rt-thread/bsp/nuvoton/libraries/m031/StdDriver/inc/nu_adc.h

419 lines
21 KiB
C

/**************************************************************************//**
* @file nu_adc.h
* @version V0.10
* $Revision: 2 $
* $Date: 19/01/11 11:23a $
* @brief M031 Series ADC Driver Header File
*
* @note
* SPDX-License-Identifier: Apache-2.0
* Copyright (C) 2018 Nuvoton Technology Corp. All rights reserved.
*****************************************************************************/
#ifndef __NU_ADC_H__
#define __NU_ADC_H__
#ifdef __cplusplus
extern "C"
{
#endif
/** @addtogroup Standard_Driver Standard Driver
@{
*/
/** @addtogroup ADC_Driver ADC Driver
@{
*/
/** @addtogroup ADC_EXPORTED_CONSTANTS ADC Exported Constants
@{
*/
/*---------------------------------------------------------------------------------------------------------*/
/* ADCR Constant Definitions */
/*---------------------------------------------------------------------------------------------------------*/
#define ADC_ADCR_ADEN_CONVERTER_DISABLE (0UL<<ADC_ADCR_ADEN_Pos) /*!< ADC converter disable \hideinitializer */
#define ADC_ADCR_ADEN_CONVERTER_ENABLE (1UL<<ADC_ADCR_ADEN_Pos) /*!< ADC converter enable \hideinitializer */
#define ADC_ADCR_ADMD_SINGLE (0UL<<ADC_ADCR_ADMD_Pos) /*!< Single mode \hideinitializer */
#define ADC_ADCR_ADMD_BURST (1UL<<ADC_ADCR_ADMD_Pos) /*!< Burst mode \hideinitializer */
#define ADC_ADCR_ADMD_SINGLE_CYCLE (2UL<<ADC_ADCR_ADMD_Pos) /*!< Single cycle scan mode \hideinitializer */
#define ADC_ADCR_ADMD_CONTINUOUS (3UL<<ADC_ADCR_ADMD_Pos) /*!< Continuous scan mode \hideinitializer */
#define ADC_ADCR_DIFFEN_SINGLE_END (0UL<<ADC_ADCR_DIFFEN_Pos) /*!< Single-end input mode \hideinitializer */
#define ADC_ADCR_DIFFEN_DIFFERENTIAL (1UL<<ADC_ADCR_DIFFEN_Pos) /*!< Differential input mode \hideinitializer */
#define ADC_ADCR_DMOF_UNSIGNED_OUTPUT (0UL<<ADC_ADCR_DMOF_Pos) /*!< Select the straight binary format as the output format of the conversion result \hideinitializer */
#define ADC_ADCR_DMOF_TWOS_COMPLEMENT (1UL<<ADC_ADCR_DMOF_Pos) /*!< Select the 2's complement format as the output format of the conversion result \hideinitializer */
#define ADC_ADCR_TRGEN_DISABLE (0UL<<ADC_ADCR_TRGEN_Pos) /*!< Disable triggering of A/D conversion by external STADC pin or PWM \hideinitializer */
#define ADC_ADCR_TRGEN_ENABLE (1UL<<ADC_ADCR_TRGEN_Pos) /*!< Enable triggering of A/D conversion by external STADC pin or PWM \hideinitializer */
#define ADC_ADCR_TRGS_STADC (0UL<<ADC_ADCR_TRGS_Pos) /*!< A/D conversion is started by external STADC pin \hideinitializer */
#define ADC_ADCR_TRGS_TIMER (1UL<<ADC_ADCR_TRGS_Pos) /*!< A/D conversion is started by Timer \hideinitializer */
#define ADC_ADCR_TRGS_BPWM (2UL<<ADC_ADCR_TRGS_Pos) /*!< A/D conversion is started by BPWM \hideinitializer */
#define ADC_ADCR_TRGS_PWM (3UL<<ADC_ADCR_TRGS_Pos) /*!< A/D conversion is started by PWM \hideinitializer */
#define ADC_ADCR_TRGCOND_LOW_LEVEL (0UL<<ADC_ADCR_TRGCOND_Pos) /*!< STADC Low level active \hideinitializer */
#define ADC_ADCR_TRGCOND_HIGH_LEVEL (1UL<<ADC_ADCR_TRGCOND_Pos) /*!< STADC High level active \hideinitializer */
#define ADC_ADCR_TRGCOND_FALLING_EDGE (2UL<<ADC_ADCR_TRGCOND_Pos) /*!< STADC Falling edge active \hideinitializer */
#define ADC_ADCR_TRGCOND_RISING_EDGE (3UL<<ADC_ADCR_TRGCOND_Pos) /*!< STADC Rising edge active \hideinitializer */
/*---------------------------------------------------------------------------------------------------------*/
