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TARGET_TY51822R3/TOOLCHAIN_IAR/nrf_saadc.h

Committer:
AnnaBridge
Date:
2018-11-08
Revision:
171:3a7713b1edbc
Parent:
TARGET_TY51822R3/TARGET_NORDIC/TARGET_NRF5x/TARGET_SDK_11/drivers_nrf/hal/nrf_saadc.h@ 169:a7c7b631e539

File content as of revision 171:3a7713b1edbc:

/* 
 * Copyright (c) 2015 Nordic Semiconductor ASA
 * All rights reserved.
 * 
 * Redistribution and use in source and binary forms, with or without modification,
 * are permitted provided that the following conditions are met:
 * 
 *   1. Redistributions of source code must retain the above copyright notice, this list 
 *      of conditions and the following disclaimer.
 *
 *   2. Redistributions in binary form, except as embedded into a Nordic Semiconductor ASA 
 *      integrated circuit in a product or a software update for such product, must reproduce 
 *      the above copyright notice, this list of conditions and the following disclaimer in 
 *      the documentation and/or other materials provided with the distribution.
 *
 *   3. Neither the name of Nordic Semiconductor ASA nor the names of its contributors may be 
 *      used to endorse or promote products derived from this software without specific prior 
 *      written permission.
 *
 *   4. This software, with or without modification, must only be used with a 
 *      Nordic Semiconductor ASA integrated circuit.
 *
 *   5. Any software provided in binary or object form under this license must not be reverse 
 *      engineered, decompiled, modified and/or disassembled. 
 * 
 * THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "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 THE COPYRIGHT HOLDER OR CONTRIBUTORS 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.
 * 
 */



#ifndef NRF_SAADC_H_
#define NRF_SAADC_H_

#ifdef NRF52

/**
 * @defgroup nrf_saadc_hal SAADC HAL
 * @{
 * @ingroup nrf_saadc
 *
 * @brief @tagAPI52 Hardware access layer for accessing the SAADC peripheral.
 */

#include <stdbool.h>
#include <stddef.h>
#include "nrf.h"
#include "nrf_assert.h"



#define NRF_SAADC_CHANNEL_COUNT 8

/**
 * @brief Resolution of the analog-to-digital converter.
 */
typedef enum
{
    NRF_SAADC_RESOLUTION_8BIT  = SAADC_RESOLUTION_VAL_8bit,  ///< 8 bit resolution.
    NRF_SAADC_RESOLUTION_10BIT = SAADC_RESOLUTION_VAL_10bit, ///< 10 bit resolution.
    NRF_SAADC_RESOLUTION_12BIT = SAADC_RESOLUTION_VAL_12bit, ///< 12 bit resolution.
    NRF_SAADC_RESOLUTION_14BIT = SAADC_RESOLUTION_VAL_14bit  ///< 14 bit resolution.
} nrf_saadc_resolution_t;


/**
 * @brief Input selection for the analog-to-digital converter.
 */
typedef enum
{
    NRF_SAADC_INPUT_DISABLED = SAADC_CH_PSELP_PSELP_NC,           ///< Not connected.
    NRF_SAADC_INPUT_AIN0     = SAADC_CH_PSELP_PSELP_AnalogInput0, ///< Analog input 0 (AIN0).
    NRF_SAADC_INPUT_AIN1     = SAADC_CH_PSELP_PSELP_AnalogInput1, ///< Analog input 1 (AIN1).
    NRF_SAADC_INPUT_AIN2     = SAADC_CH_PSELP_PSELP_AnalogInput2, ///< Analog input 2 (AIN2).
    NRF_SAADC_INPUT_AIN3     = SAADC_CH_PSELP_PSELP_AnalogInput3, ///< Analog input 3 (AIN3).
    NRF_SAADC_INPUT_AIN4     = SAADC_CH_PSELP_PSELP_AnalogInput4, ///< Analog input 4 (AIN4).
    NRF_SAADC_INPUT_AIN5     = SAADC_CH_PSELP_PSELP_AnalogInput5, ///< Analog input 5 (AIN5).
    NRF_SAADC_INPUT_AIN6     = SAADC_CH_PSELP_PSELP_AnalogInput6, ///< Analog input 6 (AIN6).
    NRF_SAADC_INPUT_AIN7     = SAADC_CH_PSELP_PSELP_AnalogInput7, ///< Analog input 7 (AIN7).
    NRF_SAADC_INPUT_VDD      = SAADC_CH_PSELP_PSELP_VDD           ///< VDD as input.
} nrf_saadc_input_t;


