\$wMkT :: a -> T [a]
\$wMkT a x = MkT [a] a [a] x
The third argument is a coerion
- [a] :: [a]:=:[a]
+ [a] :: [a]~[a]
INVARIANT: the dictionary constructor for a class
never has a wrapper.
-- *** As represented internally
-- data T a where
- -- MkT :: forall a. forall x y. (a:=:(x,y),x~y,Ord x) => x -> y -> T a
+ -- MkT :: forall a. forall x y. (a~(x,y),x~y,Ord x) => x -> y -> T a
--
-- The next six fields express the type of the constructor, in pieces
-- e.g.
--
-- dcUnivTyVars = [a]
-- dcExTyVars = [x,y]
- -- dcEqSpec = [a:=:(x,y)]
+ -- dcEqSpec = [a~(x,y)]
-- dcEqTheta = [x~y]
-- dcDictTheta = [Ord x]
-- dcOrigArgTys = [a,List b]
-- _as written by the programmer_
-- This field allows us to move conveniently between the two ways
-- of representing a GADT constructor's type:
- -- MkT :: forall a b. (a :=: [b]) => b -> T a
+ -- MkT :: forall a b. (a ~ [b]) => b -> T a
-- MkT :: forall b. b -> T [b]
- -- Each equality is of the form (a :=: ty), where 'a' is one of
+ -- Each equality is of the form (a ~ ty), where 'a' is one of
-- the universally quantified type variables
-- The next two fields give the type context of the data constructor
dcOrigArgTys :: [Type], -- Original argument types
-- (before unboxing and flattening of strict fields)
- dcOrigResTy :: Type, -- Original result type
+ dcOrigResTy :: Type, -- Original result type, as seen by the user
+ -- INVARIANT: mentions only dcUnivTyVars
-- NB: for a data instance, the original user result type may
-- differ from the DataCon's representation TyCon. Example
-- data instance T [a] where MkT :: a -> T [a]
dcRepTyCon :: TyCon, -- Result tycon, T
dcRepType :: Type, -- Type of the constructor
- -- forall a x y. (a:=:(x,y), x~y, Ord x) =>
+ -- forall a x y. (a~(x,y), x~y, Ord x) =>
-- x -> y -> T a
-- (this is *not* of the constructor wrapper Id:
-- see Note [Data con representation] below)
-- case (e :: T t) of
-- MkT x y co1 co2 (d:Ord x) (v:r) (w:F s) -> ...
-- It's convenient to apply the rep-type of MkT to 't', to get
- -- forall x y. (t:=:(x,y), x~y, Ord x) => x -> y -> T t
+ -- forall x y. (t~(x,y), x~y, Ord x) => x -> y -> T t
-- and use that to check the pattern. Mind you, this is really only
-- used in CoreLint.
mkDataCon :: Name
-> Bool -- ^ Is the constructor declared infix?
-> [StrictnessMark] -- ^ Strictness annotations written in the source file
- -> [FieldLabel] -- ^ Field labels for the constructor, if it is a record, otherwise empty
+ -> [FieldLabel] -- ^ Field labels for the constructor, if it is a record,
+ -- otherwise empty
-> [TyVar] -- ^ Universally quantified type variables
-> [TyVar] -- ^ Existentially quantified type variables
-> [(TyVar,Type)] -- ^ GADT equalities
-> ThetaType -- ^ Theta-type occuring before the arguments proper
- -> [Type] -- ^ Argument types
- -> TyCon -- ^ Type constructor we are for
- -> ThetaType -- ^ The "stupid theta", context of the data declaration e.g. @data Eq a => T a ...@
+ -> [Type] -- ^ Original argument types
+ -> Type -- ^ Original result type
+ -> TyCon -- ^ Representation type constructor
+ -> ThetaType -- ^ The "stupid theta", context of the data declaration
+ -- e.g. @data Eq a => T a ...@
-> DataConIds -- ^ The Ids of the actual builder functions
-> DataCon
-- Can get the tag from the TyCon
fields
univ_tvs ex_tvs
eq_spec theta
- orig_arg_tys tycon
+ orig_arg_tys orig_res_ty rep_tycon
stupid_theta ids
-- Warning: mkDataCon is not a good place to check invariants.
