STM32存储左右互搏 模拟U盘桥接SPI总线FATS读写FLASH W25QXX

news2024/11/30 5:42:19

STM32存储左右互搏 模拟U盘桥接SPI总线FATS读写FLASH W25QXX

STM32的USB接口可以模拟成为U盘,通过FATS文件系统对连接的存储单元进行U盘方式的读写。
这里介绍STM32CUBEIDE开发平台HAL库模拟U盘桥接SPI总线FATS读写W25Q各型号FLASH的例程。
FLASH是常用的一种非易失存储单元,W25QXX系列Flash有不同容量的型号,如W25Q64的容量为64Mbit,也就是8MByte。

W25QXX介绍

W25QXX的SOIC封装如下所示,在采用SPI而不是QUAL SPI时,管脚定义为:
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即由片选(/CS), 时钟(CLK), 数据输出(DO)和数据输入(DI)的组成4线SPI信号接口。VCC和GND提供电源和接地连接。

例程采用STM32H750VBT6芯片, FLASH可以选择为8/16/32/64/128/256/512/1024 Mbit的W25Q型号。例程实现可以通过U盘形式和串口控制双方式对FLASH内的文件进行操作,实现可交换操作的特性。

STM32工程配置

首先建立基本工程并设置时钟:
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对于STM32H7,有专用的内部48MHz时钟用于USB接口, 其它应用采用内部高速时钟接口即可:
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设置UART1作为通讯串口:
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FLASH连接到了SPI2接口,对SPI2进行配置:
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不用中断和DMA模式,SPI2的片选才用软件代码控制,配置一个GPIO作为片选输出:
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配置USB接口
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将USB接口例化为U盘模式:

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对FATS文件系统进行配置
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STM32H7资源多,可以将堆栈开大些:
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保存并生成初始工程代码:
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STM32工程代码

UART串口printf打印输出实现参考:STM32 UART串口printf函数应用及浮点打印代码空间节省 (HAL)

建立W25Q访问的库头文件W25QXX.h:

#ifndef INC_W25QXX_H_
#define INC_W25QXX_H_

#include "main.h"

uint8_t SPI2_ReadWriteByte(uint8_t TxData);

//W25QXX serial chip list:
#define W25Q80_ID 	0XEF13
#define W25Q16_ID 	0XEF14
#define W25Q32_ID 	0XEF15
#define W25Q64_ID 	0XEF16
#define W25Q128_ID	0XEF17
#define W25Q256_ID  0XEF18
#define W25Q512_ID  0XEF19
#define W25Q1024_ID 0XEF20

extern uint16_t W25QXX_TYPE; //To indicate W25QXX type used in this procedure

//W25QXX chip select control function
#define W25QXX_CS(n)  ( n ? HAL_GPIO_WritePin(GPIOB, GPIO_PIN_12, GPIO_PIN_SET) : HAL_GPIO_WritePin(GPIOB, GPIO_PIN_12, GPIO_PIN_RESET) )

//command table for W25QXX access
#define W25X_WriteEnable		0x06
#define W25X_WriteDisable		0x04
#define W25X_ReadStatusReg1		0x05
#define W25X_ReadStatusReg2		0x35
#define W25X_ReadStatusReg3		0x15
#define W25X_WriteStatusReg1    0x01
#define W25X_WriteStatusReg2    0x31
#define W25X_WriteStatusReg3    0x11
#define W25X_ReadData			0x03
#define W25X_FastReadData		0x0B
#define W25X_FastReadDual		0x3B
#define W25X_PageProgram		0x02
#define W25X_BlockErase			0xD8
#define W25X_SectorErase		0x20
#define W25X_ChipErase			0xC7
#define W25X_PowerDown			0xB9
#define W25X_ReleasePowerDown	0xAB
#define W25X_DeviceID			0xAB
#define W25X_ManufactDeviceID	0x90
#define W25X_JedecDeviceID		0x9F
#define W25X_Enable4ByteAddr    0xB7
#define W25X_Exit4ByteAddr      0xE9

uint8_t W25QXX_Init(void);
uint16_t  W25QXX_ReadID(void);  	    		  //Read W25QXX ID
uint8_t W25QXX_ReadSR(uint8_t reg_num);           //Read from status register
void W25QXX_4ByteAddr_Enable(void);               //Enable 4-byte address mode
void W25QXX_Write_SR(uint8_t reg_num,uint8_t d);  //Write to status register
void W25QXX_Write_Enable(void);  		          //Write enable
void W25QXX_Write_Disable(void);		          //Write disable
void W25QXX_Write_NoCheck(uint8_t* pBuffer,uint32_t WriteAddr,uint16_t NumByteToWrite); //Write operation w/o check
void W25QXX_Read(uint8_t* pBuffer,uint32_t ReadAddr,uint16_t NumByteToRead);            //Read operation
void W25QXX_Write(uint8_t* pBuffer,uint32_t WriteAddr,uint16_t NumByteToWrite);         //Write operation
void W25QXX_Erase_Chip(void);    	  	                                                //Erase whole chip
void W25QXX_Erase_Sector(uint32_t Sector_Num);	                                        //Erase sector in specific sector number
void W25QXX_Wait_Busy(void);           	       //Wait idle status before next operation
void W25QXX_PowerDown(void);        	       //Enter power-down mode
void W25QXX_WAKEUP(void);				       //Wake-up


#endif /* INC_W25QXX_H_ */

建立W25Q访问的库源文件W25QXX.c:

#include "W25QXX.h"

extern SPI_HandleTypeDef hspi2;
extern void PY_Delay_us_t(uint32_t Delay);
//Write and read one byte in SPI2
uint8_t SPI2_ReadWriteByte(uint8_t TxData)
{
    uint8_t Rxdata;
    HAL_SPI_TransmitReceive(&hspi2,&TxData,&Rxdata,1, 1000);
 	return Rxdata;
}

uint16_t W25QXX_TYPE=W25Q64_ID;

//W25QXX initialization
uint8_t W25QXX_Init(void)
{
    uint8_t temp;

	W25QXX_CS(1);

	W25QXX_TYPE=W25QXX_ReadID();

	if((W25QXX_TYPE==W25Q256_ID)||(W25QXX_TYPE==W25Q512_ID)||(W25QXX_TYPE==W25Q1024_ID))
    {
        temp=W25QXX_ReadSR(3);              //read status register 3
        if((temp&0X01)==0)			        //judge address mode and configure to 4-byte address mode
		{
			W25QXX_CS(0);
			SPI2_ReadWriteByte(W25X_Enable4ByteAddr);
			W25QXX_CS(1);
		}
    }

    if((W25QXX_TYPE==0x0000)||(W25QXX_TYPE==0xFFFF)) return 0;
    else return 1;
}

//Read status registers of W25QXX
//reg_num: register number from 1 to 3
//return: value of selected register

//SR1 (default 0x00):
//BIT7  6   5   4   3   2   1   0
//SPR   RV  TB BP2 BP1 BP0 WEL BUSY
//SPR: default 0, status register protection bit used with WP
//TB,BP2,BP1,BP0: FLASH region write protection configuration
//WEL: write enable lock
//BUSY: busy flag (1: busy; 0: idle)

//SR2:
//BIT7  6   5   4   3   2   1   0
//SUS   CMP LB3 LB2 LB1 (R) QE  SRP1

//SR3:
//BIT7      6    5    4   3   2   1   0
//HOLD/RST  DRV1 DRV0 (R) (R) WPS ADP ADS
uint8_t W25QXX_ReadSR(uint8_t reg_num)
{
	uint8_t byte=0,command=0;
    switch(reg_num)
    {
        case 1:
            command=W25X_ReadStatusReg1;    //To read status register 1
            break;
        case 2:
            command=W25X_ReadStatusReg2;    //To read status register 2
            break;
        case 3:
            command=W25X_ReadStatusReg3;    //To read status register 3
            break;
        default:
            command=W25X_ReadStatusReg1;
            break;
    }
	W25QXX_CS(0);
	SPI2_ReadWriteByte(command);    //send command
	byte=SPI2_ReadWriteByte(0Xff);  //read data
	W25QXX_CS(1);
	return byte;
}

