{- (c) The University of Glasgow 2006 (c) The GRASP/AQUA Project, Glasgow University, 1992-1998 -} {-# LANGUAGE CPP, DeriveDataTypeable #-} -- | -- #name_types# -- GHC uses several kinds of name internally: -- -- * 'OccName.OccName': see "OccName#name_types" -- -- * 'RdrName.RdrName' is the type of names that come directly from the parser. They -- have not yet had their scoping and binding resolved by the renamer and can be -- thought of to a first approximation as an 'OccName.OccName' with an optional module -- qualifier -- -- * 'Name.Name': see "Name#name_types" -- -- * 'Id.Id': see "Id#name_types" -- -- * 'Var.Var': see "Var#name_types" module RdrName ( -- * The main type RdrName(..), -- Constructors exported only to BinIface -- ** Construction mkRdrUnqual, mkRdrQual, mkUnqual, mkVarUnqual, mkQual, mkOrig, nameRdrName, getRdrName, -- ** Destruction rdrNameOcc, rdrNameSpace, demoteRdrName, isRdrDataCon, isRdrTyVar, isRdrTc, isQual, isQual_maybe, isUnqual, isOrig, isOrig_maybe, isExact, isExact_maybe, isSrcRdrName, -- * Local mapping of 'RdrName' to 'Name.Name' LocalRdrEnv, emptyLocalRdrEnv, extendLocalRdrEnv, extendLocalRdrEnvList, lookupLocalRdrEnv, lookupLocalRdrOcc, elemLocalRdrEnv, inLocalRdrEnvScope, localRdrEnvElts, delLocalRdrEnvList, -- * Global mapping of 'RdrName' to 'GlobalRdrElt's GlobalRdrEnv, emptyGlobalRdrEnv, mkGlobalRdrEnv, plusGlobalRdrEnv, lookupGlobalRdrEnv, extendGlobalRdrEnv, greOccName, shadowNames, pprGlobalRdrEnv, globalRdrEnvElts, lookupGRE_RdrName, lookupGRE_Name, lookupGRE_FieldLabel, lookupGRE_Name_OccName, getGRE_NameQualifier_maybes, transformGREs, pickGREs, pickGREsModExp, -- * GlobalRdrElts gresFromAvails, gresFromAvail, localGREsFromAvail, availFromGRE, greRdrNames, greSrcSpan, greQualModName, gresToAvailInfo, -- ** Global 'RdrName' mapping elements: 'GlobalRdrElt', 'Provenance', 'ImportSpec' GlobalRdrElt(..), isLocalGRE, isRecFldGRE, isOverloadedRecFldGRE, greLabel, unQualOK, qualSpecOK, unQualSpecOK, pprNameProvenance, Parent(..), greParent_maybe, ImportSpec(..), ImpDeclSpec(..), ImpItemSpec(..), importSpecLoc, importSpecModule, isExplicitItem, bestImport, -- * Utils for StarIsType starInfo ) where #include "GhclibHsVersions.h" import GhcPrelude import Module import Name import Avail import NameSet import Maybes import SrcLoc import FastString import FieldLabel import Outputable import Unique import UniqFM import UniqSet import Util import NameEnv import Data.Data import Data.List( sortBy ) {- ************************************************************************ * * \subsection{The main data type} * * ************************************************************************ -} -- | Reader Name -- -- Do not use the data constructors of RdrName directly: prefer the family -- of functions that creates them, such as 'mkRdrUnqual' -- -- - Note: A Located RdrName will only have API Annotations if it is a -- compound one, -- e.g. -- -- > `bar` -- > ( ~ ) -- -- - 'ApiAnnotation.AnnKeywordId' : 'ApiAnnotation.AnnType', -- 'ApiAnnotation.AnnOpen' @'('@ or @'['@ or @'[:'@, -- 'ApiAnnotation.AnnClose' @')'@ or @']'@ or @':]'@,, -- 'ApiAnnotation.AnnBackquote' @'`'@, -- 'ApiAnnotation.AnnVal' -- 'ApiAnnotation.AnnTilde', -- For details on above see note [Api annotations] in ApiAnnotation data RdrName = Unqual OccName -- ^ Unqualified name -- -- Used for ordinary, unqualified occurrences, e.g. @x@, @y@ or @Foo@. -- Create such a 'RdrName' with 'mkRdrUnqual' | Qual ModuleName OccName -- ^ Qualified name -- -- A qualified name written by the user in -- /source/ code. The module isn't necessarily -- the module where the thing is defined; -- just the one from which it is imported. -- Examples are @Bar.x@, @Bar.y@ or @Bar.Foo@. -- Create such a 'RdrName' with 'mkRdrQual' | Orig Module OccName -- ^ Original name -- -- An original name; the module is the /defining/ module. -- This is used when GHC generates code that will be fed -- into the renamer (e.g. from deriving clauses), but where -- we want to say \"Use Prelude.map dammit\". One of these -- can be created with 'mkOrig' | Exact Name -- ^ Exact name -- -- We know exactly the 'Name'. This is used: -- -- (1) When the parser parses built-in syntax like @[]@ -- and @(,)@, but wants a 'RdrName' from it -- -- (2) By Template Haskell, when TH has generated a unique name -- -- Such a 'RdrName' can be created by using 'getRdrName' on a 'Name' deriving Data {- ************************************************************************ * * \subsection{Simple functions} * * ************************************************************************ -} instance HasOccName RdrName where occName = rdrNameOcc rdrNameOcc :: RdrName -> OccName rdrNameOcc (Qual _ occ) = occ rdrNameOcc (Unqual occ) = occ rdrNameOcc (Orig _ occ) = occ rdrNameOcc (Exact name) = nameOccName name rdrNameSpace :: RdrName -> NameSpace rdrNameSpace = occNameSpace . rdrNameOcc -- demoteRdrName lowers the NameSpace of RdrName. -- see Note [Demotion] in OccName demoteRdrName :: RdrName -> Maybe RdrName demoteRdrName (Unqual occ) = fmap Unqual (demoteOccName occ) demoteRdrName (Qual m occ) = fmap (Qual m) (demoteOccName occ) demoteRdrName (Orig _ _) = panic "demoteRdrName" demoteRdrName (Exact _) = panic "demoteRdrName" -- These two are the basic constructors mkRdrUnqual :: OccName -> RdrName mkRdrUnqual occ = Unqual occ mkRdrQual :: ModuleName -> OccName -> RdrName mkRdrQual mod occ = Qual mod occ mkOrig :: Module -> OccName -> RdrName mkOrig mod occ = Orig mod occ --------------- -- These two are used when parsing source files -- They do encode the module and occurrence names mkUnqual :: NameSpace -> FastString -> RdrName mkUnqual sp n = Unqual (mkOccNameFS sp n) mkVarUnqual :: FastString -> RdrName mkVarUnqual n = Unqual (mkVarOccFS n) -- | Make a qualified 'RdrName' in the given namespace and where the 'ModuleName' and -- the 'OccName' are taken