The storage is "unboxed", but every time you access an element Python has to "box" it (embed it in a regular Python object) in order to do anything with it. For example, your
sum(A) iterates over the array, and boxes each integer, one at a time, in a regular Python
int object. That costs time. In your
sum(L), all the boxing was done at the time the list was created.
So, in the end, an array is generally slower, but requires substantially less memory.
Here's the relevant code from a recent version of Python 3, but the same basic ideas apply to all CPython implementations since Python was first released.
Here's the code to access a list item:
PyList_GetItem(PyObject *op, Py_ssize_t i)
/* error checking omitted */
return ((PyListObject *)op) -> ob_item[i];
There's very little to it:
somelist[i] just returns the
i'th object in the list (and all Python objects in CPython are pointers to a struct whose initial segment conforms to the layout of a
And here's the
__getitem__ implementation for an
array with type code
static PyObject *
l_getitem(arrayobject *ap, Py_ssize_t i)
return PyLong_FromLong(((long *)ap->ob_item)[i]);
The raw memory is treated as a vector of platform-native
long integers; the
C long is read up; and then
PyLong_FromLong() is called to wrap ("box") the native
C long in a Python
long object (which, in Python 3, which eliminates Python 2's distinction between
long, is actually shown as type
This boxing has to allocate new memory for a Python
int object, and spray the native
C long's bits into it. In the context of the original example, this object's lifetime is very brief (just long enough for
sum() to add the contents into a running total), and then more time is required to deallocate the new
This is where the speed difference comes from, always has come from, and always will come from in the CPython implementation.