drivers/adc/adc_sam.c - third_party/github/zephyrproject-rtos/zephyr - Git at Google

 /*
  * Copyright (c) 2022, Basalte bv
  *
  * SPDX-License-Identifier: Apache-2.0
  */

 #define DT_DRV_COMPAT atmel_sam_adc

 #include <soc.h>
 #include <zephyr/drivers/adc.h>
 #include <zephyr/drivers/pinctrl.h>
 #include <zephyr/drivers/clock_control/atmel_sam_pmc.h>

 #define ADC_CONTEXT_USES_KERNEL_TIMER
 #include "adc_context.h"

 #include <zephyr/logging/log.h>
 #include <zephyr/irq.h>
 LOG_MODULE_REGISTER(adc_sam, CONFIG_ADC_LOG_LEVEL);

 #define SAM_ADC_NUM_CHANNELS 16
 #define SAM_ADC_TEMP_CHANNEL 15

 struct adc_sam_config {
 	Adc *regs;
 	const struct atmel_sam_pmc_config clock_cfg;

 	uint8_t prescaler;
 	uint8_t startup_time;
 	uint8_t settling_time;
 	uint8_t tracking_time;

 	const struct pinctrl_dev_config *pcfg;
 	void (*config_func)(const struct device *dev);
 };

 struct adc_sam_data {
 	struct adc_context ctx;
 	const struct device *dev;

 	/* Pointer to the buffer in the sequence. */
 	uint16_t *buffer;

 	/* Pointer to the beginning of a sample. Consider the number of
 	 * channels in the sequence: this buffer changes by that amount
 	 * so all the channels would get repeated.
 	 */
 	uint16_t *repeat_buffer;

 	/* Number of active channels to fill buffer */
 	uint8_t num_active_channels;
 };

 static uint8_t count_bits(uint32_t val)
 {
 	uint8_t res = 0;

 	while (val) {
 		res += val & 1U;
 		val >>= 1;
 	}

 	return res;
 }

 static int adc_sam_channel_setup(const struct device *dev,
 				 const struct adc_channel_cfg *channel_cfg)
 {
 	const struct adc_sam_config *const cfg = dev->config;
 	Adc *const adc = cfg->regs;

 	uint8_t channel_id = channel_cfg->channel_id;

 	if (channel_cfg->differential) {
 		if (channel_id != (channel_cfg->input_positive / 2U)
 		    || channel_id != (channel_cfg->input_negative / 2U)) {
 			LOG_ERR("Invalid ADC differential input for channel %u", channel_id);
 			return -EINVAL;
 		}
 	} else {
 		if (channel_id != channel_cfg->input_positive) {
 			LOG_ERR("Invalid ADC single-ended input for channel %u", channel_id);
 			return -EINVAL;
 		}
 	}

 	if (channel_cfg->acquisition_time != ADC_ACQ_TIME_DEFAULT) {
 		LOG_ERR("Invalid ADC channel acquisition time");
 		return -EINVAL;
 	}

 	if (channel_cfg->reference != ADC_REF_EXTERNAL0) {
 		LOG_ERR("Invalid ADC channel reference (%d)", channel_cfg->reference);
 		return -EINVAL;
 	}

 	/* Enable internal temperature sensor (channel 15 / single-ended) */
 	if (channel_cfg->channel_id == SAM_ADC_TEMP_CHANNEL) {
 		adc->ADC_ACR |= ADC_ACR_TSON;
 	}

 	/* Set channel mode, always on both inputs */
 	if (channel_cfg->differential) {
 		adc->ADC_COR |= (ADC_COR_DIFF0 | ADC_COR_DIFF1) << (channel_id * 2U);
 	} else {
 		adc->ADC_COR &= ~((ADC_COR_DIFF0 | ADC_COR_DIFF1) << (channel_id * 2U));
 	}

