ghc-9.8.1: GHC/Rename/Module.hs
{-# LANGUAGE FlexibleContexts #-}
{-# LANGUAGE NamedFieldPuns #-}
{-# LANGUAGE ScopedTypeVariables #-}
{-# LANGUAGE TypeFamilies #-}
{-# OPTIONS_GHC -Wno-incomplete-uni-patterns #-}
{-
(c) The GRASP/AQUA Project, Glasgow University, 1992-1998
Main pass of renamer
-}
module GHC.Rename.Module (
rnSrcDecls, addTcgDUs, findSplice, rnWarningTxt
) where
import GHC.Prelude hiding ( head )
import {-# SOURCE #-} GHC.Rename.Expr( rnLExpr )
import {-# SOURCE #-} GHC.Rename.Splice ( rnSpliceDecl, rnTopSpliceDecls )
import GHC.Hs
import GHC.Types.FieldLabel
import GHC.Types.Name.Reader
import GHC.Rename.HsType
import GHC.Rename.Bind
import GHC.Rename.Doc
import GHC.Rename.Env
import GHC.Rename.Utils ( mapFvRn, bindLocalNames
, checkDupRdrNames, bindLocalNamesFV
, checkShadowedRdrNames, warnUnusedTypePatterns
, newLocalBndrsRn
, noNestedForallsContextsErr
, addNoNestedForallsContextsErr, checkInferredVars, warnForallIdentifier )
import GHC.Rename.Unbound ( mkUnboundName, notInScopeErr, WhereLooking(WL_Global) )
import GHC.Rename.Names
import GHC.Tc.Errors.Types
import GHC.Tc.Gen.Annotation ( annCtxt )
import GHC.Tc.Utils.Monad
import GHC.Tc.Types.Origin ( TypedThing(..) )
import GHC.Types.ForeignCall ( CCallTarget(..) )
import GHC.Unit
import GHC.Unit.Module.Warnings
import GHC.Builtin.Names( applicativeClassName, pureAName, thenAName
, monadClassName, returnMName, thenMName
, semigroupClassName, sappendName
, monoidClassName, mappendName
)
import GHC.Types.Name
import GHC.Types.Name.Set
import GHC.Types.Name.Env
import GHC.Utils.Outputable
import GHC.Data.Bag
import GHC.Types.Basic ( TypeOrKind(..) )
import GHC.Data.FastString
import GHC.Types.SrcLoc as SrcLoc
import GHC.Driver.DynFlags
import GHC.Utils.Misc ( lengthExceeds, partitionWith )
import GHC.Utils.Panic
import GHC.Driver.Env ( HscEnv(..), hsc_home_unit)
import GHC.Data.List.SetOps ( findDupsEq, removeDupsOn, equivClasses )
import GHC.Data.Graph.Directed ( SCC, flattenSCC, flattenSCCs, Node(..)
, stronglyConnCompFromEdgedVerticesUniq )
import GHC.Types.Unique.Set
import GHC.Data.OrdList
import qualified GHC.LanguageExtensions as LangExt
import GHC.Core.DataCon ( isSrcStrict )
import Control.Monad
import Control.Arrow ( first )
import Data.Foldable ( toList )
import Data.List ( mapAccumL )
import Data.List.NonEmpty ( NonEmpty(..), head )
import Data.Maybe ( isNothing, fromMaybe, mapMaybe )
import qualified Data.Set as Set ( difference, fromList, toList, null )
import GHC.Types.GREInfo (ConInfo, mkConInfo, conInfoFields)
{- | @rnSourceDecl@ "renames" declarations.
It simultaneously performs dependency analysis and precedence parsing.
It also does the following error checks:
* Checks that tyvars are used properly. This includes checking
for undefined tyvars, and tyvars in contexts that are ambiguous.
(Some of this checking has now been moved to module @TcMonoType@,
since we don't have functional dependency information at this point.)
* Checks that all variable occurrences are defined.
* Checks the @(..)@ etc constraints in the export list.
Brings the binders of the group into scope in the appropriate places;
does NOT assume that anything is in scope already
-}
rnSrcDecls :: HsGroup GhcPs -> RnM (TcGblEnv, HsGroup GhcRn)
-- Rename a top-level HsGroup; used for normal source files *and* hs-boot files
rnSrcDecls group@(HsGroup { hs_valds = val_decls,
hs_splcds = splice_decls,
hs_tyclds = tycl_decls,
hs_derivds = deriv_decls,
hs_fixds = fix_decls,
hs_warnds = warn_decls,
hs_annds = ann_decls,
hs_fords = foreign_decls,
hs_defds = default_decls,
hs_ruleds = rule_decls,
hs_docs = docs })
= do {
-- (A) Process the top-level fixity declarations, creating a mapping from
-- FastStrings to FixItems. Also checks for duplicates.
-- See Note [Top-level fixity signatures in an HsGroup] in GHC.Hs.Decls
local_fix_env <- makeMiniFixityEnv $ hsGroupTopLevelFixitySigs group ;
-- (B) Bring top level binders (and their fixities) into scope,
-- *except* for the value bindings, which get done in step (D)
-- with collectHsIdBinders. However *do* include
--
-- * Class ops, data constructors, and record fields,
-- because they do not have value declarations.
--
-- * For hs-boot files, include the value signatures
-- Again, they have no value declarations
--
(tc_envs, tc_bndrs) <- getLocalNonValBinders local_fix_env group ;
restoreEnvs tc_envs $ do {
failIfErrsM ; -- No point in continuing if (say) we have duplicate declarations
-- (D1) Bring pattern synonyms into scope.
-- Need to do this before (D2) because rnTopBindsLHS
-- looks up those pattern synonyms (#9889)
dup_fields_ok <- xopt_DuplicateRecordFields <$> getDynFlags ;
has_sel <- xopt_FieldSelectors <$> getDynFlags ;
extendPatSynEnv dup_fields_ok has_sel val_decls local_fix_env $ \pat_syn_bndrs -> do {
-- (D2) Rename the left-hand sides of the value bindings.
-- This depends on everything from (B) being in scope.
-- It uses the fixity env from (A) to bind fixities for view patterns.
-- We need to throw an error on such value bindings when in a boot file.
is_boot <- tcIsHsBootOrSig ;
new_lhs <- if is_boot
then rnTopBindsLHSBoot local_fix_env val_decls
else rnTopBindsLHS local_fix_env val_decls ;
-- Bind the LHSes (and their fixities) in the global rdr environment
let { id_bndrs = collectHsIdBinders CollNoDictBinders new_lhs } ;
-- Excludes pattern-synonym binders
-- They are already in scope
traceRn "rnSrcDecls" (ppr id_bndrs) ;
tc_envs <- extendGlobalRdrEnvRn (map (mkLocalVanillaGRE NoParent) id_bndrs) local_fix_env ;
restoreEnvs tc_envs $ do {
-- Now everything is in scope, as the remaining renaming assumes.
-- (E) Rename type and class decls
-- (note that value LHSes need to be in scope for default methods)
--
-- You might think that we could build proper def/use information
-- for type and class declarations, but they can be involved
-- in mutual recursion across modules, and we only do the SCC
-- analysis for them in the type checker.
-- So we content ourselves with gathering uses only; that
-- means we'll only report a declaration as unused if it isn't
-- mentioned at all. Ah well.
traceRn "Start rnTyClDecls" (ppr tycl_decls) ;
(rn_tycl_decls, src_fvs1) <- rnTyClDecls tycl_decls ;
-- (F) Rename Value declarations right-hand sides
traceRn "Start rnmono" empty ;
let { val_bndr_set = mkNameSet id_bndrs `unionNameSet` mkNameSet pat_syn_bndrs } ;
(rn_val_decls, bind_dus) <- if is_boot
-- For an hs-boot, use tc_bndrs (which collects how we're renamed
-- signatures), since val_bndr_set is empty (there are no x = ...
-- bindings in an hs-boot.)
then rnTopBindsBoot tc_bndrs new_lhs
else rnValBindsRHS (TopSigCtxt val_bndr_set) new_lhs ;
traceRn "finish rnmono" (ppr rn_val_decls) ;
-- (G) Rename Fixity and deprecations
-- Rename fixity declarations and error if we try to
-- fix something from another module (duplicates were checked in (A))
let { all_bndrs = tc_bndrs `unionNameSet` val_bndr_set } ;
traceRn "rnSrcDecls fixity" $
vcat [ text "all_bndrs:" <+> ppr all_bndrs ] ;
rn_fix_decls <- mapM (mapM (rnSrcFixityDecl (TopSigCtxt all_bndrs)))
fix_decls ;
-- Rename deprec decls;
-- check for duplicates and ensure that deprecated things are defined locally
-- at the moment, we don't keep these around past renaming
rn_decl_warns <- rnSrcWarnDecls all_bndrs warn_decls ;
-- (H) Rename Everything else
(rn_rule_decls, src_fvs2) <- setXOptM LangExt.ScopedTypeVariables $
rnList rnHsRuleDecls rule_decls ;
-- Inside RULES, scoped type variables are on
(rn_foreign_decls, src_fvs3) <- rnList rnHsForeignDecl foreign_decls ;
(rn_ann_decls, src_fvs4) <- rnList rnAnnDecl ann_decls ;
(rn_default_decls, src_fvs5) <- rnList rnDefaultDecl default_decls ;
(rn_deriv_decls, src_fvs6) <- rnList rnSrcDerivDecl deriv_decls ;
(rn_splice_decls, src_fvs7) <- rnList rnSpliceDecl splice_decls ;
rn_docs <- traverse rnLDocDecl docs ;
last_tcg_env <- getGblEnv ;
-- (I) Compute the results and return
let {rn_group = HsGroup { hs_ext = noExtField,
hs_valds = rn_val_decls,
hs_splcds = rn_splice_decls,
hs_tyclds = rn_tycl_decls,
hs_derivds = rn_deriv_decls,
hs_fixds = rn_fix_decls,
hs_warnds = [], -- warns are returned in the tcg_env
-- (see below) not in the HsGroup
hs_fords = rn_foreign_decls,
hs_annds = rn_ann_decls,
hs_defds = rn_default_decls,
hs_ruleds = rn_rule_decls,
hs_docs = rn_docs } ;
tcf_bndrs = hsTyClForeignBinders rn_tycl_decls rn_foreign_decls ;
other_def = (Just (mkNameSet tcf_bndrs), emptyNameSet) ;
other_fvs = plusFVs [src_fvs1, src_fvs2, src_fvs3, src_fvs4,
src_fvs5, src_fvs6, src_fvs7] ;
-- It is tiresome to gather the binders from type and class decls
src_dus = unitOL other_def `plusDU` bind_dus `plusDU` usesOnly other_fvs ;
-- Instance decls may have occurrences of things bound in bind_dus
-- so we must put other_fvs last
final_tcg_env = let tcg_env' = (last_tcg_env `addTcgDUs` src_dus)
in -- we return the deprecs in the env, not in the HsGroup above
tcg_env' { tcg_warns = insertWarnDecls (tcg_warns tcg_env') rn_decl_warns };
} ;
traceRn "finish rnSrc" (ppr rn_group) ;
traceRn "finish Dus" (ppr src_dus ) ;
return (final_tcg_env, rn_group)
}}}}
addTcgDUs :: TcGblEnv -> DefUses -> TcGblEnv
-- This function could be defined lower down in the module hierarchy,
-- but there doesn't seem anywhere very logical to put it.
addTcgDUs tcg_env dus = tcg_env { tcg_dus = tcg_dus tcg_env `plusDU` dus }
rnList :: (a -> RnM (b, FreeVars)) -> [LocatedA a] -> RnM ([LocatedA b], FreeVars)
rnList f xs = mapFvRn (wrapLocFstMA f) xs
{-
*********************************************************
* *
Source-code deprecations declarations
* *
*********************************************************
Check that the deprecated names are defined, are defined locally, and
that there are no duplicate deprecations.
It's only imported deprecations, dealt with in RnIfaces, that we
gather them together.
-}
-- checks that the deprecations are defined locally, and that there are no duplicates
rnSrcWarnDecls :: NameSet -> [LWarnDecls GhcPs] -> RnM (DeclWarnOccNames GhcRn)
rnSrcWarnDecls _ []
= return []
rnSrcWarnDecls bndr_set decls'
= do { -- check for duplicates
; mapM_ (\ dups -> let ((L loc rdr) :| (lrdr':_)) = dups
in addErrAt (locA loc) (TcRnDuplicateWarningDecls lrdr' rdr))
warn_rdr_dups
; pairs_s <- mapM (addLocMA rn_deprec) decls
; return $ concat pairs_s }
where
decls = concatMap (wd_warnings . unLoc) decls'
sig_ctxt = TopSigCtxt bndr_set
rn_deprec (Warning _ rdr_names txt)
-- ensures that the names are defined locally
= do { names <- concatMapM (lookupLocalTcNames sig_ctxt what . unLoc)
rdr_names
; txt' <- rnWarningTxt txt
; return [(nameOccName nm, txt') | (_, nm) <- names] }
-- Use the OccName from the Name we looked up, rather than from the RdrName,
-- as we might hit multiple different NameSpaces when looking up
-- (e.g. deprecating both a variable and a record field).
