I don't think this can be done but I'll ask anyway. I have a protocol:
protocol X {}
And a class:
class Y:X {}
In the rest of my code I refer to everything using the protocol X. In that code I would like to be able to do something like:
let a:X = ...
let b:X = ...
if a == b {...}
The problem is that if I try to implement Equatable:
protocol X: Equatable {}
func ==(lhs:X, rhs:X) -> Bool {
if let l = lhs as? Y, let r = hrs as? Y {
return l.something == r.something
}
return false
}
The idea to try and allow the use of == whilst hiding the implementations behind the protocol.
Swift doesn't like this though because Equatable has Self references and it will no longer allow me to use it as a type. Only as a generic argument.
So has anyone found a way to apply an operator to a protocol without the protocol becoming unusable as a type?
If you directly implement Equatable on a protocol, it will not longer be usable as a type, which defeats the purpose of using a protocol. Even if you just implement == functions on protocols without Equatable conformance, results can be erroneous. See this post on my blog for a demonstration of these issues:
https://khawerkhaliq.com/blog/swift-protocols-equatable-part-one/
The approach that I have found to work best is to use type erasure. This allows making == comparisons for protocol types (wrapped in type erasers). It is important to note that while we continue to work at the protocol level, the actual == comparisons are delegated to the underlying concrete types to ensure correct results.
I have built a type eraser using your brief example and added some test code at the end. I have added a constant of type String to the protocol and created two conforming types (structs are the easiest for demonstration purposes) to be able to test the various scenarios.
For a detailed explanation of the type erasure methodology used, check out part two of the above blog post:
https://khawerkhaliq.com/blog/swift-protocols-equatable-part-two/
The code below should support the equality comparison that you wanted to implement. You just have to wrap the protocol type in a type eraser instance.
protocol X {
var name: String { get }
func isEqualTo(_ other: X) -> Bool
func asEquatable() -> AnyEquatableX
}
extension X where Self: Equatable {
func isEqualTo(_ other: X) -> Bool {
guard let otherX = other as? Self else { return false }
return self == otherX
}
func asEquatable() -> AnyEquatableX {
return AnyEquatableX(self)
}
}
struct Y: X, Equatable {
let name: String
static func ==(lhs: Y, rhs: Y) -> Bool {
return lhs.name == rhs.name
}
}
struct Z: X, Equatable {
let name: String
static func ==(lhs: Z, rhs: Z) -> Bool {
return lhs.name == rhs.name
}
}
struct AnyEquatableX: X, Equatable {
var name: String { return value.name }
init(_ value: X) { self.value = value }
private let value: X
static func ==(lhs: AnyEquatableX, rhs: AnyEquatableX) -> Bool {
return lhs.value.isEqualTo(rhs.value)
}
}
// instances typed as the protocol
let y: X = Y(name: "My name")
let z: X = Z(name: "My name")
let equalY: X = Y(name: "My name")
let unequalY: X = Y(name: "Your name")
// equality tests
print(y.asEquatable() == z.asEquatable()) // prints false
print(y.asEquatable() == equalY.asEquatable()) // prints true
print(y.asEquatable() == unequalY.asEquatable()) // prints false
Note that since the type eraser conforms to the protocol, you can use instances of the type eraser anywhere an instance of the protocol type is expected.
Hope this helps.
The reason why you should think twice about having a protocol conform to Equatable is that in many cases it just doesn't make sense. Consider this example:
protocol Pet: Equatable {
var age: Int { get }
}
extension Pet {
static func == (lhs: Pet, rhs: Pet) -> Bool {
return lhs.age == rhs.age
}
}
struct Dog: Pet {
let age: Int
let favoriteFood: String
}
struct Cat: Pet {
let age: Int
let favoriteLitter: String
}
let rover: Pet = Dog(age: "1", favoriteFood: "Pizza")
let simba: Pet = Cat(age: "1", favoriteLitter: "Purina")
if rover == simba {
print("Should this be true??")
