I'm not a Swift programmer, so I have no clue about the language. I'm just asking out of curiosity. I came across a language construct where self inside a mutating function gets assigned a new value like in the function moveByAssigmentToSelf in the example below.

struct Point {
    var x = 0.0
    var y = 0.0

    mutating func moveByAssigmentToSelf(_ deltaX: Double, _ deltaY: Double) {
        self = Point(x: x + deltaX, y: y + deltaY)

    mutating func moveByMutatingMembers(_ deltaX: Double, _ deltaY: Double) {
        self.x += deltaX
        self.y += deltaY

Coming from a C/C++/Java/C# background I think of self as a pointer (address) to the (start of) the struct value somewhere in memory (e.g. on the stack). To me, assigning to something that should be equivalent to this in a C++ struct looks very strange. AFAICT, the function moveByMutatingMembers should have an observationally equivalent effect and would be the natural thing to do in the C++/Java world.

Can someone explain to a non-Swift programmer what is the rationale / idea behind this concept?

All I can find in the language reference (the chapter on expressions) are the following vague statements: "In an initializer, subscript, or instance method, self refers to the current instance of the type in which it occurs." and "In a mutating method of a value type, you can assign a new instance of that value type to self."

What I'm trying to understand is why is that assignment a good idea, which programming problems does it solve compared to the conventional solution?

In other words: Why does this make sense from a language-design perspective? Or: What would you lose if you had to do it the C++/Java way?

BTW, out of curiosity, I had a look at the Godbolt disassembly of this example and for my untrained eyes the output for moveByAssigmentToSelf looks horribly inefficient compared to the alternative.

  • 3
    "Coming from a C/C++/Java/C# background I think of self as a pointer " - two and a half of those languages do not make self a pointer
    – user253751
    May 3 at 8:38
  • 2
    While this is a pointer in C++, it just as easily could have been a reference.
    – R.M.
    May 3 at 15:40
  • 2
    C doesn't even have an implicit this or self; IDK why you even mention C. May 3 at 22:36

3 Answers 3


Coming from a C/C++/Java/C# background I think of self as a pointer

This is incorrect. Since this type is a value type (a struct), self is a copy of that value. The power of mutating is that it will, at the end of the function, replace the previous value with the new value. Values do not have "instances." They're just values.

For a useful introduction to value types in Swift, see Value and Reference Types. Also useful is Structures and Enumerations Are Value Types from the main Swift documentation.

Swift structs are somewhat like C++, if you let go of preconceptions about new and pointers and references, and just consider structs to be structs. They're passed as values (copies), just like C++ structs. It's just that in Swift this is the normal way to do things, unlike in C++, where things are generally passed by reference.

To your question about efficiency, that's just because you didn't turn on optimizations. With optimizations, they're literally the same code, and they inline the call to the init:

output.Point.moveByAssigmentToSelf(Swift.Double, Swift.Double) -> ():
        movupd  xmm2, xmmword ptr [r13]
        unpcklpd        xmm0, xmm1
        addpd   xmm0, xmm2
        movupd  xmmword ptr [r13], xmm0

output.Point.moveByMutatingMembers(Swift.Double, Swift.Double) -> ():
        jmp     (output.Point.moveByAssigmentToSelf(Swift.Double, Swift.Double) -> ())

Looking at your questions to @matt, I expect this may also help you understand the system a bit better:

var p: Point = Point(x: 1, y: 2) {
    didSet { print("new Point: \(p)")}

p.moveByMutatingMembers(1, 2)

This prints "new Point" just one time, because p is replaced (set) just one time.

On the other hand:

p.x = 0
p.y = 1

This will print "new point" twice because p is replaced twice. Calling a mutator on Point replaces the entire value with a new value.

