杂项系统 API

[English]

软件复位

函数 esp_restart() 用于执行芯片的软件复位。调用此函数时，程序停止执行，CPU 复位，应用程序由 bootloader 加载并重启。

函数 esp_register_shutdown_handler() 用于注册复位前会自动调用的例程（复位过程由 esp_restart() 函数触发），这与 atexit POSIX 函数的功能类似。

复位原因

ESP-IDF 应用程序启动或复位的原因有多种。调用 esp_reset_reason() 函数可获取最近一次复位的原因。复位的所有可能原因，请查看 esp_reset_reason_t 中的描述。

堆内存

ESP-IDF 中有两个与堆内存相关的函数：

函数 esp_get_free_heap_size() 用于查询当前可用的堆内存大小。
函数 esp_get_minimum_free_heap_size() 用于查询整个过程中可用的最小堆内存大小（例如应用程序生命周期内可用的最小堆内存大小）。

请注意，ESP-IDF 支持功能不同的的多个堆。上文中函数返回的堆内存大小可使用 malloc 函数族来进行分配。有关堆内存的更多信息，请参阅堆内存分配。

MAC 地址

以下 API 用于查询和自定义支持的网络接口（如 Wi-Fi、蓝牙、以太网）的 MAC 地址。

要获取特定接口（如 Wi-Fi、蓝牙、以太网）的 MAC 地址，请调用函数 esp_read_mac()。

在 ESP-IDF 中，各个网络接口的 MAC 地址是根据单个 基准 MAC 地址 (Base MAC address) 计算出来的。默认情况下使用乐鑫指定的基准 MAC 地址，该基准地址在产品生产过程中已预烧录至 ESP32-C3 eFuse。

接口	MAC 地址（默认 4 个全局地址)	MAC 地址（2 个全局地址）
Wi-Fi Station	base_mac	base_mac
Wi-Fi SoftAP	base_mac 最后一组字节后加 1	本地 MAC （由 Wi-Fi Station MAC 生成）
蓝牙	base_mac 最后一组字节后加 2	base_mac 最后一组字节后加 1
以太网	base_mac 最后一组字节后加 3	本地 MAC （由蓝牙 MAC 生成）

备注

配置选项配置了乐鑫提供的全局 MAC 地址的数量。

备注

ESP32-C3 内部未集成以太网 MAC 地址，但仍可以计算得出该地址。不过，以太网 MAC 地址只能与外部以太网接口（如 SPI 以太网设备）一起使用，具体请参阅以太网。

自定义基准 MAC

乐鑫已将默认的基准 MAC 地址预烧录至 eFuse BLK1 中。如需设置自定义基准 MAC 地址，请在初始化任一网络接口或调用 esp_read_mac() 函数前调用 esp_base_mac_addr_set() 函数。自定义基准 MAC 地址可以存储在任何支持的存储设备中（例如 flash、NVS）。

分配自定义基准 MAC 地址时，应避免 MAC 地址重叠。请根据上面的表格配置选项 CONFIG_ESP32C3_UNIVERSAL_MAC_ADDRESSES，设置可从自定义基准 MAC 地址生成的有效全局 MAC 地址。

备注

也可以调用函数 esp_netif_set_mac()，在网络初始化后设置网络接口使用的特定 MAC。但建议使用此处介绍的自定义基准 MAC 地址的方法，以避免原始 MAC 地址在更改前短暂出现在网络上。

eFuse 中的自定义 MAC 地址

ESP-IDF 提供了 esp_efuse_mac_get_custom() 函数。从 eFuse 读取自定义 MAC 地址时，调用该函数将从 eFuse BLK3 加载 MAC 地址。此函数假定自定义基准 MAC 地址的存储格式如下：

字段	比特数	比特范围
MAC address	48	200:248

备注

eFuse BLK3 在烧写时使用 RS 编码，这意味着必须同时烧写该块中的所有 eFuse 字段。

调用 esp_efuse_mac_get_custom() 函数获得 MAC 地址后，请调用 esp_base_mac_addr_set() 函数将此 MAC 地址设置为基准 MAC 地址。

