# Scala contravariance - real life example

I understand covariance and contravariance in scala. Covariance has many applications in the real world, but I can not think of any for contravariance applications, except the same old examples for Functions.

Can someone shed some light on real world examples of `contravariance` use?

In my opinion, the two most simple examples after `Function` are ordering and equality. However, the first is not contra-variant in Scala's standard library, and the second doesn't even exist in it. So, I'm going to use Scalaz equivalents: Order and Equal.

Next, I need some class hierarchy, preferably one which is familiar and, of course, it both concepts above must make sense for it. If Scala had a `Number` superclass of all numeric types, that would have been perfect. Unfortunately, it has no such thing.

So I'm going to try to make the examples with collections. To make it simple, let's just consider `Seq[Int]` and `List[Int]`. It should be clear that `List[Int]` is a subtype of `Seq[Int]`, ie, `List[Int] <: Seq[Int]`.

So, what can we do with it? First, let's write something that compares two lists:

``````def smaller(a: List[Int], b: List[Int])(implicit ord: Order[List[Int]]) =
if (ord.order(a,b) == LT) a else b
``````

Now I'm going to write an implicit `Order` for `Seq[Int]`:

``````implicit val seqOrder = new Order[Seq[Int]] {
def order(a: Seq[Int], b: Seq[Int]) =
if (a.size < b.size) LT
else if (b.size < a.size) GT
else EQ
}
``````

With these definitions, I can now do something like this:

``````scala> smaller(List(1), List(1, 2, 3))
res0: List[Int] = List(1)
``````

Note that I'm asking for an `Order[List[Int]]`, but I'm passing a `Order[Seq[Int]]`. This means that `Order[Seq[Int]] <: Order[List[Int]]`. Given that `Seq[Int] >: List[Int]`, this is only possible because of contra-variance.

The next question is: does it make any sense?

Let's consider `smaller` again. I want to compare two lists of integers. Naturally, anything that compares two lists is acceptable, but what's the logic of something that compares two `Seq[Int]` being acceptable?

Note in the definition of `seqOrder` how the things being compared becomes parameters to it. Obviously, a `List[Int]` can be a parameter to something expecting a `Seq[Int]`. From that follows that a something that something that compares `Seq[Int]` is acceptable in place of something that compares `List[Int]`: they both can be used with the same parameters.

What about the reverse? Let's say I had a method that only compared `::` (list's cons), which, together with `Nil`, is a subtype of `List`. I obviously could not use this, because `smaller` might well receive a `Nil` to compare. It follows that an `Order[::[Int]]` cannot be used instead of `Order[List[Int]]`.

Let's proceed to equality, and write a method for it:

``````def equalLists(a: List[Int], b: List[Int])(implicit eq: Equal[List[Int]]) = eq.equal(a, b)
``````

Because `Order` extends `Equal`, I can use it with the same implicit above:

``````scala> equalLists(List(4, 5, 6), List(1, 2, 3)) // we are comparing lengths!
res3: Boolean = true
``````

The logic here is the same one. Anything that can tell whether two `Seq[Int]` are the same can, obviously, also tell whether two `List[Int]` are the same. From that, it follows that `Equal[Seq[Int]] <: Equal[List[Int]]`, which is true because `Equal` is contra-variant.

• There is scala.Equiv, but it isn't contravariant either. – psp Dec 27 '11 at 9:01
• In your "smaller" example, could I have done: `def smaller(a: List[Int], b: List[Int])(implicit ord: Order[Seq[Int]]) = if (ord.order(a,b) == LT) a else b` ? instead of `Order[List[Int]]` and achieve the same purpose? Why use contravariance? – Chao Sep 22 '15 at 11:58
• @Chao Yes, you could, but then you wouldn't pick up a more specific ordering. – Daniel C. Sobral Sep 24 '15 at 23:37

This example is from the last project I was working on. Say you have a type-class `PrettyPrinter[A]` that provides logic for pretty-printing objects of type `A`. Now if `B >: A` (i.e. if `B` is superclass of `A`) and you know how to pretty-print `B` (i.e. have an instance of `PrettyPrinter[B]` available) then you can use the same logic to pretty-print `A`. In other words, `B >: A` implies `PrettyPrinter[B] <: PrettyPrinter[A]`. So you can declare `PrettyPrinter[A]` contravariant on `A`.

``````scala> trait Animal
defined trait Animal

scala> case class Dog(name: String) extends Animal
defined class Dog

scala> trait PrettyPrinter[-A] {
|   def pprint(a: A): String
| }
defined trait PrettyPrinter

scala> def pprint[A](a: A)(implicit p: PrettyPrinter[A]) = p.pprint(a)
pprint: [A](a: A)(implicit p: PrettyPrinter[A])String

scala> implicit object AnimalPrettyPrinter extends PrettyPrinter[Animal] {
|   def pprint(a: Animal) = "[Animal : %s]" format (a)
| }
defined module AnimalPrettyPrinter

scala> pprint(Dog("Tom"))
res159: String = [Animal : Dog(Tom)]
``````

