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:

1000000000000000 in range(1000000000000001)

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:

1000000000000000000000 in range(0,1000000000000000000001,10) # count by tens

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

What is the range() object doing under the hood that makes it so fast?

Martijn Pieters' 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.

  • 204
    Don't try this with xrange() in Python 2 though. – Ashwini Chaudhary May 6 '15 at 15:37
  • 59
    Note that this is the case only if the item we are checking is a bool or long type, with other object types it will go crazy. Try with: 100000000000000.0 in range(1000000000000001) – Ashwini Chaudhary May 6 '15 at 15:44
  • 5
    Who told you that range is a generator? – abarnert May 6 '15 at 15:58
  • 5
    @abarnert I think the edit I made left the confusion intact. – Rick Teachey May 6 '15 at 16:06
  • 19
    @Superbest 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 range object) and now also has count and index methods to make it compatible with collections.Sequence ABC. – Ashwini Chaudhary May 6 '15 at 21:42

The Python 3 range() object doesn't produce numbers immediately; it is a smart sequence object that produces numbers on demand. All it contains is your start, stop and step values, then as you iterate over the object the next integer is calculated each iteration.

The object also implements the object.__contains__ hook, and calculates if your number is part of its range. Calculating is a O(1) constant time operation. There is never a need to scan through all possible integers in the range.

From the range() object documentation:

The advantage of the range type over a regular list or tuple is that a range object will always take the same (small) amount of memory, no matter the size of the range it represents (as it only stores the start, stop and step values, calculating individual items and subranges as needed).

So at a minimum, your range() object would do:

class my_range(object):
    def __init__(self, start, stop=None, step=1):
        if stop is None:
            start, stop = 0, start
        self.start, self.stop, self.step = start, stop, step
        if step < 0:
            lo, hi = stop, start
            lo, hi = start, stop
        self.length = ((hi - lo - 1) // abs(step)) + 1

    def __iter__(self):
        current = self.start
        if self.step < 0:
            while current > self.stop:
                yield current
                current += self.step
            while current < self.stop:
                yield current
                current += self.step

    def __len__(self):
        return self.length

    def __getitem__(self, i):
        if i < 0:
            i += self.length
        if 0 <= i < self.length:
            return self.start + i * self.step
        raise IndexError('Index out of range: {}'.format(i))

    def __contains__(self, num):
        if self.step < 0:
            if not (self.stop < num <= self.start):
                return False
            if not (self.start <= num < self.stop):
                return False
        return (num - self.start) % self.step == 0

This is still missing several things that a real range() supports (such as the .index() or .count() methods, hashing, equality testing, or slicing), but should give you an idea.

I also simplified the __contains__ implementation to only focus on integer tests; if you give a real range() object a non-integer value (including subclasses of int), a slow scan is initiated to see if there is a match, just as if you use a containment test against a list of all the contained values. This was done to continue to support other numeric types that just happen to support equality testing with integers but are not expected to support integer arithmetic as well. See the original Python issue that implemented the containment test.

  • 93
    Ok, so, a calculation of range(1000000000)[index_number] for example, might be something like: return start + step * index_number? – Rick Teachey May 6 '15 at 15:39
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    @RickTeachey: yup. There is no need to produce any intermediary number if you can just calculate it. – Martijn Pieters May 6 '15 at 15:40
  • 7
    @Veedrac: I didn't want to make the sentence more laborious and go into the details of iterators vs iterables. I'll see if I can retool it a little. – Martijn Pieters May 6 '15 at 15:51
  • 23
    Fun fact: because you have a working implementation of __getitem__ and __len__, the __iter__ implementation is actually unnecessary. – Lucretiel May 6 '15 at 20:55
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    @stefan.schwetschke: right, when the patch was originally written, ranges only supported start and stop values up to sys.maxsize, so there was an upper bound. Compared to len(range_object), the number comparisons / modulus is near enough constant to not matter for the analysis here. – Martijn Pieters May 7 '15 at 9:09

The fundamental misunderstanding here is in thinking that range is a generator. It's not. In fact, it's not any kind of iterator.

