blob: d19e5752028803c7a05b9d5ceae985ea368fddd1 [file] [log] [blame]
/*
* Copyright (c) 2016 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 <algorithm>
#include <memory>
#include "modules/rtp_rtcp/include/flexfec_receiver.h"
#include "modules/rtp_rtcp/mocks/mock_recovered_packet_receiver.h"
#include "modules/rtp_rtcp/source/fec_test_helper.h"
#include "modules/rtp_rtcp/source/forward_error_correction.h"
#include "modules/rtp_rtcp/source/rtp_packet_received.h"
#include "test/gmock.h"
#include "test/gtest.h"
namespace webrtc {
namespace {
using ::testing::_;
using ::testing::Args;
using ::testing::ElementsAreArray;
using ::testing::Return;
using test::fec::FlexfecPacketGenerator;
using Packet = ForwardErrorCorrection::Packet;
using PacketList = ForwardErrorCorrection::PacketList;
constexpr size_t kPayloadLength = 500;
constexpr uint32_t kFlexfecSsrc = 42984;
constexpr uint32_t kMediaSsrc = 8353;
RtpPacketReceived ParsePacket(const Packet& packet) {
RtpPacketReceived parsed_packet;
EXPECT_TRUE(parsed_packet.Parse(packet.data, packet.length));
return parsed_packet;
}
} // namespace
class FlexfecReceiverForTest : public FlexfecReceiver {
public:
FlexfecReceiverForTest(uint32_t ssrc,
uint32_t protected_media_ssrc,
RecoveredPacketReceiver* recovered_packet_receiver)
: FlexfecReceiver(Clock::GetRealTimeClock(),
ssrc,
protected_media_ssrc,
recovered_packet_receiver) {}
// Expose methods for tests.
using FlexfecReceiver::AddReceivedPacket;
using FlexfecReceiver::ProcessReceivedPacket;
};
class FlexfecReceiverTest : public ::testing::Test {
protected:
FlexfecReceiverTest()
: receiver_(kFlexfecSsrc, kMediaSsrc, &recovered_packet_receiver_),
erasure_code_(
ForwardErrorCorrection::CreateFlexfec(kFlexfecSsrc, kMediaSsrc)),
packet_generator_(kMediaSsrc, kFlexfecSsrc) {}
// Generates |num_media_packets| corresponding to a single frame.
void PacketizeFrame(size_t num_media_packets,
size_t frame_offset,
PacketList* media_packets);
// Generates |num_fec_packets| FEC packets, given |media_packets|.
std::list<Packet*> EncodeFec(const PacketList& media_packets,
size_t num_fec_packets);
FlexfecReceiverForTest receiver_;
std::unique_ptr<ForwardErrorCorrection> erasure_code_;
FlexfecPacketGenerator packet_generator_;
testing::StrictMock<MockRecoveredPacketReceiver> recovered_packet_receiver_;
};
void FlexfecReceiverTest::PacketizeFrame(size_t num_media_packets,
size_t frame_offset,
PacketList* media_packets) {
packet_generator_.NewFrame(num_media_packets);
for (size_t i = 0; i < num_media_packets; ++i) {
std::unique_ptr<Packet> next_packet(
packet_generator_.NextPacket(frame_offset + i, kPayloadLength));
media_packets->push_back(std::move(next_packet));
}
}
std::list<Packet*> FlexfecReceiverTest::EncodeFec(
const PacketList& media_packets,
size_t num_fec_packets) {
const uint8_t protection_factor =
num_fec_packets * 255 / media_packets.size();
constexpr int kNumImportantPackets = 0;
constexpr bool kUseUnequalProtection = false;
constexpr FecMaskType kFecMaskType = kFecMaskRandom;
std::list<Packet*> fec_packets;
EXPECT_EQ(0, erasure_code_->EncodeFec(
media_packets, protection_factor, kNumImportantPackets,
kUseUnequalProtection, kFecMaskType, &fec_packets));
EXPECT_EQ(num_fec_packets, fec_packets.size());
return fec_packets;
}
TEST_F(FlexfecReceiverTest, ReceivesMediaPacket) {
packet_generator_.NewFrame(1);
std::unique_ptr<Packet> media_packet(
packet_generator_.NextPacket(0, kPayloadLength));
std::unique_ptr<ForwardErrorCorrection::ReceivedPacket> received_packet =
