在解决了之前的问题的基础上,但又导致了另一个问题。如果协议/类类型存储在集合中,则取回并实例化它们会引发错误。下面是一个假设的例子。该范例基于“程序到接口而不是实现”,“程序到接口”
public protocol ISpeakable { init() func speak() } class Cat : ISpeakable { required init() {} func speak() { println("Meow"); } } class Dog : ISpeakable { required init() {} func speak() { println("Woof"); } } //Test class is not aware of the specific implementations of ISpeakable at compile time class Test { func instantiateAndCallSpeak<T: ISpeakable>(Animal:T.Type) { let animal = Animal() animal.speak() } } // Users of the Test class are aware of the specific implementations at compile/runtime //works let t = Test() t.instantiateAndCallSpeak(Cat.self) t.instantiateAndCallSpeak(Dog.self) //doesn't work if types are retrieved from a collection //Uncomment to show Error - IAnimal.Type is not convertible to T.Type var animals: [ISpeakable.Type] = [Cat.self, Dog.self, Cat.self] for animal in animals { //t.instantiateAndCallSpeak(animal) //throws error } for (index:Int, value:ISpeakable.Type) in enumerate(animals) { //t.instantiateAndCallSpeak(value) //throws error }
编辑 -我当前的解决方法是遍历集合,但是由于api必须知道各种实现,所以这当然是有限的。另一个限制是这些类型的子类(例如PersianCat,GermanShepherd)将不会调用其重写的函数,否则我将进入Objective- C进行救援(NSClassFromString等),或者等待SWIFT支持此功能。
注意(背景):实用程序的用户将这些类型推送到数组中,并在通知时执行for循环
var animals: [ISpeakable.Type] = [Cat.self, Dog.self, Cat.self] for Animal in animals { if Animal is Cat.Type { if let AnimalClass = Animal as? Cat.Type { var instance = AnimalClass() instance.speak() } } else if Animal is Dog.Type { if let AnimalClass = Animal as? Dog.Type { var instance = AnimalClass() instance.speak() } } }
基本上,答案是:正确,您不能这样做。Swift需要在编译时而不是在运行时确定类型参数的具体类型。这在很多小的情况下都会出现。例如,您不能构造通用闭包并将其存储在没有类型指定的变量中。
如果我们将其简化为一个最小的测试用例,则可能会更清晰一些
protocol Creatable { init() } struct Object : Creatable { init() {} } func instantiate<T: Creatable>(Thing: T.Type) -> T { return Thing() } // works. object is of type "Object" let object = instantiate(Object.self) // (1) // 'Creatable.Type' is not convertible to 'T.Type' let type: Creatable.Type = Object.self let thing = instantiate(type) // (2)
在第1行,编译器有一个问题:T在这种情况下,应为哪种类型instantiate?这很容易,应该是Object。这是一个具体的类型,所以一切都很好。
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instantiate
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在第2行,Swift不能创建任何具体类型T。它所具有的只是Creatable一个抽象类型(我们通过代码检查知道的实际值type,但是Swift并不考虑该值,而只是类型)。可以接受和返回协议,但不能将它们设置为类型参数。今天只是不合法的Swift。
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Swift编程语言:通用参数和参数中暗示了这一点:
声明泛型类型,函数或初始化程序时,请指定泛型类型,函数或初始化程序可以使用的类型参数。这些类型参数充当占位符,当创建泛型类型的实例或调用泛型函数或初始化程序时,这些类型参数将由 实际的具体 类型参数替换。 (强调我的)
在Swift中,您将需要做的另一种尝试。
作为一项有趣的奖励,尝试明确要求不可能的事情:
let thing = instantiate(Creatable.self)
而且…迅速崩溃。
从您的进一步评论中,我认为闭包确实可以满足您的需求。您已经使协议要求构造简单(init()),但这是不必要的限制。您只需要调用者告诉函数如何构造对象。使用闭包很容易,并且完全不需要这种类型的参数化。这不是解决方法;我相信这是实现您描述的模式的更好方法。考虑以下内容(一些小的更改,以使示例更像Swift):
init()
// Removed init(). There's no need for it to be trivially creatable. // Cocoa protocols that indicate a method generally end in "ing" // (NSCopying, NSCoding, NSLocking). They do not include "I" public protocol Speaking { func speak() } // Converted these to structs since that's all that's required for // this example, but it works as well for classes. struct Cat : Speaking { func speak() { println("Meow"); } } struct Dog : Speaking { func speak() { println("Woof"); } } // Demonstrating a more complex object that is easy with closures, // but hard with your original protocol struct Person: Speaking { let name: String func speak() { println("My name is \(name)") } } // Removed Test class. There was no need for it in the example, // but it works fine if you add it. // You pass a closure that returns a Speaking. We don't care *how* it does // that. It doesn't have to be by construction. It could return an existing one. func instantiateAndCallSpeak(builder: () -> Speaking) { let animal = builder() animal.speak() } // Can call with an immediate form. // Note that Cat and Dog are not created here. They are not created until builder() // is called above. @autoclosure would avoid the braces, but I typically avoid it. instantiateAndCallSpeak { Cat() } instantiateAndCallSpeak { Dog() } // Can put them in an array, though we do have to specify the type here. You could // create a "typealias SpeakingBuilder = () -> Speaking" if that came up a lot. // Again note that no Speaking objects are created here. These are closures that // will generate objects when applied. // Notice how easy it is to pass parameters here? These don't all have to have the // same initializers. let animalBuilders: [() -> Speaking] = [{ Cat() } , { Dog() }, { Person(name: "Rob") }] for animal in animalBuilders { instantiateAndCallSpeak(animal) }
