src/transport/tests/TestSecureSessionTable.cpp - third_party/github/project-chip/connectedhomeip - Git at Google

 /*
  *
  *    Copyright (c) 2020-2021 Project CHIP Authors
  *    All rights reserved.
  *
  *    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.
  */

 /**
  *    @file
  *      This file implements unit tests for the SessionManager implementation.
  */

 #include "system/SystemClock.h"
 #include <lib/core/CHIPCore.h>
 #include <lib/support/CodeUtils.h>
 #include <lib/support/UnitTestRegistration.h>
 #include <transport/SecureSessionTable.h>
 #include <transport/SessionHolder.h>

 #include <nlbyteorder.h>
 #include <nlunit-test.h>

 #include <errno.h>
 #include <vector>

 namespace chip {
 namespace Transport {

 class TestSecureSessionTable
 {
 public:
     //
     // This test specifically validates eviction of sessions in the session table
     // with various scenarios based on the existing set of sessions in the table
     // and a provided session eviction hint
     //
     static void ValidateSessionSorting(nlTestSuite * inSuite, void * inContext);

 private:
     struct SessionParameters
     {
         ScopedNodeId mPeer;
         System::Clock::Timestamp mLastActivityTime;
         SecureSession::State mState;
     };

     //
     // This listener lets us track which sessions get evicted by
     // using a SessionHolderWithDelegate to get notified on session release.
     //
     class SessionNotificationListener : public SessionDelegate
     {
     public:
         SessionNotificationListener(const SessionHandle & session) : mSessionHolder(*this) { mSessionHolder.Grab(session); }

         void OnSessionReleased() { mSessionReleased = true; }

         NewSessionHandlingPolicy GetNewSessionHandlingPolicy() { return NewSessionHandlingPolicy::kStayAtOldSession; }

         SessionHolderWithDelegate mSessionHolder;
         bool mSessionReleased = false;
     };

     static constexpr FabricIndex kFabric1 = 1;
     static constexpr FabricIndex kFabric2 = 2;
     static constexpr FabricIndex kFabric3 = 3;

     //
     // Allocates a new secure session given an eviction hint. The session that was evicted is compared against the provided
     // evictedSessionIndex (which indexes into the provided SessionParameter table) to validate that it matches.
     //
     void AllocateSession(const ScopedNodeId & sessionEvictionHint, std::vector<SessionParameters> & sessionParameters,
                          uint16_t evictedSessionIndex);

     //
     // Reset our internal SecureSessionTable list and create a new one given the provided parameters.
     //
     void CreateSessionTable(std::vector<SessionParameters> & sessionParams);

     nlTestSuite * mTestSuite;
     Platform::UniquePtr<SecureSessionTable> mSessionTable;
     std::vector<Platform::UniquePtr<SessionNotificationListener>> mSessionList;
 };

 void TestSecureSessionTable::AllocateSession(const ScopedNodeId & sessionEvictionHint,
                                              std::vector<SessionParameters> & sessionParameters, uint16_t evictedSessionIndex)
 {
     auto session = mSessionTable->CreateNewSecureSession(SecureSession::Type::kCASE, sessionEvictionHint);
     NL_TEST_ASSERT(mTestSuite, session.HasValue());
     NL_TEST_ASSERT(mTestSuite, mSessionList[evictedSessionIndex].get()->mSessionReleased == true);
 }

 void TestSecureSessionTable::CreateSessionTable(std::vector<SessionParameters> & sessionParams)
 {
     mSessionList.clear();

     mSessionTable = Platform::MakeUnique<SecureSessionTable>();
     NL_TEST_ASSERT(mTestSuite, mSessionTable.get() != nullptr);

     mSessionTable->Init();
     mSessionTable->SetMaxSessionTableSize(static_cast<uint32_t>(sessionParams.size()));

     for (unsigned int i = 0; i < sessionParams.size(); i++)
     {
         auto session = mSessionTable->CreateNewSecureSession(SecureSession::Type::kCASE, ScopedNodeId());
         NL_TEST_ASSERT(mTestSuite, session.HasValue());

         session.Value()->AsSecureSession()->Activate(
             ScopedNodeId(1, sessionParams[i].mPeer.GetFabricIndex()), sessionParams[i].mPeer, CATValues(), static_cast<uint16_t>(i),
             ReliableMessageProtocolConfig(System::Clock::Milliseconds32(0), System::Clock::Milliseconds32(0)));
         session.Value()->AsSecureSession()->mLastActivityTime = sessionParams[i].mLastActivityTime;
         session.Value()->AsSecureSession()->mState            = sessionParams[i].mState;

         mSessionList.push_back(Platform::MakeUnique<SessionNotificationListener>(session.Value()));
     }
 }

 void TestSecureSessionTable::ValidateSessionSorting(nlTestSuite * inSuite, void * inContext)
 {
     Platform::UniquePtr<TestSecureSessionTable> & _this = *static_cast<Platform::UniquePtr<TestSecureSessionTable> *>(inContext);
     _this->mTestSuite                                   = inSuite;

