src/app/AttributePathExpandIterator-DataModel.cpp - third_party/github/project-chip/connectedhomeip - Git at Google

 /*
  *    Copyright (c) 2024 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.
  */
 #include "lib/support/CodeUtils.h"
 #include <app/AttributePathExpandIterator-DataModel.h>
 #include <app/GlobalAttributes.h>

 using namespace chip::app::DataModel;

 namespace chip {
 namespace app {

 AttributePathExpandIteratorDataModel::AttributePathExpandIteratorDataModel(
     DataModel::Provider * provider, SingleLinkedListNode<AttributePathParams> * attributePath) :
     mDataModelProvider(provider),
     mpAttributePath(attributePath), mOutputPath(kInvalidEndpointId, kInvalidClusterId, kInvalidAttributeId)

 {
     mOutputPath.mExpanded = true; // this is reset in 'next' if needed

     // Make the iterator ready to emit the first valid path in the list.
     // TODO: the bool return value here is completely unchecked
     Next();
 }

 bool AttributePathExpandIteratorDataModel::IsValidAttributeId(AttributeId attributeId)
 {
     switch (attributeId)
     {
     case Clusters::Globals::Attributes::GeneratedCommandList::Id:
     case Clusters::Globals::Attributes::AcceptedCommandList::Id:
     case Clusters::Globals::Attributes::AttributeList::Id:
         return true;
     default:
         break;
     }

     const ConcreteAttributePath attributePath(mOutputPath.mEndpointId, mOutputPath.mClusterId, attributeId);
     return mDataModelProvider->GetAttributeInfo(attributePath).has_value();
 }

 std::optional<AttributeId> AttributePathExpandIteratorDataModel::NextAttributeId()
 {
     if (mOutputPath.mAttributeId == kInvalidAttributeId)
     {
         if (mpAttributePath->mValue.HasWildcardAttributeId())
         {
             AttributeEntry entry = mDataModelProvider->FirstAttribute(mOutputPath);
             return entry.IsValid()                                         //
                 ? entry.path.mAttributeId                                  //
                 : Clusters::Globals::Attributes::GeneratedCommandList::Id; //
         }

         // We allow fixed attribute IDs if and only if they are valid:
         //    - they may be GLOBAL attributes OR
         //    - they are valid attributes for this cluster
         if (IsValidAttributeId(mpAttributePath->mValue.mAttributeId))
         {
             return mpAttributePath->mValue.mAttributeId;
         }

         return std::nullopt;
     }

     // advance the existing attribute id if it can be advanced
     VerifyOrReturnValue(mpAttributePath->mValue.HasWildcardAttributeId(), std::nullopt);

     // Ensure (including ordering) that GlobalAttributesNotInMetadata is reported as needed
     for (unsigned i = 0; i < ArraySize(GlobalAttributesNotInMetadata); i++)
     {
         if (GlobalAttributesNotInMetadata[i] != mOutputPath.mAttributeId)
         {
             continue;
         }

         unsigned nextAttributeIndex = i + 1;
         if (nextAttributeIndex < ArraySize(GlobalAttributesNotInMetadata))
         {
             return GlobalAttributesNotInMetadata[nextAttributeIndex];
         }

         // reached the end of global attributes
         return std::nullopt;
     }

     AttributeEntry entry = mDataModelProvider->NextAttribute(mOutputPath);
     if (entry.IsValid())
     {
         return entry.path.mAttributeId;
     }

     // Finished the data model, start with global attributes
     static_assert(ArraySize(GlobalAttributesNotInMetadata) > 0);
     return GlobalAttributesNotInMetadata[0];
 }

 std::optional<ClusterId> AttributePathExpandIteratorDataModel::NextClusterId()
 {

     if (mOutputPath.mClusterId == kInvalidClusterId)
     {
         if (mpAttributePath->mValue.HasWildcardClusterId())
         {
             ClusterEntry entry = mDataModelProvider->FirstCluster(mOutputPath.mEndpointId);
             return entry.IsValid() ? std::make_optional(entry.path.mClusterId) : std::nullopt;
         }

