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I'm having a little trouble understanding how I would use covariance and contravariance in the real world.

So far, the only examples I've seen have been the same old array example.

object[] objectArray = new string[] { "string 1", "string 2" };

It would be nice to see an example that would allow me to use it during my development if I could see it being used elsewhere.

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I explore covariance in this answer to (my own) question: covariance types: by example. I think you'll find it interesting, and hopefully instructive. – Cristi Diaconescu Jun 28 '13 at 11:15
up vote 46 down vote accepted

Let's say you have a class Person and a class that derives from it, Teacher. You have some operations that take an IEnumerable<Person> as the argument. In your School class you have a method that returns an IEnumerable<Teacher>. Covariance allows you to directly use that result for the methods that take an IEnumerable<Person>.

public class Person { } 

public class Teacher : Person { } 

public class MailingList
    public void Add( IEnumerable<Person> people ) { ... }

public class School
    public IEnumerable<Teacher> GetTeachers() { ... }


var teachers = school.GetTeachers();
var mailingList = new MailingList();
mailingList.Add( teachers );
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Teacher as a person (human)? That's not a real world example... – Filip Bartuzi Dec 4 '14 at 23:34
@FilipBartuzi - if, like me when I wrote this answer, you were employed at a University that is very much a real world example. – tvanfosson Dec 5 '14 at 2:16
// Contravariance
interface IGobbler<in T> {
    void gobble(T t);

// Since a QuadrupedGobbler can gobble any four-footed
// creature, it is OK to treat it as a donkey gobbler.
IGobbler<Donkey> dg = new QuadrupedGobbler();

// Covariance
interface ISpewer<out T> {
    T spew();

// A MouseSpewer obviously spews rodents (all mice are
// rodents), so we can treat it as a rodent spewer.
ISpewer<Rodent> rs = new MouseSpewer();
Rodent r = rs.spew();

For completeness…

// Invariance
interface IHat<T> {
    void hide(T t);
    T pull();

// A RabbitHat…
IHat<Rabbit> rHat = RabbitHat();

// …cannot be treated covariantly as a mammal hat…
IHat<Mammal> mHat = rHat;      // Compiler error
// …because…
mHat.hide(new Dolphin());      // Hide a dolphin in a rabbit hat??

// It also cannot be treated contravariantly as a cottontail hat…
IHat<CottonTail> cHat = rHat;  // Compiler error
// …because…
rHat.hide(new MarshRabbit());
cHat.pull();                   // Pull a marsh rabbit out of a cottontail hat??
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I like this realistic example. I was just writing some donkey gobbling code last week and i was so glad that we have covariance now. :-) – Eric Lippert Apr 18 '10 at 15:26
Those are some awesome potential robot names. – Dan Tao Apr 18 '10 at 15:43
@EricLippert The donkeygobberler is contravariant not covariant. It's still cool though. – javadba Feb 2 '14 at 5:27
This comment above with @javadba telling THE EricLippert what is covariance and contravariance is a realistic covariant example of me telling my granny how to suck eggs! :p – iAteABug_And_iLiked_it Dec 30 '14 at 13:47
Wow this is awesome, made my day – Chef_Code Nov 10 '15 at 5:56
class A {}
class B : A {}

public void SomeFunction()
    var someListOfB = new List<B>();
    someListOfB.Add(new B());
    someListOfB.Add(new B());
    someListOfB.Add(new B());

public void SomeFunctionThatTakesA(IEnumerable<A> input)
    // Before C# 4, you couldn't pass in List<B>:
    // cannot convert from
    // 'System.Collections.Generic.List<ConsoleApplication1.B>' to
    // 'System.Collections.Generic.IEnumerable<ConsoleApplication1.A>'

Basically whenever you had a function that takes an Enumerable of one type, you couldn't pass in an Enumerable of a derived type without explicitly casting it.

Just to warn you about a trap though:

var ListOfB = new List<B>();
if(ListOfB is IEnumerable<A>)
    // In C# 4, this branch will
    // execute...
    Console.Write("It is A");
else if (ListOfB is IEnumerable<B>)
    // ...but in C# 3 and earlier,
    // this one will execute instead.
    Console.Write("It is B");

That is horrible code anyway, but it does exist and the changing behavior in C# 4 might introduce subtle and hard to find bugs if you use a construct like this.