     //
     // This validates basic eviction. The table is full of sessions from Fabric1 from the same
     // Node (2). Eviction should select the oldest session in the table (with timestamp 1) and evict that
     //
     {
         ChipLogProgress(SecureChannel, "-------- Validating Basic Eviction (Matching Hint's Fabric)  --------");

         std::vector<SessionParameters> sessionParamList = {
             { { 2, kFabric1 }, System::Clock::Timestamp(9), SecureSession::State::kActive },
             { { 2, kFabric1 }, System::Clock::Timestamp(3), SecureSession::State::kActive },
             { { 2, kFabric1 }, System::Clock::Timestamp(2), SecureSession::State::kActive },
             { { 2, kFabric1 }, System::Clock::Timestamp(7), SecureSession::State::kActive },
             { { 2, kFabric1 }, System::Clock::Timestamp(1), SecureSession::State::kActive },
             { { 2, kFabric1 }, System::Clock::Timestamp(2), SecureSession::State::kActive },
         };

         _this->CreateSessionTable(sessionParamList);
         _this->AllocateSession(ScopedNodeId(2, kFabric1), sessionParamList, 4);
     }

     //
     // This validates basic eviction, with the sessionHint indicating a request from a different fabric than
     // those in the table. Nothing changes from the example above since the sessions in the table are over minima,
     // so it will just reap the oldest session in the table (with timestamp 1 again).
     //
     //
     {
         ChipLogProgress(SecureChannel, "-------- Validating Basic Eviction (No Match for Hint's Fabric) --------");

         std::vector<SessionParameters> sessionParamList = {
             { { 2, kFabric1 }, System::Clock::Timestamp(9), SecureSession::State::kActive },
             { { 2, kFabric1 }, System::Clock::Timestamp(3), SecureSession::State::kActive },
             { { 2, kFabric1 }, System::Clock::Timestamp(2), SecureSession::State::kActive },
             { { 2, kFabric1 }, System::Clock::Timestamp(7), SecureSession::State::kActive },
             { { 2, kFabric1 }, System::Clock::Timestamp(1), SecureSession::State::kActive },
             { { 2, kFabric1 }, System::Clock::Timestamp(2), SecureSession::State::kActive },
         };

         _this->CreateSessionTable(sessionParamList);
         _this->AllocateSession(ScopedNodeId(2, kFabric2), sessionParamList, 4);
     }

     //
     // This validates evicting an over-minima fabric from the session table where there
     // are sessions from two fabrics, Fabric1 and Fabric2.
     //
     // Fabric1 has 2 sessions, and Fabric2 has 4 sessions. Fabric2 will be selected since
     // it has more sessions than Fabric2.
     //
     // Within that set, there are more sessions to Node 2 than others, so the oldest one
     // in that set (timestamp 3) will be selected.
     //
     {
         ChipLogProgress(SecureChannel, "-------- Over-minima Fabric Eviction ---------");

         std::vector<SessionParameters> sessionParamList = {
             { { 2, kFabric1 }, System::Clock::Timestamp(9), SecureSession::State::kActive },
             { { 2, kFabric2 }, System::Clock::Timestamp(3), SecureSession::State::kActive },
             { { 1, kFabric1 }, System::Clock::Timestamp(2), SecureSession::State::kActive },
             { { 2, kFabric2 }, System::Clock::Timestamp(7), SecureSession::State::kActive },
             { { 3, kFabric2 }, System::Clock::Timestamp(1), SecureSession::State::kActive },
             { { 4, kFabric2 }, System::Clock::Timestamp(2), SecureSession::State::kActive },
         };

         _this->CreateSessionTable(sessionParamList);
         _this->AllocateSession(ScopedNodeId(2, kFabric1), sessionParamList, 1);
     }

     //
     // This validates evicting an over-minima fabric from the session table where there
     // are sessions from two fabrics, Fabric1 and Fabric2.
     //
     // Fabric1 has 2 sessions, and Fabric2 has 3 sessions. Fabric2 will be selected since
     // it has more sessions than Fabric2.
     //
     // Within that set, there are more sessions to Node 2 than others, except one session
     // is in the pairing state. So the active one will be selected instead.
     //
     {
         ChipLogProgress(SecureChannel, "-------- Over-minima Fabric Eviction (State) ---------");

         std::vector<SessionParameters> sessionParamList = {
             { { 2, kFabric1 }, System::Clock::Timestamp(9), SecureSession::State::kActive },
             { { 2, kFabric2 }, System::Clock::Timestamp(3), SecureSession::State::kEstablishing },
             { { 1, kFabric1 }, System::Clock::Timestamp(2), SecureSession::State::kActive },
             { { 2, kFabric2 }, System::Clock::Timestamp(7), SecureSession::State::kActive },
             { { 3, kFabric2 }, System::Clock::Timestamp(1), SecureSession::State::kActive },
             { { 4, kFabric2 }, System::Clock::Timestamp(2), SecureSession::State::kActive },
         };

