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I need to generate all "ordered subsets" (apologies if I'm not using correct mathematical terminology) of a sequence in Python, with omitted elements replaced with None.Given [1, 2], I want [(1, 2), (1, None), (None, 2), (None, None)]. Each "ordered subset" should have the property that at each position, it is either exactly the same element as in the seed sequence, or it is None.

I can fairly easily generate subsets with omitted elements missing with the following:

from itertools import combinations
for length in xrange(len(items), 0, -1):
    for combination in combinations(items, length):
        yield combination

I can't figure out what the most effective way of reconstructing the missing elements, would be though. My first thought is to do something like this:

from itertools import combinations
indexes = range(len(items))
for length in xrange(len(items), 0, -1):
    for combination in combinations(indexes, length):
        yield tuple(items[i] if i in combination else None for i in indexes)

Just wondering if anyone can spot any obvious deficiencies in this, or if there's a more efficient solution I've missed. (Note that the items will be a fairly short list, typically under 10 elements, so I am not concerned about the O(N) search of "combination" in the inner loop).

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4 Answers 4

up vote 11 down vote accepted
from itertools import product, repeat
given = [1, 2]
with_nones = zip(given, repeat(None))
print(list(product(*with_nones)))
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1  
Since I love generators, I'll use a version with izip_longest -- but awesome, thanks! –  dcrosta Aug 17 '12 at 21:01
2  
+1. Here's the izip_longest version (based on dcrosta's comment): list(product(*izip_longest(given, []))) –  Steven Rumbalski Aug 17 '12 at 21:07
1  
this is in the wrong order tho: [(None, None), (None, 2), (1, None), (1, 2)] –  the wolf Aug 18 '12 at 0:30
    
@carrot-top: Fixed, I overlooked the part that said "ordered subsets". –  Joel Cornett Aug 18 '12 at 0:43
1  
I don't care about the order of the subsets, just the order of elements within each one, as it turns out. I'm using something very like Steven Rumbalski's solution, but without list(...), since I only need to iterate once –  dcrosta Aug 18 '12 at 1:22

Here is another:

>>> given=[1,2,3,4]
>>> rtr=[[]]
>>> for t in map(None,*(given,[None])):
...    rtr=[x+[y] for x in rtr for y in t]
... 
>>> rtr
[[1, 2, 3, 4], [1, 2, 3, None], [1, 2, None, 4], [1, 2, None, None], [1, None, 3, 4], [1, None, 3, None], [1, None, None, 4], [1, None, None, None], [None, 2, 3, 4], [None, 2, 3, None], [None, 2, None, 4], [None, 2, None, None], [None, None, 3, 4], [None, None, 3, None], [None, None, None, 4], [None, None, None, None]]
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An alternate -- in case you want to show off how silly you are to NOT use itertools:

>>> given=[1,2]
>>> gz=zip(given,[None]*len(given))
>>> [(i,j) for i in gz[0] for j in gz[1]]
[(1, 2), (1, None), (None, 2), (None, None)]
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Neat. Can you generalize it to more than a 2-element given though? –  dcrosta Aug 18 '12 at 1:22

You could start with an empty list, for every element in your seed you can copy all the final lists and add the seed at the end.

e.g.

solutions = []
solutions.append([])
for elem in seed:
    newPartials = []
    for partial in solutions:
        newPartial = partial[:]
        newPartial.append(elem)
        newPartials.append(newPartial)
    solutions.extend(newPartials)

or, you could create the number of possible solutions, 2^n, where n is the length of your seed list, and using modular arithmetic, remove elements, like so:

solutions = []
for i in xrange(2**n):
    solutions.append(seed[:])
seedLen = len(seed)
for i in xrange(2**(n-1)): // % 0 case of following loop
    solutions[i].pop(0)
for elemLoc in xrange(1,seedLen):
    for solutionNum in xrange(2**n):
        if solutionNum % elemLoc = 0:
            solutions[solutionNum].pop(elemLoc)

This solution is hilariously inefficient, I mostly included it because it's an interesting way to solve the problem.

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1  
One of my co-workers proposed a one-liner version of your first suggestion -- took me a while to unravel it: reduce(lambda x,y: x+[e+[y] for e in x], items, [[]])) –  dcrosta Aug 18 '12 at 1:24
    
I was specifically going for understandability over elegance when they conflicted. Neat tricks are for people who know what they're doing, and sometimes not even then. –  rsegal Aug 18 '12 at 2:18

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