% % (c) The GRASP/AQUA Project, Glasgow University, 1992-2006 % \section[RnEnv]{Environment manipulation for the renamer monad} \begin{code} {-# OPTIONS -w #-} -- The above warning supression flag is a temporary kludge. -- While working on this module you are encouraged to remove it and fix -- any warnings in the module. See -- http://hackage.haskell.org/trac/ghc/wiki/Commentary/CodingStyle#Warnings -- for details module RnEnv ( newTopSrcBinder, lookupFamInstDeclBndr, lookupLocatedBndrRn, lookupBndrRn, lookupLocatedTopBndrRn, lookupTopBndrRn, lookupLocatedOccRn, lookupOccRn, lookupLocatedGlobalOccRn, lookupGlobalOccRn, lookupLocalDataTcNames, lookupSrcOcc_maybe, lookupFixityRn, lookupTyFixityRn, lookupLocatedSigOccRn, lookupInstDeclBndr, lookupRecordBndr, lookupConstructorFields, lookupSyntaxName, lookupSyntaxTable, lookupImportedName, lookupGreRn, lookupGreRn_maybe, getLookupOccRn, newLocalsRn, newIPNameRn, bindLocalNames, bindLocalNamesFV, bindLocatedLocalsFV, bindLocatedLocalsRn, bindSigTyVarsFV, bindPatSigTyVars, bindPatSigTyVarsFV, bindTyVarsRn, extendTyVarEnvFVRn, bindLocalFixities, checkDupNames, mapFvRn, warnUnusedMatches, warnUnusedModules, warnUnusedImports, warnUnusedTopBinds, warnUnusedLocalBinds, dataTcOccs, unknownNameErr, ) where #include "HsVersions.h" import LoadIface ( loadInterfaceForName, loadSrcInterface ) import IfaceEnv ( lookupOrig, newGlobalBinder, newIPName ) import HsSyn ( FixitySig(..), HsExpr(..), SyntaxExpr, SyntaxTable, LHsTyVarBndr, LHsType, Fixity, hsLTyVarLocNames, replaceTyVarName ) import RdrHsSyn ( extractHsTyRdrTyVars ) import RdrName ( RdrName, isQual, isUnqual, isOrig_maybe, isQual_maybe, mkRdrUnqual, setRdrNameSpace, rdrNameOcc, pprGlobalRdrEnv, lookupGRE_RdrName, isExact_maybe, isSrcRdrName, Parent(..), GlobalRdrElt(..), GlobalRdrEnv, lookupGlobalRdrEnv, isLocalGRE, extendLocalRdrEnv, elemLocalRdrEnv, lookupLocalRdrEnv, Provenance(..), pprNameProvenance, importSpecLoc, importSpecModule ) import HscTypes ( availNames, ModIface(..), FixItem(..), lookupFixity ) import TcEnv ( tcLookupDataCon ) import TcRnMonad import Name ( Name, nameIsLocalOrFrom, mkInternalName, isWiredInName, nameSrcLoc, nameOccName, nameModule, isExternalName ) import NameSet import NameEnv import DataCon ( dataConFieldLabels ) import OccName ( tcName, isDataOcc, pprNonVarNameSpace, occNameSpace, reportIfUnused ) import Module ( Module, ModuleName ) import PrelNames ( mkUnboundName, rOOT_MAIN, iNTERACTIVE, consDataConKey, hasKey ) import UniqSupply import BasicTypes ( IPName, mapIPName ) import SrcLoc ( SrcSpan, srcSpanStart, Located(..), eqLocated, unLoc, srcLocSpan, getLoc, combineSrcSpans, isOneLineSpan ) import Outputable import Util ( sortLe ) import Maybes import ListSetOps ( removeDups ) import List ( nubBy ) import Monad ( when ) import DynFlags \end{code} %********************************************************* %* * Source-code binders %* * %********************************************************* \begin{code} newTopSrcBinder :: Module -> Located RdrName -> RnM Name newTopSrcBinder this_mod (L loc rdr_name) | Just name <- isExact_maybe rdr_name = -- This is here to catch -- (a) Exact-name binders created by Template Haskell -- (b) The PrelBase defn of (say) [] and similar, for which -- the parser reads the special syntax and returns an Exact RdrName -- We are at a binding site for the name, so check first that it -- the current module is the correct one; otherwise GHC can get -- very confused indeed. This test rejects code like -- data T = (,) Int Int -- unless we are in GHC.Tup ASSERT2( isExternalName name, ppr name ) do { checkM (this_mod == nameModule name) (addErrAt loc (badOrigBinding rdr_name)) ; return name } | Just (rdr_mod, rdr_occ) <- isOrig_maybe rdr_name = do { checkM (rdr_mod == this_mod || rdr_mod == rOOT_MAIN) (addErrAt loc (badOrigBinding rdr_name)) -- When reading External Core we get Orig names as binders, -- but they should agree with the module gotten from the monad -- -- We can get built-in syntax showing up here too, sadly. If you type -- data T = (,,,) -- the constructor is