本地 MAC 地址和全局 MAC 地址

在 ESP32-C3 中，乐鑫已预烧录足够数量的有效乐鑫全局 MAC 地址，供所有内部接口使用。上文中的表格已经介绍了如何根据基准 MAC 地址计算出具体接口的 MAC 地址。

当使用自定义 MAC 地址时，可能并非所有接口都能被分配到一个全局 MAC 地址。此时，接口会被分配一个本地 MAC 地址。请注意，这些地址仅用于单个本地网络。

本地 MAC 地址和全局 MAC 地址的定义，请参见此处。

内部调用函数 esp_derive_local_mac()，可从全局 MAC 地址生成本地 MAC 地址。具体流程如下：

在全局 MAC 地址的第一个字节组中设置 U/L 位（位值为 0x2），创建本地 MAC 地址。
如果该位已存在于全局 MAC 地址中（即现有的 “全局” MAC 地址实际上已经是本地 MAC 地址），则本地 MAC 地址的第一个字节组与 0x4 异或。

芯片版本

esp_chip_info() 函数用于填充 esp_chip_info_t 结构体中的芯片信息，包括芯片版本、CPU 数量和芯片中已启用功能的位掩码。

SDK 版本

调用函数 esp_get_idf_version() 可返回一个字符串，该字符串包含了用于编译应用程序的 ESP-IDF 版本，与构建系统中通过 IDF_VER 变量所获得的值相同。该版本字符串的格式即 git describe 命令的运行结果。

也有其它的版本宏可用于在构建过程中获取 ESP-IDF 版本，它们可根据 ESP-IDF 版本启用或禁用部分程序。

ESP_IDF_VERSION_MAJOR、 ESP_IDF_VERSION_MINOR 和 ESP_IDF_VERSION_PATCH 分别被定义为代表主要版本、次要版本和补丁版本的整数。

ESP_IDF_VERSION_VAL 和 ESP_IDF_VERSION 可在确认版本时使用：

#include "esp_idf_version.h"

#if ESP_IDF_VERSION >= ESP_IDF_VERSION_VAL(4, 0, 0)
    // 启用 ESP-IDF v4.0 中的功能
#endif

应用程序版本

应用程序版本存储在 esp_app_desc_t 结构体中。该结构体位于 DROM 扇区，有一个从二进制文件头部计算的固定偏移值。该结构体位于 esp_image_header_t 和 esp_image_segment_header_t 结构体之后。字段 Version 类型为字符串，最大长度为 32 字节。

若需手动设置版本，需要在项目的 CMakeLists.txt 文件中设置 PROJECT_VER 变量，即在 CMakeLists.txt 文件中，在包含 project.cmake 之前添加 set(PROJECT_VER "0.1.0.1")。

如果设置了 CONFIG_APP_PROJECT_VER_FROM_CONFIG 选项，则将使用 CONFIG_APP_PROJECT_VER 的值。否则，如果在项目中未设置 PROJECT_VER 变量，则该变量将从 $(PROJECT_PATH)/version.txt 文件（若有）中检索，或使用 git 命令 git describe 检索。如果两者都不可用，则 PROJECT_VER 将被设置为 “1”。应用程序可通过调用 esp_app_get_description() 或 esp_ota_get_partition_description() 函数来获取应用程序的版本信息。

API 参考

Header File

components/esp_system/include/esp_system.h

Functions

esp_err_t esp_register_shutdown_handler(shutdown_handler_t handle)

Register shutdown handler.

This function allows you to register a handler that gets invoked before the application is restarted using esp_restart function.

参数

handle – function to execute on restart

返回

ESP_OK on success
ESP_ERR_INVALID_STATE if the handler has already been registered
ESP_ERR_NO_MEM if no more shutdown handler slots are available

esp_err_t esp_unregister_shutdown_handler(shutdown_handler_t handle)

Unregister shutdown handler.

This function allows you to unregister a handler which was previously registered using esp_register_shutdown_handler function.

ESP_OK on success
ESP_ERR_INVALID_STATE if the given handler hasn’t been registered before

void esp_restart(void)

Restart PRO and APP CPUs.