/* ADCMPR Constant Definitions */
/*---------------------------------------------------------------------------------------------------------*/
#define ADC_ADCMPR_CMPD(x) ((x) << ADC_ADCMPR_CMPD_Pos) /*!< Compare value for compare function \hideinitializer */
#define ADC_ADCMPR_CMPMATCNT(x) (((x)-1) << ADC_ADCMPR_CMPMATCNT_Pos) /*!< Match count for compare function \hideinitializer */
#define ADC_ADCMPR_CMPCH(x) ((x) << ADC_ADCMPR_CMPCH_Pos) /*!< Compare channel for compare function \hideinitializer */
#define ADC_ADCMPR_CMPCOND_LESS_THAN (0<<ADC_ADCMPR_CMPCOND_Pos) /*!< The compare condition is "less than" \hideinitializer */
#define ADC_ADCMPR_CMPCOND_GREATER_OR_EQUAL (1<<ADC_ADCMPR_CMPCOND_Pos) /*!< The compare condition is "greater than or equal to" \hideinitializer */
#define ADC_ADCMPR_CMPIE_INTERRUPT_ENABLE (ADC_ADCMPR_CMPIE_Msk) /*!< The compare function interrupt enable \hideinitializer */
/*---------------------------------------------------------------------------------------------------------*/
/* ADC Interrupt Constant Definitions */
/*---------------------------------------------------------------------------------------------------------*/
#define ADC_ADF_INT (ADC_ADSR0_ADF_Msk) /*!< ADC convert complete interrupt \hideinitializer */
#define ADC_CMP0_INT (ADC_ADSR0_CMPF0_Msk) /*!< ADC comparator 0 interrupt \hideinitializer */
#define ADC_CMP1_INT (ADC_ADSR0_CMPF1_Msk) /*!< ADC comparator 1 interrupt \hideinitializer */
/*---------------------------------------------------------------------------------------------------------*/
/* ADC Operation Mode Constant Definitions */
/*---------------------------------------------------------------------------------------------------------*/
#define ADC_SINGLE_MODE 0 /*!< ADC single mode \hideinitializer */
#define ADC_BURST_MODE 1 /*!< ADC burst mode \hideinitializer */
#define ADC_SINGLE_CYCLE_MODE 2 /*!< ADC single-cycle scan mode \hideinitializer */
#define ADC_CONTINUOUS_MODE 3 /*!< ADC continuous scan mode \hideinitializer */
/*---------------------------------------------------------------------------------------------------------*/
/* ADC Trigger Condition Constant Definitions */
/*---------------------------------------------------------------------------------------------------------*/
#define ADC_LOW_LEVEL 0 /*!< ADC external trigger condition is low level trigger \hideinitializer */
#define ADC_HIGH_LEVEL 1 /*!< ADC external trigger condition is high level trigger \hideinitializer */
#define ADC_FALLING_EDGE 2 /*!< ADC external trigger condition is falling edge trigger \hideinitializer */
#define ADC_RISING_EDGE 3 /*!< ADC external trigger condition is rising edge trigger \hideinitializer */
/*---------------------------------------------------------------------------------------------------------*/
/* ADC Compare Condition Constant Definitions */
/*---------------------------------------------------------------------------------------------------------*/
#define ADC_LESS_THAN 0 /*!< ADC compare condition is "less than the compare value" \hideinitializer */
#define ADC_GREATER_OR_EQUAL 1 /*!< ADC compare condition is "greater than or equal to the compare value" \hideinitializer */
/*@}*/ /* end of group ADC_EXPORTED_CONSTANTS */
/** @addtogroup ADC_EXPORTED_FUNCTIONS ADC Exported Functions
@{
*/
/**
* @brief Get conversion data of specified channel.
