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webrtc / src.git / 9c1ee368e071bf31650806289248c644095aa1df / . / modules / rtp_rtcp / source / rtp_rtcp_impl_unittest.cc
blob: 2d75a3cd42ad1ed45f903b815adb57b794a8b3f2 [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 <map>
#include <memory>
#include <set>
#include "common_types.h" // NOLINT(build/include)
#include "modules/rtp_rtcp/include/rtp_header_parser.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_rtcp_impl.h"
#include "rtc_base/rate_limiter.h"
#include "test/gmock.h"
#include "test/gtest.h"
#include "test/rtcp_packet_parser.h"
using ::testing::_;
using ::testing::ElementsAre;
using ::testing::NiceMock;
using ::testing::Return;
using ::testing::SaveArg;
namespace webrtc {
namespace {
const uint32_t kSenderSsrc = 0x12345;
const uint32_t kReceiverSsrc = 0x23456;
const int64_t kOneWayNetworkDelayMs = 100;
const uint8_t kBaseLayerTid = 0;
const uint8_t kHigherLayerTid = 1;
const uint16_t kSequenceNumber = 100;
const int64_t kMaxRttMs = 1000;
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_;
};
class SendTransport : public Transport,
public RtpData {
public:
SendTransport()
: receiver_(nullptr),
clock_(nullptr),
delay_ms_(0),
rtp_packets_sent_(0),
rtcp_packets_sent_(0),
keepalive_payload_type_(0),
num_keepalive_sent_(0) {}
void SetRtpRtcpModule(ModuleRtpRtcpImpl* receiver) {
receiver_ = receiver;
}
void SimulateNetworkDelay(int64_t delay_ms, SimulatedClock* clock) {
clock_ = clock;
delay_ms_ = delay_ms;
}
bool SendRtp(const uint8_t* data,
size_t len,
const PacketOptions& options) override {
RTPHeader header;
std::unique_ptr<RtpHeaderParser> parser(RtpHeaderParser::Create());
EXPECT_TRUE(parser->Parse(static_cast<const uint8_t*>(data), len, &header));
++rtp_packets_sent_;
if (header.payloadType == keepalive_payload_type_)
++num_keepalive_sent_;
last_rtp_header_ = header;
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();
if (clock_) {
clock_->AdvanceTimeMilliseconds(delay_ms_);
}
EXPECT_TRUE(receiver_);
receiver_->IncomingRtcpPacket(data, len);
++rtcp_packets_sent_;
return true;
}
int32_t OnReceivedPayloadData(const uint8_t* payload_data,
size_t payload_size,
const WebRtcRTPHeader* rtp_header) override {
return 0;
}
void SetKeepalivePayloadType(uint8_t payload_type) {
keepalive_payload_type_ = payload_type;
}
size_t NumKeepaliveSent() { return num_keepalive_sent_; }
size_t NumRtcpSent() { return rtcp_packets_sent_; }
ModuleRtpRtcpImpl* receiver_;
SimulatedClock* clock_;
int64_t delay_ms_;
int rtp_packets_sent_;
size_t rtcp_packets_sent_;
RTPHeader last_rtp_header_;
std::vector<uint16_t> last_nack_list_;
uint8_t keepalive_payload_type_;
size_t num_keepalive_sent_;
};
class RtpRtcpModule : public RtcpPacketTypeCounterObserver {
public:
explicit RtpRtcpModule(SimulatedClock* clock)
: receive_statistics_(ReceiveStatistics::Create(clock)),
remote_ssrc_(0),
retransmission_rate_limiter_(clock, kMaxRttMs),
clock_(clock) {
CreateModuleImpl();
transport_.SimulateNetworkDelay(kOneWayNetworkDelayMs, clock);
}
RtcpPacketTypeCounter packets_sent_;
RtcpPacketTypeCounter packets_received_;
std::unique_ptr<ReceiveStatistics> receive_statistics_;
SendTransport transport_;
RtcpRttStatsTestImpl rtt_stats_;
std::unique_ptr<ModuleRtpRtcpImpl> impl_;
uint32_t remote_ssrc_;
RateLimiter retransmission_rate_limiter_;
RtpKeepAliveConfig keepalive_config_;
RtcpIntervalConfig rtcp_interval_config_;
void SetRemoteSsrc(uint32_t ssrc) {
remote_ssrc_ = ssrc;
impl_->SetRemoteSSRC(ssrc);
}
void RtcpPacketTypesCounterUpdated(
uint32_t ssrc,
const RtcpPacketTypeCounter& packet_counter) override {
counter_map_[ssrc] = packet_counter;
}
RtcpPacketTypeCounter RtcpSent() {
// RTCP counters for remote SSRC.
return counter_map_[remote_ssrc_];
}
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 transport_.last_rtp_header_.sequenceNumber;
}
std::vector<uint16_t> LastNackListSent() {
return transport_.last_nack_list_;
}
void SetKeepaliveConfigAndReset(const RtpKeepAliveConfig& config) {
keepalive_config_ = config;
// Need to create a new module impl, since it's configured at creation.