This function can be called both from PRO and APP CPUs. After successful restart, CPU reset reason will be SW_CPU_RESET. Peripherals (except for Wi-Fi, BT, UART0, SPI1, and legacy timers) are not reset. This function does not return.

esp_reset_reason_t esp_reset_reason(void)

Get reason of last reset.

返回: See description of esp_reset_reason_t for explanation of each value.

uint32_t esp_get_free_heap_size(void)

Get the size of available heap.

备注

Note that the returned value may be larger than the maximum contiguous block which can be allocated.

返回: Available heap size, in bytes.

uint32_t esp_get_free_internal_heap_size(void)

Get the size of available internal heap.

备注

Note that the returned value may be larger than the maximum contiguous block which can be allocated.

返回: Available internal heap size, in bytes.

uint32_t esp_get_minimum_free_heap_size(void)

Get the minimum heap that has ever been available.

返回: Minimum free heap ever available

void esp_system_abort(const char *details)

Trigger a software abort.

参数: details – Details that will be displayed during panic handling.

Type Definitions

typedef void (*shutdown_handler_t)(void): Shutdown handler type

Enumerations

enum esp_reset_reason_t

Reset reasons.

Values:

enumerator ESP_RST_UNKNOWN: Reset reason can not be determined.

enumerator ESP_RST_POWERON: Reset due to power-on event.

enumerator ESP_RST_EXT: Reset by external pin (not applicable for ESP32)

enumerator ESP_RST_SW: Software reset via esp_restart.

enumerator ESP_RST_PANIC: Software reset due to exception/panic.

enumerator ESP_RST_INT_WDT: Reset (software or hardware) due to interrupt watchdog.

enumerator ESP_RST_TASK_WDT: Reset due to task watchdog.

enumerator ESP_RST_WDT: Reset due to other watchdogs.

enumerator ESP_RST_DEEPSLEEP: Reset after exiting deep sleep mode.

enumerator ESP_RST_BROWNOUT: Brownout reset (software or hardware)

enumerator ESP_RST_SDIO: Reset over SDIO.

Header File

components/esp_common/include/esp_idf_version.h

Functions

const char *esp_get_idf_version(void)

Return full IDF version string, same as ‘git describe’ output.

备注

If you are printing the ESP-IDF version in a log file or other information, this function provides more information than using the numerical version macros. For example, numerical version macros don’t differentiate between development, pre-release and release versions, but the output of this function does.

返回: constant string from IDF_VER

Macros

ESP_IDF_VERSION_MAJOR: Major version number (X.x.x)

ESP_IDF_VERSION_MINOR: Minor version number (x.X.x)

ESP_IDF_VERSION_PATCH: Patch version number (x.x.X)

ESP_IDF_VERSION_VAL(major, minor, patch)

Macro to convert IDF version number into an integer

To be used in comparisons, such as ESP_IDF_VERSION >= ESP_IDF_VERSION_VAL(4, 0, 0)

ESP_IDF_VERSION

Current IDF version, as an integer

To be used in comparisons, such as ESP_IDF_VERSION >= ESP_IDF_VERSION_VAL(4, 0, 0)

Header File

components/esp_hw_support/include/esp_mac.h

Functions

esp_err_t esp_base_mac_addr_set(const uint8_t *mac)

Set base MAC address with the MAC address which is stored in BLK3 of EFUSE or external storage e.g. flash and EEPROM.

Base MAC address is used to generate the MAC addresses used by network interfaces.

If using a custom base MAC address, call this API before initializing any network interfaces. Refer to the ESP-IDF Programming Guide for details about how the Base MAC is used.

备注

Base MAC must be a unicast MAC (least significant bit of first byte must be zero).

备注

If not using a valid OUI, set the “locally administered” bit (bit value 0x02 in the first byte) to avoid collisions.

参数: mac – base MAC address, length: 6 bytes/8 bytes. length: 6 bytes for MAC-48 8 bytes for EUI-64(used for IEEE 802.15.4)
返回: ESP_OK on success ESP_ERR_INVALID_ARG If mac is NULL or is not a unicast MAC

esp_err_t esp_base_mac_addr_get(uint8_t *mac)

Return base MAC address which is set using esp_base_mac_addr_set.

