{- (c) The University of Glasgow 2006 (c) The AQUA Project, Glasgow University, 1996-1998 -} {-# LANGUAGE CPP, TupleSections, ScopedTypeVariables, MultiWayIf #-} {-# LANGUAGE TypeFamilies #-} {-# LANGUAGE ViewPatterns #-} {-# OPTIONS_GHC -Wno-incomplete-uni-patterns #-} -- | Typecheck type and class declarations module GHC.Tc.TyCl ( tcTyAndClassDecls, -- Functions used by GHC.Tc.TyCl.Instance to check -- data/type family instance declarations kcConDecls, tcConDecls, dataDeclChecks, checkValidTyCon, tcFamTyPats, tcTyFamInstEqn, tcAddTyFamInstCtxt, tcMkDataFamInstCtxt, tcAddDataFamInstCtxt, unravelFamInstPats, addConsistencyConstraints, wrongKindOfFamily ) where #include "HsVersions.h" import GHC.Prelude import GHC.Hs import GHC.Driver.Types import GHC.Tc.TyCl.Build import GHC.Tc.Utils.Monad import GHC.Tc.Utils.Env import GHC.Tc.Validity import GHC.Tc.Utils.Zonk import GHC.Tc.TyCl.Utils import GHC.Tc.TyCl.Class import {-# SOURCE #-} GHC.Tc.TyCl.Instance( tcInstDecls1 ) import GHC.Tc.Deriv (DerivInfo(..)) import GHC.Tc.Utils.Unify ( checkTvConstraints ) import GHC.Tc.Gen.HsType import GHC.Tc.Instance.Class( AssocInstInfo(..) ) import GHC.Tc.Utils.TcMType import GHC.Builtin.Types ( unitTy, makeRecoveryTyCon ) import GHC.Tc.Utils.TcType import GHC.Core.Multiplicity import GHC.Rename.Env( lookupConstructorFields ) import GHC.Tc.Instance.Family import GHC.Core.FamInstEnv import GHC.Core.Coercion import GHC.Tc.Types.Origin import GHC.Core.Type import GHC.Core.TyCo.Rep -- for checkValidRoles import GHC.Core.TyCo.Ppr( pprTyVars, pprWithExplicitKindsWhen ) import GHC.Core.Class import GHC.Core.Coercion.Axiom import GHC.Core.TyCon import GHC.Core.DataCon import GHC.Types.Id import GHC.Types.Var import GHC.Types.Var.Env import GHC.Types.Var.Set import GHC.Unit.Module import GHC.Unit.State import GHC.Types.Name import GHC.Types.Name.Set import GHC.Types.Name.Env import GHC.Utils.Outputable import GHC.Data.Maybe import GHC.Core.Unify import GHC.Utils.Misc import GHC.Types.SrcLoc import GHC.Data.List.SetOps import GHC.Driver.Session import GHC.Types.Unique import GHC.Core.ConLike( ConLike(..) ) import GHC.Types.Basic import qualified GHC.LanguageExtensions as LangExt import Control.Monad import Data.Foldable import Data.Function ( on ) import Data.Functor.Identity import Data.List import qualified Data.List.NonEmpty as NE import Data.List.NonEmpty ( NonEmpty(..) ) import qualified Data.Set as Set import Data.Tuple( swap ) {- ************************************************************************ * * \subsection{Type checking for type and class declarations} * * ************************************************************************ Note [Grouping of type and class declarations] ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ tcTyAndClassDecls is called on a list of `TyClGroup`s. Each group is a strongly connected component of mutually dependent types and classes. We kind check and type check each group separately to enhance kind polymorphism. Take the following example: type Id a = a data X = X (Id Int) If we were to kind check the two declarations together, we would give Id the kind * -> *, since we apply it to an Int in the definition of X. But we can do better than that, since Id really is kind polymorphic, and should get kind forall (k::*). k -> k. Since it does not depend on anything else, it can be kind-checked by itself, hence getting the most general kind. We then kind check X, which works fine because we then know the polymorphic kind of Id, and simply instantiate k to *. Note [Check role annotations in a second pass] ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ Role inference potentially depends on the types of all of the datacons declared in a mutually recursive group. The validity of a role annotation, in turn, depends on the result of role inference. Because the types of datacons might be ill-formed (see #7175 and Note [Checking GADT return types]) we must check *all* the tycons in a group for validity before checking *any* of the roles. Thus, we take two passes over the resulting tycons, first checking for general validity and then checking for valid role annotations. -} tcTyAndClassDecls :: [TyClGroup GhcRn] -- Mutually-recursive groups in -- dependency order -> TcM ( TcGblEnv -- Input env extended by types and -- classes -- and their implicit Ids,DataCons , [InstInfo GhcRn] -- Source-code instance decls info , [DerivInfo] -- Deriving info ) -- Fails if there are any errors tcTyAndClassDecls tyclds_s -- The code recovers internally, but if anything gave rise to -- an error we'd better stop now, to avoid a cascade -- Type check each group in dependency order folding the global env = checkNoErrs $ fold_env [] [] tyclds_s where fold_env :: [InstInfo GhcRn] -> [DerivInfo] -> [TyClGroup GhcRn] -> TcM (TcGblEnv, [InstInfo GhcRn], [DerivInfo]) fold_env inst_info deriv_info [] = do { gbl_env <- getGblEnv ; return (gbl_env, inst_info, deriv_info) } fold_env inst_info deriv_info (tyclds:tyclds_s) = do { (tcg_env, inst_info', deriv_info') <- tcTyClGroup tyclds ; setGblEnv tcg_env $ -- remaining groups are typechecked in the extended global env. fold_env (inst_info' ++ inst_info) (deriv_info' ++ deriv_info) tyclds_s } tcTyClGroup :: TyClGroup GhcRn -> TcM (TcGblEnv, [InstInfo GhcRn], [DerivInfo]) -- Typecheck one strongly-connected component of type, class, and instance decls -- See Note [TyClGroups and dependency analysis] in GHC.Hs.Decls tcTyClGroup (TyClGroup { group_tyclds = tyclds , group_roles = roles , group_kisigs = kisigs , group_instds = instds }) = do { let role_annots = mkRoleAnnotEnv roles -- Step 1: Typecheck the standalone kind signatures and type/class declarations ; traceTc "---- tcTyClGroup ---- {" empty ; traceTc "Decls for" (ppr (map (tcdName . unLoc) tyclds)) ; (tyclss, data_deriv_info) <- tcExtendKindEnv (mkPromotionErrorEnv tyclds) $ -- See Note [Type environment evolution] do { kisig_env <- mkNameEnv <$> traverse tcStandaloneKindSig kisigs ; tcTyClDecls tyclds kisig_env role_annots } -- Step 1.5: Make sure we don't have any type synonym cycles ; traceTc "Starting synonym cycle check" (ppr tyclss) ; this_uid <- fmap homeUnit getDynFlags ; checkSynCycles this_uid tyclss tyclds ; traceTc "Done synonym cycle check" (ppr tyclss) -- Step 2: Perform the validity check on those types/classes -- We can do this now because we are done with the recursive knot -- Do it before Step 3 (adding implicit things) because the latter -- expects well-formed TyCons ; traceTc "Starting validity check" (ppr tyclss) ; tyclss <- concatMapM checkValidTyCl tyclss ; traceTc "Done validity check" (ppr tyclss) ; mapM_ (recoverM (return ()) . checkValidRoleAnnots role_annots) tyclss -- See Note [Check role annotations in a second pass] ; traceTc "---- end tcTyClGroup ---- }" empty -- Step 3: Add the implicit things; -- we want them in the environment because -- they may be mentioned in interface files ; gbl_env <- addTyConsToGblEnv tyclss -- Step 4: check instance declarations ; (gbl_env', inst_info, datafam_deriv_info) <- setGblEnv gbl_env $ tcInstDecls1 instds ; let deriv_info = datafam_deriv_info ++ data_deriv_info ; return (gbl_env', inst_info, deriv_info) } -- Gives the kind for every TyCon that has a standalone kind signature type KindSigEnv = NameEnv Kind tcTyClDecls :: [LTyClDecl GhcRn] -> KindSigEnv -> RoleAnnotEnv -> TcM ([TyCon], [DerivInfo]) tcTyClDecls tyclds kisig_env role_annots = do { -- Step 1: kind-check this group and returns the final -- (possibly-polymorphic) kind of each TyCon and Class -- See Note [Kind checking for type and class decls] tc_tycons <- kcTyClGroup kisig_env tyclds ; traceTc "tcTyAndCl generalized kinds" (vcat (map ppr_tc_tycon tc_tycons)) -- Step 2: type-check all groups together, returning -- the final TyCons and Classes -- -- NB: We have to be careful here to NOT eagerly unfold -- type synonyms, as we have not tested for type synonym -- loops yet and could fall into a black hole. ; fixM $ \ ~(rec_tyclss, _) -> do { tcg_env <- getGblEnv ; let roles = inferRoles (tcg_src tcg_env) role_annots rec_tyclss -- Populate environment with knot-tied ATyCon for TyCons -- NB: if the decls mention any ill-staged data cons -- (see Note [Recursion and promoting data constructors]) -- we will have failed already in kcTyClGroup, so no worries here ; (tycons, data_deriv_infos) <- tcExtendRecEnv (zipRecTyClss tc_tycons rec_tyclss) $ -- Also extend the local type envt with bindings giving -- a TcTyCon for each each knot-tied TyCon or Class -- See Note [Type checking recursive type and class declarations] -- and Note [Type environment evolution] tcExtendKindEnvWithTyCons tc_tycons $ -- Kind and type check declarations for this group mapAndUnzipM (tcTyClDecl roles) tyclds ; return (tycons, concat data_deriv_infos) } } where ppr_tc_tycon tc = parens (sep [ ppr (tyConName tc) <> comma , ppr (tyConBinders tc) <> comma , ppr (tyConResKind tc) , ppr (isTcTyCon tc) ]) zipRecTyClss :: [TcTyCon] -> [TyCon] -- Knot-tied -> [(Name,TyThing)] -- Build a name-TyThing mapping for the TyCons bound by decls -- being careful not to look at the knot-tied [TyThing] -- The TyThings in the result list must have a visible ATyCon, -- because typechecking types (in, say, tcTyClDecl) looks at -- this outer constructor zipRecTyClss tc_tycons rec_tycons = [ (name, ATyCon (get name)) | tc_tycon <- tc_tycons, let name = getName tc_tycon ] where rec_tc_env :: NameEnv TyCon rec_tc_env = foldr add_tc emptyNameEnv rec_tycons add_tc :: TyCon -> NameEnv TyCon -> NameEnv TyCon add_tc tc env = foldr add_one_tc env (tc : tyConATs tc) add_one_tc :: TyCon -> NameEnv TyCon -> NameEnv TyCon add_one_tc tc env = extendNameEnv env (tyConName tc) tc get name = case lookupNameEnv rec_tc_env name of Just tc -> tc other -> pprPanic "zipRecTyClss" (ppr name <+> ppr other) {- ************************************************************************ * * Kind checking * * ************************************************************************ Note [Kind checking for type and class decls] ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ Kind checking is done thus: 1. Make up a kind variable for each parameter of the declarations, and extend the kind environment (which is in the TcLclEnv) 2. Kind check the declarations We need to kind check all types in the mutually recursive group before we know the kind of the type variables. For example: class C a where op :: D b => a -> b -> b class D c where bop :: (Monad c) => ... Here, the kind of the locally-polymorphic type variable "b" depends on *all the uses of class D*. For example, the use of Monad c in bop's type signature means that D must have kind Type->Type. Note: we don't treat type synonyms specially (we used to, in the past); in particular, even if we have a type synonym cycle, we still kind check it normally, and test for cycles later (checkSynCycles). The reason we can get away with this is because we have more systematic TYPE r inference, which means that we can do unification between kinds that aren't lifted (this historically was not true.) The downside of not directly reading off the kinds of the RHS of type synonyms in topological order is that we don't transparently support making synonyms of types with higher-rank kinds. But you can always specify a CUSK directly to make this work out. See tc269 for an example. Note [CUSKs and PolyKinds] ~~~~~~~~~~~~~~~~~~~~~~~~~~ Consider data T (a :: *) = MkT (S a) -- Has CUSK data S a = MkS (T Int) (S a) -- No CUSK Via inferInitialKinds we get T :: * -> * S :: kappa -> * Then we call kcTyClDecl on each decl in the group, to constrain the kind unification variables. BUT we /skip/ the RHS of any decl with a CUSK. Here we skip the RHS of T, so we eventually get S :: forall k. k -> * This gets us more polymorphism than we would otherwise get, similar (but implemented strangely differently from) the treatment of type signatures in value declarations. However, we only want to do so when we have PolyKinds. When we have NoPolyKinds, we don't skip those decls, because we have defaulting (#16609). Skipping won't bring us more polymorphism when we have defaulting. Consider data T1 a = MkT1 T2 -- No CUSK data T2 = MkT2 (T1 Maybe) -- Has CUSK If we skip the rhs of T2 during kind-checking, the kind of a remains unsolved. With PolyKinds, we do generalization to get T1 :: forall a. a -> *. And the program type-checks. But with NoPolyKinds, we do defaulting to get T1 :: * -> *. Defaulting happens in quantifyTyVars, which is called from generaliseTcTyCon. Then type-checking (T1 Maybe) will throw a type error. Summary: with PolyKinds, we must skip; with NoPolyKinds, we must /not/ skip. Open type families ~~~~~~~~~~~~~~~~~~ This treatment of type synonyms only applies to Haskell 98-style synonyms. General type functions can be recursive, and hence, appear in `alg_decls'. The kind of an open type family is solely determinded by its kind signature; hence, only kind signatures participate in the construction of the initial kind environment (as constructed by `inferInitialKind'). In fact, we ignore instances of families altogether in the following. However, we need to include the kinds of *associated* families into the construction of the initial kind environment. (This is handled by `allDecls'). See also Note [Kind checking recursive type and class declarations] Note [How TcTyCons work] ~~~~~~~~~~~~~~~~~~~~~~~~ TcTyCons are used for two distinct purposes 1. When recovering from a type error in a type declaration, we want to put the erroneous TyCon in the environment in a way that won't lead to more errors. We use a TcTyCon for this; see makeRecoveryTyCon. 2. When checking a type/class declaration (in module GHC.Tc.TyCl), we come upon knowledge of the eventual tycon in bits and pieces. S1) First, we use inferInitialKinds to look over the user-provided kind signature of a tycon (including, for example, the number of parameters written to the tycon) to get an initial shape of the tycon's kind. We record that shape in a TcTyCon. For CUSK tycons, the TcTyCon has the final, generalised kind. For non-CUSK tycons, the TcTyCon has as its tyConBinders only the explicit arguments given -- no kind variables, etc. S2) Then, using these initial kinds, we kind-check the body of the tycon (class methods, data constructors, etc.), filling in the metavariables in the tycon's initial kind. S3) We then generalize to get the (non-CUSK) tycon's final, fixed kind. Finally, once this has happened for all tycons in a mutually recursive group, we can desugar the lot. For convenience, we store partially-known tycons in TcTyCons, which might store meta-variables. These TcTyCons are stored in the local environment in GHC.Tc.TyCl, until the real full TyCons can be created during desugaring. A desugared program should never have a TcTyCon. 3. In a TcTyCon, everything is zonked after the kind-checking pass (S2). 4. tyConScopedTyVars. A challenging piece in all of this is that we end up taking three separate passes over every declaration: - one in inferInitialKind (this pass look only at the head, not the body) - one in kcTyClDecls (to kind-check the body) - a final one in tcTyClDecls (to desugar) In the latter two passes, we need to connect the user-written type variables in an LHsQTyVars with the variables in the tycon's inferred kind. Because the tycon might not have a CUSK, this matching up is, in general, quite hard to do. (Look through the git history between Dec 2015 and Apr 2016 for GHC.Tc.Gen.HsType.splitTelescopeTvs!) Instead of trying, we just store the list of type variables to bring into scope, in the tyConScopedTyVars field of the TcTyCon. These tyvars are brought into scope in GHC.Tc.Gen.HsType.bindTyClTyVars. In a TcTyCon, why is tyConScopedTyVars :: [(Name,TcTyVar)] rather than just [TcTyVar]? Consider these mutually-recursive decls data T (a :: k1) b = MkT (S a b) data S (c :: k2) d = MkS (T c d) We start with k1 bound to kappa1, and k2 to kappa2; so initially in the (Name,TcTyVar) pairs the Name is that of the TcTyVar. But then kappa1 and kappa2 get unified; so after the zonking in 'generalise' in 'kcTyClGroup' the Name and TcTyVar may differ. See also Note [Type checking recursive type and class declarations]. Note [Swizzling the tyvars before generaliseTcTyCon] ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ This Note only applies when /inferring/ the kind of a TyCon. If there is a separate kind signature, or a CUSK, we take an entirely different code path. For inference, consider class C (f :: k) x where type T f op :: D f => blah class D (g :: j) y where op :: C g => y -> blah Here C and D are considered mutually recursive. Neither has a CUSK. Just before generalisation we have the (un-quantified) kinds C :: k1 -> k2 -> Constraint T :: k1 -> Type D :: k1 -> Type -> Constraint Notice that f's kind and g's kind have been unified to 'k1'. We say that k1 is the "representative" of k in C's decl, and of j in D's decl. Now when quantifying, we'd like to end up with C :: forall {k2}. forall k. k -> k2 -> Constraint T :: forall k. k -> Type D :: forall j. j -> Type -> Constraint That is, we want to swizzle the representative to have the Name given by the user. Partly this is to improve error messages and the output of :info in GHCi. But it is /also/ important because the code for a default method may mention the class variable(s), but at that point (tcClassDecl2), we only have the final class tyvars available. (Alternatively, we could record the scoped type variables in the TyCon, but it's a nuisance to do so.) Notes: * On the input to generaliseTyClDecl, the mapping between the user-specified Name and the representative TyVar is recorded in the tyConScopedTyVars of the TcTyCon. NB: you first need to zonk to see this representative TyVar. * The swizzling is actually performed by swizzleTcTyConBndrs * We must do the swizzling across the whole class decl. Consider class C f where type S (f :: k) type T f Here f's kind k is a parameter of C, and its identity is shared with S and T. So if we swizzle the representative k at all, we must do so consistently for the entire declaration. Hence the call to check_duplicate_tc_binders is in generaliseTyClDecl, rather than in generaliseTcTyCon. There are errors to catch here. Suppose we had class E (f :: j) (g :: k) where op :: SameKind f g -> blah Then, just before generalisation we will have the (unquantified) E :: k1 -> k1 -> Constraint That's bad! Two distinctly-named tyvars (j and k) have ended up with the same representative k1. So when swizzling, we check (in check_duplicate_tc_binders) that two distinct source names map to the same representative. Here's an interesting case: class C1 f where type S (f :: k1) type T (f :: k2) Here k1 and k2 are different Names, but they end up mapped to the same representative TyVar. To make the swizzling consistent (remember we must have a single k across C1, S and T) we reject the program. Another interesting case class C2 f where type S (f :: k) (p::Type) type T (f :: k) (p::Type->Type) Here the two k's (and the two p's) get distinct Uniques, because they are seen by the renamer as locally bound in S and T resp. But again the two (distinct) k's end up bound to the same representative TyVar. You might argue that this should be accepted, but it's definitely rejected (via an entirely different code path) if you add a kind sig: type C2' :: j -> Constraint class C2' f where type S (f :: k) (p::Type) We get • Expected kind ‘j’, but ‘f’ has kind ‘k’ • In the associated type family declaration for ‘S’ So we reject C2 too, even without the kind signature. We have to do a bit of work to get a good error message, since both k's look the same to the user. Another case class C3 (f :: k1) where type S (f :: k2) This will be rejected too. Note [Type environment evolution] ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ As we typecheck a group of declarations the type environment evolves. Consider for example: data B (a :: Type) = MkB (Proxy 'MkB) We do the following steps: 1. Start of tcTyClDecls: use mkPromotionErrorEnv to initialise the type env with promotion errors B :-> TyConPE MkB :-> DataConPE 2. kcTyCLGroup - Do inferInitialKinds, which will signal a promotion error if B is used in any of the kinds needed to initialise B's kind (e.g. (a :: Type)) here - Extend the type env with these initial kinds (monomorphic for decls that lack a CUSK) B :-> TcTyCon (thereby overriding the B :-> TyConPE binding) and do kcLTyClDecl on each decl to get equality constraints on all those initial kinds - Generalise the initial kind, making a poly-kinded TcTyCon 3. Back in tcTyDecls, extend the envt with bindings of the poly-kinded TcTyCons, again overriding the promotion-error bindings. But note that the data constructor promotion errors are still in place so that (in our example) a use of MkB will still be signalled as an error. 4. Typecheck the decls. 