| blob | 89d1dc19340b09d4d9cd9db44ae3dfc9413bea98 |
1 /*
2 * fs/kernfs/dir.c - kernfs directory implementation
3 *
4 * Copyright (c) 2001-3 Patrick Mochel
5 * Copyright (c) 2007 SUSE Linux Products GmbH
6 * Copyright (c) 2007, 2013 Tejun Heo <tj@kernel.org>
7 *
8 * This file is released under the GPLv2.
9 */
11 #include <linux/sched.h>
12 #include <linux/fs.h>
13 #include <linux/namei.h>
14 #include <linux/idr.h>
15 #include <linux/slab.h>
16 #include <linux/security.h>
17 #include <linux/hash.h>
26 #define rb_to_kn(X) rb_entry((X), struct kernfs_node, rb)
29 {
32 }
35 {
36 #ifdef CONFIG_DEBUG_LOCK_ALLOC
38 #else
40 #endif
41 }
44 {
49 }
51 /* kernfs_node_depth - compute depth from @from to @to */
53 {
57 depth++;
59 }
61 }
65 {
77 da--;
78 }
81 db--;
82 }
84 /* worst case b and a will be the same at root */
88 }
91 }
93 /**
94 * kernfs_path_from_node_locked - find a pseudo-absolute path to @kn_to,
95 * where kn_from is treated as root of the path.
96 * @kn_from: kernfs node which should be treated as root for the path
97 * @kn_to: kernfs node to which path is needed
98 * @buf: buffer to copy the path into
99 * @buflen: size of @buf
100 *
101 * We need to handle couple of scenarios here:
102 * [1] when @kn_from is an ancestor of @kn_to at some level
103 * kn_from: /n1/n2/n3
104 * kn_to: /n1/n2/n3/n4/n5
105 * result: /n4/n5
106 *
107 * [2] when @kn_from is on a different hierarchy and we need to find common
108 * ancestor between @kn_from and @kn_to.
109 * kn_from: /n1/n2/n3/n4
110 * kn_to: /n1/n2/n5
111 * result: /../../n5
112 * OR
113 * kn_from: /n1/n2/n3/n4/n5 [depth=5]
114 * kn_to: /n1/n2/n3 [depth=3]
115 * result: /../..
116 *
117 * [3] when @kn_to is NULL result will be "(null)"
118 *
119 * Returns the length of the full path. If the full length is equal to or
120 * greater than @buflen, @buf contains the truncated path with the trailing
121 * '\0'. On error, -errno is returned.
122 */
126 {
155 /* Calculate how many bytes we need for the rest */
163 }
166 }
168 /**
169 * kernfs_name - obtain the name of a given node
170 * @kn: kernfs_node of interest
171 * @buf: buffer to copy @kn's name into
172 * @buflen: size of @buf
173 *
174 * Copies the name of @kn into @buf of @buflen bytes. The behavior is
175 * similar to strlcpy(). It returns the length of @kn's name and if @buf
176 * isn't long enough, it's filled upto @buflen-1 and nul terminated.
177 *
178 * Fills buffer with "(null)" if @kn is NULL.
179 *
180 * This function can be called from any context.
181 */
183 {
191 }
193 /**
194 * kernfs_path_from_node - build path of node @to relative to @from.
195 * @from: parent kernfs_node relative to which we need to build the path
196 * @to: kernfs_node of interest
197 * @buf: buffer to copy @to's path into
198 * @buflen: size of @buf
199 *
200 * Builds @to's path relative to @from in @buf. @from and @to must
201 * be on the same kernfs-root. If @from is not parent of @to, then a relative
202 * path (which includes '..'s) as needed to reach from @from to @to is
203 * returned.
204 *
205 * Returns the length of the full path. If the full length is equal to or
206 * greater than @buflen, @buf contains the truncated path with the trailing
207 * '\0'. On error, -errno is returned.
208 */
211 {
219 }
222 /**
223 * pr_cont_kernfs_name - pr_cont name of a kernfs_node
224 * @kn: kernfs_node of interest
225 *
226 * This function can be called from any context.
227 */
229 {
238 }
240 /**
241 * pr_cont_kernfs_path - pr_cont path of a kernfs_node
242 * @kn: kernfs_node of interest
243 *
244 * This function can be called from any context.
