|
|
马上注册,结交更多好友,享用更多功能,让你轻松玩转社区
您需要 登录 才可以下载或查看,没有账号?立即注册
×
#include "flash.h"
unsigned short SPI_FLASH_TYPE=W25Q64;//默认就是25Q64
//4Kbytes为一个Sector
//16个扇区为1个Block
//W25X16
//容量为2M字节,共有32个Block,512个Sector
//初始化SPI FLASH的IO口
void delay_us1(unsigned int i)
{
unsigned char j=0xff;
while(i--)
{
while(j--);
j=0xff;
}
}
//unsigned char SPI1Buffer[1024]={0};
//void SPI_Flash_Init1( unsigned int SPI1_DR_Addr,
// unsigned int SPI1_RX_Buff ,unsigned int SPI1_ReciveBufferSize,
// unsigned int SPI1_TX_Buff ,unsigned int SPI1_SendBufferSize )
//{
// DMA_InitTypeDef DMA_InitStructure;
//
// /* DMA1 Channel2 (triggered by SPI1 Rx event) Config */
// DMA_DeInit(DMA1_Channel2);
// DMA_InitStructure.DMA_PeripheralBaseAddr = SPI1_DR_Addr; //?? SPI1 ????(0x4001300C) ??(????)
// DMA_InitStructure.DMA_MemoryBaseAddr = (uint32_t)SPI1_RX_Buff; //?? SRAM ????(????)
// DMA_InitStructure.DMA_DIR = DMA_DIR_PeripheralSRC; //???? ??-??
// DMA_InitStructure.DMA_BufferSize = SPI1_ReciveBufferSize; //?? SPI1 ????
// DMA_InitStructure.DMA_PeripheralInc = DMA_PeripheralInc_Disable;
// DMA_InitStructure.DMA_MemoryInc = DMA_MemoryInc_Enable;
// DMA_InitStructure.DMA_PeripheralDataSize = DMA_PeripheralDataSize_Byte;
// DMA_InitStructure.DMA_MemoryDataSize = DMA_MemoryDataSize_Byte;
// DMA_InitStructure.DMA_Mode = DMA_Mode_Normal;
// DMA_InitStructure.DMA_Priority = DMA_Priority_VeryHigh;
// DMA_InitStructure.DMA_M2M = DMA_M2M_Disable;
// DMA_Init(DMA1_Channel2, &DMA_InitStructure);
// DMA_ITConfig(DMA1_Channel2, DMA_IT_TC, ENABLE);
// /* Enable SPI1 DMA RX request */
// SPI1->CR2 |= 1<<0; //?????DMA??
// DMA_Cmd(DMA1_Channel2, ENABLE);
//
//
// /* DMA1 Channel3 (triggered by SPI1 Tx event) Config */
// DMA_DeInit(DMA1_Channel3);
// DMA_InitStructure.DMA_PeripheralBaseAddr = SPI1_DR_Addr; //?? ????(0x4001300C) ??(???)
// DMA_InitStructure.DMA_MemoryBaseAddr = (uint32_t)SPI1_TX_Buff; //?? SRAM ????(???)
// DMA_InitStructure.DMA_DIR = DMA_DIR_PeripheralDST; //???? ??-??
// DMA_InitStructure.DMA_BufferSize = SPI1_SendBufferSize; //?? SPI1 ????
// DMA_InitStructure.DMA_PeripheralInc = DMA_PeripheralInc_Disable; //??????(??)
// DMA_InitStructure.DMA_MemoryInc = DMA_MemoryInc_Enable; //??????(??)
// DMA_InitStructure.DMA_PeripheralDataSize = DMA_PeripheralDataSize_Byte; //??????(??)
// DMA_InitStructure.DMA_MemoryDataSize = DMA_MemoryDataSize_Byte; //??????(??)
// DMA_InitStructure.DMA_Mode = DMA_Mode_Normal; //????,???????,?????
