// Copyright 2015-2016 Espressif Systems (Shanghai) PTE LTD // // Licensed under the Apache License, Version 2.0 (the "License"); // you may not use this file except in compliance with the License. // You may obtain a copy of the License at // // http://www.apache.org/licenses/LICENSE-2.0 // // Unless required by applicable law or agreed to in writing, software // distributed under the License is distributed on an "AS IS" BASIS, // WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. // See the License for the specific language governing permissions and // limitations under the License. #include #include #include #include #include #include #include #include "esp_vfs.h" #include "esp_log.h" #include "ff.h" #include "diskio_impl.h" typedef struct { char fat_drive[8]; /* FAT drive name */ char base_path[ESP_VFS_PATH_MAX]; /* base path in VFS where partition is registered */ size_t max_files; /* max number of simultaneously open files; size of files[] array */ _lock_t lock; /* guard for access to this structure */ FATFS fs; /* fatfs library FS structure */ char tmp_path_buf[FILENAME_MAX+3]; /* temporary buffer used to prepend drive name to the path */ char tmp_path_buf2[FILENAME_MAX+3]; /* as above; used in functions which take two path arguments */ bool *o_append; /* O_APPEND is stored here for each max_files entries (because O_APPEND is not compatible with FA_OPEN_APPEND) */ FIL files[0]; /* array with max_files entries; must be the final member of the structure */ } vfs_fat_ctx_t; typedef struct { DIR dir; long offset; FF_DIR ffdir; FILINFO filinfo; struct dirent cur_dirent; } vfs_fat_dir_t; /* Date and time storage formats in FAT */ typedef union { struct { uint16_t mday : 5; /* Day of month, 1 - 31 */ uint16_t mon : 4; /* Month, 1 - 12 */ uint16_t year : 7; /* Year, counting from 1980. E.g. 37 for 2017 */ }; uint16_t as_int; } fat_date_t; typedef union { struct { uint16_t sec : 5; /* Seconds divided by 2. E.g. 21 for 42 seconds */ uint16_t min : 6; /* Minutes, 0 - 59 */ uint16_t hour : 5; /* Hour, 0 - 23 */ }; uint16_t as_int; } fat_time_t; static const char* TAG = "vfs_fat"; static ssize_t vfs_fat_write(void* p, int fd, const void * data, size_t size); static off_t vfs_fat_lseek(void* p, int fd, off_t size, int mode); static ssize_t vfs_fat_read(void* ctx, int fd, void * dst, size_t size); static ssize_t vfs_fat_pread(void *ctx, int fd, void *dst, size_t size, off_t offset); static ssize_t vfs_fat_pwrite(void *ctx, int fd, const void *src, size_t size, off_t offset); static int vfs_fat_open(void* ctx, const char * path, int flags, int mode); static int vfs_fat_close(void* ctx, int fd); static int vfs_fat_fstat(void* ctx, int fd, struct stat * st); static int vfs_fat_fsync(void* ctx, int fd); #ifdef CONFIG_VFS_SUPPORT_DIR static int vfs_fat_stat(void* ctx, const char * path, struct stat * st); static int vfs_fat_link(void* ctx, const char* n1, const char* n2); static int vfs_fat_unlink(void* ctx, const char *path); static int vfs_fat_rename(void* ctx, const char *src, const char *dst); static DIR* vfs_fat_opendir(void* ctx, const char* name); static struct dirent* vfs_fat_readdir(void* ctx, DIR* pdir); static int vfs_fat_readdir_r(void* ctx, DIR* pdir, struct dirent* entry, struct