5. In tcTyClGroup, extend the envt with bindings for TyCon and DataCons Note [Missed opportunity to retain higher-rank kinds] ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ In 'kcTyClGroup', there is a missed opportunity to make kind inference work in a few more cases. The idea is analogous to Note [Single function non-recursive binding special-case]: * If we have an SCC with a single decl, which is non-recursive, instead of creating a unification variable representing the kind of the decl and unifying it with the rhs, we can just read the type directly of the rhs. * Furthermore, we can update our SCC analysis to ignore dependencies on declarations which have CUSKs: we don't have to kind-check these all at once, since we can use the CUSK to initialize the kind environment. Unfortunately this requires reworking a bit of the code in 'kcLTyClDecl' so I've decided to punt unless someone shouts about it. Note [Don't process associated types in getInitialKind] ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ Previously, we processed associated types in the thing_inside in getInitialKind, but this was wrong -- we want to do ATs sepearately. The consequence for not doing it this way is #15142: class ListTuple (tuple :: Type) (as :: [(k, Type)]) where type ListToTuple as :: Type We assign k a kind kappa[1]. When checking the tuple (k, Type), we try to unify kappa ~ Type, but this gets deferred because we bumped the TcLevel as we bring `tuple` into scope. Thus, when we check ListToTuple, kappa[1] still hasn't unified with Type. And then, when we generalize the kind of ListToTuple (which indeed has a CUSK, according to the rules), we skolemize the free metavariable kappa. Note that we wouldn't skolemize kappa when generalizing the kind of ListTuple, because the solveEqualities in kcInferDeclHeader is at TcLevel 1 and so kappa[1] will unify with Type. Bottom line: as associated types should have no effect on a CUSK enclosing class, we move processing them to a separate action, run after the outer kind has been generalized. -} kcTyClGroup :: KindSigEnv -> [LTyClDecl GhcRn] -> TcM [TcTyCon] -- Kind check this group, kind generalize, and return the resulting local env -- This binds the TyCons and Classes of the group, but not the DataCons -- See Note [Kind checking for type and class decls] -- and Note [Inferring kinds for type declarations] kcTyClGroup kisig_env decls = do { mod <- getModule ; traceTc "---- kcTyClGroup ---- {" (text "module" <+> ppr mod $$ vcat (map ppr decls)) -- Kind checking; -- 1. Bind kind variables for decls -- 2. Kind-check decls -- 3. Generalise the inferred kinds -- See Note [Kind checking for type and class decls] ; cusks_enabled <- xoptM LangExt.CUSKs <&&> xoptM LangExt.PolyKinds -- See Note [CUSKs and PolyKinds] ; let (kindless_decls, kinded_decls) = partitionWith get_kind decls get_kind d | Just ki <- lookupNameEnv kisig_env (tcdName (unLoc d)) = Right (d, SAKS ki) | cusks_enabled && hsDeclHasCusk (unLoc d) = Right (d, CUSK) | otherwise = Left d ; checked_tcs <- checkInitialKinds kinded_decls ; inferred_tcs <- tcExtendKindEnvWithTyCons checked_tcs $ pushTcLevelM_ $ -- We are going to kind-generalise, so -- unification variables in here must -- be one level in solveEqualities $ do { -- Step 1: Bind kind variables for all decls mono_tcs <- inferInitialKinds kindless_decls ; traceTc "kcTyClGroup: initial kinds" $ ppr_tc_kinds mono_tcs -- Step 2: Set extended envt, kind-check the decls -- NB: the environment extension overrides the tycon -- promotion-errors bindings -- See Note [Type environment evolution] ; tcExtendKindEnvWithTyCons mono_tcs $ mapM_ kcLTyClDecl kindless_decls ; return mono_tcs } -- Step 3: generalisation -- Finally, go through each tycon and give it its final kind, -- with all the required, specified, and inferred variables -- in order. ; let inferred_tc_env = mkNameEnv $ map (\tc -> (tyConName tc, tc)) inferred_tcs ; generalized_tcs <- concatMapM (generaliseTyClDecl inferred_tc_env) kindless_decls ; let poly_tcs = checked_tcs ++ generalized_tcs ; traceTc "---- kcTyClGroup end ---- }" (ppr_tc_kinds poly_tcs) ; return poly_tcs } where ppr_tc_kinds tcs = vcat (map pp_tc tcs) pp_tc tc = ppr (tyConName tc) <+> dcolon <+> ppr (tyConKind tc) type ScopedPairs = [(Name, TcTyVar)] -- The ScopedPairs for a TcTyCon are precisely -- specified-tvs ++ required-tvs -- You can distinguish them because there are tyConArity required-tvs generaliseTyClDecl :: NameEnv TcTyCon -> LTyClDecl GhcRn -> TcM [TcTyCon] -- See Note [Swizzling the tyvars before generaliseTcTyCon] generaliseTyClDecl inferred_tc_env (L _ decl) = do { let names_in_this_decl :: [Name] names_in_this_decl = tycld_names decl -- Extract the specified/required binders and skolemise them ; tc_with_tvs <- mapM skolemise_tc_tycon names_in_this_decl -- Zonk, to manifest the side-effects of skolemisation to the swizzler -- NB: it's important to skolemise them all before this step. E.g. -- class C f where { type T (f :: k) } -- We only skolemise k when looking at T's binders, -- but k appears in f's kind in C's binders. ; tc_infos <- mapM zonk_tc_tycon tc_with_tvs -- Swizzle ; swizzled_infos <- tcAddDeclCtxt decl (swizzleTcTyConBndrs tc_infos) -- And finally generalise ; mapAndReportM generaliseTcTyCon swizzled_infos } where tycld_names :: TyClDecl GhcRn -> [Name] tycld_names decl = tcdName decl : at_names decl at_names :: TyClDecl GhcRn -> [Name] at_names (ClassDecl { tcdATs = ats }) = map (familyDeclName . unLoc) ats at_names _ = [] -- Only class decls have associated types skolemise_tc_tycon :: Name -> TcM (TcTyCon, ScopedPairs) -- Zonk and skolemise the Specified and Required binders skolemise_tc_tycon tc_name = do { let tc = lookupNameEnv_NF inferred_tc_env tc_name -- This lookup should not fail ; scoped_prs <- mapSndM zonkAndSkolemise (tcTyConScopedTyVars tc) ; return (tc, scoped_prs) } zonk_tc_tycon :: (TcTyCon, ScopedPairs) -> TcM (TcTyCon, ScopedPairs, TcKind) zonk_tc_tycon (tc, scoped_prs) = do { scoped_prs <- mapSndM zonkTcTyVarToTyVar scoped_prs -- We really have to do this again, even though -- we have just done zonkAndSkolemise ; res_kind <- zonkTcType (tyConResKind tc) ; return (tc, scoped_prs, res_kind) } swizzleTcTyConBndrs :: [(TcTyCon, ScopedPairs, TcKind)] -> TcM [(TcTyCon, ScopedPairs, TcKind)] swizzleTcTyConBndrs tc_infos | all no_swizzle swizzle_prs -- This fast path happens almost all the time -- See Note [Non-cloning for tyvar binders] in GHC.Tc.Gen.HsType = do { traceTc "Skipping swizzleTcTyConBndrs for" (ppr (map fstOf3 tc_infos)) ; return tc_infos } | otherwise = do { check_duplicate_tc_binders ; traceTc "swizzleTcTyConBndrs" $ vcat [ text "before" <+> ppr_infos tc_infos , text "swizzle_prs" <+> ppr swizzle_prs , text "after" <+> ppr_infos swizzled_infos ] ; return swizzled_infos } where swizzled_infos = [ (tc, mapSnd swizzle_var scoped_prs, swizzle_ty kind) | (tc, scoped_prs, kind) <- tc_infos ] swizzle_prs :: [(Name,TyVar)] -- Pairs the user-specifed Name with its representative TyVar -- See Note [Swizzling the tyvars before generaliseTcTyCon] swizzle_prs = [ pr | (_, prs, _) <- tc_infos, pr <- prs ] no_swizzle :: (Name,TyVar) -> Bool no_swizzle (nm, tv) = nm == tyVarName tv ppr_infos infos = vcat [ ppr tc <+> pprTyVars (map snd prs) | (tc, prs, _) <- infos ] -- Check for duplicates -- E.g. data SameKind (a::k) (b::k) -- data T (a::k1) (b::k2) = MkT (SameKind a b) -- Here k1 and k2 start as TyVarTvs, and get unified with each other -- If this happens, things get very confused later, so fail fast check_duplicate_tc_binders :: TcM () check_duplicate_tc_binders = unless (null err_prs) $ do { mapM_ report_dup err_prs; failM } -------------- Error reporting ------------ err_prs :: [(Name,Name)] err_prs = [ (n1,n2) | pr :| prs <- findDupsEq ((==) `on` snd) swizzle_prs , (n1,_):(n2,_):_ <- [nubBy ((==) `on` fst) (pr:prs)] ] -- This nubBy avoids bogus error reports when we have -- [("f", f), ..., ("f",f)....] in swizzle_prs -- which happens with class C f where { type T f } report_dup :: (Name,Name) -> TcM () report_dup (n1,n2) = setSrcSpan (getSrcSpan n2) $ addErrTc $ hang (text "Different names for the same type variable:") 2 info where info | nameOccName n1 /= nameOccName n2 = quotes (ppr n1) <+> text "and" <+> quotes (ppr n2) | otherwise -- Same OccNames! See C2 in -- Note [Swizzling the tyvars before generaliseTcTyCon] = vcat [ quotes (ppr n1) <+> text "bound at" <+> ppr (getSrcLoc n1) , quotes (ppr n2) <+> text "bound at" <+> ppr (getSrcLoc n2) ] -------------- The swizzler ------------ -- This does a deep traverse, simply doing a -- Name-to-Name change, governed by swizzle_env -- The 'swap' is what gets from the representative TyVar -- back to the original user-specified Name swizzle_env = mkVarEnv (map swap swizzle_prs) swizzleMapper :: TyCoMapper () Identity swizzleMapper = TyCoMapper { tcm_tyvar = swizzle_tv , tcm_covar = swizzle_cv , tcm_hole = swizzle_hole , tcm_tycobinder = swizzle_bndr , tcm_tycon = swizzle_tycon } swizzle_hole _ hole = pprPanic "swizzle_hole" (ppr hole) -- These types are pre-zonked swizzle_tycon tc = pprPanic "swizzle_tc" (ppr tc) -- TcTyCons can't appear in kinds (yet) swizzle_tv _ tv = return (mkTyVarTy (swizzle_var tv)) swizzle_cv _ cv = return (mkCoVarCo (swizzle_var cv)) swizzle_bndr _ tcv _ = return ((), swizzle_var tcv) swizzle_var :: Var -> Var swizzle_var v | Just nm <- lookupVarEnv swizzle_env v = updateVarType swizzle_ty (v `setVarName` nm) | otherwise = updateVarType swizzle_ty v (map_type, _, _, _) = mapTyCo swizzleMapper swizzle_ty ty = runIdentity (map_type ty) generaliseTcTyCon :: (TcTyCon, ScopedPairs, TcKind) -> TcM TcTyCon generaliseTcTyCon (tc, scoped_prs, tc_res_kind) -- See Note [Required, Specified, and Inferred for types] = setSrcSpan (getSrcSpan tc) $ addTyConCtxt tc $ do { -- Step 1: Separate Specified from Required variables -- NB: spec_req_tvs = spec_tvs ++ req_tvs -- And req_tvs is 1-1 with tyConTyVars -- See Note [Scoped tyvars in a TcTyCon] in GHC.Core.TyCon ; let spec_req_tvs = map snd scoped_prs n_spec = length spec_req_tvs - tyConArity tc (spec_tvs, req_tvs) = splitAt n_spec spec_req_tvs sorted_spec_tvs = scopedSort spec_tvs -- NB: We can't do the sort until we've zonked -- Maintain the L-R order of scoped_tvs -- Step 2a: find all the Inferred variables we want to quantify over ; dvs1 <- candidateQTyVarsOfKinds $ (tc_res_kind : map tyVarKind spec_req_tvs) ; let dvs2 = dvs1 `delCandidates` spec_req_tvs -- Step 2b: quantify, mainly meaning skolemise the free variables -- Returned 'inferred' are scope-sorted and skolemised ; inferred <- quantifyTyVars dvs2 ; traceTc "generaliseTcTyCon: pre zonk" (vcat [ text "tycon =" <+> ppr tc , text "spec_req_tvs =" <+> pprTyVars spec_req_tvs , text "tc_res_kind =" <+> ppr tc_res_kind , text "dvs1 =" <+> ppr dvs1 , text "inferred =" <+> pprTyVars inferred ]) -- Step 3: Final zonk (following kind generalisation) -- See Note [Swizzling the tyvars before generaliseTcTyCon] ; ze <- emptyZonkEnv ; (ze, inferred) <- zonkTyBndrsX ze inferred ; (ze, sorted_spec_tvs) <- zonkTyBndrsX ze sorted_spec_tvs ; (ze, req_tvs) <- zonkTyBndrsX ze req_tvs ; tc_res_kind <- zonkTcTypeToTypeX ze tc_res_kind ; traceTc "generaliseTcTyCon: post zonk" $ vcat [ text "tycon =" <+> ppr tc , text "inferred =" <+> pprTyVars inferred , text "spec_req_tvs =" <+> pprTyVars spec_req_tvs , text "sorted_spec_tvs =" <+> pprTyVars sorted_spec_tvs , text "req_tvs =" <+> ppr req_tvs , text "zonk-env =" <+> ppr ze ] -- Step 4: Make the TyConBinders. ; let dep_fv_set = candidateKindVars dvs1 inferred_tcbs = mkNamedTyConBinders Inferred inferred specified_tcbs = mkNamedTyConBinders Specified sorted_spec_tvs required_tcbs = map (mkRequiredTyConBinder dep_fv_set) req_tvs -- Step 5: Assemble the final list. final_tcbs = concat [ inferred_tcbs , specified_tcbs , required_tcbs ] -- Step 6: Make the result TcTyCon tycon = mkTcTyCon (tyConName tc) final_tcbs tc_res_kind (mkTyVarNamePairs (sorted_spec_tvs ++ req_tvs)) True {- it's generalised now -} (tyConFlavour tc) ; traceTc "generaliseTcTyCon done" $ vcat [ text "tycon =" <+> ppr tc , text "tc_res_kind =" <+> ppr tc_res_kind , text "dep_fv_set =" <+> ppr dep_fv_set , text "inferred_tcbs =" <+> ppr inferred_tcbs , text "specified_tcbs =" <+> ppr specified_tcbs , text "required_tcbs =" <+> ppr required_tcbs , text "final_tcbs =" <+> ppr final_tcbs ] -- Step 7: Check for validity. -- We do this here because we're about to put the tycon into the -- the environment, and we don't want anything malformed there ; checkTyConTelescope tycon ; return tycon } {- Note [Required, Specified, and Inferred for types] ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ Each forall'd type variable in a type or kind is one of * Required: an argument must be provided at every call site * Specified: the argument can be inferred at call sites, but may be instantiated with visible type/kind application * Inferred: the must be inferred at call sites; it is unavailable for use with visible type/kind application. Why have Inferred at all? Because we just can't make user-facing promises about the ordering of some variables. These might swizzle around even between minor released. By forbidding visible type application, we ensure users aren't caught unawares. Go read Note [VarBndrs, TyCoVarBinders, TyConBinders, and visibility] in GHC.Core.TyCo.Rep. The question for this Note is this: given a TyClDecl, how are its quantified type variables classified? Much of the debate is memorialized in #15743. Here is our design choice. When inferring the ordering of variables for a TyCl declaration (that is, for those variables that he user has not specified the order with an explicit `forall`), we use the following order: 1. Inferred variables 2. Specified variables; in the left-to-right order in which the user wrote them, modified by scopedSort (see below) to put them in depdendency order. 3. Required variables before a top-level :: 4. All variables after a top-level :: If this ordering does not make a valid telescope, we reject the definition. Example: data SameKind :: k -> k -> * data Bad a (c :: Proxy b) (d :: Proxy a) (x :: SameKind b d) For Bad: - a, c, d, x are Required; they are explicitly listed by the user as the positional arguments of Bad - b is Specified; it appears explicitly in a kind signature - k, the kind of a, is Inferred; it is not mentioned explicitly at all Putting variables in the order Inferred, Specified, Required gives us this telescope: Inferred: k Specified: b : Proxy a Required : (a : k) (c : Proxy b) (d : Proxy a) (x : SameKind b d) But this order is ill-scoped, because b's kind mentions a, which occurs after b in the telescope. So we reject Bad. Associated types ~~~~~~~~~~~~~~~~ For associated types everything above is determined by the associated-type declaration alone, ignoring the class header. Here is an example (#15592) class C (a :: k) b where type F (x :: b a) In the kind of C, 'k' is Specified. But what about F? In the kind of F, * Should k be Inferred or Specified? It's Specified for C, but not mentioned in F's declaration. * In which order should the Specified variables a and b occur? It's clearly 'a' then 'b' in C's declaration, but the L-R ordering in F's declaration is 'b' then 'a'. In both cases we make the choice by looking at F's declaration alone, so it gets the kind F :: forall {k}. forall b a. b a -> Type How it works ~~~~~~~~~~~~ These design choices are implemented by two completely different code paths for * Declarations with a standalone kind signature or a complete user-specified kind signature (CUSK). Handled by the kcCheckDeclHeader. * Declarations without a kind signature (standalone or CUSK) are handled by kcInferDeclHeader; see Note [Inferring kinds for type declarations]. Note that neither code path worries about point (4) above, as this is nicely handled by not mangling the res_kind. (Mangling res_kinds is done *after* all this stuff, in tcDataDefn's call to etaExpandAlgTyCon.) We can tell Inferred apart from Specified by looking at the scoped tyvars; Specified are always included there. Design alternatives ~~~~~~~~~~~~~~~~~~~ * For associated types we considered putting the class variables before the local variables, in a nod to the treatment for class methods. But it got too compilicated; see #15592, comment:21ff. * We rigidly require the ordering above, even though we could be much more permissive. Relevant musings are at https://gitlab.haskell.org/ghc/ghc/issues/15743#note_161623 The bottom line conclusion is that, if the user wants a different ordering, then can specify it themselves, and it is better to be predictable and dumb than clever and capricious. I (Richard) conjecture we could be fully permissive, allowing all classes of variables to intermix. We would have to augment ScopedSort to refuse to reorder Required variables (or check that it wouldn't have). But this would allow more programs. See #15743 for examples. Interestingly, Idris seems to allow this intermixing. The intermixing would be fully specified, in that we can be sure that inference wouldn't change between versions. However, would users be able to predict it? That I cannot answer. Test cases (and tickets) relevant to these design decisions ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ T15591* T15592* T15743* Note [Inferring kinds for type declarations] ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ This note deals with /inference/ for type declarations that do not have a CUSK. Consider data T (a :: k1) k2 (x :: k2) = MkT (S a k2 x) data S (b :: k3) k4 (y :: k4) = MkS (T b k4 y) We do kind inference as follows: * Step 1: inferInitialKinds, and in particular kcInferDeclHeader. Make a unification variable for each of the Required and Specified type variables in the header. Record the connection between the Names the user wrote and the fresh unification variables in the tcTyConScopedTyVars field of the TcTyCon we are making [ (a, aa) , (k1, kk1) , (k2, kk2) , (x, xx) ] (I'm using the convention that double letter like 'aa' or 'kk' mean a unification variable.) These unification variables - Are TyVarTvs: that is, unification variables that can unify only with other type variables. See Note [Signature skolems] in GHC.Tc.Utils.TcType - Have complete fresh Names; see GHC.Tc.Utils.TcMType Note [Unification variables need fresh Names] Assign initial monomorphic kinds to S, T T :: kk1 -> * -> kk2 -> * S :: kk3 -> * -> kk4 -> * * Step 2: kcTyClDecl. Extend the environment with a TcTyCon for S and T, with these monomorphic kinds. Now kind-check the declarations, and solve the resulting equalities. The goal here is to discover constraints on all these unification variables. Here we find that kk1 := kk3, and kk2 := kk4. This is why we can't use skolems for kk1 etc; they have to unify with each other. * Step 3: generaliseTcTyCon. Generalise each TyCon in turn. We find the free variables of the kind, skolemise them, sort them out into Inferred/Required/Specified (see the above Note [Required, Specified, and Inferred for types]), and perform some validity checks. This makes the utterly-final TyConBinders for the TyCon. All this is very similar at the level of terms: see GHC.Tc.Gen.Bind Note [Quantified variables in partial type signatures] But there some tricky corners: Note [Tricky scoping in generaliseTcTyCon] * Step 4. Extend the type environment with a TcTyCon for S and T, now with their utterly-final polymorphic kinds (needed for recursive occurrences of S, T). Now typecheck the declarations, and build the final AlgTyCon for S and T resp. The first three steps are in kcTyClGroup; the fourth is in tcTyClDecls. There are some wrinkles * Do not default TyVarTvs. We always want to kind-generalise over TyVarTvs, and /not/ default them to Type. By definition a TyVarTv is not allowed to unify with a type; it must stand for a type variable. Hence the check in GHC.Tc.Solver.defaultTyVarTcS, and GHC.Tc.Utils.TcMType.defaultTyVar. Here's another example (#14555): data Exp :: [TYPE rep] -> TYPE rep -> Type where Lam :: Exp (a:xs) b -> Exp xs (a -> b) We want to kind-generalise over the 'rep' variable. #14563 is another example. * Duplicate type variables. Consider #11203 data SameKind :: k -> k -> * data Q (a :: k1) (b :: k2) c = MkQ (SameKind a b) Here we will unify k1 with k2, but this time doing so is an error, because k1 and k2 are bound in the same declaration. We spot this during validity checking (findDupTyVarTvs), in generaliseTcTyCon. * Required arguments. Even the Required arguments should be made into TyVarTvs, not skolems. Consider data T k (a :: k) Here, k is a Required, dependent variable. For uniformity, it is helpful to have k be a TyVarTv, in parallel with other dependent variables. * Duplicate skolemisation is expected. When generalising in Step 3, we may find that one of the variables we want to quantify has already been skolemised. For example, suppose we have already generalise S. When we come to T we'll find that kk1 (now the same as kk3) has already been skolemised. That's fine -- but it means that a) when collecting quantification candidates, in candidateQTyVarsOfKind, we must collect skolems b) quantifyTyVars should be a no-op on such a skolem Note [Tricky scoping in generaliseTcTyCon] ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ Consider #16342 class C (a::ka) x where cop :: D a x => x -> Proxy a -> Proxy a cop _ x = x :: Proxy (a::ka) class D (b::kb) y where dop :: C b y => y -> Proxy b -> Proxy b dop _ x = x :: Proxy (b::kb) C and D are mutually recursive, by the time we get to generaliseTcTyCon we'll have unified kka := kkb. But when typechecking the default declarations for 'cop' and 'dop' in tcDlassDecl2 we need {a, ka} and {b, kb} respectively to be in scope. But at that point all we have is the utterly-final Class itself. Conclusion: the classTyVars of a class must have the same Name as that originally assigned by the user. In our example, C must have classTyVars {a, ka, x} while D has classTyVars {a, kb, y}. Despite the fact that kka and kkb got unified! We achieve this sleight of hand in generaliseTcTyCon, using the specialised function zonkRecTyVarBndrs. We make the call zonkRecTyVarBndrs [ka,a,x] [kkb,aa,xxx] where the [ka,a,x] are the Names originally assigned by the user, and [kkb,aa,xx] are the corresponding (post-zonking, skolemised) TcTyVars. zonkRecTyVarBndrs builds a recursive ZonkEnv that binds kkb :-> (ka :: ) aa :-> (a :: ) etc That is, it maps each skolemised TcTyVars to the utterly-final TyVar to put in the class, with its correct user-specified name. When generalising D we'll do the same thing, but the ZonkEnv will map kkb :-> (kb :: ) bb :-> (b :: ) etc Note that 'kkb' again appears in the domain of the mapping, but this time mapped to 'kb'. That's how C and D end up with differently-named final TyVars despite the fact that we unified kka:=kkb zonkRecTyVarBndrs we need to do knot-tying because of the need to apply this same substitution to the kind of each. Note [Inferring visible dependent quantification] ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ Consider data T k :: k -> Type where MkT1 :: T Type Int MkT2 :: T (Type -> Type) Maybe This looks like it should work. However, it is polymorphically recursive, as the uses of T in the constructor types specialize the k in the kind of T. This trips up our dear users (#17131, #17541), and so we add a "landmark" context (which cannot be suppressed) whenever we spot inferred visible dependent quantification (VDQ). It's hard to know when we've actually been tripped up by polymorphic recursion specifically, so we just include a note to users whenever we infer VDQ. The testsuite did not show up a single spurious inclusion of this message. The context is added in addVDQNote, which looks for a visible TyConBinder that also appears in the TyCon's kind. (I first looked at the kind for a