blob: 7ace5a38e6e25a143622291af34975352f82fb6c [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 <iterator>
#include <list>
#include <memory>
#include <set>
#include "absl/algorithm/container.h"
#include "absl/memory/memory.h"
#include "api/call/transport.h"
#include "api/transport/field_trial_based_config.h"
#include "call/rtp_stream_receiver_controller.h"
#include "call/rtx_receive_stream.h"
#include "modules/rtp_rtcp/include/receive_statistics.h"
#include "modules/rtp_rtcp/include/rtp_rtcp.h"
#include "modules/rtp_rtcp/include/rtp_rtcp_defines.h"
#include "modules/rtp_rtcp/source/playout_delay_oracle.h"
#include "modules/rtp_rtcp/source/rtp_packet_received.h"
#include "modules/rtp_rtcp/source/rtp_sender_video.h"
#include "rtc_base/rate_limiter.h"
#include "test/gtest.h"
namespace webrtc {
const int kVideoNackListSize = 30;
const uint32_t kTestSsrc = 3456;
const uint32_t kTestRtxSsrc = kTestSsrc + 1;
const uint16_t kTestSequenceNumber = 2345;
const uint32_t kTestNumberOfPackets = 1350;
const int kTestNumberOfRtxPackets = 149;
const int kNumFrames = 30;
const int kPayloadType = 123;
const int kRtxPayloadType = 98;
const int64_t kMaxRttMs = 1000;
class VerifyingMediaStream : public RtpPacketSinkInterface {
public:
VerifyingMediaStream() {}
void OnRtpPacket(const RtpPacketReceived& packet) override {
if (!sequence_numbers_.empty())
EXPECT_EQ(kTestSsrc, packet.Ssrc());
sequence_numbers_.push_back(packet.SequenceNumber());
}
std::list<uint16_t> sequence_numbers_;
};
class RtxLoopBackTransport : public webrtc::Transport {
public:
explicit RtxLoopBackTransport(uint32_t rtx_ssrc)
: count_(0),
packet_loss_(0),
consecutive_drop_start_(0),
consecutive_drop_end_(0),
rtx_ssrc_(rtx_ssrc),
count_rtx_ssrc_(0),
module_(NULL) {}
void SetSendModule(RtpRtcp* rtpRtcpModule) { module_ = rtpRtcpModule; }
void DropEveryNthPacket(int n) { packet_loss_ = n; }
void DropConsecutivePackets(int start, int total) {
consecutive_drop_start_ = start;
consecutive_drop_end_ = start + total;
packet_loss_ = 0;
}
bool SendRtp(const uint8_t* data,
size_t len,
const PacketOptions& options) override {
count_++;
RtpPacketReceived packet;
if (!packet.Parse(data, len))
return false;
if (packet.Ssrc() == rtx_ssrc_) {
count_rtx_ssrc_++;
} else {
// For non-RTX packets only.
expected_sequence_numbers_.insert(expected_sequence_numbers_.end(),
packet.SequenceNumber());
}
if (packet_loss_ > 0) {
if ((count_ % packet_loss_) == 0) {
return true;
}
} else if (count_ >= consecutive_drop_start_ &&
count_ < consecutive_drop_end_) {
return true;
}
EXPECT_TRUE(stream_receiver_controller_.OnRtpPacket(packet));
return true;
}
bool SendRtcp(const uint8_t* data, size_t len) override {
module_->IncomingRtcpPacket((const uint8_t*)data, len);
return true;
}
int count_;
int packet_loss_;
int consecutive_drop_start_;
int consecutive_drop_end_;
uint32_t rtx_ssrc_;
int count_rtx_ssrc_;
RtpRtcp* module_;
RtpStreamReceiverController stream_receiver_controller_;
std::set<uint16_t> expected_sequence_numbers_;
};
class RtpRtcpRtxNackTest : public ::testing::Test {
protected:
RtpRtcpRtxNackTest()
: rtp_rtcp_module_(nullptr),
transport_(kTestRtxSsrc),
rtx_stream_(&media_stream_, rtx_associated_payload_types_, kTestSsrc),
payload_data_length(sizeof(payload_data)),
fake_clock(123456),