         _this->CreateSessionTable(sessionParamList);
         _this->AllocateSession(ScopedNodeId(2, kFabric1), sessionParamList, 3);
     }

     //
     // This validates evicting an over-minima fabric from the session table where there
     // are sessions from two fabrics, Fabric1 and Fabric2.
     //
     // Fabric1 has 2 sessions, and Fabric2 has 4 sessions. Fabric2 will be selected since
     // it has more sessions than Fabric1.
     //
     // Within that set, there are equal sessions to each node, so the session with the
     // older timestamp will be selected.
     //
     {
         ChipLogProgress(SecureChannel, "-------- Over-minima Fabric Eviction ---------");

         std::vector<SessionParameters> sessionParamList = {
             { { 2, kFabric1 }, System::Clock::Timestamp(9), SecureSession::State::kActive },
             { { 1, kFabric2 }, System::Clock::Timestamp(3), SecureSession::State::kActive },
             { { 1, kFabric1 }, System::Clock::Timestamp(2), SecureSession::State::kActive },
             { { 2, kFabric2 }, System::Clock::Timestamp(7), SecureSession::State::kActive },
             { { 3, kFabric2 }, System::Clock::Timestamp(1), SecureSession::State::kActive },
             { { 4, kFabric2 }, System::Clock::Timestamp(2), SecureSession::State::kActive },
         };

         _this->CreateSessionTable(sessionParamList);
         _this->AllocateSession(ScopedNodeId(2, kFabric1), sessionParamList, 4);
     }

     //
     // This validates evicting from a table with equally loaded fabrics. In this scenario,
     // bias is given to the fabric that matches that of the eviction hint.
     //
     // There are more sessions to Node 2 in that fabric, so despite there be a match to
     // Node 3 in the table, the older session to Node 2 will be evicted.
     //
     {
         ChipLogProgress(SecureChannel, "-------- Equal Fabrics Eviction (Un-equal # Sessions / Node) ---------");

         std::vector<SessionParameters> sessionParamList = {
             { { 2, kFabric1 }, System::Clock::Timestamp(9), SecureSession::State::kActive },
             { { 1, kFabric2 }, System::Clock::Timestamp(3), SecureSession::State::kActive },
             { { 2, kFabric1 }, System::Clock::Timestamp(2), SecureSession::State::kActive },
             { { 3, kFabric1 }, System::Clock::Timestamp(7), SecureSession::State::kActive },
             { { 3, kFabric2 }, System::Clock::Timestamp(1), SecureSession::State::kActive },
             { { 4, kFabric2 }, System::Clock::Timestamp(2), SecureSession::State::kActive },
         };

         _this->CreateSessionTable(sessionParamList);
         _this->AllocateSession(ScopedNodeId(3, kFabric1), sessionParamList, 2);
     }

     //
     // This validates evicting from a table with equally loaded fabrics. In this scenario,
     // bias is given to the fabric that matches that of the eviction hint.
     //
     // There are equal sessions to Node 2 as well as Node 3 in that fabric, so the Node
     // that matches the session eviction hint will be selected, and in that, the older session.
     //
     {
         ChipLogProgress(SecureChannel,
                         "-------- Equal Fabrics Eviction (Equal # Sessions to Nodes, Hint Match On Fabric & Node) ---------");

         std::vector<SessionParameters> sessionParamList = {
             { { 1, kFabric1 }, System::Clock::Timestamp(9), SecureSession::State::kActive },
             { { 1, kFabric2 }, System::Clock::Timestamp(3), SecureSession::State::kActive },
             { { 2, kFabric1 }, System::Clock::Timestamp(2), SecureSession::State::kActive },
             { { 3, kFabric1 }, System::Clock::Timestamp(7), SecureSession::State::kActive },
             { { 3, kFabric2 }, System::Clock::Timestamp(1), SecureSession::State::kActive },
             { { 4, kFabric2 }, System::Clock::Timestamp(2), SecureSession::State::kActive },
         };

         _this->CreateSessionTable(sessionParamList);
         _this->AllocateSession(ScopedNodeId(3, kFabric1), sessionParamList, 3);
     }

