I’ve been learning swift and encountered a question about memory safety. The += operator takes an inout parameter on the left, which should have write access over the entire function call. And it do something like left = right+left within its implementation. It seems to be an overlapping of write and read accesses. How comes this doesn’t violate memory safety?

Edit: According to The Swift Programming Language, it can happen in a single thread:

However, the conflicting access discussed here can happen on a single thread and doesn’t involve concurrent or multi-threaded code.

Elaborate: Here are two examples from The Swift Programming Language (Swift 4.1 beta). I’m confused how this custom += implementation in a struct Vector2D is okay:

static func += (left: inout Vector2D, right: Vector2D) {
    left = left + right

When this is not:

var stepSize = 1
func incrementInPlace(_ number: inout Int) {
    number += stepSize
// Error: conflicting accesses to stepSize

Further edit:

I think my problem really is that += as a func, specifically when used

stepSize += stepSize

Or with custom implementation:

var vector = Vector2D(x: 3.0, y: 1.0)
vector += vector

This doesn’t have any error. But the func takes an inout from the left and thus have a long-term write access to “step”, then if the right also passed in “step”, I’m confused how that isn’t an instant read acess of “step” overlapping with long term write of “step.” Or is it only a problem when you pass in the same instance for two inout parameters, but nor one inout and one regular?

  • Can you elaborate your point? Of course it does not violate memory safety. Why does having a read and write access on the same line break memory safety? – Sweeper Apr 14 at 15:13
  • I’ve added elaboration to the post and exert from the book The Swift Programming Language (Swift 4.1 beta) If you can take a look? – Antonia Zhang Apr 14 at 16:15
  • 1
    In your first example, left is being incremented by some value, which is fine. In your second example, number (which is an inout reference to stepSize), is being incremented by itself, stepSize. The unsafe nature of the second example does not arise from the +=, but rather that you're changing the inout left hand side using the same memory in the right hand side expression. – Rob Apr 14 at 16:50
  • Now I see, I was too focused on the “inout” that I thought it created a problem with “+=“ that doesn’t actually exist. Then I realize it is in the end a problem with any one-line code changing self by reading self first – Antonia Zhang Apr 14 at 17:08
  • It's a bit of a vague question, but I think it's a good one. Clearly OP is confused on the topic, and misdiagnosed the source of the issue. However, they provide enough context for us to be able to figure out what they're getting at, so that we can prescribe a solution – Alexander Apr 15 at 3:27
up vote 2 down vote accepted

I know you've got it, but a clarification for future readers; in your comments, you said:

... it is, in the end, a problem with any one-line code changing self by reading self first.

No, that alone is not sufficient. As the Memory Safety chapter says, this problem manifests itself only when:

  • At least one is a write access.
  • They access the same location in memory.
  • Their durations overlap.


var foo = 41
foo = foo + 1

The foo = foo + 1 is not a problem (nor would foo += 1; nor would foo += foo) because constitutes a series of "instantaneous" accesses. So although we have (to use your phrase) "code changing self by reading self first", it is not a problem because their durations do not overlap.

The problem only manifests itself when you're dealing with "long-term" accesses. As that guide goes on to say:

A function has long-term write access to all of its in-out parameters. The write access for an in-out parameter starts after all of the non-in-out parameters have been evaluated and lasts for the entire duration of that function call. If there are multiple in-out parameters, the write accesses start in the same order as the parameters appear.

One consequence of this long-term write access is that you can’t access the original variable that was passed as in-out, even if scoping rules and access control would otherwise permit it—any access to the original creates a conflict.

So, consider your second example:

var stepSize = 1
func incrementInPlace(_ number: inout Int) {
    number += stepSize

In this case, you have a long-term access to whatever number references. When you invoke it with &stepSize, that means you have a long-term access to the memory associated with stepSize and thus number += stepSize means that you're trying to access stepSize while you already have a long-term access to it.

  • I think my problem is that += as a func, specifically “step+=step”. It takes in an inout from the left and thus have a long-term write access to that value “step”, then if the right passed in the same value, I’m confused how that isn’t an instant read of “step” overlapping with long term write of “step” – Antonia Zhang Apr 15 at 2:21
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    @AntoniaZhang The right argument is "read instantaneously" and a copy of its value is passed to the += function call, prior to to the start of the += function call (which marks the beginning of the "long-term write access"). Thus, there is no overlap – Alexander Apr 15 at 3:25
  • "then if the right passed in the same value" ... whoa, there. The question isn't whether the parameter on the right is the same value or not. The question is whether it's the same memory address. But the right parameter value types, so right is a copy of the original value, not pointing to the same memory address. Whereas in your question's stepSize example, the function is referencing a property called stepSize (with a particular memory address) and the inout parameter was passed &stepSize as number, so you're dealing with the same address. Ergo non-safe memory access. – Rob Apr 15 at 6:01
  • Here’s how I understand it now: because it is a value type that is being passed on the right, a copy was made when the parameter was evaluated before func call, and thus the instantaneous access happens before the long term access starts. So no overlap! Thank you Alexander and Rob, for finally clearing it all up for me! – Antonia Zhang Apr 15 at 10:16

When you write

x +=5

which is Equal to

x = x + 5

first a read operation happens to the variable x then the value is being added to 5 finally a write operation of the result , all of this happens synchronously by registers it's not at the same time

  • Thanks, but sorry I still don’t get it, shouldn’t the func += be taking an inout parameter from the left hand side? And shouldn’t the functions have long-term write access to their inout parameters, from start to end of the func? And the read access only happened within the func’s declaration right? How comes the read access can happen after the write access end? – Antonia Zhang Apr 14 at 15:25
  • This a high level line of code what actually happens is that line converted to a set of assembly lines that you might see during a crash , with a single thread no conflict can happen because it's guarantee that at a time a single instruction is being executed so read and write can't happen at the same time to the variable – Sh_Khan Apr 14 at 15:35
  • Could you explain more? Also I added elaboration in the post if you can take a look? – Antonia Zhang Apr 14 at 16:13

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