src/app/icd/server/ICDMonitoringTable.h - third_party/github/project-chip/connectedhomeip - Git at Google

 /**
  *
  *    Copyright (c) 2023 Project CHIP Authors
  *
  *    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.
  */
 #pragma once

 #include <crypto/CHIPCryptoPAL.h>
 #include <crypto/SessionKeystore.h>
 #include <lib/core/CHIPConfig.h>
 #include <lib/core/CHIPPersistentStorageDelegate.h>
 #include <lib/core/ClusterEnums.h>
 #include <lib/core/DataModelTypes.h>
 #include <lib/support/CodeUtils.h>
 #include <lib/support/PersistentData.h>
 #include <stddef.h>

 namespace chip {
 namespace Crypto {
 using SymmetricKeystore = SessionKeystore;
 }
 } // namespace chip

 namespace chip {

 inline constexpr size_t kICDMonitoringBufferSize = 60;

 struct ICDMonitoringEntry : public PersistentData<kICDMonitoringBufferSize>
 {

     ICDMonitoringEntry(FabricIndex fabric = kUndefinedFabricIndex, NodeId nodeId = kUndefinedNodeId)
     {
         this->fabricIndex      = fabric;
         this->checkInNodeID    = nodeId;
         this->monitoredSubject = nodeId;
     }

     ICDMonitoringEntry(Crypto::SymmetricKeystore * keyStore, FabricIndex fabric = kUndefinedFabricIndex,
                        NodeId nodeId = kUndefinedNodeId)
     {
         this->fabricIndex       = fabric;
         this->checkInNodeID     = nodeId;
         this->monitoredSubject  = nodeId;
         this->symmetricKeystore = keyStore;
     }

     CHIP_ERROR UpdateKey(StorageKeyName & key) override;
     CHIP_ERROR Serialize(TLV::TLVWriter & writer) const override;
     CHIP_ERROR Deserialize(TLV::TLVReader & reader) override;
     void Clear() override;
     /**
      * @brief Set the Key object
      *        This method will create a new keyHandle. The key handle might contain either
      *        the raw key or a keyID depending on which Crypto implementation is used.
      *        To avoid leaking keys, API consumers must either call the DeleteKey method
      *        or save the entry within the ICDMonitoring Table before this object goes out of scope.
      *
      *        A new entry object should be used for each key when adding entries to the ICDMonitoring
      *        table.
      *
      * @param keyData A byte span containing the raw key
      * @return CHIP_ERROR CHIP_NO_ERROR     success
      *         CHIP_ERROR_INVALID_ARGUMENT  wrong size of the raw key
      *         CHIP_ERROR_INTERNAL          No KeyStore for the entry or Key Handle already present
      *         CHIP_ERROR_XXX               Crypto API related failure
      */
     CHIP_ERROR SetKey(ByteSpan keyData);
     CHIP_ERROR DeleteKey(void);
     inline bool IsValid()
     {
         return (symmetricKeystore != nullptr && keyHandleValid && fabricIndex != kUndefinedFabricIndex &&
                 checkInNodeID != kUndefinedNodeId);
     }

     ICDMonitoringEntry & operator=(const ICDMonitoringEntry & icdMonitoringEntry);

     /**
      * @brief Implement the key verification needed by the ICDManagement Server.
      *        Since for some key implementations we cannot retrieve the key from the AES128KeyHandle
      *        we must implement a way to deduce whether the verification key
      *        received is the same or at least works as the same way as the one stored.
      *
      *        This method will produce a random number and then encrypt it with the keyData.
      *        It will then decrypt it with the key stored in the entry. If the resulting decrypted
      *        challenge matches the randomly generated number, then we can safely assume that both key are interchangeable.
      *        This method cannot guarantee a perfect match since the probability of two keys generating the same output in AES128 is
      *        not 0 but 1/2^128 which is small enough for our purposes.
      *
      * @param keyData
      * @return bool True if the key is equivalent to the one stored, otherwise false
      */
     bool IsKeyEquivalent(ByteSpan keyData);

