For the algorithm below:

 int x = 0;
 for (int i = 0; i < n; i++)
     for (j = 0; j < n; j++) {
         if (j < i) j = j + n;
         else x = x + 1;

So for this algorithm, my thought process goes like this:

The inner-loop performs n iterations for j when i=0. However, for every value of i=0,1..n-1, j will only perform one iteration because the if-statement will evaluate to true and end the inner-loop.

Here is my source of confusion:

Since the outer-loop will perform n iterations no matter what, and since the inner loop performs n iterations when i=0 (very first iteration), how come the big-Oh time complexity isn't O(n²) and is instead, O(n) if the loops are nested and both perform n iterations in the very first iteration?

  • Your question title however conflicts with your question "body". It is indeed O(n), here. An algorithm that is O(n) is however O(n^2) as well. – Willem Van Onsem Jul 28 at 17:49
  • This does not seem like a particularly useful algorithm. And if x is never accessed outside the loop, the compiler might eliminate the loops altogether. Everyone loves a O(1) algorithm. – Elliott Frisch Jul 28 at 17:50
  • topicstarter is correct, it's linear - inner loop runs n times when i=0, then outer loop runs n-1 times without inner loop involved – mangusta Jul 28 at 17:51
  • @mangusta that is an interesting way of looking at it, I never thought it through like that. So since they run to O(n) independently, it is simply just O(n) regardless of the first iteration? – CosmicCat Jul 28 at 17:53
  • @CosmicCat since they run to O(n) independently, it is simply just O(n) regardless Yes. In Big-O notation you drop constant factors. The code is O(2n), which is simplified in Big-O notation to O(n). But, as I mentioned, compilers (or the JIT) can detect when loops are functionally dead code. – Elliott Frisch Jul 28 at 17:55

You have a line that says if (j < i) j = j + n; which essentially breaks out of the loop (when j < i), and since the inner loop starts at 0, this will trigger on the first iteration every time (except the first time), making it run in constant time.

You essentially only have one loop here. The code can be rewritten as

int x = 0;
for (int i = 0; i < n; i++) {
    x = x + 1;

which makes it clear why it is O(n).


You could just print the values of i and j from the inner loop:

for (int i = 0; i < n; i++) {
    for (int j = 0; j < n; j++) {
        System.out.print(i + "" + j + " ");
        if (j < i) j = j + n;
        else x = x + 1;


00 01 02 03 04 ..

Which represents only the first row and the first column of the matrix, thus the complexity is:

O(2n) => O(n).

You properly notice that only for i=0 inner loop will iterate n times. For i>0 inner loop runs once only. We can sum all these iterations: i0+i1+...+n-1, where i0=n, and for other indexes ix=1. So, sum of inner iterations will be n + n - 1 => 2n - 1. Which gives us: O(2n - 1) => O(2n) - O(1) => 2*O(n) - O(1) => O(n).


For every n outer iteration, there are n inner iterations. So you will do n*n=n^2 computations and hence the complexity is O(n^2). Does this make sense or it is more confusing?

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