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1101 jermar 1 
/*
2 
 * Copyright (C) 2006 Jakub Jermar
3 
 * All rights reserved.
4 
 *
5 
 * Redistribution and use in source and binary forms, with or without
6 
 * modification, are permitted provided that the following conditions
7 
 * are met:
8 
 *
9 
 * - Redistributions of source code must retain the above copyright
10 
 *   notice, this list of conditions and the following disclaimer.
11 
 * - Redistributions in binary form must reproduce the above copyright
12 
 *   notice, this list of conditions and the following disclaimer in the
13 
 *   documentation and/or other materials provided with the distribution.
14 
 * - The name of the author may not be used to endorse or promote products
15 
 *   derived from this software without specific prior written permission.
16 
 *
17 
 * THIS SOFTWARE IS PROVIDED BY THE AUTHOR ``AS IS'' AND ANY EXPRESS OR
18 
 * IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES
19 
 * OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED.
20 
 * IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR ANY DIRECT, INDIRECT,
21 
 * INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT
22 
 * NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE,
23 
 * DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY
24 
 * THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
25 
 * (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF
26 
 * THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
27 
 */
28 
 
29 
/*
30 
 * This B-tree has the following properties:
1164 jermar 31 
 * - it is a ballanced 3-4-5 tree (i.e. BTREE_M = 5)
1101 jermar 32 
 * - values (i.e. pointers to values) are stored only in leaves
33 
 * - leaves are linked in a list
1148 jermar 34 
 * - technically, it is a B+tree (because of the previous properties)
1101 jermar 35 
 *
1134 jermar 36 
 * Be carefull when using these trees. They need to allocate
37 
 * and deallocate memory for their index nodes and as such
38 
 * can sleep.
1101 jermar 39 
 */
40 
 
41 
#include <adt/btree.h>
42 
#include <adt/list.h>
43 
#include <mm/slab.h>
44 
#include <debug.h>
45 
#include <panic.h>
46 
#include <typedefs.h>
47 
#include <print.h>
48 
 
1177 jermar 49 
static void _btree_insert(btree_t *t, btree_key_t key, void *value, btree_node_t *rsubtree, btree_node_t *node);
50 
static void _btree_remove(btree_t *t, btree_key_t key, btree_node_t *node);
1101 jermar 51 
static void node_initialize(btree_node_t *node);
1177 jermar 52 
static void node_insert_key_and_lsubtree(btree_node_t *node, btree_key_t key, void *value, btree_node_t *lsubtree);
53 
static void node_insert_key_and_rsubtree(btree_node_t *node, btree_key_t key, void *value, btree_node_t *rsubtree);
54 
static void node_remove_key_and_lsubtree(btree_node_t *node, btree_key_t key);
55 
static void node_remove_key_and_rsubtree(btree_node_t *node, btree_key_t key);
56 
static btree_node_t *node_split(btree_node_t *node, btree_key_t key, void *value, btree_node_t *rsubtree, btree_key_t *median);
1142 jermar 57 
static btree_node_t *node_combine(btree_node_t *node);
1136 jermar 58 
static index_t find_key_by_subtree(btree_node_t *node, btree_node_t *subtree, bool right);
1142 jermar 59 
static void rotate_from_right(btree_node_t *lnode, btree_node_t *rnode, index_t idx);
60 
static void rotate_from_left(btree_node_t *lnode, btree_node_t *rnode, index_t idx);
1177 jermar 61 
static bool try_insert_by_rotation_to_left(btree_node_t *node, btree_key_t key, void *value, btree_node_t *rsubtree);
62 
static bool try_insert_by_rotation_to_right(btree_node_t *node, btree_key_t key, void *value, btree_node_t *rsubtree);
1142 jermar 63 
static bool try_rotation_from_left(btree_node_t *rnode);
64 
static bool try_rotation_from_right(btree_node_t *lnode);
1101 jermar 65 
 
66 
#define ROOT_NODE(n)        (!(n)->parent)
67 
#define INDEX_NODE(n)       ((n)->subtree[0] != NULL)
68 
#define LEAF_NODE(n)        ((n)->subtree[0] == NULL)
69 
 
1140 jermar 70 
#define FILL_FACTOR     ((BTREE_M-1)/2)
71 
 
1101 jermar 72 
#define MEDIAN_LOW_INDEX(n) (((n)->keys-1)/2)
73 
#define MEDIAN_HIGH_INDEX(n)    ((n)->keys/2)
74 
#define MEDIAN_LOW(n)       ((n)->key[MEDIAN_LOW_INDEX((n))]);
75 
#define MEDIAN_HIGH(n)      ((n)->key[MEDIAN_HIGH_INDEX((n))]);
76 
 
1164 jermar 77 
static slab_cache_t *btree_node_slab;
78 
 
79 
/** Initialize B-trees. */
80 
void btree_init(void)
81 
{
82 
    btree_node_slab = slab_cache_create("btree_node_slab", sizeof(btree_node_t), 0, NULL, NULL, SLAB_CACHE_MAGDEFERRED);
83 
}
84 
 
