tests/chunks/rtt-estimator.t.cpp - ndn-tools - Gitiles

 /* -*- 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
  */

 #include "tools/chunks/catchunks/rtt-estimator.hpp"
 #include "tests/test-common.hpp"

 namespace ndn {
 namespace chunks {
 namespace tests {

 class RttEstimatorFixture
 {
 protected:
   RttEstimatorFixture()
     : options(makeRttEstimatorOptions())
     , rttEstimator(options)
   {
   }

 private:
   static RttEstimator::Options
   makeRttEstimatorOptions()
   {
     RttEstimator::Options rttOptions;
     rttOptions.alpha = 0.125;
     rttOptions.beta = 0.25;
     rttOptions.k = 4;
     rttOptions.minRto = Milliseconds(200.0);
     rttOptions.maxRto = Milliseconds(4000.0);
     return rttOptions;
   }

 protected:
   RttEstimator::Options options;
   RttEstimator rttEstimator;
 };

 BOOST_AUTO_TEST_SUITE(Chunks)
 BOOST_FIXTURE_TEST_SUITE(TestRttEstimator, RttEstimatorFixture)

 BOOST_AUTO_TEST_CASE(MinAvgMaxRtt)
 {
   // check initial values
   BOOST_CHECK_CLOSE(rttEstimator.m_rttMin, std::numeric_limits<double>::max(), 0.1);
   BOOST_CHECK_CLOSE(rttEstimator.m_rttAvg, 0.0, 0.1);
   BOOST_CHECK_CLOSE(rttEstimator.m_rttMax, std::numeric_limits<double>::min(), 0.1);
   BOOST_CHECK_EQUAL(rttEstimator.m_nRttSamples, 0);

   // start with three samples
   rttEstimator.addMeasurement(1, Milliseconds(100), 1);
   rttEstimator.addMeasurement(2, Milliseconds(400), 1);
   rttEstimator.addMeasurement(3, Milliseconds(250), 1);

   BOOST_CHECK_CLOSE(rttEstimator.m_rttMin, 100, 0.1);
   BOOST_CHECK_CLOSE(rttEstimator.m_rttAvg, 250, 0.1);
   BOOST_CHECK_CLOSE(rttEstimator.m_rttMax, 400, 0.1);
   BOOST_CHECK_EQUAL(rttEstimator.m_nRttSamples, 3);

   // add another sample (new minimum)
   rttEstimator.addMeasurement(4, Milliseconds(50), 2);
   BOOST_CHECK_CLOSE(rttEstimator.m_rttMin, 50, 0.1);
   BOOST_CHECK_CLOSE(rttEstimator.m_rttAvg, 200, 0.1);
   BOOST_CHECK_CLOSE(rttEstimator.m_rttMax, 400, 0.1);
   BOOST_CHECK_EQUAL(rttEstimator.m_nRttSamples, 4);

   // add another sample (new maximum)
   rttEstimator.addMeasurement(5, Milliseconds(700), 1);
   BOOST_CHECK_CLOSE(rttEstimator.m_rttMin, 50, 0.1);
   BOOST_CHECK_CLOSE(rttEstimator.m_rttAvg, 300, 0.1);
   BOOST_CHECK_CLOSE(rttEstimator.m_rttMax, 700, 0.1);
   BOOST_CHECK_EQUAL(rttEstimator.m_nRttSamples, 5);
 }

 BOOST_AUTO_TEST_CASE(MeasureRtt)
 {
   BOOST_REQUIRE(std::isnan(rttEstimator.m_sRtt.count()));
   BOOST_REQUIRE(std::isnan(rttEstimator.m_rttVar.count()));
   BOOST_REQUIRE_CLOSE(rttEstimator.m_rto.count(), options.initialRto.count(), 1);

   // first measurement
   rttEstimator.addMeasurement(1, Milliseconds(100), 1);

   BOOST_CHECK_CLOSE(rttEstimator.m_sRtt.count(), 100, 0.1);
   BOOST_CHECK_CLOSE(rttEstimator.m_rttVar.count(), 50, 0.1);
   BOOST_CHECK_CLOSE(rttEstimator.m_rto.count(), 300, 0.1);

   rttEstimator.m_sRtt = Milliseconds(500.0);
   rttEstimator.m_rttVar = Milliseconds(100.0);
   rttEstimator.m_rto = Milliseconds(900.0);

   size_t nExpectedSamples = 1;
   rttEstimator.addMeasurement(1, Milliseconds(100), nExpectedSamples);

   BOOST_CHECK_CLOSE(rttEstimator.m_sRtt.count(), 450, 0.1);
   BOOST_CHECK_CLOSE(rttEstimator.m_rttVar.count(), 175, 0.1);
   BOOST_CHECK_CLOSE(rttEstimator.m_rto.count(), 1150, 0.1);

   // expected samples larger than 1
   nExpectedSamples = 5;
   rttEstimator.addMeasurement(1, Milliseconds(100), nExpectedSamples);

