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/*
* Copyright (c) 2021-2022 Cisco and/or its affiliates.
* Licensed under the Apache License, Version 2.0 (the "License");
* you may not use this file except in compliance with the License.
* You may obtain a copy of the License at:
*
* http://www.apache.org/licenses/LICENSE-2.0
*
* Unless required by applicable law or agreed to in writing, software
* distributed under the License is distributed on an "AS IS" BASIS,
* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
* See the License for the specific language governing permissions and
* limitations under the License.
*/
#include <gtest/gtest.h>
#include <hicn/transport/core/content_object.h>
#include <hicn/transport/core/global_object_pool.h>
#include <protocols/fec_base.h>
#include <protocols/fec_utils.h>
#include <protocols/rtc/rtc_consts.h>
#include <algorithm>
#include <iostream>
#include <queue>
#include <random>
namespace transport {
namespace protocol {
class PacketFactory {
public:
PacketFactory(){};
~PacketFactory(){};
std::shared_ptr<transport::core::ContentObject> createData(
core::Name &name, uint32_t suffix, uint32_t payload_size,
uint32_t payload_filler) {
auto &packet_manager = core::PacketManager<>::getInstance();
// create payload
auto buff = packet_manager.getMemBuf();
buff->append(payload_size);
std::fill(buff->writableData(), buff->writableTail(), payload_filler);
// create data packet
auto data = packet_manager.getPacket<transport::core::ContentObject>(
HICN_PACKET_FORMAT_IPV6_TCP, 0);
struct rtc::data_packet_t header;
header.setTimestamp(1000);
header.setProductionRate(1);
data->appendPayload((const uint8_t *)&header, rtc::DATA_HEADER_SIZE);
data->appendPayload(buff->data(), buff->length());
data->setName(name.setSuffix(suffix));
data->setLifetime(500);
data->setPathLabel(12);
return data;
}
std::shared_ptr<transport::core::ContentObject> createData(
core::Name &name, uint32_t suffix, fec::buffer payload) {
auto &packet_manager = core::PacketManager<>::getInstance();
auto data = packet_manager.getPacket<transport::core::ContentObject>(
HICN_PACKET_FORMAT_IPV6_TCP, 0);
struct rtc::data_packet_t header;
header.setTimestamp(1000);
header.setProductionRate(1);
data->appendPayload((const uint8_t *)&header, rtc::DATA_HEADER_SIZE);
data->appendPayload(payload->data(), payload->length());
data->setName(name.setSuffix(suffix));
data->setLifetime(500);
data->setPathLabel(12);
return data;
}
};
class Encoder {
public:
Encoder(std::string fec_str) {
fec_type_ = fec::FECUtils::fecTypeFromString(fec_str.c_str());
encoder_ = fec::FECUtils::getEncoder(fec_type_, 1);
encoder_->setFECCallback(
std::bind(&Encoder::onFecPackets, this, std::placeholders::_1));
encoder_->setBufferCallback(
std::bind(&Encoder::getBuffer, this, std::placeholders::_1));
};
~Encoder(){};
void onFecPackets(fec::BufferArray &packets) {
for (auto &packet : packets) {
fec_packets_.push(packet.getBuffer());
}
}
fec::buffer getBuffer(std::size_t size) {
auto ret = core::PacketManager<>::getInstance()
.getPacket<transport::core::ContentObject>(
HICN_PACKET_FORMAT_IPV6_TCP, 0);