* @param[in] adc The pointer of the specified ADC module.
* @param[in] u32ChNum ADC Channel, valid value are from 0 to 15 and 29.
* @return 16-bit data.
* @details Read RSLT bit field to get conversion data.
* \hideinitializer
*/
#define ADC_GET_CONVERSION_DATA(adc, u32ChNum) ((adc)->ADDR[(u32ChNum)] & ADC_ADDR_RSLT_Msk)
/**
* @brief Return the user-specified interrupt flags.
* @param[in] adc The pointer of the specified ADC module.
* @param[in] u32Mask The combination of following interrupt status bits. Each bit corresponds to a interrupt status.
* Valid values are:
* - \ref ADC_ADF_INT :Convert complete interrupt flag.
* - \ref ADC_CMP0_INT :Comparator 0 interrupt flag.
* - \ref ADC_CMP1_INT :Comparator 1 interrupt flag.
* @return User specified interrupt flags.
* @details Get the status of the ADC interrupt flag.
* \hideinitializer
*/
#define ADC_GET_INT_FLAG(adc, u32Mask) ((adc)->ADSR0 & (u32Mask))
/**
* @brief This macro clear the selected interrupt status bits.
* @param[in] adc The pointer of the specified ADC module.
* @param[in] u32Mask The combination of following interrupt status bits. Each bit corresponds to a interrupt status.
* Valid values are:
* - \ref ADC_ADF_INT :Convert complete interrupt flag.
* - \ref ADC_CMP0_INT :Comparator 0 interrupt flag.
* - \ref ADC_CMP1_INT :Comparator 1 interrupt flag.
* @return None
* @details ADF (ADSR0[0])/CMPF0 (ADSR0[1])/CMPF1 (ADSR0[2]) can be cleared by writing 1 to itself.
* \hideinitializer
*/
#define ADC_CLR_INT_FLAG(adc, u32Mask) ((adc)->ADSR0 = (u32Mask))
/**
* @brief Get the busy state of ADC.
* @param[in] adc The pointer of the specified ADC module.
* @retval 0 ADC is not busy.
* @retval 1 ADC is busy.
* @details ADSR0[7] (BUSY) is a mirror of ADCR[11] (ADST).
* \hideinitializer
*/
#define ADC_IS_BUSY(adc) ((adc)->ADSR0 & ADC_ADSR0_BUSY_Msk ? 1 : 0)
/**
* @brief Check if the ADC conversion data is over written or not.
* @param[in] adc The pointer of the specified ADC module.
* @param[in] u32ChNum ADC Channel, valid value are from 0 to 15 and 29.
* @retval 0 ADC data is not overrun.
* @retval 1 ADC data is overrun.
* @details ADSR2[31:0] (OVERRUN) is the mirror of ADDR0~31[16] OVERRUN bits.
* \hideinitializer
*/
#define ADC_IS_DATA_OVERRUN(adc, u32ChNum) (((adc)->ADSR2 & (1<<(u32ChNum))) ? 1 : 0)
/**
* @brief Check if the ADC conversion data is valid or not.
* @param[in] adc The pointer of the specified ADC module.
* @param[in] u32ChNum ADC Channel, valid value are from 0 to 15 and 29.
* @retval 0 ADC data is not valid.
* @retval 1 ADC data is valid.
* @details VALID (ADDR0~31[17]) is set to 1 when corresponding channel analog input conversion is completed and cleared by hardware after ADDR register is read.
