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esp-idf/components/soc/esp32h4/include/rev2/soc/efuse_struct.h
laokaiyao 8677216576 esp32h2: renaming esp32h2 to esp32h4
2022-11-08 17:05:33 +08:00

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/**
* SPDX-FileCopyrightText: 2021-2022 Espressif Systems (Shanghai) CO LTD
*
* SPDX-License-Identifier: Apache-2.0
*/
#pragma once
#include <stdint.h>
#ifdef __cplusplus
extern "C" {
#endif
/** Group: PGM Data Register */
/** Type of pgm_data0 register
* Register 0 that stores data to be programmed.
*/
typedef union {
struct {
/** pgm_data_0 : R/W; bitpos: [31:0]; default: 0;
* The content of the 0th 32-bit data to be programmed.
*/
uint32_t pgm_data_0:32;
};
uint32_t val;
} efuse_pgm_data0_reg_t;
/** Type of pgm_data1 register
* Register 1 that stores data to be programmed.
*/
typedef union {
struct {
/** pgm_data_1 : R/W; bitpos: [31:0]; default: 0;
* The content of the 1st 32-bit data to be programmed.
*/
uint32_t pgm_data_1:32;
};
uint32_t val;
} efuse_pgm_data1_reg_t;
/** Type of pgm_data2 register
* Register 2 that stores data to be programmed.
*/
typedef union {
struct {
/** pgm_data_2 : R/W; bitpos: [31:0]; default: 0;
* The content of the 2nd 32-bit data to be programmed.
*/
uint32_t pgm_data_2:32;
};
uint32_t val;
} efuse_pgm_data2_reg_t;
/** Type of pgm_data3 register
* Register 3 that stores data to be programmed.
*/
typedef union {
struct {
/** pgm_data_3 : R/W; bitpos: [31:0]; default: 0;
* The content of the 3rd 32-bit data to be programmed.
*/
uint32_t pgm_data_3:32;
};
uint32_t val;
} efuse_pgm_data3_reg_t;
/** Type of pgm_data4 register
* Register 4 that stores data to be programmed.
*/
typedef union {
struct {
/** pgm_data_4 : R/W; bitpos: [31:0]; default: 0;
* The content of the 4th 32-bit data to be programmed.
*/
uint32_t pgm_data_4:32;
};
uint32_t val;
} efuse_pgm_data4_reg_t;
/** Type of pgm_data5 register
* Register 5 that stores data to be programmed.
*/
typedef union {
struct {
/** pgm_data_5 : R/W; bitpos: [31:0]; default: 0;
* The content of the 5th 32-bit data to be programmed.
*/
uint32_t pgm_data_5:32;
};
uint32_t val;
} efuse_pgm_data5_reg_t;
/** Type of pgm_data6 register
* Register 6 that stores data to be programmed.
*/
typedef union {
struct {
/** pgm_data_6 : R/W; bitpos: [31:0]; default: 0;
* The content of the 6th 32-bit data to be programmed.
*/
uint32_t pgm_data_6:32;
};
uint32_t val;
} efuse_pgm_data6_reg_t;
/** Type of pgm_data7 register
* Register 7 that stores data to be programmed.
*/
typedef union {
struct {
/** pgm_data_7 : R/W; bitpos: [31:0]; default: 0;
* The content of the 7th 32-bit data to be programmed.
*/
uint32_t pgm_data_7:32;
};
uint32_t val;
} efuse_pgm_data7_reg_t;
/** Type of pgm_check_value0 register
* Register 0 that stores the RS code to be programmed.
*/
typedef union {
struct {
/** pgm_rs_data_0 : R/W; bitpos: [31:0]; default: 0;
* The content of the 0th 32-bit RS code to be programmed.
*/
uint32_t pgm_rs_data_0:32;
};
uint32_t val;
} efuse_pgm_check_value0_reg_t;
/** Type of pgm_check_value1 register
* Register 1 that stores the RS code to be programmed.
*/
typedef union {
struct {
/** pgm_rs_data_1 : R/W; bitpos: [31:0]; default: 0;
* The content of the 1st 32-bit RS code to be programmed.
*/
uint32_t pgm_rs_data_1:32;
};
uint32_t val;
} efuse_pgm_check_value1_reg_t;
/** Type of pgm_check_value2 register
* Register 2 that stores the RS code to be programmed.
*/
typedef union {
struct {
/** pgm_rs_data_2 : R/W; bitpos: [31:0]; default: 0;
* The content of the 2nd 32-bit RS code to be programmed.
*/
uint32_t pgm_rs_data_2:32;
};
uint32_t val;
} efuse_pgm_check_value2_reg_t;
/** Group: ******** Registers */
/** Type of rd_wr_dis register
* BLOCK0 data register $n.
*/
typedef union {
struct {
/** wr_dis : RO; bitpos: [31:0]; default: 0;
* The value of WR_DIS.
*/
uint32_t wr_dis:32;
};
uint32_t val;
} efuse_rd_wr_dis_reg_t;
/** Type of rd_repeat_data0 register
* BLOCK0 data register $n.
*/
typedef union {
struct {
/** rd_dis : RO; bitpos: [6:0]; default: 0;
* The value of RD_DIS.
*/
uint32_t rd_dis:7;
/** rpt4_reserved5 : RO; bitpos: [7]; default: 0;
* Reserved.
*/
uint32_t rpt4_reserved5:1;
/** dis_icache : RO; bitpos: [8]; default: 0;
* The value of DIS_ICACHE.
*/
uint32_t dis_icache:1;
/** dis_usb_jtag : RO; bitpos: [9]; default: 0;
* The value of DIS_USB_JTAG.
*/
uint32_t dis_usb_jtag:1;
/** dis_download_icache : RO; bitpos: [10]; default: 0;
* The value of DIS_DOWNLOAD_ICACHE.
*/
uint32_t dis_download_icache:1;
/** dis_usb_device : RO; bitpos: [11]; default: 0;
* The value of DIS_USB_DEVICE.
*/
uint32_t dis_usb_device:1;
/** dis_force_download : RO; bitpos: [12]; default: 0;
* The value of DIS_FORCE_DOWNLOAD.
*/
uint32_t dis_force_download:1;
/** rpt4_reserved6 : RO; bitpos: [13]; default: 0;
* Reserved.
*/
uint32_t rpt4_reserved6:1;
/** dis_twai : RO; bitpos: [14]; default: 0;
* The value of DIS_TWAI.
*/
uint32_t dis_twai:1;
/** jtag_sel_enable : RO; bitpos: [15]; default: 0;
* The value of JTAG_SEL_ENABLE.
*/
uint32_t jtag_sel_enable:1;
/** soft_dis_jtag : RO; bitpos: [18:16]; default: 0;
* The value of SOFT_DIS_JTAG.
*/
uint32_t soft_dis_jtag:3;
/** dis_pad_jtag : RO; bitpos: [19]; default: 0;
* The value of DIS_PAD_JTAG.
*/
uint32_t dis_pad_jtag:1;
/** dis_download_manual_encrypt : RO; bitpos: [20]; default: 0;
* The value of DIS_DOWNLOAD_MANUAL_ENCRYPT.
*/
uint32_t dis_download_manual_encrypt:1;
/** usb_drefh : RO; bitpos: [22:21]; default: 0;
* The value of USB_DREFH.
*/
uint32_t usb_drefh:2;
/** usb_drefl : RO; bitpos: [24:23]; default: 0;
* The value of USB_DREFL.
*/
uint32_t usb_drefl:2;
/** usb_exchg_pins : RO; bitpos: [25]; default: 0;
* The value of USB_EXCHG_PINS.
*/
uint32_t usb_exchg_pins:1;
/** vdd_spi_as_gpio : RO; bitpos: [26]; default: 0;
* The value of VDD_SPI_AS_GPIO.
*/
uint32_t vdd_spi_as_gpio:1;
/** btlc_gpio_enable : RO; bitpos: [28:27]; default: 0;
* The value of BTLC_GPIO_ENABLE.
*/
uint32_t btlc_gpio_enable:2;
/** powerglitch_en : RO; bitpos: [29]; default: 0;
* The value of POWERGLITCH_EN.
*/
uint32_t powerglitch_en:1;
/** power_glitch_dsense : RO; bitpos: [31:30]; default: 0;
* The value of POWER_GLITCH_DSENSE.
*/
uint32_t power_glitch_dsense:2;
};
uint32_t val;
} efuse_rd_repeat_data0_reg_t;
/** Type of rd_repeat_data1 register
* BLOCK0 data register $n.
*/
typedef union {
struct {
/** rpt4_reserved2 : RO; bitpos: [15:0]; default: 0;
* Reserved.
*/
uint32_t rpt4_reserved2:16;
/** wdt_delay_sel : RO; bitpos: [17:16]; default: 0;
* The value of WDT_DELAY_SEL.
*/
uint32_t wdt_delay_sel:2;
/** spi_boot_crypt_cnt : RO; bitpos: [20:18]; default: 0;
* The value of SPI_BOOT_CRYPT_CNT.
*/
uint32_t spi_boot_crypt_cnt:3;
/** secure_boot_key_revoke0 : RO; bitpos: [21]; default: 0;
* The value of SECURE_BOOT_KEY_REVOKE0.
*/
uint32_t secure_boot_key_revoke0:1;
/** secure_boot_key_revoke1 : RO; bitpos: [22]; default: 0;
* The value of SECURE_BOOT_KEY_REVOKE1.
