Look at the following example (partially taken from MSDN Blog):

class Animal { }
class Giraffe : Animal { }

static void Main(string[] args)
    // Array assignment works, but...
    Animal[] animals = new Giraffe[10]; 

    // implicit...
    List<Animal> animalsList = new List<Giraffe>();

    // ...and explicit casting fails
    List<Animal> animalsList2 = (List<Animal>) new List<Giraffe>();

Is this a covariance problem? Will this be supported in the future C# release and are there any clever workarounds (using only .NET 2.0)?


Well this certainly won't be supported in C# 4. There's a fundamental problem:

List<Giraffe> giraffes = new List<Giraffe>();
giraffes.Add(new Giraffe());
List<Animal> animals = giraffes;
animals.Add(new Lion()); // Aargh!

Keep giraffes safe: just say no to unsafe variance.

The array version works because arrays do support reference type variance, with execution time checking. The point of generics is to provide compile-time type safety.

In C# 4 there will be support for safe generic variance, but only for interfaces and delegates. So you'll be able to do:

Func<string> stringFactory = () => "always return this string";
Func<object> objectFactory = stringFactory; // Safe, allowed in C# 4

Func<out T> is covariant in T because T is only used in an output position. Compare that with Action<in T> which is contravariant in T because T is only used in an input position there, making this safe:

Action<object> objectAction = x => Console.WriteLine(x.GetHashCode());
Action<string> stringAction = objectAction; // Safe, allowed in C# 4

IEnumerable<out T> is covariant as well, making this correct in C# 4, as pointed out by others:

IEnumerable<Animal> animals = new List<Giraffe>();
// Can't add a Lion to animals, as `IEnumerable<out T>` is a read-only interface.

In terms of working around this in your situation in C# 2, do you need to maintain one list, or would you be happy creating a new list? If that's acceptable, List<T>.ConvertAll is your friend.

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  • +1 just to add to Jon's answer (not that he needs any help ), following the Func<string> to Func<object> example and the fact that T is contravariant in Action. The following Action<object> = Action<string> would not work in C# 4. – Stan R. Jan 9 '10 at 16:17
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    What is wrong with animals.Add(new Lion()); // Aargh!? If you can cast a Lion and use it as an Animal, and if you are using all of the elements in animals as Animals, then what is the problem? – Jeff Apr 12 '17 at 20:04
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    @Jeff: Because animals actually refers to a List<Giraffe>. So you'd end up with a Lion reference in a List<Giraffe>, which is bad... – Jon Skeet Apr 12 '17 at 20:32
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    Worth mentioning that a better fit for List<T> might be IReadOnlyList<out T> which is also safely covariant, being immutable. – x0n Oct 18 '18 at 15:01
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    @x0n: I'm happy for you to mention that, but I'm not going to update all my old answer with types introduced later on. – Jon Skeet Oct 18 '18 at 15:08

It will work in C#4 for IEnumerable<T>, so you can do:

IEnumerable<Animal> animals = new List<Giraffe>();

However List<T> is not a covarient projection, so you cannot assign lists as you have done above since you could do this:

List<Animal> animals = new List<Giraffe>();
animals.Add(new Monkey());

Which is clearly not valid.

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In terms of List<T>, I'm afraid you're out of luck. However, .NET 4.0/C# 4.0 adds support for covariant/contravariant interfaces. Specifically, IEnumerable<T> is now defined as IEnumerable<out T>, which means that the type parameter is now covariant.

This means you can do something like this in C# 4.0...

// implicit casting
IEnumerable<Animal> animalsList = new List<Giraffe>();

// explicit casting
IEnumerable<Animal> animalsList2 = (IEnumerable<Animal>) new List<Giraffe>();

Note: Array types have also been covariant (at least since .NET 1.1).

I think it's a shame that variance support wasn't added for IList<T> and other similar generic interfaces (or generic classes even), but oh well, at least we have something.

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    You can't make IList<T> covariant safely with declaration-side variance annotations. – Eric Lippert Jan 9 '10 at 19:34

Covariance/contravariance can't be supported on mutable collections as others have mentioned because it's impossible to guarantee type safety both ways at compile time; however, it is possible to do a quick one-way conversion in C# 3.5, if that is what you're looking for:

List<Giraffe> giraffes = new List<Giraffe>();
List<Animal> animals = giraffes.Cast<Animal>().ToList();

Of course it's not the same thing, it's not actually covariance - you're actually creating another list, but it is a "workaround" so to speak.

In .NET 2.0, you can take advantage of array covariance to simplify the code:

List<Giraffe> giraffes = new List<Giraffe>();
List<Animal> animals = new List<Animal>(giraffes.ToArray());

But be aware that you're actually creating two new collections here.

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  • I think these are quite good workarounds for my simple application. At least they're good for readability - not for performance. – AndiDog Jan 9 '10 at 16:26
  • @JohnAskew: I'm not sure what your point is here - there's no Cast method on IList<T>, it's the Enumerable<T>.Cast<T2> extension method, which takes an IEnumerable<T> and explicitly casts every element to T2 and then returns it (as an IEnumerable<T2>, not an IList<T2>). It has nothing to do with IList<T> at all, save for the fact that IList<T> happens to inherit from IEnumerable<T> and thus supports the Enumerable<T> extension methods. There's no covariance whatsoever there. – Aaronaught Jul 22 '14 at 14:17
  • I didn't see the reference to C# 3.5 and was referring to C# 4.0 where the IEnumerable<T> interface was updated to be IEnumerable<out T> and the Cast<T> method changed to use covariance: IEnumerable<TResult> typedSource = source as IEnumerable<TResult> rather than an iteration with explicit casting. – John Askew Jul 23 '14 at 14:22

GenericClass<DerivedClass> and GenericClass<BaseClass> and two distinct closed constructed generic types of GenericClass<> open generic type and they not inherit one from the other.

So you can't cast GenericClass<B> to GenericClass<A> even if B inherits from A.

It is like you ask to cast this:

class A2 : A1;
class B2 : B1;

var a2 = new A2();
var b2 = new B2();
var x = (A1)b2;

GenericClass<DerivedClass> and GenericClass<BaseClass> are as distinct as A1 and B2.

But they are all object.

And since there is no diamond operator in C# yet, you can't use true polymorphism on open generic type underlying to closed constructed types like this:

var x = (GenericClass<>)b;

You can't create list like this:

List<> list;

You can't do polymorphism on such list... and it is a lack in genericity here.

For example, in C# you can't create a List<Washer<>> instance to have some Washer<Cat> and some Washer<Dog> to operate Wash() on them... and to do that you need an ugly interface pattern...

Generics -Open and closed constructed Types

About the lack of true generic polymorphism and the missing diamond operator in C#

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