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# Post order traversal of binary tree without recursion

What is the algorithm for doing a post order traversal of a binary tree WITHOUT using recursion?

-
Here is a great description: geeksforgeeks.org/iterative-postorder-traversal-using-stack – Mehmet Yesin Feb 17 '15 at 8:16

Here's a link which provides two other solutions without using any visited flags.

http://www.leetcode.com/2010/10/binary-tree-post-order-traversal.html

This is obviously a stack-based solution due to the lack of parent pointer in the tree. (We wouldn't need a stack if there's parent pointer).

We would push the root node to the stack first. While the stack is not empty, we keep pushing the left child of the node from top of stack. If the left child does not exist, we push its right child. If it's a leaf node, we process the node and pop it off the stack.

We also use a variable to keep track of a previously-traversed node. The purpose is to determine if the traversal is descending/ascending the tree, and we can also know if it ascend from the left/right.

If we ascend the tree from the left, we wouldn't want to push its left child again to the stack and should continue ascend down the tree if its right child exists. If we ascend the tree from the right, we should process it and pop it off the stack.

We would process the node and pop it off the stack in these 3 cases:

1. The node is a leaf node (no children)
2. We just traverse up the tree from the left and no right child exist.
3. We just traverse up the tree from the right.
-

Here's a sample from wikipedia:

``````nonRecursivePostorder(rootNode)
nodeStack.push(rootNode)
while (! nodeStack.empty())
currNode = nodeStack.peek()
if ((currNode.left != null) and (currNode.left.visited == false))
nodeStack.push(currNode.left)
else
if ((currNode.right != null) and (currNode.right.visited == false))
nodeStack.push(currNode.right)
else
print currNode.value
currNode.visited := true
nodeStack.pop()
``````
-
Thank you for your help. – Patrik Aug 18 '09 at 15:44

Here's the version with one stack and without a visited flag:

``````private void postorder(Node head) {
return;
}

while (!stack.isEmpty()) {
Node next = stack.peek();

boolean isLeaf = (next.left == null && next.right == null);
if (finishedSubtrees || isLeaf) {
stack.pop();
System.out.println(next.value);
}
else {
if (next.right != null) {
stack.push(next.right);
}
if (next.left != null) {
stack.push(next.left);
}
}
}
}
``````
-
can you please explain your code . – aksam Jan 16 '15 at 13:01
``````import java.util.Stack;

public class IterativePostOrderTraversal extends BinaryTree {

public static void iterativePostOrderTraversal(Node root){
Node cur = root;
Node pre = root;
Stack<Node> s = new Stack<Node>();
if(root!=null)
s.push(root);
System.out.println("sysout"+s.isEmpty());
while(!s.isEmpty()){
cur = s.peek();
if(cur==pre||cur==pre.left ||cur==pre.right){// we are traversing down the tree
if(cur.left!=null){
s.push(cur.left);
}
else if(cur.right!=null){
s.push(cur.right);
}
if(cur.left==null && cur.right==null){
System.out.println(s.pop().data);
}
}else if(pre==cur.left){// we are traversing up the tree from the left
if(cur.right!=null){
s.push(cur.right);
}else if(cur.right==null){
System.out.println(s.pop().data);
}
}else if(pre==cur.right){// we are traversing up the tree from the right
System.out.println(s.pop().data);
}
pre=cur;
}
}

public static void main(String args[]){
BinaryTree bt = new BinaryTree();
Node root = bt.generateTree();
iterativePostOrderTraversal(root);
}

}
``````
-
Added Java version – Anupam Gupta Mar 31 '12 at 15:44

// the java version with flag

``````public static <T> void printWithFlag(TreeNode<T> root){
if(null == root) return;

Stack<TreeNode<T>> stack = new Stack<TreeNode<T>>();

while(stack.size() > 0){
if(stack.peek().isVisit()){
System.out.print(stack.pop().getValue() + "  ");
}else{

TreeNode<T> tempNode = stack.peek();
if(tempNode.getRight()!=null){
}

if(tempNode.getLeft() != null){
}

tempNode.setVisit(true);

}
}
}
``````
-

