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esp-idf/components/efuse/esp32h4/esp_efuse_table.c
Konstantin Kondrashov 917adbb171 fix(efuse): Adds missing efuses fields for ESP32-H4
2025-03-12 17:19:50 +08:00

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/*
* SPDX-FileCopyrightText: 2017-2025 Espressif Systems (Shanghai) CO LTD
*
* SPDX-License-Identifier: Apache-2.0
*/
#include "sdkconfig.h"
#include "esp_efuse.h"
#include <assert.h>
#include "esp_efuse_table.h"
// md5_digest_table 39c442690c2273d557b5bb0db99fbe04
// This file was generated from the file esp_efuse_table.csv. DO NOT CHANGE THIS FILE MANUALLY.
// If you want to change some fields, you need to change esp_efuse_table.csv file
// then run `efuse_common_table` or `efuse_custom_table` command it will generate this file.
// To show efuse_table run the command 'show_efuse_table'.
static const esp_efuse_desc_t WR_DIS[] = {
{EFUSE_BLK0, 0, 32}, // [] Disable programming of individual eFuses,
};
static const esp_efuse_desc_t WR_DIS_RD_DIS[] = {
{EFUSE_BLK0, 0, 1}, // [] wr_dis of RD_DIS,
};
static const esp_efuse_desc_t WR_DIS_KM_DISABLE_DEPLOY_MODE[] = {
{EFUSE_BLK0, 1, 1}, // [] wr_dis of KM_DISABLE_DEPLOY_MODE,
};
static const esp_efuse_desc_t WR_DIS_KM_RND_SWITCH_CYCLE[] = {
{EFUSE_BLK0, 1, 1}, // [] wr_dis of KM_RND_SWITCH_CYCLE,
};
static const esp_efuse_desc_t WR_DIS_KM_DEPLOY_ONLY_ONCE[] = {
{EFUSE_BLK0, 1, 1}, // [] wr_dis of KM_DEPLOY_ONLY_ONCE,
};
static const esp_efuse_desc_t WR_DIS_FORCE_USE_KEY_MANAGER_KEY[] = {
{EFUSE_BLK0, 1, 1}, // [] wr_dis of FORCE_USE_KEY_MANAGER_KEY,
};
static const esp_efuse_desc_t WR_DIS_FORCE_DISABLE_SW_INIT_KEY[] = {
{EFUSE_BLK0, 1, 1}, // [] wr_dis of FORCE_DISABLE_SW_INIT_KEY,
};
static const esp_efuse_desc_t WR_DIS_KM_XTS_KEY_LENGTH_256[] = {
{EFUSE_BLK0, 1, 1}, // [] wr_dis of KM_XTS_KEY_LENGTH_256,
};
static const esp_efuse_desc_t WR_DIS_LOCK_KM_KEY[] = {
{EFUSE_BLK0, 1, 1}, // [] wr_dis of LOCK_KM_KEY,
};
static const esp_efuse_desc_t WR_DIS_DIS_USB_JTAG[] = {
{EFUSE_BLK0, 2, 1}, // [] wr_dis of DIS_USB_JTAG,
};
static const esp_efuse_desc_t WR_DIS_DIS_FORCE_DOWNLOAD[] = {
{EFUSE_BLK0, 2, 1}, // [] wr_dis of DIS_FORCE_DOWNLOAD,
};
static const esp_efuse_desc_t WR_DIS_SPI_DOWNLOAD_MSPI_DIS[] = {
{EFUSE_BLK0, 2, 1}, // [] wr_dis of SPI_DOWNLOAD_MSPI_DIS,
};
static const esp_efuse_desc_t WR_DIS_DIS_TWAI[] = {
{EFUSE_BLK0, 2, 1}, // [] wr_dis of DIS_TWAI,
};
static const esp_efuse_desc_t WR_DIS_JTAG_SEL_ENABLE[] = {
{EFUSE_BLK0, 2, 1}, // [] wr_dis of JTAG_SEL_ENABLE,
};
static const esp_efuse_desc_t WR_DIS_DIS_PAD_JTAG[] = {
{EFUSE_BLK0, 2, 1}, // [] wr_dis of DIS_PAD_JTAG,
};
static const esp_efuse_desc_t WR_DIS_DIS_DOWNLOAD_MANUAL_ENCRYPT[] = {
{EFUSE_BLK0, 2, 1}, // [] wr_dis of DIS_DOWNLOAD_MANUAL_ENCRYPT,
};
static const esp_efuse_desc_t WR_DIS_SPI_BOOT_CRYPT_CNT[] = {
{EFUSE_BLK0, 4, 1}, // [] wr_dis of SPI_BOOT_CRYPT_CNT,
};
static const esp_efuse_desc_t WR_DIS_SECURE_BOOT_KEY_REVOKE0[] = {
{EFUSE_BLK0, 5, 1}, // [] wr_dis of SECURE_BOOT_KEY_REVOKE0,
};
static const esp_efuse_desc_t WR_DIS_SECURE_BOOT_KEY_REVOKE1[] = {
{EFUSE_BLK0, 6, 1}, // [] wr_dis of SECURE_BOOT_KEY_REVOKE1,
};
static const esp_efuse_desc_t WR_DIS_SECURE_BOOT_KEY_REVOKE2[] = {
{EFUSE_BLK0, 7, 1}, // [] wr_dis of SECURE_BOOT_KEY_REVOKE2,
};
static const esp_efuse_desc_t WR_DIS_KEY_PURPOSE_0[] = {
{EFUSE_BLK0, 8, 1}, // [WR_DIS.KEY0_PURPOSE] wr_dis of KEY_PURPOSE_0,
};
static const esp_efuse_desc_t WR_DIS_KEY_PURPOSE_1[] = {
{EFUSE_BLK0, 9, 1}, // [WR_DIS.KEY1_PURPOSE] wr_dis of KEY_PURPOSE_1,
};
static const esp_efuse_desc_t WR_DIS_KEY_PURPOSE_2[] = {
{EFUSE_BLK0, 10, 1}, // [WR_DIS.KEY2_PURPOSE] wr_dis of KEY_PURPOSE_2,
};
static const esp_efuse_desc_t WR_DIS_KEY_PURPOSE_3[] = {
{EFUSE_BLK0, 11, 1}, // [WR_DIS.KEY3_PURPOSE] wr_dis of KEY_PURPOSE_3,
};
static const esp_efuse_desc_t WR_DIS_KEY_PURPOSE_4[] = {
{EFUSE_BLK0, 12, 1}, // [WR_DIS.KEY4_PURPOSE] wr_dis of KEY_PURPOSE_4,
};
static const esp_efuse_desc_t WR_DIS_KEY_PURPOSE_5[] = {
{EFUSE_BLK0, 13, 1}, // [WR_DIS.KEY5_PURPOSE] wr_dis of KEY_PURPOSE_5,
};
static const esp_efuse_desc_t WR_DIS_SEC_DPA_LEVEL[] = {
{EFUSE_BLK0, 14, 1}, // [] wr_dis of SEC_DPA_LEVEL,
};
static const esp_efuse_desc_t WR_DIS_XTS_DPA_PSEUDO_LEVEL[] = {
{EFUSE_BLK0, 14, 1}, // [] wr_dis of XTS_DPA_PSEUDO_LEVEL,
};
static const esp_efuse_desc_t WR_DIS_XTS_DPA_CLK_ENABLE[] = {
{EFUSE_BLK0, 14, 1}, // [] wr_dis of XTS_DPA_CLK_ENABLE,
};
static const esp_efuse_desc_t WR_DIS_ECC_FORCE_CONST_TIME[] = {
{EFUSE_BLK0, 14, 1}, // [] wr_dis of ECC_FORCE_CONST_TIME,
};
static const esp_efuse_desc_t WR_DIS_SECURE_BOOT_EN[] = {
{EFUSE_BLK0, 15, 1}, // [] wr_dis of SECURE_BOOT_EN,
};
static const esp_efuse_desc_t WR_DIS_SECURE_BOOT_AGGRESSIVE_REVOKE[] = {
{EFUSE_BLK0, 16, 1}, // [] wr_dis of SECURE_BOOT_AGGRESSIVE_REVOKE,
};
static const esp_efuse_desc_t WR_DIS_FLASH_TPUW[] = {
{EFUSE_BLK0, 18, 1}, // [] wr_dis of FLASH_TPUW,
};
static const esp_efuse_desc_t WR_DIS_DIS_DOWNLOAD_MODE[] = {
{EFUSE_BLK0, 18, 1}, // [] wr_dis of DIS_DOWNLOAD_MODE,
};
static const esp_efuse_desc_t WR_DIS_DIS_DIRECT_BOOT[] = {
{EFUSE_BLK0, 18, 1}, // [] wr_dis of DIS_DIRECT_BOOT,
};
static const esp_efuse_desc_t WR_DIS_DIS_USB_SERIAL_JTAG_ROM_PRINT[] = {
{EFUSE_BLK0, 18, 1}, // [] wr_dis of DIS_USB_SERIAL_JTAG_ROM_PRINT,
};
static const esp_efuse_desc_t WR_DIS_DIS_USB_SERIAL_JTAG_DOWNLOAD_MODE[] = {
{EFUSE_BLK0, 18, 1}, // [] wr_dis of DIS_USB_SERIAL_JTAG_DOWNLOAD_MODE,
};
static const esp_efuse_desc_t WR_DIS_ENABLE_SECURITY_DOWNLOAD[] = {
{EFUSE_BLK0, 18, 1}, // [] wr_dis of ENABLE_SECURITY_DOWNLOAD,
};
static const esp_efuse_desc_t WR_DIS_UART_PRINT_CONTROL[] = {
{EFUSE_BLK0, 18, 1}, // [] wr_dis of UART_PRINT_CONTROL,
};
static const esp_efuse_desc_t WR_DIS_FORCE_SEND_RESUME[] = {
{EFUSE_BLK0, 18, 1}, // [] wr_dis of FORCE_SEND_RESUME,
};
static const esp_efuse_desc_t WR_DIS_SECURE_VERSION[] = {
{EFUSE_BLK0, 18, 1}, // [] wr_dis of SECURE_VERSION,
};
static const esp_efuse_desc_t WR_DIS_HUK_GEN_STATE[] = {
