esp-idf/components/spi_flash/include/spi_flash_chip_driver.h
Michael (XIAO Xufeng) 2b7681ec4f esp_flash: fix set qe bit and write command issues
There used to be dummy phase before out phase in common command
transactions. This corrupts the data.

The code before never actually operate (clear) the QE bit, once it finds
the QE bit is set. It's hard to check whether the QE set/disable
functions work well.

This commit:

1. Cancel the dummy phase

2. Set and clear the QE bit according to chip settings, allowing tests
   for QE bits. However for some chips (Winbond for example), it's not
   forced to clear the QE bit if not able to.

3. Also refactor to allow chip_generic and other chips to share the same
   code to read and write qe bit; let common command and read command share
   configure_host_io_mode.

4. Rename read mode to io mode since maybe we will write data with quad
   mode one day.
2019-11-21 12:26:14 +08:00

169 lines
7.6 KiB
C

// Copyright 2015-2019 Espressif Systems (Shanghai) PTE LTD
//
// Licensed under the Apache License, Version 2.0 (the "License");
// you may not use this file except in compliance with the License.
// You may obtain a copy of the License at
//
// http://www.apache.org/licenses/LICENSE-2.0
//
// Unless required by applicable law or agreed to in writing, software
// distributed under the License is distributed on an "AS IS" BASIS,
// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
// See the License for the specific language governing permissions and
// limitations under the License.
#pragma once
#include "esp_flash.h"
struct esp_flash_t;
typedef struct esp_flash_t esp_flash_t;
typedef struct spi_flash_chip_t spi_flash_chip_t;
/** @brief SPI flash chip driver definition structure.
*
* The chip driver structure contains chip-specific pointers to functions to perform SPI flash operations, and some
* chip-specific numeric values.
*
* @note This is not a public API. These functions are called from the public API (declared in
* esp_flash.h). They assume the caller has already validated arguments and enabled relevant protections
* (disabling flash cache, prevent concurrent SPI access, etc.)
*
* Do not call chip driver functions directly in other contexts.
*
* A generic driver for generic chips and its related operations are defined in
* spi_flash_chip_generic.h which can be used as building blocks for written
* new/specific SPI flash chip drivers.
*
* @note All of these functions may be called with SPI flash cache disabled, so must only ever access IRAM/DRAM/ROM.
*/
struct spi_flash_chip_t {
const char *name; ///< Name of the chip driver
/* Probe to detect if a supported SPI flash chip is found.
*
* Attempts to configure 'chip' with these operations and probes for a matching SPI flash chip.
*
* Auto-detection of a SPI flash chip calls this function in turn on each registered driver (see esp_flash_registered_flash_drivers).
*
* ID - as read by spi_flash_generic_read_id() - is supplied so each probe
* function doesn't need to unnecessarily read ID, but probe is permitted
* to interrogate flash in any non-destructive way.
*
* It is permissible for the driver to modify the 'chip' structure if probing succeeds (specifically, to assign something to the
* driver_data pointer if that is useful for the driver.)
*
* @return ESP_OK if probing was successful, an error otherwise. Driver may
* assume that returning ESP_OK means it has claimed this chip.
*/
esp_err_t (*probe)(esp_flash_t *chip, uint32_t flash_id);
esp_err_t (*reset)(esp_flash_t *chip);
/* Detect SPI flash size
*
* Interrogate the chip to detect its size.
*/
esp_err_t (*detect_size)(esp_flash_t *chip, uint32_t *size);
/* Erase the entire chip
Caller has verified the chip is not write protected.
*/
esp_err_t (*erase_chip)(esp_flash_t *chip);
/* Erase a sector of the chip. Sector size is specified in the 'sector_size' field.
sector_address is an offset in bytes.
Caller has verified that this sector should be non-write-protected.
*/
esp_err_t (*erase_sector)(esp_flash_t *chip, uint32_t sector_address);
