We're used to having universally quantified types for polymorphic functions. Existentially quantified types are used much less often. How can we express existentially quantified types using universal type quantifiers?

## 2 Answers

It turns out that existential types are just a special case of Σ-types (sigma types). What are they?

## Sigma types

Just as Π-types (pi types) generalise our ordinary function types, allowing the resulting type to *depend* on the value of its argument, Σ-types generalise pairs, allowing the type of second component to *depend* on the value of the first one.

In a made-up Haskell-like syntax, Σ-type would look like this:

```
data Sigma (a :: *) (b :: a -> *)
= SigmaIntro
{ fst :: a
, snd :: b fst
}
-- special case is a non-dependent pair
type Pair a b = Sigma a (\_ -> b)
```

Assuming `* :: *`

(i.e. the inconsistent `Set : Set`

), we can define `exists a. a`

as:

```
Sigma * (\a -> a)
```

The first component is a *type* and the second one is a value of that type. Some examples:

```
foo, bar :: Sigma * (\a -> a)
foo = SigmaIntro Int 4
bar = SigmaIntro Char 'a'
```

`exists a. a`

is fairly useless - we have no idea what type is inside, so the only operations that can work with it are type-agnostic functions such as `id`

or `const`

. Let's extend it to `exists a. F a`

or even `exists a. Show a => F a`

. Given `F :: * -> *`

, the first case is:

```
Sigma * F -- or Sigma * (\a -> F a)
```

The second one is a bit trickier. We cannot just take a `Show a`

type class instance and put it somewhere inside. However, if we are given a `Show a`

dictionary (of type `ShowDictionary a`

), we can pack it with the actual value:

```
Sigma * (\a -> (ShowDictionary a, F a))
-- inside is a pair of "F a" and "Show a" dictionary
```

This is a bit inconvenient to work with and assumes that we have a `Show`

dictionary around, but it works. Packing the dictionary along is actually what GHC does when compiling existential types, so we could define a shortcut to have it more convenient, but that's another story. As we will learn soon enough, the encoding doesn't actually suffer from this problem.

Digression: thanks to constraint kinds, it's possible to reify the type class into concrete data type. First, we need some language pragmas and one import:

```
{-# LANGUAGE ConstraintKinds, GADTs, KindSignatures #-}
import GHC.Exts -- for Constraint
```

GADTs already give us the option to pack a type class along with the constructor, for example:

```
data BST a where
Nil :: BST a
Node :: Ord a => a -> BST a -> BST a -> BST a
```

However, we can go one step further:

```
data Dict :: Constraint -> * where
D :: ctx => Dict ctx
```

It works much like the `BST`

example above: pattern matching on `D :: Dict ctx`

gives us access to the whole context `ctx`

:

```
show' :: Dict (Show a) -> a -> String
show' D = show
(.+) :: Dict (Num a) -> a -> a -> a
(.+) D = (+)
```

We also get quite natural generalisation for existential types that quantify over more type variables, such as `exists a b. F a b`

.

```
Sigma * (\a -> Sigma * (\b -> F a b))
-- or we could use Sigma just once
Sigma (*, *) (\(a, b) -> F a b)
-- though this looks a bit strange
```

## The encoding

Now, the question is: can we *encode* Σ-types with just Π-types? If yes, then the existential type encoding is just a special case. In all glory, I present you the actual encoding:

```
newtype SigmaEncoded (a :: *) (b :: a -> *)
= SigmaEncoded (forall r. ((x :: a) -> b x -> r) -> r)
```

There are some interesting parallels. Since dependent pairs represent existential quantification and from classical logic we know that:

```
(∃x)R(x) ⇔ ¬(∀x)¬R(x) ⇔ (∀x)(R(x) → ⊥) → ⊥
```

`forall r. r`

is *almost* `⊥`

, so with a bit of rewriting we get:

```
(∀x)(R(x) → r) → r
```

And finally, representing universal quantification as a dependent function:

```
forall r. ((x :: a) -> R x -> r) -> r
```

Also, let's take a look at the type of Church-encoded pairs. We get a very similar looking type:

```
Pair a b ~ forall r. (a -> b -> r) -> r
```

We just have to express the fact that `b`

may depend on the value of `a`

, which we can do by using dependent function. And again, we get the same type.

