# Pre-order to post-order traversal

If the pre-order traversal of a binary search tree is 6, 2, 1, 4, 3, 7, 10, 9, 11, how to get the post-order traversal?

• You can't find an unique answer. Look at: stackoverflow.com/questions/1219831/… for further discussion. Commented Dec 27, 2010 at 10:16
• @ Ondrej Tucny - no not but i'm prepare for a datastucture exam and I have draw 2 different trees and they have the same postorder so i got confused a little bit Commented Dec 27, 2010 at 10:35
• Is the BST full? Are there 2^n nodes in the tree? Commented Dec 27, 2010 at 16:44
• @Gunner: For a binary search tree, it is unique, assuming in-order traversal is 1,2,..., (though I agree, there is some ambiguity there).
– Aryabhatta
Commented Dec 27, 2010 at 20:46

You are given the pre-order traversal of the tree, which is constructed by doing: output, traverse left, traverse right.

As the post-order traversal comes from a BST, you can deduce the in-order traversal (traverse left, output, traverse right) from the post-order traversal by sorting the numbers. In your example, the in-order traversal is 1, 2, 3, 4, 6, 7, 9, 10, 11.

From two traversals we can then construct the original tree. Let's use a simpler example for this:

• Pre-order: 2, 1, 4, 3
• In-order: 1, 2, 3, 4

The pre-order traversal gives us the root of the tree as 2. The in-order traversal tells us 1 falls into the left sub-tree and 3, 4 falls into the right sub-tree. The structure of the left sub-tree is trivial as it contains a single element. The right sub-tree's pre-order traversal is deduced by taking the order of the elements in this sub-tree from the original pre-order traversal: 4, 3. From this we know the root of the right sub-tree is 4 and from the in-order traversal (3, 4) we know that 3 falls into the left sub-tree. Our final tree looks like this:

``````  2
/ \
1   4
/
3
``````

With the tree structure, we can get the post-order traversal by walking the tree: traverse left, traverse right, output. For this example, the post-order traversal is 1, 3, 4, 2.

To generalise the algorithm:

1. The first element in the pre-order traversal is the root of the tree. Elements less than the root form the left sub-tree. Elements greater than the root form the right sub-tree.
2. Find the structure of the left and right sub-trees using step 1 with a pre-order traversal that consists of the elements we worked out to be in that sub-tree placed in the order they appear in the original pre-order traversal.
3. Traverse the resulting tree in post-order to get the post-order traversal associated with the given pre-order traversal.

Using the above algorithm, the post-order traversal associated with the pre-order traversal in the question is: 1, 3, 4, 2, 9, 11, 10, 7, 6. Getting there is left as an exercise.

• He is specifically asking about a binary search tree and hence there is a clear ordering between the current node's value and its left subtree and right subtree. I don't see any ambiguity here. Commented Dec 27, 2010 at 10:49
• @Ondrej Doh! Completely overead that he was using BSTs. Will edit it in. Commented Dec 27, 2010 at 10:58

Pre-order = outputting the values of a binary tree in the order of the current node, then the left subtree, then the right subtree.

Post-order = outputting the values of a binary tree in the order of the left subtree, then the right subtree, the the current node.

In a binary search tree, the values of all nodes in the left subtree are less than the value of the current node; and alike for the right subtree. Hence if you know the start of a pre-order dump of a binary search tree (i.e. its root node's value), you can easily decompose the whole dump into the root node value, the values of the left subtree's nodes, and the values of the right subtree's nodes.

To output the tree in post-order, recursion and output reordering is applied. This task is left upon the reader.

