freebsd-skq/contrib/gcclibs/libiberty/fibheap.c
2007-05-19 01:27:20 +00:00

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/* A Fibonacci heap datatype.
Copyright 1998, 1999, 2000, 2001 Free Software Foundation, Inc.
Contributed by Daniel Berlin (dan@cgsoftware.com).
This file is part of GNU CC.
GNU CC 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, or (at your option)
any later version.
GNU CC 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 GNU CC; see the file COPYING. If not, write to
the Free Software Foundation, 51 Franklin Street - Fifth Floor,
Boston, MA 02110-1301, USA. */
#ifdef HAVE_CONFIG_H
#include "config.h"
#endif
#ifdef HAVE_LIMITS_H
#include <limits.h>
#endif
#ifdef HAVE_STDLIB_H
#include <stdlib.h>
#endif
#ifdef HAVE_STRING_H
#include <string.h>
#endif
#include "libiberty.h"
#include "fibheap.h"
#define FIBHEAPKEY_MIN LONG_MIN
static void fibheap_ins_root (fibheap_t, fibnode_t);
static void fibheap_rem_root (fibheap_t, fibnode_t);
static void fibheap_consolidate (fibheap_t);
static void fibheap_link (fibheap_t, fibnode_t, fibnode_t);
static void fibheap_cut (fibheap_t, fibnode_t, fibnode_t);
static void fibheap_cascading_cut (fibheap_t, fibnode_t);
static fibnode_t fibheap_extr_min_node (fibheap_t);
static int fibheap_compare (fibheap_t, fibnode_t, fibnode_t);
static int fibheap_comp_data (fibheap_t, fibheapkey_t, void *, fibnode_t);
static fibnode_t fibnode_new (void);
static void fibnode_insert_after (fibnode_t, fibnode_t);
#define fibnode_insert_before(a, b) fibnode_insert_after (a->left, b)
static fibnode_t fibnode_remove (fibnode_t);
/* Create a new fibonacci heap. */
fibheap_t
fibheap_new (void)
{
return (fibheap_t) xcalloc (1, sizeof (struct fibheap));
}
/* Create a new fibonacci heap node. */
static fibnode_t
fibnode_new (void)
{
fibnode_t node;
node = (fibnode_t) xcalloc (1, sizeof *node);
node->left = node;
node->right = node;
return node;
}
static inline int
fibheap_compare (fibheap_t heap ATTRIBUTE_UNUSED, fibnode_t a, fibnode_t b)
{
if (a->key < b->key)
return -1;
if (a->key > b->key)
return 1;
return 0;
}
static inline int
fibheap_comp_data (fibheap_t heap, fibheapkey_t key, void *data, fibnode_t b)
{
struct fibnode a;
a.key = key;
a.data = data;
return fibheap_compare (heap, &a, b);
}
/* Insert DATA, with priority KEY, into HEAP. */
fibnode_t
fibheap_insert (fibheap_t heap, fibheapkey_t key, void *data)
{
fibnode_t node;
/* Create the new node. */
node = fibnode_new ();
/* Set the node's data. */
node->data = data;
node->key = key;
/* Insert it into the root list. */
fibheap_ins_root (heap, node);
/* If their was no minimum, or this key is less than the min,
it's the new min. */
if (heap->min == NULL || node->key < heap->min->key)
heap->min = node;
heap->nodes++;
return node;
}
/* Return the data of the minimum node (if we know it). */
void *
fibheap_min (fibheap_t heap)
{
/* If there is no min, we can't easily return it. */
if (heap->min == NULL)
return NULL;
return heap->min->data;
}
/* Return the key of the minimum node (if we know it). */
fibheapkey_t
fibheap_min_key (fibheap_t heap)
{
/* If there is no min, we can't easily return it. */
if (heap->min == NULL)
return 0;
return heap->min->key;
}
/* Union HEAPA and HEAPB into a new heap. */
fibheap_t
fibheap_union (fibheap_t heapa, fibheap_t heapb)
{
fibnode_t a_root, b_root, temp;
/* If one of the heaps is empty, the union is just the other heap. */
if ((a_root = heapa->root) == NULL)
{
free (heapa);
return heapb;
}
if ((b_root = heapb->root) == NULL)
{
free (heapb);
return heapa;
}
/* Merge them to the next nodes on the opposite chain. */
a_root->left->right = b_root;
b_root->left->right = a_root;
temp = a_root->left;
a_root->left = b_root->left;
b_root->left = temp;
heapa->nodes += heapb->nodes;
/* And set the new minimum, if it's changed. */
if (fibheap_compare (heapa, heapb->min, heapa->min) < 0)
heapa->min = heapb->min;
free (heapb);
return heapa;
}
/* Extract the data of the minimum node from HEAP. */
void *
fibheap_extract_min (fibheap_t heap)
{
fibnode_t z;
void *ret = NULL;
/* If we don't have a min set, it means we have no nodes. */
if (heap->min != NULL)
{
/* Otherwise, extract the min node, free the node, and return the
node's data. */
z = fibheap_extr_min_node (heap);
ret = z->data;
free (z);
}
return ret;
}
/* Replace both the KEY and the DATA associated with NODE. */
void *
fibheap_replace_key_data (fibheap_t heap, fibnode_t node,
fibheapkey_t key, void *data)
{
void *odata;
fibheapkey_t okey;
fibnode_t y;
/* If we wanted to, we could actually do a real increase by redeleting and
inserting. However, this would require O (log n) time. So just bail out
for now. */
if (fibheap_comp_data (heap, key, data, node) > 0)
return NULL;
odata = node->data;
okey = node->key;
node->data = data;