from the first and second elements of the tuple respectively mkQual :: NameSpace -> (FastString, FastString) -> RdrName mkQual sp (m, n) = Qual (mkModuleNameFS m) (mkOccNameFS sp n) getRdrName :: NamedThing thing => thing -> RdrName getRdrName name = nameRdrName (getName name) nameRdrName :: Name -> RdrName nameRdrName name = Exact name -- Keep the Name even for Internal names, so that the -- unique is still there for debug printing, particularly -- of Types (which are converted to IfaceTypes before printing) nukeExact :: Name -> RdrName nukeExact n | isExternalName n = Orig (nameModule n) (nameOccName n) | otherwise = Unqual (nameOccName n) isRdrDataCon :: RdrName -> Bool isRdrTyVar :: RdrName -> Bool isRdrTc :: RdrName -> Bool isRdrDataCon rn = isDataOcc (rdrNameOcc rn) isRdrTyVar rn = isTvOcc (rdrNameOcc rn) isRdrTc rn = isTcOcc (rdrNameOcc rn) isSrcRdrName :: RdrName -> Bool isSrcRdrName (Unqual _) = True isSrcRdrName (Qual _ _) = True isSrcRdrName _ = False isUnqual :: RdrName -> Bool isUnqual (Unqual _) = True isUnqual _ = False isQual :: RdrName -> Bool isQual (Qual _ _) = True isQual _ = False isQual_maybe :: RdrName -> Maybe (ModuleName, OccName) isQual_maybe (Qual m n) = Just (m,n) isQual_maybe _ = Nothing isOrig :: RdrName -> Bool isOrig (Orig _ _) = True isOrig _ = False isOrig_maybe :: RdrName -> Maybe (Module, OccName) isOrig_maybe (Orig m n) = Just (m,n) isOrig_maybe _ = Nothing isExact :: RdrName -> Bool isExact (Exact _) = True isExact _ = False isExact_maybe :: RdrName -> Maybe Name isExact_maybe (Exact n) = Just n isExact_maybe _ = Nothing {- ************************************************************************ * * \subsection{Instances} * * ************************************************************************ -} instance Outputable RdrName where ppr (Exact name) = ppr name ppr (Unqual occ) = ppr occ ppr (Qual mod occ) = ppr mod <> dot <> ppr occ ppr (Orig mod occ) = getPprStyle (\sty -> pprModulePrefix sty mod occ <> ppr occ) instance OutputableBndr RdrName where pprBndr _ n | isTvOcc (rdrNameOcc n) = char '@' <+> ppr n | otherwise = ppr n pprInfixOcc rdr = pprInfixVar (isSymOcc (rdrNameOcc rdr)) (ppr rdr) pprPrefixOcc rdr | Just name <- isExact_maybe rdr = pprPrefixName name -- pprPrefixName has some special cases, so -- we delegate to them rather than reproduce them | otherwise = pprPrefixVar (isSymOcc (rdrNameOcc rdr)) (ppr rdr) instance Eq RdrName where (Exact n1) == (Exact n2) = n1==n2 -- Convert exact to orig (Exact n1) == r2@(Orig _ _) = nukeExact n1 == r2 r1@(Orig _ _) == (Exact n2) = r1 == nukeExact n2 (Orig m1 o1) == (Orig m2 o2) = m1==m2 && o1==o2 (Qual m1 o1) == (Qual m2 o2) = m1==m2 && o1==o2 (Unqual o1) == (Unqual o2) = o1==o2 _ == _ = False instance Ord RdrName where a <= b = case (a `compare` b) of { LT -> True; EQ -> True; GT -> False } a < b = case (a `compare` b) of { LT -> True; EQ -> False; GT -> False } a >= b = case (a `compare` b) of { LT -> False; EQ -> True; GT -> True } a > b = case (a `compare` b) of { LT -> False; EQ -> False; GT -> True } -- Exact < Unqual < Qual < Orig -- [Note: Apr 2004] We used to use nukeExact to convert Exact to Orig -- before comparing so that Prelude.map == the exact Prelude.map, but -- that meant that we reported duplicates when renaming bindings -- generated by Template Haskell; e.g -- do { n1 <- newName "foo"; n2 <- newName "foo"; -- <decl involving n1,n2> } -- I think we can do without this conversion compare (Exact n1) (Exact n2) = n1 `compare` n2 compare (Exact _) _ = LT compare (Unqual _) (Exact _) = GT compare (Unqual o1) (Unqual o2) = o1 `compare` o2 compare (Unqual _) _ = LT compare (Qual _ _) (Exact _) = GT compare (Qual _ _) (Unqual _) = GT compare (Qual m1 o1) (Qual m2 o2) = (o1 `compare` o2) `thenCmp` (m1 `compare` m2) compare (Qual _ _) (Orig _ _) = LT compare (Orig m1 o1) (Orig m2 o2) = (o1 `compare` o2) `thenCmp` (m1 `compare` m2) compare (Orig _ _) _ = GT {- ************************************************************************ * * LocalRdrEnv * * ************************************************************************ -} -- | Local Reader Environment -- -- This environment is used to store local bindings -- (@let@, @where@, lambda, @case@). -- It is keyed by OccName, because we never use it for qualified names -- We keep the current mapping, *and* the set of all Names in scope -- Reason: see Note [Splicing Exact names] in RnEnv data LocalRdrEnv = LRE { lre_env :: OccEnv Name , lre_in_scope :: NameSet } instance Outputable LocalRdrEnv where ppr (LRE {lre_env = env, lre_in_scope = ns}) = hang (text "LocalRdrEnv {") 2 (vcat [ text "env =" <+> pprOccEnv ppr_elt env , text "in_scope =" <+> pprUFM (getUniqSet ns) (braces . pprWithCommas ppr) ] <+> char '}') where ppr_elt name = parens (ppr (getUnique (nameOccName name))) <+> ppr name -- So we can see if the keys line up correctly emptyLocalRdrEnv :: LocalRdrEnv emptyLocalRdrEnv = LRE { lre_env = emptyOccEnv , lre_in_scope = emptyNameSet } extendLocalRdrEnv :: LocalRdrEnv -> Name -> LocalRdrEnv -- The Name should be a non-top-level thing extendLocalRdrEnv lre@(LRE { lre_env = env, lre_in_scope = ns }) name = WARN( isExternalName name, ppr name ) lre { lre_env = extendOccEnv env (nameOccName name) name , lre_in_scope = extendNameSet ns name } extendLocalRdrEnvList :: LocalRdrEnv -> [Name] -> LocalRdrEnv extendLocalRdrEnvList lre@(LRE { lre_env = env, lre_in_scope = ns }) names = WARN( any isExternalName names, ppr names ) lre { lre_env = extendOccEnvList env [(nameOccName n, n) | n <- names] , lre_in_scope = extendNameSetList ns names } lookupLocalRdrEnv :: LocalRdrEnv -> RdrName -> Maybe Name lookupLocalRdrEnv (LRE { lre_env = env, lre_in_scope = ns }) rdr | Unqual occ <- rdr = lookupOccEnv env occ -- See Note [Local bindings with Exact Names] | Exact name <- rdr , name `elemNameSet` ns = Just name | otherwise = Nothing lookupLocalRdrOcc :: LocalRdrEnv -> OccName -> Maybe Name lookupLocalRdrOcc (LRE { lre_env = env }) occ = lookupOccEnv env occ elemLocalRdrEnv :: RdrName -> LocalRdrEnv -> Bool elemLocalRdrEnv rdr_name (LRE { lre_env = env, lre_in_scope = ns }) = case rdr_name of Unqual occ -> occ `elemOccEnv` env Exact name -> name `elemNameSet` ns -- See Note [Local bindings with Exact Names] Qual {} -> False Orig {} -> False localRdrEnvElts :: LocalRdrEnv -> [Name] localRdrEnvElts (LRE { lre_env = env }) = occEnvElts env inLocalRdrEnvScope :: Name -> LocalRdrEnv -> Bool -- This is the point of the NameSet inLocalRdrEnvScope name (LRE { lre_in_scope = ns }) = name `elemNameSet` ns delLocalRdrEnvList :: LocalRdrEnv -> [OccName] -> LocalRdrEnv delLocalRdrEnvList lre@(LRE { lre_env = env }) occs = lre { lre_env = delListFromOccEnv env occs } {- Note [Local bindings with Exact Names] ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ With Template Haskell we can make local bindings that have Exact Names. Computing shadowing etc may use elemLocalRdrEnv (at least it certainly does so in RnTpes.bindHsQTyVars), so for an Exact Name we must consult the in-scope-name-set. ************************************************************************ * * GlobalRdrEnv * * ************************************************************************ -} -- | Global Reader Environment type GlobalRdrEnv = OccEnv [GlobalRdrElt] -- ^ Keyed by 'OccName'; when looking up a qualified name -- we look up the 'OccName' part, and then check the 'Provenance' -- to see if the appropriate qualification is valid. This -- saves routinely doubling the size of the env by adding both -- qualified and unqualified names to the domain. -- -- The list in the codomain is required because there may be name clashes -- These only get reported on lookup, not on construction -- -- INVARIANT 1: All the members of the list have distinct -- 'gre_name' fields; that is, no duplicate Names -- -- INVARIANT 2: Imported provenance => Name is an ExternalName -- However LocalDefs can have an InternalName. This -- happens only when type-checking a [d| ... |] Template -- Haskell quotation; see this note in RnNames -- Note [Top-level Names in Template Haskell decl quotes] -- -- INVARIANT 3: If the GlobalRdrEnv maps [occ -> gre], then -- greOccName gre = occ -- -- NB: greOccName gre is usually the same as -- nameOccName (gre_name gre), but not always in the -- case of record seectors; see greOccName -- | Global Reader Element -- -- An element of the 'GlobalRdrEnv' data GlobalRdrElt = GRE { gre_name :: Name , gre_par :: Parent , gre_lcl :: Bool -- ^ True <=> the thing was defined locally , gre_imp :: [ImportSpec] -- ^ In scope through these imports } deriving (Data, Eq) -- INVARIANT: either gre_lcl = True or gre_imp is non-empty -- See Note [GlobalRdrElt provenance] -- | The children of a Name are the things that are abbreviated by the ".." -- notation in export lists. See Note [Parents] data Parent = NoParent | ParentIs { par_is :: Name } | FldParent { par_is :: Name, par_lbl :: Maybe FieldLabelString } -- ^ See Note [Parents for record fields] deriving (Eq, Data) instance Outputable Parent where ppr NoParent = empty ppr (ParentIs n) = text "parent:" <> ppr n ppr (FldParent n f) = text "fldparent:" <> ppr n <> colon <> ppr f plusParent :: Parent -> Parent -> Parent -- See Note [Combining parents] plusParent p1@(ParentIs _) p2 = hasParent p1 p2 plusParent p1@(FldParent _ _) p2 = hasParent p1 p2 plusParent p1 p2@(ParentIs _) = hasParent p2 p1 plusParent p1 p2@(FldParent _ _) = hasParent p2 p1 plusParent _ _ = NoParent hasParent :: Parent -> Parent -> Parent #if defined(DEBUG) hasParent p NoParent = p hasParent p p' | p /= p' = pprPanic "hasParent" (ppr p <+> ppr p') -- Parents should agree #endif hasParent p _ = p {- Note [GlobalRdrElt provenance] ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ The gre_lcl and gre_imp fields of a GlobalRdrElt describe its "provenance", i.e. how the Name came to be in scope. It can be in scope two ways: - gre_lcl = True: it is bound in this module - gre_imp: a list of all the imports that brought it into scope It's an INVARIANT that you have one or the other; that is, either gre_lcl is True, or gre_imp is non-empty. It is just possible to have *both* if there is a module loop: a Name is defined locally in A, and also brought into scope by importing a module that SOURCE-imported A. Exapmle (#7672): A.hs-boot module A where data T B.hs module B(Decl.T) where import {-# SOURCE #-} qualified A as Decl A.hs module A where import qualified B data T = Z | S B.T In A.hs, 'T' is locally bound, *and* imported as B.T. Note [Parents] ~~~~~~~~~~~~~~~~~ Parent Children ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ data T Data constructors Record-field ids data family T Data constructors and record-field ids of all visible data instances of T class C Class operations Associated type constructors ~~~~~~~~~~~~~~~~~~~~~~~~~ Constructor Meaning ~~~~~~~~~~~~~~~~~~~~~~~~ NoParent Can not be bundled with a type constructor. ParentIs n Can be bundled with the type constructor corresponding to n. FldParent See Note [Parents for record fields] Note [Parents for record fields] ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ For record fields, in addition to the Name of the type constructor (stored in par_is), we use FldParent to store the field label. This extra information is used for identifying overloaded record fields during renaming. In a definition arising from a normal module (without -XDuplicateRecordFields), par_lbl will be Nothing, meaning that the field's label is the same as the OccName of the selector's Name. The GlobalRdrEnv will contain an entry like this: "x" |-> GRE x (FldParent T Nothing) LocalDef When -XDuplicateRecordFields is enabled for the module that contains T, the selector's Name will be mangled (see comments in