receiver_.AddReceivedPacket(ParsePacket(*media_packet));
ASSERT_TRUE(received_packet);
receiver_.ProcessReceivedPacket(*received_packet);
}
TEST_F(FlexfecReceiverTest, ReceivesMediaAndFecPackets) {
const size_t kNumMediaPackets = 1;
const size_t kNumFecPackets = 1;
PacketList media_packets;
PacketizeFrame(kNumMediaPackets, 0, &media_packets);
std::list<Packet*> fec_packets = EncodeFec(media_packets, kNumFecPackets);
const auto& media_packet = media_packets.front();
auto fec_packet = packet_generator_.BuildFlexfecPacket(*fec_packets.front());
std::unique_ptr<ForwardErrorCorrection::ReceivedPacket> received_packet =
receiver_.AddReceivedPacket(ParsePacket(*media_packet));
ASSERT_TRUE(received_packet);
receiver_.ProcessReceivedPacket(*received_packet);
received_packet = receiver_.AddReceivedPacket(ParsePacket(*fec_packet));
ASSERT_TRUE(received_packet);
receiver_.ProcessReceivedPacket(*received_packet);
}
TEST_F(FlexfecReceiverTest, FailsOnTruncatedFecPacket) {
const size_t kNumMediaPackets = 1;
const size_t kNumFecPackets = 1;
PacketList media_packets;
PacketizeFrame(kNumMediaPackets, 0, &media_packets);
std::list<Packet*> fec_packets = EncodeFec(media_packets, kNumFecPackets);
const auto& media_packet = media_packets.front();
// Simulate truncated FlexFEC payload.
fec_packets.front()->length = 1;
auto fec_packet = packet_generator_.BuildFlexfecPacket(*fec_packets.front());
std::unique_ptr<ForwardErrorCorrection::ReceivedPacket> received_packet =
receiver_.AddReceivedPacket(ParsePacket(*media_packet));
ASSERT_TRUE(received_packet);
receiver_.ProcessReceivedPacket(*received_packet);
EXPECT_FALSE(receiver_.AddReceivedPacket(ParsePacket(*fec_packet)));
}
TEST_F(FlexfecReceiverTest, FailsOnUnknownMediaSsrc) {
const size_t kNumMediaPackets = 1;
PacketList media_packets;
PacketizeFrame(kNumMediaPackets, 0, &media_packets);
auto& media_packet = media_packets.front();
// Corrupt the SSRC.
media_packet->data[8] = 0;
media_packet->data[9] = 1;
media_packet->data[10] = 2;
media_packet->data[11] = 3;
EXPECT_FALSE(receiver_.AddReceivedPacket(ParsePacket(*media_packet)));
}
TEST_F(FlexfecReceiverTest, FailsOnUnknownFecSsrc) {
const size_t kNumMediaPackets = 1;
const size_t kNumFecPackets = 1;
PacketList media_packets;
PacketizeFrame(kNumMediaPackets, 0, &media_packets);
std::list<Packet*> fec_packets = EncodeFec(media_packets, kNumFecPackets);
const auto& media_packet = media_packets.front();
auto fec_packet = packet_generator_.BuildFlexfecPacket(*fec_packets.front());
// Corrupt the SSRC.
fec_packet->data[8] = 4;
fec_packet->data[9] = 5;
fec_packet->data[10] = 6;
fec_packet->data[11] = 7;
std::unique_ptr<ForwardErrorCorrection::ReceivedPacket> received_packet =
receiver_.AddReceivedPacket(ParsePacket(*media_packet));
ASSERT_TRUE(received_packet);
receiver_.ProcessReceivedPacket(*received_packet);
EXPECT_FALSE(receiver_.AddReceivedPacket(ParsePacket(*fec_packet)));
}
TEST_F(FlexfecReceiverTest, ReceivesMultiplePackets) {
const size_t kNumMediaPackets = 2;
const size_t kNumFecPackets = 1;
PacketList media_packets;
PacketizeFrame(kNumMediaPackets, 0, &media_packets);
std::list<Packet*> fec_packets = EncodeFec(media_packets, kNumFecPackets);
// Receive all media packets.
for (const auto& media_packet : media_packets) {
std::unique_ptr<ForwardErrorCorrection::ReceivedPacket> received_packet =
receiver_.AddReceivedPacket(ParsePacket(*media_packet));
ASSERT_TRUE(received_packet);
receiver_.ProcessReceivedPacket(*received_packet);
}
// Receive FEC packet.
