WebSVN – HelenOS-historic – Blame – /kernel/trunk/generic/src/adt/btree.c

Rev	Author	Line No.	Line
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
1248	jermar	29	/**
		30	* @file btree.c
		31	* @brief B+tree implementation.
1101	jermar	32	*
1248	jermar	33	* This file implements B+tree type and operations.
		34	*
		35	* The B+tree has the following properties:
		36	* @li it is a ballanced 3-4-5 tree (i.e. BTREE_M = 5)
		37	* @li values (i.e. pointers to values) are stored only in leaves
		38	* @li leaves are linked in a list
		39	*
1134	jermar	40	* Be carefull when using these trees. They need to allocate
		41	* and deallocate memory for their index nodes and as such
		42	* can sleep.
1101	jermar	43	*/
		44
		45	#include <adt/btree.h>
		46	#include <adt/list.h>
		47	#include <mm/slab.h>
		48	#include <debug.h>
		49	#include <panic.h>
		50	#include <typedefs.h>
		51	#include <print.h>
		52
1483	jermar	53	static void btree_destroy_subtree(btree_node_t *root);
1177	jermar	54	static void _btree_insert(btree_t t, btree_key_t key, void value, btree_node_t rsubtree, btree_node_t node);
		55	static void _btree_remove(btree_t t, btree_key_t key, btree_node_t node);
1101	jermar	56	static void node_initialize(btree_node_t *node);
1177	jermar	57	static void node_insert_key_and_lsubtree(btree_node_t node, btree_key_t key, void value, btree_node_t *lsubtree);
		58	static void node_insert_key_and_rsubtree(btree_node_t node, btree_key_t key, void value, btree_node_t *rsubtree);
		59	static void node_remove_key_and_lsubtree(btree_node_t *node, btree_key_t key);
		60	static void node_remove_key_and_rsubtree(btree_node_t *node, btree_key_t key);
		61	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	62	static btree_node_t node_combine(btree_node_t node);
1136	jermar	63	static index_t find_key_by_subtree(btree_node_t node, btree_node_t subtree, bool right);
1142	jermar	64	static void rotate_from_right(btree_node_t lnode, btree_node_t rnode, index_t idx);
		65	static void rotate_from_left(btree_node_t lnode, btree_node_t rnode, index_t idx);
1177	jermar	66	static bool try_insert_by_rotation_to_left(btree_node_t node, btree_key_t key, void value, btree_node_t *rsubtree);
		67	static bool try_insert_by_rotation_to_right(btree_node_t node, btree_key_t key, void value, btree_node_t *rsubtree);
1142	jermar	68	static bool try_rotation_from_left(btree_node_t *rnode);
		69	static bool try_rotation_from_right(btree_node_t *lnode);
1101	jermar	70
		71	#define ROOT_NODE(n) (!(n)->parent)
		72	#define INDEX_NODE(n) ((n)->subtree[0] != NULL)
		73	#define LEAF_NODE(n) ((n)->subtree[0] == NULL)
		74
1140	jermar	75	#define FILL_FACTOR ((BTREE_M-1)/2)
		76
1101	jermar	77	#define MEDIAN_LOW_INDEX(n) (((n)->keys-1)/2)
		78	#define MEDIAN_HIGH_INDEX(n) ((n)->keys/2)
		79	#define MEDIAN_LOW(n) ((n)->key[MEDIAN_LOW_INDEX((n))]);
		80	#define MEDIAN_HIGH(n) ((n)->key[MEDIAN_HIGH_INDEX((n))]);
		81
1164	jermar	82	static slab_cache_t *btree_node_slab;
		83
		84	/** Initialize B-trees. */
		85	void btree_init(void)
		86	{
		87	btree_node_slab = slab_cache_create("btree_node_slab", sizeof(btree_node_t), 0, NULL, NULL, SLAB_CACHE_MAGDEFERRED);
		88	}
		89
1101	jermar	90	/** Create empty B-tree.
		91	*
		92	* @param t B-tree.
		93	*/
		94	void btree_create(btree_t *t)
		95	{
		96	list_initialize(&t->leaf_head);
1164	jermar	97	t->root = (btree_node_t *) slab_alloc(btree_node_slab, 0);
1101	jermar	98	node_initialize(t->root);
		99	list_append(&t->root->leaf_link, &t->leaf_head);
		100	}
		101
		102	/** Destroy empty B-tree. */
		103	void btree_destroy(btree_t *t)
		104	{
1483	jermar	105	btree_destroy_subtree(t->root);
1101	jermar	106	}
		107
		108	/** Insert key-value pair into B-tree.
		109	*
		110	* @param t B-tree.
		111	* @param key Key to be inserted.
		112	* @param value Value to be inserted.
