src/controller/CHIPDeviceControllerFactory.h - third_party/github/project-chip/connectedhomeip - Git at Google

 /*
  *
  *    Copyright (c) 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
  *      DeviceControllerFactory is a singleton utility class that manages the
  *      runtime DeviceControllerSystemState and provides APIs to setup DeviceControllers
  *      and DeviceCommissioners.
  *
  *      Together with the SystemState this class implicitly manages the lifecycle of the underlying
  *      CHIP stack. It lazily initializes the CHIPStack when setting up Controllers if the SystemState
  *      was previously shutdown.
  */

 #pragma once

 #include <controller/CHIPDeviceController.h>
 #include <controller/CHIPDeviceControllerSystemState.h>
 #include <credentials/GroupDataProvider.h>
 #include <credentials/OperationalCertificateStore.h>
 #include <credentials/attestation_verifier/DeviceAttestationVerifier.h>

 namespace chip {

 namespace Controller {

 struct SetupParams
 {
     OperationalCredentialsDelegate * operationalCredentialsDelegate = nullptr;

     /* The following keypair must correspond to the public key used for generating
     controllerNOC. It's used by controller to establish CASE sessions with devices */
     Crypto::P256Keypair * operationalKeypair = nullptr;

     /**
      * Controls whether or not the operationalKeypair should be owned by the
      * caller.  By default, this is false, but if the keypair cannot be
      * serialized, then setting this to true will allow the caller to manage
      * this keypair's lifecycle.
      */
     bool hasExternallyOwnedOperationalKeypair = false;

     /* The following certificates must be in x509 DER format */
     ByteSpan controllerNOC;
     ByteSpan controllerICAC;
     ByteSpan controllerRCAC;

     //
     // This must be set to a valid, operational VendorId value associated with
     // the controller/commissioner.
     //
     chip::VendorId controllerVendorId = VendorId::Unspecified;

     // The Device Pairing Delegated used to initialize a Commissioner
     DevicePairingDelegate * pairingDelegate = nullptr;

     /**
      * Controls whether we permit multiple DeviceController instances to exist
      * on the same logical fabric (identified by the tuple of the fabric's
      * root public key + fabric id).
      *
      * Each controller instance will be associated with its own FabricIndex.
      * This pivots the FabricTable to tracking identities instead of fabrics,
      * represented by FabricInfo instances that can have colliding logical fabrics.
      *
      */
     bool permitMultiControllerFabrics = false;

     //
     // Controls enabling server cluster interactions on a controller. This in turn
     // causes the following to get enabled:
     //
     //  - CASEServer to listen for unsolicited Sigma1 messages.
     //  - Advertisement of active controller operational identities.
     //
     bool enableServerInteractions = false;

     Credentials::DeviceAttestationVerifier * deviceAttestationVerifier = nullptr;
     CommissioningDelegate * defaultCommissioner                        = nullptr;
 };

 // TODO everything other than the fabric storage, group data provider, OperationalKeystore
 // and OperationalCertificateStore here should be removed. We're blocked because of the
 // need to support !CHIP_DEVICE_LAYER
 struct FactoryInitParams
 {
     System::Layer * systemLayer                                        = nullptr;
     PersistentStorageDelegate * fabricIndependentStorage               = nullptr;
     Credentials::CertificateValidityPolicy * certificateValidityPolicy = nullptr;
     Credentials::GroupDataProvider * groupDataProvider                 = nullptr;
     Inet::EndPointManager<Inet::TCPEndPoint> * tcpEndPointManager      = nullptr;
     Inet::EndPointManager<Inet::UDPEndPoint> * udpEndPointManager      = nullptr;
     FabricTable * fabricTable                                          = nullptr;
     OperationalKeystore * operationalKeystore                          = nullptr;
     Credentials::OperationalCertificateStore * opCertStore             = nullptr;
 #if CONFIG_NETWORK_LAYER_BLE
     Ble::BleLayer * bleLayer = nullptr;
 #endif

     //
     // Controls enabling server cluster interactions on a controller. This in turn
     // causes the following to get enabled:
     //
     //  - Advertisement of active controller operational identities.
     //
     bool enableServerInteractions = false;

     /* The port used for operational communication to listen for and send messages over UDP/TCP.
      * The default value of `0` will pick any available port. */
     uint16_t listenPort = 0;
 };

 class DeviceControllerFactory
 {
 public:
     static DeviceControllerFactory & GetInstance()
     {
         static DeviceControllerFactory instance;
         return instance;
     }

     CHIP_ERROR Init(FactoryInitParams params);

