components/button/button.c - mcuxpresso_sdk - Git at Google

 /*
  * Copyright 2018-2019 NXP
  * All rights reserved.
  *
  *
  * SPDX-License-Identifier: BSD-3-Clause
  */

 #include "fsl_common.h"
 #include "gpio.h"
 #include "timer_manager.h"

 #include "button.h"
 /*
  * The OSA_USED macro can only be defined when the OSA component is used.
  * If the source code of the OSA component does not exist, the OSA_USED cannot be defined.
  * OR, If OSA component is not added into project event the OSA source code exists, the OSA_USED
  * also cannot be defined.
  * The source code path of the OSA component is <MCUXpresso_SDK>/components/osa.
  *
  */
 #if defined(OSA_USED)
 #include "fsl_os_abstraction.h"
 #if (defined(BUTTON_USE_COMMON_TASK) && (BUTTON_USE_COMMON_TASK > 0U))
 #include "common_task.h"
 #endif
 #endif

 /*******************************************************************************
  * Definitions
  ******************************************************************************/

 #define BUTTON_SR_ALLOC()       uint32_t buttonPrimask;
 #define BUTTON_ENTER_CRITICAL() buttonPrimask = DisableGlobalIRQ();
 #define BUTTON_EXIT_CRITICAL()  EnableGlobalIRQ(buttonPrimask);

 typedef enum _button_press_status
 {
     kStatus_BUTTON_PressIdle          = 0, /*!< Idle */
     kStatus_BUTTON_Pressed            = 1, /*!< Pressed */
     kStatus_BUTTON_PressDoubleStart   = 2, /*!< Start double click */
     kStatus_BUTTON_PressDoublePressed = 3, /*!< Second press for double click */
 } button_press_status_t;

 typedef struct _button_state
 {
     struct _button_state *next;
     button_callback_t callback;
     void *callbackParam;
     GPIO_HANDLE_DEFINE(gpioHandle);
     volatile uint32_t pushPeriodCount;
     volatile uint32_t pushPeriodCountLast;
     struct
     {
         uint16_t port : 3U;
         uint16_t reserved : 1U;
         uint16_t pin : 5U;
         uint16_t pinStateDefault : 1U;
         uint16_t reserved2 : 6U;
     } config;
     struct
     {
         volatile uint8_t pressed;
         volatile uint8_t msg;
     } state;
 } button_state_t;

 typedef struct _button_list
 {
     volatile uint32_t periodCount;
     TIMER_MANAGER_HANDLE_DEFINE(timerHandle);
 #if defined(OSA_USED)

 #if (defined(BUTTON_USE_COMMON_TASK) && (BUTTON_USE_COMMON_TASK > 0U))
     common_task_message_t commonTaskMsg;
 #else
     OSA_EVENT_HANDLE_DEFINE(eventHandle);
     OSA_TASK_HANDLE_DEFINE(taskHandle);
 #endif

 #endif
     button_state_t *button;
     volatile uint8_t timerOpenedNesting;
 } button_list_t;

 /*******************************************************************************
  * Prototypes
  ******************************************************************************/

 static void BUTTON_Task(void *param);

 /*******************************************************************************
  * Variables
  ******************************************************************************/

 static button_list_t s_buttonList;

 #if defined(OSA_USED)
 extern const uint8_t gUseRtos_c;
 #endif

 #if (defined(BUTTON_USE_COMMON_TASK) && (BUTTON_USE_COMMON_TASK > 0U))

 #else
 /*
  * \brief Defines the button task's stack
  */
 OSA_TASK_DEFINE(BUTTON_Task, BUTTON_TASK_PRIORITY, 1, BUTTON_TASK_STACK_SIZE, false);
 #endif

 /*******************************************************************************
  * Code
  ******************************************************************************/

 static void BUTTON_NotificationUpdate(button_state_t *buttonState, button_event_t event)
 {
     buttonState->state.pressed = (uint8_t)kStatus_BUTTON_PressIdle;
     buttonState->state.msg     = (uint8_t)event;
 #if defined(OSA_USED)