*/
uint32_t secure_boot_key_revoke1:1;
/** secure_boot_key_revoke2 : RO; bitpos: [23]; default: 0;
* The value of SECURE_BOOT_KEY_REVOKE2.
*/
uint32_t secure_boot_key_revoke2:1;
/** key_purpose_0 : RO; bitpos: [27:24]; default: 0;
* The value of KEY_PURPOSE_0.
*/
uint32_t key_purpose_0:4;
/** key_purpose_1 : RO; bitpos: [31:28]; default: 0;
* The value of KEY_PURPOSE_1.
*/
uint32_t key_purpose_1:4;
};
uint32_t val;
} efuse_rd_repeat_data1_reg_t;
/** Type of rd_repeat_data2 register
* BLOCK0 data register $n.
*/
typedef union {
struct {
/** key_purpose_2 : RO; bitpos: [3:0]; default: 0;
* The value of KEY_PURPOSE_2.
*/
uint32_t key_purpose_2:4;
/** key_purpose_3 : RO; bitpos: [7:4]; default: 0;
* The value of KEY_PURPOSE_3.
*/
uint32_t key_purpose_3:4;
/** key_purpose_4 : RO; bitpos: [11:8]; default: 0;
* The value of KEY_PURPOSE_4.
*/
uint32_t key_purpose_4:4;
/** key_purpose_5 : RO; bitpos: [15:12]; default: 0;
* The value of KEY_PURPOSE_5.
*/
uint32_t key_purpose_5:4;
/** rpt4_reserved3 : RO; bitpos: [19:16]; default: 0;
* Reserved.
*/
uint32_t rpt4_reserved3:4;
/** secure_boot_en : RO; bitpos: [20]; default: 0;
* The value of SECURE_BOOT_EN.
*/
uint32_t secure_boot_en:1;
/** secure_boot_aggressive_revoke : RO; bitpos: [21]; default: 0;
* The value of SECURE_BOOT_AGGRESSIVE_REVOKE.
*/
uint32_t secure_boot_aggressive_revoke:1;
/** rpt4_reserved0 : RO; bitpos: [27:22]; default: 0;
* Reserved.
*/
uint32_t rpt4_reserved0:6;
/** flash_tpuw : RO; bitpos: [31:28]; default: 0;
* The value of FLASH_TPUW.
*/
uint32_t flash_tpuw:4;
};
uint32_t val;
} efuse_rd_repeat_data2_reg_t;
/** Type of rd_repeat_data3 register
* BLOCK0 data register $n.
*/
typedef union {
struct {
/** dis_download_mode : RO; bitpos: [0]; default: 0;
* The value of DIS_DOWNLOAD_MODE.
*/
uint32_t dis_download_mode:1;
/** dis_direct_boot : RO; bitpos: [1]; default: 0;
* The value of DIS_DIRECT_BOOT.
*/
uint32_t dis_direct_boot:1;
/** dis_usb_serial_jtag_rom_print : RO; bitpos: [2]; default: 0;
* The value of DIS_USB_SERIAL_JTAG_ROM_PRINT.
*/
uint32_t dis_usb_serial_jtag_rom_print:1;
/** rpt4_reserved8 : RO; bitpos: [3]; default: 0;
* Reserved.
*/
uint32_t rpt4_reserved8:1;
/** dis_usb_serial_jtag_download_mode : RO; bitpos: [4]; default: 0;
* The value of DIS_USB_SERIAL_JTAG_DOWNLOAD_MODE.
*/
uint32_t dis_usb_serial_jtag_download_mode:1;
/** enable_security_download : RO; bitpos: [5]; default: 0;
* The value of ENABLE_SECURITY_DOWNLOAD.
*/
uint32_t enable_security_download:1;
/** uart_print_control : RO; bitpos: [7:6]; default: 0;
* The value of UART_PRINT_CONTROL.
*/
uint32_t uart_print_control:2;
/** rpt4_reserved7 : RO; bitpos: [12:8]; default: 0;
* Reserved.
*/
uint32_t rpt4_reserved7:5;
/** force_send_resume : RO; bitpos: [13]; default: 0;
* The value of FORCE_SEND_RESUME.
*/
uint32_t force_send_resume:1;
/** secure_version : RO; bitpos: [29:14]; default: 0;
* The value of SECURE_VERSION.
*/
uint32_t secure_version:16;
/** rpt4_reserved1 : RO; bitpos: [31:30]; default: 0;
* Reserved.
*/
uint32_t rpt4_reserved1:2;
};
uint32_t val;
} efuse_rd_repeat_data3_reg_t;
/** Type of rd_repeat_data4 register
* BLOCK0 data register $n.
*/
typedef union {
struct {
/** rpt4_reserved4 : RO; bitpos: [23:0]; default: 0;
* Reserved.
*/
uint32_t rpt4_reserved4:24;
uint32_t reserved_24:8;
};
uint32_t val;
} efuse_rd_repeat_data4_reg_t;
/** Type of rd_mac_spi_sys_0 register
* BLOCK1 data register $n.
*/
typedef union {
struct {
/** mac_0 : RO; bitpos: [31:0]; default: 0;
* Stores the low 32 bits of MAC address.
*/
uint32_t mac_0:32;
};
uint32_t val;
} efuse_rd_mac_spi_sys_0_reg_t;
/** Type of rd_mac_spi_sys_1 register
* BLOCK1 data register $n.
*/
typedef union {
struct {
/** mac_1 : RO; bitpos: [15:0]; default: 0;
* Stores the high 16 bits of MAC address.
*/
uint32_t mac_1:16;
/** spi_pad_conf_0 : RO; bitpos: [31:16]; default: 0;
* Stores the zeroth part of SPI_PAD_CONF.
*/
uint32_t spi_pad_conf_0:16;
};
uint32_t val;
} efuse_rd_mac_spi_sys_1_reg_t;
/** Type of rd_mac_spi_sys_2 register
* BLOCK1 data register $n.
*/
typedef union {
struct {
/** spi_pad_conf_1 : RO; bitpos: [31:0]; default: 0;
* Stores the first part of SPI_PAD_CONF.
*/
uint32_t spi_pad_conf_1:32;
};
uint32_t val;
} efuse_rd_mac_spi_sys_2_reg_t;
/** Type of rd_mac_spi_sys_3 register
* BLOCK1 data register $n.
*/
typedef union {
struct {
/** spi_pad_conf_2 : RO; bitpos: [17:0]; default: 0;
* Stores the second part of SPI_PAD_CONF.
*/
uint32_t spi_pad_conf_2:18;
uint32_t wafer_version:3;
uint32_t pkg_version:3;
uint32_t sys_data_part0_0:8;
};
uint32_t val;
} efuse_rd_mac_spi_sys_3_reg_t;
/** Type of rd_mac_spi_sys_4 register
* BLOCK1 data register $n.
*/
typedef union {
struct {
/** sys_data_part0_1 : RO; bitpos: [31:0]; default: 0;
* Stores the fist 32 bits of the zeroth part of system data.
*/
uint32_t sys_data_part0_1:32;
};
uint32_t val;
} efuse_rd_mac_spi_sys_4_reg_t;
/** Type of rd_mac_spi_sys_5 register
* BLOCK1 data register $n.
*/
typedef union {
struct {
/** sys_data_part0_2 : RO; bitpos: [31:0]; default: 0;
* Stores the second 32 bits of the zeroth part of system data.
*/
uint32_t sys_data_part0_2:32;
};
uint32_t val;
} efuse_rd_mac_spi_sys_5_reg_t;
/** Type of rd_sys_part1_data0 register
* Register $n of BLOCK2 (system).
*/
typedef union {
struct {
/** sys_data_part1_0 : RO; bitpos: [31:0]; default: 0;
* Stores the zeroth 32 bits of the first part of system data.
*/
uint32_t sys_data_part1_0:32;
};
uint32_t val;
} efuse_rd_sys_part1_data0_reg_t;
/** Type of rd_sys_part1_data1 register
* Register $n of BLOCK2 (system).
*/
typedef union {
struct {
/** sys_data_part1_1 : RO; bitpos: [31:0]; default: 0;
* Stores the first 32 bits of the first part of system data.
*/
uint32_t sys_data_part1_1:32;
};
uint32_t val;
} efuse_rd_sys_part1_data1_reg_t;
/** Type of rd_sys_part1_data2 register
* Register $n of BLOCK2 (system).
*/
typedef union {
struct {
/** sys_data_part1_2 : RO; bitpos: [31:0]; default: 0;
* Stores the second 32 bits of the first part of system data.
*/
uint32_t sys_data_part1_2:32;
};
uint32_t val;
} efuse_rd_sys_part1_data2_reg_t;
/** Type of rd_sys_part1_data3 register
* Register $n of BLOCK2 (system).
*/
typedef union {
struct {
/** sys_data_part1_3 : RO; bitpos: [31:0]; default: 0;
* Stores the third 32 bits of the first part of system data.
*/
uint32_t sys_data_part1_3:32;
};
uint32_t val;
} efuse_rd_sys_part1_data3_reg_t;
/** Type of rd_sys_part1_data4 register
* Register $n of BLOCK2 (system).
*/
typedef union {
struct {
/** sys_data_part1_4 : RO; bitpos: [31:0]; default: 0;
* Stores the fourth 32 bits of the first part of system data.
*/
uint32_t sys_data_part1_4:32;
};
uint32_t val;
} efuse_rd_sys_part1_data4_reg_t;
/** Type of rd_sys_part1_data5 register
* Register $n of BLOCK2 (system).
