// SPDX-License-Identifier: GPL-2.0-or-later /* * NTFS kernel super block handling. * * Copyright (c) 2001-2012 Anton Altaparmakov and Tuxera Inc. * Copyright (c) 2001,2002 Richard Russon * Copyright (c) 2025 LG Electronics Co., Ltd. */ #include /* For bdev_logical_block_size(). */ #include #include #include #include #include #include #include "sysctl.h" #include "logfile.h" #include "quota.h" #include "index.h" #include "ntfs.h" #include "ea.h" #include "volume.h" /* A global default upcase table and a corresponding reference count. */ static __le16 *default_upcase; static unsigned long ntfs_nr_upcase_users; static struct workqueue_struct *ntfs_wq; /* Error constants/strings used in inode.c::ntfs_show_options(). */ enum { /* One of these must be present, default is ON_ERRORS_CONTINUE. */ ON_ERRORS_PANIC = 0x01, ON_ERRORS_REMOUNT_RO = 0x02, ON_ERRORS_CONTINUE = 0x04, }; static const struct constant_table ntfs_param_enums[] = { { "panic", ON_ERRORS_PANIC }, { "remount-ro", ON_ERRORS_REMOUNT_RO }, { "continue", ON_ERRORS_CONTINUE }, {} }; enum { Opt_uid, Opt_gid, Opt_umask, Opt_dmask, Opt_fmask, Opt_errors, Opt_nls, Opt_charset, Opt_show_sys_files, Opt_show_meta, Opt_case_sensitive, Opt_disable_sparse, Opt_sparse, Opt_mft_zone_multiplier, Opt_preallocated_size, Opt_sys_immutable, Opt_nohidden, Opt_hide_dot_files, Opt_check_windows_names, Opt_acl, Opt_discard, Opt_nocase, }; static const struct fs_parameter_spec ntfs_parameters[] = { fsparam_u32("uid", Opt_uid), fsparam_u32("gid", Opt_gid), fsparam_u32oct("umask", Opt_umask), fsparam_u32oct("dmask", Opt_dmask), fsparam_u32oct("fmask", Opt_fmask), fsparam_string("nls", Opt_nls), fsparam_string("iocharset", Opt_charset), fsparam_enum("errors", Opt_errors, ntfs_param_enums), fsparam_flag("show_sys_files", Opt_show_sys_files), fsparam_flag("showmeta", Opt_show_meta), fsparam_flag("case_sensitive", Opt_case_sensitive), fsparam_flag("disable_sparse", Opt_disable_sparse), fsparam_s32("mft_zone_multiplier", Opt_mft_zone_multiplier), fsparam_u64("preallocated_size", Opt_preallocated_size), fsparam_flag("sys_immutable", Opt_sys_immutable), fsparam_flag("nohidden", Opt_nohidden), fsparam_flag("hide_dot_files", Opt_hide_dot_files), fsparam_flag("windows_names", Opt_check_windows_names), fsparam_flag("acl", Opt_acl), fsparam_flag("discard", Opt_discard), fsparam_flag("sparse", Opt_sparse), fsparam_flag("nocase", Opt_nocase), {} }; static int ntfs_parse_param(struct fs_context *fc, struct fs_parameter *param) { struct ntfs_volume *vol = fc->s_fs_info; struct fs_parse_result result; int opt; opt = fs_parse(fc, ntfs_parameters, param, &result); if (opt < 0) return opt; switch (opt) { case Opt_uid: vol->uid = make_kuid(current_user_ns(), result.uint_32); break; case Opt_gid: vol->gid = make_kgid(current_user_ns(), result.uint_32); break; case Opt_umask: vol->fmask = vol->dmask = result.uint_32; break; case Opt_dmask: vol->dmask = result.uint_32; break; case Opt_fmask: vol->fmask = result.uint_32; break; case Opt_errors: vol->on_errors = result.uint_32; break; case Opt_nls: case Opt_charset: if (vol->nls_map) unload_nls(vol->nls_map); vol->nls_map = load_nls(param->string); if (!vol->nls_map) { ntfs_error(vol->sb, "Failed to load NLS table '%s'.", param->string); return -EINVAL; } break; case Opt_mft_zone_multiplier: if (vol->mft_zone_multiplier && vol->mft_zone_multiplier != result.int_32) { ntfs_error(vol->sb, "Cannot change mft_zone_multiplier on remount."); return -EINVAL; } if (result.int_32 < 1 || result.int_32 > 4) { ntfs_error(vol->sb, "Invalid mft_zone_multiplier. Using default value, i.e. 1."); vol->mft_zone_multiplier = 1; } else vol->mft_zone_multiplier = result.int_32; break; case Opt_show_sys_files: case Opt_show_meta: if (result.boolean) NVolSetShowSystemFiles(vol); else NVolClearShowSystemFiles(vol); break; case Opt_case_sensitive: if (result.boolean) NVolSetCaseSensitive(vol); else NVolClearCaseSensitive(vol); break; case Opt_nocase: if (result.boolean) NVolClearCaseSensitive(vol); else NVolSetCaseSensitive(vol); break; case Opt_preallocated_size: vol->preallocated_size = (loff_t)result.uint_64; break; case Opt_sys_immutable: if (result.boolean) NVolSetSysImmutable(vol); else NVolClearSysImmutable(vol); break; case Opt_nohidden: if (result.boolean) NVolClearShowHiddenFiles(vol); else NVolSetShowHiddenFiles(vol); break; case Opt_hide_dot_files: if (result.boolean) NVolSetHideDotFiles(vol); else NVolClearHideDotFiles(vol); break; case Opt_check_windows_names: if (result.boolean) NVolSetCheckWindowsNames(vol); else NVolClearCheckWindowsNames(vol); break; case Opt_acl: #ifdef CONFIG_NTFS_FS_POSIX_ACL if (result.boolean) fc->sb_flags |= SB_POSIXACL; else fc->sb_flags &= ~SB_POSIXACL; break; #else return -EINVAL; #endif case Opt_discard: if (result.boolean) NVolSetDiscard(vol); else NVolClearDiscard(vol); break; case Opt_disable_sparse: if (result.boolean) NVolSetDisableSparse(vol); else NVolClearDisableSparse(vol); break; case Opt_sparse: break; default: return -EINVAL; } return 0; } static int ntfs_reconfigure(struct fs_context *fc) { struct super_block *sb = fc->root->d_sb; struct ntfs_volume *vol = NTFS_SB(sb); ntfs_debug("Entering with remount"); sync_filesystem(sb); /* * For the read-write compiled driver, if we are remounting read-write, * make sure there are no volume errors and that no unsupported volume * flags are set. Also, empty the logfile journal as it would become * stale as soon as something is written to the volume and mark the * volume dirty so that chkdsk is run if the volume is not umounted * cleanly. Finally, mark the quotas out of date so Windows rescans * the volume on boot and updates them. * * When remounting read-only, mark the volume clean if no volume errors * have occurred. */ if (sb_rdonly(sb) && !(fc->sb_flags & SB_RDONLY)) { static const char *es = ". Cannot remount read-write."; /* Remounting read-write. */ if (NVolErrors(vol)) { ntfs_error(sb, "Volume has errors and is read-only%s", es); return -EROFS; } if (vol->vol_flags & VOLUME_IS_DIRTY) { ntfs_error(sb, "Volume is dirty and read-only%s", es); return -EROFS; } if (vol->vol_flags & VOLUME_MODIFIED_BY_CHKDSK) { ntfs_error(sb, "Volume has been modified by chkdsk and is read-only%s", es); return -EROFS; } if (vol->vol_flags & VOLUME_MUST_MOUNT_RO_MASK) { ntfs_error(sb, "Volume has unsupported flags set (0x%x) and is read-only%s", le16_to_cpu(vol->vol_flags), es); return -EROFS; } if (vol->logfile_ino && !ntfs_empty_logfile(vol->logfile_ino)) { ntfs_error(sb, "Failed to empty journal LogFile%s", es); NVolSetErrors(vol); return -EROFS; } if (!ntfs_mark_quotas_out_of_date(vol)) { ntfs_error(sb, "Failed to mark quotas out of date%s", es); NVolSetErrors(vol); return -EROFS; } } else if (!sb_rdonly(sb) && (fc->sb_flags & SB_RDONLY)) { /* Remounting read-only. */ if (!NVolErrors(vol)) { if (ntfs_clear_volume_flags(vol, VOLUME_IS_DIRTY)) ntfs_warning(sb, "Failed to clear dirty bit in volume information flags. Run chkdsk."); } } ntfs_debug("Done."); return 0; } const struct option_t on_errors_arr[] = { { ON_ERRORS_PANIC, "panic" }, { ON_ERRORS_REMOUNT_RO, "remount-ro", }, { ON_ERRORS_CONTINUE, "continue", }, { 0, NULL } }; void ntfs_handle_error(struct super_block *sb) { struct ntfs_volume *vol = NTFS_SB(sb); if (sb_rdonly(sb)) return; if (vol->on_errors == ON_ERRORS_REMOUNT_RO) { sb->s_flags |= SB_RDONLY; pr_crit("(device %s): Filesystem has been set read-only\n", sb->s_id); } else if (vol->on_errors == ON_ERRORS_PANIC) { panic("ntfs: (device %s): panic from previous error\n", sb->s_id); } else if (vol->on_errors == ON_ERRORS_CONTINUE) { if (errseq_check(&sb->s_wb_err, vol->wb_err) == -ENODEV) { NVolSetShutdown(vol); vol->wb_err = sb->s_wb_err; } } } /* * ntfs_write_volume_flags - write new flags to the volume information flags * @vol: ntfs volume on which to modify the flags * @flags: new flags value for the volume information flags * * Internal function. You probably want to use ntfs_{set,clear}_volume_flags() * instead (see below). * * Replace the volume information flags on the volume @vol with the value * supplied in @flags. Note, this overwrites the volume information flags, so * make sure to combine the flags you want to modify with the old flags and use * the result when calling ntfs_write_volume_flags(). * * Return 0 on success and -errno on error. */ static int ntfs_write_volume_flags(struct ntfs_volume *vol, const __le16 flags) { struct ntfs_inode *ni = NTFS_I(vol->vol_ino); struct volume_information *vi; struct ntfs_attr_search_ctx *ctx; int err; ntfs_debug("Entering, old flags = 0x%x, new flags = 0x%x.", le16_to_cpu(vol->vol_flags), le16_to_cpu(flags)); mutex_lock(&ni->mrec_lock); if (vol->vol_flags == flags) goto done; ctx = ntfs_attr_get_search_ctx(ni, NULL); if (!ctx) { err = -ENOMEM; goto put_unm_err_out; } err = ntfs_attr_lookup(AT_VOLUME_INFORMATION, NULL, 0, 0, 0, NULL, 0, ctx); if (err) goto put_unm_err_out; vi = (struct volume_information *)((u8 *)ctx->attr + le16_to_cpu(ctx->attr->data.resident.value_offset)); vol->vol_flags = vi->flags = flags; mark_mft_record_dirty(ctx->ntfs_ino); ntfs_attr_put_search_ctx(ctx); done: mutex_unlock(&ni->mrec_lock); ntfs_debug("Done."); return 0; put_unm_err_out: if (ctx) ntfs_attr_put_search_ctx(ctx); mutex_unlock(&ni->mrec_lock); ntfs_error(vol->sb, "Failed with error code %i.", -err); return err; } /* * ntfs_set_volume_flags - set bits in the volume information flags * @vol: ntfs volume on which to modify the flags * @flags: flags to set on the volume * * Set the bits in @flags in the volume information flags on the volume @vol. * * Return 0 on success and -errno on error. */ int ntfs_set_volume_flags(struct ntfs_volume *vol, __le16 flags) { flags &= VOLUME_FLAGS_MASK; return ntfs_write_volume_flags(vol, vol->vol_flags | flags); } /* * ntfs_clear_volume_flags - clear bits in the volume information flags * @vol: ntfs volume on which to modify the flags * @flags: flags to clear on the volume * * Clear the bits in @flags in the volume information flags on the volume @vol. * * Return 0 on success and -errno on error. */ int ntfs_clear_volume_flags(struct ntfs_volume *vol, __le16 flags) { flags &= VOLUME_FLAGS_MASK; flags = vol->vol_flags & cpu_to_le16(~le16_to_cpu(flags)); return ntfs_write_volume_flags(vol, flags); } int ntfs_write_volume_label(struct ntfs_volume *vol, char *label) { struct ntfs_inode *vol_ni = NTFS_I(vol->vol_ino); struct ntfs_attr_search_ctx *ctx; __le16 *uname; int uname_len, ret; uname_len = ntfs_nlstoucs(vol, label, strlen(label), &uname, FSLABEL_MAX); if (uname_len < 0) { ntfs_error(vol->sb, "Failed to convert volume label '%s' to Unicode.", label); return uname_len; } if (uname_len > NTFS_MAX_LABEL_LEN) { ntfs_error(vol->sb, "Volume label is too long (max %d characters).", NTFS_MAX_LABEL_LEN); kvfree(uname); return -EINVAL; } mutex_lock(&vol_ni->mrec_lock); ctx = ntfs_attr_get_search_ctx(vol_ni, NULL); if (!ctx) { ret = -ENOMEM; goto out; } if (!ntfs_attr_lookup(AT_VOLUME_NAME, NULL, 0, 0, 0, NULL, 0, ctx)) ntfs_attr_record_rm(ctx); ntfs_attr_put_search_ctx(ctx); ret = ntfs_resident_attr_record_add(vol_ni, AT_VOLUME_NAME, AT_UNNAMED, 0, (u8 *)uname, uname_len * sizeof(__le16), 0); out: mutex_unlock(&vol_ni->mrec_lock); kvfree(uname); mark_inode_dirty_sync(vol->vol_ino); if (ret >= 0) { kfree(vol->volume_label); vol->volume_label = kstrdup(label, GFP_KERNEL); ret = 0; } return ret; } /* * is_boot_sector_ntfs - check whether a boot sector is a valid NTFS boot sector * @sb: Super block of the device to which @b belongs. * @b: Boot sector of device @sb to check. * @silent: If 'true', all output will be silenced. * * is_boot_sector_ntfs() checks whether the boot sector @b is a valid NTFS boot * sector. Returns 'true' if it is valid and 'false' if not. * * @sb is only needed for warning/error output, i.e. it can be NULL when silent * is 'true'. */ static bool is_boot_sector_ntfs(const struct super_block *sb, const struct ntfs_boot_sector *b, const bool silent) { /* * Check that checksum == sum of u32 values from b to the checksum * field. If checksum is zero, no checking is done. We will work when * the checksum test fails, since some utilities update the boot sector * ignoring the checksum which leaves the checksum out-of-date. We * report a warning if this is the case. */ if ((void *)b < (void *)&b->checksum && b->checksum && !silent) { __le32 *u; u32 i; for (i = 0, u = (__le32 *)b; u < (__le32 *)(&b->checksum); ++u) i += le32_to_cpup(u); if (le32_to_cpu(b->checksum) != i) ntfs_warning(sb, "Invalid boot sector checksum."); } /* Check OEMidentifier is "NTFS " */ if (b->oem_id != magicNTFS) goto not_ntfs; /* Check bytes per sector value is between 256 and 4096. */ if (le16_to_cpu(b->bpb.bytes_per_sector) < 0x100 || le16_to_cpu(b->bpb.bytes_per_sector) > 0x1000) goto not_ntfs; /* * Check sectors per cluster value is valid and the cluster size * is not above the maximum (2MB). */ if (b->bpb.sectors_per_cluster > 0x80 && b->bpb.sectors_per_cluster < 0xf4) goto not_ntfs; /* Check reserved/unused fields are really zero. */ if (le16_to_cpu(b->bpb.reserved_sectors) || le16_to_cpu(b->bpb.root_entries) || le16_to_cpu(b->bpb.sectors) || le16_to_cpu(b->bpb.sectors_per_fat) || le32_to_cpu(b->bpb.large_sectors) || b->bpb.fats) goto not_ntfs; /* Check clusters per file mft record value is valid. */ if ((u8)b->clusters_per_mft_record < 0xe1 || (u8)b->clusters_per_mft_record > 0xf7) switch (b->clusters_per_mft_record) { case 1: case 2: case 4: case 8: case 16: case 32: case 64: break; default: goto not_ntfs; } /* Check clusters per index block value is valid. */ if ((u8)b->clusters_per_index_record < 0xe1 || (u8)b->clusters_per_index_record > 0xf7) switch (b->clusters_per_index_record) { case 1: case 2: case 4: case 8: case 16: case 32: case 64: break; default: goto not_ntfs; } /* * Check for valid end of sector marker. We will work without it, but * many BIOSes will refuse to boot from a bootsector if the magic is * incorrect, so we emit a warning. */ if (!silent && b->end_of_sector_marker != cpu_to_le16(0xaa55)) ntfs_warning(sb, "Invalid end of sector marker."); return true; not_ntfs: return false; } /* * read_ntfs_boot_sector - read the NTFS boot sector of a device * @sb: super block of device to read the boot sector from * @silent: if true, suppress all output * * Reads the boot sector from the device and validates it. */ static char *read_ntfs_boot_sector(struct super_block *sb, const int silent) { char *boot_sector; boot_sector = kzalloc(PAGE_SIZE, GFP_NOFS); if (!boot_sector) return NULL; if (ntfs_bdev_read(sb->s_bdev, boot_sector, 0, PAGE_SIZE)) { if (!silent) ntfs_error(sb, "Unable to read primary boot sector."); kfree(boot_sector); return NULL; } if (!is_boot_sector_ntfs(sb, (struct ntfs_boot_sector *)boot_sector, silent)) { if (!silent) ntfs_error(sb, "Primary boot sector is invalid."); kfree(boot_sector); return NULL; } return boot_sector; } /* * parse_ntfs_boot_sector - parse the boot sector and store the data in @vol * @vol: volume structure to initialise with data from boot sector * @b: boot sector to parse * * Parse the ntfs boot sector @b and store all imporant information therein in * the ntfs super block @vol. Return 'true' on success and 'false' on error. */ static bool parse_ntfs_boot_sector(struct ntfs_volume *vol, const struct ntfs_boot_sector *b) { unsigned int sectors_per_cluster, sectors_per_cluster_bits, nr_hidden_sects; int clusters_per_mft_record, clusters_per_index_record; s64 ll; vol->sector_size = le16_to_cpu(b->bpb.bytes_per_sector); vol->sector_size_bits = ffs(vol->sector_size) - 1; ntfs_debug("vol->sector_size = %i (0x%x)", vol->sector_size, vol->sector_size); ntfs_debug("vol->sector_size_bits = %i (0x%x)", vol->sector_size_bits, vol->sector_size_bits); if (vol->sector_size < vol->sb->s_blocksize) { ntfs_error(vol->sb, "Sector size (%i) is smaller than the device block size (%lu). This is not supported.", vol->sector_size, vol->sb->s_blocksize); return false; } if (b->bpb.sectors_per_cluster >= 0xf4) sectors_per_cluster = 1U << -(s8)b->bpb.sectors_per_cluster; else sectors_per_cluster = b->bpb.sectors_per_cluster; ntfs_debug("sectors_per_cluster = 0x%x", b->bpb.sectors_per_cluster); sectors_per_cluster_bits = ffs(sectors_per_cluster) - 1; ntfs_debug("sectors_per_cluster_bits = 0x%x", sectors_per_cluster_bits); nr_hidden_sects = le32_to_cpu(b->bpb.hidden_sectors); ntfs_debug("number of hidden sectors = 0x%x", nr_hidden_sects); vol->cluster_size = vol->sector_size << sectors_per_cluster_bits; vol->cluster_size_mask = vol->cluster_size - 1; vol->cluster_size_bits = ffs(vol->cluster_size) - 1; ntfs_debug("vol->cluster_size = %i (0x%x)", vol->cluster_size, vol->cluster_size); ntfs_debug("vol->cluster_size_mask = 0x%x", vol->cluster_size_mask); ntfs_debug("vol->cluster_size_bits = %i", vol->cluster_size_bits); if (vol->cluster_size < vol->sector_size) { ntfs_error(vol->sb, "Cluster size (%i) is smaller than the sector size (%i). This is not supported.", vol->cluster_size, vol->sector_size); return false; } clusters_per_mft_record = b->clusters_per_mft_record; ntfs_debug("clusters_per_mft_record = %i (0x%x)", clusters_per_mft_record, clusters_per_mft_record); if (clusters_per_mft_record > 0) vol->mft_record_size = vol->cluster_size << (ffs(clusters_per_mft_record) - 1); else /* * When mft_record_size < cluster_size, clusters_per_mft_record * = -log2(mft_record_size) bytes. mft_record_size normaly is * 1024 bytes, which is encoded as 0xF6 (-10 in decimal). */ vol->mft_record_size = 1 << -clusters_per_mft_record; vol->mft_record_size_mask = vol->mft_record_size - 1; vol->mft_record_size_bits = ffs(vol->mft_record_size) - 1; ntfs_debug("vol->mft_record_size = %i (0x%x)", vol->mft_record_size, vol->mft_record_size); ntfs_debug("vol->mft_record_size_mask = 0x%x", vol->mft_record_size_mask); ntfs_debug("vol->mft_record_size_bits = %i (0x%x)", vol->mft_record_size_bits, vol->mft_record_size_bits); /* * We cannot support mft record sizes above the PAGE_SIZE since * we store $MFT/$DATA, the table of mft records in the page cache. */ if (vol->mft_record_size > PAGE_SIZE) { ntfs_error(vol->sb, "Mft record size (%i) exceeds the PAGE_SIZE on your system (%lu). This is not supported.", vol->mft_record_size, PAGE_SIZE); return false; } /* We cannot support mft record sizes below the sector size. */ if (vol->mft_record_size < vol->sector_size) { ntfs_warning(vol->sb, "Mft record size (%i) is smaller than the sector size (%i).", vol->mft_record_size, vol->sector_size); } clusters_per_index_record = b->clusters_per_index_record; ntfs_debug("clusters_per_index_record = %i (0x%x)", clusters_per_index_record, clusters_per_index_record); if (clusters_per_index_record > 0) vol->index_record_size = vol->cluster_size << (ffs(clusters_per_index_record) - 1); else /* * When index_record_size < cluster_size, * clusters_per_index_record = -log2(index_record_size) bytes. * index_record_size normaly equals 4096 bytes, which is * encoded as 0xF4 (-12 in decimal). */ vol->index_record_size = 1 << -clusters_per_index_record; vol->index_record_size_mask = vol->index_record_size - 1; vol->index_record_size_bits = ffs(vol->index_record_size) - 1; ntfs_debug("vol->index_record_size = %i (0x%x)", vol->index_record_size, vol->index_record_size); ntfs_debug("vol->index_record_size_mask = 0x%x", vol->index_record_size_mask); ntfs_debug("vol->index_record_size_bits = %i (0x%x)", vol->index_record_size_bits, vol->index_record_size_bits); /* We cannot support index record sizes below the sector size. */ if (vol->index_record_size < vol->sector_size) { ntfs_error(vol->sb, "Index record size (%i) is smaller than the sector size (%i). This is not supported.", vol->index_record_size, vol->sector_size); return false; } /* * Get