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NetBSD/sys/lib/libkern/rb.c

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/* $NetBSD: rb.c,v 1.2 2002/10/08 11:58:54 simonb Exp $ */
/*-
* Copyright (c) 2001 The NetBSD Foundation, Inc.
* All rights reserved.
*
* This code is derived from software contributed to The NetBSD Foundation
* by Matt Thomas <matt@3am-software.com>.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions
* are met:
* 1. Redistributions of source code must retain the above copyright
* notice, this list of conditions and the following disclaimer.
* 2. Redistributions in binary form must reproduce the above copyright
* notice, this list of conditions and the following disclaimer in the
* documentation and/or other materials provided with the distribution.
* 3. All advertising materials mentioning features or use of this software
* must display the following acknowledgement:
* This product includes software developed by the NetBSD
* Foundation, Inc. and its contributors.
* 4. Neither the name of The NetBSD Foundation nor the names of its
* contributors may be used to endorse or promote products derived
* from this software without specific prior written permission.
*
* THIS SOFTWARE IS PROVIDED BY THE NETBSD FOUNDATION, INC. AND CONTRIBUTORS
* ``AS IS'' AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED
* TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR
* PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE FOUNDATION OR CONTRIBUTORS
* BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR
* CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF
* SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS
* INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN
* CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE)
* ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE
* POSSIBILITY OF SUCH DAMAGE.
*/
#include <sys/types.h>
#include <stddef.h>
#ifndef _KERNEL
#include <assert.h>
#define KASSERT(s) assert(s)
#endif
#include "rb.h"
static void rb_tree_rotate(struct rb_tree *, struct rb_node *, int);
static void rb_tree_insert_rebalance(struct rb_tree *, struct rb_node *);
static void rb_tree_removal_rebalance(struct rb_tree *, struct rb_node *);
/*
* Rather than testing for the NULL everywhere, all terminal leaves are
* pointed to this node. Note that by setting it to be const, that on
* some architectures trying to write to it will cause a fault.
*/
static const struct rb_node sentinel_node = {
NULL, NULL, NULL, { NULL, NULL }, 0, 0, 1
};
void
rb_tree_init(struct rb_tree *rbt, rb_compare_nodes_fn compare_nodes,
rb_compare_key_fn compare_key, rb_print_node_fn print_node)
{
TAILQ_INIT(&rbt->rbt_nodes);
rbt->rbt_count = 0;
rbt->rbt_compare_nodes = compare_nodes;
rbt->rbt_compare_key = compare_key;
rbt->rbt_print_node = print_node;
*((const struct rb_node **)&rbt->rbt_root) = &sentinel_node;
}
/*
* Rotate the tree between Y and X
* X c a Y
* a b b c
*/
void
rb_tree_rotate(struct rb_tree *rbt, struct rb_node *self, int which)
{
const int other = which ^ RB_OTHER;
struct rb_node * const parent = self->rb_parent;
struct rb_node * const child = self->rb_nodes[other];
assert(!child->rb_sentinel);
assert(child->rb_parent == self);
#if 0
(*rbt->rbt_print_node)(child, which ? "before-l " : "before-r ");
#endif
if ((child->rb_parent = parent) == NULL) {
assert(rbt->rbt_root == self);
rbt->rbt_root = child;
} else {
parent->rb_nodes[self->rb_position] = child;
}
self->rb_nodes[other] = child->rb_nodes[which];
if (!self->rb_nodes[other]->rb_sentinel)
self->rb_nodes[other]->rb_parent = self;
child->rb_nodes[which] = self;
child->rb_position = self->rb_position;
self->rb_parent = child;
self->rb_position = which;
#if 0
(*rbt->rbt_print_node)(self, which ? "after-l " : "after-r ");
#endif
}
void
rb_tree_insert_node(struct rb_tree *rbt, struct rb_node *self)
{
struct rb_node *prev, *next, *tmp, *parent;
struct rb_node **insert_p;
u_int position;
prev = NULL;
next = NULL;
parent = NULL;
tmp = rbt->rbt_root;
/*
* Find out where to place this new leaf.