CreateModuleImpl();
transport_.SetKeepalivePayloadType(config.payload_type);
}
void SetRtcpIntervalConfigAndReset(const RtcpIntervalConfig& config) {
rtcp_interval_config_ = config;
CreateModuleImpl();
}
private:
void CreateModuleImpl() {
RtpRtcp::Configuration config;
config.audio = false;
config.clock = clock_;
config.outgoing_transport = &transport_;
config.receive_statistics = receive_statistics_.get();
config.rtcp_packet_type_counter_observer = this;
config.rtt_stats = &rtt_stats_;
config.retransmission_rate_limiter = &retransmission_rate_limiter_;
config.keepalive_config = keepalive_config_;
config.rtcp_interval_config = rtcp_interval_config_;
impl_.reset(new ModuleRtpRtcpImpl(config));
impl_->SetRTCPStatus(RtcpMode::kCompound);
}
SimulatedClock* const clock_;
std::map<uint32_t, RtcpPacketTypeCounter> counter_map_;
};
} // namespace
class RtpRtcpImplTest : public ::testing::Test {
protected:
RtpRtcpImplTest()
: clock_(133590000000000), sender_(&clock_), receiver_(&clock_) {}
void SetUp() override {
// Send module.
sender_.impl_->SetSSRC(kSenderSsrc);
EXPECT_EQ(0, sender_.impl_->SetSendingStatus(true));
sender_.impl_->SetSendingMediaStatus(true);
sender_.SetRemoteSsrc(kReceiverSsrc);
sender_.impl_->SetSequenceNumber(kSequenceNumber);
sender_.impl_->SetStorePacketsStatus(true, 100);
memset(&codec_, 0, sizeof(VideoCodec));
codec_.plType = 100;
codec_.width = 320;
codec_.height = 180;
sender_.impl_->RegisterVideoSendPayload(codec_.plType, "VP8");
// Receive module.
EXPECT_EQ(0, receiver_.impl_->SetSendingStatus(false));
receiver_.impl_->SetSendingMediaStatus(false);
receiver_.impl_->SetSSRC(kReceiverSsrc);
receiver_.SetRemoteSsrc(kSenderSsrc);
// Transport settings.
sender_.transport_.SetRtpRtcpModule(receiver_.impl_.get());
receiver_.transport_.SetRtpRtcpModule(sender_.impl_.get());
}
SimulatedClock clock_;
RtpRtcpModule sender_;
RtpRtcpModule receiver_;
VideoCodec codec_;
void SendFrame(const RtpRtcpModule* module, uint8_t tid) {
RTPVideoHeaderVP8 vp8_header = {};
vp8_header.temporalIdx = tid;
RTPVideoHeader rtp_video_header;
rtp_video_header.width = codec_.width;
rtp_video_header.height = codec_.height;
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 = kRtpVideoVp8;
rtp_video_header.codecHeader = {vp8_header};
rtp_video_header.video_timing = {0u, 0u, 0u, 0u, 0u, 0u, false};
const uint8_t payload[100] = {0};
EXPECT_EQ(true, module->impl_->SendOutgoingData(
kVideoFrameKey, codec_.plType, 0, 0, payload,
sizeof(payload), nullptr, &rtp_video_header, nullptr));
}
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.data(), packet.size());
}
};
TEST_F(RtpRtcpImplTest, SetSelectiveRetransmissions_BaseLayer) {
sender_.impl_->SetSelectiveRetransmissions(kRetransmitBaseLayer);
EXPECT_EQ(kRetransmitBaseLayer, sender_.impl_->SelectiveRetransmissions());
// Send frames.
