# Is O(n Log n) in polynomial time?

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.

Thanks!

Yes, O(nlogn) is polynomial time.

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.

f is O(g) iff

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)

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

• 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.

• 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
• 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