drivers/can/can_common.c - third_party/github/zephyrproject-rtos/zephyr - Git at Google

 /*
  * Copyright (c) 2019 Alexander Wachter
  *
  * SPDX-License-Identifier: Apache-2.0
  */

 #include <zephyr/drivers/can.h>
 #include <zephyr/kernel.h>
 #include <zephyr/sys/util.h>
 #include <zephyr/logging/log.h>

 LOG_MODULE_REGISTER(can_common, CONFIG_CAN_LOG_LEVEL);

 /* Maximum acceptable deviation in sample point location (permille) */
 #define SAMPLE_POINT_MARGIN 50

 /* CAN sync segment is always one time quantum */
 #define CAN_SYNC_SEG 1

 struct can_tx_default_cb_ctx {
 	struct k_sem done;
 	int status;
 };

 static void can_tx_default_cb(const struct device *dev, int error, void *user_data)
 {
 	struct can_tx_default_cb_ctx *ctx = user_data;

 	ctx->status = error;
 	k_sem_give(&ctx->done);
 }

 int z_impl_can_send(const struct device *dev, const struct can_frame *frame,
 		    k_timeout_t timeout, can_tx_callback_t callback,
 		    void *user_data)
 {
 	const struct can_driver_api *api = (const struct can_driver_api *)dev->api;

 	if (callback == NULL) {
 		struct can_tx_default_cb_ctx ctx;
 		int err;

 		k_sem_init(&ctx.done, 0, 1);

 		err = api->send(dev, frame, timeout, can_tx_default_cb, &ctx);
 		if (err != 0) {
 			return err;
 		}

 		k_sem_take(&ctx.done, K_FOREVER);

 		return ctx.status;
 	}

 	return api->send(dev, frame, timeout, callback, user_data);
 }

 static void can_msgq_put(const struct device *dev, struct can_frame *frame, void *user_data)
 {
 	struct k_msgq *msgq = (struct k_msgq *)user_data;
 	int ret;

 	ARG_UNUSED(dev);

 	__ASSERT_NO_MSG(msgq);

 	ret = k_msgq_put(msgq, frame, K_NO_WAIT);
 	if (ret) {
 		LOG_ERR("Msgq %p overflowed. Frame ID: 0x%x", msgq, frame->id);
 	}
 }

 int z_impl_can_add_rx_filter_msgq(const struct device *dev, struct k_msgq *msgq,
 				  const struct can_filter *filter)
 {
 	const struct can_driver_api *api = dev->api;

 	return api->add_rx_filter(dev, can_msgq_put, msgq, filter);
 }

 /**
  * @brief Update the timing given a total number of time quanta and a sample point.
  *
  * @code{.text}
  *
  * +---------------------------------------------------+
  * |     Nominal bit time in time quanta (total_tq)    |
  * +--------------+----------+------------+------------+
  * |   sync_seg   | prop_seg | phase_seg1 | phase_seg2 |
  * +--------------+----------+------------+------------+
  * | CAN_SYNG_SEG |        tseg1          |   tseg2    |
  * +--------------+-----------------------+------------+
  *                                        ^
  *                                   sample_pnt
  * @endcode
  *
  * @see @a can_timing
  *
  * @param total_tq   Total number of time quanta.
  * @param sample_pnt Sampling point in permill of the entire bit time.
  * @param[out] res   Result is written into the @a can_timing struct provided.
  * @param max        Maximum timing parameters values.
  * @param min        Minimum timing parameters values.
  * @return           Absolute sample point error.
  */
 static int update_sampling_pnt(uint32_t total_tq, uint32_t sample_pnt,
 			       struct can_timing *res,
 			       const struct can_timing *max,
 			       const struct can_timing *min)
 {
 	uint16_t tseg1_max = max->phase_seg1 + max->prop_seg;
 	uint16_t tseg1_min = min->phase_seg1 + min->prop_seg;
 	uint32_t sample_pnt_res;
 	uint16_t tseg1, tseg2;