You can tell this pretty easily:

>>> a = range(5)
>>> print(list(a))
[0, 1, 2, 3, 4]
>>> print(list(a))
[0, 1, 2, 3, 4]

If it were a generator, iterating it once would exhaust it:

>>> b = my_crappy_range(5)
>>> print(list(b))
[0, 1, 2, 3, 4]
>>> print(list(b))

What range actually is, is a sequence, just like a list. You can even test this:

>>> import collections.abc
>>> isinstance(a, collections.abc.Sequence)

This means it has to follow all the rules of being a sequence:

>>> a[3]         # indexable
>>> len(a)       # sized
>>> 3 in a       # membership
>>> reversed(a)  # reversible
<range_iterator at 0x101cd2360>
>>> a.index(3)   # implements 'index'
>>> a.count(3)   # implements 'count'

The difference between a range and a list is that a range is a lazy or dynamic sequence; it doesn't remember all of its values, it just remembers its start, stop, and step, and creates the values on demand on __getitem__.

(As a side note, if you print(iter(a)), you'll notice that range uses the same listiterator type as list. How does that work? A listiterator doesn't use anything special about list except for the fact that it provides a C implementation of __getitem__, so it works fine for range too.)

Now, there's nothing that says that Sequence.__contains__ has to be constant time—in fact, for obvious examples of sequences like list, it isn't. But there's nothing that says it can't be. And it's easier to implement range.__contains__ to just check it mathematically ((val - start) % step, but with some extra complexity to deal with negative steps) than to actually generate and test all the values, so why shouldn't it do it the better way?

But there doesn't seem to be anything in the language that guarantees this will happen. As Ashwini Chaudhari points out, if you give it a non-integral value, instead of converting to integer and doing the mathematical test, it will fall back to iterating all the values and comparing them one by one. And just because CPython 3.2+ and PyPy 3.x versions happen to contain this optimization, and it's an obvious good idea and easy to do, there's no reason that IronPython or NewKickAssPython 3.x couldn't leave it out. (And in fact CPython 3.0-3.1 didn't include it.)

If range actually were a generator, like my_crappy_range, then it wouldn't make sense to test __contains__ this way, or at least the way it makes sense wouldn't be obvious. If you'd already iterated the first 3 values, is 1 still in the generator? Should testing for 1 cause it to iterate and consume all the values up to 1 (or up to the first value >= 1)?

  • 6
    This is a pretty important thing to get straight. I suppose the differences between Python 2 and 3 may have lead to my confusion on this point. In any case, I should have realized since range is listed (along with list and tuple) as a sequence type. – Rick Teachey May 6 '15 at 16:05
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    @RickTeachey: Actually, in 2.6+ (I think; maybe 2.5+), xrange is a sequence too. See 2.7 docs. In fact, it was always an almost-sequence. – abarnert May 6 '15 at 16:17
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    @RickTeachey: Actually, I was wrong; in 2.6-2.7 (and 3.0-3.1), it claims to be a sequence, but it's still just an almost-sequence. See my other answer. – abarnert May 6 '15 at 22:03
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    It's not an iterator, it's a sequence (Iterable in terms of Java, IEnumerable of C#) - something with an .__iter__() method that will return an iterator. It in its turn can be used only once. – Smit Johnth Jun 18 '16 at 19:40
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    @ThomasAhle: Because range isn't checking types when it's not an integer, since it's always possible a type has a __eq__ that is compatible with int. Sure, str obviously won't work, but they didn't want to slow things down by explicitly checking all the types that can't be in there (and after all, a str subclass could override __eq__ and be contained in the range). – ShadowRanger Oct 17 '16 at 12:47

Use the source, Luke!

