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/*
*
* Copyright (c) 2021 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.
*/
#if !defined(GP_APP_DIVERSITY_POWERCYCLECOUNTING)
#error This application requires powercycle counting.
#endif
#include "gpSched.h"
#include "powercycle_counting.h"
#include "qvIO.h"
#include "AppConfig.h"
#include "AppEvent.h"
#include "AppTask.h"
#include "ota.h"
#include <app/server/OnboardingCodesUtil.h>
#include <app-common/zap-generated/attributes/Accessors.h>
#include <app/TestEventTriggerDelegate.h>
#include <app/clusters/general-diagnostics-server/GenericFaultTestEventTriggerHandler.h>
#include <app/clusters/general-diagnostics-server/general-diagnostics-server.h>
#include <app/clusters/identify-server/identify-server.h>
#include <app/clusters/on-off-server/on-off-server.h>
#include <app/server/Dnssd.h>
#include <app/server/Server.h>
#include <app/util/attribute-storage.h>
#include <lib/support/TypeTraits.h>
#include <app/DeferredAttributePersistenceProvider.h>
#include <credentials/DeviceAttestationCredsProvider.h>
#include <credentials/examples/DeviceAttestationCredsExample.h>
#include <inet/EndPointStateOpenThread.h>
#include <DeviceInfoProviderImpl.h>
#include <setup_payload/QRCodeSetupPayloadGenerator.h>
#include <setup_payload/SetupPayload.h>
using namespace ::chip;
using namespace ::chip::app;
using namespace ::chip::TLV;
using namespace ::chip::Credentials;
using namespace ::chip::DeviceLayer;
#include <platform/CHIPDeviceLayer.h>
#define FACTORY_RESET_TRIGGER_TIMEOUT 3000
#define FACTORY_RESET_CANCEL_WINDOW_TIMEOUT 3000
#define OTA_START_TRIGGER_TIMEOUT 1500
#define APP_TASK_STACK_SIZE (3 * 1024)
#define APP_TASK_PRIORITY 2
#define APP_EVENT_QUEUE_SIZE 10
#define QPG_LIGHT_ENDPOINT_ID (1)
#define SECONDS_IN_HOUR (3600) // we better keep this 3600
#define TOTAL_OPERATIONAL_HOURS_SAVE_INTERVAL_SECONDS (1 * SECONDS_IN_HOUR) // increment every hour
static uint8_t countdown = 0;
namespace {
constexpr EndpointId kLightEndpointId = 1;
TaskHandle_t sAppTaskHandle;
QueueHandle_t sAppEventQueue;
bool sIsThreadProvisioned = false;
bool sIsThreadEnabled = false;
bool sHaveBLEConnections = false;
bool sIsBLEAdvertisingEnabled = false;
// NOTE! This key is for test/certification only and should not be available in production devices!
uint8_t sTestEventTriggerEnableKey[TestEventTriggerDelegate::kEnableKeyLength] = { 0x00, 0x11, 0x22, 0x33, 0x44, 0x55, 0x66, 0x77,
0x88, 0x99, 0xaa, 0xbb, 0xcc, 0xdd, 0xee, 0xff };
uint8_t sAppEventQueueBuffer[APP_EVENT_QUEUE_SIZE * sizeof(AppEvent)];
StaticQueue_t sAppEventQueueStruct;
StackType_t appStack[APP_TASK_STACK_SIZE / sizeof(StackType_t)];
StaticTask_t appTaskStruct;
Clusters::Identify::EffectIdentifierEnum sIdentifyEffect = Clusters::Identify::EffectIdentifierEnum::kStopEffect;
chip::DeviceLayer::DeviceInfoProviderImpl gExampleDeviceInfoProvider;
// Define a custom attribute persister which makes actual write of the ColorX attribute value
// to the non-volatile storage only when it has remained constant for 5 seconds. This is to reduce
// the flash wearout when the attribute changes frequently as a result of MoveToLevel command.