FieldLabel). Thus we store the actual field label in par_lbl, and the GlobalRdrEnv entry looks like this: "x" |-> GRE $sel:x:MkT (FldParent T (Just "x")) LocalDef Note that the OccName used when adding a GRE to the environment (greOccName) now depends on the parent field: for FldParent it is the field label, if present, rather than the selector name. ~~ Record pattern synonym selectors are treated differently. Their parent information is `NoParent` in the module in which they are defined. This is because a pattern synonym `P` has no parent constructor either. However, if `f` is bundled with a type constructor `T` then whenever `f` is imported the parent will use the `Parent` constructor so the parent of `f` is now `T`. Note [Combining parents] ~~~~~~~~~~~~~~~~~~~~~~~~ With an associated type we might have module M where class C a where data T a op :: T a -> a instance C Int where data T Int = TInt instance C Bool where data T Bool = TBool Then: C is the parent of T T is the parent of TInt and TBool So: in an export list C(..) is short for C( op, T ) T(..) is short for T( TInt, TBool ) Module M exports everything, so its exports will be AvailTC C [C,T,op] AvailTC T [T,TInt,TBool] On import we convert to GlobalRdrElt and then combine those. For T that will mean we have one GRE with Parent C one GRE with NoParent That's why plusParent picks the "best" case. -} -- | make a 'GlobalRdrEnv' where all the elements point to the same -- Provenance (useful for "hiding" imports, or imports with no details). gresFromAvails :: Maybe ImportSpec -> [AvailInfo] -> [GlobalRdrElt] -- prov = Nothing => locally bound -- Just spec => imported as described by spec gresFromAvails prov avails = concatMap (gresFromAvail (const prov)) avails localGREsFromAvail :: AvailInfo -> [GlobalRdrElt] -- Turn an Avail into a list of LocalDef GlobalRdrElts localGREsFromAvail = gresFromAvail (const Nothing) gresFromAvail :: (Name -> Maybe ImportSpec) -> AvailInfo -> [GlobalRdrElt] gresFromAvail prov_fn avail = map mk_gre (availNonFldNames avail) ++ map mk_fld_gre (availFlds avail) where mk_gre n = case prov_fn n of -- Nothing => bound locally -- Just is => imported from 'is' Nothing -> GRE { gre_name = n, gre_par = mkParent n avail , gre_lcl = True, gre_imp = [] } Just is -> GRE { gre_name = n, gre_par = mkParent n avail , gre_lcl = False, gre_imp = [is] } mk_fld_gre (FieldLabel { flLabel = lbl, flIsOverloaded = is_overloaded , flSelector = n }) = case prov_fn n of -- Nothing => bound locally -- Just is => imported from 'is' Nothing -> GRE { gre_name = n, gre_par = FldParent (availName avail) mb_lbl , gre_lcl = True, gre_imp = [] } Just is -> GRE { gre_name = n, gre_par = FldParent (availName avail) mb_lbl , gre_lcl = False, gre_imp = [is] } where mb_lbl | is_overloaded = Just lbl | otherwise = Nothing greQualModName :: GlobalRdrElt -> ModuleName -- Get a suitable module qualifier for the GRE -- (used in mkPrintUnqualified) -- Prerecondition: the gre_name is always External greQualModName gre@(GRE { gre_name = name, gre_lcl = lcl, gre_imp = iss }) | lcl, Just mod <- nameModule_maybe name = moduleName mod | (is:_) <- iss = is_as (is_decl is) | otherwise = pprPanic "greQualModName" (ppr gre) greRdrNames :: GlobalRdrElt -> [RdrName] greRdrNames gre@GRE{ gre_lcl = lcl, gre_imp = iss } = (if lcl then [unqual] else []) ++ concatMap do_spec (map is_decl iss) where occ = greOccName gre unqual = Unqual occ do_spec decl_spec | is_qual decl_spec = [qual] | otherwise = [unqual,qual] where qual = Qual (is_as decl_spec) occ -- the SrcSpan that pprNameProvenance prints out depends on whether -- the Name is defined locally or not: for a local definition the -- definition site is used, otherwise the location of the import -- declaration. We want to sort the export locations in -- exportClashErr by this SrcSpan, we need to extract it: greSrcSpan :: GlobalRdrElt -> SrcSpan greSrcSpan gre@(GRE { gre_name = name, gre_lcl = lcl, gre_imp = iss } ) | lcl = nameSrcSpan name | (is:_) <- iss = is_dloc (is_decl is) | otherwise = pprPanic "greSrcSpan" (ppr gre) mkParent :: Name -> AvailInfo -> Parent mkParent _ (Avail _) = NoParent mkParent n (AvailTC m _ _) | n == m = NoParent | otherwise = ParentIs m greParent_maybe :: GlobalRdrElt -> Maybe Name greParent_maybe gre = case gre_par gre of NoParent -> Nothing ParentIs n -> Just n FldParent n _ -> Just n -- | Takes a list of distinct GREs and folds them -- into AvailInfos. This is more efficient than mapping each individual -- GRE to an AvailInfo and the folding using `plusAvail` but needs the -- uniqueness assumption. gresToAvailInfo :: [GlobalRdrElt] -> [AvailInfo] gresToAvailInfo gres = nameEnvElts avail_env where avail_env :: NameEnv AvailInfo -- Keyed by the parent (avail_env, _) = foldl' add (emptyNameEnv, emptyNameSet) gres add :: (NameEnv AvailInfo, NameSet) -> GlobalRdrElt -> (NameEnv AvailInfo, NameSet) add (env, done) gre | name `elemNameSet` done = (env, done) -- Don't insert twice into the AvailInfo | otherwise = ( extendNameEnv_Acc comb availFromGRE env key gre , done `extendNameSet` name ) where name = gre_name gre key = case greParent_maybe gre of Just parent -> parent Nothing -> gre_name gre -- We want to insert the child `k` into a list of children but -- need to maintain the invariant that the parent is first. -- -- We also use the invariant that `k` is not already in `ns`. insertChildIntoChildren :: Name -> [Name] -> Name -> [Name] insertChildIntoChildren _ [] k = [k] insertChildIntoChildren p (n:ns) k | p == k = k:n:ns | otherwise = n:k:ns comb :: GlobalRdrElt -> AvailInfo -> AvailInfo comb _ (Avail n) = Avail n -- Duplicated name, should not happen comb gre (AvailTC m ns fls) = case gre_par gre of NoParent -> AvailTC m (name:ns) fls -- Not sure this ever happens ParentIs {} -> AvailTC m (insertChildIntoChildren m ns name) fls FldParent _ mb_lbl -> AvailTC m ns (mkFieldLabel