modules/canopennode/CO_driver.c - third_party/github/zephyrproject-rtos/zephyr - Git at Google

 /*
  * Copyright (c) 2019 Vestas Wind Systems A/S
  *
  * SPDX-License-Identifier: Apache-2.0
  */

 #include <zephyr/zephyr.h>
 #include <zephyr/drivers/can.h>
 #include <zephyr/init.h>
 #include <zephyr/sys/util.h>

 #include <canopennode.h>

 #define LOG_LEVEL CONFIG_CANOPEN_LOG_LEVEL
 #include <zephyr/logging/log.h>
 LOG_MODULE_REGISTER(canopen_driver);

 K_KERNEL_STACK_DEFINE(canopen_tx_workq_stack,
 		      CONFIG_CANOPENNODE_TX_WORKQUEUE_STACK_SIZE);

 struct k_work_q canopen_tx_workq;

 struct canopen_tx_work_container {
 	struct k_work work;
 	CO_CANmodule_t *CANmodule;
 };

 struct canopen_tx_work_container canopen_tx_queue;

 K_MUTEX_DEFINE(canopen_send_mutex);
 K_MUTEX_DEFINE(canopen_emcy_mutex);
 K_MUTEX_DEFINE(canopen_co_mutex);

 inline void canopen_send_lock(void)
 {
 	k_mutex_lock(&canopen_send_mutex, K_FOREVER);
 }

 inline void canopen_send_unlock(void)
 {
 	k_mutex_unlock(&canopen_send_mutex);
 }

 inline void canopen_emcy_lock(void)
 {
 	k_mutex_lock(&canopen_emcy_mutex, K_FOREVER);
 }

 inline void canopen_emcy_unlock(void)
 {
 	k_mutex_unlock(&canopen_emcy_mutex);
 }

 inline void canopen_od_lock(void)
 {
 	k_mutex_lock(&canopen_co_mutex, K_FOREVER);
 }

 inline void canopen_od_unlock(void)
 {
 	k_mutex_unlock(&canopen_co_mutex);
 }

 static void canopen_detach_all_rx_filters(CO_CANmodule_t *CANmodule)
 {
 	uint16_t i;

 	if (!CANmodule || !CANmodule->rx_array || !CANmodule->configured) {
 		return;
 	}

 	for (i = 0U; i < CANmodule->rx_size; i++) {
 		if (CANmodule->rx_array[i].filter_id != -ENOSPC) {
 			can_remove_rx_filter(CANmodule->dev,
 					     CANmodule->rx_array[i].filter_id);
 			CANmodule->rx_array[i].filter_id = -ENOSPC;
 		}
 	}
 }

 static void canopen_rx_callback(const struct device *dev, struct zcan_frame *msg, void *arg)
 {
 	CO_CANrx_t *buffer = (CO_CANrx_t *)arg;
 	CO_CANrxMsg_t rxMsg;

 	ARG_UNUSED(dev);

 	if (!buffer || !buffer->pFunct) {
 		LOG_ERR("failed to process CAN rx callback");
 		return;
 	}

 	rxMsg.ident = msg->id;
 	rxMsg.DLC = msg->dlc;
 	memcpy(rxMsg.data, msg->data, msg->dlc);
 	buffer->pFunct(buffer->object, &rxMsg);
 }

 static void canopen_tx_callback(const struct device *dev, int error, void *arg)
 {
 	CO_CANmodule_t *CANmodule = arg;

 	ARG_UNUSED(dev);

 	if (!CANmodule) {
 		LOG_ERR("failed to process CAN tx callback");
 		return;
 	}

 	if (error == 0) {
 		CANmodule->first_tx_msg = false;
 	}

 	k_work_submit_to_queue(&canopen_tx_workq, &canopen_tx_queue.work);
 }

 static void canopen_tx_retry(struct k_work *item)
 {
 	struct canopen_tx_work_container *container =
 		CONTAINER_OF(item, struct canopen_tx_work_container, work);
 	CO_CANmodule_t *CANmodule = container->CANmodule;
 	struct zcan_frame msg;
 	CO_CANtx_t *buffer;
 	int err;
 	uint16_t i;

