I'm trying to understand singletons. As an exercise I'm manually defining an instance of SingKind
for a custom List
type:
data List a = Nil  Cons a (List a)
data SList :: List a > Type where
SNil :: SList 'Nil
SCons :: Sing x > SList xs > SList ('Cons x xs)
type instance Sing = SList
instance SingKind k => SingKind (List k) where
type Demote (List k) = List (Demote k)
fromSing :: Sing (a :: List k) > List (Demote k)
toSing :: List (Demote k) > SomeSing (List k)
This definition of toSing
works fine if I patternmatch x
and xs
via a caseof:
toSing (Cons x xs) = case toSing x of
SomeSing singX > case toSing xs of
SomeSing singXs > SomeSing $ SCons singX singXs
But it fails if I pattern match via let:
toSing (Cons x xs) =
let SomeSing singX = toSing x
SomeSing singXs = toSing xs
in SomeSing $ SCons singX singXs
This is the error (another similar one is shown for the following line):
error:
• Couldn't match type ‘x0’ with ‘a’
Expected: Sing @k x0
Actual: Sing @k1 a
• because type variable ‘a’ would escape its scope
This (rigid, skolem) type variable is bound by
a pattern with constructor:
SomeSing :: forall k (a :: k). Sing a > SomeSing k,
in a pattern binding
at door.hs:169:1326
• In the pattern: SomeSing singX
In a pattern binding: SomeSing singX = toSing x
In the expression:
let
SomeSing singX = toSing x
SomeSing singXs = toSing xs
in SomeSing $ SCons singX singXs
• Relevant bindings include
singXs :: SList xs0 (bound at door.hs:170:22)
xs :: List (Demote k1) (bound at door.hs:168:20)
x :: Demote k1 (bound at door.hs:168:18)
toSing :: List (Demote k1) > SomeSing (List k1)
(bound at door.hs:167:5)

 let SomeSing singX = toSing x
 ^^^^^
Can you explain why let bindings behave differently from a caseof and in this case they fail?
let SomeSing singX = toSing x
more or less desugars tolet singX = case toSing x of SomeSing tmp > tmp
, and it may be more obvious why this latter thing is not allowed  indeed, one way to understand existential types is that they prevent exactly that pattern.let
uses lazy pattern matching.