examples/window-app/nrfconnect/main/WindowCovering.cpp - third_party/github/project-chip/connectedhomeip - Git at Google

 /*
  *    Copyright (c) 2022 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 "WindowCovering.h"
 #include "AppConfig.h"
 #include "PWMDevice.h"

 #include <dk_buttons_and_leds.h>

 #include <app-common/zap-generated/attributes/Accessors.h>
 #include <app/util/af.h>
 #include <platform/CHIPDeviceLayer.h>
 #include <zephyr/logging/log.h>
 #include <zephyr/zephyr.h>

 LOG_MODULE_DECLARE(app, CONFIG_CHIP_APP_LOG_LEVEL);

 using namespace ::chip::Credentials;
 using namespace ::chip::DeviceLayer;
 using namespace chip::app::Clusters::WindowCovering;

 static const struct pwm_dt_spec sLiftPwmDevice = PWM_DT_SPEC_GET(DT_ALIAS(pwm_led1));
 static const struct pwm_dt_spec sTiltPwmDevice = PWM_DT_SPEC_GET(DT_ALIAS(pwm_led2));

 static constexpr uint32_t sMoveTimeoutMs{ 200 };

 WindowCovering::WindowCovering()
 {
     mLiftLED.Init(LIFT_STATE_LED);
     mTiltLED.Init(TILT_STATE_LED);

     if (mLiftIndicator.Init(&sLiftPwmDevice, 0, 255) != 0)
     {
         LOG_ERR("Cannot initialize the lift indicator");
     }
     if (mTiltIndicator.Init(&sTiltPwmDevice, 0, 255) != 0)
     {
         LOG_ERR("Cannot initialize the tilt indicator");
     }
 }

 void WindowCovering::DriveCurrentLiftPosition(intptr_t)
 {
     NPercent100ths current{};
     NPercent100ths target{};
     NPercent100ths positionToSet{};

     VerifyOrReturn(Attributes::CurrentPositionLiftPercent100ths::Get(Endpoint(), current) == EMBER_ZCL_STATUS_SUCCESS);
     VerifyOrReturn(Attributes::TargetPositionLiftPercent100ths::Get(Endpoint(), target) == EMBER_ZCL_STATUS_SUCCESS);

     UpdateOperationalStatus(MoveType::LIFT, ComputeOperationalState(target, current));

     positionToSet.SetNonNull(CalculateSingleStep(MoveType::LIFT));
     LiftPositionSet(Endpoint(), positionToSet);

     // assume single move completed
     Instance().mInLiftMove = false;

     VerifyOrReturn(Attributes::CurrentPositionLiftPercent100ths::Get(Endpoint(), current) == EMBER_ZCL_STATUS_SUCCESS);

     if (!TargetCompleted(MoveType::LIFT, current, target))
     {
         // continue to move
         StartTimer(MoveType::LIFT, sMoveTimeoutMs);
     }
     else
     {
         // the OperationalStatus should indicate no-lift-movement after the target is completed
         UpdateOperationalStatus(MoveType::LIFT, ComputeOperationalState(target, current));
     }
 }

 chip::Percent100ths WindowCovering::CalculateSingleStep(MoveType aMoveType)
 {
     EmberAfStatus status{};
     chip::Percent100ths percent100ths{};
     NPercent100ths current{};
     OperationalState opState{};

     if (aMoveType == MoveType::LIFT)
     {
         status  = Attributes::CurrentPositionLiftPercent100ths::Get(Endpoint(), current);
         opState = OperationalStateGet(Endpoint(), OperationalStatus::kLift);
     }
     else if (aMoveType == MoveType::TILT)
     {
         status  = Attributes::CurrentPositionTiltPercent100ths::Get(Endpoint(), current);
         opState = OperationalStateGet(Endpoint(), OperationalStatus::kTilt);
     }

