tests/test-nlsr.cpp - NLSR - Gitiles

 /* -*- Mode:C++; c-file-style:"gnu"; indent-tabs-mode:nil; -*- */
 /*
  * Copyright (c) 2014-2023,  The University of Memphis,
  *                           Regents of the University of California,
  *                           Arizona Board of Regents.
  *
  * This file is part of NLSR (Named-data Link State Routing).
  * See AUTHORS.md for complete list of NLSR authors and contributors.
  *
  * NLSR 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.
  *
  * NLSR 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
  * NLSR, e.g., in COPYING.md file.  If not, see <http://www.gnu.org/licenses/>.
  */

 #include "nlsr.hpp"
 #include "logger.hpp"

 #include "tests/io-key-chain-fixture.hpp"
 #include "tests/test-common.hpp"

 #include <ndn-cxx/mgmt/nfd/face-event-notification.hpp>

 namespace nlsr {
 namespace test {

 class MockNfdMgmtFixture : public IoKeyChainFixture
 {
 public:
   /** \brief send one WireEncodable in reply to StatusDataset request
    *  \param prefix dataset prefix without version and segment
    *  \param payload payload block
    *  \note payload must fit in one Data
    *  \pre Interest for dataset has been expressed, sendDataset has not been invoked
    */
   template<typename T>
   void
   sendDataset(const ndn::Name& prefix, const T& payload)
   {
     BOOST_CONCEPT_ASSERT((ndn::WireEncodable<T>));

     this->sendDatasetReply(prefix, payload.wireEncode());
   }

   /** \brief send two WireEncodables in reply to StatusDataset request
    *  \param prefix dataset prefix without version and segment
    *  \param payload1 first vector item
    *  \param payload2 second vector item
    *  \note all payloads must fit in one Data
    *  \pre Interest for dataset has been expressed, sendDataset has not been invoked
    */
   template<typename T1, typename T2>
   void
   sendDataset(const ndn::Name& prefix, const T1& payload1, const T2& payload2)
   {
     BOOST_CONCEPT_ASSERT((ndn::WireEncodable<T1>));
     BOOST_CONCEPT_ASSERT((ndn::WireEncodable<T2>));

     ndn::encoding::EncodingBuffer buffer;
     payload2.wireEncode(buffer);
     payload1.wireEncode(buffer);

     this->sendDatasetReply(prefix, buffer);
   }

   /** \brief send a payload in reply to StatusDataset request
    *  \param name dataset prefix without version and segment
    *  \param contentArgs passed to Data::setContent
    */
   template<typename ...ContentArgs>
   void
   sendDatasetReply(ndn::Name name, ContentArgs&&... contentArgs)
   {
     name.appendVersion().appendSegment(0);

     // These warnings assist in debugging when nfdc does not receive StatusDataset.
     // They usually indicate a misspelled prefix or incorrect timing in the test case.
     if (m_face.sentInterests.empty()) {
       BOOST_WARN_MESSAGE(false, "no Interest expressed");
     }
     else {
       BOOST_WARN_MESSAGE(m_face.sentInterests.back().getName().isPrefixOf(name),
                          "last Interest " << m_face.sentInterests.back().getName() <<
                          " cannot be satisfied by this Data " << name);
     }

     auto data = std::make_shared<ndn::Data>(name);
     data->setFreshnessPeriod(1_s);
     data->setFinalBlock(name[-1]);
     data->setContent(std::forward<ContentArgs>(contentArgs)...);
     signData(*data);
     m_face.receive(*data);
   }

 public:
   ndn::DummyClientFace m_face{m_io, m_keyChain, {true, true}};
 };

 class NlsrFixture : public MockNfdMgmtFixture
 {
 public:
   NlsrFixture()
     : conf(m_face, m_keyChain)
     , confProcessor(conf)
     , nlsr(m_face, m_keyChain, conf)
     , lsdb(nlsr.m_lsdb)
     , neighbors(conf.getAdjacencyList())
     , nSuccessCallbacks(0)
     , nFailureCallbacks(0)
   {
     m_keyChain.createIdentity(conf.getRouterPrefix());
   }

   void
   receiveHelloData(const ndn::Name& sender, const ndn::Name& receiver)
   {
     ndn::Name dataName(sender);
     dataName.append("NLSR")
             .append("INFO")
             .append(ndn::tlv::GenericNameComponent, receiver.wireEncode())
             .appendVersion();

     ndn::Data data(dataName);
     nlsr.m_helloProtocol.onContentValidated(data);
   }

 public:
   ConfParameter conf;
   DummyConfFileProcessor confProcessor;
   Nlsr nlsr;
   Lsdb& lsdb;
   AdjacencyList& neighbors;
   uint32_t nSuccessCallbacks;
   uint32_t nFailureCallbacks;
   ndn::signal::ScopedConnection connection;
 };

 BOOST_FIXTURE_TEST_SUITE(TestNlsr, NlsrFixture)

 BOOST_AUTO_TEST_CASE(HyperbolicOn_ZeroCostNeighbors)
 {
   // Simulate loading configuration file
   Adjacent neighborA("/ndn/neighborA", ndn::FaceUri("udp4://10.0.0.1"), 25,
                      Adjacent::STATUS_INACTIVE, 0, 0);
   neighbors.insert(neighborA);

   Adjacent neighborB("/ndn/neighborB", ndn::FaceUri("udp4://10.0.0.2"), 10,
                      Adjacent::STATUS_INACTIVE, 0, 0);
   neighbors.insert(neighborB);

   Adjacent neighborC("/ndn/neighborC", ndn::FaceUri("udp4://10.0.0.3"), 17,
                      Adjacent::STATUS_INACTIVE, 0, 0);
   neighbors.insert(neighborC);

   conf.setHyperbolicState(HYPERBOLIC_STATE_ON);

   Nlsr nlsr2(m_face, m_keyChain, conf);

   for (const auto& neighbor : neighbors.getAdjList()) {
     BOOST_CHECK_EQUAL(neighbor.getLinkCost(), 0);
   }
 }

 BOOST_AUTO_TEST_CASE(HyperbolicOff_LinkStateCost)
 {
   // Simulate loading configuration file
   Adjacent neighborA("/ndn/neighborA", ndn::FaceUri("udp4://10.0.0.1"), 25,
                      Adjacent::STATUS_INACTIVE, 0, 0);
   neighbors.insert(neighborA);