dirent** out_dirent); static long vfs_fat_telldir(void* ctx, DIR* pdir); static void vfs_fat_seekdir(void* ctx, DIR* pdir, long offset); static int vfs_fat_closedir(void* ctx, DIR* pdir); static int vfs_fat_mkdir(void* ctx, const char* name, mode_t mode); static int vfs_fat_rmdir(void* ctx, const char* name); static int vfs_fat_access(void* ctx, const char *path, int amode); static int vfs_fat_truncate(void* ctx, const char *path, off_t length); static int vfs_fat_ftruncate(void* ctx, int fd, off_t length); static int vfs_fat_utime(void* ctx, const char *path, const struct utimbuf *times); #endif // CONFIG_VFS_SUPPORT_DIR static vfs_fat_ctx_t* s_fat_ctxs[FF_VOLUMES] = { NULL, NULL }; //backwards-compatibility with esp_vfs_fat_unregister() static vfs_fat_ctx_t* s_fat_ctx = NULL; static size_t find_context_index_by_path(const char* base_path) { for(size_t i=0; ibase_path, base_path)) { return i; } } return FF_VOLUMES; } static size_t find_unused_context_index(void) { for(size_t i=0; io_append = ff_memalloc(max_files * sizeof(bool)); if (fat_ctx->o_append == NULL) { free(fat_ctx); return ESP_ERR_NO_MEM; } memset(fat_ctx->o_append, 0, max_files * sizeof(bool)); fat_ctx->max_files = max_files; strlcpy(fat_ctx->fat_drive, fat_drive, sizeof(fat_ctx->fat_drive) - 1); strlcpy(fat_ctx->base_path, base_path, sizeof(fat_ctx->base_path) - 1); esp_err_t err = esp_vfs_register(base_path, &vfs, fat_ctx); if (err != ESP_OK) { free(fat_ctx->o_append); free(fat_ctx); return err; } _lock_init(&fat_ctx->lock); s_fat_ctxs[ctx] = fat_ctx; //compatibility s_fat_ctx = fat_ctx; *out_fs = &fat_ctx->fs; return ESP_OK; } esp_err_t esp_vfs_fat_unregister_path(const char* base_path) { size_t ctx = find_context_index_by_path(base_path); if (ctx == FF_VOLUMES) { return ESP_ERR_INVALID_STATE; } vfs_fat_ctx_t* fat_ctx = s_fat_ctxs[ctx]; esp_err_t err = esp_vfs_unregister(fat_ctx->base_path); if (err != ESP_OK) { return err; } _lock_close(&fat_ctx->lock); free(fat_ctx->o_append); free(fat_ctx); s_fat_ctxs[ctx] = NULL; return ESP_OK; } static int get_next_fd(vfs_fat_ctx_t* fat_ctx) { for (size_t i = 0; i < fat_ctx->max_files; ++i) { if (fat_ctx->files[i].obj.fs == NULL) { return (int) i; } } return -1; } static int fat_mode_conv(int m) { int res = 0; int acc_mode = m & O_ACCMODE; if (acc_mode == O_RDONLY) { res |= FA_READ; } else if (acc_mode == O_WRONLY) { res |= FA_WRITE; } else if (acc_mode == O_RDWR) { res |= FA_READ | FA_WRITE; } if ((m & O_CREAT) && (m & O_EXCL)) { res |= FA_CREATE_NEW; } else if ((m & O_CREAT) && (m & O_TRUNC)) { res |= FA_CREATE_ALWAYS; } else if (m & O_APPEND) { res |= FA_OPEN_ALWAYS; } else { res |= FA_OPEN_EXISTING; } return res; } static int fresult_to_errno(FRESULT fr) { switch(fr) { case FR_DISK_ERR: return EIO; case FR_INT_ERR: return EIO; case FR_NOT_READY: return ENODEV; case FR_NO_FILE: return ENOENT; case FR_NO_PATH: return ENOENT; case FR_INVALID_NAME: return EINVAL; case FR_DENIED: return EACCES; case FR_EXIST: return EEXIST; case FR_INVALID_OBJECT: return EBADF; case FR_WRITE_PROTECTED: return EACCES; case FR_INVALID_DRIVE: return ENXIO; case FR_NOT_ENABLED: return ENODEV; case FR_NO_FILESYSTEM: return ENODEV; case FR_MKFS_ABORTED: return EINTR; case FR_TIMEOUT: return