/**
* @brief Storage get free space
* @param unit: logical storage unit index.
* @retval int
*/
uint32_t k_StorageGetFree (uint8_t unit)
{
uint32_t fre_clust = 0;
FATFS *fs;
FRESULT res = FR_INT_ERR;
if(unit == 0)
{
fs = &USBDISK_FatFs;
res = f_getfree("0:", (DWORD *)&fre_clust, &fs);
}
else if (unit == 1)
{
fs = &mSDDISK_FatFs;
res = f_getfree("1:", (DWORD *)&fre_clust, &fs);
}
if(res == FR_OK)
{
return (fre_clust * fs->csize);
}
else
{
return 0;
}
}
void cmd_tree(BaseSequentialStream *chp, int argc, char *argv[]) {
FRESULT err;
unsigned long clusters;
unsigned long long total = 0;
FATFS *fsp;
(void)argv;
if (argc > 0) {
SHELLDBG("Usage: tree\r\n");
return;
}
if (!fs_ready) {
SHELLDBG("File System not mounted\r\n");
return;
}
err = f_getfree("/", &clusters, &fsp);
if (err != FR_OK) {
err = f_getfree("/", &clusters, &fsp);
if (err != FR_OK) {
SHELLDBG("FS: f_getfree() failed. FRESULT: %d\r\n", err);
return;
}
}
SHELLDBG("FS: %lu free clusters, %lu sectors per cluster, %lu bytes free.\r\n",
clusters, (uint32_t)SDC_FS.csize,
total);
fbuff[0] = 0;
sdc_scan_files(chp, (char *)fbuff);
}
/*
* Executed as event handler at 500mS intervals.
*/
static void TimerHandler(eventid_t id) {
(void)id;
if (!palReadPad(IOPORT1, PA_BUTTON1)) {
if (fs_ready) {
FRESULT err;
uint32_t clusters;
FATFS *fsp;
err = f_getfree("/", &clusters, &fsp);
if (err != FR_OK) {
chprintf((BaseSequentialStream *)&SD1, "FS: f_getfree() failed\r\n");
return;
}
chprintf((BaseSequentialStream *)&SD1,
"FS: %lu free clusters, %lu sectors per cluster, %lu bytes free\r\n",
clusters, (uint32_t)MMC_FS.csize,
clusters * (uint32_t)MMC_FS.csize * (uint32_t)MMCSD_BLOCK_SIZE);
fbuff[0] = 0;
scan_files((BaseSequentialStream *)&SD1, (char *)fbuff);
}
}
else if (!palReadPad(IOPORT1, PA_BUTTON2)) {
static WORKING_AREA(waTestThread, 256);
Thread *tp = chThdCreateStatic(waTestThread, sizeof(waTestThread),
NORMALPRIO, TestThread, &SD1);
chThdWait(tp);
buzzPlay(500, MS2ST(100));
}
}
// Get information about the SD card and interface speed
MassStorage::InfoResult MassStorage::GetCardInfo(size_t slot, uint64_t& capacity, uint64_t& freeSpace, uint32_t& speed, uint32_t& clSize)
{
if (slot >= NumSdCards)
{
return InfoResult::badSlot;
}
SdCardInfo& inf = info[slot];
if (!inf.isMounted)
{
return InfoResult::noCard;
}
capacity = (uint64_t)sd_mmc_get_capacity(slot) * 1024;
speed = sd_mmc_get_interface_speed(slot);
String<ShortScratchStringLength> path;
path.printf("%u:/", slot);
uint32_t freeClusters;
FATFS *fs;
const FRESULT fr = f_getfree(path.c_str(), &freeClusters, &fs);
if (fr == FR_OK)
{
clSize = fs->csize * 512;