* \hideinitializer
*/
#define ADC_IS_DATA_VALID(adc, u32ChNum) ((adc)->ADSR1 & (0x1<<(u32ChNum)) ? 1 : 0)
/**
* @brief Power down ADC module.
* @param[in] adc The pointer of the specified ADC module.
* @return None
* @details Disable A/D converter analog circuit for saving power consumption.
* \hideinitializer
*/
#define ADC_POWER_DOWN(adc) ((adc)->ADCR &= ~ADC_ADCR_ADEN_Msk)
/**
* @brief Power on ADC module.
* @param[in] adc The pointer of the specified ADC module.
* @return None
* @details Before starting A/D conversion function, ADEN bit (ADCR[0]) should be set to 1.
* \hideinitializer
*/
#define ADC_POWER_ON(adc) ((adc)->ADCR |= ADC_ADCR_ADEN_Msk)
/**
* @brief Configure the comparator 0 and enable it.
* @param[in] adc The pointer of the specified ADC module.
* @param[in] u32ChNum Specifies the source channel, valid value are from 0 to 15 and 29.
* @param[in] u32Condition Specifies the compare condition. Valid values are:
* - \ref ADC_ADCMPR_CMPCOND_LESS_THAN :The compare condition is "less than the compare value".
* - \ref ADC_ADCMPR_CMPCOND_GREATER_OR_EQUAL :The compare condition is "greater than or equal to the compare value".
* @param[in] u32Data Specifies the compare value, valid value are between 0 ~ 0xFFF.
* @param[in] u32MatchCount Specifies the match count setting, valid values are between 1~16.
* @return None
* @details For example, ADC_ENABLE_CMP0(ADC, 5, ADC_ADCMPR_CMPCOND_GREATER_OR_EQUAL, 0x800, 10);
* means ADC will assert comparator 0 flag if channel 5 conversion result is greater than or
* equal to 0x800 for 10 times continuously.
* \hideinitializer
*/
#define ADC_ENABLE_CMP0(adc, \
u32ChNum, \
u32Condition, \
u32Data, \
u32MatchCount) ((adc)->ADCMPR[0] = ((u32ChNum) << ADC_ADCMPR_CMPCH_Pos) | \
(u32Condition) | \
((u32Data) << ADC_ADCMPR_CMPD_Pos) | \
(((u32MatchCount) - 1) << ADC_ADCMPR_CMPMATCNT_Pos) |\
ADC_ADCMPR_CMPEN_Msk)
/**
* @brief Disable comparator 0
* @param[in] adc The pointer of the specified ADC module
* @return None
* @details Set CMPEN (ADCMPR0[0]) to 0 and reset comparator 0 configurations to disable ADC compare function.
* \hideinitializer
*/
#define ADC_DISABLE_CMP0(adc) ((adc)->ADCMPR[0] = 0)
/**
* @brief Configure the comparator 1 and enable it.
* @param[in] adc The pointer of the specified ADC module.
* @param[in] u32ChNum Specifies the source channel, valid value are from 0 to 15 and 29.
* @param[in] u32Condition Specifies the compare condition. Valid values are:
* - \ref ADC_ADCMPR_CMPCOND_LESS_THAN :The compare condition is "less than the compare value".
* - \ref ADC_ADCMPR_CMPCOND_GREATER_OR_EQUAL :The compare condition is "greater than or equal to the compare value".
* @param[in] u32Data Specifies the compare value, valid value are between 0 ~ 0xFFF.
* @param[in] u32MatchCount Specifies the match count setting, valid values are between 1~16.
* @return None
* @details For example, ADC_ENABLE_CMP1(ADC, 5, ADC_ADCMPR_CMPCOND_GREATER_OR_EQUAL, 0x800, 10);
* means ADC will assert comparator 1 flag if channel 5 conversion result is greater than or
* equal to 0x800 for 10 times continuously.
