Stack Overflow is a community of 4.7 million programmers, just like you, helping each other.

Join them; it only takes a minute:

Sign up
Join the Stack Overflow community to:
  1. Ask programming questions
  2. Answer and help your peers
  3. Get recognized for your expertise

I had some code that contained zip(*G)[0] (and elsewhere, zip(*G)[1], with a different G). G is a list of tuples. What this does is return a list of the first (or generally, for zip(*G)[n], the n-1th) element of each tuple in G as a tuple. For example,

>>> G = [(1, 2, 3), ('a', 'b', 'c'), ('you', 'and', 'me')]
>>> zip(*G)[0]
(1, 'a', 'you')
>>> zip(*G)[1]
(2, 'b', 'and')

This is pretty clever and all, but the problem is that it doesn't work in Python 3, because zip is an iterator there. Furthermore, 2to3 isn't smart enough to fix it. So the obvious solution is to use list(zip(*G))[0], but that got me thinking: there is probably a more efficient way to do this. There is no need to create all the tuples that zip creates. I just need the nth element of each tuple in G.

Is there are more efficient, but equally compact way to do this? I'm OK with anything from the standard library. In my use case, each tuple in G will be at least length n, so there is no need to worry about the case of zip stopping at the smallest length tuple (i.e., zip(*G)[n] will always be defined).

If not, I guess I'll just stick with wrapping the zip in list().

(P.S., I know this is unnecessary optimization. I'm just curious is all)


In case anyone cares, I went with the t0, t1, t2 = zip(*G) option. First, this lets me give meaningful names to the data. My G actually consists of length 2 tuples (representing numerators and denominators). A list comprehension would only be marginally more readable than the zip, but this way is much better (and since in most cases the zip was list I was iterating through in a list comprehension, this makes things flatter).

Second, as noted by @thewolf and @Sven Marnach's excellent answers, this way is faster for smaller lists. My G is actually not large in most cases (and if it is large, then this definitely won't be the bottleneck of the code!).

But there were more ways to do this than I expected, including the new a, *b, c = G feature of Python 3 I didn't even know about.

share|improve this question
up vote 10 down vote accepted

At least the fastest way in Python 2.7 is

t0,t1,t2=zip(*G) for SMALLER lists and [x[0] for x in G] in general

Here is the test:

from operator import itemgetter

G = [(1, 2, 3), ('a', 'b', 'c'), ('you', 'and', 'me')]

def f1():
   return tuple(x[0] for x in G)

def f2():
   return tuple(map(itemgetter(0), G))

def f3():
    return tuple(x for x, y, z in G)     

def f4():
    return tuple(list(zip(*G))[0])

def f5():
    return t0

def f6():
    return t0                



    rate/sec     f4     f5     f1     f2     f3     f6
f4   494,220     -- -21.9% -24.1% -24.3% -26.6% -67.6%
f5   632,623  28.0%     --  -2.9%  -3.0%  -6.0% -58.6%
f1   651,190  31.8%   2.9%     --  -0.2%  -3.2% -57.3%
f2   652,457  32.0%   3.1%   0.2%     --  -3.0% -57.3%
f3   672,907  36.2%   6.4%   3.3%   3.1%     -- -55.9%
f6 1,526,645 208.9% 141.3% 134.4% 134.0% 126.9%     --

If you don't care if the result is a list, a list comprehension if faster.

Here is a more extended benchmark with variable list sizes:

from operator import itemgetter
import time
import timeit 
import matplotlib.pyplot as plt

def f1():
   return [x[0] for x in G]

def f1t():
   return tuple([x[0] for x in G])

def f2():
   return tuple([x for x in map(itemgetter(0), G)])

def f3():
    return tuple([x for x, y, z in G])    

def f4():
    return tuple(list(zip(*G))[0])

def f6():
    return t0     

for c in range(*r):
    G=[range(3) for i in range(c)] 
    for f in results.keys():

for f,res in sorted(results.items(),key=itemgetter(1),reverse=True):
    if f.__name__ in ['f6','f1','f1t']:
        plt.plot(res, label=f.__name__,linewidth=2.5)
        plt.plot(res, label=f.__name__,linewidth=.5)

plt.xlabel('data size => {}'.format(r))  
plt.legend(loc='upper right')

Which produces this plot for smaller data sizes (5 to 35):


And this output for larger ranges (25 to 250):


You can see that f1, a list comprehension is fastest. f6 and f1t trading places as the fastest to return a tuple.

