examples/pump-app/cc13x4_26x4/main/AppTask.cpp - third_party/github/project-chip/connectedhomeip - Git at Google

 /*
  *
  *    Copyright (c) 2020 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 "AppTask.h"
 #include "AppConfig.h"
 #include "AppEvent.h"
 #include "CHIPDeviceManager.h"
 #include "DeviceCallbacks.h"
 #include <app/server/Dnssd.h>
 #include <app/server/Server.h>

 #include "FreeRTOS.h"
 #include <credentials/DeviceAttestationCredsProvider.h>
 #include <credentials/examples/DeviceAttestationCredsExample.h>

 #include <examples/platform/cc13x4_26x4/CC13X4_26X4DeviceAttestationCreds.h>

 #include <app/EventLogging.h>
 #include <app/util/af-types.h>
 #include <app/util/af.h>

 #if defined(CHIP_DEVICE_CONFIG_ENABLE_OTA_REQUESTOR)
 #include <app/clusters/ota-requestor/BDXDownloader.h>
 #include <app/clusters/ota-requestor/DefaultOTARequestor.h>
 #include <app/clusters/ota-requestor/DefaultOTARequestorDriver.h>
 #include <app/clusters/ota-requestor/DefaultOTARequestorStorage.h>
 #include <platform/cc13xx_26xx/OTAImageProcessorImpl.h>
 #endif
 #include <app-common/zap-generated/attributes/Accessors.h>
 #include <app/clusters/identify-server/identify-server.h>
 #include <lib/support/CHIPMem.h>
 #include <lib/support/CHIPPlatformMemory.h>
 #include <platform/CHIPDeviceLayer.h>

 #include <app/server/OnboardingCodesUtil.h>

 #include <ti/drivers/apps/Button.h>
 #include <ti/drivers/apps/LED.h>

 /* syscfg */
 #include <ti_drivers_config.h>

 #define APP_TASK_STACK_SIZE (4096)
 #define APP_TASK_PRIORITY 4
 #define APP_EVENT_QUEUE_SIZE 10

 #define PCC_CLUSTER_ENDPOINT 1
 #define ONOFF_CLUSTER_ENDPOINT 1
 #define EXTENDED_DISCOVERY_TIMEOUT_SEC 20

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

 static TaskHandle_t sAppTaskHandle;
 static QueueHandle_t sAppEventQueue;

 static LED_Handle sAppRedHandle;
 static LED_Handle sAppGreenHandle;
 static Button_Handle sAppLeftHandle;
 static Button_Handle sAppRightHandle;

 AppTask AppTask::sAppTask;

 static DeviceCallbacks sDeviceCallbacks;

 #if defined(CHIP_DEVICE_CONFIG_ENABLE_OTA_REQUESTOR)
 static DefaultOTARequestor sRequestorCore;
 static DefaultOTARequestorStorage sRequestorStorage;
 static DefaultOTARequestorDriver sRequestorUser;
 static BDXDownloader sDownloader;
 static OTAImageProcessorImpl sImageProcessor;

 void InitializeOTARequestor(void)
 {
     // Initialize and interconnect the Requestor and Image Processor objects
     SetRequestorInstance(&sRequestorCore);

     sRequestorStorage.Init(chip::Server::GetInstance().GetPersistentStorage());
     sRequestorCore.Init(chip::Server::GetInstance(), sRequestorStorage, sRequestorUser, sDownloader);
     sImageProcessor.SetOTADownloader(&sDownloader);
     sDownloader.SetImageProcessorDelegate(&sImageProcessor);
     sRequestorUser.Init(&sRequestorCore, &sImageProcessor);
 }
 #endif

 static const chip::EndpointId sIdentifyEndpointId = 0;
 static const uint32_t sIdentifyBlinkRateMs        = 500;

 ::Identify stIdentify = { sIdentifyEndpointId, AppTask::IdentifyStartHandler, AppTask::IdentifyStopHandler,
                           Clusters::Identify::IdentifyTypeEnum::kVisibleIndicator, AppTask::TriggerIdentifyEffectHandler };

 int AppTask::StartAppTask()
 {
     int ret = 0;

     sAppEventQueue = xQueueCreate(APP_EVENT_QUEUE_SIZE, sizeof(AppEvent));
     if (sAppEventQueue == NULL)
     {
         PLAT_LOG("Failed to allocate app event queue");
         while (true)
             ;
     }

     // Start App task.
     if (xTaskCreate(AppTaskMain, "APP", APP_TASK_STACK_SIZE / sizeof(StackType_t), NULL, APP_TASK_PRIORITY, &sAppTaskHandle) !=
         pdPASS)
     {
         PLAT_LOG("Failed to create app task");
         while (true)
             ;
     }
     return ret;
 }

 int AppTask::Init()
 {
     LED_Params ledParams;
     Button_Params buttonParams;

     cc13xx_26xxLogInit();

     // Init Chip memory management before the stack
     Platform::MemoryInit();

     CHIP_ERROR ret = PlatformMgr().InitChipStack();
     if (ret != CHIP_NO_ERROR)
     {
         PLAT_LOG("PlatformMgr().InitChipStack() failed");
         while (true)
             ;
     }

     ret = ThreadStackMgr().InitThreadStack();
     if (ret != CHIP_NO_ERROR)
     {
         PLAT_LOG("ThreadStackMgr().InitThreadStack() failed");
         while (true)
             ;
     }

 #ifdef CONFIG_OPENTHREAD_MTD_SED
     ret = ConnectivityMgr().SetThreadDeviceType(ConnectivityManager::kThreadDeviceType_SleepyEndDevice);
 #elif CONFIG_OPENTHREAD_MTD
     ret = ConnectivityMgr().SetThreadDeviceType(ConnectivityManager::kThreadDeviceType_MinimalEndDevice);
 #else
     ret = ConnectivityMgr().SetThreadDeviceType(ConnectivityManager::kThreadDeviceType_Router);
 #endif
     if (ret != CHIP_NO_ERROR)
     {
         PLAT_LOG("ConnectivityMgr().SetThreadDeviceType() failed");
         while (true)
             ;
     }

     ret = ThreadStackMgrImpl().StartThreadTask();
     if (ret != CHIP_NO_ERROR)
     {
         PLAT_LOG("ThreadStackMgr().StartThreadTask() failed");
         while (true)
             ;
     }

     // Initialize LEDs
     PLAT_LOG("Initialize LEDs");
     LED_init();

     LED_Params_init(&ledParams); // default PWM LED
     sAppRedHandle = LED_open(CONFIG_LED_RED, &ledParams);
     LED_setOff(sAppRedHandle);

     LED_Params_init(&ledParams); // default PWM LED
     sAppGreenHandle = LED_open(CONFIG_LED_GREEN, &ledParams);
     LED_setOff(sAppGreenHandle);

