/* Inode management routines Copyright (C) 1994, 1995, 1996, 1997, 1998, 1999, 2000, 2001, 2002, 2007 Free Software Foundation, Inc. Converted for ext2fs by Miles Bader This program is free software; you can redistribute it and/or modify it under the terms of the GNU General Public License as published by the Free Software Foundation; either version 2, or (at your option) any later version. This program is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License for more details. You should have received a copy of the GNU General Public License along with this program; if not, write to the Free Software Foundation, Inc., 675 Mass Ave, Cambridge, MA 02139, USA. */ #include "ext2fs.h" #include #include #include #include #include #include /* these flags aren't actually defined by a header file yet, so temporarily disable them if necessary. */ #ifndef UF_APPEND #define UF_APPEND 0 #endif #ifndef UF_NODUMP #define UF_NODUMP 0 #endif #ifndef UF_IMMUTABLE #define UF_IMMUTABLE 0 #endif #define INOHSZ 512 #if ((INOHSZ&(INOHSZ-1)) == 0) #define INOHASH(ino) ((ino)&(INOHSZ-1)) #else #define INOHASH(ino) (((unsigned)(ino))%INOHSZ) #endif static struct node *nodehash[INOHSZ]; static error_t read_node (struct node *np); spin_lock_t generation_lock = SPIN_LOCK_INITIALIZER; /* Initialize the inode hash table. */ void inode_init () { int n; for (n = 0; n < INOHSZ; n++) nodehash[n] = 0; } /* Fetch inode INUM, set *NPP to the node structure; gain one user reference and lock the node. */ error_t diskfs_cached_lookup (ino_t inum, struct node **npp) { error_t err; struct node *np; struct disknode *dn; spin_lock (&diskfs_node_refcnt_lock); for (np = nodehash[INOHASH(inum)]; np; np = np->dn->hnext) if (np->cache_id == inum) { np->references++; spin_unlock (&diskfs_node_refcnt_lock); mutex_lock (&np->lock); *npp = np; return 0; } /* Format specific data for the new node. */ dn = malloc (sizeof (struct disknode)); if (! dn) { spin_unlock (&diskfs_node_refcnt_lock); return ENOMEM; } dn->dirents = 0; dn->dir_idx = 0; dn->pager = 0; rwlock_init (&dn->alloc_lock); pokel_init (&dn->indir_pokel, diskfs_disk_pager, disk_image); /* Create the new node. */ np = diskfs_make_node (dn); np->cache_id = inum; mutex_lock (&np->lock); /* Put NP in NODEHASH. */ dn->hnext = nodehash[INOHASH(inum)]; if (dn->hnext) dn->hnext->dn->hprevp = &dn->hnext; dn->hprevp = &nodehash[INOHASH(inum)]; nodehash[INOHASH(inum)] = np; spin_unlock (&diskfs_node_refcnt_lock); /* Get the contents of NP off disk. */ err = read_node (np); if (!diskfs_check_readonly () && !np->dn_stat.st_gen) { spin_lock (&generation_lock); if (++next_generation < diskfs_mtime->seconds) next_generation = diskfs_mtime->seconds; np->dn_stat.st_gen = next_generation; spin_unlock (&generation_lock); np->dn_set_ctime = 1; } if (err) return err; else { *npp = np; return 0; } } /* Lookup node INUM (which must have a reference already) and return it without allocating any new references. */ struct node * ifind (ino_t inum) { struct node *np; spin_lock (&diskfs_node_refcnt_lock); for (np = nodehash[INOHASH(inum)]; np; np = np->dn->hnext) { if (np->cache_id != inum) continue; assert (np->references); spin_unlock (&diskfs_node_refcnt_lock); return np; } assert (0); } /* The last reference to a node has gone away; drop it from the hash table and clean all state in the dn structure. */ void diskfs_node_norefs (struct node *np) { *np->dn->hprevp = np->dn->hnext; if (np->dn->hnext) np->dn->hnext->dn->hprevp = np->dn->hprevp; if (np->dn->dirents) free (np->dn->dirents); assert (!np->dn->pager); /* Move any pending writes of indirect blocks. */ pokel_inherit (&global_pokel, &np->dn->indir_pokel); pokel_finalize (&np->dn->indir_pokel); free (np->dn); free (np); } /* The last hard reference to a node has gone away; arrange to have all the weak references dropped that can be. */ void diskfs_try_dropping_softrefs (struct node *np) { drop_pager_softrefs (np); } /* The last hard reference