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1 /*
2 * Copyright (c) 2007-2008 The DragonFly Project. All rights reserved.
3 *
4 * This code is derived from software contributed to The DragonFly Project
5 * by Matthew Dillon <dillon@backplane.com>
6 *
7 * Redistribution and use in source and binary forms, with or without
8 * modification, are permitted provided that the following conditions
9 * are met:
10 *
11 * 1. Redistributions of source code must retain the above copyright
12 * notice, this list of conditions and the following disclaimer.
13 * 2. Redistributions in binary form must reproduce the above copyright
14 * notice, this list of conditions and the following disclaimer in
15 * the documentation and/or other materials provided with the
16 * distribution.
17 * 3. Neither the name of The DragonFly Project nor the names of its
18 * contributors may be used to endorse or promote products derived
19 * from this software without specific, prior written permission.
20 *
21 * THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS
22 * ``AS IS'' AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT
23 * LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS
24 * FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE
25 * COPYRIGHT HOLDERS OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT,
26 * INCIDENTAL, SPECIAL, EXEMPLARY OR CONSEQUENTIAL DAMAGES (INCLUDING,
27 * BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES;
28 * LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED
29 * AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY,
30 * OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT
31 * OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF
32 * SUCH DAMAGE.
33 *
34 * $DragonFly: src/sys/vfs/hammer/hammer_btree.c,v 1.76 2008/08/06 15:38:58 dillon Exp $
35 */
37 /*
38 * HAMMER B-Tree index
39 *
40 * HAMMER implements a modified B+Tree. In documentation this will
41 * simply be refered to as the HAMMER B-Tree. Basically a HAMMER B-Tree
42 * looks like a B+Tree (A B-Tree which stores its records only at the leafs
43 * of the tree), but adds two additional boundary elements which describe
44 * the left-most and right-most element a node is able to represent. In
45 * otherwords, we have boundary elements at the two ends of a B-Tree node
46 * instead of sub-tree pointers.
47 *
48 * A B-Tree internal node looks like this:
49 *
50 * B N N N N N N B <-- boundary and internal elements
51 * S S S S S S S <-- subtree pointers
52 *
53 * A B-Tree leaf node basically looks like this:
54 *
55 * L L L L L L L L <-- leaf elemenets
56 *
57 * The radix for an internal node is 1 less then a leaf but we get a
58 * number of significant benefits for our troubles.
59 *
60 * The big benefit to using a B-Tree containing boundary information
61 * is that it is possible to cache pointers into the middle of the tree
62 * and not have to start searches, insertions, OR deletions at the root
63 * node. In particular, searches are able to progress in a definitive
64 * direction from any point in the tree without revisting nodes. This
65 * greatly improves the efficiency of many operations, most especially
66 * record appends.
67 *
68 * B-Trees also make the stacking of trees fairly straightforward.
69 *
70 * INSERTIONS: A search performed with the intention of doing
71 * an insert will guarantee that the terminal leaf node is not full by
72 * splitting full nodes. Splits occur top-down during the dive down the
73 * B-Tree.
74 *
75 * DELETIONS: A deletion makes no attempt to proactively balance the
76 * tree and will recursively remove nodes that become empty. If a
77 * deadlock occurs a deletion may not be able to remove an empty leaf.
78 * Deletions never allow internal nodes to become empty (that would blow
79 * up the boundaries).
80 */
82 #include <sys/buf.h>
83 #include <sys/buf2.h>
91 hammer_tid_t mirror_tid);
96 /*
97 * Iterate records after a search. The cursor is iterated forwards past
98 * the current record until a record matching the key-range requirements
99 * is found. ENOENT is returned if the iteration goes past the ending
100 * key.
101 *
102 * The iteration is inclusive of key_beg and can be inclusive or exclusive
103 * of key_end depending on whether HAMMER_CURSOR_END_INCLUSIVE is set.
104 *
105 * When doing an as-of search (cursor->asof != 0), key_beg.create_tid
106 * may be modified by B-Tree functions.
107 *
108 * cursor->key_beg may or may not be modified by this function during
109 * the iteration. XXX future - in case of an inverted lock we may have
110 * to reinitiate the lookup and set key_beg to properly pick up where we
111 * left off.
112 *
113 * NOTE! EDEADLK *CANNOT* be returned by this procedure.
114 */
115 int
117 {
118 hammer_node_ondisk_t node;
119 hammer_btree_elm_t elm;
124 /*
125 * Skip past the current record
126 */
133 }
135 /*
136 * Loop until an element is found or we are done.
137 */
139 /*
140 * We iterate up the tree and then index over one element
141 * while we are at the last element in the current node.
142 *
143 * If we are at the root of the filesystem, cursor_up
144 * returns ENOENT.
145 *
146 * XXX this could be optimized by storing the information in
147 * the parent reference.
148 *
149 * XXX we can lose the node lock temporarily, this could mess
150 * up our scan.
151 */
162 curthread);
163 }
164 KKASSERT(cursor->parent == NULL || cursor->parent->ondisk->elms[cursor->parent_index].internal.subtree_offset == cursor->node->node_offset);
168 /* reload stale pointer */
172 /*
173 * If we are reblocking we want to return internal
174 * nodes.