     // Shuts down matter and frees the system state.
     //
     // Must not be called while any controllers are alive.
     void Shutdown();

     CHIP_ERROR SetupController(SetupParams params, DeviceController & controller);
     CHIP_ERROR SetupCommissioner(SetupParams params, DeviceCommissioner & commissioner);

     // ----- IO -----
     /**
      * @brief
      * Start the event loop task within the CHIP stack
      * @return CHIP_ERROR   The return status
      */
     CHIP_ERROR ServiceEvents();

     ~DeviceControllerFactory();
     DeviceControllerFactory(DeviceControllerFactory const &) = delete;
     void operator=(DeviceControllerFactory const &) = delete;

     //
     // Some clients do not prefer a complete shutdown of the stack being initiated if
     // all device controllers have ceased to exist. To avoid that, this method has been
     // created to permit retention of the underlying system state.
     //
     // NB: The system state will still be freed in Shutdown() regardless of this call.
     void RetainSystemState() { (void) mSystemState->Retain(); }

     //
     // To initiate shutdown of the stack upon termination of all resident controllers in the
     // system, invoke this method to decrement the refcount on the system state and consequently,
     // shut-down the stack.
     //
     // This should only be invoked if a matching call to RetainSystemState() was called prior.
     //
     void ReleaseSystemState() { mSystemState->Release(); }

     //
     // Retrieve a read-only pointer to the system state object that contains pointers to key stack
     // singletons. If the pointer is null, it indicates that the DeviceControllerFactory has yet to
     // be initialized properly, or has already been shut-down.
     //
     // This pointer ceases to be valid after a call to Shutdown has been made, or if all active
     // DeviceController instances have gone to 0. Consequently, care has to be taken to correctly
     // sequence the shutting down of active controllers with any entity that interacts with objects
     // present in the system state object. If de-coupling is desired, RetainSystemState and
     // ReleaseSystemState can be used to avoid this.
     //
     const DeviceControllerSystemState * GetSystemState() const { return mSystemState; }

     class ControllerFabricDelegate final : public chip::FabricTable::Delegate
     {
     public:
         CHIP_ERROR Init(SessionResumptionStorage * sessionResumptionStorage, Credentials::GroupDataProvider * groupDataProvider)
         {
             VerifyOrReturnError(sessionResumptionStorage != nullptr, CHIP_ERROR_INVALID_ARGUMENT);
             VerifyOrReturnError(groupDataProvider != nullptr, CHIP_ERROR_INVALID_ARGUMENT);

             mSessionResumptionStorage = sessionResumptionStorage;
             mGroupDataProvider        = groupDataProvider;
             return CHIP_NO_ERROR;
         };

         void OnFabricRemoved(const chip::FabricTable & fabricTable, FabricIndex fabricIndex) override
         {
             (void) fabricTable;
             if (mGroupDataProvider != nullptr)
             {
                 mGroupDataProvider->RemoveFabric(fabricIndex);
             }
             ClearCASEResumptionStateOnFabricChange(fabricIndex);
         };

         void OnFabricUpdated(const chip::FabricTable & fabricTable, chip::FabricIndex fabricIndex) override
         {
             (void) fabricTable;
             ClearCASEResumptionStateOnFabricChange(fabricIndex);
         }

     private:
         void ClearCASEResumptionStateOnFabricChange(chip::FabricIndex fabricIndex)
         {
             VerifyOrReturn(mSessionResumptionStorage != nullptr);
             CHIP_ERROR err = mSessionResumptionStorage->DeleteAll(fabricIndex);
             if (err != CHIP_NO_ERROR)
             {
                 ChipLogError(Controller,
                              "Warning, failed to delete session resumption state for fabric index 0x%x: %" CHIP_ERROR_FORMAT,
                              static_cast<unsigned>(fabricIndex), err.Format());
             }
         }

         Credentials::GroupDataProvider * mGroupDataProvider  = nullptr;
         SessionResumptionStorage * mSessionResumptionStorage = nullptr;
     };

 private:
     DeviceControllerFactory() {}
     void PopulateInitParams(ControllerInitParams & controllerParams, const SetupParams & params);
     CHIP_ERROR InitSystemState(FactoryInitParams params);
     CHIP_ERROR InitSystemState();

     uint16_t mListenPort;
     DeviceControllerSystemState * mSystemState              = nullptr;
     PersistentStorageDelegate * mFabricIndependentStorage   = nullptr;
     Crypto::OperationalKeystore * mOperationalKeystore      = nullptr;
     Credentials::OperationalCertificateStore * mOpCertStore = nullptr;
     bool mEnableServerInteractions                          = false;
 };