   Adjacent neighborB("/ndn/neighborB", ndn::FaceUri("udp4://10.0.0.2"), 10,
                      Adjacent::STATUS_INACTIVE, 0, 0);
   neighbors.insert(neighborB);

   Adjacent neighborC("/ndn/neighborC", ndn::FaceUri("udp4://10.0.0.3"), 17,
                      Adjacent::STATUS_INACTIVE, 0, 0);
   neighbors.insert(neighborC);

   Nlsr nlsr2(m_face, m_keyChain, conf);

   for (const auto& neighbor : neighbors.getAdjList()) {
     BOOST_CHECK_NE(neighbor.getLinkCost(), 0);
   }
 }

 BOOST_AUTO_TEST_CASE(SetEventIntervals)
 {
   // Simulate loading configuration file
   conf.setAdjLsaBuildInterval(3);
   conf.setRoutingCalcInterval(9);

   Nlsr nlsr2(m_face, m_keyChain, conf);

   const Lsdb& lsdb = nlsr2.m_lsdb;
   const RoutingTable& rt = nlsr2.m_routingTable;

   BOOST_CHECK_EQUAL(lsdb.m_adjLsaBuildInterval, 3_s);
   BOOST_CHECK_EQUAL(rt.m_routingCalcInterval, 9_s);
 }

 BOOST_AUTO_TEST_CASE(FaceCreateEvent)
 {
   // Setting constants for the unit test
   const uint32_t faceId = 128;
   const std::string faceUri = "udp4://10.0.0.1:6363";

   Adjacent neighbor("/ndn/neighborA", ndn::FaceUri(faceUri), 10,
                     Adjacent::STATUS_INACTIVE, 0, 0);

   BOOST_REQUIRE_EQUAL(conf.getAdjacencyList().insert(neighbor), true);

   this->advanceClocks(10_ms);

   // Build, sign, and send the Face Event
   ndn::nfd::FaceEventNotification event;
   event.setKind(ndn::nfd::FACE_EVENT_CREATED)
     .setRemoteUri(faceUri)
     .setFaceId(faceId);
   auto data = std::make_shared<ndn::Data>(ndn::Name("/localhost/nfd/faces/events").appendSequenceNumber(0));
   data->setFreshnessPeriod(1_s);
   data->setContent(event.wireEncode());
   m_keyChain.sign(*data);
   m_face.receive(*data);

   // Move the clocks forward so that the Face processes the event.
   this->advanceClocks(10_ms);

   // Need to explicitly provide a FaceUri object, because the
   // conversion will attempt to create Name objects.
   auto iterator = conf.getAdjacencyList().findAdjacent(ndn::FaceUri(faceUri));
   BOOST_REQUIRE(iterator != conf.getAdjacencyList().end());
   BOOST_CHECK_EQUAL(iterator->getFaceId(), faceId);
 }

 BOOST_AUTO_TEST_CASE(FaceCreateEventNoMatch)
 {
   // Setting constants for the unit test
   const uint32_t faceId = 128;
   const std::string eventUri = "udp4://10.0.0.1:6363";
   const std::string neighborUri = "udp4://10.0.0.2:6363";

   Adjacent neighbor("/ndn/neighborA", ndn::FaceUri(neighborUri), 10,
                     Adjacent::STATUS_INACTIVE, 0, 0);

   conf.getAdjacencyList().insert(neighbor);

   // Build, sign, and send the Face Event
   ndn::nfd::FaceEventNotification event;
   event.setKind(ndn::nfd::FACE_EVENT_CREATED)
     .setRemoteUri(eventUri)
     .setFaceId(faceId);
   auto data = std::make_shared<ndn::Data>(ndn::Name("/localhost/nfd/faces/events").appendSequenceNumber(0));
   data->setFreshnessPeriod(1_s);
   data->setContent(event.wireEncode());
   m_keyChain.sign(*data);
   m_face.receive(*data);

   // Move the clocks forward so that the Face processes the event.
   this->advanceClocks(10_ms);

   // The Face URIs did not match, so this neighbor should be unconfigured.
   auto iterator = conf.getAdjacencyList().findAdjacent(ndn::FaceUri(neighborUri));
   BOOST_REQUIRE(iterator != conf.getAdjacencyList().end());
   BOOST_CHECK_EQUAL(iterator->getFaceId(), 0);
 }

 BOOST_AUTO_TEST_CASE(FaceCreateEventAlreadyConfigured)
 {
   const uint32_t neighborFaceId = 128;
   const std::string faceUri = "udp4://10.0.0.1:6363";

   Adjacent neighbor("/ndn/neighborA", ndn::FaceUri(faceUri), 10,
                     Adjacent::STATUS_ACTIVE, 0, 0);
   conf.getAdjacencyList().insert(neighbor);

   // Let NLSR start the face monitor
   this->advanceClocks(10_ms);

   // Build, sign, and send the Face Event
   ndn::nfd::FaceEventNotification event;
   event.setKind(ndn::nfd::FACE_EVENT_CREATED)
     .setRemoteUri(faceUri)
     .setFaceId(neighborFaceId);
   auto data = std::make_shared<ndn::Data>(ndn::Name("/localhost/nfd/faces/events").appendSequenceNumber(0));
   data->setFreshnessPeriod(1_s);
   data->setContent(event.wireEncode());
   m_keyChain.sign(*data);
   m_face.receive(*data);

   // Move the clocks forward so that the Face processes the event.
   this->advanceClocks(10_ms);

   auto iterator = conf.getAdjacencyList().findAdjacent(ndn::FaceUri(faceUri));
   BOOST_REQUIRE(iterator != conf.getAdjacencyList().end());
   BOOST_CHECK_EQUAL(iterator->getFaceId(), neighborFaceId);

   // Resend same event notification again
   m_face.sentInterests.clear();
   data->setName(ndn::Name("/localhost/nfd/faces/events").appendSequenceNumber(1));
   m_keyChain.sign(*data);
   m_face.receive(*data);
   this->advanceClocks(10_ms);

   for (const auto& interest : m_face.sentInterests) {
     // Should not re-register prefix since this is the same event notification
     if (ndn::Name("/localhost/nfd/rib/register").isPrefixOf(interest.getName())) {
       BOOST_CHECK(false);
     }
   }
 }