     if ((status == EMBER_ZCL_STATUS_SUCCESS) && !current.IsNull())
     {
         static constexpr auto sPercentDelta{ WC_PERCENT100THS_MAX_CLOSED / 20 };
         percent100ths = ComputePercent100thsStep(opState, current.Value(), sPercentDelta);
     }
     else
     {
         LOG_ERR("Cannot read the current lift position. Error: %d", static_cast<uint8_t>(status));
     }

     return percent100ths;
 }

 bool WindowCovering::TargetCompleted(MoveType aMoveType, NPercent100ths aCurrent, NPercent100ths aTarget)
 {
     return (OperationalState::Stall == ComputeOperationalState(aTarget, aCurrent));
 }

 void WindowCovering::StartTimer(MoveType aMoveType, uint32_t aTimeoutMs)
 {
     MoveType * moveType = chip::Platform::New<MoveType>();
     VerifyOrReturn(moveType != nullptr);

     *moveType = aMoveType;
     (void) chip::DeviceLayer::SystemLayer().StartTimer(chip::System::Clock::Milliseconds32(aTimeoutMs), MoveTimerTimeoutCallback,
                                                        reinterpret_cast<void *>(moveType));
 }

 void WindowCovering::MoveTimerTimeoutCallback(chip::System::Layer * systemLayer, void * appState)
 {
     MoveType * moveType = reinterpret_cast<MoveType *>(appState);
     VerifyOrReturn(moveType != nullptr);

     if (*moveType == MoveType::LIFT)
     {
         chip::DeviceLayer::PlatformMgr().ScheduleWork(WindowCovering::DriveCurrentLiftPosition);
     }
     else if (*moveType == MoveType::TILT)
     {
         chip::DeviceLayer::PlatformMgr().ScheduleWork(WindowCovering::DriveCurrentTiltPosition);
     }

     chip::Platform::Delete(moveType);
 }

 void WindowCovering::DriveCurrentTiltPosition(intptr_t)
 {
     NPercent100ths current{};
     NPercent100ths target{};
     NPercent100ths positionToSet{};

     VerifyOrReturn(Attributes::CurrentPositionTiltPercent100ths::Get(Endpoint(), current) == EMBER_ZCL_STATUS_SUCCESS);
     VerifyOrReturn(Attributes::TargetPositionTiltPercent100ths::Get(Endpoint(), target) == EMBER_ZCL_STATUS_SUCCESS);

     UpdateOperationalStatus(MoveType::TILT, ComputeOperationalState(target, current));

     positionToSet.SetNonNull(CalculateSingleStep(MoveType::TILT));
     TiltPositionSet(Endpoint(), positionToSet);

     // assume single move completed
     Instance().mInTiltMove = false;

     VerifyOrReturn(Attributes::CurrentPositionTiltPercent100ths::Get(Endpoint(), current) == EMBER_ZCL_STATUS_SUCCESS);

     if (!TargetCompleted(MoveType::TILT, current, target))
     {
         // continue to move
         StartTimer(MoveType::TILT, sMoveTimeoutMs);
     }
     else
     {
         // the OperationalStatus should indicate no-tilt-movement after the target is completed
         UpdateOperationalStatus(MoveType::TILT, ComputeOperationalState(target, current));
     }
 }

 void WindowCovering::StartMove(MoveType aMoveType)
 {
     switch (aMoveType)
     {
     case MoveType::LIFT:
         if (!mInLiftMove)
         {
             mInLiftMove = true;
             StartTimer(aMoveType, sMoveTimeoutMs);
         }
         break;
     case MoveType::TILT:
         if (!mInTiltMove)
         {
             mInTiltMove = true;
             StartTimer(aMoveType, sMoveTimeoutMs);
         }
         break;
     default:
         break;
     };
 }

 void WindowCovering::SetSingleStepTarget(OperationalState aDirection)
 {
     UpdateOperationalStatus(mCurrentUIMoveType, aDirection);
     SetTargetPosition(aDirection, CalculateSingleStep(mCurrentUIMoveType));
 }