 	/* Reset current gain */
 	adc->ADC_CGR &= ~(ADC_CGR_GAIN0_Msk << (channel_id * 2U));

 	switch (channel_cfg->gain) {
 	case ADC_GAIN_1_2:
 		if (!channel_cfg->differential) {
 			LOG_ERR("ADC 1/2x gain only allowed for differential channel");
 			return -EINVAL;
 		}
 		/* NOP */
 		break;
 	case ADC_GAIN_1:
 		adc->ADC_CGR |= ADC_CGR_GAIN0(1) << (channel_id * 2U);
 		break;
 	case ADC_GAIN_2:
 		adc->ADC_CGR |= ADC_CGR_GAIN0(2) << (channel_id * 2U);
 		break;
 	case ADC_GAIN_4:
 		if (channel_cfg->differential) {
 			LOG_ERR("ADC 4x gain only allowed for single-ended channel");
 			return -EINVAL;
 		}
 		adc->ADC_CGR |= ADC_CGR_GAIN0(3) << (channel_id * 2U);
 		break;
 	default:
 		LOG_ERR("Invalid ADC channel gain (%d)", channel_cfg->gain);
 		return -EINVAL;
 	}

 	return 0;
 }

 static void adc_sam_start_conversion(const struct device *dev)
 {
 	const struct adc_sam_config *const cfg = dev->config;
 	Adc *const adc = cfg->regs;

 	adc->ADC_CR = ADC_CR_START;
 }

 /**
  * This is only called once at the beginning of all the conversions,
  * all channels as a group.
  */
 static void adc_context_start_sampling(struct adc_context *ctx)
 {
 	struct adc_sam_data *data = CONTAINER_OF(ctx, struct adc_sam_data, ctx);
 	const struct adc_sam_config *const cfg = data->dev->config;
 	Adc *const adc = cfg->regs;

 	data->num_active_channels = count_bits(ctx->sequence.channels);

 	/* Disable all */
 	adc->ADC_CHDR = 0xffff;

 	/* Enable selected */
 	adc->ADC_CHER = ctx->sequence.channels;

 	LOG_DBG("Starting conversion for %u channels", data->num_active_channels);

 	adc_sam_start_conversion(data->dev);
 }

 static void adc_context_update_buffer_pointer(struct adc_context *ctx, bool repeat)
 {
 	struct adc_sam_data *data = CONTAINER_OF(ctx, struct adc_sam_data, ctx);

 	if (repeat) {
 		data->buffer = data->repeat_buffer;
 	}
 }

 static int check_buffer_size(const struct adc_sequence *sequence,
 			     uint8_t active_channels)
 {
 	size_t needed_buffer_size = active_channels * sizeof(uint16_t);

 	if (sequence->options) {
 		needed_buffer_size *= (1 + sequence->options->extra_samplings);
 	}

 	if (sequence->buffer_size < needed_buffer_size) {
 		LOG_ERR("Provided buffer is too small (%u/%u)",
 				sequence->buffer_size, needed_buffer_size);
 		return -ENOMEM;
 	}

 	return 0;
 }

 static int start_read(const struct device *dev,
 		      const struct adc_sequence *sequence)
 {
 	struct adc_sam_data *data = dev->data;
 	uint32_t channels = sequence->channels;
 	int error;

 	/* Signal an error if the channel selection is invalid (no channels or
 	 * a non-existing one is selected).
 	 */
 	if (channels == 0U ||
 	    (channels & (~0UL << SAM_ADC_NUM_CHANNELS))) {
 		LOG_ERR("Invalid selection of channels");
 		return -EINVAL;
 	}

 	if (sequence->oversampling != 0U) {
 		LOG_ERR("Oversampling is not supported");
 		return -EINVAL;
 	}

 	if (sequence->resolution != 12U) {
 		LOG_ERR("ADC resolution %d is not valid", sequence->resolution);
 		return -EINVAL;
 	}

 	data->num_active_channels = count_bits(channels);

 	error = check_buffer_size(sequence, data->num_active_channels);
 	if (error) {
 		return error;
 	}

 	data->buffer = sequence->buffer;
 	data->repeat_buffer = sequence->buffer;

 	/* At this point we allow the scheduler to do other things while
 	 * we wait for the conversions to complete. This is provided by the
 	 * adc_context functions. However, the caller of this function is
 	 * blocked until the results are in.
 	 */
 	adc_context_start_read(&data->ctx, sequence);

 	return adc_context_wait_for_completion(&data->ctx);
 }

 static int adc_sam_read(const struct device *dev,
 			const struct adc_sequence *sequence)
 {
 	struct adc_sam_data *data = dev->data;
 	int error;

 	adc_context_lock(&data->ctx, false, NULL);
 	error = start_read(dev, sequence);
 	adc_context_release(&data->ctx, error);

 	return error;
 }

 static void adc_sam_isr(const struct device *dev)
 {
 	const struct adc_sam_config *const cfg = dev->config;
 	struct adc_sam_data *data = dev->data;
 	Adc *const adc = cfg->regs;

 	uint16_t result;

 	if (adc->ADC_ISR & ADC_ISR_DRDY) {
 		result = adc->ADC_LCDR & ADC_LCDR_LDATA_Msk;