* \hideinitializer
*/
#define ADC_ENABLE_CMP1(adc, \
u32ChNum, \
u32Condition, \
u32Data, \
u32MatchCount) ((adc)->ADCMPR[1] = ((u32ChNum) << ADC_ADCMPR_CMPCH_Pos) | \
(u32Condition) | \
((u32Data) << ADC_ADCMPR_CMPD_Pos) | \
(((u32MatchCount) - 1) << ADC_ADCMPR_CMPMATCNT_Pos) |\
ADC_ADCMPR_CMPEN_Msk)
/**
* @brief Disable comparator 1.
* @param[in] adc The pointer of the specified ADC module.
* @return None
* @details Set CMPEN (ADCMPR1[0]) to 0 and reset comparator 1 configurations to disable ADC compare function.
* \hideinitializer
*/
#define ADC_DISABLE_CMP1(adc) ((adc)->ADCMPR[1] = 0)
/**
* @brief Enable the compare window mode.
* @param[in] adc The pointer of the specified ADC module.
* @param[in] u32CMP Specifies the compare register, valid value are 0.
* @return None
* @details CMPF0 (ADSR0[1]) will be set when both ADC_CMP0 and ADC_CMP1 compared condition matched.
* \hideinitializer
*/
#define ADC_ENABLE_CMP_WINDOW_MODE(adc, u32CMP) ((adc)->ADCMPR[(u32CMP)] |= ADC_ADCMPR_CMPWEN_Msk)
/**
* @brief Disable the compare window mode.
* @param[in] adc The pointer of the specified ADC module.
* @param[in] u32CMP Specifies the compare register, valid value are 0.
* @return None
* @details Disable the compare window mode for specified ADC module.
* \hideinitializer
*/
#define ADC_DISABLE_CMP_WINDOW_MODE(adc, u32CMP) ((adc)->ADCMPR[(u32CMP)] &= ~ADC_ADCMPR_CMPWEN_Msk)
/**
* @brief Set ADC input channel.
* @param[in] adc The pointer of the specified ADC module.
* @param[in] u32Mask Channel enable bit. Each bit corresponds to a input channel. Bit 0 is channel 0, bit 1 is channel 1..., bit 15 is channel 15.
* @return None
* @details Enabled channel will be converted while ADC starts.
* @note In single mode, ADC can only convert 1 channel. If more than 1 channel are enabled, only the channel with smallest number will be converted.
* \hideinitializer
*/
#define ADC_SET_INPUT_CHANNEL(adc, u32Mask) ((adc)->ADCHER = ((adc)->ADCHER & ~ADC_ADCHER_CHEN_Msk) | (u32Mask))
/**
* @brief Set the output format mode.
* @param[in] adc The pointer of the specified ADC module.
* @param[in] u32Format Decides the output format. Valid values are:
* - \ref ADC_ADCR_DMOF_UNSIGNED_OUTPUT : Select the straight binary format as the output format of the conversion result.
* - \ref ADC_ADCR_DMOF_TWOS_COMPLEMENT : Select the 2's complement format as the output format of the conversion result.
* @return None
* @details The macro is used to set the output format of ADC differential input mode.
* @note ADC compare function can not support 2's complement output format, u32Format should be set to ADC_ADCR_DMOF_UNSIGNED_OUTPUT.
* \hideinitializer
*/
#define ADC_SET_DMOF(adc, u32Format) ((adc)->ADCR = ((adc)->ADCR & ~ADC_ADCR_DMOF_Msk) | (u32Format))
/**
* @brief Start the A/D conversion.
* @param[in] adc The pointer of the specified ADC module.
* @return None
* @details Set ADST bit to 1 to start the A/D conversion.
* \hideinitializer
*/
#define ADC_START_CONV(adc) ((adc)->ADCR |= ADC_ADCR_ADST_Msk)
/**
* @brief Stop the A/D conversion.
* @param[in] adc The pointer of the specified ADC module.
* @return None
* @details ADST (ADCR[11]) will be cleared to 0 by hardware automatically at the ends of single mode and single-cycle scan mode.