{EFUSE_BLK0, 19, 1}, // [] wr_dis of HUK_GEN_STATE,
};
static const esp_efuse_desc_t WR_DIS_BLK1[] = {
{EFUSE_BLK0, 20, 1}, // [] wr_dis of BLOCK1,
};
static const esp_efuse_desc_t WR_DIS_MAC[] = {
{EFUSE_BLK0, 20, 1}, // [WR_DIS.MAC_FACTORY] wr_dis of MAC,
};
static const esp_efuse_desc_t WR_DIS_MAC_EXT[] = {
{EFUSE_BLK0, 20, 1}, // [] wr_dis of MAC_EXT,
};
static const esp_efuse_desc_t WR_DIS_PVT_LIMIT[] = {
{EFUSE_BLK0, 20, 1}, // [] wr_dis of PVT_LIMIT,
};
static const esp_efuse_desc_t WR_DIS_PVT_CELL_SELECT[] = {
{EFUSE_BLK0, 20, 1}, // [] wr_dis of PVT_CELL_SELECT,
};
static const esp_efuse_desc_t WR_DIS_PVT_PUMP_LIMIT[] = {
{EFUSE_BLK0, 20, 1}, // [] wr_dis of PVT_PUMP_LIMIT,
};
static const esp_efuse_desc_t WR_DIS_PUMP_DRV[] = {
{EFUSE_BLK0, 20, 1}, // [] wr_dis of PUMP_DRV,
};
static const esp_efuse_desc_t WR_DIS_WDT_DELAY_SEL[] = {
{EFUSE_BLK0, 20, 1}, // [] wr_dis of WDT_DELAY_SEL,
};
static const esp_efuse_desc_t WR_DIS_HYS_EN_PAD[] = {
{EFUSE_BLK0, 20, 1}, // [] wr_dis of HYS_EN_PAD,
};
static const esp_efuse_desc_t WR_DIS_PVT_GLITCH_CHARGE_RESET[] = {
{EFUSE_BLK0, 20, 1}, // [] wr_dis of PVT_GLITCH_CHARGE_RESET,
};
static const esp_efuse_desc_t WR_DIS_VDD_SPI_LDO_ADJUST[] = {
{EFUSE_BLK0, 20, 1}, // [] wr_dis of VDD_SPI_LDO_ADJUST,
};
static const esp_efuse_desc_t WR_DIS_FLASH_LDO_POWER_SEL[] = {
{EFUSE_BLK0, 20, 1}, // [] wr_dis of FLASH_LDO_POWER_SEL,
};
static const esp_efuse_desc_t WR_DIS_SYS_DATA_PART1[] = {
{EFUSE_BLK0, 21, 1}, // [] wr_dis of BLOCK2,
};
static const esp_efuse_desc_t WR_DIS_BLOCK_USR_DATA[] = {
{EFUSE_BLK0, 22, 1}, // [WR_DIS.USER_DATA] wr_dis of BLOCK_USR_DATA,
};
static const esp_efuse_desc_t WR_DIS_CUSTOM_MAC[] = {
{EFUSE_BLK0, 22, 1}, // [WR_DIS.MAC_CUSTOM WR_DIS.USER_DATA_MAC_CUSTOM] wr_dis of CUSTOM_MAC,
};
static const esp_efuse_desc_t WR_DIS_BLOCK_KEY0[] = {
{EFUSE_BLK0, 23, 1}, // [WR_DIS.KEY0] wr_dis of BLOCK_KEY0,
};
static const esp_efuse_desc_t WR_DIS_BLOCK_KEY1[] = {
{EFUSE_BLK0, 24, 1}, // [WR_DIS.KEY1] wr_dis of BLOCK_KEY1,
};
static const esp_efuse_desc_t WR_DIS_BLOCK_KEY2[] = {
{EFUSE_BLK0, 25, 1}, // [WR_DIS.KEY2] wr_dis of BLOCK_KEY2,
};
static const esp_efuse_desc_t WR_DIS_BLOCK_KEY3[] = {
{EFUSE_BLK0, 26, 1}, // [WR_DIS.KEY3] wr_dis of BLOCK_KEY3,
};
static const esp_efuse_desc_t WR_DIS_BLOCK_KEY4[] = {
{EFUSE_BLK0, 27, 1}, // [WR_DIS.KEY4] wr_dis of BLOCK_KEY4,
};
static const esp_efuse_desc_t WR_DIS_BLOCK_KEY5[] = {
{EFUSE_BLK0, 28, 1}, // [WR_DIS.KEY5] wr_dis of BLOCK_KEY5,
};
static const esp_efuse_desc_t WR_DIS_BLOCK_SYS_DATA2[] = {
{EFUSE_BLK0, 29, 1}, // [WR_DIS.SYS_DATA_PART2] wr_dis of BLOCK_SYS_DATA2,
};
static const esp_efuse_desc_t WR_DIS_USB_EXCHG_PINS[] = {
{EFUSE_BLK0, 30, 1}, // [] wr_dis of USB_EXCHG_PINS,
};
static const esp_efuse_desc_t WR_DIS_SOFT_DIS_JTAG[] = {
{EFUSE_BLK0, 31, 1}, // [] wr_dis of SOFT_DIS_JTAG,
};
static const esp_efuse_desc_t RD_DIS[] = {
{EFUSE_BLK0, 32, 7}, // [] Disable reading from BlOCK4-10,
};
static const esp_efuse_desc_t RD_DIS_BLOCK_KEY0[] = {
{EFUSE_BLK0, 32, 1}, // [RD_DIS.KEY0] rd_dis of BLOCK_KEY0,
};
static const esp_efuse_desc_t RD_DIS_BLOCK_KEY1[] = {
{EFUSE_BLK0, 33, 1}, // [RD_DIS.KEY1] rd_dis of BLOCK_KEY1,
};
static const esp_efuse_desc_t RD_DIS_BLOCK_KEY2[] = {
{EFUSE_BLK0, 34, 1}, // [RD_DIS.KEY2] rd_dis of BLOCK_KEY2,
};
static const esp_efuse_desc_t RD_DIS_BLOCK_KEY3[] = {
{EFUSE_BLK0, 35, 1}, // [RD_DIS.KEY3] rd_dis of BLOCK_KEY3,
};
static const esp_efuse_desc_t RD_DIS_BLOCK_KEY4[] = {
{EFUSE_BLK0, 36, 1}, // [RD_DIS.KEY4] rd_dis of BLOCK_KEY4,
};
static const esp_efuse_desc_t RD_DIS_BLOCK_KEY5[] = {
{EFUSE_BLK0, 37, 1}, // [RD_DIS.KEY5] rd_dis of BLOCK_KEY5,
};
static const esp_efuse_desc_t RD_DIS_BLOCK_SYS_DATA2[] = {
{EFUSE_BLK0, 38, 1}, // [RD_DIS.SYS_DATA_PART2] rd_dis of BLOCK_SYS_DATA2,
};
static const esp_efuse_desc_t DIS_USB_JTAG[] = {
{EFUSE_BLK0, 39, 1}, // [] Represents whether the function of usb switch to jtag is disabled or enabled. 1: disabled 0: enabled,
};
static const esp_efuse_desc_t DIS_FORCE_DOWNLOAD[] = {
{EFUSE_BLK0, 41, 1}, // [] Represents whether the function that forces chip into download mode is disabled or enabled. 1: disabled 0: enabled,
};
static const esp_efuse_desc_t SPI_DOWNLOAD_MSPI_DIS[] = {
{EFUSE_BLK0, 42, 1}, // [] Represents whether SPI0 controller during boot_mode_download is disabled or enabled. 1: disabled 0: enabled,
};
static const esp_efuse_desc_t DIS_TWAI[] = {
{EFUSE_BLK0, 43, 1}, // [] Represents whether TWAI function is disabled or enabled. 1: disabled 0: enabled,
};
static const esp_efuse_desc_t JTAG_SEL_ENABLE[] = {
{EFUSE_BLK0, 44, 1}, // [] Represents whether the selection between usb_to_jtag and pad_to_jtag through strapping gpio15 when both EFUSE_DIS_PAD_JTAG and EFUSE_DIS_USB_JTAG are equal to 0 is enabled or disabled. 1: enabled 0: disabled,
};
static const esp_efuse_desc_t DIS_PAD_JTAG[] = {
{EFUSE_BLK0, 45, 1}, // [] Represents whether JTAG is disabled in the hard way(permanently). 1: disabled 0: enabled,
};
static const esp_efuse_desc_t DIS_DOWNLOAD_MANUAL_ENCRYPT[] = {
{EFUSE_BLK0, 46, 1}, // [] Represents whether flash encrypt function is disabled or enabled(except in SPI boot mode). 1: disabled 0: enabled,
};
static const esp_efuse_desc_t PVT_GLITCH_EN[] = {
{EFUSE_BLK0, 50, 1}, // [] Represents whether to enable PVT power glitch monitor function.1:Enable. 0:Disable,
};
static const esp_efuse_desc_t PVT_GLITCH_MODE[] = {
{EFUSE_BLK0, 52, 2}, // [] Use to configure glitch mode,
};
static const esp_efuse_desc_t DIS_CORE1[] = {
{EFUSE_BLK0, 54, 1}, // [] Represents whether the CPU-Core1 is disabled. 1: Disabled. 0: Not disable,
};
static const esp_efuse_desc_t SPI_BOOT_CRYPT_CNT[] = {
{EFUSE_BLK0, 55, 3}, // [] Enables flash encryption when 1 or 3 bits are set and disables otherwise {0: "Disable"; 1: "Enable"; 3: "Disable"; 7: "Enable"},
};
static const esp_efuse_desc_t SECURE_BOOT_KEY_REVOKE0[] = {
{EFUSE_BLK0, 58, 1}, // [] Revoke 1st secure boot key,
};
