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/* -*- Mode:C++; c-file-style:"gnu"; indent-tabs-mode:nil; -*- */
/*
* Copyright (c) 2016-2019, Regents of the University of California,
* Colorado State University,
* University Pierre & Marie Curie, Sorbonne University.
*
* This file is part of ndn-tools (Named Data Networking Essential Tools).
* See AUTHORS.md for complete list of ndn-tools authors and contributors.
*
* ndn-tools is free software: you can redistribute it and/or modify it under the terms
* of the GNU General Public License as published by the Free Software Foundation,
* either version 3 of the License, or (at your option) any later version.
*
* ndn-tools is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY;
* without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR
* PURPOSE. See the GNU General Public License for more details.
*
* You should have received a copy of the GNU General Public License along with
* ndn-tools, e.g., in COPYING.md file. If not, see <http://www.gnu.org/licenses/>.
*
* See AUTHORS.md for complete list of ndn-cxx authors and contributors.
*
* @author Weiwei Liu
* @author Chavoosh Ghasemi
* @author Klaus Schneider
*/
#include "tools/chunks/catchunks/pipeline-interests-aimd.hpp"
#include "tools/chunks/catchunks/options.hpp"
#include "pipeline-interests-fixture.hpp"
namespace ndn {
namespace chunks {
namespace tests {
using namespace ndn::tests;
class PipelineInterestAimdFixture : public PipelineInterestsFixture
{
public:
PipelineInterestAimdFixture()
: opt(makePipelineOptions())
, rttEstimator(makeRttEstimatorOptions())
{
createPipeline();
}
void
createPipeline()
{
auto pline = make_unique<PipelineInterestsAimd>(face, rttEstimator, opt);
pipeline = pline.get();
setPipeline(std::move(pline));
}
private:
static PipelineInterestsAdaptive::Options
makePipelineOptions()
{
PipelineInterestsAdaptive::Options pipelineOptions;
pipelineOptions.isQuiet = true;
pipelineOptions.isVerbose = false;
pipelineOptions.disableCwa = false;
pipelineOptions.ignoreCongMarks = false;
pipelineOptions.resetCwndToInit = false;
pipelineOptions.initCwnd = 1.0;
pipelineOptions.aiStep = 1.0;
pipelineOptions.mdCoef = 0.5;
pipelineOptions.initSsthresh = std::numeric_limits<int>::max();
return pipelineOptions;
}
static RttEstimator::Options
makeRttEstimatorOptions()
{
RttEstimator::Options rttOptions;
rttOptions.alpha = 0.125;
rttOptions.beta = 0.25;
rttOptions.k = 4;
rttOptions.minRto = RttEstimator::MillisecondsDouble(200);
rttOptions.maxRto = RttEstimator::MillisecondsDouble(4000);
return rttOptions;
}
protected:
PipelineInterestsAdaptive::Options opt;
RttEstimator rttEstimator;
PipelineInterestsAdaptive* pipeline;
static constexpr double MARGIN = 0.01;
};
constexpr double PipelineInterestAimdFixture::MARGIN;
BOOST_AUTO_TEST_SUITE(Chunks)
BOOST_FIXTURE_TEST_SUITE(TestPipelineInterestsAimd, PipelineInterestAimdFixture)
BOOST_AUTO_TEST_CASE(SlowStart)
{
nDataSegments = 4;
pipeline->m_ssthresh = 8.0;
BOOST_REQUIRE_CLOSE(pipeline->m_cwnd, 1, MARGIN);
double preCwnd = pipeline->m_cwnd;
run(name);
advanceClocks(io, time::nanoseconds(1));
