| blob | 3b46c5433b7acd853e5f9ca9381f6f6b30db6884 |
1 /* Generic associative array implementation.
2 *
3 * See Documentation/assoc_array.txt for information.
4 *
5 * Copyright (C) 2013 Red Hat, Inc. All Rights Reserved.
6 * Written by David Howells (dhowells@redhat.com)
7 *
8 * This program is free software; you can redistribute it and/or
9 * modify it under the terms of the GNU General Public Licence
10 * as published by the Free Software Foundation; either version
11 * 2 of the Licence, or (at your option) any later version.
12 */
13 //#define DEBUG
14 #include <linux/rcupdate.h>
15 #include <linux/slab.h>
16 #include <linux/err.h>
17 #include <linux/assoc_array_priv.h>
19 /*
20 * Iterate over an associative array. The caller must hold the RCU read lock
21 * or better.
22 */
28 {
37 begin_node:
39 /* Descend through a shortcut */
43 }
49 /* We perform two passes of each node.
50 *
51 * The first pass does all the leaves in this node. This means we
52 * don't miss any leaves if the node is split up by insertion whilst
53 * we're iterating over the branches rooted here (we may, however, see
54 * some leaves twice).
55 */
61 /* We need a barrier between the read of the pointer
62 * and dereferencing the pointer - but only if we are
63 * actually going to dereference it.
64 */
67 /* Invoke the callback */
69 iterator_data);
72 }
73 }
75 /* The second pass attends to all the metadata pointers. If we follow
76 * one of these we may find that we don't come back here, but rather go
77 * back to a replacement node with the leaves in a different layout.
78 *
79 * We are guaranteed to make progress, however, as the slot number for
80 * a particular portion of the key space cannot change - and we
81 * continue at the back pointer + 1.
82 */
87 continue_node:
96 }
97 }
99 finished_node:
100 /* Move up to the parent (may need to skip back over a shortcut) */
114 }
116 /* Ascend to next slot in parent node */
118 slot++;
120 }
122 /**
123 * assoc_array_iterate - Pass all objects in the array to a callback
124 * @array: The array to iterate over.
125 * @iterator: The callback function.
126 * @iterator_data: Private data for the callback function.
127 *
128 * Iterate over all the objects in an associative array. Each one will be
129 * presented to the iterator function.
130 *
131 * If the array is being modified concurrently with the iteration then it is
132 * possible that some objects in the array will be passed to the iterator
133 * callback more than once - though every object should be passed at least
134 * once. If this is undesirable then the caller must lock against modification
135 * for the duration of this function.
136 *
137 * The function will return 0 if no objects were in the array or else it will
138 * return the result of the last iterator function called. Iteration stops
139 * immediately if any call to the iteration function results in a non-zero
140 * return.
141 *
142 * The caller should hold the RCU read lock or better if concurrent
143 * modification is possible.
144 */
149 {
155 }
158 assoc_array_walk_tree_empty,
159 assoc_array_walk_found_terminal_node,
160 assoc_array_walk_found_wrong_shortcut,
161 };
176 };
178 /*
179 * Navigate through the internal tree looking for the closest node to the key.
180 */
181 static enum assoc_array_walk_status
186 {
203 /* Use segments from the key for the new leaf to navigate through the
204 * internal tree, skipping through nodes and shortcuts that are on
205 * route to the destination. Eventually we'll come to a slot that is
206 * either empty or contains a leaf at which point we've found a node in
207 * which the leaf we're looking for might be found or into which it
208 * should be inserted.
209 */
210 jumped:
217 consider_node:
229 /* The node doesn't have a node/shortcut pointer in the slot
230 * corresponding to the index key that we have to follow.
231 */
237 }
240 /* There is a pointer to a node in the slot corresponding to
241 * this index key segment, so we need to follow it.
242 */
248 }
250 /* There is a shortcut in the slot corresponding to the index key
251 * segment. We follow the shortcut if its partial index key matches
252 * this leaf's. Otherwise we need to split the shortcut.