 } // namespace Controller
 } // namespace chip
	/*
	*
	* Copyright (c) 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
	* DeviceControllerFactory is a singleton utility class that manages the
	* runtime DeviceControllerSystemState and provides APIs to setup DeviceControllers
	* and DeviceCommissioners.
	*
	* Together with the SystemState this class implicitly manages the lifecycle of the underlying
	* CHIP stack. It lazily initializes the CHIPStack when setting up Controllers if the SystemState
	* was previously shutdown.
	*/

	#pragma once

	#include <controller/CHIPDeviceController.h>
	#include <controller/CHIPDeviceControllerSystemState.h>
	#include <credentials/GroupDataProvider.h>
	#include <credentials/OperationalCertificateStore.h>
	#include <credentials/attestation_verifier/DeviceAttestationVerifier.h>

	namespace chip {

	namespace Controller {

	struct SetupParams
	{
	OperationalCredentialsDelegate * operationalCredentialsDelegate = nullptr;

	/* The following keypair must correspond to the public key used for generating
	controllerNOC. It's used by controller to establish CASE sessions with devices */
	Crypto::P256Keypair * operationalKeypair = nullptr;

	/**
	* Controls whether or not the operationalKeypair should be owned by the
	* caller. By default, this is false, but if the keypair cannot be
	* serialized, then setting this to true will allow the caller to manage
	* this keypair's lifecycle.
	*/
	bool hasExternallyOwnedOperationalKeypair = false;

	/* The following certificates must be in x509 DER format */
	ByteSpan controllerNOC;
	ByteSpan controllerICAC;
	ByteSpan controllerRCAC;

	//
	// This must be set to a valid, operational VendorId value associated with
	// the controller/commissioner.
	//
	chip::VendorId controllerVendorId = VendorId::Unspecified;

	// The Device Pairing Delegated used to initialize a Commissioner
	DevicePairingDelegate * pairingDelegate = nullptr;

	/**
	* Controls whether we permit multiple DeviceController instances to exist
	* on the same logical fabric (identified by the tuple of the fabric's
	* root public key + fabric id).
	*
	* Each controller instance will be associated with its own FabricIndex.
	* This pivots the FabricTable to tracking identities instead of fabrics,
	* represented by FabricInfo instances that can have colliding logical fabrics.
	*
	*/
	bool permitMultiControllerFabrics = false;

	//
	// Controls enabling server cluster interactions on a controller. This in turn
	// causes the following to get enabled:
	//
	// - CASEServer to listen for unsolicited Sigma1 messages.
	// - Advertisement of active controller operational identities.
	//
	bool enableServerInteractions = false;

	Credentials::DeviceAttestationVerifier * deviceAttestationVerifier = nullptr;
	CommissioningDelegate * defaultCommissioner = nullptr;
	};

	// TODO everything other than the fabric storage, group data provider, OperationalKeystore
	// and OperationalCertificateStore here should be removed. We're blocked because of the
	// need to support !CHIP_DEVICE_LAYER
	struct FactoryInitParams
	{
	System::Layer * systemLayer = nullptr;
	PersistentStorageDelegate * fabricIndependentStorage = nullptr;
	Credentials::CertificateValidityPolicy * certificateValidityPolicy = nullptr;
	Credentials::GroupDataProvider * groupDataProvider = nullptr;
	Inet::EndPointManager<Inet::TCPEndPoint> * tcpEndPointManager = nullptr;
	Inet::EndPointManager<Inet::UDPEndPoint> * udpEndPointManager = nullptr;
	FabricTable * fabricTable = nullptr;
	OperationalKeystore * operationalKeystore = nullptr;
	Credentials::OperationalCertificateStore * opCertStore = nullptr;
	#if CONFIG_NETWORK_LAYER_BLE
	Ble::BleLayer * bleLayer = nullptr;
	#endif

	//
	// Controls enabling server cluster interactions on a controller. This in turn
	// causes the following to get enabled:
	//
	// - Advertisement of active controller operational identities.
	//
	bool enableServerInteractions = false;

	/* The port used for operational communication to listen for and send messages over UDP/TCP.
	* The default value of `0` will pick any available port. */
	uint16_t listenPort = 0;
	};

	class DeviceControllerFactory
	{
	public:
	static DeviceControllerFactory & GetInstance()
	{
	static DeviceControllerFactory instance;
	return instance;
	}

	CHIP_ERROR Init(FactoryInitParams params);

	// Shuts down matter and frees the system state.
	//
	// Must not be called while any controllers are alive.
	void Shutdown();

