// SPDX-License-Identifier: GPL-2.0-or-later /* * Copyright (C) 2019 Namjae Jeon * Copyright (C) 2020 Hyunchul Lee */ #include #include #include #include #include #include #include #include #include "exfat_ondisk.h" #include "libexfat.h" #include "repair.h" #include "exfat_fs.h" #include "exfat_dir.h" #include "fsck.h" struct fsck_user_input { struct exfat_user_input ei; enum fsck_ui_options options; }; #define EXFAT_MAX_UPCASE_CHARS 0x10000 #define FSCK_EXIT_NO_ERRORS 0x00 #define FSCK_EXIT_CORRECTED 0x01 #define FSCK_EXIT_NEED_REBOOT 0x02 #define FSCK_EXIT_ERRORS_LEFT 0x04 #define FSCK_EXIT_OPERATION_ERROR 0x08 #define FSCK_EXIT_SYNTAX_ERROR 0x10 #define FSCK_EXIT_USER_CANCEL 0x20 #define FSCK_EXIT_LIBRARY_ERROR 0x80 struct exfat_stat { long dir_count; long file_count; long error_count; long fixed_count; }; struct exfat_fsck exfat_fsck; struct exfat_stat exfat_stat; struct path_resolve_ctx path_resolve_ctx; static struct option opts[] = { {"repair", no_argument, NULL, 'r' }, {"repair-yes", no_argument, NULL, 'y' }, {"repair-no", no_argument, NULL, 'n' }, {"repair-auto", no_argument, NULL, 'p' }, {"rescue", no_argument, NULL, 's' }, {"version", no_argument, NULL, 'V' }, {"verbose", no_argument, NULL, 'v' }, {"help", no_argument, NULL, 'h' }, {"?", no_argument, NULL, '?' }, {"ignore-bad-fs", no_argument, NULL, 'b' }, {NULL, 0, NULL, 0 } }; static void usage(char *name) { fprintf(stderr, "Usage: %s\n", name); fprintf(stderr, "\t-r | --repair Repair interactively\n"); fprintf(stderr, "\t-y | --repair-yes Repair without ask\n"); fprintf(stderr, "\t-n | --repair-no No repair\n"); fprintf(stderr, "\t-p | --repair-auto Repair automatically\n"); fprintf(stderr, "\t-a Repair automatically\n"); fprintf(stderr, "\t-b | --ignore-bad-fs Try to recover even if exfat is not found\n"); fprintf(stderr, "\t-s | --rescue Assign orphaned clusters to files\n"); fprintf(stderr, "\t-V | --version Show version\n"); fprintf(stderr, "\t-v | --verbose Print debug\n"); fprintf(stderr, "\t-h | --help Show help\n"); exit(FSCK_EXIT_SYNTAX_ERROR); } #define fsck_err(parent, inode, fmt, ...) \ ({ \ exfat_resolve_path_parent(&path_resolve_ctx, \ parent, inode); \ exfat_err("ERROR: %s: " fmt, \ path_resolve_ctx.local_path, \ ##__VA_ARGS__); \ }) #define repair_file_ask(iter, inode, code, fmt, ...) \ ({ \ if (inode) \ exfat_resolve_path_parent(&path_resolve_ctx, \ (iter)->parent, inode); \ else \ exfat_resolve_path(&path_resolve_ctx, \ (iter)->parent); \ exfat_repair_ask(&exfat_fsck, code, \ "ERROR: %s: " fmt " at %#" PRIx64, \ path_resolve_ctx.local_path, \ ##__VA_ARGS__, \ exfat_de_iter_device_offset(iter)); \ }) static int check_clus_chain(struct exfat_de_iter *de_iter, struct exfat_inode *node) { struct exfat *exfat = de_iter->exfat; struct exfat_dentry *stream_de; clus_t clus, prev, next; uint64_t count, max_count; clus = node->first_clus; prev = EXFAT_EOF_CLUSTER; count = 0; max_count = DIV_ROUND_UP(node->size, exfat->clus_size); if (node->size == 0 && node->first_clus == EXFAT_FREE_CLUSTER) return 0; /* the first cluster is wrong */ if ((node->size == 0 && node->first_clus != EXFAT_FREE_CLUSTER) || (node->size > 0 && !exfat_heap_clus(exfat, node->first_clus))) { if (repair_file_ask(de_iter, node, ER_FILE_FIRST_CLUS, "size %#" PRIx64 ", but the first cluster %#x", node->size, node->first_clus)) goto truncate_file; else return -EINVAL; } while (clus != EXFAT_EOF_CLUSTER) { if (count >= max_count) { if (node->is_contiguous) break; if (repair_file_ask(de_iter, node, ER_FILE_SMALLER_SIZE, "more clusters are allocated. truncate to %" PRIu64 " bytes", count * exfat->clus_size)) goto truncate_file; else return -EINVAL; } /* * This cluster is already allocated. it may be shared with * the other file, or there is a loop in cluster chain. */ if (exfat_bitmap_get(exfat->alloc_bitmap, clus)) { if (repair_file_ask(de_iter, node, ER_FILE_DUPLICATED_CLUS, "cluster is already allocated for the other file. truncated to %" PRIu64 " bytes", count * exfat->clus_size)) goto truncate_file; else return -EINVAL; } if (!exfat_bitmap_get(exfat->disk_bitmap, clus)) { if (!repair_file_ask(de_iter, node, ER_FILE_INVALID_CLUS, "cluster %#x is marked as free", clus)) return -EINVAL; } /* This cluster is allocated or not */ if (exfat_get_inode_next_clus(exfat, node, clus, &next)) goto truncate_file; if (next == EXFAT_BAD_CLUSTER) { if (repair_file_ask(de_iter, node, ER_FILE_INVALID_CLUS, "BAD cluster. truncate to %" PRIu64 " bytes", count * exfat->clus_size)) goto truncate_file; else return -EINVAL; } else if (!node->is_contiguous) { if (next != EXFAT_EOF_CLUSTER && !exfat_heap_clus(exfat, next)) { if (repair_file_ask(de_iter, node, ER_FILE_INVALID_CLUS, "broken cluster chain. truncate to %" PRIu64 " bytes", (count + 1) * exfat->clus_size)) { count++; prev = clus; exfat_bitmap_set(exfat->alloc_bitmap, clus); goto truncate_file; } else { return -EINVAL; } } } count++; exfat_bitmap_set(exfat->alloc_bitmap, clus); prev = clus; clus = next; } if (count < max_count) { if (repair_file_ask(de_iter, node, ER_FILE_LARGER_SIZE, "less clusters are allocated. truncates to %" PRIu64 " bytes", count * exfat->clus_size)) goto truncate_file; else return -EINVAL; } return 0; truncate_file: node->size = count * exfat->clus_size; if (!exfat_heap_clus(exfat, prev)) node->first_clus = EXFAT_FREE_CLUSTER; exfat_de_iter_get_dirty(de_iter, 1, &stream_de); if (count * exfat->clus_size < le64_to_cpu(stream_de->stream_valid_size)) stream_de->stream_valid_size = cpu_to_le64( count * exfat->clus_size); if (!exfat_heap_clus(exfat, prev)) stream_de->stream_start_clu = EXFAT_FREE_CLUSTER; stream_de->stream_size = cpu_to_le64( count * exfat->clus_size); /* remaining clusters will be freed while FAT is compared with * alloc_bitmap. */ if (!node->is_contiguous && exfat_heap_clus(exfat, prev)) { if (exfat_set_fat(exfat, prev, EXFAT_EOF_CLUSTER)) return -EIO; } return 1; } static int root_check_clus_chain(struct exfat *exfat, struct exfat_inode *node, clus_t *clus_count) { clus_t clus, next, prev = EXFAT_EOF_CLUSTER; if (!exfat_heap_clus(exfat, node->first_clus)) goto out_trunc; clus = node->first_clus; *clus_count = 0; do { if (exfat_bitmap_get(exfat->alloc_bitmap, clus)) { if (exfat_repair_ask(&exfat_fsck, ER_FILE_DUPLICATED_CLUS, "ERROR: the cluster chain of root is cyclic")) goto out_trunc; return -EINVAL; } exfat_bitmap_set(exfat->alloc_bitmap, clus); if (exfat_get_inode_next_clus(exfat, node, clus, &next)) { exfat_err("ERROR: failed to read the fat entry of root"); goto out_trunc; } if (next != EXFAT_EOF_CLUSTER && !exfat_heap_clus(exfat, next)) { if (exfat_repair_ask(&exfat_fsck, ER_FILE_INVALID_CLUS, "ERROR: the cluster chain of root is broken")) { if (next != EXFAT_BAD_CLUSTER) { prev = clus; (*clus_count)++; } goto out_trunc; } return -EINVAL; } prev = clus; clus = next; (*clus_count)++; } while (clus != EXFAT_EOF_CLUSTER); return 0; out_trunc: if (!exfat_heap_clus(exfat, prev)) { exfat_err("ERROR: the start cluster of root is wrong\n"); return -EINVAL; } node->size = *clus_count * exfat->clus_size; return exfat_set_fat(exfat, prev, EXFAT_EOF_CLUSTER); } static int boot_region_checksum(int dev_fd, int bs_offset, unsigned int sect_size) { void *sect; unsigned int i; uint32_t checksum; int ret = 0; sect = malloc(sect_size); if (!sect) return -ENOMEM; checksum = 0; for (i = 0; i < 11; i++) { if (exfat_read(dev_fd, sect, sect_size, bs_offset * sect_size + i * sect_size) != (ssize_t)sect_size) { exfat_err("failed to read boot region\n"); ret = -EIO; goto out; } boot_calc_checksum(sect, sect_size, i == 0, &checksum); } if (exfat_read(dev_fd, sect, sect_size, bs_offset * sect_size + 11 * sect_size) != (ssize_t)sect_size) { exfat_err("failed to read a boot checksum sector\n"); ret = -EIO; goto out; } for (i = 0; i < sect_size/sizeof(checksum); i++) { if (le32_to_cpu(((__le32 *)sect)[i]) != checksum) { exfat_err("checksum of boot region is not correct. %#x, but expected %#x\n", le32_to_cpu(((__le32 *)sect)[i]), checksum); ret = -EINVAL; goto out; } } out: free(sect); return ret; } static int exfat_mark_volume_dirty(struct exfat *exfat, bool dirty) { uint16_t flags; flags = le16_to_cpu(exfat->bs->bsx.vol_flags); if (dirty) flags |= 0x02; else flags &= ~0x02; exfat->bs->bsx.vol_flags = cpu_to_le16(flags); if (exfat_write(exfat->blk_dev->dev_fd, exfat->bs, sizeof(struct pbr), 0) != (ssize_t)sizeof(struct pbr)) { exfat_err("failed to set VolumeDirty\n"); return -EIO; } if (fsync(exfat->blk_dev->dev_fd) != 0) { exfat_err("failed to set VolumeDirty\n"); return -EIO; } return 0; } static int read_boot_region(struct exfat_blk_dev *bd, struct pbr **pbr, int bs_offset, unsigned int sect_size, bool verbose) { struct pbr *bs; int ret = -EINVAL; *pbr = NULL; bs = (struct pbr *)malloc(sizeof(struct pbr)); if (!bs) { exfat_err("failed to allocate memory\n"); return -ENOMEM; } if (exfat_read(bd->dev_fd, bs, sizeof(*bs), bs_offset * sect_size) != (ssize_t)sizeof(*bs)) { exfat_err("failed to read a boot sector\n"); ret = -EIO; goto err; } if (memcmp(bs->bpb.oem_name, "EXFAT ", 8) != 0) { if (verbose) exfat_err("failed to find exfat file system\n"); goto err; } ret = boot_region_checksum(bd->dev_fd, bs_offset, sect_size); if (ret < 0) goto err; ret = -EINVAL; if (EXFAT_SECTOR_SIZE(bs) < 512 || EXFAT_SECTOR_SIZE(bs) > 4 * KB) { if (verbose) exfat_err("too small or big sector size: %d\n", EXFAT_SECTOR_SIZE(bs)); goto err; } if (EXFAT_CLUSTER_SIZE(bs) > 32 * MB) { if (verbose) exfat_err("too big cluster size: %d\n", EXFAT_CLUSTER_SIZE(bs)); goto err; } if (bs->bsx.fs_version[1] != 1 || bs->bsx.fs_version[0] != 0) { if (verbose) exfat_err("unsupported exfat version: %d.