MNRS-BM-BSP/include/ehrenberg/devices/gen/uart.h

/*
* Copyright (c) 2023 - 2024 MINRES Technologies GmbH
*
* SPDX-License-Identifier: Apache-2.0
*
* Generated at 2024-08-02 08:46:07 UTC 
* by peakrdl_mnrs version 1.2.7
*/

#ifndef _BSP_UART_H
#define _BSP_UART_H

#include <stdint.h>

typedef struct __attribute((__packed__)) {
    volatile uint32_t RX_TX_REG;
    volatile uint32_t INT_CTRL_REG;
    volatile uint32_t CLK_DIVIDER_REG;
    volatile uint32_t FRAME_CONFIG_REG;
    volatile uint32_t STATUS_REG;
}uart_t;

#define UART_RX_TX_REG_DATA_OFFS 0
#define UART_RX_TX_REG_DATA_MASK 0xff
#define UART_RX_TX_REG_DATA(V) ((V & UART_RX_TX_REG_DATA_MASK) << UART_RX_TX_REG_DATA_OFFS)

#define UART_RX_TX_REG_RX_AVAIL_OFFS 14
#define UART_RX_TX_REG_RX_AVAIL_MASK 0x1
#define UART_RX_TX_REG_RX_AVAIL(V) ((V & UART_RX_TX_REG_RX_AVAIL_MASK) << UART_RX_TX_REG_RX_AVAIL_OFFS)

#define UART_RX_TX_REG_TX_FREE_OFFS 15
#define UART_RX_TX_REG_TX_FREE_MASK 0x1
#define UART_RX_TX_REG_TX_FREE(V) ((V & UART_RX_TX_REG_TX_FREE_MASK) << UART_RX_TX_REG_TX_FREE_OFFS)

#define UART_RX_TX_REG_TX_EMPTY_OFFS 16
#define UART_RX_TX_REG_TX_EMPTY_MASK 0x1
#define UART_RX_TX_REG_TX_EMPTY(V) ((V & UART_RX_TX_REG_TX_EMPTY_MASK) << UART_RX_TX_REG_TX_EMPTY_OFFS)

#define UART_INT_CTRL_REG_WRITE_INTR_ENABLE_OFFS 0
#define UART_INT_CTRL_REG_WRITE_INTR_ENABLE_MASK 0x1
#define UART_INT_CTRL_REG_WRITE_INTR_ENABLE(V) ((V & UART_INT_CTRL_REG_WRITE_INTR_ENABLE_MASK) << UART_INT_CTRL_REG_WRITE_INTR_ENABLE_OFFS)

#define UART_INT_CTRL_REG_READ_INTR_ENABLE_OFFS 1
#define UART_INT_CTRL_REG_READ_INTR_ENABLE_MASK 0x1
#define UART_INT_CTRL_REG_READ_INTR_ENABLE(V) ((V & UART_INT_CTRL_REG_READ_INTR_ENABLE_MASK) << UART_INT_CTRL_REG_READ_INTR_ENABLE_OFFS)

#define UART_INT_CTRL_REG_BREAK_INTR_ENABLE_OFFS 2
#define UART_INT_CTRL_REG_BREAK_INTR_ENABLE_MASK 0x1
#define UART_INT_CTRL_REG_BREAK_INTR_ENABLE(V) ((V & UART_INT_CTRL_REG_BREAK_INTR_ENABLE_MASK) << UART_INT_CTRL_REG_BREAK_INTR_ENABLE_OFFS)

#define UART_INT_CTRL_REG_WRITE_INTR_PEND_OFFS 8
#define UART_INT_CTRL_REG_WRITE_INTR_PEND_MASK 0x1
#define UART_INT_CTRL_REG_WRITE_INTR_PEND(V) ((V & UART_INT_CTRL_REG_WRITE_INTR_PEND_MASK) << UART_INT_CTRL_REG_WRITE_INTR_PEND_OFFS)

#define UART_INT_CTRL_REG_READ_INTR_PEND_OFFS 9
#define UART_INT_CTRL_REG_READ_INTR_PEND_MASK 0x1
#define UART_INT_CTRL_REG_READ_INTR_PEND(V) ((V & UART_INT_CTRL_REG_READ_INTR_PEND_MASK) << UART_INT_CTRL_REG_READ_INTR_PEND_OFFS)

