{- (c) The University of Glasgow 2006 (c) The GRASP/AQUA Project, Glasgow University, 1992-1999 Analysis functions over data types. Specficially, detecting recursive types. This stuff is only used for source-code decls; it's recorded in interface files for imported data types. -} {-# LANGUAGE CPP #-} module TcTyDecls( calcRecFlags, RecTyInfo(..), calcSynCycles, calcClassCycles, RoleAnnots, extractRoleAnnots, emptyRoleAnnots, lookupRoleAnnots ) where #include "HsVersions.h" import TypeRep import HsSyn import Class import Type import Kind import HscTypes import TyCon import DataCon import Var import Name import NameEnv import VarEnv import VarSet import NameSet import Coercion ( ltRole ) import Avail import Digraph import BasicTypes import SrcLoc import Outputable import UniqSet import Util import Maybes import Data.List #if __GLASGOW_HASKELL__ < 709 import Control.Applicative (Applicative(..)) #endif import Control.Monad {- ************************************************************************ * * Cycles in class and type synonym declarations * * ************************************************************************ Checking for class-decl loops is easy, because we don't allow class decls in interface files. We allow type synonyms in hi-boot files, but we *trust* hi-boot files, so we don't check for loops that involve them. So we only look for synonym loops in the module being compiled. We check for type synonym and class cycles on the *source* code. Main reasons: a) Otherwise we'd need a special function to extract type-synonym tycons from a type, whereas we already have the free vars pinned on the decl b) If we checked for type synonym loops after building the TyCon, we can't do a hoistForAllTys on the type synonym rhs, (else we fall into a black hole) which seems unclean. Apart from anything else, it'd mean that a type-synonym rhs could have for-alls to the right of an arrow, which means adding new cases to the validity checker Indeed, in general, checking for cycles beforehand means we need to be less careful about black holes through synonym cycles. The main disadvantage is that a cycle that goes via a type synonym in an .hi-boot file can lead the compiler into a loop, because it assumes that cycles only occur entirely within the source code of the module being compiled. But hi-boot files are trusted anyway, so this isn't much worse than (say) a kind error. [ NOTE ---------------------------------------------- If we reverse this decision, this comment came from tcTyDecl1, and should go back there -- dsHsType, not tcHsKindedType, to avoid a loop. tcHsKindedType does hoisting, -- which requires looking through synonyms... and therefore goes into a loop -- on (erroneously) recursive synonyms. -- Solution: do not hoist synonyms, because they'll be hoisted soon enough -- when they are substituted We'd also need to add back in this definition synonymTyConsOfType :: Type -> [TyCon] -- Does not look through type synonyms at all -- Return a list of synonym tycons synonymTyConsOfType ty = nameEnvElts (go ty) where go :: Type -> NameEnv TyCon -- The NameEnv does duplicate elim go (TyVarTy v) = emptyNameEnv go (TyConApp tc tys) = go_tc tc tys go (AppTy a b) = go a `plusNameEnv` go b go (FunTy a b) = go a `plusNameEnv` go b go (ForAllTy _ ty) = go ty go_tc tc tys | isTypeSynonymTyCon tc = extendNameEnv (go_s tys) (tyConName tc) tc | otherwise = go_s tys go_s tys = foldr (plusNameEnv . go) emptyNameEnv tys ---------------------------------------- END NOTE ] -} mkSynEdges :: [LTyClDecl Name] -> [(LTyClDecl Name, Name, [Name])] mkSynEdges syn_decls = [ (ldecl, name, nameSetElems fvs) | ldecl@(L _ (SynDecl { tcdLName = L _ name , tcdFVs = fvs })) <- syn_decls ] calcSynCycles :: [LTyClDecl Name] -> [SCC (LTyClDecl Name)] calcSynCycles = stronglyConnCompFromEdgedVertices . mkSynEdges {- Note [Superclass cycle check] ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ We can't allow cycles via superclasses because it would result in the type checker looping when it canonicalises a class constraint (superclasses are added during canonicalisation). More precisely, given a constraint C ty1 .. tyn we want to instantiate all of C's superclasses, transitively, and that set must be finite. So