     // Initialize buttons
     PLAT_LOG("Initialize buttons");
     Button_init();

     Button_Params_init(&buttonParams);
     buttonParams.buttonEventMask   = Button_EV_CLICKED | Button_EV_LONGPRESSED;
     buttonParams.longPressDuration = 5000U; // ms
     sAppLeftHandle                 = Button_open(CONFIG_BTN_LEFT, &buttonParams);
     Button_setCallback(sAppLeftHandle, ButtonLeftEventHandler);

     Button_Params_init(&buttonParams);
     buttonParams.buttonEventMask   = Button_EV_CLICKED;
     buttonParams.longPressDuration = 1000U; // ms
     sAppRightHandle                = Button_open(CONFIG_BTN_RIGHT, &buttonParams);
     Button_setCallback(sAppRightHandle, ButtonRightEventHandler);

     // Initialize Pump module
     PLAT_LOG("Initialize Pump");
     PumpMgr().Init();

     PumpMgr().SetCallbacks(ActionInitiated, ActionCompleted);

 #if CHIP_DEVICE_CONFIG_ENABLE_EXTENDED_DISCOVERY
     DnssdServer::Instance().SetExtendedDiscoveryTimeoutSecs(EXTENDED_DISCOVERY_TIMEOUT_SEC);
 #endif

     // Init ZCL Data Model
     static chip::CommonCaseDeviceServerInitParams initParams;
     (void) initParams.InitializeStaticResourcesBeforeServerInit();
     chip::Server::GetInstance().Init(initParams);

     // Initialize device attestation config
 #ifdef CC13X4_26X4_ATTESTATION_CREDENTIALS
     SetDeviceAttestationCredentialsProvider(CC13X4_26X4::GetCC13X4_26X4DacProvider());
 #else
     SetDeviceAttestationCredentialsProvider(Examples::GetExampleDACProvider());
 #endif

     ConfigurationMgr().LogDeviceConfig();

 #if defined(CHIP_DEVICE_CONFIG_ENABLE_OTA_REQUESTOR)
     InitializeOTARequestor();
 #endif

     // QR code will be used with CHIP Tool
     PrintOnboardingCodes(RendezvousInformationFlags(RendezvousInformationFlag::kBLE));

     CHIPDeviceManager & deviceMgr = CHIPDeviceManager::GetInstance();
     ret                           = deviceMgr.Init(&sDeviceCallbacks);
     if (ret != CHIP_NO_ERROR)
     {
         PLAT_LOG("CHIPDeviceManager::Init() failed: %s", ErrorStr(ret));
         while (true)
             ;
     }

     return 0;
 }

 void AppTask::AppTaskMain(void * pvParameter)
 {
     AppEvent event;

     sAppTask.Init();

     while (true)
     {
         /* Task pend until we have stuff to do */
         if (xQueueReceive(sAppEventQueue, &event, portMAX_DELAY) == pdTRUE)
         {
             sAppTask.DispatchEvent(&event);
         }
     }
 }

 void AppTask::PostEvent(const AppEvent * aEvent)
 {
     if (xQueueSend(sAppEventQueue, aEvent, 0) != pdPASS)
     {
         /* Failed to post the message */
     }
 }

 void AppTask::ButtonLeftEventHandler(Button_Handle handle, Button_EventMask events)
 {
     AppEvent event;
     event.Type = AppEvent::kEventType_ButtonLeft;

     if (events & Button_EV_CLICKED)
     {
         event.ButtonEvent.Type = AppEvent::kAppEventButtonType_Clicked;
     }
     else if (events & Button_EV_LONGPRESSED)
     {
         event.ButtonEvent.Type = AppEvent::kAppEventButtonType_LongPressed;
     }
     // button callbacks are in ISR context
     if (xQueueSendFromISR(sAppEventQueue, &event, NULL) != pdPASS)
     {
         /* Failed to post the message */
     }
 }

 void AppTask::ButtonRightEventHandler(Button_Handle handle, Button_EventMask events)
 {
     AppEvent event;
     event.Type = AppEvent::kEventType_ButtonRight;

     if (events & Button_EV_CLICKED)
     {
         event.ButtonEvent.Type = AppEvent::kAppEventButtonType_Clicked;
     }
     // button callbacks are in ISR context
     if (xQueueSendFromISR(sAppEventQueue, &event, NULL) != pdPASS)
     {
         /* Failed to post the message */
     }
 }

 void AppTask::ActionInitiated(PumpManager::Action_t aAction, int32_t aActor)
 {
     // If the action has been initiated by the pump, update the pump trait
     // and start flashing the LEDs rapidly to indicate action initiation.
     if (aAction == PumpManager::START_ACTION)
     {
         PLAT_LOG("Pump start initiated");
         ; // TODO
     }
     else if (aAction == PumpManager::STOP_ACTION)
     {
         PLAT_LOG("Stop initiated");
         ; // TODO
     }

     LED_setOn(sAppGreenHandle, LED_BRIGHTNESS_MAX);
     LED_startBlinking(sAppGreenHandle, 50 /* ms */, LED_BLINK_FOREVER);
     LED_setOn(sAppRedHandle, LED_BRIGHTNESS_MAX);
     LED_startBlinking(sAppRedHandle, 110 /* ms */, LED_BLINK_FOREVER);
 }

 void AppTask::ActionCompleted(PumpManager::Action_t aAction, int32_t aActor)
 {
     // if the action has been completed by the pump, update the pump trait.
     // Turn on the pump state LED if in a STARTED state OR
     // Turn off the pump state LED if in an STOPPED state.
     if (aAction == PumpManager::START_ACTION)
     {
         PLAT_LOG("Pump start completed");
         LED_stopBlinking(sAppGreenHandle);
         LED_setOn(sAppGreenHandle, LED_BRIGHTNESS_MAX);
         LED_stopBlinking(sAppRedHandle);
         LED_setOn(sAppRedHandle, LED_BRIGHTNESS_MAX);
         // Signal to the PCC cluster, that the pump is running
         sAppTask.UpdateClusterState();
     }
     else if (aAction == PumpManager::STOP_ACTION)
     {
         PLAT_LOG("Pump stop completed");
         LED_stopBlinking(sAppGreenHandle);
         LED_setOff(sAppGreenHandle);
         LED_stopBlinking(sAppRedHandle);
         LED_setOff(sAppRedHandle);
         // Signal to the PCC cluster, that the pump is NOT running
         sAppTask.UpdateClusterState();
     }
     if (aActor == AppEvent::kEventType_ButtonLeft)
     {
         sAppTask.UpdateClusterState();
     }
 }

 void AppTask::DispatchEvent(AppEvent * aEvent)
 {
     switch (aEvent->Type)
     {
     case AppEvent::kEventType_ButtonRight:
         if (AppEvent::kAppEventButtonType_Clicked == aEvent->ButtonEvent.Type)
         {
             // Toggle Pump state
             if (!PumpMgr().IsStopped())
             {
                 PumpMgr().InitiateAction(0, PumpManager::STOP_ACTION);
             }
             else
             {
                 PumpMgr().InitiateAction(0, PumpManager::START_ACTION);
             }
         }
         break;

     case AppEvent::kEventType_ButtonLeft:
         if (AppEvent::kAppEventButtonType_Clicked == aEvent->ButtonEvent.Type)
         {
             // Post event for demonstration purposes, we must ensure that the
             // LogEvent is called in the right context which is the Matter mainloop
             // thru ScheduleWork()
             chip::DeviceLayer::PlatformMgr().ScheduleWork(sAppTask.PostEvents, reinterpret_cast<intptr_t>(nullptr));

