# Printing BFS (Binary Tree) in Level Order with _specific formatting_

To begin with, this question is not a dup of this one, but builds on it.

Taking the tree in that question as an example,

``````    1
/ \
2   3
/   / \
4   5   6
``````

How would you modify your program to print it so,

``````1
2 3
4 5 6
``````

rather than the general

``````1
2
3
4
5
6
``````

I'm basically looking for intuitions on the most efficient way to do it - I've got a method involving appending the result to a list, and then looping through it. A more efficient way might be to store the last element in each level as it is popped, and print out a new line afterward.

Ideas?

-
depend whether you did too much or to little. too much, remove the / and \ of too little, use arrayindex to know depth –  909 Niklas Dec 12 '09 at 22:37
BTW, why was this question down voted? –  viksit Dec 12 '09 at 22:47
@larsOn Ok, I understand the "remove every second line" comment now. But the first block is only an intuitive representation of the tree as it exists in memory. The third block shows what viksit already knows an algorithm for, and the second block what he would like to obtain instead. –  Pascal Cuoq Dec 12 '09 at 23:12
@viksit perhaps as retaliation by a human being who was (rightly) feeling insulted? Let's stop the silliness, we are being extremely rude. –  Pascal Cuoq Dec 12 '09 at 23:14
This was a interview question to me –  Mustafa Nov 11 '11 at 21:51

Just build one level at a time, e.g.:

``````class Node(object):
def __init__(self, value, left=None, right=None):
self.value = value
self.left = left
self.right = right

def traverse(rootnode):
thislevel = [rootnode]
while thislevel:
nextlevel = list()
for n in thislevel:
print n.value,
if n.left: nextlevel.append(n.left)
if n.right: nextlevel.append(n.right)
print
thislevel = nextlevel

t = Node(1, Node(2, Node(4, Node(7))), Node(3, Node(5), Node(6)))

traverse(t)
``````

Edit: if you're keen to get a small saving in maximum consumed "auxiliary" memory (never having simultaneously all this level and the next level in such "auxiliary" memory), you can of course use `collection.deque` instead of `list`, and consume the current level as you go (via `popleft`) instead of simply looping. The idea of creating one level at a time (as you consume --or iterate on-- the previous one) remains intact -- when you do need to distinguish levels, it's just more direct than using a single big deque plus auxiliary information (such as depth, or number of nodes remaining in a given level).

However, a list that is only appended to (and looped on, rather than "consumed") is quite a bit more efficient than a deque (and if you're after C++ solutions, quite similarly, a std::vector using just `push_back` for building it, and a loop for then using it, is more efficient than a std::deque). Since all the producing happens first, then all the iteration (or consuming), an interesting alternative if memory is tightly constrained might be to use a list anyway to represent each level, then `.reverse` it before you start consuming it (with `.pop` calls) -- I don't have large trees around to check by measurement, but I suspect that this approach would still be faster (and actually less memory-consuming) than `deque` (assuming that the underlying implementation of list [[or std::vector]] actually does recycle memory after a few calls to `pop` [[or `pop_back`]] -- and with the same assumption for deque, of course;-).

-
+1 I can see how using two `vector`s for the two levels could be more efficient than using a single `deque`. Especially if `nextLevel` is moved outside the `while`-loop and cleared instead of allocating a new one on the stack for each level (this is the C++ version I'm talking about, I've no idea how memory is managed in Python). This would also allow for very good cache utilization. –  Andreas Brinck Dec 13 '09 at 7:35
Yes, in C++ you'd definitely want to `swap` the vectors (and clear out the new one -- with the old one's contents -- right after that, if you're looping on it rather than using `pop_back`). In Python you could do `thislevel[:] = nextlevel`, then if needed `del nextlevel[:]`, with similar effect (though I'm not sure the actual performance improvement would be measurable, it sure can't hurt;-). –  Alex Martelli Dec 13 '09 at 7:43
@Alex - thanks for a great answer. The note on the iteration vs consumption of lists was quite informative! –  viksit Dec 13 '09 at 10:15

Sounds like breadth-first traversal to me.

Breadth-first traversal is implemented with a queue. Here, simply insert in the queue a special token that indicate that a newline must be printed. Each time the token is found, print a newline and re-insert the token in the queue (at the end -- that's the definition of a queue).

Start the algorithm with a queue containing the root followed by the special newline token.

