153

How can I print a binary tree in Java so that the output is like:

   4 
  / \ 
 2   5 

My node:

public class Node<A extends Comparable> {
    Node<A> left, right;
    A data;

    public Node(A data){
        this.data = data;
    }
}
  • 5
    That's a tricky one. I think you have to determine the depth of the tree first. Personally, I'd just dump the node graph into graphviz and let it deal with it. :-) – Omnifarious Feb 11 '11 at 3:31
  • It seems like if you had a lot of elements, the root element would have a HUGE edge coming from it. – Kevin Evans Feb 11 '11 at 3:32
  • I have a getDept() method in the tree – Tian Feb 11 '11 at 3:34
  • 1
    Just because the idea amused me, I wrote the code in C++ and had it spit out graphviz digraph format. Beautifully formatted trees. – Omnifarious Feb 11 '11 at 4:28

26 Answers 26

222

I've created simple binary tree printer. You can use and modify it as you want, but it's not optimized anyway. I think that a lot of things can be improved here ;)

import java.util.ArrayList;
import java.util.Collections;
import java.util.List;

public class BTreePrinterTest {

    private static Node<Integer> test1() {
        Node<Integer> root = new Node<Integer>(2);
        Node<Integer> n11 = new Node<Integer>(7);
        Node<Integer> n12 = new Node<Integer>(5);
        Node<Integer> n21 = new Node<Integer>(2);
        Node<Integer> n22 = new Node<Integer>(6);
        Node<Integer> n23 = new Node<Integer>(3);
        Node<Integer> n24 = new Node<Integer>(6);
        Node<Integer> n31 = new Node<Integer>(5);
        Node<Integer> n32 = new Node<Integer>(8);
        Node<Integer> n33 = new Node<Integer>(4);
        Node<Integer> n34 = new Node<Integer>(5);
        Node<Integer> n35 = new Node<Integer>(8);
        Node<Integer> n36 = new Node<Integer>(4);
        Node<Integer> n37 = new Node<Integer>(5);
        Node<Integer> n38 = new Node<Integer>(8);

        root.left = n11;
        root.right = n12;

        n11.left = n21;
        n11.right = n22;
        n12.left = n23;
        n12.right = n24;

        n21.left = n31;
        n21.right = n32;
        n22.left = n33;
        n22.right = n34;
        n23.left = n35;
        n23.right = n36;
        n24.left = n37;
        n24.right = n38;

        return root;
    }

    private static Node<Integer> test2() {
        Node<Integer> root = new Node<Integer>(2);
        Node<Integer> n11 = new Node<Integer>(7);
        Node<Integer> n12 = new Node<Integer>(5);
        Node<Integer> n21 = new Node<Integer>(2);
        Node<Integer> n22 = new Node<Integer>(6);
        Node<Integer> n23 = new Node<Integer>(9);
        Node<Integer> n31 = new Node<Integer>(5);
        Node<Integer> n32 = new Node<Integer>(8);
        Node<Integer> n33 = new Node<Integer>(4);

        root.left = n11;
        root.right = n12;

        n11.left = n21;
        n11.right = n22;

        n12.right = n23;
        n22.left = n31;
        n22.right = n32;

        n23.left = n33;

        return root;
    }

    public static void main(String[] args) {

        BTreePrinter.printNode(test1());
        BTreePrinter.printNode(test2());

    }
}

class Node<T extends Comparable<?>> {
    Node<T> left, right;
    T data;

    public Node(T data) {
        this.data = data;
    }
}

class BTreePrinter {

    public static <T extends Comparable<?>> void printNode(Node<T> root) {
        int maxLevel = BTreePrinter.maxLevel(root);

        printNodeInternal(Collections.singletonList(root), 1, maxLevel);
    }

    private static <T extends Comparable<?>> void printNodeInternal(List<Node<T>> nodes, int level, int maxLevel) {
        if (nodes.isEmpty() || BTreePrinter.isAllElementsNull(nodes))
            return;

        int floor = maxLevel - level;
        int endgeLines = (int) Math.pow(2, (Math.max(floor - 1, 0)));
        int firstSpaces = (int) Math.pow(2, (floor)) - 1;
        int betweenSpaces = (int) Math.pow(2, (floor + 1)) - 1;

        BTreePrinter.printWhitespaces(firstSpaces);

        List<Node<T>> newNodes = new ArrayList<Node<T>>();
        for (Node<T> node : nodes) {
            if (node != null) {
                System.out.print(node.data);
                newNodes.add(node.left);
                newNodes.add(node.right);
            } else {
                newNodes.add(null);
                newNodes.add(null);
                System.out.print(" ");
            }

            BTreePrinter.printWhitespaces(betweenSpaces);
        }
        System.out.println("");

        for (int i = 1; i <= endgeLines; i++) {
            for (int j = 0; j < nodes.size(); j++) {
                BTreePrinter.printWhitespaces(firstSpaces - i);
                if (nodes.get(j) == null) {
                    BTreePrinter.printWhitespaces(endgeLines + endgeLines + i + 1);
                    continue;
                }

                if (nodes.get(j).left != null)
                    System.out.print("/");
                else
                    BTreePrinter.printWhitespaces(1);

                BTreePrinter.printWhitespaces(i + i - 1);

                if (nodes.get(j).right != null)
                    System.out.print("\\");
                else
                    BTreePrinter.printWhitespaces(1);

                BTreePrinter.printWhitespaces(endgeLines + endgeLines - i);
            }

            System.out.println("");
        }

        printNodeInternal(newNodes, level + 1, maxLevel);
    }

    private static void printWhitespaces(int count) {
        for (int i = 0; i < count; i++)
            System.out.print(" ");
    }

    private static <T extends Comparable<?>> int maxLevel(Node<T> node) {
        if (node == null)
            return 0;

        return Math.max(BTreePrinter.maxLevel(node.left), BTreePrinter.maxLevel(node.right)) + 1;
    }

    private static <T> boolean isAllElementsNull(List<T> list) {
        for (Object object : list) {
            if (object != null)
                return false;
        }

        return true;
    }

}

Output 1 :

         2               
        / \       
       /   \      
      /     \     
     /       \    
     7       5       
    / \     / \   
   /   \   /   \  
   2   6   3   6   
  / \ / \ / \ / \ 
  5 8 4 5 8 4 5 8 

Output 2 :

       2               
      / \       
     /   \      
    /     \     
   /       \    
   7       5       
  / \       \   
 /   \       \  
 2   6       9   
    / \     /   
    5 8     4   
  • 1
    how to convert this output to horizontal? – jijesh Aj Aug 26 '13 at 6:05
  • For horizontal output is better to use Vasya Novikov's solution. – michal.kreuzman Aug 26 '13 at 14:58
  • 3
    It will be great if you can elaborate on choosing 2^n - 1 as first spaces and 2^(n+1) - 1 as the between spaces – DJ' Sep 16 '13 at 0:18
  • It is good for balanced trees as I tried it for one of the right-skewed trees of 15 values and it became very unmanageable to see the print. – i_am_zero Jan 3 '15 at 8:20
  • 3
    My tree is 44 layers deep, so java crashes when trying to print 8796093022207 whitespaces. So be warned. – CX gamer Feb 11 '17 at 13:29
271