%d\n", bs->bsx.fs_version[1], bs->bsx.fs_version[0]); goto err; } if (bs->bsx.num_fats != 1) { if (verbose) exfat_err("unsupported FAT count: %d\n", bs->bsx.num_fats); goto err; } if (le64_to_cpu(bs->bsx.vol_length) * EXFAT_SECTOR_SIZE(bs) > bd->size) { if (verbose) exfat_err("too large sector count: %" PRIu64 ", expected: %llu\n", le64_to_cpu(bs->bsx.vol_length), bd->num_sectors); goto err; } if (le32_to_cpu(bs->bsx.clu_count) * EXFAT_CLUSTER_SIZE(bs) > bd->size) { if (verbose) exfat_err("too large cluster count: %u, expected: %u\n", le32_to_cpu(bs->bsx.clu_count), bd->num_clusters); goto err; } *pbr = bs; return 0; err: free(bs); return ret; } static int restore_boot_region(struct exfat_blk_dev *bd, unsigned int sect_size) { int i; char *sector; int ret; sector = malloc(sect_size); if (!sector) return -ENOMEM; for (i = 0; i < 12; i++) { if (exfat_read(bd->dev_fd, sector, sect_size, BACKUP_BOOT_SEC_IDX * sect_size + i * sect_size) != (ssize_t)sect_size) { ret = -EIO; goto free_sector; } if (i == 0) ((struct pbr *)sector)->bsx.perc_in_use = 0xff; if (exfat_write(bd->dev_fd, sector, sect_size, BOOT_SEC_IDX * sect_size + i * sect_size) != (ssize_t)sect_size) { ret = -EIO; goto free_sector; } } if (fsync(bd->dev_fd)) { ret = -EIO; goto free_sector; } ret = 0; free_sector: free(sector); return ret; } static int exfat_boot_region_check(struct exfat_blk_dev *blkdev, struct pbr **bs, bool ignore_bad_fs_name) { struct pbr *boot_sect; unsigned int sect_size; int ret; /* First, find out the exfat sector size */ boot_sect = malloc(sizeof(*boot_sect)); if (boot_sect == NULL) return -ENOMEM; if (exfat_read(blkdev->dev_fd, boot_sect, sizeof(*boot_sect), 0) != (ssize_t)sizeof(*boot_sect)) { exfat_err("failed to read Main boot sector\n"); free(boot_sect); return -EIO; } if (memcmp(boot_sect->bpb.oem_name, "EXFAT ", 8) != 0 && !ignore_bad_fs_name) { exfat_err("Bad fs_name in boot sector, which does not describe a valid exfat filesystem\n"); free(boot_sect); return -ENOTSUP; } sect_size = 1 << boot_sect->bsx.sect_size_bits; free(boot_sect); /* check boot regions */ ret = read_boot_region(blkdev, bs, BOOT_SEC_IDX, sect_size, true); if (ret == -EINVAL && exfat_repair_ask(&exfat_fsck, ER_BS_BOOT_REGION, "boot region is corrupted. try to restore the region from backup" )) { const unsigned int sector_sizes[] = {512, 4096, 1024, 2048}; unsigned int i; if (sect_size >= 512 && sect_size <= EXFAT_MAX_SECTOR_SIZE) { ret = read_boot_region(blkdev, bs, BACKUP_BOOT_SEC_IDX, sect_size, false); if (!ret) goto restore; } for (i = 0; i < sizeof(sector_sizes)/sizeof(sector_sizes[0]); i++) { if (sector_sizes[i] == sect_size) continue; ret = read_boot_region(blkdev, bs, BACKUP_BOOT_SEC_IDX, sector_sizes[i], false); if (!ret) { sect_size = sector_sizes[i]; goto restore; } } exfat_err("backup boot region is also corrupted\n"); } return ret; restore: ret = restore_boot_region(blkdev, sect_size); if (ret) { exfat_err("failed to restore boot region from backup\n"); free(*bs); *bs = NULL; } return ret; } static uint16_t file_calc_checksum(struct exfat_de_iter *iter) { uint16_t checksum; struct exfat_dentry *file_de, *de; int i; checksum = 0; exfat_de_iter_get(iter, 0, &file_de); exfat_calc_dentry_checksum(file_de, &checksum, true); for (i = 1; i <= file_de->file_num_ext; i++) { exfat_de_iter_get(iter, i, &de); exfat_calc_dentry_checksum(de, &checksum, false); } return checksum; } /* * return 0 if there are no errors, or 1 if errors are fixed, or * an error code */ static int check_inode(struct exfat_de_iter *iter, struct exfat_inode *node) { struct exfat *exfat = iter->exfat; struct exfat_dentry *dentry; int ret = 0; uint16_t checksum; bool valid = true; ret = check_clus_chain(iter, node); if (ret < 0) return ret; if (node->size > le32_to_cpu(exfat->bs->bsx.clu_count) * (uint64_t)exfat->clus_size) { fsck_err(iter->parent, node, "size %" PRIu64 " is greater than cluster heap\n", node->size); valid = false; } if (node->size == 0 && node->is_contiguous) { if (repair_file_ask(iter, node, ER_FILE_ZERO_NOFAT, "empty, but has no Fat chain")) { exfat_de_iter_get_dirty(iter, 1, &dentry); dentry->stream_flags &= ~EXFAT_SF_CONTIGUOUS; ret = 1; } else valid = false; } if ((node->attr & ATTR_SUBDIR) && node->size % exfat->clus_size != 0) { fsck_err(iter->parent, node, "directory size %" PRIu64 " is not divisible by %d\n", node->size, exfat->clus_size); valid = false; } checksum = file_calc_checksum(iter); exfat_de_iter_get(iter, 0, &dentry); if (checksum != le16_to_cpu(dentry->file_checksum)) { exfat_de_iter_get_dirty(iter, 0, &dentry); dentry->file_checksum = cpu_to_le16(checksum); ret = 1; } return valid ? ret : -EINVAL; } static int check_name_dentry_set(struct exfat_de_iter *iter, struct exfat_inode *inode) { struct exfat_dentry *stream_de; size_t name_len; __u16 hash; exfat_de_iter_get(iter, 1, &stream_de); name_len = exfat_utf16_len(inode->name, NAME_BUFFER_SIZE); if (stream_de->stream_name_len != name_len) { if (repair_file_ask(iter, NULL, ER_DE_NAME_LEN, "the name length of a file is wrong")) { exfat_de_iter_get_dirty(iter, 1, &stream_de); stream_de->stream_name_len = (__u8)name_len; } else { return -EINVAL; } } hash = exfat_calc_name_hash(iter->exfat, inode->name, (int)name_len); if (cpu_to_le16(hash) != stream_de->stream_name_hash) { if (repair_file_ask(iter, NULL, ER_DE_NAME_HASH, "the name hash of a file is wrong")) { exfat_de_iter_get_dirty(iter, 1, &stream_de); stream_de->stream_name_hash = cpu_to_le16(hash); } else { return -EINVAL; } } return 0; } static int check_bad_char(char w) { return (w < 0x0020) || (w == '*') || (w == '?') || (w == '<') || (w == '>') || (w == '|') || (w == '"') || (w == ':') || (w == '/') || (w == '\\'); } static char *get_rename_from_user(struct exfat_de_iter *iter) { char *rename = malloc(ENTRY_NAME_MAX + 2); if (!rename) return NULL; retry: /* +2 means LF(Line Feed) and NULL terminator */ memset(rename, 0x1, ENTRY_NAME_MAX + 2); printf("New name: "); if (fgets(rename, ENTRY_NAME_MAX + 2, stdin)) { int i, len, err; struct exfat_lookup_filter filter; len = strlen(rename); /* Remove LF in filename */ rename[len - 1] = '\0'; for (i = 0; i < len - 1; i++) { if (check_bad_char(rename[i])) { printf("filename contain invalid character(%c)\n", rename[i]); goto retry; } } exfat_de_iter_flush(iter); err = exfat_lookup_file(iter->exfat, iter->parent, rename, &filter); if (!err) { printf("file(%s) already exists, retry to insert name\n", rename); goto retry; } } return rename; } static char *generate_rename(struct exfat_de_iter *iter) { char *rename; if (iter->dot_name_num > DOT_NAME_NUM_MAX) return NULL; rename = malloc(ENTRY_NAME_MAX + 1); if (!rename) return NULL; while (1) { struct exfat_lookup_filter filter; int err; snprintf(rename, ENTRY_NAME_MAX + 1, "FILE%07d.CHK", iter->dot_name_num++); err = exfat_lookup_file(iter->exfat, iter->parent, rename, &filter); if (!err) continue; break; } return rename; } const __le16 MSDOS_DOT[ENTRY_NAME_MAX] = {cpu_to_le16(46), 0, }; const __le16 MSDOS_DOTDOT[ENTRY_NAME_MAX] = {cpu_to_le16(46), cpu_to_le16(46), 0, }; static int handle_dot_dotdot_filename(struct exfat_de_iter *iter, struct exfat_dentry *dentry, int strm_name_len) { char *filename; char error_msg[150]; int num; if (!memcmp(dentry->name_unicode, MSDOS_DOT, strm_name_len * 2)) filename = "."; else if (!memcmp(dentry->name_unicode, MSDOS_DOTDOT, strm_name_len * 2)) filename = ".."; else return 0; sprintf(error_msg, "ERROR: '%s' filename is not allowed.\n" " [1] Insert the name you want to rename.\n" " [2] Automatically renames filename.\n" " [3] Bypass this check(No repair)\n", filename); ask_again: num = exfat_repair_ask(&exfat_fsck, ER_DE_DOT_NAME, error_msg); if (num) { __le16 utf16_name[ENTRY_NAME_MAX]; char *rename = NULL; __u16 hash; struct exfat_dentry *stream_de; int name_len, ret; switch (num) { case 1: rename = get_rename_from_user(iter); break; case 2: rename = generate_rename(iter); break; case 3: break; default: exfat_info("select 1 or 2 number instead of %d\n", num); goto ask_again; } if (!rename) return -EINVAL; exfat_info("%s filename is renamed to %s\n", filename, rename); exfat_de_iter_get_dirty(iter, 2, &dentry); memset(utf16_name, 0, sizeof(utf16_name)); ret = exfat_utf16_enc(rename, utf16_name, sizeof(utf16_name)); free(rename); if (ret < 0) return ret; memcpy(dentry->name_unicode, utf16_name, ENTRY_NAME_MAX * 2); name_len = exfat_utf16_len(utf16_name, ENTRY_NAME_MAX * 2); hash = exfat_calc_name_hash(iter->exfat, utf16_name, (int)name_len); exfat_de_iter_get_dirty(iter, 1, &stream_de); stream_de->stream_name_len = (__u8)name_len; stream_de->stream_name_hash = cpu_to_le16(hash); } return 0; } static int read_file_dentry_set(struct exfat_de_iter *iter, struct exfat_inode **new_node, int *skip_dentries) { struct exfat_dentry *file_de, *stream_de, *dentry; struct exfat_inode *node = NULL; int i, ret; bool need_delete = false; uint16_t checksum; ret = exfat_de_iter_get(iter, 0, &file_de); if (ret || file_de->type != EXFAT_FILE) { exfat_err("failed to get file dentry\n"); return -EINVAL; } checksum = file_calc_checksum(iter); if (checksum != le16_to_cpu(file_de->file_checksum)) { if (repair_file_ask(iter, NULL, ER_DE_CHECKSUM, "the checksum of a file is wrong")) need_delete = true; *skip_dentries = 1; goto skip_dset; } if (file_de->file_num_ext < 2) { if (repair_file_ask(iter, NULL, ER_DE_SECONDARY_COUNT, "a file has too few secondary count. %d", file_de->file_num_ext)) need_delete = true; *skip_dentries = 1; goto skip_dset; } ret = exfat_de_iter_get(iter, 1, &stream_de); if (ret || stream_de->type != EXFAT_STREAM) { if (repair_file_ask(iter, NULL, ER_DE_STREAM, "failed to get stream dentry")) need_delete = true; *skip_dentries = 2; goto skip_dset; } *new_node = NULL; node = exfat_alloc_inode(le16_to_cpu(file_de->file_attr)); if (!node) return -ENOMEM; for (i = 2; i <= file_de->file_num_ext; i++) { ret = exfat_de_iter_get(iter, i, &dentry); if (ret || dentry->type != EXFAT_NAME) { if (i > 2 && repair_file_ask(iter, NULL, ER_DE_NAME, "failed to get name dentry")) { exfat_de_iter_get_dirty(iter, 0, &file_de); file_de->file_num_ext = i - 1; break; } *skip_dentries = i + 1; goto skip_dset; } memcpy(node->name + (i - 2) * ENTRY_NAME_MAX, dentry->name_unicode, sizeof(dentry->name_unicode)); } ret = check_name_dentry_set(iter, node); if (ret) { *skip_dentries = file_de->file_num_ext + 1; goto skip_dset; } if (file_de->file_num_ext == 2 && stream_de->stream_name_len <= 2) { ret = handle_dot_dotdot_filename(iter, dentry, stream_de->stream_name_len); if (ret < 0) { *skip_dentries = file_de->file_num_ext + 1; goto skip_dset; } } node->first_clus = le32_to_cpu(stream_de->stream_start_clu); node->is_contiguous = ((stream_de->stream_flags & EXFAT_SF_CONTIGUOUS) != 0); node->size = le64_to_cpu(stream_de->stream_size); if (node->size < le64_to_cpu(stream_de->stream_valid_size)) { *skip_dentries = file_de->file_num_ext + 1; if (repair_file_ask(iter, node, ER_FILE_VALID_SIZE, "valid size %" PRIu64 " greater than size %" PRIu64, le64_to_cpu(stream_de->stream_valid_size), node->size)) { exfat_de_iter_get_dirty(iter, 1, &stream_de); stream_de->stream_valid_size = stream_de->stream_size; } else { *skip_dentries = file_de->file_num_ext + 1; goto skip_dset; } } *skip_dentries = (file_de->file_num_ext + 1); *new_node = node; return 0; skip_dset: if (need_delete) { exfat_de_iter_get_dirty(iter, 0, &dentry); dentry->type &= EXFAT_DELETE; } for (i = 1; i < *skip_dentries; i++) { exfat_de_iter_get(iter, i, &dentry); if (dentry->type == EXFAT_FILE) break; if (need_delete) { exfat_de_iter_get_dirty(iter, i, &dentry); dentry->type &= EXFAT_DELETE; } } *skip_dentries = i; *new_node = NULL; exfat_free_inode(node); return need_delete ? 1 : -EINVAL; } static int read_file(struct exfat_de_iter *de_iter, struct exfat_inode **new_node, int *dentry_count) { struct exfat_inode *node; int ret; *new_node = NULL; ret = read_file_dentry_set(de_iter, &node, dentry_count); if (ret) return ret; ret = check_inode(de_iter, node); if (ret < 0) { exfat_free_inode(node); return -EINVAL; } if (node->attr & ATTR_SUBDIR) exfat_stat.dir_count++; else exfat_stat.file_count++; *new_node = node; return ret; } static int read_bitmap(struct exfat *exfat) { struct exfat_lookup_filter filter = { .in.type = EXFAT_BITMAP, .in.filter = NULL, .in.param = NULL, }; struct exfat_dentry *dentry; int retval; retval = exfat_lookup_dentry_set(exfat, exfat->root, &filter); if (retval) return retval; dentry = filter.out.dentry_set; exfat_debug("start cluster %#x, size %#" PRIx64 "\n", le32_to_cpu(dentry->bitmap_start_clu), le64_to_cpu(dentry->bitmap_size)); if (le64_to_cpu(dentry->bitmap_size) < DIV_ROUND_UP(exfat->clus_count, 8)) { exfat_err("invalid size of allocation bitmap. 0x%" PRIx64 "\n", le64_to_cpu(dentry->bitmap_size)); return -EINVAL; } if (!exfat_heap_clus(exfat, le32_to_cpu(dentry->bitmap_start_clu))) { exfat_err("invalid start cluster of allocate bitmap. 0x%x\n", le32_to_cpu(dentry->bitmap_start_clu)); return -EINVAL; } exfat->disk_bitmap_clus = le32_to_cpu(dentry->bitmap_start_clu); exfat->disk_bitmap_size = DIV_ROUND_UP(exfat->clus_count, 8); exfat_bitmap_set_range(exfat, exfat->alloc_bitmap, le64_to_cpu(dentry->bitmap_start_clu), DIV_ROUND_UP(exfat->disk_bitmap_size, exfat->clus_size)); free(filter.out.dentry_set); if (exfat_read(exfat->blk_dev->dev_fd, exfat->disk_bitmap, exfat->disk_bitmap_size, exfat_c2o(exfat, exfat->disk_bitmap_clus)) != (ssize_t)exfat->disk_bitmap_size) return -EIO; return 0; } static int decompress_upcase_table(const __le16 *in_table, size_t in_len, __u16 *out_table, size_t out_len) { size_t i, k; uint16_t ch; if (in_len > out_len) return -E2BIG; for (k = 0; k < out_len; k++) out_table[k] = k; for (i = 0, k = 0; i < in_len && k < out_len; i++) { ch = le16_to_cpu(in_table[i]); if (ch == 0xFFFF && i + 1 < in_len) { uint16_t len = le16_to_cpu(in_table[++i]); k += len; } else { out_table[k++] = ch; } } return 0; } static int read_upcase_table(struct exfat *exfat) { struct exfat_lookup_filter filter = { .in.type = EXFAT_UPCASE, .in.filter = NULL, .in.param = NULL, }; struct exfat_dentry *dentry = NULL; __le16 *upcase = NULL; int retval; ssize_t size; __le32 checksum; retval = exfat_lookup_dentry_set(exfat, exfat->root, &filter); if (retval) return retval; dentry = filter.out.dentry_set; if (!exfat_heap_clus(exfat, le32_to_cpu(dentry->upcase_start_clu))) { exfat_err("invalid start cluster of upcase table. 