src/rp2_common/hardware_flash/include/hardware/flash.h - third_party/github/raspberrypi/pico-sdk - Git at Google

 /*
  * Copyright (c) 2020 Raspberry Pi (Trading) Ltd.
  *
  * SPDX-License-Identifier: BSD-3-Clause
  */

 #ifndef _HARDWARE_FLASH_H
 #define _HARDWARE_FLASH_H

 #include "pico.h"

 /** \file flash.h
  *  \defgroup hardware_flash hardware_flash
  *
  * Low level flash programming and erase API
  *
  * Note these functions are *unsafe* if you are using both cores, and the other
  * is executing from flash concurrently with the operation. In this could be the
  * case, you must perform your own synchronisation to make sure that no XIP
  * accesses take place during flash programming. One option is to use the
  * \ref multicore_lockout functions.
  *
  * Likewise they are *unsafe* if you have interrupt handlers or an interrupt
  * vector table in flash, so you must disable interrupts before calling in
  * this case.
  *
  * If PICO_NO_FLASH=1 is not defined (i.e. if the program is built to run from
  * flash) then these functions will make a static copy of the second stage
  * bootloader in SRAM, and use this to reenter execute-in-place mode after
  * programming or erasing flash, so that they can safely be called from
  * flash-resident code.
  *
  * \subsection flash_example Example
  * \include flash_program.c
  */

 // PICO_CONFIG: PARAM_ASSERTIONS_ENABLED_FLASH, Enable/disable assertions in the flash module, type=bool, default=0, group=hardware_flash
 #ifndef PARAM_ASSERTIONS_ENABLED_FLASH
 #define PARAM_ASSERTIONS_ENABLED_FLASH 0
 #endif

 #define FLASH_PAGE_SIZE (1u << 8)
 #define FLASH_SECTOR_SIZE (1u << 12)
 #define FLASH_BLOCK_SIZE (1u << 16)

 #define FLASH_UNIQUE_ID_SIZE_BYTES 8

 // PICO_CONFIG: PICO_FLASH_SIZE_BYTES, size of primary flash in bytes, type=int, group=hardware_flash

 #ifdef __cplusplus
 extern "C" {
 #endif

 /*! \brief  Erase areas of flash
  *  \ingroup hardware_flash
  *
  * \param flash_offs Offset into flash, in bytes, to start the erase. Must be aligned to a 4096-byte flash sector.
  * \param count Number of bytes to be erased. Must be a multiple of 4096 bytes (one sector).
  */
 void flash_range_erase(uint32_t flash_offs, size_t count);

 /*! \brief  Program flash
  *  \ingroup hardware_flash
  *
  * \param flash_offs Flash address of the first byte to be programmed. Must be aligned to a 256-byte flash page.
  * \param data Pointer to the data to program into flash
  * \param count Number of bytes to program. Must be a multiple of 256 bytes (one page).
  */

 void flash_range_program(uint32_t flash_offs, const uint8_t *data, size_t count);

 /*! \brief Get flash unique 64 bit identifier
  *  \ingroup hardware_flash
  *
  * Use a standard 4Bh RUID instruction to retrieve the 64 bit unique
  * identifier from a flash device attached to the QSPI interface. Since there
  * is a 1:1 association between the MCU and this flash, this also serves as a
  * unique identifier for the board.
  *
  *  \param id_out Pointer to an 8-byte buffer to which the ID will be written
  */
 void flash_get_unique_id(uint8_t *id_out);

 /*! \brief Execute bidirectional flash command
  *  \ingroup hardware_flash
  *
  * Low-level function to execute a serial command on a flash device attached
  * to the QSPI interface. Bytes are simultaneously transmitted and received
  * from txbuf and to rxbuf. Therefore, both buffers must be the same length,
  * count, which is the length of the overall transaction. This is useful for
  * reading metadata from the flash chip, such as device ID or SFDP
  * parameters.
  *
  * The XIP cache is flushed following each command, in case flash state
  * has been modified. Like other hardware_flash functions, the flash is not
  * accessible for execute-in-place transfers whilst the command is in
  * progress, so entering a flash-resident interrupt handler or executing flash
  * code on the second core concurrently will be fatal. To avoid these pitfalls
  * it is recommended that this function only be used to extract flash metadata
  * during startup, before the main application begins to run: see the
  * implementation of pico_get_unique_id() for an example of this.
  *
  *  \param txbuf Pointer to a byte buffer which will be transmitted to the flash
  *  \param rxbuf Pointer to a byte buffer where data received from the flash will be written. txbuf and rxbuf may be the same buffer.
  *  \param count Length in bytes of txbuf and of rxbuf
  */
 void flash_do_cmd(const uint8_t *txbuf, uint8_t *rxbuf, size_t count);