1101 jermar 85 
/** Create empty B-tree.
86 
 *
87 
 * @param t B-tree.
88 
 */
89 
void btree_create(btree_t *t)
90 
{
91 
    list_initialize(&t->leaf_head);
1164 jermar 92 
    t->root = (btree_node_t *) slab_alloc(btree_node_slab, 0);
1101 jermar 93 
    node_initialize(t->root);
94 
    list_append(&t->root->leaf_link, &t->leaf_head);
95 
}
96 
 
97 
/** Destroy empty B-tree. */
98 
void btree_destroy(btree_t *t)
99 
{
100 
    ASSERT(!t->root->keys);
1164 jermar 101 
    slab_free(btree_node_slab, t->root);
1101 jermar 102 
}
103 
 
104 
/** Insert key-value pair into B-tree.
105 
 *
106 
 * @param t B-tree.
107 
 * @param key Key to be inserted.
108 
 * @param value Value to be inserted.
109 
 * @param leaf_node Leaf node where the insertion should begin.
110 
 */
1177 jermar 111 
void btree_insert(btree_t *t, btree_key_t key, void *value, btree_node_t *leaf_node)
1101 jermar 112 
{
113 
    btree_node_t *lnode;
114 
 
115 
    ASSERT(value);
116 
 
117 
    lnode = leaf_node;
118 
    if (!lnode) {
119 
        if (btree_search(t, key, &lnode)) {
120 
            panic("B-tree %P already contains key %d\n", t, key);
121 
        }
122 
    }
123 
 
124 
    _btree_insert(t, key, value, NULL, lnode);
125 
}
126 
 
127 
/** Recursively insert into B-tree.
128 
 *
129 
 * @param t B-tree.
130 
 * @param key Key to be inserted.
131 
 * @param value Value to be inserted.
132 
 * @param rsubtree Right subtree of the inserted key.
133 
 * @param node Start inserting into this node.
134 
 */
1177 jermar 135 
void _btree_insert(btree_t *t, btree_key_t key, void *value, btree_node_t *rsubtree, btree_node_t *node)
1101 jermar 136 
{
137 
    if (node->keys < BTREE_MAX_KEYS) {
138 
        /*
139 
         * Node conatins enough space, the key can be stored immediately.
140 
         */
1142 jermar 141 
        node_insert_key_and_rsubtree(node, key, value, rsubtree);
142 
    } else if (try_insert_by_rotation_to_left(node, key, value, rsubtree)) {
1136 jermar 143 
        /*
144 
         * The key-value-rsubtree triplet has been inserted because
145 
         * some keys could have been moved to the left sibling.
146 
         */
1142 jermar 147 
    } else if (try_insert_by_rotation_to_right(node, key, value, rsubtree)) {
1136 jermar 148 
        /*
149 
         * The key-value-rsubtree triplet has been inserted because
150 
         * some keys could have been moved to the right sibling.
151 
         */
1101 jermar 152 
    } else {
153 
        btree_node_t *rnode;
1177 jermar 154 
        btree_key_t median;
1101 jermar 155 
 
156 
        /*
1136 jermar 157 
         * Node is full and both siblings (if both exist) are full too.
158 
         * Split the node and insert the smallest key from the node containing
159 
         * bigger keys (i.e. the new node) into its parent.
1101 jermar 160 
         */
161 
 
162 
        rnode = node_split(node, key, value, rsubtree, &median);
163 
 
164 
        if (LEAF_NODE(node)) {
1144 jermar 165 
            list_prepend(&rnode->leaf_link, &node->leaf_link);
1101 jermar 166 
        }
167 
 
168 
        if (ROOT_NODE(node)) {
169 
            /*
170 
             * We split the root node. Create new root.
171 
             */
1164 jermar 172 
            t->root = (btree_node_t *) slab_alloc(btree_node_slab, 0);
1101 jermar 173 
            node->parent = t->root;
174 
            rnode->parent = t->root;
175 
            node_initialize(t->root);
176 
 
177 
            /*
178 
             * Left-hand side subtree will be the old root (i.e. node).
179 
             * Right-hand side subtree will be rnode.
180 
             */        
181 
            t->root->subtree[0] = node;
182 
 
183 
            t->root->depth = node->depth + 1;
184 
        }
185 
        _btree_insert(t, median, NULL, rnode, node->parent);
186 
    }  
187 
 
188 
}
189 
 
1140 jermar 190 
/** Remove B-tree node.
191 
 *
192 
 * @param B-tree.
193 
 * @param key Key to be removed from the B-tree along with its associated value.
194 
 * @param leaf_node If not NULL, pointer to the leaf node where the key is found.
195 
 */
1177 jermar 196 
void btree_remove(btree_t *t, btree_key_t key, btree_node_t *leaf_node)
1101 jermar 197 
{
1140 jermar 198 
    btree_node_t *lnode;
199 
 
200 
    lnode = leaf_node;
201 
    if (!lnode) {
202 
        if (!btree_search(t, key, &lnode)) {
203 
            panic("B-tree %P does not contain key %d\n", t, key);
204 
        }
205 
    }
206 
 