#define UART_INT_CTRL_REG_BREAK_INTR_PEND_OFFS 10
#define UART_INT_CTRL_REG_BREAK_INTR_PEND_MASK 0x1
#define UART_INT_CTRL_REG_BREAK_INTR_PEND(V) ((V & UART_INT_CTRL_REG_BREAK_INTR_PEND_MASK) << UART_INT_CTRL_REG_BREAK_INTR_PEND_OFFS)

#define UART_CLK_DIVIDER_REG_OFFS 0
#define UART_CLK_DIVIDER_REG_MASK 0xfffff
#define UART_CLK_DIVIDER_REG(V) ((V & UART_CLK_DIVIDER_REG_MASK) << UART_CLK_DIVIDER_REG_OFFS)

#define UART_FRAME_CONFIG_REG_DATA_LENGTH_OFFS 0
#define UART_FRAME_CONFIG_REG_DATA_LENGTH_MASK 0x7
#define UART_FRAME_CONFIG_REG_DATA_LENGTH(V) ((V & UART_FRAME_CONFIG_REG_DATA_LENGTH_MASK) << UART_FRAME_CONFIG_REG_DATA_LENGTH_OFFS)

#define UART_FRAME_CONFIG_REG_PARITY_OFFS 3
#define UART_FRAME_CONFIG_REG_PARITY_MASK 0x3
#define UART_FRAME_CONFIG_REG_PARITY(V) ((V & UART_FRAME_CONFIG_REG_PARITY_MASK) << UART_FRAME_CONFIG_REG_PARITY_OFFS)

#define UART_FRAME_CONFIG_REG_STOP_BIT_OFFS 5
#define UART_FRAME_CONFIG_REG_STOP_BIT_MASK 0x1
#define UART_FRAME_CONFIG_REG_STOP_BIT(V) ((V & UART_FRAME_CONFIG_REG_STOP_BIT_MASK) << UART_FRAME_CONFIG_REG_STOP_BIT_OFFS)

#define UART_STATUS_REG_READ_ERROR_OFFS 0
#define UART_STATUS_REG_READ_ERROR_MASK 0x1
#define UART_STATUS_REG_READ_ERROR(V) ((V & UART_STATUS_REG_READ_ERROR_MASK) << UART_STATUS_REG_READ_ERROR_OFFS)

#define UART_STATUS_REG_STALL_OFFS 1
#define UART_STATUS_REG_STALL_MASK 0x1
#define UART_STATUS_REG_STALL(V) ((V & UART_STATUS_REG_STALL_MASK) << UART_STATUS_REG_STALL_OFFS)

#define UART_STATUS_REG_BREAK_LINE_OFFS 8
#define UART_STATUS_REG_BREAK_LINE_MASK 0x1
#define UART_STATUS_REG_BREAK_LINE(V) ((V & UART_STATUS_REG_BREAK_LINE_MASK) << UART_STATUS_REG_BREAK_LINE_OFFS)

#define UART_STATUS_REG_BREAK_DETECTED_OFFS 9
#define UART_STATUS_REG_BREAK_DETECTED_MASK 0x1
#define UART_STATUS_REG_BREAK_DETECTED(V) ((V & UART_STATUS_REG_BREAK_DETECTED_MASK) << UART_STATUS_REG_BREAK_DETECTED_OFFS)

#define UART_STATUS_REG_SET_BREAK_OFFS 10
#define UART_STATUS_REG_SET_BREAK_MASK 0x1
#define UART_STATUS_REG_SET_BREAK(V) ((V & UART_STATUS_REG_SET_BREAK_MASK) << UART_STATUS_REG_SET_BREAK_OFFS)

#define UART_STATUS_REG_CLEAR_BREAK_OFFS 11
#define UART_STATUS_REG_CLEAR_BREAK_MASK 0x1
#define UART_STATUS_REG_CLEAR_BREAK(V) ((V & UART_STATUS_REG_CLEAR_BREAK_MASK) << UART_STATUS_REG_CLEAR_BREAK_OFFS)