     //
     // Similar to above, except that the eviction hint matches a given fabric (kFabric1) in the
     // session table, but not any nodes. In this case, the oldest session in that fabric is selected
     // for eviction from the table.
     //
     {
         ChipLogProgress(SecureChannel,
                         "-------- Equal Fabrics Eviction (Equal # of Sessions to Nodes, Hint Match on Fabric ONLY) ---------");

         std::vector<SessionParameters> sessionParamList = {
             { { 1, kFabric1 }, System::Clock::Timestamp(9), SecureSession::State::kActive },
             { { 1, kFabric2 }, System::Clock::Timestamp(3), SecureSession::State::kActive },
             { { 2, kFabric1 }, System::Clock::Timestamp(2), SecureSession::State::kActive },
             { { 3, kFabric1 }, System::Clock::Timestamp(7), SecureSession::State::kActive },
             { { 3, kFabric2 }, System::Clock::Timestamp(1), SecureSession::State::kActive },
             { { 4, kFabric2 }, System::Clock::Timestamp(2), SecureSession::State::kActive },
         };

         _this->CreateSessionTable(sessionParamList);
         _this->AllocateSession(ScopedNodeId(4, kFabric1), sessionParamList, 2);
     }

     //
     // Similar to above, except the eviction hint does not match any fabric in the session table.
     // Given all fabrics are within minimas, the oldest session is then selected.
     //
     {
         ChipLogProgress(SecureChannel, "-------- Equal Fabrics Eviction (Equal # of Sessions to Nodes, No Hint Match) ---------");

         std::vector<SessionParameters> sessionParamList = {
             { { 1, kFabric1 }, System::Clock::Timestamp(9), SecureSession::State::kActive },
             { { 1, kFabric2 }, System::Clock::Timestamp(3), SecureSession::State::kActive },
             { { 2, kFabric1 }, System::Clock::Timestamp(2), SecureSession::State::kActive },
             { { 3, kFabric1 }, System::Clock::Timestamp(7), SecureSession::State::kActive },
             { { 3, kFabric2 }, System::Clock::Timestamp(1), SecureSession::State::kActive },
             { { 4, kFabric2 }, System::Clock::Timestamp(2), SecureSession::State::kActive },
         };

         _this->CreateSessionTable(sessionParamList);
         _this->AllocateSession(ScopedNodeId(4, kFabric3), sessionParamList, 4);
     }

     //
     // Similar to above, except the oldest session happens to not be an active one. Instead,
     // select the next oldest active session.
     //
     {
         ChipLogProgress(
             SecureChannel,
             "-------- Equal Fabrics Eviction (Equal # of Sessions to Nodes, No Hint Match, In-active Session) ---------");

         std::vector<SessionParameters> sessionParamList = {
             { { 1, kFabric1 }, System::Clock::Timestamp(9), SecureSession::State::kActive },
             { { 1, kFabric2 }, System::Clock::Timestamp(3), SecureSession::State::kActive },
             { { 2, kFabric1 }, System::Clock::Timestamp(3), SecureSession::State::kActive },
             { { 3, kFabric1 }, System::Clock::Timestamp(7), SecureSession::State::kActive },
             { { 3, kFabric2 }, System::Clock::Timestamp(1), SecureSession::State::kEstablishing },
             { { 4, kFabric2 }, System::Clock::Timestamp(2), SecureSession::State::kActive },
         };

         _this->CreateSessionTable(sessionParamList);
         _this->AllocateSession(ScopedNodeId(4, kFabric3), sessionParamList, 5);
     }
 }

 Platform::UniquePtr<TestSecureSessionTable> gTestSecureSessionTable;

 } // namespace Transport
 } // namespace chip

 // Test Suite

 namespace {

 /**
  *  Test Suite that lists all the test functions.
  */
 // clang-format off
 const nlTest sTests[] =
 {
     NL_TEST_DEF("Validate Session Sorting (Over Minima)",               chip::Transport::TestSecureSessionTable::ValidateSessionSorting),
     NL_TEST_SENTINEL()
 };
 // clang-format on

 int Initialize(void * apSuite)
 {
     VerifyOrReturnError(chip::Platform::MemoryInit() == CHIP_NO_ERROR, FAILURE);
     chip::Transport::gTestSecureSessionTable = chip::Platform::MakeUnique<chip::Transport::TestSecureSessionTable>();
     return SUCCESS;
 }

 int Finalize(void * aContext)
 {
     chip::Transport::gTestSecureSessionTable.reset();
     chip::Platform::MemoryShutdown();
     return SUCCESS;
 }

 // clang-format off
 nlTestSuite sSuite =
 {
     "TestSecureSessionTable",
     &sTests[0],
     Initialize,
     Finalize
 };
 // clang-format on

 } // namespace

 /**
  *  Main
  */
 int SecureSessionTableTest()
 {
     // Run test suit against one context
     nlTestRunner(&sSuite, &chip::Transport::gTestSecureSessionTable);

     int r = (nlTestRunnerStats(&sSuite));
     return r;
 }

 CHIP_REGISTER_TEST_SUITE(SecureSessionTableTest);
	/*
	*
	* Copyright (c) 2020-2021 Project CHIP Authors
	* All rights reserved.
	*
	* 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.
	*/

