{-# LANGUAGE CPP #-} {-# LANGUAGE DeriveFunctor #-} {-# LANGUAGE TypeFamilies #-} {-# OPTIONS_GHC -Wno-incomplete-uni-patterns #-} {- (c) The University of Glasgow 2006 (c) The GRASP/AQUA Project, Glasgow University, 1992-1999 -} -- | Analysis functions over data types. Specifically, detecting recursive types. -- -- This stuff is only used for source-code decls; it's recorded in interface -- files for imported data types. module GHC.Tc.TyCl.Utils( RolesInfo, inferRoles, checkSynCycles, checkClassCycles, -- * Implicits addTyConsToGblEnv, mkDefaultMethodType, -- * Record selectors tcRecSelBinds, mkRecSelBinds, mkOneRecordSelector ) where #include "HsVersions.h" import GHC.Prelude import GHC.Tc.Utils.Monad import GHC.Tc.Utils.Env import GHC.Tc.Gen.Bind( tcValBinds ) import GHC.Tc.Utils.TcType import GHC.Builtin.Types( unitTy ) import GHC.Builtin.Uniques ( mkBuiltinUnique ) import GHC.Hs import GHC.Core.TyCo.Rep( Type(..), Coercion(..), MCoercion(..), UnivCoProvenance(..) ) import GHC.Core.Multiplicity import GHC.Core.Predicate import GHC.Core.Make( rEC_SEL_ERROR_ID ) import GHC.Core.Class import GHC.Core.Type import GHC.Core.TyCon import GHC.Core.ConLike import GHC.Core.DataCon import GHC.Core.TyCon.Set import GHC.Core.Coercion ( ltRole ) import GHC.Utils.Outputable import GHC.Utils.Panic import GHC.Utils.Misc import GHC.Utils.FV as FV import GHC.Data.Maybe import GHC.Data.Bag import GHC.Data.FastString import GHC.Unit.Module import GHC.Types.Basic import GHC.Types.FieldLabel import GHC.Types.SrcLoc import GHC.Types.SourceFile import GHC.Types.SourceText import GHC.Types.Name import GHC.Types.Name.Env import GHC.Types.Name.Reader ( mkVarUnqual ) import GHC.Types.Id import GHC.Types.Id.Info import GHC.Types.Var.Env import GHC.Types.Var.Set import GHC.Types.Unique.Set import GHC.Types.TyThing import qualified GHC.LanguageExtensions as LangExt import Control.Monad {- ************************************************************************ * * Cycles in type synonym declarations * * ************************************************************************ -} synonymTyConsOfType :: Type -> [TyCon] -- Does not look through type synonyms at all -- Return a list of synonym tycons -- Keep this synchronized with 'expandTypeSynonyms' synonymTyConsOfType ty = nameEnvElts (go ty) where go :: Type -> NameEnv TyCon -- The NameEnv does duplicate elim go (TyConApp tc tys) = go_tc tc `plusNameEnv` go_s tys go (LitTy _) = emptyNameEnv go (TyVarTy _) = emptyNameEnv go (AppTy a b) = go a `plusNameEnv` go b go (FunTy _ w a b) = go w `plusNameEnv` go a `plusNameEnv` go b go (ForAllTy _ ty) = go ty go (CastTy ty co) = go ty `plusNameEnv` go_co co go (CoercionTy co) = go_co co -- Note [TyCon cycles through coercions?!] -- ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ -- Although, in principle, it's possible for a type synonym loop -- could go through a coercion (since a coercion can refer to -- a TyCon or Type), it doesn't seem possible to actually construct -- a Haskell program which tickles this case. Here is an example -- program which causes a coercion: -- -- type family Star where -- Star = Type -- -- data T :: Star -> Type -- data S :: forall (a :: Type). T a -> Type -- -- Here, the application 'T a' must first coerce a :: Type to a :: Star, -- witnessed by the type family. But if we now try to make Type refer -- to a type synonym which in turn refers to Star, we'll run into -- trouble: we're trying to define and use the type constructor -- in the same recursive group. Possibly this restriction will be -- lifted in the future but for now, this code is "just for completeness -- sake". go_mco MRefl = emptyNameEnv go_mco (MCo co) = go_co co go_co (Refl ty) = go ty go_co (GRefl _ ty mco) = go ty `plusNameEnv` go_mco mco go_co (TyConAppCo _ tc cs) = go_tc tc `plusNameEnv` go_co_s cs go_co (AppCo co co') = go_co co `plusNameEnv` go_co co' go_co (ForAllCo _ co co') = go_co co `plusNameEnv` go_co co' go_co (FunCo _ co_mult co co') = go_co co_mult `plusNameEnv` go_co co `plusNameEnv` go_co co' go_co (CoVarCo _) = emptyNameEnv go_co (HoleCo {}) = emptyNameEnv go_co (AxiomInstCo _ _ cs) = go_co_s cs go_co (UnivCo p _ ty ty') = go_prov p `plusNameEnv` go ty `plusNameEnv` go ty' go_co (SymCo co) = go_co co go_co (TransCo co co') = go_co co `plusNameEnv` go_co co' go_co (NthCo _ _ co) = go_co co go_co (LRCo _ co) = go_co co go_co (InstCo co co') = go_co co `plusNameEnv` go_co co' go_co (KindCo co) = go_co co go_co (SubCo co) = go_co co go_co (AxiomRuleCo _ cs) = go_co_s cs go_prov (PhantomProv co) = go_co co go_prov (ProofIrrelProv co) = go_co co go_prov (PluginProv _) = emptyNameEnv go_tc tc | isTypeSynonymTyCon tc = unitNameEnv (tyConName tc) tc | otherwise = emptyNameEnv go_s tys = foldr (plusNameEnv . go) emptyNameEnv tys go_co_s cos = foldr (plusNameEnv . go_co) emptyNameEnv cos -- | A monad for type synonym cycle checking, which keeps -- track of the TyCons which are known to be acyclic, or -- a failure message reporting that a cycle was found. newtype SynCycleM a = SynCycleM { runSynCycleM :: SynCycleState -> Either (SrcSpan, SDoc) (a, SynCycleState) } deriving (Functor) -- TODO: TyConSet is implemented as IntMap over uniques. -- But we could get away with something based on IntSet -- since we only check membershib, but never extract the -- elements. type SynCycleState = TyConSet instance Applicative SynCycleM where pure x = SynCycleM $ \state -> Right (x, state) (<*>) = ap instance Monad SynCycleM where m >>= f = SynCycleM $ \state -> case runSynCycleM m state of Right (x, state') -> runSynCycleM (f x) state' Left err -> Left err failSynCycleM :: SrcSpan -> SDoc -> SynCycleM () failSynCycleM loc err = SynCycleM $ \_ -> Left (loc, err) -- | Test if a 'Name' is acyclic, short-circuiting if we've -- seen it already. checkTyConIsAcyclic :: TyCon -> SynCycleM () -> SynCycleM () checkTyConIsAcyclic tc m = SynCycleM $ \s -> if tc `elemTyConSet` s then Right ((), s) -- short circuit else case runSynCycleM m s of Right ((), s') -> Right ((), extendTyConSet s' tc) Left err -> Left err -- | Checks if any of the passed in 'TyCon's have cycles. -- Takes the 'Unit' of the home package (as we can avoid -- checking those TyCons: cycles never go through foreign packages) and -- the corresponding @LTyClDecl Name@ for each 'TyCon', so we -- can give better error messages. checkSynCycles :: Unit -> [TyCon] -> [LTyClDecl GhcRn] -> TcM () checkSynCycles this_uid tcs tyclds = case runSynCycleM (mapM_ (go emptyTyConSet []) tcs) emptyTyConSet of Left (loc, err) -> setSrcSpan loc $ failWithTc err Right _ -> return () where -- Try our best to print the LTyClDecl for locally defined things lcl_decls = mkNameEnv (zip (map tyConName tcs) tyclds) -- Short circuit if we've already seen this Name and concluded -- it was acyclic. go :: TyConSet -> [TyCon] -> TyCon -> SynCycleM () go so_far seen_tcs tc = checkTyConIsAcyclic tc $ go' so_far seen_tcs tc -- Expand type synonyms, complaining if you find the same -- type synonym a second time. go' :: TyConSet -> [TyCon] -> TyCon -> SynCycleM () go' so_far seen_tcs tc | tc `elemTyConSet` so_far = failSynCycleM (getSrcSpan (head seen_tcs)) $ sep [ text "Cycle in type synonym declarations:" , nest 2 (vcat (map ppr_decl seen_tcs)) ] -- Optimization: we don't allow cycles through external packages, -- so once we find a non-local name we are guaranteed to not -- have a cycle. -- -- This won't hold once we get recursive packages with Backpack, -- but for now it's fine. | not (isHoleModule mod || moduleUnit mod == this_uid || isInteractiveModule mod) = return () | Just ty <- synTyConRhs_maybe tc = go_ty (extendTyConSet so_far tc) (tc:seen_tcs) ty | otherwise = return () where n = tyConName tc mod = nameModule n ppr_decl tc = case lookupNameEnv lcl_decls n of Just (L loc decl) -> ppr (locA loc) <> colon <+> ppr decl Nothing -> ppr (getSrcSpan n) <> colon <+> ppr n <+> text "from external module" where n = tyConName tc go_ty :: TyConSet -> [TyCon] -> Type -> SynCycleM () go_ty so_far seen_tcs ty = mapM_ (go so_far seen_tcs) (synonymTyConsOfType ty) {- Note [Superclass cycle check] ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ The superclass cycle check for C decides if we can statically guarantee that expanding C's superclass cycles transitively is guaranteed to terminate. This is a Haskell98 requirement, but one that we lift with -XUndecidableSuperClasses. The worry is that a superclass cycle could make the type checker loop. More precisely, with a constraint (Given or Wanted) C ty1 .. tyn one approach is to instantiate all of C's superclasses, transitively. We can only do so if that set is finite. This potential loop occurs only through superclasses. This, for example, is fine class C a where op :: C b => a -> b -> b even though C's full definition uses C. Making the check static also makes it conservative. Eg type family F a class F a => C a Here an instance of (F a) might mention C: type instance F [a] = C a and now we'd have a loop. The static check works like this, starting with C * Look at C's superclass predicates * If any is a type-function application, or is headed by a type variable, fail * If any has C at the head, fail * If any has a type class D at the head, make the same test with D A tricky point is: what if there is a type variable at the head? Consider this: class f (C f) => C f class c => Id c and now expand superclasses for constraint (C Id): C Id --> Id (C Id) --> C Id --> .... Each step expands superclasses one layer, and clearly does not terminate. -} type ClassSet = UniqSet Class checkClassCycles :: Class -> Maybe SDoc -- Nothing <=> ok -- Just err <=> possible cycle error checkClassCycles cls = do { (definite_cycle, err) <- go (unitUniqSet cls) cls (mkTyVarTys (classTyVars cls)) ; let herald | definite_cycle = text "Superclass cycle for" | otherwise = text "Potential superclass cycle for" ; return (vcat [ herald <+> quotes (ppr cls) , nest 2 err, hint]) } where hint = text "Use UndecidableSuperClasses to accept this" -- Expand superclasses starting with (C a b), complaining -- if you find the same class a second time, or a type function -- or predicate headed by a type variable -- -- NB: this code duplicates