freeSpace = (fr == FR_OK) ? (uint64_t)freeClusters * clSize : 0;
}
else
{
clSize = 0;
freeSpace = 0;
}
return InfoResult::ok;
}
static void cmd_tree(BaseSequentialStream *chp, int argc, char *argv[]) {
FRESULT err;
uint32_t fre_clust;
FATFS *fsp;
(void)argv;
if (argc > 0) {
chprintf(chp, "Usage: tree\r\n");
return;
}
if (!fs_ready) {
chprintf(chp, "File System not mounted\r\n");
return;
}
err = f_getfree("/", &fre_clust, &fsp);
if (err != FR_OK) {
chprintf(chp, "FS: f_getfree() failed\r\n");
return;
}
chprintf(chp,
"FS: %lu free clusters with %lu sectors (%lu bytes) per cluster\r\n",
fre_clust, (uint32_t)fsp->csize, (uint32_t)fsp->csize * 512);
fbuff[0] = 0;
scan_files(chp, (char *)fbuff);
}
//显示剩余容量
//drv:盘符
//返回值:剩余容量(字节)
u32 mf_showfree(u8 *drv)
{
FATFS *fs1;
u8 res;
u32 fre_clust=0, fre_sect=0, tot_sect=0;
//得到磁盘信息及空闲簇数量
res = f_getfree((const TCHAR*)drv, &fre_clust, &fs1);
if(res==0)
{
tot_sect = (fs1->n_fatent - 2) * fs1->csize;//得到总扇区数
fre_sect = fre_clust * fs1->csize; //得到空闲扇区数
#if _MAX_SS!=512
tot_sect*=fs1->ssize/512;
fre_sect*=fs1->ssize/512;
#endif
if(tot_sect<20480)//总容量小于10M
{
/* Print free space in unit of KB (assuming 512 bytes/sector) */
// printf("\r\n磁盘总容量:%d KB\r\n"
// "可用空间:%d KB\r\n",
// tot_sect>>1,fre_sect>>1);
}else
{
/* Print free space in unit of KB (assuming 512 bytes/sector) */
// printf("\r\n磁盘总容量:%d MB\r\n"
// "可用空间:%d MB\r\n",
// tot_sect>>11,fre_sect>>11);
}
}
return fre_sect;
}
/*******************************************************************************
* @函数名称 MP3_getSdSize
* @函数说明 文件空间占用情况
* @输入参数 无
* @输出参数 无
* @返回参数 1: 成功
0: 失败
* @注意事项 无
*****************************************************************************/
u8 MP3_getSdSize(SD_sizeInfo *pSdSizeInfo)
{
FATFS *fs;
DWORD fre_clust;
res = f_getfree(path, &fre_clust, &fs); /* 必须是根目录,选择磁盘0 */
if ( res==FR_OK )
{
//printf("\n\rget %s drive space.\n\r",path);
/* Print free space in unit of MB (assuming 512 bytes/sector) */
//printf("%d MB total drive space.\r\n"
// "%d MB available.\r\n",
// ( (fs->n_fatent - 2) * fs->csize ) / 2 /1024 , (fre_clust * fs->csize) / 2 /1024 );
pSdSizeInfo->totalSize = ((fs->n_fatent - 2) * fs->csize ) / 2 /1024;
pSdSizeInfo->availableSize = (fre_clust * fs->csize) / 2 /1024;
return 1;
}
else
{
printf("\n\rGet total drive space faild!\n\r");
return 0;
}
}
/*
* ======== printDrive ========
* Function to print drive information such as the total disk space
* This function was created by referencing FatFs's API documentation
* http://elm-chan.org/fsw/ff/en/getfree.html
*
* This function call may take a while to process, depending on the size of
* SD Card used.