 BOOST_AUTO_TEST_CASE(FaceDestroyEvent)
 {
   // Add active neighbors
   AdjacencyList& neighbors = conf.getAdjacencyList();
   uint64_t destroyFaceId = 128;

   // Create a neighbor whose Face will be destroyed
   Adjacent failNeighbor("/ndn/neighborA", ndn::FaceUri("udp4://10.0.0.1"),
                         10, Adjacent::STATUS_ACTIVE, 0, destroyFaceId);
   neighbors.insert(failNeighbor);

   // Create an additional neighbor so an adjacency LSA can be built after the face is destroyed
   Adjacent otherNeighbor("/ndn/neighborB", ndn::FaceUri("udp4://10.0.0.2"),
                           10, Adjacent::STATUS_ACTIVE, 0, 256);
   neighbors.insert(otherNeighbor);

   // Set HelloInterest lifetime as 10 seconds so that neighbors are not marked INACTIVE
   // upon timeout before this test ends
   conf.setInterestResendTime(10);

   // Simulate successful HELLO responses
   lsdb.scheduleAdjLsaBuild();

   // Set up adjacency LSAs
   // This router
   Adjacent thisRouter(conf.getRouterPrefix(), ndn::FaceUri("udp4://10.0.0.3"),
                       10, Adjacent::STATUS_ACTIVE, 0, 256);

   AdjLsa ownAdjLsa(conf.getRouterPrefix(), 10,
                    ndn::time::system_clock::now(), 1, neighbors);
   lsdb.installLsa(std::make_shared<AdjLsa>(ownAdjLsa));

   // Router that will fail
   AdjacencyList failAdjacencies;
   failAdjacencies.insert(thisRouter);

   AdjLsa failAdjLsa("/ndn/neighborA", 10,
                     ndn::time::system_clock::now() + ndn::time::seconds(3600),
                     1, failAdjacencies);

   lsdb.installLsa(std::make_shared<AdjLsa>(failAdjLsa));

   // Other router
   AdjacencyList otherAdjacencies;
   otherAdjacencies.insert(thisRouter);

   AdjLsa otherAdjLsa("/ndn/neighborB", 10,
                      ndn::time::system_clock::now() + ndn::time::seconds(3600),
                      1, otherAdjacencies);

   lsdb.installLsa(std::make_shared<AdjLsa>(otherAdjLsa));

   // Run the scheduler to build an adjacency LSA
   this->advanceClocks(10_ms);

   // Make sure an adjacency LSA was built
   auto lsa = lsdb.findLsa(conf.getRouterPrefix(), Lsa::Type::ADJACENCY);
   BOOST_REQUIRE(lsa != nullptr);

   uint32_t lastAdjLsaSeqNo = lsa->getSeqNo();
   nlsr.m_lsdb.m_sequencingManager.setAdjLsaSeq(lastAdjLsaSeqNo);

   this->advanceClocks(1500_ms, 10);

   // Make sure the routing table was calculated
   RoutingTableEntry* rtEntry = nlsr.m_routingTable.findRoutingTableEntry(failNeighbor.getName());
   BOOST_REQUIRE(rtEntry != nullptr);
   BOOST_REQUIRE_EQUAL(rtEntry->getNexthopList().size(), 1);

   // Receive FaceEventDestroyed notification
   ndn::nfd::FaceEventNotification event;
   event.setKind(ndn::nfd::FACE_EVENT_DESTROYED)
        .setFaceId(destroyFaceId);

   auto data = std::make_shared<ndn::Data>(ndn::Name("/localhost/nfd/faces/events").appendSequenceNumber(0));
   data->setFreshnessPeriod(1_s);
   data->setContent(event.wireEncode());
   m_keyChain.sign(*data);

   m_face.receive(*data);

   // Run the scheduler to build an adjacency LSA
   this->advanceClocks(10_ms);

   Adjacent updatedNeighbor = neighbors.getAdjacent(failNeighbor.getName());

   BOOST_CHECK_EQUAL(updatedNeighbor.getFaceId(), 0);
   BOOST_CHECK_EQUAL(updatedNeighbor.getInterestTimedOutNo(),
                     conf.getInterestRetryNumber());
   BOOST_CHECK_EQUAL(updatedNeighbor.getStatus(), Adjacent::STATUS_INACTIVE);

   lsa = lsdb.findLsa<AdjLsa>(conf.getRouterPrefix());
   BOOST_REQUIRE(lsa != nullptr);

   BOOST_CHECK_EQUAL(lsa->getSeqNo(), lastAdjLsaSeqNo + 1);

   this->advanceClocks(15_s, 10);

   // Make sure the routing table was recalculated
   rtEntry = nlsr.m_routingTable.findRoutingTableEntry(failNeighbor.getName());
   BOOST_CHECK(rtEntry == nullptr);
 }

 BOOST_AUTO_TEST_CASE(BuildAdjLsaAfterHelloResponse)
 {
   // Configure NLSR
   conf.setAdjLsaBuildInterval(1);

   // Add neighbors
   // Router A
   ndn::Name neighborAName("/ndn/site/%C1.Router/routerA");
   Adjacent neighborA(neighborAName, ndn::FaceUri("udp4://10.0.0.1"),
                      0, Adjacent::STATUS_INACTIVE, 0, 0);
   neighbors.insert(neighborA);

   // Router B
   ndn::Name neighborBName("/ndn/site/%C1.Router/routerB");
   Adjacent neighborB(neighborBName, ndn::FaceUri("udp4://10.0.0.1"),
                      0, Adjacent::STATUS_INACTIVE, 0, 0);

   neighbors.insert(neighborB);

   this->advanceClocks(10_ms);

   // Receive HELLO response from Router A
   receiveHelloData(neighborAName, conf.getRouterPrefix());
   this->advanceClocks(1_s, 10);

   // Adjacency LSA should be built even though other router is INACTIVE
   auto lsa = lsdb.findLsa<AdjLsa>(conf.getRouterPrefix());
   BOOST_REQUIRE(lsa != nullptr);
   BOOST_CHECK_EQUAL(lsa->getAdl().size(), 1);

   // Receive HELLO response from Router B
   receiveHelloData(neighborBName, conf.getRouterPrefix());

