{-# LANGUAGE PatternGuards #-} -- This functionality may be moved into GHC at some point, and then -- we can use the GHC version (#if GHC version is new enough). -- Some other functions turned out to be useful for converting -- instance heads, which aren't TyThings, so just export everything. module Haddock.Convert -- ( tyThingToHsSynSig {- :: TyThing -> LHsDecl Name -} ) where import HsSyn import TcType ( tcSplitSigmaTy ) import TypeRep import Type ( splitKindFunTys ) import Name import Var import Class import TyCon import DataCon import BasicTypes import TysPrim ( alphaTyVars ) import TysWiredIn ( listTyConName ) import Bag ( emptyBag ) import SrcLoc ( Located, noLoc ) -- the main function here! yay! tyThingToLHsDecl :: TyThing -> LHsDecl Name tyThingToLHsDecl t = noLoc $ case t of -- ids (functions and zero-argument a.k.a. CAFs) get a type signature. -- Including built-in functions like seq. -- foreign-imported functions could be represented with ForD -- instead of SigD if we wanted... -- -- in a future code version we could turn idVarDetails = foreign-call -- into a ForD instead of a SigD if we wanted. Haddock doesn't -- need to care. AnId i -> SigD (synifyIdSig ImplicitizeForAll i) -- type-constructors (e.g. Maybe) are complicated, put the definition -- later in the file (also it's used for class associated-types too.) ATyCon tc -> TyClD (synifyTyCon tc) -- a data-constructor alone just gets rendered as a function: ADataCon dc -> SigD (TypeSig (synifyName dc) (synifyType ImplicitizeForAll (dataConUserType dc))) -- classes are just a little tedious AClass cl -> TyClD $ ClassDecl (synifyCtx (classSCTheta cl)) (synifyName cl) (synifyTyVars (classTyVars cl)) (map (\ (l,r) -> noLoc (map getName l, map getName r) ) $ snd $ classTvsFds cl) (map (\i -> noLoc $ synifyIdSig DeleteTopLevelQuantification i) (classMethods cl)) emptyBag --ignore default method definitions, they don't affect signature (map synifyClassAT (classATs cl)) [] --we don't have any docs at this point -- class associated-types are a subset of TyCon -- (mainly only type/data-families) synifyClassAT :: TyCon -> LTyClDecl Name synifyClassAT tc = noLoc $ synifyTyCon tc synifyTyCon :: TyCon -> TyClDecl Name synifyTyCon tc | isFunTyCon tc || isPrimTyCon tc = TyData -- arbitrary lie, they are neither algebraic data nor newtype: DataType -- no built-in type has any stupidTheta: (noLoc []) (synifyName tc) -- tyConTyVars doesn't work on fun/prim, but we can make them up: (zipWith (\fakeTyVar realKind -> noLoc $ KindedTyVar (getName fakeTyVar) realKind) alphaTyVars --a, b, c... which are unfortunately all kind * (fst . splitKindFunTys $ tyConKind tc) ) -- assume primitive types aren't members of data/newtype families: Nothing -- we have their kind accurately: (Just (tyConKind tc)) -- no algebraic constructors: [] -- "deriving" needn't be specified: Nothing | isOpenSynTyCon tc = case synTyConRhs tc of OpenSynTyCon rhs_kind _ -> TyFamily TypeFamily (synifyName tc) (synifyTyVars (tyConTyVars tc)) (Just rhs_kind) _ -> error "synifyTyCon: impossible open type synonym?" | isOpenTyCon tc = --(why no "isOpenAlgTyCon"?) case algTyConRhs tc of OpenTyCon _ -> TyFamily DataFamily (synifyName tc) (synifyTyVars (tyConTyVars tc)) Nothing --always kind '*' _ -> error "synifyTyCon: impossible open data type?" | otherwise = -- (closed) type, newtype, and data let -- alg_ only applies to newtype/data -- syn_ only applies to type -- others apply to both alg_nd = if isNewTyCon tc then NewType else DataType alg_ctx = synifyCtx (tyConStupidTheta tc) name = synifyName tc tyvars = synifyTyVars (tyConTyVars tc) typats = case tyConFamInst_maybe tc of Nothing -> Nothing Just (_, indexes) -> Just (map (synifyType WithinType) indexes) alg_kindSig = Just (tyConKind tc) -- The data constructors. -- -- Any data-constructors not exported from the module that *defines* the -- type will not (cannot) be included. -- -- Very simple constructors, Haskell98 with no existentials or anything, -- probably look nicer in non-GADT syntax. In source code, all constructors -- must be declared with the same (GADT vs. not) syntax, and it probably -- is less confusing to follow that principle for the documentation as well. -- -- There is no sensible infix-representation for GADT-syntax constructor -- declarations. They cannot be made in source code, but we could end up -- with some here in the case where some constructors use existentials. -- That seems like an acceptable compromise (they'll just be documented -- in prefix position), since, otherwise, the logic (at best) gets much more -- complicated. (would use dataConIsInfix.) alg_use_gadt_syntax = any (not . isVanillaDataCon) (tyConDataCons tc) alg_cons = map (synifyDataCon alg_use_gadt_syntax) (tyConDataCons tc) -- "deriving" doesn't affect the signature, no need to specify any. alg_deriv = Nothing syn_type = synifyType WithinType (synTyConType