/* Produced by texiweb from libavl.w. */
/* *INDENT-OFF* */
/* libavl - library for manipulation of binary trees.
Copyright (C) 1998-2002, 2004 Free Software Foundation, Inc.
This program is free software; you can redistribute it and/or
modify it under the terms of the GNU General Public License as
published by the Free Software Foundation; either version 2 of the
License, or (at your option) any later version.
This program is distributed in the hope that it will be useful, but
WITHOUT ANY WARRANTY; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.
See the GNU General Public License for more details.
You should have received a copy of the GNU General Public License
along with this program; if not, write to the Free Software
Foundation, Inc., 59 Temple Place - Suite 330, Boston, MA
02111-1307, USA.
The author may be contacted at <blp@gnu.org> on the Internet, or
write to Ben Pfaff, Stanford University, Computer Science Dept., 353
Serra Mall, Stanford CA 94305, USA.
*/
#include <assert.h>
#include <stdio.h>
#include <stdlib.h>
#include <string.h>
#include "avl.h"
/* Creates and returns a new table
with comparison function |compare| using parameter |param|
and memory allocator |allocator|.
Returns |NULL| if memory allocation failed. */
struct avl_table *avl_create(avl_comparison_func * compare, void *param,
struct libavl_allocator *allocator)
{
struct avl_table *tree;
assert(compare != NULL);
if (allocator == NULL)
allocator = &avl_allocator_default;
tree = allocator->libavl_malloc(allocator, sizeof *tree);
if (tree == NULL)
return NULL;
tree->avl_root = NULL;
tree->avl_compare = compare;
tree->avl_param = param;
tree->avl_alloc = allocator;
tree->avl_count = 0;
tree->avl_generation = 0;
return tree;
}
/* Search |tree| for an item matching |item|, and return it if found.
Otherwise return |NULL|. */
void *avl_find(const struct avl_table *tree, const void *item)
{
const struct avl_node *p;
assert(tree != NULL && item != NULL);
for (p = tree->avl_root; p != NULL;) {
int cmp = tree->avl_compare(item, p->avl_data, tree->avl_param);
if (cmp < 0)
p = p->avl_link[0];
else if (cmp > 0)
p = p->avl_link[1];
else /* |cmp == 0| */
return p->avl_data;
}
return NULL;
}
/* Inserts |item| into |tree| and returns a pointer to |item|'s address.
If a duplicate item is found in the tree,
returns a pointer to the duplicate without inserting |item|.
Returns |NULL| in case of memory allocation failure. */
void **avl_probe(struct avl_table *tree, void *item)
{
struct avl_node *y, *z; /* Top node to update balance factor, and parent. */
struct avl_node *p, *q; /* Iterator, and parent. */
struct avl_node *n; /* Newly inserted node. */
struct avl_node *w; /* New root of rebalanced subtree. */
int dir; /* Direction to descend. */
unsigned char da[AVL_MAX_HEIGHT]; /* Cached comparison results. */
int k = 0; /* Number of cached results. */
assert(tree != NULL && item != NULL);
z = (struct avl_node *) &tree->avl_root;
y = tree->avl_root;
dir = 0;
for (q = z, p = y; p != NULL; q = p, p = p->avl_link[dir]) {
int cmp = tree->avl_compare(item, p->avl_data, tree->avl_param);
if (cmp == 0)
return &p->avl_data;
if (p->avl_balance != 0)
z = q, y = p, k = 0;
dir = cmp > 0;
da[k++] = (unsigned char)dir;
}
n = q->avl_link[dir] =
