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Inspired by this question about caching small integers and strings I discovered the following behavior which I don't understand.

>>> 1000 is 10**3
False

I thought I understood this behavior: 1000 is to big to be cached. 1000 and 10**3 point to 2 different objects. But I had it wrong:

>>> 1000 is 1000
True

So, maybe Python treats calculations differently from 'normal' integers. But that assumption is also not correct:

>>> 1 is 1**2
True

How can this behavior be explained?

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1  
This is essentially a duplicate of stackoverflow.com/q/306313/1008142 - the accepted answer points a relevant section of the Python docs. [edit: sorry, not a dupe; thanks jaapz] –  Rory Yorke Feb 19 at 12:24
    
@RoryYorke essentially, yes, but it does not explain the difference between 1 is 1**2 and 1000 is 10**3 –  jaapz Feb 19 at 12:25
2  
possible duplicate of Weird Integer Cache inside Python 2.6 –  Bakuriu Feb 19 at 12:25
3  
@RoryYorke That answer explains why 1000 * 10**3 return False. Because 1000 is to big to be cached. It doesn't explain why 1000 is 1000 returns True. 1000 is bigger than 256 and therefore shouldn't be cached. Or am I missing something? –  OrangeTux Feb 19 at 12:33

1 Answer 1

up vote 38 down vote accepted

There are two separate things going on here: Python stores int literals (and other literals) as constants with compiled bytecode and small integer objects are cached as singletons.

When you run 1000 is 1000 only one such constant is stored and reused. You are really looking at the same object:

>>> import dis
>>> compile('1000 is 1000', '<stdin>', 'eval').co_consts
(1000,)
>>> dis.dis(compile('1000 is 1000', '<stdin>', 'eval'))
  1           0 LOAD_CONST               0 (1000) 
              3 LOAD_CONST               0 (1000) 
              6 COMPARE_OP               8 (is) 
              9 RETURN_VALUE         

Here LOAD_CONST refers to the constant at index 0; you can see the stored constants in the .co_consts attribute of the bytecode object.

Compare this to the 1000 is 10 ** 3 case:

>>> compile('1000 is 10**3', '<stdin>', 'eval').co_consts
(1000, 10, 3, 1000)
>>> dis.dis(compile('1000 is 10**3', '<stdin>', 'eval'))
  1           0 LOAD_CONST               0 (1000) 
              3 LOAD_CONST               3 (1000) 
              6 COMPARE_OP               8 (is) 
              9 RETURN_VALUE         

There is a peephole optimization that pre-computes expressions on constants at compile time, and this optimization has replaced 10 ** 3 with 1000, but the optimization doesn't re-use pre-existing constants. As a result, the LOAD_CONST opcodes are loading two different integer objects, at index 0 and 3, and these are two different int objects.

Then there are optimisations in place where small integers are interned; only one copy of the 1 object is ever created during the lifetime of a Python program; this applies to all integers between -5 and 256.

Thus, for the 1 is 1**2 case, the Python internals use a singleton int() object from the internal cache. This is a CPython implementation detail.

The moral of this story is that you should never use is when you really wanted to compare by value. Use == for integers, always.

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you edited your post after i posted my comment, so that part was not in there yet –  jaapz Feb 19 at 12:36
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Stop fighting ;) I got it now. Thanks –  OrangeTux Feb 19 at 12:40
4  
I'd love to hear what is not helpful or wrong about my answer, to deserve a downvote. That way I can improve my answer! –  Martijn Pieters Feb 19 at 13:41

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