 #if (defined(BUTTON_USE_COMMON_TASK) && (BUTTON_USE_COMMON_TASK > 0U))
     s_buttonList.commonTaskMsg.callback      = BUTTON_Task;
     s_buttonList.commonTaskMsg.callbackParam = buttonState;
     COMMON_TASK_post_message(&s_buttonList.commonTaskMsg);
 #else
     (void)OSA_EventSet((osa_event_handle_t)s_buttonList.eventHandle, BUTTON_EVENT_BUTTON);
 #endif

 #else
     BUTTON_Task(&s_buttonList);
 #endif
 }

 static void BUTTON_Event(void *param)
 {
     button_state_t *buttonState = (button_state_t *)param;
     uint8_t pinState            = 0U;

     assert(param);

     (void)HAL_GpioGetInput(buttonState->gpioHandle, &pinState);
     pinState = (0U != pinState) ? 1U : 0U;
     if (((uint8_t)kStatus_BUTTON_PressIdle == buttonState->state.pressed) ||
         ((uint8_t)kStatus_BUTTON_PressDoubleStart == buttonState->state.pressed))
     {
         if (buttonState->config.pinStateDefault != pinState)
         {
             buttonState->state.pressed++;
             buttonState->pushPeriodCount = s_buttonList.periodCount;
         }
     }
     else
     {
         if (buttonState->config.pinStateDefault == pinState)
         {
             if ((BUTTON_DOUBLE_CLICK_THRESHOLD + buttonState->pushPeriodCountLast) >= buttonState->pushPeriodCount)
             {
                 if ((s_buttonList.periodCount - buttonState->pushPeriodCount) < BUTTON_SHORT_PRESS_THRESHOLD)
                 {
                     BUTTON_NotificationUpdate(buttonState, kBUTTON_EventDoubleClick);
                 }
                 else
                 {
                     BUTTON_NotificationUpdate(buttonState, kBUTTON_EventError);
                 }
             }
             else
             {
                 if ((s_buttonList.periodCount - buttonState->pushPeriodCount) < BUTTON_SHORT_PRESS_THRESHOLD)
                 {
                     buttonState->pushPeriodCountLast = s_buttonList.periodCount;
                     buttonState->state.pressed       = (uint8_t)kStatus_BUTTON_PressDoubleStart;
                 }
                 else if ((s_buttonList.periodCount - buttonState->pushPeriodCount) < BUTTON_LONG_PRESS_THRESHOLD)
                 {
                     BUTTON_NotificationUpdate(buttonState, kBUTTON_EventShortPress);
                 }
                 else
                 {
                     BUTTON_NotificationUpdate(buttonState, kBUTTON_EventLongPress);
                 }
             }
         }
     }
 }

 static void BUTTON_Task(void *param)
 {
 #if defined(OSA_USED)

 #if (defined(BUTTON_USE_COMMON_TASK) && (BUTTON_USE_COMMON_TASK > 0U))
 #else
     osa_event_flags_t ev = 0;

     do
     {
         if (KOSA_StatusSuccess == OSA_EventWait((osa_event_handle_t)s_buttonList.eventHandle, osaEventFlagsAll_c, false,
                                                 osaWaitForever_c, &ev))
         {
 #endif

 #endif
     button_state_t *buttonState = s_buttonList.button;
     BUTTON_SR_ALLOC();

     BUTTON_ENTER_CRITICAL();
     while (NULL != buttonState)
     {
         if (0U != buttonState->state.msg)
         {
             button_callback_message_t msg;
             BUTTON_EXIT_CRITICAL();
             msg.event = (button_event_t)buttonState->state.msg;
             (void)buttonState->callback(buttonState, &msg, buttonState->callbackParam);
             buttonState->state.msg = 0U;
             BUTTON_ENTER_CRITICAL();
         }
         buttonState = buttonState->next;
     }
     BUTTON_EXIT_CRITICAL();
 #if defined(OSA_USED)

 #if (defined(BUTTON_USE_COMMON_TASK) && (BUTTON_USE_COMMON_TASK > 0U))
 #else
         }
     } while (gUseRtos_c);
 #endif

 #endif
 }

 static void BUTTON_TimerEvent(void *param)
 {
     button_state_t *buttonState;
     BUTTON_SR_ALLOC();

     s_buttonList.periodCount += BUTTON_TIMER_INTERVAL;