Print a [large] tree by lines.

output example:

z
├── c
│   ├── a
│   └── b
├── d
├── e
│   └── asdf
└── f

code:

public class TreeNode {

    final String name;
    final List<TreeNode> children;

    public TreeNode(String name, List<TreeNode> children) {
        this.name = name;
        this.children = children;
    }

    public String toString() {
        StringBuilder buffer = new StringBuilder(50);
        print(buffer, "", "");
        return buffer.toString();
    }

    private void print(StringBuilder buffer, String prefix, String childrenPrefix) {
        buffer.append(prefix);
        buffer.append(name);
        buffer.append('\n');
        for (Iterator<TreeNode> it = children.iterator(); it.hasNext();) {
            TreeNode next = it.next();
            if (it.hasNext()) {
                next.print(buffer, childrenPrefix + "├── ", childrenPrefix + "│   ");
            } else {
                next.print(buffer, childrenPrefix + "└── ", childrenPrefix + "    ");
            }
        }
    }
}

P.S. This answer doesn't exactly focus on "binary" trees -- instead, it prints all kinds of trees. Solution is inspired by the "tree" command in linux.

  • Does this solution handle right skewed binary trees? – patentfox Nov 2 '18 at 17:02
  • @VasyaNovikov how would you rewrite children.get(children.size() - 1) if HashMap was used for children? I managed to modify every other part but this one. – Le Nguyen Duy Anh Nov 5 '18 at 23:52
  • @LeNguyenDuyAnh what's the HashMap proposed type signature though? HashMap<String, List<String>> ? – VasiliNovikov Nov 6 '18 at 6:06
  • I have implemented my tree as HashMap<String, Node>. String is the Node's id. – Le Nguyen Duy Anh Nov 6 '18 at 17:35
43

I've made an improved algorithm for this, which handles nicely nodes with different size. It prints top-down using lines.

package alg;

import java.util.ArrayList;
import java.util.List;


/**
 * Binary tree printer
 * 
 * @author MightyPork
 */
public class TreePrinter
{
    /** Node that can be printed */
    public interface PrintableNode
    {
        /** Get left child */
        PrintableNode getLeft();


        /** Get right child */
        PrintableNode getRight();


        /** Get text to be printed */
        String getText();
    }


    /**
     * Print a tree
     * 
     * @param root
     *            tree root node
     */
    public static void print(PrintableNode root)
    {
        List<List<String>> lines = new ArrayList<List<String>>();

        List<PrintableNode> level = new ArrayList<PrintableNode>();
        List<PrintableNode> next = new ArrayList<PrintableNode>();

        level.add(root);
        int nn = 1;

        int widest = 0;

        while (nn != 0) {
            List<String> line = new ArrayList<String>();

            nn = 0;

            for (PrintableNode n : level) {
                if (n == null) {
                    line.add(null);

                    next.add(null);
                    next.add(null);
                } else {
                    String aa = n.getText();
                    line.add(aa);
                    if (aa.length() > widest) widest = aa.length();

                    next.add(n.getLeft());
                    next.add(n.getRight());

                    if (n.getLeft() != null) nn++;
                    if (n.getRight() != null) nn++;
                }
            }

            if (widest % 2 == 1) widest++;

            lines.add(line);

            List<PrintableNode> tmp = level;
            level = next;
            next = tmp;
            next.clear();
        }

        int perpiece = lines.get(lines.size() - 1).size() * (widest + 4);
        for (int i = 0; i < lines.size(); i++) {
            List<String> line = lines.get(i);
            int hpw = (int) Math.floor(perpiece / 2f) - 1;

            if (i > 0) {
                for (int j = 0; j < line.size(); j++) {

                    // split node
                    char c = ' ';
                    if (j % 2 == 1) {
                        if (line.get(j - 1) != null) {
                            c = (line.get(j) != null) ? '┴' : '┘';
                        } else {
                            if (j < line.size() && line.get(j) != null) c = '└';
                        }
                    }
                    System.out.print(c);

                    // lines and spaces
                    if (line.get(j) == null) {
                        for (int k = 0; k < perpiece - 1; k++) {
                            System.out.print(" ");
                        }
                    } else {

                        for (int k = 0; k < hpw; k++) {
                            System.out.print(j % 2 == 0 ? " " : "─");
                        }
                        System.out.print(j % 2 == 0 ? "┌" : "┐");
                        for (int k = 0; k < hpw; k++) {
                            System.out.print(j % 2 == 0 ? "─" : " ");
                        }
                    }
                }
                System.out.println();
            }

            // print line of numbers
            for (int j = 0; j < line.size(); j++) {

                String f = line.get(j);
                if (f == null) f = "";
                int gap1 = (int) Math.ceil(perpiece / 2f - f.length() / 2f);
                int gap2 = (int) Math.floor(perpiece / 2f - f.length() / 2f);

                // a number
                for (int k = 0; k < gap1; k++) {
                    System.out.print(" ");
                }
                System.out.print(f);
                for (int k = 0; k < gap2; k++) {
                    System.out.print(" ");
                }
            }
            System.out.println();

            perpiece /= 2;
        }
    }
}

To use this for your Tree, let your Node class implement PrintableNode.

Example output:

                                         2952:0                                             
                    ┌───────────────────────┴───────────────────────┐                       
                 1249:-1                                         5866:0                     
        ┌───────────┴───────────┐                       ┌───────────┴───────────┐           
     491:-1                  1572:0                  4786:1                  6190:0         
  ┌─────┘                                               └─────┐           ┌─────┴─────┐     
339:0                                                      5717:0      6061:0      6271:0   
  • I was trying to replicate the "selected answer" technique. But I think this one of the best answers here. So Robust and concise. – Vikrant Goel Apr 27 '15 at 7:29
  • After implementing this it appears to work great, but only for balanced trees. Anything imbalanced returns odd results. – mitbanip Sep 9 '15 at 19:32
  • I get ??????????? instead of the lines between nodes but should be just some UTF8 ans stuff problem. Anyway, great stuff, I have to say. Best answer for me as it is really easy to use. – Fitz Jul 29 '16 at 9:46
  • Yes, that was it. Just had to change all the special characters of your lines and spaces paragraph. – Fitz Jul 29 '16 at 9:51
  • Nice, to support printing an array of elements, created a gist which just does that using @MightyPork logic for printing the tree. See public static <T> void print(T[] elems) – Neo Apr 9 '17 at 17:54
38
public static class Node<T extends Comparable<T>> {
    T value;
    Node<T> left, right;

    public void insertToTree(T v) {
        if (value == null) {
            value = v;
            return;
        }
        if (v.compareTo(value) < 0) {
            if (left == null) {
                left = new Node<T>();
            }
            left.insertToTree(v);
        } else {
            if (right == null) {
                right = new Node<T>();
            }
            right.insertToTree(v);
        }
    }

    public void printTree(OutputStreamWriter out) throws IOException {
        if (right != null) {
            right.printTree(out, true, "");
        }
        printNodeValue(out);
        if (left != null) {
            left.printTree(out, false, "");
        }
    }
    private void printNodeValue(OutputStreamWriter out) throws IOException {
        if (value == null) {
            out.write("<null>");
        } else {
            out.write(value.toString());
        }
        out.write('\n');
    }
    // use string and not stringbuffer on purpose as we need to change the indent at each recursion
    private void printTree(OutputStreamWriter out, boolean isRight, String indent) throws IOException {
        if (right != null) {
            right.printTree(out, true, indent + (isRight ? "        " : " |      "));
        }
        out.write(indent);
        if (isRight) {
            out.write(" /");
        } else {
            out.write(" \\");
        }
        out.write("----- ");
        printNodeValue(out);
        if (left != null) {
            left.printTree(out, false, indent + (isRight ? " |      " : "        "));
        }
    }