*/
void printDrive(const char *driveNumber, FATFS **fatfs)
{
FRESULT fresult;
DWORD freeClusterCount;
DWORD totalSectorCount;
DWORD freeSectorCount;
System_printf("Reading disk information...");
System_flush();
fresult = f_getfree(driveNumber, &freeClusterCount, fatfs);
if (fresult) {
System_abort("Error getting the free cluster count from the FatFs object");
}
else {
System_printf("done\n");
/* Get total sectors and free sectors */
totalSectorCount = ((*fatfs)->n_fatent - 2) * (*fatfs)->csize;
freeSectorCount = freeClusterCount * (*fatfs)->csize;
/* Print the free space (assuming 512 bytes/sector) */
System_printf("Total Disk size: %10lu KiB\n"
"Free Disk space: %10lu KiB\n",
totalSectorCount / 2,
freeSectorCount / 2);
}
}
void get_disk_info(void)
{
FATFS fs;
FATFS *fls = &fs;
FRESULT res;
DWORD clust,tot_sect,fre_sect;
res = f_mount(0,&fs);
// printf("f_mount---%u---",res);
if (res != FR_OK)
{
printf("\r\n挂载文件系统失败,错误代码: %u",res);
return;
}
res = f_getfree((const TCHAR*)"0:",&clust,&fls);
if (res == FR_OK)
{
tot_sect = (fls->n_fatent - 2) * fls->csize;
fre_sect = clust * fls->csize;
printf("\r\nfree space in unit of KB (assuming 512B/sector)");
printf("\r\n%lu KB total drive space.\r\n"
"%lu KB available.",
fre_sect / 2, tot_sect / 2);
}
else
{
printf("\r\n获得磁盘信息失败!");
printf("\r\n错误代码: %u",res);
}
f_mount(0,NULL);
}
int FATFileSystem::statvfs(const char *path, struct statvfs *buf)
{
memset(buf, 0, sizeof(struct statvfs));
FATFS *fs;
DWORD fre_clust;
lock();
FRESULT res = f_getfree(_fsid, &fre_clust, &fs);
if (res != FR_OK) {
unlock();
return fat_error_remap(res);
}
buf->f_bsize = fs->ssize;
buf->f_frsize = fs->ssize;
buf->f_blocks = (fs->n_fatent - 2) * fs->csize;
buf->f_bfree = fre_clust * fs->csize;
buf->f_bavail = buf->f_bfree;
#if FF_USE_LFN
buf->f_namemax = FF_LFN_BUF;
#else
buf->f_namemax = FF_SFN_BUF;
#endif
unlock();
return 0;
}
// Отображение статуса устройства
void PrintStorageStatus(void)
{
unsigned long rLong;
WORD rWord;
BYTE rByte;
if (disk_ioctl(0, GET_SECTOR_COUNT, &rLong) == RES_OK) {
printf("Drive size: %u sectors\r\n", (unsigned int)rLong);
} if (disk_ioctl(0, GET_SECTOR_SIZE, &rWord) == RES_OK) {
printf("Sector size: %u\r\n", rWord);
} if (disk_ioctl(0, GET_BLOCK_SIZE, &rLong) == RES_OK) {
printf("Erase block size: %u sectors\r\n", (unsigned int)rLong);
} if (disk_ioctl(0, MMC_GET_TYPE, &rByte) == RES_OK) {
printf("MMC/SDC type: %u\r\n", rByte);
}
FATFS *fs = &_FatFs;
rByte = f_getfree("", (DWORD*)&rLong, &fs);
if (!rByte) {
printf("FAT type = %u (%s)\n\rNumber of FATs = %u\n\r",
(WORD)_FatFs.fs_type, (_FatFs.fs_type==FS_FAT12) ? "FAT12" : (_FatFs.fs_type==FS_FAT16) ? "FAT16" : "FAT32",
(WORD)_FatFs.n_fats);
} else {
printf("Cannot get more info. Error in getfree: %d\n\r", rByte);
}
}
FRESULT getMountedMemorySize(uint8_t mount_ret, uint32_t * totalSize, uint32_t * availableSize)
{
FATFS *fs;
DWORD fre_clust, fre_sect, tot_sect;
FRESULT res;