• the "binary tree" <-> "binary search tree" issue making all the difference here.
– ig2r
Commented Dec 27, 2010 at 10:48
• `you can easily decompose the whole dump into the root node value.` Exactly. Reading all the complex answers I was thinking, "Isn't this really easy?" and yep, it is.
– Ben
Commented Feb 16, 2014 at 5:42

Based on Ondrej Tucny's answer. Valid for BST only
example:

``````     20
/  \
10  30
/\    \
6  15   35
``````

Preorder = 20 10 6 15 30 35
Post = 6 15 10 35 30 20

For a BST, In Preorder traversal; first element of array is 20. This is the root of our tree. All numbers in array which are lesser than 20 form its left subtree and greater numbers form right subtree.

``````//N = number of nodes in BST (size of traversal array)
int post[N] = {0};
int i =0;

void PretoPost(int pre[],int l,int r){
if(l==r){post[i++] = pre[l]; return;}
//pre[l] is root
//Divide array in lesser numbers and greater numbers and then call this function on them recursively
for(int j=l+1;j<=r;j++)
if(pre[j]>pre[l])
break;
//root should go in the end
post[i++] = pre[l];
return;
}
``````

Please correct me if there is any mistake.

• Correct but the square time complexity bends it on the inefficient side. Commented Jun 21, 2021 at 23:26

you are given the pre-order traversal results. then put the values to a suitable binary search tree and just follow the post-order traversal algorithm for the obtained BST.

This is the code of preorder to postorder traversal in python. I am constructing a tree so you can find any type of traversal

``````def postorder(root):
if root==None:
return
postorder(root.left)
print(root.data,end=" ")
postorder(root.right)

def preordertoposorder(a,n):
root=Node(a[0])
top=Node(0)
temp=Node(0)
temp=None
stack=[]
stack.append(root)
for i in range(1,len(a)):
while len(stack)!=0 and a[i]>stack[-1].data:
temp=stack.pop()
if temp!=None:
temp.right=Node(a[i])
stack.append(temp.right)
else:
stack[-1].left=Node(a[i])
stack.append(stack[-1].left)
return root
class Node:
def __init__(self,data):
self.data=data
self.left=None
self.right=None
a=[40,30,35,80,100]
n=5
root=preordertoposorder(a,n)
postorder(root)
# print(root.data)
# print(root.left.data)
# print(root.right.data)
# print(root.left.right.data)
# print(root.right.right.data)
``````

I know this is old but there is a better solution.

We don't have to reconstruct a BST to get the post-order from the pre-order.

Here is a simple python code that does it recursively:

``````import itertools

def postorder(preorder):
if not preorder:
return []
else:
root = preorder[0]
left = list(itertools.takewhile(lambda x: x < root, preorder[1:]))
right = preorder[len(left) + 1:]
return postorder(left) + postorder(right) + [root]

if __name__ == '__main__':
preorder = [20, 10, 6, 15, 30, 35]
print(postorder(preorder))
``````

Output:

`````` [6, 15, 10, 35, 30, 20]
``````

Explanation:

We know that we are in pre-order. This means that the root is at the index `0` of the list of the values in the BST. And we know that the elements following the root are:

• first: the elements less than the `root`, which belong to the left subtree of the root
• second: the elements greater than the `root`, which belong to the right subtree of the root

We then just call recursively the function on both subtrees (which still are in pre-order) and then chain `left + right + root` (which is the post-order).

If you have been given preorder and you want to convert it into postorder. Then you should remember that in a BST in order always give numbers in ascending order.Thus you have both Inorder as well as the preorder to construct a tree.

