blob: 3f99b038f6ef82bf0794cee6607a98bbc01649db [file] [log] [blame]
/*
* Copyright (c) 2015 The WebRTC project authors. All Rights Reserved.
*
* Use of this source code is governed by a BSD-style license
* that can be found in the LICENSE file in the root of the source
* tree. An additional intellectual property rights grant can be found
* in the file PATENTS. All contributing project authors may
* be found in the AUTHORS file in the root of the source tree.
*/
#include "modules/rtp_rtcp/source/rtcp_packet/transport_feedback.h"
#include <limits>
#include <memory>
#include <utility>
#include "modules/rtp_rtcp/source/byte_io.h"
#include "modules/rtp_rtcp/source/rtcp_packet/common_header.h"
#include "test/gmock.h"
#include "test/gtest.h"
namespace webrtc {
namespace {
using rtcp::TransportFeedback;
using ::testing::ElementsAreArray;
static const int kHeaderSize = 20;
static const int kStatusChunkSize = 2;
static const int kSmallDeltaSize = 1;
static const int kLargeDeltaSize = 2;
static const int64_t kDeltaLimit = 0xFF * TransportFeedback::kDeltaScaleFactor;
class FeedbackTester {
public:
FeedbackTester() : FeedbackTester(true) {}
explicit FeedbackTester(bool include_timestamps)
: expected_size_(kAnySize),
default_delta_(TransportFeedback::kDeltaScaleFactor * 4),
include_timestamps_(include_timestamps) {}
void WithExpectedSize(size_t expected_size) {
expected_size_ = expected_size;
}
void WithDefaultDelta(int64_t delta) { default_delta_ = delta; }
void WithInput(const uint16_t received_seq[],
const int64_t received_ts[],
uint16_t length) {
std::unique_ptr<int64_t[]> temp_timestamps;
if (received_ts == nullptr) {
temp_timestamps.reset(new int64_t[length]);
GenerateReceiveTimestamps(received_seq, length, temp_timestamps.get());
received_ts = temp_timestamps.get();
}
expected_seq_.clear();
expected_deltas_.clear();
feedback_.reset(new TransportFeedback(include_timestamps_));
feedback_->SetBase(received_seq[0], received_ts[0]);
ASSERT_TRUE(feedback_->IsConsistent());
int64_t last_time = feedback_->GetBaseTimeUs();
for (int i = 0; i < length; ++i) {
int64_t time = received_ts[i];
EXPECT_TRUE(feedback_->AddReceivedPacket(received_seq[i], time));
if (last_time != -1) {
int64_t delta = time - last_time;
expected_deltas_.push_back(delta);
}
last_time = time;
}
ASSERT_TRUE(feedback_->IsConsistent());
expected_seq_.insert(expected_seq_.begin(), &received_seq[0],
&received_seq[length]);
}
void VerifyPacket() {
ASSERT_TRUE(feedback_->IsConsistent());
serialized_ = feedback_->Build();
VerifyInternal();
feedback_ =
TransportFeedback::ParseFrom(serialized_.data(), serialized_.size());
ASSERT_NE(nullptr, feedback_);
ASSERT_TRUE(feedback_->IsConsistent());
EXPECT_EQ(include_timestamps_, feedback_->IncludeTimestamps());
VerifyInternal();
}
static const size_t kAnySize = static_cast<size_t>(0) - 1;
private:
void VerifyInternal() {
if (expected_size_ != kAnySize) {
// Round up to whole 32-bit words.