ETIMEDOUT; case FR_LOCKED: return EACCES; case FR_NOT_ENOUGH_CORE: return ENOMEM; case FR_TOO_MANY_OPEN_FILES: return ENFILE; case FR_INVALID_PARAMETER: return EINVAL; case FR_OK: return 0; } assert(0 && "unhandled FRESULT"); return ENOTSUP; } static void file_cleanup(vfs_fat_ctx_t* ctx, int fd) { memset(&ctx->files[fd], 0, sizeof(FIL)); } /** * @brief Prepend drive letters to path names * This function returns new path path pointers, pointing to a temporary buffer * inside ctx. * @note Call this function with ctx->lock acquired. Paths are valid while the * lock is held. * @param ctx vfs_fat_ctx_t context * @param[inout] path as input, pointer to the path; as output, pointer to the new path * @param[inout] path2 as input, pointer to the path; as output, pointer to the new path */ static void prepend_drive_to_path(vfs_fat_ctx_t * ctx, const char ** path, const char ** path2){ snprintf(ctx->tmp_path_buf, sizeof(ctx->tmp_path_buf), "%s%s", ctx->fat_drive, *path); *path = ctx->tmp_path_buf; if(path2){ snprintf(ctx->tmp_path_buf2, sizeof(ctx->tmp_path_buf2), "%s%s", ((vfs_fat_ctx_t*)ctx)->fat_drive, *path2); *path2 = ctx->tmp_path_buf2; } } static int vfs_fat_open(void* ctx, const char * path, int flags, int mode) { ESP_LOGV(TAG, "%s: path=\"%s\", flags=%x, mode=%x", __func__, path, flags, mode); vfs_fat_ctx_t* fat_ctx = (vfs_fat_ctx_t*) ctx; _lock_acquire(&fat_ctx->lock); prepend_drive_to_path(fat_ctx, &path, NULL); int fd = get_next_fd(fat_ctx); if (fd < 0) { _lock_release(&fat_ctx->lock); ESP_LOGE(TAG, "open: no free file descriptors"); errno = ENFILE; return -1; } FRESULT res = f_open(&fat_ctx->files[fd], path, fat_mode_conv(flags)); if (res != FR_OK) { file_cleanup(fat_ctx, fd); _lock_release(&fat_ctx->lock); ESP_LOGD(TAG, "%s: fresult=%d", __func__, res); errno = fresult_to_errno(res); return -1; } #ifdef CONFIG_FATFS_USE_FASTSEEK FIL* file = &fat_ctx->files[fd]; //fast-seek is only allowed in read mode, since file cannot be expanded //to use it. if(!(fat_mode_conv(flags) & (FA_WRITE))) { DWORD *clmt_mem = ff_memalloc(sizeof(DWORD) * CONFIG_FATFS_FAST_SEEK_BUFFER_SIZE); if (clmt_mem == NULL) { f_close(file); file_cleanup(fat_ctx, fd); _lock_release(&fat_ctx->lock); ESP_LOGE(TAG, "open: Failed to pre-allocate CLMT buffer for fast-seek"); errno = ENOMEM; return -1; } file->cltbl = clmt_mem; file->cltbl[0] = CONFIG_FATFS_FAST_SEEK_BUFFER_SIZE; res = f_lseek(file, CREATE_LINKMAP); ESP_LOGD(TAG, "%s: fast-seek has: %s", __func__, (res == FR_OK) ? "activated" : "failed"); if(res != FR_OK) { ESP_LOGW(TAG, "%s: fast-seek not activated reason code: %d", __func__, res); //If linkmap creation fails, fallback to the non fast seek. ff_memfree(file->cltbl); file->cltbl = NULL; } } else { file->cltbl = NULL; } #endif // O_APPEND need to be stored because it is not compatible with FA_OPEN_APPEND: // - FA_OPEN_APPEND means to jump to the end of file only after open() // - O_APPEND means to jump to the end only before each write() // Other VFS drivers handles O_APPEND well (to the best of my knowledge), // therefore this flag is stored here (at this VFS level) in order to save // memory. fat_ctx->o_append[fd] = (flags & O_APPEND) == O_APPEND; _lock_release(&fat_ctx->lock); return fd; } static