 	CO_LOCK_CAN_SEND();

 	for (i = 0; i < CANmodule->tx_size; i++) {
 		buffer = &CANmodule->tx_array[i];
 		if (buffer->bufferFull) {
 			msg.id_type = CAN_STANDARD_IDENTIFIER;
 			msg.id = buffer->ident;
 			msg.dlc = buffer->DLC;
 			msg.rtr = (buffer->rtr ? 1 : 0);
 			memcpy(msg.data, buffer->data, buffer->DLC);

 			err = can_send(CANmodule->dev, &msg, K_NO_WAIT,
 				       canopen_tx_callback, CANmodule);
 			if (err == -EAGAIN) {
 				break;
 			} else if (err != 0) {
 				LOG_ERR("failed to send CAN frame (err %d)",
 					err);
 				CO_errorReport(CANmodule->em,
 					       CO_EM_GENERIC_SOFTWARE_ERROR,
 					       CO_EMC_COMMUNICATION, 0);

 			}

 			buffer->bufferFull = false;
 		}
 	}

 	CO_UNLOCK_CAN_SEND();
 }

 void CO_CANsetConfigurationMode(void *CANdriverState)
 {
 	/* No operation */
 }

 void CO_CANsetNormalMode(CO_CANmodule_t *CANmodule)
 {
 	CANmodule->CANnormal = true;
 }

 CO_ReturnError_t CO_CANmodule_init(CO_CANmodule_t *CANmodule,
 				   void *CANdriverState,
 				   CO_CANrx_t rxArray[], uint16_t rxSize,
 				   CO_CANtx_t txArray[], uint16_t txSize,
 				   uint16_t CANbitRate)
 {
 	struct canopen_context *ctx = (struct canopen_context *)CANdriverState;
 	uint16_t i;
 	int err;
 	int max_filters;

 	LOG_DBG("rxSize = %d, txSize = %d", rxSize, txSize);

 	if (!CANmodule || !rxArray || !txArray || !CANdriverState) {
 		LOG_ERR("failed to initialize CAN module");
 		return CO_ERROR_ILLEGAL_ARGUMENT;
 	}

 	max_filters = can_get_max_filters(ctx->dev, CAN_STANDARD_IDENTIFIER);
 	if (max_filters != -ENOSYS) {
 		if (max_filters < 0) {
 			LOG_ERR("unable to determine number of CAN RX filters");
 			return CO_ERROR_SYSCALL;
 		}

 		if (rxSize > max_filters) {
 			LOG_ERR("insufficient number of concurrent CAN RX filters"
 				" (needs %d, %d available)", rxSize, max_filters);
 			return CO_ERROR_OUT_OF_MEMORY;
 		} else if (rxSize < max_filters) {
 			LOG_DBG("excessive number of concurrent CAN RX filters enabled"
 				" (needs %d, %d available)", rxSize, max_filters);
 		}
 	}

 	canopen_detach_all_rx_filters(CANmodule);
 	canopen_tx_queue.CANmodule = CANmodule;

 	CANmodule->dev = ctx->dev;
 	CANmodule->rx_array = rxArray;
 	CANmodule->rx_size = rxSize;
 	CANmodule->tx_array = txArray;
 	CANmodule->tx_size = txSize;
 	CANmodule->CANnormal = false;
 	CANmodule->first_tx_msg = true;
 	CANmodule->errors = 0;
 	CANmodule->em = NULL;

 	for (i = 0U; i < rxSize; i++) {
 		rxArray[i].ident = 0U;
 		rxArray[i].pFunct = NULL;
 		rxArray[i].filter_id = -ENOSPC;
 	}

 	for (i = 0U; i < txSize; i++) {
 		txArray[i].bufferFull = false;
 	}

 	err = can_set_bitrate(CANmodule->dev, KHZ(CANbitRate));
 	if (err) {
 		LOG_ERR("failed to configure CAN bitrate (err %d)", err);
 		return CO_ERROR_ILLEGAL_ARGUMENT;
 	}

 	err = can_set_mode(CANmodule->dev, CAN_MODE_NORMAL);
 	if (err) {
 		LOG_ERR("failed to configure CAN interface (err %d)", err);
 		return CO_ERROR_ILLEGAL_ARGUMENT;
 	}

 	CANmodule->configured = true;

 	return CO_ERROR_NO;
 }

 void CO_CANmodule_disable(CO_CANmodule_t *CANmodule)
 {
 	int err;

 	if (!CANmodule || !CANmodule->dev) {
 		return;
 	}

 	canopen_detach_all_rx_filters(CANmodule);

 	err = can_set_mode(CANmodule->dev, CAN_MODE_LISTENONLY);
 	if (err) {
 		LOG_ERR("failed to disable CAN interface (err %d)", err);
 	}
 }

 uint16_t CO_CANrxMsg_readIdent(const CO_CANrxMsg_t *rxMsg)
 {
 	return rxMsg->ident;
 }