//UART_RX_TX_REG
inline uint32_t get_uart_rx_tx_reg(volatile uart_t* reg){
     return reg->RX_TX_REG;
}
inline void set_uart_rx_tx_reg(volatile uart_t* reg, uint32_t value){
     reg->RX_TX_REG = value;
}
inline uint32_t get_uart_rx_tx_reg_data(volatile uart_t* reg){
    return (reg->RX_TX_REG >> 0) & 0xff;
}
inline void set_uart_rx_tx_reg_data(volatile uart_t* reg, uint8_t value){
    reg->RX_TX_REG = (reg->RX_TX_REG & ~(0xffU << 0)) | (value << 0);
}
inline uint32_t get_uart_rx_tx_reg_rx_avail(volatile uart_t* reg){
    return (reg->RX_TX_REG >> 14) & 0x1;
}
inline uint32_t get_uart_rx_tx_reg_tx_free(volatile uart_t* reg){
    return (reg->RX_TX_REG >> 15) & 0x1;
}
inline uint32_t get_uart_rx_tx_reg_tx_empty(volatile uart_t* reg){
    return (reg->RX_TX_REG >> 16) & 0x1;
}

//UART_INT_CTRL_REG
inline uint32_t get_uart_int_ctrl_reg(volatile uart_t* reg){
     return reg->INT_CTRL_REG;
}
inline void set_uart_int_ctrl_reg(volatile uart_t* reg, uint32_t value){
     reg->INT_CTRL_REG = value;
}
inline uint32_t get_uart_int_ctrl_reg_write_intr_enable(volatile uart_t* reg){
    return (reg->INT_CTRL_REG >> 0) & 0x1;
}
inline void set_uart_int_ctrl_reg_write_intr_enable(volatile uart_t* reg, uint8_t value){
    reg->INT_CTRL_REG = (reg->INT_CTRL_REG & ~(0x1U << 0)) | (value << 0);
}
inline uint32_t get_uart_int_ctrl_reg_read_intr_enable(volatile uart_t* reg){
    return (reg->INT_CTRL_REG >> 1) & 0x1;
}
inline void set_uart_int_ctrl_reg_read_intr_enable(volatile uart_t* reg, uint8_t value){
    reg->INT_CTRL_REG = (reg->INT_CTRL_REG & ~(0x1U << 1)) | (value << 1);
}
inline uint32_t get_uart_int_ctrl_reg_break_intr_enable(volatile uart_t* reg){
    return (reg->INT_CTRL_REG >> 2) & 0x1;
}
inline void set_uart_int_ctrl_reg_break_intr_enable(volatile uart_t* reg, uint8_t value){
    reg->INT_CTRL_REG = (reg->INT_CTRL_REG & ~(0x1U << 2)) | (value << 2);
}
inline uint32_t get_uart_int_ctrl_reg_write_intr_pend(volatile uart_t* reg){
    return (reg->INT_CTRL_REG >> 8) & 0x1;
}
inline uint32_t get_uart_int_ctrl_reg_read_intr_pend(volatile uart_t* reg){
    return (reg->INT_CTRL_REG >> 9) & 0x1;
}
inline uint32_t get_uart_int_ctrl_reg_break_intr_pend(volatile uart_t* reg){
    return (reg->INT_CTRL_REG >> 10) & 0x1;
}

//UART_CLK_DIVIDER_REG
inline uint32_t get_uart_clk_divider_reg(volatile uart_t* reg){
     return reg->CLK_DIVIDER_REG;
}
inline void set_uart_clk_divider_reg(volatile uart_t* reg, uint32_t value){
     reg->CLK_DIVIDER_REG = value;
}
inline uint32_t get_uart_clk_divider_reg_clock_divider(volatile uart_t* reg){
    return (reg->CLK_DIVIDER_REG >> 0) & 0xfffff;
}
inline void set_uart_clk_divider_reg_clock_divider(volatile uart_t* reg, uint32_t value){
    reg->CLK_DIVIDER_REG = (reg->CLK_DIVIDER_REG & ~(0xfffffU << 0)) | (value << 0);
}

