% % (c) The University of Glasgow 2006 % \begin{code} module TcEnv( TyThing(..), TcTyThing(..), TcId, -- Instance environment, and InstInfo type InstInfo(..), iDFunId, pprInstInfo, pprInstInfoDetails, simpleInstInfoClsTy, simpleInstInfoTy, simpleInstInfoTyCon, InstBindings(..), -- Global environment tcExtendGlobalEnv, setGlobalTypeEnv, tcExtendGlobalValEnv, tcLookupLocatedGlobal, tcLookupGlobal, tcLookupField, tcLookupTyCon, tcLookupClass, tcLookupDataCon, tcLookupLocatedGlobalId, tcLookupLocatedTyCon, tcLookupLocatedClass, tcLookupFamInst, -- Local environment tcExtendKindEnv, tcExtendKindEnvTvs, tcExtendTyVarEnv, tcExtendTyVarEnv2, tcExtendGhciEnv, tcExtendIdEnv, tcExtendIdEnv1, tcExtendIdEnv2, tcLookup, tcLookupLocated, tcLookupLocalIds, tcLookupId, tcLookupTyVar, getScopedTyVarBinds, lclEnvElts, getInLocalScope, findGlobals, wrongThingErr, pprBinders, tcExtendRecEnv, -- For knot-tying -- Rules tcExtendRules, -- Global type variables tcGetGlobalTyVars, -- Template Haskell stuff checkWellStaged, tcMetaTy, thLevel, topIdLvl, thTopLevelId, thRnBrack, isBrackStage, -- New Ids newLocalName, newDFunName, newFamInstTyConName, mkStableIdFromString, mkStableIdFromName ) where #include "HsVersions.h" import HsSyn import TcIface import IfaceEnv import TcRnMonad import TcMType import TcType -- import TcSuspension import qualified Type import Id import Coercion import Var import VarSet import VarEnv import RdrName import InstEnv import FamInstEnv import DataCon import TyCon import TypeRep import Class import Name import NameEnv import HscTypes import SrcLoc import Outputable import Unique import FastString \end{code} %************************************************************************ %* * %* tcLookupGlobal * %* * %************************************************************************ Using the Located versions (eg. tcLookupLocatedGlobal) is preferred, unless you know that the SrcSpan in the monad is already set to the span of the Name. \begin{code} tcLookupLocatedGlobal :: Located Name -> TcM TyThing -- c.f. IfaceEnvEnv.tcIfaceGlobal tcLookupLocatedGlobal name = addLocM tcLookupGlobal name tcLookupGlobal :: Name -> TcM TyThing -- The Name is almost always an ExternalName, but not always -- In GHCi, we may make command-line bindings (ghci> let x = True) -- that bind a GlobalId, but with an InternalName tcLookupGlobal name = do { env <- getGblEnv -- Try local envt ; case lookupNameEnv (tcg_type_env env) name of { Just thing -> return thing ; Nothing -> do -- Try global envt { hsc_env <- getTopEnv ; mb_thing <- liftIO (lookupTypeHscEnv hsc_env name) ; case mb_thing of { Just thing -> return thing ; Nothing -> do -- Should it have been in the local envt? { case nameModule_maybe name of Nothing -> notFound name env -- Internal names can happen in GHCi Just mod | mod == tcg_mod env -- Names from this module -> notFound name env -- should be in tcg_type_env | otherwise -> tcImportDecl name -- Go find it in an interface }}}}} tcLookupField :: Name -> TcM Id -- Returns the selector Id tcLookupField name = tcLookupId name -- Note [Record field lookup] {- Note [Record field lookup] ~~~~~~~~~~~~~~~~~~~~~~~~~~ You might think we should have tcLookupGlobal here, since record fields are always top level. But consider f = e { f = True } Then the renamer (which does not keep track of what is a record selector and what is not) will rename the definition thus f_7 = e { f_7 = True } Now the type checker will find f_7 in the *local* type environment, not the global (imported) one. It's wrong, of course, but we want to report a tidy error, not in TcEnv.notFound. -} tcLookupDataCon :: Name -> TcM DataCon tcLookupDataCon name = do thing <- tcLookupGlobal name case thing of ADataCon con -> return con _ -> wrongThingErr "data constructor" (AGlobal thing) name tcLookupClass :: Name -> TcM Class tcLookupClass name = do thing <- tcLookupGlobal name case thing of AClass cls -> return cls _ -> wrongThingErr "class" (AGlobal thing) name tcLookupTyCon :: Name -> TcM TyCon tcLookupTyCon name = do thing <- tcLookupGlobal name case thing of ATyCon tc -> return tc _ -> wrongThingErr "type constructor" (AGlobal thing) name tcLookupLocatedGlobalId :: Located Name -> TcM Id tcLookupLocatedGlobalId = addLocM tcLookupId tcLookupLocatedClass :: Located Name -> TcM Class tcLookupLocatedClass = addLocM tcLookupClass tcLookupLocatedTyCon :: Located Name -> TcM TyCon tcLookupLocatedTyCon = addLocM tcLookupTyCon -- Look up the instance tycon of a family instance. -- -- The match may be ambiguous (as we know that overlapping instances have -- identical right-hand sides under overlapping substitutions - see -- 'FamInstEnv.lookupFamInstEnvConflicts'). However, the type arguments used -- for matching must be equal to or be more specific than those of the family -- instance declaration. We pick one of the matches in case of ambiguity; as -- the right-hand sides are identical under the match substitution, the choice -- does not matter. -- -- Return the instance tycon and its type instance. For example, if we have -- -- tcLookupFamInst 'T' '[Int]' yields (':R42T', 'Int') -- -- then we have a coercion (ie, type instance of family instance coercion) -- -- :Co:R42T Int :: T [Int] ~ :R42T Int -- -- which implies that :R42T was declared as 'data instance T [a]'. -- tcLookupFamInst :: TyCon -> [Type] -> TcM (Maybe (TyCon, [Type])) tcLookupFamInst tycon tys | not (isOpenTyCon tycon) = return Nothing | otherwise = do { env <- getGblEnv ; eps <- getEps ; let instEnv = (eps_fam_inst_env eps, tcg_fam_inst_env env) ; case lookupFamInstEnv instEnv tycon tys of [] -> return Nothing ((fam_inst, rep_tys):_) -> return $ Just (famInstTyCon fam_inst, rep_tys) } \end{code} \begin{code} instance MonadThings (IOEnv (Env TcGblEnv TcLclEnv)) where lookupThing = tcLookupGlobal \end{code} %************************************************************************ %* * Extending the global environment %* * %************************************************************************ \begin{code} setGlobalTypeEnv :: TcGblEnv -> TypeEnv -> TcM TcGblEnv -- Use this to update the global type env -- It updates both * the normal tcg_type_env field -- * the tcg_type_env_var field seen by interface files setGlobalTypeEnv tcg_env new_type_env = do { -- Sync the type-envt variable seen by interface files writeMutVar (tcg_type_env_var tcg_env) new_type_env ; return (tcg_env { tcg_type_env = new_type_env }) } tcExtendGlobalEnv :: [TyThing] -> TcM r -> TcM r -- Given a mixture of Ids, TyCons, Classes, all from the -- module being compiled, extend the global environment tcExtendGlobalEnv things thing_inside = do { tcg_env <- getGblEnv ; let ge' = extendTypeEnvList (tcg_type_env tcg_env) things ; tcg_env' <- setGlobalTypeEnv tcg_env ge' ; setGblEnv tcg_env' thing_inside } tcExtendGlobalValEnv :: [Id] -> TcM a -> TcM a -- Same deal as tcExtendGlobalEnv, but for Ids tcExtendGlobalValEnv ids thing_inside = tcExtendGlobalEnv [AnId id | id <- ids] thing_inside tcExtendRecEnv :: [(Name,TyThing)] -> TcM r -> TcM r -- Extend the global environments for the type/class knot tying game -- Just like tcExtendGlobalEnv, except the argument is a list of pairs tcExtendRecEnv gbl_stuff thing_inside = do { tcg_env <- getGblEnv ; let ge' = extendNameEnvList (tcg_type_env tcg_env) gbl_stuff ; tcg_env' <- setGlobalTypeEnv tcg_env ge' ; setGblEnv tcg_env' thing_inside } \end{code} %************************************************************************ %* * \subsection{The local environment} %* * %************************************************************************ \begin{code} tcLookupLocated :: Located Name -> TcM TcTyThing tcLookupLocated = addLocM tcLookup tcLookup :: Name -> TcM TcTyThing tcLookup name = do local_env <- getLclEnv case lookupNameEnv (tcl_env local_env) name of Just thing -> return thing Nothing -> AGlobal <$> tcLookupGlobal name tcLookupTyVar :: Name -> TcM TcTyVar tcLookupTyVar name = do thing <- tcLookup name case thing of ATyVar _ ty -> return (tcGetTyVar "tcLookupTyVar" ty) _ -> pprPanic "tcLookupTyVar" (ppr name) tcLookupId :: Name -> TcM Id -- Used when we aren't interested in the binding level, nor refinement. -- The "no refinement" part means that we return the un-refined Id regardless -- -- The Id is never a DataCon. (Why does that matter? see TcExpr.tcId) tcLookupId name = do thing <- tcLookup name case thing of ATcId { tct_id = id} -> return id AGlobal (AnId id) -> return id _ -> pprPanic "tcLookupId" (ppr name) tcLookupLocalIds :: [Name] -> TcM [TcId] -- We expect the variables to all be bound, and all at -- the same level as the lookup. Only used in one place... tcLookupLocalIds ns = do env <- getLclEnv return (map (lookup (tcl_env env) (thLevel (tcl_th_ctxt env))) ns) where lookup lenv lvl name = case lookupNameEnv lenv name of Just (ATcId { tct_id = id, tct_level = lvl1 }) -> ASSERT( lvl == lvl1 ) id _ -> pprPanic "tcLookupLocalIds" (ppr name) lclEnvElts :: TcLclEnv -> [TcTyThing] lclEnvElts env = nameEnvElts (tcl_env env) getInLocalScope :: TcM (Name -> Bool) -- Ids only getInLocalScope = do env <- getLclEnv let lcl_env = tcl_env env return (`elemNameEnv` lcl_env) \end{code} \begin{code} tcExtendKindEnv :: [(Name, TcKind)] -> TcM r -> TcM r tcExtendKindEnv things thing_inside = updLclEnv upd thing_inside where upd lcl_env = lcl_env { tcl_env = extend (tcl_env lcl_env) } extend env = extendNameEnvList env [(n, AThing k) | (n,k) <- things] tcExtendKindEnvTvs :: [LHsTyVarBndr Name] -> TcM r -> TcM r tcExtendKindEnvTvs bndrs thing_inside = updLclEnv upd thing_inside where upd lcl_env = lcl_env { tcl_env = extend (tcl_env lcl_env) } extend env = extendNameEnvList env pairs pairs = [(n, AThing k) | L _ (KindedTyVar n k) <- bndrs] tcExtendTyVarEnv :: [TyVar] -> TcM r -> TcM r tcExtendTyVarEnv tvs thing_inside = tcExtendTyVarEnv2 [(tyVarName tv, mkTyVarTy tv) | tv <- tvs] thing_inside tcExtendTyVarEnv2 :: [(Name,TcType)] -> TcM r -> TcM r tcExtendTyVarEnv2 binds thing_inside = do env@(TcLclEnv {tcl_env = le, tcl_tyvars = gtvs, tcl_rdr = rdr_env}) <- getLclEnv let rdr_env' = extendLocalRdrEnvList rdr_env (map fst binds) new_tv_set = tcTyVarsOfTypes (map snd binds) le' = extendNameEnvList le [(name, ATyVar name ty) | (name, ty) <- binds] -- It's important