271

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

public interface IExample<out T>
{
    ...
}

vs.

public interface IExample<T>
{
    ...
}
2
  • 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
  • 5
    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

8 Answers 8

279

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(7); // 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.

3
  • 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
83

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

String : Object
Bar : Foo

in/out

4
  • 18
    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 Mar 20, 2020 at 11:25
  • Can we use them at the same time? Jul 26, 2022 at 20:26
  • @SamShiles and technically, a derived type (string) should be "bigger" than its base type (object) because it should have more members. So the image works if you just swap the types.
    – Luke Vo
    Jan 31, 2023 at 4:48
67

consider,

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>.

59

"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>.

1
  • 29
    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
8

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

0
4

I think this screenshot from VS2022 is pretty descriptive - it says what sort of constraints this put on generics:

generics variance constraing

2
  • 2
    Screenshots of text are a terrible way to present text.
    – DavidW
    Oct 28, 2022 at 20:09
  • 2
    I disagree, cause it presents real VS IDE feedback. Feel free to edit my post @DavidW
    – lissajous
    Oct 28, 2022 at 21:46
3
covariant out
//I need a fruit farm(base class) so i can produce fruits(base type)
//But what I have is an apple farm(derived class) that produce apples (derive type)
IProducer<Apple> appleFarm = new AppleProducer(); 
//thats ok, I'll just mark it as covariant(out) since apple is also a fruit
IProducer<Fruit> fruitFarm = appleFarm; 

Apple apple = appleFarm.Produce();
//I can produce fruits since apple is a fruit
Fruit fruit = apple; 
contravariant in
//I need an apple bakery(derive class) so i can use my apples(derive type)
//But what I have is a fruit bakery(base class) that uses fruits(base type)
IConsumer<Fruit> fruitBakery = new FruitConsumer();
//thats ok, I'll just mark it as contravariant(in) since a fruit bakery can also consume apples
IConsumer<Apple> appleBakery = fruitBakery;

//can consume apples and any fruits
appleBakery.Consume(new Apple());
fruitBakery.Consume(new Fruit());
fruitBakery.Consume(new Apple());

So basically:

  • if you mark an interface generic as covariant, it must be able to output the generic type, and it allows you to convert a derive type of the generic type into its base type.
IProducer<Apple> appleFarm = new AppleProducer(); 
IProducer<Fruit> fruitFarm = appleFarm; 

Apple apple = appleFarm.Produce();
Fruit fruit = apple; 
  • if you mark an interface generic as contravariant, it must be able to input the generic type, and it allows you to convert a derive type of the generic type into its base type.
IConsumer<Fruit> fruitBakery = new FruitConsumer();
IConsumer<Apple> appleBakery = fruitBakery;

fruitBakery.Consume(new Apple());
fruitBakery.Consume(new Fruit());
appleBakery.Consume(new Apple());

To understand why, look up liskov subsitution principle.

full code:

public interface IProducer<out T>
{
    T Produce();
}
 
public class Fruit { }
 
public class Apple : Fruit { }
 
public class FruitProducer : IProducer<Fruit>
{
    public Fruit Produce() => new Fruit();
}
 
public class AppleProducer : IProducer<Apple>
{
    public Apple Produce() => new Apple();
}
 
public interface IConsumer<in T>
{
    void Consume(T item);
}
 
public class FruitConsumer : IConsumer<Fruit>
{
    public void Consume(Fruit item)
    {
        // Consume the fruit
    }
}
 
public class AppleConsumer : IConsumer<Apple>
{
    public void Consume(Apple item)
    {
        // Consume the apple
    }
}
2

The simplest explanation I found is in this article stated as

interface ISomeName<in T> <– means that T can be only passed as a parameter to a method (it enters inteface’s methods, so it goes inside, maybe that’s why we use here keyword ‘in’… Hmm, no, that’s just a coincidence ?)

interface ISomeName<out T> <– means that T can be only returned as method results (it is what we receive from a method so it goes out of it – wow, again sounds legit!)

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