-- If the programmer writes the wrong result type in the decl, thus:
dcStupidTheta = stupid_theta,
dcEqTheta = eq_theta, dcDictTheta = dict_theta,
dcOrigArgTys = orig_arg_tys, dcOrigResTy = orig_res_ty,
- dcRepTyCon = tycon,
+ dcRepTyCon = rep_tycon,
dcRepArgTys = rep_arg_tys,
dcStrictMarks = arg_stricts,
dcRepStrictness = rep_arg_stricts,
real_arg_tys = dict_tys ++ orig_arg_tys
real_stricts = map mk_dict_strict_mark dict_theta ++ arg_stricts
- -- Example
- -- data instance T (b,c) where
- -- TI :: forall e. e -> T (e,e)
- --
- -- The representation tycon looks like this:
- -- data :R7T b c where
- -- TI :: forall b1 c1. (b1 ~ c1) => b1 -> :R7T b1 c1
- -- In this case orig_res_ty = T (e,e)
- orig_res_ty = mkFamilyTyConApp tycon (substTyVars (mkTopTvSubst eq_spec) univ_tvs)
-
-- Representation arguments and demands
-- To do: eliminate duplication with MkId
(rep_arg_stricts, rep_arg_tys) = computeRep real_stricts real_arg_tys
- tag = assoc "mkDataCon" (tyConDataCons tycon `zip` [fIRST_TAG..]) con
+ tag = assoc "mkDataCon" (tyConDataCons rep_tycon `zip` [fIRST_TAG..]) con
ty = mkForAllTys univ_tvs $ mkForAllTys ex_tvs $
mkFunTys (mkPredTys (eqSpecPreds eq_spec)) $
mkFunTys (mkPredTys eq_theta) $
-- because they might be flattened..
-- but the equality predicates are not
mkFunTys rep_arg_tys $
- mkTyConApp tycon (mkTyVarTys univ_tvs)
+ mkTyConApp rep_tycon (mkTyVarTys univ_tvs)
eqSpecPreds :: [(TyVar,Type)] -> ThetaType
eqSpecPreds spec = [ mkEqPred (mkTyVarTy tv, ty) | (tv,ty) <- spec ]
-- 4) The /original/ result type of the 'DataCon'
dataConSig :: DataCon -> ([TyVar], ThetaType, [Type], Type)
dataConSig (MkData {dcUnivTyVars = univ_tvs, dcExTyVars = ex_tvs, dcEqSpec = eq_spec,
- dcEqTheta = eq_theta, dcDictTheta = dict_theta, dcOrigArgTys = arg_tys, dcOrigResTy = res_ty})
+ dcEqTheta = eq_theta, dcDictTheta = dict_theta,
+ dcOrigArgTys = arg_tys, dcOrigResTy = res_ty})
= (univ_tvs ++ ex_tvs, eqSpecPreds eq_spec ++ eq_theta ++ dict_theta, arg_tys, res_ty)
-- | The \"full signature\" of the 'DataCon' returns, in order:
--
-- 4) The result of 'dataConDictTheta'
--
--- 5) The original argument types to the 'DataCon' (i.e. before any change of the representation of the type)
+-- 5) The original argument types to the 'DataCon' (i.e. before
+-- any change of the representation of the type)
--
-- 6) The original result type of the 'DataCon'
dataConFullSig :: DataCon
-> ([TyVar], [TyVar], [(TyVar,Type)], ThetaType, ThetaType, [Type], Type)
dataConFullSig (MkData {dcUnivTyVars = univ_tvs, dcExTyVars = ex_tvs, dcEqSpec = eq_spec,
- dcEqTheta = eq_theta, dcDictTheta = dict_theta, dcOrigArgTys = arg_tys, dcOrigResTy = res_ty})
+ dcEqTheta = eq_theta, dcDictTheta = dict_theta,
+ dcOrigArgTys = arg_tys, dcOrigResTy = res_ty})
= (univ_tvs, ex_tvs, eq_spec, eq_theta, dict_theta, arg_tys, res_ty)
dataConOrigResTy :: DataCon -> Type