253 */
255 follow_shortcut:
263 /* Check the leaf against the shortcut's index key a word at a
264 * time, trimming the final word (the shortcut stores the index
265 * key completely from the root to the shortcut's target).
266 */
274 /* Trim segments that are beyond the shortcut */
281 }
284 /* This shortcut points elsewhere */
291 }
296 /* The shortcut matches the leaf's index to this point. */
304 }
305 }
307 /**
308 * assoc_array_find - Find an object by index key
309 * @array: The associative array to search.
310 * @ops: The operations to use.
311 * @index_key: The key to the object.
312 *
313 * Find an object in an associative array by walking through the internal tree
314 * to the node that should contain the object and then searching the leaves
315 * there. NULL is returned if the requested object was not found in the array.
316 *
317 * The caller must hold the RCU read lock or better.
318 */
322 {
330 assoc_array_walk_found_terminal_node)
336 /* If the target key is available to us, it's has to be pointed to by
337 * the terminal node.
338 */
342 /* We need a barrier between the read of the pointer
343 * and dereferencing the pointer - but only if we are
344 * actually going to dereference it.
345 */
350 }
351 }
354 }
356 /*
357 * Destructively iterate over an associative array. The caller must prevent
358 * other simultaneous accesses.
359 */
362 {
374 }
376 move_to_meta:
378 /* Descend through a shortcut */
388 }
396 continue_node:
406 }
411 }
412 }
421 /* Move back up to the parent (may need to free a shortcut on
422 * the way up) */
435 }
437 /* Ascend to next slot in parent node */
441 slot++;
443 }
445 /**
446 * assoc_array_destroy - Destroy an associative array
447 * @array: The array to destroy.
448 * @ops: The operations to use.
449 *
450 * Discard all metadata and free all objects in an associative array. The
451 * array will be empty and ready to use again upon completion. This function
452 * cannot fail.
453 *
454 * The caller must prevent all other accesses whilst this takes place as no
455 * attempt is made to adjust pointers gracefully to permit RCU readlock-holding
456 * accesses to continue. On the other hand, no memory allocation is required.
457 */
460 {
463 }
465 /*
466 * Handle insertion into an empty tree.
467 */
469 {
486 }
488 /*
489 * Handle insertion into a terminal node.
490 */
495 {
511 /* We arrived at a node which doesn't have an onward node or shortcut
512 * pointer that we have to follow. This means that (a) the leaf we
513 * want must go here (either by insertion or replacement) or (b) we
514 * need to split this node and insert in one of the fragments.
515 */
518 /* Firstly, we have to check the leaves in this node to see if there's
519 * a matching one we should replace in place.
520 */
526 }
529 index_key)) {
535 }
536 }
538 /* If there is a free slot in this node then we can just insert the
539 * leaf here.
540 */
547 }
549 /* The node has no spare slots - so we're either going to have to split
550 * it or insert another node before it.
551 *
552 * Whatever, we're going to need at least two new nodes - so allocate
553 * those now. We may also need a new shortcut, but we deal with that
554 * when we need it.
555 */
565 /* We need to find out how similar the leaves are. */
574 }
579 }
584 }
586 /* The node contains only leaves */
595 /* The old leaves all cluster in the same slot. We will need
596 * to insert a shortcut if the new node wants to cluster with them.
597 */
601 /* Otherwise all the old leaves cluster in the same slot, but
602 * the new leaf wants to go into a different slot - so we
603 * create a new node (n0) to hold the new leaf and a pointer to
604 * a new node (n1) holding all the old leaves.
605 *
606 * This can be done by falling through to the node splitting
607 * path.
608 */
610 }
612 split_node:
615 /* We need to split the current node. The node must contain anything
616 * from a single leaf (in the one leaf case, this leaf will cluster
617 * with the new leaf) and the rest meta-pointers, to all leaves, some
618 * of which may cluster.
