rt-thread/bsp/frdm-k64f/device/MK64F12/MK64F12_adc.h

2579 lines
96 KiB
C

/*
* Copyright (c) 2014, Freescale Semiconductor, Inc.
* All rights reserved.
*
* THIS SOFTWARE IS PROVIDED BY FREESCALE "AS IS" AND ANY EXPRESS OR IMPLIED
* WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF
* MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT
* SHALL FREESCALE BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL,
* EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT
* OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS
* INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN
* CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING
* IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY
* OF SUCH DAMAGE.
*/
/*
* WARNING! DO NOT EDIT THIS FILE DIRECTLY!
*
* This file was generated automatically and any changes may be lost.
*/
#ifndef __HW_ADC_REGISTERS_H__
#define __HW_ADC_REGISTERS_H__
#include "regs.h"
/*
* MK64F12 ADC
*
* Analog-to-Digital Converter
*
* Registers defined in this header file:
* - HW_ADC_SC1n - ADC Status and Control Registers 1
* - HW_ADC_CFG1 - ADC Configuration Register 1
* - HW_ADC_CFG2 - ADC Configuration Register 2
* - HW_ADC_Rn - ADC Data Result Register
* - HW_ADC_CV1 - Compare Value Registers
* - HW_ADC_CV2 - Compare Value Registers
* - HW_ADC_SC2 - Status and Control Register 2
* - HW_ADC_SC3 - Status and Control Register 3
* - HW_ADC_OFS - ADC Offset Correction Register
* - HW_ADC_PG - ADC Plus-Side Gain Register
* - HW_ADC_MG - ADC Minus-Side Gain Register
* - HW_ADC_CLPD - ADC Plus-Side General Calibration Value Register
* - HW_ADC_CLPS - ADC Plus-Side General Calibration Value Register
* - HW_ADC_CLP4 - ADC Plus-Side General Calibration Value Register
* - HW_ADC_CLP3 - ADC Plus-Side General Calibration Value Register
* - HW_ADC_CLP2 - ADC Plus-Side General Calibration Value Register
* - HW_ADC_CLP1 - ADC Plus-Side General Calibration Value Register
* - HW_ADC_CLP0 - ADC Plus-Side General Calibration Value Register
* - HW_ADC_CLMD - ADC Minus-Side General Calibration Value Register
* - HW_ADC_CLMS - ADC Minus-Side General Calibration Value Register
* - HW_ADC_CLM4 - ADC Minus-Side General Calibration Value Register
* - HW_ADC_CLM3 - ADC Minus-Side General Calibration Value Register
* - HW_ADC_CLM2 - ADC Minus-Side General Calibration Value Register
* - HW_ADC_CLM1 - ADC Minus-Side General Calibration Value Register
* - HW_ADC_CLM0 - ADC Minus-Side General Calibration Value Register
*
* - hw_adc_t - Struct containing all module registers.
*/
//! @name Module base addresses
//@{
#ifndef REGS_ADC_BASE
#define HW_ADC_INSTANCE_COUNT (2U) //!< Number of instances of the ADC module.
#define HW_ADC0 (0U) //!< Instance number for ADC0.
#define HW_ADC1 (1U) //!< Instance number for ADC1.
#define REGS_ADC0_BASE (0x4003B000U) //!< Base address for ADC0.
#define REGS_ADC1_BASE (0x400BB000U) //!< Base address for ADC1.
//! @brief Table of base addresses for ADC instances.
static const uint32_t __g_regs_ADC_base_addresses[] = {
REGS_ADC0_BASE,
REGS_ADC1_BASE,
};
//! @brief Get the base address of ADC by instance number.
//! @param x ADC instance number, from 0 through 1.
#define REGS_ADC_BASE(x) (__g_regs_ADC_base_addresses[(x)])
//! @brief Get the instance number given a base address.
//! @param b Base address for an instance of ADC.
#define REGS_ADC_INSTANCE(b) ((b) == REGS_ADC0_BASE ? HW_ADC0 : (b) == REGS_ADC1_BASE ? HW_ADC1 : 0)
#endif
//@}
//-------------------------------------------------------------------------------------------
// HW_ADC_SC1n - ADC Status and Control Registers 1
//-------------------------------------------------------------------------------------------
#ifndef __LANGUAGE_ASM__
/*!
* @brief HW_ADC_SC1n - ADC Status and Control Registers 1 (RW)
*
* Reset value: 0x0000001FU
*
* SC1A is used for both software and hardware trigger modes of operation. To
* allow sequential conversions of the ADC to be triggered by internal peripherals,
* the ADC can have more than one status and control register: one for each
* conversion. The SC1B-SC1n registers indicate potentially multiple SC1 registers
* for use only in hardware trigger mode. See the chip configuration information
* about the number of SC1n registers specific to this device. The SC1n registers
* have identical fields, and are used in a "ping-pong" approach to control ADC
* operation. At any one point in time, only one of the SC1n registers is actively
* controlling ADC conversions. Updating SC1A while SC1n is actively controlling
* a conversion is allowed, and vice-versa for any of the SC1n registers specific
* to this MCU. Writing SC1A while SC1A is actively controlling a conversion
* aborts the current conversion. In Software Trigger mode, when SC2[ADTRG]=0,
* writes to SC1A subsequently initiate a new conversion, if SC1[ADCH] contains a
* value other than all 1s. Writing any of the SC1n registers while that specific
* SC1n register is actively controlling a conversion aborts the current conversion.
* None of the SC1B-SC1n registers are used for software trigger operation and
* therefore writes to the SC1B-SC1n registers do not initiate a new conversion.
*/
typedef union _hw_adc_sc1n
{
uint32_t U;
struct _hw_adc_sc1n_bitfields
{
uint32_t ADCH : 5; //!< [4:0] Input channel select
uint32_t DIFF : 1; //!< [5] Differential Mode Enable
uint32_t AIEN : 1; //!< [6] Interrupt Enable
uint32_t COCO : 1; //!< [7] Conversion Complete Flag
uint32_t RESERVED0 : 24; //!< [31:8]
} B;
} hw_adc_sc1n_t;
#endif
/*!
* @name Constants and macros for entire ADC_SC1n register
*/
//@{
#define HW_ADC_SC1n_COUNT (2U)
#define HW_ADC_SC1n_ADDR(x, n) (REGS_ADC_BASE(x) + 0x0U + (0x4U * n))
#ifndef __LANGUAGE_ASM__
#define HW_ADC_SC1n(x, n) (*(__IO hw_adc_sc1n_t *) HW_ADC_SC1n_ADDR(x, n))
#define HW_ADC_SC1n_RD(x, n) (HW_ADC_SC1n(x, n).U)
#define HW_ADC_SC1n_WR(x, n, v) (HW_ADC_SC1n(x, n).U = (v))
#define HW_ADC_SC1n_SET(x, n, v) (HW_ADC_SC1n_WR(x, n, HW_ADC_SC1n_RD(x, n) | (v)))
#define HW_ADC_SC1n_CLR(x, n, v) (HW_ADC_SC1n_WR(x, n, HW_ADC_SC1n_RD(x, n) & ~(v)))
#define HW_ADC_SC1n_TOG(x, n, v) (HW_ADC_SC1n_WR(x, n, HW_ADC_SC1n_RD(x, n) ^ (v)))
#endif
//@}
/*
* Constants & macros for individual ADC_SC1n bitfields
*/
/*!
* @name Register ADC_SC1n, field ADCH[4:0] (RW)
*
* Selects one of the input channels. The input channel decode depends on the
* value of DIFF. DAD0-DAD3 are associated with the input pin pairs DADPx and
* DADMx. Some of the input channel options in the bitfield-setting descriptions might
* not be available for your device. For the actual ADC channel assignments for
* your device, see the Chip Configuration details. The successive approximation
* converter subsystem is turned off when the channel select bits are all set,
* that is, ADCH = 11111. This feature allows explicit disabling of the ADC and
* isolation of the input channel from all sources. Terminating continuous
* conversions this way prevents an additional single conversion from being performed. It
* is not necessary to set ADCH to all 1s to place the ADC in a low-power state
* when continuous conversions are not enabled because the module automatically
* enters a low-power state when a conversion completes.
*
* Values:
* - 00000 - When DIFF=0, DADP0 is selected as input; when DIFF=1, DAD0 is
* selected as input.
* - 00001 - When DIFF=0, DADP1 is selected as input; when DIFF=1, DAD1 is
* selected as input.
* - 00010 - When DIFF=0, DADP2 is selected as input; when DIFF=1, DAD2 is
* selected as input.
* - 00011 - When DIFF=0, DADP3 is selected as input; when DIFF=1, DAD3 is
* selected as input.
* - 00100 - When DIFF=0, AD4 is selected as input; when DIFF=1, it is reserved.
* - 00101 - When DIFF=0, AD5 is selected as input; when DIFF=1, it is reserved.
* - 00110 - When DIFF=0, AD6 is selected as input; when DIFF=1, it is reserved.
* - 00111 - When DIFF=0, AD7 is selected as input; when DIFF=1, it is reserved.
* - 01000 - When DIFF=0, AD8 is selected as input; when DIFF=1, it is reserved.
* - 01001 - When DIFF=0, AD9 is selected as input; when DIFF=1, it is reserved.
* - 01010 - When DIFF=0, AD10 is selected as input; when DIFF=1, it is reserved.
* - 01011 - When DIFF=0, AD11 is selected as input; when DIFF=1, it is reserved.
* - 01100 - When DIFF=0, AD12 is selected as input; when DIFF=1, it is reserved.
* - 01101 - When DIFF=0, AD13 is selected as input; when DIFF=1, it is reserved.
* - 01110 - When DIFF=0, AD14 is selected as input; when DIFF=1, it is reserved.
* - 01111 - When DIFF=0, AD15 is selected as input; when DIFF=1, it is reserved.
* - 10000 - When DIFF=0, AD16 is selected as input; when DIFF=1, it is reserved.
* - 10001 - When DIFF=0, AD17 is selected as input; when DIFF=1, it is reserved.
* - 10010 - When DIFF=0, AD18 is selected as input; when DIFF=1, it is reserved.
* - 10011 - When DIFF=0, AD19 is selected as input; when DIFF=1, it is reserved.
* - 10100 - When DIFF=0, AD20 is selected as input; when DIFF=1, it is reserved.
* - 10101 - When DIFF=0, AD21 is selected as input; when DIFF=1, it is reserved.
* - 10110 - When DIFF=0, AD22 is selected as input; when DIFF=1, it is reserved.
* - 10111 - When DIFF=0, AD23 is selected as input; when DIFF=1, it is reserved.
* - 11000 - Reserved.
* - 11001 - Reserved.
* - 11010 - When DIFF=0, Temp Sensor (single-ended) is selected as input; when
* DIFF=1, Temp Sensor (differential) is selected as input.
* - 11011 - When DIFF=0, Bandgap (single-ended) is selected as input; when
* DIFF=1, Bandgap (differential) is selected as input.
* - 11100 - Reserved.
* - 11101 - When DIFF=0,VREFSH is selected as input; when DIFF=1, -VREFSH
* (differential) is selected as input. Voltage reference selected is determined
* by SC2[REFSEL].
* - 11110 - When DIFF=0,VREFSL is selected as input; when DIFF=1, it is
* reserved. Voltage reference selected is determined by SC2[REFSEL].
* - 11111 - Module is disabled.
*/
//@{
#define BP_ADC_SC1n_ADCH (0U) //!< Bit position for ADC_SC1n_ADCH.
#define BM_ADC_SC1n_ADCH (0x0000001FU) //!< Bit mask for ADC_SC1n_ADCH.
#define BS_ADC_SC1n_ADCH (5U) //!< Bit field size in bits for ADC_SC1n_ADCH.
#ifndef __LANGUAGE_ASM__
//! @brief Read current value of the ADC_SC1n_ADCH field.
#define BR_ADC_SC1n_ADCH(x, n) (HW_ADC_SC1n(x, n).B.ADCH)
#endif
//! @brief Format value for bitfield ADC_SC1n_ADCH.
#define BF_ADC_SC1n_ADCH(v) (__REG_VALUE_TYPE((__REG_VALUE_TYPE((v), uint32_t) << BP_ADC_SC1n_ADCH), uint32_t) & BM_ADC_SC1n_ADCH)
#ifndef __LANGUAGE_ASM__
//! @brief Set the ADCH field to a new value.
#define BW_ADC_SC1n_ADCH(x, n, v) (HW_ADC_SC1n_WR(x, n, (HW_ADC_SC1n_RD(x, n) & ~BM_ADC_SC1n_ADCH) | BF_ADC_SC1n_ADCH(v)))
#endif
//@}
/*!
* @name Register ADC_SC1n, field DIFF[5] (RW)
*
* Configures the ADC to operate in differential mode. When enabled, this mode
* automatically selects from the differential channels, and changes the
* conversion algorithm and the number of cycles to complete a conversion.
*
* Values:
* - 0 - Single-ended conversions and input channels are selected.
* - 1 - Differential conversions and input channels are selected.
*/
//@{
#define BP_ADC_SC1n_DIFF (5U) //!< Bit position for ADC_SC1n_DIFF.
#define BM_ADC_SC1n_DIFF (0x00000020U) //!< Bit mask for ADC_SC1n_DIFF.
#define BS_ADC_SC1n_DIFF (1U) //!< Bit field size in bits for ADC_SC1n_DIFF.
#ifndef __LANGUAGE_ASM__
//! @brief Read current value of the ADC_SC1n_DIFF field.
#define BR_ADC_SC1n_DIFF(x, n) (BITBAND_ACCESS32(HW_ADC_SC1n_ADDR(x, n), BP_ADC_SC1n_DIFF))
#endif
//! @brief Format value for bitfield ADC_SC1n_DIFF.
#define BF_ADC_SC1n_DIFF(v) (__REG_VALUE_TYPE((__REG_VALUE_TYPE((v), uint32_t) << BP_ADC_SC1n_DIFF), uint32_t) & BM_ADC_SC1n_DIFF)
#ifndef __LANGUAGE_ASM__
//! @brief Set the DIFF field to a new value.
#define BW_ADC_SC1n_DIFF(x, n, v) (BITBAND_ACCESS32(HW_ADC_SC1n_ADDR(x, n), BP_ADC_SC1n_DIFF) = (v))
#endif
//@}
/*!
* @name Register ADC_SC1n, field AIEN[6] (RW)
*
* Enables conversion complete interrupts. When COCO becomes set while the
* respective AIEN is high, an interrupt is asserted.
*
* Values:
* - 0 - Conversion complete interrupt is disabled.
* - 1 - Conversion complete interrupt is enabled.
*/
//@{
#define BP_ADC_SC1n_AIEN (6U) //!< Bit position for ADC_SC1n_AIEN.
#define BM_ADC_SC1n_AIEN (0x00000040U) //!< Bit mask for ADC_SC1n_AIEN.
#define BS_ADC_SC1n_AIEN (1U) //!< Bit field size in bits for ADC_SC1n_AIEN.
#ifndef __LANGUAGE_ASM__
//! @brief Read current value of the ADC_SC1n_AIEN field.
#define BR_ADC_SC1n_AIEN(x, n) (BITBAND_ACCESS32(HW_ADC_SC1n_ADDR(x, n), BP_ADC_SC1n_AIEN))
#endif
//! @brief Format value for bitfield ADC_SC1n_AIEN.
#define BF_ADC_SC1n_AIEN(v) (__REG_VALUE_TYPE((__REG_VALUE_TYPE((v), uint32_t) << BP_ADC_SC1n_AIEN), uint32_t) & BM_ADC_SC1n_AIEN)
#ifndef __LANGUAGE_ASM__
//! @brief Set the AIEN field to a new value.
#define BW_ADC_SC1n_AIEN(x, n, v) (BITBAND_ACCESS32(HW_ADC_SC1n_ADDR(x, n), BP_ADC_SC1n_AIEN) = (v))
#endif
//@}
/*!
* @name Register ADC_SC1n, field COCO[7] (RO)
*
* This is a read-only field that is set each time a conversion is completed
* when the compare function is disabled, or SC2[ACFE]=0 and the hardware average
* function is disabled, or SC3[AVGE]=0. When the compare function is enabled, or
* SC2[ACFE]=1, COCO is set upon completion of a conversion only if the compare
* result is true. When the hardware average function is enabled, or SC3[AVGE]=1,
* COCO is set upon completion of the selected number of conversions (determined
* by AVGS). COCO in SC1A is also set at the completion of a calibration sequence.
