# Calculate the depth of a binary search tree?

I am having difficulty calculating the summation of depths [the sum of the individual depths for all children of the root] for a given BST. I have the total number of nodes for the tree, and I am trying to calculate the average depth for the tree, requiring I have this depth sum.

Recursion and I don't get along very well.. I am finding this problem very difficult. I would like to see a recursive solution though, if possible.

NOTE:

I have created accessors Node.getLeft() and Node.getRight()

-
This sounds an awful lot like homework. What have you written so far? Where are you getting stuck, other than that you 'don't get along well' with recursion? SO users arn't here to write out full solutions for you. –  Andrew Song Dec 9 '09 at 20:05
Also, tag as homework. –  CookieOfFortune Dec 9 '09 at 20:06
_POST CODE_ –  Jason Punyon Dec 9 '09 at 20:06
In the long run, you're not saving yourself any time by outsourcing your homework questions to StackOverflow. –  Andrew Song Dec 9 '09 at 20:39
Just for the record, I believe this can be solved in one line of Haskell :D –  Lambda Fairy Nov 28 '11 at 4:46

You just need to keep a depth counter as you traverse the tree (look up tree traversals if you have to) and add the value of the counter every time you reach a node. Then just divide by the number of nodes.

This looks like homework so I'm not providing a more detailed solution.

-

Think about how you would go about this canonically by hand if I had presented a picture of a BST to you on a sheet of paper. When you're at a node, what information do you need to keep track of? How does one find the height of a given node?

From here, try to translate this into pseudocode or even straight into Java. If you're having trouble, feel free to comment so users can help you out.

-

Is this homework? If so tag the question as such.

You could create a method that:

• has a node reference and a depth as arguments
• increment depth
• if node is not a child node call recursively for left and right and update sum accordingly
• otherwise return sum + depth

Once you have this devide by the number of children in the tree to get the average depth.

-

We need to visit all leaf nodes and figure out how deep they are. This suggests:

Give your node-visiting function an extra argument. It needs to know not just where it's going but also how deep it is. Every time it's called, it's called on to go deeper, so your node visitor just has to increment the depth number it got from the caller.

Now one of 2 things can happen:

• Either the node you found is a leaf node, i.e. it doesn't have any children; in this case, your visitor needs to return its depth to the caller. Yeah, it just returns the number it got from the caller, + 1.

• or it's not a leaf node. In that case, it will have either 1 or 2 children. We need to get those depth reports from our kids back up to the caller, so just return the sum of the depths returned by the children.

By the magic of recursion, the number returned to the root's visitor will be the sum of the depths of all children.

To get an average depth, you'll want to divide this by the number of leaf nodes; which I'd leave to a second traversal to calculate. It could be done in one, but it would be a little more complicated.

-
Could you expand on "or it's not a leaf node. In that case, it will have either 1 or 2 children. We need to get those depth reports from our kids back up to the caller, so just return the sum of the depths returned by the children."? I don't understand what you mean exactly. How do we return the sum of the depths returned by the children? –  Jon Dec 9 '09 at 21:05
Your visitor function, in whatever language, can return one number to its caller. I'm telling you how to calculate that number in each case. For a non-leaf node, it will call itself for one or two child nodes, and each of those 1 or 2 calls will return a number. If 2 children, return the sum, otherwise just return the one number you got. –  Carl Smotricz Dec 9 '09 at 21:12

Since this is homework, I don't want to just give you an answer. Instead, here's a recursive way to calculate the length of a singly linked list. Hopefully this will demonstrate recursion in a way you can understand, and you can extrapolate from there to solve your BST problem.

``````public final class LL {
public final int value;
public LL next;

public LL(final int value) {
this.value = value;
}

public void add(final int value) {
if (null == next) {
next = new LL(value);
} else {
}
}

/**
* Calculate the length of the linked list with this node as its head (includes this node in the count).
*
* @return the length.
*/
public int length() {
if (null == next) {
return 1;
}
return 1 + next.length();
}

public static void main(final String... args) {
final LL head = new LL(1);