the size of the volume in clusters and check for 64-bit-ness. * Windows currently only uses 32 bits to save the clusters so we do * the same as it is much faster on 32-bit CPUs. */ ll = le64_to_cpu(b->number_of_sectors) >> sectors_per_cluster_bits; if ((u64)ll >= 1ULL << 32) { ntfs_error(vol->sb, "Cannot handle 64-bit clusters."); return false; } vol->nr_clusters = ll; ntfs_debug("vol->nr_clusters = 0x%llx", vol->nr_clusters); ll = le64_to_cpu(b->mft_lcn); if (ll >= vol->nr_clusters) { ntfs_error(vol->sb, "MFT LCN (%lli, 0x%llx) is beyond end of volume. Weird.", ll, ll); return false; } vol->mft_lcn = ll; ntfs_debug("vol->mft_lcn = 0x%llx", vol->mft_lcn); ll = le64_to_cpu(b->mftmirr_lcn); if (ll >= vol->nr_clusters) { ntfs_error(vol->sb, "MFTMirr LCN (%lli, 0x%llx) is beyond end of volume. Weird.", ll, ll); return false; } vol->mftmirr_lcn = ll; ntfs_debug("vol->mftmirr_lcn = 0x%llx", vol->mftmirr_lcn); /* * Work out the size of the mft mirror in number of mft records. If the * cluster size is less than or equal to the size taken by four mft * records, the mft mirror stores the first four mft records. If the * cluster size is bigger than the size taken by four mft records, the * mft mirror contains as many mft records as will fit into one * cluster. */ if (vol->cluster_size <= (4 << vol->mft_record_size_bits)) vol->mftmirr_size = 4; else vol->mftmirr_size = vol->cluster_size >> vol->mft_record_size_bits; ntfs_debug("vol->mftmirr_size = %i", vol->mftmirr_size); vol->serial_no = le64_to_cpu(b->volume_serial_number); ntfs_debug("vol->serial_no = 0x%llx", vol->serial_no); vol->sparse_compression_unit = 4; if (vol->cluster_size > 4096) { switch (vol->cluster_size) { case 65536: vol->sparse_compression_unit = 0; break; case 32768: vol->sparse_compression_unit = 1; break; case 16384: vol->sparse_compression_unit = 2; break; case 8192: vol->sparse_compression_unit = 3; break; } } return true; } /* * ntfs_setup_allocators - initialize the cluster and mft allocators * @vol: volume structure for which to setup the allocators * * Setup the cluster (lcn) and mft allocators to the starting values. */ static void ntfs_setup_allocators(struct ntfs_volume *vol) { s64 mft_zone_size, mft_lcn; ntfs_debug("vol->mft_zone_multiplier = 0x%x", vol->mft_zone_multiplier); /* Determine the size of the MFT zone. */ mft_zone_size = vol->nr_clusters; switch (vol->mft_zone_multiplier) { /* % of volume size in clusters */ case 4: mft_zone_size >>= 1; /* 50% */ break; case 3: mft_zone_size = (mft_zone_size + (mft_zone_size >> 1)) >> 2; /* 37.5% */ break; case 2: mft_zone_size >>= 2; /* 25% */ break; /* case 1: */ default: mft_zone_size >>= 3; /* 12.5% */ break; } /* Setup the mft zone. */ vol->mft_zone_start = vol->mft_zone_pos = vol->mft_lcn; ntfs_debug("vol->mft_zone_pos = 0x%llx", vol->mft_zone_pos); /* * Calculate the mft_lcn for an unmodified NTFS volume (see mkntfs * source) and if the actual mft_lcn is in the expected place or even * further to the front of the volume, extend the mft_zone to cover the * beginning of the volume as well. This is in order to protect the * area reserved for the mft bitmap as well within the mft_zone itself. * On non-standard volumes we do not protect it as the overhead would * be higher than the speed increase we would get by doing it. */ mft_lcn = NTFS_B_TO_CLU(vol, 8192 + 2 * vol->cluster_size - 1); if (mft_lcn * vol->cluster_size < 16 * 1024) mft_lcn = (16 * 1024 + vol->cluster_size - 1) >> vol->cluster_size_bits; if (vol->mft_zone_start <= mft_lcn) vol->mft_zone_start = 0; ntfs_debug("vol->mft_zone_start = 0x%llx", vol->mft_zone_start); /* * Need to cap the mft zone on non-standard volumes so that it does * not point outside the boundaries of the volume. We do this by * halving the zone size until we are inside the volume. */ vol->mft_zone_end = vol->mft_lcn + mft_zone_size; while (vol->mft_zone_end >= vol->nr_clusters) { mft_zone_size >>= 1; vol->mft_zone_end = vol->mft_lcn + mft_zone_size; } ntfs_debug("vol->mft_zone_end = 0x%llx", vol->mft_zone_end); /* * Set the current position within each data zone to the start of the * respective zone. */ vol->data1_zone_pos = vol->mft_zone_end; ntfs_debug("vol->data1_zone_pos = 0x%llx", vol->data1_zone_pos); vol->data2_zone_pos = 0; ntfs_debug("vol->data2_zone_pos = 0x%llx", vol->data2_zone_pos); /* Set the mft data allocation position to mft record 24. */ vol->mft_data_pos = 24; ntfs_debug("vol->mft_data_pos = 0x%llx", vol->mft_data_pos); } static struct lock_class_key mftmirr_runlist_lock_key, mftmirr_mrec_lock_key; /* * load_and_init_mft_mirror - load and setup the mft mirror inode for a volume * @vol: ntfs super block describing device whose mft mirror to load * * Return 'true' on success or 'false' on error. */ static bool load_and_init_mft_mirror(struct ntfs_volume *vol) { struct inode *tmp_ino; struct ntfs_inode *tmp_ni; ntfs_debug("Entering."); /* Get mft mirror inode. */ tmp_ino = ntfs_iget(vol->sb, FILE_MFTMirr); if (IS_ERR(tmp_ino)) { if (!IS_ERR(tmp_ino)) iput(tmp_ino); /* Caller will display error message. */ return false; } lockdep_set_class(&NTFS_I(tmp_ino)->runlist.lock, &mftmirr_runlist_lock_key); lockdep_set_class(&NTFS_I(tmp_ino)->mrec_lock, &mftmirr_mrec_lock_key); /* * Re-initialize some specifics about $MFTMirr's inode as * ntfs_read_inode() will have set up the default ones. */ /* Set uid and gid to root. */ tmp_ino->i_uid = GLOBAL_ROOT_UID; tmp_ino->i_gid = GLOBAL_ROOT_GID; /* Regular file. No access for anyone. */ tmp_ino->i_mode = S_IFREG; /* No VFS initiated operations allowed for $MFTMirr. */ tmp_ino->i_op = &ntfs_empty_inode_ops; tmp_ino->i_fop = &ntfs_empty_file_ops; /* Put in our special address space operations. */ tmp_ino->i_mapping->a_ops = &ntfs_aops; tmp_ni = NTFS_I(tmp_ino); /* The $MFTMirr, like the $MFT is multi sector transfer protected. */ NInoSetMstProtected(tmp_ni); NInoSetSparseDisabled(tmp_ni); /* * Set up our little cheat allowing us to reuse the async read io * completion handler for directories. */ tmp_ni->itype.index.block_size = vol->mft_record_size; tmp_ni->itype.index.block_size_bits = vol->mft_record_size_bits; vol->mftmirr_ino = tmp_ino; ntfs_debug("Done."); return true; } /* * check_mft_mirror - compare contents of the mft mirror with the mft * @vol: ntfs super block describing device whose mft mirror to check * * Return 'true' on success or 'false' on error. * * Note, this function also results in the mft mirror runlist being completely * mapped into memory. The mft mirror write code requires this and will BUG() * should it find an unmapped runlist element. */ static bool check_mft_mirror(struct ntfs_volume *vol) { struct super_block *sb = vol->sb; struct ntfs_inode *mirr_ni; struct folio *mft_folio = NULL, *mirr_folio = NULL; u8 *kmft = NULL, *kmirr = NULL; struct runlist_element *rl, rl2[2]; pgoff_t index; int mrecs_per_page, i; ntfs_debug("Entering."); /* Compare contents of $MFT and $MFTMirr. */ mrecs_per_page = PAGE_SIZE / vol->mft_record_size; index = i = 0; do { u32 bytes; /* Switch pages if necessary. */ if (!(i % mrecs_per_page)) { if (index) { kunmap_local(kmirr); folio_put(mirr_folio); kunmap_local(kmft); folio_put(mft_folio); } /* Get the $MFT page. */ mft_folio = read_mapping_folio(vol->mft_ino->i_mapping, index, NULL); if (IS_ERR(mft_folio)) { ntfs_error(sb, "Failed to read $MFT."); return false; } kmft = kmap_local_folio(mft_folio, 0); /* Get the $MFTMirr page. */ mirr_folio = read_mapping_folio(vol->mftmirr_ino->i_mapping, index, NULL); if (IS_ERR(mirr_folio)) { ntfs_error(sb, "Failed to read $MFTMirr."); goto mft_unmap_out; } kmirr = kmap_local_folio(mirr_folio, 0); ++index; } /* Do not check the record if it is not in use. */ if (((struct mft_record *)kmft)->flags & MFT_RECORD_IN_USE) { /* Make sure the record is ok. */ if (ntfs_is_baad_recordp((__le32 *)kmft)) { ntfs_error(sb, "Incomplete multi sector transfer detected in mft record %i.", i); mm_unmap_out: kunmap_local(kmirr); folio_put(mirr_folio); mft_unmap_out: kunmap_local(kmft); folio_put(mft_folio); return false; } } /* Do not check the mirror record if it is not in use. */ if (((struct mft_record *)kmirr)->flags & MFT_RECORD_IN_USE) { if (ntfs_is_baad_recordp((__le32 *)kmirr)) { ntfs_error(sb, "Incomplete multi sector transfer detected in mft mirror record %i.", i); goto mm_unmap_out; } } /* Get the amount of data in the current record. */ bytes = le32_to_cpu(((struct mft_record *)kmft)->bytes_in_use); if (bytes < sizeof(struct mft_record_old) || bytes > vol->mft_record_size || ntfs_is_baad_recordp((__le32 *)kmft)) { bytes = le32_to_cpu(((struct mft_record *)kmirr)->bytes_in_use); if (bytes < sizeof(struct mft_record_old) || bytes > vol->mft_record_size || ntfs_is_baad_recordp((__le32 *)kmirr)) bytes = vol->mft_record_size; } kmft += vol->mft_record_size; kmirr += vol->mft_record_size; } while (++i < vol->mftmirr_size); /* Release the last folios. */ kunmap_local(kmirr); folio_put(mirr_folio); kunmap_local(kmft); folio_put(mft_folio); /* Construct the mft mirror runlist by hand. */ rl2[0].vcn = 0; rl2[0].lcn = vol->mftmirr_lcn; rl2[0].length = NTFS_B_TO_CLU(vol, vol->mftmirr_size * vol->mft_record_size + vol->cluster_size - 1); rl2[1].vcn = rl2[0].length; rl2[1].lcn = LCN_ENOENT; rl2[1].length = 0; /* * Because we have just read all of the mft mirror, we know we have * mapped the full runlist for it. */ mirr_ni = NTFS_I(vol->mftmirr_ino); down_read(&mirr_ni->runlist.lock); rl = mirr_ni->runlist.rl; /* Compare the two runlists. They must be identical. */ i = 0; do { if (rl2[i].vcn != rl[i].vcn || rl2[i].lcn != rl[i].lcn || rl2[i].length != rl[i].length) { ntfs_error(sb, "$MFTMirr location mismatch. Run chkdsk."); up_read(&mirr_ni->runlist.lock); return false; } } while (rl2[i++].length); up_read(&mirr_ni->runlist.lock); ntfs_debug("Done."); return true; } /* * load_and_check_logfile - load and check the