What is the difference between <out T> and <T>? For example:

public interface IExample<out T>


public interface IExample<T>
  • 2
    Good example would be IObservable<T> and IObserver<T>, defined in system ns in mscorlib. public interface IObservable<out T>, and public interface IObserver<in T>. Similarly, IEnumerator<out T>, IEnumerable<out T>
    – VivekDev
    Feb 6, 2016 at 1:00
  • 3
    The best explanation I met: agirlamonggeeks.com/2019/05/29/… .(< in T> <– means that T can be only passed as a parameter to a method; <out T> <– means that T can be only returned as method results ) Aug 16, 2019 at 8:55

5 Answers 5


The out keyword in generics is used to denote that the type T in the interface is covariant. See Covariance and contravariance for details.

The classic example is IEnumerable<out T>. Since IEnumerable<out T> is covariant, you're allowed to do the following:

IEnumerable<string> strings = new List<string>();
IEnumerable<object> objects = strings;

The second line above would fail if this wasn't covariant, even though logically it should work, since string derives from object. Before variance in generic interfaces was added to C# and VB.NET (in .NET 4 with VS 2010), this was a compile time error.

After .NET 4, IEnumerable<T> was marked covariant, and became IEnumerable<out T>. Since IEnumerable<out T> only uses the elements within it, and never adds/changes them, it's safe for it to treat an enumerable collection of strings as an enumerable collection of objects, which means it's covariant.

This wouldn't work with a type like IList<T>, since IList<T> has an Add method. Suppose this would be allowed:

IList<string> strings = new List<string>();
IList<object> objects = strings;  // NOTE: Fails at compile time

You could then call:

objects.Add(new Image()); // This should work, since IList<object> should let us add **any** object

This would, of course, fail - so IList<T> can't be marked covariant.

There is also, btw, an option for in - which is used by things like comparison interfaces. IComparer<in T>, for example, works the opposite way. You can use a concrete IComparer<Foo> directly as an IComparer<Bar> if Bar is a subclass of Foo, because the IComparer<in T> interface is contravariant.

  • 5
    @ColeJohnson Because Image is an abstract class ;) You can do new List<object>() { Image.FromFile("test.jpg") }; with no problems, or you can do new List<object>() { new Bitmap("test.jpg") }; as well. The problem with yours is that new Image() isn't allowed (you can't do var img = new Image(); either) Aug 20, 2012 at 16:28
  • 4
    a generic IList<object> is a bizarre example, if you want objects you don't need generics.
    – Jodrell
    Dec 18, 2013 at 14:54
  • 7
    @ReedCopsey Aren't you contradicting your own answer in your comment?
    – MarioDS
    Sep 21, 2015 at 10:05

For remembering easily the usage of in and out keyword (also covariance and contravariance), we can image inheritance as wrapping:

String : Object
Bar : Foo


  • 17
    Isn't this the wrong way around? Contravariance = in = allows less derived types to be used in place of more derived. / Covariance = out = allows more derived types to be used in place of less derived. Personally, looking at your diagram, I read it as the opposite of the that.
    – Sam Shiles
    Aug 24, 2017 at 7:19
  • co u variant (: for me
    – snr
    Mar 20, 2020 at 11:25
  • Can we use them at the same time? Jul 26 at 20:26


class Fruit {}

class Banana : Fruit {}

interface ICovariantSkinned<out T> {}

interface ISkinned<T> {}

and the functions,

void Peel(ISkinned<Fruit> skinned) { }

void Peel(ICovariantSkinned<Fruit> skinned) { }

The function that accepts ICovariantSkinned<Fruit> will be able to accept ICovariantSkinned<Fruit> or ICovariantSkinned<Banana> because ICovariantSkinned<T> is a covariant interface and Banana is a type of Fruit,

the function that accepts ISkinned<Fruit> will only be able to accept ISkinned<Fruit>.


"out T" means that type T is "covariant". That restricts T to appear only as a returned (outbound) value in methods of the generic class, interface or method. The implication is that you can cast the type/interface/method to an equivalent with a super-type of T.
E.g. ICovariant<out Dog> can be cast to ICovariant<Animal>.

  • 26
    I didn't realize that out enforces that T can be returned only, until I read this answer. The whole concept makes more sense now!
    – MarioDS
    Sep 21, 2015 at 10:09

From the link you posted....

For generic type parameters, the out keyword specifies that the type parameter is covariant.

EDIT: Again, from the link you posted

For more information, see Covariance and Contravariance (C# and Visual Basic). http://msdn.microsoft.com/en-us/library/ee207183.aspx


Your Answer

By clicking “Post Your Answer”, you agree to our terms of service, privacy policy and cookie policy

Not the answer you're looking for? Browse other questions tagged or ask your own question.