static const esp_efuse_desc_t SECURE_BOOT_KEY_REVOKE1[] = {
{EFUSE_BLK0, 59, 1}, // [] Revoke 2nd secure boot key,
};
static const esp_efuse_desc_t SECURE_BOOT_KEY_REVOKE2[] = {
{EFUSE_BLK0, 60, 1}, // [] Revoke 3rd secure boot key,
};
static const esp_efuse_desc_t KEY_PURPOSE_0[] = {
{EFUSE_BLK0, 64, 5}, // [KEY0_PURPOSE] Represents the purpose of Key0,
};
static const esp_efuse_desc_t KEY_PURPOSE_1[] = {
{EFUSE_BLK0, 69, 5}, // [KEY1_PURPOSE] Represents the purpose of Key1,
};
static const esp_efuse_desc_t KEY_PURPOSE_2[] = {
{EFUSE_BLK0, 74, 5}, // [KEY2_PURPOSE] Represents the purpose of Key2,
};
static const esp_efuse_desc_t KEY_PURPOSE_3[] = {
{EFUSE_BLK0, 79, 5}, // [KEY3_PURPOSE] Represents the purpose of Key3,
};
static const esp_efuse_desc_t KEY_PURPOSE_4[] = {
{EFUSE_BLK0, 84, 5}, // [KEY4_PURPOSE] Represents the purpose of Key4,
};
static const esp_efuse_desc_t KEY_PURPOSE_5[] = {
{EFUSE_BLK0, 89, 5}, // [KEY5_PURPOSE] Represents the purpose of Key5,
};
static const esp_efuse_desc_t SEC_DPA_LEVEL[] = {
{EFUSE_BLK0, 94, 2}, // [] Represents the spa secure level by configuring the clock random divide mode,
};
static const esp_efuse_desc_t XTS_DPA_PSEUDO_LEVEL[] = {
{EFUSE_BLK0, 96, 2}, // [] Represents the pseudo round level of xts-aes anti-dpa attack. 3: High. 2: Moderate 1. Low 0: Disabled,
};
static const esp_efuse_desc_t XTS_DPA_CLK_ENABLE[] = {
{EFUSE_BLK0, 98, 1}, // [] Represents whether xts-aes anti-dpa attack clock is enabled. 1. Enable. 0: Disable.,
};
static const esp_efuse_desc_t ECC_FORCE_CONST_TIME[] = {
{EFUSE_BLK0, 99, 1}, // [] Represents whether to force ecc to use const-time calculation mode. 1: Enable. 0: Disable,
};
static const esp_efuse_desc_t ECDSA_P384_ENABLE[] = {
{EFUSE_BLK0, 100, 1}, // [] Represents if the chip supports ECDSA P384,
};
static const esp_efuse_desc_t SECURE_BOOT_EN[] = {
{EFUSE_BLK0, 101, 1}, // [] Represents whether secure boot is enabled or disabled. 1: enabled 0: disabled,
};
static const esp_efuse_desc_t SECURE_BOOT_AGGRESSIVE_REVOKE[] = {
{EFUSE_BLK0, 102, 1}, // [] Represents whether revoking aggressive secure boot is enabled or disabled. 1: enabled. 0: disabled,
};
static const esp_efuse_desc_t KM_DISABLE_DEPLOY_MODE[] = {
{EFUSE_BLK0, 103, 5}, // [] Represents whether the new key deployment of key manager is disabled. Bit0: Represents whether the new ECDSA key deployment is disabled0: Enabled1: DisabledBit1: Represents whether the new XTS-AES (flash and PSRAM) key deployment is disabled0: Enabled1: DisabledBit2: Represents whether the new HMAC key deployment is disabled0: Enabled1: DisabledBit3: Represents whether the new DS key deployment is disabled0: Enabled1: Disabled,
};
static const esp_efuse_desc_t KM_RND_SWITCH_CYCLE[] = {
{EFUSE_BLK0, 108, 2}, // [] Represents the cycle at which the Key Manager switches random numbers.0: Controlled by the \hyperref[fielddesc:KEYMNGRNDSWITCHCYCLE]{KEYMNG\_RND\_SWITCH\_CYCLE} register. For more information; please refer to Chapter \ref{mod:keymng} \textit{\nameref{mod:keymng}}1: 8 Key Manager clock cycles2: 16 Key Manager clock cycles3: 32 Key Manager clock cycles,
};
static const esp_efuse_desc_t KM_DEPLOY_ONLY_ONCE[] = {
{EFUSE_BLK0, 110, 5}, // [] Represents whether the corresponding key can be deployed only once.Bit0: Represents whether the ECDSA key can be deployed only once0: The key can be deployed multiple times1: The key can be deployed only onceBit1: Represents whether the XTS-AES (flash and PSRAM) key can be deployed only once0: The key can be deployed multiple times1: The key can be deployed only onceBit2: Represents whether the HMAC key can be deployed only once0: The key can be deployed multiple times1: The key can be deployed only onceBit3: Represents whether the DS key can be deployed only once0: The key can be deployed multiple times1: The key can be deployed only once,
};
static const esp_efuse_desc_t FORCE_USE_KEY_MANAGER_KEY[] = {
{EFUSE_BLK0, 115, 5}, // [] Represents whether the corresponding key must come from Key Manager. Bit0: Represents whether the ECDSA key must come from Key Manager.0: The key does not need to come from Key Manager1: The key must come from Key ManagerBit1: Represents whether the XTS-AES (flash and PSRAM) key must come from Key Manager.0: The key does not need to come from Key Manager1: The key must come from Key ManagerBit2: Represents whether the HMAC key must come from Key Manager.0: The key does not need to come from Key Manager1: The key must come from Key ManagerBit3: Represents whether the DS key must come from Key Manager.0: The key does not need to come from Key Manager1: The key must come from Key Manager,
};
static const esp_efuse_desc_t FORCE_DISABLE_SW_INIT_KEY[] = {
{EFUSE_BLK0, 120, 1}, // [] Represents whether to disable the use of the initialization key written by software and instead force use efuse\_init\_key.0: Enable1: Disable,
};
static const esp_efuse_desc_t KM_XTS_KEY_LENGTH_256[] = {
{EFUSE_BLK0, 121, 1}, // [] Represents which key flash encryption uses.0: XTS-AES-256 key1: XTS-AES-128 key,
};
static const esp_efuse_desc_t LOCK_KM_KEY[] = {
{EFUSE_BLK0, 122, 1}, // [] Represents whether the keys in the Key Manager are locked after deployment.0: Not locked1: Locked,
};
static const esp_efuse_desc_t FLASH_TPUW[] = {
{EFUSE_BLK0, 123, 3}, // [] Represents the flash waiting time after power-up; in unit of ms. When the value less than 15; the waiting time is the programmed value. Otherwise; the waiting time is 2 times the programmed value,
};
static const esp_efuse_desc_t DIS_DOWNLOAD_MODE[] = {
{EFUSE_BLK0, 127, 1}, // [] Represents whether Download mode is disabled or enabled. 1: disabled 0: enabled,
};
static const esp_efuse_desc_t DIS_DIRECT_BOOT[] = {
{EFUSE_BLK0, 128, 1}, // [] Represents whether direct boot mode is disabled or enabled. 1: disabled 0: enabled,
};
static const esp_efuse_desc_t DIS_USB_SERIAL_JTAG_ROM_PRINT[] = {
{EFUSE_BLK0, 129, 1}, // [] Represents whether print from USB-Serial-JTAG is disabled or enabled. 1: disabled 0: enabled,