* COCO is cleared when the respective SC1n register is written or when the
* respective Rn register is read.
*
* Values:
* - 0 - Conversion is not completed.
* - 1 - Conversion is completed.
*/
//@{
#define BP_ADC_SC1n_COCO (7U) //!< Bit position for ADC_SC1n_COCO.
#define BM_ADC_SC1n_COCO (0x00000080U) //!< Bit mask for ADC_SC1n_COCO.
#define BS_ADC_SC1n_COCO (1U) //!< Bit field size in bits for ADC_SC1n_COCO.
#ifndef __LANGUAGE_ASM__
//! @brief Read current value of the ADC_SC1n_COCO field.
#define BR_ADC_SC1n_COCO(x, n) (BITBAND_ACCESS32(HW_ADC_SC1n_ADDR(x, n), BP_ADC_SC1n_COCO))
#endif
//@}
//-------------------------------------------------------------------------------------------
// HW_ADC_CFG1 - ADC Configuration Register 1
//-------------------------------------------------------------------------------------------
#ifndef __LANGUAGE_ASM__
/*!
* @brief HW_ADC_CFG1 - ADC Configuration Register 1 (RW)
*
* Reset value: 0x00000000U
*
* The configuration Register 1 (CFG1) selects the mode of operation, clock
* source, clock divide, and configuration for low power or long sample time.
*/
typedef union _hw_adc_cfg1
{
uint32_t U;
struct _hw_adc_cfg1_bitfields
{
uint32_t ADICLK : 2; //!< [1:0] Input Clock Select
uint32_t MODE : 2; //!< [3:2] Conversion mode selection
uint32_t ADLSMP : 1; //!< [4] Sample Time Configuration
uint32_t ADIV : 2; //!< [6:5] Clock Divide Select
uint32_t ADLPC : 1; //!< [7] Low-Power Configuration
uint32_t RESERVED0 : 24; //!< [31:8]
} B;
} hw_adc_cfg1_t;
#endif
/*!
* @name Constants and macros for entire ADC_CFG1 register
*/
//@{
#define HW_ADC_CFG1_ADDR(x) (REGS_ADC_BASE(x) + 0x8U)
#ifndef __LANGUAGE_ASM__
#define HW_ADC_CFG1(x) (*(__IO hw_adc_cfg1_t *) HW_ADC_CFG1_ADDR(x))
#define HW_ADC_CFG1_RD(x) (HW_ADC_CFG1(x).U)
#define HW_ADC_CFG1_WR(x, v) (HW_ADC_CFG1(x).U = (v))
#define HW_ADC_CFG1_SET(x, v) (HW_ADC_CFG1_WR(x, HW_ADC_CFG1_RD(x) | (v)))
#define HW_ADC_CFG1_CLR(x, v) (HW_ADC_CFG1_WR(x, HW_ADC_CFG1_RD(x) & ~(v)))
#define HW_ADC_CFG1_TOG(x, v) (HW_ADC_CFG1_WR(x, HW_ADC_CFG1_RD(x) ^ (v)))
#endif
//@}
/*
* Constants & macros for individual ADC_CFG1 bitfields
*/
/*!
* @name Register ADC_CFG1, field ADICLK[1:0] (RW)
*
* Selects the input clock source to generate the internal clock, ADCK. Note
* that when the ADACK clock source is selected, it is not required to be active
* prior to conversion start. When it is selected and it is not active prior to a
* conversion start, when CFG2[ADACKEN]=0, the asynchronous clock is activated at
* the start of a conversion and deactivated when conversions are terminated. In
* this case, there is an associated clock startup delay each time the clock
* source is re-activated.
*
* Values:
* - 00 - Bus clock
* - 01 - Alternate clock 2 (ALTCLK2)
* - 10 - Alternate clock (ALTCLK)
* - 11 - Asynchronous clock (ADACK)
*/
//@{
#define BP_ADC_CFG1_ADICLK (0U) //!< Bit position for ADC_CFG1_ADICLK.
#define BM_ADC_CFG1_ADICLK (0x00000003U) //!< Bit mask for ADC_CFG1_ADICLK.
#define BS_ADC_CFG1_ADICLK (2U) //!< Bit field size in bits for ADC_CFG1_ADICLK.
#ifndef __LANGUAGE_ASM__
//! @brief Read current value of the ADC_CFG1_ADICLK field.
#define BR_ADC_CFG1_ADICLK(x) (HW_ADC_CFG1(x).B.ADICLK)
#endif
//! @brief Format value for bitfield ADC_CFG1_ADICLK.
#define BF_ADC_CFG1_ADICLK(v) (__REG_VALUE_TYPE((__REG_VALUE_TYPE((v), uint32_t) << BP_ADC_CFG1_ADICLK), uint32_t) & BM_ADC_CFG1_ADICLK)
#ifndef __LANGUAGE_ASM__
//! @brief Set the ADICLK field to a new value.
#define BW_ADC_CFG1_ADICLK(x, v) (HW_ADC_CFG1_WR(x, (HW_ADC_CFG1_RD(x) & ~BM_ADC_CFG1_ADICLK) | BF_ADC_CFG1_ADICLK(v)))
#endif
//@}
/*!
* @name Register ADC_CFG1, field MODE[3:2] (RW)
*
* Selects the ADC resolution mode.
*
* Values:
* - 00 - When DIFF=0:It is single-ended 8-bit conversion; when DIFF=1, it is
* differential 9-bit conversion with 2's complement output.
* - 01 - When DIFF=0:It is single-ended 12-bit conversion ; when DIFF=1, it is
* differential 13-bit conversion with 2's complement output.
* - 10 - When DIFF=0:It is single-ended 10-bit conversion. ; when DIFF=1, it is
* differential 11-bit conversion with 2's complement output
* - 11 - When DIFF=0:It is single-ended 16-bit conversion..; when DIFF=1, it is
* differential 16-bit conversion with 2's complement output
*/
//@{
#define BP_ADC_CFG1_MODE (2U) //!< Bit position for ADC_CFG1_MODE.
#define BM_ADC_CFG1_MODE (0x0000000CU) //!< Bit mask for ADC_CFG1_MODE.
#define BS_ADC_CFG1_MODE (2U) //!< Bit field size in bits for ADC_CFG1_MODE.
#ifndef __LANGUAGE_ASM__
//! @brief Read current value of the ADC_CFG1_MODE field.
#define BR_ADC_CFG1_MODE(x) (HW_ADC_CFG1(x).B.MODE)
#endif
//! @brief Format value for bitfield ADC_CFG1_MODE.
#define BF_ADC_CFG1_MODE(v) (__REG_VALUE_TYPE((__REG_VALUE_TYPE((v), uint32_t) << BP_ADC_CFG1_MODE), uint32_t) & BM_ADC_CFG1_MODE)
#ifndef __LANGUAGE_ASM__
//! @brief Set the MODE field to a new value.
#define BW_ADC_CFG1_MODE(x, v) (HW_ADC_CFG1_WR(x, (HW_ADC_CFG1_RD(x) & ~BM_ADC_CFG1_MODE) | BF_ADC_CFG1_MODE(v)))
#endif
//@}
/*!
* @name Register ADC_CFG1, field ADLSMP[4] (RW)
*
* Selects between different sample times based on the conversion mode selected.
* This field adjusts the sample period to allow higher impedance inputs to be
* accurately sampled or to maximize conversion speed for lower impedance inputs.
* Longer sample times can also be used to lower overall power consumption if
* continuous conversions are enabled and high conversion rates are not required.
* When ADLSMP=1, the long sample time select bits, (ADLSTS[1:0]), can select the
* extent of the long sample time.
*
* Values:
* - 0 - Short sample time.
* - 1 - Long sample time.
*/
//@{
#define BP_ADC_CFG1_ADLSMP (4U) //!< Bit position for ADC_CFG1_ADLSMP.
#define BM_ADC_CFG1_ADLSMP (0x00000010U) //!< Bit mask for ADC_CFG1_ADLSMP.
#define BS_ADC_CFG1_ADLSMP (1U) //!< Bit field size in bits for ADC_CFG1_ADLSMP.
#ifndef __LANGUAGE_ASM__
//! @brief Read current value of the ADC_CFG1_ADLSMP field.
#define BR_ADC_CFG1_ADLSMP(x) (BITBAND_ACCESS32(HW_ADC_CFG1_ADDR(x), BP_ADC_CFG1_ADLSMP))
#endif
//! @brief Format value for bitfield ADC_CFG1_ADLSMP.
#define BF_ADC_CFG1_ADLSMP(v) (__REG_VALUE_TYPE((__REG_VALUE_TYPE((v), uint32_t) << BP_ADC_CFG1_ADLSMP), uint32_t) & BM_ADC_CFG1_ADLSMP)
#ifndef __LANGUAGE_ASM__
//! @brief Set the ADLSMP field to a new value.
#define BW_ADC_CFG1_ADLSMP(x, v) (BITBAND_ACCESS32(HW_ADC_CFG1_ADDR(x), BP_ADC_CFG1_ADLSMP) = (v))
#endif
//@}
/*!
* @name Register ADC_CFG1, field ADIV[6:5] (RW)
*
* Selects the divide ratio used by the ADC to generate the internal clock ADCK.
*
* Values:
* - 00 - The divide ratio is 1 and the clock rate is input clock.
* - 01 - The divide ratio is 2 and the clock rate is (input clock)/2.
* - 10 - The divide ratio is 4 and the clock rate is (input clock)/4.
* - 11 - The divide ratio is 8 and the clock rate is (input clock)/8.
*/
//@{
#define BP_ADC_CFG1_ADIV (5U) //!< Bit position for ADC_CFG1_ADIV.
#define BM_ADC_CFG1_ADIV (0x00000060U) //!< Bit mask for ADC_CFG1_ADIV.
#define BS_ADC_CFG1_ADIV (2U) //!< Bit field size in bits for ADC_CFG1_ADIV.
#ifndef __LANGUAGE_ASM__
//! @brief Read current value of the ADC_CFG1_ADIV field.
#define BR_ADC_CFG1_ADIV(x) (HW_ADC_CFG1(x).B.ADIV)
#endif
//! @brief Format value for bitfield ADC_CFG1_ADIV.
#define BF_ADC_CFG1_ADIV(v) (__REG_VALUE_TYPE((__REG_VALUE_TYPE((v), uint32_t) << BP_ADC_CFG1_ADIV), uint32_t) & BM_ADC_CFG1_ADIV)
#ifndef __LANGUAGE_ASM__
//! @brief Set the ADIV field to a new value.
#define BW_ADC_CFG1_ADIV(x, v) (HW_ADC_CFG1_WR(x, (HW_ADC_CFG1_RD(x) & ~BM_ADC_CFG1_ADIV) | BF_ADC_CFG1_ADIV(v)))
#endif
//@}
/*!
* @name Register ADC_CFG1, field ADLPC[7] (RW)
*
* Controls the power configuration of the successive approximation converter.
* This optimizes power consumption when higher sample rates are not required.
*
* Values:
* - 0 - Normal power configuration.
* - 1 - Low-power configuration. The power is reduced at the expense of maximum
* clock speed.
*/
//@{
#define BP_ADC_CFG1_ADLPC (7U) //!< Bit position for ADC_CFG1_ADLPC.
#define BM_ADC_CFG1_ADLPC (0x00000080U) //!< Bit mask for ADC_CFG1_ADLPC.
#define BS_ADC_CFG1_ADLPC (1U) //!< Bit field size in bits for ADC_CFG1_ADLPC.
#ifndef __LANGUAGE_ASM__
//! @brief Read current value of the ADC_CFG1_ADLPC field.
#define BR_ADC_CFG1_ADLPC(x) (BITBAND_ACCESS32(HW_ADC_CFG1_ADDR(x), BP_ADC_CFG1_ADLPC))
#endif
//! @brief Format value for bitfield ADC_CFG1_ADLPC.
#define BF_ADC_CFG1_ADLPC(v) (__REG_VALUE_TYPE((__REG_VALUE_TYPE((v), uint32_t) << BP_ADC_CFG1_ADLPC), uint32_t) & BM_ADC_CFG1_ADLPC)
#ifndef __LANGUAGE_ASM__
//! @brief Set the ADLPC field to a new value.
#define BW_ADC_CFG1_ADLPC(x, v) (BITBAND_ACCESS32(HW_ADC_CFG1_ADDR(x), BP_ADC_CFG1_ADLPC) = (v))
#endif
//@}
//-------------------------------------------------------------------------------------------
// HW_ADC_CFG2 - ADC Configuration Register 2
//-------------------------------------------------------------------------------------------
#ifndef __LANGUAGE_ASM__
/*!
* @brief HW_ADC_CFG2 - ADC Configuration Register 2 (RW)
*
* Reset value: 0x00000000U
*
* Configuration Register 2 (CFG2) selects the special high-speed configuration
* for very high speed conversions and selects the long sample time duration
* during long sample mode.
*/
typedef union _hw_adc_cfg2
{
uint32_t U;
struct _hw_adc_cfg2_bitfields
{
uint32_t ADLSTS : 2; //!< [1:0] Long Sample Time Select
uint32_t ADHSC : 1; //!< [2] High-Speed Configuration
uint32_t ADACKEN : 1; //!< [3] Asynchronous Clock Output Enable
uint32_t MUXSEL : 1; //!< [4] ADC Mux Select
uint32_t RESERVED0 : 27; //!< [31:5]
} B;
} hw_adc_cfg2_t;
#endif
/*!
* @name Constants and macros for entire ADC_CFG2 register
*/
//@{
#define HW_ADC_CFG2_ADDR(x) (REGS_ADC_BASE(x) + 0xCU)
#ifndef __LANGUAGE_ASM__
#define HW_ADC_CFG2(x) (*(__IO hw_adc_cfg2_t *) HW_ADC_CFG2_ADDR(x))
#define HW_ADC_CFG2_RD(x) (HW_ADC_CFG2(x).U)
#define HW_ADC_CFG2_WR(x, v) (HW_ADC_CFG2(x).U = (v))
#define HW_ADC_CFG2_SET(x, v) (HW_ADC_CFG2_WR(x, HW_ADC_CFG2_RD(x) | (v)))
#define HW_ADC_CFG2_CLR(x, v) (HW_ADC_CFG2_WR(x, HW_ADC_CFG2_RD(x) & ~(v)))
#define HW_ADC_CFG2_TOG(x, v) (HW_ADC_CFG2_WR(x, HW_ADC_CFG2_RD(x) ^ (v)))
#endif
//@}
/*
* Constants & macros for individual ADC_CFG2 bitfields
*/
/*!
* @name Register ADC_CFG2, field ADLSTS[1:0] (RW)
*
* Selects between the extended sample times when long sample time is selected,
* that is, when CFG1[ADLSMP]=1. This allows higher impedance inputs to be
* accurately sampled or to maximize conversion speed for lower impedance inputs.
* Longer sample times can also be used to lower overall power consumption when
* continuous conversions are enabled if high conversion rates are not required.
*
* Values:
* - 00 - Default longest sample time; 20 extra ADCK cycles; 24 ADCK cycles
* total.
* - 01 - 12 extra ADCK cycles; 16 ADCK cycles total sample time.
* - 10 - 6 extra ADCK cycles; 10 ADCK cycles total sample time.
* - 11 - 2 extra ADCK cycles; 6 ADCK cycles total sample time.
*/
//@{
#define BP_ADC_CFG2_ADLSTS (0U) //!< Bit position for ADC_CFG2_ADLSTS.
#define BM_ADC_CFG2_ADLSTS (0x00000003U) //!< Bit mask for ADC_CFG2_ADLSTS.
#define BS_ADC_CFG2_ADLSTS (2U) //!< Bit field size in bits for ADC_CFG2_ADLSTS.
#ifndef __LANGUAGE_ASM__
//! @brief Read current value of the ADC_CFG2_ADLSTS field.
#define BR_ADC_CFG2_ADLSTS(x) (HW_ADC_CFG2(x).B.ADLSTS)
#endif
//! @brief Format value for bitfield ADC_CFG2_ADLSTS.