 void WindowCovering::UpdateOperationalStatus(MoveType aMoveType, OperationalState aDirection)
 {
     switch (aMoveType)
     {
     case MoveType::LIFT:
         OperationalStateSet(Endpoint(), OperationalStatus::kLift, aDirection);
         break;
     case MoveType::TILT:
         OperationalStateSet(Endpoint(), OperationalStatus::kTilt, aDirection);
         break;
     case MoveType::NONE:
         break;
     default:
         break;
     }
 }

 void WindowCovering::SetTargetPosition(OperationalState aDirection, chip::Percent100ths aPosition)
 {
     EmberAfStatus status{};
     if (Instance().mCurrentUIMoveType == MoveType::LIFT)
     {
         status = Attributes::TargetPositionLiftPercent100ths::Set(Endpoint(), aPosition);
     }
     else if (Instance().mCurrentUIMoveType == MoveType::TILT)
     {
         status = Attributes::TargetPositionTiltPercent100ths::Set(Endpoint(), aPosition);
     }

     if (status != EMBER_ZCL_STATUS_SUCCESS)
     {
         LOG_ERR("Cannot set the target position. Error: %d", static_cast<uint8_t>(status));
     }
 }

 void WindowCovering::PositionLEDUpdate(MoveType aMoveType)
 {
     EmberAfStatus status{};
     NPercent100ths currentPosition{};

     if (aMoveType == MoveType::LIFT)
     {
         status = Attributes::CurrentPositionLiftPercent100ths::Get(Endpoint(), currentPosition);
         if (EMBER_ZCL_STATUS_SUCCESS == status && !currentPosition.IsNull())
         {
             Instance().SetBrightness(MoveType::LIFT, currentPosition.Value());
         }
     }
     else if (aMoveType == MoveType::TILT)
     {
         status = Attributes::CurrentPositionTiltPercent100ths::Get(Endpoint(), currentPosition);
         if (EMBER_ZCL_STATUS_SUCCESS == status && !currentPosition.IsNull())
         {
             Instance().SetBrightness(MoveType::TILT, currentPosition.Value());
         }
     }
 }

 void WindowCovering::SetBrightness(MoveType aMoveType, uint16_t aPosition)
 {
     uint8_t brightness = PositionToBrightness(aPosition, aMoveType);
     if (aMoveType == MoveType::LIFT)
     {
         mLiftIndicator.InitiateAction(PWMDevice::LEVEL_ACTION, 0, &brightness);
     }
     else if (aMoveType == MoveType::TILT)
     {
         mTiltIndicator.InitiateAction(PWMDevice::LEVEL_ACTION, 0, &brightness);
     }
 }

 uint8_t WindowCovering::PositionToBrightness(uint16_t aPosition, MoveType aMoveType)
 {
     AbsoluteLimits pwmLimits{};

     if (aMoveType == MoveType::LIFT)
     {
         pwmLimits.open   = mLiftIndicator.GetMinLevel();
         pwmLimits.closed = mLiftIndicator.GetMaxLevel();
     }
     else if (aMoveType == MoveType::TILT)
     {
         pwmLimits.open   = mTiltIndicator.GetMinLevel();
         pwmLimits.closed = mTiltIndicator.GetMaxLevel();
     }

     return Percent100thsToValue(pwmLimits, aPosition);
 }

 void WindowCovering::SchedulePostAttributeChange(chip::EndpointId aEndpoint, chip::AttributeId aAttributeId)
 {
     AttributeUpdateData * data = chip::Platform::New<AttributeUpdateData>();
     VerifyOrReturn(data != nullptr);

     data->mEndpoint    = aEndpoint;
     data->mAttributeId = aAttributeId;

     chip::DeviceLayer::PlatformMgr().ScheduleWork(DoPostAttributeChange, reinterpret_cast<intptr_t>(data));
 }

 void WindowCovering::DoPostAttributeChange(intptr_t aArg)
 {
     AttributeUpdateData * data = reinterpret_cast<AttributeUpdateData *>(aArg);
     VerifyOrReturn(data != nullptr);