*/
while (!tmp->rb_sentinel) {
const int diff = (*rbt->rbt_compare_nodes)(tmp, self);
parent = tmp;
assert(diff != 0);
if (diff < 0) {
position = RB_LEFT;
next = parent->rb_left;
prev = NULL;
} else {
position = RB_RIGHT;
prev = parent->rb_right;
next = NULL;
}
tmp = parent->rb_nodes[position];
}
/*
* Verify our sequential position
*/
if (prev != NULL && next == NULL)
next = TAILQ_NEXT(prev, rb_link);
if (prev == NULL && next != NULL)
next = TAILQ_PREV(next, rb_node_qh, rb_link);
assert(prev == NULL || (*rbt->rbt_compare_nodes)(prev, self) > 0);
assert(next == NULL || (*rbt->rbt_compare_nodes)(self, next) < 0);
/*
* Initialize the node and insert as a leaf into the tree.
*/
rbt->rbt_count++;
self->rb_parent = parent;
if (parent == NULL) {
assert(rbt->rbt_root->rb_sentinel);
self->rb_position = RB_PARENT;
self->rb_left = rbt->rbt_root;
self->rb_right = rbt->rbt_root;
rbt->rbt_root = self;
} else {
self->rb_position = position;
self->rb_left = parent->rb_nodes[position];
self->rb_right = parent->rb_nodes[position];
parent->rb_nodes[position] = self;
}
assert(self->rb_left == &sentinel_node &&
self->rb_right == &sentinel_node);
/*
* Insert the new node into a sorted list for easy sequential access
*/
if (next != NULL) {
TAILQ_INSERT_BEFORE(next, self, rb_link);
} else {
TAILQ_INSERT_TAIL(&rbt->rbt_nodes, self, rb_link);
}
/*
* Rebalance tree after insertation
*/
rb_tree_insert_rebalance(rbt, self);
}
void
rb_tree_insert_rebalance(struct rb_tree *rbt, struct rb_node *self)
{
self->rb_red = 1;
while (self != rbt->rbt_root && self->rb_parent->rb_red) {
const int which =
(self->rb_parent == self->rb_parent->rb_parent->rb_left
? RB_LEFT
: RB_RIGHT);
const int other = which ^ RB_OTHER;
struct rb_node *uncle;
assert(!self->rb_sentinel);
/*
* We are red, our are parent is red, and our
* grandparent is black.
*/
uncle = self->rb_parent->rb_parent->rb_nodes[other];
if (uncle->rb_red) {
/*
* Case 1: our uncle is red
* Simply invert the colors of our parent and
* uncle and make our grandparent red. And
* then solve the problem up at his level.
*/
uncle->rb_red = 0;
self->rb_parent->rb_red = 0;
self->rb_parent->rb_parent->rb_red = 1;
self = self->rb_parent->rb_parent;
} else {
/*
* Case 2&3: our uncle is black.
*/
if (self == self->rb_parent->rb_nodes[other]) {
/*
* Case 2: we are on the same side as our uncle
* Rotate parent away from uncle so this
* case becomes case 3
*/
self = self->rb_parent;
rb_tree_rotate(rbt, self, which);
}
/*
* Case 3: we are opposite a child of a black uncle.
* Change parent to black and grandparent to
* red. Rotate grandparent away from ourself.
*/
self->rb_parent->rb_red = 0;
self->rb_parent->rb_parent->rb_red = 1;
rb_tree_rotate(rbt, self->rb_parent->rb_parent, other);
}
}
/*
* Final step: Set the root to black.