 	/* Calculate number of time quanta in tseg2 for given sample point */
 	tseg2 = total_tq - (total_tq * sample_pnt) / 1000;
 	tseg2 = CLAMP(tseg2, min->phase_seg2, max->phase_seg2);

 	/* Calculate number of time quanta in tseg1 */
 	tseg1 = total_tq - CAN_SYNC_SEG - tseg2;
 	if (tseg1 > tseg1_max) {
 		/* Sample point location must be decreased */
 		tseg1 = tseg1_max;
 		tseg2 = total_tq - CAN_SYNC_SEG - tseg1;
 		if (tseg2 > max->phase_seg2) {
 			return -1;
 		}
 	} else if (tseg1 < tseg1_min) {
 		/* Sample point location must be increased */
 		tseg1 = tseg1_min;
 		tseg2 = total_tq - CAN_SYNC_SEG - tseg1;
 		if (tseg2 < min->phase_seg2) {
 			return -1;
 		}
 	}

 	res->phase_seg2 = tseg2;

 	/* Attempt to distribute tseg1 evenly between prop_seq and phase_seg1 */
 	res->prop_seg = CLAMP(tseg1 / 2, min->prop_seg, max->prop_seg);
 	res->phase_seg1 = tseg1 - res->prop_seg;

 	if (res->phase_seg1 > max->phase_seg1) {
 		/* Even tseg1 distribution not possible, decrease phase_seg1 */
 		res->phase_seg1 = max->phase_seg1;
 		res->prop_seg = tseg1 - res->phase_seg1;
 	} else if (res->phase_seg1 < min->phase_seg1) {
 		/* Even tseg1 distribution not possible, increase phase_seg1 */
 		res->phase_seg1 = min->phase_seg1;
 		res->prop_seg = tseg1 - res->phase_seg1;
 	}

 	/* Calculate the resulting sample point */
 	sample_pnt_res = (CAN_SYNC_SEG + tseg1) * 1000 / total_tq;

 	/* Return the absolute sample point error */
 	return sample_pnt_res > sample_pnt ?
 		sample_pnt_res - sample_pnt :
 		sample_pnt - sample_pnt_res;
 }

 /* Internal function to do the actual calculation */
 static int can_calc_timing_int(uint32_t core_clock, struct can_timing *res,
 			       const struct can_timing *min,
 			       const struct can_timing *max,
 			       uint32_t bitrate, uint16_t sp)
 {
 	uint32_t ts = max->prop_seg + max->phase_seg1 + max->phase_seg2 +
 		   CAN_SYNC_SEG;
 	uint16_t sp_err_min = UINT16_MAX;
 	int sp_err;
 	struct can_timing tmp_res;

 	if (bitrate == 0 || sp >= 1000) {
 		return -EINVAL;
 	}

 	for (int prescaler = MAX(core_clock / (ts * bitrate), 1);
 	     prescaler <= max->prescaler; ++prescaler) {
 		if (core_clock % (prescaler * bitrate)) {
 			/* No integer ts */
 			continue;
 		}

 		ts = core_clock / (prescaler * bitrate);

 		sp_err = update_sampling_pnt(ts, sp, &tmp_res,
 					     max, min);
 		if (sp_err < 0) {
 			/* No prop_seg, seg1, seg2 combination possible */
 			continue;
 		}

 		if (sp_err < sp_err_min) {
 			sp_err_min = sp_err;
 			res->prop_seg = tmp_res.prop_seg;
 			res->phase_seg1 = tmp_res.phase_seg1;
 			res->phase_seg2 = tmp_res.phase_seg2;
 			res->prescaler = (uint16_t)prescaler;
 			if (sp_err == 0) {
 				/* No better result than a perfect match*/
 				break;
 			}
 		}
 	}

 	if (sp_err_min) {
 		LOG_DBG("SP error: %d 1/1000", sp_err_min);
 	}

 	return sp_err_min == UINT16_MAX ? -ENOTSUP : (int)sp_err_min;
 }

 int z_impl_can_calc_timing(const struct device *dev, struct can_timing *res,
 			   uint32_t bitrate, uint16_t sample_pnt)
 {
 	const struct can_timing *min = can_get_timing_min(dev);
 	const struct can_timing *max = can_get_timing_max(dev);
 	uint32_t core_clock;
 	int ret;

