examples/energy-management-app/energy-management-common/src/DeviceEnergyManagementDelegateImpl.cpp - third_party/github/project-chip/connectedhomeip - Git at Google

 /*
  *
  *    Copyright (c) 2023 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 "DeviceEnergyManagementDelegateImpl.h"

 #include <app/EventLogging.h>

 using namespace chip;
 using namespace chip::app;
 using namespace chip::app::Clusters;
 using namespace chip::app::Clusters::DeviceEnergyManagement;
 using namespace chip::app::Clusters::DeviceEnergyManagement::Attributes;

 using chip::Optional;
 using namespace chip::app;
 using CostsList = DataModel::List<const Structs::CostStruct::Type>;

 /**
  * @brief Delegate handler for PowerAdjustRequest
  *
  * Note: checking of the validity of the PowerAdjustRequest has been done by the lower layer
  *
  * This function needs to notify the appliance that it should apply a new power setting.
  * It should:
  *   1) notify the appliance - if the appliance hardware cannot be adjusted, then return Failure
  *   2) start a timer (or restart the existing PowerAdjust timer) for duration seconds
  *   3) generate a PowerAdjustStart event (if there is not an existing PowerAdjustRequest running)
  *   4) if appropriate, update the forecast with the new expected end time
  *
  *  and when the timer expires:
  *   5) notify the appliance's that it can resume its intended power setting (or go idle)
  *   6) generate a PowerAdjustEnd event with cause NormalCompletion
  *   7) if necessary, update the forecast with new expected end time
  */
 Status DeviceEnergyManagementDelegate::PowerAdjustRequest(const int64_t power, const uint32_t duration, AdjustmentCauseEnum cause)
 {
     Status status = Status::UnsupportedCommand; // Status::Success;

     // TODO: implement
     mEsaState = ESAStateEnum::kPowerAdjustActive;

     // TODO:  Generate a PowerAdjustStart Event, then begins to adjust its power
     // When done, raise PowerAdjustEnd & ESAState set to kOnline.

     MatterReportingAttributeChangeCallback(mEndpointId, DeviceEnergyManagement::Id, ESAState::Id);

     return status;
 }
 /**
  * @brief Delegate handler for CancelPowerAdjustRequest
  *
  * Note: checking of the validity of the CancelPowerAdjustRequest has been done by the lower layer
  *
  * This function needs to notify the appliance that it should resume its intended power setting (or go idle).

  * It should:
  *   1) notify the appliance's that it can resume its intended power setting (or go idle)
  *   2) generate a PowerAdjustEnd event with cause code Cancelled
  *   3) if necessary, update the forecast with new expected end time
  */
 Status DeviceEnergyManagementDelegate::CancelPowerAdjustRequest()
 {
     Status status = Status::UnsupportedCommand; // Status::Success;

     // TODO: implement
     /* TODO:  If the command is accepted, the ESA SHALL generate an PowerAdjustEnd Event.    */
     mEsaState = ESAStateEnum::kOnline;
     MatterReportingAttributeChangeCallback(mEndpointId, DeviceEnergyManagement::Id, ESAState::Id);

     return status;
 }

 /**
  * @brief Delegate handler for StartTimeAdjustRequest
  *
  * Note: checking of the validity of the StartTimeAdjustRequest has been done by the lower layer
  *
  * This function needs to notify the appliance that the forecast has been updated by a client.
  *
  * It should:
  *      1) update the forecast attribute with the revised start time
  *      2) send a callback notification to the appliance so it can refresh its internal schedule
  */
 Status DeviceEnergyManagementDelegate::StartTimeAdjustRequest(const uint32_t requestedStartTime, AdjustmentCauseEnum cause)
 {
     DataModel::Nullable<Structs::ForecastStruct::Type> forecast = GetForecast();

     if (forecast.IsNull())
     {
         return Status::Failure;
     }

     uint32_t duration = forecast.Value().endTime - forecast.Value().startTime; // the current entire forecast duration

     /* Modify start time and end time */
     forecast.Value().startTime = requestedStartTime;
     forecast.Value().endTime   = requestedStartTime + duration;