EXPECT_EQ(0, sender_.RtpSent());
SendFrame(&sender_, kBaseLayerTid); // kSequenceNumber
SendFrame(&sender_, kHigherLayerTid); // kSequenceNumber + 1
SendFrame(&sender_, kNoTemporalIdx); // kSequenceNumber + 2
EXPECT_EQ(3, sender_.RtpSent());
EXPECT_EQ(kSequenceNumber + 2, sender_.LastRtpSequenceNumber());
// Min required delay until retransmit = 5 + RTT ms (RTT = 0).
clock_.AdvanceTimeMilliseconds(5);
// Frame with kBaseLayerTid re-sent.
IncomingRtcpNack(&sender_, kSequenceNumber);
EXPECT_EQ(4, sender_.RtpSent());
EXPECT_EQ(kSequenceNumber, sender_.LastRtpSequenceNumber());
// Frame with kHigherLayerTid not re-sent.
IncomingRtcpNack(&sender_, kSequenceNumber + 1);
EXPECT_EQ(4, sender_.RtpSent());
// Frame with kNoTemporalIdx re-sent.
IncomingRtcpNack(&sender_, kSequenceNumber + 2);
EXPECT_EQ(5, sender_.RtpSent());
EXPECT_EQ(kSequenceNumber + 2, sender_.LastRtpSequenceNumber());
}
TEST_F(RtpRtcpImplTest, SetSelectiveRetransmissions_HigherLayers) {
const uint8_t kSetting = kRetransmitBaseLayer + kRetransmitHigherLayers;
sender_.impl_->SetSelectiveRetransmissions(kSetting);
EXPECT_EQ(kSetting, sender_.impl_->SelectiveRetransmissions());
// Send frames.
EXPECT_EQ(0, sender_.RtpSent());
SendFrame(&sender_, kBaseLayerTid); // kSequenceNumber
SendFrame(&sender_, kHigherLayerTid); // kSequenceNumber + 1
SendFrame(&sender_, kNoTemporalIdx); // kSequenceNumber + 2
EXPECT_EQ(3, sender_.RtpSent());
EXPECT_EQ(kSequenceNumber + 2, sender_.LastRtpSequenceNumber());
// Min required delay until retransmit = 5 + RTT ms (RTT = 0).
clock_.AdvanceTimeMilliseconds(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(RtpRtcpImplTest, Rtt) {
RTPHeader header;
header.timestamp = 1;
header.sequenceNumber = 123;
header.ssrc = kSenderSsrc;
header.headerLength = 12;
receiver_.receive_statistics_->IncomingPacket(header, 100, false);
// Send Frame before sending an SR.
SendFrame(&sender_, kBaseLayerTid);
// Sender module should send an SR.
EXPECT_EQ(0, sender_.impl_->SendRTCP(kRtcpReport));
// Receiver module should send a RR with a response to the last received SR.
clock_.AdvanceTimeMilliseconds(1000);
EXPECT_EQ(0, receiver_.impl_->SendRTCP(kRtcpReport));
// 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 * kOneWayNetworkDelayMs, rtt, 1);
EXPECT_NEAR(2 * kOneWayNetworkDelayMs, avg_rtt, 1);
EXPECT_NEAR(2 * kOneWayNetworkDelayMs, min_rtt, 1);
EXPECT_NEAR(2 * kOneWayNetworkDelayMs, 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());
sender_.impl_->Process();
EXPECT_NEAR(2 * kOneWayNetworkDelayMs, sender_.rtt_stats_.LastProcessedRtt(),
1);
EXPECT_NEAR(2 * kOneWayNetworkDelayMs, sender_.impl_->rtt_ms(), 1);
}
TEST_F(RtpRtcpImplTest, SetRtcpXrRrtrStatus) {
EXPECT_FALSE(receiver_.impl_->RtcpXrRrtrStatus());
receiver_.impl_->SetRtcpXrRrtrStatus(true);
EXPECT_TRUE(receiver_.impl_->RtcpXrRrtrStatus());
}
TEST_F(RtpRtcpImplTest, RttForReceiverOnly) {
receiver_.impl_->SetRtcpXrRrtrStatus(true);
// 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).
clock_.AdvanceTimeMilliseconds(1000);
// Send Frame before sending a SR.
SendFrame(&sender_, kBaseLayerTid);
EXPECT_EQ(0, sender_.impl_->SendRTCP(kRtcpReport));
// Verify RTT.
