drivers/can/can_mcan.h - third_party/github/zephyrproject-rtos/zephyr - Git at Google

 /*
  * Copyright (c) 2020 Alexander Wachter
  *
  * SPDX-License-Identifier: Apache-2.0
  *
  */

 #ifndef ZEPHYR_DRIVERS_CAN_MCAN_H_
 #define ZEPHYR_DRIVERS_CAN_MCAN_H_

 #include <zephyr/kernel.h>
 #include <zephyr/devicetree.h>
 #include <zephyr/drivers/can.h>

 #include <zephyr/toolchain.h>
 #include <stdint.h>

 #ifdef CONFIG_CAN_MCUX_MCAN
 #define MCAN_DT_PATH DT_NODELABEL(can0)
 #else
 #define MCAN_DT_PATH DT_PATH(soc, can)
 #endif

 #define NUM_STD_FILTER_ELEMENTS DT_PROP(MCAN_DT_PATH, std_filter_elements)
 #define NUM_EXT_FILTER_ELEMENTS DT_PROP(MCAN_DT_PATH, ext_filter_elements)
 #define NUM_RX_FIFO0_ELEMENTS   DT_PROP(MCAN_DT_PATH, rx_fifo0_elements)
 #define NUM_RX_FIFO1_ELEMENTS   DT_PROP(MCAN_DT_PATH, rx_fifo0_elements)
 #define NUM_RX_BUF_ELEMENTS     DT_PROP(MCAN_DT_PATH, rx_buffer_elements)
 #define NUM_TX_BUF_ELEMENTS     DT_PROP(MCAN_DT_PATH, tx_buffer_elements)

 #ifdef CONFIG_CAN_STM32FD
 #define NUM_STD_FILTER_DATA CONFIG_CAN_MAX_STD_ID_FILTER
 #define NUM_EXT_FILTER_DATA CONFIG_CAN_MAX_EXT_ID_FILTER
 #else
 #define NUM_STD_FILTER_DATA NUM_STD_FILTER_ELEMENTS
 #define NUM_EXT_FILTER_DATA NUM_EXT_FILTER_ELEMENTS
 #endif

 struct can_mcan_rx_fifo_hdr {
 	union {
 		struct {
 			volatile uint32_t ext_id : 29; /* Extended Identifier */
 			volatile uint32_t rtr    :  1; /* Remote Transmission Request*/
 			volatile uint32_t xtd    :  1; /* Extended identifier */
 			volatile uint32_t esi    :  1; /* Error state indicator */
 		};
 		struct {
 			volatile uint32_t pad1   : 18;
 			volatile uint32_t std_id : 11; /* Standard Identifier */
 			volatile uint32_t pad2   : 3;
 		};
 	};

 	volatile uint32_t rxts : 16; /* Rx timestamp */
 	volatile uint32_t dlc  :  4; /* Data Length Code */
 	volatile uint32_t brs  :  1; /* Bit Rate Switch */
 	volatile uint32_t fdf  :  1; /* FD Format */
 	volatile uint32_t res  :  2; /* Reserved */
 	volatile uint32_t fidx :  7; /* Filter Index */
 	volatile uint32_t anmf :  1; /* Accepted non-matching frame */
 } __packed __aligned(4);

 struct can_mcan_rx_fifo {
 	struct can_mcan_rx_fifo_hdr hdr;
 	union {
 		volatile uint8_t  data[64];
 		volatile uint32_t data_32[16];
 	};
 } __packed __aligned(4);

 struct can_mcan_mm {
 	volatile uint8_t idx : 5;
 	volatile uint8_t cnt : 3;
 } __packed;

 struct can_mcan_tx_buffer_hdr {
 	union {
 		struct {
 			volatile uint32_t ext_id : 29; /* Identifier */
 			volatile uint32_t rtr    :  1; /* Remote Transmission Request*/
 			volatile uint32_t xtd    :  1; /* Extended identifier */
 			volatile uint32_t esi    :  1; /* Error state indicator */
 		};
 		struct {
 			volatile uint32_t pad1   : 18;
 			volatile uint32_t std_id : 11; /* Identifier */
 			volatile uint32_t pad2   :  3;
 		};
 	};
 	volatile uint16_t res1;      /* Reserved */
 	volatile uint8_t dlc  :  4; /* Data Length Code */
 	volatile uint8_t brs  :  1; /* Bit Rate Switch */
 	volatile uint8_t fdf  :  1; /* FD Format */
 	volatile uint8_t res2 :  1; /* Reserved */
 	volatile uint8_t efc  :  1; /* Event FIFO control (Store Tx events) */
 	struct can_mcan_mm mm; /* Message marker */
 } __packed __aligned(4);

