28

On a 64-bit system an integer in Python takes 24 bytes. This is 3 times the memory that would be needed in e.g. C for a 64-bit integer. Now, I know this is because Python integers are objects. But what is the extra memory used for? I have my guesses, but it would be nice to know for sure.

  • 3
    See this article: laurentluce.com/posts/python-integer-objects-implementation and also docs.python.org/2/c-api/structures.html for common object structures in Python – DNA Apr 11 '14 at 15:26
  • @DNA: that talks about the Python 2 basic int type; the long type in Python 2 (replacing the int type in Python 3) is a little more complicated still. – Martijn Pieters Apr 11 '14 at 15:40
  • Note that this question and its answers are specific to the CPython reference implementation. Other implementations could have entirely different memory usages (though, the same general principles apply: the size and other object metadata need to be stored). – Bob Apr 11 '14 at 22:44
37

Remember that the Python int type does not have a limited range like C int has; the only limit is the available memory.

Memory goes to storing the value, the current size of the integer storage (the storage size is variable to support arbitrary sizes), and the standard Python object bookkeeping (a reference to the relevant object and a reference count).

You can look up the longintrepr.h source (the Python 3 int type was traditionally known as the long type in Python 2); it makes effective use of the PyVarObject C type to track integer size:

struct _longobject {
        PyObject_VAR_HEAD
        digit ob_digit[1];
};

The ob_digit array stores 'digits' of either 15 or 30 bits wide (depending on your platform); so on my 64-bit OS X system, an integer up to (2 ^ 30) - 1 uses 1 'digit':

>>> sys.getsizeof((1 << 30) - 1)
28

but if you use 2 30-bit digits in the number an additional 4 bytes are needed, etc:

>>> sys.getsizeof(1 << 30)
32
>>> sys.getsizeof(1 << 60)
36
>>> sys.getsizeof(1 << 90)
40

The base 24 bytes then are the PyObject_VAR_HEAD structure, holding the object size, the reference count and the type pointer (each 8 bytes / 64 bits on my 64-bit OS X platform).

On Python 2, integers <= sys.maxint but >= -sys.maxint - 1 are stored using a simpler structure storing just the single value:

typedef struct {
    PyObject_HEAD
    long ob_ival;
} PyIntObject;

because this uses PyObject instead of PyVarObject there is no ob_size field in the struct and the memory size is limited to just 24 bytes; 8 for the long value, 8 for the reference count and 8 for the type object pointer.

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  • How are negative values handled, if an int is given as an sequence of digits? Is there a concept of twos complement in python? If I print hex(-1) I get -0x1 or similarly if I print bin(-1) I get -0b1 I understand that this may not be what is represented internally however how does python make the decision that it is a negative value if the high bit is not set? – Har Oct 8 '16 at 12:02
  • 1
    @Har: the object size is set to a negative value. see the linked header file: Negative numbers are represented with ob_size < 0;. So an integer representation that requires 2 ob_digits entries, then ob_size is either 2 or -2, the latter signalling it is a negative integer. – Martijn Pieters Oct 8 '16 at 13:21
  • so that means that it is not a twos complement it is simply a bit in the structure which represents whether it is negative or not? – Har Oct 8 '16 at 15:18
  • 1
    @Har: exactly; the internal representation does not use 2s complement. – Martijn Pieters Oct 8 '16 at 15:21
  • What happens with the remaining 1 or 2 bits in each 'digit'? (Since 16 or 32 bits are used to store digits of only 15 or 30 bits) – PieterNuyts Mar 27 '19 at 8:44
4

From longintrepr.h, we see that a Python 'int' object is defined with this C structure:

struct _longobject {
        PyObject_VAR_HEAD
        digit ob_digit[1];
};

Digit is a 32-bit unsigned value. The bulk of the space is taken by the variable size object header. From object.h, we can find its definition:

typedef struct {
    PyObject ob_base;
    Py_ssize_t ob_size; /* Number of items in variable part */
} PyVarObject;

typedef struct _object {
    _PyObject_HEAD_EXTRA
    Py_ssize_t ob_refcnt;
    struct _typeobject *ob_type;
} PyObject;

We can see that we are using a Py_ssize_t, 64-bits assuming 64-bit system, to store the count of "digits" in the value. This is possibly wasteful. We can also see that the general object header has a 64-bit reference count, and a pointer to the object type, which will also be a 64-bits of storage. The reference count is necessary for Python to know when to deallocate the object, and the pointer to the object type is necessary to know that we have an int and not, say, a string, as C structures have no way to test the type of an object from an arbitrary pointer.

_PyObject_HEAD_EXTRA is defined to nothing on most builds of python, but can be used to store a linked list of all Python objects on the heap if the build enables that option, using another two pointers of 64-bits each.

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