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dfs
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dfs_v2
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filesystems
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elmfat
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dfs_elm.c

dfs_elm.c 27 KB
文件歷史 原始文件

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  1. /*
    2. 

  2.  * Copyright (c) 2006-2021, RT-Thread Development Team
    3. 

  3.  *
    4. 

  4.  * SPDX-License-Identifier: Apache-2.0
    5. 

  5.  *
    6. 

  6.  * Change Logs:
    7. 

  7.  * Date           Author       Notes
    8. 

  8.  * 2008-02-22     QiuYi        The first version.
    9. 

  9.  * 2011-10-08     Bernard      fixed the block size in statfs.
    10. 

  10.  * 2011-11-23     Bernard      fixed the rename issue.
    11. 

  11.  * 2012-07-26     aozima       implement ff_memalloc and ff_memfree.
    12. 

  12.  * 2012-12-19     Bernard      fixed the O_APPEND and lseek issue.
    13. 

  13.  * 2013-03-01     aozima       fixed the stat(st_mtime) issue.
    14. 

  14.  * 2014-01-26     Bernard      Check the sector size before mount.
    15. 

  15.  * 2017-02-13     Hichard      Update Fatfs version to 0.12b, support exFAT.
    16. 

  16.  * 2017-04-11     Bernard      fix the st_blksize issue.
    17. 

  17.  * 2017-05-26     Urey         fix f_mount error when mount more fats
    18. 

  18.  */
    19. 

  19. 

  20. #include <rtthread.h>
    21. 

  21. #include "ffconf.h"
    22. 

  22. #include "ff.h"
    23. 

  23. #include <string.h>
    24. 

  24. #include <sys/time.h>
    25. 

  25. 

  26. /* ELM FatFs provide a DIR struct */
    27. 

  27. #define HAVE_DIR_STRUCTURE
    28. 

  28. 

  29. #include <dfs.h>
    30. 

  30. #include <dfs_fs.h>
    31. 

  31. #include <dfs_dentry.h>
    32. 

  32. #include <dfs_file.h>
    33. 

  33. #include <dfs_mnt.h>
    34. 

  34. 

  35. #undef SS
    36. 

  36. #if FF_MAX_SS == FF_MIN_SS
    37. 

  37. #define SS(fs) ((UINT)FF_MAX_SS) /* Fixed sector size */
    38. 

  38. #else
    39. 

  39. #define SS(fs) ((fs)->ssize) /* Variable sector size */
    40. 

  40. #endif
    41. 

  41. 

  42. static rt_device_t disk[FF_VOLUMES] = {0};
    43. 

  43. 

  44. int dfs_elm_unmount(struct dfs_mnt *mnt);
    45. 

  45. 

  46. static int elm_result_to_dfs(FRESULT result)
    47. 

  47. {
    48. 

  48.     int status = RT_EOK;
    49. 

  49. 

  50.     switch (result)
    51. 

  51.     {
    52. 

  52.     case FR_OK:
    53. 

  53.         break;
    54. 

  54. 

  55.     case FR_NO_FILE:
    56. 

  56.     case FR_NO_PATH:
    57. 

  57.     case FR_NO_FILESYSTEM:
    58. 

  58.         status = -ENOENT;
    59. 

  59.         break;
    60. 

  60. 

  61.     case FR_INVALID_NAME:
    62. 

  62.         status = -EINVAL;
    63. 

  63.         break;
    64. 

  64. 

  65.     case FR_EXIST:
    66. 

  66.     case FR_INVALID_OBJECT:
    67. 

  67.         status = -EEXIST;
    68. 

  68.         break;
    69. 

  69. 

  70.     case FR_DISK_ERR:
    71. 

  71.     case FR_NOT_READY:
    72. 

  72.     case FR_INT_ERR:
    73. 

  73.         status = -EIO;
    74. 

  74.         break;
    75. 

  75. 

  76.     case FR_WRITE_PROTECTED:
    77. 

  77.     case FR_DENIED:
    78. 

  78.         status = -EROFS;
    79. 

  79.         break;
    80. 

  80. 

  81.     case FR_MKFS_ABORTED:
    82. 

  82.         status = -EINVAL;
    83. 

  83.         break;
    84. 

  84. 

  85.     default:
    86. 

  86.         status = -1;
    87. 

  87.         break;
    88. 

  88.     }
    89. 

  89. 

  90.     return status;
    91. 

  91. }
    92. 

  92. 

  93. /* results:
    94. 

  94.  *  -1, no space to install fatfs driver
    95. 

  95.  *  >= 0, there is an space to install fatfs driver
    96. 

  96.  */
    97. 

  97. static int get_disk(rt_device_t id)
    98. 

  98. {
    99. 

  99.     int index;
    100. 

  100. 

  101.     for (index = 0; index < FF_VOLUMES; index ++)
    102. 

  102.     {
    103. 

  103.         if (disk[index] == id)
    104. 

  104.             return index;
    105. 

  105.     }
    106. 

  106. 

  107.     return -1;
    108. 

  108. }
    109. 

  109. 

  110. static int dfs_elm_mount(struct dfs_mnt *mnt, unsigned long rwflag, const void *data)
    111. 

  111. {
    112. 

  112.     FATFS *fat;
    113. 

  113.     FRESULT result;
    114. 

  114.     int index;
    115. 

  115.     struct rt_device_blk_geometry geometry;
    116. 

  116.     char logic_nbr[3] = {'0',':', 0};
    117. 

  117. 

  118.     /* open device, but do not check the status of device */
    119. 

  119.     if (mnt->dev_id == RT_NULL
    120. 

  120.         || rt_device_open(mnt->dev_id, RT_DEVICE_OFLAG_RDWR) != RT_EOK)
    121. 

  121.     {
    122. 

  122.         return -ENODEV;
    123. 

  123.     }
    124. 

  124. 

  125.     /* get an empty position */
    126. 

  126.     index = get_disk(RT_NULL);
    127. 

  127.     if (index == -1)
    128. 

  128.     {
    129. 

  129.         rt_device_close(mnt->dev_id);
    130. 

  130.         return -ENOENT;
    131. 

  131.     }
    132. 

  132.     logic_nbr[0] = '0' + index;
    133. 

  133. 

  134.     /* save device */
    135. 

  135.     disk[index] = mnt->dev_id;
    136. 

  136.     /* check sector size */
    137. 

  137.     if (rt_device_control(mnt->dev_id, RT_DEVICE_CTRL_BLK_GETGEOME, &geometry) == RT_EOK)
    138. 

  138.     {
    139. 

  139.         if (geometry.bytes_per_sector > FF_MAX_SS)
    140. 

  140.         {
    141. 

  141.             rt_kprintf("The sector size of device is greater than the sector size of FAT.\n");
    142. 

  142.             rt_device_close(mnt->dev_id);
    143. 

  143.             return -EINVAL;
    144. 

  144.         }
    145. 

  145.     }
    146. 

  146. 

  147.     fat = (FATFS *)rt_malloc(sizeof(FATFS));
    148. 