BOOST_CHECK_EQUAL(face.sentInterests.size(), 1);
for (uint64_t i = 0; i < nDataSegments - 1; ++i) {
face.receive(*makeDataWithSegment(i));
advanceClocks(io, time::nanoseconds(1));
BOOST_CHECK_CLOSE(pipeline->m_cwnd - preCwnd, 1, MARGIN);
preCwnd = pipeline->m_cwnd;
}
BOOST_CHECK_EQUAL(pipeline->m_nReceived, nDataSegments - 1);
}
BOOST_AUTO_TEST_CASE(CongestionAvoidance)
{
nDataSegments = 7;
pipeline->m_ssthresh = 4.0;
BOOST_REQUIRE_CLOSE(pipeline->m_cwnd, 1, MARGIN);
double preCwnd = pipeline->m_cwnd;
run(name);
advanceClocks(io, time::nanoseconds(1));
BOOST_CHECK_EQUAL(face.sentInterests.size(), 1);
for (uint64_t i = 0; i < pipeline->m_ssthresh; ++i) { // slow start
face.receive(*makeDataWithSegment(i));
advanceClocks(io, time::nanoseconds(1));
preCwnd = pipeline->m_cwnd;
}
BOOST_CHECK_CLOSE(preCwnd, 4.25, MARGIN);
for (uint64_t i = pipeline->m_ssthresh; i < nDataSegments - 1; ++i) { // congestion avoidance
face.receive(*makeDataWithSegment(i));
advanceClocks(io, time::nanoseconds(1));
BOOST_CHECK_CLOSE(pipeline->m_cwnd - preCwnd, opt.aiStep / floor(pipeline->m_cwnd), MARGIN);
preCwnd = pipeline->m_cwnd;
}
BOOST_CHECK_EQUAL(pipeline->m_nReceived, nDataSegments - 1);
}
BOOST_AUTO_TEST_CASE(Timeout)
{
nDataSegments = 8;
pipeline->m_ssthresh = 4.0;
BOOST_REQUIRE_CLOSE(pipeline->m_cwnd, 1, MARGIN);
run(name);
advanceClocks(io, time::nanoseconds(1));
BOOST_CHECK_EQUAL(face.sentInterests.size(), 1);
// receive segment 0, 1, and 2
for (uint64_t i = 0; i < 3; ++i) {
face.receive(*makeDataWithSegment(i));
advanceClocks(io, time::nanoseconds(1));
}
BOOST_CHECK_EQUAL(pipeline->m_nReceived, 3);
BOOST_CHECK_CLOSE(pipeline->m_cwnd, 4, MARGIN);
BOOST_CHECK_EQUAL(face.sentInterests.size(), 7); // request for segment 7 has been sent
advanceClocks(io, time::milliseconds(100));
// receive segment 4
face.receive(*makeDataWithSegment(4));
advanceClocks(io, time::nanoseconds(1));
// receive segment 5
face.receive(*makeDataWithSegment(5));
advanceClocks(io, time::nanoseconds(1));
BOOST_CHECK_EQUAL(pipeline->m_nReceived, 5);
BOOST_CHECK_CLOSE(pipeline->m_cwnd, 4.5, MARGIN);
BOOST_CHECK_EQUAL(face.sentInterests.size(), nDataSegments); // all the segment requests have been sent
BOOST_CHECK_EQUAL(pipeline->m_nTimeouts, 0);
BOOST_CHECK_EQUAL(pipeline->m_nLossDecr, 0);
BOOST_CHECK_EQUAL(pipeline->m_nMarkDecr, 0);
BOOST_CHECK_EQUAL(pipeline->m_nRetransmitted, 0);
BOOST_CHECK_EQUAL(pipeline->m_nSkippedRetx, 0);
BOOST_CHECK_EQUAL(pipeline->m_nCongMarks, 0);
// timeout segment 3 & 6
advanceClocks(io, time::milliseconds(150));
BOOST_CHECK_EQUAL(pipeline->m_nTimeouts, 2);
BOOST_CHECK_EQUAL(pipeline->m_nRetransmitted, 1);
BOOST_CHECK_EQUAL(pipeline->m_nLossDecr, 1);
BOOST_CHECK_EQUAL(pipeline->m_nSkippedRetx, 0);
BOOST_CHECK_EQUAL(pipeline->m_nReceived, 5);
BOOST_CHECK_CLOSE(pipeline->m_cwnd, 2.25, MARGIN); // window size drop to 1/2 of previous size
BOOST_CHECK_EQUAL(pipeline->m_retxQueue.size(), 1);
// receive segment 6, retransmit 3
face.receive(*makeDataWithSegment(6));
advanceClocks(io, time::nanoseconds(1));
BOOST_CHECK_EQUAL(pipeline->m_nReceived, 6);
BOOST_CHECK_CLOSE(pipeline->m_cwnd, 2.75, MARGIN); // congestion avoidance