0x%x\n", le32_to_cpu(dentry->upcase_start_clu)); retval = -EINVAL; goto out; } size = (ssize_t)le64_to_cpu(dentry->upcase_size); if (size > (ssize_t)(EXFAT_MAX_UPCASE_CHARS * sizeof(__le16)) || size == 0 || size % sizeof(__le16)) { exfat_err("invalid size of upcase table. 0x%" PRIx64 "\n", le64_to_cpu(dentry->upcase_size)); retval = -EINVAL; goto out; } upcase = (__le16 *)malloc(size); if (!upcase) { exfat_err("failed to allocate upcase table\n"); retval = -ENOMEM; goto out; } if (exfat_read(exfat->blk_dev->dev_fd, upcase, size, exfat_c2o(exfat, le32_to_cpu(dentry->upcase_start_clu))) != size) { exfat_err("failed to read upcase table\n"); retval = -EIO; goto out; } checksum = 0; boot_calc_checksum((unsigned char *)upcase, size, false, &checksum); if (le32_to_cpu(dentry->upcase_checksum) != checksum) { exfat_err("corrupted upcase table %#x (expected: %#x)\n", checksum, le32_to_cpu(dentry->upcase_checksum)); retval = -EINVAL; goto out; } exfat_bitmap_set_range(exfat, exfat->alloc_bitmap, le32_to_cpu(dentry->upcase_start_clu), DIV_ROUND_UP(le64_to_cpu(dentry->upcase_size), exfat->clus_size)); exfat->upcase_table = calloc(1, sizeof(uint16_t) * EXFAT_UPCASE_TABLE_CHARS); if (!exfat->upcase_table) { retval = -EIO; goto out; } decompress_upcase_table(upcase, size / 2, exfat->upcase_table, EXFAT_UPCASE_TABLE_CHARS); out: if (dentry) free(dentry); if (upcase) free(upcase); return retval; } static int read_children(struct exfat_fsck *fsck, struct exfat_inode *dir) { struct exfat *exfat = fsck->exfat; struct exfat_inode *node = NULL; struct exfat_dentry *dentry; struct exfat_de_iter *de_iter; int dentry_count; int ret; de_iter = &fsck->de_iter; ret = exfat_de_iter_init(de_iter, exfat, dir, fsck->buffer_desc); if (ret == EOF) return 0; else if (ret) return ret; while (1) { ret = exfat_de_iter_get(de_iter, 0, &dentry); if (ret == EOF) { break; } else if (ret) { fsck_err(dir->parent, dir, "failed to get a dentry. %d\n", ret); goto err; } dentry_count = 1; switch (dentry->type) { case EXFAT_FILE: ret = read_file(de_iter, &node, &dentry_count); if (ret < 0) { exfat_stat.error_count++; break; } else if (ret) { exfat_stat.error_count++; exfat_stat.fixed_count++; } if (node) { if ((node->attr & ATTR_SUBDIR) && node->size) { node->parent = dir; list_add_tail(&node->sibling, &dir->children); list_add_tail(&node->list, &exfat->dir_list); } else { exfat_free_inode(node); } } break; case EXFAT_LAST: goto out; case EXFAT_VOLUME: case EXFAT_BITMAP: case EXFAT_UPCASE: if (dir == exfat->root) break; /* fallthrough */ default: if (IS_EXFAT_DELETED(dentry->type)) break; if (repair_file_ask(de_iter, NULL, ER_DE_UNKNOWN, "unknown entry type %#x at %07" PRIx64, dentry->type, exfat_de_iter_file_offset(de_iter))) { struct exfat_dentry *dentry; exfat_de_iter_get_dirty(de_iter, 0, &dentry); dentry->type &= EXFAT_DELETE; } break; } exfat_de_iter_advance(de_iter, dentry_count); } out: exfat_de_iter_flush(de_iter); return 0; err: exfat_free_children(dir, false); INIT_LIST_HEAD(&dir->children); exfat_de_iter_flush(de_iter); return ret; } /* write bitmap segments for clusters which are marked * as free, but allocated to files. */ static int write_bitmap(struct exfat_fsck *fsck) { struct exfat *exfat = fsck->exfat; bitmap_t *disk_b, *alloc_b, *ohead_b; off_t dev_offset; unsigned int i, bitmap_bytes, byte_offset, write_bytes; dev_offset = exfat_c2o(exfat, exfat->disk_bitmap_clus); bitmap_bytes = EXFAT_BITMAP_SIZE(le32_to_cpu(exfat->bs->bsx.clu_count)); disk_b = (bitmap_t *)exfat->disk_bitmap; alloc_b = (bitmap_t *)exfat->alloc_bitmap; ohead_b = (bitmap_t *)exfat->ohead_bitmap; for (i = 0; i < bitmap_bytes / sizeof(bitmap_t); i++) ohead_b[i] = alloc_b[i] | disk_b[i]; i = 0; while (i < bitmap_bytes / sizeof(bitmap_t)) { if (ohead_b[i] == disk_b[i]) { i++; continue; } byte_offset = ((i * sizeof(bitmap_t)) / 512) * 512; write_bytes = MIN(512, bitmap_bytes - byte_offset); if (exfat_write(exfat->blk_dev->dev_fd, (char *)ohead_b + byte_offset, write_bytes, dev_offset + byte_offset) != (ssize_t)write_bytes) return -EIO; i = (byte_offset + write_bytes) / sizeof(bitmap_t); } return 0; } /* * for each directory in @dir_list. * 1. read all dentries and allocate exfat_nodes for files and directories. * and append directory exfat_nodes to the head of @dir_list * 2. free all of file exfat_nodes. * 3. if the directory does not have children, free its exfat_node. */ static int exfat_filesystem_check(struct exfat_fsck *fsck) { struct exfat *exfat = fsck->exfat; struct exfat_inode *dir; int ret = 0, dir_errors; if (!exfat->root) { exfat_err("root is NULL\n"); return -ENOENT; } list_add(&exfat->root->list, &exfat->dir_list); while (!list_empty(&exfat->dir_list)) { dir = list_entry(exfat->dir_list.next, struct exfat_inode, list); if (!