void FMD_Write2Byte(void* pBuf, unsigned int u32StartAddr)
{
unsigned int i;
uint32_t MoreByte = u32StartAddr%PAGE_SIZE;
SPI1_Write_Enable();
__SPI1_CS_ACTIVE /* activate */
SPI1_SendInt((IS_PAGE_PROGRAM << 24) | (u32StartAddr - MoreByte)); /* Write page program command */
/* Write data to SPI Flash */
for ( i = 0; i < PAGE_SIZE; i++ )
{
if(i == MoreByte)
SPI1_SendByte(((unsigned char *)pBuf)[0]);
else if(i == (MoreByte+1))
SPI1_SendByte(((unsigned char *)pBuf)[1]);
else
SPI1_SendByte(0xFF);
}
__SPI1_CS_INACTIVE /* deactivate */
WaitWriteComplete();
}
//myAccel3LV02의 특정 레지스터에서 데이터를 읽어옴
unsigned char Accel_ReadReg(unsigned char reg) {
uint8_t ret = 0;
// CS를 low로 떨어트려서 SPI 통신 시작.
SPI1_CS_LOW();
/*
* register address를 송신. Read일 경우 최상의 비트는 High
* 송신 완료될때까지 대기.
* 수신된 데이터를 저장. 이 데이터는 더미데이터 이다.
*/
ret = SPI1_SendByte(0x80|reg);
/*
* 더미 데이터를 송신.
* 송신 완료될때까지 대기.
* 수신된 data byte를 저장.
*/
ret = SPI1_SendByte(0);
// CS를 high로 올려주면서 SPI 통신 종료.
SPI1_CS_HIGH();
return ret;
}
//myAccel3LV02의 특정 레지스터에 데이터를 기록
void Accel_WriteReg(unsigned char reg, unsigned char data) {
// CS를 low로 떨어트려서 SPI 통신 시작.
SPI1_CS_LOW();
// register address를 송신.
// 송신 완료될때까지 대기.
SPI1_SendByte(reg);
// data 송신.
// 송신 완료될때까지 대기.
SPI1_SendByte(data);
// CS를 high로 올려주면서 SPI 통신 종료.
SPI1_CS_HIGH();
}
void SPI_Init(void)
{
//DrvSPI_Open(eDRVSPI_PORT0, eDRVSPI_MASTER, eDRVSPI_TYPE1, 32);
SYSCLK->APBCLK.SPI0_EN = 1;
SYS->IPRSTC2.SPI0_RST = 1;
SYS->IPRSTC2.SPI0_RST = 0;
SYS->GPA_ALT.GPA0 = 1; // MOSI0
SYS->GPA_ALT.GPA1 = 1; // SCLK
SYS->GPA_ALT.GPA2 = 1; // SSB0
SYS->GPA_ALT.GPA3 = 1; // MISO0
/* Check busy*/
while(SPI0->CNTRL.GO_BUSY) {}
SPI0->CNTRL.TX_BIT_LEN = 8; // //DrvSPI_SetBitLength(eDRVSPI_PORT0, 8);
SPI0->JS.JS = 0;
// DrvSPI_DisableAutoCS(eDRVSPI_PORT0);
SPI0->SSR.SSR = eDRVSPI_NONE;
SPI0->SSR.ASS = 0;
//eDRVSPI_TYPE1
SPI0->CNTRL.CLKP = 0;
SPI0->CNTRL.TX_NEG = 1;
SPI0->CNTRL.RX_NEG = 0;
// set SPI clk
SPI0->DIVIDER.DIVIDER = 2;
SPI0->DIVIDER.DIVIDER2 = 1;
SPI0->CNTRL.LSB = 0; //DrvSPI_SetEndian(eDRVSPI_PORT0, eDRVSPI_MSB_FIRST);
SPI0->CNTRL.SLEEP = 0; //DrvSPI_SetByteSleep(eDRVSPI_PORT0, FALSE);
SPI0->CNTRL.BYTE_ENDIAN = 0; //DrvSPI_SetByteEndian(eDRVSPI_PORT0, FALSE);
SPI0->SSR.SS_LVL = eDRVSPI_ACTIVE_LOW_FALLING; //DrvSPI_SetSlaveSelectActiveLevel(eDRVSPI_PORT0, eDRVSPI_ACTIVE_LOW_FALLING);
//DrvSPI_BurstTransfer(eDRVSPI_PORT0, 1, 2);
SPI0->CNTRL.TX_NUM = 1 - 1;
SPI0->CNTRL.SLEEP = 2 - 2;
/*
* Release from power down
*/
__SPI1_CS_ACTIVE
SPI1_SendByte(IS_Release_DP);
__SPI1_CS_INACTIVE
// Delay for a while (3us) for waiting SPIFlash stable