 CO_ReturnError_t CO_CANrxBufferInit(CO_CANmodule_t *CANmodule, uint16_t index,
 				uint16_t ident, uint16_t mask, bool_t rtr,
 				void *object,
 				CO_CANrxBufferCallback_t pFunct)
 {
 	struct zcan_filter filter;
 	CO_CANrx_t *buffer;

 	if (CANmodule == NULL) {
 		return CO_ERROR_ILLEGAL_ARGUMENT;
 	}

 	if (!pFunct || (index >= CANmodule->rx_size)) {
 		LOG_ERR("failed to initialize CAN rx buffer, illegal argument");
 		CO_errorReport(CANmodule->em, CO_EM_GENERIC_SOFTWARE_ERROR,
 			       CO_EMC_SOFTWARE_INTERNAL, 0);
 		return CO_ERROR_ILLEGAL_ARGUMENT;
 	}

 	buffer = &CANmodule->rx_array[index];
 	buffer->object = object;
 	buffer->pFunct = pFunct;

 	filter.id_type = CAN_STANDARD_IDENTIFIER;
 	filter.id = ident;
 	filter.id_mask = mask;
 	filter.rtr = (rtr ? 1 : 0);
 	filter.rtr_mask = 1;

 	if (buffer->filter_id != -ENOSPC) {
 		can_remove_rx_filter(CANmodule->dev, buffer->filter_id);
 	}

 	buffer->filter_id = can_add_rx_filter(CANmodule->dev,
 					      canopen_rx_callback,
 					      buffer, &filter);
 	if (buffer->filter_id == -ENOSPC) {
 		LOG_ERR("failed to add CAN rx callback, no free filter");
 		CO_errorReport(CANmodule->em, CO_EM_MEMORY_ALLOCATION_ERROR,
 			       CO_EMC_SOFTWARE_INTERNAL, 0);
 		return CO_ERROR_OUT_OF_MEMORY;
 	}

 	return CO_ERROR_NO;
 }

 CO_CANtx_t *CO_CANtxBufferInit(CO_CANmodule_t *CANmodule, uint16_t index,
 			       uint16_t ident, bool_t rtr, uint8_t noOfBytes,
 			       bool_t syncFlag)
 {
 	CO_CANtx_t *buffer;

 	if (CANmodule == NULL) {
 		return NULL;
 	}

 	if (index >= CANmodule->tx_size) {
 		LOG_ERR("failed to initialize CAN rx buffer, illegal argument");
 		CO_errorReport(CANmodule->em, CO_EM_GENERIC_SOFTWARE_ERROR,
 			       CO_EMC_SOFTWARE_INTERNAL, 0);
 		return NULL;
 	}

 	buffer = &CANmodule->tx_array[index];
 	buffer->ident = ident;
 	buffer->rtr = rtr;
 	buffer->DLC = noOfBytes;
 	buffer->bufferFull = false;
 	buffer->syncFlag = syncFlag;

 	return buffer;
 }

 CO_ReturnError_t CO_CANsend(CO_CANmodule_t *CANmodule, CO_CANtx_t *buffer)
 {
 	CO_ReturnError_t ret = CO_ERROR_NO;
 	struct zcan_frame msg;
 	int err;

 	if (!CANmodule || !CANmodule->dev || !buffer) {
 		return CO_ERROR_ILLEGAL_ARGUMENT;
 	}

 	CO_LOCK_CAN_SEND();

 	if (buffer->bufferFull) {
 		if (!CANmodule->first_tx_msg) {
 			CO_errorReport(CANmodule->em, CO_EM_CAN_TX_OVERFLOW,
 				       CO_EMC_CAN_OVERRUN, buffer->ident);
 		}
 		buffer->bufferFull = false;
 		ret = CO_ERROR_TX_OVERFLOW;
 	}

 	msg.id_type = CAN_STANDARD_IDENTIFIER;
 	msg.id = buffer->ident;
 	msg.dlc = buffer->DLC;
 	msg.rtr = (buffer->rtr ? 1 : 0);
 	memcpy(msg.data, buffer->data, buffer->DLC);

 	err = can_send(CANmodule->dev, &msg, K_NO_WAIT, canopen_tx_callback,
 		       CANmodule);
 	if (err == -EAGAIN) {
 		buffer->bufferFull = true;
 	} else if (err != 0) {
 		LOG_ERR("failed to send CAN frame (err %d)", err);
 		CO_errorReport(CANmodule->em, CO_EM_GENERIC_SOFTWARE_ERROR,
 			       CO_EMC_COMMUNICATION, 0);
 		ret = CO_ERROR_TX_UNCONFIGURED;
 	}