if class (D b, E b a) => C a b then when we encounter the constraint C ty1 ty2 we'll instantiate the superclasses (D ty2, E ty2 ty1) and then *their* superclasses, and so on. This set must be finite! It is OK for superclasses to be type synonyms for other classes, so must "look through" type synonyms. Eg type X a = C [a] class X a => C a -- No! Recursive superclass! We want definitions such as: class C cls a where cls a => a -> a class C D a => D a where to be accepted, even though a naive acyclicity check would reject the program as having a cycle between D and its superclass. Why? Because when we instantiate D ty1 we get the superclas C D ty1 and C has no superclasses, so we have terminated with a finite set. More precisely, the rule is this: the superclasses sup_C of a class C are rejected iff: C \elem expand(sup_C) Where expand is defined as follows: (1) expand(a ty1 ... tyN) = expand(ty1) \union ... \union expand(tyN) (2) expand(D ty1 ... tyN) = {D} \union sup_D[ty1/x1, ..., tyP/xP] \union expand(ty(P+1)) ... \union expand(tyN) where (D x1 ... xM) is a class, P = min(M,N) (3) expand(T ty1 ... tyN) = expand(ty1) \union ... \union expand(tyN) where T is not a class Eqn (1) is conservative; when there's a type variable at the head, look in all the argument types. Eqn (2) expands superclasses; the third component of the union is like Eqn (1). Eqn (3) happens mainly when the context is a (constraint) tuple, such as (Eq a, Show a). Furthermore, expand always looks through type synonyms. -} calcClassCycles :: Class -> [[TyCon]] calcClassCycles cls = nubBy eqAsCycle $ expandTheta (unitUniqSet cls) [classTyCon cls] (classSCTheta cls) [] where -- The last TyCon in the cycle is always the same as the first eqAsCycle xs ys = any (xs ==) (cycles (tail ys)) cycles xs = take n . map (take n) . tails . cycle $ xs where n = length xs -- No more superclasses to expand ==> no problems with cycles -- See Note [Superclass cycle check] expandTheta :: UniqSet Class -- Path of Classes to here in set form -> [TyCon] -- Path to here -> ThetaType -- Superclass work list -> [[TyCon]] -- Input error paths -> [[TyCon]] -- Final error paths expandTheta _ _ [] = id expandTheta seen path (pred:theta) = expandType seen path pred . expandTheta seen path theta expandType seen path (TyConApp tc tys) -- Expand unsaturated classes to their superclass theta if they are yet unseen. -- If they have already been seen then we have detected an error! | Just cls <- tyConClass_maybe tc , let (env, remainder) = papp (classTyVars cls) tys rest_tys = either (const []) id remainder = if cls `elementOfUniqSet` seen then (reverse (classTyCon cls:path):) . flip (foldr (expandType seen path)) tys else expandTheta (addOneToUniqSet seen cls) (tc:path) (substTys (mkTopTvSubst env) (classSCTheta cls)) . flip (foldr (expandType seen path)) rest_tys -- For synonyms, try to expand them: some arguments might be -- phantoms, after all. We can expand with impunity because at -- this point the type synonym cycle check has already happened. | Just (tvs, rhs) <- synTyConDefn_maybe tc , let (env, remainder) = papp tvs tys rest_tys = either (const []) id remainder = expandType seen (tc:path) (substTy (mkTopTvSubst env) rhs) . flip (foldr (expandType seen path)) rest_tys -- For non-class, non-synonyms, just check the arguments | otherwise = flip (foldr (expandType seen path)) tys expandType _ _ (TyVarTy {}) = id expandType _ _ (LitTy {}) = id expandType seen path (AppTy t1 t2) = expandType seen path t1 . expandType seen path t2 expandType seen path (FunTy t1 t2) = expandType seen path t1 . expandType seen path t2 expandType seen path (ForAllTy _tv t) = expandType seen path t papp :: [TyVar] -> [Type] -> ([(TyVar, Type)], Either [TyVar] [Type]) papp [] tys = ([], Right tys) papp tvs [] = ([], Left tvs) papp (tv:tvs) (ty:tys) = ((tv, ty):env, remainder) where (env, remainder) = papp tvs tys {- ************************************************************************ * * Deciding which type constructors are recursive * * ************************************************************************ Identification of recursive TyCons ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ The knot-tying parameters: @rec_details_list@ is an alist mapping @Name@s to @TyThing@s. Identifying a TyCon as recursive serves two purposes 1. Avoid infinite types. Non-recursive newtypes are treated as "transparent", like type synonyms, after the type checker. If we did this for all newtypes, we'd get infinite types. So we figure out for each newtype whether it is "recursive", and add a coercion if so. In effect, we are trying to "cut the loops" by identifying a loop-breaker. 