     chip::FabricIndex fabricIndex                           = kUndefinedFabricIndex;
     chip::NodeId checkInNodeID                              = kUndefinedNodeId;
     uint64_t monitoredSubject                               = static_cast<uint64_t>(0);
     app::Clusters::IcdManagement::ClientTypeEnum clientType = app::Clusters::IcdManagement::ClientTypeEnum::kPermanent;
     Crypto::Aes128KeyHandle aesKeyHandle                    = Crypto::Aes128KeyHandle();
     Crypto::Hmac128KeyHandle hmacKeyHandle                  = Crypto::Hmac128KeyHandle();
     bool keyHandleValid                                     = false;
     uint16_t index                                          = 0;
     Crypto::SymmetricKeystore * symmetricKeystore           = nullptr;
 };

 /**
  * @brief ICDMonitoringTable exists to manage the persistence of entries in the IcdManagement Cluster.
  *        To access persisted data with the ICDMonitoringTable class, instantiate an instance of this class
  *        and call the LoadFromStorage function.
  *
  *        This class can only manage one fabric at a time. The flow is load a fabric, execute necessary operations,
  *        save it if there are any changes and load another fabric.
  *
  *        Issue to refactor the class to use one entry for the entire table
  *        https://github.com/project-chip/connectedhomeip/issues/24288
  */

 struct ICDMonitoringTable
 {
     ICDMonitoringTable(PersistentStorageDelegate & storage, FabricIndex fabric, uint16_t limit,
                        Crypto::SymmetricKeystore * symmetricKeystore) :
         mStorage(&storage),
         mFabric(fabric), mLimit(limit), mSymmetricKeystore(symmetricKeystore)
     {}

     /**
      * @brief Returns the MonitoringRegistrationStruct entry at the given position.
      * @param index Zero-based position within the RegisteredClients table.
      * @param entry On success, contains the MonitoringRegistrationStruct matching the given index.
      * @return CHIP_NO_ERROR on success,
      *         CHIP_ERROR_NOT_FOUND if index is greater than the index of the last entry on the table.
      */
     CHIP_ERROR Get(uint16_t index, ICDMonitoringEntry & entry) const;

     /**
      * @brief Stores the MonitoringRegistrationStruct entry at the given position,
      *        overwriting any existing entry.
      * @param index Zero-based position within the RegisteredClients table.
      * @param entry On success, contains the MonitoringRegistrationStruct matching the given index.
      * @return CHIP_NO_ERROR on success
      */
     CHIP_ERROR Set(uint16_t index, const ICDMonitoringEntry & entry);

     /**
      * @brief Search the registered clients for an entry on the fabric whose checkInNodeID matches the given id.
      * @param id    NodeId to match.
      * @param entry On success, contains the MonitoringRegistrationStruct matching the given node ID.
      *  If found, entry.index contains the position of the entry in the table.
      *  If CHIP_ERROR_NOT_FOUND is returned, entry.index contains the total number of entries in the table.
      * @return CHIP_NO_ERROR if found, CHIP_ERROR_NOT_FOUND if no checkInNodeID matches the provided id.
      */
     CHIP_ERROR Find(NodeId id, ICDMonitoringEntry & entry);

     /**
      * @brief Removes the MonitoringRegistrationStruct entry at the given position,
      *        shifting down the upper entries.
      * @param index Zero-based position within the RegisteredClients table.
      * @return CHIP_NO_ERROR on success
      */
     CHIP_ERROR Remove(uint16_t index);

     /**
      * @brief Removes all the entries for the current fabricIndex.
      * @return CHIP_NO_ERROR on success
      */
     CHIP_ERROR RemoveAll();

     /**
      * @brief Check if the table is empty
      * @return True when there is no entry in the table. False if there is at least one
      */
     bool IsEmpty();

     /**
      * @return Maximum number of entries allowed in the RegisteredClients table.
      */
     uint16_t Limit() const;

 private:
     PersistentStorageDelegate * mStorage;
     FabricIndex mFabric;
     uint16_t mLimit                                = 0;
     Crypto::SymmetricKeystore * mSymmetricKeystore = nullptr;
 };