   // Both routers become INACTIVE and HELLO Interests have timed out
   for (Adjacent& adjacency : neighbors.getAdjList()) {
     adjacency.setStatus(Adjacent::STATUS_INACTIVE);
     adjacency.setInterestTimedOutNo(HELLO_RETRIES_DEFAULT);
   }

   this->advanceClocks(1_s, 10);

   // Adjacency LSA should have been removed since this router's adjacencies are
   // INACTIVE and have timed out
   lsa = lsdb.findLsa<AdjLsa>(conf.getRouterPrefix());
   BOOST_CHECK(lsa == nullptr);

   // Receive HELLO response from Router A and B
   receiveHelloData(neighborAName, conf.getRouterPrefix());
   receiveHelloData(neighborBName, conf.getRouterPrefix());
   this->advanceClocks(1_s, 10);

   // Adjacency LSA should be built
   lsa = lsdb.findLsa<AdjLsa>(conf.getRouterPrefix());
   BOOST_REQUIRE(lsa != nullptr);
   BOOST_CHECK_EQUAL(lsa->getAdl().size(), 2);
 }

 BOOST_AUTO_TEST_CASE(FaceDatasetFetchSuccess)
 {
   bool hasResult = false;

   nlsr.initializeFaces([&hasResult] (const std::vector<ndn::nfd::FaceStatus>& faces) {
       hasResult = true;
       BOOST_CHECK_EQUAL(faces.size(), 2);
       BOOST_CHECK_EQUAL(faces.front().getFaceId(), 25401);
       BOOST_CHECK_EQUAL(faces.back().getFaceId(), 25402);
     },
     [] (uint32_t code, const std::string& reason) {});

   this->advanceClocks(100_ms, 5);

   ndn::nfd::FaceStatus payload1;
   payload1.setFaceId(25401);
   ndn::nfd::FaceStatus payload2;
   payload2.setFaceId(25402);
   this->sendDataset("/localhost/nfd/faces/list", payload1, payload2);

   this->advanceClocks(100_ms, 5);
   BOOST_CHECK(hasResult);
 }

 BOOST_AUTO_TEST_CASE(FaceDatasetFetchFailure)
 {
   nlsr.initializeFaces([](const std::vector<ndn::nfd::FaceStatus>& faces) {},
     [this](uint32_t code, const std::string& reason){
       this->nFailureCallbacks++;
     });
   this->advanceClocks(100_ms, 5);

   ndn::Name payload;
   this->sendDataset("/localhost/nfd/faces/list", payload);
   this->advanceClocks(100_ms, 5);

   BOOST_CHECK_EQUAL(nFailureCallbacks, 1);
   BOOST_CHECK_EQUAL(nSuccessCallbacks, 0);
 }

 BOOST_AUTO_TEST_CASE(FaceDatasetProcess)
 {
   Adjacent neighborA("/ndn/neighborA", ndn::FaceUri("udp4://192.168.0.100:6363"),
                      25, Adjacent::STATUS_INACTIVE, 0, 0);
   neighbors.insert(neighborA);

   Adjacent neighborB("/ndn/neighborB", ndn::FaceUri("udp4://192.168.0.101:6363"),
                      10, Adjacent::STATUS_INACTIVE, 0, 0);
   neighbors.insert(neighborB);

   ndn::nfd::FaceStatus payload1;
   payload1.setFaceId(1)
     .setRemoteUri("udp4://192.168.0.100:6363");
   ndn::nfd::FaceStatus payload2;
   payload2.setFaceId(2)
     .setRemoteUri("udp4://192.168.0.101:6363");
   std::vector<ndn::nfd::FaceStatus> faceStatuses = {payload1, payload2};

   nlsr.processFaceDataset(faceStatuses);

   AdjacencyList adjList = conf.getAdjacencyList();

   BOOST_CHECK_EQUAL(adjList.getAdjacent("/ndn/neighborA").getFaceId(), payload1.getFaceId());
   BOOST_CHECK_EQUAL(adjList.getAdjacent("/ndn/neighborB").getFaceId(), payload2.getFaceId());
 }

 BOOST_AUTO_TEST_CASE(UnconfiguredNeighbor)
 {
   Adjacent neighborA("/ndn/neighborA", ndn::FaceUri("udp4://192.168.0.100:6363"), 25, Adjacent::STATUS_INACTIVE, 0, 0);
   neighbors.insert(neighborA);

   ndn::nfd::FaceStatus payload;
   payload.setFaceId(1)
     .setRemoteUri("udp4://192.168.0.101:6363"); // Note dissimilar Face URI.
   std::vector<ndn::nfd::FaceStatus> faceStatuses = {payload};

   nlsr.processFaceDataset(faceStatuses);
   this->advanceClocks(20_ms, 5);

   AdjacencyList adjList = conf.getAdjacencyList();

   BOOST_CHECK_EQUAL(adjList.getAdjacent("/ndn/neighborA").getFaceId(), 0);
 }

 BOOST_AUTO_TEST_CASE(FaceDatasetPeriodicFetch)
 {
   int nNameMatches = 0;
   ndn::Name datasetPrefix("/localhost/nfd/faces/list");
   ndn::nfd::CommandOptions options;
   ndn::time::milliseconds defaultTimeout = options.getTimeout();

   int fetchInterval(1);
   conf.setFaceDatasetFetchInterval(fetchInterval);
   conf.setFaceDatasetFetchTries(0);

   // Elapse the default timeout time of the interest.
   this->advanceClocks(defaultTimeout);

   // Check that we have one interest for face list in the sent interests.
   for (const auto& interest : m_face.sentInterests) {
     if (datasetPrefix.isPrefixOf(interest.getName())) {
       nNameMatches++;
     }
   }
   BOOST_CHECK_EQUAL(nNameMatches, 1);

   // Elapse the clock by the reschedule time (that we set)
   this->advanceClocks(ndn::time::seconds(fetchInterval));
   // Elapse the default timeout on the interest.
   this->advanceClocks(defaultTimeout);

   // Check that we now have two interests
   nNameMatches = 0;
   for (const auto& interest : m_face.sentInterests) {
     if (datasetPrefix.isPrefixOf(interest.getName())) {
       nNameMatches++;
     }
   }
   BOOST_CHECK_EQUAL(nNameMatches, 2);
 }