/* Get volume information and free clusters of drive 1 */
if(mount_ret == SPI_FLASHM)
res = f_getfree("0:", &fre_clust, &fs);
//else if((mount_ret >= CARD_MMC) && (mount_ret <= CARD_SDHC))
// res = f_getfree("1:", &fre_clust, &fs);
if (!res)
{
/* Get total sectors and free sectors */
tot_sect = (fs->n_fatent - 2) * fs->csize;
fre_sect = fre_clust * fs->csize;
/* Print the free space (assuming 512 bytes/sector) */
//printf(" - Available memory size : %8ld / %8ld kB\r\n", fre_sect / 2, tot_sect / 2);
*totalSize = tot_sect / 2;
*availableSize = fre_sect / 2;
}
return res;
}
uint8_t slave_null_read_data(uint8_t slave_addr, uint8_t* buf, uint8_t max_len)
{
/* limit number of registers to the max. available */
if(max_len > sizeof(modbus_null_input_register_list))
{
max_len = sizeof(modbus_null_input_register_list);
}
#if MODBUS_NULL_SLAVE_SIMULATION == 0
/* Detecta equipamentos de medição e faz a leitura dos dados */
NULL_IRList.Reg.Pressure_Valve = sensors_read(PRESSURE_VALVE);
NULL_IRList.Reg.Oil_Level = sensors_read(SENSOR_LEVEL);
FATFS *fs; /* Pointer to file system object */
uint32_t p1;
if (f_getfree(".", (DWORD*)&p1, &fs) == FR_OK)
{
NULL_IRList.Reg.SD_bytes_available = (uint32_t)(p1 * fs->csize * 512);
}
NULL_IRList.Reg.Local_time = (uint32_t)simon_clock_get();
#else
uint8_t nregs = 0;
/* return random data */
for(nregs = NULL_REGLIST_OFFSET_NREGS; nregs < (NULL_REGLIST_INPUT_NREGS+NULL_REGLIST_OFFSET_NREGS);nregs++)
{
NULL_IRList.Regs16[nregs] = random_get();
}
#endif
/* get and set timestamp of reading and device id */
SetModbusHeader(slave_addr, NULL_IRList.Regs8);
memcpy(buf,NULL_IRList.Regs8,max_len);
return (max_len);
}
void LTK_get_disk_info(void)
{
FATFS fs;
FATFS *fls = &fs;
FRESULT res;
DWORD fre_clust,tot_sect,fre_sect;
res = f_mount(0,&fs);
if (res != FR_OK)
{
printf("mont file system error, error code: %u\n",res);
return;
}
res = f_getfree("/",&fre_clust,&fls);
if (res == FR_OK)
{
tot_sect = (fls->n_fatent - 2) * fls->csize;
fre_sect = fre_clust * fls->csize;
/* Print free space in unit of KB (assuming 512 bytes/sector) */
printf("%lu KB total drive space.\n"
"%lu KB available.\n",
fre_sect / 2, tot_sect / 2);
}
else
{
printf("failed to get disk info, error code: %u\n", res);
}
f_mount(0,NULL);
}
static void cmd_tree(BaseChannel *chp, int argc, char *argv[]) {
FRESULT err;
uint32_t clusters;
FATFS *fsp;
(void)argv;
if (argc > 0) {
chprintf(chp, "Usage: tree\r\n");
return;
}
if (!fs_ready) {
chprintf(chp, "File System not mounted\r\n");
return;
}
err = f_getfree("/", &clusters, &fsp);
if (err != FR_OK) {
chprintf(chp, "FS: f_getfree() failed\r\n");
return;
}
chprintf(chp,
"FS: %lu free clusters, %lu sectors per cluster, %lu bytes free\r\n",
clusters, (uint32_t)MMC_FS.csize,
clusters * (uint32_t)MMC_FS.csize * (uint32_t)MMC_SECTOR_SIZE);
fbuff[0] = 0;
scan_files(chp, (char *)fbuff);
}
void getSDCardInfo()
{
u8 ret;
uint64_t rl;
u8 buf[1024];
ret = sd.get_CID(buf);
