/**
******************************************************************************
* @file stm32g4xx_hal_hrtim.h
* @author MCD Application Team
* @brief Header file of HRTIM HAL module.
******************************************************************************
* @attention
*
* Copyright (c) 2019 STMicroelectronics.
* All rights reserved.
*
* This software is licensed under terms that can be found in the LICENSE file
* in the root directory of this software component.
* If no LICENSE file comes with this software, it is provided AS-IS.
*
******************************************************************************
*/
/* Define to prevent recursive inclusion -------------------------------------*/
#ifndef STM32G4xx_HAL_HRTIM_H
#define STM32G4xx_HAL_HRTIM_H
#ifdef __cplusplus
extern "C" {
#endif
/* Includes ------------------------------------------------------------------*/
#include "stm32g4xx_hal_def.h"
#if defined(HRTIM1)
/** @addtogroup STM32G4xx_HAL_Driver
* @{
*/
/** @addtogroup HRTIM HRTIM
* @{
*/
/* Exported types ------------------------------------------------------------*/
/** @addtogroup HRTIM_Exported_Constants HRTIM Exported Constants
* @{
*/
/** @defgroup HRTIM_Max_Timer HRTIM Max Timer
* @{
*/
#define MAX_HRTIM_TIMER 7U
/**
* @}
*/
/**
* @}
*/
/** @defgroup HRTIM_Exported_Types HRTIM Exported Types
* @{
*/
/**
* @brief HRTIM Configuration Structure definition - Time base related parameters
*/
typedef struct
{
uint32_t HRTIMInterruptResquests; /*!< Specifies which interrupts requests must enabled for the HRTIM instance.
This parameter can be any combination of @ref HRTIM_Common_Interrupt_Enable */
uint32_t SyncOptions; /*!< Specifies how the HRTIM instance handles the external synchronization signals.
The HRTIM instance can be configured to act as a slave (waiting for a trigger
to be synchronized) or a master (generating a synchronization signal) or both.
This parameter can be a combination of @ref HRTIM_Synchronization_Options.*/
uint32_t SyncInputSource; /*!< Specifies the external synchronization input source (significant only when
the HRTIM instance is configured as a slave).
This parameter can be a value of @ref HRTIM_Synchronization_Input_Source. */
uint32_t SyncOutputSource; /*!< Specifies the source and event to be sent on the external synchronization outputs
(significant only when the HRTIM instance is configured as a master).
This parameter can be a value of @ref HRTIM_Synchronization_Output_Source */
uint32_t SyncOutputPolarity; /*!< Specifies the conditioning of the event to be sent on the external synchronization
outputs (significant only when the HRTIM instance is configured as a master).
This parameter can be a value of @ref HRTIM_Synchronization_Output_Polarity */
} HRTIM_InitTypeDef;
/**
* @brief HAL State structures definition
*/
typedef enum
{
HAL_HRTIM_STATE_RESET = 0x00U, /*!< Peripheral is not yet Initialized */
HAL_HRTIM_STATE_READY = 0x01U, /*!< Peripheral Initialized and ready for use */
HAL_HRTIM_STATE_BUSY = 0x02U, /*!< an internal process is ongoing */
HAL_HRTIM_STATE_TIMEOUT = 0x06U, /*!< Timeout state */
HAL_HRTIM_STATE_ERROR = 0x07U, /*!< Error state */
#if (USE_HAL_HRTIM_REGISTER_CALLBACKS == 1)
HAL_HRTIM_STATE_INVALID_CALLBACK = 0x08U /*!< Invalid Callback error */
#endif /* USE_HAL_HRTIM_REGISTER_CALLBACKS */
} HAL_HRTIM_StateTypeDef;
/**
* @brief HRTIM Timer Structure definition
*/
typedef struct
{
uint32_t CaptureTrigger1; /*!< Event(s) triggering capture unit 1.
When the timer operates in Simple mode, this parameter can be a value of @ref HRTIM_External_Event_Channels.
When the timer operates in Waveform mode, this parameter can be a combination of @ref HRTIM_Capture_Unit_Trigger. */
uint32_t CaptureTrigger2; /*!< Event(s) triggering capture unit 2.
When the timer operates in Simple mode, this parameter can be a value of @ref HRTIM_External_Event_Channels.
When the timer operates in Waveform mode, this parameter can be a combination of @ref HRTIM_Capture_Unit_Trigger. */
uint32_t InterruptRequests; /*!< Interrupts requests enabled for the timer. */
uint32_t DMARequests; /*!< DMA requests enabled for the timer. */
uint32_t DMASrcAddress; /*!< Address of the source address of the DMA transfer. */
uint32_t DMADstAddress; /*!< Address of the destination address of the DMA transfer. */
uint32_t DMASize; /*!< Size of the DMA transfer */
} HRTIM_TimerParamTypeDef;
/**
* @brief HRTIM Handle Structure definition
*/
#if (USE_HAL_HRTIM_REGISTER_CALLBACKS == 1)
typedef struct __HRTIM_HandleTypeDef
#else
typedef struct
#endif /* USE_HAL_HRTIM_REGISTER_CALLBACKS */
{
HRTIM_TypeDef * Instance; /*!< Register base address */
HRTIM_InitTypeDef Init; /*!< HRTIM required parameters */
HRTIM_TimerParamTypeDef TimerParam[MAX_HRTIM_TIMER]; /*!< HRTIM timers - including the master - parameters */
HAL_LockTypeDef Lock; /*!< Locking object */
__IO HAL_HRTIM_StateTypeDef State; /*!< HRTIM communication state */
DMA_HandleTypeDef * hdmaMaster; /*!< Master timer DMA handle parameters */
DMA_HandleTypeDef * hdmaTimerA; /*!< Timer A DMA handle parameters */
DMA_HandleTypeDef * hdmaTimerB; /*!< Timer B DMA handle parameters */
DMA_HandleTypeDef * hdmaTimerC; /*!< Timer C DMA handle parameters */
DMA_HandleTypeDef * hdmaTimerD; /*!< Timer D DMA handle parameters */
DMA_HandleTypeDef * hdmaTimerE; /*!< Timer E DMA handle parameters */
DMA_HandleTypeDef * hdmaTimerF; /*!< Timer F DMA handle parameters */
#if (USE_HAL_HRTIM_REGISTER_CALLBACKS == 1)
void (* Fault1Callback)(struct __HRTIM_HandleTypeDef *hhrtim); /*!< Fault 1 interrupt callback function pointer */
void (* Fault2Callback)(struct __HRTIM_HandleTypeDef *hhrtim); /*!< Fault 2 interrupt callback function pointer */
void (* Fault3Callback)(struct __HRTIM_HandleTypeDef *hhrtim); /*!< Fault 3 interrupt callback function pointer */
void (* Fault4Callback)(struct __HRTIM_HandleTypeDef *hhrtim); /*!< Fault 4 interrupt callback function pointer */
void (* Fault5Callback)(struct __HRTIM_HandleTypeDef *hhrtim); /*!< Fault 5 interrupt callback function pointer */
void (* Fault6Callback)(struct __HRTIM_HandleTypeDef *hhrtim); /*!< Fault 6 interrupt callback function pointer */
void (* SystemFaultCallback)(struct __HRTIM_HandleTypeDef *hhrtim); /*!< System fault interrupt callback function pointer */
void (* DLLCalibrationReadyCallback)(struct __HRTIM_HandleTypeDef *hhrtim); /*!< DLL Ready interrupt callback function pointer */
void (* BurstModePeriodCallback)(struct __HRTIM_HandleTypeDef *hhrtim); /*!< Burst mode period interrupt callback function pointer */
void (* SynchronizationEventCallback)(struct __HRTIM_HandleTypeDef *hhrtim); /*!< Sync Input interrupt callback function pointer */
void (* ErrorCallback)(struct __HRTIM_HandleTypeDef *hhrtim); /*!< DMA error callback function pointer */
void (* RegistersUpdateCallback)(struct __HRTIM_HandleTypeDef *hhrtim, uint32_t TimerIdx); /*!< Timer x Update interrupt callback function pointer */
void (* RepetitionEventCallback)(struct __HRTIM_HandleTypeDef *hhrtim, uint32_t TimerIdx); /*!< Timer x Repetition interrupt callback function pointer */
void (* Compare1EventCallback)(struct __HRTIM_HandleTypeDef *hhrtim, uint32_t TimerIdx); /*!< Timer x Compare 1 match interrupt callback function pointer */
void (* Compare2EventCallback)(struct __HRTIM_HandleTypeDef *hhrtim, uint32_t TimerIdx); /*!< Timer x Compare 2 match interrupt callback function pointer */
void (* Compare3EventCallback)(struct __HRTIM_HandleTypeDef *hhrtim, uint32_t TimerIdx); /*!< Timer x Compare 3 match interrupt callback function pointer */
void (* Compare4EventCallback)(struct __HRTIM_HandleTypeDef *hhrtim, uint32_t TimerIdx); /*!< Timer x Compare 4 match interrupt callback function pointer */
void (* Capture1EventCallback)(struct __HRTIM_HandleTypeDef *hhrtim, uint32_t TimerIdx); /*!< Timer x Capture 1 interrupts callback function pointer */
void (* Capture2EventCallback)(struct __HRTIM_HandleTypeDef *hhrtim, uint32_t TimerIdx); /*!< Timer x Capture 2 interrupts callback function pointer */
void (* DelayedProtectionCallback)(struct __HRTIM_HandleTypeDef *hhrtim, uint32_t TimerIdx); /*!< Timer x Delayed protection interrupt callback function pointer */
void (* CounterResetCallback)(struct __HRTIM_HandleTypeDef *hhrtim, uint32_t TimerIdx); /*!< Timer x counter reset/roll-over interrupt callback function pointer */
void (* Output1SetCallback)(struct __HRTIM_HandleTypeDef *hhrtim, uint32_t TimerIdx); /*!< Timer x output 1 set interrupt callback function pointer */
void (* Output1ResetCallback)(struct __HRTIM_HandleTypeDef *hhrtim, uint32_t TimerIdx); /*!< Timer x output 1 reset interrupt callback function pointer */
void (* Output2SetCallback)(struct __HRTIM_HandleTypeDef *hhrtim, uint32_t TimerIdx); /*!< Timer x output 2 set interrupt callback function pointer */
void (* Output2ResetCallback)(struct __HRTIM_HandleTypeDef *hhrtim, uint32_t TimerIdx); /*!< Timer x output 2 reset interrupt callback function pointer */
void (* BurstDMATransferCallback)(struct __HRTIM_HandleTypeDef *hhrtim, uint32_t TimerIdx); /*!< Timer x Burst DMA completed interrupt callback function pointer */
void (* MspInitCallback)(struct __HRTIM_HandleTypeDef *hhrtim); /*!< HRTIM MspInit callback function pointer */
void (* MspDeInitCallback)(struct __HRTIM_HandleTypeDef *hhrtim); /*!< HRTIM MspInit callback function pointer */
#endif /* USE_HAL_HRTIM_REGISTER_CALLBACKS */
} HRTIM_HandleTypeDef;
/**
* @brief Simple output compare mode configuration definition
*/
typedef struct
{
uint32_t Period; /*!< Specifies the timer period.
The period value must be above 3 periods of the fHRTIM clock.
Maximum value is = 0xFFDFU */
uint32_t RepetitionCounter; /*!< Specifies the timer repetition period.
This parameter must be a number between Min_Data = 0x00 and Max_Data = 0xFF. */
uint32_t PrescalerRatio; /*!< Specifies the timer clock prescaler ratio.
This parameter can be any value of @ref HRTIM_Prescaler_Ratio */
uint32_t Mode; /*!< Specifies the counter operating mode.
This parameter can be any value of @ref HRTIM_Counter_Operating_Mode */
} HRTIM_TimeBaseCfgTypeDef;
/**
* @brief Simple output compare mode configuration definition
*/
typedef struct
{
uint32_t Mode; /*!< Specifies the output compare mode (toggle, active, inactive).
This parameter can be any value of of @ref HRTIM_Simple_OC_Mode */
uint32_t Pulse; /*!< Specifies the compare value to be loaded into the Compare Register.
The compare value must be above or equal to 3 periods of the fHRTIM clock */
uint32_t Polarity; /*!< Specifies the output polarity.
This parameter can be any value of @ref HRTIM_Output_Polarity */
uint32_t IdleLevel; /*!< Specifies whether the output level is active or inactive when in IDLE state.
This parameter can be any value of @ref HRTIM_Output_IDLE_Level */
} HRTIM_SimpleOCChannelCfgTypeDef;
/**
* @brief Simple PWM output mode configuration definition
*/
typedef struct
{
uint32_t Pulse; /*!< Specifies the compare value to be loaded into the Compare Register.
The compare value must be above or equal to 3 periods of the fHRTIM clock */
uint32_t Polarity; /*!< Specifies the output polarity.
This parameter can be any value of @ref HRTIM_Output_Polarity */
uint32_t IdleLevel; /*!< Specifies whether the output level is active or inactive when in IDLE state.
This parameter can be any value of @ref HRTIM_Output_IDLE_Level */
} HRTIM_SimplePWMChannelCfgTypeDef;
/**
* @brief Simple capture mode configuration definition
*/
typedef struct
{
uint32_t Event; /*!< Specifies the external event triggering the capture.
This parameter can be any 'EEVx' value of @ref HRTIM_External_Event_Channels */
uint32_t EventPolarity; /*!< Specifies the polarity of the external event (in case of level sensitivity).
This parameter can be a value of @ref HRTIM_External_Event_Polarity */
uint32_t EventSensitivity; /*!< Specifies the sensitivity of the external event.
This parameter can be a value of @ref HRTIM_External_Event_Sensitivity */
uint32_t EventFilter; /*!< Defines the frequency used to sample the External Event and the length of the digital filter.
This parameter can be a value of @ref HRTIM_External_Event_Filter */
} HRTIM_SimpleCaptureChannelCfgTypeDef;
/**
* @brief Simple One Pulse mode configuration definition
*/
typedef struct
{
uint32_t Pulse; /*!< Specifies the compare value to be loaded into the Compare Register.
The compare value must be above or equal to 3 periods of the fHRTIM clock */
uint32_t OutputPolarity; /*!< Specifies the output polarity.
This parameter can be any value of @ref HRTIM_Output_Polarity */
uint32_t OutputIdleLevel; /*!< Specifies whether the output level is active or inactive when in IDLE state.
This parameter can be any value of @ref HRTIM_Output_IDLE_Level */
uint32_t Event; /*!< Specifies the external event triggering the pulse generation.
This parameter can be any 'EEVx' value of @ref HRTIM_External_Event_Channels */
uint32_t EventPolarity; /*!< Specifies the polarity of the external event (in case of level sensitivity).
This parameter can be a value of @ref HRTIM_External_Event_Polarity */
uint32_t EventSensitivity; /*!< Specifies the sensitivity of the external event.
This parameter can be a value of @ref HRTIM_External_Event_Sensitivity. */
uint32_t EventFilter; /*!< Defines the frequency used to sample the External Event and the length of the digital filter.
This parameter can be a value of @ref HRTIM_External_Event_Filter */
} HRTIM_SimpleOnePulseChannelCfgTypeDef;
/**
* @brief Timer configuration definition
*/
typedef struct
{
uint32_t InterruptRequests; /*!< Relevant for all HRTIM timers, including the master.
Specifies which interrupts requests must enabled for the timer.
This parameter can be any combination of @ref HRTIM_Master_Interrupt_Enable
or @ref HRTIM_Timing_Unit_Interrupt_Enable */
uint32_t DMARequests; /*!< Relevant for all HRTIM timers, including the master.
Specifies which DMA requests must be enabled for the timer.
This parameter can be any combination of @ref HRTIM_Master_DMA_Request_Enable
or @ref HRTIM_Timing_Unit_DMA_Request_Enable */
uint32_t DMASrcAddress; /*!< Relevant for all HRTIM timers, including the master.
Specifies the address of the source address of the DMA transfer */
uint32_t DMADstAddress; /*!< Relevant for all HRTIM timers, including the master.
Specifies the address of the destination address of the DMA transfer */
uint32_t DMASize; /*!< Relevant for all HRTIM timers, including the master.
Specifies the size of the DMA transfer */
uint32_t HalfModeEnable; /*!< Relevant for all HRTIM timers, including the master.
Specifies whether or not half mode is enabled
This parameter can be any value of @ref HRTIM_Half_Mode_Enable */
uint32_t InterleavedMode; /*!< Relevant for all HRTIM timers, including the master.
Specifies whether or not half mode is enabled
This parameter can be any value of @ref HRTIM_Interleaved_Mode */
uint32_t StartOnSync; /*!< Relevant for all HRTIM timers, including the master.
Specifies whether or not timer is reset by a rising edge on the synchronization input (when enabled).
This parameter can be any value of @ref HRTIM_Start_On_Sync_Input_Event */
uint32_t ResetOnSync; /*!< Relevant for all HRTIM timers, including the master.
Specifies whether or not timer is reset by a rising edge on the synchronization input (when enabled).
This parameter can be any value of @ref HRTIM_Reset_On_Sync_Input_Event */
uint32_t DACSynchro; /*!< Relevant for all HRTIM timers, including the master.
Indicates whether or not the a DAC synchronization event is generated.
This parameter can be any value of @ref HRTIM_DAC_Synchronization */
uint32_t PreloadEnable; /*!< Relevant for all HRTIM timers, including the master.
Specifies whether or not register preload is enabled.
This parameter can be any value of @ref HRTIM_Register_Preload_Enable */
uint32_t UpdateGating; /*!< Relevant for all HRTIM timers, including the master.
Specifies how the update occurs with respect to a burst DMA transaction or
update enable inputs (Slave timers only).
This parameter can be any value of @ref HRTIM_Update_Gating */
uint32_t BurstMode; /*!< Relevant for all HRTIM timers, including the master.
Specifies how the timer behaves during a burst mode operation.
This parameter can be any value of @ref HRTIM_Timer_Burst_Mode */
uint32_t RepetitionUpdate; /*!< Relevant for all HRTIM timers, including the master.
Specifies whether or not registers update is triggered by the repetition event.
This parameter can be any value of @ref HRTIM_Timer_Repetition_Update */
uint32_t PushPull; /*!< Relevant for Timer A to Timer F.
Specifies whether or not the push-pull mode is enabled.
This parameter can be any value of @ref HRTIM_Timer_Push_Pull_Mode */
uint32_t FaultEnable; /*!< Relevant for Timer A to Timer F.
Specifies which fault channels are enabled for the timer.
This parameter can be a combination of @ref HRTIM_Timer_Fault_Enabling */
uint32_t FaultLock; /*!< Relevant for Timer A to Timer F.
Specifies whether or not fault enabling status is write protected.
This parameter can be a value of @ref HRTIM_Timer_Fault_Lock */
uint32_t DeadTimeInsertion; /*!< Relevant for Timer A to Timer F.
Specifies whether or not dead-time insertion is enabled for the timer.
This parameter can be a value of @ref HRTIM_Timer_Deadtime_Insertion */
uint32_t DelayedProtectionMode; /*!< Relevant for Timer A to Timer F.
Specifies the delayed protection mode.
This parameter can be a value of @ref HRTIM_Timer_Delayed_Protection_Mode */
uint32_t BalancedIdleAutomaticResume; /*!< Indicates whether or not outputs are automatically re-enabled after a balanced idle event.
This parameters can be any value of @ref HRTIM_Output_Balanced_Idle_Auto_Resume */
uint32_t UpdateTrigger; /*!< Relevant for Timer A to Timer F.
Specifies source(s) triggering the timer registers update.
This parameter can be a combination of @ref HRTIM_Timer_Update_Trigger */
uint32_t ResetTrigger; /*!< Relevant for Timer A to Timer F.
Specifies source(s) triggering the timer counter reset.
This parameter can be a combination of @ref HRTIM_Timer_Reset_Trigger */
uint32_t ResetUpdate; /*!< Relevant for Timer A to Timer F.
Specifies whether or not registers update is triggered when the timer counter is reset.
This parameter can be a value of @ref HRTIM_Timer_Reset_Update */
uint32_t ReSyncUpdate; /*!< Relevant for Timer A to Timer F.
Specifies whether update source is coming from the timing unit @ref HRTIM_Timer_ReSyncUpdate */
} HRTIM_TimerCfgTypeDef;
/**
* @brief Timer control definition
*/
typedef struct
{
uint32_t UpDownMode; /*!< Relevant for Timer A to Timer F.
Specifies whether or not counter is operating in up or up-down counting mode.
This parameter can be a value of @ref HRTIM_Timer_UpDown_Mode */
uint32_t TrigHalf; /*!< Relevant for Timer A to Timer F.
Specifies whether or not compare 2 is operating in Trigger half mode.
This parameter can be a value of @ref HRTIM_Timer_TrigHalf_Mode */
uint32_t GreaterCMP3; /*!< Relevant for Timer A to Timer F.
Specifies whether or not compare 3 is operating in compare match or greater mode.
This parameter can be a value of @ref HRTIM_Timer_GreaterCMP3_Mode */
uint32_t GreaterCMP1; /*!< Relevant for Timer A to Timer F.
Specifies whether or not compare 1 is operating in compare match or greater mode.
This parameter can be a value of @ref HRTIM_Timer_GreaterCMP1_Mode */
uint32_t DualChannelDacReset; /*!< Relevant for Timer A to Timer F.
Specifies how the hrtim_dac_reset_trgx trigger is generated.
This parameter can be a value of @ref HRTIM_Timer_DualChannelDac_Reset */
uint32_t DualChannelDacStep; /*!< Relevant for Timer A to Timer F.
Specifies how the hrtim_dac_step_trgx trigger is generated.
This parameter can be a value of @ref HRTIM_Timer_DualChannelDac_Step */
uint32_t DualChannelDacEnable; /*!< Relevant for Timer A to Timer F.
Enables or not the dual channel DAC triggering mechanism.
This parameter can be a value of @ref HRTIM_Timer_DualChannelDac_Enable */
} HRTIM_TimerCtlTypeDef;
/**
* @brief Compare unit configuration definition
*/
typedef struct
{
uint32_t CompareValue; /*!< Specifies the compare value of the timer compare unit.
The minimum value must be greater than or equal to 3 periods of the fHRTIM clock.
The maximum value must be less than or equal to 0xFFFFU - 1 periods of the fHRTIM clock */
uint32_t AutoDelayedMode; /*!< Specifies the auto delayed mode for compare unit 2 or 4.
This parameter can be a value of @ref HRTIM_Compare_Unit_Auto_Delayed_Mode */
uint32_t AutoDelayedTimeout; /*!< Specifies compare value for timing unit 1 or 3 when auto delayed mode with time out is selected.
CompareValue + AutoDelayedTimeout must be less than 0xFFFFU */
} HRTIM_CompareCfgTypeDef;
/**
* @brief Capture unit content definition
*/
typedef struct
{
uint32_t Value; /*!< Holds the counter value when the capture event occurred.
This parameter can be a number between 0x0 and 0xFFFFU */
uint32_t Dir ; /*!< Holds the counting direction value when the capture event occurred.
This parameter can be a value of @ref HRTIM_Timer_UpDown_Mode */
} HRTIM_CaptureValueTypeDef;
/**
* @brief Capture unit configuration definition
*/
typedef struct
{
uint64_t Trigger; /*!< Specifies source(s) triggering the capture.
This parameter can be a combination of @ref HRTIM_Capture_Unit_Trigger */
} HRTIM_CaptureCfgTypeDef;
/**
* @brief Output configuration definition
*/
typedef struct
{
uint32_t Polarity; /*!< Specifies the output polarity.
This parameter can be any value of @ref HRTIM_Output_Polarity */
uint32_t SetSource; /*!< Specifies the event(s) transitioning the output from its inactive level to its active level.
This parameter can be a combination of @ref HRTIM_Output_Set_Source */
uint32_t ResetSource; /*!< Specifies the event(s) transitioning the output from its active level to its inactive level.
This parameter can be a combination of @ref HRTIM_Output_Reset_Source */
uint32_t IdleMode; /*!< Specifies whether or not the output is affected by a burst mode operation.
This parameter can be any value of @ref HRTIM_Output_Idle_Mode */
uint32_t IdleLevel; /*!< Specifies whether the output level is active or inactive when in IDLE state.
This parameter can be any value of @ref HRTIM_Output_IDLE_Level */
uint32_t FaultLevel; /*!< Specifies whether the output level is active or inactive when in FAULT state.
This parameter can be any value of @ref HRTIM_Output_FAULT_Level */
uint32_t ChopperModeEnable; /*!< Indicates whether or not the chopper mode is enabled
This parameter can be any value of @ref HRTIM_Output_Chopper_Mode_Enable */
uint32_t BurstModeEntryDelayed; /*!< Indicates whether or not dead-time is inserted when entering the IDLE state during a burst mode operation.
This parameters can be any value of @ref HRTIM_Output_Burst_Mode_Entry_Delayed */
} HRTIM_OutputCfgTypeDef;
/**
* @brief External event filtering in timing units configuration definition
*/
typedef struct
{
uint32_t Filter; /*!< Specifies the type of event filtering within the timing unit.
This parameter can be a value of @ref HRTIM_Timer_External_Event_Filter */
uint32_t Latch; /*!< Specifies whether or not the signal is latched.
This parameter can be a value of @ref HRTIM_Timer_External_Event_Latch */
} HRTIM_TimerEventFilteringCfgTypeDef;
/**
* @brief Dead time feature configuration definition
*/
typedef struct
{
uint32_t Prescaler; /*!< Specifies the dead-time prescaler.
This parameter can be a value of @ref HRTIM_Deadtime_Prescaler_Ratio */
uint32_t RisingValue; /*!< Specifies the dead-time following a rising edge.
This parameter can be a number between 0x0 and 0x1FFU */
uint32_t RisingSign; /*!< Specifies whether the dead-time is positive or negative on rising edge.
This parameter can be a value of @ref HRTIM_Deadtime_Rising_Sign */
uint32_t RisingLock; /*!< Specifies whether or not dead-time rising settings (value and sign) are write protected.
This parameter can be a value of @ref HRTIM_Deadtime_Rising_Lock */
uint32_t RisingSignLock; /*!< Specifies whether or not dead-time rising sign is write protected.
This parameter can be a value of @ref HRTIM_Deadtime_Rising_Sign_Lock */
uint32_t FallingValue; /*!< Specifies the dead-time following a falling edge.
This parameter can be a number between 0x0 and 0x1FFU */
uint32_t FallingSign; /*!< Specifies whether the dead-time is positive or negative on falling edge.
This parameter can be a value of @ref HRTIM_Deadtime_Falling_Sign */
uint32_t FallingLock; /*!< Specifies whether or not dead-time falling settings (value and sign) are write protected.
This parameter can be a value of @ref HRTIM_Deadtime_Falling_Lock */
uint32_t FallingSignLock; /*!< Specifies whether or not dead-time falling sign is write protected.
This parameter can be a value of @ref HRTIM_Deadtime_Falling_Sign_Lock */
} HRTIM_DeadTimeCfgTypeDef;
/**
* @brief Chopper mode configuration definition
*/
typedef struct
{
uint32_t CarrierFreq; /*!< Specifies the Timer carrier frequency value.
This parameter can be a value of @ref HRTIM_Chopper_Frequency */
uint32_t DutyCycle; /*!< Specifies the Timer chopper duty cycle value.
This parameter can be a value of @ref HRTIM_Chopper_Duty_Cycle */
uint32_t StartPulse; /*!< Specifies the Timer pulse width value.
This parameter can be a value of @ref HRTIM_Chopper_Start_Pulse_Width */
} HRTIM_ChopperModeCfgTypeDef;
/**
* @brief External event channel configuration definition
*/
typedef struct
{
uint32_t Source; /*!< Identifies the source of the external event.
This parameter can be a value of @ref HRTIM_External_Event_Sources */
uint32_t Polarity; /*!< Specifies the polarity of the external event (in case of level sensitivity).
This parameter can be a value of @ref HRTIM_External_Event_Polarity */
uint32_t Sensitivity; /*!< Specifies the sensitivity of the external event.
This parameter can be a value of @ref HRTIM_External_Event_Sensitivity */
uint32_t Filter; /*!< Defines the frequency used to sample the External Event and the length of the digital filter.
This parameter can be a value of @ref HRTIM_External_Event_Filter */
uint32_t FastMode; /*!< Indicates whether or not low latency mode is enabled for the external event.
This parameter can be a value of @ref HRTIM_External_Event_Fast_Mode */
} HRTIM_EventCfgTypeDef;
/**
* @brief Fault channel configuration definition
*/
typedef struct
{
uint32_t Source; /*!< Identifies the source of the fault.
This parameter can be a value of @ref HRTIM_Fault_Sources */
uint32_t Polarity; /*!< Specifies the polarity of the fault event.
This parameter can be a value of @ref HRTIM_Fault_Polarity */
uint32_t Filter; /*!< Defines the frequency used to sample the Fault input and the length of the digital filter.
This parameter can be a value of @ref HRTIM_Fault_Filter */
uint32_t Lock; /*!< Indicates whether or not fault programming bits are write protected.
This parameter can be a value of @ref HRTIM_Fault_Lock */
} HRTIM_FaultCfgTypeDef;
typedef struct
{
uint32_t Threshold; /*!< Specifies the Fault counter Threshold.
This parameter can be a number between 0x0 and 0xF */
uint32_t ResetMode; /*!< Specifies the reset mode of a fault event counter.
This parameter can be a value of @ref HRTIM_Fault_ResetMode */
uint32_t BlankingSource;/*!< Specifies the blanking source of a fault event.
This parameter can be a value of @ref HRTIM_Fault_Blanking */
} HRTIM_FaultBlankingCfgTypeDef;
/**
* @brief Burst mode configuration definition
*/
typedef struct
{
uint32_t Mode; /*!< Specifies the burst mode operating mode.
This parameter can be a value of @ref HRTIM_Burst_Mode_Operating_Mode */
uint32_t ClockSource; /*!< Specifies the burst mode clock source.
This parameter can be a value of @ref HRTIM_Burst_Mode_Clock_Source */
uint32_t Prescaler; /*!< Specifies the burst mode prescaler.
This parameter can be a value of @ref HRTIM_Burst_Mode_Prescaler */
uint32_t PreloadEnable; /*!< Specifies whether or not preload is enabled for burst mode related registers (HRTIM_BMCMPR and HRTIM_BMPER).
This parameter can be a combination of @ref HRTIM_Burst_Mode_Register_Preload_Enable */
uint32_t Trigger; /*!< Specifies the event(s) triggering the burst operation.
This parameter can be a combination of @ref HRTIM_Burst_Mode_Trigger */
uint32_t IdleDuration; /*!< Specifies number of periods during which the selected timers are in idle state.
This parameter can be a number between 0x0 and 0xFFFF */
uint32_t Period; /*!< Specifies burst mode repetition period.
This parameter can be a number between 0x1 and 0xFFFF */
} HRTIM_BurstModeCfgTypeDef;
/**
* @brief ADC trigger configuration definition
*/
typedef struct
{
uint32_t UpdateSource; /*!< Specifies the ADC trigger update source.
This parameter can be a value of @ref HRTIM_ADC_Trigger_Update_Source */
uint32_t Trigger; /*!< Specifies the event(s) triggering the ADC conversion.
This parameter can be a combination of @ref HRTIM_ADC_Trigger_Event */
} HRTIM_ADCTriggerCfgTypeDef;
/**
* @brief External Event Counter A or B configuration definition
*/
typedef struct
{
uint32_t ResetMode; /*!< Specifies the External Event Counter A or B Reset Mode.
This parameter can be a value of @ref HRTIM_Timer_External_Event_ResetMode */
uint32_t Source; /*!< Specifies the External Event Counter source selection.
This parameter can be one of @ref HRTIM_External_Event_Channels */
uint32_t Counter; /*!< Specifies the External Event Counter Threshold.
This parameter can be a number between 0x0 and 0x3F */
} HRTIM_ExternalEventCfgTypeDef;
#if (USE_HAL_HRTIM_REGISTER_CALLBACKS == 1)
/**
* @brief HAL HRTIM Callback ID enumeration definition
*/
typedef enum {
HAL_HRTIM_FAULT1CALLBACK_CB_ID = 0x00U, /*!< Fault 1 interrupt callback ID */
HAL_HRTIM_FAULT2CALLBACK_CB_ID = 0x01U, /*!< Fault 2 interrupt callback ID */
HAL_HRTIM_FAULT3CALLBACK_CB_ID = 0x02U, /*!< Fault 3 interrupt callback ID */
HAL_HRTIM_FAULT4CALLBACK_CB_ID = 0x03U, /*!< Fault 4 interrupt callback ID */
HAL_HRTIM_FAULT5CALLBACK_CB_ID = 0x04U, /*!< Fault 5 interrupt callback ID */
HAL_HRTIM_SYSTEMFAULTCALLBACK_CB_ID = 0x05U, /*!< System fault interrupt callback ID */
HAL_HRTIM_DLLCALBRATIONREADYCALLBACK_CB_ID = 0x06U, /*!< DLL Ready interrupt callback ID */
HAL_HRTIM_BURSTMODEPERIODCALLBACK_CB_ID = 0x07U, /*!< Burst mode period interrupt callback ID */
HAL_HRTIM_SYNCHRONIZATIONEVENTCALLBACK_CB_ID = 0x08U, /*!< Sync Input interrupt callback ID */
HAL_HRTIM_ERRORCALLBACK_CB_ID = 0x09U, /*!< DMA error callback ID */
HAL_HRTIM_REGISTERSUPDATECALLBACK_CB_ID = 0x10U, /*!< Timer x Update interrupt callback ID */
HAL_HRTIM_REPETITIONEVENTCALLBACK_CB_ID = 0x11U, /*!< Timer x Repetition interrupt callback ID */
HAL_HRTIM_COMPARE1EVENTCALLBACK_CB_ID = 0x12U, /*!< Timer x Compare 1 match interrupt callback ID */
HAL_HRTIM_COMPARE2EVENTCALLBACK_CB_ID = 0x13U, /*!< Timer x Compare 2 match interrupt callback ID */
HAL_HRTIM_COMPARE3EVENTCALLBACK_CB_ID = 0x14U, /*!< Timer x Compare 3 match interrupt callback ID */
HAL_HRTIM_COMPARE4EVENTCALLBACK_CB_ID = 0x15U, /*!< Timer x Compare 4 match interrupt callback ID */
HAL_HRTIM_CAPTURE1EVENTCALLBACK_CB_ID = 0x16U, /*!< Timer x Capture 1 interrupts callback ID */
HAL_HRTIM_CAPTURE2EVENTCALLBACK_CB_ID = 0x17U, /*!< Timer x Capture 2 interrupts callback ID */
HAL_HRTIM_DELAYEDPROTECTIONCALLBACK_CB_ID = 0x18U, /*!< Timer x Delayed protection interrupt callback ID */
HAL_HRTIM_COUNTERRESETCALLBACK_CB_ID = 0x19U, /*!< Timer x counter reset/roll-over interrupt callback ID */
HAL_HRTIM_OUTPUT1SETCALLBACK_CB_ID = 0x1AU, /*!< Timer x output 1 set interrupt callback ID */
HAL_HRTIM_OUTPUT1RESETCALLBACK_CB_ID = 0x1BU, /*!< Timer x output 1 reset interrupt callback ID */
HAL_HRTIM_OUTPUT2SETCALLBACK_CB_ID = 0x1CU, /*!< Timer x output 2 set interrupt callback ID */
HAL_HRTIM_OUTPUT2RESETCALLBACK_CB_ID = 0x1DU, /*!< Timer x output 2 reset interrupt callback ID */
HAL_HRTIM_BURSTDMATRANSFERCALLBACK_CB_ID = 0x1EU, /*!< Timer x Burst DMA completed interrupt callback ID */
HAL_HRTIM_MSPINIT_CB_ID = 0x20U, /*!< HRTIM MspInit callback ID */
HAL_HRTIM_MSPDEINIT_CB_ID = 0x21U, /*!< HRTIM MspInit callback ID */
HAL_HRTIM_FAULT6CALLBACK_CB_ID = 0x22U, /*!< Fault 6 interrupt callback ID */
}HAL_HRTIM_CallbackIDTypeDef;
/**
* @brief HAL HRTIM Callback function pointer definitions
*/
typedef void (* pHRTIM_CallbackTypeDef)(HRTIM_HandleTypeDef *hhrtim); /*!< HRTIM related callback function pointer */
typedef void (* pHRTIM_TIMxCallbackTypeDef)(HRTIM_HandleTypeDef *hhrtim, /*!< HRTIM Timer x related callback function pointer */
uint32_t TimerIdx);
#endif /* USE_HAL_HRTIM_REGISTER_CALLBACKS */
/**
* @}
*/
/* Exported constants --------------------------------------------------------*/
/** @defgroup HRTIM_Exported_Constants HRTIM Exported Constants
* @{
*/
/** @defgroup HRTIM_Timer_Index HRTIM Timer Index
* @{
* @brief Constants defining the timer indexes
*/
#define HRTIM_TIMERINDEX_TIMER_A 0x0U /*!< Index used to access timer A registers */
#define HRTIM_TIMERINDEX_TIMER_B 0x1U /*!< Index used to access timer B registers */
#define HRTIM_TIMERINDEX_TIMER_C 0x2U /*!< Index used to access timer C registers */
#define HRTIM_TIMERINDEX_TIMER_D 0x3U /*!< Index used to access timer D registers */
#define HRTIM_TIMERINDEX_TIMER_E 0x4U /*!< Index used to access timer E registers */
#define HRTIM_TIMERINDEX_TIMER_F 0x5U /*!< Index used to access timer F registers */
#define HRTIM_TIMERINDEX_MASTER 0x6U /*!< Index used to access master registers */
#define HRTIM_TIMERINDEX_COMMON 0xFFU /*!< Index used to access HRTIM common registers */
/**
* @}
*/
/** @defgroup HRTIM_Timer_identifier HRTIM Timer identifier
* @{
* @brief Constants defining timer identifiers
*/
#define HRTIM_TIMERID_MASTER (HRTIM_MCR_MCEN) /*!< Master identifier */
#define HRTIM_TIMERID_TIMER_A (HRTIM_MCR_TACEN) /*!< Timer A identifier */
#define HRTIM_TIMERID_TIMER_B (HRTIM_MCR_TBCEN) /*!< Timer B identifier */
#define HRTIM_TIMERID_TIMER_C (HRTIM_MCR_TCCEN) /*!< Timer C identifier */
#define HRTIM_TIMERID_TIMER_D (HRTIM_MCR_TDCEN) /*!< Timer D identifier */
#define HRTIM_TIMERID_TIMER_E (HRTIM_MCR_TECEN) /*!< Timer E identifier */
#define HRTIM_TIMERID_TIMER_F (HRTIM_MCR_TFCEN) /*!< Timer F identifier */
/**
* @}
*/
/** @defgroup HRTIM_Compare_Unit HRTIM Compare Unit
* @{
* @brief Constants defining compare unit identifiers
*/
#define HRTIM_COMPAREUNIT_1 0x00000001U /*!< Compare unit 1 identifier */
#define HRTIM_COMPAREUNIT_2 0x00000002U /*!< Compare unit 2 identifier */
#define HRTIM_COMPAREUNIT_3 0x00000004U /*!< Compare unit 3 identifier */
#define HRTIM_COMPAREUNIT_4 0x00000008U /*!< Compare unit 4 identifier */
/**
* @}
*/
/** @defgroup HRTIM_Capture_Unit HRTIM Capture Unit
* @{
* @brief Constants defining capture unit identifiers
*/
#define HRTIM_CAPTUREUNIT_1 0x00000001U /*!< Capture unit 1 identifier */
#define HRTIM_CAPTUREUNIT_2 0x00000002U /*!< Capture unit 2 identifier */
/**
* @}
*/
/** @defgroup HRTIM_Timer_Output HRTIM Timer Output
* @{
* @brief Constants defining timer output identifiers
*/
#define HRTIM_OUTPUT_TA1 0x00000001U /*!< Timer A - Output 1 identifier */
#define HRTIM_OUTPUT_TA2 0x00000002U /*!< Timer A - Output 2 identifier */
#define HRTIM_OUTPUT_TB1 0x00000004U /*!< Timer B - Output 1 identifier */
#define HRTIM_OUTPUT_TB2 0x00000008U /*!< Timer B - Output 2 identifier */
#define HRTIM_OUTPUT_TC1 0x00000010U /*!< Timer C - Output 1 identifier */
#define HRTIM_OUTPUT_TC2 0x00000020U /*!< Timer C - Output 2 identifier */
#define HRTIM_OUTPUT_TD1 0x00000040U /*!< Timer D - Output 1 identifier */
#define HRTIM_OUTPUT_TD2 0x00000080U /*!< Timer D - Output 2 identifier */
#define HRTIM_OUTPUT_TE1 0x00000100U /*!< Timer E - Output 1 identifier */
#define HRTIM_OUTPUT_TE2 0x00000200U /*!< Timer E - Output 2 identifier */
#define HRTIM_OUTPUT_TF1 0x00000400U /*!< Timer F - Output 1 identifier */
#define HRTIM_OUTPUT_TF2 0x00000800U /*!< Timer F - Output 2 identifier */
/**
* @}
*/
/** @defgroup HRTIM_ADC_Trigger HRTIM ADC Trigger
* @{
* @brief Constants defining ADC triggers identifiers
*/
#define HRTIM_ADCTRIGGER_1 0x00000001U /*!< ADC trigger 1 identifier */
#define HRTIM_ADCTRIGGER_2 0x00000002U /*!< ADC trigger 2 identifier */
#define HRTIM_ADCTRIGGER_3 0x00000004U /*!< ADC trigger 3 identifier */
#define HRTIM_ADCTRIGGER_4 0x00000008U /*!< ADC trigger 4 identifier */
/**
* @}
*/
/** @defgroup HRTIM_ADC_Ext_Trigger HRTIM ADC Extended Trigger
* @{
* @brief Constants defining ADC Extended triggers identifiers
*/
#define HRTIM_ADCTRIGGER_5 0x00000010U /*!< ADC trigger 5 identifier */
#define HRTIM_ADCTRIGGER_6 0x00000020U /*!< ADC trigger 6 identifier */
#define HRTIM_ADCTRIGGER_7 0x00000040U /*!< ADC trigger 7 identifier */
#define HRTIM_ADCTRIGGER_8 0x00000080U /*!< ADC trigger 8 identifier */
#define HRTIM_ADCTRIGGER_9 0x00000100U /*!< ADC trigger 9 identifier */
#define HRTIM_ADCTRIGGER_10 0x00000200U /*!< ADC trigger 10 identifier */
#define IS_HRTIM_ADCTRIGGER(ADCTRIGGER)\
(((ADCTRIGGER) == HRTIM_ADCTRIGGER_1) || \
((ADCTRIGGER) == HRTIM_ADCTRIGGER_2) || \
((ADCTRIGGER) == HRTIM_ADCTRIGGER_3) || \
((ADCTRIGGER) == HRTIM_ADCTRIGGER_4) || \
((ADCTRIGGER) == HRTIM_ADCTRIGGER_5) || \
((ADCTRIGGER) == HRTIM_ADCTRIGGER_6) || \
((ADCTRIGGER) == HRTIM_ADCTRIGGER_7) || \
((ADCTRIGGER) == HRTIM_ADCTRIGGER_8) || \
((ADCTRIGGER) == HRTIM_ADCTRIGGER_9) || \
((ADCTRIGGER) == HRTIM_ADCTRIGGER_10))
#define IS_HRTIM_ADCEXTTRIGGER(ADCTRIGGER)\
(((ADCTRIGGER) == HRTIM_ADCTRIGGER_5) || \
((ADCTRIGGER) == HRTIM_ADCTRIGGER_6) || \
((ADCTRIGGER) == HRTIM_ADCTRIGGER_7) || \
((ADCTRIGGER) == HRTIM_ADCTRIGGER_8) || \
((ADCTRIGGER) == HRTIM_ADCTRIGGER_9) || \
((ADCTRIGGER) == HRTIM_ADCTRIGGER_10))
/**
* @}
*/
/** @defgroup HRTIM_External_Event_Channels HRTIM External Event Channels
* @{
* @brief Constants defining external event channel identifiers
*/
#define HRTIM_EVENT_NONE (0x00000000U) /*!< Undefined event channel */
#define HRTIM_EVENT_1 (0x00000001U) /*!< External event channel 1 identifier */
#define HRTIM_EVENT_2 (0x00000002U) /*!< External event channel 2 identifier */
#define HRTIM_EVENT_3 (0x00000003U) /*!< External event channel 3 identifier */
#define HRTIM_EVENT_4 (0x00000004U) /*!< External event channel 4 identifier */
#define HRTIM_EVENT_5 (0x00000005U) /*!< External event channel 5 identifier */
#define HRTIM_EVENT_6 (0x00000006U) /*!< External event channel 6 identifier */
#define HRTIM_EVENT_7 (0x00000007U) /*!< External event channel 7 identifier */
#define HRTIM_EVENT_8 (0x00000008U) /*!< External event channel 8 identifier */
#define HRTIM_EVENT_9 (0x00000009U) /*!< External event channel 9 identifier */
#define HRTIM_EVENT_10 (0x0000000AU) /*!< External event channel 10 identifier */
/**
* @}
*/
/** @defgroup HRTIM_Fault_Channel HRTIM Fault Channel
* @{
* @brief Constants defining fault channel identifiers
*/
#define HRTIM_FAULT_1 (0x01U) /*!< Fault channel 1 identifier */
#define HRTIM_FAULT_2 (0x02U) /*!< Fault channel 2 identifier */
#define HRTIM_FAULT_3 (0x04U) /*!< Fault channel 3 identifier */
#define HRTIM_FAULT_4 (0x08U) /*!< Fault channel 4 identifier */
#define HRTIM_FAULT_5 (0x10U) /*!< Fault channel 5 identifier */
#define HRTIM_FAULT_6 (0x20U) /*!< Fault channel 6 identifier */
/**
* @}
*/
/** @defgroup HRTIM_Prescaler_Ratio HRTIM Prescaler Ratio
* @{
* @brief Constants defining timer high-resolution clock prescaler ratio.
*/
#define HRTIM_PRESCALERRATIO_MUL32 (0x00000000U) /*!< fHRCK: fHRTIM x 32U = 4.608 GHz - Resolution: 217 ps - Min PWM frequency: 70.3 kHz (fHRTIM=144MHz) */
#define HRTIM_PRESCALERRATIO_MUL16 (0x00000001U) /*!< fHRCK: fHRTIM x 16U = 2.304 GHz - Resolution: 434 ps - Min PWM frequency: 35.1 KHz (fHRTIM=144MHz) */
#define HRTIM_PRESCALERRATIO_MUL8 (0x00000002U) /*!< fHRCK: fHRTIM x 8U = 1.152 GHz - Resolution: 868 ps - Min PWM frequency: 17.6 kHz (fHRTIM=144MHz) */
#define HRTIM_PRESCALERRATIO_MUL4 (0x00000003U) /*!< fHRCK: fHRTIM x 4U = 576 MHz - Resolution: 1.73 ns - Min PWM frequency: 8.8 kHz (fHRTIM=144MHz) */
#define HRTIM_PRESCALERRATIO_MUL2 (0x00000004U) /*!< fHRCK: fHRTIM x 2U = 288 MHz - Resolution: 3.47 ns - Min PWM frequency: 4.4 kHz (fHRTIM=144MHz) */
#define HRTIM_PRESCALERRATIO_DIV1 (0x00000005U) /*!< fHRCK: fHRTIM = 144 MHz - Resolution: 6.95 ns - Min PWM frequency: 2.2 kHz (fHRTIM=144MHz) */
#define HRTIM_PRESCALERRATIO_DIV2 (0x00000006U) /*!< fHRCK: fHRTIM / 2U = 72 MHz - Resolution: 13.88 ns- Min PWM frequency: 1.1 kHz (fHRTIM=144MHz) */
#define HRTIM_PRESCALERRATIO_DIV4 (0x00000007U) /*!< fHRCK: fHRTIM / 4U = 36 MHz - Resolution: 27.7 ns- Min PWM frequency: 550Hz (fHRTIM=144MHz) */
/**
* @}
*/
/** @defgroup HRTIM_Counter_Operating_Mode HRTIM Counter Operating Mode
* @{
* @brief Constants defining timer counter operating mode.
*/
#define HRTIM_MODE_CONTINUOUS (0x00000008U) /*!< The timer operates in continuous (free-running) mode */
#define HRTIM_MODE_SINGLESHOT (0x00000000U) /*!< The timer operates in non retriggerable single-shot mode */
#define HRTIM_MODE_SINGLESHOT_RETRIGGERABLE (0x00000010U) /*!< The timer operates in retriggerable single-shot mode */
/**
* @}
*/
/** @defgroup HRTIM_Half_Mode_Enable HRTIM Half Mode Enable
* @{
* @brief Constants defining half mode enabling status.
*/
#define HRTIM_HALFMODE_DISABLED (0x00000000U) /*!< Half mode is disabled */
#define HRTIM_HALFMODE_ENABLED (0x00000020U) /*!< Half mode is enabled */
/**
* @}
*/
/** @defgroup HRTIM_Interleaved_Mode HRTIM Interleaved Mode
* @{
* @brief Constants defining interleaved mode enabling status.
*/
#define HRTIM_INTERLEAVED_MODE_DISABLED 0x000U /*!< HRTIM interleaved Mode is disabled */
#define HRTIM_INTERLEAVED_MODE_DUAL 0x002U /*!< HRTIM interleaved Mode is Half */
#define HRTIM_INTERLEAVED_MODE_TRIPLE 0x003U /*!< HRTIM interleaved Mode is Triple */
#define HRTIM_INTERLEAVED_MODE_QUAD 0x004U /*!< HRTIM interleaved Mode is Quad */
/**
* @}
*/
/** @defgroup HRTIM_Start_On_Sync_Input_Event HRTIM Start On Sync Input Event
* @{
* @brief Constants defining the timer behavior following the synchronization event
*/
#define HRTIM_SYNCSTART_DISABLED (0x00000000U) /*!< Synchronization input event has effect on the timer */
#define HRTIM_SYNCSTART_ENABLED (HRTIM_MCR_SYNCSTRTM) /*!< Synchronization input event starts the timer */
/**
* @}
*/
/** @defgroup HRTIM_Reset_On_Sync_Input_Event HRTIM Reset On Sync Input Event
* @{
* @brief Constants defining the timer behavior following the synchronization event
*/
#define HRTIM_SYNCRESET_DISABLED (0x00000000U) /*!< Synchronization input event has effect on the timer */
#define HRTIM_SYNCRESET_ENABLED (HRTIM_MCR_SYNCRSTM) /*!< Synchronization input event resets the timer */
/**
* @}
*/
/** @defgroup HRTIM_DAC_Synchronization HRTIM DAC Synchronization
* @{
* @brief Constants defining on which output the DAC synchronization event is sent
*/
#define HRTIM_DACSYNC_NONE 0x00000000U /*!< No DAC synchronization event generated */
#define HRTIM_DACSYNC_DACTRIGOUT_1 (HRTIM_MCR_DACSYNC_0) /*!< DAC synchronization event generated on DACTrigOut1 output upon timer update */
#define HRTIM_DACSYNC_DACTRIGOUT_2 (HRTIM_MCR_DACSYNC_1) /*!< DAC synchronization event generated on DACTrigOut2 output upon timer update */
#define HRTIM_DACSYNC_DACTRIGOUT_3 (HRTIM_MCR_DACSYNC_1 | HRTIM_MCR_DACSYNC_0) /*!< DAC update generated on DACTrigOut3 output upon timer update */
/**
* @}
*/
/** @defgroup HRTIM_Register_Preload_Enable HRTIM Register Preload Enable
* @{
* @brief Constants defining whether a write access into a preloadable
* register is done into the active or the preload register.
*/
#define HRTIM_PRELOAD_DISABLED (0x00000000U) /*!< Preload disabled: the write access is directly done into the active register */
#define HRTIM_PRELOAD_ENABLED (HRTIM_MCR_PREEN) /*!< Preload enabled: the write access is done into the preload register */
/**
* @}
*/
/** @defgroup HRTIM_Update_Gating HRTIM Update Gating
* @{
* @brief Constants defining how the update occurs relatively to the burst DMA
* transaction and the external update request on update enable inputs 1 to 3.