size_t expected_size_words = (expected_size_ + 3) / 4;
size_t expected_size_bytes = expected_size_words * 4;
EXPECT_EQ(expected_size_bytes, serialized_.size());
}
std::vector<uint16_t> actual_seq_nos;
std::vector<int64_t> actual_deltas_us;
for (const auto& packet : feedback_->GetReceivedPackets()) {
actual_seq_nos.push_back(packet.sequence_number());
actual_deltas_us.push_back(packet.delta_us());
}
EXPECT_THAT(actual_seq_nos, ElementsAreArray(expected_seq_));
if (include_timestamps_) {
EXPECT_THAT(actual_deltas_us, ElementsAreArray(expected_deltas_));
}
}
void GenerateReceiveTimestamps(const uint16_t seq[],
const size_t length,
int64_t* timestamps) {
uint16_t last_seq = seq[0];
int64_t offset = 0;
for (size_t i = 0; i < length; ++i) {
if (seq[i] < last_seq)
offset += 0x10000 * default_delta_;
last_seq = seq[i];
timestamps[i] = offset + (last_seq * default_delta_);
}
}
std::vector<uint16_t> expected_seq_;
std::vector<int64_t> expected_deltas_;
size_t expected_size_;
int64_t default_delta_;
std::unique_ptr<TransportFeedback> feedback_;
rtc::Buffer serialized_;
bool include_timestamps_;
};
// The following tests use FeedbackTester that simulates received packets as
// specified by the parameters |received_seq[]| and |received_ts[]| (optional).
// The following is verified in these tests:
// - Expected size of serialized packet.
// - Expected sequence numbers and receive deltas.
// - Sequence numbers and receive deltas are persistent after serialization
// followed by parsing.
// - The internal state of a feedback packet is consistent.
TEST(RtcpPacketTest, TransportFeedbackOneBitVector) {
const uint16_t kReceived[] = {1, 2, 7, 8, 9, 10, 13};
const size_t kLength = sizeof(kReceived) / sizeof(uint16_t);
const size_t kExpectedSizeBytes =
kHeaderSize + kStatusChunkSize + (kLength * kSmallDeltaSize);
FeedbackTester test;
test.WithExpectedSize(kExpectedSizeBytes);
test.WithInput(kReceived, nullptr, kLength);
test.VerifyPacket();
}
TEST(RtcpPacketTest, TransportFeedbackOneBitVectorNoRecvDelta) {
const uint16_t kReceived[] = {1, 2, 7, 8, 9, 10, 13};
const size_t kLength = sizeof(kReceived) / sizeof(uint16_t);
const size_t kExpectedSizeBytes = kHeaderSize + kStatusChunkSize;
FeedbackTester test(/*include_timestamps=*/false);
test.WithExpectedSize(kExpectedSizeBytes);
test.WithInput(kReceived, nullptr, kLength);
test.VerifyPacket();
}
TEST(RtcpPacketTest, TransportFeedbackFullOneBitVector) {
const uint16_t kReceived[] = {1, 2, 7, 8, 9, 10, 13, 14};
const size_t kLength = sizeof(kReceived) / sizeof(uint16_t);
const size_t kExpectedSizeBytes =
kHeaderSize + kStatusChunkSize + (kLength * kSmallDeltaSize);
FeedbackTester test;
test.WithExpectedSize(kExpectedSizeBytes);
test.WithInput(kReceived, nullptr, kLength);
test.VerifyPacket();
}
TEST(RtcpPacketTest, TransportFeedbackOneBitVectorWrapReceived) {
const uint16_t kMax = 0xFFFF;
const uint16_t kReceived[] = {kMax - 2, kMax - 1, kMax, 0, 1, 2};
const size_t kLength = sizeof(kReceived) / sizeof(uint16_t);
const size_t kExpectedSizeBytes =
kHeaderSize + kStatusChunkSize + (kLength * kSmallDeltaSize);
FeedbackTester test;
test.WithExpectedSize(kExpectedSizeBytes);
test.WithInput(kReceived, nullptr, kLength);