to a node has gone away. */ void diskfs_lost_hardrefs (struct node *np) { } /* A new hard reference to a node has been created; it's now OK to have unused weak references. */ void diskfs_new_hardrefs (struct node *np) { allow_pager_softrefs (np); } /* Read stat information out of the ext2_inode. */ static error_t read_node (struct node *np) { error_t err; struct stat *st = &np->dn_stat; struct disknode *dn = np->dn; struct ext2_inode *di = dino (np->cache_id); struct ext2_inode_info *info = &dn->info; err = diskfs_catch_exception (); if (err) return err; st->st_fstype = FSTYPE_EXT2FS; st->st_fsid = getpid (); /* This call is very cheap. */ st->st_ino = np->cache_id; st->st_blksize = vm_page_size * 2; st->st_nlink = di->i_links_count; st->st_size = di->i_size; st->st_gen = di->i_generation; st->st_atim.tv_sec = di->i_atime; #ifdef not_yet /* ``struct ext2_inode'' doesn't do better than sec. precision yet. */ #else st->st_atim.tv_nsec = 0; #endif st->st_mtim.tv_sec = di->i_mtime; #ifdef not_yet /* ``struct ext2_inode'' doesn't do better than sec. precision yet. */ #else st->st_mtim.tv_nsec = 0; #endif st->st_ctim.tv_sec = di->i_ctime; #ifdef not_yet /* ``struct ext2_inode'' doesn't do better than sec. precision yet. */ #else st->st_ctim.tv_nsec = 0; #endif st->st_blocks = di->i_blocks; st->st_flags = 0; if (di->i_flags & EXT2_APPEND_FL) st->st_flags |= UF_APPEND; if (di->i_flags & EXT2_NODUMP_FL) st->st_flags |= UF_NODUMP; if (di->i_flags & EXT2_IMMUTABLE_FL) st->st_flags |= UF_IMMUTABLE; if (sblock->s_creator_os == EXT2_OS_HURD) { st->st_mode = di->i_mode | (di->i_mode_high << 16); st->st_mode &= ~S_ITRANS; if (di->i_translator) st->st_mode |= S_IPTRANS; st->st_uid = di->i_uid | (di->i_uid_high << 16); st->st_gid = di->i_gid | (di->i_gid_high << 16); st->st_author = di->i_author; if (st->st_author == -1) st->st_author = st->st_uid; } else { st->st_mode = di->i_mode & ~S_ITRANS; st->st_uid = di->i_uid; st->st_gid = di->i_gid; st->st_author = st->st_uid; np->author_tracks_uid = 1; } /* Setup the ext2fs auxiliary inode info. */ info->i_dtime = di->i_dtime; info->i_flags = di->i_flags; info->i_faddr = di->i_faddr; info->i_frag_no = di->i_frag; info->i_frag_size = di->i_fsize; info->i_osync = 0; info->i_file_acl = di->i_file_acl; if (S_ISDIR (st->st_mode)) info->i_dir_acl = di->i_dir_acl; else { info->i_dir_acl = 0; info->i_high_size = di->i_size_high; if (info->i_high_size) /* XXX */ { ext2_warning ("cannot handle large file inode %Ld", np->cache_id); return EFBIG; } } info->i_block_group = inode_group_num (np->cache_id); info->i_next_alloc_block = 0; info->i_next_alloc_goal = 0; info->i_prealloc_count = 0; /* Set to a conservative value. */ dn->last_page_partially_writable = 0; if (S_ISCHR (st->st_mode) || S_ISBLK (st->st_mode)) st->st_rdev = di->i_block[0]; else { memcpy (info->i_data, di->i_block, EXT2_N_BLOCKS * sizeof info->i_data[0]); st->st_rdev = 0; } dn->info_i_translator = di->i_translator; diskfs_end_catch_exception (); if (S_ISREG (st->st_mode) || S_ISDIR (st->st_mode) || (S_ISLNK (st->st_mode) && st->st_blocks)) { unsigned offset; np->allocsize = np->dn_stat.st_size; /* Round up to a block multiple. */ offset = np->allocsize & ((1 << log2_block_size) - 1); if (offset > 0) np->allocsize += block_size - offset; } else /* Allocsize should be zero for anything except directories, files, and long symlinks. These are the only things allowed to have any blocks allocated as well, although st_size may be zero for any type (cases where st_blocks=0 and st_size>0 include fast symlinks, and, under linux, some devices). */ np->allocsize = 0; return 0; } /* Return EINVAL if this is not a hurd filesystem and any bits are set in L except the low 16 bits, else 0. */ static inline error_t check_high_bits (struct node *np, long l) { if (sblock->s_creator_os == EXT2_OS_HURD) return 0; /* Linux 2.3.42 has a mount-time option (not a bit stored on disk) NO_UID32 to ignore the high 16 bits of uid and gid, but by default allows them. It also does this check for "interoperability with old kernels". Note that our check refuses to change the values, while Linux 2.3.42 just silently clears the high bits in an inode it updates, even if it was updating it for an unrelated reason. */ if (np->dn->info.i_dtime != 0) return 0; return ((l & ~0xFFFF) == 0) ? 