2. Avoid infinite unboxing. This has nothing to do with newtypes. Suppose we have data T = MkT Int T f (MkT x t) = f t Well, this function diverges, but we don't want the strictness analyser to diverge. But the strictness analyser will diverge because it looks deeper and deeper into the structure of T. (I believe there are examples where the function does something sane, and the strictness analyser still diverges, but I can't see one now.) Now, concerning (1), the FC2 branch currently adds a coercion for ALL newtypes. I did this as an experiment, to try to expose cases in which the coercions got in the way of optimisations. If it turns out that we can indeed always use a coercion, then we don't risk recursive types, and don't need to figure out what the loop breakers are. For newtype *families* though, we will always have a coercion, so they are always loop breakers! So you can easily adjust the current algorithm by simply treating all newtype families as loop breakers (and indeed type families). I think. For newtypes, we label some as "recursive" such that INVARIANT: there is no cycle of non-recursive newtypes In any loop, only one newtype need be marked as recursive; it is a "loop breaker". Labelling more than necessary as recursive is OK, provided the invariant is maintained. A newtype M.T is defined to be "recursive" iff (a) it is declared in an hi-boot file (see RdrHsSyn.hsIfaceDecl) (b) it is declared in a source file, but that source file has a companion hi-boot file which declares the type or (c) one can get from T's rhs to T via type synonyms, or non-recursive newtypes *in M* e.g. newtype T = MkT (T -> Int) (a) is conservative; declarations in hi-boot files are always made loop breakers. That's why in (b) we can restrict attention to tycons in M, because any loops through newtypes outside M will be broken by those newtypes (b) ensures that a newtype is not treated as a loop breaker in one place and later as a non-loop-breaker. This matters in GHCi particularly, when a newtype T might be embedded in many types in the environment, and then T's source module is compiled. We don't want T's recursiveness to change. The "recursive" flag for algebraic data types is irrelevant (never consulted) for types with more than one constructor. An algebraic data type M.T is "recursive" iff it has just one constructor, and (a) it is declared in an hi-boot file (see RdrHsSyn.hsIfaceDecl) (b) it is declared in a source file, but that source file has a companion hi-boot file which declares the type or (c) one can get from its arg types to T via type synonyms, or by non-recursive newtypes or non-recursive product types in M e.g. data T = MkT (T -> Int) Bool Just like newtype in fact A type synonym is recursive if one can get from its right hand side back to it via type synonyms. (This is reported as an error.) A class is recursive if one can get from its superclasses back to it. (This is an error too.) Hi-boot types ~~~~~~~~~~~~~ A data type read from an hi-boot file will have an AbstractTyCon as its AlgTyConRhs and will respond True to isAbstractTyCon. The idea is that we treat these as if one could get from these types to anywhere. So when we see module Baz where import {-# SOURCE #-} Foo( T ) newtype S = MkS T then we mark S as recursive, just in case. What that means is that if we see import Baz( S ) newtype R = MkR S then we don't need to look inside S to compute R's recursiveness. Since S is imported (not from an hi-boot file), one cannot get from R back to S except via an hi-boot file, and that means that some data type will be marked recursive along the way. So R is unconditionly non-recursive (i.e. there'll be a loop breaker elsewhere if necessary) This in turn means that we grovel through fewer interface files when computing recursiveness, because we need only look at