//UART_FRAME_CONFIG_REG
inline uint32_t get_uart_frame_config_reg(volatile uart_t* reg){
     return reg->FRAME_CONFIG_REG;
}
inline void set_uart_frame_config_reg(volatile uart_t* reg, uint32_t value){
     reg->FRAME_CONFIG_REG = value;
}
inline uint32_t get_uart_frame_config_reg_data_length(volatile uart_t* reg){
    return (reg->FRAME_CONFIG_REG >> 0) & 0x7;
}
inline void set_uart_frame_config_reg_data_length(volatile uart_t* reg, uint8_t value){
    reg->FRAME_CONFIG_REG = (reg->FRAME_CONFIG_REG & ~(0x7U << 0)) | (value << 0);
}
inline uint32_t get_uart_frame_config_reg_parity(volatile uart_t* reg){
    return (reg->FRAME_CONFIG_REG >> 3) & 0x3;
}
inline void set_uart_frame_config_reg_parity(volatile uart_t* reg, uint8_t value){
    reg->FRAME_CONFIG_REG = (reg->FRAME_CONFIG_REG & ~(0x3U << 3)) | (value << 3);
}
inline uint32_t get_uart_frame_config_reg_stop_bit(volatile uart_t* reg){
    return (reg->FRAME_CONFIG_REG >> 5) & 0x1;
}
inline void set_uart_frame_config_reg_stop_bit(volatile uart_t* reg, uint8_t value){
    reg->FRAME_CONFIG_REG = (reg->FRAME_CONFIG_REG & ~(0x1U << 5)) | (value << 5);
}

//UART_STATUS_REG
inline uint32_t get_uart_status_reg(volatile uart_t* reg){
     return reg->STATUS_REG;
}
inline void set_uart_status_reg(volatile uart_t* reg, uint32_t value){
     reg->STATUS_REG = value;
}
inline uint32_t get_uart_status_reg_read_error(volatile uart_t* reg){
    return (reg->STATUS_REG >> 0) & 0x1;
}
inline uint32_t get_uart_status_reg_stall(volatile uart_t* reg){
    return (reg->STATUS_REG >> 1) & 0x1;
}
inline uint32_t get_uart_status_reg_break_line(volatile uart_t* reg){
    return (reg->STATUS_REG >> 8) & 0x1;
}
inline uint32_t get_uart_status_reg_break_detected(volatile uart_t* reg){
    return (reg->STATUS_REG >> 9) & 0x1;
}
inline void set_uart_status_reg_break_detected(volatile uart_t* reg, uint8_t value){
    reg->STATUS_REG = (reg->STATUS_REG & ~(0x1U << 9)) | (value << 9);
}
inline uint32_t get_uart_status_reg_set_break(volatile uart_t* reg){
    return (reg->STATUS_REG >> 10) & 0x1;
}
inline void set_uart_status_reg_set_break(volatile uart_t* reg, uint8_t value){
    reg->STATUS_REG = (reg->STATUS_REG & ~(0x1U << 10)) | (value << 10);
}
inline uint32_t get_uart_status_reg_clear_break(volatile uart_t* reg){
    return (reg->STATUS_REG >> 11) & 0x1;
}
inline void set_uart_status_reg_clear_break(volatile uart_t* reg, uint8_t value){
    reg->STATUS_REG = (reg->STATUS_REG & ~(0x1U << 11)) | (value << 11);
}

#endif /* _BSP_UART_H */
updates Ehrenberg register description 2024-05-30 18:32:23 +02:00			`/*`
			`* Copyright (c) 2023 - 2024 MINRES Technologies GmbH`
			`*`
			`* SPDX-License-Identifier: Apache-2.0`
			`*`
Ehrenberg firmware headers generated with peakrdl 1.2.8 2024-08-02 09:55:38 +02:00			`* Generated at 2024-08-02 08:46:07 UTC`
			`* by peakrdl_mnrs version 1.2.7`
updates Ehrenberg register description 2024-05-30 18:32:23 +02:00			`*/`

			`#ifndef _BSP_UART_H`
			`#define _BSP_UART_H`

			`#include <stdint.h>`

			`typedef struct __attribute((__packed__)) {`
			`volatile uint32_t RX_TX_REG;`
			`volatile uint32_t INT_CTRL_REG;`
			`volatile uint32_t CLK_DIVIDER_REG;`
			`volatile uint32_t FRAME_CONFIG_REG;`
			`volatile uint32_t STATUS_REG;`
			`}uart_t;`

			`#define UART_RX_TX_REG_DATA_OFFS 0`
			`#define UART_RX_TX_REG_DATA_MASK 0xff`
			`#define UART_RX_TX_REG_DATA(V) ((V & UART_RX_TX_REG_DATA_MASK) << UART_RX_TX_REG_DATA_OFFS)`

