# Need to find Time and Space complexity of my algorithm

Somehow i have managed to write an algorithm for Constructing a binary tree from it's inorder and preorder traversal data.

I am not sure how to compute time and space complexity of this algorithm.

My guess is

``````first pass  --> n(findInNode) + n/2 (constructTree) + n/2 (constructTree)
second pass --> n/2(findInNode) + n/4 (constructTree) + n/4 (constructTree)
etc..
``````

So it should be approx(3logn)

Please correct me if i am wrong.

``````public class ConstructTree {
public static void main(String[] args) {
int[] preOrder = new int[] { 1, 2, 3, 4, 5 };
int[] inOrder = new int[] { 2, 1, 4, 3, 5 };

int start = 0;
int end = inOrder.length -1;
Node root =constructTree(preOrder, inOrder, start, end);

System.out.println("In order Tree"); root.inOrder(root);
System.out.println("");
System.out.println("Pre order Tree"); root.preOrder(root);
System.out.println("");

}

public static int preInd = 0;
public static Node constructTree(int[] pre, int[] in, int start, int end) {
if (start > end) {
return null;
}

int nodeVal = pre[preInd++];
Node node = new Node(nodeVal);
if (start != end) {
int ind = findInNode(nodeVal, in, start, end);
node.left = constructTree(pre, in, start, ind-1);
node.right = constructTree(pre, in, ind+1, end);
}
return node;
}

public static int findInNode(int nodeVal, int[] in, int start, int end) {
int i = 0;
for (i = start; i <= end; i++) {
if(in[i] == nodeVal)
{
return i;
}
}
return -1;
}

}
``````
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How can this be sublinear if you insert all elements in the tree ??? At least O(N), with closed eyes. –  Yves Daoust Jul 2 '12 at 19:06

Time complexity = O(n^2). 2 recursive calls take O(n) to construct the binary tree with each node construction taking O(n) for a sequential search which is O(n^2).

Space complexity = constant ignoring the 2 input arrays and the constructed binary tree which is the output

-

To estimate the runtime complexity, let’s start off with the easy one, `findInNode`:

TfindInNode = Ο(n)

Estimating `constructTree` is a little more difficult since we have recursive calls. But we can use this pattern to split the … into local and recursive costs:

With each call of `constructTree` we have local costs of TfindInNode = Ο(n) and two recursive calls of `constructTree` with n-1 instead of n. So

TconstructTree(n) = TfindInNode(n) + 2 · TconstructTree(n-1))

Since the number of recursive calls of `constructTree` is doubled with every call of `constructTree`, the recursive call tree grows with each recursion step as follows:

``````                  n                    | 2^0·n = 1·n
_________|_________           |
|                   |          |
n-1                 n-1         | 2^1·n = 2·n
____|____           ____|____      |
|         |         |         |     |
n-2       n-2       n-2       n-2    | 2^2·n = 4·n
/ \       / \       / \       / \    |
n-3 n-3   n-3 n-3   n-3 n-3   n-3 n-3  | 2^3·n = 8·n
``````

So the total number of calls of `constructTree` after the initial call of `constructTree` is n, after the first step of recursive calls it is n+2·n calls, after the second step it is n+2·n+4·n, and so on. And since the total depth of this recursive calls tree is n (with each recursion n is decremented by 1), the number of total calls of `constructTree` sums up to:

20 + 21 + 22 + … + 2n = 2n+1-1

Thus:

TconstructTree(n) = (2n+1-1)·n ∈ Ο(2n).

So your algorithm has an exponential time complexity.

The space complexity is also Ο(2n) since you have a local space cost of 1 per recursive call of `constructTree`.

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I disagree with the analysis of deriving the complexity. The 2 recursive calls are constructing the binary tree, so in the end they construct n nodes. And the search takes O(n) for each node constructed. Hence the complexity is O(n^2). –  user1168577 Jul 3 '12 at 3:10