Apparently xrange is faster but I have no idea why it's faster (and no proof besides the anecdotal so far that it is faster) or what besides that is different about
for i in range(0, 20): for i in xrange(0, 20):
In Python 2.x:
range creates a list, so if you do
range(1, 10000000) it creates a list in memory with
xrange is a sequence object that evaluates lazily.
In Python 3:
rangedoes the equivalent of Python 2's
xrange. To get the list, you have to explicitly use
xrangeno longer exists.
range creates a list, so if you do
range(1, 10000000)it creates a list in memory with
is a generator, so itis a sequence object is athat evaluates lazily.
This is true, but in Python 3,
range() will be implemented by the Python 2
xrange(). If you need to actually generate the list, you will need to do:
Remember, use the
timeit module to test which of small snippets of code is faster!
$ python -m timeit 'for i in range(1000000):' ' pass' 10 loops, best of 3: 90.5 msec per loop $ python -m timeit 'for i in xrange(1000000):' ' pass' 10 loops, best of 3: 51.1 msec per loop
Personally, I always use
range(), unless I were dealing with really huge lists -- as you can see, time-wise, for a list of a million entries, the extra overhead is only 0.04 seconds. And as Corey points out, in Python 3.0
xrange() will go away and
range() will give you nice iterator behavior anyway.
xrange only stores the range params and generates the numbers on demand. However the C implementation of Python currently restricts its args to C longs:
xrange(2**32-1, 2**32+1) # When long is 32 bits, OverflowError: Python int too large to convert to C long range(2**32-1, 2**32+1) # OK --> [4294967295L, 4294967296L]
Note that in Python 3.0 there is only
range and it behaves like the 2.x
xrange but without the limitations on minimum and maximum end points.
Do spend some time with the Library Reference. The more familiar you are with it, the faster you can find answers to questions like this. Especially important are the first few chapters about builtin objects and types.
The advantage of the xrange type is that an xrange object will always take the same amount of memory, no matter the size of the range it represents. There are no consistent performance advantages.
Another way to find quick information about a Python construct is the docstring and the help-function:
print xrange.__doc__ # def doc(x): print x.__doc__ is super useful help(xrange)
The doc clearly reads :
This function is very similar to
range(), but returns an
xrangeobject instead of a list. This is an opaque sequence type which yields the same values as the corresponding list, without actually storing them all simultaneously. The advantage of
range()is minimal (since
xrange()still has to create the values when asked for them) except when a very large range is used on a memory-starved machine or when all of the range’s elements are never used (such as when the loop is usually terminated with
range creates a list, so if you do range(1, 10000000) it creates a list in memory with 10000000 elements. xrange is a generator, so it evaluates lazily.
This brings you two advantages:
You will find the advantage of
range in this simple example:
import timeit t1 = timeit.default_timer() a = 0 for i in xrange(1, 100000000): pass t2 = timeit.default_timer() print "time taken: ", (t2-t1) # 4.49153590202 seconds t1 = timeit.default_timer() a = 0 for i in range(1, 100000000): pass t2 = timeit.default_timer() print "time taken: ", (t2-t1) # 7.04547905922 seconds
The above example doesn't reflect anything substantially better in case of
Now look at the following case where
range is really really slow, compared to
import timeit t1 = timeit.default_timer() a = 0 for i in xrange(1, 100000000): if i == 10000: break t2 = timeit.default_timer() print "time taken: ", (t2-t1) # 0.000764846801758 seconds t1 = timeit.default_timer() a = 0 for i in range(1, 100000000): if i == 10000: break t2 = timeit.default_timer() print "time taken: ", (t2-t1) # 2.78506207466 seconds
range, it already creates a list from 0 to 100000000(time consuming), but
xrange is a generator and it only generates numbers based on the need, that is, if the iteration continues.