/**
 * @brief Analog-to-digital converter oversampling mode.
 */
typedef enum
{
    NRF_SAADC_OVERSAMPLE_DISABLED = SAADC_OVERSAMPLE_OVERSAMPLE_Bypass,   ///< No oversampling.
    NRF_SAADC_OVERSAMPLE_2X       = SAADC_OVERSAMPLE_OVERSAMPLE_Over2x,   ///< Oversample 2x.
    NRF_SAADC_OVERSAMPLE_4X       = SAADC_OVERSAMPLE_OVERSAMPLE_Over4x,   ///< Oversample 4x.
    NRF_SAADC_OVERSAMPLE_8X       = SAADC_OVERSAMPLE_OVERSAMPLE_Over8x,   ///< Oversample 8x.
    NRF_SAADC_OVERSAMPLE_16X      = SAADC_OVERSAMPLE_OVERSAMPLE_Over16x,  ///< Oversample 16x.
    NRF_SAADC_OVERSAMPLE_32X      = SAADC_OVERSAMPLE_OVERSAMPLE_Over32x,  ///< Oversample 32x.
    NRF_SAADC_OVERSAMPLE_64X      = SAADC_OVERSAMPLE_OVERSAMPLE_Over64x,  ///< Oversample 64x.
    NRF_SAADC_OVERSAMPLE_128X     = SAADC_OVERSAMPLE_OVERSAMPLE_Over128x, ///< Oversample 128x.
    NRF_SAADC_OVERSAMPLE_256X     = SAADC_OVERSAMPLE_OVERSAMPLE_Over256x  ///< Oversample 256x.
} nrf_saadc_oversample_t;


/**
 * @brief Analog-to-digital converter channel resistor control.
 */
typedef enum
{
    NRF_SAADC_RESISTOR_DISABLED = SAADC_CH_CONFIG_RESP_Bypass,   ///< Bypass resistor ladder.
    NRF_SAADC_RESISTOR_PULLDOWN = SAADC_CH_CONFIG_RESP_Pulldown, ///< Pull-down to GND.
    NRF_SAADC_RESISTOR_PULLUP   = SAADC_CH_CONFIG_RESP_Pullup,   ///< Pull-up to VDD.
    NRF_SAADC_RESISTOR_VDD1_2   = SAADC_CH_CONFIG_RESP_VDD1_2    ///< Set input at VDD/2.
} nrf_saadc_resistor_t;


/**
 * @brief Gain factor of the analog-to-digital converter input.
 */
typedef enum
{
    NRF_SAADC_GAIN1_6 = SAADC_CH_CONFIG_GAIN_Gain1_6, ///< Gain factor 1/6.
    NRF_SAADC_GAIN1_5 = SAADC_CH_CONFIG_GAIN_Gain1_5, ///< Gain factor 1/5.
    NRF_SAADC_GAIN1_4 = SAADC_CH_CONFIG_GAIN_Gain1_4, ///< Gain factor 1/4.
    NRF_SAADC_GAIN1_3 = SAADC_CH_CONFIG_GAIN_Gain1_3, ///< Gain factor 1/3.
    NRF_SAADC_GAIN1_2 = SAADC_CH_CONFIG_GAIN_Gain1_2, ///< Gain factor 1/2.
    NRF_SAADC_GAIN1   = SAADC_CH_CONFIG_GAIN_Gain1,   ///< Gain factor 1.
    NRF_SAADC_GAIN2   = SAADC_CH_CONFIG_GAIN_Gain2,   ///< Gain factor 2.
    NRF_SAADC_GAIN4   = SAADC_CH_CONFIG_GAIN_Gain4,   ///< Gain factor 4.
} nrf_saadc_gain_t;


/**
 * @brief Reference selection for the analog-to-digital converter.
 */
typedef enum
{
    NRF_SAADC_REFERENCE_INTERNAL = SAADC_CH_CONFIG_REFSEL_Internal, ///< Internal reference (0.6 V).
    NRF_SAADC_REFERENCE_VDD4     = SAADC_CH_CONFIG_REFSEL_VDD1_4    ///< VDD/4 as reference.
} nrf_saadc_reference_t;