}
You allude to type checking within the implementation of == but the problem is that you have no information about either of the types beyond them being Pets and you don't know all the things that might be a Pet (maybe you will add a Bird and Rabbit later). If you really need this, another approach can be modeling how languages like C# implement equality, by doing something like:
protocol IsEqual {
func isEqualTo(_ object: Any) -> Bool
}
protocol Pet: IsEqual {
var age: Int { get }
}
struct Dog: Pet {
let age: Int
let favoriteFood: String
func isEqualTo(_ object: Any) -> Bool {
guard let otherDog = object as? Dog else { return false }
return age == otherDog.age && favoriteFood == otherDog.favoriteFood
}
}
struct Cat: Pet {
let age: Int
let favoriteLitter: String
func isEqualTo(_ object: Any) -> Bool {
guard let otherCat = object as? Cat else { return false }
return age == otherCat.age && favoriteLitter == otherCat.favoriteLitter
}
}
let rover: Pet = Dog(age: "1", favoriteFood: "Pizza")
let simba: Pet = Cat(age: "1", favoriteLitter: "Purina")
if !rover.isEqualTo(simba) {
print("That's more like it.")
}
At which point if you really wanted, you could implement == without implementing Equatable:
static func == (lhs: IsEqual, rhs: IsEqual) -> Bool { return lhs.isEqualTo(rhs) }
One thing you would have to watch out for in this case is inheritance though. Because you could downcast an inheriting type and erase the information that might make isEqualTo not make logical sense.
The best way to go though is to only implement equality on the class/struct themselves and use another mechanism for type checking.
Determining equality across conformances to a Swift protocol is possible without type erasure if:
you are willing to forgo the operator syntax (i.e. call isEqual(to:) instead of ==)
you control the protocol (so you can add an isEqual(to:) func to it)
import XCTest
protocol Shape {
func isEqual (to: Shape) -> Bool
}
extension Shape where Self : Equatable {
func isEqual (to: Shape) -> Bool {
return (to as? Self).flatMap({ $0 == self }) ?? false
}
}
struct Circle : Shape, Equatable {
let radius: Double
}
struct Square : Shape, Equatable {
let edge: Double
}
class ProtocolConformanceEquality: XCTestCase {
func test() {
// Does the right thing for same type
XCTAssertTrue(Circle(radius: 1).isEqual(to: Circle(radius: 1)))
XCTAssertFalse(Circle(radius: 1).isEqual(to: Circle(radius: 2)))
// Does the right thing for different types
XCTAssertFalse(Square(edge: 1).isEqual(to: Circle(radius: 1)))
}
}
Any conformances don't conform to Equatable will need to implement isEqual(to:) themselves
maybe this will be helpful for you:
protocol X:Equatable {
var name: String {get set}
}
extension X {
static func ==(lhs: Self, rhs: Self) -> Bool {
return lhs.name == rhs.name
}
}
struct Test : X {
var name: String
}
let first = Test(name: "Test1")
let second = Test(name: "Test2")
print(first == second) // false
All people who say that you can't implement Equatable for a protocol just don't try hard enough. Here is the solution (Swift 4.1) for your protocol X example:
protocol X: Equatable {
var something: Int { get }
}
// Define this operator in the global scope!
func ==<L: X, R: X>(l: L, r: R) -> Bool {
return l.something == r.something
}
And it works!
class Y: X {
var something: Int = 14
}
struct Z: X {
let something: Int = 9
}
let y = Y()
let z = Z()
print(y == z) // false
y.something = z.something
print(y == z) // true
The only problem is that you can't write let a: X = Y() because of "Protocol can only be used as a generic constraint" error.
Not sure why you need all instances of your protocol to conform to Equatable, but I prefer letting classes implement their equality methods.