*/
#define HRTIM_UPDATEGATING_INDEPENDENT 0x00000000U /*!< Update done independently from the DMA burst transfer completion */
#define HRTIM_UPDATEGATING_DMABURST (HRTIM_TIMCR_UPDGAT_0) /*!< Update done when the DMA burst transfer is completed */
#define HRTIM_UPDATEGATING_DMABURST_UPDATE (HRTIM_TIMCR_UPDGAT_1) /*!< Update done on timer roll-over following a DMA burst transfer completion*/
#define HRTIM_UPDATEGATING_UPDEN1 (HRTIM_TIMCR_UPDGAT_1 | HRTIM_TIMCR_UPDGAT_0) /*!< Slave timer only - Update done on a rising edge of HRTIM update enable input 1U */
#define HRTIM_UPDATEGATING_UPDEN2 (HRTIM_TIMCR_UPDGAT_2) /*!< Slave timer only - Update done on a rising edge of HRTIM update enable input 2U */
#define HRTIM_UPDATEGATING_UPDEN3 (HRTIM_TIMCR_UPDGAT_2 | HRTIM_TIMCR_UPDGAT_0) /*!< Slave timer only - Update done on a rising edge of HRTIM update enable input 3U */
#define HRTIM_UPDATEGATING_UPDEN1_UPDATE (HRTIM_TIMCR_UPDGAT_2 | HRTIM_TIMCR_UPDGAT_1) /*!< Slave timer only - Update done on the update event following a rising edge of HRTIM update enable input 1U */
#define HRTIM_UPDATEGATING_UPDEN2_UPDATE (HRTIM_TIMCR_UPDGAT_2 | HRTIM_TIMCR_UPDGAT_1 | HRTIM_TIMCR_UPDGAT_0) /*!< Slave timer only - Update done on the update event following a rising edge of HRTIM update enable input 2U */
#define HRTIM_UPDATEGATING_UPDEN3_UPDATE (HRTIM_TIMCR_UPDGAT_3) /*!< Slave timer only - Update done on the update event following a rising edge of HRTIM update enable input 3U */
/**
* @}
*/
/** @defgroup HRTIM_Timer_Burst_Mode HRTIM Timer Burst Mode
* @{
* @brief Constants defining how the timer behaves during a burst
mode operation.
*/
#define HRTIM_TIMERBURSTMODE_MAINTAINCLOCK 0x00000000U /*!< Timer counter clock is maintained and the timer operates normally */
#define HRTIM_TIMERBURSTMODE_RESETCOUNTER (HRTIM_BMCR_MTBM) /*!< Timer counter clock is stopped and the counter is reset */
/**
* @}
*/
/** @defgroup HRTIM_Timer_UpDown_Mode HRTIM Timer UpDown Mode
* @{
* @brief Constants defining how the timer counter operates
*/
#define HRTIM_TIMERUPDOWNMODE_UP 0x00000000U /*!< Timer counter is operating in up-counting mode */
#define HRTIM_TIMERUPDOWNMODE_UPDOWN 0x00000001U /*!< Timer counter is operating in up-down counting mode */
/**
* @}
*/
/** @defgroup HRTIM_Timer_TrigHalf_Mode HRTIM Timer Triggered-Half Mode
* @{
* @brief Constants defining how the timer counter operates
*/
#define HRTIM_TIMERTRIGHALF_DISABLED 0x00000000U /*!< Timer Compare 2 register is behaving in standard mode */
#define HRTIM_TIMERTRIGHALF_ENABLED (HRTIM_TIMCR2_TRGHLF) /*!< Timer Compare 2 register is behaving in triggered-half mode */
/**
* @}
*/
/** @defgroup HRTIM_Timer_GreaterCMP3_Mode HRTIM Timer Greater than Compare 3 PWM Mode
* @{
* @brief Constants defining how the timer compare operates
*/
#define HRTIM_TIMERGTCMP3_EQUAL 0x00000000U /*!< Timer Compare 3 event is generated when counter is equal */
#define HRTIM_TIMERGTCMP3_GREATER (HRTIM_TIMCR2_GTCMP3) /*!< Timer Compare 3 Reset event is generated when counter is greater */
/**
* @}
*/
/** @defgroup HRTIM_Timer_GreaterCMP1_Mode HRTIM Timer Greater than Compare 1 PWM Mode
* @{
* @brief Constants defining how the timer compare operates
*/
#define HRTIM_TIMERGTCMP1_EQUAL 0x00000000U /*!< Timer Compare 1 event is generated when counter is equal */
#define HRTIM_TIMERGTCMP1_GREATER (HRTIM_TIMCR2_GTCMP1) /*!< Timer Compare 1 event is generated when counter is greater */
/**
* @}
*/
/** @defgroup HRTIM_Timer_DualChannelDac_Reset HRTIM Dual Channel Dac Reset Trigger
* @{
* @brief Constants defining when the hrtim_dac_reset_trgx trigger is generated
*/
#define HRTIM_TIMER_DCDR_COUNTER 0x00000000U /*!< the trigger is generated on counter reset or roll-over event */
#define HRTIM_TIMER_DCDR_OUT1SET (HRTIM_TIMCR2_DCDR) /*!< the trigger is generated on output 1 set event */
/**
* @}
*/
/** @defgroup HRTIM_Timer_DualChannelDac_Step HRTIM Dual Channel Dac Step Trigger
* @{
* @brief Constants defining when the hrtim_dac_step_trgx trigger is generated
is generated
*/
#define HRTIM_TIMER_DCDS_CMP2 0x00000000U /*!< the trigger is generated on compare 2 event */
#define HRTIM_TIMER_DCDS_OUT1RST (HRTIM_TIMCR2_DCDS) /*!< the trigger is generated on output 1 reset event */
/**
* @}
*/
/** @defgroup HRTIM_Timer_DualChannelDac_Enable HRTIM Dual Channel DAC Trigger Enable
* @{
* @brief Constants enabling the dual channel DAC triggering mechanism
*/
#define HRTIM_TIMER_DCDE_DISABLED 0x00000000U /*!< the Dual channel DAC trigger is disabled */
#define HRTIM_TIMER_DCDE_ENABLED (HRTIM_TIMCR2_DCDE) /*!< the Dual channel DAC trigger is enabled */
/**
* @}
*/
/** @defgroup HRTIM_Timer_Repetition_Update HRTIM Timer Repetition Update
* @{
* @brief Constants defining whether registers are updated when the timer
* repetition period is completed (either due to roll-over or
* reset events)
*/
#define HRTIM_UPDATEONREPETITION_DISABLED 0x00000000U /*!< Update on repetition disabled */
#define HRTIM_UPDATEONREPETITION_ENABLED (HRTIM_MCR_MREPU) /*!< Update on repetition enabled */
/**
* @}
*/
/** @defgroup HRTIM_Timer_Push_Pull_Mode HRTIM Timer Push Pull Mode
* @{
* @brief Constants defining whether or not the push-pull mode is enabled for
* a timer.
*/
#define HRTIM_TIMPUSHPULLMODE_DISABLED 0x00000000U /*!< Push-Pull mode disabled */
#define HRTIM_TIMPUSHPULLMODE_ENABLED (HRTIM_TIMCR_PSHPLL) /*!< Push-Pull mode enabled */
/**
* @}
*/
/** @defgroup HRTIM_Timer_Fault_Enabling HRTIM Timer Fault Enabling
* @{
* @brief Constants defining whether a fault channel is enabled for a timer
*/
#define HRTIM_TIMFAULTENABLE_NONE 0x00000000U /*!< No fault enabled */
#define HRTIM_TIMFAULTENABLE_FAULT1 (HRTIM_FLTR_FLT1EN) /*!< Fault 1 enabled */
#define HRTIM_TIMFAULTENABLE_FAULT2 (HRTIM_FLTR_FLT2EN) /*!< Fault 2 enabled */
#define HRTIM_TIMFAULTENABLE_FAULT3 (HRTIM_FLTR_FLT3EN) /*!< Fault 3 enabled */
#define HRTIM_TIMFAULTENABLE_FAULT4 (HRTIM_FLTR_FLT4EN) /*!< Fault 4 enabled */
#define HRTIM_TIMFAULTENABLE_FAULT5 (HRTIM_FLTR_FLT5EN) /*!< Fault 5 enabled */
#define HRTIM_TIMFAULTENABLE_FAULT6 (HRTIM_FLTR_FLT6EN) /*!< Fault 6 enabled */
/**
* @}
*/
/** @defgroup HRTIM_Timer_Fault_Lock HRTIM Timer Fault Lock
* @{
* @brief Constants defining whether or not fault enabling bits are write
* protected for a timer
*/
#define HRTIM_TIMFAULTLOCK_READWRITE (0x00000000U) /*!< Timer fault enabling bits are read/write */
#define HRTIM_TIMFAULTLOCK_READONLY (HRTIM_FLTR_FLTLCK) /*!< Timer fault enabling bits are read only */
/**
* @}
*/
/** @defgroup HRTIM_Timer_Deadtime_Insertion HRTIM Timer Dead-time Insertion
* @{
* @brief Constants defining whether or not fault the dead time insertion
* feature is enabled for a timer
*/
#define HRTIM_TIMDEADTIMEINSERTION_DISABLED (0x00000000U) /*!< Output 1 and output 2 signals are independent */
#define HRTIM_TIMDEADTIMEINSERTION_ENABLED HRTIM_OUTR_DTEN /*!< Dead-time is inserted between output 1 and output 2U */
/**
* @}
*/
/** @defgroup HRTIM_Timer_Delayed_Protection_Mode HRTIM Timer Delayed Protection Mode
* @{
* @brief Constants defining all possible delayed protection modes
* for a timer. Also define the source and outputs on which the delayed
* protection schemes are applied
*/
#define HRTIM_TIMER_A_B_C_DELAYEDPROTECTION_DISABLED (0x00000000U) /*!< No action */
#define HRTIM_TIMER_A_B_C_DELAYEDPROTECTION_DELAYEDOUT1_EEV6 (HRTIM_OUTR_DLYPRTEN) /*!< Timers A, B, C: Output 1 delayed Idle on external Event 6U */
#define HRTIM_TIMER_A_B_C_DELAYEDPROTECTION_DELAYEDOUT2_EEV6 (HRTIM_OUTR_DLYPRT_0 | HRTIM_OUTR_DLYPRTEN) /*!< Timers A, B, C: Output 2 delayed Idle on external Event 6U */
#define HRTIM_TIMER_A_B_C_DELAYEDPROTECTION_DELAYEDBOTH_EEV6 (HRTIM_OUTR_DLYPRT_1 | HRTIM_OUTR_DLYPRTEN) /*!< Timers A, B, C: Output 1 and output 2 delayed Idle on external Event 6U */
#define HRTIM_TIMER_A_B_C_DELAYEDPROTECTION_BALANCED_EEV6 (HRTIM_OUTR_DLYPRT_1 | HRTIM_OUTR_DLYPRT_0 | HRTIM_OUTR_DLYPRTEN) /*!< Timers A, B, C: Balanced Idle on external Event 6U */
#define HRTIM_TIMER_A_B_C_DELAYEDPROTECTION_DELAYEDOUT1_DEEV7 (HRTIM_OUTR_DLYPRT_2 | HRTIM_OUTR_DLYPRTEN) /*!< Timers A, B, C: Output 1 delayed Idle on external Event 7U */
#define HRTIM_TIMER_A_B_C_DELAYEDPROTECTION_DELAYEDOUT2_DEEV7 (HRTIM_OUTR_DLYPRT_2 | HRTIM_OUTR_DLYPRT_0 | HRTIM_OUTR_DLYPRTEN) /*!< Timers A, B, C: Output 2 delayed Idle on external Event 7U */
#define HRTIM_TIMER_A_B_C_DELAYEDPROTECTION_DELAYEDBOTH_EEV7 (HRTIM_OUTR_DLYPRT_2 | HRTIM_OUTR_DLYPRT_1 | HRTIM_OUTR_DLYPRTEN) /*!< Timers A, B, C: Output 1 and output2 delayed Idle on external Event 7U */
#define HRTIM_TIMER_A_B_C_DELAYEDPROTECTION_BALANCED_EEV7 (HRTIM_OUTR_DLYPRT_2 | HRTIM_OUTR_DLYPRT_1 | HRTIM_OUTR_DLYPRT_0 | HRTIM_OUTR_DLYPRTEN) /*!< Timers A, B, C: Balanced Idle on external Event 7U */
#define HRTIM_TIMER_D_E_DELAYEDPROTECTION_DISABLED (0x00000000U) /*!< No action */
#define HRTIM_TIMER_D_E_DELAYEDPROTECTION_DELAYEDOUT1_EEV8 (HRTIM_OUTR_DLYPRTEN) /*!< Timers D, E: Output 1 delayed Idle on external Event 6U */
#define HRTIM_TIMER_D_E_DELAYEDPROTECTION_DELAYEDOUT2_EEV8 (HRTIM_OUTR_DLYPRT_0 | HRTIM_OUTR_DLYPRTEN) /*!< Timers D, E: Output 2 delayed Idle on external Event 6U */
#define HRTIM_TIMER_D_E_DELAYEDPROTECTION_DELAYEDBOTH_EEV8 (HRTIM_OUTR_DLYPRT_1 | HRTIM_OUTR_DLYPRTEN) /*!< Timers D, E: Output 1 and output 2 delayed Idle on external Event 6U */
#define HRTIM_TIMER_D_E_DELAYEDPROTECTION_BALANCED_EEV8 (HRTIM_OUTR_DLYPRT_1 | HRTIM_OUTR_DLYPRT_0 | HRTIM_OUTR_DLYPRTEN) /*!< Timers D, E: Balanced Idle on external Event 6U */
#define HRTIM_TIMER_D_E_DELAYEDPROTECTION_DELAYEDOUT1_DEEV9 (HRTIM_OUTR_DLYPRT_2 | HRTIM_OUTR_DLYPRTEN) /*!< Timers D, E: Output 1 delayed Idle on external Event 7U */
#define HRTIM_TIMER_D_E_DELAYEDPROTECTION_DELAYEDOUT2_DEEV9 (HRTIM_OUTR_DLYPRT_2 | HRTIM_OUTR_DLYPRT_0 | HRTIM_OUTR_DLYPRTEN) /*!< Timers D, E: Output 2 delayed Idle on external Event 7U */
#define HRTIM_TIMER_D_E_DELAYEDPROTECTION_DELAYEDBOTH_EEV9 (HRTIM_OUTR_DLYPRT_2 | HRTIM_OUTR_DLYPRT_1 | HRTIM_OUTR_DLYPRTEN) /*!< Timers D, E: Output 1 and output2 delayed Idle on external Event 7U */
#define HRTIM_TIMER_D_E_DELAYEDPROTECTION_BALANCED_EEV9 (HRTIM_OUTR_DLYPRT_2 | HRTIM_OUTR_DLYPRT_1 | HRTIM_OUTR_DLYPRT_0 | HRTIM_OUTR_DLYPRTEN) /*!< Timers D, E: Balanced Idle on external Event 7U */
#define HRTIM_TIMER_F_DELAYEDPROTECTION_DISABLED (0x00000000U) /*!< No action */
#define HRTIM_TIMER_F_DELAYEDPROTECTION_DELAYEDOUT1_EEV8 (HRTIM_OUTR_DLYPRTEN) /*!< Timers F: Output 1 delayed Idle on external Event 6U */
#define HRTIM_TIMER_F_DELAYEDPROTECTION_DELAYEDOUT2_EEV8 (HRTIM_OUTR_DLYPRT_0 | HRTIM_OUTR_DLYPRTEN) /*!< Timers F: Output 2 delayed Idle on external Event 6U */
#define HRTIM_TIMER_F_DELAYEDPROTECTION_DELAYEDBOTH_EEV8 (HRTIM_OUTR_DLYPRT_1 | HRTIM_OUTR_DLYPRTEN) /*!< Timers F: Output 1 and output 2 delayed Idle on external Event 6U */
#define HRTIM_TIMER_F_DELAYEDPROTECTION_BALANCED_EEV8 (HRTIM_OUTR_DLYPRT_1 | HRTIM_OUTR_DLYPRT_0 | HRTIM_OUTR_DLYPRTEN) /*!< Timers F: Balanced Idle on external Event 6U */
#define HRTIM_TIMER_F_DELAYEDPROTECTION_DELAYEDOUT1_DEEV9 (HRTIM_OUTR_DLYPRT_2 | HRTIM_OUTR_DLYPRTEN) /*!< Timers F: Output 1 delayed Idle on external Event 7U */
#define HRTIM_TIMER_F_DELAYEDPROTECTION_DELAYEDOUT2_DEEV9 (HRTIM_OUTR_DLYPRT_2 | HRTIM_OUTR_DLYPRT_0 | HRTIM_OUTR_DLYPRTEN) /*!< Timers F: Output 2 delayed Idle on external Event 7U */
#define HRTIM_TIMER_F_DELAYEDPROTECTION_DELAYEDBOTH_EEV9 (HRTIM_OUTR_DLYPRT_2 | HRTIM_OUTR_DLYPRT_1 | HRTIM_OUTR_DLYPRTEN) /*!< Timers F: Output 1 and output2 delayed Idle on external Event 7U */
#define HRTIM_TIMER_F_DELAYEDPROTECTION_BALANCED_EEV9 (HRTIM_OUTR_DLYPRT_2 | HRTIM_OUTR_DLYPRT_1 | HRTIM_OUTR_DLYPRT_0 | HRTIM_OUTR_DLYPRTEN) /*!< Timers F: Balanced Idle on external Event 7U */
/**
* @}
*/
/** @defgroup HRTIM_Timer_Update_Trigger HRTIM Timer Update Trigger
* @{
* @brief Constants defining whether the registers update is done synchronously
* with any other timer or master update
*/
#define HRTIM_TIMUPDATETRIGGER_NONE 0x00000000U /*!< Register update is disabled */
#define HRTIM_TIMUPDATETRIGGER_MASTER (HRTIM_TIMCR_MSTU) /*!< Register update is triggered by the master timer update */
#define HRTIM_TIMUPDATETRIGGER_TIMER_A (HRTIM_TIMCR_TAU) /*!< Register update is triggered by the timer A update */
#define HRTIM_TIMUPDATETRIGGER_TIMER_B (HRTIM_TIMCR_TBU) /*!< Register update is triggered by the timer B update */
#define HRTIM_TIMUPDATETRIGGER_TIMER_C (HRTIM_TIMCR_TCU) /*!< Register update is triggered by the timer C update*/
#define HRTIM_TIMUPDATETRIGGER_TIMER_D (HRTIM_TIMCR_TDU) /*!< Register update is triggered by the timer D update */
#define HRTIM_TIMUPDATETRIGGER_TIMER_E (HRTIM_TIMCR_TEU) /*!< Register update is triggered by the timer E update */
#define HRTIM_TIMUPDATETRIGGER_TIMER_F (HRTIM_TIMCR_TFU) /*!< Register update is triggered by the timer F update */
/**
* @}
*/
/** @defgroup HRTIM_Timer_Reset_Trigger HRTIM Timer Reset Trigger
* @{
* @brief Constants defining the events that can be selected to trigger the reset
* of the timer counter
*/
#define HRTIM_TIMRESETTRIGGER_NONE 0x00000000U /*!< No counter reset trigger */
#define HRTIM_TIMRESETTRIGGER_UPDATE (HRTIM_RSTR_UPDATE) /*!< The timer counter is reset upon update event */
#define HRTIM_TIMRESETTRIGGER_CMP2 (HRTIM_RSTR_CMP2) /*!< The timer counter is reset upon Timer Compare 2 event */
#define HRTIM_TIMRESETTRIGGER_CMP4 (HRTIM_RSTR_CMP4) /*!< The timer counter is reset upon Timer Compare 4 event */
#define HRTIM_TIMRESETTRIGGER_MASTER_PER (HRTIM_RSTR_MSTPER) /*!< The timer counter is reset upon master timer period event */
#define HRTIM_TIMRESETTRIGGER_MASTER_CMP1 (HRTIM_RSTR_MSTCMP1) /*!< The timer counter is reset upon master timer Compare 1 event */
#define HRTIM_TIMRESETTRIGGER_MASTER_CMP2 (HRTIM_RSTR_MSTCMP2) /*!< The timer counter is reset upon master timer Compare 2 event */
#define HRTIM_TIMRESETTRIGGER_MASTER_CMP3 (HRTIM_RSTR_MSTCMP3) /*!< The timer counter is reset upon master timer Compare 3 event */
#define HRTIM_TIMRESETTRIGGER_MASTER_CMP4 (HRTIM_RSTR_MSTCMP4) /*!< The timer counter is reset upon master timer Compare 4 event */
#define HRTIM_TIMRESETTRIGGER_EEV_1 (HRTIM_RSTR_EXTEVNT1) /*!< The timer counter is reset upon external event 1U */
#define HRTIM_TIMRESETTRIGGER_EEV_2 (HRTIM_RSTR_EXTEVNT2) /*!< The timer counter is reset upon external event 2U */
#define HRTIM_TIMRESETTRIGGER_EEV_3 (HRTIM_RSTR_EXTEVNT3) /*!< The timer counter is reset upon external event 3U */
#define HRTIM_TIMRESETTRIGGER_EEV_4 (HRTIM_RSTR_EXTEVNT4) /*!< The timer counter is reset upon external event 4U */
#define HRTIM_TIMRESETTRIGGER_EEV_5 (HRTIM_RSTR_EXTEVNT5) /*!< The timer counter is reset upon external event 5U */
#define HRTIM_TIMRESETTRIGGER_EEV_6 (HRTIM_RSTR_EXTEVNT6) /*!< The timer counter is reset upon external event 6U */
#define HRTIM_TIMRESETTRIGGER_EEV_7 (HRTIM_RSTR_EXTEVNT7) /*!< The timer counter is reset upon external event 7U */
#define HRTIM_TIMRESETTRIGGER_EEV_8 (HRTIM_RSTR_EXTEVNT8) /*!< The timer counter is reset upon external event 8U */
#define HRTIM_TIMRESETTRIGGER_EEV_9 (HRTIM_RSTR_EXTEVNT9) /*!< The timer counter is reset upon external event 9U */
#define HRTIM_TIMRESETTRIGGER_EEV_10 (HRTIM_RSTR_EXTEVNT10) /*!< The timer counter is reset upon external event 10U */
#define HRTIM_TIMRESETTRIGGER_OTHER1_CMP1 (HRTIM_RSTR_TIMBCMP1) /*!< The timer counter is reset upon other timer Compare 1 event */
#define HRTIM_TIMRESETTRIGGER_OTHER1_CMP2 (HRTIM_RSTR_TIMBCMP2) /*!< The timer counter is reset upon other timer Compare 2 event */
#define HRTIM_TIMRESETTRIGGER_OTHER1_CMP4 (HRTIM_RSTR_TIMBCMP4) /*!< The timer counter is reset upon other timer Compare 4 event */
#define HRTIM_TIMRESETTRIGGER_OTHER2_CMP1 (HRTIM_RSTR_TIMCCMP1) /*!< The timer counter is reset upon other timer Compare 1 event */
#define HRTIM_TIMRESETTRIGGER_OTHER2_CMP2 (HRTIM_RSTR_TIMCCMP2) /*!< The timer counter is reset upon other timer Compare 2 event */
#define HRTIM_TIMRESETTRIGGER_OTHER2_CMP4 (HRTIM_RSTR_TIMCCMP4) /*!< The timer counter is reset upon other timer Compare 4 event */
#define HRTIM_TIMRESETTRIGGER_OTHER3_CMP1 (HRTIM_RSTR_TIMDCMP1) /*!< The timer counter is reset upon other timer Compare 1 event */
#define HRTIM_TIMRESETTRIGGER_OTHER3_CMP2 (HRTIM_RSTR_TIMDCMP2) /*!< The timer counter is reset upon other timer Compare 2 event */
#define HRTIM_TIMRESETTRIGGER_OTHER3_CMP4 (HRTIM_RSTR_TIMDCMP4) /*!< The timer counter is reset upon other timer Compare 4 event */
#define HRTIM_TIMRESETTRIGGER_OTHER4_CMP1 (HRTIM_RSTR_TIMECMP1) /*!< The timer counter is reset upon other timer Compare 1 event */
#define HRTIM_TIMRESETTRIGGER_OTHER4_CMP2 (HRTIM_RSTR_TIMECMP2) /*!< The timer counter is reset upon other timer Compare 2 event */
#define HRTIM_TIMRESETTRIGGER_OTHER4_CMP4 (HRTIM_RSTR_TIMECMP4) /*!< The timer counter is reset upon other timer Compare 4 event */
#define HRTIM_TIMRESETTRIGGER_OTHER5_CMP1 (HRTIM_RSTR_TIMFCMP1) /*!< The timer counter is reset upon other timer Compare 1 event */
#define HRTIM_TIMRESETTRIGGER_OTHER5_CMP2 (HRTIM_RSTR_TIMFCMP2) /*!< The timer counter is reset upon other timer Compare 2 event */
/**
* @}
*/
/** @defgroup HRTIM_Timer_Reset_Update HRTIM Timer Reset Update
* @{
* @brief Constants defining whether the register are updated upon Timerx
* counter reset or roll-over to 0 after reaching the period value
* in continuous mode
*/
#define HRTIM_TIMUPDATEONRESET_DISABLED 0x00000000U /*!< Update by timer x reset / roll-over disabled */
#define HRTIM_TIMUPDATEONRESET_ENABLED (HRTIM_TIMCR_TRSTU) /*!< Update by timer x reset / roll-over enabled */
/**
* @}
*/
/** @defgroup HRTIM_Timer_RollOver_Mode HRTIM Timer RollOver Mode
* @{
* @brief Constants defining when the roll-over is generated upon Timerx
* event generated when the counter is equal to 0 ('VALLEY' mode) or to HRTIM_PERxR value ('CREST' mode) or BOTH
* This setting only applies when the UDM bit is set. It is not significant otherwise.
*/
#define HRTIM_TIM_FEROM_BOTH 0x00000000U /*!< Roll-over event used by */
#define HRTIM_TIM_FEROM_CREST (HRTIM_TIMCR2_FEROM_1) /*!< the Fault and */
#define HRTIM_TIM_FEROM_VALLEY (HRTIM_TIMCR2_FEROM_0) /*!< Event counters */
#define HRTIM_TIM_BMROM_BOTH 0x00000000U /*!< Roll-over event used in the Burst mode controller */
#define HRTIM_TIM_BMROM_CREST (HRTIM_TIMCR2_BMROM_1) /*!< as clock */
#define HRTIM_TIM_BMROM_VALLEY (HRTIM_TIMCR2_BMROM_0) /*!< and as burst mode trigger */
#define HRTIM_TIM_ADROM_BOTH 0x00000000U /*!< Roll-over event which triggers */
#define HRTIM_TIM_ADROM_CREST (HRTIM_TIMCR2_ADROM_1) /*!< the */
#define HRTIM_TIM_ADROM_VALLEY (HRTIM_TIMCR2_ADROM_0) /*!< ADC */
#define HRTIM_TIM_OUTROM_BOTH 0x00000000U /*!< Roll-over event which sets and/or resets the outputs */
#define HRTIM_TIM_OUTROM_CREST (HRTIM_TIMCR2_OUTROM_1) /*!< as per HRTIM_SETxyR */
#define HRTIM_TIM_OUTROM_VALLEY (HRTIM_TIMCR2_OUTROM_0) /*!< and HRTIM_RSTxyR settings */
#define HRTIM_TIM_ROM_BOTH 0x00000000U /*!< Roll-over event with the following destinations: IRQ and DMA requests,*/
#define HRTIM_TIM_ROM_CREST (HRTIM_TIMCR2_ROM_1) /*!< Update trigger (to transfer content from preload to active registers), */
#define HRTIM_TIM_ROM_VALLEY (HRTIM_TIMCR2_ROM_0) /*!< repetition counter decrement and External Event filtering */
#define IS_HRTIM_ROLLOVERMODE(ROLLOVER)\
((((ROLLOVER) == HRTIM_TIM_FEROM_BOTH) || ((ROLLOVER) == HRTIM_TIM_FEROM_CREST) || ((ROLLOVER) == HRTIM_TIM_FEROM_VALLEY)) ||\
(((ROLLOVER) == HRTIM_TIM_ADROM_BOTH) || ((ROLLOVER) == HRTIM_TIM_ADROM_CREST) || ((ROLLOVER) == HRTIM_TIM_ADROM_VALLEY)) ||\
(((ROLLOVER) == HRTIM_TIM_BMROM_BOTH) || ((ROLLOVER) == HRTIM_TIM_BMROM_CREST) || ((ROLLOVER) == HRTIM_TIM_BMROM_VALLEY)) ||\
(((ROLLOVER) == HRTIM_TIM_OUTROM_BOTH) || ((ROLLOVER) == HRTIM_TIM_OUTROM_CREST) || ((ROLLOVER) == HRTIM_TIM_OUTROM_VALLEY)) ||\
(((ROLLOVER) == HRTIM_TIM_ROM_BOTH) || ((ROLLOVER) == HRTIM_TIM_ROM_CREST) || ((ROLLOVER) == HRTIM_TIM_ROM_VALLEY)))
/**
* @}
*/
/** @defgroup HRTIM_Compare_Unit_Auto_Delayed_Mode HRTIM Compare Unit Auto Delayed Mode
* @{
* @brief Constants defining whether the compare register is behaving in
* regular mode (compare match issued as soon as counter equal compare),
* or in auto-delayed mode
*/
#define HRTIM_AUTODELAYEDMODE_REGULAR (0x00000000U) /*!< standard compare mode */
#define HRTIM_AUTODELAYEDMODE_AUTODELAYED_NOTIMEOUT (HRTIM_TIMCR_DELCMP2_0) /*!< Compare event generated only if a capture has occurred */
#define HRTIM_AUTODELAYEDMODE_AUTODELAYED_TIMEOUTCMP1 (HRTIM_TIMCR_DELCMP2_1) /*!< Compare event generated if a capture has occurred or after a Compare 1 match (timeout if capture event is missing) */
#define HRTIM_AUTODELAYEDMODE_AUTODELAYED_TIMEOUTCMP3 (HRTIM_TIMCR_DELCMP2_1 | HRTIM_TIMCR_DELCMP2_0) /*!< Compare event generated if a capture has occurred or after a Compare 3 match (timeout if capture event is missing) */
/**
* @}
*/
/** @defgroup HRTIM_Simple_OC_Mode HRTIM Simple OC Mode
* @{
* @brief Constants defining the behavior of the output signal when the timer
operates in basic output compare mode
*/
#define HRTIM_BASICOCMODE_TOGGLE (0x00000001U) /*!< Output toggles when the timer counter reaches the compare value */
#define HRTIM_BASICOCMODE_INACTIVE (0x00000002U) /*!< Output forced to active level when the timer counter reaches the compare value */
#define HRTIM_BASICOCMODE_ACTIVE (0x00000003U) /*!< Output forced to inactive level when the timer counter reaches the compare value */
#define IS_HRTIM_BASICOCMODE(BASICOCMODE)\
(((BASICOCMODE) == HRTIM_BASICOCMODE_TOGGLE) || \
((BASICOCMODE) == HRTIM_BASICOCMODE_INACTIVE) || \
((BASICOCMODE) == HRTIM_BASICOCMODE_ACTIVE))
/**
* @}
*/
/** @defgroup HRTIM_Output_Polarity HRTIM Output Polarity
* @{
* @brief Constants defining the polarity of a timer output
*/
#define HRTIM_OUTPUTPOLARITY_HIGH (0x00000000U) /*!< Output is active HIGH */
#define HRTIM_OUTPUTPOLARITY_LOW (HRTIM_OUTR_POL1) /*!< Output is active LOW */
/**
* @}
*/
/** @defgroup HRTIM_Output_Set_Source HRTIM Output Set Source
* @{
* @brief Constants defining the events that can be selected to configure the
* set crossbar of a timer output
*/
#define HRTIM_OUTPUTSET_NONE 0x00000000U /*!< Reset the output set crossbar */
#define HRTIM_OUTPUTSET_RESYNC (HRTIM_SET1R_RESYNC) /*!< Timer reset event coming solely from software or SYNC input forces the output to its active state */
#define HRTIM_OUTPUTSET_TIMPER (HRTIM_SET1R_PER) /*!< Timer period event forces the output to its active state */
#define HRTIM_OUTPUTSET_TIMCMP1 (HRTIM_SET1R_CMP1) /*!< Timer compare 1 event forces the output to its active state */
#define HRTIM_OUTPUTSET_TIMCMP2 (HRTIM_SET1R_CMP2) /*!< Timer compare 2 event forces the output to its active state */
#define HRTIM_OUTPUTSET_TIMCMP3 (HRTIM_SET1R_CMP3) /*!< Timer compare 3 event forces the output to its active state */
#define HRTIM_OUTPUTSET_TIMCMP4 (HRTIM_SET1R_CMP4) /*!< Timer compare 4 event forces the output to its active state */
#define HRTIM_OUTPUTSET_MASTERPER (HRTIM_SET1R_MSTPER) /*!< The master timer period event forces the output to its active state */
#define HRTIM_OUTPUTSET_MASTERCMP1 (HRTIM_SET1R_MSTCMP1) /*!< Master Timer compare 1 event forces the output to its active state */
#define HRTIM_OUTPUTSET_MASTERCMP2 (HRTIM_SET1R_MSTCMP2) /*!< Master Timer compare 2 event forces the output to its active state */
#define HRTIM_OUTPUTSET_MASTERCMP3 (HRTIM_SET1R_MSTCMP3) /*!< Master Timer compare 3 event forces the output to its active state */
#define HRTIM_OUTPUTSET_MASTERCMP4 (HRTIM_SET1R_MSTCMP4) /*!< Master Timer compare 4 event forces the output to its active state */
/* Timer Events mapping for Timer A */
#define HRTIM_OUTPUTSET_TIMAEV1_TIMBCMP1 (HRTIM_SET1R_TIMEVNT1) /*!< Timer event 1 forces the output to its active state */
#define HRTIM_OUTPUTSET_TIMAEV2_TIMBCMP2 (HRTIM_SET1R_TIMEVNT2) /*!< Timer event 2 forces the output to its active state */
#define HRTIM_OUTPUTSET_TIMAEV3_TIMCCMP2 (HRTIM_SET1R_TIMEVNT3) /*!< Timer event 3 forces the output to its active state */
#define HRTIM_OUTPUTSET_TIMAEV4_TIMCCMP3 (HRTIM_SET1R_TIMEVNT4) /*!< Timer event 4 forces the output to its active state */
#define HRTIM_OUTPUTSET_TIMAEV5_TIMDCMP1 (HRTIM_SET1R_TIMEVNT5) /*!< Timer event 5 forces the output to its active state */
#define HRTIM_OUTPUTSET_TIMAEV6_TIMDCMP2 (HRTIM_SET1R_TIMEVNT6) /*!< Timer event 6 forces the output to its active state */
#define HRTIM_OUTPUTSET_TIMAEV7_TIMECMP3 (HRTIM_SET1R_TIMEVNT7) /*!< Timer event 7 forces the output to its active state */
#define HRTIM_OUTPUTSET_TIMAEV8_TIMECMP4 (HRTIM_SET1R_TIMEVNT8) /*!< Timer event 8 forces the output to its active state */
#define HRTIM_OUTPUTSET_TIMAEV9_TIMFCMP4 (HRTIM_SET1R_TIMEVNT9) /*!< Timer event 9 forces the output to its active state */
/* Timer Events mapping for Timer B */
#define HRTIM_OUTPUTSET_TIMBEV1_TIMACMP1 (HRTIM_SET1R_TIMEVNT1) /*!< Timer event 1 forces the output to its active state */
#define HRTIM_OUTPUTSET_TIMBEV2_TIMACMP2 (HRTIM_SET1R_TIMEVNT2) /*!< Timer event 2 forces the output to its active state */
#define HRTIM_OUTPUTSET_TIMBEV3_TIMCCMP3 (HRTIM_SET1R_TIMEVNT3) /*!< Timer event 3 forces the output to its active state */
#define HRTIM_OUTPUTSET_TIMBEV4_TIMCCMP4 (HRTIM_SET1R_TIMEVNT4) /*!< Timer event 4 forces the output to its active state */
#define HRTIM_OUTPUTSET_TIMBEV5_TIMDCMP3 (HRTIM_SET1R_TIMEVNT5) /*!< Timer event 5 forces the output to its active state */
#define HRTIM_OUTPUTSET_TIMBEV6_TIMDCMP4 (HRTIM_SET1R_TIMEVNT6) /*!< Timer event 6 forces the output to its active state */
#define HRTIM_OUTPUTSET_TIMBEV7_TIMECMP1 (HRTIM_SET1R_TIMEVNT7) /*!< Timer event 7 forces the output to its active state */
#define HRTIM_OUTPUTSET_TIMBEV8_TIMECMP2 (HRTIM_SET1R_TIMEVNT8) /*!< Timer event 8 forces the output to its active state */
#define HRTIM_OUTPUTSET_TIMBEV9_TIMFCMP3 (HRTIM_SET1R_TIMEVNT9) /*!< Timer event 9 forces the output to its active state */
/* Timer Events mapping for Timer C */
#define HRTIM_OUTPUTSET_TIMCEV1_TIMACMP2 (HRTIM_SET1R_TIMEVNT1) /*!< Timer event 1 forces the output to its active state */
#define HRTIM_OUTPUTSET_TIMCEV2_TIMACMP3 (HRTIM_SET1R_TIMEVNT2) /*!< Timer event 2 forces the output to its active state */
#define HRTIM_OUTPUTSET_TIMCEV3_TIMBCMP2 (HRTIM_SET1R_TIMEVNT3) /*!< Timer event 3 forces the output to its active state */
#define HRTIM_OUTPUTSET_TIMCEV4_TIMBCMP3 (HRTIM_SET1R_TIMEVNT4) /*!< Timer event 4 forces the output to its active state */
#define HRTIM_OUTPUTSET_TIMCEV5_TIMDCMP2 (HRTIM_SET1R_TIMEVNT5) /*!< Timer event 5 forces the output to its active state */
#define HRTIM_OUTPUTSET_TIMCEV6_TIMDCMP4 (HRTIM_SET1R_TIMEVNT6) /*!< Timer event 6 forces the output to its active state */
#define HRTIM_OUTPUTSET_TIMCEV7_TIMECMP3 (HRTIM_SET1R_TIMEVNT7) /*!< Timer event 7 forces the output to its active state */
#define HRTIM_OUTPUTSET_TIMCEV8_TIMECMP4 (HRTIM_SET1R_TIMEVNT8) /*!< Timer event 8 forces the output to its active state */
#define HRTIM_OUTPUTSET_TIMCEV9_TIMFCMP2 (HRTIM_SET1R_TIMEVNT9) /*!< Timer event 9 forces the output to its active state */
/* Timer Events mapping for Timer D */
#define HRTIM_OUTPUTSET_TIMDEV1_TIMACMP1 (HRTIM_SET1R_TIMEVNT1) /*!< Timer event 1 forces the output to its active state */
#define HRTIM_OUTPUTSET_TIMDEV2_TIMACMP4 (HRTIM_SET1R_TIMEVNT2) /*!< Timer event 2 forces the output to its active state */
#define HRTIM_OUTPUTSET_TIMDEV3_TIMBCMP2 (HRTIM_SET1R_TIMEVNT3) /*!< Timer event 3 forces the output to its active state */
#define HRTIM_OUTPUTSET_TIMDEV4_TIMBCMP4 (HRTIM_SET1R_TIMEVNT4) /*!< Timer event 4 forces the output to its active state */
#define HRTIM_OUTPUTSET_TIMDEV5_TIMCCMP4 (HRTIM_SET1R_TIMEVNT5) /*!< Timer event 5 forces the output to its active state */
#define HRTIM_OUTPUTSET_TIMDEV6_TIMECMP1 (HRTIM_SET1R_TIMEVNT6) /*!< Timer event 6 forces the output to its active state */
#define HRTIM_OUTPUTSET_TIMDEV7_TIMECMP4 (HRTIM_SET1R_TIMEVNT7) /*!< Timer event 7 forces the output to its active state */
#define HRTIM_OUTPUTSET_TIMDEV8_TIMFCMP1 (HRTIM_SET1R_TIMEVNT8) /*!< Timer event 8 forces the output to its active state */
#define HRTIM_OUTPUTSET_TIMDEV9_TIMFCMP3 (HRTIM_SET1R_TIMEVNT9) /*!< Timer event 9 forces the output to its active state */
/* Timer Events mapping for Timer E */
#define HRTIM_OUTPUTSET_TIMEEV1_TIMACMP4 (HRTIM_SET1R_TIMEVNT1) /*!< Timer event 1 forces the output to its active state */
#define HRTIM_OUTPUTSET_TIMEEV2_TIMBCMP3 (HRTIM_SET1R_TIMEVNT2) /*!< Timer event 2 forces the output to its active state */
#define HRTIM_OUTPUTSET_TIMEEV3_TIMBCMP4 (HRTIM_SET1R_TIMEVNT3) /*!< Timer event 3 forces the output to its active state */
#define HRTIM_OUTPUTSET_TIMEEV4_TIMCCMP1 (HRTIM_SET1R_TIMEVNT4) /*!< Timer event 4 forces the output to its active state */
#define HRTIM_OUTPUTSET_TIMEEV5_TIMCCMP2 (HRTIM_SET1R_TIMEVNT5) /*!< Timer event 5 forces the output to its active state */
#define HRTIM_OUTPUTSET_TIMEEV6_TIMDCMP1 (HRTIM_SET1R_TIMEVNT6) /*!< Timer event 6 forces the output to its active state */
#define HRTIM_OUTPUTSET_TIMEEV7_TIMDCMP2 (HRTIM_SET1R_TIMEVNT7) /*!< Timer event 7 forces the output to its active state */
#define HRTIM_OUTPUTSET_TIMEEV8_TIMFCMP3 (HRTIM_SET1R_TIMEVNT8) /*!< Timer event 8 forces the output to its active state */
#define HRTIM_OUTPUTSET_TIMEEV9_TIMFCMP4 (HRTIM_SET1R_TIMEVNT9) /*!< Timer event 9 forces the output to its active state */
/* Timer Events mapping for Timer F */
#define HRTIM_OUTPUTSET_TIMFEV1_TIMACMP3 (HRTIM_SET1R_TIMEVNT1) /*!< Timer event 1 forces the output to its active state */
#define HRTIM_OUTPUTSET_TIMFEV2_TIMBCMP1 (HRTIM_SET1R_TIMEVNT2) /*!< Timer event 2 forces the output to its active state */
#define HRTIM_OUTPUTSET_TIMFEV3_TIMBCMP4 (HRTIM_SET1R_TIMEVNT3) /*!< Timer event 3 forces the output to its active state */
#define HRTIM_OUTPUTSET_TIMFEV4_TIMCCMP1 (HRTIM_SET1R_TIMEVNT4) /*!< Timer event 4 forces the output to its active state */
#define HRTIM_OUTPUTSET_TIMFEV5_TIMCCMP4 (HRTIM_SET1R_TIMEVNT5) /*!< Timer event 5 forces the output to its active state */
#define HRTIM_OUTPUTSET_TIMFEV6_TIMDCMP3 (HRTIM_SET1R_TIMEVNT6) /*!< Timer event 6 forces the output to its active state */
#define HRTIM_OUTPUTSET_TIMFEV7_TIMDCMP4 (HRTIM_SET1R_TIMEVNT7) /*!< Timer event 7 forces the output to its active state */
#define HRTIM_OUTPUTSET_TIMFEV8_TIMECMP2 (HRTIM_SET1R_TIMEVNT8) /*!< Timer event 8 forces the output to its active state */
#define HRTIM_OUTPUTSET_TIMFEV9_TIMECMP3 (HRTIM_SET1R_TIMEVNT9) /*!< Timer event 9 forces the output to its active state */
#define HRTIM_OUTPUTSET_EEV_1 (HRTIM_SET1R_EXTVNT1) /*!< External event 1 forces the output to its active state */
#define HRTIM_OUTPUTSET_EEV_2 (HRTIM_SET1R_EXTVNT2) /*!< External event 2 forces the output to its active state */
#define HRTIM_OUTPUTSET_EEV_3 (HRTIM_SET1R_EXTVNT3) /*!< External event 3 forces the output to its active state */
#define HRTIM_OUTPUTSET_EEV_4 (HRTIM_SET1R_EXTVNT4) /*!< External event 4 forces the output to its active state */
#define HRTIM_OUTPUTSET_EEV_5 (HRTIM_SET1R_EXTVNT5) /*!< External event 5 forces the output to its active state */
#define HRTIM_OUTPUTSET_EEV_6 (HRTIM_SET1R_EXTVNT6) /*!< External event 6 forces the output to its active state */
#define HRTIM_OUTPUTSET_EEV_7 (HRTIM_SET1R_EXTVNT7) /*!< External event 7 forces the output to its active state */
#define HRTIM_OUTPUTSET_EEV_8 (HRTIM_SET1R_EXTVNT8) /*!< External event 8 forces the output to its active state */
#define HRTIM_OUTPUTSET_EEV_9 (HRTIM_SET1R_EXTVNT9) /*!< External event 9 forces the output to its active state */
#define HRTIM_OUTPUTSET_EEV_10 (HRTIM_SET1R_EXTVNT10) /*!< External event 10 forces the output to its active state */
#define HRTIM_OUTPUTSET_UPDATE (HRTIM_SET1R_UPDATE) /*!< Timer register update event forces the output to its active state */
/**
* @}
*/
/** @defgroup HRTIM_Output_Reset_Source HRTIM Output Reset Source
* @{
* @brief Constants defining the events that can be selected to configure the
* reset crossbar of a timer output
*/
#define HRTIM_OUTPUTRESET_NONE 0x00000000U /*!< Reset the output reset crossbar */
#define HRTIM_OUTPUTRESET_RESYNC (HRTIM_RST1R_RESYNC) /*!< Timer reset event coming solely from software or SYNC input forces the output to its inactive state */
#define HRTIM_OUTPUTRESET_TIMPER (HRTIM_RST1R_PER) /*!< Timer period event forces the output to its inactive state */
#define HRTIM_OUTPUTRESET_TIMCMP1 (HRTIM_RST1R_CMP1) /*!< Timer compare 1 event forces the output to its inactive state */
#define HRTIM_OUTPUTRESET_TIMCMP2 (HRTIM_RST1R_CMP2) /*!< Timer compare 2 event forces the output to its inactive state */
#define HRTIM_OUTPUTRESET_TIMCMP3 (HRTIM_RST1R_CMP3) /*!< Timer compare 3 event forces the output to its inactive state */
#define HRTIM_OUTPUTRESET_TIMCMP4 (HRTIM_RST1R_CMP4) /*!< Timer compare 4 event forces the output to its inactive state */
#define HRTIM_OUTPUTRESET_MASTERPER (HRTIM_RST1R_MSTPER) /*!< The master timer period event forces the output to its inactive state */
#define HRTIM_OUTPUTRESET_MASTERCMP1 (HRTIM_RST1R_MSTCMP1) /*!< Master Timer compare 1 event forces the output to its inactive state */
#define HRTIM_OUTPUTRESET_MASTERCMP2 (HRTIM_RST1R_MSTCMP2) /*!< Master Timer compare 2 event forces the output to its inactive state */
#define HRTIM_OUTPUTRESET_MASTERCMP3 (HRTIM_RST1R_MSTCMP3) /*!< Master Timer compare 3 event forces the output to its inactive state */
#define HRTIM_OUTPUTRESET_MASTERCMP4 (HRTIM_RST1R_MSTCMP4) /*!< Master Timer compare 4 event forces the output to its inactive state */
/* Timer Events mapping for Timer A */
#define HRTIM_OUTPUTRESET_TIMAEV1_TIMBCMP1 (HRTIM_RST1R_TIMEVNT1) /*!< Timer event 1 forces the output to its inactive state */
#define HRTIM_OUTPUTRESET_TIMAEV2_TIMBCMP2 (HRTIM_RST1R_TIMEVNT2) /*!< Timer event 2 forces the output to its inactive state */
#define HRTIM_OUTPUTRESET_TIMAEV3_TIMCCMP2 (HRTIM_RST1R_TIMEVNT3) /*!< Timer event 3 forces the output to its inactive state */
#define HRTIM_OUTPUTRESET_TIMAEV4_TIMCCMP3 (HRTIM_RST1R_TIMEVNT4) /*!< Timer event 4 forces the output to its inactive state */
#define HRTIM_OUTPUTRESET_TIMAEV5_TIMDCMP1 (HRTIM_RST1R_TIMEVNT5) /*!< Timer event 5 forces the output to its inactive state */
#define HRTIM_OUTPUTRESET_TIMAEV6_TIMDCMP2 (HRTIM_RST1R_TIMEVNT6) /*!< Timer event 6 forces the output to its inactive state */
#define HRTIM_OUTPUTRESET_TIMAEV7_TIMECMP3 (HRTIM_RST1R_TIMEVNT7) /*!< Timer event 7 forces the output to its inactive state */
#define HRTIM_OUTPUTRESET_TIMAEV8_TIMECMP4 (HRTIM_RST1R_TIMEVNT8) /*!< Timer event 8 forces the output to its inactive state */
#define HRTIM_OUTPUTRESET_TIMAEV9_TIMFCMP4 (HRTIM_RST1R_TIMEVNT9) /*!< Timer event 9 forces the output to its inactive state */
/* Timer Events mapping for Timer B */
#define HRTIM_OUTPUTRESET_TIMBEV1_TIMACMP1 (HRTIM_RST1R_TIMEVNT1) /*!< Timer event 1 forces the output to its inactive state */
#define HRTIM_OUTPUTRESET_TIMBEV2_TIMACMP2 (HRTIM_RST1R_TIMEVNT2) /*!< Timer event 2 forces the output to its inactive state */
#define HRTIM_OUTPUTRESET_TIMBEV3_TIMCCMP3 (HRTIM_RST1R_TIMEVNT3) /*!< Timer event 3 forces the output to its inactive state */
#define HRTIM_OUTPUTRESET_TIMBEV4_TIMCCMP4 (HRTIM_RST1R_TIMEVNT4) /*!< Timer event 4 forces the output to its inactive state */
#define HRTIM_OUTPUTRESET_TIMBEV5_TIMDCMP3 (HRTIM_RST1R_TIMEVNT5) /*!< Timer event 5 forces the output to its inactive state */
#define HRTIM_OUTPUTRESET_TIMBEV6_TIMDCMP4 (HRTIM_RST1R_TIMEVNT6) /*!< Timer event 6 forces the output to its inactive state */
#define HRTIM_OUTPUTRESET_TIMBEV7_TIMECMP1 (HRTIM_RST1R_TIMEVNT7) /*!< Timer event 7 forces the output to its inactive state */
#define HRTIM_OUTPUTRESET_TIMBEV8_TIMECMP2 (HRTIM_RST1R_TIMEVNT8) /*!< Timer event 8 forces the output to its inactive state */
#define HRTIM_OUTPUTRESET_TIMBEV9_TIMFCMP3 (HRTIM_RST1R_TIMEVNT9) /*!< Timer event 9 forces the output to its inactive state */
/* Timer Events mapping for Timer C */
#define HRTIM_OUTPUTRESET_TIMCEV1_TIMACMP2 (HRTIM_RST1R_TIMEVNT1) /*!< Timer event 1 forces the output to its inactive state */
#define HRTIM_OUTPUTRESET_TIMCEV2_TIMACMP3 (HRTIM_RST1R_TIMEVNT2) /*!< Timer event 2 forces the output to its inactive state */
#define HRTIM_OUTPUTRESET_TIMCEV3_TIMBCMP2 (HRTIM_RST1R_TIMEVNT3) /*!< Timer event 3 forces the output to its inactive state */
#define HRTIM_OUTPUTRESET_TIMCEV4_TIMBCMP3 (HRTIM_RST1R_TIMEVNT4) /*!< Timer event 4 forces the output to its inactive state */
#define HRTIM_OUTPUTRESET_TIMCEV5_TIMDCMP2 (HRTIM_RST1R_TIMEVNT5) /*!< Timer event 5 forces the output to its inactive state */
#define HRTIM_OUTPUTRESET_TIMCEV6_TIMDCMP4 (HRTIM_RST1R_TIMEVNT6) /*!< Timer event 6 forces the output to its inactive state */
#define HRTIM_OUTPUTRESET_TIMCEV7_TIMECMP3 (HRTIM_RST1R_TIMEVNT7) /*!< Timer event 7 forces the output to its inactive state */
#define HRTIM_OUTPUTRESET_TIMCEV8_TIMECMP4 (HRTIM_RST1R_TIMEVNT8) /*!< Timer event 8 forces the output to its inactive state */
#define HRTIM_OUTPUTRESET_TIMCEV9_TIMFCMP2 (HRTIM_RST1R_TIMEVNT9) /*!< Timer event 9 forces the output to its inactive state */
/* Timer Events mapping for Timer D */
#define HRTIM_OUTPUTRESET_TIMDEV1_TIMACMP1 (HRTIM_RST1R_TIMEVNT1) /*!< Timer event 1 forces the output to its inactive state */
#define HRTIM_OUTPUTRESET_TIMDEV2_TIMACMP4 (HRTIM_RST1R_TIMEVNT2) /*!< Timer event 2 forces the output to its inactive state */
#define HRTIM_OUTPUTRESET_TIMDEV3_TIMBCMP2 (HRTIM_RST1R_TIMEVNT3) /*!< Timer event 3 forces the output to its inactive state */
#define HRTIM_OUTPUTRESET_TIMDEV4_TIMBCMP4 (HRTIM_RST1R_TIMEVNT4) /*!< Timer event 4 forces the output to its inactive state */
#define HRTIM_OUTPUTRESET_TIMDEV5_TIMCCMP4 (HRTIM_RST1R_TIMEVNT5) /*!< Timer event 5 forces the output to its inactive state */
#define HRTIM_OUTPUTRESET_TIMDEV6_TIMECMP1 (HRTIM_RST1R_TIMEVNT6) /*!< Timer event 6 forces the output to its inactive state */
#define HRTIM_OUTPUTRESET_TIMDEV7_TIMECMP4 (HRTIM_RST1R_TIMEVNT7) /*!< Timer event 7 forces the output to its inactive state */
#define HRTIM_OUTPUTRESET_TIMDEV8_TIMFCMP1 (HRTIM_RST1R_TIMEVNT8) /*!< Timer event 8 forces the output to its inactive state */
#define HRTIM_OUTPUTRESET_TIMDEV9_TIMFCMP3 (HRTIM_RST1R_TIMEVNT9) /*!< Timer event 9 forces the output to its inactive state */
/* Timer Events mapping for Timer E */
#define HRTIM_OUTPUTRESET_TIMEEV1_TIMACMP4 (HRTIM_RST1R_TIMEVNT1) /*!< Timer event 1 forces the output to its inactive state */
#define HRTIM_OUTPUTRESET_TIMEEV2_TIMBCMP3 (HRTIM_RST1R_TIMEVNT2) /*!< Timer event 2 forces the output to its inactive state */
#define HRTIM_OUTPUTRESET_TIMEEV3_TIMBCMP4 (HRTIM_RST1R_TIMEVNT3) /*!< Timer event 3 forces the output to its inactive state */
#define HRTIM_OUTPUTRESET_TIMEEV4_TIMCCMP1 (HRTIM_RST1R_TIMEVNT4) /*!< Timer event 4 forces the output to its inactive state */
#define HRTIM_OUTPUTRESET_TIMEEV5_TIMCCMP2 (HRTIM_RST1R_TIMEVNT5) /*!< Timer event 5 forces the output to its inactive state */
#define HRTIM_OUTPUTRESET_TIMEEV6_TIMDCMP1 (HRTIM_RST1R_TIMEVNT6) /*!< Timer event 6 forces the output to its inactive state */
#define HRTIM_OUTPUTRESET_TIMEEV7_TIMDCMP2 (HRTIM_RST1R_TIMEVNT7) /*!< Timer event 7 forces the output to its inactive state */
#define HRTIM_OUTPUTRESET_TIMEEV8_TIMFCMP3 (HRTIM_RST1R_TIMEVNT8) /*!< Timer event 8 forces the output to its inactive state */
#define HRTIM_OUTPUTRESET_TIMEEV9_TIMFCMP4 (HRTIM_RST1R_TIMEVNT9) /*!< Timer event 9 forces the output to its inactive state */
/* Timer Events mapping for Timer F */
#define HRTIM_OUTPUTRESET_TIMFEV1_TIMACMP3 (HRTIM_RST1R_TIMEVNT1) /*!< Timer event 1 forces the output to its inactive state */
#define HRTIM_OUTPUTRESET_TIMFEV2_TIMBCMP1 (HRTIM_RST1R_TIMEVNT2) /*!< Timer event 2 forces the output to its inactive state */
#define HRTIM_OUTPUTRESET_TIMFEV3_TIMBCMP4 (HRTIM_RST1R_TIMEVNT3) /*!< Timer event 3 forces the output to its inactive state */
#define HRTIM_OUTPUTRESET_TIMFEV4_TIMCCMP1 (HRTIM_RST1R_TIMEVNT4) /*!< Timer event 4 forces the output to its inactive state */
#define HRTIM_OUTPUTRESET_TIMFEV5_TIMCCMP4 (HRTIM_RST1R_TIMEVNT5) /*!< Timer event 5 forces the output to its inactive state */
#define HRTIM_OUTPUTRESET_TIMFEV6_TIMDCMP3 (HRTIM_RST1R_TIMEVNT6) /*!< Timer event 6 forces the output to its inactive state */
#define HRTIM_OUTPUTRESET_TIMFEV7_TIMDCMP4 (HRTIM_RST1R_TIMEVNT7) /*!< Timer event 7 forces the output to its inactive state */
#define HRTIM_OUTPUTRESET_TIMFEV8_TIMECMP2 (HRTIM_RST1R_TIMEVNT8) /*!< Timer event 8 forces the output to its inactive state */
#define HRTIM_OUTPUTRESET_TIMFEV9_TIMECMP3 (HRTIM_RST1R_TIMEVNT9) /*!< Timer event 9 forces the output to its inactive state */
#define HRTIM_OUTPUTRESET_EEV_1 (HRTIM_RST1R_EXTVNT1) /*!< External event 1 forces the output to its inactive state */
#define HRTIM_OUTPUTRESET_EEV_2 (HRTIM_RST1R_EXTVNT2) /*!< External event 2 forces the output to its inactive state */
#define HRTIM_OUTPUTRESET_EEV_3 (HRTIM_RST1R_EXTVNT3) /*!< External event 3 forces the output to its inactive state */
#define HRTIM_OUTPUTRESET_EEV_4 (HRTIM_RST1R_EXTVNT4) /*!< External event 4 forces the output to its inactive state */
#define HRTIM_OUTPUTRESET_EEV_5 (HRTIM_RST1R_EXTVNT5) /*!< External event 5 forces the output to its inactive state */
#define HRTIM_OUTPUTRESET_EEV_6 (HRTIM_RST1R_EXTVNT6) /*!< External event 6 forces the output to its inactive state */
#define HRTIM_OUTPUTRESET_EEV_7 (HRTIM_RST1R_EXTVNT7) /*!< External event 7 forces the output to its inactive state */
#define HRTIM_OUTPUTRESET_EEV_8 (HRTIM_RST1R_EXTVNT8) /*!< External event 8 forces the output to its inactive state */
#define HRTIM_OUTPUTRESET_EEV_9 (HRTIM_RST1R_EXTVNT9) /*!< External event 9 forces the output to its inactive state */
#define HRTIM_OUTPUTRESET_EEV_10 (HRTIM_RST1R_EXTVNT10) /*!< External event 10 forces the output to its inactive state */
#define HRTIM_OUTPUTRESET_UPDATE (HRTIM_RST1R_UPDATE) /*!< Timer register update event forces the output to its inactive state */
/**
* @}
*/
/** @defgroup HRTIM_Output_Idle_Mode HRTIM Output Idle Mode
* @{
* @brief Constants defining whether or not the timer output transition to its
IDLE state when burst mode is entered
*/
#define HRTIM_OUTPUTIDLEMODE_NONE 0x00000000U /*!< The output is not affected by the burst mode operation */
#define HRTIM_OUTPUTIDLEMODE_IDLE (HRTIM_OUTR_IDLM1) /*!< The output is in idle state when requested by the burst mode controller */
/**
* @}
*/
/** @defgroup HRTIM_Output_IDLE_Level HRTIM Output IDLE Level
* @{
* @brief Constants defining the output level when output is in IDLE state
*/
#define HRTIM_OUTPUTIDLELEVEL_INACTIVE 0x00000000U /*!< Output at inactive level when in IDLE state */
#define HRTIM_OUTPUTIDLELEVEL_ACTIVE (HRTIM_OUTR_IDLES1) /*!< Output at active level when in IDLE state */
/**
* @}
*/
/** @defgroup HRTIM_Output_FAULT_Level HRTIM Output FAULT Level
* @{
* @brief Constants defining the output level when output is in FAULT state
*/
#define HRTIM_OUTPUTFAULTLEVEL_NONE 0x00000000U /*!< The output is not affected by the fault input */
#define HRTIM_OUTPUTFAULTLEVEL_ACTIVE (HRTIM_OUTR_FAULT1_0) /*!< Output at active level when in FAULT state */
#define HRTIM_OUTPUTFAULTLEVEL_INACTIVE (HRTIM_OUTR_FAULT1_1) /*!< Output at inactive level when in FAULT state */
#define HRTIM_OUTPUTFAULTLEVEL_HIGHZ (HRTIM_OUTR_FAULT1_1 | HRTIM_OUTR_FAULT1_0) /*!< Output is tri-stated when in FAULT state */
/**
* @}
*/
/** @defgroup HRTIM_Output_Chopper_Mode_Enable HRTIM Output Chopper Mode Enable
* @{
* @brief Constants defining whether or not chopper mode is enabled for a timer
output
*/
#define HRTIM_OUTPUTCHOPPERMODE_DISABLED 0x00000000U /*!< Output signal is not altered */
#define HRTIM_OUTPUTCHOPPERMODE_ENABLED (HRTIM_OUTR_CHP1) /*!< Output signal is chopped by a carrier signal */
/**
* @}
*/
/** @defgroup HRTIM_Output_Burst_Mode_Entry_Delayed HRTIM Output Burst Mode Entry Delayed
* @{
* @brief Constants defining the idle mode entry is delayed by forcing a
dead-time insertion before switching the outputs to their idle state
*/
#define HRTIM_OUTPUTBURSTMODEENTRY_REGULAR 0x00000000U /*!< The programmed Idle state is applied immediately to the Output */
#define HRTIM_OUTPUTBURSTMODEENTRY_DELAYED (HRTIM_OUTR_DIDL1) /*!< Dead-time is inserted on output before entering the idle mode */
/**
* @}
*/
/** @defgroup HRTIM_Output_Balanced_Idle_Auto_Resume HRTIM Output Balanced Idle Automatic Resume
* @{
* @brief Constants defining if the outputs are automatically
re-enabled after a balanced idle event.
