::unique_ptr<RtpPacketToSend> packet =
sender_.impl_->RtpSender()->AllocatePacket();
packet->set_packet_type(RtpPacketToSend::Type::kVideo);
packet->set_first_packet_of_frame(true);
packet->SetMarker(false); // Marker false - not last packet of frame.
EXPECT_TRUE(sender_.impl_->TrySendPacket(packet.get(), pacing_info));
// Padding not allowed in middle of frame.
EXPECT_THAT(sender_.impl_->GeneratePadding(kPaddingSize), SizeIs(0u));
packet = sender_.impl_->RtpSender()->AllocatePacket();
packet->set_packet_type(RtpPacketToSend::Type::kVideo);
packet->set_first_packet_of_frame(true);
packet->SetMarker(true);
EXPECT_TRUE(sender_.impl_->TrySendPacket(packet.get(), pacing_info));
// Padding is OK again.
EXPECT_THAT(sender_.impl_->GeneratePadding(kPaddingSize), SizeIs(Gt(0u)));
}
TEST_F(RtpRtcpImpl2Test, PaddingTimestampMatchesMedia) {
constexpr size_t kPaddingSize = 100;
const uint32_t kTimestamp = 123;
EXPECT_TRUE(SendFrame(&sender_, sender_video_.get(), kBaseLayerTid,
kTimestamp, /*capture_time_ms=*/0));
EXPECT_EQ(sender_.last_packet().Timestamp(), kTimestamp);
uint16_t media_seq = sender_.last_packet().SequenceNumber();
// Generate and send padding.
auto padding = sender_.impl_->GeneratePadding(kPaddingSize);
ASSERT_FALSE(padding.empty());
for (auto& packet : padding) {
sender_.impl_->TrySendPacket(packet.get(), PacedPacketInfo());
}
// Verify we sent a new packet, but with the same timestamp.
EXPECT_NE(sender_.last_packet().SequenceNumber(), media_seq);
EXPECT_EQ(sender_.last_packet().Timestamp(), kTimestamp);
}
TEST_F(RtpRtcpImpl2Test, AssignsTransportSequenceNumber) {
sender_.RegisterHeaderExtension(TransportSequenceNumber::Uri(),
kTransportSequenceNumberExtensionId);
EXPECT_TRUE(SendFrame(&sender_, sender_video_.get(), kBaseLayerTid));
uint16_t first_transport_seq = 0;
EXPECT_TRUE(sender_.last_packet().GetExtension<TransportSequenceNumber>(
&first_transport_seq));
EXPECT_TRUE(SendFrame(&sender_, sender_video_.get(), kBaseLayerTid));
uint16_t second_transport_seq = 0;
EXPECT_TRUE(sender_.last_packet().GetExtension<TransportSequenceNumber>(
&second_transport_seq));
EXPECT_EQ(first_transport_seq + 1, second_transport_seq);
}
TEST_F(RtpRtcpImpl2Test, AssignsAbsoluteSendTime) {
sender_.RegisterHeaderExtension(AbsoluteSendTime::Uri(),
kAbsoluteSendTimeExtensionId);
EXPECT_TRUE(SendFrame(&sender_, sender_video_.get(), kBaseLayerTid));
EXPECT_NE(sender_.last_packet().GetExtension<AbsoluteSendTime>(), 0u);
}
TEST_F(RtpRtcpImpl2Test, AssignsTransmissionTimeOffset) {
sender_.RegisterHeaderExtension(TransmissionOffset::Uri(),
kTransmissionOffsetExtensionId);
constexpr TimeDelta kOffset = TimeDelta::Millis(100);
// Transmission offset is calculated from difference between capture time
// and send time.