  148.     if (fat == RT_NULL)
    149. 

  149.     {
    150. 

  150.         disk[index] = RT_NULL;
    151. 

  151.         rt_device_close(mnt->dev_id);
    152. 

  152.         return -ENOMEM;
    153. 

  153.     }
    154. 

  154. 

  155.     /* mount fatfs, always 0 logic driver */
    156. 

  156.     result = f_mount(fat, (const TCHAR *)logic_nbr, 1);
    157. 

  157.     if (result == FR_OK)
    158. 

  158.     {
    159. 

  159.         char drive[8];
    160. 

  160.         DIR *dir;
    161. 

  161. 

  162.         rt_snprintf(drive, sizeof(drive), "%d:/", index);
    163. 

  163.         dir = (DIR *)rt_malloc(sizeof(DIR));
    164. 

  164.         if (dir == RT_NULL)
    165. 

  165.         {
    166. 

  166.             f_mount(RT_NULL, (const TCHAR *)logic_nbr, 1);
    167. 

  167.             disk[index] = RT_NULL;
    168. 

  168.             rt_free(fat);
    169. 

  169.             rt_device_close(mnt->dev_id);
    170. 

  170.             return -ENOMEM;
    171. 

  171.         }
    172. 

  172. 

  173.         /* open the root directory to test whether the fatfs is valid */
    174. 

  174.         result = f_opendir(dir, drive);
    175. 

  175.         if (result != FR_OK)
    176. 

  176.             goto __err;
    177. 

  177. 

  178.         /* mount succeed! */
    179. 

  179.         mnt->data = fat;
    180. 

  180.         rt_free(dir);
    181. 

  181.         return RT_EOK;
    182. 

  182.     }
    183. 

  183. 

  184. __err:
    185. 

  185.     f_mount(RT_NULL, (const TCHAR *)logic_nbr, 1);
    186. 

  186.     disk[index] = RT_NULL;
    187. 

  187.     rt_free(fat);
    188. 

  188.     rt_device_close(mnt->dev_id);
    189. 

  189.     return elm_result_to_dfs(result);
    190. 

  190. }
    191. 

  191. 

  192. int dfs_elm_unmount(struct dfs_mnt *mnt)
    193. 

  193. {
    194. 

  194.     FATFS *fat;
    195. 

  195.     FRESULT result;
    196. 

  196.     int  index;
    197. 

  197.     char logic_nbr[3] = {'0',':', 0};
    198. 

  198. 

  199.     fat = (FATFS *)mnt->data;
    200. 

  200. 

  201.     RT_ASSERT(fat != RT_NULL);
    202. 

  202. 

  203.     /* find the device index and then umount it */
    204. 

  204.     index = get_disk(mnt->dev_id);
    205. 

  205.     if (index == -1) /* not found */
    206. 

  206.         return -ENOENT;
    207. 

  207. 

  208.     logic_nbr[0] = '0' + index;
    209. 

  209.     result = f_mount(RT_NULL, logic_nbr, (BYTE)0);
    210. 

  210.     if (result != FR_OK)
    211. 

  211.         return elm_result_to_dfs(result);
    212. 

  212. 

  213.     mnt->data = RT_NULL;
    214. 

  214.     disk[index] = RT_NULL;
    215. 

  215.     rt_free(fat);
    216. 

  216.     rt_device_close(mnt->dev_id);
    217. 

  217. 

  218.     return RT_EOK;
    219. 

  219. }
    220. 

  220. 

  221. int dfs_elm_mkfs(rt_device_t dev_id, const char *fs_name)
    222. 

  222. {
    223. 

  223. #define FSM_STATUS_INIT            0
    224. 

  224. #define FSM_STATUS_USE_TEMP_DRIVER 1
    225. 

  225.     FATFS *fat = RT_NULL;
    226. 

  226.     BYTE *work;
    227. 

  227.     int flag;
    228. 

  228.     FRESULT result;
    229. 

  229.     int index;
    230. 

  230.     char logic_nbr[3] = {'0',':', 0};
    231. 

  231.     MKFS_PARM opt;
    232. 

  232. 

  233.     work = rt_malloc(FF_MAX_SS);
    234. 

  234.     if(RT_NULL == work) {
    235. 

  235.         return -ENOMEM;
    236. 

  236.     }
    237. 

  237. 

  238.     if (dev_id == RT_NULL)
    239. 

  239.     {
    240. 

  240.         rt_free(work); /* release memory */
    241. 

  241.         return -EINVAL;
    242. 

  242.     }
    243. 

  243. 

  244.     /* if the device is already mounted, then just do mkfs to the drv,
    245. 

  245.      * while if it is not mounted yet, then find an empty drive to do mkfs
    246. 

  246.      */
    247. 

  247. 

  248.     flag = FSM_STATUS_INIT;
    249. 

  249.     index = get_disk(dev_id);
    250. 

  250.     if (index == -1)
    251. 

  251.     {
    252. 

  252.         /* not found the device id */
    253. 

  253.         index = get_disk(RT_NULL);
    254. 

  254.         if (index == -1)
    255. 

  255.         {
    256. 

  256.             /* no space to store an temp driver */
    257. 

  257.             rt_kprintf("sorry, there is no space to do mkfs! \n");
    258. 

  258.             rt_free(work); /* release memory */
    259. 

  259.             return -ENOSPC;
    260. 

  260.         }
    261. 

  261.         else
    262. 

  262.         {
    263. 

  263.             fat = (FATFS *)rt_malloc(sizeof(FATFS));
    264. 

  264.             if (fat == RT_NULL)
    265. 

  265.             {
    266. 

  266.                 rt_free(work); /* release memory */
    267. 

  267.                 return -ENOMEM;
    268. 

  268.             }
    269. 

  269. 

  270.             flag = FSM_STATUS_USE_TEMP_DRIVER;
    271. 

  271. 

  272.             disk[index] = dev_id;
    273. 

  273.             /* try to open device */
    274. 

  274.             rt_device_open(dev_id, RT_DEVICE_OFLAG_RDWR);
    275. 

  275. 

  276.             /* just fill the FatFs[vol] in ff.c, or mkfs will failded!
    277. 

  277.              * consider this condition: you just umount the elm fat,
    278. 

  278.              * then the space in FatFs[index] is released, and now do mkfs
    279. 

  279.              * on the disk, you will get a failure. so we need f_mount here,
    280. 

  280.              * just fill the FatFS[index] in elm fatfs to make mkfs work.
    281. 

  281.              */
    282. 

  282.             logic_nbr[0] = '0' + index;
    283. 

  283.             f_mount(fat, logic_nbr, (BYTE)index);
    284. 

  284.         }
    285. 

  285.     }
    286. 

  286.     else
    287. 

  287.     {
    288. 

  288.         logic_nbr[0] = '0' + index;
    289. 

  289.     }
    290. 

  290. 

  291.     /* [IN] Logical drive number */
    292. 

  292.     /* [IN] Format options */
    293. 