     SetForecast(forecast); // This will increment forecast ID

     // TODO: callback to the appliance to notify it of a new start time

     return Status::Success;
 }
 /**
  * @brief Delegate handler for Pause Request
  *
  * Note: checking of the validity of the Pause Request has been done by the lower layer
  *
  * This function needs to notify the appliance that it should now pause.
  * It should:
  *   1) pause the appliance - if the appliance hardware cannot be paused, then return Failure
  *   2) start a timer for duration seconds
  *   3) generate a Paused event
  *   4) update the forecast with the new expected end time
  *
  *  and when the timer expires:
  *   5) restore the appliance's operational state
  *   6) generate a Resumed event
  *   7) if necessary, update the forecast with new expected end time
  */
 Status DeviceEnergyManagementDelegate::PauseRequest(const uint32_t duration, AdjustmentCauseEnum cause)
 {
     Status status = Status::UnsupportedCommand; // Status::Success;
     // TODO: implement the behaviour above
     return status;
 }

 /**
  * @brief Delegate handler for ResumeRequest
  *
  * Note: checking of the validity of the ResumeRequest has been done by the lower layer
  *
  * This function needs to notify the appliance that it should now resume operation
  *
  * It should:
  *   1) restore the appliance's operational state
  *   2) generate a Resumed event
  *   3) update the forecast with new expected end time (given that the pause duration was shorter than originally requested)
  *
  */
 Status DeviceEnergyManagementDelegate::ResumeRequest()
 {
     Status status = Status::UnsupportedCommand; // Status::Success;

     // TODO: implement the behaviour above
     SetESAState(ESAStateEnum::kOnline);

     return status;
 }

 /**
  * @brief Delegate handler for ModifyForecastRequest
  *
  * Note: Only basic checking of the validity of the ModifyForecastRequest has been
  * done by the lower layer. This is a more complex use-case and requires higher-level
  * work by the delegate.
  *
  * It should:
  *      1) determine if the new forecast adjustments are acceptable to the appliance
  *       - if not return Failure. For example, if it may cause the home to be too hot
  *         or too cold, or a battery to be insufficiently charged
  *      2) if the slot adjustments are acceptable, then update the forecast
  *      3) notify the appliance to follow the revised schedule
  */
 Status DeviceEnergyManagementDelegate::ModifyForecastRequest(
     const uint32_t forecastId, const DataModel::DecodableList<Structs::SlotAdjustmentStruct::DecodableType> & slotAdjustments,
     AdjustmentCauseEnum cause)
 {
     Status status = Status::UnsupportedCommand; // Status::Success;

     // TODO: implement the behaviour above
     return status;
 }

 /**
  * @brief Delegate handler for RequestConstraintBasedForecast
  *
  * Note: Only basic checking of the validity of the RequestConstraintBasedForecast has been
  * done by the lower layer. This is a more complex use-case and requires higher-level
  * work by the delegate.
  *
  * It should:
  *      1) perform a higher level optimization (e.g. using tariff information, and user preferences)
  *      2) if a solution can be found, then update the forecast, else return Failure
  *      3) notify the appliance to follow the revised schedule
  */
 Status DeviceEnergyManagementDelegate::RequestConstraintBasedForecast(
     const DataModel::DecodableList<Structs::ConstraintsStruct::DecodableType> & constraints, AdjustmentCauseEnum cause)
 {
     Status status = Status::UnsupportedCommand; // Status::Success;
     // TODO: implement the behaviour above
     return status;
 }

 /**
  * @brief Delegate handler for CancelRequest
  *
  * Note: This is a more complex use-case and requires higher-level work by the delegate.
  *
  * It SHALL:
  *      1) Check if the forecastUpdateReason was already InternalOptimization (and reject the command)
  *      2) Update its forecast (based on its optimization strategy) ignoring previous requests
  *      3) Update its Forecast attribute to match its new intended operation, and update the
  *         ForecastStruct.ForecastUpdateReason to `Internal Optimization`.
  */
 Status DeviceEnergyManagementDelegate::CancelRequest()
 {
     Status status = Status::UnsupportedCommand; // Status::Success;
     // TODO: implement the behaviour above
     return status;
 }

 // ------------------------------------------------------------------
 // Get attribute methods
 ESATypeEnum DeviceEnergyManagementDelegate::GetESAType()
 {
     return mEsaType;
 }

 bool DeviceEnergyManagementDelegate::GetESACanGenerate()
 {
     return mEsaCanGenerate;
 }

