# complexity of recursive string permutation function

what is the complexity of this function???

``````void permute(string elems, int mid, int end)
{
static int count;
if (mid == end) {
cout << ++count << " : " << elems << endl;
return ;
}
else {
for (int i = mid; i <= end; i++) {
swap(elems, mid, i);
permute(elems, mid + 1, end);
swap(elems, mid, i);
}
}
}
``````

Ignoring the print, the recurrence relation satisfied is

`T(n) = n*T(n-1) + O(n)`

If `G(n) = T(n)/n!` we get

`G(n) = G(n-1) + O(1/(n-1)!)`

which gives `G(n) = Theta(1)`.

Thus `T(n) = Theta(n!)`.

Assuming that the print happens exactly `n!` times, we get the time complexity as

`Theta(n * n!)`

• @rajyavardhan: Why is there an `O(n)` factor in the initial recurrence? – crisron Mar 21 '16 at 19:12
• Because of the swap operations - each operation takes O(1) and that happens in a loop. – Parth Thakkar Nov 23 '16 at 16:26

Without looking too deeply at your code, I think I can say with reasonable confidence that its complexity is O(n!). This is because any efficient procedure to enumerate all permutations of n distinct elements will have to iterate over each permutation. There are n! permutations, so the algorithm has to be at least O(n!).

Edit:

This is actually O(n*n!). Thanks to @templatetypedef for pointing this out.

• I think you're forgetting the O(n!) times you're printing O(n) characters, which takes O(n x n!) time. – templatetypedef Mar 19 '11 at 19:58
• @templatetypedef: nn!<(n+1)*n!, i.e. nn!<(n+1)!. O((n+1)!) is the same as O(n!), the extra n does not matter. – MAK Mar 19 '11 at 20:31
• @MAK- O(n!) != O((n+1)!). It's true that anything that's O(n!) is also O((n+1)!), but the opposite doesn't hold. A quick proof - (n+1)! = O((n+1)!) trivially. Now suppose that (n+1)! = O(n!); then there must be some c, n0 such that for any n > n0, (n+1)! < c n!. This would mean that for any n > n0, n < c, which is impossible for any constant c. – templatetypedef Mar 19 '11 at 20:35
• @templatetypedef: Thanks. I have corrected my post. – MAK Mar 20 '11 at 6:08
``````long long O(int n)
{
if (n == 0)
return 1;
else
return 2 + n * O(n-1);
}

int main()
{
//do something
O(end - mid);
}
``````

This will calculate complexity of the algorithm.

Actualy O(N) is `N!!! = 1 * 3 * 6 * ... * 3N`