}

will print:

                 /----- 20
                 |       \----- 15
         /----- 14
         |       \----- 13
 /----- 12
 |       |       /----- 11
 |       \----- 10
 |               \----- 9
8
 |               /----- 7
 |       /----- 6
 |       |       \----- 5
 \----- 4
         |       /----- 3
         \----- 2
                 \----- 1

for the input

8 4 12 2 6 10 14 1 3 5 7 9 11 13 20 15

this is a variant from @anurag's answer - it was bugging me to see the extra |s

  • It'd be awesome if you could rotate it 90°. – Abhijit Sarkar Apr 15 at 6:13
31

Adapted from Vasya Novikov's answer to make it more binary, and use a StringBuilder for efficiency (concatenating String objects together in Java is generally inefficient).

public StringBuilder toString(StringBuilder prefix, boolean isTail, StringBuilder sb) {
    if(right!=null) {
        right.toString(new StringBuilder().append(prefix).append(isTail ? "│   " : "    "), false, sb);
    }
    sb.append(prefix).append(isTail ? "└── " : "┌── ").append(value.toString()).append("\n");
    if(left!=null) {
        left.toString(new StringBuilder().append(prefix).append(isTail ? "    " : "│   "), true, sb);
    }
    return sb;
}

@Override
public String toString() {
    return this.toString(new StringBuilder(), true, new StringBuilder()).toString();
}

Output:

│       ┌── 7
│   ┌── 6
│   │   └── 5
└── 4
    │   ┌── 3
    └── 2
        └── 1
            └── 0
  • It does not work for a tree when we insert values: 30,40,50,60,70,80 into a BST. As that creates a right-skewed tree. The value for isTail should be false when right != null.I did the edit and tested it, it works fine. – i_am_zero Jan 3 '15 at 9:24
  • Thanks for the input, I just edited the answer, it that better? – Todd Davies Jan 3 '15 at 9:28
  • Thank you, @Vasya Novikov's answer is great but I need a linklist version of it, and your answer just fit my case. – Vito Chou Jun 14 '17 at 6:39
  • In all of the answers, this produces the best looking tree, and the code is very clean! – p-sun Oct 6 '17 at 15:32
15

michal.kreuzman nice one i will have to say. I was feeling lazy to make a program by myself and searching for code on net when i found this it really helped me. But I am afraid to see that it works only for single digits as if you are going to use more than one digit, since you are using spaces and not tabs the structure is going to get misplaced and the program will loose its use. As for my later codes i needed some bigger inputs (at least more than 10) this didn't work for me, and after searching a lot on net when i didn't found anything, i made a program myself. It has some bugs now, again right now i am feeling lazy to correct them but it prints the very beautifully and the nodes can take any large value.

The tree is not going to be as the question mentions but it is 270 degrees rotated :)

public static void printBinaryTree(TreeNode root, int level){
    if(root==null)
         return;
    printBinaryTree(root.right, level+1);
    if(level!=0){
        for(int i=0;i<level-1;i++)
            System.out.print("|\t");
            System.out.println("|-------"+root.val);
    }
    else
        System.out.println(root.val);
    printBinaryTree(root.left, level+1);
}    

Place this function with your own specified TreeNode and keep the level initialy 0.

and enjoy. Here are some of the sample outputs.

|       |       |-------11
|       |-------10
|       |       |-------9
|-------8
|       |       |-------7
|       |-------6
|       |       |-------5
4
|       |-------3
|-------2
|       |-------1


|       |       |       |-------10
|       |       |-------9
|       |-------8
|       |       |-------7
|-------6
|       |-------5
4
|       |-------3
|-------2
|       |-------1

Only problem is with the extending branches i will try to solve the problem as soon as possible but till then you can use it too.

13

Your tree will need twice the distance for each layer:

       a
      / \
     /   \
    /     \
   /       \
   b       c
  / \     / \
 /   \   /   \
 d   e   f   g
/ \ / \ / \ / \
h i j k l m n o

You can save your tree in an array of arrays, one array for every depth:

[[a],[b,c],[d,e,f,g],[h,i,j,k,l,m,n,o]]

If your tree is not full, you need to include empty values in that array:

       a
      / \
     /   \
    /     \
   /       \
   b       c
  / \     / \
 /   \   /   \
 d   e   f   g
/ \   \ / \   \
h i   k l m   o
[[a],[b,c],[d,e,f,g],[h,i, ,k,l,m, ,o]]

Then you can iterate over the array to print your tree, printing spaces before the first element and between the elements depending on the depth and printing the lines depending on if the corresponding elements in the array for the next layer are filled or not. If your values can be more than one character long, you need to find the longest value while creating the array representation and multiply all widths and the number of lines accordingly.

  • What if the tree isn't complete? In that case it seems like you should be able to do this without doubling the space at each level. – templatetypedef Feb 11 '11 at 19:18
  • Yes, but only in some very limited cases where most subtrees are linked lists instead of trees from the same level downward or you would draw different subtrees with different spacing between the layers... – hd42 Feb 12 '11 at 9:37
10

I found VasyaNovikov's answer very useful for printing a large general tree, and modified it for a binary tree

Code:

class TreeNode {
    Integer data = null;
    TreeNode left = null;
    TreeNode right = null;

    TreeNode(Integer data) {this.data = data;}

    public void print() {
        print("", this, false);
    }

    public void print(String prefix, TreeNode n, boolean isLeft) {
        if (n != null) {
            System.out.println (prefix + (isLeft ? "|-- " : "\\-- ") + n.data);
            print(prefix + (isLeft ? "|   " : "    "), n.left, true);
            print(prefix + (isLeft ? "|   " : "    "), n.right, false);
        }
    }
}

Sample output:

\-- 7
    |-- 3
    |   |-- 1
    |   |   \-- 2
    |   \-- 5
    |       |-- 4
    |       \-- 6
    \-- 11
        |-- 9
        |   |-- 8
        |   \-- 10
        \-- 13
            |-- 12
            \-- 14
6

A solution in Scala language, analogous to what I wrote in java:

case class Node(name: String, children: Node*) {

    def toTree: String = toTree("", "").mkString("\n")

    private def toTree(prefix: String, childrenPrefix: String): Seq[String] = {
        val firstLine = prefix + this.name

        val firstChildren = this.children.dropRight(1).flatMap { child =>
            child.toTree(childrenPrefix + "├── ", childrenPrefix + "│   ")
        }
        val lastChild = this.children.takeRight(1).flatMap { child =>
            child.toTree(childrenPrefix + "└── ", childrenPrefix + "    ")
        }
        firstLine +: firstChildren ++: lastChild
    }

}

Output example:

vasya
├── frosya
│   ├── petya
│   │   └── masha
│   └── kolya
└── frosya2
  • With Lambda available in Java too, maybe you want to update your Java solution? – Tintin Sep 26 at 19:27
  • @Tintin Scala is absolutely not just about lambda functions. But if you have a good improvement for Java in mind, feel free to "edit", which will then be accepted by the StackOverflow community if deemed beneficial.;) – VasiliNovikov Sep 27 at 6:12
4

I know you guys all have great solution; I just want to share mine - maybe that is not the best way, but it is perfect for myself!

