/* * Copyright (c) 1989 The Regents of the University of California. * All rights reserved. * (c) UNIX System Laboratories, Inc. * All or some portions of this file are derived from material licensed * to the University of California by American Telephone and Telegraph * Co. or Unix System Laboratories, Inc. and are reproduced herein with * the permission of UNIX System Laboratories, Inc. * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions * are met: * 1. Redistributions of source code must retain the above copyright * notice, this list of conditions and the following disclaimer. * 2. Redistributions in binary form must reproduce the above copyright * notice, this list of conditions and the following disclaimer in the * documentation and/or other materials provided with the distribution. * 3. All advertising materials mentioning features or use of this software * must display the following acknowledgement: * This product includes software developed by the University of * California, Berkeley and its contributors. * 4. Neither the name of the University nor the names of its contributors * may be used to endorse or promote products derived from this software * without specific prior written permission. * * THIS SOFTWARE IS PROVIDED BY THE REGENTS AND CONTRIBUTORS ``AS IS'' AND * ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE * ARE DISCLAIMED. IN NO EVENT SHALL THE REGENTS OR CONTRIBUTORS BE LIABLE * FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL * DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS * OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) * HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT * LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY * OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF * SUCH DAMAGE. * * from: @(#)ufs_lookup.c 7.33 (Berkeley) 5/19/91 * $Id: ufs_lookup.c,v 1.9 1994/05/17 04:26:17 cgd Exp $ */ #include #include #include #include #include #include #include #include #include struct nchstats nchstats; #ifdef DIAGNOSTIC int dirchk = 1; #else int dirchk = 0; #endif /* * Convert a component of a pathname into a pointer to a locked inode. * This is a very central and rather complicated routine. * If the file system is not maintained in a strict tree hierarchy, * this can result in a deadlock situation (see comments in code below). * * The flag argument is LOOKUP, CREATE, RENAME, or DELETE depending on * whether the name is to be looked up, created, renamed, or deleted. * When CREATE, RENAME, or DELETE is specified, information usable in * creating, renaming, or deleting a directory entry may be calculated. * If flag has LOCKPARENT or'ed into it and the target of the pathname * exists, lookup returns both the target and its parent directory locked. * When creating or renaming and LOCKPARENT is specified, the target may * not be ".". When deleting and LOCKPARENT is specified, the target may * be "."., but the caller must check to ensure it does an vrele and iput * instead of two iputs. * * Overall outline of ufs_lookup: * * check accessibility of directory * look for name in cache, if found, then if at end of path * and deleting or creating, drop it, else return name * search for name in directory, to found or notfound * notfound: * if creating, return locked directory, leaving info on available slots * else return error * found: * if at end of path and deleting, return information to allow delete * if at end of path and rewriting (RENAME and LOCKPARENT), lock target * inode and return info to allow rewrite * if not at end, add name to cache; if at end and neither creating * nor deleting, add name to cache * * NOTE: (LOOKUP | LOCKPARENT) currently returns the parent inode unlocked. */ ufs_lookup(vdp, ndp, p) register