     PostAttributeChange(data->mEndpoint, data->mAttributeId);
 }
	/*
	* Copyright (c) 2022 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 "WindowCovering.h"
	#include "AppConfig.h"
	#include "PWMDevice.h"

	#include <dk_buttons_and_leds.h>

	#include <app-common/zap-generated/attributes/Accessors.h>
	#include <app/util/af.h>
	#include <platform/CHIPDeviceLayer.h>
	#include <zephyr/logging/log.h>
	#include <zephyr/zephyr.h>

	LOG_MODULE_DECLARE(app, CONFIG_CHIP_APP_LOG_LEVEL);

	using namespace ::chip::Credentials;
	using namespace ::chip::DeviceLayer;
	using namespace chip::app::Clusters::WindowCovering;

	static const struct pwm_dt_spec sLiftPwmDevice = PWM_DT_SPEC_GET(DT_ALIAS(pwm_led1));
	static const struct pwm_dt_spec sTiltPwmDevice = PWM_DT_SPEC_GET(DT_ALIAS(pwm_led2));

	static constexpr uint32_t sMoveTimeoutMs{ 200 };

	WindowCovering::WindowCovering()
	{
	mLiftLED.Init(LIFT_STATE_LED);
	mTiltLED.Init(TILT_STATE_LED);

	if (mLiftIndicator.Init(&sLiftPwmDevice, 0, 255) != 0)
	{
	LOG_ERR("Cannot initialize the lift indicator");
	}
	if (mTiltIndicator.Init(&sTiltPwmDevice, 0, 255) != 0)
	{
	LOG_ERR("Cannot initialize the tilt indicator");
	}
	}

	void WindowCovering::DriveCurrentLiftPosition(intptr_t)
	{
	NPercent100ths current{};
	NPercent100ths target{};
	NPercent100ths positionToSet{};

	VerifyOrReturn(Attributes::CurrentPositionLiftPercent100ths::Get(Endpoint(), current) == EMBER_ZCL_STATUS_SUCCESS);
	VerifyOrReturn(Attributes::TargetPositionLiftPercent100ths::Get(Endpoint(), target) == EMBER_ZCL_STATUS_SUCCESS);

	UpdateOperationalStatus(MoveType::LIFT, ComputeOperationalState(target, current));

	positionToSet.SetNonNull(CalculateSingleStep(MoveType::LIFT));
	LiftPositionSet(Endpoint(), positionToSet);

	// assume single move completed
	Instance().mInLiftMove = false;

	VerifyOrReturn(Attributes::CurrentPositionLiftPercent100ths::Get(Endpoint(), current) == EMBER_ZCL_STATUS_SUCCESS);

	if (!TargetCompleted(MoveType::LIFT, current, target))
	{
	// continue to move
	StartTimer(MoveType::LIFT, sMoveTimeoutMs);
	}
	else
	{
	// the OperationalStatus should indicate no-lift-movement after the target is completed
	UpdateOperationalStatus(MoveType::LIFT, ComputeOperationalState(target, current));
	}
	}

	chip::Percent100ths WindowCovering::CalculateSingleStep(MoveType aMoveType)
	{
	EmberAfStatus status{};
	chip::Percent100ths percent100ths{};
	NPercent100ths current{};
	OperationalState opState{};

	if (aMoveType == MoveType::LIFT)
	{
	status = Attributes::CurrentPositionLiftPercent100ths::Get(Endpoint(), current);
	opState = OperationalStateGet(Endpoint(), OperationalStatus::kLift);
	}
	else if (aMoveType == MoveType::TILT)
	{
	status = Attributes::CurrentPositionTiltPercent100ths::Get(Endpoint(), current);
	opState = OperationalStateGet(Endpoint(), OperationalStatus::kTilt);
	}