// DeferredAttribute object describes a deferred attribute, but also holds a buffer with a value to
// be written, so it must live so long as the DeferredAttributePersistenceProvider object.
//
DeferredAttribute gPersisters[] = {
DeferredAttribute(
ConcreteAttributePath(kLightEndpointId, Clusters::ColorControl::Id, Clusters::ColorControl::Attributes::CurrentHue::Id)),
DeferredAttribute(ConcreteAttributePath(kLightEndpointId, Clusters::ColorControl::Id,
Clusters::ColorControl::Attributes::CurrentSaturation::Id)),
DeferredAttribute(
ConcreteAttributePath(kLightEndpointId, Clusters::LevelControl::Id, Clusters::LevelControl::Attributes::CurrentLevel::Id))
};
DeferredAttributePersistenceProvider gDeferredAttributePersister(Server::GetInstance().GetDefaultAttributePersister(),
Span<DeferredAttribute>(gPersisters, 3),
System::Clock::Milliseconds32(5000));
/**********************************************************
* Identify Callbacks
*********************************************************/
namespace {
void OnTriggerIdentifyEffectCompleted(chip::System::Layer * systemLayer, void * appState)
{
sIdentifyEffect = Clusters::Identify::EffectIdentifierEnum::kStopEffect;
}
} // namespace
void OnTriggerIdentifyEffect(Identify * identify)
{
sIdentifyEffect = identify->mCurrentEffectIdentifier;
if (identify->mEffectVariant != Clusters::Identify::EffectVariantEnum::kDefault)
{
ChipLogDetail(AppServer, "Identify Effect Variant unsupported. Using default");
}
switch (sIdentifyEffect)
{
case Clusters::Identify::EffectIdentifierEnum::kBlink:
case Clusters::Identify::EffectIdentifierEnum::kBreathe:
case Clusters::Identify::EffectIdentifierEnum::kOkay:
case Clusters::Identify::EffectIdentifierEnum::kChannelChange:
SystemLayer().ScheduleLambda([identify] {
(void) chip::DeviceLayer::SystemLayer().StartTimer(chip::System::Clock::Seconds16(5), OnTriggerIdentifyEffectCompleted,
identify);
});
break;
case Clusters::Identify::EffectIdentifierEnum::kFinishEffect:
SystemLayer().ScheduleLambda([identify] {
(void) chip::DeviceLayer::SystemLayer().CancelTimer(OnTriggerIdentifyEffectCompleted, identify);
(void) chip::DeviceLayer::SystemLayer().StartTimer(chip::System::Clock::Seconds16(1), OnTriggerIdentifyEffectCompleted,
identify);
});
break;
case Clusters::Identify::EffectIdentifierEnum::kStopEffect:
SystemLayer().ScheduleLambda(
[identify] { (void) chip::DeviceLayer::SystemLayer().CancelTimer(OnTriggerIdentifyEffectCompleted, identify); });
sIdentifyEffect = Clusters::Identify::EffectIdentifierEnum::kStopEffect;
break;
default:
ChipLogProgress(Zcl, "No identifier effect");
}
}
Identify gIdentify = {
chip::EndpointId{ 1 },
[](Identify *) { ChipLogProgress(Zcl, "onIdentifyStart"); },
[](Identify *) { ChipLogProgress(Zcl, "onIdentifyStop"); },
Clusters::Identify::IdentifyTypeEnum::kVisibleIndicator,
