blob: ad68de45259030f89a40240bced9fc5af48c39fc [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 "modules/rtp_rtcp/source/flexfec_03_header_reader_writer.h"
#include <string.h>
#include <memory>
#include <utility>
#include "api/scoped_refptr.h"
#include "modules/rtp_rtcp/source/byte_io.h"
#include "modules/rtp_rtcp/source/forward_error_correction.h"
#include "modules/rtp_rtcp/source/forward_error_correction_internal.h"
#include "rtc_base/checks.h"
#include "rtc_base/random.h"
#include "test/gmock.h"
#include "test/gtest.h"
namespace webrtc {
namespace {
using Packet = ForwardErrorCorrection::Packet;
using ReceivedFecPacket = ForwardErrorCorrection::ReceivedFecPacket;
using ::testing::ElementsAreArray;
using ::testing::make_tuple;
using ::testing::SizeIs;
// General. Assume single-stream protection.
constexpr uint32_t kMediaSsrc = 1254983;
constexpr uint16_t kMediaStartSeqNum = 825;
constexpr size_t kMediaPacketLength = 1234;
constexpr uint32_t kFlexfecSsrc = 52142;
constexpr size_t kFlexfecHeaderSizes[] = {20, 24, 32};
constexpr size_t kFlexfecPacketMaskOffset = 18;
constexpr size_t kFlexfecPacketMaskSizes[] = {2, 6, 14};
constexpr size_t kFlexfecMaxPacketSize = kFlexfecPacketMaskSizes[2];
// Reader tests.
constexpr uint8_t kNoRBit = 0 << 7;
constexpr uint8_t kNoFBit = 0 << 6;
constexpr uint8_t kPtRecovery = 123;
constexpr uint8_t kLengthRecov[] = {0xab, 0xcd};
constexpr uint8_t kTsRecovery[] = {0x01, 0x23, 0x45, 0x67};
constexpr uint8_t kSsrcCount = 1;
constexpr uint8_t kReservedBits = 0x00;
constexpr uint8_t kProtSsrc[] = {0x11, 0x22, 0x33, 0x44};
constexpr uint8_t kSnBase[] = {0xaa, 0xbb};
constexpr uint8_t kPayloadBits = 0x00;
std::unique_ptr<uint8_t[]> GeneratePacketMask(size_t packet_mask_size,
uint64_t seed) {
Random random(seed);
std::unique_ptr<uint8_t[]> packet_mask(new uint8_t[kFlexfecMaxPacketSize]);
memset(packet_mask.get(), 0, kFlexfecMaxPacketSize);
for (size_t i = 0; i < packet_mask_size; ++i) {
packet_mask[i] = random.Rand<uint8_t>();
}
return packet_mask;
}
void ClearBit(size_t index, uint8_t* packet_mask) {
packet_mask[index / 8] &= ~(1 << (7 - index % 8));
}
void SetBit(size_t index, uint8_t* packet_mask) {
packet_mask[index / 8] |= (1 << (7 - index % 8));
}
rtc::scoped_refptr<Packet> WriteHeader(const uint8_t* packet_mask,
size_t packet_mask_size) {
Flexfec03HeaderWriter writer;
rtc::scoped_refptr<Packet> written_packet(new Packet());
written_packet->data.SetSize(kMediaPacketLength);
uint8_t* data = written_packet->data.MutableData();
for (size_t i = 0; i < written_packet->data.size(); ++i) {
data[i] = i; // Actual content doesn't matter.