 ESAStateEnum DeviceEnergyManagementDelegate::GetESAState()
 {
     return mEsaState;
 }

 int64_t DeviceEnergyManagementDelegate::GetAbsMinPower()
 {
     return mAbsMinPower;
 }

 int64_t DeviceEnergyManagementDelegate::GetAbsMaxPower()
 {
     return mAbsMaxPower;
 }

 PowerAdjustmentCapability::TypeInfo::Type DeviceEnergyManagementDelegate::GetPowerAdjustmentCapability()
 {
     return mPowerAdjustmentCapability;
 }

 DataModel::Nullable<Structs::ForecastStruct::Type> DeviceEnergyManagementDelegate::GetForecast()
 {
     return mForecast;
 }

 OptOutStateEnum DeviceEnergyManagementDelegate::GetOptOutState()
 {
     return mOptOutState;
 }

 // ------------------------------------------------------------------
 // Set attribute methods

 CHIP_ERROR DeviceEnergyManagementDelegate::SetESAType(ESATypeEnum newValue)
 {
     ESATypeEnum oldValue = mEsaType;

     if (newValue >= ESATypeEnum::kUnknownEnumValue)
     {
         return CHIP_IM_GLOBAL_STATUS(ConstraintError);
     }

     mEsaType = newValue;
     if (oldValue != newValue)
     {
         ChipLogDetail(AppServer, "mEsaType updated to %d", static_cast<int>(mEsaType));
         MatterReportingAttributeChangeCallback(mEndpointId, DeviceEnergyManagement::Id, ESAType::Id);
     }

     return CHIP_NO_ERROR;
 }

 CHIP_ERROR DeviceEnergyManagementDelegate::SetESACanGenerate(bool newValue)
 {
     bool oldValue = mEsaCanGenerate;

     mEsaCanGenerate = newValue;
     if (oldValue != newValue)
     {
         ChipLogDetail(AppServer, "mEsaCanGenerate updated to %d", static_cast<int>(mEsaCanGenerate));
         MatterReportingAttributeChangeCallback(mEndpointId, DeviceEnergyManagement::Id, ESACanGenerate::Id);
     }

     return CHIP_NO_ERROR;
 }

 CHIP_ERROR DeviceEnergyManagementDelegate::SetESAState(ESAStateEnum newValue)
 {
     ESAStateEnum oldValue = mEsaState;

     if (newValue >= ESAStateEnum::kUnknownEnumValue)
     {
         return CHIP_IM_GLOBAL_STATUS(ConstraintError);
     }

     mEsaState = newValue;
     if (oldValue != newValue)
     {
         ChipLogDetail(AppServer, "mEsaState updated to %d", static_cast<int>(mEsaState));
         MatterReportingAttributeChangeCallback(mEndpointId, DeviceEnergyManagement::Id, ESAState::Id);
     }

     return CHIP_NO_ERROR;
 }

 CHIP_ERROR DeviceEnergyManagementDelegate::SetAbsMinPower(int64_t newValue)
 {
     int64_t oldValue = mAbsMinPower;

     mAbsMinPower = newValue;
     if (oldValue != newValue)
     {
         ChipLogDetail(AppServer, "mAbsMinPower updated to %d", static_cast<int>(mAbsMinPower));
         MatterReportingAttributeChangeCallback(mEndpointId, DeviceEnergyManagement::Id, AbsMinPower::Id);
     }

     return CHIP_NO_ERROR;
 }

 CHIP_ERROR DeviceEnergyManagementDelegate::SetAbsMaxPower(int64_t newValue)
 {
     int64_t oldValue = mAbsMaxPower;

     mAbsMaxPower = newValue;
     if (oldValue != newValue)
     {
         ChipLogDetail(AppServer, "mAbsMaxPower updated to %d", static_cast<int>(mAbsMaxPower));
         MatterReportingAttributeChangeCallback(mEndpointId, DeviceEnergyManagement::Id, AbsMaxPower::Id);
     }

     return CHIP_NO_ERROR;
 }

 CHIP_ERROR
 DeviceEnergyManagementDelegate::SetPowerAdjustmentCapability(PowerAdjustmentCapability::TypeInfo::Type powerAdjustmentCapability)
 {
     // TODO see Issue #31147
     return CHIP_NO_ERROR;
 }