 	CO_UNLOCK_CAN_SEND();

 	return ret;
 }

 void CO_CANclearPendingSyncPDOs(CO_CANmodule_t *CANmodule)
 {
 	bool_t tpdoDeleted = false;
 	CO_CANtx_t *buffer;
 	uint16_t i;

 	if (!CANmodule) {
 		return;
 	}

 	CO_LOCK_CAN_SEND();

 	for (i = 0; i < CANmodule->tx_size; i++) {
 		buffer = &CANmodule->tx_array[i];
 		if (buffer->bufferFull && buffer->syncFlag) {
 			buffer->bufferFull = false;
 			tpdoDeleted = true;
 		}
 	}

 	CO_UNLOCK_CAN_SEND();

 	if (tpdoDeleted) {
 		CO_errorReport(CANmodule->em, CO_EM_TPDO_OUTSIDE_WINDOW,
 			       CO_EMC_COMMUNICATION, 0);
 	}
 }

 void CO_CANverifyErrors(CO_CANmodule_t *CANmodule)
 {
 	CO_EM_t *em = (CO_EM_t *)CANmodule->em;
 	struct can_bus_err_cnt err_cnt;
 	enum can_state state;
 	uint8_t rx_overflows;
 	uint32_t errors;
 	int err;

 	/*
 	 * TODO: Zephyr lacks an API for reading the rx mailbox
 	 * overflow counter.
 	 */
 	rx_overflows  = 0;

 	err = can_get_state(CANmodule->dev, &state, &err_cnt);
 	if (err != 0) {
 		LOG_ERR("failed to get CAN controller state (err %d)", err);
 		return;
 	}

 	errors = ((uint32_t)err_cnt.tx_err_cnt << 16) |
 		 ((uint32_t)err_cnt.rx_err_cnt << 8) |
 		 rx_overflows;

 	if (errors != CANmodule->errors) {
 		CANmodule->errors = errors;

 		if (state == CAN_BUS_OFF) {
 			/* Bus off */
 			CO_errorReport(em, CO_EM_CAN_TX_BUS_OFF,
 				       CO_EMC_BUS_OFF_RECOVERED, errors);
 		} else {
 			/* Bus not off */
 			CO_errorReset(em, CO_EM_CAN_TX_BUS_OFF, errors);

 			if ((err_cnt.rx_err_cnt >= 96U) ||
 			    (err_cnt.tx_err_cnt >= 96U)) {
 				/* Bus warning */
 				CO_errorReport(em, CO_EM_CAN_BUS_WARNING,
 					       CO_EMC_NO_ERROR, errors);
 			} else {
 				/* Bus not warning */
 				CO_errorReset(em, CO_EM_CAN_BUS_WARNING,
 					      errors);
 			}

 			if (err_cnt.rx_err_cnt >= 128U) {
 				/* Bus rx passive */
 				CO_errorReport(em, CO_EM_CAN_RX_BUS_PASSIVE,
 					       CO_EMC_CAN_PASSIVE, errors);
 			} else {
 				/* Bus not rx passive */
 				CO_errorReset(em, CO_EM_CAN_RX_BUS_PASSIVE,
 					      errors);
 			}

 			if (err_cnt.tx_err_cnt >= 128U &&
 			    !CANmodule->first_tx_msg) {
 				/* Bus tx passive */
 				CO_errorReport(em, CO_EM_CAN_TX_BUS_PASSIVE,
 					       CO_EMC_CAN_PASSIVE, errors);
 			} else if (CO_isError(em, CO_EM_CAN_TX_BUS_PASSIVE)) {
 				/* Bus not tx passive */
 				CO_errorReset(em, CO_EM_CAN_TX_BUS_PASSIVE,
 					      errors);
 				CO_errorReset(em, CO_EM_CAN_TX_OVERFLOW,
 					      errors);
 			}
 		}

