Joining a list:

>>> ''.join([ str(_) for _ in xrange(10) ])

join must take an iterable.

Apparently, join's argument is [ str(_) for _ in xrange(10) ], and it's a list comprehension.

Look at this:

>>>''.join( str(_) for _ in xrange(10) )

Now, join's argument is just str(_) for _ in xrange(10), no [], but the result is the same.

Why? Does str(_) for _ in xrange(10) also produce a list or an iterable?

  • 1
    I would imagine that join is most likely written in C and therefore runs much faster than a list comprehension... Testing time! Jan 30, 2012 at 7:31
  • Apparently, I read your question completely wrong. It seems to be returning a generator for me... Jan 30, 2012 at 7:38
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    Just a note: _ has no special meaning, it's a regular variable name. It's often used as a throw-away name but this is not the case (you are using the variable). I would avoid using it in a code (in this way at least).
    – rplnt
    Jan 30, 2012 at 9:22

7 Answers 7


The other respondents were correct in answering that you had discovered a generator expression (which has a notation similar to list comprehensions but without the surrounding square brackets).

In general, genexps (as they are affectionately known) are more memory efficient and faster than list comprehensions.

HOWEVER, it the case of ''.join(), a list comprehension is both faster and more memory efficient. The reason is that join needs to make two passes over the data, so it actually needs a real list. If you give it one, it can start its work immediately. If you give it a genexp instead, it cannot start work until it builds-up a new list in memory by running the genexp to exhaustion:

~ $ python -m timeit '"".join(str(n) for n in xrange(1000))'
1000 loops, best of 3: 335 usec per loop
~ $ python -m timeit '"".join([str(n) for n in xrange(1000)])'
1000 loops, best of 3: 288 usec per loop

The same result holds when comparing itertools.imap versus map:

~ $ python -m timeit -s'from itertools import imap' '"".join(imap(str, xrange(1000)))'
1000 loops, best of 3: 220 usec per loop
~ $ python -m timeit '"".join(map(str, xrange(1000)))'
1000 loops, best of 3: 212 usec per loop
  • 4
    @lazyr Your second timing is doing too much work. Don't wrap a genexp around a listcomp -- just use a genexp directly. No wonder you got odd timings. Jan 30, 2012 at 9:51
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    In an effort to time only join, I put everything except "".join(l) in the setup statement. And therein lies the problem -- the genexp was exhausted on the first loop, so the next 999999 times it joined an empty genexp. No wonder it was fast. Jan 30, 2012 at 10:06
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    Could you explain why ''.join() needs 2 passes over the iterator to build a string?
    – ovgolovin
    Jan 30, 2012 at 10:42
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    @ovgolovin I'd guess the first pass is to sum the lengths of the strings so as to be able to allocate the correct amount of memory for the concatenated string, while the second pass is to copy the individual strings into the allocated space. Jan 30, 2012 at 13:42
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    @lazyr That guess is correct. That is exactly what str.join does :-) Jan 30, 2012 at 15:49
>>>''.join( str(_) for _ in xrange(10) )

This is called a generator expression, and is explained in PEP 289.

The main difference between generator expressions and list comprehensions is that the former don't create the list in memory.

Note that there's a third way to write the expression:

''.join(map(str, xrange(10)))
  • 1
    As I know it, a generator can be produce through a tuple-like expression, like ( str(_) for _ in xrange(10) ). But I was confused that, why the () can be omited in join, which means, the code should be like `''.join( (str(_) for _ in xrange(10)) ), right?
    – Alcott
    Jan 30, 2012 at 7:44
  • 2
    @Alcott My understanding of tuples is that they are actually defined by the comma-separated list of expressions and not the parenthesis; the parenthesis are only there to visually group the values in an assignment or to actually group the values if the tuple were going into some other comma-separated list, like a function call. This is often demonstrated by running code like tup = 1, 2, 3; print(tup). With that in mind, using for as a part of an expression creates the generator and the parenthesis are just there to distinguish it from an incorrectly written loop. Oct 16, 2019 at 20:08

Your second example uses a generator expression rather than a list comprehension. The difference is that with the list comprehension, a list is completely built and passed to .join(). With the generator expression, items are generated one by one and consumed by .join(). The latter uses less memory and is generally faster.

As it happens, the list constructor will happily consume any iterable, including a generator expression. So:

[str(n) for n in xrange(10)]

is just "syntactic sugar" for:

list(str(n) for n in xrange(10))

In other words, a list comprehension is just a generator expression that is turned into a list.

  • 2
    Are you sure they're equivalent under the hood? Timeit says: [str(x) for x in xrange(1000)]: 262 usec, list(str(x) for x in xrange(1000)): 304 usec. Jan 30, 2012 at 8:53
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    @lazyr You are right. List comprehension is faster. And this is the reason why list comprehensions leak in Python 2.x. This is what GVR wrote: ""This was an artifact of the original implementation of list comprehensions; it was one of Python's "dirty little secrets" for years. It started out as an intentional compromise to make list comprehensions blindingly fast, and while it was not a common pitfall for beginners, it definitely stung people occasionally." python-history.blogspot.com/2010/06/…
    – ovgolovin
    Jan 30, 2012 at 9:14
  • 3
    @ovgolovin The reason the listcomp is faster is because join has to create a list before it can start work. The "leak" you refer to isn't a speed issue -- it just means that the loop induction variable is exposed outside the listcomp. Jan 30, 2012 at 9:56
  • 1
    @RaymondHettinger Then what do these word mean "It started out as an intentional compromise to make list comprehensions blindingly fast"? As I understood there is a connection of their leakage with the speed issues. GVR also wrote: "For generator expressions we could not do this. Generator expressions are implemented using generators, whose execution requires a separate execution frame. Thus, generator expressions (especially if they iterate over a short sequence) were less efficient than list comprehensions."
    – ovgolovin
    Jan 30, 2012 at 10:08
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    @ovgolovin You've made an incorrect leap from a listcomp implementation detail to why str.join performs the way it does. One of the first lines in the str.join code is seq = PySequence_Fast(orig, ""); and that is the sole reason iterators run more slowly than lists or tuples when calling str.join(). You're welcome to start-up a chat if you want to discuss it further (I'm the author of PEP 289, the creator of the LIST_APPEND opcode, and the one who optimized the list() constructor, so I do have some familiarity with the issue). Jan 30, 2012 at 16:18

As mentioned it's a generator expression.

From the documentation:

The parentheses can be omitted on calls with only one argument. See section Calls for the detail.


If it's in parens, but not brackets, it's technically a generator expression. Generator expressions were first introduced in Python 2.4.


The part after the join, ( str(_) for _ in xrange(10) ) is, by itself, a generator expression. You could do something like:

mylist = (str(_) for _ in xrange(10))

and it means exactly the same thing that you wrote in the second case above.

Generators have some very interesting properties, not the least of which is that they don't end up allocating an entire list when you don't need one. Instead, a function like join "pumps" the items out of the generator expression one at a time, doing its work on the tiny intermediate parts.

In your particular examples, list and generator probably don't perform terribly differently, but in general, I prefer using generator expressions (and even generator functions) whenever I can, mostly because it's extremely rare for a generator to be slower than a full list materialization.


That's a generator, rather than a list comprehension. Generators are also iterables, but rather than creating the entire list first then passing it to join, it passes each value in the xrange one by one, which can be much more efficient.


The argument to your second join call is a generator expression. It does produce an iterable.

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