# Python: Fast extraction of intersections among all possible 2-combinations in a large number of lists

I have a dataset of ca. 9K lists of variable length (1 to 100K elements). I need to calculate the length of the intersection of all possible 2-list combinations in this dataset. Note that elements in each list are unique so they can be stored as sets in python.

What is the most efficient way to perform this in python?

Edit I forgot to specify that I need to have the ability to match the intersection values to the corresponding pair of lists. Thanks everybody for the prompt response and apologies for the confusion!

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I gave a try to RedGlyph's solution (#2) and it's working like a charm (reasonably fast too). So I'll stick to this, thanks all for the great and prompt response. –  radrat Nov 19 '09 at 13:25

If your sets are stored in s, for example:

``````s = [set([1, 2]), set([1, 3]), set([1, 2, 3]), set([2, 4])]
``````

Then you can use itertools.combinations to take them two by two, and calculate the intersection (note that, as Alex pointed out, `combinations` is only available since version 2.6). Here with a list comrehension (just for the sake of the example):

``````from itertools import combinations
[ i[0] & i[1] for i in combinations(s,2) ]
``````

Or, in a loop, which is probably what you need:

``````for i in combinations(s, 2):
inter = i[0] & i[1]
# processes the intersection set result "inter"
``````

So, to have the length of each one of them, that "processing" would be:

``````    l = len(inter)
``````

This would be quite efficient, since it's using iterators to compute every combinations, and does not prepare all of them in advance.

Edit: Note that with this method, each set in the list "s" can actually be something else that returns a set, like a generator. The list itself could simply be a generator if you are short on memory. It could be much slower though, depending on how you generate these elements, but you wouldn't need to have the whole list of sets in memory at the same time (not that it should be a problem in your case).

For example, if each set is made from a function `gen`:

``````def gen(parameter):
while more_sets():
# ... some code to generate the next set 'x'
yield x

with open("results", "wt") as f_results:
for i in combinations(gen("data"), 2):
inter = i[0] & i[1]
f_results.write("%d\n" % len(inter))
``````

Edit 2: How to collect indices (following redrat's comment).

Besides the quick solution I answered in comment, a more efficient way to collect the set indices would be to have a list of `(index, set)` instead of a list of `set`.

Example with new format:

``````s = [(0, set([1, 2])), (1, set([1, 3])), (2, set([1, 2, 3]))]
``````

If you are building this list to calculate the combinations anyway, it should be simple to adapt to your new requirements. The main loop becomes:

``````with open("results", "wt") as f_results:
for i in combinations(s, 2):
inter = i[0][1] & i[1][1]
f_results.write("length of %d & %d: %d\n" % (i[0][0],i[1][0],len(inter))
``````

In the loop, `i[0]` and `i[1]` would be a tuple `(index, set)`, so `i[0][1]` is the first set, `i[0][0]` its index.

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> depending on how you generate these elements The sets are imported from flat text files and cannot be generated on the fly unfortunately. –  radrat Nov 18 '09 at 20:01
They could be but that would be very slow (jumping at cached positions, reading them... would indeed be a bit daunting). In this case I would stick to the first method, which does not increase the memory consumption anyway - so long as you can hold your original list of sets in memory you are fine. The Edit part idea was more to show the flexibility. –  RedGlyph Nov 18 '09 at 20:24
@RedGlyph, using combinations and the above method I can obtain the intersections between any two items and the length of the intersection indeed. However I understand I would not be able to access the position in s of the two items being compared, right? My final output needs to be a series of triples containing the ids of the two sets (e.g. if they are defined in a dictionary, or at least their positions in s) and the length of their intersection. Can your solution based on itertools be used for this purpose? –  radrat Nov 18 '09 at 22:10
@redrat: If you also need the indices for all the lengths, you can use a combination of indices instead of a combination of sets: `for x,y in combinations(xrange(0, n), 2)`, and sets would then be accessible through them: `inter = s[x] & s[y]`. If you only need a few indices, for example the max length, you can find it with: `j = s.index(imax)`, `imax` being a set in the iteration loop. It was not in your description, so you'll have to precise what you need if you want more help. –  RedGlyph Nov 18 '09 at 23:29
@redrat, this (paste.ubuntu.com/322146) is a continuation of RedGlyph's idea, except using enumerate to collect the indices. Since `enumerate` returns an iterator, it can be daisy-chained to itertools.combinations nicely. I haven't tested it, but I think this is faster than accessing elements of `s` via indexing: `s[x]`. –  unutbu Nov 19 '09 at 4:55