what = text "deprecation"
warn_rdr_dups = findDupRdrNames
$ concatMap (\(L _ (Warning _ ns _)) -> ns) decls
rnWarningTxt :: WarningTxt GhcPs -> RnM (WarningTxt GhcRn)
rnWarningTxt (WarningTxt mb_cat st wst) = do
forM_ mb_cat $ \(L _ (InWarningCategory _ _ (L loc cat))) ->
unless (validWarningCategory cat) $
addErrAt loc (TcRnInvalidWarningCategory cat)
wst' <- traverse (traverse rnHsDoc) wst
pure (WarningTxt mb_cat st wst')
rnWarningTxt (DeprecatedTxt st wst) = do
wst' <- traverse (traverse rnHsDoc) wst
pure (DeprecatedTxt st wst')
findDupRdrNames :: [LocatedN RdrName] -> [NonEmpty (LocatedN RdrName)]
findDupRdrNames = findDupsEq (\ x -> \ y -> rdrNameOcc (unLoc x) == rdrNameOcc (unLoc y))
-- look for duplicates among the OccNames;
-- we check that the names are defined above
-- invt: the lists returned by findDupsEq always have at least two elements
{-
*********************************************************
* *
\subsection{Annotation declarations}
* *
*********************************************************
-}
rnAnnDecl :: AnnDecl GhcPs -> RnM (AnnDecl GhcRn, FreeVars)
rnAnnDecl ann@(HsAnnotation (_, s) provenance expr)
= addErrCtxt (annCtxt ann) $
do { (provenance', provenance_fvs) <- rnAnnProvenance provenance
; (expr', expr_fvs) <- setStage (Splice Untyped) $
rnLExpr expr
; return (HsAnnotation (noAnn, s) provenance' expr',
provenance_fvs `plusFV` expr_fvs) }
rnAnnProvenance :: AnnProvenance GhcPs
-> RnM (AnnProvenance GhcRn, FreeVars)
rnAnnProvenance provenance = do
provenance' <- case provenance of
ValueAnnProvenance n -> ValueAnnProvenance
<$> lookupLocatedTopBndrRnN n
TypeAnnProvenance n -> TypeAnnProvenance
<$> lookupLocatedTopConstructorRnN n
ModuleAnnProvenance -> return ModuleAnnProvenance
return (provenance', maybe emptyFVs unitFV (annProvenanceName_maybe provenance'))
{-
*********************************************************
* *
\subsection{Default declarations}
* *
*********************************************************
-}
rnDefaultDecl :: DefaultDecl GhcPs -> RnM (DefaultDecl GhcRn, FreeVars)
rnDefaultDecl (DefaultDecl _ tys)
= do { (tys', fvs) <- rnLHsTypes doc_str tys
; return (DefaultDecl noExtField tys', fvs) }
where
doc_str = DefaultDeclCtx
{-
*********************************************************
* *
\subsection{Foreign declarations}
* *
*********************************************************
-}
rnHsForeignDecl :: ForeignDecl GhcPs -> RnM (ForeignDecl GhcRn, FreeVars)
rnHsForeignDecl (ForeignImport { fd_name = name, fd_sig_ty = ty, fd_fi = spec })
= do { topEnv :: HscEnv <- getTopEnv
; warnForallIdentifier name
; name' <- lookupLocatedTopBndrRnN name
; (ty', fvs) <- rnHsSigType (ForeignDeclCtx name) TypeLevel ty
-- Mark any PackageTarget style imports as coming from the current package
; let home_unit = hsc_home_unit topEnv
spec' = patchForeignImport (homeUnitAsUnit home_unit) spec
; return (ForeignImport { fd_i_ext = noExtField
, fd_name = name', fd_sig_ty = ty'
, fd_fi = spec' }, fvs) }
rnHsForeignDecl (ForeignExport { fd_name = name, fd_sig_ty = ty, fd_fe = spec })
= do { name' <- lookupLocatedOccRn name
; (ty', fvs) <- rnHsSigType (ForeignDeclCtx name) TypeLevel ty
; return (ForeignExport { fd_e_ext = noExtField
, fd_name = name', fd_sig_ty = ty'
, fd_fe = (\(CExport x c) -> CExport x c) spec }
, fvs `addOneFV` unLoc name') }
-- NB: a foreign export is an *occurrence site* for name, so
-- we add it to the free-variable list. It might, for example,
-- be imported from another module
-- | For Windows DLLs we need to know what packages imported symbols are from
-- to generate correct calls. Imported symbols are tagged with the current
-- package, so if they get inlined across a package boundary we'll still
-- know where they're from.
--
patchForeignImport :: Unit -> (ForeignImport GhcPs) -> (ForeignImport GhcRn)
patchForeignImport unit (CImport ext cconv safety fs spec)
= CImport ext cconv safety fs (patchCImportSpec unit spec)
patchCImportSpec :: Unit -> CImportSpec -> CImportSpec
patchCImportSpec unit spec
= case spec of
CFunction callTarget -> CFunction $ patchCCallTarget unit callTarget
_ -> spec
patchCCallTarget :: Unit -> CCallTarget -> CCallTarget
patchCCallTarget unit callTarget =
case callTarget of
StaticTarget src label Nothing isFun
-> StaticTarget src label (Just unit) isFun
_ -> callTarget
{-
*********************************************************
* *
\subsection{Instance declarations}
* *
*********************************************************
-}
rnSrcInstDecl :: InstDecl GhcPs -> RnM (InstDecl GhcRn, FreeVars)
rnSrcInstDecl (TyFamInstD { tfid_inst = tfi })
= do { (tfi', fvs) <- rnTyFamInstDecl (NonAssocTyFamEqn NotClosedTyFam) tfi
; return (TyFamInstD { tfid_ext = noExtField, tfid_inst = tfi' }, fvs) }
rnSrcInstDecl (DataFamInstD { dfid_inst = dfi })
= do { (dfi', fvs) <- rnDataFamInstDecl (NonAssocTyFamEqn NotClosedTyFam) dfi
; return (DataFamInstD { dfid_ext = noExtField, dfid_inst = dfi' }, fvs) }
rnSrcInstDecl (ClsInstD { cid_inst = cid })
= do { traceRn "rnSrcIstDecl {" (ppr cid)
; (cid', fvs) <- rnClsInstDecl cid
; traceRn "rnSrcIstDecl end }" empty
; return (ClsInstD { cid_d_ext = noExtField, cid_inst = cid' }, fvs) }
-- | Warn about non-canonical typeclass instance declarations
--
-- A "non-canonical" instance definition can occur for instances of a
-- class which redundantly defines an operation its superclass
-- provides as well (c.f. `return`/`pure`). In such cases, a canonical
-- instance is one where the subclass inherits its method
-- implementation from its superclass instance (usually the subclass
-- has a default method implementation to that effect). Consequently,
-- a non-canonical instance occurs when this is not the case.
--
-- See also descriptions of 'checkCanonicalMonadInstances' and
-- 'checkCanonicalMonoidInstances'
checkCanonicalInstances :: Name -> LHsSigType GhcRn -> LHsBinds GhcRn -> RnM ()
checkCanonicalInstances cls poly_ty mbinds = do
whenWOptM Opt_WarnNonCanonicalMonadInstances
$ checkCanonicalMonadInstances
whenWOptM Opt_WarnNonCanonicalMonoidInstances
$ checkCanonicalMonoidInstances
where
-- Warn about unsound/non-canonical 'Applicative'/'Monad' instance
-- declarations. Specifically, the following conditions are verified:
--
-- In 'Monad' instances declarations:
--
-- * If 'return' is overridden it must be canonical (i.e. @return = pure@)
-- * If '(>>)' is overridden it must be canonical (i.e. @(>>) = (*>)@)
--
-- In 'Applicative' instance declarations:
--
-- * Warn if 'pure' is defined backwards (i.e. @pure = return@).
-- * Warn if '(*>)' is defined backwards (i.e. @(*>) = (>>)@).
--
checkCanonicalMonadInstances
| cls == applicativeClassName =
forM_ (bagToList mbinds) $ \(L loc mbind) -> setSrcSpanA loc $
case mbind of
FunBind { fun_id = L _ name
, fun_matches = mg }
| name == pureAName, isAliasMG mg == Just returnMName
-> addWarnNonCanonicalMonad NonCanonical_Pure
| name == thenAName, isAliasMG mg == Just thenMName
-> addWarnNonCanonicalMonad NonCanonical_ThenA
_ -> return ()
| cls == monadClassName =
forM_ (bagToList mbinds) $ \(L loc mbind) -> setSrcSpanA loc $
case mbind of
FunBind { fun_id = L _ name
, fun_matches = mg }
| name == returnMName, isAliasMG mg /= Just pureAName
-> addWarnNonCanonicalMonad NonCanonical_Return
| name == thenMName, isAliasMG mg /= Just thenAName
-> addWarnNonCanonicalMonad NonCanonical_ThenM
_ -> return ()
| otherwise = return ()
-- Check whether Monoid(mappend) is defined in terms of
-- Semigroup((<>)) (and not the other way round). Specifically,
-- the following conditions are verified:
--
-- In 'Monoid' instances declarations:
--
-- * If 'mappend' is overridden it must be canonical
-- (i.e. @mappend = (<>)@)
--
-- In 'Semigroup' instance declarations:
--
-- * Warn if '(<>)' is defined backwards (i.e. @(<>) = mappend@).
--
checkCanonicalMonoidInstances
| cls == semigroupClassName =
forM_ (bagToList mbinds) $ \(L loc mbind) -> setSrcSpanA loc $
case mbind of
FunBind { fun_id = L _ name
, fun_matches = mg }
| name == sappendName, isAliasMG mg == Just mappendName
-> addWarnNonCanonicalMonoid NonCanonical_Sappend
_ -> return ()
| cls == monoidClassName =
forM_ (bagToList mbinds) $ \(L loc mbind) -> setSrcSpanA loc $
case mbind of
FunBind { fun_id = L _ name
, fun_matches = mg }
| name == mappendName, isAliasMG mg /= Just sappendName
-> addWarnNonCanonicalMonoid NonCanonical_Mappend
_ -> return ()
| otherwise = return ()
-- test whether MatchGroup represents a trivial \"lhsName = rhsName\"
-- binding, and return @Just rhsName@ if this is the case
isAliasMG :: MatchGroup GhcRn (LHsExpr GhcRn) -> Maybe Name
isAliasMG MG {mg_alts = (L _ [L _ (Match { m_pats = []
, m_grhss = grhss })])}
| GRHSs _ [L _ (GRHS _ [] body)] lbinds <- grhss
, EmptyLocalBinds _ <- lbinds
, HsVar _ lrhsName <- unLoc body = Just (unLoc lrhsName)
isAliasMG _ = Nothing
addWarnNonCanonicalMonoid reason =
addWarnNonCanonicalDefinition (NonCanonicalMonoid reason)
addWarnNonCanonicalMonad reason =
addWarnNonCanonicalDefinition (NonCanonicalMonad reason)
addWarnNonCanonicalDefinition reason =
addDiagnostic (TcRnNonCanonicalDefinition reason poly_ty)
rnClsInstDecl :: ClsInstDecl GhcPs -> RnM (ClsInstDecl GhcRn, FreeVars)
rnClsInstDecl (ClsInstDecl { cid_poly_ty = inst_ty, cid_binds = mbinds
, cid_sigs = uprags, cid_tyfam_insts = ats
, cid_overlap_mode = oflag
, cid_datafam_insts = adts })
= do { checkInferredVars ctxt inst_ty
; (inst_ty', inst_fvs) <- rnHsSigType ctxt TypeLevel inst_ty
; let (ktv_names, _, head_ty') = splitLHsInstDeclTy inst_ty'
-- Check if there are any nested `forall`s or contexts, which are
-- illegal in the type of an instance declaration (see
-- Note [No nested foralls or contexts in instance types] in
-- GHC.Hs.Type)...
mb_nested_msg = noNestedForallsContextsErr
NFC_InstanceHead head_ty'
-- ...then check if the instance head is actually headed by a
-- class type constructor...
eith_cls = case hsTyGetAppHead_maybe head_ty' of
Just (L _ cls) -> Right cls
Nothing ->
Left
( getLocA head_ty'
, TcRnIllegalInstance $
IllegalClassInstance (HsTypeRnThing $ unLoc head_ty') $
IllegalInstanceHead $ InstHeadNonClass Nothing
)
-- ...finally, attempt to retrieve the class type constructor, failing
-- with an error message if there isn't one. To avoid excessive
-- amounts of error messages, we will only report one of the errors
-- from mb_nested_msg or eith_cls at a time.
; cls <- case (mb_nested_msg, eith_cls) of
(Nothing, Right cls) -> pure cls
(Just err1, _) -> bail_out err1
(_, Left err2) -> bail_out err2
-- Rename the bindings
-- The typechecker (not the renamer) checks that all
-- the bindings are for the right class
-- (Slightly strangely) when scoped type variables are on, the
-- forall-d tyvars scope over the method bindings too
; (mbinds', uprags', meth_fvs) <- rnMethodBinds False cls ktv_names mbinds uprags
; checkCanonicalInstances cls inst_ty' mbinds'
-- Rename the associated types, and type signatures
-- Both need to have the instance type variables in scope
; traceRn "rnSrcInstDecl" (ppr inst_ty' $$ ppr ktv_names)
; ((ats', adts'), more_fvs)
<- bindLocalNamesFV ktv_names $
do { (ats', at_fvs) <- rnATInstDecls rnTyFamInstDecl cls ktv_names ats
; (adts', adt_fvs) <- rnATInstDecls rnDataFamInstDecl cls ktv_names adts
; return ( (ats', adts'), at_fvs `plusFV` adt_fvs) }
; let all_fvs = meth_fvs `plusFV` more_fvs
`plusFV` inst_fvs
; return (ClsInstDecl { cid_ext = noExtField
, cid_poly_ty = inst_ty', cid_binds = mbinds'
, cid_sigs = uprags', cid_tyfam_insts = ats'
, cid_overlap_mode = oflag
, cid_datafam_insts = adts' },
all_fvs) }
-- We return the renamed associated data type declarations so
-- that they can be entered into the list of type declarations
-- for the binding group, but we also keep a copy in the instance.
-- The latter is needed for well-formedness checks in the type
-- checker (eg, to ensure that all ATs of the instance actually
-- receive a declaration).
-- NB: Even the copies in the instance declaration carry copies of
-- the instance context after renaming. This is a bit
-- strange, but should not matter (and it would be more work
-- to remove the context).
where
ctxt = GenericCtx $ text "an instance declaration"
-- The instance is malformed. We'd still like to make *some* progress
-- (rather than failing outright), so we report an error and continue for
-- as long as we can. Importantly, this error should be thrown before we
-- reach the typechecker, lest we encounter different errors that are
-- hopelessly confusing (such as the one in #16114).
bail_out (l, err_msg) = do
addErrAt l $ TcRnWithHsDocContext ctxt err_msg
pure $ mkUnboundName (mkTcOccFS (fsLit "<class>"))
rnFamEqn :: HsDocContext
-> AssocTyFamInfo
-> FamEqn GhcPs rhs
-> (HsDocContext -> rhs -> RnM (rhs', FreeVars))
-> RnM (FamEqn GhcRn rhs', FreeVars)
rnFamEqn doc atfi
(FamEqn { feqn_tycon = tycon
, feqn_bndrs = outer_bndrs
, feqn_pats = pats
, feqn_fixity = fixity
, feqn_rhs = payload }) rn_payload
= do { tycon' <- lookupFamInstName mb_cls tycon
-- all_imp_vars represent the implicitly bound type variables. This is
-- empty if we have an explicit `forall` (see
-- Note [forall-or-nothing rule] in GHC.Hs.Type), which means
-- ignoring pat_kity_vars, the free variables mentioned in the type patterns
-- on the LHS of the equation
--
-- Some examples:
--
-- @
-- type family F a b
-- type instance forall a b c. F [(a, b)] c = a -> b -> c
-- -- all_imp_vars = []
-- type instance F [(a, b)] c = a -> b -> c
-- -- all_imp_vars = [a, b, c]
--
-- type family G :: Maybe a
-- type instance forall a. G = (Nothing :: Maybe a)
-- -- all_imp_vars = []
--
-- data family H :: k -> Type
-- data instance forall k. H :: k -> Type where ...