ret->updateLength(rtc::DATA_HEADER_SIZE + size);
ret->append(rtc::DATA_HEADER_SIZE + size);
ret->trimStart(ret->headerSize() + rtc::DATA_HEADER_SIZE);
return ret;
}
void onPacketProduced(core::ContentObject &content_object, uint32_t offset,
uint32_t metadata) {
encoder_->onPacketProduced(content_object, offset, metadata);
}
public:
std::queue<fec::buffer> fec_packets_;
private:
std::unique_ptr<fec::ProducerFEC> encoder_;
fec::FECType fec_type_;
};
class Decoder {
public:
Decoder(std::string fec_str) {
fec_type_ = fec::FECUtils::fecTypeFromString(fec_str.c_str());
decoder_ = fec::FECUtils::getDecoder(fec_type_, 1);
decoder_->setFECCallback(
std::bind(&Decoder::onFecPackets, this, std::placeholders::_1));
decoder_->setBufferCallback(fec::FECBase::BufferRequested(0));
};
~Decoder(){};
void onFecPackets(fec::BufferArray &packets) {
for (auto &packet : packets) {
recovered_packets_.push(packet.getBuffer());
}
}
void onPacketReceived(core::ContentObject &content_object, uint32_t offset) {
decoder_->onDataPacket(content_object, offset);
}
public:
std::queue<fec::buffer> recovered_packets_;
private:
std::unique_ptr<fec::ConsumerFEC> decoder_;
fec::FECType fec_type_;
};
TEST(FECtestRS, RSTestInOrder1) {
// use RS k = 2 N = 6
std::string fec_str = "RS_K2_N6";
Encoder encoder(fec_str);
Decoder decoder(fec_str);
PacketFactory pf;
core::Name name("b001::");
auto data1 = pf.createData(name, 1, 50, 1);
const uint8_t *data1_ptr = data1->data();
auto data2 = pf.createData(name, 2, 45, 2);
const uint8_t *data2_ptr = data2->data();
// encoding
uint32_t metadata = static_cast<uint32_t>(data1->getPayloadType());
encoder.onPacketProduced(*data1, data1->headerSize() + rtc::DATA_HEADER_SIZE,
metadata);
encoder.onPacketProduced(*data2, data2->headerSize() + rtc::DATA_HEADER_SIZE,
metadata);
// create fec packet
auto data3 = pf.createData(name, 3, encoder.fec_packets_.front());
// decode in order, data 1 is lost
decoder.onPacketReceived(*data2, data2->headerSize() + rtc::DATA_HEADER_SIZE);
decoder.onPacketReceived(*data3, data3->headerSize() + rtc::DATA_HEADER_SIZE);
// test payload pointers off the original packets
EXPECT_EQ((const uint8_t *)data1->data(), data1_ptr);
EXPECT_EQ((const uint8_t *)data2->data(), data2_ptr);
// check recovered packet
EXPECT_EQ(decoder.recovered_packets_.size(), (size_t)2);
auto recovered = pf.createData(name, 1, decoder.recovered_packets_.front());
bool eq_len = (data1->length() == recovered->length());
EXPECT_TRUE(eq_len);
int ret = -1;
if (eq_len)
ret = memcmp(data1->data(), recovered->data(), recovered->length());
EXPECT_EQ(ret, (int)0);
}
TEST(FECtestRS, RSTestInOrder2) {
// use RS k = 2 N = 6
std::string fec_str = "RS_K2_N6";
Encoder encoder(fec_str);
Decoder decoder(fec_str);
PacketFactory pf;
core::Name name("b001::");
auto data1 = pf.createData(name, 1, 50, 1);
const uint8_t *data1_ptr = data1->data();
auto data2 = pf.createData(name, 2, 45, 2);
const uint8_t *data2_ptr = data2->data();
// encoding
uint32_t metadata = static_cast<uint32_t>(data1->getPayloadType());
encoder.onPacketProduced(*data1, data1->headerSize() + rtc::DATA_HEADER_SIZE,
metadata);