BOOST_CHECK_EQUAL(pipeline->m_retxQueue.size(), 0);
BOOST_CHECK_EQUAL(pipeline->m_retxCount[3], 1);
BOOST_CHECK_EQUAL(pipeline->m_nTimeouts, 2);
BOOST_CHECK_EQUAL(pipeline->m_nRetransmitted, 2);
BOOST_CHECK_EQUAL(pipeline->m_nTimeouts,
pipeline->m_nRetransmitted + pipeline->m_nSkippedRetx);
}
BOOST_AUTO_TEST_CASE(CongestionMarksWithCwa)
{
nDataSegments = 7;
pipeline->m_ssthresh = 4.0;
BOOST_REQUIRE_CLOSE(pipeline->m_cwnd, 1, MARGIN);
run(name);
advanceClocks(io, time::nanoseconds(1));
BOOST_CHECK_EQUAL(face.sentInterests.size(), 1);
// receive segments 0 to 4
for (uint64_t i = 0; i < 5; ++i) {
face.receive(*makeDataWithSegment(i));
advanceClocks(io, time::nanoseconds(1));
}
BOOST_CHECK_EQUAL(pipeline->m_nReceived, 5);
BOOST_CHECK_CLOSE(pipeline->m_cwnd, 4.5, MARGIN);
// receive segment 5 with congestion mark
face.receive(*makeDataWithSegmentAndCongMark(5));
advanceClocks(io, time::nanoseconds(1));
BOOST_CHECK_EQUAL(pipeline->m_nReceived, 6);
BOOST_CHECK_CLOSE(pipeline->m_cwnd, 2.25, MARGIN); // window size drops to 1/2 of previous size
BOOST_CHECK_EQUAL(face.sentInterests.size(), nDataSegments); // all interests have been sent
// receive the last segment with congestion mark
face.receive(*makeDataWithSegmentAndCongMark(nDataSegments - 1));
advanceClocks(io, time::nanoseconds(1));
BOOST_CHECK_EQUAL(pipeline->m_nReceived, nDataSegments);
BOOST_CHECK_CLOSE(pipeline->m_cwnd, 2.25, MARGIN); // conservative window adaption (window size should not decrease)
BOOST_CHECK_EQUAL(pipeline->m_retxQueue.size(), 0);
// make sure no interest is retransmitted for marked data packets
BOOST_CHECK_EQUAL(pipeline->m_retxCount[5], 0);
BOOST_CHECK_EQUAL(pipeline->m_retxCount[nDataSegments - 1], 0);
// check number of received marked data packets
BOOST_CHECK_EQUAL(pipeline->m_nCongMarks, 2);
}
BOOST_AUTO_TEST_CASE(CongestionMarksWithoutCwa)
{
opt.disableCwa = true;
createPipeline();
nDataSegments = 7;
pipeline->m_ssthresh = 4.0;
BOOST_REQUIRE_CLOSE(pipeline->m_cwnd, 1, MARGIN);
run(name);
advanceClocks(io, time::nanoseconds(1));
BOOST_CHECK_EQUAL(face.sentInterests.size(), 1);
// receive segments 0 to 4
for (uint64_t i = 0; i < 5; ++i) {
face.receive(*makeDataWithSegment(i));
advanceClocks(io, time::nanoseconds(1));
}
BOOST_CHECK_EQUAL(pipeline->m_nReceived, 5);
BOOST_CHECK_CLOSE(pipeline->m_cwnd, 4.5, MARGIN);
// receive segment 5 with congestion mark
face.receive(*makeDataWithSegmentAndCongMark(5));
advanceClocks(io, time::nanoseconds(1));
BOOST_CHECK_EQUAL(pipeline->m_nReceived, 6);
BOOST_CHECK_CLOSE(pipeline->m_cwnd, 2.25, MARGIN); // window size drops to 1/2 of previous size
BOOST_CHECK_EQUAL(face.sentInterests.size(), nDataSegments); // all interests have been sent
// receive the last segment with congestion mark
face.receive(*makeDataWithSegmentAndCongMark(nDataSegments - 1));
advanceClocks(io, time::nanoseconds(1));
BOOST_CHECK_EQUAL(pipeline->m_nReceived, nDataSegments);
BOOST_CHECK_CLOSE(pipeline->m_cwnd, PipelineInterestsAdaptive::MIN_SSTHRESH,
MARGIN); // window size should decrease, as cwa is disabled
BOOST_CHECK_EQUAL(pipeline->m_retxQueue.size(), 0);