  • 2
    Ah, that -O output makes me feel a lot better. I already guessed that I had missed a compiler switch. Upvoted. May 2 at 21:33
  • 1
    My point is that those bytes on the stack are copied, just as in C++. By "the normal way" I mean that in C++ you generally would avoid that copy happen (by using a reference, smart-pointer, or even a raw pointer). In Swift, it is normal to let that copy that happen (and the data types are designed such that copying is not expensive). I think you're trying to jump ahead to how value types are implemented and optimized, and working back to the language's semantics (which is how C++ generally works). But Swift starts with the semantics (copied values) and works forward to compiler optimizations.
    – Rob Napier
    May 2 at 22:06
  • 1
    Fair enough, I understand now what you meant. Nevertheless, self is not a copy of the value (as you said above) but a representative of that same value, right? (i.e., in effect its address?). May 2 at 22:11
  • 3
    No, it's a copy. The optimizer might work to avoid the copy as an implementation detail, but semantically it is absolutely a copy. Swift has many techniques (most famously copy-on-write in most stdlib data structures) to make those copies efficient. But no, it's a copy. To your questions about very large structs (that do not include collection types with CoW optimizations), yes, those can cause performance problems if you're not thoughtful about them.
    – Rob Napier
    May 2 at 22:13
  • 3
    Keep in mind that Swift has no canonical "language specification" of the kind that C or C++ has. Since the rise of the Swift Evolution process, you can often find more detailed explanations of specific features, but they are not in the form of amendments to a spec. Much of Swift is detailed in the form of WWDC videos or Swift forum discussions. Possibly still the most famous explanation of what Swift is trying to achieve is "The Crusty Talk": developer.apple.com/videos/play/wwdc2015/408
    – Rob Napier
    May 3 at 19:00

Assigning to self is useful for several reasons, but your example does not illustrate any. While this would be better spelled by + and += operators, assigning to self would make sense in your example only if another method already existed which performed the work on a new value.

func moved(_ deltaX: Double, _ deltaY: Double) -> Self {
  .init(x: x + deltaX, y: y + deltaY)

mutating func move(_ deltaX: Double, _ deltaY: Double) {
  self = moved(deltaX, deltaY)

The other option for nonmutating and mutating pairs switches the work to the mutating variant:

func moved(_ deltaX: Double, _ deltaY: Double) -> Self {
  var point = self
  point.move(deltaX, deltaY)
  return point

mutating func move(_ deltaX: Double, _ deltaY: Double) {
  x += deltaX
  y += deltaY

See union for one example of that in action in the standard library. Your performance concerns are not unfounded but the __consuming you'll find there will soon put them to rest.

  • 1
    Slowly, it starts to begin to make sense to me. Might be the explanation I was looking for. I have to study that and let that sink in a bit. Upvoted. May 2 at 22:29

Structs do not actually mutate. Merely saying myPoint.x = 1.0 actually replaces the struct. Thus it is no big deal if a struct substitutes a new copy of the struct as self, because that's exactly what you do every time you assign into a property of the struct.

That is why you cannot assign into a struct instance referenced by a let variable; this would require assigning a new struct into that variable, and you can't because let signifies a constant.

let myPoint = Point()
myPoint.x = 1 // illegal, and now you know why

Contrast a class, which is mutable in place — and that's why you can assign into a property of a class instance referenced by a let variable.

  • 1
    "myPoint.x = 1.0 actually replaces the struct". Is that always true? What if the struct is really large? Copying the whole struct and replacing the old value when only a 8 byte member needs to be changed sounds horribly inefficient to me. Nevertheless, upvoted. May 2 at 21:53
  • 2
    Just assume the struct is so big that it doesn't fit into a single xmm register? Why would the compiler load and store several of them when it is not necessary? May 2 at 21:56
  • 2
    "Merely saying myPoint.x = 1.0 actually replaces the struct." That statement doesn't seem to be true from an assembler perspective. Playing around with a larger struct in my example on Godbolt I see that only a part of the struct gets replaced. May 2 at 23:31
  • 3
    That's an optimization. Logically the entire struct is replaced. Looking at the assembly output doesn't tell you much about how Swift works; it just tells you what the optimizer was allowed to do that was equivalent in this program to how Swift actually works. If you add a didSet on the variable or property that holds the struct, you'll see that it is called every time you modify any part of the struct because the entire struct is one value.
    – Rob Napier
    May 2 at 23:49
  • 3
    See links in my answer. In particular "Structures and Enumerations Are Value Types." You may also find various docs in the compiler source helpful to understanding more technical parts of the implementation: github.com/apple/swift/blob/main/docs/Arrays.md github.com/apple/swift/blob/main/docs/proposals/… github.com/apple/swift/blob/main/docs/OwnershipManifesto.md But matt's answer is 100% correct. Mutating a struct is equivalent to making a copy with that change, then assigning that entire copy back to the original, even if the optimizer simplifies it.
    – Rob Napier
    May 3 at 18:49

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