With python and pip on, it is really quite simple! BOOM!

On Mac or Ubuntu (mine is mac)

  1. open terminal
  2. $ pip install drawtree
  3. $python, enter python console; you can do it in other way
  4. from drawtree import draw_level_order
  5. draw_level_order('{2,1,3,0,7,9,1,2,#,1,0,#,#,8,8,#,#,#,#,7}')

DONE!

        2
       / \
      /   \
     /     \
    1       3
   / \     / \
  0   7   9   1
 /   / \     / \
2   1   0   8   8
       /
      7

Source tracking:

Before I saw this post, I went google "binary tree plain text"

And I found this https://www.reddit.com/r/learnpython/comments/3naiq8/draw_binary_tree_in_plain_text/, direct me to this https://github.com/msbanik/drawtree

  • @DenysVitali oh yes you are right ): I probably should move this to 'how to print tree from serialized level order traversal (any language / python)'. – Sean L Jan 11 '17 at 22:33
  • 2
    I didn't wanted to look rude, but when a user tags the question as java he expects a Java answer :) – Denys Vitali Jan 12 '17 at 8:56
3
public void printPreety() {
    List<TreeNode> list = new ArrayList<TreeNode>();
    list.add(head);
    printTree(list, getHeight(head));
}

public int getHeight(TreeNode head) {

    if (head == null) {
        return 0;
    } else {
        return 1 + Math.max(getHeight(head.left), getHeight(head.right));
    }
}

/**
 * pass head node in list and height of the tree 
 * 
 * @param levelNodes
 * @param level
 */
private void printTree(List<TreeNode> levelNodes, int level) {

    List<TreeNode> nodes = new ArrayList<TreeNode>();

    //indentation for first node in given level
    printIndentForLevel(level);

    for (TreeNode treeNode : levelNodes) {

        //print node data
        System.out.print(treeNode == null?" ":treeNode.data);

        //spacing between nodes
        printSpacingBetweenNodes(level);

        //if its not a leaf node
        if(level>1){
            nodes.add(treeNode == null? null:treeNode.left);
            nodes.add(treeNode == null? null:treeNode.right);
        }
    }
    System.out.println();

    if(level>1){        
        printTree(nodes, level-1);
    }
}

private void printIndentForLevel(int level){
    for (int i = (int) (Math.pow(2,level-1)); i >0; i--) {
        System.out.print(" ");
    }
}

private void printSpacingBetweenNodes(int level){
    //spacing between nodes
    for (int i = (int) ((Math.pow(2,level-1))*2)-1; i >0; i--) {
        System.out.print(" ");
    }
}


Prints Tree in following format:
                4                               
        3               7               
    1               5       8       
      2                       10   
                             9   
2

This is a very simple solution to print out a tree. It is not that pretty, but it is really simple:

enum { kWidth = 6 };
void PrintSpace(int n)
{
  for (int i = 0; i < n; ++i)
    printf(" ");
}

void PrintTree(struct Node * root, int level)
{
  if (!root) return;
  PrintTree(root->right, level + 1);
  PrintSpace(level * kWidth);
  printf("%d", root->data);
  PrintTree(root->left, level + 1);
}

Sample output:

      106
            105
104
            103
                  102
                        101
      100
1

I needed to print a binary tree in one of my projects, for that I have prepared a java class TreePrinter, one of the sample output is:

                [+]
               /   \
              /     \
             /       \
            /         \
           /           \
        [*]             \
       /   \             [-]
[speed]     [2]         /   \
                    [45]     [12]

Here is the code for class TreePrinter along with class TextNode. For printing any tree you can just create an equivalent tree with TextNode class.


import java.util.ArrayList;

public class TreePrinter {

    public TreePrinter(){
    }

    public static String TreeString(TextNode root){
        ArrayList layers = new ArrayList();
        ArrayList bottom = new ArrayList();

        FillBottom(bottom, root);  DrawEdges(root);

        int height = GetHeight(root);
        for(int i = 0; i  s.length()) min = s.length();

            if(!n.isEdge) s += "[";
            s += n.text;
            if(!n.isEdge) s += "]";

            layers.set(n.depth, s);
        }

        StringBuilder sb = new StringBuilder();

        for(int i = 0; i  temp = new ArrayList();

            for(int i = 0; i  0) temp.get(i-1).left = x;
                temp.add(x);
            }

            temp.get(count-1).left = n.left;
            n.left.depth = temp.get(count-1).depth+1;
            n.left = temp.get(0);

            DrawEdges(temp.get(count-1).left);
        }
        if(n.right != null){
            int count = n.right.x - (n.x + n.text.length() + 2);
            ArrayList temp = new ArrayList();

            for(int i = 0; i  0) temp.get(i-1).right = x;
                temp.add(x);
            }

            temp.get(count-1).right = n.right;
            n.right.depth = temp.get(count-1).depth+1;
            n.right = temp.get(0);  

            DrawEdges(temp.get(count-1).right);
        }
    }

    private static void FillBottom(ArrayList bottom, TextNode n){
        if(n == null) return;

        FillBottom(bottom, n.left);

        if(!bottom.isEmpty()){            
            int i = bottom.size()-1;
            while(bottom.get(i).isEdge) i--;
            TextNode last = bottom.get(i);

            if(!n.isEdge) n.x = last.x + last.text.length() + 3;
        }
        bottom.add(n);
        FillBottom(bottom, n.right);
    }

    private static boolean isLeaf(TextNode n){
        return (n.left == null && n.right == null);
    }

    private static int GetHeight(TextNode n){
        if(n == null) return 0;

        int l = GetHeight(n.left);
        int r = GetHeight(n.right);

        return Math.max(l, r) + 1;
    }
}


class TextNode {
    public String text;
    public TextNode parent, left, right;
    public boolean isEdge;
    public int x, depth;

    public TextNode(String text){
        this.text = text;
        parent = null; left = null; right = null;
        isEdge = false;
        x = 0; depth = 0;
    }
}

Finally here is a test class for printing given sample:


public class Test {

    public static void main(String[] args){
        TextNode root = new TextNode("+");
        root.left = new TextNode("*");            root.left.parent = root;
        root.right = new TextNode("-");           root.right.parent = root;
        root.left.left = new TextNode("speed");   root.left.left.parent = root.left;
        root.left.right = new TextNode("2");      root.left.right.parent = root.left;
        root.right.left = new TextNode("45");     root.right.left.parent = root.right;
        root.right.right = new TextNode("12");    root.right.right.parent = root.right;

        System.out.println(TreePrinter.TreeString(root));
    }
}
1

You can use an applet to visualize this very easily. You need to print the following items.