retransmission_rate_limiter_(&fake_clock, kMaxRttMs) {}
~RtpRtcpRtxNackTest() override {}
void SetUp() override {
RtpRtcp::Configuration configuration;
configuration.audio = false;
configuration.clock = &fake_clock;
receive_statistics_.reset(ReceiveStatistics::Create(&fake_clock));
configuration.receive_statistics = receive_statistics_.get();
configuration.outgoing_transport = &transport_;
configuration.retransmission_rate_limiter = &retransmission_rate_limiter_;
rtp_rtcp_module_ = RtpRtcp::Create(configuration);
rtp_sender_video_ = absl::make_unique<RTPSenderVideo>(
&fake_clock, rtp_rtcp_module_->RtpSender(), nullptr,
&playout_delay_oracle_, nullptr, false, false, FieldTrialBasedConfig());
rtp_rtcp_module_->SetSSRC(kTestSsrc);
rtp_rtcp_module_->SetRTCPStatus(RtcpMode::kCompound);
rtp_rtcp_module_->SetStorePacketsStatus(true, 600);
EXPECT_EQ(0, rtp_rtcp_module_->SetSendingStatus(true));
rtp_rtcp_module_->SetSequenceNumber(kTestSequenceNumber);
rtp_rtcp_module_->SetStartTimestamp(111111);
// Used for NACK processing.
// TODO(nisse): Unclear on which side? It's confusing to use a
// single rtp_rtcp module for both send and receive side.
rtp_rtcp_module_->SetRemoteSSRC(kTestSsrc);
rtp_sender_video_->RegisterPayloadType(kPayloadType, "video",
/*raw_payload=*/false);
rtp_rtcp_module_->SetRtxSendPayloadType(kRtxPayloadType, kPayloadType);
transport_.SetSendModule(rtp_rtcp_module_.get());
media_receiver_ = transport_.stream_receiver_controller_.CreateReceiver(
kTestSsrc, &media_stream_);
for (size_t n = 0; n < payload_data_length; n++) {
payload_data[n] = n % 10;
}
}
int BuildNackList(uint16_t* nack_list) {
media_stream_.sequence_numbers_.sort();
std::list<uint16_t> missing_sequence_numbers;
std::list<uint16_t>::iterator it = media_stream_.sequence_numbers_.begin();
while (it != media_stream_.sequence_numbers_.end()) {
uint16_t sequence_number_1 = *it;
++it;
if (it != media_stream_.sequence_numbers_.end()) {
uint16_t sequence_number_2 = *it;
// Add all missing sequence numbers to list
for (uint16_t i = sequence_number_1 + 1; i < sequence_number_2; ++i) {
missing_sequence_numbers.push_back(i);
}
}
}
int n = 0;
for (it = missing_sequence_numbers.begin();
it != missing_sequence_numbers.end(); ++it) {
nack_list[n++] = (*it);
}
return n;
}
bool ExpectedPacketsReceived() {
std::list<uint16_t> received_sorted;
absl::c_copy(media_stream_.sequence_numbers_,
std::back_inserter(received_sorted));
received_sorted.sort();
return absl::c_equal(received_sorted,
transport_.expected_sequence_numbers_);
}
void RunRtxTest(RtxMode rtx_method, int loss) {
rtx_receiver_ = transport_.stream_receiver_controller_.CreateReceiver(
kTestRtxSsrc, &rtx_stream_);
rtp_rtcp_module_->SetRtxSendStatus(rtx_method);
rtp_rtcp_module_->SetRtxSsrc(kTestRtxSsrc);
transport_.DropEveryNthPacket(loss);
uint32_t timestamp = 3000;
uint16_t nack_list[kVideoNackListSize];
for (int frame = 0; frame < kNumFrames; ++frame) {
RTPVideoHeader video_header;
EXPECT_TRUE(rtp_rtcp_module_->OnSendingRtpFrame(timestamp, timestamp / 90,
kPayloadType, false));
EXPECT_TRUE(rtp_sender_video_->SendVideo(
VideoFrameType::kVideoFrameDelta, kPayloadType, timestamp,
timestamp / 90, payload_data, payload_data_length, nullptr,
&video_header, 0));
// Min required delay until retransmit = 5 + RTT ms (RTT = 0).