Here is a solution in C++ that does not require any storage for book keeping in the tree.
Instead it uses two stacks. One to help us traverse and another to store the nodes so we can do a post traversal of them.

``````std::stack<Node*> leftStack;
std::stack<Node*> rightStack;

Node* currentNode = m_root;
while( !leftStack.empty() || currentNode != NULL )
{
if( currentNode )
{
leftStack.push( currentNode );
currentNode = currentNode->m_left;
}
else
{
currentNode = leftStack.top();
leftStack.pop();

rightStack.push( currentNode );
currentNode = currentNode->m_right;
}
}

while( !rightStack.empty() )
{
currentNode = rightStack.top();
rightStack.pop();

std::cout << currentNode->m_value;
std::cout << "\n";
}
``````
-
``````void postorder_stack(Node * root){
stack ms;
ms.top = -1;
if(root == NULL) return ;

Node * temp ;
push(&ms,root);
Node * prev = NULL;
while(!is_empty(ms)){
temp = peek(ms);
/* case 1. We are nmoving down the tree. */
if(prev == NULL || prev->left == temp || prev->right == temp){
if(temp->left)
push(&ms,temp->left);
else if(temp->right)
push(&ms,temp->right);
else {
/* If node is leaf node */
printf("%d ", temp->value);
pop(&ms);
}
}
/* case 2. We are moving up the tree from left child */
if(temp->left == prev){
if(temp->right)
push(&ms,temp->right);
else
printf("%d ", temp->value);
}

/* case 3. We are moving up the tree from right child */
if(temp->right == prev){
printf("%d ", temp->value);
pop(&ms);
}
prev = temp;
}

}
``````
-

Here I am pasting different versions in c# (.net) for reference: (for in-order iterative traversal you may refer to: Help me understand Inorder Traversal without using recursion)

1. wiki (http://en.wikipedia.org/wiki/Post-order%5Ftraversal#Implementations) (elegant)
2. Another version of single stack (#1 and #2: basically uses the fact that in post order traversal the right child node is visited before visiting the actual node - so, we simply rely on the check that if stack top's right child is indeed the last post order traversal node thats been visited - i have added comments in below code snippets for details)
3. Using Two stacks version (ref: http://www.geeksforgeeks.org/iterative-postorder-traversal/) (easier: basically post order traversal reverse is nothing but pre order traversal with a simple tweak that right node is visited first, and then left node)
4. Using visitor flag (easy)
5. Unit Tests

~

``````public string PostOrderIterative_WikiVersion()
{
List<int> nodes = new List<int>();
if (null != this._root)
{
BinaryTreeNode lastPostOrderTraversalNode = null;
BinaryTreeNode iterativeNode = this._root;
Stack<BinaryTreeNode> stack = new Stack<BinaryTreeNode>();
while ((stack.Count > 0)//stack is not empty
|| (iterativeNode != null))
{
if (iterativeNode != null)
{
stack.Push(iterativeNode);
iterativeNode = iterativeNode.Left;
}
else
{
var stackTop = stack.Peek();
if((stackTop.Right != null)
&& (stackTop.Right != lastPostOrderTraversalNode))
{
//i.e. last traversal node is not right element, so right sub tree is not
//yet, traversed. so we need to start iterating over right tree
//(note left tree is by default traversed by above case)
iterativeNode = stackTop.Right;
}
else
{
//if either the iterative node is child node (right and left are null)
//or, stackTop's right element is nothing but the last traversal node
//(i.e; the element can be popped as the right sub tree have been traversed)
var top = stack.Pop();
Debug.Assert(top == stackTop);
lastPostOrderTraversalNode = top;
}
}
}
}
return this.ListToString(nodes);
}
``````