 		*data->buffer++ = result;
 		data->num_active_channels--;

 		if (data->num_active_channels == 0) {
 			/* Called once all conversions have completed.*/
 			adc_context_on_sampling_done(&data->ctx, dev);
 		} else {
 			adc_sam_start_conversion(dev);
 		}
 	}
 }

 static int adc_sam_init(const struct device *dev)
 {
 	const struct adc_sam_config *const cfg = dev->config;
 	struct adc_sam_data *data = dev->data;
 	Adc *const adc = cfg->regs;

 	int ret;
 	uint32_t frequency, conv_periods;

 	/* Get peripheral clock frequency */
 	ret = clock_control_get_rate(SAM_DT_PMC_CONTROLLER,
 				     (clock_control_subsys_t)&cfg->clock_cfg,
 				     &frequency);
 	if (ret < 0) {
 		LOG_ERR("Failed to get ADC peripheral clock rate (%d)", ret);
 		return -ENODEV;
 	}

 	/* Calculate ADC clock frequency */
 	frequency = frequency / 2U / (cfg->prescaler + 1U);
 	if (frequency < 1000000U || frequency > 22000000U) {
 		LOG_ERR("Invalid ADC clock frequency %d (1MHz < freq < 22Mhz)", frequency);
 		return -EINVAL;
 	}

 	/* The number of ADC pulses for conversion  */
 	conv_periods = MAX(20U, cfg->tracking_time + 6U);

 	/* Calculate the sampling frequency */
 	frequency /= conv_periods;

 	/* Reset ADC controller */
 	adc->ADC_CR = ADC_CR_SWRST;

 	/* Reset Mode */
 	adc->ADC_MR = 0U;

 	/* Reset PDC transfer */
 	adc->ADC_PTCR = ADC_PTCR_RXTDIS | ADC_PTCR_TXTDIS;
 	adc->ADC_RCR = 0U;
 	adc->ADC_RNCR = 0U;

 	/* Set prescaler, timings and allow different analog settings for each channel */
 	adc->ADC_MR = ADC_MR_PRESCAL(cfg->prescaler)
 		    | ADC_MR_STARTUP(cfg->startup_time)
 		    | ADC_MR_SETTLING(cfg->settling_time)
 		    | ADC_MR_TRACKTIM(cfg->tracking_time)
 		    | ADC_MR_TRANSFER(2U) /* Should be 2 to guarantee the optimal hold time. */
 		    | ADC_MR_ANACH_ALLOWED;

 	/**
 	 * Set bias current control
 	 * IBCTL = 00 is the required value for a sampling frequency below 500 kHz,
 	 * and IBCTL = 01 for a sampling frequency between 500 kHz and 1 MHz.
 	 */
 	adc->ADC_ACR = ADC_ACR_IBCTL(frequency < 500000U ? 0U : 1U);

 	/* Enable ADC clock in PMC */
 	ret = clock_control_on(SAM_DT_PMC_CONTROLLER,
 			       (clock_control_subsys_t)&cfg->clock_cfg);
 	if (ret < 0) {
 		LOG_ERR("Failed to enable ADC clock (%d)", ret);
 		return -ENODEV;
 	}

 	ret = pinctrl_apply_state(cfg->pcfg, PINCTRL_STATE_DEFAULT);
 	if (ret < 0) {
 		return ret;
 	}

 	cfg->config_func(dev);