visible, dependent quantifier, but Note [No polymorphic recursion] in GHC.Tc.Gen.HsType defeats that approach.) addVDQNote is used in kcTyClDecl, which is used only when inferring the kind of a tycon (never with a CUSK or SAK). Once upon a time, I (Richard E) thought that the tycon-kind could not be a forall-type. But this is wrong: data T :: forall k. k -> Type (with -XNoCUSKs) could end up here. And this is all OK. -} -------------- tcExtendKindEnvWithTyCons :: [TcTyCon] -> TcM a -> TcM a tcExtendKindEnvWithTyCons tcs = tcExtendKindEnvList [ (tyConName tc, ATcTyCon tc) | tc <- tcs ] -------------- mkPromotionErrorEnv :: [LTyClDecl GhcRn] -> TcTypeEnv -- Maps each tycon/datacon to a suitable promotion error -- tc :-> APromotionErr TyConPE -- dc :-> APromotionErr RecDataConPE -- See Note [Recursion and promoting data constructors] mkPromotionErrorEnv decls = foldr (plusNameEnv . mk_prom_err_env . unLoc) emptyNameEnv decls mk_prom_err_env :: TyClDecl GhcRn -> TcTypeEnv mk_prom_err_env (ClassDecl { tcdLName = L _ nm, tcdATs = ats }) = unitNameEnv nm (APromotionErr ClassPE) `plusNameEnv` mkNameEnv [ (familyDeclName at, APromotionErr TyConPE) | L _ at <- ats ] mk_prom_err_env (DataDecl { tcdLName = L _ name , tcdDataDefn = HsDataDefn { dd_cons = cons } }) = unitNameEnv name (APromotionErr TyConPE) `plusNameEnv` mkNameEnv [ (con, APromotionErr RecDataConPE) | L _ con' <- cons , L _ con <- getConNames con' ] mk_prom_err_env decl = unitNameEnv (tcdName decl) (APromotionErr TyConPE) -- Works for family declarations too -------------- inferInitialKinds :: [LTyClDecl GhcRn] -> TcM [TcTyCon] -- Returns a TcTyCon for each TyCon bound by the decls, -- each with its initial kind inferInitialKinds decls = do { traceTc "inferInitialKinds {" $ ppr (map (tcdName . unLoc) decls) ; tcs <- concatMapM infer_initial_kind decls ; traceTc "inferInitialKinds done }" empty ; return tcs } where infer_initial_kind = addLocM (getInitialKind InitialKindInfer) -- Check type/class declarations against their standalone kind signatures or -- CUSKs, producing a generalized TcTyCon for each. checkInitialKinds :: [(LTyClDecl GhcRn, SAKS_or_CUSK)] -> TcM [TcTyCon] checkInitialKinds decls = do { traceTc "checkInitialKinds {" $ ppr (mapFst (tcdName . unLoc) decls) ; tcs <- concatMapM check_initial_kind decls ; traceTc "checkInitialKinds done }" empty ; return tcs } where check_initial_kind (ldecl, msig) = addLocM (getInitialKind (InitialKindCheck msig)) ldecl -- | Get the initial kind of a TyClDecl, either generalized or non-generalized, -- depending on the 'InitialKindStrategy'. getInitialKind :: InitialKindStrategy -> TyClDecl GhcRn -> TcM [TcTyCon] -- Allocate a fresh kind variable for each TyCon and Class -- For each tycon, return a TcTyCon with kind k -- where k is the kind of tc, derived from the LHS -- of the definition (and probably including -- kind unification variables) -- Example: data T a b = ... -- return (T, kv1 -> kv2 -> kv3) -- -- This pass deals with (ie incorporates into the kind it produces) -- * The kind signatures on type-variable binders -- * The result kinds signature on a TyClDecl -- -- No family instances are passed to checkInitialKinds/inferInitialKinds getInitialKind strategy (ClassDecl { tcdLName = L _ name , tcdTyVars = ktvs , tcdATs = ats }) = do { cls <- kcDeclHeader strategy name ClassFlavour ktvs $ return (TheKind constraintKind) ; let parent_tv_prs = tcTyConScopedTyVars cls -- See Note [Don't process associated types in getInitialKind] ; inner_tcs <- tcExtendNameTyVarEnv parent_tv_prs $ mapM (addLocM (getAssocFamInitialKind cls)) ats ; return (cls : inner_tcs) } where getAssocFamInitialKind cls = case strategy of InitialKindInfer -> get_fam_decl_initial_kind (Just cls) InitialKindCheck _ -> check_initial_kind_assoc_fam cls getInitialKind strategy (DataDecl { tcdLName = L _ name , tcdTyVars = ktvs , tcdDataDefn = HsDataDefn { dd_kindSig = m_sig , dd_ND = new_or_data } }) = do { let flav = newOrDataToFlavour new_or_data ctxt = DataKindCtxt name ; tc <- kcDeclHeader strategy name flav ktvs $ case m_sig of Just ksig -> TheKind <$> tcLHsKindSig ctxt ksig Nothing -> return $ dataDeclDefaultResultKind new_or_data ; return [tc] } getInitialKind InitialKindInfer (FamDecl { tcdFam = decl }) = do { tc <- get_fam_decl_initial_kind Nothing decl ; return [tc] } getInitialKind (InitialKindCheck msig) (FamDecl { tcdFam = FamilyDecl { fdLName = unLoc -> name , fdTyVars = ktvs , fdResultSig = unLoc -> resultSig , fdInfo = info } } ) = do { let flav = getFamFlav Nothing info ctxt = TyFamResKindCtxt name ; tc <- kcDeclHeader (InitialKindCheck msig) name flav ktvs $ case famResultKindSignature resultSig of Just ksig -> TheKind <$> tcLHsKindSig ctxt ksig Nothing -> case msig of CUSK -> return (TheKind liftedTypeKind) SAKS _ -> return AnyKind ; return [tc] } getInitialKind strategy (SynDecl { tcdLName = L _ name , tcdTyVars = ktvs , tcdRhs = rhs }) = do { let ctxt = TySynKindCtxt name ; tc <- kcDeclHeader strategy name TypeSynonymFlavour ktvs $ case hsTyKindSig rhs of Just rhs_sig -> TheKind <$> tcLHsKindSig ctxt rhs_sig Nothing -> return AnyKind ; return [tc] } get_fam_decl_initial_kind :: Maybe TcTyCon -- ^ Just cls <=> this is an associated family of class cls -> FamilyDecl GhcRn -> TcM TcTyCon get_fam_decl_initial_kind mb_parent_tycon FamilyDecl { fdLName = L _ name , fdTyVars = ktvs , fdResultSig = L _ resultSig , fdInfo = info } = kcDeclHeader InitialKindInfer name flav ktvs $ case resultSig of KindSig _ ki -> TheKind <$> tcLHsKindSig ctxt ki TyVarSig _ (L _ (KindedTyVar _ _ _ ki)) -> TheKind <$> tcLHsKindSig ctxt ki _ -- open type families have * return kind by default | tcFlavourIsOpen flav -> return (TheKind liftedTypeKind) -- closed type families have their return kind inferred -- by default | otherwise -> return AnyKind where flav = getFamFlav mb_parent_tycon info ctxt = TyFamResKindCtxt name -- See Note [Standalone kind signatures for associated types] check_initial_kind_assoc_fam :: TcTyCon -- parent class -> FamilyDecl GhcRn -> TcM TcTyCon check_initial_kind_assoc_fam cls FamilyDecl { fdLName = unLoc -> name , fdTyVars = ktvs , fdResultSig = unLoc -> resultSig , fdInfo = info } = kcDeclHeader (InitialKindCheck CUSK) name flav ktvs $ case famResultKindSignature resultSig of Just ksig -> TheKind <$> tcLHsKindSig ctxt ksig Nothing -> return (TheKind liftedTypeKind) where ctxt = TyFamResKindCtxt name flav = getFamFlav (Just cls) info {- Note [Standalone kind signatures for associated types] ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ If associated types had standalone kind signatures, would they wear them ---------------------------+------------------------------ like this? (OUT) | or like this? (IN) ---------------------------+------------------------------ type T :: Type -> Type | class C a where class C a where | type T :: Type -> Type type T a | type T a The (IN) variant is syntactically ambiguous: class C a where type T :: a -- standalone kind signature? type T :: a -- declaration header? The (OUT) variant does not suffer from this issue, but it might not be the direction in which we want to take Haskell: we seek to unify type families and functions, and, by extension, associated types with class methods. And yet we give class methods their signatures inside the class, not outside. Neither do we have the counterpart of InstanceSigs for StandaloneKindSignatures. For now, we dodge the question by using CUSKs for associated types instead of standalone kind signatures. This is a simple addition to the rule we used to have before standalone kind signatures: old rule: associated type has a CUSK iff its parent class has a CUSK new rule: associated type has a CUSK iff its parent class has a CUSK or a standalone kind signature -} -- See Note [Data declaration default result kind] dataDeclDefaultResultKind :: NewOrData -> ContextKind dataDeclDefaultResultKind NewType = OpenKind -- See Note [Implementation of UnliftedNewtypes], point . dataDeclDefaultResultKind DataType = TheKind liftedTypeKind {- Note [Data declaration default result kind] ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ When the user has not written an inline result kind annotation on a data declaration, we assume it to be 'Type'. That is, the following declarations D1 and D2 are considered equivalent: data D1 where ... data D2 :: Type where ... The consequence of this assumption is that we reject D3 even though we accept D4: data D3 where MkD3 :: ... -> D3 param data D4 :: Type -> Type where MkD4 :: ... -> D4 param However, there's a twist: for newtypes, we must relax the assumed result kind to (TYPE r): newtype D5 where MkD5 :: Int# -> D5 See Note [Implementation of UnliftedNewtypes], STEP 1 and it's sub-note . -} --------------------------------- getFamFlav :: Maybe TcTyCon -- ^ Just cls <=> this is an associated family of class cls -> FamilyInfo pass -> TyConFlavour getFamFlav mb_parent_tycon info = case info of DataFamily -> DataFamilyFlavour mb_parent_tycon OpenTypeFamily -> OpenTypeFamilyFlavour mb_parent_tycon ClosedTypeFamily _ -> ASSERT( isNothing mb_parent_tycon ) -- See Note [Closed type family mb_parent_tycon] ClosedTypeFamilyFlavour {- Note [Closed type family mb_parent_tycon] ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ There's no way to write a closed type family inside a class declaration: class C a where type family F a where -- error: parse error on input ‘where’ In fact, it is not clear what the meaning of such a declaration would be. Therefore, 'mb_parent_tycon' of any closed type family has to be Nothing. -} ------------------------------------------------------------------------ kcLTyClDecl :: LTyClDecl GhcRn -> TcM () -- See Note [Kind checking for type and class decls] -- Called only for declarations without a signature (no CUSKs or SAKs here) kcLTyClDecl (L loc decl) = setSrcSpan loc $ do { tycon <- tcLookupTcTyCon tc_name ; traceTc "kcTyClDecl {" (ppr tc_name) ; addVDQNote tycon $ -- See Note [Inferring visible dependent quantification] addErrCtxt (tcMkDeclCtxt decl) $ kcTyClDecl decl tycon ; traceTc "kcTyClDecl done }" (ppr tc_name) } where tc_name = tcdName decl kcTyClDecl :: TyClDecl GhcRn -> TcTyCon -> TcM () -- This function is used solely for its side effect on kind variables -- NB kind signatures on the type variables and -- result kind signature have already been dealt with -- by inferInitialKind, so we can ignore them here. kcTyClDecl (DataDecl { tcdLName = (L _ name) , tcdDataDefn = defn }) tyCon | HsDataDefn { dd_cons = cons@((L _ (ConDeclGADT {})) : _) , dd_ctxt = (L _ []) , dd_ND = new_or_data } <- defn = -- See Note [Implementation of UnliftedNewtypes] STEP 2 kcConDecls new_or_data (tyConResKind tyCon) cons -- hs_tvs and dd_kindSig already dealt with in inferInitialKind -- This must be a GADT-style decl, -- (see invariants of DataDefn declaration) -- so (a) we don't need to bring the hs_tvs into scope, because the -- ConDecls bind all their own variables -- (b) dd_ctxt is not allowed for GADT-style decls, so we can ignore it | HsDataDefn { dd_ctxt = ctxt , dd_cons = cons , dd_ND = new_or_data } <- defn = bindTyClTyVars name $ \ _ _ _ -> do { _ <- tcHsContext ctxt ; kcConDecls new_or_data (tyConResKind tyCon) cons } kcTyClDecl (SynDecl { tcdLName = L _ name, tcdRhs = rhs }) _tycon = bindTyClTyVars name $ \ _ _ res_kind -> discardResult $ tcCheckLHsType rhs (TheKind res_kind) -- NB: check against the result kind that we allocated -- in inferInitialKinds. kcTyClDecl (ClassDecl { tcdLName = L _ name , tcdCtxt = ctxt, tcdSigs = sigs }) _tycon = bindTyClTyVars name $ \ _ _ _ -> do { _ <- tcHsContext ctxt ; mapM_ (wrapLocM_ kc_sig) sigs } where kc_sig (ClassOpSig _ _ nms op_ty) = kcClassSigType skol_info nms op_ty kc_sig _ = return () skol_info = TyConSkol ClassFlavour name kcTyClDecl (FamDecl _ (FamilyDecl { fdInfo = fd_info })) fam_tc -- closed type families look at their equations, but other families don't -- do anything here = case fd_info of ClosedTypeFamily (Just eqns) -> mapM_ (kcTyFamInstEqn fam_tc) eqns _ -> return () ------------------- -- Type check the types of the arguments to a data constructor. -- This includes doing kind unification if the type is a newtype. -- See Note [Implementation of UnliftedNewtypes] for why we need -- the first two arguments. kcConArgTys :: NewOrData -> Kind -> [HsScaled GhcRn (LHsType GhcRn)] -> TcM () kcConArgTys new_or_data res_kind arg_tys = do { let exp_kind = getArgExpKind new_or_data res_kind ; mapM_ (flip tcCheckLHsType exp_kind . getBangType . hsScaledThing) arg_tys -- See Note [Implementation of UnliftedNewtypes], STEP 2 } kcConDecls :: NewOrData -> Kind -- The result kind signature -> [LConDecl GhcRn] -- The data constructors -> TcM () kcConDecls new_or_data res_kind cons = mapM_ (wrapLocM_ (kcConDecl new_or_data final_res_kind)) cons where (_, final_res_kind) = splitPiTys res_kind -- See Note [kcConDecls result kind] -- Kind check a data constructor. In additional to the data constructor, -- we also need to know about whether or not its corresponding type was -- declared with data or newtype, and we need to know the result kind of -- this type. See Note [Implementation of UnliftedNewtypes] for why -- we need the first two arguments. kcConDecl :: NewOrData -> Kind -- Result kind of the type constructor -- Usually Type but can be TYPE UnliftedRep -- or even TYPE r, in the case of unlifted newtype -> ConDecl GhcRn -> TcM () kcConDecl new_or_data res_kind (ConDeclH98 { con_name = name, con_ex_tvs = ex_tvs , con_mb_cxt = ex_ctxt, con_args = args }) = addErrCtxt (dataConCtxtName [name]) $ discardResult $ bindExplicitTKBndrs_Tv ex_tvs $ do { _ <- tcHsMbContext ex_ctxt ; kcConArgTys new_or_data res_kind (hsConDeclArgTys args) -- We don't need to check the telescope here, -- because that's done in tcConDecl } kcConDecl new_or_data res_kind (ConDeclGADT { con_names = names, con_qvars = explicit_tkv_nms, con_mb_cxt = cxt , con_args = args, con_res_ty = res_ty, con_g_ext = implicit_tkv_nms }) = -- Even though the GADT-style data constructor's type is closed, -- we must still kind-check the type, because that may influence -- the inferred kind of the /type/ constructor. Example: -- data T f a where -- MkT :: f a -> T f a -- If we don't look at MkT we won't get the correct kind -- for the type constructor T addErrCtxt (dataConCtxtName names) $ discardResult $ bindImplicitTKBndrs_Tv implicit_tkv_nms $ bindExplicitTKBndrs_Tv explicit_tkv_nms $ -- Why "_Tv"? See Note [Kind-checking for GADTs] do { _ <- tcHsMbContext cxt ; kcConArgTys new_or_data res_kind (hsConDeclArgTys args) ; _ <- tcHsOpenType res_ty ; return () } {- Note [kcConDecls result kind] ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ We might have e.g. data T a :: Type -> Type where ... or newtype instance N a :: Type -> Type where .. in which case, the 'res_kind' passed to kcConDecls will be Type->Type We must look past those arrows, or even foralls, to the Type in the corner, to pass to kcConDecl c.f. #16828. Hence the splitPiTys here. I am a bit concerned about tycons with a declaration like data T a :: Type -> forall k. k -> Type where ... It does not have a CUSK, so kcInferDeclHeader will make a TcTyCon with tyConResKind of Type -> forall k. k -> Type. Even that is fine: the splitPiTys will look past the forall. But I'm bothered about what if the type "in the corner" mentions k? This is incredibly obscure but something like this could be bad: data T a :: Type -> foral k. k -> TYPE (F k) where ... I bet we are not quite right here, but my brain suffered a buffer overflow and I thought it best to nail the common cases right now. Note [Recursion and promoting data constructors] ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ We don't want to allow promotion in a strongly connected component when kind checking. Consider: data T f = K (f (K Any)) When kind checking the `data T' declaration the local env contains the mappings: T -> ATcTyCon K -> APromotionErr APromotionErr is only used for DataCons, and only used during type checking in tcTyClGroup. Note [Kind-checking for GADTs] ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ Consider data Proxy a where MkProxy1 :: forall k (b :: k). Proxy b MkProxy2 :: forall j (c :: j). Proxy c It seems reasonable that this should be accepted. But something very strange is going on here: when we're kind-checking this declaration, we need to unify the kind of `a` with k and j -- even though k and j's scopes are local to the type of MkProxy{1,2}. The best approach we've come up with is to use TyVarTvs during the kind-checking pass. First off, note that it's OK if the kind-checking pass is too permissive: we'll snag the problems in the type-checking pass later. (This extra permissiveness might happen with something like data SameKind :: k -> k -> Type data Bad a where MkBad :: forall k1 k2 (a :: k1) (b :: k2). Bad (SameKind a b) which would be accepted if k1 and k2 were TyVarTvs. This is correctly rejected in the second pass, though. Test case: polykinds/TyVarTvKinds3) Recall that the kind-checking pass exists solely to collect constraints on the kinds and to power unification. To achieve the use of TyVarTvs, we must be careful to use specialized functions that produce TyVarTvs, not ordinary skolems. This is why we need kcExplicitTKBndrs and kcImplicitTKBndrs in GHC.Tc.Gen.HsType, separate from their tc... variants. The drawback of this approach is sometimes it will accept a definition that a (hypothetical) declarative specification would likely reject. As a general rule, we don't want to allow polymorphic recursion without a CUSK. Indeed, the whole point of CUSKs is to allow polymorphic recursion. Yet, the TyVarTvs approach allows a limited form of polymorphic recursion *without* a CUSK. To wit: data T a = forall k (b :: k). MkT (T b) Int (test case: dependent/should_compile/T14066a) Note that this is polymorphically recursive, with the recursive occurrence of T used at a kind other than a's kind. The approach outlined here accepts this definition, because this kind is still a kind variable (and so the TyVarTvs unify). Stepping back, I (Richard) have a hard time envisioning a way to describe exactly what declarations will be accepted and which will be rejected (without a CUSK). However, the accepted definitions are indeed well-kinded and any rejected definitions would be accepted with a CUSK, and so this wrinkle need not cause anyone to lose sleep. ************************************************************************ * * \subsection{Type checking} * * ************************************************************************ Note [Type checking recursive type and class declarations] ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ At this point we have completed *kind-checking* of a mutually recursive group of type/class decls (done in kcTyClGroup). However, we discarded the kind-checked types (eg RHSs of data type decls); note that kcTyClDecl returns (). There are two reasons: * It's convenient, because we don't have to rebuild a kinded HsDecl (a fairly elaborate type) * It's necessary, because after kind-generalisation, the TyCons/Classes may now be kind-polymorphic, and hence need to be given kind arguments. Example: data T f a = MkT (f a) (T f a) During kind-checking, we give T the kind T :: k1 -> k2 -> * and figure out constraints on k1, k2 etc. Then we generalise to get T :: forall k. (k->*) -> k -> * So now the (T f a) in the RHS must be elaborated to (T k f a). However, during tcTyClDecl of T (above) we will be in a recursive "knot". So we aren't allowed to look at the TyCon T itself; we are only allowed to put it (lazily) in the returned structures. But when kind-checking the RHS of T's decl, we *do* need to know T's kind (so that we can correctly elaboarate (T k f a). How can we get T's kind without looking at T? Delicate answer: during tcTyClDecl, we extend *Global* env with T -> ATyCon (the (not yet built) final TyCon for T) *Local* env with T -> ATcTyCon (TcTyCon with the polymorphic kind of T) Then: * During GHC.Tc.Gen.HsType.tcTyVar we look in the *local* env, to get the fully-known, not knot-tied TcTyCon for T. * Then, in GHC.Tc.Utils.Zonk.zonkTcTypeToType (and zonkTcTyCon in particular) we look in the *global* env to get the TyCon. This fancy footwork (with two bindings for T) is only necessary for the TyCons or Classes of this recursive group. Earlier, finished groups, live in the global env only. See also Note [Kind checking recursive type and class declarations] Note [Kind checking recursive type and class declarations] ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ Before we can type-check the decls, we must kind check them. This is done by establishing an "initial kind", which is a rather uninformed guess at a tycon's kind (by counting arguments, mainly) and then using this initial kind for recursive occurrences. The initial kind is stored in exactly the same way during kind-checking as it is during type-checking (Note [Type checking recursive type and class declarations]): in the *local* environment, with ATcTyCon. But we still must store *something* in the *global* environment. Even though we discard the result of kind-checking, we sometimes need to produce error messages. These error messages will want to refer to the tycons being checked, except that they don't exist yet, and it would be Terribly Annoying to get the error messages to refer back to HsSyn. So we create a TcTyCon and put it in the global env. This tycon can print out its name and knows its kind, but any other action taken on it will panic. Note that TcTyCons are *not* knot-tied, unlike the rather valid but knot-tied ones that occur during type-checking. Note [Declarations for wired-in things] ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ For wired-in things we simply ignore the declaration and take the wired-in information. That avoids complications. e.g. the need to make the data constructor worker name for a constraint tuple match the wired-in one Note [Implementation of UnliftedNewtypes] ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ Expected behavior of UnliftedNewtypes: * Proposal: https://github.com/ghc-proposals/ghc-proposals/blob/master/proposals/0013-unlifted-newtypes.rst * Discussion: https://github.com/ghc-proposals/ghc-proposals/pull/98 What follows is a high-level overview of the implementation of the proposal. STEP 1: Getting the