What algorithms can be used to draw a binary tree in the console? The tree is implemented in C. For example, a BST with numbers: 2 3 4 5 8 would be shown in the console as:
closed as offtopic by George Stocker♦ Nov 12 '14 at 0:19
This question appears to be offtopic. The users who voted to close gave this specific reason:
 "Questions seeking debugging help ("why isn't this code working?") must include the desired behavior, a specific problem or error and the shortest code necessary to reproduce it in the question itself. Questions without a clear problem statement are not useful to other readers. See: How to create a Minimal, Reproducible Example." – George Stocker

2create a .dot file containing your nodes and edges, and render it with graphviz. Looks neat – Johannes Schaub  litb Apr 29 '09 at 10:41

@litb: nice. I actually implemented a renderlist and a framebuffer and generate my own BMPs! – user82238 May 21 '09 at 22:13

Please update picture :) – Andreas Storvik Strauman May 18 '15 at 16:05
Check out Printing Binary Trees in Ascii
From @AnyOneElse Pastbin below:
!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!
!!!Code originally from /http://www.openasthra.com/ctidbits/printingbinarytreesinascii/
!!! Just saved it, cause the website is down.
!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!
Printing Binary Trees in Ascii
Here we are not going to discuss what binary trees are (please refer this, if you are looking for binary search trees), or their operations but printing them in ascii.
The below routine prints tree in ascii for a given Tree representation which contains list of nodes, and node structure is this
struct Tree
{
Tree * left, * right;
int element;
};
This pic illustrates what the below routine does on canvas..
ascii tree
Here is the printing routine..
b5855d39a6b8a2735ddcaa04a404c125001
Auxiliary routines..
//This function prints the given level of the given tree, assuming
//that the node has the given x cordinate.
void print_level(asciinode *node, int x, int level)
{
int i, isleft;
if (node == NULL) return;
isleft = (node>parent_dir == 1);
if (level == 0)
{
for (i=0; i<(xprint_next((node>lablenisleft)/2)); i++)
{
printf(" ");
}
print_next += i;
printf("%s", node>label);
print_next += node>lablen;
}
else if (node>edge_length >= level)
{
if (node>left != NULL)
{
for (i=0; i<(xprint_next(level)); i++)
{
printf(" ");
}
print_next += i;
printf("/");
print_next++;
}
if (node>right != NULL)
{
for (i=0; i<(xprint_next+(level)); i++)
{
printf(" ");
}
print_next += i;
printf("\\");
print_next++;
}
}
else
{
print_level(node>left,
xnode>edge_length1,
levelnode>edge_length1);
print_level(node>right,
x+node>edge_length+1,
levelnode>edge_length1);
}
}
//This function fills in the edge_length and
//height fields of the specified tree
void compute_edge_lengths(asciinode *node)
{
int h, hmin, i, delta;
if (node == NULL) return;
compute_edge_lengths(node>left);
compute_edge_lengths(node>right);
/* first fill in the edge_length of node */
if (node>right == NULL && node>left == NULL)
{
node>edge_length = 0;
}
else
{
if (node>left != NULL)
{
for (i=0; i<node>left>height && i < MAX_HEIGHT; i++)
{
rprofile[i] = INFINITY;
}