tree->avl_alloc->libavl_malloc(tree->avl_alloc, sizeof *n);
if (n == NULL)
return NULL;
tree->avl_count++;
n->avl_data = item;
n->avl_link[0] = n->avl_link[1] = NULL;
n->avl_balance = 0;
if (y == NULL)
return &n->avl_data;
for (p = y, k = 0; p != n; p = p->avl_link[da[k]], k++)
if (da[k] == 0)
p->avl_balance--;
else
p->avl_balance++;
if (y->avl_balance == -2) {
struct avl_node *x = y->avl_link[0];
if (x->avl_balance == -1) {
w = x;
y->avl_link[0] = x->avl_link[1];
x->avl_link[1] = y;
x->avl_balance = y->avl_balance = 0;
} else {
assert(x->avl_balance == +1);
w = x->avl_link[1];
x->avl_link[1] = w->avl_link[0];
w->avl_link[0] = x;
y->avl_link[0] = w->avl_link[1];
w->avl_link[1] = y;
if (w->avl_balance == -1)
x->avl_balance = 0, y->avl_balance = +1;
else if (w->avl_balance == 0)
x->avl_balance = y->avl_balance = 0;
else /* |w->avl_balance == +1| */
x->avl_balance = -1, y->avl_balance = 0;
w->avl_balance = 0;
}
} else if (y->avl_balance == +2) {
struct avl_node *x = y->avl_link[1];
if (x->avl_balance == +1) {
w = x;
y->avl_link[1] = x->avl_link[0];
x->avl_link[0] = y;
x->avl_balance = y->avl_balance = 0;
} else {
assert(x->avl_balance == -1);
w = x->avl_link[0];
x->avl_link[0] = w->avl_link[1];
w->avl_link[1] = x;
y->avl_link[1] = w->avl_link[0];
w->avl_link[0] = y;
if (w->avl_balance == +1)
x->avl_balance = 0, y->avl_balance = -1;
else if (w->avl_balance == 0)
x->avl_balance = y->avl_balance = 0;
else /* |w->avl_balance == -1| */
x->avl_balance = +1, y->avl_balance = 0;
w->avl_balance = 0;
}
} else
return &n->avl_data;
z->avl_link[y != z->avl_link[0]] = w;
tree->avl_generation++;
return &n->avl_data;
}
/* Inserts |item| into |table|.
Returns |NULL| if |item| was successfully inserted
or if a memory allocation error occurred.
Otherwise, returns the duplicate item. */
void *avl_insert(struct avl_table *table, void *item)
{
void **p = avl_probe(table, item);
return p == NULL || *p == item ? NULL : *p;
}
/* Inserts |item| into |table|, replacing any duplicate item.
Returns |NULL| if |item| was inserted without replacing a duplicate,
or if a memory allocation error occurred.
Otherwise, returns the item that was replaced. */
void *avl_replace(struct avl_table *table, void *item)
{
void **p = avl_probe(table, item);
if (p == NULL || *p == item)
return NULL;
else {
void *r = *p;
*p = item;
return r;
}
}
/* Deletes from |tree| and returns an item matching |item|.
Returns a null pointer if no matching item found. */
void *avl_delete(struct avl_table *tree, const void *item)
{
/* Stack of nodes. */
struct avl_node *pa[AVL_MAX_HEIGHT]; /* Nodes. */
unsigned char da[AVL_MAX_HEIGHT]; /* |avl_link[]| indexes. */
int k; /* Stack pointer. */
struct avl_node *p; /* Traverses tree to find node to delete. */
int cmp; /* Result of comparison between |item| and |p|. */
void *res;
assert(tree != NULL && item != NULL);
k = 0;
p = (struct avl_node *) &tree->avl_root;
for (cmp = -1; cmp != 0;
cmp = tree->avl_compare(item, p->avl_data, tree->avl_param)) {
int dir = cmp > 0;
pa[k] = p;
da[k++] = (unsigned char)dir;
p = p->avl_link[dir];
if (p == NULL)
return NULL;
}
res = p->avl_data;
if (p->avl_link[1] == NULL)
pa[k - 1]->avl_link[da[k - 1]] = p->avl_link[0];
else {
struct avl_node *r = p->avl_link[1];
if (r->avl_link[0] == NULL) {
r->avl_link[0] = p->avl_link[0];