//HW_WaitTimeout(3);
/*
{
// 测试数据读取
unsigned char buff[16];
FMD_ReadData(buff, 0x340, 4);
FMD_ReadData(buff, 0x340, 4);
FMD_ReadData(buff, 0x340, 4);
}
*/
}
// Wait write operation complete
__inline void WaitWriteComplete(void)
{
uint32_t u32TimeOut, i;
u32TimeOut = 10;
__WaitWriteComplete_BUS_ERROR:
i = 1000;
__SPI1_CS_ACTIVE
SPI1_SendByte(IS_READ_STATUS_REGISTER);
//LOG(("/"));
while ( 1 )
{
unsigned char uSR = SPI1_ReadByte();
if ( !(uSR & SR_BIT0_BUSY) ) {
break;
}
if ( u32TimeOut-- )
{
while ( i-- )
{
__SPI1_CS_INACTIVE
}
goto __WaitWriteComplete_BUS_ERROR;
}
//LOG(("-"));
}
__SPI1_CS_INACTIVE
}
void FMD_WriteData(void* pBuf, unsigned int u32StartAddr)
{
unsigned int i;
// WaitWriteComplete();
SPI1_Write_Enable();
__SPI1_CS_ACTIVE /* activate */
SPI1_SendInt((IS_PAGE_PROGRAM << 24) | u32StartAddr); /* Write page program command */
/* Write data to SPI Flash */
for ( i = 0; i < PAGE_SIZE; i++ )
{
SPI1_SendByte(((unsigned char *)pBuf)[i]);
}
__SPI1_CS_INACTIVE /* deactivate */
// WEL bit is automatically reset after Power-up and upon completion of the
// Write status register, Page program, Sector Erase, Block erase and Chip erase instruction.
// SPI1_Write_Disable();;
// Wait for complete
WaitWriteComplete();
}
__inline void SPI1_Write_Enable()
{
__SPI1_CS_ACTIVE
SPI1_SendByte(IS_WRITE_ENABLE);
__SPI1_CS_INACTIVE
}
BOOL SPI_CheckWriteBusy(void)
{
unsigned char uSR;
// Read status register
__SPI1_CS_ACTIVE
SPI1_SendByte(IS_READ_STATUS_REGISTER);
uSR = SPI1_ReadByte();
__SPI1_CS_INACTIVE
return (uSR & SR_BIT0_BUSY);
}
// Wait write operation complete
__inline void WaitWriteComplete(void)
{
// Read status register
__SPI1_CS_ACTIVE
SPI1_SendByte(IS_READ_STATUS_REGISTER);
while ( 1 )
{
unsigned char uSR = SPI1_ReadByte();
if ( !(uSR & SR_BIT0_BUSY) ) {
break;
}
}
__SPI1_CS_INACTIVE
}
void SPI_Term(void)
{
/*
* SPIFlash power down mode
*/
__SPI1_CS_ACTIVE
SPI1_SendByte(IS_Power_Down);
__SPI1_CS_INACTIVE
//DrvSPI_Close(eDRVSPI_PORT0);
/* Wait SPIMS Busy */
while(SPI0->CNTRL.GO_BUSY) {}
SYS->IPRSTC2.SPI0_RST = 1;
SYS->IPRSTC2.SPI0_RST = 0;
SYSCLK->APBCLK.SPI0_EN = 0;
}
BYTE MEGA8_ADCRead(BYTE channel)
{
BYTE adcVal = 0;
DWORD i = 0;
IOCLR0 |= SPI1_SLAVE_SELECT; // slave select enable
SPI1_SendByte(channel);
//Delay for settling down (80 uS)
for (i=0; i<1000; i++);
adcVal = SPI1_ReceiveByte();
IOSET0 |= SPI1_SLAVE_SELECT; // slave select disable
//Delay for settling down (80 uS)
for (i=0; i<1000; i++);
return adcVal;
}