             // Toggle BLE advertisements
             if (!ConnectivityMgr().IsBLEAdvertisingEnabled())
             {
                 if (chip::Server::GetInstance().GetCommissioningWindowManager().OpenBasicCommissioningWindow() == CHIP_NO_ERROR)
                 {
                     PLAT_LOG("Enabled BLE Advertisements");
                 }
                 else
                 {
                     PLAT_LOG("OpenBasicCommissioningWindow() failed");
                 }
             }
             else
             {
                 // Disable BLE advertisements
                 ConnectivityMgr().SetBLEAdvertisingEnabled(false);
                 PLAT_LOG("Disabled BLE Advertisements");
             }
         }
         else if (AppEvent::kAppEventButtonType_LongPressed == aEvent->ButtonEvent.Type)
         {
             chip::Server::GetInstance().ScheduleFactoryReset();
         }
         break;

     case AppEvent::kEventType_IdentifyStart:
         LED_setOn(sAppGreenHandle, LED_BRIGHTNESS_MAX);
         LED_startBlinking(sAppGreenHandle, sIdentifyBlinkRateMs, LED_BLINK_FOREVER);
         PLAT_LOG("Identify started");
         break;

     case AppEvent::kEventType_IdentifyStop:
         LED_stopBlinking(sAppGreenHandle);

         if (!PumpMgr().IsStopped())
         {
             LED_setOn(sAppGreenHandle, LED_BRIGHTNESS_MAX);
         }
         else
         {
             LED_setOff(sAppGreenHandle);
         }
         PLAT_LOG("Identify stopped");
         break;

     case AppEvent::kEventType_AppEvent:
         if (NULL != aEvent->Handler)
         {
             aEvent->Handler(aEvent);
         }
         break;

     case AppEvent::kEventType_None:
     default:
         break;
     }
 }

 void AppTask::InitOnOffClusterState()
 {

     EmberStatus status;

     ChipLogProgress(NotSpecified, "Init On/Off clusterstate");

     // Write false as pump always boots in stopped mode
     status = OnOff::Attributes::OnOff::Set(ONOFF_CLUSTER_ENDPOINT, false);
     if (status != EMBER_ZCL_STATUS_SUCCESS)
     {
         ChipLogError(NotSpecified, "ERR: Init On/Off state  %x", status);
     }
 }

 void AppTask::InitPCCClusterState() {}

 void AppTask::UpdateClusterState(void)
 {
     // We must ensure that the Cluster accessors gets called in the right context
     // which is the Matter mainloop thru ScheduleWork()
     chip::DeviceLayer::PlatformMgr().ScheduleWork(UpdateCluster, reinterpret_cast<intptr_t>(nullptr));
 }

 void AppTask::UpdateCluster(intptr_t context)
 {
     EmberStatus status;
     BitMask<PumpConfigurationAndControl::PumpStatusBitmap> pumpStatus;

     ChipLogProgress(NotSpecified, "Update Cluster State");

     // Update the PumpStatus
     PumpConfigurationAndControl::Attributes::PumpStatus::Get(PCC_CLUSTER_ENDPOINT, &pumpStatus);
     if (PumpMgr().IsStopped())
     {
         pumpStatus.Clear(PumpConfigurationAndControl::PumpStatusBitmap::kRunning);
     }
     else
     {
         pumpStatus.Set(PumpConfigurationAndControl::PumpStatusBitmap::kRunning);
     }
     PumpConfigurationAndControl::Attributes::PumpStatus::Set(PCC_CLUSTER_ENDPOINT, pumpStatus);

     status = PumpConfigurationAndControl::Attributes::ControlMode::Set(PCC_CLUSTER_ENDPOINT,
                                                                        PumpConfigurationAndControl::ControlModeEnum::kConstantFlow);
     if (status != EMBER_ZCL_STATUS_SUCCESS)
     {
         ChipLogError(NotSpecified, "ERR: Constant Flow error  %x", status);
     }
     status = PumpConfigurationAndControl::Attributes::ControlMode::Set(
         PCC_CLUSTER_ENDPOINT, PumpConfigurationAndControl::ControlModeEnum::kConstantPressure);
     if (status != EMBER_ZCL_STATUS_SUCCESS)
     {
         ChipLogError(NotSpecified, "ERR: Constant Pressure error  %x", status);
     }
     status = PumpConfigurationAndControl::Attributes::ControlMode::Set(
         PCC_CLUSTER_ENDPOINT, PumpConfigurationAndControl::ControlModeEnum::kConstantSpeed);
     if (status != EMBER_ZCL_STATUS_SUCCESS)
     {
         ChipLogError(NotSpecified, "ERR: Constant Speed error  %x", status);
     }
     status = PumpConfigurationAndControl::Attributes::ControlMode::Set(
         PCC_CLUSTER_ENDPOINT, PumpConfigurationAndControl::ControlModeEnum::kConstantTemperature);
     if (status != EMBER_ZCL_STATUS_SUCCESS)
     {
         ChipLogError(NotSpecified, "ERR: Constant Temperature error  %x", status);
     }