TcType.transSuperClasses, but -- with more error message generation clobber -- Make sure the two stay in sync. go :: ClassSet -> Class -> [Type] -> Maybe (Bool, SDoc) go so_far cls tys = firstJusts $ map (go_pred so_far) $ immSuperClasses cls tys go_pred :: ClassSet -> PredType -> Maybe (Bool, SDoc) -- Nothing <=> ok -- Just (True, err) <=> definite cycle -- Just (False, err) <=> possible cycle go_pred so_far pred -- NB: tcSplitTyConApp looks through synonyms | Just (tc, tys) <- tcSplitTyConApp_maybe pred = go_tc so_far pred tc tys | hasTyVarHead pred = Just (False, hang (text "one of whose superclass constraints is headed by a type variable:") 2 (quotes (ppr pred))) | otherwise = Nothing go_tc :: ClassSet -> PredType -> TyCon -> [Type] -> Maybe (Bool, SDoc) go_tc so_far pred tc tys | isFamilyTyCon tc = Just (False, hang (text "one of whose superclass constraints is headed by a type family:") 2 (quotes (ppr pred))) | Just cls <- tyConClass_maybe tc = go_cls so_far cls tys | otherwise -- Equality predicate, for example = Nothing go_cls :: ClassSet -> Class -> [Type] -> Maybe (Bool, SDoc) go_cls so_far cls tys | cls `elementOfUniqSet` so_far = Just (True, text "one of whose superclasses is" <+> quotes (ppr cls)) | isCTupleClass cls = go so_far cls tys | otherwise = do { (b,err) <- go (so_far `addOneToUniqSet` cls) cls tys ; return (b, text "one of whose superclasses is" <+> quotes (ppr cls) $$ err) } {- ************************************************************************ * * Role inference * * ************************************************************************ Note [Role inference] ~~~~~~~~~~~~~~~~~~~~~ The role inference algorithm datatype definitions to infer the roles on the parameters. Although these roles are stored in the tycons, we can perform this algorithm on the built tycons, as long as we don't peek at an as-yet-unknown roles field! Ah, the magic of laziness. First, we choose appropriate initial roles. For families and classes, roles (including initial roles) are N. For datatypes, we start with the role in the role annotation (if any), or otherwise use Phantom. This is done in initialRoleEnv1. The function irGroup then propagates role information until it reaches a fixpoint, preferring N over (R or P) and R over P. To aid in this, we have a monad RoleM, which is a combination reader and state monad. In its state are the current RoleEnv, which gets updated by role propagation, and an update bit, which we use to know whether or not we've reached the fixpoint. The environment of RoleM contains the tycon whose parameters we are inferring, and a VarEnv from parameters to their positions, so we can update the RoleEnv. Between tycons, this reader information is missing; it is added by addRoleInferenceInfo. There are two kinds of tycons to consider: algebraic ones (excluding classes) and type synonyms. (Remember, families don't participate -- all their parameters are N.) An algebraic tycon processes each of its datacons, in turn. Note that a datacon's universally quantified parameters might be different from the parent tycon's parameters, so we use the datacon's univ parameters in the mapping from vars to positions. Note also that we don't want to infer roles for existentials (they're all at N, too), so we put them in the set of local variables. As an optimisation, we skip any tycons whose roles are already all Nominal, as there nowhere else for them to go. For synonyms, we just analyse their right-hand sides. irType walks through a type, looking for uses of a variable of interest and propagating role information. Because anything used under a phantom position is at phantom and anything used under a nominal position is at nominal, the irType function can assume that anything it sees is at representational. (The other possibilities are pruned when they're encountered.) The rest of the code is just plumbing. How do we know that this algorithm is correct? It should meet the following specification: Let Z be a role context -- a mapping from variables to roles. The following rules define the property (Z |- t : r), where t is a type and r is a role: Z(a) = r' r' <= r ------------------------- RCVar Z |- a : r ---------- RCConst Z |- T : r -- T is a type constructor Z |- t1 : r Z |- t2 : N -------------- RCApp Z |- t1 t2 : r forall i<=n. (r_i is R or N) implies Z |- t_i : r_i roles(T) = r_1 .. r_n ---------------------------------------------------- RCDApp Z |- T t_1 .. t_n : R Z, a:N |- t : r ---------------------- RCAll Z |- forall a:k.t : r We also have the following rules: For all datacon_i in type T, where a_1 .. a_n are universally quantified and b_1 .. b_m are existentially quantified, and the arguments are t_1 .. t_p, then if forall j<=p, a_1 : r_1 .. a_n : r_n, b_1 : N .. b_m : N |- t_j : R, then roles(T) = r_1 .. r_n roles(->) = R, R roles(~#) = N, N With -dcore-lint on, the output of this algorithm is checked in checkValidRoles, called from checkValidTycon. Note [Role-checking data constructor arguments] ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ Consider data T a where MkT :: Eq b => F a -> (a->a) -> T (G