# Help me understand Inorder Traversal without using recursion

I am able to understand preorder traversal without using recursion, but I'm having a hard time with inorder traversal. I just don't seem to get it, perhaps, because I haven't understood the inner working of recursion.

This is what I've tried so far:

def traverseInorder(node):
lifo = Lifo()
lifo.push(node)
while True:
if node is None:
break
if node.left is not None:
lifo.push(node.left)
node = node.left
continue
prev = node
while True:
if node is None:
break
print node.value
prev = node
node = lifo.pop()
node = prev
if node.right is not None:
lifo.push(node.right)
node = node.right
else:
break


The inner while-loop just doesn't feel right. Also, some of the elements are getting printed twice; may be I can solve this by checking if that node has been printed before, but that requires another variable, which, again, doesn't feel right. Where am I going wrong?

I haven't tried postorder traversal, but I guess it's similar and I will face the same conceptual blockage there, too.

P.S.: Definitions of Lifo and Node:

class Node:
def __init__(self, value, left=None, right=None):
self.value = value
self.left = left
self.right = right

class Lifo:
def __init__(self):
self.lifo = ()
def push(self, data):
self.lifo = (data, self.lifo)
def pop(self):
if len(self.lifo) == 0:
return None
ret, self.lifo = self.lifo
return ret

-

traverse(node):
if node != None do:
traverse(node.left)
print node.value
traverse(node.right)
endif


This is a clear case of tail recursion, so you can easily turn it into a while-loop.

traverse(node):
while node != None do:
traverse(node.left)
print node.value
node = node.right
endwhile


You're left with a recursive call. What the recursive call does is push a new context on the stack, run the code from the beginning, then retrieve the context and keep doing what it was doing. So, you create a stack for storage, and a loop that determines, on every iteration, whether we're in a "first run" situation (non-null node) or a "returning" situation (null node, non-empty stack) and runs the appropriate code:

traverse(node):
stack = []
while !empty(stack) || node != None do:
if node != None do: // this is a normal call, recurse
push(stack,node)
node = node.left
else // we are now returning: pop and print the current node
node = pop(stack)
print node.value
node = node.right
endif
endwhile


The hard thing to grasp is the "return" part: you have to determine, in your loop, whether the code you're running is in the "entering the function" situation or in the "returning from a call" situation, and you will have an if/else chain with as many cases as you have non-terminal recursions in your code.

In this specific situation, we're using the node to keep information about the situation. Another way would be to store that in the stack itself (just like a computer does for recursion). With that technique, the code is less optimal, but easier to follow

traverse(node):
// entry:
if node == NULL do return
traverse(node.left)
// after-left-traversal:
print node.value
traverse(node.right)

traverse(node):
stack = [node,'entry']
while !empty(stack) do:
[node,state] = pop(stack)
switch state:
case 'entry':
if node == None do: break; // return
push(stack,[node.left,'entry']) // recursive call
break;
case 'after-left-traversal':
print node.value;
// tail call : no return address
push(stack,[node.right,'entry']) // recursive call
end
endwhile

-
@Victor: Thank you! Your hint to think about the parts of code that have to be run in "entering-the-function" situation and "returning-from-a-call" situation helped me understand intuitively. Also, thanks for the intermediate step where you unwound the tail-recursion; I've heard about it, but seeing it in action helped a lot! – Srikanth Jan 22 '10 at 14:05
That's a nice explanation... I figured the same in an difficult way.. But the above way of step-by-step breakdown has made it understand very simpler – Harish Aug 16 '10 at 4:44
I don't think traverse(node): if node != None do: traverse(node.left) print node.value traverse(node.right) endif is tail recursive – Jackson Tale Aug 13 '13 at 11:26
I agree with @JacksonTale. This is definitely not a clear case of tail recursion. Tail recursion requires a single recursive call. Recursive tree traversal is actually a typical example of non-tail-recursion. – bluenote10 Jan 11 at 22:25

Here is a simple in-order non-recursive c++ code ..

void inorder (node *n)
{
stack s;

while(n){
s.push(n);
n=n->left;
}

while(!s.empty()){
node *t=s.pop();
cout<<t->data;
t=t->right;

while(t){
s.push(t);
t = t->left;
}
}
}

-
so much thanks dude – Vincent Dec 21 '12 at 10:47
def print_tree_in(root):
stack = []
current = root
while True:
while current is not None:
stack.append(current)
current = current.getLeft();
if not stack:
return
current = stack.pop()
print current.getValue()
while current.getRight is None and stack:
current = stack.pop()
print current.getValue()
current = current.getRight();

-
def traverseInorder(node):
lifo = Lifo()

while node is not None:
if node.left is not None:
lifo.push(node)
node = node.left
continue

print node.value

if node.right is not None:
node = node.right
continue

node = lifo.Pop()
if node is not None :
print node.value
node = node.right


PS: I don't know Python so there may be a few syntax issues.