r->avl_balance = p->avl_balance;
pa[k - 1]->avl_link[da[k - 1]] = r;
da[k] = 1;
pa[k++] = r;
} else {
struct avl_node *s;
int j = k++;
for (;;) {
da[k] = 0;
pa[k++] = r;
s = r->avl_link[0];
if (s->avl_link[0] == NULL)
break;
r = s;
}
s->avl_link[0] = p->avl_link[0];
r->avl_link[0] = s->avl_link[1];
s->avl_link[1] = p->avl_link[1];
s->avl_balance = p->avl_balance;
pa[j - 1]->avl_link[da[j - 1]] = s;
da[j] = 1;
pa[j] = s;
}
}
tree->avl_alloc->libavl_free(tree->avl_alloc, p);
assert(k > 0);
while (--k > 0) {
struct avl_node *y = pa[k];
if (da[k] == 0) {
y->avl_balance++;
if (y->avl_balance == +1)
break;
else if (y->avl_balance == +2) {
struct avl_node *x = y->avl_link[1];
if (x->avl_balance == -1) {
struct avl_node *w;
assert(x->avl_balance == -1);
w = x->avl_link[0];
x->avl_link[0] = w->avl_link[1];
w->avl_link[1] = x;
y->avl_link[1] = w->avl_link[0];
w->avl_link[0] = y;
if (w->avl_balance == +1)
x->avl_balance = 0, y->avl_balance = -1;
else if (w->avl_balance == 0)
x->avl_balance = y->avl_balance = 0;
else /* |w->avl_balance == -1| */
x->avl_balance = +1, y->avl_balance = 0;
w->avl_balance = 0;
pa[k - 1]->avl_link[da[k - 1]] = w;
} else {
y->avl_link[1] = x->avl_link[0];
x->avl_link[0] = y;
pa[k - 1]->avl_link[da[k - 1]] = x;
if (x->avl_balance == 0) {
x->avl_balance = -1;
y->avl_balance = +1;
break;
} else
x->avl_balance = y->avl_balance = 0;
}
}
} else {
y->avl_balance--;
if (y->avl_balance == -1)
break;
else if (y->avl_balance == -2) {
struct avl_node *x = y->avl_link[0];
if (x->avl_balance == +1) {
struct avl_node *w;
assert(x->avl_balance == +1);
w = x->avl_link[1];
x->avl_link[1] = w->avl_link[0];
w->avl_link[0] = x;
y->avl_link[0] = w->avl_link[1];
w->avl_link[1] = y;
if (w->avl_balance == -1)
x->avl_balance = 0, y->avl_balance = +1;
else if (w->avl_balance == 0)
x->avl_balance = y->avl_balance = 0;
else /* |w->avl_balance == +1| */
x->avl_balance = -1, y->avl_balance = 0;
w->avl_balance = 0;
pa[k - 1]->avl_link[da[k - 1]] = w;
} else {
y->avl_link[0] = x->avl_link[1];
x->avl_link[1] = y;
pa[k - 1]->avl_link[da[k - 1]] = x;
if (x->avl_balance == 0) {
x->avl_balance = +1;
y->avl_balance = -1;
break;
} else
x->avl_balance = y->avl_balance = 0;
}
}
}
}
tree->avl_count--;
tree->avl_generation++;
return res;
}
/* Refreshes the stack of parent pointers in |trav|
and updates its generation number. */
static void trav_refresh(struct avl_traverser *trav)
{
assert(trav != NULL);
trav->avl_generation = trav->avl_table->avl_generation;
if (trav->avl_node != NULL) {
avl_comparison_func *cmp = trav->avl_table->avl_compare;
void *param = trav->avl_table->avl_param;
struct avl_node *node = trav->avl_node;
struct avl_node *i;
trav->avl_height = 0;
for (i = trav->avl_table->avl_root; i != node;) {
assert(trav->avl_height < AVL_MAX_HEIGHT);
assert(i != NULL);
trav->avl_stack[trav->avl_height++] = i;
i = i->avl_link[cmp(node->avl_data, i->avl_data, param) > 0];
}
}
}
/* Initializes |trav| for use with |tree|
and selects the null node. */
void avl_t_init(struct avl_traverser *trav, struct avl_table *tree)
{
trav->avl_table = tree;
trav->avl_node = NULL;
trav->avl_height = 0;
trav->avl_generation = tree->avl_generation;
}
/* Initializes |trav| for |tree|
and selects and returns a pointer to its least-valued item.