1142 jermar 207 
    _btree_remove(t, key, lnode);
208 
}
1140 jermar 209 
 
1142 jermar 210 
/** Recursively remove B-tree node.
211 
 *
212 
 * @param B-tree.
213 
 * @param key Key to be removed from the B-tree along with its associated value.
214 
 * @param node Node where the key being removed resides.
215 
 */
1177 jermar 216 
void _btree_remove(btree_t *t, btree_key_t key, btree_node_t *node)
1142 jermar 217 
{
218 
    if (ROOT_NODE(node)) {
219 
        if (node->keys == 1 && node->subtree[0]) {
220 
            /*
221 
             * Free the current root and set new root.
222 
             */
223 
            t->root = node->subtree[0];
224 
            t->root->parent = NULL;
1164 jermar 225 
            slab_free(btree_node_slab, node);
1142 jermar 226 
        } else {
227 
            /*
228 
             * Remove the key from the root node.
229 
             * Note that the right subtree is removed because when
230 
             * combining two nodes, the left-side sibling is preserved
231 
             * and the right-side sibling is freed.
232 
             */
233 
            node_remove_key_and_rsubtree(node, key);
234 
        }
235 
        return;
236 
    }
237 
 
238 
    if (node->keys <= FILL_FACTOR) {
239 
        /*
240 
         * If the node is below the fill factor,
241 
         * try to borrow keys from left or right sibling.
242 
         */
243 
        if (!try_rotation_from_left(node))
244 
            try_rotation_from_right(node);
245 
    }
246 
 
247 
    if (node->keys > FILL_FACTOR) {
248 
        int i;
249 
 
250 
        /*
251 
         * The key can be immediatelly removed.
252 
         *
253 
         * Note that the right subtree is removed because when
254 
         * combining two nodes, the left-side sibling is preserved
255 
         * and the right-side sibling is freed.
256 
         */
257 
        node_remove_key_and_rsubtree(node, key);
258 
        for (i = 0; i < node->parent->keys; i++) {
259 
            if (node->parent->key[i] == key)
260 
                node->parent->key[i] = node->key[0];
261 
        }
262 
 
263 
    } else {
264 
        index_t idx;
265 
        btree_node_t *rnode, *parent;
266 
 
267 
        /*
268 
         * The node is below the fill factor as well as its left and right sibling.
269 
         * Resort to combining the node with one of its siblings.
270 
         * The node which is on the left is preserved and the node on the right is
271 
         * freed.
272 
         */
273 
        parent = node->parent;
274 
        node_remove_key_and_rsubtree(node, key);
275 
        rnode = node_combine(node);
276 
        if (LEAF_NODE(rnode))
277 
            list_remove(&rnode->leaf_link);
278 
        idx = find_key_by_subtree(parent, rnode, true);
279 
        ASSERT((int) idx != -1);
1164 jermar 280 
        slab_free(btree_node_slab, rnode);
1142 jermar 281 
        _btree_remove(t, parent->key[idx], parent);
282 
    }
1101 jermar 283 
}
284 
 
285 
/** Search key in a B-tree.
286 
 *
287 
 * @param t B-tree.
288 
 * @param key Key to be searched.
289 
 * @param leaf_node Address where to put pointer to visited leaf node.
290 
 *
291 
 * @return Pointer to value or NULL if there is no such key.
292 
 */
1177 jermar 293 
void *btree_search(btree_t *t, btree_key_t key, btree_node_t **leaf_node)
1101 jermar 294 
{
295 
    btree_node_t *cur, *next;
296 
 
297 
    /*
1134 jermar 298 
     * Iteratively descend to the leaf that can contain the searched key.
1101 jermar 299 
     */
300 
    for (cur = t->root; cur; cur = next) {
1134 jermar 301 
 
1101 jermar 302 
        /* Last iteration will set this with proper leaf node address. */
303 
        *leaf_node = cur;
1134 jermar 304 
 
305 
        /*
306 
         * The key can be in the leftmost subtree.
307 
         * Test it separately.
308 
         */
309 
        if (key < cur->key[0]) {
310 
            next = cur->subtree[0];
311 
            continue;
312 
        } else {
313 
            void *val;
314 
            int i;
315 
 
316 
            /*
317 
             * Now if the key is smaller than cur->key[i]
318 
             * it can only mean that the value is in cur->subtree[i]
319 
             * or it is not in the tree at all.
320 
             */
321 
            for (i = 1; i < cur->keys; i++) {
322 
                if (key < cur->key[i]) {
323 
                    next = cur->subtree[i];
324 
                    val = cur->value[i - 1];
325 
 
326 
                    if (LEAF_NODE(cur))
327 
                        return key == cur->key[i - 1] ? val : NULL;
328 
 
329 
                    goto descend;
330 
                }
1101 jermar 331 
            }
1134 jermar 332 
 
333 
            /*
334 
             * Last possibility is that the key is in the rightmost subtree.
335 
             */
336 
            next = cur->subtree[i];
337 
            val = cur->value[i - 1];
338 
            if (LEAF_NODE(cur))
339 
                return key == cur->key[i - 1] ? val : NULL;
1101 jermar 340 
        }
1134 jermar 341 
        descend:
342 
            ;
1101 jermar 343 
    }
344 
 