node->key = key;
y = node->parent;
if (okey == key)
return odata;
/* These two compares are specifically <= 0 to make sure that in the case
of equality, a node we replaced the data on, becomes the new min. This
is needed so that delete's call to extractmin gets the right node. */
if (y != NULL && fibheap_compare (heap, node, y) <= 0)
{
fibheap_cut (heap, node, y);
fibheap_cascading_cut (heap, y);
}
if (fibheap_compare (heap, node, heap->min) <= 0)
heap->min = node;
return odata;
}
/* Replace the DATA associated with NODE. */
void *
fibheap_replace_data (fibheap_t heap, fibnode_t node, void *data)
{
return fibheap_replace_key_data (heap, node, node->key, data);
}
/* Replace the KEY associated with NODE. */
fibheapkey_t
fibheap_replace_key (fibheap_t heap, fibnode_t node, fibheapkey_t key)
{
int okey = node->key;
fibheap_replace_key_data (heap, node, key, node->data);
return okey;
}
/* Delete NODE from HEAP. */
void *
fibheap_delete_node (fibheap_t heap, fibnode_t node)
{
void *ret = node->data;
/* To perform delete, we just make it the min key, and extract. */
fibheap_replace_key (heap, node, FIBHEAPKEY_MIN);
fibheap_extract_min (heap);
return ret;
}
/* Delete HEAP. */
void
fibheap_delete (fibheap_t heap)
{
while (heap->min != NULL)
free (fibheap_extr_min_node (heap));
free (heap);
}
/* Determine if HEAP is empty. */
int
fibheap_empty (fibheap_t heap)
{
return heap->nodes == 0;
}
/* Extract the minimum node of the heap. */
static fibnode_t
fibheap_extr_min_node (fibheap_t heap)
{
fibnode_t ret = heap->min;
fibnode_t x, y, orig;
/* Attach the child list of the minimum node to the root list of the heap.
If there is no child list, we don't do squat. */
for (x = ret->child, orig = NULL; x != orig && x != NULL; x = y)
{
if (orig == NULL)
orig = x;
y = x->right;
x->parent = NULL;
fibheap_ins_root (heap, x);
}
/* Remove the old root. */
fibheap_rem_root (heap, ret);
heap->nodes--;
/* If we are left with no nodes, then the min is NULL. */
if (heap->nodes == 0)
heap->min = NULL;
else
{
/* Otherwise, consolidate to find new minimum, as well as do the reorg
work that needs to be done. */
heap->min = ret->right;
fibheap_consolidate (heap);
}
return ret;
}
/* Insert NODE into the root list of HEAP. */
static void
fibheap_ins_root (fibheap_t heap, fibnode_t node)
{
/* If the heap is currently empty, the new node becomes the singleton
circular root list. */
if (heap->root == NULL)
{
heap->root = node;
node->left = node;
node->right = node;
return;
}
/* Otherwise, insert it in the circular root list between the root
and it's right node. */
fibnode_insert_after (heap->root, node);
}
/* Remove NODE from the rootlist of HEAP. */
static void
fibheap_rem_root (fibheap_t heap, fibnode_t node)
{
if (node->left == node)
heap->root = NULL;
else
heap->root = fibnode_remove (node);
}
/* Consolidate the heap. */
static void
fibheap_consolidate (fibheap_t heap)
{
fibnode_t a[1 + 8 * sizeof (long)];
fibnode_t w;
fibnode_t y;
fibnode_t x;
int i;
int d;
int D;
D = 1 + 8 * sizeof (long);
memset (a, 0, sizeof (fibnode_t) * D);
while ((w = heap->root) != NULL)
{
x = w;
fibheap_rem_root (heap, w);
d = x->degree;
while (a[d] != NULL)
{
y = a[d];
if (fibheap_compare (heap, x, y) > 0)
{
fibnode_t temp;
temp = x;
x = y;
y = temp;
}
fibheap_link (heap, y, x);
a[d] = NULL;
d++;
}
a[d] = x;
}
heap->min = NULL;
for (i = 0; i < D; i++)
if (a[i] != NULL)
{
fibheap_ins_root (heap, a[i]);
if (heap->min == NULL || fibheap_compare (heap, a[i], heap->min) < 0)
heap->min = a[i];
}
}
/* Make NODE a child of PARENT. */
static void
fibheap_link (fibheap_t heap ATTRIBUTE_UNUSED,
fibnode_t node, fibnode_t parent)
{
if (parent->child == NULL)
parent->child = node;
else
fibnode_insert_before (parent->child, node);
node->parent = parent;
parent->degree++;
node->mark = 0;
}
/* Remove NODE from PARENT's child list. */
static void
fibheap_cut (fibheap_t heap, fibnode_t node, fibnode_t parent)
{
fibnode_remove (node);
parent->degree--;
fibheap_ins_root (heap, node);
node->parent = NULL;
node->mark = 0;
}
static void
fibheap_cascading_cut (fibheap_t heap, fibnode_t y)
{
fibnode_t z;
while ((z = y->parent) != NULL)
{
if (y->mark == 0)
{
y->mark = 1;
return;
}
else
{
fibheap_cut (heap, y, z);
y = z;
}
}
}
static void
fibnode_insert_after (fibnode_t a, fibnode_t b)
{
if (a == a->right)
{
a->right = b;
a->left = b;
b->right = a;
b->left = a;
}
else
{
b->right = a->right;
a->right->left = b;
a->right = b;
b->left = a;
}
}
static fibnode_t
fibnode_remove (fibnode_t node)
{
fibnode_t ret;
if (node == node->left)
ret = NULL;
else
ret = node->left;
if (node->parent != NULL && node->parent->child == node)
node->parent->child = ret;
node->right->left = node->left;
node->left->right = node->right;
node->parent = NULL;
node->left = node;
node->right = node;
return ret;
}