bbad487deb
Routine `spi_flash_cache2phys` sometimes return incorrect value, resulting in failure in getting currently running ota partition. This in turn aborts firmware update process.This issue was more prominent with SPIRAM enabled cases. Fix ensures proper cache guards during `spi_flash_cache2phys`, and also for few other similar APIs. In addition, `esp_ota_get_running_partition` has also been optimized to save currently running partition for subsequent invocations. Fixes https://github.com/espressif/esp-idf/issues/2451
427 lines
16 KiB
C
427 lines
16 KiB
C
// Copyright 2015-2016 Espressif Systems (Shanghai) PTE LTD
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//
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// Licensed under the Apache License, Version 2.0 (the "License");
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// you may not use this file except in compliance with the License.
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// You may obtain a copy of the License at
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// http://www.apache.org/licenses/LICENSE-2.0
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//
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// Unless required by applicable law or agreed to in writing, software
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// distributed under the License is distributed on an "AS IS" BASIS,
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// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
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// See the License for the specific language governing permissions and
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// limitations under the License.
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#ifndef ESP_SPI_FLASH_H
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#define ESP_SPI_FLASH_H
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#include <stdint.h>
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#include <stdbool.h>
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#include <stddef.h>
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#include "esp_err.h"
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#include "sdkconfig.h"
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#ifdef __cplusplus
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extern "C" {
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#endif
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#define ESP_ERR_FLASH_BASE 0x10010
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#define ESP_ERR_FLASH_OP_FAIL (ESP_ERR_FLASH_BASE + 1)
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#define ESP_ERR_FLASH_OP_TIMEOUT (ESP_ERR_FLASH_BASE + 2)
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#define SPI_FLASH_SEC_SIZE 4096 /**< SPI Flash sector size */
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#define SPI_FLASH_MMU_PAGE_SIZE 0x10000 /**< Flash cache MMU mapping page size */
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/**
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* @brief Initialize SPI flash access driver
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*
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* This function must be called exactly once, before any other
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* spi_flash_* functions are called.
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* Currently this function is called from startup code. There is
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* no need to call it from application code.
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*
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*/
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void spi_flash_init();
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/**
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* @brief Get flash chip size, as set in binary image header
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*
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* @note This value does not necessarily match real flash size.
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*
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* @return size of flash chip, in bytes
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*/
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size_t spi_flash_get_chip_size();
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/**
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* @brief Erase the Flash sector.
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*
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* @param sector Sector number, the count starts at sector 0, 4KB per sector.
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*
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* @return esp_err_t
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*/
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esp_err_t spi_flash_erase_sector(size_t sector);
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/**
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* @brief Erase a range of flash sectors
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*
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* @param start_address Address where erase operation has to start.
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* Must be 4kB-aligned
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* @param size Size of erased range, in bytes. Must be divisible by 4kB.
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*
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* @return esp_err_t
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*/
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esp_err_t spi_flash_erase_range(size_t start_address, size_t size);
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/**
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* @brief Write data to Flash.
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*
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* @note For fastest write performance, write a 4 byte aligned size at a
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* 4 byte aligned offset in flash from a source buffer in DRAM. Varying any of
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* these parameters will still work, but will be slower due to buffering.
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*
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* @note Writing more than 8KB at a time will be split into multiple
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* write operations to avoid disrupting other tasks in the system.
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*
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* @param dest_addr Destination address in Flash.
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* @param src Pointer to the source buffer.
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* @param size Length of data, in bytes.
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*
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* @return esp_err_t
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*/
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esp_err_t spi_flash_write(size_t dest_addr, const void *src, size_t size);
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/**
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* @brief Write data encrypted to Flash.
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*
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* @note Flash encryption must be enabled for this function to work.
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*
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* @note Flash encryption must be enabled when calling this function.
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* If flash encryption is disabled, the function returns
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* ESP_ERR_INVALID_STATE. Use esp_flash_encryption_enabled()
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* function to determine if flash encryption is enabled.
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*
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* @note Both dest_addr and size must be multiples of 16 bytes. For
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* absolute best performance, both dest_addr and size arguments should
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* be multiples of 32 bytes.
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*
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* @param dest_addr Destination address in Flash. Must be a multiple of 16 bytes.