OnTriggerIdentifyEffect,
};
/**********************************************************
* OffWithEffect Callbacks
*********************************************************/
void OnTriggerOffWithEffect(OnOffEffect * effect)
{
auto effectId = effect->mEffectIdentifier;
auto effectVariant = effect->mEffectVariant;
// Uses print outs until we can support the effects
if (effectId == Clusters::OnOff::EffectIdentifierEnum::kDelayedAllOff)
{
auto typedEffectVariant = static_cast<Clusters::OnOff::DelayedAllOffEffectVariantEnum>(effectVariant);
if (typedEffectVariant == Clusters::OnOff::DelayedAllOffEffectVariantEnum::kDelayedOffFastFade)
{
ChipLogProgress(Zcl, "DelayedAllOffEffectVariantEnum::kDelayedOffFastFade");
}
else if (typedEffectVariant == Clusters::OnOff::DelayedAllOffEffectVariantEnum::kNoFade)
{
ChipLogProgress(Zcl, "DelayedAllOffEffectVariantEnum::kNoFade");
}
else if (typedEffectVariant == Clusters::OnOff::DelayedAllOffEffectVariantEnum::kDelayedOffSlowFade)
{
ChipLogProgress(Zcl, "DelayedAllOffEffectVariantEnum::kDelayedOffSlowFade");
}
}
else if (effectId == Clusters::OnOff::EffectIdentifierEnum::kDyingLight)
{
auto typedEffectVariant = static_cast<Clusters::OnOff::DyingLightEffectVariantEnum>(effectVariant);
if (typedEffectVariant == Clusters::OnOff::DyingLightEffectVariantEnum::kDyingLightFadeOff)
{
ChipLogProgress(Zcl, "DyingLightEffectVariantEnum::kDyingLightFadeOff");
}
}
}
OnOffEffect gEffect = {
chip::EndpointId{ 1 },
OnTriggerOffWithEffect,
Clusters::OnOff::EffectIdentifierEnum::kDelayedAllOff,
to_underlying(Clusters::OnOff::DelayedAllOffEffectVariantEnum::kDelayedOffFastFade),
};
} // namespace
AppTask AppTask::sAppTask;
namespace {
constexpr int extDiscTimeoutSecs = 20;
}
void LockOpenThreadTask(void)
{
chip::DeviceLayer::ThreadStackMgr().LockThreadStack();
}
void UnlockOpenThreadTask(void)
{
chip::DeviceLayer::ThreadStackMgr().UnlockThreadStack();
}
CHIP_ERROR AppTask::StartAppTask()
{
sAppEventQueue = xQueueCreateStatic(APP_EVENT_QUEUE_SIZE, sizeof(AppEvent), sAppEventQueueBuffer, &sAppEventQueueStruct);
if (sAppEventQueue == nullptr)
{
ChipLogError(NotSpecified, "Failed to allocate app event queue");
return CHIP_ERROR_NO_MEMORY;
}
// Start App task.
sAppTaskHandle = xTaskCreateStatic(AppTaskMain, APP_TASK_NAME, ArraySize(appStack), nullptr, 1, appStack, &appTaskStruct);
if (sAppTaskHandle == nullptr)
{
return CHIP_ERROR_NO_MEMORY;
}
return CHIP_NO_ERROR;
}
void AppTask::InitServer(intptr_t arg)
{
static chip::CommonCaseDeviceServerInitParams initParams;
(void) initParams.InitializeStaticResourcesBeforeServerInit();
gExampleDeviceInfoProvider.SetStorageDelegate(initParams.persistentStorageDelegate);
chip::DeviceLayer::SetDeviceInfoProvider(&gExampleDeviceInfoProvider);
chip::Inet::EndPointStateOpenThread::OpenThreadEndpointInitParam nativeParams;