/* Erase a multi-sector block of the chip. Block size is specified in the 'block_erase_size' field.
sector_address is an offset in bytes.
Caller has verified that this block should be non-write-protected.
*/
esp_err_t (*erase_block)(esp_flash_t *chip, uint32_t block_address);
uint32_t sector_size; /* Sector is minimum erase size */
uint32_t block_erase_size; /* Optimal (fastest) block size for multi-sector erases on this chip */
/* Read the write protect status of the entire chip. */
esp_err_t (*get_chip_write_protect)(esp_flash_t *chip, bool *out_write_protected);
/* Set the write protect status of the entire chip. */
esp_err_t (*set_chip_write_protect)(esp_flash_t *chip, bool chip_write_protect);
/* Number of individually write protectable regions on this chip. Range 0-63. */
uint8_t num_protectable_regions;
/* Pointer to an array describing each protectable region. Should have num_protectable_regions elements. */
const esp_flash_region_t *protectable_regions;
/* Get a bitmask describing all protectable regions on the chip. Each bit represents one entry in the
protectable_regions array, ie bit (1<<N) is set then the region at array entry N is write protected. */
esp_err_t (*get_protected_regions)(esp_flash_t *chip, uint64_t *regions);
/* Set protectable regions on the chip. Each bit represents on entry in the protectable regions array. */
esp_err_t (*set_protected_regions)(esp_flash_t *chip, uint64_t regions);
/* Read data from the chip.
*
* Before calling this function, the caller will have called chip->drv->set_read_mode(chip) in order to configure the chip's read mode correctly.
*/
esp_err_t (*read)(esp_flash_t *chip, void *buffer, uint32_t address, uint32_t length);
/* Write any amount of data to the chip.
*/
esp_err_t (*write)(esp_flash_t *chip, const void *buffer, uint32_t address, uint32_t length);
/* Use the page program command to write data to the chip.
*
* This function is expected to be called by chip->drv->write (if the
* chip->drv->write implementation doesn't call it then it can be left as NULL.)
*
* - The length argument supplied to this function is at most 'page_size' bytes.
*
* - The region between 'address' and 'address + length' will not cross a page_size aligned boundary (the write
* implementation is expected to split such a write into two before calling page_program.)
*/
esp_err_t (*program_page)(esp_flash_t *chip, const void *buffer, uint32_t address, uint32_t length);
/* Page size as written by the page_program function. Usually 256 bytes. */
uint32_t page_size;
/* Perform an encrypted write to the chip, using internal flash encryption hardware. */
esp_err_t (*write_encrypted)(esp_flash_t *chip, const void *buffer, uint32_t address, uint32_t length);
/* Wait for the SPI flash chip to be idle (any write operation to be complete.) This function is both called from the higher-level API functions, and from other functions in this structure.
timeout_ms should be a timeout (in milliseconds) before the function returns ESP_ERR_TIMEOUT. This is useful to avoid hanging
if the chip is otherwise unresponsive (ie returns all 0xFF or similar.)
*/
esp_err_t (*wait_idle)(esp_flash_t *chip, unsigned timeout_ms);
/* Configure both the SPI host and the chip for the read mode specified in chip->read_mode.
*
* This function is called by the higher-level API before the 'read' function is called.
*
* Can return ESP_ERR_FLASH_UNSUPPORTED_HOST or ESP_ERR_FLASH_UNSUPPORTED_CHIP if the specified mode is unsupported.
*/
esp_err_t (*set_io_mode)(esp_flash_t *chip);
/*
* Get whether the Quad Enable (QE) is set. (*out_io_mode)=SPI_FLASH_QOUT if
* enabled, otherwise disabled
*/
esp_err_t (*get_io_mode)(esp_flash_t *chip, esp_flash_io_mode_t* out_io_mode);
};
/* Pointer to an array of pointers to all known drivers for flash chips. This array is used
by esp_flash_init() to detect the flash chip driver, if none is supplied by the caller.
Array is terminated with a NULL pointer.
This pointer can be overwritten with a pointer to a new array, to update the list of known flash chips.
*/
extern const spi_flash_chip_t **esp_flash_registered_chips;