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Okay, I have read through all the other related questions and cannot find one that helps with java. I get the general idea from deciphering what i can in other languages; but i am yet to figure it out.

Problem: I would like to level sort (which i have working using recursion) and print it out in the general shape of a tree.

So say i have this:

    1 
   / \
  2   3
 /   / \
4   5   6

My code prints out the level order like this:

1 2 3 4 5 6

I want to print it out like this:

1
2 3
4 5 6

Now before you give me a moral speech about doing my work... I have already finished my AP Comp Sci project and got curious about this when my teacher mentioned the Breadth First Search thing.

I don't know if it will help, but here is my code so far:

/**
  * Calls the levelOrder helper method and prints out in levelOrder.
  */
 public void levelOrder()
 {
  q = new QueueList();
  treeHeight = height();
  levelOrder(myRoot, q, myLevel);
 }

 /**
  * Helper method that uses recursion to print out the tree in 
  * levelOrder
  */
 private void levelOrder(TreeNode root, QueueList q, int curLev)
 {
  System.out.print(curLev);
  if(root == null)
  {
   return;
  }

  if(q.isEmpty())
  {
   System.out.println(root.getValue());
  }
  else
  {
   System.out.print((String)q.dequeue()+", ");
  }

  if(root.getLeft() != null)
  {
   q.enqueue(root.getLeft().getValue());
   System.out.println();
  }
  if(root.getRight() != null)
  {
   q.enqueue(root.getRight().getValue());
   System.out.println();
   curLev++;
  }

  levelOrder(root.getLeft(),q, curLev);
  levelOrder(root.getRight(),q, curLev);
 }

From what i can figure out, i will need to use the total height of the tree, and use a level counter... Only problem is my level counter keeps counting when my levelOrder uses recursion to go back through the tree.

Sorry if this is to much, but some tips would be nice. :)

share|improve this question

14 Answers 14

This is the easiest solution

public void byLevel(Node root){
     Queue<Node> level  = new LinkedList<>();
     level.add(root);
     while(!level.isEmpty()){
         Node node = level.poll();
         System.out.print(node.item + " ");
         if(node.leftChild!= null)
         level.add(node.leftChild);
         if(node.rightChild!= null)
         level.add(node.rightChild);
     }
}

https://github.com/camluca/Samples/blob/master/Tree.java in my github you can find other helpful functions in the class Tree like:

Displaying the tree

****......................................................****
                            42
            25                              65                              
    12              37              43              87              
9      13      30      --      --      --      --      99      
****......................................................****
Inorder traversal
9 12 13 25 30 37 42 43 65 87 99  
Preorder traversal
42 25 12 9 13 37 30 65 43 87 99  
Postorder traversal
9 13 12 30 37 25 43 99 87 65 42  
By Level
42 25 65 12 37 43 87 9 13 30 99  
share|improve this answer
8  
U are not printing the new line anywhere in your solution –  everconfusedGuy Oct 23 '13 at 9:57
2  
Level printing required not tree traversal. –  Rohit Kandhal Oct 25 '13 at 23:19

Here is how I would do it:

levelOrder(List<TreeNode> n) {
    List<TreeNode> next = new List<TreeNode>();
    foreach(TreeNode t : n) {
        print(t);
        next.Add(t.left);
        next.Add(t.right);
    }
    println();
    levelOrder(next);
}

(Was originally going to be real code - got bored partway through, so it's psueodocodey)

share|improve this answer
1  
I don't think that will work with recursion though. –  JavaFail Feb 11 '10 at 1:08
    
Looks good to me. +1 –  danben Feb 11 '10 at 1:10
    
but is a list First in First out??? I thought that was only a queue? –  JavaFail Feb 11 '10 at 1:11
    
Add appends to the end of the list. foreach starts taking from the beginning. Thus we get the items in order. –  Anon. Feb 11 '10 at 1:13
1  
No, there's nothing preventing the algorithm working for any arbitrary depth. If it's not working for you, I would suspect you've implemented it incorrectly. –  Anon. Feb 14 '10 at 20:03

Just thought of sharing Anon's suggestion in real java code and fixing a couple of KEY issues (like there is not an end condition for the recursion so it never stops adding to the stack, and not checking for null in the received array gets you a null pointer exception).

Also there is no exception as Eric Hauser suggests, because it is not modifying the collection its looping through, it's modifying a new one.