(dir->attr & ATTR_SUBDIR)) { fsck_err(dir->parent, dir, "failed to travel directories. " "the node is not directory\n"); ret = -EINVAL; goto out; } dir_errors = read_children(fsck, dir); if (dir_errors) { exfat_resolve_path(&path_resolve_ctx, dir); exfat_debug("failed to check dentries: %s\n", path_resolve_ctx.local_path); ret = dir_errors; } list_del(&dir->list); exfat_free_file_children(dir); exfat_free_ancestors(dir); } out: exfat_free_dir_list(exfat); return ret; } static int exfat_root_dir_check(struct exfat *exfat) { struct exfat_inode *root; clus_t clus_count = 0; int err; root = exfat_alloc_inode(ATTR_SUBDIR); if (!root) return -ENOMEM; exfat->root = root; root->first_clus = le32_to_cpu(exfat->bs->bsx.root_cluster); if (root_check_clus_chain(exfat, root, &clus_count)) { exfat_err("failed to follow the cluster chain of root\n"); exfat_free_inode(root); exfat->root = NULL; return -EINVAL; } root->size = clus_count * exfat->clus_size; exfat_stat.dir_count++; exfat_debug("root directory: start cluster[0x%x] size[0x%" PRIx64 "]\n", root->first_clus, root->size); err = exfat_read_volume_label(exfat); if (err && err != EOF) exfat_err("failed to read volume label\n"); err = 0; err = read_bitmap(exfat); if (err) { exfat_err("failed to read bitmap\n"); return -EINVAL; } err = read_upcase_table(exfat); if (err) { exfat_err("failed to read upcase table\n"); return -EINVAL; } root->dev_offset = 0; err = exfat_build_file_dentry_set(exfat, " ", ATTR_SUBDIR, &root->dentry_set, &root->dentry_count); if (err) { exfat_free_inode(root); return -ENOMEM; } return 0; } static int read_lostfound(struct exfat *exfat, struct exfat_inode **lostfound) { struct exfat_lookup_filter filter; struct exfat_inode *inode; int err; err = exfat_lookup_file(exfat, exfat->root, "LOST+FOUND", &filter); if (err) return err; inode = exfat_alloc_inode(ATTR_SUBDIR); if (!inode) { free(filter.out.dentry_set); return -ENOMEM; } inode->dentry_set = filter.out.dentry_set; inode->dentry_count = filter.out.dentry_count; inode->dev_offset = filter.out.dev_offset; inode->first_clus = le32_to_cpu(filter.out.dentry_set[1].dentry.stream.start_clu); inode->size = le64_to_cpu(filter.out.dentry_set[1].dentry.stream.size); *lostfound = inode; return 0; } /* Create temporary files under LOST+FOUND and assign orphan * chains of clusters to these files. */ static int rescue_orphan_clusters(struct exfat_fsck *fsck) { struct exfat *exfat = fsck->exfat; struct exfat_inode *lostfound; bitmap_t *disk_b, *alloc_b, *ohead_b; struct exfat_dentry *dset; clus_t clu_count, clu, s_clu, e_clu; int err, dcount; unsigned int i; char name[] = "FILE0000000.CHK"; struct exfat_dentry_loc loc; struct exfat_lookup_filter lf = { .in.type = EXFAT_INVAL, .in.filter = NULL, }; err = read_lostfound(exfat, &lostfound); if (err) { exfat_err("failed to find LOST+FOUND\n"); return err; } /* get the last empty region of LOST+FOUND */ err = exfat_lookup_dentry_set(exfat, lostfound, &lf); if (err && err != EOF) { exfat_err("failed to find the last empty slot in LOST+FOUND\n"); goto out; } loc.parent = lostfound; loc.file_offset = lf.out.file_offset; loc.dev_offset = lf.out.dev_offset; /* build a template dentry set */ err = exfat_build_file_dentry_set(exfat, name, 0, &dset, &dcount); if (err) { exfat_err("failed to create a temporary file in LOST+FOUNDn"); goto out; } dset[1].dentry.stream.flags |= EXFAT_SF_CONTIGUOUS; clu_count = le32_to_cpu(exfat->bs->bsx.clu_count); /* find clusters which are not marked as free, but not allocated to * any files. */ disk_b = (bitmap_t *)exfat->disk_bitmap; alloc_b = (bitmap_t *)exfat->alloc_bitmap; ohead_b = (bitmap_t *)exfat->ohead_bitmap; for (i = 0; i < EXFAT_BITMAP_SIZE(clu_count) / sizeof(bitmap_t); i++) ohead_b[i] = disk_b[i] & ~alloc_b[i]; /* create temporary files and allocate contiguous orphan clusters * to each file. */ for (clu = EXFAT_FIRST_CLUSTER; clu < clu_count + EXFAT_FIRST_CLUSTER && exfat_bitmap_find_one(exfat, exfat->ohead_bitmap, clu, &s_clu) == 0;) { if (exfat_bitmap_find_zero(exfat, exfat->ohead_bitmap, s_clu, &e_clu)) e_clu = clu_count + EXFAT_FIRST_CLUSTER; clu = e_clu; snprintf(name, sizeof(name), "FILE%07d.CHK", (unsigned int)(loc.file_offset >> 5)); err = exfat_update_file_dentry_set(exfat, dset, dcount, name, s_clu, e_clu - s_clu); if (err) continue; err = exfat_add_dentry_set(exfat, &loc, dset, dcount, true); if (err) continue; } free(dset); err = 0; out: exfat_free_inode(lostfound); return err; } static char *bytes_to_human_readable(size_t bytes) { static const char * const units[] = {"B", "KB", "MB", "GB", "TB", "PB"}; static char buf[15*4]; unsigned int i, shift, quoti, remain; i = sizeof(units) / sizeof(units[0]) - 1; while (i && (bytes >> i * 10) == 0) i--; shift = i * 10; quoti = (unsigned int)(bytes / (1ULL << shift)); remain = 0; if (shift > 0) { remain = (unsigned int) ((bytes & ((1ULL << shift) - 1)) >> (shift - 10)); remain = (remain * 100) / 1024; } snprintf(buf, sizeof(buf), "%u.