Just wondering if I can get some tips on printing a pretty binary tree in the form of:

5
     10
          11
          7
               6
     3
          4
          2

Right now what it prints is:

   2
    4
    3 
    6
    7
    11
    10
    5

I know that my example is upside down from what I'm currently printing, which it doesn't matter if I print from the root down as it currently prints. Any tips are very appreciated towards my full question:

How do I modify my prints to make the tree look like a tree?

    //Binary Search Tree Program

#include <iostream>
#include <cstdlib>
#include <queue>
using namespace std;

int i = 0;

class BinarySearchTree
{
   private:
   struct tree_node
   {
      tree_node* left;
      tree_node* right;
      int data;
   };
   tree_node* root;

   public:
   BinarySearchTree()
   {
      root = NULL;
   }

   bool isEmpty() const { return root==NULL; }
   void print_inorder();
   void inorder(tree_node*);
   void print_preorder();
   void preorder(tree_node*);
   void print_postorder();
   void postorder(tree_node*);
   void insert(int);
   void remove(int);
};

// Smaller elements go left
// larger elements go right
void BinarySearchTree::insert(int d)
{
   tree_node* t = new tree_node;
   tree_node* parent;
   t->data = d;
   t->left = NULL;
   t->right = NULL;
   parent = NULL;

   // is this a new tree?
   if(isEmpty()) root = t;
   else
   {
      //Note: ALL insertions are as leaf nodes
      tree_node* curr;
      curr = root;
      // Find the Node's parent
      while(curr)
      {
         parent = curr;
         if(t->data > curr->data) curr = curr->right;
         else curr = curr->left;
      }

      if(t->data < parent->data)
      {
         parent->left = t;
      }
      else
      {
      parent->right = t;
      }
    }
}

void BinarySearchTree::remove(int d)
{
   //Locate the element
   bool found = false;
   if(isEmpty())
   {
      cout<<" This Tree is empty! "<<endl;
      return;
   }

   tree_node* curr;
   tree_node* parent;
   curr = root;

   while(curr != NULL)
   {
      if(curr->data == d)
      {
         found = true;
         break;
      }
      else
      {
         parent = curr;
         if(d>curr->data) curr = curr->right;
         else curr = curr->left;
      }
    }
    if(!found)
    {
      cout<<" Data not found! "<<endl;
      return;
    }


    // 3 cases :
    // 1. We're removing a leaf node
    // 2. We're removing a node with a single child
    // 3. we're removing a node with 2 children

    // Node with single child
    if((curr->left == NULL && curr->right != NULL) || (curr->left != NULL && curr->right == NULL))
    {
      if(curr->left == NULL && curr->right != NULL)
      {
         if(parent->left == curr)
         {
            parent->left = curr->right;
            delete curr;
         }
         else
         {
            parent->right = curr->left;
            delete curr;
         }
       }
       return;
    }

    //We're looking at a leaf node
    if( curr->left == NULL && curr->right == NULL)
    {
      if(parent->left == curr)
      {
         parent->left = NULL;
      }
      else
      {
         parent->right = NULL;
      }
      delete curr;
      return;
    }


    //Node with 2 children
    // replace node with smallest value in right subtree
    if (curr->left != NULL && curr->right != NULL)
    {
       tree_node* chkr;
       chkr = curr->right;
       if((chkr->left == NULL) && (chkr->right == NULL))
       {
         curr = chkr;
         delete chkr;
         curr->right = NULL;
       }
       else // right child has children
       {
         //if the node's right child has a left child
         // Move all the way down left to locate smallest element

         if((curr->right)->left != NULL)
         {
            tree_node* lcurr;
            tree_node* lcurrp;
            lcurrp = curr->right;
            lcurr = (curr->right)->left;
            while(lcurr->left != NULL)
            {
               lcurrp = lcurr;
               lcurr = lcurr->left;
            }
            curr->data = lcurr->data;
            delete lcurr;
            lcurrp->left = NULL;
         }
         else
         {
            tree_node* tmp;
            tmp = curr->right;
            curr->data = tmp->data;
            curr->right = tmp->right;
            delete tmp;
         }