//Write status registers of W25QXX
//reg_num: register number from 1 to 3
//d: data for updating status register
void W25QXX_Write_SR(uint8_t reg_num,uint8_t d)
{
    uint8_t command=0;
    switch(reg_num)
    {
        case 1:
            command=W25X_WriteStatusReg1;    //To write status register 1
            break;
        case 2:
            command=W25X_WriteStatusReg2;    //To write status register 2
            break;
        case 3:
            command=W25X_WriteStatusReg3;    //To write status register 3
            break;
        default:
            command=W25X_WriteStatusReg1;
            break;
    }
	W25QXX_CS(0);
	SPI2_ReadWriteByte(command);            //send command
	SPI2_ReadWriteByte(d);                  //write data
	W25QXX_CS(1);
}
//W25QXX write enable
void W25QXX_Write_Enable(void)
{
	W25QXX_CS(0);
    SPI2_ReadWriteByte(W25X_WriteEnable);
	W25QXX_CS(1);
}
//W25QXX write disable
void W25QXX_Write_Disable(void)
{
	W25QXX_CS(0);
    SPI2_ReadWriteByte(W25X_WriteDisable);
	W25QXX_CS(1);
}

//Read chip ID
//return:
//0XEF13 for W25Q80
//0XEF14 for W25Q16
//0XEF15 for W25Q32
//0XEF16 for W25Q64
//0XEF17 for W25Q128
//0XEF18 for W25Q256
uint16_t W25QXX_ReadID(void)
{
	uint16_t Temp = 0;
	W25QXX_CS(0);
	SPI2_ReadWriteByte(0x90);          //send command
	SPI2_ReadWriteByte(0x00);
	SPI2_ReadWriteByte(0x00);
	SPI2_ReadWriteByte(0x00);
	Temp|=SPI2_ReadWriteByte(0xFF)<<8; //read high byte data
	Temp|=SPI2_ReadWriteByte(0xFF);    //read low byte data
	W25QXX_CS(1);
	return Temp;
}
//Read W25QXX from specific address for specific byte length
//pBuffer: data buffer
//ReadAddr: specific address
//NumByteToRead: specific byte length (max 65535)
void W25QXX_Read(uint8_t* pBuffer,uint32_t ReadAddr,uint16_t NumByteToRead)
{
 	uint16_t i;
	W25QXX_CS(0);
    SPI2_ReadWriteByte(W25X_ReadData);                   //send read command
    if((W25QXX_TYPE==W25Q256_ID)||(W25QXX_TYPE==W25Q512_ID)||(W25QXX_TYPE==W25Q1024_ID))  //send highest 8-bit address
    {
        SPI2_ReadWriteByte((uint8_t)((ReadAddr)>>24));
    }
    SPI2_ReadWriteByte((uint8_t)((ReadAddr)>>16));       //send 24-bit address
    SPI2_ReadWriteByte((uint8_t)((ReadAddr)>>8));
    SPI2_ReadWriteByte((uint8_t)ReadAddr);
    for(i=0;i<NumByteToRead;i++)
	{
        pBuffer[i]=SPI2_ReadWriteByte(0XFF);             //read data
    }
	W25QXX_CS(1);
}

//Write W25QXX not more than 1 page (256 bytes)
//pBuffer: data buffer
//WriteAddr: specific address
//NumByteToWrite: specific byte length (max 256)
void W25QXX_Write_Page(uint8_t* pBuffer,uint32_t WriteAddr,uint16_t NumByteToWrite)
{
 	uint16_t i;
    W25QXX_Write_Enable();                                       //write enable
	W25QXX_CS(0);
    SPI2_ReadWriteByte(W25X_PageProgram);                        //send write command
    if((W25QXX_TYPE==W25Q256_ID)||(W25QXX_TYPE==W25Q512_ID)||(W25QXX_TYPE==W25Q1024_ID)) //send highest 8-bit address
    {
        SPI2_ReadWriteByte((uint8_t)((WriteAddr)>>24));
    }
    SPI2_ReadWriteByte((uint8_t)((WriteAddr)>>16));               //send 24-bit address
    SPI2_ReadWriteByte((uint8_t)((WriteAddr)>>8));
    SPI2_ReadWriteByte((uint8_t)WriteAddr);
    for(i=0;i<NumByteToWrite;i++)SPI2_ReadWriteByte(pBuffer[i]);  //write data
	W25QXX_CS(1);
	W25QXX_Wait_Busy();
}

//Write W25QXX w/o erase check and w/o byte number restriction
//pBuffer: data buffer
//WriteAddr: specific address
//NumByteToWrite: specific byte length (max 65535)
void W25QXX_Write_NoCheck(uint8_t* pBuffer,uint32_t WriteAddr,uint16_t NumByteToWrite)
{
	uint16_t remained_byte_num_in_page;
	remained_byte_num_in_page=256-WriteAddr%256;                                                       //remained byte number in page
	if( NumByteToWrite <= remained_byte_num_in_page ) remained_byte_num_in_page = NumByteToWrite;      //data can be written in single page
	while(1)
	{
		W25QXX_Write_Page(pBuffer,WriteAddr,remained_byte_num_in_page);
		if(NumByteToWrite==remained_byte_num_in_page)break;                                            //end write operation
	 	else                                                                                           //NumByteToWrite>remained_byte_num_in_page
		{
			pBuffer+=remained_byte_num_in_page;
			WriteAddr+=remained_byte_num_in_page;

			NumByteToWrite-=remained_byte_num_in_page;
			if(NumByteToWrite>256)remained_byte_num_in_page=256;                                       //for whole page write
			else remained_byte_num_in_page=NumByteToWrite; 	                                           //for non-whole page write
		}
	};
}

//Write W25QXX w/ erase after check and w/o byte number restriction
//pBuffer: data buffer
//WriteAddr: specific address
//NumByteToWrite: specific byte length (max 65535)
uint8_t W25QXX_BUFFER[4096];
void W25QXX_Write(uint8_t* pBuffer,uint32_t WriteAddr,uint16_t NumByteToWrite)
{
	uint32_t secpos;
	uint16_t secoff;
	uint16_t secremain;
 	uint16_t i;
	uint8_t * W25QXX_BUF;
   	W25QXX_BUF=W25QXX_BUFFER;
 	secpos=WriteAddr/4096;                                        //sector number (16 pages for 1 sector) for destination address
	secoff=WriteAddr%4096;                                        //offset address in sector for destination address
	secremain=4096-secoff;                                        //remained space for sector
 	if(NumByteToWrite<=secremain)secremain=NumByteToWrite;        //data can be written in single sector
	while(1)
	{
		W25QXX_Read(W25QXX_BUF,secpos*4096,4096);                 //read sector data for ease necessity judgment
		for(i=0;i<secremain;i++)                                  //check sector data status
		{
			if(W25QXX_BUF[secoff+i]!=0XFF) break;                 //ease necessary
		}

		if(i<secremain)                                           //for ease
		{
			W25QXX_Erase_Sector(secpos);                          //ease sector
			for(i=0;i<secremain;i++)	                          //data copy
			{
				W25QXX_BUF[i+secoff]=pBuffer[i];
			}
			W25QXX_Write_NoCheck(W25QXX_BUF,secpos*4096,4096);     //write sector

		}
		else W25QXX_Write_NoCheck(pBuffer,WriteAddr,secremain);   //write data for sector unnecessary to erase

		if(NumByteToWrite==secremain)break;                        //for operation end
		else                                                       //for operation continuing
		{
			secpos++;                                              //sector number + 1
			secoff=0;                                              //offset address from 0

		   	pBuffer+=secremain;                                    //pointer adjustment
			WriteAddr+=secremain;                                  //write address adjustment
		   	NumByteToWrite-=secremain;				               //write number adjustment
			if(NumByteToWrite>4096) secremain=4096;	               //not last sector
			else secremain=NumByteToWrite;			               //last sector
		}
	};
}