 CHIP_ERROR DeviceEnergyManagementDelegate::SetForecast(DataModel::Nullable<Structs::ForecastStruct::Type> forecast)
 {
     // TODO see Issue #31147

     return CHIP_NO_ERROR;
 }
	/*
	*
	* Copyright (c) 2023 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 "DeviceEnergyManagementDelegateImpl.h"

	#include <app/EventLogging.h>

	using namespace chip;
	using namespace chip::app;
	using namespace chip::app::Clusters;
	using namespace chip::app::Clusters::DeviceEnergyManagement;
	using namespace chip::app::Clusters::DeviceEnergyManagement::Attributes;

	using chip::Optional;
	using namespace chip::app;
	using CostsList = DataModel::List<const Structs::CostStruct::Type>;

	/**
	* @brief Delegate handler for PowerAdjustRequest
	*
	* Note: checking of the validity of the PowerAdjustRequest has been done by the lower layer
	*
	* This function needs to notify the appliance that it should apply a new power setting.
	* It should:
	* 1) notify the appliance - if the appliance hardware cannot be adjusted, then return Failure
	* 2) start a timer (or restart the existing PowerAdjust timer) for duration seconds
	* 3) generate a PowerAdjustStart event (if there is not an existing PowerAdjustRequest running)
	* 4) if appropriate, update the forecast with the new expected end time
	*
	* and when the timer expires:
	* 5) notify the appliance's that it can resume its intended power setting (or go idle)
	* 6) generate a PowerAdjustEnd event with cause NormalCompletion
	* 7) if necessary, update the forecast with new expected end time
	*/
	Status DeviceEnergyManagementDelegate::PowerAdjustRequest(const int64_t power, const uint32_t duration, AdjustmentCauseEnum cause)
	{
	Status status = Status::UnsupportedCommand; // Status::Success;

	// TODO: implement
	mEsaState = ESAStateEnum::kPowerAdjustActive;

	// TODO: Generate a PowerAdjustStart Event, then begins to adjust its power
	// When done, raise PowerAdjustEnd & ESAState set to kOnline.

	MatterReportingAttributeChangeCallback(mEndpointId, DeviceEnergyManagement::Id, ESAState::Id);

	return status;
	}
	/**
	* @brief Delegate handler for CancelPowerAdjustRequest
	*
	* Note: checking of the validity of the CancelPowerAdjustRequest has been done by the lower layer
	*
	* This function needs to notify the appliance that it should resume its intended power setting (or go idle).

	* It should:
	* 1) notify the appliance's that it can resume its intended power setting (or go idle)
	* 2) generate a PowerAdjustEnd event with cause code Cancelled
	* 3) if necessary, update the forecast with new expected end time
	*/
	Status DeviceEnergyManagementDelegate::CancelPowerAdjustRequest()
	{
	Status status = Status::UnsupportedCommand; // Status::Success;

	// TODO: implement
	/* TODO: If the command is accepted, the ESA SHALL generate an PowerAdjustEnd Event. */
	mEsaState = ESAStateEnum::kOnline;
	MatterReportingAttributeChangeCallback(mEndpointId, DeviceEnergyManagement::Id, ESAState::Id);

	return status;
	}

	/**
	* @brief Delegate handler for StartTimeAdjustRequest
	*
	* Note: checking of the validity of the StartTimeAdjustRequest has been done by the lower layer
	*
	* This function needs to notify the appliance that the forecast has been updated by a client.
	*
	* It should:
	* 1) update the forecast attribute with the revised start time
	* 2) send a callback notification to the appliance so it can refresh its internal schedule
	*/
	Status DeviceEnergyManagementDelegate::StartTimeAdjustRequest(const uint32_t requestedStartTime, AdjustmentCauseEnum cause)
	{
	DataModel::Nullable<Structs::ForecastStruct::Type> forecast = GetForecast();

	if (forecast.IsNull())
	{
	return Status::Failure;
	}

	uint32_t duration = forecast.Value().endTime - forecast.Value().startTime; // the current entire forecast duration

	/* Modify start time and end time */
	forecast.Value().startTime = requestedStartTime;
	forecast.Value().endTime = requestedStartTime + duration;

