# Refactoring Code Finding if a Binary Tree is a BST [closed]

I have written code to find if a given tree is a BST. But I need help refactoring it. Some of the things I am looking are:

1. Getting Rid of temp variables (As suggested by Martin Fowler)
2. Combining leftTreeMax and RighTreeMin methods
3. Better method names

Also, I would appreciate any other refactoring ideas people have.

``````package com.cc.bst;

import com.cc.queue.Queue;
import com.cc.trees.BinaryTreeNode;

public class IsBinaryTreeBST {

public static boolean binaryTreeBST ( BinaryTreeNode root) {

if (root == null) {
return false;
}
int maxVal = leftTreeMax(root.getLeft());
int minVal = rightTreeMin(root.getRight());
int rootVal = root.getData();

if (maxVal == 0 || minVal == 0 ) {
return false;
}

if (rootVal > maxVal && rootVal < minVal) {
return true;
}

return false;

}

private static int leftTreeMax (BinaryTreeNode node) {

if (node == null) {
return 0;
}
Queue nodeQueue = new Queue();
nodeQueue.enqueue(node);
int maxValue = node.getData();

while (!nodeQueue.isEmpty()) {
BinaryTreeNode tempNode = (BinaryTreeNode) nodeQueue.dequeue();
BinaryTreeNode left = tempNode.getLeft();
BinaryTreeNode right = tempNode.getRight();

if (left != null ) {
if (left.getData() > tempNode.getData()) {
return 0;
}
nodeQueue.enqueue(left);
}
if (right != null) {
if ( tempNode.getData() > right.getData()) {
return 0;
}
nodeQueue.enqueue(right);
}
if (tempNode.getData() > maxValue) {
maxValue = tempNode.getData();
}
}
System.out.println("---------- maxVal -------->" +  maxValue);
return maxValue;
}

private static int rightTreeMin(BinaryTreeNode node) {

if (node == null) {
return 0;
}
Queue nodeQueue = new Queue();
nodeQueue.enqueue(node);
int minValue = node.getData();

while (!nodeQueue.isEmpty()) {
BinaryTreeNode tempNode = (BinaryTreeNode) nodeQueue.dequeue();
BinaryTreeNode left = tempNode.getLeft();
BinaryTreeNode right = tempNode.getRight();
System.out.println("---------- tempNode -------->" + tempNode.getData());

if (left != null ) {
System.out.println("---------- left -------->" + left.getData());

if (left.getData() > tempNode.getData()) {
return 0;
}
nodeQueue.enqueue(left);
}
if (right != null) {
if ( tempNode.getData() > right.getData()) {
return 0;
}
System.out.println("---------- right -------->" + right.getData());

nodeQueue.enqueue(right);
}
if (tempNode.getData() < minValue) {
minValue = tempNode.getData();
}
}
System.out.println("---------- minVal -------->" +  minValue);

return minValue;
}
}
``````
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## closed as off topic by amit, seh, Mark, Andrew, j0kSep 21 '12 at 20:07

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Why not make an in-order traversal? Simply keep track of the prevous value you've seen. – phant0m Sep 20 '12 at 13:04
It better fits CodeReview.SE IMHO – amit Sep 20 '12 at 13:13
Is this homework? – theJollySin Sep 21 '12 at 6:06
Nopes it is not. – Manish Sep 21 '12 at 6:06

To be honest I am surprised your code is so complicated. It is hard for me to see a reason for a round of improvements: rewriting it seems simpler. Think of it like this:

We need to fulfil 3 rules, (was taken from Wikipedia):

1. The left subtree of a node contains only nodes with keys less than the node's key.
2. The right subtree of a node contains only nodes with keys greater than or equal to the node's key.
3. Both the left and right subtrees must also be binary search trees.

So as you can see, rule number 3 gives you a big hint that recursion is in order, as each subtree needs to have the same rules as his parent tree.

So why not do something like this:

``````checkBST(node,min,max) {
if(node == NULL)
return true
if(node.value < min || node.value >= max)
return false
return checkBST(left,min,node.value) && checkBST(right,node.value,max)
}

checkBST(root,-infinity,+infinity)
``````

This way what you are doing is for each subtree you are keeping a boundary for its values, which this boundary is received by its parent, so now lets say the left subtree needs to be smaller than his parent, then his parent is the maximum value this subtree can be, the same goes to the right subtree which must be bigger or equals to its parent.

This algorithm isn't the best time complexity wise, but is simplest to write and understand.

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