	/**
	* @file
	* This file implements unit tests for the SessionManager implementation.
	*/

	#include "system/SystemClock.h"
	#include <lib/core/CHIPCore.h>
	#include <lib/support/CodeUtils.h>
	#include <lib/support/UnitTestRegistration.h>
	#include <transport/SecureSessionTable.h>
	#include <transport/SessionHolder.h>

	#include <nlbyteorder.h>
	#include <nlunit-test.h>

	#include <errno.h>
	#include <vector>

	namespace chip {
	namespace Transport {

	class TestSecureSessionTable
	{
	public:
	//
	// This test specifically validates eviction of sessions in the session table
	// with various scenarios based on the existing set of sessions in the table
	// and a provided session eviction hint
	//
	static void ValidateSessionSorting(nlTestSuite * inSuite, void * inContext);

	private:
	struct SessionParameters
	{
	ScopedNodeId mPeer;
	System::Clock::Timestamp mLastActivityTime;
	SecureSession::State mState;
	};

	//
	// This listener lets us track which sessions get evicted by
	// using a SessionHolderWithDelegate to get notified on session release.
	//
	class SessionNotificationListener : public SessionDelegate
	{
	public:
	SessionNotificationListener(const SessionHandle & session) : mSessionHolder(*this) { mSessionHolder.Grab(session); }

	void OnSessionReleased() { mSessionReleased = true; }

	NewSessionHandlingPolicy GetNewSessionHandlingPolicy() { return NewSessionHandlingPolicy::kStayAtOldSession; }

	SessionHolderWithDelegate mSessionHolder;
	bool mSessionReleased = false;
	};

	static constexpr FabricIndex kFabric1 = 1;
	static constexpr FabricIndex kFabric2 = 2;
	static constexpr FabricIndex kFabric3 = 3;

	//
	// Allocates a new secure session given an eviction hint. The session that was evicted is compared against the provided
	// evictedSessionIndex (which indexes into the provided SessionParameter table) to validate that it matches.
	//
	void AllocateSession(const ScopedNodeId & sessionEvictionHint, std::vector<SessionParameters> & sessionParameters,
	uint16_t evictedSessionIndex);

	//
	// Reset our internal SecureSessionTable list and create a new one given the provided parameters.
	//
	void CreateSessionTable(std::vector<SessionParameters> & sessionParams);

	nlTestSuite * mTestSuite;
	Platform::UniquePtr<SecureSessionTable> mSessionTable;
	std::vector<Platform::UniquePtr<SessionNotificationListener>> mSessionList;
	};

	void TestSecureSessionTable::AllocateSession(const ScopedNodeId & sessionEvictionHint,
	std::vector<SessionParameters> & sessionParameters, uint16_t evictedSessionIndex)
	{
	auto session = mSessionTable->CreateNewSecureSession(SecureSession::Type::kCASE, sessionEvictionHint);
	NL_TEST_ASSERT(mTestSuite, session.HasValue());
	NL_TEST_ASSERT(mTestSuite, mSessionList[evictedSessionIndex].get()->mSessionReleased == true);
	}

	void TestSecureSessionTable::CreateSessionTable(std::vector<SessionParameters> & sessionParams)
	{
	mSessionList.clear();

	mSessionTable = Platform::MakeUnique<SecureSessionTable>();
	NL_TEST_ASSERT(mTestSuite, mSessionTable.get() != nullptr);

	mSessionTable->Init();
	mSessionTable->SetMaxSessionTableSize(static_cast<uint32_t>(sessionParams.size()));

	for (unsigned int i = 0; i < sessionParams.size(); i++)
	{
	auto session = mSessionTable->CreateNewSecureSession(SecureSession::Type::kCASE, ScopedNodeId());
	NL_TEST_ASSERT(mTestSuite, session.HasValue());

	session.Value()->AsSecureSession()->Activate(
	ScopedNodeId(1, sessionParams[i].mPeer.GetFabricIndex()), sessionParams[i].mPeer, CATValues(), static_cast<uint16_t>(i),
	ReliableMessageProtocolConfig(System::Clock::Milliseconds32(0), System::Clock::Milliseconds32(0)));
	session.Value()->AsSecureSession()->mLastActivityTime = sessionParams[i].mLastActivityTime;
	session.Value()->AsSecureSession()->mState = sessionParams[i].mState;

	mSessionList.push_back(Platform::MakeUnique<SessionNotificationListener>(session.Value()));
	}
	}

	void TestSecureSessionTable::ValidateSessionSorting(nlTestSuite * inSuite, void * inContext)
	{
	Platform::UniquePtr<TestSecureSessionTable> & _this = static_cast<Platform::UniquePtr<TestSecureSessionTable> >(inContext);
	_this->mTestSuite = inSuite;