         // only return a cluster if it is valid
         const ConcreteClusterPath clusterPath(mOutputPath.mEndpointId, mpAttributePath->mValue.mClusterId);
         if (!mDataModelProvider->GetClusterInfo(clusterPath).has_value())
         {
             return std::nullopt;
         }

         return mpAttributePath->mValue.mClusterId;
     }

     VerifyOrReturnValue(mpAttributePath->mValue.HasWildcardClusterId(), std::nullopt);

     ClusterEntry entry = mDataModelProvider->NextCluster(mOutputPath);
     return entry.IsValid() ? std::make_optional(entry.path.mClusterId) : std::nullopt;
 }

 std::optional<ClusterId> AttributePathExpandIteratorDataModel::NextEndpointId()
 {
     if (mOutputPath.mEndpointId == kInvalidEndpointId)
     {
         if (mpAttributePath->mValue.HasWildcardEndpointId())
         {
             EndpointId id = mDataModelProvider->FirstEndpoint();
             return (id != kInvalidEndpointId) ? std::make_optional(id) : std::nullopt;
         }

         return mpAttributePath->mValue.mEndpointId;
     }

     VerifyOrReturnValue(mpAttributePath->mValue.HasWildcardEndpointId(), std::nullopt);

     EndpointId id = mDataModelProvider->NextEndpoint(mOutputPath.mEndpointId);
     return (id != kInvalidEndpointId) ? std::make_optional(id) : std::nullopt;
 }

 void AttributePathExpandIteratorDataModel::ResetCurrentCluster()
 {
     // If this is a null iterator, or the attribute id of current cluster info is not a wildcard attribute id, then this function
     // will do nothing, since we won't be expanding the wildcard attribute ids under a cluster.
     VerifyOrReturn(mpAttributePath != nullptr && mpAttributePath->mValue.HasWildcardAttributeId());

     // Reset path expansion to ask for the first attribute of the current cluster
     mOutputPath.mAttributeId = kInvalidAttributeId;
     mOutputPath.mExpanded    = true; // we know this is a wildcard attribute
     Next();
 }

 bool AttributePathExpandIteratorDataModel::AdvanceOutputPath()
 {
     if (!mpAttributePath->mValue.IsWildcardPath())
     {
         if (mOutputPath.mEndpointId != kInvalidEndpointId)
         {
             return false; // cannot expand non-wildcard path
         }

         mOutputPath.mEndpointId  = mpAttributePath->mValue.mEndpointId;
         mOutputPath.mClusterId   = mpAttributePath->mValue.mClusterId;
         mOutputPath.mAttributeId = mpAttributePath->mValue.mAttributeId;
         mOutputPath.mExpanded    = false;
         return true;
     }

     while (true)
     {
         if (mOutputPath.mClusterId != kInvalidClusterId)
         {

             std::optional<AttributeId> nextAttribute = NextAttributeId();
             if (nextAttribute.has_value())
             {
                 mOutputPath.mAttributeId = *nextAttribute;
                 return true;
             }
         }

         // no valid attribute, try to advance the cluster, see if a suitable one exists
         if (mOutputPath.mEndpointId != kInvalidEndpointId)
         {
             std::optional<ClusterId> nextCluster = NextClusterId();
             if (nextCluster.has_value())
             {
                 mOutputPath.mClusterId   = *nextCluster;
                 mOutputPath.mAttributeId = kInvalidAttributeId; // restarts attributes
                 continue;
             }
         }

         // no valid cluster, try advance the endpoint, see if a suitable on exists
         std::optional<EndpointId> nextEndpoint = NextEndpointId();
         if (nextEndpoint.has_value())
         {
             mOutputPath.mEndpointId = *nextEndpoint;
             mOutputPath.mClusterId  = kInvalidClusterId; // restarts clusters
             continue;
         }
         return false;
     }
 }

 bool AttributePathExpandIteratorDataModel::Next()
 {
     while (mpAttributePath != nullptr)
     {
         if (AdvanceOutputPath())
         {
             return true;
         }
         mpAttributePath       = mpAttributePath->mpNext;
         mOutputPath           = ConcreteReadAttributePath(kInvalidEndpointId, kInvalidClusterId, kInvalidAttributeId);
         mOutputPath.mExpanded = true; // this is reset to false on advancement if needed
     }

