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.


11 Answers 11


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> fruit) { }

    public void Contravariant(IContravariant<Apple> apple) { }


ICovariant<Fruit> apple = new Covariant<Apple>(); //because it's covariant
IContravariant<Apple> fruit = new Contravariant<Fruit>(); //because it's contravariant
  • 16
    This is the best thing I have seen so far that is clear and concise.Great example!
    – Rob L
    Commented Aug 21, 2016 at 17:14
  • 8
    How can the fruit be downcasted to apple (in the Contravariance example) when Fruit is the parent of Apple? Commented Aug 19, 2018 at 7:26
  • 4
    I feel the confusion is more about "why". The fruit is downcasted to apple, and passed into some function. But the function will still use the potentially fake apple as the original fruit instead of an apple. I feel the contravarince is just for convenience that allows a less derived type to be passed in as a more derived type, but it will still be used as the original less derived type.
    – DavidY
    Commented Feb 20, 2021 at 13:52
// 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??
  • 171
    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. :-) Commented Apr 18, 2010 at 15:26
  • 4
    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 Commented Dec 30, 2014 at 13:47
  • 3
    The question didn't ask what contravariance and covariance can do, it asked why would you need to use it. Your example is far from practical because it doesn't require either. I can create a QuadrupedGobbler and treat it as itself (assign it to IGobbler<Quadruped>) and it can still gobble up Donkeys (I can pass a Donkey in to the Gobble method that requires a Quadruped). No contravariance needed. That's cool that we can treat a QuadrupedGobbler as a DonkeyGobbler, but why would we need to, in this case, if a QuadrupedGobbler can already gobble up Donkeys?
    – wired_in
    Commented Feb 27, 2016 at 0:21
  • 2
    @wired_in Because when you only care about donkeys, being more general can get in the way. For example, if you have a farm that supplies donkeys to be gobbled, you can express this as void feed(IGobbler<Donkey> dg). If you took an IGobbler<Quadruped> as a parameter instead, you couldn't pass in a dragon that only eats donkeys. Commented Feb 27, 2016 at 0:41
  • 3
    Waaay late to the party, but this is about the best written example I've seen around SO. Makes complete sense while being ridiculous. I'm going to have to up my game with answers... Commented Nov 16, 2018 at 14:24

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>, substituting a more derived type for a less derived (more generic) type. Contravariance, counter-intuitively, allows you to use a more generic type, where a more derived type is specified.

See also Covariance and Contravariance in Generics on MSDN.


public class Person 
     public string Name { get; set; }

public class Teacher : Person { } 

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

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

public class PersonNameComparer : IComparer<Person>
    public int Compare(Person a, Person b) 
        if (a == null) return b == null ? 0 : -1;
        return b == null ? 1 : Compare(a,b);

    private int Compare(string a, string b)
        if (a == null) return b == null ? 0 : -1;
        return b == null ? 1 : a.CompareTo(b);


var teachers = school.GetTeachers();
var mailingList = new MailingList();

// Add() is covariant, we can use a more derived type

// the Set<T> constructor uses a contravariant interface, IComparer<in T>,
// we can use a more generic type than required.
// See https://msdn.microsoft.com/en-us/library/8ehhxeaf.aspx for declaration syntax
var teacherSet = new SortedSet<Teachers>(teachers, new PersonNameComparer());
  • 15
    @FilipBartuzi - if, like me when I wrote this answer, you were employed at a University that is very much a real world example.
    – tvanfosson
    Commented Dec 5, 2014 at 2:16
  • 8
    How can this be marked the answer when it doesnt answer the question and doesnt give any example of using co /contra variance in c#?
    – barakcaf
    Commented Jun 28, 2016 at 12:02
  • @barakcaf added an example of contravariance. not sure why you weren't seeing the example of covariance - perhaps you needed to scroll the code down - but I added some comments around that.
    – tvanfosson
    Commented Jun 28, 2016 at 13:53
  • 1
    @tvanfosson the code uses co/contra, i ment that it doesn't show how to declare it. The example doesn't show usage of in/out in the generic declaration while the other answer does.
    – barakcaf
    Commented Jun 28, 2016 at 13:58
  • So, if I get it right, covariance is what allows Liskov's substitution principle in C#, is that right? Commented Dec 3, 2017 at 10:16

Here's a simple example using an inheritance hierarchy.