 		/* This code can be activated if we can read the overflows*/
 		if (false && rx_overflows != 0U) {
 			CO_errorReport(em, CO_EM_CAN_RXB_OVERFLOW,
 				       CO_EMC_CAN_OVERRUN, errors);
 		}
 	}
 }

 static int canopen_init(const struct device *dev)
 {
 	ARG_UNUSED(dev);

 	k_work_queue_start(&canopen_tx_workq, canopen_tx_workq_stack,
 			   K_KERNEL_STACK_SIZEOF(canopen_tx_workq_stack),
 			   CONFIG_CANOPENNODE_TX_WORKQUEUE_PRIORITY, NULL);

 	k_thread_name_set(&canopen_tx_workq.thread, "canopen_tx_workq");

 	k_work_init(&canopen_tx_queue.work, canopen_tx_retry);

 	return 0;
 }

 SYS_INIT(canopen_init, APPLICATION, CONFIG_KERNEL_INIT_PRIORITY_DEFAULT);
	/*
	* Copyright (c) 2019 Vestas Wind Systems A/S
	*
	* SPDX-License-Identifier: Apache-2.0
	*/

	#include <zephyr/zephyr.h>
	#include <zephyr/drivers/can.h>
	#include <zephyr/init.h>
	#include <zephyr/sys/util.h>

	#include <canopennode.h>

	#define LOG_LEVEL CONFIG_CANOPEN_LOG_LEVEL
	#include <zephyr/logging/log.h>
	LOG_MODULE_REGISTER(canopen_driver);

	K_KERNEL_STACK_DEFINE(canopen_tx_workq_stack,
	CONFIG_CANOPENNODE_TX_WORKQUEUE_STACK_SIZE);

	struct k_work_q canopen_tx_workq;

	struct canopen_tx_work_container {
	struct k_work work;
	CO_CANmodule_t *CANmodule;
	};

	struct canopen_tx_work_container canopen_tx_queue;

	K_MUTEX_DEFINE(canopen_send_mutex);
	K_MUTEX_DEFINE(canopen_emcy_mutex);
	K_MUTEX_DEFINE(canopen_co_mutex);

	inline void canopen_send_lock(void)
	{
	k_mutex_lock(&canopen_send_mutex, K_FOREVER);
	}

	inline void canopen_send_unlock(void)
	{
	k_mutex_unlock(&canopen_send_mutex);
	}

	inline void canopen_emcy_lock(void)
	{
	k_mutex_lock(&canopen_emcy_mutex, K_FOREVER);
	}

	inline void canopen_emcy_unlock(void)
	{
	k_mutex_unlock(&canopen_emcy_mutex);
	}

	inline void canopen_od_lock(void)
	{
	k_mutex_lock(&canopen_co_mutex, K_FOREVER);
	}

	inline void canopen_od_unlock(void)
	{
	k_mutex_unlock(&canopen_co_mutex);
	}

	static void canopen_detach_all_rx_filters(CO_CANmodule_t *CANmodule)
	{
	uint16_t i;

	if (!CANmodule \|\| !CANmodule->rx_array \|\| !CANmodule->configured) {
	return;
	}

	for (i = 0U; i < CANmodule->rx_size; i++) {
	if (CANmodule->rx_array[i].filter_id != -ENOSPC) {
	can_remove_rx_filter(CANmodule->dev,
	CANmodule->rx_array[i].filter_id);
	CANmodule->rx_array[i].filter_id = -ENOSPC;
	}
	}
	}

	static void canopen_rx_callback(const struct device dev, struct zcan_frame msg, void *arg)
	{
	CO_CANrx_t buffer = (CO_CANrx_t )arg;
	CO_CANrxMsg_t rxMsg;

	ARG_UNUSED(dev);

	if (!buffer \|\| !buffer->pFunct) {
	LOG_ERR("failed to process CAN rx callback");
	return;
	}

	rxMsg.ident = msg->id;
	rxMsg.DLC = msg->dlc;
	memcpy(rxMsg.data, msg->data, msg->dlc);
	buffer->pFunct(buffer->object, &rxMsg);
	}

	static void canopen_tx_callback(const struct device dev, int error, void arg)
	{
	CO_CANmodule_t *CANmodule = arg;

	ARG_UNUSED(dev);

	if (!CANmodule) {
	LOG_ERR("failed to process CAN tx callback");
	return;
	}

	if (error == 0) {
	CANmodule->first_tx_msg = false;
	}

	k_work_submit_to_queue(&canopen_tx_workq, &canopen_tx_queue.work);
	}

	static void canopen_tx_retry(struct k_work *item)
	{
	struct canopen_tx_work_container *container =
	CONTAINER_OF(item, struct canopen_tx_work_container, work);
	CO_CANmodule_t *CANmodule = container->CANmodule;
	struct zcan_frame msg;
	CO_CANtx_t *buffer;
	int err;
	uint16_t i;