   BOOST_CHECK_CLOSE(rttEstimator.m_sRtt.count(), 441.25, 0.1);
   BOOST_CHECK_CLOSE(rttEstimator.m_rttVar.count(), 183.75, 0.1);
   BOOST_CHECK_CLOSE(rttEstimator.m_rto.count(), 1176.25, 0.1);

   rttEstimator.m_sRtt = Milliseconds(100.0);
   rttEstimator.m_rttVar = Milliseconds(30.0);
   rttEstimator.m_rto = Milliseconds(220.0);

   // check if minRto works
   nExpectedSamples = 1;
   rttEstimator.addMeasurement(1, Milliseconds(100), nExpectedSamples);

   BOOST_CHECK_CLOSE(rttEstimator.m_sRtt.count(), 100, 0.1);
   BOOST_CHECK_CLOSE(rttEstimator.m_rttVar.count(), 22.5, 0.1);
   BOOST_CHECK_CLOSE(rttEstimator.m_rto.count(), 200, 0.1);

   rttEstimator.m_sRtt = Milliseconds(2000.0);
   rttEstimator.m_rttVar = Milliseconds(400.0);
   rttEstimator.m_rto = Milliseconds(3600.0);

   // check if maxRto works
   nExpectedSamples = 1;
   rttEstimator.addMeasurement(1, Milliseconds(100), nExpectedSamples);

   BOOST_CHECK_CLOSE(rttEstimator.m_sRtt.count(), 1762.5, 0.1);
   BOOST_CHECK_CLOSE(rttEstimator.m_rttVar.count(), 775, 0.1);
   BOOST_CHECK_CLOSE(rttEstimator.m_rto.count(), 4000, 0.1);
 }

 BOOST_AUTO_TEST_CASE(RtoBackoff)
 {
   rttEstimator.m_rto = Milliseconds(500.0);
   rttEstimator.backoffRto();
   BOOST_CHECK_CLOSE(rttEstimator.m_rto.count(), 1000, 0.1);

   // check if minRto works
   rttEstimator.m_rto = Milliseconds(10.0);
   rttEstimator.backoffRto();
   BOOST_CHECK_CLOSE(rttEstimator.m_rto.count(), 200, 0.1);

   // check if maxRto works
   rttEstimator.m_rto = Milliseconds(3000.0);
   rttEstimator.backoffRto();
   BOOST_CHECK_CLOSE(rttEstimator.m_rto.count(), 4000, 0.1);
 }

 BOOST_AUTO_TEST_SUITE_END() // TestRttEstimator
 BOOST_AUTO_TEST_SUITE_END() // Chunks

 } // namespace tests
 } // namespace chunks
 } // namespace ndn
	/* -- 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
	*/

	#include "tools/chunks/catchunks/rtt-estimator.hpp"
	#include "tests/test-common.hpp"

	namespace ndn {
	namespace chunks {
	namespace tests {

	class RttEstimatorFixture
	{
	protected:
	RttEstimatorFixture()
	: options(makeRttEstimatorOptions())
	, rttEstimator(options)
	{
	}

	private:
	static RttEstimator::Options
	makeRttEstimatorOptions()
	{
	RttEstimator::Options rttOptions;
	rttOptions.alpha = 0.125;
	rttOptions.beta = 0.25;
	rttOptions.k = 4;
	rttOptions.minRto = Milliseconds(200.0);
	rttOptions.maxRto = Milliseconds(4000.0);
	return rttOptions;
	}

	protected:
	RttEstimator::Options options;
	RttEstimator rttEstimator;
	};

	BOOST_AUTO_TEST_SUITE(Chunks)
	BOOST_FIXTURE_TEST_SUITE(TestRttEstimator, RttEstimatorFixture)

	BOOST_AUTO_TEST_CASE(MinAvgMaxRtt)
	{
	// check initial values
	BOOST_CHECK_CLOSE(rttEstimator.m_rttMin, std::numeric_limits<double>::max(), 0.1);
	BOOST_CHECK_CLOSE(rttEstimator.m_rttAvg, 0.0, 0.1);
	BOOST_CHECK_CLOSE(rttEstimator.m_rttMax, std::numeric_limits<double>::min(), 0.1);
	BOOST_CHECK_EQUAL(rttEstimator.m_nRttSamples, 0);

	// start with three samples
	rttEstimator.addMeasurement(1, Milliseconds(100), 1);
	rttEstimator.addMeasurement(2, Milliseconds(400), 1);
	rttEstimator.addMeasurement(3, Milliseconds(250), 1);

	BOOST_CHECK_CLOSE(rttEstimator.m_rttMin, 100, 0.1);
	BOOST_CHECK_CLOSE(rttEstimator.m_rttAvg, 250, 0.1);
	BOOST_CHECK_CLOSE(rttEstimator.m_rttMax, 400, 0.1);
	BOOST_CHECK_EQUAL(rttEstimator.m_nRttSamples, 3);