     // Write the new values
     bool onOffState = !PumpMgr().IsStopped();
     status          = OnOff::Attributes::OnOff::Set(ONOFF_CLUSTER_ENDPOINT, onOffState);
     if (status != EMBER_ZCL_STATUS_SUCCESS)
     {
         ChipLogError(NotSpecified, "ERR: Updating On/Off state  %x", status);
     }

     int16_t maxPressure = PumpMgr().GetMaxPressure();
     status              = PumpConfigurationAndControl::Attributes::MaxPressure::Set(PCC_CLUSTER_ENDPOINT, maxPressure);
     if (status != EMBER_ZCL_STATUS_SUCCESS)
     {
         ChipLogError(NotSpecified, "ERR: Updating MaxPressure  %x", status);
     }

     uint16_t maxSpeed = PumpMgr().GetMaxSpeed();
     status            = PumpConfigurationAndControl::Attributes::MaxSpeed::Set(PCC_CLUSTER_ENDPOINT, maxSpeed);
     if (status != EMBER_ZCL_STATUS_SUCCESS)
     {
         ChipLogError(NotSpecified, "ERR: Updating MaxSpeed  %x", status);
     }

     uint16_t maxFlow = PumpMgr().GetMaxFlow();
     status           = PumpConfigurationAndControl::Attributes::MaxFlow::Set(PCC_CLUSTER_ENDPOINT, maxFlow);
     if (status != EMBER_ZCL_STATUS_SUCCESS)
     {
         ChipLogError(NotSpecified, "ERR: Updating MaxFlow  %x", status);
     }

     int16_t minConstPress = PumpMgr().GetMinConstPressure();
     status                = PumpConfigurationAndControl::Attributes::MinConstPressure::Set(PCC_CLUSTER_ENDPOINT, minConstPress);
     if (status != EMBER_ZCL_STATUS_SUCCESS)
     {
         ChipLogError(NotSpecified, "ERR: Updating MinConstPressure  %x", status);
     }

     int16_t maxConstPress = PumpMgr().GetMaxConstPressure();
     status                = PumpConfigurationAndControl::Attributes::MaxConstPressure::Set(PCC_CLUSTER_ENDPOINT, maxConstPress);
     if (status != EMBER_ZCL_STATUS_SUCCESS)
     {
         ChipLogError(NotSpecified, "ERR: Updating MaxConstPressure  %x", status);
     }

     int16_t minCompPress = PumpMgr().GetMinCompPressure();
     status               = PumpConfigurationAndControl::Attributes::MinCompPressure::Set(PCC_CLUSTER_ENDPOINT, minCompPress);
     if (status != EMBER_ZCL_STATUS_SUCCESS)
     {
         ChipLogError(NotSpecified, "ERR: Updating MinCompPressure  %x", status);
     }

     int16_t maxCompPress = PumpMgr().GetMaxCompPressure();
     status               = PumpConfigurationAndControl::Attributes::MaxCompPressure::Set(PCC_CLUSTER_ENDPOINT, maxCompPress);
     if (status != EMBER_ZCL_STATUS_SUCCESS)
     {
         ChipLogError(NotSpecified, "ERR: Updating MaxCompPressure  %x", status);
     }

     uint16_t minConstSpeed = PumpMgr().GetMinConstSpeed();
     status                 = PumpConfigurationAndControl::Attributes::MinConstSpeed::Set(PCC_CLUSTER_ENDPOINT, minConstSpeed);
     if (status != EMBER_ZCL_STATUS_SUCCESS)
     {
         ChipLogError(NotSpecified, "ERR: Updating MinConstSpeed  %x", status);
     }

     uint16_t maxConstSpeed = PumpMgr().GetMaxConstSpeed();
     status                 = PumpConfigurationAndControl::Attributes::MaxConstSpeed::Set(PCC_CLUSTER_ENDPOINT, maxConstSpeed);
     if (status != EMBER_ZCL_STATUS_SUCCESS)
     {
         ChipLogError(NotSpecified, "ERR: Updating MaxConstSpeed  %x", status);
     }

     uint16_t minConstFlow = PumpMgr().GetMinConstFlow();
     status                = PumpConfigurationAndControl::Attributes::MinConstFlow::Set(PCC_CLUSTER_ENDPOINT, minConstFlow);
     if (status != EMBER_ZCL_STATUS_SUCCESS)
     {
         ChipLogError(NotSpecified, "ERR: Updating MinConstFlow  %x", status);
     }

     uint16_t maxConstFlow = PumpMgr().GetMaxConstFlow();
     status                = PumpConfigurationAndControl::Attributes::MaxConstFlow::Set(PCC_CLUSTER_ENDPOINT, maxConstFlow);
     if (status != EMBER_ZCL_STATUS_SUCCESS)
     {
         ChipLogError(NotSpecified, "ERR: Updating MaxConstFlow  %x", status);
     }

     int16_t minConstTemp = PumpMgr().GetMinConstTemp();
     status               = PumpConfigurationAndControl::Attributes::MinConstTemp::Set(PCC_CLUSTER_ENDPOINT, minConstTemp);
     if (status != EMBER_ZCL_STATUS_SUCCESS)
     {
         ChipLogError(NotSpecified, "ERR: Updating MinConstTemp  %x", status);
     }

     int16_t maxConstTemp = PumpMgr().GetMaxConstTemp();
     status               = PumpConfigurationAndControl::Attributes::MaxConstTemp::Set(PCC_CLUSTER_ENDPOINT, maxConstTemp);
     if (status != EMBER_ZCL_STATUS_SUCCESS)
     {
         ChipLogError(NotSpecified, "ERR: Updating MaxConstTemp  %x", status);
     }
 }

 void AppTask::PostEvents(intptr_t context)
 {
     // Example on posting events - here we post the general fault event on endpoints with PCC Server enabled
     for (auto endpoint : EnabledEndpointsWithServerCluster(PumpConfigurationAndControl::Id))
     {
         PumpConfigurationAndControl::Events::GeneralFault::Type event;
         EventNumber eventNumber;

         ChipLogProgress(Zcl, "AppTask: Post PCC GeneralFault event");
         // Using default priority for the event
         if (CHIP_NO_ERROR != LogEvent(event, endpoint, eventNumber))
         {
             ChipLogError(Zcl, "AppTask: Failed to record GeneralFault event");
         }
     }
 }

 void AppTask::IdentifyStartHandler(::Identify *)
 {
     AppEvent event;
     event.Type = AppEvent::kEventType_IdentifyStart;
     sAppTask.PostEvent(&event);
 }

 void AppTask::IdentifyStopHandler(::Identify *)
 {
     AppEvent event;
     event.Type = AppEvent::kEventType_IdentifyStop;
     sAppTask.PostEvent(&event);
 }

 void AppTask::TriggerIdentifyEffectHandler(::Identify * identify)
 {
     switch (identify->mCurrentEffectIdentifier)
     {
     case Clusters::Identify::EffectIdentifierEnum::kBlink:
         PLAT_LOG("Starting blink identifier effect");
         IdentifyStartHandler(identify);
         break;
     case Clusters::Identify::EffectIdentifierEnum::kBreathe:
         PLAT_LOG("Breathe identifier effect not implemented");
         break;
     case Clusters::Identify::EffectIdentifierEnum::kOkay:
         PLAT_LOG("Okay identifier effect not implemented");
         break;
     case Clusters::Identify::EffectIdentifierEnum::kChannelChange:
         PLAT_LOG("Channel Change identifier effect not implemented");
         break;
     case Clusters::Identify::EffectIdentifierEnum::kFinishEffect:
         PLAT_LOG("Finish identifier effect not implemented");
         break;
     case Clusters::Identify::EffectIdentifierEnum::kStopEffect:
         PLAT_LOG("Stop identifier effect");
         IdentifyStopHandler(identify);
         break;
     default:
         PLAT_LOG("No identifier effect");
     }
 }
	/*
	*
	* Copyright (c) 2020 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 "AppTask.h"
	#include "AppConfig.h"
	#include "AppEvent.h"
	#include "CHIPDeviceManager.h"
	#include "DeviceCallbacks.h"
	#include <app/server/Dnssd.h>
	#include <app/server/Server.h>