 struct can_mcan_tx_buffer {
 	struct can_mcan_tx_buffer_hdr hdr;
 	union {
 		volatile uint8_t  data[64];
 		volatile uint32_t data_32[16];
 	};
 } __packed __aligned(4);

 #define CAN_MCAN_TE_TX    0x1 /* TX event */
 #define CAN_MCAN_TE_TXC   0x2 /* TX event in spite of cancellation */

 struct can_mcan_tx_event_fifo {
 	volatile uint32_t id   : 29; /* Identifier */
 	volatile uint32_t rtr  :  1; /* Remote Transmission Request*/
 	volatile uint32_t xtd  :  1; /* Extended identifier */
 	volatile uint32_t esi  :  1; /* Error state indicator */

 	volatile uint16_t txts;      /* TX Timestamp */
 	volatile uint8_t dlc   :  4; /* Data Length Code */
 	volatile uint8_t brs   :  1; /* Bit Rate Switch */
 	volatile uint8_t fdf   :  1; /* FD Format */
 	volatile uint8_t et    :  2; /* Event type */
 	struct can_mcan_mm mm; /* Message marker */
 } __packed __aligned(4);

 #define CAN_MCAN_FCE_DISABLE    0x0
 #define CAN_MCAN_FCE_FIFO0      0x1
 #define CAN_MCAN_FCE_FIFO1      0x2
 #define CAN_MCAN_FCE_REJECT     0x3
 #define CAN_MCAN_FCE_PRIO       0x4
 #define CAN_MCAN_FCE_PRIO_FIFO0 0x5
 #define CAN_MCAN_FCE_PRIO_FIFO1 0x7

 #define CAN_MCAN_SFT_RANGE       0x0
 #define CAN_MCAN_SFT_DUAL        0x1
 #define CAN_MCAN_SFT_MASKED      0x2
 #define CAN_MCAN_SFT_DISABLED    0x3

 struct can_mcan_std_filter {
 	volatile uint32_t id2  : 11; /* ID2 for dual or range, mask otherwise */
 	volatile uint32_t res  :  5;
 	volatile uint32_t id1  : 11;
 	volatile uint32_t sfce :  3; /* Filter config */
 	volatile uint32_t sft  :  2; /* Filter type */
 } __packed __aligned(4);

 #define CAN_MCAN_EFT_RANGE_XIDAM 0x0
 #define CAN_MCAN_EFT_DUAL        0x1
 #define CAN_MCAN_EFT_MASKED      0x2
 #define CAN_MCAN_EFT_RANGE       0x3

 struct can_mcan_ext_filter {
 	volatile uint32_t id1  : 29;
 	volatile uint32_t efce :  3; /* Filter config */
 	volatile uint32_t id2  : 29; /* ID2 for dual or range, mask otherwise */
 	volatile uint32_t res  :  1;
 	volatile uint32_t eft   : 2; /* Filter type */
 } __packed __aligned(4);

 struct can_mcan_msg_sram {
 	volatile struct can_mcan_std_filter std_filt[NUM_STD_FILTER_ELEMENTS];
 	volatile struct can_mcan_ext_filter ext_filt[NUM_EXT_FILTER_ELEMENTS];
 	volatile struct can_mcan_rx_fifo rx_fifo0[NUM_RX_FIFO0_ELEMENTS];
 	volatile struct can_mcan_rx_fifo rx_fifo1[NUM_RX_FIFO1_ELEMENTS];
 	volatile struct can_mcan_rx_fifo rx_buffer[NUM_RX_BUF_ELEMENTS];
 	volatile struct can_mcan_tx_event_fifo tx_event_fifo[NUM_TX_BUF_ELEMENTS];
 	volatile struct can_mcan_tx_buffer tx_buffer[NUM_TX_BUF_ELEMENTS];
 } __packed __aligned(4);

