I'm having the hardest time trying to figure out how to balance an AVL tree for my class. I've got it inserting with this:

Node* Tree::insert(int d)
    cout << "base insert\t" << d << endl;
    if (head == NULL)
        return (head = new Node(d));
        return insert(head, d);

Node* Tree::insert(Node*& current, int d)
    cout << "insert\t" << d << endl;
    if (current == NULL)
        current = new Node(d);
    else if (d < current->data) {
        insert(current->lchild, d);
        if (height(current->lchild) - height(current->rchild)) {
            if (d < current->lchild->getData())
    else if (d > current->getData()) {
        insert(current->rchild, d);
        if (height(current->rchild) - height(current->lchild)) {
            if (d > current->rchild->getData())

    return current;

My plan was to have the calls to balance() check to see if the tree needs balancing and then balance as needed. The trouble is, I can't even figure out how to traverse the tree to find the correct unbalanced node. I know how to traverse the tree recursively, but I can't seem to translate that algorithm into finding the lowest unbalanced node. I'm also having trouble writing an iterative algorithm. Any help would be appreciated. :)

  • By the way, if you are familiar with java, for me the book Data Structures and Algorithms in Java, by Lafore helped me a lot to understand data structures. Although it does not have AVL it does talk extensively about Red-Black trees, which i if find easier. Once you understand them in Java you can do it in any other language you are familiar with, the whole point is understanding the way they work
    – Carlos
    Nov 18, 2010 at 22:32
  • @Carlos: I agree that as long as the language is not cryptic (perl ...) any will do to demonstrate the implementation of an algorithm or data-structure. Nov 19, 2010 at 7:48

4 Answers 4


You can measure the height of a branch at a given point to calculate the unbalance

(remember a difference in height (levels) >= 2 means your tree is not balanced)

int Tree::Height(TreeNode *node){
     int left, right;

         return 0;
     left = Height(node->left);
     right = Height(node->right);
  if(left > right)
            return left+1;
            return right+1;

Depending on the unevenness then you can rotate as necessary

void Tree::rotateLeftOnce(TreeNode*& node){
     TreeNode *otherNode;

     otherNode = node->left;
     node->left = otherNode->right;
     otherNode->right = node;
     node = otherNode;

void Tree::rotateLeftTwice(TreeNode*& node){

void Tree::rotateRightOnce(TreeNode*& node){
     TreeNode *otherNode;

     otherNode = node->right;
     node->right = otherNode->left;
     otherNode->left = node;
     node = otherNode;

void Tree::rotateRightTwice(TreeNode*& node){

Now that we know how to rotate, lets say you want to insert a value in the tree... First we check whether the tree is empty or not

TreeNode* Tree::insert(int d){
         return (root = new TreeNode(d));  //Is empty when root = null
         return insert(root, d);           //step-into the tree and place "d"

When the tree is not empty we use recursion to traverse the tree and get to where is needed

TreeNode* Tree::insert(TreeNode*& node, int d_IN){
     if(node == NULL)  // (1) If we are at the end of the tree place the value
         node = new TreeNode(d_IN);
     else if(d_IN < node->d_stored){  //(2) otherwise go left if smaller
         insert(node->left, d_IN);    
         if(Height(node->left) - Height(node->right) == 2){
            if(d_IN < node->left->d_stored)
     else if(d_IN > node->d_stored){ // (3) otherwise go right if bigger
        insert(node->right, d_IN);
        if(Height(node->right) - Height(node->left) == 2){
            if(d_IN > node->right->d_stored)
     return node;

You should always check for balance (and do rotations if necessary) when modifying the tree, no point waiting until the end when the tree is a mess to balance it. That just complicates things...


There is a mistake in your implementation, in the code below you are not checking correctly whether the tree is unbalanced. You need to check whether the height is equals to 2 (therefore unbalance). As a result the code bellow...

if (height(current->lchild) - height(current->rchild)) { ...

if (height(current->rchild) - height(current->lchild)) {...

Should become...

if (height(current->lchild) - height(current->rchild) == 2) { ...

if (height(current->rchild) - height(current->lchild) == 2) {...

Some Resources

  • Thanks for the detailed comment. It is very helpful. However, I don't think I understand your insert method. What is the purpose the the first parameter? In the code I show above, I start at the head and loop until I find the correct location for the tree. Is that a bad method of doing this? It seems with your insert method, you already know before hand where the node belongs.
    – gregghz
    Nov 18, 2010 at 23:14
  • 1
    see the edit hopefully it will help. Looping is not the best choice, use recursion instead, as it is easier to manipulate the nodes of the tree.
    – Carlos
    Nov 18, 2010 at 23:43
  • So when I run this code, I get a seg fault at node = new TreeNode(d_IN); in the second insert method, what might cause that?
    – gregghz
    Nov 19, 2010 at 0:24
  • update your question for a moment with your implementation to check
    – Carlos
    Nov 19, 2010 at 0:28
  • 1
    @Carlos I just don't understand the part where you are doing this: Code: "if (d_IN > node->right->d){rotateRightOnce} else{rotateRightTwice}". can you explain it a bit. It would be much of a favor.
    – Terrenium
    Mar 2, 2013 at 18:25

Wait, wait, wait. You aren't really going to check the "height" of every branch each time you're inserting something, are you?

Measuring the height means transversing all the sub-branch. Means - every insert into such a tree will cost O(N). If so - what do you need such a tree? You may use a sorted array as well: it gives O(N) insertion/deletion and O(log N) search.

A correct AVL handling algorithm must store the left/right height difference at each node. Then, after every operation (insert/remove) - you must make sure none of the affected nodes will be too much unbalanced. To do this you do the so-called "rotations". During them you don't actually re-measure the heights. You just don't have to: every rotation changes the balance of the affected nodes by some predictable value.


goto http://code.google.com/p/self-balancing-avl-tree/ , all usual operations like add, delete are implemented, plus concat and split


Commented out is the code right rotate above and left rotate, below is my working right rotate and my working left rotate. I think the logic in the rotate above is inversed:

 void rotateRight(Node *& n){
    //Node* temp = n->right;
    //n->right = temp->left;
    //temp->left = n;
    //n = temp;
    cout << "}}}}}}}}}}}}}}}}}}}}}ROTATE RIGHT}}}}}}}}}}}}}}}}}}}}}" << endl;
    Node *temp = n->left;
    n->left = temp->right;
    temp->right = n;
    n = temp;

void rotateLeft(Node *& n){
    //Node *temp = n->left;
    //n->left = temp->right;
    //temp->right = n;
    //n = temp;
    cout << "}}}}}}}}}}}}}}}}}}}}}ROTATE LEFT}}}}}}}}}}}}}}}}}}}}}" << endl;
    Node* temp = n->right;
    n->right = temp->left;
    temp->left = n;
    n = temp;

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