	CHIP_ERROR SetupController(SetupParams params, DeviceController & controller);
	CHIP_ERROR SetupCommissioner(SetupParams params, DeviceCommissioner & commissioner);

	// ----- IO -----
	/**
	* @brief
	* Start the event loop task within the CHIP stack
	* @return CHIP_ERROR The return status
	*/
	CHIP_ERROR ServiceEvents();

	~DeviceControllerFactory();
	DeviceControllerFactory(DeviceControllerFactory const &) = delete;
	void operator=(DeviceControllerFactory const &) = delete;

	//
	// Some clients do not prefer a complete shutdown of the stack being initiated if
	// all device controllers have ceased to exist. To avoid that, this method has been
	// created to permit retention of the underlying system state.
	//
	// NB: The system state will still be freed in Shutdown() regardless of this call.
	void RetainSystemState() { (void) mSystemState->Retain(); }

	//
	// To initiate shutdown of the stack upon termination of all resident controllers in the
	// system, invoke this method to decrement the refcount on the system state and consequently,
	// shut-down the stack.
	//
	// This should only be invoked if a matching call to RetainSystemState() was called prior.
	//
	void ReleaseSystemState() { mSystemState->Release(); }

	//
	// Retrieve a read-only pointer to the system state object that contains pointers to key stack
	// singletons. If the pointer is null, it indicates that the DeviceControllerFactory has yet to
	// be initialized properly, or has already been shut-down.
	//
	// This pointer ceases to be valid after a call to Shutdown has been made, or if all active
	// DeviceController instances have gone to 0. Consequently, care has to be taken to correctly
	// sequence the shutting down of active controllers with any entity that interacts with objects
	// present in the system state object. If de-coupling is desired, RetainSystemState and
	// ReleaseSystemState can be used to avoid this.
	//
	const DeviceControllerSystemState * GetSystemState() const { return mSystemState; }

	class ControllerFabricDelegate final : public chip::FabricTable::Delegate
	{
	public:
	CHIP_ERROR Init(SessionResumptionStorage * sessionResumptionStorage, Credentials::GroupDataProvider * groupDataProvider)
	{
	VerifyOrReturnError(sessionResumptionStorage != nullptr, CHIP_ERROR_INVALID_ARGUMENT);
	VerifyOrReturnError(groupDataProvider != nullptr, CHIP_ERROR_INVALID_ARGUMENT);

	mSessionResumptionStorage = sessionResumptionStorage;
	mGroupDataProvider = groupDataProvider;
	return CHIP_NO_ERROR;
	};

	void OnFabricRemoved(const chip::FabricTable & fabricTable, FabricIndex fabricIndex) override
	{
	(void) fabricTable;
	if (mGroupDataProvider != nullptr)
	{
	mGroupDataProvider->RemoveFabric(fabricIndex);
	}
	ClearCASEResumptionStateOnFabricChange(fabricIndex);
	};

	void OnFabricUpdated(const chip::FabricTable & fabricTable, chip::FabricIndex fabricIndex) override
	{
	(void) fabricTable;
	ClearCASEResumptionStateOnFabricChange(fabricIndex);
	}

	private:
	void ClearCASEResumptionStateOnFabricChange(chip::FabricIndex fabricIndex)
	{
	VerifyOrReturn(mSessionResumptionStorage != nullptr);
	CHIP_ERROR err = mSessionResumptionStorage->DeleteAll(fabricIndex);
	if (err != CHIP_NO_ERROR)
	{
	ChipLogError(Controller,
	"Warning, failed to delete session resumption state for fabric index 0x%x: %" CHIP_ERROR_FORMAT,
	static_cast<unsigned>(fabricIndex), err.Format());
	}
	}

	Credentials::GroupDataProvider * mGroupDataProvider = nullptr;
	SessionResumptionStorage * mSessionResumptionStorage = nullptr;
	};

	private:
	DeviceControllerFactory() {}
	void PopulateInitParams(ControllerInitParams & controllerParams, const SetupParams & params);
	CHIP_ERROR InitSystemState(FactoryInitParams params);
	CHIP_ERROR InitSystemState();

	uint16_t mListenPort;
	DeviceControllerSystemState * mSystemState = nullptr;
	PersistentStorageDelegate * mFabricIndependentStorage = nullptr;
	Crypto::OperationalKeystore * mOperationalKeystore = nullptr;
	Credentials::OperationalCertificateStore * mOpCertStore = nullptr;
	bool mEnableServerInteractions = false;
	};

	} // namespace Controller
	} // namespace chip