EXPECT_EQ(0, receiver_.rtt_stats_.LastProcessedRtt());
EXPECT_EQ(0, receiver_.impl_->rtt_ms());
receiver_.impl_->Process();
EXPECT_NEAR(2 * kOneWayNetworkDelayMs,
receiver_.rtt_stats_.LastProcessedRtt(), 1);
EXPECT_NEAR(2 * kOneWayNetworkDelayMs, receiver_.impl_->rtt_ms(), 1);
}
TEST_F(RtpRtcpImplTest, NoSrBeforeMedia) {
// Ignore fake transport delays in this test.
sender_.transport_.SimulateNetworkDelay(0, &clock_);
receiver_.transport_.SimulateNetworkDelay(0, &clock_);
sender_.impl_->Process();
EXPECT_EQ(-1, sender_.RtcpSent().first_packet_time_ms);
// Verify no SR is sent before media has been sent, RR should still be sent
// from the receiving module though.
clock_.AdvanceTimeMilliseconds(2000);
int64_t current_time = clock_.TimeInMilliseconds();
sender_.impl_->Process();
receiver_.impl_->Process();
EXPECT_EQ(-1, sender_.RtcpSent().first_packet_time_ms);
EXPECT_EQ(receiver_.RtcpSent().first_packet_time_ms, current_time);
SendFrame(&sender_, kBaseLayerTid);
EXPECT_EQ(sender_.RtcpSent().first_packet_time_ms, current_time);
}
TEST_F(RtpRtcpImplTest, RtcpPacketTypeCounter_Nack) {
EXPECT_EQ(-1, receiver_.RtcpSent().first_packet_time_ms);
EXPECT_EQ(-1, sender_.RtcpReceived().first_packet_time_ms);
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));
EXPECT_EQ(1U, receiver_.RtcpSent().nack_packets);
EXPECT_GT(receiver_.RtcpSent().first_packet_time_ms, -1);
// Send module receives the NACK.
EXPECT_EQ(1U, sender_.RtcpReceived().nack_packets);
EXPECT_GT(sender_.RtcpReceived().first_packet_time_ms, -1);
}
TEST_F(RtpRtcpImplTest, RtcpPacketTypeCounter_FirAndPli) {
EXPECT_EQ(0U, sender_.RtcpReceived().fir_packets);
EXPECT_EQ(0U, receiver_.RtcpSent().fir_packets);
// Receive module sends a FIR.
EXPECT_EQ(0, receiver_.impl_->SendRTCP(kRtcpFir));
EXPECT_EQ(1U, receiver_.RtcpSent().fir_packets);
// Send module receives the FIR.
EXPECT_EQ(1U, sender_.RtcpReceived().fir_packets);
// Receive module sends a FIR and PLI.
std::set<RTCPPacketType> packet_types;
packet_types.insert(kRtcpFir);
packet_types.insert(kRtcpPli);
EXPECT_EQ(0, receiver_.impl_->SendCompoundRTCP(packet_types));
EXPECT_EQ(2U, receiver_.RtcpSent().fir_packets);
EXPECT_EQ(1U, receiver_.RtcpSent().pli_packets);
// Send module receives the FIR and PLI.
EXPECT_EQ(2U, sender_.RtcpReceived().fir_packets);
EXPECT_EQ(1U, sender_.RtcpReceived().pli_packets);
}
TEST_F(RtpRtcpImplTest, 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(RtpRtcpImplTest, 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.
SendFrame(&sender_, 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(RtpRtcpImplTest, 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.
SendFrame(&sender_, 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(RtpRtcpImplTest, ReSendsNackListAfterRttMs) {
sender_.transport_.SimulateNetworkDelay(0, &clock_);
// 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.
SendFrame(&sender_, 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 int kStartupRttMs = 100;
clock_.AdvanceTimeMilliseconds(kStartupRttMs);
EXPECT_EQ(0, sender_.impl_->SendNACK(nack_list, kNackLength));
EXPECT_EQ(1U, sender_.RtcpSent().nack_packets);
// Rtt interval passed, full list sent.
clock_.AdvanceTimeMilliseconds(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(RtpRtcpImplTest, UniqueNackRequests) {
receiver_.transport_.SimulateNetworkDelay(0, &clock_);
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 int kStartupRttMs = 100;
clock_.AdvanceTimeMilliseconds(kStartupRttMs + 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(RtpRtcpImplTest, SendsKeepaliveAfterTimout) {
const int kTimeoutMs = 1500;
RtpKeepAliveConfig config;
config.timeout_interval_ms = kTimeoutMs;
// Recreate sender impl with new configuration, and redo setup.
