# Calculate the DEPTH of a binary search tree?

Original problem: Calculate the number of nodes [SOLVED].

I have another similar problem, and both of these have been killing me for a while now.

I can calculate the number of words fine now. Thank you very much for your assistance.

The issue is now calculating the summation of depths [the sum of the individual depths for all children of the root] for this BST. The individual depths of the elements are not already stored.

The reason I need the number of nodes and this summation is I am trying to calculate the average depth of this BST.

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Oh, we should ask: Is this homework? –  Carl Smotricz Dec 9 '09 at 19:36
Changing the question after people have supplied answers is going to make the original answers seem unrelated to the latest question. Also you can't Accept two answers. Would be better to ask a new question, i.e. on a new page. You might also want to Accept an answer to the original question. –  jon-hanson Dec 9 '09 at 20:02
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## 8 Answers

Something like this:

``````int countChildren(Node node)
{
if ( node == null )
return 0;
return 1 + countChildren(node.getLeft()) + countChildren(node.getRight());
}
``````

And to get the sum of the depths of every child:

``````int sumDepthOfAllChildren(Node node, int depth)
{
if ( node == null )
return 0;  // starting to see a pattern?
return depth + sumDepthOfAllChildren(node.getLeft(), depth + 1) +
sumDepthOfAllChildren(node.getRight(), depth + 1);
}
``````

Now for a hopefully informative explanation in case this is homework. Counting the number of nodes is quite simple. First of all, if the node isn't a node (`node == null`) it returns 0. If it is a node, it first counts its self (the `1`), plus the number of nodes in its left sub-tree plus the number of nodes in its right sub-tree. Another way to think of it is you visit every node via BFS, and add one to the count for every node you visit.

The Summation of depths is similar, except instead of adding just one for each node, the node adds the depth of its self. And it knows the depth of its self because its parent told it. Each node knows that the depth of it's children are it's own depth plus one, so when you get the depth of the left and right children of a node, you tell them their depth is the current node's depth plus 1.

And again, if the node isn't a node, it has no depth. So if you want the sum of the depth of all the root node's children, you pass in the root node and the root node's depth like so: `sumDepthOfAllChildren(root, 0)`

Recursion is quite useful, it's just a very different way of thinking about things and takes practice to get accustomed to it

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+1 Thats it, as if right out of a textbook. –  Kyle Rozendo Dec 9 '09 at 19:42
I would like to note that Kyle is referring to my first function and not the explanation which was added later and is of dubious quality. –  David Brown Dec 9 '09 at 20:57
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For any given tree, the number of nodes is 1 for the root plus the number of nodes in the left subtree plus the number of nodes in the right subtree :)

Details, like making sure there actually is a left or right subtree, are "left to the reader".

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Carl is right. the easiest way to do this is: public int countNodes(Node root) { if(root == null) return 0; return 1 + countNodes(root.getLeft()) + countNodes(root.getRight()); } –  Gennadiy Dec 9 '09 at 19:35
Original poster: That doesn't help me actually do it :P. Read the question, I have difficulty retaining a sum in a recursive method for the number of nodes while traversing the BST. –  Jon Dec 9 '09 at 19:35
You don't need to retain anything, as Gennadiy demonstrated above. –  StrixVaria Dec 9 '09 at 19:37
You don't have to retain a sum. All you need to do is find the sum of up to 3 numbers and return that to your caller. –  Carl Smotricz Dec 9 '09 at 19:37
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``````int maxDepth(Node node) {
if (node == NULL) {
return (0);
} else {
// compute the depth of each subtree
int lDepth = maxDepth(node.eft);
int rDepth = maxDepth(node.right);
// use the larger one
if (lDepth > rDepth)
return (lDepth + 1);
else
return (rDepth + 1);
}
}
``````
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``````public class Node {
private Node left;
private Node right;
public int size() { return 1+ (left==null?0:left.size())+ (right==null?0:right.size());}
}
``````
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``````private static int getNumberOfNodes(Node node) {
if (node == null) {
return 0;
}

return 1 + getNumberOfNodes(node.left) + getNumberOfNodes(node.right);
}
``````
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``````int depth(treenode *p)
{
if(p==NULL)return(0);
if(p->left){h1=depth(p->left);}
if(p=>right){h2=depth(p->right);}
return(max(h1,h2)+1);
}
``````
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``````public int numberOfNodes()
{
// This node.
int result = 1;

// Plus all the nodes from the left node.
Node left = getLeft();
if (left != null)
result += left.numberOfNodes();

// Plus all the nodes from the right node.
Node right = getRight();
if (right != null)
result += right.numberOfNodes();

return result;
}
``````
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``````public int countNodes(Node root)
{
// Setup
// assign to temps to avoid double call accessors.
Node left = root.getLeft();
Node right = root.getRight();
int count = 1; // count THIS node.

// count subtrees
if (left != null) count += countNodes(left);
if (right != null) count += countNodes(right);

return count;
}
``````
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