nativeParams.lockCb = LockOpenThreadTask;
nativeParams.unlockCb = UnlockOpenThreadTask;
nativeParams.openThreadInstancePtr = chip::DeviceLayer::ThreadStackMgrImpl().OTInstance();
initParams.endpointNativeParams = static_cast<void *>(&nativeParams);
// Use GenericFaultTestEventTriggerHandler to inject faults
static SimpleTestEventTriggerDelegate sTestEventTriggerDelegate{};
static GenericFaultTestEventTriggerHandler sFaultTestEventTriggerHandler{};
VerifyOrDie(sTestEventTriggerDelegate.Init(ByteSpan(sTestEventTriggerEnableKey)) == CHIP_NO_ERROR);
VerifyOrDie(sTestEventTriggerDelegate.AddHandler(&sFaultTestEventTriggerHandler) == CHIP_NO_ERROR);
(void) initParams.InitializeStaticResourcesBeforeServerInit();
initParams.testEventTriggerDelegate = &sTestEventTriggerDelegate;
chip::Server::GetInstance().Init(initParams);
app::SetAttributePersistenceProvider(&gDeferredAttributePersister);
#if CHIP_DEVICE_CONFIG_ENABLE_EXTENDED_DISCOVERY
chip::app::DnssdServer::Instance().SetExtendedDiscoveryTimeoutSecs(extDiscTimeoutSecs);
#endif
// Open commissioning after boot if no fabric was available
if (chip::Server::GetInstance().GetFabricTable().FabricCount() == 0)
{
ChipLogProgress(NotSpecified, "No fabrics, starting commissioning.");
AppTask::OpenCommissioning((intptr_t) 0);
}
}
void AppTask::OpenCommissioning(intptr_t arg)
{
// Enable BLE advertisements
SystemLayer().ScheduleLambda([] {
CHIP_ERROR err;
err = chip::Server::GetInstance().GetCommissioningWindowManager().OpenBasicCommissioningWindow();
if (err == CHIP_NO_ERROR)
{
ChipLogProgress(NotSpecified, "BLE advertising started. Waiting for Pairing.");
}
});
}
CHIP_ERROR AppTask::Init()
{
CHIP_ERROR err = CHIP_NO_ERROR;
PlatformMgr().AddEventHandler(MatterEventHandler, 0);
ChipLogProgress(NotSpecified, "Current Software Version: %s", CHIP_DEVICE_CONFIG_DEVICE_SOFTWARE_VERSION_STRING);
// Init ZCL Data Model and start server
PlatformMgr().ScheduleWork(InitServer, 0);
ReturnErrorOnFailure(mFactoryDataProvider.Init());
SetDeviceInstanceInfoProvider(&mFactoryDataProvider);
SetCommissionableDataProvider(&mFactoryDataProvider);
SetDeviceAttestationCredentialsProvider(&mFactoryDataProvider);
// Setup light
err = LightingMgr().Init();
if (err != CHIP_NO_ERROR)
{
ChipLogError(NotSpecified, "LightingMgr().Init() failed");
return err;
}
LightingMgr().SetCallbacks(ActionInitiated, ActionCompleted);
// Setup button handler
qvIO_SetBtnCallback(ButtonEventHandler);
// Log device configuration
ConfigurationMgr().LogDeviceConfig();
PrintOnboardingCodes(chip::RendezvousInformationFlags(chip::RendezvousInformationFlag::kBLE));
sIsThreadProvisioned = ConnectivityMgr().IsThreadProvisioned();
sIsThreadEnabled = ConnectivityMgr().IsThreadEnabled();
sHaveBLEConnections = (ConnectivityMgr().NumBLEConnections() != 0);