	//
	// This validates basic eviction. The table is full of sessions from Fabric1 from the same
	// Node (2). Eviction should select the oldest session in the table (with timestamp 1) and evict that
	//
	{
	ChipLogProgress(SecureChannel, "-------- Validating Basic Eviction (Matching Hint's Fabric) --------");

	std::vector<SessionParameters> sessionParamList = {
	{ { 2, kFabric1 }, System::Clock::Timestamp(9), SecureSession::State::kActive },
	{ { 2, kFabric1 }, System::Clock::Timestamp(3), SecureSession::State::kActive },
	{ { 2, kFabric1 }, System::Clock::Timestamp(2), SecureSession::State::kActive },
	{ { 2, kFabric1 }, System::Clock::Timestamp(7), SecureSession::State::kActive },
	{ { 2, kFabric1 }, System::Clock::Timestamp(1), SecureSession::State::kActive },
	{ { 2, kFabric1 }, System::Clock::Timestamp(2), SecureSession::State::kActive },
	};

	_this->CreateSessionTable(sessionParamList);
	_this->AllocateSession(ScopedNodeId(2, kFabric1), sessionParamList, 4);
	}

	//
	// This validates basic eviction, with the sessionHint indicating a request from a different fabric than
	// those in the table. Nothing changes from the example above since the sessions in the table are over minima,
	// so it will just reap the oldest session in the table (with timestamp 1 again).
	//
	//
	{
	ChipLogProgress(SecureChannel, "-------- Validating Basic Eviction (No Match for Hint's Fabric) --------");

	std::vector<SessionParameters> sessionParamList = {
	{ { 2, kFabric1 }, System::Clock::Timestamp(9), SecureSession::State::kActive },
	{ { 2, kFabric1 }, System::Clock::Timestamp(3), SecureSession::State::kActive },
	{ { 2, kFabric1 }, System::Clock::Timestamp(2), SecureSession::State::kActive },
	{ { 2, kFabric1 }, System::Clock::Timestamp(7), SecureSession::State::kActive },
	{ { 2, kFabric1 }, System::Clock::Timestamp(1), SecureSession::State::kActive },
	{ { 2, kFabric1 }, System::Clock::Timestamp(2), SecureSession::State::kActive },
	};

	_this->CreateSessionTable(sessionParamList);
	_this->AllocateSession(ScopedNodeId(2, kFabric2), sessionParamList, 4);
	}

	//
	// This validates evicting an over-minima fabric from the session table where there
	// are sessions from two fabrics, Fabric1 and Fabric2.
	//
	// Fabric1 has 2 sessions, and Fabric2 has 4 sessions. Fabric2 will be selected since
	// it has more sessions than Fabric2.
	//
	// Within that set, there are more sessions to Node 2 than others, so the oldest one
	// in that set (timestamp 3) will be selected.
	//
	{
	ChipLogProgress(SecureChannel, "-------- Over-minima Fabric Eviction ---------");

	std::vector<SessionParameters> sessionParamList = {
	{ { 2, kFabric1 }, System::Clock::Timestamp(9), SecureSession::State::kActive },
	{ { 2, kFabric2 }, System::Clock::Timestamp(3), SecureSession::State::kActive },
	{ { 1, kFabric1 }, System::Clock::Timestamp(2), SecureSession::State::kActive },
	{ { 2, kFabric2 }, System::Clock::Timestamp(7), SecureSession::State::kActive },
	{ { 3, kFabric2 }, System::Clock::Timestamp(1), SecureSession::State::kActive },
	{ { 4, kFabric2 }, System::Clock::Timestamp(2), SecureSession::State::kActive },
	};

	_this->CreateSessionTable(sessionParamList);
	_this->AllocateSession(ScopedNodeId(2, kFabric1), sessionParamList, 1);
	}

	//
	// This validates evicting an over-minima fabric from the session table where there
	// are sessions from two fabrics, Fabric1 and Fabric2.
	//
	// Fabric1 has 2 sessions, and Fabric2 has 3 sessions. Fabric2 will be selected since
	// it has more sessions than Fabric2.
	//
	// Within that set, there are more sessions to Node 2 than others, except one session
	// is in the pairing state. So the active one will be selected instead.
	//
	{
	ChipLogProgress(SecureChannel, "-------- Over-minima Fabric Eviction (State) ---------");

	std::vector<SessionParameters> sessionParamList = {
	{ { 2, kFabric1 }, System::Clock::Timestamp(9), SecureSession::State::kActive },
	{ { 2, kFabric2 }, System::Clock::Timestamp(3), SecureSession::State::kEstablishing },
	{ { 1, kFabric1 }, System::Clock::Timestamp(2), SecureSession::State::kActive },
	{ { 2, kFabric2 }, System::Clock::Timestamp(7), SecureSession::State::kActive },
	{ { 3, kFabric2 }, System::Clock::Timestamp(1), SecureSession::State::kActive },
	{ { 4, kFabric2 }, System::Clock::Timestamp(2), SecureSession::State::kActive },
	};