0 : EINVAL; } /* Return 0 if NP's owner can be changed to UID; otherwise return an error code. */ error_t diskfs_validate_owner_change (struct node *np, uid_t uid) { return check_high_bits (np, uid); } /* Return 0 if NP's group can be changed to GID; otherwise return an error code. */ error_t diskfs_validate_group_change (struct node *np, gid_t gid) { return check_high_bits (np, gid); } /* Return 0 if NP's mode can be changed to MODE; otherwise return an error code. It must always be possible to clear the mode; diskfs will not ask for permission before doing so. */ error_t diskfs_validate_mode_change (struct node *np, mode_t mode) { return check_high_bits (np, mode); } /* Return 0 if NP's author can be changed to AUTHOR; otherwise return an error code. */ error_t diskfs_validate_author_change (struct node *np, uid_t author) { if (sblock->s_creator_os == EXT2_OS_HURD) return 0; else /* For non-hurd filesystems, the author & owner are the same. */ return (author == np->dn_stat.st_uid) ? 0 : EINVAL; } /* The user may define this function. Return 0 if NP's flags can be changed to FLAGS; otherwise return an error code. It must always be possible to clear the flags. */ error_t diskfs_validate_flags_change (struct node *np, int flags) { if (flags & ~(UF_NODUMP | UF_IMMUTABLE | UF_APPEND)) return EINVAL; else return 0; } /* Writes everything from NP's inode to the disk image, and returns a pointer to it, or NULL if nothing need be done. */ static struct ext2_inode * write_node (struct node *np) { error_t err; struct stat *st = &np->dn_stat; struct ext2_inode *di = dino (np->cache_id); if (np->dn->info.i_prealloc_count) ext2_discard_prealloc (np); if (np->dn_stat_dirty) { struct ext2_inode_info *info = &np->dn->info; assert (!diskfs_readonly); ext2_debug ("writing inode %d to disk", np->cache_id); err = diskfs_catch_exception (); if (err) return NULL; di->i_generation = st->st_gen; /* We happen to know that the stat mode bits are the same as the ext2fs mode bits. */ /* XXX? */ /* Only the low 16 bits of these fields are standard across all ext2 implementations. */ di->i_mode = st->st_mode & 0xFFFF & ~S_ITRANS; di->i_uid = st->st_uid & 0xFFFF; di->i_gid = st->st_gid & 0xFFFF; if (sblock->s_creator_os == EXT2_OS_HURD) /* If this is a hurd-compatible filesystem, write the high bits too. */ { di->i_mode_high = (st->st_mode >> 16) & 0xffff & ~S_ITRANS; di->i_uid_high = st->st_uid >> 16; di->i_gid_high = st->st_gid >> 16; di->i_author = st->st_author; } else /* No hurd extensions should be turned on. */ { assert ((st->st_uid & ~0xFFFF) == 0); assert ((st->st_gid & ~0xFFFF) == 0); assert ((st->st_mode & ~0xFFFF) == 0); assert (np->author_tracks_uid && st->st_author == st->st_uid); } di->i_links_count = st->st_nlink; di->i_atime = st->st_atim.tv_sec; #ifdef not_yet /* ``struct ext2_inode'' doesn't do better than sec. precision yet. */ di->i_atime.tv_nsec = st->st_atim.tv_nsec; #endif di->i_mtime = st->st_mtim.tv_sec; #ifdef not_yet di->i_mtime.tv_nsec = st->st_mtim.tv_nsec; #endif di->i_ctime = st->st_ctim.tv_sec; #ifdef not_yet di->i_ctime.tv_nsec = st->st_ctim.tv_nsec; #endif /* Convert generic flags in ST->st_flags to ext2-specific flags in DI (but don't mess with ext2 flags we don't know about). The original set was copied from DI into INFO by read_node, but might have been modified for ext2fs-specific reasons; so we use INFO->i_flags to start with, and then apply the flags in ST->st_flags. */ info->i_flags &= ~(EXT2_APPEND_FL | EXT2_NODUMP_FL | EXT2_IMMUTABLE_FL); if (st->st_flags & UF_APPEND) info->i_flags |= EXT2_APPEND_FL; if (st->st_flags & UF_NODUMP) info->i_flags |= EXT2_NODUMP_FL; if (st->st_flags & UF_IMMUTABLE) info->i_flags |= EXT2_IMMUTABLE_FL; di->i_flags = info->i_flags; if (st->st_mode == 0) /* Set dtime non-zero to indicate a deleted file. We don't clear i_size, i_blocks, and i_translator in this case, to give "undeletion" utilities a chance. */ di->i_dtime = di->i_mtime; else { di->i_dtime = 0; di->i_size = st->st_size; di->i_blocks = st->st_blocks; } if (S_ISCHR(st->st_mode) || S_ISBLK(st->st_mode)) di->i_block[0] = st->st_rdev; else memcpy (di->i_block, np->dn->info.i_data, EXT2_N_BLOCKS * sizeof di->i_block[0]); diskfs_end_catch_exception (); np->dn_stat_dirty = 0; return di; } else return NULL; } /* Reload all data specific to NODE from disk, without writing anything. Always called with DISKFS_READONLY true. */ error_t diskfs_node_reload (struct node *node) { struct disknode *dn = node->dn; if (dn->dirents) { free (dn->dirents); dn->dirents = 0; } pokel_flush (&dn->indir_pokel); flush_node_pager (node); read_node (node); return 0; } /* For each active node, call FUN. The node is to be locked around the call to FUN. If FUN returns non-zero for any node, then immediately stop, and return that value. */ error_t diskfs_node_iterate (error_t (*fun)(struct node *)) { error_t err = 0; int n, num_nodes = 0; struct node *node, **node_list, **p; spin_lock (&diskfs_node_refcnt_lock); /* We must copy everything from the hash table into another data structure to avoid running into any problems with the hash-table being modified during processing (normally we delegate access to hash-table with diskfs_node_refcnt_lock, but we can't hold this while locking the individual node locks). */ for (n = 0; n < INOHSZ; n++) for (node = nodehash[n]; node; node = node->dn->hnext) num_nodes++; /* TODO This method doesn't scale beyond a few dozen nodes and should be replaced. */ node_list = malloc (num_nodes * sizeof (struct node *)); if (node_list == NULL) { spin_unlock (&diskfs_node_refcnt_lock); ext2_debug ("unable to allocate temporary node table"); return ENOMEM; } p = node_list; for (n = 0; n < INOHSZ; n++) for (node = nodehash[n]; node; node = node->dn->hnext) { *p++ = node; node->references++; } spin_unlock (&diskfs_node_refcnt_lock); p = node_list; while (num_nodes-- > 0) { node = *p++; if (!err) { mutex_lock (&node->lock); err = (*fun)(node); mutex_unlock (&node->lock); } diskfs_nrele (node); } free (node_list); return err; } /* Write all active disknodes into the ext2_inode pager. */ void write_all_disknodes () { error_t write_one_disknode (struct node *node) { struct ext2_inode *di; /* Sync the indirect blocks here; they'll all be done before any inodes. Waiting for them shouldn't be too bad. */ pokel_sync (&node->dn->indir_pokel, 1); diskfs_set_node_times (node); /* Update the inode image. */ di = write_node (node); if (di) record_global_poke (di); return 0; } diskfs_node_iterate (write_one_disknode); } /* Sync the info in NP->dn_stat and any associated format-specific information to disk. If WAIT is true, then return only after the physicial media has been completely updated. */ void diskfs_write_disknode (struct node *np, int wait) { struct ext2_inode *di = write_node (np); if (di) { if (wait) sync_global_ptr (di, 1); else record_global_poke (di); } } /* Set *ST with appropriate values to reflect the current state of the filesystem. */ error_t diskfs_set_statfs (struct statfs *st) { st->f_type = FSTYPE_EXT2FS; st->f_bsize = block_size; st->f_blocks = sblock->s_blocks_count; st->f_bfree = sblock->s_free_blocks_count; st->f_bavail = st->f_bfree - sblock->s_r_blocks_count; if (st->f_bfree < sblock->s_r_blocks_count) st->f_bavail = 0; st->f_files = sblock->s_inodes_count; st->f_ffree = sblock->s_free_inodes_count; st->f_fsid = getpid (); st->f_namelen = 0; st->f_favail = st->f_ffree; st->f_frsize = frag_size; return 0; } /* Implement the diskfs_set_translator callback from the diskfs library; see for the interface description. */ error_t diskfs_set_translator (struct node *np, const char *name, unsigned namelen, struct protid *cred) { daddr_t blkno; error_t err; char buf[block_size]; struct ext2_inode *di; assert (!diskfs_readonly); if (sblock->s_creator_os != EXT2_OS_HURD) return EOPNOTSUPP; if (namelen + 2 > block_size) return ENAMETOOLONG; err = diskfs_catch_exception (); if (err) return err; di = dino (np->cache_id); blkno = di->i_translator; if (namelen && !blkno) { /* Allocate block for translator */ blkno = ext2_new_block ((np->dn->info.i_block_group * EXT2_BLOCKS_PER_GROUP (sblock)) + sblock->s_first_data_block, 0, 0, 0); if (blkno == 0) { diskfs_end_catch_exception (); return ENOSPC; } di->i_translator = blkno; np->dn->info_i_translator = blkno; record_global_poke (di); np->dn_stat.st_blocks += 1 << log2_stat_blocks_per_fs_block; np->dn_set_ctime = 1; } else if (!namelen && blkno) { /* Clear block for translator going away. */ di->i_translator = 0; np->dn->info_i_translator = 0; record_global_poke (di); ext2_free_blocks (blkno, 1); np->dn_stat.st_blocks -= 1 << log2_stat_blocks_per_fs_block; np->dn_stat.st_mode &= ~S_IPTRANS; np->dn_set_ctime = 1; } if (namelen) { buf[0] = namelen & 0xFF; buf[1] = (namelen >> 8) & 0xFF; bcopy (name, buf + 2, namelen); bcopy (buf, bptr (blkno), block_size); record_global_poke (bptr (blkno)); np->dn_stat.st_mode |= S_IPTRANS; np->dn_set_ctime = 1; } diskfs_end_catch_exception (); return err; } /* Implement the diskfs_get_translator callback from the diskfs library. See for the interface description. */ error_t diskfs_get_translator (struct node *np, char **namep, unsigned *namelen) { error_t err = 0; daddr_t blkno; unsigned datalen; const void *transloc; assert (sblock->s_creator_os == EXT2_OS_HURD); err = diskfs_catch_exception (); if (err) return err; blkno = (dino (np->cache_id))->i_translator; assert (blkno); transloc = bptr (blkno); datalen = ((unsigned char *)transloc)[0] + (((unsigned char *)transloc)[1] << 8); if (datalen > block_size - 2) err = EFTYPE; /* ? */ else { *namep = malloc (datalen); if (!*namep) err = ENOMEM; else memcpy (*namep, transloc + 2, datalen); } diskfs_end_catch_exception (); *namelen = datalen; return err; } /* The maximum size of a symlink store in the inode (including '\0'). */ #define MAX_INODE_SYMLINK \ (EXT2_N_BLOCKS * sizeof (((struct ext2_inode *)0)->i_block[0])) /* Write an in-inode symlink, or return EINVAL if we can't. */ static error_t write_symlink (struct node *node, const char *target) { size_t len = strlen (target) + 1; if (len > MAX_INODE_SYMLINK) return EINVAL; assert (node->dn_stat.st_blocks == 0); bcopy (target, node->dn->info.i_data, len); node->dn_stat.st_size = len - 1; node->dn_set_ctime = 1; node->dn_set_mtime = 1; return 0; } /* Read an in-inode symlink, or return EINVAL if we can't. */ static error_t read_symlink (struct node *node, char *target) { if (node->dn_stat.st_blocks) return EINVAL; assert (node->dn_stat.st_size < MAX_INODE_SYMLINK); bcopy (node->dn->info.i_data, target, node->dn_stat.st_size); return 0; } /* If this function is nonzero (and diskfs_shortcut_symlink is set) it is called to set a symlink. If it returns EINVAL or isn't set, then the normal method (writing the contents into the file data) is used. If it returns any other error, it is returned to the user. */ error_t (*diskfs_create_symlink_hook)(struct node *np, const char *target) = write_symlink; /* If this function is nonzero (and diskfs_shortcut_symlink is set) it is called to read the contents of a symlink. If it returns EINVAL or isn't set, then the normal method (reading from the file data) is used. If it returns any other error, it is returned to the user. */ error_t (*diskfs_read_symlink_hook)(struct node *np, char *target) = read_symlink; /* Called when all hard ports have gone away. */ void diskfs_shutdown_soft_ports () { /* Should initiate termination of internally held pager ports (the only things that should be soft) XXX */ }