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I have the below code which I am using for one of my application. I want to calculate the time complexity of this code.

      for (int i = 0; i < n-1; i++)
        {
            for (int j   = 0; j < n-i-1; j++)
            {
                //TODO
            }
        }

I have tried calculating it below way:

: (n-1)(n-I-1)
: (n)(n-I-1) - (n-I-1)
: n^2-ni-n-n+i+1
: n^2-ni-2n+i+1

I don't know how to conclude this . Though I see highest value of n is o(n^2). Can anyone suggest what is the next step in determining the time complexity..

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2 Answers 2

up vote 0 down vote accepted

This code fragment is identical to this:

for m in n-1..0
    for j in 0..m
      i = n-1-m
      ...

which is the "classic" O(N^2), except the outer loop goes from high to low rather than from low to high.

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Thanks for reply.But,I want to know how does it evaluated to O(N^2) ? –  krrishna Jul 14 '13 at 13:39
    
@krrishna In the same way that for i in 0..n for j in 0..i ... does - as a sum of arithmetic sequence with the step of 1 (i.e. n(n-1)/2). –  dasblinkenlight Jul 14 '13 at 13:41
1  
@dasblinkenlight: I think he is looking for why it is O(N^2)? –  Aravind Jul 14 '13 at 14:28
    
@Aravind But that's discussed in so many places, starting with wikipedia article on arithmetic sequences, that I didn't want to repeat this discussion again. –  dasblinkenlight Jul 14 '13 at 15:23
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You are almost there. The next step is to drop the lower order terms from the polynomial: -ni-2n+i+1 and you are left with n^2.

In general you would also drop any multiplicative constants attached to n^2. I. e. drop the 5 in 5*n^2 to get n^2

This follows from the definition of big-Oh which cares about whether one function dominates another as the input increases in size. As the input increases in size, the only term that matters is n^2. The lower order terms will not allow this function to dominate another function, and neither will any constants. So you just drop them.

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