When should you use generator expressions and when should you use list comprehensions in Python?

# Generator expression
(x*2 for x in range(256))

# List comprehension
[x*2 for x in range(256)]
  • 20
    could [exp for x in iter] just be sugar for list((exp for x in iter)) ? or is there an execution difference ? – b0fh Jan 24 '13 at 0:32
  • 1
    it think I had a relevant question, so when using yield can we use just the generator expression from a function or we have to use yield for a function to return generator object ? – user1176501 Sep 6 '13 at 13:30
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    @b0fh Very late answer to your comment: in Python2 there is a tiny difference, the loop variable will leak out of a list comprehension, while a generator expression will not leak. Compare X = [x**2 for x in range(5)]; print x with Y = list(y**2 for y in range(5)); print y, the second will give an error. In Python3, a list comprehension is indeed the syntactic sugar for a generator expression fed to list() as you expected, so the loop variable will no longer leak out. – Bas Swinckels Nov 16 '14 at 19:53
  • 8
    I'd suggest reading PEP 0289. Summed up by "This PEP introduces generator expressions as a high performance, memory efficient generalization of list comprehensions and generators". It also has useful examples of when to use them. – icc97 Jan 24 '16 at 9:31
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    @icc97 I'm also eight years late to the party, and the PEP link was perfect. Thanks for making that easy to find! – eenblam Jan 28 '16 at 1:53
up vote 230 down vote accepted

John's answer is good (that list comprehensions are better when you want to iterate over something multiple times). However, it's also worth noting that you should use a list if you want to use any of the list methods. For example, the following code won't work:

def gen():
    return (something for something in get_some_stuff())

print gen()[:2]     # generators don't support indexing or slicing
print [5,6] + gen() # generators can't be added to lists

Basically, use a generator expression if all you're doing is iterating once. If you want to store and use the generated results, then you're probably better off with a list comprehension.

Since performance is the most common reason to choose one over the other, my advice is to not worry about it and just pick one; if you find that your program is running too slowly, then and only then should you go back and worry about tuning your code.

  • 58
    Sometimes you have to use generators -- for example, if you're writing coroutines with cooperative scheduling using yield. But if you're doing that, you're probably not asking this question ;) – ephemient Oct 10 '08 at 2:06
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    I know this is old, but I think it's worth noting that generators (and any iterable) can be added to lists with extend: a = [1, 2, 3] b = [4, 5, 6] a.extend(b) -- a will now be [1, 2, 3, 4, 5, 6]. (Can you add newlines in comments??) – jarvisteve Aug 13 '12 at 19:06
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    @jarvisteve your example belies the words you are saying. There's also a fine point here. Lists can be extended with generators, but then there was no point in making it a generator. Generators cannot be extended with lists, and generators are not quite iterables. a = (x for x in range(0,10)), b = [1,2,3] for instance. a.extend(b) throws an exception. b.extend(a) will evaluate all of a, in which case there's no point in making it a generator in the first place. – Slater Victoroff Jun 12 '13 at 21:54
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    @SlaterTyranus you're 100% correct, and I upvoted you for accuracy. nevertheless, I think his comment is a useful non-answer to the OP's question because it will help those who find themselves here because they typed something like 'combine generator with list comprehension' into a search engine. – rbp Aug 1 '13 at 15:21
  • Wouldn't the reason for using a generator to iterate through once (e.g. my concern about lack of memory overrides my concern about "fetching" values one at a time) probably still apply when iterating multiple times? I'd say it might make a list more useful, but whether that's enough to outweigh memory concerns is something else. – Robert Grant Aug 29 '14 at 14:09

Iterating over the generator expression or the list comprehension will do the same thing. However, the list comprehension will create the entire list in memory first while the generator expression will create the items on the fly, so you are able to use it for very large (and also infinite!) sequences.

  • 24
    +1 for infinite. You can't do that with a list, regardless of how little you care about performance. – Paul Draper Oct 30 '13 at 19:59
  • Can you create infinite generators using the comprehension method? – Annan May 22 '15 at 14:29
  • 4
    @Annan Only if you already have access to another infinite generator. For example, itertools.count(n) is an infinite sequence of integers, starting from n, so (2 ** item for item in itertools.count(n)) would be an infinite sequence of the powers of 2 starting at 2 ** n. – Kevin Jun 1 '15 at 1:48
  • 2
    A generator deletes items from memory after their iterated over. So its fast if you have big data you just want to display it, for example. Its not a memory hog. with generators items are processed 'as needed'. if you want to hang on to the list or iterate over it again (so store the items) then use list comprehension. – j2emanue Jun 11 '15 at 14:04

Use list comprehensions when the result needs to be iterated over multiple times, or where speed is paramount. Use generator expressions where the range is large or infinite.

