16

When I create some array A and assign it to B

A = [1:10]
B = A

I can modify A and the change reflects in B

A[1] = 42
# B[1] is now 42

But if I do that with scalar variables, the change doesn't propagate:

a = 1
b = a
a = 2
# b remains being 1

I can even mix the things up and transform the vector to a scalar, and the change doesn't propagate:

A = [1:10]
B = A
A = 0
# B remains being 1,2,...,10

What exactly does the = operator does? When I want to copy variables and modify the old ones preserving the integrity of the new variables, when should I use b = copy(a) over just b=a?

  • Based on your anticipation of the results reflected from the question, R language may give you least surprise. – colinfang Feb 6 '16 at 5:09
26

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.

  • Thank you for your complete answer. As I have understanded you, all my b=a operations are assignments, so in all cases b should refer to a. What I am missing? – RedPointyJackson Oct 8 '15 at 6:47
  • When you do A[1] = 42 that's mutation, not assignment. – StefanKarpinski Oct 8 '15 at 16:52
  • Ok, I undestand that. But when I do b=a, it should be assignment because it's an operation in the x = ... style, right? So now I have b 'pointed' to a, and all changes in a should reflect whenever I evaluate b, don't they? – RedPointyJackson Oct 9 '15 at 12:49
  • 1
    Yes, that's correct and all of this behavior is completely in line with that. If you do a = b then any change to b also affects a. If the value bound to b is an immutable value like 42 then you can't mutate it anyway, so there's no way to tell if it was copied or referenced. – StefanKarpinski Oct 10 '15 at 4:47
  • There is a section about this in the Julia FAQ – Mankka Mar 13 at 8:19
-4

This behavior is similar to Java. A and B are variables that can hold either a "plain" data type, such as an integer, float etc, or a references (aka pointers) to a more complex data structure. In contrast to Java, Julia handles many non-abstract types as "plain" data.

You can test with isbits(A) whether your variable A holds a bit value, or contains a reference to another data object. In the first case B=A will copy every bit from A to a new memory allocation for B, otherwise, only the reference to the object will be copied.

Also play around with pointer_from_objref(A).

  • 2
    This answer is misleading at best: mutability vs immutability is a red herring. Mutable and immutable values have identical semantics in both languages – both have reference semantics. That's because neither Julia nor Java have mutable value types, like C's structs, which do have observably different semantics. – StefanKarpinski Oct 9 '15 at 9:09

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