	SetForecast(forecast); // This will increment forecast ID

	// TODO: callback to the appliance to notify it of a new start time

	return Status::Success;
	}
	/**
	* @brief Delegate handler for Pause Request
	*
	* Note: checking of the validity of the Pause Request has been done by the lower layer
	*
	* This function needs to notify the appliance that it should now pause.
	* It should:
	* 1) pause the appliance - if the appliance hardware cannot be paused, then return Failure
	* 2) start a timer for duration seconds
	* 3) generate a Paused event
	* 4) update the forecast with the new expected end time
	*
	* and when the timer expires:
	* 5) restore the appliance's operational state
	* 6) generate a Resumed event
	* 7) if necessary, update the forecast with new expected end time
	*/
	Status DeviceEnergyManagementDelegate::PauseRequest(const uint32_t duration, AdjustmentCauseEnum cause)
	{
	Status status = Status::UnsupportedCommand; // Status::Success;
	// TODO: implement the behaviour above
	return status;
	}

	/**
	* @brief Delegate handler for ResumeRequest
	*
	* Note: checking of the validity of the ResumeRequest has been done by the lower layer
	*
	* This function needs to notify the appliance that it should now resume operation
	*
	* It should:
	* 1) restore the appliance's operational state
	* 2) generate a Resumed event
	* 3) update the forecast with new expected end time (given that the pause duration was shorter than originally requested)
	*
	*/
	Status DeviceEnergyManagementDelegate::ResumeRequest()
	{
	Status status = Status::UnsupportedCommand; // Status::Success;

	// TODO: implement the behaviour above
	SetESAState(ESAStateEnum::kOnline);

	return status;
	}

	/**
	* @brief Delegate handler for ModifyForecastRequest
	*
	* Note: Only basic checking of the validity of the ModifyForecastRequest has been
	* done by the lower layer. This is a more complex use-case and requires higher-level
	* work by the delegate.
	*
	* It should:
	* 1) determine if the new forecast adjustments are acceptable to the appliance
	* - if not return Failure. For example, if it may cause the home to be too hot
	* or too cold, or a battery to be insufficiently charged
	* 2) if the slot adjustments are acceptable, then update the forecast
	* 3) notify the appliance to follow the revised schedule
	*/
	Status DeviceEnergyManagementDelegate::ModifyForecastRequest(
	const uint32_t forecastId, const DataModel::DecodableList<Structs::SlotAdjustmentStruct::DecodableType> & slotAdjustments,
	AdjustmentCauseEnum cause)
	{
	Status status = Status::UnsupportedCommand; // Status::Success;

	// TODO: implement the behaviour above
	return status;
	}

	/**
	* @brief Delegate handler for RequestConstraintBasedForecast
	*
	* Note: Only basic checking of the validity of the RequestConstraintBasedForecast has been
	* done by the lower layer. This is a more complex use-case and requires higher-level
	* work by the delegate.
	*
	* It should:
	* 1) perform a higher level optimization (e.g. using tariff information, and user preferences)
	* 2) if a solution can be found, then update the forecast, else return Failure
	* 3) notify the appliance to follow the revised schedule
	*/
	Status DeviceEnergyManagementDelegate::RequestConstraintBasedForecast(
	const DataModel::DecodableList<Structs::ConstraintsStruct::DecodableType> & constraints, AdjustmentCauseEnum cause)
	{
	Status status = Status::UnsupportedCommand; // Status::Success;
	// TODO: implement the behaviour above
	return status;
	}

	/**
	* @brief Delegate handler for CancelRequest
	*
	* Note: This is a more complex use-case and requires higher-level work by the delegate.
	*
	* It SHALL:
	* 1) Check if the forecastUpdateReason was already InternalOptimization (and reject the command)
	* 2) Update its forecast (based on its optimization strategy) ignoring previous requests
	* 3) Update its Forecast attribute to match its new intended operation, and update the
	* ForecastStruct.ForecastUpdateReason to `Internal Optimization`.
	*/
	Status DeviceEnergyManagementDelegate::CancelRequest()
	{
	Status status = Status::UnsupportedCommand; // Status::Success;
	// TODO: implement the behaviour above
	return status;
	}

	// ------------------------------------------------------------------
	// Get attribute methods
	ESATypeEnum DeviceEnergyManagementDelegate::GetESAType()
	{
	return mEsaType;
	}

	bool DeviceEnergyManagementDelegate::GetESACanGenerate()
	{
	return mEsaCanGenerate;
	}

	ESAStateEnum DeviceEnergyManagementDelegate::GetESAState()
	{
	return mEsaState;
	}

	int64_t DeviceEnergyManagementDelegate::GetAbsMinPower()
	{
	return mAbsMinPower;
	}

	int64_t DeviceEnergyManagementDelegate::GetAbsMaxPower()
	{
	return mAbsMaxPower;
	}

