Idris2/libs/base/Deriving/Show.idr

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Idris

||| Deriving show instances using reflection
||| You can for instance define:
||| ```
||| data Tree a = Leaf a | Node (Tree a) (Tree a)
||| treeShow : Show a => Show (Tree a)
||| treeShow = %runElab derive
||| ```
module Deriving.Show
import public Control.Monad.Either
import public Control.Monad.State
import public Data.Maybe
import public Decidable.Equality
import public Language.Reflection
import public Deriving.Common
%language ElabReflection
%default total
public export
fromShowPrec :
(Prec -> ty -> String) ->
Show ty
fromShowPrec sp = MkShow (sp Open) sp
------------------------------------------------------------------------------
-- Errors
||| Possible errors for the functor-deriving machinery.
public export
data Error : Type where
NotAShowable : Name -> Error
UnsupportedType : TTImp -> Error
NotAFiniteStructure : Error
NotAnUnconstrainedValue : Count -> Error
InvalidGoal : Error
ConfusingReturnType : Error
-- Contextual information
WhenCheckingConstructor : Name -> Error -> Error
WhenCheckingArg : TTImp -> Error -> Error
export
Show Error where
show = joinBy "\n" . go [<] where
go : SnocList String -> Error -> List String
go acc (NotAShowable nm) = acc <>> ["Couldn't find a `Show' instance for the type \{show nm}"]
go acc (UnsupportedType s) = acc <>> ["Unsupported type \{show s}"]
go acc NotAFiniteStructure = acc <>> ["Cannot show an infinite structure"]
go acc (NotAnUnconstrainedValue rig) = acc <>> ["Cannot show a \{enunciate rig} value"]
go acc InvalidGoal = acc <>> ["Expected a goal of the form `Show t`"]
go acc ConfusingReturnType = acc <>> ["Confusing telescope"]
go acc (WhenCheckingConstructor nm err) = go (acc :< "When checking constructor \{show nm}") err
go acc (WhenCheckingArg s err) = go (acc :< "When checking argument of type \{show s}") err
record Parameters where
constructor MkParameters
asShowables : List Nat
initParameters : Parameters
initParameters = MkParameters []
paramConstraints : Parameters -> Nat -> Maybe TTImp
paramConstraints params pos
= IVar emptyFC `{Prelude.Show.Show} <$ guard (pos `elem` params.asShowables)
------------------------------------------------------------------------------
-- Core machinery: being showable
ShowN : TTImp -> Name -> TTImp
ShowN ty nm = go (IVar emptyFC nm) ty Z where
go : TTImp -> TTImp -> Nat -> TTImp
go acc (IPi _ _ pinfo mn (IType _) ty) n
= let var = MN "__param" (cast n) in
IPi emptyFC M0 ImplicitArg (Just var) (Implicit emptyFC False)
$ IPi emptyFC MW AutoImplicit Nothing (IApp emptyFC `(Show) (IVar emptyFC var))
$ go (TTImp.apply acc (toList (fromPiInfo emptyFC pinfo mn (IVar emptyFC var)))) ty (S n)
go acc (IPi _ _ pinfo mn _ ty) n
= let var = MN "__param" (cast n) in
IPi emptyFC M0 ImplicitArg (Just var) (Implicit emptyFC False)
$ go (TTImp.apply acc (toList (fromPiInfo emptyFC pinfo mn (IVar emptyFC var)))) ty (S n)
go acc _ _ = IApp emptyFC `(Show) acc
||| IsShowable is parametrised by
||| @ t the name of the data type whose constructors are being analysed
||| @ ty the type being analysed
||| The inductive type delivers a proof that ty can be shown,
||| assuming that t also is showable.