Given the simple class hierarchy:

enter image description here

And in code:

public abstract class LifeForm  { }
public abstract class Animal : LifeForm { }
public class Giraffe : Animal { }
public class Zebra : Animal { }

Invariance (i.e. generic type parameters not decorated with in or out keywords)

Seemingly, a method such as this

public static void PrintLifeForms(IList<LifeForm> lifeForms)
    foreach (var lifeForm in lifeForms)

... should accept a heterogeneous collection: (which it does)

var myAnimals = new List<LifeForm>
    new Giraffe(),
    new Zebra()
PrintLifeForms(myAnimals); // Giraffe, Zebra

However, passing a collection of a more derived type fails!

var myGiraffes = new List<Giraffe>
    new Giraffe(), // "Jerry"
    new Giraffe() // "Melman"
PrintLifeForms(myGiraffes); // Compile Error!

cannot convert from 'System.Collections.Generic.List<Giraffe>' to 'System.Collections.Generic.IList<LifeForm>'

Why? Because the generic parameter IList<LifeForm> is not covariant - IList<T> is invariant, so IList<LifeForm> only accepts collections (which implement IList) where the parameterized type T must be LifeForm.

If the method implementation of PrintLifeForms was malicious (but has same method signature), the reason why the compiler prevents passing List<Giraffe> becomes obvious:

 public static void PrintLifeForms(IList<LifeForm> lifeForms)
     lifeForms.Add(new Zebra());

Since IList permits adding or removal of elements, any subclass of LifeForm could thus be added to the parameter lifeForms, and would violate the type of any collection of derived types passed to the method. (Here, the malicious method would attempt to add a Zebra to var myGiraffes). Fortunately, the compiler protects us from this danger.

Covariance (Generic with parameterized type decorated with out)

Covariance is widely used with immutable collections (i.e. where new elements cannot be added or removed from a collection)

The solution to the above problem - i.e. passing a collection of a more derived type collection<Giraffe> to a function accepting a collection of a less derived superclass accepting collection<LifeForm> - is to ensure that a covariant generic collection type is used, e.g. IEnumerable (defined as IEnumerable<out T>). IEnumerable has no methods to change to the collection, and as a result of the out covariance, any collection with subtype of LifeForm may now be passed to the method:

public static void PrintLifeForms(IEnumerable<LifeForm> lifeForms)
    foreach (var lifeForm in lifeForms)

PrintLifeForms can now be called with Zebras, Giraffes and any IEnumerable<> of any subclass of LifeForm.

var myGiraffes = new List<Giraffe>
    new Giraffe(), // "Jerry"
    new Giraffe() // "Melman"
PrintLifeForms(myGiraffes); // All good!

Contravariance (Generic with parameterized type decorated with in)

Contravariance is frequently used when functions are passed as parameters.

Here's an example of a function, which takes an Action<Zebra> as a parameter, and invokes it on a known instance of a Zebra:

public void PerformZebraAction(Action<Zebra> zebraAction)
    var zebra = new Zebra();

As expected, this works just fine:

var myAction = new Action<Zebra>(z => Console.WriteLine("I'm a zebra"));
PerformZebraAction(myAction); // I'm a zebra

Intuitively, this will fail:

var myAction = new Action<Giraffe>(g => Console.WriteLine("I'm a giraffe"));

cannot convert from 'System.Action<Giraffe>' to 'System.Action<Zebra>'

However, this succeeds

var myAction = new Action<Animal>(a => Console.WriteLine("I'm an animal"));
PerformZebraAction(myAction); // I'm an animal

and even this also succeeds:

var myAction = new Action<object>(a => Console.WriteLine("I'm an amoeba"));
PerformZebraAction(myAction); // I'm an amoeba

Why? Because Action is defined as Action<in T>, i.e. it is contravariant, meaning that for Action<Zebra> myAction, that myAction can be at "most" a Action<Zebra>, but an action with a parameter of a less derived superclass of Zebra is also acceptable.