struct vnode *vdp; register struct nameidata *ndp; struct proc *p; { register struct inode *dp; /* the directory we are searching */ register struct fs *fs; /* file system that directory is in */ struct buf *bp = 0; /* a buffer of directory entries */ register struct direct *ep; /* the current directory entry */ int entryoffsetinblock; /* offset of ep in bp's buffer */ enum {NONE, COMPACT, FOUND} slotstatus; int slotoffset = -1; /* offset of area with free space */ int slotsize; /* size of area at slotoffset */ int slotfreespace; /* amount of space free in slot */ int slotneeded; /* size of the entry we're seeking */ int numdirpasses; /* strategy for directory search */ int endsearch; /* offset to end directory search */ int prevoff; /* ndp->ni_ufs.ufs_offset of previous entry */ struct inode *pdp; /* saved dp during symlink work */ struct inode *tdp; /* returned by iget */ long enduseful; /* pointer past last used dir slot XXX - doff_t */ int flag; /* LOOKUP, CREATE, RENAME, or DELETE */ int lockparent; /* 1 => lockparent flag is set */ int wantparent; /* 1 => wantparent or lockparent flag */ int error; ndp->ni_dvp = vdp; ndp->ni_vp = NULL; dp = VTOI(vdp); fs = dp->i_fs; lockparent = ndp->ni_nameiop & LOCKPARENT; flag = ndp->ni_nameiop & OPMASK; wantparent = ndp->ni_nameiop & (LOCKPARENT|WANTPARENT); /* * Check accessiblity of directory. */ if ((dp->i_mode&IFMT) != IFDIR) return (ENOTDIR); if (error = ufs_access(vdp, VEXEC, ndp->ni_cred, p)) return (error); /* * We now have a segment name to search for, and a directory to search. * * Before tediously performing a linear scan of the directory, * check the name cache to see if the directory/name pair * we are looking for is known already. */ if (error = cache_lookup(ndp)) { int vpid; /* capability number of vnode */ if (error == ENOENT) return (error); #ifdef DIAGNOSTIC if (vdp == ndp->ni_rootdir && ndp->ni_isdotdot) panic("ufs_lookup: .. through root"); #endif /* * Get the next vnode in the path. * See comment below starting `Step through' for * an explaination of the locking protocol. */ pdp = dp; dp = VTOI(ndp->ni_vp); vdp = ndp->ni_vp; vpid = vdp->v_id; if (pdp == dp) { VREF(vdp); error = 0; } else if (ndp->ni_isdotdot) { IUNLOCK(pdp); error = vget(vdp, 1); if (!error && lockparent && *ndp->ni_next == '\0') ILOCK(pdp); } else { error = vget(vdp, 1); if (!lockparent || error || *ndp->ni_next != '\0') IUNLOCK(pdp); } /* * Check that the capability number did not change * while we were waiting for the lock. */ if (!error) { if (vpid == vdp->v_id) return (0); iput(dp); if (lockparent && pdp != dp && *ndp->ni_next == '\0') IUNLOCK(pdp); } ILOCK(pdp); dp = pdp; vdp = ITOV(dp); ndp->ni_vp = NULL; } /* * Suppress search for slots unless creating * file and at end of pathname, in which case * we watch for a place to put the new file in * case it doesn't already exist. */ slotstatus = FOUND; if ((flag == CREATE || flag == RENAME) && *ndp->ni_next == 0) { slotstatus = NONE; slotfreespace = 0; slotneeded = ((sizeof (struct direct) - (MAXNAMLEN + 1)) + ((ndp->ni_namelen + 1 + 3) &~ 3)); } /* * If there is cached information on a previous search of * this directory, pick up where we last left off. * We cache only lookups as these are the most common * and have the greatest payoff. Caching CREATE has little * benefit as it usually must search the entire directory * to determine that the entry does not exist. Caching the * location of the last DELETE or RENAME has not reduced * profiling time and hence has been removed in the interest * of simplicity. */ if (flag != LOOKUP || dp->i_diroff == 0 || dp->i_diroff > dp->i_size) { ndp->ni_ufs.ufs_offset = 0; numdirpasses = 1; } else { ndp->ni_ufs.ufs_offset = dp->i_diroff; entryoffsetinblock = blkoff(fs, ndp->ni_ufs.ufs_offset); if (entryoffsetinblock != 0) { if (error = blkatoff(dp, (off_t)ndp->ni_ufs.ufs_offset, (char **)0, &bp)) return (error); } numdirpasses = 2; nchstats.ncs_2passes++; } endsearch = roundup(dp->i_size, DIRBLKSIZ); enduseful = 0; searchloop: while (ndp->ni_ufs.ufs_offset < endsearch) { /* * If offset is on a block boundary, * read the next directory block. * Release previous if it exists. */ if (blkoff(fs, ndp->ni_ufs.ufs_offset) == 0) { if (bp != NULL) brelse(bp); if (error = blkatoff(dp, (off_t)ndp->ni_ufs.ufs_offset, (char **)0, &bp)) return (error); entryoffsetinblock = 0; } /* * If still looking for a slot, and at a DIRBLKSIZE * boundary, have to start looking for free space again. */ if (slotstatus == NONE && (entryoffsetinblock & (DIRBLKSIZ - 1)) == 0) { slotoffset = -1; slotfreespace = 0; } /* * Get pointer to next entry. * Full validation checks are slow, so we only check * enough to insure forward progress through the * directory. Complete checks can be run by patching * "dirchk" to be true. */ ep = (struct direct *)(bp->b_un.b_addr + entryoffsetinblock); if (ep->d_reclen == 0 || dirchk && dirbadentry(ep, entryoffsetinblock)) { int i; printf("ep = 0x%x\n", ep); printf("addr = 0x%x\n", bp->b_un.b_addr); printf("eoib = 0x%x\n", entryoffsetinblock); printf("d_fileno = %d\n", ep->d_ino); printf("d_reclen = %d\n", ep->d_reclen); printf("d_namelen = %d\n", ep->d_namlen); dirbad(dp, ndp->ni_ufs.ufs_offset, "mangled entry"); i = DIRBLKSIZ - (entryoffsetinblock & (DIRBLKSIZ - 1)); ndp->ni_ufs.ufs_offset += i; entryoffsetinblock += i; continue; } /* * If an appropriate sized slot has not yet been found, * check to see if one is available. Also accumulate space * in the current block so that we can determine if * compaction is viable. */ if (slotstatus != FOUND) { int size = ep->d_reclen; if (ep->d_ino != 0) size -= DIRSIZ(ep); if (size > 0) { if (size >= slotneeded) { slotstatus = FOUND; slotoffset = ndp->ni_ufs.ufs_offset; slotsize = ep->d_reclen; } else if (slotstatus == NONE) { slotfreespace += size; if (slotoffset == -1) slotoffset = ndp->ni_ufs.ufs_offset; if (slotfreespace >= slotneeded) { slotstatus = COMPACT; slotsize = ndp->ni_ufs.ufs_offset + ep->d_reclen - slotoffset; } } } } /* * Check for a name match. */ if (ep->d_ino) { if (ep->d_namlen == ndp->ni_namelen && !bcmp(ndp->ni_ptr, ep->d_name, (unsigned)ep->d_namlen)) { /* * Save directory entry's inode number and * reclen in ndp->ni_ufs area, and release * directory buffer. */ ndp->ni_ufs.ufs_ino = ep->d_ino; ndp->ni_ufs.ufs_reclen = ep->d_reclen; goto found; } } prevoff = ndp->ni_ufs.ufs_offset; ndp->ni_ufs.ufs_offset += ep->d_reclen; entryoffsetinblock += ep->d_reclen; if (ep->d_ino) enduseful = ndp->ni_ufs.ufs_offset; } /* notfound: */ /* * If we started in the middle of the directory and failed * to find our target, we must check the beginning as well. */ if (numdirpasses == 2) { numdirpasses--; ndp->ni_ufs.ufs_offset = 0; endsearch = dp->i_diroff; goto searchloop; } if (bp != NULL) brelse(bp); /* * If creating, and at end of pathname and current * directory has not been removed, then can consider * allowing file to be created. */ if ((flag == CREATE || flag == RENAME) && *ndp->ni_next == 0 && dp->i_nlink != 0) { /* * Access for write is interpreted as allowing * creation of files in the directory. */ if (error = ufs_access(vdp, VWRITE, ndp->ni_cred, p)) return (error); /* * Return an indication of where the new directory * entry should be put. If we didn't find a slot, * then set ndp->ni_ufs.ufs_count to 0 indicating * that the new slot belongs at the end of the * directory. If we found a slot, then the new entry * can be put in the range from ndp->ni_ufs.ufs_offset * to ndp->ni_ufs.ufs_offset + ndp->ni_ufs.ufs_count. */ if (slotstatus == NONE) { ndp->ni_ufs.ufs_offset = roundup(dp->i_size, DIRBLKSIZ); ndp->ni_ufs.ufs_count = 0; enduseful = ndp->ni_ufs.ufs_offset; } else { ndp->ni_ufs.ufs_offset = slotoffset; ndp->ni_ufs.ufs_count = slotsize; if (enduseful < slotoffset + slotsize) enduseful = slotoffset + slotsize; } ndp->ni_ufs.ufs_endoff = roundup(enduseful, DIRBLKSIZ); dp->i_flag |= IUPD|ICHG; /* * We return with the directory locked, so that * the parameters we set up above will still be * valid if we actually decide to do a direnter(). * We return ni_vp == NULL to indicate that the entry * does not currently exist; we leave a pointer to * the (locked) directory inode in ndp->ni_dvp. * The pathname buffer is saved so that the name * can be obtained later. * * NB - if the directory is unlocked, then this * information cannot be used. */ ndp->ni_nameiop |= SAVENAME; if (!lockparent) IUNLOCK(dp); return (EJUSTRETURN); } /* * Insert name into cache (as non-existent) if appropriate. */ if (ndp->ni_makeentry && flag != CREATE) cache_enter(ndp); return (ENOENT); found: if (numdirpasses == 2) nchstats.ncs_pass2++; /* * Check that directory length properly reflects presence * of this entry. */ if (entryoffsetinblock + DIRSIZ(ep) > dp->i_size) { dirbad(dp, ndp->ni_ufs.ufs_offset, "i_size too small"); dp->i_size = entryoffsetinblock + DIRSIZ(ep); dp->i_flag |= IUPD|ICHG; } brelse(bp); /* * Found component in pathname. * If the final component of path name, save information * in the cache as to where the entry was found. */ if (*ndp->ni_next == '\0' && flag == LOOKUP) dp->i_diroff = ndp->ni_ufs.ufs_offset &~ (DIRBLKSIZ - 1); /* * If deleting, and at end of pathname, return * parameters which can be used to remove file. * If the wantparent flag isn't set, we return only * the directory (in ndp->ni_dvp), otherwise we go * on and lock the inode, being careful with ".". */ if (flag == DELETE && *ndp->ni_next == 0) { /* * Write access to directory required to delete files. */ if (error = ufs_access(vdp, VWRITE, ndp->ni_cred, p)) return (error); /* * Return pointer to current entry in ndp->ni_ufs.ufs_offset, * and distance past previous entry (if there * is a previous entry in this block) in ndp->ni_ufs.ufs_count. * Save directory inode pointer in ndp->ni_dvp for dirremove(). */ if ((ndp->ni_ufs.ufs_offset&(DIRBLKSIZ-1)) == 0) ndp->ni_ufs.ufs_count = 0; else ndp->ni_ufs.ufs_count = ndp->ni_ufs.ufs_offset - prevoff; if (dp->i_number == ndp->ni_ufs.ufs_ino) { VREF(vdp); ndp->ni_vp = vdp; return (0); } if (error = iget(dp, ndp->ni_ufs.ufs_ino, &tdp)) return (error); /* * If directory is "sticky", then user must own * the directory, or the file in it, else she * may not delete it (unless she's root). This * implements append-only directories. */ if ((dp->i_mode & ISVTX) && ndp->ni_cred->cr_uid != 0 && ndp->ni_cred->cr_uid != dp->i_uid && tdp->i_uid != ndp->ni_cred->cr_uid) { iput(tdp); return (EPERM); } ndp->ni_vp = ITOV(tdp); if (!lockparent) IUNLOCK(dp); return (0); } /* * If rewriting (RENAME), return the inode and the * information required to rewrite the present directory * Must get inode of directory entry to verify it's a * regular file, or empty directory. */ if (flag == RENAME && wantparent && *ndp->ni_next == 0) { if (error = ufs_access(vdp, VWRITE, ndp->ni_cred, p)) return (error); /* * Careful about locking second inode. * This can only occur if the target is ".". */ if (dp->i_number == ndp->ni_ufs.ufs_ino) return (EISDIR); if (error = iget(dp, ndp->ni_ufs.ufs_ino, &tdp)) return (error); ndp->ni_vp = ITOV(tdp); ndp->ni_nameiop |= SAVENAME; if (!lockparent) IUNLOCK(dp); return (0); } /* * Step through the translation in the name. We do not `iput' the * directory because we may