     BUTTON_ENTER_CRITICAL();
     buttonState = s_buttonList.button;
     while (NULL != buttonState)
     {
         /*
          * The code block is used to indentify the button event is one click or double click.
          * If the flag pending is set and the button is not pressed, check the user activity is timeout or not.
          * If is times out, notify the upper layer it is kBUTTON_EventOneClick.
          * Otherwise, check the status next time.
          */
         if ((uint8_t)kStatus_BUTTON_PressDoubleStart == buttonState->state.pressed)
         {
             if ((BUTTON_DOUBLE_CLICK_THRESHOLD + buttonState->pushPeriodCountLast) < s_buttonList.periodCount)
             {
                 BUTTON_NotificationUpdate(buttonState, kBUTTON_EventOneClick);
                 buttonState->pushPeriodCountLast = 0U;
             }
         }
         buttonState = buttonState->next;
     }
     BUTTON_EXIT_CRITICAL();
 }

 static void BUTTON_OpenTimer(void)
 {
     BUTTON_SR_ALLOC();
     uint8_t initTimer = 0U;

     BUTTON_ENTER_CRITICAL();
     initTimer = (uint8_t)(!(bool)s_buttonList.timerOpenedNesting);
     s_buttonList.timerOpenedNesting++;
     BUTTON_EXIT_CRITICAL();

     if (0U != initTimer)
     {
         timer_status_t timerStatus;
         timerStatus = TM_Open((timer_handle_t)s_buttonList.timerHandle);
         assert(kStatus_TimerSuccess == timerStatus);
         timerStatus = TM_InstallCallback(s_buttonList.timerHandle, BUTTON_TimerEvent, &s_buttonList);
         assert(kStatus_TimerSuccess == timerStatus);
         timerStatus = TM_Start(s_buttonList.timerHandle, (uint8_t)kTimerModeLowPowerTimer, BUTTON_TIMER_INTERVAL);
         assert(kStatus_TimerSuccess == timerStatus);
         (void)timerStatus;
     }
 }

 static void BUTTON_CloseTimer(void)
 {
     BUTTON_SR_ALLOC();
     uint8_t deinitTimer = 0U;

     BUTTON_ENTER_CRITICAL();
     if (s_buttonList.timerOpenedNesting > 0U)
     {
         s_buttonList.timerOpenedNesting--;
         deinitTimer = (uint8_t)(!(bool)s_buttonList.timerOpenedNesting);
     }
     BUTTON_EXIT_CRITICAL();

     if (0U != deinitTimer)
     {
         timer_status_t timerStatus;
         timerStatus = TM_Close((timer_handle_t)s_buttonList.timerHandle);
         assert(kStatus_TimerSuccess == timerStatus);
         (void)timerStatus;
     }
 }

 button_status_t BUTTON_Init(button_handle_t buttonHandle, button_config_t *buttonConfig)
 {
     hal_gpio_pin_config_t controlPin;
     button_state_t *buttonState;
     hal_gpio_status_t gpioStatus;
     BUTTON_SR_ALLOC();

     assert((NULL != buttonHandle) && (NULL != buttonConfig));
     assert(BUTTON_HANDLE_SIZE >= sizeof(button_state_t));

     buttonState = (button_state_t *)buttonHandle;

     (void)memset(buttonHandle, 0, sizeof(button_state_t));

     BUTTON_ENTER_CRITICAL();
     BUTTON_OpenTimer();
     if (NULL == s_buttonList.button)
     {
 #if defined(OSA_USED)

 #if (defined(BUTTON_USE_COMMON_TASK) && (BUTTON_USE_COMMON_TASK > 0U))
         COMMON_TASK_init();
 #else
         osa_status_t osaStatus;

         osaStatus = OSA_EventCreate((osa_event_handle_t)s_buttonList.eventHandle, true);
         assert(KOSA_StatusSuccess == osaStatus);

         osaStatus = OSA_TaskCreate((osa_task_handle_t)s_buttonList.taskHandle, OSA_TASK(BUTTON_Task), &s_buttonList);
         assert(KOSA_StatusSuccess == osaStatus);
 #endif