// DMA_InitStructure.DMA_Priority = DMA_Priority_VeryHigh; //????-?(??)
// DMA_InitStructure.DMA_M2M = DMA_M2M_Disable; //?????????
// DMA_Init(DMA1_Channel3, &DMA_InitStructure);
// DMA_ITConfig(DMA1_Channel3, DMA_IT_TC, ENABLE); //?? DMA1_Channel3 ??????
// DMA_ITConfig(DMA1_Channel3, DMA_IT_TE, ENABLE); //?? DMA1_Channel3 ??????
// /* Enable SPI1 DMA TX request */
// SPI1->CR2 |= 1<<1; //?????DMA??
// DMA_Cmd(DMA1_Channel3, DISABLE); //?? DMA ?? DMA1_Channel3
//}
//void SPI1_Recive( unsigned int SPI1_DR_Addr, unsigned char *buff, unsigned int len )
//{
// DMA1_Channel2->CCR &= ~( 1 << 0 ); //??DMA??2
//
// DMA1_Channel2->CPAR = SPI1_DR_Addr; //????
// DMA1_Channel2->CMAR = (uint32_t)buff; //mem??
// DMA1_Channel2->CNDTR = len ; //????
// DMA1_Channel2->CCR = (0 << 14) | // ??????????
// (2 << 12) | // ??????
// (0 << 11) | // ???????8bit
// (0 << 10) | // ???????8bit
// (0 << 9) | // ??????8bit
// (0 << 8) | // ??????8bit
// (1 << 7) | // ?????????
// (0 << 6) | // ????????(??)
// (0 << 5) | // ?????
// (0 << 4) | // ???? ??-??
// (0 << 3) | // ????????
// (0 << 2) | // ???????
// (1 << 1) | // ????????
// (1 << 0) ; // ????
//}
//void SPI1_Send( unsigned int SPI1_DR_Addr,unsigned char *buff, unsigned int len )
//{
// DMA1_Channel3->CPAR = SPI1_DR_Addr; //????
// DMA1_Channel3->CMAR = (u32) buff; //mem??
// DMA1_Channel3->CNDTR = len ; //????
// DMA1_Channel3->CCR = (0 << 14) | // ??????????
// (2 << 12) | // ??????
// (0 << 11) | // ???????8bit
// (0 << 10) | // ???????8bit
// (0 << 9) | // ??????8bit
// (0 << 8) | // ??????8bit
// (1 << 7) | // ?????????
// (0 << 6) | // ????????(??)
// (0 << 5) | // ?????
// (1 << 4) | // ?????
// (1 << 3) | // ????????
// (0 << 2) | // ???????
// (1 << 1) | // ????????
// (1 << 0) ; // ????
//}
void SPI_Flash_Init(void)
{
//char tem[1024]={0};
GPIO_InitTypeDef GPIO_InitStructure;
RCC_APB2PeriphClockCmd( RCC_APB2Periph_GPIOA, ENABLE );
GPIO_InitStructure.GPIO_Pin = /*GPIO_Pin_2|GPIO_Pin_3|*/GPIO_Pin_4; //SPI CS
GPIO_InitStructure.GPIO_Mode = GPIO_Mode_Out_PP; //复用推挽输出
GPIO_InitStructure.GPIO_Speed=GPIO_Speed_50MHz;
GPIO_Init(GPIOA, &GPIO_InitStructure);
GPIO_SetBits(GPIOA,/*GPIO_Pin_2|GPIO_Pin_3|*/GPIO_Pin_4);
SPI1_Init(); //初始化SPI
SPI1_SetSpeed(SPI_BaudRatePrescaler_2); //设置为18M时钟,高速模式
SPI_FLASH_TYPE=SPI_Flash_ReadID();//读取FLASH ID.