-- -- all_imp_vars = []
-- data instance H :: k -> Type where ...
-- -- all_imp_vars = [k]
-- @
--
-- For associated type family instances, exclude the type variables
-- bound by the instance head with filterInScopeM (#19649).
; all_imp_vars <- filterInScopeM $ pat_kity_vars
; bindHsOuterTyVarBndrs doc mb_cls all_imp_vars outer_bndrs $ \rn_outer_bndrs ->
do { (pats', pat_fvs) <- rnLHsTypeArgs (FamPatCtx tycon) pats
; (payload', rhs_fvs) <- rn_payload doc payload
-- Report unused binders on the LHS
-- See Note [Unused type variables in family instances]
; let -- The SrcSpan that bindHsOuterFamEqnTyVarBndrs will attach to each
-- implicitly bound type variable Name in outer_bndrs' will
-- span the entire type family instance, which will be reflected in
-- -Wunused-type-patterns warnings. We can be a little more precise
-- than that by pointing to the LHS of the instance instead, which
-- is what lhs_loc corresponds to.
rn_outer_bndrs' = mapHsOuterImplicit (map (`setNameLoc` lhs_loc))
rn_outer_bndrs
groups :: [NonEmpty (LocatedN RdrName)]
groups = equivClasses cmpLocated pat_kity_vars
; nms_dups <- mapM (lookupOccRn . unLoc) $
[ tv | (tv :| (_:_)) <- groups ]
-- Add to the used variables
-- a) any variables that appear *more than once* on the LHS
-- e.g. F a Int a = Bool
-- b) for associated instances, the variables
-- of the instance decl. See
-- Note [Unused type variables in family instances]
; let nms_used = extendNameSetList rhs_fvs $
nms_dups {- (a) -} ++ inst_head_tvs {- (b) -}
all_nms = hsOuterTyVarNames rn_outer_bndrs'
; warnUnusedTypePatterns all_nms nms_used
-- For associated family instances, if a type variable from the
-- parent instance declaration is mentioned on the RHS of the
-- associated family instance but not bound on the LHS, then reject
-- that type variable as being out of scope.
-- See Note [Renaming associated types].
-- Per that Note, the LHS type variables consist of the variables
-- mentioned in the instance's type patterns (pat_fvs)
; let improperly_scoped cls_tkv =
cls_tkv `elemNameSet` rhs_fvs
-- Mentioned on the RHS...
&& not (cls_tkv `elemNameSet` pat_fvs)
-- ...but not bound on the LHS.
bad_tvs = filter improperly_scoped inst_head_tvs
; unless (null bad_tvs) $ addErr $
TcRnIllegalInstance $ IllegalFamilyInstance $
FamInstRHSOutOfScopeTyVars Nothing bad_tvs
; let eqn_fvs = rhs_fvs `plusFV` pat_fvs
-- See Note [Type family equations and occurrences]
all_fvs = case atfi of
NonAssocTyFamEqn ClosedTyFam
-> eqn_fvs
_ -> eqn_fvs `addOneFV` unLoc tycon'
; return (FamEqn { feqn_ext = noAnn
, feqn_tycon = tycon'
-- Note [Wildcards in family instances]
, feqn_bndrs = rn_outer_bndrs'
, feqn_pats = pats'
, feqn_fixity = fixity
, feqn_rhs = payload' },
all_fvs) } }
where
-- The parent class, if we are dealing with an associated type family
-- instance.
mb_cls = case atfi of
NonAssocTyFamEqn _ -> Nothing
AssocTyFamDeflt cls -> Just cls
AssocTyFamInst cls _ -> Just cls
-- The type variables from the instance head, if we are dealing with an
-- associated type family instance.
inst_head_tvs = case atfi of
NonAssocTyFamEqn _ -> []
AssocTyFamDeflt _ -> []
AssocTyFamInst _ inst_head_tvs -> inst_head_tvs
pat_kity_vars = extractHsTyArgRdrKiTyVars pats
-- It is crucial that extractHsTyArgRdrKiTyVars return
-- duplicate occurrences, since they're needed to help
-- determine unused binders on the LHS.
-- The SrcSpan of the LHS of the instance. For example, lhs_loc would be
-- the highlighted part in the example below:
--
-- type instance F a b c = Either a b
-- ^^^^^
lhs_loc = case map lhsTypeArgSrcSpan pats of
[] -> panic "rnFamEqn.lhs_loc"
[loc] -> loc
(loc:locs) -> loc `combineSrcSpans` last locs
rnTyFamInstDecl :: AssocTyFamInfo
-> TyFamInstDecl GhcPs
-> RnM (TyFamInstDecl GhcRn, FreeVars)
rnTyFamInstDecl atfi (TyFamInstDecl { tfid_xtn = x, tfid_eqn = eqn })
= do { (eqn', fvs) <- rnTyFamInstEqn atfi eqn
; return (TyFamInstDecl { tfid_xtn = x, tfid_eqn = eqn' }, fvs) }
-- | Tracks whether we are renaming:
--
-- 1. A type family equation that is not associated
-- with a parent type class ('NonAssocTyFamEqn'). Examples:
--
-- @
-- type family F a
-- type instance F Int = Bool -- NonAssocTyFamEqn NotClosed
--
-- type family G a where
-- G Int = Bool -- NonAssocTyFamEqn Closed
-- @
--
-- 2. An associated type family default declaration ('AssocTyFamDeflt').
-- Example:
--
-- @
-- class C a where
-- type A a
-- type instance A a = a -> a -- AssocTyFamDeflt C
-- @
--
-- 3. An associated type family instance declaration ('AssocTyFamInst').
-- Example:
--
-- @
-- instance C a => C [a] where
-- type A [a] = Bool -- AssocTyFamInst C [a]
-- @
data AssocTyFamInfo
= NonAssocTyFamEqn
ClosedTyFamInfo -- Is this a closed type family?
| AssocTyFamDeflt
Name -- Name of the parent class
| AssocTyFamInst
Name -- Name of the parent class
[Name] -- Names of the tyvars of the parent instance decl
-- | Tracks whether we are renaming an equation in a closed type family
-- equation ('ClosedTyFam') or not ('NotClosedTyFam').
data ClosedTyFamInfo
= NotClosedTyFam
| ClosedTyFam
rnTyFamInstEqn :: AssocTyFamInfo
-> TyFamInstEqn GhcPs
-> RnM (TyFamInstEqn GhcRn, FreeVars)
rnTyFamInstEqn atfi eqn@(FamEqn { feqn_tycon = tycon })
= rnFamEqn (TySynCtx tycon) atfi eqn rnTySyn
rnTyFamDefltDecl :: Name
-> TyFamDefltDecl GhcPs
-> RnM (TyFamDefltDecl GhcRn, FreeVars)
rnTyFamDefltDecl cls = rnTyFamInstDecl (AssocTyFamDeflt cls)
rnDataFamInstDecl :: AssocTyFamInfo
-> DataFamInstDecl GhcPs
-> RnM (DataFamInstDecl GhcRn, FreeVars)
rnDataFamInstDecl atfi (DataFamInstDecl { dfid_eqn =
eqn@(FamEqn { feqn_tycon = tycon })})
= do { (eqn', fvs) <-
rnFamEqn (TyDataCtx tycon) atfi eqn rnDataDefn
; return (DataFamInstDecl { dfid_eqn = eqn' }, fvs) }
-- Renaming of the associated types in instances.
-- Rename associated type family decl in class
rnATDecls :: Name -- Class
-> [LFamilyDecl GhcPs]
-> RnM ([LFamilyDecl GhcRn], FreeVars)
rnATDecls cls at_decls
= rnList (rnFamDecl (Just cls)) at_decls
rnATInstDecls :: (AssocTyFamInfo -> -- The function that renames
decl GhcPs -> -- an instance. rnTyFamInstDecl
RnM (decl GhcRn, FreeVars)) -- or rnDataFamInstDecl
-> Name -- Class
-> [Name]
-> [LocatedA (decl GhcPs)]
-> RnM ([LocatedA (decl GhcRn)], FreeVars)
-- Used for data and type family defaults in a class decl
-- and the family instance declarations in an instance
--
-- NB: We allow duplicate associated-type decls;
-- See Note [Associated type instances] in GHC.Tc.TyCl.Instance
rnATInstDecls rnFun cls tv_ns at_insts
= rnList (rnFun (AssocTyFamInst cls tv_ns)) at_insts
-- See Note [Renaming associated types]
{- Note [Wildcards in family instances]
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
Wild cards can be used in type/data family instance declarations to indicate
that the name of a type variable doesn't matter. Each wild card will be
replaced with a new unique type variable. For instance:
type family F a b :: *
type instance F Int _ = Int
is the same as
type family F a b :: *
type instance F Int b = Int
This is implemented as follows: Unnamed wildcards remain unchanged after
the renamer, and then given fresh meta-variables during typechecking, and
it is handled pretty much the same way as the ones in partial type signatures.
We however don't want to emit hole constraints on wildcards in family
instances, so we turn on PartialTypeSignatures and turn off warning flag to
let typechecker know this.
See related Note [Wildcards in visible kind application] in GHC.Tc.Gen.HsType
Note [Unused type variables in family instances]
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
When the flag -fwarn-unused-type-patterns is on, the compiler reports
warnings about unused type variables in type-family instances. A
tpye variable is considered used (i.e. cannot be turned into a wildcard)
when
* it occurs on the RHS of the family instance
e.g. type instance F a b = a -- a is used on the RHS
* it occurs multiple times in the patterns on the LHS
e.g. type instance F a a = Int -- a appears more than once on LHS
* it is one of the instance-decl variables, for associated types
e.g. instance C (a,b) where
type T (a,b) = a
Here the type pattern in the type instance must be the same as that
for the class instance, so
type T (a,_) = a
would be rejected. So we should not complain about an unused variable b
As usual, the warnings are not reported for type variables with names
beginning with an underscore.
Extra-constraints wild cards are not supported in type/data family
instance declarations.
Relevant tickets: #3699, #10586, #10982 and #11451.
Note [Renaming associated types]
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
When renaming a type/data family instance, be it top-level or associated with
a class, we must check that all of the type variables mentioned on the RHS are
properly scoped. Specifically, the rule is this:
Every variable mentioned on the RHS of a type instance declaration
(whether associated or not) must be mentioned on the LHS
Here is a simple example of something we should reject:
class C a b where
type F a x
instance C Int Bool where
type F Int x = z
Here, `z` is mentioned on the RHS of the associated instance without being
mentioned on the LHS. The renamer will reject `z` as being out of scope without much fuss.
Things get slightly trickier when the instance header itself binds type
variables. Consider this example (adapted from #5515):
instance C (p,q) z where
type F (p,q) x = (x, z)
According to the rule above, this instance is improperly scoped. However, due
to the way GHC's renamer works, `z` is /technically/ in scope, as GHC will
always bring type variables from an instance header into scope over the
associated type family instances. As a result, the renamer won't simply reject
the `z` as being out of scope (like it would for the `type F Int x = z`
example) unless further action is taken. It is important to reject this sort of
thing in the renamer, because if it is allowed to make it through to the
typechecker, unexpected shenanigans can occur (see #18021 for examples).
To prevent these sorts of shenanigans, we reject programs like the one above
with an extra validity check in rnFamEqn. For each type variable bound in the
parent instance head, we check if it is mentioned on the RHS of the associated
family instance but not bound on the LHS. If any of the instance-head-bound
variables meet these criteria, we throw an error.
(See rnFamEqn.improperly_scoped for how this is implemented.)
Some additional wrinkles:
* This Note only applies to *instance* declarations. In *class* declarations
there is no RHS to worry about, and the class variables can all be in scope
(#5862):
class Category (x :: k -> k -> *) where
type Ob x :: k -> Constraint
id :: Ob x a => x a a
(.) :: (Ob x a, Ob x b, Ob x c) => x b c -> x a b -> x a c
Here 'k' is in scope in the kind signature, just like 'x'.
* Although type family equations can bind type variables with explicit foralls,
it need not be the case that all variables that appear on the RHS must be
bound by a forall. For instance, the following is acceptable:
class C4 a where
type T4 a b
instance C4 (Maybe a) where
type forall b. T4 (Maybe a) b = Either a b
Even though `a` is not bound by the forall, this is still accepted because `a`
was previously bound by the `instance C4 (Maybe a)` part. (see #16116).
* In addition to the validity check in rnFamEqn.improperly_scoped, there is an
additional check in GHC.Tc.Validity.checkFamPatBinders that checks each family
instance equation for type variables used on the RHS but not bound on the
LHS. This is not made redundant by rmFamEqn.improperly_scoped, as there are
programs that each check will reject that the other check will not catch:
- checkValidFamPats is used on all forms of family instances, whereas
rmFamEqn.improperly_scoped only checks associated family instances. Since
checkFamPatBinders occurs after typechecking, it can catch programs that
introduce dodgy scoping by way of type synonyms (see #7536), which is
impractical to accomplish in the renamer.
- rnFamEqn.improperly_scoped catches some programs that, if allowed to escape
the renamer, would accidentally be accepted by the typechecker. Here is one
such program (#18021):
class C5 a where
data family D a
instance forall a. C5 Int where
data instance D Int = MkD a
If this is not rejected in the renamer, the typechecker would treat this
program as though the `a` were existentially quantified, like so:
data instance D Int = forall a. MkD a
This is likely not what the user intended!
Here is another such program (#9574):
class Funct f where
type Codomain f
instance Funct ('KProxy :: KProxy o) where
type Codomain 'KProxy = NatTr (Proxy :: o -> Type)
Where:
data Proxy (a :: k) = Proxy
data KProxy (t :: Type) = KProxy
data NatTr (c :: o -> Type)
Note that the `o` in the `Codomain 'KProxy` instance should be considered
improperly scoped. It does not meet the criteria for being explicitly
quantified, as it is not mentioned by name on the LHS.
However, `o` /is/ bound by the instance header, so if this
program is not rejected by the renamer, the typechecker would treat it as
though you had written this:
instance Funct ('KProxy :: KProxy o) where
type Codomain ('KProxy @o) = NatTr (Proxy :: o -> Type)
Although this is a valid program, it's probably a stretch too far to turn
`type Codomain 'KProxy = ...` into `type Codomain ('KProxy @o) = ...` here.