a) Then we want to check the roles at which 'a' is used in MkT's type. We want to work on the user-written type, so we need to take into account * the arguments: (F a) and (a->a) * the context: C a b * the result type: (G a) -- this is in the eq_spec Note [Coercions in role inference] ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ Is (t |> co1) representationally equal to (t |> co2)? Of course they are! Changing the kind of a type is totally irrelevant to the representation of that type. So, we want to totally ignore coercions when doing role inference. This includes omitting any type variables that appear in nominal positions but only within coercions. -} type RolesInfo = Name -> [Role] type RoleEnv = NameEnv [Role] -- from tycon names to roles -- This, and any of the functions it calls, must *not* look at the roles -- field of a tycon we are inferring roles about! -- See Note [Role inference] inferRoles :: HscSource -> RoleAnnotEnv -> [TyCon] -> Name -> [Role] inferRoles hsc_src annots tycons = let role_env = initialRoleEnv hsc_src annots tycons role_env' = irGroup role_env tycons in \name -> case lookupNameEnv role_env' name of Just roles -> roles Nothing -> pprPanic "inferRoles" (ppr name) initialRoleEnv :: HscSource -> RoleAnnotEnv -> [TyCon] -> RoleEnv initialRoleEnv hsc_src annots = extendNameEnvList emptyNameEnv . map (initialRoleEnv1 hsc_src annots) initialRoleEnv1 :: HscSource -> RoleAnnotEnv -> TyCon -> (Name, [Role]) initialRoleEnv1 hsc_src annots_env tc | isFamilyTyCon tc = (name, map (const Nominal) bndrs) | isAlgTyCon tc = (name, default_roles) | isTypeSynonymTyCon tc = (name, default_roles) | otherwise = pprPanic "initialRoleEnv1" (ppr tc) where name = tyConName tc bndrs = tyConBinders tc argflags = map tyConBinderArgFlag bndrs num_exps = count isVisibleArgFlag argflags -- if the number of annotations in the role annotation decl -- is wrong, just ignore it. We check this in the validity check. role_annots = case lookupRoleAnnot annots_env name of Just (L _ (RoleAnnotDecl _ _ annots)) | annots `lengthIs` num_exps -> map unLoc annots _ -> replicate num_exps Nothing default_roles = build_default_roles argflags role_annots build_default_roles (argf : argfs) (m_annot : ras) | isVisibleArgFlag argf = (m_annot `orElse` default_role) : build_default_roles argfs ras build_default_roles (_argf : argfs) ras = Nominal : build_default_roles argfs ras build_default_roles [] [] = [] build_default_roles _ _ = pprPanic "initialRoleEnv1 (2)" (vcat [ppr tc, ppr role_annots]) default_role | isClassTyCon tc = Nominal -- Note [Default roles for abstract TyCons in hs-boot/hsig] | HsBootFile <- hsc_src , isAbstractTyCon tc = Representational | HsigFile <- hsc_src , isAbstractTyCon tc = Nominal | otherwise = Phantom -- Note [Default roles for abstract TyCons in hs-boot/hsig] -- ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ -- What should the default role for an abstract TyCon be? -- -- Originally, we inferred phantom role for abstract TyCons -- in hs-boot files, because the type variables were never used. -- -- This was silly, because the role of the abstract TyCon -- was required to match the implementation, and the roles of -- data types are almost never phantom. Thus, in ticket #9204, -- the default was changed so be representational (the most common case). If -- the implementing data type was actually nominal, you'd get an easy -- to understand error, and add the role annotation yourself. -- -- Then Backpack was added, and with it we added role *subtyping* -- the matching judgment: if an abstract TyCon has a nominal -- parameter, it's OK to implement it with a representational -- parameter. But now, the representational default is not a good -- one, because you should *only* request representational if -- you're planning to do coercions. To be maximally flexible -- with what data types you will accept, you want the default -- for hsig files is nominal. We don't allow role subtyping -- with hs-boot files (it's good practice to give an exactly -- accurate role here, because any types that use the abstract -- type will propagate the role information.) irGroup :: RoleEnv -> [TyCon] -> RoleEnv irGroup env tcs = let (env', update) = runRoleM env $ mapM_ irTyCon tcs in if update then irGroup env' tcs else env' irTyCon :: TyCon -> RoleM () irTyCon tc | isAlgTyCon tc = do { old_roles <- lookupRoles tc ; unless (all (== Nominal) old_roles) $ -- also catches data families, -- which don't want or need role inference irTcTyVars tc $ do { mapM_ (irType emptyVarSet) (tyConStupidTheta tc) -- See #8958 ; whenIsJust (tyConClass_maybe tc) irClass ; mapM_ irDataCon (visibleDataCons $ algTyConRhs tc) }} | Just ty <- synTyConRhs_maybe tc = irTcTyVars tc $ irType emptyVarSet ty | otherwise = return () -- any type variable used in an associated type must be Nominal irClass :: Class -> RoleM () irClass cls = mapM_ ir_at (classATs cls) where cls_tvs = classTyVars cls cls_tv_set = mkVarSet cls_tvs ir_at at_tc = mapM_ (updateRole Nominal) nvars where nvars = filter (`elemVarSet` cls_tv_set) $ tyConTyVars at_tc -- See Note [Role inference] irDataCon :: DataCon -> RoleM () irDataCon datacon = setRoleInferenceVars univ_tvs $ irExTyVars ex_tvs $ \ ex_var_set -> do mapM_ (irType ex_var_set) (eqSpecPreds eq_spec ++ theta ++ map scaledThing arg_tys) mapM_ (markNominal ex_var_set) (map tyVarKind ex_tvs ++ map scaledMult arg_tys) -- Field multiplicities are nominal (#18799) -- See Note [Role-checking data constructor arguments] where (univ_tvs, ex_tvs, eq_spec, theta, arg_tys, _res_ty) = dataConFullSig datacon irType :: VarSet -> Type -> RoleM () irType = go where go lcls ty | Just ty' <- coreView ty -- #14101 = go lcls ty' go lcls (TyVarTy tv) = unless (tv `elemVarSet` lcls) $ updateRole Representational tv go lcls (AppTy t1 t2) = go lcls t1 >> markNominal lcls t2 go lcls (TyConApp tc tys) = do { roles <- lookupRolesX tc ; zipWithM_ (go_app lcls) roles tys } go lcls (ForAllTy tvb ty) = do { let tv = binderVar tvb lcls' = extendVarSet lcls tv ; markNominal lcls (tyVarKind tv) ; go lcls' ty } go lcls (FunTy _ w arg res) = markNominal lcls w >> go lcls arg >> go lcls res go _ (LitTy {}) = return () -- See Note [Coercions in role inference] go lcls (CastTy ty _) = go lcls ty go _ (CoercionTy _) = return () go_app _ Phantom _ = return () -- nothing to do here go_app lcls Nominal ty = markNominal lcls ty -- all vars below here are N go_app lcls Representational ty = go lcls ty irTcTyVars :: TyCon -> RoleM a -> RoleM a irTcTyVars tc thing = setRoleInferenceTc (tyConName tc) $ go (tyConTyVars tc) where go [] = thing go (tv:tvs) = do { markNominal emptyVarSet (tyVarKind tv) ; addRoleInferenceVar tv $ go tvs } irExTyVars :: [TyVar] -> (TyVarSet -> RoleM a) -> RoleM a irExTyVars orig_tvs thing = go emptyVarSet orig_tvs where go lcls [] = thing lcls go lcls (tv:tvs) = do { markNominal lcls (tyVarKind tv) ; go (extendVarSet lcls tv) tvs } markNominal :: TyVarSet -- local variables -> Type -> RoleM () markNominal lcls ty = let nvars = fvVarList (FV.delFVs lcls $ get_ty_vars ty) in mapM_ (updateRole Nominal) nvars where -- get_ty_vars gets all the tyvars (no covars!) from a type *without* -- recurring into coercions. Recall: coercions are totally ignored during -- role inference. See [Coercions in role inference] get_ty_vars :: Type -> FV get_ty_vars (TyVarTy tv) = unitFV tv get_ty_vars (AppTy t1 t2) = get_ty_vars t1 `unionFV` get_ty_vars t2 get_ty_vars (FunTy _ w t1 t2) = get_ty_vars w `unionFV` get_ty_vars t1 `unionFV` get_ty_vars t2 get_ty_vars (TyConApp _ tys) = mapUnionFV get_ty_vars tys get_ty_vars (ForAllTy tvb ty) = tyCoFVsBndr tvb (get_ty_vars ty) get_ty_vars (LitTy {}) = emptyFV get_ty_vars (CastTy ty _) = get_ty_vars ty get_ty_vars (CoercionTy _) = emptyFV -- like lookupRoles, but with Nominal tags at the end for oversaturated TyConApps lookupRolesX :: TyCon -> RoleM [Role] lookupRolesX tc = do { roles <- lookupRoles tc ; return $ roles ++ repeat Nominal } -- gets the roles either from the environment or the tycon lookupRoles :: TyCon -> RoleM [Role] lookupRoles tc = do { env <- getRoleEnv ; case lookupNameEnv env (tyConName tc) of Just roles -> return roles Nothing -> return $ tyConRoles tc } -- tries to update a role; won't ever update a role "downwards" updateRole :: Role -> TyVar -> RoleM () updateRole role tv = do { var_ns <- getVarNs ; name <- getTyConName ; case lookupVarEnv var_ns tv of Nothing -> pprPanic "updateRole" (ppr name $$ ppr tv $$ ppr var_ns) Just n -> updateRoleEnv name n role } -- the state in the RoleM monad data RoleInferenceState = RIS { role_env :: RoleEnv , update :: Bool } -- the environment in the RoleM monad type VarPositions = VarEnv Int -- See [Role inference] newtype RoleM a = RM { unRM :: Maybe Name -- of the tycon -> VarPositions -> Int -- size of VarPositions -> RoleInferenceState -> (a, RoleInferenceState) } deriving (Functor) instance Applicative RoleM where pure x = RM $ \_ _ _ state -> (x, state) (<*>) = ap instance Monad RoleM where a >>= f = RM $ \m_info vps nvps state -> let (a', state') = unRM a m_info vps nvps state in unRM (f a') m_info vps nvps state' runRoleM :: RoleEnv -> RoleM () -> (RoleEnv, Bool) runRoleM env thing = (env', update) where RIS { role_env = env', update = update } = snd $ unRM thing Nothing emptyVarEnv 0 state state = RIS { role_env = env , update = False } setRoleInferenceTc :: Name -> RoleM a -> RoleM a setRoleInferenceTc name thing = RM $ \m_name vps nvps state -> ASSERT( isNothing m_name ) ASSERT( isEmptyVarEnv vps ) ASSERT( nvps == 0 ) unRM thing (Just name) vps nvps state addRoleInferenceVar :: TyVar -> RoleM a -> RoleM a addRoleInferenceVar tv thing = RM $ \m_name vps nvps state -> ASSERT( isJust m_name ) unRM thing m_name (extendVarEnv vps tv nvps) (nvps+1) state setRoleInferenceVars :: [TyVar] -> RoleM a -> RoleM a setRoleInferenceVars tvs thing = RM $ \m_name _vps _nvps state -> ASSERT( isJust m_name ) unRM thing m_name (mkVarEnv (zip tvs [0..])) (panic "setRoleInferenceVars") state getRoleEnv :: RoleM RoleEnv getRoleEnv = RM $ \_ _ _ state@(RIS { role_env = env }) -> (env, state) getVarNs :: RoleM VarPositions getVarNs = RM $ \_ vps _ state -> (vps, state) getTyConName :: RoleM Name getTyConName = RM $ \m_name _ _ state -> case m_name of Nothing -> panic "getTyConName" Just name -> (name, state) updateRoleEnv :: Name -> Int -> Role -> RoleM () updateRoleEnv name n role = RM $ \_ _ _ state@(RIS { role_env = role_env }) -> ((), case lookupNameEnv role_env name of Nothing -> pprPanic "updateRoleEnv" (ppr name) Just roles -> let (before, old_role : after) = splitAt n roles in if role `ltRole` old_role then let roles' = before ++ role : after role_env' = extendNameEnv role_env name roles' in RIS { role_env = role_env', update = True } else state ) {- ********************************************************************* * * Building implicits * * ********************************************************************* -} addTyConsToGblEnv :: [TyCon] -> TcM TcGblEnv -- Given a [TyCon], add to the TcGblEnv -- * extend the TypeEnv with the tycons -- * extend the TypeEnv with their implicitTyThings -- * extend the TypeEnv with any default method Ids -- * add bindings for record selectors addTyConsToGblEnv tyclss = tcExtendTyConEnv tyclss $ tcExtendGlobalEnvImplicit implicit_things $ tcExtendGlobalValEnv def_meth_ids $ do { traceTc "tcAddTyCons" $ vcat [ text "tycons" <+> ppr tyclss , text "implicits" <+> ppr implicit_things ] ; tcRecSelBinds (mkRecSelBinds tyclss) } where implicit_things = concatMap implicitTyConThings tyclss def_meth_ids = mkDefaultMethodIds tyclss mkDefaultMethodIds :: [TyCon] -> [Id] -- We want to put the default-method Ids (both vanilla and generic) -- into the type environment so that they are found when we typecheck -- the filled-in default methods of each instance declaration -- See Note [Default method Ids and Template Haskell] mkDefaultMethodIds tycons = [ mkExportedVanillaId dm_name (mkDefaultMethodType cls sel_id dm_spec) | tc <- tycons , Just cls <- [tyConClass_maybe tc] , (sel_id, Just (dm_name, dm_spec)) <- classOpItems cls ] mkDefaultMethodType :: Class -> Id -> DefMethSpec Type -> Type -- Returns the top-level type of the default method mkDefaultMethodType _ sel_id VanillaDM = idType sel_id mkDefaultMethodType cls _ (GenericDM dm_ty) = mkSigmaTy tv_bndrs [pred] dm_ty where pred = mkClassPred cls (mkTyVarTys (binderVars cls_bndrs)) cls_bndrs = tyConBinders (classTyCon cls) tv_bndrs = tyVarSpecToBinders $ tyConInvisTVBinders cls_bndrs -- NB: the Class doesn't have TyConBinders; we reach into its -- TyCon to get those. We /do/ need the TyConBinders because -- we need the correct visibility: these default methods are -- used in code generated by the fill-in for missing -- methods in instances (GHC.Tc.TyCl.Instance.mkDefMethBind), and -- then typechecked. So we need the right visibility info -- (#13998) {- ************************************************************************ * * Building record selectors * * ************************************************************************ -} {- Note [Default method Ids and Template Haskell] ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ Consider this (#4169): class Numeric a where fromIntegerNum :: a fromIntegerNum = ... ast :: Q [Dec] ast = [d| instance Numeric Int |] When we typecheck 'ast' we have done the first pass over the class decl (in tcTyClDecls), but we have not yet typechecked the default-method declarations (because they can mention value declarations). So we must bring the default method Ids into scope first (so they can be seen when typechecking the [d| .. |] quote, and typecheck them later. -} {- ************************************************************************ * * Building record selectors * * ************************************************************************ -} tcRecSelBinds :: [(Id, LHsBind GhcRn)] -> TcM TcGblEnv tcRecSelBinds sel_bind_prs = tcExtendGlobalValEnv [sel_id | (L _ (IdSig _ sel_id)) <- sigs] $ do { (rec_sel_binds, tcg_env) <- discardWarnings $ -- See Note [Impredicative record selectors] setXOptM LangExt.ImpredicativeTypes $ tcValBinds TopLevel binds sigs getGblEnv ; return (tcg_env `addTypecheckedBinds` map snd rec_sel_binds) } where sigs = [ L (noAnnSrcSpan loc) (IdSig noExtField sel_id) | (sel_id, _) <- sel_bind_prs , let loc = getSrcSpan sel_id ] binds = [(NonRecursive, unitBag bind) | (_, bind) <- sel_bind_prs] mkRecSelBinds :: [TyCon] -> [(Id, LHsBind GhcRn)] -- NB We produce *un-typechecked* bindings, rather like 'deriving' -- This makes life easier, because the later type checking will add -- all necessary type abstractions and applications mkRecSelBinds tycons = map mkRecSelBind [ (tc,fld) | tc <- tycons , fld <- tyConFieldLabels tc ] mkRecSelBind :: (TyCon, FieldLabel) -> (Id, LHsBind GhcRn) mkRecSelBind (tycon, fl) = mkOneRecordSelector all_cons (RecSelData tycon) fl FieldSelectors -- See Note [NoFieldSelectors and naughty record selectors] where all_cons = map RealDataCon (tyConDataCons tycon) mkOneRecordSelector :: [ConLike] -> RecSelParent -> FieldLabel -> FieldSelectors -> (Id, LHsBind GhcRn) mkOneRecordSelector all_cons idDetails fl has_sel = (sel_id, L (noAnnSrcSpan loc) sel_bind) where loc = getSrcSpan sel_name loc' = noAnnSrcSpan loc locn = noAnnSrcSpan loc lbl = flLabel fl sel_name = flSelector fl sel_id = mkExportedLocalId rec_details sel_name sel_ty rec_details = RecSelId { sel_tycon = idDetails, sel_naughty = is_naughty } -- Find a representative constructor, con1 cons_w_field = conLikesWithFields all_cons [lbl] con1 = ASSERT( not (null cons_w_field) ) head cons_w_field -- Selector type; Note [Polymorphic selectors] field_ty = conLikeFieldType con1 lbl data_tvbs = filter (\tvb -> binderVar tvb `elemVarSet` data_tv_set) $ conLikeUserTyVarBinders con1 data_tv_set= tyCoVarsOfTypes inst_tys is_naughty = not (tyCoVarsOfType field_ty `subVarSet` data_tv_set) || has_sel == NoFieldSelectors sel_ty | is_naughty = unitTy -- See Note [Naughty record selectors] | otherwise = mkForAllTys (tyVarSpecToBinders data_tvbs) $ mkPhiTy (conLikeStupidTheta con1) $ -- Urgh! -- req_theta is empty for normal DataCon mkPhiTy req_theta $ mkVisFunTyMany data_ty $ -- Record selectors are always typed with Many. We -- could improve on it in the case where all the -- fields in all the constructor have multiplicity Many. field_ty -- Make the binding: sel (C2 { fld = x }) = x -- sel (C7 { fld = x }) = x -- where cons_w_field = [C2,C7] sel_bind = mkTopFunBind Generated sel_lname alts where alts | is_naughty = [mkSimpleMatch (mkPrefixFunRhs sel_lname) [] unit_rhs] | otherwise = map mk_match cons_w_field ++ deflt mk_match con = mkSimpleMatch (mkPrefixFunRhs sel_lname) [L loc' (mk_sel_pat con)] (L loc' (HsVar noExtField (L locn field_var))) mk_sel_pat con = ConPat NoExtField (L locn (getName con)) (RecCon rec_fields) rec_fields = HsRecFields { rec_flds = [rec_field], rec_dotdot = Nothing } rec_field = noLocA (HsRecField { hsRecFieldAnn = noAnn , hsRecFieldLbl = L loc (FieldOcc sel_name (L locn $ mkVarUnqual lbl)) , hsRecFieldArg = L loc' (VarPat noExtField (L locn field_var)) , hsRecPun = False }) sel_lname = L locn sel_name field_var = mkInternalName (mkBuiltinUnique 1) (getOccName sel_name) loc -- Add catch-all default case unless the case is exhaustive -- We do this explicitly so that we get a nice error message that -- mentions this particular record selector deflt | all dealt_with all_cons = [] | otherwise = [mkSimpleMatch CaseAlt [L loc' (WildPat noExtField)] (mkHsApp (L loc' (HsVar noExtField (L locn (getName rEC_SEL_ERROR_ID)))) (L loc' (HsLit noComments msg_lit)))] -- Do not add a default case unless there are unmatched -- constructors. We must take account of GADTs, else we -- get overlap warning messages from the pattern-match checker -- NB: we need to pass type args for the *representation* TyCon -- to dataConCannotMatch, hence the calculation of inst_tys -- This matters in data families -- data instance T Int a where -- A :: { fld :: Int } -> T Int Bool -- B :: { fld :: Int } -> T Int Char dealt_with :: ConLike -> Bool dealt_with (PatSynCon _) = False -- We can't predict overlap dealt_with con@(RealDataCon dc) = con `elem` cons_w_field || dataConCannotMatch inst_tys dc (univ_tvs, _, eq_spec, _, req_theta, _, data_ty) = conLikeFullSig con1 eq_subst = mkTvSubstPrs (map eqSpecPair eq_spec) -- inst_tys corresponds to one of the following: -- -- * The arguments to the user-written return type (for GADT constructors). -- In this scenario, eq_subst provides a mapping from the universally -- quantified type variables to the argument types. Note that eq_subst -- does not need to be applied to any other part of the DataCon -- (see Note [The dcEqSpec domain invariant] in GHC.Core.DataCon). -- * The universally quantified type variables -- (for Haskell98-style constructors and pattern synonyms). In these -- scenarios, eq_subst is an empty substitution. inst_tys = substTyVars eq_subst univ_tvs unit_rhs = mkLHsTupleExpr [] noExtField msg_lit = HsStringPrim NoSourceText (bytesFS lbl) {- Note [Polymorphic selectors] ~~~~~~~~~~~~~~~~~~~~~~~~~~~~ We take care to build the type of a polymorphic selector in the right order, so that visible type application works according to the specification in the GHC User's Guide (see the "Field selectors and TypeApplications" section). We won't bother rehashing the entire specification in this Note, but the tricky part is dealing with GADT constructor fields. Here is an appropriately tricky example to illustrate the challenges: {-# LANGUAGE PolyKinds #-} data T a b where MkT :: forall b a x. { field1 :: forall c. (Num a, Show c) => (Either a c, Proxy b) , field2 :: x } -> T a b Our goal is to obtain the following type for `field1`: field1 :: forall {k} (b :: k) a. T a b -> forall c. (Num a, Show c) => (Either a c, Proxy b) (`field2` is naughty, per Note [Naughty record selectors], so we cannot turn it into a top-level field selector.) Some potential gotchas, inspired by #18023: 1. Since the user wrote `forall b a x.` in the type of `MkT`, we want the `b` to appear before the `a` when quantified in the type of `field1`. 