the type decls in the module being compiled, plus the outer structure of directly-mentioned types. -} data RecTyInfo = RTI { rti_promotable :: Bool , rti_roles :: Name -> [Role] , rti_is_rec :: Name -> RecFlag } calcRecFlags :: ModDetails -> Bool -- hs-boot file? -> RoleAnnots -> [TyThing] -> RecTyInfo -- The 'boot_names' are the things declared in M.hi-boot, if M is the current module. -- Any type constructors in boot_names are automatically considered loop breakers calcRecFlags boot_details is_boot mrole_env tyclss = RTI { rti_promotable = is_promotable , rti_roles = roles , rti_is_rec = is_rec } where rec_tycon_names = mkNameSet (map tyConName all_tycons) all_tycons = mapMaybe getTyCon tyclss -- Recursion of newtypes/data types can happen via -- the class TyCon, so tyclss includes the class tycons is_promotable = all (isPromotableTyCon rec_tycon_names) all_tycons roles = inferRoles is_boot mrole_env all_tycons ----------------- Recursion calculation ---------------- is_rec n | n `elemNameSet` rec_names = Recursive | otherwise = NonRecursive boot_name_set = availsToNameSet (md_exports boot_details) rec_names = boot_name_set `unionNameSet` nt_loop_breakers `unionNameSet` prod_loop_breakers ------------------------------------------------- -- NOTE -- These edge-construction loops rely on -- every loop going via tyclss, the types and classes -- in the module being compiled. Stuff in interface -- files should be correctly marked. If not (e.g. a -- type synonym in a hi-boot file) we can get an infinite -- loop. We could program round this, but it'd make the code -- rather less nice, so I'm not going to do that yet. single_con_tycons = [ tc | tc <- all_tycons , not (tyConName tc `elemNameSet` boot_name_set) -- Remove the boot_name_set because they are -- going to be loop breakers regardless. , isSingleton (tyConDataCons tc) ] -- Both newtypes and data types, with exactly one data constructor (new_tycons, prod_tycons) = partition isNewTyCon single_con_tycons -- NB: we do *not* call isProductTyCon because that checks -- for vanilla-ness of data constructors; and that depends -- on empty existential type variables; and that is figured -- out by tcResultType; which uses tcMatchTy; which uses -- coreView; which calls coreExpandTyCon_maybe; which uses -- the recursiveness of the TyCon. Result... a black hole. -- YUK YUK YUK --------------- Newtypes ---------------------- nt_loop_breakers = mkNameSet (findLoopBreakers nt_edges) is_rec_nt tc = tyConName tc `elemNameSet` nt_loop_breakers -- is_rec_nt is a locally-used helper function nt_edges = [(t, mk_nt_edges t) | t <- new_tycons] mk_nt_edges nt -- Invariant: nt is a newtype = [ tc | tc <- nameEnvElts (tyConsOfType (new_tc_rhs nt)) -- tyConsOfType looks through synonyms , tc `elem` new_tycons ] -- If not (tc `elem` new_tycons) we know that either it's a local *data* type, -- or it's imported. Either way, it can't form part of a newtype cycle --------------- Product types ---------------------- prod_loop_breakers = mkNameSet (findLoopBreakers prod_edges) prod_edges = [(tc, mk_prod_edges tc) | tc <- prod_tycons] mk_prod_edges tc -- Invariant: tc is a product tycon = concatMap (mk_prod_edges1 tc) (dataConOrigArgTys (head (tyConDataCons tc))) mk_prod_edges1 ptc ty = concatMap (mk_prod_edges2 ptc) (nameEnvElts (tyConsOfType ty)) mk_prod_edges2 ptc tc | tc `elem` prod_tycons = [tc] -- Local product | tc `elem` new_tycons = if is_rec_nt tc -- Local newtype then [] else mk_prod_edges1 ptc (new_tc_rhs tc) -- At this point we know that either it's a local non-product data type, -- or it's imported. Either way, it can't form part of a cycle | otherwise = [] new_tc_rhs :: TyCon -> Type new_tc_rhs tc = snd (newTyConRhs tc) -- Ignore the type variables getTyCon :: TyThing -> Maybe TyCon getTyCon (ATyCon tc) = Just tc getTyCon _ = Nothing findLoopBreakers :: [(TyCon, [TyCon])] -> [Name] -- Finds a set of tycons that cut all loops findLoopBreakers deps = go [(tc,tc,ds) | (tc,ds) <- deps] where go edges = [ name | CyclicSCC ((tc,_,_) : edges') <- stronglyConnCompFromEdgedVerticesR edges, name <- tyConName tc : go edges'] {- ************************************************************************ * * Promotion calculation * * ************************************************************************ See Note [Checking whether a group is promotable] ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ We only want to promote a TyCon if all its data constructors are promotable; it'd be very odd to promote some but not others. But the data constructors may mention this or other TyCons. So we treat the recursive uses as all OK (ie promotable) and do one pass to check that each TyCon is promotable. Currently type synonyms are not promotable, though that could change. -} isPromotableTyCon :: NameSet -> TyCon -> Bool isPromotableTyCon rec_tycons tc = isAlgTyCon tc -- Only algebraic; not even synonyms -- (we could reconsider the latter) && ok_kind (tyConKind tc) && case algTyConRhs tc of DataTyCon { data_cons = cs } -> all ok_con cs NewTyCon { data_con = c } -> ok_con c AbstractTyCon {} -> False DataFamilyTyCon {} -> False where ok_kind kind = all isLiftedTypeKind args && isLiftedTypeKind res where -- Checks for * -> ... -> * -> * (args, res) = splitKindFunTys kind -- See Note [Promoted data constructors] in TyCon ok_con con = all (isLiftedTypeKind . tyVarKind) ex_tvs && null eq_spec -- No constraints && null theta && all (isPromotableType rec_tycons) orig_arg_tys where (_, ex_tvs, eq_spec, theta, orig_arg_tys, _) = dataConFullSig con isPromotableType :: NameSet -> Type -> Bool -- Must line up with DataCon.promoteType -- But the function lives here because we must treat the -- *recursive* tycons as promotable isPromotableType rec_tcs con_arg_ty = go con_arg_ty where go (TyConApp tc tys) = tys `lengthIs` tyConArity tc && (tyConName tc `elemNameSet` rec_tcs || isJust (promotableTyCon_maybe tc)) && all go tys go (FunTy arg res) = go arg && go res go (TyVarTy {}) = True go _ = False {- ************************************************************************ * * Role annotations * * ************************************************************************ -} type RoleAnnots = NameEnv (LRoleAnnotDecl Name) extractRoleAnnots :: TyClGroup Name -> RoleAnnots extractRoleAnnots (TyClGroup { group_roles = roles }) = mkNameEnv [ (tycon, role_annot) | role_annot@(L _ (RoleAnnotDecl (L _ tycon) _)) <- roles ] emptyRoleAnnots :: RoleAnnots emptyRoleAnnots = emptyNameEnv lookupRoleAnnots :: RoleAnnots -> Name -> Maybe (LRoleAnnotDecl Name) lookupRoleAnnots = lookupNameEnv {- ************************************************************************ * * Role inference * * ************************************************************************ Note [Role inference] ~~~~~~~~~~~~~~~~~~~~~ The role inference algorithm datatype definitions to infer the roles on the parameters. Although these roles are stored in the tycons, we can perform this algorithm on the built tycons, as long as we don't peek at an as-yet-unknown roles field! Ah, the magic of laziness. First, we choose appropriate initial roles. For families and classes, roles (including initial roles) are N. For datatypes, we start with the role in the role annotation (if any), or otherwise use Phantom. This is done in initialRoleEnv1. The function irGroup then propagates role information until it reaches a fixpoint, preferring N over (R or P) and R over P. To aid in this, we have a monad RoleM, which is a combination reader and state monad. In its state are the current RoleEnv, which gets updated by role propagation, and an update bit, which we use to know whether or not we've reached the fixpoint. The environment of RoleM contains the tycon whose parameters we are inferring, and a VarEnv from parameters to their positions, so we can update the RoleEnv. Between tycons, this reader information is missing; it is added by addRoleInferenceInfo. There are two kinds of tycons to consider: algebraic ones (excluding classes) and type synonyms. (Remember, families don't participate -- all their parameters are N.) An algebraic tycon processes each of its datacons, in turn. Note that a datacon's universally quantified parameters might be different from the parent tycon's parameters, so we use the datacon's univ parameters in the mapping from vars to positions. Note also that we don't want to infer roles for existentials (they're all at N, too), so we put them in the set of local variables. As an optimisation, we