*/
#define HRTIM_OUTPUTBIAR_DISABLED 0x00000000U /*!< output is not automatically re-enabled */
#define HRTIM_OUTPUTBIAR_ENABLED (HRTIM_OUTR_BIAR) /*!< output is automatically re-enabled */
/**
* @}
*/
/** @defgroup HRTIM_Capture_Unit_Trigger HRTIM Capture Unit Trigger
* @{
* @brief Constants defining the events that can be selected to trigger the
* capture of the timing unit counter
*/
#define HRTIM_CAPTURETRIGGER_NONE 0x00000000U /*!< Capture trigger is disabled */
#define HRTIM_CAPTURETRIGGER_UPDATE (HRTIM_CPT1CR_UPDCPT) /*!< The update event triggers the Capture */
#define HRTIM_CAPTURETRIGGER_EEV_1 (HRTIM_CPT1CR_EXEV1CPT) /*!< The External event 1 triggers the Capture */
#define HRTIM_CAPTURETRIGGER_EEV_2 (HRTIM_CPT1CR_EXEV2CPT) /*!< The External event 2 triggers the Capture */
#define HRTIM_CAPTURETRIGGER_EEV_3 (HRTIM_CPT1CR_EXEV3CPT) /*!< The External event 3 triggers the Capture */
#define HRTIM_CAPTURETRIGGER_EEV_4 (HRTIM_CPT1CR_EXEV4CPT) /*!< The External event 4 triggers the Capture */
#define HRTIM_CAPTURETRIGGER_EEV_5 (HRTIM_CPT1CR_EXEV5CPT) /*!< The External event 5 triggers the Capture */
#define HRTIM_CAPTURETRIGGER_EEV_6 (HRTIM_CPT1CR_EXEV6CPT) /*!< The External event 6 triggers the Capture */
#define HRTIM_CAPTURETRIGGER_EEV_7 (HRTIM_CPT1CR_EXEV7CPT) /*!< The External event 7 triggers the Capture */
#define HRTIM_CAPTURETRIGGER_EEV_8 (HRTIM_CPT1CR_EXEV8CPT) /*!< The External event 8 triggers the Capture */
#define HRTIM_CAPTURETRIGGER_EEV_9 (HRTIM_CPT1CR_EXEV9CPT) /*!< The External event 9 triggers the Capture */
#define HRTIM_CAPTURETRIGGER_EEV_10 (HRTIM_CPT1CR_EXEV10CPT) /*!< The External event 10 triggers the Capture */
#define HRTIM_CAPTURETRIGGER_TA1_SET (HRTIM_CPT1CR_TA1SET) /*!< Capture is triggered by TA1 output inactive to active transition */
#define HRTIM_CAPTURETRIGGER_TA1_RESET (HRTIM_CPT1CR_TA1RST) /*!< Capture is triggered by TA1 output active to inactive transition */
#define HRTIM_CAPTURETRIGGER_TIMERA_CMP1 (HRTIM_CPT1CR_TIMACMP1) /*!< Timer A Compare 1 triggers Capture */
#define HRTIM_CAPTURETRIGGER_TIMERA_CMP2 (HRTIM_CPT1CR_TIMACMP2) /*!< Timer A Compare 2 triggers Capture */
#define HRTIM_CAPTURETRIGGER_TB1_SET (HRTIM_CPT1CR_TB1SET) /*!< Capture is triggered by TB1 output inactive to active transition */
#define HRTIM_CAPTURETRIGGER_TB1_RESET (HRTIM_CPT1CR_TB1RST) /*!< Capture is triggered by TB1 output active to inactive transition */
#define HRTIM_CAPTURETRIGGER_TIMERB_CMP1 (HRTIM_CPT1CR_TIMBCMP1) /*!< Timer B Compare 1 triggers Capture */
#define HRTIM_CAPTURETRIGGER_TIMERB_CMP2 (HRTIM_CPT1CR_TIMBCMP2) /*!< Timer B Compare 2 triggers Capture */
#define HRTIM_CAPTURETRIGGER_TC1_SET (HRTIM_CPT1CR_TC1SET) /*!< Capture is triggered by TC1 output inactive to active transition */
#define HRTIM_CAPTURETRIGGER_TC1_RESET (HRTIM_CPT1CR_TC1RST) /*!< Capture is triggered by TC1 output active to inactive transition */
#define HRTIM_CAPTURETRIGGER_TIMERC_CMP1 (HRTIM_CPT1CR_TIMCCMP1) /*!< Timer C Compare 1 triggers Capture */
#define HRTIM_CAPTURETRIGGER_TIMERC_CMP2 (HRTIM_CPT1CR_TIMCCMP2) /*!< Timer C Compare 2 triggers Capture */
#define HRTIM_CAPTURETRIGGER_TD1_SET (HRTIM_CPT1CR_TD1SET) /*!< Capture is triggered by TD1 output inactive to active transition */
#define HRTIM_CAPTURETRIGGER_TD1_RESET (HRTIM_CPT1CR_TD1RST) /*!< Capture is triggered by TD1 output active to inactive transition */
#define HRTIM_CAPTURETRIGGER_TIMERD_CMP1 (HRTIM_CPT1CR_TIMDCMP1) /*!< Timer D Compare 1 triggers Capture */
#define HRTIM_CAPTURETRIGGER_TIMERD_CMP2 (HRTIM_CPT1CR_TIMDCMP2) /*!< Timer D Compare 2 triggers Capture */
#define HRTIM_CAPTURETRIGGER_TE1_SET (HRTIM_CPT1CR_TE1SET) /*!< Capture is triggered by TE1 output inactive to active transition */
#define HRTIM_CAPTURETRIGGER_TE1_RESET (HRTIM_CPT1CR_TE1RST) /*!< Capture is triggered by TE1 output active to inactive transition */
#define HRTIM_CAPTURETRIGGER_TIMERE_CMP1 (HRTIM_CPT1CR_TIMECMP1) /*!< Timer E Compare 1 triggers Capture */
#define HRTIM_CAPTURETRIGGER_TIMERE_CMP2 (HRTIM_CPT1CR_TIMECMP2) /*!< Timer E Compare 2 triggers Capture */
/**
* @}
*/
/** @defgroup HRTIM_Capture_Unit_TimerF_Trigger HRTIM Capture Unit TimerF Trigger
* @{
* @brief Constants defining the events that can be selected to trigger the
* capture of the timing unit counter
*/
#define HRTIM_CAPTURETRIGGER_TF1_SET ((uint64_t)(HRTIM_CPT1CR_TF1SET ) << 32) /*!< Capture is triggered by TF1 output inactive to active transition */
#define HRTIM_CAPTURETRIGGER_TF1_RESET ((uint64_t)(HRTIM_CPT1CR_TF1RST ) << 32) /*!< Capture is triggered by TF1 output active to inactive transition */
#define HRTIM_CAPTURETRIGGER_TIMERF_CMP1 ((uint64_t)(HRTIM_CPT1CR_TIMFCMP1) << 32) /*!< Timer F Compare 1 triggers Capture */
#define HRTIM_CAPTURETRIGGER_TIMERF_CMP2 ((uint64_t)(HRTIM_CPT1CR_TIMFCMP2) << 32) /*!< Timer F Compare 2 triggers Capture */
/**
* @}
*/
/** @defgroup HRTIM_Timer_External_Event_Filter HRTIM Timer External Event Filter
* @{
* @brief Constants defining the event filtering applied to external events
* by a timer
*/
#define HRTIM_TIMEEVFLT_NONE (0x00000000U)
#define HRTIM_TIMEEVFLT_BLANKINGCMP1 (HRTIM_EEFR1_EE1FLTR_0) /*!< Blanking from counter reset/roll-over to Compare 1U */
#define HRTIM_TIMEEVFLT_BLANKINGCMP2 (HRTIM_EEFR1_EE1FLTR_1) /*!< Blanking from counter reset/roll-over to Compare 2U */
#define HRTIM_TIMEEVFLT_BLANKINGCMP3 (HRTIM_EEFR1_EE1FLTR_1 | HRTIM_EEFR1_EE1FLTR_0) /*!< Blanking from counter reset/roll-over to Compare 3U */
#define HRTIM_TIMEEVFLT_BLANKINGCMP4 (HRTIM_EEFR1_EE1FLTR_2) /*!< Blanking from counter reset/roll-over to Compare 4U */
/* Blanking Filter for TIMER A */
#define HRTIM_TIMEEVFLT_BLANKING_TIMAEEF1_TIMBCMP1 (HRTIM_EEFR1_EE1FLTR_2 | HRTIM_EEFR1_EE1FLTR_0) /*!< Blanking from another timing unit: TIMFLTR1 source */
#define HRTIM_TIMEEVFLT_BLANKING_TIMAEEF2_TIMBCMP4 (HRTIM_EEFR1_EE1FLTR_2 | HRTIM_EEFR1_EE1FLTR_1) /*!< Blanking from another timing unit: TIMFLTR2 source */
#define HRTIM_TIMEEVFLT_BLANKING_TIMAEEF3_TIMBOUT2 (HRTIM_EEFR1_EE1FLTR_2 | HRTIM_EEFR1_EE1FLTR_1 | HRTIM_EEFR1_EE1FLTR_0) /*!< Blanking from another timing unit: TIMFLTR3 source */
#define HRTIM_TIMEEVFLT_BLANKING_TIMAEEF4_TIMCCMP1 (HRTIM_EEFR1_EE1FLTR_3) /*!< Blanking from another timing unit: TIMFLTR4 source */
#define HRTIM_TIMEEVFLT_BLANKING_TIMAEEF5_TIMCCMP4 (HRTIM_EEFR1_EE1FLTR_3 | HRTIM_EEFR1_EE1FLTR_0) /*!< Blanking from another timing unit: TIMFLTR5 source */
#define HRTIM_TIMEEVFLT_BLANKING_TIMAEEF6_TIMFCMP1 (HRTIM_EEFR1_EE1FLTR_3 | HRTIM_EEFR1_EE1FLTR_1) /*!< Blanking from another timing unit: TIMFLTR6 source */
#define HRTIM_TIMEEVFLT_BLANKING_TIMAEEF7_TIMDCMP1 (HRTIM_EEFR1_EE1FLTR_3 | HRTIM_EEFR1_EE1FLTR_1 | HRTIM_EEFR1_EE1FLTR_0) /*!< Blanking from another timing unit: TIMFLTR7 source */
#define HRTIM_TIMEEVFLT_BLANKING_TIMAEEF8_TIMECMP2 (HRTIM_EEFR1_EE1FLTR_3 | HRTIM_EEFR1_EE1FLTR_2) /*!< Blanking from another timing unit: TIMFLTR8 source */
/* Blanking Filter for TIMER B */
#define HRTIM_TIMEEVFLT_BLANKING_TIMBEEF1_TIMACMP1 (HRTIM_EEFR1_EE1FLTR_2 | HRTIM_EEFR1_EE1FLTR_0) /*!< Blanking from another timing unit: TIMFLTR1 source */
#define HRTIM_TIMEEVFLT_BLANKING_TIMBEEF2_TIMACMP4 (HRTIM_EEFR1_EE1FLTR_2 | HRTIM_EEFR1_EE1FLTR_1) /*!< Blanking from another timing unit: TIMFLTR2 source */
#define HRTIM_TIMEEVFLT_BLANKING_TIMBEEF3_TIMAOUT2 (HRTIM_EEFR1_EE1FLTR_2 | HRTIM_EEFR1_EE1FLTR_1 | HRTIM_EEFR1_EE1FLTR_0) /*!< Blanking from another timing unit: TIMFLTR3 source */
#define HRTIM_TIMEEVFLT_BLANKING_TIMBEEF4_TIMCCMP1 (HRTIM_EEFR1_EE1FLTR_3) /*!< Blanking from another timing unit: TIMFLTR4 source */
#define HRTIM_TIMEEVFLT_BLANKING_TIMBEEF5_TIMCCMP2 (HRTIM_EEFR1_EE1FLTR_3 | HRTIM_EEFR1_EE1FLTR_0) /*!< Blanking from another timing unit: TIMFLTR5 source */
#define HRTIM_TIMEEVFLT_BLANKING_TIMBEEF6_TIMFCMP2 (HRTIM_EEFR1_EE1FLTR_3 | HRTIM_EEFR1_EE1FLTR_1) /*!< Blanking from another timing unit: TIMFLTR6 source */
#define HRTIM_TIMEEVFLT_BLANKING_TIMBEEF7_TIMDCMP2 (HRTIM_EEFR1_EE1FLTR_3 | HRTIM_EEFR1_EE1FLTR_1 | HRTIM_EEFR1_EE1FLTR_0) /*!< Blanking from another timing unit: TIMFLTR7 source */
#define HRTIM_TIMEEVFLT_BLANKING_TIMBEEF8_TIMECMP1 (HRTIM_EEFR1_EE1FLTR_3 | HRTIM_EEFR1_EE1FLTR_2) /*!< Blanking from another timing unit: TIMFLTR8 source */
/* Blanking Filter for TIMER C */
#define HRTIM_TIMEEVFLT_BLANKING_TIMCEEF1_TIMACMP2 (HRTIM_EEFR1_EE1FLTR_2 | HRTIM_EEFR1_EE1FLTR_0) /*!< Blanking from another timing unit: TIMFLTR1 source */
#define HRTIM_TIMEEVFLT_BLANKING_TIMCEEF2_TIMBCMP1 (HRTIM_EEFR1_EE1FLTR_2 | HRTIM_EEFR1_EE1FLTR_1) /*!< Blanking from another timing unit: TIMFLTR2 source */
#define HRTIM_TIMEEVFLT_BLANKING_TIMCEEF3_TIMBCMP4 (HRTIM_EEFR1_EE1FLTR_2 | HRTIM_EEFR1_EE1FLTR_1 | HRTIM_EEFR1_EE1FLTR_0) /*!< Blanking from another timing unit: TIMFLTR3 source */
#define HRTIM_TIMEEVFLT_BLANKING_TIMCEEF4_TIMFCMP1 (HRTIM_EEFR1_EE1FLTR_3) /*!< Blanking from another timing unit: TIMFLTR4 source */
#define HRTIM_TIMEEVFLT_BLANKING_TIMCEEF5_TIMDCMP1 (HRTIM_EEFR1_EE1FLTR_3 | HRTIM_EEFR1_EE1FLTR_0) /*!< Blanking from another timing unit: TIMFLTR5 source */
#define HRTIM_TIMEEVFLT_BLANKING_TIMCEEF6_TIMDCMP4 (HRTIM_EEFR1_EE1FLTR_3 | HRTIM_EEFR1_EE1FLTR_1) /*!< Blanking from another timing unit: TIMFLTR6 source */
#define HRTIM_TIMEEVFLT_BLANKING_TIMCEEF7_TIMDOUT2 (HRTIM_EEFR1_EE1FLTR_3 | HRTIM_EEFR1_EE1FLTR_1 | HRTIM_EEFR1_EE1FLTR_0) /*!< Blanking from another timing unit: TIMFLTR7 source */
#define HRTIM_TIMEEVFLT_BLANKING_TIMCEEF8_TIMECMP4 (HRTIM_EEFR1_EE1FLTR_3 | HRTIM_EEFR1_EE1FLTR_2) /*!< Blanking from another timing unit: TIMFLTR8 source */
/* Blanking Filter for TIMER D */
#define HRTIM_TIMEEVFLT_BLANKING_TIMDEEF1_TIMACMP1 (HRTIM_EEFR1_EE1FLTR_2 | HRTIM_EEFR1_EE1FLTR_0) /*!< Blanking from another timing unit: TIMFLTR1 source */
#define HRTIM_TIMEEVFLT_BLANKING_TIMDEEF2_TIMBCMP2 (HRTIM_EEFR1_EE1FLTR_2 | HRTIM_EEFR1_EE1FLTR_1) /*!< Blanking from another timing unit: TIMFLTR2 source */
#define HRTIM_TIMEEVFLT_BLANKING_TIMDEEF3_TIMCCMP1 (HRTIM_EEFR1_EE1FLTR_2 | HRTIM_EEFR1_EE1FLTR_1 | HRTIM_EEFR1_EE1FLTR_0) /*!< Blanking from another timing unit: TIMFLTR3 source */
#define HRTIM_TIMEEVFLT_BLANKING_TIMDEEF4_TIMCCMP2 (HRTIM_EEFR1_EE1FLTR_3) /*!< Blanking from another timing unit: TIMFLTR4 source */
#define HRTIM_TIMEEVFLT_BLANKING_TIMDEEF5_TIMCOUT2 (HRTIM_EEFR1_EE1FLTR_3 | HRTIM_EEFR1_EE1FLTR_0) /*!< Blanking from another timing unit: TIMFLTR5 source */
#define HRTIM_TIMEEVFLT_BLANKING_TIMDEEF6_TIMECMP1 (HRTIM_EEFR1_EE1FLTR_3 | HRTIM_EEFR1_EE1FLTR_1) /*!< Blanking from another timing unit: TIMFLTR6 source */
#define HRTIM_TIMEEVFLT_BLANKING_TIMDEEF7_TIMECMP4 (HRTIM_EEFR1_EE1FLTR_3 | HRTIM_EEFR1_EE1FLTR_1 | HRTIM_EEFR1_EE1FLTR_0) /*!< Blanking from another timing unit: TIMFLTR7 source */
#define HRTIM_TIMEEVFLT_BLANKING_TIMDEEF8_TIMFCMP4 (HRTIM_EEFR1_EE1FLTR_3 | HRTIM_EEFR1_EE1FLTR_2) /*!< Blanking from another timing unit: TIMFLTR8 source */
/* Blanking Filter for TIMER E */
#define HRTIM_TIMEEVFLT_BLANKING_TIMEEEF1_TIMACMP2 (HRTIM_EEFR1_EE1FLTR_2 | HRTIM_EEFR1_EE1FLTR_0) /*!< Blanking from another timing unit: TIMFLTR1 source */
#define HRTIM_TIMEEVFLT_BLANKING_TIMEEEF2_TIMBCMP1 (HRTIM_EEFR1_EE1FLTR_2 | HRTIM_EEFR1_EE1FLTR_1) /*!< Blanking from another timing unit: TIMFLTR2 source */
#define HRTIM_TIMEEVFLT_BLANKING_TIMEEEF3_TIMCCMP1 (HRTIM_EEFR1_EE1FLTR_2 | HRTIM_EEFR1_EE1FLTR_1 | HRTIM_EEFR1_EE1FLTR_0) /*!< Blanking from another timing unit: TIMFLTR3 source */
#define HRTIM_TIMEEVFLT_BLANKING_TIMEEEF4_TIMFCMP4 (HRTIM_EEFR1_EE1FLTR_3) /*!< Blanking from another timing unit: TIMFLTR4 source */
#define HRTIM_TIMEEVFLT_BLANKING_TIMEEEF5_TIMFOUT2 (HRTIM_EEFR1_EE1FLTR_3 | HRTIM_EEFR1_EE1FLTR_0) /*!< Blanking from another timing unit: TIMFLTR5 source */
#define HRTIM_TIMEEVFLT_BLANKING_TIMEEEF6_TIMDCMP1 (HRTIM_EEFR1_EE1FLTR_3 | HRTIM_EEFR1_EE1FLTR_1) /*!< Blanking from another timing unit: TIMFLTR6 source */
#define HRTIM_TIMEEVFLT_BLANKING_TIMEEEF7_TIMDCMP4 (HRTIM_EEFR1_EE1FLTR_3 | HRTIM_EEFR1_EE1FLTR_1 | HRTIM_EEFR1_EE1FLTR_0) /*!< Blanking from another timing unit: TIMFLTR7 source */
#define HRTIM_TIMEEVFLT_BLANKING_TIMEEEF8_TIMDOUT2 (HRTIM_EEFR1_EE1FLTR_3 | HRTIM_EEFR1_EE1FLTR_2) /*!< Blanking from another timing unit: TIMFLTR8 source */
/* Blanking Filter for TIMER F */
#define HRTIM_TIMEEVFLT_BLANKING_TIMFEEF1_TIMACMP4 (HRTIM_EEFR1_EE1FLTR_2 | HRTIM_EEFR1_EE1FLTR_0) /*!< Blanking from another timing unit: TIMFLTR1 source */
#define HRTIM_TIMEEVFLT_BLANKING_TIMFEEF2_TIMBCMP2 (HRTIM_EEFR1_EE1FLTR_2 | HRTIM_EEFR1_EE1FLTR_1) /*!< Blanking from another timing unit: TIMFLTR2 source */
#define HRTIM_TIMEEVFLT_BLANKING_TIMFEEF3_TIMCCMP4 (HRTIM_EEFR1_EE1FLTR_2 | HRTIM_EEFR1_EE1FLTR_1 | HRTIM_EEFR1_EE1FLTR_0) /*!< Blanking from another timing unit: TIMFLTR3 source */
#define HRTIM_TIMEEVFLT_BLANKING_TIMFEEF4_TIMDCMP2 (HRTIM_EEFR1_EE1FLTR_3) /*!< Blanking from another timing unit: TIMFLTR4 source */
#define HRTIM_TIMEEVFLT_BLANKING_TIMFEEF5_TIMDCMP4 (HRTIM_EEFR1_EE1FLTR_3 | HRTIM_EEFR1_EE1FLTR_0) /*!< Blanking from another timing unit: TIMFLTR5 source */
#define HRTIM_TIMEEVFLT_BLANKING_TIMFEEF6_TIMECMP1 (HRTIM_EEFR1_EE1FLTR_3 | HRTIM_EEFR1_EE1FLTR_1) /*!< Blanking from another timing unit: TIMFLTR6 source */
#define HRTIM_TIMEEVFLT_BLANKING_TIMFEEF7_TIMECMP4 (HRTIM_EEFR1_EE1FLTR_3 | HRTIM_EEFR1_EE1FLTR_1 | HRTIM_EEFR1_EE1FLTR_0) /*!< Blanking from another timing unit: TIMFLTR7 source */
#define HRTIM_TIMEEVFLT_BLANKING_TIMFEEF8_TIMEOUT2 (HRTIM_EEFR1_EE1FLTR_3 | HRTIM_EEFR1_EE1FLTR_2) /*!< Blanking from another timing unit: TIMFLTR8 source */
#define HRTIM_TIMEEVFLT_WINDOWINGCMP2 (HRTIM_EEFR1_EE1FLTR_3 | HRTIM_EEFR1_EE1FLTR_2 | HRTIM_EEFR1_EE1FLTR_0) /*!< Windowing from counter reset/roll-over to Compare 2U */
#define HRTIM_TIMEEVFLT_WINDOWINGCMP3 (HRTIM_EEFR1_EE1FLTR_3 | HRTIM_EEFR1_EE1FLTR_2 | HRTIM_EEFR1_EE1FLTR_1) /*!< Windowing from counter reset/roll-over to Compare 3U */
#define HRTIM_TIMEEVFLT_WINDOWINGTIM (HRTIM_EEFR1_EE1FLTR_3 | HRTIM_EEFR1_EE1FLTR_2 | HRTIM_EEFR1_EE1FLTR_1\
| HRTIM_EEFR1_EE1FLTR_0) /*!< Windowing from another timing unit: TIMWIN source */
/**
* @}
*/
/** @defgroup HRTIM_Timer_External_Event_Latch HRTIM Timer External Event Latch
* @{
* @brief Constants defining whether or not the external event is
* memorized (latched) and generated as soon as the blanking period
* is completed or the window ends
*/
#define HRTIM_TIMEVENTLATCH_DISABLED (0x00000000U) /*!< Event is ignored if it happens during a blank, or passed through during a window */
#define HRTIM_TIMEVENTLATCH_ENABLED HRTIM_EEFR1_EE1LTCH /*!< Event is latched and delayed till the end of the blanking or windowing period */
/**
* @}
*/
/** @defgroup HRTIM_Timer_External_Event HRTIM Timer External Event Counter A or B
* @{
* @brief Constants defining the External Event Counter A or B
*/
#define HRTIM_EVENTCOUNTER_A (HRTIM_EEFR3_EEVACE) /*!< External Event Counter A */
#define HRTIM_EVENTCOUNTER_B (HRTIM_EEFR3_EEVBCE) /*!< External Event Counter B */
/**
* @}
*/
/** @defgroup HRTIM_Timer_External_Event_ResetMode HRTIM Timer External Counter Reset Mode
* @{
* @brief Constants enabling the External Event Counter A or B Reset Mode
*/
#define HRTIM_EVENTCOUNTER_RSTMODE_UNCONDITIONAL (0x00000000U) /*!< External Event Counter is reset on each reset / roll-over event */
#define HRTIM_EVENTCOUNTER_RSTMODE_CONDITIONAL (0x00000001U) /*!< External Event Counter is reset on each reset / roll-over event only
if no event occurs during last counting period */
/**
* @}
*/
/** @defgroup HRTIM_Timer_ReSyncUpdate HRTIM Timer Re-Synchronized update
* @{
* @brief Constants defining the update coming condition
*/
#define HRTIM_TIMERESYNC_UPDATE_UNCONDITIONAL (0x00000000U) /*!< update taken into account immediately */
#define HRTIM_TIMERESYNC_UPDATE_CONDITIONAL (0x00000001U) /*!< update taken into account on the following Reset/Roll-over event */
/**
* @}
*/
/** @defgroup HRTIM_Deadtime_Prescaler_Ratio HRTIM Dead-time Prescaler Ratio
* @{
* @brief Constants defining division ratio between the timer clock frequency
* (fHRTIM) and the dead-time generator clock (fDTG)
*/
#define HRTIM_TIMDEADTIME_PRESCALERRATIO_MUL8 (0x00000000U) /*!< fDTG = fHRTIM * 8U */
#define HRTIM_TIMDEADTIME_PRESCALERRATIO_MUL4 (HRTIM_DTR_DTPRSC_0) /*!< fDTG = fHRTIM * 4U */
#define HRTIM_TIMDEADTIME_PRESCALERRATIO_MUL2 (HRTIM_DTR_DTPRSC_1) /*!< fDTG = fHRTIM * 2U */
#define HRTIM_TIMDEADTIME_PRESCALERRATIO_DIV1 (HRTIM_DTR_DTPRSC_1 | HRTIM_DTR_DTPRSC_0) /*!< fDTG = fHRTIM */
#define HRTIM_TIMDEADTIME_PRESCALERRATIO_DIV2 (HRTIM_DTR_DTPRSC_2) /*!< fDTG = fHRTIM / 2U */
#define HRTIM_TIMDEADTIME_PRESCALERRATIO_DIV4 (HRTIM_DTR_DTPRSC_2 | HRTIM_DTR_DTPRSC_0) /*!< fDTG = fHRTIM / 4U */
#define HRTIM_TIMDEADTIME_PRESCALERRATIO_DIV8 (HRTIM_DTR_DTPRSC_2 | HRTIM_DTR_DTPRSC_1) /*!< fDTG = fHRTIM / 8U */
#define HRTIM_TIMDEADTIME_PRESCALERRATIO_DIV16 (HRTIM_DTR_DTPRSC_2 | HRTIM_DTR_DTPRSC_1 | HRTIM_DTR_DTPRSC_0) /*!< fDTG = fHRTIM / 16U */
/**
* @}
*/
/** @defgroup HRTIM_Deadtime_Rising_Sign HRTIM Dead-time Rising Sign
* @{
* @brief Constants defining whether the dead-time is positive or negative
* (overlapping signal) on rising edge
*/
#define HRTIM_TIMDEADTIME_RISINGSIGN_POSITIVE (0x00000000U) /*!< Positive dead-time on rising edge */
#define HRTIM_TIMDEADTIME_RISINGSIGN_NEGATIVE (HRTIM_DTR_SDTR) /*!< Negative dead-time on rising edge */
/**
* @}
*/
/** @defgroup HRTIM_Deadtime_Rising_Lock HRTIM Dead-time Rising Lock
* @{
* @brief Constants defining whether or not the dead-time (rising sign and
* value) is write protected
*/
#define HRTIM_TIMDEADTIME_RISINGLOCK_WRITE (0x00000000U) /*!< Dead-time rising value and sign is writeable */
#define HRTIM_TIMDEADTIME_RISINGLOCK_READONLY (HRTIM_DTR_DTRLK) /*!< Dead-time rising value and sign is read-only */
/**
* @}
*/
/** @defgroup HRTIM_Deadtime_Rising_Sign_Lock HRTIM Dead-time Rising Sign Lock
* @{
* @brief Constants defining whether or not the dead-time rising sign is write
* protected
*/
#define HRTIM_TIMDEADTIME_RISINGSIGNLOCK_WRITE (0x00000000U) /*!< Dead-time rising sign is writeable */
#define HRTIM_TIMDEADTIME_RISINGSIGNLOCK_READONLY (HRTIM_DTR_DTRSLK) /*!< Dead-time rising sign is read-only */
/**
* @}
*/
/** @defgroup HRTIM_Deadtime_Falling_Sign HRTIM Dead-time Falling Sign
* @{
* @brief Constants defining whether the dead-time is positive or negative
* (overlapping signal) on falling edge
*/
#define HRTIM_TIMDEADTIME_FALLINGSIGN_POSITIVE (0x00000000U) /*!< Positive dead-time on falling edge */
#define HRTIM_TIMDEADTIME_FALLINGSIGN_NEGATIVE (HRTIM_DTR_SDTF) /*!< Negative dead-time on falling edge */
/**
* @}
*/
/** @defgroup HRTIM_Deadtime_Falling_Lock HRTIM Dead-time Falling Lock
* @{
* @brief Constants defining whether or not the dead-time (falling sign and
* value) is write protected
*/
#define HRTIM_TIMDEADTIME_FALLINGLOCK_WRITE (0x00000000U) /*!< Dead-time falling value and sign is writeable */
#define HRTIM_TIMDEADTIME_FALLINGLOCK_READONLY (HRTIM_DTR_DTFLK) /*!< Dead-time falling value and sign is read-only */
/**
* @}
*/
/** @defgroup HRTIM_Deadtime_Falling_Sign_Lock HRTIM Dead-time Falling Sign Lock
* @{
* @brief Constants defining whether or not the dead-time falling sign is write
* protected
*/
#define HRTIM_TIMDEADTIME_FALLINGSIGNLOCK_WRITE (0x00000000U) /*!< Dead-time falling sign is writeable */
#define HRTIM_TIMDEADTIME_FALLINGSIGNLOCK_READONLY (HRTIM_DTR_DTFSLK) /*!< Dead-time falling sign is read-only */
/**
* @}
*/
/** @defgroup HRTIM_Chopper_Frequency HRTIM Chopper Frequency
* @{
* @brief Constants defining the frequency of the generated high frequency carrier
*/
#define HRTIM_CHOPPER_PRESCALERRATIO_DIV16 (0x000000U) /*!< fCHPFRQ = fHRTIM / 16 */
#define HRTIM_CHOPPER_PRESCALERRATIO_DIV32 (HRTIM_CHPR_CARFRQ_0) /*!< fCHPFRQ = fHRTIM / 32 */
#define HRTIM_CHOPPER_PRESCALERRATIO_DIV48 (HRTIM_CHPR_CARFRQ_1) /*!< fCHPFRQ = fHRTIM / 48 */
#define HRTIM_CHOPPER_PRESCALERRATIO_DIV64 (HRTIM_CHPR_CARFRQ_1 | HRTIM_CHPR_CARFRQ_0) /*!< fCHPFRQ = fHRTIM / 64 */
#define HRTIM_CHOPPER_PRESCALERRATIO_DIV80 (HRTIM_CHPR_CARFRQ_2) /*!< fCHPFRQ = fHRTIM / 80 */
#define HRTIM_CHOPPER_PRESCALERRATIO_DIV96 (HRTIM_CHPR_CARFRQ_2 | HRTIM_CHPR_CARFRQ_0) /*!< fCHPFRQ = fHRTIM / 96 */
#define HRTIM_CHOPPER_PRESCALERRATIO_DIV112 (HRTIM_CHPR_CARFRQ_2 | HRTIM_CHPR_CARFRQ_1) /*!< fCHPFRQ = fHRTIM / 112 */
#define HRTIM_CHOPPER_PRESCALERRATIO_DIV128 (HRTIM_CHPR_CARFRQ_2 | HRTIM_CHPR_CARFRQ_1 | HRTIM_CHPR_CARFRQ_0) /*!< fCHPFRQ = fHRTIM / 128 */
#define HRTIM_CHOPPER_PRESCALERRATIO_DIV144 (HRTIM_CHPR_CARFRQ_3) /*!< fCHPFRQ = fHRTIM / 144 */
#define HRTIM_CHOPPER_PRESCALERRATIO_DIV160 (HRTIM_CHPR_CARFRQ_3 | HRTIM_CHPR_CARFRQ_0) /*!< fCHPFRQ = fHRTIM / 160 */
#define HRTIM_CHOPPER_PRESCALERRATIO_DIV176 (HRTIM_CHPR_CARFRQ_3 | HRTIM_CHPR_CARFRQ_1) /*!< fCHPFRQ = fHRTIM / 176 */
#define HRTIM_CHOPPER_PRESCALERRATIO_DIV192 (HRTIM_CHPR_CARFRQ_3 | HRTIM_CHPR_CARFRQ_1 | HRTIM_CHPR_CARFRQ_0) /*!< fCHPFRQ = fHRTIM / 192 */
#define HRTIM_CHOPPER_PRESCALERRATIO_DIV208 (HRTIM_CHPR_CARFRQ_3 | HRTIM_CHPR_CARFRQ_2) /*!< fCHPFRQ = fHRTIM / 208 */
#define HRTIM_CHOPPER_PRESCALERRATIO_DIV224 (HRTIM_CHPR_CARFRQ_3 | HRTIM_CHPR_CARFRQ_2 | HRTIM_CHPR_CARFRQ_0) /*!< fCHPFRQ = fHRTIM / 224 */
#define HRTIM_CHOPPER_PRESCALERRATIO_DIV240 (HRTIM_CHPR_CARFRQ_3 | HRTIM_CHPR_CARFRQ_2 | HRTIM_CHPR_CARFRQ_1) /*!< fCHPFRQ = fHRTIM / 240 */
#define HRTIM_CHOPPER_PRESCALERRATIO_DIV256 (HRTIM_CHPR_CARFRQ_3 | HRTIM_CHPR_CARFRQ_2 | HRTIM_CHPR_CARFRQ_1 | HRTIM_CHPR_CARFRQ_0) /*!< fCHPFRQ = fHRTIM / 256 */
/**
* @}
*/
/** @defgroup HRTIM_Chopper_Duty_Cycle HRTIM Chopper Duty Cycle
* @{
* @brief Constants defining the duty cycle of the generated high frequency carrier
* Duty cycle can be adjusted by 1/8 step (from 0/8 up to 7/8)
*/
#define HRTIM_CHOPPER_DUTYCYCLE_0 (0x000000U) /*!< Only 1st pulse is present */
#define HRTIM_CHOPPER_DUTYCYCLE_125 (HRTIM_CHPR_CARDTY_0) /*!< Duty cycle of the carrier signal is 12.5U % */
#define HRTIM_CHOPPER_DUTYCYCLE_250 (HRTIM_CHPR_CARDTY_1) /*!< Duty cycle of the carrier signal is 25U % */
#define HRTIM_CHOPPER_DUTYCYCLE_375 (HRTIM_CHPR_CARDTY_1 | HRTIM_CHPR_CARDTY_0) /*!< Duty cycle of the carrier signal is 37.5U % */
#define HRTIM_CHOPPER_DUTYCYCLE_500 (HRTIM_CHPR_CARDTY_2) /*!< Duty cycle of the carrier signal is 50U % */
#define HRTIM_CHOPPER_DUTYCYCLE_625 (HRTIM_CHPR_CARDTY_2 | HRTIM_CHPR_CARDTY_0) /*!< Duty cycle of the carrier signal is 62.5U % */
#define HRTIM_CHOPPER_DUTYCYCLE_750 (HRTIM_CHPR_CARDTY_2 | HRTIM_CHPR_CARDTY_1) /*!< Duty cycle of the carrier signal is 75U % */
#define HRTIM_CHOPPER_DUTYCYCLE_875 (HRTIM_CHPR_CARDTY_2 | HRTIM_CHPR_CARDTY_1 | HRTIM_CHPR_CARDTY_0) /*!< Duty cycle of the carrier signal is 87.5U % */
/**
* @}
*/
/** @defgroup HRTIM_Chopper_Start_Pulse_Width HRTIM Chopper Start Pulse Width
* @{
* @brief Constants defining the pulse width of the first pulse of the generated
* high frequency carrier
*/
#define HRTIM_CHOPPER_PULSEWIDTH_16 (0x000000U) /*!< tSTPW = tHRTIM x 16 */
#define HRTIM_CHOPPER_PULSEWIDTH_32 (HRTIM_CHPR_STRPW_0) /*!< tSTPW = tHRTIM x 32 */
#define HRTIM_CHOPPER_PULSEWIDTH_48 (HRTIM_CHPR_STRPW_1) /*!< tSTPW = tHRTIM x 48 */
#define HRTIM_CHOPPER_PULSEWIDTH_64 (HRTIM_CHPR_STRPW_1 | HRTIM_CHPR_STRPW_0) /*!< tSTPW = tHRTIM x 64 */
#define HRTIM_CHOPPER_PULSEWIDTH_80 (HRTIM_CHPR_STRPW_2) /*!< tSTPW = tHRTIM x 80 */
#define HRTIM_CHOPPER_PULSEWIDTH_96 (HRTIM_CHPR_STRPW_2 | HRTIM_CHPR_STRPW_0) /*!< tSTPW = tHRTIM x 96 */
#define HRTIM_CHOPPER_PULSEWIDTH_112 (HRTIM_CHPR_STRPW_2 | HRTIM_CHPR_STRPW_1) /*!< tSTPW = tHRTIM x 112 */
#define HRTIM_CHOPPER_PULSEWIDTH_128 (HRTIM_CHPR_STRPW_2 | HRTIM_CHPR_STRPW_1 | HRTIM_CHPR_STRPW_0) /*!< tSTPW = tHRTIM x 128 */
#define HRTIM_CHOPPER_PULSEWIDTH_144 (HRTIM_CHPR_STRPW_3) /*!< tSTPW = tHRTIM x 144 */
#define HRTIM_CHOPPER_PULSEWIDTH_160 (HRTIM_CHPR_STRPW_3 | HRTIM_CHPR_STRPW_0) /*!< tSTPW = tHRTIM x 160 */
#define HRTIM_CHOPPER_PULSEWIDTH_176 (HRTIM_CHPR_STRPW_3 | HRTIM_CHPR_STRPW_1) /*!< tSTPW = tHRTIM x 176 */
#define HRTIM_CHOPPER_PULSEWIDTH_192 (HRTIM_CHPR_STRPW_3 | HRTIM_CHPR_STRPW_1 | HRTIM_CHPR_STRPW_0) /*!< tSTPW = tHRTIM x 192 */
#define HRTIM_CHOPPER_PULSEWIDTH_208 (HRTIM_CHPR_STRPW_3 | HRTIM_CHPR_STRPW_2) /*!< tSTPW = tHRTIM x 208 */
#define HRTIM_CHOPPER_PULSEWIDTH_224 (HRTIM_CHPR_STRPW_3 | HRTIM_CHPR_STRPW_2 | HRTIM_CHPR_STRPW_0) /*!< tSTPW = tHRTIM x 224 */
#define HRTIM_CHOPPER_PULSEWIDTH_240 (HRTIM_CHPR_STRPW_3 | HRTIM_CHPR_STRPW_2 | HRTIM_CHPR_STRPW_1) /*!< tSTPW = tHRTIM x 240 */
#define HRTIM_CHOPPER_PULSEWIDTH_256 (HRTIM_CHPR_STRPW_3 | HRTIM_CHPR_STRPW_2 | HRTIM_CHPR_STRPW_1 | HRTIM_CHPR_STRPW_0) /*!< tSTPW = tHRTIM x 256 */
/**
* @}
*/
/** @defgroup HRTIM_Synchronization_Options HRTIM Synchronization Options
* @{
* @brief Constants defining the options for synchronizing multiple HRTIM
* instances, as a master unit (generating a synchronization signal)
* or as a slave (waiting for a trigger to be synchronized)
*/
#define HRTIM_SYNCOPTION_NONE 0x00000000U /*!< HRTIM instance doesn't handle external synchronization signals (SYNCIN, SYNCOUT) */
#define HRTIM_SYNCOPTION_MASTER 0x00000001U /*!< HRTIM instance acts as a MASTER, i.e. generates external synchronization output (SYNCOUT)*/
#define HRTIM_SYNCOPTION_SLAVE 0x00000002U /*!< HRTIM instance acts as a SLAVE, i.e. it is synchronized by external sources (SYNCIN) */
/**
* @}
*/
/** @defgroup HRTIM_Synchronization_Input_Source HRTIM Synchronization Input Source
* @{
* @brief Constants defining defining the synchronization input source
*/
#define HRTIM_SYNCINPUTSOURCE_NONE 0x00000000U /*!< disabled. HRTIM is not synchronized and runs in standalone mode */
#define HRTIM_SYNCINPUTSOURCE_INTERNALEVENT HRTIM_MCR_SYNC_IN_1 /*!< The HRTIM is synchronized with the on-chip timer */
#define HRTIM_SYNCINPUTSOURCE_EXTERNALEVENT (HRTIM_MCR_SYNC_IN_1 | HRTIM_MCR_SYNC_IN_0) /*!< A positive pulse on SYNCIN input triggers the HRTIM */
/**
* @}
*/
/** @defgroup HRTIM_Synchronization_Output_Source HRTIM Synchronization Output Source
* @{
* @brief Constants defining the source and event to be sent on the
* synchronization outputs
*/
#define HRTIM_SYNCOUTPUTSOURCE_MASTER_START 0x00000000U /*!< A pulse is sent on HRTIM_SCOUT output and hrtim_out_sync2 upon master timer start event */
#define HRTIM_SYNCOUTPUTSOURCE_MASTER_CMP1 (HRTIM_MCR_SYNC_SRC_0) /*!< A pulse is sent on HRTIM_SCOUT output and hrtim_out_sync2 upon master timer compare 1 event */
#define HRTIM_SYNCOUTPUTSOURCE_TIMA_START (HRTIM_MCR_SYNC_SRC_1) /*!< A pulse is sent on HRTIM_SCOUT output and hrtim_out_sync2 upon timer A start or reset events */
#define HRTIM_SYNCOUTPUTSOURCE_TIMA_CMP1 (HRTIM_MCR_SYNC_SRC_1 | HRTIM_MCR_SYNC_SRC_0) /*!< A pulse is sent on HRTIM_SCOUT output and hrtim_out_sync2 upon timer A compare 1 event */
/**
* @}
*/
/** @defgroup HRTIM_Synchronization_Output_Polarity HRTIM Synchronization Output Polarity
* @{
* @brief Constants defining the routing and conditioning of the synchronization output event
*/
#define HRTIM_SYNCOUTPUTPOLARITY_NONE 0x00000000U /*!< Synchronization output event is disabled */
#define HRTIM_SYNCOUTPUTPOLARITY_POSITIVE (HRTIM_MCR_SYNC_OUT_1) /*!< SCOUT pin has a low idle level and issues a positive pulse of 16 fHRTIM clock cycles length for the synchronization */
#define HRTIM_SYNCOUTPUTPOLARITY_NEGATIVE (HRTIM_MCR_SYNC_OUT_1 | HRTIM_MCR_SYNC_OUT_0) /*!< SCOUT pin has a high idle level and issues a negative pulse of 16 fHRTIM clock cycles length for the synchronization */
/**
* @}
*/
/** @defgroup HRTIM_External_Event_Sources HRTIM External Event Sources
* @{
* @brief Constants defining available sources associated to external events
*/
#define HRTIM_EEV1SRC_GPIO 0x00000000U /*!< External event source 1U for External Event 1 */
#define HRTIM_EEV2SRC_GPIO 0x00000000U /*!< External event source 1U for External Event 2 */
#define HRTIM_EEV3SRC_GPIO 0x00000000U /*!< External event source 1U for External Event 3 */
#define HRTIM_EEV4SRC_GPIO 0x00000000U /*!< External event source 1U for External Event 4 */
#define HRTIM_EEV5SRC_GPIO 0x00000000U /*!< External event source 1U for External Event 5 */
#define HRTIM_EEV6SRC_GPIO 0x00000000U /*!< External event source 1U for External Event 6 */
#define HRTIM_EEV7SRC_GPIO 0x00000000U /*!< External event source 1U for External Event 7 */
#define HRTIM_EEV8SRC_GPIO 0x00000000U /*!< External event source 1U for External Event 8 */
#define HRTIM_EEV9SRC_GPIO 0x00000000U /*!< External event source 1U for External Event 9 */
#define HRTIM_EEV10SRC_GPIO 0x00000000U /*!< External event source 1U for External Event 10 */
#define HRTIM_EEV1SRC_COMP2_OUT (HRTIM_EECR1_EE1SRC_0) /*!< External event source 2U for External Event 1 */
#define HRTIM_EEV2SRC_COMP4_OUT (HRTIM_EECR1_EE1SRC_0) /*!< External event source 2U for External Event 2 */
#define HRTIM_EEV3SRC_COMP6_OUT (HRTIM_EECR1_EE1SRC_0) /*!< External event source 2U for External Event 3 */
#define HRTIM_EEV4SRC_COMP1_OUT (HRTIM_EECR1_EE1SRC_0) /*!< External event source 2U for External Event 4 */
#define HRTIM_EEV5SRC_COMP3_OUT (HRTIM_EECR1_EE1SRC_0) /*!< External event source 2U for External Event 5 */
#define HRTIM_EEV6SRC_COMP2_OUT (HRTIM_EECR1_EE1SRC_0) /*!< External event source 2U for External Event 6 */
#define HRTIM_EEV7SRC_COMP4_OUT (HRTIM_EECR1_EE1SRC_0) /*!< External event source 2U for External Event 7 */
#define HRTIM_EEV8SRC_COMP6_OUT (HRTIM_EECR1_EE1SRC_0) /*!< External event source 2U for External Event 8 */
#define HRTIM_EEV9SRC_COMP5_OUT (HRTIM_EECR1_EE1SRC_0) /*!< External event source 2U for External Event 9 */
#define HRTIM_EEV10SRC_COMP7_OUT (HRTIM_EECR1_EE1SRC_0) /*!< External event source 2U for External Event 10 */
#define HRTIM_EEV1SRC_TIM1_TRGO (HRTIM_EECR1_EE1SRC_1) /*!< External event source 3U for External Event 1 */
#define HRTIM_EEV2SRC_TIM2_TRGO (HRTIM_EECR1_EE1SRC_1) /*!< External event source 3U for External Event 2 */
#define HRTIM_EEV3SRC_TIM3_TRGO (HRTIM_EECR1_EE1SRC_1) /*!< External event source 3U for External Event 3 */
#define HRTIM_EEV4SRC_COMP5_OUT (HRTIM_EECR1_EE1SRC_1) /*!< External event source 3U for External Event 4 */
#define HRTIM_EEV5SRC_COMP7_OUT (HRTIM_EECR1_EE1SRC_1) /*!< External event source 3U for External Event 5 */
#define HRTIM_EEV6SRC_COMP1_OUT (HRTIM_EECR1_EE1SRC_1) /*!< External event source 3U for External Event 6 */
#define HRTIM_EEV7SRC_TIM7_TRGO (HRTIM_EECR1_EE1SRC_1) /*!< External event source 3U for External Event 7 */
#define HRTIM_EEV8SRC_COMP3_OUT (HRTIM_EECR1_EE1SRC_1) /*!< External event source 3U for External Event 8 */
#define HRTIM_EEV9SRC_TIM15_TRGO (HRTIM_EECR1_EE1SRC_1) /*!< External event source 3U for External Event 9 */
#define HRTIM_EEV10SRC_TIM6_TRGO (HRTIM_EECR1_EE1SRC_1) /*!< External event source 3U for External Event 10 */
#define HRTIM_EEV1SRC_ADC1_AWD1 (HRTIM_EECR1_EE1SRC_1 | HRTIM_EECR1_EE1SRC_0) /*!< External event source 4U for External Event 1 */
#define HRTIM_EEV2SRC_ADC1_AWD2 (HRTIM_EECR1_EE1SRC_1 | HRTIM_EECR1_EE1SRC_0) /*!< External event source 4U for External Event 2 */
#define HRTIM_EEV3SRC_ADC1_AWD3 (HRTIM_EECR1_EE1SRC_1 | HRTIM_EECR1_EE1SRC_0) /*!< External event source 4U for External Event 3 */
#define HRTIM_EEV4SRC_ADC2_AWD1 (HRTIM_EECR1_EE1SRC_1 | HRTIM_EECR1_EE1SRC_0) /*!< External event source 4U for External Event 4 */
#define HRTIM_EEV5SRC_ADC2_AWD2 (HRTIM_EECR1_EE1SRC_1 | HRTIM_EECR1_EE1SRC_0) /*!< External event source 4U for External Event 5 */
#define HRTIM_EEV6SRC_ADC2_AWD3 (HRTIM_EECR1_EE1SRC_1 | HRTIM_EECR1_EE1SRC_0) /*!< External event source 4U for External Event 6 */
#define HRTIM_EEV7SRC_ADC3_AWD1 (HRTIM_EECR1_EE1SRC_1 | HRTIM_EECR1_EE1SRC_0) /*!< External event source 4U for External Event 7 */
#define HRTIM_EEV8SRC_ADC4_AWD1 (HRTIM_EECR1_EE1SRC_1 | HRTIM_EECR1_EE1SRC_0) /*!< External event source 4U for External Event 8 */
#define HRTIM_EEV9SRC_COMP4_OUT (HRTIM_EECR1_EE1SRC_1 | HRTIM_EECR1_EE1SRC_0) /*!< External event source 4U for External Event 9 */
#define HRTIM_EEV10SRC_ADC5_AWD1 (HRTIM_EECR1_EE1SRC_1 | HRTIM_EECR1_EE1SRC_0) /*!< External event source 4U for External Event 10 */
/**
* @}
*/
/** @defgroup HRTIM_External_Event_Polarity HRTIM External Event Polarity
* @{
* @brief Constants defining the polarity of an external event
*/
#define HRTIM_EVENTPOLARITY_HIGH (0x00000000U) /*!< External event is active high */
#define HRTIM_EVENTPOLARITY_LOW (HRTIM_EECR1_EE1POL) /*!< External event is active low */
/**
* @}
*/
/** @defgroup HRTIM_External_Event_Sensitivity HRTIM External Event Sensitivity
* @{
* @brief Constants defining the sensitivity (level-sensitive or edge-sensitive)
* of an external event
*/
#define HRTIM_EVENTSENSITIVITY_LEVEL (0x00000000U) /*!< External event is active on level */
#define HRTIM_EVENTSENSITIVITY_RISINGEDGE (HRTIM_EECR1_EE1SNS_0) /*!< External event is active on Rising edge */
#define HRTIM_EVENTSENSITIVITY_FALLINGEDGE (HRTIM_EECR1_EE1SNS_1) /*!< External event is active on Falling edge */
#define HRTIM_EVENTSENSITIVITY_BOTHEDGES (HRTIM_EECR1_EE1SNS_1 | HRTIM_EECR1_EE1SNS_0) /*!< External event is active on Rising and Falling edges */
/**
* @}
*/
/** @defgroup HRTIM_External_Event_Fast_Mode HRTIM External Event Fast Mode
* @{
* @brief Constants defining whether or not an external event is programmed in
fast mode
*/
#define HRTIM_EVENTFASTMODE_DISABLE (0x00000000U) /*!< External Event is re-synchronized by the HRTIM logic before acting on outputs */
#define HRTIM_EVENTFASTMODE_ENABLE (HRTIM_EECR1_EE1FAST) /*!< External Event is acting asynchronously on outputs (low latency mode) */
/**
* @}
*/
/** @defgroup HRTIM_External_Event_Filter HRTIM External Event Filter
* @{
* @brief Constants defining the frequency used to sample an external event 6
* input and the length (N) of the digital filter applied
*/
#define HRTIM_EVENTFILTER_NONE (0x00000000U) /*!< Filter disabled */
#define HRTIM_EVENTFILTER_1 (HRTIM_EECR3_EE6F_0) /*!< fSAMPLING= fHRTIM, N=2U */
#define HRTIM_EVENTFILTER_2 (HRTIM_EECR3_EE6F_1) /*!< fSAMPLING= fHRTIM, N=4U */
#define HRTIM_EVENTFILTER_3 (HRTIM_EECR3_EE6F_1 | HRTIM_EECR3_EE6F_0) /*!< fSAMPLING= fHRTIM, N=8U */
#define HRTIM_EVENTFILTER_4 (HRTIM_EECR3_EE6F_2) /*!< fSAMPLING= fEEVS/2U, N=6U */
#define HRTIM_EVENTFILTER_5 (HRTIM_EECR3_EE6F_2 | HRTIM_EECR3_EE6F_0) /*!< fSAMPLING= fEEVS/2U, N=8U */
#define HRTIM_EVENTFILTER_6 (HRTIM_EECR3_EE6F_2 | HRTIM_EECR3_EE6F_1) /*!< fSAMPLING= fEEVS/4U, N=6U */
#define HRTIM_EVENTFILTER_7 (HRTIM_EECR3_EE6F_2 | HRTIM_EECR3_EE6F_1 | HRTIM_EECR3_EE6F_0) /*!< fSAMPLING= fEEVS/4U, N=8U */
#define HRTIM_EVENTFILTER_8 (HRTIM_EECR3_EE6F_3) /*!< fSAMPLING= fEEVS/8U, N=6U */
#define HRTIM_EVENTFILTER_9 (HRTIM_EECR3_EE6F_3 | HRTIM_EECR3_EE6F_0) /*!< fSAMPLING= fEEVS/8U, N=8U */
#define HRTIM_EVENTFILTER_10 (HRTIM_EECR3_EE6F_3 | HRTIM_EECR3_EE6F_1) /*!< fSAMPLING= fEEVS/16U, N=5U */
#define HRTIM_EVENTFILTER_11 (HRTIM_EECR3_EE6F_3 | HRTIM_EECR3_EE6F_1 | HRTIM_EECR3_EE6F_0) /*!< fSAMPLING= fEEVS/16U, N=6U */
#define HRTIM_EVENTFILTER_12 (HRTIM_EECR3_EE6F_3 | HRTIM_EECR3_EE6F_2) /*!< fSAMPLING= fEEVS/16U, N=8U */
#define HRTIM_EVENTFILTER_13 (HRTIM_EECR3_EE6F_3 | HRTIM_EECR3_EE6F_2 | HRTIM_EECR3_EE6F_0) /*!< fSAMPLING= fEEVS/32U, N=5U */
#define HRTIM_EVENTFILTER_14 (HRTIM_EECR3_EE6F_3 | HRTIM_EECR3_EE6F_2 | HRTIM_EECR3_EE6F_1) /*!< fSAMPLING= fEEVS/32U, N=6U */
#define HRTIM_EVENTFILTER_15 (HRTIM_EECR3_EE6F_3 | HRTIM_EECR3_EE6F_2 | HRTIM_EECR3_EE6F_1 | HRTIM_EECR3_EE6F_0) /*!< fSAMPLING= fEEVS/32U, N=8U */
/**
* @}
*/
/** @defgroup HRTIM_External_Event_Prescaler HRTIM External Event Prescaler
* @{
* @brief Constants defining division ratio between the timer clock frequency
* fHRTIM) and the external event signal sampling clock (fEEVS)
* used by the digital filters
*/
#define HRTIM_EVENTPRESCALER_DIV1 (0x00000000U) /*!< fEEVS=fHRTIM */
#define HRTIM_EVENTPRESCALER_DIV2 (HRTIM_EECR3_EEVSD_0) /*!< fEEVS=fHRTIM / 2U */
#define HRTIM_EVENTPRESCALER_DIV4 (HRTIM_EECR3_EEVSD_1) /*!< fEEVS=fHRTIM / 4U */
#define HRTIM_EVENTPRESCALER_DIV8 (HRTIM_EECR3_EEVSD_1 | HRTIM_EECR3_EEVSD_0) /*!< fEEVS=fHRTIM / 8U */
/**
* @}
*/
/** @defgroup HRTIM_Fault_Sources HRTIM Fault Sources
* @{
* @brief Constants defining whether a fault is triggered by any external
* or internal fault source
*/
#define HRTIM_FAULTSOURCE_DIGITALINPUT (0x00000000U) /*!< Fault input is FLT input pin */
#define HRTIM_FAULTSOURCE_INTERNAL (0x00000001U) /*!< Fault input is FLT_Int signal (e.g. internal comparator) */
#define HRTIM_FAULTSOURCE_EEVINPUT (0x00000002U) /*!< Fault input is EEV pin */
/**
* @}
*/
/** @defgroup HRTIM_Fault_Polarity HRTIM Fault Polarity
* @{
* @brief Constants defining the polarity of a fault event
*/
#define HRTIM_FAULTPOLARITY_LOW (0x00000000U) /*!< Fault input is active low */
#define HRTIM_FAULTPOLARITY_HIGH (HRTIM_FLTINR1_FLT1P) /*!< Fault input is active high */
/**
* @}
*/
/** @defgroup HRTIM_Fault_Blanking HRTIM Fault Blanking Source
* @{
* @brief Constants defining the blanking source of a fault event
*/
#define HRTIM_FAULTBLANKINGMODE_RSTALIGNED (0x00000000U) /*!< Fault blanking source is Reset-aligned window */
#define HRTIM_FAULTBLANKINGMODE_MOVING (0x00000001U) /*!< Fault blanking source is Moving window */
/**
* @}
*/
/** @defgroup HRTIM_Fault_ResetMode HRTIM Fault Reset Mode
* @{
* @brief Constants defining the Counter reset mode of a fault event
*/
#define HRTIM_FAULTCOUNTERRST_UNCONDITIONAL (0x00000000U) /*!< Fault counter is reset on each reset / roll-over event */
#define HRTIM_FAULTCOUNTERRST_CONDITIONAL (0x00000001U) /*!< Fault counter is reset on each reset / roll-over event only if no fault occurred during last countingperiod.*/
/**
* @}
*/
/** @defgroup HRTIM_Fault_Blanking_Control HRTIM Fault Blanking Control
* @{
* @brief Constants used to enable or disable the blanking mode of a fault channel
*/
#define HRTIM_FAULTBLANKINGCTL_DISABLED 0x00000000U /*!< No blanking on Fault */
#define HRTIM_FAULTBLANKINGCTL_ENABLED 0x00000001U /*!< Fault blanking mode */
/**
* @}
*/
/** @defgroup HRTIM_Fault_Filter HRTIM Fault Filter
* @{
* @ brief Constants defining the frequency used to sample the fault input and
* the length (N) of the digital filter applied
*/
#define HRTIM_FAULTFILTER_NONE (0x00000000U) /*!< Filter disabled */
#define HRTIM_FAULTFILTER_1 (HRTIM_FLTINR1_FLT1F_0) /*!< fSAMPLING= fHRTIM, N=2U */
#define HRTIM_FAULTFILTER_2 (HRTIM_FLTINR1_FLT1F_1) /*!< fSAMPLING= fHRTIM, N=4U */
#define HRTIM_FAULTFILTER_3 (HRTIM_FLTINR1_FLT1F_1 | HRTIM_FLTINR1_FLT1F_0) /*!< fSAMPLING= fHRTIM, N=8U */
#define HRTIM_FAULTFILTER_4 (HRTIM_FLTINR1_FLT1F_2) /*!< fSAMPLING= fFLTS/2U, N=6U */
#define HRTIM_FAULTFILTER_5 (HRTIM_FLTINR1_FLT1F_2 | HRTIM_FLTINR1_FLT1F_0) /*!< fSAMPLING= fFLTS/2U, N=8U */
#define HRTIM_FAULTFILTER_6 (HRTIM_FLTINR1_FLT1F_2 | HRTIM_FLTINR1_FLT1F_1) /*!< fSAMPLING= fFLTS/4U, N=6U */
#define HRTIM_FAULTFILTER_7 (HRTIM_FLTINR1_FLT1F_2 | HRTIM_FLTINR1_FLT1F_1 | HRTIM_FLTINR1_FLT1F_0) /*!< fSAMPLING= fFLTS/4U, N=8U */
#define HRTIM_FAULTFILTER_8 (HRTIM_FLTINR1_FLT1F_3) /*!< fSAMPLING= fFLTS/8U, N=6U */
#define HRTIM_FAULTFILTER_9 (HRTIM_FLTINR1_FLT1F_3 | HRTIM_FLTINR1_FLT1F_0) /*!< fSAMPLING= fFLTS/8U, N=8U */
#define HRTIM_FAULTFILTER_10 (HRTIM_FLTINR1_FLT1F_3 | HRTIM_FLTINR1_FLT1F_1) /*!< fSAMPLING= fFLTS/16U, N=5U */
#define HRTIM_FAULTFILTER_11 (HRTIM_FLTINR1_FLT1F_3 | HRTIM_FLTINR1_FLT1F_1 | HRTIM_FLTINR1_FLT1F_0) /*!< fSAMPLING= fFLTS/16U, N=6U */
#define HRTIM_FAULTFILTER_12 (HRTIM_FLTINR1_FLT1F_3 | HRTIM_FLTINR1_FLT1F_2) /*!< fSAMPLING= fFLTS/16U, N=8U */
#define HRTIM_FAULTFILTER_13 (HRTIM_FLTINR1_FLT1F_3 | HRTIM_FLTINR1_FLT1F_2 | HRTIM_FLTINR1_FLT1F_0) /*!< fSAMPLING= fFLTS/32U, N=5U */
#define HRTIM_FAULTFILTER_14 (HRTIM_FLTINR1_FLT1F_3 | HRTIM_FLTINR1_FLT1F_2 | HRTIM_FLTINR1_FLT1F_1) /*!< fSAMPLING= fFLTS/32U, N=6U */
#define HRTIM_FAULTFILTER_15 (HRTIM_FLTINR1_FLT1F_3 | HRTIM_FLTINR1_FLT1F_2 | HRTIM_FLTINR1_FLT1F_1 | HRTIM_FLTINR1_FLT1F_0) /*!< fSAMPLING= fFLTS/32U, N=8U */
/**
* @}
*/
/** @defgroup HRTIM_Fault_Counter HRTIM Fault counter threshold value
* @{
* @ brief Constants defining the FAULT Counter threshold
*/
#define HRTIM_FAULTCOUNTER_NONE ((uint32_t)0U ) /*!< Counter threshold = 0U */
#define HRTIM_FAULTCOUNTER_1 ((uint32_t)1U ) /*!< Counter threshold = 1U */
#define HRTIM_FAULTCOUNTER_2 ((uint32_t)2U ) /*!< Counter threshold = 2U */
#define HRTIM_FAULTCOUNTER_3 ((uint32_t)3U ) /*!< Counter threshold = 3U */
#define HRTIM_FAULTCOUNTER_4 ((uint32_t)4U ) /*!< Counter threshold = 4U */
#define HRTIM_FAULTCOUNTER_5 ((uint32_t)5U ) /*!< Counter threshold = 5U */
#define HRTIM_FAULTCOUNTER_6 ((uint32_t)6U ) /*!< Counter threshold = 6U */
#define HRTIM_FAULTCOUNTER_7 ((uint32_t)7U ) /*!< Counter threshold = 7U */
#define HRTIM_FAULTCOUNTER_8 ((uint32_t)8U ) /*!< Counter threshold = 8U */
#define HRTIM_FAULTCOUNTER_9 ((uint32_t)9U ) /*!< Counter threshold = 9U */
#define HRTIM_FAULTCOUNTER_10 ((uint32_t)10U) /*!< Counter threshold = 10U */
#define HRTIM_FAULTCOUNTER_11 ((uint32_t)11U) /*!< Counter threshold = 11U */
#define HRTIM_FAULTCOUNTER_12 ((uint32_t)12U) /*!< Counter threshold = 12U */
#define HRTIM_FAULTCOUNTER_13 ((uint32_t)13U) /*!< Counter threshold = 13U */
#define HRTIM_FAULTCOUNTER_14 ((uint32_t)14U) /*!< Counter threshold = 14U */
#define HRTIM_FAULTCOUNTER_15 ((uint32_t)15U) /*!< Counter threshold = 15U */
/**
* @}
*/
/** @defgroup HRTIM_Fault_Lock HRTIM Fault Lock
* @{
* @brief Constants defining whether or not the fault programming bits are
write protected
*/
#define HRTIM_FAULTLOCK_READWRITE (0x00000000U) /*!< Fault settings bits are read/write */
#define HRTIM_FAULTLOCK_READONLY (HRTIM_FLTINR1_FLT1LCK) /*!< Fault settings bits are read only */
/**
* @}
*/
/** @defgroup HRTIM_External_Fault_Prescaler HRTIM External Fault Prescaler
* @{
* @brief Constants defining the division ratio between the timer clock
* frequency (fHRTIM) and the fault signal sampling clock (fFLTS) used
* by the digital filters.
*/
#define HRTIM_FAULTPRESCALER_DIV1 (0x00000000U) /*!< fFLTS=fHRTIM */
#define HRTIM_FAULTPRESCALER_DIV2 (HRTIM_FLTINR2_FLTSD_0) /*!< fFLTS=fHRTIM / 2U */
#define HRTIM_FAULTPRESCALER_DIV4 (HRTIM_FLTINR2_FLTSD_1) /*!< fFLTS=fHRTIM / 4U */
#define HRTIM_FAULTPRESCALER_DIV8 (HRTIM_FLTINR2_FLTSD_1 | HRTIM_FLTINR2_FLTSD_0) /*!< fFLTS=fHRTIM / 8U */
/**
* @}
*/
/** @defgroup HRTIM_Burst_Mode_Operating_Mode HRTIM Burst Mode Operating Mode
* @{
* @brief Constants defining if the burst mode is entered once or if it is
* continuously operating
*/
#define HRTIM_BURSTMODE_SINGLESHOT (0x00000000U) /*!< Burst mode operates in single shot mode */
#define HRTIM_BURSTMODE_CONTINOUS (HRTIM_BMCR_BMOM) /*!< Burst mode operates in continuous mode */
/**
* @}
*/
/** @defgroup HRTIM_Burst_Mode_Clock_Source HRTIM Burst Mode Clock Source
* @{
* @brief Constants defining the clock source for the burst mode counter
*/
#define HRTIM_BURSTMODECLOCKSOURCE_MASTER (0x00000000U) /*!< Master timer counter reset/roll-over is used as clock source for the burst mode counter */
#define HRTIM_BURSTMODECLOCKSOURCE_TIMER_A (HRTIM_BMCR_BMCLK_0) /*!< Timer A counter reset/roll-over is used as clock source for the burst mode counter */
#define HRTIM_BURSTMODECLOCKSOURCE_TIMER_B (HRTIM_BMCR_BMCLK_1) /*!< Timer B counter reset/roll-over is used as clock source for the burst mode counter */
#define HRTIM_BURSTMODECLOCKSOURCE_TIMER_C (HRTIM_BMCR_BMCLK_1 | HRTIM_BMCR_BMCLK_0) /*!< Timer C counter reset/roll-over is used as clock source for the burst mode counter */
#define HRTIM_BURSTMODECLOCKSOURCE_TIMER_D (HRTIM_BMCR_BMCLK_2) /*!< Timer D counter reset/roll-over is used as clock source for the burst mode counter */
#define HRTIM_BURSTMODECLOCKSOURCE_TIMER_E (HRTIM_BMCR_BMCLK_2 | HRTIM_BMCR_BMCLK_0) /*!< Timer E counter reset/roll-over is used as clock source for the burst mode counter */
#define HRTIM_BURSTMODECLOCKSOURCE_TIMER_F (HRTIM_BMCR_BMCLK_2 | HRTIM_BMCR_BMCLK_0) /*!< Timer F counter reset/roll-over is used as clock source for the burst mode counter */
#define HRTIM_BURSTMODECLOCKSOURCE_TIM16_OC (HRTIM_BMCR_BMCLK_2 | HRTIM_BMCR_BMCLK_1) /*!< On-chip Event 1 (BMClk[1]), acting as a burst mode counter clock */
#define HRTIM_BURSTMODECLOCKSOURCE_TIM17_OC (HRTIM_BMCR_BMCLK_2 | HRTIM_BMCR_BMCLK_1 | HRTIM_BMCR_BMCLK_0) /*!< On-chip Event 2 (BMClk[2]), acting as a burst mode counter clock */
#define HRTIM_BURSTMODECLOCKSOURCE_TIM7_TRGO (HRTIM_BMCR_BMCLK_3) /*!< On-chip Event 3 (BMClk[3]), acting as a burst mode counter clock */
#define HRTIM_BURSTMODECLOCKSOURCE_FHRTIM (HRTIM_BMCR_BMCLK_3 | HRTIM_BMCR_BMCLK_1) /*!< Prescaled fHRTIM clock is used as clock source for the burst mode counter */
/**
* @}
*/
/** @defgroup HRTIM_Burst_Mode_Prescaler HRTIM Burst Mode Prescaler
* @{
* @brief Constants defining the prescaling ratio of the fHRTIM clock
* for the burst mode controller
*/
#define HRTIM_BURSTMODEPRESCALER_DIV1 (0x00000000U) /*!< fBRST = fHRTIM */
#define HRTIM_BURSTMODEPRESCALER_DIV2 (HRTIM_BMCR_BMPRSC_0) /*!< fBRST = fHRTIM/2U */
#define HRTIM_BURSTMODEPRESCALER_DIV4 (HRTIM_BMCR_BMPRSC_1) /*!< fBRST = fHRTIM/4U */
#define HRTIM_BURSTMODEPRESCALER_DIV8 (HRTIM_BMCR_BMPRSC_1 | HRTIM_BMCR_BMPRSC_0) /*!< fBRST = fHRTIM/8U */
#define HRTIM_BURSTMODEPRESCALER_DIV16 (HRTIM_BMCR_BMPRSC_2) /*!< fBRST = fHRTIM/16U */
#define HRTIM_BURSTMODEPRESCALER_DIV32 (HRTIM_BMCR_BMPRSC_2 | HRTIM_BMCR_BMPRSC_0) /*!< fBRST = fHRTIM/32U */
#define HRTIM_BURSTMODEPRESCALER_DIV64 (HRTIM_BMCR_BMPRSC_2 | HRTIM_BMCR_BMPRSC_1) /*!< fBRST = fHRTIM/64U */
#define HRTIM_BURSTMODEPRESCALER_DIV128 (HRTIM_BMCR_BMPRSC_2 | HRTIM_BMCR_BMPRSC_1 | HRTIM_BMCR_BMPRSC_0) /*!< fBRST = fHRTIM/128U */
#define HRTIM_BURSTMODEPRESCALER_DIV256 (HRTIM_BMCR_BMPRSC_3) /*!< fBRST = fHRTIM/256U */
#define HRTIM_BURSTMODEPRESCALER_DIV512 (HRTIM_BMCR_BMPRSC_3 | HRTIM_BMCR_BMPRSC_0) /*!< fBRST = fHRTIM/512U */
#define HRTIM_BURSTMODEPRESCALER_DIV1024 (HRTIM_BMCR_BMPRSC_3 | HRTIM_BMCR_BMPRSC_1) /*!< fBRST = fHRTIM/1024U */
#define HRTIM_BURSTMODEPRESCALER_DIV2048 (HRTIM_BMCR_BMPRSC_3 | HRTIM_BMCR_BMPRSC_1 | HRTIM_BMCR_BMPRSC_0) /*!< fBRST = fHRTIM/2048U*/
#define HRTIM_BURSTMODEPRESCALER_DIV4096 (HRTIM_BMCR_BMPRSC_3 | HRTIM_BMCR_BMPRSC_2) /*!< fBRST = fHRTIM/4096U */
#define HRTIM_BURSTMODEPRESCALER_DIV8192 (HRTIM_BMCR_BMPRSC_3 | HRTIM_BMCR_BMPRSC_2 | HRTIM_BMCR_BMPRSC_0) /*!< fBRST = fHRTIM/8192U */
#define HRTIM_BURSTMODEPRESCALER_DIV16384 (HRTIM_BMCR_BMPRSC_3 | HRTIM_BMCR_BMPRSC_2 | HRTIM_BMCR_BMPRSC_1) /*!< fBRST = fHRTIM/16384U */
#define HRTIM_BURSTMODEPRESCALER_DIV32768 (HRTIM_BMCR_BMPRSC_3 | HRTIM_BMCR_BMPRSC_2 | HRTIM_BMCR_BMPRSC_1 | HRTIM_BMCR_BMPRSC_0) /*!< fBRST = fHRTIM/32768U */
/**
* @}
*/
/** @defgroup HRTIM_Burst_Mode_Register_Preload_Enable HRTIM Burst Mode Register Preload Enable
* @{
* @brief Constants defining whether or not burst mode registers preload
mechanism is enabled, i.e. a write access into a preloadable register
(HRTIM_BMCMPR, HRTIM_BMPER) is done into the active or the preload register
*/
#define HRIM_BURSTMODEPRELOAD_DISABLED (0x00000000U) /*!< Preload disabled: the write access is directly done into active registers */
#define HRIM_BURSTMODEPRELOAD_ENABLED (HRTIM_BMCR_BMPREN) /*!< Preload enabled: the write access is done into preload registers */
/**
* @}
*/
/** @defgroup HRTIM_Burst_Mode_Trigger HRTIM Burst Mode Trigger
* @{
* @brief Constants defining the events that can be used to trig the burst
* mode operation
*/
#define HRTIM_BURSTMODETRIGGER_NONE 0x00000000U /*!< No trigger */
#define HRTIM_BURSTMODETRIGGER_MASTER_RESET (HRTIM_BMTRGR_MSTRST) /*!< Master reset */
#define HRTIM_BURSTMODETRIGGER_MASTER_REPETITION (HRTIM_BMTRGR_MSTREP) /*!< Master repetition */
#define HRTIM_BURSTMODETRIGGER_MASTER_CMP1 (HRTIM_BMTRGR_MSTCMP1) /*!< Master compare 1U */
#define HRTIM_BURSTMODETRIGGER_MASTER_CMP2 (HRTIM_BMTRGR_MSTCMP2) /*!< Master compare 2U */
#define HRTIM_BURSTMODETRIGGER_MASTER_CMP3 (HRTIM_BMTRGR_MSTCMP3) /*!< Master compare 3U */
#define HRTIM_BURSTMODETRIGGER_MASTER_CMP4 (HRTIM_BMTRGR_MSTCMP4) /*!< Master compare 4U */
#define HRTIM_BURSTMODETRIGGER_TIMERA_RESET (HRTIM_BMTRGR_TARST) /*!< Timer A reset */
#define HRTIM_BURSTMODETRIGGER_TIMERA_REPETITION (HRTIM_BMTRGR_TAREP) /*!< Timer A repetition */
#define HRTIM_BURSTMODETRIGGER_TIMERA_CMP1 (HRTIM_BMTRGR_TACMP1) /*!< Timer A compare 1 */
#define HRTIM_BURSTMODETRIGGER_TIMERA_CMP2 (HRTIM_BMTRGR_TACMP2) /*!< Timer A compare 2 */
#define HRTIM_BURSTMODETRIGGER_TIMERB_RESET (HRTIM_BMTRGR_TBRST) /*!< Timer B reset */
#define HRTIM_BURSTMODETRIGGER_TIMERB_REPETITION (HRTIM_BMTRGR_TBREP) /*!< Timer B repetition */
#define HRTIM_BURSTMODETRIGGER_TIMERB_CMP1 (HRTIM_BMTRGR_TBCMP1) /*!< Timer B compare 1 */
#define HRTIM_BURSTMODETRIGGER_TIMERB_CMP2 (HRTIM_BMTRGR_TBCMP2) /*!< Timer B compare 2 */
#define HRTIM_BURSTMODETRIGGER_TIMERC_RESET (HRTIM_BMTRGR_TCRST) /*!< Timer C reset */
#define HRTIM_BURSTMODETRIGGER_TIMERC_REPETITION (HRTIM_BMTRGR_TCREP) /*!< Timer C repetition */
#define HRTIM_BURSTMODETRIGGER_TIMERC_CMP1 (HRTIM_BMTRGR_TCCMP1) /*!< Timer C compare 1 */
#define HRTIM_BURSTMODETRIGGER_TIMERF_RESET (HRTIM_BMTRGR_TFRST) /*!< Timer F reset */
#define HRTIM_BURSTMODETRIGGER_TIMERD_RESET (HRTIM_BMTRGR_TDRST) /*!< Timer D reset */
#define HRTIM_BURSTMODETRIGGER_TIMERD_REPETITION (HRTIM_BMTRGR_TDREP) /*!< Timer D repetition */
#define HRTIM_BURSTMODETRIGGER_TIMERF_REPETITION (HRTIM_BMTRGR_TFREP) /*!< Timer F repetition */
#define HRTIM_BURSTMODETRIGGER_TIMERD_CMP2 (HRTIM_BMTRGR_TDCMP2) /*!< Timer D compare 2 */
#define HRTIM_BURSTMODETRIGGER_TIMERF_CMP1 (HRTIM_BMTRGR_TFCMP1) /*!< Timer F compare 1 */
#define HRTIM_BURSTMODETRIGGER_TIMERE_REPETITION (HRTIM_BMTRGR_TEREP) /*!< Timer E repetition */
#define HRTIM_BURSTMODETRIGGER_TIMERE_CMP1 (HRTIM_BMTRGR_TECMP1) /*!< Timer E compare 1 */
#define HRTIM_BURSTMODETRIGGER_TIMERE_CMP2 (HRTIM_BMTRGR_TECMP2) /*!< Timer E compare 2 */
#define HRTIM_BURSTMODETRIGGER_TIMERA_EVENT7 (HRTIM_BMTRGR_TAEEV7) /*!< Timer A period following External Event 7 */
#define HRTIM_BURSTMODETRIGGER_TIMERD_EVENT8 (HRTIM_BMTRGR_TDEEV8) /*!< Timer D period following External Event 8 */
#define HRTIM_BURSTMODETRIGGER_EVENT_7 (HRTIM_BMTRGR_EEV7) /*!< External Event 7 (timer A filters applied) */
#define HRTIM_BURSTMODETRIGGER_EVENT_8 (HRTIM_BMTRGR_EEV8) /*!< External Event 8 (timer D filters applied)*/
#define HRTIM_BURSTMODETRIGGER_EVENT_ONCHIP (HRTIM_BMTRGR_OCHPEV) /*!< On-chip Event */
/**
* @}
*/
/** @defgroup HRTIM_ADC_Trigger_Update_Source HRTIM ADC Trigger Update Source
* @{
* @brief constants defining the source triggering the update of the
HRTIM_ADCxR register (transfer from preload to active register).
*/
#define HRTIM_ADCTRIGGERUPDATE_MASTER 0x00000000U /*!< Master timer */
#define HRTIM_ADCTRIGGERUPDATE_TIMER_A (HRTIM_CR1_ADC1USRC_0) /*!< Timer A */
#define HRTIM_ADCTRIGGERUPDATE_TIMER_B (HRTIM_CR1_ADC1USRC_1) /*!< Timer B */
#define HRTIM_ADCTRIGGERUPDATE_TIMER_C (HRTIM_CR1_ADC1USRC_1 | HRTIM_CR1_ADC1USRC_0) /*!< Timer C */
#define HRTIM_ADCTRIGGERUPDATE_TIMER_D (HRTIM_CR1_ADC1USRC_2) /*!< Timer D */
#define HRTIM_ADCTRIGGERUPDATE_TIMER_E (HRTIM_CR1_ADC1USRC_2 | HRTIM_CR1_ADC1USRC_0) /*!< Timer E */
#define HRTIM_ADCTRIGGERUPDATE_TIMER_F (HRTIM_CR1_ADC1USRC_2 | HRTIM_CR1_ADC1USRC_1) /*!< Timer F */
/**
* @}
*/
/** @defgroup HRTIM_ADC_Trigger_Event HRTIM ADC Trigger Event
* @{
* @brief constants defining the events triggering ADC conversion.