};
static const esp_efuse_desc_t DIS_USB_SERIAL_JTAG_DOWNLOAD_MODE[] = {
{EFUSE_BLK0, 130, 1}, // [] Represents whether the USB-Serial-JTAG download function is disabled or enabled. 1: Disable 0: Enable,
};
static const esp_efuse_desc_t ENABLE_SECURITY_DOWNLOAD[] = {
{EFUSE_BLK0, 131, 1}, // [] Represents whether security download is enabled or disabled. 1: enabled 0: disabled,
};
static const esp_efuse_desc_t UART_PRINT_CONTROL[] = {
{EFUSE_BLK0, 132, 2}, // [] Represents the type of UART printing. 00: force enable printing 01: enable printing when GPIO8 is reset at low level 10: enable printing when GPIO8 is reset at high level 11: force disable printing,
};
static const esp_efuse_desc_t FORCE_SEND_RESUME[] = {
{EFUSE_BLK0, 134, 1}, // [] Represents whether ROM code is forced to send a resume command during SPI boot. 1: forced 0:not forced,
};
static const esp_efuse_desc_t SECURE_VERSION[] = {
{EFUSE_BLK0, 135, 16}, // [] Represents the version used by ESP-IDF anti-rollback feature,
};
static const esp_efuse_desc_t HUK_GEN_STATE[] = {
{EFUSE_BLK0, 151, 5}, // [] Represents whether the HUK generate mode is valid.Odd count of bits with a value of 1: InvalidEven count of bits with a value of 1: Valid,
};
static const esp_efuse_desc_t FLASH_LDO_EFUSE_SEL[] = {
{EFUSE_BLK0, 156, 1}, // [] Represents whether to select efuse control flash ldo default voltage. 1 : efuse 0 : strapping,
};
static const esp_efuse_desc_t USB_EXCHG_PINS[] = {
{EFUSE_BLK0, 168, 1}, // [] Represents whether the D+ and D- pins of USB_SERIAL_JTAG PHY is exchanged. 1: exchanged 0: not exchanged,
};
static const esp_efuse_desc_t USB_OTG_FS_EXCHG_PINS[] = {
{EFUSE_BLK0, 169, 1}, // [] Represents whether the D+ and D- pins of USB_OTG_FS PHY is exchanged. 1: exchanged 0: not exchanged,
};
static const esp_efuse_desc_t USB_PHY_SEL[] = {
{EFUSE_BLK0, 170, 1}, // [] Represents whether to exchange the USB_SERIAL_JTAG PHY with USB_OTG_FS PHY. 1: exchanged. 0: not exchanged,
};
static const esp_efuse_desc_t SOFT_DIS_JTAG[] = {
{EFUSE_BLK0, 171, 3}, // [] Represents whether JTAG is disabled in soft way. Odd number: disabled Even number: enabled,
};
static const esp_efuse_desc_t IO_LDO_ADJUST[] = {
{EFUSE_BLK0, 174, 8}, // [] Represents configuration of IO LDO mode and voltage.,
};
static const esp_efuse_desc_t IO_LDO_1P8[] = {
{EFUSE_BLK0, 182, 1}, // [] Represents select IO LDO voltage to 1.8V or 3.3V. 1: 1.8V 0: 3.3V,
};
static const esp_efuse_desc_t DCDC_CCM_EN[] = {
{EFUSE_BLK0, 183, 1}, // [] Represents whether change DCDC to CCM mode,
};
static const esp_efuse_desc_t MAC[] = {
{EFUSE_BLK1, 40, 8}, // [MAC_FACTORY] MAC address,
{EFUSE_BLK1, 32, 8}, // [MAC_FACTORY] MAC address,
{EFUSE_BLK1, 24, 8}, // [MAC_FACTORY] MAC address,
{EFUSE_BLK1, 16, 8}, // [MAC_FACTORY] MAC address,
{EFUSE_BLK1, 8, 8}, // [MAC_FACTORY] MAC address,
{EFUSE_BLK1, 0, 8}, // [MAC_FACTORY] MAC address,
};
static const esp_efuse_desc_t MAC_EXT[] = {
{EFUSE_BLK1, 56, 8}, // [] Stores the extended bits of MAC address,
{EFUSE_BLK1, 48, 8}, // [] Stores the extended bits of MAC address,
};
static const esp_efuse_desc_t PVT_LIMIT[] = {
{EFUSE_BLK1, 64, 16}, // [] Power glitch monitor threthold,
};
static const esp_efuse_desc_t PVT_CELL_SELECT[] = {
{EFUSE_BLK1, 80, 7}, // [] Power glitch monitor PVT cell select,
};
static const esp_efuse_desc_t PVT_PUMP_LIMIT[] = {
{EFUSE_BLK1, 87, 8}, // [] Use to configure voltage monitor limit for charge pump,
};
static const esp_efuse_desc_t PUMP_DRV[] = {
{EFUSE_BLK1, 96, 4}, // [] Use to configure charge pump voltage gain,
};
static const esp_efuse_desc_t WDT_DELAY_SEL[] = {
{EFUSE_BLK1, 100, 2}, // [] Represents the threshold level of the RTC watchdog STG0 timeout. 0: Original threshold configuration value of STG0 *2 1: Original threshold configuration value of STG0 *4 2: Original threshold configuration value of STG0 *8 3: Original threshold configuration value of STG0 *16,
};
static const esp_efuse_desc_t HYS_EN_PAD[] = {
{EFUSE_BLK1, 102, 1}, // [] Represents whether the hysteresis function of corresponding PAD is enabled. 1: enabled 0:disabled,
};
static const esp_efuse_desc_t PVT_GLITCH_CHARGE_RESET[] = {
{EFUSE_BLK1, 103, 1}, // [] Represents whether to trigger reset or charge pump when PVT power glitch happened.1:Trigger charge pump. 0:Trigger reset,
};
static const esp_efuse_desc_t VDD_SPI_LDO_ADJUST[] = {
{EFUSE_BLK1, 105, 8}, // [] Represents configuration of FLASH LDO mode and voltage.,
};
static const esp_efuse_desc_t FLASH_LDO_POWER_SEL[] = {
{EFUSE_BLK1, 113, 1}, // [] Represents which flash ldo be select: 1: FLASH LDO 1P2 0 : FLASH LDO 1P8,
};
static const esp_efuse_desc_t USER_DATA[] = {
{EFUSE_BLK3, 0, 256}, // [BLOCK_USR_DATA] User data,
};
static const esp_efuse_desc_t USER_DATA_MAC_CUSTOM[] = {
{EFUSE_BLK3, 200, 48}, // [MAC_CUSTOM CUSTOM_MAC] Custom MAC,
};
static const esp_efuse_desc_t KEY0[] = {
{EFUSE_BLK4, 0, 256}, // [BLOCK_KEY0] Key0 or user data,
};
static const esp_efuse_desc_t KEY1[] = {
{EFUSE_BLK5, 0, 256}, // [BLOCK_KEY1] Key1 or user data,
};
static const esp_efuse_desc_t KEY2[] = {
{EFUSE_BLK6, 0, 256}, // [BLOCK_KEY2] Key2 or user data,
};
static const esp_efuse_desc_t KEY3[] = {
{EFUSE_BLK7, 0, 256}, // [BLOCK_KEY3] Key3 or user data,
};
static const esp_efuse_desc_t KEY4[] = {
{EFUSE_BLK8, 0, 256}, // [BLOCK_KEY4] Key4 or user data,
};
static const esp_efuse_desc_t KEY5[] = {
{EFUSE_BLK9, 0, 256}, // [BLOCK_KEY5] Key5 or user data,
};
static const esp_efuse_desc_t SYS_DATA_PART2[] = {
{EFUSE_BLK10, 0, 256}, // [BLOCK_SYS_DATA2] System data part 2 (reserved),
};
const esp_efuse_desc_t* ESP_EFUSE_WR_DIS[] = {
&WR_DIS[0], // [] Disable programming of individual eFuses
NULL
};
const esp_efuse_desc_t* ESP_EFUSE_WR_DIS_RD_DIS[] = {
&WR_DIS_RD_DIS[0], // [] wr_dis of RD_DIS
NULL
};
const esp_efuse_desc_t* ESP_EFUSE_WR_DIS_KM_DISABLE_DEPLOY_MODE[] = {
&WR_DIS_KM_DISABLE_DEPLOY_MODE[0], // [] wr_dis of KM_DISABLE_DEPLOY_MODE
NULL
};