parsed as a type, and then RdrHsSyn.tyConToDataCon -- uses setRdrNameSpace to make it into a data constructors. At that point -- the nice Exact name for the TyCon gets swizzled to an Orig name. -- Hence the badOrigBinding error message. -- -- Except for the ":Main.main = ..." definition inserted into -- the Main module; ugh! -- Because of this latter case, we call newGlobalBinder with a module from -- the RdrName, not from the environment. In principle, it'd be fine to -- have an arbitrary mixture of external core definitions in a single module, -- (apart from module-initialisation issues, perhaps). ; newGlobalBinder rdr_mod rdr_occ loc } --TODO, should pass the whole span | otherwise = do { checkM (not (isQual rdr_name)) (addErrAt loc (badQualBndrErr rdr_name)) -- Binders should not be qualified; if they are, and with a different -- module name, we we get a confusing "M.T is not in scope" error later ; newGlobalBinder this_mod (rdrNameOcc rdr_name) loc } \end{code} %********************************************************* %* * Source code occurrences %* * %********************************************************* Looking up a name in the RnEnv. \begin{code} lookupLocatedBndrRn :: Located RdrName -> RnM (Located Name) lookupLocatedBndrRn = wrapLocM lookupBndrRn lookupBndrRn :: RdrName -> RnM Name -- NOTE: assumes that the SrcSpan of the binder has already been setSrcSpan'd lookupBndrRn rdr_name = getLocalRdrEnv `thenM` \ local_env -> case lookupLocalRdrEnv local_env rdr_name of Just name -> returnM name Nothing -> lookupTopBndrRn rdr_name lookupLocatedTopBndrRn :: Located RdrName -> RnM (Located Name) lookupLocatedTopBndrRn = wrapLocM lookupTopBndrRn lookupTopBndrRn :: RdrName -> RnM Name -- Look up a top-level source-code binder. We may be looking up an unqualified 'f', -- and there may be several imported 'f's too, which must not confuse us. -- For example, this is OK: -- import Foo( f ) -- infix 9 f -- The 'f' here does not need to be qualified -- f x = x -- Nor here, of course -- So we have to filter out the non-local ones. -- -- A separate function (importsFromLocalDecls) reports duplicate top level -- decls, so here it's safe just to choose an arbitrary one. -- -- There should never be a qualified name in a binding position in Haskell, -- but there can be if we have read in an external-Core file. -- The Haskell parser checks for the illegal qualified name in Haskell -- source files, so we don't need to do so here. lookupTopBndrRn rdr_name | Just name <- isExact_maybe rdr_name = returnM name | Just (rdr_mod, rdr_occ) <- isOrig_maybe rdr_name -- This deals with the case of derived bindings, where -- we don't bother to call newTopSrcBinder first -- We assume there is no "parent" name = do { loc <- getSrcSpanM ; newGlobalBinder rdr_mod rdr_occ loc } | otherwise = do { mb_gre <- lookupGreLocalRn rdr_name ; case mb_gre of Nothing -> do traceRn $ text "lookupTopBndrRn" unboundName rdr_name Just gre -> returnM (gre_name gre) } -- lookupLocatedSigOccRn is used for type signatures and pragmas -- Is this valid? -- module A -- import M( f ) -- f :: Int -> Int -- f x = x -- It's clear that the 'f' in the signature must refer to A.f -- The Haskell98 report does not stipulate this, but it will! -- So we must treat the 'f' in the signature in the same way -- as the binding occurrence of 'f', using lookupBndrRn -- -- However, consider this case: -- import M( f ) -- f :: Int -> Int -- g x = x -- We don't want to say 'f' is out of scope; instead, we want to -- return the imported 'f', so that later on the reanamer will -- correctly report "misplaced type sig". lookupLocatedSigOccRn :: Located RdrName -> RnM (Located Name) lookupLocatedSigOccRn = wrapLocM $ \ rdr_name -> do { local_env <- getLocalRdrEnv ; case lookupLocalRdrEnv local_env rdr_name of { Just n -> return n ; Nothing -> do { mb_gre <- lookupGreLocalRn rdr_name ; case mb_gre of Just gre -> return (gre_name gre) Nothing -> lookupGlobalOccRn rdr_name }}} ----------------------------------------------- lookupInstDeclBndr :: Name -> Located RdrName -> RnM (Located Name) -- This