	CO_LOCK_CAN_SEND();

	for (i = 0; i < CANmodule->tx_size; i++) {
	buffer = &CANmodule->tx_array[i];
	if (buffer->bufferFull) {
	msg.id_type = CAN_STANDARD_IDENTIFIER;
	msg.id = buffer->ident;
	msg.dlc = buffer->DLC;
	msg.rtr = (buffer->rtr ? 1 : 0);
	memcpy(msg.data, buffer->data, buffer->DLC);

	err = can_send(CANmodule->dev, &msg, K_NO_WAIT,
	canopen_tx_callback, CANmodule);
	if (err == -EAGAIN) {
	break;
	} else if (err != 0) {
	LOG_ERR("failed to send CAN frame (err %d)",
	err);
	CO_errorReport(CANmodule->em,
	CO_EM_GENERIC_SOFTWARE_ERROR,
	CO_EMC_COMMUNICATION, 0);

	}

	buffer->bufferFull = false;
	}
	}

	CO_UNLOCK_CAN_SEND();
	}

	void CO_CANsetConfigurationMode(void *CANdriverState)
	{
	/* No operation */
	}

	void CO_CANsetNormalMode(CO_CANmodule_t *CANmodule)
	{
	CANmodule->CANnormal = true;
	}

	CO_ReturnError_t CO_CANmodule_init(CO_CANmodule_t *CANmodule,
	void *CANdriverState,
	CO_CANrx_t rxArray[], uint16_t rxSize,
	CO_CANtx_t txArray[], uint16_t txSize,
	uint16_t CANbitRate)
	{
	struct canopen_context ctx = (struct canopen_context )CANdriverState;
	uint16_t i;
	int err;
	int max_filters;

	LOG_DBG("rxSize = %d, txSize = %d", rxSize, txSize);

	if (!CANmodule \|\| !rxArray \|\| !txArray \|\| !CANdriverState) {
	LOG_ERR("failed to initialize CAN module");
	return CO_ERROR_ILLEGAL_ARGUMENT;
	}

	max_filters = can_get_max_filters(ctx->dev, CAN_STANDARD_IDENTIFIER);
	if (max_filters != -ENOSYS) {
	if (max_filters < 0) {
	LOG_ERR("unable to determine number of CAN RX filters");
	return CO_ERROR_SYSCALL;
	}

	if (rxSize > max_filters) {
	LOG_ERR("insufficient number of concurrent CAN RX filters"
	" (needs %d, %d available)", rxSize, max_filters);
	return CO_ERROR_OUT_OF_MEMORY;
	} else if (rxSize < max_filters) {
	LOG_DBG("excessive number of concurrent CAN RX filters enabled"
	" (needs %d, %d available)", rxSize, max_filters);
	}
	}

	canopen_detach_all_rx_filters(CANmodule);
	canopen_tx_queue.CANmodule = CANmodule;

	CANmodule->dev = ctx->dev;
	CANmodule->rx_array = rxArray;
	CANmodule->rx_size = rxSize;
	CANmodule->tx_array = txArray;
	CANmodule->tx_size = txSize;
	CANmodule->CANnormal = false;
	CANmodule->first_tx_msg = true;
	CANmodule->errors = 0;
	CANmodule->em = NULL;

	for (i = 0U; i < rxSize; i++) {
	rxArray[i].ident = 0U;
	rxArray[i].pFunct = NULL;
	rxArray[i].filter_id = -ENOSPC;
	}

	for (i = 0U; i < txSize; i++) {
	txArray[i].bufferFull = false;
	}

	err = can_set_bitrate(CANmodule->dev, KHZ(CANbitRate));
	if (err) {
	LOG_ERR("failed to configure CAN bitrate (err %d)", err);
	return CO_ERROR_ILLEGAL_ARGUMENT;
	}

	err = can_set_mode(CANmodule->dev, CAN_MODE_NORMAL);
	if (err) {
	LOG_ERR("failed to configure CAN interface (err %d)", err);
	return CO_ERROR_ILLEGAL_ARGUMENT;
	}

	CANmodule->configured = true;

	return CO_ERROR_NO;
	}

	void CO_CANmodule_disable(CO_CANmodule_t *CANmodule)
	{
	int err;

	if (!CANmodule \|\| !CANmodule->dev) {
	return;
	}

	canopen_detach_all_rx_filters(CANmodule);

	err = can_set_mode(CANmodule->dev, CAN_MODE_LISTENONLY);
	if (err) {
	LOG_ERR("failed to disable CAN interface (err %d)", err);
	}
	}

	uint16_t CO_CANrxMsg_readIdent(const CO_CANrxMsg_t *rxMsg)
	{
	return rxMsg->ident;
	}

