After dive into Python's source code, I find out that it maintains an array of PyInt_Objects ranging from int(-5) to int(256) (@src/Objects/intobject.c)

A little experiment proves it:

>>> a = 1
>>> b = 1
>>> a is b
>>> a = 257
>>> b = 257
>>> a is b

But if I run those code together in a py file (or join them with semi-colons), the result is different:

>>> a = 257; b = 257; a is b

I'm curious why they are still the same object, so I digg deeper into the syntax tree and compiler, I came up with a calling hierarchy listed below:

    mod = PyParser_ASTFromFile() 
        node *n = PyParser_ParseFileFlagsEx() //source to cst
                ps = PyParser_New() 
                for (;;)
                    PyParser_AddToken(ps, ...)
        mod = PyAST_FromNode(n, ...)  //cst to ast
    run_mod(mod, ...)
        co = PyAST_Compile(mod, ...) //ast to CFG
            co = compiler_mod()
        PyEval_EvalCode(co, ...)

Then I added some debug code in PyInt_FromLong and before/after PyAST_FromNode, and executed a test.py:

a = 257
b = 257
print "id(a) = %d, id(b) = %d" % (id(a), id(b))

the output looks like:

DEBUG: before PyAST_FromNode
name = a
ival = 257, id = 176046536
name = b
ival = 257, id = 176046752
name = a
name = b
DEBUG: after PyAST_FromNode
PyAST_Compile ok
id(a) = 176046536, id(b) = 176046536
Eval ok

It means that during the cst to ast transform, two different PyInt_Objects are created (actually it's performed in the ast_for_atom() function), but they are later merged.

I find it hard to comprehend the source in PyAST_Compile and PyEval_EvalCode, so I'm here to ask for help, I'll be appreciative if some one gives a hint?

  • 1
    Are you just trying to understand how the Python source works, or are you trying to understand what the upshot is for code written in Python? Because the upshot for code written in Python is "this is an implementation detail, don't ever rely on it happening or not happening". – BrenBarn Mar 2 '13 at 6:53
  • I'm not going to rely on the implemention detail. I'm just curious and try to break into the source code. – felix021 Mar 2 '13 at 7:35
  • @Blckknght thanks. I've known the answer of that question, and I go further than that. – felix021 Mar 2 '13 at 7:49

Python caches integers in the range [-5, 256], so it is expected that integers in that range are also identical.

What you see is the Python compiler optimizing identical literals when part of the same text.

When typing in the Python shell each line is a completely different statement, parsed in a different moment, thus:

>>> a = 257
>>> b = 257
>>> a is b

But if you put the same code into a file:

$ echo 'a = 257
> b = 257
> print a is b' > testing.py
$ python testing.py

This happens whenever the parser has a chance to analyze where the literals are used, for example when defining a function in the interactive interpreter:

>>> def test():
...     a = 257
...     b = 257
...     print a is b
>>> dis.dis(test)
  2           0 LOAD_CONST               1 (257)
              3 STORE_FAST               0 (a)

  3           6 LOAD_CONST               1 (257)
              9 STORE_FAST               1 (b)

  4          12 LOAD_FAST                0 (a)
             15 LOAD_FAST                1 (b)
             18 COMPARE_OP               8 (is)
             21 PRINT_ITEM          
             22 PRINT_NEWLINE       
             23 LOAD_CONST               0 (None)
             26 RETURN_VALUE        
>>> test()
>>> test.func_code.co_consts
(None, 257)

Note how the compiled code contains a single constant for the 257.

In conclusion, the Python bytecode compiler is not able to perform massive optimizations (like static types languages), but it does more than you think. One of these things is to analyze usage of literals and avoid duplicating them.