is called on the method name on the left-hand side of an -- instance declaration binding. eg. instance Functor T where -- fmap = ... -- ^^^^ called on this -- Regardless of how many unqualified fmaps are in scope, we want -- the one that comes from the Functor class. -- -- Furthermore, note that we take no account of whether the -- name is only in scope qualified. I.e. even if method op is -- in scope as M.op, we still allow plain 'op' on the LHS of -- an instance decl lookupInstDeclBndr cls rdr = lookup_located_sub_bndr is_op doc rdr where doc = ptext SLIT("method of class") <+> quotes (ppr cls) is_op gre@(GRE {gre_par = ParentIs n}) = n == cls is_op other = False ----------------------------------------------- lookupRecordBndr :: Maybe (Located Name) -> Located RdrName -> RnM (Located Name) -- Used for record construction and pattern matching -- When the -fdisambiguate-record-fields flag is on, take account of the -- constructor name to disambiguate which field to use; it's just the -- same as for instance decls lookupRecordBndr Nothing rdr_name = lookupLocatedGlobalOccRn rdr_name lookupRecordBndr (Just (L _ data_con)) rdr_name = do { flag_on <- doptM Opt_DisambiguateRecordFields ; if not flag_on then lookupLocatedGlobalOccRn rdr_name else do { fields <- lookupConstructorFields data_con ; let is_field gre = gre_name gre `elem` fields ; lookup_located_sub_bndr is_field doc rdr_name }} where doc = ptext SLIT("field of constructor") <+> quotes (ppr data_con) lookupConstructorFields :: Name -> RnM [Name] -- Look up the fields of a given constructor -- * For constructors from this module, use the record field env, -- which is itself gathered from the (as yet un-typechecked) -- data type decls -- -- * For constructors from imported modules, use the *type* environment -- since imported modles are already compiled, the info is conveniently -- right there lookupConstructorFields con_name = do { this_mod <- getModule ; if nameIsLocalOrFrom this_mod con_name then do { field_env <- getRecFieldEnv ; return (lookupNameEnv field_env con_name `orElse` []) } else do { con <- tcLookupDataCon con_name ; return (dataConFieldLabels con) } } ----------------------------------------------- lookup_located_sub_bndr :: (GlobalRdrElt -> Bool) -> SDoc -> Located RdrName -> RnM (Located Name) lookup_located_sub_bndr is_good doc rdr_name = wrapLocM (lookup_sub_bndr is_good doc) rdr_name lookup_sub_bndr is_good doc rdr_name | isUnqual rdr_name -- Find all the things the rdr-name maps to = do { -- and pick the one with the right parent name ; env <- getGlobalRdrEnv ; case filter is_good (lookupGlobalRdrEnv env (rdrNameOcc rdr_name)) of -- NB: lookupGlobalRdrEnv, not lookupGRE_RdrName! -- The latter does pickGREs, but we want to allow 'x' -- even if only 'M.x' is in scope [gre] -> return (gre_name gre) [] -> do { addErr (unknownSubordinateErr doc rdr_name) ; traceRn (text "RnEnv.lookup_sub_bndr" <+> ppr rdr_name) ; return (mkUnboundName rdr_name) } gres -> do { addNameClashErrRn rdr_name gres ; return (gre_name (head gres)) } } | otherwise -- Occurs in derived instances, where we just -- refer directly to the right method = ASSERT2( not (isQual rdr_name), ppr rdr_name ) -- NB: qualified names are rejected by the parser lookupImportedName rdr_name newIPNameRn :: IPName RdrName -> TcRnIf m n (IPName Name) newIPNameRn ip_rdr = newIPName (mapIPName rdrNameOcc ip_rdr) -- Looking up family names in type instances is a subtle affair. The family -- may be imported, in which case we need to lookup the occurence of a global -- name. Alternatively, the family may be in the same binding group (and in -- fact in a declaration processed later), and we need to create a new top -- source binder. -- -- So, also this is strictly speaking an occurence, we cannot raise an error -- message yet for instances without a family declaration. This will happen -- during renaming the type instance declaration in RnSource.rnTyClDecl. -- lookupFamInstDeclBndr :: Module -> Located RdrName -> RnM Name lookupFamInstDeclBndr mod lrdr_name@(L _ rdr_name) = do { mb_gre <- lookupGreRn_maybe