# The setup

Consider a type of terms parameterized over a type of function symbols `node`

and a type of variables `var`

:

```
data Term node var
= VarTerm !var
| FunTerm !node !(Vector (Term node var))
deriving (Eq, Ord, Show)
instance Functor (Term node) where
fmap f (VarTerm var) = VarTerm (f var)
fmap f (FunTerm n cs) = FunTerm n (Vector.map (fmap f) cs)
instance Monad (Term node) where
pure = VarTerm
join (VarTerm term) = term
join (FunTerm n cs) = FunTerm n (Vector.map join cs)
```

This is a useful type, since we encode open terms with `Term node Var`

,
closed terms with `Term node Void`

, and contexts with `Term node ()`

.

The goal is to define a type of substitutions on `Term`

s in the most pleasant
possible way. Here's a first stab:

```
newtype Substitution (node ∷ Type) (var ∷ Type)
= Substitution { fromSubstitution ∷ Map var (Term node var) }
deriving (Eq, Ord, Show)
```

Now let's define some auxiliary values related to `Substitution`

:

```
subst ∷ Substitution node var → Term node var → Term node var
subst s (VarTerm var) = fromMaybe (MkVarTerm var)
(Map.lookup var (fromSubstitution s))
subst s (FunTerm n ts) = FunTerm n (Vector.map (subst s) ts)
identity ∷ Substitution node var
identity = Substitution Map.empty
-- Laws:
--
-- 1. Unitality:
-- ∀ s ∷ Substitution n v → s ≡ (s ∘ identity) ≡ (identity ∘ s)
-- 2. Associativity:
-- ∀ a, b, c ∷ Substitution n v → ((a ∘ b) ∘ c) ≡ (a ∘ (b ∘ c))
-- 3. Monoid action:
-- ∀ x, y ∷ Substitution n v → subst (y ∘ x) ≡ (subst y . subst x)
(∘) ∷ (Ord var)
⇒ Substitution node var
→ Substitution node var
→ Substitution node var
s1 ∘ s2 = Substitution
(Map.unionWith
(λ _ _ → error "this should never happen")
(Map.map (subst s1) (fromSubstitution s2))
((fromSubstitution s1) `Map.difference` (fromSubstitution s2)))
```

Clearly, `(Substitution n v, ∘, identity)`

is a monoid (ignoring the `Ord`

constraint on `∘`

) and `(Term n v, subst)`

is a monoid action of
`Substitution n v`

.

Now suppose that we want to make this scheme encode substitutions
*that change the variable type*. This would look like some type `SubstCat`

that satisfies the module signature below:

```
data SubstCat (node ∷ Type) (domainVar ∷ Type) (codomainVar ∷ Type)
= … ∷ Type
subst ∷ SubstCat node dom cod → Term node dom → Term node cod
identity ∷ SubstCat node var var
(∘) ∷ (Ord v1, Ord v2, Ord v3)
→ SubstCat node v2 v3
→ SubstCat node v1 v2
→ SubstCat node v1 v3
```

This is almost a Haskell `Category`

, but for the `Ord`

constraints on `∘`

.
You might think that if `(Substitution n v, ∘, identity)`

was a monoid before,
and `subst`

was a monoid action before, then `subst`

should now be a category
action, but in point of fact category actions are just functors (in this case,
a functor from a subcategory of Hask to another subcategory of Hask).

Now there are some properties we'd hope would be true about `SubstCat`

:

`SubstCat node var Void`

should be the type of ground substitutions.`SubstCat Void var var`

should be the type of flat substitutions.`instance (Eq node, Eq dom, Eq cod) ⇒ Eq (SubstCat node dom cod)`

should exist (as well as similar instances for`Ord`

and`Show`

).- It should be possible to compute the domain variable set, the image term
set, and the introduced variable set, given a
`SubstCat node dom cod`

. - The operations I have described should be about as fast/space-efficient
as their equivalents in the
`Substitution`

implementation above.

The simplest possible approach to writing `SubstCat`

would be to simply
generalize `Substitution`

:

```
newtype SubstCat (node ∷ Type) (dom ∷ Type) (cod ∷ Type)
= SubstCat { fromSubstCat ∷ Map dom (Term node cod) }
deriving (Eq, Ord, Show)
```

Unfortunately, this does not work because when we run `subst`

it may be the
case that the term we are running substitution on contains variables that are
not in the domain of the `Map`

. We could get away with this in `Substitution`

since `dom ~ cod`

, but in `SubstCat`

we have no way to deal with these
variables.

My next attempt was to deal with this issue by also including a function of
type `dom → cod`

:

```
data SubstCat (node ∷ Type) (dom ∷ Type) (cod ∷ Type)
= SubstCat
!(Map dom (Term node cod))
!(dom → cod)
```

This causes a few problems, however. Firstly, since `SubstCat`

now contains a
function, it can no longer have `Eq`

, `Ord`

, or `Show`

instances. We cannot
simply ignore the `dom → cod`

field when comparing for equality, since the
semantics of substitution change depending on its value. Secondly, it is now
no longer the case that `SubstCat node var Void`

represents a type of ground
substitutions; in fact, `SubstCat node var Void`

is *uninhabited*!

Érdi Gergő suggested on Facebook that I use the following definition:

```
newtype SubstCat (node ∷ Type) (dom ∷ Type) (cod ∷ Type)
= SubstCat (dom → Term node cod)
```

This is certainly a fascinating prospect. There is an obvious category for this
type: the Kleisli category given by the `Monad`

instance on `Term node`

. I am
not sure if this actually corresponds to the usual notion of substitution
composition, however. Unfortunately, this representation cannot have instances
for `Eq`

et al. and I suspect it could be very inefficient in practice, since
in the best case it will end up being a tower of closures of height `Θ(n)`

,
where `n`

is the number of insertions. It also doesn't allow computation of the
domain variable set.

# The question

Is there a sensible type for `SubstCat`

that fits my requirements? Can you prove
that one does not exist? If I give up having correct instances of `Eq`

, `Ord`

,
and `Show`

, is it possible?

`Term`

monad”, has already been given below, so I’ll just point you towards some further reading:Type- and Scope-Safe Programs and Their Proofs`Map`

lookup inside the function`Term node ()`

is a context? If I unravel that definition, I get a tree of`node`

s. How is that a context?