*/
typedef union {
struct {
/** sys_data_part1_5 : RO; bitpos: [31:0]; default: 0;
* Stores the fifth 32 bits of the first part of system data.
*/
uint32_t sys_data_part1_5:32;
};
uint32_t val;
} efuse_rd_sys_part1_data5_reg_t;
/** Type of rd_sys_part1_data6 register
* Register $n of BLOCK2 (system).
*/
typedef union {
struct {
/** sys_data_part1_6 : RO; bitpos: [31:0]; default: 0;
* Stores the sixth 32 bits of the first part of system data.
*/
uint32_t sys_data_part1_6:32;
};
uint32_t val;
} efuse_rd_sys_part1_data6_reg_t;
/** Type of rd_sys_part1_data7 register
* Register $n of BLOCK2 (system).
*/
typedef union {
struct {
/** sys_data_part1_7 : RO; bitpos: [31:0]; default: 0;
* Stores the seventh 32 bits of the first part of system data.
*/
uint32_t sys_data_part1_7:32;
};
uint32_t val;
} efuse_rd_sys_part1_data7_reg_t;
/** Type of rd_usr_data0 register
* Register $n of BLOCK3 (user).
*/
typedef union {
struct {
/** usr_data0 : RO; bitpos: [31:0]; default: 0;
* Stores the zeroth 32 bits of BLOCK3 (user).
*/
uint32_t usr_data0:32;
};
uint32_t val;
} efuse_rd_usr_data0_reg_t;
/** Type of rd_usr_data1 register
* Register $n of BLOCK3 (user).
*/
typedef union {
struct {
/** usr_data1 : RO; bitpos: [31:0]; default: 0;
* Stores the first 32 bits of BLOCK3 (user).
*/
uint32_t usr_data1:32;
};
uint32_t val;
} efuse_rd_usr_data1_reg_t;
/** Type of rd_usr_data2 register
* Register $n of BLOCK3 (user).
*/
typedef union {
struct {
/** usr_data2 : RO; bitpos: [31:0]; default: 0;
* Stores the second 32 bits of BLOCK3 (user).
*/
uint32_t usr_data2:32;
};
uint32_t val;
} efuse_rd_usr_data2_reg_t;
/** Type of rd_usr_data3 register
* Register $n of BLOCK3 (user).
*/
typedef union {
struct {
/** usr_data3 : RO; bitpos: [31:0]; default: 0;
* Stores the third 32 bits of BLOCK3 (user).
*/
uint32_t usr_data3:32;
};
uint32_t val;
} efuse_rd_usr_data3_reg_t;
/** Type of rd_usr_data4 register
* Register $n of BLOCK3 (user).
*/
typedef union {
struct {
/** usr_data4 : RO; bitpos: [31:0]; default: 0;
* Stores the fourth 32 bits of BLOCK3 (user).
*/
uint32_t usr_data4:32;
};
uint32_t val;
} efuse_rd_usr_data4_reg_t;
/** Type of rd_usr_data5 register
* Register $n of BLOCK3 (user).
*/
typedef union {
struct {
/** usr_data5 : RO; bitpos: [31:0]; default: 0;
* Stores the fifth 32 bits of BLOCK3 (user).
*/
uint32_t usr_data5:32;
};
uint32_t val;
} efuse_rd_usr_data5_reg_t;
/** Type of rd_usr_data6 register
* Register $n of BLOCK3 (user).
*/
typedef union {
struct {
/** usr_data6 : RO; bitpos: [31:0]; default: 0;
* Stores the sixth 32 bits of BLOCK3 (user).
*/
uint32_t usr_data6:32;
};
uint32_t val;
} efuse_rd_usr_data6_reg_t;
/** Type of rd_usr_data7 register
* Register $n of BLOCK3 (user).
*/
typedef union {
struct {
/** usr_data7 : RO; bitpos: [31:0]; default: 0;
* Stores the seventh 32 bits of BLOCK3 (user).
*/
uint32_t usr_data7:32;
};
uint32_t val;
} efuse_rd_usr_data7_reg_t;
/** Type of rd_key0_data0 register
* Register $n of BLOCK4 (KEY0).
*/
typedef union {
struct {
/** key0_data0 : RO; bitpos: [31:0]; default: 0;
* Stores the zeroth 32 bits of KEY0.
*/
uint32_t key0_data0:32;
};
uint32_t val;
} efuse_rd_key0_data0_reg_t;
/** Type of rd_key0_data1 register
* Register $n of BLOCK4 (KEY0).
*/
typedef union {
struct {
/** key0_data1 : RO; bitpos: [31:0]; default: 0;
* Stores the first 32 bits of KEY0.
*/
uint32_t key0_data1:32;
};
uint32_t val;
} efuse_rd_key0_data1_reg_t;
/** Type of rd_key0_data2 register
* Register $n of BLOCK4 (KEY0).
*/
typedef union {
struct {
/** key0_data2 : RO; bitpos: [31:0]; default: 0;
* Stores the second 32 bits of KEY0.
*/
uint32_t key0_data2:32;
};
uint32_t val;
} efuse_rd_key0_data2_reg_t;
/** Type of rd_key0_data3 register
* Register $n of BLOCK4 (KEY0).
*/
typedef union {
struct {
/** key0_data3 : RO; bitpos: [31:0]; default: 0;
* Stores the third 32 bits of KEY0.
*/
uint32_t key0_data3:32;
};
uint32_t val;
} efuse_rd_key0_data3_reg_t;
/** Type of rd_key0_data4 register
* Register $n of BLOCK4 (KEY0).
*/
typedef union {
struct {
/** key0_data4 : RO; bitpos: [31:0]; default: 0;
* Stores the fourth 32 bits of KEY0.
*/
uint32_t key0_data4:32;
};
uint32_t val;
} efuse_rd_key0_data4_reg_t;
/** Type of rd_key0_data5 register
* Register $n of BLOCK4 (KEY0).
*/
typedef union {
struct {
/** key0_data5 : RO; bitpos: [31:0]; default: 0;
* Stores the fifth 32 bits of KEY0.
*/
uint32_t key0_data5:32;
};
uint32_t val;
} efuse_rd_key0_data5_reg_t;
/** Type of rd_key0_data6 register
* Register $n of BLOCK4 (KEY0).
*/
typedef union {
struct {
/** key0_data6 : RO; bitpos: [31:0]; default: 0;
* Stores the sixth 32 bits of KEY0.
*/
uint32_t key0_data6:32;
};
uint32_t val;
} efuse_rd_key0_data6_reg_t;
/** Type of rd_key0_data7 register
* Register $n of BLOCK4 (KEY0).
*/
typedef union {
struct {
/** key0_data7 : RO; bitpos: [31:0]; default: 0;
* Stores the seventh 32 bits of KEY0.
*/
uint32_t key0_data7:32;
};
uint32_t val;
} efuse_rd_key0_data7_reg_t;
/** Type of rd_key1_data0 register
* Register $n of BLOCK5 (KEY1).
*/
typedef union {
struct {
/** key1_data0 : RO; bitpos: [31:0]; default: 0;
* Stores the zeroth 32 bits of KEY1.
*/
uint32_t key1_data0:32;
};
uint32_t val;
} efuse_rd_key1_data0_reg_t;
/** Type of rd_key1_data1 register
* Register $n of BLOCK5 (KEY1).
*/
typedef union {
struct {
/** key1_data1 : RO; bitpos: [31:0]; default: 0;
* Stores the first 32 bits of KEY1.
*/
uint32_t key1_data1:32;
};
uint32_t val;
} efuse_rd_key1_data1_reg_t;
/** Type of rd_key1_data2 register
* Register $n of BLOCK5 (KEY1).
*/
typedef union {
struct {
/** key1_data2 : RO; bitpos: [31:0]; default: 0;
* Stores the second 32 bits of KEY1.
*/
uint32_t key1_data2:32;
};
uint32_t val;
} efuse_rd_key1_data2_reg_t;
/** Type of rd_key1_data3 register
* Register $n of BLOCK5 (KEY1).
*/
typedef union {
struct {
/** key1_data3 : RO; bitpos: [31:0]; default: 0;
* Stores the third 32 bits of KEY1.
*/
uint32_t key1_data3:32;
};
uint32_t val;
} efuse_rd_key1_data3_reg_t;
/** Type of rd_key1_data4 register
* Register $n of BLOCK5 (KEY1).
*/
typedef union {
struct {
/** key1_data4 : RO; bitpos: [31:0]; default: 0;
* Stores the fourth 32 bits of KEY1.
*/
uint32_t key1_data4:32;
};
uint32_t val;
} efuse_rd_key1_data4_reg_t;
/** Type of rd_key1_data5 register
* Register $n of BLOCK5 (KEY1).
*/
typedef union {
struct {
/** key1_data5 : RO; bitpos: [31:0]; default: 0;
* Stores the fifth 32 bits of KEY1.
*/
uint32_t key1_data5:32;
};
uint32_t val;
} efuse_rd_key1_data5_reg_t;
/** Type of rd_key1_data6 register
* Register $n of BLOCK5 (KEY1).
*/
typedef union {
struct {
/** key1_data6 : RO; bitpos: [31:0]; default: 0;
* Stores the sixth 32 bits of KEY1.
*/
uint32_t key1_data6:32;
};
uint32_t val;
} efuse_rd_key1_data6_reg_t;
/** Type of rd_key1_data7 register
* Register $n of BLOCK5 (KEY1).