	#include "FreeRTOS.h"
	#include <credentials/DeviceAttestationCredsProvider.h>
	#include <credentials/examples/DeviceAttestationCredsExample.h>

	#include <examples/platform/cc13x4_26x4/CC13X4_26X4DeviceAttestationCreds.h>

	#include <app/EventLogging.h>
	#include <app/util/af-types.h>
	#include <app/util/af.h>

	#if defined(CHIP_DEVICE_CONFIG_ENABLE_OTA_REQUESTOR)
	#include <app/clusters/ota-requestor/BDXDownloader.h>
	#include <app/clusters/ota-requestor/DefaultOTARequestor.h>
	#include <app/clusters/ota-requestor/DefaultOTARequestorDriver.h>
	#include <app/clusters/ota-requestor/DefaultOTARequestorStorage.h>
	#include <platform/cc13xx_26xx/OTAImageProcessorImpl.h>
	#endif
	#include <app-common/zap-generated/attributes/Accessors.h>
	#include <app/clusters/identify-server/identify-server.h>
	#include <lib/support/CHIPMem.h>
	#include <lib/support/CHIPPlatformMemory.h>
	#include <platform/CHIPDeviceLayer.h>

	#include <app/server/OnboardingCodesUtil.h>

	#include <ti/drivers/apps/Button.h>
	#include <ti/drivers/apps/LED.h>

	/* syscfg */
	#include <ti_drivers_config.h>

	#define APP_TASK_STACK_SIZE (4096)
	#define APP_TASK_PRIORITY 4
	#define APP_EVENT_QUEUE_SIZE 10

	#define PCC_CLUSTER_ENDPOINT 1
	#define ONOFF_CLUSTER_ENDPOINT 1
	#define EXTENDED_DISCOVERY_TIMEOUT_SEC 20

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

	static TaskHandle_t sAppTaskHandle;
	static QueueHandle_t sAppEventQueue;

	static LED_Handle sAppRedHandle;
	static LED_Handle sAppGreenHandle;
	static Button_Handle sAppLeftHandle;
	static Button_Handle sAppRightHandle;

	AppTask AppTask::sAppTask;

	static DeviceCallbacks sDeviceCallbacks;

	#if defined(CHIP_DEVICE_CONFIG_ENABLE_OTA_REQUESTOR)
	static DefaultOTARequestor sRequestorCore;
	static DefaultOTARequestorStorage sRequestorStorage;
	static DefaultOTARequestorDriver sRequestorUser;
	static BDXDownloader sDownloader;
	static OTAImageProcessorImpl sImageProcessor;

	void InitializeOTARequestor(void)
	{
	// Initialize and interconnect the Requestor and Image Processor objects
	SetRequestorInstance(&sRequestorCore);

	sRequestorStorage.Init(chip::Server::GetInstance().GetPersistentStorage());
	sRequestorCore.Init(chip::Server::GetInstance(), sRequestorStorage, sRequestorUser, sDownloader);
	sImageProcessor.SetOTADownloader(&sDownloader);
	sDownloader.SetImageProcessorDelegate(&sImageProcessor);
	sRequestorUser.Init(&sRequestorCore, &sImageProcessor);
	}
	#endif

	static const chip::EndpointId sIdentifyEndpointId = 0;
	static const uint32_t sIdentifyBlinkRateMs = 500;

	::Identify stIdentify = { sIdentifyEndpointId, AppTask::IdentifyStartHandler, AppTask::IdentifyStopHandler,
	Clusters::Identify::IdentifyTypeEnum::kVisibleIndicator, AppTask::TriggerIdentifyEffectHandler };

	int AppTask::StartAppTask()
	{
	int ret = 0;

	sAppEventQueue = xQueueCreate(APP_EVENT_QUEUE_SIZE, sizeof(AppEvent));
	if (sAppEventQueue == NULL)
	{
	PLAT_LOG("Failed to allocate app event queue");
	while (true)
	;
	}

	// Start App task.
	if (xTaskCreate(AppTaskMain, "APP", APP_TASK_STACK_SIZE / sizeof(StackType_t), NULL, APP_TASK_PRIORITY, &sAppTaskHandle) !=
	pdPASS)
	{
	PLAT_LOG("Failed to create app task");
	while (true)
	;
	}
	return ret;
	}

	int AppTask::Init()
	{
	LED_Params ledParams;
	Button_Params buttonParams;

	cc13xx_26xxLogInit();

	// Init Chip memory management before the stack
	Platform::MemoryInit();

	CHIP_ERROR ret = PlatformMgr().InitChipStack();
	if (ret != CHIP_NO_ERROR)
	{
	PLAT_LOG("PlatformMgr().InitChipStack() failed");
	while (true)
	;
	}

	ret = ThreadStackMgr().InitThreadStack();
	if (ret != CHIP_NO_ERROR)
	{
	PLAT_LOG("ThreadStackMgr().InitThreadStack() failed");
	while (true)
	;
	}

	#ifdef CONFIG_OPENTHREAD_MTD_SED
	ret = ConnectivityMgr().SetThreadDeviceType(ConnectivityManager::kThreadDeviceType_SleepyEndDevice);
	#elif CONFIG_OPENTHREAD_MTD
	ret = ConnectivityMgr().SetThreadDeviceType(ConnectivityManager::kThreadDeviceType_MinimalEndDevice);
	#else
	ret = ConnectivityMgr().SetThreadDeviceType(ConnectivityManager::kThreadDeviceType_Router);
	#endif
	if (ret != CHIP_NO_ERROR)
	{
	PLAT_LOG("ConnectivityMgr().SetThreadDeviceType() failed");
	while (true)
	;
	}

	ret = ThreadStackMgrImpl().StartThreadTask();
	if (ret != CHIP_NO_ERROR)
	{
	PLAT_LOG("ThreadStackMgr().StartThreadTask() failed");
	while (true)
	;
	}

	// Initialize LEDs
	PLAT_LOG("Initialize LEDs");
	LED_init();

	LED_Params_init(&ledParams); // default PWM LED
	sAppRedHandle = LED_open(CONFIG_LED_RED, &ledParams);
	LED_setOff(sAppRedHandle);

	LED_Params_init(&ledParams); // default PWM LED
	sAppGreenHandle = LED_open(CONFIG_LED_GREEN, &ledParams);
	LED_setOff(sAppGreenHandle);