The corresponding encoding/decoding functions are:

```
encode :: Sigma a b -> SigmaEncoded a b
encode (SigmaIntro a b) = SigmaEncoded (\f -> f a b)
decode :: SigmaEncoded a b -> Sigma a b
decode (SigmaEncoded f) = f SigmaIntro
-- recall that SigmaIntro is a constructor
```

The special case actually simplifies things enough that it becomes expressible in Haskell, let's take a look:

```
newtype ExistsEncoded (F :: * -> *)
= ExistsEncoded (forall r. ((x :: *) -> (ShowDictionary x, F x) -> r) -> r)
-- simplify a bit
= ExistsEncoded (forall r. (forall x. (ShowDictionary x, F x) -> r) -> r)
-- curry (ShowDictionary x, F x) -> r
= ExistsEncoded (forall r. (forall x. ShowDictionary x -> F x -> r) -> r)
-- and use the actual type class
= ExistsEncoded (forall r. (forall x. Show x => F x -> r) -> r)
```

Note that we can view `f :: (x :: *) -> x -> x`

as `f :: forall x. x -> x`

. That is, a function with extra `*`

argument behaves as a polymorphic function.

And some examples:

```
showEx :: ExistsEncoded [] -> String
showEx (ExistsEncoded f) = f show
someList :: ExistsEncoded []
someList = ExistsEncoded $ \f -> f [1]
showEx someList == "[1]"
```

Notice that `someList`

is actually constructed via `encode`

, but we dropped the `a`

argument. That's because Haskell will infer what `x`

in the `forall x.`

part you actually mean.

## From Π to Σ?

Strangely enough (although out of the scope of this question), you can encode Π-types via Σ-types and regular function types:

```
newtype PiEncoded (a :: *) (b :: a -> *)
= PiEncoded (forall r. Sigma a (\x -> b x -> r) -> r)
-- \x -> is lambda introduction, b x -> r is a function type
-- a bit confusing, I know
encode :: ((x :: a) -> b x) -> PiEncoded a b
encode f = PiEncoded $ \sigma -> case sigma of
SigmaIntro a bToR -> bToR (f a)
decode :: PiEncoded a b -> (x :: a) -> b x
decode (PiEncoded f) x = f (SigmaIntro x (\b -> b))
```

I found an anwer in Proofs and Types by Jean-Yves Girard, Yves Lafont and Paul Taylor.

Imagine we have some one-argument type `t :: * -> *`

and construct an existential type that holds `t a`

for some `a`

: `exists a. t a`

. What can we do with such a type? In order to compute something out of it we need a function that can accept `t a`

for arbitrary `a`

, that means a function of type `forall a. t a -> b`

. Knowing this, we can encode an existential type simply as a function that takes functions of type `forall a. t a -> b`

, supplies the existential value to them and returns the result `b`

:

```
{-# LANGUAGE RankNTypes #-}
newtype Exists t = Exists (forall b. (forall a. t a -> b) -> b)
```

Creating an existential value is now easy:

```
exists :: t a -> Exists t
exists x = Exists (\f -> f x)
```

And if we want to unpack the existential value, we just apply its content to a function that produces the result:

```
unexists :: (forall a. t a -> b) -> Exists t -> b
unexists f (Exists e) = e f
```

However, purely existential types are of very little use. We cannot do anything reasonable with a value we know nothing about. More often we need an existential type with a type class constraint. The procedure is just the same, we just add a type class constraint for `a`

. For example:

```
newtype ExistsShow t = ExistsShow (forall b. (forall a. Show a => t a -> b) -> b)
existsShow :: Show a => t a -> ExistsShow t
existsShow x = ExistsShow (\f -> f x)
unexistsShow :: (forall a. Show a => t a -> b) -> ExistsShow t -> b
unexistsShow f (ExistsShow e) = e f
```

Note: Using existential quantification in functional programs is often considered a code-smell. It can indicate that we haven't liberated ourselves from OO thinking.