#define BF_ADC_CFG2_ADLSTS(v) (__REG_VALUE_TYPE((__REG_VALUE_TYPE((v), uint32_t) << BP_ADC_CFG2_ADLSTS), uint32_t) & BM_ADC_CFG2_ADLSTS)
#ifndef __LANGUAGE_ASM__
//! @brief Set the ADLSTS field to a new value.
#define BW_ADC_CFG2_ADLSTS(x, v) (HW_ADC_CFG2_WR(x, (HW_ADC_CFG2_RD(x) & ~BM_ADC_CFG2_ADLSTS) | BF_ADC_CFG2_ADLSTS(v)))
#endif
//@}
/*!
* @name Register ADC_CFG2, field ADHSC[2] (RW)
*
* Configures the ADC for very high-speed operation. The conversion sequence is
* altered with 2 ADCK cycles added to the conversion time to allow higher speed
* conversion clocks.
*
* Values:
* - 0 - Normal conversion sequence selected.
* - 1 - High-speed conversion sequence selected with 2 additional ADCK cycles
* to total conversion time.
*/
//@{
#define BP_ADC_CFG2_ADHSC (2U) //!< Bit position for ADC_CFG2_ADHSC.
#define BM_ADC_CFG2_ADHSC (0x00000004U) //!< Bit mask for ADC_CFG2_ADHSC.
#define BS_ADC_CFG2_ADHSC (1U) //!< Bit field size in bits for ADC_CFG2_ADHSC.
#ifndef __LANGUAGE_ASM__
//! @brief Read current value of the ADC_CFG2_ADHSC field.
#define BR_ADC_CFG2_ADHSC(x) (BITBAND_ACCESS32(HW_ADC_CFG2_ADDR(x), BP_ADC_CFG2_ADHSC))
#endif
//! @brief Format value for bitfield ADC_CFG2_ADHSC.
#define BF_ADC_CFG2_ADHSC(v) (__REG_VALUE_TYPE((__REG_VALUE_TYPE((v), uint32_t) << BP_ADC_CFG2_ADHSC), uint32_t) & BM_ADC_CFG2_ADHSC)
#ifndef __LANGUAGE_ASM__
//! @brief Set the ADHSC field to a new value.
#define BW_ADC_CFG2_ADHSC(x, v) (BITBAND_ACCESS32(HW_ADC_CFG2_ADDR(x), BP_ADC_CFG2_ADHSC) = (v))
#endif
//@}
/*!
* @name Register ADC_CFG2, field ADACKEN[3] (RW)
*
* Enables the asynchronous clock source and the clock source output regardless
* of the conversion and status of CFG1[ADICLK]. Based on MCU configuration, the
* asynchronous clock may be used by other modules. See chip configuration
* information. Setting this field allows the clock to be used even while the ADC is
* idle or operating from a different clock source. Also, latency of initiating a
* single or first-continuous conversion with the asynchronous clock selected is
* reduced because the ADACK clock is already operational.
*
* Values:
* - 0 - Asynchronous clock output disabled; Asynchronous clock is enabled only
* if selected by ADICLK and a conversion is active.
* - 1 - Asynchronous clock and clock output is enabled regardless of the state
* of the ADC.
*/
//@{
#define BP_ADC_CFG2_ADACKEN (3U) //!< Bit position for ADC_CFG2_ADACKEN.
#define BM_ADC_CFG2_ADACKEN (0x00000008U) //!< Bit mask for ADC_CFG2_ADACKEN.
#define BS_ADC_CFG2_ADACKEN (1U) //!< Bit field size in bits for ADC_CFG2_ADACKEN.
#ifndef __LANGUAGE_ASM__
//! @brief Read current value of the ADC_CFG2_ADACKEN field.
#define BR_ADC_CFG2_ADACKEN(x) (BITBAND_ACCESS32(HW_ADC_CFG2_ADDR(x), BP_ADC_CFG2_ADACKEN))
#endif
//! @brief Format value for bitfield ADC_CFG2_ADACKEN.
#define BF_ADC_CFG2_ADACKEN(v) (__REG_VALUE_TYPE((__REG_VALUE_TYPE((v), uint32_t) << BP_ADC_CFG2_ADACKEN), uint32_t) & BM_ADC_CFG2_ADACKEN)
#ifndef __LANGUAGE_ASM__
//! @brief Set the ADACKEN field to a new value.
#define BW_ADC_CFG2_ADACKEN(x, v) (BITBAND_ACCESS32(HW_ADC_CFG2_ADDR(x), BP_ADC_CFG2_ADACKEN) = (v))
#endif
//@}
/*!
* @name Register ADC_CFG2, field MUXSEL[4] (RW)
*
* Changes the ADC mux setting to select between alternate sets of ADC channels.
*
* Values:
* - 0 - ADxxa channels are selected.
* - 1 - ADxxb channels are selected.
*/
//@{
#define BP_ADC_CFG2_MUXSEL (4U) //!< Bit position for ADC_CFG2_MUXSEL.
#define BM_ADC_CFG2_MUXSEL (0x00000010U) //!< Bit mask for ADC_CFG2_MUXSEL.
#define BS_ADC_CFG2_MUXSEL (1U) //!< Bit field size in bits for ADC_CFG2_MUXSEL.
#ifndef __LANGUAGE_ASM__
//! @brief Read current value of the ADC_CFG2_MUXSEL field.
#define BR_ADC_CFG2_MUXSEL(x) (BITBAND_ACCESS32(HW_ADC_CFG2_ADDR(x), BP_ADC_CFG2_MUXSEL))
#endif
//! @brief Format value for bitfield ADC_CFG2_MUXSEL.
#define BF_ADC_CFG2_MUXSEL(v) (__REG_VALUE_TYPE((__REG_VALUE_TYPE((v), uint32_t) << BP_ADC_CFG2_MUXSEL), uint32_t) & BM_ADC_CFG2_MUXSEL)
#ifndef __LANGUAGE_ASM__
//! @brief Set the MUXSEL field to a new value.
#define BW_ADC_CFG2_MUXSEL(x, v) (BITBAND_ACCESS32(HW_ADC_CFG2_ADDR(x), BP_ADC_CFG2_MUXSEL) = (v))
#endif
//@}
//-------------------------------------------------------------------------------------------
// HW_ADC_Rn - ADC Data Result Register
//-------------------------------------------------------------------------------------------
#ifndef __LANGUAGE_ASM__
/*!
* @brief HW_ADC_Rn - ADC Data Result Register (RO)
*
* Reset value: 0x00000000U
*
* The data result registers (Rn) contain the result of an ADC conversion of the
* channel selected by the corresponding status and channel control register
* (SC1A:SC1n). For every status and channel control register, there is a
* corresponding data result register. Unused bits in R n are cleared in unsigned
* right-aligned modes and carry the sign bit (MSB) in sign-extended 2's complement modes.
* For example, when configured for 10-bit single-ended mode, D[15:10] are
* cleared. When configured for 11-bit differential mode, D[15:10] carry the sign bit,
* that is, bit 10 extended through bit 15. The following table describes the
* behavior of the data result registers in the different modes of operation. Data
* result register description Conversion mode D15 D14 D13 D12 D11 D10 D9 D8 D7
* D6 D5 D4 D3 D2 D1 D0 Format 16-bit differential S D D D D D D D D D D D D D D D
* Signed 2's complement 16-bit single-ended D D D D D D D D D D D D D D D D
* Unsigned right justified 13-bit differential S S S S D D D D D D D D D D D D
* Sign-extended 2's complement 12-bit single-ended 0 0 0 0 D D D D D D D D D D D D
* Unsigned right-justified 11-bit differential S S S S S S D D D D D D D D D D
* Sign-extended 2's complement 10-bit single-ended 0 0 0 0 0 0 D D D D D D D D D D
* Unsigned right-justified 9-bit differential S S S S S S S S D D D D D D D D
* Sign-extended 2's complement 8-bit single-ended 0 0 0 0 0 0 0 0 D D D D D D D D
* Unsigned right-justified S: Sign bit or sign bit extension; D: Data, which is
* 2's complement data if indicated
*/
typedef union _hw_adc_rn
{
uint32_t U;
struct _hw_adc_rn_bitfields
{
uint32_t D : 16; //!< [15:0] Data result
uint32_t RESERVED0 : 16; //!< [31:16]
} B;
} hw_adc_rn_t;
#endif
/*!
* @name Constants and macros for entire ADC_Rn register
*/
//@{
#define HW_ADC_Rn_COUNT (2U)
#define HW_ADC_Rn_ADDR(x, n) (REGS_ADC_BASE(x) + 0x10U + (0x4U * n))
#ifndef __LANGUAGE_ASM__
#define HW_ADC_Rn(x, n) (*(__I hw_adc_rn_t *) HW_ADC_Rn_ADDR(x, n))
#define HW_ADC_Rn_RD(x, n) (HW_ADC_Rn(x, n).U)
#endif
//@}
/*
* Constants & macros for individual ADC_Rn bitfields
*/
/*!
* @name Register ADC_Rn, field D[15:0] (RO)
*/
//@{
#define BP_ADC_Rn_D (0U) //!< Bit position for ADC_Rn_D.
#define BM_ADC_Rn_D (0x0000FFFFU) //!< Bit mask for ADC_Rn_D.
#define BS_ADC_Rn_D (16U) //!< Bit field size in bits for ADC_Rn_D.
#ifndef __LANGUAGE_ASM__
//! @brief Read current value of the ADC_Rn_D field.
#define BR_ADC_Rn_D(x, n) (HW_ADC_Rn(x, n).B.D)
#endif
//@}
//-------------------------------------------------------------------------------------------
// HW_ADC_CV1 - Compare Value Registers
//-------------------------------------------------------------------------------------------
#ifndef __LANGUAGE_ASM__
/*!
* @brief HW_ADC_CV1 - Compare Value Registers (RW)
*
* Reset value: 0x00000000U
*
* The Compare Value Registers (CV1 and CV2) contain a compare value used to
* compare the conversion result when the compare function is enabled, that is,
* SC2[ACFE]=1. This register is formatted in the same way as the Rn registers in
* different modes of operation for both bit position definition and value format
* using unsigned or sign-extended 2's complement. Therefore, the compare function
* uses only the CVn fields that are related to the ADC mode of operation. The
* compare value 2 register (CV2) is used only when the compare range function is
* enabled, that is, SC2[ACREN]=1.
*/
typedef union _hw_adc_cv1
{
uint32_t U;
struct _hw_adc_cv1_bitfields
{
uint32_t CV : 16; //!< [15:0] Compare Value.
uint32_t RESERVED0 : 16; //!< [31:16]
} B;
} hw_adc_cv1_t;
#endif
/*!
* @name Constants and macros for entire ADC_CV1 register
*/
//@{
#define HW_ADC_CV1_ADDR(x) (REGS_ADC_BASE(x) + 0x18U)
#ifndef __LANGUAGE_ASM__
#define HW_ADC_CV1(x) (*(__IO hw_adc_cv1_t *) HW_ADC_CV1_ADDR(x))
#define HW_ADC_CV1_RD(x) (HW_ADC_CV1(x).U)
#define HW_ADC_CV1_WR(x, v) (HW_ADC_CV1(x).U = (v))
#define HW_ADC_CV1_SET(x, v) (HW_ADC_CV1_WR(x, HW_ADC_CV1_RD(x) | (v)))
#define HW_ADC_CV1_CLR(x, v) (HW_ADC_CV1_WR(x, HW_ADC_CV1_RD(x) & ~(v)))
#define HW_ADC_CV1_TOG(x, v) (HW_ADC_CV1_WR(x, HW_ADC_CV1_RD(x) ^ (v)))
#endif
//@}
/*
* Constants & macros for individual ADC_CV1 bitfields
*/
/*!
* @name Register ADC_CV1, field CV[15:0] (RW)
*/
//@{
#define BP_ADC_CV1_CV (0U) //!< Bit position for ADC_CV1_CV.
#define BM_ADC_CV1_CV (0x0000FFFFU) //!< Bit mask for ADC_CV1_CV.
#define BS_ADC_CV1_CV (16U) //!< Bit field size in bits for ADC_CV1_CV.
#ifndef __LANGUAGE_ASM__
//! @brief Read current value of the ADC_CV1_CV field.
#define BR_ADC_CV1_CV(x) (HW_ADC_CV1(x).B.CV)
#endif
//! @brief Format value for bitfield ADC_CV1_CV.
#define BF_ADC_CV1_CV(v) (__REG_VALUE_TYPE((__REG_VALUE_TYPE((v), uint32_t) << BP_ADC_CV1_CV), uint32_t) & BM_ADC_CV1_CV)
#ifndef __LANGUAGE_ASM__
//! @brief Set the CV field to a new value.
#define BW_ADC_CV1_CV(x, v) (HW_ADC_CV1_WR(x, (HW_ADC_CV1_RD(x) & ~BM_ADC_CV1_CV) | BF_ADC_CV1_CV(v)))
#endif
//@}
//-------------------------------------------------------------------------------------------
// HW_ADC_CV2 - Compare Value Registers
//-------------------------------------------------------------------------------------------
#ifndef __LANGUAGE_ASM__
/*!
* @brief HW_ADC_CV2 - Compare Value Registers (RW)
*
* Reset value: 0x00000000U
*
* The Compare Value Registers (CV1 and CV2) contain a compare value used to
* compare the conversion result when the compare function is enabled, that is,
* SC2[ACFE]=1. This register is formatted in the same way as the Rn registers in
* different modes of operation for both bit position definition and value format
* using unsigned or sign-extended 2's complement. Therefore, the compare function
* uses only the CVn fields that are related to the ADC mode of operation. The
* compare value 2 register (CV2) is used only when the compare range function is
* enabled, that is, SC2[ACREN]=1.
*/
typedef union _hw_adc_cv2
{
uint32_t U;
struct _hw_adc_cv2_bitfields
{
uint32_t CV : 16; //!< [15:0] Compare Value.
uint32_t RESERVED0 : 16; //!< [31:16]
} B;
} hw_adc_cv2_t;
#endif
/*!
* @name Constants and macros for entire ADC_CV2 register
*/
//@{
#define HW_ADC_CV2_ADDR(x) (REGS_ADC_BASE(x) + 0x1CU)
#ifndef __LANGUAGE_ASM__
#define HW_ADC_CV2(x) (*(__IO hw_adc_cv2_t *) HW_ADC_CV2_ADDR(x))
#define HW_ADC_CV2_RD(x) (HW_ADC_CV2(x).U)
#define HW_ADC_CV2_WR(x, v) (HW_ADC_CV2(x).U = (v))
#define HW_ADC_CV2_SET(x, v) (HW_ADC_CV2_WR(x, HW_ADC_CV2_RD(x) | (v)))
#define HW_ADC_CV2_CLR(x, v) (HW_ADC_CV2_WR(x, HW_ADC_CV2_RD(x) & ~(v)))
#define HW_ADC_CV2_TOG(x, v) (HW_ADC_CV2_WR(x, HW_ADC_CV2_RD(x) ^ (v)))
#endif
//@}
/*
* Constants & macros for individual ADC_CV2 bitfields
*/
/*!
* @name Register ADC_CV2, field CV[15:0] (RW)
*/
//@{
#define BP_ADC_CV2_CV (0U) //!< Bit position for ADC_CV2_CV.
#define BM_ADC_CV2_CV (0x0000FFFFU) //!< Bit mask for ADC_CV2_CV.
#define BS_ADC_CV2_CV (16U) //!< Bit field size in bits for ADC_CV2_CV.
#ifndef __LANGUAGE_ASM__
//! @brief Read current value of the ADC_CV2_CV field.
#define BR_ADC_CV2_CV(x) (HW_ADC_CV2(x).B.CV)
#endif
//! @brief Format value for bitfield ADC_CV2_CV.
#define BF_ADC_CV2_CV(v) (__REG_VALUE_TYPE((__REG_VALUE_TYPE((v), uint32_t) << BP_ADC_CV2_CV), uint32_t) & BM_ADC_CV2_CV)
#ifndef __LANGUAGE_ASM__
//! @brief Set the CV field to a new value.
#define BW_ADC_CV2_CV(x, v) (HW_ADC_CV2_WR(x, (HW_ADC_CV2_RD(x) & ~BM_ADC_CV2_CV) | BF_ADC_CV2_CV(v)))
#endif
//@}
//-------------------------------------------------------------------------------------------
// HW_ADC_SC2 - Status and Control Register 2
//-------------------------------------------------------------------------------------------
#ifndef __LANGUAGE_ASM__
/*!