* HRTIM_ADCTRIGGEREVENT13_*: ADC Triggers 1 and 3
* HRTIM_ADCTRIGGEREVENT24_*: ADC Triggers 2 and 4
* HRTIM_ADCTRIGGEREVENT579_*: ADC Triggers 5 and 7 and 9
* HRTIM_ADCTRIGGEREVENT6810_*: ADC Triggers 6 and 8 and 10
*/
#define HRTIM_ADCTRIGGEREVENT13_NONE 0x00000000U /*!< No ADC trigger event */
#define HRTIM_ADCTRIGGEREVENT13_MASTER_CMP1 (HRTIM_ADC1R_AD1MC1) /*!< ADC Trigger on master compare 1U */
#define HRTIM_ADCTRIGGEREVENT13_MASTER_CMP2 (HRTIM_ADC1R_AD1MC2) /*!< ADC Trigger on master compare 2U */
#define HRTIM_ADCTRIGGEREVENT13_MASTER_CMP3 (HRTIM_ADC1R_AD1MC3) /*!< ADC Trigger on master compare 3U */
#define HRTIM_ADCTRIGGEREVENT13_MASTER_CMP4 (HRTIM_ADC1R_AD1MC4) /*!< ADC Trigger on master compare 4U */
#define HRTIM_ADCTRIGGEREVENT13_MASTER_PERIOD (HRTIM_ADC1R_AD1MPER) /*!< ADC Trigger on master period */
#define HRTIM_ADCTRIGGEREVENT13_EVENT_1 (HRTIM_ADC1R_AD1EEV1) /*!< ADC Trigger on external event 1U */
#define HRTIM_ADCTRIGGEREVENT13_EVENT_2 (HRTIM_ADC1R_AD1EEV2) /*!< ADC Trigger on external event 2U */
#define HRTIM_ADCTRIGGEREVENT13_EVENT_3 (HRTIM_ADC1R_AD1EEV3) /*!< ADC Trigger on external event 3U */
#define HRTIM_ADCTRIGGEREVENT13_EVENT_4 (HRTIM_ADC1R_AD1EEV4) /*!< ADC Trigger on external event 4U */
#define HRTIM_ADCTRIGGEREVENT13_EVENT_5 (HRTIM_ADC1R_AD1EEV5) /*!< ADC Trigger on external event 5U */
#define HRTIM_ADCTRIGGEREVENT13_TIMERF_CMP2 (HRTIM_ADC1R_AD1TFC2) /*!< ADC Trigger on Timer F compare 2U */
#define HRTIM_ADCTRIGGEREVENT13_TIMERA_CMP3 (HRTIM_ADC1R_AD1TAC3) /*!< ADC Trigger on Timer A compare 3U */
#define HRTIM_ADCTRIGGEREVENT13_TIMERA_CMP4 (HRTIM_ADC1R_AD1TAC4) /*!< ADC Trigger on Timer A compare 4U */
#define HRTIM_ADCTRIGGEREVENT13_TIMERA_PERIOD (HRTIM_ADC1R_AD1TAPER) /*!< ADC Trigger on Timer A period */
#define HRTIM_ADCTRIGGEREVENT13_TIMERA_RESET (HRTIM_ADC1R_AD1TARST) /*!< ADC Trigger on Timer A reset */
#define HRTIM_ADCTRIGGEREVENT13_TIMERF_CMP3 (HRTIM_ADC1R_AD1TFC3) /*!< ADC Trigger on Timer F compare 3U */
#define HRTIM_ADCTRIGGEREVENT13_TIMERB_CMP3 (HRTIM_ADC1R_AD1TBC3) /*!< ADC Trigger on Timer B compare 3U */
#define HRTIM_ADCTRIGGEREVENT13_TIMERB_CMP4 (HRTIM_ADC1R_AD1TBC4) /*!< ADC Trigger on Timer B compare 4U */
#define HRTIM_ADCTRIGGEREVENT13_TIMERB_PERIOD (HRTIM_ADC1R_AD1TBPER) /*!< ADC Trigger on Timer B period */
#define HRTIM_ADCTRIGGEREVENT13_TIMERB_RESET (HRTIM_ADC1R_AD1TBRST) /*!< ADC Trigger on Timer B reset */
#define HRTIM_ADCTRIGGEREVENT13_TIMERF_CMP4 (HRTIM_ADC1R_AD1TFC4) /*!< ADC Trigger on Timer F compare 4U */
#define HRTIM_ADCTRIGGEREVENT13_TIMERC_CMP3 (HRTIM_ADC1R_AD1TCC3) /*!< ADC Trigger on Timer C compare 3U */
#define HRTIM_ADCTRIGGEREVENT13_TIMERC_CMP4 (HRTIM_ADC1R_AD1TCC4) /*!< ADC Trigger on Timer C compare 4U */
#define HRTIM_ADCTRIGGEREVENT13_TIMERC_PERIOD (HRTIM_ADC1R_AD1TCPER) /*!< ADC Trigger on Timer C period */
#define HRTIM_ADCTRIGGEREVENT13_TIMERF_PERIOD (HRTIM_ADC1R_AD1TFPER) /*!< ADC Trigger on Timer F period */
#define HRTIM_ADCTRIGGEREVENT13_TIMERD_CMP3 (HRTIM_ADC1R_AD1TDC3) /*!< ADC Trigger on Timer D compare 3U */
#define HRTIM_ADCTRIGGEREVENT13_TIMERD_CMP4 (HRTIM_ADC1R_AD1TDC4) /*!< ADC Trigger on Timer D compare 4U */
#define HRTIM_ADCTRIGGEREVENT13_TIMERD_PERIOD (HRTIM_ADC1R_AD1TDPER) /*!< ADC Trigger on Timer D period */
#define HRTIM_ADCTRIGGEREVENT13_TIMERF_RESET (HRTIM_ADC1R_AD1TFRST) /*!< ADC Trigger on Timer F reset */
#define HRTIM_ADCTRIGGEREVENT13_TIMERE_CMP3 (HRTIM_ADC1R_AD1TEC3) /*!< ADC Trigger on Timer E compare 3U */
#define HRTIM_ADCTRIGGEREVENT13_TIMERE_CMP4 (HRTIM_ADC1R_AD1TEC4) /*!< ADC Trigger on Timer E compare 4U */
#define HRTIM_ADCTRIGGEREVENT13_TIMERE_PERIOD (HRTIM_ADC1R_AD1TEPER) /*!< ADC Trigger on Timer E period */
#define HRTIM_ADCTRIGGEREVENT24_NONE 0x00000000U /*!< No ADC trigger event */
#define HRTIM_ADCTRIGGEREVENT24_MASTER_CMP1 (HRTIM_ADC2R_AD2MC1) /*!< ADC Trigger on master compare 1U */
#define HRTIM_ADCTRIGGEREVENT24_MASTER_CMP2 (HRTIM_ADC2R_AD2MC2) /*!< ADC Trigger on master compare 2U */
#define HRTIM_ADCTRIGGEREVENT24_MASTER_CMP3 (HRTIM_ADC2R_AD2MC3) /*!< ADC Trigger on master compare 3U */
#define HRTIM_ADCTRIGGEREVENT24_MASTER_CMP4 (HRTIM_ADC2R_AD2MC4) /*!< ADC Trigger on master compare 4U */
#define HRTIM_ADCTRIGGEREVENT24_MASTER_PERIOD (HRTIM_ADC2R_AD2MPER) /*!< ADC Trigger on master period */
#define HRTIM_ADCTRIGGEREVENT24_EVENT_6 (HRTIM_ADC2R_AD2EEV6) /*!< ADC Trigger on external event 6U */
#define HRTIM_ADCTRIGGEREVENT24_EVENT_7 (HRTIM_ADC2R_AD2EEV7) /*!< ADC Trigger on external event 7U */
#define HRTIM_ADCTRIGGEREVENT24_EVENT_8 (HRTIM_ADC2R_AD2EEV8) /*!< ADC Trigger on external event 8U */
#define HRTIM_ADCTRIGGEREVENT24_EVENT_9 (HRTIM_ADC2R_AD2EEV9) /*!< ADC Trigger on external event 9U */
#define HRTIM_ADCTRIGGEREVENT24_EVENT_10 (HRTIM_ADC2R_AD2EEV10) /*!< ADC Trigger on external event 10U */
#define HRTIM_ADCTRIGGEREVENT24_TIMERA_CMP2 (HRTIM_ADC2R_AD2TAC2) /*!< ADC Trigger on Timer A compare 2U */
#define HRTIM_ADCTRIGGEREVENT24_TIMERF_CMP2 (HRTIM_ADC2R_AD2TFC2) /*!< ADC Trigger on Timer F compare 2U */
#define HRTIM_ADCTRIGGEREVENT24_TIMERA_CMP4 (HRTIM_ADC2R_AD2TAC4) /*!< ADC Trigger on Timer A compare 4U */
#define HRTIM_ADCTRIGGEREVENT24_TIMERA_PERIOD (HRTIM_ADC2R_AD2TAPER) /*!< ADC Trigger on Timer A period */
#define HRTIM_ADCTRIGGEREVENT24_TIMERB_CMP2 (HRTIM_ADC2R_AD2TBC2) /*!< ADC Trigger on Timer B compare 2U */
#define HRTIM_ADCTRIGGEREVENT24_TIMERF_CMP3 (HRTIM_ADC2R_AD2TFC3) /*!< ADC Trigger on Timer F compare 3U */
#define HRTIM_ADCTRIGGEREVENT24_TIMERB_CMP4 (HRTIM_ADC2R_AD2TBC4) /*!< ADC Trigger on Timer B compare 4U */
#define HRTIM_ADCTRIGGEREVENT24_TIMERB_PERIOD (HRTIM_ADC2R_AD2TBPER) /*!< ADC Trigger on Timer B period */
#define HRTIM_ADCTRIGGEREVENT24_TIMERC_CMP2 (HRTIM_ADC2R_AD2TCC2) /*!< ADC Trigger on Timer C compare 2U */
#define HRTIM_ADCTRIGGEREVENT24_TIMERF_CMP4 (HRTIM_ADC2R_AD2TFC4) /*!< ADC Trigger on Timer F compare 4U */
#define HRTIM_ADCTRIGGEREVENT24_TIMERC_CMP4 (HRTIM_ADC2R_AD2TCC4) /*!< ADC Trigger on Timer C compare 4U */
#define HRTIM_ADCTRIGGEREVENT24_TIMERC_PERIOD (HRTIM_ADC2R_AD2TCPER) /*!< ADC Trigger on Timer C period */
#define HRTIM_ADCTRIGGEREVENT24_TIMERC_RESET (HRTIM_ADC2R_AD2TCRST) /*!< ADC Trigger on Timer C reset */
#define HRTIM_ADCTRIGGEREVENT24_TIMERD_CMP2 (HRTIM_ADC2R_AD2TDC2) /*!< ADC Trigger on Timer D compare 2U */
#define HRTIM_ADCTRIGGEREVENT24_TIMERF_PERIOD (HRTIM_ADC2R_AD2TFPER) /*!< ADC Trigger on Timer F period */
#define HRTIM_ADCTRIGGEREVENT24_TIMERD_CMP4 (HRTIM_ADC2R_AD2TDC4) /*!< ADC Trigger on Timer D compare 4U */
#define HRTIM_ADCTRIGGEREVENT24_TIMERD_PERIOD (HRTIM_ADC2R_AD2TDPER) /*!< ADC Trigger on Timer D period */
#define HRTIM_ADCTRIGGEREVENT24_TIMERD_RESET (HRTIM_ADC2R_AD2TDRST) /*!< ADC Trigger on Timer D reset */
#define HRTIM_ADCTRIGGEREVENT24_TIMERE_CMP2 (HRTIM_ADC2R_AD2TEC2) /*!< ADC Trigger on Timer E compare 2U */
#define HRTIM_ADCTRIGGEREVENT24_TIMERE_CMP3 (HRTIM_ADC2R_AD2TEC3) /*!< ADC Trigger on Timer E compare 3U */
#define HRTIM_ADCTRIGGEREVENT24_TIMERE_CMP4 (HRTIM_ADC2R_AD2TEC4) /*!< ADC Trigger on Timer E compare 4U */
#define HRTIM_ADCTRIGGEREVENT24_TIMERE_RESET (HRTIM_ADC2R_AD2TERST) /*!< ADC Trigger on Timer E reset */
#define HRTIM_ADCTRIGGEREVENT6810_MASTER_CMP1 ((uint32_t)0x00U) /*!< ADC Trigger on master compare 1U */
#define HRTIM_ADCTRIGGEREVENT6810_MASTER_CMP2 ((uint32_t)0x01U) /*!< ADC Trigger on master compare 2U */
#define HRTIM_ADCTRIGGEREVENT6810_MASTER_CMP3 ((uint32_t)0x02U) /*!< ADC Trigger on master compare 3U */
#define HRTIM_ADCTRIGGEREVENT6810_MASTER_CMP4 ((uint32_t)0x03U) /*!< ADC Trigger on master compare 4U */
#define HRTIM_ADCTRIGGEREVENT6810_MASTER_PERIOD ((uint32_t)0x04U) /*!< ADC Trigger on master period */
#define HRTIM_ADCTRIGGEREVENT6810_EVENT_6 ((uint32_t)0x05U) /*!< ADC Trigger on external event 6U */
#define HRTIM_ADCTRIGGEREVENT6810_EVENT_7 ((uint32_t)0x06U) /*!< ADC Trigger on external event 7U */
#define HRTIM_ADCTRIGGEREVENT6810_EVENT_8 ((uint32_t)0x07U) /*!< ADC Trigger on external event 8U */
#define HRTIM_ADCTRIGGEREVENT6810_EVENT_9 ((uint32_t)0x08U) /*!< ADC Trigger on external event 9U */
#define HRTIM_ADCTRIGGEREVENT6810_EVENT_10 ((uint32_t)0x09U) /*!< ADC Trigger on external event 10U */
#define HRTIM_ADCTRIGGEREVENT6810_TIMERA_CMP2 ((uint32_t)0x0AU) /*!< ADC Trigger on Timer A compare 2U */
#define HRTIM_ADCTRIGGEREVENT6810_TIMERA_CMP4 ((uint32_t)0x0BU) /*!< ADC Trigger on Timer A compare 4U */
#define HRTIM_ADCTRIGGEREVENT6810_TIMERA_PERIOD ((uint32_t)0x0CU) /*!< ADC Trigger on Timer A period */
#define HRTIM_ADCTRIGGEREVENT6810_TIMERB_CMP2 ((uint32_t)0x0DU) /*!< ADC Trigger on Timer B compare 2U */
#define HRTIM_ADCTRIGGEREVENT6810_TIMERB_CMP4 ((uint32_t)0x0EU) /*!< ADC Trigger on Timer B compare 4U */
#define HRTIM_ADCTRIGGEREVENT6810_TIMERB_PERIOD ((uint32_t)0x0FU) /*!< ADC Trigger on Timer B period */
#define HRTIM_ADCTRIGGEREVENT6810_TIMERC_CMP2 ((uint32_t)0x10U) /*!< ADC Trigger on Timer C compare 2U */
#define HRTIM_ADCTRIGGEREVENT6810_TIMERC_CMP4 ((uint32_t)0x11U) /*!< ADC Trigger on Timer C compare 4U */
#define HRTIM_ADCTRIGGEREVENT6810_TIMERC_PERIOD ((uint32_t)0x12U) /*!< ADC Trigger on Timer C period */
#define HRTIM_ADCTRIGGEREVENT6810_TIMERC_RESET ((uint32_t)0x13U) /*!< ADC Trigger on Timer C reset */
#define HRTIM_ADCTRIGGEREVENT6810_TIMERD_CMP2 ((uint32_t)0x14U) /*!< ADC Trigger on Timer D compare 2U */
#define HRTIM_ADCTRIGGEREVENT6810_TIMERD_CMP4 ((uint32_t)0x15U) /*!< ADC Trigger on Timer D compare 4U */
#define HRTIM_ADCTRIGGEREVENT6810_TIMERD_PERIOD ((uint32_t)0x16U) /*!< ADC Trigger on Timer D period */
#define HRTIM_ADCTRIGGEREVENT6810_TIMERD_RESET ((uint32_t)0x17U) /*!< ADC Trigger on Timer D reset */
#define HRTIM_ADCTRIGGEREVENT6810_TIMERE_CMP2 ((uint32_t)0x18U) /*!< ADC Trigger on Timer E compare 2U */
#define HRTIM_ADCTRIGGEREVENT6810_TIMERE_CMP3 ((uint32_t)0x19U) /*!< ADC Trigger on Timer E compare 3U */
#define HRTIM_ADCTRIGGEREVENT6810_TIMERE_CMP4 ((uint32_t)0x1AU) /*!< ADC Trigger on Timer E compare 4U */
#define HRTIM_ADCTRIGGEREVENT6810_TIMERE_RESET ((uint32_t)0x1BU) /*!< ADC Trigger on Timer E reset */
#define HRTIM_ADCTRIGGEREVENT6810_TIMERF_CMP2 ((uint32_t)0x1CU) /*!< ADC Trigger on Timer F compare 2U */
#define HRTIM_ADCTRIGGEREVENT6810_TIMERF_CMP3 ((uint32_t)0x1DU) /*!< ADC Trigger on Timer F compare 3U */
#define HRTIM_ADCTRIGGEREVENT6810_TIMERF_CMP4 ((uint32_t)0x1EU) /*!< ADC Trigger on Timer F compare 4U */
#define HRTIM_ADCTRIGGEREVENT6810_TIMERF_PERIOD ((uint32_t)0x1FU) /*!< ADC Trigger on Timer F period */
#define HRTIM_ADCTRIGGEREVENT579_MASTER_CMP1 ((uint32_t)0x00U) /*!< ADC Trigger on master compare 1U */
#define HRTIM_ADCTRIGGEREVENT579_MASTER_CMP2 ((uint32_t)0x01U) /*!< ADC Trigger on master compare 2U */
#define HRTIM_ADCTRIGGEREVENT579_MASTER_CMP3 ((uint32_t)0x02U) /*!< ADC Trigger on master compare 3U */
#define HRTIM_ADCTRIGGEREVENT579_MASTER_CMP4 ((uint32_t)0x03U) /*!< ADC Trigger on master compare 4U */
#define HRTIM_ADCTRIGGEREVENT579_MASTER_PERIOD ((uint32_t)0x04U) /*!< ADC Trigger on master period */
#define HRTIM_ADCTRIGGEREVENT579_EVENT_1 ((uint32_t)0x05U) /*!< ADC Trigger on external event 1U */
#define HRTIM_ADCTRIGGEREVENT579_EVENT_2 ((uint32_t)0x06U) /*!< ADC Trigger on external event 2U */
#define HRTIM_ADCTRIGGEREVENT579_EVENT_3 ((uint32_t)0x07U) /*!< ADC Trigger on external event 3U */
#define HRTIM_ADCTRIGGEREVENT579_EVENT_4 ((uint32_t)0x08U) /*!< ADC Trigger on external event 4U */
#define HRTIM_ADCTRIGGEREVENT579_EVENT_5 ((uint32_t)0x09U) /*!< ADC Trigger on external event 5U */
#define HRTIM_ADCTRIGGEREVENT579_TIMERA_CMP3 ((uint32_t)0x0AU) /*!< ADC Trigger on Timer A compare 3U */
#define HRTIM_ADCTRIGGEREVENT579_TIMERA_CMP4 ((uint32_t)0x0BU) /*!< ADC Trigger on Timer A compare 4U */
#define HRTIM_ADCTRIGGEREVENT579_TIMERA_PERIOD ((uint32_t)0x0CU) /*!< ADC Trigger on Timer A period */
#define HRTIM_ADCTRIGGEREVENT579_TIMERA_RESET ((uint32_t)0x0DU) /*!< ADC Trigger on Timer A reset */
#define HRTIM_ADCTRIGGEREVENT579_TIMERB_CMP3 ((uint32_t)0x0EU) /*!< ADC Trigger on Timer B compare 3U */
#define HRTIM_ADCTRIGGEREVENT579_TIMERB_CMP4 ((uint32_t)0x0FU) /*!< ADC Trigger on Timer B compare 4U */
#define HRTIM_ADCTRIGGEREVENT579_TIMERB_PERIOD ((uint32_t)0x10U) /*!< ADC Trigger on Timer B period */
#define HRTIM_ADCTRIGGEREVENT579_TIMERB_RESET ((uint32_t)0x11U) /*!< ADC Trigger on Timer B reset */
#define HRTIM_ADCTRIGGEREVENT579_TIMERC_CMP3 ((uint32_t)0x12U) /*!< ADC Trigger on Timer C compare 3U */
#define HRTIM_ADCTRIGGEREVENT579_TIMERC_CMP4 ((uint32_t)0x13U) /*!< ADC Trigger on Timer C compare 4U */
#define HRTIM_ADCTRIGGEREVENT579_TIMERC_PERIOD ((uint32_t)0x14U) /*!< ADC Trigger on Timer C period */
#define HRTIM_ADCTRIGGEREVENT579_TIMERD_CMP3 ((uint32_t)0x15U) /*!< ADC Trigger on Timer D compare 3U */
#define HRTIM_ADCTRIGGEREVENT579_TIMERD_CMP4 ((uint32_t)0x16U) /*!< ADC Trigger on Timer D compare 4U */
#define HRTIM_ADCTRIGGEREVENT579_TIMERD_PERIOD ((uint32_t)0x17U) /*!< ADC Trigger on Timer D period */
#define HRTIM_ADCTRIGGEREVENT579_TIMERE_CMP3 ((uint32_t)0x18U) /*!< ADC Trigger on Timer E compare 3U */
#define HRTIM_ADCTRIGGEREVENT579_TIMERE_CMP4 ((uint32_t)0x19U) /*!< ADC Trigger on Timer E compare 4U */
#define HRTIM_ADCTRIGGEREVENT579_TIMERE_PERIOD ((uint32_t)0x1AU) /*!< ADC Trigger on Timer E period */
#define HRTIM_ADCTRIGGEREVENT579_TIMERF_CMP2 ((uint32_t)0x1BU) /*!< ADC Trigger on Timer F compare 2U */
#define HRTIM_ADCTRIGGEREVENT579_TIMERF_CMP3 ((uint32_t)0x1CU) /*!< ADC Trigger on Timer F compare 3U */
#define HRTIM_ADCTRIGGEREVENT579_TIMERF_CMP4 ((uint32_t)0x1DU) /*!< ADC Trigger on Timer F compare 4U */
#define HRTIM_ADCTRIGGEREVENT579_TIMERF_PERIOD ((uint32_t)0x1EU) /*!< ADC Trigger on Timer F period */
#define HRTIM_ADCTRIGGEREVENT579_TIMERF_RESET ((uint32_t)0x1FU) /*!< ADC Trigger on Timer F reset */
/**
* @}
*/
/** @defgroup HRTIM_DLL_Calibration_Rate HRTIM DLL Calibration Rate
* @{
* @brief Constants defining the DLL calibration periods (in micro seconds)
*/
#define HRTIM_SINGLE_CALIBRATION 0xFFFFFFFFU /*!< Non periodic DLL calibration */
#define HRTIM_CALIBRATIONRATE_0 0x00000000U /*!< Periodic DLL calibration: T = 1048576U * tHRTIM (6.168 ms) */
#define HRTIM_CALIBRATIONRATE_1 (HRTIM_DLLCR_CALRTE_0) /*!< Periodic DLL calibration: T = 131072U * tHRTIM (0.771 ms) */
#define HRTIM_CALIBRATIONRATE_2 (HRTIM_DLLCR_CALRTE_1) /*!< Periodic DLL calibration: T = 16384U * tHRTIM (0.096 ms) */
#define HRTIM_CALIBRATIONRATE_3 (HRTIM_DLLCR_CALRTE_1 | HRTIM_DLLCR_CALRTE_0) /*!< Periodic DLL calibration: T = 2048U * tHRTIM (0.012 ms) */
/**
* @}
*/
/** @defgroup HRTIM_Burst_DMA_Registers_Update HRTIM Burst DMA Registers Update
* @{
* @brief Constants defining the registers that can be written during a burst
* DMA operation
*/
#define HRTIM_BURSTDMA_NONE 0x00000000U /*!< No register is updated by Burst DMA accesses */
#define HRTIM_BURSTDMA_CR (HRTIM_BDTUPR_TIMCR) /*!< MCR or TIMxCR register is updated by Burst DMA accesses */
#define HRTIM_BURSTDMA_ICR (HRTIM_BDTUPR_TIMICR) /*!< MICR or TIMxICR register is updated by Burst DMA accesses */
#define HRTIM_BURSTDMA_DIER (HRTIM_BDTUPR_TIMDIER) /*!< MDIER or TIMxDIER register is updated by Burst DMA accesses */
#define HRTIM_BURSTDMA_CNT (HRTIM_BDTUPR_TIMCNT) /*!< MCNTR or CNTxCR register is updated by Burst DMA accesses */
#define HRTIM_BURSTDMA_PER (HRTIM_BDTUPR_TIMPER) /*!< MPER or PERxR register is updated by Burst DMA accesses */
#define HRTIM_BURSTDMA_REP (HRTIM_BDTUPR_TIMREP) /*!< MREPR or REPxR register is updated by Burst DMA accesses */
#define HRTIM_BURSTDMA_CMP1 (HRTIM_BDTUPR_TIMCMP1) /*!< MCMP1R or CMP1xR register is updated by Burst DMA accesses */
#define HRTIM_BURSTDMA_CMP2 (HRTIM_BDTUPR_TIMCMP2) /*!< MCMP2R or CMP2xR register is updated by Burst DMA accesses */
#define HRTIM_BURSTDMA_CMP3 (HRTIM_BDTUPR_TIMCMP3) /*!< MCMP3R or CMP3xR register is updated by Burst DMA accesses */
#define HRTIM_BURSTDMA_CMP4 (HRTIM_BDTUPR_TIMCMP4) /*!< MCMP4R or CMP4xR register is updated by Burst DMA accesses */
#define HRTIM_BURSTDMA_DTR (HRTIM_BDTUPR_TIMDTR) /*!< TDxR register is updated by Burst DMA accesses */
#define HRTIM_BURSTDMA_SET1R (HRTIM_BDTUPR_TIMSET1R) /*!< SET1R register is updated by Burst DMA accesses */
#define HRTIM_BURSTDMA_RST1R (HRTIM_BDTUPR_TIMRST1R) /*!< RST1R register is updated by Burst DMA accesses */
#define HRTIM_BURSTDMA_SET2R (HRTIM_BDTUPR_TIMSET2R) /*!< SET2R register is updated by Burst DMA accesses */
#define HRTIM_BURSTDMA_RST2R (HRTIM_BDTUPR_TIMRST2R) /*!< RST1R register is updated by Burst DMA accesses */
#define HRTIM_BURSTDMA_EEFR1 (HRTIM_BDTUPR_TIMEEFR1) /*!< EEFxR1 register is updated by Burst DMA accesses */
#define HRTIM_BURSTDMA_EEFR2 (HRTIM_BDTUPR_TIMEEFR2) /*!< EEFxR2 register is updated by Burst DMA accesses */
#define HRTIM_BURSTDMA_RSTR (HRTIM_BDTUPR_TIMRSTR) /*!< RSTxR register is updated by Burst DMA accesses */
#define HRTIM_BURSTDMA_CHPR (HRTIM_BDTUPR_TIMCHPR) /*!< CHPxR register is updated by Burst DMA accesses */
#define HRTIM_BURSTDMA_OUTR (HRTIM_BDTUPR_TIMOUTR) /*!< OUTxR register is updated by Burst DMA accesses */
#define HRTIM_BURSTDMA_FLTR (HRTIM_BDTUPR_TIMFLTR) /*!< FLTxR register is updated by Burst DMA accesses */
#define HRTIM_BURSTDMA_CR2 (HRTIM_BDTUPR_TIMCR2) /*!< TIMxCR2 register is updated by Burst DMA accesses */
#define HRTIM_BURSTDMA_EEFR3 (HRTIM_BDTUPR_TIMEEFR3) /*!< EEFxR3 register is updated by Burst DMA accesses */
/**
* @}
*/
/** @defgroup HRTIM_Burst_Mode_Control HRTIM Burst Mode Control
* @{
* @brief Constants used to enable or disable the burst mode controller
*/
#define HRTIM_BURSTMODECTL_DISABLED 0x00000000U /*!< Burst mode disabled */
#define HRTIM_BURSTMODECTL_ENABLED (HRTIM_BMCR_BME) /*!< Burst mode enabled */
/**
* @}
*/
/** @defgroup HRTIM_Fault_Mode_Control HRTIM Fault Mode Control
* @{
* @brief Constants used to enable or disable a fault channel
*/
#define HRTIM_FAULTMODECTL_DISABLED 0x00000000U /*!< Fault channel is disabled */
#define HRTIM_FAULTMODECTL_ENABLED 0x00000001U /*!< Fault channel is enabled */
/**
* @}
*/
/** @defgroup HRTIM_Software_Timer_Update HRTIM Software Timer Update
* @{
* @brief Constants used to force timer registers update
*/
#define HRTIM_TIMERUPDATE_MASTER (HRTIM_CR2_MSWU) /*!< Force an immediate transfer from the preload to the active register in the master timer */
#define HRTIM_TIMERUPDATE_A (HRTIM_CR2_TASWU) /*!< Force an immediate transfer from the preload to the active register in the timer A */
#define HRTIM_TIMERUPDATE_B (HRTIM_CR2_TBSWU) /*!< Force an immediate transfer from the preload to the active register in the timer B */
#define HRTIM_TIMERUPDATE_C (HRTIM_CR2_TCSWU) /*!< Force an immediate transfer from the preload to the active register in the timer C */
#define HRTIM_TIMERUPDATE_D (HRTIM_CR2_TDSWU) /*!< Force an immediate transfer from the preload to the active register in the timer D */
#define HRTIM_TIMERUPDATE_E (HRTIM_CR2_TESWU) /*!< Force an immediate transfer from the preload to the active register in the timer E */
#define HRTIM_TIMERUPDATE_F (HRTIM_CR2_TFSWU) /*!< Forces an immediate transfer from the preload to the active register in the timer F */
/**
* @}
*/
/** @defgroup HRTIM_Software_Timer_SwapOutput HRTIM Software Timer swap Output
* @{
* @brief Constants used to swap the output of the timer registers
*/
#define HRTIM_TIMERSWAP_A (HRTIM_CR2_SWPA) /*!< Swap the output of the Timer A */
#define HRTIM_TIMERSWAP_B (HRTIM_CR2_SWPB) /*!< Swap the output of the Timer B */
#define HRTIM_TIMERSWAP_C (HRTIM_CR2_SWPC) /*!< Swap the output of the Timer C */
#define HRTIM_TIMERSWAP_D (HRTIM_CR2_SWPD) /*!< Swap the output of the Timer D */
#define HRTIM_TIMERSWAP_E (HRTIM_CR2_SWPE) /*!< Swap the output of the Timer E */
#define HRTIM_TIMERSWAP_F (HRTIM_CR2_SWPF) /*!< Swap the output of the Timer F */
/**
* @}
*/
/** @defgroup HRTIM_Software_Timer_Reset HRTIM Software Timer Reset
* @{
* @brief Constants used to force timer counter reset
*/
#define HRTIM_TIMERRESET_MASTER (HRTIM_CR2_MRST) /*!< Reset the master timer counter */
#define HRTIM_TIMERRESET_TIMER_A (HRTIM_CR2_TARST) /*!< Reset the timer A counter */
#define HRTIM_TIMERRESET_TIMER_B (HRTIM_CR2_TBRST) /*!< Reset the timer B counter */
#define HRTIM_TIMERRESET_TIMER_C (HRTIM_CR2_TCRST) /*!< Reset the timer C counter */
#define HRTIM_TIMERRESET_TIMER_D (HRTIM_CR2_TDRST) /*!< Reset the timer D counter */
#define HRTIM_TIMERRESET_TIMER_E (HRTIM_CR2_TERST) /*!< Reset the timer E counter */
#define HRTIM_TIMERRESET_TIMER_F (HRTIM_CR2_TFRST) /*!< Reset the timer F counter */
/**
* @}
*/
/** @defgroup HRTIM_Output_Level HRTIM Output Level
* @{
* @brief Constants defining the level of a timer output
*/
#define HRTIM_OUTPUTLEVEL_ACTIVE (0x00000001U) /*!< Force the output to its active state */
#define HRTIM_OUTPUTLEVEL_INACTIVE (0x00000002U) /*!< Force the output to its inactive state */
#define IS_HRTIM_OUTPUTLEVEL(OUTPUTLEVEL)\
(((OUTPUTLEVEL) == HRTIM_OUTPUTLEVEL_ACTIVE) || \
((OUTPUTLEVEL) == HRTIM_OUTPUTLEVEL_INACTIVE))
/**
* @}
*/
/** @defgroup HRTIM_Output_State HRTIM Output State
* @{
* @brief Constants defining the state of a timer output
*/
#define HRTIM_OUTPUTSTATE_IDLE (0x00000001U) /*!< Main operating mode, where the output can take the active or
inactive level as programmed in the crossbar unit */
#define HRTIM_OUTPUTSTATE_RUN (0x00000002U) /*!< Default operating state (e.g. after an HRTIM reset, when the
outputs are disabled by software or during a burst mode operation */
#define HRTIM_OUTPUTSTATE_FAULT (0x00000003U) /*!< Safety state, entered in case of a shut-down request on
FAULTx inputs */
/**
* @}
*/
/** @defgroup HRTIM_Burst_Mode_Status HRTIM Burst Mode Status
* @{
* @brief Constants defining the operating state of the burst mode controller
*/
#define HRTIM_BURSTMODESTATUS_NORMAL 0x00000000U /*!< Normal operation */
#define HRTIM_BURSTMODESTATUS_ONGOING (HRTIM_BMCR_BMSTAT) /*!< Burst operation on-going */
/**
* @}
*/
/** @defgroup HRTIM_Current_Push_Pull_Status HRTIM Current Push Pull Status
* @{
* @brief Constants defining on which output the signal is currently applied
* in push-pull mode
*/
#define HRTIM_PUSHPULL_CURRENTSTATUS_OUTPUT1 0x00000000U /*!< Signal applied on output 1 and output 2 forced inactive */
#define HRTIM_PUSHPULL_CURRENTSTATUS_OUTPUT2 (HRTIM_TIMISR_CPPSTAT) /*!< Signal applied on output 2 and output 1 forced inactive */
/**
* @}
*/
/** @defgroup HRTIM_Idle_Push_Pull_Status HRTIM Idle Push Pull Status
* @{
* @brief Constants defining on which output the signal was applied, in
* push-pull mode balanced fault mode or delayed idle mode, when the
* protection was triggered
*/
#define HRTIM_PUSHPULL_IDLESTATUS_OUTPUT1 0x00000000U /*!< Protection occurred when the output 1 was active and output 2 forced inactive */
#define HRTIM_PUSHPULL_IDLESTATUS_OUTPUT2 (HRTIM_TIMISR_IPPSTAT) /*!< Protection occurred when the output 2 was active and output 1 forced inactive */
/**
* @}
*/
/** @defgroup HRTIM_Common_Interrupt_Enable HRTIM Common Interrupt Enable
* @{
*/
#define HRTIM_IT_NONE 0x00000000U /*!< No interrupt enabled */
#define HRTIM_IT_FLT1 HRTIM_IER_FLT1 /*!< Fault 1 interrupt enable */
#define HRTIM_IT_FLT2 HRTIM_IER_FLT2 /*!< Fault 2 interrupt enable */
#define HRTIM_IT_FLT3 HRTIM_IER_FLT3 /*!< Fault 3 interrupt enable */
#define HRTIM_IT_FLT4 HRTIM_IER_FLT4 /*!< Fault 4 interrupt enable */
#define HRTIM_IT_FLT5 HRTIM_IER_FLT5 /*!< Fault 5 interrupt enable */
#define HRTIM_IT_FLT6 HRTIM_IER_FLT6 /*!< Fault 6 interrupt enable */
#define HRTIM_IT_SYSFLT HRTIM_IER_SYSFLT /*!< System Fault interrupt enable */
#define HRTIM_IT_DLLRDY HRTIM_IER_DLLRDY /*!< DLL ready interrupt enable */
#define HRTIM_IT_BMPER HRTIM_IER_BMPER /*!< Burst mode period interrupt enable */
/**
* @}
*/
/** @defgroup HRTIM_Master_Interrupt_Enable HRTIM Master Interrupt Enable
* @{
*/
#define HRTIM_MASTER_IT_NONE 0x00000000U /*!< No interrupt enabled */
#define HRTIM_MASTER_IT_MCMP1 HRTIM_MDIER_MCMP1IE /*!< Master compare 1 interrupt enable */
#define HRTIM_MASTER_IT_MCMP2 HRTIM_MDIER_MCMP2IE /*!< Master compare 2 interrupt enable */
#define HRTIM_MASTER_IT_MCMP3 HRTIM_MDIER_MCMP3IE /*!< Master compare 3 interrupt enable */
#define HRTIM_MASTER_IT_MCMP4 HRTIM_MDIER_MCMP4IE /*!< Master compare 4 interrupt enable */
#define HRTIM_MASTER_IT_MREP HRTIM_MDIER_MREPIE /*!< Master Repetition interrupt enable */
#define HRTIM_MASTER_IT_SYNC HRTIM_MDIER_SYNCIE /*!< Synchronization input interrupt enable */
#define HRTIM_MASTER_IT_MUPD HRTIM_MDIER_MUPDIE /*!< Master update interrupt enable */
/**
* @}
*/
/** @defgroup HRTIM_Timing_Unit_Interrupt_Enable HRTIM Timing Unit Interrupt Enable
* @{
*/
#define HRTIM_TIM_IT_NONE 0x00000000U /*!< No interrupt enabled */
#define HRTIM_TIM_IT_CMP1 HRTIM_TIMDIER_CMP1IE /*!< Timer compare 1 interrupt enable */
#define HRTIM_TIM_IT_CMP2 HRTIM_TIMDIER_CMP2IE /*!< Timer compare 2 interrupt enable */
#define HRTIM_TIM_IT_CMP3 HRTIM_TIMDIER_CMP3IE /*!< Timer compare 3 interrupt enable */
#define HRTIM_TIM_IT_CMP4 HRTIM_TIMDIER_CMP4IE /*!< Timer compare 4 interrupt enable */
#define HRTIM_TIM_IT_REP HRTIM_TIMDIER_REPIE /*!< Timer repetition interrupt enable */
#define HRTIM_TIM_IT_UPD HRTIM_TIMDIER_UPDIE /*!< Timer update interrupt enable */
#define HRTIM_TIM_IT_CPT1 HRTIM_TIMDIER_CPT1IE /*!< Timer capture 1 interrupt enable */
#define HRTIM_TIM_IT_CPT2 HRTIM_TIMDIER_CPT2IE /*!< Timer capture 2 interrupt enable */
#define HRTIM_TIM_IT_SET1 HRTIM_TIMDIER_SET1IE /*!< Timer output 1 set interrupt enable */
#define HRTIM_TIM_IT_RST1 HRTIM_TIMDIER_RST1IE /*!< Timer output 1 reset interrupt enable */
#define HRTIM_TIM_IT_SET2 HRTIM_TIMDIER_SET2IE /*!< Timer output 2 set interrupt enable */
#define HRTIM_TIM_IT_RST2 HRTIM_TIMDIER_RST2IE /*!< Timer output 2 reset interrupt enable */
#define HRTIM_TIM_IT_RST HRTIM_TIMDIER_RSTIE /*!< Timer reset interrupt enable */