*/
rbt->rbt_root->rb_red = 0;
}
struct rb_node *
rb_tree_lookup(struct rb_tree *rbt, void *key)
{
struct rb_node *parent = rbt->rbt_root;
while (!parent->rb_sentinel) {
const int diff = (*rbt->rbt_compare_key)(parent, key);
if (diff == 0)
return parent;
parent = parent->rb_nodes[diff > 0];
}
return NULL;
}
void
rb_tree_remove_node(struct rb_tree *rbt, struct rb_node *self)
{
struct rb_node *child;
/*
* Easy case, one or more children is NULL (leaf node or parent of
* leaf node).
*/
if (self->rb_left->rb_sentinel || self->rb_left->rb_sentinel) {
const int which = (!self->rb_left->rb_sentinel ? RB_LEFT : RB_RIGHT);
child = self->rb_nodes[which];
if (self->rb_parent == NULL) {
rbt->rbt_root = child;
} else {
self->rb_parent->rb_nodes[self->rb_position] = child;
}
if (child->rb_sentinel)
child = self->rb_parent;
else
child->rb_parent = self->rb_parent;
} else {
struct rb_node *new_self;
child = self->rb_right;
while (!child->rb_left->rb_sentinel)
child = child->rb_left;
new_self = child;
assert(new_self == TAILQ_NEXT(self, rb_link));
/*
* Take new_self out of the tree (its only subnode can be on the
* right since we know the left subnode is NULL).
*/
child->rb_parent->rb_left = child->rb_right;
if (!child->rb_right->rb_sentinel) {
child->rb_right->rb_parent = child->rb_parent;
child->rb_right->rb_position = RB_LEFT;
}
/*
* Take self out of the tree and insert new_self into its place.
*/
new_self->rb_right = self->rb_right;
new_self->rb_left = self->rb_left;
if (!new_self->rb_right->rb_sentinel)
new_self->rb_right->rb_parent = new_self;
if (!new_self->rb_left->rb_sentinel)
new_self->rb_left->rb_parent = new_self;
new_self->rb_red = self->rb_red;
new_self->rb_parent = self->rb_parent;
/*
* Update parent
*/
if (new_self->rb_parent == NULL) {
rbt->rbt_root = new_self;
} else {
new_self->rb_parent->rb_nodes[self->rb_position] = new_self;
}
}
TAILQ_REMOVE(&rbt->rbt_nodes, self, rb_link);
rbt->rbt_count--;
if (child != NULL) {
assert(!child->rb_sentinel);
#if 0
(*rbt->rbt_print_node)(child, "before ");
#endif
rb_tree_removal_rebalance(rbt, child);
#if 0
(*rbt->rbt_print_node)(child, "after ");
#endif
}
}
void
rb_tree_removal_rebalance(struct rb_tree *rbt, struct rb_node *self)
{
assert(!self->rb_sentinel);
while (self->rb_parent != NULL && !self->rb_red) {
struct rb_node *parent = self->rb_parent;
int which = (self == parent->rb_left) ? RB_LEFT : RB_RIGHT;
int other = which ^ RB_OTHER;
struct rb_node *sibling = parent->rb_nodes[other];
if (sibling->rb_red) {
sibling->rb_red = 0;
parent->rb_red = 1;
rb_tree_rotate(rbt, parent, which);
parent = self->rb_parent;
sibling = parent->rb_nodes[other];
}
if (sibling->rb_sentinel ||
(!sibling->rb_left->rb_red && !sibling->rb_right->rb_red)) {
sibling->rb_red = 1;
self = parent;
continue;
}
if (!sibling->rb_nodes[other]->rb_red) {
sibling->rb_nodes[which]->rb_red = 0;
sibling->rb_red = 1;
rb_tree_rotate(rbt, sibling, other);
parent = self->rb_parent;
sibling = parent->rb_nodes[other];
}
sibling->rb_red = parent->rb_red;
parent->rb_red = 0;
sibling->rb_nodes[other]->rb_red = 0;
rb_tree_rotate(rbt, parent, which);
break;
}
}
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