Here it goes:

public void levelOrder(List<TreeNode> n) {
    List<TreeNode> next = new ArrayList<TreeNode>();
    for (TreeNode t : n) {
        if (t != null) {
            System.out.print(t.getValue());
            next.add(t.getLeftChild());
            next.add(t.getRightChild());
        }
    }
    System.out.println();
    if(next.size() > 0)levelOrder(next);
}
share|improve this answer
public void printTree(TreeNode tmpRoot) {

        Queue<TreeNode> currentLevel = new LinkedList<TreeNode>();
        Queue<TreeNode> nextLevel = new LinkedList<TreeNode>();

        currentLevel.add(tmpRoot);

        while (!currentLevel.isEmpty()) {
            Iterator<TreeNode> iter = currentLevel.iterator();
            while (iter.hasNext()) {
                TreeNode currentNode = iter.next();
                if (currentNode.left != null) {
                    nextLevel.add(currentNode.left);
                }
                if (currentNode.right != null) {
                    nextLevel.add(currentNode.right);
                }
                System.out.print(currentNode.value + " ");
            }
            System.out.println();
            currentLevel = nextLevel;
            nextLevel = new LinkedList<TreeNode>();

        }

    }

This question was asked to me in one of the interviews...
share|improve this answer

The answer is close....the only issue I could see with it is that if a tree doesn't have a node in a particular position, you would set that pointer to null. What happens when you try to put a null pointer into the list?

Here is something I did for a recent assignment. It works flawlessly. You can use it starting from any root.

  //Prints the tree in level order
  public void printTree(){
    printTree(root);
  }

 public void printTree(TreeNode tmpRoot){

    //If the first node isn't null....continue on
    if(tmpRoot != null){

        Queue<TreeNode> currentLevel = new LinkedList<TreeNode>(); //Queue that holds the nodes on the current level
        Queue<TreeNode> nextLevel = new LinkedList<TreeNode>();     //Queue the stores the nodes for the next level

        int treeHeight = height(tmpRoot);     //Stores the height of the current tree
        int levelTotal = 0;  //keeps track of the total levels printed so we don't  pass the height and print a billion "null"s

        //put the root on the currnt level's queue
        currentLevel.add(tmpRoot);

        //while there is still another level to print and we haven't gone past the tree's height
        while(!currentLevel.isEmpty()&& (levelTotal< treeHeight)){

            //Print the next node on the level, add its childen to the next level's queue, and dequeue the node...do this until the current level has been printed
            while(!currentLevel.isEmpty()){

                //Print the current value
                System.out.print(currentLevel.peek().getValue()+" ");

                //If there is a left pointer, put the node on the nextLevel's stack. If there is no ponter, add a node with a null value to the next level's stack
                tmpRoot = currentLevel.peek().getLeft();
                if(tmpRoot != null)
                    nextLevel.add(tmpRoot);
                else
                    nextLevel.add(new TreeNode(null));

                //If there is a right pointer, put the node on the nextLevel's stack. If there is no ponter, add a node with a null value to the next level's stack
                tmpRoot = currentLevel.remove().getRight();
                if(tmpRoot != null)
                    nextLevel.add(tmpRoot);
                else
                    nextLevel.add(new TreeNode(null));

            }//end while(!currentLevel.isEmpty())

            //populate the currentLevel queue with items from the next level
            while(!nextLevel.isEmpty()){
                currentLevel.add(nextLevel.remove());
            }

            //Print a blank line to show height
            System.out.println("");

            //flag that we are working on the next level
            levelTotal++;

        }//end while(!currentLevel.isEmpty())

    }//end if(tmpRoot != null)

}//end method printTree

public int height(){
    return height(getRoot());
}

public int height(TreeNode tmpRoot){

    if (tmpRoot == null)
        return 0;
    int leftHeight = height(tmpRoot.getLeft());
    int rightHeight = height(tmpRoot.getRight());

    if(leftHeight >= rightHeight)
        return leftHeight + 1;
    else
        return rightHeight + 1;
 }
share|improve this answer

I really like the simplicity of Anon's code; its elegant. But, sometimes elegant code doesn't always translate into code that is intuitively easy to grasp. So, here's my attempt to show a similar approach that requires Log(n) more space, but should read more naturally to those who are most familiar with depth first search (going down the length of a tree)

The following snippet of code sets nodes belonging to a particular level in a list, and arranges that list in a list that holds all the levels of the tree. Hence the List<List<BinaryNode<T>>> that you will see below. The rest should be fairly self explanatory.

public static final <T extends Comparable<T>> void printTreeInLevelOrder(
        BinaryTree<T> tree) {
    BinaryNode<T> root = tree.getRoot();
    List<List<BinaryNode<T>>> levels = new ArrayList<List<BinaryNode<T>>>();
    addNodesToLevels(root, levels, 0);
    for(List<BinaryNode<T>> level: levels){
        for(BinaryNode<T> node: level){
            System.out.print(node+ " ");
        }
        System.out.println();
    }
}

private static final <T extends Comparable<T>> void addNodesToLevels(
        BinaryNode<T> node, List<List<BinaryNode<T>>> levels, int level) {
    if(null == node){
        return;
    }