#define HRTIM_TIM_IT_DLYPRT HRTIM_TIMDIER_DLYPRTIE /*!< Timer delay protection interrupt enable */
/**
* @}
*/
/** @defgroup HRTIM_Common_Interrupt_Flag HRTIM Common Interrupt Flag
* @{
*/
#define HRTIM_FLAG_FLT1 HRTIM_ISR_FLT1 /*!< Fault 1 interrupt flag */
#define HRTIM_FLAG_FLT2 HRTIM_ISR_FLT2 /*!< Fault 2 interrupt flag */
#define HRTIM_FLAG_FLT3 HRTIM_ISR_FLT3 /*!< Fault 3 interrupt flag */
#define HRTIM_FLAG_FLT4 HRTIM_ISR_FLT4 /*!< Fault 4 interrupt flag */
#define HRTIM_FLAG_FLT5 HRTIM_ISR_FLT5 /*!< Fault 5 interrupt flag */
#define HRTIM_FLAG_FLT6 HRTIM_ISR_FLT6 /*!< Fault 6 interrupt flag */
#define HRTIM_FLAG_SYSFLT HRTIM_ISR_SYSFLT /*!< System Fault interrupt flag */
#define HRTIM_FLAG_DLLRDY HRTIM_ISR_DLLRDY /*!< DLL ready interrupt flag */
#define HRTIM_FLAG_BMPER HRTIM_ISR_BMPER /*!< Burst mode period interrupt flag */
/**
* @}
*/
/** @defgroup HRTIM_Master_Interrupt_Flag HRTIM Master Interrupt Flag
* @{
*/
#define HRTIM_MASTER_FLAG_MCMP1 HRTIM_MISR_MCMP1 /*!< Master compare 1 interrupt flag */
#define HRTIM_MASTER_FLAG_MCMP2 HRTIM_MISR_MCMP2 /*!< Master compare 2 interrupt flag */
#define HRTIM_MASTER_FLAG_MCMP3 HRTIM_MISR_MCMP3 /*!< Master compare 3 interrupt flag */
#define HRTIM_MASTER_FLAG_MCMP4 HRTIM_MISR_MCMP4 /*!< Master compare 4 interrupt flag */
#define HRTIM_MASTER_FLAG_MREP HRTIM_MISR_MREP /*!< Master Repetition interrupt flag */
#define HRTIM_MASTER_FLAG_SYNC HRTIM_MISR_SYNC /*!< Synchronization input interrupt flag */
#define HRTIM_MASTER_FLAG_MUPD HRTIM_MISR_MUPD /*!< Master update interrupt flag */
/**
* @}
*/
/** @defgroup HRTIM_Timing_Unit_Interrupt_Flag HRTIM Timing Unit Interrupt Flag
* @{
*/
#define HRTIM_TIM_FLAG_CMP1 HRTIM_TIMISR_CMP1 /*!< Timer compare 1 interrupt flag */
#define HRTIM_TIM_FLAG_CMP2 HRTIM_TIMISR_CMP2 /*!< Timer compare 2 interrupt flag */
#define HRTIM_TIM_FLAG_CMP3 HRTIM_TIMISR_CMP3 /*!< Timer compare 3 interrupt flag */
#define HRTIM_TIM_FLAG_CMP4 HRTIM_TIMISR_CMP4 /*!< Timer compare 4 interrupt flag */
#define HRTIM_TIM_FLAG_REP HRTIM_TIMISR_REP /*!< Timer repetition interrupt flag */
#define HRTIM_TIM_FLAG_UPD HRTIM_TIMISR_UPD /*!< Timer update interrupt flag */
#define HRTIM_TIM_FLAG_CPT1 HRTIM_TIMISR_CPT1 /*!< Timer capture 1 interrupt flag */
#define HRTIM_TIM_FLAG_CPT2 HRTIM_TIMISR_CPT2 /*!< Timer capture 2 interrupt flag */
#define HRTIM_TIM_FLAG_SET1 HRTIM_TIMISR_SET1 /*!< Timer output 1 set interrupt flag */
#define HRTIM_TIM_FLAG_RST1 HRTIM_TIMISR_RST1 /*!< Timer output 1 reset interrupt flag */
#define HRTIM_TIM_FLAG_SET2 HRTIM_TIMISR_SET2 /*!< Timer output 2 set interrupt flag */
#define HRTIM_TIM_FLAG_RST2 HRTIM_TIMISR_RST2 /*!< Timer output 2 reset interrupt flag */
#define HRTIM_TIM_FLAG_RST HRTIM_TIMISR_RST /*!< Timer reset interrupt flag */
#define HRTIM_TIM_FLAG_DLYPRT HRTIM_TIMISR_DLYPRT /*!< Timer delay protection interrupt flag */
/**
* @}
*/
/** @defgroup HRTIM_Master_DMA_Request_Enable HRTIM Master DMA Request Enable
* @{
*/
#define HRTIM_MASTER_DMA_NONE 0x00000000U /*!< No DMA request enable */
#define HRTIM_MASTER_DMA_MCMP1 HRTIM_MDIER_MCMP1DE /*!< Master compare 1 DMA request enable */
#define HRTIM_MASTER_DMA_MCMP2 HRTIM_MDIER_MCMP2DE /*!< Master compare 2 DMA request enable */
#define HRTIM_MASTER_DMA_MCMP3 HRTIM_MDIER_MCMP3DE /*!< Master compare 3 DMA request enable */
#define HRTIM_MASTER_DMA_MCMP4 HRTIM_MDIER_MCMP4DE /*!< Master compare 4 DMA request enable */
#define HRTIM_MASTER_DMA_MREP HRTIM_MDIER_MREPDE /*!< Master Repetition DMA request enable */
#define HRTIM_MASTER_DMA_SYNC HRTIM_MDIER_SYNCDE /*!< Synchronization input DMA request enable */
#define HRTIM_MASTER_DMA_MUPD HRTIM_MDIER_MUPDDE /*!< Master update DMA request enable */
/**
* @}
*/
/** @defgroup HRTIM_Timing_Unit_DMA_Request_Enable HRTIM Timing Unit DMA Request Enable
* @{
*/
#define HRTIM_TIM_DMA_NONE 0x00000000U /*!< No DMA request enable */
#define HRTIM_TIM_DMA_CMP1 HRTIM_TIMDIER_CMP1DE /*!< Timer compare 1 DMA request enable */
#define HRTIM_TIM_DMA_CMP2 HRTIM_TIMDIER_CMP2DE /*!< Timer compare 2 DMA request enable */
#define HRTIM_TIM_DMA_CMP3 HRTIM_TIMDIER_CMP3DE /*!< Timer compare 3 DMA request enable */
#define HRTIM_TIM_DMA_CMP4 HRTIM_TIMDIER_CMP4DE /*!< Timer compare 4 DMA request enable */
#define HRTIM_TIM_DMA_REP HRTIM_TIMDIER_REPDE /*!< Timer repetition DMA request enable */
#define HRTIM_TIM_DMA_UPD HRTIM_TIMDIER_UPDDE /*!< Timer update DMA request enable */
#define HRTIM_TIM_DMA_CPT1 HRTIM_TIMDIER_CPT1DE /*!< Timer capture 1 DMA request enable */
#define HRTIM_TIM_DMA_CPT2 HRTIM_TIMDIER_CPT2DE /*!< Timer capture 2 DMA request enable */
#define HRTIM_TIM_DMA_SET1 HRTIM_TIMDIER_SET1DE /*!< Timer output 1 set DMA request enable */
#define HRTIM_TIM_DMA_RST1 HRTIM_TIMDIER_RST1DE /*!< Timer output 1 reset DMA request enable */
#define HRTIM_TIM_DMA_SET2 HRTIM_TIMDIER_SET2DE /*!< Timer output 2 set DMA request enable */
#define HRTIM_TIM_DMA_RST2 HRTIM_TIMDIER_RST2DE /*!< Timer output 2 reset DMA request enable */
#define HRTIM_TIM_DMA_RST HRTIM_TIMDIER_RSTDE /*!< Timer reset DMA request enable */
#define HRTIM_TIM_DMA_DLYPRT HRTIM_TIMDIER_DLYPRTDE /*!< Timer delay protection DMA request enable */
/**
* @}
*/
/**
* @}
*/
/* Private Constants --------------------------------------------------------*/
/** @addtogroup HRTIM_Private_Constants
* @{
*/
#define HRTIM_CAPTUREFTRIGGER_NONE 0x00000000U /*!< 32bit value Capture trigger is disabled */
#define HRTIM_CAPTUREFTRIGGER_TF1_SET (HRTIM_CPT1CR_TF1SET) /*!< 32bit value Capture is triggered by TF1 output inactive to active transition */
#define HRTIM_CAPTUREFTRIGGER_TF1_RESET (HRTIM_CPT1CR_TF1RST) /*!< 32bit value Capture is triggered by TF1 output active to inactive transition */
#define HRTIM_CAPTUREFTRIGGER_TIMERF_CMP1 (HRTIM_CPT1CR_TIMFCMP1) /*!< 32bit value Timer F Compare 1 triggers Capture */
#define HRTIM_CAPTUREFTRIGGER_TIMERF_CMP2 (HRTIM_CPT1CR_TIMFCMP2) /*!< 32bit value Timer F Compare 2 triggers Capture */
/**
* @}
*/
/* Private macros --------------------------------------------------------*/
/** @addtogroup HRTIM_Private_Macros
* @{
*/
#define IS_HRTIM_TIMERINDEX(TIMERINDEX)\
(((TIMERINDEX) == HRTIM_TIMERINDEX_MASTER) || \
((TIMERINDEX) == HRTIM_TIMERINDEX_TIMER_A) || \
((TIMERINDEX) == HRTIM_TIMERINDEX_TIMER_B) || \
((TIMERINDEX) == HRTIM_TIMERINDEX_TIMER_C) || \
((TIMERINDEX) == HRTIM_TIMERINDEX_TIMER_D) || \
((TIMERINDEX) == HRTIM_TIMERINDEX_TIMER_E) || \
((TIMERINDEX) == HRTIM_TIMERINDEX_TIMER_F))
#define IS_HRTIM_TIMING_UNIT(TIMERINDEX)\
(((TIMERINDEX) == HRTIM_TIMERINDEX_TIMER_A) || \
((TIMERINDEX) == HRTIM_TIMERINDEX_TIMER_B) || \
((TIMERINDEX) == HRTIM_TIMERINDEX_TIMER_C) || \
((TIMERINDEX) == HRTIM_TIMERINDEX_TIMER_D) || \
((TIMERINDEX) == HRTIM_TIMERINDEX_TIMER_E) || \
((TIMERINDEX) == HRTIM_TIMERINDEX_TIMER_F))
#define IS_HRTIM_TIMERID(TIMERID) (((TIMERID) & 0xFF80FFFFU) == 0x00000000U)
#define IS_HRTIM_COMPAREUNIT(COMPAREUNIT)\
(((COMPAREUNIT) == HRTIM_COMPAREUNIT_1) || \
((COMPAREUNIT) == HRTIM_COMPAREUNIT_2) || \
((COMPAREUNIT) == HRTIM_COMPAREUNIT_3) || \
((COMPAREUNIT) == HRTIM_COMPAREUNIT_4))
#define IS_HRTIM_CAPTUREUNIT(CAPTUREUNIT)\
(((CAPTUREUNIT) == HRTIM_CAPTUREUNIT_1) || \
((CAPTUREUNIT) == HRTIM_CAPTUREUNIT_2))
#define IS_HRTIM_OUTPUT(OUTPUT) (((OUTPUT) & 0xFFFFF000U) == 0x00000000U)
#define IS_HRTIM_TIMER_OUTPUT(TIMER, OUTPUT)\
((((TIMER) == HRTIM_TIMERINDEX_TIMER_A) && \
(((OUTPUT) == HRTIM_OUTPUT_TA1) || \
((OUTPUT) == HRTIM_OUTPUT_TA2))) \
|| \
(((TIMER) == HRTIM_TIMERINDEX_TIMER_B) && \
(((OUTPUT) == HRTIM_OUTPUT_TB1) || \
((OUTPUT) == HRTIM_OUTPUT_TB2))) \
|| \
(((TIMER) == HRTIM_TIMERINDEX_TIMER_C) && \
(((OUTPUT) == HRTIM_OUTPUT_TC1) || \
((OUTPUT) == HRTIM_OUTPUT_TC2))) \
|| \
(((TIMER) == HRTIM_TIMERINDEX_TIMER_D) && \
(((OUTPUT) == HRTIM_OUTPUT_TD1) || \
((OUTPUT) == HRTIM_OUTPUT_TD2))) \
|| \
(((TIMER) == HRTIM_TIMERINDEX_TIMER_E) && \
(((OUTPUT) == HRTIM_OUTPUT_TE1) || \
((OUTPUT) == HRTIM_OUTPUT_TE2))) \
|| \
(((TIMER) == HRTIM_TIMERINDEX_TIMER_F) && \
(((OUTPUT) == HRTIM_OUTPUT_TF1) || \
((OUTPUT) == HRTIM_OUTPUT_TF2))))
#define IS_HRTIM_TIMEEVENT(EVENT)\
(((EVENT) == HRTIM_EVENTCOUNTER_A) || \
((EVENT) == HRTIM_EVENTCOUNTER_B))
#define IS_HRTIM_TIMEEVENT_RESETMODE(EVENT)\
(((EVENT) == HRTIM_EVENTCOUNTER_RSTMODE_UNCONDITIONAL) || \
((EVENT) == HRTIM_EVENTCOUNTER_RSTMODE_CONDITIONAL))
#define IS_HRTIM_TIMSYNCUPDATE(EVENT)\
(((EVENT) == HRTIM_TIMERESYNC_UPDATE_UNCONDITIONAL) || \
((EVENT) == HRTIM_TIMERESYNC_UPDATE_CONDITIONAL))
#define IS_HRTIM_TIMEEVENT_COUNTER(COUNTER)\
((((COUNTER) > (uint32_t)0x00U) && ((COUNTER) <= (uint32_t)0x3FU)) ||\
((COUNTER) == (uint32_t)0x00U))
#define IS_HRTIM_TIMEEVENT_SOURCE(SOURCE)\
(((SOURCE) >= (uint32_t)0x00U) && ((SOURCE) <= (uint32_t)0x9U))
#define IS_HRTIM_EVENT(EVENT)\
(((EVENT) == HRTIM_EVENT_NONE)|| \
((EVENT) == HRTIM_EVENT_1) || \
((EVENT) == HRTIM_EVENT_2) || \
((EVENT) == HRTIM_EVENT_3) || \
((EVENT) == HRTIM_EVENT_4) || \
((EVENT) == HRTIM_EVENT_5) || \
((EVENT) == HRTIM_EVENT_6) || \
((EVENT) == HRTIM_EVENT_7) || \
((EVENT) == HRTIM_EVENT_8) || \
((EVENT) == HRTIM_EVENT_9) || \
((EVENT) == HRTIM_EVENT_10))
#define IS_HRTIM_FAULT(FAULT)\
(((FAULT) == HRTIM_FAULT_1) || \
((FAULT) == HRTIM_FAULT_2) || \
((FAULT) == HRTIM_FAULT_3) || \
((FAULT) == HRTIM_FAULT_4) || \
((FAULT) == HRTIM_FAULT_5) || \
((FAULT) == HRTIM_FAULT_6))
#define IS_HRTIM_PRESCALERRATIO(PRESCALERRATIO)\
(((PRESCALERRATIO) == HRTIM_PRESCALERRATIO_MUL32) || \
((PRESCALERRATIO) == HRTIM_PRESCALERRATIO_MUL16) || \
((PRESCALERRATIO) == HRTIM_PRESCALERRATIO_MUL8) || \
((PRESCALERRATIO) == HRTIM_PRESCALERRATIO_MUL4) || \
((PRESCALERRATIO) == HRTIM_PRESCALERRATIO_MUL2) || \
((PRESCALERRATIO) == HRTIM_PRESCALERRATIO_DIV1) || \
((PRESCALERRATIO) == HRTIM_PRESCALERRATIO_DIV2) || \
((PRESCALERRATIO) == HRTIM_PRESCALERRATIO_DIV4))
#define IS_HRTIM_MODE(MODE)\
(((MODE) == HRTIM_MODE_CONTINUOUS) || \
((MODE) == HRTIM_MODE_SINGLESHOT) || \
((MODE) == HRTIM_MODE_SINGLESHOT_RETRIGGERABLE))
#define IS_HRTIM_MODE_ONEPULSE(MODE)\
(((MODE) == HRTIM_MODE_SINGLESHOT) || \
((MODE) == HRTIM_MODE_SINGLESHOT_RETRIGGERABLE))
#define IS_HRTIM_HALFMODE(HALFMODE)\
(((HALFMODE) == HRTIM_HALFMODE_DISABLED) || \
((HALFMODE) == HRTIM_HALFMODE_ENABLED))
#define IS_HRTIM_INTERLEAVEDMODE(INTLVDMODE)\
(((INTLVDMODE) == HRTIM_INTERLEAVED_MODE_DISABLED) || \
((INTLVDMODE) == HRTIM_INTERLEAVED_MODE_DUAL) || \
((INTLVDMODE) == HRTIM_INTERLEAVED_MODE_DISABLED) || \
((INTLVDMODE) == HRTIM_INTERLEAVED_MODE_TRIPLE) || \
((INTLVDMODE) == HRTIM_INTERLEAVED_MODE_DISABLED) || \
((INTLVDMODE) == HRTIM_INTERLEAVED_MODE_QUAD))
#define IS_HRTIM_SYNCSTART(SYNCSTART)\
(((SYNCSTART) == HRTIM_SYNCSTART_DISABLED) || \
((SYNCSTART) == HRTIM_SYNCSTART_ENABLED))
#define IS_HRTIM_SYNCRESET(SYNCRESET)\
(((SYNCRESET) == HRTIM_SYNCRESET_DISABLED) || \
((SYNCRESET) == HRTIM_SYNCRESET_ENABLED))
#define IS_HRTIM_DACSYNC(DACSYNC)\
(((DACSYNC) == HRTIM_DACSYNC_NONE) || \
((DACSYNC) == HRTIM_DACSYNC_DACTRIGOUT_1) || \
((DACSYNC) == HRTIM_DACSYNC_DACTRIGOUT_2) || \
((DACSYNC) == HRTIM_DACSYNC_DACTRIGOUT_3))
#define IS_HRTIM_PRELOAD(PRELOAD)\
(((PRELOAD) == HRTIM_PRELOAD_DISABLED) || \
((PRELOAD) == HRTIM_PRELOAD_ENABLED))
#define IS_HRTIM_UPDATEGATING_MASTER(UPDATEGATING)\
(((UPDATEGATING) == HRTIM_UPDATEGATING_INDEPENDENT) || \
((UPDATEGATING) == HRTIM_UPDATEGATING_DMABURST) || \
((UPDATEGATING) == HRTIM_UPDATEGATING_DMABURST_UPDATE))
#define IS_HRTIM_UPDATEGATING_TIM(UPDATEGATING)\
(((UPDATEGATING) == HRTIM_UPDATEGATING_INDEPENDENT) || \
((UPDATEGATING) == HRTIM_UPDATEGATING_DMABURST) || \
((UPDATEGATING) == HRTIM_UPDATEGATING_DMABURST_UPDATE) || \
((UPDATEGATING) == HRTIM_UPDATEGATING_UPDEN1) || \
((UPDATEGATING) == HRTIM_UPDATEGATING_UPDEN2) || \
((UPDATEGATING) == HRTIM_UPDATEGATING_UPDEN3) || \
((UPDATEGATING) == HRTIM_UPDATEGATING_UPDEN1_UPDATE) || \
((UPDATEGATING) == HRTIM_UPDATEGATING_UPDEN2_UPDATE) || \
((UPDATEGATING) == HRTIM_UPDATEGATING_UPDEN3_UPDATE))
#define IS_HRTIM_TIMERBURSTMODE(MODE) \
(((MODE) == HRTIM_TIMERBURSTMODE_MAINTAINCLOCK) || \
((MODE) == HRTIM_TIMERBURSTMODE_RESETCOUNTER))
#define IS_HRTIM_TIMERUPDOWNMODE(MODE) \
(((MODE) == HRTIM_TIMERUPDOWNMODE_UP) || \
((MODE) == HRTIM_TIMERUPDOWNMODE_UPDOWN))
#define IS_HRTIM_TIMERTRGHLFMODE(MODE) \
(((MODE) == HRTIM_TIMERTRIGHALF_DISABLED) || \
((MODE) == HRTIM_TIMERTRIGHALF_ENABLED))
#define IS_HRTIM_TIMERGTCMP3(MODE) \
(((MODE) == HRTIM_TIMERGTCMP3_EQUAL) || \
((MODE) == HRTIM_TIMERGTCMP3_GREATER))
#define IS_HRTIM_TIMERGTCMP1(MODE) \
(((MODE) == HRTIM_TIMERGTCMP1_EQUAL) || \
((MODE) == HRTIM_TIMERGTCMP1_GREATER))
#define IS_HRTIM_DUALDAC_RESET(DUALCHANNELDAC) \
(((DUALCHANNELDAC) == HRTIM_TIMER_DCDR_COUNTER) || \
((DUALCHANNELDAC) == HRTIM_TIMER_DCDR_OUT1SET))
#define IS_HRTIM_DUALDAC_STEP(DUALCHANNELDAC) \
(((DUALCHANNELDAC) == HRTIM_TIMER_DCDS_CMP2) || \
((DUALCHANNELDAC) == HRTIM_TIMER_DCDS_OUT1RST))
#define IS_HRTIM_DUALDAC_ENABLE(DUALCHANNELDAC) \
(((DUALCHANNELDAC) == HRTIM_TIMER_DCDE_DISABLED) || \
((DUALCHANNELDAC) == HRTIM_TIMER_DCDE_ENABLED ))
#define IS_HRTIM_UPDATEONREPETITION(UPDATEONREPETITION) \
(((UPDATEONREPETITION) == HRTIM_UPDATEONREPETITION_DISABLED) || \
((UPDATEONREPETITION) == HRTIM_UPDATEONREPETITION_ENABLED))
#define IS_HRTIM_TIMPUSHPULLMODE(TIMPUSHPULLMODE)\
(((TIMPUSHPULLMODE) == HRTIM_TIMPUSHPULLMODE_DISABLED) || \
((TIMPUSHPULLMODE) == HRTIM_TIMPUSHPULLMODE_ENABLED))
#define IS_HRTIM_TIMFAULTENABLE(TIMFAULTENABLE) (((TIMFAULTENABLE) & 0xFFFFFFC0U) == 0x00000000U)
#define IS_HRTIM_TIMFAULTLOCK(TIMFAULTLOCK)\
(((TIMFAULTLOCK) == HRTIM_TIMFAULTLOCK_READWRITE) || \
((TIMFAULTLOCK) == HRTIM_TIMFAULTLOCK_READONLY))
#define IS_HRTIM_TIMDEADTIMEINSERTION(TIMPUSHPULLMODE, TIMDEADTIMEINSERTION)\
(((TIMDEADTIMEINSERTION) == HRTIM_TIMDEADTIMEINSERTION_DISABLED) || \
((TIMDEADTIMEINSERTION) == HRTIM_TIMDEADTIMEINSERTION_ENABLED))
#define IS_HRTIM_TIMDELAYEDPROTECTION(TIMPUSHPULLMODE, TIMDELAYEDPROTECTION)\
((((TIMDELAYEDPROTECTION) == HRTIM_TIMER_A_B_C_DELAYEDPROTECTION_DISABLED) || \
((TIMDELAYEDPROTECTION) == HRTIM_TIMER_A_B_C_DELAYEDPROTECTION_DELAYEDOUT1_EEV6) || \
((TIMDELAYEDPROTECTION) == HRTIM_TIMER_A_B_C_DELAYEDPROTECTION_DELAYEDOUT2_EEV6) || \
((TIMDELAYEDPROTECTION) == HRTIM_TIMER_A_B_C_DELAYEDPROTECTION_DELAYEDBOTH_EEV6) || \
((TIMDELAYEDPROTECTION) == HRTIM_TIMER_A_B_C_DELAYEDPROTECTION_DELAYEDOUT1_DEEV7) || \
((TIMDELAYEDPROTECTION) == HRTIM_TIMER_A_B_C_DELAYEDPROTECTION_DELAYEDOUT2_DEEV7) || \
((TIMDELAYEDPROTECTION) == HRTIM_TIMER_A_B_C_DELAYEDPROTECTION_DELAYEDBOTH_EEV7)) \
|| \
(((TIMPUSHPULLMODE) == HRTIM_TIMPUSHPULLMODE_ENABLED) && \
(((TIMDELAYEDPROTECTION) == HRTIM_TIMER_A_B_C_DELAYEDPROTECTION_BALANCED_EEV6) || \
((TIMDELAYEDPROTECTION) == HRTIM_TIMER_A_B_C_DELAYEDPROTECTION_BALANCED_EEV7))))
#define IS_HRTIM_TIMUPDATETRIGGER(TIMUPDATETRIGGER) (((TIMUPDATETRIGGER) & 0xFE06FFFFU) == 0x00000000U)
#define IS_HRTIM_TIMRESETTRIGGER(TIMRESETTRIGGER) (((TIMRESETTRIGGER) & 0x00000000U) == 0x00000000U)
#define IS_HRTIM_TIMUPDATEONRESET(TIMUPDATEONRESET) \
(((TIMUPDATEONRESET) == HRTIM_TIMUPDATEONRESET_DISABLED) || \
((TIMUPDATEONRESET) == HRTIM_TIMUPDATEONRESET_ENABLED))
#define IS_HRTIM_AUTODELAYEDMODE(AUTODELAYEDMODE)\
(((AUTODELAYEDMODE) == HRTIM_AUTODELAYEDMODE_REGULAR) || \
((AUTODELAYEDMODE) == HRTIM_AUTODELAYEDMODE_AUTODELAYED_NOTIMEOUT) || \
((AUTODELAYEDMODE) == HRTIM_AUTODELAYEDMODE_AUTODELAYED_TIMEOUTCMP1) || \
((AUTODELAYEDMODE) == HRTIM_AUTODELAYEDMODE_AUTODELAYED_TIMEOUTCMP3))
/* Auto delayed mode is only available for compare units 2 and 4U */
#define IS_HRTIM_COMPAREUNIT_AUTODELAYEDMODE(COMPAREUNIT, AUTODELAYEDMODE) \
((((COMPAREUNIT) == HRTIM_COMPAREUNIT_2) && \
(((AUTODELAYEDMODE) == HRTIM_AUTODELAYEDMODE_REGULAR) || \
((AUTODELAYEDMODE) == HRTIM_AUTODELAYEDMODE_AUTODELAYED_NOTIMEOUT) || \
((AUTODELAYEDMODE) == HRTIM_AUTODELAYEDMODE_AUTODELAYED_TIMEOUTCMP1) || \
((AUTODELAYEDMODE) == HRTIM_AUTODELAYEDMODE_AUTODELAYED_TIMEOUTCMP3))) \
|| \
(((COMPAREUNIT) == HRTIM_COMPAREUNIT_4) && \
(((AUTODELAYEDMODE) == HRTIM_AUTODELAYEDMODE_REGULAR) || \
((AUTODELAYEDMODE) == HRTIM_AUTODELAYEDMODE_AUTODELAYED_NOTIMEOUT) || \
((AUTODELAYEDMODE) == HRTIM_AUTODELAYEDMODE_AUTODELAYED_TIMEOUTCMP1) || \
((AUTODELAYEDMODE) == HRTIM_AUTODELAYEDMODE_AUTODELAYED_TIMEOUTCMP3))))
#define IS_HRTIM_OUTPUTPOLARITY(OUTPUTPOLARITY)\
(((OUTPUTPOLARITY) == HRTIM_OUTPUTPOLARITY_HIGH) || \
((OUTPUTPOLARITY) == HRTIM_OUTPUTPOLARITY_LOW))
#define IS_HRTIM_OUTPUTPULSE(OUTPUTPULSE) ((OUTPUTPULSE) <= 0x0000FFFFU)
#define IS_HRTIM_OUTPUTSET(OUTPUTSET)\
(((OUTPUTSET) == HRTIM_OUTPUTSET_NONE) || \
((OUTPUTSET) == HRTIM_OUTPUTSET_RESYNC) || \
((OUTPUTSET) == HRTIM_OUTPUTSET_TIMPER) || \
((OUTPUTSET) == HRTIM_OUTPUTSET_TIMCMP1) || \
((OUTPUTSET) == HRTIM_OUTPUTSET_TIMCMP2) || \
((OUTPUTSET) == HRTIM_OUTPUTSET_TIMCMP3) || \
((OUTPUTSET) == HRTIM_OUTPUTSET_TIMCMP4) || \
((OUTPUTSET) == HRTIM_OUTPUTSET_MASTERPER) || \
((OUTPUTSET) == HRTIM_OUTPUTSET_MASTERCMP1) || \
((OUTPUTSET) == HRTIM_OUTPUTSET_MASTERCMP2) || \
((OUTPUTSET) == HRTIM_OUTPUTSET_MASTERCMP3) || \
((OUTPUTSET) == HRTIM_OUTPUTSET_MASTERCMP4) || \
((OUTPUTSET) == HRTIM_OUTPUTSET_TIMAEV1_TIMBCMP1) || \
((OUTPUTSET) == HRTIM_OUTPUTSET_TIMAEV2_TIMBCMP2) || \
((OUTPUTSET) == HRTIM_OUTPUTSET_TIMAEV3_TIMCCMP2) || \
((OUTPUTSET) == HRTIM_OUTPUTSET_TIMAEV4_TIMCCMP3) || \
((OUTPUTSET) == HRTIM_OUTPUTSET_TIMAEV5_TIMDCMP1) || \
((OUTPUTSET) == HRTIM_OUTPUTSET_TIMAEV6_TIMDCMP2) || \
((OUTPUTSET) == HRTIM_OUTPUTSET_TIMAEV7_TIMECMP3) || \
((OUTPUTSET) == HRTIM_OUTPUTSET_TIMAEV8_TIMECMP4) || \
((OUTPUTSET) == HRTIM_OUTPUTSET_TIMAEV9_TIMFCMP4) || \
((OUTPUTSET) == HRTIM_OUTPUTSET_EEV_1) || \
((OUTPUTSET) == HRTIM_OUTPUTSET_EEV_2) || \
((OUTPUTSET) == HRTIM_OUTPUTSET_EEV_3) || \
((OUTPUTSET) == HRTIM_OUTPUTSET_EEV_4) || \
((OUTPUTSET) == HRTIM_OUTPUTSET_EEV_5) || \
((OUTPUTSET) == HRTIM_OUTPUTSET_EEV_6) || \
((OUTPUTSET) == HRTIM_OUTPUTSET_EEV_7) || \
((OUTPUTSET) == HRTIM_OUTPUTSET_EEV_8) || \
((OUTPUTSET) == HRTIM_OUTPUTSET_EEV_9) || \
((OUTPUTSET) == HRTIM_OUTPUTSET_EEV_10) || \
((OUTPUTSET) == HRTIM_OUTPUTSET_UPDATE))
#define IS_HRTIM_OUTPUTRESET(OUTPUTRESET)\
(((OUTPUTRESET) == HRTIM_OUTPUTRESET_NONE) || \
((OUTPUTRESET) == HRTIM_OUTPUTRESET_RESYNC) || \
((OUTPUTRESET) == HRTIM_OUTPUTRESET_TIMPER) || \
((OUTPUTRESET) == HRTIM_OUTPUTRESET_TIMCMP1) || \
((OUTPUTRESET) == HRTIM_OUTPUTRESET_TIMCMP2) || \
((OUTPUTRESET) == HRTIM_OUTPUTRESET_TIMCMP3) || \
((OUTPUTRESET) == HRTIM_OUTPUTRESET_TIMCMP4) || \
((OUTPUTRESET) == HRTIM_OUTPUTRESET_MASTERPER) || \
((OUTPUTRESET) == HRTIM_OUTPUTRESET_MASTERCMP1) || \
((OUTPUTRESET) == HRTIM_OUTPUTRESET_MASTERCMP2) || \
((OUTPUTRESET) == HRTIM_OUTPUTRESET_MASTERCMP3) || \
((OUTPUTRESET) == HRTIM_OUTPUTRESET_MASTERCMP4) || \
((OUTPUTRESET) == HRTIM_OUTPUTRESET_TIMAEV1_TIMBCMP1) || \
((OUTPUTRESET) == HRTIM_OUTPUTRESET_TIMAEV2_TIMBCMP2) || \
((OUTPUTRESET) == HRTIM_OUTPUTRESET_TIMAEV3_TIMCCMP2) || \
((OUTPUTRESET) == HRTIM_OUTPUTRESET_TIMAEV4_TIMCCMP3) || \
((OUTPUTRESET) == HRTIM_OUTPUTRESET_TIMAEV5_TIMDCMP1) || \
((OUTPUTRESET) == HRTIM_OUTPUTRESET_TIMAEV6_TIMDCMP2) || \
((OUTPUTRESET) == HRTIM_OUTPUTRESET_TIMAEV7_TIMECMP3) || \
((OUTPUTRESET) == HRTIM_OUTPUTRESET_TIMAEV8_TIMECMP4) || \
((OUTPUTRESET) == HRTIM_OUTPUTRESET_TIMAEV9_TIMFCMP4) || \
((OUTPUTRESET) == HRTIM_OUTPUTRESET_EEV_1) || \
((OUTPUTRESET) == HRTIM_OUTPUTRESET_EEV_2) || \
((OUTPUTRESET) == HRTIM_OUTPUTRESET_EEV_3) || \
((OUTPUTRESET) == HRTIM_OUTPUTRESET_EEV_4) || \
((OUTPUTRESET) == HRTIM_OUTPUTRESET_EEV_5) || \
((OUTPUTRESET) == HRTIM_OUTPUTRESET_EEV_6) || \
((OUTPUTRESET) == HRTIM_OUTPUTRESET_EEV_7) || \
((OUTPUTRESET) == HRTIM_OUTPUTRESET_EEV_8) || \
((OUTPUTRESET) == HRTIM_OUTPUTRESET_EEV_9) || \
((OUTPUTRESET) == HRTIM_OUTPUTRESET_EEV_10) || \
((OUTPUTRESET) == HRTIM_OUTPUTRESET_UPDATE))
#define IS_HRTIM_OUTPUTIDLEMODE(OUTPUTIDLEMODE)\
(((OUTPUTIDLEMODE) == HRTIM_OUTPUTIDLEMODE_NONE) || \
((OUTPUTIDLEMODE) == HRTIM_OUTPUTIDLEMODE_IDLE))
#define IS_HRTIM_OUTPUTIDLELEVEL(OUTPUTIDLELEVEL)\
(((OUTPUTIDLELEVEL) == HRTIM_OUTPUTIDLELEVEL_INACTIVE) || \
((OUTPUTIDLELEVEL) == HRTIM_OUTPUTIDLELEVEL_ACTIVE))
#define IS_HRTIM_OUTPUTFAULTLEVEL(OUTPUTFAULTLEVEL)\
(((OUTPUTFAULTLEVEL) == HRTIM_OUTPUTFAULTLEVEL_NONE) || \
((OUTPUTFAULTLEVEL) == HRTIM_OUTPUTFAULTLEVEL_ACTIVE) || \
((OUTPUTFAULTLEVEL) == HRTIM_OUTPUTFAULTLEVEL_INACTIVE) || \
((OUTPUTFAULTLEVEL) == HRTIM_OUTPUTFAULTLEVEL_HIGHZ))
#define IS_HRTIM_OUTPUTCHOPPERMODE(OUTPUTCHOPPERMODE)\
(((OUTPUTCHOPPERMODE) == HRTIM_OUTPUTCHOPPERMODE_DISABLED) || \
((OUTPUTCHOPPERMODE) == HRTIM_OUTPUTCHOPPERMODE_ENABLED))
#define IS_HRTIM_OUTPUTBURSTMODEENTRY(OUTPUTBURSTMODEENTRY)\
(((OUTPUTBURSTMODEENTRY) == HRTIM_OUTPUTBURSTMODEENTRY_REGULAR) || \
((OUTPUTBURSTMODEENTRY) == HRTIM_OUTPUTBURSTMODEENTRY_DELAYED))
#define IS_HRTIM_OUTPUTBALANCEDIDLE(OUTPUTBIAR)\
(((OUTPUTBIAR) == HRTIM_OUTPUTBIAR_DISABLED) || \
((OUTPUTBIAR) == HRTIM_OUTPUTBIAR_ENABLED))
#define IS_HRTIM_TIMER_CAPTURETRIGGER(TIMER, CAPTURETRIGGER) \
(((CAPTURETRIGGER) == HRTIM_CAPTURETRIGGER_NONE) || \
((CAPTURETRIGGER) == HRTIM_CAPTURETRIGGER_UPDATE) || \
((CAPTURETRIGGER) == HRTIM_CAPTURETRIGGER_EEV_1) || \
((CAPTURETRIGGER) == HRTIM_CAPTURETRIGGER_EEV_2) || \
((CAPTURETRIGGER) == HRTIM_CAPTURETRIGGER_EEV_3) || \
((CAPTURETRIGGER) == HRTIM_CAPTURETRIGGER_EEV_4) || \
((CAPTURETRIGGER) == HRTIM_CAPTURETRIGGER_EEV_5) || \
((CAPTURETRIGGER) == HRTIM_CAPTURETRIGGER_EEV_6) || \
((CAPTURETRIGGER) == HRTIM_CAPTURETRIGGER_EEV_7) || \
((CAPTURETRIGGER) == HRTIM_CAPTURETRIGGER_EEV_8) || \
((CAPTURETRIGGER) == HRTIM_CAPTURETRIGGER_EEV_9) || \
((CAPTURETRIGGER) == HRTIM_CAPTURETRIGGER_EEV_10) \
|| \
(((TIMER) == HRTIM_TIMERINDEX_TIMER_A) && \
(((CAPTURETRIGGER) == HRTIM_CAPTURETRIGGER_TB1_SET) || \
((CAPTURETRIGGER) == HRTIM_CAPTURETRIGGER_TB1_RESET) || \
((CAPTURETRIGGER) == HRTIM_CAPTURETRIGGER_TIMERB_CMP1) || \
((CAPTURETRIGGER) == HRTIM_CAPTURETRIGGER_TIMERB_CMP2) || \
((CAPTURETRIGGER) == HRTIM_CAPTURETRIGGER_TC1_SET) || \
((CAPTURETRIGGER) == HRTIM_CAPTURETRIGGER_TC1_RESET) || \
((CAPTURETRIGGER) == HRTIM_CAPTURETRIGGER_TIMERC_CMP1) || \
((CAPTURETRIGGER) == HRTIM_CAPTURETRIGGER_TIMERC_CMP2) || \
((CAPTURETRIGGER) == HRTIM_CAPTURETRIGGER_TD1_SET) || \
((CAPTURETRIGGER) == HRTIM_CAPTURETRIGGER_TD1_RESET) || \
((CAPTURETRIGGER) == HRTIM_CAPTURETRIGGER_TIMERD_CMP1) || \
((CAPTURETRIGGER) == HRTIM_CAPTURETRIGGER_TIMERD_CMP2) || \
((CAPTURETRIGGER) == HRTIM_CAPTURETRIGGER_TE1_SET) || \
((CAPTURETRIGGER) == HRTIM_CAPTURETRIGGER_TE1_RESET) || \
((CAPTURETRIGGER) == HRTIM_CAPTURETRIGGER_TIMERE_CMP1) || \
((CAPTURETRIGGER) == HRTIM_CAPTURETRIGGER_TIMERE_CMP2))) \
|| \
(((TIMER) == HRTIM_TIMERINDEX_TIMER_B) && \
(((CAPTURETRIGGER) == HRTIM_CAPTURETRIGGER_TA1_SET) || \
((CAPTURETRIGGER) == HRTIM_CAPTURETRIGGER_TA1_RESET) || \
((CAPTURETRIGGER) == HRTIM_CAPTURETRIGGER_TIMERA_CMP1) || \
((CAPTURETRIGGER) == HRTIM_CAPTURETRIGGER_TIMERA_CMP2) || \
((CAPTURETRIGGER) == HRTIM_CAPTURETRIGGER_TC1_SET) || \
((CAPTURETRIGGER) == HRTIM_CAPTURETRIGGER_TC1_RESET) || \
((CAPTURETRIGGER) == HRTIM_CAPTURETRIGGER_TIMERC_CMP1) || \
((CAPTURETRIGGER) == HRTIM_CAPTURETRIGGER_TIMERC_CMP2) || \
((CAPTURETRIGGER) == HRTIM_CAPTURETRIGGER_TD1_SET) || \
((CAPTURETRIGGER) == HRTIM_CAPTURETRIGGER_TD1_RESET) || \
((CAPTURETRIGGER) == HRTIM_CAPTURETRIGGER_TIMERD_CMP1) || \
((CAPTURETRIGGER) == HRTIM_CAPTURETRIGGER_TIMERD_CMP2) || \
((CAPTURETRIGGER) == HRTIM_CAPTURETRIGGER_TE1_SET) || \
((CAPTURETRIGGER) == HRTIM_CAPTURETRIGGER_TE1_RESET) || \
((CAPTURETRIGGER) == HRTIM_CAPTURETRIGGER_TIMERE_CMP1) || \
((CAPTURETRIGGER) == HRTIM_CAPTURETRIGGER_TIMERE_CMP2))) \
|| \
(((TIMER) == HRTIM_TIMERINDEX_TIMER_C) && \
(((CAPTURETRIGGER) == HRTIM_CAPTURETRIGGER_TA1_SET) || \
((CAPTURETRIGGER) == HRTIM_CAPTURETRIGGER_TA1_RESET) || \
((CAPTURETRIGGER) == HRTIM_CAPTURETRIGGER_TIMERA_CMP1) || \
((CAPTURETRIGGER) == HRTIM_CAPTURETRIGGER_TIMERA_CMP2) || \
((CAPTURETRIGGER) == HRTIM_CAPTURETRIGGER_TB1_SET) || \
((CAPTURETRIGGER) == HRTIM_CAPTURETRIGGER_TB1_RESET) || \
((CAPTURETRIGGER) == HRTIM_CAPTURETRIGGER_TIMERB_CMP1) || \
((CAPTURETRIGGER) == HRTIM_CAPTURETRIGGER_TIMERB_CMP2) || \
((CAPTURETRIGGER) == HRTIM_CAPTURETRIGGER_TD1_SET) || \
((CAPTURETRIGGER) == HRTIM_CAPTURETRIGGER_TD1_RESET) || \
((CAPTURETRIGGER) == HRTIM_CAPTURETRIGGER_TIMERD_CMP1) || \
((CAPTURETRIGGER) == HRTIM_CAPTURETRIGGER_TIMERD_CMP2) || \
((CAPTURETRIGGER) == HRTIM_CAPTURETRIGGER_TE1_SET) || \
((CAPTURETRIGGER) == HRTIM_CAPTURETRIGGER_TE1_RESET) || \
((CAPTURETRIGGER) == HRTIM_CAPTURETRIGGER_TIMERE_CMP1) || \
((CAPTURETRIGGER) == HRTIM_CAPTURETRIGGER_TIMERE_CMP2))) \
|| \
(((TIMER) == HRTIM_TIMERINDEX_TIMER_D) && \
(((CAPTURETRIGGER) == HRTIM_CAPTURETRIGGER_TA1_SET) || \
((CAPTURETRIGGER) == HRTIM_CAPTURETRIGGER_TA1_RESET) || \
((CAPTURETRIGGER) == HRTIM_CAPTURETRIGGER_TIMERA_CMP1) || \
((CAPTURETRIGGER) == HRTIM_CAPTURETRIGGER_TIMERA_CMP2) || \
((CAPTURETRIGGER) == HRTIM_CAPTURETRIGGER_TB1_SET) || \
((CAPTURETRIGGER) == HRTIM_CAPTURETRIGGER_TB1_RESET) || \
((CAPTURETRIGGER) == HRTIM_CAPTURETRIGGER_TIMERB_CMP1) || \
((CAPTURETRIGGER) == HRTIM_CAPTURETRIGGER_TIMERB_CMP2) || \
((CAPTURETRIGGER) == HRTIM_CAPTURETRIGGER_TC1_SET) || \
((CAPTURETRIGGER) == HRTIM_CAPTURETRIGGER_TC1_RESET) || \
((CAPTURETRIGGER) == HRTIM_CAPTURETRIGGER_TIMERC_CMP1) || \
((CAPTURETRIGGER) == HRTIM_CAPTURETRIGGER_TIMERC_CMP2) || \
((CAPTURETRIGGER) == HRTIM_CAPTURETRIGGER_TE1_SET) || \
((CAPTURETRIGGER) == HRTIM_CAPTURETRIGGER_TE1_RESET) || \
((CAPTURETRIGGER) == HRTIM_CAPTURETRIGGER_TIMERE_CMP1) || \
((CAPTURETRIGGER) == HRTIM_CAPTURETRIGGER_TIMERE_CMP2))) \
|| \
(((TIMER) == HRTIM_TIMERINDEX_TIMER_E) && \
(((CAPTURETRIGGER) == HRTIM_CAPTURETRIGGER_TA1_SET) || \
((CAPTURETRIGGER) == HRTIM_CAPTURETRIGGER_TA1_RESET) || \
((CAPTURETRIGGER) == HRTIM_CAPTURETRIGGER_TIMERA_CMP1) || \
((CAPTURETRIGGER) == HRTIM_CAPTURETRIGGER_TIMERA_CMP2) || \
((CAPTURETRIGGER) == HRTIM_CAPTURETRIGGER_TB1_SET) || \
((CAPTURETRIGGER) == HRTIM_CAPTURETRIGGER_TB1_RESET) || \
((CAPTURETRIGGER) == HRTIM_CAPTURETRIGGER_TIMERB_CMP1) || \
