It is my understanding that the
range() function, which is actually an object type in Python 3, generates its contents on the fly, similar to a generator.
This being the case, I would have expected the following line to take an inordinate amount of time because, in order to determine whether 1 quadrillion is in the range, a quadrillion values would have to be generated:
1_000_000_000_000_000 in range(1_000_000_000_000_001)
Furthermore: it seems that no matter how many zeroes I add on, the calculation more or less takes the same amount of time (basically instantaneous).
I have also tried things like this, but the calculation is still almost instant:
# count by tens 1_000_000_000_000_000_000_000 in range(0,1_000_000_000_000_000_000_001,10)
If I try to implement my own range function, the result is not so nice!
def my_crappy_range(N): i = 0 while i < N: yield i i += 1 return
What is the
range() object doing under the hood that makes it so fast?
Martijn Pieters's answer was chosen for its completeness, but also see abarnert's first answer for a good discussion of what it means for
range to be a full-fledged sequence in Python 3, and some information/warning regarding potential inconsistency for
__contains__ function optimization across Python implementations. abarnert's other answer goes into some more detail and provides links for those interested in the history behind the optimization in Python 3 (and lack of optimization of
xrange in Python 2). Answers by poke and by wim provide the relevant C source code and explanations for those who are interested.
longtype, with other object types it will go crazy. Try with:
100000000000000.0 in range(1000000000000001)
xrangethe same as Python3
xrange()objects have no
__contains__method, so the item check has to loop through all the items. Plus there are few other changes in
range(), like it supports slicing(which again returns a
rangeobject) and now also has
indexmethods to make it compatible with
range.__contains__method implemented in pure Python