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|
/* Sequential list data type implemented by a binary tree.
Copyright (C) 2006-2007, 2009-2022 Free Software Foundation, Inc.
Written by Bruno Haible <bruno@clisp.org>, 2006.
This file is free software: you can redistribute it and/or modify
it under the terms of the GNU Lesser General Public License as
published by the Free Software Foundation; either version 2.1 of the
License, or (at your option) any later version.
This file 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 Lesser General Public License for more details.
You should have received a copy of the GNU Lesser General Public License
along with this program. If not, see <https://www.gnu.org/licenses/>. */
/* Common code of gl_rbtree_list.c and gl_rbtreehash_list.c. */
/* -------------------------- gl_list_t Data Type -------------------------- */
/* Creates a subtree for count >= 1 elements.
Its black-height bh is passed as argument, with
2^bh - 1 <= count <= 2^(bh+1) - 1. bh == 0 implies count == 1.
Its height is h where 2^(h-1) <= count <= 2^h - 1.
Return NULL upon out-of-memory. */
static gl_list_node_t
create_subtree_with_contents (unsigned int bh,
size_t count, const void **contents)
{
size_t half1 = (count - 1) / 2;
size_t half2 = count / 2;
/* Note: half1 + half2 = count - 1. */
gl_list_node_t node =
(struct gl_list_node_impl *) malloc (sizeof (struct gl_list_node_impl));
if (node == NULL)
return NULL;
if (half1 > 0)
{
/* half1 > 0 implies count > 1, implies bh >= 1, implies
2^(bh-1) - 1 <= half1 <= 2^bh - 1. */
node->left =
create_subtree_with_contents (bh - 1, half1, contents);
if (node->left == NULL)
goto fail1;
node->left->parent = node;
}
else
node->left = NULL;
node->value = contents[half1];
if (half2 > 0)
{
/* half2 > 0 implies count > 1, implies bh >= 1, implies
2^(bh-1) - 1 <= half2 <= 2^bh - 1. */
node->right =
create_subtree_with_contents (bh - 1, half2, contents + half1 + 1);
if (node->right == NULL)
goto fail2;
node->right->parent = node;
}
else
node->right = NULL;
node->color = (bh == 0 ? RED : BLACK);
node->branch_size = count;
return node;
fail2:
if (node->left != NULL)
free_subtree (node->left);
fail1:
free (node);
return NULL;
}
static gl_list_t
gl_tree_nx_create (gl_list_implementation_t implementation,
gl_listelement_equals_fn equals_fn,
gl_listelement_hashcode_fn hashcode_fn,
gl_listelement_dispose_fn dispose_fn,
bool allow_duplicates,
size_t count, const void **contents)
{
struct gl_list_impl *list =
(struct gl_list_impl *) malloc (sizeof (struct gl_list_impl));
if (list == NULL)
return NULL;
list->base.vtable = implementation;
list->base.equals_fn = equals_fn;
list->base.hashcode_fn = hashcode_fn;
list->base.dispose_fn = dispose_fn;
list->base.allow_duplicates = allow_duplicates;
#if WITH_HASHTABLE
{
size_t estimate = xsum (count, count / 2); /* 1.5 * count */
if (estimate < 10)
estimate = 10;
list->table_size = next_prime (estimate);
if (size_overflow_p (xtimes (list->table_size, sizeof (gl_hash_entry_t))))
goto fail1;
list->table =
(gl_hash_entry_t *) calloc (list->table_size, sizeof (gl_hash_entry_t));
if (list->table == NULL)
goto fail1;
}
#endif
if (count > 0)
{
/* Assuming 2^bh - 1 <= count <= 2^(bh+1) - 2, we create a tree whose
upper bh levels are black, and only the partially present lowest
level is red. */
unsigned int bh;
{
size_t n;
for (n = count + 1, bh = 0; n > 1; n = n >> 1)
bh++;
}
list->root = create_subtree_with_contents (bh, count, contents);
if (list->root == NULL)
goto fail2;
list->root->parent = NULL;
#if WITH_HASHTABLE
/* Now that the tree is built, node_position() works. Now we can
add the nodes to the hash table. */
if (add_nodes_to_buckets (list) < 0)
goto fail3;
#endif
}
else
list->root = NULL;
return list;
#if WITH_HASHTABLE
fail3:
free_subtree (list->root);
#endif
fail2:
#if WITH_HASHTABLE
free (list->table);
fail1:
#endif
free (list);
return NULL;
}
/* Rotates left a subtree.