	// Initialize buttons
	PLAT_LOG("Initialize buttons");
	Button_init();

	Button_Params_init(&buttonParams);
	buttonParams.buttonEventMask = Button_EV_CLICKED \| Button_EV_LONGPRESSED;
	buttonParams.longPressDuration = 5000U; // ms
	sAppLeftHandle = Button_open(CONFIG_BTN_LEFT, &buttonParams);
	Button_setCallback(sAppLeftHandle, ButtonLeftEventHandler);

	Button_Params_init(&buttonParams);
	buttonParams.buttonEventMask = Button_EV_CLICKED;
	buttonParams.longPressDuration = 1000U; // ms
	sAppRightHandle = Button_open(CONFIG_BTN_RIGHT, &buttonParams);
	Button_setCallback(sAppRightHandle, ButtonRightEventHandler);

	// Initialize Pump module
	PLAT_LOG("Initialize Pump");
	PumpMgr().Init();

	PumpMgr().SetCallbacks(ActionInitiated, ActionCompleted);

	#if CHIP_DEVICE_CONFIG_ENABLE_EXTENDED_DISCOVERY
	DnssdServer::Instance().SetExtendedDiscoveryTimeoutSecs(EXTENDED_DISCOVERY_TIMEOUT_SEC);
	#endif

	// Init ZCL Data Model
	static chip::CommonCaseDeviceServerInitParams initParams;
	(void) initParams.InitializeStaticResourcesBeforeServerInit();
	chip::Server::GetInstance().Init(initParams);

	// Initialize device attestation config
	#ifdef CC13X4_26X4_ATTESTATION_CREDENTIALS
	SetDeviceAttestationCredentialsProvider(CC13X4_26X4::GetCC13X4_26X4DacProvider());
	#else
	SetDeviceAttestationCredentialsProvider(Examples::GetExampleDACProvider());
	#endif

	ConfigurationMgr().LogDeviceConfig();

	#if defined(CHIP_DEVICE_CONFIG_ENABLE_OTA_REQUESTOR)
	InitializeOTARequestor();
	#endif

	// QR code will be used with CHIP Tool
	PrintOnboardingCodes(RendezvousInformationFlags(RendezvousInformationFlag::kBLE));

	CHIPDeviceManager & deviceMgr = CHIPDeviceManager::GetInstance();
	ret = deviceMgr.Init(&sDeviceCallbacks);
	if (ret != CHIP_NO_ERROR)
	{
	PLAT_LOG("CHIPDeviceManager::Init() failed: %s", ErrorStr(ret));
	while (true)
	;
	}

	return 0;
	}

	void AppTask::AppTaskMain(void * pvParameter)
	{
	AppEvent event;

	sAppTask.Init();

	while (true)
	{
	/* Task pend until we have stuff to do */
	if (xQueueReceive(sAppEventQueue, &event, portMAX_DELAY) == pdTRUE)
	{
	sAppTask.DispatchEvent(&event);
	}
	}
	}

	void AppTask::PostEvent(const AppEvent * aEvent)
	{
	if (xQueueSend(sAppEventQueue, aEvent, 0) != pdPASS)
	{
	/* Failed to post the message */
	}
	}

	void AppTask::ButtonLeftEventHandler(Button_Handle handle, Button_EventMask events)
	{
	AppEvent event;
	event.Type = AppEvent::kEventType_ButtonLeft;

	if (events & Button_EV_CLICKED)
	{
	event.ButtonEvent.Type = AppEvent::kAppEventButtonType_Clicked;
	}
	else if (events & Button_EV_LONGPRESSED)
	{
	event.ButtonEvent.Type = AppEvent::kAppEventButtonType_LongPressed;
	}
	// button callbacks are in ISR context
	if (xQueueSendFromISR(sAppEventQueue, &event, NULL) != pdPASS)
	{
	/* Failed to post the message */
	}
	}

	void AppTask::ButtonRightEventHandler(Button_Handle handle, Button_EventMask events)
	{
	AppEvent event;
	event.Type = AppEvent::kEventType_ButtonRight;

	if (events & Button_EV_CLICKED)
	{
	event.ButtonEvent.Type = AppEvent::kAppEventButtonType_Clicked;
	}
	// button callbacks are in ISR context
	if (xQueueSendFromISR(sAppEventQueue, &event, NULL) != pdPASS)
	{
	/* Failed to post the message */
	}
	}

	void AppTask::ActionInitiated(PumpManager::Action_t aAction, int32_t aActor)
	{
	// If the action has been initiated by the pump, update the pump trait
	// and start flashing the LEDs rapidly to indicate action initiation.
	if (aAction == PumpManager::START_ACTION)
	{
	PLAT_LOG("Pump start initiated");
	; // TODO
	}
	else if (aAction == PumpManager::STOP_ACTION)
	{
	PLAT_LOG("Stop initiated");
	; // TODO
	}

	LED_setOn(sAppGreenHandle, LED_BRIGHTNESS_MAX);
	LED_startBlinking(sAppGreenHandle, 50 /* ms */, LED_BLINK_FOREVER);
	LED_setOn(sAppRedHandle, LED_BRIGHTNESS_MAX);
	LED_startBlinking(sAppRedHandle, 110 /* ms */, LED_BLINK_FOREVER);
	}

	void AppTask::ActionCompleted(PumpManager::Action_t aAction, int32_t aActor)
	{
	// if the action has been completed by the pump, update the pump trait.
	// Turn on the pump state LED if in a STARTED state OR
	// Turn off the pump state LED if in an STOPPED state.
	if (aAction == PumpManager::START_ACTION)
	{
	PLAT_LOG("Pump start completed");
	LED_stopBlinking(sAppGreenHandle);
	LED_setOn(sAppGreenHandle, LED_BRIGHTNESS_MAX);
	LED_stopBlinking(sAppRedHandle);
	LED_setOn(sAppRedHandle, LED_BRIGHTNESS_MAX);
	// Signal to the PCC cluster, that the pump is running
	sAppTask.UpdateClusterState();
	}
	else if (aAction == PumpManager::STOP_ACTION)
	{
	PLAT_LOG("Pump stop completed");
	LED_stopBlinking(sAppGreenHandle);
	LED_setOff(sAppGreenHandle);
	LED_stopBlinking(sAppRedHandle);
	LED_setOff(sAppRedHandle);
	// Signal to the PCC cluster, that the pump is NOT running
	sAppTask.UpdateClusterState();
	}
	if (aActor == AppEvent::kEventType_ButtonLeft)
	{
	sAppTask.UpdateClusterState();
	}
	}

	void AppTask::DispatchEvent(AppEvent * aEvent)
	{
	switch (aEvent->Type)
	{
	case AppEvent::kEventType_ButtonRight:
	if (AppEvent::kAppEventButtonType_Clicked == aEvent->ButtonEvent.Type)
	{
	// Toggle Pump state
	if (!PumpMgr().IsStopped())
	{
	PumpMgr().InitiateAction(0, PumpManager::STOP_ACTION);
	}
	else
	{
	PumpMgr().InitiateAction(0, PumpManager::START_ACTION);
	}
	}
	break;

	case AppEvent::kEventType_ButtonLeft:
	if (AppEvent::kAppEventButtonType_Clicked == aEvent->ButtonEvent.Type)
	{
	// Post event for demonstration purposes, we must ensure that the
	// LogEvent is called in the right context which is the Matter mainloop
	// thru ScheduleWork()
	chip::DeviceLayer::PlatformMgr().ScheduleWork(sAppTask.PostEvents, reinterpret_cast<intptr_t>(nullptr));