 struct can_mcan_data {
 	struct can_mcan_msg_sram *msg_ram;
 	struct k_mutex inst_mutex;
 	struct k_sem tx_sem;
 	struct k_mutex tx_mtx;
 	struct k_sem tx_fin_sem[NUM_TX_BUF_ELEMENTS];
 	can_tx_callback_t tx_fin_cb[NUM_TX_BUF_ELEMENTS];
 	void *tx_fin_cb_arg[NUM_TX_BUF_ELEMENTS];
 	can_rx_callback_t rx_cb_std[NUM_STD_FILTER_DATA];
 	can_rx_callback_t rx_cb_ext[NUM_EXT_FILTER_DATA];
 	void *cb_arg_std[NUM_STD_FILTER_DATA];
 	void *cb_arg_ext[NUM_EXT_FILTER_DATA];
 	can_state_change_callback_t state_change_cb;
 	void *state_change_cb_data;
 	uint32_t std_filt_rtr;
 	uint32_t std_filt_rtr_mask;
 	uint8_t ext_filt_rtr;
 	uint8_t ext_filt_rtr_mask;
 	struct can_mcan_mm mm;
 	void *custom;
 } __aligned(4);

 struct can_mcan_config {
 	struct can_mcan_reg *can;   /*!< CAN Registers*/
 	uint32_t bus_speed;
 	uint32_t bus_speed_data;
 	uint16_t sjw;
 	uint16_t sample_point;
 	uint16_t prop_ts1;
 	uint16_t ts2;
 #ifdef CONFIG_CAN_FD_MODE
 	uint16_t sample_point_data;
 	uint8_t sjw_data;
 	uint8_t prop_ts1_data;
 	uint8_t ts2_data;
 	uint8_t tx_delay_comp_offset;
 #endif
 	const struct device *phy;
 	uint32_t max_bitrate;
 	const void *custom;
 };

 struct can_mcan_reg;

 #ifdef CONFIG_CAN_FD_MODE
 #define CAN_MCAN_DT_CONFIG_GET(node_id, _custom_config)				\
 	{									\
 		.can = (struct can_mcan_reg *)DT_REG_ADDR_BY_NAME(node_id, m_can), \
 		.bus_speed = DT_PROP(node_id, bus_speed),			\
 		.sjw = DT_PROP(node_id, sjw),					\
 		.sample_point = DT_PROP_OR(node_id, sample_point, 0),		\
 		.prop_ts1 = DT_PROP_OR(node_id, prop_seg, 0) +			\
 			DT_PROP_OR(node_id, phase_seg1, 0),			\
 		.ts2 = DT_PROP_OR(node_id, phase_seg2, 0),			\
 		.bus_speed_data = DT_PROP(node_id, bus_speed_data),		\
 		.sjw_data = DT_PROP(node_id, sjw_data),				\
 		.sample_point_data =						\
 			DT_PROP_OR(node_id, sample_point_data, 0),		\
 		.prop_ts1_data = DT_PROP_OR(node_id, prop_seg_data, 0) +	\
 			DT_PROP_OR(node_id, phase_seg1_data, 0),		\
 		.ts2_data = DT_PROP_OR(node_id, phase_seg2_data, 0),		\
 		.tx_delay_comp_offset =						\
 			DT_PROP(node_id, tx_delay_comp_offset),			\
 		.phy = DEVICE_DT_GET_OR_NULL(DT_PHANDLE(node_id, phys)),	\
 		.max_bitrate = DT_CAN_TRANSCEIVER_MAX_BITRATE(node_id, 8000000),\
 		.custom = _custom_config,					\
 	}
 #else /* CONFIG_CAN_FD_MODE */
 #define CAN_MCAN_DT_CONFIG_GET(node_id, _custom_config)				\
 	{									\
 		.can = (struct can_mcan_reg *)DT_REG_ADDR_BY_NAME(node_id, m_can), \
 		.bus_speed = DT_PROP(node_id, bus_speed),			\
 		.sjw = DT_PROP(node_id, sjw),					\
 		.sample_point = DT_PROP_OR(node_id, sample_point, 0),		\
 		.prop_ts1 = DT_PROP_OR(node_id, prop_seg, 0) +			\
 			DT_PROP_OR(node_id, phase_seg1, 0),			\
 		.ts2 = DT_PROP_OR(node_id, phase_seg2, 0),			\
 		.phy = DEVICE_DT_GET_OR_NULL(DT_PHANDLE(node_id, phys)),	\
 		.max_bitrate = DT_CAN_TRANSCEIVER_MAX_BITRATE(node_id, 1000000),\
 		.custom = _custom_config,					\
 	}
 #endif /* !CONFIG_CAN_FD_MODE */