345 
    /*
1134 jermar 346 
     * The key was not found in the *leaf_node and is smaller than any of its keys.
1101 jermar 347 
     */
348 
    return NULL;
349 
}
350 
 
1150 jermar 351 
/** Return pointer to B-tree leaf node's left neighbour.
1147 jermar 352 
 *
353 
 * @param t B-tree.
1150 jermar 354 
 * @param node Node whose left neighbour will be returned.
1147 jermar 355 
 *
1150 jermar 356 
 * @return Left neighbour of the node or NULL if the node does not have the left neighbour.
1147 jermar 357 
 */
1150 jermar 358 
btree_node_t *btree_leaf_node_left_neighbour(btree_t *t, btree_node_t *node)
1147 jermar 359 
{
360 
    ASSERT(LEAF_NODE(node));
361 
    if (node->leaf_link.prev != &t->leaf_head)
362 
        return list_get_instance(node->leaf_link.prev, btree_node_t, leaf_link);
363 
    else
364 
        return NULL;
365 
}
366 
 
1150 jermar 367 
/** Return pointer to B-tree leaf node's right neighbour.
1147 jermar 368 
 *
369 
 * @param t B-tree.
1150 jermar 370 
 * @param node Node whose right neighbour will be returned.
1147 jermar 371 
 *
1150 jermar 372 
 * @return Right neighbour of the node or NULL if the node does not have the right neighbour.
1147 jermar 373 
 */
1150 jermar 374 
btree_node_t *btree_leaf_node_right_neighbour(btree_t *t, btree_node_t *node)
1147 jermar 375 
{
376 
    ASSERT(LEAF_NODE(node));
377 
    if (node->leaf_link.next != &t->leaf_head)
378 
        return list_get_instance(node->leaf_link.next, btree_node_t, leaf_link);
379 
    else
380 
        return NULL;
381 
}
382 
 
1101 jermar 383 
/** Initialize B-tree node.
384 
 *
385 
 * @param node B-tree node.
386 
 */
387 
void node_initialize(btree_node_t *node)
388 
{
389 
    int i;
390 
 
391 
    node->keys = 0;
392 
 
393 
    /* Clean also space for the extra key. */
394 
    for (i = 0; i < BTREE_MAX_KEYS + 1; i++) {
395 
        node->key[i] = 0;
396 
        node->value[i] = NULL;
397 
        node->subtree[i] = NULL;
398 
    }
399 
    node->subtree[i] = NULL;
400 
 
401 
    node->parent = NULL;
402 
 
403 
    link_initialize(&node->leaf_link);
404 
 
405 
    link_initialize(&node->bfs_link);
406 
    node->depth = 0;
407 
}
408 
 
1136 jermar 409 
/** Insert key-value-lsubtree triplet into B-tree node.
1101 jermar 410 
 *
411 
 * It is actually possible to have more keys than BTREE_MAX_KEYS.
1136 jermar 412 
 * This feature is used during insert by right rotation.
413 
 *
414 
 * @param node B-tree node into wich the new key is to be inserted.
415 
 * @param key The key to be inserted.
416 
 * @param value Pointer to value to be inserted.
417 
 * @param lsubtree Pointer to the left subtree.
418 
 */
1177 jermar 419 
void node_insert_key_and_lsubtree(btree_node_t *node, btree_key_t key, void *value, btree_node_t *lsubtree)
1136 jermar 420 
{
421 
    int i;
422 
 
423 
    for (i = 0; i < node->keys; i++) {
424 
        if (key < node->key[i]) {
425 
            int j;
426 
 
427 
            for (j = node->keys; j > i; j--) {
428 
                node->key[j] = node->key[j - 1];
429 
                node->value[j] = node->value[j - 1];
430 
                node->subtree[j + 1] = node->subtree[j];
431 
            }
432 
            node->subtree[j + 1] = node->subtree[j];
433 
            break; 
434 
        }
435 
    }
436 
    node->key[i] = key;
437 
    node->value[i] = value;
438 
    node->subtree[i] = lsubtree;
439 
 
440 
    node->keys++;
441 
}
442 
 
443 
/** Insert key-value-rsubtree triplet into B-tree node.
444 
 *
445 
 * It is actually possible to have more keys than BTREE_MAX_KEYS.
1101 jermar 446 
 * This feature is used during splitting the node when the
1136 jermar 447 
 * number of keys is BTREE_MAX_KEYS + 1. Insert by left rotation
448 
 * also makes use of this feature.
1101 jermar 449 
 *
450 
 * @param node B-tree node into wich the new key is to be inserted.
451 
 * @param key The key to be inserted.
452 
 * @param value Pointer to value to be inserted.
453 
 * @param rsubtree Pointer to the right subtree.
454 
 */
1177 jermar 455 
void node_insert_key_and_rsubtree(btree_node_t *node, btree_key_t key, void *value, btree_node_t *rsubtree)
1101 jermar 456 
{
457 
    int i;
458 
 
459 
    for (i = 0; i < node->keys; i++) {
460 
        if (key < node->key[i]) {
461 
            int j;
462 
 