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That helps my understanding a little more, thanks Michael – Vince Panuccio Apr 18 '10 at 13:38
So this affects collections more than anything, because in c# 3 you could pass a more derived type into a method of a less derived type. – Vince Panuccio Apr 18 '10 at 13:50
Yes, the big change is that IEnumerable now supports this, whereas it didn't before. – Michael Stum Apr 18 '10 at 13:51

The in and out keywords control the compiler's casting rules for interfaces and delegates with generic parameters:

interface IInvariant<T> {
    // This interface can not be implicitly cast AT ALL
    // Used for non-readonly collections
    IList<T> GetList { get; }
    // Used when T is used as both argument *and* return type
    T Method(T argument);

interface ICovariant<out T> {
    // This interface can be implicitly cast to LESS DERIVED (upcasting)
    // Used for readonly collections
    IEnumerable<T> GetList { get; }
    // Used when T is used as return type
    T Method();

interface IContravariant<in T> {
    // This interface can be implicitly cast to MORE DERIVED (downcasting)
    // Usually means T is used as argument
    void Method(T argument);

class Casting {

    IInvariant<Animal> invariantAnimal;
    ICovariant<Animal> covariantAnimal;
    IContravariant<Animal> contravariantAnimal;

    IInvariant<Fish> invariantFish;
    ICovariant<Fish> covariantFish;
    IContravariant<Fish> contravariantFish;

    public void Go() {

        // NOT ALLOWED invariants do *not* allow implicit casting:
        invariantAnimal = invariantFish; 
        invariantFish = invariantAnimal; // NOT ALLOWED

        // ALLOWED covariants *allow* implicit upcasting:
        covariantAnimal = covariantFish; 
        // NOT ALLOWED covariants do *not* allow implicit downcasting:
        covariantFish = covariantAnimal; 

        // NOT ALLOWED contravariants do *not* allow implicit upcasting:
        contravariantAnimal = contravariantFish; 
        // ALLOWED contravariants *allow* implicit downcasting
        contravariantFish = contravariantAnimal; 



// .NET Framework Examples:
public interface IList<T> : ICollection<T>, IEnumerable<T>, IEnumerable { }
public interface IEnumerable<out T> : IEnumerable { }

class Delegates {

    // When T is used as both "in" (argument) and "out" (return value)
    delegate T Invariant<T>(T argument);

    // When T is used as "out" (return value) only
    delegate T Covariant<out T>();

    // When T is used as "in" (argument) only
    delegate void Contravariant<in T>(T argument);

    // Confusing
    delegate T CovariantBoth<out T>(T argument);

    // Confusing
    delegate T ContravariantBoth<in T>(T argument);

    // From .NET Framework:
    public delegate void Action<in T>(T obj);
    public delegate TResult Func<in T, out TResult>(T arg);

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Here you can find 2 simple examples of Covariance and contravariance for delegates.

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Here's what I put together to help me understand the difference

public interface ICovariant<out T> { }
public interface IContravariant<in T> { }

public class Covariant<T> : ICovariant<T> { }
public class Contravariant<T> : IContravariant<T> { }

public class Fruit { }
public class Apple : Fruit { }

public class TheInsAndOuts
    public void Covariance()
        ICovariant<Fruit> fruit = new Covariant<Fruit>();
        ICovariant<Apple> apple = new Covariant<Apple>();

        Covariant(apple); //apple is being upcasted to fruit, without the out keyword this will not compile

    public void Contravariance()
        IContravariant<Fruit> fruit = new Contravariant<Fruit>();
        IContravariant<Apple> apple = new Contravariant<Apple>();

        Contravariant(fruit); //fruit is being downcasted to apple, without the in keyword this will not compile

    public void Covariant(ICovariant<Fruit> person)

    public void Contravariant(IContravariant<Apple> person)


ICovariant<Fruit> apple = new Covariant<Apple>(); //bc it's covariant
IContravariant<Apple> fruit = new Contravariant<Fruit>(); //bc it's contravariant
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The following code example shows covariance and contravariance support for method groups

static object GetObject() { return null; }
static void SetObject(object obj) { }

static string GetString() { return ""; }
static void SetString(string str) { }

static void Test()
    // Covariance. A delegate specifies a return type as object, 
    // but you can assign a method that returns a string.
    Func<object> del = GetString;

    // Contravariance. A delegate specifies a parameter type as string, 
    // but you can assign a method that takes an object.
    Action<string> del2 = SetObject;
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