uart1.printf("\r\n========================");
uart1.printf("\r\nget CID Info,ret = %d", ret);
uart1.printf("\r\n");
uart1.printf((const char *)buf);
rl = sd.get_capacity();
uart1.printf("\r\n========================");
uart1.printf("\r\ncapacity = %dMB", rl / 1024 / 1024);
uart1.printf("\r\ncapacity = %0.1fGB", rl / 1024 / 1024/1024.0);
uart1.printf("\r\nWaiting...");
res = f_getfree("/", &free_clust, &fss);
if(res == FR_OK)
{
uart1.printf("\r\npartition size:%dMB", (fss->free_clust) * (fss->csize) / 2048);
uart1.printf("\r\npartition free sectors: %d", (fss->free_clust) * (fss->csize));
uart1.printf("\r\npartition free clust:%d", free_clust);
}
else
uart1.printf("\r\nget capacity faile,err = %d", res);
uart1.printf("\r\nOVER !");
}
int dfs_elm_statfs(struct dfs_filesystem *fs, struct statfs *buf)
{
FATFS *f;
FRESULT res;
char driver[4];
DWORD fre_clust, fre_sect, tot_sect;
RT_ASSERT(fs != RT_NULL);
RT_ASSERT(buf != RT_NULL);
f = (FATFS *)fs->data;
rt_snprintf(driver, sizeof(driver), "%d:", f->drv);
res = f_getfree(driver, &fre_clust, &f);
if (res)
return elm_result_to_dfs(res);
/* Get total sectors and free sectors */
tot_sect = (f->n_fatent - 2) * f->csize;
fre_sect = fre_clust * f->csize;
buf->f_bfree = fre_sect;
buf->f_blocks = tot_sect;
#if _MAX_SS != 512
buf->f_bsize = f->ssize;
#else
buf->f_bsize = 512;
#endif
return 0;
}
static msg_t SdThread(void *arg){
chRegSetThreadName("MicroSD");
(void)arg;
FRESULT err;
uint32_t clusters;
FATFS *fsp;
FIL Log;
msg_t id;
/* wait until card not ready */
NOT_READY:
while (!sdcIsCardInserted(&SDCD1))
chThdSleepMilliseconds(SDC_POLLING_INTERVAL);
chThdSleepMilliseconds(SDC_POLLING_INTERVAL);
if (!sdcIsCardInserted(&SDCD1))
goto NOT_READY;
else
insert_handler();
/* fs mounted? */
if (!fs_ready)
return RDY_RESET;
/* are we have at least 16MB of free space? */
err = f_getfree("/", &clusters, &fsp);
err_check();
if ((clusters * (uint32_t)SDC_FS.csize * (uint32_t)MMCSD_BLOCK_SIZE) < (16*1024*1024))
return RDY_RESET;
/* open file for writing log */
char namebuf[MAX_FILENAME_SIZE];
name_from_time(namebuf);
err = f_open(&Log, namebuf, FA_WRITE | FA_CREATE_ALWAYS);
err_check();
/* main write cycle
* This writer waits msg_t with mavlink message ID. Based on that ID it
* will pack extern mavlink struct with proper packing function. */
setGlobalFlag(GlobalFlags.logger_ready);
while (TRUE){
/* wait ID */
if (logwriter_mb.fetch(&id, TIME_INFINITE) == RDY_OK){
if (!sdcIsCardInserted(&SDCD1)){
clearGlobalFlag(GlobalFlags.logger_ready);
remove_handler();
goto NOT_READY;
}
err = WriteLog(&Log, id, &fresh_data);
err_check();
}
err = fs_sync(&Log);
err_check();
}
return 0;
}
uintmax_t FSFreeSpace(const wchar_t *path) {
FATFS *fs;
DWORD fre_clust;
if (f_getfree(path, &fre_clust, &fs) != FR_OK)
return 0;
return (uintmax_t)fre_clust * fs->csize * _MIN_SS;
}
int main(void)
{
DelayInit();
GPIO_QuickInit(HW_GPIOE, 6, kGPIO_Mode_OPP);
UART_QuickInit(UART0_RX_PD06_TX_PD07, 115200);
