# number of all subsets of a set

This is what I came up with to calculate all subsets of length 0, 1, ... , n of a set of length n with doubling single elements. Difficult to describe...

def subsets(seq, *args):

seqstart = [[seq[i] for i in args], ]

if len(args) == 0:
for i in range(len(seq)):
seqstart += subsets(seq, i)
elif len(args) < len(seq):
for i in range(args[-1], len(seq)):
seqstart += subsets(seq, *args + (i, ))

return seqstart


Examples:

>>> subsets(['x', 'y'])
[[], ['x'], ['x', 'x'], ['x', 'y'], ['y'], ['y', 'y']]

>>> subsets(['x', 'y', 'z'])
[[], ['x'], ['x', 'x'], ['x', 'x', 'x'], ['x', 'x', 'y'], ['x', 'x', 'z'], ['x', 'y'], ['x', 'y', 'y'], ['x', 'y', 'z'], ['x', 'z'], ['x', 'z', 'z'], ['y'], ['y', 'y'], ['y', 'y', 'y'], ['y', 'y', 'z'], ['y', 'z'], ['y', 'z', 'z'], ['z'], ['z', 'z'], ['z', 'z', 'z']]


What is the length of subsets(sequence) dependent on the length of the sequence? (I killed the process after 50 hours with n=14)

Thank You

Michael

edit: Thank you all. So it is the Binomial Coefficient of 2n over n.

To obtain all subsets instead of multisets (so a total length of 2^n) I needed to replace

for i in range(args[-1], len(seq)):

with

for i in range(args[-1] + 1, len(seq)):

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These aren't really subsets. I guess I would describe them as sorted strings over an alphabet Σ of length at most |Σ|. – user635541 Mar 7 '11 at 13:11
Try this one on cstheory.stackexchange.com - they specialize in this kind of thing. – Björn Pollex Mar 7 '11 at 13:15
No, don't; it's an elementary combinatorics problem. – user635541 Mar 7 '11 at 13:16
@user: And why does that not ft on cstheory? – Björn Pollex Mar 7 '11 at 13:19
Read their FAQ. – user635541 Mar 7 '11 at 13:19

The number of multisets of size up to n of a set of size n is equal to the binomial coefficient

/ 2n \
|    |
\ n  /


This follows by summing up the number of combinations with repetition for k from 0 to n.

For n=14, this yields 40116600 multisets.

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I'm not sure, but maxima evaluates sum(binomial(n+i-1,n-1), i, 0, n) to binomial(2 n, n) - 1. Where does this -1 come from? – phimuemue Mar 7 '11 at 14:19
@phimuemue: Maybe a bug in maxima? Just compare binomial(1, 1) + binomial(2, 1) + binomial(3, 1) to binomial(4, 2) to see that at least in this special case my summation is right and maxima's summation is wrong. Or do the summation yourself (use something like Vandermonde's identity, should be on Wilipedia). – Sven Marnach Mar 7 '11 at 14:58

For a given set A with N number of elements, the number of subsets is equal to 2^N

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That's the number of subsets, not the number of multisubsets. – Sven Marnach Mar 7 '11 at 13:14
@Sven Marnach: True, however the question was formulated about subsets not multisubsets so I did not account for duplicate elements. – Jean-Louis Mbaka Mar 7 '11 at 13:23
The question used the word "subset" incorrectly, but it includes code and examples, so there is no room for doubt. – Sven Marnach Mar 7 '11 at 13:28

A number of (normal) subsets of a set is 2^N

A number of subsets of length K, with duplication, is N^K. Think of your elements like digits of some number system. If N is 10 then your elements are simply digits 0..9.

If you want the size of subset-with-duplication to be any from 1 to N, then there will be N^1+N^2+N^3+...+N^N sets.

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Note that n^1 + n^2 + ... n^n = (n^(n+1)-1)/(n-1) (geometric series), but this solution counts e.g. x,x,y and y,x,x and x,y,x as three elements, while the questioner interprets these three as one! – phimuemue Mar 7 '11 at 14:05
Oups, indeed. I have missed that. – CygnusX1 Mar 7 '11 at 14:20