initial kind, as done by inferInitialKind. We have two sub-cases: * With a SAK/CUSK: no change in kind-checking; the tycon is given the kind the user writes, whatever it may be. * Without a SAK/CUSK: If there is no kind signature, the tycon is given a kind `TYPE r`, for a fresh unification variable `r`. We do this even when -XUnliftedNewtypes is not on; see , below. STEP 2: Kind-checking, as done by kcTyClDecl. This step is skipped for CUSKs. The key function here is kcConDecl, which looks at an individual constructor declaration. When we are processing a newtype (but whether or not -XUnliftedNewtypes is enabled; see , below), we generate a correct ContextKind for the checking argument types: see getArgExpKind. Examples of newtypes affected by STEP 2, assuming -XUnliftedNewtypes is enabled (we use r0 to denote a unification variable): newtype Foo rep = MkFoo (forall (a :: TYPE rep). a) + kcConDecl unifies (TYPE r0) with (TYPE rep), where (TYPE r0) is the kind that inferInitialKind invented for (Foo rep). data Color = Red | Blue type family Interpret (x :: Color) :: RuntimeRep where Interpret 'Red = 'IntRep Interpret 'Blue = 'WordRep data family Foo (x :: Color) :: TYPE (Interpret x) newtype instance Foo 'Red = FooRedC Int# + kcConDecl unifies TYPE (Interpret 'Red) with TYPE 'IntRep Note that, in the GADT case, we might have a kind signature with arrows (newtype XYZ a b :: Type -> Type where ...). We want only the final component of the kind for checking in kcConDecl, so we call etaExpandAlgTyCon in kcTyClDecl. STEP 3: Type-checking (desugaring), as done by tcTyClDecl. The key function here is tcConDecl. Once again, we must use getArgExpKind to ensure that the representation type's kind matches that of the newtype, for two reasons: A. It is possible that a GADT has a CUSK. (Note that this is *not* possible for H98 types.) Recall that CUSK types don't go through kcTyClDecl, so we might not have done this kind check. B. We need to produce the coercion to put on the argument type if the kinds are different (for both H98 and GADT). Example of (B): type family F a where F Int = LiftedRep newtype N :: TYPE (F Int) where MkN :: Int -> N We really need to have the argument to MkN be (Int |> TYPE (sym axF)), where axF :: F Int ~ LiftedRep. That way, the argument kind is the same as the newtype kind, which is the principal correctness condition for newtypes. Wrinkle: Consider (#17021, typecheck/should_fail/T17021) type family Id (x :: a) :: a where Id x = x newtype T :: TYPE (Id LiftedRep) where MkT :: Int -> T In the type of MkT, we must end with (Int |> TYPE (sym axId)) -> T, never Int -> (T |> TYPE axId); otherwise, the result type of the constructor wouldn't match the datatype. However, type-checking the HsType T might reasonably result in (T |> hole). We thus must ensure that this cast is dropped, forcing the type-checker to add one to the Int instead. Why is it always safe to drop the cast? This result type is type-checked by tcHsOpenType, so its kind definitely looks like TYPE r, for some r. It is important that even after dropping the cast, the type's kind has the form TYPE r. This is guaranteed by restrictions on the kinds of datatypes. For example, a declaration like `newtype T :: Id Type` is rejected: a newtype's final kind always has the form TYPE r, just as we want. Note that this is possible in the H98 case only for a data family, because the H98 syntax doesn't permit a kind signature on the newtype itself. There are also some changes for deailng with families: 1. In tcFamDecl1, we suppress a tcIsLiftedTypeKind check if UnliftedNewtypes is on. This allows us to write things like: data family Foo :: TYPE 'IntRep 2. In a newtype instance (with -XUnliftedNewtypes), if the user does not write a kind signature, we want to allow the possibility that the kind is not Type, so we use newOpenTypeKind instead of liftedTypeKind. This is done in tcDataFamInstHeader in GHC.Tc.TyCl.Instance. Example: data family Bar (a :: RuntimeRep) :: TYPE a newtype instance Bar 'IntRep = BarIntC Int# newtype instance Bar 'WordRep :: TYPE 'WordRep where BarWordC :: Word# -> Bar 'WordRep The data instance corresponding to IntRep does not specify a kind signature, so tc_kind_sig just returns `TYPE r0` (where `r0` is a fresh metavariable). The data instance corresponding to WordRep does have a kind signature, so we use that kind signature. 3. A data family and its newtype instance may be declared with slightly different kinds. See point 7 in Note [Datatype return kinds]. There's also a change in the renamer: * In GHC.RenameSource.rnTyClDecl, enabling UnliftedNewtypes changes what is means for a newtype to have a CUSK. This is necessary since UnliftedNewtypes means that, for newtypes without kind signatures, we must use the field inside the data constructor to determine the result kind. See Note [Unlifted Newtypes and CUSKs] for more detail. For completeness, it was also necessary to make coerce work on unlifted types, resolving #13595. : It's tempting to think that the expected kind for a newtype constructor argument when -XUnliftedNewtypes is *not* enabled should just be Type. But this leads to difficulty in suggesting to enable UnliftedNewtypes. Here is an example: newtype A = MkA Int# If we expect the argument to MkA to have kind Type, then we get a kind-mismatch error. The problem is that there is no way to connect this mismatch error to -XUnliftedNewtypes, and suggest enabling the extension. So, instead, we allow the A to type-check, but then find the problem when doing validity checking (and where we get make a suitable error message). One potential worry is {-# LANGUAGE PolyKinds #-} newtype B a = MkB a This turns out OK, because unconstrained RuntimeReps default to LiftedRep, just as we would like. Another potential problem comes in a case like -- no UnliftedNewtypes data family D :: k newtype instance D = MkD Any Here, we want inference to tell us that k should be instantiated to Type in the instance. With the approach described here (checking for Type only in the validity checker), that will not happen. But I cannot think of a non-contrived example that will notice this lack of inference, so it seems better to improve error messages than be able to infer this instantiation. -} tcTyClDecl :: RolesInfo -> LTyClDecl GhcRn -> TcM (TyCon, [DerivInfo]) tcTyClDecl roles_info (L loc decl) | Just thing <- wiredInNameTyThing_maybe (tcdName decl) = case thing of -- See Note [Declarations for wired-in things] ATyCon tc -> return (tc, wiredInDerivInfo tc decl) _ -> pprPanic "tcTyClDecl" (ppr thing) | otherwise = setSrcSpan loc $ tcAddDeclCtxt decl $ do { traceTc "---- tcTyClDecl ---- {" (ppr decl) ; (tc, deriv_infos) <- tcTyClDecl1 Nothing roles_info decl ; traceTc "---- tcTyClDecl end ---- }" (ppr tc) ; return (tc, deriv_infos) } noDerivInfos :: a -> (a, [DerivInfo]) noDerivInfos a = (a, []) wiredInDerivInfo :: TyCon -> TyClDecl GhcRn -> [DerivInfo] wiredInDerivInfo tycon decl | DataDecl { tcdDataDefn = dataDefn } <- decl , HsDataDefn { dd_derivs = derivs } <- dataDefn = [ DerivInfo { di_rep_tc = tycon , di_scoped_tvs = if isFunTyCon tycon || isPrimTyCon tycon then [] -- no tyConTyVars else mkTyVarNamePairs (tyConTyVars tycon) , di_clauses = unLoc derivs , di_ctxt = tcMkDeclCtxt decl } ] wiredInDerivInfo _ _ = [] -- "type family" declarations tcTyClDecl1 :: Maybe Class -> RolesInfo -> TyClDecl GhcRn -> TcM (TyCon, [DerivInfo]) tcTyClDecl1 parent _roles_info (FamDecl { tcdFam = fd }) = fmap noDerivInfos $ tcFamDecl1 parent fd -- "type" synonym declaration tcTyClDecl1 _parent roles_info (SynDecl { tcdLName = L _ tc_name , tcdRhs = rhs }) = ASSERT( isNothing _parent ) fmap noDerivInfos $ tcTySynRhs roles_info tc_name rhs -- "data/newtype" declaration tcTyClDecl1 _parent roles_info decl@(DataDecl { tcdLName = L _ tc_name , tcdDataDefn = defn }) = ASSERT( isNothing _parent ) tcDataDefn (tcMkDeclCtxt decl) roles_info tc_name defn tcTyClDecl1 _parent roles_info (ClassDecl { tcdLName = L _ class_name , tcdCtxt = hs_ctxt , tcdMeths = meths , tcdFDs = fundeps , tcdSigs = sigs , tcdATs = ats , tcdATDefs = at_defs }) = ASSERT( isNothing _parent ) do { clas <- tcClassDecl1 roles_info class_name hs_ctxt meths fundeps sigs ats at_defs ; return (noDerivInfos (classTyCon clas)) } {- ********************************************************************* * * Class declarations * * ********************************************************************* -} tcClassDecl1 :: RolesInfo -> Name -> LHsContext GhcRn -> LHsBinds GhcRn -> [LHsFunDep GhcRn] -> [LSig GhcRn] -> [LFamilyDecl GhcRn] -> [LTyFamDefltDecl GhcRn] -> TcM Class tcClassDecl1 roles_info class_name hs_ctxt meths fundeps sigs ats at_defs = fixM $ \ clas -> -- We need the knot because 'clas' is passed into tcClassATs bindTyClTyVars class_name $ \ _ binders res_kind -> do { checkClassKindSig res_kind ; traceTc "tcClassDecl 1" (ppr class_name $$ ppr binders) ; let tycon_name = class_name -- We use the same name roles = roles_info tycon_name -- for TyCon and Class ; (ctxt, fds, sig_stuff, at_stuff) <- pushTcLevelM_ $ solveEqualities $ checkTvConstraints skol_info (binderVars binders) $ -- The checkTvConstraints is needed bring into scope the -- skolems bound by the class decl header (#17841) do { ctxt <- tcHsContext hs_ctxt ; fds <- mapM (addLocM tc_fundep) fundeps ; sig_stuff <- tcClassSigs class_name sigs meths ; at_stuff <- tcClassATs class_name clas ats at_defs ; return (ctxt, fds, sig_stuff, at_stuff) } -- The solveEqualities will report errors for any -- unsolved equalities, so these zonks should not encounter -- any unfilled coercion variables unless there is such an error -- The zonk also squeeze out the TcTyCons, and converts -- Skolems to tyvars. ; ze <- emptyZonkEnv ; ctxt <- zonkTcTypesToTypesX ze ctxt ; sig_stuff <- mapM (zonkTcMethInfoToMethInfoX ze) sig_stuff -- ToDo: do we need to zonk at_stuff? -- TODO: Allow us to distinguish between abstract class, -- and concrete class with no methods (maybe by -- specifying a trailing where or not ; mindef <- tcClassMinimalDef class_name sigs sig_stuff ; is_boot <- tcIsHsBootOrSig ; let body | is_boot, null ctxt, null at_stuff, null sig_stuff = Nothing | otherwise = Just (ctxt, at_stuff, sig_stuff, mindef) ; clas <- buildClass class_name binders roles fds body ; traceTc "tcClassDecl" (ppr fundeps $$ ppr binders $$ ppr fds) ; return clas } where skol_info = TyConSkol ClassFlavour class_name tc_fundep (tvs1, tvs2) = do { tvs1' <- mapM (tcLookupTyVar . unLoc) tvs1 ; ; tvs2' <- mapM (tcLookupTyVar . unLoc) tvs2 ; ; return (tvs1', tvs2') } {- Note [Associated type defaults] ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ The following is an example of associated type defaults: class C a where data D a type F a b :: * type F a b = [a] -- Default Note that we can get default definitions only for type families, not data families. -} tcClassATs :: Name -- The class name (not knot-tied) -> Class -- The class parent of this associated type -> [LFamilyDecl GhcRn] -- Associated types. -> [LTyFamDefltDecl GhcRn] -- Associated type defaults. -> TcM [ClassATItem] tcClassATs class_name cls ats at_defs = do { -- Complain about associated type defaults for non associated-types sequence_ [ failWithTc (badATErr class_name n) | n <- map at_def_tycon at_defs , not (n `elemNameSet` at_names) ] ; mapM tc_at ats } where at_def_tycon :: LTyFamDefltDecl GhcRn -> Name at_def_tycon = tyFamInstDeclName . unLoc at_fam_name :: LFamilyDecl GhcRn -> Name at_fam_name = familyDeclName . unLoc at_names = mkNameSet (map at_fam_name ats) at_defs_map :: NameEnv [LTyFamDefltDecl GhcRn] -- Maps an AT in 'ats' to a list of all its default defs in 'at_defs' at_defs_map = foldr (\at_def nenv -> extendNameEnv_C (++) nenv (at_def_tycon at_def) [at_def]) emptyNameEnv at_defs tc_at at = do { fam_tc <- addLocM (tcFamDecl1 (Just cls)) at ; let at_defs = lookupNameEnv at_defs_map (at_fam_name at) `orElse` [] ; atd <- tcDefaultAssocDecl fam_tc at_defs ; return (ATI fam_tc atd) } ------------------------- tcDefaultAssocDecl :: TyCon -- ^ Family TyCon (not knot-tied) -> [LTyFamDefltDecl GhcRn] -- ^ Defaults -> TcM (Maybe (KnotTied Type, SrcSpan)) -- ^ Type checked RHS tcDefaultAssocDecl _ [] = return Nothing -- No default declaration tcDefaultAssocDecl _ (d1:_:_) = failWithTc (text "More than one default declaration for" <+> ppr (tyFamInstDeclName (unLoc d1))) tcDefaultAssocDecl fam_tc [L loc (TyFamInstDecl { tfid_eqn = HsIB { hsib_ext = imp_vars , hsib_body = FamEqn { feqn_tycon = L _ tc_name , feqn_bndrs = mb_expl_bndrs , feqn_pats = hs_pats , feqn_rhs = hs_rhs_ty }}})] = -- See Note [Type-checking default assoc decls] setSrcSpan loc $ tcAddFamInstCtxt (text "default type instance") tc_name $ do { traceTc "tcDefaultAssocDecl 1" (ppr tc_name) ; let fam_tc_name = tyConName fam_tc vis_arity = length (tyConVisibleTyVars fam_tc) vis_pats = numVisibleArgs hs_pats -- Kind of family check ; ASSERT( fam_tc_name == tc_name ) checkTc (isTypeFamilyTyCon fam_tc) (wrongKindOfFamily fam_tc) -- Arity check ; checkTc (vis_pats == vis_arity) (wrongNumberOfParmsErr vis_arity) -- Typecheck RHS -- -- You might think we should pass in some AssocInstInfo, as we're looking -- at an associated type. But this would be wrong, because an associated -- type default LHS can mention *different* type variables than the -- enclosing class. So it's treated more as a freestanding beast. ; (qtvs, pats, rhs_ty) <- tcTyFamInstEqnGuts fam_tc NotAssociated imp_vars (mb_expl_bndrs `orElse` []) hs_pats hs_rhs_ty ; let fam_tvs = tyConTyVars fam_tc ppr_eqn = ppr_default_eqn pats rhs_ty pats_vis = tyConArgFlags fam_tc pats ; traceTc "tcDefaultAssocDecl 2" (vcat [ text "fam_tvs" <+> ppr fam_tvs , text "qtvs" <+> ppr qtvs , text "pats" <+> ppr pats , text "rhs_ty" <+> ppr rhs_ty ]) ; cpt_tvs <- zipWithM (extract_tv ppr_eqn) pats pats_vis ; check_all_distinct_tvs ppr_eqn $ zip cpt_tvs pats_vis ; let subst = zipTvSubst cpt_tvs (mkTyVarTys fam_tvs) ; pure $ Just (substTyUnchecked subst rhs_ty, loc) -- We also perform other checks for well-formedness and validity -- later, in checkValidClass } where -- Checks that a pattern on the LHS of a default is a type -- variable. If so, return the underlying type variable, and if -- not, throw an error. -- See Note [Type-checking default assoc decls] extract_tv :: SDoc -- The pretty-printed default equation -- (only used for error message purposes) -> Type -- The particular type pattern from which to extract -- its underlying type variable -> ArgFlag -- The visibility of the type pattern -- (only used for error message purposes) -> TcM TyVar extract_tv ppr_eqn pat pat_vis = case getTyVar_maybe pat of Just tv -> pure tv Nothing -> failWithTc $ pprWithExplicitKindsWhen (isInvisibleArgFlag pat_vis) $ hang (text "Illegal argument" <+> quotes (ppr pat) <+> text "in:") 2 (vcat [ppr_eqn, suggestion]) -- Checks that no type variables in an associated default declaration are -- duplicated. If that is the case, throw an error. -- See Note [Type-checking default assoc decls] check_all_distinct_tvs :: SDoc -- The pretty-printed default equation (only used -- for error message purposes) -> [(TyVar, ArgFlag)] -- The type variable arguments in the associated -- default declaration, along with their respective -- visibilities (the latter are only used for error -- message purposes) -> TcM () check_all_distinct_tvs ppr_eqn cpt_tvs_vis = let dups = findDupsEq ((==) `on` fst) cpt_tvs_vis in traverse_ (\d -> let (pat_tv, pat_vis) = NE.head d in failWithTc $ pprWithExplicitKindsWhen (isInvisibleArgFlag pat_vis) $ hang (text "Illegal duplicate variable" <+> quotes (ppr pat_tv) <+> text "in:") 2 (vcat [ppr_eqn, suggestion])) dups ppr_default_eqn :: [Type] -> Type -> SDoc ppr_default_eqn pats rhs_ty = quotes (text "type" <+> ppr (mkTyConApp fam_tc pats) <+> equals <+> ppr rhs_ty) suggestion :: SDoc suggestion = text "The arguments to" <+> quotes (ppr fam_tc) <+> text "must all be distinct type variables" {- Note [Type-checking default assoc decls] ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ Consider this default declaration for an associated type class C a where type F (a :: k) b :: Type type F (x :: j) y = Proxy x -> y Note that the class variable 'a' doesn't scope over the default assoc decl (rather oddly I think), and (less oddly) neither does the second argument 'b' of the associated type 'F', or the kind variable 'k'. Instead, the default decl is treated more like a top-level type instance. However we store the default rhs (Proxy x -> y) in F's TyCon, using F's own type variables, so we need to convert it to (Proxy a -> b). We do this by creating a substitution [j |-> k, x |-> a, b |-> y] and applying this substitution to the RHS. In order to create this substitution, we must first ensure that all of the arguments in the default instance consist of distinct type variables. One might think that this is a simple task that could be implemented earlier in the compiler, perhaps in the parser or the renamer. However, there are some tricky corner cases that really do require the full power of typechecking to weed out, as the examples below should illustrate. First, we must check that all arguments are type variables. As a motivating example, consider this erroneous program (inspired by #11361): class C a where type F (a :: k) b :: Type type F x b = x If you squint, you'll notice that the kind of `x` is actually Type. However, we cannot substitute from [Type |-> k], so we reject this default. Next, we must check that all arguments are distinct. Here is another offending example, this time taken from #13971: class C2 (a :: j) where type F2 (a :: j) (b :: k) type F2 (x :: z) y = SameKind x y data SameKind :: k -> k -> Type All of the arguments in the default equation for `F2` are type variables, so that passes the first check. However, if we were to build this substitution, then both `j` and `k` map to `z`! In terms of visible kind application, it's as if we had written `type F2 @z @z x y = SameKind @z x y`, which makes it clear that we have duplicated a use of `z` on the LHS. Therefore, `F2`'s default is also rejected. Since the LHS of an associated type family default is always just variables, it won't contain any tycons. Accordingly, the patterns used in the substitution won't actually be knot-tied, even though we're in the knot. This is too delicate for my taste, but it works. Note [Datatype return kinds] ~~~~~~~~~~~~~~~~~~~~~~~~~~~~ There are several poorly lit corners around datatype/newtype return kinds. This Note explains these. Within this note, always understand "instance" to mean data or newtype instance, and understand "family" to mean data family. No type families or classes here. Some examples: data T a :: where ... -- See Point 4 newtype T a :: where ... -- See Point 5 data family T a :: -- See Point 6 data instance T [a] :: where ... -- See Point 4 newtype instance T [a] :: where ... -- See Point 5 1. Where this applies: Only GADT syntax for data/newtype/instance declarations can have declared return kinds. This Note does not apply to Haskell98 syntax. 2. Where these kinds come from: Return kinds are processed through several different code paths: Data/newtypes: The return kind is part of the TyCon kind, gotten either by checkInitialKind (standalone kind signature / CUSK) or inferInitialKind. It is extracted by bindTyClTyVars in tcTyClDecl1. It is then passed to tcDataDefn. Families: The return kind is either written in a standalone signature or extracted from a family declaration in getInitialKind. If a family declaration is missing a result kind, it is assumed to be Type. This assumption is in getInitialKind for CUSKs or get_fam_decl_initial_kind for non-signature & non-CUSK cases. Instances: The data family already has a known kind. The return kind of an instance is then calculated by applying the data family tycon to the patterns provided, as computed by the typeKind lhs_ty in the end of tcDataFamInstHeader. In the case of an instance written in GADT syntax, there are potentially *two* return kinds: the one computed from applying the data family tycon to the patterns, and the one given by the user. This second kind is checked by the tc_kind_sig function within tcDataFamInstHeader. 3. Eta-expansion: Any forall-bound variables and function arguments in a result kind become parameters to the type. That is, when we say data T a :: Type -> Type where ... we really mean for T to have two parameters. The second parameter is produced by processing the return kind in etaExpandAlgTyCon, called in tcDataDefn for data/newtypes and in tcDataFamInstDecl for instances. This is true for data families as well, though their arity only matters for pretty-printing. See also Note [TyConBinders for the result kind signatures of a data type] in GHC.Tc.Gen.HsType. 4. Datatype return kind restriction: A data/data-instance return kind must end in a type that, after type-synonym expansion, yields `TYPE LiftedRep`. By "end in", we mean we strip any foralls and function arguments off before checking: this remaining part of the type is returned from etaExpandAlgTyCon. Examples: data T1 :: Type -- good data T2 :: Bool -> Type -- good data T3 :: Bool -> forall k. Type -- strange, but still accepted data T4 :: forall k. k -> Type -- good data T5 :: Bool -- bad data T6 :: Type -> Bool -- bad Exactly the same applies to data instance (but not data family) declarations. Examples data instance D1 :: Type -- good data instance D2 :: Boool -> Type -- good We can "look through" type synonyms type Star = Type data T7 :: Bool -> Star -- good (synonym expansion ok) type Arrow = (->) data T8 :: Arrow Bool Type -- good (ditto) But we specifically do *not* do type family reduction here. type family ARROW where ARROW = (->) data T9 :: ARROW Bool Type -- bad type family F a where F Int = Bool F Bool = Type data T10 :: Bool -> F Bool -- bad The /principle/ here is that in the TyCon for a data type or data instance, we must be able to lay out all the type-variable binders, one by one, until we reach (TYPE xx). There is no place for a cast here. We could add one, but let's not! This check is done in checkDataKindSig. For data declarations, this call is in tcDataDefn; for data instances, this call is in tcDataFamInstDecl. 