175 */
179 }
182 }
184 /*
185 * Check internal or leaf element. Determine if the record
186 * at the cursor has gone beyond the end of our range.
187 *
188 * We recurse down through internal nodes.
189 */
203 r,
204 curthread
205 );
213 s
214 );
215 }
220 }
225 }
228 /*
229 * Better not be zero
230 */
233 /*
234 * If running the mirror filter see if we can skip
235 * one or more entire sub-trees. If we can we
236 * return the internal mode and the caller processes
237 * the skipped range (see mirror_read)
238 */
244 }
245 }
251 /* reload stale pointer */
267 r
268 );
269 }
273 }
275 /*
276 * We support both end-inclusive and
277 * end-exclusive searches.
278 */
283 }
291 }
297 }
300 }
301 /*
302 * node pointer invalid after loop
303 */
305 /*
306 * Return entry
307 */
317 );
318 }
320 }
322 }
324 /*
325 * We hit an internal element that we could skip as part of a mirroring
326 * scan. Calculate the entire range being skipped.
327 *
328 * It is important to include any gaps between the parent's left_bound
329 * and the node's left_bound, and same goes for the right side.
330 */
331 static void
333 {
335 hammer_node_ondisk_t ondisk;
336 hammer_btree_elm_t elm;
341 /*
342 * Calculate the skipped range
343 */
347 else
354 }
357 else
360 /*
361 * clip the returned result.
362 */
367 }
369 /*
370 * Iterate in the reverse direction. This is used by the pruning code to
371 * avoid overlapping records.
372 */
373 int
375 {
376 hammer_node_ondisk_t node;
377 hammer_btree_elm_t elm;
382 /* mirror filtering not supported for reverse iteration */
385 /*
386 * Skip past the current record. For various reasons the cursor
387 * may end up set to -1 or set to point at the end of the current
388 * node. These cases must be addressed.
389 */
396 }
400 /*
401 * Loop until an element is found or we are done.
402 */
407 /*
408 * We iterate up the tree and then index over one element
409 * while we are at the last element in the current node.
410 */
416 }
417 /* reload stale pointer */
422 }
424 /*
425 * Check internal or leaf element. Determine if the record
426 * at the cursor has gone beyond the end of our range.
427 *
428 * We recurse down through internal nodes.
429 */
443 r
444 );
452 s
453 );
454 }
459 }
462 /*
463 * Better not be zero
464 */
471 /* reload stale pointer */
474 /* this can assign -1 if the leaf was empty */
490 s
491 );
492 }
496 }
504 }
510 }
513 }
514 /*
515 * node pointer invalid after loop
516 */
518 /*
519 * Return entry
520 */
530 );
531 }
533 }
535 }
537 /*
538 * Lookup cursor->key_beg. 0 is returned on success, ENOENT if the entry
539 * could not be found, EDEADLK if inserting and a retry is needed, and a
540 * fatal error otherwise. When retrying, the caller must terminate the
541 * cursor and reinitialize it. EDEADLK cannot be returned if not inserting.
542 *
543 * The cursor is suitably positioned for a deletion on success, and suitably
544 * positioned for an insertion on ENOENT if HAMMER_CURSOR_INSERT was
545 * specified.
546 *
547 * The cursor may begin anywhere, the search will traverse the tree in
548 * either direction to locate the requested element.
549 *
550 * Most of the logic implementing historical searches is handled here. We
551 * do an initial lookup with create_tid set to the asof TID. Due to the
552 * way records are laid out, a backwards iteration may be required if
553 * ENOENT is returned to locate the historical record. Here's the
554 * problem:
555 *
556 * create_tid: 10 15 20
557 * LEAF1 LEAF2
558 * records: (11) (18)
559 *
560 * Lets say we want to do a lookup AS-OF timestamp 17. We will traverse
561 * LEAF2 but the only record in LEAF2 has a create_tid of 18, which is
562 * not visible and thus causes ENOENT to be returned. We really need
563 * to check record 11 in LEAF1. If it also fails then the search fails
564 * (e.g. it might represent the range 11-16 and thus still not match our
565 * AS-OF timestamp of 17). Note that LEAF1 could be empty, requiring
566 * further iterations.
567 *
568 * If this case occurs btree_search() will set HAMMER_CURSOR_CREATE_CHECK
569 * and the cursor->create_check TID if an iteration might be needed.
570 * In the above example create_check would be set to 14.
571 */
572 int
574 {
588 /*
589 * Stop if no error.
590 * Stop if error other then ENOENT.
591 * Stop if ENOENT and not special case.
592 */
594 }
598 }
600 /* loop */
601 }
604 }
608 }
610 /*
611 * Execute the logic required to start an iteration. The first record
612 * located within the specified range is returned and iteration control
613 * flags are adjusted for successive hammer_btree_iterate() calls.
614 */
615 int
617 {
624 }
627 }
629 /*
630 * Similarly but for an iteration in the reverse direction.