Returns |NULL| if |tree| contains no nodes. */
void *avl_t_first(struct avl_traverser *trav, struct avl_table *tree)
{
struct avl_node *x;
assert(tree != NULL && trav != NULL);
trav->avl_table = tree;
trav->avl_height = 0;
trav->avl_generation = tree->avl_generation;
x = tree->avl_root;
if (x != NULL)
while (x->avl_link[0] != NULL) {
assert(trav->avl_height < AVL_MAX_HEIGHT);
trav->avl_stack[trav->avl_height++] = x;
x = x->avl_link[0];
}
trav->avl_node = x;
return x != NULL ? x->avl_data : NULL;
}
/* Initializes |trav| for |tree|
and selects and returns a pointer to its greatest-valued item.
Returns |NULL| if |tree| contains no nodes. */
void *avl_t_last(struct avl_traverser *trav, struct avl_table *tree)
{
struct avl_node *x;
assert(tree != NULL && trav != NULL);
trav->avl_table = tree;
trav->avl_height = 0;
trav->avl_generation = tree->avl_generation;
x = tree->avl_root;
if (x != NULL)
while (x->avl_link[1] != NULL) {
assert(trav->avl_height < AVL_MAX_HEIGHT);
trav->avl_stack[trav->avl_height++] = x;
x = x->avl_link[1];
}
trav->avl_node = x;
return x != NULL ? x->avl_data : NULL;
}
/* Searches for |item| in |tree|.
If found, initializes |trav| to the item found and returns the item
as well.
If there is no matching item, initializes |trav| to the null item
and returns |NULL|. */
void *avl_t_find(struct avl_traverser *trav, struct avl_table *tree, void *item)
{
struct avl_node *p, *q;
assert(trav != NULL && tree != NULL && item != NULL);
trav->avl_table = tree;
trav->avl_height = 0;
trav->avl_generation = tree->avl_generation;
for (p = tree->avl_root; p != NULL; p = q) {
int cmp = tree->avl_compare(item, p->avl_data, tree->avl_param);
if (cmp < 0)
q = p->avl_link[0];
else if (cmp > 0)
q = p->avl_link[1];
else { /* |cmp == 0| */
trav->avl_node = p;
return p->avl_data;
}
assert(trav->avl_height < AVL_MAX_HEIGHT);
trav->avl_stack[trav->avl_height++] = p;
}
trav->avl_height = 0;
trav->avl_node = NULL;
return NULL;
}
/* Attempts to insert |item| into |tree|.
If |item| is inserted successfully, it is returned and |trav| is
initialized to its location.
If a duplicate is found, it is returned and |trav| is initialized to
its location. No replacement of the item occurs.
