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So say I have an algorithm like this:

void dummy_algorithm(int a[]) {
   int center = floor(a.length/2);
   //For reference purposes: Loop 1  
   for(int i = 0; i < center; i++) {
       //The best code you've ever seen
   //Loop 2
   for(int j = center + 1; j < a.length; j++) {
      //Slightly less awesome code

It's pretty basic stuff. I know both loops iterate through one half of the array, thus giving each an (n/2) complexity. However, the total work the method does is obviously O(n).

So, my question is: How do I prove (via a recurrence relation) that this algorithm is O(n)? Or am I wrong on this altogether?

Note: I cannot combine the two loops into one. They preform actions that eventually go into recursive calls. Anything else you can think of isn't allowed. There are a lot of constraints on this problem.

share|improve this question
Do you really need to prove that O(n/2 + n/2) is in O(n)? It's what I'd call trivial. – keyser Nov 1 '12 at 16:43
Your code uses two loops, so assuming the content of the loops are both O(n), then you actually have O(n) + O(n), which is just O(2n) which is the same as O(n). – Niet the Dark Absol Nov 1 '12 at 16:44
A recurrence relation is for analyzing a recursive function. – btilly Nov 1 '12 at 16:47
up vote 1 down vote accepted

If you are really looking for a proof that O(x) + O(y) = O(x+y), it would work along these lines:

R1 ∈ O(x) ∧ R2 ∈ O(y)
⇒ ∃ a. R1 < ax ∧ ∃ b. R2 < by
⇒ ∃ a, b. R1 < ax ∧ R2 < by
⇒ ∃ a, b. R1+R2 < ax + by
⇒ ∃ a, b. c=max(a,b) ∧ R1+R2 < cx + cy
⇒ ∃ c. R1+R2 < c(x+y)
⇒ R1+R2 ∈ O(x+y)

share|improve this answer
This only shows O(x) + O(y) \subseteq O(x+y), but the other direction is shown analogously. Hence +1. – DaveFar Nov 1 '12 at 17:06
Thanks guys! Provided much need clarity! – Taylor Jones Nov 1 '12 at 20:13
  (N/2) + (N/2)
= 2*(N/2)
= 2N/2
= N
share|improve this answer
asymptotic math doesn't work quite like that. – Niet the Dark Absol Nov 1 '12 at 16:44
@Kolink Well almost (maybe not when proving, but when looking for an answer). – keyser Nov 1 '12 at 16:47
@Kolink O(N/2) with all standard algebra rules is perfectly valid asymptotic math. It just happens to be the same as O(N). – btilly Nov 1 '12 at 16:48
O(N) + O(N) is not O(2N). It is still O(N). – Sani Huttunen Nov 1 '12 at 16:56
@Sani: It is both, since O(2N) = O(N). Ignoring constant factors is the whole reason d'etre of big-O.... – DaveFar Nov 1 '12 at 17:08

The time complexity (and whether you need a recurrence relation) depends on what you do in the loops, i.e. what the complexity of

//The best code you've ever seen (*complexity1*)


 //Slightly less awesome code (*complexity2*)


If each iteration only requires a constant amount of time, i.e. complexity1 and complexity2 in O(1), then the total complexity will be n*O(1) = O(n). This shows what the Big-O-Notation really does: abstract away from constant factors such as complexity1 and complexity2.

If each iteration requires O(f(n)), then your total time complexity will be O(n*f(n)).

If each iteration makes a recursive call, i.e. calls dummy_algorithm with a smaller parameter, you do need a recurrence relation to compute the time complexity. How the recurrence relation looks like depends on how often you make recursive calls and with what parameter. shows you how to find and solve the appropriate recurrence relation.

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