  1. Print the nodes as circles with some visible radius

    • Get the coordinates for each node.

    • The x coordinate can be visualized as the number of nodes visited before the node is visited in its inorder traversal.

    • The y coordinate can be visualized as the depth of the particular node.


  1. Print the lines between parent and children

    • This can be done by maintaining the x and y coordinates of the nodes and the parents of each node in separate lists.

    • For each node except root join each node with its parent by taking the x and y coordinates of both the child and the parent.

  • can you please visualize and give a better solution than existing answers? – Enamul Hassan Dec 17 '15 at 3:00
1
private StringBuilder prettyPrint(Node root, int currentHeight, int totalHeight) {
        StringBuilder sb = new StringBuilder();
        int spaces = getSpaceCount(totalHeight-currentHeight + 1);
        if(root == null) {
            //create a 'spatial' block and return it
            String row = String.format("%"+(2*spaces+1)+"s%n", "");
            //now repeat this row space+1 times
            String block = new String(new char[spaces+1]).replace("\0", row);
            return new StringBuilder(block);
        }
        if(currentHeight==totalHeight) return new StringBuilder(root.data+"");
        int slashes = getSlashCount(totalHeight-currentHeight +1);
        sb.append(String.format("%"+(spaces+1)+"s%"+spaces+"s", root.data+"", ""));
        sb.append("\n");
        //now print / and \
        // but make sure that left and right exists
        char leftSlash = root.left == null? ' ':'/';
        char rightSlash = root.right==null? ' ':'\\';
        int spaceInBetween = 1;
        for(int i=0, space = spaces-1; i<slashes; i++, space --, spaceInBetween+=2) {
            for(int j=0; j<space; j++) sb.append(" ");
            sb.append(leftSlash);
            for(int j=0; j<spaceInBetween; j++) sb.append(" ");
            sb.append(rightSlash+"");
            for(int j=0; j<space; j++) sb.append(" ");
            sb.append("\n");
        }
        //sb.append("\n");

        //now get string representations of left and right subtrees
        StringBuilder leftTree = prettyPrint(root.left, currentHeight+1, totalHeight);
        StringBuilder rightTree = prettyPrint(root.right, currentHeight+1, totalHeight);
        // now line by line print the trees side by side
        Scanner leftScanner = new Scanner(leftTree.toString());
        Scanner rightScanner = new Scanner(rightTree.toString());
//      spaceInBetween+=1;
        while(leftScanner.hasNextLine()) {
            if(currentHeight==totalHeight-1) {
                sb.append(String.format("%-2s %2s", leftScanner.nextLine(), rightScanner.nextLine()));
                sb.append("\n");
                spaceInBetween-=2;              
            }
            else {
                sb.append(leftScanner.nextLine());
                sb.append(" ");
                sb.append(rightScanner.nextLine()+"\n");
            }
        }

        return sb;

    }
private int getSpaceCount(int height) {
        return (int) (3*Math.pow(2, height-2)-1);
    }
private int getSlashCount(int height) {
        if(height <= 3) return height -1;
        return (int) (3*Math.pow(2, height-3)-1);
    }

https://github.com/murtraja/java-binary-tree-printer

only works for 1 to 2 digit integers (i was lazy to make it generic)

skewed full

1

This was the simplest solution for horizontal view. Tried with bunch of examples. Works well for my purpose. Updated from @nitin-k 's answer.

public void print(String prefix, BTNode n, boolean isLeft) {
    if (n != null) {
        print(prefix + "     ", n.right, false);
        System.out.println (prefix + ("|-- ") + n.data);
        print(prefix + "     ", n.left, true);
    }
}

Call:

bst.print("", bst.root, false);

Solution:

                         |-- 80
                    |-- 70
               |-- 60
          |-- 50
     |-- 40
|-- 30
     |-- 20
          |-- 10
1

I wrote a binary tree printer in Java.

Code is on GitHub here.

It hasn't been optimized for run time efficiency, but since we're talking about printing in ASCII, I figured it's not going to be used on very large trees. It does have some nice features though.

  1. It makes efficient use of space in that a large subtree extends under a smaller one as much as possible.
  2. There's a parameter to set the minimum horizontal space between node labels.
  3. Node labels are strings of arbitrary length.
  4. In addition to a method for printing a single tree, there's a method for printing a list of trees horizontally across the page (with a parameter for page width), using as many rows as necessary.
  5. There's an option to print trees with diagonal branches (using slash and backslash characters) or with horizontal branches (using ascii box drawing characters). The latter is more compact and makes tree levels more visually clear.
  6. It works.

Some demo/test programs are included.

An example of a randomly generated binary tree, as printed by the program, follows. This illustrates the efficient use of space, with a large right subtree extending under a small left subtree:

             seven                                        
              / \                                         
             /   \                                        
            /     \                                       
           /       \                                      
          /         \                                     
         /           \                                    
       five        thirteen                               
       / \           / \                                  
      /   \         /   \                                 
     /     \       /     \                                
  three    six    /       \                               
   / \           /         \                              
  /   \         /           \                             
one   four     /             \                            
  \           /               \                           
  two        /                 \                          
           nine            twenty four                    
           / \                 / \                        
          /   \               /   \                       
         /     \             /     \                      
      eight   twelve        /       \                     
               /           /         \                    
             ten          /           \                   
               \         /             \                  
              eleven    /               \                 
                       /                 \                
                      /                   \               
                     /                     \              
                 eighteen              twenty seven       
                   / \                     / \            
                  /   \                   /   \           
                 /     \                 /     \          
                /       \               /       \         
               /         \             /         \        
              /           \           /           \       
             /             \    twenty five   twenty eight
            /               \         \             \     
           /                 \     twenty six      thirty 
       fourteen            nineteen                 /     
           \                   \              twenty nine 
         sixteen           twenty three                   
           / \                 /                          
          /   \           twenty two                      
         /     \             /                            
        /       \         twenty                          
       /         \           \                            
   fifteen    seventeen   twenty one                      