*/
typedef union {
struct {
/** key1_data7 : RO; bitpos: [31:0]; default: 0;
* Stores the seventh 32 bits of KEY1.
*/
uint32_t key1_data7:32;
};
uint32_t val;
} efuse_rd_key1_data7_reg_t;
/** Type of rd_key2_data0 register
* Register $n of BLOCK6 (KEY2).
*/
typedef union {
struct {
/** key2_data0 : RO; bitpos: [31:0]; default: 0;
* Stores the zeroth 32 bits of KEY2.
*/
uint32_t key2_data0:32;
};
uint32_t val;
} efuse_rd_key2_data0_reg_t;
/** Type of rd_key2_data1 register
* Register $n of BLOCK6 (KEY2).
*/
typedef union {
struct {
/** key2_data1 : RO; bitpos: [31:0]; default: 0;
* Stores the first 32 bits of KEY2.
*/
uint32_t key2_data1:32;
};
uint32_t val;
} efuse_rd_key2_data1_reg_t;
/** Type of rd_key2_data2 register
* Register $n of BLOCK6 (KEY2).
*/
typedef union {
struct {
/** key2_data2 : RO; bitpos: [31:0]; default: 0;
* Stores the second 32 bits of KEY2.
*/
uint32_t key2_data2:32;
};
uint32_t val;
} efuse_rd_key2_data2_reg_t;
/** Type of rd_key2_data3 register
* Register $n of BLOCK6 (KEY2).
*/
typedef union {
struct {
/** key2_data3 : RO; bitpos: [31:0]; default: 0;
* Stores the third 32 bits of KEY2.
*/
uint32_t key2_data3:32;
};
uint32_t val;
} efuse_rd_key2_data3_reg_t;
/** Type of rd_key2_data4 register
* Register $n of BLOCK6 (KEY2).
*/
typedef union {
struct {
/** key2_data4 : RO; bitpos: [31:0]; default: 0;
* Stores the fourth 32 bits of KEY2.
*/
uint32_t key2_data4:32;
};
uint32_t val;
} efuse_rd_key2_data4_reg_t;
/** Type of rd_key2_data5 register
* Register $n of BLOCK6 (KEY2).
*/
typedef union {
struct {
/** key2_data5 : RO; bitpos: [31:0]; default: 0;
* Stores the fifth 32 bits of KEY2.
*/
uint32_t key2_data5:32;
};
uint32_t val;
} efuse_rd_key2_data5_reg_t;
/** Type of rd_key2_data6 register
* Register $n of BLOCK6 (KEY2).
*/
typedef union {
struct {
/** key2_data6 : RO; bitpos: [31:0]; default: 0;
* Stores the sixth 32 bits of KEY2.
*/
uint32_t key2_data6:32;
};
uint32_t val;
} efuse_rd_key2_data6_reg_t;
/** Type of rd_key2_data7 register
* Register $n of BLOCK6 (KEY2).
*/
typedef union {
struct {
/** key2_data7 : RO; bitpos: [31:0]; default: 0;
* Stores the seventh 32 bits of KEY2.
*/
uint32_t key2_data7:32;
};
uint32_t val;
} efuse_rd_key2_data7_reg_t;
/** Type of rd_key3_data0 register
* Register $n of BLOCK7 (KEY3).
*/
typedef union {
struct {
/** key3_data0 : RO; bitpos: [31:0]; default: 0;
* Stores the zeroth 32 bits of KEY3.
*/
uint32_t key3_data0:32;
};
uint32_t val;
} efuse_rd_key3_data0_reg_t;
/** Type of rd_key3_data1 register
* Register $n of BLOCK7 (KEY3).
*/
typedef union {
struct {
/** key3_data1 : RO; bitpos: [31:0]; default: 0;
* Stores the first 32 bits of KEY3.
*/
uint32_t key3_data1:32;
};
uint32_t val;
} efuse_rd_key3_data1_reg_t;
/** Type of rd_key3_data2 register
* Register $n of BLOCK7 (KEY3).
*/
typedef union {
struct {
/** key3_data2 : RO; bitpos: [31:0]; default: 0;
* Stores the second 32 bits of KEY3.
*/
uint32_t key3_data2:32;
};
uint32_t val;
} efuse_rd_key3_data2_reg_t;
/** Type of rd_key3_data3 register
* Register $n of BLOCK7 (KEY3).
*/
typedef union {
struct {
/** key3_data3 : RO; bitpos: [31:0]; default: 0;
* Stores the third 32 bits of KEY3.
*/
uint32_t key3_data3:32;
};
uint32_t val;
} efuse_rd_key3_data3_reg_t;
/** Type of rd_key3_data4 register
* Register $n of BLOCK7 (KEY3).
*/
typedef union {
struct {
/** key3_data4 : RO; bitpos: [31:0]; default: 0;
* Stores the fourth 32 bits of KEY3.
*/
uint32_t key3_data4:32;
};
uint32_t val;
} efuse_rd_key3_data4_reg_t;
/** Type of rd_key3_data5 register
* Register $n of BLOCK7 (KEY3).
*/
typedef union {
struct {
/** key3_data5 : RO; bitpos: [31:0]; default: 0;
* Stores the fifth 32 bits of KEY3.
*/
uint32_t key3_data5:32;
};
uint32_t val;
} efuse_rd_key3_data5_reg_t;
/** Type of rd_key3_data6 register
* Register $n of BLOCK7 (KEY3).
*/
typedef union {
struct {
/** key3_data6 : RO; bitpos: [31:0]; default: 0;
* Stores the sixth 32 bits of KEY3.
*/
uint32_t key3_data6:32;
};
uint32_t val;
} efuse_rd_key3_data6_reg_t;
/** Type of rd_key3_data7 register
* Register $n of BLOCK7 (KEY3).
*/
typedef union {
struct {
/** key3_data7 : RO; bitpos: [31:0]; default: 0;
* Stores the seventh 32 bits of KEY3.
*/
uint32_t key3_data7:32;
};
uint32_t val;
} efuse_rd_key3_data7_reg_t;
/** Type of rd_key4_data0 register
* Register $n of BLOCK8 (KEY4).
*/
typedef union {
struct {
/** key4_data0 : RO; bitpos: [31:0]; default: 0;
* Stores the zeroth 32 bits of KEY4.
*/
uint32_t key4_data0:32;
};
uint32_t val;
} efuse_rd_key4_data0_reg_t;
/** Type of rd_key4_data1 register
* Register $n of BLOCK8 (KEY4).
*/
typedef union {
struct {
/** key4_data1 : RO; bitpos: [31:0]; default: 0;
* Stores the first 32 bits of KEY4.
*/
uint32_t key4_data1:32;
};
uint32_t val;
} efuse_rd_key4_data1_reg_t;
/** Type of rd_key4_data2 register
* Register $n of BLOCK8 (KEY4).
*/
typedef union {
struct {
/** key4_data2 : RO; bitpos: [31:0]; default: 0;
* Stores the second 32 bits of KEY4.
*/
uint32_t key4_data2:32;
};
uint32_t val;
} efuse_rd_key4_data2_reg_t;
/** Type of rd_key4_data3 register
* Register $n of BLOCK8 (KEY4).
*/
typedef union {
struct {
/** key4_data3 : RO; bitpos: [31:0]; default: 0;
* Stores the third 32 bits of KEY4.
*/
uint32_t key4_data3:32;
};
uint32_t val;
} efuse_rd_key4_data3_reg_t;
/** Type of rd_key4_data4 register
* Register $n of BLOCK8 (KEY4).
*/
typedef union {
struct {
/** key4_data4 : RO; bitpos: [31:0]; default: 0;
* Stores the fourth 32 bits of KEY4.
*/
uint32_t key4_data4:32;
};
uint32_t val;
} efuse_rd_key4_data4_reg_t;
/** Type of rd_key4_data5 register
* Register $n of BLOCK8 (KEY4).
*/
typedef union {
struct {
/** key4_data5 : RO; bitpos: [31:0]; default: 0;
* Stores the fifth 32 bits of KEY4.
*/
uint32_t key4_data5:32;
};
uint32_t val;
} efuse_rd_key4_data5_reg_t;
/** Type of rd_key4_data6 register
* Register $n of BLOCK8 (KEY4).
*/
typedef union {
struct {
/** key4_data6 : RO; bitpos: [31:0]; default: 0;
* Stores the sixth 32 bits of KEY4.
*/
uint32_t key4_data6:32;
};
uint32_t val;
} efuse_rd_key4_data6_reg_t;
/** Type of rd_key4_data7 register
* Register $n of BLOCK8 (KEY4).
*/
typedef union {
struct {
/** key4_data7 : RO; bitpos: [31:0]; default: 0;
* Stores the seventh 32 bits of KEY4.
*/
uint32_t key4_data7:32;
};
uint32_t val;
} efuse_rd_key4_data7_reg_t;
/** Type of rd_key5_data0 register
* Register $n of BLOCK9 (KEY5).
*/
typedef union {
struct {
/** key5_data0 : RO; bitpos: [31:0]; default: 0;
* Stores the zeroth 32 bits of KEY5.
*/
uint32_t key5_data0:32;
};
uint32_t val;
} efuse_rd_key5_data0_reg_t;
/** Type of rd_key5_data1 register
* Register $n of BLOCK9 (KEY5).
*/
typedef union {
struct {
/** key5_data1 : RO; bitpos: [31:0]; default: 0;
* Stores the first 32 bits of KEY5.
*/
uint32_t key5_data1:32;
};
uint32_t val;
} efuse_rd_key5_data1_reg_t;
/** Type of rd_key5_data2 register
* Register $n of BLOCK9 (KEY5).