631 *
632 * Set ATEDISK when iterating backwards to skip the current entry,
633 * which after an ENOENT lookup will be pointing beyond our end point.
634 */
635 int
637 {
649 }
652 }
654 /*
655 * Extract the record and/or data associated with the cursor's current
656 * position. Any prior record or data stored in the cursor is replaced.
657 * The cursor must be positioned at a leaf node.
658 *
659 * NOTE: All extractions occur at the leaf of the B-Tree.
660 */
661 int
663 {
664 hammer_node_ondisk_t node;
665 hammer_btree_elm_t elm;
666 hammer_off_t data_off;
667 hammer_mount_t hmp;
671 /*
672 * The case where the data reference resolves to the same buffer
673 * as the record reference must be handled.
674 */
680 /*
681 * There is nothing to extract for an internal element.
682 */
686 /*
687 * Only record types have data.
688 */
701 /*
702 * Load the data
703 */
711 }
713 }
716 /*
717 * Insert a leaf element into the B-Tree at the current cursor position.
718 * The cursor is positioned such that the element at and beyond the cursor
719 * are shifted to make room for the new record.
720 *
721 * The caller must call hammer_btree_lookup() with the HAMMER_CURSOR_INSERT
722 * flag set and that call must return ENOENT before this function can be
723 * called.
724 *
725 * The caller may depend on the cursor's exclusive lock after return to
726 * interlock frontend visibility (see HAMMER_RECF_CONVERT_DELETE).
727 *
728 * ENOSPC is returned if there is no room to insert a new record.
729 */
730 int
733 {
734 hammer_node_ondisk_t node;
743 /*
744 * Insert the element at the leaf node and update the count in the
745 * parent. It is possible for parent to be NULL, indicating that
746 * the filesystem's ROOT B-Tree node is a leaf itself, which is
747 * possible. The root inode can never be deleted so the leaf should
748 * never be empty.
749 *
750 * Remember that the right-hand boundary is not included in the
751 * count.
752 */
762 }
767 /*
768 * Update the leaf node's aggregate mirror_tid for mirroring
769 * support.
770 */
774 }
778 }
781 /*
782 * Debugging sanity checks.
783 */
788 }
793 }
795 /*
796 * Delete a record from the B-Tree at the current cursor position.
797 * The cursor is positioned such that the current element is the one
798 * to be deleted.
799 *
800 * On return the cursor will be positioned after the deleted element and
801 * MAY point to an internal node. It will be suitable for the continuation
802 * of an iteration but not for an insertion or deletion.
803 *
804 * Deletions will attempt to partially rebalance the B-Tree in an upward
805 * direction, but will terminate rather then deadlock. Empty internal nodes
806 * are never allowed by a deletion which deadlocks may end up giving us an
807 * empty leaf. The pruner will clean up and rebalance the tree.
808 *
809 * This function can return EDEADLK, requiring the caller to retry the
810 * operation after clearing the deadlock.
811 */
812 int
814 {
815 hammer_node_ondisk_t ondisk;
816 hammer_node_t node;
817 hammer_node_t parent;
826 /*
827 * Delete the element from the leaf node.
828 *
829 * Remember that leaf nodes do not have boundaries.
830 */
841 }
846 /*
847 * Validate local parent
848 */
854 }
856 /*
857 * If the leaf becomes empty it must be detached from the parent,
858 * potentially recursing through to the filesystem root.
859 *
860 * This may reposition the cursor at one of the parent's of the
861 * current node.
862 *
863 * Ignore deadlock errors, that simply means that btree_remove
864 * was unable to recurse and had to leave us with an empty leaf.
865 */
873 }
877 }
879 /*
880 * PRIMAY B-TREE SEARCH SUPPORT PROCEDURE
881 *
882 * Search the filesystem B-Tree for cursor->key_beg, return the matching node.
883 *
884 * The search can begin ANYWHERE in the B-Tree. As a first step the search
885 * iterates up the tree as necessary to properly position itself prior to
886 * actually doing the sarch.
887 *
888 * INSERTIONS: The search will split full nodes and leaves on its way down
889 * and guarentee that the leaf it ends up on is not full. If we run out
890 * of space the search continues to the leaf (to position the cursor for
891 * the spike), but ENOSPC is returned.
892 *
893 * The search is only guarenteed to end up on a leaf if an error code of 0
894 * is returned, or if inserting and an error code of ENOENT is returned.
895 * Otherwise it can stop at an internal node. On success a search returns
896 * a leaf node.
897 *
898 * COMPLEXITY WARNING! This is the core B-Tree search code for the entire
899 * filesystem, and it is not simple code. Please note the following facts:
900 *
901 * - Internal node recursions have a boundary on the left AND right. The
902 * right boundary is non-inclusive. The create_tid is a generic part
903 * of the key for internal nodes.
904 *
905 * - Leaf nodes contain terminal elements only now.
906 *
907 * - Filesystem lookups typically set HAMMER_CURSOR_ASOF, indicating a
908 * historical search. ASOF and INSERT are mutually exclusive. When
909 * doing an as-of lookup btree_search() checks for a right-edge boundary
910 * case. If while recursing down the left-edge differs from the key
911 * by ONLY its create_tid, HAMMER_CURSOR_CREATE_CHECK is set along
912 * with cursor->create_check. This is used by btree_lookup() to iterate.
