Are there any real O(n^n) algorithms?

Is there any real Algorithm with a time complexity O(n^n), that isn't just a gimmick?

I can create such an Algorithm, like computing n^n in O(n^n) / Θ(n^n):

``````long n_to_the_power_of_m(int n, int m) {
if(m == 0) return 1;
long sum = 0;
for(int i = 0; i < n; ++i)
sum += n_to_the_power_of_m(n, m-1);
return sum;
}
``````

(needs more than 4 minutes to compute 10^10)

Or other way around: Are there any Problems, which cannot be solved better than in O(n^n)?

-
Does generating the cartesian product of `{1, 2, ..., n}` with itself `n` times count? –  IVlad May 27 '11 at 18:27
Enumerating all values of a base-n number with n digits! –  dfb May 27 '11 at 18:28
–  dfb May 27 '11 at 18:39

What you have coded in your example is very similar to a depth first search. So, that's one answer.

A depth first search algorithm without any special characteristics ( like re-convergent paths that can be optimized out ), should be n^n.

This is actually not a contrived example. Chess programs operate on the same algorithm. Each move there are n moves to consider ( i.e. branches ), and you search d moves deep. So that becomes O(n^d)

-
Ah, but OP asked about problems which cannot be solved in better than O(n^n). An O(n^n) algorithm for a problem doesn't demonstrate that the problem can't be solved by a more efficient algorithm. –  Ted Hopp May 29 '11 at 1:28
@Ted: No more efficient algorithm has been found for solving chess so far. There are optimizations - like alpha-beta pruning - but that doesn't change the fundamental characteristic of chess solving algorithm being O(n^d). –  Himadri Choudhury May 29 '11 at 11:13
I totally agree that there are O(n^n) problems. I was just making the point that proving that a problem is O(n^n) involves more than showing that there's an O(n^n) algorithm that solves it. Chess is a good example of this because it is a finite game (there are a finite number of board positions). Theoretically, then it has O(1) complexity. But all known (practical) algorithms are very inefficient. –  Ted Hopp May 29 '11 at 14:22
@Ted: Ok fair point. Though the OP did ask the question in 2 ways ( your interpretation being the second ). The first way he/she was asking whether there any algorithm that was O(n^n) that is not a gimmick. –  Himadri Choudhury May 29 '11 at 16:02
Thank you, I guess your example with Chess is the most realistic one, even though there are better Algorithms to play Chess. And DFS based Algorithms are afaik not uncommon. –  Floern May 30 '11 at 19:55

There are computations (for instance, tetration) where the output size is O(nn). It's kind of hard to compute them with time complexity less than O(nn).

-

There are many optimization problems that are essentially O(n!), i.e in data compression. The common algorithms for this all need to cheat one way or another (many rely on heuristics) but can't make sure that they have found the perfect result this way. I.e. choosing the optimal line filters during compression of a PNG image is such a problem that is comparatively easy to understand.

Another example are algorithms to break encryption which can potentially be even worse than O(n!).

-
My knowledge of crypto is really small, but isn't the dumbest form of encryption breakage enumerating all possible keys? How is this worse than n! ? –  dfb May 27 '11 at 18:45
I thought it was usually the latter. If n were representing the number of keys, it would be O(n) :) –  dfb May 27 '11 at 18:50
It depends on what your n is. The number of keys or the length of the message? The worst case for breaking an encryption is O(n*m) with n and m for keys and message length. –  x4u May 27 '11 at 18:52

According to Wikipedia, there are some double exponential time problems O(22poly(n)) which is more complex than O(nn), e.g. "Decision procedures for Presburger arithmetic" (O(22cn)) and "Computing a Gröbner basis" (in worst case O(22n/10)

-
quantifier elimination is another such example (being actually Omega(2^2^n) !). There are some problems which would greatly benefit from a fast quantifier elimination algorithm. –  Alexandre C. May 29 '11 at 10:14