logfile inode for a volume * @vol: ntfs volume to load the logfile for * @rp: on success, set to the restart page header * * Return 0 on success or errno on error. */ static int load_and_check_logfile(struct ntfs_volume *vol, struct restart_page_header **rp) { struct inode *tmp_ino; int err = 0; ntfs_debug("Entering."); tmp_ino = ntfs_iget(vol->sb, FILE_LogFile); if (IS_ERR(tmp_ino)) { if (!IS_ERR(tmp_ino)) iput(tmp_ino); /* Caller will display error message. */ return -ENOENT; } if (!ntfs_check_logfile(tmp_ino, rp)) err = -EINVAL; NInoSetSparseDisabled(NTFS_I(tmp_ino)); vol->logfile_ino = tmp_ino; ntfs_debug("Done."); return err; } #define NTFS_HIBERFIL_HEADER_SIZE 4096 /* * check_windows_hibernation_status - check if Windows is suspended on a volume * @vol: ntfs super block of device to check * * Check if Windows is hibernated on the ntfs volume @vol. This is done by * looking for the file hiberfil.sys in the root directory of the volume. If * the file is not present Windows is definitely not suspended. * * If hiberfil.sys exists and is less than 4kiB in size it means Windows is * definitely suspended (this volume is not the system volume). Caveat: on a * system with many volumes it is possible that the < 4kiB check is bogus but * for now this should do fine. * * If hiberfil.sys exists and is larger than 4kiB in size, we need to read the * hiberfil header (which is the first 4kiB). If this begins with "hibr", * Windows is definitely suspended. If it is completely full of zeroes, * Windows is definitely not hibernated. Any other case is treated as if * Windows is suspended. This caters for the above mentioned caveat of a * system with many volumes where no "hibr" magic would be present and there is * no zero header. * * Return 0 if Windows is not hibernated on the volume, >0 if Windows is * hibernated on the volume, and -errno on error. */ static int check_windows_hibernation_status(struct ntfs_volume *vol) { static const __le16 hiberfil[13] = { cpu_to_le16('h'), cpu_to_le16('i'), cpu_to_le16('b'), cpu_to_le16('e'), cpu_to_le16('r'), cpu_to_le16('f'), cpu_to_le16('i'), cpu_to_le16('l'), cpu_to_le16('.'), cpu_to_le16('s'), cpu_to_le16('y'), cpu_to_le16('s'), 0 }; u64 mref; struct inode *vi; struct folio *folio; u32 *kaddr, *kend, *start_addr = NULL; struct ntfs_name *name = NULL; int ret = 1; ntfs_debug("Entering."); /* * Find the inode number for the hibernation file by looking up the * filename hiberfil.sys in the root directory. */ inode_lock(vol->root_ino); mref = ntfs_lookup_inode_by_name(NTFS_I(vol->root_ino), hiberfil, 12, &name); inode_unlock(vol->root_ino); kfree(name); if (IS_ERR_MREF(mref)) { ret = MREF_ERR(mref); /* If the file does not exist, Windows is not hibernated. */ if (ret == -ENOENT) { ntfs_debug("hiberfil.sys not present. Windows is not hibernated on the volume."); return 0; } /* A real error occurred. */ ntfs_error(vol->sb, "Failed to find inode number for hiberfil.sys."); return ret; } /* Get the inode. */ vi = ntfs_iget(vol->sb, MREF(mref)); if (IS_ERR(vi)) { if (!IS_ERR(vi)) iput(vi); ntfs_error(vol->sb, "Failed to load hiberfil.sys."); return IS_ERR(vi) ? PTR_ERR(vi) : -EIO; } if (unlikely(i_size_read(vi) < NTFS_HIBERFIL_HEADER_SIZE)) { ntfs_debug("hiberfil.sys is smaller than 4kiB (0x%llx). Windows is hibernated on the volume. This is not the system volume.", i_size_read(vi)); goto iput_out; } folio = read_mapping_folio(vi->i_mapping, 0, NULL); if (IS_ERR(folio)) { ntfs_error(vol->sb, "Failed to read from hiberfil.sys."); ret = PTR_ERR(folio); goto iput_out; } start_addr = (u32 *)kmap_local_folio(folio, 0); kaddr = start_addr; if (*(__le32 *)kaddr == cpu_to_le32(0x72626968)/*'hibr'*/) { ntfs_debug("Magic \"hibr\" found in hiberfil.sys. Windows is hibernated on the volume. This is the system volume."); goto unm_iput_out; } kend = kaddr + NTFS_HIBERFIL_HEADER_SIZE/sizeof(*kaddr); do { if (unlikely(*kaddr)) { ntfs_debug("hiberfil.sys is larger than 4kiB (0x%llx), does not contain the \"hibr\" magic, and does not have a zero header. Windows is hibernated on the volume. This is not the system volume.", i_size_read(vi)); goto unm_iput_out; } } while (++kaddr < kend); ntfs_debug("hiberfil.sys contains a zero header. Windows is not hibernated on the volume. This is the system volume."); ret = 0; unm_iput_out: kunmap_local(start_addr); folio_put(folio); iput_out: iput(vi); return ret; } /* * load_and_init_quota - load and setup the quota file for a volume if present * @vol: ntfs super block describing device whose quota file to load * * Return 'true' on success or 'false' on error. If $Quota is not present, we * leave vol->quota_ino as NULL and return success. */ static bool load_and_init_quota(struct ntfs_volume *vol) { static const __le16 Quota[7] = { cpu_to_le16('$'), cpu_to_le16('Q'), cpu_to_le16('u'), cpu_to_le16('o'), cpu_to_le16('t'), cpu_to_le16('a'), 0 }; static __le16 Q[3] = { cpu_to_le16('$'), cpu_to_le16('Q'), 0 }; struct ntfs_name *name = NULL; u64 mref; struct inode *tmp_ino; ntfs_debug("Entering."); /* * Find the inode number for the quota file by looking up the filename * $Quota in the extended system files directory $Extend. */ inode_lock(vol->extend_ino); mref = ntfs_lookup_inode_by_name(NTFS_I(vol->extend_ino), Quota, 6, &name); inode_unlock(vol->extend_ino); kfree(name); if (IS_ERR_MREF(mref)) { /* * If the file does not exist, quotas are disabled and have * never been enabled on this volume, just return success. */ if (MREF_ERR(mref) == -ENOENT) { ntfs_debug("$Quota not present. Volume does not have quotas enabled."); /* * No need to try to set quotas out of date if they are * not enabled. */ NVolSetQuotaOutOfDate(vol); return true; } /* A real error occurred. */ ntfs_error(vol->sb, "Failed to find inode number for $Quota."); return false; } /* Get the inode. */ tmp_ino = ntfs_iget(vol->sb, MREF(mref)); if (IS_ERR(tmp_ino)) { if (!IS_ERR(tmp_ino)) iput(tmp_ino); ntfs_error(vol->sb, "Failed to load $Quota."); return false; } vol->quota_ino = tmp_ino; /* Get the $Q index allocation attribute. */ tmp_ino = ntfs_index_iget(vol->quota_ino, Q, 2); if (IS_ERR(tmp_ino)) { ntfs_error(vol->sb, "Failed to load $Quota/$Q index."); return false; } vol->quota_q_ino = tmp_ino; ntfs_debug("Done."); return true; } /* * load_and_init_attrdef - load the attribute definitions table for a volume * @vol: ntfs super block describing device whose attrdef to load * * Return 'true' on success or 'false' on error. */ static bool load_and_init_attrdef(struct ntfs_volume *vol) { loff_t i_size; struct super_block *sb = vol->sb; struct inode *ino; struct folio *folio; u8 *addr; pgoff_t index, max_index; unsigned int size; ntfs_debug("Entering."); /* Read attrdef table and setup vol->attrdef and vol->attrdef_size. */ ino = ntfs_iget(sb, FILE_AttrDef); if (IS_ERR(ino)) { if (!IS_ERR(ino)) iput(ino); goto failed; } NInoSetSparseDisabled(NTFS_I(ino)); /* The size of FILE_AttrDef must be above 0 and fit inside 31 bits. */ i_size = i_size_read(ino); if (i_size <= 0 || i_size > 0x7fffffff) goto iput_failed; vol->attrdef = kvzalloc(i_size, GFP_NOFS); if (!vol->attrdef) goto iput_failed; index = 0; max_index = i_size >> PAGE_SHIFT; size = PAGE_SIZE; while (index < max_index) { /* Read the attrdef table and copy it into the linear buffer. */ read_partial_attrdef_page: folio = read_mapping_folio(ino->i_mapping, index, NULL); if (IS_ERR(folio)) goto free_iput_failed; addr = kmap_local_folio(folio, 0); memcpy((u8 *)vol->attrdef + (index++ << PAGE_SHIFT), addr, size); kunmap_local(addr); folio_put(folio); } if (size == PAGE_SIZE) { size = i_size & ~PAGE_MASK; if (size) goto read_partial_attrdef_page; } vol->attrdef_size = i_size; ntfs_debug("Read %llu bytes from $AttrDef.", i_size); iput(ino); return true; free_iput_failed: kvfree(vol->attrdef); vol->attrdef = NULL; iput_failed: iput(ino); failed: ntfs_error(sb, "Failed to initialize attribute definition table."); return false; } /* * load_and_init_upcase - load the upcase table for an ntfs volume * @vol: ntfs super block describing device whose upcase to load * * Return 'true' on success or 'false' on error. */ static bool load_and_init_upcase(struct ntfs_volume *vol) { loff_t i_size; struct super_block *sb = vol->sb; struct inode *ino; struct folio *folio; u8 *addr; pgoff_t index, max_index; unsigned int size; int i, max; ntfs_debug("Entering."); /* Read upcase table and setup vol->upcase and vol->upcase_len. */ ino = ntfs_iget(sb, FILE_UpCase); if (IS_ERR(ino)) { if (!IS_ERR(ino)) iput(ino); goto upcase_failed; } /* * The upcase size must not be above 64k Unicode characters, must not * be zero and must be a multiple of sizeof(__le16). */ i_size = i_size_read(ino); if (!i_size || i_size & (sizeof(__le16) - 1) || i_size > 64ULL * 1024 * sizeof(__le16)) goto iput_upcase_failed; vol->upcase = kvzalloc(i_size, GFP_NOFS); if (!vol->upcase) goto iput_upcase_failed; index = 0; max_index = i_size >> PAGE_SHIFT; size = PAGE_SIZE; while (index < max_index) { /* Read the upcase table and copy it into the linear buffer. */ read_partial_upcase_page: folio = read_mapping_folio(ino->i_mapping, index, NULL); if (IS_ERR(folio)) goto iput_upcase_failed; addr = kmap_local_folio(folio, 0); memcpy((char *)vol->upcase + (index++ << PAGE_SHIFT), addr, size); kunmap_local(addr); folio_put(folio); } if (size == PAGE_SIZE) { size = i_size & ~PAGE_MASK; if (size) goto read_partial_upcase_page; } vol->upcase_len = i_size >> sizeof(unsigned char); ntfs_debug("Read %llu bytes from $UpCase (expected %zu bytes).", i_size, 64 * 1024 * sizeof(__le16)); iput(ino); mutex_lock(&ntfs_lock); if (!default_upcase) { ntfs_debug("Using volume specified $UpCase since default is not present."); mutex_unlock(&ntfs_lock); return true; } max = default_upcase_len; if (max > vol->upcase_len) max = vol->upcase_len; for (i = 0; i < max; i++) if (vol->upcase[i] != default_upcase[i]) break; if (i == max) { kvfree(vol->upcase); vol->upcase = default_upcase; vol->upcase_len = max; ntfs_nr_upcase_users++; mutex_unlock(&ntfs_lock); ntfs_debug("Volume specified $UpCase matches default. Using default."); return true; } mutex_unlock(&ntfs_lock); ntfs_debug("Using volume specified $UpCase since it does not match the default."); return true; iput_upcase_failed: iput(ino); kvfree(vol->upcase); vol->upcase = NULL; upcase_failed: mutex_lock(&ntfs_lock); if (default_upcase) { vol->upcase = default_upcase; vol->upcase_len = default_upcase_len; ntfs_nr_upcase_users++; mutex_unlock(&ntfs_lock); ntfs_error(sb, "Failed to load $UpCase from the volume. Using default."); return true; } mutex_unlock(&ntfs_lock); ntfs_error(sb, "Failed to initialize upcase table."); return false; } /* * The lcn and mft bitmap inodes are NTFS-internal inodes with * their own special locking rules: */ static struct lock_class_key lcnbmp_runlist_lock_key, lcnbmp_mrec_lock_key, mftbmp_runlist_lock_key, mftbmp_mrec_lock_key; /* * load_system_files - open the system files using normal functions * @vol: ntfs super block describing device whose system files to load * * Open the system files with normal access functions and complete setting up * the ntfs super block @vol. * * Return 'true' on success or 'false' on error. */ static bool load_system_files(struct ntfs_volume *vol) { struct super_block *sb = vol->sb; struct mft_record *m; struct volume_information *vi; struct ntfs_attr_search_ctx *ctx; struct restart_page_header *rp; int err; ntfs_debug("Entering."); /* Get mft mirror inode compare the contents of $MFT and $MFTMirr. */ if (!load_and_init_mft_mirror(vol) || !check_mft_mirror(vol)) { /* If a read-write mount, convert it to a read-only mount. */ if (!sb_rdonly(sb) && vol->on_errors == ON_ERRORS_REMOUNT_RO) { static const char *es1 = "Failed to load $MFTMirr"; static const char *es2 = "$MFTMirr does not match $MFT"; static const char *es3 = ". Run ntfsck and/or chkdsk."; sb->s_flags |= SB_RDONLY; ntfs_error(sb, "%s. Mounting read-only%s", !vol->mftmirr_ino ? es1 : es2, es3); } NVolSetErrors(vol); } /* Get mft bitmap attribute inode. */ vol->mftbmp_ino = ntfs_attr_iget(vol->mft_ino, AT_BITMAP, NULL, 0); if (IS_ERR(vol->mftbmp_ino)) { ntfs_error(sb, "Failed to load $MFT/$BITMAP attribute."); goto iput_mirr_err_out; } lockdep_set_class(&NTFS_I(vol->mftbmp_ino)->runlist.lock, &mftbmp_runlist_lock_key); lockdep_set_class(&NTFS_I(vol->mftbmp_ino)->mrec_lock, &mftbmp_mrec_lock_key); /* Read upcase table and setup @vol->upcase and @vol->upcase_len. */ if (!load_and_init_upcase(vol)) goto iput_mftbmp_err_out; /* * Read attribute definitions table and setup @vol->attrdef and * @vol->attrdef_size. */ if (!load_and_init_attrdef(vol)) goto iput_upcase_err_out; /* * Get the cluster allocation bitmap inode and verify the size, no * need for any locking at this stage as we are already running * exclusively as we are mount in progress task. */ vol->lcnbmp_ino = ntfs_iget(sb, FILE_Bitmap); if (IS_ERR(vol->lcnbmp_ino)) { if (!IS_ERR(vol->lcnbmp_ino)) iput(vol->lcnbmp_ino); goto bitmap_failed; } lockdep_set_class(&NTFS_I(vol->lcnbmp_ino)->runlist.lock, &lcnbmp_runlist_lock_key); lockdep_set_class(&NTFS_I(vol->lcnbmp_ino)->mrec_lock, &lcnbmp_mrec_lock_key); NInoSetSparseDisabled(NTFS_I(vol->lcnbmp_ino)); if ((vol->nr_clusters + 7) >> 3 > i_size_read(vol->lcnbmp_ino)) { iput(vol->lcnbmp_ino); bitmap_failed: ntfs_error(sb, "Failed to load $Bitmap."); goto iput_attrdef_err_out; } /* * Get the volume inode and setup our cache of the volume flags and * version. */ vol->vol_ino = ntfs_iget(sb, FILE_Volume); if (IS_ERR(vol->vol_ino)) { if (!IS_ERR(vol->vol_ino)) iput(vol->vol_ino); volume_failed: ntfs_error(sb, "Failed to load $Volume."); goto iput_lcnbmp_err_out; } m = map_mft_record(NTFS_I(vol->vol_ino)); if (IS_ERR(m)) { iput_volume_failed: iput(vol->vol_ino); goto volume_failed; } ctx = ntfs_attr_get_search_ctx(NTFS_I(vol->vol_ino), m); if (!ctx) { ntfs_error(sb, "Failed to get attribute search context."); goto get_ctx_vol_failed; } if (!ntfs_attr_lookup(AT_VOLUME_NAME, NULL, 0, 0, 0, NULL, 0, ctx) && !ctx->attr->non_resident && !(ctx->attr->flags & (ATTR_IS_SPARSE | ATTR_IS_COMPRESSED)) && le32_to_cpu(ctx->attr->data.resident.value_length) > 0) { err = ntfs_ucstonls(vol, (__le16 *)((u8 *)ctx->attr + le16_to_cpu(ctx->attr->data.resident.value_offset)), le32_to_cpu(ctx->attr->data.resident.value_length) / 2, &vol->volume_label, NTFS_MAX_LABEL_LEN); if (err < 0) vol->volume_label = NULL; } if (ntfs_attr_lookup(AT_VOLUME_INFORMATION, NULL, 0, 0, 0, NULL, 0, ctx) || ctx->attr->non_resident || ctx->attr->flags) { ntfs_attr_put_search_ctx(ctx); get_ctx_vol_failed: unmap_mft_record(NTFS_I(vol->vol_ino)); goto iput_volume_failed; } vi = (struct volume_information *)((char *)ctx->attr + le16_to_cpu(ctx->attr->data.resident.value_offset)); /* Copy the volume flags and version to the struct ntfs_volume structure. */ vol->vol_flags = vi->flags; vol->major_ver = vi->major_ver; vol->minor_ver = vi->minor_ver; ntfs_attr_put_search_ctx(ctx); unmap_mft_record(NTFS_I(vol->vol_ino)); pr_info("volume version %i.%i, dev %s, cluster size %d\n", vol->major_ver, vol->minor_ver, sb->s_id, vol->cluster_size); /* Make sure that no unsupported volume flags are set. */ if (vol->vol_flags & VOLUME_MUST_MOUNT_RO_MASK) { static const char *es1a = "Volume is dirty"; static const char *es1b = "Volume has been modified by chkdsk"; static const char *es1c = "Volume has unsupported flags set"; static const char *es2a = ". Run chkdsk and mount in Windows."; static const char *es2b = ". Mount in Windows."; const char *es1, *es2; es2 = es2a; if (vol->vol_flags & VOLUME_IS_DIRTY) es1 = es1a; else if (vol->vol_flags & VOLUME_MODIFIED_BY_CHKDSK) { es1 = es1b; es2 = es2b; } else { es1 = es1c; ntfs_warning(sb, "Unsupported volume flags 0x%x encountered.", (unsigned int)le16_to_cpu(vol->vol_flags)); } /* If a read-write mount, convert it to a read-only mount. */ if (!sb_rdonly(sb) && vol->on_errors == ON_ERRORS_REMOUNT_RO) { sb->s_flags |= SB_RDONLY; ntfs_error(sb, "%s. Mounting read-only%s", es1, es2); } /* * Do not set NVolErrors() because ntfs_remount() re-checks the * flags which we need to do in case any flags have changed. */ } /* * Get the inode for the logfile, check it and determine if the volume * was shutdown cleanly. */ rp = NULL; err = load_and_check_logfile(vol, &rp); if (err) { /* If a read-write mount, convert it to a read-only mount. */ if (!sb_rdonly(sb) && vol->on_errors == ON_ERRORS_REMOUNT_RO) { sb->s_flags |= SB_RDONLY; ntfs_error(sb, "Failed to load LogFile. Mounting read-only."); } NVolSetErrors(vol); } kvfree(rp); /* Get the root directory inode so we can do path lookups. */ vol->root_ino = ntfs_iget(sb, FILE_root); if (IS_ERR(vol->root_ino)) { if (!IS_ERR(vol->root_ino)) iput(vol->root_ino); ntfs_error(sb, "Failed to load root directory."); goto iput_logfile_err_out; } /* * Check if Windows is suspended to disk on the target volume. If it * is hibernated, we must not write *anything* to the disk so set * NVolErrors() without setting the dirty volume flag and mount * read-only. This will prevent read-write remounting and it will also * prevent all writes. */ err = check_windows_hibernation_status(vol); if (unlikely(err)) { static const char *es1a = "Failed to determine if Windows is hibernated"; static const char *es1b = "Windows is hibernated"; static const char *es2 = ". Run chkdsk."; const char *es1; es1 = err < 0 ? es1a : es1b; /* If a read-write mount, convert it to a read-only mount. */ if (!sb_rdonly(sb) && vol->on_errors == ON_ERRORS_REMOUNT_RO) { sb->s_flags |= SB_RDONLY; ntfs_error(sb, "%s. Mounting read-only%s", es1, es2); } NVolSetErrors(vol); } /* If (still) a read-write mount, empty the logfile. */ if (!sb_rdonly(sb) && vol->logfile_ino && !ntfs_empty_logfile(vol->logfile_ino) && vol->on_errors == ON_ERRORS_REMOUNT_RO) { static const char *es1 = "Failed to empty LogFile"; static const char *es2 = ". Mount in Windows."; /* Convert to a read-only mount. */ ntfs_error(sb, "%s. Mounting read-only%s", es1, es2); sb->s_flags |= SB_RDONLY; NVolSetErrors(vol); } /* If on NTFS versions before 3.0, we are done. */ if (unlikely(vol->major_ver < 3)) return true; /* NTFS 3.0+ specific initialization. */ /* Get the security descriptors inode. */ vol->secure_ino = ntfs_iget(sb, FILE_Secure); if (IS_ERR(vol->secure_ino)) { if (!IS_ERR(vol->secure_ino)) iput(vol->secure_ino); ntfs_error(sb, "Failed to load $Secure."); goto iput_root_err_out; } /* Get the extended system files' directory inode. */ vol->extend_ino = ntfs_iget(sb, FILE_Extend); if (IS_ERR(vol->extend_ino) || !S_ISDIR(vol->extend_ino->i_mode)) { if (!IS_ERR(vol->extend_ino)) iput(vol->extend_ino); ntfs_error(sb, "Failed to load $Extend."); goto iput_sec_err_out; } /* Find the quota file, load it if present, and set it up. */ if (!load_and_init_quota(vol) && vol->on_errors == ON_ERRORS_REMOUNT_RO) { static const char *es1 = "Failed to load $Quota"; static const char *es2 = ". Run chkdsk."; sb->s_flags |= SB_RDONLY; ntfs_error(sb, "%s. Mounting read-only%s", es1, es2); /* This will prevent a read-write remount. */ NVolSetErrors(vol); } return true; iput_sec_err_out: iput(vol->secure_ino); iput_root_err_out: iput(vol->root_ino); iput_logfile_err_out: if (vol->logfile_ino) iput(vol->logfile_ino); iput(vol->vol_ino); iput_lcnbmp_err_out: iput(vol->lcnbmp_ino); iput_attrdef_err_out: vol->attrdef_size = 0; if (vol->attrdef) { kvfree(vol->attrdef); vol->attrdef = NULL; } iput_upcase_err_out: vol->upcase_len = 0; mutex_lock(&ntfs_lock); if (vol->upcase == default_upcase) { ntfs_nr_upcase_users--; vol->upcase = NULL; } mutex_unlock(&ntfs_lock); if (vol->upcase) { kvfree(vol->upcase); vol->upcase = NULL; } iput_mftbmp_err_out: iput(vol->mftbmp_ino); iput_mirr_err_out: iput(vol->mftmirr_ino); return false; } static