# time complexity of the composite function in terms of n

Assuming n is a positive integer, the composite function performs as follows:

``````(define (composite? n)
(define (iter i)
(cond ((= i n) #f)
((= (remainder n i) 0) #t)
(else (iter (+ i 1)))))
(iter 2))
``````

It seems to me that the time complexity (with a tight bound) here is O(n) or rather big theta(n). I am just eyeballing it right now. Because we are adding 1 to the argument of iter every time we loop through, it seems to be O(n). Is there a better explanation?

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You got it. You increase by 1 each recursive call up to a maximum of `n`, and then stop. If you assume that the divide operation is constant-time, then you do O(1) work each loop for a total of O(n). It's only an upper bound though, because some inputs stop right away. If `= n 800`, for example, you stop on the first loop where `(remainder n i)` is 0. –  japreiss Feb 15 '12 at 1:50
Right, if `n` is prime, the recursion goes all the way to `n`, `n-1` steps. But if `n` is composite, it takes at most `sqrt(n)` steps. –  Daniel Fischer Feb 15 '12 at 1:56

The function as written is O(n). But if you change the test (= i n) to (< n (* i i)) the time complexity drops to O(sqrt(n)), which is a considerable improvement; if n is a million, the time complexity drops from a million to a thousand. That test works because if n = pq, one of p and q must be less than the square root of n while the other is greater than the square root of n; thus, if no factor is found less than the square root of n, n cannot be composite. Newacct's answer correctly suggests that the cost of the arithmetic matters if n is large, but the cost of the arithmetic is log log n, not log n as newacct suggests.

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