The following is a stunt, but it's quite a safe stunt so do try it at home. It uses some of the entertaining new toys to bake *order* invariants into mergeSort.

```
{-# LANGUAGE GADTs, PolyKinds, KindSignatures, MultiParamTypeClasses,
FlexibleInstances, RankNTypes, FlexibleContexts #-}
```

I'll have natural numbers, just to keep things simple.

```
data Nat = Z | S Nat deriving (Show, Eq, Ord)
```

But I'll define `<=`

in type class Prolog, so the typechecker can try to figure order out implicitly.

```
class LeN (m :: Nat) (n :: Nat) where
instance LeN Z n where
instance LeN m n => LeN (S m) (S n) where
```

In order to sort numbers, I need to know that any two numbers can be ordered *one way or the other*. Let's say what it means for two numbers to be so orderable.

```
data OWOTO :: Nat -> Nat -> * where
LE :: LeN x y => OWOTO x y
GE :: LeN y x => OWOTO x y
```

We'd like to know that every two numbers are indeed orderable, provided we have a runtime representation of them. These days, we get that by building the *singleton family* for `Nat`

. `Natty n`

is the type of runtime copies of `n`

.

```
data Natty :: Nat -> * where
Zy :: Natty Z
Sy :: Natty n -> Natty (S n)
```

Testing which way around the numbers are is quite a lot like the usual Boolean version, except with evidence. The step case requires unpacking and repacking because the types change. Instance inference is good for the logic involved.

```
owoto :: forall m n. Natty m -> Natty n -> OWOTO m n
owoto Zy n = LE
owoto (Sy m) Zy = GE
owoto (Sy m) (Sy n) = case owoto m n of
LE -> LE
GE -> GE
```

Now we know how to put numbers in order, let's see how to make ordered lists. The plan is to describe what it is to be in order *between loose bounds*. Of course, we don't want to exclude any elements from being sortable, so the type of *bounds* extends the element type with bottom and top elements.

```
data Bound x = Bot | Val x | Top deriving (Show, Eq, Ord)
```

I extend the notion of `<=`

accordingly, so the typechecker can do bound checking.

```
class LeB (a :: Bound Nat)(b :: Bound Nat) where
instance LeB Bot b where
instance LeN x y => LeB (Val x) (Val y) where
instance LeB (Val x) Top where
instance LeB Top Top where
```

And here are ordered lists of numbers: an `OList l u`

is a sequence `x1 :< x2 :< ... :< xn :< ONil`

such that `l <= x1 <= x2 <= ... <= xn <= u`

. The `x :<`

checks that `x`

is above the lower bound, then imposes `x`

as the lower bound on the tail.

```
data OList :: Bound Nat -> Bound Nat -> * where
ONil :: LeB l u => OList l u
(:<) :: forall l x u. LeB l (Val x) =>
Natty x -> OList (Val x) u -> OList l u
```

We can write `merge`

for ordered lists just the same way we would if they were ordinary. The key invariant is that if both lists share the same bounds, so does their merge.

```
merge :: OList l u -> OList l u -> OList l u
merge ONil lu = lu
merge lu ONil = lu
merge (x :< xu) (y :< yu) = case owoto x y of
LE -> x :< merge xu (y :< yu)
GE -> y :< merge (x :< xu) yu
```

The branches of the case analysis extend what is already known from the inputs with just enough ordering information to satisfy the requirements for the results. Instance inference acts as a basic theorem prover: fortunately (or rather, with a bit of practice) the proof obligations are easy enough.

Let's seal the deal. We need to construct runtime witnesses for numbers in order to sort them this
way.

```
data NATTY :: * where
Nat :: Natty n -> NATTY
natty :: Nat -> NATTY
natty Z = Nat Zy
natty (S n) = case natty n of Nat n -> Nat (Sy n)
```

We need to trust that this translation gives us the `NATTY`

that corresponds to the `Nat`

we want to sort. This interplay between `Nat`

, `Natty`

and `NATTY`

is a bit frustrating, but that's what it takes in Haskell just now. Once we've got that, we can build `sort`

in the usual divide-and-conquer way.

```
deal :: [x] -> ([x], [x])
deal [] = ([], [])
deal (x : xs) = (x : zs, ys) where (ys, zs) = deal xs
sort :: [Nat] -> OList Bot Top
sort [] = ONil
sort [n] = case natty n of Nat n -> n :< ONil
sort xs = merge (sort ys) (sort zs) where (ys, zs) = deal xs
```

I'm often surprised by how many programs that make sense to us can make just as much sense to a typechecker.

[Here's some spare kit I built to see what was happening.

```
instance Show (Natty n) where
show Zy = "Zy"
show (Sy n) = "(Sy " ++ show n ++ ")"
instance Show (OList l u) where
show ONil = "ONil"
show (x :< xs) = show x ++ " :< " ++ show xs
ni :: Int -> Nat
ni 0 = Z
ni x = S (ni (x - 1))
```

And nothing was hidden.]