 	/* Enable data ready interrupt */
 	adc->ADC_IER = ADC_IER_DRDY;

 	data->dev = dev;

 	adc_context_unlock_unconditionally(&data->ctx);

 	return 0;
 }

 #ifdef CONFIG_ADC_ASYNC
 static int adc_sam_read_async(const struct device *dev,
 			      const struct adc_sequence *sequence,
 			      struct k_poll_signal *async)
 {
 	struct adc_sam_data *data = dev->data;
 	int error;

 	adc_context_lock(&data->ctx, true, async);
 	error = start_read(dev, sequence);
 	adc_context_release(&data->ctx, error);

 	return error;
 }
 #endif

 static const struct adc_driver_api adc_sam_api = {
 	.channel_setup = adc_sam_channel_setup,
 	.read = adc_sam_read,
 #ifdef CONFIG_ADC_ASYNC
 	.read_async = adc_sam_read_async,
 #endif
 };

 #define ADC_SAM_DEVICE(n)						\
 	PINCTRL_DT_INST_DEFINE(n);					\
 	static void adc_sam_irq_config_##n(const struct device *dev)	\
 	{								\
 		IRQ_CONNECT(DT_INST_IRQN(n),				\
 			    DT_INST_IRQ(n, priority),			\
 			    adc_sam_isr,				\
 			    DEVICE_DT_INST_GET(n), 0);			\
 		irq_enable(DT_INST_IRQN(n));				\
 	}								\
 	static const struct adc_sam_config adc_sam_config_##n = {	\
 		.regs = (Adc *)DT_INST_REG_ADDR(n),			\
 		.clock_cfg = SAM_DT_INST_CLOCK_PMC_CFG(n),		\
 		.prescaler = DT_INST_PROP(n, prescaler),		\
 		.startup_time = DT_INST_ENUM_IDX(n, startup_time),	\
 		.settling_time = DT_INST_ENUM_IDX(n, settling_time),	\
 		.tracking_time = DT_INST_ENUM_IDX(n, tracking_time),	\
 		.config_func = &adc_sam_irq_config_##n,			\
 		.pcfg = PINCTRL_DT_INST_DEV_CONFIG_GET(n),		\
 	};								\
 	static struct adc_sam_data adc_sam_data_##n = {			\
 		ADC_CONTEXT_INIT_TIMER(adc_sam_data_##n, ctx),		\
 		ADC_CONTEXT_INIT_LOCK(adc_sam_data_##n, ctx),		\
 		ADC_CONTEXT_INIT_SYNC(adc_sam_data_##n, ctx),		\
 		.dev = DEVICE_DT_INST_GET(n),				\
 	};								\
 	DEVICE_DT_INST_DEFINE(n, adc_sam_init, NULL,			\
 			      &adc_sam_data_##n,			\
 			      &adc_sam_config_##n, POST_KERNEL,		\
 			      CONFIG_ADC_INIT_PRIORITY,			\
 			      &adc_sam_api);

 DT_INST_FOREACH_STATUS_OKAY(ADC_SAM_DEVICE)
	/*
	* Copyright (c) 2022, Basalte bv
	*
	* SPDX-License-Identifier: Apache-2.0
	*/

	#define DT_DRV_COMPAT atmel_sam_adc

	#include <soc.h>
	#include <zephyr/drivers/adc.h>
	#include <zephyr/drivers/pinctrl.h>
	#include <zephyr/drivers/clock_control/atmel_sam_pmc.h>

	#define ADC_CONTEXT_USES_KERNEL_TIMER
	#include "adc_context.h"

	#include <zephyr/logging/log.h>
	#include <zephyr/irq.h>
	LOG_MODULE_REGISTER(adc_sam, CONFIG_ADC_LOG_LEVEL);

	#define SAM_ADC_NUM_CHANNELS 16
	#define SAM_ADC_TEMP_CHANNEL 15

	struct adc_sam_config {
	Adc *regs;
	const struct atmel_sam_pmc_config clock_cfg;

	uint8_t prescaler;
	uint8_t startup_time;
	uint8_t settling_time;
	uint8_t tracking_time;

	const struct pinctrl_dev_config *pcfg;
	void (config_func)(const struct device dev);
	};

	struct adc_sam_data {
	struct adc_context ctx;
	const struct device *dev;

	/* Pointer to the buffer in the sequence. */
	uint16_t *buffer;

	/* Pointer to the beginning of a sample. Consider the number of
	* channels in the sequence: this buffer changes by that amount
	* so all the channels would get repeated.
	*/
	uint16_t *repeat_buffer;