to add the in-scope tyvars to the global tyvar set -- as well. Consider -- f (_::r) = let g y = y::r in ... -- Here, g mustn't be generalised. This is also important during -- class and instance decls, when we mustn't generalise the class tyvars -- when typechecking the methods. gtvs' <- tc_extend_gtvs gtvs new_tv_set setLclEnv (env {tcl_env = le', tcl_tyvars = gtvs', tcl_rdr = rdr_env'}) thing_inside getScopedTyVarBinds :: TcM [(Name, TcType)] getScopedTyVarBinds = do { lcl_env <- getLclEnv ; return [(name, ty) | ATyVar name ty <- nameEnvElts (tcl_env lcl_env)] } \end{code} \begin{code} tcExtendIdEnv :: [TcId] -> TcM a -> TcM a tcExtendIdEnv ids thing_inside = tcExtendIdEnv2 [(idName id, id) | id <- ids] thing_inside tcExtendIdEnv1 :: Name -> TcId -> TcM a -> TcM a tcExtendIdEnv1 name id thing_inside = tcExtendIdEnv2 [(name,id)] thing_inside tcExtendIdEnv2 :: [(Name,TcId)] -> TcM a -> TcM a -- Invariant: the TcIds are fully zonked (see tcExtendIdEnv above) tcExtendIdEnv2 names_w_ids thing_inside = do { env <- getLclEnv ; tc_extend_local_id_env env (thLevel (tcl_th_ctxt env)) names_w_ids thing_inside } tcExtendGhciEnv :: [TcId] -> TcM a -> TcM a -- Used to bind Ids for GHCi identifiers bound earlier in the user interaction -- Note especially that we bind them at TH level 'impLevel'. That's because it's -- OK to use a variable bound earlier in the interaction in a splice, becuase -- GHCi has already compiled it to bytecode tcExtendGhciEnv ids thing_inside = do { env <- getLclEnv ; tc_extend_local_id_env env impLevel [(idName id, id) | id <- ids] thing_inside } tc_extend_local_id_env -- This is the guy who does the work :: TcLclEnv -> ThLevel -> [(Name,TcId)] -> TcM a -> TcM a -- Invariant: the TcIds are fully zonked. Reasons: -- (a) The kinds of the forall'd type variables are defaulted -- (see Kind.defaultKind, done in zonkQuantifiedTyVar) -- (b) There are no via-Indirect occurrences of the bound variables -- in the types, because instantiation does not look through such things -- (c) The call to tyVarsOfTypes is ok without looking through refs tc_extend_local_id_env env th_lvl names_w_ids thing_inside = do { traceTc (text "env2") ; traceTc (text "env3" <+> ppr extra_env) ; gtvs' <- tc_extend_gtvs (tcl_tyvars env) extra_global_tyvars ; let env' = env {tcl_env = le', tcl_tyvars = gtvs', tcl_rdr = rdr_env'} ; setLclEnv env' thing_inside } where extra_global_tyvars = tcTyVarsOfTypes [idType id | (_,id) <- names_w_ids] extra_env = [ (name, ATcId { tct_id = id, tct_level = th_lvl, tct_type = id_ty, tct_co = case isRefineableTy id_ty of (True,_) -> Unrefineable (_,True) -> Rigid idHsWrapper _ -> Wobbly}) | (name,id) <- names_w_ids, let id_ty = idType id] le' = extendNameEnvList (tcl_env env) extra_env rdr_env' = extendLocalRdrEnvList (tcl_rdr env) [name | (name,_) <- names_w_ids] \end{code} \begin{code} ----------------------- -- findGlobals looks at the value environment and finds values -- whose types mention the offending type variable. It has to be -- careful to zonk the Id's type first, so it has to be in the monad. -- We must be careful to pass it a zonked type variable, too. findGlobals :: TcTyVarSet -> TidyEnv -> TcM (TidyEnv, [SDoc]) findGlobals tvs tidy_env = do lcl_env <- getLclEnv go tidy_env [] (lclEnvElts lcl_env) where go tidy_env acc [] = return (tidy_env, acc) go tidy_env acc (thing : things) = do (tidy_env1, maybe_doc) <- find_thing ignore_it