ssize_t vfs_fat_write(void* ctx, int fd, const void * data, size_t size) { vfs_fat_ctx_t* fat_ctx = (vfs_fat_ctx_t*) ctx; FIL* file = &fat_ctx->files[fd]; FRESULT res; if (fat_ctx->o_append[fd]) { if ((res = f_lseek(file, f_size(file))) != FR_OK) { ESP_LOGD(TAG, "%s: fresult=%d", __func__, res); errno = fresult_to_errno(res); return -1; } } unsigned written = 0; res = f_write(file, data, size, &written); if (((written == 0) && (size != 0)) && (res == 0)) { errno = ENOSPC; return -1; } if (res != FR_OK) { ESP_LOGD(TAG, "%s: fresult=%d", __func__, res); errno = fresult_to_errno(res); if (written == 0) { return -1; } } return written; } static ssize_t vfs_fat_read(void* ctx, int fd, void * dst, size_t size) { vfs_fat_ctx_t* fat_ctx = (vfs_fat_ctx_t*) ctx; FIL* file = &fat_ctx->files[fd]; unsigned read = 0; FRESULT res = f_read(file, dst, size, &read); if (res != FR_OK) { ESP_LOGD(TAG, "%s: fresult=%d", __func__, res); errno = fresult_to_errno(res); if (read == 0) { return -1; } } return read; } static ssize_t vfs_fat_pread(void *ctx, int fd, void *dst, size_t size, off_t offset) { ssize_t ret = -1; vfs_fat_ctx_t *fat_ctx = (vfs_fat_ctx_t *) ctx; _lock_acquire(&fat_ctx->lock); FIL *file = &fat_ctx->files[fd]; const off_t prev_pos = f_tell(file); FRESULT f_res = f_lseek(file, offset); if (f_res != FR_OK) { ESP_LOGD(TAG, "%s: fresult=%d", __func__, f_res); errno = fresult_to_errno(f_res); goto pread_release; } unsigned read = 0; f_res = f_read(file, dst, size, &read); if (f_res == FR_OK) { ret = read; } else { ESP_LOGD(TAG, "%s: fresult=%d", __func__, f_res); errno = fresult_to_errno(f_res); // No return yet - need to restore previous position } f_res = f_lseek(file, prev_pos); if (f_res != FR_OK) { ESP_LOGD(TAG, "%s: fresult=%d", __func__, f_res); if (ret >= 0) { errno = fresult_to_errno(f_res); } // else f_read failed so errno shouldn't be overwritten ret = -1; // in case the read was successful but the seek wasn't } pread_release: _lock_release(&fat_ctx->lock); return ret; } static ssize_t vfs_fat_pwrite(void *ctx, int fd, const void *src, size_t size, off_t offset) { ssize_t ret = -1; vfs_fat_ctx_t *fat_ctx = (vfs_fat_ctx_t *) ctx; _lock_acquire(&fat_ctx->lock); FIL *file = &fat_ctx->files[fd]; const off_t prev_pos = f_tell(file); FRESULT f_res = f_lseek(file, offset); if (f_res != FR_OK) { ESP_LOGD(TAG, "%s: fresult=%d", __func__, f_res); errno = fresult_to_errno(f_res); goto pwrite_release; } unsigned wr = 0; f_res = f_write(file, src, size, &wr); if (((wr == 0) && (size != 0)) && (f_res == 0)) { errno = ENOSPC; return -1; } if (f_res == FR_OK) { ret = wr; } else { ESP_LOGD(TAG, "%s: fresult=%d", __func__, f_res); errno = fresult_to_errno(f_res); // No return yet - need to restore previous position } f_res = f_lseek(file, prev_pos); if (f_res != FR_OK) { ESP_LOGD(TAG, "%s: fresult=%d", __func__, f_res); if (ret >= 0) { errno = fresult_to_errno(f_res); } // else f_write failed so errno shouldn't be overwritten ret = -1; // in case the write was successful but the seek wasn't } pwrite_release: _lock_release(&fat_ctx->lock); return ret; } static int vfs_fat_fsync(void* ctx, int fd) { vfs_fat_ctx_t* fat_ctx = (vfs_fat_ctx_t*) ctx; _lock_acquire(&fat_ctx->lock); FIL* file = &fat_ctx->files[fd]; FRESULT res = f_sync(file); _lock_release(&fat_ctx->lock); int rc = 0; if (res != FR_OK) { ESP_LOGD(TAG, "%s: fresult=%d", __func__, res); errno = fresult_to_errno(res); rc = -1; } return rc; } static int vfs_fat_close(void* ctx, int fd) { vfs_fat_ctx_t* fat_ctx = (vfs_fat_ctx_t*) ctx; _lock_acquire(&fat_ctx->lock); FIL* file = &fat_ctx->files[fd]; #ifdef CONFIG_FATFS_USE_FASTSEEK ff_memfree(file->cltbl); file->cltbl = NULL; #endif FRESULT res = f_close(file); file_cleanup(fat_ctx, fd); _lock_release(&fat_ctx->lock); int rc = 0; if (res != FR_OK) { ESP_LOGD(TAG, "%s: fresult=%d", __func__, res); errno = fresult_to_errno(res); rc = -1; } return rc; } static off_t vfs_fat_lseek(void* ctx, int fd, off_t offset, int mode) { vfs_fat_ctx_t* fat_ctx = (vfs_fat_ctx_t*) ctx; FIL* file = &fat_ctx->files[fd]; off_t new_pos; if (mode == SEEK_SET) { new_pos = offset; } else if (mode == SEEK_CUR) { off_t cur_pos = f_tell(file); new_pos = cur_pos + offset; } else if (mode == SEEK_END) { off_t size = f_size(file); new_pos = size + offset; } else { errno = EINVAL; return -1; } ESP_LOGD(TAG, "%s: offset=%ld, filesize:=%d", __func__, new_pos, f_size(file)); FRESULT res = f_lseek(file, new_pos); if (res != FR_OK) { ESP_LOGD(TAG, "%s: fresult=%d", __func__, res); errno = fresult_to_errno(res); return -1; } return new_pos; } static int vfs_fat_fstat(void* ctx, int fd, struct stat * st) { vfs_fat_ctx_t* fat_ctx = (vfs_fat_ctx_t*) ctx; FIL* file = &fat_ctx->files[fd]; memset(st, 0, sizeof(*st)); st->st_size = f_size(file); st->st_mode = S_IRWXU | S_IRWXG | S_IRWXO | S_IFREG; st->st_mtime = 0; st->st_atime = 0; st->st_ctime = 0; return 0; } #ifdef CONFIG_VFS_SUPPORT_DIR static inline mode_t get_stat_mode(bool is_dir) { return S_IRWXU | S_IRWXG | S_IRWXO | ((is_dir) ? S_IFDIR : S_IFREG); } static int vfs_fat_stat(void* ctx, const char * path, struct stat * st) { if (strcmp(path, "/") == 0) { /* FatFS f_stat function does not work for the drive root. * Just pretend that this is a directory. */ memset(st, 0, sizeof(*st)); st->st_mode = get_stat_mode(true); return 0; } vfs_fat_ctx_t* fat_ctx = (vfs_fat_ctx_t*) ctx; _lock_acquire(&fat_ctx->lock); prepend_drive_to_path(fat_ctx, &path, NULL); FILINFO info; FRESULT res = f_stat(path, &info); _lock_release(&fat_ctx->lock); if (res != FR_OK) { ESP_LOGD(TAG, "%s: fresult=%d", __func__, res); errno = fresult_to_errno(res); return -1; } memset(st, 0, sizeof(*st)); st->st_size = info.fsize; st->st_mode = get_stat_mode((info.fattrib & AM_DIR) != 0); fat_date_t fdate = { .as_int = info.fdate }; fat_time_t ftime = { .as_int = info.ftime }; struct tm tm = { .tm_mday = fdate.mday, .tm_mon = fdate.mon - 1, /* unlike tm_mday, tm_mon is zero-based */ .tm_year = fdate.year + 80, .tm_sec = ftime.sec * 2, .tm_min = ftime.min, .tm_hour = ftime.hour, /* FAT doesn't keep track if the time was DST or not, ask the C library * to try to figure this out. Note that this may yield incorrect result * in the hour before the DST comes in effect, when the local time can't * be converted to UTC uniquely. */ .tm_isdst = -1 }; st->st_mtime = mktime(&tm); st->st_atime = 0; st->st_ctime = 0; return 0; } static int vfs_fat_unlink(void* ctx, const char *path) { vfs_fat_ctx_t* fat_ctx = (vfs_fat_ctx_t*) ctx; _lock_acquire(&fat_ctx->lock); prepend_drive_to_path(fat_ctx, &path, NULL); FRESULT res = f_unlink(path); _lock_release(&fat_ctx->lock); if (res != FR_OK) { ESP_LOGD(TAG, "%s: fresult=%d", __func__, res); errno = fresult_to_errno(res); return -1; } return 0; } static int vfs_fat_link(void* ctx, const char* n1, const char* n2) { vfs_fat_ctx_t* fat_ctx = (vfs_fat_ctx_t*) ctx; _lock_acquire(&fat_ctx->lock); prepend_drive_to_path(fat_ctx, &n1, &n2); const size_t copy_buf_size = fat_ctx->fs.csize; FRESULT res; FIL* pf1 = (FIL*) ff_memalloc(sizeof(FIL)); FIL* pf2 = (FIL*) ff_memalloc(sizeof(FIL)); void* buf = ff_memalloc(copy_buf_size); if (buf == NULL || pf1 == NULL || pf2 == NULL) { _lock_release(&fat_ctx->lock); ESP_LOGD(TAG, "alloc failed, pf1=%p, pf2=%p, buf=%p", pf1, pf2, buf); free(pf1); free(pf2); free(buf); errno = ENOMEM; return -1; } memset(pf1, 0, sizeof(*pf1)); memset(pf2, 0, sizeof(*pf2)); res = f_open(pf1, n1, FA_READ | FA_OPEN_EXISTING); if (res != FR_OK) { _lock_release(&fat_ctx->lock); goto fail1; } res = f_open(pf2, n2, FA_WRITE | FA_CREATE_NEW); _lock_release(&fat_ctx->lock); if (res != FR_OK) { goto fail2; } size_t size_left = f_size(pf1); while (size_left > 0) { size_t will_copy = (size_left < copy_buf_size) ? size_left : copy_buf_size; size_t read; res = f_read(pf1, buf, will_copy, &read); if (res != FR_OK) { goto fail3; } else if (read != will_copy) { res = FR_DISK_ERR; goto fail3; } size_t written; res = f_write(pf2, buf, will_copy, &written); if (res != FR_OK) { goto fail3; } else if (written != will_copy) { res = FR_DISK_ERR; goto fail3; } size_left -= will_copy; } fail3: f_close(pf2); fail2: f_close(pf1); fail1: free(buf); free(pf2); free(pf1); if (res != FR_OK) { ESP_LOGD(TAG, "%s: fresult=%d", __func__, res); errno = fresult_to_errno(res); return -1; } return 0; } static int vfs_fat_rename(void* ctx, const char *src, const char *dst) { vfs_fat_ctx_t* fat_ctx = (vfs_fat_ctx_t*) ctx; _lock_acquire(&fat_ctx->lock); prepend_drive_to_path(fat_ctx, &src, &dst); FRESULT res = f_rename(src, dst); _lock_release(&fat_ctx->lock); if (res != FR_OK) { ESP_LOGD(TAG, "%s: fresult=%d", __func__, res); errno = fresult_to_errno(res); return -1; } return 0; } static DIR* vfs_fat_opendir(void* ctx, const char* name) { vfs_fat_ctx_t* fat_ctx = (vfs_fat_ctx_t*) ctx; _lock_acquire(&fat_ctx->lock); prepend_drive_to_path(fat_ctx, &name, NULL); vfs_fat_dir_t* fat_dir = ff_memalloc(sizeof(vfs_fat_dir_t)); if (!fat_dir) { _lock_release(&fat_ctx->lock); errno = ENOMEM; return NULL; } memset(fat_dir, 0, sizeof(*fat_dir)); FRESULT res = f_opendir(&fat_dir->ffdir, name); _lock_release(&fat_ctx->lock); if (res != FR_OK) { free(fat_dir); ESP_LOGD(TAG, "%s: fresult=%d", __func__, res); errno = fresult_to_errno(res); return NULL; } return (DIR*) fat_dir; } static int vfs_fat_closedir(void* ctx, DIR* pdir) { assert(pdir); vfs_fat_dir_t* fat_dir = (vfs_fat_dir_t*) pdir; FRESULT res = f_closedir(&fat_dir->ffdir); free(pdir); if (res != FR_OK) { ESP_LOGD(TAG, "%s: fresult=%d", __func__, res); errno = fresult_to_errno(res); return -1; } return 0; } static struct dirent* vfs_fat_readdir(void* ctx, DIR* pdir) { vfs_fat_dir_t* fat_dir = (vfs_fat_dir_t*) pdir; struct dirent* out_dirent; int