# Covariance and contravariance in programming languages

Can anyone explain me, the concept of covariance and contravariance in programming languages theory?

-
I smell a homework question. – Andy_Vulhop Jul 22 '09 at 16:38
Covariance vs contravariance – KMån Apr 11 '11 at 8:00

Covariance is pretty simple and best thought of from the perspective of some collection class `List`. We can parameterize the `List` class with some type parameter `T`. That is, our list contains elements of type `T` for some `T`. List would be covariant if

S is a subtype of T iff List[S] is a subtype of List[T]

(Where I'm using the mathematical definition iff to mean if and only if.)

That is, a `List[Apple]` is a `List[Fruit]`. If there is some routine which accepts a `List[Fruit]` as a parameter, and I have a `List[Apple]`, then I can pass this in as a valid parameter.

``````def something(l: List[Fruit]) {
}
``````

If our collection class `List` is mutable, then covariance makes no sense because we might assume that our routine could add some other fruit (which was not an apple) as above. Hence we should only like immutable collection classes to be covariant!

-
Good definition, but it misses the fact that not only types can be treated as co/contravariant. For example, Java `List<T>` isn't either, but Java wildcards let you treat in either covariant or contravariant fashion at point of use (rather than declaration) - of course, restricting the set of operations on the type to those that are actually covariant and contravariant for it. – Pavel Minaev Jul 22 '09 at 7:48
I believe that `List<? extends Fruit>` is a kind of existential type: i.e. `List[T] forSome T <: Fruit` - the forSome T <: Fruit is itself a type in this instance. Java is still not covariant in this type though. For example a method accepting a `List<? extends Fruit>` would not accept `List<? extends Fruit>` – oxbow_lakes Jul 22 '09 at 14:29
I mean "would not accept a `List<? extends Apple>` of course – oxbow_lakes Jul 22 '09 at 14:29
-
This is such a good explanation, not bookish. Thanks. – Anonymous Jul 22 '09 at 8:59
Heck - I even enjoyed reading it. More than Wikipedia's :) – xtofl Jul 22 '09 at 9:45
Well FWIW, the explanation is from a discussion that i and my colleagues had with an eminent member (former HP) when the discussion veered towards OOSC by Bertrand Meyers in which i think Meyers highlights the importance of contravariance in OOP. He said to us OOSC by B.Meyers is a must read book if one is to practically understand OOP. – Abhay Jul 22 '09 at 10:27
This maybe copyrighted material. This appears to be from a HP tech report and i think they have not given permission to republish. hpl.hp.com/techreports/90/HPL-90-121.pdf – chikak Jul 22 '09 at 10:33
Removed content (replaced with link). The original document is clearly marked with copyright (not that it needs to be...). Feel free to add your own original content in addition to the link. But don't paste verbatim. – Marc Gravell Jul 22 '09 at 21:08
-

Here are my articles on how we have added new variance features to C# 4.0. Start from the bottom.

http://blogs.msdn.com/ericlippert/archive/tags/Covariance+and+Contravariance/default.aspx

-
OT: Eric, you had posted a puzzle on one of the questions earlier. I couldn't solve it and asked question about it. Could you please look at it? stackoverflow.com/questions/1167666/… – SolutionYogi Jul 22 '09 at 20:00
OMG Eric Lippert!!!! – Janie Jul 22 '09 at 22:56
Watch it with those exclamation marks there. You can put someone's eye out with one of those things. – Eric Lippert Jul 23 '09 at 5:10
-

There is a distinction being made between covariance and contravariance.
Very roughly, an operation is covariant if it preserves the ordering of types, and contravariant if it reverses this order.

The ordering itself is meant to represent more general types as larger than more specific types.
Here's one example of a situation where C# supports covariance. First, this is an array of objects:

``````object[] objects=new object[3];
objects[0]=new object();
objects[1]="Just a string";
objects[2]=10;
``````

Of course it is possible to insert different values into the array because in the end they all derive from `System.Object` in .Net framework. In other words, `System.Object` is a very general or large type. Now here's a spot where covariance is supported:
assigning a value of a smaller type to a variable of a larger type

``````string[] strings=new string[] { "one", "two", "three" };
objects=strings;
``````

The variable objects, which is of type `object[]`, can store a value that is in fact of type `string[]`.

Think about it — to a point, it's what you expect, but then again it isn't. After all, while `string` derives from `object`, `string[]` DOES NOT derive from `object[]`. The language support for covariance in this example makes the assignment possible anyway, which is something you'll find in many cases. Variance is a feature that makes the language work more intuitively.