void ntfs_volume_free(struct ntfs_volume *vol) { /* Throw away the table of attribute definitions. */ vol->attrdef_size = 0; if (vol->attrdef) { kvfree(vol->attrdef); vol->attrdef = NULL; } vol->upcase_len = 0; /* * Destroy the global default upcase table if necessary. Also decrease * the number of upcase users if we are a user. */ mutex_lock(&ntfs_lock); if (vol->upcase == default_upcase) { ntfs_nr_upcase_users--; vol->upcase = NULL; } if (!ntfs_nr_upcase_users && default_upcase) { kvfree(default_upcase); default_upcase = NULL; } free_compression_buffers(); mutex_unlock(&ntfs_lock); if (vol->upcase) { kvfree(vol->upcase); vol->upcase = NULL; } unload_nls(vol->nls_map); if (vol->lcn_empty_bits_per_page) kvfree(vol->lcn_empty_bits_per_page); kfree(vol->volume_label); kfree(vol); } /* * ntfs_put_super - called by the vfs to unmount a volume * @sb: vfs superblock of volume to unmount */ static void ntfs_put_super(struct super_block *sb) { struct ntfs_volume *vol = NTFS_SB(sb); pr_info("Entering %s, dev %s\n", __func__, sb->s_id); cancel_work_sync(&vol->precalc_work); /* * Commit all inodes while they are still open in case some of them * cause others to be dirtied. */ ntfs_commit_inode(vol->vol_ino); /* NTFS 3.0+ specific. */ if (vol->major_ver >= 3) { if (vol->quota_q_ino) ntfs_commit_inode(vol->quota_q_ino); if (vol->quota_ino) ntfs_commit_inode(vol->quota_ino); if (vol->extend_ino) ntfs_commit_inode(vol->extend_ino); if (vol->secure_ino) ntfs_commit_inode(vol->secure_ino); } ntfs_commit_inode(vol->root_ino); ntfs_commit_inode(vol->lcnbmp_ino); /* * the GFP_NOFS scope is not needed because ntfs_commit_inode * does nothing */ ntfs_commit_inode(vol->mftbmp_ino); if (vol->logfile_ino) ntfs_commit_inode(vol->logfile_ino); if (vol->mftmirr_ino) ntfs_commit_inode(vol->mftmirr_ino); ntfs_commit_inode(vol->mft_ino); /* * If a read-write mount and no volume errors have occurred, mark the * volume clean. Also, re-commit all affected inodes. */ if (!sb_rdonly(sb)) { if (!NVolErrors(vol)) { if (ntfs_clear_volume_flags(vol, VOLUME_IS_DIRTY)) ntfs_warning(sb, "Failed to clear dirty bit in volume information flags. Run chkdsk."); ntfs_commit_inode(vol->vol_ino); ntfs_commit_inode(vol->root_ino); if (vol->mftmirr_ino) ntfs_commit_inode(vol->mftmirr_ino); ntfs_commit_inode(vol->mft_ino); } else { ntfs_warning(sb, "Volume has errors. Leaving volume marked dirty. Run chkdsk."); } } iput(vol->vol_ino); vol->vol_ino = NULL; /* NTFS 3.0+ specific clean up. */ if (vol->major_ver >= 3) { if (vol->quota_q_ino) { iput(vol->quota_q_ino); vol->quota_q_ino = NULL; } if (vol->quota_ino) { iput(vol->quota_ino); vol->quota_ino = NULL; } if (vol->extend_ino) { iput(vol->extend_ino); vol->extend_ino = NULL; } if (vol->secure_ino) { iput(vol->secure_ino); vol->secure_ino = NULL; } } iput(vol->root_ino); vol->root_ino = NULL; iput(vol->lcnbmp_ino); vol->lcnbmp_ino = NULL; iput(vol->mftbmp_ino); vol->mftbmp_ino = NULL; if (vol->logfile_ino) { iput(vol->logfile_ino); vol->logfile_ino = NULL; } if (vol->mftmirr_ino) { /* Re-commit the mft mirror and mft just in case. */ ntfs_commit_inode(vol->mftmirr_ino); ntfs_commit_inode(vol->mft_ino); iput(vol->mftmirr_ino); vol->mftmirr_ino = NULL; } /* * We should have no dirty inodes left, due to * mft.c::ntfs_mft_writepage() cleaning all the dirty pages as * the underlying mft records are written out and cleaned. */ ntfs_commit_inode(vol->mft_ino); write_inode_now(vol->mft_ino, 1); iput(vol->mft_ino); vol->mft_ino = NULL; blkdev_issue_flush(sb->s_bdev); ntfs_volume_free(vol); } int ntfs_force_shutdown(struct super_block *sb, u32 flags) { struct ntfs_volume *vol = NTFS_SB(sb); int ret; if (NVolShutdown(vol)) return 0; switch (flags) { case FS_SHUTDOWN_FLAGS_DEFAULT: case FS_SHUTDOWN_FLAGS_LOGFLUSH: ret = bdev_freeze(sb->s_bdev); if (ret) return ret; bdev_thaw(sb->s_bdev); NVolSetShutdown(vol); break; case FS_SHUTDOWN_FLAGS_NOLOGFLUSH: NVolSetShutdown(vol); break; default: return -EINVAL; } return 0; } static void ntfs_shutdown(struct super_block *sb) { ntfs_force_shutdown(sb, FS_SHUTDOWN_FLAGS_NOLOGFLUSH); } static int ntfs_sync_fs(struct super_block *sb, int wait) { struct ntfs_volume *vol = NTFS_SB(sb); int err = 0; if (NVolShutdown(vol)) return -EIO; if (!wait) return 0; /* If there are some dirty buffers in the bdev inode */ if (ntfs_clear_volume_flags(vol, VOLUME_IS_DIRTY)) { ntfs_warning(sb, "Failed to clear dirty bit in volume information flags. Run chkdsk."); err = -EIO; } sync_inodes_sb(sb); sync_blockdev(sb->s_bdev); blkdev_issue_flush(sb->s_bdev); return err; } /* * get_nr_free_clusters - return the number of free clusters on a volume * @vol: ntfs volume for which to obtain free cluster count * * Calculate the number of free clusters on the mounted NTFS volume @vol. We * actually calculate the number of clusters in use instead because this * allows us to not care about partial pages as these will be just zero filled * and hence not be counted as allocated clusters. * * The only particularity is that clusters beyond the end of the logical ntfs * volume will be marked as allocated to prevent errors which means we have to * discount those at the end. This is important as the cluster bitmap always * has a size in multiples of 8 bytes, i.e. up to 63 clusters could be outside * the logical volume and marked in use when they are not as they do not exist. * * If any pages cannot be read we assume all clusters in the erroring pages are * in use. This means we return an underestimate on errors which is better than * an overestimate. */ s64 get_nr_free_clusters(struct ntfs_volume *vol) { s64 nr_free = vol->nr_clusters; u32 nr_used; struct address_space *mapping = vol->lcnbmp_ino->i_mapping; struct folio *folio; pgoff_t index, max_index; struct file_ra_state *ra; ntfs_debug("Entering."); /* Serialize accesses to the cluster bitmap. */ if (NVolFreeClusterKnown(vol)) return atomic64_read(&vol->free_clusters); ra = kzalloc(sizeof(*ra), GFP_NOFS); if (!ra) return 0; file_ra_state_init(ra, mapping); /* * Convert the number of bits into bytes rounded up, then convert into * multiples of PAGE_SIZE, rounding up so that if we have one * full and one partial page max_index = 2. */ max_index = (((vol->nr_clusters + 7) >> 3) + PAGE_SIZE - 1) >> PAGE_SHIFT; /* Use multiples of 4 bytes, thus max_size is PAGE_SIZE / 4. */ ntfs_debug("Reading $Bitmap, max_index = 0x%lx, max_size = 0x%lx.", max_index, PAGE_SIZE / 4); for (index = 0; index < max_index; index++) { unsigned long *kaddr; /* * Get folio from page cache, getting it from backing store * if necessary, and increment the use count. */ folio = ntfs_get_locked_folio(mapping, index, max_index, ra); /* Ignore pages which errored synchronously. */ if (IS_ERR(folio)) { ntfs_debug("Skipping page (index 0x%lx).", index); nr_free -= PAGE_SIZE * 8; vol->lcn_empty_bits_per_page[index] = 0; continue; } kaddr = kmap_local_folio(folio, 0); /* * Subtract the number of set bits. If this * is the last page and it is partial we don't really care as * it just means we do a little extra work but it won't affect * the result as all out of range bytes are set to zero by * ntfs_readpage(). */ nr_used = bitmap_weight(kaddr, PAGE_SIZE * BITS_PER_BYTE); nr_free -= nr_used; vol->lcn_empty_bits_per_page[index] = PAGE_SIZE * BITS_PER_BYTE - nr_used; kunmap_local(kaddr); folio_unlock(folio); folio_put(folio); } ntfs_debug("Finished reading $Bitmap, last index = 0x%lx.", index - 1); /* * Fixup for eventual bits outside logical ntfs volume (see function * description above). */ if (vol->nr_clusters & 63) nr_free += 64 - (vol->nr_clusters & 63); /* If errors occurred we may well have gone below zero, fix this. */ if (nr_free < 0) nr_free = 0; else atomic64_set(&vol->free_clusters, nr_free); kfree(ra); NVolSetFreeClusterKnown(vol); wake_up_all(&vol->free_waitq); ntfs_debug("Exiting."); return nr_free; } /* * @nr_clusters is the number of clusters requested for allocation. * * Return the number of clusters available for allocation within * the range of @nr_clusters, which is counts that considered * for delayed allocation. */ s64 ntfs_available_clusters_count(struct ntfs_volume *vol, s64 nr_clusters) { s64 free_clusters; /* wait event */ if (!NVolFreeClusterKnown(vol)) wait_event(vol->free_waitq, NVolFreeClusterKnown(vol)); free_clusters = atomic64_read(&vol->free_clusters) - atomic64_read(&vol->dirty_clusters); if (free_clusters <= 0) return -ENOSPC; else if (free_clusters < nr_clusters) nr_clusters = free_clusters; return nr_clusters; } /* * __get_nr_free_mft_records - return the number of free inodes on a volume * @vol: ntfs volume for which to obtain free inode count * @nr_free: number of mft records in filesystem * @max_index: maximum number of pages containing set bits * * Calculate the number of free mft records (inodes) on the mounted NTFS * volume @vol. We actually calculate the number of mft records in use instead * because this allows us to not care about partial pages as these will be just * zero filled and hence not be counted as allocated mft record. * * If any pages cannot be read we assume all mft records in the erroring pages * are in use. This means we return an underestimate on errors which is better * than an overestimate. * * NOTE: Caller must hold mftbmp_lock rw_semaphore for reading or writing. */ static unsigned long __get_nr_free_mft_records(struct ntfs_volume *vol, s64 nr_free, const pgoff_t max_index) { struct address_space *mapping = vol->mftbmp_ino->i_mapping; struct folio *folio; pgoff_t index; struct file_ra_state *ra; ntfs_debug("Entering."); ra = kzalloc(sizeof(*ra), GFP_NOFS); if (!ra) return 0; file_ra_state_init(ra, mapping); /* Use multiples of 4 bytes, thus max_size is PAGE_SIZE / 4. */ ntfs_debug("Reading $MFT/$BITMAP, max_index = 0x%lx, max_size = 0x%lx.", max_index, PAGE_SIZE / 4); for (index = 0; index < max_index; index++) { unsigned