			`#define UART_RX_TX_REG_RX_AVAIL_OFFS 14`
			`#define UART_RX_TX_REG_RX_AVAIL_MASK 0x1`
			`#define UART_RX_TX_REG_RX_AVAIL(V) ((V & UART_RX_TX_REG_RX_AVAIL_MASK) << UART_RX_TX_REG_RX_AVAIL_OFFS)`

			`#define UART_RX_TX_REG_TX_FREE_OFFS 15`
			`#define UART_RX_TX_REG_TX_FREE_MASK 0x1`
			`#define UART_RX_TX_REG_TX_FREE(V) ((V & UART_RX_TX_REG_TX_FREE_MASK) << UART_RX_TX_REG_TX_FREE_OFFS)`

updates ehrenberg devices and BSP 2024-06-10 10:13:07 +02:00			`#define UART_RX_TX_REG_TX_EMPTY_OFFS 16`
			`#define UART_RX_TX_REG_TX_EMPTY_MASK 0x1`
			`#define UART_RX_TX_REG_TX_EMPTY(V) ((V & UART_RX_TX_REG_TX_EMPTY_MASK) << UART_RX_TX_REG_TX_EMPTY_OFFS)`

updates Ehrenberg register description 2024-05-30 18:32:23 +02:00			`#define UART_INT_CTRL_REG_WRITE_INTR_ENABLE_OFFS 0`
			`#define UART_INT_CTRL_REG_WRITE_INTR_ENABLE_MASK 0x1`
			`#define UART_INT_CTRL_REG_WRITE_INTR_ENABLE(V) ((V & UART_INT_CTRL_REG_WRITE_INTR_ENABLE_MASK) << UART_INT_CTRL_REG_WRITE_INTR_ENABLE_OFFS)`

			`#define UART_INT_CTRL_REG_READ_INTR_ENABLE_OFFS 1`
			`#define UART_INT_CTRL_REG_READ_INTR_ENABLE_MASK 0x1`
			`#define UART_INT_CTRL_REG_READ_INTR_ENABLE(V) ((V & UART_INT_CTRL_REG_READ_INTR_ENABLE_MASK) << UART_INT_CTRL_REG_READ_INTR_ENABLE_OFFS)`

			`#define UART_INT_CTRL_REG_BREAK_INTR_ENABLE_OFFS 2`
			`#define UART_INT_CTRL_REG_BREAK_INTR_ENABLE_MASK 0x1`
			`#define UART_INT_CTRL_REG_BREAK_INTR_ENABLE(V) ((V & UART_INT_CTRL_REG_BREAK_INTR_ENABLE_MASK) << UART_INT_CTRL_REG_BREAK_INTR_ENABLE_OFFS)`

			`#define UART_INT_CTRL_REG_WRITE_INTR_PEND_OFFS 8`
			`#define UART_INT_CTRL_REG_WRITE_INTR_PEND_MASK 0x1`
			`#define UART_INT_CTRL_REG_WRITE_INTR_PEND(V) ((V & UART_INT_CTRL_REG_WRITE_INTR_PEND_MASK) << UART_INT_CTRL_REG_WRITE_INTR_PEND_OFFS)`

			`#define UART_INT_CTRL_REG_READ_INTR_PEND_OFFS 9`
			`#define UART_INT_CTRL_REG_READ_INTR_PEND_MASK 0x1`
			`#define UART_INT_CTRL_REG_READ_INTR_PEND(V) ((V & UART_INT_CTRL_REG_READ_INTR_PEND_MASK) << UART_INT_CTRL_REG_READ_INTR_PEND_OFFS)`

			`#define UART_INT_CTRL_REG_BREAK_INTR_PEND_OFFS 10`
			`#define UART_INT_CTRL_REG_BREAK_INTR_PEND_MASK 0x1`
			`#define UART_INT_CTRL_REG_BREAK_INTR_PEND(V) ((V & UART_INT_CTRL_REG_BREAK_INTR_PEND_MASK) << UART_INT_CTRL_REG_BREAK_INTR_PEND_OFFS)`