//Erase whole chip, long waiting...
void W25QXX_Erase_Chip(void)
{
    W25QXX_Write_Enable();                  //write enable
    W25QXX_Wait_Busy();
  	W25QXX_CS(0);
    SPI2_ReadWriteByte(W25X_ChipErase);     //send erase command
	W25QXX_CS(1);
	W25QXX_Wait_Busy();   				    //wait for erase complete
}

//Erase one sector
//Sector_Num: sector number
void W25QXX_Erase_Sector(uint32_t Sector_Num)
{
 	Sector_Num*=4096;
    W25QXX_Write_Enable();                                     //write enable
    W25QXX_Wait_Busy();
  	W25QXX_CS(0);
    SPI2_ReadWriteByte(W25X_SectorErase);                      //send erase command
    if((W25QXX_TYPE==W25Q256_ID)||(W25QXX_TYPE==W25Q512_ID)||(W25QXX_TYPE==W25Q1024_ID)) //send highest 8-bit address
    {
        SPI2_ReadWriteByte((uint8_t)((Sector_Num)>>24));
    }
    SPI2_ReadWriteByte((uint8_t)((Sector_Num)>>16));           //send 24-bit address
    SPI2_ReadWriteByte((uint8_t)((Sector_Num)>>8));
    SPI2_ReadWriteByte((uint8_t)Sector_Num);
	W25QXX_CS(1);
    W25QXX_Wait_Busy();   				                       //wait for erase complete
}

//Wait idle status before next operation
void W25QXX_Wait_Busy(void)
{
	while((W25QXX_ReadSR(1)&0x01)==0x01);    //wait for busy flag cleared
}

//Enter power-down mode
#define tDP_us 3
void W25QXX_PowerDown(void)
{
  	W25QXX_CS(0);
    SPI2_ReadWriteByte(W25X_PowerDown);      //send power-down command
	W25QXX_CS(1);
	PY_Delay_us_t(tDP_us);                   //tDP
}
//Wake-up
#define tRES1_us 3
void W25QXX_WAKEUP(void)
{
  	W25QXX_CS(0);
    SPI2_ReadWriteByte(W25X_ReleasePowerDown);//send release power-down command
	W25QXX_CS(1);
	PY_Delay_us_t(tRES1_us);                  //tRES1
}

对ffconf.h添加包含信息:
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#include "main.h"
#include "stm32h7xx_hal.h"

修改user_diskio.c,对文件操作函数与底层FLASH读写提供连接:

/* USER CODE BEGIN Header */
/**
 ******************************************************************************
  * @file    user_diskio.c
  * @brief   This file includes a diskio driver skeleton to be completed by the user.
  ******************************************************************************
  * @attention
  *
  * Copyright (c) 2023 STMicroelectronics.
  * All rights reserved.
  *
  * This software is licensed under terms that can be found in the LICENSE file
  * in the root directory of this software component.
  * If no LICENSE file comes with this software, it is provided AS-IS.
  *
  ******************************************************************************
  */
 /* USER CODE END Header */

#ifdef USE_OBSOLETE_USER_CODE_SECTION_0
/*
 * Warning: the user section 0 is no more in use (starting from CubeMx version 4.16.0)
 * To be suppressed in the future.
 * Kept to ensure backward compatibility with previous CubeMx versions when
 * migrating projects.
 * User code previously added there should be copied in the new user sections before
 * the section contents can be deleted.
 */
/* USER CODE BEGIN 0 */
/* USER CODE END 0 */
#endif

/* USER CODE BEGIN DECL */
/**************************SELF DEFINITION PART************/
#include "diskio.h"		/* Declarations of disk functions */
#include "W25QXX.h"
/**********************************************************/
/* Includes ------------------------------------------------------------------*/
#include <string.h>
#include "ff_gen_drv.h"

/* Private typedef -----------------------------------------------------------*/
/* Private define ------------------------------------------------------------*/

/* Private variables ---------------------------------------------------------*/
/* Disk status */
static volatile DSTATUS Stat = STA_NOINIT;

/* USER CODE END DECL */

/* Private function prototypes -----------------------------------------------*/
DSTATUS USER_initialize (BYTE pdrv);
DSTATUS USER_status (BYTE pdrv);
DRESULT USER_read (BYTE pdrv, BYTE *buff, DWORD sector, UINT count);
#if _USE_WRITE == 1
  DRESULT USER_write (BYTE pdrv, const BYTE *buff, DWORD sector, UINT count);
#endif /* _USE_WRITE == 1 */
#if _USE_IOCTL == 1
  DRESULT USER_ioctl (BYTE pdrv, BYTE cmd, void *buff);
#endif /* _USE_IOCTL == 1 */

Diskio_drvTypeDef  USER_Driver =
{
  USER_initialize,
  USER_status,
  USER_read,
#if  _USE_WRITE
  USER_write,
#endif  /* _USE_WRITE == 1 */
#if  _USE_IOCTL == 1
  USER_ioctl,
#endif /* _USE_IOCTL == 1 */
};

/* Private functions ---------------------------------------------------------*/

/**
  * @brief  Initializes a Drive
  * @param  pdrv: Physical drive number (0..)
  * @retval DSTATUS: Operation status
  */
DSTATUS USER_initialize (
	BYTE pdrv           /* Physical drive nmuber to identify the drive */
)
{
  /* USER CODE BEGIN INIT */
	/**************************SELF DEFINITION PART************/
		  uint8_t res;
		  res = W25QXX_Init();

		  if(res) return RES_OK;
		  else return  STA_NOINIT;
	/**********************************************************/
	/*
    Stat = STA_NOINIT;
    return Stat;
    */
  /* USER CODE END INIT */
}

/**
  * @brief  Gets Disk Status
  * @param  pdrv: Physical drive number (0..)
  * @retval DSTATUS: Operation status
  */
DSTATUS USER_status (
	BYTE pdrv       /* Physical drive number to identify the drive */
)
{
  /* USER CODE BEGIN STATUS */
	/**************************SELF DEFINITION PART************/
		switch (pdrv)
			{
				case 0 :
					return RES_OK;
				case 1 :
					return RES_OK;
				case 2 :
					return RES_OK;
				default:
					return STA_NOINIT;
			}
	/**********************************************************/
	/*
    Stat = STA_NOINIT;
    return Stat;
    */
  /* USER CODE END STATUS */
}

/**
  * @brief  Reads Sector(s)
  * @param  pdrv: Physical drive number (0..)
  * @param  *buff: Data buffer to store read data
  * @param  sector: Sector address (LBA)
  * @param  count: Number of sectors to read (1..128)
  * @retval DRESULT: Operation result
  */
DRESULT USER_read (
	BYTE pdrv,      /* Physical drive nmuber to identify the drive */
	BYTE *buff,     /* Data buffer to store read data */
	DWORD sector,   /* Sector address in LBA */
	UINT count      /* Number of sectors to read */
)
{
  /* USER CODE BEGIN READ */
	/**************************SELF DEFINITION PART************/
		    uint16_t len;
			if( !count )
			{
				return RES_PARERR;  /* count不能等于0,否则返回参数错误 */
			}
			switch (pdrv)
			{
				case 0:
					sector <<= 9; //Convert sector number to byte address
				    len = count*512;
				    W25QXX_Read(buff, sector, len);
				    return RES_OK;
				default:
					return RES_ERROR;
			}
	/**********************************************************/
	/*
    return RES_OK;
    */
  /* USER CODE END READ */
}