* @brief HW_ADC_SC2 - Status and Control Register 2 (RW)
*
* Reset value: 0x00000000U
*
* The status and control register 2 (SC2) contains the conversion active,
* hardware/software trigger select, compare function, and voltage reference select of
* the ADC module.
*/
typedef union _hw_adc_sc2
{
uint32_t U;
struct _hw_adc_sc2_bitfields
{
uint32_t REFSEL : 2; //!< [1:0] Voltage Reference Selection
uint32_t DMAEN : 1; //!< [2] DMA Enable
uint32_t ACREN : 1; //!< [3] Compare Function Range Enable
uint32_t ACFGT : 1; //!< [4] Compare Function Greater Than Enable
uint32_t ACFE : 1; //!< [5] Compare Function Enable
uint32_t ADTRG : 1; //!< [6] Conversion Trigger Select
uint32_t ADACT : 1; //!< [7] Conversion Active
uint32_t RESERVED0 : 24; //!< [31:8]
} B;
} hw_adc_sc2_t;
#endif
/*!
* @name Constants and macros for entire ADC_SC2 register
*/
//@{
#define HW_ADC_SC2_ADDR(x) (REGS_ADC_BASE(x) + 0x20U)
#ifndef __LANGUAGE_ASM__
#define HW_ADC_SC2(x) (*(__IO hw_adc_sc2_t *) HW_ADC_SC2_ADDR(x))
#define HW_ADC_SC2_RD(x) (HW_ADC_SC2(x).U)
#define HW_ADC_SC2_WR(x, v) (HW_ADC_SC2(x).U = (v))
#define HW_ADC_SC2_SET(x, v) (HW_ADC_SC2_WR(x, HW_ADC_SC2_RD(x) | (v)))
#define HW_ADC_SC2_CLR(x, v) (HW_ADC_SC2_WR(x, HW_ADC_SC2_RD(x) & ~(v)))
#define HW_ADC_SC2_TOG(x, v) (HW_ADC_SC2_WR(x, HW_ADC_SC2_RD(x) ^ (v)))
#endif
//@}
/*
* Constants & macros for individual ADC_SC2 bitfields
*/
/*!
* @name Register ADC_SC2, field REFSEL[1:0] (RW)
*
* Selects the voltage reference source used for conversions.
*
* Values:
* - 00 - Default voltage reference pin pair, that is, external pins VREFH and
* VREFL
* - 01 - Alternate reference pair, that is, VALTH and VALTL . This pair may be
* additional external pins or internal sources depending on the MCU
* configuration. See the chip configuration information for details specific to this
* MCU
* - 10 - Reserved
* - 11 - Reserved
*/
//@{
#define BP_ADC_SC2_REFSEL (0U) //!< Bit position for ADC_SC2_REFSEL.
#define BM_ADC_SC2_REFSEL (0x00000003U) //!< Bit mask for ADC_SC2_REFSEL.
#define BS_ADC_SC2_REFSEL (2U) //!< Bit field size in bits for ADC_SC2_REFSEL.
#ifndef __LANGUAGE_ASM__
//! @brief Read current value of the ADC_SC2_REFSEL field.
#define BR_ADC_SC2_REFSEL(x) (HW_ADC_SC2(x).B.REFSEL)
#endif
//! @brief Format value for bitfield ADC_SC2_REFSEL.
#define BF_ADC_SC2_REFSEL(v) (__REG_VALUE_TYPE((__REG_VALUE_TYPE((v), uint32_t) << BP_ADC_SC2_REFSEL), uint32_t) & BM_ADC_SC2_REFSEL)
#ifndef __LANGUAGE_ASM__
//! @brief Set the REFSEL field to a new value.
#define BW_ADC_SC2_REFSEL(x, v) (HW_ADC_SC2_WR(x, (HW_ADC_SC2_RD(x) & ~BM_ADC_SC2_REFSEL) | BF_ADC_SC2_REFSEL(v)))
#endif
//@}
/*!
* @name Register ADC_SC2, field DMAEN[2] (RW)
*
* Values:
* - 0 - DMA is disabled.
* - 1 - DMA is enabled and will assert the ADC DMA request during an ADC
* conversion complete event noted when any of the SC1n[COCO] flags is asserted.
*/
//@{
#define BP_ADC_SC2_DMAEN (2U) //!< Bit position for ADC_SC2_DMAEN.
#define BM_ADC_SC2_DMAEN (0x00000004U) //!< Bit mask for ADC_SC2_DMAEN.
#define BS_ADC_SC2_DMAEN (1U) //!< Bit field size in bits for ADC_SC2_DMAEN.
#ifndef __LANGUAGE_ASM__
//! @brief Read current value of the ADC_SC2_DMAEN field.
#define BR_ADC_SC2_DMAEN(x) (BITBAND_ACCESS32(HW_ADC_SC2_ADDR(x), BP_ADC_SC2_DMAEN))
#endif
//! @brief Format value for bitfield ADC_SC2_DMAEN.
#define BF_ADC_SC2_DMAEN(v) (__REG_VALUE_TYPE((__REG_VALUE_TYPE((v), uint32_t) << BP_ADC_SC2_DMAEN), uint32_t) & BM_ADC_SC2_DMAEN)
#ifndef __LANGUAGE_ASM__
//! @brief Set the DMAEN field to a new value.
#define BW_ADC_SC2_DMAEN(x, v) (BITBAND_ACCESS32(HW_ADC_SC2_ADDR(x), BP_ADC_SC2_DMAEN) = (v))
#endif
//@}
/*!
* @name Register ADC_SC2, field ACREN[3] (RW)
*
* Configures the compare function to check if the conversion result of the
* input being monitored is either between or outside the range formed by CV1 and CV2
* determined by the value of ACFGT. ACFE must be set for ACFGT to have any
* effect.
*
* Values:
* - 0 - Range function disabled. Only CV1 is compared.
* - 1 - Range function enabled. Both CV1 and CV2 are compared.
*/
//@{
#define BP_ADC_SC2_ACREN (3U) //!< Bit position for ADC_SC2_ACREN.
#define BM_ADC_SC2_ACREN (0x00000008U) //!< Bit mask for ADC_SC2_ACREN.
#define BS_ADC_SC2_ACREN (1U) //!< Bit field size in bits for ADC_SC2_ACREN.
#ifndef __LANGUAGE_ASM__
//! @brief Read current value of the ADC_SC2_ACREN field.
#define BR_ADC_SC2_ACREN(x) (BITBAND_ACCESS32(HW_ADC_SC2_ADDR(x), BP_ADC_SC2_ACREN))
#endif
//! @brief Format value for bitfield ADC_SC2_ACREN.
#define BF_ADC_SC2_ACREN(v) (__REG_VALUE_TYPE((__REG_VALUE_TYPE((v), uint32_t) << BP_ADC_SC2_ACREN), uint32_t) & BM_ADC_SC2_ACREN)
#ifndef __LANGUAGE_ASM__
//! @brief Set the ACREN field to a new value.
#define BW_ADC_SC2_ACREN(x, v) (BITBAND_ACCESS32(HW_ADC_SC2_ADDR(x), BP_ADC_SC2_ACREN) = (v))
#endif
//@}
/*!
* @name Register ADC_SC2, field ACFGT[4] (RW)
*
* Configures the compare function to check the conversion result relative to
* the CV1 and CV2 based upon the value of ACREN. ACFE must be set for ACFGT to
* have any effect.
*
* Values:
* - 0 - Configures less than threshold, outside range not inclusive and inside
* range not inclusive; functionality based on the values placed in CV1 and
* CV2.
* - 1 - Configures greater than or equal to threshold, outside and inside
* ranges inclusive; functionality based on the values placed in CV1 and CV2.
*/
//@{
#define BP_ADC_SC2_ACFGT (4U) //!< Bit position for ADC_SC2_ACFGT.
#define BM_ADC_SC2_ACFGT (0x00000010U) //!< Bit mask for ADC_SC2_ACFGT.
#define BS_ADC_SC2_ACFGT (1U) //!< Bit field size in bits for ADC_SC2_ACFGT.
#ifndef __LANGUAGE_ASM__
//! @brief Read current value of the ADC_SC2_ACFGT field.
#define BR_ADC_SC2_ACFGT(x) (BITBAND_ACCESS32(HW_ADC_SC2_ADDR(x), BP_ADC_SC2_ACFGT))
#endif
//! @brief Format value for bitfield ADC_SC2_ACFGT.
#define BF_ADC_SC2_ACFGT(v) (__REG_VALUE_TYPE((__REG_VALUE_TYPE((v), uint32_t) << BP_ADC_SC2_ACFGT), uint32_t) & BM_ADC_SC2_ACFGT)
#ifndef __LANGUAGE_ASM__
//! @brief Set the ACFGT field to a new value.
#define BW_ADC_SC2_ACFGT(x, v) (BITBAND_ACCESS32(HW_ADC_SC2_ADDR(x), BP_ADC_SC2_ACFGT) = (v))
#endif
//@}
/*!
* @name Register ADC_SC2, field ACFE[5] (RW)
*
* Enables the compare function.
*
* Values:
* - 0 - Compare function disabled.
* - 1 - Compare function enabled.
*/
//@{
#define BP_ADC_SC2_ACFE (5U) //!< Bit position for ADC_SC2_ACFE.
#define BM_ADC_SC2_ACFE (0x00000020U) //!< Bit mask for ADC_SC2_ACFE.
#define BS_ADC_SC2_ACFE (1U) //!< Bit field size in bits for ADC_SC2_ACFE.
#ifndef __LANGUAGE_ASM__
//! @brief Read current value of the ADC_SC2_ACFE field.
#define BR_ADC_SC2_ACFE(x) (BITBAND_ACCESS32(HW_ADC_SC2_ADDR(x), BP_ADC_SC2_ACFE))
#endif
//! @brief Format value for bitfield ADC_SC2_ACFE.
#define BF_ADC_SC2_ACFE(v) (__REG_VALUE_TYPE((__REG_VALUE_TYPE((v), uint32_t) << BP_ADC_SC2_ACFE), uint32_t) & BM_ADC_SC2_ACFE)
#ifndef __LANGUAGE_ASM__
//! @brief Set the ACFE field to a new value.
#define BW_ADC_SC2_ACFE(x, v) (BITBAND_ACCESS32(HW_ADC_SC2_ADDR(x), BP_ADC_SC2_ACFE) = (v))
#endif
//@}
/*!
* @name Register ADC_SC2, field ADTRG[6] (RW)
*
* Selects the type of trigger used for initiating a conversion. Two types of
* trigger are selectable: Software trigger: When software trigger is selected, a
* conversion is initiated following a write to SC1A. Hardware trigger: When
* hardware trigger is selected, a conversion is initiated following the assertion of
* the ADHWT input after a pulse of the ADHWTSn input.
*
* Values:
* - 0 - Software trigger selected.
* - 1 - Hardware trigger selected.
*/
//@{
#define BP_ADC_SC2_ADTRG (6U) //!< Bit position for ADC_SC2_ADTRG.
#define BM_ADC_SC2_ADTRG (0x00000040U) //!< Bit mask for ADC_SC2_ADTRG.
#define BS_ADC_SC2_ADTRG (1U) //!< Bit field size in bits for ADC_SC2_ADTRG.
#ifndef __LANGUAGE_ASM__
//! @brief Read current value of the ADC_SC2_ADTRG field.
#define BR_ADC_SC2_ADTRG(x) (BITBAND_ACCESS32(HW_ADC_SC2_ADDR(x), BP_ADC_SC2_ADTRG))
#endif
//! @brief Format value for bitfield ADC_SC2_ADTRG.
#define BF_ADC_SC2_ADTRG(v) (__REG_VALUE_TYPE((__REG_VALUE_TYPE((v), uint32_t) << BP_ADC_SC2_ADTRG), uint32_t) & BM_ADC_SC2_ADTRG)
#ifndef __LANGUAGE_ASM__
//! @brief Set the ADTRG field to a new value.
#define BW_ADC_SC2_ADTRG(x, v) (BITBAND_ACCESS32(HW_ADC_SC2_ADDR(x), BP_ADC_SC2_ADTRG) = (v))
#endif
//@}
/*!
* @name Register ADC_SC2, field ADACT[7] (RO)
*
* Indicates that a conversion or hardware averaging is in progress. ADACT is
* set when a conversion is initiated and cleared when a conversion is completed or
* aborted.
*
* Values:
* - 0 - Conversion not in progress.
* - 1 - Conversion in progress.
*/
//@{
#define BP_ADC_SC2_ADACT (7U) //!< Bit position for ADC_SC2_ADACT.
#define BM_ADC_SC2_ADACT (0x00000080U) //!< Bit mask for ADC_SC2_ADACT.
#define BS_ADC_SC2_ADACT (1U) //!< Bit field size in bits for ADC_SC2_ADACT.
#ifndef __LANGUAGE_ASM__
//! @brief Read current value of the ADC_SC2_ADACT field.
#define BR_ADC_SC2_ADACT(x) (BITBAND_ACCESS32(HW_ADC_SC2_ADDR(x), BP_ADC_SC2_ADACT))
#endif
//@}
//-------------------------------------------------------------------------------------------
// HW_ADC_SC3 - Status and Control Register 3
//-------------------------------------------------------------------------------------------
#ifndef __LANGUAGE_ASM__
/*!
* @brief HW_ADC_SC3 - Status and Control Register 3 (RW)
*
* Reset value: 0x00000000U
*
* The Status and Control Register 3 (SC3) controls the calibration, continuous
* convert, and hardware averaging functions of the ADC module.
*/
typedef union _hw_adc_sc3
{
uint32_t U;
struct _hw_adc_sc3_bitfields
{
uint32_t AVGS : 2; //!< [1:0] Hardware Average Select
uint32_t AVGE : 1; //!< [2] Hardware Average Enable
uint32_t ADCO : 1; //!< [3] Continuous Conversion Enable
uint32_t RESERVED0 : 2; //!< [5:4]
uint32_t CALF : 1; //!< [6] Calibration Failed Flag
uint32_t CAL : 1; //!< [7] Calibration
uint32_t RESERVED1 : 24; //!< [31:8]
} B;
} hw_adc_sc3_t;
#endif
/*!
* @name Constants and macros for entire ADC_SC3 register
*/
//@{
#define HW_ADC_SC3_ADDR(x) (REGS_ADC_BASE(x) + 0x24U)
#ifndef __LANGUAGE_ASM__
#define HW_ADC_SC3(x) (*(__IO hw_adc_sc3_t *) HW_ADC_SC3_ADDR(x))
#define HW_ADC_SC3_RD(x) (HW_ADC_SC3(x).U)
#define HW_ADC_SC3_WR(x, v) (HW_ADC_SC3(x).U = (v))
#define HW_ADC_SC3_SET(x, v) (HW_ADC_SC3_WR(x, HW_ADC_SC3_RD(x) | (v)))
#define HW_ADC_SC3_CLR(x, v) (HW_ADC_SC3_WR(x, HW_ADC_SC3_RD(x) & ~(v)))
#define HW_ADC_SC3_TOG(x, v) (HW_ADC_SC3_WR(x, HW_ADC_SC3_RD(x) ^ (v)))
#endif
//@}
/*
* Constants & macros for individual ADC_SC3 bitfields
*/
/*!
* @name Register ADC_SC3, field AVGS[1:0] (RW)
*
* Determines how many ADC conversions will be averaged to create the ADC
* average result.
*
* Values:
* - 00 - 4 samples averaged.
* - 01 - 8 samples averaged.
* - 10 - 16 samples averaged.
* - 11 - 32 samples averaged.
*/
//@{
#define BP_ADC_SC3_AVGS (0U) //!< Bit position for ADC_SC3_AVGS.
#define BM_ADC_SC3_AVGS (0x00000003U) //!< Bit mask for ADC_SC3_AVGS.
#define BS_ADC_SC3_AVGS (2U) //!< Bit field size in bits for ADC_SC3_AVGS.
#ifndef __LANGUAGE_ASM__
//! @brief Read current value of the ADC_SC3_AVGS field.
#define BR_ADC_SC3_AVGS(x) (HW_ADC_SC3(x).B.AVGS)
#endif
//! @brief Format value for bitfield ADC_SC3_AVGS.