913 * The iteration backwards because as-of searches can wind up going
914 * down the wrong branch of the B-Tree.
915 */
916 static
917 int
919 {
920 hammer_node_ondisk_t node;
921 hammer_btree_elm_t elm;
940 curthread
941 );
953 );
954 }
956 /*
957 * Move our cursor up the tree until we find a node whos range covers
958 * the key we are trying to locate.
959 *
960 * The left bound is inclusive, the right bound is non-inclusive.
961 * It is ok to cursor up too far.
962 */
973 }
975 /*
976 * The delete-checks below are based on node, not parent. Set the
977 * initial delete-check based on the parent.
978 */
983 }
985 /*
986 * We better have ended up with a node somewhere.
987 */
990 /*
991 * If we are inserting we can't start at a full node if the parent
992 * is also full (because there is no way to split the node),
993 * continue running up the tree until the requirement is satisfied
994 * or we hit the root of the filesystem.
995 *
996 * (If inserting we aren't doing an as-of search so we don't have
997 * to worry about create_check).
998 */
1006 }
1010 }
1013 /* node may have become stale */
1016 }
1018 /*
1019 * Push down through internal nodes to locate the requested key.
1020 */
1023 /*
1024 * Scan the node to find the subtree index to push down into.
1025 * We go one-past, then back-up.
1026 *
1027 * We must proactively remove deleted elements which may
1028 * have been left over from a deadlocked btree_remove().
1029 *
1030 * The left and right boundaries are included in the loop
1031 * in order to detect edge cases.
1032 *
1033 * If the separator only differs by create_tid (r == 1)
1034 * and we are doing an as-of search, we may end up going
1035 * down a branch to the left of the one containing the
1036 * desired key. This requires numerous special cases.
1037 */
1043 }
1045 /*
1046 * Try to shortcut the search before dropping into the
1047 * linear loop. Locate the first node where r <= 1.
1048 */
1057 }
1064 }
1066 }
1070 }
1072 /*
1073 * These cases occur when the parent's idea of the boundary
1074 * is wider then the child's idea of the boundary, and
1075 * require special handling. If not inserting we can
1076 * terminate the search early for these cases but the
1077 * child's boundaries cannot be unconditionally modified.
1078 */
1080 /*
1081 * If i == 0 the search terminated to the LEFT of the
1082 * left_boundary but to the RIGHT of the parent's left
1083 * boundary.
1084 */
1085 u_int8_t save;
1089 /*
1090 * If we aren't inserting we can stop here.
1091 */
1096 }
1098 /*
1099 * Correct a left-hand boundary mismatch.
1100 *
1101 * We can only do this if we can upgrade the lock,
1102 * and synchronized as a background cursor (i.e.
1103 * inserting or pruning).
1104 *
1105 * WARNING: We can only do this if inserting, i.e.
1106 * we are running on the backend.
1107 */
1118 /*
1119 * If i == node->count + 1 the search terminated to
1120 * the RIGHT of the right boundary but to the LEFT
1121 * of the parent's right boundary. If we aren't
1122 * inserting we can stop here.
1123 *
1124 * Note that the last element in this case is
1125 * elms[i-2] prior to adjustments to 'i'.
1126 */
1132 }
1134 /*
1135 * Correct a right-hand boundary mismatch.
1136 * (actual push-down record is i-2 prior to
1137 * adjustments to i).
1138 *
1139 * We can only do this if we can upgrade the lock,
1140 * and synchronized as a background cursor (i.e.
1141 * inserting or pruning).
1142 *
1143 * WARNING: We can only do this if inserting, i.e.
1144 * we are running on the backend.
1145 */
1156 /*
1157 * The push-down index is now i - 1. If we had
1158 * terminated on the right boundary this will point
1159 * us at the last element.
1160 */
1162 }
1170 i,
1176 );
1177 }
1179 /*
1180 * We better have a valid subtree offset.
1181 */
1184 /*
1185 * Handle insertion and deletion requirements.
1186 *
1187 * If inserting split full nodes. The split code will
1188 * adjust cursor->node and cursor->index if the current
1189 * index winds up in the new node.
1190 *
1191 * If inserting and a left or right edge case was detected,
1192 * we cannot correct the left or right boundary and must
1193 * prepend and append an empty leaf node in order to make
1194 * the boundary correction.
1195 *
1196 * If we run out of space we set enospc and continue on
1197 * to a leaf to provide the spike code with a good point
1198 * of entry.
1199 */
1207 }
1208 /*
1209 * reload stale pointers
1210 */
1213 }
1214 }
1216 /*
1217 * Push down (push into new node, existing node becomes
1218 * the parent) and continue the search.
1219 */
1221 /* node may have become stale */
1225 }
1227 /*
1228 * We are at a leaf, do a linear search of the key array.
1229 *
1230 * On success the index is set to the matching element and 0
1231 * is returned.