/**
 * @brief Analog-to-digital converter acquisition time.
 */
typedef enum
{
    NRF_SAADC_ACQTIME_3US  = SAADC_CH_CONFIG_TACQ_3us,  ///< 3 us.
    NRF_SAADC_ACQTIME_5US  = SAADC_CH_CONFIG_TACQ_5us,  ///< 5 us.
    NRF_SAADC_ACQTIME_10US = SAADC_CH_CONFIG_TACQ_10us, ///< 10 us.
    NRF_SAADC_ACQTIME_15US = SAADC_CH_CONFIG_TACQ_15us, ///< 15 us.
    NRF_SAADC_ACQTIME_20US = SAADC_CH_CONFIG_TACQ_20us, ///< 20 us.
    NRF_SAADC_ACQTIME_40US = SAADC_CH_CONFIG_TACQ_40us  ///< 40 us.
} nrf_saadc_acqtime_t;


/**
 * @brief Analog-to-digital converter channel mode.
 */
typedef enum
{
    NRF_SAADC_MODE_SINGLE_ENDED = SAADC_CH_CONFIG_MODE_SE,  ///< Single ended, PSELN will be ignored, negative input to ADC shorted to GND.
    NRF_SAADC_MODE_DIFFERENTIAL = SAADC_CH_CONFIG_MODE_Diff ///< Differential mode.
} nrf_saadc_mode_t;


/**
 * @brief Analog-to-digital converter tasks.
 */
typedef enum /*lint -save -e30 -esym(628,__INTADDR__) */
{
    NRF_SAADC_TASK_START           = offsetof(NRF_SAADC_Type, TASKS_START),           ///< Start the ADC and prepare the result buffer in RAM.
    NRF_SAADC_TASK_SAMPLE          = offsetof(NRF_SAADC_Type, TASKS_SAMPLE),          ///< Take one ADC sample. If scan is enabled, all channels are sampled.
    NRF_SAADC_TASK_STOP            = offsetof(NRF_SAADC_Type, TASKS_STOP),            ///< Stop the ADC and terminate any on-going conversion.
    NRF_SAADC_TASK_CALIBRATEOFFSET = offsetof(NRF_SAADC_Type, TASKS_CALIBRATEOFFSET), ///< Starts offset auto-calibration.
} nrf_saadc_task_t;