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* @param src Pointer to the source buffer.
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* @param size Length of data, in bytes. Must be a multiple of 16 bytes.
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*
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* @return esp_err_t
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*/
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esp_err_t spi_flash_write_encrypted(size_t dest_addr, const void *src, size_t size);
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/**
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* @brief Read data from Flash.
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*
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* @note For fastest read performance, all parameters should be
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* 4 byte aligned. If source address and read size are not 4 byte
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* aligned, read may be split into multiple flash operations. If
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* destination buffer is not 4 byte aligned, a temporary buffer will
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* be allocated on the stack.
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*
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* @note Reading more than 16KB of data at a time will be split
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* into multiple reads to avoid disruption to other tasks in the
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* system. Consider using spi_flash_mmap() to read large amounts
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* of data.
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*
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* @param src_addr source address of the data in Flash.
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* @param dest pointer to the destination buffer
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* @param size length of data
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*
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*
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* @return esp_err_t
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*/
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esp_err_t spi_flash_read(size_t src_addr, void *dest, size_t size);
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/**
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* @brief Read data from Encrypted Flash.
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*
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* If flash encryption is enabled, this function will transparently decrypt data as it is read.
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* If flash encryption is not enabled, this function behaves the same as spi_flash_read().
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*
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* See esp_flash_encryption_enabled() for a function to check if flash encryption is enabled.
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*
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* @param src source address of the data in Flash.
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* @param dest pointer to the destination buffer
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* @param size length of data
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*
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* @return esp_err_t
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*/
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esp_err_t spi_flash_read_encrypted(size_t src, void *dest, size_t size);
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/**
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* @brief Enumeration which specifies memory space requested in an mmap call
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*/
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typedef enum {
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SPI_FLASH_MMAP_DATA, /**< map to data memory (Vaddr0), allows byte-aligned access, 4 MB total */
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SPI_FLASH_MMAP_INST, /**< map to instruction memory (Vaddr1-3), allows only 4-byte-aligned access, 11 MB total */
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} spi_flash_mmap_memory_t;
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/**
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* @brief Opaque handle for memory region obtained from spi_flash_mmap.
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*/
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typedef uint32_t spi_flash_mmap_handle_t;
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/**
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* @brief Map region of flash memory into data or instruction address space
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*
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* This function allocates sufficient number of 64kB MMU pages and configures
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* them to map the requested region of flash memory into the address space.
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* It may reuse MMU pages which already provide the required mapping.
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*
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* As with any allocator, if mmap/munmap are heavily used then the address space
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* may become fragmented. To troubleshoot issues with page allocation, use
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* spi_flash_mmap_dump() function.
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*
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* @param src_addr Physical address in flash where requested region starts.
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* This address *must* be aligned to 64kB boundary
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* (SPI_FLASH_MMU_PAGE_SIZE)
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* @param size Size of region to be mapped. This size will be rounded
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* up to a 64kB boundary
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* @param memory Address space where the region should be mapped (data or instruction)
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* @param[out] out_ptr Output, pointer to the mapped memory region
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* @param[out] out_handle Output, handle which should be used for spi_flash_munmap call
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*
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* @return ESP_OK on success, ESP_ERR_NO_MEM if pages can not be allocated
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*/
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esp_err_t spi_flash_mmap(size_t src_addr, size_t size, spi_flash_mmap_memory_t memory,
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const void** out_ptr, spi_flash_mmap_handle_t* out_handle);
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/**
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* @brief Map sequences of pages of flash memory into data or instruction address space
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*
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* This function allocates sufficient number of 64kB MMU pages and configures
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* them to map the indicated pages of flash memory contiguously into address space.
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* In this respect, it works in a similar way as spi_flash_mmap() but it allows mapping
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* a (maybe non-contiguous) set of pages into a contiguous region of memory.
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*
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* @param pages An array of numbers indicating the 64kB pages in flash to be mapped
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* contiguously into memory. These indicate the indexes of the 64kB pages,
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* not the byte-size addresses as used in other functions.
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* Array must be located in internal memory.