1232 *
1233 * On failure the index is set to the insertion point and ENOENT
1234 * is returned.
1235 *
1236 * Boundaries are not stored in leaf nodes, so the index can wind
1237 * up to the left of element 0 (index == 0) or past the end of
1238 * the array (index == node->count). It is also possible that the
1239 * leaf might be empty.
1240 */
1248 }
1250 /*
1251 * Try to shortcut the search before dropping into the
1252 * linear loop. Locate the first node where r <= 1.
1253 */
1264 /*
1265 * We are at a record element. Stop if we've flipped past
1266 * key_beg, not counting the create_tid test. Allow the
1267 * r == 1 case (key_beg > element but differs only by its
1268 * create_tid) to fall through to the AS-OF check.
1269 */
1277 }
1279 /*
1280 * Check our as-of timestamp against the element.
1281 */
1287 }
1288 /* success */
1293 }
1294 /* success */
1295 }
1301 }
1303 }
1305 /*
1306 * The search of the leaf node failed. i is the insertion point.
1307 */
1308 failed:
1312 }
1314 /*
1315 * No exact match was found, i is now at the insertion point.
1316 *
1317 * If inserting split a full leaf before returning. This
1318 * may have the side effect of adjusting cursor->node and
1319 * cursor->index.
1320 */
1329 }
1330 /*
1331 * reload stale pointers
1332 */
1333 /* NOT USED
1334 i = cursor->index;
1335 node = &cursor->node->internal;
1336 */
1337 }
1339 /*
1340 * We reached a leaf but did not find the key we were looking for.
1341 * If this is an insert we will be properly positioned for an insert
1342 * (ENOENT) or spike (ENOSPC) operation.
1343 */
1345 done:
1347 }
1349 /*
1350 * Heuristical search for the first element whos comparison is <= 1. May
1351 * return an index whos compare result is > 1 but may only return an index
1352 * whos compare result is <= 1 if it is the first element with that result.
1353 */
1354 int
1356 {
1362 /*
1363 * Don't bother if the node does not have very many elements
1364 */
1375 }
1376 }
1378 }
1381 /************************************************************************
1382 * SPLITTING AND MERGING *
1383 ************************************************************************
1384 *
1385 * These routines do all the dirty work required to split and merge nodes.
1386 */
1388 /*
1389 * Split an internal node into two nodes and move the separator at the split
1390 * point to the parent.
1391 *
1392 * (cursor->node, cursor->index) indicates the element the caller intends
1393 * to push into. We will adjust node and index if that element winds
1394 * up in the split node.
1395 *
1396 * If we are at the root of the filesystem a new root must be created with
1397 * two elements, one pointing to the original root and one pointing to the
1398 * newly allocated split node.
1399 */
1400 static
1401 int
1403 {
1404 hammer_node_ondisk_t ondisk;
1405 hammer_node_t node;
1406 hammer_node_t parent;
1407 hammer_node_t new_node;
1408 hammer_btree_elm_t elm;
1409 hammer_btree_elm_t parent_elm;
1426 /*
1427 * We are splitting but elms[split] will be promoted to the parent,
1428 * leaving the right hand node with one less element. If the
1429 * insertion point will be on the left-hand side adjust the split
1430 * point to give the right hand side one additional node.
1431 */
1438 /*
1439 * If we are at the root of the filesystem, create a new root node
1440 * with 1 element and split normally. Avoid making major
1441 * modifications until we know the whole operation will work.
1442 */
1459 /* ondisk->elms[1].base.btype - not used */
1466 }
1468 /*
1469 * Split node into new_node at the split point.
1470 *
1471 * B O O O P N N B <-- P = node->elms[split]
1472 * 0 1 2 3 4 5 6 <-- subtree indices
1473 *
1474 * x x P x x
1475 * s S S s
1476 * / \
1477 * B O O O B B N N B <--- inner boundary points are 'P'
1478 * 0 1 2 3 4 5 6
1479 *
1480 */
1487 }
1489 }
1492 /*
1493 * Create the new node. P becomes the left-hand boundary in the
1494 * new node. Copy the right-hand boundary as well.
1495 *
1496 * elm is the new separator.
1497 */
1511 /*
1512 * Cleanup the original node. Elm (P) becomes the new boundary,
1513 * its subtree_offset was moved to the new node. If we had created
1514 * a new root its parent pointer may have changed.
1515 */
1519 /*
1520 * Insert the separator into the parent, fixup the parent's
1521 * reference to the original node, and reference the new node.
1522 * The separator is P.
1523 *
1524 * Remember that base.count does not include the right-hand boundary.
1525 */
1540 /*
1541 * The children of new_node need their parent pointer set to new_node.
1542 * The children have already been locked by
1543 * hammer_btree_lock_children().
1544 */
1550 }
1551 }
1554 /*
1555 * The filesystem's root B-Tree pointer may have to be updated.
1556 */
1558 hammer_volume_t volume;
1564 vol0_btree_root);
1571 }
1574 }
1577 /*
1578 * Ok, now adjust the cursor depending on which element the original
1579 * index was pointing at. If we are >= the split point the push node
1580 * is now in the new node.