 } // namespace chip
	/**
	*
	* Copyright (c) 2023 Project CHIP Authors
	*
	* 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.
	*/
	#pragma once

	#include <crypto/CHIPCryptoPAL.h>
	#include <crypto/SessionKeystore.h>
	#include <lib/core/CHIPConfig.h>
	#include <lib/core/CHIPPersistentStorageDelegate.h>
	#include <lib/core/ClusterEnums.h>
	#include <lib/core/DataModelTypes.h>
	#include <lib/support/CodeUtils.h>
	#include <lib/support/PersistentData.h>
	#include <stddef.h>

	namespace chip {
	namespace Crypto {
	using SymmetricKeystore = SessionKeystore;
	}
	} // namespace chip

	namespace chip {

	inline constexpr size_t kICDMonitoringBufferSize = 60;

	struct ICDMonitoringEntry : public PersistentData<kICDMonitoringBufferSize>
	{

	ICDMonitoringEntry(FabricIndex fabric = kUndefinedFabricIndex, NodeId nodeId = kUndefinedNodeId)
	{
	this->fabricIndex = fabric;
	this->checkInNodeID = nodeId;
	this->monitoredSubject = nodeId;
	}

	ICDMonitoringEntry(Crypto::SymmetricKeystore * keyStore, FabricIndex fabric = kUndefinedFabricIndex,
	NodeId nodeId = kUndefinedNodeId)
	{
	this->fabricIndex = fabric;
	this->checkInNodeID = nodeId;
	this->monitoredSubject = nodeId;
	this->symmetricKeystore = keyStore;
	}

	CHIP_ERROR UpdateKey(StorageKeyName & key) override;
	CHIP_ERROR Serialize(TLV::TLVWriter & writer) const override;
	CHIP_ERROR Deserialize(TLV::TLVReader & reader) override;
	void Clear() override;
	/**
	* @brief Set the Key object
	* This method will create a new keyHandle. The key handle might contain either
	* the raw key or a keyID depending on which Crypto implementation is used.
	* To avoid leaking keys, API consumers must either call the DeleteKey method
	* or save the entry within the ICDMonitoring Table before this object goes out of scope.
	*
	* A new entry object should be used for each key when adding entries to the ICDMonitoring
	* table.
	*
	* @param keyData A byte span containing the raw key
	* @return CHIP_ERROR CHIP_NO_ERROR success
	* CHIP_ERROR_INVALID_ARGUMENT wrong size of the raw key
	* CHIP_ERROR_INTERNAL No KeyStore for the entry or Key Handle already present
	* CHIP_ERROR_XXX Crypto API related failure
	*/
	CHIP_ERROR SetKey(ByteSpan keyData);
	CHIP_ERROR DeleteKey(void);
	inline bool IsValid()
	{
	return (symmetricKeystore != nullptr && keyHandleValid && fabricIndex != kUndefinedFabricIndex &&
	checkInNodeID != kUndefinedNodeId);
	}

	ICDMonitoringEntry & operator=(const ICDMonitoringEntry & icdMonitoringEntry);

	/**
	* @brief Implement the key verification needed by the ICDManagement Server.
	* Since for some key implementations we cannot retrieve the key from the AES128KeyHandle
	* we must implement a way to deduce whether the verification key
	* received is the same or at least works as the same way as the one stored.
	*
	* This method will produce a random number and then encrypt it with the keyData.
	* It will then decrypt it with the key stored in the entry. If the resulting decrypted
	* challenge matches the randomly generated number, then we can safely assume that both key are interchangeable.
	* This method cannot guarantee a perfect match since the probability of two keys generating the same output in AES128 is
	* not 0 but 1/2^128 which is small enough for our purposes.
	*
	* @param keyData
	* @return bool True if the key is equivalent to the one stored, otherwise false
	*/
	bool IsKeyEquivalent(ByteSpan keyData);