sIsBLEAdvertisingEnabled = ConnectivityMgr().IsBLEAdvertisingEnabled();
UpdateLEDs();
err = chip::DeviceLayer::SystemLayer().StartTimer(chip::System::Clock::Seconds32(TOTAL_OPERATIONAL_HOURS_SAVE_INTERVAL_SECONDS),
TotalHoursTimerHandler, this);
if (err != CHIP_NO_ERROR)
{
ChipLogError(NotSpecified, "StartTimer failed %s: ", chip::ErrorStr(err));
}
return err;
}
void AppTask::AppTaskMain(void * pvParameter)
{
AppEvent event;
while (true)
{
BaseType_t eventReceived = xQueueReceive(sAppEventQueue, &event, portMAX_DELAY);
while (eventReceived == pdTRUE)
{
sAppTask.DispatchEvent(&event);
eventReceived = xQueueReceive(sAppEventQueue, &event, 0);
}
}
}
void AppTask::LightingActionEventHandler(AppEvent * aEvent)
{
LightingManager::Action_t action;
if (aEvent->Type == AppEvent::kEventType_Button)
{
// Toggle light
if (LightingMgr().IsTurnedOn())
{
action = LightingManager::OFF_ACTION;
}
else
{
action = LightingManager::ON_ACTION;
}
sAppTask.mSyncClusterToButtonAction = true;
LightingMgr().InitiateAction(action, 0, 0, 0);
}
if (aEvent->Type == AppEvent::kEventType_Level && aEvent->ButtonEvent.Action != 0)
{
// Toggle Dimming of light between 2 fixed levels
uint8_t val = 0x0;
val = LightingMgr().GetLevel() == 0x40 ? 0xfe : 0x40;
action = LightingManager::LEVEL_ACTION;
sAppTask.mSyncClusterToButtonAction = true;
LightingMgr().InitiateAction(action, 0, 1, &val);
}
}
void AppTask::ButtonEventHandler(uint8_t btnIdx, bool btnPressed)
{
if (btnIdx != APP_ON_OFF_BUTTON && btnIdx != APP_FUNCTION_BUTTON && btnIdx != APP_LEVEL_BUTTON)
{
return;
}
ChipLogProgress(NotSpecified, "ButtonEventHandler %d, %d", btnIdx, btnPressed);
AppEvent button_event = {};
button_event.Type = AppEvent::kEventType_Button;
button_event.ButtonEvent.ButtonIdx = btnIdx;
button_event.ButtonEvent.Action = btnPressed;
if (btnIdx == APP_ON_OFF_BUTTON && btnPressed == true)
{
// Hand off to Light handler - On/Off light
button_event.Handler = LightingActionEventHandler;
}
else if (btnIdx == APP_LEVEL_BUTTON)
{
// Hand off to Light handler - Change level of light
button_event.Type = AppEvent::kEventType_Level;
button_event.Handler = LightingActionEventHandler;
}
else if (btnIdx == APP_FUNCTION_BUTTON)
{
// Hand off to Functionality handler - depends on duration of press
button_event.Handler = FunctionHandler;
}
else
{
return;
}
sAppTask.PostEvent(&button_event);
}
void AppTask::TimerEventHandler(chip::System::Layer * aLayer, void * aAppState)
{
AppEvent event;
event.Type = AppEvent::kEventType_Timer;
event.TimerEvent.Context = aAppState;
event.Handler = FunctionTimerEventHandler;
sAppTask.PostEvent(&event);
}
void AppTask::TotalHoursTimerHandler(chip::System::Layer * aLayer, void * aAppState)
{
ChipLogProgress(NotSpecified, "HourlyTimer");
CHIP_ERROR err;
uint32_t totalOperationalHours = 0;