备注

If no custom Base MAC has been set, this returns the pre-programmed Espressif base MAC address.

参数: mac – base MAC address, length: 6 bytes/8 bytes. length: 6 bytes for MAC-48 8 bytes for EUI-64(used for IEEE 802.15.4)
返回: ESP_OK on success ESP_ERR_INVALID_ARG mac is NULL ESP_ERR_INVALID_MAC base MAC address has not been set

esp_err_t esp_efuse_mac_get_custom(uint8_t *mac)

Return base MAC address which was previously written to BLK3 of EFUSE.

Base MAC address is used to generate the MAC addresses used by the networking interfaces. This API returns the custom base MAC address which was previously written to EFUSE BLK3 in a specified format.

Writing this EFUSE allows setting of a different (non-Espressif) base MAC address. It is also possible to store a custom base MAC address elsewhere, see esp_base_mac_addr_set() for details.

备注

This function is currently only supported on ESP32.

参数: mac – base MAC address, length: 6 bytes/8 bytes. length: 6 bytes for MAC-48 8 bytes for EUI-64(used for IEEE 802.15.4)
返回: ESP_OK on success ESP_ERR_INVALID_ARG mac is NULL ESP_ERR_INVALID_MAC CUSTOM_MAC address has not been set, all zeros (for esp32-xx) ESP_ERR_INVALID_VERSION An invalid MAC version field was read from BLK3 of EFUSE (for esp32) ESP_ERR_INVALID_CRC An invalid MAC CRC was read from BLK3 of EFUSE (for esp32)

esp_err_t esp_efuse_mac_get_default(uint8_t *mac)

Return base MAC address which is factory-programmed by Espressif in EFUSE.

参数: mac – base MAC address, length: 6 bytes/8 bytes. length: 6 bytes for MAC-48 8 bytes for EUI-64(used for IEEE 802.15.4)
返回: ESP_OK on success ESP_ERR_INVALID_ARG mac is NULL

esp_err_t esp_read_mac(uint8_t *mac, esp_mac_type_t type)

Read base MAC address and set MAC address of the interface.

This function first get base MAC address using esp_base_mac_addr_get(). Then calculates the MAC address of the specific interface requested, refer to ESP-IDF Programming Guide for the algorithm.

参数

mac – base MAC address, length: 6 bytes/8 bytes. length: 6 bytes for MAC-48 8 bytes for EUI-64(used for IEEE 802.15.4)
type – Type of MAC address to return

返回

ESP_OK on success

esp_err_t esp_derive_local_mac(uint8_t *local_mac, const uint8_t *universal_mac)

Derive local MAC address from universal MAC address.

This function copies a universal MAC address and then sets the “locally

administered” bit (bit 0x2) in the first octet, creating a locally administered MAC address.

If the universal MAC address argument is already a locally administered MAC address, then the first octet is XORed with 0x4 in order to create a different locally administered MAC address.

参数

local_mac – base MAC address, length: 6 bytes/8 bytes. length: 6 bytes for MAC-48 8 bytes for EUI-64(used for IEEE 802.15.4)
universal_mac – Source universal MAC address, length: 6 bytes.

返回

ESP_OK on success

Macros

MAC2STR(a)

MACSTR

Enumerations

enum esp_mac_type_t

Values:

enumerator ESP_MAC_WIFI_STA

enumerator ESP_MAC_WIFI_SOFTAP

enumerator ESP_MAC_BT

enumerator ESP_MAC_ETH

enumerator ESP_MAC_IEEE802154

Header File

components/esp_hw_support/include/esp_chip_info.h

Functions

void esp_chip_info(esp_chip_info_t *out_info)

Fill an esp_chip_info_t structure with information about the chip.

参数: out_info – [out] structure to be filled

Structures

struct esp_chip_info_t

The structure represents information about the chip.

Public Members

esp_chip_model_t model: chip model, one of esp_chip_model_t

uint32_t features: bit mask of CHIP_FEATURE_x feature flags

uint16_t revision: chip revision number (in format MXX; where M - wafer major version, XX - wafer minor version)

uint8_t cores: number of CPU cores

Macros

CHIP_FEATURE_EMB_FLASH: Chip has embedded flash memory.

