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What is an example (in code) of a O(n!) function? It should take appropriate number of operations to run in reference to n; that is, I'm asking about time complexity.

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What should be O(n!)? The execution time? The memory consumption? The output of the program? – meriton Oct 17 '10 at 12:44
It may not be a well-phrased question, but it’s a real question and it’s related to programming. – Konrad Rudolph Oct 17 '10 at 12:46
@Peter: Actually it is used to measure memory consumption quite often. One quick example: – sepp2k Oct 17 '10 at 13:03
@sepp2k, thanks, good to know. Still, by default (i.e. without any clarifying note) I interpret it to refer to time complexity. – Péter Török Oct 17 '10 at 13:09
Just to be pedantic, you mean Ω(n!) [lower bound on asymptotic growth] or "time proportional to n!" [upper and lower], not O(n!) [upper bound on asymptotic growth]. Since O(n!) is only the upper bound, lots of algorithms are O(n!) in uninteresting way, because they're O(n) or O(n log n) or O(1) or something like that. – jacobm Oct 17 '10 at 14:16

13 Answers 13

up vote 37 down vote accepted

There you go. This is probably the most trivial example of a function that runs in O(n!) time (where n is the argument to the function):

void nFac(int n) {
  for(int i=0; i<n; i++) {
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Given that this is a one-for-one calculation of n!, this is the very definition of O(n!) order of growth. – Adam Robinson Oct 17 '10 at 12:51
isnt this O(N)? – Derek Long Oct 18 '10 at 3:40
On a second thought, will the recursive method nFac affect the time complexity of this algorithm? – Derek Long Oct 18 '10 at 3:54
@Derek: It's definitely O(n!) (and more importantly Θ(n!)). And yes, the time complexity of a function called in a loop affects the time complexity of the loop. If the loop is executed n times and the function in the loop executes (n-1)! steps, then a total of n * (n-1)! = n! steps will be performed. Which is exactly how you proof that this function's time complexity is in Θ(n!). – sepp2k Oct 18 '10 at 10:24
@Derek Long the loop is O(n), since it is called recursively with (n-1) you get n * (n-1)*(n-2)*...*1 = n! so the function is O(n!). – josefx Oct 18 '10 at 10:43

One classic example is the traveling salesman problem through brute-force search.

If there are N cities, the brute force method will try each and every permutation of these N cities to find which one is cheapest. Now the number of permutations with N cities is N! making it's complexity factorial (O(N!)).

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i need an example in codes? couldnt find in the net. – Derek Long Oct 17 '10 at 12:42
I didn't DV, but perhaps it's because it has no sample code, and the big-o notation is not provided... – aioobe Oct 17 '10 at 12:49
@aioobe: since the question is "What's an O(n!) problem" and the answer is "here's one", I wouldn't think you have to say O(n!) explicitly.. – Claudiu Oct 17 '10 at 14:22
Ah, yes. I didn't see that the OP asked for a specific complexity... I agree :) – aioobe Oct 17 '10 at 15:10
Imagine 3 cities. To check any potential route, you have to check the distance between two cities twice. A->B and B-> C. You have to start from all 3 corners. Sum the distance onto the first city, so in total that's 3 checks, then sum the distance from the 2nd city onto the 3rd for a total of 6 checks. that's 3! = 6. Do this for 4 cities and the checks become 24. – Eric Leschinski May 15 '12 at 15:49

See the Orders of common functions section of the Big O Wikipedia article.

According to the article, solving the traveling salesman problem via brute-force search and finding the determinant with expansion by minors are both O(n!).

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Finding the determinant with expansion by minors.

Very good explanation here.

