Consider these classes:

struct OrderedSet<T: Hashable> {}

class Exercise: Hashable {}

class StrengthExercise: Exercise {}

class CardioExercise: Exercise {}

I'd like to do the following:

var displayedExercises = OrderedSet<Exercise>() {
    didSet {
        self.tableView.reloadData()
    }
}
var cardioExercises = OrderedSet<CardioExercise>()
var strengthExercises = OrderedSet<StrengthExercise>()


@IBAction func segmentControlChanged(segmentControl: UISegmentedControl) {
    switch segmentControl.selectedSegmentIndex {
    case 0:     self.displayedExercises = self.strengthExercises
    case 1:     self.displayedExercises = self.cardioExercises
    default:    break
    }
}

But I get this error:

Cannot assign value of type 'OrderedSet<StrengthExercise>' to type 'OrderedSet<Exercise>

I don't quite get this, since StrengthExercise is a subclass of Exercise and will have everything that OrderedSet<Exercise> expects.

The question(s)

  • Why is this error necessary?
  • How to I write something that achieves the functionality I'm going for?



Radar filed
rdar://23608799


Blog post on covariance and contravariance
https://www.mikeash.com/pyblog/friday-qa-2015-11-20-covariance-and-contravariance.html

  • 2
    Is this a case where having a protocol (Exercisable? lol) is better than a class hierarchy? Or perhaps categories/extensions? – Cocoadelica Nov 17 '15 at 9:40
  • 1
    Fun aside: for the didSet: function of displayed exercise would you wrap the call to reload the tableview in a dispatch)async to the main queue or rely on documenting the interface to say you must set the value on the main queue? – Cocoadelica Nov 17 '15 at 9:41
  • @Cocoadelica of course! Lovely idea! ❤️ it! Adding a dispatch_async() to the main queue is also a good idea. I'd prefer that over documenting because then it's only written once and the new developer approaching it doesn't have to learn anything extra. Perhaps you should offer this as an answer? If no one offers an answer that also explains why the error is necessary, I could accept yours :) – kylejm Nov 17 '15 at 9:45
  • @Cocoadelica I strongly suspect displayedExercises is used by the table view data source callbacks, so if anything is setting that variable from anything other than the main thread the reloadData() call being on the wrong thread will be the least of your troubles—you will be concurrently modifying a collection! So either you assume displayedExercises is only ever set on the main thread and dispatch_async is unnecessary or if it is called from multiple threads, additional synchronisation all over the shop is needed. – Nicholas H. Nov 17 '15 at 17:14
  • @NicholasH. Good call. In that circumstance you're quite right. – Cocoadelica Nov 18 '15 at 10:02
up vote 7 down vote accepted

I am afraid this is not currently possible as of Swift 2.1. Only the following conversions are supported

  • Built in collections types are covariant on their element type.
  • Conversions between function types are supported, exhibiting covariance in function result types and contravariance in function parameter types. (Cf. Xcode 7.1 Release Notes)

As Objective-C's generics support type variance, and given the progress made on function type conversions in Swift 2.1, I believe there is reason to believe type variance support will be added to Swift in the future. In the mean time, remember to file a radar, like jlieske has.

In the mean time you will have to copy the collection or use one of the builtin collection types.

Update since Swift become open source: I believe the Complete generics section of Swift 3.0 Dev Roadmap indicates type variance will be addressed in 3.0. While type variance is not specifically called out, special cased exceptions in the standard library (which includes type variance) are.

  • I wonder if conforming to CollectionType would give this functionality? Worth trying? – kylejm Nov 17 '15 at 17:53
  • @kylejm it would appear you are right about CollectionType enabling the special cased behaviour of the type system. – Nicholas H. Nov 18 '15 at 11:00
  • @kylejm rolled back answer to original version based on discussion on @user3441734's answer indicating that it is not sufficient to inherit from CollectionType after all. – Nicholas H. Nov 18 '15 at 13:27
  • Thanks Nicholas! Will file a radar in a moment :) – kylejm Nov 18 '15 at 14:24
  • Radar filed 👍🏼 – kylejm Nov 19 '15 at 9:28

As the OrderedSet<StrengthExercise> is of that specific type it cannot be assigned to the more general OrderedSet<Exercise>. Think about what would happen if you tried to append a Cardio exercise to that OrderedSet after assigning it.

The answer might be to modify append the contents of the strength exercises set to the exercise set rather than assign the whole typed set.