const esp_efuse_desc_t* ESP_EFUSE_WR_DIS_KM_RND_SWITCH_CYCLE[] = {
&WR_DIS_KM_RND_SWITCH_CYCLE[0], // [] wr_dis of KM_RND_SWITCH_CYCLE
NULL
};
const esp_efuse_desc_t* ESP_EFUSE_WR_DIS_KM_DEPLOY_ONLY_ONCE[] = {
&WR_DIS_KM_DEPLOY_ONLY_ONCE[0], // [] wr_dis of KM_DEPLOY_ONLY_ONCE
NULL
};
const esp_efuse_desc_t* ESP_EFUSE_WR_DIS_FORCE_USE_KEY_MANAGER_KEY[] = {
&WR_DIS_FORCE_USE_KEY_MANAGER_KEY[0], // [] wr_dis of FORCE_USE_KEY_MANAGER_KEY
NULL
};
const esp_efuse_desc_t* ESP_EFUSE_WR_DIS_FORCE_DISABLE_SW_INIT_KEY[] = {
&WR_DIS_FORCE_DISABLE_SW_INIT_KEY[0], // [] wr_dis of FORCE_DISABLE_SW_INIT_KEY
NULL
};
const esp_efuse_desc_t* ESP_EFUSE_WR_DIS_KM_XTS_KEY_LENGTH_256[] = {
&WR_DIS_KM_XTS_KEY_LENGTH_256[0], // [] wr_dis of KM_XTS_KEY_LENGTH_256
NULL
};
const esp_efuse_desc_t* ESP_EFUSE_WR_DIS_LOCK_KM_KEY[] = {
&WR_DIS_LOCK_KM_KEY[0], // [] wr_dis of LOCK_KM_KEY
NULL
};
const esp_efuse_desc_t* ESP_EFUSE_WR_DIS_DIS_USB_JTAG[] = {
&WR_DIS_DIS_USB_JTAG[0], // [] wr_dis of DIS_USB_JTAG
NULL
};
const esp_efuse_desc_t* ESP_EFUSE_WR_DIS_DIS_FORCE_DOWNLOAD[] = {
&WR_DIS_DIS_FORCE_DOWNLOAD[0], // [] wr_dis of DIS_FORCE_DOWNLOAD
NULL
};
const esp_efuse_desc_t* ESP_EFUSE_WR_DIS_SPI_DOWNLOAD_MSPI_DIS[] = {
&WR_DIS_SPI_DOWNLOAD_MSPI_DIS[0], // [] wr_dis of SPI_DOWNLOAD_MSPI_DIS
NULL
};
const esp_efuse_desc_t* ESP_EFUSE_WR_DIS_DIS_TWAI[] = {
&WR_DIS_DIS_TWAI[0], // [] wr_dis of DIS_TWAI
NULL
};
const esp_efuse_desc_t* ESP_EFUSE_WR_DIS_JTAG_SEL_ENABLE[] = {
&WR_DIS_JTAG_SEL_ENABLE[0], // [] wr_dis of JTAG_SEL_ENABLE
NULL
};
const esp_efuse_desc_t* ESP_EFUSE_WR_DIS_DIS_PAD_JTAG[] = {
&WR_DIS_DIS_PAD_JTAG[0], // [] wr_dis of DIS_PAD_JTAG
NULL
};
const esp_efuse_desc_t* ESP_EFUSE_WR_DIS_DIS_DOWNLOAD_MANUAL_ENCRYPT[] = {
&WR_DIS_DIS_DOWNLOAD_MANUAL_ENCRYPT[0], // [] wr_dis of DIS_DOWNLOAD_MANUAL_ENCRYPT
NULL
};
const esp_efuse_desc_t* ESP_EFUSE_WR_DIS_SPI_BOOT_CRYPT_CNT[] = {
&WR_DIS_SPI_BOOT_CRYPT_CNT[0], // [] wr_dis of SPI_BOOT_CRYPT_CNT
NULL
};
const esp_efuse_desc_t* ESP_EFUSE_WR_DIS_SECURE_BOOT_KEY_REVOKE0[] = {
&WR_DIS_SECURE_BOOT_KEY_REVOKE0[0], // [] wr_dis of SECURE_BOOT_KEY_REVOKE0
NULL
};
const esp_efuse_desc_t* ESP_EFUSE_WR_DIS_SECURE_BOOT_KEY_REVOKE1[] = {
&WR_DIS_SECURE_BOOT_KEY_REVOKE1[0], // [] wr_dis of SECURE_BOOT_KEY_REVOKE1
NULL
};
const esp_efuse_desc_t* ESP_EFUSE_WR_DIS_SECURE_BOOT_KEY_REVOKE2[] = {
&WR_DIS_SECURE_BOOT_KEY_REVOKE2[0], // [] wr_dis of SECURE_BOOT_KEY_REVOKE2
NULL
};
const esp_efuse_desc_t* ESP_EFUSE_WR_DIS_KEY_PURPOSE_0[] = {
&WR_DIS_KEY_PURPOSE_0[0], // [WR_DIS.KEY0_PURPOSE] wr_dis of KEY_PURPOSE_0
NULL
};
const esp_efuse_desc_t* ESP_EFUSE_WR_DIS_KEY_PURPOSE_1[] = {
&WR_DIS_KEY_PURPOSE_1[0], // [WR_DIS.KEY1_PURPOSE] wr_dis of KEY_PURPOSE_1
NULL
};
const esp_efuse_desc_t* ESP_EFUSE_WR_DIS_KEY_PURPOSE_2[] = {
&WR_DIS_KEY_PURPOSE_2[0], // [WR_DIS.KEY2_PURPOSE] wr_dis of KEY_PURPOSE_2
NULL
};
const esp_efuse_desc_t* ESP_EFUSE_WR_DIS_KEY_PURPOSE_3[] = {
&WR_DIS_KEY_PURPOSE_3[0], // [WR_DIS.KEY3_PURPOSE] wr_dis of KEY_PURPOSE_3
NULL
};
const esp_efuse_desc_t* ESP_EFUSE_WR_DIS_KEY_PURPOSE_4[] = {
&WR_DIS_KEY_PURPOSE_4[0], // [WR_DIS.KEY4_PURPOSE] wr_dis of KEY_PURPOSE_4
NULL
};
const esp_efuse_desc_t* ESP_EFUSE_WR_DIS_KEY_PURPOSE_5[] = {
&WR_DIS_KEY_PURPOSE_5[0], // [WR_DIS.KEY5_PURPOSE] wr_dis of KEY_PURPOSE_5
NULL
};
const esp_efuse_desc_t* ESP_EFUSE_WR_DIS_SEC_DPA_LEVEL[] = {
&WR_DIS_SEC_DPA_LEVEL[0], // [] wr_dis of SEC_DPA_LEVEL
NULL
};
const esp_efuse_desc_t* ESP_EFUSE_WR_DIS_XTS_DPA_PSEUDO_LEVEL[] = {
&WR_DIS_XTS_DPA_PSEUDO_LEVEL[0], // [] wr_dis of XTS_DPA_PSEUDO_LEVEL
NULL
};
const esp_efuse_desc_t* ESP_EFUSE_WR_DIS_XTS_DPA_CLK_ENABLE[] = {
&WR_DIS_XTS_DPA_CLK_ENABLE[0], // [] wr_dis of XTS_DPA_CLK_ENABLE
NULL
};
const esp_efuse_desc_t* ESP_EFUSE_WR_DIS_ECC_FORCE_CONST_TIME[] = {
&WR_DIS_ECC_FORCE_CONST_TIME[0], // [] wr_dis of ECC_FORCE_CONST_TIME
NULL
};
const esp_efuse_desc_t* ESP_EFUSE_WR_DIS_SECURE_BOOT_EN[] = {
&WR_DIS_SECURE_BOOT_EN[0], // [] wr_dis of SECURE_BOOT_EN
NULL
};
const esp_efuse_desc_t* ESP_EFUSE_WR_DIS_SECURE_BOOT_AGGRESSIVE_REVOKE[] = {
&WR_DIS_SECURE_BOOT_AGGRESSIVE_REVOKE[0], // [] wr_dis of SECURE_BOOT_AGGRESSIVE_REVOKE
NULL
};
const esp_efuse_desc_t* ESP_EFUSE_WR_DIS_FLASH_TPUW[] = {
&WR_DIS_FLASH_TPUW[0], // [] wr_dis of FLASH_TPUW
NULL
};
const esp_efuse_desc_t* ESP_EFUSE_WR_DIS_DIS_DOWNLOAD_MODE[] = {
&WR_DIS_DIS_DOWNLOAD_MODE[0], // [] wr_dis of DIS_DOWNLOAD_MODE
NULL
};
const esp_efuse_desc_t* ESP_EFUSE_WR_DIS_DIS_DIRECT_BOOT[] = {
&WR_DIS_DIS_DIRECT_BOOT[0], // [] wr_dis of DIS_DIRECT_BOOT
NULL
};
const esp_efuse_desc_t* ESP_EFUSE_WR_DIS_DIS_USB_SERIAL_JTAG_ROM_PRINT[] = {
&WR_DIS_DIS_USB_SERIAL_JTAG_ROM_PRINT[0], // [] wr_dis of DIS_USB_SERIAL_JTAG_ROM_PRINT
NULL
};
const esp_efuse_desc_t* ESP_EFUSE_WR_DIS_DIS_USB_SERIAL_JTAG_DOWNLOAD_MODE[] = {
&WR_DIS_DIS_USB_SERIAL_JTAG_DOWNLOAD_MODE[0], // [] wr_dis of DIS_USB_SERIAL_JTAG_DOWNLOAD_MODE
NULL
};
const esp_efuse_desc_t* ESP_EFUSE_WR_DIS_ENABLE_SECURITY_DOWNLOAD[] = {
&WR_DIS_ENABLE_SECURITY_DOWNLOAD[0], // [] wr_dis of ENABLE_SECURITY_DOWNLOAD
NULL
};
const esp_efuse_desc_t* ESP_EFUSE_WR_DIS_UART_PRINT_CONTROL[] = {
&WR_DIS_UART_PRINT_CONTROL[0], // [] wr_dis of UART_PRINT_CONTROL
NULL
};
const esp_efuse_desc_t* ESP_EFUSE_WR_DIS_FORCE_SEND_RESUME[] = {
&WR_DIS_FORCE_SEND_RESUME[0], // [] wr_dis of FORCE_SEND_RESUME
NULL
};
const esp_efuse_desc_t* ESP_EFUSE_WR_DIS_SECURE_VERSION[] = {
&WR_DIS_SECURE_VERSION[0], // [] wr_dis of SECURE_VERSION
NULL
};
const esp_efuse_desc_t* ESP_EFUSE_WR_DIS_HUK_GEN_STATE[] = {
&WR_DIS_HUK_GEN_STATE[0], // [] wr_dis of HUK_GEN_STATE
NULL
};
const esp_efuse_desc_t* ESP_EFUSE_WR_DIS_BLK1[] = {
&WR_DIS_BLK1[0], // [] wr_dis of BLOCK1
NULL
};
const esp_efuse_desc_t* ESP_EFUSE_WR_DIS_MAC[] = {
&WR_DIS_MAC[0], // [WR_DIS.MAC_FACTORY] wr_dis of MAC
NULL
};
const esp_efuse_desc_t* ESP_EFUSE_WR_DIS_MAC_EXT[] = {
&WR_DIS_MAC_EXT[0], // [] wr_dis of MAC_EXT
NULL
};
const esp_efuse_desc_t* ESP_EFUSE_WR_DIS_PVT_LIMIT[] = {
&WR_DIS_PVT_LIMIT[0], // [] wr_dis of PVT_LIMIT