* In continuous scan mode and burst mode, A/D conversion is continuously performed until software writes 0 to this bit.
* @note When the ADST bit is cleared to 0, the ADST bit must be kept at 0 at least one ADC peripheral clock period
* before setting it to 1 again, otherwise the A/D converter may not work.
* If ADST bit is cleared to 0 when ADC is in converting, the BUSY bit will be cleared to 0 immediately,
* ADC will terminate the current conversion and enter idle state directly.
* \hideinitializer
*/
#define ADC_STOP_CONV(adc) ((adc)->ADCR &= ~ADC_ADCR_ADST_Msk)
/**
* @brief Enable PDMA transfer.
* @param[in] adc The pointer of the specified ADC module
* @return None
* @details Enable PDMA to transfer the conversion data.
* @note While enable PDMA transfer, software must set ADIE = 0 to disable interrupt.
* \hideinitializer
*/
#define ADC_ENABLE_PDMA(adc) ((adc)->ADCR |= ADC_ADCR_PTEN_Msk)
/**
* @brief Disable PDMA transfer.
* @param[in] adc The pointer of the specified ADC module
* @return None
* @details Disable PDMA to transfer the conversion data.
* \hideinitializer
*/
#define ADC_DISABLE_PDMA(adc) ((adc)->ADCR &= ~ADC_ADCR_PTEN_Msk)
/**
* @brief Get PDMA current transfer data
* @param[in] adc The pointer of the specified ADC module.
* @return PDMA current transfer data
* \hideinitializer
*/
#define ADC_GET_PDMA_DATA(adc) ((adc)->ADPDMA & ADC_ADPDMA_CURDAT_Msk)
/**
* @brief Enable the interrupt(s) selected by u32Mask parameter.
* @param[in] adc The pointer of the specified ADC module
* @param[in] u32Mask The combination of interrupt status bits listed below. Each bit
* corresponds to a interrupt status. This parameter decides which
* interrupts will be enabled.
* - \ref ADC_ADF_INT :ADC convert complete interrupt
* - \ref ADC_CMP0_INT :ADC comparator 0 interrupt
* - \ref ADC_CMP1_INT :ADC comparator 1 interrupt
* @return None
* \hideinitializer
*/
#define ADC_ENABLE_INT ADC_EnableInt
/**
* @brief Disable the interrupt(s) selected by u32Mask parameter.
* @param[in] adc The pointer of the specified ADC module
* @param[in] u32Mask The combination of interrupt status bits listed below. Each bit
* corresponds to a interrupt status. This parameter decides which
* interrupts will be disabled.
* - \ref ADC_ADF_INT :ADC convert complete interrupt
* - \ref ADC_CMP0_INT :ADC comparator 0 interrupt
* - \ref ADC_CMP1_INT :ADC comparator 1 interrupt
* @return None
* \hideinitializer
*/
#define ADC_DISABLE_INT ADC_DisableInt
void ADC_Open(ADC_T *adc,
uint32_t u32InputMode,
uint32_t u32OpMode,
uint32_t u32ChMask);
void ADC_Close(ADC_T *adc);
void ADC_EnableHWTrigger(ADC_T *adc,
uint32_t u32Source,
uint32_t u32Param);
void ADC_DisableHWTrigger(ADC_T *adc);
void ADC_EnableInt(ADC_T *adc, uint32_t u32Mask);
void ADC_DisableInt(ADC_T *adc, uint32_t u32Mask);
void ADC_SetExtendSampleTime(ADC_T *adc,
uint32_t u32ModuleNum,
uint32_t u32ExtendSampleTime);
/*@}*/ /* end of group ADC_EXPORTED_FUNCTIONS */
/*@}*/ /* end of group ADC_Driver */
/*@}*/ /* end of group Standard_Driver */
#ifdef __cplusplus
}
#endif
#endif //__NU_ADC_H__
/*** (C) COPYRIGHT 2018 Nuvoton Technology Corp. ***/