  • I still don't understand why assigning a more specific type to a more general type is a problem here. The OrderedSet is a struct, so it's passed by value? Therefore, appending something to displayedExercises would not affect strengthExercises if you assigned strengthExercises to it before hand. What's more, you could not append a CardioExercise to displayedExercises, since it's of type OrderedSet<Exercise>. – kylejm Nov 17 '15 at 10:14
  • I think I get it now! In writing that comment to you, I realised the problem! What if I were to append an Exercise to displayedExercises and it actually contained StrengthExercises! Which is why you can't assign an OrderedSet<StrengthExercise> to displayedExercises! Got it! Thank you! – kylejm Nov 17 '15 at 10:16
  • On second thoughts, I still don't see why this would be a problem, since displayedExercises would have it's own copy of OrderedSet<StrengthExercise> because OrderedSet is a struct (pass by value). So appending an Exercise to it would not be a problem, since it would append said Exercise to strengthExercises as well? – kylejm Nov 17 '15 at 10:22
  • 1
    OrderedSet<StrengthExercise> IS the type, it is not just an ordered set that happens to be holding Strength Exercises. You could init a new OrderedSet based on its contents and type that as OrderedSet<Exercise> but that would absolutely be a new value of a new type. – Joseph Lord Nov 17 '15 at 10:28
  • What about covariance. Does Swift not support covariance for non-builtin types? (Sorry don't use Swift day-to-day.) It would be very disappointing if not. Even Objective-C's lightweight generics support type variance, cf. @interface NSArray<__covariant ObjectType>. – Nicholas H. Nov 17 '15 at 10:53

this should work

class Base {}
class A: Base {}
class B: Base {}

var arrBase: Array<Base> = []

var arrA: Array<A> = []
arrA.append(A())

var arrB: Array<B> = []
arrB.append(B())

arrBase = arrA   // no error
arrBase = arrB   // no error

... your trouble seems to be somewhere else in your code. can you show us your generic struct OrderedSet implementation ?? it seems like you are trying to do something like

class Base {}
class A: Base {}

let base = Base()
let a = A()

struct S<T:Base> {
    var t: T
}
var s = S(t: base)
let sa = S(t: a)
//s = sa  // error: cannot assign value of type 'S<A>' to type 'S<Base>'
let sb = S(t: a as Base)
s = sb

... this works

protocol P {
    func whoAmI()->Void
}
class Base:P {
    func whoAmI() {
        print("I am Base")
    }
}
class A: Base {
    override func whoAmI() {
        print("I am A")
    }
}

let base = Base()
let a = A()

struct S<T: Base> {
    var t: Base
}
var s = S(t: base)
let sa = S(t: a)
s = sa

s.t.whoAmI() // I am A

.... guys, build-in type or not

import Foundation
// Int and Double conforms to Hashable protocol
var a: Set<Int> = []
var b: Set<Double> = []
a = b   // IMPOSSIBLE eventhough Set<T:Hashable> is build-in Swift type

... how to deal with OrderedSet

import Foundation

class Exercise: Hashable {
    var name: String = ""
    var hashValue: Int {
        return name.hashValue
    }
}
func ==(lhs: Exercise, rhs: Exercise) -> Bool {
    return lhs.name == rhs.name
}
class StrengthExercise: Exercise {}
class CardioExercise: Exercise {}
var displayedExercises = Set<Exercise>()
let strengthExercises = Set<StrengthExercise>()
let cardioExercises = Set<CardioExercise>()
displayedExercises = strengthExercises

// OK, the question is how to implement OrderedSet<T:Hashable>
// ------------------------------------------------------------------------------------------
//
//  OrderedSet.swift
//  Weebly
//
//  Created by James Richard on 10/22/14.
//  Copyright (c) 2014 Weebly. All rights reserved.
//
//  Slightly modified by user3441734 on 11/18/15
//  
//  original code OrderedSet is available under the MIT license


/// An ordered, unique collection of objects.
public struct OrderedSet<T: Hashable> {
    private var contents = [T: Index]() // Needs to have a value of Index instead of Void for fast removals
    private var sequencedContents = Array<UnsafeMutablePointer<T>>()

    /**
     Inititalizes an empty ordered set.

     :return: An empty ordered set.
     */
    public init() { }

    /**
     Initializes a new ordered set with the order and contents
     of sequence.

     If an object appears more than once in the sequence it will only appear
     once in the ordered set, at the position of its first occurance.