  293.     /* [-]  Working buffer */
    294. 

  294.     /* [IN] Size of working buffer */
    295. 

  295.     rt_memset(&opt, 0, sizeof(opt));
    296. 

  296.     opt.fmt = FM_ANY|FM_SFD;
    297. 

  297.     result = f_mkfs(logic_nbr, &opt, work, FF_MAX_SS);
    298. 

  298.     rt_free(work); work = RT_NULL;
    299. 

  299. 

  300.     /* check flag status, we need clear the temp driver stored in disk[] */
    301. 

  301.     if (flag == FSM_STATUS_USE_TEMP_DRIVER)
    302. 

  302.     {
    303. 

  303.         rt_free(fat);
    304. 

  304.         f_mount(RT_NULL, logic_nbr, (BYTE)index);
    305. 

  305.         disk[index] = RT_NULL;
    306. 

  306.         /* close device */
    307. 

  307.         rt_device_close(dev_id);
    308. 

  308.     }
    309. 

  309. 

  310.     if (result != FR_OK)
    311. 

  311.     {
    312. 

  312.         rt_kprintf("format error, result=%d\n", result);
    313. 

  313.         return elm_result_to_dfs(result);
    314. 

  314.     }
    315. 

  315. 

  316.     return RT_EOK;
    317. 

  317. }
    318. 

  318. 

  319. int dfs_elm_statfs(struct dfs_mnt *mnt, struct statfs *buf)
    320. 

  320. {
    321. 

  321.     FATFS *f;
    322. 

  322.     FRESULT res;
    323. 

  323.     char driver[4];
    324. 

  324.     DWORD fre_clust, fre_sect, tot_sect;
    325. 

  325. 

  326.     RT_ASSERT(mnt != RT_NULL);
    327. 

  327.     RT_ASSERT(buf != RT_NULL);
    328. 

  328. 

  329.     f = (FATFS *)mnt->data;
    330. 

  330. 

  331.     rt_snprintf(driver, sizeof(driver), "%d:", f->pdrv);
    332. 

  332.     res = f_getfree(driver, &fre_clust, &f);
    333. 

  333.     if (res)
    334. 

  334.         return elm_result_to_dfs(res);
    335. 

  335. 

  336.     /* Get total sectors and free sectors */
    337. 

  337.     tot_sect = (f->n_fatent - 2) * f->csize;
    338. 

  338.     fre_sect = fre_clust * f->csize;
    339. 

  339. 

  340.     buf->f_bfree = fre_sect;
    341. 

  341.     buf->f_blocks = tot_sect;
    342. 

  342. #if FF_MAX_SS != 512
    343. 

  343.     buf->f_bsize = f->ssize;
    344. 

  344. #else
    345. 

  345.     buf->f_bsize = 512;
    346. 

  346. #endif
    347. 

  347. 

  348.     return 0;
    349. 

  349. }
    350. 

  350. 

  351. int dfs_elm_open(struct dfs_file *file)
    352. 

  352. {
    353. 

  353.     FIL *fd;
    354. 

  354.     BYTE mode;
    355. 

  355.     FRESULT result;
    356. 

  356.     char *drivers_fn;
    357. 

  357. 

  358. #if (FF_VOLUMES > 1)
    359. 

  359.     int vol;
    360. 

  360.     struct dfs_mnt *mnt = file->vnode->mnt;
    361. 

  361.     extern int elm_get_vol(FATFS * fat);
    362. 

  362. 

  363.     RT_ASSERT(file->vnode->ref_count > 0);
    364. 

  364.     if (file->vnode->ref_count > 1)
    365. 

  365.     {
    366. 

  366.         if (file->vnode->type == FT_DIRECTORY
    367. 

  367.                 && !(file->flags & O_DIRECTORY))
    368. 

  368.         {
    369. 

  369.             return -ENOENT;
    370. 

  370.         }
    371. 

  371.         file->fpos = 0;
    372. 

  372.         return 0;
    373. 

  373.     }
    374. 

  374. 

  375.     if (mnt == NULL)
    376. 

  376.         return -ENOENT;
    377. 

  377. 

  378.     /* add path for ELM FatFS driver support */
    379. 

  379.     vol = elm_get_vol((FATFS *)mnt->data);
    380. 

  380.     if (vol < 0)
    381. 

  381.         return -ENOENT;
    382. 

  382.     drivers_fn = (char *)rt_malloc(256);
    383. 

  383.     if (drivers_fn == RT_NULL)
    384. 

  384.         return -ENOMEM;
    385. 

  385. 

  386.     rt_snprintf(drivers_fn, 256, "%d:%s", vol, file->dentry->pathname);
    387. 

  387. #else
    388. 

  388.     drivers_fn = file->dentry->pathname;
    389. 

  389. #endif
    390. 

  390. 

  391.     if (file->flags & O_DIRECTORY)
    392. 

  392.     {
    393. 

  393.         DIR *dir;
    394. 

  394. 

  395.         if (file->flags & O_CREAT)
    396. 

  396.         {
    397. 

  397.             result = f_mkdir(drivers_fn);
    398. 

  398.             if (result != FR_OK)
    399. 

  399.             {
    400. 

  400. #if FF_VOLUMES > 1
    401. 

  401.                 rt_free(drivers_fn);
    402. 

  402. #endif
    403. 

  403.                 return elm_result_to_dfs(result);
    404. 

  404.             }
    405. 

  405.         }
    406. 

  406. 

  407.         /* open directory */
    408. 

  408.         dir = (DIR *)rt_malloc(sizeof(DIR));
    409. 

  409.         if (dir == RT_NULL)
    410. 

  410.         {
    411. 

  411. #if FF_VOLUMES > 1
    412. 

  412.             rt_free(drivers_fn);
    413. 

  413. #endif
    414. 

  414.             return -ENOMEM;
    415. 

  415.         }
    416. 

  416. 

  417.         result = f_opendir(dir, drivers_fn);
    418. 

  418. #if FF_VOLUMES > 1
    419. 

  419.         rt_free(drivers_fn);
    420. 

  420. #endif
    421. 

  421.         if (result != FR_OK)
    422. 

  422.         {
    423. 

  423.             rt_free(dir);
    424. 

  424.             return elm_result_to_dfs(result);
    425. 

  425.         }
    426. 

  426. 

  427.         file->vnode->data = dir;
    428. 

  428.         return RT_EOK;
    429. 

  429.     }
    430. 

  430.     else
    431. 

  431.     {
    432. 

  432.         mode = FA_READ;
    433. 

  433. 

  434.         if (file->flags & O_WRONLY)
    435. 

  435.             mode |= FA_WRITE;
    436. 

  436.         if ((file->flags & O_ACCMODE) & O_RDWR)
    437. 

  437.             mode |= FA_WRITE;
    438. 

  438.         /* Opens the file, if it is existing. If not, a new file is created. */
    439. 

  439.         if (file->flags & O_CREAT)
    440. 

  440.             mode |= FA_OPEN_ALWAYS;
    441. 