	// Toggle BLE advertisements
	if (!ConnectivityMgr().IsBLEAdvertisingEnabled())
	{
	if (chip::Server::GetInstance().GetCommissioningWindowManager().OpenBasicCommissioningWindow() == CHIP_NO_ERROR)
	{
	PLAT_LOG("Enabled BLE Advertisements");
	}
	else
	{
	PLAT_LOG("OpenBasicCommissioningWindow() failed");
	}
	}
	else
	{
	// Disable BLE advertisements
	ConnectivityMgr().SetBLEAdvertisingEnabled(false);
	PLAT_LOG("Disabled BLE Advertisements");
	}
	}
	else if (AppEvent::kAppEventButtonType_LongPressed == aEvent->ButtonEvent.Type)
	{
	chip::Server::GetInstance().ScheduleFactoryReset();
	}
	break;

	case AppEvent::kEventType_IdentifyStart:
	LED_setOn(sAppGreenHandle, LED_BRIGHTNESS_MAX);
	LED_startBlinking(sAppGreenHandle, sIdentifyBlinkRateMs, LED_BLINK_FOREVER);
	PLAT_LOG("Identify started");
	break;

	case AppEvent::kEventType_IdentifyStop:
	LED_stopBlinking(sAppGreenHandle);

	if (!PumpMgr().IsStopped())
	{
	LED_setOn(sAppGreenHandle, LED_BRIGHTNESS_MAX);
	}
	else
	{
	LED_setOff(sAppGreenHandle);
	}
	PLAT_LOG("Identify stopped");
	break;

	case AppEvent::kEventType_AppEvent:
	if (NULL != aEvent->Handler)
	{
	aEvent->Handler(aEvent);
	}
	break;

	case AppEvent::kEventType_None:
	default:
	break;
	}
	}

	void AppTask::InitOnOffClusterState()
	{

	EmberStatus status;

	ChipLogProgress(NotSpecified, "Init On/Off clusterstate");

	// Write false as pump always boots in stopped mode
	status = OnOff::Attributes::OnOff::Set(ONOFF_CLUSTER_ENDPOINT, false);
	if (status != EMBER_ZCL_STATUS_SUCCESS)
	{
	ChipLogError(NotSpecified, "ERR: Init On/Off state %x", status);
	}
	}

	void AppTask::InitPCCClusterState() {}

	void AppTask::UpdateClusterState(void)
	{
	// We must ensure that the Cluster accessors gets called in the right context
	// which is the Matter mainloop thru ScheduleWork()
	chip::DeviceLayer::PlatformMgr().ScheduleWork(UpdateCluster, reinterpret_cast<intptr_t>(nullptr));
	}

	void AppTask::UpdateCluster(intptr_t context)
	{
	EmberStatus status;
	BitMask<PumpConfigurationAndControl::PumpStatusBitmap> pumpStatus;

	ChipLogProgress(NotSpecified, "Update Cluster State");

	// Update the PumpStatus
	PumpConfigurationAndControl::Attributes::PumpStatus::Get(PCC_CLUSTER_ENDPOINT, &pumpStatus);
	if (PumpMgr().IsStopped())
	{
	pumpStatus.Clear(PumpConfigurationAndControl::PumpStatusBitmap::kRunning);
	}
	else
	{
	pumpStatus.Set(PumpConfigurationAndControl::PumpStatusBitmap::kRunning);
	}
	PumpConfigurationAndControl::Attributes::PumpStatus::Set(PCC_CLUSTER_ENDPOINT, pumpStatus);

	status = PumpConfigurationAndControl::Attributes::ControlMode::Set(PCC_CLUSTER_ENDPOINT,
	PumpConfigurationAndControl::ControlModeEnum::kConstantFlow);
	if (status != EMBER_ZCL_STATUS_SUCCESS)
	{
	ChipLogError(NotSpecified, "ERR: Constant Flow error %x", status);
	}
	status = PumpConfigurationAndControl::Attributes::ControlMode::Set(
	PCC_CLUSTER_ENDPOINT, PumpConfigurationAndControl::ControlModeEnum::kConstantPressure);
	if (status != EMBER_ZCL_STATUS_SUCCESS)
	{
	ChipLogError(NotSpecified, "ERR: Constant Pressure error %x", status);
	}
	status = PumpConfigurationAndControl::Attributes::ControlMode::Set(
	PCC_CLUSTER_ENDPOINT, PumpConfigurationAndControl::ControlModeEnum::kConstantSpeed);
	if (status != EMBER_ZCL_STATUS_SUCCESS)
	{
	ChipLogError(NotSpecified, "ERR: Constant Speed error %x", status);
	}
	status = PumpConfigurationAndControl::Attributes::ControlMode::Set(
	PCC_CLUSTER_ENDPOINT, PumpConfigurationAndControl::ControlModeEnum::kConstantTemperature);
	if (status != EMBER_ZCL_STATUS_SUCCESS)
	{
	ChipLogError(NotSpecified, "ERR: Constant Temperature error %x", status);
	}

	// Write the new values
	bool onOffState = !PumpMgr().IsStopped();
	status = OnOff::Attributes::OnOff::Set(ONOFF_CLUSTER_ENDPOINT, onOffState);
	if (status != EMBER_ZCL_STATUS_SUCCESS)
	{
	ChipLogError(NotSpecified, "ERR: Updating On/Off state %x", status);
	}

	int16_t maxPressure = PumpMgr().GetMaxPressure();
	status = PumpConfigurationAndControl::Attributes::MaxPressure::Set(PCC_CLUSTER_ENDPOINT, maxPressure);
	if (status != EMBER_ZCL_STATUS_SUCCESS)
	{
	ChipLogError(NotSpecified, "ERR: Updating MaxPressure %x", status);
	}

	uint16_t maxSpeed = PumpMgr().GetMaxSpeed();
	status = PumpConfigurationAndControl::Attributes::MaxSpeed::Set(PCC_CLUSTER_ENDPOINT, maxSpeed);
	if (status != EMBER_ZCL_STATUS_SUCCESS)
	{
	ChipLogError(NotSpecified, "ERR: Updating MaxSpeed %x", status);
	}