rdr_name ; case mb_gre of Just gre -> returnM (gre_name gre) ; Nothing -> newTopSrcBinder mod lrdr_name } -------------------------------------------------- -- Occurrences -------------------------------------------------- getLookupOccRn :: RnM (Name -> Maybe Name) getLookupOccRn = getLocalRdrEnv `thenM` \ local_env -> return (lookupLocalRdrEnv local_env . mkRdrUnqual . nameOccName) lookupLocatedOccRn :: Located RdrName -> RnM (Located Name) lookupLocatedOccRn = wrapLocM lookupOccRn -- lookupOccRn looks up an occurrence of a RdrName lookupOccRn :: RdrName -> RnM Name lookupOccRn rdr_name = getLocalRdrEnv `thenM` \ local_env -> case lookupLocalRdrEnv local_env rdr_name of Just name -> returnM name Nothing -> lookupGlobalOccRn rdr_name lookupLocatedGlobalOccRn :: Located RdrName -> RnM (Located Name) lookupLocatedGlobalOccRn = wrapLocM lookupGlobalOccRn lookupGlobalOccRn :: RdrName -> RnM Name -- lookupGlobalOccRn is like lookupOccRn, except that it looks in the global -- environment. It's used only for -- record field names -- class op names in class and instance decls lookupGlobalOccRn rdr_name | not (isSrcRdrName rdr_name) = lookupImportedName rdr_name | otherwise = -- First look up the name in the normal environment. lookupGreRn_maybe rdr_name `thenM` \ mb_gre -> case mb_gre of { Just gre -> returnM (gre_name gre) ; Nothing -> -- We allow qualified names on the command line to refer to -- *any* name exported by any module in scope, just as if -- there was an "import qualified M" declaration for every -- module. getModule `thenM` \ mod -> if isQual rdr_name && mod == iNTERACTIVE then -- This test is not expensive, lookupQualifiedName rdr_name -- and only happens for failed lookups else do traceRn $ text "lookupGlobalOccRn" unboundName rdr_name } lookupImportedName :: RdrName -> TcRnIf m n Name -- Lookup the occurrence of an imported name -- The RdrName is *always* qualified or Exact -- Treat it as an original name, and conjure up the Name -- Usually it's Exact or Orig, but it can be Qual if it -- comes from an hi-boot file. (This minor infelicity is -- just to reduce duplication in the parser.) lookupImportedName rdr_name | Just n <- isExact_maybe rdr_name -- This happens in derived code = returnM n -- Always Orig, even when reading a .hi-boot file | Just (rdr_mod, rdr_occ) <- isOrig_maybe rdr_name = lookupOrig rdr_mod rdr_occ | otherwise = pprPanic "RnEnv.lookupImportedName" (ppr rdr_name) unboundName :: RdrName -> RnM Name unboundName rdr_name = do { addErr (unknownNameErr rdr_name) ; env <- getGlobalRdrEnv; ; traceRn (vcat [unknownNameErr rdr_name, ptext SLIT("Global envt is:"), nest 3 (pprGlobalRdrEnv env)]) ; returnM (mkUnboundName rdr_name) } -------------------------------------------------- -- Lookup in the Global RdrEnv of the module -------------------------------------------------- lookupSrcOcc_maybe :: RdrName -> RnM (Maybe Name) -- No filter function; does not report an error on failure lookupSrcOcc_maybe rdr_name = do { mb_gre <- lookupGreRn_maybe rdr_name ; case mb_gre of Nothing -> returnM Nothing Just gre -> returnM (Just (gre_name gre)) } ------------------------- lookupGreRn_maybe :: RdrName -> RnM (Maybe GlobalRdrElt) -- Just look up the RdrName in the GlobalRdrEnv lookupGreRn_maybe rdr_name = lookupGreRn_help rdr_name (lookupGRE_RdrName rdr_name) lookupGreRn :: RdrName -> RnM GlobalRdrElt -- If not found, add error message, and return a fake GRE lookupGreRn rdr_name = do { mb_gre <- lookupGreRn_maybe rdr_name ; case mb_gre of { Just gre -> return gre ; Nothing -> do { traceRn $ text "lookupGreRn" ; name <- unboundName rdr_name ; return (GRE { gre_name = name, gre_par = NoParent, gre_prov = LocalDef }) }}} lookupGreLocalRn :: RdrName -> RnM (Maybe GlobalRdrElt) -- Similar, but restricted to locally-defined things lookupGreLocalRn rdr_name = lookupGreRn_help rdr_name lookup_fn where lookup_fn env = filter isLocalGRE (lookupGRE_RdrName rdr_name env) lookupGreRn_help :: RdrName -- Only used in error message -> (GlobalRdrEnv -> [GlobalRdrElt]) -- Lookup function -> RnM (Maybe GlobalRdrElt) -- Checks