//SPI_Flash_Read( (unsigned char*)tem,0,1024 ); //从倒数第100个地址处开始,读出SIZE个字节
}
//读取SPI_FLASH的状态寄存器
//BIT7 6 5 4 3 2 1 0
//SPR RV TB BP2 BP1 BP0 WEL BUSY
//SPR:默认0,状态寄存器保护位,配合WP使用
//TB,BP2,BP1,BP0:FLASH区域写保护设置
//WEL:写使能锁定
//BUSY:忙标记位(1,忙;0,空闲)
//默认:0x00
unsigned char SPI_Flash_ReadSR(void)
{
unsigned char byte=0;
SPI_FLASH_CS=0; //使能器件
SPI1_ReadWriteByte(W25X_ReadStatusReg); //发送读取状态寄存器命令
byte=SPI1_ReadWriteByte(0Xff); //读取一个字节
SPI_FLASH_CS=1; //取消片选
return byte;
}
//写SPI_FLASH状态寄存器
//只有SPR,TB,BP2,BP1,BP0(bit 7,5,4,3,2)可以写!!!
void SPI_FLASH_Write_SR(unsigned char sr)
{
SPI_FLASH_CS=0; //使能器件
SPI1_ReadWriteByte(W25X_WriteStatusReg); //发送写取状态寄存器命令
SPI1_ReadWriteByte(sr); //写入一个字节
SPI_FLASH_CS=1; //取消片选
}
//SPI_FLASH写使能
//将WEL置位
void SPI_FLASH_Write_Enable(void)
{
SPI_FLASH_CS=0; //使能器件
SPI1_ReadWriteByte(W25X_WriteEnable); //发送写使能
SPI_FLASH_CS=1; //取消片选
}
//SPI_FLASH写禁止
//将WEL清零
void SPI_FLASH_Write_Disable(void)
{
SPI_FLASH_CS=0; //使能器件
SPI1_ReadWriteByte(W25X_WriteDisable); //发送写禁止指令
SPI_FLASH_CS=1; //取消片选
}
//读取芯片ID W25X16的ID:0XEF14
unsigned short SPI_Flash_ReadID(void)
{
unsigned short Temp = 0;
SPI_FLASH_CS=0;
SPI1_ReadWriteByte(0x90);//发送读取ID命令
SPI1_ReadWriteByte(0x00);
SPI1_ReadWriteByte(0x00);
SPI1_ReadWriteByte(0x00);
Temp|=SPI1_ReadWriteByte(0xFF)<<8;
Temp|=SPI1_ReadWriteByte(0xFF);
SPI_FLASH_CS=1;
return Temp;
}
//读取SPI FLASH
//在指定地址开始读取指定长度的数据
//pBuffer:数据存储区
//ReadAddr:开始读取的地址(24bit)
//NumByteToRead:要读取的字节数(最大65535)
void SPI_Flash_Read(unsigned char * pBuffer,unsigned int ReadAddr,unsigned short NumByteToRead)
{
unsigned short i;
SPI_FLASH_CS=0; //使能器件
SPI1_ReadWriteByte(W25X_ReadData); //发送读取命令
SPI1_ReadWriteByte((unsigned char)((ReadAddr)>>16)); //发送24bit地址
SPI1_ReadWriteByte((unsigned char)((ReadAddr)>>8));
SPI1_ReadWriteByte((unsigned char)ReadAddr);
for(i=0;i<NumByteToRead;i++)
{
// pBuffer=SPI1_ReadWriteByte(0XFF); //循环读数
// while (SPI_I2S_GetFlagStatus(SPI1, SPI_I2S_FLAG_TXE) == RESET); //检查指定的SPI标志位设置与否:发送缓存空标志位
// SPI_I2S_SendData(SPI1,0xff); //通过外设SPIx发送一个数据
// while (SPI_I2S_GetFlagStatus(SPI1, SPI_I2S_FLAG_RXNE) == RESET);//检查指定的SPI标志位设置与否:接受缓存非空标志位
// pBuffer = SPI_I2S_ReceiveData(SPI1); //返回通过SPIx最近接收的数据
while( (SPI1->SR&SPI_I2S_FLAG_TXE)==RESET );
SPI1->DR = 0xFF;
while( (SPI1->SR&SPI_I2S_FLAG_RXNE)==RESET );
pBuffer = SPI1->DR;
}
SPI_FLASH_CS=1; //取消片选
}
//SPI在一页(0~65535)内写入少于256个字节的数据
//在指定地址开始写入最大256字节的数据
//pBuffer:数据存储区
//WriteAddr:开始写入的地址(24bit)
//NumByteToWrite:要写入的字节数(最大256),该数不应该超过该页的剩余字节数!!!
