# Splitting Up Lists of Lists by Length in Python

Given the following problem, what is the most efficient (or reasonably efficient) way to do this in Python:

Problem. Given a list of lists,

L = [list_0, list_1, list_2, list_3, ..., list_n]

where len(list_i) <= 3, let's say, for each list inside of L. How can we split up L into L_1, L_2, L_3, where L_1 has only length 1 lists, L_2 has only length 2 lists, and L_3 has only length 3 lists?

Potential Solutions. Here's the best I could do; I've also included a sample set here as well. It runs in around 8.6 seconds on my PC.

import time

# These 4 lines make a large sample list-of-list to test on.
asc_sample0 = [[i] for i in range(500)]
asc_sample1 = [[i,j] for i in range(500) for j in range(20)]
asc_sample2 = [[i,j,k] for i in range(20) for j in range(10) for k in range(20)]
asc_sample = asc_sample0 + asc_sample1 + asc_sample2

start = time.clock()
cells0 = [i for i in asc if len(i) == 1]
cells1 = [i for i in asc if len(i) == 2]
cells2 = [i for i in asc if len(i) == 3]
print time.clock() - start

I also attempted to "pop" elements off and append to lists cells0, etc., but this took significantly longer. I also attempted to append and then remove that element so I could get through in one loop which worked okay when there were, say, 10^10 lists of size 1, but only a few of size 2 and 3, but, in general, it was not efficient.

I'd mostly appreciate some neat ideas. I know that one of the answers will most likely be "Write this in C", but for now I'd just like to look at Python solutions for this.

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What's the point of L_3? You just said len(list_i) <= 2 for all lists in L. –  slider Nov 27 '13 at 22:54
You could probably get a significant speedup by sorting the list and then using itertools.groupby –  Waleed Khan Nov 27 '13 at 22:59
@slider Sorry; I meant that to be a 3. It's a bit confusing because length 1 lists stand for "0-cells", length 1 lists stand for "1-cells", etc., so I get mixed up a bunch. Edited to reflect this! –  james Nov 27 '13 at 23:12

This is definitely one of the best because it runs in parallel. Another thing that you should look at though is the itertools.groupby and the built-in filter method.

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The itertools.groupby looks good; I'll try this out. For the filter method, the doc for 2.7.x says that this is equivalent to the list comprehension above, unless I'm thinking about it the wrong way. –  james Nov 27 '13 at 23:23
The filter method creates a generator in python 3.x which a number of advantages over the list comprehension. –  randomusername Nov 27 '13 at 23:25
If you want to use groupby you need to sort by length first –  gnibbler Nov 27 '13 at 23:29
As gnibbler points out, I think groupby needs a sorted list first. And sorting these seem to take a bunch of time (at least on my PC, on Python 2.7.x). Maybe there's a way around the sorting? –  james Nov 27 '13 at 23:36
Look up count sort –  randomusername Nov 27 '13 at 23:37

An old fashioned solution might work better here:

cells0, cells1, cells2 = [], [], []

for lst in asc_sample:
n = len(lst)
if n == 1:
cells0.append(lst)
elif n == 2:
cells1.append(lst)
else:
cells2.append(lst)
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Exactly. One iteration instead of three. –  slider Nov 27 '13 at 22:56
I used cells_by_length = collections.defaultdict(list) to shorten the code for the inner loop to for sublist in asc_sample: cells_by_length[len(sublist)].append(sublist) but it's the same idea. –  Peter DeGlopper Nov 27 '13 at 22:59
This runs slower than the original on my computer! –  gnibbler Nov 27 '13 at 23:30
I thought that this might have been slower because of the "append" part, but I was wrong --- this is a bit faster than my method. Nice! –  james Nov 27 '13 at 23:31
After a little more testing on a few more randomly generated lists-of-lists, this seems to either be slightly better or slightly worse than the original one. Is there maybe some lag created by the appending on very, very long lists? It's strange, because I'd expect the original to have the same problems. –  james Nov 27 '13 at 23:38
result = dict()

for lst in L:
result.setdefault(len(lst), []).append(lst)

print result

Output

{
1: [[0], [1], [2], [3]],
2: [[0, 0], [0, 1], [0, 2]],
3: [[0, 0, 0], [0, 0, 1], [0, 0, 2]]
}
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This runs a bit slower than the rest, but not by much! I didn't know about setdefault, though, which is pretty cool. –  james Nov 27 '13 at 23:48

Indexing a list/tuple should be faster than doing key lookups. This is about 30% faster than the version given in the question

cells = [],[],[],[]     # first list here isn't used, but it's handy for the second version
for i in asc:
cells[len(i)].append(i)

Slightly faster again by extracting the append methods (On larger lists this is almost twice as fast as the OP)

cells = [],[],[],[]
appends = [x.append for x in cells]
for i in asc:
appends[len(i)](i)
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For me, the first seems to run a bit slower on very, very large lists, but the second is a little faster than the original. The second one is also neat because I had no idea you could do things like that --- or, at least, I don't think I've seen things like that before. –  james Nov 27 '13 at 23:55