If a memory allocation failure occurs, |NULL| is returned and |trav|
is initialized to the null item. */
void *avl_t_insert(struct avl_traverser *trav, struct avl_table *tree,
void *item)
{
void **p;
assert(trav != NULL && tree != NULL && item != NULL);
p = avl_probe(tree, item);
if (p != NULL) {
trav->avl_table = tree;
trav->avl_node = ((struct avl_node *)
((char *) p - offsetof(struct avl_node, avl_data)));
trav->avl_generation = tree->avl_generation - 1;
return *p;
} else {
avl_t_init(trav, tree);
return NULL;
}
}
/* Initializes |trav| to have the same current node as |src|. */
void *avl_t_copy(struct avl_traverser *trav, const struct avl_traverser *src)
{
assert(trav != NULL && src != NULL);
if (trav != src) {
trav->avl_table = src->avl_table;
trav->avl_node = src->avl_node;
trav->avl_generation = src->avl_generation;
if (trav->avl_generation == trav->avl_table->avl_generation) {
trav->avl_height = src->avl_height;
memcpy(trav->avl_stack, (const void *) src->avl_stack,
sizeof *trav->avl_stack * trav->avl_height);
}
}
return trav->avl_node != NULL ? trav->avl_node->avl_data : NULL;
}
/* Returns the next data item in inorder
within the tree being traversed with |trav|,
or if there are no more data items returns |NULL|. */
void *avl_t_next(struct avl_traverser *trav)
{
struct avl_node *x;
assert(trav != NULL);
if (trav->avl_generation != trav->avl_table->avl_generation)
trav_refresh(trav);
x = trav->avl_node;
if (x == NULL) {
return avl_t_first(trav, trav->avl_table);
} else if (x->avl_link[1] != NULL) {
assert(trav->avl_height < AVL_MAX_HEIGHT);
trav->avl_stack[trav->avl_height++] = x;
x = x->avl_link[1];
while (x->avl_link[0] != NULL) {
assert(trav->avl_height < AVL_MAX_HEIGHT);
trav->avl_stack[trav->avl_height++] = x;
x = x->avl_link[0];
}
} else {
struct avl_node *y;
do {
if (trav->avl_height == 0) {
trav->avl_node = NULL;
return NULL;
}
y = x;
x = trav->avl_stack[--trav->avl_height];
}
while (y == x->avl_link[1]);
}
trav->avl_node = x;
return x->avl_data;
}
/* Returns the previous data item in inorder
within the tree being traversed with |trav|,
or if there are no more data items returns |NULL|. */
void *avl_t_prev(struct avl_traverser *trav)
{
struct avl_node *x;
assert(trav != NULL);
if (trav->avl_generation != trav->avl_table->avl_generation)
trav_refresh(trav);
x = trav->avl_node;
if (x == NULL) {
return avl_t_last(trav, trav->avl_table);
} else if (x->avl_link[0] != NULL) {
assert(trav->avl_height < AVL_MAX_HEIGHT);
trav->avl_stack[trav->avl_height++] = x;
x = x->avl_link[0];
while (x->avl_link[1] != NULL) {
assert(trav->avl_height < AVL_MAX_HEIGHT);
trav->avl_stack[trav->avl_height++] = x;
x = x->avl_link[1];
}
} else {
struct avl_node *y;
do {
if (trav->avl_height == 0) {
trav->avl_node = NULL;
return NULL;
}
y = x;
x = trav->avl_stack[--trav->avl_height];
}
while (y == x->avl_link[0]);
}
trav->avl_node = x;
return x->avl_data;
}
/* Returns |trav|'s current item. */
void *avl_t_cur(struct avl_traverser *trav)
{
assert(trav != NULL);
return trav->avl_node != NULL ? trav->avl_node->avl_data : NULL;
}
/* Replaces the current item in |trav| by |new| and returns the item replaced.
|trav| must not have the null item selected.
The new item must not upset the ordering of the tree. */
void *avl_t_replace(struct avl_traverser *trav, void *new)
{
void *old;
assert(trav != NULL && trav->avl_node != NULL && new != NULL);
old = trav->avl_node->avl_data;
trav->avl_node->avl_data = new;
return old;
}
/* Destroys |new| with |avl_destroy (new, destroy)|,
first setting right links of nodes in |stack| within |new|
to null pointers to avoid touching uninitialized data. */
static void
copy_error_recovery(struct avl_node **stack, int height,
struct avl_table *new, avl_item_func * destroy)
{
assert(stack != NULL && height >= 0 && new != NULL);
for (; height > 2; height -= 2)
stack[height - 1]->avl_link[1] = NULL;
avl_destroy(new, destroy);
}
/* Copies |org| to a newly created tree, which is returned.
If |copy != NULL|, each data item in |org| is first passed to |copy|,
and the return values are inserted into the tree,
with |NULL| return values taken as indications of failure.
On failure, destroys the partially created new tree,
applying |destroy|, if non-null, to each item in the new tree so far,
and returns |NULL|.
If |allocator != NULL|, it is used for allocation in the new tree.