  441.         /* Creates a new file. If the file is existing, it is truncated and overwritten. */
    442. 

  442.         if (file->flags & O_TRUNC)
    443. 

  443.             mode |= FA_CREATE_ALWAYS;
    444. 

  444.         /* Creates a new file. The function fails if the file is already existing. */
    445. 

  445.         if (file->flags & O_EXCL)
    446. 

  446.             mode |= FA_CREATE_NEW;
    447. 

  447. 

  448.         /* allocate a fd */
    449. 

  449.         fd = (FIL *)rt_malloc(sizeof(FIL));
    450. 

  450.         if (fd == RT_NULL)
    451. 

  451.         {
    452. 

  452. #if FF_VOLUMES > 1
    453. 

  453.             rt_free(drivers_fn);
    454. 

  454. #endif
    455. 

  455.             return -ENOMEM;
    456. 

  456.         }
    457. 

  457. 

  458.         result = f_open(fd, drivers_fn, mode);
    459. 

  459. #if FF_VOLUMES > 1
    460. 

  460.         rt_free(drivers_fn);
    461. 

  461. #endif
    462. 

  462.         if (result == FR_OK)
    463. 

  463.         {
    464. 

  464.             file->fpos  = fd->fptr;
    465. 

  465.             file->vnode->size = f_size(fd);
    466. 

  466.             file->vnode->type = FT_REGULAR;
    467. 

  467.             file->vnode->data = fd;
    468. 

  468. 

  469.             if (file->flags & O_APPEND)
    470. 

  470.             {
    471. 

  471.                 /* seek to the end of file */
    472. 

  472.                 f_lseek(fd, f_size(fd));
    473. 

  473.                 file->fpos = fd->fptr;
    474. 

  474.             }
    475. 

  475.         }
    476. 

  476.         else
    477. 

  477.         {
    478. 

  478.             /* open failed, return */
    479. 

  479.             rt_free(fd);
    480. 

  480.             return elm_result_to_dfs(result);
    481. 

  481.         }
    482. 

  482.     }
    483. 

  483. 

  484.     return RT_EOK;
    485. 

  485. }
    486. 

  486. 

  487. int dfs_elm_close(struct dfs_file *file)
    488. 

  488. {
    489. 

  489.     FRESULT result;
    490. 

  490. 

  491.     RT_ASSERT(file->vnode->ref_count > 0);
    492. 

  492.     if (file->vnode->ref_count > 1)
    493. 

  493.     {
    494. 

  494.         return 0;
    495. 

  495.     }
    496. 

  496.     result = FR_OK;
    497. 

  497.     if (file->vnode->type == FT_DIRECTORY)
    498. 

  498.     {
    499. 

  499.         DIR *dir = RT_NULL;
    500. 

  500. 

  501.         dir = (DIR *)(file->vnode->data);
    502. 

  502.         RT_ASSERT(dir != RT_NULL);
    503. 

  503. 

  504.         /* release memory */
    505. 

  505.         rt_free(dir);
    506. 

  506.     }
    507. 

  507.     else if (file->vnode->type == FT_REGULAR)
    508. 

  508.     {
    509. 

  509.         FIL *fd = RT_NULL;
    510. 

  510.         fd = (FIL *)(file->vnode->data);
    511. 

  511.         RT_ASSERT(fd != RT_NULL);
    512. 

  512. 

  513.         result = f_close(fd);
    514. 

  514.         if (result == FR_OK)
    515. 

  515.         {
    516. 

  516.             /* release memory */
    517. 

  517.             rt_free(fd);
    518. 

  518.         }
    519. 

  519.     }
    520. 

  520. 

  521.     return elm_result_to_dfs(result);
    522. 

  522. }
    523. 

  523. 

  524. int dfs_elm_ioctl(struct dfs_file *file, int cmd, void *args)
    525. 

  525. {
    526. 

  526.     switch (cmd)
    527. 

  527.     {
    528. 

  528.     case RT_FIOFTRUNCATE:
    529. 

  529.         {
    530. 

  530.             FIL *fd;
    531. 

  531.             FSIZE_t fptr, length;
    532. 

  532.             FRESULT result = FR_OK;
    533. 

  533.             fd = (FIL *)(file->vnode->data);
    534. 

  534.             RT_ASSERT(fd != RT_NULL);
    535. 

  535. 

  536.             /* save file read/write point */
    537. 

  537.             fptr = fd->fptr;
    538. 

  538.             length = *(off_t*)args;
    539. 

  539.             if (length <= fd->obj.objsize)
    540. 

  540.             {
    541. 

  541.                 fd->fptr = length;
    542. 

  542.                 result = f_truncate(fd);
    543. 

  543.             }
    544. 

  544.             else
    545. 

  545.             {
    546. 

  546.                 result = f_lseek(fd, length);
    547. 

  547.             }
    548. 

  548.             /* restore file read/write point */
    549. 

  549.             fd->fptr = fptr;
    550. 

  550.             return elm_result_to_dfs(result);
    551. 

  551.         }
    552. 

  552.     case F_GETLK:
    553. 

  553.             return 0;
    554. 

  554.     case F_SETLK:
    555. 

  555.             return 0;
    556. 

  556.     }
    557. 

  557.     return -ENOSYS;
    558. 

  558. }
    559. 

  559. 

  560. int dfs_elm_read(struct dfs_file *file, void *buf, size_t len, off_t *pos)
    561. 

  561. {
    562. 

  562.     FIL *fd;
    563. 

  563.     FRESULT result;
    564. 

  564.     UINT byte_read;
    565. 

  565. 

  566.     if (file->vnode->type == FT_DIRECTORY)
    567. 

  567.     {
    568. 

  568.         return -EISDIR;
    569. 

  569.     }
    570. 

  570. 

  571.     fd = (FIL *)(file->vnode->data);
    572. 

  572.     RT_ASSERT(fd != RT_NULL);
    573. 

  573. 

  574.     result = f_read(fd, buf, len, &byte_read);
    575. 

  575.     /* update position */
    576. 

  576.     file->fpos  = fd->fptr;
    577. 

  577.     *pos = file->fpos;
    578. 

  578.     if (result == FR_OK)
    579. 

  579.         return byte_read;
    580. 

  580. 

  581.     return elm_result_to_dfs(result);
    582. 

  582. }
    583. 

  583. 

  584. int dfs_elm_write(struct dfs_file *file, const void *buf, size_t len, off_t *pos)
    585. 

  585. {
    586. 

  586.     FIL *fd;
    587. 

  587.     FRESULT result;
    588. 

  588.     UINT byte_write;
    589. 

  589. 

  590.     if (file->vnode->type == FT_DIRECTORY)
    591. 

  591.     {
    592. 

  592.         return -EISDIR;
    593. 

  593.     }
    594. 

  594. 

  595.     fd = (FIL *)(file->vnode->data);
    596. 

  596.     RT_ASSERT(fd != RT_NULL);
    597. 

  597. 

  598.     result = f_write(fd, buf, len, &byte_write);
    599. 