			`#define UART_CLK_DIVIDER_REG_OFFS 0`
			`#define UART_CLK_DIVIDER_REG_MASK 0xfffff`
			`#define UART_CLK_DIVIDER_REG(V) ((V & UART_CLK_DIVIDER_REG_MASK) << UART_CLK_DIVIDER_REG_OFFS)`

updates Ehrenberg device files 2024-07-16 16:22:42 +02:00			`#define UART_FRAME_CONFIG_REG_DATA_LENGTH_OFFS 0`
			`#define UART_FRAME_CONFIG_REG_DATA_LENGTH_MASK 0x7`
			`#define UART_FRAME_CONFIG_REG_DATA_LENGTH(V) ((V & UART_FRAME_CONFIG_REG_DATA_LENGTH_MASK) << UART_FRAME_CONFIG_REG_DATA_LENGTH_OFFS)`
updates Ehrenberg register description 2024-05-30 18:32:23 +02:00
			`#define UART_FRAME_CONFIG_REG_PARITY_OFFS 3`
			`#define UART_FRAME_CONFIG_REG_PARITY_MASK 0x3`
			`#define UART_FRAME_CONFIG_REG_PARITY(V) ((V & UART_FRAME_CONFIG_REG_PARITY_MASK) << UART_FRAME_CONFIG_REG_PARITY_OFFS)`

			`#define UART_FRAME_CONFIG_REG_STOP_BIT_OFFS 5`
			`#define UART_FRAME_CONFIG_REG_STOP_BIT_MASK 0x1`
			`#define UART_FRAME_CONFIG_REG_STOP_BIT(V) ((V & UART_FRAME_CONFIG_REG_STOP_BIT_MASK) << UART_FRAME_CONFIG_REG_STOP_BIT_OFFS)`

			`#define UART_STATUS_REG_READ_ERROR_OFFS 0`
			`#define UART_STATUS_REG_READ_ERROR_MASK 0x1`
			`#define UART_STATUS_REG_READ_ERROR(V) ((V & UART_STATUS_REG_READ_ERROR_MASK) << UART_STATUS_REG_READ_ERROR_OFFS)`

			`#define UART_STATUS_REG_STALL_OFFS 1`
			`#define UART_STATUS_REG_STALL_MASK 0x1`
			`#define UART_STATUS_REG_STALL(V) ((V & UART_STATUS_REG_STALL_MASK) << UART_STATUS_REG_STALL_OFFS)`

			`#define UART_STATUS_REG_BREAK_LINE_OFFS 8`
			`#define UART_STATUS_REG_BREAK_LINE_MASK 0x1`
			`#define UART_STATUS_REG_BREAK_LINE(V) ((V & UART_STATUS_REG_BREAK_LINE_MASK) << UART_STATUS_REG_BREAK_LINE_OFFS)`

			`#define UART_STATUS_REG_BREAK_DETECTED_OFFS 9`
			`#define UART_STATUS_REG_BREAK_DETECTED_MASK 0x1`
			`#define UART_STATUS_REG_BREAK_DETECTED(V) ((V & UART_STATUS_REG_BREAK_DETECTED_MASK) << UART_STATUS_REG_BREAK_DETECTED_OFFS)`

			`#define UART_STATUS_REG_SET_BREAK_OFFS 10`
			`#define UART_STATUS_REG_SET_BREAK_MASK 0x1`
			`#define UART_STATUS_REG_SET_BREAK(V) ((V & UART_STATUS_REG_SET_BREAK_MASK) << UART_STATUS_REG_SET_BREAK_OFFS)`

			`#define UART_STATUS_REG_CLEAR_BREAK_OFFS 11`
			`#define UART_STATUS_REG_CLEAR_BREAK_MASK 0x1`
			`#define UART_STATUS_REG_CLEAR_BREAK(V) ((V & UART_STATUS_REG_CLEAR_BREAK_MASK) << UART_STATUS_REG_CLEAR_BREAK_OFFS)`