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* @param page_count Number of entries in the pages array
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* @param memory Address space where the region should be mapped (instruction or data)
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* @param[out] out_ptr Output, pointer to the mapped memory region
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* @param[out] out_handle Output, handle which should be used for spi_flash_munmap call
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*
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* @return
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* - ESP_OK on success
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* - ESP_ERR_NO_MEM if pages can not be allocated
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* - ESP_ERR_INVALID_ARG if pagecount is zero or pages array is not in
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* internal memory
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*/
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esp_err_t spi_flash_mmap_pages(const int *pages, size_t page_count, spi_flash_mmap_memory_t memory,
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const void** out_ptr, spi_flash_mmap_handle_t* out_handle);
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/**
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* @brief Release region previously obtained using spi_flash_mmap
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*
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* @note Calling this function will not necessarily unmap memory region.
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* Region will only be unmapped when there are no other handles which
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* reference this region. In case of partially overlapping regions
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* it is possible that memory will be unmapped partially.
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*
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* @param handle Handle obtained from spi_flash_mmap
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*/
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void spi_flash_munmap(spi_flash_mmap_handle_t handle);
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/**
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* @brief Display information about mapped regions
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*
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* This function lists handles obtained using spi_flash_mmap, along with range
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* of pages allocated to each handle. It also lists all non-zero entries of
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* MMU table and corresponding reference counts.
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*/
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void spi_flash_mmap_dump();
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/**
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* @brief get free pages number which can be mmap
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*
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* This function will return number of free pages available in mmu table. This could be useful
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* before calling actual spi_flash_mmap (maps flash range to DCache or ICache memory) to check
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* if there is sufficient space available for mapping.
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*
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* @param memory memory type of MMU table free page
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*
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* @return number of free pages which can be mmaped
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*/
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uint32_t spi_flash_mmap_get_free_pages(spi_flash_mmap_memory_t memory);
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#define SPI_FLASH_CACHE2PHYS_FAIL UINT32_MAX /*<! Result from spi_flash_cache2phys() if flash cache address is invalid */
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/**
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* @brief Given a memory address where flash is mapped, return the corresponding physical flash offset.
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*
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* Cache address does not have have been assigned via spi_flash_mmap(), any address in memory mapped flash space can be looked up.
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*
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* @param cached Pointer to flashed cached memory.
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*
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* @return
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* - SPI_FLASH_CACHE2PHYS_FAIL If cache address is outside flash cache region, or the address is not mapped.
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* - Otherwise, returns physical offset in flash
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*/
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size_t spi_flash_cache2phys(const void *cached);
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/** @brief Given a physical offset in flash, return the address where it is mapped in the memory space.
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*
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* Physical address does not have to have been assigned via spi_flash_mmap(), any address in flash can be looked up.
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*
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* @note Only the first matching cache address is returned. If MMU flash cache table is configured so multiple entries
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* point to the same physical address, there may be more than one cache address corresponding to that physical
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* address. It is also possible for a single physical address to be mapped to both the IROM and DROM regions.
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*
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* @note This function doesn't impose any alignment constraints, but if memory argument is SPI_FLASH_MMAP_INST and
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* phys_offs is not 4-byte aligned, then reading from the returned pointer will result in a crash.
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*
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* @param phys_offs Physical offset in flash memory to look up.
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* @param memory Address space type to look up a flash cache address mapping for (instruction or data)
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*
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* @return
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* - NULL if the physical address is invalid or not mapped to flash cache of the specified memory type.
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* - Cached memory address (in IROM or DROM space) corresponding to phys_offs.
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*/
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const void *spi_flash_phys2cache(size_t phys_offs, spi_flash_mmap_memory_t memory);
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/** @brief Check at runtime if flash cache is enabled on both CPUs
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*
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* @return true if both CPUs have flash cache enabled, false otherwise.
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*/
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bool spi_flash_cache_enabled();
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/**
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* @brief SPI flash critical section enter function.
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*
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*/
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typedef void (*spi_flash_guard_start_func_t)(void);
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/**
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* @brief SPI flash critical section exit function.
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*/
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typedef void (*spi_flash_guard_end_func_t)(void);
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/**
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* @brief SPI flash operation lock function.
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*/
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typedef void (*spi_flash_op_lock_func_t)(void);
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/**
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* @brief SPI flash operation unlock function.