int64_t capture_time_ms = time_controller_.GetClock()->TimeInMilliseconds();
time_controller_.AdvanceTime(kOffset);
EXPECT_TRUE(SendFrame(&sender_, sender_video_.get(), kBaseLayerTid,
/*timestamp=*/0, capture_time_ms));
EXPECT_EQ(sender_.last_packet().GetExtension<TransmissionOffset>(),
kOffset.ms() * kCaptureTimeMsToRtpTimestamp);
}
TEST_F(RtpRtcpImpl2Test, PropagatesSentPacketInfo) {
sender_.RegisterHeaderExtension(TransportSequenceNumber::Uri(),
kTransportSequenceNumberExtensionId);
int64_t now_ms = time_controller_.GetClock()->TimeInMilliseconds();
EXPECT_TRUE(SendFrame(&sender_, sender_video_.get(), kBaseLayerTid));
EXPECT_THAT(
sender_.last_sent_packet(),
Optional(
AllOf(Field(&RtpRtcpModule::SentPacket::packet_id,
Eq(sender_.last_packet()
.GetExtension<TransportSequenceNumber>())),
Field(&RtpRtcpModule::SentPacket::capture_time_ms, Eq(now_ms)),
Field(&RtpRtcpModule::SentPacket::ssrc, Eq(kSenderSsrc)))));
}
TEST_F(RtpRtcpImpl2Test, GeneratesFlexfec) {
constexpr int kFlexfecPayloadType = 118;
constexpr uint32_t kFlexfecSsrc = 17;
const char kNoMid[] = "";
const std::vector<RtpExtension> kNoRtpExtensions;
const std::vector<RtpExtensionSize> kNoRtpExtensionSizes;
// Make sure FlexFec sequence numbers start at a different point than media.
const uint16_t fec_start_seq = sender_.impl_->SequenceNumber() + 100;
RtpState start_state;
start_state.sequence_number = fec_start_seq;
FlexfecSender flexfec_sender(kFlexfecPayloadType, kFlexfecSsrc, kSenderSsrc,
kNoMid, kNoRtpExtensions, kNoRtpExtensionSizes,
&start_state, time_controller_.GetClock());
ReinitWithFec(&flexfec_sender, /*red_payload_type=*/absl::nullopt);
// Parameters selected to generate a single FEC packet per media packet.
FecProtectionParams params;
params.fec_rate = 15;
params.max_fec_frames = 1;
params.fec_mask_type = kFecMaskRandom;
sender_.impl_->SetFecProtectionParams(params, params);
// Send a one packet frame, expect one media packet and one FEC packet.
EXPECT_TRUE(SendFrame(&sender_, sender_video_.get(), kBaseLayerTid));
ASSERT_THAT(sender_.transport_.rtp_packets_sent_, Eq(2));
const RtpPacketReceived& fec_packet = sender_.last_packet();
EXPECT_EQ(fec_packet.SequenceNumber(), fec_start_seq);
EXPECT_EQ(fec_packet.Ssrc(), kFlexfecSsrc);
EXPECT_EQ(fec_packet.PayloadType(), kFlexfecPayloadType);
}
TEST_F(RtpRtcpImpl2Test, GeneratesUlpfec) {
constexpr int kUlpfecPayloadType = 118;
constexpr int kRedPayloadType = 119;
UlpfecGenerator ulpfec_sender(kRedPayloadType, kUlpfecPayloadType,
time_controller_.GetClock());
ReinitWithFec(&ulpfec_sender, kRedPayloadType);
// Parameters selected to generate a single FEC packet per media packet.
FecProtectionParams params;
params.fec_rate = 15;
params.max_fec_frames = 1;
params.fec_mask_type = kFecMaskRandom;
sender_.impl_->SetFecProtectionParams(params, params);
// Send a one packet frame, expect one media packet and one FEC packet.
EXPECT_TRUE(SendFrame(&sender_, sender_video_.get(), kBaseLayerTid));
ASSERT_THAT(sender_.transport_.rtp_packets_sent_, Eq(2));
// Ulpfec is sent on the media ssrc, sharing the sequene number series.
const RtpPacketReceived& fec_packet = sender_.last_packet();
EXPECT_EQ(fec_packet.SequenceNumber(), kSequenceNumber + 1);
EXPECT_EQ(fec_packet.Ssrc(), kSenderSsrc);
// The packets are encapsulated in RED packets, check that and that the RED
// header (first byte of payload) indicates the desired FEC payload type.
EXPECT_EQ(fec_packet.PayloadType(), kRedPayloadType);
EXPECT_EQ(fec_packet.payload()[0], kUlpfecPayloadType);
}
TEST_F(RtpRtcpImpl2Test, RtpStateReflectsCurrentState) {
// Verify that that each of the field of GetRtpState actually reflects
// the current state.
// Current time will be used for `timestamp`, `capture_time_ms` and
// `last_timestamp_time_ms`.
const int64_t time_ms = time_controller_.GetClock()->TimeInMilliseconds();
// Use different than default sequence number to test `sequence_number`.
const uint16_t kSeq = kSequenceNumber + 123;
// Hard-coded value for `start_timestamp`.
const uint32_t kStartTimestamp = 3456;
const int64_t capture_time_ms = time_ms;
const uint32_t timestamp = capture_time_ms * kCaptureTimeMsToRtpTimestamp;
sender_.impl_->SetSequenceNumber(kSeq - 1);
sender_.impl_->SetStartTimestamp(kStartTimestamp);
EXPECT_TRUE(SendFrame(&sender_, sender_video_.get(), kBaseLayerTid));
// Simulate an RTCP receiver report in order to populate `ssrc_has_acked`.
