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 Terms 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
           (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:

  1. SubstCat node var Void should be the type of ground substitutions.
  2. SubstCat Void var var should be the type of flat substitutions.
  3. instance (Eq node, Eq dom, Eq cod) ⇒ Eq (SubstCat node dom cod) should exist (as well as similar instances for Ord and Show).
  4. 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.
  5. 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?

  • 2
    The answer I would’ve written, “it’s the Kleisli category of the 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 Commented Jun 17, 2018 at 1:03
  • 2
    “in the best case it will end up being a tower of closures” - the function doesn’t have to be built by composition. Nothing stopping you from just doing a Map lookup inside the function Commented Jun 17, 2018 at 1:10
  • How do you understand that Term node () is a context? If I unravel that definition, I get a tree of nodes. How is that a context? Commented Oct 19, 2019 at 18:03
  • When I say a "context", I mean that in the sense of "a term with exactly one free variable". Like an evaluation context; not like a typing context.
    – taktoa
    Commented Oct 20, 2019 at 19:36

2 Answers 2


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.

It does correspond to that, and it's an all-around correct definition of parallel substitution for well-scoped terms. You may note that this substitution is total; this is a requirement if you want term substitution to be total, i. e. that it's a functor from the category of substitutions (Subst) to Set. For a simple example for why partial substitutions don't work, if you have an empty SubstCat node () Void, then you would have to invent arbitrary closed terms when hitting VarTerm () in subst - and closed terms don't even exist if you choose Void for node.

Hence, if you have Map dom (Term node cod) then you have partial term substitution, i. e. a functor from Subst to the Kleisli category for Maybe (disregarding for now formal complications from the Ord constraints):

type Subst node i j = Map i (Term node j)

subst :: Ord i => Subst node i j -> Term node i -> Maybe (Term node j)
subst sub (VarTerm x)    = Map.lookup x sub
subst sub (FunTerm f ts) = FunTerm f <$> traverse (subst sub) ts

Now, total term substitution along with your 1-5 desiderata for SubstCat is possible, but not with the current kinds for SubstCat and Term. As I mentioned, in this case substitutions must be total, but currently we can just have SubstCat node dom cod with some infinite dom, which makes equality of substitutions undecidable.

So let's switch to a more precise formalization, which contains only what we care about here. We have well-scoped untyped terms, and we assume that terms are finite and live in finite variable contexts.

Untyped terms imply that only sizes of variable contexts matter. So, Subst has natural numbers as objects:

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

Terms are indexed by n :: Nat, containing n possible values for variables:

-- {-# language TypeInType, GADTs, TypeFamilies, ScopedTypeVariables,
--           FlexibleInstances, MultiParamTypeClasses, RankNTypes,
--           TypeApplications, StandaloneDeriving #-}

data Fin n where
  FZ :: Fin (S n)
  FS :: Fin n -> Fin (S n)
deriving instance Eq (Fin n)
deriving instance Ord (Fin n)
deriving instance Show (Fin n)

data Term node (n :: Nat) where
  VarTerm :: !(Fin n) -> Term node n
  FunTerm :: !node -> !(Vector (Term node n)) -> Term node n

deriving instance Eq node => Eq (Term node n)
deriving instance Ord node => Ord (Term node n)
deriving instance Show node => Show (Term node n)

Substitutions (morphisms) are vectors of terms:

data Vec a n where
  Nil  :: Vec a Z
  (:>) :: a -> Vec a n -> Vec a (S n)
infixr 5 :>

deriving instance Eq a => Eq (Vec a n)
deriving instance Ord a => Ord (Vec a n)
deriving instance Show a => Show (Vec a n)

type Subst node i j = Vec (Term node j) i

Term substitution is as follows:

subst :: Subst node i j -> Term node i -> Term node j
subst (t :> _ ) (VarTerm FZ)     = t
subst (_ :> ts) (VarTerm (FS x)) = subst ts (VarTerm x)
subst sub       (FunTerm f ts)   = FunTerm f (Vector.map (subst sub) ts)

Composition is just pointwise subst:

comp :: Subst node i j -> Subst node j k -> Subst node i k
comp Nil       sub2 = Nil
comp (t :> ts) sub2 = subst sub2 t :> comp ts sub2

Identity substitution is not so easy. We need to dispatch on a type-level Nat. For this, we use here a type class; singletons would be a heavier but more principled solution. The implementation itself is also a bit mind-bending. It makes use of the fact that Subst node n m is isomorphic to (Fin n -> Term node m). In fact, we could just use the functional representation all the time, but then the Eq, Ord and Show instances would still effectively need the backwards conversion, and we would not have the spacetime boundedness guarantees of (strict) vectors.

class Tabulate n where
  tabulate :: (Fin n -> Term node m) -> Subst node n m

instance Tabulate Z where
  tabulate f = Nil

instance Tabulate n => Tabulate (S n) where
  tabulate f = f FZ :> tabulate (f . FS)

idSubst :: Tabulate n => Subst node n n
idSubst = tabulate VarTerm

That's it! Proofs of category laws for Subst and functor laws for subst are left as exercise.

PS: I note that in literature and formal Agda/Coq developments, Nat indices of Subst are usually in swapped order, and subst has contravariant action.

  • "indices of Subst are usually in swapped order" -- do you know why this is the case? Commented Jun 17, 2018 at 18:04
  • 2
    @user3237465 A term is a single thing in a context, a substitution is zero or more things in a context. This suggests notation such as Γ ⊢ t : A and Γ ⊢ σ : Δ, or people use (Γ ⇒ Δ) or (Sub Γ Δ) etc. Also, if you take the standard set-semantics, ⟦ Sub Γ Δ ⟧ is ⟦ Γ ⟧ → ⟦ Δ ⟧, and I don't know of any semantics when the (generalized) arrow goes in the other direction. With polymorphic and dependent TT, the arrow generally can't go in the other direction because of A possibly depending on Γ in Γ ⊢ t : A. Commented Jun 21, 2018 at 9:50
{-# LANGUAGE TypeFamilies, TypeOperators #-}

import Data.MemoTrie
import Control.Category.Constrained

newtype SubstCat node dom cod = SubstCat (dom :->: Term node cod)

instance Category (SubstCat node) where
  type Object (SubstCat node) a = HasTrie a
  id = SubstCat (trie VarTerm)
  SubstCat f . SubstCat g = SubstCat $ fmap (untrie f =<<) g

The memo-trie type :->: is basically a map type, but the mappings are always total. I.e., they are proper functions, but in a memory-fixed representation – no closures needed. This only works for types that are not only orderable but also completely enumeratable, which is what the HasTrie class expresses; thus we can't define an instance for Control.Category.Category but we can define an instance for its constrainable pendant.

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