		113	* @param leaf_node Leaf node where the insertion should begin.
		114	*/
1177	jermar	115	void btree_insert(btree_t t, btree_key_t key, void value, btree_node_t *leaf_node)
1101	jermar	116	{
		117	btree_node_t *lnode;
		118
		119	ASSERT(value);
		120
		121	lnode = leaf_node;
		122	if (!lnode) {
		123	if (btree_search(t, key, &lnode)) {
1221	decky	124	panic("B-tree %p already contains key %d\n", t, key);
1101	jermar	125	}
		126	}
		127
		128	_btree_insert(t, key, value, NULL, lnode);
		129	}
		130
1483	jermar	131	/** Destroy subtree rooted in a node.
		132	*
		133	* @param root Root of the subtree.
		134	*/
		135	void btree_destroy_subtree(btree_node_t *root)
		136	{
		137	int i;
		138
		139	if (root->keys) {
		140	for (i = 0; i < root->keys + 1; i++) {
		141	if (root->subtree[i])
		142	btree_destroy_subtree(root->subtree[i]);
		143	}
		144	}
		145	slab_free(btree_node_slab, root);
		146	}
		147
1101	jermar	148	/** Recursively insert into B-tree.
		149	*
		150	* @param t B-tree.
		151	* @param key Key to be inserted.
		152	* @param value Value to be inserted.
		153	* @param rsubtree Right subtree of the inserted key.
		154	* @param node Start inserting into this node.
		155	*/
1177	jermar	156	void _btree_insert(btree_t t, btree_key_t key, void value, btree_node_t rsubtree, btree_node_t node)
1101	jermar	157	{
		158	if (node->keys < BTREE_MAX_KEYS) {
		159	/*
		160	* Node conatins enough space, the key can be stored immediately.
		161	*/
1142	jermar	162	node_insert_key_and_rsubtree(node, key, value, rsubtree);
		163	} else if (try_insert_by_rotation_to_left(node, key, value, rsubtree)) {
1136	jermar	164	/*
		165	* The key-value-rsubtree triplet has been inserted because
		166	* some keys could have been moved to the left sibling.
		167	*/
1142	jermar	168	} else if (try_insert_by_rotation_to_right(node, key, value, rsubtree)) {
1136	jermar	169	/*
		170	* The key-value-rsubtree triplet has been inserted because
		171	* some keys could have been moved to the right sibling.
		172	*/
1101	jermar	173	} else {
		174	btree_node_t *rnode;
1177	jermar	175	btree_key_t median;
1101	jermar	176
		177	/*
1136	jermar	178	* Node is full and both siblings (if both exist) are full too.
		179	* Split the node and insert the smallest key from the node containing
		180	* bigger keys (i.e. the new node) into its parent.
1101	jermar	181	*/
		182
		183	rnode = node_split(node, key, value, rsubtree, &median);
		184
		185	if (LEAF_NODE(node)) {
1144	jermar	186	list_prepend(&rnode->leaf_link, &node->leaf_link);
1101	jermar	187	}
		188
		189	if (ROOT_NODE(node)) {
		190	/*
		191	* We split the root node. Create new root.
		192	*/
1164	jermar	193	t->root = (btree_node_t *) slab_alloc(btree_node_slab, 0);
1101	jermar	194	node->parent = t->root;
		195	rnode->parent = t->root;
		196	node_initialize(t->root);
		197
		198	/*
		199	* Left-hand side subtree will be the old root (i.e. node).
		200	* Right-hand side subtree will be rnode.
		201	*/
		202	t->root->subtree[0] = node;
		203
		204	t->root->depth = node->depth + 1;
		205	}
		206	_btree_insert(t, median, NULL, rnode, node->parent);
		207	}
		208
		209	}
		210
1140	jermar	211	/** Remove B-tree node.
		212	*
		213	* @param B-tree.
		214	* @param key Key to be removed from the B-tree along with its associated value.
		215	* @param leaf_node If not NULL, pointer to the leaf node where the key is found.
		216	*/
1177	jermar	217	void btree_remove(btree_t t, btree_key_t key, btree_node_t leaf_node)
1101	jermar	218	{
1140	jermar	219	btree_node_t *lnode;
		220
		221	lnode = leaf_node;
		222	if (!lnode) {
		223	if (!btree_search(t, key, &lnode)) {
1221	decky	224	panic("B-tree %p does not contain key %d\n", t, key);
1140	jermar	225	}
		226	}
		227
1142	jermar	228	_btree_remove(t, key, lnode);
		229	}
1140	jermar	230
1142	jermar	231	/** Recursively remove B-tree node.
		232	*
		233	* @param B-tree.
		234	* @param key Key to be removed from the B-tree along with its associated value.
		235	* @param node Node where the key being removed resides.