245 */
247 {
258 }
263 }
267 out:
269 }
271 /**
272 * kernfs_get_parent - determine the parent node and pin it
273 * @kn: kernfs_node of interest
274 *
275 * Determines @kn's parent, pins and returns it. This function can be
276 * called from any context.
277 */
279 {
289 }
291 /**
292 * kernfs_name_hash
293 * @name: Null terminated string to hash
294 * @ns: Namespace tag to hash
295 *
296 * Returns 31 bit hash of ns + name (so it fits in an off_t )
297 */
299 {
306 /* Reserve hash numbers 0, 1 and INT_MAX for magic directory entries */
312 }
316 {
326 }
330 {
332 }
334 /**
335 * kernfs_link_sibling - link kernfs_node into sibling rbtree
336 * @kn: kernfs_node of interest
337 *
338 * Link @kn into its sibling rbtree which starts from
339 * @kn->parent->dir.children.
340 *
341 * Locking:
342 * mutex_lock(kernfs_mutex)
343 *
344 * RETURNS:
345 * 0 on susccess -EEXIST on failure.
346 */
348 {
363 else
365 }
367 /* add new node and rebalance the tree */
371 /* successfully added, account subdir number */
376 }
378 /**
379 * kernfs_unlink_sibling - unlink kernfs_node from sibling rbtree
380 * @kn: kernfs_node of interest
381 *
382 * Try to unlink @kn from its sibling rbtree which starts from
383 * kn->parent->dir.children. Returns %true if @kn was actually
384 * removed, %false if @kn wasn't on the rbtree.
385 *
386 * Locking:
387 * mutex_lock(kernfs_mutex)
388 */
390 {
400 }
402 /**
403 * kernfs_get_active - get an active reference to kernfs_node
404 * @kn: kernfs_node to get an active reference to
405 *
406 * Get an active reference of @kn. This function is noop if @kn
407 * is NULL.
408 *
409 * RETURNS:
410 * Pointer to @kn on success, NULL on failure.
411 */
413 {
423 }
425 /**
426 * kernfs_put_active - put an active reference to kernfs_node
427 * @kn: kernfs_node to put an active reference to
428 *
429 * Put an active reference to @kn. This function is noop if @kn
430 * is NULL.
431 */
433 {
447 }
449 /**
450 * kernfs_drain - drain kernfs_node
451 * @kn: kernfs_node to drain
452 *
453 * Drain existing usages and nuke all existing mmaps of @kn. Mutiple
454 * removers may invoke this function concurrently on @kn and all will
455 * return after draining is complete.
456 */
459 {
471 }
473 /* but everyone should wait for draining */
480 }
485 }
487 /**
488 * kernfs_get - get a reference count on a kernfs_node
489 * @kn: the target kernfs_node
490 */
492 {
496 }
497 }
500 /**
501 * kernfs_put - put a reference count on a kernfs_node
502 * @kn: the target kernfs_node
503 *
504 * Put a reference count of @kn and destroy it if it reached zero.
505 */
507 {
511 /*
512 * kernfs_node is freed with ->count 0, kernfs_find_and_get_node_by_ino
513 * depends on this to filter reused stale node
514 */
518 repeat:
519 /*
520 * Moving/renaming is always done while holding reference.
521 * kn->parent won't change beneath us.
522 */
539 }
551 /* just released the root kn, free @root too */
554 }
555 }
559 {
565 /* Always perform fresh lookup for negatives */
572 /* The kernfs node has been deactivated */
576 /* The kernfs node has been moved? */
580 /* The kernfs node has been renamed */
584 /* The kernfs node has been moved to a different namespace */
591 out_bad:
593 out_bad_unlocked:
595 }
599 };
601 /**
602 * kernfs_node_from_dentry - determine kernfs_node associated with a dentry
603 * @dentry: the dentry in question
604 *
605 * Return the kernfs_node associated with @dentry. If @dentry is not a
606 * kernfs one, %NULL is returned.
607 *
608 * While the returned kernfs_node will stay accessible as long as @dentry
609 * is accessible, the returned node can be in any state and the caller is
610 * fully responsible for determining what's accessible.