 #define CAN_MCAN_DT_CONFIG_INST_GET(inst, _custom_config)		\
 	CAN_MCAN_DT_CONFIG_GET(DT_DRV_INST(inst), _custom_config)

 #define CAN_MCAN_DATA_INITIALIZER(_msg_ram, _custom_data)		\
 	{								\
 		.msg_ram = _msg_ram,					\
 		.custom = _custom_data,					\
 	}

 int can_mcan_get_capabilities(const struct device *dev, can_mode_t *cap);

 int can_mcan_set_mode(const struct device *dev, can_mode_t mode);

 int can_mcan_set_timing(const struct device *dev,
 			const struct can_timing *timing);

 int can_mcan_set_timing_data(const struct device *dev,
 			     const struct can_timing *timing_data);

 int can_mcan_init(const struct device *dev);

 void can_mcan_line_0_isr(const struct device *dev);

 void can_mcan_line_1_isr(const struct device *dev);

 int can_mcan_recover(const struct device *dev, k_timeout_t timeout);

 int can_mcan_send(const struct device *dev, const struct zcan_frame *frame,
 		  k_timeout_t timeout, can_tx_callback_t callback,
 		  void *user_data);

 int can_mcan_get_max_filters(const struct device *dev, enum can_ide id_type);

 int can_mcan_add_rx_filter(const struct device *dev,
 			   can_rx_callback_t callback, void *user_data,
 			   const struct zcan_filter *filter);

 void can_mcan_remove_rx_filter(const struct device *dev, int filter_id);

 int can_mcan_get_state(const struct device *dev, enum can_state *state,
 		       struct can_bus_err_cnt *err_cnt);

 void can_mcan_set_state_change_callback(const struct device *dev,
 					can_state_change_callback_t callback,
 					void *user_data);

 int can_mcan_get_max_bitrate(const struct device *dev, uint32_t *max_bitrate);

 #endif /* ZEPHYR_DRIVERS_CAN_MCAN_H_ */
	/*
	* Copyright (c) 2020 Alexander Wachter
	*
	* SPDX-License-Identifier: Apache-2.0
	*
	*/

	#ifndef ZEPHYR_DRIVERS_CAN_MCAN_H_
	#define ZEPHYR_DRIVERS_CAN_MCAN_H_

	#include <zephyr/kernel.h>
	#include <zephyr/devicetree.h>
	#include <zephyr/drivers/can.h>

	#include <zephyr/toolchain.h>
	#include <stdint.h>

	#ifdef CONFIG_CAN_MCUX_MCAN
	#define MCAN_DT_PATH DT_NODELABEL(can0)
	#else
	#define MCAN_DT_PATH DT_PATH(soc, can)
	#endif

	#define NUM_STD_FILTER_ELEMENTS DT_PROP(MCAN_DT_PATH, std_filter_elements)
	#define NUM_EXT_FILTER_ELEMENTS DT_PROP(MCAN_DT_PATH, ext_filter_elements)
	#define NUM_RX_FIFO0_ELEMENTS DT_PROP(MCAN_DT_PATH, rx_fifo0_elements)
	#define NUM_RX_FIFO1_ELEMENTS DT_PROP(MCAN_DT_PATH, rx_fifo0_elements)
	#define NUM_RX_BUF_ELEMENTS DT_PROP(MCAN_DT_PATH, rx_buffer_elements)
	#define NUM_TX_BUF_ELEMENTS DT_PROP(MCAN_DT_PATH, tx_buffer_elements)