4a Because data instances in GADT syntax can have two return kinds (see point (2) above), we must check both return kinds. The user-written return kind is checked by the call to checkDataKindSig in tcDataFamInstDecl. Examples: data family D (a :: Nat) :: k -- good (see Point 6) data instance D 1 :: Type -- good data instance D 2 :: F Bool -- bad 5. Newtype return kind restriction: If -XUnliftedNewtypes is on, then a newtype/newtype-instance return kind must end in TYPE xyz, for some xyz (after type synonym expansion). The "xyz" may include type families, but the TYPE part must be visible with expanding type families (only synonyms). This kind is unified with the kind of the representation type (the type of the one argument to the one constructor). See also steps (2) and (3) of Note [Implementation of UnliftedNewtypes]. If -XUnliftedNewtypes is not on, then newtypes are treated just like datatypes. The checks are done in the same places as for datatypes. Examples (assume -XUnliftedNewtypes): newtype N1 :: Type -- good newtype N2 :: Bool -> Type -- good newtype N3 :: forall r. Bool -> TYPE r -- good type family F (t :: Type) :: RuntimeRep newtype N4 :: forall t -> TYPE (F t) -- good type family STAR where STAR = Type newtype N5 :: Bool -> STAR -- bad 6. Family return kind restrictions: The return kind of a data family must be either TYPE xyz (for some xyz) or a kind variable. The idea is that instances may specialise the kind variable to fit one of the restrictions above. This is checked by the call to checkDataKindSig in tcFamDecl1. Examples: data family D1 :: Type -- good data family D2 :: Bool -> Type -- good data family D3 k :: k -- good data family D4 :: forall k -> k -- good data family D5 :: forall k. k -> k -- good data family D6 :: forall r. TYPE r -- good data family D7 :: Bool -> STAR -- bad (see STAR from point 5) 7. Two return kinds for instances: If an instance has two return kinds, one from the family declaration and one from the instance declaration (see point (2) above), they are unified. More accurately, we make sure that the kind of the applied data family is a subkind of the user-written kind. GHC.Tc.Gen.HsType.checkExpectedKind normally does this check for types, but that's overkill for our needs here. Instead, we just instantiate any invisible binders in the (instantiated) kind of the data family (called lhs_kind in tcDataFamInstHeader) with tcInstInvisibleTyBinders and then unify the resulting kind with the kind written by the user. This unification naturally produces a coercion, which we can drop, as the kind annotation on the instance is redundant (except perhaps for effects of unification). Example: data Color = Red | Blue type family Interpret (x :: Color) :: RuntimeRep where Interpret 'Red = 'IntRep Interpret 'Blue = 'WordRep data family Foo (x :: Color) :: TYPE (Interpret x) newtype instance Foo 'Red :: TYPE IntRep where FooRedC :: Int# -> Foo 'Red Here we get that Foo 'Red :: TYPE (Interpret Red) and we have to unify the kind with TYPE IntRep. Example requiring subkinding: data family D :: forall k. k data instance D :: Type -- forall k. k <: Type data instance D :: Type -> Type -- forall k. k <: Type -> Type -- NB: these do not overlap This all is Wrinkle (3) in Note [Implementation of UnliftedNewtypes]. -} {- ********************************************************************* * * Type family declarations * * ********************************************************************* -} tcFamDecl1 :: Maybe Class -> FamilyDecl GhcRn -> TcM TyCon tcFamDecl1 parent (FamilyDecl { fdInfo = fam_info , fdLName = tc_lname@(L _ tc_name) , fdResultSig = L _ sig , fdInjectivityAnn = inj }) | DataFamily <- fam_info = bindTyClTyVars tc_name $ \ _ binders res_kind -> do { traceTc "data family:" (ppr tc_name) ; checkFamFlag tc_name -- Check that the result kind is OK -- We allow things like -- data family T (a :: Type) :: forall k. k -> Type -- We treat T as having arity 1, but result kind forall k. k -> Type -- But we want to check that the result kind finishes in -- Type or a kind-variable -- For the latter, consider -- data family D a :: forall k. Type -> k -- When UnliftedNewtypes is enabled, we loosen this restriction -- on the return kind. See Note [Implementation of UnliftedNewtypes], wrinkle (1). -- See also Note [Datatype return kinds] ; let (_, final_res_kind) = splitPiTys res_kind ; checkDataKindSig DataFamilySort final_res_kind ; tc_rep_name <- newTyConRepName tc_name ; let inj = Injective $ replicate (length binders) True tycon = mkFamilyTyCon tc_name binders res_kind (resultVariableName sig) (DataFamilyTyCon tc_rep_name) parent inj ; return tycon } | OpenTypeFamily <- fam_info = bindTyClTyVars tc_name $ \ _ binders res_kind -> do { traceTc "open type family:" (ppr tc_name) ; checkFamFlag tc_name ; inj' <- tcInjectivity binders inj ; checkResultSigFlag tc_name sig -- check after injectivity for better errors ; let tycon = mkFamilyTyCon tc_name binders res_kind (resultVariableName sig) OpenSynFamilyTyCon parent inj' ; return tycon } | ClosedTypeFamily mb_eqns <- fam_info = -- Closed type families are a little tricky, because they contain the definition -- of both the type family and the equations for a CoAxiom. do { traceTc "Closed type family:" (ppr tc_name) -- the variables in the header scope only over the injectivity -- declaration but this is not involved here ; (inj', binders, res_kind) <- bindTyClTyVars tc_name $ \ _ binders res_kind -> do { inj' <- tcInjectivity binders inj ; return (inj', binders, res_kind) } ; checkFamFlag tc_name -- make sure we have -XTypeFamilies ; checkResultSigFlag tc_name sig -- If Nothing, this is an abstract family in a hs-boot file; -- but eqns might be empty in the Just case as well ; case mb_eqns of Nothing -> return $ mkFamilyTyCon tc_name binders res_kind (resultVariableName sig) AbstractClosedSynFamilyTyCon parent inj' Just eqns -> do { -- Process the equations, creating CoAxBranches ; let tc_fam_tc = mkTcTyCon tc_name binders res_kind noTcTyConScopedTyVars False {- this doesn't matter here -} ClosedTypeFamilyFlavour ; branches <- mapAndReportM (tcTyFamInstEqn tc_fam_tc NotAssociated) eqns -- Do not attempt to drop equations dominated by earlier -- ones here; in the case of mutual recursion with a data -- type, we get a knot-tying failure. Instead we check -- for this afterwards, in GHC.Tc.Validity.checkValidCoAxiom -- Example: tc265 -- Create a CoAxiom, with the correct src location. ; co_ax_name <- newFamInstAxiomName tc_lname [] ; let mb_co_ax | null eqns = Nothing -- mkBranchedCoAxiom fails on empty list | otherwise = Just (mkBranchedCoAxiom co_ax_name fam_tc branches) fam_tc = mkFamilyTyCon tc_name binders res_kind (resultVariableName sig) (ClosedSynFamilyTyCon mb_co_ax) parent inj' -- We check for instance validity later, when doing validity -- checking for the tycon. Exception: checking equations -- overlap done by dropDominatedAxioms ; return fam_tc } } #if __GLASGOW_HASKELL__ <= 810 | otherwise = panic "tcFamInst1" -- Silence pattern-exhaustiveness checker #endif -- | Maybe return a list of Bools that say whether a type family was declared -- injective in the corresponding type arguments. Length of the list is equal to -- the number of arguments (including implicit kind/coercion arguments). -- True on position -- N means that a function is injective in its Nth argument. False means it is -- not. tcInjectivity :: [TyConBinder] -> Maybe (LInjectivityAnn GhcRn) -> TcM Injectivity tcInjectivity _ Nothing = return NotInjective -- User provided an injectivity annotation, so for each tyvar argument we -- check whether a type family was declared injective in that argument. We -- return a list of Bools, where True means that corresponding type variable -- was mentioned in lInjNames (type family is injective in that argument) and -- False means that it was not mentioned in lInjNames (type family is not -- injective in that type variable). We also extend injectivity information to -- kind variables, so if a user declares: -- -- type family F (a :: k1) (b :: k2) = (r :: k3) | r -> a -- -- then we mark both `a` and `k1` as injective. -- NB: the return kind is considered to be *input* argument to a type family. -- Since injectivity allows to infer input arguments from the result in theory -- we should always mark the result kind variable (`k3` in this example) as -- injective. The reason is that result type has always an assigned kind and -- therefore we can always infer the result kind if we know the result type. -- But this does not seem to be useful in any way so we don't do it. (Another -- reason is that the implementation would not be straightforward.) tcInjectivity tcbs (Just (L loc (InjectivityAnn _ lInjNames))) = setSrcSpan loc $ do { let tvs = binderVars tcbs ; dflags <- getDynFlags ; checkTc (xopt LangExt.TypeFamilyDependencies dflags) (text "Illegal injectivity annotation" $$ text "Use TypeFamilyDependencies to allow this") ; inj_tvs <- mapM (tcLookupTyVar . unLoc) lInjNames ; inj_tvs <- mapM zonkTcTyVarToTyVar inj_tvs -- zonk the kinds ; let inj_ktvs = filterVarSet isTyVar $ -- no injective coercion vars closeOverKinds (mkVarSet inj_tvs) ; let inj_bools = map (`elemVarSet` inj_ktvs) tvs ; traceTc "tcInjectivity" (vcat [ ppr tvs, ppr lInjNames, ppr inj_tvs , ppr inj_ktvs, ppr inj_bools ]) ; return $ Injective inj_bools } tcTySynRhs :: RolesInfo -> Name -> LHsType GhcRn -> TcM TyCon tcTySynRhs roles_info tc_name hs_ty = bindTyClTyVars tc_name $ \ _ binders res_kind -> do { env <- getLclEnv ; traceTc "tc-syn" (ppr tc_name $$ ppr (tcl_env env)) ; rhs_ty <- pushTcLevelM_ $ solveEqualities $ tcCheckLHsType hs_ty (TheKind res_kind) ; rhs_ty <- zonkTcTypeToType rhs_ty ; let roles = roles_info tc_name tycon = buildSynTyCon tc_name binders res_kind roles rhs_ty ; return tycon } tcDataDefn :: SDoc -> RolesInfo -> Name -> HsDataDefn GhcRn -> TcM (TyCon, [DerivInfo]) -- NB: not used for newtype/data instances (whether associated or not) tcDataDefn err_ctxt roles_info tc_name (HsDataDefn { dd_ND = new_or_data, dd_cType = cType , dd_ctxt = ctxt , dd_kindSig = mb_ksig -- Already in tc's kind -- via inferInitialKinds , dd_cons = cons , dd_derivs = derivs }) = bindTyClTyVars tc_name $ \ tctc tycon_binders res_kind -> -- 'tctc' is a 'TcTyCon' and has the 'tcTyConScopedTyVars' that we need -- unlike the finalized 'tycon' defined above which is an 'AlgTyCon' -- -- The TyCon tyvars must scope over -- - the stupid theta (dd_ctxt) -- - for H98 constructors only, the ConDecl -- But it does no harm to bring them into scope -- over GADT ConDecls as well; and it's awkward not to do { gadt_syntax <- dataDeclChecks tc_name new_or_data ctxt cons -- see Note [Datatype return kinds] ; (extra_bndrs, final_res_kind) <- etaExpandAlgTyCon tycon_binders res_kind ; tcg_env <- getGblEnv ; let hsc_src = tcg_src tcg_env ; unless (mk_permissive_kind hsc_src cons) $ checkDataKindSig (DataDeclSort new_or_data) final_res_kind ; stupid_tc_theta <- pushTcLevelM_ $ solveEqualities $ tcHsContext ctxt ; stupid_theta <- zonkTcTypesToTypes stupid_tc_theta ; kind_signatures <- xoptM LangExt.KindSignatures -- Check that we don't use kind signatures without Glasgow extensions ; when (isJust mb_ksig) $ checkTc (kind_signatures) (badSigTyDecl tc_name) ; tycon <- fixM $ \ tycon -> do { let final_bndrs = tycon_binders `chkAppend` extra_bndrs res_ty = mkTyConApp tycon (mkTyVarTys (binderVars final_bndrs)) roles = roles_info tc_name ; data_cons <- tcConDecls tycon new_or_data final_bndrs final_res_kind res_ty cons ; tc_rhs <- mk_tc_rhs hsc_src tycon data_cons ; tc_rep_nm <- newTyConRepName tc_name ; return (mkAlgTyCon tc_name final_bndrs final_res_kind roles (fmap unLoc cType) stupid_theta tc_rhs (VanillaAlgTyCon tc_rep_nm) gadt_syntax) } ; let deriv_info = DerivInfo { di_rep_tc = tycon , di_scoped_tvs = tcTyConScopedTyVars tctc , di_clauses = unLoc derivs , di_ctxt = err_ctxt } ; traceTc "tcDataDefn" (ppr tc_name $$ ppr tycon_binders $$ ppr extra_bndrs) ; return (tycon, [deriv_info]) } where -- Abstract data types in hsig files can have arbitrary kinds, -- because they may be implemented by type synonyms -- (which themselves can have arbitrary kinds, not just *). See #13955. -- -- Note that this is only a property that data type declarations possess, -- so one could not have, say, a data family instance in an hsig file that -- has kind `Bool`. Therefore, this check need only occur in the code that -- typechecks data type declarations. mk_permissive_kind HsigFile [] = True mk_permissive_kind _ _ = False -- In hs-boot, a 'data' declaration with no constructors -- indicates a nominally distinct abstract data type. mk_tc_rhs HsBootFile _ [] = return AbstractTyCon mk_tc_rhs HsigFile _ [] -- ditto = return AbstractTyCon mk_tc_rhs _ tycon data_cons = case new_or_data of DataType -> return (mkDataTyConRhs data_cons) NewType -> ASSERT( not (null data_cons) ) mkNewTyConRhs tc_name tycon (head data_cons) ------------------------- kcTyFamInstEqn :: TcTyCon -> LTyFamInstEqn GhcRn -> TcM () -- Used for the equations of a closed type family only -- Not used for data/type instances kcTyFamInstEqn tc_fam_tc (L loc (HsIB { hsib_ext = imp_vars , hsib_body = FamEqn { feqn_tycon = L _ eqn_tc_name , feqn_bndrs = mb_expl_bndrs , feqn_pats = hs_pats , feqn_rhs = hs_rhs_ty }})) = setSrcSpan loc $ do { traceTc "kcTyFamInstEqn" (vcat [ text "tc_name =" <+> ppr eqn_tc_name , text "fam_tc =" <+> ppr tc_fam_tc <+> dcolon <+> ppr (tyConKind tc_fam_tc) , text "hsib_vars =" <+> ppr imp_vars , text "feqn_bndrs =" <+> ppr mb_expl_bndrs , text "feqn_pats =" <+> ppr hs_pats ]) -- this check reports an arity error instead of a kind error; easier for user ; let vis_pats = numVisibleArgs hs_pats ; checkTc (vis_pats == vis_arity) $ wrongNumberOfParmsErr vis_arity ; discardResult $ bindImplicitTKBndrs_Q_Tv imp_vars $ bindExplicitTKBndrs_Q_Tv AnyKind (mb_expl_bndrs `orElse` []) $ do { (_fam_app, res_kind) <- tcFamTyPats tc_fam_tc hs_pats ; tcCheckLHsType hs_rhs_ty (TheKind res_kind) } -- Why "_Tv" here? Consider (#14066 -- type family Bar x y where -- Bar (x :: a) (y :: b) = Int -- Bar (x :: c) (y :: d) = Bool -- During kind-checking, a,b,c,d should be TyVarTvs and unify appropriately } where vis_arity = length (tyConVisibleTyVars tc_fam_tc) -------------------------- tcTyFamInstEqn :: TcTyCon -> AssocInstInfo -> LTyFamInstEqn GhcRn -> TcM (KnotTied CoAxBranch) -- Needs to be here, not in GHC.Tc.TyCl.Instance, because closed families -- (typechecked here) have TyFamInstEqns tcTyFamInstEqn fam_tc mb_clsinfo (L loc (HsIB { hsib_ext = imp_vars , hsib_body = FamEqn { feqn_tycon = L _ eqn_tc_name , feqn_bndrs = mb_expl_bndrs , feqn_pats = hs_pats , feqn_rhs = hs_rhs_ty }})) = ASSERT( getName fam_tc == eqn_tc_name ) setSrcSpan loc $ do { traceTc "tcTyFamInstEqn" $ vcat [ ppr fam_tc <+> ppr hs_pats , text "fam tc bndrs" <+> pprTyVars (tyConTyVars fam_tc) , case mb_clsinfo of NotAssociated -> empty InClsInst { ai_class = cls } -> text "class" <+> ppr cls <+> pprTyVars (classTyVars cls) ] -- First, check the arity of visible arguments -- If we wait until validity checking, we'll get kind errors -- below when an arity error will be much easier to understand. ; let vis_arity = length (tyConVisibleTyVars fam_tc) vis_pats = numVisibleArgs hs_pats ; checkTc (vis_pats == vis_arity) $ wrongNumberOfParmsErr vis_arity ; (qtvs, pats, rhs_ty) <- tcTyFamInstEqnGuts fam_tc mb_clsinfo imp_vars (mb_expl_bndrs `orElse` []) hs_pats hs_rhs_ty -- Don't print results they may be knot-tied -- (tcFamInstEqnGuts zonks to Type) ; return (mkCoAxBranch qtvs [] [] fam_tc pats rhs_ty (map (const Nominal) qtvs) loc) } {- Kind check type patterns and kind annotate the embedded type variables. type instance F [a] = rhs * Here we check that a type instance matches its kind signature, but we do not check whether there is a pattern for each type index; the latter check is only required for type synonym instances. Note [Instantiating a family tycon] ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ It's possible that kind-checking the result of a family tycon applied to its patterns will instantiate the tycon further. For example, we might have type family F :: k where F = Int F = Maybe After checking (F :: forall k. k) (with no visible patterns), we still need to instantiate the k. With data family instances, this problem can be even more intricate, due to Note [Arity of data families] in GHC.Core.FamInstEnv. See indexed-types/should_compile/T12369 for an example. So, the kind-checker must return the new skolems and args (that is, Type or (Type -> Type) for the equations above) and the instantiated kind. Note [Generalising in tcTyFamInstEqnGuts] ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ Suppose we have something like type instance forall (a::k) b. F t1 t2 = rhs Then imp_vars = [k], exp_bndrs = [a::k, b] We want to quantify over * k, a, and b (all user-specified) * and any inferred free kind vars from - the kinds of k, a, b - the types t1, t2 However, unlike a type signature like f :: forall (a::k). blah we do /not/ care about the Inferred/Specified designation or order for the final quantified tyvars. Type-family instances are not invoked directly in Haskell source code, so visible type application etc plays no role. So, the simple thing is - gather candidates from [k, a, b] and pats - quantify over them Hence the slightly mysterious call: candidateQTyVarsOfTypes (pats ++ mkTyVarTys scoped_tvs) Simple, neat, but a little non-obvious! See also Note [Re-quantify type variables in rules] in GHC.Tc.Gen.Rule, which explains a very similar design when generalising over the type of a rewrite rule. -} -------------------------- tcTyFamInstEqnGuts :: TyCon -> AssocInstInfo -> [Name] -> [LHsTyVarBndr () GhcRn] -- Implicit and explicicit binder -> HsTyPats GhcRn -- Patterns -> LHsType GhcRn -- RHS -> TcM ([TyVar], [TcType], TcType) -- (tyvars, pats, rhs) -- Used only for type families, not data families tcTyFamInstEqnGuts fam_tc mb_clsinfo imp_vars exp_bndrs hs_pats hs_rhs_ty = do { traceTc "tcTyFamInstEqnGuts {" (ppr fam_tc) -- By now, for type families (but not data families) we should -- have checked that the number of patterns matches tyConArity -- This code is closely related to the code -- in GHC.Tc.Gen.HsType.kcCheckDeclHeader_cusk ; (imp_tvs, (exp_tvs, (lhs_ty, rhs_ty))) <- pushTcLevelM_ $ solveEqualities $ bindImplicitTKBndrs_Q_Skol imp_vars $ bindExplicitTKBndrs_Q_Skol AnyKind exp_bndrs $ do { (lhs_ty, rhs_kind) <- tcFamTyPats fam_tc hs_pats -- Ensure that the instance is consistent with its -- parent class (#16008) ; addConsistencyConstraints mb_clsinfo lhs_ty ; rhs_ty <- tcCheckLHsType hs_rhs_ty (TheKind rhs_kind) ; return (lhs_ty, rhs_ty) } -- See Note [Generalising in tcTyFamInstEqnGuts] -- This code (and the stuff immediately above) is very similar -- to that in tcDataFamInstHeader. Maybe we should abstract the -- common code; but for the moment I concluded that it's -- clearer to duplicate it. Still, if you fix a bug here, -- check there too! ; let scoped_tvs = imp_tvs ++ exp_tvs ; dvs <- candidateQTyVarsOfTypes (lhs_ty : mkTyVarTys scoped_tvs) ; qtvs <- quantifyTyVars dvs ; traceTc "tcTyFamInstEqnGuts 2" $ vcat [ ppr fam_tc , text "scoped_tvs" <+> pprTyVars scoped_tvs , text "lhs_ty" <+> ppr lhs_ty , text "dvs" <+> ppr dvs , text "qtvs" <+> pprTyVars qtvs ] ; (ze, qtvs) <- zonkTyBndrs qtvs ; lhs_ty <- zonkTcTypeToTypeX ze lhs_ty ; rhs_ty <- zonkTcTypeToTypeX ze rhs_ty ; let pats = unravelFamInstPats lhs_ty -- Note that we do this after solveEqualities -- so that any strange coercions inside lhs_ty -- have been solved before we attempt to unravel it ; traceTc "tcTyFamInstEqnGuts }" (ppr fam_tc <+> pprTyVars qtvs) ; return (qtvs, pats, rhs_ty) } ----------------- unravelFamInstPats :: TcType -> [TcType] -- Decompose fam_app to get the argument patterns -- -- We expect fam_app to look like (F t1 .. tn) -- tcFamTyPats is capable of returning ((F ty1 |> co) ty2), -- but that can't happen here because we already checked the -- arity of F matches the number of pattern unravelFamInstPats fam_app = case splitTyConApp_maybe fam_app of Just (_, pats) -> pats Nothing -> panic "unravelFamInstPats: Ill-typed LHS of family instance" -- The Nothing case cannot happen for type families, because -- we don't call unravelFamInstPats until we've solved the -- equalities. For data families, it shouldn't happen either, -- we need to fail hard and early if it does. See trac issue #15905 -- for an example of this happening. addConsistencyConstraints :: AssocInstInfo -> TcType -> TcM () -- In the corresponding positions of the class and type-family, -- ensure the the family argument is the same as the class argument -- E.g class C a b c d where -- F c x y a :: Type -- Here the first arg of F should be the same as the third of C -- and the fourth arg of F should be the same as the first of C -- -- We emit /Derived/ constraints (a bit like fundeps) to encourage -- unification to happen, but without actually reporting errors. -- If, despite the efforts, corresponding positions do not match, -- checkConsistentFamInst will complain addConsistencyConstraints mb_clsinfo fam_app | InClsInst { ai_inst_env = inst_env } <- mb_clsinfo , Just (fam_tc, pats) <- tcSplitTyConApp_maybe fam_app = do { let eqs = [ (cls_ty, pat) | (fam_tc_tv, pat) <- tyConTyVars fam_tc `zip` pats , Just cls_ty <- [lookupVarEnv inst_env fam_tc_tv] ] ; traceTc "addConsistencyConstraints" (ppr eqs) ; emitDerivedEqs AssocFamPatOrigin eqs } -- Improve inference -- Any mis-match is reports by checkConsistentFamInst | otherwise = return () {- Note [Constraints in patterns] ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ NB: This isn't the whole story. See comment in tcFamTyPats. At first glance, it seems there is a complicated story to tell in tcFamTyPats around constraint solving. After all, type family patterns can now do GADT pattern-matching, which is jolly complicated. But, there's a key fact which makes this all simple: everything is at top level! There cannot be untouchable type variables. There can't be weird interaction between case branches. There can't be global skolems. This means that the semantics of type-level GADT matching is a little different than term level. If we have data G a where MkGBool :: G Bool And then type family F (a :: G k) :: k type instance F MkGBool = True we get axF : F Bool (MkGBool ) ~ True Simple! No casting on the RHS, because we can affect the kind parameter to F. If we ever introduce local type families, this all gets a lot