	/* Number of active channels to fill buffer */
	uint8_t num_active_channels;
	};

	static uint8_t count_bits(uint32_t val)
	{
	uint8_t res = 0;

	while (val) {
	res += val & 1U;
	val >>= 1;
	}

	return res;
	}

	static int adc_sam_channel_setup(const struct device *dev,
	const struct adc_channel_cfg *channel_cfg)
	{
	const struct adc_sam_config *const cfg = dev->config;
	Adc *const adc = cfg->regs;

	uint8_t channel_id = channel_cfg->channel_id;

	if (channel_cfg->differential) {
	if (channel_id != (channel_cfg->input_positive / 2U)
	\|\| channel_id != (channel_cfg->input_negative / 2U)) {
	LOG_ERR("Invalid ADC differential input for channel %u", channel_id);
	return -EINVAL;
	}
	} else {
	if (channel_id != channel_cfg->input_positive) {
	LOG_ERR("Invalid ADC single-ended input for channel %u", channel_id);
	return -EINVAL;
	}
	}

	if (channel_cfg->acquisition_time != ADC_ACQ_TIME_DEFAULT) {
	LOG_ERR("Invalid ADC channel acquisition time");
	return -EINVAL;
	}

	if (channel_cfg->reference != ADC_REF_EXTERNAL0) {
	LOG_ERR("Invalid ADC channel reference (%d)", channel_cfg->reference);
	return -EINVAL;
	}

	/* Enable internal temperature sensor (channel 15 / single-ended) */
	if (channel_cfg->channel_id == SAM_ADC_TEMP_CHANNEL) {
	adc->ADC_ACR \|= ADC_ACR_TSON;
	}

	/* Set channel mode, always on both inputs */
	if (channel_cfg->differential) {
	adc->ADC_COR \|= (ADC_COR_DIFF0 \| ADC_COR_DIFF1) << (channel_id * 2U);
	} else {
	adc->ADC_COR &= ~((ADC_COR_DIFF0 \| ADC_COR_DIFF1) << (channel_id * 2U));
	}

	/* Reset current gain */
	adc->ADC_CGR &= ~(ADC_CGR_GAIN0_Msk << (channel_id * 2U));

	switch (channel_cfg->gain) {
	case ADC_GAIN_1_2:
	if (!channel_cfg->differential) {
	LOG_ERR("ADC 1/2x gain only allowed for differential channel");
	return -EINVAL;
	}
	/* NOP */
	break;
	case ADC_GAIN_1:
	adc->ADC_CGR \|= ADC_CGR_GAIN0(1) << (channel_id * 2U);
	break;
	case ADC_GAIN_2:
	adc->ADC_CGR \|= ADC_CGR_GAIN0(2) << (channel_id * 2U);
	break;
	case ADC_GAIN_4:
	if (channel_cfg->differential) {
	LOG_ERR("ADC 4x gain only allowed for single-ended channel");
	return -EINVAL;
	}
	adc->ADC_CGR \|= ADC_CGR_GAIN0(3) << (channel_id * 2U);
	break;
	default:
	LOG_ERR("Invalid ADC channel gain (%d)", channel_cfg->gain);
	return -EINVAL;
	}

	return 0;
	}

	static void adc_sam_start_conversion(const struct device *dev)
	{
	const struct adc_sam_config *const cfg = dev->config;
	Adc *const adc = cfg->regs;

	adc->ADC_CR = ADC_CR_START;
	}

	/**
	* This is only called once at the beginning of all the conversions,
	* all channels as a group.
	*/
	static void adc_context_start_sampling(struct adc_context *ctx)
	{
	struct adc_sam_data *data = CONTAINER_OF(ctx, struct adc_sam_data, ctx);
	const struct adc_sam_config *const cfg = data->dev->config;
	Adc *const adc = cfg->regs;

	data->num_active_channels = count_bits(ctx->sequence.channels);

	/* Disable all */
	adc->ADC_CHDR = 0xffff;

	/* Enable selected */
	adc->ADC_CHER = ctx->sequence.channels;

