The natural reference is the paper Generic programming with fixed points for mutually recursive datatypes
where the multirec package is explained.

`HFix`

is a fixpoint type combinator for mutually recursive data types.
It is well explained in Section 3.2 in the paper, but the idea is
to generalise this pattern:

```
Fix :: (∗ -> ∗) -> ∗
Fix2 :: (∗ -> ∗ -> ∗) -> (∗ -> ∗ -> ∗) -> ∗
```

to

```
Fixn :: ((∗ ->)^n * ->)^n ∗
≈
Fixn :: (*^n -> *)^n -> *
```

To restrict how many types it does a fixed point over, they use type constructors
instead of *^n. They give an example of an AST data type, mutually recursive over
three types in the paper. I offer you perhaps the simplest example instead. Let
us HFix this data type:

```
data Even = Zero | ESucc Odd deriving (Show,Eq)
data Odd = OSucc Even deriving (Show,Eq)
```

Let us introduce the family specific GADT for this datatype as is done in section 4.1

```
data EO :: * -> * where
E :: EO Even
O :: EO Odd
```

`EO Even`

will mean that we are carrying around an even number.
We need El instances for this to work, which says which specific constructor
we are refering to when writing `EO Even`

and `EO Odd`

respectively.

```
instance El EO Even where proof = E
instance El EO Odd where proof = O
```

These are used as constraints for the `HFunctor`

instance
for I.

Let us now define the pattern functor for the even and odd data type.
We use the combinators from the library. The `:>:`

type constructor tags
a value with its type index:

```
type PFEO = U :>: Even -- ≈ Zero :: () -> EO Even
:+: I Odd :>: Even -- ≈ ESucc :: EO Odd -> EO Even
:+: I Even :>: Odd -- ≈ OSucc :: EO Even -> EO Odd
```

Now we can use `HFix`

to tie the knot around this pattern functor:

```
type Even' = HFix PFEO Even
type Odd' = HFix PFEO Odd
```

These are now isomorphic to EO Even and EO Odd, and we can use the
`hfrom`

and `hto`

functions
if we make it an instance of `Fam`

:

```
type instance PF EO = PFEO
instance Fam EO where
from E Zero = L (Tag U)
from E (ESucc o) = R (L (Tag (I (I0 o))))
from O (OSucc e) = R (R (Tag (I (I0 e))))
to E (L (Tag U)) = Zero
to E (R (L (Tag (I (I0 o))))) = ESucc o
to O (R (R (Tag (I (I0 e))))) = OSucc e
```

A simple little test:

```
test :: Even'
test = hfrom E (ESucc (OSucc Zero))
test' :: Even
test' = hto E test
*HFix> test'
ESucc (OSucc Zero)
```

Another silly test with an Algebra turning `Even`

and `Odd`

s to their `Int`

value:

```
newtype Const a b = Const { unConst :: a }
valueAlg :: Algebra EO (Const Int)
valueAlg _ = tag (\U -> Const 0)
& tag (\(I (Const x)) -> Const (succ x))
& tag (\(I (Const x)) -> Const (succ x))
value :: Even -> Int
value = unConst . fold valueAlg E
```