	chip::FabricIndex fabricIndex = kUndefinedFabricIndex;
	chip::NodeId checkInNodeID = kUndefinedNodeId;
	uint64_t monitoredSubject = static_cast<uint64_t>(0);
	app::Clusters::IcdManagement::ClientTypeEnum clientType = app::Clusters::IcdManagement::ClientTypeEnum::kPermanent;
	Crypto::Aes128KeyHandle aesKeyHandle = Crypto::Aes128KeyHandle();
	Crypto::Hmac128KeyHandle hmacKeyHandle = Crypto::Hmac128KeyHandle();
	bool keyHandleValid = false;
	uint16_t index = 0;
	Crypto::SymmetricKeystore * symmetricKeystore = nullptr;
	};

	/**
	* @brief ICDMonitoringTable exists to manage the persistence of entries in the IcdManagement Cluster.
	* To access persisted data with the ICDMonitoringTable class, instantiate an instance of this class
	* and call the LoadFromStorage function.
	*
	* This class can only manage one fabric at a time. The flow is load a fabric, execute necessary operations,
	* save it if there are any changes and load another fabric.
	*
	* Issue to refactor the class to use one entry for the entire table
	* https://github.com/project-chip/connectedhomeip/issues/24288
	*/

	struct ICDMonitoringTable
	{
	ICDMonitoringTable(PersistentStorageDelegate & storage, FabricIndex fabric, uint16_t limit,
	Crypto::SymmetricKeystore * symmetricKeystore) :
	mStorage(&storage),
	mFabric(fabric), mLimit(limit), mSymmetricKeystore(symmetricKeystore)
	{}

	/**
	* @brief Returns the MonitoringRegistrationStruct entry at the given position.
	* @param index Zero-based position within the RegisteredClients table.
	* @param entry On success, contains the MonitoringRegistrationStruct matching the given index.
	* @return CHIP_NO_ERROR on success,
	* CHIP_ERROR_NOT_FOUND if index is greater than the index of the last entry on the table.
	*/
	CHIP_ERROR Get(uint16_t index, ICDMonitoringEntry & entry) const;

	/**
	* @brief Stores the MonitoringRegistrationStruct entry at the given position,
	* overwriting any existing entry.
	* @param index Zero-based position within the RegisteredClients table.
	* @param entry On success, contains the MonitoringRegistrationStruct matching the given index.
	* @return CHIP_NO_ERROR on success
	*/
	CHIP_ERROR Set(uint16_t index, const ICDMonitoringEntry & entry);

	/**
	* @brief Search the registered clients for an entry on the fabric whose checkInNodeID matches the given id.
	* @param id NodeId to match.
	* @param entry On success, contains the MonitoringRegistrationStruct matching the given node ID.
	* If found, entry.index contains the position of the entry in the table.
	* If CHIP_ERROR_NOT_FOUND is returned, entry.index contains the total number of entries in the table.
	* @return CHIP_NO_ERROR if found, CHIP_ERROR_NOT_FOUND if no checkInNodeID matches the provided id.
	*/
	CHIP_ERROR Find(NodeId id, ICDMonitoringEntry & entry);

	/**
	* @brief Removes the MonitoringRegistrationStruct entry at the given position,
	* shifting down the upper entries.
	* @param index Zero-based position within the RegisteredClients table.
	* @return CHIP_NO_ERROR on success
	*/
	CHIP_ERROR Remove(uint16_t index);

	/**
	* @brief Removes all the entries for the current fabricIndex.
	* @return CHIP_NO_ERROR on success
	*/
	CHIP_ERROR RemoveAll();

	/**
	* @brief Check if the table is empty
	* @return True when there is no entry in the table. False if there is at least one
	*/
	bool IsEmpty();

	/**
	* @return Maximum number of entries allowed in the RegisteredClients table.
	*/
	uint16_t Limit() const;

	private:
	PersistentStorageDelegate * mStorage;
	FabricIndex mFabric;
	uint16_t mLimit = 0;
	Crypto::SymmetricKeystore * mSymmetricKeystore = nullptr;
	};

	} // namespace chip