| blob | 8b3c284ce92ea55698b8bd5f1d132de62e5076a2 |
1 /*
2 *
3 * Copyright (C) 2011 Novell Inc.
4 *
5 * This program is free software; you can redistribute it and/or modify it
6 * under the terms of the GNU General Public License version 2 as published by
7 * the Free Software Foundation.
8 */
10 #include <linux/fs.h>
11 #include <linux/slab.h>
12 #include <linux/cred.h>
13 #include <linux/xattr.h>
14 #include <linux/posix_acl.h>
15 #include <linux/ratelimit.h>
20 {
41 /* Truncate should trigger data copy up as well */
43 }
47 else
59 }
74 }
75 out_drop_write:
77 out:
79 }
83 {
88 /*
89 * When all layers are on the same fs, all real inode
90 * number are unique, so we use the overlay st_dev,
91 * which is friendly to du -x.
92 */
97 /*
98 * All inode numbers of underlying fs should not be using the
99 * high xinobits, so we use high xinobits to partition the
100 * overlay st_ino address space. The high bits holds the fsid
101 * (upper fsid is 0). This way overlay inode numbers are unique
102 * and all inodes use overlay st_dev. Inode numbers are also
103 * persistent for a given layer configuration.
104 */
114 }
115 }
117 /* The inode could not be mapped to a unified st_ino address space */
119 /*
120 * Always use the overlay st_dev for directories, so 'find
121 * -xdev' will scan the entire overlay mount and won't cross the
122 * overlay mount boundaries.
123 *
124 * If not all layers are on the same fs the pair {real st_ino;
125 * overlay st_dev} is not unique, so use the non persistent
126 * overlay st_ino for directories.
127 */
131 /*
132 * For non-samefs setup, if we cannot map all layers st_ino
133 * to a unified address space, we need to make sure that st_dev
134 * is unique per lower fs. Upper layer uses real st_dev and
135 * lower layers use the unique anonymous bdev assigned to the
136 * lower fs.
137 */
139 }
142 }
146 {
165 /*
166 * For non-dir or same fs, we use st_ino of the copy up origin.
167 * This guaranties constant st_dev/st_ino across copy up.
168 * With xino feature and non-samefs, we use st_ino of the copy up
169 * origin masked with high bits that represent the layer id.
170 *
171 * If lower filesystem supports NFS file handles, this also guaranties
172 * persistent st_ino across mount cycle.
173 */
188 /*
189 * Lower hardlinks may be broken on copy up to different
190 * upper files, so we cannot use the lower origin st_ino
191 * for those different files, even for the same fs case.
192 *
193 * Similarly, several redirected dirs can point to the
194 * same dir on a lower layer. With the "verify_lower"
195 * feature, we do not use the lower origin st_ino, if
196 * we haven't verified that this redirect is unique.
197 *
198 * With inodes index enabled, it is safe to use st_ino
199 * of an indexed origin. The index validates that the
200 * upper hardlink is not broken and that a redirected
201 * dir is the only redirect to that origin.
202 */
207 /*
208 * Cannot use origin st_dev;st_ino because
209 * origin inode content may differ from overlay
210 * inode content.
211 */
214 }
216 /*
217 * If we are querying a metacopy dentry and lower
218 * dentry is data dentry, then use the blocks we
219 * queried just now. We don't have to do additional
220 * vfs_getattr(). If lower itself is metacopy, then
221 * additional vfs_getattr() is unavoidable.
222 */
227 }
228 }
231 /*
232 * If lower is not same as lowerdata or if there was
233 * no origin on upper, we can end up here.
234 */
244 }
245 }
251 /*
252 * It's probably not worth it to count subdirs to get the
253 * correct link count. nlink=1 seems to pacify 'find' and
254 * other utilities.
255 */
259 /*
260 * Return the overlay inode nlinks for indexed upper inodes.
261 * Overlay inode nlink counts the union of the upper hardlinks
262 * and non-covered lower hardlinks. It does not include the upper
263 * index hardlink.
264 */
268 out:
272 }
275 {
281 /* Careful in RCU walk mode */
285 }
287 /*
288 * Check overlay inode with the creds of task and underlying inode
289 * with creds of mounter
290 */
299 /* Make sure mounter can read file for copy up later */
301 }
306 }
311 {
322 }
325 {
328 }
332 {
346 }
354 }
362 }
365 /* copy c/mtime */
368 out_drop_write:
370 out:
372 }
376 {
377 ssize_t res;
386 }
389 {
390 /* List all non-trusted xatts */
394 /* Never list trusted.overlay, list other trusted for superuser only */
397 }
400 {
402 ssize_t res;
413 /* filter out private xattrs */
417 /* underlying fs providing us with an broken xattr list? */
427 }
428 }
431 }
434 {
447 }
450 {
456 };
461 }
462 }
464 }
468 {
485 }
495 };
503 };
512 };
515 /* For O_DIRECT dentry_open() checks f_mapping->a_ops->direct_IO */
517 };
519 /*
520 * It is possible to stack overlayfs instance on top of another
521 * overlayfs instance as lower layer. We need to annonate the
522 * stackable i_mutex locks according to stack level of the super
523 * block instance. An overlayfs instance can never be in stack
524 * depth 0 (there is always a real fs below it). An overlayfs
525 * inode lock will use the lockdep annotaion ovl_i_mutex_key[depth].