 BOOST_AUTO_TEST_SUITE_END()

 } // namespace test
 } // namespace nlsr
	/* -- Mode:C++; c-file-style:"gnu"; indent-tabs-mode:nil; -- */
	/*
	* Copyright (c) 2014-2023, The University of Memphis,
	* Regents of the University of California,
	* Arizona Board of Regents.
	*
	* This file is part of NLSR (Named-data Link State Routing).
	* See AUTHORS.md for complete list of NLSR authors and contributors.
	*
	* NLSR 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.
	*
	* NLSR 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
	* NLSR, e.g., in COPYING.md file. If not, see <http://www.gnu.org/licenses/>.
	*/

	#include "nlsr.hpp"
	#include "logger.hpp"

	#include "tests/io-key-chain-fixture.hpp"
	#include "tests/test-common.hpp"

	#include <ndn-cxx/mgmt/nfd/face-event-notification.hpp>

	namespace nlsr {
	namespace test {

	class MockNfdMgmtFixture : public IoKeyChainFixture
	{
	public:
	/** \brief send one WireEncodable in reply to StatusDataset request
	* \param prefix dataset prefix without version and segment
	* \param payload payload block
	* \note payload must fit in one Data
	* \pre Interest for dataset has been expressed, sendDataset has not been invoked
	*/
	template<typename T>
	void
	sendDataset(const ndn::Name& prefix, const T& payload)
	{
	BOOST_CONCEPT_ASSERT((ndn::WireEncodable<T>));

	this->sendDatasetReply(prefix, payload.wireEncode());
	}

	/** \brief send two WireEncodables in reply to StatusDataset request
	* \param prefix dataset prefix without version and segment
	* \param payload1 first vector item
	* \param payload2 second vector item
	* \note all payloads must fit in one Data
	* \pre Interest for dataset has been expressed, sendDataset has not been invoked
	*/
	template<typename T1, typename T2>
	void
	sendDataset(const ndn::Name& prefix, const T1& payload1, const T2& payload2)
	{
	BOOST_CONCEPT_ASSERT((ndn::WireEncodable<T1>));
	BOOST_CONCEPT_ASSERT((ndn::WireEncodable<T2>));

	ndn::encoding::EncodingBuffer buffer;
	payload2.wireEncode(buffer);
	payload1.wireEncode(buffer);

	this->sendDatasetReply(prefix, buffer);
	}

	/** \brief send a payload in reply to StatusDataset request
	* \param name dataset prefix without version and segment
	* \param contentArgs passed to Data::setContent
	*/
	template<typename ...ContentArgs>
	void
	sendDatasetReply(ndn::Name name, ContentArgs&&... contentArgs)
	{
	name.appendVersion().appendSegment(0);

	// These warnings assist in debugging when nfdc does not receive StatusDataset.
	// They usually indicate a misspelled prefix or incorrect timing in the test case.
	if (m_face.sentInterests.empty()) {
	BOOST_WARN_MESSAGE(false, "no Interest expressed");
	}
	else {
	BOOST_WARN_MESSAGE(m_face.sentInterests.back().getName().isPrefixOf(name),
	"last Interest " << m_face.sentInterests.back().getName() <<
	" cannot be satisfied by this Data " << name);
	}

	auto data = std::make_shared<ndn::Data>(name);
	data->setFreshnessPeriod(1_s);
	data->setFinalBlock(name[-1]);
	data->setContent(std::forward<ContentArgs>(contentArgs)...);
	signData(*data);
	m_face.receive(*data);
	}

	public:
	ndn::DummyClientFace m_face{m_io, m_keyChain, {true, true}};
	};

	class NlsrFixture : public MockNfdMgmtFixture
	{
	public:
	NlsrFixture()
	: conf(m_face, m_keyChain)
	, confProcessor(conf)
	, nlsr(m_face, m_keyChain, conf)
	, lsdb(nlsr.m_lsdb)
	, neighbors(conf.getAdjacencyList())
	, nSuccessCallbacks(0)
	, nFailureCallbacks(0)
	{
	m_keyChain.createIdentity(conf.getRouterPrefix());
	}

	void
	receiveHelloData(const ndn::Name& sender, const ndn::Name& receiver)
	{
	ndn::Name dataName(sender);
	dataName.append("NLSR")
	.append("INFO")
	.append(ndn::tlv::GenericNameComponent, receiver.wireEncode())
	.appendVersion();

	ndn::Data data(dataName);
	nlsr.m_helloProtocol.onContentValidated(data);
	}

	public:
	ConfParameter conf;
	DummyConfFileProcessor confProcessor;
	Nlsr nlsr;
	Lsdb& lsdb;
	AdjacencyList& neighbors;
	uint32_t nSuccessCallbacks;
	uint32_t nFailureCallbacks;
	ndn::signal::ScopedConnection connection;
	};

	BOOST_FIXTURE_TEST_SUITE(TestNlsr, NlsrFixture)

	BOOST_AUTO_TEST_CASE(HyperbolicOn_ZeroCostNeighbors)
	{
	// Simulate loading configuration file
	Adjacent neighborA("/ndn/neighborA", ndn::FaceUri("udp4://10.0.0.1"), 25,
	Adjacent::STATUS_INACTIVE, 0, 0);
	neighbors.insert(neighborA);

	Adjacent neighborB("/ndn/neighborB", ndn::FaceUri("udp4://10.0.0.2"), 10,
	Adjacent::STATUS_INACTIVE, 0, 0);
	neighbors.insert(neighborB);

	Adjacent neighborC("/ndn/neighborC", ndn::FaceUri("udp4://10.0.0.3"), 17,
	Adjacent::STATUS_INACTIVE, 0, 0);
	neighbors.insert(neighborC);

	conf.setHyperbolicState(HYPERBOLIC_STATE_ON);

	Nlsr nlsr2(m_face, m_keyChain, conf);

	for (const auto& neighbor : neighbors.getAdjList()) {
	BOOST_CHECK_EQUAL(neighbor.getLinkCost(), 0);
	}
	}

	BOOST_AUTO_TEST_CASE(HyperbolicOff_LinkStateCost)
	{
	// Simulate loading configuration file
	Adjacent neighborA("/ndn/neighborA", ndn::FaceUri("udp4://10.0.0.1"), 25,
	Adjacent::STATUS_INACTIVE, 0, 0);
	neighbors.insert(neighborA);

