Here's a lazy oneliner, also using itertools:
def combinations(items):
return ( set(compress(items,mask)) for mask in product(*[[0,1]]*len(items)) )
# alternative: ...in product([0,1], repeat=len(items)) )
Main idea behind this answer: there are 2^N combinations  same as the number of binary strings of length N. For each binary string, you pick all elements corresponding to a "1".
items=abc * mask=###

V
000 >
001 > c
010 > b
011 > bc
100 > a
101 > a c
110 > ab
111 > abc
Things to consider:
 This requires that you can call
len(...)
on items
(workaround: if items
is something like an iterable like a generator, turn it into a list first with items=list(_itemsArg)
)
 This requires that the order of iteration on
items
is not random (workaround: don't be insane)
 This requires that the items are unique, or else
{2,2,1}
and {2,1,1}
will both collapse to {2,1}
(workaround: use collections.Counter
as a dropin replacement for set
; it's basically a multiset... though you may need to later use tuple(sorted(Counter(...).elements()))
if you need it to be hashable)
Demo
>>> list(combinations(range(4)))
[set(), {3}, {2}, {2, 3}, {1}, {1, 3}, {1, 2}, {1, 2, 3}, {0}, {0, 3}, {0, 2}, {0, 2, 3}, {0, 1}, {0, 1, 3}, {0, 1, 2}, {0, 1, 2, 3}]
>>> list(combinations('abcd'))
[set(), {'d'}, {'c'}, {'c', 'd'}, {'b'}, {'b', 'd'}, {'c', 'b'}, {'c', 'b', 'd'}, {'a'}, {'a', 'd'}, {'a', 'c'}, {'a', 'c', 'd'}, {'a', 'b'}, {'a', 'b', 'd'}, {'a', 'c', 'b'}, {'a', 'c', 'b', 'd'}]