619 *
620 * It won't contain the case in which all the current leaves plus the
621 * new leaves want to cluster in the same slot.
622 *
623 * We need to expel at least two leaves out of a set consisting of the
624 * leaves in the node and the new leaf. The current meta pointers can
625 * just be copied as they shouldn't cluster with any of the leaves.
626 *
627 * We need a new node (n0) to replace the current one and a new node to
628 * take the expelled nodes (n1).
629 */
636 do_split_node:
642 /* Begin by finding two matching leaves. There have to be at least two
643 * that match - even if there are meta pointers - because any leaf that
644 * would match a slot with a meta pointer in it must be somewhere
645 * behind that meta pointer and cannot be here. Further, given N
646 * remaining leaf slots, we now have N+1 leaves to go in them.
647 */
654 }
655 found_slot_for_multiple_occupancy:
663 /* Metadata pointers cannot change slot */
667 else
672 /* Filter the leaf pointers between the new nodes */
683 free_slot++;
686 }
687 }
693 free_slot++;
700 }
715 }
716 }
717 }
724 else
730 all_leaves_cluster_together:
731 /* All the leaves, new and old, want to cluster together in this node
732 * in the same slot, so we have to replace this node with a shortcut to
733 * skip over the identical parts of the key and then place a pair of
734 * nodes, one inside the other, at the end of the shortcut and
735 * distribute the keys between them.
736 *
737 * Firstly we need to work out where the leaves start diverging as a
738 * bit position into their keys so that we know how big the shortcut
739 * needs to be.
740 *
741 * We only need to make a single pass of N of the N+1 leaves because if
742 * any keys differ between themselves at bit X then at least one of
743 * them must also differ with the base key at bit X or before.
744 */
749 index_key);
753 }
754 }
788 }
790 /* This now reduces to a node splitting exercise for which we'll need
791 * to regenerate the disparity table.
792 */
796 level);
799 }
805 }
807 /*
808 * Handle insertion into the middle of a shortcut.
809 */
813 {
830 /* We need to split a shortcut and insert a node between the two
831 * pieces. Zero-length pieces will be dispensed with entirely.
832 *
833 * First of all, we need to find out in which level the first
834 * difference was.
835 */
848 }
852 /* Create a new node now since we're going to need it anyway */
859 /* Insert a new shortcut before the new node if this segment isn't of
860 * zero length - otherwise we just connect the new node directly to the
861 * parent.
862 */
894 }
899 /* We need to know which slot in the new node is going to take a
900 * metadata pointer.
901 */
908 /* Determine whether we need to follow the new node with a replacement
909 * for the current shortcut. We could in theory reuse the current
910 * shortcut if its parent slot number doesn't change - but that's a
911 * 1-in-16 chance so not worth expending the code upon.
912 */
940 /* We don't have to replace the pointed-to node as long as we
941 * use memory barriers to make sure the parent slot number is
942 * changed before the back pointer (the parent slot number is
943 * irrelevant to the old parent shortcut).
944 */
950 }
952 /* Install the new leaf in a spare slot in the new node. */
955 else
960 }
962 /**
963 * assoc_array_insert - Script insertion of an object into an associative array
964 * @array: The array to insert into.
965 * @ops: The operations to use.
966 * @index_key: The key to insert at.
967 * @object: The object to insert.
968 *
969 * Precalculate and preallocate a script for the insertion or replacement of an
970 * object in an associative array. This results in an edit script that can
971 * either be applied or cancelled.
972 *
973 * The function returns a pointer to an edit script or -ENOMEM.
974 *
975 * The caller should lock against other modifications and must continue to hold
976 * the lock until assoc_array_apply_edit() has been called.
977 *
978 * Accesses to the tree may take place concurrently with this function,
979 * provided they hold the RCU read lock.