	Adjacent neighborB("/ndn/neighborB", ndn::FaceUri("udp4://10.0.0.2"), 10,
	Adjacent::STATUS_INACTIVE, 0, 0);
	neighbors.insert(neighborB);

	Adjacent neighborC("/ndn/neighborC", ndn::FaceUri("udp4://10.0.0.3"), 17,
	Adjacent::STATUS_INACTIVE, 0, 0);
	neighbors.insert(neighborC);

	Nlsr nlsr2(m_face, m_keyChain, conf);

	for (const auto& neighbor : neighbors.getAdjList()) {
	BOOST_CHECK_NE(neighbor.getLinkCost(), 0);
	}
	}

	BOOST_AUTO_TEST_CASE(SetEventIntervals)
	{
	// Simulate loading configuration file
	conf.setAdjLsaBuildInterval(3);
	conf.setRoutingCalcInterval(9);

	Nlsr nlsr2(m_face, m_keyChain, conf);

	const Lsdb& lsdb = nlsr2.m_lsdb;
	const RoutingTable& rt = nlsr2.m_routingTable;

	BOOST_CHECK_EQUAL(lsdb.m_adjLsaBuildInterval, 3_s);
	BOOST_CHECK_EQUAL(rt.m_routingCalcInterval, 9_s);
	}

	BOOST_AUTO_TEST_CASE(FaceCreateEvent)
	{
	// Setting constants for the unit test
	const uint32_t faceId = 128;
	const std::string faceUri = "udp4://10.0.0.1:6363";

	Adjacent neighbor("/ndn/neighborA", ndn::FaceUri(faceUri), 10,
	Adjacent::STATUS_INACTIVE, 0, 0);

	BOOST_REQUIRE_EQUAL(conf.getAdjacencyList().insert(neighbor), true);

	this->advanceClocks(10_ms);

	// Build, sign, and send the Face Event
	ndn::nfd::FaceEventNotification event;
	event.setKind(ndn::nfd::FACE_EVENT_CREATED)
	.setRemoteUri(faceUri)
	.setFaceId(faceId);
	auto data = std::make_shared<ndn::Data>(ndn::Name("/localhost/nfd/faces/events").appendSequenceNumber(0));
	data->setFreshnessPeriod(1_s);
	data->setContent(event.wireEncode());
	m_keyChain.sign(*data);
	m_face.receive(*data);

	// Move the clocks forward so that the Face processes the event.
	this->advanceClocks(10_ms);

	// Need to explicitly provide a FaceUri object, because the
	// conversion will attempt to create Name objects.
	auto iterator = conf.getAdjacencyList().findAdjacent(ndn::FaceUri(faceUri));
	BOOST_REQUIRE(iterator != conf.getAdjacencyList().end());
	BOOST_CHECK_EQUAL(iterator->getFaceId(), faceId);
	}

	BOOST_AUTO_TEST_CASE(FaceCreateEventNoMatch)
	{
	// Setting constants for the unit test
	const uint32_t faceId = 128;
	const std::string eventUri = "udp4://10.0.0.1:6363";
	const std::string neighborUri = "udp4://10.0.0.2:6363";

	Adjacent neighbor("/ndn/neighborA", ndn::FaceUri(neighborUri), 10,
	Adjacent::STATUS_INACTIVE, 0, 0);

	conf.getAdjacencyList().insert(neighbor);

	// Build, sign, and send the Face Event
	ndn::nfd::FaceEventNotification event;
	event.setKind(ndn::nfd::FACE_EVENT_CREATED)
	.setRemoteUri(eventUri)
	.setFaceId(faceId);
	auto data = std::make_shared<ndn::Data>(ndn::Name("/localhost/nfd/faces/events").appendSequenceNumber(0));
	data->setFreshnessPeriod(1_s);
	data->setContent(event.wireEncode());
	m_keyChain.sign(*data);
	m_face.receive(*data);

	// Move the clocks forward so that the Face processes the event.
	this->advanceClocks(10_ms);

	// The Face URIs did not match, so this neighbor should be unconfigured.
	auto iterator = conf.getAdjacencyList().findAdjacent(ndn::FaceUri(neighborUri));
	BOOST_REQUIRE(iterator != conf.getAdjacencyList().end());
	BOOST_CHECK_EQUAL(iterator->getFaceId(), 0);
	}

	BOOST_AUTO_TEST_CASE(FaceCreateEventAlreadyConfigured)
	{
	const uint32_t neighborFaceId = 128;
	const std::string faceUri = "udp4://10.0.0.1:6363";

	Adjacent neighbor("/ndn/neighborA", ndn::FaceUri(faceUri), 10,
	Adjacent::STATUS_ACTIVE, 0, 0);
	conf.getAdjacencyList().insert(neighbor);

	// Let NLSR start the face monitor
	this->advanceClocks(10_ms);

	// Build, sign, and send the Face Event
	ndn::nfd::FaceEventNotification event;
	event.setKind(ndn::nfd::FACE_EVENT_CREATED)
	.setRemoteUri(faceUri)
	.setFaceId(neighborFaceId);
	auto data = std::make_shared<ndn::Data>(ndn::Name("/localhost/nfd/faces/events").appendSequenceNumber(0));
	data->setFreshnessPeriod(1_s);
	data->setContent(event.wireEncode());
	m_keyChain.sign(*data);
	m_face.receive(*data);

	// Move the clocks forward so that the Face processes the event.
	this->advanceClocks(10_ms);

	auto iterator = conf.getAdjacencyList().findAdjacent(ndn::FaceUri(faceUri));
	BOOST_REQUIRE(iterator != conf.getAdjacencyList().end());
	BOOST_CHECK_EQUAL(iterator->getFaceId(), neighborFaceId);

	// Resend same event notification again
	m_face.sentInterests.clear();
	data->setName(ndn::Name("/localhost/nfd/faces/events").appendSequenceNumber(1));
	m_keyChain.sign(*data);
	m_face.receive(*data);
	this->advanceClocks(10_ms);

	for (const auto& interest : m_face.sentInterests) {
	// Should not re-register prefix since this is the same event notification
	if (ndn::Name("/localhost/nfd/rib/register").isPrefixOf(interest.getName())) {
	BOOST_CHECK(false);
	}
	}
	}