auto* fec_packet = fec_packets.front();
std::unique_ptr<Packet> packet_with_rtp_header =
packet_generator_.BuildFlexfecPacket(*fec_packet);
std::unique_ptr<ForwardErrorCorrection::ReceivedPacket> received_packet =
receiver_.AddReceivedPacket(ParsePacket(*packet_with_rtp_header));
ASSERT_TRUE(received_packet);
receiver_.ProcessReceivedPacket(*received_packet);
}
TEST_F(FlexfecReceiverTest, RecoversFromSingleMediaLoss) {
const size_t kNumMediaPackets = 2;
const size_t kNumFecPackets = 1;
PacketList media_packets;
PacketizeFrame(kNumMediaPackets, 0, &media_packets);
std::list<Packet*> fec_packets = EncodeFec(media_packets, kNumFecPackets);
// Receive first media packet but drop second.
auto media_it = media_packets.begin();
receiver_.OnRtpPacket(ParsePacket(**media_it));
// Receive FEC packet and ensure recovery of lost media packet.
auto fec_it = fec_packets.begin();
std::unique_ptr<Packet> packet_with_rtp_header =
packet_generator_.BuildFlexfecPacket(**fec_it);
media_it++;
EXPECT_CALL(recovered_packet_receiver_,
OnRecoveredPacket(_, (*media_it)->length))
.With(
Args<0, 1>(ElementsAreArray((*media_it)->data, (*media_it)->length)));
receiver_.OnRtpPacket(ParsePacket(*packet_with_rtp_header));
}
TEST_F(FlexfecReceiverTest, RecoversFromDoubleMediaLoss) {
const size_t kNumMediaPackets = 2;
const size_t kNumFecPackets = 2;
PacketList media_packets;
PacketizeFrame(kNumMediaPackets, 0, &media_packets);
std::list<Packet*> fec_packets = EncodeFec(media_packets, kNumFecPackets);
// Drop both media packets.
// Receive first FEC packet and recover first lost media packet.
auto fec_it = fec_packets.begin();
std::unique_ptr<Packet> packet_with_rtp_header =
packet_generator_.BuildFlexfecPacket(**fec_it);
auto media_it = media_packets.begin();
EXPECT_CALL(recovered_packet_receiver_,
OnRecoveredPacket(_, (*media_it)->length))
.With(
Args<0, 1>(ElementsAreArray((*media_it)->data, (*media_it)->length)));
receiver_.OnRtpPacket(ParsePacket(*packet_with_rtp_header));
// Receive second FEC packet and recover second lost media packet.
fec_it++;
packet_with_rtp_header = packet_generator_.BuildFlexfecPacket(**fec_it);
media_it++;
EXPECT_CALL(recovered_packet_receiver_,
OnRecoveredPacket(_, (*media_it)->length))
.With(
Args<0, 1>(ElementsAreArray((*media_it)->data, (*media_it)->length)));
receiver_.OnRtpPacket(ParsePacket(*packet_with_rtp_header));
}
TEST_F(FlexfecReceiverTest, DoesNotRecoverFromMediaAndFecLoss) {
const size_t kNumMediaPackets = 2;
const size_t kNumFecPackets = 1;
PacketList media_packets;
PacketizeFrame(kNumMediaPackets, 0, &media_packets);
std::list<Packet*> fec_packets = EncodeFec(media_packets, kNumFecPackets);
// Receive first media packet.
auto media_it = media_packets.begin();
receiver_.OnRtpPacket(ParsePacket(**media_it));
// Drop second media packet and FEC packet. Do not expect call back.
}
TEST_F(FlexfecReceiverTest, DoesNotCallbackTwice) {
const size_t kNumMediaPackets = 2;
const size_t kNumFecPackets = 1;
PacketList media_packets;
PacketizeFrame(kNumMediaPackets, 0, &media_packets);
std::list<Packet*> fec_packets = EncodeFec(media_packets, kNumFecPackets);
// Receive first media packet but drop second.
auto media_it = media_packets.begin();
receiver_.OnRtpPacket(ParsePacket(**media_it));
// Receive FEC packet and ensure recovery of lost media packet.
auto fec_it = fec_packets.begin();
std::unique_ptr<Packet> packet_with_rtp_header =
packet_generator_.BuildFlexfecPacket(**fec_it);
media_it++;
EXPECT_CALL(recovered_packet_receiver_,
OnRecoveredPacket(_, (*media_it)->length))
.With(
Args<0, 1>(ElementsAreArray((*media_it)->data, (*media_it)->length)));
receiver_.OnRtpPacket(ParsePacket(*packet_with_rtp_header));
// Receive the FEC packet again, but do not call back.
receiver_.OnRtpPacket(ParsePacket(*packet_with_rtp_header));
// Receive the first media packet again, but do not call back.
media_it = media_packets.begin();
receiver_.OnRtpPacket(ParsePacket(**media_it));
// Receive the second media packet again (the one recovered above),
// but do not call back again.
media_it++;
receiver_.OnRtpPacket(ParsePacket(**media_it));
}
// Here we are implicitly assuming packet masks that are suitable for
// this type of 50% correlated loss. If we are changing our precomputed
// packet masks, this test might need to be updated.