preorder: `6, 2, 1, 4, 3, 7, 10, 9, 11`

inorder: `1, 2, 3, 4, 6, 7, 9, 10, 11`

And its postorder: `1 3 4 2 9 11 10 7 6`

Here pre-order traversal of a binary search tree is given in array. So the 1st element of pre-order array will root of BST.We will find the left part of BST and right part of BST.All the element in pre-order array is lesser than root will be left node and All the element in pre-order array is greater then root will be right node.

``````#include <bits/stdc++.h>
using namespace std;
int arr[1002];
int no_ans = 0;
int n = 1000;
int ans[1002] ;
int k = 0;

int find_ind(int l,int r,int x){
int index = -1;
for(int i = l;i<=r;i++){
if(x<arr[i]){
index = i;
break;
}
}
if(index == -1)return index;
for(int i =l+1;i<index;i++){
if(arr[i] > x){
no_ans = 1;
return index;
}
}
for(int i = index;i<=r;i++){
if(arr[i]<x){
no_ans = 1;
return index;
}
}
return index;

}

void postorder(int l ,int r){

if(l < 0 || r >= n || l >r ) return;
ans[k++] = arr[l];
if(l==r) return;
int index = find_ind(l+1,r,arr[l]);
if(no_ans){
return;
}
if(index!=-1){
postorder(index,r);
postorder(l+1,index-1);
}
else{
postorder(l+1,r);
}
}

int main(void){

int t;
scanf("%d",&t);
while(t--){
no_ans = 0;
int n ;
scanf("%d",&n);

for(int i = 0;i<n;i++){
cin>>arr[i];
}
postorder(0,n-1);
if(no_ans){
cout<<"NO"<<endl;
}
else{

for(int i =n-1;i>=0;i--){
cout<<ans[i]<<" ";
}
cout<<endl;
}
}

return 0;
}
``````

As we Know preOrder follow parent, left, right series.

In order to construct tree we need to follow few basic steps-:

your question consist of series 6, 2,1,4,3,7,10,9,11

points-:

1. First number of series will be root(parent) i.e 6

2.Find the number which is greater than 6 so in this series 7 is first greater number in this series so right node will be starting from here and left to this number(7) is your left subtrees.

``````                      6
/   \
2     7
/  \     \
1    4     10
/     / \
3     9  11
``````

3.same way follow the basic rule of BST i.e left,root,right

the series of post order will be L, R, N i.e. 1,3,4,2,9,11,10,7,6

Here is full code )

``````class Tree:
def __init__(self, data = None):
self.left = None
self.right = None
self.data = data

if self.data is None:
self.data = data
else:
if data < self.data:
if self.left is None:
self.left = Tree(data)
else:
elif data > self.data:
if self.right is None:
self.right = Tree(data)
else:
def inOrder(self):
if self.data:
if self.left is not None:
self.left.inOrder()
print(self.data)
if self.right is not None:
self.right.inOrder()

def postOrder(self):
if self.data:
if self.left is not None:
self.left.postOrder()
if self.right is not None:
self.right.postOrder()
print(self.data)

def preOrder(self):
if self.data:
print(self.data)
if self.left is not None:
self.left.preOrder()
if self.right is not None:
self.right.preOrder()
arr = [6, 2, 1, 4, 3, 7, 10, 9, 11]
root = Tree()
for i in range(len(arr)):
print(root.inOrder())
``````

Since, it is a binary search tree, the inorder traversal will be always be the sorted elements. (left < root < right)

so, you can easily write its in-order traversal results first, which is : 1,2,3,4,6,7,9,10,11

given Pre-order : 6, 2, 1, 4, 3, 7, 10, 9, 11

In-order : left, root, right Pre-order : root, left, right Post-order : left, right, root

now, we got from pre-order, that root is 6.

now, using in-order and pre-order results: Step 1:

``````             6
/ \
/   \
/     \
/       \
{1,2,3,4}  {7,9,10,11}
``````

Step 2: next root is, using in-order traversal, 2:

``````             6
/ \
/   \
/     \
/       \
2  {7,9,10,11}
/ \
/   \
/     \
1    {3,4}
``````

Step 3: Similarly, next root is 4:

``````             6
/ \
/   \
/     \
/       \
2  {7,9,10,11}
/ \
/   \
/     \
1       4
/
3
``````

Step 4: next root is 3, but no other element is remaining to be fit in the child tree for "3". Considering next root as 7 now,

``````             6
/ \
/   \
/     \
/       \
2         7
/ \         \
/   \       {9,10,11}
/     \
1       4
/
3
``````

Step 5: Next root is 10 :

``````             6
/ \
/   \
/     \
/       \
2         7
/ \         \
/   \         10
/     \       /  \
1       4     9   11
/
3
``````

This is how, you can construct a tree, and finally find its post-order traversal, which is : 1, 3, 4, 2, 9, 11, 10, 7, 6