# how to build a binary tree from preorder and inorder traversals

Im doing an assignment on building a binary tree from the preorder and inorder traversals (a char in each Node) and im trying to wrap my brain around how to build the actual tree.

Here is my thought process on how to accomplish this:

1. store the first entry in the preorder as the root node
2. search the inorder for that entry.
3. take the chars to the left of the root node and save them as a char array.
4. take the chars to the right of the root node and save them as a char array.
5. make a new tree, with the root as the parent and its 2 children being the left and right char arrays.
6. keep going recursively until the preorder length is 0.

I have steps 1-4 taken care of, but im not too sure how to properly build my tree, and was wondering if anyone had any pointers. Thank you.

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Do the recursion before building the new tree. So, your list would look like this:

1. store the first entry in the preorder as the root node
2. search the inorder for that entry.
3. take the chars to the left of the root node and save them as a char array.
4. take the chars to the right of the root node and save them as a char array.
5. recursively make a tree from the left chars.
6. recursively make a tree from the right chars.
7. combine both trees with your root node.
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This is a pretty cool method. But you will have to partition both the in-order and pre-order sequences, no? – Andre Artus Apr 20 '11 at 15:22
Yes, seems so. I think this is easy, since you can get the partition sizes for the preorder from the inorder partition. – Paŭlo Ebermann Apr 20 '11 at 15:42
You are right, it is easy. One just needs to ensure that the partitioning is done correctly. Your way is the easiest way to do it on paper. – Andre Artus Apr 20 '11 at 16:34

See my answer to this question. You build the tree by adding nodes in pre-order sequence, but by using the inorder position as comparator.

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While this link may answer the question, it is better to include the essential parts of the answer here and provide the link for reference. Link-only answers can become invalid if the linked page changes. - From Review – Ahmed Ashour Apr 9 at 21:36
@AhmedAshour: I disagree...this isn't a link-only answer. Andre has given a [short] description of his solution, and then a link to a code example. Just because an answer is short, and has a link, doesn't automatically make it a link only answer. See: meta.stackoverflow.com/questions/287563/… – gariepy Apr 10 at 3:59
@gariepy, thanks. – Andre Artus Apr 12 at 3:35

You can use the below code, I just wrote for the same problem. It works for me.

``````public class TreeFromInorderAndPreOrder {

public static List<Integer> inOrder = new ArrayList<Integer>();
public static List<Integer> preOrder = new ArrayList<Integer>();

public static void main(String[] args) {

Node root = new Node();
root.createRoot(5);
for(int i = 0 ; i < 9 ; i++){
if(i != 5){
root.insert(i);
}
}

inOrder(root);
preOrder(root);
for(Integer temp : inOrder){
System.out.print(temp +  " ");
}

System.out.println();
for(Integer temp : preOrder){
System.out.print(temp + " ");
}

Node node1 = null;
node1 = reConstructTree(root, (ArrayList<Integer>) inOrder, true);

System.out.println();
inOrder(node1);
for(Integer temp : inOrder){
System.out.print(temp +  " ");
}

System.out.println();

for(Integer temp : preOrder){
System.out.print(temp + " ");
}

}

public static void inOrder(Node node){

if(node!= null){
inOrder(node.leftchild);
inOrder(node.rightChild);
}

}

public static void preOrder(Node node){

if(node != null){
preOrder(node.leftchild);
preOrder(node.rightChild);
}

}

public static Node reConstructTree(Node root, ArrayList<Integer> inOrder,
boolean  isLeft){

if(preOrder.size() != 0 && inOrder.size() != 0){
return null;
}

Node node = new Node();
node.createRoot(preOrder.get(0));
if(root != null && isLeft){
root.leftchild = node;
}else if(root != null && !isLeft){
root.rightChild = node;
}
int indx = inOrder.get(preOrder.get(0));
preOrder.remove(0);
List<Integer> leftInorder = getSublist(0, indx);
reConstructTree(node, (ArrayList<Integer>) leftInorder, true);
List<Integer> rightInorder = getSublist(indx+1, inOrder.size());
reConstructTree(node, (ArrayList<Integer>)rightInorder, false);
return node;

}

public static ArrayList<Integer> getSublist(int start, int end){
ArrayList<Integer> list = new ArrayList<Integer>();
for(int i = start ; i < end ; i++){
}

return list;
}
}
``````
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I have written a sample program using divide and conquer approach using recursion in java

``````import java.util.LinkedList;
import java.util.Queue;

public class BinaryTreeNode {

private char data;
public char getData() {
return data;
}
public void setData(char data) {
this.data = data;
}
public BinaryTreeNode getLeft() {
return left;
}
public void setLeft(BinaryTreeNode left) {
this.left = left;
}
public BinaryTreeNode getRight() {
return right;
}
public void setRight(BinaryTreeNode right) {
this.right = right;
}
private BinaryTreeNode left;
private BinaryTreeNode right;

public static void levelTravesal(BinaryTreeNode node)
{

if(node == null)
return;
queue.offer(node);
queue.offer(null);
int level =0;
while(!queue.isEmpty())
{
BinaryTreeNode temp = (BinaryTreeNode) queue.poll();

if(temp == null)
{
System.out.println("Level: "+level);
if(!queue.isEmpty())
queue.offer(null);
level++;
}else {

System.out.println(temp.data);

if(temp.getLeft()!=null)
queue.offer(temp.getLeft());

if(temp.getRight()!=null)
queue.offer(temp.getRight());
}

}
}

static int preIndex = 0;

public static void main(String[] args) {

if(args.length < 2)
{
System.out.println("Usage: preorder inorder");
return;
}

char[] preOrderSequence = args[0].toCharArray();
char[] inOrderSequence = args[1].toCharArray();

//char[] preOrderSequence = {'A','B','D','E','C','F'};
//char[] inOrderSequence = "DBEAFC".toCharArray();

if(preOrderSequence.length != inOrderSequence.length)
{
System.out.println("Pre-order and in-order sequences must be of same length");
return;
}

BinaryTreeNode root = buildBinaryTree(preOrderSequence, inOrderSequence, 0, preOrderSequence.length-1);

System.out.println();
levelTravesal(root);

}

static BinaryTreeNode buildBinaryTree(char[] preOrder, char[] inOrder, int start, int end)
{
if(start > end)
return null;
BinaryTreeNode rootNode = new BinaryTreeNode();
rootNode.setData(preOrder[preIndex]);
preIndex++;
//System.out.println(rootNode.getData());
if(start == end)
return rootNode;
int dataIndex = search(inOrder, start, end, rootNode.getData());
if(dataIndex == -1)
return null;
//System.out.println("Left Bounds: "+start+" "+(dataIndex-1));
rootNode.setLeft(buildBinaryTree(preOrder, inOrder, start, dataIndex - 1));
//System.out.println("Right Bounds: "+(dataIndex+1)+" "+end);
rootNode.setRight(buildBinaryTree(preOrder, inOrder, dataIndex+1, end));
return rootNode;
}

static int search(char[] inOrder,int start,int end,char data)
{
for(int i=start;i<=end;i++)
{
if(inOrder[i] == data)
return i;
}
return -1;

}

}
``````
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