    List<BinaryNode<T>> levelNodes;
    if(levels.size() == level){
        levelNodes = new ArrayList<BinaryNode<T>>();
        levels.add(level, levelNodes);
    }
    else{
        levelNodes = levels.get(level);
    }

    levelNodes.add(node);
    addNodesToLevels(node.getLeftChild(), levels, level+1);
    addNodesToLevels(node.getRightChild(), levels, level+1);
}
share|improve this answer

Following implementation uses 2 queues. Using ListBlokcingQueue here but any queue would work.

import java.util.concurrent.*;

public class Test5 {

    public class Tree {
        private String value;
        private Tree left;
        private Tree right;

        public Tree(String value) {
            this.value = value;
        }

        public void setLeft(Tree t) {
            this.left = t;
        }

        public void setRight(Tree t) {
            this.right = t;
        }

        public Tree getLeft() {
            return this.left;
        }

        public Tree getRight() {
            return this.right;
        }

        public String getValue() {
            return this.value;
        }
    }

    Tree tree = null;

    public void setTree(Tree t) {
        this.tree = t;
    }

    public void printTree() {
        LinkedBlockingQueue<Tree> q = new LinkedBlockingQueue<Tree>();
        q.add(this.tree);
        while (true) {
            LinkedBlockingQueue<Tree> subQueue = new LinkedBlockingQueue<Tree>();
            while (!q.isEmpty()) {
                Tree aTree = q.remove();
                System.out.print(aTree.getValue() + ", ");
                if (aTree.getLeft() != null) {
                    subQueue.add(aTree.getLeft());
                }
                if (aTree.getRight() != null) {
                    subQueue.add(aTree.getRight());
                }
            }
            System.out.println("");
            if (subQueue.isEmpty()) {
                return;
            } else {
                q = subQueue;
            }
        }
    }

    public void testPrint() {
        Tree a = new Tree("A");
        a.setLeft(new Tree("B"));
        a.setRight(new Tree("C"));
        a.getLeft().setLeft(new Tree("D"));
        a.getLeft().setRight(new Tree("E"));
        a.getRight().setLeft(new Tree("F"));
        a.getRight().setRight(new Tree("G"));
        setTree(a);
        printTree();
    }

    public static void main(String args[]) {
        Test5 test5 = new Test5();
        test5.testPrint();
    }
}
share|improve this answer

Try this, using 2 Queues to keep track of the levels.

public static void printByLevel(Node root){
    LinkedList<Node> curLevel = new LinkedList<Node>();
    LinkedList<Node> nextLevel = curLevel;

    StringBuilder sb = new StringBuilder();
    curLevel.add(root);
    sb.append(root.data + "\n");

    while(nextLevel.size() > 0){
        nextLevel = new LinkedList<Node>();
        for (int i = 0; i < curLevel.size(); i++){
            Node cur = curLevel.get(i);
            if (cur.left != null) {
                nextLevel.add(cur.left);
                sb.append(cur.left.data + " ");
            }
            if (cur.right != null) {
                nextLevel.add(cur.right);
                sb.append(cur.right.data + " ");
            }
        }
        if (nextLevel.size() > 0) {
            sb.append("\n");
            curLevel = nextLevel;

        } 
    }
    System.out.println(sb.toString());
}
share|improve this answer
public void printAllLevels(BNode node, int h){
    int i;
    for(i=1;i<=h;i++){
        printLevel(node,i);
        System.out.println();
    }
}

public void printLevel(BNode node, int level){
    if (node==null)
        return;
    if (level==1)
        System.out.print(node.value + " ");
        else if (level>1){
            printLevel(node.left, level-1);
            printLevel(node.right, level-1);
        }
}

public int height(BNode node) {
    if (node == null) {
        return 0;
    } else {
        return 1 + Math.max(height(node.left),
                height(node.right));
    }
}

First of all, I do not like to take credit for this solution. It's a modification of somebody's function and I tailored it to provide the solution.

I am using 3 functions here.

  1. First I calculate the height of the tree.
  2. I then have a function to print a particular level of the tree.
  3. Using the height of the tree and the function to print the level of a tree, I traverse the tree and iterate and print all levels of the tree using my third function.

I hope this helps.

EDIT: The time complexity on this solution for printing all node in level order traversal will not be O(n). The reason being, each time you go down a level, you will visit the same nodes again and again.