*/
typedef union {
struct {
/** key5_data2 : RO; bitpos: [31:0]; default: 0;
* Stores the second 32 bits of KEY5.
*/
uint32_t key5_data2:32;
};
uint32_t val;
} efuse_rd_key5_data2_reg_t;
/** Type of rd_key5_data3 register
* Register $n of BLOCK9 (KEY5).
*/
typedef union {
struct {
/** key5_data3 : RO; bitpos: [31:0]; default: 0;
* Stores the third 32 bits of KEY5.
*/
uint32_t key5_data3:32;
};
uint32_t val;
} efuse_rd_key5_data3_reg_t;
/** Type of rd_key5_data4 register
* Register $n of BLOCK9 (KEY5).
*/
typedef union {
struct {
/** key5_data4 : RO; bitpos: [31:0]; default: 0;
* Stores the fourth 32 bits of KEY5.
*/
uint32_t key5_data4:32;
};
uint32_t val;
} efuse_rd_key5_data4_reg_t;
/** Type of rd_key5_data5 register
* Register $n of BLOCK9 (KEY5).
*/
typedef union {
struct {
/** key5_data5 : RO; bitpos: [31:0]; default: 0;
* Stores the fifth 32 bits of KEY5.
*/
uint32_t key5_data5:32;
};
uint32_t val;
} efuse_rd_key5_data5_reg_t;
/** Type of rd_key5_data6 register
* Register $n of BLOCK9 (KEY5).
*/
typedef union {
struct {
/** key5_data6 : RO; bitpos: [31:0]; default: 0;
* Stores the sixth 32 bits of KEY5.
*/
uint32_t key5_data6:32;
};
uint32_t val;
} efuse_rd_key5_data6_reg_t;
/** Type of rd_key5_data7 register
* Register $n of BLOCK9 (KEY5).
*/
typedef union {
struct {
/** key5_data7 : RO; bitpos: [31:0]; default: 0;
* Stores the seventh 32 bits of KEY5.
*/
uint32_t key5_data7:32;
};
uint32_t val;
} efuse_rd_key5_data7_reg_t;
/** Type of rd_sys_part2_data0 register
* Register $n of BLOCK10 (system).
*/
typedef union {
struct {
/** sys_data_part2_0 : RO; bitpos: [31:0]; default: 0;
* Stores the $nth 32 bits of the 2nd part of system data.
*/
uint32_t sys_data_part2_0:32;
};
uint32_t val;
} efuse_rd_sys_part2_data0_reg_t;
/** Type of rd_sys_part2_data1 register
* Register $n of BLOCK9 (KEY5).
*/
typedef union {
struct {
/** sys_data_part2_1 : RO; bitpos: [31:0]; default: 0;
* Stores the $nth 32 bits of the 2nd part of system data.
*/
uint32_t sys_data_part2_1:32;
};
uint32_t val;
} efuse_rd_sys_part2_data1_reg_t;
/** Type of rd_sys_part2_data2 register
* Register $n of BLOCK10 (system).
*/
typedef union {
struct {
/** sys_data_part2_2 : RO; bitpos: [31:0]; default: 0;
* Stores the $nth 32 bits of the 2nd part of system data.
*/
uint32_t sys_data_part2_2:32;
};
uint32_t val;
} efuse_rd_sys_part2_data2_reg_t;
/** Type of rd_sys_part2_data3 register
* Register $n of BLOCK10 (system).
*/
typedef union {
struct {
/** sys_data_part2_3 : RO; bitpos: [31:0]; default: 0;
* Stores the $nth 32 bits of the 2nd part of system data.
*/
uint32_t sys_data_part2_3:32;
};
uint32_t val;
} efuse_rd_sys_part2_data3_reg_t;
/** Type of rd_sys_part2_data4 register
* Register $n of BLOCK10 (system).
*/
typedef union {
struct {
/** sys_data_part2_4 : RO; bitpos: [31:0]; default: 0;
* Stores the $nth 32 bits of the 2nd part of system data.
*/
uint32_t sys_data_part2_4:32;
};
uint32_t val;
} efuse_rd_sys_part2_data4_reg_t;
/** Type of rd_sys_part2_data5 register
* Register $n of BLOCK10 (system).
*/
typedef union {
struct {
/** sys_data_part2_5 : RO; bitpos: [31:0]; default: 0;
* Stores the $nth 32 bits of the 2nd part of system data.
*/
uint32_t sys_data_part2_5:32;
};
uint32_t val;
} efuse_rd_sys_part2_data5_reg_t;
/** Type of rd_sys_part2_data6 register
* Register $n of BLOCK10 (system).
*/
typedef union {
struct {
/** sys_data_part2_6 : RO; bitpos: [31:0]; default: 0;
* Stores the $nth 32 bits of the 2nd part of system data.
*/
uint32_t sys_data_part2_6:32;
};
uint32_t val;
} efuse_rd_sys_part2_data6_reg_t;
/** Type of rd_sys_part2_data7 register
* Register $n of BLOCK10 (system).
*/
typedef union {
struct {
/** sys_data_part2_7 : RO; bitpos: [31:0]; default: 0;
* Stores the $nth 32 bits of the 2nd part of system data.
*/
uint32_t sys_data_part2_7:32;
};
uint32_t val;
} efuse_rd_sys_part2_data7_reg_t;
/** Type of rd_repeat_err0 register
* Programming error record register 0 of BLOCK0.
*/
typedef union {
struct {
/** rd_dis_err : RO; bitpos: [6:0]; default: 0;
* If any bit in RD_DIS is 1, then it indicates a programming error.
*/
uint32_t rd_dis_err:7;
/** rpt4_reserved5_err : RO; bitpos: [7]; default: 0;
* Reserved.
*/
uint32_t rpt4_reserved5_err:1;
/** dis_icache_err : RO; bitpos: [8]; default: 0;
* If DIS_ICACHE is 1, then it indicates a programming error.
*/
uint32_t dis_icache_err:1;
/** dis_usb_jtag_err : RO; bitpos: [9]; default: 0;
* If DIS_USB_JTAG is 1, then it indicates a programming error.
*/
uint32_t dis_usb_jtag_err:1;
/** dis_download_icache_err : RO; bitpos: [10]; default: 0;
* If DIS_DOWNLOAD_ICACHE is 1, then it indicates a programming error.
*/
uint32_t dis_download_icache_err:1;
/** dis_usb_device_err : RO; bitpos: [11]; default: 0;
* If DIS_USB_DEVICE is 1, then it indicates a programming error.
*/
uint32_t dis_usb_device_err:1;
/** dis_force_download_err : RO; bitpos: [12]; default: 0;
* If DIS_FORCE_DOWNLOAD is 1, then it indicates a programming error.
*/
uint32_t dis_force_download_err:1;
/** rpt4_reserved6_err : RO; bitpos: [13]; default: 0;
* Reserved.
*/
uint32_t rpt4_reserved6_err:1;
/** dis_twai_err : RO; bitpos: [14]; default: 0;
* If DIS_TWAI is 1, then it indicates a programming error.
*/
uint32_t dis_twai_err:1;
/** jtag_sel_enable_err : RO; bitpos: [15]; default: 0;
* If JTAG_SEL_ENABLE is 1, then it indicates a programming error.
*/
uint32_t jtag_sel_enable_err:1;
/** soft_dis_jtag_err : RO; bitpos: [18:16]; default: 0;
* If SOFT_DIS_JTAG is 1, then it indicates a programming error.
*/
uint32_t soft_dis_jtag_err:3;
/** dis_pad_jtag_err : RO; bitpos: [19]; default: 0;
* If DIS_PAD_JTAG is 1, then it indicates a programming error.
*/
uint32_t dis_pad_jtag_err:1;
/** dis_download_manual_encrypt_err : RO; bitpos: [20]; default: 0;
* If DIS_DOWNLOAD_MANUAL_ENCRYPT is 1, then it indicates a programming error.
*/
uint32_t dis_download_manual_encrypt_err:1;
/** usb_drefh_err : RO; bitpos: [22:21]; default: 0;
* If any bit in USB_DREFH is 1, then it indicates a programming error.
*/
uint32_t usb_drefh_err:2;
/** usb_drefl_err : RO; bitpos: [24:23]; default: 0;
* If any bit in USB_DREFL is 1, then it indicates a programming error.
*/
uint32_t usb_drefl_err:2;
/** usb_exchg_pins_err : RO; bitpos: [25]; default: 0;
* If USB_EXCHG_PINS is 1, then it indicates a programming error.
*/
uint32_t usb_exchg_pins_err:1;
/** vdd_spi_as_gpio_err : RO; bitpos: [26]; default: 0;
* If VDD_SPI_AS_GPIO is 1, then it indicates a programming error.
*/
uint32_t vdd_spi_as_gpio_err:1;
/** btlc_gpio_enable_err : RO; bitpos: [28:27]; default: 0;
* If any bit in BTLC_GPIO_ENABLE is 1, then it indicates a programming error.
*/
uint32_t btlc_gpio_enable_err:2;
/** powerglitch_en_err : RO; bitpos: [29]; default: 0;
* If POWERGLITCH_EN is 1, then it indicates a programming error.
*/
uint32_t powerglitch_en_err:1;
/** power_glitch_dsense_err : RO; bitpos: [31:30]; default: 0;
* If any bit in POWER_GLITCH_DSENSE is 1, then it indicates a programming error.