tidy_env thing case maybe_doc of Just d -> go tidy_env1 (d:acc) things Nothing -> go tidy_env1 acc things ignore_it ty = tvs `disjointVarSet` tyVarsOfType ty ----------------------- find_thing :: (TcType -> Bool) -> TidyEnv -> TcTyThing -> TcM (TidyEnv, Maybe SDoc) find_thing ignore_it tidy_env (ATcId { tct_id = id }) = do id_ty <- zonkTcType (idType id) if ignore_it id_ty then return (tidy_env, Nothing) else let (tidy_env', tidy_ty) = tidyOpenType tidy_env id_ty msg = sep [ppr id <+> dcolon <+> ppr tidy_ty, nest 2 (parens (ptext (sLit "bound at") <+> ppr (getSrcLoc id)))] in return (tidy_env', Just msg) find_thing ignore_it tidy_env (ATyVar tv ty) = do tv_ty <- zonkTcType ty if ignore_it tv_ty then return (tidy_env, Nothing) else let -- The name tv is scoped, so we don't need to tidy it (tidy_env1, tidy_ty) = tidyOpenType tidy_env tv_ty msg = sep [ptext (sLit "Scoped type variable") <+> quotes (ppr tv) <+> eq_stuff, nest 2 bound_at] eq_stuff | Just tv' <- Type.getTyVar_maybe tv_ty, getOccName tv == getOccName tv' = empty | otherwise = equals <+> ppr tidy_ty -- It's ok to use Type.getTyVar_maybe because ty is zonked by now bound_at = parens $ ptext (sLit "bound at:") <+> ppr (getSrcLoc tv) in return (tidy_env1, Just msg) find_thing _ _ thing = pprPanic "find_thing" (ppr thing) \end{code} %************************************************************************ %* * \subsection{The global tyvars} %* * %************************************************************************ \begin{code} tc_extend_gtvs :: IORef VarSet -> VarSet -> TcM (IORef VarSet) tc_extend_gtvs gtvs extra_global_tvs = do global_tvs <- readMutVar gtvs newMutVar (global_tvs `unionVarSet` extra_global_tvs) \end{code} @tcGetGlobalTyVars@ returns a fully-zonked set of tyvars free in the environment. To improve subsequent calls to the same function it writes the zonked set back into the environment. \begin{code} tcGetGlobalTyVars :: TcM TcTyVarSet tcGetGlobalTyVars = do (TcLclEnv {tcl_tyvars = gtv_var}) <- getLclEnv gbl_tvs <- readMutVar gtv_var gbl_tvs' <- zonkTcTyVarsAndFV (varSetElems gbl_tvs) writeMutVar gtv_var gbl_tvs' return gbl_tvs' \end{code} %************************************************************************ %* * \subsection{Rules} %* * %************************************************************************ \begin{code} tcExtendRules :: [LRuleDecl Id] -> TcM a -> TcM a -- Just pop the new rules into the EPS and envt resp -- All the rules come from an interface file, not soruce -- Nevertheless, some may be for this module, if we read -- its interface instead of its source code tcExtendRules lcl_rules thing_inside = do { env <- getGblEnv ; let env' = env { tcg_rules = lcl_rules ++ tcg_rules env } ; setGblEnv env' thing_inside } \end{code} %************************************************************************ %* * Meta level %* * %************************************************************************ \begin{code} checkWellStaged :: SDoc -- What the stage check is for -> ThLevel -- Binding level (increases inside brackets) -> ThLevel -- Use stage -> TcM () -- Fail if badly staged, adding an error checkWellStaged pp_thing bind_lvl use_lvl | use_lvl >= bind_lvl -- OK! Used later than bound = return () -- E.g. \x -> [| $(f x) |] | bind_lvl == outerLevel -- GHC restriction on top level splices = failWithTc $ sep [ptext (sLit "GHC stage restriction:") <+> pp_thing, nest 2 (vcat [ ptext (sLit "is used in a top-level splice or annotation,") , ptext (sLit "and must be imported, not defined locally")])] | otherwise -- Badly staged = failWithTc $ -- E.g. \x -> $(f x) ptext (sLit "Stage error:") <+> pp_thing <+> hsep [ptext (sLit "is bound at stage") <+> ppr bind_lvl, ptext (sLit "but used at stage") <+> ppr use_lvl] topIdLvl :: Id -> ThLevel -- Globals may either be imported, or may be from an earlier "chunk" -- (separated by declaration splices) of this module. The former -- *can* be used inside a top-level splice, but the latter cannot. -- Hence we give the former impLevel, but the latter topLevel -- E.g. this is bad: -- x = [| foo |] -- $( f x ) -- By the time we are prcessing the $(f x), the binding for "x" -- will be in the global env, not the local one. topIdLvl id | isLocalId id = outerLevel | otherwise = impLevel tcMetaTy :: Name -> TcM Type -- Given the name of a Template Haskell data type, -- return the type -- E.g. given the name "Expr" return the type "Expr" tcMetaTy tc_name = do t <- tcLookupTyCon tc_name return (mkTyConApp t []) thRnBrack :: ThStage -- Used *only* to indicate that we are inside a TH bracket during renaming -- Tested by TcEnv.isBrackStage -- See Note [Top-level Names in Template Haskell decl quotes] thRnBrack = Brack (panic "thRnBrack1") (panic "thRnBrack2") (panic "thRnBrack3") isBrackStage :: ThStage -> Bool isBrackStage (Brack {}) = True isBrackStage _other = False thTopLevelId :: Id -> Bool -- See Note [What is a top-level Id?] in TcSplice thTopLevelId id = isGlobalId id || isExternalName (idName id) \end{code} %************************************************************************ %* * \subsection{The InstInfo type} %* * %************************************************************************ The InstInfo type summarises the information in an instance declaration instance c => k (t tvs) where b It is used just for *local* instance decls (not ones from interface files). But local instance decls includes - derived ones - generic ones as well as explicit user written ones. \begin{code} data InstInfo a = InstInfo { iSpec :: Instance, -- Includes the dfun id. Its forall'd type iBinds :: InstBindings a -- variables scope over the stuff in InstBindings! } iDFunId :: InstInfo a -> DFunId iDFunId info = instanceDFunId (iSpec info) data InstBindings a = VanillaInst -- The normal case (LHsBinds a) -- Bindings for the instance methods [LSig a] -- User pragmas recorded for generating -- specialised instances Bool -- True <=> This code came from a standalone deriving clause | NewTypeDerived -- Used for deriving instances of newtypes, where the -- witness dictionary is identical to the argument -- dictionary. Hence no bindings, no pragmas. CoercionI -- The coercion maps from newtype to the representation type -- (mentioning type variables bound by the forall'd iSpec variables) -- E.g. newtype instance N [a] = N1 (Tree a) -- co : N [a] ~ Tree a TyCon -- The TyCon is the newtype N. If it's indexed, then it's the -- representation TyCon, so that tyConDataCons returns [N1], -- the "data constructor". -- See Note [Newtype deriving and unused constructors] -- in TcDeriv pprInstInfo :: InstInfo a -> SDoc pprInstInfo info = vcat [ptext (sLit "InstInfo:") <+> ppr (idType (iDFunId info))] pprInstInfoDetails :: OutputableBndr a => InstInfo a -> SDoc pprInstInfoDetails info = pprInstInfo info $$ nest 2 (details (iBinds