what is the complexity of a loop which goes this

for (int i = 0; i < n; i++)
{
for (int j = 0; j < log(i); j++)
{
// do something
}
}


According to me the inner loop will be running log(1)+log(2)+log(3)+...+log(n) times so how do i calculate its complexity?

• "According to me" Always found this phrase amusing. We typically use "according to" to announce a third-party authority we used to arrive at a conclusion. You can't use yourself as a third-party authority. Aug 9, 2016 at 11:46
• @LightnessRacesinOrbit According to me you can. Aug 9, 2016 at 13:00

So, you have a sum log(1) + log(2) + log(3) + ... + log(n) = log(n!). By using Stirling's approximation and the fact that ln(x) = log(x) / log(e) one can get

log(n!) = log(e) * ln(n!) = log(e) (n ln(n) - n + O(ln(n)))


which gives the same complexity O(n ln(n)) as in the other answer (with slightly better understanding of the constants involved).

• Nice qualitative analysis -- \sum_{i=1}^{n} log(i) => log(n!) which allows us to use Stirling's approximation good catch! Aug 9, 2016 at 13:02

Without doing this in a formal manner, such complexity calculations can be "guessed" using integrals. The integrand is the complexity of do_something, which is assumed to be O(1), and combined with the interval of log N, this then becomes log N for the inner loop. Combined with the outer loop, the overall complexity is O(N log N). So between linear and quadratic.

Note: this assumes that "do something" is O(1) (in terms of N, it could be of a very high constant of course).

• Multiply that by the complexity of "do something". Aug 9, 2016 at 11:35
• How can the complexity be worse than that of a basic two-dimensional loop over n^2? How can it be worse than n*log n for that matter? Honestly asking - it's been a while since I've studied this formally. But "between quadratic and cubic" for this intuitively seems wrong to me? Aug 9, 2016 at 11:48
• @LightnessRacesinOrbit duh, you are right, I messed up, fixed now. Aug 9, 2016 at 11:55

Lets start with log(1)+log(2)+log(3)+...+log(n). Roughly half of the elements of this sum are greater than or equal to log(n/2) = log(n) - log(2). Hence the lower bound of this sum is n / 2 * (log(n) - log(2)) = Omega(nlog(n)). To get upper bound simply multiply n by the largest element which is log(n), hence O(nlog(n)).