*/
uint32_t power_glitch_dsense_err:2;
};
uint32_t val;
} efuse_rd_repeat_err0_reg_t;
/** Type of rd_repeat_err1 register
* Programming error record register 1 of BLOCK0.
*/
typedef union {
struct {
/** rpt4_reserved2_err : RO; bitpos: [15:0]; default: 0;
* Reserved.
*/
uint32_t rpt4_reserved2_err:16;
/** wdt_delay_sel_err : RO; bitpos: [17:16]; default: 0;
* If any bit in WDT_DELAY_SEL is 1, then it indicates a programming error.
*/
uint32_t wdt_delay_sel_err:2;
/** spi_boot_crypt_cnt_err : RO; bitpos: [20:18]; default: 0;
* If any bit in SPI_BOOT_CRYPT_CNT is 1, then it indicates a programming error.
*/
uint32_t spi_boot_crypt_cnt_err:3;
/** secure_boot_key_revoke0_err : RO; bitpos: [21]; default: 0;
* If SECURE_BOOT_KEY_REVOKE0 is 1, then it indicates a programming error.
*/
uint32_t secure_boot_key_revoke0_err:1;
/** secure_boot_key_revoke1_err : RO; bitpos: [22]; default: 0;
* If SECURE_BOOT_KEY_REVOKE1 is 1, then it indicates a programming error.
*/
uint32_t secure_boot_key_revoke1_err:1;
/** secure_boot_key_revoke2_err : RO; bitpos: [23]; default: 0;
* If SECURE_BOOT_KEY_REVOKE2 is 1, then it indicates a programming error.
*/
uint32_t secure_boot_key_revoke2_err:1;
/** key_purpose_0_err : RO; bitpos: [27:24]; default: 0;
* If any bit in KEY_PURPOSE_0 is 1, then it indicates a programming error.
*/
uint32_t key_purpose_0_err:4;
/** key_purpose_1_err : RO; bitpos: [31:28]; default: 0;
* If any bit in KEY_PURPOSE_1 is 1, then it indicates a programming error.
*/
uint32_t key_purpose_1_err:4;
};
uint32_t val;
} efuse_rd_repeat_err1_reg_t;
/** Type of rd_repeat_err2 register
* Programming error record register 2 of BLOCK0.
*/
typedef union {
struct {
/** key_purpose_2_err : RO; bitpos: [3:0]; default: 0;
* If any bit in KEY_PURPOSE_2 is 1, then it indicates a programming error.
*/
uint32_t key_purpose_2_err:4;
/** key_purpose_3_err : RO; bitpos: [7:4]; default: 0;
* If any bit in KEY_PURPOSE_3 is 1, then it indicates a programming error.
*/
uint32_t key_purpose_3_err:4;
/** key_purpose_4_err : RO; bitpos: [11:8]; default: 0;
* If any bit in KEY_PURPOSE_4 is 1, then it indicates a programming error.
*/
uint32_t key_purpose_4_err:4;
/** key_purpose_5_err : RO; bitpos: [15:12]; default: 0;
* If any bit in KEY_PURPOSE_5 is 1, then it indicates a programming error.
*/
uint32_t key_purpose_5_err:4;
/** rpt4_reserved3_err : RO; bitpos: [19:16]; default: 0;
* Reserved.
*/
uint32_t rpt4_reserved3_err:4;
/** secure_boot_en_err : RO; bitpos: [20]; default: 0;
* If SECURE_BOOT_EN is 1, then it indicates a programming error.
*/
uint32_t secure_boot_en_err:1;
/** secure_boot_aggressive_revoke_err : RO; bitpos: [21]; default: 0;
* If SECURE_BOOT_AGGRESSIVE_REVOKE is 1, then it indicates a programming error.
*/
uint32_t secure_boot_aggressive_revoke_err:1;
/** rpt4_reserved0_err : RO; bitpos: [27:22]; default: 0;
* Reserved.
*/
uint32_t rpt4_reserved0_err:6;
/** flash_tpuw_err : RO; bitpos: [31:28]; default: 0;
* If any bit in FLASH_TPUM is 1, then it indicates a programming error.
*/
uint32_t flash_tpuw_err:4;
};
uint32_t val;
} efuse_rd_repeat_err2_reg_t;
/** Type of rd_repeat_err3 register
* Programming error record register 3 of BLOCK0.
*/
typedef union {
struct {
/** dis_download_mode_err : RO; bitpos: [0]; default: 0;
* If DIS_DOWNLOAD_MODE is 1, then it indicates a programming error.
*/
uint32_t dis_download_mode_err:1;
/** dis_direct_boot_err : RO; bitpos: [1]; default: 0;
* If DIS_DIRECT_BOOT is 1, then it indicates a programming error.
*/
uint32_t dis_direct_boot_err:1;
/** dis_usb_serial_jtag_rom_print_err : RO; bitpos: [2]; default: 0;
* If DIS_USB_SERIAL_JTAG_ROM_PRINT is 1, then it indicates a programming error.
*/
uint32_t dis_usb_serial_jtag_rom_print_err:1;
/** rpt4_reserved8_err : RO; bitpos: [3]; default: 0;
* Reserved.
*/
uint32_t rpt4_reserved8_err:1;
/** dis_usb_serial_jtag_download_mode_err : RO; bitpos: [4]; default: 0;
* If DIS_USB_SERIAL_JTAG_DOWNLOAD_MODE is 1, then it indicates a programming error.
*/
uint32_t dis_usb_serial_jtag_download_mode_err:1;
/** enable_security_download_err : RO; bitpos: [5]; default: 0;
* If ENABLE_SECURITY_DOWNLOAD is 1, then it indicates a programming error.
*/
uint32_t enable_security_download_err:1;
/** uart_print_control_err : RO; bitpos: [7:6]; default: 0;
* If any bit in UART_PRINT_CONTROL is 1, then it indicates a programming error.
*/
uint32_t uart_print_control_err:2;
/** rpt4_reserved7 : RO; bitpos: [12:8]; default: 0;
* Reserved.
*/
uint32_t rpt4_reserved7:5;
/** force_send_resume_err : RO; bitpos: [13]; default: 0;
* If FORCE_SEND_RESUME is 1, then it indicates a programming error.
*/
uint32_t force_send_resume_err:1;
/** secure_version_err : RO; bitpos: [29:14]; default: 0;
* If any bit in SECURE_VERSION is 1, then it indicates a programming error.
*/
uint32_t secure_version_err:16;
/** rpt4_reserved1_err : RO; bitpos: [31:30]; default: 0;
* Reserved.
*/
uint32_t rpt4_reserved1_err:2;
};
uint32_t val;
} efuse_rd_repeat_err3_reg_t;
/** Type of rd_repeat_err4 register
* Programming error record register 4 of BLOCK0.
*/
typedef union {
struct {
/** rpt4_reserved4_err : RO; bitpos: [23:0]; default: 0;
* Reserved.
*/
uint32_t rpt4_reserved4_err:24;
uint32_t reserved_24:8;
};
uint32_t val;
} efuse_rd_repeat_err4_reg_t;
/** Type of rd_rs_err0 register
* Programming error record register 0 of BLOCK1-10.
*/
typedef union {
struct {
/** mac_spi_8m_err_num : RO; bitpos: [2:0]; default: 0;
* The value of this signal means the number of error bytes.
*/
uint32_t mac_spi_8m_err_num:3;
/** mac_spi_8m_fail : RO; bitpos: [3]; default: 0;
* 0: Means no failure and that the data of MAC_SPI_8M is reliable 1: Means that
* programming user data failed and the number of error bytes is over 6.
*/
uint32_t mac_spi_8m_fail:1;
/** sys_part1_num : RO; bitpos: [6:4]; default: 0;
* The value of this signal means the number of error bytes.
*/
uint32_t sys_part1_num:3;
/** sys_part1_fail : RO; bitpos: [7]; default: 0;
* 0: Means no failure and that the data of system part1 is reliable 1: Means that
* programming user data failed and the number of error bytes is over 6.
*/
uint32_t sys_part1_fail:1;
/** usr_data_err_num : RO; bitpos: [10:8]; default: 0;
* The value of this signal means the number of error bytes.
*/
uint32_t usr_data_err_num:3;
/** usr_data_fail : RO; bitpos: [11]; default: 0;
* 0: Means no failure and that the user data is reliable 1: Means that programming
* user data failed and the number of error bytes is over 6.
*/
uint32_t usr_data_fail:1;
/** key0_err_num : RO; bitpos: [14:12]; default: 0;
* The value of this signal means the number of error bytes.
*/
uint32_t key0_err_num:3;
/** key0_fail : RO; bitpos: [15]; default: 0;
* 0: Means no failure and that the data of key$n is reliable 1: Means that
* programming key$n failed and the number of error bytes is over 6.
*/
uint32_t key0_fail:1;
/** key1_err_num : RO; bitpos: [18:16]; default: 0;
* The value of this signal means the number of error bytes.
*/
uint32_t key1_err_num:3;
/** key1_fail : RO; bitpos: [19]; default: 0;
* 0: Means no failure and that the data of key$n is reliable 1: Means that
* programming key$n failed and the number of error bytes is over 6.
*/
uint32_t key1_fail:1;
/** key2_err_num : RO; bitpos: [22:20]; default: 0;
* The value of this signal means the number of error bytes.
*/
uint32_t key2_err_num:3;
/** key2_fail : RO; bitpos: [23]; default: 0;
* 0: Means no failure and that the data of key$n is reliable 1: Means that
* programming key$n failed and the number of error bytes is over 6.