If the user really wants the latter, it is simple enough to communicate
their intent by mentioning `o` on the LHS by name.
* Historical note: Previously we had to add type variables from the outermost
kind signature on the RHS to the scope of associated type family instance,
i.e. GHC did implicit quantification over them. But now that we implement
GHC Proposal #425 "Invisible binders in type declarations"
we don't need to do this anymore.
Note [Type family equations and occurrences]
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
In most data/type family equations, the type family name used in the equation
is treated as an occurrence. For example:
module A where
type family F a
module B () where
import B (F)
type instance F Int = Bool
We do not want to warn about `F` being unused in the module `B`, as the
instance constitutes a use site for `F`. The exception to this rule is closed
type families, whose equations constitute a definition, not occurrences. For
example:
module C () where
type family CF a where
CF Char = Float
Here, we /do/ want to warn that `CF` is unused in the module `C`, as it is
defined but not used (#18470).
GHC accomplishes this in rnFamEqn when determining the set of free
variables to return at the end. If renaming a data family or open type family
equation, we add the name of the type family constructor to the set of returned
free variables to ensure that the name is marked as an occurrence. If renaming
a closed type family equation, we avoid adding the type family constructor name
to the free variables. This is quite simple, but it is not a perfect solution.
Consider this example:
module X () where
type family F a where
F Int = Bool
F Double = F Int
At present, GHC will treat any use of a type family constructor on the RHS of a
type family equation as an occurrence. Since `F` is used on the RHS of the
second equation of `F`, it is treated as an occurrence, causing `F` not to be
warned about. This is not ideal, since `F` isn't exported—it really /should/
cause a warning to be emitted. There is some discussion in #10089/#12920 about
how this limitation might be overcome, but until then, we stick to the
simplistic solution above, as it fixes the egregious bug in #18470.
-}
{-
*********************************************************
* *
\subsection{Stand-alone deriving declarations}
* *
*********************************************************
-}
rnSrcDerivDecl :: DerivDecl GhcPs -> RnM (DerivDecl GhcRn, FreeVars)
rnSrcDerivDecl (DerivDecl _ ty mds overlap)
= do { standalone_deriv_ok <- xoptM LangExt.StandaloneDeriving
; unless standalone_deriv_ok (addErr TcRnUnexpectedStandaloneDerivingDecl)
; checkInferredVars ctxt nowc_ty
; (mds', ty', fvs) <- rnLDerivStrategy ctxt mds $ rnHsSigWcType ctxt ty
-- Check if there are any nested `forall`s or contexts, which are
-- illegal in the type of an instance declaration (see
-- Note [No nested foralls or contexts in instance types] in
-- GHC.Hs.Type).
; addNoNestedForallsContextsErr ctxt
NFC_StandaloneDerivedInstanceHead
(getLHsInstDeclHead $ dropWildCards ty')
; warnNoDerivStrat mds' loc
; return (DerivDecl noAnn ty' mds' overlap, fvs) }
where
ctxt = DerivDeclCtx
loc = getLocA nowc_ty
nowc_ty = dropWildCards ty
{-
*********************************************************
* *
\subsection{Rules}
* *
*********************************************************
-}
rnHsRuleDecls :: RuleDecls GhcPs -> RnM (RuleDecls GhcRn, FreeVars)
rnHsRuleDecls (HsRules { rds_ext = (_, src)
, rds_rules = rules })
= do { (rn_rules,fvs) <- rnList rnHsRuleDecl rules
; return (HsRules { rds_ext = src
, rds_rules = rn_rules }, fvs) }
rnHsRuleDecl :: RuleDecl GhcPs -> RnM (RuleDecl GhcRn, FreeVars)
rnHsRuleDecl (HsRule { rd_ext = (_, st)
, rd_name = rule_name
, rd_act = act
, rd_tyvs = tyvs
, rd_tmvs = tmvs
, rd_lhs = lhs
, rd_rhs = rhs })
= do { let rdr_names_w_loc = map (get_var . unLoc) tmvs
; mapM_ warnForallIdentifier rdr_names_w_loc
; checkDupRdrNames rdr_names_w_loc
; checkShadowedRdrNames rdr_names_w_loc
; names <- newLocalBndrsRn rdr_names_w_loc
; let doc = RuleCtx (unLoc rule_name)
; bindRuleTyVars doc tyvs $ \ tyvs' ->
bindRuleTmVars doc tyvs' tmvs names $ \ tmvs' ->
do { (lhs', fv_lhs') <- rnLExpr lhs
; (rhs', fv_rhs') <- rnLExpr rhs
; checkValidRule (unLoc rule_name) names lhs' fv_lhs'
; return (HsRule { rd_ext = (HsRuleRn fv_lhs' fv_rhs', st)
, rd_name = rule_name
, rd_act = act
, rd_tyvs = tyvs'
, rd_tmvs = tmvs'
, rd_lhs = lhs'
, rd_rhs = rhs' }, fv_lhs' `plusFV` fv_rhs') } }
where
get_var :: RuleBndr GhcPs -> LocatedN RdrName
get_var (RuleBndrSig _ v _) = v
get_var (RuleBndr _ v) = v
bindRuleTmVars :: HsDocContext -> Maybe ty_bndrs
-> [LRuleBndr GhcPs] -> [Name]
-> ([LRuleBndr GhcRn] -> RnM (a, FreeVars))
-> RnM (a, FreeVars)
bindRuleTmVars doc tyvs vars names thing_inside
= go vars names $ \ vars' ->
bindLocalNamesFV names (thing_inside vars')
where
go ((L l (RuleBndr _ (L loc _))) : vars) (n : ns) thing_inside
= go vars ns $ \ vars' ->
thing_inside (L l (RuleBndr noAnn (L loc n)) : vars')
go ((L l (RuleBndrSig _ (L loc _) bsig)) : vars)
(n : ns) thing_inside
= rnHsPatSigType bind_free_tvs doc bsig $ \ bsig' ->
go vars ns $ \ vars' ->
thing_inside (L l (RuleBndrSig noAnn (L loc n) bsig') : vars')
go [] [] thing_inside = thing_inside []
go vars names _ = pprPanic "bindRuleVars" (ppr vars $$ ppr names)
bind_free_tvs = case tyvs of Nothing -> AlwaysBind
Just _ -> NeverBind
bindRuleTyVars :: HsDocContext -> Maybe [LHsTyVarBndr () GhcPs]
-> (Maybe [LHsTyVarBndr () GhcRn] -> RnM (b, FreeVars))
-> RnM (b, FreeVars)
bindRuleTyVars doc (Just bndrs) thing_inside
= bindLHsTyVarBndrs doc WarnUnusedForalls Nothing bndrs (thing_inside . Just)
bindRuleTyVars _ _ thing_inside = thing_inside Nothing
{-
Note [Rule LHS validity checking]
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
Check the shape of a rewrite rule LHS. Currently we only allow
LHSs of the form @(f e1 .. en)@, where @f@ is not one of the
@forall@'d variables.
We used restrict the form of the 'ei' to prevent you writing rules
with LHSs with a complicated desugaring (and hence unlikely to match);
(e.g. a case expression is not allowed: too elaborate.)
But there are legitimate non-trivial args ei, like sections and
lambdas. So it seems simpler not to check at all, and that is why
check_e is commented out.
-}
checkValidRule :: FastString -> [Name] -> LHsExpr GhcRn -> NameSet -> RnM ()
checkValidRule rule_name ids lhs' fv_lhs'
= do { -- Check for the form of the LHS
case (validRuleLhs ids lhs') of
Nothing -> return ()
Just bad -> failWithTc (badRuleLhsErr rule_name lhs' bad)
-- Check that LHS vars are all bound
; let bad_vars = [var | var <- ids, not (var `elemNameSet` fv_lhs')]
; mapM_ (addErr . TcRnUnusedVariableInRuleDecl rule_name) bad_vars }
validRuleLhs :: [Name] -> LHsExpr GhcRn -> Maybe (HsExpr GhcRn)
-- Nothing => OK
-- Just e => Not ok, and e is the offending sub-expression
validRuleLhs foralls lhs
= checkl lhs
where
checkl = check . unLoc
check (OpApp _ e1 op e2) = checkl op `mplus` checkl_e e1
`mplus` checkl_e e2
check (HsApp _ e1 e2) = checkl e1 `mplus` checkl_e e2
check (HsAppType _ e _ _) = checkl e
check (HsVar _ lv)
| (unLoc lv) `notElem` foralls = Nothing
check other = Just other -- Failure
-- Check an argument
checkl_e _ = Nothing
-- Was (check_e e); see Note [Rule LHS validity checking]
{- Commented out; see Note [Rule LHS validity checking] above
check_e (HsVar v) = Nothing
check_e (HsPar e) = checkl_e e
check_e (HsLit e) = Nothing
check_e (HsOverLit e) = Nothing
check_e (OpApp e1 op _ e2) = checkl_e e1 `mplus` checkl_e op `mplus` checkl_e e2
check_e (HsApp e1 e2) = checkl_e e1 `mplus` checkl_e e2
check_e (NegApp e _) = checkl_e e
check_e (ExplicitList _ es) = checkl_es es
check_e other = Just other -- Fails
checkl_es es = foldr (mplus . checkl_e) Nothing es
-}
badRuleLhsErr :: FastString -> LHsExpr GhcRn -> HsExpr GhcRn -> TcRnMessage
badRuleLhsErr name lhs bad_e
= TcRnIllegalRuleLhs errReason name lhs bad_e
where
errReason = case bad_e of
HsUnboundVar _ uv ->
UnboundVariable uv $ notInScopeErr WL_Global uv
_ -> IllegalExpression
{- **************************************************************
* *
Renaming type, class, instance and role declarations
* *
*****************************************************************
@rnTyDecl@ uses the `global name function' to create a new type
declaration in which local names have been replaced by their original
names, reporting any unknown names.
Renaming type variables is a pain. Because they now contain uniques,
it is necessary to pass in an association list which maps a parsed
tyvar to its @Name@ representation.
In some cases (type signatures of values),
it is even necessary to go over the type first
in order to get the set of tyvars used by it, make an assoc list,
and then go over it again to rename the tyvars!
However, we can also do some scoping checks at the same time.
Note [Dependency analysis of type, class, and instance decls]
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
A TyClGroup represents a strongly connected components of
type/class/instance decls, together with the role annotations for the
type/class declarations. The renamer uses strongly connected
component analysis to build these groups. We do this for a number of
reasons:
* Improve kind error messages. Consider
data T f a = MkT f a
data S f a = MkS f (T f a)
This has a kind error, but the error message is better if you
check T first, (fixing its kind) and *then* S. If you do kind
inference together, you might get an error reported in S, which
is jolly confusing. See #4875
* Increase kind polymorphism. See GHC.Tc.TyCl
Note [Grouping of type and class declarations]
Why do the instance declarations participate? At least two reasons
* Consider (#11348)
type family F a
type instance F Int = Bool
data R = MkR (F Int)
type Foo = 'MkR 'True
For Foo to kind-check we need to know that (F Int) ~ Bool. But we won't
know that unless we've looked at the type instance declaration for F
before kind-checking Foo.
* Another example is this (#3990).
data family Complex a
data instance Complex Double = CD {-# UNPACK #-} !Double
{-# UNPACK #-} !Double
data T = T {-# UNPACK #-} !(Complex Double)
Here, to generate the right kind of unpacked implementation for T,
we must have access to the 'data instance' declaration.
* Things become more complicated when we introduce transitive
dependencies through imported definitions, like in this scenario:
A.hs
type family Closed (t :: Type) :: Type where
Closed t = Open t
type family Open (t :: Type) :: Type
B.hs
data Q where
Q :: Closed Bool -> Q
type instance Open Int = Bool
type S = 'Q 'True
Somehow, we must ensure that the instance Open Int = Bool is checked before
the type synonym S. While we know that S depends upon 'Q depends upon Closed,
we have no idea that Closed depends upon Open!
To accommodate for these situations, we ensure that an instance is checked
before every @TyClDecl@ on which it does not depend. That's to say, instances
are checked as early as possible in @tcTyAndClassDecls@.
------------------------------------
So much for WHY. What about HOW? It's pretty easy:
(1) Rename the type/class, instance, and role declarations
individually
(2) Do strongly-connected component analysis of the type/class decls,
We'll make a TyClGroup for each SCC
In this step we treat a reference to a (promoted) data constructor
K as a dependency on its parent type. Thus
data T = K1 | K2
data S = MkS (Proxy 'K1)
Here S depends on 'K1 and hence on its parent T.
In this step we ignore instances; see
Note [No dependencies on data instances]
(3) Attach roles to the appropriate SCC
(4) Attach instances to the appropriate SCC.
We add an instance decl to SCC when:
all its free types/classes are bound in this SCC or earlier ones
(5) We make an initial TyClGroup, with empty group_tyclds, for any
(orphan) instances that affect only imported types/classes
Steps (3) and (4) are done by the (mapAccumL mk_group) call.
Note [No dependencies on data instances]
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
Consider this
data family D a
data instance D Int = D1
data S = MkS (Proxy 'D1)
Here the declaration of S depends on the /data instance/ declaration
for 'D Int'. That makes things a lot more complicated, especially
if the data instance is an associated type of an enclosing class instance.
(And the class instance might have several associated type instances
with different dependency structure!)