      }
      return;
   }

}
void BinarySearchTree::print_postorder()
{
   postorder(root);
}

void BinarySearchTree::postorder(tree_node* p)
{
   if(p != NULL)
   {
      if(p->left) postorder(p->left);
      if(p->right) postorder(p->right);
      cout<<"     "<<p->data<<"\n ";
   }
   else return;
}

int main()
{
    BinarySearchTree b;
    int ch,tmp,tmp1;
    while(1)
    {
       cout<<endl<<endl;
       cout<<" Binary Search Tree Operations "<<endl;
       cout<<" ----------------------------- "<<endl;
       cout<<" 1. Insertion/Creation "<<endl;
       cout<<" 2. Printing "<<endl;
       cout<<" 3. Removal "<<endl;
       cout<<" 4. Exit "<<endl;
       cout<<" Enter your choice : ";
       cin>>ch;
       switch(ch)
       {
           case 1 : cout<<" Enter Number to be inserted : ";
                    cin>>tmp;
                    b.insert(tmp);
                    i++;
                    break;
           case 2 : cout<<endl;
                    cout<<" Printing "<<endl;
                    cout<<" --------------------"<<endl;
                    b.print_postorder();
                    break;
           case 3 : cout<<" Enter data to be deleted : ";
                    cin>>tmp1;
                    b.remove(tmp1);
                    break;
           case 4:
                    return 0;

       }
    }
}

14 Answers 14

up vote 12 down vote accepted

In order to pretty-print a tree recursively, you need to pass two arguments to your printing function:

  • The tree node to be printed, and
  • The indentation level

For example, you can do this:

void BinarySearchTree::postorder(tree_node* p, int indent=0)
{
    if(p != NULL) {
        if(p->left) postorder(p->left, indent+4);
        if(p->right) postorder(p->right, indent+4);
        if (indent) {
            std::cout << std::setw(indent) << ' ';
        }
        cout<< p->data << "\n ";
    }
}

The initial call should be postorder(root);

If you would like to print the tree with the root at the top, move cout to the top of the if.

  • This worked great, thank you. – user1840555 Nov 22 '12 at 6:56
  • This satisfies my cravings for more performance. – Mooing Duck Sep 10 '13 at 19:45
  • @MooingDuck I agree! And makes a perfect edit, too :-) – dasblinkenlight Sep 10 '13 at 19:49
void btree::postorder(node* p, int indent)
{
    if(p != NULL) {
        if(p->right) {
            postorder(p->right, indent+4);
        }
        if (indent) {
            std::cout << std::setw(indent) << ' ';
        }
        if (p->right) std::cout<<" /\n" << std::setw(indent) << ' ';
        std::cout<< p->key_value << "\n ";
        if(p->left) {
            std::cout << std::setw(indent) << ' ' <<" \\\n";
            postorder(p->left, indent+4);
        }
    }
}

With this tree:

btree *mytree = new btree();
mytree->insert(2);
mytree->insert(1);
mytree->insert(3);
mytree->insert(7);
mytree->insert(10);
mytree->insert(2);
mytree->insert(5);
mytree->insert(8);
mytree->insert(6);
mytree->insert(4);
mytree->postorder(mytree->root);

Would lead to this result:

enter image description here

  • 2
    Your example shows you calling a function postOrder(node* p) but the function you've declared is postOrder(node* p, int indent) ? What is the initial value of indent? – James Wierzba Feb 26 '17 at 0:10

It's never going to be pretty enough, unless one does some backtracking to re-calibrate the display output. But one can emit pretty enough binary trees efficiently using heuristics: Given the height of a tree, one can guess what the expected width and setw of nodes at different depths. There are a few pieces needed to do this, so let's start with the higher level functions first to provide context.

The pretty print function:

   // create a pretty vertical tree
   void postorder(Node *p)
   {
      int height = getHeight(p) * 2;
      for (int i = 0 ; i < height; i ++) {
         printRow(p, height, i);
      }
   }

The above code is easy. The main logic is in the printRow function. Let's delve into that.

void printRow(const Node *p, const int height, int depth)
{
        vector<int> vec;
        getLine(p, depth, vec);
        cout << setw((height - depth)*2); // scale setw with depth
        bool toggle = true; // start with left
        if (vec.size() > 1) {
                for (int v : vec) {
                        if (v != placeholder) {
                                if (toggle)
                                        cout << "/" << "   ";
                                else
                                        cout << "\\" << "   ";
                        }
                        toggle = !toggle;
                }
                cout << endl;
                cout << setw((height - depth)*2);
        }
        for (int v : vec) {
                if (v != placeholder)
                        cout << v << "   ";
        }
        cout << endl;
}

getLine() does what you'd expect: it stores all nodes with a given equal depth into vec. Here's the code for that:

void getLine(const Node *root, int depth, vector<int>& vals)
{
        if (depth <= 0 && root != nullptr) {
                vals.push_back(root->val);
                return;
        }
        if (root->left != nullptr)
                getLine(root->left, depth-1, vals);
        else if (depth-1 <= 0)
                vals.push_back(placeholder);
        if (root->right != nullptr)
                getLine(root->right, depth-1, vals);
        else if (depth-1 <= 0)
                vals.push_back(placeholder);
}