1581 *
1582 * NOTE: If we are at the split point itself we cannot stay with the
1583 * original node because the push index will point at the right-hand
1584 * boundary, which is illegal.
1585 *
1586 * NOTE: The cursor's parent or parent_index must be adjusted for
1587 * the case where a new parent (new root) was created, and the case
1588 * where the cursor is now pointing at the split node.
1589 */
1600 }
1602 /*
1603 * Fixup left and right bounds
1604 */
1613 done:
1617 }
1619 /*
1620 * Same as the above, but splits a full leaf node.
1621 *
1622 * This function
1623 */
1624 static
1625 int
1627 {
1628 hammer_node_ondisk_t ondisk;
1629 hammer_node_t parent;
1630 hammer_node_t leaf;
1631 hammer_mount_t hmp;
1632 hammer_node_t new_leaf;
1633 hammer_btree_elm_t elm;
1634 hammer_btree_elm_t parent_elm;
1635 hammer_base_elm_t mid_boundary;
1651 /*
1652 * Calculate the split point. If the insertion point will be on
1653 * the left-hand side adjust the split point to give the right
1654 * hand side one additional node.
1655 *
1656 * Spikes are made up of two leaf elements which cannot be
1657 * safely split.
1658 */
1674 /*
1675 * If we are at the root of the tree, create a new root node with
1676 * 1 element and split normally. Avoid making major modifications
1677 * until we know the whole operation will work.
1678 */
1694 /* ondisk->elms[1].base.btype = not used */
1702 }
1704 /*
1705 * Split leaf into new_leaf at the split point. Select a separator
1706 * value in-between the two leafs but with a bent towards the right
1707 * leaf since comparisons use an 'elm >= separator' inequality.
1708 *
1709 * L L L L L L L L
1710 *
1711 * x x P x x
1712 * s S S s
1713 * / \
1714 * L L L L L L L L
1715 */
1722 }
1724 }
1727 /*
1728 * Create the new node and copy the leaf elements from the split
1729 * point on to the new node.
1730 */
1744 /*
1745 * Cleanup the original node. Because this is a leaf node and
1746 * leaf nodes do not have a right-hand boundary, there
1747 * aren't any special edge cases to clean up. We just fixup the
1748 * count.
1749 */
1752 /*
1753 * Insert the separator into the parent, fixup the parent's
1754 * reference to the original node, and reference the new node.
1755 * The separator is P.
1756 *
1757 * Remember that base.count does not include the right-hand boundary.
1758 * We are copying parent_index+1 to parent_index+2, not +0 to +1.
1759 */
1777 /*
1778 * The filesystem's root B-Tree pointer may have to be updated.
1779 */
1781 hammer_volume_t volume;
1787 vol0_btree_root);
1794 }
1797 }
1800 /*
1801 * Ok, now adjust the cursor depending on which element the original
1802 * index was pointing at. If we are >= the split point the push node
1803 * is now in the new node.
1804 *
1805 * NOTE: If we are at the split point itself we need to select the
1806 * old or new node based on where key_beg's insertion point will be.
1807 * If we pick the wrong side the inserted element will wind up in
1808 * the wrong leaf node and outside that node's bounds.
1809 */
1822 }
1824 /*
1825 * Fixup left and right bounds
1826 */
1831 /*
1832 * Assert that the bounds are correct.
1833 */
1841 done:
1844 }
1846 #if 0
1848 /*
1849 * Recursively correct the right-hand boundary's create_tid to (tid) as
1850 * long as the rest of the key matches. We have to recurse upward in
1851 * the tree as well as down the left side of each parent's right node.
1852 *
1853 * Return EDEADLK if we were only partially successful, forcing the caller
1854 * to try again. The original cursor is not modified. This routine can
1855 * also fail with EDEADLK if it is forced to throw away a portion of its
1856 * record history.
1857 *
1858 * The caller must pass a downgraded cursor to us (otherwise we can't dup it).
1859 */
1862 hammer_node_t node;
1864 };
1868 int
1870 {
1873 hammer_base_elm_t elm;
1874 hammer_node_t orig_node;
1882 /*
1883 * Save our position so we can restore it on return. This also
1884 * gives us a stable 'elm'.
1885 */
1892 /*
1893 * Now build a list of parents going up, allocating a rhb
1894 * structure for each one.
1895 */
1897 /*
1898 * Stop if we no longer have any right-bounds to fix up
1899 */
1904 }
1906 /*
1907 * Stop if the right-hand bound's create_tid does not
1908 * need to be corrected.
1909 */
1921 }
1923 /*
1924 * now safely adjust the right hand bound for each rhb. This may
1925 * also require taking the right side of the tree and iterating down
1926 * ITS left side.
1927 */
1940 /*
1941 * Right-boundary for parent at internal node
1942 * is one element to the right of the element whos
1943 * right boundary needs adjusting. We must then
1944 * traverse down the left side correcting any left
1945 * bounds (which may now be too far to the left).
