# Nonrecursive/Iterative Binary Search Tree in C (Homework)

How can I create/delete a node in a Binary Search Tree using Iterative Algorithm in C?

-
homework? homework? –  Joe Dec 21 '10 at 22:50

Iterative insertion:

``````struct tree_node *Insert_Element (struct tree_node *root, void *key, void *data) {
struct tree_node *new_node, *node;

node = root;

do {
switch (compare(key, node->key)) {

case -1: {
if (node->left == NULL) {
if ((new_node = create_node(key, data)) == NULL) {
return NULL;
}

node->left = new_node;
return new_node;
}

node = node->left;
} break;

case 1: {
if (node->right == NULL) {
if ((new_node = create_node(key, data)) == NULL) {
return NULL;
}

node->right = new_node;
return new_node;
}

node = node->right;
} break;

default: {
return node;
}
}
} while (node != NULL);

return NULL;
}
``````
-
I would make note that this will not give you a balanced tree - it will depend on the order in which the items are added and their respective key values. –  Will Dec 21 '10 at 22:40
You'll need some modifications if you want to handle the insertion of the first item into an empty tree. This implementation assumes there is a root node. –  Adrian McCarthy Dec 21 '10 at 22:57

In C, you can cast the pointers in the tree to `intptr_t` type and perform bitwise operations to them.

As you traverse down the tree, you can store the 'parent' pointer of a node by xoring it with the pointer you traversed with. You can then traverse back up the tree by xoring the the address of the node you are coming from with the modified pointer.

Given the ability to traverse the tree without recursion, you can then create iterative versions of any of the algorithms based on traversing the tree.

-

Iterative insertion & deletion in BST

``````struct bst {
int data;
struct bst *left;
struct bst *right;
};
typedef struct bst bst_t;

bst_t *get_new_node(int val)
{
bst_t *node = (bst_t *) malloc(sizeof(bst_t));
node->data = val;
node->left = NULL;
node->right= NULL;
return node;
}

bst_t *insert(bst_t *root, int val)
{
if(!root) return get_new_node(val);
bst_t *prev = NULL, *ptr = root;
char type = ' ';
while(ptr) {
prev = ptr;
if(val < ptr->data) {
ptr = ptr->left;
type = 'l';
} else {
ptr = ptr->right;
type = 'r';
}
}
if(type == 'l')
prev->left  = get_new_node(val);
else
prev->right = get_new_node(val);
return root;
}

int find_minimum_value(bst_t *ptr)
{
int min = ptr ? ptr->data : 0;
while(ptr) {
if(ptr->data < min) min = ptr->data;
if(ptr->left) {
ptr = ptr->left;
} else if(ptr->right) {
ptr = ptr->right;
} else ptr = NULL;
}
return min;
}

bst_t *delete(bst_t *root, int val)
{
bst_t *prev = NULL, *ptr = root;
char type = ' ';
while(ptr) {
if(ptr->data == val) {
if(!ptr->left && !ptr->right) { // node to be removed has no children's
if(ptr != root && prev) { // delete leaf node
if(type == 'l')
prev->left = NULL;
else
prev->right = NULL;
} else root = NULL; // deleted node is root
} else if (ptr->left && ptr->right) { // node to be removed has two children's
ptr->data = find_minimum_value(ptr->right); // find minimum value from right subtree
val = ptr->data;
prev = ptr;
ptr = ptr->right; // continue from right subtree delete min node
type = 'r';
continue;
} else { // node to be removed has one children
if(ptr == root)  { // root with one child
root = root->left ? root->left : root->right;
} else { // subtree with one child
if(type == 'l')
prev->left = ptr->left ? ptr->left : ptr->right;
else
prev->right = ptr->left ? ptr->left : ptr->right;
}
}
free(ptr);
}
prev = ptr;
if(val < ptr->data) {
ptr = ptr->left;
type = 'l';
} else {
ptr = ptr->right;
type = 'r';
}
}
return root;
}
``````
-