	#ifdef CONFIG_CAN_STM32FD
	#define NUM_STD_FILTER_DATA CONFIG_CAN_MAX_STD_ID_FILTER
	#define NUM_EXT_FILTER_DATA CONFIG_CAN_MAX_EXT_ID_FILTER
	#else
	#define NUM_STD_FILTER_DATA NUM_STD_FILTER_ELEMENTS
	#define NUM_EXT_FILTER_DATA NUM_EXT_FILTER_ELEMENTS
	#endif

	struct can_mcan_rx_fifo_hdr {
	union {
	struct {
	volatile uint32_t ext_id : 29; /* Extended Identifier */
	volatile uint32_t rtr : 1; /* Remote Transmission Request*/
	volatile uint32_t xtd : 1; /* Extended identifier */
	volatile uint32_t esi : 1; /* Error state indicator */
	};
	struct {
	volatile uint32_t pad1 : 18;
	volatile uint32_t std_id : 11; /* Standard Identifier */
	volatile uint32_t pad2 : 3;
	};
	};

	volatile uint32_t rxts : 16; /* Rx timestamp */
	volatile uint32_t dlc : 4; /* Data Length Code */
	volatile uint32_t brs : 1; /* Bit Rate Switch */
	volatile uint32_t fdf : 1; /* FD Format */
	volatile uint32_t res : 2; /* Reserved */
	volatile uint32_t fidx : 7; /* Filter Index */
	volatile uint32_t anmf : 1; /* Accepted non-matching frame */
	} __packed __aligned(4);

	struct can_mcan_rx_fifo {
	struct can_mcan_rx_fifo_hdr hdr;
	union {
	volatile uint8_t data[64];
	volatile uint32_t data_32[16];
	};
	} __packed __aligned(4);

	struct can_mcan_mm {
	volatile uint8_t idx : 5;
	volatile uint8_t cnt : 3;
	} __packed;

	struct can_mcan_tx_buffer_hdr {
	union {
	struct {
	volatile uint32_t ext_id : 29; /* Identifier */
	volatile uint32_t rtr : 1; /* Remote Transmission Request*/
	volatile uint32_t xtd : 1; /* Extended identifier */
	volatile uint32_t esi : 1; /* Error state indicator */
	};
	struct {
	volatile uint32_t pad1 : 18;
	volatile uint32_t std_id : 11; /* Identifier */
	volatile uint32_t pad2 : 3;
	};
	};
	volatile uint16_t res1; /* Reserved */
	volatile uint8_t dlc : 4; /* Data Length Code */
	volatile uint8_t brs : 1; /* Bit Rate Switch */
	volatile uint8_t fdf : 1; /* FD Format */
	volatile uint8_t res2 : 1; /* Reserved */
	volatile uint8_t efc : 1; /* Event FIFO control (Store Tx events) */
	struct can_mcan_mm mm; /* Message marker */
	} __packed __aligned(4);

	struct can_mcan_tx_buffer {
	struct can_mcan_tx_buffer_hdr hdr;
	union {
	volatile uint8_t data[64];
	volatile uint32_t data_32[16];
	};
	} __packed __aligned(4);

	#define CAN_MCAN_TE_TX 0x1 /* TX event */
	#define CAN_MCAN_TE_TXC 0x2 /* TX event in spite of cancellation */

	struct can_mcan_tx_event_fifo {
	volatile uint32_t id : 29; /* Identifier */
	volatile uint32_t rtr : 1; /* Remote Transmission Request*/
	volatile uint32_t xtd : 1; /* Extended identifier */
	volatile uint32_t esi : 1; /* Error state indicator */

	volatile uint16_t txts; /* TX Timestamp */
	volatile uint8_t dlc : 4; /* Data Length Code */
	volatile uint8_t brs : 1; /* Bit Rate Switch */
	volatile uint8_t fdf : 1; /* FD Format */
	volatile uint8_t et : 2; /* Event type */
	struct can_mcan_mm mm; /* Message marker */
	} __packed __aligned(4);

	#define CAN_MCAN_FCE_DISABLE 0x0
	#define CAN_MCAN_FCE_FIFO0 0x1
	#define CAN_MCAN_FCE_FIFO1 0x2
	#define CAN_MCAN_FCE_REJECT 0x3
	#define CAN_MCAN_FCE_PRIO 0x4
	#define CAN_MCAN_FCE_PRIO_FIFO0 0x5
	#define CAN_MCAN_FCE_PRIO_FIFO1 0x7