In this case, I'd leave the protocol simple:
protocol MyProtocol {
func doSomething()
}
If you require that an object that conforms to MyProtocol is also Equatable you can use MyProtocol & Equatable as type constraint:
// Equivalent: func doSomething<T>(element1: T, element2: T) where T: MyProtocol & Equatable {
func doSomething<T: MyProtocol & Equatable>(element1: T, element2: T) {
if element1 == element2 {
element1.doSomething()
}
}
This way you can keep your specification clear and let subclasses implement their equality method only if required.
I would still advise against implementing == using polymorphism. It's a bit of a code smell. If you want to give the framework user something he can test equality with then you should really be vending a struct, not a protocol. That's not to say that it can't be the protocols that are vending the structs though:
struct Info: Equatable {
let a: Int
let b: String
static func == (lhs: Info, rhs: Info) -> Bool {
return lhs.a == rhs.a && lhs.b == rhs.b
}
}
protocol HasInfo {
var info: Info { get }
}
class FirstClass: HasInfo {
/* ... */
}
class SecondClass: HasInfo {
/* ... */
}
let x: HasInfo = FirstClass( /* ... */ )
let y: HasInfo = SecondClass( /* ... */ )
print(x == y) // nope
print(x.info == y.info) // yep
I think this more efficiently communicates your intent, which is basically "you have these things and you don't know if they are the same things, but you do know they have the same set of properties and you can test whether those properties are the same." That is pretty close to how I would implement that Money example.
You have to implement a protocol extension constrained to your class type. Inside that extension you should implement the Equatable operator.
public protocol Protocolable: class, Equatable
{
// Other stuff here...
}
public extension Protocolable where Self: TheClass
{
public static func ==(lhs: Self, rhs:Self) -> Bool
{
return lhs.name == rhs.name
}
}
public class TheClass: Protocolable
{
public var name: String
public init(named name: String)
{
self.name = name
}
}
let aClass: TheClass = TheClass(named: "Cars")
let otherClass: TheClass = TheClass(named: "Wall-E")
if aClass == otherClass
{
print("Equals")
}
else
{
print("Non Equals")
}
But let me recommend you add the operator implementation to your class. Keep It Simple ;-)
Swift 5.1 introduces a new feature into the language called opaque types
Check code below
that still gets back a X, which might be an Y, a Z, or something else that conforms to the X protocol,
but the compiler knows exactly what is being returned
protocol X: Equatable { }
class Y: X {
var something = 3
static func == (lhs: Y, rhs: Y) -> Bool {
return lhs.something == rhs.something
}
static func make() -> some X {
return Y()
}
}
class Z: X {
var something = "5"
static func == (lhs: Z, rhs: Z) -> Bool {
return lhs.something == rhs.something
}
static func make() -> some X {
return Z()
}
}
let a = Z.make()
let b = Z.make()
a == b
I came cross this same issue and I figured that the == operator can be implemented in the global scope (as it used to be), as opposed to a static func inside the protocol's scope:
// This should go in the global scope
public func == (lhs: MyProtocol?, rhs: MyProtocol?) -> Bool { return lhs?.id == rhs?.id }
public func != (lhs: MyProtocol?, rhs: MyProtocol?) -> Bool { return lhs?.id != rhs?.id }
Note that if you use linters such as SwiftLint's static_operator, you'll have to wrap that code around // swiftlint:disable static_operator to silent linter warnings.
Then this code will start compiling:
let obj1: MyProtocol = ConcreteType(id: "1")
let obj2: MyProtocol = ConcreteType(id: "2")
if obj1 == obj2 {
print("They're equal.")
} else {
print("They're not equal.")