463 
            for (j = node->keys; j > i; j--) {
464 
                node->key[j] = node->key[j - 1];
465 
                node->value[j] = node->value[j - 1];
466 
                node->subtree[j + 1] = node->subtree[j];
467 
            }
468 
            break; 
469 
        }
470 
    }
471 
    node->key[i] = key;
472 
    node->value[i] = value;
473 
    node->subtree[i + 1] = rsubtree;
474 
 
475 
    node->keys++;
476 
}
477 
 
1144 jermar 478 
/** Remove key and its left subtree pointer from B-tree node.
479 
 *
480 
 * Remove the key and eliminate gaps in node->key array.
481 
 * Note that the value pointer and the left subtree pointer
482 
 * is removed from the node as well.
483 
 *
484 
 * @param node B-tree node.
485 
 * @param key Key to be removed.
486 
 */
1177 jermar 487 
void node_remove_key_and_lsubtree(btree_node_t *node, btree_key_t key)
1144 jermar 488 
{
489 
    int i, j;
490 
 
491 
    for (i = 0; i < node->keys; i++) {
492 
        if (key == node->key[i]) {
493 
            for (j = i + 1; j < node->keys; j++) {
494 
                node->key[j - 1] = node->key[j];
495 
                node->value[j - 1] = node->value[j];
496 
                node->subtree[j - 1] = node->subtree[j];
497 
            }
498 
            node->subtree[j - 1] = node->subtree[j];
499 
            node->keys--;
500 
            return;
501 
        }
502 
    }
503 
    panic("node %P does not contain key %d\n", node, key);
504 
}
505 
 
506 
/** Remove key and its right subtree pointer from B-tree node.
507 
 *
508 
 * Remove the key and eliminate gaps in node->key array.
509 
 * Note that the value pointer and the right subtree pointer
510 
 * is removed from the node as well.
511 
 *
512 
 * @param node B-tree node.
513 
 * @param key Key to be removed.
514 
 */
1177 jermar 515 
void node_remove_key_and_rsubtree(btree_node_t *node, btree_key_t key)
1144 jermar 516 
{
517 
    int i, j;
518 
 
519 
    for (i = 0; i < node->keys; i++) {
520 
        if (key == node->key[i]) {
521 
            for (j = i + 1; j < node->keys; j++) {
522 
                node->key[j - 1] = node->key[j];
523 
                node->value[j - 1] = node->value[j];
524 
                node->subtree[j] = node->subtree[j + 1];
525 
            }
526 
            node->keys--;
527 
            return;
528 
        }
529 
    }
530 
    panic("node %P does not contain key %d\n", node, key);
531 
}
532 
 
1134 jermar 533 
/** Split full B-tree node and insert new key-value-right-subtree triplet.
1101 jermar 534 
 *
535 
 * This function will split a node and return pointer to a newly created
1134 jermar 536 
 * node containing keys greater than or equal to the greater of medians
537 
 * (or median) of the old keys and the newly added key. It will also write
538 
 * the median key to a memory address supplied by the caller.
1101 jermar 539 
 *
1134 jermar 540 
 * If the node being split is an index node, the median will not be
541 
 * included in the new node. If the node is a leaf node,
542 
 * the median will be copied there.
1101 jermar 543 
 *
544 
 * @param node B-tree node wich is going to be split.
545 
 * @param key The key to be inserted.
546 
 * @param value Pointer to the value to be inserted.
547 
 * @param rsubtree Pointer to the right subtree of the key being added.
548 
 * @param median Address in memory, where the median key will be stored.
549 
 *
550 
 * @return Newly created right sibling of node.
551 
 */
1177 jermar 552 
btree_node_t *node_split(btree_node_t *node, btree_key_t key, void *value, btree_node_t *rsubtree, btree_key_t *median)
1101 jermar 553 
{
554 
    btree_node_t *rnode;
555 
    int i, j;
556 
 
557 
    ASSERT(median);
558 
    ASSERT(node->keys == BTREE_MAX_KEYS);
1136 jermar 559 
 
1101 jermar 560 
    /*
561 
     * Use the extra space to store the extra node.
562 
     */
1142 jermar 563 
    node_insert_key_and_rsubtree(node, key, value, rsubtree);
1101 jermar 564 
 
565 
    /*
566 
     * Compute median of keys.
567 
     */
1134 jermar 568 
    *median = MEDIAN_HIGH(node);
1101 jermar 569 
 
1134 jermar 570 
    /*
571 
     * Allocate and initialize new right sibling.
572 
     */
1164 jermar 573 
    rnode = (btree_node_t *) slab_alloc(btree_node_slab, 0);
1101 jermar 574 
    node_initialize(rnode);
575 
    rnode->parent = node->parent;
576 
    rnode->depth = node->depth;
577 
 
578 
    /*
579 
     * Copy big keys, values and subtree pointers to the new right sibling.
1134 jermar 580 
     * If this is an index node, do not copy the median.
1101 jermar 581 
     */
1134 jermar 582 
    i = (int) INDEX_NODE(node);
583 
    for (i += MEDIAN_HIGH_INDEX(node), j = 0; i < node->keys; i++, j++) {
1101 jermar 584 
        rnode->key[j] = node->key[i];
585 
        rnode->value[j] = node->value[i];
586 
        rnode->subtree[j] = node->subtree[i];
587 
 