}
const FecHeaderWriter::ProtectedStream protected_streams[] = {
{.ssrc = kMediaSsrc,
.seq_num_base = kMediaStartSeqNum,
.packet_mask = {packet_mask, packet_mask_size}}};
writer.FinalizeFecHeader(protected_streams, *written_packet);
return written_packet;
}
std::unique_ptr<ReceivedFecPacket> ReadHeader(const Packet& written_packet) {
Flexfec03HeaderReader reader;
std::unique_ptr<ReceivedFecPacket> read_packet(new ReceivedFecPacket());
read_packet->ssrc = kFlexfecSsrc;
read_packet->pkt = rtc::scoped_refptr<Packet>(new Packet());
read_packet->pkt->data = written_packet.data;
EXPECT_TRUE(reader.ReadFecHeader(read_packet.get()));
return read_packet;
}
void VerifyReadHeaders(size_t expected_fec_header_size,
const uint8_t* expected_packet_mask,
size_t expected_packet_mask_size,
const ReceivedFecPacket& read_packet) {
EXPECT_EQ(expected_fec_header_size, read_packet.fec_header_size);
EXPECT_EQ(ByteReader<uint32_t>::ReadBigEndian(kProtSsrc),
read_packet.protected_streams[0].ssrc);
EXPECT_EQ(ByteReader<uint16_t>::ReadBigEndian(kSnBase),
read_packet.protected_streams[0].seq_num_base);
auto packet_mask_offset = read_packet.protected_streams[0].packet_mask_offset;
EXPECT_EQ(kFlexfecPacketMaskOffset, packet_mask_offset);
EXPECT_EQ(expected_packet_mask_size,
read_packet.protected_streams[0].packet_mask_size);
EXPECT_EQ(read_packet.pkt->data.size() - expected_fec_header_size,
read_packet.protection_length);
// Ensure that the K-bits are removed and the packet mask has been packed.
EXPECT_THAT(
make_tuple(read_packet.pkt->data.cdata() + packet_mask_offset,
read_packet.protected_streams[0].packet_mask_size),
ElementsAreArray(expected_packet_mask, expected_packet_mask_size));
}
void VerifyFinalizedHeaders(const uint8_t* expected_packet_mask,
size_t expected_packet_mask_size,
const Packet& written_packet) {
const uint8_t* packet = written_packet.data.cdata();
EXPECT_EQ(0x00, packet[0] & 0x80); // F bit clear.
EXPECT_EQ(0x00, packet[0] & 0x40); // R bit clear.
EXPECT_EQ(0x01, packet[8]); // SSRCCount = 1.
EXPECT_EQ(kMediaSsrc, ByteReader<uint32_t>::ReadBigEndian(packet + 12));
EXPECT_EQ(kMediaStartSeqNum,
ByteReader<uint16_t>::ReadBigEndian(packet + 16));
EXPECT_THAT(
make_tuple(packet + kFlexfecPacketMaskOffset, expected_packet_mask_size),
ElementsAreArray(expected_packet_mask, expected_packet_mask_size));
}
void VerifyWrittenAndReadHeaders(size_t expected_fec_header_size,
const uint8_t* expected_packet_mask,
size_t expected_packet_mask_size,
const Packet& written_packet,
const ReceivedFecPacket& read_packet) {
EXPECT_EQ(kFlexfecSsrc, read_packet.ssrc);
EXPECT_EQ(expected_fec_header_size, read_packet.fec_header_size);
ASSERT_THAT(read_packet.protected_streams, SizeIs(1));
EXPECT_EQ(read_packet.protected_streams[0].ssrc, kMediaSsrc);
EXPECT_EQ(read_packet.protected_streams[0].seq_num_base, kMediaStartSeqNum);
EXPECT_EQ(read_packet.protected_streams[0].packet_mask_offset,
kFlexfecPacketMaskOffset);
ASSERT_EQ(read_packet.protected_streams[0].packet_mask_size,
expected_packet_mask_size);
EXPECT_EQ(written_packet.data.size() - expected_fec_header_size,
read_packet.protection_length);
// Verify that the call to ReadFecHeader did normalize the packet masks.
EXPECT_THAT(
make_tuple(read_packet.pkt->data.cdata() + kFlexfecPacketMaskOffset,
read_packet.protected_streams[0].packet_mask_size),
ElementsAreArray(expected_packet_mask, expected_packet_mask_size));
// Verify that the call to ReadFecHeader did not tamper with the payload.