/**
  * @brief  Writes Sector(s)
  * @param  pdrv: Physical drive number (0..)
  * @param  *buff: Data to be written
  * @param  sector: Sector address (LBA)
  * @param  count: Number of sectors to write (1..128)
  * @retval DRESULT: Operation result
  */
#if _USE_WRITE == 1
DRESULT USER_write (
	BYTE pdrv,          /* Physical drive nmuber to identify the drive */
	const BYTE *buff,   /* Data to be written */
	DWORD sector,       /* Sector address in LBA */
	UINT count          /* Number of sectors to write */
)
{
  /* USER CODE BEGIN WRITE */
  /* USER CODE HERE */
	/**************************SELF DEFINITION PART************/
		    uint16_t len;
			if( !count )
			{
				return RES_PARERR;  /* count不能等于0,否则返回参数错误 */
			}
			switch (pdrv)
			{
				case 0:
					sector <<= 9; //Convert sector number to byte address
				    len = count*512;
				    W25QXX_Write((uint8_t *)buff, sector, len);
				    return RES_OK;
				default:
					return RES_ERROR;
			}
	/*********************************************************/
	/*
    return RES_OK;
    */
  /* USER CODE END WRITE */
}
#endif /* _USE_WRITE == 1 */

/**
  * @brief  I/O control operation
  * @param  pdrv: Physical drive number (0..)
  * @param  cmd: Control code
  * @param  *buff: Buffer to send/receive control data
  * @retval DRESULT: Operation result
  */
#if _USE_IOCTL == 1
DRESULT USER_ioctl (
	BYTE pdrv,      /* Physical drive nmuber (0..) */
	BYTE cmd,       /* Control code */
	void *buff      /* Buffer to send/receive control data */
)
{
  /* USER CODE BEGIN IOCTL */
	/**************************SELF DEFINITION PART************/
             #define user_sector_byte_size 512
		     DRESULT res;
			 switch(cmd)
			    {
				    case CTRL_SYNC:
								W25QXX_Wait_Busy();
								res=RES_OK;
				        break;
				    case GET_SECTOR_SIZE:
				        *(WORD*)buff = user_sector_byte_size;
				        res = RES_OK;
				        break;
				    case GET_BLOCK_SIZE:
				        *(WORD*)buff = 4096/user_sector_byte_size;
				        res = RES_OK;
				        break;
				    case GET_SECTOR_COUNT:
				    	W25QXX_TYPE=W25QXX_ReadID();
				    	if(W25QXX_TYPE==W25Q80_ID) *(DWORD*)buff = (8*1024*1024/512);
				    	else if(W25QXX_TYPE==W25Q16_ID) *(DWORD*)buff = (16*1024*1024/512);
				    	else if(W25QXX_TYPE==W25Q32_ID) *(DWORD*)buff = (32*1024*1024/512);
				    	else if(W25QXX_TYPE==W25Q64_ID) *(DWORD*)buff = (64*1024*1024/512);
				    	else if(W25QXX_TYPE==W25Q128_ID) *(DWORD*)buff = (128*1024*1024/512);
				    	else if(W25QXX_TYPE==W25Q256_ID) *(DWORD*)buff = (256*1024*1024/512);
				    	else if(W25QXX_TYPE==W25Q512_ID) *(DWORD*)buff = (512*1024*1024/512);
				    	else if(W25QXX_TYPE==W25Q1024_ID) *(DWORD*)buff = (1024*1024*1024/512);
				    	else *(DWORD*)buff = (8*1024*1024/512);
				        res = RES_OK;
				        break;
				    default:
				        res = RES_PARERR;
				        break;
			    }
				return res;
	/**********************************************************/
	/*
    DRESULT res = RES_ERROR;
    return res;
    */
  /* USER CODE END IOCTL */
}
#endif /* _USE_IOCTL == 1 */


上面配置的FATS协议是用户可操作的显式协议,譬如本例程通过串口发送指令后控制对FLASH的FATS操作。STM32的U盘接口相当于包含对PC端的握手协议和对内部的隐式FATS协议,还需要配置底层对针对的存储单元读写操作函数。
配置U盘接口包含如下部分:
引入头文件申明
在这里插入图片描述
设置U盘识别的大小参数:
在这里插入图片描述
这里0x4000对应16K,0x200对应512(字节), 16K*512=8M, 所以U盘会识别为8MB的U盘。

然后是U盘初始化的设置
在这里插入图片描述
U盘识别时获取U盘容量的函数
在这里插入图片描述
然后再配置读操作和写操作函数
在这里插入图片描述
完整的代码如下:

/* USER CODE BEGIN Header */
/**
  ******************************************************************************
  * @file           : usbd_storage_if.c
  * @version        : v1.0_Cube
  * @brief          : Memory management layer.
  ******************************************************************************
  * @attention
  *
  * Copyright (c) 2023 STMicroelectronics.
  * All rights reserved.
  *
  * This software is licensed under terms that can be found in the LICENSE file
  * in the root directory of this software component.
  * If no LICENSE file comes with this software, it is provided AS-IS.
  *
  ******************************************************************************
  */
/* USER CODE END Header */

/* Includes ------------------------------------------------------------------*/
#include "usbd_storage_if.h"

/* USER CODE BEGIN INCLUDE */
#include "W25QXX.h"
/* USER CODE END INCLUDE */

/* Private typedef -----------------------------------------------------------*/
/* Private define ------------------------------------------------------------*/
/* Private macro -------------------------------------------------------------*/

/* USER CODE BEGIN PV */
/* Private variables ---------------------------------------------------------*/

/* USER CODE END PV */

/** @addtogroup STM32_USB_OTG_DEVICE_LIBRARY
  * @brief Usb device.
  * @{
  */

/** @defgroup USBD_STORAGE
  * @brief Usb mass storage device module
  * @{
  */

/** @defgroup USBD_STORAGE_Private_TypesDefinitions
  * @brief Private types.
  * @{
  */

/* USER CODE BEGIN PRIVATE_TYPES */
#if 0
/* USER CODE END PRIVATE_TYPES */

/**
  * @}
  */

/** @defgroup USBD_STORAGE_Private_Defines
  * @brief Private defines.
  * @{
  */

#define STORAGE_LUN_NBR                  1
#define STORAGE_BLK_NBR                  0x10000
#define STORAGE_BLK_SIZ                  0x200

/* USER CODE BEGIN PRIVATE_DEFINES */
#endif

#define STORAGE_LUN_NBR                  1         //STORAGE_LUN_NBR : disk number
#define STORAGE_BLK_NBR                  0x4000    //STORAGE_BLK_NBR : block number
#define STORAGE_BLK_SIZ                  0x200     //STORAGE_BLK_SIZ : block size
/* USER CODE END PRIVATE_DEFINES */

/**
  * @}
  */

/** @defgroup USBD_STORAGE_Private_Macros
  * @brief Private macros.
  * @{
  */

/* USER CODE BEGIN PRIVATE_MACRO */

/* USER CODE END PRIVATE_MACRO */

/**
  * @}
  */

/** @defgroup USBD_STORAGE_Private_Variables
  * @brief Private variables.
  * @{
  */

/* USER CODE BEGIN INQUIRY_DATA_FS */
/** USB Mass storage Standard Inquiry Data. */
const int8_t STORAGE_Inquirydata_FS[] = {/* 36 */

  /* LUN 0 */
  0x00,
  0x80,
  0x02,
  0x02,
  (STANDARD_INQUIRY_DATA_LEN - 5),
  0x00,
  0x00,
  0x00,
  'S', 'T', 'M', ' ', ' ', ' ', ' ', ' ', /* Manufacturer : 8 bytes */
  'P', 'r', 'o', 'd', 'u', 'c', 't', ' ', /* Product      : 16 Bytes */
  ' ', ' ', ' ', ' ', ' ', ' ', ' ', ' ',
  '0', '.', '0' ,'1'                      /* Version      : 4 Bytes */
};
/* USER CODE END INQUIRY_DATA_FS */

/* USER CODE BEGIN PRIVATE_VARIABLES */

/* USER CODE END PRIVATE_VARIABLES */

/**
  * @}
  */

/** @defgroup USBD_STORAGE_Exported_Variables
  * @brief Public variables.
  * @{
  */

extern USBD_HandleTypeDef hUsbDeviceFS;