611 */
613 {
618 }
623 {
625 u32 gen;
651 /*
652 * set ino first. This barrier is paired with atomic_inc_not_zero in
653 * kernfs_find_and_get_node_by_ino
654 */
666 err_out2:
668 err_out1:
671 }
676 {
683 }
685 }
687 /*
688 * kernfs_find_and_get_node_by_ino - get kernfs_node from inode number
689 * @root: the kernfs root
690 * @ino: inode number
691 *
692 * RETURNS:
693 * NULL on failure. Return a kernfs node with reference counter incremented
694 */
697 {
705 /*
706 * Since kernfs_node is freed in RCU, it's possible an old node for ino
707 * is freed, but reused before RCU grace period. But a freed node (see
708 * kernfs_put) or an incompletedly initialized node (see
709 * __kernfs_new_node) should have 'count' 0. We can use this fact to
710 * filter out such node.
711 */
715 }
717 /*
718 * The node could be a new node or a reused node. If it's a new node,
719 * we are ok. If it's reused because of RCU (because of
720 * SLAB_TYPESAFE_BY_RCU), the __kernfs_new_node always sets its 'ino'
721 * before 'count'. So if 'count' is uptodate, 'ino' should be uptodate,
722 * hence we can use 'ino' to filter stale node.
723 */
729 out:
733 }
735 /**
736 * kernfs_add_one - add kernfs_node to parent without warning
737 * @kn: kernfs_node to be added
738 *
739 * The caller must already have initialized @kn->parent. This
740 * function increments nlink of the parent's inode if @kn is a
741 * directory and link into the children list of the parent.
742 *
743 * RETURNS:
744 * 0 on success, -EEXIST if entry with the given name already
745 * exists.
746 */
748 {
778 /* Update timestamps on the parent */
784 }
788 /*
789 * Activate the new node unless CREATE_DEACTIVATED is requested.
790 * If not activated here, the kernfs user is responsible for
791 * activating the node with kernfs_activate(). A node which hasn't
792 * been activated is not visible to userland and its removal won't
793 * trigger deactivation.
794 */
799 out_unlock:
802 }
804 /**
805 * kernfs_find_ns - find kernfs_node with the given name
806 * @parent: kernfs_node to search under
807 * @name: name to look for
808 * @ns: the namespace tag to use
809 *
810 * Look for kernfs_node with name @name under @parent. Returns pointer to
811 * the found kernfs_node on success, %NULL on failure.
812 */
816 {
827 }
840 else
842 }
844 }
849 {
855 /* grab kernfs_rename_lock to piggy back on kernfs_pr_cont_buf */
863 }
871 }
876 }
878 /**
879 * kernfs_find_and_get_ns - find and get kernfs_node with the given name
880 * @parent: kernfs_node to search under
881 * @name: name to look for
882 * @ns: the namespace tag to use
883 *
884 * Look for kernfs_node with name @name under @parent and get a reference
885 * if found. This function may sleep and returns pointer to the found
886 * kernfs_node on success, %NULL on failure.
887 */
890 {
899 }
902 /**
903 * kernfs_walk_and_get_ns - find and get kernfs_node with the given path
904 * @parent: kernfs_node to search under
905 * @path: path to look for
906 * @ns: the namespace tag to use
907 *
908 * Look for kernfs_node with path @path under @parent and get a reference
909 * if found. This function may sleep and returns pointer to the found
910 * kernfs_node on success, %NULL on failure.
911 */
914 {
923 }
925 /**
926 * kernfs_create_root - create a new kernfs hierarchy
927 * @scops: optional syscall operations for the hierarchy
928 * @flags: KERNFS_ROOT_* flags
929 * @priv: opaque data associated with the new directory
930 *
931 * Returns the root of the new hierarchy on success, ERR_PTR() value on
932 * failure.
933 */
936 {
949 KERNFS_DIR);
954 }
968 }
970 /**
971 * kernfs_destroy_root - destroy a kernfs hierarchy
972 * @root: root of the hierarchy to destroy
973 *
974 * Destroy the hierarchy anchored at @root by removing all existing
975 * directories and destroying @root.
976 */
978 {
980 }
982 /**
983 * kernfs_create_dir_ns - create a directory
984 * @parent: parent in which to create a new directory
985 * @name: name of the new directory
986 * @mode: mode of the new directory
987 * @priv: opaque data associated with the new directory
988 * @ns: optional namespace tag of the directory
989 *
990 * Returns the created node on success, ERR_PTR() value on failure.