CHIP_FEATURE_WIFI_BGN: Chip has 2.4GHz WiFi.

CHIP_FEATURE_BLE: Chip has Bluetooth LE.

CHIP_FEATURE_BT: Chip has Bluetooth Classic.

CHIP_FEATURE_IEEE802154: Chip has IEEE 802.15.4.

CHIP_FEATURE_EMB_PSRAM: Chip has embedded psram.

Enumerations

enum esp_chip_model_t

Chip models.

Values:

enumerator CHIP_ESP32: ESP32.

enumerator CHIP_ESP32S2: ESP32-S2.

enumerator CHIP_ESP32S3: ESP32-S3.

enumerator CHIP_ESP32C3: ESP32-C3.

enumerator CHIP_ESP32H2: ESP32-H2.

enumerator CHIP_ESP32C2: ESP32-C2.

Header File

components/esp_hw_support/include/esp_cpu.h

Functions

void esp_cpu_stall(int core_id)

Stall a CPU core.

参数: core_id – The core’s ID

void esp_cpu_unstall(int core_id)

Resume a previously stalled CPU core.

参数: core_id – The core’s ID

void esp_cpu_reset(int core_id)

Reset a CPU core.

参数: core_id – The core’s ID

void esp_cpu_wait_for_intr(void)

Wait for Interrupt.

This function causes the current CPU core to execute its Wait For Interrupt (WFI or equivalent) instruction. After executing this function, the CPU core will stop execution until an interrupt occurs.

int esp_cpu_get_core_id(void)

Get the current core’s ID.

This function will return the ID of the current CPU (i.e., the CPU that calls this function).

返回: The current core’s ID [0..SOC_CPU_CORES_NUM - 1]

void *esp_cpu_get_sp(void)

Read the current stack pointer address.

返回: Stack pointer address

esp_cpu_cycle_count_t esp_cpu_get_cycle_count(void)

Get the current CPU core’s cycle count.

Each CPU core maintains an internal counter (i.e., cycle count) that increments every CPU clock cycle.

返回: Current CPU’s cycle count, 0 if not supported.

void esp_cpu_set_cycle_count(esp_cpu_cycle_count_t cycle_count)

Set the current CPU core’s cycle count.

Set the given value into the internal counter that increments every CPU clock cycle.

参数: cycle_count – CPU cycle count

void *esp_cpu_pc_to_addr(uint32_t pc)

Convert a program counter (PC) value to address.

If the architecture does not store the true virtual address in the CPU’s PC or return addresses, this function will convert the PC value to a virtual address. Otherwise, the PC is just returned

参数: pc – PC value
返回: Virtual address

void esp_cpu_intr_get_desc(int core_id, int intr_num, esp_cpu_intr_desc_t *intr_desc_ret)

Get a CPU interrupt’s descriptor.

Each CPU interrupt has a descriptor describing the interrupt’s capabilities and restrictions. This function gets the descriptor of a particular interrupt on a particular CPU.

参数

core_id – [in] The core’s ID
intr_num – [in] Interrupt number
intr_desc_ret – [out] The interrupt’s descriptor

void esp_cpu_intr_set_ivt_addr(const void *ivt_addr)

Set the base address of the current CPU’s Interrupt Vector Table (IVT)

参数: ivt_addr – Interrupt Vector Table’s base address

void esp_cpu_intr_set_type(int intr_num, esp_cpu_intr_type_t intr_type)

Set the interrupt type of a particular interrupt.

Set the interrupt type (Level or Edge) of a particular interrupt on the current CPU.

参数

intr_num – Interrupt number (from 0 to 31)
intr_type – The interrupt’s type

esp_cpu_intr_type_t esp_cpu_intr_get_type(int intr_num)

Get the current configured type of a particular interrupt.

Get the currently configured type (i.e., level or edge) of a particular interrupt on the current CPU.

参数: intr_num – Interrupt number (from 0 to 31)
返回: Interrupt type

void esp_cpu_intr_set_priority(int intr_num, int intr_priority)

Set the priority of a particular interrupt.