err = ConfigurationMgr().GetTotalOperationalHours(totalOperationalHours);
if (err == CHIP_NO_ERROR)
{
ConfigurationMgr().StoreTotalOperationalHours(totalOperationalHours +
(TOTAL_OPERATIONAL_HOURS_SAVE_INTERVAL_SECONDS / SECONDS_IN_HOUR));
}
else if (err == CHIP_DEVICE_ERROR_CONFIG_NOT_FOUND)
{
totalOperationalHours = 0; // set this explicitly to 0 for safety
ConfigurationMgr().StoreTotalOperationalHours(totalOperationalHours +
(TOTAL_OPERATIONAL_HOURS_SAVE_INTERVAL_SECONDS / SECONDS_IN_HOUR));
}
else
{
ChipLogError(DeviceLayer, "Failed to get total operational hours of the Node");
}
err = chip::DeviceLayer::SystemLayer().StartTimer(chip::System::Clock::Seconds32(TOTAL_OPERATIONAL_HOURS_SAVE_INTERVAL_SECONDS),
TotalHoursTimerHandler, nullptr);
if (err != CHIP_NO_ERROR)
{
ChipLogError(NotSpecified, "StartTimer failed %s: ", chip::ErrorStr(err));
}
}
void AppTask::FunctionTimerEventHandler(AppEvent * aEvent)
{
if (aEvent->Type != AppEvent::kEventType_Timer)
{
return;
}
if (sAppTask.mFunctionTimerActive && sAppTask.mFunction == kFunction_StartBleAdv)
{
ChipLogProgress(NotSpecified, "[BTN] Release button now to start Software Updater");
ChipLogProgress(NotSpecified, "[BTN] Hold to trigger Factory Reset");
sAppTask.mFunction = kFunction_SoftwareUpdate;
sAppTask.StartTimer(FACTORY_RESET_TRIGGER_TIMEOUT - OTA_START_TRIGGER_TIMEOUT);
}
// If we reached here, the button was held past OTA_START_TRIGGER_TIMEOUT,
// initiate OTA update
else if (sAppTask.mFunctionTimerActive && sAppTask.mFunction == kFunction_SoftwareUpdate)
{
ChipLogProgress(NotSpecified, "[BTN] Factory Reset selected. Release within %us to cancel.",
FACTORY_RESET_CANCEL_WINDOW_TIMEOUT / 1000);
// Start timer for FACTORY_RESET_CANCEL_WINDOW_TIMEOUT to allow user to
// cancel, if required.
sAppTask.StartTimer(FACTORY_RESET_CANCEL_WINDOW_TIMEOUT);
sAppTask.mFunction = kFunction_FactoryReset;
// Turn off all LEDs before starting blink to make sure blink is
// co-ordinated.
qvIO_LedSet(SYSTEM_STATE_LED, false);
qvIO_LedBlink(SYSTEM_STATE_LED, 500, 500);
}
else if (sAppTask.mFunctionTimerActive && sAppTask.mFunction == kFunction_FactoryReset)
{
// Actually trigger Factory Reset
sAppTask.mFunction = kFunction_NoneSelected;
SystemLayer().ScheduleLambda([] { chip::Server::GetInstance().ScheduleFactoryReset(); });
}
}
void AppTask::FunctionHandler(AppEvent * aEvent)
{
if (aEvent->ButtonEvent.ButtonIdx != APP_FUNCTION_BUTTON)
{
return;
}
// To trigger software update: press the APP_FUNCTION_BUTTON button briefly (<
// FACTORY_RESET_TRIGGER_TIMEOUT) To initiate factory reset: press the
// APP_FUNCTION_BUTTON for FACTORY_RESET_TRIGGER_TIMEOUT +
// FACTORY_RESET_CANCEL_WINDOW_TIMEOUT All LEDs start blinking after
// FACTORY_RESET_TRIGGER_TIMEOUT to signal factory reset has been initiated.