/* USER CODE BEGIN EXPORTED_VARIABLES */

/* USER CODE END EXPORTED_VARIABLES */

/**
  * @}
  */

/** @defgroup USBD_STORAGE_Private_FunctionPrototypes
  * @brief Private functions declaration.
  * @{
  */

static int8_t STORAGE_Init_FS(uint8_t lun);
static int8_t STORAGE_GetCapacity_FS(uint8_t lun, uint32_t *block_num, uint16_t *block_size);
static int8_t STORAGE_IsReady_FS(uint8_t lun);
static int8_t STORAGE_IsWriteProtected_FS(uint8_t lun);
static int8_t STORAGE_Read_FS(uint8_t lun, uint8_t *buf, uint32_t blk_addr, uint16_t blk_len);
static int8_t STORAGE_Write_FS(uint8_t lun, uint8_t *buf, uint32_t blk_addr, uint16_t blk_len);
static int8_t STORAGE_GetMaxLun_FS(void);

/* USER CODE BEGIN PRIVATE_FUNCTIONS_DECLARATION */

/* USER CODE END PRIVATE_FUNCTIONS_DECLARATION */

/**
  * @}
  */

USBD_StorageTypeDef USBD_Storage_Interface_fops_FS =
{
  STORAGE_Init_FS,
  STORAGE_GetCapacity_FS,
  STORAGE_IsReady_FS,
  STORAGE_IsWriteProtected_FS,
  STORAGE_Read_FS,
  STORAGE_Write_FS,
  STORAGE_GetMaxLun_FS,
  (int8_t *)STORAGE_Inquirydata_FS
};

/* Private functions ---------------------------------------------------------*/
/**
  * @brief  Initializes the storage unit (medium) over USB FS IP
  * @param  lun: Logical unit number.
  * @retval USBD_OK if all operations are OK else USBD_FAIL
  */
int8_t STORAGE_Init_FS(uint8_t lun)
{
  /* USER CODE BEGIN 2 */
  //UNUSED(lun);

	W25QXX_Init();

  return (USBD_OK);
  /* USER CODE END 2 */
}

/**
  * @brief  Returns the medium capacity.
  * @param  lun: Logical unit number.
  * @param  block_num: Number of total block number.
  * @param  block_size: Block size.
  * @retval USBD_OK if all operations are OK else USBD_FAIL
  */
int8_t STORAGE_GetCapacity_FS(uint8_t lun, uint32_t *block_num, uint16_t *block_size)
{
  /* USER CODE BEGIN 3 */
  //UNUSED(lun);

  *block_num  = STORAGE_BLK_NBR;
  *block_size = STORAGE_BLK_SIZ;
  return (USBD_OK);
  /* USER CODE END 3 */
}

/**
  * @brief   Checks whether the medium is ready.
  * @param  lun:  Logical unit number.
  * @retval USBD_OK if all operations are OK else USBD_FAIL
  */
int8_t STORAGE_IsReady_FS(uint8_t lun)
{
  /* USER CODE BEGIN 4 */
  //UNUSED(lun);

  return (USBD_OK);
  /* USER CODE END 4 */
}

/**
  * @brief  Checks whether the medium is write protected.
  * @param  lun: Logical unit number.
  * @retval USBD_OK if all operations are OK else USBD_FAIL
  */
int8_t STORAGE_IsWriteProtected_FS(uint8_t lun)
{
  /* USER CODE BEGIN 5 */
  //UNUSED(lun);

  return (USBD_OK);
  /* USER CODE END 5 */
}

/**
  * @brief  Reads data from the medium.
  * @param  lun: Logical unit number.
  * @param  buf: data buffer.
  * @param  blk_addr: Logical block address.
  * @param  blk_len: Blocks number.
  * @retval USBD_OK if all operations are OK else USBD_FAIL
  */
int8_t STORAGE_Read_FS(uint8_t lun, uint8_t *buf, uint32_t blk_addr, uint16_t blk_len)
{
  /* USER CODE BEGIN 6 */
  //UNUSED(lun);
  //UNUSED(buf);
  //UNUSED(blk_addr);
  //UNUSED(blk_len);
  W25QXX_Read(buf, blk_addr*STORAGE_BLK_SIZ, blk_len*STORAGE_BLK_SIZ);

  return (USBD_OK);
  /* USER CODE END 6 */
}

/**
  * @brief  Writes data into the medium.
  * @param  lun: Logical unit number.
  * @param  buf: data buffer.
  * @param  blk_addr: Logical block address.
  * @param  blk_len: Blocks number.
  * @retval USBD_OK if all operations are OK else USBD_FAIL
  */
int8_t STORAGE_Write_FS(uint8_t lun, uint8_t *buf, uint32_t blk_addr, uint16_t blk_len)
{
  /* USER CODE BEGIN 7 */
  //UNUSED(lun);
  //UNUSED(buf);
  //UNUSED(blk_addr);
  //UNUSED(blk_len);
  W25QXX_Write(buf, blk_addr*STORAGE_BLK_SIZ, blk_len*STORAGE_BLK_SIZ);

  return (USBD_OK);
  /* USER CODE END 7 */
}

/**
  * @brief  Returns the Max Supported LUNs.
  * @param  None
  * @retval Lun(s) number.
  */
int8_t STORAGE_GetMaxLun_FS(void)
{
  /* USER CODE BEGIN 8 */
  return (STORAGE_LUN_NBR - 1);
  /* USER CODE END 8 */
}

/* USER CODE BEGIN PRIVATE_FUNCTIONS_IMPLEMENTATION */

/* USER CODE END PRIVATE_FUNCTIONS_IMPLEMENTATION */

/**
  * @}
  */

/**
  * @}
  */


(番外)由上面的设置可以看出设计扩容盘的方式,如把8M的盘扩容成64M,则进行两步操作即可:

  1. 将STORAGE_BLK_NBR放大8倍从而盘容量识别扩大为64M
  2. 在读写函数里,对操作地址进行处理,即把操作地址对8M空间取余,这样刚过8M尾部空间的操作就会跳到头部空间进行,当然如果是写操作就会产生覆盖
    扩容盘是一种循环访问非常规方式,一般在行车记录仪等监控领域出现较多,用户想存储更长时间的数据,但实际上要查数据时都是近期数据,扩容盘能够保持对近期数据的记录,因此不良商家卖出扩容盘非法牟利。扩容盘的缺点是实际容量小于标称容量,要查远期数据是被覆盖丢失的,另一个缺点是如果一个文件正好存储时跨过了实际容量尾部,那么这个文件对PC端时损坏文件不能读取,如果正好这个近期文件是重要取证文件,则是不良事件。

然后在main.c里根据串口输入命令(16进制单字节)实现如下功能:
0x01. 读取FLASH ID
0x02. 装载FATS文件系统
0x03: 创建/打开文件并从头位置写入数据
0x04: 打开文件并从头位置读入数据
0x05: 创建/打开文件并从特定位置写入数据
0x06: 打开文件并从特定位置读入数据
完整的代码实现如下:

/* USER CODE BEGIN Header */
/**
  ******************************************************************************
  * @file           : main.c
  * @brief          : Main program body
  ******************************************************************************
  * @attention
  *
  * Copyright (c) 2023 STMicroelectronics.
  * All rights reserved.
  *
  * This software is licensed under terms that can be found in the LICENSE file
  * in the root directory of this software component.
  * If no LICENSE file comes with this software, it is provided AS-IS.
  *
  ******************************************************************************
  */
//Written by Pegasus Yu in 2023
/* USER CODE END Header */
/* Includes ------------------------------------------------------------------*/
#include "main.h"
#include "fatfs.h"
#include "usb_device.h"

/* Private includes ----------------------------------------------------------*/
/* USER CODE BEGIN Includes */
#include "usart.h"
#include "W25QXX.h"
#include <string.h>
/* USER CODE END Includes */