 #endif
     }
     else
     {
         buttonState->next = s_buttonList.button;
     }
     s_buttonList.button = buttonState;
     BUTTON_EXIT_CRITICAL();

     controlPin.port      = buttonConfig->gpio.port;
     controlPin.pin       = buttonConfig->gpio.pin;
     controlPin.direction = kHAL_GpioDirectionIn;
     controlPin.level     = buttonConfig->gpio.pinStateDefault;
     gpioStatus           = HAL_GpioInit(buttonState->gpioHandle, &controlPin);
     assert(kStatus_HAL_GpioSuccess == gpioStatus);
     (void)gpioStatus;

     buttonState->config.port            = buttonConfig->gpio.port;
     buttonState->config.pin             = buttonConfig->gpio.pin;
     buttonState->config.pinStateDefault = (0U != buttonConfig->gpio.pinStateDefault) ? 1U : 0U;

     gpioStatus = HAL_GpioSetTriggerMode(buttonState->gpioHandle, kHAL_GpioInterruptEitherEdge);
     assert(kStatus_HAL_GpioSuccess == gpioStatus);
     (void)gpioStatus;

     return kStatus_BUTTON_Success;
 }

 button_status_t BUTTON_InstallCallback(button_handle_t buttonHandle, button_callback_t callback, void *callbackParam)
 {
     button_state_t *buttonState;
     assert(buttonHandle);

     buttonState = (button_state_t *)buttonHandle;

     buttonState->callback      = callback;
     buttonState->callbackParam = callbackParam;

     (void)HAL_GpioInstallCallback(buttonState->gpioHandle, BUTTON_Event, buttonState);

     return kStatus_BUTTON_Success;
 }

 button_status_t BUTTON_Deinit(button_handle_t buttonHandle)
 {
     button_state_t *buttonState;
     button_state_t *buttonStatePre;
     BUTTON_SR_ALLOC();

     assert(buttonHandle);

     buttonState = (button_state_t *)buttonHandle;

     BUTTON_ENTER_CRITICAL();
     buttonStatePre = s_buttonList.button;
     if (buttonStatePre != buttonState)
     {
         while ((NULL != buttonStatePre) && (buttonStatePre->next != buttonState))
         {
             buttonStatePre = buttonStatePre->next;
         }
         if (NULL != buttonStatePre)
         {
             buttonStatePre->next = buttonState->next;
         }
     }
     else
     {
         s_buttonList.button = buttonState->next;
     }

     if (NULL == s_buttonList.button)
     {
 #if defined(OSA_USED)

 #if (defined(BUTTON_USE_COMMON_TASK) && (BUTTON_USE_COMMON_TASK > 0U))

 #else
         (void)OSA_TaskDestroy((osa_task_handle_t)s_buttonList.taskHandle);
         (void)OSA_EventDestroy((osa_event_handle_t)s_buttonList.eventHandle);
 #endif

 #endif
     }
     BUTTON_CloseTimer();
     BUTTON_EXIT_CRITICAL();

     (void)HAL_GpioDeinit(buttonState->gpioHandle);

     return kStatus_BUTTON_Success;
 }

 button_status_t BUTTON_WakeUpSetting(button_handle_t buttonHandle, uint8_t enable)
 {
     button_state_t *buttonState;
     hal_gpio_status_t status;

     assert(buttonHandle);

     buttonState = (button_state_t *)buttonHandle;

     status = HAL_GpioWakeUpSetting(buttonState->gpioHandle, enable);

     if (kStatus_HAL_GpioSuccess == status)
     {
         return kStatus_BUTTON_Success;
     }
     return kStatus_BUTTON_Error;
 }

 button_status_t BUTTON_EnterLowpower(button_handle_t buttonHandle)
 {
     button_state_t *buttonState;
     hal_gpio_status_t status;

     assert(buttonHandle);

     buttonState = (button_state_t *)buttonHandle;

     status = HAL_GpioEnterLowpower(buttonState->gpioHandle);

     if (kStatus_HAL_GpioSuccess != status)
     {
         return kStatus_BUTTON_Error;
     }

     BUTTON_CloseTimer();

     return kStatus_BUTTON_Success;
 }

 button_status_t BUTTON_ExitLowpower(button_handle_t buttonHandle)
 {
     button_state_t *buttonState;
     hal_gpio_status_t status;

     assert(buttonHandle);

     buttonState = (button_state_t *)buttonHandle;