980 */
985 {
991 /* The leaf pointer we're given must not have the bottom bit set as we
992 * use those for type-marking the pointer. NULL pointers are also not
993 * allowed as they indicate an empty slot but we have to allow them
994 * here as they can be updated later.
995 */
1008 /* Allocate a root node if there isn't one yet */
1014 /* We found a node that doesn't have a node/shortcut pointer in
1015 * the slot corresponding to the index key that we have to
1016 * follow.
1017 */
1024 /* We found a shortcut that didn't match our key in a slot we
1025 * needed to follow.
1026 */
1030 }
1032 enomem:
1033 /* Clean up after an out of memory error */
1037 }
1039 /**
1040 * assoc_array_insert_set_object - Set the new object pointer in an edit script
1041 * @edit: The edit script to modify.
1042 * @object: The object pointer to set.
1043 *
1044 * Change the object to be inserted in an edit script. The object pointed to
1045 * by the old object is not freed. This must be done prior to applying the
1046 * script.
1047 */
1049 {
1052 }
1058 };
1060 /*
1061 * Subtree collapse to node iterator.
1062 */
1065 {
1075 }
1077 /**
1078 * assoc_array_delete - Script deletion of an object from an associative array
1079 * @array: The array to search.
1080 * @ops: The operations to use.
1081 * @index_key: The key to the object.
1082 *
1083 * Precalculate and preallocate a script for the deletion of an object from an
1084 * associative array. This results in an edit script that can either be
1085 * applied or cancelled.
1086 *
1087 * The function returns a pointer to an edit script if the object was found,
1088 * NULL if the object was not found or -ENOMEM.
1089 *
1090 * The caller should lock against other modifications and must continue to hold
1091 * the lock until assoc_array_apply_edit() has been called.
1092 *
1093 * Accesses to the tree may take place concurrently with this function,
1094 * provided they hold the RCU read lock.
1095 */
1099 {
1119 /* We found a node that should contain the leaf we've been
1120 * asked to remove - *if* it's in the tree.
1121 */
1130 index_key))
1132 }
1139 }
1141 found_leaf:
1144 /* In the simplest form of deletion we just clear the slot and release
1145 * the leaf after a suitable interval.
1146 */
1152 /* If that concludes erasure of the last leaf, then delete the entire
1153 * internal array.
1154 */
1162 }
1164 /* However, we'd also like to clear up some metadata blocks if we
1165 * possibly can.
1166 *
1167 * We go for a simple algorithm of: if this node has FAN_OUT or fewer
1168 * leaves in it, then attempt to collapse it - and attempt to
1169 * recursively collapse up the tree.
1170 *
1171 * We could also try and collapse in partially filled subtrees to take
1172 * up space in this node.
1173 */
1178 /* First of all, we need to know if this node has metadata so
1179 * that we don't try collapsing if all the leaves are already
1180 * here.
1181 */
1188 }
1189 }
1194 /* Look further up the tree to see if we can collapse this node
1195 * into a more proximal node too.
1196 */
1198 collapse_up:
1209 }
1215 }
1217 do_collapse:
1218 /* There's no point collapsing if the original node has no meta
1219 * pointers to discard and if we didn't merge into one of that
1220 * node's ancestry.
1221 */
1225 /* Create a new node to collapse into */
1241 assoc_array_delete_collapse_iterator,
1258 }
1261 }
1262 }
1266 enomem:
1267 /* Clean up after an out of memory error */
1271 }
1273 /**
1274 * assoc_array_clear - Script deletion of all objects from an associative array
1275 * @array: The array to clear.
1276 * @ops: The operations to use.
1277 *
1278 * Precalculate and preallocate a script for the deletion of all the objects
1279 * from an associative array. This results in an edit script that can either
1280 * be applied or cancelled.
1281 *
1282 * The function returns a pointer to an edit script if there are objects to be
1283 * deleted, NULL if there are no objects in the array or -ENOMEM.