	BOOST_AUTO_TEST_CASE(FaceDestroyEvent)
	{
	// Add active neighbors
	AdjacencyList& neighbors = conf.getAdjacencyList();
	uint64_t destroyFaceId = 128;

	// Create a neighbor whose Face will be destroyed
	Adjacent failNeighbor("/ndn/neighborA", ndn::FaceUri("udp4://10.0.0.1"),
	10, Adjacent::STATUS_ACTIVE, 0, destroyFaceId);
	neighbors.insert(failNeighbor);

	// Create an additional neighbor so an adjacency LSA can be built after the face is destroyed
	Adjacent otherNeighbor("/ndn/neighborB", ndn::FaceUri("udp4://10.0.0.2"),
	10, Adjacent::STATUS_ACTIVE, 0, 256);
	neighbors.insert(otherNeighbor);

	// Set HelloInterest lifetime as 10 seconds so that neighbors are not marked INACTIVE
	// upon timeout before this test ends
	conf.setInterestResendTime(10);

	// Simulate successful HELLO responses
	lsdb.scheduleAdjLsaBuild();

	// Set up adjacency LSAs
	// This router
	Adjacent thisRouter(conf.getRouterPrefix(), ndn::FaceUri("udp4://10.0.0.3"),
	10, Adjacent::STATUS_ACTIVE, 0, 256);

	AdjLsa ownAdjLsa(conf.getRouterPrefix(), 10,
	ndn::time::system_clock::now(), 1, neighbors);
	lsdb.installLsa(std::make_shared<AdjLsa>(ownAdjLsa));

	// Router that will fail
	AdjacencyList failAdjacencies;
	failAdjacencies.insert(thisRouter);

	AdjLsa failAdjLsa("/ndn/neighborA", 10,
	ndn::time::system_clock::now() + ndn::time::seconds(3600),
	1, failAdjacencies);

	lsdb.installLsa(std::make_shared<AdjLsa>(failAdjLsa));

	// Other router
	AdjacencyList otherAdjacencies;
	otherAdjacencies.insert(thisRouter);

	AdjLsa otherAdjLsa("/ndn/neighborB", 10,
	ndn::time::system_clock::now() + ndn::time::seconds(3600),
	1, otherAdjacencies);

	lsdb.installLsa(std::make_shared<AdjLsa>(otherAdjLsa));

	// Run the scheduler to build an adjacency LSA
	this->advanceClocks(10_ms);

	// Make sure an adjacency LSA was built
	auto lsa = lsdb.findLsa(conf.getRouterPrefix(), Lsa::Type::ADJACENCY);
	BOOST_REQUIRE(lsa != nullptr);

	uint32_t lastAdjLsaSeqNo = lsa->getSeqNo();
	nlsr.m_lsdb.m_sequencingManager.setAdjLsaSeq(lastAdjLsaSeqNo);

	this->advanceClocks(1500_ms, 10);

	// Make sure the routing table was calculated
	RoutingTableEntry* rtEntry = nlsr.m_routingTable.findRoutingTableEntry(failNeighbor.getName());
	BOOST_REQUIRE(rtEntry != nullptr);
	BOOST_REQUIRE_EQUAL(rtEntry->getNexthopList().size(), 1);

	// Receive FaceEventDestroyed notification
	ndn::nfd::FaceEventNotification event;
	event.setKind(ndn::nfd::FACE_EVENT_DESTROYED)
	.setFaceId(destroyFaceId);

	auto data = std::make_shared<ndn::Data>(ndn::Name("/localhost/nfd/faces/events").appendSequenceNumber(0));
	data->setFreshnessPeriod(1_s);
	data->setContent(event.wireEncode());
	m_keyChain.sign(*data);

	m_face.receive(*data);

	// Run the scheduler to build an adjacency LSA
	this->advanceClocks(10_ms);

	Adjacent updatedNeighbor = neighbors.getAdjacent(failNeighbor.getName());

	BOOST_CHECK_EQUAL(updatedNeighbor.getFaceId(), 0);
	BOOST_CHECK_EQUAL(updatedNeighbor.getInterestTimedOutNo(),
	conf.getInterestRetryNumber());
	BOOST_CHECK_EQUAL(updatedNeighbor.getStatus(), Adjacent::STATUS_INACTIVE);

	lsa = lsdb.findLsa<AdjLsa>(conf.getRouterPrefix());
	BOOST_REQUIRE(lsa != nullptr);

	BOOST_CHECK_EQUAL(lsa->getSeqNo(), lastAdjLsaSeqNo + 1);

	this->advanceClocks(15_s, 10);

	// Make sure the routing table was recalculated
	rtEntry = nlsr.m_routingTable.findRoutingTableEntry(failNeighbor.getName());
	BOOST_CHECK(rtEntry == nullptr);
	}

	BOOST_AUTO_TEST_CASE(BuildAdjLsaAfterHelloResponse)
	{
	// Configure NLSR
	conf.setAdjLsaBuildInterval(1);

	// Add neighbors
	// Router A
	ndn::Name neighborAName("/ndn/site/%C1.Router/routerA");
	Adjacent neighborA(neighborAName, ndn::FaceUri("udp4://10.0.0.1"),
	0, Adjacent::STATUS_INACTIVE, 0, 0);
	neighbors.insert(neighborA);

	// Router B
	ndn::Name neighborBName("/ndn/site/%C1.Router/routerB");
	Adjacent neighborB(neighborBName, ndn::FaceUri("udp4://10.0.0.1"),
	0, Adjacent::STATUS_INACTIVE, 0, 0);

	neighbors.insert(neighborB);

	this->advanceClocks(10_ms);

	// Receive HELLO response from Router A
	receiveHelloData(neighborAName, conf.getRouterPrefix());
	this->advanceClocks(1_s, 10);

	// Adjacency LSA should be built even though other router is INACTIVE
	auto lsa = lsdb.findLsa<AdjLsa>(conf.getRouterPrefix());
	BOOST_REQUIRE(lsa != nullptr);
	BOOST_CHECK_EQUAL(lsa->getAdl().size(), 1);

	// Receive HELLO response from Router B
	receiveHelloData(neighborBName, conf.getRouterPrefix());