# include <cppad/cppad.hpp>
# include <cppad/speed/det_by_minor.hpp>

bool det_by_minor()
{   bool ok = true;

    // dimension of the matrix
    size_t n = 3;

    // construct the determinat object
    CppAD::det_by_minor<double> Det(n);

    double  a[] = {
        1., 2., 3.,  // a[0] a[1] a[2]
        3., 2., 1.,  // a[3] a[4] a[5]
        2., 1., 2.   // a[6] a[7] a[8]
    CPPAD_TEST_VECTOR<double> A(9);
    size_t i;
    for(i = 0; i < 9; i++)
        A[i] = a[i];

    // evaluate the determinant
    double det = Det(A);

    double check;
    check = a[0]*(a[4]*a[8] - a[5]*a[7])
          - a[1]*(a[3]*a[8] - a[5]*a[6])
          + a[2]*(a[3]*a[7] - a[4]*a[6]);

    ok = det == check;

    return ok;

Code from here. You will also find the necessary .hpp files there.

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You should expand this answer, it's pretty obtuse right now – Daenyth Oct 17 '10 at 14:14
There you go. I've added some code. – Jungle Hunter Oct 17 '10 at 14:20

I think I'm a bit late, but I find snailsort to be the best example of O(n!) deterministic algorithm. It basically finds the next permutation of an array until it sorts it.

It looks like this:

template <class Iter> 
void snail_sort(Iter first, Iter last)
    while (next_permutation(first, last)) {}
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There are problems, that are NP-complete(verifiable in nondeterministic polynomial time). Meaning if input scales, then your computation needed to solve the problem increases more then a lot.

Some NP-hard problems are: Hamiltonian path problem( open img ), Travelling salesman problem( open img )
Some NP-complete problems are: Boolean satisfiability problem (Sat.)( open img ), N-puzzle( open img ), Knapsack problem( open img ), Subgraph isomorphism problem( open img ), Subset sum problem( open img ), Clique problem( open img ), Vertex cover problem( open img ), Independent set problem( open img ), Dominating set problem( open img ), Graph coloring problem( open img ),

Source: link 1, link 2

alt text
Source: link

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You should at least add a link to the Wikipedia article that you have copied. – Peter Lang Oct 17 '10 at 13:02
Theres no need to pollute the page with all those examples; or at least don't use the diagrams. – alternative Oct 17 '10 at 14:53
I like the examples here. SO should have a way to hide/expand certain parts of a post. – devoured elysium Oct 17 '10 at 14:59
Note to self: Personally you liked how examples had picture images, but after a while you found out, that lots of people does not. So after +10 down votes, You removed the images. (And added a comic to compensate mental loss). – Margus Oct 17 '10 at 20:24
NP stands for Nondeterministic Polynomial, meaning faster than exponential time (but only in theory). Factorial is slower than exponential, in theory and practice. So, this is totally irrelevant. – Potatoswatter Oct 18 '10 at 6:39

the simplest example :)


input N
calculate N! and store the value in a vaiable NFac - this operation is o(N)
loop from 1 to NFac and output the letter 'z' - this is O(N!)

there you go :)

As a real example - what about generating all the permutations of a set of items?

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In Wikipedia

Solving the traveling salesman problem via brute-force search; finding the determinant with expansion by minors.

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printf("Hello World");

Yes, this is O(n!). If you think it is not, I suggest you read the definition of BigOh.

I only added this answer because of the annoying habit people have to always use BigOh irrespective of what they actually mean.

For instance, I am pretty sure the question intended to ask Theta(n!), at least cn! steps and no more than Cn! steps for some constants c, C > 0, but chose to use O(n!) instead.

Another instance: Quicksort is O(n^2) in the worst case, while technically correct (Even heapsort is O(n^2) in the worst case!), what they actually mean is Quicksort is Omega(n^2) in the worst case.

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Any algorithm that calculates all permutation of a given array is O(N!).

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In C#

Wouldn't this be O(N!) in space complexity? because, string in C# is immutable.

string reverseString(string orgString) {
    string reversedString = String.Empty;

    for (int i = 0; i < orgString.Length; i++) {
        reversedString += orgString[i];

    return reversedString;
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Bogosort is the only "official" one I've encountered that ventures into the O(n!) area. But it's not a guaranteed O(n!) as it's random in nature.

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-1. Bogosort isn't O(n!) but even slower. – progo Feb 9 '11 at 12:01

The recursive method you probably learned for taking the determinant of a matrix (if you took linear algebra) takes O(n!) time. Though I dont particularly feel like coding that all up.

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