((CAPTURETRIGGER) == HRTIM_CAPTURETRIGGER_TIMERB_CMP2) || \
((CAPTURETRIGGER) == HRTIM_CAPTURETRIGGER_TC1_SET) || \
((CAPTURETRIGGER) == HRTIM_CAPTURETRIGGER_TC1_RESET) || \
((CAPTURETRIGGER) == HRTIM_CAPTURETRIGGER_TIMERC_CMP1) || \
((CAPTURETRIGGER) == HRTIM_CAPTURETRIGGER_TIMERC_CMP2) || \
((CAPTURETRIGGER) == HRTIM_CAPTURETRIGGER_TD1_SET) || \
((CAPTURETRIGGER) == HRTIM_CAPTURETRIGGER_TD1_RESET) || \
((CAPTURETRIGGER) == HRTIM_CAPTURETRIGGER_TIMERD_CMP1) || \
((CAPTURETRIGGER) == HRTIM_CAPTURETRIGGER_TIMERD_CMP2))) \
|| \
(((TIMER) == HRTIM_TIMERINDEX_TIMER_F) && \
(((CAPTURETRIGGER) == HRTIM_CAPTURETRIGGER_TA1_SET) || \
((CAPTURETRIGGER) == HRTIM_CAPTURETRIGGER_TA1_RESET) || \
((CAPTURETRIGGER) == HRTIM_CAPTURETRIGGER_TIMERA_CMP1) || \
((CAPTURETRIGGER) == HRTIM_CAPTURETRIGGER_TIMERA_CMP2) || \
((CAPTURETRIGGER) == HRTIM_CAPTURETRIGGER_TB1_SET) || \
((CAPTURETRIGGER) == HRTIM_CAPTURETRIGGER_TB1_RESET) || \
((CAPTURETRIGGER) == HRTIM_CAPTURETRIGGER_TIMERB_CMP1) || \
((CAPTURETRIGGER) == HRTIM_CAPTURETRIGGER_TIMERB_CMP2) || \
((CAPTURETRIGGER) == HRTIM_CAPTURETRIGGER_TC1_SET) || \
((CAPTURETRIGGER) == HRTIM_CAPTURETRIGGER_TC1_RESET) || \
((CAPTURETRIGGER) == HRTIM_CAPTURETRIGGER_TIMERC_CMP1) || \
((CAPTURETRIGGER) == HRTIM_CAPTURETRIGGER_TIMERC_CMP2) || \
((CAPTURETRIGGER) == HRTIM_CAPTURETRIGGER_TD1_SET) || \
((CAPTURETRIGGER) == HRTIM_CAPTURETRIGGER_TD1_RESET) || \
((CAPTURETRIGGER) == HRTIM_CAPTURETRIGGER_TIMERD_CMP1) || \
((CAPTURETRIGGER) == HRTIM_CAPTURETRIGGER_TIMERD_CMP2) || \
((CAPTURETRIGGER) == HRTIM_CAPTURETRIGGER_TE1_SET) || \
((CAPTURETRIGGER) == HRTIM_CAPTURETRIGGER_TE1_RESET) || \
((CAPTURETRIGGER) == HRTIM_CAPTURETRIGGER_TIMERE_CMP1) || \
((CAPTURETRIGGER) == HRTIM_CAPTURETRIGGER_TIMERE_CMP2))))
#define IS_HRTIM_TIMER_CAPTUREFTRIGGER(TIMER, CAPTUREFTRIGGER) \
( ((CAPTUREFTRIGGER) == HRTIM_CAPTUREFTRIGGER_NONE) || \
((CAPTUREFTRIGGER) == HRTIM_CAPTUREFTRIGGER_TF1_SET) || \
((CAPTUREFTRIGGER) == HRTIM_CAPTUREFTRIGGER_TF1_RESET) || \
((CAPTUREFTRIGGER) == HRTIM_CAPTUREFTRIGGER_TIMERF_CMP1) || \
((CAPTUREFTRIGGER) == HRTIM_CAPTUREFTRIGGER_TIMERF_CMP2))
#define IS_HRTIM_TIMEVENTFILTER(TIMER,TIMEVENTFILTER)\
(((TIMEVENTFILTER) == HRTIM_TIMEEVFLT_NONE) || \
((TIMEVENTFILTER) == HRTIM_TIMEEVFLT_BLANKINGCMP1) || \
((TIMEVENTFILTER) == HRTIM_TIMEEVFLT_BLANKINGCMP2) || \
((TIMEVENTFILTER) == HRTIM_TIMEEVFLT_BLANKINGCMP3) || \
((TIMEVENTFILTER) == HRTIM_TIMEEVFLT_BLANKINGCMP4) || \
((TIMEVENTFILTER) == HRTIM_TIMEEVFLT_WINDOWINGCMP2) || \
((TIMEVENTFILTER) == HRTIM_TIMEEVFLT_WINDOWINGCMP3) || \
((TIMEVENTFILTER) == HRTIM_TIMEEVFLT_WINDOWINGTIM) \
|| \
(((TIMER) == HRTIM_TIMERINDEX_TIMER_A) && \
(((TIMEVENTFILTER) == HRTIM_TIMEEVFLT_BLANKING_TIMAEEF1_TIMBCMP1) || \
((TIMEVENTFILTER) == HRTIM_TIMEEVFLT_BLANKING_TIMAEEF2_TIMBCMP4) || \
((TIMEVENTFILTER) == HRTIM_TIMEEVFLT_BLANKING_TIMAEEF3_TIMBOUT2) || \
((TIMEVENTFILTER) == HRTIM_TIMEEVFLT_BLANKING_TIMAEEF4_TIMCCMP1) || \
((TIMEVENTFILTER) == HRTIM_TIMEEVFLT_BLANKING_TIMAEEF5_TIMCCMP4) || \
((TIMEVENTFILTER) == HRTIM_TIMEEVFLT_BLANKING_TIMAEEF6_TIMFCMP1) || \
((TIMEVENTFILTER) == HRTIM_TIMEEVFLT_BLANKING_TIMAEEF7_TIMDCMP1) || \
((TIMEVENTFILTER) == HRTIM_TIMEEVFLT_BLANKING_TIMAEEF8_TIMECMP2))) \
|| \
(((TIMER) == HRTIM_TIMERINDEX_TIMER_B) && \
(((TIMEVENTFILTER) == HRTIM_TIMEEVFLT_BLANKING_TIMBEEF1_TIMACMP1) || \
((TIMEVENTFILTER) == HRTIM_TIMEEVFLT_BLANKING_TIMBEEF2_TIMACMP4) || \
((TIMEVENTFILTER) == HRTIM_TIMEEVFLT_BLANKING_TIMBEEF3_TIMAOUT2) || \
((TIMEVENTFILTER) == HRTIM_TIMEEVFLT_BLANKING_TIMBEEF4_TIMCCMP1) || \
((TIMEVENTFILTER) == HRTIM_TIMEEVFLT_BLANKING_TIMBEEF5_TIMCCMP2) || \
((TIMEVENTFILTER) == HRTIM_TIMEEVFLT_BLANKING_TIMBEEF6_TIMFCMP2) || \
((TIMEVENTFILTER) == HRTIM_TIMEEVFLT_BLANKING_TIMBEEF7_TIMDCMP2) || \
((TIMEVENTFILTER) == HRTIM_TIMEEVFLT_BLANKING_TIMBEEF8_TIMECMP1))) \
|| \
(((TIMER) == HRTIM_TIMERINDEX_TIMER_C) && \
(((TIMEVENTFILTER) == HRTIM_TIMEEVFLT_BLANKING_TIMCEEF1_TIMACMP2) || \
((TIMEVENTFILTER) == HRTIM_TIMEEVFLT_BLANKING_TIMCEEF2_TIMBCMP1) || \
((TIMEVENTFILTER) == HRTIM_TIMEEVFLT_BLANKING_TIMCEEF3_TIMBCMP4) || \
((TIMEVENTFILTER) == HRTIM_TIMEEVFLT_BLANKING_TIMCEEF4_TIMFCMP1) || \
((TIMEVENTFILTER) == HRTIM_TIMEEVFLT_BLANKING_TIMCEEF5_TIMDCMP1) || \
((TIMEVENTFILTER) == HRTIM_TIMEEVFLT_BLANKING_TIMCEEF6_TIMDCMP4) || \
((TIMEVENTFILTER) == HRTIM_TIMEEVFLT_BLANKING_TIMCEEF7_TIMDOUT2) || \
((TIMEVENTFILTER) == HRTIM_TIMEEVFLT_BLANKING_TIMCEEF8_TIMECMP4))) \
|| \
(((TIMER) == HRTIM_TIMERINDEX_TIMER_D) && \
(((TIMEVENTFILTER) == HRTIM_TIMEEVFLT_BLANKING_TIMDEEF1_TIMACMP1) || \
((TIMEVENTFILTER) == HRTIM_TIMEEVFLT_BLANKING_TIMDEEF2_TIMBCMP2) || \
((TIMEVENTFILTER) == HRTIM_TIMEEVFLT_BLANKING_TIMDEEF3_TIMCCMP1) || \
((TIMEVENTFILTER) == HRTIM_TIMEEVFLT_BLANKING_TIMDEEF4_TIMCCMP2) || \
((TIMEVENTFILTER) == HRTIM_TIMEEVFLT_BLANKING_TIMDEEF5_TIMCOUT2) || \
((TIMEVENTFILTER) == HRTIM_TIMEEVFLT_BLANKING_TIMDEEF6_TIMECMP1) || \
((TIMEVENTFILTER) == HRTIM_TIMEEVFLT_BLANKING_TIMDEEF7_TIMECMP4) || \
((TIMEVENTFILTER) == HRTIM_TIMEEVFLT_BLANKING_TIMDEEF8_TIMFCMP4))) \
|| \
(((TIMER) == HRTIM_TIMERINDEX_TIMER_E) && \
(((TIMEVENTFILTER) == HRTIM_TIMEEVFLT_BLANKING_TIMEEEF1_TIMACMP2) || \
((TIMEVENTFILTER) == HRTIM_TIMEEVFLT_BLANKING_TIMEEEF2_TIMBCMP1) || \
((TIMEVENTFILTER) == HRTIM_TIMEEVFLT_BLANKING_TIMEEEF3_TIMCCMP1) || \
((TIMEVENTFILTER) == HRTIM_TIMEEVFLT_BLANKING_TIMEEEF4_TIMFCMP4) || \
((TIMEVENTFILTER) == HRTIM_TIMEEVFLT_BLANKING_TIMEEEF5_TIMFOUT2) || \
((TIMEVENTFILTER) == HRTIM_TIMEEVFLT_BLANKING_TIMEEEF6_TIMDCMP1) || \
((TIMEVENTFILTER) == HRTIM_TIMEEVFLT_BLANKING_TIMEEEF7_TIMDCMP4) || \
((TIMEVENTFILTER) == HRTIM_TIMEEVFLT_BLANKING_TIMEEEF8_TIMDOUT2))) \
|| \
(((TIMER) == HRTIM_TIMERINDEX_TIMER_F) && \
(((TIMEVENTFILTER) == HRTIM_TIMEEVFLT_BLANKING_TIMFEEF1_TIMACMP4) || \
((TIMEVENTFILTER) == HRTIM_TIMEEVFLT_BLANKING_TIMFEEF2_TIMBCMP2) || \
((TIMEVENTFILTER) == HRTIM_TIMEEVFLT_BLANKING_TIMFEEF3_TIMCCMP4) || \
((TIMEVENTFILTER) == HRTIM_TIMEEVFLT_BLANKING_TIMFEEF4_TIMDCMP2) || \
((TIMEVENTFILTER) == HRTIM_TIMEEVFLT_BLANKING_TIMFEEF5_TIMDCMP4) || \
((TIMEVENTFILTER) == HRTIM_TIMEEVFLT_BLANKING_TIMFEEF6_TIMECMP1) || \
((TIMEVENTFILTER) == HRTIM_TIMEEVFLT_BLANKING_TIMFEEF7_TIMECMP4) || \
((TIMEVENTFILTER) == HRTIM_TIMEEVFLT_BLANKING_TIMFEEF8_TIMEOUT2))))
#define IS_HRTIM_TIMEVENTLATCH(TIMEVENTLATCH)\
(((TIMEVENTLATCH) == HRTIM_TIMEVENTLATCH_DISABLED) || \
((TIMEVENTLATCH) == HRTIM_TIMEVENTLATCH_ENABLED))
#define IS_HRTIM_TIMDEADTIME_PRESCALERRATIO(PRESCALERRATIO)\
(((PRESCALERRATIO) == HRTIM_TIMDEADTIME_PRESCALERRATIO_MUL8) || \
((PRESCALERRATIO) == HRTIM_TIMDEADTIME_PRESCALERRATIO_MUL4) || \
((PRESCALERRATIO) == HRTIM_TIMDEADTIME_PRESCALERRATIO_MUL2) || \
((PRESCALERRATIO) == HRTIM_TIMDEADTIME_PRESCALERRATIO_DIV1) || \
((PRESCALERRATIO) == HRTIM_TIMDEADTIME_PRESCALERRATIO_DIV2) || \
((PRESCALERRATIO) == HRTIM_TIMDEADTIME_PRESCALERRATIO_DIV4) || \
((PRESCALERRATIO) == HRTIM_TIMDEADTIME_PRESCALERRATIO_DIV8) || \
((PRESCALERRATIO) == HRTIM_TIMDEADTIME_PRESCALERRATIO_DIV16))
#define IS_HRTIM_TIMDEADTIME_RISINGSIGN(RISINGSIGN)\
(((RISINGSIGN) == HRTIM_TIMDEADTIME_RISINGSIGN_POSITIVE) || \
((RISINGSIGN) == HRTIM_TIMDEADTIME_RISINGSIGN_NEGATIVE))
#define IS_HRTIM_TIMDEADTIME_RISINGLOCK(RISINGLOCK)\
(((RISINGLOCK) == HRTIM_TIMDEADTIME_RISINGLOCK_WRITE) || \
((RISINGLOCK) == HRTIM_TIMDEADTIME_RISINGLOCK_READONLY))
#define IS_HRTIM_TIMDEADTIME_RISINGSIGNLOCK(RISINGSIGNLOCK)\
(((RISINGSIGNLOCK) == HRTIM_TIMDEADTIME_RISINGSIGNLOCK_WRITE) || \
((RISINGSIGNLOCK) == HRTIM_TIMDEADTIME_RISINGSIGNLOCK_READONLY))
#define IS_HRTIM_TIMDEADTIME_FALLINGSIGN(FALLINGSIGN)\
(((FALLINGSIGN) == HRTIM_TIMDEADTIME_FALLINGSIGN_POSITIVE) || \
((FALLINGSIGN) == HRTIM_TIMDEADTIME_FALLINGSIGN_NEGATIVE))
#define IS_HRTIM_TIMDEADTIME_FALLINGLOCK(FALLINGLOCK)\
(((FALLINGLOCK) == HRTIM_TIMDEADTIME_FALLINGLOCK_WRITE) || \
((FALLINGLOCK) == HRTIM_TIMDEADTIME_FALLINGLOCK_READONLY))
#define IS_HRTIM_TIMDEADTIME_FALLINGSIGNLOCK(FALLINGSIGNLOCK)\
(((FALLINGSIGNLOCK) == HRTIM_TIMDEADTIME_FALLINGSIGNLOCK_WRITE) || \
((FALLINGSIGNLOCK) == HRTIM_TIMDEADTIME_FALLINGSIGNLOCK_READONLY))
#define IS_HRTIM_CHOPPER_PRESCALERRATIO(PRESCALERRATIO)\
(((PRESCALERRATIO) == HRTIM_CHOPPER_PRESCALERRATIO_DIV16) || \
((PRESCALERRATIO) == HRTIM_CHOPPER_PRESCALERRATIO_DIV32) || \
((PRESCALERRATIO) == HRTIM_CHOPPER_PRESCALERRATIO_DIV48) || \
((PRESCALERRATIO) == HRTIM_CHOPPER_PRESCALERRATIO_DIV64) || \
((PRESCALERRATIO) == HRTIM_CHOPPER_PRESCALERRATIO_DIV80) || \
((PRESCALERRATIO) == HRTIM_CHOPPER_PRESCALERRATIO_DIV96) || \
((PRESCALERRATIO) == HRTIM_CHOPPER_PRESCALERRATIO_DIV112) || \
((PRESCALERRATIO) == HRTIM_CHOPPER_PRESCALERRATIO_DIV128) || \
((PRESCALERRATIO) == HRTIM_CHOPPER_PRESCALERRATIO_DIV144) || \
((PRESCALERRATIO) == HRTIM_CHOPPER_PRESCALERRATIO_DIV160) || \
((PRESCALERRATIO) == HRTIM_CHOPPER_PRESCALERRATIO_DIV176) || \
((PRESCALERRATIO) == HRTIM_CHOPPER_PRESCALERRATIO_DIV192) || \
((PRESCALERRATIO) == HRTIM_CHOPPER_PRESCALERRATIO_DIV208) || \
((PRESCALERRATIO) == HRTIM_CHOPPER_PRESCALERRATIO_DIV224) || \
((PRESCALERRATIO) == HRTIM_CHOPPER_PRESCALERRATIO_DIV240) || \
((PRESCALERRATIO) == HRTIM_CHOPPER_PRESCALERRATIO_DIV256))
#define IS_HRTIM_CHOPPER_DUTYCYCLE(DUTYCYCLE)\
(((DUTYCYCLE) == HRTIM_CHOPPER_DUTYCYCLE_0) || \
((DUTYCYCLE) == HRTIM_CHOPPER_DUTYCYCLE_125) || \
((DUTYCYCLE) == HRTIM_CHOPPER_DUTYCYCLE_250) || \
((DUTYCYCLE) == HRTIM_CHOPPER_DUTYCYCLE_375) || \
((DUTYCYCLE) == HRTIM_CHOPPER_DUTYCYCLE_500) || \
((DUTYCYCLE) == HRTIM_CHOPPER_DUTYCYCLE_625) || \
((DUTYCYCLE) == HRTIM_CHOPPER_DUTYCYCLE_750) || \
((DUTYCYCLE) == HRTIM_CHOPPER_DUTYCYCLE_875))
#define IS_HRTIM_CHOPPER_PULSEWIDTH(PULSEWIDTH)\
(((PULSEWIDTH) == HRTIM_CHOPPER_PULSEWIDTH_16) || \
((PULSEWIDTH) == HRTIM_CHOPPER_PULSEWIDTH_32) || \
((PULSEWIDTH) == HRTIM_CHOPPER_PULSEWIDTH_48) || \
((PULSEWIDTH) == HRTIM_CHOPPER_PULSEWIDTH_64) || \
((PULSEWIDTH) == HRTIM_CHOPPER_PULSEWIDTH_80) || \
((PULSEWIDTH) == HRTIM_CHOPPER_PULSEWIDTH_96) || \
((PULSEWIDTH) == HRTIM_CHOPPER_PULSEWIDTH_112) || \
((PULSEWIDTH) == HRTIM_CHOPPER_PULSEWIDTH_128) || \
((PULSEWIDTH) == HRTIM_CHOPPER_PULSEWIDTH_144) || \
((PULSEWIDTH) == HRTIM_CHOPPER_PULSEWIDTH_160) || \
((PULSEWIDTH) == HRTIM_CHOPPER_PULSEWIDTH_176) || \
((PULSEWIDTH) == HRTIM_CHOPPER_PULSEWIDTH_192) || \
((PULSEWIDTH) == HRTIM_CHOPPER_PULSEWIDTH_208) || \
((PULSEWIDTH) == HRTIM_CHOPPER_PULSEWIDTH_224) || \
((PULSEWIDTH) == HRTIM_CHOPPER_PULSEWIDTH_240) || \
((PULSEWIDTH) == HRTIM_CHOPPER_PULSEWIDTH_256))
#define IS_HRTIM_SYNCINPUTSOURCE(SYNCINPUTSOURCE)\
(((SYNCINPUTSOURCE) == HRTIM_SYNCINPUTSOURCE_NONE) || \
((SYNCINPUTSOURCE) == HRTIM_SYNCINPUTSOURCE_INTERNALEVENT) || \
((SYNCINPUTSOURCE) == HRTIM_SYNCINPUTSOURCE_EXTERNALEVENT))
#define IS_HRTIM_SYNCOUTPUTSOURCE(SYNCOUTPUTSOURCE)\
(((SYNCOUTPUTSOURCE) == HRTIM_SYNCOUTPUTSOURCE_MASTER_START) || \
((SYNCOUTPUTSOURCE) == HRTIM_SYNCOUTPUTSOURCE_MASTER_CMP1) || \
((SYNCOUTPUTSOURCE) == HRTIM_SYNCOUTPUTSOURCE_TIMA_START) || \
((SYNCOUTPUTSOURCE) == HRTIM_SYNCOUTPUTSOURCE_TIMA_CMP1))
#define IS_HRTIM_SYNCOUTPUTPOLARITY(SYNCOUTPUTPOLARITY)\
(((SYNCOUTPUTPOLARITY) == HRTIM_SYNCOUTPUTPOLARITY_NONE) || \
((SYNCOUTPUTPOLARITY) == HRTIM_SYNCOUTPUTPOLARITY_POSITIVE) || \
((SYNCOUTPUTPOLARITY) == HRTIM_SYNCOUTPUTPOLARITY_NEGATIVE))
#define IS_HRTIM_EVENTSRC(EVENT, EVENTSRC) \
((((EVENT) == HRTIM_EVENT_1) && \
(((EVENTSRC) == HRTIM_EEV1SRC_GPIO ) || \
((EVENTSRC) == HRTIM_EEV1SRC_COMP2_OUT ) || \
((EVENTSRC) == HRTIM_EEV1SRC_TIM1_TRGO ) || \
((EVENTSRC) == HRTIM_EEV1SRC_ADC1_AWD1 ))) \
|| \
(((EVENT) == HRTIM_EVENT_2) && \
(((EVENTSRC) == HRTIM_EEV2SRC_GPIO ) || \
((EVENTSRC) == HRTIM_EEV2SRC_COMP4_OUT ) || \
((EVENTSRC) == HRTIM_EEV2SRC_TIM2_TRGO ) || \
((EVENTSRC) == HRTIM_EEV2SRC_ADC1_AWD2 ))) \
|| \
(((EVENT) == HRTIM_EVENT_3) && \
(((EVENTSRC) == HRTIM_EEV3SRC_GPIO ) || \
((EVENTSRC) == HRTIM_EEV3SRC_COMP6_OUT ) || \
((EVENTSRC) == HRTIM_EEV3SRC_TIM3_TRGO ) || \
((EVENTSRC) == HRTIM_EEV3SRC_ADC1_AWD3 ))) \
|| \
(((EVENT) == HRTIM_EVENT_4) && \
(((EVENTSRC) == HRTIM_EEV4SRC_GPIO ) || \
((EVENTSRC) == HRTIM_EEV4SRC_COMP1_OUT ) || \
((EVENTSRC) == HRTIM_EEV4SRC_COMP5_OUT ) || \
((EVENTSRC) == HRTIM_EEV4SRC_ADC2_AWD1 ))) \
|| \
(((EVENT) == HRTIM_EVENT_5) && \
(((EVENTSRC) == HRTIM_EEV5SRC_GPIO ) || \
((EVENTSRC) == HRTIM_EEV5SRC_COMP3_OUT ) || \
((EVENTSRC) == HRTIM_EEV5SRC_COMP7_OUT ) || \
((EVENTSRC) == HRTIM_EEV5SRC_ADC2_AWD2 ))) \
|| \
(((EVENT) == HRTIM_EVENT_6) && \
(((EVENTSRC) == HRTIM_EEV6SRC_GPIO ) || \
((EVENTSRC) == HRTIM_EEV6SRC_COMP2_OUT ) || \
((EVENTSRC) == HRTIM_EEV6SRC_COMP1_OUT ) || \
((EVENTSRC) == HRTIM_EEV6SRC_ADC2_AWD3 ))) \
|| \
(((EVENT) == HRTIM_EVENT_7) && \
(((EVENTSRC) == HRTIM_EEV7SRC_GPIO ) || \
((EVENTSRC) == HRTIM_EEV7SRC_COMP4_OUT ) || \
((EVENTSRC) == HRTIM_EEV7SRC_TIM7_TRGO ) || \
((EVENTSRC) == HRTIM_EEV7SRC_ADC3_AWD1 ))) \
|| \
(((EVENT) == HRTIM_EVENT_8) && \
(((EVENTSRC) == HRTIM_EEV8SRC_GPIO ) || \
((EVENTSRC) == HRTIM_EEV8SRC_COMP6_OUT ) || \
((EVENTSRC) == HRTIM_EEV8SRC_COMP3_OUT ) || \
((EVENTSRC) == HRTIM_EEV8SRC_ADC4_AWD1 ))) \
|| \
(((EVENT) == HRTIM_EVENT_9) && \
(((EVENTSRC) == HRTIM_EEV9SRC_GPIO ) || \
((EVENTSRC) == HRTIM_EEV9SRC_COMP5_OUT ) || \
((EVENTSRC) == HRTIM_EEV9SRC_TIM15_TRGO) || \
((EVENTSRC) == HRTIM_EEV9SRC_COMP4_OUT ))) \
|| \
(((EVENT) == HRTIM_EVENT_10) && \
(((EVENTSRC) == HRTIM_EEV10SRC_GPIO ) || \
((EVENTSRC) == HRTIM_EEV10SRC_COMP7_OUT) || \
((EVENTSRC) == HRTIM_EEV10SRC_TIM6_TRGO) || \
((EVENTSRC) == HRTIM_EEV10SRC_ADC5_AWD1))))
#define IS_HRTIM_EVENTPOLARITY(EVENTSENSITIVITY, EVENTPOLARITY)\
((((EVENTSENSITIVITY) == HRTIM_EVENTSENSITIVITY_LEVEL) && \
(((EVENTPOLARITY) == HRTIM_EVENTPOLARITY_HIGH) || \
((EVENTPOLARITY) == HRTIM_EVENTPOLARITY_LOW))) \
|| \
(((EVENTSENSITIVITY) == HRTIM_EVENTSENSITIVITY_RISINGEDGE) || \
((EVENTSENSITIVITY) == HRTIM_EVENTSENSITIVITY_FALLINGEDGE)|| \
((EVENTSENSITIVITY) == HRTIM_EVENTSENSITIVITY_BOTHEDGES)))
#define IS_HRTIM_EVENTSENSITIVITY(EVENTSENSITIVITY)\
(((EVENTSENSITIVITY) == HRTIM_EVENTSENSITIVITY_LEVEL) || \
((EVENTSENSITIVITY) == HRTIM_EVENTSENSITIVITY_RISINGEDGE) || \
((EVENTSENSITIVITY) == HRTIM_EVENTSENSITIVITY_FALLINGEDGE) || \
((EVENTSENSITIVITY) == HRTIM_EVENTSENSITIVITY_BOTHEDGES))
#define IS_HRTIM_EVENTFASTMODE(EVENT, FASTMODE)\
(((((EVENT) == HRTIM_EVENT_1) || \
((EVENT) == HRTIM_EVENT_2) || \
((EVENT) == HRTIM_EVENT_3) || \
((EVENT) == HRTIM_EVENT_4) || \
((EVENT) == HRTIM_EVENT_5)) && \
(((FASTMODE) == HRTIM_EVENTFASTMODE_ENABLE) || \
((FASTMODE) == HRTIM_EVENTFASTMODE_DISABLE))) \
|| \
(((EVENT) == HRTIM_EVENT_6) || \
((EVENT) == HRTIM_EVENT_7) || \
((EVENT) == HRTIM_EVENT_8) || \
((EVENT) == HRTIM_EVENT_9) || \
((EVENT) == HRTIM_EVENT_10)))
#define IS_HRTIM_EVENTFILTER(EVENT, FILTER)\
((((EVENT) == HRTIM_EVENT_1) || \
((EVENT) == HRTIM_EVENT_2) || \
((EVENT) == HRTIM_EVENT_3) || \
((EVENT) == HRTIM_EVENT_4) || \
((EVENT) == HRTIM_EVENT_5)) \
|| \
((((EVENT) == HRTIM_EVENT_6) || \
((EVENT) == HRTIM_EVENT_7) || \
((EVENT) == HRTIM_EVENT_8) || \
((EVENT) == HRTIM_EVENT_9) || \
((EVENT) == HRTIM_EVENT_10)) && \
(((FILTER) == HRTIM_EVENTFILTER_NONE) || \
((FILTER) == HRTIM_EVENTFILTER_1) || \
((FILTER) == HRTIM_EVENTFILTER_2) || \
((FILTER) == HRTIM_EVENTFILTER_3) || \
((FILTER) == HRTIM_EVENTFILTER_4) || \
((FILTER) == HRTIM_EVENTFILTER_5) || \
((FILTER) == HRTIM_EVENTFILTER_6) || \
((FILTER) == HRTIM_EVENTFILTER_7) || \
((FILTER) == HRTIM_EVENTFILTER_8) || \
((FILTER) == HRTIM_EVENTFILTER_9) || \
((FILTER) == HRTIM_EVENTFILTER_10) || \
((FILTER) == HRTIM_EVENTFILTER_11) || \
((FILTER) == HRTIM_EVENTFILTER_12) || \
((FILTER) == HRTIM_EVENTFILTER_13) || \
((FILTER) == HRTIM_EVENTFILTER_14) || \
((FILTER) == HRTIM_EVENTFILTER_15))))
#define IS_HRTIM_EVENTPRESCALER(EVENTPRESCALER)\
(((EVENTPRESCALER) == HRTIM_EVENTPRESCALER_DIV1) || \
((EVENTPRESCALER) == HRTIM_EVENTPRESCALER_DIV2) || \
((EVENTPRESCALER) == HRTIM_EVENTPRESCALER_DIV4) || \
((EVENTPRESCALER) == HRTIM_EVENTPRESCALER_DIV8))
#define IS_HRTIM_FAULTSOURCE(FAULTSOURCE)\
(((FAULTSOURCE) == HRTIM_FAULTSOURCE_DIGITALINPUT) || \
((FAULTSOURCE) == HRTIM_FAULTSOURCE_INTERNAL) || \
((FAULTSOURCE) == HRTIM_FAULTSOURCE_EEVINPUT))
#define IS_HRTIM_FAULTPOLARITY(HRTIM_FAULTPOLARITY)\
(((HRTIM_FAULTPOLARITY) == HRTIM_FAULTPOLARITY_LOW) || \
((HRTIM_FAULTPOLARITY) == HRTIM_FAULTPOLARITY_HIGH))
#define IS_HRTIM_FAULTMODECTL(FAULTMODECTL)\
(((FAULTMODECTL) == HRTIM_FAULTMODECTL_DISABLED) || \
((FAULTMODECTL) == HRTIM_FAULTMODECTL_ENABLED))
#define IS_HRTIM_FAULTBLANKNGMODE(FAULTBLANKINGMODE)\
(((FAULTBLANKINGMODE) == HRTIM_FAULTBLANKINGMODE_RSTALIGNED) || \
((FAULTBLANKINGMODE) == HRTIM_FAULTBLANKINGMODE_MOVING))
#define IS_HRTIM_FAULTBLANKING(FAULTBLANKINGCTL)\
(((FAULTBLANKINGCTL) == HRTIM_FAULTBLANKING_DISABLED) || \
((FAULTBLANKINGCTL) == HRTIM_FAULTBLANKING_ENABLED))
#define IS_HRTIM_FAULTCOUNTERRST(HRTIM_FAULTCOUNTERRST)\
(((HRTIM_FAULTCOUNTERRST) == HRTIM_FAULTCOUNTERRST_UNCONDITIONAL) || \
((HRTIM_FAULTCOUNTERRST) == HRTIM_FAULTCOUNTERRST_CONDITIONAL))
#define IS_HRTIM_FAULTBLANKINGCTL(FAULTBLANKINGCTL)\
(((FAULTBLANKINGCTL) == HRTIM_FAULTBLANKINGCTL_DISABLED) || \
((FAULTBLANKINGCTL) == HRTIM_FAULTBLANKINGCTL_ENABLED))
#define IS_HRTIM_FAULTCOUNTER(FAULTCOUNTER)\
(((FAULTCOUNTER) == HRTIM_FAULTCOUNTER_NONE) || \
((FAULTCOUNTER) == HRTIM_FAULTCOUNTER_1) || \
((FAULTCOUNTER) == HRTIM_FAULTCOUNTER_2) || \
((FAULTCOUNTER) == HRTIM_FAULTCOUNTER_3) || \
((FAULTCOUNTER) == HRTIM_FAULTCOUNTER_4) || \
((FAULTCOUNTER) == HRTIM_FAULTCOUNTER_5) || \
((FAULTCOUNTER) == HRTIM_FAULTCOUNTER_6) || \
((FAULTCOUNTER) == HRTIM_FAULTCOUNTER_7) || \
((FAULTCOUNTER) == HRTIM_FAULTCOUNTER_8) || \
((FAULTCOUNTER) == HRTIM_FAULTCOUNTER_9) || \
((FAULTCOUNTER) == HRTIM_FAULTCOUNTER_10) || \
((FAULTCOUNTER) == HRTIM_FAULTCOUNTER_11) || \
((FAULTCOUNTER) == HRTIM_FAULTCOUNTER_12) || \
((FAULTCOUNTER) == HRTIM_FAULTCOUNTER_13) || \
((FAULTCOUNTER) == HRTIM_FAULTCOUNTER_14) || \
((FAULTCOUNTER) == HRTIM_FAULTCOUNTER_15))
#define IS_HRTIM_FAULTFILTER(FAULTFILTER)\
(((FAULTFILTER) == HRTIM_FAULTFILTER_NONE) || \
((FAULTFILTER) == HRTIM_FAULTFILTER_1) || \
((FAULTFILTER) == HRTIM_FAULTFILTER_2) || \
((FAULTFILTER) == HRTIM_FAULTFILTER_3) || \
((FAULTFILTER) == HRTIM_FAULTFILTER_4) || \
((FAULTFILTER) == HRTIM_FAULTFILTER_5) || \
((FAULTFILTER) == HRTIM_FAULTFILTER_6) || \
((FAULTFILTER) == HRTIM_FAULTFILTER_7) || \
((FAULTFILTER) == HRTIM_FAULTFILTER_8) || \
((FAULTFILTER) == HRTIM_FAULTFILTER_9) || \
((FAULTFILTER) == HRTIM_FAULTFILTER_10) || \
((FAULTFILTER) == HRTIM_FAULTFILTER_11) || \
((FAULTFILTER) == HRTIM_FAULTFILTER_12) || \
((FAULTFILTER) == HRTIM_FAULTFILTER_13) || \
((FAULTFILTER) == HRTIM_FAULTFILTER_14) || \
((FAULTFILTER) == HRTIM_FAULTFILTER_15))
#define IS_HRTIM_FAULTLOCK(FAULTLOCK)\
(((FAULTLOCK) == HRTIM_FAULTLOCK_READWRITE) || \
((FAULTLOCK) == HRTIM_FAULTLOCK_READONLY))
#define IS_HRTIM_FAULTPRESCALER(FAULTPRESCALER)\
(((FAULTPRESCALER) == HRTIM_FAULTPRESCALER_DIV1) || \
((FAULTPRESCALER) == HRTIM_FAULTPRESCALER_DIV2) || \
((FAULTPRESCALER) == HRTIM_FAULTPRESCALER_DIV4) || \
((FAULTPRESCALER) == HRTIM_FAULTPRESCALER_DIV8))
#define IS_HRTIM_BURSTMODE(BURSTMODE)\
(((BURSTMODE) == HRTIM_BURSTMODE_SINGLESHOT) || \
((BURSTMODE) == HRTIM_BURSTMODE_CONTINOUS))
#define IS_HRTIM_BURSTMODECLOCKSOURCE(BURSTMODECLOCKSOURCE)\
(((BURSTMODECLOCKSOURCE) == HRTIM_BURSTMODECLOCKSOURCE_MASTER) || \
((BURSTMODECLOCKSOURCE) == HRTIM_BURSTMODECLOCKSOURCE_TIMER_A) || \
((BURSTMODECLOCKSOURCE) == HRTIM_BURSTMODECLOCKSOURCE_TIMER_B) || \
((BURSTMODECLOCKSOURCE) == HRTIM_BURSTMODECLOCKSOURCE_TIMER_C) || \
((BURSTMODECLOCKSOURCE) == HRTIM_BURSTMODECLOCKSOURCE_TIMER_D) || \
((BURSTMODECLOCKSOURCE) == HRTIM_BURSTMODECLOCKSOURCE_TIMER_E) || \
((BURSTMODECLOCKSOURCE) == HRTIM_BURSTMODECLOCKSOURCE_TIMER_F) || \
((BURSTMODECLOCKSOURCE) == HRTIM_BURSTMODECLOCKSOURCE_TIM16_OC) || \
((BURSTMODECLOCKSOURCE) == HRTIM_BURSTMODECLOCKSOURCE_TIM17_OC) || \
((BURSTMODECLOCKSOURCE) == HRTIM_BURSTMODECLOCKSOURCE_TIM7_TRGO) || \
((BURSTMODECLOCKSOURCE) == HRTIM_BURSTMODECLOCKSOURCE_FHRTIM))
#define IS_HRTIM_HRTIM_BURSTMODEPRESCALER(BURSTMODEPRESCALER)\
(((BURSTMODEPRESCALER) == HRTIM_BURSTMODEPRESCALER_DIV1) || \
((BURSTMODEPRESCALER) == HRTIM_BURSTMODEPRESCALER_DIV2) || \
((BURSTMODEPRESCALER) == HRTIM_BURSTMODEPRESCALER_DIV4) || \
((BURSTMODEPRESCALER) == HRTIM_BURSTMODEPRESCALER_DIV8) || \
((BURSTMODEPRESCALER) == HRTIM_BURSTMODEPRESCALER_DIV16) || \
((BURSTMODEPRESCALER) == HRTIM_BURSTMODEPRESCALER_DIV32) || \
((BURSTMODEPRESCALER) == HRTIM_BURSTMODEPRESCALER_DIV64) || \
((BURSTMODEPRESCALER) == HRTIM_BURSTMODEPRESCALER_DIV128) || \
((BURSTMODEPRESCALER) == HRTIM_BURSTMODEPRESCALER_DIV256) || \
((BURSTMODEPRESCALER) == HRTIM_BURSTMODEPRESCALER_DIV512) || \
((BURSTMODEPRESCALER) == HRTIM_BURSTMODEPRESCALER_DIV1024) || \
((BURSTMODEPRESCALER) == HRTIM_BURSTMODEPRESCALER_DIV2048) || \
((BURSTMODEPRESCALER) == HRTIM_BURSTMODEPRESCALER_DIV4096) || \
((BURSTMODEPRESCALER) == HRTIM_BURSTMODEPRESCALER_DIV8192) || \
((BURSTMODEPRESCALER) == HRTIM_BURSTMODEPRESCALER_DIV16384) || \
((BURSTMODEPRESCALER) == HRTIM_BURSTMODEPRESCALER_DIV32768))
#define IS_HRTIM_BURSTMODEPRELOAD(BURSTMODEPRELOAD)\
(((BURSTMODEPRELOAD) == HRIM_BURSTMODEPRELOAD_DISABLED) || \
((BURSTMODEPRELOAD) == HRIM_BURSTMODEPRELOAD_ENABLED))
#define IS_HRTIM_BURSTMODETRIGGER(BURSTMODETRIGGER)\
(((BURSTMODETRIGGER) == HRTIM_BURSTMODETRIGGER_NONE) || \
((BURSTMODETRIGGER) == HRTIM_BURSTMODETRIGGER_MASTER_RESET) || \
((BURSTMODETRIGGER) == HRTIM_BURSTMODETRIGGER_MASTER_REPETITION) || \
((BURSTMODETRIGGER) == HRTIM_BURSTMODETRIGGER_MASTER_CMP1) || \
((BURSTMODETRIGGER) == HRTIM_BURSTMODETRIGGER_MASTER_CMP2) || \
((BURSTMODETRIGGER) == HRTIM_BURSTMODETRIGGER_MASTER_CMP3) || \
((BURSTMODETRIGGER) == HRTIM_BURSTMODETRIGGER_MASTER_CMP4) || \
((BURSTMODETRIGGER) == HRTIM_BURSTMODETRIGGER_TIMERA_RESET) || \
((BURSTMODETRIGGER) == HRTIM_BURSTMODETRIGGER_TIMERA_REPETITION) || \
((BURSTMODETRIGGER) == HRTIM_BURSTMODETRIGGER_TIMERA_CMP1) || \
((BURSTMODETRIGGER) == HRTIM_BURSTMODETRIGGER_TIMERA_CMP2) || \
((BURSTMODETRIGGER) == HRTIM_BURSTMODETRIGGER_TIMERB_RESET) || \
((BURSTMODETRIGGER) == HRTIM_BURSTMODETRIGGER_TIMERB_REPETITION) || \
((BURSTMODETRIGGER) == HRTIM_BURSTMODETRIGGER_TIMERB_CMP1) || \
((BURSTMODETRIGGER) == HRTIM_BURSTMODETRIGGER_TIMERB_CMP2) || \
((BURSTMODETRIGGER) == HRTIM_BURSTMODETRIGGER_TIMERC_RESET) || \
((BURSTMODETRIGGER) == HRTIM_BURSTMODETRIGGER_TIMERC_REPETITION) || \
((BURSTMODETRIGGER) == HRTIM_BURSTMODETRIGGER_TIMERC_CMP1) || \
((BURSTMODETRIGGER) == HRTIM_BURSTMODETRIGGER_TIMERF_RESET) || \
((BURSTMODETRIGGER) == HRTIM_BURSTMODETRIGGER_TIMERD_RESET) || \
((BURSTMODETRIGGER) == HRTIM_BURSTMODETRIGGER_TIMERD_REPETITION) || \
((BURSTMODETRIGGER) == HRTIM_BURSTMODETRIGGER_TIMERF_REPETITION) || \
((BURSTMODETRIGGER) == HRTIM_BURSTMODETRIGGER_TIMERD_CMP2) || \
((BURSTMODETRIGGER) == HRTIM_BURSTMODETRIGGER_TIMERF_CMP1) || \
((BURSTMODETRIGGER) == HRTIM_BURSTMODETRIGGER_TIMERE_REPETITION) || \
((BURSTMODETRIGGER) == HRTIM_BURSTMODETRIGGER_TIMERE_CMP1) || \
((BURSTMODETRIGGER) == HRTIM_BURSTMODETRIGGER_TIMERE_CMP2) || \
((BURSTMODETRIGGER) == HRTIM_BURSTMODETRIGGER_TIMERA_EVENT7) || \
((BURSTMODETRIGGER) == HRTIM_BURSTMODETRIGGER_TIMERD_EVENT8) || \
((BURSTMODETRIGGER) == HRTIM_BURSTMODETRIGGER_EVENT_7) || \
((BURSTMODETRIGGER) == HRTIM_BURSTMODETRIGGER_EVENT_8) || \
((BURSTMODETRIGGER) == HRTIM_BURSTMODETRIGGER_EVENT_ONCHIP))
#define IS_HRTIM_ADCTRIGGERUPDATE(ADCTRIGGERUPDATE)\
(((ADCTRIGGERUPDATE) == HRTIM_ADCTRIGGERUPDATE_MASTER) || \
((ADCTRIGGERUPDATE) == HRTIM_ADCTRIGGERUPDATE_TIMER_A) || \
((ADCTRIGGERUPDATE) == HRTIM_ADCTRIGGERUPDATE_TIMER_B) || \
((ADCTRIGGERUPDATE) == HRTIM_ADCTRIGGERUPDATE_TIMER_C) || \
((ADCTRIGGERUPDATE) == HRTIM_ADCTRIGGERUPDATE_TIMER_D) || \
((ADCTRIGGERUPDATE) == HRTIM_ADCTRIGGERUPDATE_TIMER_E) || \
((ADCTRIGGERUPDATE) == HRTIM_ADCTRIGGERUPDATE_TIMER_F))
#define IS_HRTIM_CALIBRATIONRATE(CALIBRATIONRATE)\
(((CALIBRATIONRATE) == HRTIM_SINGLE_CALIBRATION) || \
((CALIBRATIONRATE) == HRTIM_CALIBRATIONRATE_0) || \
((CALIBRATIONRATE) == HRTIM_CALIBRATIONRATE_1) || \
((CALIBRATIONRATE) == HRTIM_CALIBRATIONRATE_2) || \
((CALIBRATIONRATE) == HRTIM_CALIBRATIONRATE_3))
#define IS_HRTIM_TIMER_BURSTDMA(TIMER, BURSTDMA) \
((((TIMER) == HRTIM_TIMERINDEX_MASTER) && (((BURSTDMA) & 0xFFFFC000U) == 0x00000000U)) \
|| (((TIMER) == HRTIM_TIMERINDEX_TIMER_A) && (((BURSTDMA) & 0xFF800000U) == 0x00000000U)) \
|| (((TIMER) == HRTIM_TIMERINDEX_TIMER_B) && (((BURSTDMA) & 0xFF800000U) == 0x00000000U)) \
|| (((TIMER) == HRTIM_TIMERINDEX_TIMER_C) && (((BURSTDMA) & 0xFF800000U) == 0x00000000U)) \
|| (((TIMER) == HRTIM_TIMERINDEX_TIMER_D) && (((BURSTDMA) & 0xFF800000U) == 0x00000000U)) \
|| (((TIMER) == HRTIM_TIMERINDEX_TIMER_E) && (((BURSTDMA) & 0xFF800000U) == 0x00000000U)) \
|| (((TIMER) == HRTIM_TIMERINDEX_TIMER_F) && (((BURSTDMA) & 0xFF800000U) == 0x00000000U)))
#define IS_HRTIM_BURSTMODECTL(BURSTMODECTL)\
(((BURSTMODECTL) == HRTIM_BURSTMODECTL_DISABLED) || \
((BURSTMODECTL) == HRTIM_BURSTMODECTL_ENABLED))
#define IS_HRTIM_TIMERUPDATE(TIMERUPDATE) (((TIMERUPDATE) & 0xFFFFFF80U) == 0x00000000U)
#define IS_HRTIM_TIMERRESET(TIMERRESET) (((TIMERRESET) & 0xFFFF80FFU) == 0x00000000U)
#define IS_HRTIM_TIMERSWAP(TIMERSWAP) (((TIMERSWAP) & 0xFFC0FFFFU) == 0x00000000U)
#define IS_HRTIM_IT(IT) (((IT) & 0xFFFCFF80U) == 0x00000000U)
#define IS_HRTIM_MASTER_IT(MASTER_IT) (((MASTER_IT) & 0xFFFFFF80U) == 0x00000000U)
#define IS_HRTIM_TIM_IT(TIM_IT) (((TIM_IT) & 0xFFFF8020U) == 0x00000000U)
#define IS_HRTIM_MASTER_DMA(MASTER_DMA) (((MASTER_DMA) & 0xFF80FFFFU) == 0x00000000U)
#define IS_HRTIM_TIM_DMA(TIM_DMA) (((TIM_DMA) & 0x8020FFFFU) == 0x00000000U)
/**
* @}
*/
/* Exported macros -----------------------------------------------------------*/
/** @defgroup HRTIM_Exported_Macros HRTIM Exported Macros
* @{
*/
/**
* @brief configures the actual direction of the counter to UP counting mode
* @param __HANDLE__ : HRTIM handle.