long *kaddr; /* * Get folio from page cache, getting it from backing store * if necessary, and increment the use count. */ folio = ntfs_get_locked_folio(mapping, index, max_index, ra); /* Ignore pages which errored synchronously. */ if (IS_ERR(folio)) { ntfs_debug("read_mapping_page() error. Skipping page (index 0x%lx).", index); nr_free -= PAGE_SIZE * 8; continue; } kaddr = kmap_local_folio(folio, 0); /* * Subtract the number of set bits. If this * is the last page and it is partial we don't really care as * it just means we do a little extra work but it won't affect * the result as all out of range bytes are set to zero by * ntfs_readpage(). */ nr_free -= bitmap_weight(kaddr, PAGE_SIZE * BITS_PER_BYTE); kunmap_local(kaddr); folio_unlock(folio); folio_put(folio); } ntfs_debug("Finished reading $MFT/$BITMAP, last index = 0x%lx.", index - 1); /* If errors occurred we may well have gone below zero, fix this. */ if (nr_free < 0) nr_free = 0; else atomic64_set(&vol->free_mft_records, nr_free); kfree(ra); ntfs_debug("Exiting."); return nr_free; } /* * ntfs_statfs - return information about mounted NTFS volume * @dentry: dentry from mounted volume * @sfs: statfs structure in which to return the information * * Return information about the mounted NTFS volume @dentry in the statfs structure * pointed to by @sfs (this is initialized with zeros before ntfs_statfs is * called). We interpret the values to be correct of the moment in time at * which we are called. Most values are variable otherwise and this isn't just * the free values but the totals as well. For example we can increase the * total number of file nodes if we run out and we can keep doing this until * there is no more space on the volume left at all. * * Called from vfs_statfs which is used to handle the statfs, fstatfs, and * ustat system calls. * * Return 0 on success or -errno on error. */ static int ntfs_statfs(struct dentry *dentry, struct kstatfs *sfs) { struct super_block *sb = dentry->d_sb; s64 size; struct ntfs_volume *vol = NTFS_SB(sb); struct ntfs_inode *mft_ni = NTFS_I(vol->mft_ino); unsigned long flags; ntfs_debug("Entering."); /* Type of filesystem. */ sfs->f_type = NTFS_SB_MAGIC; /* Optimal transfer block size. */ sfs->f_bsize = vol->cluster_size; /* Fundamental file system block size, used as the unit. */ sfs->f_frsize = vol->cluster_size; /* * Total data blocks in filesystem in units of f_bsize and since * inodes are also stored in data blocs ($MFT is a file) this is just * the total clusters. */ sfs->f_blocks = vol->nr_clusters; /* wait event */ if (!NVolFreeClusterKnown(vol)) wait_event(vol->free_waitq, NVolFreeClusterKnown(vol)); /* Free data blocks in filesystem in units of f_bsize. */ size = atomic64_read(&vol->free_clusters) - atomic64_read(&vol->dirty_clusters); if (size < 0LL) size = 0LL; /* Free blocks avail to non-superuser, same as above on NTFS. */ sfs->f_bavail = sfs->f_bfree = size; /* Number of inodes in filesystem (at this point in time). */ read_lock_irqsave(&mft_ni->size_lock, flags); sfs->f_files = i_size_read(vol->mft_ino) >> vol->mft_record_size_bits; read_unlock_irqrestore(&mft_ni->size_lock, flags); /* Free inodes in fs (based on current total count). */ sfs->f_ffree = atomic64_read(&vol->free_mft_records); /* * File system id. This is extremely *nix flavour dependent and even * within Linux itself all fs do their own thing. I interpret this to * mean a unique id associated with the mounted fs and not the id * associated with the filesystem driver, the latter is already given * by the filesystem type in sfs->f_type. Thus we use the 64-bit * volume serial number splitting it into two 32-bit parts. We enter * the least significant 32-bits in f_fsid[0] and the most significant * 32-bits in f_fsid[1]. */ sfs->f_fsid = u64_to_fsid(vol->serial_no); /* Maximum length of filenames. */ sfs->f_namelen = NTFS_MAX_NAME_LEN; return 0; } static int ntfs_write_inode(struct inode *vi, struct writeback_control *wbc) { return __ntfs_write_inode(vi, wbc->sync_mode == WB_SYNC_ALL); } /* * The complete super operations. */ static const struct super_operations ntfs_sops = { .alloc_inode = ntfs_alloc_big_inode, /* VFS: Allocate new inode. */ .free_inode = ntfs_free_big_inode, /* VFS: Deallocate inode. */ .drop_inode = ntfs_drop_big_inode, .write_inode = ntfs_write_inode, /* VFS: Write dirty inode to disk. */ .put_super = ntfs_put_super, /* Syscall: umount. */ .shutdown = ntfs_shutdown, .sync_fs = ntfs_sync_fs, /* Syscall: sync. */ .statfs = ntfs_statfs, /* Syscall: statfs */ .evict_inode = ntfs_evict_big_inode, .show_options = ntfs_show_options, /* Show mount options in proc. */ }; static void precalc_free_clusters(struct work_struct *work) { struct ntfs_volume *vol = container_of(work, struct ntfs_volume, precalc_work); s64 nr_free; nr_free = get_nr_free_clusters(vol); ntfs_debug("pre-calculate free clusters(%lld) using workqueue", nr_free); } static struct lock_class_key ntfs_mft_inval_lock_key; /* * ntfs_fill_super - mount an ntfs filesystem * @sb: super block of the device to mount * @fc: filesystem context containing mount options * * ntfs_fill_super() is called by the VFS to mount the device described by @sb * with the mount otions in @data with the NTFS filesystem. * * If @silent is true, remain silent even if errors are detected. This is used * during bootup, when the kernel tries to mount the root filesystem with all * registered filesystems one after the other until one succeeds. This implies * that all filesystems except the correct one will quite correctly and * expectedly return an error, but nobody wants to see error messages when in * fact this is what is supposed to happen. */ static int ntfs_fill_super(struct super_block *sb, struct fs_context *fc) { char *boot; struct inode *tmp_ino; int blocksize, result; pgoff_t lcn_bit_pages; struct ntfs_volume *vol = NTFS_SB(sb); int silent = fc->sb_flags & SB_SILENT; vol->sb = sb; /* * We do a pretty difficult piece of bootstrap by reading the * MFT (and other metadata) from disk into memory. We'll only * release this metadata during umount, so the locking patterns * observed during bootstrap do not count. So turn off the * observation of locking patterns (strictly for this context * only) while mounting NTFS. [The validator is still active * otherwise, even for this context: it will for example record * lock class registrations.] */ lockdep_off(); ntfs_debug("Entering."); if (vol->nls_map && !strcmp(vol->nls_map->charset, "utf8")) vol->nls_utf8 = true; if (NVolDisableSparse(vol)) vol->preallocated_size = 0; if (NVolDiscard(vol) && !bdev_max_discard_sectors(sb->s_bdev)) { ntfs_warning( sb, "Discard requested but device does not support discard. Discard disabled."); NVolClearDiscard(vol); } /* We support sector sizes up to the PAGE_SIZE. */ if (bdev_logical_block_size(sb->s_bdev) > PAGE_SIZE) { if (!silent) ntfs_error(sb, "Device has unsupported sector size (%i). The maximum supported sector size on this architecture is %lu bytes.", bdev_logical_block_size(sb->s_bdev), PAGE_SIZE); goto err_out_now; } /* * Setup the device access block size to NTFS_BLOCK_SIZE or the hard * sector size, whichever is bigger. */ blocksize = sb_min_blocksize(sb, NTFS_BLOCK_SIZE); if (blocksize < NTFS_BLOCK_SIZE) { if (!silent) ntfs_error(sb, "Unable to set device block size."); goto err_out_now; } ntfs_debug("Set device block size to %i bytes (block size bits %i).", blocksize, sb->s_blocksize_bits); /* Determine the size of the device in units of block_size bytes. */ if (!bdev_nr_bytes(sb->s_bdev)) { if (!silent) ntfs_error(sb, "Unable to determine device size."); goto err_out_now; } vol->nr_blocks = bdev_nr_bytes(sb->s_bdev) >> sb->s_blocksize_bits; /* Read the boot sector and return unlocked buffer head to it. */ boot = read_ntfs_boot_sector(sb, silent); if (!boot) { if (!silent) ntfs_error(sb, "Not an NTFS volume."); goto err_out_now; } /* * Extract the data from the boot sector and setup the ntfs volume * using it. */ result = parse_ntfs_boot_sector(vol, (struct ntfs_boot_sector *)boot); kfree(boot); if (!result) { if (!silent) ntfs_error(sb, "Unsupported NTFS filesystem."); goto err_out_now; } if (vol->sector_size > blocksize) { blocksize = sb_set_blocksize(sb, vol->sector_size); if (blocksize != vol->sector_size) { if (!silent) ntfs_error(sb, "Unable to set device block size to sector size (%i).", vol->sector_size); goto err_out_now; } vol->nr_blocks = bdev_nr_bytes(sb->s_bdev) >> sb->s_blocksize_bits; ntfs_debug("Changed device block size to %i bytes (block size bits %i) to match volume sector size.", blocksize, sb->s_blocksize_bits); } /* Initialize the cluster and mft allocators. */ ntfs_setup_allocators(vol); /* Setup remaining fields in the super block. */ sb->s_magic = NTFS_SB_MAGIC; /* * Ntfs allows 63 bits for the file size, i.e. correct would be: * sb->s_maxbytes = ~0ULL >> 1; * But the kernel uses a long as the page cache page index which on * 32-bit architectures is only 32-bits. MAX_LFS_FILESIZE is kernel * defined to the maximum the page cache page index can cope with * without overflowing the index or to 2^63 - 1, whichever is smaller. */ sb->s_maxbytes = MAX_LFS_FILESIZE; /* Ntfs measures time in 100ns intervals. */ sb->s_time_gran = 100; sb->s_xattr = ntfs_xattr_handlers; /* * Now load the metadata required for the page cache and our address * space operations to function. We do this by setting up a specialised * read_inode method and then just calling the normal iget() to obtain * the inode for $MFT which is sufficient to allow our normal inode * operations and associated address space operations to function. */ sb->s_op = &ntfs_sops; tmp_ino = new_inode(sb); if (!tmp_ino) { if (!silent) ntfs_error(sb, "Failed to load essential metadata."); goto err_out_now; } tmp_ino->i_ino = FILE_MFT; insert_inode_hash(tmp_ino); if (ntfs_read_inode_mount(tmp_ino) < 0) { if (!silent) ntfs_error(sb, "Failed to load essential metadata."); goto iput_tmp_ino_err_out_now; } lockdep_set_class(&tmp_ino->i_mapping->invalidate_lock, &ntfs_mft_inval_lock_key); mutex_lock(&ntfs_lock); /* * Generate the global default upcase table if necessary. Also * temporarily increment the number of upcase users to avoid race * conditions with concurrent (u)mounts. */ if (!default_upcase) default_upcase = generate_default_upcase(); ntfs_nr_upcase_users++; mutex_unlock(&ntfs_lock); lcn_bit_pages = (((vol->nr_clusters + 7) >> 3) + PAGE_SIZE - 1) >> PAGE_SHIFT; vol->lcn_empty_bits_per_page = kvmalloc_array(lcn_bit_pages, sizeof(unsigned int), GFP_KERNEL); if (!vol->lcn_empty_bits_per_page) { ntfs_error(sb, "Unable to allocate pages for storing LCN empty bit counts\n"); goto unl_upcase_iput_tmp_ino_err_out_now; } /* * From now on, ignore @silent parameter. If we fail below this line, * it will be due to a corrupt fs or a system error, so we report it. */ /* * Open the system files with normal access functions and complete * setting up the ntfs super block. */ if (!load_system_files(vol)) { ntfs_error(sb, "Failed to load system files."); goto unl_upcase_iput_tmp_ino_err_out_now; } /* We grab a reference, simulating an ntfs_iget(). */ ihold(vol->root_ino); sb->s_root = d_make_root(vol->root_ino); if (sb->s_root) { s64 nr_records; ntfs_debug("Exiting, status successful."); /* Release the default upcase if it has no users. */ mutex_lock(&ntfs_lock); if (!