Ugh. For now we simply don't allow promotion of data constructors for
data instances. See Note [AFamDataCon: not promoting data family
constructors] in GHC.Tc.Utils.Env
-}
rnTyClDecls :: [TyClGroup GhcPs]
-> RnM ([TyClGroup GhcRn], FreeVars)
-- Rename the declarations and do dependency analysis on them
rnTyClDecls tycl_ds
= do { -- Rename the type/class, instance, and role declarations
; tycls_w_fvs <- mapM (wrapLocFstMA rnTyClDecl) (tyClGroupTyClDecls tycl_ds)
; let tc_names = mkNameSet (map (tcdName . unLoc . fst) tycls_w_fvs)
; traceRn "rnTyClDecls" $
vcat [ text "tyClGroupTyClDecls:" <+> ppr tycls_w_fvs
, text "tc_names:" <+> ppr tc_names ]
; kisigs_w_fvs <- rnStandaloneKindSignatures tc_names (tyClGroupKindSigs tycl_ds)
; instds_w_fvs <- mapM (wrapLocFstMA rnSrcInstDecl) (tyClGroupInstDecls tycl_ds)
; role_annots <- rnRoleAnnots tc_names (tyClGroupRoleDecls tycl_ds)
-- Do SCC analysis on the type/class decls
; rdr_env <- getGlobalRdrEnv
; traceRn "rnTyClDecls SCC analysis" $
vcat [ text "rdr_env:" <+> ppr rdr_env ]
; let tycl_sccs = depAnalTyClDecls rdr_env kisig_fv_env tycls_w_fvs
role_annot_env = mkRoleAnnotEnv role_annots
(kisig_env, kisig_fv_env) = mkKindSig_fv_env kisigs_w_fvs
inst_ds_map = mkInstDeclFreeVarsMap rdr_env tc_names instds_w_fvs
(init_inst_ds, rest_inst_ds) = getInsts [] inst_ds_map
first_group
| null init_inst_ds = []
| otherwise = [TyClGroup { group_ext = noExtField
, group_tyclds = []
, group_kisigs = []
, group_roles = []
, group_instds = init_inst_ds }]
(final_inst_ds, groups)
= mapAccumL (mk_group role_annot_env kisig_env) rest_inst_ds tycl_sccs
all_fvs = foldr (plusFV . snd) emptyFVs tycls_w_fvs `plusFV`
foldr (plusFV . snd) emptyFVs instds_w_fvs `plusFV`
foldr (plusFV . snd) emptyFVs kisigs_w_fvs
all_groups = first_group ++ groups
; massertPpr (null final_inst_ds)
(ppr instds_w_fvs
$$ ppr inst_ds_map
$$ ppr (flattenSCCs tycl_sccs)
$$ ppr final_inst_ds)
; traceRn "rnTycl dependency analysis made groups" (ppr all_groups)
; return (all_groups, all_fvs) }
where
mk_group :: RoleAnnotEnv
-> KindSigEnv
-> InstDeclFreeVarsMap
-> SCC (LTyClDecl GhcRn)
-> (InstDeclFreeVarsMap, TyClGroup GhcRn)
mk_group role_env kisig_env inst_map scc
= (inst_map', group)
where
tycl_ds = flattenSCC scc
bndrs = map (tcdName . unLoc) tycl_ds
roles = getRoleAnnots bndrs role_env
kisigs = getKindSigs bndrs kisig_env
(inst_ds, inst_map') = getInsts bndrs inst_map
group = TyClGroup { group_ext = noExtField
, group_tyclds = tycl_ds
, group_kisigs = kisigs
, group_roles = roles
, group_instds = inst_ds }
-- | Free variables of standalone kind signatures.
newtype KindSig_FV_Env = KindSig_FV_Env (NameEnv FreeVars)
lookupKindSig_FV_Env :: KindSig_FV_Env -> Name -> FreeVars
lookupKindSig_FV_Env (KindSig_FV_Env e) name
= fromMaybe emptyFVs (lookupNameEnv e name)
-- | Standalone kind signatures.
type KindSigEnv = NameEnv (LStandaloneKindSig GhcRn)
mkKindSig_fv_env :: [(LStandaloneKindSig GhcRn, FreeVars)] -> (KindSigEnv, KindSig_FV_Env)
mkKindSig_fv_env kisigs_w_fvs = (kisig_env, kisig_fv_env)
where
kisig_env = mapNameEnv fst compound_env
kisig_fv_env = KindSig_FV_Env (mapNameEnv snd compound_env)
compound_env :: NameEnv (LStandaloneKindSig GhcRn, FreeVars)
= mkNameEnvWith (standaloneKindSigName . unLoc . fst) kisigs_w_fvs
getKindSigs :: [Name] -> KindSigEnv -> [LStandaloneKindSig GhcRn]
getKindSigs bndrs kisig_env = mapMaybe (lookupNameEnv kisig_env) bndrs
rnStandaloneKindSignatures
:: NameSet -- names of types and classes in the current TyClGroup
-> [LStandaloneKindSig GhcPs]
-> RnM [(LStandaloneKindSig GhcRn, FreeVars)]
rnStandaloneKindSignatures tc_names kisigs
= do { let (no_dups, dup_kisigs) = removeDupsOn get_name kisigs
get_name = standaloneKindSigName . unLoc
; mapM_ dupKindSig_Err dup_kisigs
; mapM (wrapLocFstMA (rnStandaloneKindSignature tc_names)) no_dups
}
rnStandaloneKindSignature
:: NameSet -- names of types and classes in the current TyClGroup
-> StandaloneKindSig GhcPs
-> RnM (StandaloneKindSig GhcRn, FreeVars)
rnStandaloneKindSignature tc_names (StandaloneKindSig _ v ki)
= do { standalone_ki_sig_ok <- xoptM LangExt.StandaloneKindSignatures
; unless standalone_ki_sig_ok $ addErr TcRnUnexpectedStandaloneKindSig
; new_v <- lookupSigCtxtOccRn (TopSigCtxt tc_names) (text "standalone kind signature") v
; let doc = StandaloneKindSigCtx (ppr v)
; (new_ki, fvs) <- rnHsSigType doc KindLevel ki
; return (StandaloneKindSig noExtField new_v new_ki, fvs)
}
depAnalTyClDecls :: GlobalRdrEnv
-> KindSig_FV_Env
-> [(LTyClDecl GhcRn, FreeVars)]
-> [SCC (LTyClDecl GhcRn)]
-- See Note [Dependency analysis of type, class, and instance decls]
depAnalTyClDecls rdr_env kisig_fv_env ds_w_fvs
= stronglyConnCompFromEdgedVerticesUniq edges
where
edges :: [ Node Name (LTyClDecl GhcRn) ]
edges = [ DigraphNode d name (map (getParent rdr_env) (nonDetEltsUniqSet deps))
| (d, fvs) <- ds_w_fvs,
let { name = tcdName (unLoc d)
; kisig_fvs = lookupKindSig_FV_Env kisig_fv_env name
; deps = fvs `plusFV` kisig_fvs
}
]
-- It's OK to use nonDetEltsUFM here as
-- stronglyConnCompFromEdgedVertices is still deterministic
-- even if the edges are in nondeterministic order as explained
-- in Note [Deterministic SCC] in GHC.Data.Graph.Directed.
toParents :: GlobalRdrEnv -> NameSet -> NameSet
toParents rdr_env ns
= nonDetStrictFoldUniqSet add emptyNameSet ns
-- It's OK to use a non-deterministic fold because we immediately forget the
-- ordering by creating a set
where
add n s = extendNameSet s (getParent rdr_env n)
getParent :: GlobalRdrEnv -> Name -> Name
getParent rdr_env n
= case lookupGRE_Name rdr_env n of
Just gre -> case greParent gre of
ParentIs { par_is = p } -> p
_ -> n
Nothing -> n
{- ******************************************************
* *
Role annotations
* *
****************************************************** -}
-- | Renames role annotations, returning them as the values in a NameEnv
-- and checks for duplicate role annotations.
-- It is quite convenient to do both of these in the same place.
-- See also Note [Role annotations in the renamer]
rnRoleAnnots :: NameSet
-> [LRoleAnnotDecl GhcPs]
-> RnM [LRoleAnnotDecl GhcRn]
rnRoleAnnots tc_names role_annots
= do { -- Check for duplicates *before* renaming, to avoid
-- lumping together all the unboundNames
let (no_dups, dup_annots) = removeDupsOn get_name role_annots
get_name = roleAnnotDeclName . unLoc
; mapM_ dupRoleAnnotErr dup_annots
; mapM (wrapLocMA rn_role_annot1) no_dups }
where
rn_role_annot1 (RoleAnnotDecl _ tycon roles)
= do { -- the name is an *occurrence*, but look it up only in the
-- decls defined in this group (see #10263)
tycon' <- lookupSigCtxtOccRn (RoleAnnotCtxt tc_names)
(text "role annotation")
tycon
; return $ RoleAnnotDecl noExtField tycon' roles }
dupRoleAnnotErr :: NonEmpty (LRoleAnnotDecl GhcPs) -> RnM ()
dupRoleAnnotErr list@(L loc _ :| _)
= addErrAt (locA loc) (TcRnDuplicateRoleAnnot list)
dupKindSig_Err :: NonEmpty (LStandaloneKindSig GhcPs) -> RnM ()
dupKindSig_Err list@(L loc _ :| _)
= addErrAt (locA loc) (TcRnDuplicateKindSig list)
{- Note [Role annotations in the renamer]
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
We must ensure that a type's role annotation is put in the same group as the
proper type declaration. This is because role annotations are needed during
type-checking when creating the type's TyCon. So, rnRoleAnnots builds a
NameEnv (LRoleAnnotDecl Name) that maps a name to a role annotation for that
type, if any. Then, this map can be used to add the role annotations to the
groups after dependency analysis.
This process checks for duplicate role annotations, where we must be careful
to do the check *before* renaming to avoid calling all unbound names duplicates
of one another.
The renaming process, as usual, might identify and report errors for unbound
names. This is done by using lookupSigCtxtOccRn in rnRoleAnnots (using
lookupGlobalOccRn led to #8485).
-}
{- ******************************************************
* *
Dependency info for instances
* *
****************************************************** -}
----------------------------------------------------------
-- | 'InstDeclFreeVarsMap is an association of an
-- @InstDecl@ with @FreeVars@. The @FreeVars@ are
-- the tycon names that are both
-- a) free in the instance declaration
-- b) bound by this group of type/class/instance decls
type InstDeclFreeVarsMap = [(LInstDecl GhcRn, FreeVars)]
-- | Construct an @InstDeclFreeVarsMap@ by eliminating any @Name@s from the
-- @FreeVars@ which are *not* the binders of a @TyClDecl@.
mkInstDeclFreeVarsMap :: GlobalRdrEnv
-> NameSet
-> [(LInstDecl GhcRn, FreeVars)]
-> InstDeclFreeVarsMap
mkInstDeclFreeVarsMap rdr_env tycl_bndrs inst_ds_fvs
= [ (inst_decl, toParents rdr_env fvs `intersectFVs` tycl_bndrs)
| (inst_decl, fvs) <- inst_ds_fvs ]
-- | Get the @LInstDecl@s which have empty @FreeVars@ sets, and the
-- @InstDeclFreeVarsMap@ with these entries removed.
-- We call (getInsts tcs instd_map) when we've completed the declarations
-- for 'tcs'. The call returns (inst_decls, instd_map'), where
-- inst_decls are the instance declarations all of
-- whose free vars are now defined
-- instd_map' is the inst-decl map with 'tcs' removed from
-- the free-var set
getInsts :: [Name] -> InstDeclFreeVarsMap
-> ([LInstDecl GhcRn], InstDeclFreeVarsMap)
getInsts bndrs inst_decl_map
= partitionWith pick_me inst_decl_map
where
pick_me :: (LInstDecl GhcRn, FreeVars)
-> Either (LInstDecl GhcRn) (LInstDecl GhcRn, FreeVars)
pick_me (decl, fvs)
| isEmptyNameSet depleted_fvs = Left decl
| otherwise = Right (decl, depleted_fvs)
where
depleted_fvs = delFVs bndrs fvs
{- ******************************************************
* *
Renaming a type or class declaration
* *
****************************************************** -}
rnTyClDecl :: TyClDecl GhcPs
-> RnM (TyClDecl GhcRn, FreeVars)
-- All flavours of top-level type family declarations ("type family", "newtype
-- family", and "data family")
rnTyClDecl (FamDecl { tcdFam = fam })
= do { (fam', fvs) <- rnFamDecl Nothing fam
; return (FamDecl noExtField fam', fvs) }
rnTyClDecl (SynDecl { tcdLName = tycon, tcdTyVars = tyvars,
tcdFixity = fixity, tcdRhs = rhs })
= do { tycon' <- lookupLocatedTopConstructorRnN tycon
; let kvs = extractHsTyRdrTyVarsKindVars rhs
doc = TySynCtx tycon
; traceRn "rntycl-ty" (ppr tycon <+> ppr kvs)
; bindHsQTyVars doc Nothing kvs tyvars $ \ tyvars' free_rhs_kvs ->
do { mapM_ warn_implicit_kvs (nubL free_rhs_kvs)
; (rhs', fvs) <- rnTySyn doc rhs
; return (SynDecl { tcdLName = tycon', tcdTyVars = tyvars'
, tcdFixity = fixity
, tcdRhs = rhs', tcdSExt = fvs }, fvs) } }
where
warn_implicit_kvs :: LocatedN RdrName -> RnM ()
warn_implicit_kvs kv =
addDiagnosticAt (getLocA kv) (TcRnImplicitRhsQuantification kv)
-- "data", "newtype" declarations
rnTyClDecl (DataDecl
{ tcdLName = tycon, tcdTyVars = tyvars,
tcdFixity = fixity,
tcdDataDefn = defn@HsDataDefn{ dd_cons = cons, dd_kindSig = kind_sig} })
= do { tycon' <- lookupLocatedTopConstructorRnN tycon
; let kvs = extractDataDefnKindVars defn
doc = TyDataCtx tycon
new_or_data = dataDefnConsNewOrData cons
; traceRn "rntycl-data" (ppr tycon <+> ppr kvs)
; bindHsQTyVars doc Nothing kvs tyvars $ \ tyvars' free_rhs_kvs ->
do { (defn', fvs) <- rnDataDefn doc defn
; cusk <- data_decl_has_cusk tyvars' new_or_data (null free_rhs_kvs) kind_sig
; let rn_info = DataDeclRn { tcdDataCusk = cusk
, tcdFVs = fvs }
; traceRn "rndata" (ppr tycon <+> ppr cusk <+> ppr free_rhs_kvs)
; return (DataDecl { tcdLName = tycon'
, tcdTyVars = tyvars'
, tcdFixity = fixity
, tcdDataDefn = defn'
, tcdDExt = rn_info }, fvs) } }
rnTyClDecl (ClassDecl { tcdLayout = layout,
tcdCtxt = context, tcdLName = lcls,
tcdTyVars = tyvars, tcdFixity = fixity,
tcdFDs = fds, tcdSigs = sigs,
tcdMeths = mbinds, tcdATs = ats, tcdATDefs = at_defs,
tcdDocs = docs})
= do { lcls' <- lookupLocatedTopConstructorRnN lcls
; let cls' = unLoc lcls'
kvs = [] -- No scoped kind vars except those in
-- kind signatures on the tyvars
-- Tyvars scope over superclass context and method signatures
; ((tyvars', context', fds', ats'), stuff_fvs)
<- bindHsQTyVars cls_doc Nothing kvs tyvars $ \ tyvars' _ -> do
-- Checks for distinct tyvars
{ (context', cxt_fvs) <- rnMaybeContext cls_doc context
; fds' <- rnFds fds
-- The fundeps have no free variables
; (ats', fv_ats) <- rnATDecls cls' ats
; let fvs = cxt_fvs `plusFV`
fv_ats
; return ((tyvars', context', fds', ats'), fvs) }
; (at_defs', fv_at_defs) <- rnList (rnTyFamDefltDecl cls') at_defs
-- No need to check for duplicate associated type decls
-- since that is done by GHC.Rename.Names.extendGlobalRdrEnvRn
-- Check the signatures
-- First process the class op sigs (op_sigs), then the fixity sigs (non_op_sigs).