588 
        /*
589 
         * Fix parent links in subtrees.
590 
         */
591 
        if (rnode->subtree[j])
592 
            rnode->subtree[j]->parent = rnode;
593 
 
594 
    }
595 
    rnode->subtree[j] = node->subtree[i];
596 
    if (rnode->subtree[j])
597 
        rnode->subtree[j]->parent = rnode;
1134 jermar 598 
 
599 
    rnode->keys = j;    /* Set number of keys of the new node. */
600 
    node->keys /= 2;    /* Shrink the old node. */
1101 jermar 601 
 
602 
    return rnode;
603 
}
604 
 
1142 jermar 605 
/** Combine node with any of its siblings.
606 
 *
607 
 * The siblings are required to be below the fill factor.
608 
 *
609 
 * @param node Node to combine with one of its siblings.
610 
 *
611 
 * @return Pointer to the rightmost of the two nodes.
612 
 */
613 
btree_node_t *node_combine(btree_node_t *node)
614 
{
615 
    index_t idx;
616 
    btree_node_t *rnode;
617 
    int i;
618 
 
619 
    ASSERT(!ROOT_NODE(node));
620 
 
621 
    idx = find_key_by_subtree(node->parent, node, false);
622 
    if (idx == node->parent->keys) {
623 
        /*
624 
         * Rightmost subtree of its parent, combine with the left sibling.
625 
         */
626 
        idx--;
627 
        rnode = node;
628 
        node = node->parent->subtree[idx];
629 
    } else {
630 
        rnode = node->parent->subtree[idx + 1];
631 
    }
632 
 
633 
    /* Index nodes need to insert parent node key in between left and right node. */
634 
    if (INDEX_NODE(node))
635 
        node->key[node->keys++] = node->parent->key[idx];
636 
 
637 
    /* Copy the key-value-subtree triplets from the right node. */
638 
    for (i = 0; i < rnode->keys; i++) {
639 
        node->key[node->keys + i] = rnode->key[i];
640 
        node->value[node->keys + i] = rnode->value[i];
641 
        if (INDEX_NODE(node)) {
642 
            node->subtree[node->keys + i] = rnode->subtree[i];
643 
            rnode->subtree[i]->parent = node;
644 
        }
645 
    }
646 
    if (INDEX_NODE(node)) {
647 
        node->subtree[node->keys + i] = rnode->subtree[i];
648 
        rnode->subtree[i]->parent = node;
649 
    }
650 
 
651 
    node->keys += rnode->keys;
652 
 
653 
    return rnode;
654 
}
655 
 
1136 jermar 656 
/** Find key by its left or right subtree.
657 
 *
658 
 * @param node B-tree node.
659 
 * @param subtree Left or right subtree of a key found in node.
660 
 * @param right If true, subtree is a right subtree. If false, subtree is a left subtree.
661 
 *
662 
 * @return Index of the key associated with the subtree.
663 
 */
664 
index_t find_key_by_subtree(btree_node_t *node, btree_node_t *subtree, bool right)
665 
{
666 
    int i;
667 
 
668 
    for (i = 0; i < node->keys + 1; i++) {
669 
        if (subtree == node->subtree[i])
670 
            return i - (int) (right != false);
671 
    }
672 
    panic("node %P does not contain subtree %P\n", node, subtree);
673 
}
674 
 
1142 jermar 675 
/** Rotate one key-value-rsubtree triplet from the left sibling to the right sibling.
676 
 *
677 
 * The biggest key and its value and right subtree is rotated from the left node
678 
 * to the right. If the node is an index node, than the parent node key belonging to
679 
 * the left node takes part in the rotation.
680 
 *
681 
 * @param lnode Left sibling.
682 
 * @param rnode Right sibling.
683 
 * @param idx Index of the parent node key that is taking part in the rotation.
684 
 */
685 
void rotate_from_left(btree_node_t *lnode, btree_node_t *rnode, index_t idx)
686 
{
1177 jermar 687 
    btree_key_t key;
1142 jermar 688 
 
689 
    key = lnode->key[lnode->keys - 1];
690 
 
691 
    if (LEAF_NODE(lnode)) {
692 
        void *value;
693 
 
694 
        value = lnode->value[lnode->keys - 1];
695 
        node_remove_key_and_rsubtree(lnode, key);
696 
        node_insert_key_and_lsubtree(rnode, key, value, NULL);
697 
        lnode->parent->key[idx] = key;
698 
    } else {
699 
        btree_node_t *rsubtree;
700 
 
701 
        rsubtree = lnode->subtree[lnode->keys];
702 
        node_remove_key_and_rsubtree(lnode, key);
703 
        node_insert_key_and_lsubtree(rnode, lnode->parent->key[idx], NULL, rsubtree);
704 
        lnode->parent->key[idx] = key;
705 
 
706 
        /* Fix parent link of the reconnected right subtree. */
707 
        rsubtree->parent = rnode;
708 
    }
709 
 