test.VerifyPacket();
}
TEST(RtcpPacketTest, TransportFeedbackOneBitVectorWrapMissing) {
const uint16_t kMax = 0xFFFF;
const uint16_t kReceived[] = {kMax - 2, kMax - 1, 1, 2};
const size_t kLength = sizeof(kReceived) / sizeof(uint16_t);
const size_t kExpectedSizeBytes =
kHeaderSize + kStatusChunkSize + (kLength * kSmallDeltaSize);
FeedbackTester test;
test.WithExpectedSize(kExpectedSizeBytes);
test.WithInput(kReceived, nullptr, kLength);
test.VerifyPacket();
}
TEST(RtcpPacketTest, TransportFeedbackTwoBitVector) {
const uint16_t kReceived[] = {1, 2, 6, 7};
const size_t kLength = sizeof(kReceived) / sizeof(uint16_t);
const size_t kExpectedSizeBytes =
kHeaderSize + kStatusChunkSize + (kLength * kLargeDeltaSize);
FeedbackTester test;
test.WithExpectedSize(kExpectedSizeBytes);
test.WithDefaultDelta(kDeltaLimit + TransportFeedback::kDeltaScaleFactor);
test.WithInput(kReceived, nullptr, kLength);
test.VerifyPacket();
}
TEST(RtcpPacketTest, TransportFeedbackTwoBitVectorFull) {
const uint16_t kReceived[] = {1, 2, 6, 7, 8};
const size_t kLength = sizeof(kReceived) / sizeof(uint16_t);
const size_t kExpectedSizeBytes =
kHeaderSize + (2 * kStatusChunkSize) + (kLength * kLargeDeltaSize);
FeedbackTester test;
test.WithExpectedSize(kExpectedSizeBytes);
test.WithDefaultDelta(kDeltaLimit + TransportFeedback::kDeltaScaleFactor);
test.WithInput(kReceived, nullptr, kLength);
test.VerifyPacket();
}
TEST(RtcpPacketTest, TransportFeedbackLargeAndNegativeDeltas) {
const uint16_t kReceived[] = {1, 2, 6, 7, 8};
const int64_t kReceiveTimes[] = {
2000, 1000, 4000, 3000,
3000 + TransportFeedback::kDeltaScaleFactor * (1 << 8)};
const size_t kLength = sizeof(kReceived) / sizeof(uint16_t);
const size_t kExpectedSizeBytes =
kHeaderSize + kStatusChunkSize + (3 * kLargeDeltaSize) + kSmallDeltaSize;
FeedbackTester test;
test.WithExpectedSize(kExpectedSizeBytes);
test.WithInput(kReceived, kReceiveTimes, kLength);
test.VerifyPacket();
}
TEST(RtcpPacketTest, TransportFeedbackMaxRle) {
// Expected chunks created:
// * 1-bit vector chunk (1xreceived + 13xdropped)
// * RLE chunk of max length for dropped symbol
// * 1-bit vector chunk (1xreceived + 13xdropped)
const size_t kPacketCount = (1 << 13) - 1 + 14;
const uint16_t kReceived[] = {0, kPacketCount};
const int64_t kReceiveTimes[] = {1000, 2000};
const size_t kLength = sizeof(kReceived) / sizeof(uint16_t);
const size_t kExpectedSizeBytes =
kHeaderSize + (3 * kStatusChunkSize) + (kLength * kSmallDeltaSize);
FeedbackTester test;
test.WithExpectedSize(kExpectedSizeBytes);
test.WithInput(kReceived, kReceiveTimes, kLength);
test.VerifyPacket();
}
TEST(RtcpPacketTest, TransportFeedbackMinRle) {
// Expected chunks created:
// * 1-bit vector chunk (1xreceived + 13xdropped)
// * RLE chunk of length 15 for dropped symbol
// * 1-bit vector chunk (1xreceived + 13xdropped)
const uint16_t kReceived[] = {0, (14 * 2) + 1};
const int64_t kReceiveTimes[] = {1000, 2000};
const size_t kLength = sizeof(kReceived) / sizeof(uint16_t);
const size_t kExpectedSizeBytes =
kHeaderSize + (3 * kStatusChunkSize) + (kLength * kSmallDeltaSize);
FeedbackTester test;
test.WithExpectedSize(kExpectedSizeBytes);
test.WithInput(kReceived, kReceiveTimes, kLength);