526 *
527 * For example, here is a snip from /proc/lockdep_chains after
528 * dir_iterate of nested overlayfs:
529 *
530 * [...] &ovl_i_mutex_dir_key[depth] (stack_depth=2)
531 * [...] &ovl_i_mutex_dir_key[depth]#2 (stack_depth=1)
532 * [...] &type->i_mutex_dir_key (stack_depth=0)
533 */
534 #define OVL_MAX_NESTING FILESYSTEM_MAX_STACK_DEPTH
537 {
538 #ifdef CONFIG_LOCKDEP
550 else
554 #endif
555 }
559 {
562 /*
563 * When d_ino is consistent with st_ino (samefs or i_ino has enough
564 * bits to encode layer), set the same value used for st_ino to i_ino,
565 * so inode number exposed via /proc/locks and a like will be
566 * consistent with d_ino and st_ino values. An i_ino value inconsistent
567 * with d_ino also causes nfsd readdirplus to fail. When called from
568 * ovl_new_inode(), ino arg is 0, so i_ino will be updated to real
569 * upper inode i_ino on ovl_inode_init() or ovl_inode_update().
570 */
577 }
580 #ifdef CONFIG_FS_POSIX_ACL
582 #endif
606 }
607 }
609 /*
610 * With inodes index enabled, an overlay inode nlink counts the union of upper
611 * hardlinks and non-covered lower hardlinks. During the lifetime of a non-pure
612 * upper inode, the following nlink modifying operations can happen:
613 *
614 * 1. Lower hardlink copy up
615 * 2. Upper hardlink created, unlinked or renamed over
616 * 3. Lower hardlink whiteout or renamed over
617 *
618 * For the first, copy up case, the union nlink does not change, whether the
619 * operation succeeds or fails, but the upper inode nlink may change.
620 * Therefore, before copy up, we store the union nlink value relative to the
621 * lower inode nlink in the index inode xattr trusted.overlay.nlink.
622 *
623 * For the second, upper hardlink case, the union nlink should be incremented
624 * or decremented IFF the operation succeeds, aligned with nlink change of the
625 * upper inode. Therefore, before link/unlink/rename, we store the union nlink
626 * value relative to the upper inode nlink in the index inode.
627 *
628 * For the last, lower cover up case, we simplify things by preceding the
629 * whiteout or cover up with copy up. This makes sure that there is an index
630 * upper inode where the nlink xattr can be stored before the copied up upper
631 * entry is unlink.
632 */
633 #define OVL_NLINK_ADD_UPPER (1 << 0)
635 /*
636 * On-disk format for indexed nlink:
637 *
638 * nlink relative to the upper inode - "U[+-]NUM"
639 * nlink relative to the lower inode - "L[+-]NUM"
640 */
644 {
658 }
661 {
663 }
666 {
668 }
673 {
703 fail:
707 }
710 {
718 }
721 {
723 }
726 {
729 }
733 {
734 /*
735 * For directories, @strict verify from lookup path performs consistency
736 * checks, so NULL lower/upper in dentry must match NULL lower/upper in
737 * inode. Non @strict verify from NFS handle decode path passes NULL for
738 * 'unknown' lower/upper.
739 */
741 /* Real lower dir moved to upper layer under us? */
745 /* Lookup of an uncovered redirect origin? */
748 }
750 /*
751 * Allow non-NULL lower inode in ovl_inode even if lowerdentry is NULL.
752 * This happens when finding a copied up overlay inode for a renamed
753 * or hardlinked overlay dentry and lower dentry cannot be followed
754 * by origin because lower fs does not support file handles.
755 */
759 /*
760 * Allow non-NULL __upperdentry in inode even if upperdentry is NULL.
761 * This happens when finding a lower alias for a copied up hard link.
762 */
767 }
771 {
782 }
785 }
788 {
802 }
804 /*
805 * Create an inode cache entry for layer root dir, that will intentionally
806 * fail ovl_verify_inode(), so any lookup that will find some layer root
807 * will fail.
808 */
810 {
823 /* Conflicting layer roots? */
826 }
833 }
835 /*
836 * Does overlay inode need to be hashed by lower inode?
837 */
840 {
843 /* No, if pure upper */
847 /* Yes, if already indexed */
851 /* Yes, if won't be copied up */
855 /* No, if lower hardlink is or will be broken on copy up */
860 /* No, if non-indexed upper with NFS export */
864 /* Otherwise, hash by lower inode for fsnotify */
866 }
870 {
875 }
879 {
895 /*
896 * Copy up origin (lower) may exist for non-indexed upper, but we must
897 * not use lower as hash key if this is a broken hardlink.
898 */
902 upperdentry);
909 /*
910 * Verify that the underlying files stored in the inode
911 * match those in the dentry.
912 */
918 }
923 }
925 /* Recalculate nlink for non-dir due to indexing */
931 /* Lower hardlink that will be broken on copy up */
936 }
939 }
956 }
963 /* Check for non-merge dir that may have whiteouts */
968 }
969 }
973 out:
976 out_err:
980 }