# How many bytes per element are there in a Python list (tuple)?

For example, how much memory is required to store a list of one million (32-bit) integers?

``````alist = range(1000000) # or list(range(1000000)) in Python 3.0
``````
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"It depends." Python allocates space for lists in such a way as to achieve amortized constant time for appending elements to the list.

In practice, what this means with the current implementation is... the list always has space allocated for a power-of-two number of elements. So range(1000000) will actually allocate a list big enough to hold 2^20 elements (~ 1.045 million).

This is only the space required to store the list structure itself (which is an array of pointers to the Python objects for each element). A 32-bit system will require 4 bytes per element, a 64-bit system will use 8 bytes per element.

Furthermore, you need space to store the actual elements. This varies widely. For small integers (-5 to 256 currently), no additional space is needed, but for larger numbers Python allocates a new object for each integer, which takes 10-100 bytes and tends to fragment memory.

Bottom line: it's complicated and Python lists are not a good way to store large homogeneous data structures. For that, use the `array` module or, if you need to do vectorized math, use NumPy.

PS- Tuples, unlike lists, are not designed to have elements progressively appended to them. I don't know how the allocator works, but don't even think about using it for large data structures :-)

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Tuples aren't just not designed to be appended to, they can't be appended to. The closest analog involves creating a new tuple entirely (and then possibly destroying the old one) which is very inefficient. –  Thomas Wouters Sep 25 '08 at 20:15
Yes indeed. I guess what I was getting is... not only does Python not allow appending to tuples, but internally the memory for them is not managed in such a way as to make this efficient. –  Dan Sep 25 '08 at 20:18
Nitpick: Its not a power-of-two growth factor. It over-allocates by size/8, plus 6 (or 3 if <=8 items) Its proportional to size, so will still give amortized constant appending, but only uses ~12.5% extra space. See listobject.c for the implementation. –  Brian Sep 25 '08 at 22:11

How to get memory size/usage of python object

Memory sizes of python objects?

However they don't give a definitive answer. The way to go:

1. Measure memory consumed by Python interpreter with/without the list (use OS tools).

2. Use a third-party extension module which defines some sort of sizeof(PyObject).

Update:

Recipe 546530: Size of Python objects (revised)

``````import asizeof

N = 1000000
print asizeof.asizeof(range(N)) / N
# -> 20 (python 2.5, WinXP, 32-bit Linux)
# -> 33 (64-bit Linux)
``````
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Can I use sys.getsizeof() to get the size of a list? –  Alcott Sep 11 '11 at 23:50
@Alcott: Module `asizeof` uses `sys.getsizeof` when it is available and applicable. –  J.F. Sebastian Sep 12 '11 at 9:10
well, asizeof is a 3rd party stuff, right? –  Alcott Sep 12 '11 at 9:25

Addressing "tuple" part of the question

Declaration of CPython's PyTuple in a typical build configuration boils down to this:

``````struct PyTuple {
size_t refcount; // tuple's reference count
typeobject *type; // tuple type object
size_t n_items; // number of items in tuple
PyObject *items[1]; // contains space for n_items elements
};
``````

Size of PyTuple instance is fixed during it's construction and cannot be changed afterwards. The number of bytes occupied by PyTuple can be calculated as

`sizeof(size_t) x 2 + sizeof(void*) x (n_items + 1)`.

This gives shallow size of tuple. To get full size you also need to add total number of bytes consumed by object graph rooted in `PyTuple::items[]` array.

It's worth noting that tuple construction routines make sure that only single instance of empty tuple is ever created (singleton).

References: Python.h, object.h, tupleobject.h, tupleobject.c

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It is not that simple e.g., `() 32`, `(1,) 48`, `(1, 2) 72`, `(1, 2, 3) 88` -- sizes including items sizes (`16` for integers). –  J.F. Sebastian Sep 26 '08 at 15:17
Added "shallow vs full size" note. –  Constantin Sep 26 '08 at 20:02

A new function, `getsizeof()`, takes a Python object and returns the amount of memory used by the object, measured in bytes. Built-in objects return correct results; third-party extensions may not, but can define a `__sizeof__()` method to return the object’s size.

``````kveretennicov@nosignal:~/py/r26rc2\$ ./python
Python 2.6rc2 (r26rc2:66712, Sep  2 2008, 13:11:55)
[GCC 4.2.3 (Ubuntu 4.2.3-2ubuntu7)] on linux2
>>> import sys
>>> sys.getsizeof(range(1000000))
4000032
>>> sys.getsizeof(tuple(range(1000000)))
4000024
``````

Obviously returned numbers don't include memory consumed by contained objects (sys.getsizeof(1) == 12).

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Module `asizeof` uses `sys.getsizeof` when it is available and applicable. See my answer. –  J.F. Sebastian Oct 3 '08 at 1:26

This is implementation specific, I'm pretty sure. Certainly it depends on the internal representation of integers - you can't assume they'll be stored as 32-bit since Python gives you arbitrarily large integers so perhaps small ints are stored more compactly.

On my Python (2.5.1 on Fedora 9 on core 2 duo) the VmSize before allocation is 6896kB, after is 22684kB. After one more million element assignment, VmSize goes to 38340kB. This very grossly indicates around 16000kB for 1000000 integers, which is around 16 bytes per integer. That suggests a lot of overhead for the list. I'd take these numbers with a large pinch of salt.

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I'm wary of why you're asking. Are you trying to figure out how much memory you'll need for a given implementation? Say, you're going to read 10,000,000 widgets and want to know how much RAM it will suck?

If that's the case, rather than trying to figure out how much RAM each widget takes, figure out how much RAM, say, 10,000 widgets takes and multiply up to get your actual size.

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The main application is back-of-the-envelope calculations to have a general feeling when and where Python is the right tool for a job. –  J.F. Sebastian Oct 3 '08 at 1:39