test.VerifyPacket();
}
TEST(RtcpPacketTest, TransportFeedbackOneToTwoBitVector) {
const size_t kTwoBitVectorCapacity = 7;
const uint16_t kReceived[] = {0, kTwoBitVectorCapacity - 1};
const int64_t kReceiveTimes[] = {
0, kDeltaLimit + TransportFeedback::kDeltaScaleFactor};
const size_t kLength = sizeof(kReceived) / sizeof(uint16_t);
const size_t kExpectedSizeBytes =
kHeaderSize + kStatusChunkSize + kSmallDeltaSize + kLargeDeltaSize;
FeedbackTester test;
test.WithExpectedSize(kExpectedSizeBytes);
test.WithInput(kReceived, kReceiveTimes, kLength);
test.VerifyPacket();
}
TEST(RtcpPacketTest, TransportFeedbackOneToTwoBitVectorSimpleSplit) {
const size_t kTwoBitVectorCapacity = 7;
const uint16_t kReceived[] = {0, kTwoBitVectorCapacity};
const int64_t kReceiveTimes[] = {
0, kDeltaLimit + TransportFeedback::kDeltaScaleFactor};
const size_t kLength = sizeof(kReceived) / sizeof(uint16_t);
const size_t kExpectedSizeBytes =
kHeaderSize + (kStatusChunkSize * 2) + kSmallDeltaSize + kLargeDeltaSize;
FeedbackTester test;
test.WithExpectedSize(kExpectedSizeBytes);
test.WithInput(kReceived, kReceiveTimes, kLength);
test.VerifyPacket();
}
TEST(RtcpPacketTest, TransportFeedbackOneToTwoBitVectorSplit) {
// With received small delta = S, received large delta = L, use input
// SSSSSSSSLSSSSSSSSSSSS. This will cause a 1:2 split at the L.
// After split there will be two symbols in symbol_vec: SL.
const int64_t kLargeDelta = TransportFeedback::kDeltaScaleFactor * (1 << 8);
const size_t kNumPackets = (3 * 7) + 1;
const size_t kExpectedSizeBytes = kHeaderSize + (kStatusChunkSize * 3) +
(kSmallDeltaSize * (kNumPackets - 1)) +
(kLargeDeltaSize * 1);
uint16_t kReceived[kNumPackets];
for (size_t i = 0; i < kNumPackets; ++i)
kReceived[i] = i;
int64_t kReceiveTimes[kNumPackets];
kReceiveTimes[0] = 1000;
for (size_t i = 1; i < kNumPackets; ++i) {
int delta = (i == 8) ? kLargeDelta : 1000;
kReceiveTimes[i] = kReceiveTimes[i - 1] + delta;
}
FeedbackTester test;
test.WithExpectedSize(kExpectedSizeBytes);
test.WithInput(kReceived, kReceiveTimes, kNumPackets);
test.VerifyPacket();
}
TEST(RtcpPacketTest, TransportFeedbackAliasing) {
TransportFeedback feedback;
feedback.SetBase(0, 0);
const int kSamples = 100;
const int64_t kTooSmallDelta = TransportFeedback::kDeltaScaleFactor / 3;
for (int i = 0; i < kSamples; ++i)
feedback.AddReceivedPacket(i, i * kTooSmallDelta);
feedback.Build();
int64_t accumulated_delta = 0;
int num_samples = 0;
for (const auto& packet : feedback.GetReceivedPackets()) {
accumulated_delta += packet.delta_us();
int64_t expected_time = num_samples * kTooSmallDelta;
++num_samples;
EXPECT_NEAR(expected_time, accumulated_delta,
TransportFeedback::kDeltaScaleFactor / 2);
}
}
TEST(RtcpPacketTest, TransportFeedbackLimits) {
// Sequence number wrap above 0x8000.
std::unique_ptr<TransportFeedback> packet(new TransportFeedback());
packet->SetBase(0, 0);
EXPECT_TRUE(packet->AddReceivedPacket(0x0, 0));
EXPECT_TRUE(packet->AddReceivedPacket(0x8000, 1000));
packet.reset(new TransportFeedback());
packet->SetBase(0, 0);
EXPECT_TRUE(packet->AddReceivedPacket(0x0, 0));
EXPECT_FALSE(packet->AddReceivedPacket(0x8000 + 1, 1000));
// Packet status count max 0xFFFF.
