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I have a protocol that itself conforms to Swift's Collection protocol, and that requires an additional subscript (Key) -> Value? returning the value associated with a given key, only if it exists (pretty much like Swift's Dictionary does).

protocol SearchTree: Collection {
    subscript(key: Int) -> String? { get }
}

struct ConformingTree: SearchTree {
    // Implementation ...
}

Now, I'd like to extend it with a default implementation for all Collection's requirements, plus my additional subscript (I guess the implementation specifics are irrelevant, which is why I removed them).

protocol SearchTree: Collection {
    subscript(key: Int) -> String? { get }
}

extension SearchTree {
    // MARK: Conformance to Sequence
    func makeIterator() -> AnyIterator<(key: Int, value: String)> { /* ... */ }

    // MARK: Conformance to Collection
    var startIndex: Int { /* ... */ }
    var endIndex: Int { /* ... */ }
    func index(after i: Int) -> Int { /* ... */ }
    subscript(key: Int) -> (key: Int, value: String) { /* ... */ }

    // MARK: Conformance to SearchTree
    subscript(key: Int) -> String? { /* ... */ }
}

struct ConformingTree: SearchTree {
    // Removing previous implementations ...
}

Unfortunately, this code will fail with Swift complaining that ConformingTree doesn't conforms to Collection, unless I keep an implementation for at least one of the subscripts in the conforming type.

struct ConformingTree: SearchTree {
    subscript(key: Int) -> String? { /* ... */ }
}

I originally thought that Swift was unable to infer the type of the correct subscript in my extension. But this seems unlikely as it eventually can figure out which implementation correspond to which protocol requirement if I push them in the conforming type. As I understand, the return type of makeIterator() should force the subscript with signature (Int) -> (Key, String) to fulfil Collection's requirement anyway.

Does anyone know what I'm missing here?

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  • Isn't the problem that the requirement in Collection is couched in terms of its generic placeholders Self.Index and Self.Element? I don't see where you are resolving those. The compiler isn't going to magically know that these are Int and String; you have to tell it.
    – matt
    Sep 3, 2017 at 22:15
  • @matt Well, it kind of magically does when the subscripts are declared within the conforming type body. At the very least, Self.Element should get resolved as AnyIterator<(key: Int, value: String)>.Element because of makeIterator().
    – Alvae
    Sep 3, 2017 at 23:48
  • By magically I meant that I expected type inference to work. Type aliases can be omitted in most situations, letting the compiler figure out how associated types should be resolved. I guess I'm just confused as to why type inference works for concrete types and not protocol extensions.
    – Alvae
    Sep 4, 2017 at 10:25
  • But that is exactly why, isn't it? You are not an adopter of the protocol. So the compiler has no reason to expect that your method declaration is intended to satisfy a generic requirement. That's not what protocol extensions do. The compiler thinks you are defining a new requirement (and possibly satisfying it).
    – matt
    Sep 4, 2017 at 11:52

1 Answer 1

1

Two problems:

  1. Your declaration of the subscript in the SearchTree protocol needs to have { get } after it.

  2. Collection requires a subscript that returns its Element. You have two subscripts, one of which returns a String? and one of which returns a (key: Int, value: String), but neither of these is Element, which the compiler needs; therefore the type does not conform to Collection. If you define Element in either your protocol or in the extension, it should compile.

In the protocol:

associatedtype Element = (key: Int, value: String)

or:

associatedtype Element = String?

Or in the extension:

typealias Element = (key: Int, value: String)

or:

typealias Element = String?

EDIT:

The above is true for Swift 4; however, for Swift 3, you also need to define _Element in addition to Element. Copying and pasting your code into a project, the following declaration of the protocol causes everything to compile in Swift 3:

protocol SearchTree: Collection {
    associatedtype Element = (key: Int, value: String)
    associatedtype _Element = (key: Int, value: String)

    subscript(key: Int) -> String? { get }
}
3
  • Thanks for pointing out the missing {get}. However, I tried both of your suggestions with no more success. As indicated, I do think the compiler should be able to guess the correct signature because makeIterator() should already constrain SearchTree.Element to be (key: Int, value: String) (or more precisely AnyIterator<(key: Int, value: String)>.Element).
    – Alvae
    Sep 3, 2017 at 23:44
  • I'm guessing you are using Swift 3. I tried it there, and it turns out that in Swift 3 you need to define _Element as well as Element, a requirement that was removed in Swift 4. The reason that the inference doesn't work here is that the compiler gets confused by the presence of two subscript(key: Int) -> Something methods. Sep 4, 2017 at 0:10
  • So it was indeed the fact that the type inference failed. I'd be interesting to know why it doesn't when the subscript are defined in the concrete type, but I guess that's another question. Sorry I forgot to mention I was still using Swift 3. Thanks for your help!
    – Alvae
    Sep 4, 2017 at 10:21

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