 	if (bitrate > 1000000) {
 		return -EINVAL;
 	}

 	ret = can_get_core_clock(dev, &core_clock);
 	if (ret != 0) {
 		return ret;
 	}

 	return can_calc_timing_int(core_clock, res, min, max, bitrate, sample_pnt);
 }

 #ifdef CONFIG_CAN_FD_MODE
 int z_impl_can_calc_timing_data(const struct device *dev, struct can_timing *res,
 				uint32_t bitrate, uint16_t sample_pnt)
 {
 	const struct can_timing *min = can_get_timing_data_min(dev);
 	const struct can_timing *max = can_get_timing_data_max(dev);
 	uint32_t core_clock;
 	int ret;

 	if (bitrate > 8000000) {
 		return -EINVAL;
 	}

 	ret = can_get_core_clock(dev, &core_clock);
 	if (ret != 0) {
 		return ret;
 	}

 	return can_calc_timing_int(core_clock, res, min, max, bitrate, sample_pnt);
 }
 #endif /* CONFIG_CAN_FD_MODE */

 int can_calc_prescaler(const struct device *dev, struct can_timing *timing,
 		       uint32_t bitrate)
 {
 	uint32_t ts = timing->prop_seg + timing->phase_seg1 + timing->phase_seg2 +
 		   CAN_SYNC_SEG;
 	uint32_t core_clock;
 	int ret;

 	ret = can_get_core_clock(dev, &core_clock);
 	if (ret != 0) {
 		return ret;
 	}

 	timing->prescaler = core_clock / (bitrate * ts);

 	return core_clock % (ts * timing->prescaler);
 }

 /**
  * @brief Get the sample point location for a given bitrate
  *
  * @param  bitrate The bitrate in bits/second.
  * @return The sample point in permille.
  */
 static uint16_t sample_point_for_bitrate(uint32_t bitrate)
 {
 	uint16_t sample_pnt;

 	if (bitrate > 800000) {
 		/* 75.0% */
 		sample_pnt = 750;
 	} else if (bitrate > 500000) {
 		/* 80.0% */
 		sample_pnt = 800;
 	} else {
 		/* 87.5% */
 		sample_pnt = 875;
 	}

 	return sample_pnt;
 }

 static int check_timing_in_range(const struct can_timing *timing,
 				 const struct can_timing *min,
 				 const struct can_timing *max)
 {
 	if (timing->sjw != CAN_SJW_NO_CHANGE &&
 	    !IN_RANGE(timing->sjw, min->sjw, max->sjw)) {
 		return -ENOTSUP;
 	}

 	if (!IN_RANGE(timing->prop_seg, min->prop_seg, max->prop_seg) ||
 	    !IN_RANGE(timing->phase_seg1, min->phase_seg1, max->phase_seg1) ||
 	    !IN_RANGE(timing->phase_seg2, min->phase_seg2, max->phase_seg2) ||
 	    !IN_RANGE(timing->prescaler, min->prescaler, max->prescaler)) {
 		return -ENOTSUP;
 	}

 	return 0;
 }

 int z_impl_can_set_timing(const struct device *dev,
 			  const struct can_timing *timing)
 {
 	const struct can_driver_api *api = (const struct can_driver_api *)dev->api;
 	const struct can_timing *min = can_get_timing_min(dev);
 	const struct can_timing *max = can_get_timing_max(dev);
 	int err;

 	err = check_timing_in_range(timing, min, max);
 	if (err != 0) {
 		return err;
 	}

 	return api->set_timing(dev, timing);
 }

 int z_impl_can_set_bitrate(const struct device *dev, uint32_t bitrate)
 {
 	struct can_timing timing;
 	uint32_t max_bitrate;
 	uint16_t sample_pnt;
 	int ret;

 	ret = can_get_max_bitrate(dev, &max_bitrate);
 	if (ret == -ENOSYS) {
 		/* Maximum bitrate unknown */
 		max_bitrate = 0;
 	} else if (ret < 0) {
 		return ret;
 	}