public export
data IsShowable : (t : Name) -> (ty : TTImp) -> Type
data IsShowableArgs : (t : Name) -> (tconty : TTImp) -> (ty : List (Argument TTImp)) -> Type
data IsShowable : (t : Name) -> (ty : TTImp) -> Type where
||| The subterm is delayed (Lazy only, we can't traverse infinite structures)
ISDelayed : IsShowable t ty -> IsShowable t (IDelayed fc LLazy ty)
||| There is a recursive subtree of type (t a1 ... an)
ISRec : (0 _ : IsAppView (_, t) _ ty) -> IsShowable t ty
||| There are nested subtrees somewhere inside a 3rd party type constructor
||| which satisfies the Show interface
ISShowN : (0 _ : IsAppView (_, tcon) args ty) ->
HasType tcon tconty ->
IsProvable (ShowN tconty tcon) ->
IsShowableArgs t tconty (args <>> []) -> IsShowable t ty
||| Or we could be referring to one of the parameters
ISParam : IsShowable t ty
||| A primitive type is trivially Showable
ISPrim : (ty : PrimType) -> IsShowable t (IPrimVal fc (PrT ty))
data IsShowableArgs : (t : Name) -> (tconty : TTImp) -> (ty : List (Argument TTImp)) -> Type where
Done : IsShowableArgs t tconty []
Step : IsShowable t (unArg arg) -> IsShowableArgs t ty args ->
IsShowableArgs t (IPi fc1 r ExplicitArg mn (IType fc2) ty) (arg :: args)
Drop : (forall fc. Not (dom === IType fc)) -> IsShowableArgs t ty args ->
IsShowableArgs t (IPi fc1 r ExplicitArg mn dom ty) (arg :: args)
Skip : Not (pinfo === ExplicitArg) -> IsShowableArgs t ty args ->
IsShowableArgs t (IPi fc1 r pinfo mn dom ty) args -- TODO: constrain more?
parameters (fc : FC) (mutualWith : List Name)
isRecs : IsShowableArgs t ty ts -> Bool
isRec : IsShowable t ts -> Bool
isRecs Done = False
isRecs (Step x xs) = isRec x || isRecs xs
isRecs (Drop f xs) = isRecs xs
isRecs (Skip f xs) = isRecs xs
isRec (ISDelayed x) = isRec x
isRec (ISRec _) = True
isRec (ISShowN _ _ _ xs) = isRecs xs
isRec ISParam = False
isRec (ISPrim _) = False
showPrecFun : {ty : _} -> IsShowable t ty -> TTImp -> TTImp
showPrecFun (ISDelayed p) t = showPrecFun p (IForce (getFC t) t)
showPrecFun (ISRec _) t = IApp emptyFC `(assert_total) (IApp emptyFC `(showArg) t)
showPrecFun {ty} (ISShowN _ _ _ as) t
= let isMutual = fromMaybe False (appView ty >>= \ v => pure (snd v.head `elem` mutualWith)) in
ifThenElse (isMutual || isRecs as) (IApp emptyFC `(assert_total)) id
$ IApp emptyFC `(showArg) t
showPrecFun ISParam t = IApp emptyFC `(showArg) t
showPrecFun (ISPrim pty) t = IApp emptyFC `(showArg) t
parameters
{0 m : Type -> Type}
{auto elab : Elaboration m}
{auto error : MonadError Error m}
{auto cs : MonadState Parameters m}
(t : Name)
(ps : List (Name, Nat))
||| Hoping to observe that ty can be shown
export
typeView : (ty : TTImp) -> m (IsShowable t ty)
typeViews : (tconty : TTImp) -> (tys : List (Argument TTImp)) ->
m (IsShowableArgs t tconty tys)
typeView (IDelayed _ lz ty) = case lz of
LLazy => ISDelayed <$> typeView ty
_ => throwError NotAFiniteStructure
typeView (IPrimVal _ (PrT ty)) = pure (ISPrim ty)
typeView ty = do
let Just (MkAppView (_, hd) ts prf) = appView ty
| _ => throwError (UnsupportedType ty)
let No _ = decEq hd t
| Yes Refl => pure (ISRec prf)
Just (hdty ** hT) <- hasType hd
| _ => case lookup hd ps <* guard (null ts) of
Just n => do
-- record that the nth parameter should be showable
ns <- gets asShowables
let ns = ifThenElse (n `elem` ns) ns (n :: ns)
modify { asShowables := ns }
-- and happily succeed
logMsg "derive.show.assumption" 10 $
"I am assuming that the parameter \{show hd} can be shown"
pure ISParam
_ => throwError (UnsupportedType ty)
Just iP <- isProvable (ShowN hdty hd)
| _ => throwError (NotAShowable hd)
ISShowN prf hT iP <$> typeViews hdty (ts <>> [])
typeViews _ [] = pure Done
typeViews (IPi _ _ ExplicitArg _ (IType fc) ty) (t :: ts)
= Step <$> assert_total (typeView (unArg t)) <*> typeViews ty ts