			`//UART_RX_TX_REG`
			`inline uint32_t get_uart_rx_tx_reg(volatile uart_t* reg){`
			`return reg->RX_TX_REG;`
			`}`
			`inline void set_uart_rx_tx_reg(volatile uart_t* reg, uint32_t value){`
			`reg->RX_TX_REG = value;`
			`}`
			`inline uint32_t get_uart_rx_tx_reg_data(volatile uart_t* reg){`
			`return (reg->RX_TX_REG >> 0) & 0xff;`
			`}`
			`inline void set_uart_rx_tx_reg_data(volatile uart_t* reg, uint8_t value){`
			`reg->RX_TX_REG = (reg->RX_TX_REG & ~(0xffU << 0)) \| (value << 0);`
			`}`
			`inline uint32_t get_uart_rx_tx_reg_rx_avail(volatile uart_t* reg){`
			`return (reg->RX_TX_REG >> 14) & 0x1;`
			`}`
			`inline uint32_t get_uart_rx_tx_reg_tx_free(volatile uart_t* reg){`
			`return (reg->RX_TX_REG >> 15) & 0x1;`
			`}`
updates ehrenberg devices and BSP 2024-06-10 10:13:07 +02:00			`inline uint32_t get_uart_rx_tx_reg_tx_empty(volatile uart_t* reg){`
			`return (reg->RX_TX_REG >> 16) & 0x1;`
			`}`
updates Ehrenberg register description 2024-05-30 18:32:23 +02:00
			`//UART_INT_CTRL_REG`
			`inline uint32_t get_uart_int_ctrl_reg(volatile uart_t* reg){`
			`return reg->INT_CTRL_REG;`
			`}`
			`inline void set_uart_int_ctrl_reg(volatile uart_t* reg, uint32_t value){`
			`reg->INT_CTRL_REG = value;`
			`}`
			`inline uint32_t get_uart_int_ctrl_reg_write_intr_enable(volatile uart_t* reg){`
			`return (reg->INT_CTRL_REG >> 0) & 0x1;`
			`}`
			`inline void set_uart_int_ctrl_reg_write_intr_enable(volatile uart_t* reg, uint8_t value){`
			`reg->INT_CTRL_REG = (reg->INT_CTRL_REG & ~(0x1U << 0)) \| (value << 0);`
			`}`
			`inline uint32_t get_uart_int_ctrl_reg_read_intr_enable(volatile uart_t* reg){`
			`return (reg->INT_CTRL_REG >> 1) & 0x1;`
			`}`
			`inline void set_uart_int_ctrl_reg_read_intr_enable(volatile uart_t* reg, uint8_t value){`
			`reg->INT_CTRL_REG = (reg->INT_CTRL_REG & ~(0x1U << 1)) \| (value << 1);`
			`}`
			`inline uint32_t get_uart_int_ctrl_reg_break_intr_enable(volatile uart_t* reg){`
			`return (reg->INT_CTRL_REG >> 2) & 0x1;`
			`}`
			`inline void set_uart_int_ctrl_reg_break_intr_enable(volatile uart_t* reg, uint8_t value){`
			`reg->INT_CTRL_REG = (reg->INT_CTRL_REG & ~(0x1U << 2)) \| (value << 2);`
			`}`
			`inline uint32_t get_uart_int_ctrl_reg_write_intr_pend(volatile uart_t* reg){`
			`return (reg->INT_CTRL_REG >> 8) & 0x1;`
			`}`
			`inline uint32_t get_uart_int_ctrl_reg_read_intr_pend(volatile uart_t* reg){`
			`return (reg->INT_CTRL_REG >> 9) & 0x1;`
			`}`
			`inline uint32_t get_uart_int_ctrl_reg_break_intr_pend(volatile uart_t* reg){`
			`return (reg->INT_CTRL_REG >> 10) & 0x1;`
			`}`

			`//UART_CLK_DIVIDER_REG`
			`inline uint32_t get_uart_clk_divider_reg(volatile uart_t* reg){`
Ehrenberg firmware headers generated with peakrdl 1.2.8 2024-08-02 09:55:38 +02:00			`return reg->CLK_DIVIDER_REG;`
updates Ehrenberg register description 2024-05-30 18:32:23 +02:00			`}`
			`inline void set_uart_clk_divider_reg(volatile uart_t* reg, uint32_t value){`
Ehrenberg firmware headers generated with peakrdl 1.2.8 2024-08-02 09:55:38 +02:00			`reg->CLK_DIVIDER_REG = value;`
			`}`
			`inline uint32_t get_uart_clk_divider_reg_clock_divider(volatile uart_t* reg){`
			`return (reg->CLK_DIVIDER_REG >> 0) & 0xfffff;`
			`}`
			`inline void set_uart_clk_divider_reg_clock_divider(volatile uart_t* reg, uint32_t value){`
updates Ehrenberg register description 2024-05-30 18:32:23 +02:00			`reg->CLK_DIVIDER_REG = (reg->CLK_DIVIDER_REG & ~(0xfffffU << 0)) \| (value << 0);`
			`}`