 	if ((max_bitrate > 0) && (bitrate > max_bitrate)) {
 		return -ENOTSUP;
 	}

 	sample_pnt = sample_point_for_bitrate(bitrate);
 	ret = can_calc_timing(dev, &timing, bitrate, sample_pnt);
 	if (ret < 0) {
 		return ret;
 	}

 	if (ret > SAMPLE_POINT_MARGIN) {
 		return -ERANGE;
 	}

 	timing.sjw = CAN_SJW_NO_CHANGE;

 	return can_set_timing(dev, &timing);
 }

 #ifdef CONFIG_CAN_FD_MODE
 int z_impl_can_set_timing_data(const struct device *dev,
 			       const struct can_timing *timing_data)
 {
 	const struct can_driver_api *api = (const struct can_driver_api *)dev->api;
 	const struct can_timing *min = can_get_timing_data_min(dev);
 	const struct can_timing *max = can_get_timing_data_max(dev);
 	int err;

 	if (api->set_timing_data == NULL) {
 		return -ENOSYS;
 	}

 	err = check_timing_in_range(timing_data, min, max);
 	if (err != 0) {
 		return err;
 	}

 	return api->set_timing_data(dev, timing_data);
 }

 int z_impl_can_set_bitrate_data(const struct device *dev, uint32_t bitrate_data)
 {
 	struct can_timing timing_data;
 	uint32_t max_bitrate;
 	uint16_t sample_pnt;
 	int ret;

 	ret = can_get_max_bitrate(dev, &max_bitrate);
 	if (ret == -ENOSYS) {
 		/* Maximum bitrate unknown */
 		max_bitrate = 0;
 	} else if (ret < 0) {
 		return ret;
 	}

 	if ((max_bitrate > 0) && (bitrate_data > max_bitrate)) {
 		return -ENOTSUP;
 	}

 	sample_pnt = sample_point_for_bitrate(bitrate_data);
 	ret = can_calc_timing_data(dev, &timing_data, bitrate_data, sample_pnt);
 	if (ret < 0) {
 		return ret;
 	}

 	if (ret > SAMPLE_POINT_MARGIN) {
 		return -ERANGE;
 	}

 	timing_data.sjw = CAN_SJW_NO_CHANGE;

 	return can_set_timing_data(dev, &timing_data);
 }
 #endif /* CONFIG_CAN_FD_MODE */
	/*
	* Copyright (c) 2019 Alexander Wachter
	*
	* SPDX-License-Identifier: Apache-2.0
	*/

	#include <zephyr/drivers/can.h>
	#include <zephyr/kernel.h>
	#include <zephyr/sys/util.h>
	#include <zephyr/logging/log.h>

	LOG_MODULE_REGISTER(can_common, CONFIG_CAN_LOG_LEVEL);

	/* Maximum acceptable deviation in sample point location (permille) */
	#define SAMPLE_POINT_MARGIN 50

	/* CAN sync segment is always one time quantum */
	#define CAN_SYNC_SEG 1

	struct can_tx_default_cb_ctx {
	struct k_sem done;
	int status;
	};

	static void can_tx_default_cb(const struct device dev, int error, void user_data)
	{
	struct can_tx_default_cb_ctx *ctx = user_data;

	ctx->status = error;
	k_sem_give(&ctx->done);
	}

	int z_impl_can_send(const struct device dev, const struct can_frame frame,
	k_timeout_t timeout, can_tx_callback_t callback,
	void *user_data)
	{
	const struct can_driver_api api = (const struct can_driver_api )dev->api;

	if (callback == NULL) {
	struct can_tx_default_cb_ctx ctx;
	int err;

	k_sem_init(&ctx.done, 0, 1);

	err = api->send(dev, frame, timeout, can_tx_default_cb, &ctx);
	if (err != 0) {
	return err;
	}

	k_sem_take(&ctx.done, K_FOREVER);

	return ctx.status;
	}

	return api->send(dev, frame, timeout, callback, user_data);
	}

	static void can_msgq_put(const struct device dev, struct can_frame frame, void *user_data)
	{
	struct k_msgq msgq = (struct k_msgq )user_data;
	int ret;