#define BF_ADC_SC3_AVGS(v) (__REG_VALUE_TYPE((__REG_VALUE_TYPE((v), uint32_t) << BP_ADC_SC3_AVGS), uint32_t) & BM_ADC_SC3_AVGS)
#ifndef __LANGUAGE_ASM__
//! @brief Set the AVGS field to a new value.
#define BW_ADC_SC3_AVGS(x, v) (HW_ADC_SC3_WR(x, (HW_ADC_SC3_RD(x) & ~BM_ADC_SC3_AVGS) | BF_ADC_SC3_AVGS(v)))
#endif
//@}
/*!
* @name Register ADC_SC3, field AVGE[2] (RW)
*
* Enables the hardware average function of the ADC.
*
* Values:
* - 0 - Hardware average function disabled.
* - 1 - Hardware average function enabled.
*/
//@{
#define BP_ADC_SC3_AVGE (2U) //!< Bit position for ADC_SC3_AVGE.
#define BM_ADC_SC3_AVGE (0x00000004U) //!< Bit mask for ADC_SC3_AVGE.
#define BS_ADC_SC3_AVGE (1U) //!< Bit field size in bits for ADC_SC3_AVGE.
#ifndef __LANGUAGE_ASM__
//! @brief Read current value of the ADC_SC3_AVGE field.
#define BR_ADC_SC3_AVGE(x) (BITBAND_ACCESS32(HW_ADC_SC3_ADDR(x), BP_ADC_SC3_AVGE))
#endif
//! @brief Format value for bitfield ADC_SC3_AVGE.
#define BF_ADC_SC3_AVGE(v) (__REG_VALUE_TYPE((__REG_VALUE_TYPE((v), uint32_t) << BP_ADC_SC3_AVGE), uint32_t) & BM_ADC_SC3_AVGE)
#ifndef __LANGUAGE_ASM__
//! @brief Set the AVGE field to a new value.
#define BW_ADC_SC3_AVGE(x, v) (BITBAND_ACCESS32(HW_ADC_SC3_ADDR(x), BP_ADC_SC3_AVGE) = (v))
#endif
//@}
/*!
* @name Register ADC_SC3, field ADCO[3] (RW)
*
* Enables continuous conversions.
*
* Values:
* - 0 - One conversion or one set of conversions if the hardware average
* function is enabled, that is, AVGE=1, after initiating a conversion.
* - 1 - Continuous conversions or sets of conversions if the hardware average
* function is enabled, that is, AVGE=1, after initiating a conversion.
*/
//@{
#define BP_ADC_SC3_ADCO (3U) //!< Bit position for ADC_SC3_ADCO.
#define BM_ADC_SC3_ADCO (0x00000008U) //!< Bit mask for ADC_SC3_ADCO.
#define BS_ADC_SC3_ADCO (1U) //!< Bit field size in bits for ADC_SC3_ADCO.
#ifndef __LANGUAGE_ASM__
//! @brief Read current value of the ADC_SC3_ADCO field.
#define BR_ADC_SC3_ADCO(x) (BITBAND_ACCESS32(HW_ADC_SC3_ADDR(x), BP_ADC_SC3_ADCO))
#endif
//! @brief Format value for bitfield ADC_SC3_ADCO.
#define BF_ADC_SC3_ADCO(v) (__REG_VALUE_TYPE((__REG_VALUE_TYPE((v), uint32_t) << BP_ADC_SC3_ADCO), uint32_t) & BM_ADC_SC3_ADCO)
#ifndef __LANGUAGE_ASM__
//! @brief Set the ADCO field to a new value.
#define BW_ADC_SC3_ADCO(x, v) (BITBAND_ACCESS32(HW_ADC_SC3_ADDR(x), BP_ADC_SC3_ADCO) = (v))
#endif
//@}
/*!
* @name Register ADC_SC3, field CALF[6] (RO)
*
* Displays the result of the calibration sequence. The calibration sequence
* will fail if SC2[ADTRG] = 1, any ADC register is written, or any stop mode is
* entered before the calibration sequence completes. Writing 1 to CALF clears it.
*
* Values:
* - 0 - Calibration completed normally.
* - 1 - Calibration failed. ADC accuracy specifications are not guaranteed.
*/
//@{
#define BP_ADC_SC3_CALF (6U) //!< Bit position for ADC_SC3_CALF.
#define BM_ADC_SC3_CALF (0x00000040U) //!< Bit mask for ADC_SC3_CALF.
#define BS_ADC_SC3_CALF (1U) //!< Bit field size in bits for ADC_SC3_CALF.
#ifndef __LANGUAGE_ASM__
//! @brief Read current value of the ADC_SC3_CALF field.
#define BR_ADC_SC3_CALF(x) (BITBAND_ACCESS32(HW_ADC_SC3_ADDR(x), BP_ADC_SC3_CALF))
#endif
//@}
/*!
* @name Register ADC_SC3, field CAL[7] (RW)
*
* Begins the calibration sequence when set. This field stays set while the
* calibration is in progress and is cleared when the calibration sequence is
* completed. CALF must be checked to determine the result of the calibration sequence.
* Once started, the calibration routine cannot be interrupted by writes to the
* ADC registers or the results will be invalid and CALF will set. Setting CAL
* will abort any current conversion.
*/
//@{
#define BP_ADC_SC3_CAL (7U) //!< Bit position for ADC_SC3_CAL.
#define BM_ADC_SC3_CAL (0x00000080U) //!< Bit mask for ADC_SC3_CAL.
#define BS_ADC_SC3_CAL (1U) //!< Bit field size in bits for ADC_SC3_CAL.
#ifndef __LANGUAGE_ASM__
//! @brief Read current value of the ADC_SC3_CAL field.
#define BR_ADC_SC3_CAL(x) (BITBAND_ACCESS32(HW_ADC_SC3_ADDR(x), BP_ADC_SC3_CAL))
#endif
//! @brief Format value for bitfield ADC_SC3_CAL.
#define BF_ADC_SC3_CAL(v) (__REG_VALUE_TYPE((__REG_VALUE_TYPE((v), uint32_t) << BP_ADC_SC3_CAL), uint32_t) & BM_ADC_SC3_CAL)
#ifndef __LANGUAGE_ASM__
//! @brief Set the CAL field to a new value.
#define BW_ADC_SC3_CAL(x, v) (BITBAND_ACCESS32(HW_ADC_SC3_ADDR(x), BP_ADC_SC3_CAL) = (v))
#endif
//@}
//-------------------------------------------------------------------------------------------
// HW_ADC_OFS - ADC Offset Correction Register
//-------------------------------------------------------------------------------------------
#ifndef __LANGUAGE_ASM__
/*!
* @brief HW_ADC_OFS - ADC Offset Correction Register (RW)
*
* Reset value: 0x00000004U
*
* The ADC Offset Correction Register (OFS) contains the user-selected or
* calibration-generated offset error correction value. This register is a 2's
* complement, left-justified, 16-bit value . The value in OFS is subtracted from the
* conversion and the result is transferred into the result registers, Rn. If the
* result is greater than the maximum or less than the minimum result value, it is
* forced to the appropriate limit for the current mode of operation.
*/
typedef union _hw_adc_ofs
{
uint32_t U;
struct _hw_adc_ofs_bitfields
{
uint32_t OFS : 16; //!< [15:0] Offset Error Correction Value
uint32_t RESERVED0 : 16; //!< [31:16]
} B;
} hw_adc_ofs_t;
#endif
/*!
* @name Constants and macros for entire ADC_OFS register
*/
//@{
#define HW_ADC_OFS_ADDR(x) (REGS_ADC_BASE(x) + 0x28U)
#ifndef __LANGUAGE_ASM__
#define HW_ADC_OFS(x) (*(__IO hw_adc_ofs_t *) HW_ADC_OFS_ADDR(x))
#define HW_ADC_OFS_RD(x) (HW_ADC_OFS(x).U)
#define HW_ADC_OFS_WR(x, v) (HW_ADC_OFS(x).U = (v))
#define HW_ADC_OFS_SET(x, v) (HW_ADC_OFS_WR(x, HW_ADC_OFS_RD(x) | (v)))
#define HW_ADC_OFS_CLR(x, v) (HW_ADC_OFS_WR(x, HW_ADC_OFS_RD(x) & ~(v)))
#define HW_ADC_OFS_TOG(x, v) (HW_ADC_OFS_WR(x, HW_ADC_OFS_RD(x) ^ (v)))
#endif
//@}
/*
* Constants & macros for individual ADC_OFS bitfields
*/
/*!
* @name Register ADC_OFS, field OFS[15:0] (RW)
*/
//@{
#define BP_ADC_OFS_OFS (0U) //!< Bit position for ADC_OFS_OFS.
#define BM_ADC_OFS_OFS (0x0000FFFFU) //!< Bit mask for ADC_OFS_OFS.
#define BS_ADC_OFS_OFS (16U) //!< Bit field size in bits for ADC_OFS_OFS.
#ifndef __LANGUAGE_ASM__
//! @brief Read current value of the ADC_OFS_OFS field.
#define BR_ADC_OFS_OFS(x) (HW_ADC_OFS(x).B.OFS)
#endif
//! @brief Format value for bitfield ADC_OFS_OFS.
#define BF_ADC_OFS_OFS(v) (__REG_VALUE_TYPE((__REG_VALUE_TYPE((v), uint32_t) << BP_ADC_OFS_OFS), uint32_t) & BM_ADC_OFS_OFS)
#ifndef __LANGUAGE_ASM__
//! @brief Set the OFS field to a new value.
#define BW_ADC_OFS_OFS(x, v) (HW_ADC_OFS_WR(x, (HW_ADC_OFS_RD(x) & ~BM_ADC_OFS_OFS) | BF_ADC_OFS_OFS(v)))
#endif
//@}
//-------------------------------------------------------------------------------------------
// HW_ADC_PG - ADC Plus-Side Gain Register
//-------------------------------------------------------------------------------------------
#ifndef __LANGUAGE_ASM__
/*!
* @brief HW_ADC_PG - ADC Plus-Side Gain Register (RW)
*
* Reset value: 0x00008200U
*
* The Plus-Side Gain Register (PG) contains the gain error correction for the
* plus-side input in differential mode or the overall conversion in single-ended
* mode. PG, a 16-bit real number in binary format, is the gain adjustment
* factor, with the radix point fixed between ADPG15 and ADPG14. This register must be
* written by the user with the value described in the calibration procedure.
* Otherwise, the gain error specifications may not be met.
*/
typedef union _hw_adc_pg
{
uint32_t U;
struct _hw_adc_pg_bitfields
{
uint32_t PG : 16; //!< [15:0] Plus-Side Gain
uint32_t RESERVED0 : 16; //!< [31:16]
} B;
} hw_adc_pg_t;
#endif
/*!
* @name Constants and macros for entire ADC_PG register
*/
//@{
#define HW_ADC_PG_ADDR(x) (REGS_ADC_BASE(x) + 0x2CU)
#ifndef __LANGUAGE_ASM__
#define HW_ADC_PG(x) (*(__IO hw_adc_pg_t *) HW_ADC_PG_ADDR(x))
#define HW_ADC_PG_RD(x) (HW_ADC_PG(x).U)
#define HW_ADC_PG_WR(x, v) (HW_ADC_PG(x).U = (v))
#define HW_ADC_PG_SET(x, v) (HW_ADC_PG_WR(x, HW_ADC_PG_RD(x) | (v)))
#define HW_ADC_PG_CLR(x, v) (HW_ADC_PG_WR(x, HW_ADC_PG_RD(x) & ~(v)))
#define HW_ADC_PG_TOG(x, v) (HW_ADC_PG_WR(x, HW_ADC_PG_RD(x) ^ (v)))
#endif
//@}
/*
* Constants & macros for individual ADC_PG bitfields
*/
/*!
* @name Register ADC_PG, field PG[15:0] (RW)
*/
//@{
#define BP_ADC_PG_PG (0U) //!< Bit position for ADC_PG_PG.
#define BM_ADC_PG_PG (0x0000FFFFU) //!< Bit mask for ADC_PG_PG.
#define BS_ADC_PG_PG (16U) //!< Bit field size in bits for ADC_PG_PG.
#ifndef __LANGUAGE_ASM__
//! @brief Read current value of the ADC_PG_PG field.
#define BR_ADC_PG_PG(x) (HW_ADC_PG(x).B.PG)
#endif
//! @brief Format value for bitfield ADC_PG_PG.
#define BF_ADC_PG_PG(v) (__REG_VALUE_TYPE((__REG_VALUE_TYPE((v), uint32_t) << BP_ADC_PG_PG), uint32_t) & BM_ADC_PG_PG)
#ifndef __LANGUAGE_ASM__
//! @brief Set the PG field to a new value.
#define BW_ADC_PG_PG(x, v) (HW_ADC_PG_WR(x, (HW_ADC_PG_RD(x) & ~BM_ADC_PG_PG) | BF_ADC_PG_PG(v)))
#endif
//@}
//-------------------------------------------------------------------------------------------
// HW_ADC_MG - ADC Minus-Side Gain Register
//-------------------------------------------------------------------------------------------
#ifndef __LANGUAGE_ASM__
/*!
* @brief HW_ADC_MG - ADC Minus-Side Gain Register (RW)
*
* Reset value: 0x00008200U
*
* The Minus-Side Gain Register (MG) contains the gain error correction for the
* minus-side input in differential mode. This register is ignored in
* single-ended mode. MG, a 16-bit real number in binary format, is the gain adjustment
* factor, with the radix point fixed between ADMG15 and ADMG14. This register must
* be written by the user with the value described in the calibration procedure.
* Otherwise, the gain error specifications may not be met.
*/
typedef union _hw_adc_mg
{
uint32_t U;
struct _hw_adc_mg_bitfields
{
uint32_t MG : 16; //!< [15:0] Minus-Side Gain
uint32_t RESERVED0 : 16; //!< [31:16]
} B;
} hw_adc_mg_t;
#endif
/*!
* @name Constants and macros for entire ADC_MG register
*/
//@{
#define HW_ADC_MG_ADDR(x) (REGS_ADC_BASE(x) + 0x30U)
#ifndef __LANGUAGE_ASM__
#define HW_ADC_MG(x) (*(__IO hw_adc_mg_t *) HW_ADC_MG_ADDR(x))
#define HW_ADC_MG_RD(x) (HW_ADC_MG(x).U)
#define HW_ADC_MG_WR(x, v) (HW_ADC_MG(x).U = (v))
#define HW_ADC_MG_SET(x, v) (HW_ADC_MG_WR(x, HW_ADC_MG_RD(x) | (v)))
#define HW_ADC_MG_CLR(x, v) (HW_ADC_MG_WR(x, HW_ADC_MG_RD(x) & ~(v)))
#define HW_ADC_MG_TOG(x, v) (HW_ADC_MG_WR(x, HW_ADC_MG_RD(x) ^ (v)))
#endif
//@}
/*
* Constants & macros for individual ADC_MG bitfields
*/
/*!
* @name Register ADC_MG, field MG[15:0] (RW)
*/
//@{
#define BP_ADC_MG_MG (0U) //!< Bit position for ADC_MG_MG.
#define BM_ADC_MG_MG (0x0000FFFFU) //!< Bit mask for ADC_MG_MG.
#define BS_ADC_MG_MG (16U) //!< Bit field size in bits for ADC_MG_MG.
#ifndef __LANGUAGE_ASM__
//! @brief Read current value of the ADC_MG_MG field.
#define BR_ADC_MG_MG(x) (HW_ADC_MG(x).B.MG)
#endif
//! @brief Format value for bitfield ADC_MG_MG.
#define BF_ADC_MG_MG(v) (__REG_VALUE_TYPE((__REG_VALUE_TYPE((v), uint32_t) << BP_ADC_MG_MG), uint32_t) & BM_ADC_MG_MG)
#ifndef __LANGUAGE_ASM__
//! @brief Set the MG field to a new value.
#define BW_ADC_MG_MG(x, v) (HW_ADC_MG_WR(x, (HW_ADC_MG_RD(x) & ~BM_ADC_MG_MG) | BF_ADC_MG_MG(v)))
#endif
//@}
//-------------------------------------------------------------------------------------------
// HW_ADC_CLPD - ADC Plus-Side General Calibration Value Register
//-------------------------------------------------------------------------------------------
#ifndef __LANGUAGE_ASM__
/*!