NULL
};
const esp_efuse_desc_t* ESP_EFUSE_WR_DIS_PVT_CELL_SELECT[] = {
&WR_DIS_PVT_CELL_SELECT[0], // [] wr_dis of PVT_CELL_SELECT
NULL
};
const esp_efuse_desc_t* ESP_EFUSE_WR_DIS_PVT_PUMP_LIMIT[] = {
&WR_DIS_PVT_PUMP_LIMIT[0], // [] wr_dis of PVT_PUMP_LIMIT
NULL
};
const esp_efuse_desc_t* ESP_EFUSE_WR_DIS_PUMP_DRV[] = {
&WR_DIS_PUMP_DRV[0], // [] wr_dis of PUMP_DRV
NULL
};
const esp_efuse_desc_t* ESP_EFUSE_WR_DIS_WDT_DELAY_SEL[] = {
&WR_DIS_WDT_DELAY_SEL[0], // [] wr_dis of WDT_DELAY_SEL
NULL
};
const esp_efuse_desc_t* ESP_EFUSE_WR_DIS_HYS_EN_PAD[] = {
&WR_DIS_HYS_EN_PAD[0], // [] wr_dis of HYS_EN_PAD
NULL
};
const esp_efuse_desc_t* ESP_EFUSE_WR_DIS_PVT_GLITCH_CHARGE_RESET[] = {
&WR_DIS_PVT_GLITCH_CHARGE_RESET[0], // [] wr_dis of PVT_GLITCH_CHARGE_RESET
NULL
};
const esp_efuse_desc_t* ESP_EFUSE_WR_DIS_VDD_SPI_LDO_ADJUST[] = {
&WR_DIS_VDD_SPI_LDO_ADJUST[0], // [] wr_dis of VDD_SPI_LDO_ADJUST
NULL
};
const esp_efuse_desc_t* ESP_EFUSE_WR_DIS_FLASH_LDO_POWER_SEL[] = {
&WR_DIS_FLASH_LDO_POWER_SEL[0], // [] wr_dis of FLASH_LDO_POWER_SEL
NULL
};
const esp_efuse_desc_t* ESP_EFUSE_WR_DIS_SYS_DATA_PART1[] = {
&WR_DIS_SYS_DATA_PART1[0], // [] wr_dis of BLOCK2
NULL
};
const esp_efuse_desc_t* ESP_EFUSE_WR_DIS_BLOCK_USR_DATA[] = {
&WR_DIS_BLOCK_USR_DATA[0], // [WR_DIS.USER_DATA] wr_dis of BLOCK_USR_DATA
NULL
};
const esp_efuse_desc_t* ESP_EFUSE_WR_DIS_CUSTOM_MAC[] = {
&WR_DIS_CUSTOM_MAC[0], // [WR_DIS.MAC_CUSTOM WR_DIS.USER_DATA_MAC_CUSTOM] wr_dis of CUSTOM_MAC
NULL
};
const esp_efuse_desc_t* ESP_EFUSE_WR_DIS_BLOCK_KEY0[] = {
&WR_DIS_BLOCK_KEY0[0], // [WR_DIS.KEY0] wr_dis of BLOCK_KEY0
NULL
};
const esp_efuse_desc_t* ESP_EFUSE_WR_DIS_BLOCK_KEY1[] = {
&WR_DIS_BLOCK_KEY1[0], // [WR_DIS.KEY1] wr_dis of BLOCK_KEY1
NULL
};
const esp_efuse_desc_t* ESP_EFUSE_WR_DIS_BLOCK_KEY2[] = {
&WR_DIS_BLOCK_KEY2[0], // [WR_DIS.KEY2] wr_dis of BLOCK_KEY2
NULL
};
const esp_efuse_desc_t* ESP_EFUSE_WR_DIS_BLOCK_KEY3[] = {
&WR_DIS_BLOCK_KEY3[0], // [WR_DIS.KEY3] wr_dis of BLOCK_KEY3
NULL
};
const esp_efuse_desc_t* ESP_EFUSE_WR_DIS_BLOCK_KEY4[] = {
&WR_DIS_BLOCK_KEY4[0], // [WR_DIS.KEY4] wr_dis of BLOCK_KEY4
NULL
};
const esp_efuse_desc_t* ESP_EFUSE_WR_DIS_BLOCK_KEY5[] = {
&WR_DIS_BLOCK_KEY5[0], // [WR_DIS.KEY5] wr_dis of BLOCK_KEY5
NULL
};
const esp_efuse_desc_t* ESP_EFUSE_WR_DIS_BLOCK_SYS_DATA2[] = {
&WR_DIS_BLOCK_SYS_DATA2[0], // [WR_DIS.SYS_DATA_PART2] wr_dis of BLOCK_SYS_DATA2
NULL
};
const esp_efuse_desc_t* ESP_EFUSE_WR_DIS_USB_EXCHG_PINS[] = {
&WR_DIS_USB_EXCHG_PINS[0], // [] wr_dis of USB_EXCHG_PINS
NULL
};
const esp_efuse_desc_t* ESP_EFUSE_WR_DIS_SOFT_DIS_JTAG[] = {
&WR_DIS_SOFT_DIS_JTAG[0], // [] wr_dis of SOFT_DIS_JTAG
NULL
};
const esp_efuse_desc_t* ESP_EFUSE_RD_DIS[] = {
&RD_DIS[0], // [] Disable reading from BlOCK4-10
NULL
};
const esp_efuse_desc_t* ESP_EFUSE_RD_DIS_BLOCK_KEY0[] = {
&RD_DIS_BLOCK_KEY0[0], // [RD_DIS.KEY0] rd_dis of BLOCK_KEY0
NULL
};
const esp_efuse_desc_t* ESP_EFUSE_RD_DIS_BLOCK_KEY1[] = {
&RD_DIS_BLOCK_KEY1[0], // [RD_DIS.KEY1] rd_dis of BLOCK_KEY1
NULL
};
const esp_efuse_desc_t* ESP_EFUSE_RD_DIS_BLOCK_KEY2[] = {
&RD_DIS_BLOCK_KEY2[0], // [RD_DIS.KEY2] rd_dis of BLOCK_KEY2
NULL
};
const esp_efuse_desc_t* ESP_EFUSE_RD_DIS_BLOCK_KEY3[] = {
&RD_DIS_BLOCK_KEY3[0], // [RD_DIS.KEY3] rd_dis of BLOCK_KEY3
NULL
};
const esp_efuse_desc_t* ESP_EFUSE_RD_DIS_BLOCK_KEY4[] = {
&RD_DIS_BLOCK_KEY4[0], // [RD_DIS.KEY4] rd_dis of BLOCK_KEY4
NULL
};
const esp_efuse_desc_t* ESP_EFUSE_RD_DIS_BLOCK_KEY5[] = {
&RD_DIS_BLOCK_KEY5[0], // [RD_DIS.KEY5] rd_dis of BLOCK_KEY5
NULL
};
const esp_efuse_desc_t* ESP_EFUSE_RD_DIS_BLOCK_SYS_DATA2[] = {
&RD_DIS_BLOCK_SYS_DATA2[0], // [RD_DIS.SYS_DATA_PART2] rd_dis of BLOCK_SYS_DATA2
NULL
};
const esp_efuse_desc_t* ESP_EFUSE_DIS_USB_JTAG[] = {
&DIS_USB_JTAG[0], // [] Represents whether the function of usb switch to jtag is disabled or enabled. 1: disabled 0: enabled
NULL
};
const esp_efuse_desc_t* ESP_EFUSE_DIS_FORCE_DOWNLOAD[] = {
&DIS_FORCE_DOWNLOAD[0], // [] Represents whether the function that forces chip into download mode is disabled or enabled. 1: disabled 0: enabled
NULL
};
const esp_efuse_desc_t* ESP_EFUSE_SPI_DOWNLOAD_MSPI_DIS[] = {
&SPI_DOWNLOAD_MSPI_DIS[0], // [] Represents whether SPI0 controller during boot_mode_download is disabled or enabled. 1: disabled 0: enabled
NULL
};
const esp_efuse_desc_t* ESP_EFUSE_DIS_TWAI[] = {
&DIS_TWAI[0], // [] Represents whether TWAI function is disabled or enabled. 1: disabled 0: enabled
NULL
};
const esp_efuse_desc_t* ESP_EFUSE_JTAG_SEL_ENABLE[] = {
&JTAG_SEL_ENABLE[0], // [] Represents whether the selection between usb_to_jtag and pad_to_jtag through strapping gpio15 when both EFUSE_DIS_PAD_JTAG and EFUSE_DIS_USB_JTAG are equal to 0 is enabled or disabled. 1: enabled 0: disabled
NULL
};
const esp_efuse_desc_t* ESP_EFUSE_DIS_PAD_JTAG[] = {
&DIS_PAD_JTAG[0], // [] Represents whether JTAG is disabled in the hard way(permanently). 1: disabled 0: enabled
NULL
};
const esp_efuse_desc_t* ESP_EFUSE_DIS_DOWNLOAD_MANUAL_ENCRYPT[] = {
&DIS_DOWNLOAD_MANUAL_ENCRYPT[0], // [] Represents whether flash encrypt function is disabled or enabled(except in SPI boot mode). 1: disabled 0: enabled
NULL
};
const esp_efuse_desc_t* ESP_EFUSE_PVT_GLITCH_EN[] = {
&PVT_GLITCH_EN[0], // [] Represents whether to enable PVT power glitch monitor function.1:Enable. 0:Disable
NULL
};
const esp_efuse_desc_t* ESP_EFUSE_PVT_GLITCH_MODE[] = {
&PVT_GLITCH_MODE[0], // [] Use to configure glitch mode
NULL
};
const esp_efuse_desc_t* ESP_EFUSE_DIS_CORE1[] = {
&DIS_CORE1[0], // [] Represents whether the CPU-Core1 is disabled. 1: Disabled. 0: Not disable
NULL
};
const esp_efuse_desc_t* ESP_EFUSE_SPI_BOOT_CRYPT_CNT[] = {
&SPI_BOOT_CRYPT_CNT[0], // [] Enables flash encryption when 1 or 3 bits are set and disables otherwise {0: "Disable"; 1: "Enable"; 3: "Disable"; 7: "Enable"}
NULL
};
const esp_efuse_desc_t* ESP_EFUSE_SECURE_BOOT_KEY_REVOKE0[] = {
&SECURE_BOOT_KEY_REVOKE0[0], // [] Revoke 1st secure boot key
NULL
};
const esp_efuse_desc_t* ESP_EFUSE_SECURE_BOOT_KEY_REVOKE1[] = {