991 */
995 {
999 /* allocate */
1008 /* link in */
1015 }
1017 /**
1018 * kernfs_create_empty_dir - create an always empty directory
1019 * @parent: parent in which to create a new directory
1020 * @name: name of the new directory
1021 *
1022 * Returns the created node on success, ERR_PTR() value on failure.
1023 */
1026 {
1030 /* allocate */
1040 /* link in */
1047 }
1052 {
1066 /* no such entry */
1070 }
1072 /* attach dentry and inode */
1077 }
1079 /* instantiate and hash dentry */
1081 out_unlock:
1084 }
1087 umode_t mode)
1088 {
1103 }
1106 {
1121 }
1126 {
1144 }
1151 }
1163 };
1166 {
1182 }
1185 }
1187 /**
1188 * kernfs_next_descendant_post - find the next descendant for post-order walk
1189 * @pos: the current position (%NULL to initiate traversal)
1190 * @root: kernfs_node whose descendants to walk
1191 *
1192 * Find the next descendant to visit for post-order traversal of @root's
1193 * descendants. @root is included in the iteration and the last node to be
1194 * visited.
1195 */
1198 {
1203 /* if first iteration, visit leftmost descendant which may be root */
1207 /* if we visited @root, we're done */
1211 /* if there's an unvisited sibling, visit its leftmost descendant */
1216 /* no sibling left, visit parent */
1218 }
1220 /**
1221 * kernfs_activate - activate a node which started deactivated
1222 * @kn: kernfs_node whose subtree is to be activated
1223 *
1224 * If the root has KERNFS_ROOT_CREATE_DEACTIVATED set, a newly created node
1225 * needs to be explicitly activated. A node which hasn't been activated
1226 * isn't visible to userland and deactivation is skipped during its
1227 * removal. This is useful to construct atomic init sequences where
1228 * creation of multiple nodes should either succeed or fail atomically.
1229 *
1230 * The caller is responsible for ensuring that this function is not called
1231 * after kernfs_remove*() is invoked on @kn.
1232 */
1234 {
1249 }
1252 }
1255 {
1260 /*
1261 * Short-circuit if non-root @kn has already finished removal.
1262 * This is for kernfs_remove_self() which plays with active ref
1263 * after removal.
1264 */
1270 /* prevent any new usage under @kn by deactivating all nodes */
1276 /* deactivate and unlink the subtree node-by-node */
1280 /*
1281 * kernfs_drain() drops kernfs_mutex temporarily and @pos's
1282 * base ref could have been put by someone else by the time
1283 * the function returns. Make sure it doesn't go away
1284 * underneath us.
1285 */
1288 /*
1289 * Drain iff @kn was activated. This avoids draining and
1290 * its lockdep annotations for nodes which have never been
1291 * activated and allows embedding kernfs_remove() in create
1292 * error paths without worrying about draining.
1293 */
1296 else
1299 /*
1300 * kernfs_unlink_sibling() succeeds once per node. Use it
1301 * to decide who's responsible for cleanups.
1302 */
1307 /* update timestamps on the parent */
1312 }
1315 }
1319 }
1321 /**
1322 * kernfs_remove - remove a kernfs_node recursively
1323 * @kn: the kernfs_node to remove
1324 *
1325 * Remove @kn along with all its subdirectories and files.
1326 */
1328 {
1332 }
1334 /**
1335 * kernfs_break_active_protection - break out of active protection
1336 * @kn: the self kernfs_node
1337 *
1338 * The caller must be running off of a kernfs operation which is invoked
1339 * with an active reference - e.g. one of kernfs_ops. Each invocation of
1340 * this function must also be matched with an invocation of
1341 * kernfs_unbreak_active_protection().
1342 *
1343 * This function releases the active reference of @kn the caller is
1344 * holding. Once this function is called, @kn may be removed at any point
1345 * and the caller is solely responsible for ensuring that the objects it
1346 * dereferences are accessible.
1347 */
1349 {
1350 /*
1351 * Take out ourself out of the active ref dependency chain. If
1352 * we're called without an active ref, lockdep will complain.
1353 */
1355 }
1357 /**
1358 * kernfs_unbreak_active_protection - undo kernfs_break_active_protection()
1359 * @kn: the self kernfs_node
1360 *
1361 * If kernfs_break_active_protection() was called, this function must be
1362 * invoked before finishing the kernfs operation. Note that while this
1363 * function restores the active reference, it doesn't and can't actually
1364 * restore the active protection - @kn may already or be in the process of
1365 * being removed. Once kernfs_break_active_protection() is invoked, that
1366 * protection is irreversibly gone for the kernfs operation instance.
