Consider the `Functor`

type class in Haskell, where `f`

is a higher-kinded type variable:

```
class Functor f where
fmap :: (a -> b) -> f a -> f b
```

What this type signature says is that fmap changes the type parameter of an `f`

from `a`

to `b`

, but leaves `f`

as it was. So if you use `fmap`

over a list you get a list, if you use it over a parser you get a parser, and so on. And these are *static*, compile-time guarantees.

I don't know F#, but let's consider what happens if we try to express the `Functor`

abstraction in a language like Java or C#, with inheritance and generics, but no higher-kinded generics. First try:

```
interface Functor<A> {
Functor<B> map(Function<A, B> f);
}
```

The problem with this first try is that an implementation of the interface is allowed to return *any* class that implements `Functor`

. Somebody could write a `FunnyList<A> implements Functor<A>`

whose `map`

method returns a different kind of collection, or even something else that's not a collection at all but is still a `Functor`

. Also, when you use the `map`

method you can't invoke any subtype-specific methods on the result unless you downcast it to the type that you're actually expecting. So we have two problems:

- The type system doesn't allow us to express the invariant that the
`map`

method always returns the same `Functor`

subclass as the receiver.
- Therefore, there's no statically type-safe manner to invoke a non-
`Functor`

method on the result of `map`

.

There are other, more complicated ways you can try, but none of them really works. For example, you could try augment the first try by defining subtypes of `Functor`

that restrict the result type:

```
interface Collection<A> extends Functor<A> {
Collection<B> map(Function<A, B> f);
}
interface List<A> extends Collection<A> {
List<B> map(Function<A, B> f);
}
interface Set<A> extends Collection<A> {
Set<B> map(Function<A, B> f);
}
interface Parser<A> extends Functor<A> {
Parser<B> map(Function<A, B> f);
}
// …
```

This helps to forbid implementers of those narrower interfaces from returning the wrong type of `Functor`

from the `map`

method, but since there is no limit to how many `Functor`

implementations you can have, there is no limit to how many narrower interfaces you'll need.

(**EDIT:** And note that this only works because `Functor<B>`

appears as the result type, and so the child interfaces can narrow it. So AFAIK we can't narrow both uses of `Monad<B>`

in the following interface:

```
interface Monad<A> {
<B> Monad<B> flatMap(Function<? super A, ? extends Monad<? extends B>> f);
}
```

In Haskell, with higher-rank type variables, this is `(>>=) :: Monad m => m a -> (a -> m b) -> m b`

.)

Yet another try is to use recursive generics to try and have the interface restrict the result type of the subtype to the subtype itself. Toy example:

```
/**
* A semigroup is a type with a binary associative operation. Law:
*
* > x.append(y).append(z) = x.append(y.append(z))
*/
interface Semigroup<T extends Semigroup<T>> {
T append(T arg);
}
class Foo implements Semigroup<Foo> {
// Since this implements Semigroup<Foo>, now this method must accept
// a Foo argument and return a Foo result.
Foo append(Foo arg);
}
class Bar implements Semigroup<Bar> {
// Any of these is a compilation error:
Semigroup<Bar> append(Semigroup<Bar> arg);
Semigroup<Foo> append(Bar arg);
Semigroup append(Bar arg);
Foo append(Bar arg);
}
```

But this sort of technique (which is rather arcane to your run-of-the-mill OOP developer, heck to your run-of-the-mill functional developer as well) still can't express the desired `Functor`

constraint either:

```
interface Functor<FA extends Functor<FA, A>, A> {
<FB extends Functor<FB, B>, B> FB map(Function<A, B> f);
}
```

The problem here is this doesn't restrict `FB`

to have the same `F`

as `FA`

—so that when you declare a type `List<A> implements Functor<List<A>, A>`

, the `map`

method can **still** return a `NotAList<B> implements Functor<NotAList<B>, B>`

.

Final try, in Java, using raw types (unparametrized containers):

```
interface FunctorStrategy<F> {
F map(Function f, F arg);
}
```

Here `F`

will get instantiated to unparametrized types like just `List`

or `Map`

. This guarantees that a `FunctorStrategy<List>`

can only return a `List`

—but you've abandoned the use of type variables to track the element types of the lists.

The heart of the problem here is that languages like Java and C# don't allow type parameters to have parameters. In Java, if `T`

is a type variable, you can write `T`

and `List<T>`

, but not `T<String>`

. Higher-kinded types remove this restriction, so that you could have something like this (not fully thought out):

```
interface Functor<F, A> {
<B> F<B> map(Function<A, B> f);
}
class List<A> implements Functor<List, A> {
// Since F := List, F<B> := List<B>
<B> List<B> map(Function<A, B> f) {
// ...
}
}
```

And addressing this bit in particular:

(I think) I get that instead of `myList |> List.map f`

or `myList |> Seq.map f |> Seq.toList`

higher kinded types allow you to simply write `myList |> map f`

and it'll return a `List`

. That's great (assuming it's correct), but seems kind of petty? (And couldn't it be done simply by allowing function overloading?) I usually convert to `Seq`

anyway and then I can convert to whatever I want afterwards.

There are many languages that generalize the idea of the `map`

function this way, by modeling it as if, at heart, mapping is about sequences. This remark of yours is in that spirit: if you have a type that supports conversion to and from `Seq`

, you get the map operation "for free" by reusing `Seq.map`

.

In Haskell, however, the `Functor`

class is more general than that; it isn't tied to the notion of sequences. You can implement `fmap`

for types that have no good mapping to sequences, like `IO`

actions, parser combinators, functions, etc.:

```
instance Functor IO where
fmap f action =
do x <- action
return (f x)
-- This declaration is just to make things easier to read for non-Haskellers
newtype Function a b = Function (a -> b)
instance Functor (Function a) where
fmap f (Function g) = Function (f . g) -- `.` is function composition
```

The concept of "mapping" really isn't tied to sequences. It's best to understand the functor laws:

```
(1) fmap id xs == xs
(2) fmap f (fmap g xs) = fmap (f . g) xs
```

Very informally:

- The first law says that mapping with an identity/noop function is the same as doing nothing.
- The second law says that any result that you can produce by mapping twice, you can also produce by mapping once.

This is why you want `fmap`

to preserve the type—because as soon as you get `map`

operations that produce a different result type, it becomes much, much harder to make guarantees like this.

`IMonad<T>`

and then cast it back to e.g.`IEnumerable<int>`

or`IObservable<int>`

when you're done? Is this all just to avoid casting? – lobsterism Jan 16 '14 at 19:49`return`

would work since that really belongs to the monad type, not a particular instance so you wouldn't want to put it in the`IMonad`

interface at all. – Lee Jan 16 '14 at 20:07`bind`

aka`SelectMany`

etc too. Which means someone could use the API to`bind`

an`IObservable`

to an`IEnumerable`

and assume it would work, which yeah yuck if that's the case and there's no way around that. Just not 100% sure there's no way around it. – lobsterism Jan 16 '14 at 20:29