*/
uint32_t key2_fail:1;
/** key3_err_num : RO; bitpos: [26:24]; default: 0;
* The value of this signal means the number of error bytes.
*/
uint32_t key3_err_num:3;
/** key3_fail : RO; bitpos: [27]; default: 0;
* 0: Means no failure and that the data of key$n is reliable 1: Means that
* programming key$n failed and the number of error bytes is over 6.
*/
uint32_t key3_fail:1;
/** key4_err_num : RO; bitpos: [30:28]; default: 0;
* The value of this signal means the number of error bytes.
*/
uint32_t key4_err_num:3;
/** key4_fail : RO; bitpos: [31]; default: 0;
* 0: Means no failure and that the data of key$n is reliable 1: Means that
* programming key$n failed and the number of error bytes is over 6.
*/
uint32_t key4_fail:1;
};
uint32_t val;
} efuse_rd_rs_err0_reg_t;
/** Type of rd_rs_err1 register
* Programming error record register 1 of BLOCK1-10.
*/
typedef union {
struct {
/** key5_err_num : RO; bitpos: [2:0]; default: 0;
* The value of this signal means the number of error bytes.
*/
uint32_t key5_err_num:3;
/** key5_fail : RO; bitpos: [3]; default: 0;
* 0: Means no failure and that the data of KEY5 is reliable 1: Means that programming
* user data failed and the number of error bytes is over 6.
*/
uint32_t key5_fail:1;
/** sys_part2_err_num : RO; bitpos: [6:4]; default: 0;
* The value of this signal means the number of error bytes.
*/
uint32_t sys_part2_err_num:3;
/** sys_part2_fail : RO; bitpos: [7]; default: 0;
* 0: Means no failure and that the data of system part2 is reliable 1: Means that
* programming user data failed and the number of error bytes is over 6.
*/
uint32_t sys_part2_fail:1;
uint32_t reserved_8:24;
};
uint32_t val;
} efuse_rd_rs_err1_reg_t;
/** Type of clk register
* eFuse clcok configuration register.
*/
typedef union {
struct {
/** mem_force_pd : R/W; bitpos: [0]; default: 0;
* Set this bit to force eFuse SRAM into power-saving mode.
*/
uint32_t mem_force_pd:1;
/** mem_clk_force_on : R/W; bitpos: [1]; default: 1;
* Set this bit and force to activate clock signal of eFuse SRAM.
*/
uint32_t mem_clk_force_on:1;
/** mem_force_pu : R/W; bitpos: [2]; default: 0;
* Set this bit to force eFuse SRAM into working mode.
*/
uint32_t mem_force_pu:1;
uint32_t reserved_3:13;
/** clk_en : R/W; bitpos: [16]; default: 0;
* Set this bit and force to enable clock signal of eFuse memory.
*/
uint32_t clk_en:1;
uint32_t reserved_17:15;
};
uint32_t val;
} efuse_clk_reg_t;
/** Type of conf register
* eFuse operation mode configuraiton register
*/
typedef union {
struct {
/** op_code : R/W; bitpos: [15:0]; default: 0;
* 0x5A5A: Operate programming command 0x5AA5: Operate read command.
*/
uint32_t op_code:16;
uint32_t reserved_16:16;
};
uint32_t val;
} efuse_conf_reg_t;
/** Type of status register
* eFuse status register.
*/
typedef union {
struct {
/** state : RO; bitpos: [3:0]; default: 0;
* Indicates the state of the eFuse state machine.
*/
uint32_t state:4;
/** otp_load_sw : RO; bitpos: [4]; default: 0;
* The value of OTP_LOAD_SW.
*/
uint32_t otp_load_sw:1;
/** otp_vddq_c_sync2 : RO; bitpos: [5]; default: 0;
* The value of OTP_VDDQ_C_SYNC2.
*/
uint32_t otp_vddq_c_sync2:1;
/** otp_strobe_sw : RO; bitpos: [6]; default: 0;
* The value of OTP_STROBE_SW.
*/
uint32_t otp_strobe_sw:1;
/** otp_csb_sw : RO; bitpos: [7]; default: 0;
* The value of OTP_CSB_SW.
*/
uint32_t otp_csb_sw:1;
/** otp_pgenb_sw : RO; bitpos: [8]; default: 0;
* The value of OTP_PGENB_SW.
*/
uint32_t otp_pgenb_sw:1;
/** otp_vddq_is_sw : RO; bitpos: [9]; default: 0;
* The value of OTP_VDDQ_IS_SW.
*/
uint32_t otp_vddq_is_sw:1;
/** repeat_err_cnt : RO; bitpos: [17:10]; default: 0;
* Indicates the number of error bits during programming BLOCK0.
*/
uint32_t repeat_err_cnt:8;
uint32_t reserved_18:14;
};
uint32_t val;
} efuse_status_reg_t;
/** Type of cmd register
* eFuse command register.
*/
typedef union {
struct {
/** read_cmd : R/W; bitpos: [0]; default: 0;
* Set this bit to send read command.
*/
uint32_t read_cmd:1;
/** pgm_cmd : R/W; bitpos: [1]; default: 0;
* Set this bit to send programming command.
*/
uint32_t pgm_cmd:1;
/** blk_num : R/W; bitpos: [5:2]; default: 0;
* The serial number of the block to be programmed. Value 0-10 corresponds to block
* number 0-10, respectively.
*/
uint32_t blk_num:4;
uint32_t reserved_6:26;
};
uint32_t val;
} efuse_cmd_reg_t;
/** Type of int_raw register
* eFuse raw interrupt register.
*/
typedef union {
struct {
/** read_done_int_raw : RO; bitpos: [0]; default: 0;
* The raw bit signal for read_done interrupt.
*/
uint32_t read_done_int_raw:1;
/** pgm_done_int_raw : RO; bitpos: [1]; default: 0;
* The raw bit signal for pgm_done interrupt.
*/
uint32_t pgm_done_int_raw:1;
uint32_t reserved_2:30;
};
uint32_t val;
} efuse_int_raw_reg_t;
/** Type of int_st register
* eFuse interrupt status register.
*/
typedef union {
struct {
/** read_done_int_st : RO; bitpos: [0]; default: 0;
* The status signal for read_done interrupt.
*/
uint32_t read_done_int_st:1;
/** pgm_done_int_st : RO; bitpos: [1]; default: 0;
* The status signal for pgm_done interrupt.
*/
uint32_t pgm_done_int_st:1;
uint32_t reserved_2:30;
};
uint32_t val;
} efuse_int_st_reg_t;
/** Type of int_ena register
* eFuse interrupt enable register.
*/
typedef union {
struct {
/** read_done_int_ena : R/W; bitpos: [0]; default: 0;
* The enable signal for read_done interrupt.
*/
uint32_t read_done_int_ena:1;
/** pgm_done_int_ena : R/W; bitpos: [1]; default: 0;
* The enable signal for pgm_done interrupt.
*/
uint32_t pgm_done_int_ena:1;
uint32_t reserved_2:30;
};
uint32_t val;
} efuse_int_ena_reg_t;
/** Type of int_clr register
* eFuse interrupt clear register.
*/
typedef union {
struct {
/** read_done_int_clr : WO; bitpos: [0]; default: 0;
* The clear signal for read_done interrupt.
*/
uint32_t read_done_int_clr:1;
/** pgm_done_int_clr : WO; bitpos: [1]; default: 0;
* The clear signal for pgm_done interrupt.
*/
uint32_t pgm_done_int_clr:1;
uint32_t reserved_2:30;
};
uint32_t val;
} efuse_int_clr_reg_t;
/** Type of dac_conf register
* Controls the eFuse programming voltage.
*/
typedef union {
struct {
/** dac_clk_div : R/W; bitpos: [7:0]; default: 28;
* Controls the division factor of the rising clock of the programming voltage.
*/
uint32_t dac_clk_div:8;
/** dac_clk_pad_sel : R/W; bitpos: [8]; default: 0;
* Don't care.
*/
uint32_t dac_clk_pad_sel:1;
/** dac_num : R/W; bitpos: [16:9]; default: 255;
* Controls the rising period of the programming voltage.
*/
uint32_t dac_num:8;
/** oe_clr : R/W; bitpos: [17]; default: 0;
* Reduces the power supply of the programming voltage.
*/
uint32_t oe_clr:1;
uint32_t reserved_18:14;
};
uint32_t val;
} efuse_dac_conf_reg_t;
/** Type of rd_tim_conf register
* Configures read timing parameters.
*/
typedef union {
struct {
uint32_t reserved_0:24;
/** read_init_num : R/W; bitpos: [31:24]; default: 18;
* Configures the initial read time of eFuse.
*/
uint32_t read_init_num:8;
};
uint32_t val;
} efuse_rd_tim_conf_reg_t;
/** Type of wr_tim_conf1 register
* Configurarion register 1 of eFuse programming timing parameters.
*/
typedef union {
struct {
uint32_t reserved_0:8;
/** pwr_on_num : R/W; bitpos: [23:8]; default: 10368;
* Configures the power up time for VDDQ.
*/
uint32_t pwr_on_num:16;
uint32_t reserved_24:8;
};
uint32_t val;
} efuse_wr_tim_conf1_reg_t;
/** Type of wr_tim_conf2 register
* Configurarion register 2 of eFuse programming timing parameters.
*/
typedef union {
struct {
/** pwr_off_num : R/W; bitpos: [15:0]; default: 400;
* Configures the power outage time for VDDQ.
