Interview questions where I start with "this might be solved by generating all possible combinations for the array elements" are usually meant to let me find something better.

Anyway I would like to add "I would definitely prefer another solution since this is O(X)".. the question is: what is the O(X) complexity of generating all combinations for a given set?

I know that there are n! / (n-k)!k! combinations (binomial coefficients), but how to get the big-O notation from that?

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    Are you referring to k as constant? Is O(k!) is O(1) ? If so, complexity is O(n^min{k,n-k}). Otherwise - not sure you simplify it much. – amit Jun 29 '15 at 16:16
  • yes, given k as a constant. – Albert Jun 29 '15 at 16:24
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    @amit If k is a constant, the complexity will be O(n^k), since k < n-k for a sufficiently large n – SomeWittyUsername Dec 3 '16 at 6:15

First, there is nothing wrong with using O(n! / (n-k)!k!) - or any other function f(n) as O(f(n)), but I believe you are looking for a simpler solution that still holds the same set.

If you are willing to look at the size of the subset k as constant,

for k<=n-k:

n! / ((n-k)!k!) = ((n-k+1) (n-k+2) (n-k+3) ... n ) / k! 

But the above is actually (n^k + O(n^(k-1))) / k!, which is in O(n^k)

Similarly, if n-k<k, you get O(n^(n-k))

Which gives us O(n^min{k,n-k})


As a follow up to @amit, an upper-bound of min{k,n-k} is n/2.

Therefore, the upper-bound for "n choose k" complexity is O(n^(n/2))


case1: if n-k < k

Let suppose n=11 and k=8 and n-k=3 then

 n!/(n-k)!k! = 11!/(3!8!)= 11x10x9/3!
 let suppose it is (11x11x11)/6 = O(11^3) and 11 was equal to n so O(n^3) and also n-k=3 so it become O(n^(n-k))

case2: if k < n-k

Let suppose n=11 and k=3 and n-k=8 then

 n!/(n-k)!k! = 11!/(8!3!)= 11x10x9/3!
 let suppose it is (11x11x11)/6 = O(11^3) and 11 was equal to n so O(n^3) and also k=3 so it become O(n^(k))

Which gives us O(n^min{k,n-k})

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