	if ((status == EMBER_ZCL_STATUS_SUCCESS) && !current.IsNull())
	{
	static constexpr auto sPercentDelta{ WC_PERCENT100THS_MAX_CLOSED / 20 };
	percent100ths = ComputePercent100thsStep(opState, current.Value(), sPercentDelta);
	}
	else
	{
	LOG_ERR("Cannot read the current lift position. Error: %d", static_cast<uint8_t>(status));
	}

	return percent100ths;
	}

	bool WindowCovering::TargetCompleted(MoveType aMoveType, NPercent100ths aCurrent, NPercent100ths aTarget)
	{
	return (OperationalState::Stall == ComputeOperationalState(aTarget, aCurrent));
	}

	void WindowCovering::StartTimer(MoveType aMoveType, uint32_t aTimeoutMs)
	{
	MoveType * moveType = chip::Platform::New<MoveType>();
	VerifyOrReturn(moveType != nullptr);

	*moveType = aMoveType;
	(void) chip::DeviceLayer::SystemLayer().StartTimer(chip::System::Clock::Milliseconds32(aTimeoutMs), MoveTimerTimeoutCallback,
	reinterpret_cast<void *>(moveType));
	}

	void WindowCovering::MoveTimerTimeoutCallback(chip::System::Layer * systemLayer, void * appState)
	{
	MoveType * moveType = reinterpret_cast<MoveType *>(appState);
	VerifyOrReturn(moveType != nullptr);

	if (*moveType == MoveType::LIFT)
	{
	chip::DeviceLayer::PlatformMgr().ScheduleWork(WindowCovering::DriveCurrentLiftPosition);
	}
	else if (*moveType == MoveType::TILT)
	{
	chip::DeviceLayer::PlatformMgr().ScheduleWork(WindowCovering::DriveCurrentTiltPosition);
	}

	chip::Platform::Delete(moveType);
	}

	void WindowCovering::DriveCurrentTiltPosition(intptr_t)
	{
	NPercent100ths current{};
	NPercent100ths target{};
	NPercent100ths positionToSet{};

	VerifyOrReturn(Attributes::CurrentPositionTiltPercent100ths::Get(Endpoint(), current) == EMBER_ZCL_STATUS_SUCCESS);
	VerifyOrReturn(Attributes::TargetPositionTiltPercent100ths::Get(Endpoint(), target) == EMBER_ZCL_STATUS_SUCCESS);

	UpdateOperationalStatus(MoveType::TILT, ComputeOperationalState(target, current));

	positionToSet.SetNonNull(CalculateSingleStep(MoveType::TILT));
	TiltPositionSet(Endpoint(), positionToSet);

	// assume single move completed
	Instance().mInTiltMove = false;

	VerifyOrReturn(Attributes::CurrentPositionTiltPercent100ths::Get(Endpoint(), current) == EMBER_ZCL_STATUS_SUCCESS);

	if (!TargetCompleted(MoveType::TILT, current, target))
	{
	// continue to move
	StartTimer(MoveType::TILT, sMoveTimeoutMs);
	}
	else
	{
	// the OperationalStatus should indicate no-tilt-movement after the target is completed
	UpdateOperationalStatus(MoveType::TILT, ComputeOperationalState(target, current));
	}
	}

	void WindowCovering::StartMove(MoveType aMoveType)
	{
	switch (aMoveType)
	{
	case MoveType::LIFT:
	if (!mInLiftMove)
	{
	mInLiftMove = true;
	StartTimer(aMoveType, sMoveTimeoutMs);
	}
	break;
	case MoveType::TILT:
	if (!mInTiltMove)
	{
	mInTiltMove = true;
	StartTimer(aMoveType, sMoveTimeoutMs);
	}
	break;
	default:
	break;
	};
	}

	void WindowCovering::SetSingleStepTarget(OperationalState aDirection)
	{
	UpdateOperationalStatus(mCurrentUIMoveType, aDirection);
	SetTargetPosition(aDirection, CalculateSingleStep(mCurrentUIMoveType));
	}