EXPECT_THAT(
make_tuple(read_packet.pkt->data.cdata() + read_packet.fec_header_size,
read_packet.pkt->data.size() - read_packet.fec_header_size),
ElementsAreArray(written_packet.data.cdata() + expected_fec_header_size,
written_packet.data.size() - expected_fec_header_size));
}
} // namespace
TEST(Flexfec03HeaderReaderTest, ReadsHeaderWithKBit0Set) {
constexpr uint8_t kKBit0 = 1 << 7;
constexpr size_t kExpectedPacketMaskSize = 2;
constexpr size_t kExpectedFecHeaderSize = 20;
// clang-format off
constexpr uint8_t kFlexfecPktMask[] = {kKBit0 | 0x08, 0x81};
constexpr uint8_t kUlpfecPacketMask[] = {0x11, 0x02};
// clang-format on
constexpr uint8_t kPacketData[] = {
kNoRBit | kNoFBit, kPtRecovery, kLengthRecov[0], kLengthRecov[1],
kTsRecovery[0], kTsRecovery[1], kTsRecovery[2], kTsRecovery[3],
kSsrcCount, kReservedBits, kReservedBits, kReservedBits,
kProtSsrc[0], kProtSsrc[1], kProtSsrc[2], kProtSsrc[3],
kSnBase[0], kSnBase[1], kFlexfecPktMask[0], kFlexfecPktMask[1],
kPayloadBits, kPayloadBits, kPayloadBits, kPayloadBits};
const size_t packet_length = sizeof(kPacketData);
ReceivedFecPacket read_packet;
read_packet.pkt = rtc::scoped_refptr<Packet>(new Packet());
read_packet.pkt->data.SetData(kPacketData, packet_length);
Flexfec03HeaderReader reader;
EXPECT_TRUE(reader.ReadFecHeader(&read_packet));
VerifyReadHeaders(kExpectedFecHeaderSize, kUlpfecPacketMask,
kExpectedPacketMaskSize, read_packet);
}
TEST(Flexfec03HeaderReaderTest, ReadsHeaderWithKBit1Set) {
constexpr uint8_t kKBit0 = 0 << 7;
constexpr uint8_t kKBit1 = 1 << 7;
constexpr size_t kExpectedPacketMaskSize = 6;
constexpr size_t kExpectedFecHeaderSize = 24;
// clang-format off
constexpr uint8_t kFlxfecPktMsk[] = {kKBit0 | 0x48, 0x81,
kKBit1 | 0x02, 0x11, 0x00, 0x21};
constexpr uint8_t kUlpfecPacketMask[] = {0x91, 0x02,
0x08, 0x44, 0x00, 0x84};
// clang-format on
constexpr uint8_t kPacketData[] = {
kNoRBit | kNoFBit, kPtRecovery, kLengthRecov[0], kLengthRecov[1],
kTsRecovery[0], kTsRecovery[1], kTsRecovery[2], kTsRecovery[3],
kSsrcCount, kReservedBits, kReservedBits, kReservedBits,
kProtSsrc[0], kProtSsrc[1], kProtSsrc[2], kProtSsrc[3],
kSnBase[0], kSnBase[1], kFlxfecPktMsk[0], kFlxfecPktMsk[1],
kFlxfecPktMsk[2], kFlxfecPktMsk[3], kFlxfecPktMsk[4], kFlxfecPktMsk[5],
kPayloadBits, kPayloadBits, kPayloadBits, kPayloadBits};
const size_t packet_length = sizeof(kPacketData);
ReceivedFecPacket read_packet;
read_packet.pkt = rtc::scoped_refptr<Packet>(new Packet());
read_packet.pkt->data.SetData(kPacketData, packet_length);
Flexfec03HeaderReader reader;
EXPECT_TRUE(reader.ReadFecHeader(&read_packet));
VerifyReadHeaders(kExpectedFecHeaderSize, kUlpfecPacketMask,
kExpectedPacketMaskSize, read_packet);
}
TEST(Flexfec03HeaderReaderTest, ReadsHeaderWithKBit2Set) {
constexpr uint8_t kKBit0 = 0 << 7;
constexpr uint8_t kKBit1 = 0 << 7;
constexpr uint8_t kKBit2 = 1 << 7;
constexpr size_t kExpectedPacketMaskSize = 14;
constexpr size_t kExpectedFecHeaderSize = 32;
// clang-format off
constexpr uint8_t kFlxfcPktMsk[] = {kKBit0 | 0x48, 0x81,
kKBit1 | 0x02, 0x11, 0x00, 0x21,
kKBit2 | 0x01, 0x11, 0x11, 0x11,
0x11, 0x11, 0x11, 0x11};
constexpr uint8_t kUlpfecPacketMask[] = {0x91, 0x02,