  599.     /* update position and file size */
    600. 

  600.     file->fpos  = fd->fptr;
    601. 

  601.     *pos = file->fpos;
    602. 

  602.     file->vnode->size = f_size(fd);
    603. 

  603.     if (result == FR_OK)
    604. 

  604.         return byte_write;
    605. 

  605. 

  606.     return elm_result_to_dfs(result);
    607. 

  607. }
    608. 

  608. 

  609. int dfs_elm_flush(struct dfs_file *file)
    610. 

  610. {
    611. 

  611.     FIL *fd;
    612. 

  612.     FRESULT result;
    613. 

  613. 

  614.     fd = (FIL *)(file->vnode->data);
    615. 

  615.     RT_ASSERT(fd != RT_NULL);
    616. 

  616. 

  617.     result = f_sync(fd);
    618. 

  618.     return elm_result_to_dfs(result);
    619. 

  619. }
    620. 

  620. 

  621. int dfs_elm_lseek(struct dfs_file *file, off_t offset, int wherece)
    622. 

  622. {
    623. 

  623.     FRESULT result = FR_OK;
    624. 

  624.     if (file->vnode->type == FT_REGULAR)
    625. 

  625.     {
    626. 

  626.         FIL *fd;
    627. 

  627. 

  628.         /* regular file type */
    629. 

  629.         fd = (FIL *)(file->vnode->data);
    630. 

  630.         RT_ASSERT(fd != RT_NULL);
    631. 

  631. 

  632.         result = f_lseek(fd, offset);
    633. 

  633.         if (result == FR_OK)
    634. 

  634.         {
    635. 

  635.             /* return current position */
    636. 

  636.             file->fpos = fd->fptr;
    637. 

  637.             return fd->fptr;
    638. 

  638.         }
    639. 

  639.     }
    640. 

  640.     else if (file->vnode->type == FT_DIRECTORY)
    641. 

  641.     {
    642. 

  642.         /* which is a directory */
    643. 

  643.         DIR *dir = RT_NULL;
    644. 

  644. 

  645.         dir = (DIR *)(file->vnode->data);
    646. 

  646.         RT_ASSERT(dir != RT_NULL);
    647. 

  647. 

  648.         result = f_seekdir(dir, offset / sizeof(struct dirent));
    649. 

  649.         if (result == FR_OK)
    650. 

  650.         {
    651. 

  651.             /* update file position */
    652. 

  652.             file->fpos = offset;
    653. 

  653.             return file->fpos;
    654. 

  654.         }
    655. 

  655.     }
    656. 

  656. 

  657.     return elm_result_to_dfs(result);
    658. 

  658. }
    659. 

  659. 

  660. int dfs_elm_getdents(struct dfs_file *file, struct dirent *dirp, uint32_t count)
    661. 

  661. {
    662. 

  662.     DIR *dir;
    663. 

  663.     FILINFO fno;
    664. 

  664.     FRESULT result;
    665. 

  665.     rt_uint32_t index;
    666. 

  666.     struct dirent *d;
    667. 

  667. 

  668.     dir = (DIR *)(file->vnode->data);
    669. 

  669.     RT_ASSERT(dir != RT_NULL);
    670. 

  670. 

  671.     /* make integer count */
    672. 

  672.     count = (count / sizeof(struct dirent)) * sizeof(struct dirent);
    673. 

  673.     if (count == 0)
    674. 

  674.         return -EINVAL;
    675. 

  675. 

  676.     index = 0;
    677. 

  677.     while (1)
    678. 

  678.     {
    679. 

  679.         char *fn;
    680. 

  680. 

  681.         d = dirp + index;
    682. 

  682. 

  683.         result = f_readdir(dir, &fno);
    684. 

  684.         if (result != FR_OK || fno.fname[0] == 0)
    685. 

  685.             break;
    686. 

  686. 

  687. #if FF_USE_LFN
    688. 

  688.         fn = *fno.fname ? fno.fname : fno.altname;
    689. 

  689. #else
    690. 

  690.         fn = fno.fname;
    691. 

  691. #endif
    692. 

  692. 

  693.         d->d_type = DT_UNKNOWN;
    694. 

  694.         if (fno.fattrib & AM_DIR)
    695. 

  695.             d->d_type = DT_DIR;
    696. 

  696.         else
    697. 

  697.             d->d_type = DT_REG;
    698. 

  698. 

  699.         d->d_namlen = (rt_uint8_t)rt_strlen(fn);
    700. 

  700.         d->d_reclen = (rt_uint16_t)sizeof(struct dirent);
    701. 

  701.         rt_strncpy(d->d_name, fn, DFS_PATH_MAX);
    702. 

  702. 

  703.         index ++;
    704. 

  704.         if (index * sizeof(struct dirent) >= count)
    705. 

  705.             break;
    706. 

  706.     }
    707. 

  707. 

  708.     if (index == 0)
    709. 

  709.         return elm_result_to_dfs(result);
    710. 

  710. 

  711.     file->fpos += index * sizeof(struct dirent);
    712. 

  712. 

  713.     return index * sizeof(struct dirent);
    714. 

  714. }
    715. 

  715. 

  716. int dfs_elm_unlink(struct dfs_dentry *dentry)
    717. 

  717. {
    718. 

  718.     FRESULT result;
    719. 

  719. 

  720. #if FF_VOLUMES > 1
    721. 

  721.     int vol;
    722. 

  722.     char *drivers_fn;
    723. 

  723.     extern int elm_get_vol(FATFS * fat);
    724. 

  724. 

  725.     /* add path for ELM FatFS driver support */
    726. 

  726.     vol = elm_get_vol((FATFS *)dentry->mnt->data);
    727. 

  727.     if (vol < 0)
    728. 

  728.         return -ENOENT;
    729. 

  729.     drivers_fn = (char *)rt_malloc(256);
    730. 

  730.     if (drivers_fn == RT_NULL)
    731. 

  731.         return -ENOMEM;
    732. 

  732. 

  733.     rt_snprintf(drivers_fn, 256, "%d:%s", vol, dentry->pathname);
    734. 

  734. #else
    735. 

  735.     const char *drivers_fn;
    736. 

  736.     drivers_fn = path;
    737. 

  737. #endif
    738. 

  738. 

  739.     result = f_unlink(drivers_fn);
    740. 

  740. #if FF_VOLUMES > 1
    741. 

  741.     rt_free(drivers_fn);
    742. 

  742. #endif
    743. 

  743.     return elm_result_to_dfs(result);
    744. 

  744. }
    745. 

  745. 

  746. int dfs_elm_rename(struct dfs_dentry *old_dentry, struct dfs_dentry *new_dentry)
    747. 

  747. {
    748. 

  748.     FRESULT result;
    749. 

  749. 

  750. #if FF_VOLUMES > 1
    751. 

  751.     char *drivers_oldfn;
    752. 

  752.     const char *drivers_newfn;
    753. 

  753.     int vol;
    754. 

  754.     extern int elm_get_vol(FATFS * fat);
    755. 

