avl_tree insert_avl_tree(avl_tree avltr, ElementType e)
{
if ( avltr == NULL ) {
avltr = (avl_tree)malloc( sizeof(struct AvlNode) );
avltr->element = e;
avltr->height = 0;
avltr->left = avltr->right = NULL;
} else if ( avltr->element >= e ) { //to left
avltr->left = insert_avl_tree(avltr->left, e);
if ( height_avl_tree(avltr->left) - height_avl_tree(avltr->right) == 2 ) {
if ( avltr->left->element >= e ) {
avltr = single_rotate_with_left(avltr);
} else {
avltr = double_rotate_with_left(avltr);
}
}
} else if ( avltr->element < e ) { //to right
avltr->right = insert_avl_tree(avltr->right, e);
avltr->height ++;
if ( height_avl_tree(avltr->right) - height_avl_tree(avltr->left) == 2 ) {
if ( avltr->right->element < e ) {
avltr = single_rotate_with_right(avltr);
} else {
avltr = double_rotate_with_right(avltr);
}
}
}
avltr->height = fmaxf(height_avl_tree(avltr->left), height_avl_tree(avltr->right)) + 1;
return avltr;
}
/* Insert a new node into the tree. */
node* insert (node *entry_node, node *current_node) {
if (current_node == NULL) {
current_node = entry_node;
} else if (entry_node->sequence.len - current_node->sequence.len > 0) {
current_node->left = insert (entry_node, current_node->left);
if (height (current_node->left) - height (current_node->right) == 2) {
if (entry_node->sequence.len - current_node->left->sequence.len > 0) {
current_node = single_rotate_with_left (current_node);
} else {
current_node = double_rotate_with_left (current_node);
}
}
} else if (entry_node->sequence.len - current_node->sequence.len <= 0) {
current_node->right = insert (entry_node, current_node->right);
if (height (current_node->right) - height (current_node->left) == 2) {
if (entry_node->sequence.len - current_node->right->sequence.len <= 0) {
current_node = single_rotate_with_right (current_node);
} else {
current_node = double_rotate_with_right (current_node);
}
}
}
current_node->height = max (height (current_node->left), height (current_node->right)) + 1;
return current_node;
}
static NodeEntry double_rotate_with_right( NodeEntry K1 )
{
/* Rotate between K3 and K2 */
K1->right = single_rotate_with_left( K1->right );
/* Rotate between K1 and K2 */
return single_rotate_with_right( K1 );
}
static NodeEntry double_rotate_with_left( NodeEntry K3 )
{
/* Rotate between K1 and K2 */
K3->left = single_rotate_with_right( K3->left );
/* Rotate between K3 and K2 */
return single_rotate_with_left( K3 );
}
AvlTree AVL_insert( u_long key, uint16_t port, struct pbsnode *node, AvlTree tree )
{
if (tree == NULL)
{
/* Create and return a node */
if ((tree = ( AvlTree )calloc(1, sizeof( struct AvlNode ) )) == NULL)
{
return( tree );
}
tree->key = key;
tree->port = port;
tree->pbsnode = node;
tree->left = NULL;
tree->right = NULL;
tree->height = 0;
}
/* If key is less than current node value go left else go right.
If equal compare port and go left or right accordingly */
if (key < tree->key)
{
tree->left = AVL_insert( key, port, node, tree->left );
if (height(tree->left) - height(tree->right) >= 2 )
{
if (key <= tree->left->key )
tree = single_rotate_with_left( tree );
else
tree = double_rotate_with_left( tree );
}
}
else if (key > tree->key )
{
tree->right = AVL_insert( key, port, node, tree->right );
if (height(tree->right) - height(tree->left) >= 2 )
{
if (key >= tree->right->key)
tree = single_rotate_with_right( tree );
else
tree = double_rotate_with_right( tree );
}
}
else
{
/* if it is in the tree, do not add it again */
if (port == tree->port)
return(tree);
/* the keys are equal. sort by port */
if (port != 0)
{
if (port < tree->port)
{
tree->left = AVL_insert( key, port, node, tree->left );
if (height(tree->left) - height(tree->right) >= 2)
{
if (port <= tree->left->port)
tree = single_rotate_with_left( tree );
else
tree = double_rotate_with_left( tree );
}
}
else if (port > tree->port )
{
tree->right = AVL_insert( key, port, node, tree->right );
if (height(tree->right) - height(tree->left) >= 2)
{
if (port >= tree->right->port)
tree = single_rotate_with_right( tree );
else
tree = double_rotate_with_right( tree );
}
}
}
}
tree->height = Max(height(tree->left), height(tree->right)) + 1;
return(tree);
} /* End AVL_insert */
avl_tree double_rotate_with_right(avl_tree avltr)
{
avltr->right = single_rotate_with_left(avltr->right);
avltr = single_rotate_with_right(avltr);
return avltr;
}
/* Right-left double rotation
note: call double_rotate_with_right only if k1 has a right child and k1's right child has a left child. */
static node* double_rotate_with_right (node* k1) {
/* rotate between K3 and k2 */
k1->right = single_rotate_with_left (k1->right);
/* rotate between k1 and k2 */
return single_rotate_with_right (k1);
}
/* Left-right double rotation
note: call double_rotate_with_left only if k3 node has a left child and k3's left child has a right child. */
static node* double_rotate_with_left (node* k3) {
/* Rotate between k1 and k2 */
k3->left = single_rotate_with_right (k3->left);
/* Rotate between K3 and k2 */
return single_rotate_with_left (k3);
}