0x08, 0x44, 0x00, 0x84,
0x08, 0x88, 0x88, 0x88,
0x88, 0x88, 0x88, 0x88};
// clang-format on
constexpr uint8_t kPacketData[] = {
kNoRBit | kNoFBit, kPtRecovery, kLengthRecov[0], kLengthRecov[1],
kTsRecovery[0], kTsRecovery[1], kTsRecovery[2], kTsRecovery[3],
kSsrcCount, kReservedBits, kReservedBits, kReservedBits,
kProtSsrc[0], kProtSsrc[1], kProtSsrc[2], kProtSsrc[3],
kSnBase[0], kSnBase[1], kFlxfcPktMsk[0], kFlxfcPktMsk[1],
kFlxfcPktMsk[2], kFlxfcPktMsk[3], kFlxfcPktMsk[4], kFlxfcPktMsk[5],
kFlxfcPktMsk[6], kFlxfcPktMsk[7], kFlxfcPktMsk[8], kFlxfcPktMsk[9],
kFlxfcPktMsk[10], kFlxfcPktMsk[11], kFlxfcPktMsk[12], kFlxfcPktMsk[13],
kPayloadBits, kPayloadBits, kPayloadBits, kPayloadBits};
const size_t packet_length = sizeof(kPacketData);
ReceivedFecPacket read_packet;
read_packet.pkt = rtc::scoped_refptr<Packet>(new Packet());
read_packet.pkt->data.SetData(kPacketData, packet_length);
Flexfec03HeaderReader reader;
EXPECT_TRUE(reader.ReadFecHeader(&read_packet));
VerifyReadHeaders(kExpectedFecHeaderSize, kUlpfecPacketMask,
kExpectedPacketMaskSize, read_packet);
}
TEST(Flexfec03HeaderReaderTest,
ReadPacketWithoutStreamSpecificHeaderShouldFail) {
const size_t packet_mask_size = kUlpfecPacketMaskSizeLBitClear;
auto packet_mask = GeneratePacketMask(packet_mask_size, 0xabcd);
auto written_packet = WriteHeader(packet_mask.get(), packet_mask_size);
// Simulate short received packet.
ReceivedFecPacket read_packet;
read_packet.ssrc = kFlexfecSsrc;
read_packet.pkt = std::move(written_packet);
read_packet.pkt->data.SetSize(12);
Flexfec03HeaderReader reader;
EXPECT_FALSE(reader.ReadFecHeader(&read_packet));
}
TEST(Flexfec03HeaderReaderTest, ReadShortPacketWithKBit0SetShouldFail) {
const size_t packet_mask_size = kUlpfecPacketMaskSizeLBitClear;
auto packet_mask = GeneratePacketMask(packet_mask_size, 0xabcd);
auto written_packet = WriteHeader(packet_mask.get(), packet_mask_size);
// Simulate short received packet.
ReceivedFecPacket read_packet;
read_packet.ssrc = kFlexfecSsrc;
read_packet.pkt = std::move(written_packet);
read_packet.pkt->data.SetSize(18);
Flexfec03HeaderReader reader;
EXPECT_FALSE(reader.ReadFecHeader(&read_packet));
}
TEST(Flexfec03HeaderReaderTest, ReadShortPacketWithKBit1SetShouldFail) {
const size_t packet_mask_size = kUlpfecPacketMaskSizeLBitClear;
auto packet_mask = GeneratePacketMask(packet_mask_size, 0xabcd);
SetBit(15, packet_mask.get()); // This expands the packet mask "once".
auto written_packet = WriteHeader(packet_mask.get(), packet_mask_size);
// Simulate short received packet.
ReceivedFecPacket read_packet;
read_packet.ssrc = kFlexfecSsrc;
read_packet.pkt = std::move(written_packet);
read_packet.pkt->data.SetSize(20);
Flexfec03HeaderReader reader;
EXPECT_FALSE(reader.ReadFecHeader(&read_packet));
}
TEST(Flexfec03HeaderReaderTest, ReadShortPacketWithKBit2SetShouldFail) {
const size_t packet_mask_size = kUlpfecPacketMaskSizeLBitSet;
auto packet_mask = GeneratePacketMask(packet_mask_size, 0xabcd);
SetBit(47, packet_mask.get()); // This expands the packet mask "twice".
auto written_packet = WriteHeader(packet_mask.get(), packet_mask_size);
// Simulate short received packet.