	void WindowCovering::UpdateOperationalStatus(MoveType aMoveType, OperationalState aDirection)
	{
	switch (aMoveType)
	{
	case MoveType::LIFT:
	OperationalStateSet(Endpoint(), OperationalStatus::kLift, aDirection);
	break;
	case MoveType::TILT:
	OperationalStateSet(Endpoint(), OperationalStatus::kTilt, aDirection);
	break;
	case MoveType::NONE:
	break;
	default:
	break;
	}
	}

	void WindowCovering::SetTargetPosition(OperationalState aDirection, chip::Percent100ths aPosition)
	{
	EmberAfStatus status{};
	if (Instance().mCurrentUIMoveType == MoveType::LIFT)
	{
	status = Attributes::TargetPositionLiftPercent100ths::Set(Endpoint(), aPosition);
	}
	else if (Instance().mCurrentUIMoveType == MoveType::TILT)
	{
	status = Attributes::TargetPositionTiltPercent100ths::Set(Endpoint(), aPosition);
	}

	if (status != EMBER_ZCL_STATUS_SUCCESS)
	{
	LOG_ERR("Cannot set the target position. Error: %d", static_cast<uint8_t>(status));
	}
	}

	void WindowCovering::PositionLEDUpdate(MoveType aMoveType)
	{
	EmberAfStatus status{};
	NPercent100ths currentPosition{};

	if (aMoveType == MoveType::LIFT)
	{
	status = Attributes::CurrentPositionLiftPercent100ths::Get(Endpoint(), currentPosition);
	if (EMBER_ZCL_STATUS_SUCCESS == status && !currentPosition.IsNull())
	{
	Instance().SetBrightness(MoveType::LIFT, currentPosition.Value());
	}
	}
	else if (aMoveType == MoveType::TILT)
	{
	status = Attributes::CurrentPositionTiltPercent100ths::Get(Endpoint(), currentPosition);
	if (EMBER_ZCL_STATUS_SUCCESS == status && !currentPosition.IsNull())
	{
	Instance().SetBrightness(MoveType::TILT, currentPosition.Value());
	}
	}
	}

	void WindowCovering::SetBrightness(MoveType aMoveType, uint16_t aPosition)
	{
	uint8_t brightness = PositionToBrightness(aPosition, aMoveType);
	if (aMoveType == MoveType::LIFT)
	{
	mLiftIndicator.InitiateAction(PWMDevice::LEVEL_ACTION, 0, &brightness);
	}
	else if (aMoveType == MoveType::TILT)
	{
	mTiltIndicator.InitiateAction(PWMDevice::LEVEL_ACTION, 0, &brightness);
	}
	}

	uint8_t WindowCovering::PositionToBrightness(uint16_t aPosition, MoveType aMoveType)
	{
	AbsoluteLimits pwmLimits{};

	if (aMoveType == MoveType::LIFT)
	{
	pwmLimits.open = mLiftIndicator.GetMinLevel();
	pwmLimits.closed = mLiftIndicator.GetMaxLevel();
	}
	else if (aMoveType == MoveType::TILT)
	{
	pwmLimits.open = mTiltIndicator.GetMinLevel();
	pwmLimits.closed = mTiltIndicator.GetMaxLevel();
	}

	return Percent100thsToValue(pwmLimits, aPosition);
	}

	void WindowCovering::SchedulePostAttributeChange(chip::EndpointId aEndpoint, chip::AttributeId aAttributeId)
	{
	AttributeUpdateData * data = chip::Platform::New<AttributeUpdateData>();
	VerifyOrReturn(data != nullptr);

	data->mEndpoint = aEndpoint;
	data->mAttributeId = aAttributeId;

	chip::DeviceLayer::PlatformMgr().ScheduleWork(DoPostAttributeChange, reinterpret_cast<intptr_t>(data));
	}

	void WindowCovering::DoPostAttributeChange(intptr_t aArg)
	{
	AttributeUpdateData * data = reinterpret_cast<AttributeUpdateData *>(aArg);
	VerifyOrReturn(data != nullptr);

	PostAttributeChange(data->mEndpoint, data->mAttributeId);
	}