Here is post order traversal with one stack (my version)

``````public string PostOrderIterative()
{
List<int> nodes = new List<int>();
if (null != this._root)
{
BinaryTreeNode lastPostOrderTraversalNode = null;
BinaryTreeNode iterativeNode = null;
Stack<BinaryTreeNode> stack = new Stack<BinaryTreeNode>();
stack.Push(this._root);
while(stack.Count > 0)
{
iterativeNode = stack.Pop();
if ((iterativeNode.Left == null)
&& (iterativeNode.Right == null))
{
lastPostOrderTraversalNode = iterativeNode;
//make sure the stack is not empty as we need to peek at the top
//for ex, a tree with just root node doesn't have to enter loop
//and also node Peek() will throw invalidoperationexception
//if it is performed if the stack is empty
//so, it handles both of them.
while(stack.Count > 0)
{
var stackTop = stack.Peek();
bool removeTop = false;
if ((stackTop.Right != null) &&
//i.e. last post order traversal node is nothing but right node of
//stacktop. so, all the elements in the right subtree have been visted
//So, we can pop the top element
(stackTop.Right == lastPostOrderTraversalNode))
{
//in other words, we can pop the top if whole right subtree is
//traversed. i.e. last traversal node should be the right node
//as the right node will be traverse once all the subtrees of
//right node has been traversed
removeTop = true;
}
else if(
//right subtree is null
(stackTop.Right == null)
&& (stackTop.Left != null)
//last traversal node is nothing but the root of left sub tree node
&& (stackTop.Left == lastPostOrderTraversalNode))
{
//in other words, we can pop the top of stack if right subtree is null,
//and whole left subtree has been traversed
removeTop = true;
}
else
{
break;
}
if(removeTop)
{
var top = stack.Pop();
Debug.Assert(stackTop == top);
lastPostOrderTraversalNode = top;
}
}
}
else
{
stack.Push(iterativeNode);
if(iterativeNode.Right != null)
{
stack.Push(iterativeNode.Right);
}
if(iterativeNode.Left != null)
{
stack.Push(iterativeNode.Left);
}
}
}
}
return this.ListToString(nodes);
}
``````

Using two stacks

``````public string PostOrderIterative_TwoStacksVersion()
{
List<int> nodes = new List<int>();
if (null != this._root)
{
Stack<BinaryTreeNode> postOrderStack = new Stack<BinaryTreeNode>();
Stack<BinaryTreeNode> rightLeftPreOrderStack = new Stack<BinaryTreeNode>();
rightLeftPreOrderStack.Push(this._root);
while(rightLeftPreOrderStack.Count > 0)
{
var top = rightLeftPreOrderStack.Pop();
postOrderStack.Push(top);
if(top.Left != null)
{
rightLeftPreOrderStack.Push(top.Left);
}
if(top.Right != null)
{
rightLeftPreOrderStack.Push(top.Right);
}
}
while(postOrderStack.Count > 0)
{
var top = postOrderStack.Pop();
}
}
return this.ListToString(nodes);
}
``````

With visited flag in C# (.net):

``````public string PostOrderIterative()
{
List<int> nodes = new List<int>();
if (null != this._root)
{
BinaryTreeNode iterativeNode = null;
Stack<BinaryTreeNode> stack = new Stack<BinaryTreeNode>();
stack.Push(this._root);
while(stack.Count > 0)
{
iterativeNode = stack.Pop();
if(iterativeNode.visted)
{
//reset the flag, for further traversals
iterativeNode.visted = false;
}
else
{
iterativeNode.visted = true;
stack.Push(iterativeNode);
if(iterativeNode.Right != null)
{
stack.Push(iterativeNode.Right);
}
if(iterativeNode.Left != null)
{
stack.Push(iterativeNode.Left);
}
}
}
}
return this.ListToString(nodes);
}
``````

The definitions:

``````class BinaryTreeNode
{
public int Element;
public BinaryTreeNode Left;
public BinaryTreeNode Right;
public bool visted;
}

string ListToString(List<int> list)
{
string s = string.Join(", ", list);
return s;
}
``````

Unit Tests

``````[TestMethod]
public void PostOrderTests()
{
int[] a = { 13, 2, 18, 1, 5, 17, 20, 3, 6, 16, 21, 4, 14, 15, 25, 22, 24 };
BinarySearchTree bst = new BinarySearchTree();
foreach (int e in a)
{
string s1 = bst.PostOrderRecursive();
string s2 = bst.PostOrderIterativeWithVistedFlag();
string s3 = bst.PostOrderIterative();
string s4 = bst.PostOrderIterative_WikiVersion();
string s5 = bst.PostOrderIterative_TwoStacksVersion();
Assert.AreEqual(s1, s2);
Assert.AreEqual(s2, s3);
Assert.AreEqual(s3, s4);
Assert.AreEqual(s4, s5);
bst.Delete(e);
s1 = bst.PostOrderRecursive();
s2 = bst.PostOrderIterativeWithVistedFlag();
s3 = bst.PostOrderIterative();
s4 = bst.PostOrderIterative_WikiVersion();
s5 = bst.PostOrderIterative_TwoStacksVersion();
Assert.AreEqual(s1, s2);
Assert.AreEqual(s2, s3);
Assert.AreEqual(s3, s4);
Assert.AreEqual(s4, s5);
}
Debug.WriteLine(string.Format("PostOrderIterative: {0}", bst.PostOrderIterative()));
Debug.WriteLine(string.Format("PostOrderIterative_WikiVersion: {0}", bst.PostOrderIterative_WikiVersion()));
Debug.WriteLine(string.Format("PostOrderIterative_TwoStacksVersion: {0}", bst.PostOrderIterative_TwoStacksVersion()));
Debug.WriteLine(string.Format("PostOrderIterativeWithVistedFlag: {0}", bst.PostOrderIterativeWithVistedFlag()));
Debug.WriteLine(string.Format("PostOrderRecursive: {0}", bst.PostOrderRecursive()));
}
``````
-