Although this may be non-intuitive at first (e.g. how can an Action<object> be passed as a parameter requiring Action<Zebra> ?), if you unpack the steps, you will note that the called function (PerformZebraAction) itself is responsible for passing data (in this case a Zebra instance) to the function - the data doesn't come from the calling code.

Because of the inverted approach of using higher order functions in this manner, by the time the Action is invoked, it is the more derived Zebra instance which is invoked against the zebraAction function (passed as a parameter), although the function itself uses a less derived type.

  • 13
    This is a great explanation for the different variance options, since it talks through the example and also clarifies why the compiler restricts or permits without the in/out keywords
    – Vikhram
    Commented Nov 13, 2018 at 14:45
  • Where is the in keyword used for the contravariance ? Commented May 4, 2020 at 4:47
  • @javadba in the above, Action<in T> and Func<in T, out TResult> are contravariant in the input type. (My examples use existing invariant (List), covariant (IEnumerable) and contravariant (Action, Func) types)
    – StuartLC
    Commented May 4, 2020 at 9:53
  • Ok I don't do C# so would not know that. Commented May 4, 2020 at 11:25
  • 3
    This is by far the most easily understood explanation of those provided.
    – Adrian K
    Commented Sep 13, 2021 at 4:51

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);

  • Assuming Fish is a subtype of Animal. Great answer by the way. Commented Apr 10, 2017 at 14:07
  • In your example near the end: "delegate T ContravariantBoth<in T>(T argument);", isn't T contravariant and can't be used as an output? I don't think that will compile.
    – Kyle B
    Commented Dec 28, 2021 at 16:05
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.

  • 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.
    – Razor
    Commented Apr 18, 2010 at 13:50
  • 3
    Yes, the big change is that IEnumerable now supports this, whereas it didn't before. Commented Apr 18, 2010 at 13:51


In the real world, you can always use a shelter for animals instead of a shelter for rabbits because every time an animal shelter hosts a rabbit it is an animal. However, if you use a rabbit shelter instead of an animal shelter its staff can get eaten by a tiger.

In code, this means that if you have an IShelter<Animal> animals you can simply write IShelter<Rabbit> rabbits = animals if you promise and use T in the IShelter<T> only as method parameters like so:

public class Contravariance
    public class Animal { }
    public class Rabbit : Animal { }

    public interface IShelter<in T>
        void Host(T thing);

    public void NoCompileErrors()
        IShelter<Animal> animals = null;
        IShelter<Rabbit> rabbits = null;

        rabbits = animals;

and replace an item with a more generic one, i.e. reduce the variance or introduce contravariance.


In the real world, you can always use a supplier of rabbits instead of a supplier of animals because every time a rabbit supplier gives you a rabbit it is an animal. However, if you use an animal supplier instead of a rabbit supplier you can get eaten by a tiger.

In code, this means that if you have an ISupply<Rabbit> rabbits you can simply write ISupply<Animal> animals = rabbits if you promise and use T in the ISupply<T> only as method return values like so:

public class Covariance
    public class Animal { }
    public class Rabbit : Animal { }

    public interface ISupply<out T>
        T Get();

    public void NoCompileErrors()
        ISupply<Animal> animals = null;
        ISupply<Rabbit> rabbits = null;

        animals = rabbits;

and replace an item with a more derived one, i.e. increase the variance or introduce covariance.

All in all, this is just a compile-time checkable promise from you that you would treat a generic type in a certain fashion to keep the type safety and not get anyone eaten.

You might want to give this a read to double-wrap your head around this.

  • 1
    you can get eaten by a tiger That was worth an upvote Commented May 4, 2020 at 4:33
  • Your comment on contravariance is interesting. I am reading into it as indicating a operational requirement: that the more general type must support the use cases of all types derived from it. So in this case the animal shelter must be able to support sheltering every animal type. In that case adding a new subclass might break the superclass! That is - if we add a subtype Tyrannosaurus Rex then it could wreck our existing animal shelter. Commented May 4, 2020 at 4:39
  • (Continued). That differs sharply from the covariance that is clearly described structurally: all more specific sub-types support the operations defined in the super type - but not necessarily in the same manner. Commented May 4, 2020 at 4:42
  • This is such a great example, since it also visualizes a mental bridge for giving animals in to a shelter, as well as taking animals out of a supply. Great summary! Commented Sep 9, 2021 at 18:01


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;

The converter delegate helps me to visualise both concepts working together:

delegate TOutput Converter<in TInput, out TOutput>(TInput input);

TOutput represents covariance where a method returns a more specific type.