%02u %s", quoti, remain, units[i]); return buf; } static void exfat_show_info(struct exfat_fsck *fsck, const char *dev_name) { struct exfat *exfat = fsck->exfat; bool clean; exfat_info("sector size: %s\n", bytes_to_human_readable(1 << exfat->bs->bsx.sect_size_bits)); exfat_info("cluster size: %s\n", bytes_to_human_readable(exfat->clus_size)); exfat_info("volume size: %s\n", bytes_to_human_readable(exfat->blk_dev->size)); clean = exfat_stat.error_count == 0 || exfat_stat.error_count == exfat_stat.fixed_count; printf("%s: %s. directories %ld, files %ld\n", dev_name, clean ? "clean" : "corrupted", exfat_stat.dir_count, exfat_stat.file_count); if (exfat_stat.error_count) printf("%s: files corrupted %ld, files fixed %ld\n", dev_name, exfat_stat.error_count - exfat_stat.fixed_count, exfat_stat.fixed_count); } int main(int argc, char * const argv[]) { struct fsck_user_input ui; struct exfat_blk_dev bd; struct pbr *bs = NULL; int c, ret, exit_code; bool version_only = false; memset(&ui, 0, sizeof(ui)); memset(&bd, 0, sizeof(bd)); print_level = EXFAT_ERROR; if (!setlocale(LC_CTYPE, "")) exfat_err("failed to init locale/codeset\n"); opterr = 0; while ((c = getopt_long(argc, argv, "arynpbsVvh", opts, NULL)) != EOF) { switch (c) { case 'n': if (ui.options & FSCK_OPTS_REPAIR_ALL) usage(argv[0]); ui.options |= FSCK_OPTS_REPAIR_NO; break; case 'r': if (ui.options & FSCK_OPTS_REPAIR_ALL) usage(argv[0]); ui.options |= FSCK_OPTS_REPAIR_ASK; break; case 'y': if (ui.options & FSCK_OPTS_REPAIR_ALL) usage(argv[0]); ui.options |= FSCK_OPTS_REPAIR_YES; break; case 'a': case 'p': if (ui.options & FSCK_OPTS_REPAIR_ALL) usage(argv[0]); ui.options |= FSCK_OPTS_REPAIR_AUTO; break; case 'b': ui.options |= FSCK_OPTS_IGNORE_BAD_FS_NAME; break; case 's': ui.options |= FSCK_OPTS_RESCUE_CLUS; break; case 'V': version_only = true; break; case 'v': if (print_level < EXFAT_DEBUG) print_level++; break; case '?': case 'h': default: usage(argv[0]); } } show_version(); if (optind != argc - 1) usage(argv[0]); if (version_only) exit(FSCK_EXIT_SYNTAX_ERROR); if (ui.options & FSCK_OPTS_REPAIR_WRITE) ui.ei.writeable = true; else { if (ui.options & (FSCK_OPTS_IGNORE_BAD_FS_NAME | FSCK_OPTS_RESCUE_CLUS)) usage(argv[0]); ui.options |= FSCK_OPTS_REPAIR_NO; ui.ei.writeable = false; } exfat_fsck.options = ui.options; snprintf(ui.ei.dev_name, sizeof(ui.ei.dev_name), "%s", argv[optind]); ret = exfat_get_blk_dev_info(&ui.ei, &bd); if (ret < 0) { exfat_err("failed to open %s. %d\n", ui.ei.dev_name, ret); return FSCK_EXIT_OPERATION_ERROR; } ret = exfat_boot_region_check(&bd, &bs, ui.options & FSCK_OPTS_IGNORE_BAD_FS_NAME ? true : false); if (ret) goto err; exfat_fsck.exfat = exfat_alloc_exfat(&bd, bs); if (!exfat_fsck.exfat) { ret = -ENOMEM; goto err; } exfat_fsck.buffer_desc = exfat_alloc_buffer(2, exfat_fsck.exfat->clus_size, exfat_fsck.exfat->sect_size); if (!exfat_fsck.buffer_desc) { ret = -ENOMEM; goto err; } if ((exfat_fsck.options & FSCK_OPTS_REPAIR_WRITE) && exfat_mark_volume_dirty(exfat_fsck.exfat, true)) { ret = -EIO; goto err; } exfat_debug("verifying root directory...\n"); ret = exfat_root_dir_check(exfat_fsck.exfat); if (ret) { exfat_err("failed to verify root directory.\n"); goto out; } if (exfat_fsck.options & FSCK_OPTS_RESCUE_CLUS) { ret = exfat_create_file(exfat_fsck.exfat, exfat_fsck.exfat->root, "LOST+FOUND", ATTR_SUBDIR); if (ret) { exfat_err("failed to create lost+found directory\n"); goto out; } if (fsync(exfat_fsck.exfat->blk_dev->dev_fd) != 0) { ret = -EIO; exfat_err("failed to sync()\n"); goto out; } } exfat_debug("verifying directory entries...\n"); ret = exfat_filesystem_check(&exfat_fsck); if (ret) goto out; if (exfat_fsck.options & FSCK_OPTS_RESCUE_CLUS) { rescue_orphan_clusters(&exfat_fsck); exfat_fsck.dirty = true; exfat_fsck.dirty_fat = true; } if (exfat_fsck.options & FSCK_OPTS_REPAIR_WRITE) { ret = write_bitmap(&exfat_fsck); if (ret) { exfat_err("failed to write bitmap\n"); goto out; } } if (ui.ei.writeable && fsync(bd.dev_fd)) { exfat_err("failed to sync\n"); ret = -EIO; goto out; } if (exfat_fsck.options & FSCK_OPTS_REPAIR_WRITE) exfat_mark_volume_dirty(exfat_fsck.exfat, false); out: exfat_show_info(&exfat_fsck, ui.ei.dev_name); err: if (ret && ret != -EINVAL) exit_code = FSCK_EXIT_OPERATION_ERROR; else if (ret == -EINVAL || exfat_stat.error_count != exfat_stat.fixed_count) exit_code = FSCK_EXIT_ERRORS_LEFT; else if (exfat_fsck.dirty) exit_code = FSCK_EXIT_CORRECTED; else exit_code = FSCK_EXIT_NO_ERRORS; if (exfat_fsck.buffer_desc) exfat_free_buffer(exfat_fsck.buffer_desc, 2); if (exfat_fsck.exfat) exfat_free_exfat(exfat_fsck.exfat); close(bd.dev_fd); return exit_code; }