Is O(n Log n) in polynomial time? If so, could you explain why?

I am interested in a mathematical proof, but I would be grateful for any strong intuition as well.



Yes, O(nlogn) is polynomial time.

From http://mathworld.wolfram.com/PolynomialTime.html:

An algorithm is said to be solvable in polynomial time if the number of steps required to complete the algorithm for a given input is O(n^m) for some nonnegative integer m, where n is the complexity of the input.

From http://en.wikipedia.org/wiki/Big_O_notation:

f is O(g) iff

enter image description here

I will now prove that n log n is O(n^m) for some m which means that n log n is polynomial time.

Indeed, take m=2. (this means I will prove that n log n is O(n^2))

For the proof, take k=2. (This could be smaller, but it doesn't have to.) There exists an n_0 such that for all larger n the following holds.

n_0 * f(n) <= g(n) * k

Take n_0 = 1 (this is sufficient) It is now easy to see that

n log n <= 2n*n

log n <= 2n

n > 0 (assumption)

Click here if you're not sure about this.

This proof could be a lot nicer in latex math mode, but I don't think stackoverflow supports that.

  • 1
    How about proving that log n <= 2n? :) – Inspired May 18 '14 at 13:55
  • 1. That n_0 shouldn't be there. 2. To prove that logn < 2n, I'll just prove that logn < n < 2n. This becomes h(n) = log(n)/n < 1. This is true for n = n0 = 1 (0<1) and you can focus on showing that h(n) is a monotonically decreasing function. – ROMANIA_engineer Jan 27 '16 at 20:07

It is, because it is upper-bounded by a polynomial (n). You could take a look at the graphs and go from there, but I can't formulate a mathematical proof other than that :P

EDIT: From the wikipedia page, "An algorithm is said to be of polynomial time if its running time is upper bounded by a polynomial expression in the size of the input for the algorithm".


It is at least not worse than polynomial time. And still not better: n < n log n < n*n.

  • 1
  • Could you elaborate what exactly is wrong here? (Also note that in computer science Big-O is often used in a sense of Big-Theta.) – Inspired May 18 '14 at 12:17
  • O(n^2) is still polynomial time. The fact that n < n log n < n*n holds for large n is indeed true. n log n is not linear time, but dat does not mean that n lon n is not polynomial time. I will consider adding a mathematical proof to my answer. – Syd Kerckhove May 18 '14 at 12:42
  • I have now added a mathematical proof :D – Syd Kerckhove May 18 '14 at 12:58
  • Thank you for the comments, I am always eager to improve my understanding and my answers. However, I believe I have never said that O(n^2) is not polynomial, or that O(n log n) is not. – Inspired May 18 '14 at 13:42

Yes. What's the limit of nlogn as n goes to infinity? Intuitively, for large n, n >> logn and you can consider the product dominated by n and so nlogn ~ n, which is clearly polynomial time. A more rigorous proof is by using the the Sandwich theorem which Inspired did:

n^1 < nlogn < n^2.

Hence nlogn is bounded above (and below) by a sequence which is polynomial time.

  • I didn't say it was 1, if we're being pedantic we could say that n dominates the limit of nlogn as n goes to infinity. Strictly speaking, a sequence which tends to infinity diverges. And if you have two functions f(n)*g(n) then the limit if the product is lim f(n) * lim g(n), which in this case is infinity*infinity, which is undefined. – user1654183 Nov 10 '13 at 2:00
  • "the limit of nlogn as n goes to infinity" is "n which is n^1". Could you explain that statement a little further then? – Teepeemm Nov 10 '13 at 2:09
  • I did already. To repeat: as n goes to infinity, n >> logn. Hence, you can basically ignore the contribution of logn to nlogn as n goes to infinity, leaving you with just n. This is not "rigorous", but the guy asked for intuition... – user1654183 Nov 10 '13 at 13:07
  • 1
    But you're essentially saying that "log(n)=o(n), so log(n)=O(1)". I agree that ignoring the logarithm is a good way to intuitively start seeing how nlog(n) grows, but we can't ignore it completely. To make my point a different way: if we change log to sqrt, you still have n>>sqrt(n), but n^1.5 does not grow like n. – Teepeemm Nov 11 '13 at 14:38

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