TInput represents contravariance where a method is passed a less specific type.

public class Dog { public string Name { get; set; } }
public class Poodle : Dog { public void DoBackflip(){ System.Console.WriteLine("2nd smartest breed - woof!"); } }

public static Poodle ConvertDogToPoodle(Dog dog)
    return new Poodle() { Name = dog.Name };

List<Dog> dogs = new List<Dog>() { new Dog { Name = "Truffles" }, new Dog { Name = "Fuzzball" } };
List<Poodle> poodles = dogs.ConvertAll(new Converter<Dog, Poodle>(ConvertDogToPoodle));

Though I appreciate the other answers, has always given me insight, I think this is how you can start easily!

using System;
using System.Collections.Generic;
using System.Linq;
using System.Text.RegularExpressions;

namespace Variance
    public class Program
        public static void Main(string[] args)
            IResidential<object> res1 = new House<object>();
            IResidential<object> res2 = new Apartment<object>();
            //IResidential<object> res2 = new Apartment<string>();
            House<object> house1 = new House<object>();
            //House<object> house1 = new House<string>();
            IShelter<object> shl1 = new Bunker<object>();
            IShelter<object> shl2 = new Bunker<string>();
            IMovable<object> mvb1 = new Tank<object>();
            //IMovable<object> mbv2 = new Car<string>();
            IMovable<string> mbv2 = new Car<object>();
    interface IResidential<T> {}
    class House<T> : IResidential<T> {}
    class Apartment<T> : IResidential<T> {}
    interface IShelter<out T> {}
    class Bunker<T> : IShelter<T> {}
    class Trench<T> : IShelter<T> {}
    //class Trench<out T> : IShelter<T> {}
    interface IMovable<in T> {}
    class Tank<T> : IMovable<T> {}
    class Car<T> : IMovable<T> {}
    interface IAnimal<out U, in V>
        U GetEnergy();
        //V GetEnergy();
        void SetEnergy(V energy);
        //void SetEnergy(U energy);
        U GetSetEnergy(V energy);

I stumbled upon this method of copying a List to another in the Java library (Don't know if C# has similar implementations, I think the following Java code is simple enough to show the point though):


Essentially is:

    public static <T> void copy(List<? super T> dest, List<? extends T> src) {
        //skipped some checks and optimization code...
            ListIterator<? super T> di=dest.listIterator();
            ListIterator<? extends T> si=src.listIterator();
            for (int i=0; i<srcSize; i++) {

Where List<? extends T> expressed covariance (accepting a List whose actual value of the type parameter is extending T), while List<? super T> expressed contravariance (accepting a List whose actual value of the type parameter is extended by T).

An in-depth view on this is, when dealing with method interfaces (or a method signature along side with the return type):

  • Covariance usually only being useful for return types (when used for method parameters, there is no way to know what is the exact subtype the method can accept, so the only valid value you can use is null in Java, which is the only value that can be assigned to any reference type given).

  • Contravariance is only being useful for method parameter types (when used for return types, there is no way to know what is the exact super type the method returns, so the only valid value is Object in Java, which is the only type that can annotate any reference given).

And this principle seems to be referenced as PECS (Producer Extends, Consumer Super).

  • So the animal feeder and dog feeder example (which says animal feeder is a subtype of dog feeder, so that a animal feeder can feed a dog) is somewhat invalid or missing the point IMO, because when you get something like "a super type of Dog", how do you know you can feed it? What if that wasn't an animal at all, but more generic like "Vector3D"? Clearly you can not feed a Vector3D. To make it useful, you need to at least cap the upper limit, like accepting "a super type of Dog, but subtype of Animal", then you may possibly feed it.
    – Cavor Kehl
    Commented Nov 16, 2023 at 2:08

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