/**
 * @brief Analog-to-digital converter events.
 */
typedef enum /*lint -save -e30 -esym(628,__INTADDR__) */
{
    NRF_SAADC_EVENT_STARTED       = offsetof(NRF_SAADC_Type, EVENTS_STARTED),       ///< The ADC has started.
    NRF_SAADC_EVENT_END           = offsetof(NRF_SAADC_Type, EVENTS_END),           ///< The ADC has filled up the result buffer.
    NRF_SAADC_EVENT_CALIBRATEDONE = offsetof(NRF_SAADC_Type, EVENTS_CALIBRATEDONE), ///< Calibration is complete.
    NRF_SAADC_EVENT_STOPPED       = offsetof(NRF_SAADC_Type, EVENTS_STOPPED),       ///< The ADC has stopped.
    NRF_SAADC_EVENT_CH0_LIMITH    = offsetof(NRF_SAADC_Type, EVENTS_CH[0].LIMITH),  ///< Last result is equal or above CH[0].LIMIT.HIGH.
    NRF_SAADC_EVENT_CH0_LIMITL    = offsetof(NRF_SAADC_Type, EVENTS_CH[0].LIMITL),  ///< Last result is equal or below CH[0].LIMIT.LOW.
    NRF_SAADC_EVENT_CH1_LIMITH    = offsetof(NRF_SAADC_Type, EVENTS_CH[1].LIMITH),  ///< Last result is equal or above CH[1].LIMIT.HIGH.
    NRF_SAADC_EVENT_CH1_LIMITL    = offsetof(NRF_SAADC_Type, EVENTS_CH[1].LIMITL),  ///< Last result is equal or below CH[1].LIMIT.LOW.
    NRF_SAADC_EVENT_CH2_LIMITH    = offsetof(NRF_SAADC_Type, EVENTS_CH[2].LIMITH),  ///< Last result is equal or above CH[2].LIMIT.HIGH.
    NRF_SAADC_EVENT_CH2_LIMITL    = offsetof(NRF_SAADC_Type, EVENTS_CH[2].LIMITL),  ///< Last result is equal or below CH[2].LIMIT.LOW.
    NRF_SAADC_EVENT_CH3_LIMITH    = offsetof(NRF_SAADC_Type, EVENTS_CH[3].LIMITH),  ///< Last result is equal or above CH[3].LIMIT.HIGH.
    NRF_SAADC_EVENT_CH3_LIMITL    = offsetof(NRF_SAADC_Type, EVENTS_CH[3].LIMITL),  ///< Last result is equal or below CH[3].LIMIT.LOW.
    NRF_SAADC_EVENT_CH4_LIMITH    = offsetof(NRF_SAADC_Type, EVENTS_CH[4].LIMITH),  ///< Last result is equal or above CH[4].LIMIT.HIGH.
    NRF_SAADC_EVENT_CH4_LIMITL    = offsetof(NRF_SAADC_Type, EVENTS_CH[4].LIMITL),  ///< Last result is equal or below CH[4].LIMIT.LOW.
    NRF_SAADC_EVENT_CH5_LIMITH    = offsetof(NRF_SAADC_Type, EVENTS_CH[5].LIMITH),  ///< Last result is equal or above CH[5].LIMIT.HIGH.
    NRF_SAADC_EVENT_CH5_LIMITL    = offsetof(NRF_SAADC_Type, EVENTS_CH[5].LIMITL),  ///< Last result is equal or below CH[5].LIMIT.LOW.
    NRF_SAADC_EVENT_CH6_LIMITH    = offsetof(NRF_SAADC_Type, EVENTS_CH[6].LIMITH),  ///< Last result is equal or above CH[6].LIMIT.HIGH.
    NRF_SAADC_EVENT_CH6_LIMITL    = offsetof(NRF_SAADC_Type, EVENTS_CH[6].LIMITL),  ///< Last result is equal or below CH[6].LIMIT.LOW.
    NRF_SAADC_EVENT_CH7_LIMITH    = offsetof(NRF_SAADC_Type, EVENTS_CH[7].LIMITH),  ///< Last result is equal or above CH[7].LIMIT.HIGH.
    NRF_SAADC_EVENT_CH7_LIMITL    = offsetof(NRF_SAADC_Type, EVENTS_CH[7].LIMITL)   ///< Last result is equal or below CH[7].LIMIT.LOW.
} nrf_saadc_event_t;


/**
 * @brief Analog-to-digital converter interrupt masks.
 */
typedef enum
{
    NRF_SAADC_INT_STARTED   = SAADC_INTENSET_STARTED_Msk,   ///< Interrupt on EVENTS_STARTED event.
    NRF_SAADC_INT_END       = SAADC_INTENSET_END_Msk,       ///< Interrupt on EVENTS_END event.
    NRF_SAADC_INT_STOPPED   = SAADC_INTENSET_STOPPED_Msk,   ///< Interrupt on EVENTS_STOPPED event.
    NRF_SAADC_INT_CH0LIMITH = SAADC_INTENSET_CH0LIMITH_Msk, ///< Interrupt on EVENTS_CH[0].LIMITH event.
    NRF_SAADC_INT_CH0LIMITL = SAADC_INTENSET_CH0LIMITL_Msk, ///< Interrupt on EVENTS_CH[0].LIMITL event.
    NRF_SAADC_INT_CH1LIMITH = SAADC_INTENSET_CH1LIMITH_Msk, ///< Interrupt on EVENTS_CH[1].LIMITH event.
    NRF_SAADC_INT_CH1LIMITL = SAADC_INTENSET_CH1LIMITL_Msk, ///< Interrupt on EVENTS_CH[1].LIMITL event.
    NRF_SAADC_INT_CH2LIMITH = SAADC_INTENSET_CH2LIMITH_Msk, ///< Interrupt on EVENTS_CH[2].LIMITH event.
    NRF_SAADC_INT_CH2LIMITL = SAADC_INTENSET_CH2LIMITL_Msk, ///< Interrupt on EVENTS_CH[2].LIMITL event.
    NRF_SAADC_INT_CH3LIMITH = SAADC_INTENSET_CH3LIMITH_Msk, ///< Interrupt on EVENTS_CH[3].LIMITH event.
    NRF_SAADC_INT_CH3LIMITL = SAADC_INTENSET_CH3LIMITL_Msk, ///< Interrupt on EVENTS_CH[3].LIMITL event.
    NRF_SAADC_INT_CH4LIMITH = SAADC_INTENSET_CH4LIMITH_Msk, ///< Interrupt on EVENTS_CH[4].LIMITH event.
    NRF_SAADC_INT_CH4LIMITL = SAADC_INTENSET_CH4LIMITL_Msk, ///< Interrupt on EVENTS_CH[4].LIMITL event.
    NRF_SAADC_INT_CH5LIMITH = SAADC_INTENSET_CH5LIMITH_Msk, ///< Interrupt on EVENTS_CH[5].LIMITH event.
    NRF_SAADC_INT_CH5LIMITL = SAADC_INTENSET_CH5LIMITL_Msk, ///< Interrupt on EVENTS_CH[5].LIMITL event.
    NRF_SAADC_INT_CH6LIMITH = SAADC_INTENSET_CH6LIMITH_Msk, ///< Interrupt on EVENTS_CH[6].LIMITH event.
    NRF_SAADC_INT_CH6LIMITL = SAADC_INTENSET_CH6LIMITL_Msk, ///< Interrupt on EVENTS_CH[6].LIMITL event.
    NRF_SAADC_INT_CH7LIMITH = SAADC_INTENSET_CH7LIMITH_Msk, ///< Interrupt on EVENTS_CH[7].LIMITH event.
    NRF_SAADC_INT_CH7LIMITL = SAADC_INTENSET_CH7LIMITL_Msk, ///< Interrupt on EVENTS_CH[7].LIMITL event.
    NRF_SAADC_INT_ALL       = 0x7FFFFFFFUL                  ///< Mask of all interrupts.
} nrf_saadc_int_mask_t;