* @brief HW_ADC_CLPD - ADC Plus-Side General Calibration Value Register (RW)
*
* Reset value: 0x0000000AU
*
* The Plus-Side General Calibration Value Registers (CLPx) contain calibration
* information that is generated by the calibration function. These registers
* contain seven calibration values of varying widths: CLP0[5:0], CLP1[6:0],
* CLP2[7:0], CLP3[8:0], CLP4[9:0], CLPS[5:0], and CLPD[5:0]. CLPx are automatically set
* when the self-calibration sequence is done, that is, CAL is cleared. If these
* registers are written by the user after calibration, the linearity error
* specifications may not be met.
*/
typedef union _hw_adc_clpd
{
uint32_t U;
struct _hw_adc_clpd_bitfields
{
uint32_t CLPD : 6; //!< [5:0]
uint32_t RESERVED0 : 26; //!< [31:6]
} B;
} hw_adc_clpd_t;
#endif
/*!
* @name Constants and macros for entire ADC_CLPD register
*/
//@{
#define HW_ADC_CLPD_ADDR(x) (REGS_ADC_BASE(x) + 0x34U)
#ifndef __LANGUAGE_ASM__
#define HW_ADC_CLPD(x) (*(__IO hw_adc_clpd_t *) HW_ADC_CLPD_ADDR(x))
#define HW_ADC_CLPD_RD(x) (HW_ADC_CLPD(x).U)
#define HW_ADC_CLPD_WR(x, v) (HW_ADC_CLPD(x).U = (v))
#define HW_ADC_CLPD_SET(x, v) (HW_ADC_CLPD_WR(x, HW_ADC_CLPD_RD(x) | (v)))
#define HW_ADC_CLPD_CLR(x, v) (HW_ADC_CLPD_WR(x, HW_ADC_CLPD_RD(x) & ~(v)))
#define HW_ADC_CLPD_TOG(x, v) (HW_ADC_CLPD_WR(x, HW_ADC_CLPD_RD(x) ^ (v)))
#endif
//@}
/*
* Constants & macros for individual ADC_CLPD bitfields
*/
/*!
* @name Register ADC_CLPD, field CLPD[5:0] (RW)
*
* Calibration Value
*/
//@{
#define BP_ADC_CLPD_CLPD (0U) //!< Bit position for ADC_CLPD_CLPD.
#define BM_ADC_CLPD_CLPD (0x0000003FU) //!< Bit mask for ADC_CLPD_CLPD.
#define BS_ADC_CLPD_CLPD (6U) //!< Bit field size in bits for ADC_CLPD_CLPD.
#ifndef __LANGUAGE_ASM__
//! @brief Read current value of the ADC_CLPD_CLPD field.
#define BR_ADC_CLPD_CLPD(x) (HW_ADC_CLPD(x).B.CLPD)
#endif
//! @brief Format value for bitfield ADC_CLPD_CLPD.
#define BF_ADC_CLPD_CLPD(v) (__REG_VALUE_TYPE((__REG_VALUE_TYPE((v), uint32_t) << BP_ADC_CLPD_CLPD), uint32_t) & BM_ADC_CLPD_CLPD)
#ifndef __LANGUAGE_ASM__
//! @brief Set the CLPD field to a new value.
#define BW_ADC_CLPD_CLPD(x, v) (HW_ADC_CLPD_WR(x, (HW_ADC_CLPD_RD(x) & ~BM_ADC_CLPD_CLPD) | BF_ADC_CLPD_CLPD(v)))
#endif
//@}
//-------------------------------------------------------------------------------------------
// HW_ADC_CLPS - ADC Plus-Side General Calibration Value Register
//-------------------------------------------------------------------------------------------
#ifndef __LANGUAGE_ASM__
/*!
* @brief HW_ADC_CLPS - ADC Plus-Side General Calibration Value Register (RW)
*
* Reset value: 0x00000020U
*
* For more information, see CLPD register description.
*/
typedef union _hw_adc_clps
{
uint32_t U;
struct _hw_adc_clps_bitfields
{
uint32_t CLPS : 6; //!< [5:0]
uint32_t RESERVED0 : 26; //!< [31:6]
} B;
} hw_adc_clps_t;
#endif
/*!
* @name Constants and macros for entire ADC_CLPS register
*/
//@{
#define HW_ADC_CLPS_ADDR(x) (REGS_ADC_BASE(x) + 0x38U)
#ifndef __LANGUAGE_ASM__
#define HW_ADC_CLPS(x) (*(__IO hw_adc_clps_t *) HW_ADC_CLPS_ADDR(x))
#define HW_ADC_CLPS_RD(x) (HW_ADC_CLPS(x).U)
#define HW_ADC_CLPS_WR(x, v) (HW_ADC_CLPS(x).U = (v))
#define HW_ADC_CLPS_SET(x, v) (HW_ADC_CLPS_WR(x, HW_ADC_CLPS_RD(x) | (v)))
#define HW_ADC_CLPS_CLR(x, v) (HW_ADC_CLPS_WR(x, HW_ADC_CLPS_RD(x) & ~(v)))
#define HW_ADC_CLPS_TOG(x, v) (HW_ADC_CLPS_WR(x, HW_ADC_CLPS_RD(x) ^ (v)))
#endif
//@}
/*
* Constants & macros for individual ADC_CLPS bitfields
*/
/*!
* @name Register ADC_CLPS, field CLPS[5:0] (RW)
*
* Calibration Value
*/
//@{
#define BP_ADC_CLPS_CLPS (0U) //!< Bit position for ADC_CLPS_CLPS.
#define BM_ADC_CLPS_CLPS (0x0000003FU) //!< Bit mask for ADC_CLPS_CLPS.
#define BS_ADC_CLPS_CLPS (6U) //!< Bit field size in bits for ADC_CLPS_CLPS.
#ifndef __LANGUAGE_ASM__
//! @brief Read current value of the ADC_CLPS_CLPS field.
#define BR_ADC_CLPS_CLPS(x) (HW_ADC_CLPS(x).B.CLPS)
#endif
//! @brief Format value for bitfield ADC_CLPS_CLPS.
#define BF_ADC_CLPS_CLPS(v) (__REG_VALUE_TYPE((__REG_VALUE_TYPE((v), uint32_t) << BP_ADC_CLPS_CLPS), uint32_t) & BM_ADC_CLPS_CLPS)
#ifndef __LANGUAGE_ASM__
//! @brief Set the CLPS field to a new value.
#define BW_ADC_CLPS_CLPS(x, v) (HW_ADC_CLPS_WR(x, (HW_ADC_CLPS_RD(x) & ~BM_ADC_CLPS_CLPS) | BF_ADC_CLPS_CLPS(v)))
#endif
//@}
//-------------------------------------------------------------------------------------------
// HW_ADC_CLP4 - ADC Plus-Side General Calibration Value Register
//-------------------------------------------------------------------------------------------
#ifndef __LANGUAGE_ASM__
/*!
* @brief HW_ADC_CLP4 - ADC Plus-Side General Calibration Value Register (RW)
*
* Reset value: 0x00000200U
*
* For more information, see CLPD register description.
*/
typedef union _hw_adc_clp4
{
uint32_t U;
struct _hw_adc_clp4_bitfields
{
uint32_t CLP4 : 10; //!< [9:0]
uint32_t RESERVED0 : 22; //!< [31:10]
} B;
} hw_adc_clp4_t;
#endif
/*!
* @name Constants and macros for entire ADC_CLP4 register
*/
//@{
#define HW_ADC_CLP4_ADDR(x) (REGS_ADC_BASE(x) + 0x3CU)
#ifndef __LANGUAGE_ASM__
#define HW_ADC_CLP4(x) (*(__IO hw_adc_clp4_t *) HW_ADC_CLP4_ADDR(x))
#define HW_ADC_CLP4_RD(x) (HW_ADC_CLP4(x).U)
#define HW_ADC_CLP4_WR(x, v) (HW_ADC_CLP4(x).U = (v))
#define HW_ADC_CLP4_SET(x, v) (HW_ADC_CLP4_WR(x, HW_ADC_CLP4_RD(x) | (v)))
#define HW_ADC_CLP4_CLR(x, v) (HW_ADC_CLP4_WR(x, HW_ADC_CLP4_RD(x) & ~(v)))
#define HW_ADC_CLP4_TOG(x, v) (HW_ADC_CLP4_WR(x, HW_ADC_CLP4_RD(x) ^ (v)))
#endif
//@}
/*
* Constants & macros for individual ADC_CLP4 bitfields
*/
/*!
* @name Register ADC_CLP4, field CLP4[9:0] (RW)
*
* Calibration Value
*/
//@{
#define BP_ADC_CLP4_CLP4 (0U) //!< Bit position for ADC_CLP4_CLP4.
#define BM_ADC_CLP4_CLP4 (0x000003FFU) //!< Bit mask for ADC_CLP4_CLP4.
#define BS_ADC_CLP4_CLP4 (10U) //!< Bit field size in bits for ADC_CLP4_CLP4.
#ifndef __LANGUAGE_ASM__
//! @brief Read current value of the ADC_CLP4_CLP4 field.
#define BR_ADC_CLP4_CLP4(x) (HW_ADC_CLP4(x).B.CLP4)
#endif
//! @brief Format value for bitfield ADC_CLP4_CLP4.
#define BF_ADC_CLP4_CLP4(v) (__REG_VALUE_TYPE((__REG_VALUE_TYPE((v), uint32_t) << BP_ADC_CLP4_CLP4), uint32_t) & BM_ADC_CLP4_CLP4)
#ifndef __LANGUAGE_ASM__
//! @brief Set the CLP4 field to a new value.
#define BW_ADC_CLP4_CLP4(x, v) (HW_ADC_CLP4_WR(x, (HW_ADC_CLP4_RD(x) & ~BM_ADC_CLP4_CLP4) | BF_ADC_CLP4_CLP4(v)))
#endif
//@}
//-------------------------------------------------------------------------------------------
// HW_ADC_CLP3 - ADC Plus-Side General Calibration Value Register
//-------------------------------------------------------------------------------------------
#ifndef __LANGUAGE_ASM__
/*!
* @brief HW_ADC_CLP3 - ADC Plus-Side General Calibration Value Register (RW)
*
* Reset value: 0x00000100U
*
* For more information, see CLPD register description.
*/
typedef union _hw_adc_clp3
{
uint32_t U;
struct _hw_adc_clp3_bitfields
{
uint32_t CLP3 : 9; //!< [8:0]
uint32_t RESERVED0 : 23; //!< [31:9]
} B;
} hw_adc_clp3_t;
#endif
/*!
* @name Constants and macros for entire ADC_CLP3 register
*/
//@{
#define HW_ADC_CLP3_ADDR(x) (REGS_ADC_BASE(x) + 0x40U)
#ifndef __LANGUAGE_ASM__
#define HW_ADC_CLP3(x) (*(__IO hw_adc_clp3_t *) HW_ADC_CLP3_ADDR(x))
#define HW_ADC_CLP3_RD(x) (HW_ADC_CLP3(x).U)
#define HW_ADC_CLP3_WR(x, v) (HW_ADC_CLP3(x).U = (v))
#define HW_ADC_CLP3_SET(x, v) (HW_ADC_CLP3_WR(x, HW_ADC_CLP3_RD(x) | (v)))
#define HW_ADC_CLP3_CLR(x, v) (HW_ADC_CLP3_WR(x, HW_ADC_CLP3_RD(x) & ~(v)))
#define HW_ADC_CLP3_TOG(x, v) (HW_ADC_CLP3_WR(x, HW_ADC_CLP3_RD(x) ^ (v)))
#endif
//@}
/*
* Constants & macros for individual ADC_CLP3 bitfields
*/
/*!
* @name Register ADC_CLP3, field CLP3[8:0] (RW)
*
* Calibration Value
*/
//@{
#define BP_ADC_CLP3_CLP3 (0U) //!< Bit position for ADC_CLP3_CLP3.
#define BM_ADC_CLP3_CLP3 (0x000001FFU) //!< Bit mask for ADC_CLP3_CLP3.
#define BS_ADC_CLP3_CLP3 (9U) //!< Bit field size in bits for ADC_CLP3_CLP3.
#ifndef __LANGUAGE_ASM__
//! @brief Read current value of the ADC_CLP3_CLP3 field.
#define BR_ADC_CLP3_CLP3(x) (HW_ADC_CLP3(x).B.CLP3)
#endif
//! @brief Format value for bitfield ADC_CLP3_CLP3.
#define BF_ADC_CLP3_CLP3(v) (__REG_VALUE_TYPE((__REG_VALUE_TYPE((v), uint32_t) << BP_ADC_CLP3_CLP3), uint32_t) & BM_ADC_CLP3_CLP3)
#ifndef __LANGUAGE_ASM__
//! @brief Set the CLP3 field to a new value.
#define BW_ADC_CLP3_CLP3(x, v) (HW_ADC_CLP3_WR(x, (HW_ADC_CLP3_RD(x) & ~BM_ADC_CLP3_CLP3) | BF_ADC_CLP3_CLP3(v)))
#endif
//@}
//-------------------------------------------------------------------------------------------
// HW_ADC_CLP2 - ADC Plus-Side General Calibration Value Register
//-------------------------------------------------------------------------------------------
#ifndef __LANGUAGE_ASM__
/*!
* @brief HW_ADC_CLP2 - ADC Plus-Side General Calibration Value Register (RW)
*
* Reset value: 0x00000080U
*
* For more information, see CLPD register description.
*/
typedef union _hw_adc_clp2
{
uint32_t U;
struct _hw_adc_clp2_bitfields
{
uint32_t CLP2 : 8; //!< [7:0]
uint32_t RESERVED0 : 24; //!< [31:8]
} B;
} hw_adc_clp2_t;
#endif
/*!
* @name Constants and macros for entire ADC_CLP2 register
*/
//@{
#define HW_ADC_CLP2_ADDR(x) (REGS_ADC_BASE(x) + 0x44U)
#ifndef __LANGUAGE_ASM__
#define HW_ADC_CLP2(x) (*(__IO hw_adc_clp2_t *) HW_ADC_CLP2_ADDR(x))
#define HW_ADC_CLP2_RD(x) (HW_ADC_CLP2(x).U)
#define HW_ADC_CLP2_WR(x, v) (HW_ADC_CLP2(x).U = (v))
#define HW_ADC_CLP2_SET(x, v) (HW_ADC_CLP2_WR(x, HW_ADC_CLP2_RD(x) | (v)))
#define HW_ADC_CLP2_CLR(x, v) (HW_ADC_CLP2_WR(x, HW_ADC_CLP2_RD(x) & ~(v)))
#define HW_ADC_CLP2_TOG(x, v) (HW_ADC_CLP2_WR(x, HW_ADC_CLP2_RD(x) ^ (v)))
#endif
//@}
/*
* Constants & macros for individual ADC_CLP2 bitfields
*/
/*!
* @name Register ADC_CLP2, field CLP2[7:0] (RW)
*
* Calibration Value
*/
//@{
#define BP_ADC_CLP2_CLP2 (0U) //!< Bit position for ADC_CLP2_CLP2.
#define BM_ADC_CLP2_CLP2 (0x000000FFU) //!< Bit mask for ADC_CLP2_CLP2.
#define BS_ADC_CLP2_CLP2 (8U) //!< Bit field size in bits for ADC_CLP2_CLP2.
#ifndef __LANGUAGE_ASM__
//! @brief Read current value of the ADC_CLP2_CLP2 field.
#define BR_ADC_CLP2_CLP2(x) (HW_ADC_CLP2(x).B.CLP2)
#endif
//! @brief Format value for bitfield ADC_CLP2_CLP2.
#define BF_ADC_CLP2_CLP2(v) (__REG_VALUE_TYPE((__REG_VALUE_TYPE((v), uint32_t) << BP_ADC_CLP2_CLP2), uint32_t) & BM_ADC_CLP2_CLP2)
#ifndef __LANGUAGE_ASM__
//! @brief Set the CLP2 field to a new value.
#define BW_ADC_CLP2_CLP2(x, v) (HW_ADC_CLP2_WR(x, (HW_ADC_CLP2_RD(x) & ~BM_ADC_CLP2_CLP2) | BF_ADC_CLP2_CLP2(v)))
#endif
//@}
//-------------------------------------------------------------------------------------------
// HW_ADC_CLP1 - ADC Plus-Side General Calibration Value Register
//-------------------------------------------------------------------------------------------
#ifndef __LANGUAGE_ASM__
/*!