Now back to printRow(). For each line, we set the stream width based on how deep we are in the binary tree. This formatting will be nice because, typically, the deeper you go, the more width is needed. I say typically because in degenerate trees, this wouldn't look as pretty. As long as the tree is roughly balanced and smallish (< 20 items), it should turn out fine. A placeholder is needed to align the '/' and '\' characters properly. So when a row is obtained via getLine(), we insert the placeholder if there isn't any node present at the specified depth. The placeholder can be set to anything like (1<<31) for example. Obviously, this isn't robust because the placeholder could be a valid node value. If a coder's got spunk and is only dealing with decimals, one could modify the code to emit decimal-converted strings via getLine() and use a placeholder like "_". (Unfortunately, I'm not such a coder :P)

The result for the following items inserted in order: 8, 12, 4, 2, 5, 15 is

       8   
     /   \   
     4   12   
   /   \   \   
   2   5   15   

getHeight() is left to the reader as an exercise. :) One could even get prettier results by retroactively updating the setw of shallow nodes based on the number of items in deeper nodes. That too is left to the reader as an exercise.

    //Binary tree (pretty print):
    //                        ________________________50______________________                        
    //            ____________30                                  ____________70__________            
    //      ______20____                                          60                ______90          
    //      10          15                                                          80                


    // prettyPrint
    public static void prettyPrint(BTNode node) {
        // get height first
        int height = heightRecursive(node);

        // perform  level order traversal
        Queue<BTNode> queue = new LinkedList<BTNode>();

        int level = 0;
        final int SPACE = 6;
        int nodePrintLocation = 0;

        // special node for pushing when a node has no left or right child (assumption, say this node is a node with value Integer.MIN_VALUE)
        BTNode special = new BTNode(Integer.MIN_VALUE);

        queue.add(node);
        queue.add(null);    // end of level 0
        while(! queue.isEmpty()) {
            node = queue.remove();

            if (node == null) {
                if (!queue.isEmpty()) {
                    queue.add(null);
                }

                // start of new level
                System.out.println();
                level++;
            } else {
                nodePrintLocation = ((int) Math.pow(2, height - level)) * SPACE;

                System.out.print(getPrintLine(node, nodePrintLocation));

                if (level < height) {
                    // only go till last level
                    queue.add((node.left != null) ? node.left : special);
                    queue.add((node.right != null) ? node.right : special);
                }
            }
        }       
    }
    public void prettyPrint() {
        System.out.println("\nBinary tree (pretty print):");
        prettyPrint(root);
    }
    private static String getPrintLine(BTNode node, int spaces) {
        StringBuilder sb = new StringBuilder();

        if (node.data == Integer.MIN_VALUE) {
            // for child nodes, print spaces
            for (int i = 0; i < 2 * spaces; i++) {
                sb.append(" ");
            }

            return sb.toString();
        }

        int i = 0;
        int to = spaces/2;

        for (; i < to; i++) {
            sb.append(' ');
        }
        to += spaces/2;
        char ch = ' ';
        if (node.left != null) {
            ch = '_';
        }
        for (; i < to; i++) {
            sb.append(ch);
        }

        String value = Integer.toString(node.data);
        sb.append(value);

        to += spaces/2;
        ch = ' ';
        if (node.right != null) {
            ch = '_';
        }
        for (i += value.length(); i < to; i++) {
            sb.append(ch);
        }

        to += spaces/2;
        for (; i < to; i++) {
            sb.append(' ');
        }

        return sb.toString();
    }

    private static int heightRecursive(BTNode  node) {
        if (node == null) {
            // empty tree
            return -1;
        }

        if (node.left == null && node.right == null) {
            // leaf node
            return 0;
        }

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

If your only need is to visualize your tree, a better method would be to output it into a dot format and draw it with grapviz.