packet.reset(new TransportFeedback());
packet->SetBase(0, 0);
EXPECT_TRUE(packet->AddReceivedPacket(0x0, 0));
EXPECT_TRUE(packet->AddReceivedPacket(0x8000, 1000));
EXPECT_TRUE(packet->AddReceivedPacket(0xFFFE, 2000));
EXPECT_FALSE(packet->AddReceivedPacket(0xFFFF, 3000));
// Too large delta.
packet.reset(new TransportFeedback());
packet->SetBase(0, 0);
int64_t kMaxPositiveTimeDelta = std::numeric_limits<int16_t>::max() *
TransportFeedback::kDeltaScaleFactor;
EXPECT_FALSE(packet->AddReceivedPacket(
1, kMaxPositiveTimeDelta + TransportFeedback::kDeltaScaleFactor));
EXPECT_TRUE(packet->AddReceivedPacket(1, kMaxPositiveTimeDelta));
// Too large negative delta.
packet.reset(new TransportFeedback());
packet->SetBase(0, 0);
int64_t kMaxNegativeTimeDelta = std::numeric_limits<int16_t>::min() *
TransportFeedback::kDeltaScaleFactor;
EXPECT_FALSE(packet->AddReceivedPacket(
1, kMaxNegativeTimeDelta - TransportFeedback::kDeltaScaleFactor));
EXPECT_TRUE(packet->AddReceivedPacket(1, kMaxNegativeTimeDelta));
// Base time at maximum value.
int64_t kMaxBaseTime =
static_cast<int64_t>(TransportFeedback::kDeltaScaleFactor) * (1L << 8) *
((1L << 23) - 1);
packet.reset(new TransportFeedback());
packet->SetBase(0, kMaxBaseTime);
EXPECT_TRUE(packet->AddReceivedPacket(0, kMaxBaseTime));
// Serialize and de-serialize (verify 24bit parsing).
rtc::Buffer raw_packet = packet->Build();
packet = TransportFeedback::ParseFrom(raw_packet.data(), raw_packet.size());
EXPECT_EQ(kMaxBaseTime, packet->GetBaseTimeUs());
// Base time above maximum value.
int64_t kTooLargeBaseTime =
kMaxBaseTime + (TransportFeedback::kDeltaScaleFactor * (1L << 8));
packet.reset(new TransportFeedback());
packet->SetBase(0, kTooLargeBaseTime);
packet->AddReceivedPacket(0, kTooLargeBaseTime);
raw_packet = packet->Build();
packet = TransportFeedback::ParseFrom(raw_packet.data(), raw_packet.size());
EXPECT_NE(kTooLargeBaseTime, packet->GetBaseTimeUs());
// TODO(sprang): Once we support max length lower than RTCP length limit,
// add back test for max size in bytes.
}
TEST(RtcpPacketTest, TransportFeedbackPadding) {
const size_t kExpectedSizeBytes =
kHeaderSize + kStatusChunkSize + kSmallDeltaSize;
const size_t kExpectedSizeWords = (kExpectedSizeBytes + 3) / 4;
const size_t kExpectedPaddingSizeBytes =
4 * kExpectedSizeWords - kExpectedSizeBytes;
TransportFeedback feedback;
feedback.SetBase(0, 0);
EXPECT_TRUE(feedback.AddReceivedPacket(0, 0));
rtc::Buffer packet = feedback.Build();
EXPECT_EQ(kExpectedSizeWords * 4, packet.size());
ASSERT_GT(kExpectedSizeWords * 4, kExpectedSizeBytes);
for (size_t i = kExpectedSizeBytes; i < (kExpectedSizeWords * 4 - 1); ++i)
EXPECT_EQ(0u, packet[i]);
EXPECT_EQ(kExpectedPaddingSizeBytes, packet[kExpectedSizeWords * 4 - 1]);
// Modify packet by adding 4 bytes of padding at the end. Not currently used
// when we're sending, but need to be able to handle it when receiving.