     BUTTON_OpenTimer();

     status = HAL_GpioExitLowpower(buttonState->gpioHandle);

     if (kStatus_HAL_GpioSuccess != status)
     {
         return kStatus_BUTTON_Error;
     }
     BUTTON_Event(buttonState);
     return kStatus_BUTTON_Success;
 }
	/*
	* Copyright 2018-2019 NXP
	* All rights reserved.
	*
	*
	* SPDX-License-Identifier: BSD-3-Clause
	*/

	#include "fsl_common.h"
	#include "gpio.h"
	#include "timer_manager.h"

	#include "button.h"
	/*
	* The OSA_USED macro can only be defined when the OSA component is used.
	* If the source code of the OSA component does not exist, the OSA_USED cannot be defined.
	* OR, If OSA component is not added into project event the OSA source code exists, the OSA_USED
	* also cannot be defined.
	* The source code path of the OSA component is <MCUXpresso_SDK>/components/osa.
	*
	*/
	#if defined(OSA_USED)
	#include "fsl_os_abstraction.h"
	#if (defined(BUTTON_USE_COMMON_TASK) && (BUTTON_USE_COMMON_TASK > 0U))
	#include "common_task.h"
	#endif
	#endif

	/*******************************************************************************
	* Definitions
	******************************************************************************/

	#define BUTTON_SR_ALLOC() uint32_t buttonPrimask;
	#define BUTTON_ENTER_CRITICAL() buttonPrimask = DisableGlobalIRQ();
	#define BUTTON_EXIT_CRITICAL() EnableGlobalIRQ(buttonPrimask);

	typedef enum _button_press_status
	{
	kStatus_BUTTON_PressIdle = 0, /!< Idle /
	kStatus_BUTTON_Pressed = 1, /!< Pressed /
	kStatus_BUTTON_PressDoubleStart = 2, /!< Start double click /
	kStatus_BUTTON_PressDoublePressed = 3, /!< Second press for double click /
	} button_press_status_t;

	typedef struct _button_state
	{
	struct _button_state *next;
	button_callback_t callback;
	void *callbackParam;
	GPIO_HANDLE_DEFINE(gpioHandle);
	volatile uint32_t pushPeriodCount;
	volatile uint32_t pushPeriodCountLast;
	struct
	{
	uint16_t port : 3U;
	uint16_t reserved : 1U;
	uint16_t pin : 5U;
	uint16_t pinStateDefault : 1U;
	uint16_t reserved2 : 6U;
	} config;
	struct
	{
	volatile uint8_t pressed;
	volatile uint8_t msg;
	} state;
	} button_state_t;

	typedef struct _button_list
	{
	volatile uint32_t periodCount;
	TIMER_MANAGER_HANDLE_DEFINE(timerHandle);
	#if defined(OSA_USED)

	#if (defined(BUTTON_USE_COMMON_TASK) && (BUTTON_USE_COMMON_TASK > 0U))
	common_task_message_t commonTaskMsg;
	#else
	OSA_EVENT_HANDLE_DEFINE(eventHandle);
	OSA_TASK_HANDLE_DEFINE(taskHandle);
	#endif

	#endif
	button_state_t *button;
	volatile uint8_t timerOpenedNesting;
	} button_list_t;

	/*******************************************************************************
	* Prototypes
	******************************************************************************/

	static void BUTTON_Task(void *param);

	/*******************************************************************************
	* Variables
	******************************************************************************/

	static button_list_t s_buttonList;

	#if defined(OSA_USED)
	extern const uint8_t gUseRtos_c;
	#endif

	#if (defined(BUTTON_USE_COMMON_TASK) && (BUTTON_USE_COMMON_TASK > 0U))

	#else
	/*
	* \brief Defines the button task's stack
	*/
	OSA_TASK_DEFINE(BUTTON_Task, BUTTON_TASK_PRIORITY, 1, BUTTON_TASK_STACK_SIZE, false);
	#endif

	/*******************************************************************************
	* Code
	******************************************************************************/

	static void BUTTON_NotificationUpdate(button_state_t *buttonState, button_event_t event)
	{
	buttonState->state.pressed = (uint8_t)kStatus_BUTTON_PressIdle;
	buttonState->state.msg = (uint8_t)event;
	#if defined(OSA_USED)