     mOutputPath = ConcreteReadAttributePath();
     return false;
 }

 } // namespace app
 } // namespace chip
	/*
	* Copyright (c) 2024 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.
	*/
	#include "lib/support/CodeUtils.h"
	#include <app/AttributePathExpandIterator-DataModel.h>
	#include <app/GlobalAttributes.h>

	using namespace chip::app::DataModel;

	namespace chip {
	namespace app {

	AttributePathExpandIteratorDataModel::AttributePathExpandIteratorDataModel(
	DataModel::Provider * provider, SingleLinkedListNode<AttributePathParams> * attributePath) :
	mDataModelProvider(provider),
	mpAttributePath(attributePath), mOutputPath(kInvalidEndpointId, kInvalidClusterId, kInvalidAttributeId)

	{
	mOutputPath.mExpanded = true; // this is reset in 'next' if needed

	// Make the iterator ready to emit the first valid path in the list.
	// TODO: the bool return value here is completely unchecked
	Next();
	}

	bool AttributePathExpandIteratorDataModel::IsValidAttributeId(AttributeId attributeId)
	{
	switch (attributeId)
	{
	case Clusters::Globals::Attributes::GeneratedCommandList::Id:
	case Clusters::Globals::Attributes::AcceptedCommandList::Id:
	case Clusters::Globals::Attributes::AttributeList::Id:
	return true;
	default:
	break;
	}

	const ConcreteAttributePath attributePath(mOutputPath.mEndpointId, mOutputPath.mClusterId, attributeId);
	return mDataModelProvider->GetAttributeInfo(attributePath).has_value();
	}

	std::optional<AttributeId> AttributePathExpandIteratorDataModel::NextAttributeId()
	{
	if (mOutputPath.mAttributeId == kInvalidAttributeId)
	{
	if (mpAttributePath->mValue.HasWildcardAttributeId())
	{
	AttributeEntry entry = mDataModelProvider->FirstAttribute(mOutputPath);
	return entry.IsValid() //
	? entry.path.mAttributeId //
	: Clusters::Globals::Attributes::GeneratedCommandList::Id; //
	}

	// We allow fixed attribute IDs if and only if they are valid:
	// - they may be GLOBAL attributes OR
	// - they are valid attributes for this cluster
	if (IsValidAttributeId(mpAttributePath->mValue.mAttributeId))
	{
	return mpAttributePath->mValue.mAttributeId;
	}

	return std::nullopt;
	}

	// advance the existing attribute id if it can be advanced
	VerifyOrReturnValue(mpAttributePath->mValue.HasWildcardAttributeId(), std::nullopt);

	// Ensure (including ordering) that GlobalAttributesNotInMetadata is reported as needed
	for (unsigned i = 0; i < ArraySize(GlobalAttributesNotInMetadata); i++)
	{
	if (GlobalAttributesNotInMetadata[i] != mOutputPath.mAttributeId)
	{
	continue;
	}

	unsigned nextAttributeIndex = i + 1;
	if (nextAttributeIndex < ArraySize(GlobalAttributesNotInMetadata))
	{
	return GlobalAttributesNotInMetadata[nextAttributeIndex];
	}

	// reached the end of global attributes
	return std::nullopt;
	}

	AttributeEntry entry = mDataModelProvider->NextAttribute(mOutputPath);
	if (entry.IsValid())
	{
	return entry.path.mAttributeId;
	}

	// Finished the data model, start with global attributes
	static_assert(ArraySize(GlobalAttributesNotInMetadata) > 0);
	return GlobalAttributesNotInMetadata[0];
	}

	std::optional<ClusterId> AttributePathExpandIteratorDataModel::NextClusterId()
	{

	if (mOutputPath.mClusterId == kInvalidClusterId)
	{
	if (mpAttributePath->mValue.HasWildcardClusterId())
	{
	ClusterEntry entry = mDataModelProvider->FirstCluster(mOutputPath.mEndpointId);
	return entry.IsValid() ? std::make_optional(entry.path.mClusterId) : std::nullopt;
	}