B D
/ \ / \
A D --> B E
/ \ / \
C E A C
Changes the tree structure, updates the branch sizes.
The caller must update the colors and register D as child of its parent. */
static gl_list_node_t
rotate_left (gl_list_node_t b_node, gl_list_node_t d_node)
{
gl_list_node_t a_node = b_node->left;
gl_list_node_t c_node = d_node->left;
gl_list_node_t e_node = d_node->right;
b_node->right = c_node;
d_node->left = b_node;
d_node->parent = b_node->parent;
b_node->parent = d_node;
if (c_node != NULL)
c_node->parent = b_node;
b_node->branch_size =
(a_node != NULL ? a_node->branch_size : 0)
+ 1 + (c_node != NULL ? c_node->branch_size : 0);
d_node->branch_size =
b_node->branch_size + 1 + (e_node != NULL ? e_node->branch_size : 0);
return d_node;
}
/* Rotates right a subtree.
D B
/ \ / \
B E --> A D
/ \ / \
A C C E
Changes the tree structure, updates the branch sizes.
The caller must update the colors and register B as child of its parent. */
static gl_list_node_t
rotate_right (gl_list_node_t b_node, gl_list_node_t d_node)
{
gl_list_node_t a_node = b_node->left;
gl_list_node_t c_node = b_node->right;
gl_list_node_t e_node = d_node->right;
d_node->left = c_node;
b_node->right = d_node;
b_node->parent = d_node->parent;
d_node->parent = b_node;
if (c_node != NULL)
c_node->parent = d_node;
d_node->branch_size =
(c_node != NULL ? c_node->branch_size : 0)
+ 1 + (e_node != NULL ? e_node->branch_size : 0);
b_node->branch_size =
(a_node != NULL ? a_node->branch_size : 0) + 1 + d_node->branch_size;
return b_node;
}
/* Ensures the tree is balanced, after an insertion operation.
Also assigns node->color.
parent is the given node's parent, known to be non-NULL. */
static void
rebalance_after_add (gl_list_t list, gl_list_node_t node, gl_list_node_t parent)
{
for (;;)
{
/* At this point, parent = node->parent != NULL.
Think of node->color being RED (although node->color is not yet
assigned.) */
gl_list_node_t grandparent;
gl_list_node_t uncle;
if (parent->color == BLACK)
{
/* A RED color for node is acceptable. */
node->color = RED;
return;
}
grandparent = parent->parent;
/* Since parent is RED, we know that
grandparent is != NULL and colored BLACK. */
if (grandparent->left == parent)
uncle = grandparent->right;
else if (grandparent->right == parent)
uncle = grandparent->left;
else
abort ();
if (uncle != NULL && uncle->color == RED)
{
/* Change grandparent from BLACK to RED, and
change parent and uncle from RED to BLACK.
This makes it acceptable for node to be RED. */
node->color = RED;
parent->color = uncle->color = BLACK;
node = grandparent;
}
else
{
/* grandparent and uncle are BLACK. parent is RED. node wants
to be RED too.
In this case, recoloring is not sufficient. Need to perform
one or two rotations. */
gl_list_node_t *grandparentp;
if (grandparent->parent == NULL)
grandparentp = &list->root;
else if (grandparent->parent->left == grandparent)
grandparentp = &grandparent->parent->left;
else if (grandparent->parent->right == grandparent)
grandparentp = &grandparent->parent->right;
else
abort ();
if (grandparent->left == parent)
{
if (parent->right == node)
{
/* Rotation between node and parent. */
grandparent->left = rotate_left (parent, node);
node = parent;
parent = grandparent->left;
}
/* grandparent and uncle are BLACK. parent and node want to be
RED. parent = grandparent->left. node = parent->left.
grandparent parent
bh+1 bh+1
/ \ / \
parent uncle --> node grandparent
bh bh bh bh
/ \ / \
node C C uncle
bh bh bh bh
*/
*grandparentp = rotate_right (parent, grandparent);
parent->color = BLACK;
node->color = grandparent->color = RED;
}
else /* grandparent->right == parent */
{
if (parent->left == node)
{
/* Rotation between node and parent. */
grandparent->right = rotate_right (node, parent);
node = parent;
parent = grandparent->right;
}
/* grandparent and uncle are BLACK. parent and node want to be
RED. parent = grandparent->right. node = parent->right.