* @brief HW_ADC_CLP1 - ADC Plus-Side General Calibration Value Register (RW)
*
* Reset value: 0x00000040U
*
* For more information, see CLPD register description.
*/
typedef union _hw_adc_clp1
{
uint32_t U;
struct _hw_adc_clp1_bitfields
{
uint32_t CLP1 : 7; //!< [6:0]
uint32_t RESERVED0 : 25; //!< [31:7]
} B;
} hw_adc_clp1_t;
#endif
/*!
* @name Constants and macros for entire ADC_CLP1 register
*/
//@{
#define HW_ADC_CLP1_ADDR(x) (REGS_ADC_BASE(x) + 0x48U)
#ifndef __LANGUAGE_ASM__
#define HW_ADC_CLP1(x) (*(__IO hw_adc_clp1_t *) HW_ADC_CLP1_ADDR(x))
#define HW_ADC_CLP1_RD(x) (HW_ADC_CLP1(x).U)
#define HW_ADC_CLP1_WR(x, v) (HW_ADC_CLP1(x).U = (v))
#define HW_ADC_CLP1_SET(x, v) (HW_ADC_CLP1_WR(x, HW_ADC_CLP1_RD(x) | (v)))
#define HW_ADC_CLP1_CLR(x, v) (HW_ADC_CLP1_WR(x, HW_ADC_CLP1_RD(x) & ~(v)))
#define HW_ADC_CLP1_TOG(x, v) (HW_ADC_CLP1_WR(x, HW_ADC_CLP1_RD(x) ^ (v)))
#endif
//@}
/*
* Constants & macros for individual ADC_CLP1 bitfields
*/
/*!
* @name Register ADC_CLP1, field CLP1[6:0] (RW)
*
* Calibration Value
*/
//@{
#define BP_ADC_CLP1_CLP1 (0U) //!< Bit position for ADC_CLP1_CLP1.
#define BM_ADC_CLP1_CLP1 (0x0000007FU) //!< Bit mask for ADC_CLP1_CLP1.
#define BS_ADC_CLP1_CLP1 (7U) //!< Bit field size in bits for ADC_CLP1_CLP1.
#ifndef __LANGUAGE_ASM__
//! @brief Read current value of the ADC_CLP1_CLP1 field.
#define BR_ADC_CLP1_CLP1(x) (HW_ADC_CLP1(x).B.CLP1)
#endif
//! @brief Format value for bitfield ADC_CLP1_CLP1.
#define BF_ADC_CLP1_CLP1(v) (__REG_VALUE_TYPE((__REG_VALUE_TYPE((v), uint32_t) << BP_ADC_CLP1_CLP1), uint32_t) & BM_ADC_CLP1_CLP1)
#ifndef __LANGUAGE_ASM__
//! @brief Set the CLP1 field to a new value.
#define BW_ADC_CLP1_CLP1(x, v) (HW_ADC_CLP1_WR(x, (HW_ADC_CLP1_RD(x) & ~BM_ADC_CLP1_CLP1) | BF_ADC_CLP1_CLP1(v)))
#endif
//@}
//-------------------------------------------------------------------------------------------
// HW_ADC_CLP0 - ADC Plus-Side General Calibration Value Register
//-------------------------------------------------------------------------------------------
#ifndef __LANGUAGE_ASM__
/*!
* @brief HW_ADC_CLP0 - ADC Plus-Side General Calibration Value Register (RW)
*
* Reset value: 0x00000020U
*
* For more information, see CLPD register description.
*/
typedef union _hw_adc_clp0
{
uint32_t U;
struct _hw_adc_clp0_bitfields
{
uint32_t CLP0 : 6; //!< [5:0]
uint32_t RESERVED0 : 26; //!< [31:6]
} B;
} hw_adc_clp0_t;
#endif
/*!
* @name Constants and macros for entire ADC_CLP0 register
*/
//@{
#define HW_ADC_CLP0_ADDR(x) (REGS_ADC_BASE(x) + 0x4CU)
#ifndef __LANGUAGE_ASM__
#define HW_ADC_CLP0(x) (*(__IO hw_adc_clp0_t *) HW_ADC_CLP0_ADDR(x))
#define HW_ADC_CLP0_RD(x) (HW_ADC_CLP0(x).U)
#define HW_ADC_CLP0_WR(x, v) (HW_ADC_CLP0(x).U = (v))
#define HW_ADC_CLP0_SET(x, v) (HW_ADC_CLP0_WR(x, HW_ADC_CLP0_RD(x) | (v)))
#define HW_ADC_CLP0_CLR(x, v) (HW_ADC_CLP0_WR(x, HW_ADC_CLP0_RD(x) & ~(v)))
#define HW_ADC_CLP0_TOG(x, v) (HW_ADC_CLP0_WR(x, HW_ADC_CLP0_RD(x) ^ (v)))
#endif
//@}
/*
* Constants & macros for individual ADC_CLP0 bitfields
*/
/*!
* @name Register ADC_CLP0, field CLP0[5:0] (RW)
*
* Calibration Value
*/
//@{
#define BP_ADC_CLP0_CLP0 (0U) //!< Bit position for ADC_CLP0_CLP0.
#define BM_ADC_CLP0_CLP0 (0x0000003FU) //!< Bit mask for ADC_CLP0_CLP0.
#define BS_ADC_CLP0_CLP0 (6U) //!< Bit field size in bits for ADC_CLP0_CLP0.
#ifndef __LANGUAGE_ASM__
//! @brief Read current value of the ADC_CLP0_CLP0 field.
#define BR_ADC_CLP0_CLP0(x) (HW_ADC_CLP0(x).B.CLP0)
#endif
//! @brief Format value for bitfield ADC_CLP0_CLP0.
#define BF_ADC_CLP0_CLP0(v) (__REG_VALUE_TYPE((__REG_VALUE_TYPE((v), uint32_t) << BP_ADC_CLP0_CLP0), uint32_t) & BM_ADC_CLP0_CLP0)
#ifndef __LANGUAGE_ASM__
//! @brief Set the CLP0 field to a new value.
#define BW_ADC_CLP0_CLP0(x, v) (HW_ADC_CLP0_WR(x, (HW_ADC_CLP0_RD(x) & ~BM_ADC_CLP0_CLP0) | BF_ADC_CLP0_CLP0(v)))
#endif
//@}
//-------------------------------------------------------------------------------------------
// HW_ADC_CLMD - ADC Minus-Side General Calibration Value Register
//-------------------------------------------------------------------------------------------
#ifndef __LANGUAGE_ASM__
/*!
* @brief HW_ADC_CLMD - ADC Minus-Side General Calibration Value Register (RW)
*
* Reset value: 0x0000000AU
*
* The Minus-Side General Calibration Value (CLMx) registers contain calibration
* information that is generated by the calibration function. These registers
* contain seven calibration values of varying widths: CLM0[5:0], CLM1[6:0],
* CLM2[7:0], CLM3[8:0], CLM4[9:0], CLMS[5:0], and CLMD[5:0]. CLMx are automatically
* set when the self-calibration sequence is done, that is, CAL is cleared. If
* these registers are written by the user after calibration, the linearity error
* specifications may not be met.
*/
typedef union _hw_adc_clmd
{
uint32_t U;
struct _hw_adc_clmd_bitfields
{
uint32_t CLMD : 6; //!< [5:0]
uint32_t RESERVED0 : 26; //!< [31:6]
} B;
} hw_adc_clmd_t;
#endif
/*!
* @name Constants and macros for entire ADC_CLMD register
*/
//@{
#define HW_ADC_CLMD_ADDR(x) (REGS_ADC_BASE(x) + 0x54U)
#ifndef __LANGUAGE_ASM__
#define HW_ADC_CLMD(x) (*(__IO hw_adc_clmd_t *) HW_ADC_CLMD_ADDR(x))
#define HW_ADC_CLMD_RD(x) (HW_ADC_CLMD(x).U)
#define HW_ADC_CLMD_WR(x, v) (HW_ADC_CLMD(x).U = (v))
#define HW_ADC_CLMD_SET(x, v) (HW_ADC_CLMD_WR(x, HW_ADC_CLMD_RD(x) | (v)))
#define HW_ADC_CLMD_CLR(x, v) (HW_ADC_CLMD_WR(x, HW_ADC_CLMD_RD(x) & ~(v)))
#define HW_ADC_CLMD_TOG(x, v) (HW_ADC_CLMD_WR(x, HW_ADC_CLMD_RD(x) ^ (v)))
#endif
//@}
/*
* Constants & macros for individual ADC_CLMD bitfields
*/
/*!
* @name Register ADC_CLMD, field CLMD[5:0] (RW)
*
* Calibration Value
*/
//@{
#define BP_ADC_CLMD_CLMD (0U) //!< Bit position for ADC_CLMD_CLMD.
#define BM_ADC_CLMD_CLMD (0x0000003FU) //!< Bit mask for ADC_CLMD_CLMD.
#define BS_ADC_CLMD_CLMD (6U) //!< Bit field size in bits for ADC_CLMD_CLMD.
#ifndef __LANGUAGE_ASM__
//! @brief Read current value of the ADC_CLMD_CLMD field.
#define BR_ADC_CLMD_CLMD(x) (HW_ADC_CLMD(x).B.CLMD)
#endif
//! @brief Format value for bitfield ADC_CLMD_CLMD.
#define BF_ADC_CLMD_CLMD(v) (__REG_VALUE_TYPE((__REG_VALUE_TYPE((v), uint32_t) << BP_ADC_CLMD_CLMD), uint32_t) & BM_ADC_CLMD_CLMD)
#ifndef __LANGUAGE_ASM__
//! @brief Set the CLMD field to a new value.
#define BW_ADC_CLMD_CLMD(x, v) (HW_ADC_CLMD_WR(x, (HW_ADC_CLMD_RD(x) & ~BM_ADC_CLMD_CLMD) | BF_ADC_CLMD_CLMD(v)))
#endif
//@}
//-------------------------------------------------------------------------------------------
// HW_ADC_CLMS - ADC Minus-Side General Calibration Value Register
//-------------------------------------------------------------------------------------------
#ifndef __LANGUAGE_ASM__
/*!
* @brief HW_ADC_CLMS - ADC Minus-Side General Calibration Value Register (RW)
*
* Reset value: 0x00000020U
*
* For more information, see CLMD register description.
*/
typedef union _hw_adc_clms
{
uint32_t U;
struct _hw_adc_clms_bitfields
{
uint32_t CLMS : 6; //!< [5:0]
uint32_t RESERVED0 : 26; //!< [31:6]
} B;
} hw_adc_clms_t;
#endif
/*!
* @name Constants and macros for entire ADC_CLMS register
*/
//@{
#define HW_ADC_CLMS_ADDR(x) (REGS_ADC_BASE(x) + 0x58U)
#ifndef __LANGUAGE_ASM__
#define HW_ADC_CLMS(x) (*(__IO hw_adc_clms_t *) HW_ADC_CLMS_ADDR(x))
#define HW_ADC_CLMS_RD(x) (HW_ADC_CLMS(x).U)
#define HW_ADC_CLMS_WR(x, v) (HW_ADC_CLMS(x).U = (v))
#define HW_ADC_CLMS_SET(x, v) (HW_ADC_CLMS_WR(x, HW_ADC_CLMS_RD(x) | (v)))
#define HW_ADC_CLMS_CLR(x, v) (HW_ADC_CLMS_WR(x, HW_ADC_CLMS_RD(x) & ~(v)))
#define HW_ADC_CLMS_TOG(x, v) (HW_ADC_CLMS_WR(x, HW_ADC_CLMS_RD(x) ^ (v)))
#endif
//@}
/*
* Constants & macros for individual ADC_CLMS bitfields
*/
/*!
* @name Register ADC_CLMS, field CLMS[5:0] (RW)
*
* Calibration Value
*/
//@{
#define BP_ADC_CLMS_CLMS (0U) //!< Bit position for ADC_CLMS_CLMS.
#define BM_ADC_CLMS_CLMS (0x0000003FU) //!< Bit mask for ADC_CLMS_CLMS.
#define BS_ADC_CLMS_CLMS (6U) //!< Bit field size in bits for ADC_CLMS_CLMS.
#ifndef __LANGUAGE_ASM__
//! @brief Read current value of the ADC_CLMS_CLMS field.
#define BR_ADC_CLMS_CLMS(x) (HW_ADC_CLMS(x).B.CLMS)
#endif
//! @brief Format value for bitfield ADC_CLMS_CLMS.
#define BF_ADC_CLMS_CLMS(v) (__REG_VALUE_TYPE((__REG_VALUE_TYPE((v), uint32_t) << BP_ADC_CLMS_CLMS), uint32_t) & BM_ADC_CLMS_CLMS)
#ifndef __LANGUAGE_ASM__
//! @brief Set the CLMS field to a new value.
#define BW_ADC_CLMS_CLMS(x, v) (HW_ADC_CLMS_WR(x, (HW_ADC_CLMS_RD(x) & ~BM_ADC_CLMS_CLMS) | BF_ADC_CLMS_CLMS(v)))
#endif
//@}
//-------------------------------------------------------------------------------------------
// HW_ADC_CLM4 - ADC Minus-Side General Calibration Value Register
//-------------------------------------------------------------------------------------------
#ifndef __LANGUAGE_ASM__
/*!
* @brief HW_ADC_CLM4 - ADC Minus-Side General Calibration Value Register (RW)
*
* Reset value: 0x00000200U
*
* For more information, see CLMD register description.
*/
typedef union _hw_adc_clm4
{
uint32_t U;
struct _hw_adc_clm4_bitfields
{
uint32_t CLM4 : 10; //!< [9:0]
uint32_t RESERVED0 : 22; //!< [31:10]
} B;
} hw_adc_clm4_t;
#endif
/*!
* @name Constants and macros for entire ADC_CLM4 register
*/
//@{
#define HW_ADC_CLM4_ADDR(x) (REGS_ADC_BASE(x) + 0x5CU)
#ifndef __LANGUAGE_ASM__
#define HW_ADC_CLM4(x) (*(__IO hw_adc_clm4_t *) HW_ADC_CLM4_ADDR(x))
#define HW_ADC_CLM4_RD(x) (HW_ADC_CLM4(x).U)
#define HW_ADC_CLM4_WR(x, v) (HW_ADC_CLM4(x).U = (v))
#define HW_ADC_CLM4_SET(x, v) (HW_ADC_CLM4_WR(x, HW_ADC_CLM4_RD(x) | (v)))
#define HW_ADC_CLM4_CLR(x, v) (HW_ADC_CLM4_WR(x, HW_ADC_CLM4_RD(x) & ~(v)))
#define HW_ADC_CLM4_TOG(x, v) (HW_ADC_CLM4_WR(x, HW_ADC_CLM4_RD(x) ^ (v)))
#endif
//@}
/*
* Constants & macros for individual ADC_CLM4 bitfields
*/
/*!
* @name Register ADC_CLM4, field CLM4[9:0] (RW)
*
* Calibration Value
*/
//@{
#define BP_ADC_CLM4_CLM4 (0U) //!< Bit position for ADC_CLM4_CLM4.
#define BM_ADC_CLM4_CLM4 (0x000003FFU) //!< Bit mask for ADC_CLM4_CLM4.
#define BS_ADC_CLM4_CLM4 (10U) //!< Bit field size in bits for ADC_CLM4_CLM4.
#ifndef __LANGUAGE_ASM__
//! @brief Read current value of the ADC_CLM4_CLM4 field.
#define BR_ADC_CLM4_CLM4(x) (HW_ADC_CLM4(x).B.CLM4)
#endif
//! @brief Format value for bitfield ADC_CLM4_CLM4.
#define BF_ADC_CLM4_CLM4(v) (__REG_VALUE_TYPE((__REG_VALUE_TYPE((v), uint32_t) << BP_ADC_CLM4_CLM4), uint32_t) & BM_ADC_CLM4_CLM4)
#ifndef __LANGUAGE_ASM__
//! @brief Set the CLM4 field to a new value.