/**
 * @brief Analog-to-digital converter value limit type.
 */
typedef enum
{
    NRF_SAADC_LIMIT_LOW  = 0,
    NRF_SAADC_LIMIT_HIGH = 1
} nrf_saadc_limit_t;


typedef int16_t nrf_saadc_value_t;  ///< Type of a single ADC conversion result.


/**
 * @brief Analog-to-digital converter configuration structure.
 */
typedef struct
{
    nrf_saadc_resolution_t resolution;
    nrf_saadc_oversample_t oversample;
    nrf_saadc_value_t *    buffer;
    uint32_t               buffer_size;
} nrf_saadc_config_t;


/**
 * @brief Analog-to-digital converter channel configuration structure.
 */
typedef struct
{
    nrf_saadc_resistor_t  resistor_p;
    nrf_saadc_resistor_t  resistor_n;
    nrf_saadc_gain_t      gain;
    nrf_saadc_reference_t reference;
    nrf_saadc_acqtime_t   acq_time;
    nrf_saadc_mode_t      mode;
    nrf_saadc_input_t     pin_p;
    nrf_saadc_input_t     pin_n;
} nrf_saadc_channel_config_t;


/**
 * @brief Function for triggering a specific SAADC task.
 *
 * @param[in] saadc_task SAADC task.
 */
__STATIC_INLINE void nrf_saadc_task_trigger(nrf_saadc_task_t saadc_task)
{
    *((volatile uint32_t *)((uint8_t *)NRF_SAADC + (uint32_t)saadc_task)) = 0x1UL;
}


/**
 * @brief Function for getting the address of a specific SAADC task register.
 *
 * @param[in] saadc_task SAADC task.
 *
 * @return Address of the specified SAADC task.
 */
__STATIC_INLINE uint32_t nrf_saadc_task_address_get(nrf_saadc_task_t saadc_task)
{
    return (uint32_t)((uint8_t *)NRF_SAADC + (uint32_t)saadc_task);
}


/**
 * @brief Function for getting the state of a specific SAADC event.
 *
 * @param[in] saadc_event SAADC event.
 *
 * @return State of the specified SAADC event.
 */
__STATIC_INLINE bool nrf_saadc_event_check(nrf_saadc_event_t saadc_event)
{
    return (bool)*(volatile uint32_t *)((uint8_t *)NRF_SAADC + (uint32_t)saadc_event);
}


/**
 * @brief Function for clearing the specific SAADC event.
 *
 * @param[in] saadc_event SAADC event.
 */
__STATIC_INLINE void nrf_saadc_event_clear(nrf_saadc_event_t saadc_event)
{
    *((volatile uint32_t *)((uint8_t *)NRF_SAADC + (uint32_t)saadc_event)) = 0x0UL;
}