Python with 1 stack and no flag:

``````def postorderTraversal(self, root):
ret = []
if not root:
return ret
stack = [root]
current = None
while stack:
previous = current
current = stack.pop()
if previous and ((previous is current) or (previous is current.left) or (previous is current.right)):
ret.append(current.val)
else:
stack.append(current)
if current.right:
stack.append(current.right)
if current.left:
stack.append(current.left)

return ret
``````

And what is better is with similar statements, in order traversal works too

``````def inorderTraversal(self, root):
ret = []
if not root:
return ret
stack = [root]
current = None
while stack:
previous = current
current = stack.pop()
if None == previous or previous.left is current or previous.right is current:
if current.right:
stack.append(current.right)
stack.append(current)
if current.left:
stack.append(current.left)
else:
ret.append(current.val)

return ret
``````
-

I have not added the node class as its not particularly relevant or any test cases, leaving those as an excercise for the reader etc.

``````void postOrderTraversal(node* root)
{
if(root == NULL)
return;

stack<node*> st;
st.push(root);

//store most recent 'visited' node
node* prev=root;

while(st.size() > 0)
{
node* top = st.top();
if((top->left == NULL && top->right == NULL))
{
prev = top;
cerr<<top->val<<" ";
st.pop();
continue;
}
else
{
//we can check if we are going back up the tree if the current
//node has a left or right child that was previously outputted
if((top->left == prev) || (top->right== prev))
{
prev = top;
cerr<<top->val<<" ";
st.pop();
continue;
}

if(top->right != NULL)
st.push(top->right);

if(top->left != NULL)
st.push(top->left);
}
}
cerr<<endl;
}
``````

running time O(n) - all nodes need to be visited AND space O(n) - for the stack, worst case tree is a single line linked list

-

It's very nice to see so many spirited approaches to this problem. Quite inspiring indeed!

I came across this topic searching for a simple iterative solution for deleting all nodes in my binary tree implementation. I tried some of them, and I tried something similar found elsewhere on the Net, but none of them were really to my liking.

The thing is, I am developing a database indexing module for a very specific purpose (Bitcoin Blockchain indexing), and my data is stored on disk, not in RAM. I swap in pages as needed, doing my own memory management. It's slower, but fast enough for the purpose, and with having storage on disk instead of RAM, I have no religious bearings against wasting space (hard disks are cheap).

For that reason my nodes in my binary tree have parent pointers. That's (all) the extra space I'm talking about. I need the parents because I need to iterate both ascending and descending through the tree for various purposes.

Having that in my mind, I quickly wrote down a little piece of pseudo-code on how it could be done, that is, a post-order traversal deleting nodes on the fly. It's implemented and tested, and became a part of my solution. And it's pretty fast too.

The thing is: It gets really, REALLY, simple when nodes have parent pointers, and furthermore since I can null out the parent's link to the "just departed" node.

