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I thought I had the whole list alias thing figured out, but then I came across this:

    l = [1, 2, 3, 4]
    for i in l:
        i = 0
    print(l)

which results in:

    [1, 2, 3, 4]

So far so good.

However, when I tried this:

    l = [[1, 2], [3, 4], [5, 6]]
    for i in l:
        i[0] = 0

I get

    [[0, 2], [0, 4], [0, 5]]

Why is this?

Does this have to do with how deep aliasing goes?

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there is no such thing as "aliasing" in python –  user102008 Jan 25 '12 at 4:14
    
@user102008: If I define a function f, and then set some variable to equal f (i.e. x = f). I can then call f by using x(). That sure sounds like aliasing to me. If I understand correctly, using the assignment x = f makes x refers to f, it doesn't create an instance of f? –  Joel Cornett Jan 25 '12 at 4:28
    
correct. f is created at def time. x = f just points another name at f. –  wim Jan 25 '12 at 4:35
1  
But that's not aliasing, that's just copying the reference. Rebinding f doesn't affect x after the fact. –  Ignacio Vazquez-Abrams Jan 25 '12 at 4:40
    
It's strange how "yet another" is usually "the same one as always", in disguise. –  Karl Knechtel Jan 25 '12 at 8:15
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6 Answers 6

up vote 4 down vote accepted

i = 0 is very different from i[0] = 0.

Ignacio has said why succintly and correctly. So I will just try to explain in a more casual kind of language what's actually going on.

In the first case, i is just a label pointing at some object (one of the members in your list). i = 0 changes the reference to some other object, so that i now references the literal 0. The list is unmodified, because you never asked to modify l[0] or any element of l, you only modified i.

In the second case, i is also just a name pointing at one of the members in your list. But i[0] is now calling .__getitem__(0) on one of the list l members. It is not simply pointing i at a different object.

An easy way to think of it is always that names in python are just labels pointing to objects. And a scope or namespace is just like a dict mapping names to instances.

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So, if I understand this correctly, in this case i is treated differently based on whether it is indexed or not? –  Joel Cornett Jan 25 '12 at 4:25
2  
@Joel: i is never indexed. The object i is bound to is indexed. –  Ignacio Vazquez-Abrams Jan 25 '12 at 4:27
    
i is just a name in the namespace. i = 0 assigns that name i to a different object, and i[0] = 0 does not. –  wim Jan 25 '12 at 4:29
    
@IgnacioVazquez-Abrams: ah ok. Thanks for clearing that up. –  Joel Cornett Jan 25 '12 at 4:30
2  
@Joel: It's not that i is treated differently, but that i[0] = 0 is a different operation from i = 0. The first just makes i be a name for 0. The second makes the 0th slot in whatever i is currently a name for refer to 0. i[0] = 0 would have the same effect if i was bound to a number, except that numbers don't contain any "slots", so the operation throws an error. –  Ben Jan 25 '12 at 4:33
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The first rebinds the name. Rebinding a name changes only the local name. The second mutates the object. Mutating an object changes it everywhere it is referenced (since it's always the same object).

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Assignment is always just rebinding names in Python, which means you end up with aliases for the same object all over the place. Any time you give a name to any kind of object (you assign an existing object a new name, or you receive it passed into a function, or you pull it out of some container), anything you do to actually alter this object will affect it wherever it originally was (i.e. the caller who passed it into your function, or anybody else looking at the container you pulled it out of).

You can make your code explicitly take copies of things, if you need it to; list slicing with mylist[:] is probably the way you're most likely to be familiar with. Many built in operations do this; in particular it's usually a safe assumption with builtin functions/methods that if they return an object they haven't modified the originals (and this is a very good rule to follow most of the time; if your function or method has its effect by altering existing objects, it should return None and let the callers just look at the objects they gave you). In fact particularly for lists there are lots of pairs of methods/functions that do the same thing; usually there's a function that returns a new modified copy of the list and a method that returns nothing but alters the list. e.g. compare sorted_list = sorted(mylist) vs mylist.sort(), reversed_list = reversed(mylist) vs mylist.reverse(), etc.

But in the case when copying is going on, you do need to be careful about how deep the copy goes; in most cases it's only to the outer-most level, so mutating anything contained inside the copy will be visible from the original object.

New Python programmers need to get a handle on this as early as possible, as it pervades every single aspect of programming in Python.

Unfortunately, this issue is obscured by the most natural staring point for new programmers. You start by figuring out how to do basic manipulations of numbers and text strings, but those are immutable in Python. That doesn't mean they don't work "the same way" as lists, it just means there are no operations you can do that will cause them to change. So you don't need to care about whether they're being shared, because it won't make a difference even if they are.

Other answers have explained in more detail exactly what's going on in your example. But whenever you modify a list (or any other object), you need to think "where did this list come from?". Because most of the time, unless it's a new list that's just been created, other parts of your program will be able to see the changes you make. There is nearly always aliasing going on with list manipulations. Much of the time it doesn't matter, especially for lists of numbers or text. But you need to be aware of it all the time, so that you can decide whether or not it matters.

It does become second nature fairly easily though, so persevere and it'll get a lot easier. Having said that, even very experienced Python programmers still get caught by the occasional aliasing bug!

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Is there a limit to how deep deepcopy goes? –  Joel Cornett Jan 25 '12 at 4:32
2  
deepcopy tries to go all the way; it is your antimatter-bomb in the war against aliasing. It can't work on absolutely every possible object through, and almost all of the time you can write your programs so that you don't have to deepcopy everything. But for any object you're likely to be able to construct as a beginner Python programmer, deepcopy will work fine, and will give you back an object with no relevant aliasing. –  Ben Jan 25 '12 at 4:36
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for i in l:

This means "each time through the loop, i shall be a name for the next element of l".

i = 0

This means "i shall cease to be a name for whatever it's currently a name for, and begin to be a name for the integer object 0".

i[0] = 0

This means "The zeroth element of the thing that i names shall be replaced with 0". (You can't really say "i[0] shall cease to be a name for..." because it isn't a name.)

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When you say i = 0 you assign a new value to the variable i.

When you say i[0] = 0 you modify the list in variable i, setting the first element to a new value. Since the list in i is an element of l, l ends up with modified elements.

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Sometimes I find it easier to think in the less abstract world of C. In Python, think of every variable as being a pointer. When you do i = 0; i = 1, you're not doing this:

int * i = malloc(sizeof(int));
*i = 0;
*i = 1;

It's more like this:

int * i = malloc(sizeof(int));
*i = 0;
free(i);
i = malloc(sizeof(int));
*i = 1;

You're not changing the value, you're moving the pointer to a new value.

With a list though, the l pointer stays the same, but you're updating the value at the specified index. Thus l = [0]; l[0] = 1 looks like:

int * l[] = {0};
l[0] = 1;

(Note: I realize Python ints and lists are not really C ints and arrays, but for this purpose, they're similar.)

Protip: "alias" is not a Python term, so please avoid it. "Reference" or just "variable" are better.

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