grandparent parent
bh+1 bh+1
/ \ / \
uncle parent --> grandparent node
bh bh bh bh
/ \ / \
C node uncle C
bh bh bh bh
*/
*grandparentp = rotate_left (grandparent, parent);
parent->color = BLACK;
node->color = grandparent->color = RED;
}
return;
}
/* Start again with a new (node, parent) pair. */
parent = node->parent;
if (parent == NULL)
{
/* Change node's color from RED to BLACK. This increases the
tree's black-height. */
node->color = BLACK;
return;
}
}
}
/* Ensures the tree is balanced, after a deletion operation.
CHILD was a grandchild of PARENT and is now its child. Between them,
a black node was removed. CHILD is also black, or NULL.
(CHILD can also be NULL. But PARENT is non-NULL.) */
static void
rebalance_after_remove (gl_list_t list, gl_list_node_t child, gl_list_node_t parent)
{
for (;;)
{
/* At this point, we reduced the black-height of the CHILD subtree by 1.
To make up, either look for a possibility to turn a RED to a BLACK
node, or try to reduce the black-height tree of CHILD's sibling
subtree as well. */
gl_list_node_t *parentp;
if (parent->parent == NULL)
parentp = &list->root;
else if (parent->parent->left == parent)
parentp = &parent->parent->left;
else if (parent->parent->right == parent)
parentp = &parent->parent->right;
else
abort ();
if (parent->left == child)
{
gl_list_node_t sibling = parent->right;
/* sibling's black-height is >= 1. In particular,
sibling != NULL.
parent
/ \
child sibling
bh bh+1
*/
if (sibling->color == RED)
{
/* sibling is RED, hence parent is BLACK and sibling's children
are non-NULL and BLACK.
parent sibling
bh+2 bh+2
/ \ / \
child sibling --> parent SR
bh bh+1 bh+1 bh+1
/ \ / \
SL SR child SL
bh+1 bh+1 bh bh+1
*/
*parentp = rotate_left (parent, sibling);
parent->color = RED;
sibling->color = BLACK;
/* Concentrate on the subtree of parent. The new sibling is
one of the old sibling's children, and known to be BLACK. */
parentp = &sibling->left;
sibling = parent->right;
}
/* Now we know that sibling is BLACK.
parent
/ \
child sibling
bh bh+1
*/
if (sibling->right != NULL && sibling->right->color == RED)
{
/*
parent sibling
bh+1|bh+2 bh+1|bh+2
/ \ / \
child sibling --> parent SR
bh bh+1 bh+1 bh+1
/ \ / \
SL SR child SL
bh bh bh bh
*/
*parentp = rotate_left (parent, sibling);
sibling->color = parent->color;
parent->color = BLACK;
sibling->right->color = BLACK;
return;
}
else if (sibling->left != NULL && sibling->left->color == RED)
{
/*
parent parent
bh+1|bh+2 bh+1|bh+2
/ \ / \
child sibling --> child SL
bh bh+1 bh bh+1
/ \ / \
SL SR SLL sibling
bh bh bh bh
/ \ / \
SLL SLR SLR SR
bh bh bh bh
where SLL, SLR, SR are all black.
*/
parent->right = rotate_right (sibling->left, sibling);
/* Change sibling from BLACK to RED and SL from RED to BLACK. */
sibling->color = RED;
sibling = parent->right;
sibling->color = BLACK;
/* Now do as in the previous case. */
*parentp = rotate_left (parent, sibling);
sibling->color = parent->color;
parent->color = BLACK;
sibling->right->color = BLACK;
return;
}
else
{
if (parent->color == BLACK)
{
/* Change sibling from BLACK to RED. Then the entire
subtree at parent has decreased its black-height.
parent parent
bh+2 bh+1
/ \ / \
child sibling --> child sibling
bh bh+1 bh bh
*/
sibling->color = RED;
child = parent;
}
else
{
/* Change parent from RED to BLACK, but compensate by
changing sibling from BLACK to RED.