more complicated, and will end up looking awfully like term-level GADT pattern-matching. ** The new story ** Here is really what we want: The matcher really can't deal with covars in arbitrary spots in coercions. But it can deal with covars that are arguments to GADT data constructors. So we somehow want to allow covars only in precisely those spots, then use them as givens when checking the RHS. TODO (RAE): Implement plan. Note [Quantified kind variables of a family pattern] ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ Consider type family KindFam (p :: k1) (q :: k1) data T :: Maybe k1 -> k2 -> * type instance KindFam (a :: Maybe k) b = T a b -> Int The HsBSig for the family patterns will be ([k], [a]) Then in the family instance we want to * Bring into scope [ "k" -> k:*, "a" -> a:k ] * Kind-check the RHS * Quantify the type instance over k and k', as well as a,b, thus type instance [k, k', a:Maybe k, b:k'] KindFam (Maybe k) k' a b = T k k' a b -> Int Notice that in the third step we quantify over all the visibly-mentioned type variables (a,b), but also over the implicitly mentioned kind variables (k, k'). In this case one is bound explicitly but often there will be none. The role of the kind signature (a :: Maybe k) is to add a constraint that 'a' must have that kind, and to bring 'k' into scope. ************************************************************************ * * Data types * * ************************************************************************ -} dataDeclChecks :: Name -> NewOrData -> LHsContext GhcRn -> [LConDecl GhcRn] -> TcM Bool dataDeclChecks tc_name new_or_data (L _ stupid_theta) cons = do { -- Check that we don't use GADT syntax in H98 world gadtSyntax_ok <- xoptM LangExt.GADTSyntax ; let gadt_syntax = consUseGadtSyntax cons ; checkTc (gadtSyntax_ok || not gadt_syntax) (badGadtDecl tc_name) -- Check that the stupid theta is empty for a GADT-style declaration ; checkTc (null stupid_theta || not gadt_syntax) (badStupidTheta tc_name) -- Check that a newtype has exactly one constructor -- Do this before checking for empty data decls, so that -- we don't suggest -XEmptyDataDecls for newtypes ; checkTc (new_or_data == DataType || isSingleton cons) (newtypeConError tc_name (length cons)) -- Check that there's at least one condecl, -- or else we're reading an hs-boot file, or -XEmptyDataDecls ; empty_data_decls <- xoptM LangExt.EmptyDataDecls ; is_boot <- tcIsHsBootOrSig -- Are we compiling an hs-boot file? ; checkTc (not (null cons) || empty_data_decls || is_boot) (emptyConDeclsErr tc_name) ; return gadt_syntax } ----------------------------------- consUseGadtSyntax :: [LConDecl GhcRn] -> Bool consUseGadtSyntax (L _ (ConDeclGADT {}) : _) = True consUseGadtSyntax _ = False -- All constructors have same shape ----------------------------------- tcConDecls :: KnotTied TyCon -> NewOrData -> [TyConBinder] -> TcKind -- binders and result kind of tycon -> KnotTied Type -> [LConDecl GhcRn] -> TcM [DataCon] tcConDecls rep_tycon new_or_data tmpl_bndrs res_kind res_tmpl = concatMapM $ addLocM $ tcConDecl rep_tycon (mkTyConTagMap rep_tycon) tmpl_bndrs res_kind res_tmpl new_or_data -- It's important that we pay for tag allocation here, once per TyCon, -- See Note [Constructor tag allocation], fixes #14657 tcConDecl :: KnotTied TyCon -- Representation tycon. Knot-tied! -> NameEnv ConTag -> [TyConBinder] -> TcKind -- tycon binders and result kind -> KnotTied Type -- Return type template (T tys), where T is the family TyCon -> NewOrData -> ConDecl GhcRn -> TcM [DataCon] tcConDecl rep_tycon tag_map tmpl_bndrs res_kind res_tmpl new_or_data (ConDeclH98 { con_name = name , con_ex_tvs = explicit_tkv_nms , con_mb_cxt = hs_ctxt , con_args = hs_args }) = addErrCtxt (dataConCtxtName [name]) $ do { -- NB: the tyvars from the declaration header are in scope -- Get hold of the existential type variables -- e.g. data T a = forall k (b::k) f. MkT a (f b) -- Here tmpl_bndrs = {a} -- hs_qvars = HsQTvs { hsq_implicit = {k} -- , hsq_explicit = {f,b} } ; traceTc "tcConDecl 1" (vcat [ ppr name, ppr explicit_tkv_nms ]) ; (exp_tvbndrs, (ctxt, arg_tys, field_lbls, stricts)) <- pushTcLevelM_ $ solveEqualities $ bindExplicitTKBndrs_Skol explicit_tkv_nms $ do { ctxt <- tcHsMbContext hs_ctxt ; let exp_kind = getArgExpKind new_or_data res_kind ; btys <- tcConArgs exp_kind hs_args ; field_lbls <- lookupConstructorFields (unLoc name) ; let (arg_tys, stricts) = unzip btys ; return (ctxt, arg_tys, field_lbls, stricts) } ; let tmpl_tvs = binderVars tmpl_bndrs -- exp_tvs have explicit, user-written binding sites -- the kvs below are those kind variables entirely unmentioned by the user -- and discovered only by generalization ; kvs <- kindGeneralizeAll (mkSpecForAllTys tmpl_tvs $ mkInvisForAllTys exp_tvbndrs $ mkPhiTy ctxt $ mkVisFunTys arg_tys $ unitTy) -- That type is a lie, of course. (It shouldn't end in ()!) -- And we could construct a proper result type from the info -- at hand. But the result would mention only the tmpl_tvs, -- and so it just creates more work to do it right. Really, -- we're only doing this to find the right kind variables to -- quantify over, and this type is fine for that purpose. -- Zonk to Types ; (ze, qkvs) <- zonkTyBndrs kvs ; (ze, user_qtvbndrs) <- zonkTyVarBindersX ze exp_tvbndrs ; let user_qtvs = binderVars user_qtvbndrs ; arg_tys <- zonkScaledTcTypesToTypesX ze arg_tys ; ctxt <- zonkTcTypesToTypesX ze ctxt ; fam_envs <- tcGetFamInstEnvs -- Can't print univ_tvs, arg_tys etc, because we are inside the knot here ; traceTc "tcConDecl 2" (ppr name $$ ppr field_lbls) ; let univ_tvbs = tyConInvisTVBinders tmpl_bndrs univ_tvs = binderVars univ_tvbs ex_tvbs = mkTyVarBinders InferredSpec qkvs ++ user_qtvbndrs ex_tvs = qkvs ++ user_qtvs -- For H98 datatypes, the user-written tyvar binders are precisely -- the universals followed by the existentials. -- See Note [DataCon user type variable binders] in GHC.Core.DataCon. user_tvbs = univ_tvbs ++ ex_tvbs buildOneDataCon (L _ name) = do { is_infix <- tcConIsInfixH98 name hs_args ; rep_nm <- newTyConRepName name ; buildDataCon fam_envs name is_infix rep_nm stricts Nothing field_lbls univ_tvs ex_tvs user_tvbs [{- no eq_preds -}] ctxt arg_tys res_tmpl rep_tycon tag_map -- NB: we put data_tc, the type constructor gotten from the -- constructor type signature into the data constructor; -- that way checkValidDataCon can complain if it's wrong. } ; traceTc "tcConDecl 2" (ppr name) ; mapM buildOneDataCon [name] } tcConDecl rep_tycon tag_map tmpl_bndrs _res_kind res_tmpl new_or_data -- NB: don't use res_kind here, as it's ill-scoped. Instead, we get -- the res_kind by typechecking the result type. (ConDeclGADT { con_g_ext = implicit_tkv_nms , con_names = names , con_qvars = explicit_tkv_nms , con_mb_cxt = cxt, con_args = hs_args , con_res_ty = hs_res_ty }) = addErrCtxt (dataConCtxtName names) $ do { traceTc "tcConDecl 1 gadt" (ppr names) ; let (L _ name : _) = names ; (imp_tvs, (exp_tvbndrs, (ctxt, arg_tys, res_ty, field_lbls, stricts))) <- pushTcLevelM_ $ -- We are going to generalise solveEqualities $ -- We won't get another crack, and we don't -- want an error cascade bindImplicitTKBndrs_Skol implicit_tkv_nms $ bindExplicitTKBndrs_Skol explicit_tkv_nms $ do { ctxt <- tcHsMbContext cxt ; casted_res_ty <- tcHsOpenType hs_res_ty ; res_ty <- if not debugIsOn then return $ discardCast casted_res_ty else case splitCastTy_maybe casted_res_ty of Just (ty, _) -> do unlifted_nts <- xoptM LangExt.UnliftedNewtypes MASSERT( unlifted_nts ) MASSERT( new_or_data == NewType ) return ty _ -> return casted_res_ty -- See Note [Datatype return kinds] ; let exp_kind = getArgExpKind new_or_data (typeKind res_ty) ; btys <- tcConArgs exp_kind hs_args ; let (arg_tys, stricts) = unzip btys ; field_lbls <- lookupConstructorFields name ; return (ctxt, arg_tys, res_ty, field_lbls, stricts) } ; imp_tvs <- zonkAndScopedSort imp_tvs ; tkvs <- kindGeneralizeAll (mkSpecForAllTys imp_tvs $ mkInvisForAllTys exp_tvbndrs $ mkPhiTy ctxt $ mkVisFunTys arg_tys $ res_ty) ; let tvbndrs = (mkTyVarBinders InferredSpec tkvs) ++ (mkTyVarBinders SpecifiedSpec imp_tvs) ++ exp_tvbndrs -- Zonk to Types ; (ze, tvbndrs) <- zonkTyVarBinders tvbndrs ; arg_tys <- zonkScaledTcTypesToTypesX ze arg_tys ; ctxt <- zonkTcTypesToTypesX ze ctxt ; res_ty <- zonkTcTypeToTypeX ze res_ty ; let (univ_tvs, ex_tvs, tvbndrs', eq_preds, arg_subst) = rejigConRes tmpl_bndrs res_tmpl tvbndrs res_ty -- See Note [Checking GADT return types] ctxt' = substTys arg_subst ctxt arg_tys' = substScaledTys arg_subst arg_tys res_ty' = substTy arg_subst res_ty ; fam_envs <- tcGetFamInstEnvs -- Can't print univ_tvs, arg_tys etc, because we are inside the knot here ; traceTc "tcConDecl 2" (ppr names $$ ppr field_lbls) ; let buildOneDataCon (L _ name) = do { is_infix <- tcConIsInfixGADT name hs_args ; rep_nm <- newTyConRepName name ; buildDataCon fam_envs name is_infix rep_nm stricts Nothing field_lbls univ_tvs ex_tvs tvbndrs' eq_preds ctxt' arg_tys' res_ty' rep_tycon tag_map -- NB: we put data_tc, the type constructor gotten from the -- constructor type signature into the data constructor; -- that way checkValidDataCon can complain if it's wrong. } ; traceTc "tcConDecl 2" (ppr names) ; mapM buildOneDataCon names } -- | Produce an "expected kind" for the arguments of a data/newtype. -- If the declaration is indeed for a newtype, -- then this expected kind will be the kind provided. Otherwise, -- it is OpenKind for datatypes and liftedTypeKind. -- Why do we not check for -XUnliftedNewtypes? See point -- in Note [Implementation of UnliftedNewtypes] getArgExpKind :: NewOrData -> Kind -> ContextKind getArgExpKind NewType res_ki = TheKind res_ki getArgExpKind DataType _ = OpenKind tcConIsInfixH98 :: Name -> HsConDetails a b -> TcM Bool tcConIsInfixH98 _ details = case details of InfixCon {} -> return True _ -> return False tcConIsInfixGADT :: Name -> HsConDetails (HsScaled GhcRn (LHsType GhcRn)) r -> TcM Bool tcConIsInfixGADT con details = case details of InfixCon {} -> return True RecCon {} -> return False PrefixCon arg_tys -- See Note [Infix GADT constructors] | isSymOcc (getOccName con) , [_ty1,_ty2] <- map hsScaledThing arg_tys -> do { fix_env <- getFixityEnv ; return (con `elemNameEnv` fix_env) } | otherwise -> return False tcConArgs :: ContextKind -- expected kind of arguments -- always OpenKind for datatypes, but unlifted newtypes -- might have a specific kind -> HsConDeclDetails GhcRn -> TcM [(Scaled TcType, HsSrcBang)] tcConArgs exp_kind (PrefixCon btys) = mapM (tcConArg exp_kind) btys tcConArgs exp_kind (InfixCon bty1 bty2) = do { bty1' <- tcConArg exp_kind bty1 ; bty2' <- tcConArg exp_kind bty2 ; return [bty1', bty2'] } tcConArgs exp_kind (RecCon fields) = mapM (tcConArg exp_kind) btys where -- We need a one-to-one mapping from field_names to btys combined = map (\(L _ f) -> (cd_fld_names f,hsLinear (cd_fld_type f))) (unLoc fields) explode (ns,ty) = zip ns (repeat ty) exploded = concatMap explode combined (_,btys) = unzip exploded tcConArg :: ContextKind -- expected kind for args; always OpenKind for datatypes, -- but might be an unlifted type with UnliftedNewtypes -> HsScaled GhcRn (LHsType GhcRn) -> TcM (Scaled TcType, HsSrcBang) tcConArg exp_kind (HsScaled w bty) = do { traceTc "tcConArg 1" (ppr bty) ; arg_ty <- tcCheckLHsType (getBangType bty) exp_kind ; w' <- tcMult w ; traceTc "tcConArg 2" (ppr bty) ; return (Scaled w' arg_ty, getBangStrictness bty) } {- Note [Infix GADT constructors] ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ We do not currently have syntax to declare an infix constructor in GADT syntax, but it makes a (small) difference to the Show instance. So as a slightly ad-hoc solution, we regard a GADT data constructor as infix if a) it is an operator symbol b) it has two arguments c) there is a fixity declaration for it For example: infix 6 (:--:) data T a where (:--:) :: t1 -> t2 -> T Int Note [Checking GADT return types] ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ There is a delicacy around checking the return types of a datacon. The central problem is dealing with a declaration like data T a where MkT :: T a -> Q a Note that the return type of MkT is totally bogus. When creating the T tycon, we also need to create the MkT datacon, which must have a "rejigged" return type. That is, the MkT datacon's type must be transformed to have a uniform return type with explicit coercions for GADT-like type parameters. This rejigging is what rejigConRes does. The problem is, though, that checking that the return type is appropriate is much easier when done over *Type*, not *HsType*, and doing a call to tcMatchTy will loop because T isn't fully defined yet. So, we want to make rejigConRes lazy and then check the validity of the return type in checkValidDataCon. To do this we /always/ return a 6-tuple from rejigConRes (so that we can compute the return type from it, which checkValidDataCon needs), but the first three fields may be bogus if the return type isn't valid (the last equation for rejigConRes). This is better than an earlier solution which reduced the number of errors reported in one pass. See #7175, and #10836. -} -- 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) rejigConRes :: [KnotTied TyConBinder] -> KnotTied Type -- Template for result type; e.g. -- data instance T [a] b c ... -- gives template ([a,b,c], T [a] b c) -> [InvisTVBinder] -- The constructor's type variables (both inferred and user-written) -> KnotTied Type -- res_ty -> ([TyVar], -- Universal [TyVar], -- Existential (distinct OccNames from univs) [InvisTVBinder], -- The constructor's rejigged, user-written -- type variables [EqSpec], -- Equality predicates TCvSubst) -- Substitution to apply to argument types -- We don't check that the TyCon given in the ResTy is -- the same as the parent tycon, because checkValidDataCon will do it -- NB: All arguments may potentially be knot-tied rejigConRes tmpl_bndrs res_tmpl dc_tvbndrs res_ty -- E.g. data T [a] b c where -- MkT :: forall x y z. T [(x,y)] z z -- The {a,b,c} are the tmpl_tvs, and the {x,y,z} are the dc_tvs -- (NB: unlike the H98 case, the dc_tvs are not all existential) -- Then we generate -- Univ tyvars Eq-spec -- a a~(x,y) -- b b~z -- z -- Existentials are the leftover type vars: [x,y] -- The user-written type variables are what is listed in the forall: -- [x, y, z] (all specified). We must rejig these as well. -- See Note [DataCon user type variable binders] in GHC.Core.DataCon. -- So we return ( [a,b,z], [x,y] -- , [], [x,y,z] -- , [a~(x,y),b~z], ) | Just subst <- tcMatchTy res_tmpl res_ty = let (univ_tvs, raw_eqs, kind_subst) = mkGADTVars tmpl_tvs dc_tvs subst raw_ex_tvs = dc_tvs `minusList` univ_tvs (arg_subst, substed_ex_tvs) = substTyVarBndrs kind_subst raw_ex_tvs -- After rejigging the existential tyvars, the resulting substitution -- gives us exactly what we need to rejig the user-written tyvars, -- since the dcUserTyVarBinders invariant guarantees that the -- substitution has *all* the tyvars in its domain. -- See Note [DataCon user type variable binders] in GHC.Core.DataCon. subst_user_tvs = mapVarBndrs (getTyVar "rejigConRes" . substTyVar arg_subst) substed_tvbndrs = subst_user_tvs dc_tvbndrs substed_eqs = map (substEqSpec arg_subst) raw_eqs in (univ_tvs, substed_ex_tvs, substed_tvbndrs, substed_eqs, arg_subst) | otherwise -- If the return type of the data constructor doesn't match the parent -- type constructor, or the arity is wrong, the tcMatchTy will fail -- e.g data T a b where -- T1 :: Maybe a -- Wrong tycon -- T2 :: T [a] -- Wrong arity -- We are detect that later, in checkValidDataCon, but meanwhile -- we must do *something*, not just crash. So we do something simple -- albeit bogus, relying on checkValidDataCon to check the -- bad-result-type error before seeing that the other fields look odd -- See Note [Checking GADT return types] = (tmpl_tvs, dc_tvs `minusList` tmpl_tvs, dc_tvbndrs, [], emptyTCvSubst) where dc_tvs = binderVars dc_tvbndrs tmpl_tvs = binderVars tmpl_bndrs {- Note [mkGADTVars] ~~~~~~~~~~~~~~~~~~~~ Running example: data T (k1 :: *) (k2 :: *) (a :: k2) (b :: k2) where MkT :: forall (x1 : *) (y :: x1) (z :: *). T x1 * (Proxy (y :: x1), z) z We need the rejigged type to be MkT :: forall (x1 :: *) (k2 :: *) (a :: k2) (b :: k2). forall (y :: x1) (z :: *). (k2 ~ *, a ~ (Proxy x1 y, z), b ~ z) => T x1 k2 a b You might naively expect that z should become a universal tyvar, not an existential. (After all, x1 becomes a universal tyvar.) But z has kind * while b has kind k2, so the return type T x1 k2 a z is ill-kinded. Another way to say it is this: the universal tyvars must have exactly the same kinds as the tyConTyVars. So we need an existential tyvar and a heterogeneous equality constraint. (The b ~ z is a bit redundant with the k2 ~ * that comes before in that b ~ z implies k2 ~ *. I'm sure we could do some analysis that could eliminate k2 ~ *. But we don't do this yet.) The data con signature has already been fully kind-checked. The return type T x1 * (Proxy (y :: x1), z) z becomes qtkvs = [x1 :: *, y :: x1, z :: *] res_tmpl = T x1 * (Proxy x1 y, z) z We start off by matching (T k1 k2 a b) with (T x1 * (Proxy x1 y, z) z). We know this match will succeed because of the validity check (actually done later, but laziness saves us -- see Note [Checking GADT return types]). Thus, we get subst := { k1 |-> x1, k2 |-> *, a |-> (Proxy x1 y, z), b |-> z } Now, we need to figure out what the GADT equalities should be. In this case, we *don't* want (k1 ~ x1) to be a GADT equality: it should just be a renaming. The others should be GADT equalities. We also need to make sure that the universally-quantified variables of the datacon match up with the tyvars of the tycon, as required for Core context well-formedness. (This last bit is why we have to rejig at all!) `choose` walks down the tycon tyvars, figuring out what to do with each one. It carries two substitutions: - t_sub's domain is *template* or *tycon* tyvars, mapping them to variables mentioned in the datacon signature. - r_sub's domain is *result* tyvars, names written by the programmer in the datacon signature. The final rejigged type will use these names, but the subst is still needed because sometimes the printed name of these variables is different. (See choose_tv_name, below.) Before explaining the details of `choose`, let's just look at its operation on our example: choose [] [] {} {} [k1, k2, a, b] --> -- first branch of `case` statement choose univs: [x1 :: *] eq_spec: [] t_sub: {k1 |-> x1} r_sub: {x1 |-> x1} t_tvs: [k2, a, b] --> -- second branch of `case` statement choose univs: [k2 :: *, x1 :: *] eq_spec: [k2 ~ *] t_sub: {k1 |-> x1, k2 |-> k2} r_sub: {x1 |-> x1} t_tvs: [a, b] --> -- second branch of `case` statement choose univs: [a :: k2, k2 :: *, x1 :: *] eq_spec: [ a ~ (Proxy x1 y, z) , k2 ~ * ] t_sub: {k1 |-> x1, k2 |-> k2, a |-> a} r_sub: {x1 |-> x1} t_tvs: [b] --> -- second branch of `case` statement choose univs: [b :: k2, a :: k2, k2 :: *, x1 :: *] eq_spec: [ b ~ z , a ~ (Proxy x1 y, z) , k2 ~ * ] t_sub: {k1 |-> x1, k2 |-> k2, a |-> a, b |-> z} r_sub: {x1 |-> x1} t_tvs: [] --> -- end of recursion ( [x1 :: *, k2 :: *, a :: k2, b :: k2] , [k2 ~ *, a ~ (Proxy x1 y, z), b ~ z] , {x1 |-> x1} ) `choose` looks up each tycon tyvar in the matching (it *must* be matched!). * If it finds a bare result tyvar (the first branch of the `case` statement), it checks to make sure that the result tyvar isn't yet in the list of univ_tvs. If it is in that list, then we have a repeated variable in the return type, and we in fact need a GADT equality. * It then checks to make sure that the kind of the result tyvar matches the kind of the template tyvar. This check is what forces `z` to be existential, as it should be, explained above. * Assuming no repeated variables or kind-changing, we wish to use the variable name given in the datacon signature (that is, `x1` not `k1`), not the tycon signature (which may have been made up by GHC). So, we add a mapping from the tycon tyvar to the result tyvar to t_sub. * If we discover that a mapping in `subst` gives us a non-tyvar (the second branch of the `case` statement), then we have a GADT equality to create. We create a fresh equality, but we don't extend any substitutions. The template variable substitution is meant for use in universal tyvar kinds, and these shouldn't be affected by any GADT equalities. This whole algorithm is quite delicate, indeed. I (Richard E.) see two ways of simplifying it: 1) The first branch of the `case` statement is really an optimization, used in order to get fewer GADT equalities. It might be possible to make a GADT equality for *every* univ. tyvar, even if the equality is trivial, and then either deal with the bigger type or somehow reduce it later. 