		236	*/
1177	jermar	237	void _btree_remove(btree_t t, btree_key_t key, btree_node_t node)
1142	jermar	238	{
		239	if (ROOT_NODE(node)) {
		240	if (node->keys == 1 && node->subtree[0]) {
		241	/*
		242	* Free the current root and set new root.
		243	*/
		244	t->root = node->subtree[0];
		245	t->root->parent = NULL;
1164	jermar	246	slab_free(btree_node_slab, node);
1142	jermar	247	} else {
		248	/*
		249	* Remove the key from the root node.
		250	* Note that the right subtree is removed because when
		251	* combining two nodes, the left-side sibling is preserved
		252	* and the right-side sibling is freed.
		253	*/
		254	node_remove_key_and_rsubtree(node, key);
		255	}
		256	return;
		257	}
		258
		259	if (node->keys <= FILL_FACTOR) {
		260	/*
		261	* If the node is below the fill factor,
		262	* try to borrow keys from left or right sibling.
		263	*/
		264	if (!try_rotation_from_left(node))
		265	try_rotation_from_right(node);
		266	}
		267
		268	if (node->keys > FILL_FACTOR) {
		269	int i;
		270
		271	/*
		272	* The key can be immediatelly removed.
		273	*
		274	* Note that the right subtree is removed because when
		275	* combining two nodes, the left-side sibling is preserved
		276	* and the right-side sibling is freed.
		277	*/
		278	node_remove_key_and_rsubtree(node, key);
		279	for (i = 0; i < node->parent->keys; i++) {
		280	if (node->parent->key[i] == key)
		281	node->parent->key[i] = node->key[0];
		282	}
		283
		284	} else {
		285	index_t idx;
		286	btree_node_t rnode, parent;
		287
		288	/*
		289	* The node is below the fill factor as well as its left and right sibling.
		290	* Resort to combining the node with one of its siblings.
		291	* The node which is on the left is preserved and the node on the right is
		292	* freed.
		293	*/
		294	parent = node->parent;
		295	node_remove_key_and_rsubtree(node, key);
		296	rnode = node_combine(node);
		297	if (LEAF_NODE(rnode))
		298	list_remove(&rnode->leaf_link);
		299	idx = find_key_by_subtree(parent, rnode, true);
		300	ASSERT((int) idx != -1);
1164	jermar	301	slab_free(btree_node_slab, rnode);
1142	jermar	302	_btree_remove(t, parent->key[idx], parent);
		303	}
1101	jermar	304	}
		305
		306	/** Search key in a B-tree.
		307	*
		308	* @param t B-tree.
		309	* @param key Key to be searched.
		310	* @param leaf_node Address where to put pointer to visited leaf node.
		311	*
		312	* @return Pointer to value or NULL if there is no such key.
		313	*/
1177	jermar	314	void btree_search(btree_t t, btree_key_t key, btree_node_t **leaf_node)
1101	jermar	315	{
		316	btree_node_t cur, next;
		317
		318	/*
1134	jermar	319	* Iteratively descend to the leaf that can contain the searched key.
1101	jermar	320	*/
		321	for (cur = t->root; cur; cur = next) {
1134	jermar	322
1101	jermar	323	/* Last iteration will set this with proper leaf node address. */
		324	*leaf_node = cur;
1134	jermar	325
		326	/*
		327	* The key can be in the leftmost subtree.
		328	* Test it separately.
		329	*/
		330	if (key < cur->key[0]) {
		331	next = cur->subtree[0];
		332	continue;
		333	} else {
		334	void *val;
		335	int i;
		336
		337	/*
		338	* Now if the key is smaller than cur->key[i]
		339	* it can only mean that the value is in cur->subtree[i]
		340	* or it is not in the tree at all.
		341	*/
		342	for (i = 1; i < cur->keys; i++) {
		343	if (key < cur->key[i]) {
		344	next = cur->subtree[i];
		345	val = cur->value[i - 1];
		346
		347	if (LEAF_NODE(cur))
		348	return key == cur->key[i - 1] ? val : NULL;
		349
		350	goto descend;
		351	}
1101	jermar	352	}
1134	jermar	353
		354	/*
		355	* Last possibility is that the key is in the rightmost subtree.
		356	*/
		357	next = cur->subtree[i];
		358	val = cur->value[i - 1];
		359	if (LEAF_NODE(cur))
		360	return key == cur->key[i - 1] ? val : NULL;
1101	jermar	361	}
1134	jermar	362	descend:
		363	;
1101	jermar	364	}
		365
		366	/*
1134	jermar	367	* The key was not found in the *leaf_node and is smaller than any of its keys.
1101	jermar	368	*/
		369	return NULL;
		370	}
		371
1150	jermar	372	/** Return pointer to B-tree leaf node's left neighbour.