/**
 * @brief Function for getting the address of a specific SAADC event register.
 *
 * @param[in] saadc_event SAADC event.
 *
 * @return Address of the specified SAADC event.
 */
__STATIC_INLINE volatile uint32_t * nrf_saadc_event_address_get(nrf_saadc_event_t saadc_event)
{
    return (volatile uint32_t *)((uint8_t *)NRF_SAADC + (uint32_t)saadc_event);
}


/**
 * @brief Function for getting the address of a specific SAADC limit event register.
 *
 * @param[in] channel Channel number.
 * @param[in] limit_type Low limit or high limit.
 *
 * @return Address of the specified SAADC limit event.
 */
__STATIC_INLINE volatile uint32_t * nrf_saadc_event_limit_address_get(uint8_t channel, nrf_saadc_limit_t limit_type)
{
    ASSERT(channel < NRF_SAADC_CHANNEL_COUNT);
    if (limit_type == NRF_SAADC_LIMIT_HIGH)
    {
        return &NRF_SAADC->EVENTS_CH[channel].LIMITH;
    }
    else
    {
        return &NRF_SAADC->EVENTS_CH[channel].LIMITL;
    }
}


/**
 * @brief Function for getting the SAADC channel monitoring limit events.
 *
 * @param[in] channel    Channel number.
 * @param[in] limit_type Low limit or high limit.
 */
__STATIC_INLINE nrf_saadc_event_t nrf_saadc_event_limit_get(uint8_t channel, nrf_saadc_limit_t limit_type)
{
    if (limit_type == NRF_SAADC_LIMIT_HIGH)
    {
        return (nrf_saadc_event_t)( (uint32_t) NRF_SAADC_EVENT_CH0_LIMITH + 
                        (uint32_t) (NRF_SAADC_EVENT_CH1_LIMITH - NRF_SAADC_EVENT_CH0_LIMITH)
                        * (uint32_t) channel );
    }
    else
    {
        return (nrf_saadc_event_t)( (uint32_t) NRF_SAADC_EVENT_CH0_LIMITL + 
                        (uint32_t) (NRF_SAADC_EVENT_CH1_LIMITL - NRF_SAADC_EVENT_CH0_LIMITL)
                        * (uint32_t) channel );
    }
}


/**
 * @brief Function for configuring the input pins for a specific SAADC channel.
 *
 * @param[in] channel Channel number.
 * @param[in] pselp   Positive input.
 * @param[in] pseln   Negative input. Set to NRF_SAADC_INPUT_DISABLED in single ended mode.
 */
__STATIC_INLINE void nrf_saadc_channel_input_set(uint8_t channel,
                                                 nrf_saadc_input_t pselp,
                                                 nrf_saadc_input_t pseln)
{
    NRF_SAADC->CH[channel].PSELN = pseln;
    NRF_SAADC->CH[channel].PSELP = pselp;
}


/**
 * @brief Function for setting the SAADC channel monitoring limits.
 *
 * @param[in] channel Channel number.
 * @param[in] low     Low limit.
 * @param[in] high    High limit.
 */
__STATIC_INLINE void nrf_saadc_channel_limits_set(uint8_t channel, int16_t low, int16_t high)
{
    NRF_SAADC->CH[channel].LIMIT = (
            (((uint32_t) low << SAADC_CH_LIMIT_LOW_Pos) & SAADC_CH_LIMIT_LOW_Msk)
          | (((uint32_t) high << SAADC_CH_LIMIT_HIGH_Pos) & SAADC_CH_LIMIT_HIGH_Msk));
}


/**
 * @brief Function for enabling specified SAADC interrupts.
 *
 * @param[in] saadc_int_mask Interrupt(s) to enable.
 */
__STATIC_INLINE void nrf_saadc_int_enable(uint32_t saadc_int_mask)
{
    NRF_SAADC->INTENSET = saadc_int_mask;
}


/**
 * @brief Function for retrieving the state of specified SAADC interrupts.
 *
 * @param[in] saadc_int_mask Interrupt(s) to check.
 *
 * @retval true  If all specified interrupts are enabled.
 * @retval false If at least one of the given interrupts is not enabled.
 */
__STATIC_INLINE bool nrf_saadc_int_enable_check(uint32_t saadc_int_mask)
{
    return (bool)(NRF_SAADC->INTENSET & saadc_int_mask);
}