ReceivedFecPacket read_packet;
read_packet.ssrc = kFlexfecSsrc;
read_packet.pkt = std::move(written_packet);
read_packet.pkt->data.SetSize(24);
Flexfec03HeaderReader reader;
EXPECT_FALSE(reader.ReadFecHeader(&read_packet));
}
TEST(Flexfec03HeaderWriterTest, FinalizesHeaderWithKBit0Set) {
constexpr size_t kExpectedPacketMaskSize = 2;
constexpr uint8_t kFlexfecPacketMask[] = {0x88, 0x81};
constexpr uint8_t kUlpfecPacketMask[] = {0x11, 0x02};
Packet written_packet;
written_packet.data.SetSize(kMediaPacketLength);
uint8_t* data = written_packet.data.MutableData();
for (size_t i = 0; i < written_packet.data.size(); ++i) {
data[i] = i;
}
Flexfec03HeaderWriter writer;
const FecHeaderWriter::ProtectedStream protected_streams[] = {
{.ssrc = kMediaSsrc,
.seq_num_base = kMediaStartSeqNum,
.packet_mask = kUlpfecPacketMask}};
writer.FinalizeFecHeader(protected_streams, written_packet);
VerifyFinalizedHeaders(kFlexfecPacketMask, kExpectedPacketMaskSize,
written_packet);
}
TEST(Flexfec03HeaderWriterTest, FinalizesHeaderWithKBit1Set) {
constexpr size_t kExpectedPacketMaskSize = 6;
constexpr uint8_t kFlexfecPacketMask[] = {0x48, 0x81, 0x82, 0x11, 0x00, 0x21};
constexpr uint8_t kUlpfecPacketMask[] = {0x91, 0x02, 0x08, 0x44, 0x00, 0x84};
Packet written_packet;
written_packet.data.SetSize(kMediaPacketLength);
uint8_t* data = written_packet.data.MutableData();
for (size_t i = 0; i < written_packet.data.size(); ++i) {
data[i] = i;
}
Flexfec03HeaderWriter writer;
const FecHeaderWriter::ProtectedStream protected_streams[] = {
{.ssrc = kMediaSsrc,
.seq_num_base = kMediaStartSeqNum,
.packet_mask = kUlpfecPacketMask}};
writer.FinalizeFecHeader(protected_streams, written_packet);
VerifyFinalizedHeaders(kFlexfecPacketMask, kExpectedPacketMaskSize,
written_packet);
}
TEST(Flexfec03HeaderWriterTest, FinalizesHeaderWithKBit2Set) {
constexpr size_t kExpectedPacketMaskSize = 14;
constexpr uint8_t kFlexfecPacketMask[] = {
0x11, 0x11, // K-bit 0 clear.
0x11, 0x11, 0x11, 0x10, // K-bit 1 clear.
0xa0, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00 // K-bit 2 set.