1147	jermar	373	*
		374	* @param t B-tree.
1150	jermar	375	* @param node Node whose left neighbour will be returned.
1147	jermar	376	*
1150	jermar	377	* @return Left neighbour of the node or NULL if the node does not have the left neighbour.
1147	jermar	378	*/
1150	jermar	379	btree_node_t btree_leaf_node_left_neighbour(btree_t t, btree_node_t *node)
1147	jermar	380	{
		381	ASSERT(LEAF_NODE(node));
		382	if (node->leaf_link.prev != &t->leaf_head)
		383	return list_get_instance(node->leaf_link.prev, btree_node_t, leaf_link);
		384	else
		385	return NULL;
		386	}
		387
1150	jermar	388	/** Return pointer to B-tree leaf node's right neighbour.
1147	jermar	389	*
		390	* @param t B-tree.
1150	jermar	391	* @param node Node whose right neighbour will be returned.
1147	jermar	392	*
1150	jermar	393	* @return Right neighbour of the node or NULL if the node does not have the right neighbour.
1147	jermar	394	*/
1150	jermar	395	btree_node_t btree_leaf_node_right_neighbour(btree_t t, btree_node_t *node)
1147	jermar	396	{
		397	ASSERT(LEAF_NODE(node));
		398	if (node->leaf_link.next != &t->leaf_head)
		399	return list_get_instance(node->leaf_link.next, btree_node_t, leaf_link);
		400	else
		401	return NULL;
		402	}
		403
1101	jermar	404	/** Initialize B-tree node.
		405	*
		406	* @param node B-tree node.
		407	*/
		408	void node_initialize(btree_node_t *node)
		409	{
		410	int i;
		411
		412	node->keys = 0;
		413
		414	/* Clean also space for the extra key. */
		415	for (i = 0; i < BTREE_MAX_KEYS + 1; i++) {
		416	node->key[i] = 0;
		417	node->value[i] = NULL;
		418	node->subtree[i] = NULL;
		419	}
		420	node->subtree[i] = NULL;
		421
		422	node->parent = NULL;
		423
		424	link_initialize(&node->leaf_link);
		425
		426	link_initialize(&node->bfs_link);
		427	node->depth = 0;
		428	}
		429
1136	jermar	430	/** Insert key-value-lsubtree triplet into B-tree node.
1101	jermar	431	*
		432	* It is actually possible to have more keys than BTREE_MAX_KEYS.
1136	jermar	433	* This feature is used during insert by right rotation.
		434	*
		435	* @param node B-tree node into wich the new key is to be inserted.
		436	* @param key The key to be inserted.
		437	* @param value Pointer to value to be inserted.
		438	* @param lsubtree Pointer to the left subtree.
		439	*/
1177	jermar	440	void node_insert_key_and_lsubtree(btree_node_t node, btree_key_t key, void value, btree_node_t *lsubtree)
1136	jermar	441	{
		442	int i;
		443
		444	for (i = 0; i < node->keys; i++) {
		445	if (key < node->key[i]) {
		446	int j;
		447
		448	for (j = node->keys; j > i; j--) {
		449	node->key[j] = node->key[j - 1];
		450	node->value[j] = node->value[j - 1];
		451	node->subtree[j + 1] = node->subtree[j];
		452	}
		453	node->subtree[j + 1] = node->subtree[j];
		454	break;
		455	}
		456	}
		457	node->key[i] = key;
		458	node->value[i] = value;
		459	node->subtree[i] = lsubtree;
		460
		461	node->keys++;
		462	}
		463
		464	/** Insert key-value-rsubtree triplet into B-tree node.
		465	*
		466	* It is actually possible to have more keys than BTREE_MAX_KEYS.
1101	jermar	467	* This feature is used during splitting the node when the
1136	jermar	468	* number of keys is BTREE_MAX_KEYS + 1. Insert by left rotation
		469	* also makes use of this feature.
1101	jermar	470	*
		471	* @param node B-tree node into wich the new key is to be inserted.
		472	* @param key The key to be inserted.
		473	* @param value Pointer to value to be inserted.
		474	* @param rsubtree Pointer to the right subtree.
		475	*/
1177	jermar	476	void node_insert_key_and_rsubtree(btree_node_t node, btree_key_t key, void value, btree_node_t *rsubtree)
1101	jermar	477	{
		478	int i;
		479
		480	for (i = 0; i < node->keys; i++) {
		481	if (key < node->key[i]) {
		482	int j;
		483
		484	for (j = node->keys; j > i; j--) {
		485	node->key[j] = node->key[j - 1];
		486	node->value[j] = node->value[j - 1];
		487	node->subtree[j + 1] = node->subtree[j];
		488	}
		489	break;
		490	}
		491	}
		492	node->key[i] = key;
		493	node->value[i] = value;
		494	node->subtree[i + 1] = rsubtree;
		495
		496	node->keys++;
		497	}
		498
1144	jermar	499	/** Remove key and its left subtree pointer from B-tree node.