/* Private typedef -----------------------------------------------------------*/
/* USER CODE BEGIN PTD */
__IO float usDelayBase;
void PY_usDelayTest(void)
{
  __IO uint32_t firstms, secondms;
  __IO uint32_t counter = 0;

  firstms = HAL_GetTick()+1;
  secondms = firstms+1;

  while(uwTick!=firstms) ;

  while(uwTick!=secondms) counter++;

  usDelayBase = ((float)counter)/1000;
}

void PY_Delay_us_t(uint32_t Delay)
{
  __IO uint32_t delayReg;
  __IO uint32_t usNum = (uint32_t)(Delay*usDelayBase);

  delayReg = 0;
  while(delayReg!=usNum) delayReg++;
}

void PY_usDelayOptimize(void)
{
  __IO uint32_t firstms, secondms;
  __IO float coe = 1.0;

  firstms = HAL_GetTick();
  PY_Delay_us_t(1000000) ;
  secondms = HAL_GetTick();

  coe = ((float)1000)/(secondms-firstms);
  usDelayBase = coe*usDelayBase;
}


void PY_Delay_us(uint32_t Delay)
{
  __IO uint32_t delayReg;

  __IO uint32_t msNum = Delay/1000;
  __IO uint32_t usNum = (uint32_t)((Delay%1000)*usDelayBase);

  if(msNum>0) HAL_Delay(msNum);

  delayReg = 0;
  while(delayReg!=usNum) delayReg++;
}
/* USER CODE END PTD */

/* Private define ------------------------------------------------------------*/
/* USER CODE BEGIN PD */
/* USER CODE END PD */

/* Private macro -------------------------------------------------------------*/
/* USER CODE BEGIN PM */

/* USER CODE END PM */

/* Private variables ---------------------------------------------------------*/

SPI_HandleTypeDef hspi2;

UART_HandleTypeDef huart1;

/* USER CODE BEGIN PV */
uint8_t uart1_rx[16];
uint8_t cmd;

uint8_t Flash_mount_status = 0; //FLASH fats mount status indication (0: unmount; 1: mount)
uint8_t FATS_Buff[_MAX_SS]; //Buffer for f_mkfs() operation

FRESULT retFLASH;
FIL file;
FATFS *fs;

UINT bytesread;
UINT byteswritten;
uint8_t rBuffer[20];      //Buffer for read
uint8_t WBuffer[20] ={1,2,3,4,5,6,7,8,9,10,11,12,13,14,15,16,17,18,19,20}; //Buffer for write

#define user_sector_byte_size 512
uint8_t flashbuffer[user_sector_byte_size];

extern char USERPath[4];
/* USER CODE END PV */

/* Private function prototypes -----------------------------------------------*/
void SystemClock_Config(void);
void PeriphCommonClock_Config(void);
static void MX_GPIO_Init(void);
static void MX_USART1_UART_Init(void);
static void MX_SPI2_Init(void);
/* USER CODE BEGIN PFP */

/* USER CODE END PFP */

/* Private user code ---------------------------------------------------------*/
/* USER CODE BEGIN 0 */

/* USER CODE END 0 */

/**
  * @brief  The application entry point.
  * @retval int
  */
int main(void)
{
  /* USER CODE BEGIN 1 */
	Flash_mount_status = 0;
	uint32_t FLASH_Read_Size;

	char * dpath = "0:"; //Disk Path
	for(uint8_t i=0; i<4; i++)
	{
		USERPath[i] = *(dpath+i);
	}

	const TCHAR* filepath = "0:test.txt";
  /* USER CODE END 1 */

  /* MCU Configuration--------------------------------------------------------*/

  /* Reset of all peripherals, Initializes the Flash interface and the Systick. */
  HAL_Init();

  /* USER CODE BEGIN Init */

  /* USER CODE END Init */

  /* Configure the system clock */
  SystemClock_Config();

/* Configure the peripherals common clocks */
  PeriphCommonClock_Config();

  /* USER CODE BEGIN SysInit */

  /* USER CODE END SysInit */

  /* Initialize all configured peripherals */
  MX_GPIO_Init();
  MX_USART1_UART_Init();
  MX_SPI2_Init();
  MX_FATFS_Init();
  MX_USB_DEVICE_Init();
  /* USER CODE BEGIN 2 */
  PY_usDelayTest();
  PY_usDelayOptimize();

  HAL_UART_Receive_IT(&huart1, uart1_rx, 1);

  W25QXX_Init();

  /* USER CODE END 2 */

  /* Infinite loop */
  /* USER CODE BEGIN WHILE */
  while (1)
  {
	     if(cmd==1) //Read ID
	     {
	    	 cmd = 0;
	    	 printf("FLASH ID=0x%x\r\n\r\n", W25QXX_ReadID());
		     printf("W25Q80_ID: 0XEF13\r\n");
		     printf("W25Q16_ID: 0XEF14\r\n");
		     printf("W25Q32_ID: 0XEF15\r\n");
		     printf("W25Q64_ID: 0XEF16\r\n");
		     printf("W25Q128_ID: 0XEF17\r\n");
		     printf("W25Q256_ID: 0XEF18\r\n");
		     printf("W25Q512_ID: 0XEF18\r\n");
		     printf("W25Q1024_ID: 0XEF20\r\n");
	     }
	     else if(cmd==2) //Flash File System Mount
	     {
	    	 cmd = 0;

	    	 retFLASH=f_mount(&USERFatFS, (TCHAR const*)USERPath, 1);
	    	    		 if (retFLASH != FR_OK)
	    	    		 {
	    	    		   printf("File system mount failure: %d\r\n", retFLASH);

	    	    		   if(retFLASH==FR_NO_FILESYSTEM)
	    	    		   {
	    	    			   printf("No file system. Now to format......\r\n");
	    	    			   retFLASH = f_mkfs((TCHAR const*)USERPath, FM_FAT, 1024, FATS_Buff, sizeof(FATS_Buff)); //FLASH formatting
	    	    			   if(retFLASH == FR_OK)
	    	    			   {
	    	                      printf("FLASH formatting success!\r\n");
	    	    			   }
	    	    				else
	    	    			   {
	    	    				  printf("FLASH formatting failure!\r\n");
	    	    			   }

	    	    		   }
	    	    		 }
	    	    		 else
	    	    		 {
	    	    			 Flash_mount_status = 1;
	    	    			 printf("File system mount success\r\n");
	    	    		 }
	     }

		 else if(cmd==3) //File creation and write
		 {
				  cmd = 0;

				  if(Flash_mount_status==0) printf("\r\nFLASH File system not mounted: %d\r\n",retFLASH);
				  else
				  {
						retFLASH = f_open( &file, filepath, FA_CREATE_ALWAYS | FA_WRITE );  //Open or create file
						if(retFLASH == FR_OK)
						{
							printf("\r\nFile open or creation successful\r\n");

							retFLASH = f_write( &file, (const void *)WBuffer, sizeof(WBuffer), &byteswritten); //Write data

							if(retFLASH == FR_OK)
							{
								printf("\r\nFile write successful\r\n");

							}
							else
							{
								printf("\r\nFile write error: %d\r\n",retFLASH);
							}

							f_close(&file);   //Close file
						}
						else
						{
							printf("\r\nFile open or creation error %d\r\n",retFLASH);
						}
				   }

	    }

	    else if(cmd==4) //File read
	    {
				  cmd = 0;

				  if(Flash_mount_status==0) printf("\r\nFLASH File system not mounted: %d\r\n",retFLASH);
				  else
				  {
						retFLASH = f_open( &file, filepath, FA_OPEN_EXISTING | FA_READ); //Open file
						if(retFLASH == FR_OK)
						{
							printf("\r\nFile open successful\r\n");

							retFLASH = f_read( &file, (void *)rBuffer, sizeof(rBuffer), &bytesread); //Read data

							if(retFLASH == FR_OK)
							{
								printf("\r\nFile read successful\r\n");
								PY_Delay_us_t(200000);

								FLASH_Read_Size = sizeof(rBuffer);
								for(uint16_t i = 0;i < FLASH_Read_Size;i++)
								{
									printf("%d ", rBuffer[i]);
								}
								printf("\r\n");