	#define CAN_MCAN_SFT_RANGE 0x0
	#define CAN_MCAN_SFT_DUAL 0x1
	#define CAN_MCAN_SFT_MASKED 0x2
	#define CAN_MCAN_SFT_DISABLED 0x3

	struct can_mcan_std_filter {
	volatile uint32_t id2 : 11; /* ID2 for dual or range, mask otherwise */
	volatile uint32_t res : 5;
	volatile uint32_t id1 : 11;
	volatile uint32_t sfce : 3; /* Filter config */
	volatile uint32_t sft : 2; /* Filter type */
	} __packed __aligned(4);

	#define CAN_MCAN_EFT_RANGE_XIDAM 0x0
	#define CAN_MCAN_EFT_DUAL 0x1
	#define CAN_MCAN_EFT_MASKED 0x2
	#define CAN_MCAN_EFT_RANGE 0x3

	struct can_mcan_ext_filter {
	volatile uint32_t id1 : 29;
	volatile uint32_t efce : 3; /* Filter config */
	volatile uint32_t id2 : 29; /* ID2 for dual or range, mask otherwise */
	volatile uint32_t res : 1;
	volatile uint32_t eft : 2; /* Filter type */
	} __packed __aligned(4);

	struct can_mcan_msg_sram {
	volatile struct can_mcan_std_filter std_filt[NUM_STD_FILTER_ELEMENTS];
	volatile struct can_mcan_ext_filter ext_filt[NUM_EXT_FILTER_ELEMENTS];
	volatile struct can_mcan_rx_fifo rx_fifo0[NUM_RX_FIFO0_ELEMENTS];
	volatile struct can_mcan_rx_fifo rx_fifo1[NUM_RX_FIFO1_ELEMENTS];
	volatile struct can_mcan_rx_fifo rx_buffer[NUM_RX_BUF_ELEMENTS];
	volatile struct can_mcan_tx_event_fifo tx_event_fifo[NUM_TX_BUF_ELEMENTS];
	volatile struct can_mcan_tx_buffer tx_buffer[NUM_TX_BUF_ELEMENTS];
	} __packed __aligned(4);

	struct can_mcan_data {
	struct can_mcan_msg_sram *msg_ram;
	struct k_mutex inst_mutex;
	struct k_sem tx_sem;
	struct k_mutex tx_mtx;
	struct k_sem tx_fin_sem[NUM_TX_BUF_ELEMENTS];
	can_tx_callback_t tx_fin_cb[NUM_TX_BUF_ELEMENTS];
	void *tx_fin_cb_arg[NUM_TX_BUF_ELEMENTS];
	can_rx_callback_t rx_cb_std[NUM_STD_FILTER_DATA];
	can_rx_callback_t rx_cb_ext[NUM_EXT_FILTER_DATA];
	void *cb_arg_std[NUM_STD_FILTER_DATA];
	void *cb_arg_ext[NUM_EXT_FILTER_DATA];
	can_state_change_callback_t state_change_cb;
	void *state_change_cb_data;
	uint32_t std_filt_rtr;
	uint32_t std_filt_rtr_mask;
	uint8_t ext_filt_rtr;
	uint8_t ext_filt_rtr_mask;
	struct can_mcan_mm mm;
	void *custom;
	} __aligned(4);

	struct can_mcan_config {
	struct can_mcan_reg can; /!< CAN Registers*/
	uint32_t bus_speed;
	uint32_t bus_speed_data;
	uint16_t sjw;
	uint16_t sample_point;
	uint16_t prop_ts1;
	uint16_t ts2;
	#ifdef CONFIG_CAN_FD_MODE
	uint16_t sample_point_data;
	uint8_t sjw_data;
	uint8_t prop_ts1_data;
	uint8_t ts2_data;
	uint8_t tx_delay_comp_offset;
	#endif
	const struct device *phy;
	uint32_t max_bitrate;
	const void *custom;
	};

	struct can_mcan_reg;