In CPython, range(...).__contains__ (a method wrapper) will eventually delegate to a simple calculation which checks if the value can possibly be in the range. The reason for the speed here is we're using mathematical reasoning about the bounds, rather than a direct iteration of the range object. To explain the logic used:

  1. Check that the number is between start and stop, and
  2. Check that the stride value doesn't "step over" our number.

For example, 994 is in range(4, 1000, 2) because:

  1. 4 <= 994 < 1000, and
  2. (994 - 4) % 2 == 0.

The full C code is included below, which is a bit more verbose because of memory management and reference counting details, but the basic idea is there:

static int
range_contains_long(rangeobject *r, PyObject *ob)
    int cmp1, cmp2, cmp3;
    PyObject *tmp1 = NULL;
    PyObject *tmp2 = NULL;
    PyObject *zero = NULL;
    int result = -1;

    zero = PyLong_FromLong(0);
    if (zero == NULL) /* MemoryError in int(0) */
        goto end;

    /* Check if the value can possibly be in the range. */

    cmp1 = PyObject_RichCompareBool(r->step, zero, Py_GT);
    if (cmp1 == -1)
        goto end;
    if (cmp1 == 1) { /* positive steps: start <= ob < stop */
        cmp2 = PyObject_RichCompareBool(r->start, ob, Py_LE);
        cmp3 = PyObject_RichCompareBool(ob, r->stop, Py_LT);
    else { /* negative steps: stop < ob <= start */
        cmp2 = PyObject_RichCompareBool(ob, r->start, Py_LE);
        cmp3 = PyObject_RichCompareBool(r->stop, ob, Py_LT);

    if (cmp2 == -1 || cmp3 == -1) /* TypeError */
        goto end;
    if (cmp2 == 0 || cmp3 == 0) { /* ob outside of range */
        result = 0;
        goto end;

    /* Check that the stride does not invalidate ob's membership. */
    tmp1 = PyNumber_Subtract(ob, r->start);
    if (tmp1 == NULL)
        goto end;
    tmp2 = PyNumber_Remainder(tmp1, r->step);
    if (tmp2 == NULL)
        goto end;
    /* result = ((int(ob) - start) % step) == 0 */
    result = PyObject_RichCompareBool(tmp2, zero, Py_EQ);
    return result;

static int
range_contains(rangeobject *r, PyObject *ob)
    if (PyLong_CheckExact(ob) || PyBool_Check(ob))
        return range_contains_long(r, ob);

    return (int)_PySequence_IterSearch((PyObject*)r, ob,

The "meat" of the idea is mentioned in the line:

/* result = ((int(ob) - start) % step) == 0 */ 

As a final note - look at the range_contains function at the bottom of the code snippet. If the exact type check fails then we don't use the clever algorithm described, instead falling back to a dumb iteration search of the range using _PySequence_IterSearch! You can check this behaviour in the interpreter (I'm using v3.5.0 here):

>>> x, r = 1000000000000000, range(1000000000000001)
>>> class MyInt(int):
...     pass
>>> x_ = MyInt(x)
>>> x in r  # calculates immediately :) 
>>> x_ in r  # iterates for ages.. :( 
^\Quit (core dumped)
  • 2
    @brian_o Would be better implemented with a try: finally: and a return instead of goto... – wizzwizz4 Apr 4 '18 at 8:34
  • 22
    @wizzwizz4 Since when does C support try/finally? (Except some vendor-specific extensions...) – ace Aug 10 '18 at 7:20

To add to Martijn’s answer, this is the relevant part of the source (in C, as the range object is written in native code):

static int
range_contains(rangeobject *r, PyObject *ob)
    if (PyLong_CheckExact(ob) || PyBool_Check(ob))
        return range_contains_long(r, ob);

    return (int)_PySequence_IterSearch((PyObject*)r, ob,

So for PyLong objects (which is int in Python 3), it will use the range_contains_long function to determine the result. And that function essentially checks if ob is in the specified range (although it looks a bit more complex in C).