	CO_ReturnError_t CO_CANrxBufferInit(CO_CANmodule_t *CANmodule, uint16_t index,
	uint16_t ident, uint16_t mask, bool_t rtr,
	void *object,
	CO_CANrxBufferCallback_t pFunct)
	{
	struct zcan_filter filter;
	CO_CANrx_t *buffer;

	if (CANmodule == NULL) {
	return CO_ERROR_ILLEGAL_ARGUMENT;
	}

	if (!pFunct \|\| (index >= CANmodule->rx_size)) {
	LOG_ERR("failed to initialize CAN rx buffer, illegal argument");
	CO_errorReport(CANmodule->em, CO_EM_GENERIC_SOFTWARE_ERROR,
	CO_EMC_SOFTWARE_INTERNAL, 0);
	return CO_ERROR_ILLEGAL_ARGUMENT;
	}

	buffer = &CANmodule->rx_array[index];
	buffer->object = object;
	buffer->pFunct = pFunct;

	filter.id_type = CAN_STANDARD_IDENTIFIER;
	filter.id = ident;
	filter.id_mask = mask;
	filter.rtr = (rtr ? 1 : 0);
	filter.rtr_mask = 1;

	if (buffer->filter_id != -ENOSPC) {
	can_remove_rx_filter(CANmodule->dev, buffer->filter_id);
	}

	buffer->filter_id = can_add_rx_filter(CANmodule->dev,
	canopen_rx_callback,
	buffer, &filter);
	if (buffer->filter_id == -ENOSPC) {
	LOG_ERR("failed to add CAN rx callback, no free filter");
	CO_errorReport(CANmodule->em, CO_EM_MEMORY_ALLOCATION_ERROR,
	CO_EMC_SOFTWARE_INTERNAL, 0);
	return CO_ERROR_OUT_OF_MEMORY;
	}

	return CO_ERROR_NO;
	}

	CO_CANtx_t CO_CANtxBufferInit(CO_CANmodule_t CANmodule, uint16_t index,
	uint16_t ident, bool_t rtr, uint8_t noOfBytes,
	bool_t syncFlag)
	{
	CO_CANtx_t *buffer;

	if (CANmodule == NULL) {
	return NULL;
	}

	if (index >= CANmodule->tx_size) {
	LOG_ERR("failed to initialize CAN rx buffer, illegal argument");
	CO_errorReport(CANmodule->em, CO_EM_GENERIC_SOFTWARE_ERROR,
	CO_EMC_SOFTWARE_INTERNAL, 0);
	return NULL;
	}

	buffer = &CANmodule->tx_array[index];
	buffer->ident = ident;
	buffer->rtr = rtr;
	buffer->DLC = noOfBytes;
	buffer->bufferFull = false;
	buffer->syncFlag = syncFlag;

	return buffer;
	}

	CO_ReturnError_t CO_CANsend(CO_CANmodule_t CANmodule, CO_CANtx_t buffer)
	{
	CO_ReturnError_t ret = CO_ERROR_NO;
	struct zcan_frame msg;
	int err;

	if (!CANmodule \|\| !CANmodule->dev \|\| !buffer) {
	return CO_ERROR_ILLEGAL_ARGUMENT;
	}

	CO_LOCK_CAN_SEND();

	if (buffer->bufferFull) {
	if (!CANmodule->first_tx_msg) {
	CO_errorReport(CANmodule->em, CO_EM_CAN_TX_OVERFLOW,
	CO_EMC_CAN_OVERRUN, buffer->ident);
	}
	buffer->bufferFull = false;
	ret = CO_ERROR_TX_OVERFLOW;
	}

	msg.id_type = CAN_STANDARD_IDENTIFIER;
	msg.id = buffer->ident;
	msg.dlc = buffer->DLC;
	msg.rtr = (buffer->rtr ? 1 : 0);
	memcpy(msg.data, buffer->data, buffer->DLC);

	err = can_send(CANmodule->dev, &msg, K_NO_WAIT, canopen_tx_callback,
	CANmodule);
	if (err == -EAGAIN) {
	buffer->bufferFull = true;
	} else if (err != 0) {
	LOG_ERR("failed to send CAN frame (err %d)", err);
	CO_errorReport(CANmodule->em, CO_EM_GENERIC_SOFTWARE_ERROR,
	CO_EMC_COMMUNICATION, 0);
	ret = CO_ERROR_TX_UNCONFIGURED;
	}

