Reading binary tree floor by floor. What would be the fastest way to do that?

Let's say theres a binary tree like that.

I'd like to read it floor by floor (from left to the right) so the output would look like:

``````2 4 5 3 1 3 9
``````

Thanks.

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Its BFS, use queue. –  Grijesh Chauhan Nov 18 '12 at 17:11
Also note that my first code prints tree level by level –  Sumit Kumar Saha Nov 18 '12 at 20:52

Its Printing in `BFS`, You should use auxiliary data-structure Queue: Learn here

`listed below is pseudocode for a simple queue based level order traversal`,

``````levelorder(root)
q = empty queue
q.enqueue(root)
while not q.empty do
node := q.dequeue()
visit(node)
if node.left ≠ null
q.enqueue(node.left)
if node.right ≠ null
q.enqueue(node.right)
``````
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removed unnecessary details. –  Grijesh Chauhan Nov 18 '12 at 17:22
`````` This is one way of doing it.
void tree::BFS()
{
queue<node *>p;
node *leaf=root;

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

}

This implementation is using queue.There are other implementations also in which you
do not need queue.

The below mwntioned code do not need any queue.

1) Using the parent pointer, get the level of the given node. Also, get the root of the
tree.

int level = 1;
struct node *temp = node;

/* Find the level of the given node and root of the tree */
while(temp->parent != NULL)
{
temp = temp->parent;
level++;
}
/* temp is now root of the tree and level is level of the node */
2) Once we have level of the given node and root of the tree, traverse the tree from
root to the calculated level + 1. We are traversing one extra level for the case
when given node is the rightmost node of its level. While traversing if you visit
the given node, mark visited flag as 1. Print the node just after the visited flag.

#include <stdio.h>
#include <stdlib.h>

/* Note the structure of root. It has data and pointers to left childe, right child and
parent node */
struct node
{
int data;
struct node *left;
struct node *right;
struct node *parent;
};

/* Prints the level order successor of node
root  --> root of the tree
level --> level of node */
void _print(struct node* root, struct node *node, int level)
{
static int visited = 0;
if(root == NULL)
return;
if(level == 1)
{
/* If the given node is visited then print the current root */
if(visited == 1)
{
printf("Level Order Successor is %d ", root->data);
visited = 0;
return;
}
/* If the current root is same as given node then change the visited flag
so that current node is printed */
if(root == node)
visited = 1;
}
else if (level > 1)
{
_print(root->left, node, level-1);
_print(root->right, node, level-1);
}
}

void printLevelOrderSuccessor(struct node *node)
{
int level = 1;
struct node *temp = node;

/* Find the level of the given node and root of the tree */
while(temp->parent != NULL)
{
temp = temp->parent;
level++;
}
_print(temp, node, level);
}

/* Helper function that allocates a new node with the
given data and NULL left and right pointers. */
struct node* newNode(int data)
{
struct node* node = (struct node*)malloc(sizeof(struct node));
node->data = data;
node->left = NULL;
node->right = NULL;
node->parent = NULL;
return(node);
}

/* Driver program to test above functions*/
int main()
{
struct node *root  = newNode(1);
root->parent      = NULL;
root->left         = newNode(2);
root->right        = newNode(3);
root->left->parent = root;
root->right->parent = root;

root->left->left  = newNode(4);
root->right->right = newNode(5);

root->left->left->parent   = root->left;
root->right->right->parent  = root->right;

// printf("\n Level order successor of %d is: ", root->right->data);
printLevelOrderSuccessor(root->left->left);

return 0;
}

Time Complexity: O(n) for both the algos.
Space Complexity: O(n) if we consider the size of recursion stack, otherwise O(1).
``````
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