710 
}
711 
 
712 
/** Rotate one key-value-lsubtree triplet from the right sibling to the left sibling.
713 
 *
714 
 * The smallest key and its value and left subtree is rotated from the right node
715 
 * to the left. If the node is an index node, than the parent node key belonging to
716 
 * the right node takes part in the rotation.
717 
 *
718 
 * @param lnode Left sibling.
719 
 * @param rnode Right sibling.
720 
 * @param idx Index of the parent node key that is taking part in the rotation.
721 
 */
722 
void rotate_from_right(btree_node_t *lnode, btree_node_t *rnode, index_t idx)
723 
{
1177 jermar 724 
    btree_key_t key;
1142 jermar 725 
 
726 
    key = rnode->key[0];
727 
 
728 
    if (LEAF_NODE(rnode)) {
729 
        void *value;
730 
 
731 
        value = rnode->value[0];
732 
        node_remove_key_and_lsubtree(rnode, key);
733 
        node_insert_key_and_rsubtree(lnode, key, value, NULL);
734 
        rnode->parent->key[idx] = rnode->key[0];
735 
    } else {
736 
        btree_node_t *lsubtree;
737 
 
738 
        lsubtree = rnode->subtree[0];
739 
        node_remove_key_and_lsubtree(rnode, key);
740 
        node_insert_key_and_rsubtree(lnode, rnode->parent->key[idx], NULL, lsubtree);
741 
        rnode->parent->key[idx] = key;
742 
 
743 
        /* Fix parent link of the reconnected left subtree. */
744 
        lsubtree->parent = lnode;
745 
    }
746 
 
747 
}
748 
 
1136 jermar 749 
/** Insert key-value-rsubtree triplet and rotate the node to the left, if this operation can be done.
750 
 *
751 
 * Left sibling of the node (if it exists) is checked for free space.
752 
 * If there is free space, the key is inserted and the smallest key of
753 
 * the node is moved there. The index node which is the parent of both
754 
 * nodes is fixed.
755 
 *
756 
 * @param node B-tree node.
757 
 * @param inskey Key to be inserted.
758 
 * @param insvalue Value to be inserted.
759 
 * @param rsubtree Right subtree of inskey.
760 
 *
761 
 * @return True if the rotation was performed, false otherwise.
762 
 */
1177 jermar 763 
bool try_insert_by_rotation_to_left(btree_node_t *node, btree_key_t inskey, void *insvalue, btree_node_t *rsubtree)
1136 jermar 764 
{
765 
    index_t idx;
766 
    btree_node_t *lnode;
767 
 
768 
    /*
769 
     * If this is root node, the rotation can not be done.
770 
     */
771 
    if (ROOT_NODE(node))
772 
        return false;
773 
 
774 
    idx = find_key_by_subtree(node->parent, node, true);
775 
    if ((int) idx == -1) {
776 
        /*
777 
         * If this node is the leftmost subtree of its parent,
778 
         * the rotation can not be done.
779 
         */
780 
        return false;
781 
    }
782 
 
783 
    lnode = node->parent->subtree[idx];
784 
    if (lnode->keys < BTREE_MAX_KEYS) {
785 
        /*
786 
         * The rotaion can be done. The left sibling has free space.
787 
         */
1142 jermar 788 
        node_insert_key_and_rsubtree(node, inskey, insvalue, rsubtree);
789 
        rotate_from_right(lnode, node, idx);
1136 jermar 790 
        return true;
791 
    }
792 
 
793 
    return false;
794 
}
795 
 
796 
/** Insert key-value-rsubtree triplet and rotate the node to the right, if this operation can be done.
797 
 *
798 
 * Right sibling of the node (if it exists) is checked for free space.
799 
 * If there is free space, the key is inserted and the biggest key of
800 
 * the node is moved there. The index node which is the parent of both
801 
 * nodes is fixed.
802 
 *
803 
 * @param node B-tree node.
804 
 * @param inskey Key to be inserted.
805 
 * @param insvalue Value to be inserted.
806 
 * @param rsubtree Right subtree of inskey.
807 
 *
808 
 * @return True if the rotation was performed, false otherwise.
809 
 */
1177 jermar 810 
bool try_insert_by_rotation_to_right(btree_node_t *node, btree_key_t inskey, void *insvalue, btree_node_t *rsubtree)
1136 jermar 811 
{
812 
    index_t idx;
813 
    btree_node_t *rnode;
814 
 
815 
    /*
816 
     * If this is root node, the rotation can not be done.
817 
     */
818 
    if (ROOT_NODE(node))
819 
        return false;
820 
 
821 
    idx = find_key_by_subtree(node->parent, node, false);
822 
    if (idx == node->parent->keys) {
823 
        /*
824 
         * If this node is the rightmost subtree of its parent,
825 
         * the rotation can not be done.
826 
         */
827 
        return false;
828 
    }
829 
 
830 
    rnode = node->parent->subtree[idx + 1];
831 
    if (rnode->keys < BTREE_MAX_KEYS) {
832 
        /*
833 
         * The rotaion can be done. The right sibling has free space.
834 
         */
1142 jermar 835 
        node_insert_key_and_rsubtree(node, inskey, insvalue, rsubtree);
836 
        rotate_from_left(node, rnode, idx);
837 
        return true;
838 
    }
1136 jermar 839 
 