	#if (defined(BUTTON_USE_COMMON_TASK) && (BUTTON_USE_COMMON_TASK > 0U))
	s_buttonList.commonTaskMsg.callback = BUTTON_Task;
	s_buttonList.commonTaskMsg.callbackParam = buttonState;
	COMMON_TASK_post_message(&s_buttonList.commonTaskMsg);
	#else
	(void)OSA_EventSet((osa_event_handle_t)s_buttonList.eventHandle, BUTTON_EVENT_BUTTON);
	#endif

	#else
	BUTTON_Task(&s_buttonList);
	#endif
	}

	static void BUTTON_Event(void *param)
	{
	button_state_t buttonState = (button_state_t )param;
	uint8_t pinState = 0U;

	assert(param);

	(void)HAL_GpioGetInput(buttonState->gpioHandle, &pinState);
	pinState = (0U != pinState) ? 1U : 0U;
	if (((uint8_t)kStatus_BUTTON_PressIdle == buttonState->state.pressed) \|\|
	((uint8_t)kStatus_BUTTON_PressDoubleStart == buttonState->state.pressed))
	{
	if (buttonState->config.pinStateDefault != pinState)
	{
	buttonState->state.pressed++;
	buttonState->pushPeriodCount = s_buttonList.periodCount;
	}
	}
	else
	{
	if (buttonState->config.pinStateDefault == pinState)
	{
	if ((BUTTON_DOUBLE_CLICK_THRESHOLD + buttonState->pushPeriodCountLast) >= buttonState->pushPeriodCount)
	{
	if ((s_buttonList.periodCount - buttonState->pushPeriodCount) < BUTTON_SHORT_PRESS_THRESHOLD)
	{
	BUTTON_NotificationUpdate(buttonState, kBUTTON_EventDoubleClick);
	}
	else
	{
	BUTTON_NotificationUpdate(buttonState, kBUTTON_EventError);
	}
	}
	else
	{
	if ((s_buttonList.periodCount - buttonState->pushPeriodCount) < BUTTON_SHORT_PRESS_THRESHOLD)
	{
	buttonState->pushPeriodCountLast = s_buttonList.periodCount;
	buttonState->state.pressed = (uint8_t)kStatus_BUTTON_PressDoubleStart;
	}
	else if ((s_buttonList.periodCount - buttonState->pushPeriodCount) < BUTTON_LONG_PRESS_THRESHOLD)
	{
	BUTTON_NotificationUpdate(buttonState, kBUTTON_EventShortPress);
	}
	else
	{
	BUTTON_NotificationUpdate(buttonState, kBUTTON_EventLongPress);
	}
	}
	}
	}
	}

	static void BUTTON_Task(void *param)
	{
	#if defined(OSA_USED)

	#if (defined(BUTTON_USE_COMMON_TASK) && (BUTTON_USE_COMMON_TASK > 0U))
	#else
	osa_event_flags_t ev = 0;

	do
	{
	if (KOSA_StatusSuccess == OSA_EventWait((osa_event_handle_t)s_buttonList.eventHandle, osaEventFlagsAll_c, false,
	osaWaitForever_c, &ev))
	{
	#endif

	#endif
	button_state_t *buttonState = s_buttonList.button;
	BUTTON_SR_ALLOC();

	BUTTON_ENTER_CRITICAL();
	while (NULL != buttonState)
	{
	if (0U != buttonState->state.msg)
	{
	button_callback_message_t msg;
	BUTTON_EXIT_CRITICAL();
	msg.event = (button_event_t)buttonState->state.msg;
	(void)buttonState->callback(buttonState, &msg, buttonState->callbackParam);
	buttonState->state.msg = 0U;
	BUTTON_ENTER_CRITICAL();
	}
	buttonState = buttonState->next;
	}
	BUTTON_EXIT_CRITICAL();
	#if defined(OSA_USED)

	#if (defined(BUTTON_USE_COMMON_TASK) && (BUTTON_USE_COMMON_TASK > 0U))
	#else
	}
	} while (gUseRtos_c);
	#endif

	#endif
	}

	static void BUTTON_TimerEvent(void *param)
	{
	button_state_t *buttonState;
	BUTTON_SR_ALLOC();

	s_buttonList.periodCount += BUTTON_TIMER_INTERVAL;