An example of printing all five node binary trees (with in-order labels) across the page:

one           one         one          one        one       one         one     
  \             \           \            \          \         \           \     
  two           two         two          two        two      three       three  
    \             \           \            \          \       / \         / \   
   three         three        four         five       five  two four    two five
      \             \         / \          /          /           \         /   
      four          five     /   \      three       four          five    four  
        \           /     three  five      \        /                           
        five      four                     four  three                          



one          one        one        one       one       one         one        two        
  \            \          \          \         \         \           \        / \        
  four         four       five       five      five      five        five    /   \       
  / \          / \        /          /         /         /           /     one  three    
two five      /   \     two        two      three      four        four            \     
  \        three  five    \          \       / \       /           /               four  
 three      /            three       four  two four  two        three                \   
          two               \        /                 \         /                   five
                            four  three               three    two                       



   two          two          two        two      three         three         three    
   / \          / \          / \        / \       / \           / \           / \     
  /   \       one four     one five   one five  one four       /   \        two four  
one  three        / \          /          /       \   \       /     \       /     \   
        \        /   \      three       four      two five  one     five  one     five
        five  three  five      \        /                     \     /                 
        /                      four  three                    two four                
      four                                                                            



   three      four      four         four         four            four       five    
    / \       / \       / \          / \          / \             / \        /       
  two five  one five  one five     two five      /   \           /   \     one       
  /   /       \         \          / \        three  five     three  five    \       
one four      two      three      /   \        /               /             two     
                \       /       one  three   one             two               \     
               three  two                      \             /                three  
                                               two         one                   \   
                                                                                 four



  five      five      five      five       five         five      five        five
  /         /         /         /          /            /         /           /   
one       one       one       one        two          two      three       three  
  \         \         \         \        / \          / \       / \         / \   
  two      three      four      four    /   \       one four  one four    two four
    \       / \       /         /     one  three        /       \         /       
    four  two four  two      three            \      three      two     one       
    /                 \       /               four                                
 three               three  two                                                   



    five      five         five        five          five
    /         /            /           /             /   
  four      four         four        four          four  
  /         /            /           /             /     
one       one          two        three         three    
  \         \          / \         /             /       
  two      three      /   \      one           two       
    \       /       one  three     \           /         
   three  two                      two       one 

The following is an example of the same tree printed 4 different ways, with horizontal spacing of 1 and of 3, and with diagonal and horizontal branches.

                   27        
             ┌─────┴─────┐   
             13          29  
      ┌──────┴──────┐  ┌─┴─┐ 
      8             23 28  30
   ┌──┴──┐       ┌──┴──┐     
   4     11      21    26    
 ┌─┴─┐  ┌┴┐    ┌─┴─┐  ┌┘     
 2   5  9 12   18  22 24     
┌┴┐  └┐ └┐   ┌─┴─┐    └┐     
1 3   6  10  17  19    25    
      └┐    ┌┘   └┐          
       7    15    20         
          ┌─┴─┐              
          14  16             


                 27        
                / \        
               /   \       
              13    29     
             / \   / \     
            /   \ 28  30   
           /     \         
          /       \        
         /         \       
        /           \      
       8             23    
      / \           / \    
     /   \         /   \   
    4     11      /     \  
   / \   / \     21      26
  2   5 9   12  / \     /  
 / \   \ \     18  22  24  
1   3   6 10  / \       \  
         \   17  19      25
          7 /     \        
           15      20      
          / \              
         14  16            


                             27            
                    ┌────────┴────────┐    
                    13                29   
          ┌─────────┴─────────┐    ┌──┴──┐ 
          8                   23   28    30
     ┌────┴────┐         ┌────┴────┐       
     4         11        21        26      
  ┌──┴──┐    ┌─┴─┐    ┌──┴──┐     ┌┘       
  2     5    9   12   18    22    24       
┌─┴─┐   └┐   └┐    ┌──┴──┐        └┐       
1   3    6    10   17    19        25      
         └┐       ┌┘     └┐                
          7       15      20               
               ┌──┴──┐                     
               14    16                    


                      27         
                     / \         
                    /   \        
                   /     \       
                  /       \      
                 13        29    
                / \       / \    
               /   \     /   \   
              /     \   28    30 
             /       \           
            /         \          
           /           \         
          /             \        
         /               \       
        8                 23     
       / \               / \     
      /   \             /   \    
     /     \           /     \   
    4       11        /       \  
   / \     / \       21        26
  2   5   9   12    / \       /  
 / \   \   \       /   \     24  
1   3   6   10    18    22    \  
         \       / \           25
          7     /   \            
               17    19          
              /       \          
             15        20        
            / \                  
           /   \                 
          14    16               

  • It's nice that you wrote an published this project. It looks like it does a good job, but basically just a link to your library doesn't make for a good answer on Stack Overflow. At a minimum, you should include the code necessary to use your library to display the examples you've provided, so people know what's involved with using your library. Right now, this is just an advertisement for your GitHub repo. That's not a bad thing, if you're showing people how to actually use it. – Makyen Jul 20 at 16:19
  • BTW: If you do edit in example code, please ping me here by including @Makyen in a comment. – Makyen Jul 20 at 16:23
0

Print in Console:

                                                500
                       700                                             300   
    200                                   400                                                                                          

Simple code :

public int getHeight()
    {
        if(rootNode == null) return -1;
        return getHeight(rootNode);
    }

    private int getHeight(Node node)
    {
        if(node == null) return -1;

        return Math.max(getHeight(node.left), getHeight(node.right)) + 1;
    }

    public void printBinaryTree(Node rootNode)
    {
        Queue<Node> rootsQueue = new LinkedList<Node>();
        Queue<Node> levelQueue = new LinkedList<Node>();
        levelQueue.add(rootNode);
        int treeHeight = getHeight();
        int firstNodeGap;
        int internalNodeGap;
        int copyinternalNodeGap;
        while(true)
        {
            System.out.println("");
            internalNodeGap = (int)(Math.pow(2, treeHeight + 1) -1);  
            copyinternalNodeGap = internalNodeGap;
            firstNodeGap = internalNodeGap/2;

            boolean levelFirstNode = true;

            while(!levelQueue.isEmpty())
            {
                internalNodeGap = copyinternalNodeGap;
                Node currNode = levelQueue.poll();
                if(currNode != null)
                {
                    if(levelFirstNode)
                    {
                        while(firstNodeGap > 0)
                        {
                            System.out.format("%s", "   ");
                            firstNodeGap--; 
                        }
                        levelFirstNode =false;
                    }
                    else
                    {
                        while(internalNodeGap>0)
                        {
                            internalNodeGap--;
                            System.out.format("%s", "   ");
                        }
                    }
                    System.out.format("%3d",currNode.data);
                    rootsQueue.add(currNode);
                }
            }

            --treeHeight;

            while(!rootsQueue.isEmpty())
            {
                Node currNode = rootsQueue.poll();
                if(currNode != null)
                {
                    levelQueue.add(currNode.left);
                    levelQueue.add(currNode.right);
                }
            }

            if(levelQueue.isEmpty()) break;
        }

    }
0

Here's a very versatile tree printer. Not the best looking, but it handles a lot of cases. Feel free to add slashes if you can figure that out. enter image description here

package com.tomac120.NodePrinter;

import java.util.ArrayList;
import java.util.LinkedList;
import java.util.List;

