In addition to viewing a functor as a container, you can also view it as a certain kind of context. Your values are in that context, and if you want to operate on them, you use
map to lift a function into the context. Another way of putting it is that your values are augmented with that context.
To understand how the list functor is a context of nondeterministic choice, it may be useful to see how another functor is a context: The Maybe functor is a context of a computation that may fail. If you try to apply a function to a value in a Maybe functor, the resulting value will still keep the same context of whether or not it was a failed computation in the first place.
In the same way, a list can be seen as the result of a computation that does not have a deterministic result, but whose result might instead be chosen nondeterministically from one of several values. If you tried to map a function over a list with 3 elements, those elements would be changed, but the context of being able to choose between three values would remain the same.
Borrowing a bit from Dan Burtons answer, look at the monadic notation for lists:
foo = do
x <- [1 .. 10]
y <- [2, 3, 5, 7]
return (x * y)
It seems at first a bit odd, since the notation seems to indicate, that you could extract a single value from each of the lists, but then you get as result a list that is 40 elements long. It makes more sense when you look at functors (well, monads in this case) as a context for a single value. In the example,
y are such values, but their context is that they are nondeterministic. When you multiply two such values, you get even more nondeterminism, resulting in a longer list. So with monads and
>>=, the context can be changed, whereas with functors and
map, it cannot.