need it again if a symbolic link * is relative to the current directory. Instead we save it * unlocked as "pdp". We must get the target inode before unlocking * the directory to insure that the inode will not be removed * before we get it. We prevent deadlock by always fetching * inodes from the root, moving down the directory tree. Thus * when following backward pointers ".." we must unlock the * parent directory before getting the requested directory. * There is a potential race condition here if both the current * and parent directories are removed before the `iget' for the * inode associated with ".." returns. We hope that this occurs * infrequently since we cannot avoid this race condition without * implementing a sophisticated deadlock detection algorithm. * Note also that this simple deadlock detection scheme will not * work if the file system has any hard links other than ".." * that point backwards in the directory structure. */ pdp = dp; if (ndp->ni_isdotdot) { IUNLOCK(pdp); /* race to get the inode */ if (error = iget(dp, ndp->ni_ufs.ufs_ino, &tdp)) { ILOCK(pdp); return (error); } if (lockparent && *ndp->ni_next == '\0') ILOCK(pdp); ndp->ni_vp = ITOV(tdp); } else if (dp->i_number == ndp->ni_ufs.ufs_ino) { VREF(vdp); /* we want ourself, ie "." */ ndp->ni_vp = vdp; } else { if (error = iget(dp, ndp->ni_ufs.ufs_ino, &tdp)) return (error); if (!lockparent || *ndp->ni_next != '\0') IUNLOCK(pdp); ndp->ni_vp = ITOV(tdp); } /* * Insert name into cache if appropriate. */ if (ndp->ni_makeentry) cache_enter(ndp); return (0); } dirbad(ip, offset, how) struct inode *ip; long offset; /* doff_t */ char *how; { printf("%s: bad dir ino %d at offset %d: %s\n", ip->i_fs->fs_fsmnt, ip->i_number, offset, how); if (ip->i_fs->fs_ronly == 0) panic("bad dir"); } /* * Do consistency checking on a directory entry: * record length must be multiple of 4 * entry must fit in rest of its DIRBLKSIZ block * record must be large enough to contain entry * name is not longer than MAXNAMLEN * name must be as long as advertised, and null terminated */ dirbadentry(ep, entryoffsetinblock) register struct direct *ep; int entryoffsetinblock; { register int i; if ((ep->d_reclen & 0x3) != 0 || ep->d_reclen > DIRBLKSIZ - (entryoffsetinblock & (DIRBLKSIZ - 1)) || ep->d_reclen < DIRSIZ(ep) || ep->d_namlen > MAXNAMLEN) return (1); for (i = 0; i < ep->d_namlen; i++) if (ep->d_name[i] == '\0') return (1); return (ep->d_name[i]); } /* * Write a directory entry after a call to namei, using the parameters * that it left in nameidata. The argument ip is the inode which the new * directory entry will refer to. The nameidata field ndp->ni_dvp is a * pointer to the directory to be written, which was left locked by namei. * Remaining parameters (ndp->ni_ufs.ufs_offset, ndp->ni_ufs.ufs_count) * indicate how the space for the new entry is to be obtained. */ direnter(ip, ndp) struct inode *ip; register struct nameidata *ndp; { register struct direct *ep, *nep; register struct inode *dp = VTOI(ndp->ni_dvp); struct buf *bp; int loc, spacefree, error = 0; u_int dsize; int newentrysize; char *dirbuf; struct uio auio; struct iovec aiov; struct direct newdir; #ifdef DIAGNOSTIC if ((ndp->ni_nameiop & SAVENAME) == 0) panic("direnter: missing name"); #endif newdir.d_ino = ip->i_number; newdir.d_namlen = ndp->ni_namelen; bcopy(ndp->ni_ptr, newdir.d_name, (unsigned)ndp->ni_namelen + 1); newentrysize = DIRSIZ(&newdir); if (ndp->ni_ufs.ufs_count == 0) { /* * If ndp->ni_ufs.ufs_count is 0, then namei could find no * space in the directory. Here, ndp->ni_ufs.ufs_offset will * be on a directory block boundary and we will write the * new entry into a fresh block. */ if (ndp->ni_ufs.ufs_offset & (DIRBLKSIZ - 1)) panic("wdir: newblk"); auio.uio_offset = ndp->ni_ufs.ufs_offset; newdir.d_reclen = DIRBLKSIZ; auio.uio_resid = newentrysize; aiov.iov_len = newentrysize; aiov.iov_base = (caddr_t)&newdir; auio.uio_iov = &aiov; auio.uio_iovcnt = 1; auio.uio_rw = UIO_WRITE; auio.uio_segflg = UIO_SYSSPACE; auio.uio_procp = (struct proc *)0; error = ufs_write(ndp->ni_dvp, &auio, IO_SYNC, ndp->ni_cred); if (DIRBLKSIZ > dp->i_fs->fs_fsize) { panic("wdir: blksize"); /* XXX - should grow w/balloc */ } else if (!error) { dp->i_size = roundup(dp->i_size, DIRBLKSIZ); dp->i_flag |= ICHG; } return (error); } /* * If ndp->ni_ufs.ufs_count is non-zero, then namei found space * for the new entry in the range ndp->ni_ufs.ufs_offset to * ndp->ni_ufs.ufs_offset + ndp->ni_ufs.ufs_count in the directory. * To use this space, we may have to compact the entries located * there, by copying them together towards the beginning of the * block, leaving the free space in one usable chunk at the end. */ /* * Increase size of directory if entry eats into new space. * This should never push the size past a new multiple of * DIRBLKSIZE. * * N.B. - THIS IS AN ARTIFACT OF 4.2 AND SHOULD NEVER HAPPEN. */ if (ndp->ni_ufs.ufs_offset + ndp->ni_ufs.ufs_count > dp->i_size) dp->i_size = ndp->ni_ufs.ufs_offset + ndp->ni_ufs.ufs_count; /* * Get the block containing the space for the new directory entry. */ if (error = blkatoff(dp, (off_t)ndp->ni_ufs.ufs_offset, (char **)&dirbuf, &bp)) return (error); /* * Find space for the new entry. In the simple case, the entry at * offset base will have the space. If it does not, then namei * arranged that compacting the region ndp->ni_ufs.ufs_offset to * ndp->ni_ufs.ufs_offset + ndp->ni_ufs.ufs_count would yield the * space. */ ep = (struct direct *)dirbuf; dsize = DIRSIZ(ep); spacefree = ep->d_reclen - dsize; for (loc = ep->d_reclen; loc < ndp->ni_ufs.ufs_count; ) { nep = (struct direct *)(dirbuf + loc); if (ep->d_ino) { /* trim the existing slot */ ep->d_reclen = dsize; ep = (struct direct *)((char *)ep + dsize); } else { /* overwrite; nothing there; header is ours */ spacefree += dsize; } dsize = DIRSIZ(nep); spacefree += nep->d_reclen - dsize; loc += nep->d_reclen; bcopy((caddr_t)nep, (caddr_t)ep, dsize); } /* * Update the pointer fields in the previous entry (if any), * copy in the new entry, and write out the block. */ if (ep->d_ino == 0) { if (spacefree + dsize < newentrysize) panic("wdir: compact1"); newdir.d_reclen = spacefree + dsize; } else { if (spacefree < newentrysize) panic("wdir: compact2"); newdir.d_reclen = spacefree; ep->d_reclen = dsize; ep = (struct direct *)((char *)ep + dsize); } bcopy((caddr_t)&newdir, (caddr_t)ep, (u_int)newentrysize); error = bwrite(bp); dp->i_flag |= IUPD|ICHG; if (!error && ndp->ni_ufs.ufs_endoff && ndp->ni_ufs.ufs_endoff < dp->i_size) error = itrunc(dp, (u_long)ndp->ni_ufs.ufs_endoff, IO_SYNC); return (error); } /* * Remove a directory entry after a call to namei, using * the parameters which it left in nameidata. The entry * ni_ufs.ufs_offset contains the offset into the directory of the * entry to be eliminated. The ni_ufs.ufs_count field contains the * size of the previous record in the directory. If this * is 0, the first entry is being deleted, so we need only * zero the inode number to mark the entry as free. If the * entry is not the first in the directory, we must reclaim * the space of the now empty record by adding the record size * to the size of the previous entry. */ dirremove(ndp) register struct nameidata *ndp; { register struct inode *dp = VTOI(ndp->ni_dvp); struct direct *ep; struct buf *bp; int error; if (ndp->ni_ufs.ufs_count == 0) { /* * First entry in block: set d_ino to zero. */ error = blkatoff(dp, (off_t)ndp->ni_ufs.ufs_offset, (char **)&ep, &bp); if (error) return (error); ep->d_ino = 0; error = bwrite(bp); dp->i_flag |= IUPD|ICHG; return (error); } /* * Collapse new free space into previous entry. */ if (error = blkatoff(dp, (off_t)ndp->ni_ufs.ufs_offset - ndp->ni_ufs.ufs_count, (char **)&ep, &bp)) { return (error); } ep->d_reclen += ndp->ni_ufs.ufs_reclen; error = bwrite(bp); dp->i_flag |= IUPD|ICHG; return (error); } /* * Rewrite an existing directory entry to point at the inode * supplied. The parameters describing the directory entry are * set up by a call to namei. */ dirrewrite(dp, ip, ndp) struct inode *dp, *ip; struct nameidata *ndp; { struct direct *ep; struct buf *bp; int error; if (error = blkatoff(dp, (off_t)ndp->ni_ufs.ufs_offset, (char **)&ep, &bp)) return (error); ep->d_ino = ip->i_number; error = bwrite(bp); dp->i_flag |= IUPD|ICHG; return (error); } /* * Return buffer with contents of block "offset" * from the beginning of directory "ip". If "res" * is non-zero, fill it in with a pointer to the * remaining space in the directory. */ blkatoff(ip, offset, res, bpp) struct inode *ip; off_t offset; char **res; struct buf **bpp; { register struct fs *fs = ip->i_fs; daddr_t lbn = lblkno(fs, offset); int bsize = blksize(fs, ip, lbn); struct buf *bp; daddr_t bn; int error; *bpp = 0; if (error = bread(ITOV(ip), lbn, bsize, NOCRED, &bp)) { brelse(bp); return (error); } if (res) *res = bp->b_un.b_addr + blkoff(fs, offset); *bpp = bp; return (0); } /* * Check if a directory is empty or not. * Inode supplied must be locked. * * Using a struct dirtemplate here is not precisely * what we want, but better than using a struct direct. * * NB: does not handle corrupted directories. */ dirempty(ip, parentino, cred) register struct inode *ip; ino_t parentino; struct ucred *cred; { register off_t off; struct dirtemplate dbuf; register struct direct *dp = (struct direct *)&dbuf; int error, count; #define MINDIRSIZ (sizeof (struct dirtemplate) / 2) for (off = 0; off < ip->i_size; off += dp->d_reclen) { error = vn_rdwr(UIO_READ, ITOV(ip), (caddr_t)dp, MINDIRSIZ, off, UIO_SYSSPACE, IO_NODELOCKED, cred, &count, (struct proc *)0); /* * Since we read MINDIRSIZ, residual must * be 0 unless we're at end of file. */ if (error || count != 0) return (0); /* avoid infinite loops */ if (dp->d_reclen == 0) return (0); /* skip empty entries */ if (dp->d_ino == 0) continue; /* accept only "." and ".." */ if (dp->d_namlen > 2) return (0); if (dp->d_name[0] != '.') return (0); /* * At this point d_namlen must be 1 or 2. * 1 implies ".", 2 implies ".." if second * char is also "." */ if (dp->d_namlen == 1) continue; if (dp->d_name[1] == '.' && dp->d_ino == parentino) continue; return (0); } return (1); } /* * Check if source directory is in the path of the target directory. * Target is supplied locked, source is unlocked. * The target is always iput() before returning. */ checkpath(source, target, cred) struct inode *source, *target; struct ucred *cred; { struct dirtemplate dirbuf; struct inode *ip; int error = 0; ip = target; if (ip->i_number == source->i_number) { error = EEXIST; goto out; } if (ip->i_number == ROOTINO) goto out; for (;;) { if ((ip->i_mode&IFMT) != IFDIR) { error = ENOTDIR; break; } error = vn_rdwr(UIO_READ, ITOV(ip), (caddr_t)&dirbuf, sizeof (struct dirtemplate), (off_t)0, UIO_SYSSPACE, IO_NODELOCKED, cred, (int *)0, (struct proc *)0); if (error != 0) break; if (dirbuf.dotdot_namlen != 2 || dirbuf.dotdot_name[0] != '.' || dirbuf.dotdot_name[1] != '.') { error = ENOTDIR; break; } if (dirbuf.dotdot_ino == source->i_number) { error = EINVAL; break; } if (dirbuf.dotdot_ino == ROOTINO) break; iput(ip); if (error = iget(ip, dirbuf.dotdot_ino, &ip)) break; } out: if (error == ENOTDIR) printf("checkpath: .. not a directory\n"); if (ip != NULL) iput(ip); return (error); }