		500	*
		501	* Remove the key and eliminate gaps in node->key array.
		502	* Note that the value pointer and the left subtree pointer
		503	* is removed from the node as well.
		504	*
		505	* @param node B-tree node.
		506	* @param key Key to be removed.
		507	*/
1177	jermar	508	void node_remove_key_and_lsubtree(btree_node_t *node, btree_key_t key)
1144	jermar	509	{
		510	int i, j;
		511
		512	for (i = 0; i < node->keys; i++) {
		513	if (key == node->key[i]) {
		514	for (j = i + 1; j < node->keys; j++) {
		515	node->key[j - 1] = node->key[j];
		516	node->value[j - 1] = node->value[j];
		517	node->subtree[j - 1] = node->subtree[j];
		518	}
		519	node->subtree[j - 1] = node->subtree[j];
		520	node->keys--;
		521	return;
		522	}
		523	}
1221	decky	524	panic("node %p does not contain key %d\n", node, key);
1144	jermar	525	}
		526
		527	/** Remove key and its right subtree pointer from B-tree node.
		528	*
		529	* Remove the key and eliminate gaps in node->key array.
		530	* Note that the value pointer and the right subtree pointer
		531	* is removed from the node as well.
		532	*
		533	* @param node B-tree node.
		534	* @param key Key to be removed.
		535	*/
1177	jermar	536	void node_remove_key_and_rsubtree(btree_node_t *node, btree_key_t key)
1144	jermar	537	{
		538	int i, j;
		539
		540	for (i = 0; i < node->keys; i++) {
		541	if (key == node->key[i]) {
		542	for (j = i + 1; j < node->keys; j++) {
		543	node->key[j - 1] = node->key[j];
		544	node->value[j - 1] = node->value[j];
		545	node->subtree[j] = node->subtree[j + 1];
		546	}
		547	node->keys--;
		548	return;
		549	}
		550	}
1221	decky	551	panic("node %p does not contain key %d\n", node, key);
1144	jermar	552	}
		553
1134	jermar	554	/** Split full B-tree node and insert new key-value-right-subtree triplet.
1101	jermar	555	*
		556	* This function will split a node and return pointer to a newly created
1134	jermar	557	* node containing keys greater than or equal to the greater of medians
		558	* (or median) of the old keys and the newly added key. It will also write
		559	* the median key to a memory address supplied by the caller.
1101	jermar	560	*
1134	jermar	561	* If the node being split is an index node, the median will not be
		562	* included in the new node. If the node is a leaf node,
		563	* the median will be copied there.
1101	jermar	564	*
		565	* @param node B-tree node wich is going to be split.
		566	* @param key The key to be inserted.
		567	* @param value Pointer to the value to be inserted.
		568	* @param rsubtree Pointer to the right subtree of the key being added.
		569	* @param median Address in memory, where the median key will be stored.
		570	*
		571	* @return Newly created right sibling of node.
		572	*/
1177	jermar	573	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	574	{
		575	btree_node_t *rnode;
		576	int i, j;
		577
		578	ASSERT(median);
		579	ASSERT(node->keys == BTREE_MAX_KEYS);
1136	jermar	580
1101	jermar	581	/*
		582	* Use the extra space to store the extra node.
		583	*/
1142	jermar	584	node_insert_key_and_rsubtree(node, key, value, rsubtree);
1101	jermar	585
		586	/*
		587	* Compute median of keys.
		588	*/
1134	jermar	589	*median = MEDIAN_HIGH(node);
1101	jermar	590
1134	jermar	591	/*
		592	* Allocate and initialize new right sibling.
		593	*/
1164	jermar	594	rnode = (btree_node_t *) slab_alloc(btree_node_slab, 0);
1101	jermar	595	node_initialize(rnode);
		596	rnode->parent = node->parent;
		597	rnode->depth = node->depth;
		598
		599	/*
		600	* Copy big keys, values and subtree pointers to the new right sibling.
1134	jermar	601	* If this is an index node, do not copy the median.
1101	jermar	602	*/
1134	jermar	603	i = (int) INDEX_NODE(node);
		604	for (i += MEDIAN_HIGH_INDEX(node), j = 0; i < node->keys; i++, j++) {
1101	jermar	605	rnode->key[j] = node->key[i];
		606	rnode->value[j] = node->value[i];
		607	rnode->subtree[j] = node->subtree[i];
		608
		609	/*
		610	* Fix parent links in subtrees.