}
took some of the code from above and came with the following sollution.
it uses the IsEqual protocol instead of the Equatable protocol and with a few line codes you will be able to compare any two protocol objects with each other, wether they are optional or not, are in an array and even add comparing dates while I was at it.
protocol IsEqual {
func isEqualTo(_ object: Any) -> Bool
}
func == (lhs: IsEqual?, rhs: IsEqual?) -> Bool {
guard let lhs = lhs else { return rhs == nil }
guard let rhs = rhs else { return false }
return lhs.isEqualTo(rhs) }
func == (lhs: [IsEqual]?, rhs: [IsEqual]?) -> Bool {
guard let lhs = lhs else { return rhs == nil }
guard let rhs = rhs else { return false }
guard lhs.count == rhs.count else { return false }
for i in 0..<lhs.count {
if !lhs[i].isEqualTo(rhs[i]) {
return false
}
}
return true
}
func == (lhs: Date?, rhs: Date?) -> Bool {
guard let lhs = lhs else { return rhs == nil }
guard let rhs = rhs else { return false }
return lhs.compare(rhs) == .orderedSame
}
protocol Pet: IsEqual {
var age: Int { get }
}
struct Dog: Pet {
let age: Int
let favoriteFood: String
func isEqualTo(_ object: Any) -> Bool {
guard let otherDog = object as? Dog else { return false }
return age == otherDog.age && favoriteFood == otherDog.favoriteFood
}
}
Related
Value of protocol type 'Any' cannot conform to 'Equatable'; only struct/enum/class types can conform to protocols
Value is type "ANY" as it can be Int or String. So not able to implement Equatable protocol.
struct BusinessDetail:Equatable {
static func == (lhs: BusinessDetail, rhs: BusinessDetail) -> Bool {
lhs.cellType == rhs.cellType && lhs.value == rhs.value
}
let cellType: BusinessDetailCellType
var value: Any?
}
enum BusinessDetailCellType:Int {
case x
case y
var textValue:String {
Switch self {
case x:
return "x"
case y:
return "y"
}
}
}
I had a similar issue, where using [AnyHashable] instead of [Any] type was the solution!
Use Generics instead of Any ...
struct BusinessDetail<T> {
let cellType: BusinessDetailCellType
var value: T?
}
extension BusinessDetail: Equatable {
static func ==<T> (lhs: BusinessDetail<T>, rhs: BusinessDetail<T>) -> Bool {
lhs.cellType == rhs.cellType
}
static func == <T1:Equatable>(lhs: BusinessDetail<T1>, rhs: BusinessDetail<T1>) -> Bool {
lhs.cellType == rhs.cellType && lhs.value == rhs.value
}
}
enum BusinessDetailCellType:Int {
case x
case y
var textVlaue:String {
switch self {
case .x:
return "x"
case .y:
return "y"
}
}
}
I've got a protocol:
protocol Adjustable: Equatable {
associatedtype T
var id: String { get set }
var value: T { get set }
init(id: String, value: T)
}
And a struct that conforms to it:
struct Adjustment: Adjustable {
static func == (lhs: Adjustment, rhs: Adjustment) -> Bool {
return lhs.id == rhs.id
}
typealias T = CGFloat
var id: String
var value: T
}
And I'm building a wrapper class that behaves like a Set to handle an ordered list of these properties:
struct AdjustmentSet {
var adjustmentSet: [Adjustable] = []
func contains<T: Adjustable>(_ item: T) -> Bool {
return adjustmentSet.filter({ $0.id == item.id }).first != nil
}
}
let brightness = Adjustment(id: "Brightness", value: 0)
let set = AdjustmentSet()
print(set.contains(brightness))
But that of course doesn't work, erroring with:
error: protocol 'Adjustable' can only be used as a generic constraint because it has Self or associated type requirements
var adjustmentSet: [Adjustable] = []
Looking around, I thought at first this was because the protocol doesn't conform to Equatable, but then I added it, and it still doesn't work (or I did it wrong).