/**
 * Created by elijah on 6/28/16.
 */
public class NodePrinter{
    final private List<List<PrintableNodePosition>> nodesByRow;
    int maxColumnsLeft = 0;
    int maxColumnsRight = 0;
    int maxTitleLength = 0;
    String sep = " ";
    int depth = 0;

    public NodePrinter(PrintableNode rootNode, int chars_per_node){
        this.setDepth(rootNode,1);
        nodesByRow = new ArrayList<>(depth);
        this.addNode(rootNode._getPrintableNodeInfo(),0,0);
        for (int i = 0;i<chars_per_node;i++){
            //sep += " ";
        }
    }

    private void setDepth(PrintableNode info, int depth){
        if (depth > this.depth){
            this.depth = depth;
        }
        if (info._getLeftChild() != null){
            this.setDepth(info._getLeftChild(),depth+1);
        }
        if (info._getRightChild() != null){
            this.setDepth(info._getRightChild(),depth+1);
        }
    }

    private void addNode(PrintableNodeInfo node, int level, int position){
        if (position < 0 && -position > maxColumnsLeft){
            maxColumnsLeft = -position;
        }
        if (position > 0 && position > maxColumnsRight){
            maxColumnsRight = position;
        }
        if (node.getTitleLength() > maxTitleLength){
           maxTitleLength = node.getTitleLength();
        }
        List<PrintableNodePosition> row = this.getRow(level);
        row.add(new PrintableNodePosition(node, level, position));
        level++;

        int depthToUse = Math.min(depth,6);
        int levelToUse = Math.min(level,6);
        int offset = depthToUse - levelToUse-1;
        offset = (int)(Math.pow(offset,Math.log(depthToUse)*1.4));
        offset = Math.max(offset,3);


        PrintableNodeInfo leftChild = node.getLeftChildInfo();
        PrintableNodeInfo rightChild = node.getRightChildInfo();
        if (leftChild != null){
            this.addNode(leftChild,level,position-offset);
        }
        if (rightChild != null){
            this.addNode(rightChild,level,position+offset);
        }
    }

    private List<PrintableNodePosition> getRow(int row){
        if (row > nodesByRow.size() - 1){
            nodesByRow.add(new LinkedList<>());
        }
        return nodesByRow.get(row);
    }

    public void print(){
        int max_chars = this.maxColumnsLeft+maxColumnsRight+1;
        int level = 0;
        String node_format = "%-"+this.maxTitleLength+"s";
        for (List<PrintableNodePosition> pos_arr : this.nodesByRow){
            String[] chars = this.getCharactersArray(pos_arr,max_chars);
            String line = "";
            int empty_chars = 0;
            for (int i=0;i<chars.length+1;i++){
                String value_i = i < chars.length ? chars[i]:null;
                if (chars.length + 1 == i || value_i != null){
                    if (empty_chars > 0) {
                        System.out.print(String.format("%-" + empty_chars + "s", " "));
                    }
                    if (value_i != null){
                        System.out.print(String.format(node_format,value_i));
                        empty_chars = -1;
                    } else{
                        empty_chars = 0;
                    }
                } else {
                    empty_chars++;
                }
            }
            System.out.print("\n");

            int depthToUse = Math.min(6,depth);
            int line_offset = depthToUse - level;
            line_offset *= 0.5;
            line_offset = Math.max(0,line_offset);

            for (int i=0;i<line_offset;i++){
                System.out.println("");
            }


            level++;
        }
    }

    private String[] getCharactersArray(List<PrintableNodePosition> nodes, int max_chars){
        String[] positions = new String[max_chars+1];
        for (PrintableNodePosition a : nodes){
            int pos_i = maxColumnsLeft + a.column;
            String title_i = a.nodeInfo.getTitleFormatted(this.maxTitleLength);
            positions[pos_i] = title_i;
        }
        return positions;
    }
}

NodeInfo class

package com.tomac120.NodePrinter;

/**
 * Created by elijah on 6/28/16.
 */
public class PrintableNodeInfo {
    public enum CLI_PRINT_COLOR {
        RESET("\u001B[0m"),
        BLACK("\u001B[30m"),
        RED("\u001B[31m"),
        GREEN("\u001B[32m"),
        YELLOW("\u001B[33m"),
        BLUE("\u001B[34m"),
        PURPLE("\u001B[35m"),
        CYAN("\u001B[36m"),
        WHITE("\u001B[37m");

        final String value;
        CLI_PRINT_COLOR(String value){
            this.value = value;
        }

        @Override
        public String toString() {
            return value;
        }
    }
    private final String title;
    private final PrintableNode leftChild;
    private final PrintableNode rightChild;
    private final CLI_PRINT_COLOR textColor;

    public PrintableNodeInfo(String title, PrintableNode leftChild, PrintableNode rightChild){
        this(title,leftChild,rightChild,CLI_PRINT_COLOR.BLACK);
    }

    public PrintableNodeInfo(String title, PrintableNode leftChild, PrintableNode righthild, CLI_PRINT_COLOR textColor){
        this.title = title;
        this.leftChild = leftChild;
        this.rightChild = righthild;
        this.textColor = textColor;
    }

    public String getTitle(){
        return title;
    }

    public CLI_PRINT_COLOR getTextColor(){
        return textColor;
    }

    public String getTitleFormatted(int max_chars){
        return this.textColor+title+CLI_PRINT_COLOR.RESET;
        /*
        String title = this.title.length() > max_chars ? this.title.substring(0,max_chars+1):this.title;
        boolean left = true;
        while(title.length() < max_chars){
            if (left){
                title = " "+title;
            } else {
                title = title + " ";
            }
        }
        return this.textColor+title+CLI_PRINT_COLOR.RESET;*/
    }

    public int getTitleLength(){
        return title.length();
    }

    public PrintableNodeInfo getLeftChildInfo(){
        if (leftChild == null){
            return null;
        }
        return leftChild._getPrintableNodeInfo();
    }

    public PrintableNodeInfo getRightChildInfo(){
        if (rightChild == null){
            return null;
        }
        return rightChild._getPrintableNodeInfo();
    }
}

NodePosition class

package com.tomac120.NodePrinter;

/**
 * Created by elijah on 6/28/16.
 */
public class PrintableNodePosition implements Comparable<PrintableNodePosition> {
    public final int row;
    public final int column;
    public final PrintableNodeInfo nodeInfo;
    public PrintableNodePosition(PrintableNodeInfo nodeInfo, int row, int column){
        this.row = row;
        this.column = column;
        this.nodeInfo = nodeInfo;
    }

    @Override
    public int compareTo(PrintableNodePosition o) {
        return Integer.compare(this.column,o.column);
    }
}

And, finally, Node Interface

package com.tomac120.NodePrinter;

/**
 * Created by elijah on 6/28/16.
 */
public interface PrintableNode {
    PrintableNodeInfo _getPrintableNodeInfo();
    PrintableNode _getLeftChild();
    PrintableNode _getRightChild();
}
0

A Scala solution, adapted from Vasya Novikov's answer and specialized for binary trees:

/** An immutable Binary Tree. */
case class BTree[T](value: T, left: Option[BTree[T]], right: Option[BTree[T]]) {

  /* Adapted from: http://stackoverflow.com/a/8948691/643684 */
  def pretty: String = {
    def work(tree: BTree[T], prefix: String, isTail: Boolean): String = {
      val (line, bar) = if (isTail) ("└── ", " ") else ("├── ", "│")

      val curr = s"${prefix}${line}${tree.value}"

      val rights = tree.right match {
        case None    => s"${prefix}${bar}   ├── ∅"
        case Some(r) => work(r, s"${prefix}${bar}   ", false)
      }

      val lefts = tree.left match {
        case None    => s"${prefix}${bar}   └── ∅"
        case Some(l) => work(l, s"${prefix}${bar}   ", true)
      }

      s"${curr}\n${rights}\n${lefts}"

    }

    work(this, "", true)
  }
}
0

See also these answers.