Some other examples would be `Ordering` type-class from Scala standard library, `Equal`, `Show` (isomorphic to `PrettyPrinter` above), `Resource` type-classes from Scalaz etc.

Edit:
As Daniel pointed out, Scala's `Ordering` isn't contravariant. (I really don't know why.) You may instead consider `scalaz.Order` which is intended for the same purpose as `scala.Ordering` but is contravariant on its type parameter.

Supertype-subtype relationship is but one type of relationship that can exist between two types. There can be many such relationships possible. Let's consider two types `A` and `B` related with function `f: B => A` (i.e. an arbitrary relation). Data-type `F[_]` is said to be a contravariant functor if you can define an operation `contramap` for it that can lift a function of type `B => A` to `F[A => B]`.

The following laws need to be satisfied:

1. `x.contramap(identity)` == `x`
2. `x.contramap(f).contramap(g)` == `x.contramap(f compose g)`

All of the data types discussed above (`Show`, `Equal` etc.) are contravariant functors. This property lets us do useful things such as the one illustrated below:

Suppose you have a class `Candidate` defined as:

``````case class Candidate(name: String, age: Int)
``````

You need an `Order[Candidate]` which orders candidates by their age. Now you know that there is an `Order[Int]` instance available. You can obtain an `Order[Candidate]` instance from that with the `contramap` operation:

``````val byAgeOrder: Order[Candidate] =
implicitly[Order[Int]] contramap ((_: Candidate).age)
``````

An example based on a real-world event-driven software system. Such a system is based on broad categories of events, like events related to the functioning of the system (system events), events generated by user actions (user events) and so on.

A possible event hierarchy:

``````trait Event

trait UserEvent extends Event

trait SystemEvent extends Event

trait ApplicationEvent extends SystemEvent

trait ErrorEvent extends ApplicationEvent
``````

Now the programmers working on the event-driven system need to find a way to register/process the events generated in the system. They will create a trait, `Sink`, that is used to mark components in need to be notified when an event has been fired.

``````trait Sink[-In] {
def notify(o: In)
}
``````

As a consequence of marking the type parameter with the `-` symbol, the Sink type became contravariant.

A possible way to notify interested parties that an event happened is to write a method and to pass it the corresponding event. This method will hypothetically do some processing and then it will take care of notifying the event sink:

``````def appEventFired(e: ApplicationEvent, s: Sink[ApplicationEvent]): Unit = {
// do some processing related to the event
// notify the event sink
s.notify(e)
}

def errorEventFired(e: ErrorEvent, s: Sink[ErrorEvent]): Unit = {
// do some processing related to the event
// notify the event sink
s.notify(e)
}
``````

A couple of hypothetical Sink implementations.

``````trait SystemEventSink extends Sink[SystemEvent]

val ses = new SystemEventSink {
override def notify(o: SystemEvent): Unit = ???
}

trait GenericEventSink extends Sink[Event]

val ges = new GenericEventSink {
override def notify(o: Event): Unit = ???
}
``````

The following method calls are accepted by the compiler:

``````appEventFired(new ApplicationEvent {}, ses)

errorEventFired(new ErrorEvent {}, ges)

appEventFired(new ApplicationEvent {}, ges)
``````

Looking at the series of calls you notice that it is possible to call a method expecting a `Sink[ApplicationEvent]` with a `Sink[SystemEvent]` and even with a `Sink[Event]`. Also, you can call the method expecting a `Sink[ErrorEvent]` with a `Sink[Event]`.

By replacing invariance with a contravariance constraint, a `Sink[SystemEvent]` becomes a subtype of `Sink[ApplicationEvent]`. Therefore, contravariance can also be thought of as a ‘widening’ relationship, since types are ‘widened’ from more specific to more generic.

Conclusion

This example has been described in a series of articles about variance found on my blog

In the end, I think it helps to also understand the theory behind it...