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*/
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typedef void (*spi_flash_op_unlock_func_t)(void);
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/**
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* Structure holding SPI flash access critical sections management functions.
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*
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* Flash API uses two types of flash access management functions:
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* 1) Functions which prepare/restore flash cache and interrupts before calling
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* appropriate ROM functions (SPIWrite, SPIRead and SPIEraseBlock):
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* - 'start' function should disables flash cache and non-IRAM interrupts and
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* is invoked before the call to one of ROM function above.
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* - 'end' function should restore state of flash cache and non-IRAM interrupts and
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* is invoked after the call to one of ROM function above.
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* These two functions are not recursive.
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* 2) Functions which synchronizes access to internal data used by flash API.
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* This functions are mostly intended to synchronize access to flash API internal data
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* in multithreaded environment and use OS primitives:
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* - 'op_lock' locks access to flash API internal data.
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* - 'op_unlock' unlocks access to flash API internal data.
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* These two functions are recursive and can be used around the outside of multiple calls to
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* 'start' & 'end', in order to create atomic multi-part flash operations.
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*
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* Different versions of the guarding functions should be used depending on the context of
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* execution (with or without functional OS). In normal conditions when flash API is called
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* from task the functions use OS primitives. When there is no OS at all or when
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* it is not guaranteed that OS is functional (accessing flash from exception handler) these
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* functions cannot use OS primitives or even does not need them (multithreaded access is not possible).
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*
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* @note Structure and corresponding guard functions should not reside in flash.
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* For example structure can be placed in DRAM and functions in IRAM sections.
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*/
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typedef struct {
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spi_flash_guard_start_func_t start; /**< critical section start function. */
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spi_flash_guard_end_func_t end; /**< critical section end function. */
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spi_flash_op_lock_func_t op_lock; /**< flash access API lock function.*/
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spi_flash_op_unlock_func_t op_unlock; /**< flash access API unlock function.*/
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} spi_flash_guard_funcs_t;
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/**
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* @brief Sets guard functions to access flash.
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*
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* @note Pointed structure and corresponding guard functions should not reside in flash.
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* For example structure can be placed in DRAM and functions in IRAM sections.
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*
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* @param funcs pointer to structure holding flash access guard functions.
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*/
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void spi_flash_guard_set(const spi_flash_guard_funcs_t* funcs);
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/**
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* @brief Get the guard functions used for flash access
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*
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* @return The guard functions that were set via spi_flash_guard_set(). These functions
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* can be called if implementing custom low-level SPI flash operations.
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*/
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const spi_flash_guard_funcs_t *spi_flash_guard_get();
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/**
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* @brief Default OS-aware flash access guard functions
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*/
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extern const spi_flash_guard_funcs_t g_flash_guard_default_ops;
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/**
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* @brief Non-OS flash access guard functions
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*
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* @note This version of flash guard functions is to be used when no OS is present or from panic handler.
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* It does not use any OS primitives and IPC and implies that only calling CPU is active.
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*/
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extern const spi_flash_guard_funcs_t g_flash_guard_no_os_ops;
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#if CONFIG_SPI_FLASH_ENABLE_COUNTERS
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/**
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* Structure holding statistics for one type of operation
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*/
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typedef struct {
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uint32_t count; // number of times operation was executed
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uint32_t time; // total time taken, in microseconds
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uint32_t bytes; // total number of bytes
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} spi_flash_counter_t;
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typedef struct {
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spi_flash_counter_t read;
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spi_flash_counter_t write;
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spi_flash_counter_t erase;
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} spi_flash_counters_t;
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/**
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* @brief Reset SPI flash operation counters
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*/
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void spi_flash_reset_counters();
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/**
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* @brief Print SPI flash operation counters
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*/
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void spi_flash_dump_counters();
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/**
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* @brief Return current SPI flash operation counters
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*
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* @return pointer to the spi_flash_counters_t structure holding values
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* of the operation counters
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*/
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const spi_flash_counters_t* spi_flash_get_counters();
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#endif //CONFIG_SPI_FLASH_ENABLE_COUNTERS
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#ifdef __cplusplus
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}
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#endif
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#endif /* ESP_SPI_FLASH_H */
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