# Is my function O(n!), or is O((n-1)!) more accurate?

I've written a brute force search algorithm for the travelling salesman problem, and tested it to see the time it takes for various numbers of 'cities'. From the graph below, we can see that the time is roughly proportional to `(n-1)!` where `n` is the number of 'cities'. It is not directly proportional to `n!` (after all, `(n-1)! = n! / n`).

My question is, is it still correct to say that the algorithm runs in `O(n!)`, or is it better for me to say `O((n-1)!)`? I've never seen the latter before, but it seems more accurate. It seems that I've misunderstood something here. [t = time taken, n = number of cities]

• Possible duplicate of Which Big-O grows faster asymptotically – Idos Sep 5 '16 at 13:28
• The Big-O notation is not meant to actually provide a calculation of an algorithm, but rather to provide an abstract means of comparison between them. The end-behavior of your algorithm is a factorial - the fact that it happens to be +1 or -1 is immaterial. – iAdjunct Sep 6 '16 at 4:02

## 4 Answers

By definition, O(f(n)) is the set of all functions that are asymptotically dominated by f(n), i.e. the set of all functions g(n) for which there are constants C and n_0 such that

``````g(n) < C * f(n)   for all n > n_0
``````

From this definition, it follows that O(n!) is actually a superset of O((n-1)!), since the function f(n) = n! is a member of the first set, but not of the second set. The two sets aren't actually the same.

It is correct, though, to say that your problem is O(n!), since this only states an upper boundary. It would not be correct to say that your problem is ϴ(n!), since this denotes the exact asymptotic behaviour up to constant factors.

There is no big difference in practice, and, as noted in another answer, you can redefine n to mean the number of cities minus one.

• This answer uses the correct approach. Indeed, often one has `O(f(n)) = O(f(n-1))` -- this is true if `f` is a polynomial or an exponential, for instance. However, as pointed above, this is not true for all functions: we have `lim n!/(n-1)! = lim n = infty` for `n -> infty`. – chi Sep 5 '16 at 12:08
• Right. I wouldn't quite agree with “there's no big difference in practice” between `f(n)` and `f(n-1)` – not when the function grows as fast as the factorial! IOW, one can say any Θ (n!) algorithm is only usable for really small inputs; you never get a chance to make `n` so big that one more or less would be insignificant. – leftaroundabout Sep 5 '16 at 12:13
• "you can redefine n to mean the number of cities minus one." Which is a bad idea as this would lead to confusion. Why not defining it as sqrt(|cities|)? – FooBar Sep 5 '16 at 16:25

`O(n!)` is good enough. `n` or `n-1` makes no difference for large `n`.

• Say, a large value is `n=100`, then `O(n!)=9.33*10^157` , where `O((n-1)!)=9.33*10^155`. Do you think there is no difference between this two?? :) – jbsu32 Sep 5 '16 at 10:41
• Both of them are 'big like hell and non usable for large n anyway'. So, no difference indeed :) Both numbers are bigger than estimated number of atoms in the universe (which is mere 10^81).. – Bartosz Bilicki Sep 5 '16 at 10:44
• @jbsu32, that is just nonsense. `O(...)` is a class of functions and can't be equal to a number. And yes, `O(10n) = O(n)`, so there is no difference between `39.9 million` and `3.6 million` for `O`-notation. – deniss Sep 5 '16 at 10:57
• @jbsu32, `O(f(n))` is a class of functions, like even or differentiable functions. What exactly belongs to this class explained by Sven (or in a math book). And if we treat class as a set of all functions belonging to this class (common conception), then yes, `O(10n) = O(n) = O(10^100n)` as their elements are the same. – deniss Sep 5 '16 at 11:14
• @jbsu32, O(10n) is always equal to O(n), because we don't care about constant factor – Adam Stawicki Sep 5 '16 at 11:18

You could simply prove as:

O((n-1)!) means there is constant c such as:

algorithm steps(or else time complexity) < c (n-1)! < c n!/n < c n! for every n>1 .

So since your for algorithm complexity function holds: algorithm steps(or else time complexity)

your algorithm is also O(n!).

So we proved that if the time complexity of your algorithm is O((n-1)!) then it is also O(n!).

Sven Marnach's answer is a really good one, I just want to elaborate a bit on this part:

or is it better for me to say O((n-1)!)?

As others have said, `O(n)` is usually good enough. If you do want to find out more about the problem, you can try to find and prove:

• A lower bound (usually denoted by `Ω(n)`)
• A tight upper bound

A lower bound basically says that, under certain asymptions, there can be no algorithm solving the problem asymptotically faster. A tight upper bound is an upper bound that matches a lower bound, i.e., you'd have to prove a lower bound of `Ω(f(n))` and an upper bound of `O(f(n))`. If you can prove a lower bound and a tight upper bound, it means that your algorithm is an asymptotically optimal algorithm for the problem.

To give a concrete example for this: You surely know sorting algorithms like merge sort or quick sort and their upper bound of `O(n log n))`. Donald Knuth showed (decades ago) that comparison based sorting algorithms for integers require at least `n log n` comparisons, that is, `Ω(n log n)` operations. Since we have a matching upper bound, both merge sort and quick sort are said to be asymptotically optimal (although their performance differs a lot in practice).