err = vfs_fat_readdir_r(ctx, pdir, &fat_dir->cur_dirent, &out_dirent); if (err != 0) { errno = err; return NULL; } return out_dirent; } static int vfs_fat_readdir_r(void* ctx, DIR* pdir, struct dirent* entry, struct dirent** out_dirent) { assert(pdir); vfs_fat_dir_t* fat_dir = (vfs_fat_dir_t*) pdir; FRESULT res = f_readdir(&fat_dir->ffdir, &fat_dir->filinfo); if (res != FR_OK) { *out_dirent = NULL; ESP_LOGD(TAG, "%s: fresult=%d", __func__, res); return fresult_to_errno(res); } if (fat_dir->filinfo.fname[0] == 0) { // end of directory *out_dirent = NULL; return 0; } entry->d_ino = 0; if (fat_dir->filinfo.fattrib & AM_DIR) { entry->d_type = DT_DIR; } else { entry->d_type = DT_REG; } strlcpy(entry->d_name, fat_dir->filinfo.fname, sizeof(entry->d_name)); fat_dir->offset++; *out_dirent = entry; return 0; } static long vfs_fat_telldir(void* ctx, DIR* pdir) { assert(pdir); vfs_fat_dir_t* fat_dir = (vfs_fat_dir_t*) pdir; return fat_dir->offset; } static void vfs_fat_seekdir(void* ctx, DIR* pdir, long offset) { assert(pdir); vfs_fat_dir_t* fat_dir = (vfs_fat_dir_t*) pdir; FRESULT res; if (offset < fat_dir->offset) { res = f_rewinddir(&fat_dir->ffdir); if (res != FR_OK) { ESP_LOGD(TAG, "%s: rewinddir fresult=%d", __func__, res); errno = fresult_to_errno(res); return; } fat_dir->offset = 0; } while (fat_dir->offset < offset) { res = f_readdir(&fat_dir->ffdir, &fat_dir->filinfo); if (res != FR_OK) { ESP_LOGD(TAG, "%s: f_readdir fresult=%d", __func__, res); errno = fresult_to_errno(res); return; } fat_dir->offset++; } } static int vfs_fat_mkdir(void* ctx, const char* name, mode_t mode) { (void) mode; vfs_fat_ctx_t* fat_ctx = (vfs_fat_ctx_t*) ctx; _lock_acquire(&fat_ctx->lock); prepend_drive_to_path(fat_ctx, &name, NULL); FRESULT res = f_mkdir(name); _lock_release(&fat_ctx->lock); if (res != FR_OK) { ESP_LOGD(TAG, "%s: fresult=%d", __func__, res); errno = fresult_to_errno(res); return -1; } return 0; } static int vfs_fat_rmdir(void* ctx, const char* name) { vfs_fat_ctx_t* fat_ctx = (vfs_fat_ctx_t*) ctx; _lock_acquire(&fat_ctx->lock); prepend_drive_to_path(fat_ctx, &name, NULL); FRESULT res = f_unlink(name); _lock_release(&fat_ctx->lock); if (res != FR_OK) { ESP_LOGD(TAG, "%s: fresult=%d", __func__, res); errno = fresult_to_errno(res); return -1; } return 0; } static int vfs_fat_access(void* ctx, const char *path, int amode) { FILINFO info; int ret = 0; FRESULT res; vfs_fat_ctx_t* fat_ctx = (vfs_fat_ctx_t*) ctx; _lock_acquire(&fat_ctx->lock); prepend_drive_to_path(fat_ctx, &path, NULL); res = f_stat(path, &info); _lock_release(&fat_ctx->lock); if (res == FR_OK) { if (((amode & W_OK) == W_OK) && ((info.fattrib & AM_RDO) == AM_RDO)) { ret = -1; errno = EACCES; } // There is no flag to test readable or executable: we assume that if // it exists then it is readable and executable } else { ret = -1; errno = ENOENT; } return ret; } static int vfs_fat_truncate(void* ctx, const char *path, off_t length) { FRESULT res; FIL* file = NULL; int ret = 0; vfs_fat_ctx_t* fat_ctx = (vfs_fat_ctx_t*) ctx; if (length < 0) { errno = EINVAL; ret = -1; goto out; } _lock_acquire(&fat_ctx->lock); prepend_drive_to_path(fat_ctx, &path, NULL); file = (FIL*) ff_memalloc(sizeof(FIL)); if (file == NULL) { _lock_release(&fat_ctx->lock); ESP_LOGD(TAG, "truncate alloc failed"); errno = ENOMEM; ret = -1; goto out; } memset(file, 0, sizeof(*file)); res = f_open(file, path, FA_WRITE); if (res != FR_OK) { _lock_release(&fat_ctx->lock); ESP_LOGD(TAG, "%s: fresult=%d", __func__, res); errno = fresult_to_errno(res); ret = -1; goto out; } long sz = f_size(file); if (sz < length) { _lock_release(&fat_ctx->lock); ESP_LOGD(TAG, "truncate does not support extending size"); errno = EPERM; ret = -1; goto close; } res = f_lseek(file, length); if (res != FR_OK) { _lock_release(&fat_ctx->lock); ESP_LOGD(TAG, "%s: fresult=%d", __func__, res); errno = fresult_to_errno(res); ret = -1; goto close; } res = f_truncate(file); _lock_release(&fat_ctx->lock); if (res != FR_OK) { ESP_LOGD(TAG, "%s: fresult=%d", __func__, res); errno = fresult_to_errno(res); ret = -1; } close: res = f_close(file); if (res != FR_OK) { ESP_LOGE(TAG, "closing file opened for truncate failed"); // Overwrite previous errors, since not being able to close // an opened file is a more critical issue. errno = fresult_to_errno(res); ret = -1; } out: free(file); return ret; } static int vfs_fat_ftruncate(void* ctx, int fd, off_t length) { FRESULT res; FIL* file = NULL; int ret = 0; vfs_fat_ctx_t* fat_ctx = (vfs_fat_ctx_t*) ctx; if (length < 0) { errno = EINVAL; ret = -1; return ret; } _lock_acquire(&fat_ctx->lock); file = &fat_ctx->files[fd]; if (file == NULL) { ESP_LOGD(TAG, "ftruncate NULL file pointer"); errno = EINVAL; ret = -1; goto out; } long sz = f_size(file); if (sz < length) { ESP_LOGD(TAG, "ftruncate does not support extending size"); errno = EPERM; ret = -1; goto out; } res = f_lseek(file, length); if (res != FR_OK) { ESP_LOGD(TAG, "%s: fresult=%d", __func__, res); errno = fresult_to_errno(res); ret = -1; goto out; } res = f_truncate(file); if (res != FR_OK) { ESP_LOGD(TAG, "%s: fresult=%d", __func__, res); errno = fresult_to_errno(res); ret = -1; } out: _lock_release(&fat_ctx->lock); return ret; } static int vfs_fat_utime(void *ctx, const char *path, const struct utimbuf *times) { FILINFO filinfo_time; { struct tm tm_time; if (times) { localtime_r(×->modtime, &tm_time); } else { // use current time struct timeval tv; gettimeofday(&tv, NULL); localtime_r(&tv.tv_sec, &tm_time); } if (tm_time.tm_year < 80) { // FATFS cannot handle years before 1980 errno = EINVAL; return -1; } fat_date_t fdate; fat_time_t ftime; // this time transformation is esentially the reverse of the one in vfs_fat_stat() fdate.mday = tm_time.tm_mday; fdate.mon = tm_time.tm_mon + 1; // January in fdate.mon is 1, and 0 in tm_time.tm_mon fdate.year = tm_time.tm_year - 80; // tm_time.tm_year=0 is 1900, tm_time.tm_year=0 is 1980 ftime.sec = tm_time.tm_sec / 2, // ftime.sec counts seconds by 2 ftime.min = tm_time.tm_min; ftime.hour = tm_time.tm_hour; filinfo_time.fdate = fdate.as_int; filinfo_time.ftime = ftime.as_int; } vfs_fat_ctx_t *fat_ctx = (vfs_fat_ctx_t *) ctx; _lock_acquire(&fat_ctx->lock); prepend_drive_to_path(fat_ctx, &path, NULL); FRESULT res = f_utime(path, &filinfo_time); _lock_release(&fat_ctx->lock); if (res != FR_OK) { ESP_LOGD(TAG, "%s: fresult=%d", __func__, res); errno = fresult_to_errno(res); return -1; } return 0; } #endif // CONFIG_VFS_SUPPORT_DIR