Note that this does not have to do with the cache, because it works also for floats, which do not have a cache:

>>> a = 5.0
>>> b = 5.0
>>> a is b
>>> a = 5.0; b = 5.0
>>> a is b

For more complex literals, like tuples, it "doesn't work":

>>> a = (1,2)
>>> b = (1,2)
>>> a is b
>>> a = (1,2); b = (1,2)
>>> a is b

But the literals inside the tuple are shared:

>>> a = (257, 258)
>>> b = (257, 258)
>>> a[0] is b[0]
>>> a[1] is b[1]
>>> a = (257, 258); b = (257, 258)
>>> a[0] is b[0]
>>> a[1] is b[1]

Regarding why you see that two PyInt_Object are created, I'd guess that this is done to avoid literal comparison. for example, the number 257 can be expressed by multiple literals:

>>> 257
>>> 0x101
>>> 0b100000001
>>> 0o401

The parser has two choices:

  • Convert the literals to some common base before creating the integer, and see if the literals are equivalent. then create a single integer object.
  • Create the integer objects and see if they are equal. If yes, keep only a single value and assign it to all the literals, otherwise, you already have the integers to assign.

Probably the Python parser uses the second approach, which avoids rewriting the conversion code and also it's easier to extend (for example it works with floats as well).

Reading the Python/ast.c file, the function that parses all numbers is parsenumber, which calls PyOS_strtoul to obtain the integer value (for intgers) and eventually calls PyLong_FromString:

    x = (long) PyOS_strtoul((char *)s, (char **)&end, 0);
    if (x < 0 && errno == 0) {
        return PyLong_FromString((char *)s,
                                 (char **)0,

As you can see here the parser does not check whether it already found an integer with the given value and so this explains why you see that two int objects are created, and this also means that my guess was correct: the parser first creates the constants and only afterward optimizes the bytecode to use the same object for equal constants.

The code that does this check must be somewhere in Python/compile.c or Python/peephole.c, since these are the files that transform the AST into bytecode.

In particular, the compiler_add_o function seems the one that does it. There is this comment in compiler_lambda:

/* Make None the first constant, so the lambda can't have a
   docstring. */
if (compiler_add_o(c, c->u->u_consts, Py_None) < 0)
    return 0;

So it seems like compiler_add_o is used to insert constants for functions/lambdas etc. The compiler_add_o function stores the constants into a dict object, and from this immediately follows that equal constants will fall in the same slot, resulting in a single constant in the final bytecode.

  • Thanks. I know why the intepreter do this, and I've also tested strings before, which acts just the same as int and float, and I've also printed the syntax tree using compiler.parse() which shows two Const(257). I'm just wondering when and how in the source code ... What's more the test I did above shows that the intepreter already created two PyInt_Object for a and b, so there's actually little meaning merging them (apart from save memory). – felix021 Mar 2 '13 at 8:23
  • @felix021 I've updated my answer again. I found where the two ints are created and I know in which files the optimization happens, even though I still didn't find the exact line of code that handle that. – Bakuriu Mar 3 '13 at 12:47
  • Thanks very much! I carefully went over compile.c, the calling chain is compiler_visit_stmt -> VISIT(c, expr, e) -> compiler_visit_expr(c, e) -> ADDOP_O(c, LOAD_CONST, e->v.Num.n, consts) -> compiler_addop_o(c, LOAD_CONSTS, c->u->u_consts, e->v.Num.n) -> compiler_add_o(c, c->u->u_consts, e->v.Num.n). in the compoler_add_o(), python will try to if-not-find-then-set PyTuple(PyIntObject n, PyInt_Type) as key into c->u->u_consts, and while calculating the hash of that tuple, only the actual int value is used, so only one PyInt_Object will be inserted to the u_consts dict. – felix021 Mar 5 '13 at 3:20
  • I get False executing a = 5.0; b = 5.0; print (a is b) both with py2 and py3 on win7 – zhangxaochen Feb 19 '14 at 14:50
  • 1
    @zhangxaochen Did you write the two statements on the same line or on different lines in the interactive interpreter? Anyway, different versions of python can produce different behaviour. On my machine it does results in True (just rechecked now). Optimizations aren't reliable since they are just an implementation detail, so that doesn't invalidate the point I wanted to make in my answer. Also compile('a=5.0;b=5.0', '<stdin>', 'exec')).co_consts shows that there is only a 5.0 constant (in python3.3 on linux). – Bakuriu Feb 19 '14 at 17:20

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