		611	*/
		612	if (rnode->subtree[j])
		613	rnode->subtree[j]->parent = rnode;
		614
		615	}
		616	rnode->subtree[j] = node->subtree[i];
		617	if (rnode->subtree[j])
		618	rnode->subtree[j]->parent = rnode;
1134	jermar	619
		620	rnode->keys = j; /* Set number of keys of the new node. */
		621	node->keys /= 2; /* Shrink the old node. */
1101	jermar	622
		623	return rnode;
		624	}
		625
1142	jermar	626	/** Combine node with any of its siblings.
		627	*
		628	* The siblings are required to be below the fill factor.
		629	*
		630	* @param node Node to combine with one of its siblings.
		631	*
		632	* @return Pointer to the rightmost of the two nodes.
		633	*/
		634	btree_node_t node_combine(btree_node_t node)
		635	{
		636	index_t idx;
		637	btree_node_t *rnode;
		638	int i;
		639
		640	ASSERT(!ROOT_NODE(node));
		641
		642	idx = find_key_by_subtree(node->parent, node, false);
		643	if (idx == node->parent->keys) {
		644	/*
		645	* Rightmost subtree of its parent, combine with the left sibling.
		646	*/
		647	idx--;
		648	rnode = node;
		649	node = node->parent->subtree[idx];
		650	} else {
		651	rnode = node->parent->subtree[idx + 1];
		652	}
		653
		654	/* Index nodes need to insert parent node key in between left and right node. */
		655	if (INDEX_NODE(node))
		656	node->key[node->keys++] = node->parent->key[idx];
		657
		658	/* Copy the key-value-subtree triplets from the right node. */
		659	for (i = 0; i < rnode->keys; i++) {
		660	node->key[node->keys + i] = rnode->key[i];
		661	node->value[node->keys + i] = rnode->value[i];
		662	if (INDEX_NODE(node)) {
		663	node->subtree[node->keys + i] = rnode->subtree[i];
		664	rnode->subtree[i]->parent = node;
		665	}
		666	}
		667	if (INDEX_NODE(node)) {
		668	node->subtree[node->keys + i] = rnode->subtree[i];
		669	rnode->subtree[i]->parent = node;
		670	}
		671
		672	node->keys += rnode->keys;
		673
		674	return rnode;
		675	}
		676
1136	jermar	677	/** Find key by its left or right subtree.
		678	*
		679	* @param node B-tree node.
		680	* @param subtree Left or right subtree of a key found in node.
		681	* @param right If true, subtree is a right subtree. If false, subtree is a left subtree.
		682	*
		683	* @return Index of the key associated with the subtree.
		684	*/
		685	index_t find_key_by_subtree(btree_node_t node, btree_node_t subtree, bool right)
		686	{
		687	int i;
		688
		689	for (i = 0; i < node->keys + 1; i++) {
		690	if (subtree == node->subtree[i])
		691	return i - (int) (right != false);
		692	}
1221	decky	693	panic("node %p does not contain subtree %p\n", node, subtree);
1136	jermar	694	}
		695
1142	jermar	696	/** Rotate one key-value-rsubtree triplet from the left sibling to the right sibling.
		697	*
		698	* The biggest key and its value and right subtree is rotated from the left node
		699	* to the right. If the node is an index node, than the parent node key belonging to
		700	* the left node takes part in the rotation.
		701	*
		702	* @param lnode Left sibling.
		703	* @param rnode Right sibling.
		704	* @param idx Index of the parent node key that is taking part in the rotation.
		705	*/
		706	void rotate_from_left(btree_node_t lnode, btree_node_t rnode, index_t idx)
		707	{
1177	jermar	708	btree_key_t key;
1142	jermar	709
		710	key = lnode->key[lnode->keys - 1];
		711
		712	if (LEAF_NODE(lnode)) {
		713	void *value;
		714
		715	value = lnode->value[lnode->keys - 1];
		716	node_remove_key_and_rsubtree(lnode, key);
		717	node_insert_key_and_lsubtree(rnode, key, value, NULL);
		718	lnode->parent->key[idx] = key;
		719	} else {
		720	btree_node_t *rsubtree;
		721
		722	rsubtree = lnode->subtree[lnode->keys];
		723	node_remove_key_and_rsubtree(lnode, key);
		724	node_insert_key_and_lsubtree(rnode, lnode->parent->key[idx], NULL, rsubtree);
		725	lnode->parent->key[idx] = key;
		726
		727	/* Fix parent link of the reconnected right subtree. */
		728	rsubtree->parent = rnode;
		729	}
		730
		731	}
		732
		733	/** Rotate one key-value-lsubtree triplet from the right sibling to the left sibling.
