# Non-recursive method to find all nodes of each vine of Binary Search Tree using a stack

I am trying to create one method that will find all nodes from the paths from the root to each leaf in a binary search tree and store them in an array. So far I have made a rediculous method that works fine if the right side of the root doesn't have more than one node that's parent to two nodes. It took me a long time to figure out what was wrong, but if my current method is to work I have to know the tree, and that's just stupid.

This is basically what I'm trying to do:

Output: `[[8, 3, 1],[8 ,3 ,6 ,4],[8, 3, 6, 7],[8, 10, 14, 13]]`

I want to avoid recursion and rather use stack. But I don't see how I can "control" which nodes to pop from the stack.. What if they have subtrees with subtrees.

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maybe you should google this: depth first search –  Alex Lynch Nov 6 '12 at 14:34
Why does the subject call for a "non-recursive" method? –  Patricia Shanahan Nov 6 '12 at 19:35
@PatriciaShanahan We are "physically" proving differences for our application. Not only Big-O, but ms. etc. Pros and cons. So far I have a regular in-order traversal. In `if(p.right == null && p.left == null)` I print out `stringValues` and then `clear it ( = "" ) `. This string gets values appended in `if(p.left!=null)` and `if(p.right!=null)`. For this image, it logs out `8 3 1`, `6 4`, `7` and `10 14 13`. So when clearing the string in the last statement, I clear the previous vine, but I obviously need parts of the vine to stay sometimes –  Sti Nov 6 '12 at 20:11

Something like this:

``````function Explore(node, currentPath)

If node has any Children
If node has a left child
Explore(left child, currentPath)
if node has a right child
Explore(right child, currentPath)
Else
Node is a leaf node, report currentPath as a result.

Remove the last node from currentPath
end
``````
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http://en.wikipedia.org/wiki/Tree_traversal#Preorder

Wikipedia explains it better than I ever could. You want Depth First traversal, and when you hit a leaf, record the entire path taken so far.

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If you are not going to do recursion, you have to store explicitly in a stack the sort of data that would be implied by where a call was done or in local variables in a recursive solution. In this case, I used a couple of booleans to indicate whether the left subtree has been done and whether the right subtree has been done.

I could not quite bring myself to do it all in one method. I do use a separate method to extract the list of node labels from the stack. Also, to save carrying around a separate label list, I'm not treating it strictly as a stack. I think the changes to make it a strict stack are fairly obvious. I've only commented the core code. Feel free to ask if anything else is unclear.

I do want to emphasize that this is not a design I recommend. I would use recursion, which I think would result in simpler code. I have also not spent a lot of time polishing it.

``````  import java.util.Stack;

public static void main(String[] args) {
TreeNode root;
boolean firstLeaf = true;
root = makeTree();
Stack<StackNode> stack = new Stack<StackNode>();
stack.push(new StackNode(root));
System.out.print("[");
while (stack.size() > 0) {
// Decide what to do next with the top element
StackNode top = stack.lastElement();
if (top.tn == null) {
// Nothing to do for a null subtree
stack.pop();
} else {
if (top.tn.left == null && top.tn.right == null) {
// leaf element, print it out and pop it.
if(!firstLeaf) {
System.out.print(",");
}
firstLeaf = false;
System.out.print("[" + getLabelList(stack) + "]");
stack.pop();
} else {
if (top.leftDone) {
if (!top.rightDone) {
stack.push(new StackNode(top.tn.right));
top.rightDone = true;
} else {
// Done both subtrees
stack.pop();
}
} else {
stack.push(new StackNode(top.tn.left));
top.leftDone = true;
}
}
}
}
System.out.println("]");
}

private static class StackNode {
TreeNode tn;
boolean leftDone;
boolean rightDone;

public StackNode(TreeNode tn) {
this.tn = tn;
}
}

private static String getLabelList(Stack<StackNode> in) {
String result = "";
for (StackNode node : in) {
if (result.length() > 0) {
result += ", ";
}
result += node.tn.label;
}
//System.out.print("getLabelList: " + result);
return result;
}

private static TreeNode makeTree() {
TreeNode l;
TreeNode r;
l = new TreeNode(4, null, null);
r = new TreeNode(7, null, null);
r = new TreeNode(6, l, r);
l = new TreeNode(1, null, null);
l = new TreeNode(3, l, r);
r = new TreeNode(14, new TreeNode(13, null, null), null);
r = new TreeNode(10, null, r);
return (new TreeNode(8, l, r));
}
}

class StackNode {
TreeNode current;
boolean leftSubtreeDone;
}

class TreeNode {
int label;
TreeNode left;
TreeNode right;

public TreeNode(int label, TreeNode left, TreeNode right) {
this.label = label;
this.left = left;
this.right = right;
}
}
``````
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Woa! Looks great, will try it. I'm not too familiar with stacks, but I know the basics, but `.lastElement()` is new to me.. What is different from that to `.peek()` or `.pop()`? –  Sti Nov 6 '12 at 23:08
I used it because it is available in java.util.stack. It looks at the top element without popping it. In a pure stack, you could get the same effect by popping the top element, taking a look at it, and remembering to put it back on the stack before taking the next action. –  Patricia Shanahan Nov 6 '12 at 23:22

See Iterative DFS vs Recursive DFS and different elements order for both recursive and iterative (using a stack) DFS implementations.

Edit:

It's really quite readable if you ignore the c++ specific syntax, but here's a brief pseudocodish description.

``````create a stack of nodes
push root node of the tree on the stack.
while (the stack is not empty) {
pop the top of the stack, call it 'node'
if (we have not already marked 'node') {
print the name of that node
mark that node
push any children of that node onto the stack
}
}
``````

What you will need, that isn't required in the recursive method is a way of keeping track of which nodes you've already visited (that's what's meant by 'marking' a node). This can either be a property of the node itself, or you can maintain a separate data structure. A Java HashSet would work well for this.

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I don't really understand C++ so I'm having a hard time understanding what he has done.. I am trying to iterate through a binary search tree using a loop and a stack - ultimately to `find all vines` (from root-to-leaf). I can't find answers anywhere.. Or is it just not doable? –  Sti Nov 6 '12 at 22:37