	LOG_DBG("Starting conversion for %u channels", data->num_active_channels);

	adc_sam_start_conversion(data->dev);
	}

	static void adc_context_update_buffer_pointer(struct adc_context *ctx, bool repeat)
	{
	struct adc_sam_data *data = CONTAINER_OF(ctx, struct adc_sam_data, ctx);

	if (repeat) {
	data->buffer = data->repeat_buffer;
	}
	}

	static int check_buffer_size(const struct adc_sequence *sequence,
	uint8_t active_channels)
	{
	size_t needed_buffer_size = active_channels * sizeof(uint16_t);

	if (sequence->options) {
	needed_buffer_size *= (1 + sequence->options->extra_samplings);
	}

	if (sequence->buffer_size < needed_buffer_size) {
	LOG_ERR("Provided buffer is too small (%u/%u)",
	sequence->buffer_size, needed_buffer_size);
	return -ENOMEM;
	}

	return 0;
	}

	static int start_read(const struct device *dev,
	const struct adc_sequence *sequence)
	{
	struct adc_sam_data *data = dev->data;
	uint32_t channels = sequence->channels;
	int error;

	/* Signal an error if the channel selection is invalid (no channels or
	* a non-existing one is selected).
	*/
	if (channels == 0U \|\|
	(channels & (~0UL << SAM_ADC_NUM_CHANNELS))) {
	LOG_ERR("Invalid selection of channels");
	return -EINVAL;
	}

	if (sequence->oversampling != 0U) {
	LOG_ERR("Oversampling is not supported");
	return -EINVAL;
	}

	if (sequence->resolution != 12U) {
	LOG_ERR("ADC resolution %d is not valid", sequence->resolution);
	return -EINVAL;
	}

	data->num_active_channels = count_bits(channels);

	error = check_buffer_size(sequence, data->num_active_channels);
	if (error) {
	return error;
	}

	data->buffer = sequence->buffer;
	data->repeat_buffer = sequence->buffer;

	/* At this point we allow the scheduler to do other things while
	* we wait for the conversions to complete. This is provided by the
	* adc_context functions. However, the caller of this function is
	* blocked until the results are in.
	*/
	adc_context_start_read(&data->ctx, sequence);

	return adc_context_wait_for_completion(&data->ctx);
	}

	static int adc_sam_read(const struct device *dev,
	const struct adc_sequence *sequence)
	{
	struct adc_sam_data *data = dev->data;
	int error;

	adc_context_lock(&data->ctx, false, NULL);
	error = start_read(dev, sequence);
	adc_context_release(&data->ctx, error);

	return error;
	}

	static void adc_sam_isr(const struct device *dev)
	{
	const struct adc_sam_config *const cfg = dev->config;
	struct adc_sam_data *data = dev->data;
	Adc *const adc = cfg->regs;

	uint16_t result;

	if (adc->ADC_ISR & ADC_ISR_DRDY) {
	result = adc->ADC_LCDR & ADC_LCDR_LDATA_Msk;

	*data->buffer++ = result;
	data->num_active_channels--;

	if (data->num_active_channels == 0) {
	/* Called once all conversions have completed.*/
	adc_context_on_sampling_done(&data->ctx, dev);
	} else {
	adc_sam_start_conversion(dev);
	}
	}
	}

	static int adc_sam_init(const struct device *dev)
	{
	const struct adc_sam_config *const cfg = dev->config;
	struct adc_sam_data *data = dev->data;
	Adc *const adc = cfg->regs;

	int ret;
	uint32_t frequency, conv_periods;

	/* Get peripheral clock frequency */
	ret = clock_control_get_rate(SAM_DT_PMC_CONTROLLER,
	(clock_control_subsys_t)&cfg->clock_cfg,
	&frequency);
	if (ret < 0) {
	LOG_ERR("Failed to get ADC peripheral clock rate (%d)", ret);
	return -ENODEV;
	}

	/* Calculate ADC clock frequency */
	frequency = frequency / 2U / (cfg->prescaler + 1U);
	if (frequency < 1000000U \|\| frequency > 22000000U) {
	LOG_ERR("Invalid ADC clock frequency %d (1MHz < freq < 22Mhz)", frequency);
	return -EINVAL;
	}

	/* The number of ADC pulses for conversion */
	conv_periods = MAX(20U, cfg->tracking_time + 6U);

	/* Calculate the sampling frequency */
	frequency /= conv_periods;

	/* Reset ADC controller */
	adc->ADC_CR = ADC_CR_SWRST;

	/* Reset Mode */
	adc->ADC_MR = 0U;

	/* Reset PDC transfer */
	adc->ADC_PTCR = ADC_PTCR_RXTDIS \| ADC_PTCR_TXTDIS;
	adc->ADC_RCR = 0U;
	adc->ADC_RNCR = 0U;