/**
 * @brief Function for disabling specified interrupts.
 *
 * @param saadc_int_mask Interrupt(s) to disable.
 */
__STATIC_INLINE void nrf_saadc_int_disable(uint32_t saadc_int_mask)
{
    NRF_SAADC->INTENCLR = saadc_int_mask;
}


/**
 * @brief Function for generating masks for SAADC channel limit interrupts.
 * 
 * @param[in] channel    SAADC channel number.
 * @param[in] limit_type Limit type.
 *
 * @returns Interrupt mask.
 */
__STATIC_INLINE uint32_t nrf_saadc_limit_int_get(uint8_t channel, nrf_saadc_limit_t limit_type)
{
    ASSERT(channel < NRF_SAADC_CHANNEL_COUNT);
    uint32_t mask = (limit_type == NRF_SAADC_LIMIT_LOW) ? NRF_SAADC_INT_CH0LIMITL : NRF_SAADC_INT_CH0LIMITH;
    return mask << (channel * 2);
}


/**
 * @brief Function for checking whether the SAADC is busy.
 *
 * This function checks whether the analog-to-digital converter is busy with a conversion.
 *
 * @retval true  If the SAADC is busy.
 * @retval false If the SAADC is not busy.
 */
__STATIC_INLINE bool nrf_saadc_busy_check(void)
{
    //return ((NRF_SAADC->STATUS & SAADC_STATUS_STATUS_Msk) == SAADC_STATUS_STATUS_Msk);
    //simplified for performance
    return NRF_SAADC->STATUS;
}


/**
 * @brief Function for enabling the SAADC.
 *
 * The analog-to-digital converter must be enabled before use.
 */
__STATIC_INLINE void nrf_saadc_enable(void)
{
    NRF_SAADC->ENABLE = (SAADC_ENABLE_ENABLE_Enabled << SAADC_ENABLE_ENABLE_Pos);
}


/**
 * @brief Function for disabling the SAADC.
 */
__STATIC_INLINE void nrf_saadc_disable(void)
{
    NRF_SAADC->ENABLE = (SAADC_ENABLE_ENABLE_Disabled << SAADC_ENABLE_ENABLE_Pos);
}


/**
 * @brief Function for checking if the SAADC is enabled.
 *
 * @retval true  If the SAADC is enabled.
 * @retval false If the SAADC is not enabled.
 */
__STATIC_INLINE bool nrf_saadc_enable_check(void)
{
    //simplified for performance
    return NRF_SAADC->ENABLE;
}


/**
 * @brief Function for initializing the SAADC result buffer.
 *
 * @param[in] buffer Pointer to the result buffer.
 * @param[in] num    Size of buffer in words.
 */
__STATIC_INLINE void nrf_saadc_buffer_init(nrf_saadc_value_t * buffer, uint32_t num)
{
    NRF_SAADC->RESULT.PTR = (uint32_t)buffer;
    NRF_SAADC->RESULT.MAXCNT = num;
}

/**
 * @brief Function for getting the number of buffer words transferred since last START operation.
 *
 * @returns Number of words transferred.
 */
__STATIC_INLINE uint16_t nrf_saadc_amount_get(void)
{
    return NRF_SAADC->RESULT.AMOUNT;
}


/**
 * @brief Function for setting the SAADC sample resolution.
 * 
 * @param[in] resolution Bit resolution.
 */
__STATIC_INLINE void nrf_saadc_resolution_set(nrf_saadc_resolution_t resolution)
{
    NRF_SAADC->RESOLUTION = resolution;
}


/**
 * @brief Function for configuring the oversampling feature.
 *
 * @param[in] oversample Oversampling mode.
 */
__STATIC_INLINE void nrf_saadc_oversample_set(nrf_saadc_oversample_t oversample)
{
    NRF_SAADC->OVERSAMPLE = oversample;
}

/**
 * @brief Function for getting the oversampling feature configuration.
 *
 * @return Oversampling configuration.
 */
__STATIC_INLINE nrf_saadc_oversample_t nrf_saadc_oversample_get(void)
{
    return (nrf_saadc_oversample_t)NRF_SAADC->OVERSAMPLE;
}

/**
 * @brief Function for initializing the SAADC channel.
 *
 * @param[in] channel Channel number.
 * @param[in] config  Pointer to the channel configuration structure.
 */
void nrf_saadc_channel_init(uint8_t channel, nrf_saadc_channel_config_t const * const config);

/**
 *@}
 **/
 
#endif //  NRF52

#endif /* NRF_SAADC_H_ */