	CO_UNLOCK_CAN_SEND();

	return ret;
	}

	void CO_CANclearPendingSyncPDOs(CO_CANmodule_t *CANmodule)
	{
	bool_t tpdoDeleted = false;
	CO_CANtx_t *buffer;
	uint16_t i;

	if (!CANmodule) {
	return;
	}

	CO_LOCK_CAN_SEND();

	for (i = 0; i < CANmodule->tx_size; i++) {
	buffer = &CANmodule->tx_array[i];
	if (buffer->bufferFull && buffer->syncFlag) {
	buffer->bufferFull = false;
	tpdoDeleted = true;
	}
	}

	CO_UNLOCK_CAN_SEND();

	if (tpdoDeleted) {
	CO_errorReport(CANmodule->em, CO_EM_TPDO_OUTSIDE_WINDOW,
	CO_EMC_COMMUNICATION, 0);
	}
	}

	void CO_CANverifyErrors(CO_CANmodule_t *CANmodule)
	{
	CO_EM_t em = (CO_EM_t )CANmodule->em;
	struct can_bus_err_cnt err_cnt;
	enum can_state state;
	uint8_t rx_overflows;
	uint32_t errors;
	int err;

	/*
	* TODO: Zephyr lacks an API for reading the rx mailbox
	* overflow counter.
	*/
	rx_overflows = 0;

	err = can_get_state(CANmodule->dev, &state, &err_cnt);
	if (err != 0) {
	LOG_ERR("failed to get CAN controller state (err %d)", err);
	return;
	}

	errors = ((uint32_t)err_cnt.tx_err_cnt << 16) \|
	((uint32_t)err_cnt.rx_err_cnt << 8) \|
	rx_overflows;

	if (errors != CANmodule->errors) {
	CANmodule->errors = errors;

	if (state == CAN_BUS_OFF) {
	/* Bus off */
	CO_errorReport(em, CO_EM_CAN_TX_BUS_OFF,
	CO_EMC_BUS_OFF_RECOVERED, errors);
	} else {
	/* Bus not off */
	CO_errorReset(em, CO_EM_CAN_TX_BUS_OFF, errors);

	if ((err_cnt.rx_err_cnt >= 96U) \|\|
	(err_cnt.tx_err_cnt >= 96U)) {
	/* Bus warning */
	CO_errorReport(em, CO_EM_CAN_BUS_WARNING,
	CO_EMC_NO_ERROR, errors);
	} else {
	/* Bus not warning */
	CO_errorReset(em, CO_EM_CAN_BUS_WARNING,
	errors);
	}

	if (err_cnt.rx_err_cnt >= 128U) {
	/* Bus rx passive */
	CO_errorReport(em, CO_EM_CAN_RX_BUS_PASSIVE,
	CO_EMC_CAN_PASSIVE, errors);
	} else {
	/* Bus not rx passive */
	CO_errorReset(em, CO_EM_CAN_RX_BUS_PASSIVE,
	errors);
	}

	if (err_cnt.tx_err_cnt >= 128U &&
	!CANmodule->first_tx_msg) {
	/* Bus tx passive */
	CO_errorReport(em, CO_EM_CAN_TX_BUS_PASSIVE,
	CO_EMC_CAN_PASSIVE, errors);
	} else if (CO_isError(em, CO_EM_CAN_TX_BUS_PASSIVE)) {
	/* Bus not tx passive */
	CO_errorReset(em, CO_EM_CAN_TX_BUS_PASSIVE,
	errors);
	CO_errorReset(em, CO_EM_CAN_TX_OVERFLOW,
	errors);
	}
	}

	/* This code can be activated if we can read the overflows*/
	if (false && rx_overflows != 0U) {
	CO_errorReport(em, CO_EM_CAN_RXB_OVERFLOW,
	CO_EMC_CAN_OVERRUN, errors);
	}
	}
	}

	static int canopen_init(const struct device *dev)
	{
	ARG_UNUSED(dev);

	k_work_queue_start(&canopen_tx_workq, canopen_tx_workq_stack,
	K_KERNEL_STACK_SIZEOF(canopen_tx_workq_stack),
	CONFIG_CANOPENNODE_TX_WORKQUEUE_PRIORITY, NULL);

	k_thread_name_set(&canopen_tx_workq.thread, "canopen_tx_workq");

	k_work_init(&canopen_tx_queue.work, canopen_tx_retry);

	return 0;
	}

	SYS_INIT(canopen_init, APPLICATION, CONFIG_KERNEL_INIT_PRIORITY_DEFAULT);