You can look at dot guide for more information abt syntax etc

  • 2
    It could be good comment. But can not be considered as answer. – Shiplu Mokaddim Nov 21 '12 at 1:28
#include <stdio.h>
#include <stdlib.h>

struct Node
{
    struct Node *left,*right;
    int val;
} *root=NULL;

int rec[1000006];
void addNode(int,struct Node*);
void printTree(struct Node* curr,int depth)
{
    int i;
    if(curr==NULL)return;
    printf("\t");
    for(i=0;i<depth;i++)
        if(i==depth-1)
            printf("%s\u2014\u2014\u2014",rec[depth-1]?"\u0371":"\u221F");
        else
            printf("%s   ",rec[i]?"\u23B8":"  ");
    printf("%d\n",curr->val);
    rec[depth]=1;
    printTree(curr->left,depth+1);
    rec[depth]=0;
    printTree(curr->right,depth+1);
}
int main()
{
    root=(struct Node*)malloc(sizeof(struct Node));
    root->val=50;
    //addNode(50,root);
    addNode(75,root);    addNode(25,root);
    addNode(15,root);    addNode(30,root);
    addNode(100,root);    addNode(60,root);
    addNode(27,root);    addNode(31,root);
    addNode(101,root);    addNode(99,root);
    addNode(5,root);    addNode(61,root);
    addNode(55,root);    addNode(20,root);
    addNode(0,root);    addNode(21,root);
    //deleteNode(5,root);

    printTree(root,0);
    return 0;
}

void addNode(int v,struct Node* traveller)
{
    struct Node *newEle=(struct Node*)malloc(sizeof(struct Node));
    newEle->val=v;
    for(;;)
    {
        if(v<traveller->val)
        {
            if(traveller->left==NULL){traveller->left=newEle;return;}
            traveller=traveller->left;
        }
        else if(v>traveller->val)
        {
            if(traveller->right==NULL){traveller->right=newEle;return;}
            traveller=traveller->right;
        }
        else
        {
            printf("%d Input Value is already present in the Tree !!!\n",v);
            return;
        }
    }
}

Hope, you find it pretty...

Output:

50
ͱ———25
⎸   ͱ———15
⎸   ⎸   ͱ———5
⎸   ⎸   ⎸   ͱ———0
⎸   ⎸   ∟———20
⎸   ⎸        ∟———21
⎸   ∟———30
⎸        ͱ———27
⎸        ∟———31
∟———75
     ͱ———60
     ⎸   ͱ———55
     ⎸   ∟———61
     ∟———100
          ͱ———99
          ∟———101

Here's a little example for printing out an array based heap in tree form. It would need a little adjusting to the algorithm for bigger numbers. I just made a grid on paper and figured out what space index each node would be to look nice, then noticed there was a pattern to how many spaces each node needed based on its parent's number of spaces and the level of recursion as well as how tall the tree is. This solution goes a bit beyond just printing in level order and satisfies the "beauty" requirement.

#include <iostream>
#include <vector>

static const int g_TerminationNodeValue = -999;

class HeapJ
{
public:
HeapJ(int* pHeapArray, int numElements)
{
    m_pHeapPointer = pHeapArray;
    m_numElements = numElements;

    m_treeHeight = GetTreeHeight(1);
}

void Print()
{
    m_printVec.clear();

    int initialIndex = 0;
    for(int i=1; i<m_treeHeight; ++i)
    {
        int powerOfTwo = 1;
        for(int j=0; j<i; ++j)
        {
            powerOfTwo *= 2;
        }

        initialIndex += powerOfTwo - (i-1);
    }

    DoPrintHeap(1,0,initialIndex);

    for(size_t i=0; i<m_printVec.size(); ++i)
    {
        std::cout << m_printVec[i] << '\n' << '\n';
    }
}

private:
int* m_pHeapPointer;
int m_numElements;
int m_treeHeight;
std::vector<std::string> m_printVec;

int GetTreeHeight(int index)
{
    const int value = m_pHeapPointer[index-1];

    if(value == g_TerminationNodeValue)
    {
        return -1;
    }

    const int childIndexLeft = 2*index;
    const int childIndexRight = childIndexLeft+1;

    int valLeft = 0;
    int valRight = 0;

    if(childIndexLeft <= m_numElements)
    {
        valLeft = GetTreeHeight(childIndexLeft);
    }

    if(childIndexRight <= m_numElements)
    {
        valRight = GetTreeHeight(childIndexRight);
    }