skip any tycons whose roles are already all Nominal, as there nowhere else for them to go. For synonyms, we just analyse their right-hand sides. irType walks through a type, looking for uses of a variable of interest and propagating role information. Because anything used under a phantom position is at phantom and anything used under a nominal position is at nominal, the irType function can assume that anything it sees is at representational. (The other possibilities are pruned when they're encountered.) The rest of the code is just plumbing. How do we know that this algorithm is correct? It should meet the following specification: Let Z be a role context -- a mapping from variables to roles. The following rules define the property (Z |- t : r), where t is a type and r is a role: Z(a) = r' r' <= r ------------------------- RCVar Z |- a : r ---------- RCConst Z |- T : r -- T is a type constructor Z |- t1 : r Z |- t2 : N -------------- RCApp Z |- t1 t2 : r forall i<=n. (r_i is R or N) implies Z |- t_i : r_i roles(T) = r_1 .. r_n ---------------------------------------------------- RCDApp Z |- T t_1 .. t_n : R Z, a:N |- t : r ---------------------- RCAll Z |- forall a:k.t : r We also have the following rules: For all datacon_i in type T, where a_1 .. a_n are universally quantified and b_1 .. b_m are existentially quantified, and the arguments are t_1 .. t_p, then if forall j<=p, a_1 : r_1 .. a_n : r_n, b_1 : N .. b_m : N |- t_j : R, then roles(T) = r_1 .. r_n roles(->) = R, R roles(~#) = N, N With -dcore-lint on, the output of this algorithm is checked in checkValidRoles, called from checkValidTycon. Note [Role-checking data constructor arguments] ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ Consider data T a where MkT :: Eq b => F a -> (a->a) -> T (G a) Then we want to check the roles at which 'a' is used in MkT's type. We want to work on the user-written type, so we need to take into account * the arguments: (F a) and (a->a) * the context: C a b * the result type: (G a) -- this is in the eq_spec -} type RoleEnv = NameEnv [Role] -- from tycon names to roles -- This, and any of the functions it calls, must *not* look at the roles -- field of a tycon we are inferring roles about! -- See Note [Role inference] inferRoles :: Bool -> RoleAnnots -> [TyCon] -> Name -> [Role] inferRoles is_boot annots tycons = let role_env = initialRoleEnv is_boot annots tycons role_env' = irGroup role_env tycons in \name -> case lookupNameEnv role_env' name of Just roles -> roles Nothing -> pprPanic "inferRoles" (ppr name) initialRoleEnv :: Bool -> RoleAnnots -> [TyCon] -> RoleEnv initialRoleEnv is_boot annots = extendNameEnvList emptyNameEnv . map (initialRoleEnv1 is_boot annots) initialRoleEnv1 :: Bool -> RoleAnnots -> TyCon -> (Name, [Role]) initialRoleEnv1 is_boot annots_env tc | isFamilyTyCon tc = (name, map (const Nominal) tyvars) | isAlgTyCon tc = (name, default_roles) | isTypeSynonymTyCon tc = (name, default_roles) | otherwise = pprPanic "initialRoleEnv1" (ppr tc) where name = tyConName tc tyvars = tyConTyVars tc (kvs, tvs) = span isKindVar tyvars -- if the number of annotations in the role annotation decl -- is wrong, just ignore it. We check this in the validity check. role_annots = case lookupNameEnv annots_env name of Just (L _ (RoleAnnotDecl _ annots)) | annots `equalLength` tvs -> map unLoc annots _ -> map (const Nothing) tvs default_roles = map (const Nominal) kvs ++ zipWith orElse role_annots (repeat default_role) default_role | isClassTyCon tc = Nominal | is_boot = Representational | otherwise = Phantom irGroup :: RoleEnv -> [TyCon] -> RoleEnv irGroup env tcs = let (env', update) = runRoleM env $ mapM_ irTyCon tcs in if update then irGroup env' tcs else env' irTyCon :: TyCon -> RoleM () irTyCon tc | isAlgTyCon tc = do { old_roles <- lookupRoles tc ; unless (all (== Nominal) old_roles) $ -- also catches data families, -- which don't want or need role inference do { whenIsJust (tyConClass_maybe tc) (irClass tc_name) ; addRoleInferenceInfo tc_name (tyConTyVars tc) $ mapM_ (irType emptyVarSet) (tyConStupidTheta tc) -- See #8958 ; mapM_ (irDataCon tc_name) (visibleDataCons $ algTyConRhs tc) }} | Just ty <- synTyConRhs_maybe tc = addRoleInferenceInfo tc_name (tyConTyVars tc) $ irType