typeViews (IPi _ _ ExplicitArg _ dom ty) (t :: ts)
= Drop (\ x => believe_me x) <$> typeViews ty ts
typeViews (IPi _ _ _ _ _ ty) ts
= Skip (\ x => believe_me x) <$> typeViews ty ts
typeViews ty ts = throwError (UnsupportedType ty)
namespace Show
derive' : (Elaboration m, MonadError Error m) =>
{default Private vis : Visibility} ->
{default Total treq : TotalReq} ->
{default [] mutualWith : List Name} ->
m (Show f)
derive' = do
-- expand the mutualwith names to have the internal, fully qualified, names
mutualWith <- map concat $ for mutualWith $ \ nm => do
ntys <- getType nm
pure (fst <$> ntys)
-- The goal should have the shape (Show t)
Just (IApp _ (IVar _ showable) t) <- goal
| _ => throwError InvalidGoal
when (`{Prelude.Show.Show} /= showable) $
logMsg "derive.show" 1 "Expected to derive Show but got \{show showable}"
-- t should be a type constructor
logMsg "derive.show" 1 "Deriving Show for \{showPrec App $ mapTTImp cleanup t}"
MkIsType f params cs <- isType t
logMsg "derive.show.constructors" 1 $
joinBy "\n" $ "" :: map (\ (n, ty) => " \{showPrefix True $ dropNS n} : \{show $ mapTTImp cleanup ty}") cs
-- Generate a clause for each data constructor
let fc = emptyFC
let un = UN . Basic
let showName = un ("showPrec" ++ show (dropNS f))
let precName = un "d"
let prec = IVar fc precName
(ns, cls) <- runStateT {m = m} initParameters $ for cs $ \ (cName, ty) =>
withError (WhenCheckingConstructor cName) $ do
-- Grab the types of the constructor's explicit arguments
let Just (MkConstructorView paraz args) = constructorView ty
| _ => throwError ConfusingReturnType
logMsg "derive.show.clauses" 10 $
"\{showPrefix True (dropNS cName)} (\{joinBy ", " (map (showPrec Dollar . mapTTImp cleanup . unArg . snd) args)})"
-- Only keep the visible arguments
let args = mapMaybe (bitraverse pure (map snd . isExplicit)) args
-- Special case for constructors with no argument
let (_ :: _) = args
| [] => pure $ PatClause fc
(apply fc (IVar fc showName) [ prec, IVar fc cName])
(IPrimVal fc (Str (showPrefix True (dropNS cName))))
let vars = zipWith (const . IVar fc . un . ("x" ++) . show . (`minus` 1)) [1..length args] args
recs <- for (zip vars args) $ \ (v, (rig, ty)) => do
let MW = rig
| _ => throwError (NotAnUnconstrainedValue rig)
-- try to reduce the type before analysis
ty <- try (check {expected=Type} ty >>= \x => quote x) (pure ty)
res <- withError (WhenCheckingArg (mapTTImp cleanup ty)) $ do
typeView f (paraz <>> []) ty
pure $ Just (showPrecFun fc mutualWith res v)
let args = catMaybes recs
let asList = foldr (\ a, as => apply fc (IVar fc `{Prelude.(::)}) [a,as]) `(Prelude.Nil)
pure $ PatClause fc
(apply fc (IVar fc showName) [ prec, apply fc (IVar fc cName) vars])
(apply fc (IVar fc (un "showCon"))
[ prec
, IPrimVal fc (Str (showPrefix True (dropNS cName)))
, case args of
[a] => a
_ => IApp fc (IVar fc (un "concat")) (asList args)
])
-- Generate the type of the show function
let ty = MkTy fc fc showName $ withParams fc (paramConstraints ns) params
$ `(Prec -> ~(t) -> String)
logMsg "derive.show.clauses" 1 $
joinBy "\n" ("" :: (" " ++ show (mapITy cleanup ty))
:: map ((" " ++) . showClause InDecl . mapClause cleanup) cls)
-- Define the instance
check $ ILocal fc
[ IClaim fc MW vis [Totality treq] ty
, IDef fc showName cls
] `(fromShowPrec ~(IVar fc showName))
||| Derive an implementation of Show for a type constructor.
||| This can be used like so:
||| ```
||| data Tree a = Leaf a | Node (Tree a) (Tree a)
||| treeShow : Show a => Show (Tree a)
||| treeShow = %runElab derive
||| ```
export
derive : {default Private vis : Visibility} ->
{default Total treq : TotalReq} ->
{default [] mutualWith : List Name} ->
Elab (Show f)
derive = do
res <- runEitherT {e = Error, m = Elab} (derive' {vis, treq, mutualWith})
case res of
Left err => fail (show err)
Right prf => pure prf