Further to TomMD's answer, you can use Agda to the same effect. Although it doesn't have typeclasses, you get most of the functionality (apart from dynamic dispatch) from records.

```
record Direction (a : Set) : Set₁ where
field
turnLeft : a → a
turnRight : a → a
commLaw : ∀ x → turnLeft (turnRight x) ≡ turnRight (turnLeft x)
```

I thought I'd edit the post and answer the question of why you can't do this in Haskell.

In Haskell (+ extensions), you can represent equivalence as used in the Agda code above.

```
{-# LANGUAGE GADTs, KindSignatures, TypeOperators #-}
data (:=:) a :: * -> * where
Refl :: a :=: a
```

This represents theorems about two types being equal. E.g. `a`

is equivalent to `b`

is `a :=: b`

.

Where we they are equivalent, we can use the constructor `Refl`

. Using this, we can perform functions on the proofs (values) of the theorems (types).

```
-- symmetry
sym :: a :=: b -> b :=: a
sym Refl = Refl
-- transitivity
trans :: a :=: b -> b :=: c -> a :=: c
trans Refl Refl = Refl
```

These are all type-correct, and therefore true. However this;

```
wrong :: a :=: b
wrong = Refl
```

is clearly wrong and does indeed fails on type checking.

However, through all this, the barrier between values and types has not been broken. Values, value-level functions and proofs still live on one side of the colon; types, type-level functions and theorems live on the other. Your `turnLeft`

and `turnRight`

are value-level functions and therefore cannot be involved in theorems.

Agda and Coq are dependently-typed languages, where the barrier does not exist or things are allowed to cross over. The Strathclyde Haskell Enhancement (SHE) is a preprocessor for Haskell code that can cheat some of the effects of DTP into Haskell. It does this by duplicating data from the value world in the type world. I don't think it handles duplicating value-level functions yet and if it did, my hunch is this might be too complicated for it to handle.