};
constexpr uint8_t kUlpfecPacketMask[] = {0x22, 0x22, 0x44, 0x44, 0x44, 0x41};
Packet written_packet;
written_packet.data.SetSize(kMediaPacketLength);
uint8_t* data = written_packet.data.MutableData();
for (size_t i = 0; i < written_packet.data.size(); ++i) {
data[i] = i;
}
Flexfec03HeaderWriter writer;
const FecHeaderWriter::ProtectedStream protected_streams[] = {
{.ssrc = kMediaSsrc,
.seq_num_base = kMediaStartSeqNum,
.packet_mask = kUlpfecPacketMask}};
writer.FinalizeFecHeader(protected_streams, written_packet);
VerifyFinalizedHeaders(kFlexfecPacketMask, kExpectedPacketMaskSize,
written_packet);
}
TEST(Flexfec03HeaderWriterTest, ContractsShortUlpfecPacketMaskWithBit15Clear) {
const size_t packet_mask_size = kUlpfecPacketMaskSizeLBitClear;
auto packet_mask = GeneratePacketMask(packet_mask_size, 0xabcd);
ClearBit(15, packet_mask.get());
Flexfec03HeaderWriter writer;
size_t min_packet_mask_size =
writer.MinPacketMaskSize(packet_mask.get(), packet_mask_size);
EXPECT_EQ(kFlexfecPacketMaskSizes[0], min_packet_mask_size);
EXPECT_EQ(kFlexfecHeaderSizes[0], writer.FecHeaderSize(min_packet_mask_size));
}
TEST(Flexfec03HeaderWriterTest, ExpandsShortUlpfecPacketMaskWithBit15Set) {
const size_t packet_mask_size = kUlpfecPacketMaskSizeLBitClear;
auto packet_mask = GeneratePacketMask(packet_mask_size, 0xabcd);
SetBit(15, packet_mask.get());
Flexfec03HeaderWriter writer;
size_t min_packet_mask_size =
writer.MinPacketMaskSize(packet_mask.get(), packet_mask_size);
EXPECT_EQ(kFlexfecPacketMaskSizes[1], min_packet_mask_size);
EXPECT_EQ(kFlexfecHeaderSizes[1], writer.FecHeaderSize(min_packet_mask_size));
}
TEST(Flexfec03HeaderWriterTest,
ContractsLongUlpfecPacketMaskWithBit46ClearBit47Clear) {
const size_t packet_mask_size = kUlpfecPacketMaskSizeLBitSet;
auto packet_mask = GeneratePacketMask(packet_mask_size, 0xabcd);
ClearBit(46, packet_mask.get());
ClearBit(47, packet_mask.get());
Flexfec03HeaderWriter writer;
size_t min_packet_mask_size =
writer.MinPacketMaskSize(packet_mask.get(), packet_mask_size);
EXPECT_EQ(kFlexfecPacketMaskSizes[1], min_packet_mask_size);
EXPECT_EQ(kFlexfecHeaderSizes[1], writer.FecHeaderSize(min_packet_mask_size));
}
TEST(Flexfec03HeaderWriterTest,
ExpandsLongUlpfecPacketMaskWithBit46SetBit47Clear) {
const size_t packet_mask_size = kUlpfecPacketMaskSizeLBitSet;
auto packet_mask = GeneratePacketMask(packet_mask_size, 0xabcd);
SetBit(46, packet_mask.get());
ClearBit(47, packet_mask.get());
Flexfec03HeaderWriter writer;
size_t min_packet_mask_size =
writer.MinPacketMaskSize(packet_mask.get(), packet_mask_size);
EXPECT_EQ(kFlexfecPacketMaskSizes[2], min_packet_mask_size);
EXPECT_EQ(kFlexfecHeaderSizes[2], writer.FecHeaderSize(min_packet_mask_size));
}
TEST(Flexfec03HeaderWriterTest,
ExpandsLongUlpfecPacketMaskWithBit46ClearBit47Set) {
const size_t packet_mask_size = kUlpfecPacketMaskSizeLBitSet;
auto packet_mask = GeneratePacketMask(packet_mask_size, 0xabcd);
ClearBit(46, packet_mask.get());
SetBit(47, packet_mask.get());
Flexfec03HeaderWriter writer;
size_t min_packet_mask_size =
writer.MinPacketMaskSize(packet_mask.get(), packet_mask_size);
EXPECT_EQ(kFlexfecPacketMaskSizes[2], min_packet_mask_size);
EXPECT_EQ(kFlexfecHeaderSizes[2], writer.FecHeaderSize(min_packet_mask_size));
}
TEST(Flexfec03HeaderWriterTest,
ExpandsLongUlpfecPacketMaskWithBit46SetBit47Set) {
const size_t packet_mask_size = kUlpfecPacketMaskSizeLBitSet;
auto packet_mask = GeneratePacketMask(packet_mask_size, 0xabcd);
SetBit(46, packet_mask.get());