	_this->CreateSessionTable(sessionParamList);
	_this->AllocateSession(ScopedNodeId(2, kFabric1), sessionParamList, 3);
	}

	//
	// This validates evicting an over-minima fabric from the session table where there
	// are sessions from two fabrics, Fabric1 and Fabric2.
	//
	// Fabric1 has 2 sessions, and Fabric2 has 4 sessions. Fabric2 will be selected since
	// it has more sessions than Fabric1.
	//
	// Within that set, there are equal sessions to each node, so the session with the
	// older timestamp will be selected.
	//
	{
	ChipLogProgress(SecureChannel, "-------- Over-minima Fabric Eviction ---------");

	std::vector<SessionParameters> sessionParamList = {
	{ { 2, kFabric1 }, System::Clock::Timestamp(9), SecureSession::State::kActive },
	{ { 1, kFabric2 }, System::Clock::Timestamp(3), SecureSession::State::kActive },
	{ { 1, kFabric1 }, System::Clock::Timestamp(2), SecureSession::State::kActive },
	{ { 2, kFabric2 }, System::Clock::Timestamp(7), SecureSession::State::kActive },
	{ { 3, kFabric2 }, System::Clock::Timestamp(1), SecureSession::State::kActive },
	{ { 4, kFabric2 }, System::Clock::Timestamp(2), SecureSession::State::kActive },
	};

	_this->CreateSessionTable(sessionParamList);
	_this->AllocateSession(ScopedNodeId(2, kFabric1), sessionParamList, 4);
	}

	//
	// This validates evicting from a table with equally loaded fabrics. In this scenario,
	// bias is given to the fabric that matches that of the eviction hint.
	//
	// There are more sessions to Node 2 in that fabric, so despite there be a match to
	// Node 3 in the table, the older session to Node 2 will be evicted.
	//
	{
	ChipLogProgress(SecureChannel, "-------- Equal Fabrics Eviction (Un-equal # Sessions / Node) ---------");

	std::vector<SessionParameters> sessionParamList = {
	{ { 2, kFabric1 }, System::Clock::Timestamp(9), SecureSession::State::kActive },
	{ { 1, kFabric2 }, System::Clock::Timestamp(3), SecureSession::State::kActive },
	{ { 2, kFabric1 }, System::Clock::Timestamp(2), SecureSession::State::kActive },
	{ { 3, kFabric1 }, System::Clock::Timestamp(7), SecureSession::State::kActive },
	{ { 3, kFabric2 }, System::Clock::Timestamp(1), SecureSession::State::kActive },
	{ { 4, kFabric2 }, System::Clock::Timestamp(2), SecureSession::State::kActive },
	};

	_this->CreateSessionTable(sessionParamList);
	_this->AllocateSession(ScopedNodeId(3, kFabric1), sessionParamList, 2);
	}

	//
	// This validates evicting from a table with equally loaded fabrics. In this scenario,
	// bias is given to the fabric that matches that of the eviction hint.
	//
	// There are equal sessions to Node 2 as well as Node 3 in that fabric, so the Node
	// that matches the session eviction hint will be selected, and in that, the older session.
	//
	{
	ChipLogProgress(SecureChannel,
	"-------- Equal Fabrics Eviction (Equal # Sessions to Nodes, Hint Match On Fabric & Node) ---------");

	std::vector<SessionParameters> sessionParamList = {
	{ { 1, kFabric1 }, System::Clock::Timestamp(9), SecureSession::State::kActive },
	{ { 1, kFabric2 }, System::Clock::Timestamp(3), SecureSession::State::kActive },
	{ { 2, kFabric1 }, System::Clock::Timestamp(2), SecureSession::State::kActive },
	{ { 3, kFabric1 }, System::Clock::Timestamp(7), SecureSession::State::kActive },
	{ { 3, kFabric2 }, System::Clock::Timestamp(1), SecureSession::State::kActive },
	{ { 4, kFabric2 }, System::Clock::Timestamp(2), SecureSession::State::kActive },
	};

	_this->CreateSessionTable(sessionParamList);
	_this->AllocateSession(ScopedNodeId(3, kFabric1), sessionParamList, 3);
	}