Moreover, I would like to be able to use a generic here, so that I can do something like:
struct Adjustment<T>: Adjustable {
static func == (lhs: Adjustment, rhs: Adjustment) -> Bool {
return lhs.id == rhs.id
}
var id: String
var value: T
}
let brightness = Adjustment<CGFloat>(id: "Brightness", value: 0)
Or:
struct FloatAdjustment: Adjustable {
static func == (lhs: Adjustment, rhs: Adjustment) -> Bool {
return lhs.id == rhs.id
}
typealias T = CGFloat
var id: String
var value: T
}
let brightness = FloatAdjustment(id: "Brightness", value: 0)
And still be able to store an array of [Adjustable] types, so that eventually I can do:
var set = AdjustmentSet()
if set.contains(.brightness) {
// Do something!
}
Or
var brightness = ...
brightness.value = 1.5
set.append(.brightness)
You can't have an array of items of type Adjustable, because Adjustable isn't really a type. It's a blue print that describes a set of types, one per every possible value of T.
To get around this, you need to use a type eraser https://medium.com/dunnhumby-data-science-engineering/swift-associated-type-design-patterns-6c56c5b0a73a
Have made some great progress using Alexander's suggestion; I was able to use some nested class types to inherit the base type erasure class, and use a generic protocol that conforms to AnyHashable so I can use this with a set!
// Generic conforming protocol to AnyHashable
protocol AnyAdjustmentProtocol {
func make() -> AnyHashable
}
protocol AdjustmentProtocol: AnyAdjustmentProtocol {
associatedtype A
func make() -> A
}
struct AdjustmentTypes {
internal class BaseType<T>: Hashable {
static func == (lhs: AdjustmentTypes.BaseType<T>, rhs: AdjustmentTypes.BaseType<T>) -> Bool {
return lhs.name == rhs.name
}
typealias A = T
var hashValue: Int { return name.hashValue }
let name: String
let defaultValue: T
let min: T
let max: T
var value: T
init(name: String, defaultValue: T, min: T, max: T) {
self.name = name
self.defaultValue = defaultValue
self.min = min
self.max = max
self.value = defaultValue
}
}
class FloatType: BaseType<CGFloat> { }
class IntType: BaseType<Int> { }
}
struct AnyAdjustmentType<A>: AdjustmentProtocol, Hashable {
static func == (lhs: AnyAdjustmentType<A>, rhs: AnyAdjustmentType<A>) -> Bool {
return lhs.hashValue == rhs.hashValue
}
private let _make: () -> AnyHashable
private let hashClosure:() -> Int
var hashValue: Int {
return hashClosure()
}
init<T: AdjustmentProtocol & Hashable>(_ adjustment: T) where T.A == A {
_make = adjustment.make
hashClosure = { return adjustment.hashValue }
}
func make() -> AnyHashable {
return _make()
}
}
struct Brightness: AdjustmentProtocol, Hashable {
func make() -> AnyHashable {
return AdjustmentTypes.FloatType(name: "Brightness", defaultValue: 0, min: 0, max: 1)
}
}
struct WhiteBalance: AdjustmentProtocol, Hashable {
func make() -> AnyHashable {
return AdjustmentTypes.IntType(name: "White Balance", defaultValue: 4000, min: 3000, max: 7000)
}
}
let brightness = Brightness().make()
let whiteBalance = WhiteBalance().make()
var orderedSet = Set<AnyHashable>()
orderedSet.insert(brightness)
print(type(of: orderedSet))
print(orderedSet.contains(brightness))
for obj in orderedSet {
if let o = obj as? AdjustmentTypes.FloatType {
print(o.value)
}
if let o = obj as? AdjustmentTypes.IntType {
print(o.value)
}
}
Prints:
Set<AnyHashable>
true
0.0
Special thanks to this article: https://medium.com/#chris_dus/type-erasure-in-swift-84480c807534 which had a simple and clean example on how to implement a generic type eraser.
With Swift 5.7 you will be able to this without any error from the compiler by prefixing your protocol with any, so your set becomes:
struct AdjustmentSet {
var adjustmentSet: [any Adjustable] = []
func contains(_ item: some Adjustable) -> Bool {
return adjustmentSet.first { $0.id == item.id } != nil
}
}
Note that all items in your adjustmentSet array will be allocated on heap since compile time swift can't determine the size of existential type Adjustable as types implementing it will have variable size.