In Python-3, the implementation of the
range functionality is same as that of
xrange in Python-2, while they have done away with
xrange in Python-3
It is for optimization reasons.
range() will create a list of values from start to end (0 .. 20 in your example). This will become an expensive operation on very large ranges.
xrange() on the other hand is much more optimised. it will only compute the next value when needed (via an xrange sequence object) and does not create a list of all values like range() does.
range(): range(1, 10) returns a list from 1 to 10 numbers & hold whole list in memory.
xrange(): Like range(), but instead of returning a list, returns an object that generates the numbers in the range on demand. For looping, this is lightly faster than range() and more memory efficient. xrange() object like an iterator and generates the numbers on demand.(Lazy Evaluation)
In : range(1,10) Out: [1, 2, 3, 4, 5, 6, 7, 8, 9] In : xrange(10) Out: xrange(10) In : print xrange.__doc__ xrange([start,] stop[, step]) -> xrange object
range(x,y) returns a list of each number in between x and y if you use a
for loop, then
range is slower. In fact,
range has a bigger Index range.
range(x.y) will print out a list of all the numbers in between x and y
xrange(x,y) but if you used a
for loop, then
xrange is faster.
xrange has a smaller Index range.
xrange will not only print out
xrange(x,y) but it will still keep all the numbers that are in it.
[In] range(1,10) [Out] [1, 2, 3, 4, 5, 6, 7, 8, 9] [In] xrange(1,10) [Out] xrange(1,10)
If you use a
for loop, then it would work
[In] for i in range(1,10): print i [Out] 1 2 3 4 5 6 7 8 9 [In] for i in xrange(1,10): print i [Out] 1 2 3 4 5 6 7 8 9
There isn't much difference when using loops, though there is a difference when just printing it!
Some of the other answers mention that Python 3 eliminated 2.x's
range and renamed 2.x's
range. However, unless you're using 3.0 or 3.1 (which nobody should be), it's actually a somewhat different type.
As the 3.1 docs say:
Range objects have very little behavior: they only support indexing, iteration, and the
However, in 3.2+,
range is a full sequence—it supports extended slices, and all of the methods of
collections.abc.Sequence with the same semantics as a
And, at least in CPython and PyPy (the only two 3.2+ implementations that currently exist), it also has constant-time implementations of the
count methods and the
in operator (as long as you only pass it integers). This means writing
123456 in r is reasonable in 3.2+, while in 2.7 or 3.1 it would be a horrible idea.
* The fact that
issubclass(xrange, collections.Sequence) returns
True in 2.6-2.7 and 3.0-3.1 is a bug that was fixed in 3.2 and not backported.
In python 2.x
range(x) returns a list, that is created in memory with x elements.
>>> a = range(5) >>> a [0, 1, 2, 3, 4]
xrange(x) returns an xrange object which is a generator obj which generates the numbers on demand. they are computed during for-loop(Lazy Evaluation).
For looping, this is slightly faster than range() and more memory efficient.
>>> b = xrange(5) >>> b xrange(5)
When testing range against xrange in a loop (I know I should use timeit, but this was swiftly hacked up from memory using a simple list comprehension example) I found the following:
import time for x in range(1, 10): t = time.time() [v*10 for v in range(1, 10000)] print "range: %.4f" % ((time.time()-t)*100) t = time.time() [v*10 for v in xrange(1, 10000)] print "xrange: %.4f" % ((time.time()-t)*100)
$python range_tests.py range: 0.4273 xrange: 0.3733 range: 0.3881 xrange: 0.3507 range: 0.3712 xrange: 0.3565 range: 0.4031 xrange: 0.3558 range: 0.3714 xrange: 0.3520 range: 0.3834 xrange: 0.3546 range: 0.3717 xrange: 0.3511 range: 0.3745 xrange: 0.3523 range: 0.3858 xrange: 0.3997 <- garbage collection?
Or, using xrange in the for loop:
range: 0.4172 xrange: 0.3701 range: 0.3840 xrange: 0.3547 range: 0.3830 xrange: 0.3862 <- garbage collection? range: 0.4019 xrange: 0.3532 range: 0.3738 xrange: 0.3726 range: 0.3762 xrange: 0.3533 range: 0.3710 xrange: 0.3509 range: 0.3738 xrange: 0.3512 range: 0.3703 xrange: 0.3509
Is my snippet testing properly? Any comments on the slower instance of xrange? Or a better example :-)
xrange() and range() in python works similarly as for the user , but the difference comes when we are talking about how the memory is allocated in using both the function.
When we are using range() we allocate memory for all the variables it is generating, so it is not recommended to use with larger no. of variables to be generated.
xrange() on the other hand generate only a particular value at a time and can only be used with the for loop to print all the values required.
range returns a static list at runtime.
xrange returns an
object (which acts like a generator, although it's certainly not one) from which values are generated as and when required.