* @param __TIMER__ : Timer index
* This parameter can be a combination of the following values:
* @arg HRTIM_TIMERINDEX_TIMER_A for timer A
* @arg HRTIM_TIMERINDEX_TIMER_B for timer B
* @arg HRTIM_TIMERINDEX_TIMER_C for timer C
* @arg HRTIM_TIMERINDEX_TIMER_D for timer D
* @arg HRTIM_TIMERINDEX_TIMER_E for timer E
* @arg HRTIM_TIMERINDEX_TIMER_F for timer F
* @retval none
*/
#define __HAL_HRTIM_COUNTER_MODE_UP(__HANDLE__, __TIMERS__)\
do {\
if (((__TIMERS__) & HRTIM_TIMERINDEX_TIMER_A) == HRTIM_TIMERINDEX_TIMER_A)\
{\
CLEAR_BIT((__HANDLE__)->Instance->sTimerxRegs[(HRTIM_TIMERINDEX_TIMER_A)].TIMxCR2 , (HRTIM_TIMCR2_UDM)); \
}\
if (((__TIMERS__) & HRTIM_TIMERINDEX_TIMER_B) == HRTIM_TIMERINDEX_TIMER_B)\
{\
CLEAR_BIT((__HANDLE__)->Instance->sTimerxRegs[(HRTIM_TIMERINDEX_TIMER_B)].TIMxCR2 , (HRTIM_TIMCR2_UDM)); \
}\
if (((__TIMERS__) & HRTIM_TIMERINDEX_TIMER_C) == HRTIM_TIMERINDEX_TIMER_C)\
{\
CLEAR_BIT((__HANDLE__)->Instance->sTimerxRegs[(HRTIM_TIMERINDEX_TIMER_C)].TIMxCR2 , (HRTIM_TIMCR2_UDM)); \
}\
if (((__TIMERS__) & HRTIM_TIMERINDEX_TIMER_D) == HRTIM_TIMERINDEX_TIMER_D)\
{\
CLEAR_BIT((__HANDLE__)->Instance->sTimerxRegs[(HRTIM_TIMERINDEX_TIMER_D)].TIMxCR2 , (HRTIM_TIMCR2_UDM)); \
}\
if (((__TIMERS__) & HRTIM_TIMERINDEX_TIMER_E) == HRTIM_TIMERINDEX_TIMER_E)\
{\
CLEAR_BIT((__HANDLE__)->Instance->sTimerxRegs[(HRTIM_TIMERINDEX_TIMER_E)].TIMxCR2 , (HRTIM_TIMCR2_UDM)); \
}\
if (((__TIMERS__) & HRTIM_TIMERINDEX_TIMER_F) == HRTIM_TIMERINDEX_TIMER_F)\
{\
CLEAR_BIT((__HANDLE__)->Instance->sTimerxRegs[(HRTIM_TIMERINDEX_TIMER_F)].TIMxCR2 , (HRTIM_TIMCR2_UDM)); \
}\
} while(0U)
/**
* @brief configures the actual direction of the counter to UP-DOWN counting mode
* @param __HANDLE__ : HRTIM handle.
* @param __TIMER__ : Timer index
* This parameter can be a combination of the following values:
* @arg HRTIM_TIMERINDEX_TIMER_A for timer A
* @arg HRTIM_TIMERINDEX_TIMER_B for timer B
* @arg HRTIM_TIMERINDEX_TIMER_C for timer C
* @arg HRTIM_TIMERINDEX_TIMER_D for timer D
* @arg HRTIM_TIMERINDEX_TIMER_E for timer E
* @arg HRTIM_TIMERINDEX_TIMER_F for timer F
* @retval none
*/
#define __HAL_HRTIM_COUNTER_MODE_UPDOWN(__HANDLE__, __TIMERS__)\
do {\
if (((__TIMERS__) & HRTIM_TIMERINDEX_TIMER_A) == HRTIM_TIMERINDEX_TIMER_A)\
{\
SET_BIT((__HANDLE__)->Instance->sTimerxRegs[(HRTIM_TIMERINDEX_TIMER_A)].TIMxCR2 , (HRTIM_TIMCR2_UDM)); \
}\
if (((__TIMERS__) & HRTIM_TIMERINDEX_TIMER_B) == HRTIM_TIMERINDEX_TIMER_B)\
{\
SET_BIT((__HANDLE__)->Instance->sTimerxRegs[(HRTIM_TIMERINDEX_TIMER_B)].TIMxCR2 , (HRTIM_TIMCR2_UDM)); \
}\
if (((__TIMERS__) & HRTIM_TIMERINDEX_TIMER_C) == HRTIM_TIMERINDEX_TIMER_C)\
{\
SET_BIT((__HANDLE__)->Instance->sTimerxRegs[(HRTIM_TIMERINDEX_TIMER_C)].TIMxCR2 , (HRTIM_TIMCR2_UDM)); \
}\
if (((__TIMERS__) & HRTIM_TIMERINDEX_TIMER_D) == HRTIM_TIMERINDEX_TIMER_D)\
{\
SET_BIT((__HANDLE__)->Instance->sTimerxRegs[(HRTIM_TIMERINDEX_TIMER_D)].TIMxCR2 , (HRTIM_TIMCR2_UDM)); \
}\
if (((__TIMERS__) & HRTIM_TIMERINDEX_TIMER_E) == HRTIM_TIMERINDEX_TIMER_E)\
{\
SET_BIT((__HANDLE__)->Instance->sTimerxRegs[(HRTIM_TIMERINDEX_TIMER_E)].TIMxCR2 , (HRTIM_TIMCR2_UDM)); \
}\
if (((__TIMERS__) & HRTIM_TIMERINDEX_TIMER_F) == HRTIM_TIMERINDEX_TIMER_F)\
{\
SET_BIT((__HANDLE__)->Instance->sTimerxRegs[(HRTIM_TIMERINDEX_TIMER_F)].TIMxCR2 , (HRTIM_TIMCR2_UDM)); \
}\
} while(0U)
/**
* @brief swap the output of the timer
* HRTIM_SETA1R and HRTIM_RSTA1R are coding for the output A2,
* HRTIM_SETA2R and HRTIM_RSTA2R are coding for the output A1
* @param __HANDLE__ : HRTIM handle.
* @param __TIMER__ : Timer index
* This parameter can be a combination of the following values:
* @arg HRTIM_TIMERINDEX_TIMER_A for timer A
* @arg HRTIM_TIMERINDEX_TIMER_B for timer B
* @arg HRTIM_TIMERINDEX_TIMER_C for timer C
* @arg HRTIM_TIMERINDEX_TIMER_D for timer D
* @arg HRTIM_TIMERINDEX_TIMER_E for timer E
* @arg HRTIM_TIMERINDEX_TIMER_F for timer F
* @retval none
*/
#define __HAL_HRTIM_TIMER_OUTPUT_SWAP(__HANDLE__, __TIMERS__)\
do {\
if (((__TIMERS__) & HRTIM_TIMERID_TIMER_A) == HRTIM_TIMERID_TIMER_A)\
{\
SET_BIT((__HANDLE__)->Instance->sCommonRegs.CR2 , (HRTIM_CR2_SWPA)); \
}\
if (((__TIMERS__) & HRTIM_TIMERID_TIMER_B) == HRTIM_TIMERID_TIMER_B)\
{\
SET_BIT((__HANDLE__)->Instance->sCommonRegs.CR2 , (HRTIM_CR2_SWPB)); \
}\
if (((__TIMERS__) & HRTIM_TIMERID_TIMER_C) == HRTIM_TIMERID_TIMER_C)\
{\
SET_BIT((__HANDLE__)->Instance->sCommonRegs.CR2 , (HRTIM_CR2_SWPC)); \
}\
if (((__TIMERS__) & HRTIM_TIMERID_TIMER_D) == HRTIM_TIMERID_TIMER_D)\
{\
SET_BIT((__HANDLE__)->Instance->sCommonRegs.CR2 , (HRTIM_CR2_SWPD)); \
}\
if (((__TIMERS__) & HRTIM_TIMERID_TIMER_E) == HRTIM_TIMERID_TIMER_E)\
{\
SET_BIT((__HANDLE__)->Instance->sCommonRegs.CR2 , (HRTIM_CR2_SWPE)); \
}\
if (((__TIMERS__) & HRTIM_TIMERID_TIMER_F) == HRTIM_TIMERID_TIMER_F)\
{\
SET_BIT((__HANDLE__)->Instance->sCommonRegs.CR2 , (HRTIM_CR2_SWPF)); \
}\
} while(0U)
/**
* @brief Un-swap the output of the timer
* HRTIM_SETA1R and HRTIM_RSTA1R are coding for the output A1,
* HRTIM_SETA2R and HRTIM_RSTA2R are coding for the output A2
* @param __HANDLE__ : HRTIM handle.
* @param __TIMER__ : Timer index
* This parameter can be a combination of the following values:
* @arg HRTIM_TIMERINDEX_TIMER_A for timer A
* @arg HRTIM_TIMERINDEX_TIMER_B for timer B
* @arg HRTIM_TIMERINDEX_TIMER_C for timer C
* @arg HRTIM_TIMERINDEX_TIMER_D for timer D
* @arg HRTIM_TIMERINDEX_TIMER_E for timer E
* @arg HRTIM_TIMERINDEX_TIMER_F for timer F
* @retval none
*/
#define __HAL_HRTIM_TIMER_OUTPUT_NOSWAP(__HANDLE__, __TIMERS__)\
do {\
if (((__TIMERS__) & HRTIM_TIMERID_TIMER_A) == HRTIM_TIMERID_TIMER_A)\
{\
CLEAR_BIT((__HANDLE__)->Instance->sCommonRegs.CR2 , (HRTIM_CR2_SWPA)); \
}\
if (((__TIMERS__) & HRTIM_TIMERID_TIMER_B) == HRTIM_TIMERID_TIMER_B)\
{\
CLEAR_BIT((__HANDLE__)->Instance->sCommonRegs.CR2 , (HRTIM_CR2_SWPB)); \
}\
if (((__TIMERS__) & HRTIM_TIMERID_TIMER_C) == HRTIM_TIMERID_TIMER_C)\
{\
CLEAR_BIT((__HANDLE__)->Instance->sCommonRegs.CR2 , (HRTIM_CR2_SWPC)); \
}\
if (((__TIMERS__) & HRTIM_TIMERID_TIMER_D) == HRTIM_TIMERID_TIMER_D)\
{\
CLEAR_BIT((__HANDLE__)->Instance->sCommonRegs.CR2 , (HRTIM_CR2_SWPD)); \
}\
if (((__TIMERS__) & HRTIM_TIMERID_TIMER_E) == HRTIM_TIMERID_TIMER_E)\
{\
CLEAR_BIT((__HANDLE__)->Instance->sCommonRegs.CR2 , (HRTIM_CR2_SWPE)); \
}\
if (((__TIMERS__) & HRTIM_TIMERID_TIMER_F) == HRTIM_TIMERID_TIMER_F)\
{\
CLEAR_BIT((__HANDLE__)->Instance->sCommonRegs.CR2 , (HRTIM_CR2_SWPF)); \
}\
} while(0U)
/** @brief Reset HRTIM handle state
* @param __HANDLE__ HRTIM handle.
* @retval None
*/
#if (USE_HAL_HRTIM_REGISTER_CALLBACKS == 1)
#define __HAL_HRTIM_RESET_HANDLE_STATE(__HANDLE__) do{ \
(__HANDLE__)->State = HAL_HRTIM_STATE_RESET; \
(__HANDLE__)->MspInitCallback = NULL; \
(__HANDLE__)->MspDeInitCallback = NULL; \
} while(0)
#else
#define __HAL_HRTIM_RESET_HANDLE_STATE(__HANDLE__) ((__HANDLE__)->State = HAL_HRTIM_STATE_RESET)
#endif
/** @brief Enables or disables the timer counter(s)
* @param __HANDLE__ specifies the HRTIM Handle.
* @param __TIMERS__ timers to enable/disable
* This parameter can be any combinations of the following values:
* @arg HRTIM_TIMERID_MASTER: Master timer identifier
* @arg HRTIM_TIMERID_TIMER_A: Timer A identifier
* @arg HRTIM_TIMERID_TIMER_B: Timer B identifier
* @arg HRTIM_TIMERID_TIMER_C: Timer C identifier
* @arg HRTIM_TIMERID_TIMER_D: Timer D identifier
* @arg HRTIM_TIMERID_TIMER_E: Timer E identifier
* @arg HRTIM_TIMERID_TIMER_F: Timer F identifier
* @retval None
*/
#define __HAL_HRTIM_ENABLE(__HANDLE__, __TIMERS__) ((__HANDLE__)->Instance->sMasterRegs.MCR |= (__TIMERS__))
/* The counter of a timing unit is disabled only if all the timer outputs */
/* are disabled and no capture is configured */
#define HRTIM_TAOEN_MASK (HRTIM_OENR_TA2OEN | HRTIM_OENR_TA1OEN)
#define HRTIM_TBOEN_MASK (HRTIM_OENR_TB2OEN | HRTIM_OENR_TB1OEN)
#define HRTIM_TCOEN_MASK (HRTIM_OENR_TC2OEN | HRTIM_OENR_TC1OEN)
#define HRTIM_TDOEN_MASK (HRTIM_OENR_TD2OEN | HRTIM_OENR_TD1OEN)
#define HRTIM_TEOEN_MASK (HRTIM_OENR_TE2OEN | HRTIM_OENR_TE1OEN)
#define HRTIM_TFOEN_MASK (HRTIM_OENR_TF2OEN | HRTIM_OENR_TF1OEN)
#define __HAL_HRTIM_DISABLE(__HANDLE__, __TIMERS__)\
do {\
if (((__TIMERS__) & HRTIM_TIMERID_MASTER) == HRTIM_TIMERID_MASTER)\
{\
((__HANDLE__)->Instance->sMasterRegs.MCR &= ~HRTIM_TIMERID_MASTER);\
}\
if (((__TIMERS__) & HRTIM_TIMERID_TIMER_A) == HRTIM_TIMERID_TIMER_A)\
{\
if (((__HANDLE__)->Instance->sCommonRegs.OENR & HRTIM_TAOEN_MASK) == (uint32_t)RESET)\
{\
((__HANDLE__)->Instance->sMasterRegs.MCR &= ~HRTIM_TIMERID_TIMER_A);\
}\
}\
if (((__TIMERS__) & HRTIM_TIMERID_TIMER_B) == HRTIM_TIMERID_TIMER_B)\
{\
if (((__HANDLE__)->Instance->sCommonRegs.OENR & HRTIM_TBOEN_MASK) == (uint32_t)RESET)\
{\
((__HANDLE__)->Instance->sMasterRegs.MCR &= ~HRTIM_TIMERID_TIMER_B);\
}\
}\
if (((__TIMERS__) & HRTIM_TIMERID_TIMER_C) == HRTIM_TIMERID_TIMER_C)\
{\
if (((__HANDLE__)->Instance->sCommonRegs.OENR & HRTIM_TCOEN_MASK) == (uint32_t)RESET)\
{\
((__HANDLE__)->Instance->sMasterRegs.MCR &= ~HRTIM_TIMERID_TIMER_C);\
}\
}\
if (((__TIMERS__) & HRTIM_TIMERID_TIMER_D) == HRTIM_TIMERID_TIMER_D)\
{\
if (((__HANDLE__)->Instance->sCommonRegs.OENR & HRTIM_TDOEN_MASK) == (uint32_t)RESET)\
{\
((__HANDLE__)->Instance->sMasterRegs.MCR &= ~HRTIM_TIMERID_TIMER_D);\
}\
}\
if (((__TIMERS__) & HRTIM_TIMERID_TIMER_E) == HRTIM_TIMERID_TIMER_E)\
{\
if (((__HANDLE__)->Instance->sCommonRegs.OENR & HRTIM_TEOEN_MASK) == (uint32_t)RESET)\
{\
((__HANDLE__)->Instance->sMasterRegs.MCR &= ~HRTIM_TIMERID_TIMER_E);\
}\
}\
if (((__TIMERS__) & HRTIM_TIMERID_TIMER_F) == HRTIM_TIMERID_TIMER_F)\
{\
if (((__HANDLE__)->Instance->sCommonRegs.OENR & HRTIM_TFOEN_MASK) == (uint32_t)RESET)\
{\
((__HANDLE__)->Instance->sMasterRegs.MCR &= ~HRTIM_TIMERID_TIMER_F);\
}\
}\
} while(0U)
/** @brief Enables the External Event counter
* @param __HANDLE__ specifies the HRTIM Handle.
* @param __TIMERS__ timers to enable/disable
* This parameter can be one of the following values:
* @arg HRTIM_TIMERINDEX_TIMER_A: Timer A identifier
* @arg HRTIM_TIMERINDEX_TIMER_B: Timer B identifier
* @arg HRTIM_TIMERINDEX_TIMER_C: Timer C identifier
* @arg HRTIM_TIMERINDEX_TIMER_D: Timer D identifier
* @arg HRTIM_TIMERINDEX_TIMER_E: Timer E identifier
* @arg HRTIM_TIMERINDEX_TIMER_F: Timer F identifier
* @param Event external event Counter A or B for which timer event must be enabled
* This parameter can be one of the following values:
* @arg HRTIM_EVENTCOUNTER_A
* @arg HRTIM_EVENTCOUNTER_B
* @retval None
*/
#define __HAL_HRTIM_EXTERNAL_EVENT_COUNTER_ENABLE(__HANDLE__, __TIMER__, __EVENT__)\
do {\
if (((__TIMER__) & HRTIM_TIMERINDEX_TIMER_A) == HRTIM_TIMERINDEX_TIMER_A)\
{\
if (((__EVENT__) & HRTIM_EVENTCOUNTER_A) == HRTIM_EVENTCOUNTER_A)\
{\
((__HANDLE__)->Instance->sTimerxRegs[HRTIM_TIMERINDEX_TIMER_A].EEFxR3) |= HRTIM_EEFR3_EEVACE;\
}\
if (((__EVENT__) & HRTIM_TIMERINDEX_TIMER_B) == HRTIM_TIMERINDEX_TIMER_B)\
{\
((__HANDLE__)->Instance->sTimerxRegs[HRTIM_TIMERINDEX_TIMER_A].EEFxR3) |= HRTIM_EEFR3_EEVBCE;\
}\
}\
if (((__TIMER__) & HRTIM_TIMERINDEX_TIMER_B) == HRTIM_TIMERINDEX_TIMER_B)\
{\
if (((__EVENT__) & HRTIM_EVENTCOUNTER_A) == HRTIM_EVENTCOUNTER_A)\
{\
((__HANDLE__)->Instance->sTimerxRegs[HRTIM_TIMERINDEX_TIMER_B].EEFxR3) |= HRTIM_EEFR3_EEVACE;\
}\
if (((__EVENT__) & HRTIM_EVENTCOUNTER_B) == HRTIM_EVENTCOUNTER_B)\
{\
((__HANDLE__)->Instance->sTimerxRegs[HRTIM_TIMERINDEX_TIMER_B].EEFxR3) |= HRTIM_EEFR3_EEVBCE;\
}\
}\
if (((__TIMER__) & HRTIM_TIMERINDEX_TIMER_C) == HRTIM_TIMERINDEX_TIMER_C)\
{\
if (((__EVENT__) & HRTIM_EVENTCOUNTER_A) == HRTIM_EVENTCOUNTER_A)\
{\
((__HANDLE__)->Instance->sTimerxRegs[HRTIM_TIMERINDEX_TIMER_C].EEFxR3) |= HRTIM_EEFR3_EEVACE;\
}\
if (((__EVENT__) & HRTIM_EVENTCOUNTER_B) == HRTIM_EVENTCOUNTER_B)\
{\
((__HANDLE__)->Instance->sTimerxRegs[HRTIM_TIMERINDEX_TIMER_C].EEFxR3) |= HRTIM_EEFR3_EEVBCE;\
}\
}\
if (((__TIMER__) & HRTIM_TIMERINDEX_TIMER_D) == HRTIM_TIMERINDEX_TIMER_D)\
{\
if (((__EVENT__) & HRTIM_EVENTCOUNTER_A) == HRTIM_EVENTCOUNTER_A)\
{\
((__HANDLE__)->Instance->sTimerxRegs[HRTIM_TIMERINDEX_TIMER_D].EEFxR3) |= HRTIM_EEFR3_EEVACE;\
}\
if (((__EVENT__) & HRTIM_EVENTCOUNTER_B) == HRTIM_EVENTCOUNTER_B)\
{\
((__HANDLE__)->Instance->sTimerxRegs[HRTIM_TIMERINDEX_TIMER_D].EEFxR3) |= HRTIM_EEFR3_EEVBCE;\
}\
}\
if (((__TIMER__) & HRTIM_TIMERINDEX_TIMER_E) == HRTIM_TIMERINDEX_TIMER_E)\
{\
if (((__EVENT__) & HRTIM_EVENTCOUNTER_A) == HRTIM_EVENTCOUNTER_A)\
{\
((__HANDLE__)->Instance->sTimerxRegs[HRTIM_TIMERINDEX_TIMER_E].EEFxR3) |= HRTIM_EEFR3_EEVACE;\
}\
if (((__EVENT__) & HRTIM_EVENTCOUNTER_B) == HRTIM_EVENTCOUNTER_B)\
{\
((__HANDLE__)->Instance->sTimerxRegs[HRTIM_TIMERINDEX_TIMER_E].EEFxR3) |= HRTIM_EEFR3_EEVBCE;\
}\
}\
if (((__TIMER__) & HRTIM_TIMERINDEX_TIMER_F) == HRTIM_TIMERINDEX_TIMER_F)\
{\
if (((__EVENT__) & HRTIM_EVENTCOUNTER_A) == HRTIM_EVENTCOUNTER_A)\
{\
((__HANDLE__)->Instance->sTimerxRegs[HRTIM_TIMERINDEX_TIMER_F].EEFxR3) |= HRTIM_EEFR3_EEVACE;\
}\
if (((__EVENT__) & HRTIM_EVENTCOUNTER_B) == HRTIM_EVENTCOUNTER_B)\
{\
((__HANDLE__)->Instance->sTimerxRegs[HRTIM_TIMERINDEX_TIMER_F].EEFxR3) |= HRTIM_EEFR3_EEVBCE;\
}\
}\
} while(0U)
/** @brief Disables the External Event counter
* @param __HANDLE__ specifies the HRTIM Handle.
* @param __TIMERS__ timers to enable/disable
* This parameter can be one of the following values:
* @arg HRTIM_TIMERINDEX_TIMER_A: Timer A identifier
* @arg HRTIM_TIMERINDEX_TIMER_B: Timer B identifier
* @arg HRTIM_TIMERINDEX_TIMER_C: Timer C identifier
* @arg HRTIM_TIMERINDEX_TIMER_D: Timer D identifier
* @arg HRTIM_TIMERINDEX_TIMER_E: Timer E identifier
* @arg HRTIM_TIMERINDEX_TIMER_F: Timer F identifier
* @param Event external event A or B for which timer event must be disabled
* This parameter can be one of the following values:
* @arg HRTIM_EVENTCOUNTER_A
* @arg HRTIM_EVENTCOUNTER_B
* @retval None
*/
#define __HAL_HRTIM_EXTERNAL_EVENT_COUNTER_DISABLE(__HANDLE__, __TIMER__, __EVENT__)\
do {\
if (((__TIMER__) & HRTIM_TIMERINDEX_TIMER_A) == HRTIM_TIMERINDEX_TIMER_A)\
{\
if (((__EVENT__) & HRTIM_EVENTCOUNTER_A) == HRTIM_EVENTCOUNTER_A)\
{\
((__HANDLE__)->Instance->sTimerxRegs[HRTIM_TIMERINDEX_TIMER_A].EEFxR3) &= ~HRTIM_EEFR3_EEVACE;\
}\
if (((__EVENT__) & HRTIM_EVENTCOUNTER_B) == HRTIM_EVENTCOUNTER_B)\
{\
((__HANDLE__)->Instance->sTimerxRegs[HRTIM_TIMERINDEX_TIMER_A].EEFxR3) &= ~HRTIM_EEFR3_EEVBCE;\
}\
}\
if (((__TIMER__) & HRTIM_TIMERINDEX_TIMER_B) == HRTIM_TIMERINDEX_TIMER_B)\
{\
if (((__EVENT__) & HRTIM_EVENTCOUNTER_A) == HRTIM_EVENTCOUNTER_A)\
{\
((__HANDLE__)->Instance->sTimerxRegs[HRTIM_TIMERINDEX_TIMER_B].EEFxR3) &= ~HRTIM_EEFR3_EEVACE;\
}\
if (((__EVENT__) & HRTIM_EVENTCOUNTER_B) == HRTIM_EVENTCOUNTER_B)\
{\
((__HANDLE__)->Instance->sTimerxRegs[HRTIM_TIMERINDEX_TIMER_B].EEFxR3) &= ~HRTIM_EEFR3_EEVBCE;\
}\
}\
if (((__TIMER__) & HRTIM_TIMERINDEX_TIMER_C) == HRTIM_TIMERINDEX_TIMER_C)\
{\
if (((__EVENT__) & HRTIM_EVENTCOUNTER_A) == HRTIM_EVENTCOUNTER_A)\
{\
((__HANDLE__)->Instance->sTimerxRegs[HRTIM_TIMERINDEX_TIMER_C].EEFxR3) &= ~HRTIM_EEFR3_EEVACE;\
}\
if (((__EVENT__) & HRTIM_EVENTCOUNTER_B) == HRTIM_EVENTCOUNTER_B)\
{\
((__HANDLE__)->Instance->sTimerxRegs[HRTIM_TIMERINDEX_TIMER_C].EEFxR3) &= ~HRTIM_EEFR3_EEVBCE;\
}\
}\
if (((__TIMER__) & HRTIM_TIMERINDEX_TIMER_D) == HRTIM_TIMERINDEX_TIMER_D)\
{\
if (((__EVENT__) & HRTIM_EVENTCOUNTER_A) == HRTIM_EVENTCOUNTER_A)\
{\
((__HANDLE__)->Instance->sTimerxRegs[HRTIM_TIMERINDEX_TIMER_D].EEFxR3) &= ~HRTIM_EEFR3_EEVACE;\
}\
if (((__EVENT__) & HRTIM_EVENTCOUNTER_B) == HRTIM_EVENTCOUNTER_B)\
{\
((__HANDLE__)->Instance->sTimerxRegs[HRTIM_TIMERINDEX_TIMER_D].EEFxR3) &= ~HRTIM_EEFR3_EEVBCE;\
}\
}\
if (((__TIMER__) & HRTIM_TIMERINDEX_TIMER_E) == HRTIM_TIMERINDEX_TIMER_E)\
{\
if (((__EVENT__) & HRTIM_EVENTCOUNTER_A) == HRTIM_EVENTCOUNTER_A)\
{\
((__HANDLE__)->Instance->sTimerxRegs[HRTIM_TIMERINDEX_TIMER_E].EEFxR3) &= ~HRTIM_EEFR3_EEVACE;\
}\
if (((__EVENT__) & HRTIM_EVENTCOUNTER_B) == HRTIM_EVENTCOUNTER_B)\
{\
((__HANDLE__)->Instance->sTimerxRegs[HRTIM_TIMERINDEX_TIMER_E].EEFxR3) &= ~HRTIM_EEFR3_EEVBCE;\
}\
}\
if (((__TIMER__) & HRTIM_TIMERINDEX_TIMER_F) == HRTIM_TIMERINDEX_TIMER_F)\
{\
if (((__EVENT__) & HRTIM_EVENTCOUNTER_A) == HRTIM_EVENTCOUNTER_A)\
{\
((__HANDLE__)->Instance->sTimerxRegs[HRTIM_TIMERINDEX_TIMER_F].EEFxR3) &= ~HRTIM_EEFR3_EEVACE;\
}\
if (((__EVENT__) & HRTIM_EVENTCOUNTER_B) == HRTIM_EVENTCOUNTER_B)\
{\
((__HANDLE__)->Instance->sTimerxRegs[HRTIM_TIMERINDEX_TIMER_F].EEFxR3) &= ~HRTIM_EEFR3_EEVBCE;\
}\
}\
} while(0U)
/** @brief Resets the External Event counter
* @param __HANDLE__ specifies the HRTIM Handle.
* @param __TIMERS__ timers to enable/disable
* This parameter can be one of the following values:
* @arg HRTIM_TIMERINDEX_TIMER_A: Timer A identifier
* @arg HRTIM_TIMERINDEX_TIMER_B: Timer B identifier
* @arg HRTIM_TIMERINDEX_TIMER_C: Timer C identifier
* @arg HRTIM_TIMERINDEX_TIMER_D: Timer D identifier
* @arg HRTIM_TIMERINDEX_TIMER_E: Timer E identifier
* @arg HRTIM_TIMERINDEX_TIMER_F: Timer F identifier
* @param Event external event A or B for which timer event must be reset
* This parameter can be one of the following values:
* @arg HRTIM_EVENTCOUNTER_A
* @arg HRTIM_EVENTCOUNTER_B
* @retval None
*/
#define __HAL_HRTIM_EXTERNAL_EVENT_COUNTER_RESET(__HANDLE__, __TIMER__, __EVENT__)\
do {\
if (((__TIMER__) & HRTIM_TIMERINDEX_TIMER_A) == HRTIM_TIMERINDEX_TIMER_A)\
{\
if (((__EVENT__) & HRTIM_EVENTCOUNTER_A) == HRTIM_EVENTCOUNTER_A)\
{\
((__HANDLE__)->Instance->sTimerxRegs[HRTIM_TIMERINDEX_TIMER_A].EEFxR3) |= HRTIM_EEFR3_EEVACRES;\
}\
if (((__EVENT__) & HRTIM_EVENTCOUNTER_B) == HRTIM_EVENTCOUNTER_B)\
{\
((__HANDLE__)->Instance->sTimerxRegs[HRTIM_TIMERINDEX_TIMER_A].EEFxR3) |= HRTIM_EEFR3_EEVBCRES;\
}\
}\
if (((__TIMER__) & HRTIM_TIMERINDEX_TIMER_B) == HRTIM_TIMERINDEX_TIMER_B)\
{\
if (((__EVENT__) & HRTIM_EVENTCOUNTER_A) == HRTIM_EVENTCOUNTER_A)\
{\
((__HANDLE__)->Instance->sTimerxRegs[HRTIM_TIMERINDEX_TIMER_B].EEFxR3) |= HRTIM_EEFR3_EEVACRES;\
}\
if (((__EVENT__) & HRTIM_EVENTCOUNTER_B) == HRTIM_EVENTCOUNTER_B)\
{\
((__HANDLE__)->Instance->sTimerxRegs[HRTIM_TIMERINDEX_TIMER_B].EEFxR3) |= HRTIM_EEFR3_EEVBCRES;\
}\
}\
if (((__TIMER__) & HRTIM_TIMERINDEX_TIMER_C) == HRTIM_TIMERINDEX_TIMER_C)\
{\
if (((__EVENT__) & HRTIM_EVENTCOUNTER_A) == HRTIM_EVENTCOUNTER_A)\
{\
((__HANDLE__)->Instance->sTimerxRegs[HRTIM_TIMERINDEX_TIMER_C].EEFxR3) |= HRTIM_EEFR3_EEVACRES;\
}\
if (((__EVENT__) & HRTIM_EVENTCOUNTER_B) == HRTIM_EVENTCOUNTER_B)\
{\
((__HANDLE__)->Instance->sTimerxRegs[HRTIM_TIMERINDEX_TIMER_C].EEFxR3) |= HRTIM_EEFR3_EEVBCRES;\
}\
}\
if (((__TIMER__) & HRTIM_TIMERINDEX_TIMER_D) == HRTIM_TIMERINDEX_TIMER_D)\
{\
if (((__EVENT__) & HRTIM_EVENTCOUNTER_A) == HRTIM_EVENTCOUNTER_A)\
{\
((__HANDLE__)->Instance->sTimerxRegs[HRTIM_TIMERINDEX_TIMER_D].EEFxR3) |= HRTIM_EEFR3_EEVACRES;\
}\
if (((__EVENT__) & HRTIM_EVENTCOUNTER_B) == HRTIM_EVENTCOUNTER_B)\
{\
((__HANDLE__)->Instance->sTimerxRegs[HRTIM_TIMERINDEX_TIMER_D].EEFxR3) |= HRTIM_EEFR3_EEVBCRES;\
}\
}\
if (((__TIMER__) & HRTIM_TIMERINDEX_TIMER_E) == HRTIM_TIMERINDEX_TIMER_E)\
{\
if (((__EVENT__) & HRTIM_EVENTCOUNTER_A) == HRTIM_EVENTCOUNTER_A)\
{\
((__HANDLE__)->Instance->sTimerxRegs[HRTIM_TIMERINDEX_TIMER_E].EEFxR3) |= HRTIM_EEFR3_EEVACRES;\
}\
if (((__EVENT__) & HRTIM_EVENTCOUNTER_B) == HRTIM_EVENTCOUNTER_B)\
{\
((__HANDLE__)->Instance->sTimerxRegs[HRTIM_TIMERINDEX_TIMER_E].EEFxR3) |= HRTIM_EEFR3_EEVBCRES;\
}\
}\
if (((__TIMER__) & HRTIM_TIMERINDEX_TIMER_F) == HRTIM_TIMERINDEX_TIMER_F)\
{\
if (((__EVENT__) & HRTIM_EVENTCOUNTER_A) == HRTIM_EVENTCOUNTER_A)\
{\
((__HANDLE__)->Instance->sTimerxRegs[HRTIM_TIMERINDEX_TIMER_F].EEFxR3) |= HRTIM_EEFR3_EEVACRES;\
}\
if (((__EVENT__) & HRTIM_EVENTCOUNTER_B) == HRTIM_EVENTCOUNTER_B)\
{\
((__HANDLE__)->Instance->sTimerxRegs[HRTIM_TIMERINDEX_TIMER_F].EEFxR3) |= HRTIM_EEFR3_EEVBCRES;\
}\
}\
} while(0U)
/** @brief Enables or disables the specified HRTIM common interrupts.
* @param __HANDLE__ specifies the HRTIM Handle.
* @param __INTERRUPT__ specifies the interrupt source to enable or disable.
* This parameter can be one of the following values:
* @arg HRTIM_IT_FLT1: Fault 1 interrupt enable
* @arg HRTIM_IT_FLT2: Fault 2 interrupt enable
* @arg HRTIM_IT_FLT3: Fault 3 interrupt enable
* @arg HRTIM_IT_FLT4: Fault 4 interrupt enable
* @arg HRTIM_IT_FLT5: Fault 5 interrupt enable
* @arg HRTIM_IT_FLT6: Fault 6 interrupt enable
* @arg HRTIM_IT_SYSFLT: System Fault interrupt enable
* @arg HRTIM_IT_DLLRDY: DLL ready interrupt enable
* @arg HRTIM_IT_BMPER: Burst mode period interrupt enable
* @retval None
*/
#define __HAL_HRTIM_ENABLE_IT(__HANDLE__, __INTERRUPT__) ((__HANDLE__)->Instance->sCommonRegs.IER |= (__INTERRUPT__))
#define __HAL_HRTIM_DISABLE_IT(__HANDLE__, __INTERRUPT__) ((__HANDLE__)->Instance->sCommonRegs.IER &= ~(__INTERRUPT__))
/** @brief Enables or disables the specified HRTIM Master timer interrupts.
* @param __HANDLE__ specifies the HRTIM Handle.
* @param __INTERRUPT__ specifies the interrupt source to enable or disable.
* This parameter can be one of the following values:
* @arg HRTIM_MASTER_IT_MCMP1: Master compare 1 interrupt enable
* @arg HRTIM_MASTER_IT_MCMP2: Master compare 2 interrupt enable
* @arg HRTIM_MASTER_IT_MCMP3: Master compare 3 interrupt enable
* @arg HRTIM_MASTER_IT_MCMP4: Master compare 4 interrupt enable
* @arg HRTIM_MASTER_IT_MREP: Master Repetition interrupt enable
* @arg HRTIM_MASTER_IT_SYNC: Synchronization input interrupt enable
* @arg HRTIM_MASTER_IT_MUPD: Master update interrupt enable
* @retval None
*/
#define __HAL_HRTIM_MASTER_ENABLE_IT(__HANDLE__, __INTERRUPT__) ((__HANDLE__)->Instance->sMasterRegs.MDIER |= (__INTERRUPT__))
#define __HAL_HRTIM_MASTER_DISABLE_IT(__HANDLE__, __INTERRUPT__) ((__HANDLE__)->Instance->sMasterRegs.MDIER &= ~(__INTERRUPT__))
/** @brief Enables or disables the specified HRTIM Timerx interrupts.
* @param __HANDLE__ specifies the HRTIM Handle.
* @param __TIMER__ specified the timing unit (Timer A to F)
* @param __INTERRUPT__ specifies the interrupt source to enable or disable.
* This parameter can be one of the following values:
* @arg HRTIM_TIM_IT_CMP1: Timer compare 1 interrupt enable
* @arg HRTIM_TIM_IT_CMP2: Timer compare 2 interrupt enable
* @arg HRTIM_TIM_IT_CMP3: Timer compare 3 interrupt enable
* @arg HRTIM_TIM_IT_CMP4: Timer compare 4 interrupt enable
* @arg HRTIM_TIM_IT_REP: Timer repetition interrupt enable
* @arg HRTIM_TIM_IT_UPD: Timer update interrupt enable
* @arg HRTIM_TIM_IT_CPT1: Timer capture 1 interrupt enable
* @arg HRTIM_TIM_IT_CPT2: Timer capture 2 interrupt enable
* @arg HRTIM_TIM_IT_SET1: Timer output 1 set interrupt enable
* @arg HRTIM_TIM_IT_RST1: Timer output 1 reset interrupt enable
* @arg HRTIM_TIM_IT_SET2: Timer output 2 set interrupt enable
* @arg HRTIM_TIM_IT_RST2: Timer output 2 reset interrupt enable
* @arg HRTIM_TIM_IT_RST: Timer reset interrupt enable
* @arg HRTIM_TIM_IT_DLYPRT: Timer delay protection interrupt enable
* @retval None
*/
#define __HAL_HRTIM_TIMER_ENABLE_IT(__HANDLE__, __TIMER__, __INTERRUPT__) ((__HANDLE__)->Instance->sTimerxRegs[(__TIMER__)].TIMxDIER |= (__INTERRUPT__))
#define __HAL_HRTIM_TIMER_DISABLE_IT(__HANDLE__, __TIMER__, __INTERRUPT__) ((__HANDLE__)->Instance->sTimerxRegs[(__TIMER__)].TIMxDIER &= ~(__INTERRUPT__))
/** @brief Checks if the specified HRTIM common interrupt source is enabled or disabled.
* @param __HANDLE__ specifies the HRTIM Handle.
* @param __INTERRUPT__ specifies the interrupt source to check.
* This parameter can be one of the following values:
* @arg HRTIM_IT_FLT1: Fault 1 interrupt enable
* @arg HRTIM_IT_FLT2: Fault 2 interrupt enable
* @arg HRTIM_IT_FLT3: Fault 3 enable
* @arg HRTIM_IT_FLT4: Fault 4 enable
* @arg HRTIM_IT_FLT5: Fault 5 enable
* @arg HRTIM_IT_FLT6: Fault 6 enable
* @arg HRTIM_IT_SYSFLT: System Fault interrupt enable
* @arg HRTIM_IT_DLLRDY: DLL ready interrupt enable
* @arg HRTIM_IT_BMPER: Burst mode period interrupt enable
* @retval The new state of __INTERRUPT__ (TRUE or FALSE).