info)) where details (VanillaInst b _ _) = pprLHsBinds b details (NewTypeDerived {}) = text "Derived from the representation type" simpleInstInfoClsTy :: InstInfo a -> (Class, Type) simpleInstInfoClsTy info = case instanceHead (iSpec info) of (_, _, cls, [ty]) -> (cls, ty) _ -> panic "simpleInstInfoClsTy" simpleInstInfoTy :: InstInfo a -> Type simpleInstInfoTy info = snd (simpleInstInfoClsTy info) simpleInstInfoTyCon :: InstInfo a -> TyCon -- Gets the type constructor for a simple instance declaration, -- i.e. one of the form instance (...) => C (T a b c) where ... simpleInstInfoTyCon inst = tcTyConAppTyCon (simpleInstInfoTy inst) \end{code} Make a name for the dict fun for an instance decl. It's an *external* name, like otber top-level names, and hence must be made with newGlobalBinder. \begin{code} newDFunName :: Class -> [Type] -> SrcSpan -> TcM Name newDFunName clas tys loc = do { is_boot <- tcIsHsBoot ; mod <- getModule ; let info_string = occNameString (getOccName clas) ++ concatMap (occNameString.getDFunTyKey) tys ; dfun_occ <- chooseUniqueOccTc (mkDFunOcc info_string is_boot) ; newGlobalBinder mod dfun_occ loc } \end{code} Make a name for the representation tycon of a family instance. It's an *external* name, like otber top-level names, and hence must be made with newGlobalBinder. \begin{code} newFamInstTyConName :: Name -> [Type] -> SrcSpan -> TcM Name newFamInstTyConName tc_name tys loc = do { mod <- getModule ; let info_string = occNameString (getOccName tc_name) ++ concatMap (occNameString.getDFunTyKey) tys ; occ <- chooseUniqueOccTc (mkInstTyTcOcc info_string) ; newGlobalBinder mod occ loc } \end{code} Stable names used for foreign exports and annotations. For stable names, the name must be unique (see #1533). If the same thing has several stable Ids based on it, the top-level bindings generated must not have the same name. Hence we create an External name (doesn't change), and we append a Unique to the string right here. \begin{code} mkStableIdFromString :: String -> Type -> SrcSpan -> (OccName -> OccName) -> TcM TcId mkStableIdFromString str sig_ty loc occ_wrapper = do uniq <- newUnique mod <- getModule let uniq_str = showSDoc (pprUnique uniq) :: String occ = mkVarOcc (str ++ '_' : uniq_str) :: OccName gnm = mkExternalName uniq mod (occ_wrapper occ) loc :: Name id = mkExportedLocalId gnm sig_ty :: Id return id mkStableIdFromName :: Name -> Type -> SrcSpan -> (OccName -> OccName) -> TcM TcId mkStableIdFromName nm = mkStableIdFromString (getOccString nm) \end{code} %************************************************************************ %* * \subsection{Errors} %* * %************************************************************************ \begin{code} pprBinders :: [Name] -> SDoc -- Used in error messages -- Use quotes for a single one; they look a bit "busy" for several pprBinders [bndr] = quotes (ppr bndr) pprBinders bndrs = pprWithCommas ppr bndrs notFound :: Name -> TcGblEnv -> TcM TyThing notFound name env = failWithTc (vcat[ptext (sLit "GHC internal error:") <+> quotes (ppr name) <+> ptext (sLit "is not in scope during type checking, but it passed the renamer"), ptext (sLit "tcg_type_env of environment:") <+> ppr (tcg_type_env env)] ) wrongThingErr :: String -> TcTyThing -> Name -> TcM a wrongThingErr expected thing name = failWithTc (pprTcTyThingCategory thing <+> quotes (ppr name) <+> ptext (sLit "used as a") <+> text expected) \end{code}