		734	*
		735	* The smallest key and its value and left subtree is rotated from the right node
		736	* to the left. If the node is an index node, than the parent node key belonging to
		737	* the right node takes part in the rotation.
		738	*
		739	* @param lnode Left sibling.
		740	* @param rnode Right sibling.
		741	* @param idx Index of the parent node key that is taking part in the rotation.
		742	*/
		743	void rotate_from_right(btree_node_t lnode, btree_node_t rnode, index_t idx)
		744	{
1177	jermar	745	btree_key_t key;
1142	jermar	746
		747	key = rnode->key[0];
		748
		749	if (LEAF_NODE(rnode)) {
		750	void *value;
		751
		752	value = rnode->value[0];
		753	node_remove_key_and_lsubtree(rnode, key);
		754	node_insert_key_and_rsubtree(lnode, key, value, NULL);
		755	rnode->parent->key[idx] = rnode->key[0];
		756	} else {
		757	btree_node_t *lsubtree;
		758
		759	lsubtree = rnode->subtree[0];
		760	node_remove_key_and_lsubtree(rnode, key);
		761	node_insert_key_and_rsubtree(lnode, rnode->parent->key[idx], NULL, lsubtree);
		762	rnode->parent->key[idx] = key;
		763
		764	/* Fix parent link of the reconnected left subtree. */
		765	lsubtree->parent = lnode;
		766	}
		767
		768	}
		769
1136	jermar	770	/** Insert key-value-rsubtree triplet and rotate the node to the left, if this operation can be done.
		771	*
		772	* Left sibling of the node (if it exists) is checked for free space.
		773	* If there is free space, the key is inserted and the smallest key of
		774	* the node is moved there. The index node which is the parent of both
		775	* nodes is fixed.
		776	*
		777	* @param node B-tree node.
		778	* @param inskey Key to be inserted.
		779	* @param insvalue Value to be inserted.
		780	* @param rsubtree Right subtree of inskey.
		781	*
		782	* @return True if the rotation was performed, false otherwise.
		783	*/
1177	jermar	784	bool try_insert_by_rotation_to_left(btree_node_t node, btree_key_t inskey, void insvalue, btree_node_t *rsubtree)
1136	jermar	785	{
		786	index_t idx;
		787	btree_node_t *lnode;
		788
		789	/*
		790	* If this is root node, the rotation can not be done.
		791	*/
		792	if (ROOT_NODE(node))
		793	return false;
		794
		795	idx = find_key_by_subtree(node->parent, node, true);
		796	if ((int) idx == -1) {
		797	/*
		798	* If this node is the leftmost subtree of its parent,
		799	* the rotation can not be done.
		800	*/
		801	return false;
		802	}
		803
		804	lnode = node->parent->subtree[idx];
		805	if (lnode->keys < BTREE_MAX_KEYS) {
		806	/*
		807	* The rotaion can be done. The left sibling has free space.
		808	*/
1142	jermar	809	node_insert_key_and_rsubtree(node, inskey, insvalue, rsubtree);
		810	rotate_from_right(lnode, node, idx);
1136	jermar	811	return true;
		812	}
		813
		814	return false;
		815	}
		816
		817	/** Insert key-value-rsubtree triplet and rotate the node to the right, if this operation can be done.
		818	*
		819	* Right sibling of the node (if it exists) is checked for free space.
		820	* If there is free space, the key is inserted and the biggest key of
		821	* the node is moved there. The index node which is the parent of both
		822	* nodes is fixed.
		823	*
		824	* @param node B-tree node.
		825	* @param inskey Key to be inserted.
		826	* @param insvalue Value to be inserted.
		827	* @param rsubtree Right subtree of inskey.
		828	*
		829	* @return True if the rotation was performed, false otherwise.
		830	*/
1177	jermar	831	bool try_insert_by_rotation_to_right(btree_node_t node, btree_key_t inskey, void insvalue, btree_node_t *rsubtree)
1136	jermar	832	{
		833	index_t idx;
		834	btree_node_t *rnode;
		835
		836	/*
		837	* If this is root node, the rotation can not be done.
		838	*/
		839	if (ROOT_NODE(node))
		840	return false;
		841
		842	idx = find_key_by_subtree(node->parent, node, false);
		843	if (idx == node->parent->keys) {
		844	/*
		845	* If this node is the rightmost subtree of its parent,
		846	* the rotation can not be done.
		847	*/
		848	return false;
		849	}
		850
		851	rnode = node->parent->subtree[idx + 1];
		852	if (rnode->keys < BTREE_MAX_KEYS) {
		853	/*
		854	* The rotaion can be done. The right sibling has free space.