parent parent
bh+1 bh+1
/ \ / \
child sibling --> child sibling
bh bh+1 bh bh
*/
parent->color = BLACK;
sibling->color = RED;
return;
}
}
}
else if (parent->right == child)
{
gl_list_node_t sibling = parent->left;
/* sibling's black-height is >= 1. In particular,
sibling != NULL.
parent
/ \
sibling child
bh+1 bh
*/
if (sibling->color == RED)
{
/* sibling is RED, hence parent is BLACK and sibling's children
are non-NULL and BLACK.
parent sibling
bh+2 bh+2
/ \ / \
sibling child --> SR parent
bh+1 ch bh+1 bh+1
/ \ / \
SL SR SL child
bh+1 bh+1 bh+1 bh
*/
*parentp = rotate_right (sibling, parent);
parent->color = RED;
sibling->color = BLACK;
/* Concentrate on the subtree of parent. The new sibling is
one of the old sibling's children, and known to be BLACK. */
parentp = &sibling->right;
sibling = parent->left;
}
/* Now we know that sibling is BLACK.
parent
/ \
sibling child
bh+1 bh
*/
if (sibling->left != NULL && sibling->left->color == RED)
{
/*
parent sibling
bh+1|bh+2 bh+1|bh+2
/ \ / \
sibling child --> SL parent
bh+1 bh bh+1 bh+1
/ \ / \
SL SR SR child
bh bh bh bh
*/
*parentp = rotate_right (sibling, parent);
sibling->color = parent->color;
parent->color = BLACK;
sibling->left->color = BLACK;
return;
}
else if (sibling->right != NULL && sibling->right->color == RED)
{
/*
parent parent
bh+1|bh+2 bh+1|bh+2
/ \ / \
sibling child --> SR child
bh+1 bh bh+1 bh
/ \ / \
SL SR sibling SRR
bh bh bh bh
/ \ / \
SRL SRR SL SRL
bh bh bh bh
where SL, SRL, SRR are all black.
*/
parent->left = rotate_left (sibling, sibling->right);
/* Change sibling from BLACK to RED and SL from RED to BLACK. */
sibling->color = RED;
sibling = parent->left;
sibling->color = BLACK;
/* Now do as in the previous case. */
*parentp = rotate_right (sibling, parent);
sibling->color = parent->color;
parent->color = BLACK;
sibling->left->color = BLACK;
return;
}
else
{
if (parent->color == BLACK)
{
/* Change sibling from BLACK to RED. Then the entire
subtree at parent has decreased its black-height.
parent parent
bh+2 bh+1
/ \ / \
sibling child --> sibling child
bh+1 bh bh bh
*/
sibling->color = RED;
child = parent;
}
else
{
/* Change parent from RED to BLACK, but compensate by
changing sibling from BLACK to RED.
parent parent
bh+1 bh+1
/ \ / \
sibling child --> sibling child
bh+1 bh bh bh
*/
parent->color = BLACK;
sibling->color = RED;
return;
}
}
}
else
abort ();
/* Start again with a new (child, parent) pair. */
parent = child->parent;
#if 0 /* Already handled. */
if (child != NULL && child->color == RED)
{
child->color = BLACK;
return;
}
#endif
if (parent == NULL)
return;
}
}
static void
gl_tree_remove_node_from_tree (gl_list_t list, gl_list_node_t node)
{
gl_list_node_t parent = node->parent;
if (node->left == NULL)
{
/* Replace node with node->right. */
gl_list_node_t child = node->right;
if (child != NULL)
{
child->parent = parent;
/* Since node->left == NULL, child must be RED and of height 1,
hence node must have been BLACK. Recolor the child. */
child->color = BLACK;
}
if (parent == NULL)
list->root = child;
else
{
if (parent->left == node)
parent->left = child;
else /* parent->right == node */
parent->right = child;
/* Update branch_size fields of the parent nodes. */
{
gl_list_node_t p;
for (p = parent; p != NULL; p = p->parent)
p->branch_size--;
}
if (child == NULL && node->color == BLACK)
rebalance_after_remove (list, child, parent);
}
}
else if (node->right == NULL)
{
/* It is not absolutely necessary to treat this case. But the more
general case below is more complicated, hence slower. */
/* Replace node with node->left. */
gl_list_node_t child = node->left;
child->parent = parent;
/* Since node->right == NULL, child must be RED and of height 1,
hence node must have been BLACK. Recolor the child. */
child->color = BLACK;
if (parent == NULL)
list->root = child;
else
{
if (parent->left == node)
parent->left = child;
else /* parent->right == node */
parent->right = child;
/* Update branch_size fields of the parent nodes. */
{
gl_list_node_t p;
for (p = parent; p != NULL; p = p->parent)
p->branch_size--;
}
}
}
else
{
/* Replace node with the rightmost element of the node->left subtree. */
gl_list_node_t subst;
gl_list_node_t subst_parent;
gl_list_node_t child;
color_t removed_color;
for (subst = node->left; subst->right != NULL; )
subst = subst->right;
subst_parent = subst->parent;
child = subst->left;
removed_color = subst->color;
/* The case subst_parent == node is special: If we do nothing special,
we get confusion about node->left, subst->left and child->parent.