compute_rprofile(node>left, 0, 0);
hmin = node>left>height;
}
else
{
hmin = 0;
}
if (node>right != NULL)
{
for (i=0; i<node>right>height && i < MAX_HEIGHT; i++)
{
lprofile[i] = INFINITY;
}
compute_lprofile(node>right, 0, 0);
hmin = MIN(node>right>height, hmin);
}
else
{
hmin = 0;
}
delta = 4;
for (i=0; i<hmin; i++)
{
delta = MAX(delta, gap + 1 + rprofile[i]  lprofile[i]);
}
//If the node has two children of height 1, then we allow the
//two leaves to be within 1, instead of 2
if (((node>left != NULL && node>left>height == 1) 
(node>right != NULL && node>right>height == 1))&&delta>4)
{
delta;
}
node>edge_length = ((delta+1)/2)  1;
}
//now fill in the height of node
h = 1;
if (node>left != NULL)
{
h = MAX(node>left>height + node>edge_length + 1, h);
}
if (node>right != NULL)
{
h = MAX(node>right>height + node>edge_length + 1, h);
}
node>height = h;
}
asciinode * build_ascii_tree_recursive(Tree * t)
{
asciinode * node;
if (t == NULL) return NULL;
node = malloc(sizeof(asciinode));
node>left = build_ascii_tree_recursive(t>left);
node>right = build_ascii_tree_recursive(t>right);
if (node>left != NULL)
{
node>left>parent_dir = 1;
}
if (node>right != NULL)
{
node>right>parent_dir = 1;
}
sprintf(node>label, "%d", t>element);
node>lablen = strlen(node>label);
return node;
}
//Copy the tree into the ascii node structre
asciinode * build_ascii_tree(Tree * t)
{
asciinode *node;
if (t == NULL) return NULL;
node = build_ascii_tree_recursive(t);
node>parent_dir = 0;
return node;
}
//Free all the nodes of the given tree
void free_ascii_tree(asciinode *node)
{
if (node == NULL) return;
free_ascii_tree(node>left);
free_ascii_tree(node>right);
free(node);
}
//The following function fills in the lprofile array for the given tree.
//It assumes that the center of the label of the root of this tree
//is located at a position (x,y). It assumes that the edge_length
//fields have been computed for this tree.
void compute_lprofile(asciinode *node, int x, int y)
{
int i, isleft;
if (node == NULL) return;
isleft = (node>parent_dir == 1);
lprofile[y] = MIN(lprofile[y], x((node>lablenisleft)/2));
if (node>left != NULL)
{
for (i=1; i <= node>edge_length && y+i < MAX_HEIGHT; i++)
{
lprofile[y+i] = MIN(lprofile[y+i], xi);
}
}
compute_lprofile(node>left, xnode>edge_length1, y+node>edge_length+1);
compute_lprofile(node>right, x+node>edge_length+1, y+node>edge_length+1);
}
void compute_rprofile(asciinode *node, int x, int y)
{
int i, notleft;
if (node == NULL) return;
notleft = (node>parent_dir != 1);
rprofile[y] = MAX(rprofile[y], x+((node>lablennotleft)/2));
if (node>right != NULL)
{
for (i=1; i <= node>edge_length && y+i < MAX_HEIGHT; i++)
{
rprofile[y+i] = MAX(rprofile[y+i], x+i);
}
}
compute_rprofile(node>left, xnode>edge_length1, y+node>edge_length+1);
compute_rprofile(node>right, x+node>edge_length+1, y+node>edge_length+1);
}
Here is the asciii tree structure…
struct asciinode_struct
{
asciinode * left, * right;
//length of the edge from this node to its children
int edge_length;
int height;
int lablen;
//1=I am left, 0=I am root, 1=right
int parent_dir;
//max supported unit32 in dec, 10 digits max
char label[11];
};
output:
2
/ \
/ \
/ \
1 3
/ \ / \
0 7 9 1
/ / \ / \
2 1 0 8 8
/
7

