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Why does the following behave unexpectedly in Python?

>>> a = 256
>>> b = 256
>>> a is b
True           # This is an expected result
>>> a = 257
>>> b = 257
>>> a is b
False          # What happened here? Why is this False?
>>> 257 is 257
True           # Yet the literal numbers compare properly

I am using Python 2.5.2. Trying some different versions of Python, it appears that Python 2.3.3 shows the above behaviour between 99 and 100.

Based on the above, I can hypothesise that Python is internally implemented such that "small" integers are stored in a different way than larger integers, and the is operator can tell the difference. Why the leaky abstraction? What is a better way of comparing two arbitrary objects to see whether they are the same, and I don't know in advance whether they are numbers or not?

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it is unexpected, but the other way round; you expect the wrong things: it is unexpected that a is identical to be if you assigned them via a = 256; b = 256, since you assigned them both to different integer objects. I would expect them to be identical if you did e.g. a = 257; b = a or a = b = 257, and indeed, they are. – flying sheep Feb 3 '11 at 19:31
This just scares me! I am trying to find a PHP's identical "===" compare operator equivalent in python and find that even "is" has quirks. Closest solution I found is something lengthy like so "type(x) is int and x == 100" - it's either that or assert statements; Python is just a debugging nightmare waiting to happen. – Daniel Sokolowski Jun 26 '12 at 20:48
@DanielSokolowski: There's no precise Python equivalent of PHP's === operator, and that is because Python is a strongly typed language while PHP is weakly typed. In my experience, Python is much more predictable than PHP in this regard. – Greg Hewgill Jun 26 '12 at 22:16
@Greg Hewgill: that is a misconception, at best python is just a little stronger typed than PHP. In Python you can do "'1' == 1", and even more wired do "1 ==" where bar is a function. If a language was strong typed those operations would not be allowed as it involves implicit casting, implicit casting leads to gotchas. For at truly strong typed language see Haskell. Regardless I could use === in python to avoid these gotchas :) . – Daniel Sokolowski Jun 27 '12 at 15:05
@DanielSokolowski: Python does not perform any implicit casting. Although you can evaluate '1' == 1, the result is always False (because strings can never be equal to integers). – Greg Hewgill Jun 27 '12 at 19:25

10 Answers 10

up vote 187 down vote accepted

Take a look at this:

>>> a = 256
>>> b = 256
>>> id(a)
>>> id(b)
>>> a = 257
>>> b = 257
>>> id(a)
>>> id(b)

EDIT: Here's what I found in the Python documentation, 7.2.1, "Plain Integer Objects":

The current implementation keeps an array of integer objects for all integers between -5 and 256, when you create an int in that range you actually just get back a reference to the existing object. So it should be possible to change the value of 1. I suspect the behaviour of Python in this case is undefined. :-)

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The id function is the hash function that is used for dictionaries and such and doesn't have any relation to the "is" operator. The "is" operator is to detect multiple references (aliases) to the same object, not equality or hash equality. For instance for a = b = 20007, a is b should be true. The fact that it works on separate assignments to small integers is just an implementation detail. – Lara Dougan Nov 6 '09 at 2:46
Note that many languages have this quirk.(I know java does). – Roman A. Taycher Nov 11 '10 at 4:09
@Adam, that's not right. The documentation for both id and is say they're based on object identity. Neither mention any kind of hashing, value-based or otherwise. Hashing is based on the __hash__ method. – Matthew Flaschen Nov 11 '10 at 19:37
__hash__ uses id by default, but it doesn't have to. – Matthew Flaschen Nov 11 '10 at 19:46
@LaraDougan Actually, the hash function for dictionaries and such is called hash() – Christian Oudard Oct 18 '12 at 16:56

It depends on whether you're looking to see if 2 things are equal, or the same object.

"is" checks to see if they are the same object, not just equal. The small ints are probably pointing to the same memory location for space efficiency

In [29]: a = 3
In [30]: b = 3
In [31]: id(a)
Out[31]: 500729144
In [32]: id(b)
Out[32]: 500729144

You should use "==" to compare equality of arbitrary objects. You can specify the behavior with the __eq__, and __ne__ attributes.