; let sig_rdr_names_w_locs =
[op | L _ (ClassOpSig _ False ops _) <- sigs
, op <- ops]
; checkDupRdrNames sig_rdr_names_w_locs
-- Typechecker is responsible for checking that we only
-- give default-method bindings for things in this class.
-- The renamer *could* check this for class decls, but can't
-- for instance decls.
-- The newLocals call is tiresome: given a generic class decl
-- class C a where
-- op :: a -> a
-- op {| x+y |} (Inl a) = ...
-- op {| x+y |} (Inr b) = ...
-- op {| a*b |} (a*b) = ...
-- we want to name both "x" tyvars with the same unique, so that they are
-- easy to group together in the typechecker.
; (mbinds', sigs', meth_fvs)
<- rnMethodBinds True cls' (hsAllLTyVarNames tyvars') mbinds sigs
-- No need to check for duplicate method signatures
-- since that is done by GHC.Rename.Names.extendGlobalRdrEnvRn
-- and the methods are already in scope
; let all_fvs = meth_fvs `plusFV` stuff_fvs `plusFV` fv_at_defs
; docs' <- traverse rnLDocDecl docs
; return (ClassDecl { tcdLayout = rnLayoutInfo layout,
tcdCtxt = context', tcdLName = lcls',
tcdTyVars = tyvars', tcdFixity = fixity,
tcdFDs = fds', tcdSigs = sigs',
tcdMeths = mbinds', tcdATs = ats', tcdATDefs = at_defs',
tcdDocs = docs', tcdCExt = all_fvs },
all_fvs ) }
where
cls_doc = ClassDeclCtx lcls
rnLayoutInfo :: LayoutInfo GhcPs -> LayoutInfo GhcRn
rnLayoutInfo (ExplicitBraces ob cb) = ExplicitBraces ob cb
rnLayoutInfo (VirtualBraces n) = VirtualBraces n
rnLayoutInfo NoLayoutInfo = NoLayoutInfo
-- Does the data type declaration include a CUSK?
data_decl_has_cusk :: LHsQTyVars (GhcPass p) -> NewOrData -> Bool -> Maybe (LHsKind (GhcPass p')) -> RnM Bool
data_decl_has_cusk tyvars new_or_data no_rhs_kvs kind_sig = do
{ -- See Note [Unlifted Newtypes and CUSKs], and for a broader
-- picture, see Note [Implementation of UnliftedNewtypes].
; unlifted_newtypes <- xoptM LangExt.UnliftedNewtypes
; let non_cusk_newtype
| NewType <- new_or_data =
unlifted_newtypes && isNothing kind_sig
| otherwise = False
-- See Note [CUSKs: complete user-supplied kind signatures] in GHC.Hs.Decls
; return $ hsTvbAllKinded tyvars && no_rhs_kvs && not non_cusk_newtype
}
{- Note [Unlifted Newtypes and CUSKs]
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
When unlifted newtypes are enabled, a newtype must have a kind signature
in order to be considered have a CUSK. This is because the flow of
kind inference works differently. Consider:
newtype Foo = FooC Int
When UnliftedNewtypes is disabled, we decide that Foo has kind
`TYPE 'LiftedRep` without looking inside the data constructor. So, we
can say that Foo has a CUSK. However, when UnliftedNewtypes is enabled,
we fill in the kind of Foo as a metavar that gets solved by unification
with the kind of the field inside FooC (that is, Int, whose kind is
`TYPE 'LiftedRep`). But since we have to look inside the data constructors
to figure out the kind signature of Foo, it does not have a CUSK.
See Note [Implementation of UnliftedNewtypes] for where this fits in to
the broader picture of UnliftedNewtypes.
-}
-- "type" and "type instance" declarations
rnTySyn :: HsDocContext -> LHsType GhcPs -> RnM (LHsType GhcRn, FreeVars)
rnTySyn doc rhs = rnLHsType doc rhs
rnDataDefn :: HsDocContext -> HsDataDefn GhcPs
-> RnM (HsDataDefn GhcRn, FreeVars)
rnDataDefn doc (HsDataDefn { dd_cType = cType, dd_ctxt = context, dd_cons = condecls
, dd_kindSig = m_sig, dd_derivs = derivs })
= do { -- DatatypeContexts (i.e., stupid contexts) can't be combined with
-- GADT syntax. See Note [The stupid context] in GHC.Core.DataCon.
checkTc (h98_style || null (fromMaybeContext context))
(TcRnStupidThetaInGadt doc)
-- Check restrictions on "type data" declarations.
-- See Note [Type data declarations].
; when (isTypeDataDefnCons condecls) check_type_data
; (m_sig', sig_fvs) <- case m_sig of
Just sig -> first Just <$> rnLHsKind doc sig
Nothing -> return (Nothing, emptyFVs)
; (context', fvs1) <- rnMaybeContext doc context
; (derivs', fvs3) <- rn_derivs derivs
-- For the constructor declarations, drop the LocalRdrEnv
-- in the GADT case, where the type variables in the declaration
-- do not scope over the constructor signatures
-- data T a where { T1 :: forall b. b-> b }
; let { zap_lcl_env | h98_style = \ thing -> thing
| otherwise = setLocalRdrEnv emptyLocalRdrEnv }
; (condecls', con_fvs) <- zap_lcl_env $ rnConDecls condecls
-- No need to check for duplicate constructor decls
-- since that is done by GHC.Rename.Names.extendGlobalRdrEnvRn
; let all_fvs = fvs1 `plusFV` fvs3 `plusFV`
con_fvs `plusFV` sig_fvs
; return ( HsDataDefn { dd_ext = noExtField, dd_cType = cType
, dd_ctxt = context', dd_kindSig = m_sig'
, dd_cons = condecls'
, dd_derivs = derivs' }
, all_fvs )
}
where
h98_style = not $ anyLConIsGadt condecls -- Note [Stupid theta]
rn_derivs ds
= do { deriv_strats_ok <- xoptM LangExt.DerivingStrategies
; failIfTc (lengthExceeds ds 1 && not deriv_strats_ok)
TcRnIllegalMultipleDerivClauses
; (ds', fvs) <- mapFvRn (rnLHsDerivingClause doc) ds
; return (ds', fvs) }
-- Given a "type data" declaration, check that the TypeData extension
-- is enabled and check restrictions (R1), (R2), (R3) and (R5)
-- on the declaration. See Note [Type data declarations].
check_type_data
= do { unlessXOptM LangExt.TypeData $ failWith TcRnIllegalTypeData
; unless (null (fromMaybeContext context)) $
failWith $ TcRnTypeDataForbids TypeDataForbidsDatatypeContexts
; mapM_ (addLocMA check_type_data_condecl) condecls
; unless (null derivs) $
failWith $ TcRnTypeDataForbids TypeDataForbidsDerivingClauses
}
-- Check restrictions (R2) and (R3) on a "type data" constructor.
-- See Note [Type data declarations].
check_type_data_condecl :: ConDecl GhcPs -> RnM ()
check_type_data_condecl condecl
= do {
; when (has_labelled_fields condecl) $
failWith $ TcRnTypeDataForbids TypeDataForbidsLabelledFields
; when (has_strictness_flags condecl) $
failWith $ TcRnTypeDataForbids TypeDataForbidsStrictnessAnnotations
}
has_labelled_fields (ConDeclGADT { con_g_args = RecConGADT _ _ }) = True
has_labelled_fields (ConDeclH98 { con_args = RecCon rec })
= not (null (unLoc rec))
has_labelled_fields _ = False
has_strictness_flags condecl
= any (is_strict . getBangStrictness . hsScaledThing) (con_args condecl)
is_strict (HsSrcBang _ _ s) = isSrcStrict s
con_args (ConDeclGADT { con_g_args = PrefixConGADT args }) = args
con_args (ConDeclH98 { con_args = PrefixCon _ args }) = args
con_args (ConDeclH98 { con_args = InfixCon arg1 arg2 }) = [arg1, arg2]
con_args _ = []
{-
Note [Type data declarations]
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
With the TypeData extension (GHC proposal #106), one can write `type data`
declarations, like
type data Nat = Zero | Succ Nat
or equivalently in GADT style:
type data Nat where
Zero :: Nat
Succ :: Nat -> Nat
This defines the constructors `Zero` and `Succ` in the TcCls namespace
(type constructors and classes) instead of the Data namespace (data
constructors). This contrasts with the DataKinds extension, which
allows constructors defined in the Data namespace to be promoted to the
TcCls namespace at the point of use in a type.
Type data declarations have the syntax of `data` declarations (but not
`newtype` declarations), either ordinary algebraic data types or GADTs,
preceded by `type`, with the following restrictions:
(R0) 'data' decls only, not 'newtype' decls. This is checked by
the parser.
(R1) There are no data type contexts (even with the DatatypeContexts
extension).
(R2) There are no labelled fields. Perhaps these could be supported
using type families, but they are omitted for now.
(R3) There are no strictness flags, because they don't make sense at
the type level.
(R4) The types of the constructors contain no constraints.
(R5) There are no deriving clauses.
The data constructors of a `type data` declaration obey the following
Core invariant:
(I1) The data constructors of a `type data` declaration may be mentioned in
/types/, but never in /terms/ or the /pattern of a case alternative/.
Wrinkles:
(W0) Wrappers. The data constructor of a `type data` declaration has a worker
(like every data constructor) but does /not/ have a wrapper. Wrappers
only make sense for value-level data constructors. Indeed, the worker Id
is never used (invariant (I1)), so it barely makes sense to talk about
the worker. A `type data` constructor only shows up in types, where it
appears as a TyCon, specifically a PromotedDataCon -- no Id in sight.
See `wrapped_reqd` in GHC.Types.Id.Make.mkDataConRep` for the place where
this check is implemented.
This specifically includes `type data` declarations implemented as GADTs,
such as this example from #22948:
type data T a where
A :: T Int
B :: T a
If `T` were an ordinary `data` declaration, then `A` would have a wrapper
to account for the GADT-like equality in its return type. Because `T` is
declared as a `type data` declaration, however, the wrapper is omitted.
(W1) To prevent users from conjuring up `type data` values at the term level,
we disallow using the tagToEnum# function on a type headed by a `type
data` type. For instance, GHC will reject this code:
type data Letter = A | B | C
f :: Letter
f = tagToEnum# 0#
See `GHC.Tc.Gen.App.checkTagToEnum`, specifically `check_enumeration`.
(W2) Although `type data` data constructors do not exist at the value level,
it is still possible to match on a value whose type is headed by a `type data`
type constructor, such as this example from #22964:
type data T a where
A :: T Int
B :: T a
f :: T a -> ()
f x = case x of {}
And yet we must guarantee invariant (I1). This has three consequences:
(W2a) During checking the coverage of `f`'s pattern matches, we treat `T`
as if it were an empty data type so that GHC does not warn the user
to match against `A` or `B`. (Otherwise, you end up with the bug
reported in #22964.) See GHC.HsToCore.Pmc.Solver.vanillaCompleteMatchTC.
(W2b) In `GHC.Core.Utils.refineDataAlt`, do /not/ fill in the DEFAULT case
with the data constructor, else (I1) is violated. See GHC.Core.Utils
Note [Refine DEFAULT case alternatives] Exception 2
(W2c) In `GHC.Core.Opt.ConstantFold.caseRules`, disable the rule for
`dataToTag#` in the case of `type data`. We do not want to transform
case dataToTag# x of t -> blah
into
case x of { A -> ...; B -> .. }
because again that conjures up the type-level-only data contructors
`A` and `B` in a pattern, violating (I1) (#23023).
The main parts of the implementation are:
* The parser recognizes `type data` (but not `type newtype`); this ensures (R0).
* During the initial construction of the AST,
GHC.Parser.PostProcess.checkNewOrData sets the `Bool` argument of the
`DataTypeCons` inside a `HsDataDefn` to mark a `type data` declaration.
It also puts the the constructor names (`Zero` and `Succ` in our
example) in the TcCls namespace.
* GHC.Rename.Module.rnDataDefn calls `check_type_data` on these
declarations, which checks that the TypeData extension is enabled and
checks restrictions (R1), (R2), (R3) and (R5). They could equally
well be checked in the typechecker, but we err on the side of catching
imposters early.
* GHC.Tc.TyCl.checkValidDataCon checks restriction (R4) on these declarations.
* When beginning to type check a mutually recursive group of declarations,
the `type data` constructors (`Zero` and `Succ` in our example) are
added to the type-checker environment as `APromotionErr TyConPE` by
GHC.Tc.TyCl.mkPromotionErrorEnv, so they cannot be used within the
recursive group. This mirrors the DataKinds behaviour described
at Note [Recursion and promoting data constructors] in GHC.Tc.TyCl.
For example, this is rejected:
type data T f = K (f (K Int)) -- illegal: tycon K is recursively defined
* The `type data` data type, such as `Nat` in our example, is represented
by a `TyCon` that is an `AlgTyCon`, but its `AlgTyConRhs` has the
`is_type_data` field set.
* The constructors of the data type, `Zero` and `Succ` in our example,
are each represented by a `DataCon` as usual. That `DataCon`'s
`dcPromotedField` is a `TyCon` (for `Zero`, say) that you can use
in a type.
* After a `type data` declaration has been type-checked, the
type-checker environment entry (a `TyThing`) for each constructor
(`Zero` and `Succ` in our example) is
- just an `ATyCon` for the promoted type constructor,
- not the bundle (`ADataCon` for the data con, `AnId` for the work id,
wrap id) required for a normal data constructor
See GHC.Types.TyThing.implicitTyConThings.
* GHC.Core.TyCon.isDataKindsPromotedDataCon ignores promoted constructors
from `type data`, which do not use the distinguishing quote mark added
to constructors promoted by DataKinds.
* GHC.Core.TyCon.isDataTyCon ignores types coming from a `type data`
declaration (by checking the `is_type_data` field), so that these do
not contribute executable code such as constructor wrappers.