	BUTTON_ENTER_CRITICAL();
	buttonState = s_buttonList.button;
	while (NULL != buttonState)
	{
	/*
	* The code block is used to indentify the button event is one click or double click.
	* If the flag pending is set and the button is not pressed, check the user activity is timeout or not.
	* If is times out, notify the upper layer it is kBUTTON_EventOneClick.
	* Otherwise, check the status next time.
	*/
	if ((uint8_t)kStatus_BUTTON_PressDoubleStart == buttonState->state.pressed)
	{
	if ((BUTTON_DOUBLE_CLICK_THRESHOLD + buttonState->pushPeriodCountLast) < s_buttonList.periodCount)
	{
	BUTTON_NotificationUpdate(buttonState, kBUTTON_EventOneClick);
	buttonState->pushPeriodCountLast = 0U;
	}
	}
	buttonState = buttonState->next;
	}
	BUTTON_EXIT_CRITICAL();
	}

	static void BUTTON_OpenTimer(void)
	{
	BUTTON_SR_ALLOC();
	uint8_t initTimer = 0U;

	BUTTON_ENTER_CRITICAL();
	initTimer = (uint8_t)(!(bool)s_buttonList.timerOpenedNesting);
	s_buttonList.timerOpenedNesting++;
	BUTTON_EXIT_CRITICAL();

	if (0U != initTimer)
	{
	timer_status_t timerStatus;
	timerStatus = TM_Open((timer_handle_t)s_buttonList.timerHandle);
	assert(kStatus_TimerSuccess == timerStatus);
	timerStatus = TM_InstallCallback(s_buttonList.timerHandle, BUTTON_TimerEvent, &s_buttonList);
	assert(kStatus_TimerSuccess == timerStatus);
	timerStatus = TM_Start(s_buttonList.timerHandle, (uint8_t)kTimerModeLowPowerTimer, BUTTON_TIMER_INTERVAL);
	assert(kStatus_TimerSuccess == timerStatus);
	(void)timerStatus;
	}
	}

	static void BUTTON_CloseTimer(void)
	{
	BUTTON_SR_ALLOC();
	uint8_t deinitTimer = 0U;

	BUTTON_ENTER_CRITICAL();
	if (s_buttonList.timerOpenedNesting > 0U)
	{
	s_buttonList.timerOpenedNesting--;
	deinitTimer = (uint8_t)(!(bool)s_buttonList.timerOpenedNesting);
	}
	BUTTON_EXIT_CRITICAL();

	if (0U != deinitTimer)
	{
	timer_status_t timerStatus;
	timerStatus = TM_Close((timer_handle_t)s_buttonList.timerHandle);
	assert(kStatus_TimerSuccess == timerStatus);
	(void)timerStatus;
	}
	}

	button_status_t BUTTON_Init(button_handle_t buttonHandle, button_config_t *buttonConfig)
	{
	hal_gpio_pin_config_t controlPin;
	button_state_t *buttonState;
	hal_gpio_status_t gpioStatus;
	BUTTON_SR_ALLOC();

	assert((NULL != buttonHandle) && (NULL != buttonConfig));
	assert(BUTTON_HANDLE_SIZE >= sizeof(button_state_t));

	buttonState = (button_state_t *)buttonHandle;

	(void)memset(buttonHandle, 0, sizeof(button_state_t));

	BUTTON_ENTER_CRITICAL();
	BUTTON_OpenTimer();
	if (NULL == s_buttonList.button)
	{
	#if defined(OSA_USED)

	#if (defined(BUTTON_USE_COMMON_TASK) && (BUTTON_USE_COMMON_TASK > 0U))
	COMMON_TASK_init();
	#else
	osa_status_t osaStatus;

	osaStatus = OSA_EventCreate((osa_event_handle_t)s_buttonList.eventHandle, true);
	assert(KOSA_StatusSuccess == osaStatus);

	osaStatus = OSA_TaskCreate((osa_task_handle_t)s_buttonList.taskHandle, OSA_TASK(BUTTON_Task), &s_buttonList);
	assert(KOSA_StatusSuccess == osaStatus);
	#endif