printf("FATFS test\r\n");
printf("please insert SD card...\r\n");
if(SD_QuickInit(20*1000*1000))
{
printf("SD card init failed!\r\n");
while(1);
}
printf("SD size:%dMB\r\n", SD_GetSizeInMB());
FRESULT rc;
FATFS fs_sd;
FIL fil;
FATFS *fs;
fs = &fs_sd;
UINT bw,br; /* bw = byte writted br = byte readed */
DWORD fre_clust, fre_sect, tot_sect;
/* 挂载文件系统 */
rc = f_mount(fs, "0:", 0);
ERROR_TRACE(rc);
rc = f_getfree("0:", &fre_clust, &fs);
ERROR_TRACE(rc);
/* 计算磁盘空间及剩余空间 */
tot_sect = (fs->n_fatent - 2) * fs->csize;
fre_sect = fre_clust * fs->csize;
printf("%d KB total drive space.\r\n%d KB available.\r\n", tot_sect / 2, fre_sect / 2);
/* 写入文件 */
printf("open or create file\r\n");
rc = f_open(&fil, "0:/fatfs.txt", FA_WRITE | FA_CREATE_ALWAYS);
ERROR_TRACE(rc);
printf("write file\r\n");
rc = f_write(&fil, "HelloWorld\r\n", 12, &bw);
ERROR_TRACE(rc);
printf("%d bytes writen\r\n", bw);
rc = f_close(&fil);
/* 读取文件 */
rc = f_open(&fil, "0:/fatfs.txt", FA_READ);
ERROR_TRACE(rc);
printf("file size:%l\r\n", f_size(&fil));
printf("file contents:\r\n");
while(1)
{
rc = f_read(&fil, buf, sizeof(buf), &br);
if(rc || !br ) break;
printf("%s", buf);
}
rc = f_close(&fil);
ERROR_TRACE(rc);
while(1)
{
GPIO_ToggleBit(HW_GPIOE, 6);
DelayMs(500);
}
}
uint32_t diskdrive_sector_count()
{
disk_interface_t* disk = diskdrive_get_disk(current_drive);
FATFS *fs;
DWORD fre_clust;
DWORD tot_sect;
f_getfree(disk->volume.lvn, &fre_clust, &fs);
tot_sect = (fs->n_fatent - 2) * fs->csize;
return (uint32_t)tot_sect;
}
unsigned int long long getpartitionfree(const TCHAR* driverpath){
unsigned long freeclst;
FATFS *fs;
FRESULT r ;
r = f_getfree(driverpath,&freeclst,&fs);
if (FR_OK!=r) {
return 0;
}
return (long long)freeclst * fs->csize * SS(fs);
}
uint32_t sdGetFreeSectors()
{
DWORD nofree;
FATFS * fat;
if (f_getfree("", &nofree, &fat) != FR_OK)
{
return 0;
}
return nofree * fat->csize;
}
void setup()
{
ebox_init();
uart1.begin(9600);
ret = sd.begin();
if(!ret)
uart1.printf("\r\nsdcard init ok!");
f_mount(0, &fs);
w5500.begin(mac,lip,sub,gw);
attachEthToSocket(&w5500);
attachSDCardToFat(&sd);
w5500.getMAC (ip);
uart1.printf("\r\nmac : %02x.%02x.%02x.%02x.%02x.%02x\r\n", ip[0],ip[1],ip[2],ip[3],ip[4],ip[5]);
w5500.getIP (ip);
uart1.printf("IP : %d.%d.%d.%d\r\n", ip[0],ip[1],ip[2],ip[3]);
w5500.getSubnet(ip);
uart1.printf("mask : %d.%d.%d.%d\r\n", ip[0],ip[1],ip[2],ip[3]);
w5500.getGateway(ip);
uart1.printf("GW : %d.%d.%d.%d\r\n", ip[0],ip[1],ip[2],ip[3]);
uart1.printf("Network is ready.\r\n");
if(udp1.begin(0,30000) == 0)
uart1.printf("\r\nudp1 server creat ok! listen on 30000");
uart1.printf("\r\nret = %d",ret);
ret = sd.getCID(buf);
uart1.printf("\r\nret = %d",ret);
uart1.printf((const char*)buf);
ret = sd.getCSD(buf);
uart1.printf("\r\nret = %d",ret);
rl = sd.getCapacity();
x = (float)rl;
uart1.printf("\r\n容量 = %f",x/1024/1024);
res=f_getfree("/",&free_clust,&fss);
uart1.printf("该分区所有扇区数为:%d\r\n",(fss->max_clust-2)*(fss->csize));
