int y = 1;
for (int x = 1 ; x <= n+2 ; x++)
  for (int w = n ; w > 0 ; w--)
    y = y + 1;

I'm a little confused about determining the BigO of the above code. If in the outermost loop it was for(int x = 1; x <= n; w++), then the BigO of the loop would be O(n^2) because the outermost loop would iterate n times and the innermost loop would also iterate n times.

However, given that the outermost loop iterates n+2 times, would that change the bigO or does the rule that additive constants don't matter imply? Lastly, would it change anything if the innermost loop were to iterate n+2 times instead of n?

Thank you!

  • As n goes to infinity, a +2 swiftly becomes irrelevant. You're taking the limit of (n+2)*(n), which equals n^2 + 2n, as n goes to infinity. – F. Stephen Q Oct 7 '15 at 17:00

Outer loop run n + 2 times, and inner loop runs n times, so code block runs (n + 2) * n times, which is n * n + 2 * n times. With increasing values of n, the 2 * n becomes insignificant, so you're left with n * n, giving you the answer: O(n^2)


Long-ish answer short, the additive constants don't matter.

Suppose we did count the constants. Then, the inner loop is executed

(n+2)(n) = n^2 + 2n

times. This is still O(n^2), since the squared term takes precedence over the linear term.


n and n+2 are the same order of magnitude, so this code run in O(n^2). Even if the inner loop runs n + 2 times.

for (int x = 1 ; x <= n+2 ; x++)

outer loop is (n+2) times.

  for (int w = n ; w > 0 ; w--)

inner loop is (n) time

((n+2) * n) => n^2 + 2n => O(n^2). Because we consider the larger value.

The reason is for the larger values of n, value of 2n will be insignificant to n^2. So we drop the n.

You can read here for more explanation: Big O Analysis

  • Does the 2 in (n+2) drop then during the multiplication of ((n+2)*n)) because of the additive constants don't matter rule? – Mike Neal Oct 7 '15 at 17:01
  • @MikeNeal it drop because it is smaller than the n^2. Only consider what is the maximum. – YoungHobbit Oct 7 '15 at 17:02
  • @MikeNeal when you consider the larger values then 2n will be way smaller then n^2. so it does not affect much of the complexity. – YoungHobbit Oct 7 '15 at 17:06

Your Answer

By clicking “Post Your Answer”, you agree to our terms of service, privacy policy and cookie policy

Not the answer you're looking for? Browse other questions tagged or ask your own question.