As you need to produce a (N by N/2) matrix of results, i.e., O(N squared) outputs, no approach can be less than O(N squared) -- in any language, of course. (N is "about 9K" in your question). So, I see nothing intrinsically faster than (a) making the N sets you need, and (b) iterating over them to produce the output -- i.e., the simplest approach. IOW:

``````def lotsofintersections(manylists):
manysets = [set(x) for x in manylists]
moresets = list(manysets)
for  s in reversed(manysets):
moresets.pop()
for z in moresets:
yield s & z
``````

This code's already trying to add some minor optimization (e.g. by avoiding slicing or popping off the front of lists, which might add other O(N squared) factors).

If you have many cores and/or nodes available and are looking for parallel algorithms, it's a different case of course -- if that's your case, can you mention the kind of cluster you have, its size, how nodes and cores can best communicate, and so forth?

Edit: as the OP has casually mentioned in a comment (!) that they actually need the numbers of the sets being intersected (really, why omit such crucial parts of the specs?! at least edit the question to clarify them...), this would only require changing this to:

``````  L = len(manysets)
for i, s in enumerate(reversed(manysets)):
moresets.pop()
for j, z in enumerate(moresets):
yield L - i, j + 1, s & z
``````

(if you need to "count from 1" for the progressive identifiers -- otherwise obvious change).

But if that's part of the specs you might as well use simpler code -- forget moresets, and:

``````  L = len(manysets)
for i xrange(L):
s = manysets[i]
for j in range(i+1, L):
yield i, j, s & manysets[z]
``````

this time assuming you want to "count from 0" instead, just for variety;-)

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@Alex Martelli: Would you please explain more about why this code is faster than itertools.combination? My timeit tests suggests this is the case, but I find that disturbing since "the one obvious way to do it" (itertools.combination) does not appear to be the fastest way to do it in this case. Should be always be using your code instead of combinations? –  unutbu Nov 18 '09 at 19:29
Thanks Alex, I am not planning to run this on a cluster so it might be quite demanding indeed. I too am interested in hearing about known differences in performance between different methods. –  radrat Nov 18 '09 at 19:59
@Alex: don't you need to exclude identical sets, with `if s is not z: yield s & z`? –  RedGlyph Nov 18 '09 at 20:31
@unutbu: I've done a few measurements and both yield very close timings (within 0.1% for minute-long tests), regardless of the list and/or set sizes. Did you observe something much different? –  RedGlyph Nov 18 '09 at 20:53
@RedGlyph: I have to retract my previous comment. The two algorithms I tested do not return the same results, even with `if s is not z: yield s & z`. So comparing times is meaningless. It is probably an error that I introduced somehow, but so far I haven't been able to find it. You can look at my code here: paste.ubuntu.com/321906 –  unutbu Nov 18 '09 at 22:14

Try this:

``````_lists = [[1, 2, 3, 7], [1, 3], [1, 2, 3], [1, 3, 4, 7]]
_sets = map( set, _lists )
_intersection = reduce( set.intersection, _sets )
``````

And to obtain the indexes:

``````_idxs = [ map(_i.index, _intersection ) for _i in _lists ]
``````

Cheers,

José María García

PS: Sorry I misunderstood the question

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