	// Both routers become INACTIVE and HELLO Interests have timed out
	for (Adjacent& adjacency : neighbors.getAdjList()) {
	adjacency.setStatus(Adjacent::STATUS_INACTIVE);
	adjacency.setInterestTimedOutNo(HELLO_RETRIES_DEFAULT);
	}

	this->advanceClocks(1_s, 10);

	// Adjacency LSA should have been removed since this router's adjacencies are
	// INACTIVE and have timed out
	lsa = lsdb.findLsa<AdjLsa>(conf.getRouterPrefix());
	BOOST_CHECK(lsa == nullptr);

	// Receive HELLO response from Router A and B
	receiveHelloData(neighborAName, conf.getRouterPrefix());
	receiveHelloData(neighborBName, conf.getRouterPrefix());
	this->advanceClocks(1_s, 10);

	// Adjacency LSA should be built
	lsa = lsdb.findLsa<AdjLsa>(conf.getRouterPrefix());
	BOOST_REQUIRE(lsa != nullptr);
	BOOST_CHECK_EQUAL(lsa->getAdl().size(), 2);
	}

	BOOST_AUTO_TEST_CASE(FaceDatasetFetchSuccess)
	{
	bool hasResult = false;

	nlsr.initializeFaces([&hasResult] (const std::vector<ndn::nfd::FaceStatus>& faces) {
	hasResult = true;
	BOOST_CHECK_EQUAL(faces.size(), 2);
	BOOST_CHECK_EQUAL(faces.front().getFaceId(), 25401);
	BOOST_CHECK_EQUAL(faces.back().getFaceId(), 25402);
	},
	[] (uint32_t code, const std::string& reason) {});

	this->advanceClocks(100_ms, 5);

	ndn::nfd::FaceStatus payload1;
	payload1.setFaceId(25401);
	ndn::nfd::FaceStatus payload2;
	payload2.setFaceId(25402);
	this->sendDataset("/localhost/nfd/faces/list", payload1, payload2);

	this->advanceClocks(100_ms, 5);
	BOOST_CHECK(hasResult);
	}

	BOOST_AUTO_TEST_CASE(FaceDatasetFetchFailure)
	{
	nlsr.initializeFaces([](const std::vector<ndn::nfd::FaceStatus>& faces) {},
	[this](uint32_t code, const std::string& reason){
	this->nFailureCallbacks++;
	});
	this->advanceClocks(100_ms, 5);

	ndn::Name payload;
	this->sendDataset("/localhost/nfd/faces/list", payload);
	this->advanceClocks(100_ms, 5);

	BOOST_CHECK_EQUAL(nFailureCallbacks, 1);
	BOOST_CHECK_EQUAL(nSuccessCallbacks, 0);
	}

	BOOST_AUTO_TEST_CASE(FaceDatasetProcess)
	{
	Adjacent neighborA("/ndn/neighborA", ndn::FaceUri("udp4://192.168.0.100:6363"),
	25, Adjacent::STATUS_INACTIVE, 0, 0);
	neighbors.insert(neighborA);

	Adjacent neighborB("/ndn/neighborB", ndn::FaceUri("udp4://192.168.0.101:6363"),
	10, Adjacent::STATUS_INACTIVE, 0, 0);
	neighbors.insert(neighborB);

	ndn::nfd::FaceStatus payload1;
	payload1.setFaceId(1)
	.setRemoteUri("udp4://192.168.0.100:6363");
	ndn::nfd::FaceStatus payload2;
	payload2.setFaceId(2)
	.setRemoteUri("udp4://192.168.0.101:6363");
	std::vector<ndn::nfd::FaceStatus> faceStatuses = {payload1, payload2};

	nlsr.processFaceDataset(faceStatuses);

	AdjacencyList adjList = conf.getAdjacencyList();

	BOOST_CHECK_EQUAL(adjList.getAdjacent("/ndn/neighborA").getFaceId(), payload1.getFaceId());
	BOOST_CHECK_EQUAL(adjList.getAdjacent("/ndn/neighborB").getFaceId(), payload2.getFaceId());
	}

	BOOST_AUTO_TEST_CASE(UnconfiguredNeighbor)
	{
	Adjacent neighborA("/ndn/neighborA", ndn::FaceUri("udp4://192.168.0.100:6363"), 25, Adjacent::STATUS_INACTIVE, 0, 0);
	neighbors.insert(neighborA);

	ndn::nfd::FaceStatus payload;
	payload.setFaceId(1)
	.setRemoteUri("udp4://192.168.0.101:6363"); // Note dissimilar Face URI.
	std::vector<ndn::nfd::FaceStatus> faceStatuses = {payload};

	nlsr.processFaceDataset(faceStatuses);
	this->advanceClocks(20_ms, 5);

	AdjacencyList adjList = conf.getAdjacencyList();

	BOOST_CHECK_EQUAL(adjList.getAdjacent("/ndn/neighborA").getFaceId(), 0);
	}

	BOOST_AUTO_TEST_CASE(FaceDatasetPeriodicFetch)
	{
	int nNameMatches = 0;
	ndn::Name datasetPrefix("/localhost/nfd/faces/list");
	ndn::nfd::CommandOptions options;
	ndn::time::milliseconds defaultTimeout = options.getTimeout();

	int fetchInterval(1);
	conf.setFaceDatasetFetchInterval(fetchInterval);
	conf.setFaceDatasetFetchTries(0);

	// Elapse the default timeout time of the interest.
	this->advanceClocks(defaultTimeout);

	// Check that we have one interest for face list in the sent interests.
	for (const auto& interest : m_face.sentInterests) {
	if (datasetPrefix.isPrefixOf(interest.getName())) {
	nNameMatches++;
	}
	}
	BOOST_CHECK_EQUAL(nNameMatches, 1);

	// Elapse the clock by the reschedule time (that we set)
	this->advanceClocks(ndn::time::seconds(fetchInterval));
	// Elapse the default timeout on the interest.
	this->advanceClocks(defaultTimeout);

	// Check that we now have two interests
	nNameMatches = 0;
	for (const auto& interest : m_face.sentInterests) {
	if (datasetPrefix.isPrefixOf(interest.getName())) {
	nNameMatches++;
	}
	}
	BOOST_CHECK_EQUAL(nNameMatches, 2);
	}

	BOOST_AUTO_TEST_SUITE_END()

	} // namespace test
	} // namespace nlsr