name mb_lbl : fls) availFromGRE :: GlobalRdrElt -> AvailInfo availFromGRE (GRE { gre_name = me, gre_par = parent }) = case parent of ParentIs p -> AvailTC p [me] [] NoParent | isTyConName me -> AvailTC me [me] [] | otherwise -> avail me FldParent p mb_lbl -> AvailTC p [] [mkFieldLabel me mb_lbl] mkFieldLabel :: Name -> Maybe FastString -> FieldLabel mkFieldLabel me mb_lbl = case mb_lbl of Nothing -> FieldLabel { flLabel = occNameFS (nameOccName me) , flIsOverloaded = False , flSelector = me } Just lbl -> FieldLabel { flLabel = lbl , flIsOverloaded = True , flSelector = me } emptyGlobalRdrEnv :: GlobalRdrEnv emptyGlobalRdrEnv = emptyOccEnv globalRdrEnvElts :: GlobalRdrEnv -> [GlobalRdrElt] globalRdrEnvElts env = foldOccEnv (++) [] env instance Outputable GlobalRdrElt where ppr gre = hang (ppr (gre_name gre) <+> ppr (gre_par gre)) 2 (pprNameProvenance gre) pprGlobalRdrEnv :: Bool -> GlobalRdrEnv -> SDoc pprGlobalRdrEnv locals_only env = vcat [ text "GlobalRdrEnv" <+> ppWhen locals_only (ptext (sLit "(locals only)")) <+> lbrace , nest 2 (vcat [ pp (remove_locals gre_list) | gre_list <- occEnvElts env ] <+> rbrace) ] where remove_locals gres | locals_only = filter isLocalGRE gres | otherwise = gres pp [] = empty pp gres = hang (ppr occ <+> parens (text "unique" <+> ppr (getUnique occ)) <> colon) 2 (vcat (map ppr gres)) where occ = nameOccName (gre_name (head gres)) lookupGlobalRdrEnv :: GlobalRdrEnv -> OccName -> [GlobalRdrElt] lookupGlobalRdrEnv env occ_name = case lookupOccEnv env occ_name of Nothing -> [] Just gres -> gres greOccName :: GlobalRdrElt -> OccName greOccName (GRE{gre_par = FldParent{par_lbl = Just lbl}}) = mkVarOccFS lbl greOccName gre = nameOccName (gre_name gre) lookupGRE_RdrName :: RdrName -> GlobalRdrEnv -> [GlobalRdrElt] lookupGRE_RdrName rdr_name env = case lookupOccEnv env (rdrNameOcc rdr_name) of Nothing -> [] Just gres -> pickGREs rdr_name gres lookupGRE_Name :: GlobalRdrEnv -> Name -> Maybe GlobalRdrElt -- ^ Look for precisely this 'Name' in the environment. This tests -- whether it is in scope, ignoring anything else that might be in -- scope with the same 'OccName'. lookupGRE_Name env name = lookupGRE_Name_OccName env name (nameOccName name) lookupGRE_FieldLabel :: GlobalRdrEnv -> FieldLabel -> Maybe GlobalRdrElt -- ^ Look for a particular record field selector in the environment, where the -- selector name and field label may be different: the GlobalRdrEnv is keyed on -- the label. See Note [Parents for record fields] for why this happens. lookupGRE_FieldLabel env fl = lookupGRE_Name_OccName env (flSelector fl) (mkVarOccFS (flLabel fl)) lookupGRE_Name_OccName :: GlobalRdrEnv -> Name -> OccName -> Maybe GlobalRdrElt -- ^ Look for precisely this 'Name' in the environment, but with an 'OccName' -- that might differ from that of the 'Name'. See 'lookupGRE_FieldLabel' and -- Note [Parents for record fields]. lookupGRE_Name_OccName env name occ = case [ gre | gre <- lookupGlobalRdrEnv env occ , gre_name gre == name ] of [] -> Nothing [gre] -> Just gre gres -> pprPanic "lookupGRE_Name_OccName" (ppr name $$ ppr occ $$ ppr gres) -- See INVARIANT 1 on GlobalRdrEnv getGRE_NameQualifier_maybes :: GlobalRdrEnv -> Name -> [Maybe [ModuleName]] -- Returns all the qualifiers by which 'x' is in scope -- Nothing means "the unqualified version is in scope" -- [] means the thing is not in scope at all getGRE_NameQualifier_maybes env name = case lookupGRE_Name env name of Just gre -> [qualifier_maybe gre] Nothing -> [] where qualifier_maybe (GRE { gre_lcl = lcl, gre_imp = iss }) | lcl = Nothing | otherwise = Just $ map (is_as . is_decl) iss isLocalGRE :: GlobalRdrElt -> Bool isLocalGRE (GRE {gre_lcl = lcl }) = lcl isRecFldGRE :: GlobalRdrElt -> Bool isRecFldGRE (GRE {gre_par = FldParent{}}) = True isRecFldGRE _ = False isOverloadedRecFldGRE :: GlobalRdrElt -> Bool -- ^ Is this a record field defined with DuplicateRecordFields? -- (See Note [Parents for record fields]) isOverloadedRecFldGRE (GRE {gre_par = FldParent{par_lbl = Just _}}) = True isOverloadedRecFldGRE _ = False -- Returns the field label of this GRE, if it has one greLabel :: GlobalRdrElt -> Maybe FieldLabelString greLabel (GRE{gre_par = FldParent{par_lbl = Just lbl}}) = Just lbl greLabel (GRE{gre_name = n, gre_par = FldParent{}}) = Just (occNameFS (nameOccName n)) greLabel _ = Nothing unQualOK :: GlobalRdrElt -> Bool -- ^ Test if an unqualified version of this thing would be in scope unQualOK (GRE {gre_lcl = lcl, gre_imp = iss }) | lcl = True | otherwise = any unQualSpecOK iss {- Note [GRE filtering] ~~~~~~~~~~~~~~~~~~~~~~~ (pickGREs rdr gres) takes a list of GREs which have the same OccName as 'rdr', say "x". It does two things: (a) filters the GREs to a subset that are in scope * Qualified, as 'M.x' if want_qual is Qual M _ * Unqualified, as 'x' if want_unqual is Unqual _ (b) for that subset, filter the provenance field (gre_lcl and gre_imp) to ones that brought it into scope qualified or unqualified resp. Example: module A ( f ) where import qualified Foo( f ) import Baz( f ) f = undefined Let's suppose that Foo.f and Baz.f are the same entity really, but the local 'f' is different, so there will be two GREs matching "f": gre1: gre_lcl = True, gre_imp = [] gre2: gre_lcl = False, gre_imp = [ imported from Foo, imported from Bar ] The use of "f" in the export list is ambiguous because it's in scope from the local def and the import Baz(f); but *not* the import qualified Foo. pickGREs returns two GRE gre1: gre_lcl = True, gre_imp = [] gre2: gre_lcl = False, gre_imp = [ imported from Bar ] Now the "ambiguous occurrence" message can correctly report how the ambiguity arises. -} pickGREs :: RdrName -> [GlobalRdrElt] -> [GlobalRdrElt] -- ^ Takes a list of GREs which have the right OccName 'x' -- Pick those GREs that are in scope -- * Qualified, as 'M.x' if want_qual is Qual M _ -- * Unqualified, as 'x' if want_unqual