* The `is_type_data` field is copied into a Boolean argument
of the `IfDataTyCon` constructor of `IfaceConDecls` by
GHC.Iface.Make.tyConToIfaceDecl.
* The Template Haskell `Dec` type has an constructor `TypeDataD` for
`type data` declarations. When these are converted back to Hs types
in a splice, the constructors are placed in the TcCls namespace.
-}
warnNoDerivStrat :: Maybe (LDerivStrategy GhcRn)
-> SrcSpan
-> RnM ()
warnNoDerivStrat mds loc
= do { dyn_flags <- getDynFlags
; case mds of
Nothing ->
addDiagnosticAt loc $ TcRnNoDerivStratSpecified
(xopt LangExt.DerivingStrategies dyn_flags)
_ -> pure ()
}
rnLHsDerivingClause :: HsDocContext -> LHsDerivingClause GhcPs
-> RnM (LHsDerivingClause GhcRn, FreeVars)
rnLHsDerivingClause doc
(L loc (HsDerivingClause
{ deriv_clause_ext = noExtField
, deriv_clause_strategy = dcs
, deriv_clause_tys = dct }))
= do { (dcs', dct', fvs)
<- rnLDerivStrategy doc dcs $ rn_deriv_clause_tys dct
; warnNoDerivStrat dcs' (locA loc)
; pure ( L loc (HsDerivingClause { deriv_clause_ext = noExtField
, deriv_clause_strategy = dcs'
, deriv_clause_tys = dct' })
, fvs ) }
where
rn_deriv_clause_tys :: LDerivClauseTys GhcPs
-> RnM (LDerivClauseTys GhcRn, FreeVars)
rn_deriv_clause_tys (L l dct) = case dct of
DctSingle x ty -> do
(ty', fvs) <- rn_clause_pred ty
pure (L l (DctSingle x ty'), fvs)
DctMulti x tys -> do
(tys', fvs) <- mapFvRn rn_clause_pred tys
pure (L l (DctMulti x tys'), fvs)
rn_clause_pred :: LHsSigType GhcPs -> RnM (LHsSigType GhcRn, FreeVars)
rn_clause_pred pred_ty = do
checkInferredVars doc pred_ty
ret@(pred_ty', _) <- rnHsSigType doc TypeLevel pred_ty
-- Check if there are any nested `forall`s, which are illegal in a
-- `deriving` clause.
-- See Note [No nested foralls or contexts in instance types]
-- (Wrinkle: Derived instances) in GHC.Hs.Type.
addNoNestedForallsContextsErr doc NFC_DerivedClassType
(getLHsInstDeclHead pred_ty')
pure ret
rnLDerivStrategy :: forall a.
HsDocContext
-> Maybe (LDerivStrategy GhcPs)
-> RnM (a, FreeVars)
-> RnM (Maybe (LDerivStrategy GhcRn), a, FreeVars)
rnLDerivStrategy doc mds thing_inside
= case mds of
Nothing -> boring_case Nothing
Just (L loc ds) ->
setSrcSpanA loc $ do
(ds', thing, fvs) <- rn_deriv_strat ds
pure (Just (L loc ds'), thing, fvs)
where
rn_deriv_strat :: DerivStrategy GhcPs
-> RnM (DerivStrategy GhcRn, a, FreeVars)
rn_deriv_strat ds = do
let extNeeded :: LangExt.Extension
extNeeded
| ViaStrategy{} <- ds
= LangExt.DerivingVia
| otherwise
= LangExt.DerivingStrategies
unlessXOptM extNeeded $
failWith $ TcRnIllegalDerivStrategy ds
case ds of
StockStrategy _ -> boring_case (StockStrategy noExtField)
AnyclassStrategy _ -> boring_case (AnyclassStrategy noExtField)
NewtypeStrategy _ -> boring_case (NewtypeStrategy noExtField)
ViaStrategy (XViaStrategyPs _ via_ty) ->
do checkInferredVars doc via_ty
(via_ty', fvs1) <- rnHsSigType doc TypeLevel via_ty
let HsSig { sig_bndrs = via_outer_bndrs
, sig_body = via_body } = unLoc via_ty'
via_tvs = hsOuterTyVarNames via_outer_bndrs
-- Check if there are any nested `forall`s, which are illegal in a
-- `via` type.
-- See Note [No nested foralls or contexts in instance types]
-- (Wrinkle: Derived instances) in GHC.Hs.Type.
addNoNestedForallsContextsErr doc
NFC_ViaType via_body
(thing, fvs2) <- bindLocalNamesFV via_tvs thing_inside
pure (ViaStrategy via_ty', thing, fvs1 `plusFV` fvs2)
boring_case :: ds -> RnM (ds, a, FreeVars)
boring_case ds = do
(thing, fvs) <- thing_inside
pure (ds, thing, fvs)
rnFamDecl :: Maybe Name -- Just cls => this FamilyDecl is nested
-- inside an *class decl* for cls
-- used for associated types
-> FamilyDecl GhcPs
-> RnM (FamilyDecl GhcRn, FreeVars)
rnFamDecl mb_cls (FamilyDecl { fdLName = tycon, fdTyVars = tyvars
, fdTopLevel = toplevel
, fdFixity = fixity
, fdInfo = info, fdResultSig = res_sig
, fdInjectivityAnn = injectivity })
= do { tycon' <- lookupLocatedTopConstructorRnN tycon
; ((tyvars', res_sig', injectivity'), fv1) <-
bindHsQTyVars doc mb_cls kvs tyvars $ \ tyvars' _ ->
do { let rn_sig = rnFamResultSig doc
; (res_sig', fv_kind) <- wrapLocFstMA rn_sig res_sig
; injectivity' <- traverse (rnInjectivityAnn tyvars' res_sig')
injectivity
; return ( (tyvars', res_sig', injectivity') , fv_kind ) }
; (info', fv2) <- rn_info info
; return (FamilyDecl { fdExt = noAnn
, fdLName = tycon', fdTyVars = tyvars'
, fdTopLevel = toplevel
, fdFixity = fixity
, fdInfo = info', fdResultSig = res_sig'
, fdInjectivityAnn = injectivity' }
, fv1 `plusFV` fv2) }
where
doc = TyFamilyCtx tycon
kvs = extractRdrKindSigVars res_sig
----------------------
rn_info :: FamilyInfo GhcPs -> RnM (FamilyInfo GhcRn, FreeVars)
rn_info (ClosedTypeFamily (Just eqns))
= do { (eqns', fvs)
<- rnList (rnTyFamInstEqn (NonAssocTyFamEqn ClosedTyFam)) eqns
-- no class context
; return (ClosedTypeFamily (Just eqns'), fvs) }
rn_info (ClosedTypeFamily Nothing)
= return (ClosedTypeFamily Nothing, emptyFVs)
rn_info OpenTypeFamily = return (OpenTypeFamily, emptyFVs)
rn_info DataFamily = return (DataFamily, emptyFVs)
rnFamResultSig :: HsDocContext
-> FamilyResultSig GhcPs
-> RnM (FamilyResultSig GhcRn, FreeVars)
rnFamResultSig _ (NoSig _)
= return (NoSig noExtField, emptyFVs)
rnFamResultSig doc (KindSig _ kind)
= do { (rndKind, ftvs) <- rnLHsKind doc kind
; return (KindSig noExtField rndKind, ftvs) }
rnFamResultSig doc (TyVarSig _ tvbndr)
= do { -- `TyVarSig` tells us that user named the result of a type family by
-- writing `= tyvar` or `= (tyvar :: kind)`. In such case we want to
-- be sure that the supplied result name is not identical to an
-- already in-scope type variable from an enclosing class.
--
-- Example of disallowed declaration:
-- class C a b where
-- type F b = a | a -> b
rdr_env <- getLocalRdrEnv
; let resName = hsLTyVarName tvbndr
; when (resName `elemLocalRdrEnv` rdr_env) $
addErrAt (getLocA tvbndr) $
TcRnShadowedTyVarNameInFamResult resName
; bindLHsTyVarBndr doc Nothing -- This might be a lie, but it's used for
-- scoping checks that are irrelevant here
tvbndr $ \ tvbndr' ->
return (TyVarSig noExtField tvbndr', unitFV (hsLTyVarName tvbndr')) }
-- Note [Renaming injectivity annotation]
-- ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
--
-- During renaming of injectivity annotation we have to make several checks to
-- make sure that it is well-formed. At the moment injectivity annotation
-- consists of a single injectivity condition, so the terms "injectivity
-- annotation" and "injectivity condition" might be used interchangeably. See
-- Note [Injectivity annotation] for a detailed discussion of currently allowed
-- injectivity annotations.
--
-- Checking LHS is simple because the only type variable allowed on the LHS of
-- injectivity condition is the variable naming the result in type family head.
-- Example of disallowed annotation:
--
-- type family Foo a b = r | b -> a
--
-- Verifying RHS of injectivity consists of checking that:
--
-- 1. only variables defined in type family head appear on the RHS (kind
-- variables are also allowed). Example of disallowed annotation:
--
-- type family Foo a = r | r -> b
--
-- 2. for associated types the result variable does not shadow any of type
-- class variables. Example of disallowed annotation:
--
-- class Foo a b where
-- type F a = b | b -> a
--
-- Breaking any of these assumptions results in an error.
-- | Rename injectivity annotation. Note that injectivity annotation is just the
-- part after the "|". Everything that appears before it is renamed in
-- rnFamDecl.
rnInjectivityAnn :: LHsQTyVars GhcRn -- ^ Type variables declared in
-- type family head
-> LFamilyResultSig GhcRn -- ^ Result signature
-> LInjectivityAnn GhcPs -- ^ Injectivity annotation
-> RnM (LInjectivityAnn GhcRn)
rnInjectivityAnn tvBndrs (L _ (TyVarSig _ resTv))
(L srcSpan (InjectivityAnn x injFrom injTo))
= do
{ (injDecl'@(L _ (InjectivityAnn _ injFrom' injTo')), noRnErrors)
<- askNoErrs $
bindLocalNames [hsLTyVarName resTv] $
-- The return type variable scopes over the injectivity annotation
-- e.g. type family F a = (r::*) | r -> a
do { injFrom' <- rnLTyVar injFrom
; injTo' <- mapM rnLTyVar injTo
-- Note: srcSpan is unchanged, but typechecker gets
-- confused, l2l call makes it happy
; return $ L (l2l srcSpan) (InjectivityAnn x injFrom' injTo') }
; let tvNames = Set.fromList $ hsAllLTyVarNames tvBndrs
resName = hsLTyVarName resTv
-- See Note [Renaming injectivity annotation]
lhsValid = EQ == (stableNameCmp resName (unLoc injFrom'))
rhsValid = Set.fromList (map unLoc injTo') `Set.difference` tvNames
-- if renaming of type variables ended with errors (eg. there were
-- not-in-scope variables) don't check the validity of injectivity
-- annotation. This gives better error messages.
; when (noRnErrors && not lhsValid) $
addErrAt (getLocA injFrom) $
TcRnIncorrectTyVarOnLhsOfInjCond resName injFrom
; when (noRnErrors && not (Set.null rhsValid)) $
do { let errorVars = Set.toList rhsValid
; addErrAt (locA srcSpan) $
TcRnUnknownTyVarsOnRhsOfInjCond errorVars }
; return injDecl' }
-- We can only hit this case when the user writes injectivity annotation without
-- naming the result:
--
-- type family F a | result -> a
-- type family F a :: * | result -> a
--
-- So we rename injectivity annotation like we normally would except that
-- this time we expect "result" to be reported not in scope by rnLTyVar.
rnInjectivityAnn _ _ (L srcSpan (InjectivityAnn x injFrom injTo)) =
setSrcSpanA srcSpan $ do
(injDecl', _) <- askNoErrs $ do
injFrom' <- rnLTyVar injFrom
injTo' <- mapM rnLTyVar injTo
return $ L srcSpan (InjectivityAnn x injFrom' injTo')
return $ injDecl'
{-
Note [Stupid theta]
~~~~~~~~~~~~~~~~~~~
#3850 complains about a regression wrt 6.10 for
data Show a => T a
There is no reason not to allow the stupid theta if there are no data
constructors. It's still stupid, but does no harm, and I don't want
to cause programs to break unnecessarily (notably HList). So if there
are no data constructors we allow h98_style = True
-}
{- *****************************************************
* *
Support code for type/data declarations
* *
***************************************************** -}
-----------------
rnConDecls :: DataDefnCons (LConDecl GhcPs) -> RnM (DataDefnCons (LConDecl GhcRn), FreeVars)
rnConDecls = mapFvRn (wrapLocFstMA rnConDecl)
rnConDecl :: ConDecl GhcPs -> RnM (ConDecl GhcRn, FreeVars)
rnConDecl decl@(ConDeclH98 { con_name = name, con_ex_tvs = ex_tvs
, con_mb_cxt = mcxt, con_args = args
, con_doc = mb_doc, con_forall = forall_ })
= do { _ <- addLocMA checkConName name
; new_name <- lookupLocatedTopConstructorRnN name
-- We bind no implicit binders here; this is just like
-- a nested HsForAllTy. E.g. consider
-- data T a = forall (b::k). MkT (...)
-- The 'k' will already be in scope from the bindHsQTyVars
-- for the data decl itself. So we'll get
-- data T {k} a = ...
-- And indeed we may later discover (a::k). But that's the
-- scoping we get. So no implicit binders at the existential forall
; let ctxt = ConDeclCtx [new_name]
; bindLHsTyVarBndrs ctxt WarnUnusedForalls
Nothing ex_tvs $ \ new_ex_tvs ->
do { (new_context, fvs1) <- rnMbContext ctxt mcxt
; (new_args, fvs2) <- rnConDeclH98Details (unLoc new_name) ctxt args
; let all_fvs = fvs1 `plusFV` fvs2
; traceRn "rnConDecl (ConDeclH98)" (ppr name <+> vcat
[ text "ex_tvs:" <+> ppr ex_tvs
, text "new_ex_dqtvs':" <+> ppr new_ex_tvs ])
; mb_doc' <- traverse rnLHsDoc mb_doc
; return (decl { con_ext = noAnn
, con_name = new_name, con_ex_tvs = new_ex_tvs
, con_mb_cxt = new_context, con_args = new_args
, con_doc = mb_doc'
, con_forall = forall_ }, -- Remove when #18311 is fixed
all_fvs) }}
rnConDecl (ConDeclGADT { con_names = names
, con_dcolon = dcol
, con_bndrs = L l outer_bndrs
, con_mb_cxt = mcxt
, con_g_args = args
, con_res_ty = res_ty
, con_doc = mb_doc })
= do { mapM_ (addLocMA checkConName) names
; new_names <- mapM (lookupLocatedTopConstructorRnN) names
; let -- We must ensure that we extract the free tkvs in left-to-right
-- order of their appearance in the constructor type.