sender_.SetKeepaliveConfigAndReset(config);
SetUp();
// Initial process call.
sender_.impl_->Process();
EXPECT_EQ(0U, sender_.transport_.NumKeepaliveSent());
// After one time, a single keep-alive packet should be sent.
clock_.AdvanceTimeMilliseconds(kTimeoutMs);
sender_.impl_->Process();
EXPECT_EQ(1U, sender_.transport_.NumKeepaliveSent());
// Process for the same timestamp again, no new packet should be sent.
sender_.impl_->Process();
EXPECT_EQ(1U, sender_.transport_.NumKeepaliveSent());
// Move ahead to the last ms before a keep-alive is expected, no action.
clock_.AdvanceTimeMilliseconds(kTimeoutMs - 1);
sender_.impl_->Process();
EXPECT_EQ(1U, sender_.transport_.NumKeepaliveSent());
// Move the final ms, timeout relative last KA. Should create new keep-alive.
clock_.AdvanceTimeMilliseconds(1);
sender_.impl_->Process();
EXPECT_EQ(2U, sender_.transport_.NumKeepaliveSent());
// Move ahead to the last ms before Christmas.
clock_.AdvanceTimeMilliseconds(kTimeoutMs - 1);
sender_.impl_->Process();
EXPECT_EQ(2U, sender_.transport_.NumKeepaliveSent());
// Send actual payload data, no keep-alive expected.
SendFrame(&sender_, 0);
sender_.impl_->Process();
EXPECT_EQ(2U, sender_.transport_.NumKeepaliveSent());
// Move ahead as far as possible again, timeout now relative payload. No KA.
clock_.AdvanceTimeMilliseconds(kTimeoutMs - 1);
sender_.impl_->Process();
EXPECT_EQ(2U, sender_.transport_.NumKeepaliveSent());
// Timeout relative payload, send new keep-alive.
clock_.AdvanceTimeMilliseconds(1);
sender_.impl_->Process();
EXPECT_EQ(3U, sender_.transport_.NumKeepaliveSent());
}
TEST_F(RtpRtcpImplTest, ConfigurableRtcpReportInterval) {
const int kVideoReportInterval = 3000;
RtcpIntervalConfig config;
config.video_interval_ms = kVideoReportInterval;
// Recreate sender impl with new configuration, and redo setup.
sender_.SetRtcpIntervalConfigAndReset(config);
SetUp();
SendFrame(&sender_, kBaseLayerTid);
// Initial state
sender_.impl_->Process();
EXPECT_EQ(sender_.RtcpSent().first_packet_time_ms, -1);
EXPECT_EQ(0u, sender_.transport_.NumRtcpSent());
// Move ahead to the last ms before a rtcp is expected, no action.
clock_.AdvanceTimeMilliseconds(kVideoReportInterval / 2 - 1);
sender_.impl_->Process();
EXPECT_EQ(sender_.RtcpSent().first_packet_time_ms, -1);
EXPECT_EQ(sender_.transport_.NumRtcpSent(), 0u);
// Move ahead to the first rtcp. Send RTCP.
clock_.AdvanceTimeMilliseconds(1);
sender_.impl_->Process();
EXPECT_GT(sender_.RtcpSent().first_packet_time_ms, -1);
EXPECT_EQ(sender_.transport_.NumRtcpSent(), 1u);
SendFrame(&sender_, kBaseLayerTid);
// Move ahead to the last possible second before second rtcp is expected.
clock_.AdvanceTimeMilliseconds(kVideoReportInterval * 1 / 2 - 1);
sender_.impl_->Process();
EXPECT_EQ(sender_.transport_.NumRtcpSent(), 1u);
// Move ahead into the range of second rtcp, the second rtcp may be sent.
clock_.AdvanceTimeMilliseconds(1);
sender_.impl_->Process();
EXPECT_GE(sender_.transport_.NumRtcpSent(), 1u);
clock_.AdvanceTimeMilliseconds(kVideoReportInterval / 2);
sender_.impl_->Process();
EXPECT_GE(sender_.transport_.NumRtcpSent(), 1u);
// Move out the range of second rtcp, the second rtcp must have been sent.
clock_.AdvanceTimeMilliseconds(kVideoReportInterval / 2);
sender_.impl_->Process();
EXPECT_EQ(sender_.transport_.NumRtcpSent(), 2u);
}
} // namespace webrtc