Here's the pseudo-code for iterative post-order deletion:

``````Node current = root;
while (current)
{
if (current.left)       current = current.left;  // Dive down left
else if (current.right) current = current.right; // Dive down right
else
{
// Node "current" is a leaf, i.e. no left or right child
Node parent = current.parent; // assuming root.parent == null
if (parent)
{
// Null out the parent's link to the just departing node
if (parent.left == current) parent.left = null;
else                        parent.right = null;
}
delete current;
current = parent;
}
}
root = null;
``````

If you are interested in a more theoretical approach to coding complex collections (such as my binary tree, which is really a self-balancing red-black-tree), then check out these links:

Happy coding :-)

Søren Fog http://iprotus.eu/

-

Depth first, post order, non recursive, without stack

When you have parent:

``````   node_t
{
left,
right
parent
}

traverse(node_t rootNode)
{
node_t node = rootNode

while(node <> 0)

if (node->left <> 0) and backthreading = false then
node = node->left

continue
endif

>>> process node here <<<

if node->right <> 0 then
lNode = node->right
else
node = node->parent

endif
endwhile
``````
-

This is the approach I use for iterative, post-order traversal. I like this approach because:

1. It only handles a single transition per loop-cycle, so it's easy to follow.
2. A similar solution works for in-order and pre-order traversals

## Code:

``````enum State {LEFT, RIGHT, UP, CURR}

public void iterativePostOrder(Node root){
Deque<Node> parents = new ArrayDeque<>();
Node   curr = root;
State state = LEFT;

while(!(curr == root && state == UP)){
if(state == LEFT){
if(curr.left != null){
parents.push(curr);
curr = curr.left;
} else {
state = RIGHT;
}
}
else if(state == RIGHT) {
if(curr.right != null){
parents.push(curr);
curr = curr.right;
state = LEFT;
} else {
state = CURR;
}
}
else if(state == CURR) {
System.out.println(curr);
state = UP;
}
else if(state == UP) {
Node child = curr;
curr = parents.pop();
state = child == curr.left ? RIGHT : CURR;
}
else { throw new IllegalStateException(); }
}
}
``````

## Explanation:

You can think about the steps like this:

1. Try LEFT
• if left-node exists: Try LEFT again
• if left-node does not exist: Try RIGHT
2. Try RIGHT
• If a right node exists: Try LEFT from there
• If no right exists, you're at a leaf: Try CURR
3. Try CURR
• Print current node
• All nodes below have been executed (post-order): Try UP
4. Try UP
• If node is root, there is no UP, so EXIT
• If coming up from left, Try RIGHT
• If coming up from right, Try CURR
-

1.1 Create an empty stack

2.1 Do following while root is not NULL

``````a) Push root's right child and then root to stack.

b) Set root as root's left child.
``````

2.2 Pop an item from stack and set it as root.

``````a) If the popped item has a right child and the right child
is at top of stack, then remove the right child from stack,
push the root back and set root as root's right child.

b) Else print root's data and set root as NULL.
``````

2.3 Repeat steps 2.1 and 2.2 while stack is not empty.

-

Here is the Java implementation with two stacks

``````public static <T> List<T> iPostOrder(BinaryTreeNode<T> root) {
if (root == null) {
return Collections.emptyList();
}
List<T> result = new ArrayList<T>();
firstLevel.push(root);
while (!firstLevel.isEmpty()) {
BinaryTreeNode<T> node = firstLevel.pop();
secondLevel.push(node);
if (node.hasLeftChild()) {
firstLevel.push(node.getLeft());
}
if (node.hasRightChild()) {
firstLevel.push(node.getRight());
}
}
while (!secondLevel.isEmpty()) {
}
return result;
}
``````

