# Algorithm complexity

I got this problem "Implement this method to return the sum of the two largest numbers in a given array."

I resolved it in this way:

`````` public static int sumOfTwoLargestElements(int[] a) {

int firstLargest = largest(a, 0, a.length-1);

int firstLarge =  a[firstLargest];
a[firstLargest] = -1;

int secondLargest = largest(a, 0, a.length-1);

return firstLarge + a[secondLargest];
}

private static int largest(int s[], int start , int end){

if (end - start == 0){

return end;
}

int a = largest(s, start, start + (end-start)/2) ;
int b = largest(s, start + (end-start)/2+1 , end);
if(s[a] > s[b]) {

return a;
}else {

return b;
}

}
``````

Explanation: I implemented a method 'largeset'. This method is responsible to get the largest number in a given array.

I call the method tow times in the same array. The first call will get the first largest number.I put it aside into variable and i replace it by '-1' number into the array. Then, i call the largest medhod second time.

Some one can tell me what is the complexity of this algo? please

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You can find both numbers in the first pass and spare the second pass. It won't change the complexity but it'll run faster. :-) – gfgqtmakia Jul 12 '13 at 18:42
+1 for the above comment. Also if it is just a list of numbers, then there are various other ways of solving the same... if you use an mechanism like count sort etc with negligible extra space and O(n) time complexity... – dharam Jul 12 '13 at 18:46
The real measure of complexity is that of future readers of this code, the time they spend figuring out how this works, when a much simpler algorithm will do the job. There is no clear benefit to recursion, or why two passes through the set are needed. And the algorithm is fundamentally broken (returns an incorrect result) when the two largest integers in the array are both less than -1. Accckkk! – spencer7593 Jul 12 '13 at 19:16

The time complexity of the algorithm is `O(n)`.

Each recursive call's complexity is actually:

``````f(n) = 2*f(n/2) + CONST
``````

It is easy to see (by induction1) that `f(n) <= CONST'*n` - and thus it is `O(n)`.

The space complexity is `O(logN)` - because this is the maximal depth of the recursion - so you allocate `O(logN)` memory on the call stack.

(1) If you use `f(n) = 2*n*CONST - CONST` you get:

``````f(n) = 2*f(n/2) + CONST = (h.i.) 2*(2*CONST*n/2 - CONST) + CONST =
=  2*n*CONST - 2CONST + CONST = 2*n*CONST - CONST
``````

(Checking the base is is left as exercise for the reader)

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So, f(0) has negative complexity? I rather think the complexity is O(2^n * log n). – undur_gongor Jul 12 '13 at 19:01
@undur_gongor The formula does not apply for the base or lower values, obviously (this is the point of induction, we prove from some point and up, all bets are off below it). The base should be for `f(1)`, and as mentioned left as an exercise. – amit Jul 12 '13 at 19:02
@undur_gongor: And, to be exact - since we used only equality in the proof, we actually showed that the `f(n)` is in `Theta(n)` - so `O(n)` is a tight asymptotic bound. – amit Jul 12 '13 at 19:05
I must be blind. Sorry for the noise. +1 – undur_gongor Jul 12 '13 at 19:12

The complexity of the algorithm would be measured as `O(n)`.

But the real answer is that your algorithm is WAY more complex, and more expensive in terms of machine resources than it needs to be. And it's WAY more expensive in terms of someone reading your code and figuring out what it's doing.

The complexity of your algorithm should really be on the order of:

``````public static int sumOfTwoLargestElements(int[] a) {

//TODO handle case when argument is null,
//TODO handle case when array has less than two non-null elements, etc.

int firstLargest = Integer.MIN_VALUE;
int secondLargest = Integer.MIN_VALUE;
for (int v : a) {
if ( v > firstLargest ) {
secondLargest = firstLargest;
firstLargest = v;
} else if ( v > secondLargest ) secondLargest = v;
}
//TODO handle case when sum exceeds Integer.MAX_VALUE;
return firstLargest + secondLargest;
}
``````
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I think you'll need `if ( v > firstLargest ) { secondLargest = firstLargest; firstLargest = v };` – Rhialto Jul 12 '13 at 19:04

My purpose is to implement an algorithm for 'largest' with complexity less than O(n). That is why i didn't want to do the for loop. Thanks for your answers:)

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It is not possible to do better than O(n) on an unsorted array. It is certainly possible to do better than your code--spencer's is a good example. You only need to make one pass through the array, and of course modifying the array just to get a statistic is real no-no. What if the given array were read-only? – Lee Daniel Crocker Aug 5 '13 at 0:02

The reccurence for 'Largest' method is:

``````        _
f(n) = !
!  1        n = 1
!  2f(n/2)  n >=2
!_

If we experiment some few cases, we notice that

f(n) = 2^log(n)   When n is power of 2       Rq:Log base 2

Proof:

By induction,

f(1) = 2^log(1) = 2^log(2^0) = 1

We suppose that f(n) = 2^log(n)=n

We show f(2n) = 2^log(2n)= 2n^log(2)=2n

f(2n) = 2*f(2n/2) = 2*f(n)
= 2*2^log(n)
= 2^log(n) + 1
= 2^log(n) + log(2^0)
= 2^log(2n)
= 2n^log(2)  by log properties
= 2n
Then f(n) = 2^log(n)=n  When n is power of2-smooth function f(2n) < c f(n). it follows smooth function properties that **f(n) = theta of n**
``````
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