{- (c) The University of Glasgow 2006 (c) The GRASP/AQUA Project, Glasgow University, 1992-1998 -} {-# OPTIONS_GHC -Wno-incomplete-uni-patterns #-} module GHC.Tc.TyCl.Build ( buildDataCon, buildPatSyn, TcMethInfo, MethInfo, buildClass, mkNewTyConRhs, newImplicitBinder, newTyConRepName ) where import GHC.Prelude import GHC.Iface.Env import GHC.Core.FamInstEnv( FamInstEnvs, mkNewTypeCoAxiom ) import GHC.Builtin.Types( isCTupleTyConName, unboxedUnitTy ) import GHC.Core.DataCon import GHC.Core.PatSyn import GHC.Types.Var import GHC.Types.Var.Set import GHC.Types.Basic import GHC.Types.Name import GHC.Types.Name.Env import GHC.Types.Id.Make import GHC.Core.Class import GHC.Core.TyCon import GHC.Core.Type import GHC.Types.SourceText import GHC.Tc.Utils.TcType import GHC.Core.Multiplicity import GHC.Types.SrcLoc( SrcSpan, noSrcSpan ) import GHC.Tc.Utils.Monad import GHC.Types.Unique.Supply import GHC.Utils.Misc import GHC.Utils.Outputable import GHC.Utils.Panic mkNewTyConRhs :: Name -> TyCon -> DataCon -> TcRnIf m n AlgTyConRhs -- ^ Monadic because it makes a Name for the coercion TyCon -- We pass the Name of the parent TyCon, as well as the TyCon itself, -- because the latter is part of a knot, whereas the former is not. mkNewTyConRhs tycon_name tycon con = do { co_tycon_name <- newImplicitBinder tycon_name mkNewTyCoOcc ; let nt_ax = mkNewTypeCoAxiom co_tycon_name tycon etad_tvs etad_roles etad_rhs ; traceIf (text "mkNewTyConRhs" <+> ppr nt_ax) ; return (NewTyCon { data_con = con, nt_rhs = rhs_ty, nt_etad_rhs = (etad_tvs, etad_rhs), nt_co = nt_ax, nt_fixed_rep = isFixedRuntimeRepKind res_kind } ) } -- Coreview looks through newtypes with a Nothing -- for nt_co, or uses explicit coercions otherwise where tvs = tyConTyVars tycon roles = tyConRoles tycon res_kind = tyConResKind tycon con_arg_ty = case dataConRepArgTys con of [arg_ty] -> scaledThing arg_ty tys -> pprPanic "mkNewTyConRhs" (ppr con <+> ppr tys) rhs_ty = substTyWith (dataConUnivTyVars con) (mkTyVarTys tvs) con_arg_ty -- Instantiate the newtype's RHS with the -- type variables from the tycon -- NB: a newtype DataCon has a type that must look like -- forall tvs. -> T tvs -- Note that we *can't* use dataConInstOrigArgTys here because -- the newtype arising from class Foo a => Bar a where {} -- has a single argument (Foo a) that is a *type class*, so -- dataConInstOrigArgTys returns []. -- Eta-reduce the newtype -- See Note [Newtype eta] in GHC.Core.TyCon etad_tvs :: [TyVar] -- Matched lazily, so that mkNewTypeCo can etad_roles :: [Role] -- return a TyCon without pulling on rhs_ty etad_rhs :: Type -- See Note [Tricky iface loop] in GHC.Iface.Load (etad_tvs, etad_roles, etad_rhs) = eta_reduce (reverse tvs) (reverse roles) rhs_ty eta_reduce :: [TyVar] -- Reversed -> [Role] -- also reversed -> Type -- Rhs type -> ([TyVar], [Role], Type) -- Eta-reduced version -- (tyvars in normal order) eta_reduce (a:as) (_:rs) ty | Just (fun, arg) <- splitAppTy_maybe ty , Just tv <- getTyVar_maybe arg , tv == a , not (a `elemVarSet` tyCoVarsOfType fun) , typeKind fun `eqType` typeKind (mkTyConApp tycon (mkTyVarTys $ reverse as)) -- Why this kind-check? See Note [Newtype eta and homogeneous axioms] = eta_reduce as rs fun eta_reduce as rs ty = (reverse as, reverse rs, ty) {- Note [Newtype eta and homogeneous axioms] ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ When eta-reducing a newtype, we must be careful to make sure the axiom is homogeneous. (That is, the two types related by the axiom must have the same kind.) All known proofs of type safety for Core rely on the homogeneity of axioms, so let's not monkey with that. It is easy to mistakenly make an inhomogeneous axiom (#19739): type T :: forall (a :: Type) -> Type newtype T a = MkT (Proxy a) Can we eta-reduce, thus? axT :: T ~ Proxy No! Because T :: forall a -> Type Proxy :: Type -> Type This is inhomogeneous. Hence, we have an extra kind-check in eta_reduce, to make sure the reducts have the same kind. This is simple, although perhaps quadratic in complexity, if we eta-reduce many arguments (which seems vanishingly