fake_clock.AdvanceTimeMilliseconds(5);
int length = BuildNackList(nack_list);
if (length > 0)
rtp_rtcp_module_->SendNACK(nack_list, length);
fake_clock.AdvanceTimeMilliseconds(28); // 33ms - 5ms delay.
rtp_rtcp_module_->Process();
// Prepare next frame.
timestamp += 3000;
}
media_stream_.sequence_numbers_.sort();
}
std::unique_ptr<ReceiveStatistics> receive_statistics_;
std::unique_ptr<RtpRtcp> rtp_rtcp_module_;
PlayoutDelayOracle playout_delay_oracle_;
std::unique_ptr<RTPSenderVideo> rtp_sender_video_;
RtxLoopBackTransport transport_;
const std::map<int, int> rtx_associated_payload_types_ = {
{kRtxPayloadType, kPayloadType}};
VerifyingMediaStream media_stream_;
RtxReceiveStream rtx_stream_;
uint8_t payload_data[65000];
size_t payload_data_length;
SimulatedClock fake_clock;
RateLimiter retransmission_rate_limiter_;
std::unique_ptr<RtpStreamReceiverInterface> media_receiver_;
std::unique_ptr<RtpStreamReceiverInterface> rtx_receiver_;
};
TEST_F(RtpRtcpRtxNackTest, LongNackList) {
const int kNumPacketsToDrop = 900;
const int kNumRequiredRtcp = 4;
uint32_t timestamp = 3000;
uint16_t nack_list[kNumPacketsToDrop];
// Disable StorePackets to be able to set a larger packet history.
rtp_rtcp_module_->SetStorePacketsStatus(false, 0);
// Enable StorePackets with a packet history of 2000 packets.
rtp_rtcp_module_->SetStorePacketsStatus(true, 2000);
// Drop 900 packets from the second one so that we get a NACK list which is
// big enough to require 4 RTCP packets to be fully transmitted to the sender.
transport_.DropConsecutivePackets(2, kNumPacketsToDrop);
// Send 30 frames which at the default size is roughly what we need to get
// enough packets.
for (int frame = 0; frame < kNumFrames; ++frame) {
RTPVideoHeader video_header;
EXPECT_TRUE(rtp_rtcp_module_->OnSendingRtpFrame(timestamp, timestamp / 90,
kPayloadType, false));
EXPECT_TRUE(rtp_sender_video_->SendVideo(
VideoFrameType::kVideoFrameDelta, kPayloadType, timestamp,
timestamp / 90, payload_data, payload_data_length, nullptr,
&video_header, 0));
// Prepare next frame.
timestamp += 3000;
fake_clock.AdvanceTimeMilliseconds(33);
rtp_rtcp_module_->Process();
}
EXPECT_FALSE(transport_.expected_sequence_numbers_.empty());
EXPECT_FALSE(media_stream_.sequence_numbers_.empty());
size_t last_receive_count = media_stream_.sequence_numbers_.size();
int length = BuildNackList(nack_list);
for (int i = 0; i < kNumRequiredRtcp - 1; ++i) {
rtp_rtcp_module_->SendNACK(nack_list, length);
EXPECT_GT(media_stream_.sequence_numbers_.size(), last_receive_count);
last_receive_count = media_stream_.sequence_numbers_.size();
EXPECT_FALSE(ExpectedPacketsReceived());
}
rtp_rtcp_module_->SendNACK(nack_list, length);
EXPECT_GT(media_stream_.sequence_numbers_.size(), last_receive_count);
EXPECT_TRUE(ExpectedPacketsReceived());
}
TEST_F(RtpRtcpRtxNackTest, RtxNack) {
RunRtxTest(kRtxRetransmitted, 10);
EXPECT_EQ(kTestSequenceNumber, *(media_stream_.sequence_numbers_.begin()));
EXPECT_EQ(kTestSequenceNumber + kTestNumberOfPackets - 1,
*(media_stream_.sequence_numbers_.rbegin()));
EXPECT_EQ(kTestNumberOfPackets, media_stream_.sequence_numbers_.size());
EXPECT_EQ(kTestNumberOfRtxPackets, transport_.count_rtx_ssrc_);
EXPECT_TRUE(ExpectedPacketsReceived());
}
} // namespace webrtc