	PowerAdjustmentCapability::TypeInfo::Type DeviceEnergyManagementDelegate::GetPowerAdjustmentCapability()
	{
	return mPowerAdjustmentCapability;
	}

	DataModel::Nullable<Structs::ForecastStruct::Type> DeviceEnergyManagementDelegate::GetForecast()
	{
	return mForecast;
	}

	OptOutStateEnum DeviceEnergyManagementDelegate::GetOptOutState()
	{
	return mOptOutState;
	}

	// ------------------------------------------------------------------
	// Set attribute methods

	CHIP_ERROR DeviceEnergyManagementDelegate::SetESAType(ESATypeEnum newValue)
	{
	ESATypeEnum oldValue = mEsaType;

	if (newValue >= ESATypeEnum::kUnknownEnumValue)
	{
	return CHIP_IM_GLOBAL_STATUS(ConstraintError);
	}

	mEsaType = newValue;
	if (oldValue != newValue)
	{
	ChipLogDetail(AppServer, "mEsaType updated to %d", static_cast<int>(mEsaType));
	MatterReportingAttributeChangeCallback(mEndpointId, DeviceEnergyManagement::Id, ESAType::Id);
	}

	return CHIP_NO_ERROR;
	}

	CHIP_ERROR DeviceEnergyManagementDelegate::SetESACanGenerate(bool newValue)
	{
	bool oldValue = mEsaCanGenerate;

	mEsaCanGenerate = newValue;
	if (oldValue != newValue)
	{
	ChipLogDetail(AppServer, "mEsaCanGenerate updated to %d", static_cast<int>(mEsaCanGenerate));
	MatterReportingAttributeChangeCallback(mEndpointId, DeviceEnergyManagement::Id, ESACanGenerate::Id);
	}

	return CHIP_NO_ERROR;
	}

	CHIP_ERROR DeviceEnergyManagementDelegate::SetESAState(ESAStateEnum newValue)
	{
	ESAStateEnum oldValue = mEsaState;

	if (newValue >= ESAStateEnum::kUnknownEnumValue)
	{
	return CHIP_IM_GLOBAL_STATUS(ConstraintError);
	}

	mEsaState = newValue;
	if (oldValue != newValue)
	{
	ChipLogDetail(AppServer, "mEsaState updated to %d", static_cast<int>(mEsaState));
	MatterReportingAttributeChangeCallback(mEndpointId, DeviceEnergyManagement::Id, ESAState::Id);
	}

	return CHIP_NO_ERROR;
	}

	CHIP_ERROR DeviceEnergyManagementDelegate::SetAbsMinPower(int64_t newValue)
	{
	int64_t oldValue = mAbsMinPower;

	mAbsMinPower = newValue;
	if (oldValue != newValue)
	{
	ChipLogDetail(AppServer, "mAbsMinPower updated to %d", static_cast<int>(mAbsMinPower));
	MatterReportingAttributeChangeCallback(mEndpointId, DeviceEnergyManagement::Id, AbsMinPower::Id);
	}

	return CHIP_NO_ERROR;
	}

	CHIP_ERROR DeviceEnergyManagementDelegate::SetAbsMaxPower(int64_t newValue)
	{
	int64_t oldValue = mAbsMaxPower;

	mAbsMaxPower = newValue;
	if (oldValue != newValue)
	{
	ChipLogDetail(AppServer, "mAbsMaxPower updated to %d", static_cast<int>(mAbsMaxPower));
	MatterReportingAttributeChangeCallback(mEndpointId, DeviceEnergyManagement::Id, AbsMaxPower::Id);
	}

	return CHIP_NO_ERROR;
	}

	CHIP_ERROR
	DeviceEnergyManagementDelegate::SetPowerAdjustmentCapability(PowerAdjustmentCapability::TypeInfo::Type powerAdjustmentCapability)
	{
	// TODO see Issue #31147
	return CHIP_NO_ERROR;
	}

	CHIP_ERROR DeviceEnergyManagementDelegate::SetForecast(DataModel::Nullable<Structs::ForecastStruct::Type> forecast)
	{
	// TODO see Issue #31147

	return CHIP_NO_ERROR;
	}