  • 1
    This will be probably a little off-topic, but unfortunately "un-googlable"... What would "paramount" mean in this context? I'm not a native english speaker... :) – Guillermo Ares Feb 16 '16 at 21:26
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    @GuillermoAres this is direct result of "googling" for meaning of paramount: more important than anything else; supreme. – Sнаđошƒаӽ Mar 7 '16 at 7:04
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    So lists are speedier than generator expressions? From reading dF's answer, it came across that it was the other way around. – Hassan Baig Sep 3 '16 at 14:40

The important point is that the list comprehension creates a new list. The generator creates a an iterable object that will "filter" the source material on-the-fly as you consume the bits.

Imagine you have a 2TB log file called "hugefile.txt", and you want the content and length for all the lines that start with the word "ENTRY".

So you try starting out by writing a list comprehension:

logfile = open("hugefile.txt","r")
entry_lines = [(line,len(line)) for line in logfile if line.startswith("ENTRY")]

This slurps up the whole file, processes each line, and stores the matching lines in your array. This array could therefore contain up to 2TB of content. That's a lot of RAM, and probably not practical for your purposes.

So instead we can use a generator to apply a "filter" to our content. No data is actually read until we start iterating over the result.

logfile = open("hugefile.txt","r")
entry_lines = ((line,len(line)) for line in logfile if line.startswith("ENTRY"))

Not even a single line has been read from our file yet. In fact, say we want to filter our result even further:

long_entries = ((line,length) for (line,length) in entry_lines if length > 80)

Still nothing has been read, but we've specified now two generators that will act on our data as we wish.

Lets write out our filtered lines to another file:

outfile = open("filtered.txt","a")
for entry,length in long_entries:
    outfile.write(entry)

Now we read the input file. As our for loop continues to request additional lines, the long_entries generator demands lines from the entry_lines generator, returning only those whose length is greater than 80 characters. And in turn, the entry_lines generator requests lines (filtered as indicated) from the logfile iterator, which in turn reads the file.

So instead of "pushing" data to your output function in the form of a fully-populated list, you're giving the output function a way to "pull" data only when its needed. This is in our case much more efficient, but not quite as flexible. Generators are one way, one pass; the data from the log file we've read gets immediately discarded, so we can't go back to a previous line. On the other hand, we don't have to worry about keeping data around once we're done with it.

The benefit of a generator expression is that it uses less memory since it doesn't build the whole list at once. Generator expressions are best used when the list is an intermediary, such as summing the results, or creating a dict out of the results.

For example:

sum(x*2 for x in xrange(256))

dict( ((k, some_func(k) for k in some_list_of_keys) )

The advantage there is that the list isn't completely generated, and thus little memory is used (and should also be faster)

You should, though, use list comprehensions when the desired final product is a list. You are not going to save any memeory using generator expressions, since you want the generated list. You also get the benefit of being able to use any of the list functions like sorted or reversed.

For example:

reversed( [x*2 for x in xrange(256)] )
  • 9
    There is a hint put for you right in the language that generator expressions are meant to be used that way. Lose the brackets! sum(x*2 for x in xrange(256)) – u0b34a0f6ae Sep 29 '09 at 0:04
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    That should be dict( ((k, some_func(k)) for k in some_list_of_keys ). Of course the 2.7+ dict/set comprehension syntax is even sweeter. – Beni Cherniavsky-Paskin Aug 14 '12 at 10:38
  • 7
    sorted and reversed work fine on any iterable, generator expressions included. – marr75 Mar 25 '13 at 22:37
  • If you can use 2.7 and above, that dict() example would looks better as a dict comprehension (the PEP for that is older than then the generator expressions PEP, but took longer to land) – Jürgen A. Erhard Mar 5 '17 at 20:11
  • note: there is a typo in the code. See Beni's comment above to fix the typo if you're trying to implement the example provided. – SherylHohman May 17 '17 at 18:17

When creating a generator from a mutable object (like a list) be aware that the generator will get evaluated on the state of the list at time of using the generator, not at time of the creation of the generator:

>>> mylist = ["a", "b", "c"]
>>> gen = (elem + "1" for elem in mylist)
>>> mylist.clear()
>>> for x in gen: print (x)
# nothing

If there is any chance of your list getting modified (or a mutable object inside that list) but you need the state at creation of the generator you need to use a list comprehension instead.

I'm using the Hadoop Mincemeat module. I think this is a great example to take a note of:

import mincemeat

def mapfn(k,v):
    for w in v:
        yield 'sum',w
        #yield 'count',1


def reducefn(k,v): 
    r1=sum(v)
    r2=len(v)
    print r2
    m=r1/r2
    std=0
    for i in range(r2):
       std+=pow(abs(v[i]-m),2)  
    res=pow((std/r2),0.5)
    return r1,r2,res

Here the generator gets numbers out of a text file (as big as 15GB) and applies simple math on those numbers using Hadoop's map-reduce. If I had not used the yield function, but instead a list comprehension, it would have taken a much longer time calculating the sums and average (not to mention the space complexity).

Hadoop is a great example for using all the advantages of Generators.

Sometimes you can get away with the tee function from itertools, it returns multiple iterators for the same generator that can be used independently.

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