     :param: sequence The sequence to initialize the ordered set with.
     :return: An initialized ordered set with the contents of sequence.
     */
    public init<S: SequenceType where S.Generator.Element == T>(sequence: S) {
        // FIXME: For some reason, Swift gives the error "Cannot convert the expression's type 'S' to type 'S'" with a regular for-in, so this is a hack to fix that.
        var gen = sequence.generate()
        while let object: T = gen.next() {
            if contents[object] == nil {
                contents[object] = contents.count

                let pointer = UnsafeMutablePointer<T>.alloc(1)
                pointer.initialize(object)
                sequencedContents.append(pointer)
            }
        }
    }

    /**
     Replace, remove, or retrieve an object in the ordered set.

     When setting an index to nil the object will be removed. If
     it is not the last object in the set, all subsequent objects
     will be shifted down one position.

     When setting an index to another object, the existing object
     at that index will be removed. If you attempt to set an index
     that does not currently have an object, this is a no-op.

     :param:     index   The index to retrieve or set.
     :return:   On get operations, the object at the specified index, or nil
     if no object exists at that index.
     */
    public subscript(index: Index) -> T {
        get {
            return sequencedContents[index].memory
        }

        set {
            contents[sequencedContents[index].memory] = nil
            contents[newValue] = index
            sequencedContents[index].memory = newValue
        }
    }


    /**
     Locate the index of an object in the ordered set.

     It is preferable to use this method over the global find() for performance reasons.

     :param:     object      The object to find the index for.
     :return:    The index of the object, or nil if the object is not in the ordered set.
     */
    public func indexOfObject(object: T) -> Index? {
        if let index = contents[object] {
            return index
        }

        return nil
    }

    /// The number of objects contained in the ordered set.
    public var count: Int {
        return contents.count
    }

    /// Whether the ordered set has any objects or not.
    public var isEmpty: Bool {
        return count == 0
    }

    /**
     Tests if the ordered set contains an object or not.

     :param:     object  The object to search for.
     :return:    true if the object exists in the ordered set, otherwise false.
     */
    public func contains(object: T) -> Bool {
        return contents[object] != nil
    }

    /**
     Appends an object to the end of the ordered set.

     :param:     object  The object to be appended.
     */
    mutating public func append(object: T) {
        if contents[object] != nil {
            return
        }

        contents[object] = contents.count

        let pointer = UnsafeMutablePointer<T>.alloc(1)
        pointer.initialize(object)
        sequencedContents.append(pointer)
    }

    /**
     Appends a sequence of objects to the end of the ordered set.

     :param:     objects  The objects to be appended.
     */
    mutating public func appendObjects<S: SequenceType where S.Generator.Element == T>(objects: S) {
        var gen = objects.generate()
        while let object: T = gen.next() {
            append(object)
        }
    }

    /**
     Removes an object from the ordered set.

     If the object exists in the ordered set, it will be removed.
     If it is not the last object in the ordered set, subsequent
     objects will be shifted down one position.

     :param:     object  The object to be removed.
     */
    mutating public func remove(object: T) {
        if let index = contents[object] {
            contents[object] = nil
            sequencedContents[index].dealloc(1)
            sequencedContents.removeAtIndex(index)

            for (object, i) in contents {
                if i < index {
                    continue
                }

                contents[object] = i - 1
            }
        }
    }

    /**
     Removes the given objects from the ordered set.

     :param:     objects     The objects to be removed.
     */
    mutating public func removeObjects<S: SequenceType where S.Generator.Element == T>(objects: S) {
        var gen = objects.generate()
        while let object: T = gen.next() {
            remove(object)
        }
    }

    /**
     Removes an object at a given index.

     This method will cause a fatal error if you attempt to move an object to an index that is out of bounds.

     :param:     index       The index of the object to be removed.
     */
    mutating public func removeObjectAtIndex(index: Index) {
        if index < 0 || index >= count {
            fatalError("Attempting to remove an object at an index that does not exist")
        }

        remove(sequencedContents[index].memory)
    }

    /**
     Removes all objects in the ordered set.
     */
    mutating public func removeAllObjects() {
        contents.removeAll()
        sequencedContents.removeAll()
    }

    /**
     Return an OrderedSet containing the results of calling
     `transform(x)` on each element `x` of `self`

     :param:     transform   A closure that is called for each element in the ordered set.
     The result of the closure is appended to the new ordered set.
     :result:     An ordered set containing the result of `transform(x)` on each element.
     */
    public func map<U: Hashable>(transform: (T) -> U) -> OrderedSet<U> {
        var result = OrderedSet<U>()

        for object in self {
            result.append(transform(object))
        }

        return result
    }

    /// The first object in the ordered set, or nil if it is empty.
    public var first: T? {
        return count > 0 ? self[0] : nil
    }

    /// The last object in the ordered set, or nil if it is empty.
    public var last: T? {
        return count > 0 ? self[count - 1] : nil
    }

    /**
     Swaps two objects contained within the ordered set.