&SECURE_BOOT_KEY_REVOKE1[0], // [] Revoke 2nd secure boot key
NULL
};
const esp_efuse_desc_t* ESP_EFUSE_SECURE_BOOT_KEY_REVOKE2[] = {
&SECURE_BOOT_KEY_REVOKE2[0], // [] Revoke 3rd secure boot key
NULL
};
const esp_efuse_desc_t* ESP_EFUSE_KEY_PURPOSE_0[] = {
&KEY_PURPOSE_0[0], // [KEY0_PURPOSE] Represents the purpose of Key0
NULL
};
const esp_efuse_desc_t* ESP_EFUSE_KEY_PURPOSE_1[] = {
&KEY_PURPOSE_1[0], // [KEY1_PURPOSE] Represents the purpose of Key1
NULL
};
const esp_efuse_desc_t* ESP_EFUSE_KEY_PURPOSE_2[] = {
&KEY_PURPOSE_2[0], // [KEY2_PURPOSE] Represents the purpose of Key2
NULL
};
const esp_efuse_desc_t* ESP_EFUSE_KEY_PURPOSE_3[] = {
&KEY_PURPOSE_3[0], // [KEY3_PURPOSE] Represents the purpose of Key3
NULL
};
const esp_efuse_desc_t* ESP_EFUSE_KEY_PURPOSE_4[] = {
&KEY_PURPOSE_4[0], // [KEY4_PURPOSE] Represents the purpose of Key4
NULL
};
const esp_efuse_desc_t* ESP_EFUSE_KEY_PURPOSE_5[] = {
&KEY_PURPOSE_5[0], // [KEY5_PURPOSE] Represents the purpose of Key5
NULL
};
const esp_efuse_desc_t* ESP_EFUSE_SEC_DPA_LEVEL[] = {
&SEC_DPA_LEVEL[0], // [] Represents the spa secure level by configuring the clock random divide mode
NULL
};
const esp_efuse_desc_t* ESP_EFUSE_XTS_DPA_PSEUDO_LEVEL[] = {
&XTS_DPA_PSEUDO_LEVEL[0], // [] Represents the pseudo round level of xts-aes anti-dpa attack. 3: High. 2: Moderate 1. Low 0: Disabled
NULL
};
const esp_efuse_desc_t* ESP_EFUSE_XTS_DPA_CLK_ENABLE[] = {
&XTS_DPA_CLK_ENABLE[0], // [] Represents whether xts-aes anti-dpa attack clock is enabled. 1. Enable. 0: Disable.
NULL
};
const esp_efuse_desc_t* ESP_EFUSE_ECC_FORCE_CONST_TIME[] = {
&ECC_FORCE_CONST_TIME[0], // [] Represents whether to force ecc to use const-time calculation mode. 1: Enable. 0: Disable
NULL
};
const esp_efuse_desc_t* ESP_EFUSE_ECDSA_P384_ENABLE[] = {
&ECDSA_P384_ENABLE[0], // [] Represents if the chip supports ECDSA P384
NULL
};
const esp_efuse_desc_t* ESP_EFUSE_SECURE_BOOT_EN[] = {
&SECURE_BOOT_EN[0], // [] Represents whether secure boot is enabled or disabled. 1: enabled 0: disabled
NULL
};
const esp_efuse_desc_t* ESP_EFUSE_SECURE_BOOT_AGGRESSIVE_REVOKE[] = {
&SECURE_BOOT_AGGRESSIVE_REVOKE[0], // [] Represents whether revoking aggressive secure boot is enabled or disabled. 1: enabled. 0: disabled
NULL
};
const esp_efuse_desc_t* ESP_EFUSE_KM_DISABLE_DEPLOY_MODE[] = {
&KM_DISABLE_DEPLOY_MODE[0], // [] Represents whether the new key deployment of key manager is disabled. Bit0: Represents whether the new ECDSA key deployment is disabled0: Enabled1: DisabledBit1: Represents whether the new XTS-AES (flash and PSRAM) key deployment is disabled0: Enabled1: DisabledBit2: Represents whether the new HMAC key deployment is disabled0: Enabled1: DisabledBit3: Represents whether the new DS key deployment is disabled0: Enabled1: Disabled
NULL
};
const esp_efuse_desc_t* ESP_EFUSE_KM_RND_SWITCH_CYCLE[] = {
&KM_RND_SWITCH_CYCLE[0], // [] Represents the cycle at which the Key Manager switches random numbers.0: Controlled by the \hyperref[fielddesc:KEYMNGRNDSWITCHCYCLE]{KEYMNG\_RND\_SWITCH\_CYCLE} register. For more information; please refer to Chapter \ref{mod:keymng} \textit{\nameref{mod:keymng}}1: 8 Key Manager clock cycles2: 16 Key Manager clock cycles3: 32 Key Manager clock cycles
NULL
};
const esp_efuse_desc_t* ESP_EFUSE_KM_DEPLOY_ONLY_ONCE[] = {
&KM_DEPLOY_ONLY_ONCE[0], // [] Represents whether the corresponding key can be deployed only once.Bit0: Represents whether the ECDSA key can be deployed only once0: The key can be deployed multiple times1: The key can be deployed only onceBit1: Represents whether the XTS-AES (flash and PSRAM) key can be deployed only once0: The key can be deployed multiple times1: The key can be deployed only onceBit2: Represents whether the HMAC key can be deployed only once0: The key can be deployed multiple times1: The key can be deployed only onceBit3: Represents whether the DS key can be deployed only once0: The key can be deployed multiple times1: The key can be deployed only once
NULL
};
const esp_efuse_desc_t* ESP_EFUSE_FORCE_USE_KEY_MANAGER_KEY[] = {
&FORCE_USE_KEY_MANAGER_KEY[0], // [] Represents whether the corresponding key must come from Key Manager. Bit0: Represents whether the ECDSA key must come from Key Manager.0: The key does not need to come from Key Manager1: The key must come from Key ManagerBit1: Represents whether the XTS-AES (flash and PSRAM) key must come from Key Manager.0: The key does not need to come from Key Manager1: The key must come from Key ManagerBit2: Represents whether the HMAC key must come from Key Manager.0: The key does not need to come from Key Manager1: The key must come from Key ManagerBit3: Represents whether the DS key must come from Key Manager.0: The key does not need to come from Key Manager1: The key must come from Key Manager
NULL
};
const esp_efuse_desc_t* ESP_EFUSE_FORCE_DISABLE_SW_INIT_KEY[] = {
&FORCE_DISABLE_SW_INIT_KEY[0], // [] Represents whether to disable the use of the initialization key written by software and instead force use efuse\_init\_key.0: Enable1: Disable
NULL
};
const esp_efuse_desc_t* ESP_EFUSE_KM_XTS_KEY_LENGTH_256[] = {
&KM_XTS_KEY_LENGTH_256[0], // [] Represents which key flash encryption uses.0: XTS-AES-256 key1: XTS-AES-128 key
NULL
};
const esp_efuse_desc_t* ESP_EFUSE_LOCK_KM_KEY[] = {
&LOCK_KM_KEY[0], // [] Represents whether the keys in the Key Manager are locked after deployment.0: Not locked1: Locked
NULL
};
const esp_efuse_desc_t* ESP_EFUSE_FLASH_TPUW[] = {
&FLASH_TPUW[0], // [] Represents the flash waiting time after power-up; in unit of ms. When the value less than 15; the waiting time is the programmed value. Otherwise; the waiting time is 2 times the programmed value
NULL
};
const esp_efuse_desc_t* ESP_EFUSE_DIS_DOWNLOAD_MODE[] = {
&DIS_DOWNLOAD_MODE[0], // [] Represents whether Download mode is disabled or enabled. 1: disabled 0: enabled
NULL
};
const esp_efuse_desc_t* ESP_EFUSE_DIS_DIRECT_BOOT[] = {
&DIS_DIRECT_BOOT[0], // [] Represents whether direct boot mode is disabled or enabled. 1: disabled 0: enabled
