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I have a question here the loop is:

for (i=0; i < n; ++i)
   for (j = 3; j < n; ++j)
           {
            ...
           }

I kind of understand how to calculate the big-oh but I am not entirely sure on how to do it. The outer loop executes n times and the inner loop executes i times for each value of i. The complexity is supposed to be N^2 (I think). Can you guys elaborate on how this is calculated? I understand some of it but not all of it.

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Are you sure you typed that out right? Did you mean "j = i"? Because this just executes n*(n-3) times. –  Adrian Petrescu Jun 20 '10 at 17:25
    
I think your code is wrong – or your question is: the inner loop is supposed to read for (j = 3; j < i; ++j), right? I.e. j < i, not j < n. –  Konrad Rudolph Jun 20 '10 at 17:25
    
One probable mistake and two different solutions... I am excited to see how it goes on ;) –  Felix Kling Jun 20 '10 at 17:26
    
@Felix Kling - even if it's j < i, the complexity is still O(n^2). –  IVlad Jun 20 '10 at 17:30
    
@IVlad: yup, but the current answers fail to explain why. Care to write a better one? –  Konrad Rudolph Jun 20 '10 at 17:41

6 Answers 6

It is (n*(n-3)) = n²-3n and for very big n it is close to . So for Big-Oh notation I would write O(n²) because the -3n can be ignored.


Just a correction to your test in the question: the outer loop executes n times, the inner (n-3) times for each iteration on the outer loop.

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Yes. You always discard terms that are smaller than the highest order term when expressing O() notion. –  Loren Pechtel Jun 20 '10 at 18:29

The complexity isn't necessarily O(n^2). It actually depends on what is going on in the "...". If the stuff in the inner loop has O(1) complexity, then yes, the overall complexity is O(n^2). The reason is because on any iteration of the outer loop you have n-3 iterations of the inner loop. Each iteration of the inner loop has 1 execution of the body, which we assume is O(1). So, you end up with n*(n-3) executions of the body. If we assume the body is O(1), then the complexity of the whole thing is O(n*(n-3)) = O(n^2).

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Remember what Crom said: it depends on what's in the ellipsis. I may be abusing the notation, but I think you could say that this is O(mn2), where m is a function that bounds the growth of whatever is in the ellipsis (it could be related to n, but we don't know that).

You didn't ask this part specifically, but make sure that you're clear on why n2 - 3n is O(n2). Look at the definition for big-O, which says that n2 - 3n ≤ cn2, where c is a constant of our choosing. When c = 2, we can rewrite as n2 - 3n ≤ n2 + n2, which is clearly true.

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In general, the construct of nested for loops is O(n^2), but there are some exceptions. In computer graphics, it is normal to see something like:

for (int x=0; x < width; x++) {
  for (int y=0; y < height; y++) {
    // Do something on a specific pixel in the image in constant time
  }
}

And see it called O(n) instead on O(n^2) because n is assumed to be the number of pixels in some contexts, instead of the linear size of the image. So, the "n^2" is already taken into account. There are probably other domain-specific contexts where the accepted definition of "n" may not be immediately obvious just from looking at the code.

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thanks for the replies, I can see now that the inner loop executes n-3 times due to j starting out as 3. The outer loop executes n times as usual. As for the people who were confused that I wrote the problem wrong, that is how the problem is given. I triple checked and its exactly how I wrote it. Thanks a lot for the help!

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Formally, you can use Sigma Notation to obtain the exact number of iterations, and consequently determine the order of growth.

enter image description here

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