That's a nice link! – anon Apr 29 '09 at 10:46

3

3

2Unfortunately it seems so. Couldn't find it Google Cache or at Internet Archive Wayback machine. This could be it, I haven't tried to run it yet: datastructuresblog.wordpress.com/2007/12/21/… – Jonas Elfström Jul 9 '10 at 6:40

6Found it, saved it! pastebin.com/d3AtFKAK and web.archive.org/web/20071224095835/http://www.openasthra.com/… – AnyOneElse Sep 24 '13 at 9:04
Code:
int _print_t(tnode *tree, int is_left, int offset, int depth, char s[20][255])
{
char b[20];
int width = 5;
if (!tree) return 0;
sprintf(b, "(%03d)", tree>val);
int left = _print_t(tree>left, 1, offset, depth + 1, s);
int right = _print_t(tree>right, 0, offset + left + width, depth + 1, s);
#ifdef COMPACT
for (int i = 0; i < width; i++)
s[depth][offset + left + i] = b[i];
if (depth && is_left) {
for (int i = 0; i < width + right; i++)
s[depth  1][offset + left + width/2 + i] = '';
s[depth  1][offset + left + width/2] = '.';
} else if (depth && !is_left) {
for (int i = 0; i < left + width; i++)
s[depth  1][offset  width/2 + i] = '';
s[depth  1][offset + left + width/2] = '.';
}
#else
for (int i = 0; i < width; i++)
s[2 * depth][offset + left + i] = b[i];
if (depth && is_left) {
for (int i = 0; i < width + right; i++)
s[2 * depth  1][offset + left + width/2 + i] = '';
s[2 * depth  1][offset + left + width/2] = '+';
s[2 * depth  1][offset + left + width + right + width/2] = '+';
} else if (depth && !is_left) {
for (int i = 0; i < left + width; i++)
s[2 * depth  1][offset  width/2 + i] = '';
s[2 * depth  1][offset + left + width/2] = '+';
s[2 * depth  1][offset  width/2  1] = '+';
}
#endif
return left + width + right;
}
void print_t(tnode *tree)
{
char s[20][255];
for (int i = 0; i < 20; i++)
sprintf(s[i], "%80s", " ");
_print_t(tree, 0, 0, 0, s);
for (int i = 0; i < 20; i++)
printf("%s\n", s[i]);
}
Output:
.(006).
.(001). .(008).
.(02) .(003). (007) (009)
.(06) (002) .(005)
.(08). (004)
(09) (07)
or
(006)
+++
(001) (008)
+++ +++
(02) (003) (007) (009)
++ +++
(06) (002) (005)
++ ++
(08) (004)
+++
(09) (07)

6

I tried to use this with a tree with string values. Didn't really work well, even when increasing the width variable. Also the fixed amount of lines is unfortunate. – Ray Hulha Oct 4 '16 at 20:40
Some hints: the spacing between nodes at the same depth, (e.g., 2 and 4 or 3 and 8 in your example), is a function of the depth.
Each printed row consists of all nodes with the same depth, printed from the leftmost node to the rightmost node.
So you need a way to, for example, arrange your nodes in arrays of rows, according to their depth, in order of their leftmostness.
Starting from the root node, a breadthfirst search will visit nodes in the order of depth and leftmostness.
Spacing between nodes can be found by finding the maximum height of the tree, using some constant width for the deepest nodes, and doubling that width for every lesser depth, so that the width for any depth = ( 1 + maxdepth  currentdepth ) * deepestwidth.
That number gives you the printed "horizontal width" of each node at any particular depth.
A left node is horizontally positioned in the left half of its parent's width, a righ node in the right half. You'll insert dummy spacers for any node that doesn't have parents; an easier way to do this would be to ensure that all leaves are at the same depth as the deepest node, with blank as their value. Obviously, you'll also have to compensate for the width of the values, perhaps by making the greatest depth's width at least as wide as the printed (decimal representaion, presumably) of he largest valued node.
Here is one more take when a tree is implemented in array:
#include <stdio.h>
#include <math.h>
#define PARENT(i) ((i1) / 2)
#define NUM_NODES 15
#define LINE_WIDTH 70
int main() {
int tree[NUM_NODES]={0,1,2,3,4,5,6,7,8,9,1,2,3,4,5};
int print_pos[NUM_NODES];
int i, j, k, pos, x=1, level=0;
print_pos[0] = 0;
for(i=0,j=1; i<NUM_NODES; i++,j++) {
pos = print_pos[PARENT(i)] + (i%2?1:1)*(LINE_WIDTH/(pow(2,level+1))+1);
for (k=0; k<posx; k++) printf("%c",i==0i%2?' ':'');
printf("%d",tree[i]);
print_pos[i] = x = pos+1;
if (j==pow(2,level)) {
printf("\n");
level++;
x = 1;
j = 0;
}
}
return 0;
}
Output:
0
12
34 56
78 91 23 45
I have this little solution in c++  it could readily be converted to c.
My solution does require a supplementary data structure to store the current node's depth within the tree (this because if you're working with an incomplete tree a given subtree's depth may not be consistent with it's depth in the full tree.)
#include <iostream>
#include <utility>
#include <algorithm>
#include <list>
namespace tree {
template<typename T>
struct node
{
T data;
node* l;
node* r;
node(T&& data_ = T()) : data(std::move(data_)), l(0), r(0) {}
};
template<typename T>
int max_depth(node<T>* n)
{
if (!n) return 0;
return 1 + std::max(max_depth(n>l), max_depth(n>r));
}
template<typename T>
void prt(node<T>* n)
{
struct node_depth
{
node<T>* n;
int lvl;
node_depth(node<T>* n_, int lvl_) : n(n_), lvl(lvl_) {}
};
int depth = max_depth(n);
char buf[1024];
int last_lvl = 0;
int offset = (1 << depth)  1;
// using a queue means we perform a breadth first iteration through the tree
std::list<node_depth> q;
q.push_back(node_depth(n, last_lvl));
while (q.size())
{
const node_depth& nd = *q.begin();
// moving to a new level in the tree, output a new line and calculate new offset
if (last_lvl != nd.lvl)
{
std::cout << "\n";
last_lvl = nd.lvl;
offset = (1 << (depth  nd.lvl))  1;
}
// output <offset><data><offset>
if (nd.n)
sprintf(buf, " %*s%d%*s", offset, " ", nd.n>data, offset, " ");
else
sprintf(buf, " %*s", offset << 1, " ");
std::cout << buf;
if (nd.n)
{
q.push_back(node_depth(nd.n>l, last_lvl + 1));
q.push_back(node_depth(nd.n>r, last_lvl + 1));
}
q.pop_front();
}
std::cout << "\n";
}
}
int main()
{
typedef tree::node<int> node;
node* head = new node();
head>l = new node(1);
head>r = new node(2);
head>l>l = new node(3);
head>l>r = new node(4);
head>r>l = new node(5);
head>r>r = new node(6);
tree::prt(head);
return 0;
}
It prints out the following:
0
1 2
3 4 5 6