    return std::max(valLeft,valRight)+1;
}

void DoPrintHeap(int index, size_t recursionLevel, int numIndents)
{
    const int value = m_pHeapPointer[index-1];

    if(value == g_TerminationNodeValue)
    {
        return;
    }

    if(m_printVec.size() == recursionLevel)
    {
        m_printVec.push_back(std::string(""));
    }

    const int numLoops = numIndents - (int)m_printVec[recursionLevel].size();
    for(int i=0; i<numLoops; ++i)
    {
        m_printVec[recursionLevel].append(" ");
    }

    m_printVec[recursionLevel].append(std::to_string(value));

    const int childIndexLeft = 2*index;
    const int childIndexRight = childIndexLeft+1;

    const int exponent = m_treeHeight-(recursionLevel+1);
    int twoToPower = 1;
    for(int i=0; i<exponent; ++i)
    {
        twoToPower *= 2;
    }
    const int recursionAdjust = twoToPower-(exponent-1);

    if(childIndexLeft <= m_numElements)
    {
        DoPrintHeap(childIndexLeft, recursionLevel+1, numIndents-recursionAdjust);
    }

    if(childIndexRight <= m_numElements)
    {
        DoPrintHeap(childIndexRight, recursionLevel+1, numIndents+recursionAdjust);
    }
}
};

const int g_heapArraySample_Size = 14;
int g_heapArraySample[g_heapArraySample_Size] = {16,14,10,8,7,9,3,2,4,1,g_TerminationNodeValue,g_TerminationNodeValue,g_TerminationNodeValue,0};

int main()
{
    HeapJ myHeap(g_heapArraySample,g_heapArraySample_Size);
    myHeap.Print();

    return 0;
}

/* output looks like this:

           16

     14          10

  8     7     9     3

2   4 1           0

*/
  • It's probably worth mentioning that std::to_string() is available with -std=c++11 or a similar standard version flag. It is not available with -std=c++03 or -std=c++98. – Jonathan Leffler Aug 18 '13 at 2:09

Do an in-order traversal, descending to children before moving to siblings. At each level, that is when you descent to a child, increase the indent. After each node you output, print a newline.

Some psuedocode. Call Print with the root of your tree.

void PrintNode(int indent, Node* node)
{
    while (--indent >= 0)
        std::cout << " ";
    std::cout << node->value() << "\n";
}

void PrintNodeChildren(int indent, Node* node)
{
    for (int child = 0; child < node->ChildCount(); ++child)
    {
        Node* childNode = node->GetChild(child);
        PrintNode(indent, childNode);
        PrintNodeChildren(indent + 1, childNode);
    }
}

void Print(Node* root)
{
   int indent = 0;
   PrintNode(indent, root);
   PrintNodeChildren(indent + 1, root);  
}

From your root, count the number of your left children. From the total number of left children, proceed with printing the root with the indention of the number of left children. Move to the next level of the tree with the decremented number of indention for the left child, followed by an initial two indentions for the right child. Decrement the indention of the left child based on its level and its parent with a double indention for its right sibling.

For an Array I find this much more concise. Merely pass in the array. Could be improved to handle very large numbers(long digit lengths). Copy and paste for c++ :)

#include <math.h>
using namespace std;   
void printSpace(int count){
    for (int x = 0; x<count; x++) {
        cout<<"-";
    }
}
void printHeap(int heap[], int size){
    cout<<endl;
    int height = ceil(log(size)+1); //+1 handle the last leaves
    int width = pow(2, height)*height;
    int index = 0;
    for (int x = 0; x <= height; x++) { //for each level of the tree
        for (int z = 0; z < pow(2, x); z++) { // for each node on that tree level
            int digitWidth = 1;
            if(heap[index] != 0) digitWidth = floor(log10(abs(heap[index]))) + 1;
            printSpace(width/(pow(2,x))-digitWidth);
            if(index<size)cout<<heap[index++];
            else cout<<"-";
            printSpace(width/(pow(2,x)));
        }
        cout<<endl;
    }
}