1142 jermar 840 
    return false;
841 
}
1136 jermar 842 
 
1142 jermar 843 
/** Rotate in a key from the left sibling or from the index node, if this operation can be done.
844 
 *
845 
 * @param rnode Node into which to add key from its left sibling or from the index node.
846 
 *
847 
 * @return True if the rotation was performed, false otherwise.
848 
 */
849 
bool try_rotation_from_left(btree_node_t *rnode)
850 
{
851 
    index_t idx;
852 
    btree_node_t *lnode;
1136 jermar 853 
 
1142 jermar 854 
    /*
855 
     * If this is root node, the rotation can not be done.
856 
     */
857 
    if (ROOT_NODE(rnode))
858 
        return false;
859 
 
860 
    idx = find_key_by_subtree(rnode->parent, rnode, true);
861 
    if ((int) idx == -1) {
862 
        /*
863 
         * If this node is the leftmost subtree of its parent,
864 
         * the rotation can not be done.
865 
         */
866 
        return false;
867 
    }
868 
 
869 
    lnode = rnode->parent->subtree[idx];
870 
    if (lnode->keys > FILL_FACTOR) {
871 
        rotate_from_left(lnode, rnode, idx);
1136 jermar 872 
        return true;
873 
    }
1142 jermar 874 
 
875 
    return false;
876 
}
1136 jermar 877 
 
1142 jermar 878 
/** Rotate in a key from the right sibling or from the index node, if this operation can be done.
879 
 *
880 
 * @param rnode Node into which to add key from its right sibling or from the index node.
881 
 *
882 
 * @return True if the rotation was performed, false otherwise.
883 
 */
884 
bool try_rotation_from_right(btree_node_t *lnode)
885 
{
886 
    index_t idx;
887 
    btree_node_t *rnode;
888 
 
889 
    /*
890 
     * If this is root node, the rotation can not be done.
891 
     */
892 
    if (ROOT_NODE(lnode))
893 
        return false;
894 
 
895 
    idx = find_key_by_subtree(lnode->parent, lnode, false);
896 
    if (idx == lnode->parent->keys) {
897 
        /*
898 
         * If this node is the rightmost subtree of its parent,
899 
         * the rotation can not be done.
900 
         */
901 
        return false;
902 
    }
903 
 
904 
    rnode = lnode->parent->subtree[idx + 1];
905 
    if (rnode->keys > FILL_FACTOR) {
906 
        rotate_from_right(lnode, rnode, idx);
907 
        return true;
908 
    }  
909 
 
1136 jermar 910 
    return false;
911 
}
912 
 
1101 jermar 913 
/** Print B-tree.
914 
 *
915 
 * @param t Print out B-tree.
916 
 */
917 
void btree_print(btree_t *t)
918 
{
919 
    int i, depth = t->root->depth;
1144 jermar 920 
    link_t head, *cur;
921 
 
922 
    printf("Printing B-tree:\n");
1101 jermar 923 
    list_initialize(&head);
924 
    list_append(&t->root->bfs_link, &head);
925 
 
926 
    /*
927 
     * Use BFS search to print out the tree.
928 
     * Levels are distinguished from one another by node->depth.
929 
     */
930 
    while (!list_empty(&head)) {
931 
        link_t *hlp;
932 
        btree_node_t *node;
933 
 
934 
        hlp = head.next;
935 
        ASSERT(hlp != &head);
936 
        node = list_get_instance(hlp, btree_node_t, bfs_link);
937 
        list_remove(hlp);
938 
 
939 
        ASSERT(node);
940 
 
941 
        if (node->depth != depth) {
942 
            printf("\n");
943 
            depth = node->depth;
944 
        }
945 
 
946 
        printf("(");
947 
        for (i = 0; i < node->keys; i++) {
1196 cejka 948 
            printf("%lld%s", node->key[i], i < node->keys - 1 ? "," : "");
1101 jermar 949 
            if (node->depth && node->subtree[i]) {
950 
                list_append(&node->subtree[i]->bfs_link, &head);
951 
            }
952 
        }
953 
        if (node->depth && node->subtree[i]) {
954 
            list_append(&node->subtree[i]->bfs_link, &head);
955 
        }
956 
        printf(")");
957 
    }
958 
    printf("\n");
1144 jermar 959 
 
960 
    printf("Printing list of leaves:\n");
961 
    for (cur = t->leaf_head.next; cur != &t->leaf_head; cur = cur->next) {
962 
        btree_node_t *node;
963 
 
964 
        node = list_get_instance(cur, btree_node_t, leaf_link);
965 
 
966 
        ASSERT(node);
967 
 
968 
        printf("(");
969 
        for (i = 0; i < node->keys; i++)
1196 cejka 970 
            printf("%lld%s", node->key[i], i < node->keys - 1 ? "," : "");
1144 jermar 971 
        printf(")");
972 
    }
973 
    printf("\n");
1101 jermar 974 
}