Set the priority of a particular interrupt on the current CPU.

参数

intr_num – Interrupt number (from 0 to 31)
intr_priority – The interrupt’s priority

int esp_cpu_intr_get_priority(int intr_num)

Get the current configured priority of a particular interrupt.

Get the currently configured priority of a particular interrupt on the current CPU.

参数: intr_num – Interrupt number (from 0 to 31)
返回: Interrupt’s priority

bool esp_cpu_intr_has_handler(int intr_num)

Check if a particular interrupt already has a handler function.

Check if a particular interrupt on the current CPU already has a handler function assigned.

备注

This function simply checks if the IVT of the current CPU already has a handler assigned.

参数: intr_num – Interrupt number (from 0 to 31)
返回: True if the interrupt has a handler function, false otherwise.

void esp_cpu_intr_set_handler(int intr_num, esp_cpu_intr_handler_t handler, void *handler_arg)

Set the handler function of a particular interrupt.

Assign a handler function (i.e., ISR) to a particular interrupt on the current CPU.

备注

This function simply sets the handler function (in the IVT) and does not actually enable the interrupt.

参数

intr_num – Interrupt number (from 0 to 31)
handler – Handler function
handler_arg – Argument passed to the handler function

void *esp_cpu_intr_get_handler_arg(int intr_num)

Get a handler function’s argument of.

Get the argument of a previously assigned handler function on the current CPU.

参数: intr_num – Interrupt number (from 0 to 31)
返回: The the argument passed to the handler function

void esp_cpu_intr_enable(uint32_t intr_mask)

Enable particular interrupts on the current CPU.

参数: intr_mask – Bit mask of the interrupts to enable

void esp_cpu_intr_disable(uint32_t intr_mask)

Disable particular interrupts on the current CPU.

参数: intr_mask – Bit mask of the interrupts to disable

uint32_t esp_cpu_intr_get_enabled_mask(void)

Get the enabled interrupts on the current CPU.

返回: Bit mask of the enabled interrupts

void esp_cpu_intr_edge_ack(int intr_num)

Acknowledge an edge interrupt.

参数: intr_num – Interrupt number (from 0 to 31)

void esp_cpu_configure_region_protection(void): Configure the CPU to disable access to invalid memory regions.

esp_err_t esp_cpu_set_breakpoint(int bp_num, const void *bp_addr)

Set and enable a hardware breakpoint on the current CPU.

备注

This function is meant to be called by the panic handler to set a breakpoint for an attached debugger during a panic.

备注

Overwrites previously set breakpoint with same breakpoint number.

参数

bp_num – Hardware breakpoint number [0..SOC_CPU_BREAKPOINTS_NUM - 1]
bp_addr – Address to set a breakpoint on

返回

ESP_OK if breakpoint is set. Failure otherwise

esp_err_t esp_cpu_clear_breakpoint(int bp_num)

Clear a hardware breakpoint on the current CPU.

备注

Clears a breakpoint regardless of whether it was previously set

参数: bp_num – Hardware breakpoint number [0..SOC_CPU_BREAKPOINTS_NUM - 1]
返回: ESP_OK if breakpoint is cleared. Failure otherwise

esp_err_t esp_cpu_set_watchpoint(int wp_num, const void *wp_addr, size_t size, esp_cpu_watchpoint_trigger_t trigger)

Set and enable a hardware watchpoint on the current CPU.

Set and enable a hardware watchpoint on the current CPU, specifying the memory range and trigger operation. Watchpoints will break/panic the CPU when the CPU accesses (according to the trigger type) on a certain memory range.

备注

Overwrites previously set watchpoint with same watchpoint number.

参数

wp_num – Hardware watchpoint number [0..SOC_CPU_WATCHPOINTS_NUM - 1]
wp_addr – Watchpoint’s base address
size – Size of the region to watch. Must be one of 2^n, with n in [0..6].
trigger – Trigger type

返回

ESP_ERR_INVALID_ARG on invalid arg, ESP_OK otherwise

esp_err_t esp_cpu_clear_watchpoint(int wp_num)

Clear a hardware watchpoint on the current CPU.

