Copyright | (C) 2017 Ryan Scott |
---|---|
License | BSD-style (see LICENSE) |
Maintainer | Ryan Scott |
Stability | experimental |
Portability | non-portable |
Safe Haskell | None |
Language | Haskell2010 |
The ShowSing
type
class (forall (z :: k). ShowSing' z) => ShowSing (k :: Type) Source #
In addition to the promoted and singled versions of the Show
class that
singletons-base
provides, it is also useful to be able to directly define
Show
instances for singleton types themselves. Doing so is almost entirely
straightforward, as a derived Show
instance does 90 percent of the work.
The last 10 percent—getting the right instance context—is a bit tricky, and
that's where ShowSing
comes into play.
As an example, let's consider the singleton type for lists. We want to write an instance with the following shape:
instance ??? =>Show
(SList
(z :: [k])) where showsPrec pSNil
= showString "SNil" showsPrec p (SCons
sx sxs) = showParen (p > 10) $ showString "SCons " . showsPrec 11 sx . showSpace . showsPrec 11 sxs
To figure out what should go in place of ???
, observe that we require the
type of each field to also be Show
instances. In other words, we need
something like (
. But this isn't quite right, as the
type variable Show
(Sing
(a :: k)))a
doesn't appear in the instance head. In fact, this a
type is really referring to an existentially quantified type variable in the
SCons
constructor, so it doesn't make sense to try and use it like this.
Luckily, the QuantifiedConstraints
language extension provides a solution
to this problem. This lets you write a context of the form
(forall a.
, which demands that there be an instance
for Show
(Sing
(a :: k)))
that is parametric in the use of Show
(Sing
(a :: k))a
.
This lets us write something closer to this:
instance (forall a.Show
(Sing
(a :: k))) =>SList
(Sing
(z :: [k])) where ...
The ShowSing
class is a thin wrapper around
(forall a.
. With Show
(Sing
(a :: k)))ShowSing
, our final instance
declaration becomes this:
instanceShowSing
k =>Show
(SList
(z :: [k])) where ...
In fact, this instance can be derived:
deriving instanceShowSing
k =>Show
(SList
(z :: [k]))
(Note that the actual definition of ShowSing
is slightly more complicated
than what this documentation might suggest. For the full story,
refer to the documentation for ShowSing
`.)
When singling a derived Show
instance, singletons-th
will also generate
a Show
instance for the corresponding singleton type using ShowSing
.
In other words, if you give singletons-th
a derived Show
instance, then
you'll receive the following in return:
- A promoted (
PShow
) instance - A singled (
SShow
) instance - A
Show
instance for the singleton type
What a bargain!
Instances
(forall (z :: k). ShowSing' z) => ShowSing k Source # | |
Defined in Data.Singletons.ShowSing |
Internal utilities
class (forall (sing :: k -> Type). sing ~ Sing => Show (sing z)) => ShowSing' (z :: k) Source #
The workhorse that powers ShowSing
. The only reason that ShowSing
`
exists is to work around GHC's inability to put type families in the head
of a quantified constraint (see
this GHC issue for more
details on this point). In other words, GHC will not let you define
ShowSing
like so:
class (forall (z :: k).Show
(Sing
z)) =>ShowSing
k
By replacing
with Show
(Sing
z)ShowSing' z
, we are able to avoid
this restriction for the most part.
The superclass of ShowSing
` is a bit peculiar:
class (forall (sing :: k -> Type). sing ~Sing
=>Show
(sing z)) =>ShowSing
` (z :: k)
One might wonder why this superclass is used instead of this seemingly more direct equivalent:
classShow
(Sing
z) =>ShowSing
` (z :: k)
Actually, these aren't equivalent! The latter's superclass mentions a type
family in its head, and this gives GHC's constraint solver trouble when
trying to match this superclass against other constraints. (See the
discussion beginning at
https://gitlab.haskell.org/ghc/ghc/-/issues/16365#note_189057 for more on
this point). The former's superclass, on the other hand, does not mention
a type family in its head, which allows it to match other constraints more
easily. It may sound like a small difference, but it's the only reason that
ShowSing
is able to work at all without a significant amount of additional
workarounds.
The quantified superclass has one major downside. Although the head of the
quantified superclass is more eager to match, which is usually a good thing,
it can bite under certain circumstances. Because
will
match a Show
(sing z)Show
instance for any types sing :: k -> Type
and z :: k
,
(where k
is a kind variable), it is possible for GHC's constraint solver
to get into a situation where multiple instances match
,
and GHC will get confused as a result. Consider this example:Show
(sing z)
-- As in Data.Singletons newtypeWrappedSing
:: forall k. k -> Type whereWrapSing
:: forall k (a :: k). {unwrapSing
::Sing
a } ->WrappedSing
a instanceShowSing
k =>Show
(WrappedSing
(a :: k)) whereshowsPrec
_ s =showString
"WrapSing {unwrapSing = " . showsPrec 0 s . showChar '}'
When typechecking the Show
instance for WrappedSing
, GHC must fill in a
default definition
, where
show
= defaultShowdefaultShow ::
.
GHC's constraint solver has two possible ways to satisfy the
Show
(WrappedSing
a) => WrappedSing
a -> String
constraint for Show
(WrappedSing
a)defaultShow
:
- The top-level instance declaration for
itself, andShow
(WrappedSing
(a :: k))
from the head of the quantified constraint arising fromShow
(sing (z :: k))
.ShowSing
k
In practice, GHC will choose (2), as local quantified constraints shadow
global constraints. This confuses GHC greatly, causing it to error out with
an error akin to Couldn't match type Sing with WrappedSing
. See
https://gitlab.haskell.org/ghc/ghc/-/issues/17934 for a full diagnosis of
the issue.
The bad news is that because of GHC#17934, we have to manually define show
(and showList
) in the Show
instance for WrappedSing
in order to avoid
confusing GHC's constraint solver. In other words, deriving
is a
no-go for Show
WrappedSing
. The good news is that situations like WrappedSing
are quite rare in the world of singletons
—most of the time, Show
instances for singleton types do not have the shape
, where Show
(sing (z :: k))k
is a polymorphic kind variable. Rather,
most such instances instantiate k
to a specific kind (e.g., Bool
, or
[a]
), which means that they will not overlap the head of the quantified
superclass in ShowSing
` as observed above.
Note that we define the single instance for ShowSing
` without the use of a
quantified constraint in the instance context:
instanceShow
(Sing
z) =>ShowSing
` (z :: k)
We could define this instance with a quantified constraint in the instance context, and it would be equally as expressive. But it doesn't provide any additional functionality that the non-quantified version gives, so we opt for the non-quantified version, which is easier to read.
Orphan instances
ShowSing k => Show (WrappedSing a) Source # | |
showsPrec :: Int -> WrappedSing a -> ShowS # show :: WrappedSing a -> String # showList :: [WrappedSing a] -> ShowS # | |
ShowSing k => Show (SWrappedSing ws) Source # | |
showsPrec :: Int -> SWrappedSing ws -> ShowS # show :: SWrappedSing ws -> String # showList :: [SWrappedSing ws] -> ShowS # |