const int kPaddingBytes = 4;
const size_t kExpectedSizeWithPadding =
(kExpectedSizeWords * 4) + kPaddingBytes;
uint8_t mod_buffer[kExpectedSizeWithPadding];
memcpy(mod_buffer, packet.data(), kExpectedSizeWords * 4);
memset(&mod_buffer[kExpectedSizeWords * 4], 0, kPaddingBytes - 1);
mod_buffer[kExpectedSizeWithPadding - 1] =
kPaddingBytes + kExpectedPaddingSizeBytes;
const uint8_t padding_flag = 1 << 5;
mod_buffer[0] |= padding_flag;
ByteWriter<uint16_t>::WriteBigEndian(
&mod_buffer[2], ByteReader<uint16_t>::ReadBigEndian(&mod_buffer[2]) +
((kPaddingBytes + 3) / 4));
std::unique_ptr<TransportFeedback> parsed_packet(
TransportFeedback::ParseFrom(mod_buffer, kExpectedSizeWithPadding));
ASSERT_TRUE(parsed_packet != nullptr);
EXPECT_EQ(kExpectedSizeWords * 4, packet.size()); // Padding not included.
}
TEST(RtcpPacketTest, TransportFeedbackPaddingBackwardsCompatibility) {
const size_t kExpectedSizeBytes =
kHeaderSize + kStatusChunkSize + kSmallDeltaSize;
const size_t kExpectedSizeWords = (kExpectedSizeBytes + 3) / 4;
const size_t kExpectedPaddingSizeBytes =
4 * kExpectedSizeWords - kExpectedSizeBytes;
TransportFeedback feedback;
feedback.SetBase(0, 0);
EXPECT_TRUE(feedback.AddReceivedPacket(0, 0));
rtc::Buffer packet = feedback.Build();
EXPECT_EQ(kExpectedSizeWords * 4, packet.size());
ASSERT_GT(kExpectedSizeWords * 4, kExpectedSizeBytes);
for (size_t i = kExpectedSizeBytes; i < (kExpectedSizeWords * 4 - 1); ++i)
EXPECT_EQ(0u, packet[i]);
EXPECT_GT(kExpectedPaddingSizeBytes, 0u);
EXPECT_EQ(kExpectedPaddingSizeBytes, packet[kExpectedSizeWords * 4 - 1]);
// Modify packet by removing padding bit and writing zero at the last padding
// byte to verify that we can parse packets from old clients, where zero
// padding of up to three bytes was used without the padding bit being set.
uint8_t mod_buffer[kExpectedSizeWords * 4];
memcpy(mod_buffer, packet.data(), kExpectedSizeWords * 4);
mod_buffer[kExpectedSizeWords * 4 - 1] = 0;
const uint8_t padding_flag = 1 << 5;
mod_buffer[0] &= ~padding_flag; // Unset padding flag.
std::unique_ptr<TransportFeedback> parsed_packet(
TransportFeedback::ParseFrom(mod_buffer, kExpectedSizeWords * 4));
ASSERT_TRUE(parsed_packet != nullptr);
EXPECT_EQ(kExpectedSizeWords * 4, packet.size());
}
TEST(RtcpPacketTest, TransportFeedbackCorrectlySplitsVectorChunks) {
const int kOneBitVectorCapacity = 14;
const int64_t kLargeTimeDelta =
TransportFeedback::kDeltaScaleFactor * (1 << 8);
// Test that a number of small deltas followed by a large delta results in a
// correct split into multiple chunks, as needed.