Here is preorder routine that prints a general tree graph in a compact way:

        void preOrder(Node* nd, bool newLine=false,int indent=0)
        {
                if(nd != NULL) {    
                        if (newLine && indent) {
                                std::cout << "\n" << std::setw(indent) << ' '
                        }  else if(newLine)
                                std::cout << "\n";
                        cout<< nd->_c;
                        vector<Node *> &edges=nd->getEdges();
                        int eSize=edges.size();
                        bool nwLine=false;
                        for(int i=0; i<eSize; i++) {
                                preOrder(edges[i],nwLine,indent+1);
                                nwLine=true;
                        }
                }
        }

int printGraph()
{
     preOrder(root,true);
}

i have a easier code.......... consider a tree made of nodes of structure

 struct treeNode{
  treeNode *lc;
  element data;
  short int bf;
  treeNode *rc;
};

Tree's depth can be found out using

int depth(treeNode *p){
    if(p==NULL) return 0;
    int l=depth(p->lc);
    int r=depth(p->rc);
    if(l>=r)
        return l+1;
    else
        return r+1;
}

below gotoxy function moves your cursor to the desired position

void gotoxy(int x,int y)
{
printf("%c[%d;%df",0x1B,y,x);
}

Then Printing a Tree can be done as:

void displayTreeUpDown(treeNode * root,int x,int y,int px=0){
if(root==NULL) return;
gotoxy(x,y);
int a=abs(px-x)/2;
cout<<root->data.key;
displayTreeUpDown(root->lc,x-a,y+1,x);
displayTreeUpDown(root->rc,x+a,y+1,x);
}

which can be called using:

display(t,pow(2,depth(t)),1,1);

Here is my code. It prints very well,maybe its not perfectly symmetrical. little description:

  • 1st function - prints level by level (root lv -> leaves lv)
  • 2nd function - distance from the beginning of new line
  • 3rd function - prints nodes and calculates distance between two prints;

void Tree::TREEPRINT()
{
    int i = 0;
    while (i <= treeHeight(getroot())){
        printlv(i);
        i++;
        cout << endl;
    }
}

void Tree::printlv(int n){
    Node* temp = getroot();
    int val = pow(2, treeHeight(root) -n+2);
    cout << setw(val) << "";
    prinlv(temp, n, val);
}

void Tree::dispLV(Node*p, int lv, int d)
{
    int disp = 2 * d;
    if (lv == 0){
        if (p == NULL){

            cout << " x ";
            cout << setw(disp -3) << "";
            return;
        }
        else{
            int result = ((p->key <= 1) ? 1 : log10(p->key) + 1);
            cout << " " << p->key << " ";
            cout << setw(disp - result-2) << "";
        }
    }
    else
    {
        if (p == NULL&& lv >= 1){
            dispLV(NULL, lv - 1, d);
            dispLV(NULL, lv - 1, d);
        }
        else{
            dispLV(p->left, lv - 1, d);
            dispLV(p->right, lv - 1, d);
        }
    }
}   

Input:

50-28-19-30-29-17-42-200-160-170-180-240-44-26-27

Output: https://i.stack.imgur.com/TtPXY.png

  • 1
    please do not paste images as output, prefere always to paste (and format) your code / traceback / logs in SO – Arount Jul 31 '17 at 23:22

Here's yet another C++98 implementation, with tree like output.

Sample output:

PHP
└── is
    ├── minor
    │   └── perpetrated
    │       └── whereas
    │           └── skilled
    │               └── perverted
    │                   └── professionals.
    └── a
        ├── evil
        │   ├── incompetent
        │   │   ├── insidious
        │   │   └── great
        │   └── and
        │       ├── created
        │       │   └── by
        │       │       └── but
        │       └── amateurs
        └── Perl

The code:

void printTree(Node* root)
{
        if (root == NULL)
        {
                return;
        }

        cout << root->val << endl;
        printSubtree(root, "");
        cout << endl;
}

void printSubtree(Node* root, const string& prefix)
{
        if (root == NULL)
        {
                return;
        }

        bool hasLeft = (root->left != NULL);
        bool hasRight = (root->right != NULL);

        if (!hasLeft && !hasRight)
        {
                return;
        }

        cout << prefix;
        cout << ((hasLeft  && hasRight) ? "├── " : "");
        cout << ((!hasLeft && hasRight) ? "└── " : "");

        if (hasRight)
        {
                bool printStrand = (hasLeft && hasRight && (root->right->right != NULL || root->right->left != NULL));
                string newPrefix = prefix + (printStrand ? "│   " : "    ");
                cout << root->right->val << endl;
                printSubtree(root->right, newPrefix);
        }

        if (hasLeft)
        {
                cout << (hasRight ? prefix : "") << "└── " << root->left->val << endl;
                printSubtree(root->left, prefix + "    ");
        }
}

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