							}
							else
							{
								printf("\r\nFile read error: %d\r\n", retFLASH);
							}
							f_close(&file); //Close file
						}
						else
						{
							printf("\r\nFile open error: %d\r\n", retFLASH);
						}
				  }

		}

		else if(cmd==5) //File locating write
	    {
				  cmd = 0;

				  if(Flash_mount_status==0) printf("\r\nFLASH File system not mounted: %d\r\n",retFLASH);
				  else
				  {
						retFLASH = f_open( &file, filepath, FA_CREATE_ALWAYS | FA_WRITE);  //Open or create file
						if(retFLASH == FR_OK)
						{
							printf("\r\nFile open or creation successful\r\n");

							retFLASH=f_lseek( &file, f_tell(&file) + sizeof(WBuffer) ); //move file operation pointer, f_tell(&file) gets file head locating

							if(retFLASH == FR_OK)
							{

								retFLASH = f_write( &file, (const void *)WBuffer, sizeof(WBuffer), &byteswritten);
								if(retFLASH == FR_OK)
								{
									printf("\r\nFile locating write successful\r\n");
								}
								else
								{
									printf("\r\nFile locating write error: %d\r\n", retFLASH);
								}

							}
							else
							{
								printf("\r\nFile pointer error: %d\r\n",retFLASH);
							}

							f_close(&file);   //Close file
						}
						else
						{
							printf("\r\nFile open or creation error %d\r\n",retFLASH);
						}
				  }
		}

	    else if(cmd==6) //File locating read
		{
				  cmd = 0;

				  if(Flash_mount_status==0) printf("\r\nFLASH File system not mounted: %d\r\n",retFLASH);
				  else
				  {
						retFLASH = f_open(&file, filepath, FA_OPEN_EXISTING | FA_READ); //Open file
						if(retFLASH == FR_OK)
						{
							printf("\r\nFile open successful\r\n");

							retFLASH =  f_lseek(&file,f_tell(&file)+ sizeof(WBuffer)/2); //move file operation pointer, f_tell(&file) gets file head locating

							if(retFLASH == FR_OK)
							{
								retFLASH = f_read( &file, (void *)rBuffer, sizeof(rBuffer), &bytesread);
								if(retFLASH == FR_OK)
								{
									printf("\r\nFile locating read successful\r\n");
									PY_Delay_us_t(200000);

									FLASH_Read_Size = sizeof(rBuffer);
									for(uint16_t i = 0;i < FLASH_Read_Size;i++)
									{
										printf("%d ",rBuffer[i]);
									}
									printf("\r\n");
								}
								else
								{
									printf("\r\nFile locating read error: %d\r\n",retFLASH);
								}
							}
							else
							{
								printf("\r\nFile pointer error: %d\r\n",retFLASH);
							}
							f_close(&file);
						}
						else
						{
							printf("\r\nFile open error: %d\r\n",retFLASH);
						}
				  }
	     }

    /* USER CODE END WHILE */

    /* USER CODE BEGIN 3 */
  }
  /* USER CODE END 3 */
}

/**
  * @brief System Clock Configuration
  * @retval None
  */
void SystemClock_Config(void)
{
  RCC_OscInitTypeDef RCC_OscInitStruct = {0};
  RCC_ClkInitTypeDef RCC_ClkInitStruct = {0};

  /** Supply configuration update enable
  */
  HAL_PWREx_ConfigSupply(PWR_LDO_SUPPLY);

  /** Configure the main internal regulator output voltage
  */
  __HAL_PWR_VOLTAGESCALING_CONFIG(PWR_REGULATOR_VOLTAGE_SCALE1);

  while(!__HAL_PWR_GET_FLAG(PWR_FLAG_VOSRDY)) {}

  __HAL_RCC_SYSCFG_CLK_ENABLE();
  __HAL_PWR_VOLTAGESCALING_CONFIG(PWR_REGULATOR_VOLTAGE_SCALE0);

  while(!__HAL_PWR_GET_FLAG(PWR_FLAG_VOSRDY)) {}

  /** Initializes the RCC Oscillators according to the specified parameters
  * in the RCC_OscInitTypeDef structure.
  */
  RCC_OscInitStruct.OscillatorType = RCC_OSCILLATORTYPE_HSI48|RCC_OSCILLATORTYPE_HSI;
  RCC_OscInitStruct.HSIState = RCC_HSI_DIV1;
  RCC_OscInitStruct.HSICalibrationValue = RCC_HSICALIBRATION_DEFAULT;
  RCC_OscInitStruct.HSI48State = RCC_HSI48_ON;
  RCC_OscInitStruct.PLL.PLLState = RCC_PLL_ON;
  RCC_OscInitStruct.PLL.PLLSource = RCC_PLLSOURCE_HSI;
  RCC_OscInitStruct.PLL.PLLM = 4;
  RCC_OscInitStruct.PLL.PLLN = 60;
  RCC_OscInitStruct.PLL.PLLP = 2;
  RCC_OscInitStruct.PLL.PLLQ = 2;
  RCC_OscInitStruct.PLL.PLLR = 2;
  RCC_OscInitStruct.PLL.PLLRGE = RCC_PLL1VCIRANGE_3;
  RCC_OscInitStruct.PLL.PLLVCOSEL = RCC_PLL1VCOWIDE;
  RCC_OscInitStruct.PLL.PLLFRACN = 0;
  if (HAL_RCC_OscConfig(&RCC_OscInitStruct) != HAL_OK)
  {
    Error_Handler();
  }

  /** Initializes the CPU, AHB and APB buses clocks
  */
  RCC_ClkInitStruct.ClockType = RCC_CLOCKTYPE_HCLK|RCC_CLOCKTYPE_SYSCLK
                              |RCC_CLOCKTYPE_PCLK1|RCC_CLOCKTYPE_PCLK2
                              |RCC_CLOCKTYPE_D3PCLK1|RCC_CLOCKTYPE_D1PCLK1;
  RCC_ClkInitStruct.SYSCLKSource = RCC_SYSCLKSOURCE_PLLCLK;
  RCC_ClkInitStruct.SYSCLKDivider = RCC_SYSCLK_DIV1;
  RCC_ClkInitStruct.AHBCLKDivider = RCC_HCLK_DIV2;
  RCC_ClkInitStruct.APB3CLKDivider = RCC_APB3_DIV2;
  RCC_ClkInitStruct.APB1CLKDivider = RCC_APB1_DIV2;
  RCC_ClkInitStruct.APB2CLKDivider = RCC_APB2_DIV2;
  RCC_ClkInitStruct.APB4CLKDivider = RCC_APB4_DIV2;

  if (HAL_RCC_ClockConfig(&RCC_ClkInitStruct, FLASH_LATENCY_4) != HAL_OK)
  {
    Error_Handler();
  }
}

/**
  * @brief Peripherals Common Clock Configuration
  * @retval None
  */
void PeriphCommonClock_Config(void)
{
  RCC_PeriphCLKInitTypeDef PeriphClkInitStruct = {0};

  /** Initializes the peripherals clock
  */
  PeriphClkInitStruct.PeriphClockSelection = RCC_PERIPHCLK_CKPER;
  PeriphClkInitStruct.CkperClockSelection = RCC_CLKPSOURCE_HSI;
  if (HAL_RCCEx_PeriphCLKConfig(&PeriphClkInitStruct) != HAL_OK)
  {
    Error_Handler();
  }
}

/**
  * @brief SPI2 Initialization Function
  * @param None
  * @retval None
  */
static void MX_SPI2_Init(void)
{