Thanks. I am using your solution, but there is a minor error. The second q.push_back(node_depth(nd.n>l, last_lvl + 1)) should be q.push_back(node_depth(nd.n>r, last_lvl + 1)) – sank Dec 18 '12 at 2:55

@sank  not sure what you're talking about  it does calculate the
node_depth
of the right subtree already. Prehaps you mistyped it when you copied it? Working code here: ideone.com/wrY8Vo – Steve Lorimer Dec 18 '12 at 3:53
Look at the output of pstree command in Linux. It does not produce the output in the exact form that you want, but IMHO it's more readable that way.
I second litb's recommendation. I had to do this lately to print the VAD tree of a Windows process and I used DOT language (just print out nodes from your binary tree walking function):
http://en.wikipedia.org/wiki/DOT_language
For example, your DOT file would contains:
digraph graphname { 5 > 3; 5 > 8; 3 > 4; 3 > 2; }
You generate the graph with dotty.exe or convert it to PNG using dot.exe.
A very simple C++ solution printing tree in horizontal direction:
5
1
5
9
7
14
Code (Node::print()
function is what matters):
#include<iostream>
using namespace std;
class Tree;
class Node{
public:
Node(int val): _val(val){}
int val(){ return _val; }
void add(Node *temp)
{
if (temp>val() > _val)
{
if (_rchild)
_rchild>add(temp);
else
{
_rchild = temp;
}
}
else
{
if (_lchild)
_lchild>add(temp);
else
{
_lchild = temp;
}
}
}
void print()
{
for (int ix = 0; ix < _level; ++ix) cout << ' ';
cout << _val << endl;
++_level;
if (_lchild)
{
_lchild>print();
_level;
}
if (_rchild)
{
_rchild>print();
_level;
}
}
private:
int _val;
Node *_lchild;
Node *_rchild;
static int _level;
};
int Node::_level = 0;
class Tree{
public:
Tree(): _root(0){}
void add(int val)
{
Node *temp = new Node(val);
if (!_root)
_root = temp;
else
_root>add(temp);
}
void print()
{
if (!_root)
return;
_root>print();
}
private:
Node *_root;
};
int main()
{
Tree tree;
tree.add(5);
tree.add(9);
tree.add(1);
tree.add(7);
tree.add(5);
tree.add(14);
tree.print();
}
I think you shouldn't code that yourself, but have a look at Tree::Visualize which seems to be a nice Perl implementation with different possible styles and use/port one of the algorithms there.
I've got a Ruby program that calculates the coordinates where each node in a binary tree should be drawn here: http://hectorcorrea.com/Blog/DrawingaBinaryTreeinRuby
This code uses a very basic algorithm to calculate the coordinates and it's not "area efficient" but it's a good start. If you want to the see the code "live" you can test it here: http://binarytree.heroku.com/


@Norman  yes indeed, but he is also asking for an algorithm too and he can find that on the post that I listed. – Hector Correa Apr 11 '11 at 12:33