2) This algorithm strives to use the names for type variables as specified by the user in the datacon signature. If we always used the tycon tyvar names, for example, this would be simplified. This change would almost certainly degrade error messages a bit, though. -} -- ^ From information about a source datacon definition, extract out -- what the universal variables and the GADT equalities should be. -- See Note [mkGADTVars]. mkGADTVars :: [TyVar] -- ^ The tycon vars -> [TyVar] -- ^ The datacon vars -> TCvSubst -- ^ The matching between the template result type -- and the actual result type -> ( [TyVar] , [EqSpec] , TCvSubst ) -- ^ The univ. variables, the GADT equalities, -- and a subst to apply to the GADT equalities -- and existentials. mkGADTVars tmpl_tvs dc_tvs subst = choose [] [] empty_subst empty_subst tmpl_tvs where in_scope = mkInScopeSet (mkVarSet tmpl_tvs `unionVarSet` mkVarSet dc_tvs) `unionInScope` getTCvInScope subst empty_subst = mkEmptyTCvSubst in_scope choose :: [TyVar] -- accumulator of univ tvs, reversed -> [EqSpec] -- accumulator of GADT equalities, reversed -> TCvSubst -- template substitution -> TCvSubst -- res. substitution -> [TyVar] -- template tvs (the univ tvs passed in) -> ( [TyVar] -- the univ_tvs , [EqSpec] -- GADT equalities , TCvSubst ) -- a substitution to fix kinds in ex_tvs choose univs eqs _t_sub r_sub [] = (reverse univs, reverse eqs, r_sub) choose univs eqs t_sub r_sub (t_tv:t_tvs) | Just r_ty <- lookupTyVar subst t_tv = case getTyVar_maybe r_ty of Just r_tv | not (r_tv `elem` univs) , tyVarKind r_tv `eqType` (substTy t_sub (tyVarKind t_tv)) -> -- simple, well-kinded variable substitution. choose (r_tv:univs) eqs (extendTvSubst t_sub t_tv r_ty') (extendTvSubst r_sub r_tv r_ty') t_tvs where r_tv1 = setTyVarName r_tv (choose_tv_name r_tv t_tv) r_ty' = mkTyVarTy r_tv1 -- Not a simple substitution: make an equality predicate _ -> choose (t_tv':univs) (mkEqSpec t_tv' r_ty : eqs) (extendTvSubst t_sub t_tv (mkTyVarTy t_tv')) -- We've updated the kind of t_tv, -- so add it to t_sub (#14162) r_sub t_tvs where t_tv' = updateTyVarKind (substTy t_sub) t_tv | otherwise = pprPanic "mkGADTVars" (ppr tmpl_tvs $$ ppr subst) -- choose an appropriate name for a univ tyvar. -- This *must* preserve the Unique of the result tv, so that we -- can detect repeated variables. It prefers user-specified names -- over system names. A result variable with a system name can -- happen with GHC-generated implicit kind variables. choose_tv_name :: TyVar -> TyVar -> Name choose_tv_name r_tv t_tv | isSystemName r_tv_name = setNameUnique t_tv_name (getUnique r_tv_name) | otherwise = r_tv_name where r_tv_name = getName r_tv t_tv_name = getName t_tv {- Note [Substitution in template variables kinds] ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ data G (a :: Maybe k) where MkG :: G Nothing With explicit kind variables data G k (a :: Maybe k) where MkG :: G k1 (Nothing k1) Note how k1 is distinct from k. So, when we match the template `G k a` against `G k1 (Nothing k1)`, we get a subst [ k |-> k1, a |-> Nothing k1 ]. Even though this subst has two mappings, we surely don't want to add (k, k1) to the list of GADT equalities -- that would be overly complex and would create more untouchable variables than we need. So, when figuring out which tyvars are GADT-like and which aren't (the fundamental job of `choose`), we want to treat `k` as *not* GADT-like. Instead, we wish to substitute in `a`'s kind, to get (a :: Maybe k1) instead of (a :: Maybe k). This is the reason for dealing with a substitution in here. However, we do not *always* want to substitute. Consider data H (a :: k) where MkH :: H Int With explicit kind variables: data H k (a :: k) where MkH :: H * Int Here, we have a kind-indexed GADT. The subst in question is [ k |-> *, a |-> Int ]. Now, we *don't* want to substitute in `a`'s kind, because that would give a constructor with the type MkH :: forall (k :: *) (a :: *). (k ~ *) -> (a ~ Int) -> H k a The problem here is that a's kind is wrong -- it needs to be k, not *! So, if the matching for a variable is anything but another bare variable, we drop the mapping from the substitution before proceeding. This was not an issue before kind-indexed GADTs because this case could never happen. ************************************************************************ * * Validity checking * * ************************************************************************ Validity checking is done once the mutually-recursive knot has been tied, so we can look at things freely. -} checkValidTyCl :: TyCon -> TcM [TyCon] -- The returned list is either a singleton (if valid) -- or a list of "fake tycons" (if not); the fake tycons -- include any implicits, like promoted data constructors -- See Note [Recover from validity error] checkValidTyCl tc = setSrcSpan (getSrcSpan tc) $ addTyConCtxt tc $ recoverM recovery_code $ do { traceTc "Starting validity for tycon" (ppr tc) ; checkValidTyCon tc ; traceTc "Done validity for tycon" (ppr tc) ; return [tc] } where recovery_code -- See Note [Recover from validity error] = do { traceTc "Aborted validity for tycon" (ppr tc) ; return (concatMap mk_fake_tc $ ATyCon tc : implicitTyConThings tc) } mk_fake_tc (ATyCon tc) | isClassTyCon tc = [tc] -- Ugh! Note [Recover from validity error] | otherwise = [makeRecoveryTyCon tc] mk_fake_tc (AConLike (RealDataCon dc)) = [makeRecoveryTyCon (promoteDataCon dc)] mk_fake_tc _ = [] {- Note [Recover from validity error] ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ We recover from a validity error in a type or class, which allows us to report multiple validity errors. In the failure case we return a TyCon of the right kind, but with no interesting behaviour (makeRecoveryTyCon). Why? Suppose we have type T a = Fun where Fun is a type family of arity 1. The RHS is invalid, but we want to go on checking validity of subsequent type declarations. So we replace T with an abstract TyCon which will do no harm. See indexed-types/should_fail/BadSock and #10896 Some notes: * We must make fakes for promoted DataCons too. Consider (#15215) data T a = MkT ... data S a = ...T...MkT.... If there is an error in the definition of 'T' we add a "fake type constructor" to the type environment, so that we can continue to typecheck 'S'. But we /were not/ adding a fake anything for 'MkT' and so there was an internal error when we met 'MkT' in the body of 'S'. * Painfully, we *don't* want to do this for classes. Consider tcfail041: class (?x::Int) => C a where ... instance C Int The class is invalid because of the superclass constraint. But we still want it to look like a /class/, else the instance bleats that the instance is mal-formed because it hasn't got a class in the head. This is really bogus; now we have in scope a Class that is invalid in some way, with unknown downstream consequences. A better alternative might be to make a fake class TyCon. A job for another day. -} ------------------------- -- For data types declared with record syntax, we require -- that each constructor that has a field 'f' -- (a) has the same result type -- (b) has the same type for 'f' -- module alpha conversion of the quantified type variables -- of the constructor. -- -- Note that we allow existentials to match because the -- fields can never meet. E.g -- data T where -- T1 { f1 :: b, f2 :: a, f3 ::Int } :: T -- T2 { f1 :: c, f2 :: c, f3 ::Int } :: T -- Here we do not complain about f1,f2 because they are existential checkValidTyCon :: TyCon -> TcM () checkValidTyCon tc | isPrimTyCon tc -- Happens when Haddock'ing GHC.Prim = return () | isWiredIn tc -- validity-checking wired-in tycons is a waste of -- time. More importantly, a wired-in tycon might -- violate assumptions. Example: (~) has a superclass -- mentioning (~#), which is ill-kinded in source Haskell = traceTc "Skipping validity check for wired-in" (ppr tc) | otherwise = do { traceTc "checkValidTyCon" (ppr tc $$ ppr (tyConClass_maybe tc)) ; if | Just cl <- tyConClass_maybe tc -> checkValidClass cl | Just syn_rhs <- synTyConRhs_maybe tc -> do { checkValidType syn_ctxt syn_rhs ; checkTySynRhs syn_ctxt syn_rhs } | Just fam_flav <- famTyConFlav_maybe tc -> case fam_flav of { ClosedSynFamilyTyCon (Just ax) -> tcAddClosedTypeFamilyDeclCtxt tc $ checkValidCoAxiom ax ; ClosedSynFamilyTyCon Nothing -> return () ; AbstractClosedSynFamilyTyCon -> do { hsBoot <- tcIsHsBootOrSig ; checkTc hsBoot $ text "You may define an abstract closed type family" $$ text "only in a .hs-boot file" } ; DataFamilyTyCon {} -> return () ; OpenSynFamilyTyCon -> return () ; BuiltInSynFamTyCon _ -> return () } | otherwise -> do { -- Check the context on the data decl traceTc "cvtc1" (ppr tc) ; checkValidTheta (DataTyCtxt name) (tyConStupidTheta tc) ; traceTc "cvtc2" (ppr tc) ; dflags <- getDynFlags ; existential_ok <- xoptM LangExt.ExistentialQuantification ; gadt_ok <- xoptM LangExt.GADTs ; let ex_ok = existential_ok || gadt_ok -- Data cons can have existential context ; mapM_ (checkValidDataCon dflags ex_ok tc) data_cons ; mapM_ (checkPartialRecordField data_cons) (tyConFieldLabels tc) -- Check that fields with the same name share a type ; mapM_ check_fields groups }} where syn_ctxt = TySynCtxt name name = tyConName tc data_cons = tyConDataCons tc groups = equivClasses cmp_fld (concatMap get_fields data_cons) cmp_fld (f1,_) (f2,_) = flLabel f1 `compare` flLabel f2 get_fields con = dataConFieldLabels con `zip` repeat con -- dataConFieldLabels may return the empty list, which is fine -- See Note [GADT record selectors] in GHC.Tc.TyCl.Utils -- We must check (a) that the named field has the same -- type in each constructor -- (b) that those constructors have the same result type -- -- However, the constructors may have differently named type variable -- and (worse) we don't know how the correspond to each other. E.g. -- C1 :: forall a b. { f :: a, g :: b } -> T a b -- C2 :: forall d c. { f :: c, g :: c } -> T c d -- -- So what we do is to ust Unify.tcMatchTys to compare the first candidate's -- result type against other candidates' types BOTH WAYS ROUND. -- If they magically agrees, take the substitution and -- apply them to the latter ones, and see if they match perfectly. check_fields ((label, con1) :| other_fields) -- These fields all have the same name, but are from -- different constructors in the data type = recoverM (return ()) $ mapM_ checkOne other_fields -- Check that all the fields in the group have the same type -- NB: this check assumes that all the constructors of a given -- data type use the same type variables where res1 = dataConOrigResTy con1 fty1 = dataConFieldType con1 lbl lbl = flLabel label checkOne (_, con2) -- Do it both ways to ensure they are structurally identical = do { checkFieldCompat lbl con1 con2 res1 res2 fty1 fty2 ; checkFieldCompat lbl con2 con1 res2 res1 fty2 fty1 } where res2 = dataConOrigResTy con2 fty2 = dataConFieldType con2 lbl checkPartialRecordField :: [DataCon] -> FieldLabel -> TcM () -- Checks the partial record field selector, and warns. -- See Note [Checking partial record field] checkPartialRecordField all_cons fld = setSrcSpan loc $ warnIfFlag Opt_WarnPartialFields (not is_exhaustive && not (startsWithUnderscore occ_name)) (sep [text "Use of partial record field selector" <> colon, nest 2 $ quotes (ppr occ_name)]) where sel_name = flSelector fld loc = getSrcSpan sel_name occ_name = getOccName sel_name (cons_with_field, cons_without_field) = partition has_field all_cons has_field con = fld `elem` (dataConFieldLabels con) is_exhaustive = all (dataConCannotMatch inst_tys) cons_without_field con1 = ASSERT( not (null cons_with_field) ) head cons_with_field (univ_tvs, _, eq_spec, _, _, _) = dataConFullSig con1 eq_subst = mkTvSubstPrs (map eqSpecPair eq_spec) inst_tys = substTyVars eq_subst univ_tvs checkFieldCompat :: FieldLabelString -> DataCon -> DataCon -> Type -> Type -> Type -> Type -> TcM () checkFieldCompat fld con1 con2 res1 res2 fty1 fty2 = do { checkTc (isJust mb_subst1) (resultTypeMisMatch fld con1 con2) ; checkTc (isJust mb_subst2) (fieldTypeMisMatch fld con1 con2) } where mb_subst1 = tcMatchTy res1 res2 mb_subst2 = tcMatchTyX (expectJust "checkFieldCompat" mb_subst1) fty1 fty2 ------------------------------- checkValidDataCon :: DynFlags -> Bool -> TyCon -> DataCon -> TcM () checkValidDataCon dflags existential_ok tc con = setSrcSpan (getSrcSpan con) $ addErrCtxt (dataConCtxt con) $ do { -- Check that the return type of the data constructor -- matches the type constructor; eg reject this: -- data T a where { MkT :: Bogus a } -- It's important to do this first: -- see Note [Checking GADT return types] -- and c.f. Note [Check role annotations in a second pass] let tc_tvs = tyConTyVars tc res_ty_tmpl = mkFamilyTyConApp tc (mkTyVarTys tc_tvs) orig_res_ty = dataConOrigResTy con ; traceTc "checkValidDataCon" (vcat [ ppr con, ppr tc, ppr tc_tvs , ppr res_ty_tmpl <+> dcolon <+> ppr (tcTypeKind res_ty_tmpl) , ppr orig_res_ty <+> dcolon <+> ppr (tcTypeKind orig_res_ty)]) ; checkTc (isJust (tcMatchTy res_ty_tmpl orig_res_ty)) (badDataConTyCon con res_ty_tmpl) -- Note that checkTc aborts if it finds an error. This is -- critical to avoid panicking when we call dataConDisplayType -- on an un-rejiggable datacon! ; traceTc "checkValidDataCon 2" (ppr data_con_display_type) -- Check that the result type is a *monotype* -- e.g. reject this: MkT :: T (forall a. a->a) -- Reason: it's really the argument of an equality constraint ; checkValidMonoType orig_res_ty -- If we are dealing with a newtype, we allow levity polymorphism -- regardless of whether or not UnliftedNewtypes is enabled. A -- later check in checkNewDataCon handles this, producing a -- better error message than checkForLevPoly would. ; unless (isNewTyCon tc) (mapM_ (checkForLevPoly empty) (map scaledThing $ dataConOrigArgTys con)) -- Extra checks for newtype data constructors. Importantly, these -- checks /must/ come before the call to checkValidType below. This -- is because checkValidType invokes the constraint solver, and -- invoking the solver on an ill formed newtype constructor can -- confuse GHC to the point of panicking. See #17955 for an example. ; when (isNewTyCon tc) (checkNewDataCon con) -- Check all argument types for validity ; checkValidType ctxt data_con_display_type -- Check that existentials are allowed if they are used ; checkTc (existential_ok || isVanillaDataCon con) (badExistential con) -- Check that UNPACK pragmas and bangs work out -- E.g. reject data T = MkT {-# UNPACK #-} Int -- No "!" -- data T = MkT {-# UNPACK #-} !a -- Can't unpack ; zipWith3M_ check_bang (dataConSrcBangs con) (dataConImplBangs con) [1..] -- Check the dcUserTyVarBinders invariant -- See Note [DataCon user type variable binders] in GHC.Core.DataCon -- checked here because we sometimes build invalid DataCons before -- erroring above here ; when debugIsOn $ do { let (univs, exs, eq_spec, _, _, _) = dataConFullSig con user_tvs = dataConUserTyVars con user_tvbs_invariant = Set.fromList (filterEqSpec eq_spec univs ++ exs) == Set.fromList user_tvs ; MASSERT2( user_tvbs_invariant , vcat ([ ppr con , ppr univs , ppr exs , ppr eq_spec , ppr user_tvs ])) } ; traceTc "Done validity of data con" $ vcat [ ppr con , text "Datacon wrapper type:" <+> ppr (dataConWrapperType con) , text "Datacon rep type:" <+> ppr (dataConRepType con) , text "Datacon display type:" <+> ppr data_con_display_type , text "Rep typcon binders:" <+> ppr (tyConBinders (dataConTyCon con)) , case tyConFamInst_maybe (dataConTyCon con) of Nothing -> text "not family" Just (f, _) -> ppr (tyConBinders f) ] } where ctxt = ConArgCtxt (dataConName con) check_bang :: HsSrcBang -> HsImplBang -> Int -> TcM () check_bang (HsSrcBang _ _ SrcLazy) _ n | not (xopt LangExt.StrictData dflags) = addErrTc (bad_bang n (text "Lazy annotation (~) without StrictData")) check_bang (HsSrcBang _ want_unpack strict_mark) rep_bang n | isSrcUnpacked want_unpack, not is_strict = addWarnTc NoReason (bad_bang n (text "UNPACK pragma lacks '!'")) | isSrcUnpacked want_unpack , case rep_bang of { HsUnpack {} -> False; _ -> True } -- If not optimising, we don't unpack (rep_bang is never -- HsUnpack), so don't complain! This happens, e.g., in Haddock. -- See dataConSrcToImplBang. , not (gopt Opt_OmitInterfacePragmas dflags) -- When typechecking an indefinite package in Backpack, we -- may attempt to UNPACK an abstract type. The test here will -- conclude that this is unusable, but it might become usable -- when we actually fill in the abstract type. As such, don't -- warn in this case (it gives users the wrong idea about whether -- or not UNPACK on abstract types is supported; it is!) , homeUnitIsDefinite dflags = addWarnTc NoReason (bad_bang n (text "Ignoring unusable UNPACK pragma")) where is_strict = case strict_mark of NoSrcStrict -> xopt LangExt.StrictData dflags bang -> isSrcStrict bang check_bang _ _ _ = return () bad_bang n herald = hang herald 2 (text "on the" <+> speakNth n <+> text "argument of" <+> quotes (ppr con)) data_con_display_type = dataConDisplayType dflags con ------------------------------- checkNewDataCon :: DataCon -> TcM () -- Further checks for the data constructor of a newtype checkNewDataCon con = do { checkTc (isSingleton arg_tys) (newtypeFieldErr con (length arg_tys)) -- One argument ; unlifted_newtypes <- xoptM LangExt.UnliftedNewtypes ; let allowedArgType = unlifted_newtypes || isLiftedType_maybe (scaledThing arg_ty1) == Just True ; checkTc allowedArgType $ vcat [ text "A newtype cannot have an unlifted argument type" , text "Perhaps you intended to use UnliftedNewtypes" ] ; dflags <- getDynFlags ; let check_con what msg = checkTc what (msg $$ ppr con <+> dcolon <+> ppr (dataConDisplayType dflags con)) ; checkTc (ok_mult (scaledMult arg_ty1)) $ text "A newtype constructor must be linear" ; check_con (null eq_spec) $ text "A newtype constructor must have a return type of form T a1 ... an" -- Return type is (T a b c) ; check_con (null theta) $ text "A newtype constructor cannot have a context in its type" ; check_con (null ex_tvs) $ text "A newtype constructor cannot have existential type variables" -- No existentials ; checkTc (all ok_bang (dataConSrcBangs con)) (newtypeStrictError con) -- No strictness annotations } where (_univ_tvs, ex_tvs, eq_spec, theta, arg_tys, _res_ty) = dataConFullSig con (arg_ty1 : _) = arg_tys ok_bang (HsSrcBang _ _ SrcStrict) = False ok_bang (HsSrcBang _ _ SrcLazy) = False ok_bang _ = True ok_mult One = True ok_mult _ = False ------------------------------- checkValidClass :: Class -> TcM () checkValidClass cls = do { constrained_class_methods <- xoptM LangExt.ConstrainedClassMethods ; multi_param_type_classes <- xoptM LangExt.MultiParamTypeClasses ; nullary_type_classes <- xoptM LangExt.NullaryTypeClasses ; fundep_classes <- xoptM LangExt.FunctionalDependencies ; undecidable_super_classes <- xoptM LangExt.UndecidableSuperClasses -- Check that the class is unary, unless multiparameter type classes -- are enabled; also recognize deprecated nullary type classes -- extension (subsumed by multiparameter type classes, #8993) ; checkTc (multi_param_type_classes || cls_arity == 1 || (nullary_type_classes && cls_arity == 0)) (classArityErr cls_arity cls) ; checkTc (fundep_classes || null fundeps) (classFunDepsErr cls) -- Check the super-classes ; checkValidTheta (ClassSCCtxt (className cls)) theta -- Now check for cyclic superclasses -- If there are superclass cycles, checkClassCycleErrs bails. ; unless undecidable_super_classes $ case checkClassCycles cls of Just err -> setSrcSpan (getSrcSpan cls) $ addErrTc err Nothing -> return () -- Check the class operations. -- But only if there have been no earlier errors -- See Note [Abort when superclass cycle is detected] ; whenNoErrs $ mapM_ (check_op constrained_class_methods) op_stuff -- Check the associated type defaults are well-formed and instantiated ; mapM_ check_at at_stuff } where (tyvars, fundeps, theta, _, at_stuff, op_stuff) = classExtraBigSig cls cls_arity = length (tyConVisibleTyVars (classTyCon cls)) -- Ignore invisible variables cls_tv_set = mkVarSet tyvars check_op constrained_class_methods (sel_id, dm) = setSrcSpan (getSrcSpan sel_id) $ addErrCtxt (classOpCtxt sel_id op_ty) $ do { traceTc "class op type" (ppr op_ty) ; checkValidType ctxt op_ty -- This implements the ambiguity check, among other things -- Example: tc223 -- class Error e => Game b mv e | b -> mv e where -- newBoard :: MonadState b m => m () -- Here, MonadState has a fundep m->b, so newBoard is fine -- a method cannot be levity polymorphic, as we have to store the -- method in a dictionary -- example of what this prevents: -- class BoundedX (a :: TYPE r) where minBound :: a -- See Note [Levity polymorphism checking] in GHC.HsToCore.Monad ; checkForLevPoly empty tau1 ; unless constrained_class_methods $ mapM_ check_constraint (tail (cls_pred:op_theta)) ; check_dm ctxt sel_id cls_pred tau2 dm } where ctxt = FunSigCtxt op_name True -- Report redundant class constraints op_name = idName sel_id op_ty = idType sel_id (_,cls_pred,tau1) = tcSplitMethodTy op_ty -- See Note [Splitting nested sigma types in class type signatures] (_,op_theta,tau2) = tcSplitNestedSigmaTys tau1 check_constraint :: TcPredType -> TcM () check_constraint pred -- See Note [Class method constraints] = when (not (isEmptyVarSet pred_tvs) && pred_tvs `subVarSet` cls_tv_set) (addErrTc (badMethPred sel_id pred)) where pred_tvs = tyCoVarsOfType pred check_at (ATI fam_tc m_dflt_rhs) = do { checkTc (cls_arity == 0 || any (`elemVarSet` cls_tv_set) fam_tvs) (noClassTyVarErr cls fam_tc) -- Check that the associated type mentions at least -- one of the class type variables -- The check is disabled for nullary type classes, -- since there is no possible ambiguity (#10020) -- Check that any default declarations for associated types are valid ; whenIsJust m_dflt_rhs $ \ (rhs, loc) -> setSrcSpan loc $ tcAddFamInstCtxt (text "default type instance") (getName fam_tc) $ checkValidTyFamEqn fam_tc fam_tvs (mkTyVarTys fam_tvs) rhs } where fam_tvs = tyConTyVars fam_tc check_dm :: UserTypeCtxt -> Id -> PredType -> Type -> DefMethInfo -> TcM () -- Check validity of the /top-level/ generic-default type -- E.g for class C a where -- default op :: forall b. (a~b) => blah -- we do not want to do an ambiguity check on a type with -- a free TyVar 'a' (#11608). See TcType -- Note [TyVars and TcTyVars during type checking] in GHC.Tc.Utils.TcType -- Hence the mkDefaultMethodType to close the type. check_dm ctxt sel_id vanilla_cls_pred vanilla_tau (Just (dm_name, dm_spec@(GenericDM dm_ty))) = setSrcSpan (getSrcSpan dm_name) $ do -- We have carefully set the SrcSpan on the generic -- default-method Name to be that of the generic -- default type signature -- First, we check that that the method's default type signature -- aligns with the non-default type signature. -- See Note [Default method type signatures must align] let cls_pred = mkClassPred cls $ mkTyVarTys $ classTyVars cls -- Note that the second field of this tuple contains the context -- of the default type signature, making it apparent that we -- ignore method contexts completely when validity-checking -- default type signatures. See the end of -- Note [Default method type signatures must align] -- to learn why this is OK. -- -- See also -- Note [Splitting nested sigma types in class type signatures] -- for an explanation of why we don't use tcSplitSigmaTy here. (_, _, dm_tau) = tcSplitNestedSigmaTys dm_ty -- Given this class definition: -- -- class C a b where -- op :: forall p q. (Ord a, D p q) -- => a -> b -> p -> (a, b) -- default op :: forall r s. E r -- => a -> b -> s -> (a, b) -- -- We want to match up two types of the form: -- -- Vanilla type sig: C aa bb => aa -> bb -> p -> (aa, bb) -- Default type sig: C a b => a -> b -> s -> (a, b) -- -- Notice that the two type signatures can be quantified over -- different class type variables! Therefore, it's important that -- we include the class predicate parts to match up a with aa and -- b with bb. vanilla_phi_ty = mkPhiTy [vanilla_cls_pred] vanilla_tau dm_phi_ty = mkPhiTy [cls_pred] dm_tau traceTc "check_dm" $ vcat [ text "vanilla_phi_ty" <+> ppr vanilla_phi_ty , text "dm_phi_ty" <+> ppr dm_phi_ty ] -- Actually checking that the types align is done with a call to -- tcMatchTys. We need to get a match in both directions to rule -- out degenerate cases like these: -- -- class Foo a where -- foo1 :: a -> b -- default foo1 :: a -> Int -- -- foo2 :: a -> Int -- default foo2 :: a -> b unless (isJust $ tcMatchTys [dm_phi_ty, vanilla_phi_ty] [vanilla_phi_ty, dm_phi_ty]) $ addErrTc $ hang (text "The default type signature for" <+> ppr sel_id <> colon) 2 (ppr dm_ty) $$ (text "does not match its corresponding" <+> text "non-default type signature") -- Now do an ambiguity check on the default type signature. checkValidType ctxt (mkDefaultMethodType cls sel_id dm_spec) check_dm _ _ _ _ _ = return () checkFamFlag :: Name -> TcM () -- Check that we don't use families without -XTypeFamilies -- The parser won't even parse them, but I suppose a GHC API -- client might have a go! checkFamFlag tc_name = do { idx_tys <- xoptM LangExt.TypeFamilies ; checkTc idx_tys err_msg } where err_msg = hang (text "Illegal family declaration for" <+> quotes (ppr tc_name)) 2 (text "Enable TypeFamilies to allow indexed type families") checkResultSigFlag :: Name -> FamilyResultSig GhcRn -> TcM () checkResultSigFlag tc_name (TyVarSig _ tvb) = do { ty_fam_deps <- xoptM LangExt.TypeFamilyDependencies ; checkTc ty_fam_deps $ hang (text "Illegal result type variable" <+> ppr tvb <+> text "for" <+> quotes (ppr tc_name)) 2 (text "Enable TypeFamilyDependencies to allow result variable names") } checkResultSigFlag _ _ = return () -- other cases OK {- Note [Class method constraints] ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ Haskell 2010 is supposed to reject class C a where op :: Eq a => a -> a where the method type constrains only the class variable(s). (The extension -XConstrainedClassMethods switches off this check.) But regardless we should not reject class C a where op :: (?x::Int) => a -> a as pointed out in #11793. So the test here rejects the program if * -XConstrainedClassMethods is off * the tyvars of the constraint are non-empty * all the tyvars are class tyvars, none are locally quantified Note [Abort when superclass cycle is detected] ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ We must avoid doing the ambiguity check for the methods (in checkValidClass.check_op) when there are already errors accumulated. This is because one of the errors may be a superclass cycle, and superclass cycles cause canonicalization to loop. Here is a representative example: class D a => C a where meth :: D a => () class C a => D a This fixes #9415, #9739 Note [Default method type signatures must align] ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ GHC enforces the invariant that a class method's default type signature must "align" with that of the method's non-default type signature, as per GHC #12918. For instance, if you have: class Foo a where bar :: forall b. Context => a -> b Then a default type signature for bar must be alpha equivalent to (forall b. a -> b). That is, the types must be the same modulo differences in contexts. So the following would be acceptable default type signatures: default bar :: forall b. Context1 => a -> b default bar :: forall x. Context2 => a -> x But the following are NOT acceptable default type signatures: default bar :: forall b. b -> a default bar :: forall x. x default bar :: a -> Int Note that a is bound by the class declaration for Foo itself, so it is not allowed to differ in the default type signature. The default type signature (default bar :: a -> Int) deserves special mention, since (a -> Int) is a straightforward instantiation of (forall b. a -> b). To write this, you need to declare the default type signature like so: default bar :: forall b. (b ~ Int). a -> b As noted in #12918, there are several reasons to do this: 1. It would make no sense to have a type that was flat-out incompatible with the non-default type signature. For instance, if you had: class Foo a where bar :: a -> Int default bar :: a -> Bool Then that would always fail in an instance declaration. So this check nips such cases in the bud before they have the chance to produce confusing error messages. 2. Internally, GHC uses TypeApplications to instantiate the default method in an instance. See Note [Default methods in instances] in GHC.Tc.TyCl.Instance. Thus, GHC needs to know exactly what the universally quantified type variables are, and when instantiated that way, the default method's type must match the expected type. 3. Aesthetically, by only allowing the default type signature to differ in its context, we are making it more explicit the ways in which the default type signature is less polymorphic than the non-default type signature. You might be wondering: why are the contexts allowed to be different, but not the rest of the type signature? That's because default implementations often rely on assumptions that the more general, non-default type signatures do not. For instance, in the Enum class declaration: class Enum a where enum :: [a] default enum :: (Generic a, GEnum (Rep a)) => [a] enum = map to genum class GEnum f where genum :: [f a] The default implementation for enum only works for types that are instances of Generic, and for which their generic Rep type is an instance of GEnum. But clearly enum doesn't _have_ to use this implementation, so naturally, the context for enum is allowed to be different to accommodate this. As a result, when we validity-check default type signatures, we ignore contexts completely. Note that when checking whether two type signatures match, we must take care to split as many foralls as it takes to retrieve the tau types we which to check. See Note [Splitting nested sigma types in class type signatures]. Note [Splitting nested sigma types in class type signatures] ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ Consider this type synonym and class definition: type Traversal s t a b = forall f. Applicative f => (a -> f b) -> s -> f t class Each s t a b where each :: Traversal s t a b default each :: (Traversable g, s ~ g a, t ~ g b) => Traversal s t a b It might seem obvious that the tau types in both type signatures for `each` are the same, but actually getting GHC to conclude this is surprisingly tricky. That is because in general, the form of a class method's non-default type signature is: forall a. C a => forall d. D d => E a b And the general form of a default type signature is: forall f. F f => E a f -- The variable `a` comes from the class So it you want to get the tau types in each type signature, you might find it reasonable to call tcSplitSigmaTy twice on the non-default type signature, and call it once on the default type signature. For most classes and methods, this will work, but Each is a bit of an exceptional case. The way `each` is written, it doesn't quantify any additional type variables besides those of the Each class itself, so the non-default type signature for `each` is actually this: forall s t a b. Each s t a b => Traversal s t a b Notice that there _appears_ to only be one forall. But there's actually another forall lurking in the Traversal type synonym, so if you call tcSplitSigmaTy twice, you'll also go under the forall in Traversal! That is, you'll end up with: (a -> f b) -> s -> f t A problem arises because you only call tcSplitSigmaTy once on the default type signature for `each`, which gives you Traversal s t a b Or, equivalently: forall f. Applicative f => (a -> f b) -> s -> f t This is _not_ the same thing as (a -> f b) -> s -> f t! So now tcMatchTy will say that the tau types for `each` are not equal. A solution to this problem is to use tcSplitNestedSigmaTys instead of tcSplitSigmaTy. tcSplitNestedSigmaTys will always split any foralls that it sees until it can't go any further, so if you called it on the default type signature for `each`, it would return (a -> f b) -> s -> f t like we desired. Note [Checking partial record field] ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ This check checks the partial record field selector, and warns (#7169). For example: data T a = A { m1 :: a, m2 :: a } | B { m1 :: a } The function 'm2' is partial record field, and will fail when it is applied to 'B'. The warning identifies such partial fields. The check is performed at the declaration of T, not at the call-sites of m2. The warning can be suppressed by prefixing the field-name with an underscore. For example: data T a = A { m1 :: a, _m2 :: a } | B { m1 :: a } ************************************************************************ * * Checking role validity * * ************************************************************************ -} checkValidRoleAnnots :: RoleAnnotEnv -> TyCon -> TcM () checkValidRoleAnnots role_annots tc | isTypeSynonymTyCon tc = check_no_roles | isFamilyTyCon tc = check_no_roles | isAlgTyCon tc = check_roles | otherwise = return () where -- Role annotations are given only on *explicit* variables, -- but a tycon stores roles for all variables. -- So, we drop the implicit roles (which are all Nominal, anyway). name = tyConName tc roles = tyConRoles tc (vis_roles, vis_vars) = unzip $ mapMaybe pick_vis $ zip roles (tyConBinders tc) role_annot_decl_maybe = lookupRoleAnnot role_annots name pick_vis :: (Role, TyConBinder) -> Maybe (Role, TyVar) pick_vis (role, tvb) | isVisibleTyConBinder tvb = Just (role, binderVar tvb) | otherwise = Nothing check_roles = whenIsJust role_annot_decl_maybe $ \decl@(L loc (RoleAnnotDecl _ _ the_role_annots)) -> addRoleAnnotCtxt name $ setSrcSpan loc $ do { role_annots_ok <- xoptM LangExt.RoleAnnotations ; checkTc role_annots_ok $ needXRoleAnnotations tc ; checkTc (vis_vars `equalLength` the_role_annots) (wrongNumberOfRoles vis_vars decl) ; _ <- zipWith3M checkRoleAnnot vis_vars the_role_annots vis_roles -- Representational or phantom roles for class parameters -- quickly lead to incoherence. So, we require -- IncoherentInstances to have them. See #8773, #14292 ; incoherent_roles_ok <- xoptM LangExt.IncoherentInstances ; checkTc ( incoherent_roles_ok || (not $ isClassTyCon tc) || (all (== Nominal) vis_roles)) incoherentRoles ; lint <- goptM Opt_DoCoreLinting ; when lint $ checkValidRoles tc } check_no_roles = whenIsJust role_annot_decl_maybe illegalRoleAnnotDecl checkRoleAnnot :: TyVar -> Located (Maybe Role) -> Role -> TcM () checkRoleAnnot _ (L _ Nothing) _ = return () checkRoleAnnot tv (L _ (Just r1)) r2 = when (r1 /= r2) $ addErrTc $ badRoleAnnot (tyVarName tv) r1 r2 -- This is a double-check on the role inference algorithm. It is only run when -- -dcore-lint is enabled. See Note [Role inference] in GHC.Tc.TyCl.Utils checkValidRoles :: TyCon -> TcM () -- If you edit this function, you may need to update the GHC formalism -- See Note [GHC Formalism] in GHC.Core.Lint checkValidRoles tc | isAlgTyCon tc -- tyConDataCons returns an empty list for data families = mapM_ check_dc_roles (tyConDataCons tc) | Just rhs <- synTyConRhs_maybe tc = check_ty_roles (zipVarEnv (tyConTyVars tc) (tyConRoles tc)) Representational rhs | otherwise = return () where check_dc_roles datacon = do { traceTc "check_dc_roles" (ppr datacon <+> ppr (tyConRoles tc)) ; mapM_ (check_ty_roles role_env Representational) $ eqSpecPreds eq_spec ++ theta ++ (map scaledThing arg_tys) } -- See Note [Role-checking data constructor arguments] in GHC.Tc.TyCl.Utils where (univ_tvs, ex_tvs, eq_spec, theta, arg_tys, _res_ty) = dataConFullSig datacon univ_roles = zipVarEnv univ_tvs (tyConRoles tc) -- zipVarEnv uses zipEqual, but we don't want that for ex_tvs ex_roles = mkVarEnv (map (, Nominal) ex_tvs) role_env = univ_roles `plusVarEnv` ex_roles check_ty_roles env role ty | Just ty' <- coreView ty -- #14101 = check_ty_roles env role ty' check_ty_roles env role (TyVarTy tv) = case lookupVarEnv env tv of Just role' -> unless (role' `ltRole` role || role' == role) $ report_error $ text "type variable" <+> quotes (ppr tv) <+> text "cannot have role" <+> ppr role <+> text "because it was assigned role" <+> ppr role' Nothing -> report_error $ text "type variable" <+> quotes (ppr tv) <+> text "missing in environment" check_ty_roles env Representational (TyConApp tc tys) = let roles' = tyConRoles tc in zipWithM_ (maybe_check_ty_roles env) roles' tys check_ty_roles env Nominal (TyConApp _ tys) = mapM_ (check_ty_roles env Nominal) tys check_ty_roles _ Phantom ty@(TyConApp {}) = pprPanic "check_ty_roles" (ppr ty) check_ty_roles env role (AppTy ty1 ty2) = check_ty_roles env role ty1 >> check_ty_roles env Nominal ty2 check_ty_roles env role (FunTy _ w ty1 ty2) = check_ty_roles env Nominal w >> check_ty_roles env role ty1 >> check_ty_roles env role ty2 check_ty_roles env role (ForAllTy (Bndr tv _) ty) = check_ty_roles env Nominal (tyVarKind tv) >> check_ty_roles (extendVarEnv env tv Nominal) role ty check_ty_roles _ _ (LitTy {}) = return () check_ty_roles env role (CastTy t _) = check_ty_roles env role t check_ty_roles _ role (CoercionTy co) = unless (role == Phantom) $ report_error $ text "coercion" <+> ppr co <+> text "has bad role" <+> ppr role maybe_check_ty_roles env role ty = when (role == Nominal || role == Representational) $ check_ty_roles env role ty report_error doc = addErrTc $ vcat [text "Internal error in role inference:", doc, text "Please report this as a GHC bug: https://www.haskell.org/ghc/reportabug"] {- ************************************************************************ * * Error messages * * ************************************************************************ -} tcMkDeclCtxt :: TyClDecl GhcRn -> SDoc tcMkDeclCtxt decl = hsep [text "In the", pprTyClDeclFlavour decl, text "declaration for", quotes (ppr (tcdName decl))] addVDQNote :: TcTyCon -> TcM a -> TcM a -- See Note [Inferring visible dependent quantification] -- Only types without a signature (CUSK or SAK) here addVDQNote tycon thing_inside | ASSERT2( isTcTyCon tycon, ppr tycon ) ASSERT2( not (tcTyConIsPoly tycon), ppr tycon $$ ppr tc_kind ) has_vdq = addLandmarkErrCtxt vdq_warning thing_inside | otherwise = thing_inside where -- Check whether a tycon has visible dependent quantification. -- This will *always* be a TcTyCon. Furthermore, it will *always* -- be an ungeneralised TcTyCon, straight out of kcInferDeclHeader. -- Thus, all the TyConBinders will be anonymous. Thus, the -- free variables of the tycon's kind will be the same as the free -- variables from all the binders. has_vdq = any is_vdq_tcb (tyConBinders tycon) tc_kind = tyConKind tycon kind_fvs = tyCoVarsOfType tc_kind is_vdq_tcb tcb = (binderVar tcb `elemVarSet` kind_fvs) && isVisibleTyConBinder tcb vdq_warning = vcat [ text "NB: Type" <+> quotes (ppr tycon) <+> text "was inferred to use visible dependent quantification." , text "Most types with visible dependent quantification are" , text "polymorphically recursive and need a standalone kind" , text "signature. Perhaps supply one, with StandaloneKindSignatures." ] tcAddDeclCtxt :: TyClDecl GhcRn -> TcM a -> TcM a tcAddDeclCtxt decl thing_inside = addErrCtxt (tcMkDeclCtxt decl) thing_inside tcAddTyFamInstCtxt :: TyFamInstDecl GhcRn -> TcM a -> TcM a tcAddTyFamInstCtxt decl = tcAddFamInstCtxt (text "type instance") (tyFamInstDeclName decl) tcMkDataFamInstCtxt :: DataFamInstDecl GhcRn -> SDoc tcMkDataFamInstCtxt decl@(DataFamInstDecl { dfid_eqn = HsIB { hsib_body = eqn }}) = tcMkFamInstCtxt (pprDataFamInstFlavour decl <+> text "instance") (unLoc (feqn_tycon eqn)) tcAddDataFamInstCtxt :: DataFamInstDecl GhcRn -> TcM a -> TcM a tcAddDataFamInstCtxt decl = addErrCtxt (tcMkDataFamInstCtxt decl) tcMkFamInstCtxt :: SDoc -> Name -> SDoc tcMkFamInstCtxt flavour tycon = hsep [ text "In the" <+> flavour <+> text "declaration for" , quotes (ppr tycon) ] tcAddFamInstCtxt :: SDoc -> Name -> TcM a -> TcM a tcAddFamInstCtxt flavour tycon thing_inside = addErrCtxt (tcMkFamInstCtxt flavour tycon) thing_inside tcAddClosedTypeFamilyDeclCtxt :: TyCon -> TcM a -> TcM a tcAddClosedTypeFamilyDeclCtxt tc = addErrCtxt ctxt where ctxt = text "In the equations for closed type family" <+> quotes (ppr tc) resultTypeMisMatch :: FieldLabelString -> DataCon -> DataCon -> SDoc resultTypeMisMatch field_name con1 con2 = vcat [sep [text "Constructors" <+> ppr con1 <+> text "and" <+> ppr con2, text "have a common field" <+> quotes (ppr field_name) <> comma], nest 2 $ text "but have different result types"] fieldTypeMisMatch :: FieldLabelString -> DataCon -> DataCon -> SDoc fieldTypeMisMatch field_name con1 con2 = sep [text "Constructors" <+> ppr con1 <+> text "and" <+> ppr con2, text "give different types for field", quotes (ppr field_name)] dataConCtxtName :: [Located Name] -> SDoc dataConCtxtName [con] = text "In the definition of data constructor" <+> quotes (ppr con) dataConCtxtName con = text "In the definition of data constructors" <+> interpp'SP con dataConCtxt :: Outputable a => a -> SDoc dataConCtxt con = text "In the definition of data constructor" <+> quotes (ppr con) classOpCtxt :: Var -> Type -> SDoc classOpCtxt sel_id tau = sep [text "When checking the class method:", nest 2 (pprPrefixOcc sel_id <+> dcolon <+> ppr tau)] classArityErr :: Int -> Class -> SDoc classArityErr n cls | n == 0 = mkErr "No" "no-parameter" | otherwise = mkErr "Too many" "multi-parameter" where mkErr howMany allowWhat = vcat [text (howMany ++ " parameters for class") <+> quotes (ppr cls), parens (text ("Enable MultiParamTypeClasses to allow " ++ allowWhat ++ " classes"))] classFunDepsErr :: Class -> SDoc classFunDepsErr cls = vcat [text "Fundeps in class" <+> quotes (ppr cls), parens (text "Enable FunctionalDependencies to allow fundeps")] badMethPred :: Id -> TcPredType -> SDoc badMethPred sel_id pred = vcat [ hang (text "Constraint" <+> quotes (ppr pred) <+> text "in the type of" <+> quotes (ppr sel_id)) 2 (text "constrains only the class type variables") , text "Enable ConstrainedClassMethods to allow it" ] noClassTyVarErr :: Class -> TyCon -> SDoc noClassTyVarErr clas fam_tc = sep [ text "The associated type" <+> quotes (ppr fam_tc <+> hsep (map ppr (tyConTyVars fam_tc))) , text "mentions none of the type or kind variables of the class" <+> quotes (ppr clas <+> hsep (map ppr (classTyVars clas)))] badDataConTyCon :: DataCon -> Type -> SDoc badDataConTyCon data_con res_ty_tmpl = hang (text "Data constructor" <+> quotes (ppr data_con) <+> text "returns type" <+> quotes (ppr actual_res_ty)) 2 (text "instead of an instance of its parent type" <+> quotes (ppr res_ty_tmpl)) where actual_res_ty = dataConOrigResTy data_con badGadtDecl :: Name -> SDoc badGadtDecl tc_name = vcat [ text "Illegal generalised algebraic data declaration for" <+> quotes (ppr tc_name) , nest 2 (parens $ text "Enable the GADTs extension to allow this") ] badExistential :: DataCon -> SDoc badExistential con = sdocWithDynFlags (\dflags -> hang (text "Data constructor" <+> quotes (ppr con) <+> text "has existential type variables, a context, or a specialised result type") 2 (vcat [ ppr con <+> dcolon <+> ppr (dataConDisplayType dflags con) , parens $ text "Enable ExistentialQuantification or GADTs to allow this" ])) badStupidTheta :: Name -> SDoc badStupidTheta tc_name = text "A data type declared in GADT style cannot have a context:" <+> quotes (ppr tc_name) newtypeConError :: Name -> Int -> SDoc newtypeConError tycon n = sep [text "A newtype must have exactly one constructor,", nest 2 $ text "but" <+> quotes (ppr tycon) <+> text "has" <+> speakN n ] newtypeStrictError :: DataCon -> SDoc newtypeStrictError con = sep [text "A newtype constructor cannot have a strictness annotation,", nest 2 $ text "but" <+> quotes (ppr con) <+> text "does"] newtypeFieldErr :: DataCon -> Int -> SDoc newtypeFieldErr con_name n_flds = sep [text "The constructor of a newtype must have exactly one field", nest 2 $ text "but" <+> quotes (ppr con_name) <+> text "has" <+> speakN n_flds] badSigTyDecl :: Name -> SDoc badSigTyDecl tc_name = vcat [ text "Illegal kind signature" <+> quotes (ppr tc_name) , nest 2 (parens $ text "Use KindSignatures to allow kind signatures") ] emptyConDeclsErr :: Name -> SDoc emptyConDeclsErr tycon = sep [quotes (ppr tycon) <+> text "has no constructors", nest 2 $ text "(EmptyDataDecls permits this)"] wrongKindOfFamily :: TyCon -> SDoc wrongKindOfFamily family = text "Wrong category of family instance; declaration was for a" <+> kindOfFamily where kindOfFamily | isTypeFamilyTyCon family = text "type family" | isDataFamilyTyCon family = text "data family" | otherwise = pprPanic "wrongKindOfFamily" (ppr family) -- | Produce an error for oversaturated type family equations with too many -- required arguments. -- See Note [Oversaturated type family equations] in "GHC.Tc.Validity". wrongNumberOfParmsErr :: Arity -> SDoc wrongNumberOfParmsErr max_args = text "Number of parameters must match family declaration; expected" <+> ppr max_args badRoleAnnot :: Name -> Role -> Role -> SDoc badRoleAnnot var annot inferred = hang (text "Role mismatch on variable" <+> ppr var <> colon) 2 (sep [ text "Annotation says", ppr annot , text "but role", ppr inferred , text "is required" ]) wrongNumberOfRoles :: [a] -> LRoleAnnotDecl GhcRn -> SDoc wrongNumberOfRoles tyvars d@(L _ (RoleAnnotDecl _ _ annots)) = hang (text "Wrong number of roles listed in role annotation;" $$ text "Expected" <+> (ppr $ length tyvars) <> comma <+> text "got" <+> (ppr $ length annots) <> colon) 2 (ppr d) illegalRoleAnnotDecl :: LRoleAnnotDecl GhcRn -> TcM () illegalRoleAnnotDecl (L loc (RoleAnnotDecl _ tycon _)) = setErrCtxt [] $ setSrcSpan loc $ addErrTc (text "Illegal role annotation for" <+> ppr tycon <> char ';' $$ text "they are allowed only for datatypes and classes.") needXRoleAnnotations :: TyCon -> SDoc needXRoleAnnotations tc = text "Illegal role annotation for" <+> ppr tc <> char ';' $$ text "did you intend to use RoleAnnotations?" incoherentRoles :: SDoc incoherentRoles = (text "Roles other than" <+> quotes (text "nominal") <+> text "for class parameters can lead to incoherence.") $$ (text "Use IncoherentInstances to allow this; bad role found") addTyConCtxt :: TyCon -> TcM a -> TcM a addTyConCtxt tc = addTyConFlavCtxt name flav where name = getName tc flav = tyConFlavour tc addRoleAnnotCtxt :: Name -> TcM a -> TcM a addRoleAnnotCtxt name = addErrCtxt $ text "while checking a role annotation for" <+> quotes (ppr name)