In particular it wasn't too difficult to use abego TreeLayout to produce results shown below with the default settings.

If you try that tool, note this caveat: It prints children in the order they were added. For a BST where left vs right matters I found this library to be inappropriate without modification.

Also, the method to add children simply takes a parent and child node as parameters. (So to process a bunch of nodes, you must take the first one separately to create a root.)

I ended up using this solution above, modifying it to take in the type <Node> so as to have access to Node's left and right (children).

tree created with abego TreeLayout

0

Here is another way to visualize your tree: save the nodes as an xml file and then let your browser show you the hierarchy:

class treeNode{
    int key;
    treeNode left;
    treeNode right;

    public treeNode(int key){
        this.key = key;
        left = right = null;
    }

    public void printNode(StringBuilder output, String dir){
        output.append("<node key='" + key + "' dir='" + dir + "'>");
        if(left != null)
            left.printNode(output, "l");
        if(right != null)
            right.printNode(output, "r");
        output.append("</node>");
    }
}

class tree{
    private treeNode treeRoot;

    public tree(int key){
        treeRoot = new treeNode(key);
    }

    public void insert(int key){
        insert(treeRoot, key);
    }

    private treeNode insert(treeNode root, int key){
        if(root == null){
            treeNode child = new treeNode(key);
            return child;
        }

        if(key < root.key)
            root.left = insert(root.left, key);
        else if(key > root.key)
            root.right = insert(root.right, key);

        return root;
    }

    public void saveTreeAsXml(){
        StringBuilder strOutput = new StringBuilder();
        strOutput.append("<?xml version=\"1.0\" encoding=\"UTF-8\"?>");
        treeRoot.printNode(strOutput, "root");
        try {
            PrintWriter writer = new PrintWriter("C:/tree.xml", "UTF-8");
            writer.write(strOutput.toString());
            writer.close();
        }
        catch (FileNotFoundException e){

        }
        catch(UnsupportedEncodingException e){

        }
    }
}

Here is code to test it:

    tree t = new tree(1);
    t.insert(10);
    t.insert(5);
    t.insert(4);
    t.insert(20);
    t.insert(40);
    t.insert(30);
    t.insert(80);
    t.insert(60);
    t.insert(50);

    t.saveTreeAsXml();

And the output looks like this:

enter image description here

0

Based on VasyaNovikov answer. Improved with some Java magic: Generics and Functional interface.

/**
 * Print a tree structure in a pretty ASCII fromat.
 * @param prefix Currnet previx. Use "" in initial call!
 * @param node The current node. Pass the root node of your tree in initial call.
 * @param getChildrenFunc A {@link Function} that returns the children of a given node.
 * @param isTail Is node the last of its sibblings. Use true in initial call. (This is needed for pretty printing.)
 * @param <T> The type of your nodes. Anything that has a toString can be used.
 */
private <T> void printTreeRec(String prefix, T node, Function<T, List<T>> getChildrenFunc, boolean isTail) {
    String nodeName = node.toString();
    String nodeConnection = isTail ? "└── " : "├── ";
    log.debug(prefix + nodeConnection + nodeName);
    List<T> children = getChildrenFunc.apply(node);
    for (int i = 0; i < children.size(); i++) {
        String newPrefix = prefix + (isTail ? "    " : "│   ");
        printTreeRec(newPrefix, children.get(i), getChildrenFunc, i == children.size()-1);
    }
}

Example initial call:

Function<ChecksumModel, List<ChecksumModel>> getChildrenFunc = node -> getChildrenOf(node)
printTreeRec("", rootNode, getChildrenFunc, true);

Will output something like

└── rootNode
    ├── childNode1
    ├── childNode2
    │   ├── childNode2.1
    │   ├── childNode2.2
    │   └── childNode2.3
    ├── childNode3
    └── childNode4
0
using map...
{
Map<Integer,String> m = new LinkedHashMap<>();

         tn.printNodeWithLvl(node,l,m);

        for(Entry<Integer, String> map :m.entrySet()) {
            System.out.println(map.getValue());
        }
then....method


   private  void printNodeWithLvl(Node node,int l,Map<Integer,String> m) {
       if(node==null) {
           return;
       }
      if(m.containsKey(l)) {
          m.put(l, new StringBuilder(m.get(l)).append(node.value).toString());
      }else {
          m.put(l, node.value+"");
      }
      l++;
      printNodeWithLvl( node.left,l,m);
      printNodeWithLvl(node.right,l,m);

    }
}
0
  1. You will need to level order traverse your tree.
  2. Choose node length and space length.
  3. Get the tree's base width relative to each level which is node_length * nodes_count + space_length * spaces_count*.
  4. Find a relation between branching, spacing, indentation and the calculated base width.

Code on GitHub: YoussefRaafatNasry/bst-ascii-visualization

                                             07                     
                                             /\                     
                                            /  \                    
                                           /    \                   
                                          /      \                  
                                         /        \                 
                                        /          \                
                                       /            \               
                                      /              \              
                                     /                \             
                                    /                  \            
                                   /                    \           
                                 03                      11         
                                 /\                      /\         
                                /  \                    /  \        
                               /    \                  /    \       
                              /      \                /      \      
                             /        \              /        \     
                           01          05          09          13   
                           /\          /\          /\          /\   
                          /  \        /  \        /  \        /  \  
                        00    02    04    06    08    10    12    14
  • I'd say the code is short enough that you can embed it into your answer. – m02ph3u5 Jul 19 at 14:59
  • The code is not just the visualize function, it is the whole visualizer class which is about 200 loc including the header file. – YoussefRaafatNasry Jul 20 at 14:28
0

this is one of the simplest version i could implement. i hope it helps you

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

    def add(self, data):

        if data < self.data:
            if self.left is None:
                self.left = Node(data)
            else:
                self.left.add(data)
        if data > self.data:
            if self.right is None:
                self.right = Node(data)
            else:
                self.right.add(data)

    def display(self):
        diff = 16
        start = 50
        c = ' '

        this_level = [(self, start)]

        while this_level:
            next_level = list()
            last_line = ''

            for node, d in this_level:
                line = last_line + c*(d - len(last_line)) + str(node.data)
                print(line, end='\r')
                last_line = line

                if node.left:
                    next_level.append((node.left, d - diff))
                if node.right:
                    next_level.append((node.right, d + diff))
                this_level = next_level
                diff = max(diff//2, 2)
            print('\n')


if __name__ == '__main__':
    from random import randint, choice
    values = [randint(0, 100) for _ in range(10)]
    bst = Node(choice(values))
    for data in values:
        bst.add(data)

    bst.display()


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