*/
uint32_t pwr_off_num:16;
uint32_t reserved_16:16;
};
uint32_t val;
} efuse_wr_tim_conf2_reg_t;
/** Type of date register
* eFuse version register.
*/
typedef union {
struct {
/** date : R/W; bitpos: [27:0]; default: 33583616;
* Stores eFuse version.
*/
uint32_t date:28;
uint32_t reserved_28:4;
};
uint32_t val;
} efuse_date_reg_t;
typedef struct {
volatile efuse_pgm_data0_reg_t pgm_data0;
volatile efuse_pgm_data1_reg_t pgm_data1;
volatile efuse_pgm_data2_reg_t pgm_data2;
volatile efuse_pgm_data3_reg_t pgm_data3;
volatile efuse_pgm_data4_reg_t pgm_data4;
volatile efuse_pgm_data5_reg_t pgm_data5;
volatile efuse_pgm_data6_reg_t pgm_data6;
volatile efuse_pgm_data7_reg_t pgm_data7;
volatile efuse_pgm_check_value0_reg_t pgm_check_value0;
volatile efuse_pgm_check_value1_reg_t pgm_check_value1;
volatile efuse_pgm_check_value2_reg_t pgm_check_value2;
volatile efuse_rd_wr_dis_reg_t rd_wr_dis;
volatile efuse_rd_repeat_data0_reg_t rd_repeat_data0;
volatile efuse_rd_repeat_data1_reg_t rd_repeat_data1;
volatile efuse_rd_repeat_data2_reg_t rd_repeat_data2;
volatile efuse_rd_repeat_data3_reg_t rd_repeat_data3;
volatile efuse_rd_repeat_data4_reg_t rd_repeat_data4;
volatile efuse_rd_mac_spi_sys_0_reg_t rd_mac_spi_sys_0;
volatile efuse_rd_mac_spi_sys_1_reg_t rd_mac_spi_sys_1;
volatile efuse_rd_mac_spi_sys_2_reg_t rd_mac_spi_sys_2;
volatile efuse_rd_mac_spi_sys_3_reg_t rd_mac_spi_sys_3;
volatile efuse_rd_mac_spi_sys_4_reg_t rd_mac_spi_sys_4;
volatile efuse_rd_mac_spi_sys_5_reg_t rd_mac_spi_sys_5;
volatile efuse_rd_sys_part1_data0_reg_t rd_sys_part1_data0;
volatile efuse_rd_sys_part1_data1_reg_t rd_sys_part1_data1;
volatile efuse_rd_sys_part1_data2_reg_t rd_sys_part1_data2;
volatile efuse_rd_sys_part1_data3_reg_t rd_sys_part1_data3;
volatile efuse_rd_sys_part1_data4_reg_t rd_sys_part1_data4;
volatile efuse_rd_sys_part1_data5_reg_t rd_sys_part1_data5;
volatile efuse_rd_sys_part1_data6_reg_t rd_sys_part1_data6;
volatile efuse_rd_sys_part1_data7_reg_t rd_sys_part1_data7;
volatile efuse_rd_usr_data0_reg_t rd_usr_data0;
volatile efuse_rd_usr_data1_reg_t rd_usr_data1;
volatile efuse_rd_usr_data2_reg_t rd_usr_data2;
volatile efuse_rd_usr_data3_reg_t rd_usr_data3;
volatile efuse_rd_usr_data4_reg_t rd_usr_data4;
volatile efuse_rd_usr_data5_reg_t rd_usr_data5;
volatile efuse_rd_usr_data6_reg_t rd_usr_data6;
volatile efuse_rd_usr_data7_reg_t rd_usr_data7;
volatile efuse_rd_key0_data0_reg_t rd_key0_data0;
volatile efuse_rd_key0_data1_reg_t rd_key0_data1;
volatile efuse_rd_key0_data2_reg_t rd_key0_data2;
volatile efuse_rd_key0_data3_reg_t rd_key0_data3;
volatile efuse_rd_key0_data4_reg_t rd_key0_data4;
volatile efuse_rd_key0_data5_reg_t rd_key0_data5;
volatile efuse_rd_key0_data6_reg_t rd_key0_data6;
volatile efuse_rd_key0_data7_reg_t rd_key0_data7;
volatile efuse_rd_key1_data0_reg_t rd_key1_data0;
volatile efuse_rd_key1_data1_reg_t rd_key1_data1;
volatile efuse_rd_key1_data2_reg_t rd_key1_data2;
volatile efuse_rd_key1_data3_reg_t rd_key1_data3;
volatile efuse_rd_key1_data4_reg_t rd_key1_data4;
volatile efuse_rd_key1_data5_reg_t rd_key1_data5;
volatile efuse_rd_key1_data6_reg_t rd_key1_data6;
volatile efuse_rd_key1_data7_reg_t rd_key1_data7;
volatile efuse_rd_key2_data0_reg_t rd_key2_data0;
volatile efuse_rd_key2_data1_reg_t rd_key2_data1;
volatile efuse_rd_key2_data2_reg_t rd_key2_data2;
volatile efuse_rd_key2_data3_reg_t rd_key2_data3;
volatile efuse_rd_key2_data4_reg_t rd_key2_data4;
volatile efuse_rd_key2_data5_reg_t rd_key2_data5;
volatile efuse_rd_key2_data6_reg_t rd_key2_data6;
volatile efuse_rd_key2_data7_reg_t rd_key2_data7;
volatile efuse_rd_key3_data0_reg_t rd_key3_data0;
volatile efuse_rd_key3_data1_reg_t rd_key3_data1;
volatile efuse_rd_key3_data2_reg_t rd_key3_data2;
volatile efuse_rd_key3_data3_reg_t rd_key3_data3;
volatile efuse_rd_key3_data4_reg_t rd_key3_data4;
volatile efuse_rd_key3_data5_reg_t rd_key3_data5;
volatile efuse_rd_key3_data6_reg_t rd_key3_data6;
volatile efuse_rd_key3_data7_reg_t rd_key3_data7;
volatile efuse_rd_key4_data0_reg_t rd_key4_data0;
volatile efuse_rd_key4_data1_reg_t rd_key4_data1;
volatile efuse_rd_key4_data2_reg_t rd_key4_data2;
volatile efuse_rd_key4_data3_reg_t rd_key4_data3;
volatile efuse_rd_key4_data4_reg_t rd_key4_data4;
volatile efuse_rd_key4_data5_reg_t rd_key4_data5;
volatile efuse_rd_key4_data6_reg_t rd_key4_data6;
volatile efuse_rd_key4_data7_reg_t rd_key4_data7;
volatile efuse_rd_key5_data0_reg_t rd_key5_data0;
volatile efuse_rd_key5_data1_reg_t rd_key5_data1;
volatile efuse_rd_key5_data2_reg_t rd_key5_data2;
volatile efuse_rd_key5_data3_reg_t rd_key5_data3;
volatile efuse_rd_key5_data4_reg_t rd_key5_data4;
volatile efuse_rd_key5_data5_reg_t rd_key5_data5;
volatile efuse_rd_key5_data6_reg_t rd_key5_data6;
volatile efuse_rd_key5_data7_reg_t rd_key5_data7;
volatile efuse_rd_sys_part2_data0_reg_t rd_sys_part2_data0;
volatile efuse_rd_sys_part2_data1_reg_t rd_sys_part2_data1;
volatile efuse_rd_sys_part2_data2_reg_t rd_sys_part2_data2;
volatile efuse_rd_sys_part2_data3_reg_t rd_sys_part2_data3;
volatile efuse_rd_sys_part2_data4_reg_t rd_sys_part2_data4;
volatile efuse_rd_sys_part2_data5_reg_t rd_sys_part2_data5;
volatile efuse_rd_sys_part2_data6_reg_t rd_sys_part2_data6;
volatile efuse_rd_sys_part2_data7_reg_t rd_sys_part2_data7;
volatile efuse_rd_repeat_err0_reg_t rd_repeat_err0;
volatile efuse_rd_repeat_err1_reg_t rd_repeat_err1;
volatile efuse_rd_repeat_err2_reg_t rd_repeat_err2;
volatile efuse_rd_repeat_err3_reg_t rd_repeat_err3;
uint32_t reserved_18c;
volatile efuse_rd_repeat_err4_reg_t rd_repeat_err4;
uint32_t reserved_194[11];
volatile efuse_rd_rs_err0_reg_t rd_rs_err0;
volatile efuse_rd_rs_err1_reg_t rd_rs_err1;
volatile efuse_clk_reg_t clk;
volatile efuse_conf_reg_t conf;
volatile efuse_status_reg_t status;
volatile efuse_cmd_reg_t cmd;
volatile efuse_int_raw_reg_t int_raw;
volatile efuse_int_st_reg_t int_st;
volatile efuse_int_ena_reg_t int_ena;
volatile efuse_int_clr_reg_t int_clr;
volatile efuse_dac_conf_reg_t dac_conf;
volatile efuse_rd_tim_conf_reg_t rd_tim_conf;
volatile efuse_wr_tim_conf1_reg_t wr_tim_conf1;
volatile efuse_wr_tim_conf2_reg_t wr_tim_conf2;
uint32_t reserved_1f8;
volatile efuse_date_reg_t date;
} efuse_dev_t;
extern efuse_dev_t EFUSE;
#ifndef __cplusplus
_Static_assert(sizeof(efuse_dev_t) == 0x200, "Invalid size of efuse_dev_t structure");
#endif
#ifdef __cplusplus
}
#endif
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