#define BW_ADC_CLM4_CLM4(x, v) (HW_ADC_CLM4_WR(x, (HW_ADC_CLM4_RD(x) & ~BM_ADC_CLM4_CLM4) | BF_ADC_CLM4_CLM4(v)))
#endif
//@}
//-------------------------------------------------------------------------------------------
// HW_ADC_CLM3 - ADC Minus-Side General Calibration Value Register
//-------------------------------------------------------------------------------------------
#ifndef __LANGUAGE_ASM__
/*!
* @brief HW_ADC_CLM3 - ADC Minus-Side General Calibration Value Register (RW)
*
* Reset value: 0x00000100U
*
* For more information, see CLMD register description.
*/
typedef union _hw_adc_clm3
{
uint32_t U;
struct _hw_adc_clm3_bitfields
{
uint32_t CLM3 : 9; //!< [8:0]
uint32_t RESERVED0 : 23; //!< [31:9]
} B;
} hw_adc_clm3_t;
#endif
/*!
* @name Constants and macros for entire ADC_CLM3 register
*/
//@{
#define HW_ADC_CLM3_ADDR(x) (REGS_ADC_BASE(x) + 0x60U)
#ifndef __LANGUAGE_ASM__
#define HW_ADC_CLM3(x) (*(__IO hw_adc_clm3_t *) HW_ADC_CLM3_ADDR(x))
#define HW_ADC_CLM3_RD(x) (HW_ADC_CLM3(x).U)
#define HW_ADC_CLM3_WR(x, v) (HW_ADC_CLM3(x).U = (v))
#define HW_ADC_CLM3_SET(x, v) (HW_ADC_CLM3_WR(x, HW_ADC_CLM3_RD(x) | (v)))
#define HW_ADC_CLM3_CLR(x, v) (HW_ADC_CLM3_WR(x, HW_ADC_CLM3_RD(x) & ~(v)))
#define HW_ADC_CLM3_TOG(x, v) (HW_ADC_CLM3_WR(x, HW_ADC_CLM3_RD(x) ^ (v)))
#endif
//@}
/*
* Constants & macros for individual ADC_CLM3 bitfields
*/
/*!
* @name Register ADC_CLM3, field CLM3[8:0] (RW)
*
* Calibration Value
*/
//@{
#define BP_ADC_CLM3_CLM3 (0U) //!< Bit position for ADC_CLM3_CLM3.
#define BM_ADC_CLM3_CLM3 (0x000001FFU) //!< Bit mask for ADC_CLM3_CLM3.
#define BS_ADC_CLM3_CLM3 (9U) //!< Bit field size in bits for ADC_CLM3_CLM3.
#ifndef __LANGUAGE_ASM__
//! @brief Read current value of the ADC_CLM3_CLM3 field.
#define BR_ADC_CLM3_CLM3(x) (HW_ADC_CLM3(x).B.CLM3)
#endif
//! @brief Format value for bitfield ADC_CLM3_CLM3.
#define BF_ADC_CLM3_CLM3(v) (__REG_VALUE_TYPE((__REG_VALUE_TYPE((v), uint32_t) << BP_ADC_CLM3_CLM3), uint32_t) & BM_ADC_CLM3_CLM3)
#ifndef __LANGUAGE_ASM__
//! @brief Set the CLM3 field to a new value.
#define BW_ADC_CLM3_CLM3(x, v) (HW_ADC_CLM3_WR(x, (HW_ADC_CLM3_RD(x) & ~BM_ADC_CLM3_CLM3) | BF_ADC_CLM3_CLM3(v)))
#endif
//@}
//-------------------------------------------------------------------------------------------
// HW_ADC_CLM2 - ADC Minus-Side General Calibration Value Register
//-------------------------------------------------------------------------------------------
#ifndef __LANGUAGE_ASM__
/*!
* @brief HW_ADC_CLM2 - ADC Minus-Side General Calibration Value Register (RW)
*
* Reset value: 0x00000080U
*
* For more information, see CLMD register description.
*/
typedef union _hw_adc_clm2
{
uint32_t U;
struct _hw_adc_clm2_bitfields
{
uint32_t CLM2 : 8; //!< [7:0]
uint32_t RESERVED0 : 24; //!< [31:8]
} B;
} hw_adc_clm2_t;
#endif
/*!
* @name Constants and macros for entire ADC_CLM2 register
*/
//@{
#define HW_ADC_CLM2_ADDR(x) (REGS_ADC_BASE(x) + 0x64U)
#ifndef __LANGUAGE_ASM__
#define HW_ADC_CLM2(x) (*(__IO hw_adc_clm2_t *) HW_ADC_CLM2_ADDR(x))
#define HW_ADC_CLM2_RD(x) (HW_ADC_CLM2(x).U)
#define HW_ADC_CLM2_WR(x, v) (HW_ADC_CLM2(x).U = (v))
#define HW_ADC_CLM2_SET(x, v) (HW_ADC_CLM2_WR(x, HW_ADC_CLM2_RD(x) | (v)))
#define HW_ADC_CLM2_CLR(x, v) (HW_ADC_CLM2_WR(x, HW_ADC_CLM2_RD(x) & ~(v)))
#define HW_ADC_CLM2_TOG(x, v) (HW_ADC_CLM2_WR(x, HW_ADC_CLM2_RD(x) ^ (v)))
#endif
//@}
/*
* Constants & macros for individual ADC_CLM2 bitfields
*/
/*!
* @name Register ADC_CLM2, field CLM2[7:0] (RW)
*
* Calibration Value
*/
//@{
#define BP_ADC_CLM2_CLM2 (0U) //!< Bit position for ADC_CLM2_CLM2.
#define BM_ADC_CLM2_CLM2 (0x000000FFU) //!< Bit mask for ADC_CLM2_CLM2.
#define BS_ADC_CLM2_CLM2 (8U) //!< Bit field size in bits for ADC_CLM2_CLM2.
#ifndef __LANGUAGE_ASM__
//! @brief Read current value of the ADC_CLM2_CLM2 field.
#define BR_ADC_CLM2_CLM2(x) (HW_ADC_CLM2(x).B.CLM2)
#endif
//! @brief Format value for bitfield ADC_CLM2_CLM2.
#define BF_ADC_CLM2_CLM2(v) (__REG_VALUE_TYPE((__REG_VALUE_TYPE((v), uint32_t) << BP_ADC_CLM2_CLM2), uint32_t) & BM_ADC_CLM2_CLM2)
#ifndef __LANGUAGE_ASM__
//! @brief Set the CLM2 field to a new value.
#define BW_ADC_CLM2_CLM2(x, v) (HW_ADC_CLM2_WR(x, (HW_ADC_CLM2_RD(x) & ~BM_ADC_CLM2_CLM2) | BF_ADC_CLM2_CLM2(v)))
#endif
//@}
//-------------------------------------------------------------------------------------------
// HW_ADC_CLM1 - ADC Minus-Side General Calibration Value Register
//-------------------------------------------------------------------------------------------
#ifndef __LANGUAGE_ASM__
/*!
* @brief HW_ADC_CLM1 - ADC Minus-Side General Calibration Value Register (RW)
*
* Reset value: 0x00000040U
*
* For more information, see CLMD register description.
*/
typedef union _hw_adc_clm1
{
uint32_t U;
struct _hw_adc_clm1_bitfields
{
uint32_t CLM1 : 7; //!< [6:0]
uint32_t RESERVED0 : 25; //!< [31:7]
} B;
} hw_adc_clm1_t;
#endif
/*!
* @name Constants and macros for entire ADC_CLM1 register
*/
//@{
#define HW_ADC_CLM1_ADDR(x) (REGS_ADC_BASE(x) + 0x68U)
#ifndef __LANGUAGE_ASM__
#define HW_ADC_CLM1(x) (*(__IO hw_adc_clm1_t *) HW_ADC_CLM1_ADDR(x))
#define HW_ADC_CLM1_RD(x) (HW_ADC_CLM1(x).U)
#define HW_ADC_CLM1_WR(x, v) (HW_ADC_CLM1(x).U = (v))
#define HW_ADC_CLM1_SET(x, v) (HW_ADC_CLM1_WR(x, HW_ADC_CLM1_RD(x) | (v)))
#define HW_ADC_CLM1_CLR(x, v) (HW_ADC_CLM1_WR(x, HW_ADC_CLM1_RD(x) & ~(v)))
#define HW_ADC_CLM1_TOG(x, v) (HW_ADC_CLM1_WR(x, HW_ADC_CLM1_RD(x) ^ (v)))
#endif
//@}
/*
* Constants & macros for individual ADC_CLM1 bitfields
*/
/*!
* @name Register ADC_CLM1, field CLM1[6:0] (RW)
*
* Calibration Value
*/
//@{
#define BP_ADC_CLM1_CLM1 (0U) //!< Bit position for ADC_CLM1_CLM1.
#define BM_ADC_CLM1_CLM1 (0x0000007FU) //!< Bit mask for ADC_CLM1_CLM1.
#define BS_ADC_CLM1_CLM1 (7U) //!< Bit field size in bits for ADC_CLM1_CLM1.
#ifndef __LANGUAGE_ASM__
//! @brief Read current value of the ADC_CLM1_CLM1 field.
#define BR_ADC_CLM1_CLM1(x) (HW_ADC_CLM1(x).B.CLM1)
#endif
//! @brief Format value for bitfield ADC_CLM1_CLM1.
#define BF_ADC_CLM1_CLM1(v) (__REG_VALUE_TYPE((__REG_VALUE_TYPE((v), uint32_t) << BP_ADC_CLM1_CLM1), uint32_t) & BM_ADC_CLM1_CLM1)
#ifndef __LANGUAGE_ASM__
//! @brief Set the CLM1 field to a new value.
#define BW_ADC_CLM1_CLM1(x, v) (HW_ADC_CLM1_WR(x, (HW_ADC_CLM1_RD(x) & ~BM_ADC_CLM1_CLM1) | BF_ADC_CLM1_CLM1(v)))
#endif
//@}
//-------------------------------------------------------------------------------------------
// HW_ADC_CLM0 - ADC Minus-Side General Calibration Value Register
//-------------------------------------------------------------------------------------------
#ifndef __LANGUAGE_ASM__
/*!
* @brief HW_ADC_CLM0 - ADC Minus-Side General Calibration Value Register (RW)
*
* Reset value: 0x00000020U
*
* For more information, see CLMD register description.
*/
typedef union _hw_adc_clm0
{
uint32_t U;
struct _hw_adc_clm0_bitfields
{
uint32_t CLM0 : 6; //!< [5:0]
uint32_t RESERVED0 : 26; //!< [31:6]
} B;
} hw_adc_clm0_t;
#endif
/*!
* @name Constants and macros for entire ADC_CLM0 register
*/
//@{
#define HW_ADC_CLM0_ADDR(x) (REGS_ADC_BASE(x) + 0x6CU)
#ifndef __LANGUAGE_ASM__
#define HW_ADC_CLM0(x) (*(__IO hw_adc_clm0_t *) HW_ADC_CLM0_ADDR(x))
#define HW_ADC_CLM0_RD(x) (HW_ADC_CLM0(x).U)
#define HW_ADC_CLM0_WR(x, v) (HW_ADC_CLM0(x).U = (v))
#define HW_ADC_CLM0_SET(x, v) (HW_ADC_CLM0_WR(x, HW_ADC_CLM0_RD(x) | (v)))
#define HW_ADC_CLM0_CLR(x, v) (HW_ADC_CLM0_WR(x, HW_ADC_CLM0_RD(x) & ~(v)))
#define HW_ADC_CLM0_TOG(x, v) (HW_ADC_CLM0_WR(x, HW_ADC_CLM0_RD(x) ^ (v)))
#endif
//@}
/*
* Constants & macros for individual ADC_CLM0 bitfields
*/
/*!
* @name Register ADC_CLM0, field CLM0[5:0] (RW)
*
* Calibration Value
*/
//@{
#define BP_ADC_CLM0_CLM0 (0U) //!< Bit position for ADC_CLM0_CLM0.
#define BM_ADC_CLM0_CLM0 (0x0000003FU) //!< Bit mask for ADC_CLM0_CLM0.
#define BS_ADC_CLM0_CLM0 (6U) //!< Bit field size in bits for ADC_CLM0_CLM0.
#ifndef __LANGUAGE_ASM__
//! @brief Read current value of the ADC_CLM0_CLM0 field.
#define BR_ADC_CLM0_CLM0(x) (HW_ADC_CLM0(x).B.CLM0)
#endif
//! @brief Format value for bitfield ADC_CLM0_CLM0.
#define BF_ADC_CLM0_CLM0(v) (__REG_VALUE_TYPE((__REG_VALUE_TYPE((v), uint32_t) << BP_ADC_CLM0_CLM0), uint32_t) & BM_ADC_CLM0_CLM0)
#ifndef __LANGUAGE_ASM__
//! @brief Set the CLM0 field to a new value.
#define BW_ADC_CLM0_CLM0(x, v) (HW_ADC_CLM0_WR(x, (HW_ADC_CLM0_RD(x) & ~BM_ADC_CLM0_CLM0) | BF_ADC_CLM0_CLM0(v)))
#endif
//@}
//-------------------------------------------------------------------------------------------
// hw_adc_t - module struct
//-------------------------------------------------------------------------------------------
/*!
* @brief All ADC module registers.
*/
#ifndef __LANGUAGE_ASM__
#pragma pack(1)
typedef struct _hw_adc
{
__IO hw_adc_sc1n_t SC1n[2]; //!< [0x0] ADC Status and Control Registers 1
__IO hw_adc_cfg1_t CFG1; //!< [0x8] ADC Configuration Register 1
__IO hw_adc_cfg2_t CFG2; //!< [0xC] ADC Configuration Register 2
__I hw_adc_rn_t Rn[2]; //!< [0x10] ADC Data Result Register
__IO hw_adc_cv1_t CV1; //!< [0x18] Compare Value Registers
__IO hw_adc_cv2_t CV2; //!< [0x1C] Compare Value Registers
__IO hw_adc_sc2_t SC2; //!< [0x20] Status and Control Register 2
__IO hw_adc_sc3_t SC3; //!< [0x24] Status and Control Register 3
__IO hw_adc_ofs_t OFS; //!< [0x28] ADC Offset Correction Register
__IO hw_adc_pg_t PG; //!< [0x2C] ADC Plus-Side Gain Register
__IO hw_adc_mg_t MG; //!< [0x30] ADC Minus-Side Gain Register
__IO hw_adc_clpd_t CLPD; //!< [0x34] ADC Plus-Side General Calibration Value Register
__IO hw_adc_clps_t CLPS; //!< [0x38] ADC Plus-Side General Calibration Value Register
__IO hw_adc_clp4_t CLP4; //!< [0x3C] ADC Plus-Side General Calibration Value Register
__IO hw_adc_clp3_t CLP3; //!< [0x40] ADC Plus-Side General Calibration Value Register
__IO hw_adc_clp2_t CLP2; //!< [0x44] ADC Plus-Side General Calibration Value Register
__IO hw_adc_clp1_t CLP1; //!< [0x48] ADC Plus-Side General Calibration Value Register
__IO hw_adc_clp0_t CLP0; //!< [0x4C] ADC Plus-Side General Calibration Value Register
uint8_t _reserved0[4];
__IO hw_adc_clmd_t CLMD; //!< [0x54] ADC Minus-Side General Calibration Value Register
__IO hw_adc_clms_t CLMS; //!< [0x58] ADC Minus-Side General Calibration Value Register
__IO hw_adc_clm4_t CLM4; //!< [0x5C] ADC Minus-Side General Calibration Value Register
__IO hw_adc_clm3_t CLM3; //!< [0x60] ADC Minus-Side General Calibration Value Register
__IO hw_adc_clm2_t CLM2; //!< [0x64] ADC Minus-Side General Calibration Value Register
__IO hw_adc_clm1_t CLM1; //!< [0x68] ADC Minus-Side General Calibration Value Register
__IO hw_adc_clm0_t CLM0; //!< [0x6C] ADC Minus-Side General Calibration Value Register
} hw_adc_t;
#pragma pack()
//! @brief Macro to access all ADC registers.
//! @param x ADC instance number.
//! @return Reference (not a pointer) to the registers struct. To get a pointer to the struct,
//! use the '&' operator, like <code>&HW_ADC(0)</code>.
#define HW_ADC(x) (*(hw_adc_t *) REGS_ADC_BASE(x))
#endif
#endif // __HW_ADC_REGISTERS_H__
// v22/130726/0.9
// EOF