While this question doesn't have any real use in practise, I am curious as to how Python does string interning. I have noticed the following.

>> "string" is "string"
>> True

This is as I expected.

You can also do this.

>> "strin"+"g" is "string"
>> True

And that's pretty clever!

But you can't do this.

>> s1 = "strin"
>> s2 = "string"
>> s1+"g" is s2
>> False

Why wouldn't Python evaluate s1+"g", realise it is the same as s1 and point it to the same address? What is actually going on in that last block to have it return False?

up vote 67 down vote accepted

This is implementation-specific, but your interpreter is probably interning compile-time constants but not the results of run-time expressions.

In what follows I use CPython 2.7.3.

In the second example, the expression "strin"+"g" is evaluated at compile time, and is replaced with "string". This makes the first two examples behave the same.

If we examine the bytecodes, we'll see that they are exactly the same:

  # s1 = "string"
  2           0 LOAD_CONST               1 ('string')
              3 STORE_FAST               0 (s1)

  # s2 = "strin" + "g"
  3           6 LOAD_CONST               4 ('string')
              9 STORE_FAST               1 (s2)

The third example involves a run-time concatenation, the result of which is not automatically interned:

  # s3a = "strin"
  # s3 = s3a + "g"
  4          12 LOAD_CONST               2 ('strin')
             15 STORE_FAST               2 (s3a)

  5          18 LOAD_FAST                2 (s3a)
             21 LOAD_CONST               3 ('g')
             24 BINARY_ADD          
             25 STORE_FAST               3 (s3)
             28 LOAD_CONST               0 (None)
             31 RETURN_VALUE        

If you were to manually intern() the result of the third expression, you'd get the same object as before:

>>> s3a = "strin"
>>> s3 = s3a + "g"
>>> s3 is "string"
False
>>> intern(s3) is "string"
True
  • 16
    How did you get this sexy output? – Serdalis Mar 21 '13 at 7:19
  • 16
    @Serdalis: docs.python.org/2/library/dis.html – NPE Mar 21 '13 at 7:22
  • 13
    And for the record: Python's peep-hole optimisation will pre-calculate arithmetic operations on constants ("string1" + "s2", 10 + 3*20, etc.) at compile time, but limits resulting sequences to just 20 elements (to prevent [None] * 10**1000 from overly expanding your bytecode). It is this optimisation that collapsed "strin" + "g" into "string"; the result is shorter than 20 characters. – Martijn Pieters Jul 10 '13 at 9:12
  • 10
    And to make it doubly clear: there is not interning going on here at all. Immutable literals are instead stored as constants with the bytecode. Interning does take place for names used in code, but not for string values created by the program unless specifically interned by the intern() function. – Martijn Pieters Feb 12 '14 at 11:23
  • 1
    For those, who tries to find intern function in Python 3 - it is moved to sys.intern – Timofey Chernousov Jul 21 '17 at 8:55

Case 1

>>> x = "123"  
>>> y = "123"  
>>> x == y  
True  
>>> x is y  
True  
>>> id(x)  
50986112  
>>> id(y)  
50986112  

Case 2

>>> x = "12"
>>> y = "123"
>>> x = x + "3"
>>> x is y
False
>>> x == y
True

Now, your question is why the id is same in case 1 and not in case 2.
In case 1, you have assigned a string literal "123" to x and y.

Since string are immutable, it makes sense for the interpreter to store the string literal only once and point all the variables to the same object.
Hence you see the id as identical.

In case 2, you are modifying x using concatenation. Both x and y has same values, but not same identity.
Both points to different objects in memory. Hence they have different id and is operator returned False

  • How come, since strings are immutable, assigning x+"3" (and looking for a new spot to store the string) doesn't assign to the same reference as y? – Andrea Aug 9 '16 at 21:14
  • Because then it needs to compare the new string with all existing strings; potentially a very expensive operation. It could do this in the background after assignment I suppose, to reduce memory, but then you would end up with even stranger behaviour: id(x) != id(x) for instance, because the string was moved in the process of evaluation. – DylanYoung Sep 23 '17 at 19:55
  • @AndreaConte because strings' concatenation doesn't do the extra job of looking up into the pool of all the used strings each time it generates a new one. On the other hand, interpreter "optimizes" the expression x = "12" + "3" into x = "123" (concatenation of two string literals in a single expression) so the assignment actually does the lookup and finds the same "internal" string as for y = "123". – derenio Sep 25 '17 at 8:38
  • Actually, it isn't that assignment does the lookup rather than every string literal from the source code gets "internalized" and that object gets reused in all the other places. – derenio Sep 25 '17 at 8:42

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