// make sure no interest is retransmitted for marked data packets
BOOST_CHECK_EQUAL(pipeline->m_retxCount[5], 0);
BOOST_CHECK_EQUAL(pipeline->m_retxCount[nDataSegments - 1], 0);
// check number of received marked data packets
BOOST_CHECK_EQUAL(pipeline->m_nCongMarks, 2);
}
BOOST_AUTO_TEST_CASE(IgnoreCongestionMarks)
{
opt.ignoreCongMarks = true;
createPipeline();
nDataSegments = 7;
pipeline->m_ssthresh = 4.0;
BOOST_REQUIRE_CLOSE(pipeline->m_cwnd, 1, MARGIN);
run(name);
advanceClocks(io, time::nanoseconds(1));
BOOST_CHECK_EQUAL(face.sentInterests.size(), 1);
// receive segments 0 to 5
for (uint64_t i = 0; i < 6; ++i) {
face.receive(*makeDataWithSegment(i));
advanceClocks(io, time::nanoseconds(1));
}
BOOST_CHECK_EQUAL(pipeline->m_nReceived, 6);
BOOST_CHECK_CLOSE(pipeline->m_cwnd, 4.75, MARGIN);
BOOST_CHECK_EQUAL(face.sentInterests.size(), nDataSegments); // all interests have been sent
// receive the last segment with congestion mark
face.receive(*makeDataWithSegmentAndCongMark(nDataSegments - 1));
advanceClocks(io, time::nanoseconds(1));
BOOST_CHECK_EQUAL(pipeline->m_nReceived, nDataSegments);
BOOST_CHECK_CLOSE(pipeline->m_cwnd, 5.0, MARGIN); // window size increases
BOOST_CHECK_EQUAL(pipeline->m_retxQueue.size(), 0);
// make sure no interest is retransmitted for marked data packet
BOOST_CHECK_EQUAL(pipeline->m_retxCount[nDataSegments - 1], 0);
// check number of received marked data packets
BOOST_CHECK_EQUAL(pipeline->m_nCongMarks, 1);
}
BOOST_AUTO_TEST_CASE(Nack)
{
nDataSegments = 5;
pipeline->m_cwnd = 10.0;
run(name);
advanceClocks(io, time::nanoseconds(1));
face.receive(*makeDataWithSegment(0));
advanceClocks(io, time::nanoseconds(1));
face.receive(*makeDataWithSegment(1));
advanceClocks(io, time::nanoseconds(1));
BOOST_CHECK_EQUAL(pipeline->m_nReceived, 2);
BOOST_REQUIRE_EQUAL(face.sentInterests.size(), 10);
// receive a nack with NackReason::DUPLICATE for segment 1
auto nack1 = makeNack(face.sentInterests[1], lp::NackReason::DUPLICATE);
face.receive(nack1);
advanceClocks(io, time::nanoseconds(1));
// nack1 is ignored
BOOST_CHECK_EQUAL(hasFailed, false);
BOOST_CHECK_EQUAL(pipeline->m_nReceived, 2);
BOOST_CHECK_EQUAL(pipeline->m_retxQueue.size(), 0);
// receive a nack with NackReason::CONGESTION for segment 2
auto nack2 = makeNack(face.sentInterests[2], lp::NackReason::CONGESTION);
face.receive(nack2);
advanceClocks(io, time::nanoseconds(1));
// segment 2 is retransmitted
BOOST_CHECK_EQUAL(pipeline->m_retxCount[2], 1);
// receive a nack with NackReason::NONE for segment 3
auto nack3 = makeNack(face.sentInterests[3], lp::NackReason::NONE);
face.receive(nack3);
advanceClocks(io, time::nanoseconds(1));
// Other types of Nack will trigger a failure
BOOST_CHECK_EQUAL(hasFailed, true);
BOOST_CHECK_EQUAL(pipeline->m_nReceived, 2);
}
BOOST_AUTO_TEST_CASE(FinalBlockIdNotSetAtBeginning)
{
nDataSegments = 4;
pipeline->m_cwnd = 4;
run(name);
advanceClocks(io, time::nanoseconds(1));
// receive segment 0 without FinalBlockId
face.receive(*makeDataWithSegment(0, false));
advanceClocks(io, time::nanoseconds(1));
// interests for segment 0 - 5 have been sent
BOOST_CHECK_EQUAL(face.sentInterests.size(), 6);