TEST_F(FlexfecReceiverTest, RecoversFrom50PercentLoss) {
const size_t kNumFecPackets = 5;
const size_t kNumFrames = 2 * kNumFecPackets;
const size_t kNumMediaPacketsPerFrame = 1;
PacketList media_packets;
for (size_t i = 0; i < kNumFrames; ++i) {
PacketizeFrame(kNumMediaPacketsPerFrame, i, &media_packets);
}
std::list<Packet*> fec_packets = EncodeFec(media_packets, kNumFecPackets);
// Drop every second media packet.
auto media_it = media_packets.begin();
while (media_it != media_packets.end()) {
receiver_.OnRtpPacket(ParsePacket(**media_it));
++media_it;
if (media_it == media_packets.end()) {
break;
}
++media_it;
}
// Receive all FEC packets.
media_it = media_packets.begin();
for (const auto* fec_packet : fec_packets) {
std::unique_ptr<Packet> fec_packet_with_rtp_header =
packet_generator_.BuildFlexfecPacket(*fec_packet);
++media_it;
if (media_it == media_packets.end()) {
break;
}
EXPECT_CALL(recovered_packet_receiver_,
OnRecoveredPacket(_, (*media_it)->length))
.With(Args<0, 1>(
ElementsAreArray((*media_it)->data, (*media_it)->length)));
receiver_.OnRtpPacket(ParsePacket(*fec_packet_with_rtp_header));
++media_it;
}
}
TEST_F(FlexfecReceiverTest, DelayedFecPacketDoesHelp) {
// These values need to be updated if the underlying erasure code
// implementation changes.
const size_t kNumFrames = 48;
const size_t kNumMediaPacketsPerFrame = 1;
const size_t kNumFecPackets = 1;
PacketList media_packets;
PacketizeFrame(kNumMediaPacketsPerFrame, 0, &media_packets);
PacketizeFrame(kNumMediaPacketsPerFrame, 1, &media_packets);
// Protect two first frames.
std::list<Packet*> fec_packets = EncodeFec(media_packets, kNumFecPackets);
for (size_t i = 2; i < kNumFrames; ++i) {
PacketizeFrame(kNumMediaPacketsPerFrame, i, &media_packets);
}
// Drop first media packet and delay FEC packet.
auto media_it = media_packets.begin();
++media_it;
// Receive all other media packets.
while (media_it != media_packets.end()) {
receiver_.OnRtpPacket(ParsePacket(**media_it));
++media_it;
}
// Receive FEC packet and recover first media packet.
auto fec_it = fec_packets.begin();
std::unique_ptr<Packet> packet_with_rtp_header =
packet_generator_.BuildFlexfecPacket(**fec_it);
media_it = media_packets.begin();
EXPECT_CALL(recovered_packet_receiver_,
OnRecoveredPacket(_, (*media_it)->length))
.With(
Args<0, 1>(ElementsAreArray((*media_it)->data, (*media_it)->length)));
receiver_.OnRtpPacket(ParsePacket(*packet_with_rtp_header));
}
TEST_F(FlexfecReceiverTest, TooDelayedFecPacketDoesNotHelp) {
// These values need to be updated if the underlying erasure code
// implementation changes.
const size_t kNumFrames = 49;
const size_t kNumMediaPacketsPerFrame = 1;
const size_t kNumFecPackets = 1;
PacketList media_packets;
PacketizeFrame(kNumMediaPacketsPerFrame, 0, &media_packets);
PacketizeFrame(kNumMediaPacketsPerFrame, 1, &media_packets);
// Protect two first frames.
std::list<Packet*> fec_packets = EncodeFec(media_packets, kNumFecPackets);
for (size_t i = 2; i < kNumFrames; ++i) {
PacketizeFrame(kNumMediaPacketsPerFrame, i, &media_packets);
}
// Drop first media packet and delay FEC packet.
auto media_it = media_packets.begin();
++media_it;
// Receive all other media packets.
while (media_it != media_packets.end()) {
receiver_.OnRtpPacket(ParsePacket(**media_it));
++media_it;
}
// Receive FEC packet.
auto fec_it = fec_packets.begin();
std::unique_ptr<Packet> packet_with_rtp_header =
packet_generator_.BuildFlexfecPacket(**fec_it);
receiver_.OnRtpPacket(ParsePacket(*packet_with_rtp_header));
// Do not expect a call back.