	// only return a cluster if it is valid
	const ConcreteClusterPath clusterPath(mOutputPath.mEndpointId, mpAttributePath->mValue.mClusterId);
	if (!mDataModelProvider->GetClusterInfo(clusterPath).has_value())
	{
	return std::nullopt;
	}

	return mpAttributePath->mValue.mClusterId;
	}

	VerifyOrReturnValue(mpAttributePath->mValue.HasWildcardClusterId(), std::nullopt);

	ClusterEntry entry = mDataModelProvider->NextCluster(mOutputPath);
	return entry.IsValid() ? std::make_optional(entry.path.mClusterId) : std::nullopt;
	}

	std::optional<ClusterId> AttributePathExpandIteratorDataModel::NextEndpointId()
	{
	if (mOutputPath.mEndpointId == kInvalidEndpointId)
	{
	if (mpAttributePath->mValue.HasWildcardEndpointId())
	{
	EndpointId id = mDataModelProvider->FirstEndpoint();
	return (id != kInvalidEndpointId) ? std::make_optional(id) : std::nullopt;
	}

	return mpAttributePath->mValue.mEndpointId;
	}

	VerifyOrReturnValue(mpAttributePath->mValue.HasWildcardEndpointId(), std::nullopt);

	EndpointId id = mDataModelProvider->NextEndpoint(mOutputPath.mEndpointId);
	return (id != kInvalidEndpointId) ? std::make_optional(id) : std::nullopt;
	}

	void AttributePathExpandIteratorDataModel::ResetCurrentCluster()
	{
	// If this is a null iterator, or the attribute id of current cluster info is not a wildcard attribute id, then this function
	// will do nothing, since we won't be expanding the wildcard attribute ids under a cluster.
	VerifyOrReturn(mpAttributePath != nullptr && mpAttributePath->mValue.HasWildcardAttributeId());

	// Reset path expansion to ask for the first attribute of the current cluster
	mOutputPath.mAttributeId = kInvalidAttributeId;
	mOutputPath.mExpanded = true; // we know this is a wildcard attribute
	Next();
	}

	bool AttributePathExpandIteratorDataModel::AdvanceOutputPath()
	{
	if (!mpAttributePath->mValue.IsWildcardPath())
	{
	if (mOutputPath.mEndpointId != kInvalidEndpointId)
	{
	return false; // cannot expand non-wildcard path
	}

	mOutputPath.mEndpointId = mpAttributePath->mValue.mEndpointId;
	mOutputPath.mClusterId = mpAttributePath->mValue.mClusterId;
	mOutputPath.mAttributeId = mpAttributePath->mValue.mAttributeId;
	mOutputPath.mExpanded = false;
	return true;
	}

	while (true)
	{
	if (mOutputPath.mClusterId != kInvalidClusterId)
	{

	std::optional<AttributeId> nextAttribute = NextAttributeId();
	if (nextAttribute.has_value())
	{
	mOutputPath.mAttributeId = *nextAttribute;
	return true;
	}
	}

	// no valid attribute, try to advance the cluster, see if a suitable one exists
	if (mOutputPath.mEndpointId != kInvalidEndpointId)
	{
	std::optional<ClusterId> nextCluster = NextClusterId();
	if (nextCluster.has_value())
	{
	mOutputPath.mClusterId = *nextCluster;
	mOutputPath.mAttributeId = kInvalidAttributeId; // restarts attributes
	continue;
	}
	}

	// no valid cluster, try advance the endpoint, see if a suitable on exists
	std::optional<EndpointId> nextEndpoint = NextEndpointId();
	if (nextEndpoint.has_value())
	{
	mOutputPath.mEndpointId = *nextEndpoint;
	mOutputPath.mClusterId = kInvalidClusterId; // restarts clusters
	continue;
	}
	return false;
	}
	}

	bool AttributePathExpandIteratorDataModel::Next()
	{
	while (mpAttributePath != nullptr)
	{
	if (AdvanceOutputPath())
	{
	return true;
	}
	mpAttributePath = mpAttributePath->mpNext;
	mOutputPath = ConcreteReadAttributePath(kInvalidEndpointId, kInvalidClusterId, kInvalidAttributeId);
	mOutputPath.mExpanded = true; // this is reset to false on advancement if needed
	}

	mOutputPath = ConcreteReadAttributePath();
	return false;
	}

	} // namespace app
	} // namespace chip