BOOST_CHECK_EQUAL(pipeline->m_nReceived, 1);
BOOST_CHECK_EQUAL(pipeline->m_hasFinalBlockId, false);
// pending interests: segment 1, 2, 3, 4, 5
BOOST_CHECK_EQUAL(face.getNPendingInterests(), 5);
// receive segment 1 with FinalBlockId
face.receive(*makeDataWithSegment(1));
advanceClocks(io, time::nanoseconds(1));
BOOST_CHECK_EQUAL(pipeline->m_nReceived, 2);
BOOST_CHECK_EQUAL(pipeline->m_hasFinalBlockId, true);
// pending interests for segment 1, 4, 5 haven been removed
BOOST_CHECK_EQUAL(face.getNPendingInterests(), 2);
}
BOOST_AUTO_TEST_CASE(FailureBeforeFinalBlockIdReceived)
{
// failed to retrieve segNo while the FinalBlockId has not yet been
// set, and later received a FinalBlockId >= segNo, i.e. segNo is
// part of the content.
nDataSegments = 4;
pipeline->m_cwnd = 4;
run(name);
advanceClocks(io, time::nanoseconds(1));
// receive segment 0 without FinalBlockId
face.receive(*makeDataWithSegment(0, false));
advanceClocks(io, time::nanoseconds(1));
// receive segment 1 without FinalBlockId
face.receive(*makeDataWithSegment(1, false));
advanceClocks(io, time::nanoseconds(1));
// interests for segment 0 - 7 have been sent
BOOST_REQUIRE_EQUAL(face.sentInterests.size(), 8);
// receive nack with NackReason::NONE for segment 3
auto nack = makeNack(face.sentInterests[3], lp::NackReason::NONE);
face.receive(nack);
advanceClocks(io, time::nanoseconds(1));
// error not triggered
// pending interests for segment > 3 haven been removed
BOOST_CHECK_EQUAL(hasFailed, false);
BOOST_CHECK_EQUAL(face.getNPendingInterests(), 1);
// receive segment 2 with FinalBlockId
face.receive(*makeDataWithSegment(2));
advanceClocks(io, time::nanoseconds(1));
// error triggered since segment 3 is part of the content
BOOST_CHECK_EQUAL(hasFailed, true);
}
BOOST_AUTO_TEST_CASE(SpuriousFailureBeforeFinalBlockIdReceived)
{
// failed to retrieve segNo while the FinalBlockId has not yet been
// set, and later received a FinalBlockId < segNo, i.e. segNo is
// not part of the content, and it was actually a spurious failure
nDataSegments = 4;
pipeline->m_cwnd = 4;
run(name);
advanceClocks(io, time::nanoseconds(1));
// receive segment 0 without FinalBlockId
face.receive(*makeDataWithSegment(0, false));
advanceClocks(io, time::nanoseconds(1));
// receive segment 1 without FinalBlockId
face.receive(*makeDataWithSegment(1, false));
advanceClocks(io, time::nanoseconds(1));
// interests for segment 0 - 7 have been sent
BOOST_REQUIRE_EQUAL(face.sentInterests.size(), 8);
// receive nack with NackReason::NONE for segment 4
auto nack = makeNack(face.sentInterests[4], lp::NackReason::NONE);
face.receive(nack);
advanceClocks(io, time::nanoseconds(1));
// error not triggered
// pending interests for segment > 3 have been removed
BOOST_CHECK_EQUAL(hasFailed, false);
BOOST_CHECK_EQUAL(face.getNPendingInterests(), 2);
// receive segment 2 with FinalBlockId
face.receive(*makeDataWithSegment(2));
advanceClocks(io, time::nanoseconds(1));
// timeout segment 3
advanceClocks(io, time::seconds(1));
// segment 3 is retransmitted
BOOST_CHECK_EQUAL(pipeline->m_retxCount[3], 1);
// receive segment 3
face.receive(*makeDataWithSegment(3));