// To cancel factory reset: release the APP_FUNCTION_BUTTON once all LEDs
// start blinking within the FACTORY_RESET_CANCEL_WINDOW_TIMEOUT
if (aEvent->ButtonEvent.Action == true)
{
if (!sAppTask.mFunctionTimerActive && sAppTask.mFunction == kFunction_NoneSelected)
{
ChipLogProgress(NotSpecified, "[BTN] Hold to select function:");
ChipLogProgress(NotSpecified, "[BTN] - Trigger BLE adv (0-1.5s)");
ChipLogProgress(NotSpecified, "[BTN] - Trigger OTA (1.5-3s)");
ChipLogProgress(NotSpecified, "[BTN] - Factory Reset (>6s)");
sAppTask.StartTimer(FACTORY_RESET_TRIGGER_TIMEOUT);
sAppTask.mFunction = kFunction_StartBleAdv;
}
}
else
{
if (sAppTask.mFunctionTimerActive && sAppTask.mFunction == kFunction_StartBleAdv)
{
sAppTask.CancelTimer();
sAppTask.mFunction = kFunction_NoneSelected;
if (ConnectivityMgr().IsBLEAdvertisingEnabled())
{
ChipLogProgress(NotSpecified, "BLE advertising already in progress.");
}
else
{
// Enable BLE advertisements and pairing window
AppTask::OpenCommissioning((intptr_t) 0);
ChipLogProgress(NotSpecified, "BLE advertising started. Waiting for Pairing.");
}
}
else if (sAppTask.mFunctionTimerActive && sAppTask.mFunction == kFunction_SoftwareUpdate)
{
sAppTask.CancelTimer();
sAppTask.mFunction = kFunction_NoneSelected;
ChipLogProgress(NotSpecified, "[BTN] Triggering OTA Query");
TriggerOTAQuery();
}
else if (sAppTask.mFunctionTimerActive && sAppTask.mFunction == kFunction_FactoryReset)
{
sAppTask.CancelTimer();
// Change the function to none selected since factory reset has been
// canceled.
sAppTask.mFunction = kFunction_NoneSelected;
ChipLogProgress(NotSpecified, "[BTN] Factory Reset has been Canceled");
}
}
}
void AppTask::CancelTimer()
{
SystemLayer().ScheduleLambda([this] {
chip::DeviceLayer::SystemLayer().CancelTimer(TimerEventHandler, this);
this->mFunctionTimerActive = false;
});
}
void AppTask::StartTimer(uint32_t aTimeoutInMs)
{
SystemLayer().ScheduleLambda([aTimeoutInMs, this] {
CHIP_ERROR err;
chip::DeviceLayer::SystemLayer().CancelTimer(TimerEventHandler, this);
err =
chip::DeviceLayer::SystemLayer().StartTimer(chip::System::Clock::Milliseconds32(aTimeoutInMs), TimerEventHandler, this);
SuccessOrExit(err);
this->mFunctionTimerActive = true;
exit:
if (err != CHIP_NO_ERROR)
{
ChipLogError(NotSpecified, "StartTimer failed %s: ", chip::ErrorStr(err));
}
});
}
void AppTask::ActionInitiated(LightingManager::Action_t aAction)
{
// Placeholder for light action
if (aAction == LightingManager::ON_ACTION)
{
ChipLogProgress(NotSpecified, "Light goes on");
}
else if (aAction == LightingManager::OFF_ACTION)
{
ChipLogProgress(NotSpecified, "Light goes off ");
}
}
void AppTask::ActionCompleted(LightingManager::Action_t aAction)
{
// Placeholder for light action completed
if (aAction == LightingManager::ON_ACTION)
{
ChipLogProgress(NotSpecified, "Light On Action has been completed");
}
else if (aAction == LightingManager::OFF_ACTION)
{
ChipLogProgress(NotSpecified, "Light Off Action has been completed");
}
if (sAppTask.mSyncClusterToButtonAction)
{
sAppTask.UpdateClusterState();
sAppTask.mSyncClusterToButtonAction = false;
}
}
void AppTask::PostEvent(const AppEvent * aEvent)
{
if (sAppEventQueue != nullptr)
{
if (!xQueueSend(sAppEventQueue, aEvent, 1))
{
ChipLogError(NotSpecified, "Failed to post event to app task event queue");
}
}
else
{
ChipLogError(NotSpecified, "Event Queue is nullptr should never happen");
}
}
void AppTask::DispatchEvent(AppEvent * aEvent)
{
if (aEvent->Handler)
{
aEvent->Handler(aEvent);
}
else
{
ChipLogError(NotSpecified, "Event received with no handler. Dropping event.");
}
}
/**
* Update cluster status after application level changes
*/
void AppTask::UpdateClusterState(void)
{
SystemLayer().ScheduleLambda([] {
ChipLogProgress(NotSpecified, "UpdateClusterState");
// Write the new on/off value
Protocols::InteractionModel::Status status =
Clusters::OnOff::Attributes::OnOff::Set(QPG_LIGHT_ENDPOINT_ID, LightingMgr().IsTurnedOn());
if (status != Protocols::InteractionModel::Status::Success)
{
ChipLogError(NotSpecified, "ERR: updating on/off %x", to_underlying(status));
}
// Write new level value
status = Clusters::LevelControl::Attributes::CurrentLevel::Set(QPG_LIGHT_ENDPOINT_ID, LightingMgr().GetLevel());
if (status != Protocols::InteractionModel::Status::Success)
{
ChipLogError(NotSpecified, "ERR: updating level %x", to_underlying(status));
}
});
}
void AppTask::UpdateLEDs(void)
{
// If system has "full connectivity", keep the LED On constantly.