	#endif
	}
	else
	{
	buttonState->next = s_buttonList.button;
	}
	s_buttonList.button = buttonState;
	BUTTON_EXIT_CRITICAL();

	controlPin.port = buttonConfig->gpio.port;
	controlPin.pin = buttonConfig->gpio.pin;
	controlPin.direction = kHAL_GpioDirectionIn;
	controlPin.level = buttonConfig->gpio.pinStateDefault;
	gpioStatus = HAL_GpioInit(buttonState->gpioHandle, &controlPin);
	assert(kStatus_HAL_GpioSuccess == gpioStatus);
	(void)gpioStatus;

	buttonState->config.port = buttonConfig->gpio.port;
	buttonState->config.pin = buttonConfig->gpio.pin;
	buttonState->config.pinStateDefault = (0U != buttonConfig->gpio.pinStateDefault) ? 1U : 0U;

	gpioStatus = HAL_GpioSetTriggerMode(buttonState->gpioHandle, kHAL_GpioInterruptEitherEdge);
	assert(kStatus_HAL_GpioSuccess == gpioStatus);
	(void)gpioStatus;

	return kStatus_BUTTON_Success;
	}

	button_status_t BUTTON_InstallCallback(button_handle_t buttonHandle, button_callback_t callback, void *callbackParam)
	{
	button_state_t *buttonState;
	assert(buttonHandle);

	buttonState = (button_state_t *)buttonHandle;

	buttonState->callback = callback;
	buttonState->callbackParam = callbackParam;

	(void)HAL_GpioInstallCallback(buttonState->gpioHandle, BUTTON_Event, buttonState);

	return kStatus_BUTTON_Success;
	}

	button_status_t BUTTON_Deinit(button_handle_t buttonHandle)
	{
	button_state_t *buttonState;
	button_state_t *buttonStatePre;
	BUTTON_SR_ALLOC();

	assert(buttonHandle);

	buttonState = (button_state_t *)buttonHandle;

	BUTTON_ENTER_CRITICAL();
	buttonStatePre = s_buttonList.button;
	if (buttonStatePre != buttonState)
	{
	while ((NULL != buttonStatePre) && (buttonStatePre->next != buttonState))
	{
	buttonStatePre = buttonStatePre->next;
	}
	if (NULL != buttonStatePre)
	{
	buttonStatePre->next = buttonState->next;
	}
	}
	else
	{
	s_buttonList.button = buttonState->next;
	}

	if (NULL == s_buttonList.button)
	{
	#if defined(OSA_USED)

	#if (defined(BUTTON_USE_COMMON_TASK) && (BUTTON_USE_COMMON_TASK > 0U))

	#else
	(void)OSA_TaskDestroy((osa_task_handle_t)s_buttonList.taskHandle);
	(void)OSA_EventDestroy((osa_event_handle_t)s_buttonList.eventHandle);
	#endif

	#endif
	}
	BUTTON_CloseTimer();
	BUTTON_EXIT_CRITICAL();

	(void)HAL_GpioDeinit(buttonState->gpioHandle);

	return kStatus_BUTTON_Success;
	}

	button_status_t BUTTON_WakeUpSetting(button_handle_t buttonHandle, uint8_t enable)
	{
	button_state_t *buttonState;
	hal_gpio_status_t status;

	assert(buttonHandle);

	buttonState = (button_state_t *)buttonHandle;

	status = HAL_GpioWakeUpSetting(buttonState->gpioHandle, enable);

	if (kStatus_HAL_GpioSuccess == status)
	{
	return kStatus_BUTTON_Success;
	}
	return kStatus_BUTTON_Error;
	}

	button_status_t BUTTON_EnterLowpower(button_handle_t buttonHandle)
	{
	button_state_t *buttonState;
	hal_gpio_status_t status;

	assert(buttonHandle);

	buttonState = (button_state_t *)buttonHandle;

	status = HAL_GpioEnterLowpower(buttonState->gpioHandle);

	if (kStatus_HAL_GpioSuccess != status)
	{
	return kStatus_BUTTON_Error;
	}

	BUTTON_CloseTimer();

	return kStatus_BUTTON_Success;
	}

	button_status_t BUTTON_ExitLowpower(button_handle_t buttonHandle)
	{
	button_state_t *buttonState;
	hal_gpio_status_t status;

	assert(buttonHandle);

	buttonState = (button_state_t *)buttonHandle;

	BUTTON_OpenTimer();

	status = HAL_GpioExitLowpower(buttonState->gpioHandle);

	if (kStatus_HAL_GpioSuccess != status)
	{
	return kStatus_BUTTON_Error;
	}
	BUTTON_Event(buttonState);
	return kStatus_BUTTON_Success;
	}