is Unqual _ -- -- Return each such GRE, with its ImportSpecs filtered, to reflect -- how it is in scope qualified or unqualified respectively. -- See Note [GRE filtering] pickGREs (Unqual {}) gres = mapMaybe pickUnqualGRE gres pickGREs (Qual mod _) gres = mapMaybe (pickQualGRE mod) gres pickGREs _ _ = [] -- I don't think this actually happens pickUnqualGRE :: GlobalRdrElt -> Maybe GlobalRdrElt pickUnqualGRE gre@(GRE { gre_lcl = lcl, gre_imp = iss }) | not lcl, null iss' = Nothing | otherwise = Just (gre { gre_imp = iss' }) where iss' = filter unQualSpecOK iss pickQualGRE :: ModuleName -> GlobalRdrElt -> Maybe GlobalRdrElt pickQualGRE mod gre@(GRE { gre_name = n, gre_lcl = lcl, gre_imp = iss }) | not lcl', null iss' = Nothing | otherwise = Just (gre { gre_lcl = lcl', gre_imp = iss' }) where iss' = filter (qualSpecOK mod) iss lcl' = lcl && name_is_from mod n name_is_from :: ModuleName -> Name -> Bool name_is_from mod name = case nameModule_maybe name of Just n_mod -> moduleName n_mod == mod Nothing -> False pickGREsModExp :: ModuleName -> [GlobalRdrElt] -> [(GlobalRdrElt,GlobalRdrElt)] -- ^ Pick GREs that are in scope *both* qualified *and* unqualified -- Return each GRE that is, as a pair -- (qual_gre, unqual_gre) -- These two GREs are the original GRE with imports filtered to express how -- it is in scope qualified an unqualified respectively -- -- Used only for the 'module M' item in export list; -- see RnNames.exports_from_avail pickGREsModExp mod gres = mapMaybe (pickBothGRE mod) gres pickBothGRE :: ModuleName -> GlobalRdrElt -> Maybe (GlobalRdrElt, GlobalRdrElt) pickBothGRE mod gre@(GRE { gre_name = n }) | isBuiltInSyntax n = Nothing | Just gre1 <- pickQualGRE mod gre , Just gre2 <- pickUnqualGRE gre = Just (gre1, gre2) | otherwise = Nothing where -- isBuiltInSyntax filter out names for built-in syntax They -- just clutter up the environment (esp tuples), and the -- parser will generate Exact RdrNames for them, so the -- cluttered envt is no use. Really, it's only useful for -- GHC.Base and GHC.Tuple. -- Building GlobalRdrEnvs plusGlobalRdrEnv :: GlobalRdrEnv -> GlobalRdrEnv -> GlobalRdrEnv plusGlobalRdrEnv env1 env2 = plusOccEnv_C (foldr insertGRE) env1 env2 mkGlobalRdrEnv :: [GlobalRdrElt] -> GlobalRdrEnv mkGlobalRdrEnv gres = foldr add emptyGlobalRdrEnv gres where add gre env = extendOccEnv_Acc insertGRE singleton env (greOccName gre) gre insertGRE :: GlobalRdrElt -> [GlobalRdrElt] -> [GlobalRdrElt] insertGRE new_g [] = [new_g] insertGRE new_g (old_g : old_gs) | gre_name new_g == gre_name old_g = new_g `plusGRE` old_g : old_gs | otherwise = old_g : insertGRE new_g old_gs plusGRE :: GlobalRdrElt -> GlobalRdrElt -> GlobalRdrElt -- Used when the gre_name fields match plusGRE g1 g2 = GRE { gre_name = gre_name g1 , gre_lcl = gre_lcl g1 || gre_lcl g2 , gre_imp = gre_imp g1 ++ gre_imp g2 , gre_par = gre_par g1 `plusParent` gre_par g2 } transformGREs :: (GlobalRdrElt -> GlobalRdrElt) -> [OccName] -> GlobalRdrEnv -> GlobalRdrEnv -- ^ Apply a transformation function to the GREs for these OccNames transformGREs trans_gre occs rdr_env = foldr trans rdr_env occs where trans occ env = case lookupOccEnv env occ of Just gres -> extendOccEnv env occ (map trans_gre gres) Nothing -> env extendGlobalRdrEnv :: GlobalRdrEnv -> GlobalRdrElt -> GlobalRdrEnv extendGlobalRdrEnv env gre = extendOccEnv_Acc insertGRE singleton env (greOccName gre) gre shadowNames :: GlobalRdrEnv -> [Name] -> GlobalRdrEnv shadowNames = foldl' shadowName {- Note [GlobalRdrEnv shadowing] ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ Before adding new names to the GlobalRdrEnv we nuke some existing entries; this is "shadowing". The actual work is done by RdrEnv.shadowName. Suppose env' = shadowName env M.f Then: * Looking up (Unqual f) in env' should succeed, returning M.f, even if env contains existing unqualified bindings for f. They are shadowed * Looking up (Qual M.f) in env' should succeed, returning M.f * Looking up (Qual X.f) in env', where X /= M, should be the same as looking up (Qual X.f) in env. That is, shadowName does /not/ delete earlier qualified bindings There are two reasons for shadowing: * The GHCi REPL - Ids bought into scope on the command line (eg let x = True) have External Names, like Ghci4.x. We want a new binding for 'x' (say) to override the existing binding for 'x'. Example: ghci> :load M -- Brings `x` and `M.x` into scope ghci> x ghci> "Hello" ghci> M.x ghci> "hello" ghci> let x = True -- Shadows `x` ghci> x -- The locally bound `x` -- NOT an ambiguous reference ghci> True ghci> M.x -- M.x is still in scope! ghci> "Hello" So when we add `x = True` we must not delete the `M.x` from the `GlobalRdrEnv`; rather we just want to make it "qualified only"; hence the `mk_fake-imp_spec` in `shadowName`. See also Note [Interactively-bound Ids in GHCi] in HscTypes - Data types also have External Names, like Ghci4.T; but we still want 'T' to mean the newly-declared 'T', not an old one. * Nested Template Haskell declaration brackets See Note [Top-level Names in Template Haskell decl quotes] in RnNames Consider a TH decl quote: module M where f x = h [d| f = ...f...M.f... |] We must shadow the outer unqualified binding of 'f', else we'll get a complaint when extending the GlobalRdrEnv, saying that there are two bindings for 'f'. There are several tricky points: - This shadowing applies even if the binding for 'f' is in a where-clause, and hence is in the *local* RdrEnv not the *global* RdrEnv. This is done in lcl_env_TH in extendGlobalRdrEnvRn. - The External Name M.f from the enclosing module must certainly still be available. So we don't nuke it entirely; we just make it seem like qualified import. - We only shadow *External* names (which come from the main module), or from earlier GHCi commands. Do not shadow *Internal* names because in the bracket [d| class C a where f :: a f = 4 |] rnSrcDecls will first call extendGlobalRdrEnvRn with C[f] from the class decl, and *separately* extend the envt with the value binding. At that stage, the class op 'f' will have an Internal name. -} shadowName :: GlobalRdrEnv -> Name -> GlobalRdrEnv -- Remove certain old GREs that share the same OccName as this new Name. -- See Note [GlobalRdrEnv shadowing] for details shadowName env name = alterOccEnv (fmap alter_fn) env (nameOccName name) where alter_fn :: [GlobalRdrElt] -> [GlobalRdrElt] alter_fn gres = mapMaybe (shadow_with name) gres shadow_with :: Name -> GlobalRdrElt -> Maybe GlobalRdrElt shadow_with new_name old_gre@(GRE { gre_name = old_name, gre_lcl = lcl, gre_imp = iss }) = case nameModule_maybe old_name of Nothing -> Just old_gre -- Old name is Internal; do not shadow Just old_mod | Just new_mod <- nameModule_maybe new_name , new_mod == old_mod -- Old name same as new name; shadow completely -> Nothing | null iss' -- Nothing remains -> Nothing | otherwise -> Just (old_gre { gre_lcl = False, gre_imp = iss' }) where iss' = lcl_imp ++ mapMaybe (shadow_is new_name) iss lcl_imp | lcl = [mk_fake_imp_spec old_name old_mod] | otherwise = [] mk_fake_imp_spec old_name old_mod -- Urgh! = ImpSpec id_spec ImpAll where old_mod_name = moduleName old_mod id_spec = ImpDeclSpec { is_mod = old_mod_name , is_as = old_mod_name , is_qual = True , is_dloc = nameSrcSpan old_name } shadow_is :: Name -> ImportSpec -> Maybe ImportSpec shadow_is new_name is@(ImpSpec { is_decl = id_spec }) | Just new_mod <- nameModule_maybe new_name , is_as id_spec == moduleName new_mod = Nothing -- Shadow both qualified and unqualified | otherwise -- Shadow unqualified only = Just (is { is_decl = id_spec { is_qual = True } }) {- ************************************************************************ * * ImportSpec * * ************************************************************************ -} -- | Import Specification -- -- The 'ImportSpec' of something says how it came to be imported -- It's quite elaborate so that we can give accurate unused-name warnings. data ImportSpec = ImpSpec { is_decl :: ImpDeclSpec, is_item :: ImpItemSpec } deriving( Eq, Ord, Data ) -- | Import Declaration Specification -- -- Describes a particular import declaration and is -- shared among all the 'Provenance's for that decl data ImpDeclSpec = ImpDeclSpec { is_mod :: ModuleName, -- ^ Module imported, e.g. @import Muggle@ -- Note the @Muggle@ may well not be -- the defining module for this thing! -- TODO: either should be Module, or there -- should be a Maybe UnitId here too. is_as :: ModuleName, -- ^ Import alias, e.g. from @as M@ (or @Muggle@ if there is no @as@ clause) is_qual :: Bool, -- ^ Was this import qualified? is_dloc :: SrcSpan -- ^ The location of the entire import declaration } deriving Data -- | Import Item Specification -- -- Describes import info a particular Name data ImpItemSpec = ImpAll -- ^ The import had no import list, -- or had a hiding list | ImpSome { is_explicit :: Bool, is_iloc :: SrcSpan -- Location of the import item } -- ^ The import had an import list. -- The 'is_explicit' field is @True@ iff the thing was named -- /explicitly/ in the import specs rather -- than being imported as part of a "..." group. Consider: -- -- > import C( T(..) ) -- -- Here the constructors of @T@ are not named explicitly; -- only @T@ is named explicitly. deriving Data instance Eq ImpDeclSpec where p1 == p2 = case p1 `compare` p2 of EQ -> True; _ -> False instance Ord ImpDeclSpec where compare is1 is2 = (is_mod is1 `compare` is_mod is2) `thenCmp` (is_dloc is1 `compare` is_dloc is2) instance Eq ImpItemSpec where p1 == p2 = case p1 `compare` p2 of EQ -> True; _ -> False instance Ord ImpItemSpec where compare is1 is2 = case (is1, is2) of (ImpAll, ImpAll) -> EQ (ImpAll, _) -> GT (_, ImpAll) -> LT (ImpSome _ l1, ImpSome _ l2) -> l1 `compare` l2 bestImport :: [ImportSpec] -> ImportSpec -- See Note [Choosing the best import declaration] bestImport iss = case sortBy best iss of (is:_) -> is [] -> pprPanic "bestImport" (ppr iss) where best :: ImportSpec -> ImportSpec -> Ordering -- Less means better -- Unqualified always wins over qualified; then -- import-all wins over import-some; then -- earlier declaration wins over later best (ImpSpec { is_item = item1, is_decl = d1 }) (ImpSpec { is_item = item2, is_decl = d2 }) = (is_qual d1 `compare` is_qual d2) `thenCmp` (best_item item1 item2) `thenCmp` (is_dloc d1 `compare` is_dloc d2) best_item :: ImpItemSpec -> ImpItemSpec -> Ordering best_item ImpAll ImpAll = EQ best_item ImpAll (ImpSome {}) = LT best_item (ImpSome {}) ImpAll = GT best_item (ImpSome { is_explicit = e1 }) (ImpSome { is_explicit = e2 }) = e1 `compare` e2 -- False < True, so if e1 is explicit and e2 is not, we get GT {- Note [Choosing the best import declaration] ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ When reporting unused import declarations we use the following rules. (see [wiki:commentary/compiler/unused-imports]) Say that an import-item is either * an entire import-all decl (eg import Foo), or * a particular item in an import list (eg import Foo( ..., x, ...)). The general idea is that for each /occurrence/ of an imported name, we will attribute that use to one import-item. Once we have processed all the occurrences, any import items with no uses attributed to them are unused, and are warned about. More precisely: 1. For every RdrName in the program text, find its GlobalRdrElt. 