*/
#define __HAL_HRTIM_GET_ITSTATUS(__HANDLE__, __INTERRUPT__) ((((__HANDLE__)->Instance->sCommonRegs.IER & (__INTERRUPT__)) == (__INTERRUPT__)) ? SET : RESET)
/** @brief Checks if the specified HRTIM Master interrupt source is enabled or disabled.
* @param __HANDLE__ specifies the HRTIM Handle.
* @param __INTERRUPT__ specifies the interrupt source to check.
* This parameter can be one of the following values:
* @arg HRTIM_MASTER_IT_MCMP1: Master compare 1 interrupt enable
* @arg HRTIM_MASTER_IT_MCMP2: Master compare 2 interrupt enable
* @arg HRTIM_MASTER_IT_MCMP3: Master compare 3 interrupt enable
* @arg HRTIM_MASTER_IT_MCMP4: Master compare 4 interrupt enable
* @arg HRTIM_MASTER_IT_MREP: Master Repetition interrupt enable
* @arg HRTIM_MASTER_IT_SYNC: Synchronization input interrupt enable
* @arg HRTIM_MASTER_IT_MUPD: Master update interrupt enable
* @retval The new state of __INTERRUPT__ (TRUE or FALSE).
*/
#define __HAL_HRTIM_MASTER_GET_ITSTATUS(__HANDLE__, __INTERRUPT__) ((((__HANDLE__)->Instance->sMasterRegs.MDIER & (__INTERRUPT__)) == (__INTERRUPT__)) ? SET : RESET)
/** @brief Checks if the specified HRTIM Timerx interrupt source is enabled or disabled.
* @param __HANDLE__ specifies the HRTIM Handle.
* @param __TIMER__ specified the timing unit (Timer A to F)
* @param __INTERRUPT__ specifies the interrupt source to check.
* This parameter can be one of the following values:
* @arg HRTIM_MASTER_IT_MCMP1: Master compare 1 interrupt enable
* @arg HRTIM_MASTER_IT_MCMP2: Master compare 2 interrupt enable
* @arg HRTIM_MASTER_IT_MCMP3: Master compare 3 interrupt enable
* @arg HRTIM_MASTER_IT_MCMP4: Master compare 4 interrupt enable
* @arg HRTIM_MASTER_IT_MREP: Master Repetition interrupt enable
* @arg HRTIM_MASTER_IT_SYNC: Synchronization input interrupt enable
* @arg HRTIM_MASTER_IT_MUPD: Master update interrupt enable
* @arg HRTIM_TIM_IT_CMP1: Timer compare 1 interrupt enable
* @arg HRTIM_TIM_IT_CMP2: Timer compare 2 interrupt enable
* @arg HRTIM_TIM_IT_CMP3: Timer compare 3 interrupt enable
* @arg HRTIM_TIM_IT_CMP4: Timer compare 4 interrupt enable
* @arg HRTIM_TIM_IT_REP: Timer repetition interrupt enable
* @arg HRTIM_TIM_IT_UPD: Timer update interrupt enable
* @arg HRTIM_TIM_IT_CPT1: Timer capture 1 interrupt enable
* @arg HRTIM_TIM_IT_CPT2: Timer capture 2 interrupt enable
* @arg HRTIM_TIM_IT_SET1: Timer output 1 set interrupt enable
* @arg HRTIM_TIM_IT_RST1: Timer output 1 reset interrupt enable
* @arg HRTIM_TIM_IT_SET2: Timer output 2 set interrupt enable
* @arg HRTIM_TIM_IT_RST2: Timer output 2 reset interrupt enable
* @arg HRTIM_TIM_IT_RST: Timer reset interrupt enable
* @arg HRTIM_TIM_IT_DLYPRT: Timer delay protection interrupt enable
* @retval The new state of __INTERRUPT__ (TRUE or FALSE).
*/
#define __HAL_HRTIM_TIMER_GET_ITSTATUS(__HANDLE__, __TIMER__, __INTERRUPT__) ((((__HANDLE__)->Instance->sTimerxRegs[(__TIMER__)].TIMxDIER & (__INTERRUPT__)) == (__INTERRUPT__)) ? SET : RESET)
/** @brief Clears the specified HRTIM common pending flag.
* @param __HANDLE__ specifies the HRTIM Handle.
* @param __INTERRUPT__ specifies the interrupt pending bit to clear.
* This parameter can be one of the following values:
* @arg HRTIM_IT_FLT1: Fault 1 interrupt clear flag
* @arg HRTIM_IT_FLT2: Fault 2 interrupt clear flag
* @arg HRTIM_IT_FLT3: Fault 3 clear flag
* @arg HRTIM_IT_FLT4: Fault 4 clear flag
* @arg HRTIM_IT_FLT5: Fault 5 clear flag
* @arg HRTIM_IT_FLT6: Fault 6 clear flag
* @arg HRTIM_IT_SYSFLT: System Fault interrupt clear flag
* @arg HRTIM_IT_DLLRDY: DLL ready interrupt clear flag
* @arg HRTIM_IT_BMPER: Burst mode period interrupt clear flag
* @retval None
*/
#define __HAL_HRTIM_CLEAR_IT(__HANDLE__, __INTERRUPT__) ((__HANDLE__)->Instance->sCommonRegs.ICR = (__INTERRUPT__))
/** @brief Clears the specified HRTIM Master pending flag.
* @param __HANDLE__ specifies the HRTIM Handle.
* @param __INTERRUPT__ specifies the interrupt pending bit to clear.
* This parameter can be one of the following values:
* @arg HRTIM_MASTER_IT_MCMP1: Master compare 1 interrupt clear flag
* @arg HRTIM_MASTER_IT_MCMP2: Master compare 2 interrupt clear flag
* @arg HRTIM_MASTER_IT_MCMP3: Master compare 3 interrupt clear flag
* @arg HRTIM_MASTER_IT_MCMP4: Master compare 4 interrupt clear flag
* @arg HRTIM_MASTER_IT_MREP: Master Repetition interrupt clear flag
* @arg HRTIM_MASTER_IT_SYNC: Synchronization input interrupt clear flag
* @arg HRTIM_MASTER_IT_MUPD: Master update interrupt clear flag
* @retval None
*/
#define __HAL_HRTIM_MASTER_CLEAR_IT(__HANDLE__, __INTERRUPT__) ((__HANDLE__)->Instance->sMasterRegs.MICR = (__INTERRUPT__))
/** @brief Clears the specified HRTIM Timerx pending flag.
* @param __HANDLE__ specifies the HRTIM Handle.
* @param __TIMER__ specified the timing unit (Timer A to F)
* @param __INTERRUPT__ specifies the interrupt pending bit to clear.
* This parameter can be one of the following values:
* @arg HRTIM_TIM_IT_CMP1: Timer compare 1 interrupt clear flag
* @arg HRTIM_TIM_IT_CMP2: Timer compare 2 interrupt clear flag
* @arg HRTIM_TIM_IT_CMP3: Timer compare 3 interrupt clear flag
* @arg HRTIM_TIM_IT_CMP4: Timer compare 4 interrupt clear flag
* @arg HRTIM_TIM_IT_REP: Timer repetition interrupt clear flag
* @arg HRTIM_TIM_IT_UPD: Timer update interrupt clear flag
* @arg HRTIM_TIM_IT_CPT1: Timer capture 1 interrupt clear flag
* @arg HRTIM_TIM_IT_CPT2: Timer capture 2 interrupt clear flag
* @arg HRTIM_TIM_IT_SET1: Timer output 1 set interrupt clear flag
* @arg HRTIM_TIM_IT_RST1: Timer output 1 reset interrupt clear flag
* @arg HRTIM_TIM_IT_SET2: Timer output 2 set interrupt clear flag
* @arg HRTIM_TIM_IT_RST2: Timer output 2 reset interrupt clear flag
* @arg HRTIM_TIM_IT_RST: Timer reset interrupt clear flag
* @arg HRTIM_TIM_IT_DLYPRT: Timer output 1 delay protection interrupt clear flag
* @retval None
*/
#define __HAL_HRTIM_TIMER_CLEAR_IT(__HANDLE__, __TIMER__, __INTERRUPT__) ((__HANDLE__)->Instance->sTimerxRegs[(__TIMER__)].TIMxICR = (__INTERRUPT__))
/* DMA HANDLING */
/** @brief Enables or disables the specified HRTIM Master timer DMA requests.
* @param __HANDLE__ specifies the HRTIM Handle.
* @param __DMA__ specifies the DMA request to enable or disable.
* This parameter can be one of the following values:
* @arg HRTIM_MASTER_DMA_MCMP1: Master compare 1 DMA request enable
* @arg HRTIM_MASTER_DMA_MCMP2: Master compare 2 DMA request enable
* @arg HRTIM_MASTER_DMA_MCMP3: Master compare 3 DMA request enable
* @arg HRTIM_MASTER_DMA_MCMP4: Master compare 4 DMA request enable
* @arg HRTIM_MASTER_DMA_MREP: Master Repetition DMA request enable
* @arg HRTIM_MASTER_DMA_SYNC: Synchronization input DMA request enable
* @arg HRTIM_MASTER_DMA_MUPD: Master update DMA request enable
* @retval None
*/
#define __HAL_HRTIM_MASTER_ENABLE_DMA(__HANDLE__, __DMA__) ((__HANDLE__)->Instance->sMasterRegs.MDIER |= (__DMA__))
#define __HAL_HRTIM_MASTER_DISABLE_DMA(__HANDLE__, __DMA__) ((__HANDLE__)->Instance->sMasterRegs.MDIER &= ~(__DMA__))
/** @brief Enables or disables the specified HRTIM Timerx DMA requests.
* @param __HANDLE__ specifies the HRTIM Handle.
* @param __TIMER__ specified the timing unit (Timer A to F)
* @param __DMA__ specifies the DMA request to enable or disable.
* This parameter can be one of the following values:
* @arg HRTIM_TIM_DMA_CMP1: Timer compare 1 DMA request enable
* @arg HRTIM_TIM_DMA_CMP2: Timer compare 2 DMA request enable
* @arg HRTIM_TIM_DMA_CMP3: Timer compare 3 DMA request enable
* @arg HRTIM_TIM_DMA_CMP4: Timer compare 4 DMA request enable
* @arg HRTIM_TIM_DMA_REP: Timer repetition DMA request enable
* @arg HRTIM_TIM_DMA_UPD: Timer update DMA request enable
* @arg HRTIM_TIM_DMA_CPT1: Timer capture 1 DMA request enable
* @arg HRTIM_TIM_DMA_CPT2: Timer capture 2 DMA request enable
* @arg HRTIM_TIM_DMA_SET1: Timer output 1 set DMA request enable
* @arg HRTIM_TIM_DMA_RST1: Timer output 1 reset DMA request enable
* @arg HRTIM_TIM_DMA_SET2: Timer output 2 set DMA request enable
* @arg HRTIM_TIM_DMA_RST2: Timer output 2 reset DMA request enable
* @arg HRTIM_TIM_DMA_RST: Timer reset DMA request enable
* @arg HRTIM_TIM_DMA_DLYPRT: Timer delay protection DMA request enable
* @retval None
*/
#define __HAL_HRTIM_TIMER_ENABLE_DMA(__HANDLE__, __TIMER__, __DMA__) ((__HANDLE__)->Instance->sTimerxRegs[(__TIMER__)].TIMxDIER |= (__DMA__))
#define __HAL_HRTIM_TIMER_DISABLE_DMA(__HANDLE__, __TIMER__, __DMA__) ((__HANDLE__)->Instance->sTimerxRegs[(__TIMER__)].TIMxDIER &= ~(__DMA__))
#define __HAL_HRTIM_GET_FLAG(__HANDLE__, __FLAG__) (((__HANDLE__)->Instance->sCommonRegs.ISR & (__FLAG__)) == (__FLAG__))
#define __HAL_HRTIM_CLEAR_FLAG(__HANDLE__, __FLAG__) ((__HANDLE__)->Instance->sCommonRegs.ICR = (__FLAG__))
#define __HAL_HRTIM_MASTER_GET_FLAG(__HANDLE__, __FLAG__) (((__HANDLE__)->Instance->sMasterRegs.MISR & (__FLAG__)) == (__FLAG__))
#define __HAL_HRTIM_MASTER_CLEAR_FLAG(__HANDLE__, __FLAG__) ((__HANDLE__)->Instance->sMasterRegs.MICR = (__FLAG__))
#define __HAL_HRTIM_TIMER_GET_FLAG(__HANDLE__, __TIMER__, __FLAG__) (((__HANDLE__)->Instance->sTimerxRegs[(__TIMER__)].TIMxISR & (__FLAG__)) == (__FLAG__))
#define __HAL_HRTIM_TIMER_CLEAR_FLAG(__HANDLE__, __TIMER__, __FLAG__) ((__HANDLE__)->Instance->sTimerxRegs[(__TIMER__)].TIMxICR = (__FLAG__))
/** @brief Sets the HRTIM timer Counter Register value on runtime
* @param __HANDLE__ HRTIM Handle.
* @param __TIMER__ HRTIM timer
* This parameter can be one of the following values:
* @arg 0x6 for master timer
* @arg 0x0 to 0x5 for timers A to F
* @param __COUNTER__ specifies the Counter Register new value.
* @retval None
*/
#define __HAL_HRTIM_SETCOUNTER(__HANDLE__, __TIMER__, __COUNTER__) \
(((__TIMER__) == HRTIM_TIMERINDEX_MASTER) ? ((__HANDLE__)->Instance->sMasterRegs.MCNTR = (__COUNTER__)) :\
((__HANDLE__)->Instance->sTimerxRegs[(__TIMER__)].CNTxR = (__COUNTER__)))
/** @brief Gets the HRTIM timer Counter Register value on runtime
* @param __HANDLE__ HRTIM Handle.
* @param __TIMER__ HRTIM timer
* This parameter can be one of the following values:
* @arg 0x6 for master timer
* @arg 0x0 to 0x5 for timers A to F
* @retval HRTIM timer Counter Register value
*/
#define __HAL_HRTIM_GETCOUNTER(__HANDLE__, __TIMER__) \
(((__TIMER__) == HRTIM_TIMERINDEX_MASTER) ? ((__HANDLE__)->Instance->sMasterRegs.MCNTR) :\
((__HANDLE__)->Instance->sTimerxRegs[(__TIMER__)].CNTxR))
/** @brief Sets the HRTIM timer Period value on runtime
* @param __HANDLE__ HRTIM Handle.
* @param __TIMER__ HRTIM timer
* This parameter can be one of the following values:
* @arg 0x6 for master timer
* @arg 0x0 to 0x5 for timers A to F
* @param __PERIOD__ specifies the Period Register new value.
* @retval None
*/
#define __HAL_HRTIM_SETPERIOD(__HANDLE__, __TIMER__, __PERIOD__) \
(((__TIMER__) == HRTIM_TIMERINDEX_MASTER) ? ((__HANDLE__)->Instance->sMasterRegs.MPER = (__PERIOD__)) :\
((__HANDLE__)->Instance->sTimerxRegs[(__TIMER__)].PERxR = (__PERIOD__)))
/** @brief Gets the HRTIM timer Period Register value on runtime
* @param __HANDLE__ HRTIM Handle.
* @param __TIMER__ HRTIM timer
* This parameter can be one of the following values:
* @arg 0x6 for master timer
* @arg 0x0 to 0x5 for timers A to F
* @retval timer Period Register
*/
#define __HAL_HRTIM_GETPERIOD(__HANDLE__, __TIMER__) \
(((__TIMER__) == HRTIM_TIMERINDEX_MASTER) ? ((__HANDLE__)->Instance->sMasterRegs.MPER) :\
((__HANDLE__)->Instance->sTimerxRegs[(__TIMER__)].PERxR))
/** @brief Sets the HRTIM timer clock prescaler value on runtime
* @param __HANDLE__ HRTIM Handle.
* @param __TIMER__ HRTIM timer
* This parameter can be one of the following values:
* @arg 0x6 for master timer
* @arg 0x0 to 0x5 for timers A to F
* @param __PRESCALER__ specifies the clock prescaler new value.
* This parameter can be one of the following values:
* @arg HRTIM_PRESCALERRATIO_MUL32: fHRCK: 4.608 GHz - Resolution: 217 ps - Min PWM frequency: 70.3 kHz (fHRTIM=144MHz)
* @arg HRTIM_PRESCALERRATIO_MUL16: fHRCK: 2.304 GHz - Resolution: 434 ps - Min PWM frequency: 35.1 KHz (fHRTIM=144MHz)
* @arg HRTIM_PRESCALERRATIO_MUL8: fHRCK: 1.152 GHz - Resolution: 868 ps - Min PWM frequency: 17.6 kHz (fHRTIM=144MHz)
* @arg HRTIM_PRESCALERRATIO_MUL4: fHRCK: 576 MHz - Resolution: 1.73 ns - Min PWM frequency: 8.8 kHz (fHRTIM=144MHz)
* @arg HRTIM_PRESCALERRATIO_MUL2: fHRCK: 288 MHz - Resolution: 3.47 ns - Min PWM frequency: 4.4 kHz (fHRTIM=144MHz)
* @arg HRTIM_PRESCALERRATIO_DIV1: fHRCK: 144 MHz - Resolution: 6.95 ns - Min PWM frequency: 2.2 kHz (fHRTIM=144MHz)
* @arg HRTIM_PRESCALERRATIO_DIV2: fHRCK: 72 MHz - Resolution: 13.88 ns- Min PWM frequency: 1.1 kHz (fHRTIM=144MHz)
* @arg HRTIM_PRESCALERRATIO_DIV4: fHRCK: 36 MHz - Resolution: 27.7 ns- Min PWM frequency: 550Hz (fHRTIM=144MHz)
* @retval None
*/
#define __HAL_HRTIM_SETCLOCKPRESCALER(__HANDLE__, __TIMER__, __PRESCALER__) \
(((__TIMER__) == HRTIM_TIMERINDEX_MASTER) ? (MODIFY_REG((__HANDLE__)->Instance->sMasterRegs.MCR, HRTIM_MCR_CK_PSC, (__PRESCALER__))) :\
(MODIFY_REG((__HANDLE__)->Instance->sTimerxRegs[(__TIMER__)].TIMxCR, HRTIM_TIMCR_CK_PSC, (__PRESCALER__))))
/** @brief Gets the HRTIM timer clock prescaler value on runtime
* @param __HANDLE__ HRTIM Handle.
* @param __TIMER__ HRTIM timer
* This parameter can be one of the following values:
* @arg 0x6 for master timer
* @arg 0x0 to 0x5 for timers A to F
* @retval timer clock prescaler value
*/
#define __HAL_HRTIM_GETCLOCKPRESCALER(__HANDLE__, __TIMER__) \
(((__TIMER__) == HRTIM_TIMERINDEX_MASTER) ? ((__HANDLE__)->Instance->sMasterRegs.MCR & HRTIM_MCR_CK_PSC) :\
((__HANDLE__)->Instance->sTimerxRegs[(__TIMER__)].TIMxCR & HRTIM_TIMCR_CK_PSC))
/** @brief Sets the HRTIM timer Compare Register value on runtime
* @param __HANDLE__ HRTIM Handle.
* @param __TIMER__ HRTIM timer
* This parameter can be one of the following values:
* @arg 0x0 to 0x5 for timers A to F
* @param __COMPAREUNIT__ timer compare unit
* This parameter can be one of the following values:
* @arg HRTIM_COMPAREUNIT_1: Compare unit 1
* @arg HRTIM_COMPAREUNIT_2: Compare unit 2
* @arg HRTIM_COMPAREUNIT_3: Compare unit 3
* @arg HRTIM_COMPAREUNIT_4: Compare unit 4
* @param __COMPARE__ specifies the Compare new value.
* @retval None
*/
#define __HAL_HRTIM_SETCOMPARE(__HANDLE__, __TIMER__, __COMPAREUNIT__, __COMPARE__) \
(((__TIMER__) == HRTIM_TIMERINDEX_MASTER) ? \
(((__COMPAREUNIT__) == HRTIM_COMPAREUNIT_1) ? ((__HANDLE__)->Instance->sMasterRegs.MCMP1R = (__COMPARE__)) :\
((__COMPAREUNIT__) == HRTIM_COMPAREUNIT_2) ? ((__HANDLE__)->Instance->sMasterRegs.MCMP2R = (__COMPARE__)) :\
((__COMPAREUNIT__) == HRTIM_COMPAREUNIT_3) ? ((__HANDLE__)->Instance->sMasterRegs.MCMP3R = (__COMPARE__)) :\
((__HANDLE__)->Instance->sMasterRegs.MCMP4R = (__COMPARE__))) \
: \
(((__COMPAREUNIT__) == HRTIM_COMPAREUNIT_1) ? ((__HANDLE__)->Instance->sTimerxRegs[(__TIMER__)].CMP1xR = (__COMPARE__)) :\
((__COMPAREUNIT__) == HRTIM_COMPAREUNIT_2) ? ((__HANDLE__)->Instance->sTimerxRegs[(__TIMER__)].CMP2xR = (__COMPARE__)) :\
((__COMPAREUNIT__) == HRTIM_COMPAREUNIT_3) ? ((__HANDLE__)->Instance->sTimerxRegs[(__TIMER__)].CMP3xR = (__COMPARE__)) :\
((__HANDLE__)->Instance->sTimerxRegs[(__TIMER__)].CMP4xR = (__COMPARE__))))
/** @brief Gets the HRTIM timer Compare Register value on runtime
* @param __HANDLE__ HRTIM Handle.
* @param __TIMER__ HRTIM timer
* This parameter can be one of the following values:
* @arg 0x0 to 0x5 for timers A to F
* @param __COMPAREUNIT__ timer compare unit
* This parameter can be one of the following values:
* @arg HRTIM_COMPAREUNIT_1: Compare unit 1
* @arg HRTIM_COMPAREUNIT_2: Compare unit 2
* @arg HRTIM_COMPAREUNIT_3: Compare unit 3
* @arg HRTIM_COMPAREUNIT_4: Compare unit 4
* @retval Compare value
*/
#define __HAL_HRTIM_GETCOMPARE(__HANDLE__, __TIMER__, __COMPAREUNIT__) \
(((__TIMER__) == HRTIM_TIMERINDEX_MASTER) ? \
(((__COMPAREUNIT__) == HRTIM_COMPAREUNIT_1) ? ((__HANDLE__)->Instance->sMasterRegs.MCMP1R) :\
((__COMPAREUNIT__) == HRTIM_COMPAREUNIT_2) ? ((__HANDLE__)->Instance->sMasterRegs.MCMP2R) :\
((__COMPAREUNIT__) == HRTIM_COMPAREUNIT_3) ? ((__HANDLE__)->Instance->sMasterRegs.MCMP3R) :\
((__HANDLE__)->Instance->sMasterRegs.MCMP4R)) \
: \
(((__COMPAREUNIT__) == HRTIM_COMPAREUNIT_1) ? ((__HANDLE__)->Instance->sTimerxRegs[(__TIMER__)].CMP1xR) :\
((__COMPAREUNIT__) == HRTIM_COMPAREUNIT_2) ? ((__HANDLE__)->Instance->sTimerxRegs[(__TIMER__)].CMP2xR) :\
((__COMPAREUNIT__) == HRTIM_COMPAREUNIT_3) ? ((__HANDLE__)->Instance->sTimerxRegs[(__TIMER__)].CMP3xR) :\
((__HANDLE__)->Instance->sTimerxRegs[(__TIMER__)].CMP4xR)))
/**
* @brief Enables the Fault Counter
* @param hhrtim pointer to HAL HRTIM handle
* @param Fault fault input to enable
* This parameter can be one of the following values:
* @arg HRTIM_FAULT_1: Fault input 1
* @arg HRTIM_FAULT_2: Fault input 2
* @arg HRTIM_FAULT_3: Fault input 3
* @arg HRTIM_FAULT_4: Fault input 4
* @arg HRTIM_FAULT_5: Fault input 5
* @arg HRTIM_FAULT_6: Fault input 6
* @note This function must be called when fault is not enabled
* @retval HAL status
*/
#define __HAL_HRTIM_FAULT_BLANKING_ENABLE(__HANDLE__, __FAULT__)\
do {\
if (((__FAULT__) & HRTIM_FAULT_1) == HRTIM_FAULT_1)\
{\
((__HANDLE__)->Instance->sCommonRegs.FLTINR3) |= HRTIM_FLTINR3_FLT1BLKE;\
}\
if (((__FAULT__) & HRTIM_FAULT_2) == HRTIM_FAULT_2)\
{\
((__HANDLE__)->Instance->sCommonRegs.FLTINR3) |= HRTIM_FLTINR3_FLT2BLKE;\
}\
if (((__FAULT__) & HRTIM_FAULT_3) == HRTIM_FAULT_3)\
{\
((__HANDLE__)->Instance->sCommonRegs.FLTINR3) |= HRTIM_FLTINR3_FLT3BLKE;\
}\
if (((__FAULT__) & HRTIM_FAULT_4) == HRTIM_FAULT_4)\
{\
((__HANDLE__)->Instance->sCommonRegs.FLTINR3) |= HRTIM_FLTINR3_FLT4BLKE;\
}\
if (((__FAULT__) & HRTIM_FAULT_5) == HRTIM_FAULT_5)\
{\
((__HANDLE__)->Instance->sCommonRegs.FLTINR4) |= HRTIM_FLTINR4_FLT5BLKE;\
}\
if (((__FAULT__) & HRTIM_FAULT_6) == HRTIM_FAULT_6)\
{\
((__HANDLE__)->Instance->sCommonRegs.FLTINR4) |= HRTIM_FLTINR4_FLT6BLKE;\
}\
} while(0U)
/**
* @brief Disables the Fault Counter
* @param hhrtim pointer to HAL HRTIM handle
* @param Fault fault input to disable
* This parameter can be one of the following values:
* @arg HRTIM_FAULT_1: Fault input 1
* @arg HRTIM_FAULT_2: Fault input 2
* @arg HRTIM_FAULT_3: Fault input 3
* @arg HRTIM_FAULT_4: Fault input 4
* @arg HRTIM_FAULT_5: Fault input 5
* @arg HRTIM_FAULT_6: Fault input 6
* @retval HAL status
*/
#define __HAL_HRTIM_FAULT_BLANKING_DISABLE(__HANDLE__, __FAULT__)\
do {\
if (((__FAULT__) & HRTIM_FAULT_1) == HRTIM_FAULT_1)\
{\
((__HANDLE__)->Instance->sCommonRegs.FLTINR3) &= ~HRTIM_FLTINR3_FLT1BLKE;\
}\
if (((__FAULT__) & HRTIM_FAULT_2) == HRTIM_FAULT_2)\
{\
((__HANDLE__)->Instance->sCommonRegs.FLTINR3) &= ~HRTIM_FLTINR3_FLT2BLKE;\
}\
if (((__FAULT__) & HRTIM_FAULT_3) == HRTIM_FAULT_3)\
{\
((__HANDLE__)->Instance->sCommonRegs.FLTINR3) &= ~HRTIM_FLTINR3_FLT3BLKE;\
}\
if (((__FAULT__) & HRTIM_FAULT_4) == HRTIM_FAULT_4)\
{\
((__HANDLE__)->Instance->sCommonRegs.FLTINR3) &= ~HRTIM_FLTINR3_FLT4BLKE;\
}\
if (((__FAULT__) & HRTIM_FAULT_5) == HRTIM_FAULT_5)\
{\
((__HANDLE__)->Instance->sCommonRegs.FLTINR4) &= ~HRTIM_FLTINR4_FLT5BLKE;\
}\
if (((__FAULT__) & HRTIM_FAULT_6) == HRTIM_FAULT_6)\
{\
((__HANDLE__)->Instance->sCommonRegs.FLTINR4) &= ~HRTIM_FLTINR4_FLT6BLKE;\
}\
} while(0U)
/**
* @}
*/
/* Exported functions --------------------------------------------------------*/
/** @addtogroup HRTIM_Exported_Functions
* @{
*/
/** @addtogroup HRTIM_Exported_Functions_Group1
* @{
*/
/* Initialization and Configuration functions ********************************/
HAL_StatusTypeDef HAL_HRTIM_Init(HRTIM_HandleTypeDef *hhrtim);
HAL_StatusTypeDef HAL_HRTIM_DeInit (HRTIM_HandleTypeDef *hhrtim);
void HAL_HRTIM_MspInit(HRTIM_HandleTypeDef *hhrtim);
void HAL_HRTIM_MspDeInit(HRTIM_HandleTypeDef *hhrtim);
HAL_StatusTypeDef HAL_HRTIM_TimeBaseConfig(HRTIM_HandleTypeDef *hhrtim,
uint32_t TimerIdx,
HRTIM_TimeBaseCfgTypeDef * pTimeBaseCfg);
HAL_StatusTypeDef HAL_HRTIM_DLLCalibrationStart(HRTIM_HandleTypeDef *hhrtim,
uint32_t CalibrationRate);
HAL_StatusTypeDef HAL_HRTIM_DLLCalibrationStart_IT(HRTIM_HandleTypeDef *hhrtim,
uint32_t CalibrationRate);
HAL_StatusTypeDef HAL_HRTIM_PollForDLLCalibration(HRTIM_HandleTypeDef *hhrtim,
uint32_t Timeout);
/**
* @}
*/
/** @addtogroup HRTIM_Exported_Functions_Group2
* @{
*/
/* Simple time base related functions *****************************************/
HAL_StatusTypeDef HAL_HRTIM_SimpleBaseStart(HRTIM_HandleTypeDef *hhrtim,
uint32_t TimerIdx);
HAL_StatusTypeDef HAL_HRTIM_SimpleBaseStop(HRTIM_HandleTypeDef *hhrtim,
uint32_t TimerIdx);
HAL_StatusTypeDef HAL_HRTIM_SimpleBaseStart_IT(HRTIM_HandleTypeDef *hhrtim,
uint32_t TimerIdx);
HAL_StatusTypeDef HAL_HRTIM_SimpleBaseStop_IT(HRTIM_HandleTypeDef *hhrtim,
uint32_t TimerIdx);
HAL_StatusTypeDef HAL_HRTIM_SimpleBaseStart_DMA(HRTIM_HandleTypeDef *hhrtim,
uint32_t TimerIdx,
uint32_t SrcAddr,
uint32_t DestAddr,
uint32_t Length);
HAL_StatusTypeDef HAL_HRTIM_SimpleBaseStop_DMA(HRTIM_HandleTypeDef *hhrtim,
uint32_t TimerIdx);
/**
* @}
*/
/** @addtogroup HRTIM_Exported_Functions_Group3
* @{
*/
/* Simple output compare related functions ************************************/
HAL_StatusTypeDef HAL_HRTIM_SimpleOCChannelConfig(HRTIM_HandleTypeDef *hhrtim,
uint32_t TimerIdx,
uint32_t OCChannel,
HRTIM_SimpleOCChannelCfgTypeDef* pSimpleOCChannelCfg);
HAL_StatusTypeDef HAL_HRTIM_SimpleOCStart(HRTIM_HandleTypeDef *hhrtim,
uint32_t TimerIdx,
uint32_t OCChannel);
HAL_StatusTypeDef HAL_HRTIM_SimpleOCStop(HRTIM_HandleTypeDef *hhrtim,
uint32_t TimerIdx,
uint32_t OCChannel);
HAL_StatusTypeDef HAL_HRTIM_SimpleOCStart_IT(HRTIM_HandleTypeDef *hhrtim,
uint32_t TimerIdx,
uint32_t OCChannel);
HAL_StatusTypeDef HAL_HRTIM_SimpleOCStop_IT(HRTIM_HandleTypeDef *hhrtim,
uint32_t TimerIdx,
uint32_t OCChannel);
HAL_StatusTypeDef HAL_HRTIM_SimpleOCStart_DMA(HRTIM_HandleTypeDef *hhrtim,
uint32_t TimerIdx,
uint32_t OCChannel,
uint32_t SrcAddr,
uint32_t DestAddr,
uint32_t Length);
HAL_StatusTypeDef HAL_HRTIM_SimpleOCStop_DMA(HRTIM_HandleTypeDef *hhrtim,
uint32_t TimerIdx,
uint32_t OCChannel);
/**
* @}
*/
/** @addtogroup HRTIM_Exported_Functions_Group4
* @{
*/
/* Simple PWM output related functions ****************************************/
HAL_StatusTypeDef HAL_HRTIM_SimplePWMChannelConfig(HRTIM_HandleTypeDef *hhrtim,
uint32_t TimerIdx,
uint32_t PWMChannel,
HRTIM_SimplePWMChannelCfgTypeDef* pSimplePWMChannelCfg);
HAL_StatusTypeDef HAL_HRTIM_SimplePWMStart(HRTIM_HandleTypeDef *hhrtim,
uint32_t TimerIdx,
uint32_t PWMChannel);
HAL_StatusTypeDef HAL_HRTIM_SimplePWMStop(HRTIM_HandleTypeDef *hhrtim,
uint32_t TimerIdx,
uint32_t PWMChannel);
HAL_StatusTypeDef HAL_HRTIM_SimplePWMStart_IT(HRTIM_HandleTypeDef *hhrtim,
uint32_t TimerIdx,
uint32_t PWMChannel);
HAL_StatusTypeDef HAL_HRTIM_SimplePWMStop_IT(HRTIM_HandleTypeDef *hhrtim,
uint32_t TimerIdx,
uint32_t PWMChannel);
HAL_StatusTypeDef HAL_HRTIM_SimplePWMStart_DMA(HRTIM_HandleTypeDef *hhrtim,
uint32_t TimerIdx,
uint32_t PWMChannel,
uint32_t SrcAddr,
uint32_t DestAddr,
uint32_t Length);
HAL_StatusTypeDef HAL_HRTIM_SimplePWMStop_DMA(HRTIM_HandleTypeDef *hhrtim,
uint32_t TimerIdx,
uint32_t PWMChannel);
/**
* @}
*/
/** @addtogroup HRTIM_Exported_Functions_Group5
* @{
*/
/* Simple capture related functions *******************************************/
HAL_StatusTypeDef HAL_HRTIM_SimpleCaptureChannelConfig(HRTIM_HandleTypeDef *hhrtim,
uint32_t TimerIdx,
uint32_t CaptureChannel,
HRTIM_SimpleCaptureChannelCfgTypeDef* pSimpleCaptureChannelCfg);
HAL_StatusTypeDef HAL_HRTIM_SimpleCaptureStart(HRTIM_HandleTypeDef *hhrtim,
uint32_t TimerIdx,
uint32_t CaptureChannel);
HAL_StatusTypeDef HAL_HRTIM_SimpleCaptureStop(HRTIM_HandleTypeDef *hhrtim,
uint32_t TimerIdx,
uint32_t CaptureChannel);
HAL_StatusTypeDef HAL_HRTIM_SimpleCaptureStart_IT(HRTIM_HandleTypeDef *hhrtim,
uint32_t TimerIdx,
uint32_t CaptureChannel);
HAL_StatusTypeDef HAL_HRTIM_SimpleCaptureStop_IT(HRTIM_HandleTypeDef *hhrtim,
uint32_t TimerIdx,
uint32_t CaptureChannel);
HAL_StatusTypeDef HAL_HRTIM_SimpleCaptureStart_DMA(HRTIM_HandleTypeDef *hhrtim,
uint32_t TimerIdx,
uint32_t CaptureChannel,
uint32_t SrcAddr,
uint32_t DestAddr,
uint32_t Length);
HAL_StatusTypeDef HAL_HRTIM_SimpleCaptureStop_DMA(HRTIM_HandleTypeDef *hhrtim,
uint32_t TimerIdx,
uint32_t CaptureChannel);
/**
* @}
*/
/** @addtogroup HRTIM_Exported_Functions_Group6
* @{
*/
/* Simple one pulse related functions *****************************************/
HAL_StatusTypeDef HAL_HRTIM_SimpleOnePulseChannelConfig(HRTIM_HandleTypeDef *hhrtim,
uint32_t TimerIdx,
uint32_t OnePulseChannel,
HRTIM_SimpleOnePulseChannelCfgTypeDef* pSimpleOnePulseChannelCfg);
HAL_StatusTypeDef HAL_HRTIM_SimpleOnePulseStart(HRTIM_HandleTypeDef *hhrtim,
uint32_t TimerIdx,
uint32_t OnePulseChannel);
HAL_StatusTypeDef HAL_HRTIM_SimpleOnePulseStop(HRTIM_HandleTypeDef *hhrtim,
uint32_t TimerIdx,
uint32_t OnePulseChannel);
HAL_StatusTypeDef HAL_HRTIM_SimpleOnePulseStart_IT(HRTIM_HandleTypeDef *hhrtim,
uint32_t TimerIdx,
uint32_t OnePulseChannel);
HAL_StatusTypeDef HAL_HRTIM_SimpleOnePulseStop_IT(HRTIM_HandleTypeDef *hhrtim,
uint32_t TimerIdx,
uint32_t OnePulseChannel);
/**
* @}
*/
/** @addtogroup HRTIM_Exported_Functions_Group7
* @{
*/
HAL_StatusTypeDef HAL_HRTIM_BurstModeConfig(HRTIM_HandleTypeDef *hhrtim,
HRTIM_BurstModeCfgTypeDef* pBurstModeCfg);
HAL_StatusTypeDef HAL_HRTIM_EventConfig(HRTIM_HandleTypeDef *hhrtim,
uint32_t Event,
HRTIM_EventCfgTypeDef* pEventCfg);
HAL_StatusTypeDef HAL_HRTIM_EventPrescalerConfig(HRTIM_HandleTypeDef *hhrtim,
uint32_t Prescaler);
HAL_StatusTypeDef HAL_HRTIM_FaultConfig(HRTIM_HandleTypeDef *hhrtim,
uint32_t Fault,
HRTIM_FaultCfgTypeDef* pFaultCfg);
HAL_StatusTypeDef HAL_HRTIM_FaultPrescalerConfig(HRTIM_HandleTypeDef *hhrtim,
uint32_t Prescaler);
HAL_StatusTypeDef HAL_HRTIM_FaultBlankingConfigAndEnable(HRTIM_HandleTypeDef * hhrtim,
uint32_t Fault,
HRTIM_FaultBlankingCfgTypeDef* pFaultBlkCfg);
HAL_StatusTypeDef HAL_HRTIM_FaultCounterConfig(HRTIM_HandleTypeDef * hhrtim,
uint32_t Fault,
HRTIM_FaultBlankingCfgTypeDef* pFaultBlkCfg);
HAL_StatusTypeDef HAL_HRTIM_FaultCounterReset(HRTIM_HandleTypeDef * hhrtim,
uint32_t Fault);
HAL_StatusTypeDef HAL_HRTIM_SwapTimerOutput(HRTIM_HandleTypeDef * hhrtim,
uint32_t Timers);
void HAL_HRTIM_FaultModeCtl(HRTIM_HandleTypeDef * hhrtim,
uint32_t Faults,
uint32_t Enable);
HAL_StatusTypeDef HAL_HRTIM_ADCTriggerConfig(HRTIM_HandleTypeDef *hhrtim,
uint32_t ADCTrigger,
HRTIM_ADCTriggerCfgTypeDef* pADCTriggerCfg);
HAL_StatusTypeDef HAL_HRTIM_ADCPostScalerConfig(HRTIM_HandleTypeDef * hhrtim,
uint32_t ADCTrigger,
uint32_t Postscaler);
HAL_StatusTypeDef HAL_HRTIM_RollOverModeConfig(HRTIM_HandleTypeDef * hhrtim,
uint32_t TimerIdx,
uint32_t RollOverCfg);
HAL_StatusTypeDef HAL_HRTIM_OutputSwapEnable(HRTIM_HandleTypeDef * hhrtim,
uint32_t Timers);
HAL_StatusTypeDef HAL_HRTIM_OutputSwapDisable(HRTIM_HandleTypeDef * hhrtim,
uint32_t Timers);
/**
* @}
*/
/** @addtogroup HRTIM_Exported_Functions_Group8
* @{
*/
/* Waveform related functions *************************************************/
HAL_StatusTypeDef HAL_HRTIM_WaveformTimerConfig(HRTIM_HandleTypeDef *hhrtim,
uint32_t TimerIdx,
HRTIM_TimerCfgTypeDef * pTimerCfg);
HAL_StatusTypeDef HAL_HRTIM_WaveformTimerControl(HRTIM_HandleTypeDef * hhrtim,
uint32_t TimerIdx,
HRTIM_TimerCtlTypeDef * pTimerCtl);
HAL_StatusTypeDef HAL_HRTIM_TimerDualChannelDacConfig(HRTIM_HandleTypeDef * hhrtim,
uint32_t TimerIdx,
HRTIM_TimerCtlTypeDef * pTimerCtl);
HAL_StatusTypeDef HAL_HRTIM_WaveformCompareConfig(HRTIM_HandleTypeDef *hhrtim,
uint32_t TimerIdx,
uint32_t CompareUnit,
HRTIM_CompareCfgTypeDef* pCompareCfg);
HAL_StatusTypeDef HAL_HRTIM_WaveformCaptureConfig(HRTIM_HandleTypeDef *hhrtim,
uint32_t TimerIdx,
uint32_t CaptureUnit,
HRTIM_CaptureCfgTypeDef* pCaptureCfg);
HAL_StatusTypeDef HAL_HRTIM_WaveformOutputConfig(HRTIM_HandleTypeDef *hhrtim,
uint32_t TimerIdx,
uint32_t Output,
HRTIM_OutputCfgTypeDef * pOutputCfg);
HAL_StatusTypeDef HAL_HRTIM_WaveformSetOutputLevel(HRTIM_HandleTypeDef *hhrtim,
uint32_t TimerIdx,
uint32_t Output,
uint32_t OutputLevel);
HAL_StatusTypeDef HAL_HRTIM_TimerEventFilteringConfig(HRTIM_HandleTypeDef *hhrtim,
uint32_t TimerIdx,
uint32_t Event,
HRTIM_TimerEventFilteringCfgTypeDef * pTimerEventFilteringCfg);
HAL_StatusTypeDef HAL_HRTIM_ExtEventCounterConfig(HRTIM_HandleTypeDef * hhrtim,
uint32_t TimerIdx,
uint32_t EventCounter,
HRTIM_ExternalEventCfgTypeDef* pTimerExternalEventCfg);
HAL_StatusTypeDef HAL_HRTIM_ExtEventCounterEnable(HRTIM_HandleTypeDef * hhrtim,
uint32_t TimerIdx,
uint32_t EventCounter);
HAL_StatusTypeDef HAL_HRTIM_ExtEventCounterDisable(HRTIM_HandleTypeDef * hhrtim,
uint32_t TimerIdx,
uint32_t EventCounter);
HAL_StatusTypeDef HAL_HRTIM_ExtEventCounterReset(HRTIM_HandleTypeDef * hhrtim,
uint32_t TimerIdx,
uint32_t EventCounter);
HAL_StatusTypeDef HAL_HRTIM_DeadTimeConfig(HRTIM_HandleTypeDef *hhrtim,
uint32_t TimerIdx,
HRTIM_DeadTimeCfgTypeDef* pDeadTimeCfg);
HAL_StatusTypeDef HAL_HRTIM_ChopperModeConfig(HRTIM_HandleTypeDef *hhrtim,
uint32_t TimerIdx,
HRTIM_ChopperModeCfgTypeDef* pChopperModeCfg);
HAL_StatusTypeDef HAL_HRTIM_BurstDMAConfig(HRTIM_HandleTypeDef *hhrtim,
uint32_t TimerIdx,
uint32_t RegistersToUpdate);
HAL_StatusTypeDef HAL_HRTIM_WaveformCountStart(HRTIM_HandleTypeDef *hhrtim,
uint32_t Timers);
HAL_StatusTypeDef HAL_HRTIM_WaveformCountStop(HRTIM_HandleTypeDef *hhrtim,
uint32_t Timers);
HAL_StatusTypeDef HAL_HRTIM_WaveformCountStart_IT(HRTIM_HandleTypeDef *hhrtim,
uint32_t Timers);
HAL_StatusTypeDef HAL_HRTIM_WaveformCountStop_IT(HRTIM_HandleTypeDef *hhrtim,
uint32_t Timers);
HAL_StatusTypeDef HAL_HRTIM_WaveformCountStart_DMA(HRTIM_HandleTypeDef *hhrtim,
uint32_t Timers);
HAL_StatusTypeDef HAL_HRTIM_WaveformCountStop_DMA(HRTIM_HandleTypeDef *hhrtim,
uint32_t Timers);
HAL_StatusTypeDef HAL_HRTIM_WaveformOutputStart(HRTIM_HandleTypeDef *hhrtim,
uint32_t OutputsToStart);
HAL_StatusTypeDef HAL_HRTIM_WaveformOutputStop(HRTIM_HandleTypeDef *hhrtim,
uint32_t OutputsToStop);
HAL_StatusTypeDef HAL_HRTIM_BurstModeCtl(HRTIM_HandleTypeDef *hhrtim,
uint32_t Enable);
HAL_StatusTypeDef HAL_HRTIM_BurstModeSoftwareTrigger(HRTIM_HandleTypeDef *hhrtim);
HAL_StatusTypeDef HAL_HRTIM_SoftwareCapture(HRTIM_HandleTypeDef *hhrtim,
uint32_t TimerIdx,
uint32_t CaptureUnit);
HAL_StatusTypeDef HAL_HRTIM_SoftwareUpdate(HRTIM_HandleTypeDef *hhrtim,
uint32_t Timers);
HAL_StatusTypeDef HAL_HRTIM_SoftwareReset(HRTIM_HandleTypeDef *hhrtim,
uint32_t Timers);
HAL_StatusTypeDef HAL_HRTIM_BurstDMATransfer(HRTIM_HandleTypeDef *hhrtim,
uint32_t TimerIdx,
uint32_t BurstBufferAddress,
uint32_t BurstBufferLength);
HAL_StatusTypeDef HAL_HRTIM_UpdateEnable(HRTIM_HandleTypeDef *hhrtim,
uint32_t Timers);
HAL_StatusTypeDef HAL_HRTIM_UpdateDisable(HRTIM_HandleTypeDef *hhrtim,
uint32_t Timers);
/**
* @}
*/
/** @addtogroup HRTIM_Exported_Functions_Group9
* @{
*/
/* HRTIM peripheral state functions */
HAL_HRTIM_StateTypeDef HAL_HRTIM_GetState(HRTIM_HandleTypeDef* hhrtim);
uint32_t HAL_HRTIM_GetCapturedValue(HRTIM_HandleTypeDef * hhrtim,
uint32_t TimerIdx,
uint32_t CaptureUnit);
uint32_t HAL_HRTIM_GetCapturedDir(HRTIM_HandleTypeDef * hhrtim,
uint32_t TimerIdx,
uint32_t CaptureUnit);
HRTIM_CaptureValueTypeDef HAL_HRTIM_GetCaptured(HRTIM_HandleTypeDef * hhrtim,
uint32_t TimerIdx,
uint32_t CaptureUnit);
uint32_t HAL_HRTIM_WaveformGetOutputLevel(HRTIM_HandleTypeDef *hhrtim,
uint32_t TimerIdx,
uint32_t Output);
uint32_t HAL_HRTIM_WaveformGetOutputState(HRTIM_HandleTypeDef * hhrtim,
uint32_t TimerIdx,
uint32_t Output);
uint32_t HAL_HRTIM_GetDelayedProtectionStatus(HRTIM_HandleTypeDef *hhrtim,
uint32_t TimerIdx,
uint32_t Output);
uint32_t HAL_HRTIM_GetBurstStatus(HRTIM_HandleTypeDef *hhrtim);
uint32_t HAL_HRTIM_GetCurrentPushPullStatus(HRTIM_HandleTypeDef *hhrtim,
uint32_t TimerIdx);
uint32_t HAL_HRTIM_GetIdlePushPullStatus(HRTIM_HandleTypeDef *hhrtim,
uint32_t TimerIdx);
/**
* @}
*/
/** @addtogroup HRTIM_Exported_Functions_Group10
* @{
*/
/* IRQ handler */
void HAL_HRTIM_IRQHandler(HRTIM_HandleTypeDef *hhrtim,
uint32_t TimerIdx);
/* HRTIM events related callback functions */
void HAL_HRTIM_Fault1Callback(HRTIM_HandleTypeDef *hhrtim);
void HAL_HRTIM_Fault2Callback(HRTIM_HandleTypeDef *hhrtim);
void HAL_HRTIM_Fault3Callback(HRTIM_HandleTypeDef *hhrtim);
void HAL_HRTIM_Fault4Callback(HRTIM_HandleTypeDef *hhrtim);
void HAL_HRTIM_Fault5Callback(HRTIM_HandleTypeDef *hhrtim);
void HAL_HRTIM_Fault6Callback(HRTIM_HandleTypeDef *hhrtim);
void HAL_HRTIM_SystemFaultCallback(HRTIM_HandleTypeDef *hhrtim);
void HAL_HRTIM_DLLCalibrationReadyCallback(HRTIM_HandleTypeDef *hhrtim);
void HAL_HRTIM_BurstModePeriodCallback(HRTIM_HandleTypeDef *hhrtim);
void HAL_HRTIM_SynchronizationEventCallback(HRTIM_HandleTypeDef *hhrtim);
/* Timer events related callback functions */
void HAL_HRTIM_RegistersUpdateCallback(HRTIM_HandleTypeDef *hhrtim,
uint32_t TimerIdx);
void HAL_HRTIM_RepetitionEventCallback(HRTIM_HandleTypeDef *hhrtim,
uint32_t TimerIdx);
void HAL_HRTIM_Compare1EventCallback(HRTIM_HandleTypeDef *hhrtim,
uint32_t TimerIdx);
void HAL_HRTIM_Compare2EventCallback(HRTIM_HandleTypeDef *hhrtim,
uint32_t TimerIdx);
void HAL_HRTIM_Compare3EventCallback(HRTIM_HandleTypeDef *hhrtim,
uint32_t TimerIdx);
void HAL_HRTIM_Compare4EventCallback(HRTIM_HandleTypeDef *hhrtim,
uint32_t TimerIdx);
void HAL_HRTIM_Capture1EventCallback(HRTIM_HandleTypeDef *hhrtim,
uint32_t TimerIdx);
void HAL_HRTIM_Capture2EventCallback(HRTIM_HandleTypeDef *hhrtim,
uint32_t TimerIdx);
void HAL_HRTIM_DelayedProtectionCallback(HRTIM_HandleTypeDef *hhrtim,
uint32_t TimerIdx);
void HAL_HRTIM_CounterResetCallback(HRTIM_HandleTypeDef *hhrtim,
uint32_t TimerIdx);
void HAL_HRTIM_Output1SetCallback(HRTIM_HandleTypeDef *hhrtim,
uint32_t TimerIdx);
void HAL_HRTIM_Output1ResetCallback(HRTIM_HandleTypeDef *hhrtim,
uint32_t TimerIdx);
void HAL_HRTIM_Output2SetCallback(HRTIM_HandleTypeDef *hhrtim,
uint32_t TimerIdx);
void HAL_HRTIM_Output2ResetCallback(HRTIM_HandleTypeDef *hhrtim,
uint32_t TimerIdx);
void HAL_HRTIM_BurstDMATransferCallback(HRTIM_HandleTypeDef *hhrtim,
uint32_t TimerIdx);
void HAL_HRTIM_ErrorCallback(HRTIM_HandleTypeDef *hhrtim);
#if (USE_HAL_HRTIM_REGISTER_CALLBACKS == 1)
HAL_StatusTypeDef HAL_HRTIM_RegisterCallback(HRTIM_HandleTypeDef * hhrtim,
HAL_HRTIM_CallbackIDTypeDef CallbackID,
pHRTIM_CallbackTypeDef pCallback);
HAL_StatusTypeDef HAL_HRTIM_UnRegisterCallback(HRTIM_HandleTypeDef * hhrtim,
HAL_HRTIM_CallbackIDTypeDef CallbackID);
HAL_StatusTypeDef HAL_HRTIM_TIMxRegisterCallback(HRTIM_HandleTypeDef * hhrtim,
HAL_HRTIM_CallbackIDTypeDef CallbackID,
pHRTIM_TIMxCallbackTypeDef pCallback);
HAL_StatusTypeDef HAL_HRTIM_TIMxUnRegisterCallback(HRTIM_HandleTypeDef * hhrtim,
HAL_HRTIM_CallbackIDTypeDef CallbackID);
#endif /* USE_HAL_HRTIM_REGISTER_CALLBACKS */
/**
* @}
*/
/**
* @}
*/
/**
* @}
*/
/**
* @}
*/
#endif /* HRTIM1 */
#ifdef __cplusplus
}
#endif
#endif /* STM32G4xx_HAL_HRTIM_H */