subst_parent == node
<==> The 'for' loop above terminated immediately.
<==> subst == subst_parent->left
[otherwise subst == subst_parent->right]
In this case, we would need to first set
child->parent = node; node->left = child;
and later - when we copy subst into node's position - again
child->parent = subst; subst->left = child;
Altogether a no-op. */
if (subst_parent != node)
{
if (child != NULL)
child->parent = subst_parent;
subst_parent->right = child;
}
/* Update branch_size fields of the parent nodes. */
{
gl_list_node_t p;
for (p = subst_parent; p != NULL; p = p->parent)
p->branch_size--;
}
/* Copy subst into node's position.
(This is safer than to copy subst's value into node, keep node in
place, and free subst.) */
if (subst_parent != node)
{
subst->left = node->left;
subst->left->parent = subst;
}
subst->right = node->right;
subst->right->parent = subst;
subst->color = node->color;
subst->branch_size = node->branch_size;
subst->parent = parent;
if (parent == NULL)
list->root = subst;
else if (parent->left == node)
parent->left = subst;
else /* parent->right == node */
parent->right = subst;
if (removed_color == BLACK)
{
if (child != NULL && child->color == RED)
/* Recolor the child. */
child->color = BLACK;
else
/* Rebalancing starts at child's parent, that is subst_parent -
except when subst_parent == node. In this case, we need to use
its replacement, subst. */
rebalance_after_remove (list, child,
subst_parent != node ? subst_parent : subst);
}
}
}
static gl_list_node_t
gl_tree_nx_add_first (gl_list_t list, const void *elt)
{
/* Create new node. */
gl_list_node_t new_node =
(struct gl_list_node_impl *) malloc (sizeof (struct gl_list_node_impl));
if (new_node == NULL)
return NULL;
new_node->left = NULL;
new_node->right = NULL;
new_node->branch_size = 1;
new_node->value = elt;
#if WITH_HASHTABLE
new_node->h.hashcode =
(list->base.hashcode_fn != NULL
? list->base.hashcode_fn (new_node->value)
: (size_t)(uintptr_t) new_node->value);
#endif
/* Add it to the tree. */
if (list->root == NULL)
{
new_node->color = BLACK;
list->root = new_node;
new_node->parent = NULL;
}
else
{
gl_list_node_t node;
for (node = list->root; node->left != NULL; )
node = node->left;
node->left = new_node;
new_node->parent = node;
/* Update branch_size fields of the parent nodes. */
{
gl_list_node_t p;
for (p = node; p != NULL; p = p->parent)
p->branch_size++;
}
/* Color and rebalance. */
rebalance_after_add (list, new_node, node);
}
#if WITH_HASHTABLE
/* Add node to the hash table.