void SPI_Flash_Write_Page(unsigned char* pBuffer,unsigned int WriteAddr,unsigned short NumByteToWrite)
{
unsigned short i;
SPI_FLASH_Write_Enable(); //SET WEL
SPI_FLASH_CS=0; //使能器件
SPI1_ReadWriteByte(W25X_PageProgram); //发送写页命令
SPI1_ReadWriteByte((unsigned char)((WriteAddr)>>16)); //发送24bit地址
SPI1_ReadWriteByte((unsigned char)((WriteAddr)>>8));
SPI1_ReadWriteByte((unsigned char)WriteAddr);
for(i=0;i<NumByteToWrite;i++)SPI1_ReadWriteByte(pBuffer);//循环写数
SPI_FLASH_CS=1; //取消片选
SPI_Flash_Wait_Busy(); //等待写入结束
}
//无检验写SPI FLASH
//必须确保所写的地址范围内的数据全部为0XFF,否则在非0XFF处写入的数据将失败!
//具有自动换页功能
//在指定地址开始写入指定长度的数据,但是要确保地址不越界!
//pBuffer:数据存储区
//WriteAddr:开始写入的地址(24bit)
//NumByteToWrite:要写入的字节数(最大65535)
//CHECK OK
void SPI_Flash_Write_NoCheck(unsigned char* pBuffer,u32 WriteAddr,unsigned short NumByteToWrite)
{
unsigned short pageremain;
pageremain=256-WriteAddr%256; //单页剩余的字节数
if(NumByteToWrite<=pageremain)pageremain=NumByteToWrite;//不大于256个字节
while(1)
{
SPI_Flash_Write_Page(pBuffer,WriteAddr,pageremain);
if(NumByteToWrite==pageremain)break;//写入结束了
else //NumByteToWrite>pageremain
{
pBuffer+=pageremain;
WriteAddr+=pageremain;
NumByteToWrite-=pageremain; //减去已经写入了的字节数
if(NumByteToWrite>256)pageremain=256; //一次可以写入256个字节
else pageremain=NumByteToWrite; //不够256个字节了
}
};
}
//写SPI FLASH
//在指定地址开始写入指定长度的数据
//该函数带擦除操作!
//pBuffer:数据存储区
//WriteAddr:开始写入的地址(24bit)
//NumByteToWrite:要写入的字节数(最大65535)
unsigned char SPI_FLASH_BUF[4096];
void SPI_Flash_Write(unsigned char* pBuffer,u32 WriteAddr,unsigned short NumByteToWrite)
{
unsigned int secpos;
unsigned short secoff;
unsigned short secremain;
unsigned short i;
secpos=WriteAddr/4096;//扇区地址 0~511 for w25x16
secoff=WriteAddr%4096;//在扇区内的偏移
secremain=4096-secoff;//扇区剩余空间大小
if(NumByteToWrite<=secremain)secremain=NumByteToWrite;//不大于4096个字节
while(1)
{
SPI_Flash_Read(SPI_FLASH_BUF,secpos*4096,4096);//读出整个扇区的内容
for(i=0;i<secremain;i++)//校验数据
{
if(SPI_FLASH_BUF[secoff+i]!=0XFF)break;//需要擦除
}
if(i<secremain)//需要擦除
{
SPI_Flash_Erase_Sector(secpos);//擦除这个扇区
for(i=0;i<secremain;i++) //复制
{
SPI_FLASH_BUF[i+secoff]=pBuffer;
}
SPI_Flash_Write_NoCheck(SPI_FLASH_BUF,secpos*4096,4096);//写入整个扇区
}else SPI_Flash_Write_NoCheck(pBuffer,WriteAddr,secremain);//写已经擦除了的,直接写入扇区剩余区间.