  /* USER CODE BEGIN SPI2_Init 0 */

  /* USER CODE END SPI2_Init 0 */

  /* USER CODE BEGIN SPI2_Init 1 */

  /* USER CODE END SPI2_Init 1 */
  /* SPI2 parameter configuration*/
  hspi2.Instance = SPI2;
  hspi2.Init.Mode = SPI_MODE_MASTER;
  hspi2.Init.Direction = SPI_DIRECTION_2LINES;
  hspi2.Init.DataSize = SPI_DATASIZE_8BIT;
  hspi2.Init.CLKPolarity = SPI_POLARITY_LOW;
  hspi2.Init.CLKPhase = SPI_PHASE_1EDGE;
  hspi2.Init.NSS = SPI_NSS_SOFT;
  hspi2.Init.BaudRatePrescaler = SPI_BAUDRATEPRESCALER_2;
  hspi2.Init.FirstBit = SPI_FIRSTBIT_MSB;
  hspi2.Init.TIMode = SPI_TIMODE_DISABLE;
  hspi2.Init.CRCCalculation = SPI_CRCCALCULATION_DISABLE;
  hspi2.Init.CRCPolynomial = 0x0;
  hspi2.Init.NSSPMode = SPI_NSS_PULSE_ENABLE;
  hspi2.Init.NSSPolarity = SPI_NSS_POLARITY_LOW;
  hspi2.Init.FifoThreshold = SPI_FIFO_THRESHOLD_01DATA;
  hspi2.Init.TxCRCInitializationPattern = SPI_CRC_INITIALIZATION_ALL_ZERO_PATTERN;
  hspi2.Init.RxCRCInitializationPattern = SPI_CRC_INITIALIZATION_ALL_ZERO_PATTERN;
  hspi2.Init.MasterSSIdleness = SPI_MASTER_SS_IDLENESS_00CYCLE;
  hspi2.Init.MasterInterDataIdleness = SPI_MASTER_INTERDATA_IDLENESS_00CYCLE;
  hspi2.Init.MasterReceiverAutoSusp = SPI_MASTER_RX_AUTOSUSP_DISABLE;
  hspi2.Init.MasterKeepIOState = SPI_MASTER_KEEP_IO_STATE_DISABLE;
  hspi2.Init.IOSwap = SPI_IO_SWAP_DISABLE;
  if (HAL_SPI_Init(&hspi2) != HAL_OK)
  {
    Error_Handler();
  }
  /* USER CODE BEGIN SPI2_Init 2 */

  /* USER CODE END SPI2_Init 2 */

}

/**
  * @brief USART1 Initialization Function
  * @param None
  * @retval None
  */
static void MX_USART1_UART_Init(void)
{

  /* USER CODE BEGIN USART1_Init 0 */

  /* USER CODE END USART1_Init 0 */

  /* USER CODE BEGIN USART1_Init 1 */

  /* USER CODE END USART1_Init 1 */
  huart1.Instance = USART1;
  huart1.Init.BaudRate = 115200;
  huart1.Init.WordLength = UART_WORDLENGTH_8B;
  huart1.Init.StopBits = UART_STOPBITS_1;
  huart1.Init.Parity = UART_PARITY_NONE;
  huart1.Init.Mode = UART_MODE_TX_RX;
  huart1.Init.HwFlowCtl = UART_HWCONTROL_NONE;
  huart1.Init.OverSampling = UART_OVERSAMPLING_16;
  huart1.Init.OneBitSampling = UART_ONE_BIT_SAMPLE_DISABLE;
  huart1.Init.ClockPrescaler = UART_PRESCALER_DIV1;
  huart1.AdvancedInit.AdvFeatureInit = UART_ADVFEATURE_NO_INIT;
  if (HAL_UART_Init(&huart1) != HAL_OK)
  {
    Error_Handler();
  }
  if (HAL_UARTEx_SetTxFifoThreshold(&huart1, UART_TXFIFO_THRESHOLD_1_8) != HAL_OK)
  {
    Error_Handler();
  }
  if (HAL_UARTEx_SetRxFifoThreshold(&huart1, UART_RXFIFO_THRESHOLD_1_8) != HAL_OK)
  {
    Error_Handler();
  }
  if (HAL_UARTEx_DisableFifoMode(&huart1) != HAL_OK)
  {
    Error_Handler();
  }
  /* USER CODE BEGIN USART1_Init 2 */

  /* USER CODE END USART1_Init 2 */

}

/**
  * @brief GPIO Initialization Function
  * @param None
  * @retval None
  */
static void MX_GPIO_Init(void)
{
  GPIO_InitTypeDef GPIO_InitStruct = {0};

  /* GPIO Ports Clock Enable */
  __HAL_RCC_GPIOB_CLK_ENABLE();
  __HAL_RCC_GPIOA_CLK_ENABLE();

  /*Configure GPIO pin Output Level */
  HAL_GPIO_WritePin(GPIOB, GPIO_PIN_12, GPIO_PIN_SET);

  /*Configure GPIO pin : PB12 */
  GPIO_InitStruct.Pin = GPIO_PIN_12;
  GPIO_InitStruct.Mode = GPIO_MODE_OUTPUT_PP;
  GPIO_InitStruct.Pull = GPIO_NOPULL;
  GPIO_InitStruct.Speed = GPIO_SPEED_FREQ_VERY_HIGH;
  HAL_GPIO_Init(GPIOB, &GPIO_InitStruct);

}

/* USER CODE BEGIN 4 */
void HAL_UART_RxCpltCallback(UART_HandleTypeDef *huart)
{
	if(huart==&huart1)
	{
		cmd = uart1_rx[0];
		HAL_UART_Receive_IT(&huart1, uart1_rx, 1);
	}

}
/* USER CODE END 4 */

/**
  * @brief  This function is executed in case of error occurrence.
  * @retval None
  */
void Error_Handler(void)
{
  /* USER CODE BEGIN Error_Handler_Debug */
  /* User can add his own implementation to report the HAL error return state */
  __disable_irq();
  while (1)
  {
  }
  /* USER CODE END Error_Handler_Debug */
}

#ifdef  USE_FULL_ASSERT
/**
  * @brief  Reports the name of the source file and the source line number
  *         where the assert_param error has occurred.
  * @param  file: pointer to the source file name
  * @param  line: assert_param error line source number
  * @retval None
  */
void assert_failed(uint8_t *file, uint32_t line)
{
  /* USER CODE BEGIN 6 */
  /* User can add his own implementation to report the file name and line number,
     ex: printf("Wrong parameters value: file %s on line %d\r\n", file, line) */
  /* USER CODE END 6 */
}
#endif /* USE_FULL_ASSERT */


STM32例程测试

串口指令0x01测试效果如下:
在这里插入图片描述

串口指令0x02测试效果如下:
在这里插入图片描述

串口指令0x03测试效果如下:
在这里插入图片描述

串口指令0x04测试效果如下:
在这里插入图片描述

串口指令0x05测试效果如下:
在这里插入图片描述

串口指令0x06测试效果如下:
在这里插入图片描述
通过串口对FLASH对操作后,可以将STM32 USB接口连接到PC, 从PC端可以看到U盘接入,打开后可以看到通过串口建立和操作的文件:
在这里插入图片描述
在这里插入图片描述
串口写入文件里的是1~20范围的16进制数据,这里显示为非常规字符,如果串口写入文件里的是英文字母对应的ASCII码16进制数据,文件里也就会显示为英文字母。
当通过U盘形式对文件进行操作后,同样也可以再通过串口对U盘形式操作过的文件访问操作。

STM32例程下载

STM32H750VBT6 模拟U盘桥接SPI总线FATS读写FLASH W25QXX例程下载

U盘模式升级方式

一种STM32升级方式为通过模拟U盘,从PC端将升级文件(.bin文件)存储进到外部FLASH里,STM32重新上电时识别标识从外部FLASH里将版本拷贝进到内部FLASH跳转空间,然后跳转执行。这是IAP升级的U盘接口常见方式,可以参考串口IAP升级过程,主要区别是版本数据获得方式不同。
一个不复杂的问题是为什么不从PC端直接写入.bin文件进到内部FLASH里,因为文件管理系统会占用额外的空间,也会导致文件放置首地址(跳转地址)易变,因此对MCU有限的内部FLASH空间而言不利资源使用。

–End–

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