	ARG_UNUSED(dev);

	__ASSERT_NO_MSG(msgq);

	ret = k_msgq_put(msgq, frame, K_NO_WAIT);
	if (ret) {
	LOG_ERR("Msgq %p overflowed. Frame ID: 0x%x", msgq, frame->id);
	}
	}

	int z_impl_can_add_rx_filter_msgq(const struct device dev, struct k_msgq msgq,
	const struct can_filter *filter)
	{
	const struct can_driver_api *api = dev->api;

	return api->add_rx_filter(dev, can_msgq_put, msgq, filter);
	}

	/**
	* @brief Update the timing given a total number of time quanta and a sample point.
	*
	* @code{.text}
	*
	* +---------------------------------------------------+
	* \| Nominal bit time in time quanta (total_tq) \|
	* +--------------+----------+------------+------------+
	* \| sync_seg \| prop_seg \| phase_seg1 \| phase_seg2 \|
	* +--------------+----------+------------+------------+
	* \| CAN_SYNG_SEG \| tseg1 \| tseg2 \|
	* +--------------+-----------------------+------------+
	* ^
	* sample_pnt
	* @endcode
	*
	* @see @a can_timing
	*
	* @param total_tq Total number of time quanta.
	* @param sample_pnt Sampling point in permill of the entire bit time.
	* @param[out] res Result is written into the @a can_timing struct provided.
	* @param max Maximum timing parameters values.
	* @param min Minimum timing parameters values.
	* @return Absolute sample point error.
	*/
	static int update_sampling_pnt(uint32_t total_tq, uint32_t sample_pnt,
	struct can_timing *res,
	const struct can_timing *max,
	const struct can_timing *min)
	{
	uint16_t tseg1_max = max->phase_seg1 + max->prop_seg;
	uint16_t tseg1_min = min->phase_seg1 + min->prop_seg;
	uint32_t sample_pnt_res;
	uint16_t tseg1, tseg2;

	/* Calculate number of time quanta in tseg2 for given sample point */
	tseg2 = total_tq - (total_tq * sample_pnt) / 1000;
	tseg2 = CLAMP(tseg2, min->phase_seg2, max->phase_seg2);

	/* Calculate number of time quanta in tseg1 */
	tseg1 = total_tq - CAN_SYNC_SEG - tseg2;
	if (tseg1 > tseg1_max) {
	/* Sample point location must be decreased */
	tseg1 = tseg1_max;
	tseg2 = total_tq - CAN_SYNC_SEG - tseg1;
	if (tseg2 > max->phase_seg2) {
	return -1;
	}
	} else if (tseg1 < tseg1_min) {
	/* Sample point location must be increased */
	tseg1 = tseg1_min;
	tseg2 = total_tq - CAN_SYNC_SEG - tseg1;
	if (tseg2 < min->phase_seg2) {
	return -1;
	}
	}

	res->phase_seg2 = tseg2;

	/* Attempt to distribute tseg1 evenly between prop_seq and phase_seg1 */
	res->prop_seg = CLAMP(tseg1 / 2, min->prop_seg, max->prop_seg);
	res->phase_seg1 = tseg1 - res->prop_seg;

	if (res->phase_seg1 > max->phase_seg1) {
	/* Even tseg1 distribution not possible, decrease phase_seg1 */
	res->phase_seg1 = max->phase_seg1;
	res->prop_seg = tseg1 - res->phase_seg1;
	} else if (res->phase_seg1 < min->phase_seg1) {
	/* Even tseg1 distribution not possible, increase phase_seg1 */
	res->phase_seg1 = min->phase_seg1;
	res->prop_seg = tseg1 - res->phase_seg1;
	}

	/* Calculate the resulting sample point */
	sample_pnt_res = (CAN_SYNC_SEG + tseg1) * 1000 / total_tq;