备注

Clears a watchpoint regardless of whether it was previously set

参数: wp_num – Hardware watchpoint number [0..SOC_CPU_WATCHPOINTS_NUM - 1]
返回: ESP_OK if watchpoint was cleared. Failure otherwise.

bool esp_cpu_dbgr_is_attached(void)

Check if the current CPU has a debugger attached.

返回: True if debugger is attached, false otherwise

void esp_cpu_dbgr_break(void): Trigger a call to the current CPU’s attached debugger.

intptr_t esp_cpu_get_call_addr(intptr_t return_address)

Given the return address, calculate the address of the preceding call instruction This is typically used to answer the question “where was the function called from?”.

参数: return_address – The value of the return address register. Typically set to the value of __builtin_return_address(0).
返回: Address of the call instruction preceding the return address.

bool esp_cpu_compare_and_set(volatile uint32_t *addr, uint32_t compare_value, uint32_t new_value)

Atomic compare-and-set operation.

参数

addr – Address of atomic variable
compare_value – Value to compare the atomic variable to
new_value – New value to set the atomic variable to

返回

Whether the atomic variable was set or not

Structures

struct esp_cpu_intr_desc_t

CPU interrupt descriptor.

Each particular CPU interrupt has an associated descriptor describing that particular interrupt’s characteristics. Call esp_cpu_intr_get_desc() to get the descriptors of a particular interrupt.

Public Members

int priority: Priority of the interrupt if it has a fixed priority, (-1) if the priority is configurable.

esp_cpu_intr_type_t type: Whether the interrupt is an edge or level type interrupt, ESP_CPU_INTR_TYPE_NA if the type is configurable.

uint32_t flags: Flags indicating extra details.

Macros

ESP_CPU_INTR_DESC_FLAG_SPECIAL

Interrupt descriptor flags of esp_cpu_intr_desc_t.

The interrupt is a special interrupt (e.g., a CPU timer interrupt)

ESP_CPU_INTR_DESC_FLAG_RESVD: The interrupt is reserved for internal use

Type Definitions

typedef uint32_t esp_cpu_cycle_count_t

CPU cycle count type.

This data type represents the CPU’s clock cycle count

typedef void (*esp_cpu_intr_handler_t)(void *arg): CPU interrupt handler type.

Enumerations

enum esp_cpu_intr_type_t

CPU interrupt type.

Values:

enumerator ESP_CPU_INTR_TYPE_LEVEL

enumerator ESP_CPU_INTR_TYPE_EDGE

enumerator ESP_CPU_INTR_TYPE_NA

enum esp_cpu_watchpoint_trigger_t

CPU watchpoint trigger type.

Values:

enumerator ESP_CPU_WATCHPOINT_LOAD

enumerator ESP_CPU_WATCHPOINT_STORE

enumerator ESP_CPU_WATCHPOINT_ACCESS

Header File

components/esp_app_format/include/esp_app_desc.h

Functions

const esp_app_desc_t *esp_app_get_description(void)

Return esp_app_desc structure. This structure includes app version.

Return description for running app.

返回: Pointer to esp_app_desc structure.

int esp_app_get_elf_sha256(char *dst, size_t size)

Fill the provided buffer with SHA256 of the ELF file, formatted as hexadecimal, null-terminated. If the buffer size is not sufficient to fit the entire SHA256 in hex plus a null terminator, the largest possible number of bytes will be written followed by a null.

参数

dst – Destination buffer
size – Size of the buffer

返回

Number of bytes written to dst (including null terminator)

Structures

struct esp_app_desc_t

Description about application.

Public Members

uint32_t magic_word: Magic word ESP_APP_DESC_MAGIC_WORD

uint32_t secure_version: Secure version

uint32_t reserv1[2]: reserv1

char version[32]: Application version

char project_name[32]: Project name

char time[16]: Compile time

char date[16]: Compile date

char idf_ver[32]: Version IDF

uint8_t app_elf_sha256[32]: sha256 of elf file

uint32_t reserv2[20]: reserv2

Macros

ESP_APP_DESC_MAGIC_WORD: The magic word for the esp_app_desc structure that is in DROM.

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