If it’s not an int object, it falls back to iterating until it finds the value (or not).

The whole logic could be translated to pseudo-Python like this:

def range_contains (rangeObj, obj):
    if isinstance(obj, int):
        return range_contains_long(rangeObj, obj)

    # default logic by iterating
    return any(obj == x for x in rangeObj)

def range_contains_long (r, num):
    if r.step > 0:
        # positive step: r.start <= num < r.stop
        cmp2 = r.start <= num
        cmp3 = num < r.stop
        # negative step: r.start >= num > r.stop
        cmp2 = num <= r.start
        cmp3 = r.stop < num

    # outside of the range boundaries
    if not cmp2 or not cmp3:
        return False

    # num must be on a valid step inside the boundaries
    return (num - r.start) % r.step == 0
  • 10
    @ChrisWesseling: I think this is different-enough information (and enough of it) that editing Martijn's answer wouldn't have been appropriate here. It's a judgment call, but people usually err on the side of not making drastic changes to other people's answers. – abarnert May 11 '15 at 19:23

If you're wondering why this optimization was added to range.__contains__, and why it wasn't added to xrange.__contains__ in 2.7:

First, as Ashwini Chaudhary discovered, issue 1766304 was opened explicitly to optimize [x]range.__contains__. A patch for this was accepted and checked in for 3.2, but not backported to 2.7 because "xrange has behaved like this for such a long time that I don't see what it buys us to commit the patch this late." (2.7 was nearly out at that point.)


Originally, xrange was a not-quite-sequence object. As the 3.1 docs say:

Range objects have very little behavior: they only support indexing, iteration, and the len function.

This wasn't quite true; an xrange object actually supported a few other things that come automatically with indexing and len,* including __contains__ (via linear search). But nobody thought it was worth making them full sequences at the time.

Then, as part of implementing the Abstract Base Classes PEP, it was important to figure out which builtin types should be marked as implementing which ABCs, and xrange/range claimed to implement collections.Sequence, even though it still only handled the same "very little behavior". Nobody noticed that problem until issue 9213. The patch for that issue not only added index and count to 3.2's range, it also re-worked the optimized __contains__ (which shares the same math with index, and is directly used by count).** This change went in for 3.2 as well, and was not backported to 2.x, because "it's a bugfix that adds new methods". (At this point, 2.7 was already past rc status.)

So, there were two chances to get this optimization backported to 2.7, but they were both rejected.

* In fact, you even get iteration for free with len and indexing, but in 2.3 xrange objects got a custom iterator. Which they then lost in 3.x, which uses the same listiterator type as list.

** The first version actually reimplemented it, and got the details wrong—e.g., it would give you MyIntSubclass(2) in range(5) == False. But Daniel Stutzbach's updated version of the patch restored most of the previous code, including the fallback to the generic, slow _PySequence_IterSearch that pre-3.2 range.__contains__ was implicitly using when the optimization doesn't apply.

  • 4
    From the comments here: improve xrange.__contains__, it looks like they didn't backport it to Python 2 just to leave an element of surprise for users and it was too late o_O. The count and index patch was added later on. File at that time: hg.python.org/cpython/file/d599a3f2e72d/Objects/rangeobject.c – Ashwini Chaudhary May 6 '15 at 22:11
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    I have a sinister suspicion that some core python devs are partial to "tough love" for python 2.x because they want to encourage people to switch to the far-superior python3 :) – wim May 7 '15 at 2:08
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    Also I bet it's a huge burden to have to add new features to old versions. Imagine if you went to Oracle and said, "Look, I'm on Java 1.4 and I deserve lambda expressions! Backport them for nothing." – Robert Grant May 11 '15 at 11:34
  • 2
    @RickTeachey yeah it's just an example. If I said 1.7 it would still apply. It's a quantitative difference not qualitative. Basically the (unpaid) devs can't forever make cool new stuff in 3.x and backport it to 2.x for those who don't want to upgrade. It's a huge and ridiculous burden. Do you think there's still something wrong with my reasoning? – Robert Grant May 12 '15 at 13:41
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    @RickTeachey: 2.7 was between 3.1 and 3.2, not around 3.3. And that means 2.7 was in rc when the last changes to 3.2 went in, which makes the bug comments easier to understand. Anyway, I think they made a few mistakes in retrospect (especially assuming people would migrate via 2to3 instead of via dual-version code with the help of libraries like six, which is why we got things like dict.viewkeys that nobody's ever going to use), and there were a few changes that just came too late in 3.2, but for the most part 2.7 was a pretty impressive "last 2.x ever" release. – abarnert May 16 '15 at 9:03

