/* Inode management routines Copyright (C) 1994, 1995 Free Software Foundation, Inc. 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 #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_disknode (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 iget (ino_t inum, struct node **npp) { int offset; struct disknode *dn; struct node *np; error_t err; spin_lock (&diskfs_node_refcnt_lock); for (np = nodehash[INOHASH(inum)]; np; np = np->dn->hnext) { if (np->dn->number != inum) continue; np->references++; spin_unlock (&diskfs_node_refcnt_lock); mutex_lock (&np->lock); *npp = np; return 0; } dn = malloc (sizeof (struct disknode)); dn->number = inum; dn->dirents = 0; rwlock_init (&dn->alloc_lock); pokel_init (&dn->pokel, disk_pager->p, disk_image); dn->fileinfo = 0; np = diskfs_make_node (dn); mutex_lock (&np->lock); 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); err = read_disknode (np); np->allocsize = np->dn_stat.st_size; offset = np->allocsize % block_size; if (offset > 0) np->allocsize += block_size - offset; if (!diskfs_readonly && !np->dn_stat.st_gen) { spin_lock (&generation_lock); if (++nextgennumber < diskfs_mtime->seconds) nextgennumber = diskfs_mtime->seconds; np->dn_stat.st_gen = nextgennumber; 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->dn->number != 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->fileinfo); 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) { #ifdef notanymore struct port_info *pi; struct pager *p; /* Check and see if there is a pager which has only one reference (ours). If so, then drop that reference, breaking the cycle. The complexity in this routine is all due to this cycle. */ if (np->dn->fileinfo) { spin_lock (&_libports_portrefcntlock); pi = (struct port_info *) np->dn->fileinfo->p; if (pi->refcnt == 1) { /* The only way to get a new reference to the pager in this state is to call diskfs_get_filemap; this can't happen as long as we hold NP locked. So we can safely unlock _libports_portrefcntlock for the following call. */ spin_unlock (&_libports_portrefcntlock); /* Right now the node is locked with no hard refs; this is an anomolous situation. Before messing with the reference count on the file pager, we have to give ourselves a reference back so that we are really allowed to hold the lock. Then we can do the unreference. */ p = np->dn->fileinfo->p; np->dn->fileinfo = 0; diskfs_nref (np); pager_unreference (p); assert (np->references == 1 && np->light_references == 0); /* This will do the real deallocate. Whew. */ diskfs_nput (np); } else spin_unlock (&_libports_portrefcntlock); } #endif } /* 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_disknode (struct node *np) { static int fsid, fsidset; struct stat *st = &np->dn_stat; struct ext2_inode *di = dino (np->dn->number); struct ext2_inode_info *info = &np->dn->info; error_t err; err = diskfs_catch_exception (); if (err) return err; np->istranslated = !! di->i_translator; if (!fsidset) { fsid = getpid (); fsidset = 1; } st->st_fstype = FSTYPE_EXT2FS; st->st_fsid = fsid; st->st_ino = np->dn->number; st->st_blksize = block_size; st->st_mode = di->i_mode | (di->i_mode_high << 16); st->st_nlink = di->i_links_count; st->st_size = di->i_size; st->st_gen = di->i_version; st->st_atime = di->i_atime; st->st_mtime = di->i_mtime; st->st_ctime = di->i_ctime; #ifdef XXX st->st_atime_usec = di->i_atime.ts_nsec / 1000; st->st_mtime_usec = di->i_mtime.ts_nsec / 1000; st->st_ctime_usec = di->i_ctime.ts_nsec / 1000; #endif st->st_blocks = di->i_blocks; st->st_flags = di->i_flags; 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; /* 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; info->i_dir_acl = di->i_dir_acl; info->i_version = di->i_version; info->i_block_group = inode_group_num(np->dn->number); info->i_next_alloc_block = 0; info->i_next_alloc_goal = 0; if (info->i_prealloc_count) ext2_error ("ext2_read_inode", "New inode has non-zero prealloc count!"); if (S_ISCHR(st->st_mode) || S_ISBLK(st->st_mode)) st->st_rdev = di->i_block[0]; else { int block; for (block = 0; block < EXT2_N_BLOCKS; block++) info->i_data[block] = di->i_block[block]; st->st_rdev = 0; } diskfs_end_catch_exception (); return 0; } static void write_node (struct node *np) { struct stat *st = &np->dn_stat; struct ext2_inode *di = dino (np->dn->number); error_t err; assert (!np->dn_set_ctime && !np->dn_set_atime && !np->dn_set_mtime); if (np->dn_stat_dirty) { assert (!diskfs_readonly); err = diskfs_catch_exception (); if (err) return; di->i_version = st->st_gen; /* We happen to know that the stat mode bits are the same as the ext2fs mode bits. */ /* XXX? */ di->i_mode = st->st_mode & 0xffff; di->i_mode_high = (st->st_mode >> 16) & 0xffff; di->i_uid = st->st_uid & 0xFFFF; di->i_gid = st->st_gid & 0xFFFF; di->i_uid_high = st->st_uid >> 16; di->i_gid_high = st->st_gid >> 16; di->i_author = st->st_author; di->i_links_count = st->st_nlink; di->i_size = st->st_size; di->i_atime = st->st_atime; di->i_mtime = st->st_mtime; di->i_ctime = st->st_ctime; #ifdef XXX di->i_atime.ts_nsec = st->st_atime_usec * 1000; di->i_mtime.ts_nsec = st->st_mtime_usec * 1000; di->i_ctime.ts_nsec = st->st_ctime_usec * 1000; #endif di->i_blocks = st->st_blocks; di->i_flags = st->st_flags; if (S_ISCHR(st->st_mode) || S_ISBLK(st->st_mode)) di->i_block[0] = st->st_rdev; else { int block; for (block = 0; block < EXT2_N_BLOCKS; block++) di->i_block[block] = np->dn->info.i_data[block]; } diskfs_end_catch_exception (); np->dn_stat_dirty = 0; pokel_add (&np->dn->pokel, di, sizeof (struct ext2_inode)); } } /* Write all active disknodes into the ext2_inode pager. */ void write_all_disknodes () { int n; struct node *np; spin_lock (&diskfs_node_refcnt_lock); for (n = 0; n < INOHSZ; n++) for (np = nodehash[n]; np; np = np->dn->hnext) { diskfs_set_node_times (np); write_node (np); } spin_unlock (&diskfs_node_refcnt_lock); } void diskfs_write_disknode (struct node *np, int wait) { write_node (np); pokel_sync (&np->dn->pokel, wait); } /* Implement the diskfs_set_statfs callback from the diskfs library; see for the interface description. */ error_t diskfs_set_statfs (struct fsys_statfsbuf *st) { st->fsys_stb_type = FSTYPE_EXT2FS; st->fsys_stb_fsize = EXT2_BLOCK_SIZE(sblock); st->fsys_stb_fsize = EXT2_FRAG_SIZE(sblock); st->fsys_stb_blocks = sblock->s_blocks_count; st->fsys_stb_bfree = sblock->s_free_blocks_count; st->fsys_stb_bavail = st->fsys_stb_bfree - sblock->s_r_blocks_count; st->fsys_stb_files = sblock->s_inodes_count; st->fsys_stb_ffree = sblock->s_free_inodes_count; st->fsys_stb_fsid = getpid (); 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, char *name, u_int namelen, struct protid *cred) { #ifdef XXX daddr_t blkno; error_t err; char buf[sblock->fs_bsize]; struct ext2_inode *di; if (compat_mode != COMPAT_GNU) return EOPNOTSUPP; if (namelen + sizeof (u_int) > sblock->fs_bsize) return ENAMETOOLONG; err = diskfs_catch_exception (); if (err) return err; di = dino (np->dn->number); blkno = di->i_trans; if (namelen && !blkno) { /* Allocate block for translator */ err = ffs_alloc (np, 0, 0, sblock->fs_bsize, &blkno, cred); if (err) { diskfs_end_catch_exception (); return err; } di->i_trans = blkno; pokel_add (&np->dn.pokel, di, sizeof (struct ext2_inode)); np->dn_set_ctime = 1; } else if (!namelen && blkno) { /* Clear block for translator going away. */ ffs_blkfree (np, blkno, sblock->fs_bsize); di->i_trans = 0; pokel_add (&np->dn.pokel, di, sizeof (struct ext2_inode)); np->dn_stat.st_blocks -= btodb (sblock->fs_bsize); np->istranslated = 0; np->dn_set_ctime = 1; } if (namelen) { bcopy (&namelen, buf, sizeof (u_int)); bcopy (name, buf + sizeof (u_int), namelen); bcopy (buf, disk_image + fsaddr (sblock, blkno), sblock->fs_bsize); sync_disk_blocks (blkno, sblock->fs_bsize, 1); np->istranslated = 1; np->dn_set_ctime = 1; } diskfs_end_catch_exception (); return err; #else return EOPNOTSUPP; #endif } /* 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, u_int *namelen) { #ifdef XXX error_t err; daddr_t blkno; u_int datalen; void *transloc; err = diskfs_catch_exception (); if (err) return err; blkno = (dino (np->dn->number))->i_trans; assert (blkno); transloc = disk_image + fsaddr (sblock, blkno); datalen = *(u_int *)transloc; if (datalen > *namelen) vm_allocate (mach_task_self (), (vm_address_t *) namep, datalen, 1); bcopy (transloc + sizeof (u_int), *namep, datalen); diskfs_end_catch_exception (); *namelen = datalen; return 0; #else return EOPNOTSUPP; #endif } /* 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 */ }