		855	*/
1142	jermar	856	node_insert_key_and_rsubtree(node, inskey, insvalue, rsubtree);
		857	rotate_from_left(node, rnode, idx);
		858	return true;
		859	}
1136	jermar	860
1142	jermar	861	return false;
		862	}
1136	jermar	863
1142	jermar	864	/** Rotate in a key from the left sibling or from the index node, if this operation can be done.
		865	*
		866	* @param rnode Node into which to add key from its left sibling or from the index node.
		867	*
		868	* @return True if the rotation was performed, false otherwise.
		869	*/
		870	bool try_rotation_from_left(btree_node_t *rnode)
		871	{
		872	index_t idx;
		873	btree_node_t *lnode;
1136	jermar	874
1142	jermar	875	/*
		876	* If this is root node, the rotation can not be done.
		877	*/
		878	if (ROOT_NODE(rnode))
		879	return false;
		880
		881	idx = find_key_by_subtree(rnode->parent, rnode, true);
		882	if ((int) idx == -1) {
		883	/*
		884	* If this node is the leftmost subtree of its parent,
		885	* the rotation can not be done.
		886	*/
		887	return false;
		888	}
		889
		890	lnode = rnode->parent->subtree[idx];
		891	if (lnode->keys > FILL_FACTOR) {
		892	rotate_from_left(lnode, rnode, idx);
1136	jermar	893	return true;
		894	}
1142	jermar	895
		896	return false;
		897	}
1136	jermar	898
1142	jermar	899	/** Rotate in a key from the right sibling or from the index node, if this operation can be done.
		900	*
		901	* @param rnode Node into which to add key from its right sibling or from the index node.
		902	*
		903	* @return True if the rotation was performed, false otherwise.
		904	*/
		905	bool try_rotation_from_right(btree_node_t *lnode)
		906	{
		907	index_t idx;
		908	btree_node_t *rnode;
		909
		910	/*
		911	* If this is root node, the rotation can not be done.
		912	*/
		913	if (ROOT_NODE(lnode))
		914	return false;
		915
		916	idx = find_key_by_subtree(lnode->parent, lnode, false);
		917	if (idx == lnode->parent->keys) {
		918	/*
		919	* If this node is the rightmost subtree of its parent,
		920	* the rotation can not be done.
		921	*/
		922	return false;
		923	}
		924
		925	rnode = lnode->parent->subtree[idx + 1];
		926	if (rnode->keys > FILL_FACTOR) {
		927	rotate_from_right(lnode, rnode, idx);
		928	return true;
		929	}
		930
1136	jermar	931	return false;
		932	}
		933
1101	jermar	934	/** Print B-tree.
		935	*
		936	* @param t Print out B-tree.
		937	*/
		938	void btree_print(btree_t *t)
		939	{
		940	int i, depth = t->root->depth;
1144	jermar	941	link_t head, *cur;
		942
		943	printf("Printing B-tree:\n");
1101	jermar	944	list_initialize(&head);
		945	list_append(&t->root->bfs_link, &head);
		946
		947	/*
		948	* Use BFS search to print out the tree.
		949	* Levels are distinguished from one another by node->depth.
		950	*/
		951	while (!list_empty(&head)) {
		952	link_t *hlp;
		953	btree_node_t *node;
		954
		955	hlp = head.next;
		956	ASSERT(hlp != &head);
		957	node = list_get_instance(hlp, btree_node_t, bfs_link);
		958	list_remove(hlp);
		959
		960	ASSERT(node);
		961
		962	if (node->depth != depth) {
		963	printf("\n");
		964	depth = node->depth;
		965	}
		966
		967	printf("(");
		968	for (i = 0; i < node->keys; i++) {
1196	cejka	969	printf("%lld%s", node->key[i], i < node->keys - 1 ? "," : "");
1101	jermar	970	if (node->depth && node->subtree[i]) {
		971	list_append(&node->subtree[i]->bfs_link, &head);
		972	}
		973	}
		974	if (node->depth && node->subtree[i]) {
		975	list_append(&node->subtree[i]->bfs_link, &head);
		976	}
		977	printf(")");
		978	}
		979	printf("\n");
1144	jermar	980
		981	printf("Printing list of leaves:\n");
		982	for (cur = t->leaf_head.next; cur != &t->leaf_head; cur = cur->next) {
		983	btree_node_t *node;
		984
		985	node = list_get_instance(cur, btree_node_t, leaf_link);
		986
		987	ASSERT(node);
		988
		989	printf("(");
		990	for (i = 0; i < node->keys; i++)
1196	cejka	991	printf("%lld%s", node->key[i], i < node->keys - 1 ? "," : "");
1144	jermar	992	printf(")");
		993	}
		994	printf("\n");
1101	jermar	995	}

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(root)/kernel/trunk/generic/src/adt/btree.c @ 1757 – Rev 1483