The other answers explained it well already, but I'd like to offer another experiment illustrating the nature of range objects:

>>> r = range(5)
>>> for i in r:
        print(i, 2 in r, list(r))

0 True [0, 1, 2, 3, 4]
1 True [0, 1, 2, 3, 4]
2 True [0, 1, 2, 3, 4]
3 True [0, 1, 2, 3, 4]
4 True [0, 1, 2, 3, 4]

As you can see, a range object is an object that remembers its range and can be used many times (even while iterating over it), not just a one-time generator.

  • 5
    I wouldn't play up the similarity to slice objects too much; it seems to confuse more people than it helps. (Once someone realizes that, they start wondering why there are two different types in the first place, and it takes a bit to explain it to them. And then some of them go and design other languages like Swift without ever figuring it out, and we get all kinds of annoying problems that they hack back and forth for 5 betas before they finally come up with a reasonable design…) – abarnert May 6 '15 at 21:09
  • @abarnert Do you think I should delete that part? I never explicitly create slice objects anyway. I just added it because they're similar and at least to me, it feels more intuitive that slice objects are "static", as the data isn't coming from them but from the sequence they're used on. – Stefan Pochmann May 6 '15 at 21:44
  • I think your intuition definitely helps make it clearer… but I don't know if you can work that into the answer. Maybe by explicitly calling the indices method? But at that point maybe it's getting too far off the main point? – abarnert May 6 '15 at 21:59
  • @abarnert Nah, since I never explicitly used slice objects, I didn't even know the indices method and I don't feel like thinking about it now. I'll just remove that part from the answer. – Stefan Pochmann May 6 '15 at 22:22

It's all about a lazy approach to the evaluation and some extra optimization of range. Values in ranges don't need to be computed until real use, or even further due to extra optimization.

By the way, your integer is not such big, consider sys.maxsize

sys.maxsize in range(sys.maxsize) is pretty fast

due to optimization - it's easy to compare given integer just with min and max of range.


float(sys.maxsize) in range(sys.maxsize) is pretty slow.

(in this case, there is no optimization in range, so if python receives unexpected float, python will compare all numbers)

You should be aware of an implementation detail but should not be relied upon, because this may change in the future.


Here is implementation in C#. You can see how Contains works in O(1) time.

public struct Range
    private readonly int _start;
    private readonly int _stop;
    private readonly int _step;

    // other members omitted for brevity

    public bool Contains(int number)
        // precheck - if the number is not in a valid step point, return false
        // for example, if start=5, step=10, stop=1000, it is obvious that 163 is not in this range (due to remainder)

        if ((_start % _step + _step) % _step != (number % _step + _step) % _step)
            return false;

        // with the help of step sign, we can check borders in linear manner
        int s = Math.Sign(_step);

        // no need if/else to handle both cases - negative and positive step    
        return number * s >= _start * s && number * s < _stop * s;


The object returned by range() is actually a range object. This object implements the iterator interface so you can iterate through its values sequentially, just like a generator, but it also implements the __contains__ interface which is actually what gets called when an object appears on the right hand side of the in operator. The __contains__() method returns a bool of whether or not the item is in the object. Since range objects know their bounds and stride, this is very easy to implement in O(1).

protected by cs95 Oct 1 '17 at 10:44

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