	#ifdef CONFIG_CAN_FD_MODE
	#define CAN_MCAN_DT_CONFIG_GET(node_id, _custom_config) \
	{ \
	.can = (struct can_mcan_reg *)DT_REG_ADDR_BY_NAME(node_id, m_can), \
	.bus_speed = DT_PROP(node_id, bus_speed), \
	.sjw = DT_PROP(node_id, sjw), \
	.sample_point = DT_PROP_OR(node_id, sample_point, 0), \
	.prop_ts1 = DT_PROP_OR(node_id, prop_seg, 0) + \
	DT_PROP_OR(node_id, phase_seg1, 0), \
	.ts2 = DT_PROP_OR(node_id, phase_seg2, 0), \
	.bus_speed_data = DT_PROP(node_id, bus_speed_data), \
	.sjw_data = DT_PROP(node_id, sjw_data), \
	.sample_point_data = \
	DT_PROP_OR(node_id, sample_point_data, 0), \
	.prop_ts1_data = DT_PROP_OR(node_id, prop_seg_data, 0) + \
	DT_PROP_OR(node_id, phase_seg1_data, 0), \
	.ts2_data = DT_PROP_OR(node_id, phase_seg2_data, 0), \
	.tx_delay_comp_offset = \
	DT_PROP(node_id, tx_delay_comp_offset), \
	.phy = DEVICE_DT_GET_OR_NULL(DT_PHANDLE(node_id, phys)), \
	.max_bitrate = DT_CAN_TRANSCEIVER_MAX_BITRATE(node_id, 8000000),\
	.custom = _custom_config, \
	}
	#else /* CONFIG_CAN_FD_MODE */
	#define CAN_MCAN_DT_CONFIG_GET(node_id, _custom_config) \
	{ \
	.can = (struct can_mcan_reg *)DT_REG_ADDR_BY_NAME(node_id, m_can), \
	.bus_speed = DT_PROP(node_id, bus_speed), \
	.sjw = DT_PROP(node_id, sjw), \
	.sample_point = DT_PROP_OR(node_id, sample_point, 0), \
	.prop_ts1 = DT_PROP_OR(node_id, prop_seg, 0) + \
	DT_PROP_OR(node_id, phase_seg1, 0), \
	.ts2 = DT_PROP_OR(node_id, phase_seg2, 0), \
	.phy = DEVICE_DT_GET_OR_NULL(DT_PHANDLE(node_id, phys)), \
	.max_bitrate = DT_CAN_TRANSCEIVER_MAX_BITRATE(node_id, 1000000),\
	.custom = _custom_config, \
	}
	#endif /* !CONFIG_CAN_FD_MODE */

	#define CAN_MCAN_DT_CONFIG_INST_GET(inst, _custom_config) \
	CAN_MCAN_DT_CONFIG_GET(DT_DRV_INST(inst), _custom_config)

	#define CAN_MCAN_DATA_INITIALIZER(_msg_ram, _custom_data) \
	{ \
	.msg_ram = _msg_ram, \
	.custom = _custom_data, \
	}

	int can_mcan_get_capabilities(const struct device dev, can_mode_t cap);

	int can_mcan_set_mode(const struct device *dev, can_mode_t mode);

	int can_mcan_set_timing(const struct device *dev,
	const struct can_timing *timing);

	int can_mcan_set_timing_data(const struct device *dev,
	const struct can_timing *timing_data);

	int can_mcan_init(const struct device *dev);

	void can_mcan_line_0_isr(const struct device *dev);

	void can_mcan_line_1_isr(const struct device *dev);

	int can_mcan_recover(const struct device *dev, k_timeout_t timeout);

	int can_mcan_send(const struct device dev, const struct zcan_frame frame,
	k_timeout_t timeout, can_tx_callback_t callback,
	void *user_data);

	int can_mcan_get_max_filters(const struct device *dev, enum can_ide id_type);

	int can_mcan_add_rx_filter(const struct device *dev,
	can_rx_callback_t callback, void *user_data,
	const struct zcan_filter *filter);

	void can_mcan_remove_rx_filter(const struct device *dev, int filter_id);

	int can_mcan_get_state(const struct device dev, enum can_state state,
	struct can_bus_err_cnt *err_cnt);

	void can_mcan_set_state_change_callback(const struct device *dev,
	can_state_change_callback_t callback,
	void *user_data);

	int can_mcan_get_max_bitrate(const struct device dev, uint32_t max_bitrate);

	#endif /* ZEPHYR_DRIVERS_CAN_MCAN_H_ */