1946 */
1954 }
1955 }
1957 /*
1958 * Cleanup
1959 */
1965 }
1970 }
1972 /*
1973 * Similar to rhb (in fact, rhb calls lhb), but corrects the left hand
1974 * bound going downward starting at the current cursor position.
1975 *
1976 * This function does not restore the cursor after use.
1977 */
1978 int
1980 {
1982 hammer_base_elm_t elm;
1983 hammer_base_elm_t cmp;
1993 /*
1994 * Record the node and traverse down the left-hand side for all
1995 * matching records needing a boundary correction.
1996 */
2007 /*
2008 * Nothing to traverse down if we are at the right
2009 * boundary of an internal node.
2010 */
2018 }
2028 }
2032 }
2034 /*
2035 * Now we can safely adjust the left-hand boundary from the bottom-up.
2036 * The last element we remove from the list is the caller's right hand
2037 * boundary, which must also be adjusted.
2038 */
2057 }
2058 }
2060 /*
2061 * Cleanup
2062 */
2068 }
2070 }
2072 #endif
2074 /*
2075 * Attempt to remove the locked, empty or want-to-be-empty B-Tree node at
2076 * (cursor->node). Returns 0 on success, EDEADLK if we could not complete
2077 * the operation due to a deadlock, or some other error.
2078 *
2079 * This routine is initially called with an empty leaf and may be
2080 * recursively called with single-element internal nodes.
2081 *
2082 * It should also be noted that when removing empty leaves we must be sure
2083 * to test and update mirror_tid because another thread may have deadlocked
2084 * against us (or someone) trying to propagate it up and cannot retry once
2085 * the node has been deleted.
2086 *
2087 * On return the cursor may end up pointing to an internal node, suitable
2088 * for further iteration but not for an immediate insertion or deletion.
2089 */
2090 static int
2092 {
2093 hammer_node_ondisk_t ondisk;
2094 hammer_btree_elm_t elm;
2095 hammer_node_t node;
2096 hammer_node_t parent;
2102 /*
2103 * When deleting the root of the filesystem convert it to
2104 * an empty leaf node. Internal nodes cannot be empty.
2105 */
2116 }
2121 /*
2122 * Attempt to remove the parent's reference to the child. If the
2123 * parent would become empty we have to recurse. If we fail we
2124 * leave the parent pointing to an empty leaf node.
2125 *
2126 * We have to recurse successfully before we can delete the internal
2127 * node as it is illegal to have empty internal nodes. Even though
2128 * the operation may be aborted we must still fixup any unlocked
2129 * cursors as if we had deleted the element prior to recursing
2130 * (by calling hammer_cursor_deleted_element()) so those cursors
2131 * are properly forced up the chain by the recursion.
2132 */
2134 /*
2135 * This special cursor_up_locked() call leaves the original
2136 * node exclusively locked and referenced, leaves the
2137 * original parent locked (as the new node), and locks the
2138 * new parent. It can return EDEADLK.
2139 */
2156 }
2163 }
2175 /*
2176 * We must retain the highest mirror_tid. The deleted
2177 * range is now encompassed by the element to the left.
2178 * If we are already at the left edge the new left edge
2179 * inherits mirror_tid.
2180 *
2181 * Note that bounds of the parent to our parent may create
2182 * a gap to the left of our left-most node or to the right
2183 * of our right-most node. The gap is silently included
2184 * in the mirror_tid's area of effect from the point of view
2185 * of the scan.
2186 */
2192 }
2198 }
2199 }
2201 /*
2202 * Delete the subtree reference in the parent
2203 */
2212 /*
2213 * cursor->node is invalid, cursor up to make the cursor
2214 * valid again.
2215 */
2217 }
2219 }
2221 /*
2222 * Propagate cursor->trans->tid up the B-Tree starting at the current
2223 * cursor position using pseudofs info gleaned from the passed inode.
2224 *
2225 * The passed inode has no relationship to the cursor position other
2226 * then being in the same pseudofs as the insertion or deletion we
2227 * are propagating the mirror_tid for.
2228 */
2229 void
2231 hammer_pseudofs_inmem_t pfsm,
2232 hammer_btree_leaf_elm_t leaf)
2233 {
2234 hammer_cursor_t ncursor;
2235 hammer_tid_t mirror_tid;
2238 /*
2239 * We do not propagate a mirror_tid if the filesystem was mounted
2240 * in no-mirror mode.
2241 */
2245 /*
2246 * This is a bit of a hack because we cannot deadlock or return
2247 * EDEADLK here. The related operation has already completed and
2248 * we must propagate the mirror_tid now regardless.
2249 *
2250 * Generate a new cursor which inherits the original's locks and
2251 * unlock the original. Use the new cursor to propagate the
2252 * mirror_tid. Then clean up the new cursor and reacquire locks
2253 * on the original.
2254 *
2255 * hammer_dup_cursor() cannot dup locks. The dup inherits the
2256 * original's locks and the original is tracked and must be
2257 * re-locked.
2258 */
2265 }
2268 /*
2269 * Propagate a mirror TID update upwards through the B-Tree to the root.
2270 *
2271 * A locked internal node must be passed in. The node will remain locked
2272 * on return.