	// add another sample (new minimum)
	rttEstimator.addMeasurement(4, Milliseconds(50), 2);
	BOOST_CHECK_CLOSE(rttEstimator.m_rttMin, 50, 0.1);
	BOOST_CHECK_CLOSE(rttEstimator.m_rttAvg, 200, 0.1);
	BOOST_CHECK_CLOSE(rttEstimator.m_rttMax, 400, 0.1);
	BOOST_CHECK_EQUAL(rttEstimator.m_nRttSamples, 4);

	// add another sample (new maximum)
	rttEstimator.addMeasurement(5, Milliseconds(700), 1);
	BOOST_CHECK_CLOSE(rttEstimator.m_rttMin, 50, 0.1);
	BOOST_CHECK_CLOSE(rttEstimator.m_rttAvg, 300, 0.1);
	BOOST_CHECK_CLOSE(rttEstimator.m_rttMax, 700, 0.1);
	BOOST_CHECK_EQUAL(rttEstimator.m_nRttSamples, 5);
	}

	BOOST_AUTO_TEST_CASE(MeasureRtt)
	{
	BOOST_REQUIRE(std::isnan(rttEstimator.m_sRtt.count()));
	BOOST_REQUIRE(std::isnan(rttEstimator.m_rttVar.count()));
	BOOST_REQUIRE_CLOSE(rttEstimator.m_rto.count(), options.initialRto.count(), 1);

	// first measurement
	rttEstimator.addMeasurement(1, Milliseconds(100), 1);

	BOOST_CHECK_CLOSE(rttEstimator.m_sRtt.count(), 100, 0.1);
	BOOST_CHECK_CLOSE(rttEstimator.m_rttVar.count(), 50, 0.1);
	BOOST_CHECK_CLOSE(rttEstimator.m_rto.count(), 300, 0.1);

	rttEstimator.m_sRtt = Milliseconds(500.0);
	rttEstimator.m_rttVar = Milliseconds(100.0);
	rttEstimator.m_rto = Milliseconds(900.0);

	size_t nExpectedSamples = 1;
	rttEstimator.addMeasurement(1, Milliseconds(100), nExpectedSamples);

	BOOST_CHECK_CLOSE(rttEstimator.m_sRtt.count(), 450, 0.1);
	BOOST_CHECK_CLOSE(rttEstimator.m_rttVar.count(), 175, 0.1);
	BOOST_CHECK_CLOSE(rttEstimator.m_rto.count(), 1150, 0.1);

	// expected samples larger than 1
	nExpectedSamples = 5;
	rttEstimator.addMeasurement(1, Milliseconds(100), nExpectedSamples);

	BOOST_CHECK_CLOSE(rttEstimator.m_sRtt.count(), 441.25, 0.1);
	BOOST_CHECK_CLOSE(rttEstimator.m_rttVar.count(), 183.75, 0.1);
	BOOST_CHECK_CLOSE(rttEstimator.m_rto.count(), 1176.25, 0.1);

	rttEstimator.m_sRtt = Milliseconds(100.0);
	rttEstimator.m_rttVar = Milliseconds(30.0);
	rttEstimator.m_rto = Milliseconds(220.0);

	// check if minRto works
	nExpectedSamples = 1;
	rttEstimator.addMeasurement(1, Milliseconds(100), nExpectedSamples);

	BOOST_CHECK_CLOSE(rttEstimator.m_sRtt.count(), 100, 0.1);
	BOOST_CHECK_CLOSE(rttEstimator.m_rttVar.count(), 22.5, 0.1);
	BOOST_CHECK_CLOSE(rttEstimator.m_rto.count(), 200, 0.1);

	rttEstimator.m_sRtt = Milliseconds(2000.0);
	rttEstimator.m_rttVar = Milliseconds(400.0);
	rttEstimator.m_rto = Milliseconds(3600.0);

	// check if maxRto works
	nExpectedSamples = 1;
	rttEstimator.addMeasurement(1, Milliseconds(100), nExpectedSamples);

	BOOST_CHECK_CLOSE(rttEstimator.m_sRtt.count(), 1762.5, 0.1);
	BOOST_CHECK_CLOSE(rttEstimator.m_rttVar.count(), 775, 0.1);
	BOOST_CHECK_CLOSE(rttEstimator.m_rto.count(), 4000, 0.1);
	}

	BOOST_AUTO_TEST_CASE(RtoBackoff)
	{
	rttEstimator.m_rto = Milliseconds(500.0);
	rttEstimator.backoffRto();
	BOOST_CHECK_CLOSE(rttEstimator.m_rto.count(), 1000, 0.1);

	// check if minRto works
	rttEstimator.m_rto = Milliseconds(10.0);
	rttEstimator.backoffRto();
	BOOST_CHECK_CLOSE(rttEstimator.m_rto.count(), 200, 0.1);

	// check if maxRto works
	rttEstimator.m_rto = Milliseconds(3000.0);
	rttEstimator.backoffRto();
	BOOST_CHECK_CLOSE(rttEstimator.m_rto.count(), 4000, 0.1);
	}

	BOOST_AUTO_TEST_SUITE_END() // TestRttEstimator
	BOOST_AUTO_TEST_SUITE_END() // Chunks

	} // namespace tests
	} // namespace chunks
	} // namespace ndn