When to use which?
xrangeif you want to generate a list for a gigantic range, say 1 billion, especially when you have a "memory sensitive system" like a cell phone.
rangeif you want to iterate over the list several times.
PS: Python 3.x's
range function == Python 2.x's
Everyone has explained it greatly. But I wanted it to see it for myself. I use python3. So, I opened the resource monitor (in Windows!), and first, executed the following command first:
a=0 for i in range(1,100000): a=a+i
and then checked the change in 'In Use' memory. It was insignificant. Then, I ran the following code:
for i in list(range(1,100000)): a=a+i
And it took a big chunk of the memory for use, instantly. And, I was convinced. You can try it for yourself.
If you are using Python 2X, then replace 'range()' with 'xrange()' in the first code and 'list(range())' with 'range()'.
From the help docs.
>>> print range.__doc__ range(stop) -> list of integers range(start, stop[, step]) -> list of integers Return a list containing an arithmetic progression of integers. range(i, j) returns [i, i+1, i+2, ..., j-1]; start (!) defaults to 0. When step is given, it specifies the increment (or decrement). For example, range(4) returns [0, 1, 2, 3]. The end point is omitted! These are exactly the valid indices for a list of 4 elements. >>> print xrange.__doc__ xrange(stop) -> xrange object xrange(start, stop[, step]) -> xrange object Like range(), but instead of returning a list, returns an object that generates the numbers in the range on demand. For looping, this is slightly faster than range() and more memory efficient.
>>> print(range.__doc__) range(stop) -> range object range(start, stop[, step]) -> range object Return an object that produces a sequence of integers from start (inclusive) to stop (exclusive) by step. range(i, j) produces i, i+1, i+2, ..., j-1. start defaults to 0, and stop is omitted! range(4) produces 0, 1, 2, 3. These are exactly the valid indices for a list of 4 elements. When step is given, it specifies the increment (or decrement). >>> print(xrange.__doc__) Traceback (most recent call last): File "<stdin>", line 1, in <module> NameError: name 'xrange' is not defined
Difference is apparent. In Python 2.x,
range returns a list,
xrange returns an xrange object which is iterable.
In Python 3.x,
xrange of Python 2.x, and
xrange is removed.
range() in Python
This function is essentially the old
range() function that was available in Python
2.x and returns an instance of a
list object that contains the elements in the specified range.
However, this implementation is too inefficient when it comes to initialise a list with a range of numbers. For example,
for i in range(1000000) would be a very expensive command to execute, both in terms of memory and time usage as it requires the storage of this list into the memory.
3.x introduced a newer implementation of
range() (while the newer implementation was already available in Python
2.x through the
range() exploits a strategy known as lazy evaluation. Instead of creating a huge list of elements in range, the newer implementation introduces the class
range, a lightweight object that represents the required elements in the given range, without storing them explicitly in memory (this might sound like generators but the concept of lazy evaluation is different).
As an example, consider the following:
# Python 2.x >>> a = range(10) >>> type(a) <type 'list'> >>> b = xrange(10) >>> type(b) <type 'xrange'>
# Python 3.x >>> a = range(10) >>> type(a) <class 'range'>
On a requirement for scanning/printing of 0-N items , range and xrange works as follows.
range() - creates a new list in the memory and takes the whole 0 to N items(totally N+1) and prints them. xrange() - creates a iterator instance that scans through the items and keeps only the current encountered item into the memory , hence utilising same amount of memory all the time.
In case the required element is somewhat at the beginning of the list only then it saves a good amount of time and memory.
The difference decreases for smaller arguments to
$ python -m timeit "for i in xrange(10111):" " for k in range(100):" " pass" 10 loops, best of 3: 59.4 msec per loop $ python -m timeit "for i in xrange(10111):" " for k in xrange(100):" " pass" 10 loops, best of 3: 46.9 msec per loop
In this case
xrange(100) is only about 20% more efficient.
range :-range will populate everything at once.which means every number of the range will occupy the memory.
xrange :-xrange is something like generator ,it will comes into picture when you want the range of numbers but you dont want them to be stored,like when you want to use in for loop.so memory efficient.
See this post to find difference between range and xrange:
rangereturns exactly what you think: a list of consecutive integers, of a defined length beginning with 0.
xrange, however, returns an "xrange object", which acts a great deal like an iterator