}
TEST_F(FlexfecReceiverTest, SurvivesOldRecoveredPacketBeingReinserted) {
// Simulates the behaviour of the
// Call->FlexfecReceiveStream->FlexfecReceiver->Call loop in production code.
class LoopbackRecoveredPacketReceiver : public RecoveredPacketReceiver {
public:
LoopbackRecoveredPacketReceiver() : receiver_(nullptr) {}
void SetReceiver(FlexfecReceiver* receiver) { receiver_ = receiver; }
// Implements RecoveredPacketReceiver.
void OnRecoveredPacket(const uint8_t* packet, size_t length) override {
RtpPacketReceived parsed_packet;
EXPECT_TRUE(parsed_packet.Parse(packet, length));
parsed_packet.set_recovered(true);
RTC_DCHECK(receiver_);
receiver_->OnRtpPacket(parsed_packet);
}
private:
FlexfecReceiver* receiver_;
} loopback_recovered_packet_receiver;
// Feed recovered packets back into |receiver|.
FlexfecReceiver receiver(Clock::GetRealTimeClock(), kFlexfecSsrc, kMediaSsrc,
&loopback_recovered_packet_receiver);
loopback_recovered_packet_receiver.SetReceiver(&receiver);
// Receive first set of packets.
PacketList first_media_packets;
for (int i = 0; i < 46; ++i) {
PacketizeFrame(1, 0, &first_media_packets);
}
for (const auto& media_packet : first_media_packets) {
receiver.OnRtpPacket(ParsePacket(*media_packet));
}
// Protect one media packet. Lose the media packet,
// but do not receive FEC packet yet.
PacketList protected_media_packet;
PacketizeFrame(1, 0, &protected_media_packet);
const std::list<Packet*> fec_packets = EncodeFec(protected_media_packet, 1);
EXPECT_EQ(1u, fec_packets.size());
std::unique_ptr<Packet> fec_packet_with_rtp_header =
packet_generator_.BuildFlexfecPacket(*fec_packets.front());
// Lose some packets, thus introducing a sequence number gap.
PacketList lost_packets;
for (int i = 0; i < 100; ++i) {
PacketizeFrame(1, 0, &lost_packets);
}
// Receive one more packet.
PacketList second_media_packets;
PacketizeFrame(1, 0, &second_media_packets);
for (const auto& media_packet : second_media_packets) {
receiver.OnRtpPacket(ParsePacket(*media_packet));
}
// Receive delayed FEC packet.
receiver.OnRtpPacket(ParsePacket(*fec_packet_with_rtp_header));
// Expect no crash.
}
TEST_F(FlexfecReceiverTest, RecoversWithMediaPacketsOutOfOrder) {
const size_t kNumMediaPackets = 6;
const size_t kNumFecPackets = 2;
PacketList media_packets;
PacketizeFrame(kNumMediaPackets, 0, &media_packets);
std::list<Packet*> fec_packets = EncodeFec(media_packets, kNumFecPackets);
// Lose two media packets, and receive the others out of order.
auto media_it = media_packets.begin();
auto media_packet0 = media_it++;
auto media_packet1 = media_it++;
auto media_packet2 = media_it++;
auto media_packet3 = media_it++;
auto media_packet4 = media_it++;
auto media_packet5 = media_it++;
receiver_.OnRtpPacket(ParsePacket(**media_packet5));
receiver_.OnRtpPacket(ParsePacket(**media_packet2));
receiver_.OnRtpPacket(ParsePacket(**media_packet3));
receiver_.OnRtpPacket(ParsePacket(**media_packet0));
// Expect to recover lost media packets.