--ntfs_nr_upcase_users && default_upcase) { kvfree(default_upcase); default_upcase = NULL; } mutex_unlock(&ntfs_lock); sb->s_export_op = &ntfs_export_ops; lockdep_on(); nr_records = __get_nr_free_mft_records(vol, i_size_read(vol->mft_ino) >> vol->mft_record_size_bits, ((((NTFS_I(vol->mft_ino)->initialized_size >> vol->mft_record_size_bits) + 7) >> 3) + PAGE_SIZE - 1) >> PAGE_SHIFT); ntfs_debug("Free mft records(%lld)", nr_records); init_waitqueue_head(&vol->free_waitq); INIT_WORK(&vol->precalc_work, precalc_free_clusters); queue_work(ntfs_wq, &vol->precalc_work); return 0; } ntfs_error(sb, "Failed to allocate root directory."); /* Clean up after the successful load_system_files() call from above. */ iput(vol->vol_ino); vol->vol_ino = NULL; /* NTFS 3.0+ specific clean up. */ if (vol->major_ver >= 3) { if (vol->quota_q_ino) { iput(vol->quota_q_ino); vol->quota_q_ino = NULL; } if (vol->quota_ino) { iput(vol->quota_ino); vol->quota_ino = NULL; } if (vol->extend_ino) { iput(vol->extend_ino); vol->extend_ino = NULL; } if (vol->secure_ino) { iput(vol->secure_ino); vol->secure_ino = NULL; } } iput(vol->root_ino); vol->root_ino = NULL; iput(vol->lcnbmp_ino); vol->lcnbmp_ino = NULL; iput(vol->mftbmp_ino); vol->mftbmp_ino = NULL; if (vol->logfile_ino) { iput(vol->logfile_ino); vol->logfile_ino = NULL; } if (vol->mftmirr_ino) { iput(vol->mftmirr_ino); vol->mftmirr_ino = NULL; } /* Throw away the table of attribute definitions. */ vol->attrdef_size = 0; if (vol->attrdef) { kvfree(vol->attrdef); vol->attrdef = NULL; } vol->upcase_len = 0; mutex_lock(&ntfs_lock); if (vol->upcase == default_upcase) { ntfs_nr_upcase_users--; vol->upcase = NULL; } mutex_unlock(&ntfs_lock); if (vol->upcase) { kvfree(vol->upcase); vol->upcase = NULL; } if (vol->nls_map) { unload_nls(vol->nls_map); vol->nls_map = NULL; } /* Error exit code path. */ unl_upcase_iput_tmp_ino_err_out_now: if (vol->lcn_empty_bits_per_page) kvfree(vol->lcn_empty_bits_per_page); /* * Decrease the number of upcase users and destroy the global default * upcase table if necessary. */ mutex_lock(&ntfs_lock); if (!--ntfs_nr_upcase_users && default_upcase) { kvfree(default_upcase); default_upcase = NULL; } mutex_unlock(&ntfs_lock); iput_tmp_ino_err_out_now: iput(tmp_ino); if (vol->mft_ino && vol->mft_ino != tmp_ino) iput(vol->mft_ino); vol->mft_ino = NULL; /* Errors at this stage are irrelevant. */ err_out_now: sb->s_fs_info = NULL; kfree(vol); ntfs_debug("Failed, returning -EINVAL."); lockdep_on(); return -EINVAL; } /* * This is a slab cache to optimize allocations and deallocations of Unicode * strings of the maximum length allowed by NTFS, which is NTFS_MAX_NAME_LEN * (255) Unicode characters + a terminating NULL Unicode character. */ struct kmem_cache *ntfs_name_cache; /* Slab caches for efficient allocation/deallocation of inodes. */ struct kmem_cache *ntfs_inode_cache; struct kmem_cache *ntfs_big_inode_cache; /* Init once constructor for the inode slab cache. */ static void ntfs_big_inode_init_once(void *foo) { struct ntfs_inode *ni = foo; inode_init_once(VFS_I(ni)); } /* * Slab caches to optimize allocations and deallocations of attribute search * contexts and index contexts, respectively. */ struct kmem_cache *ntfs_attr_ctx_cache; struct kmem_cache *ntfs_index_ctx_cache; /* Driver wide mutex. */ DEFINE_MUTEX(ntfs_lock); static int ntfs_get_tree(struct fs_context *fc) { return get_tree_bdev(fc, ntfs_fill_super); } static void ntfs_free_fs_context(struct fs_context *fc) { struct ntfs_volume *vol = fc->s_fs_info; if (vol) ntfs_volume_free(vol); } static const struct fs_context_operations ntfs_context_ops = { .parse_param = ntfs_parse_param, .get_tree = ntfs_get_tree, .free = ntfs_free_fs_context, .reconfigure = ntfs_reconfigure, }; static int ntfs_init_fs_context(struct fs_context *fc) { struct ntfs_volume *vol; /* Allocate a new struct ntfs_volume and place it in sb->s_fs_info. */ vol = kmalloc(sizeof(struct ntfs_volume), GFP_NOFS); if (!vol) return -ENOMEM; /* Initialize struct ntfs_volume structure. */ *vol = (struct ntfs_volume) { .uid = INVALID_UID, .gid = INVALID_GID, .fmask = 0, .dmask = 0, .mft_zone_multiplier = 1, .on_errors = ON_ERRORS_CONTINUE, .nls_map = load_nls_default(), .preallocated_size = NTFS_DEF_PREALLOC_SIZE, }; NVolSetShowHiddenFiles(vol); NVolSetCaseSensitive(vol); init_rwsem(&vol->mftbmp_lock); init_rwsem(&vol->lcnbmp_lock); fc->s_fs_info = vol; fc->ops = &ntfs_context_ops; return 0; } static struct file_system_type ntfs_fs_type = { .owner = THIS_MODULE, .name = "ntfs", .init_fs_context = ntfs_init_fs_context, .parameters = ntfs_parameters, .kill_sb = kill_block_super, .fs_flags = FS_REQUIRES_DEV | FS_ALLOW_IDMAP, }; MODULE_ALIAS_FS("ntfs"); static int ntfs_workqueue_init(void) { ntfs_wq = alloc_workqueue("ntfs-bg-io", 0, 0); if (!ntfs_wq) return -ENOMEM; return 0; } static void ntfs_workqueue_destroy(void) { destroy_workqueue(ntfs_wq); ntfs_wq = NULL; } /* Stable names for the slab caches. */ static const char ntfs_index_ctx_cache_name[] = "ntfs_index_ctx_cache"; static const char ntfs_attr_ctx_cache_name[] = "ntfs_attr_ctx_cache"; static const char ntfs_name_cache_name[] = "ntfs_name_cache"; static const char ntfs_inode_cache_name[] = "ntfs_inode_cache"; static const char ntfs_big_inode_cache_name[] = "ntfs_big_inode_cache"; static int __init init_ntfs_fs(void) { int err = 0; err = ntfs_workqueue_init(); if (err) { pr_crit("Failed to register workqueue!\n"); return err; } ntfs_index_ctx_cache = kmem_cache_create(ntfs_index_ctx_cache_name, sizeof(struct ntfs_index_context), 0 /* offset */, SLAB_HWCACHE_ALIGN, NULL /* ctor */); if (!ntfs_index_ctx_cache) { pr_crit("Failed to create %s!\n", ntfs_index_ctx_cache_name); goto ictx_err_out; } ntfs_attr_ctx_cache = kmem_cache_create(ntfs_attr_ctx_cache_name, sizeof(struct ntfs_attr_search_ctx), 0 /* offset */, SLAB_HWCACHE_ALIGN, NULL /* ctor */); if (!ntfs_attr_ctx_cache) { pr_crit("NTFS: Failed to create %s!\n", ntfs_attr_ctx_cache_name); goto actx_err_out; } ntfs_name_cache = kmem_cache_create(ntfs_name_cache_name, (NTFS_MAX_NAME_LEN+2) * sizeof(__le16), 0, SLAB_HWCACHE_ALIGN, NULL); if (!ntfs_name_cache) { pr_crit("Failed to create %s!\n", ntfs_name_cache_name); goto name_err_out; } ntfs_inode_cache = kmem_cache_create(ntfs_inode_cache_name, sizeof(struct ntfs_inode), 0, SLAB_RECLAIM_ACCOUNT, NULL); if (!ntfs_inode_cache) { pr_crit("Failed to create %s!\n", ntfs_inode_cache_name); goto inode_err_out; } ntfs_big_inode_cache = kmem_cache_create(ntfs_big_inode_cache_name, sizeof(struct big_ntfs_inode), 0, SLAB_HWCACHE_ALIGN | SLAB_RECLAIM_ACCOUNT | SLAB_ACCOUNT, ntfs_big_inode_init_once); if (!ntfs_big_inode_cache) { pr_crit("Failed to create %s!\n", ntfs_big_inode_cache_name); goto big_inode_err_out; } /* Register the ntfs sysctls. */ err = ntfs_sysctl(1); if (err) { pr_crit("Failed to register NTFS sysctls!\n"); goto sysctl_err_out; } err = register_filesystem(&ntfs_fs_type); if (!err) { ntfs_debug("NTFS driver registered successfully."); return 0; /* Success! */ } pr_crit("Failed to register NTFS filesystem driver!\n"); /* Unregister the ntfs sysctls. */ ntfs_sysctl(0); sysctl_err_out: kmem_cache_destroy(ntfs_big_inode_cache); big_inode_err_out: kmem_cache_destroy(ntfs_inode_cache); inode_err_out: kmem_cache_destroy(ntfs_name_cache); name_err_out: kmem_cache_destroy(ntfs_attr_ctx_cache); actx_err_out: kmem_cache_destroy(ntfs_index_ctx_cache); ictx_err_out: if (!err) { pr_crit("Aborting NTFS filesystem driver registration...\n"); err = -ENOMEM; } return err; } static void __exit exit_ntfs_fs(void) { ntfs_debug("Unregistering NTFS driver."); unregister_filesystem(&ntfs_fs_type); /* * Make sure all delayed rcu free inodes are flushed before we * destroy cache. */ rcu_barrier(); kmem_cache_destroy(ntfs_big_inode_cache); kmem_cache_destroy(ntfs_inode_cache); kmem_cache_destroy(ntfs_name_cache); kmem_cache_destroy(ntfs_attr_ctx_cache); kmem_cache_destroy(ntfs_index_ctx_cache); ntfs_workqueue_destroy(); /* Unregister the ntfs sysctls. */ ntfs_sysctl(0); } module_init(init_ntfs_fs); module_exit(exit_ntfs_fs); MODULE_AUTHOR("Anton Altaparmakov "); /* Original read-only NTFS driver */ MODULE_AUTHOR("Namjae Jeon "); /* Add write, iomap and various features */ MODULE_DESCRIPTION("NTFS read-write filesystem driver"); MODULE_LICENSE("GPL"); #ifdef DEBUG module_param(debug_msgs, uint, 0); MODULE_PARM_DESC(debug_msgs, "Enable debug messages."); #endif