	/* Return the absolute sample point error */
	return sample_pnt_res > sample_pnt ?
	sample_pnt_res - sample_pnt :
	sample_pnt - sample_pnt_res;
	}

	/* Internal function to do the actual calculation */
	static int can_calc_timing_int(uint32_t core_clock, struct can_timing *res,
	const struct can_timing *min,
	const struct can_timing *max,
	uint32_t bitrate, uint16_t sp)
	{
	uint32_t ts = max->prop_seg + max->phase_seg1 + max->phase_seg2 +
	CAN_SYNC_SEG;
	uint16_t sp_err_min = UINT16_MAX;
	int sp_err;
	struct can_timing tmp_res;

	if (bitrate == 0 \|\| sp >= 1000) {
	return -EINVAL;
	}

	for (int prescaler = MAX(core_clock / (ts * bitrate), 1);
	prescaler <= max->prescaler; ++prescaler) {
	if (core_clock % (prescaler * bitrate)) {
	/* No integer ts */
	continue;
	}

	ts = core_clock / (prescaler * bitrate);

	sp_err = update_sampling_pnt(ts, sp, &tmp_res,
	max, min);
	if (sp_err < 0) {
	/* No prop_seg, seg1, seg2 combination possible */
	continue;
	}

	if (sp_err < sp_err_min) {
	sp_err_min = sp_err;
	res->prop_seg = tmp_res.prop_seg;
	res->phase_seg1 = tmp_res.phase_seg1;
	res->phase_seg2 = tmp_res.phase_seg2;
	res->prescaler = (uint16_t)prescaler;
	if (sp_err == 0) {
	/* No better result than a perfect match*/
	break;
	}
	}
	}

	if (sp_err_min) {
	LOG_DBG("SP error: %d 1/1000", sp_err_min);
	}

	return sp_err_min == UINT16_MAX ? -ENOTSUP : (int)sp_err_min;
	}

	int z_impl_can_calc_timing(const struct device dev, struct can_timing res,
	uint32_t bitrate, uint16_t sample_pnt)
	{
	const struct can_timing *min = can_get_timing_min(dev);
	const struct can_timing *max = can_get_timing_max(dev);
	uint32_t core_clock;
	int ret;

	if (bitrate > 1000000) {
	return -EINVAL;
	}

	ret = can_get_core_clock(dev, &core_clock);
	if (ret != 0) {
	return ret;
	}

	return can_calc_timing_int(core_clock, res, min, max, bitrate, sample_pnt);
	}

	#ifdef CONFIG_CAN_FD_MODE
	int z_impl_can_calc_timing_data(const struct device dev, struct can_timing res,
	uint32_t bitrate, uint16_t sample_pnt)
	{
	const struct can_timing *min = can_get_timing_data_min(dev);
	const struct can_timing *max = can_get_timing_data_max(dev);
	uint32_t core_clock;
	int ret;

	if (bitrate > 8000000) {
	return -EINVAL;
	}

	ret = can_get_core_clock(dev, &core_clock);
	if (ret != 0) {
	return ret;
	}

	return can_calc_timing_int(core_clock, res, min, max, bitrate, sample_pnt);
	}
	#endif /* CONFIG_CAN_FD_MODE */

	int can_calc_prescaler(const struct device dev, struct can_timing timing,
	uint32_t bitrate)
	{
	uint32_t ts = timing->prop_seg + timing->phase_seg1 + timing->phase_seg2 +
	CAN_SYNC_SEG;
	uint32_t core_clock;
	int ret;

	ret = can_get_core_clock(dev, &core_clock);
	if (ret != 0) {
	return ret;
	}

	timing->prescaler = core_clock / (bitrate * ts);

	return core_clock % (ts * timing->prescaler);
	}

	/**
	* @brief Get the sample point location for a given bitrate
	*
	* @param bitrate The bitrate in bits/second.
	* @return The sample point in permille.
	*/
	static uint16_t sample_point_for_bitrate(uint32_t bitrate)
	{
	uint16_t sample_pnt;

	if (bitrate > 800000) {
	/* 75.0% */
	sample_pnt = 750;
	} else if (bitrate > 500000) {
	/* 80.0% */
	sample_pnt = 800;
	} else {
	/* 87.5% */
	sample_pnt = 875;
	}