if(res==FR_OK)
{
uart1.printf("该分区所有扇区数为:%d\r\n",(fss->max_clust-2)*(fss->csize));
uart1.printf("该分区大小为:%dM\r\n",(fss->max_clust-2)*(fss->csize)/2048);
uart1.printf("该分区空簇数为:%d\r\n",free_clust);
uart1.printf("该分区空扇区数为:%d\r\n",free_clust*(fss->csize));
}
else
uart1.printf("获取分区空簇失败\r\n,res = %d",res);
uart1.printf("\r\n");
}
uint32_t diskdrive_clusters_free()
{
disk_interface_t* disk = diskdrive_get_disk(current_drive);
if(disk)
{
FATFS *fs;
DWORD nclst;
f_getfree(disk->volume.lvn, &nclst, &fs);
return nclst;
}
return 0;
}
int getSDFreeSpace()
{
FATFS *fs1;
DWORD fre_clust,fre_sect;
DWORD free = 0;
FRESULT res;
res = f_getfree((const TCHAR*)SDPath, (DWORD*)&fre_clust, &fs1);
if(res==FR_OK)
{
fre_sect=fre_clust*fs1->csize;
free=fre_sect>>1;
return free;
}
/**********************************************************************
functionName:float get_free_space(void)
description:获取SD卡剩余空间,单位是Mb
**********************************************************************/
FRESULT get_free_space(float *space)
{
FRESULT fresult;
unsigned long free_space=0;
FATFS *fs;
fresult = f_getfree("/", &free_space, &fs);
if(fresult != FR_OK)
{
*space=0;
return(fresult);
}
*space=free_space * fs->csize /2048.0f; //之前用的时0.04版本的FATFS系统,0.07E版本的文件系统不一样
return FR_OK;
}
void sdcardInit(void) {
/*
static const evhandler_t evhndl[] = {
InsertHandler,
RemoveHandler
};
struct EventListener el0, el1;
*/
palSetPadMode(GPIOC, 8, PAL_MODE_ALTERNATE(12) | PAL_STM32_OSPEED_HIGHEST);
palSetPadMode(GPIOC, 9, PAL_MODE_ALTERNATE(12) | PAL_STM32_OSPEED_HIGHEST);
palSetPadMode(GPIOC, 10, PAL_MODE_ALTERNATE(12) | PAL_STM32_OSPEED_HIGHEST);
palSetPadMode(GPIOC, 11, PAL_MODE_ALTERNATE(12) | PAL_STM32_OSPEED_HIGHEST);
palSetPadMode(GPIOC, 12, PAL_MODE_ALTERNATE(12) | PAL_STM32_OSPEED_HIGHEST);
palSetPadMode(GPIOD, 2, PAL_MODE_ALTERNATE(12) | PAL_STM32_OSPEED_HIGHEST);
chThdSleepMilliseconds(50);
sdcStart(&SDCD1, NULL);
chThdSleepMilliseconds(50);
InsertHandler(0);
FRESULT err;
uint32_t clusters;
FATFS *fsp;
err = f_getfree("/", &clusters, &fsp);
int retries = 3;
while (err != FR_OK) {
InsertHandler(0);
chThdSleepMilliseconds(20);
err = f_getfree("/", &clusters, &fsp);
chThdSleepMilliseconds(50);
retries--;
if (!retries)
break;
}
}
FRESULT TM_FATFS_DriveSize(uint32_t* total, uint32_t* free) {
FATFS *fs;
DWORD fre_clust;
FRESULT res;
// Get volume information and free clusters of drive
res = f_getfree("0:", &fre_clust, &fs);
if (res != FR_OK) {
return res;
}
// Get total sectors and free sectors
*total = (fs->n_fatent - 2) * fs->csize / 2;
*free = fre_clust * fs->csize / 2;
return FR_OK;
}
/**
* @brief Storage get free space
* @param unit:
* @retval int
*/
uint32_t kStorage_GetFree(void)
{
uint32_t fre_clust = 0;
FATFS *fs ;
FRESULT res = FR_INT_ERR;
fs = &mSDDISK_FatFs;
res = f_getfree("1:", (DWORD *)&fre_clust, &fs);
if(res == FR_OK)
{
return (fre_clust * fs->csize);
}
else
{
return 0;
}
}