Otherwise, the same allocator used for |org| is used. */
struct avl_table *avl_copy(const struct avl_table *org, avl_copy_func * copy,
avl_item_func * destroy,
struct libavl_allocator *allocator)
{
struct avl_node *stack[2 * (AVL_MAX_HEIGHT + 1)];
int height = 0;
struct avl_table *new;
struct avl_node org_head, *x, *y;
assert(org != NULL);
new = avl_create(org->avl_compare, org->avl_param,
allocator != NULL ? allocator : org->avl_alloc);
if (new == NULL)
return NULL;
new->avl_count = org->avl_count;
if (new->avl_count == 0)
return new;
org_head.avl_link[0] = (struct avl_node *) org->avl_root;
x = &org_head;
y = (struct avl_node *) &new->avl_root;
for (;;) {
while (x->avl_link[0] != NULL) {
assert(height < 2 * (AVL_MAX_HEIGHT + 1));
y->avl_link[0] =
new->avl_alloc->libavl_malloc(new->avl_alloc,
sizeof *y->avl_link[0]);
if (y->avl_link[0] == NULL) {
if (y != (struct avl_node *) &new->avl_root) {
y->avl_data = NULL;
y->avl_link[1] = NULL;
}
copy_error_recovery(stack, height, new, destroy);
return NULL;
}
stack[height++] = x;
stack[height++] = y;
x = x->avl_link[0];
y = y->avl_link[0];
}
y->avl_link[0] = NULL;
for (;;) {
y->avl_balance = x->avl_balance;
if (copy == NULL)
y->avl_data = x->avl_data;
else {
y->avl_data = copy(x->avl_data, org->avl_param);
if (y->avl_data == NULL) {
y->avl_link[1] = NULL;
copy_error_recovery(stack, height, new, destroy);
return NULL;
}
}
if (x->avl_link[1] != NULL) {
y->avl_link[1] =
new->avl_alloc->libavl_malloc(new->avl_alloc,
sizeof *y->avl_link[1]);
if (y->avl_link[1] == NULL) {
copy_error_recovery(stack, height, new, destroy);
return NULL;
}
x = x->avl_link[1];
y = y->avl_link[1];
break;
} else
y->avl_link[1] = NULL;
if (height <= 2)
return new;
y = stack[--height];
x = stack[--height];
}
}
}
/* Frees storage allocated for |tree|.
If |destroy != NULL|, applies it to each data item in inorder. */
void avl_destroy(struct avl_table *tree, avl_item_func * destroy)
{
struct avl_node *p, *q;
assert(tree != NULL);
for (p = tree->avl_root; p != NULL; p = q)
if (p->avl_link[0] == NULL) {
q = p->avl_link[1];
if (destroy != NULL && p->avl_data != NULL)
destroy(p->avl_data, tree->avl_param);
tree->avl_alloc->libavl_free(tree->avl_alloc, p);
} else {
q = p->avl_link[0];
p->avl_link[0] = q->avl_link[1];
q->avl_link[1] = p;
}
tree->avl_alloc->libavl_free(tree->avl_alloc, tree);
}
/* Allocates |size| bytes of space using |malloc()|.
Returns a null pointer if allocation fails. */
void *avl_malloc(struct libavl_allocator *allocator, size_t size)
{
assert(allocator != NULL && size > 0);
return malloc(size);
}
/* Frees |block|. */
void avl_free(struct libavl_allocator *allocator, void *block)
{
assert(allocator != NULL && block != NULL);
free(block);
}
/* Default memory allocator that uses |malloc()| and |free()|. */
struct libavl_allocator avl_allocator_default = {
avl_malloc,
avl_free
};
#undef NDEBUG
#include <assert.h>
/* Asserts that |avl_insert()| succeeds at inserting |item| into |table|. */
void
(avl_assert_insert) (struct avl_table * table, void *item) {
void **p = avl_probe(table, item);
assert(p != NULL && *p == item);
}
/* Asserts that |avl_delete()| really removes |item| from |table|,
and returns the removed item. */
void *(avl_assert_delete) (struct avl_table * table, void *item) {
void *p = avl_delete(table, item);
assert(p != NULL);
return p;
}
/* *INDENT-ON* */