1284 *
1285 * The caller should lock against other modifications and must continue to hold
1286 * the lock until assoc_array_apply_edit() has been called.
1287 *
1288 * Accesses to the tree may take place concurrently with this function,
1289 * provided they hold the RCU read lock.
1290 */
1293 {
1312 }
1314 /*
1315 * Handle the deferred destruction after an applied edit.
1316 */
1318 {
1341 }
1344 }
1347 }
1349 /**
1350 * assoc_array_apply_edit - Apply an edit script to an associative array
1351 * @edit: The script to apply.
1352 *
1353 * Apply an edit script to an associative array to effect an insertion,
1354 * deletion or clearance. As the edit script includes preallocated memory,
1355 * this is guaranteed not to fail.
1356 *
1357 * The edit script, dead objects and dead metadata will be scheduled for
1358 * destruction after an RCU grace period to permit those doing read-only
1359 * accesses on the array to continue to do so under the RCU read lock whilst
1360 * the edit is taking place.
1361 */
1363 {
1405 }
1408 }
1411 }
1414 }
1416 /**
1417 * assoc_array_cancel_edit - Discard an edit script.
1418 * @edit: The script to discard.
1419 *
1420 * Free an edit script and all the preallocated data it holds without making
1421 * any changes to the associative array it was intended for.
1422 *
1423 * NOTE! In the case of an insertion script, this does _not_ release the leaf
1424 * that was to be inserted. That is left to the caller.
1425 */
1427 {
1433 /* Clean up after an out of memory error */
1439 else
1441 }
1442 }
1444 }
1446 /**
1447 * assoc_array_gc - Garbage collect an associative array.
1448 * @array: The array to clean.
1449 * @ops: The operations to use.
1450 * @iterator: A callback function to pass judgement on each object.
1451 * @iterator_data: Private data for the callback function.
1452 *
1453 * Collect garbage from an associative array and pack down the internal tree to
1454 * save memory.
1455 *
1456 * The iterator function is asked to pass judgement upon each object in the
1457 * array. If it returns false, the object is discard and if it returns true,
1458 * the object is kept. If it returns true, it must increment the object's
1459 * usage count (or whatever it needs to do to retain it) before returning.
1460 *
1461 * This function returns 0 if successful or -ENOMEM if out of memory. In the
1462 * latter case, the array is not changed.
1463 *
1464 * The caller should lock against other modifications and must continue to hold
1465 * the lock until assoc_array_apply_edit() has been called.
1466 *
1467 * Accesses to the tree may take place concurrently with this function,
1468 * provided they hold the RCU read lock.
1469 */
1474 {
1501 descend:
1502 /* If this point is a shortcut, then we need to duplicate it and
1503 * advance the target cursor.
1504 */
1521 }
1523 /* Duplicate the node at this position */
1535 continue_node:
1536 /* Filter across any leaves and gc any subtrees */
1544 iterator_data))
1545 /* The iterator will have done any reference
1546 * counting on the object for us.
1547 */
1550 }
1555 }
1559 /* Count up the number of empty slots in this node and work out the
1560 * subtree leaf count.
1561 */
1567 nr_free++;
1570 }
1573 /* See what we can fold in */
1587 }
1593 /* Fold the child node into this one */
1596 next_slot);
1598 /* We would already have reaped an intervening shortcut
1599 * on the way back up the tree.
1600 */
1604 nr_free++;
1613 next_slot++;
1616 nr_free--;
1617 }
1622 next_slot);
1623 }
1624 }
1630 /* Excise this node if it is singly occupied by a shortcut */
1648 }
1651 /* We can discard any preceding shortcut also */
1665 }
1666 }
1673 }
1674 }
1676 /* Excise any shortcuts we might encounter that point to nodes that
1677 * only contain leaves.
1678 */
1698 }
1702 }
1705 }
1708 ascend_old_tree:
1719 }
1722 slot++;
1725 gc_complete:
1731 enomem:
1736 }