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My goal is to compare object identity, rather than equality of value. Except for numbers, where I want to treat object identity the same as equality of value. – Greg Hewgill Nov 20 '08 at 18:47
In that case I suggest that you build a custom comparison function that checks the type of the operands and uses is or == appropriately. – David Locke Nov 20 '08 at 18:51

As you can check in source file intobject.c, Python caches small integers for efficiency. Every time you create a reference to a small integer, you are referring the cached small integer, not a new object. 257 is not an small integer, so it is calculated as a different object.

It is better to use "==" for that purpose.

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The is operator is not another way to type ==.

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That's true, but I really do want to compare object identity. – Greg Hewgill Nov 20 '08 at 18:45
How is this an answer? – kevin Apr 20 at 19:12

I think your hypotheses is correct. Experiment with id (identity of object)..

In [1]: id(255)
Out[1]: 146349024

In [2]: id(255)
Out[2]: 146349024

In [3]: id(257)
Out[3]: 146802752

In [4]: id(257)
Out[4]: 148993740

In [5]: a=255

In [6]: b=255

In [7]: c=257

In [8]: d=257

In [9]: id(a), id(b), id(c), id(d)
Out[9]: (146349024, 146349024, 146783024, 146804020)

It appears that numbers <= 255 are treated as literals and anything above is treated differently!

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Aack, posted just a moment before mine was. Good analysis though, and I think you could be correct. – Cybis Nov 20 '08 at 18:31
You forgot to test 256. By default, integer values between -5 and 256 (inclusive) are shared. – Rhymoid Dec 21 '12 at 0:32
@Rhymoid, 256 is also the same with 255 – WeizhongTu Apr 29 at 0:17

For immutable value objects, like ints, strings or datetimes, object identity is not especially useful. It's better to think about equality. Identity is essentially an implementation detail for value objects - since they're immutable, there's no effective difference between having multiple refs to the same object or multiple objects.

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Why does the following behave unexpectedly in Python?

>>> a = 256
>>> b = 256
>>> a is b
True           # This is an expected result

Why is it expected? It only means that the integers valued at 256 referenced by both a and b are the same instance of integer. Integers are immutable in Python, thus they cannot change. This should have no impact on any code. It should not be expected. It is merely an implementation detail. But perhaps we should be glad that there are not two separate instances in memory every time we state a value equals 256.

>>> a = 257
>>> b = 257
>>> a is b
False          # What happened here? Why is this False?

Looks like we now have two separate instances of integers with the value of 257 in memory. Since integers are immutable, this wastes memory. Let's hope we're not wasting a lot of it. We're probably not. But this behavior is not guaranteed.

>>> 257 is 257
True           # Yet the literal numbers compare properly

Well, this looks like your particular implementation of Python is trying to be smart and not creating redundantly valued integers in memory unless it has to. You seem to indicate you are using the referent implementation of Python, which is CPython. Good for CPython.

It might be even better if CPython could do this globally, if it could do so cheaply (as there would a cost in the lookup), perhaps another implementation might.

But as for impact on code, you should not care if an integer is a particular instance of an integer. You should only care what the value of that instance is, and you would use the normal comparison operators for that, i.e. ==.

What is does

is checks that the id of two objects are the same. In CPython, the id is the location in memory, but it could be some other uniquely identifying number in another implementation. To restate this with code:

>>> a is b

is the same as

>>> id(a) == id(b)

Why would we want to use is then?

This can be a very fast check relative to say, checking if two very long strings are equal in value. But since it applies to the uniqueness of the object, we thus have limited use-cases for it. In fact, we mostly want to use it to check for None, which is a singleton (a sole instance existing in one place in memory). We might create other singletons if there is potential to conflate them, which we might check with is, but these are relatively rare. Here's an example (will work in Python 2 and 3) e.g.