EXPECT_CALL(recovered_packet_receiver_,
OnRecoveredPacket(_, (*media_packet1)->length))
.With(Args<0, 1>(
ElementsAreArray((*media_packet1)->data, (*media_packet1)->length)));
EXPECT_CALL(recovered_packet_receiver_,
OnRecoveredPacket(_, (*media_packet4)->length))
.With(Args<0, 1>(
ElementsAreArray((*media_packet4)->data, (*media_packet4)->length)));
// Add FEC packets.
auto fec_it = fec_packets.begin();
std::unique_ptr<Packet> packet_with_rtp_header;
while (fec_it != fec_packets.end()) {
packet_with_rtp_header = packet_generator_.BuildFlexfecPacket(**fec_it);
receiver_.OnRtpPacket(ParsePacket(*packet_with_rtp_header));
++fec_it;
}
}
// Recovered media packets may be fed back into the FlexfecReceiver by the
// callback. This test ensures the idempotency of such a situation.
TEST_F(FlexfecReceiverTest, RecoveryCallbackDoesNotLoopInfinitely) {
class LoopbackRecoveredPacketReceiver : public RecoveredPacketReceiver {
public:
const int kMaxRecursionDepth = 10;
LoopbackRecoveredPacketReceiver()
: receiver_(nullptr),
did_receive_call_back_(false),
recursion_depth_(0),
deep_recursion_(false) {}
void SetReceiver(FlexfecReceiver* receiver) { receiver_ = receiver; }
bool DidReceiveCallback() const { return did_receive_call_back_; }
bool DeepRecursion() const { return deep_recursion_; }
// Implements RecoveredPacketReceiver.
void OnRecoveredPacket(const uint8_t* packet, size_t length) override {
RtpPacketReceived parsed_packet;
EXPECT_TRUE(parsed_packet.Parse(packet, length));
did_receive_call_back_ = true;
if (recursion_depth_ > kMaxRecursionDepth) {
deep_recursion_ = true;
return;
}
++recursion_depth_;
RTC_DCHECK(receiver_);
receiver_->OnRtpPacket(parsed_packet);
--recursion_depth_;
}
private:
FlexfecReceiver* receiver_;
bool did_receive_call_back_;
int recursion_depth_;
bool deep_recursion_;
} loopback_recovered_packet_receiver;
// Feed recovered packets back into |receiver|.
FlexfecReceiver receiver(Clock::GetRealTimeClock(), kFlexfecSsrc, kMediaSsrc,
&loopback_recovered_packet_receiver);
loopback_recovered_packet_receiver.SetReceiver(&receiver);
const size_t kNumMediaPackets = 2;
const size_t kNumFecPackets = 1;
PacketList media_packets;
PacketizeFrame(kNumMediaPackets, 0, &media_packets);
std::list<Packet*> fec_packets = EncodeFec(media_packets, kNumFecPackets);
// Receive first media packet but drop second.
auto media_it = media_packets.begin();
receiver.OnRtpPacket(ParsePacket(**media_it));
// Receive FEC packet and verify that a packet was recovered.
auto fec_it = fec_packets.begin();
std::unique_ptr<Packet> packet_with_rtp_header =
packet_generator_.BuildFlexfecPacket(**fec_it);
receiver.OnRtpPacket(ParsePacket(*packet_with_rtp_header));
EXPECT_TRUE(loopback_recovered_packet_receiver.DidReceiveCallback());
EXPECT_FALSE(loopback_recovered_packet_receiver.DeepRecursion());
}
TEST_F(FlexfecReceiverTest, CalculatesNumberOfPackets) {
const size_t kNumMediaPackets = 2;
const size_t kNumFecPackets = 1;
PacketList media_packets;
PacketizeFrame(kNumMediaPackets, 0, &media_packets);
std::list<Packet*> fec_packets = EncodeFec(media_packets, kNumFecPackets);
// Receive first media packet but drop second.
auto media_it = media_packets.begin();
receiver_.OnRtpPacket(ParsePacket(**media_it));
// Receive FEC packet and ensure recovery of lost media packet.
auto fec_it = fec_packets.begin();
std::unique_ptr<Packet> packet_with_rtp_header =
packet_generator_.BuildFlexfecPacket(**fec_it);
media_it++;
EXPECT_CALL(recovered_packet_receiver_,
OnRecoveredPacket(_, (*media_it)->length))
.With(
Args<0, 1>(ElementsAreArray((*media_it)->data, (*media_it)->length)));
receiver_.OnRtpPacket(ParsePacket(*packet_with_rtp_header));
// Check stats calculations.
FecPacketCounter packet_counter = receiver_.GetPacketCounter();
EXPECT_EQ(2U, packet_counter.num_packets);
EXPECT_EQ(1U, packet_counter.num_fec_packets);
EXPECT_EQ(1U, packet_counter.num_recovered_packets);
}
} // namespace webrtc