unlikely in practice). But NB that the free-variable check, which immediately precedes the kind check, is also potentially quadratic. There are other ways we could do the check (discussion on #19739): * We could look at the sequence of binders on the newtype and on the head of the representation type, and make sure the visibilities on the binders match up. This is quite a bit more code, and the reasoning is subtler. * We could, say, do the kind-check at the end and then backtrack until the kinds match up. Hard to know whether that's more performant or not. -} ------------------------------------------------------ buildDataCon :: FamInstEnvs -> DataConBangOpts -> Name -> Bool -- Declared infix -> TyConRepName -> [HsSrcBang] -> [FieldLabel] -- Field labels -> [TyVar] -- Universals -> [TyCoVar] -- Existentials -> [InvisTVBinder] -- User-written 'TyVarBinder's -> [EqSpec] -- Equality spec -> KnotTied ThetaType -- Does not include the "stupid theta" -- or the GADT equalities -> [KnotTied (Scaled Type)] -- Arguments -> KnotTied Type -- Result types -> KnotTied TyCon -- Rep tycon -> NameEnv ConTag -- Maps the Name of each DataCon to its -- ConTag -> TcRnIf m n DataCon -- A wrapper for DataCon.mkDataCon that -- a) makes the worker Id -- b) makes the wrapper Id if necessary, including -- allocating its unique (hence monadic) buildDataCon fam_envs dc_bang_opts src_name declared_infix prom_info src_bangs field_lbls univ_tvs ex_tvs user_tvbs eq_spec ctxt arg_tys res_ty rep_tycon tag_map = do { wrap_name <- newImplicitBinder src_name mkDataConWrapperOcc ; work_name <- newImplicitBinder src_name mkDataConWorkerOcc -- This last one takes the name of the data constructor in the source -- code, which (for Haskell source anyway) will be in the DataName name -- space, and puts it into the VarName name space ; traceIf (text "buildDataCon 1" <+> ppr src_name) ; us <- newUniqueSupply ; let stupid_ctxt = mkDataConStupidTheta rep_tycon (map scaledThing arg_tys) univ_tvs tag = lookupNameEnv_NF tag_map src_name -- See Note [Constructor tag allocation], fixes #14657 data_con = mkDataCon src_name declared_infix prom_info src_bangs field_lbls univ_tvs ex_tvs user_tvbs eq_spec ctxt arg_tys res_ty NoRRI rep_tycon tag stupid_ctxt dc_wrk dc_rep dc_wrk = mkDataConWorkId work_name data_con dc_rep = initUs_ us (mkDataConRep dc_bang_opts fam_envs wrap_name data_con) ; traceIf (text "buildDataCon 2" <+> ppr src_name) ; return data_con } -- The stupid context for a data constructor should be limited to -- the type variables mentioned in the arg_tys -- ToDo: Or functionally dependent on? -- This whole stupid theta thing is, well, stupid. -- -- See Note [The stupid context] in GHC.Core.DataCon. mkDataConStupidTheta :: TyCon -> [Type] -> [TyVar] -> [PredType] mkDataConStupidTheta tycon arg_tys univ_tvs | null stupid_theta = [] -- The common case | otherwise = filter in_arg_tys stupid_theta where tc_subst = zipTvSubst (tyConTyVars tycon) (mkTyVarTys univ_tvs) stupid_theta = substTheta tc_subst (tyConStupidTheta tycon) -- Start by instantiating the master copy of the -- stupid theta, taken from the TyCon arg_tyvars = tyCoVarsOfTypes arg_tys in_arg_tys pred = tyCoVarsOfType pred `intersectsVarSet` arg_tyvars ------------------------------------------------------ buildPatSyn :: Name -> Bool -> PatSynMatcher -> PatSynBuilder -> ([InvisTVBinder], ThetaType) -- ^ Univ and req -> ([InvisTVBinder], ThetaType) -- ^ Ex and prov -> [FRRType] -- ^ Argument types -> Type -- ^ Result type -> [FieldLabel] -- ^ Field labels for -- a record pattern synonym -> PatSyn buildPatSyn src_name declared_infix matcher@(_, matcher_ty,_) builder (univ_tvs, req_theta) (ex_tvs, prov_theta) arg_tys pat_ty field_labels = -- The assertion checks that the matcher is -- compatible with the pattern synonym assertPpr (and [ univ_tvs `equalLength` univ_tvs1 , ex_tvs `equalLength` ex_tvs1 , pat_ty `eqType` substTy subst (scaledThing pat_ty1) , prov_theta `eqTypes` substTys subst prov_theta1 , req_theta `eqTypes` substTys subst req_theta1 , compareArgTys arg_tys (substTys subst (map scaledThing