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I have a list with 15 numbers in, and I need to write some code that produces all 32,768 combinations of those numbers.

I've found some code (by googling) that apparently does what I'm looking for, but I found the code fairly opaque and am wary of using it. Plus I have a feeling there must be a more elegant solution.

The only thing that occurs to me would be to just loop through the decimal integers 1-32768 and convert those to binary, and use the binary representation as a filter to pick out the appropriate numbers.

Does anyone know of a better way? Using map(), maybe?

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Just curious, @Ben. Why is the current accepted answer the accepted answer? I understand the OP can decide which answer to accept, but I feel Dan's answer is way more complete and it should be the accepted one. –  Amal Murali Sep 14 '14 at 9:14

7 Answers 7

up vote 91 down vote accepted

Have a look at itertools.combinations:

itertools.combinations(iterable, r)

Return r length subsequences of elements from the input iterable.

Combinations are emitted in lexicographic sort order. So, if the input iterable is sorted, the combination tuples will be produced in sorted order.

Since 2.6, batteries are included!

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That looks good to me! Thanks. –  Ben Jan 21 '09 at 11:22
I don't have python 2.6, but since that link contained the code for combinations, I was able to get it working. Thanks again! –  Ben Jan 21 '09 at 11:38
Ah, yes - I didn't see that it was 2.6 only... updated my answer –  James Brady Jan 21 '09 at 12:52
-1 This answer seems incomplete; you need another line of code to get all combinations; see answer by Dan. –  ninjagecko Jul 1 '11 at 0:04

Alabaster's answer missed one aspect: Ben asked for ALL combinations... not just combinations of length "r".

So you'd either have to loop through all lengths "L":

stuff = [1, 2, 3]
for L in range(0, len(stuff)+1):
  for subset in itertools.combinations(stuff, L):

Or -- if you want to get snazzy (or bend the brain of whoever reads your code after you) -- you can generate the chain of "combinations()" generators, and iterate through that:

from itertools import chain, combinations
def all_subsets(ss):
  return chain(*map(lambda x: combinations(ss, x), range(0, len(ss)+1)))

for subset in all_subsets(stuff):
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People should upvote this answer. I feel the currently accepted answer is misleading. –  ninjagecko Jul 1 '11 at 0:03
Thanks for the support! In the weeks since I've posted the above reply, I've found that the NAME of the concept for what Ben is looking for is the "powerset" of the original set of 15 items. In fact, an example implementation is given on the standard python "itertools" doc page: docs.python.org/library/itertools.html (grep for "powerset"). –  Dan H Nov 16 '11 at 17:45
This just saved me a lot of time –  NuSkooler Aug 1 '12 at 21:11

Here's a lazy one-liner, 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=###
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 drop-in 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)


>>> 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'}]
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I agree with Dan H that Ben indeed asked for all combinations. itertools.combinations() does not give all combinations.

Another issue is, if the input iterable is big, it is perhaps better to return a generator instead of everything in a list:

iterable = range(10)
for s in xrange(len(iterable)+1):
  for comb in itertools.combinations(iterable, s):
    yield comb
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Nice example. I love generators... and I love Python for having them! This example only has one combinations() object around at a time, and yields one of the combinations at time. (Perhaps you want to add the def block around this -- as a usage example.) Note that my implementation (with chain(), given above) is not too much worse: it's true that is creates all len(iterable) generators at once... but it does NOT create all 2 ** len(iterable) combinations at once, as -- to my understanding -- chain "uses up" the first generator before drawing from subsequent ones. –  Dan H Nov 16 '11 at 17:54

Here is one using recursion:

>>> import copy
>>> def combinations(target,data):
...     for i in range(len(data)):
...         new_target = copy.copy(target)
...         new_data = copy.copy(data)
...         new_target.append(data[i])
...         new_data = data[i+1:]
...         print new_target
...         combinations(new_target,
...                      new_data)
>>> target = []
>>> data = ['a','b','c','d']
>>> combinations(target,data)
['a', 'b']
['a', 'b', 'c']
['a', 'b', 'c', 'd']
['a', 'b', 'd']
['a', 'c']
['a', 'c', 'd']
['a', 'd']
['b', 'c']
['b', 'c', 'd']
['b', 'd']
['c', 'd']
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Using list comprehension:

def selfCombine( list2Combine, length ):
    listCombined = str( ['list2Combine[i' + str( i ) + ']' for i in range( length )] ).replace( "'", '' ) \
                     + 'for i0 in range(len( list2Combine ) )'
    if length > 1:
        listCombined += str( [' for i' + str( i ) + ' in range( i' + str( i - 1 ) + ', len( list2Combine ) )' for i in range( 1, length )] )\
            .replace( "', '", ' ' )\
            .replace( "['", '' )\
            .replace( "']", '' )

    listCombined = '[' + listCombined + ']'
    listCombined = eval( listCombined )

    return listCombined

list2Combine = ['A', 'B', 'C']
listCombined = selfCombine( list2Combine, 2 )

Output would be:

['A', 'A']
['A', 'B']
['A', 'C']
['B', 'B']
['B', 'C']
['C', 'C']
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This proposal is to do string mangling to build up sets?!?! Holy crow.... And: it is not returning the powerset, but rather, something like combinations_with_replacement(). (See docs.python.org/library/…) –  Dan H Nov 16 '11 at 18:00
This indeed does the same as combination_with_replacement(), but at least on my box this runs slightly faster than itertools. What can I say, I like list comprehensions. –  zmk Nov 24 '11 at 23:16

This one-liner gives you all the combinations (between 0 and n items if the original list/set contains n distinct elements):

from itertools import combinations

input = ['a', 'b', 'c', 'd']

output = sum([map(list, combinations(input, i)) for i in range(len(input) + 1)], [])

The output will be:

 ['a', 'b'],
 ['a', 'c'],
 ['a', 'd'],
 ['b', 'c'],
 ['b', 'd'],
 ['c', 'd'],
 ['a', 'b', 'c'],
 ['a', 'b', 'd'],
 ['a', 'c', 'd'],
 ['b', 'c', 'd'],
 ['a', 'b', 'c', 'd']]
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