SetBit(47, packet_mask.get());
Flexfec03HeaderWriter writer;
size_t min_packet_mask_size =
writer.MinPacketMaskSize(packet_mask.get(), packet_mask_size);
EXPECT_EQ(kFlexfecPacketMaskSizes[2], min_packet_mask_size);
EXPECT_EQ(kFlexfecHeaderSizes[2], writer.FecHeaderSize(min_packet_mask_size));
}
TEST(Flexfec03HeaderReaderWriterTest,
WriteAndReadSmallUlpfecPacketHeaderWithMaskBit15Clear) {
const size_t packet_mask_size = kUlpfecPacketMaskSizeLBitClear;
auto packet_mask = GeneratePacketMask(packet_mask_size, 0xabcd);
ClearBit(15, packet_mask.get());
auto written_packet = WriteHeader(packet_mask.get(), packet_mask_size);
auto read_packet = ReadHeader(*written_packet);
VerifyWrittenAndReadHeaders(kFlexfecHeaderSizes[0], packet_mask.get(),
kFlexfecPacketMaskSizes[0], *written_packet,
*read_packet);
}
TEST(Flexfec03HeaderReaderWriterTest,
WriteAndReadSmallUlpfecPacketHeaderWithMaskBit15Set) {
const size_t packet_mask_size = kUlpfecPacketMaskSizeLBitClear;
auto packet_mask = GeneratePacketMask(packet_mask_size, 0xabcd);
SetBit(15, packet_mask.get());
auto written_packet = WriteHeader(packet_mask.get(), packet_mask_size);
auto read_packet = ReadHeader(*written_packet);
VerifyWrittenAndReadHeaders(kFlexfecHeaderSizes[1], packet_mask.get(),
kFlexfecPacketMaskSizes[1], *written_packet,
*read_packet);
}
TEST(Flexfec03HeaderReaderWriterTest,
WriteAndReadLargeUlpfecPacketHeaderWithMaskBits46And47Clear) {
const size_t packet_mask_size = kUlpfecPacketMaskSizeLBitSet;
auto packet_mask = GeneratePacketMask(packet_mask_size, 0xabcd);
ClearBit(46, packet_mask.get());
ClearBit(47, packet_mask.get());
auto written_packet = WriteHeader(packet_mask.get(), packet_mask_size);
auto read_packet = ReadHeader(*written_packet);
VerifyWrittenAndReadHeaders(kFlexfecHeaderSizes[1], packet_mask.get(),
kFlexfecPacketMaskSizes[1], *written_packet,
*read_packet);
}
TEST(Flexfec03HeaderReaderWriterTest,
WriteAndReadLargeUlpfecPacketHeaderWithMaskBit46SetBit47Clear) {
const size_t packet_mask_size = kUlpfecPacketMaskSizeLBitSet;
auto packet_mask = GeneratePacketMask(packet_mask_size, 0xabcd);
SetBit(46, packet_mask.get());
ClearBit(47, packet_mask.get());
auto written_packet = WriteHeader(packet_mask.get(), packet_mask_size);
auto read_packet = ReadHeader(*written_packet);
VerifyWrittenAndReadHeaders(kFlexfecHeaderSizes[2], packet_mask.get(),
kFlexfecPacketMaskSizes[2], *written_packet,
*read_packet);
}
TEST(Flexfec03HeaderReaderWriterTest,
WriteAndReadLargeUlpfecPacketHeaderMaskWithBit46ClearBit47Set) {
const size_t packet_mask_size = kUlpfecPacketMaskSizeLBitSet;
auto packet_mask = GeneratePacketMask(packet_mask_size, 0xabcd);
ClearBit(46, packet_mask.get());
SetBit(47, packet_mask.get());
auto written_packet = WriteHeader(packet_mask.get(), packet_mask_size);
auto read_packet = ReadHeader(*written_packet);
VerifyWrittenAndReadHeaders(kFlexfecHeaderSizes[2], packet_mask.get(),
kFlexfecPacketMaskSizes[2], *written_packet,
*read_packet);
}
TEST(Flexfec03HeaderReaderWriterTest,
WriteAndReadLargeUlpfecPacketHeaderWithMaskBits46And47Set) {
const size_t packet_mask_size = kUlpfecPacketMaskSizeLBitSet;
auto packet_mask = GeneratePacketMask(packet_mask_size, 0xabcd);
SetBit(46, packet_mask.get());
SetBit(47, packet_mask.get());
auto written_packet = WriteHeader(packet_mask.get(), packet_mask_size);
auto read_packet = ReadHeader(*written_packet);
VerifyWrittenAndReadHeaders(kFlexfecHeaderSizes[2], packet_mask.get(),
kFlexfecPacketMaskSizes[2], *written_packet,
*read_packet);
}
} // namespace webrtc