  755. 

  756.     /* add path for ELM FatFS driver support */
    757. 

  757.     vol = elm_get_vol((FATFS *)old_dentry->mnt->data);
    758. 

  758.     if (vol < 0)
    759. 

  759.         return -ENOENT;
    760. 

  760. 

  761.     drivers_oldfn = (char *)rt_malloc(256);
    762. 

  762.     if (drivers_oldfn == RT_NULL)
    763. 

  763.         return -ENOMEM;
    764. 

  764.     drivers_newfn = new_dentry->pathname;
    765. 

  765. 

  766.     rt_snprintf(drivers_oldfn, 256, "%d:%s", vol, old_dentry->pathname);
    767. 

  767. #else
    768. 

  768.     const char *drivers_oldfn, *drivers_newfn;
    769. 

  769. 

  770.     drivers_oldfn = old_dentry->pathname;
    771. 

  771.     drivers_newfn = new_dentry->pathname;
    772. 

  772. #endif
    773. 

  773. 

  774.     result = f_rename(drivers_oldfn, drivers_newfn);
    775. 

  775. #if FF_VOLUMES > 1
    776. 

  776.     rt_free(drivers_oldfn);
    777. 

  777. #endif
    778. 

  778.     return elm_result_to_dfs(result);
    779. 

  779. }
    780. 

  780. 

  781. int dfs_elm_stat(struct dfs_dentry *dentry, struct stat *st)
    782. 

  782. {
    783. 

  783.     FATFS  *fat;
    784. 

  784.     FILINFO file_info;
    785. 

  785.     FRESULT result;
    786. 

  786. 

  787.     fat = (FATFS *)dentry->mnt->data;
    788. 

  788. 

  789. #if FF_VOLUMES > 1
    790. 

  790.     int vol;
    791. 

  791.     char *drivers_fn;
    792. 

  792.     extern int elm_get_vol(FATFS * fat);
    793. 

  793. 

  794.     /* add path for ELM FatFS driver support */
    795. 

  795.     vol = elm_get_vol(fat);
    796. 

  796.     if (vol < 0)
    797. 

  797.         return -ENOENT;
    798. 

  798.     drivers_fn = (char *)rt_malloc(256);
    799. 

  799.     if (drivers_fn == RT_NULL)
    800. 

  800.         return -ENOMEM;
    801. 

  801. 

  802.     rt_snprintf(drivers_fn, 256, "%d:%s", vol, dentry->pathname);
    803. 

  803. #else
    804. 

  804.     const char *drivers_fn;
    805. 

  805.     drivers_fn = dentry->pathname;
    806. 

  806. #endif
    807. 

  807. 

  808.     result = f_stat(drivers_fn, &file_info);
    809. 

  809. #if FF_VOLUMES > 1
    810. 

  810.     rt_free(drivers_fn);
    811. 

  811. #endif
    812. 

  812.     if (result == FR_OK)
    813. 

  813.     {
    814. 

  814.         /* convert to dfs stat structure */
    815. 

  815.         st->st_dev = (dev_t)(size_t)(dentry->mnt->dev_id);
    816. 

  816.         st->st_ino = (ino_t)dfs_dentry_full_path_crc32(dentry);
    817. 

  817. 

  818.         st->st_mode = S_IFREG | S_IRUSR | S_IRGRP | S_IROTH |
    819. 

  819.                       S_IWUSR | S_IWGRP | S_IWOTH;
    820. 

  820.         if (file_info.fattrib & AM_DIR)
    821. 

  821.         {
    822. 

  822.             st->st_mode &= ~S_IFREG;
    823. 

  823.             st->st_mode |= S_IFDIR | S_IXUSR | S_IXGRP | S_IXOTH;
    824. 

  824.         }
    825. 

  825.         if (file_info.fattrib & AM_RDO)
    826. 

  826.             st->st_mode &= ~(S_IWUSR | S_IWGRP | S_IWOTH);
    827. 

  827. 

  828.         st->st_size  = file_info.fsize;
    829. 

  829.         st->st_blksize = fat->csize * SS(fat);
    830. 

  830.         if (file_info.fattrib & AM_ARC)
    831. 

  831.         {
    832. 

  832.             st->st_blocks = file_info.fsize ? ((file_info.fsize - 1) / SS(fat) / fat->csize + 1) : 0;
    833. 

  833.             st->st_blocks *= (st->st_blksize / 512);  // man say st_blocks is number of 512B blocks allocated
    834. 

  834.         }
    835. 

  835.         else
    836. 

  836.         {
    837. 

  837.             st->st_blocks = fat->csize;
    838. 

  838.         }
    839. 

  839.         /* get st_mtime. */
    840. 

  840.         {
    841. 

  841.             struct tm tm_file;
    842. 

  842.             int year, mon, day, hour, min, sec;
    843. 

  843.             WORD tmp;
    844. 

  844. 

  845.             tmp = file_info.fdate;
    846. 

  846.             day = tmp & 0x1F;           /* bit[4:0] Day(1..31) */
    847. 

  847.             tmp >>= 5;
    848. 

  848.             mon = tmp & 0x0F;           /* bit[8:5] Month(1..12) */
    849. 

  849.             tmp >>= 4;
    850. 

  850.             year = (tmp & 0x7F) + 1980; /* bit[15:9] Year origin from 1980(0..127) */
    851. 

  851. 

  852.             tmp = file_info.ftime;
    853. 

  853.             sec = (tmp & 0x1F) * 2;     /* bit[4:0] Second/2(0..29) */
    854. 

  854.             tmp >>= 5;
    855. 

  855.             min = tmp & 0x3F;           /* bit[10:5] Minute(0..59) */
    856. 

  856.             tmp >>= 6;
    857. 

  857.             hour = tmp & 0x1F;          /* bit[15:11] Hour(0..23) */
    858. 

  858. 

  859.             rt_memset(&tm_file, 0, sizeof(tm_file));
    860. 

  860.             tm_file.tm_year = year - 1900; /* Years since 1900 */
    861. 

  861.             tm_file.tm_mon  = mon - 1;     /* Months *since* january: 0-11 */
    862. 

  862.             tm_file.tm_mday = day;         /* Day of the month: 1-31 */
    863. 

  863.             tm_file.tm_hour = hour;        /* Hours since midnight: 0-23 */
    864. 

  864.             tm_file.tm_min  = min;         /* Minutes: 0-59 */
    865. 

  865.             tm_file.tm_sec  = sec;         /* Seconds: 0-59 */
    866. 

  866. 

  867.             st->st_mtime = timegm(&tm_file);
    868. 

  868.         } /* get st_mtime. */
    869. 

  869.     }
    870. 

  870. 

  871.     return elm_result_to_dfs(result);
    872. 

  872. }
    873. 

  873. 

  874. static struct dfs_vnode *dfs_elm_lookup(struct dfs_dentry *dentry)
    875. 

  875. {
    876. 

  876.     struct stat st;
    877. 

  877.     struct dfs_vnode *vnode = RT_NULL;
    878. 