encoder.onPacketProduced(*data2, data2->headerSize() + rtc::DATA_HEADER_SIZE,
metadata);
// create fec packet
auto data3 = pf.createData(name, 3, encoder.fec_packets_.front());
// decode in order, data 2 is lost
decoder.onPacketReceived(*data1, data1->headerSize() + rtc::DATA_HEADER_SIZE);
decoder.onPacketReceived(*data3, data3->headerSize() + rtc::DATA_HEADER_SIZE);
// test payload pointers off the original packets
EXPECT_EQ((const uint8_t *)data1->data(), data1_ptr);
EXPECT_EQ((const uint8_t *)data2->data(), data2_ptr);
// check recovered packet
EXPECT_EQ(decoder.recovered_packets_.size(), (size_t)2);
decoder.recovered_packets_.pop(); // pop data packet 1
auto recovered = pf.createData(name, 2, decoder.recovered_packets_.front());
bool eq_len = (data2->length() == recovered->length());
EXPECT_TRUE(eq_len);
int ret = -1;
if (eq_len)
ret = memcmp(data2->data(), recovered->data(), recovered->length());
EXPECT_EQ(ret, (int)0);
}
TEST(FECtestRS, RSTestOutOfOrder1) {
// use RS k = 2 N = 6
std::string fec_str = "RS_K2_N6";
Encoder encoder(fec_str);
Decoder decoder(fec_str);
PacketFactory pf;
core::Name name("b001::");
auto data1 = pf.createData(name, 1, 50, 1);
const uint8_t *data1_ptr = data1->data();
auto data2 = pf.createData(name, 2, 45, 2);
const uint8_t *data2_ptr = data2->data();
// encoding
uint32_t metadata = static_cast<uint32_t>(data1->getPayloadType());
encoder.onPacketProduced(*data1, data1->headerSize() + rtc::DATA_HEADER_SIZE,
metadata);
encoder.onPacketProduced(*data2, data2->headerSize() + rtc::DATA_HEADER_SIZE,
metadata);
// create fec packet
auto data3 = pf.createData(name, 3, encoder.fec_packets_.front());
// decoding ooo packets. data 1 is lost.
decoder.onPacketReceived(*data3, data3->headerSize() + rtc::DATA_HEADER_SIZE);
decoder.onPacketReceived(*data2, data2->headerSize() + rtc::DATA_HEADER_SIZE);
// test payload pointers off the original packets
EXPECT_EQ((const uint8_t *)data1->data(), data1_ptr);
EXPECT_EQ((const uint8_t *)data2->data(), data2_ptr);
// get recovered packet
EXPECT_EQ(decoder.recovered_packets_.size(), (size_t)2);
auto recovered = pf.createData(name, 1, decoder.recovered_packets_.front());
bool eq_len = (data1->length() == recovered->length());
EXPECT_TRUE(eq_len);
int ret = -1;
if (eq_len)
ret = memcmp(data1->data(), recovered->data(), recovered->length());
EXPECT_EQ(ret, (int)0);
}
TEST(FECtestRS, RSTestOutOfOrder2) {
// use RS k = 2 N = 6
std::string fec_str = "RS_K2_N6";
Encoder encoder(fec_str);
Decoder decoder(fec_str);
PacketFactory pf;
core::Name name("b001::");
auto data1 = pf.createData(name, 1, 50, 1);
const uint8_t *data1_ptr = data1->data();
auto data2 = pf.createData(name, 2, 45, 2);
const uint8_t *data2_ptr = data2->data();
// encoding
uint32_t metadata = static_cast<uint32_t>(data1->getPayloadType());
encoder.onPacketProduced(*data1, data1->headerSize() + rtc::DATA_HEADER_SIZE,
metadata);
encoder.onPacketProduced(*data2, data2->headerSize() + rtc::DATA_HEADER_SIZE,
metadata);
// create fec packet
auto data3 = pf.createData(name, 3, encoder.fec_packets_.front());
// decoding ooo packets. data 2 is lost.