arg_tys1)) ]) (vcat [ ppr univ_tvs <+> twiddle <+> ppr univ_tvs1 , ppr ex_tvs <+> twiddle <+> ppr ex_tvs1 , ppr pat_ty <+> twiddle <+> ppr pat_ty1 , ppr prov_theta <+> twiddle <+> ppr prov_theta1 , ppr req_theta <+> twiddle <+> ppr req_theta1 , ppr arg_tys <+> twiddle <+> ppr arg_tys1]) $ mkPatSyn src_name declared_infix (univ_tvs, req_theta) (ex_tvs, prov_theta) arg_tys pat_ty matcher builder field_labels where ((_:_:univ_tvs1), req_theta1, tau) = tcSplitSigmaTy $ matcher_ty ([pat_ty1, cont_sigma, _], _) = tcSplitFunTys tau (ex_tvs1, prov_theta1, cont_tau) = tcSplitSigmaTy (scaledThing cont_sigma) (arg_tys1, _) = (tcSplitFunTys cont_tau) twiddle = char '~' subst = zipTvSubst (univ_tvs1 ++ ex_tvs1) (mkTyVarTys (binderVars (univ_tvs ++ ex_tvs))) -- For a nullary pattern synonym we add a single (# #) argument to the -- matcher to preserve laziness in the case of unlifted types. -- See #12746 compareArgTys :: [Type] -> [Type] -> Bool compareArgTys [] [x] = x `eqType` unboxedUnitTy compareArgTys arg_tys matcher_arg_tys = arg_tys `eqTypes` matcher_arg_tys ------------------------------------------------------ type TcMethInfo = MethInfo -- this variant needs zonking type MethInfo -- A temporary intermediate, to communicate -- between tcClassSigs and buildClass. = ( Name -- Name of the class op , Type -- Type of the class op , Maybe (DefMethSpec (SrcSpan, Type))) -- Nothing => no default method -- -- Just VanillaDM => There is an ordinary -- polymorphic default method -- -- Just (GenericDM (loc, ty)) => There is a generic default metho -- Here is its type, and the location -- of the type signature -- We need that location /only/ to attach it to the -- generic default method's Name; and we need /that/ -- only to give the right location of an ambiguity error -- for the generic default method, spat out by checkValidClass buildClass :: Name -- Name of the class/tycon (they have the same Name) -> [TyConBinder] -- Of the tycon -> [Role] -> [FunDep TyVar] -- Functional dependencies -- Super classes, associated types, method info, minimal complete def. -- This is Nothing if the class is abstract. -> Maybe (KnotTied ThetaType, [ClassATItem], [KnotTied MethInfo], ClassMinimalDef) -> TcRnIf m n Class buildClass tycon_name binders roles fds Nothing = fixM $ \ rec_clas -> -- Only name generation inside loop do { traceIf (text "buildClass") ; tc_rep_name <- newTyConRepName tycon_name ; let univ_tvs = binderVars binders tycon = mkClassTyCon tycon_name binders roles AbstractTyCon rec_clas tc_rep_name result = mkAbstractClass tycon_name univ_tvs fds tycon ; traceIf (text "buildClass" <+> ppr tycon) ; return result } buildClass tycon_name binders roles fds (Just (sc_theta, at_items, sig_stuff, mindef)) = fixM $ \ rec_clas -> -- Only name generation inside loop do { traceIf (text "buildClass") ; datacon_name <- newImplicitBinder tycon_name mkClassDataConOcc ; tc_rep_name <- newTyConRepName tycon_name ; op_items <- mapM (mk_op_item rec_clas) sig_stuff -- Build the selector id and default method id -- Make selectors for the superclasses ; sc_sel_names <- mapM (newImplicitBinder tycon_name . mkSuperDictSelOcc) (takeList sc_theta [fIRST_TAG..]) ; let sc_sel_ids = [ mkDictSelId sc_name rec_clas | sc_name <- sc_sel_names] -- We number off the Dict superclass selectors, 1, 2, 3 etc so that we -- can construct names for the selectors. Thus -- class (C a, C b) => D a b where ... -- gives superclass selectors -- D_sc1, D_sc2 -- (We used to call them D_C, but now we can have two different -- superclasses both called C!) ; let use_newtype = isSingleton arg_tys -- Use a newtype if the data constructor -- (a) has exactly one value field -- i.e. exactly one operation or superclass taken together -- (b) that value is of lifted type (which they always are, because -- we box equality superclasses) -- See Note [Class newtypes and equality predicates] -- We treat the dictionary superclasses as ordinary arguments. -- That means that in the case of -- class C a => D a -- we don't get a newtype with no arguments! args = sc_sel_names ++ op_names op_tys = [ty | (_,ty,_) <- sig_stuff] op_names = [op | (op,_,_) <- sig_stuff] arg_tys = sc_theta ++ op_tys rec_tycon = classTyCon rec_clas univ_bndrs = tyConInvisTVBinders binders univ_tvs = binderVars univ_bndrs bang_opts = FixedBangOpts (map (const HsLazy) args) ; rep_nm <- newTyConRepName datacon_name ; dict_con <- buildDataCon (panic "buildClass: FamInstEnvs") bang_opts datacon_name False -- Not declared infix rep_nm (map (const no_bang) args) [{- No fields -}] univ_tvs [{- no existentials -}] univ_bndrs [{- No GADT equalities -}] [{- No theta -}] (map unrestricted arg_tys) -- type classes are unrestricted (mkTyConApp rec_tycon (mkTyVarTys univ_tvs)) rec_tycon (mkTyConTagMap rec_tycon) ; rhs <- case () of _ | use_newtype -> mkNewTyConRhs tycon_name rec_tycon dict_con | isCTupleTyConName tycon_name -> return (TupleTyCon { data_con = dict_con , tup_sort = ConstraintTuple }) | otherwise -> return (mkDataTyConRhs [dict_con]) ; let { tycon = mkClassTyCon tycon_name binders roles rhs rec_clas tc_rep_name -- A class can be recursive, and in the case of newtypes -- this matters. For example -- class C a where { op :: C b => a -> b -> Int } -- Because C has only one operation, it is represented by -- a newtype, and it should be a *recursive* newtype. -- [If we don't make it a recursive newtype, we'll expand the -- newtype like a synonym, but that will lead to an infinite -- type] ; result = mkClass tycon_name univ_tvs fds sc_theta sc_sel_ids at_items op_items mindef tycon } ; traceIf (text "buildClass" <+> ppr tycon) ; return result } where no_bang = HsSrcBang NoSourceText NoSrcUnpack NoSrcStrict mk_op_item :: Class -> TcMethInfo -> TcRnIf n m ClassOpItem mk_op_item rec_clas (op_name, _, dm_spec) = do { dm_info <- mk_dm_info op_name dm_spec ; return (mkDictSelId op_name rec_clas, dm_info) } mk_dm_info :: Name -> Maybe (DefMethSpec (SrcSpan, Type)) -> TcRnIf n m (Maybe (Name, DefMethSpec Type)) mk_dm_info _ Nothing = return Nothing mk_dm_info op_name (Just VanillaDM) = do { dm_name <- newImplicitBinder op_name mkDefaultMethodOcc ; return (Just (dm_name, VanillaDM)) } mk_dm_info op_name (Just (GenericDM (loc, dm_ty))) = do { dm_name <- newImplicitBinderLoc op_name mkDefaultMethodOcc loc ; return (Just (dm_name, GenericDM dm_ty)) } {- Note [Class newtypes and equality predicates] ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ Consider class (a ~ F b) => C a b where op :: a -> b We cannot represent this by a newtype, even though it's not existential, because there are two value fields (the equality predicate and op. See #2238 Moreover, class (a ~ F b) => C a b where {} Here we can't use a newtype either, even though there is only one field, because equality predicates are unboxed, and classes are boxed. -} newImplicitBinder :: Name -- Base name -> (OccName -> OccName) -- Occurrence name modifier -> TcRnIf m n Name -- Implicit name -- Called in GHC.Tc.TyCl.Build to allocate the implicit binders of type/class decls -- For source type/class decls, this is the first occurrence -- For iface ones, GHC.Iface.Load has already allocated a suitable name in the cache newImplicitBinder base_name mk_sys_occ = newImplicitBinderLoc base_name mk_sys_occ (nameSrcSpan base_name) newImplicitBinderLoc :: Name -- Base name -> (OccName -> OccName) -- Occurrence name modifier -> SrcSpan -> TcRnIf m n Name -- Implicit name -- Just the same, but lets you specify the SrcSpan newImplicitBinderLoc base_name mk_sys_occ loc | Just mod <- nameModule_maybe base_name = newGlobalBinder mod occ loc | otherwise -- When typechecking a [d| decl bracket |], -- TH generates types, classes etc with Internal names, -- so we follow suit for the implicit binders = do { uniq <- newUnique ; return (mkInternalName uniq occ loc) } where occ = mk_sys_occ (nameOccName base_name) -- | Make the 'TyConRepName' for this 'TyCon' newTyConRepName :: Name -> TcRnIf gbl lcl TyConRepName newTyConRepName tc_name | Just mod <- nameModule_maybe tc_name , (mod, occ) <- tyConRepModOcc mod (nameOccName tc_name) = newGlobalBinder mod occ noSrcSpan | otherwise = newImplicitBinder tc_name mkTyConRepOcc