  878. 

  879.     if (dentry == NULL || dentry->mnt == NULL || dentry->mnt->data == NULL)
    880. 

  880.     {
    881. 

  881.         return NULL;
    882. 

  882.     }
    883. 

  883. 

  884.     if (dfs_elm_stat(dentry, &st) != 0)
    885. 

  885.     {
    886. 

  886.         return vnode;
    887. 

  887.     }
    888. 

  888. 

  889.     vnode = dfs_vnode_create();
    890. 

  890.     if (vnode)
    891. 

  891.     {
    892. 

  892.         if (S_ISDIR(st.st_mode))
    893. 

  893.         {
    894. 

  894.             vnode->mode = S_IFDIR | (S_IRUSR | S_IWUSR | S_IRGRP | S_IWGRP | S_IROTH | S_IWOTH);
    895. 

  895.             vnode->type = FT_DIRECTORY;
    896. 

  896.         }
    897. 

  897.         else
    898. 

  898.         {
    899. 

  899.             vnode->mode = S_IFREG | (S_IRUSR | S_IWUSR | S_IRGRP | S_IWGRP | S_IROTH | S_IWOTH);
    900. 

  900.             vnode->type = FT_REGULAR;
    901. 

  901.         }
    902. 

  902. 

  903.         vnode->mnt = dentry->mnt;
    904. 

  904.         vnode->data = NULL;
    905. 

  905.         vnode->size = 0;
    906. 

  906.     }
    907. 

  907. 

  908.     return vnode;
    909. 

  909. }
    910. 

  910. 

  911. static struct dfs_vnode *dfs_elm_create_vnode(struct dfs_dentry *dentry, int type, mode_t mode)
    912. 

  912. {
    913. 

  913.     struct dfs_vnode *vnode = RT_NULL;
    914. 

  914. 

  915.     if (dentry == NULL || dentry->mnt == NULL || dentry->mnt->data == NULL)
    916. 

  916.     {
    917. 

  917.         return NULL;
    918. 

  918.     }
    919. 

  919. 

  920.     vnode = dfs_vnode_create();
    921. 

  921.     if (vnode)
    922. 

  922.     {
    923. 

  923.         if (type == FT_DIRECTORY)
    924. 

  924.         {
    925. 

  925.             vnode->mode = S_IFDIR | mode;
    926. 

  926.             vnode->type = FT_DIRECTORY;
    927. 

  927.         }
    928. 

  928.         else
    929. 

  929.         {
    930. 

  930. 

  931.             vnode->mode = S_IFREG | mode;
    932. 

  932.             vnode->type = FT_REGULAR;
    933. 

  933.         }
    934. 

  934. 

  935.         vnode->mnt = dentry->mnt;
    936. 

  936.         vnode->data = NULL;
    937. 

  937.         vnode->size = 0;
    938. 

  938.     }
    939. 

  939. 

  940.     return vnode;
    941. 

  941. }
    942. 

  942. 

  943. static int dfs_elm_free_vnode(struct dfs_vnode *vnode)
    944. 

  944. {
    945. 

  945.     /* nothing to be freed */
    946. 

  946.     if (vnode && vnode->ref_count <= 1)
    947. 

  947.     {
    948. 

  948.         vnode->data = NULL;
    949. 

  949.     }
    950. 

  950. 

  951.     return 0;
    952. 

  952. }
    953. 

  953. 

  954. static const struct dfs_file_ops dfs_elm_fops =
    955. 

  955. {
    956. 

  956.     .open = dfs_elm_open,
    957. 

  957.     .close = dfs_elm_close,
    958. 

  958.     .ioctl = dfs_elm_ioctl,
    959. 

  959.     .read = dfs_elm_read,
    960. 

  960.     .write = dfs_elm_write,
    961. 

  961.     .flush = dfs_elm_flush,
    962. 

  962.     .lseek = dfs_elm_lseek,
    963. 

  963.     .getdents = dfs_elm_getdents,
    964. 

  964. };
    965. 

  965. 

  966. static const struct dfs_filesystem_ops dfs_elm =
    967. 

  967. {
    968. 

  968.     "elm",
    969. 

  969.     FS_NEED_DEVICE,
    970. 

  970.     &dfs_elm_fops,
    971. 

  971. 

  972.     .mount = dfs_elm_mount,
    973. 

  973.     .umount = dfs_elm_unmount,
    974. 

  974.     .mkfs = dfs_elm_mkfs,
    975. 

  975.     .statfs = dfs_elm_statfs,
    976. 

  976. 

  977.     .unlink = dfs_elm_unlink,
    978. 

  978.     .stat = dfs_elm_stat,
    979. 

  979.     .rename = dfs_elm_rename,
    980. 

  980. 

  981.     .lookup = dfs_elm_lookup,
    982. 

  982.     .create_vnode = dfs_elm_create_vnode,
    983. 

  983.     .free_vnode = dfs_elm_free_vnode
    984. 

  984. };
    985. 

  985. 

  986. static struct dfs_filesystem_type _elmfs =
    987. 

  987. {
    988. 

  988.     .fs_ops = &dfs_elm,
    989. 

  989. };
    990. 

  990. 

  991. int elm_init(void)
    992. 

  992. {
    993. 

  993.     /* register fatfs file system */
    994. 

  994.     dfs_register(&_elmfs);
    995. 

  995. 

  996.     return 0;
    997. 

  997. }
    998. 

  998. INIT_COMPONENT_EXPORT(elm_init);
    999. 

  999. 

  1000. /*
    1001. 

  1001.  * RT-Thread Device Interface for ELM FatFs
    1002. 

  1002.  */
    1003. 

  1003. #include "diskio.h"
    1004. 

  1004. 

  1005. /* Initialize a Drive */
    1006. 

  1006. DSTATUS disk_initialize(BYTE drv)
    1007. 

  1007. {
    1008. 

  1008.     return 0;
    1009. 

  1009. }
    1010. 

  1010. 

  1011. /* Return Disk Status */
    1012. 

  1012. DSTATUS disk_status(BYTE drv)
    1013. 

  1013. {
    1014. 

  1014.     return 0;
    1015. 

  1015. }
    1016. 

  1016. 

  1017. /* Read Sector(s) */
    1018. 

  1018. DRESULT disk_read(BYTE drv, BYTE *buff, DWORD sector, UINT count)
    1019. 

  1019. {
    1020. 

  1020.     rt_size_t result;
    1021. 

  1021.     rt_device_t device = disk[drv];
    1022. 

  1022. 

  1023.     result = rt_device_read(device, sector, buff, count);
    1024. 

  1024.     if (result == count)
    1025. 

  1025.     {
    1026. 

  1026.         return RES_OK;
    1027. 

  1027.     }
    1028. 

  1028. 

  1029.     return RES_ERROR;
    1030. 

  1030. }
    1031. 

  1031. 

  1032. /* Write Sector(s) */
    1033. 

  1033. DRESULT disk_write(BYTE drv, const BYTE *buff, DWORD sector, UINT count)
    1034. 

  1034. {
    1035. 