     Both objects must exist within the set, or the swap will not occur.

     :param:     first   The first object to be swapped.
     :param:     second  The second object to be swapped.
     */
    mutating public func swapObject(first: T, withObject second: T) {
        if let firstPosition = contents[first] {
            if let secondPosition = contents[second] {
                contents[first] = secondPosition
                contents[second] = firstPosition

                sequencedContents[firstPosition].memory = second
                sequencedContents[secondPosition].memory = first
            }
        }
    }

    /**
     Tests if the ordered set contains any objects within a sequence.

     :param:     sequence    The sequence to look for the intersection in.
     :return:    Returns true if the sequence and set contain any equal objects, otherwise false.
     */
    public func intersectsSequence<S: SequenceType where S.Generator.Element == T>(sequence: S) -> Bool {
        var gen = sequence.generate()
        while let object: T = gen.next() {
            if contains(object) {
                return true
            }
        }

        return false
    }

    /**
     Tests if a the ordered set is a subset of another sequence.

     :param:     sequence    The sequence to check.
     :return:    true if the sequence contains all objects contained in the receiver, otherwise false.
     */
    public func isSubsetOfSequence<S: SequenceType where S.Generator.Element == T>(sequence: S) -> Bool {
        for (object, _) in contents {
            if !sequence.contains(object) {
                return false
            }
        }

        return true
    }

    /**
     Moves an object to a different index, shifting all objects in between the movement.

     This method is a no-op if the object doesn't exist in the set or the index is the
     same that the object is currently at.

     This method will cause a fatal error if you attempt to move an object to an index that is out of bounds.

     :param:     object  The object to be moved
     :param:     index   The index that the object should be moved to.
     */
    mutating public func moveObject(object: T, toIndex index: Index) {
        if index < 0 || index >= count {
            fatalError("Attempting to move an object at an index that does not exist")
        }

        if let position = contents[object] {
            // Return if the client attempted to move to the current index
            if position == index {
                return
            }

            let adjustment = position < index ? -1 : 1
            let range = index < position ? index..<position : position..<index
            for (object, i) in contents {
                // Skip items not within the range of movement
                if i < range.startIndex || i > range.endIndex || i == position {
                    continue
                }

                let originalIndex = contents[object]!
                let newIndex = i + adjustment

                let firstObject = sequencedContents[originalIndex].memory
                let secondObject = sequencedContents[newIndex].memory

                sequencedContents[originalIndex].memory = secondObject
                sequencedContents[newIndex].memory = firstObject

                contents[object] = newIndex
            }

            contents[object] = index
        }
    }

    /**
     Moves an object from one index to a different index, shifting all objects in between the movement.

     This method is a no-op if the index is the same that the object is currently at.

     This method will cause a fatal error if you attempt to move an object fro man index that is out of bounds
     or to an index that is out of bounds.

     :param:     index   The index of the object to be moved.
     :param:     toIndex   The index that the object should be moved to.
     */
    mutating public func moveObjectAtIndex(index: Index, toIndex: Index) {
        if ((index < 0 || index >= count) || (toIndex < 0 || toIndex >= count)) {
            fatalError("Attempting to move an object at or to an index that does not exist")
        }

        moveObject(self[index], toIndex: toIndex)
    }

    /**
     Inserts an object at a given index, shifting all objects above it up one.

     This method will cause a fatal error if you attempt to insert the object out of bounds.

     If the object already exists in the OrderedSet, this operation is a no-op.

     :param:     object      The object to be inserted.
     :param:     atIndex     The index to be inserted at.
     */
    mutating public func insertObject(object: T, atIndex index: Index) {
        if index > count || index < 0 {
            fatalError("Attempting to insert an object at an index that does not exist")
        }

        if contents[object] != nil {
            return
        }

        // Append our object, then swap them until its at the end.
        append(object)

        for i in Range(start: index, end: count-1) {
            swapObject(self[i], withObject: self[i+1])
        }
    }

    /**
     Inserts objects at a given index, shifting all objects above it up one.

     This method will cause a fatal error if you attempt to insert the objects out of bounds.

     If an object in objects already exists in the OrderedSet it will not be added. Objects that occur twice
     in the sequence will only be added once.