Here is the unit tests

``````@Test
public void iterativePostOrderTest() {
BinaryTreeNode<Integer> bst = BinaryTreeUtil.<Integer>fromInAndPostOrder(new Integer[]{4,2,5,1,6,3,7}, new Integer[]{4,5,2,6,7,3,1});
assertThat(BinaryTreeUtil.iPostOrder(bst).toArray(new Integer[0]), equalTo(new Integer[]{4,5,2,6,7,3,1}));

}
``````
-
``````/**
* This code will ensure holding of chain(links) of nodes from the root to till the level of the tree.
* The number of extra nodes in the memory (other than tree) is height of the tree.
* I haven't used java stack instead used this ParentChain.
* This parent chain is the link for any node from the top(root node) to till its immediate parent.
* This code will not require any altering of existing BinaryTree (NO flag/parent on all the nodes).
*
*  while visiting the Node 11; ParentChain will be holding the nodes 9 -> 8 -> 7 -> 1 where (-> is parent)
*
*             1
/ \
/   \
/     \
/       \
/         \
/           \
/             \
/               \
2               7
/ \             /
/   \           /
/     \         /
/       \       /
3       6       8
/ \             /
/   \           /
4   5           9
/ \
10 11

*
* @author ksugumar
*
*/
public class InOrderTraversalIterative {
public static void main(String[] args) {
BTNode<String> rt;
String[] dataArray = {"1","2","3","4",null,null,"5",null,null,"6",null,null,"7","8","9","10",null,null,"11",null,null,null,null};
rt = BTNode.buildBTWithPreOrder(dataArray, new Counter(0));
BTDisplay.printTreeNode(rt);
inOrderTravesal(rt);
}

public static void postOrderTravesal(BTNode<String> root) {
ParentChain rootChain = new ParentChain(root);
rootChain.Parent = new ParentChain(null);

while (root != null) {

//Going back to parent
if(rootChain.leftVisited && rootChain.rightVisited) {
System.out.println(root.data); //Visit the node.
ParentChain parentChain = rootChain.Parent;
rootChain.Parent = null; //Avoid the leak
rootChain = parentChain;
root = rootChain.root;
continue;
}

//Traverse Left
if(!rootChain.leftVisited) {
rootChain.leftVisited = true;
if (root.left != null) {
ParentChain local = new ParentChain(root.left); //It is better to use pool to reuse the instances.
local.Parent = rootChain;
rootChain = local;
root = root.left;
continue;
}
}

//Traverse RIGHT
if(!rootChain.rightVisited) {
rootChain.rightVisited = true;
if (root.right != null) {
ParentChain local = new ParentChain(root.right); //It is better to use pool to reuse the instances.
local.Parent = rootChain;
rootChain = local;
root = root.right;
continue;
}
}
}
}

class ParentChain {
BTNode<String> root;
ParentChain Parent;
boolean leftVisited = false;
boolean rightVisited = false;

public ParentChain(BTNode<String> node) {
this.root = node;
}

@Override
public String toString() {
return root.toString();
}
}
``````
-
``````void display_without_recursion(struct btree **b)
{
deque< struct btree* > dtree;
if(*b)
dtree.push_back(*b);
while(!dtree.empty() )
{
struct btree* t = dtree.front();
cout << t->nodedata << " " ;
dtree.pop_front();
if(t->right)
dtree.push_front(t->right);
if(t->left)
dtree.push_front(t->left);
}
cout << endl;
}
``````
-

Please see this full Java implementation. Just copy the code and paste in your compiler. It will work fine.

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

class Node
{
Node left;
String data;
Node right;

Node(Node left, String data, Node right)
{
this.left = left;
this.right = right;
this.data = data;
}

public String getData()
{
return data;
}
}

class Tree
{
Node node;

//insert
public void insert(String data)
{
if(node == null)
node = new Node(null,data,null);
else
{

while(q.peek() != null)
{
Node temp = q.remove();
if(temp.left == null)
{
temp.left = new Node(null,data,null);
break;
}
else
{
}

if(temp.right == null)
{
temp.right = new Node(null,data,null);
break;
}
else
{
}
}
}
}

public void postorder(Node node)
{
if(node == null)
return;
postorder(node.left);
postorder(node.right);
System.out.print(node.getData()+" --> ");
}

public void iterative(Node node)
{
Stack<Node> s = new Stack<Node>();
while(true)
{
while(node != null)
{
s.push(node);
node = node.left;
}

if(s.peek().right == null)
{
node = s.pop();
System.out.print(node.getData()+" --> ");
if(node == s.peek().right)
{
System.out.print(s.peek().getData()+" --> ");
s.pop();
}
}

if(s.isEmpty())
break;

if(s.peek() != null)
{
node = s.peek().right;
}
else
{
node = null;
}
}
}
}

class Main
{
public static void main(String[] args)
{
Tree t = new Tree();
t.insert("A");
t.insert("B");
t.insert("C");
t.insert("D");
t.insert("E");

t.postorder(t.node);
System.out.println();

t.iterative(t.node);
System.out.println();
}
}
``````
-
You have a bug in your code: try 'abcdefghi' and it loops forever – Flethuseo Apr 15 '14 at 4:05
To fix the bug I changed the 'if (node == s.peek().right)' with ---> while (!s.isEmpty() && node == s.peek().right) – Flethuseo Apr 15 '14 at 4:07