SENTINEL_SINGLETON = object() # this will only be created one time.

def foo(keyword_argument=None):
    if keyword_argument is None:
        print('no argument given to foo')

def bar(keyword_argument=SENTINEL_SINGLETON):
    # SENTINEL_SINGLETON tells us if we were not passed anything
    # as None is a legitimate potential argument we could get.
    if keyword_argument is SENTINEL_SINGLETON:
        print('no argument given to bar')
        print('argument to bar: {0}'.format(keyword_argument))


Which prints:

no argument given to foo
no argument given to bar
argument to bar: None
argument to bar: baz

And so we see, with is and a sentinel, we are able to differentiate between when bar is called with no arguments and when it is called with None. These are the primary use-cases for is - do not use it to test for equality of integers, strings, tuples, or other things like these.

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is is the identity equality operator (functioning like id(a) == id(b)); it's just that two equal numbers aren't necessarily the same object. For performance reasons some small integers happen to be memoized so they will tend to be the same (this can be done since they are immutable).

PHP's === operator, on the other hand, is described as checking equality and type: x == y and type(x) == type(y) as per Paulo Freitas' comment. This will suffice for common numbers, but differ from is for classes that define __eq__ in an absurd manner:

class Unequal:
    def __eq__(self, other):
        return False

PHP apparently allows the same thing for "built-in" classes (which I take to mean implemented at C level, not in PHP). A slightly less absurd use might be a timer object, which has a different value every time it's used as a number. Quite why you'd want to emulate Visual Basic's Now instead of showing that it is an evaluation with time.time() I don't know.

Greg Hewgill (OP) made one clarifying comment "My goal is to compare object identity, rather than equality of value. Except for numbers, where I want to treat object identity the same as equality of value."

This would have yet another answer, as we have to categorize things as numbers or not, to select whether we compare with == or is. CPython defines the number protocol, including PyNumber_Check, but this is not accessible from Python itself.

We could try to use isinstance with all the number types we know of, but this would inevitably be incomplete. The types module contains a StringTypes list but no NumberTypes. Since Python 2.6, the built in number classes have a base class numbers.Number, but it has the same problem:

import numpy, numbers
assert not issubclass(numpy.int16,numbers.Number)
assert issubclass(int,numbers.Number)

By the way, NumPy will produce separate instances of low numbers.

I don't actually know an answer to this variant of the question. I suppose one could theoretically use ctypes to call PyNumber_Check, but even that function has been debated, and it's certainly not portable. We'll just have to be less particular about what we test for now.

In the end, this issue stems from Python not originally having a type tree with predicates like Scheme's number?, or Haskell's type class Num. is checks object identity, not value equality. PHP has a colorful history as well, where === apparently behaves as is only on objects in PHP5, but not PHP4. Such are the growing pains of moving across languages (including versions of one).

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It also happens with strings:

>>> s = b = 'somestr'
>>> s == b, s is b, id(s), id(b)
(True, True, 4555519392, 4555519392)

Now everything seems fine.

>>> s = 'somestr'
>>> b = 'somestr'
>>> s == b, s is b, id(s), id(b)
(True, True, 4555519392, 4555519392)

That's expected too.

>>> s1 = b1 = 'somestrdaasd ad ad asd as dasddsg,dlfg ,;dflg, dfg a'
>>> s1 == b1, s1 is b1, id(s1), id(b1)
(True, True, 4555308080, 4555308080)

>>> s1 = 'somestrdaasd ad ad asd as dasddsg,dlfg ,;dflg, dfg a'
>>> b1 = 'somestrdaasd ad ad asd as dasddsg,dlfg ,;dflg, dfg a'
>>> s1 == b1, s1 is b1, id(s1), id(b1)
(True, False, 4555308176, 4555308272)

Now that's unexpected.

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Other similar situation:

Imagine 2 variables that keep 2 lists

a = [1,2,3]

b = [1,2,3]

These 2 objects are kept in memory at different addresses.

There are 2 possible operations of equality:

  • is to compare the addresses of memory of objects a and b and say if they are equal.

  • to compare the objects composing the lists, and to say if the lists look the same

These 2 operations have associated different operators.

The operator is cope with the first situation. The id operator is useful, because it returns a hash of the object a, which is a pointer to the object a in memory.

So the id operator is useful to see the result of the is operator.

For the second situation is useful the == operator.

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id does not return a hash. – Erik Allik Apr 17 '14 at 12:46

protected by Jon Clements May 27 '13 at 18:21

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