Note that this is only possible _after_ the node has been added to the
tree structure, because add_to_bucket() uses node_position(). */
if (add_to_bucket (list, new_node) < 0)
{
gl_tree_remove_node_from_tree (list, new_node);
free (new_node);
return NULL;
}
hash_resize_after_add (list);
#endif
return new_node;
}
static gl_list_node_t
gl_tree_nx_add_last (gl_list_t list, const void *elt)
{
/* Create new node. */
gl_list_node_t new_node =
(struct gl_list_node_impl *) malloc (sizeof (struct gl_list_node_impl));
if (new_node == NULL)
return NULL;
new_node->left = NULL;
new_node->right = NULL;
new_node->branch_size = 1;
new_node->value = elt;
#if WITH_HASHTABLE
new_node->h.hashcode =
(list->base.hashcode_fn != NULL
? list->base.hashcode_fn (new_node->value)
: (size_t)(uintptr_t) new_node->value);
#endif
/* Add it to the tree. */
if (list->root == NULL)
{
new_node->color = BLACK;
list->root = new_node;
new_node->parent = NULL;
}
else
{
gl_list_node_t node;
for (node = list->root; node->right != NULL; )
node = node->right;
node->right = new_node;
new_node->parent = node;
/* Update branch_size fields of the parent nodes. */
{
gl_list_node_t p;
for (p = node; p != NULL; p = p->parent)
p->branch_size++;
}
/* Color and rebalance. */
rebalance_after_add (list, new_node, node);
}
#if WITH_HASHTABLE
/* Add node to the hash table.
Note that this is only possible _after_ the node has been added to the
tree structure, because add_to_bucket() uses node_position(). */
if (add_to_bucket (list, new_node) < 0)
{
gl_tree_remove_node_from_tree (list, new_node);
free (new_node);
return NULL;
}
hash_resize_after_add (list);
#endif
return new_node;
}
static gl_list_node_t
gl_tree_nx_add_before (gl_list_t list, gl_list_node_t node, const void *elt)
{
/* Create new node. */
gl_list_node_t new_node =
(struct gl_list_node_impl *) malloc (sizeof (struct gl_list_node_impl));
if (new_node == NULL)
return NULL;
new_node->left = NULL;
new_node->right = NULL;
new_node->branch_size = 1;
new_node->value = elt;
#if WITH_HASHTABLE
new_node->h.hashcode =
(list->base.hashcode_fn != NULL
? list->base.hashcode_fn (new_node->value)
: (size_t)(uintptr_t) new_node->value);
#endif
/* Add it to the tree. */
if (node->left == NULL)
node->left = new_node;
else
{
for (node = node->left; node->right != NULL; )
node = node->right;
node->right = new_node;
}
new_node->parent = node;
/* Update branch_size fields of the parent nodes. */
{
gl_list_node_t p;
for (p = node; p != NULL; p = p->parent)
p->branch_size++;
}
/* Color and rebalance. */
rebalance_after_add (list, new_node, node);
#if WITH_HASHTABLE
/* Add node to the hash table.
Note that this is only possible _after_ the node has been added to the
tree structure, because add_to_bucket() uses node_position(). */
if (add_to_bucket (list, new_node) < 0)
{
gl_tree_remove_node_from_tree (list, new_node);
free (new_node);
return NULL;
}
hash_resize_after_add (list);
#endif
return new_node;
}
static gl_list_node_t
gl_tree_nx_add_after (gl_list_t list, gl_list_node_t node, const void *elt)
{
/* Create new node. */
gl_list_node_t new_node =
(struct gl_list_node_impl *) malloc (sizeof (struct gl_list_node_impl));
if (new_node == NULL)
return NULL;
new_node->left = NULL;
new_node->right = NULL;
new_node->branch_size = 1;
new_node->value = elt;
#if WITH_HASHTABLE
new_node->h.hashcode =
(list->base.hashcode_fn != NULL
? list->base.hashcode_fn (new_node->value)
: (size_t)(uintptr_t) new_node->value);
#endif
/* Add it to the tree. */
if (node->right == NULL)
node->right = new_node;
else
{
for (node = node->right; node->left != NULL; )
node = node->left;
node->left = new_node;
}
new_node->parent = node;
/* Update branch_size fields of the parent nodes. */
{
gl_list_node_t p;
for (p = node; p != NULL; p = p->parent)
p->branch_size++;
}
/* Color and rebalance. */
rebalance_after_add (list, new_node, node);
#if WITH_HASHTABLE
/* Add node to the hash table.
Note that this is only possible _after_ the node has been added to the
tree structure, because add_to_bucket() uses node_position(). */
if (add_to_bucket (list, new_node) < 0)
{
gl_tree_remove_node_from_tree (list, new_node);
free (new_node);
return NULL;
}
hash_resize_after_add (list);
#endif
return new_node;
}
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