share|improve this answer
I'm not familiar with cmpthese. How should I interpret the results? – asmeurer Sep 15 '12 at 21:56
@asmeurer: cmpthese prints a Perl style performance comparison. It is based on Python's timeit module. It just runs all the subroutines and compares the speed. The table is printed slowest on top to fastest on the bottom. The faster the rate / sec, the faster the subroutine. The table to the right shows how much faster: f6 is 208.9% faster than f4; f3 is 3.1% faster than f2 but 55.9% slower than f6 and so on. You read it from the left and it shows how much faster / slower each is in comparison to each other. – the wolf Sep 15 '12 at 22:10
I'm marking this as the answer for now. I'm quite surprised that f6 is the fastest. Maybe you should test with a larger G. Anyhow, this will also make my list comprehensions where I tend to have the zip(*G) a little easier to read, as it will split part of it into a separate line. – asmeurer Sep 15 '12 at 22:11
I also just noticed that in at least one place I am using zip(*G)[0] and zip(*G)[1] for the same G. So this way will clearly be the best for that. – asmeurer Sep 15 '12 at 22:14
This comparison has a few issues: 1. The test data set is far too small for any meaningful results. If the data is that small, it simply does not matter which variant to use, and details like looking up names from the global namespace bias the results. 2. The benchmark only compares the variants producing tuples. The only reason the OP used a tuple seems to be that the zip() solution happens to give one. 3. As a consequence, it does not include the list comprehensions, which are probably the variants most people would use in practise (and they are pretty fat, too). – Sven Marnach Sep 15 '12 at 23:38

You can use a list comprehension

[x[0] for x in G]

or operator.itemgetter()

from operator import itemgetter
map(itemgetter(0), G)

or sequence unpacking

[x for x, y, z in G]

Edit: Here is my take on timing the different options, also in Python 3.2:

from operator import itemgetter
import timeit

G = list(zip(*[iter(range(30000))] * 3))

def f1():
    return [x[0] for x in G]
def f2():
    return list(map(itemgetter(0), G))
def f3():
    return [x for x, y, z in G]
def f4():
    return list(zip(*G))[0]
def f5():
    c0, *rest = zip(*G)
    return c0
def f6():
    c0, c1, c2 = zip(*G)
    return c0
def f7():
    return next(zip(*G))

for f in f1, f2, f3, f4, f5, f6, f7:
    print(f.__name__, timeit.timeit(f, number=1000))

Results on my machine:

f1 0.6753780841827393
f2 0.8274149894714355
f3 0.5576457977294922
f4 0.7980241775512695
f5 0.7952430248260498
f6 0.7965989112854004
f7 0.5748469829559326


  1. I used a list with 10000 triples to measure the actual processing time, and make function call overhead, name lookups etc. negligible, which would otherwise seriously influence the results.

  2. The functions return a list or a tuple – whatever is more convenient for the particular solution.

  3. Compared to the wolf's answer, I removed the redundant call to tuple() from f4() (the result of the expression is a tuple already), and I added a function f7() which only works to extract the first column.

As expected, the list comprehensions are fastest, together with the somewhat less general f7().

Another edit: Here are the results for ten columns instead of three, with the code adapted where appropriate:

f1 0.7429649829864502
f2 0.881648063659668
f3 1.234360933303833
f4 1.92038893699646
f5 1.9218590259552002
f6 1.9172680377960205
f7 0.6230220794677734
share|improve this answer
Which one is the best way? – martineau Sep 15 '12 at 21:39
I vote for the first one as the best way. There's no need to create dummy variables, or use some (to me strange and overly complicated) operators and maps. – asmeurer Sep 15 '12 at 21:53
@martineau: I'd usually go with the first one. In some situations, I prefer the last one, e.g. when iterating over a list of heterogeneous tuples, because I can document the field names of the tuples by using matching loop variable names. – Sven Marnach Sep 15 '12 at 22:06
Interesting how your timing results differ so much from @the wolf's. I can see how you measured things and it looks sound. Any idea why his are so different, esp for f6()? – martineau Sep 16 '12 at 16:45
@martineau: The main reason is that the input data set was too small. In the wolf's answer, the overhead of name lookups etc is significant. You would get quite different results with optimisations like importing global names into the local namespace via bogus default parameters etc. All those things won't matter with a big data set, since they are completely dominated by the actual processing time. – Sven Marnach Sep 16 '12 at 17:27

A very clever Python 3 only way is with starred assignments or extended iterable unpacking:

>>> G = [(1, 2, 3), ('a', 'b', 'c'), ('you', 'and', 'me')]
>>> items_I_want,*the_rest=zip(*G)
>>> items_I_want
(1, 'a', 'you')
>>> the_rest
[(2, 'b', 'and'), (3, 'c', 'me')]

Since you are writing code for both, you could use explicit unpacking (which works on Python 2 and Python 3):

>>> z1,z2,z3=zip(*G)
>>> z1
(1, 'a', 'you')
>>> z2
(2, 'b', 'and')
>>> z3
(3, 'c', 'me')
share|improve this answer
Why the downvote? Starred assignments are unique in Py3 and the closest to the OP's code? – user688635 Sep 15 '12 at 21:01
That's pretty cool! And it even works in list comprehensions: [j for j, *_ in [(1, 2, 3), ('a', 'b', 'c')]] -> [1, 'a']. Unfortunately, as I noted, I am writing code in Python 2 and converting it to Python 3. – asmeurer Sep 15 '12 at 21:52
@asmeurer: Then use the form of z1,z2,z3=zip(*G) which works in both Python 2 and Python 3 and is the fastest. – user688635 Sep 15 '12 at 22:14

Your Answer


By posting your answer, you agree to the privacy policy and terms of service.

Not the answer you're looking for? Browse other questions tagged or ask your own question.