decoder.onPacketReceived(*data3, data3->headerSize() + rtc::DATA_HEADER_SIZE);
decoder.onPacketReceived(*data1, data2->headerSize() + rtc::DATA_HEADER_SIZE);
// test payload pointers off the original packets
EXPECT_EQ((const uint8_t *)data1->data(), data1_ptr);
EXPECT_EQ((const uint8_t *)data2->data(), data2_ptr);
// get recovered packet
EXPECT_EQ(decoder.recovered_packets_.size(), (size_t)2);
decoder.recovered_packets_.pop(); // pop data packet 1
auto recovered = pf.createData(name, 2, decoder.recovered_packets_.front());
bool eq_len = (data2->length() == recovered->length());
EXPECT_TRUE(eq_len);
int ret = -1;
if (eq_len)
ret = memcmp(data2->data(), recovered->data(), recovered->length());
EXPECT_EQ(ret, (int)0);
}
TEST(FECtestRS, RSTestLargerBlocks) {
// use RS k = 4 N = 7
std::string fec_str = "RS_K4_N7";
Encoder encoder(fec_str);
Decoder decoder(fec_str);
PacketFactory pf;
core::Name name("b001::");
auto data1 = pf.createData(name, 1, 50, 1);
const uint8_t *data1_ptr = data1->data();
auto data2 = pf.createData(name, 2, 45, 2);
const uint8_t *data2_ptr = data2->data();
auto data3 = pf.createData(name, 3, 12, 3);
const uint8_t *data3_ptr = data3->data();
auto data4 = pf.createData(name, 4, 20, 4);
const uint8_t *data4_ptr = data4->data();
// encoding
uint32_t metadata = static_cast<uint32_t>(data1->getPayloadType());
encoder.onPacketProduced(*data1, data1->headerSize() + rtc::DATA_HEADER_SIZE,
metadata);
encoder.onPacketProduced(*data2, data2->headerSize() + rtc::DATA_HEADER_SIZE,
metadata);
encoder.onPacketProduced(*data3, data3->headerSize() + rtc::DATA_HEADER_SIZE,
metadata);
encoder.onPacketProduced(*data4, data4->headerSize() + rtc::DATA_HEADER_SIZE,
metadata);
// create fec packet
auto data5 = pf.createData(name, 5, encoder.fec_packets_.front());
encoder.fec_packets_.pop(); // pop 5
encoder.fec_packets_.pop(); // pop 6
auto data7 = pf.createData(name, 7, encoder.fec_packets_.front());
// decoding packets: lost data 3 and data 4
decoder.onPacketReceived(*data2, data2->headerSize() + rtc::DATA_HEADER_SIZE);
decoder.onPacketReceived(*data7, data7->headerSize() + rtc::DATA_HEADER_SIZE);
decoder.onPacketReceived(*data1, data1->headerSize() + rtc::DATA_HEADER_SIZE);
decoder.onPacketReceived(*data5, data5->headerSize() + rtc::DATA_HEADER_SIZE);
// test payload pointers off the original packets
EXPECT_EQ((const uint8_t *)data1->data(), data1_ptr);
EXPECT_EQ((const uint8_t *)data2->data(), data2_ptr);
EXPECT_EQ((const uint8_t *)data3->data(), data3_ptr);
EXPECT_EQ((const uint8_t *)data4->data(), data4_ptr);
// get recovered packet
EXPECT_EQ(decoder.recovered_packets_.size(), (size_t)4);
decoder.recovered_packets_.pop(); // pop data 1
decoder.recovered_packets_.pop(); // pop data 2
auto recovered3 = pf.createData(name, 3, decoder.recovered_packets_.front());
decoder.recovered_packets_.pop(); // pop data 3
auto recovered4 = pf.createData(name, 4, decoder.recovered_packets_.front());
bool eq_len = (data3->length() == recovered3->length());
EXPECT_TRUE(eq_len);
int ret = -1;
if (eq_len)
ret = memcmp(data3->data(), recovered3->data(), recovered3->length());
EXPECT_EQ(ret, (int)0);
eq_len = (data4->length() == recovered4->length());
EXPECT_TRUE(eq_len);
ret = -1;
if (eq_len)
ret = memcmp(data4->data(), recovered4->data(), recovered4->length());
EXPECT_EQ(ret, (int)0);
}
} // namespace protocol
} // namespace transport
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