2. Then, from the [ImportSpec] (gre_imp) of that GRE, choose one the "chosen import-item", and mark it "used". This is done by 'bestImport' 3. After processing all the RdrNames, bleat about any import-items that are unused. This is done in RnNames.warnUnusedImportDecls. The function 'bestImport' returns the dominant import among the ImportSpecs it is given, implementing Step 2. We say import-item A dominates import-item B if we choose A over B. In general, we try to choose the import that is most likely to render other imports unnecessary. Here is the dominance relationship we choose: a) import Foo dominates import qualified Foo. b) import Foo dominates import Foo(x). c) Otherwise choose the textually first one. Rationale for (a). Consider import qualified M -- Import #1 import M( x ) -- Import #2 foo = M.x + x The unqualified 'x' can only come from import #2. The qualified 'M.x' could come from either, but bestImport picks import #2, because it is more likely to be useful in other imports, as indeed it is in this case (see #5211 for a concrete example). But the rules are not perfect; consider import qualified M -- Import #1 import M( x ) -- Import #2 foo = M.x + M.y The M.x will use import #2, but M.y can only use import #1. -} unQualSpecOK :: ImportSpec -> Bool -- ^ Is in scope unqualified? unQualSpecOK is = not (is_qual (is_decl is)) qualSpecOK :: ModuleName -> ImportSpec -> Bool -- ^ Is in scope qualified with the given module? qualSpecOK mod is = mod == is_as (is_decl is) importSpecLoc :: ImportSpec -> SrcSpan importSpecLoc (ImpSpec decl ImpAll) = is_dloc decl importSpecLoc (ImpSpec _ item) = is_iloc item importSpecModule :: ImportSpec -> ModuleName importSpecModule is = is_mod (is_decl is) isExplicitItem :: ImpItemSpec -> Bool isExplicitItem ImpAll = False isExplicitItem (ImpSome {is_explicit = exp}) = exp pprNameProvenance :: GlobalRdrElt -> SDoc -- ^ Print out one place where the name was define/imported -- (With -dppr-debug, print them all) pprNameProvenance (GRE { gre_name = name, gre_lcl = lcl, gre_imp = iss }) = ifPprDebug (vcat pp_provs) (head pp_provs) where pp_provs = pp_lcl ++ map pp_is iss pp_lcl = if lcl then [text "defined at" <+> ppr (nameSrcLoc name)] else [] pp_is is = sep [ppr is, ppr_defn_site is name] -- If we know the exact definition point (which we may do with GHCi) -- then show that too. But not if it's just "imported from X". ppr_defn_site :: ImportSpec -> Name -> SDoc ppr_defn_site imp_spec name | same_module && not (isGoodSrcSpan loc) = empty -- Nothing interesting to say | otherwise = parens $ hang (text "and originally defined" <+> pp_mod) 2 (pprLoc loc) where loc = nameSrcSpan name defining_mod = ASSERT2( isExternalName name, ppr name ) nameModule name same_module = importSpecModule imp_spec == moduleName defining_mod pp_mod | same_module = empty | otherwise = text "in" <+> quotes (ppr defining_mod) instance Outputable ImportSpec where ppr imp_spec = text "imported" <+> qual <+> text "from" <+> quotes (ppr (importSpecModule imp_spec)) <+> pprLoc (importSpecLoc imp_spec) where qual | is_qual (is_decl imp_spec) = text "qualified" | otherwise = empty pprLoc :: SrcSpan -> SDoc pprLoc (RealSrcSpan s) = text "at" <+> ppr s pprLoc (UnhelpfulSpan {}) = empty -- | Display info about the treatment of '*' under NoStarIsType. -- -- With StarIsType, three properties of '*' hold: -- -- (a) it is not an infix operator -- (b) it is always in scope -- (c) it is a synonym for Data.Kind.Type -- -- However, the user might not know that he's working on a module with -- NoStarIsType and write code that still assumes (a), (b), and (c), which -- actually do not hold in that module. -- -- Violation of (a) shows up in the parser. For instance, in the following -- examples, we have '*' not applied to enough arguments: -- -- data A :: * -- data F :: * -> * -- -- Violation of (b) or (c) show up in the renamer and the typechecker -- respectively. For instance: -- -- type K = Either * Bool -- -- This will parse differently depending on whether StarIsType is enabled, -- but it will parse nonetheless. With NoStarIsType it is parsed as a type -- operator, thus we have ((*) Either Bool). Now there are two cases to -- consider: -- -- 1. There is no definition of (*) in scope. In this case the renamer will -- fail to look it up. This is a violation of assumption (b). -- -- 2. There is a definition of the (*) type operator in scope (for example -- coming from GHC.TypeNats). In this case the user will get a kind -- mismatch error. This is a violation of assumption (c). -- -- The user might unknowingly be working on a module with NoStarIsType -- or use '*' as 'Data.Kind.Type' out of habit. So it is important to give a -- hint whenever an assumption about '*' is violated. Unfortunately, it is -- somewhat difficult to deal with (c), so we limit ourselves to (a) and (b). -- -- 'starInfo' generates an appropriate hint to the user depending on the -- extensions enabled in the module and the name that triggered the error. -- That is, if we have NoStarIsType and the error is related to '*' or its -- Unicode variant, the resulting SDoc will contain a helpful suggestion. -- Otherwise it is empty. -- starInfo :: Bool -> RdrName -> SDoc starInfo star_is_type rdr_name = -- One might ask: if can use sdocWithDynFlags here, why bother to take -- star_is_type as input? Why not refactor? -- -- The reason is that sdocWithDynFlags would provide DynFlags that are active -- in the module that tries to load the problematic definition, not -- in the module that is being loaded. -- -- So if we have 'data T :: *' in a module with NoStarIsType, then the hint -- must be displayed even if we load this definition from a module (or GHCi) -- with StarIsType enabled! -- if isUnqualStar && not star_is_type then text "With NoStarIsType, " <> quotes (ppr rdr_name) <> text " is treated as a regular type operator. " $$ text "Did you mean to use " <> quotes (text "Type") <> text " from Data.Kind instead?" else empty where -- Does rdr_name look like the user might have meant the '*' kind by it? -- We focus on unqualified stars specifically, because qualified stars are -- treated as type operators even under StarIsType. isUnqualStar | Unqual occName <- rdr_name = let fs = occNameFS occName in fs == fsLit "*" || fs == fsLit "★" | otherwise = False