-
Yes, I mentioned the BFS part in the title :) I was thinking about the newline in the queue as well, but it seems wrong to intersperse formatting tokens within the queue itself. –  viksit Dec 12 '09 at 22:14
@Viksit Would it be more acceptible to store the depth of each node in the queue? In that case you could simply print a newline each time the current traversal depth is increased. –  Andreas Brinck Dec 12 '09 at 22:27
Ah, yes, "BFS"... I see what this three-letter acronym means now. Is the "S" for search? Isn't "search" always depth-first (or you built your binary tree wrong in the first place)? –  Pascal Cuoq Dec 12 '09 at 22:31
@Andreas Nice! I was a little reluctant to mix special tokens and nodes in the queue too (but you have to do what you have to do...) –  Pascal Cuoq Dec 12 '09 at 22:33
@Pascal I actually thought a little more and came up with a version that didn't require any extra storage whatsoever :) –  Andreas Brinck Dec 12 '09 at 22:46
show 1 more comment

why not keep sentinal in queue and check when all the nodes in current level are processed.

``````public void printLevel(Node n) {
Queue<Integer> q = new ArrayBlockingQueue<Integer>();
Node sentinal = new Node(-1);
q.put(n);
q.put(sentinal);
while(q.size() > 0) {
n = q.poll();
System.out.println(n.value + " ");
if (n == sentinal && q.size() > 0) {
q.put(sentinal); //push at the end again for next level
System.out.println();
}
if (q.left != null) q.put(n.left);
if (q.right != null) q.put(n.right);
}
}
``````
-

A simple Version based on Bread First Search, This code is applicable for graphs in general and can be used for binary trees as well.

``````def printBfsLevels(graph,start):
queue=[start]
path=[]
currLevel=1
levelMembers=1
height=[(0,start)]
childCount=0
print queue
while queue:
visNode=queue.pop(0)
if visNode not in path:
if  levelMembers==0:
levelMembers=childCount
childCount=0
currLevel=currLevel+1
queue=queue+graph.get(visNode,[])
if levelMembers > 0:
levelMembers=levelMembers-1
for node in graph.get(visNode,[]):
childCount=childCount+1
height.append((currLevel,node))
path=path+[visNode]

prevLevel=None

for v,k in sorted(height):
if prevLevel!=v:
if prevLevel!=None:
print "\n"
prevLevel=v
print k,
return height

g={1: [2, 3,6], 2: [4, 5], 3: [6, 7],4:[8,9,13]}
printBfsLevels(g,1)

>>>
[1]
1

2 3 6

4 5 6 7

8 9 13
>>>
``````

Another version based on Recursion, which is specific to binary tree

``````class BinTree:
"Node in a binary tree"
def __init__(self,val,leftChild=None,rightChild=None,root=None):
self.val=val
self.leftChild=leftChild
self.rightChild=rightChild
self.root=root
if not leftChild and not rightChild:
self.isExternal=True

def getChildren(self,node):
children=[]
if node.isExternal:
return []
if node.leftChild:
children.append(node.leftChild)
if node.rightChild:
children.append(node.rightChild)
return children

@staticmethod
def createTree(tupleList):
"Creates a Binary tree Object from a given Tuple List"
Nodes={}
root=None
for item in treeRep:
if not root:
root=BinTree(item[0])
root.isExternal=False
Nodes[item[0]]=root
root.root=root
root.leftChild=BinTree(item[1],root=root)
Nodes[item[1]]=root.leftChild
root.rightChild=BinTree(item[2],root=root)
Nodes[item[2]]=root.rightChild
else:
CurrentParent=Nodes[item[0]]
CurrentParent.isExternal=False
CurrentParent.leftChild=BinTree(item[1],root=root)
Nodes[item[1]]=CurrentParent.leftChild
CurrentParent.rightChild=BinTree(item[2],root=root)
Nodes[item[2]]=CurrentParent.rightChild
root.nodeDict=Nodes
return root

def printBfsLevels(self,levels=None):
if levels==None:
levels=[self]
nextLevel=[]
for node in levels:
print node.val,
for node in levels:
nextLevel.extend(node.getChildren(node))
print '\n'
if nextLevel:
node.printBfsLevels(nextLevel)

##       1
##     2     3
##   4   5  6  7
##  8

treeRep = [(1,2,3),(2,4,5),(3,6,7),(4,8,None)]
tree= BinTree.createTree(treeRep)
tree.printBfsLevels()

>>>
1

2 3

4 5 6 7

8 None
``````
-