			`//UART_FRAME_CONFIG_REG`
			`inline uint32_t get_uart_frame_config_reg(volatile uart_t* reg){`
			`return reg->FRAME_CONFIG_REG;`
			`}`
			`inline void set_uart_frame_config_reg(volatile uart_t* reg, uint32_t value){`
			`reg->FRAME_CONFIG_REG = value;`
			`}`
updates Ehrenberg device files 2024-07-16 16:22:42 +02:00			`inline uint32_t get_uart_frame_config_reg_data_length(volatile uart_t* reg){`
updates Ehrenberg register description 2024-05-30 18:32:23 +02:00			`return (reg->FRAME_CONFIG_REG >> 0) & 0x7;`
			`}`
updates Ehrenberg device files 2024-07-16 16:22:42 +02:00			`inline void set_uart_frame_config_reg_data_length(volatile uart_t* reg, uint8_t value){`
updates Ehrenberg register description 2024-05-30 18:32:23 +02:00			`reg->FRAME_CONFIG_REG = (reg->FRAME_CONFIG_REG & ~(0x7U << 0)) \| (value << 0);`
			`}`
			`inline uint32_t get_uart_frame_config_reg_parity(volatile uart_t* reg){`
			`return (reg->FRAME_CONFIG_REG >> 3) & 0x3;`
			`}`
			`inline void set_uart_frame_config_reg_parity(volatile uart_t* reg, uint8_t value){`
			`reg->FRAME_CONFIG_REG = (reg->FRAME_CONFIG_REG & ~(0x3U << 3)) \| (value << 3);`
			`}`
			`inline uint32_t get_uart_frame_config_reg_stop_bit(volatile uart_t* reg){`
			`return (reg->FRAME_CONFIG_REG >> 5) & 0x1;`
			`}`
			`inline void set_uart_frame_config_reg_stop_bit(volatile uart_t* reg, uint8_t value){`
			`reg->FRAME_CONFIG_REG = (reg->FRAME_CONFIG_REG & ~(0x1U << 5)) \| (value << 5);`
			`}`

			`//UART_STATUS_REG`
			`inline uint32_t get_uart_status_reg(volatile uart_t* reg){`
			`return reg->STATUS_REG;`
			`}`
			`inline void set_uart_status_reg(volatile uart_t* reg, uint32_t value){`
			`reg->STATUS_REG = value;`
			`}`
			`inline uint32_t get_uart_status_reg_read_error(volatile uart_t* reg){`
			`return (reg->STATUS_REG >> 0) & 0x1;`
			`}`
			`inline uint32_t get_uart_status_reg_stall(volatile uart_t* reg){`
			`return (reg->STATUS_REG >> 1) & 0x1;`
			`}`
			`inline uint32_t get_uart_status_reg_break_line(volatile uart_t* reg){`
			`return (reg->STATUS_REG >> 8) & 0x1;`
			`}`
			`inline uint32_t get_uart_status_reg_break_detected(volatile uart_t* reg){`
			`return (reg->STATUS_REG >> 9) & 0x1;`
			`}`
			`inline void set_uart_status_reg_break_detected(volatile uart_t* reg, uint8_t value){`
			`reg->STATUS_REG = (reg->STATUS_REG & ~(0x1U << 9)) \| (value << 9);`
			`}`
			`inline uint32_t get_uart_status_reg_set_break(volatile uart_t* reg){`
			`return (reg->STATUS_REG >> 10) & 0x1;`
			`}`
			`inline void set_uart_status_reg_set_break(volatile uart_t* reg, uint8_t value){`
			`reg->STATUS_REG = (reg->STATUS_REG & ~(0x1U << 10)) \| (value << 10);`
			`}`
			`inline uint32_t get_uart_status_reg_clear_break(volatile uart_t* reg){`
			`return (reg->STATUS_REG >> 11) & 0x1;`
			`}`
			`inline void set_uart_status_reg_clear_break(volatile uart_t* reg, uint8_t value){`
			`reg->STATUS_REG = (reg->STATUS_REG & ~(0x1U << 11)) \| (value << 11);`
			`}`

			`#endif /* _BSP_UART_H */`