-- That order governs the order the implicitly-quantified type
-- variable, and hence the order needed for visible type application
-- See #14808.
implicit_bndrs =
extractHsOuterTvBndrs outer_bndrs $
extractHsTysRdrTyVars (hsConDeclTheta mcxt) $
extractConDeclGADTDetailsTyVars args $
extractHsTysRdrTyVars [res_ty] []
; let ctxt = ConDeclCtx (toList new_names)
; bindHsOuterTyVarBndrs ctxt Nothing implicit_bndrs outer_bndrs $ \outer_bndrs' ->
do { (new_cxt, fvs1) <- rnMbContext ctxt mcxt
; (new_args, fvs2) <- rnConDeclGADTDetails (unLoc (head new_names)) ctxt args
; (new_res_ty, fvs3) <- rnLHsType ctxt res_ty
-- Ensure that there are no nested `forall`s or contexts, per
-- Note [GADT abstract syntax] (Wrinkle: No nested foralls or contexts)
-- in GHC.Hs.Type.
; addNoNestedForallsContextsErr ctxt
NFC_GadtConSig new_res_ty
; let all_fvs = fvs1 `plusFV` fvs2 `plusFV` fvs3
; traceRn "rnConDecl (ConDeclGADT)"
(ppr names $$ ppr outer_bndrs')
; new_mb_doc <- traverse rnLHsDoc mb_doc
; return (ConDeclGADT { con_g_ext = noAnn, con_names = new_names
, con_dcolon = dcol
, con_bndrs = L l outer_bndrs', con_mb_cxt = new_cxt
, con_g_args = new_args, con_res_ty = new_res_ty
, con_doc = new_mb_doc },
all_fvs) } }
rnMbContext :: HsDocContext -> Maybe (LHsContext GhcPs)
-> RnM (Maybe (LHsContext GhcRn), FreeVars)
rnMbContext _ Nothing = return (Nothing, emptyFVs)
rnMbContext doc cxt = do { (ctx',fvs) <- rnMaybeContext doc cxt
; return (ctx',fvs) }
rnConDeclH98Details ::
Name
-> HsDocContext
-> HsConDeclH98Details GhcPs
-> RnM (HsConDeclH98Details GhcRn, FreeVars)
rnConDeclH98Details _ doc (PrefixCon _ tys)
= do { (new_tys, fvs) <- mapFvRn (rnScaledLHsType doc) tys
; return (PrefixCon noTypeArgs new_tys, fvs) }
rnConDeclH98Details _ doc (InfixCon ty1 ty2)
= do { (new_ty1, fvs1) <- rnScaledLHsType doc ty1
; (new_ty2, fvs2) <- rnScaledLHsType doc ty2
; return (InfixCon new_ty1 new_ty2, fvs1 `plusFV` fvs2) }
rnConDeclH98Details con doc (RecCon flds)
= do { (new_flds, fvs) <- rnRecConDeclFields con doc flds
; return (RecCon new_flds, fvs) }
rnConDeclGADTDetails ::
Name
-> HsDocContext
-> HsConDeclGADTDetails GhcPs
-> RnM (HsConDeclGADTDetails GhcRn, FreeVars)
rnConDeclGADTDetails _ doc (PrefixConGADT tys)
= do { (new_tys, fvs) <- mapFvRn (rnScaledLHsType doc) tys
; return (PrefixConGADT new_tys, fvs) }
rnConDeclGADTDetails con doc (RecConGADT flds arr)
= do { (new_flds, fvs) <- rnRecConDeclFields con doc flds
; return (RecConGADT new_flds arr, fvs) }
rnRecConDeclFields ::
Name
-> HsDocContext
-> LocatedL [LConDeclField GhcPs]
-> RnM (LocatedL [LConDeclField GhcRn], FreeVars)
rnRecConDeclFields con doc (L l fields)
= do { fls <- lookupConstructorFields con
; (new_fields, fvs) <- rnConDeclFields doc fls fields
-- No need to check for duplicate fields
-- since that is done by GHC.Rename.Names.extendGlobalRdrEnvRn
; pure (L l new_fields, fvs) }
-------------------------------------------------
-- | Brings pattern synonym names and also pattern synonym selectors
-- from record pattern synonyms into scope.
extendPatSynEnv :: DuplicateRecordFields -> FieldSelectors -> HsValBinds GhcPs -> MiniFixityEnv
-> ([Name] -> TcRnIf TcGblEnv TcLclEnv a) -> TcM a
extendPatSynEnv dup_fields_ok has_sel val_decls local_fix_env thing = do {
names_with_fls <- new_ps val_decls
; let pat_syn_bndrs = concat [ conLikeName_Name name : map flSelector flds
| (name, con_info) <- names_with_fls
, let flds = conInfoFields con_info ]
; let gres = map (mkLocalConLikeGRE NoParent) names_with_fls
++ mkLocalFieldGREs NoParent names_with_fls
-- Recall Note [Parents] in GHC.Types.Name.Reader:
--
-- pattern synonym constructors and their record fields have no parent
-- in the module in which they are defined.
; (gbl_env, lcl_env) <- extendGlobalRdrEnvRn gres local_fix_env
; restoreEnvs (gbl_env, lcl_env) (thing pat_syn_bndrs) }
where
new_ps :: HsValBinds GhcPs -> TcM [(ConLikeName, ConInfo)]
new_ps (ValBinds _ binds _) = foldrM new_ps' [] binds
new_ps _ = panic "new_ps"
new_ps' :: LHsBindLR GhcPs GhcPs
-> [(ConLikeName, ConInfo)]
-> TcM [(ConLikeName, ConInfo)]
new_ps' bind names
| (L bind_loc (PatSynBind _ (PSB { psb_id = L _ n
, psb_args = RecCon as }))) <- bind
= do
bnd_name <- newTopSrcBinder (L (l2l bind_loc) n)
let field_occs = map ((\ f -> L (noAnnSrcSpan $ getLocA (foLabel f)) f) . recordPatSynField) as
flds <- mapM (newRecordFieldLabel dup_fields_ok has_sel [bnd_name]) field_occs
let con_info = mkConInfo (conDetailsArity length (RecCon as)) flds
return ((PatSynName bnd_name, con_info) : names)
| L bind_loc (PatSynBind _ (PSB { psb_id = L _ n, psb_args = as })) <- bind
= do
bnd_name <- newTopSrcBinder (L (la2na bind_loc) n)
let con_info = mkConInfo (conDetailsArity length as) []
return ((PatSynName bnd_name, con_info) : names)
| otherwise
= return names
{-
*********************************************************
* *
\subsection{Support code to rename types}
* *
*********************************************************
-}
rnFds :: [LHsFunDep GhcPs] -> RnM [LHsFunDep GhcRn]
rnFds fds
= mapM (wrapLocMA rn_fds) fds
where
rn_fds :: FunDep GhcPs -> RnM (FunDep GhcRn)
rn_fds (FunDep x tys1 tys2)
= do { tys1' <- rnHsTyVars tys1
; tys2' <- rnHsTyVars tys2
; return (FunDep x tys1' tys2') }
rnHsTyVars :: [LocatedN RdrName] -> RnM [LocatedN Name]
rnHsTyVars tvs = mapM rnHsTyVar tvs
rnHsTyVar :: LocatedN RdrName -> RnM (LocatedN Name)
rnHsTyVar (L l tyvar) = do
tyvar' <- lookupOccRn tyvar
return (L l tyvar')
{-
*********************************************************
* *
findSplice
* *
*********************************************************
This code marches down the declarations, looking for the first
Template Haskell splice. As it does so it
a) groups the declarations into a HsGroup
b) runs any top-level quasi-quotes
-}
findSplice :: [LHsDecl GhcPs]
-> RnM (HsGroup GhcPs, Maybe (SpliceDecl GhcPs, [LHsDecl GhcPs]))
findSplice ds = addl emptyRdrGroup ds
addl :: HsGroup GhcPs -> [LHsDecl GhcPs]
-> RnM (HsGroup GhcPs, Maybe (SpliceDecl GhcPs, [LHsDecl GhcPs]))
-- This stuff reverses the declarations (again) but it doesn't matter
addl gp [] = return (gp, Nothing)
addl gp (L l d : ds) = add gp l d ds
add :: HsGroup GhcPs -> SrcSpanAnnA -> HsDecl GhcPs -> [LHsDecl GhcPs]
-> RnM (HsGroup GhcPs, Maybe (SpliceDecl GhcPs, [LHsDecl GhcPs]))
-- #10047: Declaration QuasiQuoters are expanded immediately, without
-- causing a group split
add gp _ (SpliceD _ (SpliceDecl _ (L _ qq@HsQuasiQuote{}) _)) ds
= do { (ds', _) <- rnTopSpliceDecls qq
; addl gp (ds' ++ ds)
}
add gp loc (SpliceD _ splice@(SpliceDecl _ _ flag)) ds
= do { -- We've found a top-level splice. If it is an *implicit* one
-- (i.e. a naked top level expression), throw an error if
-- TemplateHaskell is not enabled.
case flag of
DollarSplice -> return ()
BareSplice -> do { unlessXOptM LangExt.TemplateHaskell
$ setSrcSpan (locA loc)
$ failWith badImplicitSplice }
; return (gp, Just (splice, ds)) }
where
badImplicitSplice :: TcRnMessage
badImplicitSplice = TcRnTHError (THSyntaxError BadImplicitSplice)
-- Class declarations: added to the TyClGroup
add gp@(HsGroup {hs_tyclds = ts}) l (TyClD _ d) ds
= addl (gp { hs_tyclds = add_tycld (L l d) ts }) ds
-- Signatures: fixity sigs go a different place than all others
add gp@(HsGroup {hs_fixds = ts}) l (SigD _ (FixSig _ f)) ds
= addl (gp {hs_fixds = L l f : ts}) ds
-- Standalone kind signatures: added to the TyClGroup
add gp@(HsGroup {hs_tyclds = ts}) l (KindSigD _ s) ds
= addl (gp {hs_tyclds = add_kisig (L l s) ts}) ds
add gp@(HsGroup {hs_valds = ts}) l (SigD _ d) ds
= addl (gp {hs_valds = add_sig (L l d) ts}) ds
-- Value declarations: use add_bind
add gp@(HsGroup {hs_valds = ts}) l (ValD _ d) ds
= addl (gp { hs_valds = add_bind (L l d) ts }) ds
-- Role annotations: added to the TyClGroup
add gp@(HsGroup {hs_tyclds = ts}) l (RoleAnnotD _ d) ds
= addl (gp { hs_tyclds = add_role_annot (L l d) ts }) ds
-- NB instance declarations go into TyClGroups. We throw them into the first
-- group, just as we do for the TyClD case. The renamer will go on to group
-- and order them later.
add gp@(HsGroup {hs_tyclds = ts}) l (InstD _ d) ds
= addl (gp { hs_tyclds = add_instd (L l d) ts }) ds
-- The rest are routine
add gp@(HsGroup {hs_derivds = ts}) l (DerivD _ d) ds
= addl (gp { hs_derivds = L l d : ts }) ds
add gp@(HsGroup {hs_defds = ts}) l (DefD _ d) ds
= addl (gp { hs_defds = L l d : ts }) ds
add gp@(HsGroup {hs_fords = ts}) l (ForD _ d) ds
= addl (gp { hs_fords = L l d : ts }) ds
add gp@(HsGroup {hs_warnds = ts}) l (WarningD _ d) ds
= addl (gp { hs_warnds = L l d : ts }) ds
add gp@(HsGroup {hs_annds = ts}) l (AnnD _ d) ds
= addl (gp { hs_annds = L l d : ts }) ds
add gp@(HsGroup {hs_ruleds = ts}) l (RuleD _ d) ds
= addl (gp { hs_ruleds = L l d : ts }) ds
add gp l (DocD _ d) ds
= addl (gp { hs_docs = (L l d) : (hs_docs gp) }) ds
add_tycld :: LTyClDecl (GhcPass p) -> [TyClGroup (GhcPass p)]
-> [TyClGroup (GhcPass p)]
add_tycld d [] = [TyClGroup { group_ext = noExtField
, group_tyclds = [d]
, group_kisigs = []
, group_roles = []
, group_instds = []
}
]
add_tycld d (ds@(TyClGroup { group_tyclds = tyclds }):dss)
= ds { group_tyclds = d : tyclds } : dss
add_instd :: LInstDecl (GhcPass p) -> [TyClGroup (GhcPass p)]
-> [TyClGroup (GhcPass p)]
add_instd d [] = [TyClGroup { group_ext = noExtField
, group_tyclds = []
, group_kisigs = []
, group_roles = []
, group_instds = [d]
}
]
add_instd d (ds@(TyClGroup { group_instds = instds }):dss)
= ds { group_instds = d : instds } : dss
add_role_annot :: LRoleAnnotDecl (GhcPass p) -> [TyClGroup (GhcPass p)]
-> [TyClGroup (GhcPass p)]
add_role_annot d [] = [TyClGroup { group_ext = noExtField
, group_tyclds = []
, group_kisigs = []
, group_roles = [d]
, group_instds = []
}
]
add_role_annot d (tycls@(TyClGroup { group_roles = roles }) : rest)
= tycls { group_roles = d : roles } : rest
add_kisig :: LStandaloneKindSig (GhcPass p)
-> [TyClGroup (GhcPass p)] -> [TyClGroup (GhcPass p)]
add_kisig d [] = [TyClGroup { group_ext = noExtField
, group_tyclds = []
, group_kisigs = [d]
, group_roles = []
, group_instds = []
}
]
add_kisig d (tycls@(TyClGroup { group_kisigs = kisigs }) : rest)
= tycls { group_kisigs = d : kisigs } : rest
add_bind :: LHsBind a -> HsValBinds a -> HsValBinds a
add_bind b (ValBinds x bs sigs) = ValBinds x (bs `snocBag` b) sigs
add_bind _ (XValBindsLR {}) = panic "GHC.Rename.Module.add_bind"
add_sig :: LSig (GhcPass a) -> HsValBinds (GhcPass a) -> HsValBinds (GhcPass a)
add_sig s (ValBinds x bs sigs) = ValBinds x bs (s:sigs)
add_sig _ (XValBindsLR {}) = panic "GHC.Rename.Module.add_sig"