     :param:     objects      The objects to be inserted.
     :param:     atIndex      The index to be inserted at.
     */
    mutating public func insertObjects<S: SequenceType where S.Generator.Element == T>(objects: S, atIndex index: Index) {
        if index > count || index < 0 {
            fatalError("Attempting to insert an object at an index that does not exist")
        }

        var addedObjectCount = 0
        // FIXME: For some reason, Swift gives the error "Cannot convert the expression's type 'S' to type 'S'" with a regular for-in, so this is a hack to fix that.
        var gen = objects.generate()

        // This loop will make use of our sequncedContents array to update the contents dictionary's
        // values. During this loop there will be duplicate values in the dictionary.
        while let object: T = gen.next() {
            if contents[object] == nil {
                let seqIdx = index + addedObjectCount
                let element = UnsafeMutablePointer<T>.alloc(1)
                element.initialize(object)
                sequencedContents.insert(element, atIndex: seqIdx)
                contents[object] = seqIdx
                addedObjectCount++
            }
        }

        // Now we'll remove duplicates and update the shifted objects position in the contents
        // dictionary.
        for i in index + addedObjectCount..<count {
            contents[sequencedContents[i].memory] = i
        }
    }
}

extension OrderedSet: MutableCollectionType {
    public typealias Index = Int
    public typealias _Element = T
    public typealias Generator = OrderedSetGenerator<T>

    public func generate() -> Generator {
        return OrderedSetGenerator(set: self)
    }

    public var startIndex: Int {
        return 0
    }

    public var endIndex: Int {
        return count
    }
}

public struct OrderedSetGenerator<T: Hashable>: GeneratorType {
    public typealias Element = T
    private var generator: IndexingGenerator<Array<UnsafeMutablePointer<T>>>

    public init(set: OrderedSet<T>) {
        generator = set.sequencedContents.generate()
    }

    mutating public func next() -> Element? {
        return generator.next()?.memory
    }
}



public func +<T: Hashable, S: SequenceType where S.Generator.Element == T> (lhs: OrderedSet<T>, rhs: S) -> OrderedSet<T> {
    var joinedSet = lhs
    joinedSet.appendObjects(rhs)

    return joinedSet
}

public func +=<T: Hashable, S: SequenceType where S.Generator.Element == T> (inout lhs: OrderedSet<T>, rhs: S) {
    lhs.appendObjects(rhs)
}

public func -<T: Hashable, S: SequenceType where S.Generator.Element == T> (lhs: OrderedSet<T>, rhs: S) -> OrderedSet<T> {
    var purgedSet = lhs
    purgedSet.removeObjects(rhs)

    return purgedSet
}

public func -=<T: Hashable, S: SequenceType where S.Generator.Element == T> (inout lhs: OrderedSet<T>, rhs: S) {
    lhs.removeObjects(rhs)
}

extension OrderedSet: Equatable { }

public func ==<T: Hashable> (lhs: OrderedSet<T>, rhs: OrderedSet<T>) -> Bool {
    if lhs.count != rhs.count {
        return false
    }

    for object in lhs {
        if lhs.contents[object] != rhs.contents[object] {
            return false
        }
    }

    return true
}
// ------------------------------------------------------------------------------------------


// finaly what do you want

var displayedExercises1 = OrderedSet<Exercise>()
let strengthExercises1 = OrderedSet<StrengthExercise>()
let cardioExercises1 = OrderedSet<CardioExercise>()
displayedExercises = strengthExercises
  • The problem is not in @kylejm's code, the trouble is that it appears his OrderedSet is invariant. I suspect because Swift doesn't support type variance on non-builtin types. If so that would explain why Array works, it must be special cased somehow to be covariant. – Nicholas H. Nov 17 '15 at 11:10
  • @NicholasH. we don't know nothing about his generic OrderedSet .... – user3441734 Nov 17 '15 at 11:22
  • I don't think we need to see anything about his OrderedSet. It is clearly supposed to be a generic collection. The fact that the type system throws a hissy with empty implementation eliminates his implementation as a factor. Your proposal works around the issue by letting the type inference make s and sa both S<Base> which does not provide a suitable answer to @kylejm's question as sa is not actually S<A>. Try adding :S<A> after let sa to see the problem, namely it would appear Swift generics are invariant 😞 (except for the special cased builtin types like Array) – Nicholas H. Nov 17 '15 at 12:42
  • 1
    @user3441734 your solution still doesn't work I'm afraid. You made a typo on the last line, which is actually referencing the two Sets declared at the top of the code snippet. Here's a playground to illustrate. You still get the error I've stated in the question. – kylejm Nov 18 '15 at 11:50
  • 1
    yes. maybe, i go back in few days. if i find something useful, i will inform you, guys ... at least now we know what we are talking about – user3441734 Nov 18 '15 at 12:47

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