if(NumByteToWrite==secremain)break;//写入结束了
else//写入未结束
{
secpos++;//扇区地址增1
secoff=0;//偏移位置为0
pBuffer+=secremain; //指针偏移
WriteAddr+=secremain;//写地址偏移
NumByteToWrite-=secremain; //字节数递减
if(NumByteToWrite>4096)secremain=4096; //下一个扇区还是写不完
else secremain=NumByteToWrite; //下一个扇区可以写完了
}
};
}
//擦除整个芯片
//整片擦除时间:
//W25X16:25s
//W25X32:40s
//W25X64:40s
//等待时间超长...
void SPI_Flash_Erase_Chip(void)
{
SPI_FLASH_Write_Enable(); //SET WEL
SPI_Flash_Wait_Busy();
SPI_FLASH_CS=0; //使能器件
SPI1_ReadWriteByte(W25X_ChipErase); //发送片擦除命令
SPI_FLASH_CS=1; //取消片选
SPI_Flash_Wait_Busy(); //等待芯片擦除结束
}
//擦除一个扇区
//Dst_Addr:扇区地址 0~511 for w25x16
//擦除一个山区的最少时间:150ms
void SPI_Flash_Erase_Sector(unsigned int Dst_Addr)
{
Dst_Addr*=4096;
SPI_FLASH_Write_Enable(); //SET WEL
SPI_Flash_Wait_Busy();
SPI_FLASH_CS=0; //使能器件
SPI1_ReadWriteByte(W25X_SectorErase); //发送扇区擦除指令
SPI1_ReadWriteByte((unsigned char)((Dst_Addr)>>16)); //发送24bit地址
SPI1_ReadWriteByte((unsigned char)((Dst_Addr)>>8));
SPI1_ReadWriteByte((unsigned char) Dst_Addr);
SPI_FLASH_CS=1; //取消片选
SPI_Flash_Wait_Busy(); //等待擦除完成
}
//等待空闲
void SPI_Flash_Wait_Busy(void)
{
while ((SPI_Flash_ReadSR()&0x01)==0x01); // 等待BUSY位清空
}
//进入掉电模式
void SPI_Flash_PowerDown1(void)
{
SPI_FLASH_CS=0; //使能器件
SPI1_ReadWriteByte(W25X_PowerDown); //发送掉电命令
SPI_FLASH_CS=1; //取消片选
delay_us1(3); //等待TPD
}
//唤醒
void SPI_Flash_WAKEUP1(void)
{
SPI_FLASH_CS=0; //使能器件
SPI1_ReadWriteByte(W25X_ReleasePowerDown); // send W25X_PowerDown command 0xAB
SPI_FLASH_CS=1; //取消片选
delay_us1(3); //等待TRES1
} |
|
再发某公司的PADS格式 PCB封装库全套共享
Allegro超强最全模仿PADS快捷键实现Z切换层
2层设计 车载DVD主板PCB文件
N32WB452 蓝牙5.0 方案PCB 原理图 源码文档
ALLWINNER 全志V583 挂一个DDR3 参考版PCB
MTK6762(MT6762) 10层2介盲埋孔智能手持终
CR95HF +PIC18F25J11 做的NFC读卡器PCB和原
allegro羊皮卷
仪表放大器入门与应用指南.pdf
时域反射计的技术原理和应用场景
22×4段码液晶屏驱动液晶显示驱动IC段码LCD
allegro17.4 PCB设计选择区别
最新元件丝印代码反查手册-3181页.pdf
VKD233HQ SOT23-6低电流单通道触摸/低电流1
发表于 2020-11-24 07:53:15