for (int deltas = 0; deltas <= kOneBitVectorCapacity + 1; ++deltas) {
TransportFeedback feedback;
feedback.SetBase(0, 0);
for (int i = 0; i < deltas; ++i)
feedback.AddReceivedPacket(i, i * 1000);
feedback.AddReceivedPacket(deltas, deltas * 1000 + kLargeTimeDelta);
rtc::Buffer serialized_packet = feedback.Build();
std::unique_ptr<TransportFeedback> deserialized_packet =
TransportFeedback::ParseFrom(serialized_packet.data(),
serialized_packet.size());
EXPECT_TRUE(deserialized_packet != nullptr);
}
}
TEST(RtcpPacketTest, TransportFeedbackMoveConstructor) {
const int kSamples = 100;
const int64_t kDelta = TransportFeedback::kDeltaScaleFactor;
const uint16_t kBaseSeqNo = 7531;
const int64_t kBaseTimestampUs = 123456789;
const uint8_t kFeedbackSeqNo = 90;
TransportFeedback feedback;
feedback.SetBase(kBaseSeqNo, kBaseTimestampUs);
feedback.SetFeedbackSequenceNumber(kFeedbackSeqNo);
for (int i = 0; i < kSamples; ++i) {
feedback.AddReceivedPacket(kBaseSeqNo + i, kBaseTimestampUs + i * kDelta);
}
EXPECT_TRUE(feedback.IsConsistent());
TransportFeedback feedback_copy(feedback);
EXPECT_TRUE(feedback_copy.IsConsistent());
EXPECT_TRUE(feedback.IsConsistent());
EXPECT_EQ(feedback_copy.Build(), feedback.Build());
TransportFeedback moved(std::move(feedback));
EXPECT_TRUE(moved.IsConsistent());
EXPECT_TRUE(feedback.IsConsistent());
EXPECT_EQ(moved.Build(), feedback_copy.Build());
}
TEST(TransportFeedbackTest, ReportsMissingPackets) {
const uint16_t kBaseSeqNo = 1000;
const int64_t kBaseTimestampUs = 10000;
const uint8_t kFeedbackSeqNo = 90;
TransportFeedback feedback_builder(/*include_timestamps*/ true);
feedback_builder.SetBase(kBaseSeqNo, kBaseTimestampUs);
feedback_builder.SetFeedbackSequenceNumber(kFeedbackSeqNo);
feedback_builder.AddReceivedPacket(kBaseSeqNo + 0, kBaseTimestampUs);
// Packet losses indicated by jump in sequence number.
feedback_builder.AddReceivedPacket(kBaseSeqNo + 3, kBaseTimestampUs + 2000);
rtc::Buffer coded = feedback_builder.Build();
rtcp::CommonHeader header;
header.Parse(coded.data(), coded.size());
TransportFeedback feedback(/*include_timestamps*/ true,
/*include_lost*/ true);
feedback.Parse(header);
auto packets = feedback.GetAllPackets();
EXPECT_TRUE(packets[0].received());
EXPECT_FALSE(packets[1].received());
EXPECT_FALSE(packets[2].received());
EXPECT_TRUE(packets[3].received());
}
TEST(TransportFeedbackTest, ReportsMissingPacketsWithoutTimestamps) {
const uint16_t kBaseSeqNo = 1000;
const uint8_t kFeedbackSeqNo = 90;
TransportFeedback feedback_builder(/*include_timestamps*/ false);
feedback_builder.SetBase(kBaseSeqNo, 10000);
feedback_builder.SetFeedbackSequenceNumber(kFeedbackSeqNo);
feedback_builder.AddReceivedPacket(kBaseSeqNo + 0, /*timestamp_us*/ 0);
// Packet losses indicated by jump in sequence number.
feedback_builder.AddReceivedPacket(kBaseSeqNo + 3, /*timestamp_us*/ 0);
rtc::Buffer coded = feedback_builder.Build();
rtcp::CommonHeader header;
header.Parse(coded.data(), coded.size());
TransportFeedback feedback(/*include_timestamps*/ true,
/*include_lost*/ true);
feedback.Parse(header);
auto packets = feedback.GetAllPackets();
EXPECT_TRUE(packets[0].received());
EXPECT_FALSE(packets[1].received());
EXPECT_FALSE(packets[2].received());
EXPECT_TRUE(packets[3].received());
}
} // namespace
} // namespace webrtc