# Order of growth for Permutation

This is a simple program which finds all the permutations of a given string :

``````void perm( char str[], int len )
{
if ( len == 1 )
cout << str << endl ;
else
for ( int i=0; i<len; i++ ) {
swap( str[len-1], str[i] ) ;
perm( str, len-1 ) ;
swap( str[len-1], str[i] ) ;
}
}
``````

What is the T(n) for this function ? How to calculate the Big Oh ( or Theta ) for this function ?

-
What does n count here? Does it count how often perm is called or how many bytes are moved or printed? –  Nobody Aug 28 '12 at 18:44
n is the length of our input. In here, length of the string. –  Rsh Aug 28 '12 at 18:50

Let the length of the initial input string be N.

Let the time taken for a call of perm(str (size = N), len=i) be T(i)

``````T(1) = N
``````

and

``````T(i > 1) = iT(i-1) + i
``````

then the total time taken is T(N),

To calculate the closed form of this recurrence see here:

http://math.stackexchange.com/questions/188119/closed-form-for-t1-k-tx-xtx-1-x

``````T(N) is approximately (N + e - 1)N!
``````

So as N approaches infinity the performance of the function is:

``````O((N + e - 1)N!) = O(N(N!))
``````
-
Thanks, but I've read some where that it claims it's O( n*n! ) and I'm kinda confused with the n. Do you have any explanation ? –  Rsh Aug 28 '12 at 19:41
Thanks, I'll change the code in the question so it becomes more clear. –  Rsh Aug 28 '12 at 19:46
I am sorry but how is T(1) = n... you aren't doing n couts, only 1. T(1) is obviously 1, the recurrence is more complicated than this –  yngum Aug 28 '12 at 20:33
@yngum: I thought you were right briefly but then I realized at len==1 the str argument is still n bytes long (to its terminating null) - so I think I'm right again. –  Andrew Tomazos Aug 28 '12 at 20:45
@ArashThr: So the reason that T(1) = N, is because for a call of perm(str(size = N), 1), the function must take time proportional to N to output the string (the cout) - so the answer is O(N(N!)). If T(1) were 1 and not N (for example it only printed the first character of the string), than the overall complexity would be O(N!). –  Andrew Tomazos Aug 29 '12 at 18:33

For loop perform n recursion, to n*T(n-1), plus O(n) since you also need to swap 2n times, so

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

n = 5 for sake of my keyboard

T(n) = n*T(n-1) + n
T(n) = n*[(n-1)*T(n-2) + (n-1)] + n
T(n) = n*[(n-1)*[(n-2)*T(n-3) + (n-2)] + (n+1)] + n
T(n) = n*[(n-1)*[(n-2)*[(n-3)*T(n-4) + (n-3)] + (n-2)] + (n-1)] + n
T(n-4) = 1 ----------------------^
Simplify
T(n) = n*[(n-1)*[(n-2)*[(n-3) + (n-3)] + (n-2)] + (n-1)] + n
T(n) = n*[(n-1)*[(n-2)*[2(n-3)] + (n-2)] + (n-1)] + n
T(n) = n(n-1)(n-2)*(n-3)*2 + (n-1)(n-2) + n(n-1) + n
T(n) = n! + O(n*n!)    <--  wrong, see comment for right answer
T(n) = O(n*n!)    <--  wrong, see comment for right answer
``````

you see the pattern

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You are using `T(1) = 1` yet you came out with `n*n!`. I think this is incorrect, `T(1) = 1` and `T(x) = xT(x) + x` should be approx `T(y) = (e)y!`. See math.stackexchange.com/questions/188119/… You have made two mistakes that have combined to give the right answer, but the working is wrong. –  Andrew Tomazos Aug 28 '12 at 22:29
well, O(n!) if print function is complexity of 1. surprising –  yngum Aug 28 '12 at 22:35
@ArashThr: This answer is wrong. `(n-1)(n-2) + n(n-1) + n` is not equal to `O(n*n!)`. I realize it has become a bit confusing. My answer is the correct one. –  Andrew Tomazos Aug 29 '12 at 18:20
One should note that `O(N!) = O(N^N)` –  Nobody Aug 28 '12 at 18:41