My solution is similar to Alex Martelli's, but I separate traversal of the data structure from processing the data structure. I put the meat of the code into iterLayers to keep printByLayer short and sweet.

``````from collections import deque

class Node:
def __init__(self, val, lc=None, rc=None):
self.val = val
self.lc = lc
self.rc = rc

def iterLayers(self):
q = deque()
q.append(self)
def layerIterator(layerSize):
for i in xrange(layerSize):
n = q.popleft()
if n.lc: q.append(n.lc)
if n.rc: q.append(n.rc)
yield n.val
while (q):
yield layerIterator(len(q))

def printByLayer(self):
for layer in self.iterLayers():
print ' '.join([str(v) for v in layer])

root = Node(1, Node(2, Node(4, Node(7))), Node(3, Node(5), Node(6)))
root.printByLayer()
``````

which prints the following when run:

``````1
2 3
4 5 6
7
``````
-

A version that doesn't require extra storage:

``````std::deque<Node> bfs;
bfs.push_back(start);
int nodesInThisLayer = 1;
int nodesInNextLayer = 0;
while (!bfs.empty()) {
Node front = bfs.front();
bfs.pop_front();
for (/*iterate over front's children*/) {
++nodesInNextLayer;
nodes.push_back(child);
}
std::cout << node.value;
if (0 == --nodesInThisLayer) {
std::cout << std::endl;
nodesInThisLayer = nodesInNextLayer;
nodesInNextLayer = 0;
} else {
std::cout << " ";
}
}
``````

P.S. sorry for the C++ code, I'm not very fluent in Python yet.

-
@Andreas - nice! I was looking at a version of this algorithm where I would store the "level" or "depth" of where the loop was (so, this tree would have 3 levels). The problem I faced was how to increment this level each time. Looks like your approach of storing the depth of each element works better. –  viksit Dec 12 '09 at 22:52
@Viksit If you look closer I only stores two extra integers, one for how many nodes are left to process in the current level and one for how many nodes are left to process in the next level (Or was this what you meant?) –  Andreas Brinck Dec 12 '09 at 22:56

The following code will print each level of binary tree into new line:

``````public void printbylevel(node root){
int counter = 0, level = 0;

level = 1;
if(root.child1 != null)counter++;
if(root.child2 != null)counter++;

while(!qu.isEmpty()){
node temp = qu.remove();
level--;
System.out.print(temp.val);
if(level == 0 ){
System.out.println();

level = counter;
counter = 0;
}
if(temp.child1 != null){
counter++;
}
if(temp.child2 != null){
counter++;
}
}
}
``````
-

Here my code prints the tree level by level as well as upside down

``````int counter=0;// to count the toatl no. of elments in the tree

void tree::print_treeupsidedown_levelbylevel(int *array)
{
int j=2;
int next=j;
int temp=0;
while(j<2*counter)
{
if(array[j]==0)
break;

while(array[j]!=-1)
{
j++;
}

for(int i=next,k=j-1 ;i<k; i++,k--)
{
temp=array[i];
array[i]=array[k];
array[k]=temp;
}

next=j+1;
j++;
}

for(int i=2*counter-1;i>=0;i--)
{
if(array[i]>0)
printf("%d ",array[i]);

if(array[i]==-1)
printf("\n");
}
}

void tree::BFS()
{
queue<node *>p;

node *leaf=root;

int array[2*counter];
for(int i=0;i<2*counter;i++)
array[i]=0;

int count=0;

node *newline=new node; //this node helps to print a tree level by level
newline->val=0;
newline->left=NULL;
newline->right=NULL;
newline->parent=NULL;

p.push(leaf);
p.push(newline);

while(!p.empty())
{
leaf=p.front();
if(leaf==newline)
{
printf("\n");
p.pop();
if(!p.empty())
p.push(newline);
array[count++]=-1;
}
else
{
cout<<leaf->val<<" ";
array[count++]=leaf->val;

if(leaf->left!=NULL)
{
p.push(leaf->left);
}
if(leaf->right!=NULL)
{
p.push(leaf->right);
}
p.pop();
}
}
delete newline;

print_treeupsidedown_levelbylevel(array);
}
``````

Here in my code the function BFS prints the tree level by level, which also fills the data in an int array for printing the tree upside down. (note there is a bit of swapping is used while printing the tree upside down which helps to achieve our goal). If the swapping is not performed then for a tree like

``````                    8
/  \
1    12
\     /
5   9
/   \
4     7
/
6
``````

o/p will be

``````  6
7 4
9 5
12 1
8
``````

but the o/p has to be

``````  6
4 7
5 9
1 12
8
``````

this the reason why swapping part was needed in that array.

-

This is breadth first search, so you can use a queue and recursively do this in a simple and compact way ...

``````# built-in data structure we can use as a queue
from collections import deque