1367 *
1368 * While this function may be called at any point after
1369 * kernfs_break_active_protection() is invoked, its most useful location
1370 * would be right before the enclosing kernfs operation returns.
1371 */
1373 {
1374 /*
1375 * @kn->active could be in any state; however, the increment we do
1376 * here will be undone as soon as the enclosing kernfs operation
1377 * finishes and this temporary bump can't break anything. If @kn
1378 * is alive, nothing changes. If @kn is being deactivated, the
1379 * soon-to-follow put will either finish deactivation or restore
1380 * deactivated state. If @kn is already removed, the temporary
1381 * bump is guaranteed to be gone before @kn is released.
1382 */
1386 }
1388 /**
1389 * kernfs_remove_self - remove a kernfs_node from its own method
1390 * @kn: the self kernfs_node to remove
1391 *
1392 * The caller must be running off of a kernfs operation which is invoked
1393 * with an active reference - e.g. one of kernfs_ops. This can be used to
1394 * implement a file operation which deletes itself.
1395 *
1396 * For example, the "delete" file for a sysfs device directory can be
1397 * implemented by invoking kernfs_remove_self() on the "delete" file
1398 * itself. This function breaks the circular dependency of trying to
1399 * deactivate self while holding an active ref itself. It isn't necessary
1400 * to modify the usual removal path to use kernfs_remove_self(). The
1401 * "delete" implementation can simply invoke kernfs_remove_self() on self
1402 * before proceeding with the usual removal path. kernfs will ignore later
1403 * kernfs_remove() on self.
1404 *
1405 * kernfs_remove_self() can be called multiple times concurrently on the
1406 * same kernfs_node. Only the first one actually performs removal and
1407 * returns %true. All others will wait until the kernfs operation which
1408 * won self-removal finishes and return %false. Note that the losers wait
1409 * for the completion of not only the winning kernfs_remove_self() but also
1410 * the whole kernfs_ops which won the arbitration. This can be used to
1411 * guarantee, for example, all concurrent writes to a "delete" file to
1412 * finish only after the whole operation is complete.
1413 */
1415 {
1421 /*
1422 * SUICIDAL is used to arbitrate among competing invocations. Only
1423 * the first one will actually perform removal. When the removal
1424 * is complete, SUICIDED is set and the active ref is restored
1425 * while holding kernfs_mutex. The ones which lost arbitration
1426 * waits for SUICDED && drained which can happen only after the
1427 * enclosing kernfs operation which executed the winning instance
1428 * of kernfs_remove_self() finished.
1429 */
1449 }
1453 }
1455 /*
1456 * This must be done while holding kernfs_mutex; otherwise, waiting
1457 * for SUICIDED && deactivated could finish prematurely.
1458 */
1463 }
1465 /**
1466 * kernfs_remove_by_name_ns - find a kernfs_node by name and remove it
1467 * @parent: parent of the target
1468 * @name: name of the kernfs_node to remove
1469 * @ns: namespace tag of the kernfs_node to remove
1470 *
1471 * Look for the kernfs_node with @name and @ns under @parent and remove it.
1472 * Returns 0 on success, -ENOENT if such entry doesn't exist.
1473 */
1476 {
1481 name);
1483 }
1495 else
1497 }
1499 /**
1500 * kernfs_rename_ns - move and rename a kernfs_node
1501 * @kn: target node
1502 * @new_parent: new parent to put @sd under
1503 * @new_name: new name
1504 * @new_ns: new namespace tag
1505 */
1508 {
1513 /* can't move or rename root */
1533 /* rename kernfs_node */
1541 }
1543 /*
1544 * Move to the appropriate place in the appropriate directories rbtree.
1545 */
1549 /* rename_lock protects ->parent and ->name accessors */
1559 }
1570 out:
1573 }
1575 /* Relationship between s_mode and the DT_xxx types */
1577 {
1579 }
1582 {
1585 }
1589 {
1596 }
1606 else
1608 }
1609 }
1610 /* Skip over entries which are dying/dead or in the wrong namespace */
1615 else
1617 }
1619 }
1623 {
1630 else
1633 }
1635 }
1638 {
1652 pos;
1667 }
1672 }
1679 };