I am trying to extend my protocol Option with Comparable to use simple .sort() method.
Below short example only with Equatable to show errors.
#objc protocol Option: Equatable {
var title: String { get }
var enabled: Bool { get }
var position: Int { get }
}
func ==(lhs: Option, rhs: Option) -> Bool {
return lhs.position == rhs.position
}
The Option protocol must be marked as #objc or inherit from NSObjectProtocol because it will be used with UIKit.
Errors:
#objc protocol 'Option' cannot refine non-#objc protocol
'Equatable'
Protocol 'Option' can only be used as a generic constraint
because it has Self or associated type requirements
Do you have any suggestion how to solve this problem?
Equatable lives in the Swift world only, thus you cannot extend it to a protocol that will be used by Objective-C. Trying to do this results in error #1
Protocols that have a Self requirement (i.e. at least one method from the protocol declaration contains Self) cannot be used as arguments to functions, or to variable declarations, only as arguments to a generic clause, e.g. func doSomething<T: Option>(argument: T).
Removing Equatable from the Option protocol declaration, and declaring == as generic on Option will solve the compile errors. As for sorting, you can also overload the < operator, and sort via that operator (without needing to implement Comparable):
#objc protocol Option {
var title: String { get }
var enabled: Bool { get }
var position: Int { get }
}
func ==<T: Option>(lhs: T, rhs: T) -> Bool {
return lhs.position == rhs.position
}
func <<T: Option>(lhs: T, rhs: T) -> Bool {
return lhs.position < rhs.position
}
This allows you to pass objects that conform to the protocol to UIKit, and to also compare them within your swift code.
class A: NSObject, Option { .. }
class B: NSObject, Option { ... }
let a = A()
let b = B()
a == b // compiles, and returns true if a and b have the same position
let c: [Option] = [a, b]
c.sort(<) // returns a sorted array by the `position` field
One important note regarding the sorting code above: if you don't specify the type for c, then the compiler infers its type as [NSObject], and the sort call will not compile due to ambiguity of the < operator. You need to explicitly declare c as [Option] to take advantage of the overloaded operator.
The issue can be fixed by the new protocol oriented programming features introduced in swift 2.0
#objc protocol 'Option' cannot refine non-#objc protocol 'Equatable'
As the error states, the Equatable protocol is a swift protocol that you can't to Obj C context
Protocol 'Option' can only be used as a generic constraint because it
has Self or associated type requirements
You can achieve this in the following way:
#objc protocol Option {
var title: String { get }
var enabled: Bool { get }
var position: Int { get }
}
extension Equatable where Self : Option
{
}
extension Comparable where Self : Option
{
}
func ==(lhs: Option, rhs: Option) -> Bool
{
return lhs.position == rhs.position
}
func <(lhs: Option, rhs: Option) -> Bool
{
return lhs.position < rhs.position
}
func >(lhs: Option, rhs: Option) -> Bool
{
return lhs.position > rhs.position
}
And your class and implementation looks like:
class MyClass: Option
{
#objc var title: String = ""
#objc var enabled: Bool = true
#objc var position: Int = 0
init()
{
}
convenience init(title : String, enabled : Bool, position: Int)
{
self.init()
self.title = title
self.enabled = enabled
self.position = position
}
}
let firstObj = MyClass()
let secondObj = MyClass()
let optionArray : [Option] = [firstObj, secondObj]
// Sort array of options
optionArray.sort(<)
I have an array of users [User] called conversationUsers
User is defined as
public class User: NSManagedObject { ... }
and currUser is an User object
if I try
currUser == conversationUsers[0]
it results true
but
conversationUsers.contains(currUser)
results false
If instead I use
conversationUsers.contains({$0 == currUser})
it returns true
FYI I have also defined this:
public func ==(lhs: User, rhs: User) -> Bool {
let logicalExpression = lhs.email.lowercaseString == rhs.email.lowercaseString
return logicalExpression
}
Why contains returns false? Which is his default predicate?