advanceClocks(io, time::nanoseconds(1));
BOOST_CHECK_EQUAL(hasFailed, false);
}
BOOST_AUTO_TEST_CASE(SegmentInfoMaintenance)
{
// test that m_segmentInfo is properly maintained when
// a segment is received after two consecutive timeouts
nDataSegments = 3;
run(name);
advanceClocks(io, time::nanoseconds(1));
// receive segment 0
face.receive(*makeDataWithSegment(0));
advanceClocks(io, time::nanoseconds(1));
// receive segment 1
face.receive(*makeDataWithSegment(1));
advanceClocks(io, time::nanoseconds(1));
BOOST_CHECK_EQUAL(face.sentInterests.size(), 3);
// check if segment 2's state is FirstTimeSent
auto it = pipeline->m_segmentInfo.find(2);
BOOST_REQUIRE(it != pipeline->m_segmentInfo.end());
BOOST_CHECK(it->second.state == SegmentState::FirstTimeSent);
// timeout segment 2 twice
advanceClocks(io, time::milliseconds(400), 3);
BOOST_CHECK_EQUAL(face.sentInterests.size(), 5);
// check if segment 2's state is Retransmitted
it = pipeline->m_segmentInfo.find(2);
BOOST_REQUIRE(it != pipeline->m_segmentInfo.end());
BOOST_CHECK(it->second.state == SegmentState::Retransmitted);
// check if segment 2 was retransmitted twice
BOOST_CHECK_EQUAL(pipeline->m_retxCount.at(2), 2);
// receive segment 2 the first time
face.receive(*makeDataWithSegment(2));
advanceClocks(io, time::nanoseconds(1));
// check if segment 2 was erased from m_segmentInfo
it = pipeline->m_segmentInfo.find(2);
BOOST_CHECK(it == pipeline->m_segmentInfo.end());
auto prevRtt = rttEstimator.getAvgRtt();
auto prevRto = rttEstimator.getEstimatedRto();
// receive segment 2 the second time
face.receive(*makeDataWithSegment(2));
advanceClocks(io, time::nanoseconds(1));
// nothing changed
it = pipeline->m_segmentInfo.find(2);
BOOST_CHECK(it == pipeline->m_segmentInfo.end());
BOOST_CHECK_EQUAL(face.sentInterests.size(), 5);
BOOST_CHECK_EQUAL(rttEstimator.getAvgRtt(), prevRtt);
BOOST_CHECK_EQUAL(rttEstimator.getEstimatedRto(), prevRto);
}
BOOST_AUTO_TEST_CASE(PrintSummaryWithNoRttMeasurements)
{
// test the console ouptut when no RTT measurement is available,
// to make sure a proper message will be printed out
std::stringstream ss;
// change the underlying buffer and save the old buffer
auto oldBuf = std::cerr.rdbuf(ss.rdbuf());
pipeline->printSummary();
std::string line;
bool found = false;
while (std::getline(ss, line)) {
if (line == "RTT stats unavailable") {
found = true;
break;
}
}
BOOST_CHECK(found);
std::cerr.rdbuf(oldBuf); // reset
}
BOOST_AUTO_TEST_CASE(StopsWhenFileSizeLessThanChunkSize)
{
// test to see if the program doesn't hang,
// when transfer is complete, for files less than the chunk size
// (i.e. when only one segment is sent/received)
createPipeline();
nDataSegments = 1;
run(name);
advanceClocks(io, time::nanoseconds(1));
face.receive(*makeDataWithSegment(0));
advanceClocks(io, time::nanoseconds(1));
BOOST_CHECK_EQUAL(pipeline->m_hasFinalBlockId, true);
BOOST_CHECK_EQUAL(pipeline->m_segmentInfo.size(), 0);
BOOST_CHECK_EQUAL(face.getNPendingInterests(), 0);
}
BOOST_AUTO_TEST_SUITE_END() // TestPipelineInterestsAimd
BOOST_AUTO_TEST_SUITE_END() // Chunks
} // namespace tests
} // namespace chunks
} // namespace ndn