//
// If thread and service provisioned, but not attached to the thread network
// yet OR no connectivity to the service OR subscriptions are not fully
// established THEN blink the LED Off for a short period of time.
//
// If the system has ble connection(s) uptill the stage above, THEN blink
// the LEDs at an even rate of 100ms.
//
// Otherwise, turn the LED OFF.
if (sIsThreadProvisioned && sIsThreadEnabled)
{
qvIO_LedSet(SYSTEM_STATE_LED, true);
}
else if (sIsThreadProvisioned && !sIsThreadEnabled)
{
qvIO_LedBlink(SYSTEM_STATE_LED, 950, 50);
}
else if (sHaveBLEConnections)
{
qvIO_LedBlink(SYSTEM_STATE_LED, 100, 100);
}
else if (sIsBLEAdvertisingEnabled)
{
qvIO_LedBlink(SYSTEM_STATE_LED, 50, 50);
}
else
{
// not commisioned yet
qvIO_LedSet(SYSTEM_STATE_LED, false);
}
}
void AppTask::MatterEventHandler(const ChipDeviceEvent * event, intptr_t)
{
switch (event->Type)
{
case DeviceEventType::kServiceProvisioningChange: {
sIsThreadProvisioned = event->ServiceProvisioningChange.IsServiceProvisioned;
UpdateLEDs();
break;
}
case DeviceEventType::kThreadConnectivityChange: {
sIsThreadEnabled = (event->ThreadConnectivityChange.Result == kConnectivity_Established);
UpdateLEDs();
break;
}
case DeviceEventType::kCHIPoBLEConnectionEstablished: {
sHaveBLEConnections = true;
UpdateLEDs();
break;
}
case DeviceEventType::kCHIPoBLEConnectionClosed: {
sHaveBLEConnections = false;
UpdateLEDs();
break;
}
case DeviceEventType::kCHIPoBLEAdvertisingChange: {
sIsBLEAdvertisingEnabled = (event->CHIPoBLEAdvertisingChange.Result == kActivity_Started);
UpdateLEDs();
break;
}
default:
break;
}
}
static void NextCountdown(void)
{
if (countdown > 0)
{
LightingMgr().InitiateAction((countdown % 2 == 0) ? LightingManager::ON_ACTION : LightingManager::OFF_ACTION, 0, 0, 0);
countdown--;
gpSched_ScheduleEvent(1000000UL, NextCountdown);
}
else
{
SystemLayer().ScheduleLambda([] { ConfigurationMgr().InitiateFactoryReset(); });
}
}
extern "C" {
void gpAppFramework_Reset_cbTriggerResetCountCompleted(void)
{
uint8_t resetCount = gpAppFramework_Reset_GetResetCount();
ChipLogProgress(NotSpecified, "%d resets so far", resetCount);
if (resetCount == 10)
{
ChipLogProgress(NotSpecified, "Factory Reset Triggered!");
countdown = 5;
NextCountdown();
}
}
}