	//
	// Similar to above, except that the eviction hint matches a given fabric (kFabric1) in the
	// session table, but not any nodes. In this case, the oldest session in that fabric is selected
	// for eviction from the table.
	//
	{
	ChipLogProgress(SecureChannel,
	"-------- Equal Fabrics Eviction (Equal # of Sessions to Nodes, Hint Match on Fabric ONLY) ---------");

	std::vector<SessionParameters> sessionParamList = {
	{ { 1, kFabric1 }, System::Clock::Timestamp(9), SecureSession::State::kActive },
	{ { 1, kFabric2 }, System::Clock::Timestamp(3), SecureSession::State::kActive },
	{ { 2, kFabric1 }, System::Clock::Timestamp(2), SecureSession::State::kActive },
	{ { 3, kFabric1 }, System::Clock::Timestamp(7), SecureSession::State::kActive },
	{ { 3, kFabric2 }, System::Clock::Timestamp(1), SecureSession::State::kActive },
	{ { 4, kFabric2 }, System::Clock::Timestamp(2), SecureSession::State::kActive },
	};

	_this->CreateSessionTable(sessionParamList);
	_this->AllocateSession(ScopedNodeId(4, kFabric1), sessionParamList, 2);
	}

	//
	// Similar to above, except the eviction hint does not match any fabric in the session table.
	// Given all fabrics are within minimas, the oldest session is then selected.
	//
	{
	ChipLogProgress(SecureChannel, "-------- Equal Fabrics Eviction (Equal # of Sessions to Nodes, No Hint Match) ---------");

	std::vector<SessionParameters> sessionParamList = {
	{ { 1, kFabric1 }, System::Clock::Timestamp(9), SecureSession::State::kActive },
	{ { 1, kFabric2 }, System::Clock::Timestamp(3), SecureSession::State::kActive },
	{ { 2, kFabric1 }, System::Clock::Timestamp(2), SecureSession::State::kActive },
	{ { 3, kFabric1 }, System::Clock::Timestamp(7), SecureSession::State::kActive },
	{ { 3, kFabric2 }, System::Clock::Timestamp(1), SecureSession::State::kActive },
	{ { 4, kFabric2 }, System::Clock::Timestamp(2), SecureSession::State::kActive },
	};

	_this->CreateSessionTable(sessionParamList);
	_this->AllocateSession(ScopedNodeId(4, kFabric3), sessionParamList, 4);
	}

	//
	// Similar to above, except the oldest session happens to not be an active one. Instead,
	// select the next oldest active session.
	//
	{
	ChipLogProgress(
	SecureChannel,
	"-------- Equal Fabrics Eviction (Equal # of Sessions to Nodes, No Hint Match, In-active Session) ---------");

	std::vector<SessionParameters> sessionParamList = {
	{ { 1, kFabric1 }, System::Clock::Timestamp(9), SecureSession::State::kActive },
	{ { 1, kFabric2 }, System::Clock::Timestamp(3), SecureSession::State::kActive },
	{ { 2, kFabric1 }, System::Clock::Timestamp(3), SecureSession::State::kActive },
	{ { 3, kFabric1 }, System::Clock::Timestamp(7), SecureSession::State::kActive },
	{ { 3, kFabric2 }, System::Clock::Timestamp(1), SecureSession::State::kEstablishing },
	{ { 4, kFabric2 }, System::Clock::Timestamp(2), SecureSession::State::kActive },
	};

	_this->CreateSessionTable(sessionParamList);
	_this->AllocateSession(ScopedNodeId(4, kFabric3), sessionParamList, 5);
	}
	}

	Platform::UniquePtr<TestSecureSessionTable> gTestSecureSessionTable;

	} // namespace Transport
	} // namespace chip

	// Test Suite

	namespace {

	/**
	* Test Suite that lists all the test functions.
	*/
	// clang-format off
	const nlTest sTests[] =
	{
	NL_TEST_DEF("Validate Session Sorting (Over Minima)", chip::Transport::TestSecureSessionTable::ValidateSessionSorting),
	NL_TEST_SENTINEL()
	};
	// clang-format on

	int Initialize(void * apSuite)
	{
	VerifyOrReturnError(chip::Platform::MemoryInit() == CHIP_NO_ERROR, FAILURE);
	chip::Transport::gTestSecureSessionTable = chip::Platform::MakeUnique<chip::Transport::TestSecureSessionTable>();
	return SUCCESS;
	}

	int Finalize(void * aContext)
	{
	chip::Transport::gTestSecureSessionTable.reset();
	chip::Platform::MemoryShutdown();
	return SUCCESS;
	}

	// clang-format off
	nlTestSuite sSuite =
	{
	"TestSecureSessionTable",
	&sTests[0],
	Initialize,
	Finalize
	};
	// clang-format on

	} // namespace

	/**
	* Main
	*/
	int SecureSessionTableTest()
	{
	// Run test suit against one context
	nlTestRunner(&sSuite, &chip::Transport::gTestSecureSessionTable);

	int r = (nlTestRunnerStats(&sSuite));
	return r;
	}

	CHIP_REGISTER_TEST_SUITE(SecureSessionTableTest);