	return sample_pnt;
	}

	static int check_timing_in_range(const struct can_timing *timing,
	const struct can_timing *min,
	const struct can_timing *max)
	{
	if (timing->sjw != CAN_SJW_NO_CHANGE &&
	!IN_RANGE(timing->sjw, min->sjw, max->sjw)) {
	return -ENOTSUP;
	}

	if (!IN_RANGE(timing->prop_seg, min->prop_seg, max->prop_seg) \|\|
	!IN_RANGE(timing->phase_seg1, min->phase_seg1, max->phase_seg1) \|\|
	!IN_RANGE(timing->phase_seg2, min->phase_seg2, max->phase_seg2) \|\|
	!IN_RANGE(timing->prescaler, min->prescaler, max->prescaler)) {
	return -ENOTSUP;
	}

	return 0;
	}

	int z_impl_can_set_timing(const struct device *dev,
	const struct can_timing *timing)
	{
	const struct can_driver_api api = (const struct can_driver_api )dev->api;
	const struct can_timing *min = can_get_timing_min(dev);
	const struct can_timing *max = can_get_timing_max(dev);
	int err;

	err = check_timing_in_range(timing, min, max);
	if (err != 0) {
	return err;
	}

	return api->set_timing(dev, timing);
	}

	int z_impl_can_set_bitrate(const struct device *dev, uint32_t bitrate)
	{
	struct can_timing timing;
	uint32_t max_bitrate;
	uint16_t sample_pnt;
	int ret;

	ret = can_get_max_bitrate(dev, &max_bitrate);
	if (ret == -ENOSYS) {
	/* Maximum bitrate unknown */
	max_bitrate = 0;
	} else if (ret < 0) {
	return ret;
	}

	if ((max_bitrate > 0) && (bitrate > max_bitrate)) {
	return -ENOTSUP;
	}

	sample_pnt = sample_point_for_bitrate(bitrate);
	ret = can_calc_timing(dev, &timing, bitrate, sample_pnt);
	if (ret < 0) {
	return ret;
	}

	if (ret > SAMPLE_POINT_MARGIN) {
	return -ERANGE;
	}

	timing.sjw = CAN_SJW_NO_CHANGE;

	return can_set_timing(dev, &timing);
	}

	#ifdef CONFIG_CAN_FD_MODE
	int z_impl_can_set_timing_data(const struct device *dev,
	const struct can_timing *timing_data)
	{
	const struct can_driver_api api = (const struct can_driver_api )dev->api;
	const struct can_timing *min = can_get_timing_data_min(dev);
	const struct can_timing *max = can_get_timing_data_max(dev);
	int err;

	if (api->set_timing_data == NULL) {
	return -ENOSYS;
	}

	err = check_timing_in_range(timing_data, min, max);
	if (err != 0) {
	return err;
	}

	return api->set_timing_data(dev, timing_data);
	}

	int z_impl_can_set_bitrate_data(const struct device *dev, uint32_t bitrate_data)
	{
	struct can_timing timing_data;
	uint32_t max_bitrate;
	uint16_t sample_pnt;
	int ret;

	ret = can_get_max_bitrate(dev, &max_bitrate);
	if (ret == -ENOSYS) {
	/* Maximum bitrate unknown */
	max_bitrate = 0;
	} else if (ret < 0) {
	return ret;
	}

	if ((max_bitrate > 0) && (bitrate_data > max_bitrate)) {
	return -ENOTSUP;
	}

	sample_pnt = sample_point_for_bitrate(bitrate_data);
	ret = can_calc_timing_data(dev, &timing_data, bitrate_data, sample_pnt);
	if (ret < 0) {
	return ret;
	}

	if (ret > SAMPLE_POINT_MARGIN) {
	return -ERANGE;
	}

	timing_data.sjw = CAN_SJW_NO_CHANGE;

	return can_set_timing_data(dev, &timing_data);
	}
	#endif /* CONFIG_CAN_FD_MODE */