RTCPReportBlock ack;
ack.source_ssrc = kSenderSsrc;
ack.extended_highest_sequence_number = kSeq;
sender_.impl_->OnReceivedRtcpReportBlocks({ack});
RtpState state = sender_.impl_->GetRtpState();
EXPECT_EQ(state.sequence_number, kSeq);
EXPECT_EQ(state.start_timestamp, kStartTimestamp);
EXPECT_EQ(state.timestamp, timestamp);
EXPECT_EQ(state.capture_time_ms, capture_time_ms);
EXPECT_EQ(state.last_timestamp_time_ms, time_ms);
EXPECT_EQ(state.ssrc_has_acked, true);
// Reset sender, advance time, restore state. Directly observing state
// is not feasible, so just verify returned state matches what we set.
sender_.CreateModuleImpl();
time_controller_.AdvanceTime(TimeDelta::Millis(10));
sender_.impl_->SetRtpState(state);
state = sender_.impl_->GetRtpState();
EXPECT_EQ(state.sequence_number, kSeq);
EXPECT_EQ(state.start_timestamp, kStartTimestamp);
EXPECT_EQ(state.timestamp, timestamp);
EXPECT_EQ(state.capture_time_ms, capture_time_ms);
EXPECT_EQ(state.last_timestamp_time_ms, time_ms);
EXPECT_EQ(state.ssrc_has_acked, true);
}
TEST_F(RtpRtcpImpl2Test, RtxRtpStateReflectsCurrentState) {
// Enable RTX.
sender_.impl_->SetStorePacketsStatus(/*enable=*/true, /*number_to_store=*/10);
sender_.impl_->SetRtxSendPayloadType(kRtxPayloadType, kPayloadType);
sender_.impl_->SetRtxSendStatus(kRtxRetransmitted | kRtxRedundantPayloads);
// `start_timestamp` is the only timestamp populate in the RTX state.
const uint32_t kStartTimestamp = 3456;
sender_.impl_->SetStartTimestamp(kStartTimestamp);
// Send a frame and ask for a retransmit of the last packet. Capture the RTX
// packet in order to verify RTX sequence number.
EXPECT_TRUE(SendFrame(&sender_, sender_video_.get(), kBaseLayerTid));
time_controller_.AdvanceTime(TimeDelta::Millis(5));
sender_.impl_->OnReceivedNack(
std::vector<uint16_t>{sender_.transport_.last_packet_.SequenceNumber()});
RtpPacketReceived& rtx_packet = sender_.transport_.last_packet_;
EXPECT_EQ(rtx_packet.Ssrc(), kRtxSenderSsrc);
// Simulate an RTCP receiver report in order to populate `ssrc_has_acked`.
RTCPReportBlock ack;
ack.source_ssrc = kRtxSenderSsrc;
ack.extended_highest_sequence_number = rtx_packet.SequenceNumber();
sender_.impl_->OnReceivedRtcpReportBlocks({ack});
RtpState rtp_state = sender_.impl_->GetRtpState();
RtpState rtx_state = sender_.impl_->GetRtxState();
EXPECT_EQ(rtx_state.start_timestamp, kStartTimestamp);
EXPECT_EQ(rtx_state.ssrc_has_acked, true);
EXPECT_EQ(rtx_state.sequence_number, rtx_packet.SequenceNumber() + 1);
// Reset sender, advance time, restore state. Directly observing state
// is not feasible, so just verify returned state matches what we set.
// Needs SetRtpState() too in order to propagate start timestamp.
sender_.CreateModuleImpl();
time_controller_.AdvanceTime(TimeDelta::Millis(10));
sender_.impl_->SetRtpState(rtp_state);
sender_.impl_->SetRtxState(rtx_state);
rtx_state = sender_.impl_->GetRtxState();
EXPECT_EQ(rtx_state.start_timestamp, kStartTimestamp);
EXPECT_EQ(rtx_state.ssrc_has_acked, true);
EXPECT_EQ(rtx_state.sequence_number, rtx_packet.SequenceNumber() + 1);
}
} // namespace webrtc