2. On the other hand, we *don't* want to quantify `x` in the type of `field1`. This is because `x` does not appear in the GADT return type, so it is not needed in the selector type. 3. Because of PolyKinds, the kind of `b` is generalized to `k`. Moreover, since this `k` is not written in the source code, it is inferred (i.e., not available for explicit type applications) and thus written as {k} in the type of `field1`. In order to address these gotchas, we start by looking at the conLikeUserTyVarBinders, which gives the order and specificity of each binder. This effectively solves (1) and (3). To solve (2), we filter the binders to leave only those that are needed for the selector type. Note [Naughty record selectors] ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ A "naughty" field is one for which we can't define a record selector, because an existential type variable would escape. For example: data T = forall a. MkT { x,y::a } We obviously can't define x (MkT v _) = v Nevertheless we *do* put a RecSelId into the type environment so that if the user tries to use 'x' as a selector we can bleat helpfully, rather than saying unhelpfully that 'x' is not in scope. Hence the sel_naughty flag, to identify record selectors that don't really exist. In general, a field is "naughty" if its type mentions a type variable that isn't in the result type of the constructor. Note that this *allows* GADT record selectors (Note [GADT record selectors]) whose types may look like sel :: T [a] -> a For naughty selectors we make a dummy binding sel = () so that the later type-check will add them to the environment, and they'll be exported. The function is never called, because the typechecker spots the sel_naughty field. Note [NoFieldSelectors and naughty record selectors] ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ Under NoFieldSelectors (see Note [NoFieldSelectors] in GHC.Rename.Env), record selectors will not be in scope in the renamer. However, for normal datatype declarations we still generate the underlying selector functions, so they can be used for constructing the dictionaries for HasField constraints (as described by Note [HasField instances] in GHC.Tc.Instance.Class). Hence the call to mkOneRecordSelector in mkRecSelBind always uses FieldSelectors. However, record pattern synonyms are not used with HasField, so when NoFieldSelectors is used we do not need to generate selector functions. Thus mkPatSynRecSelBinds passes the current state of the FieldSelectors extension to mkOneRecordSelector, and in the NoFieldSelectors case it will treat them as "naughty" fields (see Note [Naughty record selectors]). Why generate a naughty binding, rather than no binding at all? Because when type-checking a record update, we need to look up Ids for the fields. In particular, disambiguateRecordBinds calls lookupParents which needs to look up the RecSelIds to determine the sel_tycon. Note [GADT record selectors] ~~~~~~~~~~~~~~~~~~~~~~~~~~~~ For GADTs, we require that all constructors with a common field 'f' have the same result type (modulo alpha conversion). [Checked in GHC.Tc.TyCl.checkValidTyCon] E.g. data T where T1 { f :: Maybe a } :: T [a] T2 { f :: Maybe a, y :: b } :: T [a] T3 :: T Int and now the selector takes that result type as its argument: f :: forall a. T [a] -> Maybe a Details: the "real" types of T1,T2 are: T1 :: forall r a. (r~[a]) => a -> T r T2 :: forall r a b. (r~[a]) => a -> b -> T r So the selector loooks like this: f :: forall a. T [a] -> Maybe a f (a:*) (t:T [a]) = case t of T1 c (g:[a]~[c]) (v:Maybe c) -> v `cast` Maybe (right (sym g)) T2 c d (g:[a]~[c]) (v:Maybe c) (w:d) -> v `cast` Maybe (right (sym g)) T3 -> error "T3 does not have field f" Note the forall'd tyvars of the selector are just the free tyvars of the result type; there may be other tyvars in the constructor's type (e.g. 'b' in T2). Note the need for casts in the result! Note [Selector running example] ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ It's OK to combine GADTs and type families. Here's a running example: data instance T [a] where T1 { fld :: b } :: T [Maybe b] The representation type looks like this data :R7T a where T1 { fld :: b } :: :R7T (Maybe b) and there's coercion from the family type to the representation type :CoR7T a :: T [a] ~ :R7T a The selector we want for fld looks like this: fld :: forall b. T [Maybe b] -> b fld = /\b. \(d::T [Maybe b]). case d `cast` :CoR7T (Maybe b) of T1 (x::b) -> x The scrutinee of the case has type :R7T (Maybe b), which can be gotten by applying the eq_spec to the univ_tvs of the data con. Note [Impredicative record selectors] ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ There are situations where generating code for record selectors requires the use of ImpredicativeTypes. Here is one example (adapted from #18005): type S = (forall b. b -> b) -> Int data T = MkT {unT :: S} | Dummy We want to generate HsBinds for unT that look something like this: unT :: S unT (MkT x) = x unT _ = recSelError "unT"# Note that the type of recSelError is `forall r (a :: TYPE r). Addr# -> a`. Therefore, when used in the right-hand side of `unT`, GHC attempts to instantiate `a` with `(forall b. b -> b) -> Int`, which is impredicative. To make sure that GHC is OK with this, we enable ImpredicativeTypes internally when typechecking these HsBinds so that the user does not have to. -}