emptyVarSet ty | otherwise = return () where tc_name = tyConName tc -- any type variable used in an associated type must be Nominal irClass :: Name -> Class -> RoleM () irClass tc_name cls = addRoleInferenceInfo tc_name cls_tvs $ mapM_ ir_at (classATs cls) where cls_tvs = classTyVars cls cls_tv_set = mkVarSet cls_tvs ir_at at_tc = mapM_ (updateRole Nominal) (varSetElems nvars) where nvars = (mkVarSet $ tyConTyVars at_tc) `intersectVarSet` cls_tv_set -- See Note [Role inference] irDataCon :: Name -> DataCon -> RoleM () irDataCon tc_name datacon = addRoleInferenceInfo tc_name univ_tvs $ mapM_ (irType ex_var_set) (eqSpecPreds eq_spec ++ theta ++ arg_tys) -- See Note [Role-checking data constructor arguments] where (univ_tvs, ex_tvs, eq_spec, theta, arg_tys, _res_ty) = dataConFullSig datacon ex_var_set = mkVarSet ex_tvs irType :: VarSet -> Type -> RoleM () irType = go where go lcls (TyVarTy tv) = unless (tv `elemVarSet` lcls) $ updateRole Representational tv go lcls (AppTy t1 t2) = go lcls t1 >> mark_nominal lcls t2 go lcls (TyConApp tc tys) = do { roles <- lookupRolesX tc ; zipWithM_ (go_app lcls) roles tys } go lcls (FunTy t1 t2) = go lcls t1 >> go lcls t2 go lcls (ForAllTy tv ty) = go (extendVarSet lcls tv) ty go _ (LitTy {}) = return () go_app _ Phantom _ = return () -- nothing to do here go_app lcls Nominal ty = mark_nominal lcls ty -- all vars below here are N go_app lcls Representational ty = go lcls ty mark_nominal lcls ty = let nvars = tyVarsOfType ty `minusVarSet` lcls in mapM_ (updateRole Nominal) (varSetElems nvars) -- like lookupRoles, but with Nominal tags at the end for oversaturated TyConApps lookupRolesX :: TyCon -> RoleM [Role] lookupRolesX tc = do { roles <- lookupRoles tc ; return $ roles ++ repeat Nominal } -- gets the roles either from the environment or the tycon lookupRoles :: TyCon -> RoleM [Role] lookupRoles tc = do { env <- getRoleEnv ; case lookupNameEnv env (tyConName tc) of Just roles -> return roles Nothing -> return $ tyConRoles tc } -- tries to update a role; won't ever update a role "downwards" updateRole :: Role -> TyVar -> RoleM () updateRole role tv = do { var_ns <- getVarNs ; case lookupVarEnv var_ns tv of { Nothing -> pprPanic "updateRole" (ppr tv) ; Just n -> do { name <- getTyConName ; updateRoleEnv name n role }}} -- the state in the RoleM monad data RoleInferenceState = RIS { role_env :: RoleEnv , update :: Bool } -- the environment in the RoleM monad type VarPositions = VarEnv Int data RoleInferenceInfo = RII { var_ns :: VarPositions , name :: Name } -- See [Role inference] newtype RoleM a = RM { unRM :: Maybe RoleInferenceInfo -> RoleInferenceState -> (a, RoleInferenceState) } instance Functor RoleM where fmap = liftM instance Applicative RoleM where pure = return (<*>) = ap instance Monad RoleM where return x = RM $ \_ state -> (x, state) a >>= f = RM $ \m_info state -> let (a', state') = unRM a m_info state in unRM (f a') m_info state' runRoleM :: RoleEnv -> RoleM () -> (RoleEnv, Bool) runRoleM env thing = (env', update) where RIS { role_env = env', update = update } = snd $ unRM thing Nothing state state = RIS { role_env = env, update = False } addRoleInferenceInfo :: Name -> [TyVar] -> RoleM a -> RoleM a addRoleInferenceInfo name tvs thing = RM $ \_nothing state -> ASSERT( isNothing _nothing ) unRM thing (Just info) state where info = RII { var_ns = mkVarEnv (zip tvs [0..]), name = name } getRoleEnv :: RoleM RoleEnv getRoleEnv = RM $ \_ state@(RIS { role_env = env }) -> (env, state) getVarNs :: RoleM VarPositions getVarNs = RM $ \m_info state -> case m_info of Nothing -> panic "getVarNs" Just (RII { var_ns = var_ns }) -> (var_ns, state) getTyConName :: RoleM Name getTyConName = RM $ \m_info state -> case m_info of Nothing -> panic "getTyConName" Just (RII { name = name }) -> (name, state) updateRoleEnv :: Name -> Int -> Role -> RoleM () updateRoleEnv name n role = RM $ \_ state@(RIS { role_env = role_env }) -> ((), case lookupNameEnv role_env name of Nothing -> pprPanic "updateRoleEnv" (ppr name) Just roles -> let (before, old_role : after) = splitAt n roles in if role `ltRole` old_role then let roles' = before ++ role : after role_env' = extendNameEnv role_env name roles' in RIS { role_env = role_env', update = True } else state )