for exactly one match; reports deprecations -- Returns Nothing, without error, if too few lookupGreRn_help rdr_name lookup = do { env <- getGlobalRdrEnv ; case lookup env of [] -> returnM Nothing [gre] -> returnM (Just gre) gres -> do { addNameClashErrRn rdr_name gres ; returnM (Just (head gres)) } } ------------------------------ -- GHCi support ------------------------------ -- A qualified name on the command line can refer to any module at all: we -- try to load the interface if we don't already have it. lookupQualifiedName :: RdrName -> RnM Name lookupQualifiedName rdr_name | Just (mod,occ) <- isQual_maybe rdr_name -- Note: we want to behave as we would for a source file import here, -- and respect hiddenness of modules/packages, hence loadSrcInterface. = loadSrcInterface doc mod False `thenM` \ iface -> case [ (mod,occ) | (mod,avails) <- mi_exports iface, avail <- avails, name <- availNames avail, name == occ ] of ((mod,occ):ns) -> ASSERT (null ns) lookupOrig mod occ _ -> unboundName rdr_name | otherwise = pprPanic "RnEnv.lookupQualifiedName" (ppr rdr_name) where doc = ptext SLIT("Need to find") <+> ppr rdr_name \end{code} %********************************************************* %* * Fixities %* * %********************************************************* \begin{code} lookupLocalDataTcNames :: RdrName -> RnM [Name] -- GHC extension: look up both the tycon and data con -- for con-like things -- Complain if neither is in scope lookupLocalDataTcNames rdr_name | Just n <- isExact_maybe rdr_name -- Special case for (:), which doesn't get into the GlobalRdrEnv = return [n] -- For this we don't need to try the tycon too | otherwise = do { mb_gres <- mapM lookupGreLocalRn (dataTcOccs rdr_name) ; case [gre_name gre | Just gre <- mb_gres] of [] -> do { addErr (unknownNameErr rdr_name) ; return [] } names -> return names } -------------------------------- bindLocalFixities :: [FixitySig RdrName] -> RnM a -> RnM a -- Used for nested fixity decls -- No need to worry about type constructors here, -- Should check for duplicates but we don't bindLocalFixities fixes thing_inside | null fixes = thing_inside | otherwise = mappM rn_sig fixes `thenM` \ new_bit -> extendFixityEnv new_bit thing_inside where rn_sig (FixitySig lv@(L loc v) fix) = addLocM lookupBndrRn lv `thenM` \ new_v -> returnM (new_v, (FixItem (rdrNameOcc v) fix loc)) \end{code} -------------------------------- lookupFixity is a bit strange. * Nested local fixity decls are put in the local fixity env, which we find with getFixtyEnv * Imported fixities are found in the HIT or PIT * Top-level fixity decls in this module may be for Names that are either Global (constructors, class operations) or Local/Exported (everything else) (See notes with RnNames.getLocalDeclBinders for why we have this split.) We put them all in the local fixity environment \begin{code} lookupFixityRn :: Name -> RnM Fixity lookupFixityRn name = getModule `thenM` \ this_mod -> if nameIsLocalOrFrom this_mod name then -- It's defined in this module getFixityEnv `thenM` \ local_fix_env -> traceRn (text "lookupFixityRn" <+> (ppr name $$ ppr local_fix_env)) `thenM_` returnM (lookupFixity local_fix_env name) else -- It's imported -- For imported names, we have to get their fixities by doing a -- loadInterfaceForName, and consulting the Ifaces that comes back -- from that, because the interface file for the Name might not -- have been loaded yet. Why not? Suppose you import module A, -- which exports a function 'f', thus; -- module CurrentModule where -- import A( f ) -- module A( f ) where -- import B( f ) -- Then B isn't loaded right away (after all, it's possible that -- nothing from B will be used). When we come across a use of -- 'f', we need to know its fixity, and it's then, and only -- then, that we load B.hi. That is what's happening here. -- -- loadInterfaceForName will find B.hi even if B is a hidden module, -- and that's what we want. loadInterfaceForName doc name `thenM` \ iface -> returnM (mi_fix_fn iface (nameOccName name)) where doc = ptext SLIT("Checking fixity for") <+> ppr name --------------- lookupTyFixityRn :: Located Name -> RnM Fixity lookupTyFixityRn (L loc n) = lookupFixityRn n --------------- dataTcOccs :: RdrName -> [RdrName] -- If the input is a data constructor, return both it and a type -- constructor. This is useful when we aren't sure which we are -- looking at. dataTcOccs rdr_name | Just n <- isExact_maybe rdr_name -- Ghastly special case , n `hasKey` consDataConKey = [rdr_name] -- see note below | isDataOcc occ = [rdr_name_tc, rdr_name] | otherwise = [rdr_name] where occ = rdrNameOcc rdr_name rdr_name_tc = setRdrNameSpace rdr_name tcName -- If the user typed "[]" or "(,,)", we'll generate an Exact RdrName, -- and setRdrNameSpace generates an Orig, which is fine -- But it's not fine for (:), because there *is* no corresponding type -- constructor. If we generate an Orig tycon for GHC.Base.(:), it'll -- appear to be in scope (because Orig's simply allocate a new name-cache -- entry) and then we get an error when we use dataTcOccs in -- TcRnDriver.tcRnGetInfo. Large sigh. \end{code} %************************************************************************ %* * Rebindable names Dealing with rebindable syntax is driven by the Opt_NoImplicitPrelude dynamic flag. In "deriving" code we don't want to use rebindable syntax so we switch off the flag locally %* * %************************************************************************ Haskell 98 says that when you say "3" you get the "fromInteger" from the Standard Prelude, regardless of what is in scope. However, to experiment with having a language that is less coupled to the standard prelude, we're trying a non-standard extension that instead gives you whatever "Prelude.fromInteger" happens to be in scope. Then you can import Prelude () import MyPrelude as Prelude to get the desired effect. At the moment this just happens for * fromInteger, fromRational on literals (in expressions and patterns) * negate (in expressions) * minus (arising from n+k patterns) * "do" notation We store the relevant Name in the HsSyn tree, in * HsIntegral/HsFractional/HsIsString * NegApp * NPlusKPat * HsDo respectively. Initially, we just store the "standard" name (PrelNames.fromIntegralName, fromRationalName etc), but the renamer changes this to the appropriate user name if Opt_NoImplicitPrelude is on. That is what lookupSyntaxName does. We treat the orignal (standard) names as free-vars too, because the type checker checks the type of the user thing against the type of the standard thing. \begin{code} lookupSyntaxName :: Name -- The standard name -> RnM (SyntaxExpr Name, FreeVars) -- Possibly a non-standard name lookupSyntaxName std_name = doptM Opt_ImplicitPrelude `thenM` \ implicit_prelude -> if implicit_prelude then normal_case else -- Get the similarly named thing from the local environment lookupOccRn (mkRdrUnqual (nameOccName std_name)) `thenM` \ usr_name -> returnM (HsVar usr_name, unitFV usr_name) where normal_case = returnM (HsVar std_name, emptyFVs) lookupSyntaxTable :: [Name] -- Standard names -> RnM (SyntaxTable Name, FreeVars) -- See comments with HsExpr.ReboundNames lookupSyntaxTable std_names = doptM Opt_ImplicitPrelude `thenM` \ implicit_prelude -> if implicit_prelude then normal_case else -- Get the similarly named thing from the local environment mappM (lookupOccRn . mkRdrUnqual . nameOccName) std_names `thenM` \ usr_names -> returnM (std_names `zip` map HsVar usr_names, mkFVs usr_names) where normal_case = returnM (std_names `zip` map HsVar std_names, emptyFVs) \end{code} %********************************************************* %* * \subsection{Binding} %* * %********************************************************* \begin{code} newLocalsRn :: [Located RdrName] -> RnM [Name] newLocalsRn rdr_names_w_loc = newUniqueSupply `thenM` \ us -> returnM (zipWith mk rdr_names_w_loc (uniqsFromSupply us)) where mk (L loc rdr_name) uniq | Just name <- isExact_maybe rdr_name = name -- This happens in code generated by Template Haskell | otherwise = ASSERT2( isUnqual rdr_name, ppr rdr_name ) -- We only bind unqualified names here -- lookupRdrEnv doesn't