-
Yeah, your continues are pointless. :) – Lennart Regebro Jan 22 '10 at 11:10

Here is a sample of in order traversal using stack in c# (.net):

(for post order iterative you may refer to: Post order traversal of binary tree without recursion)

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


Here is a sample with visited flag:

public string InorderIterative_VisitedFlag()
{
List<int> nodes = new List<int>();
if (null != this._root)
{
Stack<BinaryTreeNode> stack = new Stack<BinaryTreeNode>();
BinaryTreeNode iterativeNode = null;
stack.Push(this._root);
while(stack.Count > 0)
{
iterativeNode = stack.Pop();
if(iterativeNode.visted)
{
iterativeNode.visted = false;
}
else
{
iterativeNode.visted = true;
if(iterativeNode.Right != null)
{
stack.Push(iterativeNode.Right);
}
stack.Push(iterativeNode);
if (iterativeNode.Left != null)
{
stack.Push(iterativeNode.Left);
}
}
}
}
return this.ListToString(nodes);
}


the definitions of the binarytreenode, listtostring utility:

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

class BinaryTreeNode
{
public int Element;
public BinaryTreeNode Left;
public BinaryTreeNode Right;
}

-

State can be remembered implicitly,

traverse(node) {
if(!node) return;
push(stack, node);
while (!empty(stack)) {
/*Remember the left nodes in stack*/
while (node->left) {
push(stack, node->left);
node = node->left;
}

/*Process the node*/
printf("%d", node->data);

/*Do the tail recursion*/
if(node->right) {
node = node->right
} else {
node = pop(stack); /*New Node will be from previous*/
}
}
}

-
Negative. This version gets stuck in an infinite loop around the bottom of the tree. – Dathan Oct 11 '12 at 20:15

@Victor, I have some suggestion on your implementation trying to push the state into the stack. I don't see it is necessary. Because every element you take from the stack is already left traversed. so instead of store the information into the stack, all we need is a flag to indicate if the next node to be processed is from that stack or not. Following is my implementation which works fine:

def intraverse(node):
stack = []
leftChecked = False
while node != None:
if not leftChecked and node.left != None:
stack.append(node)
node = node.left
else:
print node.data
if node.right != None:
node = node.right
leftChecked = False
elif len(stack)>0:
node = stack.pop()
leftChecked = True
else:
node = None

-

def in_order_search(node):
stack = Stack()
current = node

while True:
while current is not None:
stack.push(current)
current = current.l_child

if stack.size() == 0:
break

current = stack.pop()
print(current.data)
current = current.r_child

-

This may be helpful (Java implementation)

public void inorderDisplay(Node root) {
Node current = root;
while (true) {
if (current != null) {
stack.push(current);
current = current.left;
} else if (!stack.isEmpty()) {
current = stack.poll();
System.out.print(current.data + " ");
current = current.right;
} else {
break;
}
}
}

-

I think part of the problem is the use of the "prev" variable. You shouldn't have to store the previous node you should be able to maintain the state on the stack (Lifo) itself.

From Wikipedia, the algorithm you are aiming for is:

1. Visit the root.
2. Traverse the left subtree
3. Traverse the right subtree

In pseudo code (disclaimer, I don't know Python so apologies for the Python/C++ style code below!) your algorithm would be something like:

lifo = Lifo();
lifo.push(rootNode);

while(!lifo.empty())
{
node = lifo.pop();
if(node is not None)
{
print node.value;
if(node.right is not None)
{
lifo.push(node.right);
}
if(node.left is not None)
{
lifo.push(node.left);
}
}
}


For postorder traversal you simply swap the order you push the left and right subtrees onto the stack.

-
@Paolo: This is pre-order traversal, not in-order. Thanks for your reply, anyway :) – Srikanth Jan 22 '10 at 18:53
D'oh! Mis-read the question... – Paolo Jan 22 '10 at 20:11