146

Is it a linked list, an array? I searched around and only found people guessing. My C knowledge isn't good enough to look at the source code.

  • 3
    "google("python list implementation") ... The second hit even has a diagram." @JohnMachin but this IS the second hit – tail_recursion Feb 20 '18 at 9:10
45

It's a dynamic array. Practical proof: Indexing takes (of course with extremely small differences (0.0013 µsecs!)) the same time regardless of index:

...>python -m timeit --setup="x = [None]*1000" "x[500]"
10000000 loops, best of 3: 0.0579 usec per loop

...>python -m timeit --setup="x = [None]*1000" "x[0]"
10000000 loops, best of 3: 0.0566 usec per loop

I would be astounded if IronPython or Jython used linked lists - they would ruin the performance of many many widely-used libraries built on the assumption that lists are dynamic arrays.

  • 1
    @Ralf: I know my CPU (most other hardware too, for that matter) is old and dog slow - on the bright side, I can assume that code that runs fast enough for me is fast enough for all users :D – user395760 Oct 12 '10 at 19:58
  • 71
    @delnan: -1 Your "practical proof" is a nonsense, as are the 6 upvotes. About 98% of the time is taken up doing x=[None]*1000, leaving the measurement of any possible list access difference rather imprecise. You need to separate out the initialisation: -s "x=[None]*100" "x[0]" – John Machin Oct 12 '10 at 20:44
  • 22
    Shows that it's not a naive implementation of a linked list. Doesn't definitively show that it's an array. – Michael Mior Oct 14 '10 at 5:15
  • 3
    You can read about it here : docs.python.org/2/faq/design.html#how-are-lists-implemented – CCoder Sep 3 '13 at 9:39
  • 3
    There are far more structures than just linked list and array, timing is of no practical use for deciding between them. – Ross Hemsley Jul 1 '14 at 6:24
198

The C code is pretty simple, actually. Expanding one macro and pruning some irrelevant comments, the basic structure is in listobject.h, which defines a list as:

typedef struct {
    PyObject_HEAD
    Py_ssize_t ob_size;

    /* Vector of pointers to list elements.  list[0] is ob_item[0], etc. */
    PyObject **ob_item;

    /* ob_item contains space for 'allocated' elements.  The number
     * currently in use is ob_size.
     * Invariants:
     *     0 <= ob_size <= allocated
     *     len(list) == ob_size
     *     ob_item == NULL implies ob_size == allocated == 0
     */
    Py_ssize_t allocated;
} PyListObject;

PyObject_HEAD contains a reference count and a type identifier. So, it's a vector/array that overallocates. The code for resizing such an array when it's full is in listobject.c. It doesn't actually double the array, but grows by allocating

new_allocated = (newsize >> 3) + (newsize < 9 ? 3 : 6);
new_allocated += newsize;

to the capacity each time, where newsize is the requested size (not necessarily allocated + 1 because you can extend by an arbitrary number of elements instead of append'ing them one by one).

See also the Python FAQ.

  • 6
    So, when iterating over python lists it's as slow as linked lists, because every entry is just a pointer, so every element most likely would cause a cache miss. – Kr0e Apr 10 '14 at 15:24
  • 9
    @Kr0e: not if subsequent elements are actually the same object :) But if you need smaller/cache-friendlier data structures, the array module or NumPy are to be preferred. – Fred Foo Apr 11 '14 at 8:55
  • @larsmans: True =) – Kr0e Apr 11 '14 at 10:04
29

In CPython, lists are arrays of pointers. Other implementations of Python may choose to store them in different ways.

26

This is implementation dependent, but IIRC:

  • CPython uses an array of pointers
  • Jython uses an ArrayList
  • IronPython apparently also uses an array. You can browse the source code to find out.

Thus they all have O(1) random access.

  • 1
    Implementation dependent as in a python interpreter which implemented lists as linked lists would be a valid implementation of the python language? In other words: O(1) random access into lists is not guaranteed? Doesn't that make it impossible to write efficient code without relying on implementation details? – sepp2k Oct 12 '10 at 18:02
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    @sepp I believe lists in Python are just ordered collections; the implementation and/or performance requirements of said implementation are not explicitly stated – NullUserException Oct 12 '10 at 18:05
  • 5
    @sppe2k: Since Python doesn't really have a standard or formal specification (though there are some pieces of documentations that say "... is guaranteed to ..."), you can't be 100% sure as in "this is guaranteed by some piece of paper". But since O(1) for list indexing is a pretty common and valid assumption, no implementation would dare to break it. – user395760 Oct 12 '10 at 18:07
  • @Paul It says nothing about how the underlying implementation of lists should be done. – NullUserException Oct 12 '10 at 21:40
  • It just doesn't happen to specify the big O running time of things. Language syntax specification doesn't necessarily mean the same thing as implementation details, it just happens to often be the case. – Paul McMillan Oct 12 '10 at 21:40
22

According to the documentation,

Python’s lists are really variable-length arrays, not Lisp-style linked lists.

20

I would suggest Laurent Luce's article "Python list implementation". Was really useful for me because the author explains how the list is implemented in CPython and uses excellent diagrams for this purpose.

List object C structure

A list object in CPython is represented by the following C structure. ob_item is a list of pointers to the list elements. allocated is the number of slots allocated in memory.

typedef struct {

PyObject_VAR_HEAD

PyObject **ob_item;

Py_ssize_t allocated;

} PyListObject;

It is important to notice the difference between allocated slots and the size of the list. The size of a list is the same as len(l). The number of allocated slots is what has been allocated in memory. Often, you will see that allocated can be greater than size. This is to avoid needing calling realloc each time a new elements is appended to the list.

...

Append

We append an integer to the list: l.append(1). What happens?
enter image description here

We continue by adding one more element: l.append(2). list_resize is called with n+1 = 2 but because the allocated size is 4, there is no need to allocate more memory. Same thing happens when we add 2 more integers: l.append(3), l.append(4). The following diagram shows what we have so far.

enter image description here

...

Insert

Let’s insert a new integer (5) at position 1: l.insert(1,5) and look at what happens internally. enter image description here

...

Pop

When you pop the last element: l.pop(), listpop() is called. list_resize is called inside listpop() and if the new size is less than half of the allocated size then the list is shrunk.enter image description here

You can observe that slot 4 still points to the integer but the important thing is the size of the list which is now 4. Let’s pop one more element. In list_resize(), size – 1 = 4 – 1 = 3 is less than half of the allocated slots so the list is shrunk to 6 slots and the new size of the list is now 3.

You can observe that slot 3 and 4 still point to some integers but the important thing is the size of the list which is now 3.enter image description here

...

Remove Python list object has a method to remove a specific element: l.remove(5).enter image description here

  • Thanks, I understand the link part of the list more now. Python list is a aggregation, not composition. I wish there were a list of composition too. – shuva Sep 10 '18 at 22:30
5

As others have stated above, the lists (when appreciably large) are implemented by allocating a fixed amount of space, and, if that space should fill, allocating a larger amount of space and copying over the elements.

To understand why the method is O(1) amortized, without loss of generality, assume we have inserted a = 2^n elements, and we now have to double our table to 2^(n+1) size. That means we're currently doing 2^(n+1) operations. Last copy, we did 2^n operations. Before that we did 2^(n-1)... all the way down to 8,4,2,1. Now, if we add these up, we get 1 + 2 + 4 + 8 + ... + 2^(n+1) = 2^(n+2) - 1 < 4*2^n = O(2^n) = O(a) total insertions (i.e. O(1) amortized time). Also, it should be noted that if the table allows deletions the table shrinking has to be done at a different factor (e.g 3x)

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