If you are looking for a O(n) solution, i think using Queues would be a better option.

share|improve this answer

I think we can achieve this by using one queue itself. This is a java implementation using one queue only. Based on BFS...

public void BFSPrint()
{
    Queue<Node> q = new LinkedList<Node>();
    q.offer(root);
    BFSPrint(q);
}

private void BFSPrint(Queue<Node> q)
{
    if(q.isEmpty())
        return;
    int qLen = q.size(),i=0;
     /*limiting it to q size when it is passed, 
       this will make it print in next lines. if we use iterator instead, 
       we will again have same output as question, because iterator 
       will end only q empties*/
    while(i<qLen) 
        {
        Node current = q.remove();
        System.out.print(current.data+" ");
        if(current.left!=null)
            q.offer(current.left);
        if(current.right!=null)
            q.offer(current.right);
        i++;
    }
    System.out.println();
    BFSPrint(q);

}
share|improve this answer

the top solutions only print the children of each node together. This is wrong according to the description.

What we need is all the nodes of the same level together in the same line.

1) Apply BFS

2) Store heights of nodes to a map that will hold level - list of nodes.

3) Iterate over the map and print out the results.

See Java code below:

public void printByLevel(Node root){
    Queue<Node> q = new LinkedBlockingQueue<Node>();
    root.visited = true;
    root.height=1;
    q.add(root);
    //Node height - list of nodes with same level
    Map<Integer, List<Node>> buckets = new HashMap<Integer, List<Node>>();
    addToBuckets(buckets, root);
    while (!q.isEmpty()){
        Node r = q.poll();

        if (r.adjacent!=null)
        for (Node n : r.adjacent){
            if (!n.visited){
                n.height = r.height+1; //adjust new height
                addToBuckets(buckets, n);
                n.visited = true;
                q.add(n);
            }
        }
    }

    //iterate over buckets and print each list
    printMap(buckets);

}

//helper method that adds to Buckets list
private void addToBuckets(Map<Integer, List<Node>> buckets, Node n){
        List<Node> currlist = buckets.get(n.height);
    if (currlist==null)
    {
        List<Node> list = new ArrayList<Node>();
        list.add(n);
        buckets.put(n.height, list);
    }
    else{
        currlist.add(n);
    }

}

//prints the Map
private void printMap(Map<Integer, List<Node>> buckets){
    for (Entry<Integer, List<Node>> e : buckets.entrySet()){
        for (Node n : e.getValue()){
            System.out.print(n.value + " ");
        }
    System.out.println();
}
share|improve this answer
public class PrintATreeLevelByLevel {
public static class Node{
    int data;
    public Node left;
    public Node right;

    public Node(int data){
        this.data = data;
        this.left = null;
        this.right = null;

    }
}

public void printATreeLevelByLevel(Node n){
    Queue<Node> queue =  new LinkedList<Node>();
    queue.add(n);
    int node = 1; //because at root
    int child = 0; //initialize it with 0 
    while(queue.size() != 0){
        Node n1 = queue.remove();
        node--;
        System.err.print(n1.data +" ");

        if(n1.left !=null){
            queue.add(n1.left);
            child ++;
        }
        if(n1.right != null){
            queue.add(n1.right);
            child ++;
        }
        if( node == 0){
            System.err.println();
            node = child ;
            child = 0;
        }

    }


}

public static void main(String[]args){
    PrintATreeLevelByLevel obj = new PrintATreeLevelByLevel();
    Node node1 = new Node(1);
    Node node2 = new Node(2);
    Node node3 = new Node(3);
    Node node4 = new Node(4);
    Node node5 = new Node(5);
    Node node6 = new Node(6);
    Node node7 = new Node(7);
    Node node8 = new Node(8);

    node4.left = node2;
    node4.right = node6;
    node2.left = node1;
//  node2.right = node3;
    node6.left = node5;
    node6.right = node7;
    node1.left = node8;
    obj.printATreeLevelByLevel(node4);
}

}

share|improve this answer

Simplest way to do this without using any level information implicitly assumed to be in each Node. Just append a 'null' node after each level. check for this null node to know when to print a new line:

public class BST{
     private Node<T> head;
     BST(){}
     public void setHead(Node<T> val){head = val;}

     public static void printBinaryTreebyLevels(Node<T> head){
         if(head == null) return;
         Queue<Node<T>> q = new LinkedList<>();//assuming you have type inference (JDK 7)
         q.add(head);
         q.add(null);
         while(q.size() > 0){
              Node n = q.poll();
              if(n == null){
                   System.out.println();
                   q.add(null);
                   n = q.poll();
              }
              System.out.print(n.value+" ");
              if(n.left != null) q.add(n.left);
              if(n.right != null) q.add(n.right);
         }
     }
     public static void main(String[] args){
           BST b = new BST();
           c = buildListedList().getHead();//assume we have access to this for the sake of the example
           b.setHead(c);
           printBinaryTreeByLevels();
           return;
     }
}
class Node<T extends Number>{
     public Node left, right;
     public T value;
     Node(T val){value = val;}
}
share|improve this answer

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