The confusion stems from this: assignment and mutation are not the same thing.
Assignment. Assignment looks like
x = ... – what's left of the
= is an identifier, i.e. a variable name. Assignment changes which object the variable
x refers to (this is called a variable binding). It does not mutate any objects at all.
Mutation. There are two typical ways to mutate something in Julia:
x.f = ... – what's left of the
= is a field access expression;
x[i] = ... – what's left of the
= is an indexing expression. Currently, field mutation is fundamental – that syntax can only mean that you are mutating a structure by changing its field. This may change. Array mutation syntax is not fundamental –
x[i] = y means
setindex!(x, y, i) and you can either add methods to setindex! or locally change which generic function
setindex!. Actual array assignment is a builtin – a function implemented in C (and for which we know how to generate corresponding LLVM code).
Mutation changes the values of objects; it doesn't change any variable bindings. After doing either of the above, the variable
x still refers to the same object it did before; that object may have different contents, however. In particular, if that object is accessible from some other scope – say the function that called one doing the mutation – then the changed value will be visible there. But no bindings have changed – all bindings in all scopes still refer to the same objects.
You'll note that in this explanation I never once talked about mutability or immutability. That's because it has nothing to do with any of this – mutable and immutable objects have exactly the same semantics when it comes to assignment, argument passing, etc. The only difference is that if you try to do
x.f = ... when x is immutable, you will get an error.