tc) in if isSynTyCon tc then TySynonym name tyvars typats syn_type else TyData alg_nd alg_ctx name tyvars typats alg_kindSig alg_cons alg_deriv -- User beware: it is your responsibility to pass True (use_gadt_syntax) -- for any constructor that would be misrepresented by omitting its -- result-type. -- But you might want pass False in simple enough cases, -- if you think it looks better. synifyDataCon :: Bool -> DataCon -> LConDecl Name synifyDataCon use_gadt_syntax dc = noLoc $ let -- dataConIsInfix allegedly tells us whether it was declared with -- infix *syntax*. use_infix_syntax = dataConIsInfix dc use_named_field_syntax = not (null field_tys) name = synifyName dc -- con_qvars means a different thing depending on gadt-syntax qvars = if use_gadt_syntax then synifyTyVars (dataConAllTyVars dc) else synifyTyVars (dataConExTyVars dc) -- skip any EqTheta, use 'orig'inal syntax ctx = synifyCtx (dataConDictTheta dc) linear_tys = zipWith (\ty strict -> let tySyn = synifyType WithinType ty in case strict of MarkedStrict -> noLoc $ HsBangTy HsStrict tySyn MarkedUnboxed -> noLoc $ HsBangTy HsUnbox tySyn NotMarkedStrict -> -- HsNoBang never appears, it's implied instead. tySyn ) (dataConOrigArgTys dc) (dataConStrictMarks dc) field_tys = zipWith (\field synTy -> ConDeclField (synifyName field) synTy Nothing) (dataConFieldLabels dc) linear_tys tys = case (use_named_field_syntax, use_infix_syntax) of (True,True) -> error "synifyDataCon: contradiction!" (True,False) -> RecCon field_tys (False,False) -> PrefixCon linear_tys (False,True) -> case linear_tys of [a,b] -> InfixCon a b _ -> error "synifyDataCon: infix with non-2 args?" res_ty = if use_gadt_syntax then ResTyGADT (synifyType WithinType (dataConOrigResTy dc)) else ResTyH98 -- finally we get synifyDataCon's result! in ConDecl name Implicit{-we don't know nor care-} qvars ctx tys res_ty Nothing #if __GLASGOW_HASKELL__ >= 611 False --we don't want any "deprecated GADT syntax" warnings! #endif synifyName :: NamedThing n => n -> Located Name synifyName n = noLoc (getName n) synifyIdSig :: SynifyTypeState -> Id -> Sig Name synifyIdSig s i = TypeSig (synifyName i) (synifyType s (varType i)) synifyCtx :: [PredType] -> LHsContext Name synifyCtx ps = noLoc (map synifyPred ps) synifyPred :: PredType -> LHsPred Name synifyPred (ClassP cls tys) = let sTys = map (synifyType WithinType) tys in noLoc $ HsClassP (getName cls) sTys synifyPred (IParam ip ty) = let sTy = synifyType WithinType ty -- IPName should be in class NamedThing... in noLoc $ HsIParam ip sTy synifyPred (EqPred ty1 ty2) = let s1 = synifyType WithinType ty1 s2 = synifyType WithinType ty2 in noLoc $ HsEqualP s1 s2 synifyTyVars :: [TyVar] -> [LHsTyVarBndr Name] synifyTyVars = map synifyTyVar where synifyTyVar tv = noLoc $ let kind = tyVarKind tv name = getName tv in if isLiftedTypeKind kind then UserTyVar name else KindedTyVar name kind --states of what to do with foralls: data SynifyTypeState = WithinType -- ^ normal situation. This is the safe one to use if you don't -- quite understand what's going on. | ImplicitizeForAll -- ^ beginning of a function definition, in which, to make it look -- less ugly, those rank-1 foralls are made implicit. | DeleteTopLevelQuantification -- ^ because in class methods the context is added to the type -- (e.g. adding @forall a. Num a =>@ to @(+) :: a -> a -> a@) -- which is rather sensible, -- but we want to restore things to the source-syntax situation where -- the defining class gets to quantify all its functions for free! synifyType :: SynifyTypeState -> Type -> LHsType Name synifyType _ (PredTy{}) = --should never happen. error "synifyType: PredTys are not, in themselves, source-level types." synifyType _ (TyVarTy tv) = noLoc $ HsTyVar (getName tv) synifyType _ (TyConApp tc tys) -- Use non-prefix tuple syntax where possible, because it looks nicer. | isTupleTyCon tc, tyConArity tc == length tys = noLoc $ HsTupleTy (tupleTyConBoxity tc) (map (synifyType WithinType) tys) -- ditto for lists | getName tc == listTyConName, [ty] <- tys = noLoc $ HsListTy (synifyType WithinType ty) -- Most TyCons: | otherwise = foldl (\t1 t2 -> noLoc (HsAppTy t1 t2)) (noLoc $ HsTyVar (getName tc)) (map (synifyType WithinType) tys) synifyType _ (AppTy t1 t2) = let s1 = synifyType WithinType t1 s2 = synifyType WithinType t2 in noLoc $ HsAppTy s1 s2 synifyType _ (FunTy t1 t2) = let s1 = synifyType WithinType t1 s2 = synifyType WithinType t2 in noLoc $ HsFunTy s1 s2 synifyType s forallty@(ForAllTy _tv _ty) = let (tvs, ctx, tau) = tcSplitSigmaTy forallty in case s of DeleteTopLevelQuantification -> synifyType ImplicitizeForAll tau _ -> let forallPlicitness = case s of WithinType -> Explicit ImplicitizeForAll -> Implicit _ -> error "synifyType: impossible case!!!" sTvs = synifyTyVars tvs sCtx = synifyCtx ctx sTau = synifyType WithinType tau in noLoc $ HsForAllTy forallPlicitness sTvs sCtx sTau