 #ifdef __cplusplus
 }
 #endif

 #endif
	/*
	* Copyright (c) 2020 Raspberry Pi (Trading) Ltd.
	*
	* SPDX-License-Identifier: BSD-3-Clause
	*/

	#ifndef _HARDWARE_FLASH_H
	#define _HARDWARE_FLASH_H

	#include "pico.h"

	/** \file flash.h
	* \defgroup hardware_flash hardware_flash
	*
	* Low level flash programming and erase API
	*
	* Note these functions are unsafe if you are using both cores, and the other
	* is executing from flash concurrently with the operation. In this could be the
	* case, you must perform your own synchronisation to make sure that no XIP
	* accesses take place during flash programming. One option is to use the
	* \ref multicore_lockout functions.
	*
	* Likewise they are unsafe if you have interrupt handlers or an interrupt
	* vector table in flash, so you must disable interrupts before calling in
	* this case.
	*
	* If PICO_NO_FLASH=1 is not defined (i.e. if the program is built to run from
	* flash) then these functions will make a static copy of the second stage
	* bootloader in SRAM, and use this to reenter execute-in-place mode after
	* programming or erasing flash, so that they can safely be called from
	* flash-resident code.
	*
	* \subsection flash_example Example
	* \include flash_program.c
	*/

	// PICO_CONFIG: PARAM_ASSERTIONS_ENABLED_FLASH, Enable/disable assertions in the flash module, type=bool, default=0, group=hardware_flash
	#ifndef PARAM_ASSERTIONS_ENABLED_FLASH
	#define PARAM_ASSERTIONS_ENABLED_FLASH 0
	#endif

	#define FLASH_PAGE_SIZE (1u << 8)
	#define FLASH_SECTOR_SIZE (1u << 12)
	#define FLASH_BLOCK_SIZE (1u << 16)

	#define FLASH_UNIQUE_ID_SIZE_BYTES 8

	// PICO_CONFIG: PICO_FLASH_SIZE_BYTES, size of primary flash in bytes, type=int, group=hardware_flash

	#ifdef __cplusplus
	extern "C" {
	#endif

	/*! \brief Erase areas of flash
	* \ingroup hardware_flash
	*
	* \param flash_offs Offset into flash, in bytes, to start the erase. Must be aligned to a 4096-byte flash sector.
	* \param count Number of bytes to be erased. Must be a multiple of 4096 bytes (one sector).
	*/
	void flash_range_erase(uint32_t flash_offs, size_t count);

	/*! \brief Program flash
	* \ingroup hardware_flash
	*
	* \param flash_offs Flash address of the first byte to be programmed. Must be aligned to a 256-byte flash page.
	* \param data Pointer to the data to program into flash
	* \param count Number of bytes to program. Must be a multiple of 256 bytes (one page).
	*/

	void flash_range_program(uint32_t flash_offs, const uint8_t *data, size_t count);

	/*! \brief Get flash unique 64 bit identifier
	* \ingroup hardware_flash
	*
	* Use a standard 4Bh RUID instruction to retrieve the 64 bit unique
	* identifier from a flash device attached to the QSPI interface. Since there
	* is a 1:1 association between the MCU and this flash, this also serves as a
	* unique identifier for the board.
	*
	* \param id_out Pointer to an 8-byte buffer to which the ID will be written
	*/
	void flash_get_unique_id(uint8_t *id_out);

	/*! \brief Execute bidirectional flash command
	* \ingroup hardware_flash
	*
	* Low-level function to execute a serial command on a flash device attached
	* to the QSPI interface. Bytes are simultaneously transmitted and received
	* from txbuf and to rxbuf. Therefore, both buffers must be the same length,
	* count, which is the length of the overall transaction. This is useful for
	* reading metadata from the flash chip, such as device ID or SFDP
	* parameters.
	*
	* The XIP cache is flushed following each command, in case flash state
	* has been modified. Like other hardware_flash functions, the flash is not
	* accessible for execute-in-place transfers whilst the command is in
	* progress, so entering a flash-resident interrupt handler or executing flash
	* code on the second core concurrently will be fatal. To avoid these pitfalls
	* it is recommended that this function only be used to extract flash metadata
	* during startup, before the main application begins to run: see the
	* implementation of pico_get_unique_id() for an example of this.
	*
	* \param txbuf Pointer to a byte buffer which will be transmitted to the flash
	* \param rxbuf Pointer to a byte buffer where data received from the flash will be written. txbuf and rxbuf may be the same buffer.
	* \param count Length in bytes of txbuf and of rxbuf
	*/
	void flash_do_cmd(const uint8_t txbuf, uint8_t rxbuf, size_t count);


	#ifdef __cplusplus
	}
	#endif

	#endif