/****************************************************************************
* 名 称:void Play_Music(void)
* 功 能:TXT文件输出函数
* 入口参数:无
* 出口参数:无
* 说 明:
* 调用方法:无
****************************************************************************/
void Play_Music(void)
{
FILINFO finfo;
DIR dirs;
unsigned int count=0;
char path[50]={""},j=0;
char *result1,*result2,*result3,*result4;
/*开启长文件名功能时, 要预先初始化文件名缓冲区的长度 */
#if _USE_LFN
static char lfn[_MAX_LFN * (_DF1S ? 2 : 1) + 1];
finfo.lfname = lfn;
finfo.lfsize = sizeof(lfn);
#endif
USART_OUT(USART1,"\n文件系统(Tini-FatFS0.09a)启动成功! \n");
disk_initialize(0); //fatfs可以管理多个介质的分区, 所以把物理存储介质SST25VF016B标示为0区,相当于磁盘编号
VS1003_start();
f_mount(0, &fs); //将文件系统设置到0区
if (f_opendir(&dirs, path) == FR_OK) //读取该磁盘的根目录
{
while (f_readdir(&dirs, &finfo) == FR_OK) //循环依次读取文件名
{
if (finfo.fattrib & AM_ARC) //判断文件属性是否为存档型 TXT文件一般都为存档型
{
if(!finfo.fname[0]) break; //如果是文件名为空表示到目录的末尾。退出
if(finfo.lfname[0]){ //长文件名
USART_OUT(USART1,"\r\n文件名是:\n %s\n",finfo.lfname); //输出文件名
result1=strstr(finfo.lfname,".mp3"); //比较后缀是否为音频文件
result2=strstr(finfo.lfname,".mid"); //比较后缀是否为音频文件
result3=strstr(finfo.lfname,".wav"); //比较后缀是否为音频文件
result4=strstr(finfo.lfname,".wma"); //比较后缀是否为音频文件
}
else{ //8.3格式文件名
USART_OUT(USART1,"\r\n文件名是:\n %s\n",finfo.fname); //输出文件名
result1=strstr(finfo.fname,".mp3"); //比较后缀是否为音频文件
result2=strstr(finfo.fname,".mid"); //比较后缀是否为音频文件
result3=strstr(finfo.fname,".wav"); //比较后缀是否为音频文件
result4=strstr(finfo.fname,".wma"); //比较后缀是否为音频文件
}
if(result1!=NULL||result2!=NULL||result3!=NULL||result4!=NULL){
if(finfo.lfname[0]){ //长文件名
res = f_open(&fsrc, finfo.lfname, FA_OPEN_EXISTING | FA_READ);
}
else{ //8.3格式文件名
res = f_open(&fsrc, finfo.fname, FA_OPEN_EXISTING | FA_READ);
}
USART_OUT(USART1,"\r\n Playing...");
br=1;
XDCS_SET(0); //xDCS = 0,选择vs1003的数据接口
LED1_ON;
for (;;) {
res = f_read(&fsrc, buffer, sizeof(buffer), &br);
if(res==0){
count=0;
Delay_us(1000);
while(count<512){ //根据SD卡介质的原因,文件每次只能读出512字节
if(DREQ!=0){ //VS1003数据申请口线, 每次为高后,可以通过SPI2写入32字节的音频数据
for(j=0;j<32;j++) //每次送32个数据
{
VS1003_WriteByte(buffer[count]); //写入音频数据
/*修改的地方*/ // USART_OUT(USART1,"%d\n",buffer[count]);
SPI1_SendByte(buffer[count]);
count++;
}
}
if (res || br == 0) break; // 是否到文件尾
}
}
if (res || br == 0) break; // 是否到文件尾
}
LED1_OFF;
count=0;
while(count<2048){ //根据VS1003的特性,需要音乐文件的末尾发送一些个0 ,保证下一个音频文件的播放
if(DREQ!=0){
for(j=0;j<32;j++) //每次送32个数据
{
VS1003_WriteByte(0);
count++;
}
}
}
XDCS_SET(1);
f_close(&fsrc);
}
}
}
}
}
uint8 IINCHIP_SpiSendData(uint8 dat)
{
return(SPI1_SendByte(dat));
}