	uint16_t maxFlow = PumpMgr().GetMaxFlow();
	status = PumpConfigurationAndControl::Attributes::MaxFlow::Set(PCC_CLUSTER_ENDPOINT, maxFlow);
	if (status != EMBER_ZCL_STATUS_SUCCESS)
	{
	ChipLogError(NotSpecified, "ERR: Updating MaxFlow %x", status);
	}

	int16_t minConstPress = PumpMgr().GetMinConstPressure();
	status = PumpConfigurationAndControl::Attributes::MinConstPressure::Set(PCC_CLUSTER_ENDPOINT, minConstPress);
	if (status != EMBER_ZCL_STATUS_SUCCESS)
	{
	ChipLogError(NotSpecified, "ERR: Updating MinConstPressure %x", status);
	}

	int16_t maxConstPress = PumpMgr().GetMaxConstPressure();
	status = PumpConfigurationAndControl::Attributes::MaxConstPressure::Set(PCC_CLUSTER_ENDPOINT, maxConstPress);
	if (status != EMBER_ZCL_STATUS_SUCCESS)
	{
	ChipLogError(NotSpecified, "ERR: Updating MaxConstPressure %x", status);
	}

	int16_t minCompPress = PumpMgr().GetMinCompPressure();
	status = PumpConfigurationAndControl::Attributes::MinCompPressure::Set(PCC_CLUSTER_ENDPOINT, minCompPress);
	if (status != EMBER_ZCL_STATUS_SUCCESS)
	{
	ChipLogError(NotSpecified, "ERR: Updating MinCompPressure %x", status);
	}

	int16_t maxCompPress = PumpMgr().GetMaxCompPressure();
	status = PumpConfigurationAndControl::Attributes::MaxCompPressure::Set(PCC_CLUSTER_ENDPOINT, maxCompPress);
	if (status != EMBER_ZCL_STATUS_SUCCESS)
	{
	ChipLogError(NotSpecified, "ERR: Updating MaxCompPressure %x", status);
	}

	uint16_t minConstSpeed = PumpMgr().GetMinConstSpeed();
	status = PumpConfigurationAndControl::Attributes::MinConstSpeed::Set(PCC_CLUSTER_ENDPOINT, minConstSpeed);
	if (status != EMBER_ZCL_STATUS_SUCCESS)
	{
	ChipLogError(NotSpecified, "ERR: Updating MinConstSpeed %x", status);
	}

	uint16_t maxConstSpeed = PumpMgr().GetMaxConstSpeed();
	status = PumpConfigurationAndControl::Attributes::MaxConstSpeed::Set(PCC_CLUSTER_ENDPOINT, maxConstSpeed);
	if (status != EMBER_ZCL_STATUS_SUCCESS)
	{
	ChipLogError(NotSpecified, "ERR: Updating MaxConstSpeed %x", status);
	}

	uint16_t minConstFlow = PumpMgr().GetMinConstFlow();
	status = PumpConfigurationAndControl::Attributes::MinConstFlow::Set(PCC_CLUSTER_ENDPOINT, minConstFlow);
	if (status != EMBER_ZCL_STATUS_SUCCESS)
	{
	ChipLogError(NotSpecified, "ERR: Updating MinConstFlow %x", status);
	}

	uint16_t maxConstFlow = PumpMgr().GetMaxConstFlow();
	status = PumpConfigurationAndControl::Attributes::MaxConstFlow::Set(PCC_CLUSTER_ENDPOINT, maxConstFlow);
	if (status != EMBER_ZCL_STATUS_SUCCESS)
	{
	ChipLogError(NotSpecified, "ERR: Updating MaxConstFlow %x", status);
	}

	int16_t minConstTemp = PumpMgr().GetMinConstTemp();
	status = PumpConfigurationAndControl::Attributes::MinConstTemp::Set(PCC_CLUSTER_ENDPOINT, minConstTemp);
	if (status != EMBER_ZCL_STATUS_SUCCESS)
	{
	ChipLogError(NotSpecified, "ERR: Updating MinConstTemp %x", status);
	}

	int16_t maxConstTemp = PumpMgr().GetMaxConstTemp();
	status = PumpConfigurationAndControl::Attributes::MaxConstTemp::Set(PCC_CLUSTER_ENDPOINT, maxConstTemp);
	if (status != EMBER_ZCL_STATUS_SUCCESS)
	{
	ChipLogError(NotSpecified, "ERR: Updating MaxConstTemp %x", status);
	}
	}

	void AppTask::PostEvents(intptr_t context)
	{
	// Example on posting events - here we post the general fault event on endpoints with PCC Server enabled
	for (auto endpoint : EnabledEndpointsWithServerCluster(PumpConfigurationAndControl::Id))
	{
	PumpConfigurationAndControl::Events::GeneralFault::Type event;
	EventNumber eventNumber;

	ChipLogProgress(Zcl, "AppTask: Post PCC GeneralFault event");
	// Using default priority for the event
	if (CHIP_NO_ERROR != LogEvent(event, endpoint, eventNumber))
	{
	ChipLogError(Zcl, "AppTask: Failed to record GeneralFault event");
	}
	}
	}

	void AppTask::IdentifyStartHandler(::Identify *)
	{
	AppEvent event;
	event.Type = AppEvent::kEventType_IdentifyStart;
	sAppTask.PostEvent(&event);
	}

	void AppTask::IdentifyStopHandler(::Identify *)
	{
	AppEvent event;
	event.Type = AppEvent::kEventType_IdentifyStop;
	sAppTask.PostEvent(&event);
	}

	void AppTask::TriggerIdentifyEffectHandler(::Identify * identify)
	{
	switch (identify->mCurrentEffectIdentifier)
	{
	case Clusters::Identify::EffectIdentifierEnum::kBlink:
	PLAT_LOG("Starting blink identifier effect");
	IdentifyStartHandler(identify);
	break;
	case Clusters::Identify::EffectIdentifierEnum::kBreathe:
	PLAT_LOG("Breathe identifier effect not implemented");
	break;
	case Clusters::Identify::EffectIdentifierEnum::kOkay:
	PLAT_LOG("Okay identifier effect not implemented");
	break;
	case Clusters::Identify::EffectIdentifierEnum::kChannelChange:
	PLAT_LOG("Channel Change identifier effect not implemented");
	break;
	case Clusters::Identify::EffectIdentifierEnum::kFinishEffect:
	PLAT_LOG("Finish identifier effect not implemented");
	break;
	case Clusters::Identify::EffectIdentifierEnum::kStopEffect:
	PLAT_LOG("Stop identifier effect");
	IdentifyStopHandler(identify);
	break;
	default:
	PLAT_LOG("No identifier effect");
	}
	}