  1035.     rt_size_t result;
    1036. 

  1036.     rt_device_t device = disk[drv];
    1037. 

  1037. 

  1038.     result = rt_device_write(device, sector, buff, count);
    1039. 

  1039.     if (result == count)
    1040. 

  1040.     {
    1041. 

  1041.         return RES_OK;
    1042. 

  1042.     }
    1043. 

  1043. 

  1044.     return RES_ERROR;
    1045. 

  1045. }
    1046. 

  1046. 

  1047. /* Miscellaneous Functions */
    1048. 

  1048. DRESULT disk_ioctl(BYTE drv, BYTE ctrl, void *buff)
    1049. 

  1049. {
    1050. 

  1050.     rt_device_t device = disk[drv];
    1051. 

  1051. 

  1052.     if (device == RT_NULL)
    1053. 

  1053.         return RES_ERROR;
    1054. 

  1054. 

  1055.     if (ctrl == GET_SECTOR_COUNT)
    1056. 

  1056.     {
    1057. 

  1057.         struct rt_device_blk_geometry geometry;
    1058. 

  1058. 

  1059.         rt_memset(&geometry, 0, sizeof(geometry));
    1060. 

  1060.         rt_device_control(device, RT_DEVICE_CTRL_BLK_GETGEOME, &geometry);
    1061. 

  1061. 

  1062.         *(DWORD *)buff = geometry.sector_count;
    1063. 

  1063.         if (geometry.sector_count == 0)
    1064. 

  1064.             return RES_ERROR;
    1065. 

  1065.     }
    1066. 

  1066.     else if (ctrl == GET_SECTOR_SIZE)
    1067. 

  1067.     {
    1068. 

  1068.         struct rt_device_blk_geometry geometry;
    1069. 

  1069. 

  1070.         rt_memset(&geometry, 0, sizeof(geometry));
    1071. 

  1071.         rt_device_control(device, RT_DEVICE_CTRL_BLK_GETGEOME, &geometry);
    1072. 

  1072. 

  1073.         *(WORD *)buff = (WORD)(geometry.bytes_per_sector);
    1074. 

  1074.     }
    1075. 

  1075.     else if (ctrl == GET_BLOCK_SIZE) /* Get erase block size in unit of sectors (DWORD) */
    1076. 

  1076.     {
    1077. 

  1077.         struct rt_device_blk_geometry geometry;
    1078. 

  1078. 

  1079.         rt_memset(&geometry, 0, sizeof(geometry));
    1080. 

  1080.         rt_device_control(device, RT_DEVICE_CTRL_BLK_GETGEOME, &geometry);
    1081. 

  1081. 

  1082.         *(DWORD *)buff = geometry.block_size / geometry.bytes_per_sector;
    1083. 

  1083.     }
    1084. 

  1084.     else if (ctrl == CTRL_SYNC)
    1085. 

  1085.     {
    1086. 

  1086.         rt_device_control(device, RT_DEVICE_CTRL_BLK_SYNC, RT_NULL);
    1087. 

  1087.     }
    1088. 

  1088.     else if (ctrl == CTRL_TRIM)
    1089. 

  1089.     {
    1090. 

  1090.         rt_device_control(device, RT_DEVICE_CTRL_BLK_ERASE, buff);
    1091. 

  1091.     }
    1092. 

  1092. 

  1093.     return RES_OK;
    1094. 

  1094. }
    1095. 

  1095. 

  1096. DWORD get_fattime(void)
    1097. 

  1097. {
    1098. 

  1098.     DWORD fat_time = 0;
    1099. 

  1099.     time_t now;
    1100. 

  1100.     struct tm tm_now;
    1101. 

  1101. 

  1102.     now = time(RT_NULL);
    1103. 

  1103.     gmtime_r(&now, &tm_now);
    1104. 

  1104. 

  1105.     fat_time = (DWORD)(tm_now.tm_year - 80) << 25 |
    1106. 

  1106.                (DWORD)(tm_now.tm_mon + 1)   << 21 |
    1107. 

  1107.                (DWORD)tm_now.tm_mday        << 16 |
    1108. 

  1108.                (DWORD)tm_now.tm_hour        << 11 |
    1109. 

  1109.                (DWORD)tm_now.tm_min         <<  5 |
    1110. 

  1110.                (DWORD)tm_now.tm_sec / 2 ;
    1111. 

  1111. 

  1112.     return fat_time;
    1113. 

  1113. }
    1114. 

  1114. 

  1115. #if FF_FS_REENTRANT
    1116. 

  1116. int ff_cre_syncobj(BYTE drv, FF_SYNC_t *m)
    1117. 

  1117. {
    1118. 

  1118.     char name[8];
    1119. 

  1119.     rt_mutex_t mutex;
    1120. 

  1120. 

  1121.     rt_snprintf(name, sizeof(name), "fat%d", drv);
    1122. 

  1122.     mutex = rt_mutex_create(name, RT_IPC_FLAG_PRIO);
    1123. 

  1123.     if (mutex != RT_NULL)
    1124. 

  1124.     {
    1125. 

  1125.         *m = mutex;
    1126. 

  1126.         return RT_TRUE;
    1127. 

  1127.     }
    1128. 

  1128. 

  1129.     return RT_FALSE;
    1130. 

  1130. }
    1131. 

  1131. 

  1132. int ff_del_syncobj(FF_SYNC_t m)
    1133. 

  1133. {
    1134. 

  1134.     if (m != RT_NULL)
    1135. 

  1135.         rt_mutex_delete(m);
    1136. 

  1136. 

  1137.     return RT_TRUE;
    1138. 

  1138. }
    1139. 

  1139. 

  1140. int ff_req_grant(FF_SYNC_t m)
    1141. 

  1141. {
    1142. 

  1142.     if (rt_mutex_take(m, FF_FS_TIMEOUT) == RT_EOK)
    1143. 

  1143.         return RT_TRUE;
    1144. 

  1144. 

  1145.     return RT_FALSE;
    1146. 

  1146. }
    1147. 

  1147. 

  1148. void ff_rel_grant(FF_SYNC_t m)
    1149. 

  1149. {
    1150. 

  1150.     rt_mutex_release(m);
    1151. 

  1151. }
    1152. 

  1152. 

  1153. #endif
    1154. 

  1154. 

  1155. /* Memory functions */
    1156. 

  1156. #if FF_USE_LFN == 3
    1157. 

  1157. /* Allocate memory block */
    1158. 

  1158. void *ff_memalloc(UINT size)
    1159. 

  1159. {
    1160. 

  1160.     return rt_malloc(size);
    1161. 

  1161. }
    1162. 

  1162. 

  1163. /* Free memory block */
    1164. 

  1164. void ff_memfree(void *mem)
    1165. 

  1165. {
    1166. 

  1166.     rt_free(mem);
    1167. 

  1167. }
    1168. 

  1168. #endif /* FF_USE_LFN == 3 */
    1169. 

  1169.