Thank you for your help
UPDATE
In short, you should override NSObject.isEqual() method:
public class User: NSManagedObject {
...
override func isEqual(object: AnyObject?) -> Bool {
if let rhs = object as? User {
return self == rhs
}
return false
}
}
I made a little research. It seems that if class A is inherited from NSObject then collection methods like contains use NSObject.isEqual() method for determining equality of two objects. Class B is not inherited from NSObject so contains method is working as expected.
import Foundation
class A: NSObject {
var value: Int
init(_ value: Int) {
self.value = value
}
}
func ==(lhs: A, rhs: A) -> Bool {
return lhs.value == rhs.value
}
var a = A(1)
var array: [A] = [a, A(2)]
array.contains(a) // true
array.contains(A(1)) // false
array.contains { $0 == A(1) } // true
array[0] == A(1) // true
class B: Equatable {
var value: Int
init(_ value: Int) {
self.value = value
}
}
func ==(lhs: B, rhs: B) -> Bool {
return lhs.value == rhs.value
}
var b = B(1)
var array2: [B] = [b, B(2)]
array2.contains(b) // true
array2.contains(B(1)) // true
array2.contains { $0 == B(1) } // true
array2[0] == B(1) // true
So you need to override NSObject.isEqual() method:
class A: NSObject {
var value: Int
init(_ value: Int) {
self.value = value
}
override func isEqual(object: AnyObject?) -> Bool {
if let rhs = object as? A {
return self == rhs
}
return false
}
}
OLD ANSWER
User class should also conform to Equatable protocol:
extension User: Equatable {}
Or you can add it directly to class definition:
public class User: NSManagedObject, Equatable {}
I am trying to extend Swift's Array class with the following func:
func containsObjectIdenticalTo(obj: T) -> Bool {
// objectPassingTest returns the first object passing the test
return objectPassingTest { x in x == obj }
}
Apparently, this won't compile as the compiler doesn't know yet if == is implemented for type T. I then change the code to this
func containsObjectIdenticalTo(obj: T) -> Bool {
return objectPassingTest {
x in
assert(x is Equatable && obj is Equatable)
return (x as Equatable) == (obj as Equatable)
} != nil
}
Which doesn't work either, since conformance against Equatable can't be checked (because Equatable wasn't defined with #obj) !
Any thoughts on this? Would be nice if there's some way to assert directly if T conforms to Equatable, but I haven't read that anywhere. Swift seems to be less dynamic than Obj-C in these stuffs.
UPDATE:
Tried this suggestion and it doesn't work (don't know exactly what <T: Equatable> is for, tho it does compile).
func containsObjectIdenticalTo<T: Equatable>(obj: T) -> Bool {
var x = self[0]
var y = self[0]
return x == y // Error here
}
Specify that T must be equatable in the Method's signature:
func containsObjectIdenticalTo<T: Equatable>(obj: T) -> Bool {/*...*/}
i got this from ExSwift : https://github.com/pNre/ExSwift
func contains <T: Equatable> (items: T...) -> Bool {
return items.all { self.indexOf($0) >= 0 }
}
func indexOf <U: Equatable> (item: U) -> Int? {
if item is Element {
if let found = find(reinterpretCast(self) as Array<U>, item) {
return found
}
return nil
}
return nil
}
func all (call: (Element) -> Bool) -> Bool {
for item in self {
if !call(item) {
return false
}
}
return true
}
maybe you can try it
How about:
func containsObjectIdenticalTo<T : Equatable>(obj: T) -> Bool {
... etc ...
}
In the end, I resorted to this solution
func containsObjectIdenticalTo<U: Equatable>(obj: U) -> Bool {
return objectPassingTest({
x in
return x as U == obj
}) != nil
}
Might not be the best (ie safest) one. But it works great.