even attempt to look up a qualified RdrName mkInternalName uniq (rdrNameOcc rdr_name) loc bindLocatedLocalsRn :: SDoc -- Documentation string for error message -> [Located RdrName] -> ([Name] -> RnM a) -> RnM a bindLocatedLocalsRn doc_str rdr_names_w_loc enclosed_scope = -- Check for duplicate names checkDupNames doc_str rdr_names_w_loc `thenM_` -- Warn about shadowing, but only in source modules ifOptM Opt_WarnNameShadowing (checkShadowing doc_str rdr_names_w_loc) `thenM_` -- Make fresh Names and extend the environment newLocalsRn rdr_names_w_loc `thenM` \ names -> getLocalRdrEnv `thenM` \ local_env -> setLocalRdrEnv (extendLocalRdrEnv local_env names) (enclosed_scope names) bindLocalNames :: [Name] -> RnM a -> RnM a bindLocalNames names enclosed_scope = getLocalRdrEnv `thenM` \ name_env -> setLocalRdrEnv (extendLocalRdrEnv name_env names) enclosed_scope bindLocalNamesFV :: [Name] -> RnM (a, FreeVars) -> RnM (a, FreeVars) bindLocalNamesFV names enclosed_scope = do { (result, fvs) <- bindLocalNames names enclosed_scope ; returnM (result, delListFromNameSet fvs names) } ------------------------------------- -- binLocalsFVRn is the same as bindLocalsRn -- except that it deals with free vars bindLocatedLocalsFV :: SDoc -> [Located RdrName] -> ([Name] -> RnM (a,FreeVars)) -> RnM (a, FreeVars) bindLocatedLocalsFV doc rdr_names enclosed_scope = bindLocatedLocalsRn doc rdr_names $ \ names -> enclosed_scope names `thenM` \ (thing, fvs) -> returnM (thing, delListFromNameSet fvs names) ------------------------------------- bindTyVarsRn :: SDoc -> [LHsTyVarBndr RdrName] -> ([LHsTyVarBndr Name] -> RnM a) -> RnM a -- Haskell-98 binding of type variables; e.g. within a data type decl bindTyVarsRn doc_str tyvar_names enclosed_scope = let located_tyvars = hsLTyVarLocNames tyvar_names in bindLocatedLocalsRn doc_str located_tyvars $ \ names -> enclosed_scope (zipWith replace tyvar_names names) where replace (L loc n1) n2 = L loc (replaceTyVarName n1 n2) bindPatSigTyVars :: [LHsType RdrName] -> ([Name] -> RnM a) -> RnM a -- Find the type variables in the pattern type -- signatures that must be brought into scope bindPatSigTyVars tys thing_inside = do { scoped_tyvars <- doptM Opt_ScopedTypeVariables ; if not scoped_tyvars then thing_inside [] else do { name_env <- getLocalRdrEnv ; let locd_tvs = [ tv | ty <- tys , tv <- extractHsTyRdrTyVars ty , not (unLoc tv `elemLocalRdrEnv` name_env) ] nubbed_tvs = nubBy eqLocated locd_tvs -- The 'nub' is important. For example: -- f (x :: t) (y :: t) = .... -- We don't want to complain about binding t twice! ; bindLocatedLocalsRn doc_sig nubbed_tvs thing_inside }} where doc_sig = text "In a pattern type-signature" bindPatSigTyVarsFV :: [LHsType RdrName] -> RnM (a, FreeVars) -> RnM (a, FreeVars) bindPatSigTyVarsFV tys thing_inside = bindPatSigTyVars tys $ \ tvs -> thing_inside `thenM` \ (result,fvs) -> returnM (result, fvs `delListFromNameSet` tvs) bindSigTyVarsFV :: [Name] -> RnM (a, FreeVars) -> RnM (a, FreeVars) bindSigTyVarsFV tvs thing_inside = do { scoped_tyvars <- doptM Opt_ScopedTypeVariables ; if not scoped_tyvars then thing_inside else bindLocalNamesFV tvs thing_inside } extendTyVarEnvFVRn :: [Name] -> RnM (a, FreeVars) -> RnM (a, FreeVars) -- This function is used only in rnSourceDecl on InstDecl extendTyVarEnvFVRn tyvars thing_inside = bindLocalNamesFV tyvars thing_inside ------------------------------------- checkDupNames :: SDoc -> [Located RdrName] -> RnM () checkDupNames doc_str rdr_names_w_loc = -- Check for duplicated names in a binding group mappM_ (dupNamesErr doc_str) dups where (_, dups) = removeDups (\n1 n2 -> unLoc n1 `compare` unLoc n2) rdr_names_w_loc ------------------------------------- checkShadowing doc_str loc_rdr_names = getLocalRdrEnv `thenM` \ local_env -> getGlobalRdrEnv `thenM` \ global_env -> let check_shadow (L loc rdr_name) | rdr_name `elemLocalRdrEnv` local_env || not (null (lookupGRE_RdrName rdr_name global_env )) = addWarnAt loc (shadowedNameWarn doc_str rdr_name) | otherwise = returnM () in mappM_ check_shadow loc_rdr_names \end{code} %************************************************************************ %* * \subsection{Free variable manipulation} %* * %************************************************************************ \begin{code} -- A useful utility mapFvRn f xs = mappM f xs `thenM` \ stuff -> let (ys, fvs_s) = unzip stuff in returnM (ys, plusFVs fvs_s) \end{code} %************************************************************************ %* * \subsection{Envt utility functions} %* * %************************************************************************ \begin{code} warnUnusedModules :: [(ModuleName,SrcSpan)] -> RnM () warnUnusedModules mods = ifOptM Opt_WarnUnusedImports (mappM_ bleat mods) where bleat (mod,loc) = addWarnAt loc (mk_warn mod) mk_warn m = vcat [ptext SLIT("Module") <+> quotes (ppr m) <+> text "is imported, but nothing from it is used,", nest 2 (ptext SLIT("except perhaps instances visible in") <+> quotes (ppr m)), ptext SLIT("To suppress this warning, use:") <+> ptext SLIT("import") <+> ppr m <> parens empty ] warnUnusedImports, warnUnusedTopBinds :: [GlobalRdrElt] -> RnM () warnUnusedImports gres = ifOptM Opt_WarnUnusedImports (warnUnusedGREs gres) warnUnusedTopBinds gres = ifOptM Opt_WarnUnusedBinds (warnUnusedGREs gres) warnUnusedLocalBinds, warnUnusedMatches :: [Name] -> RnM () warnUnusedLocalBinds names = ifOptM Opt_WarnUnusedBinds (warnUnusedLocals names) warnUnusedMatches names = ifOptM Opt_WarnUnusedMatches (warnUnusedLocals names) ------------------------- -- Helpers warnUnusedGREs gres = warnUnusedBinds [(n,p) | GRE {gre_name = n, gre_prov = p} <- gres] warnUnusedLocals names = warnUnusedBinds [(n,LocalDef) | n<-names] warnUnusedBinds :: [(Name,Provenance)] -> RnM () warnUnusedBinds names = mappM_ warnUnusedName (filter reportable names) where reportable (name,_) | isWiredInName name = False -- Don't report unused wired-in names -- Otherwise we get a zillion warnings -- from Data.Tuple | otherwise = reportIfUnused (nameOccName name) ------------------------- warnUnusedName :: (Name, Provenance) -> RnM () warnUnusedName (name, LocalDef) = addUnusedWarning name (srcLocSpan (nameSrcLoc name)) (ptext SLIT("Defined but not used")) warnUnusedName (name, Imported is) = mapM_ warn is where warn spec = addUnusedWarning name span msg where span = importSpecLoc spec pp_mod = quotes (ppr (importSpecModule spec)) msg = ptext SLIT("Imported from") <+> pp_mod <+> ptext SLIT("but not used") addUnusedWarning name span msg = addWarnAt span $ sep [msg <> colon, nest 2 $ pprNonVarNameSpace (occNameSpace (nameOccName name)) <+> quotes (ppr name)] \end{code} \begin{code} addNameClashErrRn rdr_name names = addErr (vcat [ptext SLIT("Ambiguous occurrence") <+> quotes (ppr rdr_name), ptext SLIT("It could refer to") <+> vcat (msg1 : msgs)]) where (np1:nps) = names msg1 = ptext SLIT("either") <+> mk_ref np1 msgs = [ptext SLIT(" or") <+> mk_ref np | np <- nps] mk_ref gre = quotes (ppr (gre_name gre)) <> comma <+> pprNameProvenance gre shadowedNameWarn doc shadow = hsep [ptext SLIT("This binding for"), quotes (ppr shadow), ptext SLIT("shadows an existing binding")] $$ doc unknownNameErr rdr_name = sep [ptext SLIT("Not in scope:"), nest 2 $ pprNonVarNameSpace (occNameSpace (rdrNameOcc rdr_name)) <+> quotes (ppr rdr_name)] unknownSubordinateErr doc op -- Doc is "method of class" or -- "field of constructor" = quotes (ppr op) <+> ptext SLIT("is not a (visible)") <+> doc badOrigBinding name = ptext SLIT("Illegal binding of built-in syntax:") <+> ppr (rdrNameOcc name) -- The rdrNameOcc is because we don't want to print Prelude.(,) dupNamesErr :: SDoc -> [Located RdrName] -> RnM () dupNamesErr descriptor located_names = addErrAt big_loc $ vcat [ptext SLIT("Conflicting definitions for") <+> quotes (ppr name1), locations, descriptor] where L _ name1 = head located_names locs = map getLoc located_names big_loc = foldr1 combineSrcSpans locs one_line = isOneLineSpan big_loc locations | one_line = empty | otherwise = ptext SLIT("Bound at:") <+> vcat (map ppr (sortLe (<=) locs)) badQualBndrErr rdr_name = ptext SLIT("Qualified name in binding position:") <+> ppr rdr_name \end{code}