NULL
};
const esp_efuse_desc_t* ESP_EFUSE_DIS_USB_SERIAL_JTAG_ROM_PRINT[] = {
&DIS_USB_SERIAL_JTAG_ROM_PRINT[0], // [] Represents whether print from USB-Serial-JTAG is disabled or enabled. 1: disabled 0: enabled
NULL
};
const esp_efuse_desc_t* ESP_EFUSE_DIS_USB_SERIAL_JTAG_DOWNLOAD_MODE[] = {
&DIS_USB_SERIAL_JTAG_DOWNLOAD_MODE[0], // [] Represents whether the USB-Serial-JTAG download function is disabled or enabled. 1: Disable 0: Enable
NULL
};
const esp_efuse_desc_t* ESP_EFUSE_ENABLE_SECURITY_DOWNLOAD[] = {
&ENABLE_SECURITY_DOWNLOAD[0], // [] Represents whether security download is enabled or disabled. 1: enabled 0: disabled
NULL
};
const esp_efuse_desc_t* ESP_EFUSE_UART_PRINT_CONTROL[] = {
&UART_PRINT_CONTROL[0], // [] Represents the type of UART printing. 00: force enable printing 01: enable printing when GPIO8 is reset at low level 10: enable printing when GPIO8 is reset at high level 11: force disable printing
NULL
};
const esp_efuse_desc_t* ESP_EFUSE_FORCE_SEND_RESUME[] = {
&FORCE_SEND_RESUME[0], // [] Represents whether ROM code is forced to send a resume command during SPI boot. 1: forced 0:not forced
NULL
};
const esp_efuse_desc_t* ESP_EFUSE_SECURE_VERSION[] = {
&SECURE_VERSION[0], // [] Represents the version used by ESP-IDF anti-rollback feature
NULL
};
const esp_efuse_desc_t* ESP_EFUSE_HUK_GEN_STATE[] = {
&HUK_GEN_STATE[0], // [] Represents whether the HUK generate mode is valid.Odd count of bits with a value of 1: InvalidEven count of bits with a value of 1: Valid
NULL
};
const esp_efuse_desc_t* ESP_EFUSE_FLASH_LDO_EFUSE_SEL[] = {
&FLASH_LDO_EFUSE_SEL[0], // [] Represents whether to select efuse control flash ldo default voltage. 1 : efuse 0 : strapping
NULL
};
const esp_efuse_desc_t* ESP_EFUSE_USB_EXCHG_PINS[] = {
&USB_EXCHG_PINS[0], // [] Represents whether the D+ and D- pins of USB_SERIAL_JTAG PHY is exchanged. 1: exchanged 0: not exchanged
NULL
};
const esp_efuse_desc_t* ESP_EFUSE_USB_OTG_FS_EXCHG_PINS[] = {
&USB_OTG_FS_EXCHG_PINS[0], // [] Represents whether the D+ and D- pins of USB_OTG_FS PHY is exchanged. 1: exchanged 0: not exchanged
NULL
};
const esp_efuse_desc_t* ESP_EFUSE_USB_PHY_SEL[] = {
&USB_PHY_SEL[0], // [] Represents whether to exchange the USB_SERIAL_JTAG PHY with USB_OTG_FS PHY. 1: exchanged. 0: not exchanged
NULL
};
const esp_efuse_desc_t* ESP_EFUSE_SOFT_DIS_JTAG[] = {
&SOFT_DIS_JTAG[0], // [] Represents whether JTAG is disabled in soft way. Odd number: disabled Even number: enabled
NULL
};
const esp_efuse_desc_t* ESP_EFUSE_IO_LDO_ADJUST[] = {
&IO_LDO_ADJUST[0], // [] Represents configuration of IO LDO mode and voltage.
NULL
};
const esp_efuse_desc_t* ESP_EFUSE_IO_LDO_1P8[] = {
&IO_LDO_1P8[0], // [] Represents select IO LDO voltage to 1.8V or 3.3V. 1: 1.8V 0: 3.3V
NULL
};
const esp_efuse_desc_t* ESP_EFUSE_DCDC_CCM_EN[] = {
&DCDC_CCM_EN[0], // [] Represents whether change DCDC to CCM mode
NULL
};
const esp_efuse_desc_t* ESP_EFUSE_MAC[] = {
&MAC[0], // [MAC_FACTORY] MAC address
&MAC[1], // [MAC_FACTORY] MAC address
&MAC[2], // [MAC_FACTORY] MAC address
&MAC[3], // [MAC_FACTORY] MAC address
&MAC[4], // [MAC_FACTORY] MAC address
&MAC[5], // [MAC_FACTORY] MAC address
NULL
};
const esp_efuse_desc_t* ESP_EFUSE_MAC_EXT[] = {
&MAC_EXT[0], // [] Stores the extended bits of MAC address
&MAC_EXT[1], // [] Stores the extended bits of MAC address
NULL
};
const esp_efuse_desc_t* ESP_EFUSE_PVT_LIMIT[] = {
&PVT_LIMIT[0], // [] Power glitch monitor threthold
NULL
};
const esp_efuse_desc_t* ESP_EFUSE_PVT_CELL_SELECT[] = {
&PVT_CELL_SELECT[0], // [] Power glitch monitor PVT cell select
NULL
};
const esp_efuse_desc_t* ESP_EFUSE_PVT_PUMP_LIMIT[] = {
&PVT_PUMP_LIMIT[0], // [] Use to configure voltage monitor limit for charge pump
NULL
};
const esp_efuse_desc_t* ESP_EFUSE_PUMP_DRV[] = {
&PUMP_DRV[0], // [] Use to configure charge pump voltage gain
NULL
};
const esp_efuse_desc_t* ESP_EFUSE_WDT_DELAY_SEL[] = {
&WDT_DELAY_SEL[0], // [] Represents the threshold level of the RTC watchdog STG0 timeout. 0: Original threshold configuration value of STG0 *2 1: Original threshold configuration value of STG0 *4 2: Original threshold configuration value of STG0 *8 3: Original threshold configuration value of STG0 *16
NULL
};
const esp_efuse_desc_t* ESP_EFUSE_HYS_EN_PAD[] = {
&HYS_EN_PAD[0], // [] Represents whether the hysteresis function of corresponding PAD is enabled. 1: enabled 0:disabled
NULL
};
const esp_efuse_desc_t* ESP_EFUSE_PVT_GLITCH_CHARGE_RESET[] = {
&PVT_GLITCH_CHARGE_RESET[0], // [] Represents whether to trigger reset or charge pump when PVT power glitch happened.1:Trigger charge pump. 0:Trigger reset
NULL
};
const esp_efuse_desc_t* ESP_EFUSE_VDD_SPI_LDO_ADJUST[] = {
&VDD_SPI_LDO_ADJUST[0], // [] Represents configuration of FLASH LDO mode and voltage.
NULL
};
const esp_efuse_desc_t* ESP_EFUSE_FLASH_LDO_POWER_SEL[] = {
&FLASH_LDO_POWER_SEL[0], // [] Represents which flash ldo be select: 1: FLASH LDO 1P2 0 : FLASH LDO 1P8
NULL
};
const esp_efuse_desc_t* ESP_EFUSE_USER_DATA[] = {
&USER_DATA[0], // [BLOCK_USR_DATA] User data
NULL
};
const esp_efuse_desc_t* ESP_EFUSE_USER_DATA_MAC_CUSTOM[] = {
&USER_DATA_MAC_CUSTOM[0], // [MAC_CUSTOM CUSTOM_MAC] Custom MAC
NULL
};
const esp_efuse_desc_t* ESP_EFUSE_KEY0[] = {
&KEY0[0], // [BLOCK_KEY0] Key0 or user data
NULL
};
const esp_efuse_desc_t* ESP_EFUSE_KEY1[] = {
&KEY1[0], // [BLOCK_KEY1] Key1 or user data
NULL
};
const esp_efuse_desc_t* ESP_EFUSE_KEY2[] = {
&KEY2[0], // [BLOCK_KEY2] Key2 or user data
NULL
};
const esp_efuse_desc_t* ESP_EFUSE_KEY3[] = {
&KEY3[0], // [BLOCK_KEY3] Key3 or user data
NULL
};
const esp_efuse_desc_t* ESP_EFUSE_KEY4[] = {
&KEY4[0], // [BLOCK_KEY4] Key4 or user data
NULL
};
const esp_efuse_desc_t* ESP_EFUSE_KEY5[] = {
&KEY5[0], // [BLOCK_KEY5] Key5 or user data
NULL
};
const esp_efuse_desc_t* ESP_EFUSE_SYS_DATA_PART2[] = {
&SYS_DATA_PART2[0], // [BLOCK_SYS_DATA2] System data part 2 (reserved)
NULL
};
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