The considerations around these topics are extremely complicated. For instance, based on the preceding code, here are two scenarios that will result in errors.

``````// Runtime exception here - the array is still of type string[],
// ints can't be inserted
objects[2]=10;

// Compiler error here - covariance support in this scenario only
// covers reference types, and int is a value type
int[] ints=new int[] { 1, 2, 3 };
objects=ints;
``````

An example for the workings of contravariance is a bit more complicated. Imagine these two classes:

``````public partial class Person: IPerson {
public Person() {
}
}

public partial class Woman: Person {
public Woman() {
}
}
``````

`Woman` is derived from `Person`, obviously. Now consider you have these two functions:

``````static void WorkWithPerson(Person person) {
}

static void WorkWithWoman(Woman woman) {
}
``````

One of the functions does something(it doesn't matter what) with a `Woman`, the other is more general and can work with any type derived from `Person`. On the `Woman` side of things, you now also have these:

``````delegate void AcceptWomanDelegate(Woman person);

static void DoWork(Woman woman, AcceptWomanDelegate acceptWoman) {
acceptWoman(woman);
}
``````

`DoWork` is a function that can take a `Woman` and a reference to a function that also takes a `Woman`, and then it passes the instance of `Woman` to the delegate. Consider the polymorphism of the elements you have here. `Person` is larger than `Woman`, and `WorkWithPerson` is larger than `WorkWithWoman`. `WorkWithPerson` is also considered larger than `AcceptWomanDelegate` for the purpose of variance.

Finally, you have these three lines of code:

``````Woman woman=new Woman();
DoWork(woman, WorkWithWoman);
DoWork(woman, WorkWithPerson);
``````

A `Woman` instance is created. Then DoWork is called, passing in the `Woman` instance as well as a reference to the `WorkWithWoman` method. The latter is obviously compatible with the delegate type `AcceptWomanDelegate` — one parameter of type `Woman`, no return type. The third line is a bit odd, though. The method `WorkWithPerson` takes a `Person` as parameter, not a `Woman`, as required by `AcceptWomanDelegate`. Nevertheless, `WorkWithPerson` is compatible with the delegate type. Contravariance makes it possible, so in the case of delegates the larger type `WorkWithPerson` can be stored in a variable of the smaller type `AcceptWomanDelegate`. Once more it's the intuitive thing: if `WorkWithPerson` can work with any `Person`, passing in a `Woman` can't be wrong, right?

By now, you may be wondering how all this relates to generics. The answer is that variance can be applied to generics as well. The preceding example used `object` and `string` arrays. Here the code uses generic lists instead of the arrays:

``````List<object> objectList=new List<object>();
List<string> stringList=new List<string>();
objectList=stringList;
``````

If you try this out, you will find that this is not a supported scenario in C#. In C# version 4.0 as well as .Net framework 4.0, variance support in generics has been cleaned up, and it is now possible to use the new keywords in and out with generic type parameters. They can define and restrict the direction of data flow for a particular type parameter, allowing variance to work. But in the case of `List<T>`, the data of type `T` flows in both directions — there are methods on the type `List<T>` that return `T` values, and others that receive such values.

The point of these directional restrictions is to allow variance where it makes sense, but to prevent problems like the runtime error mentioned in one of the previous array examples. When type parameters are correctly decorated with in or out, the compiler can check, and allow or disallow, its variance at compile time. Microsoft has gone to the effort of adding these keywords to many standard interfaces in .Net framework, like `IEnumerable<T>`:

``````public interface IEnumerable<out T>: IEnumerable {
// ...
}
``````

For this interface, the data flow of type `T` objects is clear: they can only ever be retrieved from methods supported by this interface, not passed into them. As a result, it is possible to construct an example similar to the `List<T>` attempt described previously, but using `IEnumerable<T>` :

``````IEnumerable<object> objectSequence=new List<object>();
IEnumerable<string> stringSequence=new List<string>();
objectSequence=stringSequence;
``````

This code is acceptable to the C# compiler since version 4.0 because `IEnumerable<T>` is covariant due to the out specifier on the type parameter `T`.

When working with generic types, it is important to be aware of variance and the way the compiler is applying various kinds of trickery in order to make your code work the way you expect it to.

There's more to know about variance than is covered in this chapter, but this shall suffice to make all further code understandable.

Ref:

-

Bart De Smet has a great blog entry about covariance & contravariance here.

-

Both C# and the CLR allow for covariance and contra-variance of reference types when binding a method to a delegate. Covariance means that a method can return a type that is derived from the delegate’s return type. Contra-variance means that a method can take a parameter that is a base of the delegate’s parameter type. For example, given a delegate defined like this:

delegate Object MyCallback(FileStream s);

it is possible to construct an instance of this delegate type bound to a method that is prototyped

like this:

String SomeMethod(Stream s);

Here, SomeMethod’s return type (String) is a type that is derived from the delegate’s return type (Object); this covariance is allowed. SomeMethod’s parameter type (Stream) is a type that is a base class of the delegate’s parameter type (FileStream); this contra-variance is allowed.

Note that covariance and contra-variance are supported only for reference types, not for value types or for void. So, for example, I cannot bind the following method to the MyCallback delegate:

Int32 SomeOtherMethod(Stream s);

Even though SomeOtherMethod’s return type (Int32) is derived from MyCallback’s return type (Object), this form of covariance is not allowed because Int32 is a value type.

Obviously, the reason why value types and void cannot be used for covariance and contra-variance is because the memory structure for these things varies, whereas the memory structure for reference types is always a pointer. Fortunately, the C# compiler will produce an error if you attempt to do something that is not supported.

-