# Red-Black Tree Height using Recursion

I have these following methods to get the height of a red black tree and this works (I send the root). Now my question is, how is this working? I have drawn a tree and have tried following this step by step for each recursion call but I can't pull it off. I know the general idea of what the code is doing, which is going through all the leaves and comparing them but can anyone give a clear explanation on this?

``````int RedBlackTree::heightHelper(Node * n) const{
if ( n == NULL ){
return -1;
}
else{
return max(heightHelper(n->left), heightHelper(n->right)) + 1;
}
}

int RedBlackTree::max(int x, int y) const{
if (x >= y){
return x;
}
else{
return y;
}
}
``````
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Think about that `+ 1` you see hanging on the end of that `max()` result from the recursive calls, and what it contributes to the caller of the current call. – WhozCraig Nov 24 '13 at 5:27
Try first to simulate the working of the algorithm with very simple trees. How does it work if only the root exists? How does it work in tree with tree nodes? – Parzival Nov 24 '13 at 5:30
As it seems you don't know about it, you don't have to make your own `max` function as there is `std::max`. – Joachim Pileborg Nov 24 '13 at 5:33

Well, the general algorithm to find the height of any binary tree (whether a BST,AVL tree, Red Black,etc) is as follows

``````For the current node:
if(node is NULL) return -1
else
h1=Height of your left child//A Recursive call
h2=Height of your right child//A Recursive call
Add 1 to max(h1,h2) to account for the current node
return this value to parent.
``````

An illustration to the above algorithm is as follows:

(Image courtesy Wikipedia.org)

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This code will return the height of any binary tree, not just a red-black tree. It works recursively.

I found this problem difficult to think about in the past, but if we imagine we have a function which returns the height of a sub-tree, we could easily use that to compute the height of a full tree. We do this by computing the height of each side, taking the max, and adding one.

The height of the tree either goes through the left or right branch, so we can take the max of those. Then we add 1 for the root.

Handle the base case of no tree (-1), and we're done.

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This is a basic recursion algorithm.

Start at the base case, if the root itself is `null` the height of tree is `-1` as the tree does not exist.

Now imagine at any node what will be the height of the tree if this node were its root?

It would be simply the maximum of the height of left subtree or the right subtree (since you are trying to find the maximum possible height, so you have to take the greater of the 2) and add a 1 to it to incorporate the node itself.

That's it, once you follow this, you're done!

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As a recursive function, this computes the height of each child node, using that result to compute the height of the current node by adding `+ 1` to it. The height of any node is always the maximum height of the two children + 1. A single-node case is probably the easiest to understand, since it has a height of zero (0).

``````    A
``````

Here the call stack looks like this:

``````height(A) =
max(height(A->left), height(A->right)) + 1
``````

Since both left and right are null, both return `(-1)`, and therefore this reduces to

``````height(A) = max (-1, -1) + 1;
height(A) = -1 + 1;
height(A) = 0
``````

A slightly more complicated version

``````         A
B         C
D   E
``````

The recursive calls we care about are:

``````height(A) =
max(height(B), height(C)) + 1

height(B) =
max(height(D), height(E)) + 1
``````

The single nodes D, E, and C we already know from our first example have a height of zero (they have no children). therefore all of the above reduces to

``````height(A) = max( (max(0, 0) + 1), 0) + 1
height(A) = max(1, 0) + 1
height(A) = 1 + 1
height(A) = 2
``````

I hope that makes at least a dent in the learning curve for you. Draw them out on paper with some sample trees to understand better if you still have doubts.

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