	/* Set prescaler, timings and allow different analog settings for each channel */
	adc->ADC_MR = ADC_MR_PRESCAL(cfg->prescaler)
	\| ADC_MR_STARTUP(cfg->startup_time)
	\| ADC_MR_SETTLING(cfg->settling_time)
	\| ADC_MR_TRACKTIM(cfg->tracking_time)
	\| ADC_MR_TRANSFER(2U) /* Should be 2 to guarantee the optimal hold time. */
	\| ADC_MR_ANACH_ALLOWED;

	/**
	* Set bias current control
	* IBCTL = 00 is the required value for a sampling frequency below 500 kHz,
	* and IBCTL = 01 for a sampling frequency between 500 kHz and 1 MHz.
	*/
	adc->ADC_ACR = ADC_ACR_IBCTL(frequency < 500000U ? 0U : 1U);

	/* Enable ADC clock in PMC */
	ret = clock_control_on(SAM_DT_PMC_CONTROLLER,
	(clock_control_subsys_t)&cfg->clock_cfg);
	if (ret < 0) {
	LOG_ERR("Failed to enable ADC clock (%d)", ret);
	return -ENODEV;
	}

	ret = pinctrl_apply_state(cfg->pcfg, PINCTRL_STATE_DEFAULT);
	if (ret < 0) {
	return ret;
	}

	cfg->config_func(dev);

	/* Enable data ready interrupt */
	adc->ADC_IER = ADC_IER_DRDY;

	data->dev = dev;

	adc_context_unlock_unconditionally(&data->ctx);

	return 0;
	}

	#ifdef CONFIG_ADC_ASYNC
	static int adc_sam_read_async(const struct device *dev,
	const struct adc_sequence *sequence,
	struct k_poll_signal *async)
	{
	struct adc_sam_data *data = dev->data;
	int error;

	adc_context_lock(&data->ctx, true, async);
	error = start_read(dev, sequence);
	adc_context_release(&data->ctx, error);

	return error;
	}
	#endif

	static const struct adc_driver_api adc_sam_api = {
	.channel_setup = adc_sam_channel_setup,
	.read = adc_sam_read,
	#ifdef CONFIG_ADC_ASYNC
	.read_async = adc_sam_read_async,
	#endif
	};

	#define ADC_SAM_DEVICE(n) \
	PINCTRL_DT_INST_DEFINE(n); \
	static void adc_sam_irq_config_##n(const struct device *dev) \
	{ \
	IRQ_CONNECT(DT_INST_IRQN(n), \
	DT_INST_IRQ(n, priority), \
	adc_sam_isr, \
	DEVICE_DT_INST_GET(n), 0); \
	irq_enable(DT_INST_IRQN(n)); \
	} \
	static const struct adc_sam_config adc_sam_config_##n = { \
	.regs = (Adc *)DT_INST_REG_ADDR(n), \
	.clock_cfg = SAM_DT_INST_CLOCK_PMC_CFG(n), \
	.prescaler = DT_INST_PROP(n, prescaler), \
	.startup_time = DT_INST_ENUM_IDX(n, startup_time), \
	.settling_time = DT_INST_ENUM_IDX(n, settling_time), \
	.tracking_time = DT_INST_ENUM_IDX(n, tracking_time), \
	.config_func = &adc_sam_irq_config_##n, \
	.pcfg = PINCTRL_DT_INST_DEV_CONFIG_GET(n), \
	}; \
	static struct adc_sam_data adc_sam_data_##n = { \
	ADC_CONTEXT_INIT_TIMER(adc_sam_data_##n, ctx), \
	ADC_CONTEXT_INIT_LOCK(adc_sam_data_##n, ctx), \
	ADC_CONTEXT_INIT_SYNC(adc_sam_data_##n, ctx), \
	.dev = DEVICE_DT_INST_GET(n), \
	}; \
	DEVICE_DT_INST_DEFINE(n, adc_sam_init, NULL, \
	&adc_sam_data_##n, \
	&adc_sam_config_##n, POST_KERNEL, \
	CONFIG_ADC_INIT_PRIORITY, \
	&adc_sam_api);

	DT_INST_FOREACH_STATUS_OKAY(ADC_SAM_DEVICE)