2273 *
2274 * This function syncs mirror_tid at the specified internal node's element,
2275 * adjusts the node's aggregation mirror_tid, and then recurses upwards.
2276 */
2277 static int
2279 {
2280 hammer_btree_internal_elm_t elm;
2281 hammer_node_t node;
2291 }
2297 /*
2298 * Adjust the node's element
2299 */
2311 }
2314 /*
2315 * Adjust the node's mirror_tid aggregator
2316 */
2326 }
2327 }
2331 }
2333 hammer_node_t
2336 {
2337 hammer_node_t parent;
2338 hammer_btree_elm_t elm;
2341 /*
2342 * Get the node
2343 */
2348 }
2351 /*
2352 * Lock the node
2353 */
2359 }
2362 }
2364 /*
2365 * Figure out which element in the parent is pointing to the
2366 * child.
2367 */
2373 }
2379 }
2383 }
2387 }
2389 /*
2390 * The element (elm) has been moved to a new internal node (node).
2391 *
2392 * If the element represents a pointer to an internal node that node's
2393 * parent must be adjusted to the element's new location.
2394 *
2395 * XXX deadlock potential here with our exclusive locks
2396 */
2397 int
2399 hammer_btree_elm_t elm)
2400 {
2401 hammer_node_t child;
2416 }
2420 }
2422 }
2424 /*
2425 * Exclusively lock all the children of node. This is used by the split
2426 * code to prevent anyone from accessing the children of a cursor node
2427 * while we fix-up its parent offset.
2428 *
2429 * If we don't lock the children we can really mess up cursors which block
2430 * trying to cursor-up into our node.
2431 *
2432 * On failure EDEADLK (or some other error) is returned. If a deadlock
2433 * error is returned the cursor is adjusted to block on termination.
2434 */
2435 int
2438 {
2439 hammer_node_t node;
2440 hammer_node_locklist_t item;
2441 hammer_node_ondisk_t ondisk;
2442 hammer_btree_elm_t elm;
2443 hammer_node_t child;
2453 /*
2454 * We really do not want to block on I/O with exclusive locks held,
2455 * pre-get the children before trying to lock the mess.
2456 */
2463 }
2469 }
2471 /*
2472 * Do it for real
2473 */
2489 }
2495 }
2504 }
2505 }
2506 }
2510 }
2513 /*
2514 * Release previously obtained node locks.
2515 */
2516 void
2519 {
2520 hammer_node_locklist_t item;
2527 }
2528 }
2530 /************************************************************************
2531 * MISCELLANIOUS SUPPORT *
2532 ************************************************************************/
2534 /*
2535 * Compare two B-Tree elements, return -N, 0, or +N (e.g. similar to strcmp).
2536 *
2537 * Note that for this particular function a return value of -1, 0, or +1
2538 * can denote a match if create_tid is otherwise discounted. A create_tid
2539 * of zero is considered to be 'infinity' in comparisons.
2540 *
2541 * See also hammer_rec_rb_compare() and hammer_rec_cmp() in hammer_object.c.
2542 */
2543 int
2545 {
2566 /*
2567 * A create_tid of zero indicates a record which is undeletable
2568 * and must be considered to have a value of positive infinity.
2569 */
2574 }
2582 }
2584 /*
2585 * Test a timestamp against an element to determine whether the
2586 * element is visible. A timestamp of 0 means 'infinity'.
2587 */
2588 int
2590 {
2595 }
2601 }
2603 /*
2604 * Create a separator half way inbetween key1 and key2. For fields just
2605 * one unit apart, the separator will match key2. key1 is on the left-hand
2606 * side and key2 is on the right-hand side.
2607 *
2608 * key2 must be >= the separator. It is ok for the separator to match key2.
2609 *
2610 * NOTE: Even if key1 does not match key2, the separator may wind up matching
2611 * key2.
2612 *
2613 * NOTE: It might be beneficial to just scrap this whole mess and just
2614 * set the separator to key2.
2615 */
2616 #define MAKE_SEPARATOR(key1, key2, dest, field) \
2617 dest->field = key1->field + ((key2->field - key1->field + 1) >> 1);
2619 static void
2621 hammer_base_elm_t dest)
2622 {
2637 /*
2638 * Don't bother creating a separator for
2639 * create_tid, which also conveniently avoids
2640 * having to handle the create_tid == 0
2641 * (infinity) case. Just leave create_tid
2642 * set to key2.
2643 *
2644 * Worst case, dest matches key2 exactly,
2645 * which is acceptable.
2646 */
2647 }
2648 }
2649 }
2650 }
2652 #undef MAKE_SEPARATOR
2654 /*
2655 * Return whether a generic internal or leaf node is full
2656 */
2657 static int
2659 {
2671 }
2673 }
2675 #if 0
2676 static int
2678 {
2684 }
2685 #endif
2687 void
2689 {
2690 hammer_btree_elm_t elm;
2696 /*
2697 * Dump both boundary elements if an internal node
2698 */
2703 }
2708 }
2709 }
2710 }
2712 void
2714 {
2737 }
2738 }